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numam-dpdk/lib/pipeline/rte_swx_pipeline.c

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pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2020 Intel Corporation
*/
#include <stdlib.h>
#include <stdio.h>
#include <errno.h>
pipeline: build shared object for pipeline Build the generated C file into a shared object library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Cunming Liang <cunming.liang@intel.com>
2021-09-13 16:44:42 +00:00
#include <dlfcn.h>
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
#include <rte_jhash.h>
#include <rte_hash_crc.h>
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
#include <rte_swx_port_ethdev.h>
#include <rte_swx_port_fd.h>
#include <rte_swx_port_ring.h>
#include "rte_swx_port_source_sink.h"
pipeline: move table type registration to library Move the table type registration for the well known table types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:53 +00:00
#include <rte_swx_table_em.h>
#include <rte_swx_table_wm.h>
pipeline: move data structures to internal header file Start to consolidate the data structures and inline functions required by the pipeline instructions into an internal header file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:20 +00:00
#include "rte_swx_pipeline_internal.h"
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
#define CHECK(condition, err_code) \
do { \
if (!(condition)) \
return -(err_code); \
} while (0)
#define CHECK_NAME(name, err_code) \
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK((name) && \
(name)[0] && \
(strnlen((name), RTE_SWX_NAME_SIZE) < RTE_SWX_NAME_SIZE), \
err_code)
#define CHECK_INSTRUCTION(instr, err_code) \
CHECK((instr) && \
(instr)[0] && \
(strnlen((instr), RTE_SWX_INSTRUCTION_SIZE) < \
RTE_SWX_INSTRUCTION_SIZE), \
err_code)
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/*
* Environment.
*/
#ifndef RTE_SWX_PIPELINE_HUGE_PAGES_DISABLE
#include <rte_malloc.h>
static void *
env_malloc(size_t size, size_t alignment, int numa_node)
{
return rte_zmalloc_socket(NULL, size, alignment, numa_node);
}
static void
env_free(void *start, size_t size __rte_unused)
{
rte_free(start);
}
#else
#include <numa.h>
static void *
env_malloc(size_t size, size_t alignment __rte_unused, int numa_node)
{
void *start;
if (numa_available() == -1)
return NULL;
start = numa_alloc_onnode(size, numa_node);
if (!start)
return NULL;
memset(start, 0, size);
return start;
}
static void
env_free(void *start, size_t size)
{
if (numa_available() == -1)
return;
numa_free(start, size);
}
#endif
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
/*
* Struct.
*/
static struct struct_type *
struct_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct struct_type *elem;
TAILQ_FOREACH(elem, &p->struct_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
static struct field *
struct_type_field_find(struct struct_type *st, const char *name)
{
uint32_t i;
for (i = 0; i < st->n_fields; i++) {
struct field *f = &st->fields[i];
if (strcmp(f->name, name) == 0)
return f;
}
return NULL;
}
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
int
rte_swx_pipeline_struct_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_field_params *fields,
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
uint32_t n_fields,
int last_field_has_variable_size)
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
{
struct struct_type *st;
uint32_t i;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(fields, EINVAL);
CHECK(n_fields, EINVAL);
for (i = 0; i < n_fields; i++) {
struct rte_swx_field_params *f = &fields[i];
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
int var_size = ((i == n_fields - 1) && last_field_has_variable_size) ? 1 : 0;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
uint32_t j;
CHECK_NAME(f->name, EINVAL);
CHECK(f->n_bits, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK((f->n_bits <= 64) || var_size, EINVAL);
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
CHECK((f->n_bits & 7) == 0, EINVAL);
for (j = 0; j < i; j++) {
struct rte_swx_field_params *f_prev = &fields[j];
CHECK(strcmp(f->name, f_prev->name), EINVAL);
}
}
CHECK(!struct_type_find(p, name), EEXIST);
/* Node allocation. */
st = calloc(1, sizeof(struct struct_type));
CHECK(st, ENOMEM);
st->fields = calloc(n_fields, sizeof(struct field));
if (!st->fields) {
free(st);
CHECK(0, ENOMEM);
}
/* Node initialization. */
strcpy(st->name, name);
for (i = 0; i < n_fields; i++) {
struct field *dst = &st->fields[i];
struct rte_swx_field_params *src = &fields[i];
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
int var_size = ((i == n_fields - 1) && last_field_has_variable_size) ? 1 : 0;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
strcpy(dst->name, src->name);
dst->n_bits = src->n_bits;
dst->offset = st->n_bits;
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
dst->var_size = var_size;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
st->n_bits += src->n_bits;
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
st->n_bits_min += var_size ? 0 : src->n_bits;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
}
st->n_fields = n_fields;
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
st->var_size = last_field_has_variable_size;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->struct_types, st, node);
return 0;
}
static int
struct_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
t->structs = calloc(p->n_structs, sizeof(uint8_t *));
CHECK(t->structs, ENOMEM);
}
return 0;
}
static void
struct_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->structs);
t->structs = NULL;
}
}
static void
struct_free(struct rte_swx_pipeline *p)
{
struct_build_free(p);
/* Struct types. */
for ( ; ; ) {
struct struct_type *elem;
elem = TAILQ_FIRST(&p->struct_types);
if (!elem)
break;
TAILQ_REMOVE(&p->struct_types, elem, node);
free(elem->fields);
free(elem);
}
}
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
/*
* Input port.
*/
static struct port_in_type *
port_in_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct port_in_type *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->port_in_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
int
rte_swx_pipeline_port_in_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_port_in_ops *ops)
{
struct port_in_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->free, EINVAL);
CHECK(ops->pkt_rx, EINVAL);
CHECK(ops->stats_read, EINVAL);
CHECK(!port_in_type_find(p, name), EEXIST);
/* Node allocation. */
elem = calloc(1, sizeof(struct port_in_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->port_in_types, elem, node);
return 0;
}
static struct port_in *
port_in_find(struct rte_swx_pipeline *p, uint32_t port_id)
{
struct port_in *port;
TAILQ_FOREACH(port, &p->ports_in, node)
if (port->id == port_id)
return port;
return NULL;
}
int
rte_swx_pipeline_port_in_config(struct rte_swx_pipeline *p,
uint32_t port_id,
const char *port_type_name,
void *args)
{
struct port_in_type *type = NULL;
struct port_in *port = NULL;
void *obj = NULL;
CHECK(p, EINVAL);
CHECK(!port_in_find(p, port_id), EINVAL);
CHECK_NAME(port_type_name, EINVAL);
type = port_in_type_find(p, port_type_name);
CHECK(type, EINVAL);
obj = type->ops.create(args);
CHECK(obj, ENODEV);
/* Node allocation. */
port = calloc(1, sizeof(struct port_in));
CHECK(port, ENOMEM);
/* Node initialization. */
port->type = type;
port->obj = obj;
port->id = port_id;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->ports_in, port, node);
if (p->n_ports_in < port_id + 1)
p->n_ports_in = port_id + 1;
return 0;
}
static int
port_in_build(struct rte_swx_pipeline *p)
{
struct port_in *port;
uint32_t i;
CHECK(p->n_ports_in, EINVAL);
CHECK(rte_is_power_of_2(p->n_ports_in), EINVAL);
for (i = 0; i < p->n_ports_in; i++)
CHECK(port_in_find(p, i), EINVAL);
p->in = calloc(p->n_ports_in, sizeof(struct port_in_runtime));
CHECK(p->in, ENOMEM);
TAILQ_FOREACH(port, &p->ports_in, node) {
struct port_in_runtime *in = &p->in[port->id];
in->pkt_rx = port->type->ops.pkt_rx;
in->obj = port->obj;
}
return 0;
}
static void
port_in_build_free(struct rte_swx_pipeline *p)
{
free(p->in);
p->in = NULL;
}
static void
port_in_free(struct rte_swx_pipeline *p)
{
port_in_build_free(p);
/* Input ports. */
for ( ; ; ) {
struct port_in *port;
port = TAILQ_FIRST(&p->ports_in);
if (!port)
break;
TAILQ_REMOVE(&p->ports_in, port, node);
port->type->ops.free(port->obj);
free(port);
}
/* Input port types. */
for ( ; ; ) {
struct port_in_type *elem;
elem = TAILQ_FIRST(&p->port_in_types);
if (!elem)
break;
TAILQ_REMOVE(&p->port_in_types, elem, node);
free(elem);
}
}
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
/*
* Output port.
*/
static struct port_out_type *
port_out_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct port_out_type *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->port_out_types, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
int
rte_swx_pipeline_port_out_type_register(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_port_out_ops *ops)
{
struct port_out_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->free, EINVAL);
CHECK(ops->pkt_tx, EINVAL);
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
CHECK(ops->pkt_fast_clone_tx, EINVAL);
CHECK(ops->pkt_clone_tx, EINVAL);
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
CHECK(ops->stats_read, EINVAL);
CHECK(!port_out_type_find(p, name), EEXIST);
/* Node allocation. */
elem = calloc(1, sizeof(struct port_out_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->port_out_types, elem, node);
return 0;
}
static struct port_out *
port_out_find(struct rte_swx_pipeline *p, uint32_t port_id)
{
struct port_out *port;
TAILQ_FOREACH(port, &p->ports_out, node)
if (port->id == port_id)
return port;
return NULL;
}
int
rte_swx_pipeline_port_out_config(struct rte_swx_pipeline *p,
uint32_t port_id,
const char *port_type_name,
void *args)
{
struct port_out_type *type = NULL;
struct port_out *port = NULL;
void *obj = NULL;
CHECK(p, EINVAL);
CHECK(!port_out_find(p, port_id), EINVAL);
CHECK_NAME(port_type_name, EINVAL);
type = port_out_type_find(p, port_type_name);
CHECK(type, EINVAL);
obj = type->ops.create(args);
CHECK(obj, ENODEV);
/* Node allocation. */
port = calloc(1, sizeof(struct port_out));
CHECK(port, ENOMEM);
/* Node initialization. */
port->type = type;
port->obj = obj;
port->id = port_id;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->ports_out, port, node);
if (p->n_ports_out < port_id + 1)
p->n_ports_out = port_id + 1;
return 0;
}
static int
port_out_build(struct rte_swx_pipeline *p)
{
struct port_out *port;
uint32_t i;
CHECK(p->n_ports_out, EINVAL);
for (i = 0; i < p->n_ports_out; i++)
CHECK(port_out_find(p, i), EINVAL);
p->out = calloc(p->n_ports_out, sizeof(struct port_out_runtime));
CHECK(p->out, ENOMEM);
TAILQ_FOREACH(port, &p->ports_out, node) {
struct port_out_runtime *out = &p->out[port->id];
out->pkt_tx = port->type->ops.pkt_tx;
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
out->pkt_fast_clone_tx = port->type->ops.pkt_fast_clone_tx;
out->pkt_clone_tx = port->type->ops.pkt_clone_tx;
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
out->flush = port->type->ops.flush;
out->obj = port->obj;
}
return 0;
}
static void
port_out_build_free(struct rte_swx_pipeline *p)
{
free(p->out);
p->out = NULL;
}
static void
port_out_free(struct rte_swx_pipeline *p)
{
port_out_build_free(p);
/* Output ports. */
for ( ; ; ) {
struct port_out *port;
port = TAILQ_FIRST(&p->ports_out);
if (!port)
break;
TAILQ_REMOVE(&p->ports_out, port, node);
port->type->ops.free(port->obj);
free(port);
}
/* Output port types. */
for ( ; ; ) {
struct port_out_type *elem;
elem = TAILQ_FIRST(&p->port_out_types);
if (!elem)
break;
TAILQ_REMOVE(&p->port_out_types, elem, node);
free(elem);
}
}
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
/*
* Packet mirroring.
*/
int
rte_swx_pipeline_mirroring_config(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_mirroring_params *params)
{
CHECK(p, EINVAL);
CHECK(params, EINVAL);
CHECK(params->n_slots, EINVAL);
CHECK(params->n_sessions, EINVAL);
CHECK(!p->build_done, EEXIST);
p->n_mirroring_slots = rte_align32pow2(params->n_slots);
if (p->n_mirroring_slots > 64)
p->n_mirroring_slots = 64;
p->n_mirroring_sessions = rte_align32pow2(params->n_sessions);
return 0;
}
static void
mirroring_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
/* mirroring_slots. */
free(t->mirroring_slots);
t->mirroring_slots = NULL;
}
/* mirroring_sessions. */
free(p->mirroring_sessions);
p->mirroring_sessions = NULL;
}
static void
mirroring_free(struct rte_swx_pipeline *p)
{
mirroring_build_free(p);
}
static int
mirroring_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
/* mirroring_slots. */
t->mirroring_slots = calloc(p->n_mirroring_slots, sizeof(uint32_t));
if (!t->mirroring_slots)
goto error;
}
/* mirroring_sessions. */
p->mirroring_sessions = calloc(p->n_mirroring_sessions, sizeof(struct mirroring_session));
if (!p->mirroring_sessions)
goto error;
return 0;
error:
mirroring_build_free(p);
return -ENOMEM;
}
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
/*
* Extern object.
*/
static struct extern_type *
extern_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_type *elem;
TAILQ_FOREACH(elem, &p->extern_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_type_member_func *
extern_type_member_func_find(struct extern_type *type, const char *name)
{
struct extern_type_member_func *elem;
TAILQ_FOREACH(elem, &type->funcs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct extern_obj *
extern_obj_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_obj *elem;
TAILQ_FOREACH(elem, &p->extern_objs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
static struct extern_type_member_func *
extern_obj_member_func_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_obj **obj)
{
struct extern_obj *object;
struct extern_type_member_func *func;
char *object_name, *func_name;
if (name[0] != 'e' || name[1] != '.')
return NULL;
object_name = strdup(&name[2]);
if (!object_name)
return NULL;
func_name = strchr(object_name, '.');
if (!func_name) {
free(object_name);
return NULL;
}
*func_name = 0;
func_name++;
object = extern_obj_find(p, object_name);
if (!object) {
free(object_name);
return NULL;
}
func = extern_type_member_func_find(object->type, func_name);
if (!func) {
free(object_name);
return NULL;
}
if (obj)
*obj = object;
free(object_name);
return func;
}
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
static struct field *
extern_obj_mailbox_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_obj **object)
{
struct extern_obj *obj;
struct field *f;
char *obj_name, *field_name;
if ((name[0] != 'e') || (name[1] != '.'))
return NULL;
obj_name = strdup(&name[2]);
if (!obj_name)
return NULL;
field_name = strchr(obj_name, '.');
if (!field_name) {
free(obj_name);
return NULL;
}
*field_name = 0;
field_name++;
obj = extern_obj_find(p, obj_name);
if (!obj) {
free(obj_name);
return NULL;
}
f = struct_type_field_find(obj->type->mailbox_struct_type, field_name);
if (!f) {
free(obj_name);
return NULL;
}
if (object)
*object = obj;
free(obj_name);
return f;
}
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
int
rte_swx_pipeline_extern_type_register(struct rte_swx_pipeline *p,
const char *name,
const char *mailbox_struct_type_name,
rte_swx_extern_type_constructor_t constructor,
rte_swx_extern_type_destructor_t destructor)
{
struct extern_type *elem;
struct struct_type *mailbox_struct_type;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_type_find(p, name), EEXIST);
CHECK_NAME(mailbox_struct_type_name, EINVAL);
mailbox_struct_type = struct_type_find(p, mailbox_struct_type_name);
CHECK(mailbox_struct_type, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!mailbox_struct_type->var_size, EINVAL);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
CHECK(constructor, EINVAL);
CHECK(destructor, EINVAL);
/* Node allocation. */
elem = calloc(1, sizeof(struct extern_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
elem->mailbox_struct_type = mailbox_struct_type;
elem->constructor = constructor;
elem->destructor = destructor;
TAILQ_INIT(&elem->funcs);
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_types, elem, node);
return 0;
}
int
rte_swx_pipeline_extern_type_member_func_register(struct rte_swx_pipeline *p,
const char *extern_type_name,
const char *name,
rte_swx_extern_type_member_func_t member_func)
{
struct extern_type *type;
struct extern_type_member_func *type_member;
CHECK(p, EINVAL);
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_NAME(extern_type_name, EINVAL);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
type = extern_type_find(p, extern_type_name);
CHECK(type, EINVAL);
CHECK(type->n_funcs < RTE_SWX_EXTERN_TYPE_MEMBER_FUNCS_MAX, ENOSPC);
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_NAME(name, EINVAL);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
CHECK(!extern_type_member_func_find(type, name), EEXIST);
CHECK(member_func, EINVAL);
/* Node allocation. */
type_member = calloc(1, sizeof(struct extern_type_member_func));
CHECK(type_member, ENOMEM);
/* Node initialization. */
strcpy(type_member->name, name);
type_member->func = member_func;
type_member->id = type->n_funcs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&type->funcs, type_member, node);
type->n_funcs++;
return 0;
}
int
rte_swx_pipeline_extern_object_config(struct rte_swx_pipeline *p,
const char *extern_type_name,
const char *name,
const char *args)
{
struct extern_type *type;
struct extern_obj *obj;
void *obj_handle;
CHECK(p, EINVAL);
CHECK_NAME(extern_type_name, EINVAL);
type = extern_type_find(p, extern_type_name);
CHECK(type, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_obj_find(p, name), EEXIST);
/* Node allocation. */
obj = calloc(1, sizeof(struct extern_obj));
CHECK(obj, ENOMEM);
/* Object construction. */
obj_handle = type->constructor(args);
if (!obj_handle) {
free(obj);
CHECK(0, ENODEV);
}
/* Node initialization. */
strcpy(obj->name, name);
obj->type = type;
obj->obj = obj_handle;
obj->struct_id = p->n_structs;
obj->id = p->n_extern_objs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_objs, obj, node);
p->n_extern_objs++;
p->n_structs++;
return 0;
}
static int
extern_obj_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct extern_obj *obj;
t->extern_objs = calloc(p->n_extern_objs,
sizeof(struct extern_obj_runtime));
CHECK(t->extern_objs, ENOMEM);
TAILQ_FOREACH(obj, &p->extern_objs, node) {
struct extern_obj_runtime *r =
&t->extern_objs[obj->id];
struct extern_type_member_func *func;
uint32_t mailbox_size =
obj->type->mailbox_struct_type->n_bits / 8;
r->obj = obj->obj;
r->mailbox = calloc(1, mailbox_size);
CHECK(r->mailbox, ENOMEM);
TAILQ_FOREACH(func, &obj->type->funcs, node)
r->funcs[func->id] = func->func;
t->structs[obj->struct_id] = r->mailbox;
}
}
return 0;
}
static void
extern_obj_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->extern_objs)
continue;
for (j = 0; j < p->n_extern_objs; j++) {
struct extern_obj_runtime *r = &t->extern_objs[j];
free(r->mailbox);
}
free(t->extern_objs);
t->extern_objs = NULL;
}
}
static void
extern_obj_free(struct rte_swx_pipeline *p)
{
extern_obj_build_free(p);
/* Extern objects. */
for ( ; ; ) {
struct extern_obj *elem;
elem = TAILQ_FIRST(&p->extern_objs);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_objs, elem, node);
if (elem->obj)
elem->type->destructor(elem->obj);
free(elem);
}
/* Extern types. */
for ( ; ; ) {
struct extern_type *elem;
elem = TAILQ_FIRST(&p->extern_types);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_types, elem, node);
for ( ; ; ) {
struct extern_type_member_func *func;
func = TAILQ_FIRST(&elem->funcs);
if (!func)
break;
TAILQ_REMOVE(&elem->funcs, func, node);
free(func);
}
free(elem);
}
}
/*
* Extern function.
*/
static struct extern_func *
extern_func_find(struct rte_swx_pipeline *p, const char *name)
{
struct extern_func *elem;
TAILQ_FOREACH(elem, &p->extern_funcs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
static struct extern_func *
extern_func_parse(struct rte_swx_pipeline *p,
const char *name)
{
if (name[0] != 'f' || name[1] != '.')
return NULL;
return extern_func_find(p, &name[2]);
}
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
static struct field *
extern_func_mailbox_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct extern_func **function)
{
struct extern_func *func;
struct field *f;
char *func_name, *field_name;
if ((name[0] != 'f') || (name[1] != '.'))
return NULL;
func_name = strdup(&name[2]);
if (!func_name)
return NULL;
field_name = strchr(func_name, '.');
if (!field_name) {
free(func_name);
return NULL;
}
*field_name = 0;
field_name++;
func = extern_func_find(p, func_name);
if (!func) {
free(func_name);
return NULL;
}
f = struct_type_field_find(func->mailbox_struct_type, field_name);
if (!f) {
free(func_name);
return NULL;
}
if (function)
*function = func;
free(func_name);
return f;
}
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
int
rte_swx_pipeline_extern_func_register(struct rte_swx_pipeline *p,
const char *name,
const char *mailbox_struct_type_name,
rte_swx_extern_func_t func)
{
struct extern_func *f;
struct struct_type *mailbox_struct_type;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!extern_func_find(p, name), EEXIST);
CHECK_NAME(mailbox_struct_type_name, EINVAL);
mailbox_struct_type = struct_type_find(p, mailbox_struct_type_name);
CHECK(mailbox_struct_type, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!mailbox_struct_type->var_size, EINVAL);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
CHECK(func, EINVAL);
/* Node allocation. */
f = calloc(1, sizeof(struct extern_func));
CHECK(func, ENOMEM);
/* Node initialization. */
strcpy(f->name, name);
f->mailbox_struct_type = mailbox_struct_type;
f->func = func;
f->struct_id = p->n_structs;
f->id = p->n_extern_funcs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->extern_funcs, f, node);
p->n_extern_funcs++;
p->n_structs++;
return 0;
}
static int
extern_func_build(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct extern_func *func;
/* Memory allocation. */
t->extern_funcs = calloc(p->n_extern_funcs,
sizeof(struct extern_func_runtime));
CHECK(t->extern_funcs, ENOMEM);
/* Extern function. */
TAILQ_FOREACH(func, &p->extern_funcs, node) {
struct extern_func_runtime *r =
&t->extern_funcs[func->id];
uint32_t mailbox_size =
func->mailbox_struct_type->n_bits / 8;
r->func = func->func;
r->mailbox = calloc(1, mailbox_size);
CHECK(r->mailbox, ENOMEM);
t->structs[func->struct_id] = r->mailbox;
}
}
return 0;
}
static void
extern_func_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->extern_funcs)
continue;
for (j = 0; j < p->n_extern_funcs; j++) {
struct extern_func_runtime *r = &t->extern_funcs[j];
free(r->mailbox);
}
free(t->extern_funcs);
t->extern_funcs = NULL;
}
}
static void
extern_func_free(struct rte_swx_pipeline *p)
{
extern_func_build_free(p);
for ( ; ; ) {
struct extern_func *elem;
elem = TAILQ_FIRST(&p->extern_funcs);
if (!elem)
break;
TAILQ_REMOVE(&p->extern_funcs, elem, node);
free(elem);
}
}
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
/*
* Hash function.
*/
static struct hash_func *
hash_func_find(struct rte_swx_pipeline *p, const char *name)
{
struct hash_func *elem;
TAILQ_FOREACH(elem, &p->hash_funcs, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
int
rte_swx_pipeline_hash_func_register(struct rte_swx_pipeline *p,
const char *name,
rte_swx_hash_func_t func)
{
struct hash_func *f;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!hash_func_find(p, name), EEXIST);
CHECK(func, EINVAL);
/* Node allocation. */
f = calloc(1, sizeof(struct hash_func));
CHECK(func, ENOMEM);
/* Node initialization. */
strcpy(f->name, name);
f->func = func;
f->id = p->n_hash_funcs;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->hash_funcs, f, node);
p->n_hash_funcs++;
return 0;
}
static int
hash_func_build(struct rte_swx_pipeline *p)
{
struct hash_func *func;
/* Memory allocation. */
p->hash_func_runtime = calloc(p->n_hash_funcs, sizeof(struct hash_func_runtime));
CHECK(p->hash_func_runtime, ENOMEM);
/* Hash function. */
TAILQ_FOREACH(func, &p->hash_funcs, node) {
struct hash_func_runtime *r = &p->hash_func_runtime[func->id];
r->func = func->func;
}
return 0;
}
static void
hash_func_build_free(struct rte_swx_pipeline *p)
{
free(p->hash_func_runtime);
p->hash_func_runtime = NULL;
}
static void
hash_func_free(struct rte_swx_pipeline *p)
{
hash_func_build_free(p);
for ( ; ; ) {
struct hash_func *elem;
elem = TAILQ_FIRST(&p->hash_funcs);
if (!elem)
break;
TAILQ_REMOVE(&p->hash_funcs, elem, node);
free(elem);
}
}
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
/*
* Header.
*/
static struct header *
header_find(struct rte_swx_pipeline *p, const char *name)
{
struct header *elem;
TAILQ_FOREACH(elem, &p->headers, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
static struct header *
header_find_by_struct_id(struct rte_swx_pipeline *p, uint32_t struct_id)
{
struct header *elem;
TAILQ_FOREACH(elem, &p->headers, node)
if (elem->struct_id == struct_id)
return elem;
return NULL;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
static struct header *
header_parse(struct rte_swx_pipeline *p,
const char *name)
{
if (name[0] != 'h' || name[1] != '.')
return NULL;
return header_find(p, &name[2]);
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
static struct field *
header_field_parse(struct rte_swx_pipeline *p,
const char *name,
struct header **header)
{
struct header *h;
struct field *f;
char *header_name, *field_name;
if ((name[0] != 'h') || (name[1] != '.'))
return NULL;
header_name = strdup(&name[2]);
if (!header_name)
return NULL;
field_name = strchr(header_name, '.');
if (!field_name) {
free(header_name);
return NULL;
}
*field_name = 0;
field_name++;
h = header_find(p, header_name);
if (!h) {
free(header_name);
return NULL;
}
f = struct_type_field_find(h->st, field_name);
if (!f) {
free(header_name);
return NULL;
}
if (header)
*header = h;
free(header_name);
return f;
}
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
int
rte_swx_pipeline_packet_header_register(struct rte_swx_pipeline *p,
const char *name,
const char *struct_type_name)
{
struct struct_type *st;
struct header *h;
size_t n_headers_max;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK_NAME(struct_type_name, EINVAL);
CHECK(!header_find(p, name), EEXIST);
st = struct_type_find(p, struct_type_name);
CHECK(st, EINVAL);
n_headers_max = RTE_SIZEOF_FIELD(struct thread, valid_headers) * 8;
CHECK(p->n_headers < n_headers_max, ENOSPC);
/* Node allocation. */
h = calloc(1, sizeof(struct header));
CHECK(h, ENOMEM);
/* Node initialization. */
strcpy(h->name, name);
h->st = st;
h->struct_id = p->n_structs;
h->id = p->n_headers;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->headers, h, node);
p->n_headers++;
p->n_structs++;
return 0;
}
static int
header_build(struct rte_swx_pipeline *p)
{
struct header *h;
uint32_t n_bytes = 0, i;
TAILQ_FOREACH(h, &p->headers, node) {
n_bytes += h->st->n_bits / 8;
}
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t offset = 0;
t->headers = calloc(p->n_headers,
sizeof(struct header_runtime));
CHECK(t->headers, ENOMEM);
t->headers_out = calloc(p->n_headers,
sizeof(struct header_out_runtime));
CHECK(t->headers_out, ENOMEM);
t->header_storage = calloc(1, n_bytes);
CHECK(t->header_storage, ENOMEM);
t->header_out_storage = calloc(1, n_bytes);
CHECK(t->header_out_storage, ENOMEM);
TAILQ_FOREACH(h, &p->headers, node) {
uint8_t *header_storage;
pipeline: prepare for variable size headers The emit instruction that is responsible for pushing headers into the output packet is now reading the header length from internal run-time structures as opposed to constant value from the instruction opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:36 +00:00
uint32_t n_bytes = h->st->n_bits / 8;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
header_storage = &t->header_storage[offset];
pipeline: prepare for variable size headers The emit instruction that is responsible for pushing headers into the output packet is now reading the header length from internal run-time structures as opposed to constant value from the instruction opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:36 +00:00
offset += n_bytes;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
t->headers[h->id].ptr0 = header_storage;
pipeline: prepare for variable size headers The emit instruction that is responsible for pushing headers into the output packet is now reading the header length from internal run-time structures as opposed to constant value from the instruction opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:36 +00:00
t->headers[h->id].n_bytes = n_bytes;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
t->structs[h->struct_id] = header_storage;
}
}
return 0;
}
static void
header_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->headers_out);
t->headers_out = NULL;
free(t->headers);
t->headers = NULL;
free(t->header_out_storage);
t->header_out_storage = NULL;
free(t->header_storage);
t->header_storage = NULL;
}
}
static void
header_free(struct rte_swx_pipeline *p)
{
header_build_free(p);
for ( ; ; ) {
struct header *elem;
elem = TAILQ_FIRST(&p->headers);
if (!elem)
break;
TAILQ_REMOVE(&p->headers, elem, node);
free(elem);
}
}
/*
* Meta-data.
*/
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
static struct field *
metadata_field_parse(struct rte_swx_pipeline *p, const char *name)
{
if (!p->metadata_st)
return NULL;
if (name[0] != 'm' || name[1] != '.')
return NULL;
return struct_type_field_find(p->metadata_st, &name[2]);
}
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
int
rte_swx_pipeline_packet_metadata_register(struct rte_swx_pipeline *p,
const char *struct_type_name)
{
struct struct_type *st = NULL;
CHECK(p, EINVAL);
CHECK_NAME(struct_type_name, EINVAL);
st = struct_type_find(p, struct_type_name);
CHECK(st, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!st->var_size, EINVAL);
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
CHECK(!p->metadata_st, EINVAL);
p->metadata_st = st;
p->metadata_struct_id = p->n_structs;
p->n_structs++;
return 0;
}
static int
metadata_build(struct rte_swx_pipeline *p)
{
uint32_t n_bytes = p->metadata_st->n_bits / 8;
uint32_t i;
/* Thread-level initialization. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint8_t *metadata;
metadata = calloc(1, n_bytes);
CHECK(metadata, ENOMEM);
t->metadata = metadata;
t->structs[p->metadata_struct_id] = metadata;
}
return 0;
}
static void
metadata_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
free(t->metadata);
t->metadata = NULL;
}
}
static void
metadata_free(struct rte_swx_pipeline *p)
{
metadata_build_free(p);
}
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
/*
* Instruction.
*/
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
static int
instruction_is_tx(enum instruction_type type)
{
switch (type) {
case INSTR_TX:
case INSTR_TX_I:
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
case INSTR_DROP:
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
return 1;
default:
return 0;
}
}
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
static int
instruction_does_tx(struct instruction *instr)
{
switch (instr->type) {
case INSTR_TX:
case INSTR_TX_I:
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
case INSTR_DROP:
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
case INSTR_HDR_EMIT_TX:
case INSTR_HDR_EMIT2_TX:
case INSTR_HDR_EMIT3_TX:
case INSTR_HDR_EMIT4_TX:
case INSTR_HDR_EMIT5_TX:
case INSTR_HDR_EMIT6_TX:
case INSTR_HDR_EMIT7_TX:
case INSTR_HDR_EMIT8_TX:
return 1;
default:
return 0;
}
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static int
instruction_is_jmp(struct instruction *instr)
{
switch (instr->type) {
case INSTR_JMP:
case INSTR_JMP_VALID:
case INSTR_JMP_INVALID:
case INSTR_JMP_HIT:
case INSTR_JMP_MISS:
case INSTR_JMP_ACTION_HIT:
case INSTR_JMP_ACTION_MISS:
case INSTR_JMP_EQ:
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
case INSTR_JMP_EQ_MH:
case INSTR_JMP_EQ_HM:
case INSTR_JMP_EQ_HH:
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
case INSTR_JMP_EQ_I:
case INSTR_JMP_NEQ:
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
case INSTR_JMP_NEQ_MH:
case INSTR_JMP_NEQ_HM:
case INSTR_JMP_NEQ_HH:
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
case INSTR_JMP_NEQ_I:
case INSTR_JMP_LT:
case INSTR_JMP_LT_MH:
case INSTR_JMP_LT_HM:
case INSTR_JMP_LT_HH:
case INSTR_JMP_LT_MI:
case INSTR_JMP_LT_HI:
case INSTR_JMP_GT:
case INSTR_JMP_GT_MH:
case INSTR_JMP_GT_HM:
case INSTR_JMP_GT_HH:
case INSTR_JMP_GT_MI:
case INSTR_JMP_GT_HI:
return 1;
default:
return 0;
}
}
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
static int
instruction_does_thread_yield(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX:
case INSTR_TABLE:
case INSTR_TABLE_AF:
case INSTR_SELECTOR:
case INSTR_LEARNER:
case INSTR_LEARNER_AF:
case INSTR_EXTERN_OBJ:
case INSTR_EXTERN_FUNC:
return 1;
default:
return 0;
}
}
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
static struct field *
action_field_parse(struct action *action, const char *name);
static struct field *
struct_field_parse(struct rte_swx_pipeline *p,
struct action *action,
const char *name,
uint32_t *struct_id)
{
struct field *f;
switch (name[0]) {
case 'h':
{
struct header *header;
f = header_field_parse(p, name, &header);
if (!f)
return NULL;
*struct_id = header->struct_id;
return f;
}
case 'm':
{
f = metadata_field_parse(p, name);
if (!f)
return NULL;
*struct_id = p->metadata_struct_id;
return f;
}
case 't':
{
if (!action)
return NULL;
f = action_field_parse(action, name);
if (!f)
return NULL;
*struct_id = 0;
return f;
}
case 'e':
{
struct extern_obj *obj;
f = extern_obj_mailbox_field_parse(p, name, &obj);
if (!f)
return NULL;
*struct_id = obj->struct_id;
return f;
}
case 'f':
{
struct extern_func *func;
f = extern_func_mailbox_field_parse(p, name, &func);
if (!f)
return NULL;
*struct_id = func->struct_id;
return f;
}
default:
return NULL;
}
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/*
* rx.
*/
static int
instr_rx_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct field *f;
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
f = metadata_field_parse(p, tokens[1]);
CHECK(f, EINVAL);
instr->type = INSTR_RX;
instr->io.io.offset = f->offset / 8;
instr->io.io.n_bits = f->n_bits;
return 0;
}
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
/*
* tx.
*/
static int
instr_tx_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
char *port = tokens[1];
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
struct field *f;
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
uint32_t port_val;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
CHECK(n_tokens == 2, EINVAL);
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
f = metadata_field_parse(p, port);
if (f) {
instr->type = INSTR_TX;
instr->io.io.offset = f->offset / 8;
instr->io.io.n_bits = f->n_bits;
return 0;
}
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
/* TX_I. */
port_val = strtoul(port, &port, 0);
CHECK(!port[0], EINVAL);
instr->type = INSTR_TX_I;
instr->io.io.val = port_val;
return 0;
}
static int
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
instr_drop_translate(struct rte_swx_pipeline *p __rte_unused,
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
struct action *action __rte_unused,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(n_tokens == 1, EINVAL);
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
/* DROP. */
instr->type = INSTR_DROP;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
return 0;
}
static inline void
instr_tx_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for Tx instruction Create inline functions for the Tx instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:23 +00:00
__instr_tx_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
static inline void
instr_tx_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for Tx instruction Create inline functions for the Tx instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:23 +00:00
__instr_tx_i_exec(p, t, ip);
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
static inline void
instr_drop_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_drop_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
}
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
/*
* mirror.
*/
static int
instr_mirror_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
uint32_t dst_struct_id = 0, src_struct_id = 0;
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, action, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
CHECK(dst[0] != 'h', EINVAL);
CHECK(!fdst->var_size, EINVAL);
fsrc = struct_field_parse(p, action, src, &src_struct_id);
CHECK(fsrc, EINVAL);
CHECK(src[0] != 'h', EINVAL);
CHECK(!fsrc->var_size, EINVAL);
instr->type = INSTR_MIRROR;
instr->mirror.dst.struct_id = (uint8_t)dst_struct_id;
instr->mirror.dst.n_bits = fdst->n_bits;
instr->mirror.dst.offset = fdst->offset / 8;
instr->mirror.src.struct_id = (uint8_t)src_struct_id;
instr->mirror.src.n_bits = fsrc->n_bits;
instr->mirror.src.offset = fsrc->offset / 8;
return 0;
}
static inline void
instr_mirror_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_mirror_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
/*
* recirculate.
*/
static int
instr_recirculate_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action __rte_unused,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(n_tokens == 1, EINVAL);
instr->type = INSTR_RECIRCULATE;
return 0;
}
static int
instr_recircid_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct field *f;
CHECK(n_tokens == 2, EINVAL);
f = metadata_field_parse(p, tokens[1]);
CHECK(f, EINVAL);
instr->type = INSTR_RECIRCID;
instr->io.io.offset = f->offset / 8;
instr->io.io.n_bits = f->n_bits;
return 0;
}
static inline void
instr_recirculate_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_recirculate_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_recircid_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_recircid_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/*
* extract.
*/
static int
instr_hdr_extract_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(!action, EINVAL);
pipeline: add variable size headers extract instruction Added a mechanism to extract variable size headers through a special flavor of the extract instruction. The length of the last struct field which has variable size is passed as argument to the instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:38 +00:00
CHECK((n_tokens == 2) || (n_tokens == 3), EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
pipeline: add variable size headers extract instruction Added a mechanism to extract variable size headers through a special flavor of the extract instruction. The length of the last struct field which has variable size is passed as argument to the instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:38 +00:00
if (n_tokens == 2) {
CHECK(!h->st->var_size, EINVAL);
instr->type = INSTR_HDR_EXTRACT;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits / 8;
} else {
struct field *mf;
CHECK(h->st->var_size, EINVAL);
mf = metadata_field_parse(p, tokens[2]);
CHECK(mf, EINVAL);
CHECK(!mf->var_size, EINVAL);
instr->type = INSTR_HDR_EXTRACT_M;
instr->io.io.offset = mf->offset / 8;
instr->io.io.n_bits = mf->n_bits;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits_min / 8;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
return 0;
}
pipeline: add header look-ahead instruction Added look-ahead instruction to read a header from the input packet without advancing the extraction pointer. This is typically used in correlation with the special extract instruction to extract variable size headers from the input packet: the first few header fields are read without advancing the extraction pointer, just enough to detect the actual length of the header (e.g. IPv4 IHL field); then the full header is extracted. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:39 +00:00
static int
instr_hdr_lookahead_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
CHECK(!h->st->var_size, EINVAL);
instr->type = INSTR_HDR_LOOKAHEAD;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = 0; /* Unused. */
return 0;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
static inline void
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
instr_hdr_extract_exec(struct rte_swx_pipeline *p)
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract2_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract2_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract3_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract3_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract4_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract4_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract5_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract5_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract6_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract6_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract7_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract7_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_extract8_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract8_exec(p, t, ip);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: add variable size headers extract instruction Added a mechanism to extract variable size headers through a special flavor of the extract instruction. The length of the last struct field which has variable size is passed as argument to the instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:38 +00:00
static inline void
instr_hdr_extract_m_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_extract_m_exec(p, t, ip);
pipeline: add variable size headers extract instruction Added a mechanism to extract variable size headers through a special flavor of the extract instruction. The length of the last struct field which has variable size is passed as argument to the instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: add header look-ahead instruction Added look-ahead instruction to read a header from the input packet without advancing the extraction pointer. This is typically used in correlation with the special extract instruction to extract variable size headers from the input packet: the first few header fields are read without advancing the extraction pointer, just enough to detect the actual length of the header (e.g. IPv4 IHL field); then the full header is extracted. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:39 +00:00
static inline void
instr_hdr_lookahead_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for extract instruction Create inline functions for the extract instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:24 +00:00
__instr_hdr_lookahead_exec(p, t, ip);
pipeline: add header look-ahead instruction Added look-ahead instruction to read a header from the input packet without advancing the extraction pointer. This is typically used in correlation with the special extract instruction to extract variable size headers from the input packet: the first few header fields are read without advancing the extraction pointer, just enough to detect the actual length of the header (e.g. IPv4 IHL field); then the full header is extracted. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
/*
* emit.
*/
static int
instr_hdr_emit_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_EMIT;
instr->io.hdr.header_id[0] = h->id;
instr->io.hdr.struct_id[0] = h->struct_id;
instr->io.hdr.n_bytes[0] = h->st->n_bits / 8;
return 0;
}
static inline void
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
instr_hdr_emit_exec(struct rte_swx_pipeline *p)
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
__instr_hdr_emit_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_hdr_emit_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
__instr_hdr_emit_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit2_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit2_tx_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit3_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
__instr_hdr_emit3_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit4_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit4_tx_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit5_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
__instr_hdr_emit5_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit6_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit6_tx_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit7_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_hdr_emit7_tx_exec(p, t, ip);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
static inline void
instr_hdr_emit8_tx_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: create inline functions for emit instruction Create inline functions for the emit instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:25 +00:00
__instr_hdr_emit8_tx_exec(p, t, ip);
/* Thread. */
thread_ip_reset(p, t);
instr_rx_exec(p);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
}
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
/*
* validate.
*/
static int
instr_hdr_validate_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_VALIDATE;
instr->valid.header_id = h->id;
return 0;
}
static inline void
instr_hdr_validate_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for validate instruction Create inline functions for the validate and invalidate instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:26 +00:00
__instr_hdr_validate_exec(p, t, ip);
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
/*
* invalidate.
*/
static int
instr_hdr_invalidate_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct header *h;
CHECK(n_tokens == 2, EINVAL);
h = header_parse(p, tokens[1]);
CHECK(h, EINVAL);
instr->type = INSTR_HDR_INVALIDATE;
instr->valid.header_id = h->id;
return 0;
}
static inline void
instr_hdr_invalidate_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for validate instruction Create inline functions for the validate and invalidate instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:26 +00:00
__instr_hdr_invalidate_exec(p, t, ip);
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
/*
* table.
*/
static struct table *
table_find(struct rte_swx_pipeline *p, const char *name);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
static struct selector *
selector_find(struct rte_swx_pipeline *p, const char *name);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static struct learner *
learner_find(struct rte_swx_pipeline *p, const char *name);
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
static int
instr_table_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct table *t;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
struct selector *s;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
struct learner *l;
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
t = table_find(p, tokens[1]);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
if (t) {
instr->type = INSTR_TABLE;
instr->table.table_id = t->id;
return 0;
}
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
s = selector_find(p, tokens[1]);
if (s) {
instr->type = INSTR_SELECTOR;
instr->table.table_id = s->id;
return 0;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l = learner_find(p, tokens[1]);
if (l) {
instr->type = INSTR_LEARNER;
instr->table.table_id = l->id;
return 0;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
CHECK(0, EINVAL);
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
}
static inline void
instr_table_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t table_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[table_id];
struct table_runtime *table = &t->tables[table_id];
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
struct table_statistics *stats = &p->table_stats[table_id];
uint64_t action_id, n_pkts_hit, n_pkts_action;
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
uint8_t *action_data;
int done, hit;
/* Table. */
done = table->func(ts->obj,
table->mailbox,
table->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] table %u (not finalized)\n",
p->thread_id,
table_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
TRACE("[Thread %2u] table %u (%s, action %u)\n",
p->thread_id,
table_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
/* Thread. */
thread_ip_action_call(p, t, action_id);
}
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
static inline void
instr_table_af_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t table_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[table_id];
struct table_runtime *table = &t->tables[table_id];
struct table_statistics *stats = &p->table_stats[table_id];
uint64_t action_id, n_pkts_hit, n_pkts_action;
uint8_t *action_data;
action_func_t action_func;
int done, hit;
/* Table. */
done = table->func(ts->obj,
table->mailbox,
table->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] table %u (not finalized)\n",
p->thread_id,
table_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
action_func = p->action_funcs[action_id];
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] table %u (%s, action %u)\n",
p->thread_id,
table_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_inc(p);
/* Action. */
action_func(p);
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
static inline void
instr_selector_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t selector_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables + selector_id];
struct selector_runtime *selector = &t->selectors[selector_id];
struct selector_statistics *stats = &p->selector_stats[selector_id];
uint64_t n_pkts = stats->n_pkts;
int done;
/* Table. */
done = rte_swx_table_selector_select(ts->obj,
selector->mailbox,
selector->group_id_buffer,
selector->selector_buffer,
selector->member_id_buffer);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] selector %u (not finalized)\n",
p->thread_id,
selector_id);
thread_yield(p);
return;
}
TRACE("[Thread %2u] selector %u\n",
p->thread_id,
selector_id);
stats->n_pkts = n_pkts + 1;
/* Thread. */
thread_ip_inc(p);
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static inline void
instr_learner_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t learner_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables +
p->n_selectors + learner_id];
struct learner_runtime *l = &t->learners[learner_id];
struct learner_statistics *stats = &p->learner_stats[learner_id];
uint64_t action_id, n_pkts_hit, n_pkts_action, time;
uint8_t *action_data;
int done, hit;
/* Table. */
time = rte_get_tsc_cycles();
done = rte_swx_table_learner_lookup(ts->obj,
l->mailbox,
time,
l->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] learner %u (not finalized)\n",
p->thread_id,
learner_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] learner %u (%s, action %u)\n",
p->thread_id,
learner_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
t->learner_id = learner_id;
t->time = time;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
thread_ip_action_call(p, t, action_id);
}
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
static inline void
instr_learner_af_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t learner_id = ip->table.table_id;
struct rte_swx_table_state *ts = &t->table_state[p->n_tables +
p->n_selectors + learner_id];
struct learner_runtime *l = &t->learners[learner_id];
struct learner_statistics *stats = &p->learner_stats[learner_id];
uint64_t action_id, n_pkts_hit, n_pkts_action, time;
uint8_t *action_data;
action_func_t action_func;
int done, hit;
/* Table. */
time = rte_get_tsc_cycles();
done = rte_swx_table_learner_lookup(ts->obj,
l->mailbox,
time,
l->key,
&action_id,
&action_data,
&hit);
if (!done) {
/* Thread. */
TRACE("[Thread %2u] learner %u (not finalized)\n",
p->thread_id,
learner_id);
thread_yield(p);
return;
}
action_id = hit ? action_id : ts->default_action_id;
action_data = hit ? action_data : ts->default_action_data;
action_func = p->action_funcs[action_id];
n_pkts_hit = stats->n_pkts_hit[hit];
n_pkts_action = stats->n_pkts_action[action_id];
TRACE("[Thread %2u] learner %u (%s, action %u)\n",
p->thread_id,
learner_id,
hit ? "hit" : "miss",
(uint32_t)action_id);
t->action_id = action_id;
t->structs[0] = action_data;
t->hit = hit;
t->learner_id = learner_id;
t->time = time;
stats->n_pkts_hit[hit] = n_pkts_hit + 1;
stats->n_pkts_action[action_id] = n_pkts_action + 1;
/* Thread. */
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
thread_ip_inc(p);
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
/* Action */
action_func(p);
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/*
* learn.
*/
static struct action *
action_find(struct rte_swx_pipeline *p, const char *name);
static int
action_has_nbo_args(struct action *a);
pipeline: improve handling of learner action arguments The arguments of actions that are learned are now specified as part of the learn instruction as opposed to being statically specified as part of the learner table configuration. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-14 19:00:05 +00:00
static int
learner_action_args_check(struct rte_swx_pipeline *p, struct action *a, const char *mf_name);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static int
instr_learn_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct action *a;
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
struct field *mf_first_arg = NULL, *mf_timeout_id = NULL;
const char *mf_first_arg_name, *mf_timeout_id_name;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
CHECK(action, EINVAL);
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
CHECK((n_tokens == 3) || (n_tokens == 4), EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
/* Action. */
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
a = action_find(p, tokens[1]);
CHECK(a, EINVAL);
CHECK(!action_has_nbo_args(a), EINVAL);
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
/* Action first argument. */
mf_first_arg_name = (n_tokens == 4) ? tokens[2] : NULL;
CHECK(!learner_action_args_check(p, a, mf_first_arg_name), EINVAL);
pipeline: improve handling of learner action arguments The arguments of actions that are learned are now specified as part of the learn instruction as opposed to being statically specified as part of the learner table configuration. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-14 19:00:05 +00:00
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
if (mf_first_arg_name) {
mf_first_arg = metadata_field_parse(p, mf_first_arg_name);
CHECK(mf_first_arg, EINVAL);
pipeline: improve handling of learner action arguments The arguments of actions that are learned are now specified as part of the learn instruction as opposed to being statically specified as part of the learner table configuration. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-14 19:00:05 +00:00
}
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
/* Timeout ID. */
mf_timeout_id_name = (n_tokens == 4) ? tokens[3] : tokens[2];
CHECK_NAME(mf_timeout_id_name, EINVAL);
mf_timeout_id = metadata_field_parse(p, mf_timeout_id_name);
CHECK(mf_timeout_id, EINVAL);
/* Instruction. */
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
instr->type = INSTR_LEARNER_LEARN;
instr->learn.action_id = a->id;
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
instr->learn.mf_first_arg_offset = mf_first_arg ? (mf_first_arg->offset / 8) : 0;
instr->learn.mf_timeout_id_offset = mf_timeout_id->offset / 8;
instr->learn.mf_timeout_id_n_bits = mf_timeout_id->n_bits;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return 0;
}
static inline void
instr_learn_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for learn instruction Create inline functions for the learn and forget instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:27 +00:00
__instr_learn_exec(p, t, ip);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
/*
* rearm.
*/
static int
instr_rearm_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct field *mf_timeout_id;
const char *mf_timeout_id_name;
CHECK(action, EINVAL);
CHECK((n_tokens == 1) || (n_tokens == 2), EINVAL);
/* INSTR_LEARNER_REARM. */
if (n_tokens == 1) {
instr->type = INSTR_LEARNER_REARM;
return 0;
}
/* INSTR_LEARNER_REARM_NEW. */
mf_timeout_id_name = tokens[1];
CHECK_NAME(mf_timeout_id_name, EINVAL);
mf_timeout_id = metadata_field_parse(p, mf_timeout_id_name);
CHECK(mf_timeout_id, EINVAL);
instr->type = INSTR_LEARNER_REARM_NEW;
instr->learn.mf_timeout_id_offset = mf_timeout_id->offset / 8;
instr->learn.mf_timeout_id_n_bits = mf_timeout_id->n_bits;
return 0;
}
static inline void
instr_rearm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_rearm_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_rearm_new_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
__instr_rearm_new_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/*
* forget.
*/
static int
instr_forget_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(action, EINVAL);
CHECK(n_tokens == 1, EINVAL);
instr->type = INSTR_LEARNER_FORGET;
return 0;
}
static inline void
instr_forget_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
pipeline: create inline functions for learn instruction Create inline functions for the learn and forget instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:27 +00:00
struct instruction *ip = t->ip;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
pipeline: create inline functions for learn instruction Create inline functions for the learn and forget instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:27 +00:00
__instr_forget_exec(p, t, ip);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
/*
* extern.
*/
static int
instr_extern_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *token = tokens[1];
CHECK(n_tokens == 2, EINVAL);
if (token[0] == 'e') {
struct extern_obj *obj;
struct extern_type_member_func *func;
func = extern_obj_member_func_parse(p, token, &obj);
CHECK(func, EINVAL);
instr->type = INSTR_EXTERN_OBJ;
instr->ext_obj.ext_obj_id = obj->id;
instr->ext_obj.func_id = func->id;
return 0;
}
if (token[0] == 'f') {
struct extern_func *func;
func = extern_func_parse(p, token);
CHECK(func, EINVAL);
instr->type = INSTR_EXTERN_FUNC;
instr->ext_func.ext_func_id = func->id;
return 0;
}
CHECK(0, EINVAL);
}
static inline void
instr_extern_obj_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for extern instruction Create inline functions for the extern instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:28 +00:00
uint32_t done;
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
/* Extern object member function execute. */
pipeline: create inline functions for extern instruction Create inline functions for the extern instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:28 +00:00
done = __instr_extern_obj_exec(p, t, ip);
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
/* Thread. */
thread_ip_inc_cond(t, done);
thread_yield_cond(p, done ^ 1);
}
static inline void
instr_extern_func_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for extern instruction Create inline functions for the extern instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:28 +00:00
uint32_t done;
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
/* Extern function execute. */
pipeline: create inline functions for extern instruction Create inline functions for the extern instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:28 +00:00
done = __instr_extern_func_exec(p, t, ip);
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
/* Thread. */
thread_ip_inc_cond(t, done);
thread_yield_cond(p, done ^ 1);
}
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
/*
* hash.
*/
static int
instr_hash_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
struct hash_func *func;
struct field *dst, *src_first, *src_last;
uint32_t src_struct_id_first = 0, src_struct_id_last = 0;
CHECK(n_tokens == 5, EINVAL);
func = hash_func_find(p, tokens[1]);
CHECK(func, EINVAL);
dst = metadata_field_parse(p, tokens[2]);
CHECK(dst, EINVAL);
src_first = struct_field_parse(p, action, tokens[3], &src_struct_id_first);
CHECK(src_first, EINVAL);
src_last = struct_field_parse(p, action, tokens[4], &src_struct_id_last);
CHECK(src_last, EINVAL);
CHECK(src_struct_id_first == src_struct_id_last, EINVAL);
instr->type = INSTR_HASH_FUNC;
instr->hash_func.hash_func_id = (uint8_t)func->id;
instr->hash_func.dst.offset = (uint8_t)dst->offset / 8;
instr->hash_func.dst.n_bits = (uint8_t)dst->n_bits;
instr->hash_func.src.struct_id = (uint8_t)src_struct_id_first;
instr->hash_func.src.offset = (uint16_t)src_first->offset / 8;
instr->hash_func.src.n_bytes = (uint16_t)((src_last->offset + src_last->n_bits -
src_first->offset) / 8);
return 0;
}
static inline void
instr_hash_func_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Extern function execute. */
__instr_hash_func_exec(p, t, ip);
/* Thread. */
thread_ip_inc(p);
}
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
/*
* mov.
*/
static int
instr_mov_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* MOV, MOV_MH, MOV_HM or MOV_HH. */
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
instr->type = INSTR_MOV;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_MOV_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_MOV_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_MOV_HH;
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
instr->mov.dst.struct_id = (uint8_t)dst_struct_id;
instr->mov.dst.n_bits = fdst->n_bits;
instr->mov.dst.offset = fdst->offset / 8;
instr->mov.src.struct_id = (uint8_t)src_struct_id;
instr->mov.src.n_bits = fsrc->n_bits;
instr->mov.src.offset = fsrc->offset / 8;
return 0;
}
/* MOV_I. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = hton64(src_val) >> (64 - fdst->n_bits);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
instr->type = INSTR_MOV_I;
instr->mov.dst.struct_id = (uint8_t)dst_struct_id;
instr->mov.dst.n_bits = fdst->n_bits;
instr->mov.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->mov.src_val = src_val;
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
return 0;
}
static inline void
instr_mov_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for move instruction Create inline functions for the move instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:29 +00:00
__instr_mov_exec(p, t, ip);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_mov_mh_exec(struct rte_swx_pipeline *p)
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for move instruction Create inline functions for the move instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:29 +00:00
__instr_mov_mh_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for move instruction Create inline functions for the move instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:29 +00:00
__instr_mov_hm_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for move instruction Create inline functions for the move instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:29 +00:00
__instr_mov_hh_exec(p, t, ip);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_mov_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for move instruction Create inline functions for the move instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:29 +00:00
__instr_mov_i_exec(p, t, ip);
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/*
* dma.
*/
static inline void
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
instr_dma_ht_exec(struct rte_swx_pipeline *p)
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht2_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht2_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht3_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht3_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht4_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht4_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht5_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht5_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht6_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht6_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht7_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht7_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_dma_ht8_exec(struct rte_swx_pipeline *p)
{
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: create inline functions for DMA instruction Create inline functions for the DMA instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:30 +00:00
__instr_dma_ht8_exec(p, t, ip);
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/*
* alu.
*/
static int
instr_alu_add_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* ADD, ADD_HM, ADD_MH, ADD_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
instr->type = INSTR_ALU_ADD;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] == 'h' && src[0] != 'h')
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
instr->type = INSTR_ALU_ADD_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] != 'h' && src[0] == 'h')
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
instr->type = INSTR_ALU_ADD_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_ADD_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* ADD_MI, ADD_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_ADD_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_ADD_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
return 0;
}
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
static int
instr_alu_sub_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* SUB, SUB_HM, SUB_MH, SUB_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
instr->type = INSTR_ALU_SUB;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] == 'h' && src[0] != 'h')
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
instr->type = INSTR_ALU_SUB_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] != 'h' && src[0] == 'h')
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
instr->type = INSTR_ALU_SUB_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SUB_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SUB_MI, SUB_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SUB_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SUB_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
return 0;
}
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
static int
instr_alu_ckadd_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct header *hdst, *hsrc;
struct field *fdst, *fsrc;
CHECK(n_tokens == 3, EINVAL);
fdst = header_field_parse(p, dst, &hdst);
pipeline: support checksum for variable size headers Added checksum support for variable size headers such as IPv4 headers with options. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com>
2022-02-11 15:11:14 +00:00
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size && (fdst->n_bits == 16), EINVAL);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
/* CKADD_FIELD. */
fsrc = header_field_parse(p, src, &hsrc);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
instr->type = INSTR_ALU_CKADD_FIELD;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* CKADD_STRUCT, CKADD_STRUCT20. */
hsrc = header_parse(p, src);
CHECK(hsrc, EINVAL);
instr->type = INSTR_ALU_CKADD_STRUCT;
pipeline: support checksum for variable size headers Added checksum support for variable size headers such as IPv4 headers with options. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com>
2022-02-11 15:11:14 +00:00
if (!hsrc->st->var_size && ((hsrc->st->n_bits / 8) == 20))
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
instr->type = INSTR_ALU_CKADD_STRUCT20;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
pipeline: support checksum for variable size headers Added checksum support for variable size headers such as IPv4 headers with options. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com>
2022-02-11 15:11:14 +00:00
instr->alu.src.n_bits = (uint8_t)hsrc->id; /* The src header ID is stored here. */
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
instr->alu.src.offset = 0; /* Unused. */
return 0;
}
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
static int
instr_alu_cksub_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct header *hdst, *hsrc;
struct field *fdst, *fsrc;
CHECK(n_tokens == 3, EINVAL);
fdst = header_field_parse(p, dst, &hdst);
pipeline: support checksum for variable size headers Added checksum support for variable size headers such as IPv4 headers with options. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com>
2022-02-11 15:11:14 +00:00
CHECK(fdst, EINVAL);
CHECK(!fdst->var_size && (fdst->n_bits == 16), EINVAL);
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
fsrc = header_field_parse(p, src, &hsrc);
CHECK(fsrc, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
instr->type = INSTR_ALU_CKSUB_FIELD;
instr->alu.dst.struct_id = (uint8_t)hdst->struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)hsrc->struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
static int
instr_alu_shl_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* SHL, SHL_HM, SHL_MH, SHL_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
instr->type = INSTR_ALU_SHL;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] == 'h' && src[0] != 'h')
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
instr->type = INSTR_ALU_SHL_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] != 'h' && src[0] == 'h')
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
instr->type = INSTR_ALU_SHL_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHL_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SHL_MI, SHL_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SHL_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SHL_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
return 0;
}
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
static int
instr_alu_shr_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* SHR, SHR_HM, SHR_MH, SHR_HH. */
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
instr->type = INSTR_ALU_SHR;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] == 'h' && src[0] != 'h')
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
instr->type = INSTR_ALU_SHR_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (dst[0] != 'h' && src[0] == 'h')
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
instr->type = INSTR_ALU_SHR_MH;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_SHR_HH;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* SHR_MI, SHR_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
CHECK(!src[0], EINVAL);
instr->type = INSTR_ALU_SHR_MI;
if (dst[0] == 'h')
instr->type = INSTR_ALU_SHR_HI;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
return 0;
}
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
static int
instr_alu_and_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* AND, AND_MH, AND_HM, AND_HH. */
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
instr->type = INSTR_ALU_AND;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_AND_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_AND_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_AND_HH;
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* AND_I. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = hton64(src_val) >> (64 - fdst->n_bits);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
instr->type = INSTR_ALU_AND_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
return 0;
}
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
static int
instr_alu_or_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* OR, OR_MH, OR_HM, OR_HH. */
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
instr->type = INSTR_ALU_OR;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_OR_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_OR_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_OR_HH;
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* OR_I. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = hton64(src_val) >> (64 - fdst->n_bits);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
instr->type = INSTR_ALU_OR_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
return 0;
}
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
static int
instr_alu_xor_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
char *dst = tokens[1], *src = tokens[2];
struct field *fdst, *fsrc;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t src_val;
pipeline: fix build with GCC 4.8.5 Compilation on CentOS 7 with gcc version 4.8.5 fails with the following errors: error: 'src_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] error: 'dst_struct_id' may be used uninitialized in this function [-Werror=maybe-uninitialized] This patch fixes the build errors by initializing both variables. Bugzilla ID: 683 Fixes: 783768136f29 ("pipeline: auto-detect endianness of action arguments") Signed-off-by: Ali Alnubani <alialnu@nvidia.com>
2021-04-21 10:06:38 +00:00
uint32_t dst_struct_id = 0, src_struct_id = 0;
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
CHECK(n_tokens == 3, EINVAL);
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* XOR, XOR_MH, XOR_HM, XOR_HH. */
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
instr->type = INSTR_ALU_XOR;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (dst[0] != 'h' && src[0] == 'h')
instr->type = INSTR_ALU_XOR_MH;
if (dst[0] == 'h' && src[0] != 'h')
instr->type = INSTR_ALU_XOR_HM;
if (dst[0] == 'h' && src[0] == 'h')
instr->type = INSTR_ALU_XOR_HH;
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
instr->alu.src.struct_id = (uint8_t)src_struct_id;
instr->alu.src.n_bits = fsrc->n_bits;
instr->alu.src.offset = fsrc->offset / 8;
return 0;
}
/* XOR_I. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = strtoull(src, &src, 0);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
CHECK(!src[0], EINVAL);
if (dst[0] == 'h')
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
src_val = hton64(src_val) >> (64 - fdst->n_bits);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
instr->type = INSTR_ALU_XOR_I;
instr->alu.dst.struct_id = (uint8_t)dst_struct_id;
instr->alu.dst.n_bits = fdst->n_bits;
instr->alu.dst.offset = fdst->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->alu.src_val = src_val;
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
return 0;
}
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
static inline void
instr_alu_add_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
/* Structs */
__instr_alu_add_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_add_mh_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_add_hm_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_add_hh_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_add_mi_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_add_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_add_hi_exec(p, t, ip);
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
static inline void
instr_alu_sub_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_mh_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_hm_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_hh_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_mi_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_sub_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_sub_hi_exec(p, t, ip);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
static inline void
instr_alu_shl_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_mh_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_hm_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_hh_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_mi_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shl_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shl_hi_exec(p, t, ip);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
static inline void
instr_alu_shr_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_mh_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_hm_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_hh_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_mi_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_shr_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_shr_hi_exec(p, t, ip);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
static inline void
instr_alu_and_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_and_exec(p, t, ip);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_alu_and_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_and_mh_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_and_hm_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_hh_exec(struct rte_swx_pipeline *p)
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_and_hh_exec(p, t, ip);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_and_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_and_i_exec(p, t, ip);
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
static inline void
instr_alu_or_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_or_exec(p, t, ip);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_alu_or_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_or_mh_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_or_hm_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_hh_exec(struct rte_swx_pipeline *p)
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_or_hh_exec(p, t, ip);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_or_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_or_i_exec(p, t, ip);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
static inline void
instr_alu_xor_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_xor_exec(p, t, ip);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_alu_xor_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_xor_mh_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_hm_exec(struct rte_swx_pipeline *p)
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_xor_hm_exec(p, t, ip);
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_xor_hh_exec(p, t, ip);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_xor_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_xor_i_exec(p, t, ip);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
static inline void
instr_alu_ckadd_field_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_ckadd_field_exec(p, t, ip);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
static inline void
instr_alu_cksub_field_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_cksub_field_exec(p, t, ip);
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
static inline void
instr_alu_ckadd_struct20_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_ckadd_struct20_exec(p, t, ip);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_alu_ckadd_struct_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for ALU instructions Create inline functions for the ALU instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:31 +00:00
__instr_alu_ckadd_struct_exec(p, t, ip);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
/*
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
* Register array.
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
*/
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
static struct regarray *
regarray_find(struct rte_swx_pipeline *p, const char *name);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static int
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr_regprefetch_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
char *regarray = tokens[1], *idx = tokens[2];
struct regarray *r;
struct field *fidx;
uint32_t idx_struct_id, idx_val;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(n_tokens == 3, EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
/* REGPREFETCH_RH, REGPREFETCH_RM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGPREFETCH_RM;
if (idx[0] == 'h')
instr->type = INSTR_REGPREFETCH_RH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = 0; /* Unused. */
return 0;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGPREFETCH_RI. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGPREFETCH_RI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = 0; /* Unused. */
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static int
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr_regrd_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
char *dst = tokens[1], *regarray = tokens[2], *idx = tokens[3];
struct regarray *r;
struct field *fdst, *fidx;
uint32_t dst_struct_id, idx_struct_id, idx_val;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
CHECK(n_tokens == 4, EINVAL);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
fdst = struct_field_parse(p, NULL, dst, &dst_struct_id);
CHECK(fdst, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fdst->var_size, EINVAL);
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGRD_HRH, REGRD_HRM, REGRD_MRH, REGRD_MRM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGRD_MRM;
if (dst[0] == 'h' && idx[0] != 'h')
instr->type = INSTR_REGRD_HRM;
if (dst[0] != 'h' && idx[0] == 'h')
instr->type = INSTR_REGRD_MRH;
if (dst[0] == 'h' && idx[0] == 'h')
instr->type = INSTR_REGRD_HRH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)dst_struct_id;
instr->regarray.dstsrc.n_bits = fdst->n_bits;
instr->regarray.dstsrc.offset = fdst->offset / 8;
return 0;
}
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGRD_MRI, REGRD_HRI. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGRD_MRI;
if (dst[0] == 'h')
instr->type = INSTR_REGRD_HRI;
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)dst_struct_id;
instr->regarray.dstsrc.n_bits = fdst->n_bits;
instr->regarray.dstsrc.offset = fdst->offset / 8;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static int
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr_regwr_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
char *regarray = tokens[1], *idx = tokens[2], *src = tokens[3];
struct regarray *r;
struct field *fidx, *fsrc;
uint64_t src_val;
uint32_t idx_struct_id, idx_val, src_struct_id;
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
CHECK(n_tokens == 4, EINVAL);
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGWR_RHH, REGWR_RHM, REGWR_RMH, REGWR_RMM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fidx && fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
CHECK(!fsrc->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGWR_RMM;
if (idx[0] == 'h' && src[0] != 'h')
instr->type = INSTR_REGWR_RHM;
if (idx[0] != 'h' && src[0] == 'h')
instr->type = INSTR_REGWR_RMH;
if (idx[0] == 'h' && src[0] == 'h')
instr->type = INSTR_REGWR_RHH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGWR_RHI, REGWR_RMI. */
if (fidx && !fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGWR_RMI;
if (idx[0] == 'h')
instr->type = INSTR_REGWR_RHI;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = src_val;
return 0;
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGWR_RIH, REGWR_RIM. */
if (!fidx && fsrc) {
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGWR_RIM;
if (src[0] == 'h')
instr->type = INSTR_REGWR_RIH;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGWR_RII. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGWR_RII;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = src_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
static int
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr_regadd_translate(struct rte_swx_pipeline *p,
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
struct instruction_data *data __rte_unused)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
char *regarray = tokens[1], *idx = tokens[2], *src = tokens[3];
struct regarray *r;
struct field *fidx, *fsrc;
uint64_t src_val;
uint32_t idx_struct_id, idx_val, src_struct_id;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(n_tokens == 4, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
r = regarray_find(p, regarray);
CHECK(r, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGADD_RHH, REGADD_RHM, REGADD_RMH, REGADD_RMM. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
fsrc = struct_field_parse(p, action, src, &src_struct_id);
if (fidx && fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
CHECK(!fsrc->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGADD_RMM;
if (idx[0] == 'h' && src[0] != 'h')
instr->type = INSTR_REGADD_RHM;
if (idx[0] != 'h' && src[0] == 'h')
instr->type = INSTR_REGADD_RMH;
if (idx[0] == 'h' && src[0] == 'h')
instr->type = INSTR_REGADD_RHH;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGADD_RHI, REGADD_RMI. */
if (fidx && !fsrc) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGADD_RMI;
if (idx[0] == 'h')
instr->type = INSTR_REGADD_RHI;
instr->regarray.regarray_id = r->id;
instr->regarray.idx.struct_id = (uint8_t)idx_struct_id;
instr->regarray.idx.n_bits = fidx->n_bits;
instr->regarray.idx.offset = fidx->offset / 8;
instr->regarray.dstsrc_val = src_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* REGADD_RIH, REGADD_RIM. */
if (!fidx && fsrc) {
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fsrc->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->type = INSTR_REGADD_RIM;
if (src[0] == 'h')
instr->type = INSTR_REGADD_RIH;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
instr->regarray.regarray_id = r->id;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc.struct_id = (uint8_t)src_struct_id;
instr->regarray.dstsrc.n_bits = fsrc->n_bits;
instr->regarray.dstsrc.offset = fsrc->offset / 8;
return 0;
}
/* REGADD_RII. */
src_val = strtoull(src, &src, 0);
CHECK(!src[0], EINVAL);
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_REGADD_RII;
instr->regarray.idx_val = idx_val;
instr->regarray.dstsrc_val = src_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
static inline void
instr_regprefetch_rh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regprefetch_rh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regprefetch_rm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regprefetch_rm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regprefetch_ri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regprefetch_ri_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hrh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_hrh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hrm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_hrm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mrh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_mrh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mrm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_mrm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_hri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_hri_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regrd_mri_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regrd_mri_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rhh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rhm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rmh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rmm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rhi_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rmi_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rih_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rih_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rim_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rim_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regwr_rii_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regwr_rii_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rhh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rhm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rmh_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rmm_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rhi_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rmi_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rih_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rih_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rim_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rim_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_regadd_rii_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for register instructions Create inline functions for the register instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:32 +00:00
__instr_regadd_rii_exec(p, t, ip);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/* Thread. */
thread_ip_inc(p);
}
/*
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
* metarray.
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
*/
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
static struct metarray *
metarray_find(struct rte_swx_pipeline *p, const char *name);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
static int
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr_metprefetch_translate(struct rte_swx_pipeline *p,
struct action *action,
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
char **tokens,
int n_tokens,
struct instruction *instr,
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
struct instruction_data *data __rte_unused)
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
{
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
char *metarray = tokens[1], *idx = tokens[2];
struct metarray *m;
struct field *fidx;
uint32_t idx_struct_id, idx_val;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
CHECK(n_tokens == 3, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
m = metarray_find(p, metarray);
CHECK(m, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* METPREFETCH_H, METPREFETCH_M. */
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
if (fidx) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_METPREFETCH_M;
if (idx[0] == 'h')
instr->type = INSTR_METPREFETCH_H;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.metarray_id = m->id;
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
return 0;
}
/* METPREFETCH_I. */
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
instr->type = INSTR_METPREFETCH_I;
instr->meter.metarray_id = m->id;
instr->meter.idx_val = idx_val;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
return 0;
}
static int
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr_meter_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
{
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
char *metarray = tokens[1], *idx = tokens[2], *length = tokens[3];
char *color_in = tokens[4], *color_out = tokens[5];
struct metarray *m;
struct field *fidx, *flength, *fcin, *fcout;
uint32_t idx_struct_id, length_struct_id;
uint32_t color_in_struct_id, color_out_struct_id;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
CHECK(n_tokens == 6, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
m = metarray_find(p, metarray);
CHECK(m, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
fidx = struct_field_parse(p, action, idx, &idx_struct_id);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
flength = struct_field_parse(p, action, length, &length_struct_id);
CHECK(flength, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!flength->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
fcin = struct_field_parse(p, action, color_in, &color_in_struct_id);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
fcout = struct_field_parse(p, NULL, color_out, &color_out_struct_id);
CHECK(fcout, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fcout->var_size, EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* index = HMEFT, length = HMEFT, color_in = MEFT, color_out = MEF. */
if (fidx && fcin) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fidx->var_size, EINVAL);
CHECK(!fcin->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_METER_MMM;
if (idx[0] == 'h' && length[0] == 'h')
instr->type = INSTR_METER_HHM;
if (idx[0] == 'h' && length[0] != 'h')
instr->type = INSTR_METER_HMM;
if (idx[0] != 'h' && length[0] == 'h')
instr->type = INSTR_METER_MHM;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.metarray_id = m->id;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_in.struct_id = (uint8_t)color_in_struct_id;
instr->meter.color_in.n_bits = fcin->n_bits;
instr->meter.color_in.offset = fcin->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* index = HMEFT, length = HMEFT, color_in = I, color_out = MEF. */
if (fidx && !fcin) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
uint32_t color_in_val;
CHECK(!fidx->var_size, EINVAL);
color_in_val = strtoul(color_in, &color_in, 0);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
CHECK(!color_in[0], EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_METER_MMI;
if (idx[0] == 'h' && length[0] == 'h')
instr->type = INSTR_METER_HHI;
if (idx[0] == 'h' && length[0] != 'h')
instr->type = INSTR_METER_HMI;
if (idx[0] != 'h' && length[0] == 'h')
instr->type = INSTR_METER_MHI;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.metarray_id = m->id;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.idx.struct_id = (uint8_t)idx_struct_id;
instr->meter.idx.n_bits = fidx->n_bits;
instr->meter.idx.offset = fidx->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_in_val = color_in_val;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
}
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* index = I, length = HMEFT, color_in = MEFT, color_out = MEF. */
if (!fidx && fcin) {
uint32_t idx_val;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fcin->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_METER_IMM;
if (length[0] == 'h')
instr->type = INSTR_METER_IHM;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.metarray_id = m->id;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.idx_val = idx_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_in.struct_id = (uint8_t)color_in_struct_id;
instr->meter.color_in.n_bits = fcin->n_bits;
instr->meter.color_in.offset = fcin->offset / 8;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
}
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* index = I, length = HMEFT, color_in = I, color_out = MEF. */
if (!fidx && !fcin) {
uint32_t idx_val, color_in_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
idx_val = strtoul(idx, &idx, 0);
CHECK(!idx[0], EINVAL);
color_in_val = strtoul(color_in, &color_in, 0);
CHECK(!color_in[0], EINVAL);
instr->type = INSTR_METER_IMI;
if (length[0] == 'h')
instr->type = INSTR_METER_IHI;
instr->meter.metarray_id = m->id;
instr->meter.idx_val = idx_val;
instr->meter.length.struct_id = (uint8_t)length_struct_id;
instr->meter.length.n_bits = flength->n_bits;
instr->meter.length.offset = flength->offset / 8;
instr->meter.color_in_val = color_in_val;
instr->meter.color_out.struct_id = (uint8_t)color_out_struct_id;
instr->meter.color_out.n_bits = fcout->n_bits;
instr->meter.color_out.offset = fcout->offset / 8;
}
pipeline: remove unreachable branch A previous change blamed it on compiler/ASan, while this is a real (yet minor) issue. This return -EINVAL is never reached since we test all combinations of fidx and fcin booleans. All branches end up with a return 0, factorize them. Fixes: 84f5ac9418ea ("pipeline: fix build with ASan") Fixes: f38913b7fb8e ("pipeline: add meter array to SWX") Signed-off-by: David Marchand <david.marchand@redhat.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-11-03 06:56:58 +00:00
return 0;
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
}
static inline void
instr_metprefetch_h_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_metprefetch_h_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_metprefetch_m_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_metprefetch_m_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_metprefetch_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_metprefetch_i_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_hhm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_hhi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_hmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_hmm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
static inline void
instr_meter_hmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_hmi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mhm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_mhm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mhi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_mhi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mmm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_mmm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_mmi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_mmi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_ihm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_ihm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_ihi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_ihi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
static inline void
instr_meter_imm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_imm_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
static inline void
instr_meter_imi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
/* Structs. */
pipeline: create inline functions for meter instructions Create inline functions for the meter instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:33 +00:00
__instr_meter_imi_exec(p, t, ip);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/* Thread. */
thread_ip_inc(p);
}
/*
* jmp.
*/
static int
instr_jmp_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_valid_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct header *h;
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
h = header_parse(p, tokens[2]);
CHECK(h, EINVAL);
instr->type = INSTR_JMP_VALID;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.header_id = h->id;
return 0;
}
static int
instr_jmp_invalid_translate(struct rte_swx_pipeline *p,
struct action *action __rte_unused,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct header *h;
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
h = header_parse(p, tokens[2]);
CHECK(h, EINVAL);
instr->type = INSTR_JMP_INVALID;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.header_id = h->id;
return 0;
}
static int
instr_jmp_hit_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP_HIT;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_miss_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
CHECK(!action, EINVAL);
CHECK(n_tokens == 2, EINVAL);
strcpy(data->jmp_label, tokens[1]);
instr->type = INSTR_JMP_MISS;
instr->jmp.ip = NULL; /* Resolved later. */
return 0;
}
static int
instr_jmp_action_hit_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct action *a;
CHECK(!action, EINVAL);
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
a = action_find(p, tokens[2]);
CHECK(a, EINVAL);
instr->type = INSTR_JMP_ACTION_HIT;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.action_id = a->id;
return 0;
}
static int
instr_jmp_action_miss_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
struct action *a;
CHECK(!action, EINVAL);
CHECK(n_tokens == 3, EINVAL);
strcpy(data->jmp_label, tokens[1]);
a = action_find(p, tokens[2]);
CHECK(a, EINVAL);
instr->type = INSTR_JMP_ACTION_MISS;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.action_id = a->id;
return 0;
}
static int
instr_jmp_eq_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fa->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* JMP_EQ, JMP_EQ_MH, JMP_EQ_HM, JMP_EQ_HH. */
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fb->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_JMP_EQ;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_EQ_MH;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_EQ_HM;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_EQ_HH;
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_EQ_I. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
if (a[0] == 'h')
b_val = hton64(b_val) >> (64 - fa->n_bits);
instr->type = INSTR_JMP_EQ_I;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b_val = b_val;
return 0;
}
static int
instr_jmp_neq_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fa->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
/* JMP_NEQ, JMP_NEQ_MH, JMP_NEQ_HM, JMP_NEQ_HH. */
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fb->var_size, EINVAL);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->type = INSTR_JMP_NEQ;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
if (a[0] != 'h' && b[0] == 'h')
instr->type = INSTR_JMP_NEQ_MH;
if (a[0] == 'h' && b[0] != 'h')
instr->type = INSTR_JMP_NEQ_HM;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_NEQ_HH;
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_NEQ_I. */
b_val = strtoull(b, &b, 0);
CHECK(!b[0], EINVAL);
if (a[0] == 'h')
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
b_val = hton64(b_val) >> (64 - fa->n_bits);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_NEQ_I;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->jmp.b_val = b_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
static int
instr_jmp_lt_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fa->var_size, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
/* JMP_LT, JMP_LT_MH, JMP_LT_HM, JMP_LT_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fb->var_size, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_LT;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (a[0] == 'h' && b[0] != 'h')
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_LT_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (a[0] != 'h' && b[0] == 'h')
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_LT_MH;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_LT_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_LT_MI, JMP_LT_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
b_val = strtoull(b, &b, 0);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(!b[0], EINVAL);
instr->type = INSTR_JMP_LT_MI;
if (a[0] == 'h')
instr->type = INSTR_JMP_LT_HI;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->jmp.b_val = b_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
static int
instr_jmp_gt_translate(struct rte_swx_pipeline *p,
struct action *action,
char **tokens,
int n_tokens,
struct instruction *instr,
struct instruction_data *data)
{
char *a = tokens[2], *b = tokens[3];
struct field *fa, *fb;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
uint64_t b_val;
uint32_t a_struct_id, b_struct_id;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(n_tokens == 4, EINVAL);
strcpy(data->jmp_label, tokens[1]);
fa = struct_field_parse(p, action, a, &a_struct_id);
CHECK(fa, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fa->var_size, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
/* JMP_GT, JMP_GT_MH, JMP_GT_HM, JMP_GT_HH. */
fb = struct_field_parse(p, action, b, &b_struct_id);
if (fb) {
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!fb->var_size, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_GT;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (a[0] == 'h' && b[0] != 'h')
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_GT_HM;
pipeline: fix instruction translation The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. For some pipeline instructions (add/sub, srl/shr, jmplt/jmpgt), only the H, M and I cases were handled, while the E, F and T cases were disregarded. This is what we fix here. Fixes: baf7999303d0 ("pipeline: introduce SWX add instruction") Fixes: c88c62943818 ("pipeline: introduce SWX subtract instruction") Fixes: b09ba6d0a3c2 ("pipeline: introduce SWX SHL instruction") Fixes: e0f51638b715 ("pipeline: introduce SWX SHR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-24 11:36:03 +00:00
if (a[0] != 'h' && b[0] == 'h')
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
instr->type = INSTR_JMP_GT_MH;
if (a[0] == 'h' && b[0] == 'h')
instr->type = INSTR_JMP_GT_HH;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
instr->jmp.b.struct_id = (uint8_t)b_struct_id;
instr->jmp.b.n_bits = fb->n_bits;
instr->jmp.b.offset = fb->offset / 8;
return 0;
}
/* JMP_GT_MI, JMP_GT_HI. */
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
b_val = strtoull(b, &b, 0);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
CHECK(!b[0], EINVAL);
instr->type = INSTR_JMP_GT_MI;
if (a[0] == 'h')
instr->type = INSTR_JMP_GT_HI;
instr->jmp.ip = NULL; /* Resolved later. */
instr->jmp.a.struct_id = (uint8_t)a_struct_id;
instr->jmp.a.n_bits = fa->n_bits;
instr->jmp.a.offset = fa->offset / 8;
pipeline: increase SWX immediate operand size This patch increases the immediate operand size from 32 to 64 bits. Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-29 18:08:10 +00:00
instr->jmp.b_val = b_val;
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
return 0;
}
static inline void
instr_jmp_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmp\n", p->thread_id);
thread_ip_set(t, ip->jmp.ip);
}
static inline void
instr_jmp_valid_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t header_id = ip->jmp.header_id;
TRACE("[Thread %2u] jmpv\n", p->thread_id);
t->ip = HEADER_VALID(t, header_id) ? ip->jmp.ip : (t->ip + 1);
}
static inline void
instr_jmp_invalid_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
uint32_t header_id = ip->jmp.header_id;
TRACE("[Thread %2u] jmpnv\n", p->thread_id);
t->ip = HEADER_VALID(t, header_id) ? (t->ip + 1) : ip->jmp.ip;
}
static inline void
instr_jmp_hit_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
struct instruction *ip_next[] = {t->ip + 1, ip->jmp.ip};
TRACE("[Thread %2u] jmph\n", p->thread_id);
t->ip = ip_next[t->hit];
}
static inline void
instr_jmp_miss_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
struct instruction *ip_next[] = {ip->jmp.ip, t->ip + 1};
TRACE("[Thread %2u] jmpnh\n", p->thread_id);
t->ip = ip_next[t->hit];
}
static inline void
instr_jmp_action_hit_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpa\n", p->thread_id);
t->ip = (ip->jmp.action_id == t->action_id) ? ip->jmp.ip : (t->ip + 1);
}
static inline void
instr_jmp_action_miss_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpna\n", p->thread_id);
t->ip = (ip->jmp.action_id == t->action_id) ? (t->ip + 1) : ip->jmp.ip;
}
static inline void
instr_jmp_eq_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq\n", p->thread_id);
JMP_CMP(t, ip, ==);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_jmp_eq_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, ==);
}
static inline void
instr_jmp_eq_hm_exec(struct rte_swx_pipeline *p)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
TRACE("[Thread %2u] jmpeq (hm)\n", p->thread_id);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
JMP_CMP_HM(t, ip, ==);
}
static inline void
instr_jmp_eq_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (hh)\n", p->thread_id);
JMP_CMP_HH_FAST(t, ip, ==);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
}
static inline void
instr_jmp_eq_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpeq (i)\n", p->thread_id);
JMP_CMP_I(t, ip, ==);
}
static inline void
instr_jmp_neq_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq\n", p->thread_id);
JMP_CMP(t, ip, !=);
}
static inline void
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
instr_jmp_neq_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, !=);
}
static inline void
instr_jmp_neq_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, !=);
}
static inline void
instr_jmp_neq_hh_exec(struct rte_swx_pipeline *p)
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
TRACE("[Thread %2u] jmpneq (hh)\n", p->thread_id);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
JMP_CMP_HH_FAST(t, ip, !=);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
}
static inline void
instr_jmp_neq_i_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpneq (i)\n", p->thread_id);
JMP_CMP_I(t, ip, !=);
}
static inline void
instr_jmp_lt_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt\n", p->thread_id);
JMP_CMP(t, ip, <);
}
static inline void
instr_jmp_lt_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, <);
}
static inline void
instr_jmp_lt_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, <);
}
static inline void
instr_jmp_lt_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hh)\n", p->thread_id);
JMP_CMP_HH(t, ip, <);
}
static inline void
instr_jmp_lt_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (mi)\n", p->thread_id);
JMP_CMP_MI(t, ip, <);
}
static inline void
instr_jmp_lt_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmplt (hi)\n", p->thread_id);
JMP_CMP_HI(t, ip, <);
}
static inline void
instr_jmp_gt_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt\n", p->thread_id);
JMP_CMP(t, ip, >);
}
static inline void
instr_jmp_gt_mh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (mh)\n", p->thread_id);
JMP_CMP_MH(t, ip, >);
}
static inline void
instr_jmp_gt_hm_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hm)\n", p->thread_id);
JMP_CMP_HM(t, ip, >);
}
static inline void
instr_jmp_gt_hh_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hh)\n", p->thread_id);
JMP_CMP_HH(t, ip, >);
}
static inline void
instr_jmp_gt_mi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (mi)\n", p->thread_id);
JMP_CMP_MI(t, ip, >);
}
static inline void
instr_jmp_gt_hi_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
TRACE("[Thread %2u] jmpgt (hi)\n", p->thread_id);
JMP_CMP_HI(t, ip, >);
}
/*
* return.
*/
static int
instr_return_translate(struct rte_swx_pipeline *p __rte_unused,
struct action *action,
char **tokens __rte_unused,
int n_tokens,
struct instruction *instr,
struct instruction_data *data __rte_unused)
{
CHECK(action, EINVAL);
CHECK(n_tokens == 1, EINVAL);
instr->type = INSTR_RETURN;
return 0;
}
static inline void
instr_return_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
TRACE("[Thread %2u] return\n", p->thread_id);
t->ip = t->ret;
}
static int
instr_translate(struct rte_swx_pipeline *p,
struct action *action,
char *string,
struct instruction *instr,
struct instruction_data *data)
{
char *tokens[RTE_SWX_INSTRUCTION_TOKENS_MAX];
int n_tokens = 0, tpos = 0;
/* Parse the instruction string into tokens. */
for ( ; ; ) {
char *token;
token = strtok_r(string, " \t\v", &string);
if (!token)
break;
CHECK(n_tokens < RTE_SWX_INSTRUCTION_TOKENS_MAX, EINVAL);
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_NAME(token, EINVAL);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
tokens[n_tokens] = token;
n_tokens++;
}
CHECK(n_tokens, EINVAL);
/* Handle the optional instruction label. */
if ((n_tokens >= 2) && !strcmp(tokens[1], ":")) {
strcpy(data->label, tokens[0]);
tpos += 2;
CHECK(n_tokens - tpos, EINVAL);
}
/* Identify the instruction type. */
if (!strcmp(tokens[tpos], "rx"))
return instr_rx_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "tx"))
return instr_tx_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
if (!strcmp(tokens[tpos], "drop"))
return instr_drop_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
if (!strcmp(tokens[tpos], "mirror"))
return instr_mirror_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
if (!strcmp(tokens[tpos], "recirculate"))
return instr_recirculate_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "recircid"))
return instr_recircid_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
if (!strcmp(tokens[tpos], "extract"))
return instr_hdr_extract_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: add header look-ahead instruction Added look-ahead instruction to read a header from the input packet without advancing the extraction pointer. This is typically used in correlation with the special extract instruction to extract variable size headers from the input packet: the first few header fields are read without advancing the extraction pointer, just enough to detect the actual length of the header (e.g. IPv4 IHL field); then the full header is extracted. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:39 +00:00
if (!strcmp(tokens[tpos], "lookahead"))
return instr_hdr_lookahead_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
if (!strcmp(tokens[tpos], "emit"))
return instr_hdr_emit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "validate"))
return instr_hdr_validate_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "invalidate"))
return instr_hdr_invalidate_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "mov"))
return instr_mov_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "add"))
return instr_alu_add_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "sub"))
return instr_alu_sub_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "ckadd"))
return instr_alu_ckadd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "cksub"))
return instr_alu_cksub_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "and"))
return instr_alu_and_translate(p,
action,
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
if (!strcmp(tokens[tpos], "or"))
return instr_alu_or_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
if (!strcmp(tokens[tpos], "xor"))
return instr_alu_xor_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
if (!strcmp(tokens[tpos], "shl"))
return instr_alu_shl_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
if (!strcmp(tokens[tpos], "shr"))
return instr_alu_shr_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
if (!strcmp(tokens[tpos], "regprefetch"))
return instr_regprefetch_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regrd"))
return instr_regrd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regwr"))
return instr_regwr_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "regadd"))
return instr_regadd_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
if (!strcmp(tokens[tpos], "metprefetch"))
return instr_metprefetch_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "meter"))
return instr_meter_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
if (!strcmp(tokens[tpos], "table"))
return instr_table_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
if (!strcmp(tokens[tpos], "learn"))
return instr_learn_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
if (!strcmp(tokens[tpos], "rearm"))
return instr_rearm_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
if (!strcmp(tokens[tpos], "forget"))
return instr_forget_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
if (!strcmp(tokens[tpos], "extern"))
return instr_extern_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
if (!strcmp(tokens[tpos], "hash"))
return instr_hash_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
if (!strcmp(tokens[tpos], "jmp"))
return instr_jmp_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpv"))
return instr_jmp_valid_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpnv"))
return instr_jmp_invalid_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmph"))
return instr_jmp_hit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpnh"))
return instr_jmp_miss_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpa"))
return instr_jmp_action_hit_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpna"))
return instr_jmp_action_miss_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpeq"))
return instr_jmp_eq_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpneq"))
return instr_jmp_neq_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmplt"))
return instr_jmp_lt_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "jmpgt"))
return instr_jmp_gt_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
if (!strcmp(tokens[tpos], "return"))
return instr_return_translate(p,
action,
&tokens[tpos],
n_tokens - tpos,
instr,
data);
pipeline: fix build with ASan Code changes to avoid the following build error: "Control reaches end of non-void function". Signed-off-by: Xueqin Lin <xueqin.lin@intel.com> Signed-off-by: Zhihong Peng <zhihongx.peng@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-20 07:46:42 +00:00
return -EINVAL;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static struct instruction_data *
label_find(struct instruction_data *data, uint32_t n, const char *label)
{
uint32_t i;
for (i = 0; i < n; i++)
if (!strcmp(label, data[i].label))
return &data[i];
return NULL;
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
static uint32_t
label_is_used(struct instruction_data *data, uint32_t n, const char *label)
{
uint32_t count = 0, i;
if (!label[0])
return 0;
for (i = 0; i < n; i++)
if (!strcmp(label, data[i].jmp_label))
count++;
return count;
}
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
static int
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
instr_label_check(struct instruction_data *instruction_data,
uint32_t n_instructions)
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
{
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
uint32_t i;
/* Check that all instruction labels are unique. */
for (i = 0; i < n_instructions; i++) {
struct instruction_data *data = &instruction_data[i];
char *label = data->label;
uint32_t j;
if (!label[0])
continue;
for (j = i + 1; j < n_instructions; j++)
pipeline: fix instruction label check The instruction_data array was incorrectly indexed, which resulted in the array index getting out of bounds and sometimes segfault. Fixes: a1711f (“pipeline: add SWX Rx and extract instructions“) Cc: stable@dpdk.org Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-21 03:23:32 +00:00
CHECK(strcmp(label, instruction_data[j].label), EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
}
pipeline: add check against loops Detect when a jump instruction, either conditional or unconditional, is jumping to itself, thus creating a loop, which is not allowed in data plane code. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com>
2021-12-01 12:21:19 +00:00
/* Check that no jump instruction (either conditional or not) can jump to itself (loop). */
for (i = 0; i < n_instructions; i++) {
struct instruction_data *data = &instruction_data[i];
char *label = data->label;
char *jmp_label = data->jmp_label;
/* Continue if this instruction does not have a label or it is not a jump. */
if (!label[0] || !jmp_label[0])
continue;
CHECK(strcmp(label, jmp_label), EINVAL);
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Get users for each instruction label. */
for (i = 0; i < n_instructions; i++) {
struct instruction_data *data = &instruction_data[i];
char *label = data->label;
data->n_users = label_is_used(instruction_data,
n_instructions,
label);
}
return 0;
}
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
static int
instr_jmp_resolve(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
struct instruction_data *found;
if (!instruction_is_jmp(instr))
continue;
found = label_find(instruction_data,
n_instructions,
data->jmp_label);
CHECK(found, EINVAL);
pipeline: fix SWX jump instruction population This patch fixes jump next instruction pointer population. Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-16 13:57:47 +00:00
instr->jmp.ip = &instructions[found - instruction_data];
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
}
return 0;
}
pipeline: add SWX instruction verifier Instruction verifier. Executes at instruction translation time during SWX pipeline build, i.e. at initialization instead of run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:55 +00:00
static int
instr_verify(struct rte_swx_pipeline *p __rte_unused,
struct action *a,
struct instruction *instr,
struct instruction_data *data __rte_unused,
uint32_t n_instructions)
{
if (!a) {
enum instruction_type type;
uint32_t i;
/* Check that the first instruction is rx. */
CHECK(instr[0].type == INSTR_RX, EINVAL);
/* Check that there is at least one tx instruction. */
for (i = 0; i < n_instructions; i++) {
type = instr[i].type;
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
if (instruction_is_tx(type))
pipeline: add SWX instruction verifier Instruction verifier. Executes at instruction translation time during SWX pipeline build, i.e. at initialization instead of run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:55 +00:00
break;
}
CHECK(i < n_instructions, EINVAL);
/* Check that the last instruction is either tx or unconditional
* jump.
*/
type = instr[n_instructions - 1].type;
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
CHECK(instruction_is_tx(type) || (type == INSTR_JMP), EINVAL);
pipeline: add SWX instruction verifier Instruction verifier. Executes at instruction translation time during SWX pipeline build, i.e. at initialization instead of run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:55 +00:00
}
if (a) {
enum instruction_type type;
uint32_t i;
/* Check that there is at least one return or tx instruction. */
for (i = 0; i < n_instructions; i++) {
type = instr[i].type;
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
if ((type == INSTR_RETURN) || instruction_is_tx(type))
pipeline: add SWX instruction verifier Instruction verifier. Executes at instruction translation time during SWX pipeline build, i.e. at initialization instead of run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:55 +00:00
break;
}
CHECK(i < n_instructions, EINVAL);
}
return 0;
}
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
static uint32_t
instr_compact(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i, pos = 0;
/* Eliminate the invalid instructions that have been optimized out. */
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
if (data->invalid)
continue;
if (i != pos) {
memcpy(&instructions[pos], instr, sizeof(*instr));
memcpy(&instruction_data[pos], data, sizeof(*data));
}
pos++;
}
return pos;
}
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
static int
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_extract_many_search(struct instruction *instr,
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_HDR_EXTRACT)
break;
if (i == RTE_DIM(instr->io.hdr.header_id))
break;
if (i && data[i].n_users)
break;
}
if (i < 2)
return 0;
*n_pattern_instr = i;
return 1;
}
static void
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_extract_many_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
{
uint32_t i;
for (i = 1; i < n_instr; i++) {
instr[0].type++;
instr[0].io.hdr.header_id[i] = instr[i].io.hdr.header_id[0];
instr[0].io.hdr.struct_id[i] = instr[i].io.hdr.struct_id[0];
instr[0].io.hdr.n_bytes[i] = instr[i].io.hdr.n_bytes[0];
data[i].invalid = 1;
}
}
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
static uint32_t
instr_pattern_extract_many_optimize(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Extract many. */
detected = instr_pattern_extract_many_search(instr,
data,
n_instructions - i,
&n_instr);
if (detected) {
instr_pattern_extract_many_replace(instr,
data,
n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
static int
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_emit_many_tx_search(struct instruction *instr,
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_HDR_EMIT)
break;
if (i == RTE_DIM(instr->io.hdr.header_id))
break;
if (i && data[i].n_users)
break;
}
if (!i)
return 0;
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
if (instr[i].type != INSTR_TX)
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
return 0;
pipeline: fix multiple SWX emit pattern detection Fix the detection of instruction pattern with multiple emits followed by TX. Once detected, this is one of the instruction patterns that is internally replaced with a single optimized instruction, as long as none of the instructions to be replaced is referenced by a jump instruction. The fix enforces this check for the TX instruction of the pattern. Fixes: 31035e87b207 ("pipeline: add SWX instruction optimizer") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-11-12 14:50:13 +00:00
if (data[i].n_users)
return 0;
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
i++;
*n_pattern_instr = i;
return 1;
}
static void
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_emit_many_tx_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
{
uint32_t i;
/* Any emit instruction in addition to the first one. */
for (i = 1; i < n_instr - 1; i++) {
instr[0].type++;
instr[0].io.hdr.header_id[i] = instr[i].io.hdr.header_id[0];
instr[0].io.hdr.struct_id[i] = instr[i].io.hdr.struct_id[0];
instr[0].io.hdr.n_bytes[i] = instr[i].io.hdr.n_bytes[0];
data[i].invalid = 1;
}
/* The TX instruction is the last one in the pattern. */
instr[0].type++;
instr[0].io.io.offset = instr[i].io.io.offset;
instr[0].io.io.n_bits = instr[i].io.io.n_bits;
data[i].invalid = 1;
}
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
static uint32_t
instr_pattern_emit_many_tx_optimize(struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Emit many + TX. */
detected = instr_pattern_emit_many_tx_search(instr,
data,
n_instructions - i,
&n_instr);
if (detected) {
instr_pattern_emit_many_tx_replace(instr,
data,
n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
static uint32_t
action_arg_src_mov_count(struct action *a,
uint32_t arg_id,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions);
static int
instr_pattern_mov_all_validate_search(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions,
uint32_t *n_pattern_instr)
{
struct header *h;
uint32_t src_field_id, i, j;
/* Prerequisites. */
if (!a || !a->st)
return 0;
/* First instruction: MOV_HM. */
if (data[0].invalid || (instr[0].type != INSTR_MOV_HM))
return 0;
h = header_find_by_struct_id(p, instr[0].mov.dst.struct_id);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
if (!h || h->st->var_size)
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
return 0;
for (src_field_id = 0; src_field_id < a->st->n_fields; src_field_id++)
if (instr[0].mov.src.offset == a->st->fields[src_field_id].offset / 8)
break;
if (src_field_id == a->st->n_fields)
return 0;
if (instr[0].mov.dst.offset ||
(instr[0].mov.dst.n_bits != h->st->fields[0].n_bits) ||
instr[0].mov.src.struct_id ||
(instr[0].mov.src.n_bits != a->st->fields[src_field_id].n_bits) ||
(instr[0].mov.dst.n_bits != instr[0].mov.src.n_bits))
return 0;
if ((n_instr < h->st->n_fields + 1) ||
(a->st->n_fields < src_field_id + h->st->n_fields + 1))
return 0;
/* Subsequent instructions: MOV_HM. */
for (i = 1; i < h->st->n_fields; i++)
if (data[i].invalid ||
data[i].n_users ||
(instr[i].type != INSTR_MOV_HM) ||
(instr[i].mov.dst.struct_id != h->struct_id) ||
(instr[i].mov.dst.offset != h->st->fields[i].offset / 8) ||
(instr[i].mov.dst.n_bits != h->st->fields[i].n_bits) ||
instr[i].mov.src.struct_id ||
(instr[i].mov.src.offset != a->st->fields[src_field_id + i].offset / 8) ||
(instr[i].mov.src.n_bits != a->st->fields[src_field_id + i].n_bits) ||
(instr[i].mov.dst.n_bits != instr[i].mov.src.n_bits))
return 0;
/* Last instruction: HDR_VALIDATE. */
if ((instr[i].type != INSTR_HDR_VALIDATE) ||
(instr[i].valid.header_id != h->id))
return 0;
/* Check that none of the action args that are used as source for this
* DMA transfer are not used as source in any other mov instruction.
*/
for (j = src_field_id; j < src_field_id + h->st->n_fields; j++) {
uint32_t n_users;
n_users = action_arg_src_mov_count(a,
j,
instructions,
instruction_data,
n_instructions);
if (n_users > 1)
return 0;
}
*n_pattern_instr = 1 + i;
return 1;
}
static void
instr_pattern_mov_all_validate_replace(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
{
struct header *h;
uint32_t src_field_id, src_offset, i;
/* Read from the instructions before they are modified. */
h = header_find_by_struct_id(p, instr[0].mov.dst.struct_id);
if (!h)
return;
for (src_field_id = 0; src_field_id < a->st->n_fields; src_field_id++)
if (instr[0].mov.src.offset == a->st->fields[src_field_id].offset / 8)
break;
if (src_field_id == a->st->n_fields)
return;
src_offset = instr[0].mov.src.offset;
/* Modify the instructions. */
instr[0].type = INSTR_DMA_HT;
instr[0].dma.dst.header_id[0] = h->id;
instr[0].dma.dst.struct_id[0] = h->struct_id;
instr[0].dma.src.offset[0] = (uint8_t)src_offset;
instr[0].dma.n_bytes[0] = h->st->n_bits / 8;
for (i = 1; i < n_instr; i++)
data[i].invalid = 1;
/* Update the endianness of the action arguments to header endianness. */
for (i = 0; i < h->st->n_fields; i++)
a->args_endianness[src_field_id + i] = 1;
}
static uint32_t
instr_pattern_mov_all_validate_optimize(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t i;
if (!a || !a->st)
return n_instructions;
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* Mov all + validate. */
detected = instr_pattern_mov_all_validate_search(p,
a,
instr,
data,
n_instructions - i,
instructions,
instruction_data,
n_instructions,
&n_instr);
if (detected) {
instr_pattern_mov_all_validate_replace(p, a, instr, data, n_instr);
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
return n_instructions;
}
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
static int
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_dma_many_search(struct instruction *instr,
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
struct instruction_data *data,
uint32_t n_instr,
uint32_t *n_pattern_instr)
{
uint32_t i;
for (i = 0; i < n_instr; i++) {
if (data[i].invalid)
break;
if (instr[i].type != INSTR_DMA_HT)
break;
if (i == RTE_DIM(instr->dma.dst.header_id))
break;
if (i && data[i].n_users)
break;
}
if (i < 2)
return 0;
*n_pattern_instr = i;
return 1;
}
static void
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_dma_many_replace(struct instruction *instr,
struct instruction_data *data,
uint32_t n_instr)
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
{
uint32_t i;
for (i = 1; i < n_instr; i++) {
instr[0].type++;
instr[0].dma.dst.header_id[i] = instr[i].dma.dst.header_id[0];
instr[0].dma.dst.struct_id[i] = instr[i].dma.dst.struct_id[0];
instr[0].dma.src.offset[i] = instr[i].dma.src.offset[0];
instr[0].dma.n_bytes[i] = instr[i].dma.n_bytes[0];
data[i].invalid = 1;
}
}
static uint32_t
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_dma_many_optimize(struct instruction *instructions,
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
uint32_t i;
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
for (i = 0; i < n_instructions; ) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
uint32_t n_instr = 0;
int detected;
/* DMA many. */
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
detected = instr_pattern_dma_many_search(instr,
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
data,
n_instructions - i,
&n_instr);
if (detected) {
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
instr_pattern_dma_many_replace(instr, data, n_instr);
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
i += n_instr;
continue;
}
/* No pattern starting at the current instruction. */
i++;
}
/* Eliminate the invalid instructions that have been optimized out. */
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
n_instructions = instr_compact(instructions,
instruction_data,
n_instructions);
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
return n_instructions;
}
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
static uint32_t
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
instr_optimize(struct rte_swx_pipeline *p,
struct action *a,
struct instruction *instructions,
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
/* Extract many. */
n_instructions = instr_pattern_extract_many_optimize(instructions,
instruction_data,
n_instructions);
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
/* Emit many + TX. */
n_instructions = instr_pattern_emit_many_tx_optimize(instructions,
instruction_data,
n_instructions);
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
/* Mov all + validate. */
n_instructions = instr_pattern_mov_all_validate_optimize(p,
a,
instructions,
instruction_data,
n_instructions);
pipeline: modularize SWX instruction optimizer Decouple between the different instruction optimizer. Allow each optimization to run as a separate iteration on the entire instruction stream. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:37 +00:00
/* DMA many. */
n_instructions = instr_pattern_dma_many_optimize(instructions,
instruction_data,
n_instructions);
return n_instructions;
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
static int
instruction_config(struct rte_swx_pipeline *p,
struct action *a,
const char **instructions,
uint32_t n_instructions)
{
struct instruction *instr = NULL;
struct instruction_data *data = NULL;
int err = 0;
uint32_t i;
CHECK(n_instructions, EINVAL);
CHECK(instructions, EINVAL);
for (i = 0; i < n_instructions; i++)
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_INSTRUCTION(instructions[i], EINVAL);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
/* Memory allocation. */
instr = calloc(n_instructions, sizeof(struct instruction));
if (!instr) {
pipeline: adjust error code for internal function Adjusting the error code for the internal function instruction_config to match the rest of the code which is returning a negative value on error. Cosmetic change. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-30 10:19:04 +00:00
err = -ENOMEM;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
goto error;
}
data = calloc(n_instructions, sizeof(struct instruction_data));
if (!data) {
pipeline: adjust error code for internal function Adjusting the error code for the internal function instruction_config to match the rest of the code which is returning a negative value on error. Cosmetic change. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-30 10:19:04 +00:00
err = -ENOMEM;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
goto error;
}
for (i = 0; i < n_instructions; i++) {
pipeline: fix instruction config free Coverity issue: 362901 Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-06 20:37:55 +00:00
char *string = strdup(instructions[i]);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
if (!string) {
pipeline: adjust error code for internal function Adjusting the error code for the internal function instruction_config to match the rest of the code which is returning a negative value on error. Cosmetic change. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-30 10:19:04 +00:00
err = -ENOMEM;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
goto error;
}
err = instr_translate(p, a, string, &instr[i], &data[i]);
pipeline: fix instruction config free Coverity issue: 362901 Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-06 20:37:55 +00:00
if (err) {
free(string);
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
goto error;
pipeline: fix instruction config free Coverity issue: 362901 Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-06 20:37:55 +00:00
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
free(string);
}
err = instr_label_check(data, n_instructions);
if (err)
goto error;
pipeline: add SWX instruction verifier Instruction verifier. Executes at instruction translation time during SWX pipeline build, i.e. at initialization instead of run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:55 +00:00
err = instr_verify(p, a, instr, data, n_instructions);
if (err)
goto error;
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
n_instructions = instr_optimize(p, a, instr, data, n_instructions);
pipeline: add SWX instruction optimizer Instruction optimizer. Detects frequent patterns and replaces them with some more powerful vector-like pipeline instructions without any user effort. Executes at instruction translation, not at run-time. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:56 +00:00
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
err = instr_jmp_resolve(instr, data, n_instructions);
if (err)
goto error;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
if (a) {
a->instructions = instr;
pipeline: enable persistent instruction meta-data Save the instruction meta-data for later use instead of freeing it up once the instruction translation is completed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:35 +00:00
a->instruction_data = data;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
a->n_instructions = n_instructions;
} else {
p->instructions = instr;
pipeline: enable persistent instruction meta-data Save the instruction meta-data for later use instead of freeing it up once the instruction translation is completed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:35 +00:00
p->instruction_data = data;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
p->n_instructions = n_instructions;
}
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
return 0;
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
error:
free(data);
free(instr);
return err;
}
static instr_exec_t instruction_table[] = {
[INSTR_RX] = instr_rx_exec,
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
[INSTR_TX] = instr_tx_exec,
pipeline: add drop instruction to SWX Enabled the TX instruction to accept an immediate value for the output port argument. The drop instruction is simply an alias to the TX instruction for the last output port of the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-26 22:11:08 +00:00
[INSTR_TX_I] = instr_tx_i_exec,
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
[INSTR_DROP] = instr_drop_exec,
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
[INSTR_MIRROR] = instr_mirror_exec,
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
[INSTR_RECIRCULATE] = instr_recirculate_exec,
[INSTR_RECIRCID] = instr_recircid_exec,
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
[INSTR_HDR_EXTRACT] = instr_hdr_extract_exec,
[INSTR_HDR_EXTRACT2] = instr_hdr_extract2_exec,
[INSTR_HDR_EXTRACT3] = instr_hdr_extract3_exec,
[INSTR_HDR_EXTRACT4] = instr_hdr_extract4_exec,
[INSTR_HDR_EXTRACT5] = instr_hdr_extract5_exec,
[INSTR_HDR_EXTRACT6] = instr_hdr_extract6_exec,
[INSTR_HDR_EXTRACT7] = instr_hdr_extract7_exec,
[INSTR_HDR_EXTRACT8] = instr_hdr_extract8_exec,
pipeline: add variable size headers extract instruction Added a mechanism to extract variable size headers through a special flavor of the extract instruction. The length of the last struct field which has variable size is passed as argument to the instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:38 +00:00
[INSTR_HDR_EXTRACT_M] = instr_hdr_extract_m_exec,
pipeline: add header look-ahead instruction Added look-ahead instruction to read a header from the input packet without advancing the extraction pointer. This is typically used in correlation with the special extract instruction to extract variable size headers from the input packet: the first few header fields are read without advancing the extraction pointer, just enough to detect the actual length of the header (e.g. IPv4 IHL field); then the full header is extracted. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:39 +00:00
[INSTR_HDR_LOOKAHEAD] = instr_hdr_lookahead_exec,
pipeline: add SWX Tx and emit instructions Add header emit and packet transmission instructions. Emit adds to the output packet a header that is either generated (e.g. read from table entry by action) or extracted from the input packet. Tx ends the pipeline processing; discard is implemented by tx to special port. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:38 +00:00
[INSTR_HDR_EMIT] = instr_hdr_emit_exec,
[INSTR_HDR_EMIT_TX] = instr_hdr_emit_tx_exec,
[INSTR_HDR_EMIT2_TX] = instr_hdr_emit2_tx_exec,
[INSTR_HDR_EMIT3_TX] = instr_hdr_emit3_tx_exec,
[INSTR_HDR_EMIT4_TX] = instr_hdr_emit4_tx_exec,
[INSTR_HDR_EMIT5_TX] = instr_hdr_emit5_tx_exec,
[INSTR_HDR_EMIT6_TX] = instr_hdr_emit6_tx_exec,
[INSTR_HDR_EMIT7_TX] = instr_hdr_emit7_tx_exec,
[INSTR_HDR_EMIT8_TX] = instr_hdr_emit8_tx_exec,
pipeline: add header validate and invalidate SWX instructions Add instructions to flag a header as valid or invalid. This flag can be tested by the jmpv (jump if header valid) and jmpnv (jump if header not valid) instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:39 +00:00
[INSTR_HDR_VALIDATE] = instr_hdr_validate_exec,
[INSTR_HDR_INVALIDATE] = instr_hdr_invalidate_exec,
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
[INSTR_MOV] = instr_mov_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_MOV_MH] = instr_mov_mh_exec,
[INSTR_MOV_HM] = instr_mov_hm_exec,
[INSTR_MOV_HH] = instr_mov_hh_exec,
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
[INSTR_MOV_I] = instr_mov_i_exec,
pipeline: add SWX DMA instruction The DMA instruction handles the bulk read transfer of one header from the table entry action data. Typically used to generate headers, i.e. headers that are not extracted from the input packet. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:41 +00:00
[INSTR_DMA_HT] = instr_dma_ht_exec,
[INSTR_DMA_HT2] = instr_dma_ht2_exec,
[INSTR_DMA_HT3] = instr_dma_ht3_exec,
[INSTR_DMA_HT4] = instr_dma_ht4_exec,
[INSTR_DMA_HT5] = instr_dma_ht5_exec,
[INSTR_DMA_HT6] = instr_dma_ht6_exec,
[INSTR_DMA_HT7] = instr_dma_ht7_exec,
[INSTR_DMA_HT8] = instr_dma_ht8_exec,
pipeline: introduce SWX add instruction The add instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:42 +00:00
[INSTR_ALU_ADD] = instr_alu_add_exec,
[INSTR_ALU_ADD_MH] = instr_alu_add_mh_exec,
[INSTR_ALU_ADD_HM] = instr_alu_add_hm_exec,
[INSTR_ALU_ADD_HH] = instr_alu_add_hh_exec,
[INSTR_ALU_ADD_MI] = instr_alu_add_mi_exec,
[INSTR_ALU_ADD_HI] = instr_alu_add_hi_exec,
pipeline: introduce SWX subtract instruction The sub (i.e. subtract) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:43 +00:00
[INSTR_ALU_SUB] = instr_alu_sub_exec,
[INSTR_ALU_SUB_MH] = instr_alu_sub_mh_exec,
[INSTR_ALU_SUB_HM] = instr_alu_sub_hm_exec,
[INSTR_ALU_SUB_HH] = instr_alu_sub_hh_exec,
[INSTR_ALU_SUB_MI] = instr_alu_sub_mi_exec,
[INSTR_ALU_SUB_HI] = instr_alu_sub_hi_exec,
pipeline: introduce SWX ckadd instruction The ckadd (i.e. checksum add) instruction is used to either compute, verify or update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:44 +00:00
[INSTR_ALU_CKADD_FIELD] = instr_alu_ckadd_field_exec,
[INSTR_ALU_CKADD_STRUCT] = instr_alu_ckadd_struct_exec,
[INSTR_ALU_CKADD_STRUCT20] = instr_alu_ckadd_struct20_exec,
pipeline: introduce SWX cksub instruction The cksub (i.e. checksum subtract) instruction is used to update the 1's complement sum commonly used by protocols such as IPv4, TCP or UDP. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:45 +00:00
[INSTR_ALU_CKSUB_FIELD] = instr_alu_cksub_field_exec,
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
[INSTR_ALU_AND] = instr_alu_and_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_ALU_AND_MH] = instr_alu_and_mh_exec,
[INSTR_ALU_AND_HM] = instr_alu_and_hm_exec,
[INSTR_ALU_AND_HH] = instr_alu_and_hh_exec,
pipeline: introduce SWX and instruction The and (i.e. bitwise and) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:46 +00:00
[INSTR_ALU_AND_I] = instr_alu_and_i_exec,
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
[INSTR_ALU_OR] = instr_alu_or_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_ALU_OR_MH] = instr_alu_or_mh_exec,
[INSTR_ALU_OR_HM] = instr_alu_or_hm_exec,
[INSTR_ALU_OR_HH] = instr_alu_or_hh_exec,
pipeline: introduce SWX or instruction The or (i.e. bitwise or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:47 +00:00
[INSTR_ALU_OR_I] = instr_alu_or_i_exec,
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
[INSTR_ALU_XOR] = instr_alu_xor_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_ALU_XOR_MH] = instr_alu_xor_mh_exec,
[INSTR_ALU_XOR_HM] = instr_alu_xor_hm_exec,
[INSTR_ALU_XOR_HH] = instr_alu_xor_hh_exec,
pipeline: introduce SWX XOR instruction The xor (i.e. bitwise exclusive or) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:48 +00:00
[INSTR_ALU_XOR_I] = instr_alu_xor_i_exec,
pipeline: introduce SWX SHL instruction The shl (i.e. shift left) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:49 +00:00
[INSTR_ALU_SHL] = instr_alu_shl_exec,
[INSTR_ALU_SHL_MH] = instr_alu_shl_mh_exec,
[INSTR_ALU_SHL_HM] = instr_alu_shl_hm_exec,
[INSTR_ALU_SHL_HH] = instr_alu_shl_hh_exec,
[INSTR_ALU_SHL_MI] = instr_alu_shl_mi_exec,
[INSTR_ALU_SHL_HI] = instr_alu_shl_hi_exec,
pipeline: introduce SWX SHR instruction The shr (i.e. shift right) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:50 +00:00
[INSTR_ALU_SHR] = instr_alu_shr_exec,
[INSTR_ALU_SHR_MH] = instr_alu_shr_mh_exec,
[INSTR_ALU_SHR_HM] = instr_alu_shr_hm_exec,
[INSTR_ALU_SHR_HH] = instr_alu_shr_hh_exec,
[INSTR_ALU_SHR_MI] = instr_alu_shr_mi_exec,
[INSTR_ALU_SHR_HI] = instr_alu_shr_hi_exec,
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
[INSTR_REGPREFETCH_RH] = instr_regprefetch_rh_exec,
[INSTR_REGPREFETCH_RM] = instr_regprefetch_rm_exec,
[INSTR_REGPREFETCH_RI] = instr_regprefetch_ri_exec,
[INSTR_REGRD_HRH] = instr_regrd_hrh_exec,
[INSTR_REGRD_HRM] = instr_regrd_hrm_exec,
[INSTR_REGRD_MRH] = instr_regrd_mrh_exec,
[INSTR_REGRD_MRM] = instr_regrd_mrm_exec,
[INSTR_REGRD_HRI] = instr_regrd_hri_exec,
[INSTR_REGRD_MRI] = instr_regrd_mri_exec,
[INSTR_REGWR_RHH] = instr_regwr_rhh_exec,
[INSTR_REGWR_RHM] = instr_regwr_rhm_exec,
[INSTR_REGWR_RMH] = instr_regwr_rmh_exec,
[INSTR_REGWR_RMM] = instr_regwr_rmm_exec,
[INSTR_REGWR_RHI] = instr_regwr_rhi_exec,
[INSTR_REGWR_RMI] = instr_regwr_rmi_exec,
[INSTR_REGWR_RIH] = instr_regwr_rih_exec,
[INSTR_REGWR_RIM] = instr_regwr_rim_exec,
[INSTR_REGWR_RII] = instr_regwr_rii_exec,
[INSTR_REGADD_RHH] = instr_regadd_rhh_exec,
[INSTR_REGADD_RHM] = instr_regadd_rhm_exec,
[INSTR_REGADD_RMH] = instr_regadd_rmh_exec,
[INSTR_REGADD_RMM] = instr_regadd_rmm_exec,
[INSTR_REGADD_RHI] = instr_regadd_rhi_exec,
[INSTR_REGADD_RMI] = instr_regadd_rmi_exec,
[INSTR_REGADD_RIH] = instr_regadd_rih_exec,
[INSTR_REGADD_RIM] = instr_regadd_rim_exec,
[INSTR_REGADD_RII] = instr_regadd_rii_exec,
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
[INSTR_METPREFETCH_H] = instr_metprefetch_h_exec,
[INSTR_METPREFETCH_M] = instr_metprefetch_m_exec,
[INSTR_METPREFETCH_I] = instr_metprefetch_i_exec,
[INSTR_METER_HHM] = instr_meter_hhm_exec,
[INSTR_METER_HHI] = instr_meter_hhi_exec,
[INSTR_METER_HMM] = instr_meter_hmm_exec,
[INSTR_METER_HMI] = instr_meter_hmi_exec,
[INSTR_METER_MHM] = instr_meter_mhm_exec,
[INSTR_METER_MHI] = instr_meter_mhi_exec,
[INSTR_METER_MMM] = instr_meter_mmm_exec,
[INSTR_METER_MMI] = instr_meter_mmi_exec,
[INSTR_METER_IHM] = instr_meter_ihm_exec,
[INSTR_METER_IHI] = instr_meter_ihi_exec,
[INSTR_METER_IMM] = instr_meter_imm_exec,
[INSTR_METER_IMI] = instr_meter_imi_exec,
pipeline: introduce SWX table instruction The table instruction looks up the input key into the table and then it triggers the execution of the action found in the table entry. On lookup miss, the default table action is executed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:51 +00:00
[INSTR_TABLE] = instr_table_exec,
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
[INSTR_TABLE_AF] = instr_table_af_exec,
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
[INSTR_SELECTOR] = instr_selector_exec,
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
[INSTR_LEARNER] = instr_learner_exec,
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
[INSTR_LEARNER_AF] = instr_learner_af_exec,
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
[INSTR_LEARNER_LEARN] = instr_learn_exec,
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
[INSTR_LEARNER_REARM] = instr_rearm_exec,
[INSTR_LEARNER_REARM_NEW] = instr_rearm_new_exec,
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
[INSTR_LEARNER_FORGET] = instr_forget_exec,
pipeline: introduce SWX extern instruction The extern instruction calls one of the member functions of a given extern object or it calls the given extern function. The function arguments must be written in advance to the mailbox. The results are available in the same place after execution. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:52 +00:00
[INSTR_EXTERN_OBJ] = instr_extern_obj_exec,
[INSTR_EXTERN_FUNC] = instr_extern_func_exec,
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
[INSTR_HASH_FUNC] = instr_hash_func_exec,
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
[INSTR_JMP] = instr_jmp_exec,
[INSTR_JMP_VALID] = instr_jmp_valid_exec,
[INSTR_JMP_INVALID] = instr_jmp_invalid_exec,
[INSTR_JMP_HIT] = instr_jmp_hit_exec,
[INSTR_JMP_MISS] = instr_jmp_miss_exec,
[INSTR_JMP_ACTION_HIT] = instr_jmp_action_hit_exec,
[INSTR_JMP_ACTION_MISS] = instr_jmp_action_miss_exec,
[INSTR_JMP_EQ] = instr_jmp_eq_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_JMP_EQ_MH] = instr_jmp_eq_mh_exec,
[INSTR_JMP_EQ_HM] = instr_jmp_eq_hm_exec,
[INSTR_JMP_EQ_HH] = instr_jmp_eq_hh_exec,
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
[INSTR_JMP_EQ_I] = instr_jmp_eq_i_exec,
[INSTR_JMP_NEQ] = instr_jmp_neq_exec,
pipeline: fix endianness conversions The SWX pipeline instructions work with operands of different types: header fields (h.header.field), packet meta-data (m.field), extern object mailbox field (e.obj.field), extern function (f.field), action data read from table entries (t.field), or immediate values; hence the HMEFTI acronym. The H operands are stored in network byte order (NBO), while the MEFT operands are stored in host byte order (HBO), hence the need to operate endianness conversions. Some of the endianness conversion macros were not working correctly for some cases such as operands of different sizes, and they are fixed now. Affected instructions: mov, and, or, xor, jmpeq, jmpneq. Fixes: 7210349d5baa ("pipeline: add SWX move instruction") Fixes: 650195cf965a ("pipeline: introduce SWX and instruction") Fixes: 8f796198dcda ("pipeline: introduce SWX or instruction") Fixes: b4e607f9fd5e ("pipeline: introduce SWX XOR instruction") Fixes: b3947e25bed4 ("pipeline: introduce SWX jump and return instructions") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-03 00:17:09 +00:00
[INSTR_JMP_NEQ_MH] = instr_jmp_neq_mh_exec,
[INSTR_JMP_NEQ_HM] = instr_jmp_neq_hm_exec,
[INSTR_JMP_NEQ_HH] = instr_jmp_neq_hh_exec,
pipeline: introduce SWX jump and return instructions The jump instructions are either unconditional (jmp) or conditional on positive/negative tests such as header validity (jmpv/jmpnv), table lookup hit/miss (jmph/jmpnh), executed action (jmpa/jmpna), equality (jmpeq/jmpneq), comparison result (jmplt/jmpgt). The return instruction resumes the pipeline execution after action subroutine. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:53 +00:00
[INSTR_JMP_NEQ_I] = instr_jmp_neq_i_exec,
[INSTR_JMP_LT] = instr_jmp_lt_exec,
[INSTR_JMP_LT_MH] = instr_jmp_lt_mh_exec,
[INSTR_JMP_LT_HM] = instr_jmp_lt_hm_exec,
[INSTR_JMP_LT_HH] = instr_jmp_lt_hh_exec,
[INSTR_JMP_LT_MI] = instr_jmp_lt_mi_exec,
[INSTR_JMP_LT_HI] = instr_jmp_lt_hi_exec,
[INSTR_JMP_GT] = instr_jmp_gt_exec,
[INSTR_JMP_GT_MH] = instr_jmp_gt_mh_exec,
[INSTR_JMP_GT_HM] = instr_jmp_gt_hm_exec,
[INSTR_JMP_GT_HH] = instr_jmp_gt_hh_exec,
[INSTR_JMP_GT_MI] = instr_jmp_gt_mi_exec,
[INSTR_JMP_GT_HI] = instr_jmp_gt_hi_exec,
[INSTR_RETURN] = instr_return_exec,
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
};
pipeline: introduce custom instructions For better performance, the option to create custom instructions when the program is translated and add them on-the-fly to the pipeline is now provided. Multiple regular instructions can now be consolidated into a single C function optimized by the C compiler directly. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:37 +00:00
static int
instruction_table_build(struct rte_swx_pipeline *p)
{
p->instruction_table = calloc(RTE_SWX_PIPELINE_INSTRUCTION_TABLE_SIZE_MAX,
sizeof(struct instr_exec_t *));
if (!p->instruction_table)
return -EINVAL;
memcpy(p->instruction_table, instruction_table, sizeof(instruction_table));
return 0;
}
static void
instruction_table_build_free(struct rte_swx_pipeline *p)
{
if (!p->instruction_table)
return;
free(p->instruction_table);
p->instruction_table = NULL;
}
static void
instruction_table_free(struct rte_swx_pipeline *p)
{
instruction_table_build_free(p);
}
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
static inline void
instr_exec(struct rte_swx_pipeline *p)
{
struct thread *t = &p->threads[p->thread_id];
struct instruction *ip = t->ip;
pipeline: introduce custom instructions For better performance, the option to create custom instructions when the program is translated and add them on-the-fly to the pipeline is now provided. Multiple regular instructions can now be consolidated into a single C function optimized by the C compiler directly. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:37 +00:00
instr_exec_t instr = p->instruction_table[ip->type];
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
instr(p);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
}
/*
* Action.
*/
static struct action *
action_find(struct rte_swx_pipeline *p, const char *name)
{
struct action *elem;
if (!name)
return NULL;
TAILQ_FOREACH(elem, &p->actions, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
static struct action *
action_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct action *action = NULL;
TAILQ_FOREACH(action, &p->actions, node)
if (action->id == id)
return action;
return NULL;
}
pipeline: add SWX move instruction The mov (i.e. move) instruction source can be header field (H), meta-data field (M), extern object (E) or function (F) mailbox field, table entry action data field (T) or immediate value (I). The destination is HMEF. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:40 +00:00
static struct field *
action_field_find(struct action *a, const char *name)
{
return a->st ? struct_type_field_find(a->st, name) : NULL;
}
static struct field *
action_field_parse(struct action *action, const char *name)
{
if (name[0] != 't' || name[1] != '.')
return NULL;
return action_field_find(action, &name[2]);
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static int
action_has_nbo_args(struct action *a)
{
uint32_t i;
/* Return if the action does not have any args. */
if (!a->st)
return 0; /* FALSE */
for (i = 0; i < a->st->n_fields; i++)
if (a->args_endianness[i])
return 1; /* TRUE */
return 0; /* FALSE */
}
static int
action_does_learning(struct action *a)
{
uint32_t i;
for (i = 0; i < a->n_instructions; i++)
switch (a->instructions[i].type) {
case INSTR_LEARNER_LEARN:
return 1; /* TRUE */
case INSTR_LEARNER_FORGET:
return 1; /* TRUE */
default:
continue;
}
return 0; /* FALSE */
}
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
int
rte_swx_pipeline_action_config(struct rte_swx_pipeline *p,
const char *name,
const char *args_struct_type_name,
const char **instructions,
uint32_t n_instructions)
{
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
struct struct_type *args_struct_type = NULL;
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
struct action *a = NULL;
int status = 0;
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!action_find(p, name), EEXIST);
if (args_struct_type_name) {
CHECK_NAME(args_struct_type_name, EINVAL);
args_struct_type = struct_type_find(p, args_struct_type_name);
CHECK(args_struct_type, EINVAL);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
CHECK(!args_struct_type->var_size, EINVAL);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
}
/* Node allocation. */
a = calloc(1, sizeof(struct action));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!a) {
status = -ENOMEM;
goto error;
}
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
if (args_struct_type) {
a->args_endianness = calloc(args_struct_type->n_fields, sizeof(int));
if (!a->args_endianness) {
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
status = -ENOMEM;
goto error;
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
}
}
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
/* Node initialization. */
strcpy(a->name, name);
a->st = args_struct_type;
a->id = p->n_actions;
/* Instruction translation. */
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
status = instruction_config(p, a, instructions, n_instructions);
if (status)
goto error;
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->actions, a, node);
p->n_actions++;
return 0;
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
error:
if (!a)
return status;
free(a->args_endianness);
free(a->instructions);
free(a->instruction_data);
free(a);
return status;
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
}
static int
action_build(struct rte_swx_pipeline *p)
{
struct action *action;
pipeline: enable persistent instruction meta-data Save the instruction meta-data for later use instead of freeing it up once the instruction translation is completed. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:35 +00:00
/* p->action_instructions. */
p->action_instructions = calloc(p->n_actions, sizeof(struct instruction *));
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
CHECK(p->action_instructions, ENOMEM);
TAILQ_FOREACH(action, &p->actions, node)
p->action_instructions[action->id] = action->instructions;
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
/* p->action_funcs. */
p->action_funcs = calloc(p->n_actions, sizeof(action_func_t));
CHECK(p->action_funcs, ENOMEM);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
return 0;
}
static void
action_build_free(struct rte_swx_pipeline *p)
{
pipeline: introduce action functions For better performance, the option to run a single function per action is now provided, which requires a single function call per action that can be better optimized by the C compiler, as opposed to one function call per instruction. Special table lookup instructions are added to to support this feature. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:36 +00:00
free(p->action_funcs);
p->action_funcs = NULL;
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
free(p->action_instructions);
p->action_instructions = NULL;
}
static void
action_free(struct rte_swx_pipeline *p)
{
action_build_free(p);
for ( ; ; ) {
struct action *action;
action = TAILQ_FIRST(&p->actions);
if (!action)
break;
TAILQ_REMOVE(&p->actions, action, node);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
free(action->args_endianness);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
free(action->instructions);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
free(action->instruction_data);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
free(action);
}
}
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
static uint32_t
action_arg_src_mov_count(struct action *a,
uint32_t arg_id,
struct instruction *instructions,
struct instruction_data *instruction_data,
uint32_t n_instructions)
{
uint32_t offset, n_users = 0, i;
if (!a->st ||
(arg_id >= a->st->n_fields) ||
!instructions ||
!instruction_data ||
!n_instructions)
return 0;
offset = a->st->fields[arg_id].offset / 8;
for (i = 0; i < n_instructions; i++) {
struct instruction *instr = &instructions[i];
struct instruction_data *data = &instruction_data[i];
if (data->invalid ||
((instr->type != INSTR_MOV) && (instr->type != INSTR_MOV_HM)) ||
instr->mov.src.struct_id ||
(instr->mov.src.offset != offset))
continue;
n_users++;
}
return n_users;
}
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
#if RTE_BYTE_ORDER == RTE_LITTLE_ENDIAN
#define field_ntoh(val, n_bits) (ntoh64((val) << (64 - n_bits)))
#define field_hton(val, n_bits) (hton64((val) << (64 - n_bits)))
#else
#define field_ntoh(val, n_bits) (val)
#define field_hton(val, n_bits) (val)
#endif
#define ACTION_ARGS_TOKENS_MAX 256
static int
action_args_parse(struct action *a, const char *args, uint8_t *data)
{
char *tokens[ACTION_ARGS_TOKENS_MAX], *s0 = NULL, *s;
uint32_t n_tokens = 0, offset = 0, i;
int status = 0;
/* Checks. */
if (!a->st || !args || !args[0]) {
status = -EINVAL;
goto error;
}
/* Memory allocation. */
s0 = strdup(args);
if (!s0) {
status = -ENOMEM;
goto error;
}
/* Parse the string into tokens. */
for (s = s0; ; ) {
char *token;
token = strtok_r(s, " \f\n\r\t\v", &s);
if (!token)
break;
if (n_tokens >= RTE_DIM(tokens)) {
status = -EINVAL;
goto error;
}
tokens[n_tokens] = token;
n_tokens++;
}
/* More checks. */
if (n_tokens != a->st->n_fields * 2) {
status = -EINVAL;
goto error;
}
/* Process the action arguments. */
for (i = 0; i < a->st->n_fields; i++) {
struct field *f = &a->st->fields[i];
char *arg_name = tokens[i * 2];
char *arg_val = tokens[i * 2 + 1];
uint64_t val;
if (strcmp(arg_name, f->name)) {
status = -EINVAL;
goto error;
}
val = strtoull(arg_val, &arg_val, 0);
if (arg_val[0]) {
status = -EINVAL;
goto error;
}
/* Endianness conversion. */
if (a->args_endianness[i])
val = field_hton(val, f->n_bits);
/* Copy to entry. */
memcpy(&data[offset], (uint8_t *)&val, f->n_bits / 8);
offset += f->n_bits / 8;
}
error:
free(s0);
return status;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
/*
* Table.
*/
static struct table_type *
table_type_find(struct rte_swx_pipeline *p, const char *name)
{
struct table_type *elem;
TAILQ_FOREACH(elem, &p->table_types, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct table_type *
table_type_resolve(struct rte_swx_pipeline *p,
const char *recommended_type_name,
enum rte_swx_table_match_type match_type)
{
struct table_type *elem;
/* Only consider the recommended type if the match type is correct. */
if (recommended_type_name)
TAILQ_FOREACH(elem, &p->table_types, node)
if (!strcmp(elem->name, recommended_type_name) &&
(elem->match_type == match_type))
return elem;
/* Ignore the recommended type and get the first element with this match
* type.
*/
TAILQ_FOREACH(elem, &p->table_types, node)
if (elem->match_type == match_type)
return elem;
return NULL;
}
static struct table *
table_find(struct rte_swx_pipeline *p, const char *name)
{
struct table *elem;
TAILQ_FOREACH(elem, &p->tables, node)
if (strcmp(elem->name, name) == 0)
return elem;
return NULL;
}
static struct table *
table_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct table *table = NULL;
TAILQ_FOREACH(table, &p->tables, node)
if (table->id == id)
return table;
return NULL;
}
int
rte_swx_pipeline_table_type_register(struct rte_swx_pipeline *p,
const char *name,
enum rte_swx_table_match_type match_type,
struct rte_swx_table_ops *ops)
{
struct table_type *elem;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_type_find(p, name), EEXIST);
CHECK(ops, EINVAL);
CHECK(ops->create, EINVAL);
CHECK(ops->lkp, EINVAL);
CHECK(ops->free, EINVAL);
/* Node allocation. */
elem = calloc(1, sizeof(struct table_type));
CHECK(elem, ENOMEM);
/* Node initialization. */
strcpy(elem->name, name);
elem->match_type = match_type;
memcpy(&elem->ops, ops, sizeof(*ops));
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->table_types, elem, node);
return 0;
}
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
static int
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
table_match_type_resolve(struct rte_swx_match_field_params *fields,
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
uint32_t n_fields,
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
enum rte_swx_table_match_type *match_type)
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
{
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
uint32_t n_fields_em = 0, n_fields_lpm = 0, i;
for (i = 0; i < n_fields; i++) {
struct rte_swx_match_field_params *f = &fields[i];
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
if (f->match_type == RTE_SWX_TABLE_MATCH_EXACT)
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
n_fields_em++;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
if (f->match_type == RTE_SWX_TABLE_MATCH_LPM)
n_fields_lpm++;
}
if ((n_fields_lpm > 1) ||
(n_fields_lpm && (n_fields_em != n_fields - 1)))
return -EINVAL;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
*match_type = (n_fields_em == n_fields) ?
RTE_SWX_TABLE_MATCH_EXACT :
RTE_SWX_TABLE_MATCH_WILDCARD;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
return 0;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
}
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
static int
table_match_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_table_params *params,
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
struct header **header)
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
{
struct header *h0 = NULL;
struct field *hf, *mf;
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
uint32_t *offset = NULL, i;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
int status = 0;
/* Return if no match fields. */
if (!params->n_fields) {
if (params->fields) {
status = -EINVAL;
goto end;
}
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
if (header)
*header = NULL;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
return 0;
}
/* Memory allocation. */
offset = calloc(params->n_fields, sizeof(uint32_t));
if (!offset) {
status = -ENOMEM;
goto end;
}
/* Check that all the match fields belong to either the same header or
* to the meta-data.
*/
hf = header_field_parse(p, params->fields[0].name, &h0);
mf = metadata_field_parse(p, params->fields[0].name);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
if ((!hf && !mf) || (hf && hf->var_size)) {
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
status = -EINVAL;
goto end;
}
offset[0] = h0 ? hf->offset : mf->offset;
for (i = 1; i < params->n_fields; i++)
if (h0) {
struct header *h;
hf = header_field_parse(p, params->fields[i].name, &h);
pipeline: support variable size headers Added support for variable size headers. The last field of a struct type can now have a variable size between 0 and N bytes. Useful to accommodate IPv4 packets with options, etc. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-27 17:43:37 +00:00
if (!hf || (h->id != h0->id) || hf->var_size) {
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
status = -EINVAL;
goto end;
}
offset[i] = hf->offset;
} else {
mf = metadata_field_parse(p, params->fields[i].name);
if (!mf) {
status = -EINVAL;
goto end;
}
offset[i] = mf->offset;
}
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_fields; i++) {
uint32_t j;
for (j = 0; j < i; j++)
if (offset[j] == offset[i]) {
status = -EINVAL;
goto end;
}
}
/* Return. */
if (header)
*header = h0;
end:
free(offset);
return status;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
int
rte_swx_pipeline_table_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_table_params *params,
const char *recommended_table_type_name,
const char *args,
uint32_t size)
{
struct table_type *type;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
struct table *t = NULL;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
struct action *default_action;
struct header *header = NULL;
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
uint32_t action_data_size_max = 0, i;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
int status = 0;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
CHECK(!selector_find(p, name), EEXIST);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
CHECK(!learner_find(p, name), EEXIST);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
CHECK(params, EINVAL);
/* Match checks. */
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
status = table_match_fields_check(p, params, &header);
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
if (status)
return status;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
/* Action checks. */
CHECK(params->n_actions, EINVAL);
CHECK(params->action_names, EINVAL);
for (i = 0; i < params->n_actions; i++) {
const char *action_name = params->action_names[i];
struct action *a;
uint32_t action_data_size;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_NAME(action_name, EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
a = action_find(p, action_name);
CHECK(a, EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
CHECK(!action_does_learning(a), EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
action_data_size = a->st ? a->st->n_bits / 8 : 0;
if (action_data_size > action_data_size_max)
action_data_size_max = action_data_size;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
CHECK(action_is_for_table_entries || action_is_for_default_entry, EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
}
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
CHECK_NAME(params->default_action_name, EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
for (i = 0; i < p->n_actions; i++)
if (!strcmp(params->action_names[i],
params->default_action_name))
break;
CHECK(i < params->n_actions, EINVAL);
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
CHECK(!params->action_is_for_default_entry || params->action_is_for_default_entry[i],
EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
default_action = action_find(p, params->default_action_name);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
CHECK((default_action->st && params->default_action_args) || !params->default_action_args,
EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
/* Table type checks. */
pipeline: fix string copy into fixed size buffer Fix potential buffer overflows by string copy into fixed size buffer. Coverity issue: 362732, 362736, 362760, 362772, 362775, 362784 Coverity issue: 362800, 362803, 362806, 362811, 362814, 362816 Coverity issue: 362834, 362837, 362844, 362845, 362857, 362861 Coverity issue: 362868, 362890, 362893, 362904, 362905 Fixes: 56492fd536 ("pipeline: add new SWX pipeline type") Fixes: 1e4c88caea ("pipeline: add SWX extern objects and funcs") Fixes: e9d870dd93 ("pipeline: add SWX pipeline tables") Fixes: a1711f948d ("pipeline: add SWX Rx and extract instructions") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-26 19:59:16 +00:00
if (recommended_table_type_name)
CHECK_NAME(recommended_table_type_name, EINVAL);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
if (params->n_fields) {
enum rte_swx_table_match_type match_type;
pipeline: support LPM lookup Add support for the Longest Prefix Match (LPM) lookup to the SWX pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Churchill Khangar <churchill.khangar@intel.com>
2021-07-08 10:11:29 +00:00
status = table_match_type_resolve(params->fields, params->n_fields, &match_type);
if (status)
return status;
type = table_type_resolve(p, recommended_table_type_name, match_type);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
CHECK(type, EINVAL);
} else {
type = NULL;
}
/* Memory allocation. */
t = calloc(1, sizeof(struct table));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t) {
status = -ENOMEM;
goto error;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
t->fields = calloc(params->n_fields, sizeof(struct match_field));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t->fields) {
status = -ENOMEM;
goto error;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
t->actions = calloc(params->n_actions, sizeof(struct action *));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t->actions) {
status = -ENOMEM;
goto error;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
if (action_data_size_max) {
t->default_action_data = calloc(1, action_data_size_max);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t->default_action_data) {
status = -ENOMEM;
goto error;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
t->action_is_for_table_entries = calloc(params->n_actions, sizeof(int));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t->action_is_for_table_entries) {
status = -ENOMEM;
goto error;
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
t->action_is_for_default_entry = calloc(params->n_actions, sizeof(int));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!t->action_is_for_default_entry) {
status = -ENOMEM;
goto error;
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
/* Node initialization. */
strcpy(t->name, name);
if (args && args[0])
strcpy(t->args, args);
t->type = type;
for (i = 0; i < params->n_fields; i++) {
struct rte_swx_match_field_params *field = &params->fields[i];
struct match_field *f = &t->fields[i];
f->match_type = field->match_type;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
f->field = header ?
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
header_field_parse(p, field->name, NULL) :
metadata_field_parse(p, field->name);
}
t->n_fields = params->n_fields;
t->header = header;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
for (i = 0; i < params->n_actions; i++) {
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
t->actions[i] = action_find(p, params->action_names[i]);
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
t->action_is_for_table_entries[i] = action_is_for_table_entries;
t->action_is_for_default_entry[i] = action_is_for_default_entry;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
t->default_action = default_action;
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (default_action->st) {
status = action_args_parse(default_action,
params->default_action_args,
t->default_action_data);
if (status)
goto error;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
t->n_actions = params->n_actions;
t->default_action_is_const = params->default_action_is_const;
t->action_data_size_max = action_data_size_max;
t->size = size;
t->id = p->n_tables;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->tables, t, node);
p->n_tables++;
return 0;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
error:
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
if (!t)
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
return status;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
free(t->action_is_for_default_entry);
free(t->action_is_for_table_entries);
free(t->default_action_data);
free(t->actions);
free(t->fields);
free(t);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
return status;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
}
static struct rte_swx_table_params *
table_params_get(struct table *table)
{
struct rte_swx_table_params *params;
struct field *first, *last;
uint8_t *key_mask;
uint32_t key_size, key_offset, action_data_size, i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_params));
if (!params)
return NULL;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
/* Find first (smallest offset) and last (biggest offset) match fields. */
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
first = table->fields[0].field;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
last = table->fields[0].field;
for (i = 0; i < table->n_fields; i++) {
struct field *f = table->fields[i].field;
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Key offset and size. */
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
key_offset = first->offset / 8;
key_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
key_mask = calloc(1, key_size);
if (!key_mask) {
free(params);
return NULL;
}
/* Key mask. */
for (i = 0; i < table->n_fields; i++) {
struct field *f = table->fields[i].field;
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&key_mask[start], 0xFF, size);
}
/* Action data size. */
action_data_size = 0;
for (i = 0; i < table->n_actions; i++) {
struct action *action = table->actions[i];
uint32_t ads = action->st ? action->st->n_bits / 8 : 0;
if (ads > action_data_size)
action_data_size = ads;
}
/* Fill in. */
params->match_type = table->type->match_type;
params->key_size = key_size;
params->key_offset = key_offset;
params->key_mask0 = key_mask;
params->action_data_size = action_data_size;
params->n_keys_max = table->size;
return params;
}
static void
table_params_free(struct rte_swx_table_params *params)
{
if (!params)
return;
free(params->key_mask0);
free(params);
}
static int
table_stub_lkp(void *table __rte_unused,
void *mailbox __rte_unused,
uint8_t **key __rte_unused,
uint64_t *action_id __rte_unused,
uint8_t **action_data __rte_unused,
int *hit)
{
*hit = 0;
return 1; /* DONE. */
}
static int
table_build(struct rte_swx_pipeline *p)
{
uint32_t i;
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
/* Per pipeline: table statistics. */
p->table_stats = calloc(p->n_tables, sizeof(struct table_statistics));
CHECK(p->table_stats, ENOMEM);
for (i = 0; i < p->n_tables; i++) {
p->table_stats[i].n_pkts_action = calloc(p->n_actions, sizeof(uint64_t));
CHECK(p->table_stats[i].n_pkts_action, ENOMEM);
}
/* Per thread: table runt-time. */
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct table *table;
t->tables = calloc(p->n_tables, sizeof(struct table_runtime));
CHECK(t->tables, ENOMEM);
TAILQ_FOREACH(table, &p->tables, node) {
struct table_runtime *r = &t->tables[table->id];
if (table->type) {
uint64_t size;
size = table->type->ops.mailbox_size_get();
/* r->func. */
r->func = table->type->ops.lkp;
/* r->mailbox. */
if (size) {
r->mailbox = calloc(1, size);
CHECK(r->mailbox, ENOMEM);
}
/* r->key. */
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
r->key = table->header ?
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
&t->structs[table->header->struct_id] :
&t->structs[p->metadata_struct_id];
} else {
r->func = table_stub_lkp;
}
}
}
return 0;
}
static void
table_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->tables)
continue;
for (j = 0; j < p->n_tables; j++) {
struct table_runtime *r = &t->tables[j];
free(r->mailbox);
}
free(t->tables);
t->tables = NULL;
}
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
if (p->table_stats) {
for (i = 0; i < p->n_tables; i++)
free(p->table_stats[i].n_pkts_action);
free(p->table_stats);
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
}
static void
table_free(struct rte_swx_pipeline *p)
{
table_build_free(p);
/* Tables. */
for ( ; ; ) {
struct table *elem;
elem = TAILQ_FIRST(&p->tables);
if (!elem)
break;
TAILQ_REMOVE(&p->tables, elem, node);
free(elem->fields);
free(elem->actions);
free(elem->default_action_data);
free(elem);
}
/* Table types. */
for ( ; ; ) {
struct table_type *elem;
elem = TAILQ_FIRST(&p->table_types);
if (!elem)
break;
TAILQ_REMOVE(&p->table_types, elem, node);
free(elem);
}
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
/*
* Selector.
*/
static struct selector *
selector_find(struct rte_swx_pipeline *p, const char *name)
{
struct selector *s;
TAILQ_FOREACH(s, &p->selectors, node)
if (strcmp(s->name, name) == 0)
return s;
return NULL;
}
static struct selector *
selector_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct selector *s = NULL;
TAILQ_FOREACH(s, &p->selectors, node)
if (s->id == id)
return s;
return NULL;
}
static int
selector_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_selector_params *params,
struct header **header)
{
struct header *h0 = NULL;
struct field *hf, *mf;
uint32_t i;
/* Return if no selector fields. */
if (!params->n_selector_fields || !params->selector_field_names)
return -EINVAL;
/* Check that all the selector fields either belong to the same header
* or are all meta-data fields.
*/
hf = header_field_parse(p, params->selector_field_names[0], &h0);
mf = metadata_field_parse(p, params->selector_field_names[0]);
if (!hf && !mf)
return -EINVAL;
for (i = 1; i < params->n_selector_fields; i++)
if (h0) {
struct header *h;
hf = header_field_parse(p, params->selector_field_names[i], &h);
if (!hf || (h->id != h0->id))
return -EINVAL;
} else {
mf = metadata_field_parse(p, params->selector_field_names[i]);
if (!mf)
return -EINVAL;
}
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
uint32_t j;
for (j = i + 1; j < params->n_selector_fields; j++)
if (!strcmp(params->selector_field_names[j], field_name))
return -EINVAL;
}
/* Return. */
if (header)
*header = h0;
return 0;
}
int
rte_swx_pipeline_selector_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_selector_params *params)
{
struct selector *s;
struct header *selector_header = NULL;
struct field *group_id_field, *member_id_field;
uint32_t i;
int status = 0;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
CHECK(!selector_find(p, name), EEXIST);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
CHECK(!learner_find(p, name), EEXIST);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
CHECK(params, EINVAL);
CHECK_NAME(params->group_id_field_name, EINVAL);
group_id_field = metadata_field_parse(p, params->group_id_field_name);
CHECK(group_id_field, EINVAL);
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
CHECK_NAME(field_name, EINVAL);
}
status = selector_fields_check(p, params, &selector_header);
if (status)
return status;
CHECK_NAME(params->member_id_field_name, EINVAL);
member_id_field = metadata_field_parse(p, params->member_id_field_name);
CHECK(member_id_field, EINVAL);
CHECK(params->n_groups_max, EINVAL);
CHECK(params->n_members_per_group_max, EINVAL);
/* Memory allocation. */
s = calloc(1, sizeof(struct selector));
if (!s) {
status = -ENOMEM;
goto error;
}
s->selector_fields = calloc(params->n_selector_fields, sizeof(struct field *));
if (!s->selector_fields) {
status = -ENOMEM;
goto error;
}
/* Node initialization. */
strcpy(s->name, name);
s->group_id_field = group_id_field;
for (i = 0; i < params->n_selector_fields; i++) {
const char *field_name = params->selector_field_names[i];
s->selector_fields[i] = selector_header ?
header_field_parse(p, field_name, NULL) :
metadata_field_parse(p, field_name);
}
s->n_selector_fields = params->n_selector_fields;
s->selector_header = selector_header;
s->member_id_field = member_id_field;
s->n_groups_max = params->n_groups_max;
s->n_members_per_group_max = params->n_members_per_group_max;
s->id = p->n_selectors;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->selectors, s, node);
p->n_selectors++;
return 0;
error:
if (!s)
return status;
free(s->selector_fields);
free(s);
return status;
}
static void
selector_params_free(struct rte_swx_table_selector_params *params)
{
if (!params)
return;
free(params->selector_mask);
free(params);
}
static struct rte_swx_table_selector_params *
selector_table_params_get(struct selector *s)
{
struct rte_swx_table_selector_params *params = NULL;
struct field *first, *last;
uint32_t i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_selector_params));
if (!params)
goto error;
/* Group ID. */
params->group_id_offset = s->group_id_field->offset / 8;
/* Find first (smallest offset) and last (biggest offset) selector fields. */
first = s->selector_fields[0];
last = s->selector_fields[0];
for (i = 0; i < s->n_selector_fields; i++) {
struct field *f = s->selector_fields[i];
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Selector offset and size. */
params->selector_offset = first->offset / 8;
params->selector_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
params->selector_mask = calloc(1, params->selector_size);
if (!params->selector_mask)
goto error;
/* Selector mask. */
for (i = 0; i < s->n_selector_fields; i++) {
struct field *f = s->selector_fields[i];
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&params->selector_mask[start], 0xFF, size);
}
/* Member ID. */
params->member_id_offset = s->member_id_field->offset / 8;
/* Maximum number of groups. */
params->n_groups_max = s->n_groups_max;
/* Maximum number of members per group. */
params->n_members_per_group_max = s->n_members_per_group_max;
return params;
error:
selector_params_free(params);
return NULL;
}
static void
selector_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->selectors)
continue;
for (j = 0; j < p->n_selectors; j++) {
struct selector_runtime *r = &t->selectors[j];
free(r->mailbox);
}
free(t->selectors);
t->selectors = NULL;
}
free(p->selector_stats);
p->selector_stats = NULL;
}
static int
selector_build(struct rte_swx_pipeline *p)
{
uint32_t i;
int status = 0;
/* Per pipeline: selector statistics. */
p->selector_stats = calloc(p->n_selectors, sizeof(struct selector_statistics));
if (!p->selector_stats) {
status = -ENOMEM;
goto error;
}
/* Per thread: selector run-time. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct selector *s;
t->selectors = calloc(p->n_selectors, sizeof(struct selector_runtime));
if (!t->selectors) {
status = -ENOMEM;
goto error;
}
TAILQ_FOREACH(s, &p->selectors, node) {
struct selector_runtime *r = &t->selectors[s->id];
uint64_t size;
/* r->mailbox. */
size = rte_swx_table_selector_mailbox_size_get();
if (size) {
r->mailbox = calloc(1, size);
if (!r->mailbox) {
status = -ENOMEM;
goto error;
}
}
/* r->group_id_buffer. */
r->group_id_buffer = &t->structs[p->metadata_struct_id];
/* r->selector_buffer. */
r->selector_buffer = s->selector_header ?
&t->structs[s->selector_header->struct_id] :
&t->structs[p->metadata_struct_id];
/* r->member_id_buffer. */
r->member_id_buffer = &t->structs[p->metadata_struct_id];
}
}
return 0;
error:
selector_build_free(p);
return status;
}
static void
selector_free(struct rte_swx_pipeline *p)
{
selector_build_free(p);
/* Selector tables. */
for ( ; ; ) {
struct selector *elem;
elem = TAILQ_FIRST(&p->selectors);
if (!elem)
break;
TAILQ_REMOVE(&p->selectors, elem, node);
free(elem->selector_fields);
free(elem);
}
}
/*
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
* Learner table.
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
*/
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static struct learner *
learner_find(struct rte_swx_pipeline *p, const char *name)
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
{
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
struct learner *l;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
TAILQ_FOREACH(l, &p->learners, node)
if (!strcmp(l->name, name))
return l;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return NULL;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static struct learner *
learner_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct learner *l = NULL;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
TAILQ_FOREACH(l, &p->learners, node)
if (l->id == id)
return l;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return NULL;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static int
learner_match_fields_check(struct rte_swx_pipeline *p,
struct rte_swx_pipeline_learner_params *params,
struct header **header)
{
struct header *h0 = NULL;
struct field *hf, *mf;
uint32_t i;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Return if no match fields. */
if (!params->n_fields || !params->field_names)
return -EINVAL;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Check that all the match fields either belong to the same header
* or are all meta-data fields.
*/
hf = header_field_parse(p, params->field_names[0], &h0);
mf = metadata_field_parse(p, params->field_names[0]);
if (!hf && !mf)
return -EINVAL;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
for (i = 1; i < params->n_fields; i++)
if (h0) {
struct header *h;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
hf = header_field_parse(p, params->field_names[i], &h);
if (!hf || (h->id != h0->id))
return -EINVAL;
} else {
mf = metadata_field_parse(p, params->field_names[i]);
if (!mf)
return -EINVAL;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Check that there are no duplicated match fields. */
for (i = 0; i < params->n_fields; i++) {
const char *field_name = params->field_names[i];
uint32_t j;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
for (j = i + 1; j < params->n_fields; j++)
if (!strcmp(params->field_names[j], field_name))
return -EINVAL;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Return. */
if (header)
*header = h0;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
return 0;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
static int
learner_action_args_check(struct rte_swx_pipeline *p, struct action *a, const char *mf_name)
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
{
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
struct struct_type *mst = p->metadata_st, *ast = a->st;
struct field *mf, *af;
uint32_t mf_pos, i;
if (!ast) {
if (mf_name)
return -EINVAL;
return 0;
}
/* Check that mf_name is the name of a valid meta-data field. */
CHECK_NAME(mf_name, EINVAL);
mf = metadata_field_parse(p, mf_name);
CHECK(mf, EINVAL);
/* Check that there are enough meta-data fields, starting with the mf_name field, to cover
* all the action arguments.
*/
mf_pos = mf - mst->fields;
CHECK(mst->n_fields - mf_pos >= ast->n_fields, EINVAL);
/* Check that the size of each of the identified meta-data fields matches exactly the size
* of the corresponding action argument.
*/
for (i = 0; i < ast->n_fields; i++) {
mf = &mst->fields[mf_pos + i];
af = &ast->fields[i];
CHECK(mf->n_bits == af->n_bits, EINVAL);
}
return 0;
}
static int
learner_action_learning_check(struct rte_swx_pipeline *p,
struct action *action,
const char **action_names,
uint32_t n_actions)
{
uint32_t i;
/* For each "learn" instruction of the current action, check that the learned action (i.e.
* the action passed as argument to the "learn" instruction) is also enabled for the
* current learner table.
*/
for (i = 0; i < action->n_instructions; i++) {
struct instruction *instr = &action->instructions[i];
uint32_t found = 0, j;
if (instr->type != INSTR_LEARNER_LEARN)
continue;
for (j = 0; j < n_actions; j++) {
struct action *a;
a = action_find(p, action_names[j]);
if (!a)
return -EINVAL;
if (a->id == instr->learn.action_id)
found = 1;
}
if (!found)
return -EINVAL;
}
return 0;
}
int
rte_swx_pipeline_learner_config(struct rte_swx_pipeline *p,
const char *name,
struct rte_swx_pipeline_learner_params *params,
uint32_t size,
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
uint32_t *timeout,
uint32_t n_timeouts)
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
{
struct learner *l = NULL;
struct action *default_action;
struct header *header = NULL;
uint32_t action_data_size_max = 0, i;
int status = 0;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!table_find(p, name), EEXIST);
CHECK(!selector_find(p, name), EEXIST);
CHECK(!learner_find(p, name), EEXIST);
CHECK(params, EINVAL);
/* Match checks. */
status = learner_match_fields_check(p, params, &header);
if (status)
return status;
/* Action checks. */
CHECK(params->n_actions, EINVAL);
CHECK(params->action_names, EINVAL);
for (i = 0; i < params->n_actions; i++) {
const char *action_name = params->action_names[i];
struct action *a;
uint32_t action_data_size;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
CHECK_NAME(action_name, EINVAL);
a = action_find(p, action_name);
CHECK(a, EINVAL);
status = learner_action_learning_check(p,
a,
params->action_names,
params->n_actions);
if (status)
return status;
action_data_size = a->st ? a->st->n_bits / 8 : 0;
if (action_data_size > action_data_size_max)
action_data_size_max = action_data_size;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
CHECK(action_is_for_table_entries || action_is_for_default_entry, EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
}
CHECK_NAME(params->default_action_name, EINVAL);
for (i = 0; i < p->n_actions; i++)
if (!strcmp(params->action_names[i],
params->default_action_name))
break;
CHECK(i < params->n_actions, EINVAL);
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
CHECK(!params->action_is_for_default_entry || params->action_is_for_default_entry[i],
EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
default_action = action_find(p, params->default_action_name);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
CHECK((default_action->st && params->default_action_args) || !params->default_action_args,
EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Any other checks. */
CHECK(size, EINVAL);
CHECK(timeout, EINVAL);
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
CHECK(n_timeouts && (n_timeouts < RTE_SWX_TABLE_LEARNER_N_KEY_TIMEOUTS_MAX), EINVAL);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Memory allocation. */
l = calloc(1, sizeof(struct learner));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l) {
status = -ENOMEM;
goto error;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->fields = calloc(params->n_fields, sizeof(struct field *));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l->fields) {
status = -ENOMEM;
goto error;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->actions = calloc(params->n_actions, sizeof(struct action *));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l->actions) {
status = -ENOMEM;
goto error;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
if (action_data_size_max) {
l->default_action_data = calloc(1, action_data_size_max);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l->default_action_data) {
status = -ENOMEM;
goto error;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
l->action_is_for_table_entries = calloc(params->n_actions, sizeof(int));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l->action_is_for_table_entries) {
status = -ENOMEM;
goto error;
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
l->action_is_for_default_entry = calloc(params->n_actions, sizeof(int));
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (!l->action_is_for_default_entry) {
status = -ENOMEM;
goto error;
}
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Node initialization. */
strcpy(l->name, name);
for (i = 0; i < params->n_fields; i++) {
const char *field_name = params->field_names[i];
l->fields[i] = header ?
header_field_parse(p, field_name, NULL) :
metadata_field_parse(p, field_name);
}
l->n_fields = params->n_fields;
l->header = header;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
for (i = 0; i < params->n_actions; i++) {
int action_is_for_table_entries = 1, action_is_for_default_entry = 1;
if (params->action_is_for_table_entries)
action_is_for_table_entries = params->action_is_for_table_entries[i];
if (params->action_is_for_default_entry)
action_is_for_default_entry = params->action_is_for_default_entry[i];
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->actions[i] = action_find(p, params->action_names[i]);
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
l->action_is_for_table_entries[i] = action_is_for_table_entries;
l->action_is_for_default_entry[i] = action_is_for_default_entry;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->default_action = default_action;
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
if (default_action->st) {
status = action_args_parse(default_action,
params->default_action_args,
l->default_action_data);
if (status)
goto error;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->n_actions = params->n_actions;
l->default_action_is_const = params->default_action_is_const;
l->action_data_size_max = action_data_size_max;
l->size = size;
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
for (i = 0; i < n_timeouts; i++)
l->timeout[i] = timeout[i];
l->n_timeouts = n_timeouts;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
l->id = p->n_learners;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->learners, l, node);
p->n_learners++;
return 0;
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
error:
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
if (!l)
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
return status;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
free(l->action_is_for_default_entry);
free(l->action_is_for_table_entries);
free(l->default_action_data);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
free(l->actions);
free(l->fields);
free(l);
pipeline: support default action arguments Add support for arguments to the default action of regular and learner tables at initialization time. Until now, only default actions with no arguments were accepted in the .spec file. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2022-04-11 18:21:08 +00:00
return status;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
}
static void
learner_params_free(struct rte_swx_table_learner_params *params)
{
if (!params)
return;
free(params->key_mask0);
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
free(params->key_timeout);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
free(params);
}
static struct rte_swx_table_learner_params *
learner_params_get(struct learner *l)
{
struct rte_swx_table_learner_params *params = NULL;
struct field *first, *last;
uint32_t i;
/* Memory allocation. */
params = calloc(1, sizeof(struct rte_swx_table_learner_params));
if (!params)
goto error;
/* Find first (smallest offset) and last (biggest offset) match fields. */
first = l->fields[0];
last = l->fields[0];
for (i = 0; i < l->n_fields; i++) {
struct field *f = l->fields[i];
if (f->offset < first->offset)
first = f;
if (f->offset > last->offset)
last = f;
}
/* Key offset and size. */
params->key_offset = first->offset / 8;
params->key_size = (last->offset + last->n_bits - first->offset) / 8;
/* Memory allocation. */
params->key_mask0 = calloc(1, params->key_size);
if (!params->key_mask0)
goto error;
/* Key mask. */
for (i = 0; i < l->n_fields; i++) {
struct field *f = l->fields[i];
uint32_t start = (f->offset - first->offset) / 8;
size_t size = f->n_bits / 8;
memset(&params->key_mask0[start], 0xFF, size);
}
/* Action data size. */
params->action_data_size = l->action_data_size_max;
/* Maximum number of keys. */
params->n_keys_max = l->size;
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
/* Memory allocation. */
params->key_timeout = calloc(l->n_timeouts, sizeof(uint32_t));
if (!params->key_timeout)
goto error;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
/* Timeout. */
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
for (i = 0; i < l->n_timeouts; i++)
params->key_timeout[i] = l->timeout[i];
params->n_key_timeouts = l->n_timeouts;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return params;
error:
learner_params_free(params);
return NULL;
}
static void
learner_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
uint32_t j;
if (!t->learners)
continue;
for (j = 0; j < p->n_learners; j++) {
struct learner_runtime *r = &t->learners[j];
free(r->mailbox);
}
free(t->learners);
t->learners = NULL;
}
if (p->learner_stats) {
for (i = 0; i < p->n_learners; i++)
free(p->learner_stats[i].n_pkts_action);
free(p->learner_stats);
}
}
static int
learner_build(struct rte_swx_pipeline *p)
{
uint32_t i;
int status = 0;
/* Per pipeline: learner statistics. */
p->learner_stats = calloc(p->n_learners, sizeof(struct learner_statistics));
CHECK(p->learner_stats, ENOMEM);
for (i = 0; i < p->n_learners; i++) {
p->learner_stats[i].n_pkts_action = calloc(p->n_actions, sizeof(uint64_t));
CHECK(p->learner_stats[i].n_pkts_action, ENOMEM);
}
/* Per thread: learner run-time. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
struct learner *l;
t->learners = calloc(p->n_learners, sizeof(struct learner_runtime));
if (!t->learners) {
status = -ENOMEM;
goto error;
}
TAILQ_FOREACH(l, &p->learners, node) {
struct learner_runtime *r = &t->learners[l->id];
uint64_t size;
/* r->mailbox. */
size = rte_swx_table_learner_mailbox_size_get();
if (size) {
r->mailbox = calloc(1, size);
if (!r->mailbox) {
status = -ENOMEM;
goto error;
}
}
/* r->key. */
r->key = l->header ?
&t->structs[l->header->struct_id] :
&t->structs[p->metadata_struct_id];
}
}
return 0;
error:
learner_build_free(p);
return status;
}
static void
learner_free(struct rte_swx_pipeline *p)
{
learner_build_free(p);
/* Learner tables. */
for ( ; ; ) {
struct learner *l;
l = TAILQ_FIRST(&p->learners);
if (!l)
break;
TAILQ_REMOVE(&p->learners, l, node);
free(l->fields);
free(l->actions);
free(l->default_action_data);
free(l);
}
}
/*
* Table state.
*/
static int
table_state_build(struct rte_swx_pipeline *p)
{
struct table *table;
struct selector *s;
struct learner *l;
pipeline: fix table state memory allocation The regular tables, selector tables and learner tables are all sharing the table state array. The locations in this array were computed incorrectly, leading to memory corruption issues. Fixes: 4f59d3726147 ("pipeline: support learner tables") Cc: stable@dpdk.org Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Harshad Narayane <harshad.suresh.narayane@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com> Signed-off-by: Venkata Suresh Kumar P <venkata.suresh.kumar.p@intel.com>
2022-02-10 19:45:08 +00:00
p->table_state = calloc(p->n_tables + p->n_selectors + p->n_learners,
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
sizeof(struct rte_swx_table_state));
CHECK(p->table_state, ENOMEM);
TAILQ_FOREACH(table, &p->tables, node) {
struct rte_swx_table_state *ts = &p->table_state[table->id];
if (table->type) {
struct rte_swx_table_params *params;
/* ts->obj. */
params = table_params_get(table);
CHECK(params, ENOMEM);
ts->obj = table->type->ops.create(params,
NULL,
table->args,
p->numa_node);
table_params_free(params);
CHECK(ts->obj, ENODEV);
}
/* ts->default_action_data. */
if (table->action_data_size_max) {
ts->default_action_data =
malloc(table->action_data_size_max);
CHECK(ts->default_action_data, ENOMEM);
memcpy(ts->default_action_data,
table->default_action_data,
table->action_data_size_max);
}
/* ts->default_action_id. */
ts->default_action_id = table->default_action->id;
}
TAILQ_FOREACH(s, &p->selectors, node) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + s->id];
struct rte_swx_table_selector_params *params;
/* ts->obj. */
params = selector_table_params_get(s);
CHECK(params, ENOMEM);
ts->obj = rte_swx_table_selector_create(params, NULL, p->numa_node);
selector_params_free(params);
CHECK(ts->obj, ENODEV);
}
TAILQ_FOREACH(l, &p->learners, node) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables +
p->n_selectors + l->id];
struct rte_swx_table_learner_params *params;
/* ts->obj. */
params = learner_params_get(l);
CHECK(params, ENOMEM);
ts->obj = rte_swx_table_learner_create(params, p->numa_node);
learner_params_free(params);
CHECK(ts->obj, ENODEV);
/* ts->default_action_data. */
if (l->action_data_size_max) {
ts->default_action_data = malloc(l->action_data_size_max);
CHECK(ts->default_action_data, ENOMEM);
memcpy(ts->default_action_data,
l->default_action_data,
l->action_data_size_max);
}
/* ts->default_action_id. */
ts->default_action_id = l->default_action->id;
}
return 0;
}
static void
table_state_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
if (!p->table_state)
return;
for (i = 0; i < p->n_tables; i++) {
struct rte_swx_table_state *ts = &p->table_state[i];
struct table *table = table_find_by_id(p, i);
/* ts->obj. */
if (table->type && ts->obj)
table->type->ops.free(ts->obj);
/* ts->default_action_data. */
free(ts->default_action_data);
}
for (i = 0; i < p->n_selectors; i++) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + i];
/* ts->obj. */
if (ts->obj)
rte_swx_table_selector_free(ts->obj);
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
for (i = 0; i < p->n_learners; i++) {
struct rte_swx_table_state *ts = &p->table_state[p->n_tables + p->n_selectors + i];
/* ts->obj. */
if (ts->obj)
rte_swx_table_learner_free(ts->obj);
/* ts->default_action_data. */
free(ts->default_action_data);
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
free(p->table_state);
p->table_state = NULL;
}
static void
table_state_free(struct rte_swx_pipeline *p)
{
table_state_build_free(p);
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
/*
* Register array.
*/
static struct regarray *
regarray_find(struct rte_swx_pipeline *p, const char *name)
{
struct regarray *elem;
TAILQ_FOREACH(elem, &p->regarrays, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct regarray *
regarray_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct regarray *elem = NULL;
TAILQ_FOREACH(elem, &p->regarrays, node)
if (elem->id == id)
return elem;
return NULL;
}
int
rte_swx_pipeline_regarray_config(struct rte_swx_pipeline *p,
const char *name,
uint32_t size,
uint64_t init_val)
{
struct regarray *r;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!regarray_find(p, name), EEXIST);
CHECK(size, EINVAL);
size = rte_align32pow2(size);
/* Memory allocation. */
r = calloc(1, sizeof(struct regarray));
CHECK(r, ENOMEM);
/* Node initialization. */
strcpy(r->name, name);
r->init_val = init_val;
r->size = size;
r->id = p->n_regarrays;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->regarrays, r, node);
p->n_regarrays++;
return 0;
}
static int
regarray_build(struct rte_swx_pipeline *p)
{
struct regarray *regarray;
if (!p->n_regarrays)
return 0;
p->regarray_runtime = calloc(p->n_regarrays, sizeof(struct regarray_runtime));
CHECK(p->regarray_runtime, ENOMEM);
TAILQ_FOREACH(regarray, &p->regarrays, node) {
struct regarray_runtime *r = &p->regarray_runtime[regarray->id];
uint32_t i;
r->regarray = env_malloc(regarray->size * sizeof(uint64_t),
RTE_CACHE_LINE_SIZE,
p->numa_node);
CHECK(r->regarray, ENOMEM);
if (regarray->init_val)
for (i = 0; i < regarray->size; i++)
r->regarray[i] = regarray->init_val;
r->size_mask = regarray->size - 1;
}
return 0;
}
static void
regarray_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
if (!p->regarray_runtime)
return;
for (i = 0; i < p->n_regarrays; i++) {
struct regarray *regarray = regarray_find_by_id(p, i);
struct regarray_runtime *r = &p->regarray_runtime[i];
env_free(r->regarray, regarray->size * sizeof(uint64_t));
}
free(p->regarray_runtime);
p->regarray_runtime = NULL;
}
static void
regarray_free(struct rte_swx_pipeline *p)
{
regarray_build_free(p);
for ( ; ; ) {
struct regarray *elem;
elem = TAILQ_FIRST(&p->regarrays);
if (!elem)
break;
TAILQ_REMOVE(&p->regarrays, elem, node);
free(elem);
}
}
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
/*
* Meter array.
*/
static struct meter_profile *
meter_profile_find(struct rte_swx_pipeline *p, const char *name)
{
struct meter_profile *elem;
TAILQ_FOREACH(elem, &p->meter_profiles, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct metarray *
metarray_find(struct rte_swx_pipeline *p, const char *name)
{
struct metarray *elem;
TAILQ_FOREACH(elem, &p->metarrays, node)
if (!strcmp(elem->name, name))
return elem;
return NULL;
}
static struct metarray *
metarray_find_by_id(struct rte_swx_pipeline *p, uint32_t id)
{
struct metarray *elem = NULL;
TAILQ_FOREACH(elem, &p->metarrays, node)
if (elem->id == id)
return elem;
return NULL;
}
int
rte_swx_pipeline_metarray_config(struct rte_swx_pipeline *p,
const char *name,
uint32_t size)
{
struct metarray *m;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(!metarray_find(p, name), EEXIST);
CHECK(size, EINVAL);
size = rte_align32pow2(size);
/* Memory allocation. */
m = calloc(1, sizeof(struct metarray));
CHECK(m, ENOMEM);
/* Node initialization. */
strcpy(m->name, name);
m->size = size;
m->id = p->n_metarrays;
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->metarrays, m, node);
p->n_metarrays++;
return 0;
}
struct meter_profile meter_profile_default = {
.node = {0},
.name = "",
.params = {0},
.profile = {
.cbs = 10000,
.pbs = 10000,
.cir_period = 1,
.cir_bytes_per_period = 1,
.pir_period = 1,
.pir_bytes_per_period = 1,
},
.n_users = 0,
};
static void
meter_init(struct meter *m)
{
memset(m, 0, sizeof(struct meter));
rte_meter_trtcm_config(&m->m, &meter_profile_default.profile);
m->profile = &meter_profile_default;
m->color_mask = RTE_COLOR_GREEN;
meter_profile_default.n_users++;
}
static int
metarray_build(struct rte_swx_pipeline *p)
{
struct metarray *m;
if (!p->n_metarrays)
return 0;
p->metarray_runtime = calloc(p->n_metarrays, sizeof(struct metarray_runtime));
CHECK(p->metarray_runtime, ENOMEM);
TAILQ_FOREACH(m, &p->metarrays, node) {
struct metarray_runtime *r = &p->metarray_runtime[m->id];
uint32_t i;
r->metarray = env_malloc(m->size * sizeof(struct meter),
RTE_CACHE_LINE_SIZE,
p->numa_node);
CHECK(r->metarray, ENOMEM);
for (i = 0; i < m->size; i++)
meter_init(&r->metarray[i]);
r->size_mask = m->size - 1;
}
return 0;
}
static void
metarray_build_free(struct rte_swx_pipeline *p)
{
uint32_t i;
if (!p->metarray_runtime)
return;
for (i = 0; i < p->n_metarrays; i++) {
struct metarray *m = metarray_find_by_id(p, i);
struct metarray_runtime *r = &p->metarray_runtime[i];
env_free(r->metarray, m->size * sizeof(struct meter));
}
free(p->metarray_runtime);
p->metarray_runtime = NULL;
}
static void
metarray_free(struct rte_swx_pipeline *p)
{
metarray_build_free(p);
/* Meter arrays. */
for ( ; ; ) {
struct metarray *elem;
elem = TAILQ_FIRST(&p->metarrays);
if (!elem)
break;
TAILQ_REMOVE(&p->metarrays, elem, node);
free(elem);
}
/* Meter profiles. */
for ( ; ; ) {
struct meter_profile *elem;
elem = TAILQ_FIRST(&p->meter_profiles);
if (!elem)
break;
TAILQ_REMOVE(&p->meter_profiles, elem, node);
free(elem);
}
}
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
/*
* Pipeline.
*/
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
void
rte_swx_pipeline_free(struct rte_swx_pipeline *p)
{
void *lib;
if (!p)
return;
lib = p->lib;
free(p->instruction_data);
free(p->instructions);
metarray_free(p);
regarray_free(p);
table_state_free(p);
learner_free(p);
selector_free(p);
table_free(p);
action_free(p);
instruction_table_free(p);
metadata_free(p);
header_free(p);
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
hash_func_free(p);
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
extern_func_free(p);
extern_obj_free(p);
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
mirroring_free(p);
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
port_out_free(p);
port_in_free(p);
struct_free(p);
free(p);
if (lib)
dlclose(lib);
}
static int
port_in_types_register(struct rte_swx_pipeline *p)
{
int status;
status = rte_swx_pipeline_port_in_type_register(p,
"ethdev",
&rte_swx_port_ethdev_reader_ops);
if (status)
return status;
status = rte_swx_pipeline_port_in_type_register(p,
"ring",
&rte_swx_port_ring_reader_ops);
if (status)
return status;
#ifdef RTE_PORT_PCAP
status = rte_swx_pipeline_port_in_type_register(p,
"source",
&rte_swx_port_source_ops);
if (status)
return status;
#endif
status = rte_swx_pipeline_port_in_type_register(p,
"fd",
&rte_swx_port_fd_reader_ops);
if (status)
return status;
return 0;
}
static int
port_out_types_register(struct rte_swx_pipeline *p)
{
int status;
status = rte_swx_pipeline_port_out_type_register(p,
"ethdev",
&rte_swx_port_ethdev_writer_ops);
if (status)
return status;
status = rte_swx_pipeline_port_out_type_register(p,
"ring",
&rte_swx_port_ring_writer_ops);
if (status)
return status;
status = rte_swx_pipeline_port_out_type_register(p,
"sink",
&rte_swx_port_sink_ops);
if (status)
return status;
status = rte_swx_pipeline_port_out_type_register(p,
"fd",
&rte_swx_port_fd_writer_ops);
if (status)
return status;
return 0;
}
pipeline: move table type registration to library Move the table type registration for the well known table types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:53 +00:00
static int
table_types_register(struct rte_swx_pipeline *p)
{
int status;
status = rte_swx_pipeline_table_type_register(p,
"exact",
RTE_SWX_TABLE_MATCH_EXACT,
&rte_swx_table_exact_match_ops);
if (status)
return status;
status = rte_swx_pipeline_table_type_register(p,
"wildcard",
RTE_SWX_TABLE_MATCH_WILDCARD,
&rte_swx_table_wildcard_match_ops);
if (status)
return status;
return 0;
}
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
static int
hash_funcs_register(struct rte_swx_pipeline *p)
{
int status;
status = rte_swx_pipeline_hash_func_register(p, "jhash", rte_jhash);
if (status)
return status;
status = rte_swx_pipeline_hash_func_register(p, "crc32", rte_hash_crc);
if (status)
return status;
return 0;
}
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
int
rte_swx_pipeline_config(struct rte_swx_pipeline **p, int numa_node)
{
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
struct rte_swx_pipeline *pipeline = NULL;
int status = 0;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
/* Check input parameters. */
CHECK(p, EINVAL);
/* Memory allocation. */
pipeline = calloc(1, sizeof(struct rte_swx_pipeline));
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
if (!pipeline) {
status = -ENOMEM;
goto error;
}
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
/* Initialization. */
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
TAILQ_INIT(&pipeline->struct_types);
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
TAILQ_INIT(&pipeline->port_in_types);
TAILQ_INIT(&pipeline->ports_in);
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
TAILQ_INIT(&pipeline->port_out_types);
TAILQ_INIT(&pipeline->ports_out);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
TAILQ_INIT(&pipeline->extern_types);
TAILQ_INIT(&pipeline->extern_objs);
TAILQ_INIT(&pipeline->extern_funcs);
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
TAILQ_INIT(&pipeline->hash_funcs);
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
TAILQ_INIT(&pipeline->headers);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
TAILQ_INIT(&pipeline->actions);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
TAILQ_INIT(&pipeline->table_types);
TAILQ_INIT(&pipeline->tables);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
TAILQ_INIT(&pipeline->selectors);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
TAILQ_INIT(&pipeline->learners);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
TAILQ_INIT(&pipeline->regarrays);
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
TAILQ_INIT(&pipeline->meter_profiles);
TAILQ_INIT(&pipeline->metarrays);
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
pipeline->n_structs = 1; /* Struct 0 is reserved for action_data. */
pipeline: fix packet mirroring configuration Fix segmentation fault due to null pointer dereferencing inside the "mirror" instruction when number of mirroring slots is set to 0. This was taking place when the "mirror" instruction was used without the mirror feature being properly configured, i.e. the API function rte_swx_pipeline_mirroring_config was not called at initialization. Fixes: dac0ecd9098 ("pipeline: support packet mirroring") Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-06-13 17:28:34 +00:00
pipeline->n_mirroring_slots = RTE_SWX_PACKET_MIRRORING_SLOTS_DEFAULT;
pipeline->n_mirroring_sessions = RTE_SWX_PACKET_MIRRORING_SESSIONS_DEFAULT;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
pipeline->numa_node = numa_node;
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
status = port_in_types_register(pipeline);
if (status)
goto error;
pipeline: add SWX pipeline instructions The SWX pipeline instructions represent the main program that defines the life of the packet. As packets go through tables that trigger action subroutines, the headers and meta-data get transformed along the way. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:36 +00:00
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
status = port_out_types_register(pipeline);
if (status)
goto error;
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
pipeline: move table type registration to library Move the table type registration for the well known table types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:53 +00:00
status = table_types_register(pipeline);
if (status)
goto error;
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
status = hash_funcs_register(pipeline);
if (status)
goto error;
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
*p = pipeline;
return 0;
pipeline: build shared object for pipeline Build the generated C file into a shared object library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Cunming Liang <cunming.liang@intel.com>
2021-09-13 16:44:42 +00:00
pipeline: move port type registration to library Move the port type registration for the well known port types from the application to the pipeline library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:52 +00:00
error:
rte_swx_pipeline_free(pipeline);
return status;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
}
pipeline: add SWX pipeline instructions The SWX pipeline instructions represent the main program that defines the life of the packet. As packets go through tables that trigger action subroutines, the headers and meta-data get transformed along the way. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:36 +00:00
int
rte_swx_pipeline_instructions_config(struct rte_swx_pipeline *p,
const char **instructions,
uint32_t n_instructions)
{
int err;
uint32_t i;
err = instruction_config(p, NULL, instructions, n_instructions);
if (err)
return err;
/* Thread instruction pointer reset. */
for (i = 0; i < RTE_SWX_PIPELINE_THREADS_MAX; i++) {
struct thread *t = &p->threads[i];
thread_ip_reset(p, t);
}
return 0;
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
static int
pipeline_compile(struct rte_swx_pipeline *p);
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
int
rte_swx_pipeline_build(struct rte_swx_pipeline *p)
{
pipeline: add drop port for each pipeline An additional output port is now implicitly created for every pipeline to serve as the packet drop port. Up to now, the drop port had to be explicitly created for each pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:54 +00:00
struct rte_swx_port_sink_params drop_port_params = {
.file_name = NULL,
};
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
int status;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
CHECK(p, EINVAL);
CHECK(p->build_done == 0, EEXIST);
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
status = port_in_build(p);
if (status)
goto error;
pipeline: add drop port for each pipeline An additional output port is now implicitly created for every pipeline to serve as the packet drop port. Up to now, the drop port had to be explicitly created for each pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:54 +00:00
/* Drop port. */
status = rte_swx_pipeline_port_out_config(p,
p->n_ports_out,
"sink",
&drop_port_params);
if (status)
goto error;
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
status = port_out_build(p);
if (status)
goto error;
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
status = mirroring_build(p);
if (status)
goto error;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
status = struct_build(p);
if (status)
goto error;
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
status = extern_obj_build(p);
if (status)
goto error;
status = extern_func_build(p);
if (status)
goto error;
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
status = hash_func_build(p);
if (status)
goto error;
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
status = header_build(p);
if (status)
goto error;
status = metadata_build(p);
if (status)
goto error;
pipeline: introduce custom instructions For better performance, the option to create custom instructions when the program is translated and add them on-the-fly to the pipeline is now provided. Multiple regular instructions can now be consolidated into a single C function optimized by the C compiler directly. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:37 +00:00
status = instruction_table_build(p);
if (status)
goto error;
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
status = action_build(p);
if (status)
goto error;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
status = table_build(p);
if (status)
goto error;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
status = selector_build(p);
if (status)
goto error;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
status = learner_build(p);
if (status)
goto error;
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
status = table_state_build(p);
if (status)
goto error;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
status = regarray_build(p);
if (status)
goto error;
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
status = metarray_build(p);
if (status)
goto error;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
p->build_done = 1;
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
pipeline_compile(p);
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
return 0;
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
error:
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
metarray_build_free(p);
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
regarray_build_free(p);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
table_state_build_free(p);
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
learner_build_free(p);
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
selector_build_free(p);
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
table_build_free(p);
pipeline: add SWX pipeline action Add SWX actions that are dynamically-defined through instructions as opposed to pre-defined. The actions are subroutines of the pipeline program that triggered by table lookup. The input arguments are the action data from the table entry (format defined by struct), the headers and meta-data are in/out. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:34 +00:00
action_build_free(p);
pipeline: introduce custom instructions For better performance, the option to create custom instructions when the program is translated and add them on-the-fly to the pipeline is now provided. Multiple regular instructions can now be consolidated into a single C function optimized by the C compiler directly. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:37 +00:00
instruction_table_build_free(p);
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
metadata_build_free(p);
header_build_free(p);
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
hash_func_build_free(p);
pipeline: add SWX extern objects and funcs Add extern objects and functions to plug into the SWX pipeline any functionality that cannot be efficiently implemented with existing instructions, e.g. special checksum/ECC, crypto, meters, stats arrays, heuristics, etc. In/out arguments are passed through mailbox with format defined by struct. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:33 +00:00
extern_func_build_free(p);
extern_obj_build_free(p);
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
mirroring_build_free(p);
pipeline: add SWX pipeline output port Add output ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The TX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:31 +00:00
port_out_build_free(p);
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
port_in_build_free(p);
pipeline: add SWX headers and meta-data Add support for dynamically-defined packet headers and meta-data to the SWX pipeline. The header and meta-data format are defined by the struct type they instantiate. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:32 +00:00
struct_build_free(p);
pipeline: add SWX pipeline input port Add input ports to the newly introduced SWX pipeline type. Each port instantiates a port type that defines the port operations, e.g. ethdev port, PCAP port, etc. The RX interface is single packet, with packet batching internally for performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:30 +00:00
return status;
pipeline: add new SWX pipeline type Add new improved Software Switch (SWX) pipeline type that supports dynamically-defined packet headers, meta-data, actions and pipelines. Actions and pipelines are defined through instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:29 +00:00
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
pipeline: add SWX Rx and extract instructions Add packet reception and header extraction instructions. The Rx must be the first pipeline instruction. Each extracted header is logically removed from the packet, then it can be read/written by instructions, emitted into the outgoing packet or discarded. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:37 +00:00
void
rte_swx_pipeline_run(struct rte_swx_pipeline *p, uint32_t n_instructions)
{
uint32_t i;
for (i = 0; i < n_instructions; i++)
instr_exec(p);
}
pipeline: add SWX pipeline flush Flush the packets currently buffered by the SWX pipeline output ports. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:58 +00:00
void
rte_swx_pipeline_flush(struct rte_swx_pipeline *p)
{
uint32_t i;
for (i = 0; i < p->n_ports_out; i++) {
struct port_out_runtime *port = &p->out[i];
if (port->flush)
port->flush(port->obj);
}
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
/*
* Control.
*/
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
int
rte_swx_ctl_pipeline_info_get(struct rte_swx_pipeline *p,
struct rte_swx_ctl_pipeline_info *pipeline)
{
struct action *action;
struct table *table;
uint32_t n_actions = 0, n_tables = 0;
if (!p || !pipeline)
return -EINVAL;
TAILQ_FOREACH(action, &p->actions, node)
n_actions++;
TAILQ_FOREACH(table, &p->tables, node)
n_tables++;
pipeline->n_ports_in = p->n_ports_in;
pipeline->n_ports_out = p->n_ports_out;
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
pipeline->n_mirroring_slots = p->n_mirroring_slots;
pipeline->n_mirroring_sessions = p->n_mirroring_sessions;
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
pipeline->n_actions = n_actions;
pipeline->n_tables = n_tables;
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
pipeline->n_selectors = p->n_selectors;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
pipeline->n_learners = p->n_learners;
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline->n_regarrays = p->n_regarrays;
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
pipeline->n_metarrays = p->n_metarrays;
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
return 0;
}
int
rte_swx_ctl_pipeline_numa_node_get(struct rte_swx_pipeline *p, int *numa_node)
{
if (!p || !numa_node)
return -EINVAL;
*numa_node = p->numa_node;
return 0;
}
int
rte_swx_ctl_action_info_get(struct rte_swx_pipeline *p,
uint32_t action_id,
struct rte_swx_ctl_action_info *action)
{
struct action *a = NULL;
if (!p || (action_id >= p->n_actions) || !action)
return -EINVAL;
a = action_find_by_id(p, action_id);
if (!a)
return -EINVAL;
strcpy(action->name, a->name);
action->n_args = a->st ? a->st->n_fields : 0;
return 0;
}
int
rte_swx_ctl_action_arg_info_get(struct rte_swx_pipeline *p,
uint32_t action_id,
uint32_t action_arg_id,
struct rte_swx_ctl_action_arg_info *action_arg)
{
struct action *a = NULL;
struct field *arg = NULL;
if (!p || (action_id >= p->n_actions) || !action_arg)
return -EINVAL;
a = action_find_by_id(p, action_id);
if (!a || !a->st || (action_arg_id >= a->st->n_fields))
return -EINVAL;
arg = &a->st->fields[action_arg_id];
strcpy(action_arg->name, arg->name);
action_arg->n_bits = arg->n_bits;
pipeline: auto-detect endianness of action arguments Each table entry is made up of match fields and action data, with the latter made up of the action ID and the action arguments. The approach of having the user specify explicitly the endianness of the action arguments is difficult to be picked up by P4 compilers, as the P4 compiler is generally unaware about this aspect. This commit introduces the auto-detection of the endianness of the action arguments by examining the endianness of the their destination: network byte order (NBO) when they get copied to headers and host byte order (HBO) when they get copied to packet meta-data or mailboxes. The endianness specification of each action argument as part of the rule specification, e.g. H(...) and N(...) is removed from the rule file and auto-detected based on their destination. The DMA instruction scope is made internal, so mov instructions need to be used. The pattern of transferring complete headers from table entry action args to headers is detected, and the associated set of mov instructions plus header validate is internally detected and replaced with the internal-only DMA instruction to preserve performance. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-11 23:23:38 +00:00
action_arg->is_network_byte_order = a->args_endianness[action_arg_id];
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
return 0;
}
int
rte_swx_ctl_table_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
struct rte_swx_ctl_table_info *table)
{
struct table *t = NULL;
if (!p || !table)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t)
return -EINVAL;
strcpy(table->name, t->name);
strcpy(table->args, t->args);
table->n_match_fields = t->n_fields;
table->n_actions = t->n_actions;
table->default_action_is_const = t->default_action_is_const;
table->size = t->size;
return 0;
}
int
rte_swx_ctl_table_match_field_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
uint32_t match_field_id,
struct rte_swx_ctl_table_match_field_info *match_field)
{
struct table *t;
struct match_field *f;
if (!p || (table_id >= p->n_tables) || !match_field)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t || (match_field_id >= t->n_fields))
return -EINVAL;
f = &t->fields[match_field_id];
match_field->match_type = f->match_type;
pipeline: relax table match field requirements The match fields for a given table have to be part of the same header or the metadata structure. This commit removes the requirement that the list of match fields must observe the order of fields within their structure. For example, the h.ipv4.dst_addr field can now be listed before the h.ipv4.src_addr field in a table match field list, even though within the IPv4 header the dst_addr field is present after the src_addr field. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-04-15 21:15:35 +00:00
match_field->is_header = t->header ? 1 : 0;
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
match_field->n_bits = f->field->n_bits;
match_field->offset = f->field->offset;
return 0;
}
int
rte_swx_ctl_table_action_info_get(struct rte_swx_pipeline *p,
uint32_t table_id,
uint32_t table_action_id,
struct rte_swx_ctl_table_action_info *table_action)
{
struct table *t;
if (!p || (table_id >= p->n_tables) || !table_action)
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t || (table_action_id >= t->n_actions))
return -EINVAL;
table_action->action_id = t->actions[table_action_id]->id;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
table_action->action_is_for_table_entries = t->action_is_for_table_entries[table_action_id];
table_action->action_is_for_default_entry = t->action_is_for_default_entry[table_action_id];
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
return 0;
}
int
rte_swx_ctl_table_ops_get(struct rte_swx_pipeline *p,
uint32_t table_id,
struct rte_swx_table_ops *table_ops,
int *is_stub)
{
struct table *t;
if (!p || (table_id >= p->n_tables))
return -EINVAL;
t = table_find_by_id(p, table_id);
if (!t)
return -EINVAL;
if (t->type) {
if (table_ops)
memcpy(table_ops, &t->type->ops, sizeof(*table_ops));
*is_stub = 0;
} else {
*is_stub = 1;
}
return 0;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
int
rte_swx_ctl_selector_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_selector_info *selector)
{
struct selector *s = NULL;
if (!p || !selector)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
strcpy(selector->name, s->name);
selector->n_selector_fields = s->n_selector_fields;
selector->n_groups_max = s->n_groups_max;
selector->n_members_per_group_max = s->n_members_per_group_max;
return 0;
}
int
rte_swx_ctl_selector_group_id_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = 0;
field->n_bits = s->group_id_field->n_bits;
field->offset = s->group_id_field->offset;
return 0;
}
int
rte_swx_ctl_selector_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
uint32_t selector_field_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
struct field *f;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s || (selector_field_id >= s->n_selector_fields))
return -EINVAL;
f = s->selector_fields[selector_field_id];
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = s->selector_header ? 1 : 0;
field->n_bits = f->n_bits;
field->offset = f->offset;
return 0;
}
int
rte_swx_ctl_selector_member_id_field_info_get(struct rte_swx_pipeline *p,
uint32_t selector_id,
struct rte_swx_ctl_table_match_field_info *field)
{
struct selector *s;
if (!p || (selector_id >= p->n_selectors) || !field)
return -EINVAL;
s = selector_find_by_id(p, selector_id);
if (!s)
return -EINVAL;
field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
field->is_header = 0;
field->n_bits = s->member_id_field->n_bits;
field->offset = s->member_id_field->offset;
return 0;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
int
rte_swx_ctl_learner_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
struct rte_swx_ctl_learner_info *learner)
{
struct learner *l = NULL;
if (!p || !learner)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l)
return -EINVAL;
strcpy(learner->name, l->name);
learner->n_match_fields = l->n_fields;
learner->n_actions = l->n_actions;
learner->default_action_is_const = l->default_action_is_const;
learner->size = l->size;
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
learner->n_key_timeouts = l->n_timeouts;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return 0;
}
int
rte_swx_ctl_learner_match_field_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t match_field_id,
struct rte_swx_ctl_table_match_field_info *match_field)
{
struct learner *l;
struct field *f;
if (!p || (learner_id >= p->n_learners) || !match_field)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (match_field_id >= l->n_fields))
return -EINVAL;
f = l->fields[match_field_id];
match_field->match_type = RTE_SWX_TABLE_MATCH_EXACT;
match_field->is_header = l->header ? 1 : 0;
match_field->n_bits = f->n_bits;
match_field->offset = f->offset;
return 0;
}
int
rte_swx_ctl_learner_action_info_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t learner_action_id,
struct rte_swx_ctl_table_action_info *learner_action)
{
struct learner *l;
if (!p || (learner_id >= p->n_learners) || !learner_action)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (learner_action_id >= l->n_actions))
return -EINVAL;
learner_action->action_id = l->actions[learner_action_id]->id;
pipeline: support action annotations Enable restricting the scope of an action to regular table entries or to the table default entry in order to support the P4 language tableonly or defaultonly annotations. Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-10-18 01:22:53 +00:00
learner_action->action_is_for_table_entries =
l->action_is_for_table_entries[learner_action_id];
learner_action->action_is_for_default_entry =
l->action_is_for_default_entry[learner_action_id];
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
return 0;
}
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
int
rte_swx_ctl_pipeline_learner_timeout_get(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t timeout_id,
uint32_t *timeout)
{
struct learner *l;
if (!p || (learner_id >= p->n_learners) || !timeout)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (timeout_id >= l->n_timeouts))
return -EINVAL;
*timeout = l->timeout[timeout_id];
return 0;
}
int
rte_swx_ctl_pipeline_learner_timeout_set(struct rte_swx_pipeline *p,
uint32_t learner_id,
uint32_t timeout_id,
uint32_t timeout)
{
struct learner *l;
struct rte_swx_table_state *ts;
int status;
if (!p || (learner_id >= p->n_learners) || !timeout)
return -EINVAL;
l = learner_find_by_id(p, learner_id);
if (!l || (timeout_id >= l->n_timeouts))
return -EINVAL;
if (!p->build_done)
return -EINVAL;
ts = &p->table_state[p->n_tables + p->n_selectors + l->id];
status = rte_swx_table_learner_timeout_update(ts->obj, timeout_id, timeout);
if (status)
return -EINVAL;
l->timeout[timeout_id] = timeout;
return 0;
}
pipeline: add SWX pipeline tables Add tables to the SWX pipeline. The match fields are flexibly selected from the headers and meta-data. The set of table actions is flexibly selected for each table from the set of pipeline actions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:35 +00:00
int
rte_swx_pipeline_table_state_get(struct rte_swx_pipeline *p,
struct rte_swx_table_state **table_state)
{
if (!p || !table_state || !p->build_done)
return -EINVAL;
*table_state = p->table_state;
return 0;
}
int
rte_swx_pipeline_table_state_set(struct rte_swx_pipeline *p,
struct rte_swx_table_state *table_state)
{
if (!p || !table_state || !p->build_done)
return -EINVAL;
p->table_state = table_state;
return 0;
}
pipeline: add SWX pipeline query API Query API to be used by the control plane to detect the configuration and state of the SWX pipeline and its internal objects. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2020-10-01 10:19:57 +00:00
int
rte_swx_ctl_pipeline_port_in_stats_read(struct rte_swx_pipeline *p,
uint32_t port_id,
struct rte_swx_port_in_stats *stats)
{
struct port_in *port;
if (!p || !stats)
return -EINVAL;
port = port_in_find(p, port_id);
if (!port)
return -EINVAL;
port->type->ops.stats_read(port->obj, stats);
return 0;
}
int
rte_swx_ctl_pipeline_port_out_stats_read(struct rte_swx_pipeline *p,
uint32_t port_id,
struct rte_swx_port_out_stats *stats)
{
struct port_out *port;
if (!p || !stats)
return -EINVAL;
port = port_out_find(p, port_id);
if (!port)
return -EINVAL;
port->type->ops.stats_read(port->obj, stats);
return 0;
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
int
rte_swx_ctl_pipeline_table_stats_read(struct rte_swx_pipeline *p,
const char *table_name,
struct rte_swx_table_stats *stats)
{
struct table *table;
struct table_statistics *table_stats;
if (!p || !table_name || !table_name[0] || !stats || !stats->n_pkts_action)
return -EINVAL;
table = table_find(p, table_name);
if (!table)
return -EINVAL;
table_stats = &p->table_stats[table->id];
pipeline: fix table statistics This patch fixes the memcpy function call which was incorrect and led to memory corruption for tables with more that just a few actions. Fixes: 742b0a57f50e4 ("pipeline: add table statistics to SWX") Cc: stable@dpdk.org Signed-off-by: Churchill Khangar <churchill.khangar@intel.com> Acked-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-08-02 05:32:12 +00:00
memcpy(stats->n_pkts_action,
table_stats->n_pkts_action,
pipeline: add table statistics to SWX Add support for table statistics for the SWX pipeline. For each table, we maintain a counter for lookup hit packets, one for lookup miss packets and one packet counter for each table action. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-04-16 23:46:41 +00:00
p->n_actions * sizeof(uint64_t));
stats->n_pkts_hit = table_stats->n_pkts_hit[1];
stats->n_pkts_miss = table_stats->n_pkts_hit[0];
return 0;
}
pipeline: support selector table Add pipeline-level support for selector tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-07-10 00:20:34 +00:00
int
rte_swx_ctl_pipeline_selector_stats_read(struct rte_swx_pipeline *p,
const char *selector_name,
struct rte_swx_pipeline_selector_stats *stats)
{
struct selector *s;
if (!p || !selector_name || !selector_name[0] || !stats)
return -EINVAL;
s = selector_find(p, selector_name);
if (!s)
return -EINVAL;
stats->n_pkts = p->selector_stats[s->id].n_pkts;
return 0;
}
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
int
rte_swx_ctl_pipeline_learner_stats_read(struct rte_swx_pipeline *p,
const char *learner_name,
struct rte_swx_learner_stats *stats)
{
struct learner *l;
struct learner_statistics *learner_stats;
if (!p || !learner_name || !learner_name[0] || !stats || !stats->n_pkts_action)
return -EINVAL;
l = learner_find(p, learner_name);
if (!l)
return -EINVAL;
learner_stats = &p->learner_stats[l->id];
memcpy(stats->n_pkts_action,
learner_stats->n_pkts_action,
p->n_actions * sizeof(uint64_t));
stats->n_pkts_hit = learner_stats->n_pkts_hit[1];
stats->n_pkts_miss = learner_stats->n_pkts_hit[0];
stats->n_pkts_learn_ok = learner_stats->n_pkts_learn[0];
stats->n_pkts_learn_err = learner_stats->n_pkts_learn[1];
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
stats->n_pkts_rearm = learner_stats->n_pkts_rearm;
pipeline: support learner tables Add pipeline level support for learner tables. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-20 15:01:31 +00:00
stats->n_pkts_forget = learner_stats->n_pkts_forget;
return 0;
}
pipeline: add register array to SWX Register arrays are stateful objects that can be read & modified by both the data plane and the control plane, as opposed to tables, which are read-only for data plane. One key use-case is the implementation of stats counters. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:38 +00:00
int
rte_swx_ctl_regarray_info_get(struct rte_swx_pipeline *p,
uint32_t regarray_id,
struct rte_swx_ctl_regarray_info *regarray)
{
struct regarray *r;
if (!p || !regarray)
return -EINVAL;
r = regarray_find_by_id(p, regarray_id);
if (!r)
return -EINVAL;
strcpy(regarray->name, r->name);
regarray->size = r->size;
return 0;
}
int
rte_swx_ctl_pipeline_regarray_read(struct rte_swx_pipeline *p,
const char *regarray_name,
uint32_t regarray_index,
uint64_t *value)
{
struct regarray *regarray;
struct regarray_runtime *r;
if (!p || !regarray_name || !value)
return -EINVAL;
regarray = regarray_find(p, regarray_name);
if (!regarray || (regarray_index >= regarray->size))
return -EINVAL;
r = &p->regarray_runtime[regarray->id];
*value = r->regarray[regarray_index];
return 0;
}
int
rte_swx_ctl_pipeline_regarray_write(struct rte_swx_pipeline *p,
const char *regarray_name,
uint32_t regarray_index,
uint64_t value)
{
struct regarray *regarray;
struct regarray_runtime *r;
if (!p || !regarray_name)
return -EINVAL;
regarray = regarray_find(p, regarray_name);
if (!regarray || (regarray_index >= regarray->size))
return -EINVAL;
r = &p->regarray_runtime[regarray->id];
r->regarray[regarray_index] = value;
return 0;
}
pipeline: add meter array to SWX Meter arrays are stateful objects that are updated by the data plane and configured & monitored by the control plane. The meters implement the RFC 2698 Two Rate Three Color Marker (trTCM) algorithm. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-03-16 11:40:39 +00:00
int
rte_swx_ctl_metarray_info_get(struct rte_swx_pipeline *p,
uint32_t metarray_id,
struct rte_swx_ctl_metarray_info *metarray)
{
struct metarray *m;
if (!p || !metarray)
return -EINVAL;
m = metarray_find_by_id(p, metarray_id);
if (!m)
return -EINVAL;
strcpy(metarray->name, m->name);
metarray->size = m->size;
return 0;
}
int
rte_swx_ctl_meter_profile_add(struct rte_swx_pipeline *p,
const char *name,
struct rte_meter_trtcm_params *params)
{
struct meter_profile *mp;
int status;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
CHECK(params, EINVAL);
CHECK(!meter_profile_find(p, name), EEXIST);
/* Node allocation. */
mp = calloc(1, sizeof(struct meter_profile));
CHECK(mp, ENOMEM);
/* Node initialization. */
strcpy(mp->name, name);
memcpy(&mp->params, params, sizeof(struct rte_meter_trtcm_params));
status = rte_meter_trtcm_profile_config(&mp->profile, params);
if (status) {
free(mp);
CHECK(0, EINVAL);
}
/* Node add to tailq. */
TAILQ_INSERT_TAIL(&p->meter_profiles, mp, node);
return 0;
}
int
rte_swx_ctl_meter_profile_delete(struct rte_swx_pipeline *p,
const char *name)
{
struct meter_profile *mp;
CHECK(p, EINVAL);
CHECK_NAME(name, EINVAL);
mp = meter_profile_find(p, name);
CHECK(mp, EINVAL);
CHECK(!mp->n_users, EBUSY);
/* Remove node from tailq. */
TAILQ_REMOVE(&p->meter_profiles, mp, node);
free(mp);
return 0;
}
int
rte_swx_ctl_meter_reset(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index)
{
struct meter_profile *mp_old;
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
mp_old = m->profile;
meter_init(m);
mp_old->n_users--;
return 0;
}
int
rte_swx_ctl_meter_set(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index,
const char *profile_name)
{
struct meter_profile *mp, *mp_old;
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
mp = meter_profile_find(p, profile_name);
CHECK(mp, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
mp_old = m->profile;
memset(m, 0, sizeof(struct meter));
rte_meter_trtcm_config(&m->m, &mp->profile);
m->profile = mp;
m->color_mask = RTE_COLORS;
mp->n_users++;
mp_old->n_users--;
return 0;
}
int
rte_swx_ctl_meter_stats_read(struct rte_swx_pipeline *p,
const char *metarray_name,
uint32_t metarray_index,
struct rte_swx_ctl_meter_stats *stats)
{
struct metarray *metarray;
struct metarray_runtime *metarray_runtime;
struct meter *m;
CHECK(p, EINVAL);
CHECK_NAME(metarray_name, EINVAL);
metarray = metarray_find(p, metarray_name);
CHECK(metarray, EINVAL);
CHECK(metarray_index < metarray->size, EINVAL);
CHECK(stats, EINVAL);
metarray_runtime = &p->metarray_runtime[metarray->id];
m = &metarray_runtime->metarray[metarray_index];
memcpy(stats->n_pkts, m->n_pkts, sizeof(m->n_pkts));
memcpy(stats->n_bytes, m->n_bytes, sizeof(m->n_bytes));
return 0;
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
int
rte_swx_ctl_pipeline_mirroring_session_set(struct rte_swx_pipeline *p,
uint32_t session_id,
struct rte_swx_pipeline_mirroring_session_params *params)
{
struct mirroring_session *s;
CHECK(p, EINVAL);
CHECK(p->build_done, EEXIST);
CHECK(session_id < p->n_mirroring_sessions, EINVAL);
CHECK(params, EINVAL);
CHECK(params->port_id < p->n_ports_out, EINVAL);
s = &p->mirroring_sessions[session_id];
s->port_id = params->port_id;
s->fast_clone = params->fast_clone;
s->truncation_length = params->truncation_length ? params->truncation_length : UINT32_MAX;
return 0;
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
/*
* Pipeline compilation.
*/
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
static const char *
instr_type_to_name(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX: return "INSTR_RX";
case INSTR_TX: return "INSTR_TX";
case INSTR_TX_I: return "INSTR_TX_I";
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
case INSTR_DROP: return "INSTR_DROP";
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
case INSTR_MIRROR: return "INSTR_MIRROR";
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
case INSTR_RECIRCULATE: return "INSTR_RECIRCULATE";
case INSTR_RECIRCID: return "INSTR_RECIRCID";
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
case INSTR_HDR_EXTRACT: return "INSTR_HDR_EXTRACT";
case INSTR_HDR_EXTRACT2: return "INSTR_HDR_EXTRACT2";
case INSTR_HDR_EXTRACT3: return "INSTR_HDR_EXTRACT3";
case INSTR_HDR_EXTRACT4: return "INSTR_HDR_EXTRACT4";
case INSTR_HDR_EXTRACT5: return "INSTR_HDR_EXTRACT5";
case INSTR_HDR_EXTRACT6: return "INSTR_HDR_EXTRACT6";
case INSTR_HDR_EXTRACT7: return "INSTR_HDR_EXTRACT7";
case INSTR_HDR_EXTRACT8: return "INSTR_HDR_EXTRACT8";
case INSTR_HDR_EXTRACT_M: return "INSTR_HDR_EXTRACT_M";
case INSTR_HDR_LOOKAHEAD: return "INSTR_HDR_LOOKAHEAD";
case INSTR_HDR_EMIT: return "INSTR_HDR_EMIT";
case INSTR_HDR_EMIT_TX: return "INSTR_HDR_EMIT_TX";
case INSTR_HDR_EMIT2_TX: return "INSTR_HDR_EMIT2_TX";
case INSTR_HDR_EMIT3_TX: return "INSTR_HDR_EMIT3_TX";
case INSTR_HDR_EMIT4_TX: return "INSTR_HDR_EMIT4_TX";
case INSTR_HDR_EMIT5_TX: return "INSTR_HDR_EMIT5_TX";
case INSTR_HDR_EMIT6_TX: return "INSTR_HDR_EMIT6_TX";
case INSTR_HDR_EMIT7_TX: return "INSTR_HDR_EMIT7_TX";
case INSTR_HDR_EMIT8_TX: return "INSTR_HDR_EMIT8_TX";
case INSTR_HDR_VALIDATE: return "INSTR_HDR_VALIDATE";
case INSTR_HDR_INVALIDATE: return "INSTR_HDR_INVALIDATE";
case INSTR_MOV: return "INSTR_MOV";
case INSTR_MOV_MH: return "INSTR_MOV_MH";
case INSTR_MOV_HM: return "INSTR_MOV_HM";
case INSTR_MOV_HH: return "INSTR_MOV_HH";
case INSTR_MOV_I: return "INSTR_MOV_I";
case INSTR_DMA_HT: return "INSTR_DMA_HT";
case INSTR_DMA_HT2: return "INSTR_DMA_HT2";
case INSTR_DMA_HT3: return "INSTR_DMA_HT3";
case INSTR_DMA_HT4: return "INSTR_DMA_HT4";
case INSTR_DMA_HT5: return "INSTR_DMA_HT5";
case INSTR_DMA_HT6: return "INSTR_DMA_HT6";
case INSTR_DMA_HT7: return "INSTR_DMA_HT7";
case INSTR_DMA_HT8: return "INSTR_DMA_HT8";
case INSTR_ALU_ADD: return "INSTR_ALU_ADD";
case INSTR_ALU_ADD_MH: return "INSTR_ALU_ADD_MH";
case INSTR_ALU_ADD_HM: return "INSTR_ALU_ADD_HM";
case INSTR_ALU_ADD_HH: return "INSTR_ALU_ADD_HH";
case INSTR_ALU_ADD_MI: return "INSTR_ALU_ADD_MI";
case INSTR_ALU_ADD_HI: return "INSTR_ALU_ADD_HI";
case INSTR_ALU_SUB: return "INSTR_ALU_SUB";
case INSTR_ALU_SUB_MH: return "INSTR_ALU_SUB_MH";
case INSTR_ALU_SUB_HM: return "INSTR_ALU_SUB_HM";
case INSTR_ALU_SUB_HH: return "INSTR_ALU_SUB_HH";
case INSTR_ALU_SUB_MI: return "INSTR_ALU_SUB_MI";
case INSTR_ALU_SUB_HI: return "INSTR_ALU_SUB_HI";
case INSTR_ALU_CKADD_FIELD: return "INSTR_ALU_CKADD_FIELD";
case INSTR_ALU_CKADD_STRUCT20: return "INSTR_ALU_CKADD_STRUCT20";
case INSTR_ALU_CKADD_STRUCT: return "INSTR_ALU_CKADD_STRUCT";
case INSTR_ALU_CKSUB_FIELD: return "INSTR_ALU_CKSUB_FIELD";
case INSTR_ALU_AND: return "INSTR_ALU_AND";
case INSTR_ALU_AND_MH: return "INSTR_ALU_AND_MH";
case INSTR_ALU_AND_HM: return "INSTR_ALU_AND_HM";
case INSTR_ALU_AND_HH: return "INSTR_ALU_AND_HH";
case INSTR_ALU_AND_I: return "INSTR_ALU_AND_I";
case INSTR_ALU_OR: return "INSTR_ALU_OR";
case INSTR_ALU_OR_MH: return "INSTR_ALU_OR_MH";
case INSTR_ALU_OR_HM: return "INSTR_ALU_OR_HM";
case INSTR_ALU_OR_HH: return "INSTR_ALU_OR_HH";
case INSTR_ALU_OR_I: return "INSTR_ALU_OR_I";
case INSTR_ALU_XOR: return "INSTR_ALU_XOR";
case INSTR_ALU_XOR_MH: return "INSTR_ALU_XOR_MH";
case INSTR_ALU_XOR_HM: return "INSTR_ALU_XOR_HM";
case INSTR_ALU_XOR_HH: return "INSTR_ALU_XOR_HH";
case INSTR_ALU_XOR_I: return "INSTR_ALU_XOR_I";
case INSTR_ALU_SHL: return "INSTR_ALU_SHL";
case INSTR_ALU_SHL_MH: return "INSTR_ALU_SHL_MH";
case INSTR_ALU_SHL_HM: return "INSTR_ALU_SHL_HM";
case INSTR_ALU_SHL_HH: return "INSTR_ALU_SHL_HH";
case INSTR_ALU_SHL_MI: return "INSTR_ALU_SHL_MI";
case INSTR_ALU_SHL_HI: return "INSTR_ALU_SHL_HI";
case INSTR_ALU_SHR: return "INSTR_ALU_SHR";
case INSTR_ALU_SHR_MH: return "INSTR_ALU_SHR_MH";
case INSTR_ALU_SHR_HM: return "INSTR_ALU_SHR_HM";
case INSTR_ALU_SHR_HH: return "INSTR_ALU_SHR_HH";
case INSTR_ALU_SHR_MI: return "INSTR_ALU_SHR_MI";
case INSTR_ALU_SHR_HI: return "INSTR_ALU_SHR_HI";
case INSTR_REGPREFETCH_RH: return "INSTR_REGPREFETCH_RH";
case INSTR_REGPREFETCH_RM: return "INSTR_REGPREFETCH_RM";
case INSTR_REGPREFETCH_RI: return "INSTR_REGPREFETCH_RI";
case INSTR_REGRD_HRH: return "INSTR_REGRD_HRH";
case INSTR_REGRD_HRM: return "INSTR_REGRD_HRM";
case INSTR_REGRD_HRI: return "INSTR_REGRD_HRI";
case INSTR_REGRD_MRH: return "INSTR_REGRD_MRH";
case INSTR_REGRD_MRM: return "INSTR_REGRD_MRM";
case INSTR_REGRD_MRI: return "INSTR_REGRD_MRI";
case INSTR_REGWR_RHH: return "INSTR_REGWR_RHH";
case INSTR_REGWR_RHM: return "INSTR_REGWR_RHM";
case INSTR_REGWR_RHI: return "INSTR_REGWR_RHI";
case INSTR_REGWR_RMH: return "INSTR_REGWR_RMH";
case INSTR_REGWR_RMM: return "INSTR_REGWR_RMM";
case INSTR_REGWR_RMI: return "INSTR_REGWR_RMI";
case INSTR_REGWR_RIH: return "INSTR_REGWR_RIH";
case INSTR_REGWR_RIM: return "INSTR_REGWR_RIM";
case INSTR_REGWR_RII: return "INSTR_REGWR_RII";
case INSTR_REGADD_RHH: return "INSTR_REGADD_RHH";
case INSTR_REGADD_RHM: return "INSTR_REGADD_RHM";
case INSTR_REGADD_RHI: return "INSTR_REGADD_RHI";
case INSTR_REGADD_RMH: return "INSTR_REGADD_RMH";
case INSTR_REGADD_RMM: return "INSTR_REGADD_RMM";
case INSTR_REGADD_RMI: return "INSTR_REGADD_RMI";
case INSTR_REGADD_RIH: return "INSTR_REGADD_RIH";
case INSTR_REGADD_RIM: return "INSTR_REGADD_RIM";
case INSTR_REGADD_RII: return "INSTR_REGADD_RII";
case INSTR_METPREFETCH_H: return "INSTR_METPREFETCH_H";
case INSTR_METPREFETCH_M: return "INSTR_METPREFETCH_M";
case INSTR_METPREFETCH_I: return "INSTR_METPREFETCH_I";
case INSTR_METER_HHM: return "INSTR_METER_HHM";
case INSTR_METER_HHI: return "INSTR_METER_HHI";
case INSTR_METER_HMM: return "INSTR_METER_HMM";
case INSTR_METER_HMI: return "INSTR_METER_HMI";
case INSTR_METER_MHM: return "INSTR_METER_MHM";
case INSTR_METER_MHI: return "INSTR_METER_MHI";
case INSTR_METER_MMM: return "INSTR_METER_MMM";
case INSTR_METER_MMI: return "INSTR_METER_MMI";
case INSTR_METER_IHM: return "INSTR_METER_IHM";
case INSTR_METER_IHI: return "INSTR_METER_IHI";
case INSTR_METER_IMM: return "INSTR_METER_IMM";
case INSTR_METER_IMI: return "INSTR_METER_IMI";
case INSTR_TABLE: return "INSTR_TABLE";
case INSTR_TABLE_AF: return "INSTR_TABLE_AF";
case INSTR_SELECTOR: return "INSTR_SELECTOR";
case INSTR_LEARNER: return "INSTR_LEARNER";
case INSTR_LEARNER_AF: return "INSTR_LEARNER_AF";
case INSTR_LEARNER_LEARN: return "INSTR_LEARNER_LEARN";
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
case INSTR_LEARNER_REARM: return "INSTR_LEARNER_REARM";
case INSTR_LEARNER_REARM_NEW: return "INSTR_LEARNER_REARM_NEW";
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
case INSTR_LEARNER_FORGET: return "INSTR_LEARNER_FORGET";
case INSTR_EXTERN_OBJ: return "INSTR_EXTERN_OBJ";
case INSTR_EXTERN_FUNC: return "INSTR_EXTERN_FUNC";
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
case INSTR_HASH_FUNC: return "INSTR_HASH_FUNC";
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
case INSTR_JMP: return "INSTR_JMP";
case INSTR_JMP_VALID: return "INSTR_JMP_VALID";
case INSTR_JMP_INVALID: return "INSTR_JMP_INVALID";
case INSTR_JMP_HIT: return "INSTR_JMP_HIT";
case INSTR_JMP_MISS: return "INSTR_JMP_MISS";
case INSTR_JMP_ACTION_HIT: return "INSTR_JMP_ACTION_HIT";
case INSTR_JMP_ACTION_MISS: return "INSTR_JMP_ACTION_MISS";
case INSTR_JMP_EQ: return "INSTR_JMP_EQ";
case INSTR_JMP_EQ_MH: return "INSTR_JMP_EQ_MH";
case INSTR_JMP_EQ_HM: return "INSTR_JMP_EQ_HM";
case INSTR_JMP_EQ_HH: return "INSTR_JMP_EQ_HH";
case INSTR_JMP_EQ_I: return "INSTR_JMP_EQ_I";
case INSTR_JMP_NEQ: return "INSTR_JMP_NEQ";
case INSTR_JMP_NEQ_MH: return "INSTR_JMP_NEQ_MH";
case INSTR_JMP_NEQ_HM: return "INSTR_JMP_NEQ_HM";
case INSTR_JMP_NEQ_HH: return "INSTR_JMP_NEQ_HH";
case INSTR_JMP_NEQ_I: return "INSTR_JMP_NEQ_I";
case INSTR_JMP_LT: return "INSTR_JMP_LT";
case INSTR_JMP_LT_MH: return "INSTR_JMP_LT_MH";
case INSTR_JMP_LT_HM: return "INSTR_JMP_LT_HM";
case INSTR_JMP_LT_HH: return "INSTR_JMP_LT_HH";
case INSTR_JMP_LT_MI: return "INSTR_JMP_LT_MI";
case INSTR_JMP_LT_HI: return "INSTR_JMP_LT_HI";
case INSTR_JMP_GT: return "INSTR_JMP_GT";
case INSTR_JMP_GT_MH: return "INSTR_JMP_GT_MH";
case INSTR_JMP_GT_HM: return "INSTR_JMP_GT_HM";
case INSTR_JMP_GT_HH: return "INSTR_JMP_GT_HH";
case INSTR_JMP_GT_MI: return "INSTR_JMP_GT_MI";
case INSTR_JMP_GT_HI: return "INSTR_JMP_GT_HI";
case INSTR_RETURN: return "INSTR_RETURN";
default: return "INSTR_UNKNOWN";
}
}
typedef void
(*instruction_export_t)(struct instruction *, FILE *);
static void
instr_io_export(struct instruction *instr, FILE *f)
{
uint32_t n_io = 0, n_io_imm = 0, n_hdrs = 0, i;
/* n_io, n_io_imm, n_hdrs. */
if (instr->type == INSTR_RX ||
instr->type == INSTR_TX ||
instr->type == INSTR_HDR_EXTRACT_M ||
(instr->type >= INSTR_HDR_EMIT_TX && instr->type <= INSTR_HDR_EMIT8_TX))
n_io = 1;
if (instr->type == INSTR_TX_I)
n_io_imm = 1;
if (instr->type >= INSTR_HDR_EXTRACT && instr->type <= INSTR_HDR_EXTRACT8)
n_hdrs = 1 + (instr->type - INSTR_HDR_EXTRACT);
if (instr->type == INSTR_HDR_EXTRACT_M ||
instr->type == INSTR_HDR_LOOKAHEAD ||
instr->type == INSTR_HDR_EMIT)
n_hdrs = 1;
if (instr->type >= INSTR_HDR_EMIT_TX && instr->type <= INSTR_HDR_EMIT8_TX)
n_hdrs = 1 + (instr->type - INSTR_HDR_EMIT_TX);
/* instr. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
/* instr.io. */
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
if (n_io || n_io_imm || n_hdrs)
fprintf(f,
"\t\t.io = {\n");
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
/* instr.io.io. */
if (n_io)
fprintf(f,
"\t\t\t.io = {\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t},\n",
instr->io.io.offset,
instr->io.io.n_bits);
if (n_io_imm)
fprintf(f,
"\t\t\t.io = {\n"
"\t\t\t\t.val = %u,\n"
"\t\t\t},\n",
instr->io.io.val);
/* instr.io.hdr. */
if (n_hdrs) {
fprintf(f,
"\t\t.hdr = {\n");
/* instr.io.hdr.header_id. */
fprintf(f,
"\t\t\t.header_id = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.header_id[i]);
fprintf(f,
"},\n");
/* instr.io.hdr.struct_id. */
fprintf(f,
"\t\t\t.struct_id = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.struct_id[i]);
fprintf(f,
"},\n");
/* instr.io.hdr.n_bytes. */
fprintf(f,
"\t\t\t.n_bytes = {");
for (i = 0; i < n_hdrs; i++)
fprintf(f,
"%u, ",
instr->io.hdr.n_bytes[i]);
fprintf(f,
"},\n");
/* instr.io.hdr - closing curly brace. */
fprintf(f,
"\t\t\t}\n,");
}
/* instr.io - closing curly brace. */
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
if (n_io || n_io_imm || n_hdrs)
fprintf(f,
"\t\t},\n");
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
/* instr - closing curly brace. */
fprintf(f,
"\t},\n");
}
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
static void
instr_mirror_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.mirror = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->mirror.dst.struct_id,
instr->mirror.dst.n_bits,
instr->mirror.dst.offset,
instr->mirror.src.struct_id,
instr->mirror.src.n_bits,
instr->mirror.src.offset);
}
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
static void
instr_recirculate_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t},\n",
instr_type_to_name(instr));
}
static void
instr_recircid_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.io = {\n"
"\t\t\t.offset = %u,\n"
"\t\t\t.n_bits = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->io.io.offset,
instr->io.io.n_bits);
}
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
static void
instr_hdr_validate_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.valid = {\n"
"\t\t\t.header_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->valid.header_id);
}
static void
instr_mov_export(struct instruction *instr, FILE *f)
{
if (instr->type != INSTR_MOV_I)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.mov = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->mov.dst.struct_id,
instr->mov.dst.n_bits,
instr->mov.dst.offset,
instr->mov.src.struct_id,
instr->mov.src.n_bits,
instr->mov.src.offset);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.mov = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.src_val = %" PRIu64 ",\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->mov.dst.struct_id,
instr->mov.dst.n_bits,
instr->mov.dst.offset,
instr->mov.src_val);
}
static void
instr_dma_ht_export(struct instruction *instr, FILE *f)
{
uint32_t n_dma = 0, i;
/* n_dma. */
n_dma = 1 + (instr->type - INSTR_DMA_HT);
/* instr. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
/* instr.dma. */
fprintf(f,
"\t\t.dma = {\n");
/* instr.dma.dst. */
fprintf(f,
"\t\t\t.dst = {\n");
/* instr.dma.dst.header_id. */
fprintf(f,
"\t\t\t\t.header_id = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.dst.header_id[i]);
fprintf(f,
"},\n");
/* instr.dma.dst.struct_id. */
fprintf(f,
"\t\t\t\t.struct_id = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.dst.struct_id[i]);
fprintf(f,
"},\n");
/* instr.dma.dst - closing curly brace. */
fprintf(f,
"\t\t\t},\n");
/* instr.dma.src. */
fprintf(f,
"\t\t\t.src = {\n");
/* instr.dma.src.offset. */
fprintf(f,
"\t\t\t\t.offset = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.src.offset[i]);
fprintf(f,
"},\n");
/* instr.dma.src - closing curly brace. */
fprintf(f,
"\t\t\t},\n");
/* instr.dma.n_bytes. */
fprintf(f,
"\t\t\t.n_bytes = {");
for (i = 0; i < n_dma; i++)
fprintf(f,
"%u, ",
instr->dma.n_bytes[i]);
fprintf(f,
"},\n");
/* instr.dma - closing curly brace. */
fprintf(f,
"\t\t},\n");
/* instr - closing curly brace. */
fprintf(f,
"\t},\n");
}
static void
instr_alu_export(struct instruction *instr, FILE *f)
{
int imm = 0;
if (instr->type == INSTR_ALU_ADD_MI ||
instr->type == INSTR_ALU_ADD_HI ||
instr->type == INSTR_ALU_SUB_MI ||
instr->type == INSTR_ALU_SUB_HI ||
instr->type == INSTR_ALU_SHL_MI ||
instr->type == INSTR_ALU_SHL_HI ||
instr->type == INSTR_ALU_SHR_MI ||
instr->type == INSTR_ALU_SHR_HI ||
instr->type == INSTR_ALU_AND_I ||
instr->type == INSTR_ALU_OR_I ||
instr->type == INSTR_ALU_XOR_I)
imm = 1;
if (!imm)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.alu = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->alu.dst.struct_id,
instr->alu.dst.n_bits,
instr->alu.dst.offset,
instr->alu.src.struct_id,
instr->alu.src.n_bits,
instr->alu.src.offset);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.alu = {\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.src_val = %" PRIu64 ",\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->alu.dst.struct_id,
instr->alu.dst.n_bits,
instr->alu.dst.offset,
instr->alu.src_val);
}
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
static void
instr_hash_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.hash_func = {\n"
"\t\t\t.hash_func_id = %u,\n"
"\t\t\t.dst = {\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t},\n"
"\t\t\t.src = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t\t.n_bytes = %u,\n"
"\t\t\t},\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->hash_func.hash_func_id,
instr->hash_func.dst.offset,
instr->hash_func.dst.n_bits,
instr->hash_func.src.struct_id,
instr->hash_func.src.offset,
instr->hash_func.src.n_bytes);
}
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
static void
instr_reg_export(struct instruction *instr __rte_unused, FILE *f __rte_unused)
{
int prefetch = 0, idx_imm = 0, src_imm = 0;
if (instr->type == INSTR_REGPREFETCH_RH ||
instr->type == INSTR_REGPREFETCH_RM ||
instr->type == INSTR_REGPREFETCH_RI)
prefetch = 1;
/* index is the 3rd operand for the regrd instruction and the 2nd
* operand for the regwr and regadd instructions.
*/
if (instr->type == INSTR_REGPREFETCH_RI ||
instr->type == INSTR_REGRD_HRI ||
instr->type == INSTR_REGRD_MRI ||
instr->type == INSTR_REGWR_RIH ||
instr->type == INSTR_REGWR_RIM ||
instr->type == INSTR_REGWR_RII ||
instr->type == INSTR_REGADD_RIH ||
instr->type == INSTR_REGADD_RIM ||
instr->type == INSTR_REGADD_RII)
idx_imm = 1;
/* src is the 3rd operand for the regwr and regadd instructions. */
if (instr->type == INSTR_REGWR_RHI ||
instr->type == INSTR_REGWR_RMI ||
instr->type == INSTR_REGWR_RII ||
instr->type == INSTR_REGADD_RHI ||
instr->type == INSTR_REGADD_RMI ||
instr->type == INSTR_REGADD_RII)
src_imm = 1;
/* instr.regarray.regarray_id. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.regarray = {\n"
"\t\t\t.regarray_id = %u,\n",
instr_type_to_name(instr),
instr->regarray.regarray_id);
/* instr.regarray.idx / instr.regarray.idx_val. */
if (!idx_imm)
fprintf(f,
"\t\t\t\t.idx = {\n"
"\t\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t\t.offset = %u,\n"
"\t\t\t\t},\n",
instr->regarray.idx.struct_id,
instr->regarray.idx.n_bits,
instr->regarray.idx.offset);
else
fprintf(f,
"\t\t\t\t.idx_val = %u,\n",
instr->regarray.idx_val);
/* instr.regarray.dstsrc / instr.regarray.dstsrc_val. */
if (!prefetch) {
if (!src_imm)
fprintf(f,
"\t\t\t\t.dstsrc = {\n"
"\t\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t\t.offset = %u,\n"
"\t\t\t\t},\n",
instr->regarray.dstsrc.struct_id,
instr->regarray.dstsrc.n_bits,
instr->regarray.dstsrc.offset);
else
fprintf(f,
"\t\t\t\t.dstsrc_val = %" PRIu64 ",\n",
instr->regarray.dstsrc_val);
}
/* instr.regarray and instr - closing curly braces. */
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_meter_export(struct instruction *instr __rte_unused, FILE *f __rte_unused)
{
int prefetch = 0, idx_imm = 0, color_in_imm = 0;
if (instr->type == INSTR_METPREFETCH_H ||
instr->type == INSTR_METPREFETCH_M ||
instr->type == INSTR_METPREFETCH_I)
prefetch = 1;
/* idx_imm. */
if (instr->type == INSTR_METPREFETCH_I ||
instr->type == INSTR_METER_IHM ||
instr->type == INSTR_METER_IHI ||
instr->type == INSTR_METER_IMM ||
instr->type == INSTR_METER_IMI)
idx_imm = 1;
/* color_in_imm. */
if (instr->type == INSTR_METER_HHI ||
instr->type == INSTR_METER_HMI ||
instr->type == INSTR_METER_MHI ||
instr->type == INSTR_METER_MMI ||
instr->type == INSTR_METER_IHI ||
instr->type == INSTR_METER_IMI)
color_in_imm = 1;
/* instr.meter.metarray_id. */
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.meter = {\n"
"\t\t\t.metarray_id = %u,\n",
instr_type_to_name(instr),
instr->meter.metarray_id);
/* instr.meter.idx / instr.meter.idx_val. */
if (!idx_imm)
fprintf(f,
"\t\t\t.idx = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.idx.struct_id,
instr->meter.idx.n_bits,
instr->meter.idx.offset);
else
fprintf(f,
"\t\t\t.idx_val = %u,\n",
instr->meter.idx_val);
if (!prefetch) {
/* instr.meter.length. */
fprintf(f,
"\t\t\t.length = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.length.struct_id,
instr->meter.length.n_bits,
instr->meter.length.offset);
/* instr.meter.color_in / instr.meter.color_in_val. */
if (!color_in_imm)
fprintf(f,
"\t\t\t.color_in = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.color_in.struct_id,
instr->meter.color_in.n_bits,
instr->meter.color_in.offset);
else
fprintf(f,
"\t\t\t.color_in_val = %u,\n",
(uint32_t)instr->meter.color_in_val);
/* instr.meter.color_out. */
fprintf(f,
"\t\t\t.color_out = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->meter.color_out.struct_id,
instr->meter.color_out.n_bits,
instr->meter.color_out.offset);
}
/* instr.meter and instr - closing curly braces. */
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_table_export(struct instruction *instr,
FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.table = {\n"
"\t\t\t.table_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->table.table_id);
}
static void
instr_learn_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.learn = {\n"
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
"\t\t\t.action_id = %u,\n"
"\t\t\t.mf_first_arg_offset = %u,\n"
"\t\t\t.mf_timeout_id_offset = %u,\n"
"\t\t\t.mf_timeout_id_n_bits = %u,\n"
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
instr->learn.action_id,
instr->learn.mf_first_arg_offset,
instr->learn.mf_timeout_id_offset,
instr->learn.mf_timeout_id_n_bits);
}
static void
instr_rearm_export(struct instruction *instr, FILE *f)
{
if (instr->type == INSTR_LEARNER_REARM)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t},\n",
instr_type_to_name(instr));
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.learn = {\n"
"\t\t\t.mf_timeout_id_offset = %u,\n"
"\t\t\t.mf_timeout_id_n_bits = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->learn.mf_timeout_id_offset,
instr->learn.mf_timeout_id_n_bits);
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
}
static void
instr_forget_export(struct instruction *instr, FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t},\n",
instr_type_to_name(instr));
}
static void
instr_extern_export(struct instruction *instr, FILE *f)
{
if (instr->type == INSTR_EXTERN_OBJ)
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.ext_obj = {\n"
"\t\t\t.ext_obj_id = %u,\n"
"\t\t\t.func_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->ext_obj.ext_obj_id,
instr->ext_obj.func_id);
else
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.ext_func = {\n"
"\t\t\t.ext_func_id = %u,\n"
"\t\t},\n"
"\t},\n",
instr_type_to_name(instr),
instr->ext_func.ext_func_id);
}
static void
instr_jmp_export(struct instruction *instr, FILE *f __rte_unused)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n"
"\t\t.jmp = {\n"
"\t\t\t.ip = NULL,\n",
instr_type_to_name(instr));
switch (instr->type) {
case INSTR_JMP_VALID:
case INSTR_JMP_INVALID:
fprintf(f,
"\t\t\t.header_id = %u,\n",
instr->jmp.header_id);
break;
case INSTR_JMP_ACTION_HIT:
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"\t\t\t.action_id = %u,\n",
instr->jmp.action_id);
break;
case INSTR_JMP_EQ:
case INSTR_JMP_EQ_MH:
case INSTR_JMP_EQ_HM:
case INSTR_JMP_EQ_HH:
case INSTR_JMP_NEQ:
case INSTR_JMP_NEQ_MH:
case INSTR_JMP_NEQ_HM:
case INSTR_JMP_NEQ_HH:
case INSTR_JMP_LT:
case INSTR_JMP_LT_MH:
case INSTR_JMP_LT_HM:
case INSTR_JMP_LT_HH:
case INSTR_JMP_GT:
case INSTR_JMP_GT_MH:
case INSTR_JMP_GT_HM:
case INSTR_JMP_GT_HH:
fprintf(f,
"\t\t\t.a = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n"
"\t\t\t.b = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t},\n",
instr->jmp.a.struct_id,
instr->jmp.a.n_bits,
instr->jmp.a.offset,
instr->jmp.b.struct_id,
instr->jmp.b.n_bits,
instr->jmp.b.offset);
break;
case INSTR_JMP_EQ_I:
case INSTR_JMP_NEQ_I:
case INSTR_JMP_LT_MI:
case INSTR_JMP_LT_HI:
case INSTR_JMP_GT_MI:
case INSTR_JMP_GT_HI:
fprintf(f,
"\t\t\t.a = {\n"
"\t\t\t\t.struct_id = %u,\n"
"\t\t\t\t.n_bits = %u,\n"
"\t\t\t\t.offset = %u,\n"
"\t\t\t}\n,"
"\t\t\t.b_val = %" PRIu64 ",\n",
instr->jmp.a.struct_id,
instr->jmp.a.n_bits,
instr->jmp.a.offset,
instr->jmp.b_val);
break;
default:
break;
}
fprintf(f,
"\t\t},\n"
"\t},\n");
}
static void
instr_return_export(struct instruction *instr,
FILE *f)
{
fprintf(f,
"\t{\n"
"\t\t.type = %s,\n",
instr_type_to_name(instr));
fprintf(f,
"\t},\n");
}
static instruction_export_t export_table[] = {
[INSTR_RX] = instr_io_export,
[INSTR_TX] = instr_io_export,
[INSTR_TX_I] = instr_io_export,
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
[INSTR_DROP] = instr_io_export,
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
[INSTR_MIRROR] = instr_mirror_export,
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
[INSTR_RECIRCULATE] = instr_recirculate_export,
[INSTR_RECIRCID] = instr_recircid_export,
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
[INSTR_HDR_EXTRACT] = instr_io_export,
[INSTR_HDR_EXTRACT2] = instr_io_export,
[INSTR_HDR_EXTRACT3] = instr_io_export,
[INSTR_HDR_EXTRACT4] = instr_io_export,
[INSTR_HDR_EXTRACT5] = instr_io_export,
[INSTR_HDR_EXTRACT6] = instr_io_export,
[INSTR_HDR_EXTRACT7] = instr_io_export,
[INSTR_HDR_EXTRACT8] = instr_io_export,
[INSTR_HDR_EXTRACT_M] = instr_io_export,
[INSTR_HDR_LOOKAHEAD] = instr_io_export,
[INSTR_HDR_EMIT] = instr_io_export,
[INSTR_HDR_EMIT_TX] = instr_io_export,
[INSTR_HDR_EMIT2_TX] = instr_io_export,
[INSTR_HDR_EMIT3_TX] = instr_io_export,
[INSTR_HDR_EMIT4_TX] = instr_io_export,
[INSTR_HDR_EMIT5_TX] = instr_io_export,
[INSTR_HDR_EMIT6_TX] = instr_io_export,
[INSTR_HDR_EMIT7_TX] = instr_io_export,
[INSTR_HDR_EMIT8_TX] = instr_io_export,
[INSTR_HDR_VALIDATE] = instr_hdr_validate_export,
[INSTR_HDR_INVALIDATE] = instr_hdr_validate_export,
[INSTR_MOV] = instr_mov_export,
[INSTR_MOV_MH] = instr_mov_export,
[INSTR_MOV_HM] = instr_mov_export,
[INSTR_MOV_HH] = instr_mov_export,
[INSTR_MOV_I] = instr_mov_export,
[INSTR_DMA_HT] = instr_dma_ht_export,
[INSTR_DMA_HT2] = instr_dma_ht_export,
[INSTR_DMA_HT3] = instr_dma_ht_export,
[INSTR_DMA_HT4] = instr_dma_ht_export,
[INSTR_DMA_HT5] = instr_dma_ht_export,
[INSTR_DMA_HT6] = instr_dma_ht_export,
[INSTR_DMA_HT7] = instr_dma_ht_export,
[INSTR_DMA_HT8] = instr_dma_ht_export,
[INSTR_ALU_ADD] = instr_alu_export,
[INSTR_ALU_ADD_MH] = instr_alu_export,
[INSTR_ALU_ADD_HM] = instr_alu_export,
[INSTR_ALU_ADD_HH] = instr_alu_export,
[INSTR_ALU_ADD_MI] = instr_alu_export,
[INSTR_ALU_ADD_HI] = instr_alu_export,
[INSTR_ALU_SUB] = instr_alu_export,
[INSTR_ALU_SUB_MH] = instr_alu_export,
[INSTR_ALU_SUB_HM] = instr_alu_export,
[INSTR_ALU_SUB_HH] = instr_alu_export,
[INSTR_ALU_SUB_MI] = instr_alu_export,
[INSTR_ALU_SUB_HI] = instr_alu_export,
[INSTR_ALU_CKADD_FIELD] = instr_alu_export,
[INSTR_ALU_CKADD_STRUCT] = instr_alu_export,
[INSTR_ALU_CKADD_STRUCT20] = instr_alu_export,
[INSTR_ALU_CKSUB_FIELD] = instr_alu_export,
[INSTR_ALU_AND] = instr_alu_export,
[INSTR_ALU_AND_MH] = instr_alu_export,
[INSTR_ALU_AND_HM] = instr_alu_export,
[INSTR_ALU_AND_HH] = instr_alu_export,
[INSTR_ALU_AND_I] = instr_alu_export,
[INSTR_ALU_OR] = instr_alu_export,
[INSTR_ALU_OR_MH] = instr_alu_export,
[INSTR_ALU_OR_HM] = instr_alu_export,
[INSTR_ALU_OR_HH] = instr_alu_export,
[INSTR_ALU_OR_I] = instr_alu_export,
[INSTR_ALU_XOR] = instr_alu_export,
[INSTR_ALU_XOR_MH] = instr_alu_export,
[INSTR_ALU_XOR_HM] = instr_alu_export,
[INSTR_ALU_XOR_HH] = instr_alu_export,
[INSTR_ALU_XOR_I] = instr_alu_export,
[INSTR_ALU_SHL] = instr_alu_export,
[INSTR_ALU_SHL_MH] = instr_alu_export,
[INSTR_ALU_SHL_HM] = instr_alu_export,
[INSTR_ALU_SHL_HH] = instr_alu_export,
[INSTR_ALU_SHL_MI] = instr_alu_export,
[INSTR_ALU_SHL_HI] = instr_alu_export,
[INSTR_ALU_SHR] = instr_alu_export,
[INSTR_ALU_SHR_MH] = instr_alu_export,
[INSTR_ALU_SHR_HM] = instr_alu_export,
[INSTR_ALU_SHR_HH] = instr_alu_export,
[INSTR_ALU_SHR_MI] = instr_alu_export,
[INSTR_ALU_SHR_HI] = instr_alu_export,
[INSTR_REGPREFETCH_RH] = instr_reg_export,
[INSTR_REGPREFETCH_RM] = instr_reg_export,
[INSTR_REGPREFETCH_RI] = instr_reg_export,
[INSTR_REGRD_HRH] = instr_reg_export,
[INSTR_REGRD_HRM] = instr_reg_export,
[INSTR_REGRD_MRH] = instr_reg_export,
[INSTR_REGRD_MRM] = instr_reg_export,
[INSTR_REGRD_HRI] = instr_reg_export,
[INSTR_REGRD_MRI] = instr_reg_export,
[INSTR_REGWR_RHH] = instr_reg_export,
[INSTR_REGWR_RHM] = instr_reg_export,
[INSTR_REGWR_RMH] = instr_reg_export,
[INSTR_REGWR_RMM] = instr_reg_export,
[INSTR_REGWR_RHI] = instr_reg_export,
[INSTR_REGWR_RMI] = instr_reg_export,
[INSTR_REGWR_RIH] = instr_reg_export,
[INSTR_REGWR_RIM] = instr_reg_export,
[INSTR_REGWR_RII] = instr_reg_export,
[INSTR_REGADD_RHH] = instr_reg_export,
[INSTR_REGADD_RHM] = instr_reg_export,
[INSTR_REGADD_RMH] = instr_reg_export,
[INSTR_REGADD_RMM] = instr_reg_export,
[INSTR_REGADD_RHI] = instr_reg_export,
[INSTR_REGADD_RMI] = instr_reg_export,
[INSTR_REGADD_RIH] = instr_reg_export,
[INSTR_REGADD_RIM] = instr_reg_export,
[INSTR_REGADD_RII] = instr_reg_export,
[INSTR_METPREFETCH_H] = instr_meter_export,
[INSTR_METPREFETCH_M] = instr_meter_export,
[INSTR_METPREFETCH_I] = instr_meter_export,
[INSTR_METER_HHM] = instr_meter_export,
[INSTR_METER_HHI] = instr_meter_export,
[INSTR_METER_HMM] = instr_meter_export,
[INSTR_METER_HMI] = instr_meter_export,
[INSTR_METER_MHM] = instr_meter_export,
[INSTR_METER_MHI] = instr_meter_export,
[INSTR_METER_MMM] = instr_meter_export,
[INSTR_METER_MMI] = instr_meter_export,
[INSTR_METER_IHM] = instr_meter_export,
[INSTR_METER_IHI] = instr_meter_export,
[INSTR_METER_IMM] = instr_meter_export,
[INSTR_METER_IMI] = instr_meter_export,
[INSTR_TABLE] = instr_table_export,
[INSTR_TABLE_AF] = instr_table_export,
[INSTR_SELECTOR] = instr_table_export,
[INSTR_LEARNER] = instr_table_export,
[INSTR_LEARNER_AF] = instr_table_export,
[INSTR_LEARNER_LEARN] = instr_learn_export,
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
[INSTR_LEARNER_REARM] = instr_rearm_export,
[INSTR_LEARNER_REARM_NEW] = instr_rearm_export,
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
[INSTR_LEARNER_FORGET] = instr_forget_export,
[INSTR_EXTERN_OBJ] = instr_extern_export,
[INSTR_EXTERN_FUNC] = instr_extern_export,
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
[INSTR_HASH_FUNC] = instr_hash_export,
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
[INSTR_JMP] = instr_jmp_export,
[INSTR_JMP_VALID] = instr_jmp_export,
[INSTR_JMP_INVALID] = instr_jmp_export,
[INSTR_JMP_HIT] = instr_jmp_export,
[INSTR_JMP_MISS] = instr_jmp_export,
[INSTR_JMP_ACTION_HIT] = instr_jmp_export,
[INSTR_JMP_ACTION_MISS] = instr_jmp_export,
[INSTR_JMP_EQ] = instr_jmp_export,
[INSTR_JMP_EQ_MH] = instr_jmp_export,
[INSTR_JMP_EQ_HM] = instr_jmp_export,
[INSTR_JMP_EQ_HH] = instr_jmp_export,
[INSTR_JMP_EQ_I] = instr_jmp_export,
[INSTR_JMP_NEQ] = instr_jmp_export,
[INSTR_JMP_NEQ_MH] = instr_jmp_export,
[INSTR_JMP_NEQ_HM] = instr_jmp_export,
[INSTR_JMP_NEQ_HH] = instr_jmp_export,
[INSTR_JMP_NEQ_I] = instr_jmp_export,
[INSTR_JMP_LT] = instr_jmp_export,
[INSTR_JMP_LT_MH] = instr_jmp_export,
[INSTR_JMP_LT_HM] = instr_jmp_export,
[INSTR_JMP_LT_HH] = instr_jmp_export,
[INSTR_JMP_LT_MI] = instr_jmp_export,
[INSTR_JMP_LT_HI] = instr_jmp_export,
[INSTR_JMP_GT] = instr_jmp_export,
[INSTR_JMP_GT_MH] = instr_jmp_export,
[INSTR_JMP_GT_HM] = instr_jmp_export,
[INSTR_JMP_GT_HH] = instr_jmp_export,
[INSTR_JMP_GT_MI] = instr_jmp_export,
[INSTR_JMP_GT_HI] = instr_jmp_export,
[INSTR_RETURN] = instr_return_export,
};
static void
action_data_codegen(struct action *a, FILE *f)
{
uint32_t i;
fprintf(f,
"static const struct instruction action_%s_instructions[] = {\n",
a->name);
for (i = 0; i < a->n_instructions; i++) {
struct instruction *instr = &a->instructions[i];
instruction_export_t func = export_table[instr->type];
func(instr, f);
}
fprintf(f, "};\n");
}
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
static const char *
instr_type_to_func(struct instruction *instr)
{
switch (instr->type) {
case INSTR_RX: return NULL;
case INSTR_TX: return "__instr_tx_exec";
case INSTR_TX_I: return "__instr_tx_i_exec";
pipeline: improve drop instruction The output port to be used as the drop port is now determined when the drop instruction is executed as opposed to being statically determined at instruction translation time and hardcoded in the opcode. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Yogesh Jangra <yogesh.jangra@intel.com>
2021-11-27 00:02:51 +00:00
case INSTR_DROP: return "__instr_drop_exec";
pipeline: support packet mirroring The packet mirroring is configured through slots and sessions, with the number of slots and sessions set at init. The new "mirror" instruction assigns one of the existing sessions to a specific slot, which results in scheduling a mirror operation for the current packet to be executed later at the time the packet is either transmitted or dropped. Several copies of the same input packet can be mirrored to different output ports by using multiple slots. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Kamalakannan R <kamalakannan.r@intel.com>
2022-04-06 18:55:31 +00:00
case INSTR_MIRROR: return "__instr_mirror_exec";
pipeline: support packet recirculation Add support for packet recirculation. The current packet is flagged for recirculation using the new "recirculate" instruction; on TX, this flag causes the packet to execute the full pipeline again as if it was a new packet, except the packet meta-data is preserved. The new "recircid" instruction can be used to read the pass number in case the packet goes several times through the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-04-06 18:55:34 +00:00
case INSTR_RECIRCULATE: return "__instr_recirculate_exec";
case INSTR_RECIRCID: return "__instr_recircid_exec";
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
case INSTR_HDR_EXTRACT: return "__instr_hdr_extract_exec";
case INSTR_HDR_EXTRACT2: return "__instr_hdr_extract2_exec";
case INSTR_HDR_EXTRACT3: return "__instr_hdr_extract3_exec";
case INSTR_HDR_EXTRACT4: return "__instr_hdr_extract4_exec";
case INSTR_HDR_EXTRACT5: return "__instr_hdr_extract5_exec";
case INSTR_HDR_EXTRACT6: return "__instr_hdr_extract6_exec";
case INSTR_HDR_EXTRACT7: return "__instr_hdr_extract7_exec";
case INSTR_HDR_EXTRACT8: return "__instr_hdr_extract8_exec";
case INSTR_HDR_EXTRACT_M: return "__instr_hdr_extract_m_exec";
case INSTR_HDR_LOOKAHEAD: return "__instr_hdr_lookahead_exec";
case INSTR_HDR_EMIT: return "__instr_hdr_emit_exec";
case INSTR_HDR_EMIT_TX: return "__instr_hdr_emit_tx_exec";
case INSTR_HDR_EMIT2_TX: return "__instr_hdr_emit2_tx_exec";
case INSTR_HDR_EMIT3_TX: return "__instr_hdr_emit3_tx_exec";
case INSTR_HDR_EMIT4_TX: return "__instr_hdr_emit4_tx_exec";
case INSTR_HDR_EMIT5_TX: return "__instr_hdr_emit5_tx_exec";
case INSTR_HDR_EMIT6_TX: return "__instr_hdr_emit6_tx_exec";
case INSTR_HDR_EMIT7_TX: return "__instr_hdr_emit7_tx_exec";
case INSTR_HDR_EMIT8_TX: return "__instr_hdr_emit8_tx_exec";
case INSTR_HDR_VALIDATE: return "__instr_hdr_validate_exec";
case INSTR_HDR_INVALIDATE: return "__instr_hdr_invalidate_exec";
case INSTR_MOV: return "__instr_mov_exec";
case INSTR_MOV_MH: return "__instr_mov_mh_exec";
case INSTR_MOV_HM: return "__instr_mov_hm_exec";
case INSTR_MOV_HH: return "__instr_mov_hh_exec";
case INSTR_MOV_I: return "__instr_mov_i_exec";
case INSTR_DMA_HT: return "__instr_dma_ht_exec";
case INSTR_DMA_HT2: return "__instr_dma_ht2_exec";
case INSTR_DMA_HT3: return "__instr_dma_ht3_exec";
case INSTR_DMA_HT4: return "__instr_dma_ht4_exec";
case INSTR_DMA_HT5: return "__instr_dma_ht5_exec";
case INSTR_DMA_HT6: return "__instr_dma_ht6_exec";
case INSTR_DMA_HT7: return "__instr_dma_ht7_exec";
case INSTR_DMA_HT8: return "__instr_dma_ht8_exec";
case INSTR_ALU_ADD: return "__instr_alu_add_exec";
case INSTR_ALU_ADD_MH: return "__instr_alu_add_mh_exec";
case INSTR_ALU_ADD_HM: return "__instr_alu_add_hm_exec";
case INSTR_ALU_ADD_HH: return "__instr_alu_add_hh_exec";
case INSTR_ALU_ADD_MI: return "__instr_alu_add_mi_exec";
case INSTR_ALU_ADD_HI: return "__instr_alu_add_hi_exec";
case INSTR_ALU_SUB: return "__instr_alu_sub_exec";
case INSTR_ALU_SUB_MH: return "__instr_alu_sub_mh_exec";
case INSTR_ALU_SUB_HM: return "__instr_alu_sub_hm_exec";
case INSTR_ALU_SUB_HH: return "__instr_alu_sub_hh_exec";
case INSTR_ALU_SUB_MI: return "__instr_alu_sub_mi_exec";
case INSTR_ALU_SUB_HI: return "__instr_alu_sub_hi_exec";
case INSTR_ALU_CKADD_FIELD: return "__instr_alu_ckadd_field_exec";
case INSTR_ALU_CKADD_STRUCT20: return "__instr_alu_ckadd_struct20_exec";
case INSTR_ALU_CKADD_STRUCT: return "__instr_alu_ckadd_struct_exec";
case INSTR_ALU_CKSUB_FIELD: return "__instr_alu_cksub_field_exec";
case INSTR_ALU_AND: return "__instr_alu_and_exec";
case INSTR_ALU_AND_MH: return "__instr_alu_and_mh_exec";
case INSTR_ALU_AND_HM: return "__instr_alu_and_hm_exec";
case INSTR_ALU_AND_HH: return "__instr_alu_and_hh_exec";
case INSTR_ALU_AND_I: return "__instr_alu_and_i_exec";
case INSTR_ALU_OR: return "__instr_alu_or_exec";
case INSTR_ALU_OR_MH: return "__instr_alu_or_mh_exec";
case INSTR_ALU_OR_HM: return "__instr_alu_or_hm_exec";
case INSTR_ALU_OR_HH: return "__instr_alu_or_hh_exec";
case INSTR_ALU_OR_I: return "__instr_alu_or_i_exec";
case INSTR_ALU_XOR: return "__instr_alu_xor_exec";
case INSTR_ALU_XOR_MH: return "__instr_alu_xor_mh_exec";
case INSTR_ALU_XOR_HM: return "__instr_alu_xor_hm_exec";
case INSTR_ALU_XOR_HH: return "__instr_alu_xor_hh_exec";
case INSTR_ALU_XOR_I: return "__instr_alu_xor_i_exec";
case INSTR_ALU_SHL: return "__instr_alu_shl_exec";
case INSTR_ALU_SHL_MH: return "__instr_alu_shl_mh_exec";
case INSTR_ALU_SHL_HM: return "__instr_alu_shl_hm_exec";
case INSTR_ALU_SHL_HH: return "__instr_alu_shl_hh_exec";
case INSTR_ALU_SHL_MI: return "__instr_alu_shl_mi_exec";
case INSTR_ALU_SHL_HI: return "__instr_alu_shl_hi_exec";
case INSTR_ALU_SHR: return "__instr_alu_shr_exec";
case INSTR_ALU_SHR_MH: return "__instr_alu_shr_mh_exec";
case INSTR_ALU_SHR_HM: return "__instr_alu_shr_hm_exec";
case INSTR_ALU_SHR_HH: return "__instr_alu_shr_hh_exec";
case INSTR_ALU_SHR_MI: return "__instr_alu_shr_mi_exec";
case INSTR_ALU_SHR_HI: return "__instr_alu_shr_hi_exec";
case INSTR_REGPREFETCH_RH: return "__instr_regprefetch_rh_exec";
case INSTR_REGPREFETCH_RM: return "__instr_regprefetch_rm_exec";
case INSTR_REGPREFETCH_RI: return "__instr_regprefetch_ri_exec";
case INSTR_REGRD_HRH: return "__instr_regrd_hrh_exec";
case INSTR_REGRD_HRM: return "__instr_regrd_hrm_exec";
case INSTR_REGRD_HRI: return "__instr_regrd_hri_exec";
case INSTR_REGRD_MRH: return "__instr_regrd_mrh_exec";
case INSTR_REGRD_MRM: return "__instr_regrd_mrm_exec";
case INSTR_REGRD_MRI: return "__instr_regrd_mri_exec";
case INSTR_REGWR_RHH: return "__instr_regwr_rhh_exec";
case INSTR_REGWR_RHM: return "__instr_regwr_rhm_exec";
case INSTR_REGWR_RHI: return "__instr_regwr_rhi_exec";
case INSTR_REGWR_RMH: return "__instr_regwr_rmh_exec";
case INSTR_REGWR_RMM: return "__instr_regwr_rmm_exec";
case INSTR_REGWR_RMI: return "__instr_regwr_rmi_exec";
case INSTR_REGWR_RIH: return "__instr_regwr_rih_exec";
case INSTR_REGWR_RIM: return "__instr_regwr_rim_exec";
case INSTR_REGWR_RII: return "__instr_regwr_rii_exec";
case INSTR_REGADD_RHH: return "__instr_regadd_rhh_exec";
case INSTR_REGADD_RHM: return "__instr_regadd_rhm_exec";
case INSTR_REGADD_RHI: return "__instr_regadd_rhi_exec";
case INSTR_REGADD_RMH: return "__instr_regadd_rmh_exec";
case INSTR_REGADD_RMM: return "__instr_regadd_rmm_exec";
case INSTR_REGADD_RMI: return "__instr_regadd_rmi_exec";
case INSTR_REGADD_RIH: return "__instr_regadd_rih_exec";
case INSTR_REGADD_RIM: return "__instr_regadd_rim_exec";
case INSTR_REGADD_RII: return "__instr_regadd_rii_exec";
case INSTR_METPREFETCH_H: return "__instr_metprefetch_h_exec";
case INSTR_METPREFETCH_M: return "__instr_metprefetch_m_exec";
case INSTR_METPREFETCH_I: return "__instr_metprefetch_i_exec";
case INSTR_METER_HHM: return "__instr_meter_hhm_exec";
case INSTR_METER_HHI: return "__instr_meter_hhi_exec";
case INSTR_METER_HMM: return "__instr_meter_hmm_exec";
case INSTR_METER_HMI: return "__instr_meter_hmi_exec";
case INSTR_METER_MHM: return "__instr_meter_mhm_exec";
case INSTR_METER_MHI: return "__instr_meter_mhi_exec";
case INSTR_METER_MMM: return "__instr_meter_mmm_exec";
case INSTR_METER_MMI: return "__instr_meter_mmi_exec";
case INSTR_METER_IHM: return "__instr_meter_ihm_exec";
case INSTR_METER_IHI: return "__instr_meter_ihi_exec";
case INSTR_METER_IMM: return "__instr_meter_imm_exec";
case INSTR_METER_IMI: return "__instr_meter_imi_exec";
case INSTR_TABLE: return NULL;
case INSTR_TABLE_AF: return NULL;
case INSTR_SELECTOR: return NULL;
case INSTR_LEARNER: return NULL;
case INSTR_LEARNER_AF: return NULL;
case INSTR_LEARNER_LEARN: return "__instr_learn_exec";
pipeline: improve learner table timers Enable the pipeline to use the improved learner table timer operation through the new "rearm" instruction. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:12:54 +00:00
case INSTR_LEARNER_REARM: return "__instr_rearm_exec";
case INSTR_LEARNER_REARM_NEW: return "__instr_rearm_new_exec";
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
case INSTR_LEARNER_FORGET: return "__instr_forget_exec";
case INSTR_EXTERN_OBJ: return NULL;
case INSTR_EXTERN_FUNC: return NULL;
pipeline: support hash functions Add support for hash functions that compute a signature for an array of bytes read from a packet header or meta-data. Useful for flow affinity-based load balancing. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2022-05-20 22:31:24 +00:00
case INSTR_HASH_FUNC: return "__instr_hash_func_exec";
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
case INSTR_JMP: return NULL;
case INSTR_JMP_VALID: return NULL;
case INSTR_JMP_INVALID: return NULL;
case INSTR_JMP_HIT: return NULL;
case INSTR_JMP_MISS: return NULL;
case INSTR_JMP_ACTION_HIT: return NULL;
case INSTR_JMP_ACTION_MISS: return NULL;
case INSTR_JMP_EQ: return NULL;
case INSTR_JMP_EQ_MH: return NULL;
case INSTR_JMP_EQ_HM: return NULL;
case INSTR_JMP_EQ_HH: return NULL;
case INSTR_JMP_EQ_I: return NULL;
case INSTR_JMP_NEQ: return NULL;
case INSTR_JMP_NEQ_MH: return NULL;
case INSTR_JMP_NEQ_HM: return NULL;
case INSTR_JMP_NEQ_HH: return NULL;
case INSTR_JMP_NEQ_I: return NULL;
case INSTR_JMP_LT: return NULL;
case INSTR_JMP_LT_MH: return NULL;
case INSTR_JMP_LT_HM: return NULL;
case INSTR_JMP_LT_HH: return NULL;
case INSTR_JMP_LT_MI: return NULL;
case INSTR_JMP_LT_HI: return NULL;
case INSTR_JMP_GT: return NULL;
case INSTR_JMP_GT_MH: return NULL;
case INSTR_JMP_GT_HM: return NULL;
case INSTR_JMP_GT_HH: return NULL;
case INSTR_JMP_GT_MI: return NULL;
case INSTR_JMP_GT_HI: return NULL;
case INSTR_RETURN: return NULL;
default: return NULL;
}
}
static void
action_instr_does_tx_codegen(struct action *a,
uint32_t instr_pos,
struct instruction *instr,
FILE *f)
{
fprintf(f,
"%s(p, t, &action_%s_instructions[%u]);\n"
"\tthread_ip_reset(p, t);\n"
"\tinstr_rx_exec(p);\n"
"\treturn;\n",
instr_type_to_func(instr),
a->name,
instr_pos);
}
static void
action_instr_extern_obj_codegen(struct action *a,
uint32_t instr_pos,
FILE *f)
{
fprintf(f,
"while (!__instr_extern_obj_exec(p, t, &action_%s_instructions[%u]));\n",
a->name,
instr_pos);
}
static void
action_instr_extern_func_codegen(struct action *a,
uint32_t instr_pos,
FILE *f)
{
fprintf(f,
"while (!__instr_extern_func_exec(p, t, &action_%s_instructions[%u]));\n",
a->name,
instr_pos);
}
static void
action_instr_jmp_codegen(struct action *a,
uint32_t instr_pos,
struct instruction *instr,
struct instruction_data *data,
FILE *f)
{
switch (instr->type) {
case INSTR_JMP:
fprintf(f,
"goto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_VALID:
fprintf(f,
"if (HEADER_VALID(t, action_%s_instructions[%u].jmp.header_id))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_INVALID:
fprintf(f,
"if (!HEADER_VALID(t, action_%s_instructions[%u].jmp.header_id))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_HIT:
fprintf(f,
"if (t->hit)\n"
"\t\tgoto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_MISS:
fprintf(f,
"if (!t->hit)\n"
"\t\tgoto %s;\n",
data->jmp_label);
return;
case INSTR_JMP_ACTION_HIT:
fprintf(f,
"if (t->action_id == action_%s_instructions[%u].jmp.action_id)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"if (t->action_id != action_%s_instructions[%u].jmp.action_id)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_EQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) == "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_NEQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) != "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) < "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_LT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) < "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &action_%s_instructions[%u].jmp.b))\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &action_%s_instructions[%u].jmp.a) > "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
case INSTR_JMP_GT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &action_%s_instructions[%u].jmp.a) > "
"action_%s_instructions[%u].jmp.b_val)\n"
"\t\tgoto %s;\n",
a->name,
instr_pos,
a->name,
instr_pos,
data->jmp_label);
return;
default:
return;
}
}
static void
action_instr_return_codegen(FILE *f)
{
fprintf(f,
"return;\n");
}
static void
action_instr_codegen(struct action *a, FILE *f)
{
uint32_t i;
fprintf(f,
"void\n"
"action_%s_run(struct rte_swx_pipeline *p)\n"
"{\n"
"\tstruct thread *t = &p->threads[p->thread_id];\n"
"\n",
a->name);
for (i = 0; i < a->n_instructions; i++) {
struct instruction *instr = &a->instructions[i];
struct instruction_data *data = &a->instruction_data[i];
/* Label, if present. */
if (data->label[0])
fprintf(f, "\n%s : ", data->label);
else
fprintf(f, "\n\t");
/* TX instruction type. */
if (instruction_does_tx(instr)) {
action_instr_does_tx_codegen(a, i, instr, f);
continue;
}
/* Extern object/function instruction type. */
if (instr->type == INSTR_EXTERN_OBJ) {
action_instr_extern_obj_codegen(a, i, f);
continue;
}
if (instr->type == INSTR_EXTERN_FUNC) {
action_instr_extern_func_codegen(a, i, f);
continue;
}
/* Jump instruction type. */
if (instruction_is_jmp(instr)) {
action_instr_jmp_codegen(a, i, instr, data, f);
continue;
}
/* Return instruction type. */
if (instr->type == INSTR_RETURN) {
action_instr_return_codegen(f);
continue;
}
/* Any other instruction type. */
fprintf(f,
"%s(p, t, &action_%s_instructions[%u]);\n",
instr_type_to_func(instr),
a->name,
i);
}
fprintf(f, "}\n\n");
}
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
struct instruction_group {
TAILQ_ENTRY(instruction_group) node;
uint32_t group_id;
uint32_t first_instr_id;
uint32_t last_instr_id;
instr_exec_t func;
};
TAILQ_HEAD(instruction_group_list, instruction_group);
static struct instruction_group *
instruction_group_list_group_find(struct instruction_group_list *igl, uint32_t instruction_id)
{
struct instruction_group *g;
TAILQ_FOREACH(g, igl, node)
if ((g->first_instr_id <= instruction_id) && (instruction_id <= g->last_instr_id))
return g;
return NULL;
}
static void
instruction_group_list_free(struct instruction_group_list *igl)
{
if (!igl)
return;
for ( ; ; ) {
struct instruction_group *g;
g = TAILQ_FIRST(igl);
if (!g)
break;
TAILQ_REMOVE(igl, g, node);
free(g);
}
free(igl);
}
static struct instruction_group_list *
instruction_group_list_create(struct rte_swx_pipeline *p)
{
struct instruction_group_list *igl = NULL;
struct instruction_group *g = NULL;
uint32_t n_groups = 0, i;
if (!p || !p->instructions || !p->instruction_data || !p->n_instructions)
goto error;
/* List init. */
igl = calloc(1, sizeof(struct instruction_group_list));
if (!igl)
goto error;
TAILQ_INIT(igl);
/* Allocate the first group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Iteration 1: Separate the instructions into groups based on the thread yield
* instructions. Do not worry about the jump instructions at this point.
*/
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
/* Check for thread yield instructions. */
if (!instruction_does_thread_yield(instr))
continue;
/* If the current group contains at least one instruction, then finalize it (with
* the previous instruction), add it to the list and allocate a new group (that
* starts with the current instruction).
*/
if (i - g->first_instr_id) {
/* Finalize the group. */
g->last_instr_id = i - 1;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
/* Allocate a new group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Initialize the new group. */
g->group_id = n_groups;
g->first_instr_id = i;
}
/* Finalize the current group (with the current instruction, therefore this group
* contains just the current thread yield instruction), add it to the list and
* allocate a new group (that starts with the next instruction).
*/
/* Finalize the group. */
g->last_instr_id = i;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
/* Allocate a new group. */
g = calloc(1, sizeof(struct instruction_group));
if (!g)
goto error;
/* Initialize the new group. */
g->group_id = n_groups;
g->first_instr_id = i + 1;
}
/* Handle the last group. */
if (i - g->first_instr_id) {
/* Finalize the group. */
g->last_instr_id = i - 1;
/* Add the group to the list. Advance the number of groups. */
TAILQ_INSERT_TAIL(igl, g, node);
n_groups++;
} else
free(g);
g = NULL;
/* Iteration 2: Handle jumps. If the current group contains an instruction which represents
* the destination of a jump instruction located in a different group ("far jump"), then the
* current group has to be split, so that the instruction representing the far jump
* destination is at the start of its group.
*/
for ( ; ; ) {
int is_modified = 0;
for (i = 0; i < p->n_instructions; i++) {
struct instruction_data *data = &p->instruction_data[i];
struct instruction_group *g;
uint32_t j;
/* Continue when the current instruction is not a jump destination. */
if (!data->n_users)
continue;
g = instruction_group_list_group_find(igl, i);
if (!g)
goto error;
/* Find out all the jump instructions with this destination. */
for (j = 0; j < p->n_instructions; j++) {
struct instruction *jmp_instr = &p->instructions[j];
struct instruction_data *jmp_data = &p->instruction_data[j];
struct instruction_group *jmp_g, *new_g;
/* Continue when not a jump instruction. Even when jump instruction,
* continue when the jump destination is not this instruction.
*/
if (!instruction_is_jmp(jmp_instr) ||
strcmp(jmp_data->jmp_label, data->label))
continue;
jmp_g = instruction_group_list_group_find(igl, j);
if (!jmp_g)
goto error;
/* Continue when both the jump instruction and the jump destination
* instruction are in the same group. Even when in different groups,
* still continue if the jump destination instruction is already the
* first instruction of its group.
*/
if ((jmp_g->group_id == g->group_id) || (g->first_instr_id == i))
continue;
/* Split the group of the current jump destination instruction to
* make this instruction the first instruction of a new group.
*/
new_g = calloc(1, sizeof(struct instruction_group));
if (!new_g)
goto error;
new_g->group_id = n_groups;
new_g->first_instr_id = i;
new_g->last_instr_id = g->last_instr_id;
g->last_instr_id = i - 1;
TAILQ_INSERT_AFTER(igl, g, new_g, node);
n_groups++;
is_modified = 1;
/* The decision to split this group (to make the current instruction
* the first instruction of a new group) is already taken and fully
* implemented, so no need to search for more reasons to do it.
*/
break;
}
}
/* Re-evaluate everything, as at least one group got split, so some jumps that were
* previously considered local (i.e. the jump destination is in the same group as
* the jump instruction) can now be "far jumps" (i.e. the jump destination is in a
* different group than the jump instruction). Wost case scenario: each instruction
* that is a jump destination ends up as the first instruction of its group.
*/
if (!is_modified)
break;
}
/* Re-assign the group IDs to be in incremental order. */
i = 0;
TAILQ_FOREACH(g, igl, node) {
g->group_id = i;
i++;
}
return igl;
error:
instruction_group_list_free(igl);
free(g);
return NULL;
}
static void
pipeline_instr_does_tx_codegen(struct rte_swx_pipeline *p __rte_unused,
uint32_t instr_pos,
struct instruction *instr,
FILE *f)
{
fprintf(f,
"%s(p, t, &pipeline_instructions[%u]);\n"
"\tthread_ip_reset(p, t);\n"
"\tinstr_rx_exec(p);\n"
"\treturn;\n",
instr_type_to_func(instr),
instr_pos);
}
static int
pipeline_instr_jmp_codegen(struct rte_swx_pipeline *p,
struct instruction_group_list *igl,
uint32_t jmp_instr_id,
struct instruction *jmp_instr,
struct instruction_data *jmp_data,
FILE *f)
{
struct instruction_group *jmp_g, *g;
struct instruction_data *data;
uint32_t instr_id;
switch (jmp_instr->type) {
case INSTR_JMP:
break;
case INSTR_JMP_VALID:
fprintf(f,
"if (HEADER_VALID(t, pipeline_instructions[%u].jmp.header_id))",
jmp_instr_id);
break;
case INSTR_JMP_INVALID:
fprintf(f,
"if (!HEADER_VALID(t, pipeline_instructions[%u].jmp.header_id))",
jmp_instr_id);
break;
case INSTR_JMP_HIT:
fprintf(f,
"if (t->hit)\n");
break;
case INSTR_JMP_MISS:
fprintf(f,
"if (!t->hit)\n");
break;
case INSTR_JMP_ACTION_HIT:
fprintf(f,
"if (t->action_id == pipeline_instructions[%u].jmp.action_id)",
jmp_instr_id);
break;
case INSTR_JMP_ACTION_MISS:
fprintf(f,
"if (t->action_id != pipeline_instructions[%u].jmp.action_id)",
jmp_instr_id);
break;
case INSTR_JMP_EQ:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) == "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_EQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) == "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) != "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_NEQ_I:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) != "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) < "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_LT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) < "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_MH:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HM:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_hbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HH:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"instr_operand_nbo(t, &pipeline_instructions[%u].jmp.b))",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_MI:
fprintf(f,
"if (instr_operand_hbo(t, &pipeline_instructions[%u].jmp.a) > "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
case INSTR_JMP_GT_HI:
fprintf(f,
"if (instr_operand_nbo(t, &pipeline_instructions[%u].jmp.a) > "
"pipeline_instructions[%u].jmp.b_val)",
jmp_instr_id,
jmp_instr_id);
break;
default:
break;
}
/* Find the instruction group of the jump instruction. */
jmp_g = instruction_group_list_group_find(igl, jmp_instr_id);
if (!jmp_g)
return -EINVAL;
/* Find the instruction group of the jump destination instruction. */
data = label_find(p->instruction_data, p->n_instructions, jmp_data->jmp_label);
if (!data)
return -EINVAL;
instr_id = data - p->instruction_data;
g = instruction_group_list_group_find(igl, instr_id);
if (!g)
return -EINVAL;
/* Code generation for "near" jump (same instruction group) or "far" jump (different
* instruction group).
*/
if (g->group_id == jmp_g->group_id)
fprintf(f,
"\n\t\tgoto %s;\n",
jmp_data->jmp_label);
else
fprintf(f,
" {\n"
"\t\tthread_ip_set(t, &p->instructions[%u]);\n"
"\t\treturn;\n"
"\t}\n\n",
g->group_id);
return 0;
}
static void
instruction_group_list_codegen(struct instruction_group_list *igl,
struct rte_swx_pipeline *p,
FILE *f)
{
struct instruction_group *g;
uint32_t i;
int is_required = 0;
/* Check if code generation is required. */
TAILQ_FOREACH(g, igl, node)
if (g->first_instr_id < g->last_instr_id)
is_required = 1;
if (!is_required)
return;
/* Generate the code for the pipeline instruction array. */
fprintf(f,
"static const struct instruction pipeline_instructions[] = {\n");
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
instruction_export_t func = export_table[instr->type];
func(instr, f);
}
fprintf(f, "};\n\n");
/* Generate the code for the pipeline functions: one function for each instruction group
* that contains more than one instruction.
*/
TAILQ_FOREACH(g, igl, node) {
struct instruction *last_instr;
uint32_t j;
/* Skip if group contains a single instruction. */
if (g->last_instr_id == g->first_instr_id)
continue;
/* Generate new pipeline function. */
fprintf(f,
"void\n"
"pipeline_func_%u(struct rte_swx_pipeline *p)\n"
"{\n"
"\tstruct thread *t = &p->threads[p->thread_id];\n"
"\n",
g->group_id);
/* Generate the code for each pipeline instruction. */
for (j = g->first_instr_id; j <= g->last_instr_id; j++) {
struct instruction *instr = &p->instructions[j];
struct instruction_data *data = &p->instruction_data[j];
/* Label, if present. */
if (data->label[0])
fprintf(f, "\n%s : ", data->label);
else
fprintf(f, "\n\t");
/* TX instruction type. */
if (instruction_does_tx(instr)) {
pipeline_instr_does_tx_codegen(p, j, instr, f);
continue;
}
/* Jump instruction type. */
if (instruction_is_jmp(instr)) {
pipeline_instr_jmp_codegen(p, igl, j, instr, data, f);
continue;
}
/* Any other instruction type. */
fprintf(f,
"%s(p, t, &pipeline_instructions[%u]);\n",
instr_type_to_func(instr),
j);
}
/* Finalize the generated pipeline function. For some instructions such as TX,
* emit-many-and-TX and unconditional jump, the next instruction has been already
* decided unconditionally and the instruction pointer of the current thread set
* accordingly; for all the other instructions, the instruction pointer must be
* incremented now.
*/
last_instr = &p->instructions[g->last_instr_id];
if (!instruction_does_tx(last_instr) && (last_instr->type != INSTR_JMP))
fprintf(f,
"thread_ip_inc(p);\n");
fprintf(f,
"}\n"
"\n");
}
}
pipeline: enable pipeline compilation Commit the pipeline changes when the compilation process is successful: change the table lookup instructions to execute the action function for each action, replace the regular pipeline instructions with the custom instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:43 +00:00
static uint32_t
instruction_group_list_custom_instructions_count(struct instruction_group_list *igl)
{
struct instruction_group *g;
uint32_t n_custom_instr = 0;
/* Groups with a single instruction: no function is generated for this group, the group
* keeps its current instruction. Groups with more than two instructions: one function and
* the associated custom instruction get generated for each such group.
*/
TAILQ_FOREACH(g, igl, node) {
if (g->first_instr_id == g->last_instr_id)
continue;
n_custom_instr++;
}
return n_custom_instr;
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
static int
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
pipeline_codegen(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
{
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
struct action *a;
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
FILE *f = NULL;
/* Create the .c file. */
f = fopen("/tmp/pipeline.c", "w");
if (!f)
return -EIO;
/* Include the .h file. */
fprintf(f, "#include \"rte_swx_pipeline_internal.h\"\n");
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
/* Add the code for each action. */
TAILQ_FOREACH(a, &p->actions, node) {
fprintf(f, "/**\n * Action %s\n */\n\n", a->name);
action_data_codegen(a, f);
fprintf(f, "\n");
pipeline: generate action functions Generate a C function for each action. For most instructions, the associated inline function is called directly. Special care is taken for TX, jump and return instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:40 +00:00
action_instr_codegen(a, f);
fprintf(f, "\n");
pipeline: export pipeline instructions to file Export the array of translated instructions to a C file. There is one such array per action and one for the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:39 +00:00
}
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
/* Add the pipeline code. */
instruction_group_list_codegen(igl, p, f);
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
/* Close the .c file. */
fclose(f);
return 0;
}
pipeline: build shared object for pipeline Build the generated C file into a shared object library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Cunming Liang <cunming.liang@intel.com>
2021-09-13 16:44:42 +00:00
#ifndef RTE_SWX_PIPELINE_CMD_MAX_SIZE
#define RTE_SWX_PIPELINE_CMD_MAX_SIZE 4096
#endif
static int
pipeline_libload(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
{
struct action *a;
struct instruction_group *g;
char *dir_in, *buffer = NULL;
const char *dir_out;
int status = 0;
/* Get the environment variables. */
dir_in = getenv("RTE_INSTALL_DIR");
if (!dir_in) {
status = -EINVAL;
goto free;
}
dir_out = "/tmp";
/* Memory allocation for the command buffer. */
buffer = malloc(RTE_SWX_PIPELINE_CMD_MAX_SIZE);
if (!buffer) {
status = -ENOMEM;
goto free;
}
snprintf(buffer,
RTE_SWX_PIPELINE_CMD_MAX_SIZE,
"gcc -c -O3 -fpic -Wno-deprecated-declarations -o %s/pipeline.o %s/pipeline.c "
"-I %s/lib/pipeline "
"-I %s/lib/eal/include "
"-I %s/lib/eal/x86/include "
"-I %s/lib/eal/include/generic "
"-I %s/lib/meter "
"-I %s/lib/port "
"-I %s/lib/table "
"-I %s/lib/pipeline "
"-I %s/config "
"-I %s/build "
"-I %s/lib/eal/linux/include "
">%s/pipeline.log 2>&1 "
"&& "
"gcc -shared %s/pipeline.o -o %s/libpipeline.so "
">>%s/pipeline.log 2>&1",
dir_out,
dir_out,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_in,
dir_out,
dir_out,
dir_out,
dir_out);
/* Build the shared object library. */
status = system(buffer);
if (status)
goto free;
/* Open library. */
snprintf(buffer,
RTE_SWX_PIPELINE_CMD_MAX_SIZE,
"%s/libpipeline.so",
dir_out);
p->lib = dlopen(buffer, RTLD_LAZY);
if (!p->lib) {
status = -EIO;
goto free;
}
/* Get the action function symbols. */
TAILQ_FOREACH(a, &p->actions, node) {
snprintf(buffer, RTE_SWX_PIPELINE_CMD_MAX_SIZE, "action_%s_run", a->name);
p->action_funcs[a->id] = dlsym(p->lib, buffer);
if (!p->action_funcs[a->id]) {
status = -EINVAL;
goto free;
}
}
/* Get the pipeline function symbols. */
TAILQ_FOREACH(g, igl, node) {
if (g->first_instr_id == g->last_instr_id)
continue;
snprintf(buffer, RTE_SWX_PIPELINE_CMD_MAX_SIZE, "pipeline_func_%u", g->group_id);
g->func = dlsym(p->lib, buffer);
if (!g->func) {
status = -EINVAL;
goto free;
}
}
free:
if (status && p->lib) {
dlclose(p->lib);
p->lib = NULL;
}
free(buffer);
return status;
}
pipeline: enable pipeline compilation Commit the pipeline changes when the compilation process is successful: change the table lookup instructions to execute the action function for each action, replace the regular pipeline instructions with the custom instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:43 +00:00
static int
pipeline_adjust_check(struct rte_swx_pipeline *p __rte_unused,
struct instruction_group_list *igl)
{
uint32_t n_custom_instr = instruction_group_list_custom_instructions_count(igl);
/* Check that enough space is available within the pipeline instruction table to store all
* the custom instructions.
*/
if (INSTR_CUSTOM_0 + n_custom_instr > RTE_SWX_PIPELINE_INSTRUCTION_TABLE_SIZE_MAX)
return -ENOSPC;
return 0;
}
static void
pipeline_adjust(struct rte_swx_pipeline *p, struct instruction_group_list *igl)
{
struct instruction_group *g;
uint32_t i;
/* Pipeline table instructions. */
for (i = 0; i < p->n_instructions; i++) {
struct instruction *instr = &p->instructions[i];
if (instr->type == INSTR_TABLE)
instr->type = INSTR_TABLE_AF;
if (instr->type == INSTR_LEARNER)
instr->type = INSTR_LEARNER_AF;
}
/* Pipeline custom instructions. */
i = 0;
TAILQ_FOREACH(g, igl, node) {
struct instruction *instr = &p->instructions[g->first_instr_id];
uint32_t j;
if (g->first_instr_id == g->last_instr_id)
continue;
/* Install a new custom instruction. */
p->instruction_table[INSTR_CUSTOM_0 + i] = g->func;
/* First instruction of the group: change its type to the new custom instruction. */
instr->type = INSTR_CUSTOM_0 + i;
/* All the subsequent instructions of the group: invalidate. */
for (j = g->first_instr_id + 1; j <= g->last_instr_id; j++) {
struct instruction_data *data = &p->instruction_data[j];
data->invalid = 1;
}
i++;
}
/* Remove the invalidated instructions. */
p->n_instructions = instr_compact(p->instructions, p->instruction_data, p->n_instructions);
/* Resolve the jump destination for any "standalone" jump instructions (i.e. those jump
* instructions that are the only instruction within their group, so they were left
* unmodified).
*/
instr_jmp_resolve(p->instructions, p->instruction_data, p->n_instructions);
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
static int
pipeline_compile(struct rte_swx_pipeline *p)
{
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
struct instruction_group_list *igl = NULL;
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
int status = 0;
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
igl = instruction_group_list_create(p);
if (!igl) {
status = -ENOMEM;
goto free;
}
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
/* Code generation. */
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
status = pipeline_codegen(p, igl);
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
if (status)
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
goto free;
pipeline: build shared object for pipeline Build the generated C file into a shared object library. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com> Signed-off-by: Cunming Liang <cunming.liang@intel.com>
2021-09-13 16:44:42 +00:00
/* Build and load the shared object library. */
status = pipeline_libload(p, igl);
if (status)
goto free;
pipeline: enable pipeline compilation Commit the pipeline changes when the compilation process is successful: change the table lookup instructions to execute the action function for each action, replace the regular pipeline instructions with the custom instructions. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:43 +00:00
/* Adjust instructions. */
status = pipeline_adjust_check(p, igl);
if (status)
goto free;
pipeline_adjust(p, igl);
pipeline: generate custom instruction functions Generate a C function for each custom instruction, which essentially consolidate multiple regular instructions into a single function call. The pipeline program is split into groups of instructions, and a custom instruction is generated for each group that has more than one instruction. Special care is taken the instructions that can do thread yield (RX, extern) and for those that can change the instruction pointer (TX, near/far jump). Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:41 +00:00
free:
instruction_group_list_free(igl);
pipeline: introduce pipeline compilation Lay the foundation to generate C code for the pipeline: C functions for actions and custom instructions are generated, built as shared object library and loaded into the pipeline. Signed-off-by: Cristian Dumitrescu <cristian.dumitrescu@intel.com>
2021-09-13 16:44:38 +00:00
return status;
}
Reference in New Issue Copy Permalink