numam-dpdk/lib/table/rte_swx_table_wm.c
Bruce Richardson 99a2dd955f lib: remove librte_ prefix from directory names
There is no reason for the DPDK libraries to all have 'librte_' prefix on
the directory names. This prefix makes the directory names longer and also
makes it awkward to add features referring to individual libraries in the
build - should the lib names be specified with or without the prefix.
Therefore, we can just remove the library prefix and use the library's
unique name as the directory name, i.e. 'eal' rather than 'librte_eal'

Signed-off-by: Bruce Richardson <bruce.richardson@intel.com>
2021-04-21 14:04:09 +02:00

470 lines
9.6 KiB
C

/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2020 Intel Corporation
*/
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <errno.h>
#include <rte_common.h>
#include <rte_prefetch.h>
#include <rte_cycles.h>
#include <rte_acl.h>
#include "rte_swx_table_wm.h"
#ifndef RTE_SWX_TABLE_EM_USE_HUGE_PAGES
#define RTE_SWX_TABLE_EM_USE_HUGE_PAGES 1
#endif
#if RTE_SWX_TABLE_EM_USE_HUGE_PAGES
#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)
{
return numa_alloc_onnode(size, numa_node);
}
static void
env_free(void *start, size_t size)
{
numa_free(start, size);
}
#endif
static char *get_unique_name(void)
{
uint64_t tsc = rte_get_tsc_cycles();
size_t size = sizeof(uint64_t) * 2 + 1;
char *name = calloc(1, size);
if (!name)
return NULL;
snprintf(name, size, "%016" PRIx64, tsc);
return name;
}
static uint32_t
count_entries(struct rte_swx_table_entry_list *entries)
{
struct rte_swx_table_entry *entry;
uint32_t n_entries = 0;
if (!entries)
return 0;
TAILQ_FOREACH(entry, entries, node)
n_entries++;
return n_entries;
}
static int
acl_table_cfg_get(struct rte_acl_config *cfg, struct rte_swx_table_params *p)
{
uint32_t byte_id = 0, field_id = 0;
/* cfg->num_categories. */
cfg->num_categories = 1;
/* cfg->defs and cfg->num_fields. */
for (byte_id = 0; byte_id < p->key_size; ) {
uint32_t field_size = field_id ? 4 : 1;
uint8_t byte = p->key_mask0 ? p->key_mask0[byte_id] : 0xFF;
if (!byte) {
byte_id++;
continue;
}
if (field_id == RTE_ACL_MAX_FIELDS)
return -1;
cfg->defs[field_id].type = RTE_ACL_FIELD_TYPE_BITMASK;
cfg->defs[field_id].size = field_size;
cfg->defs[field_id].field_index = field_id;
cfg->defs[field_id].input_index = field_id;
cfg->defs[field_id].offset = p->key_offset + byte_id;
field_id++;
byte_id += field_size;
}
if (!field_id)
return -1;
cfg->num_fields = field_id;
/* cfg->max_size. */
cfg->max_size = 0;
return 0;
}
static void
acl_table_rule_field8(uint8_t *value,
uint8_t *mask,
uint8_t *key_mask0,
uint8_t *key_mask,
uint8_t *key,
uint32_t offset)
{
uint8_t km0, km;
km0 = key_mask0 ? key_mask0[offset] : 0xFF;
km = key_mask ? key_mask[offset] : 0xFF;
*value = key[offset];
*mask = km0 & km;
}
static void
acl_table_rule_field32(uint32_t *value,
uint32_t *mask,
uint8_t *key_mask0,
uint8_t *key_mask,
uint8_t *key,
uint32_t key_size,
uint32_t offset)
{
uint32_t km0[4], km[4], k[4];
uint32_t byte_id;
/* Byte 0 = MSB, byte 3 = LSB. */
for (byte_id = 0; byte_id < 4; byte_id++) {
if (offset + byte_id >= key_size) {
km0[byte_id] = 0;
km[byte_id] = 0;
k[byte_id] = 0;
continue;
}
km0[byte_id] = key_mask0 ? key_mask0[offset + byte_id] : 0xFF;
km[byte_id] = key_mask ? key_mask[offset + byte_id] : 0xFF;
k[byte_id] = key[offset + byte_id];
}
*value = (k[0] << 24) |
(k[1] << 16) |
(k[2] << 8) |
k[3];
*mask = ((km[0] & km0[0]) << 24) |
((km[1] & km0[1]) << 16) |
((km[2] & km0[2]) << 8) |
(km[3] & km0[3]);
}
RTE_ACL_RULE_DEF(acl_rule, RTE_ACL_MAX_FIELDS);
static struct rte_acl_rule *
acl_table_rules_get(struct rte_acl_config *acl_cfg,
struct rte_swx_table_params *p,
struct rte_swx_table_entry_list *entries,
uint32_t n_entries)
{
struct rte_swx_table_entry *entry;
uint8_t *memory;
uint32_t acl_rule_size = RTE_ACL_RULE_SZ(acl_cfg->num_fields);
uint32_t n_fields = acl_cfg->num_fields;
uint32_t rule_id;
if (!n_entries)
return NULL;
memory = malloc(n_entries * acl_rule_size);
if (!memory)
return NULL;
rule_id = 0;
TAILQ_FOREACH(entry, entries, node) {
uint8_t *m = &memory[rule_id * acl_rule_size];
struct acl_rule *acl_rule = (struct acl_rule *)m;
uint32_t field_id;
acl_rule->data.category_mask = 1;
acl_rule->data.priority = RTE_ACL_MAX_PRIORITY -
entry->key_priority;
acl_rule->data.userdata = rule_id + 1;
for (field_id = 0; field_id < n_fields; field_id++) {
struct rte_acl_field *f = &acl_rule->field[field_id];
uint32_t size = acl_cfg->defs[field_id].size;
uint32_t offset = acl_cfg->defs[field_id].offset -
p->key_offset;
if (size == 1) {
uint8_t value, mask;
acl_table_rule_field8(&value,
&mask,
p->key_mask0,
entry->key_mask,
entry->key,
offset);
f->value.u8 = value;
f->mask_range.u8 = mask;
} else {
uint32_t value, mask;
acl_table_rule_field32(&value,
&mask,
p->key_mask0,
entry->key_mask,
entry->key,
p->key_size,
offset);
f->value.u32 = value;
f->mask_range.u32 = mask;
}
}
rule_id++;
}
return (struct rte_acl_rule *)memory;
}
/* When the table to be created has no rules, the expected behavior is to always
* get lookup miss for any input key. To achieve this, we add a single bogus
* rule to the table with the rule user data set to 0, i.e. the value returned
* when lookup miss takes place. Whether lookup hit (the bogus rule is hit) or
* miss, a user data of 0 is returned, which for the ACL library is equivalent
* to lookup miss.
*/
static struct rte_acl_rule *
acl_table_rules_default_get(struct rte_acl_config *acl_cfg)
{
struct rte_acl_rule *acl_rule;
uint32_t acl_rule_size = RTE_ACL_RULE_SZ(acl_cfg->num_fields);
acl_rule = calloc(1, acl_rule_size);
if (!acl_rule)
return NULL;
acl_rule->data.category_mask = 1;
acl_rule->data.priority = RTE_ACL_MAX_PRIORITY;
acl_rule->data.userdata = 0;
memset(&acl_rule[1], 0xFF, acl_rule_size - sizeof(struct rte_acl_rule));
return acl_rule;
}
static struct rte_acl_ctx *
acl_table_create(struct rte_swx_table_params *params,
struct rte_swx_table_entry_list *entries,
uint32_t n_entries,
int numa_node)
{
struct rte_acl_param acl_params = {0};
struct rte_acl_config acl_cfg = {0};
struct rte_acl_ctx *acl_ctx = NULL;
struct rte_acl_rule *acl_rules = NULL;
char *name = NULL;
int status = 0;
/* ACL config data structures. */
name = get_unique_name();
if (!name) {
status = -1;
goto free_resources;
}
status = acl_table_cfg_get(&acl_cfg, params);
if (status)
goto free_resources;
acl_rules = n_entries ?
acl_table_rules_get(&acl_cfg, params, entries, n_entries) :
acl_table_rules_default_get(&acl_cfg);
if (!acl_rules) {
status = -1;
goto free_resources;
}
n_entries = n_entries ? n_entries : 1;
/* ACL create. */
acl_params.name = name;
acl_params.socket_id = numa_node;
acl_params.rule_size = RTE_ACL_RULE_SZ(acl_cfg.num_fields);
acl_params.max_rule_num = n_entries;
acl_ctx = rte_acl_create(&acl_params);
if (!acl_ctx) {
status = -1;
goto free_resources;
}
/* ACL add rules. */
status = rte_acl_add_rules(acl_ctx, acl_rules, n_entries);
if (status)
goto free_resources;
/* ACL build. */
status = rte_acl_build(acl_ctx, &acl_cfg);
free_resources:
if (status && acl_ctx)
rte_acl_free(acl_ctx);
free(acl_rules);
free(name);
return status ? NULL : acl_ctx;
}
static void
entry_data_copy(uint8_t *data,
struct rte_swx_table_entry_list *entries,
uint32_t n_entries,
uint32_t entry_data_size)
{
struct rte_swx_table_entry *entry;
uint32_t i = 0;
if (!n_entries)
return;
TAILQ_FOREACH(entry, entries, node) {
uint64_t *d = (uint64_t *)&data[i * entry_data_size];
d[0] = entry->action_id;
memcpy(&d[1], entry->action_data, entry_data_size - 8);
i++;
}
}
struct table {
struct rte_acl_ctx *acl_ctx;
uint8_t *data;
size_t total_size;
uint32_t entry_data_size;
};
static void
table_free(void *table)
{
struct table *t = table;
if (!t)
return;
if (t->acl_ctx)
rte_acl_free(t->acl_ctx);
env_free(t, t->total_size);
}
static void *
table_create(struct rte_swx_table_params *params,
struct rte_swx_table_entry_list *entries,
const char *args __rte_unused,
int numa_node)
{
struct table *t = NULL;
size_t meta_sz, data_sz, total_size;
uint32_t entry_data_size;
uint32_t n_entries = count_entries(entries);
/* Check input arguments. */
if (!params || !params->key_size)
goto error;
/* Memory allocation and initialization. */
entry_data_size = 8 + params->action_data_size;
meta_sz = sizeof(struct table);
data_sz = n_entries * entry_data_size;
total_size = meta_sz + data_sz;
t = env_malloc(total_size, RTE_CACHE_LINE_SIZE, numa_node);
if (!t)
goto error;
memset(t, 0, total_size);
t->entry_data_size = entry_data_size;
t->total_size = total_size;
t->data = (uint8_t *)&t[1];
t->acl_ctx = acl_table_create(params, entries, n_entries, numa_node);
if (!t->acl_ctx)
goto error;
entry_data_copy(t->data, entries, n_entries, entry_data_size);
return t;
error:
table_free(t);
return NULL;
}
struct mailbox {
};
static uint64_t
table_mailbox_size_get(void)
{
return sizeof(struct mailbox);
}
static int
table_lookup(void *table,
void *mailbox __rte_unused,
const uint8_t **key,
uint64_t *action_id,
uint8_t **action_data,
int *hit)
{
struct table *t = table;
uint8_t *data;
uint32_t user_data;
rte_acl_classify(t->acl_ctx, key, &user_data, 1, 1);
if (!user_data) {
*hit = 0;
return 1;
}
data = &t->data[(user_data - 1) * t->entry_data_size];
*action_id = ((uint64_t *)data)[0];
*action_data = &data[8];
*hit = 1;
return 1;
}
struct rte_swx_table_ops rte_swx_table_wildcard_match_ops = {
.footprint_get = NULL,
.mailbox_size_get = table_mailbox_size_get,
.create = table_create,
.add = NULL,
.del = NULL,
.lkp = (rte_swx_table_lookup_t)table_lookup,
.free = table_free,
};