numam-dpdk/lib/librte_table/rte_table_hash_key32.c
Stephen Hemminger c5ba278876 lib: remove unnecessary void cast
Remove unnecessary casts of void * pointers to a specific type.

Signed-off-by: Stephen Hemminger <stephen@networkplumber.org>
2017-04-11 18:05:10 +02:00

1145 lines
32 KiB
C

/*-
* BSD LICENSE
*
* Copyright(c) 2010-2014 Intel Corporation. All rights reserved.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <string.h>
#include <stdio.h>
#include <rte_common.h>
#include <rte_mbuf.h>
#include <rte_memory.h>
#include <rte_malloc.h>
#include <rte_log.h>
#include "rte_table_hash.h"
#include "rte_lru.h"
#define RTE_TABLE_HASH_KEY_SIZE 32
#define RTE_BUCKET_ENTRY_VALID 0x1LLU
#ifdef RTE_TABLE_STATS_COLLECT
#define RTE_TABLE_HASH_KEY32_STATS_PKTS_IN_ADD(table, val) \
table->stats.n_pkts_in += val
#define RTE_TABLE_HASH_KEY32_STATS_PKTS_LOOKUP_MISS(table, val) \
table->stats.n_pkts_lookup_miss += val
#else
#define RTE_TABLE_HASH_KEY32_STATS_PKTS_IN_ADD(table, val)
#define RTE_TABLE_HASH_KEY32_STATS_PKTS_LOOKUP_MISS(table, val)
#endif
struct rte_bucket_4_32 {
/* Cache line 0 */
uint64_t signature[4 + 1];
uint64_t lru_list;
struct rte_bucket_4_32 *next;
uint64_t next_valid;
/* Cache lines 1 and 2 */
uint64_t key[4][4];
/* Cache line 3 */
uint8_t data[0];
};
struct rte_table_hash {
struct rte_table_stats stats;
/* Input parameters */
uint32_t n_buckets;
uint32_t n_entries_per_bucket;
uint32_t key_size;
uint32_t entry_size;
uint32_t bucket_size;
uint32_t signature_offset;
uint32_t key_offset;
rte_table_hash_op_hash f_hash;
uint64_t seed;
/* Extendible buckets */
uint32_t n_buckets_ext;
uint32_t stack_pos;
uint32_t *stack;
/* Lookup table */
uint8_t memory[0] __rte_cache_aligned;
};
static int
check_params_create_lru(struct rte_table_hash_key32_lru_params *params) {
/* n_entries */
if (params->n_entries == 0) {
RTE_LOG(ERR, TABLE, "%s: n_entries is zero\n", __func__);
return -EINVAL;
}
/* f_hash */
if (params->f_hash == NULL) {
RTE_LOG(ERR, TABLE, "%s: f_hash function pointer is NULL\n",
__func__);
return -EINVAL;
}
return 0;
}
static void *
rte_table_hash_create_key32_lru(void *params,
int socket_id,
uint32_t entry_size)
{
struct rte_table_hash_key32_lru_params *p =
(struct rte_table_hash_key32_lru_params *) params;
struct rte_table_hash *f;
uint32_t n_buckets, n_entries_per_bucket, key_size, bucket_size_cl;
uint32_t total_size, i;
/* Check input parameters */
if ((check_params_create_lru(p) != 0) ||
((sizeof(struct rte_table_hash) % RTE_CACHE_LINE_SIZE) != 0) ||
((sizeof(struct rte_bucket_4_32) % 64) != 0)) {
return NULL;
}
n_entries_per_bucket = 4;
key_size = 32;
/* Memory allocation */
n_buckets = rte_align32pow2((p->n_entries + n_entries_per_bucket - 1) /
n_entries_per_bucket);
bucket_size_cl = (sizeof(struct rte_bucket_4_32) + n_entries_per_bucket
* entry_size + RTE_CACHE_LINE_SIZE - 1) / RTE_CACHE_LINE_SIZE;
total_size = sizeof(struct rte_table_hash) + n_buckets *
bucket_size_cl * RTE_CACHE_LINE_SIZE;
f = rte_zmalloc_socket("TABLE", total_size, RTE_CACHE_LINE_SIZE, socket_id);
if (f == NULL) {
RTE_LOG(ERR, TABLE,
"%s: Cannot allocate %u bytes for hash table\n",
__func__, total_size);
return NULL;
}
RTE_LOG(INFO, TABLE,
"%s: Hash table memory footprint is %u bytes\n", __func__,
total_size);
/* Memory initialization */
f->n_buckets = n_buckets;
f->n_entries_per_bucket = n_entries_per_bucket;
f->key_size = key_size;
f->entry_size = entry_size;
f->bucket_size = bucket_size_cl * RTE_CACHE_LINE_SIZE;
f->signature_offset = p->signature_offset;
f->key_offset = p->key_offset;
f->f_hash = p->f_hash;
f->seed = p->seed;
for (i = 0; i < n_buckets; i++) {
struct rte_bucket_4_32 *bucket;
bucket = (struct rte_bucket_4_32 *) &f->memory[i *
f->bucket_size];
bucket->lru_list = 0x0000000100020003LLU;
}
return f;
}
static int
rte_table_hash_free_key32_lru(void *table)
{
struct rte_table_hash *f = table;
/* Check input parameters */
if (f == NULL) {
RTE_LOG(ERR, TABLE, "%s: table parameter is NULL\n", __func__);
return -EINVAL;
}
rte_free(f);
return 0;
}
static int
rte_table_hash_entry_add_key32_lru(
void *table,
void *key,
void *entry,
int *key_found,
void **entry_ptr)
{
struct rte_table_hash *f = table;
struct rte_bucket_4_32 *bucket;
uint64_t signature, pos;
uint32_t bucket_index, i;
signature = f->f_hash(key, f->key_size, f->seed);
bucket_index = signature & (f->n_buckets - 1);
bucket = (struct rte_bucket_4_32 *)
&f->memory[bucket_index * f->bucket_size];
signature |= RTE_BUCKET_ENTRY_VALID;
/* Key is present in the bucket */
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if ((bucket_signature == signature) &&
(memcmp(key, bucket_key, f->key_size) == 0)) {
uint8_t *bucket_data = &bucket->data[i * f->entry_size];
memcpy(bucket_data, entry, f->entry_size);
lru_update(bucket, i);
*key_found = 1;
*entry_ptr = (void *) bucket_data;
return 0;
}
}
/* Key is not present in the bucket */
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if (bucket_signature == 0) {
uint8_t *bucket_data = &bucket->data[i * f->entry_size];
bucket->signature[i] = signature;
memcpy(bucket_key, key, f->key_size);
memcpy(bucket_data, entry, f->entry_size);
lru_update(bucket, i);
*key_found = 0;
*entry_ptr = (void *) bucket_data;
return 0;
}
}
/* Bucket full: replace LRU entry */
pos = lru_pos(bucket);
bucket->signature[pos] = signature;
memcpy(bucket->key[pos], key, f->key_size);
memcpy(&bucket->data[pos * f->entry_size], entry, f->entry_size);
lru_update(bucket, pos);
*key_found = 0;
*entry_ptr = (void *) &bucket->data[pos * f->entry_size];
return 0;
}
static int
rte_table_hash_entry_delete_key32_lru(
void *table,
void *key,
int *key_found,
void *entry)
{
struct rte_table_hash *f = table;
struct rte_bucket_4_32 *bucket;
uint64_t signature;
uint32_t bucket_index, i;
signature = f->f_hash(key, f->key_size, f->seed);
bucket_index = signature & (f->n_buckets - 1);
bucket = (struct rte_bucket_4_32 *)
&f->memory[bucket_index * f->bucket_size];
signature |= RTE_BUCKET_ENTRY_VALID;
/* Key is present in the bucket */
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if ((bucket_signature == signature) &&
(memcmp(key, bucket_key, f->key_size) == 0)) {
uint8_t *bucket_data = &bucket->data[i * f->entry_size];
bucket->signature[i] = 0;
*key_found = 1;
if (entry)
memcpy(entry, bucket_data, f->entry_size);
return 0;
}
}
/* Key is not present in the bucket */
*key_found = 0;
return 0;
}
static int
check_params_create_ext(struct rte_table_hash_key32_ext_params *params) {
/* n_entries */
if (params->n_entries == 0) {
RTE_LOG(ERR, TABLE, "%s: n_entries is zero\n", __func__);
return -EINVAL;
}
/* n_entries_ext */
if (params->n_entries_ext == 0) {
RTE_LOG(ERR, TABLE, "%s: n_entries_ext is zero\n", __func__);
return -EINVAL;
}
/* f_hash */
if (params->f_hash == NULL) {
RTE_LOG(ERR, TABLE, "%s: f_hash function pointer is NULL\n",
__func__);
return -EINVAL;
}
return 0;
}
static void *
rte_table_hash_create_key32_ext(void *params,
int socket_id,
uint32_t entry_size)
{
struct rte_table_hash_key32_ext_params *p =
params;
struct rte_table_hash *f;
uint32_t n_buckets, n_buckets_ext, n_entries_per_bucket;
uint32_t key_size, bucket_size_cl, stack_size_cl, total_size, i;
/* Check input parameters */
if ((check_params_create_ext(p) != 0) ||
((sizeof(struct rte_table_hash) % RTE_CACHE_LINE_SIZE) != 0) ||
((sizeof(struct rte_bucket_4_32) % 64) != 0))
return NULL;
n_entries_per_bucket = 4;
key_size = 32;
/* Memory allocation */
n_buckets = rte_align32pow2((p->n_entries + n_entries_per_bucket - 1) /
n_entries_per_bucket);
n_buckets_ext = (p->n_entries_ext + n_entries_per_bucket - 1) /
n_entries_per_bucket;
bucket_size_cl = (sizeof(struct rte_bucket_4_32) + n_entries_per_bucket
* entry_size + RTE_CACHE_LINE_SIZE - 1) / RTE_CACHE_LINE_SIZE;
stack_size_cl = (n_buckets_ext * sizeof(uint32_t) + RTE_CACHE_LINE_SIZE - 1)
/ RTE_CACHE_LINE_SIZE;
total_size = sizeof(struct rte_table_hash) +
((n_buckets + n_buckets_ext) * bucket_size_cl + stack_size_cl) *
RTE_CACHE_LINE_SIZE;
f = rte_zmalloc_socket("TABLE", total_size, RTE_CACHE_LINE_SIZE, socket_id);
if (f == NULL) {
RTE_LOG(ERR, TABLE,
"%s: Cannot allocate %u bytes for hash table\n",
__func__, total_size);
return NULL;
}
RTE_LOG(INFO, TABLE,
"%s: Hash table memory footprint is %u bytes\n", __func__,
total_size);
/* Memory initialization */
f->n_buckets = n_buckets;
f->n_entries_per_bucket = n_entries_per_bucket;
f->key_size = key_size;
f->entry_size = entry_size;
f->bucket_size = bucket_size_cl * RTE_CACHE_LINE_SIZE;
f->signature_offset = p->signature_offset;
f->key_offset = p->key_offset;
f->f_hash = p->f_hash;
f->seed = p->seed;
f->n_buckets_ext = n_buckets_ext;
f->stack_pos = n_buckets_ext;
f->stack = (uint32_t *)
&f->memory[(n_buckets + n_buckets_ext) * f->bucket_size];
for (i = 0; i < n_buckets_ext; i++)
f->stack[i] = i;
return f;
}
static int
rte_table_hash_free_key32_ext(void *table)
{
struct rte_table_hash *f = table;
/* Check input parameters */
if (f == NULL) {
RTE_LOG(ERR, TABLE, "%s: table parameter is NULL\n", __func__);
return -EINVAL;
}
rte_free(f);
return 0;
}
static int
rte_table_hash_entry_add_key32_ext(
void *table,
void *key,
void *entry,
int *key_found,
void **entry_ptr)
{
struct rte_table_hash *f = table;
struct rte_bucket_4_32 *bucket0, *bucket, *bucket_prev;
uint64_t signature;
uint32_t bucket_index, i;
signature = f->f_hash(key, f->key_size, f->seed);
bucket_index = signature & (f->n_buckets - 1);
bucket0 = (struct rte_bucket_4_32 *)
&f->memory[bucket_index * f->bucket_size];
signature |= RTE_BUCKET_ENTRY_VALID;
/* Key is present in the bucket */
for (bucket = bucket0; bucket != NULL; bucket = bucket->next) {
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if ((bucket_signature == signature) &&
(memcmp(key, bucket_key, f->key_size) == 0)) {
uint8_t *bucket_data = &bucket->data[i *
f->entry_size];
memcpy(bucket_data, entry, f->entry_size);
*key_found = 1;
*entry_ptr = (void *) bucket_data;
return 0;
}
}
}
/* Key is not present in the bucket */
for (bucket_prev = NULL, bucket = bucket0; bucket != NULL;
bucket_prev = bucket, bucket = bucket->next)
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if (bucket_signature == 0) {
uint8_t *bucket_data = &bucket->data[i *
f->entry_size];
bucket->signature[i] = signature;
memcpy(bucket_key, key, f->key_size);
memcpy(bucket_data, entry, f->entry_size);
*key_found = 0;
*entry_ptr = (void *) bucket_data;
return 0;
}
}
/* Bucket full: extend bucket */
if (f->stack_pos > 0) {
bucket_index = f->stack[--f->stack_pos];
bucket = (struct rte_bucket_4_32 *)
&f->memory[(f->n_buckets + bucket_index) *
f->bucket_size];
bucket_prev->next = bucket;
bucket_prev->next_valid = 1;
bucket->signature[0] = signature;
memcpy(bucket->key[0], key, f->key_size);
memcpy(&bucket->data[0], entry, f->entry_size);
*key_found = 0;
*entry_ptr = (void *) &bucket->data[0];
return 0;
}
return -ENOSPC;
}
static int
rte_table_hash_entry_delete_key32_ext(
void *table,
void *key,
int *key_found,
void *entry)
{
struct rte_table_hash *f = table;
struct rte_bucket_4_32 *bucket0, *bucket, *bucket_prev;
uint64_t signature;
uint32_t bucket_index, i;
signature = f->f_hash(key, f->key_size, f->seed);
bucket_index = signature & (f->n_buckets - 1);
bucket0 = (struct rte_bucket_4_32 *)
&f->memory[bucket_index * f->bucket_size];
signature |= RTE_BUCKET_ENTRY_VALID;
/* Key is present in the bucket */
for (bucket_prev = NULL, bucket = bucket0; bucket != NULL;
bucket_prev = bucket, bucket = bucket->next)
for (i = 0; i < 4; i++) {
uint64_t bucket_signature = bucket->signature[i];
uint8_t *bucket_key = (uint8_t *) bucket->key[i];
if ((bucket_signature == signature) &&
(memcmp(key, bucket_key, f->key_size) == 0)) {
uint8_t *bucket_data = &bucket->data[i *
f->entry_size];
bucket->signature[i] = 0;
*key_found = 1;
if (entry)
memcpy(entry, bucket_data,
f->entry_size);
if ((bucket->signature[0] == 0) &&
(bucket->signature[1] == 0) &&
(bucket->signature[2] == 0) &&
(bucket->signature[3] == 0) &&
(bucket_prev != NULL)) {
bucket_prev->next = bucket->next;
bucket_prev->next_valid =
bucket->next_valid;
memset(bucket, 0,
sizeof(struct rte_bucket_4_32));
bucket_index = (((uint8_t *)bucket -
(uint8_t *)f->memory)/f->bucket_size) - f->n_buckets;
f->stack[f->stack_pos++] = bucket_index;
}
return 0;
}
}
/* Key is not present in the bucket */
*key_found = 0;
return 0;
}
#define lookup_key32_cmp(key_in, bucket, pos) \
{ \
uint64_t xor[4][4], or[4], signature[4]; \
\
signature[0] = ((~bucket->signature[0]) & 1); \
signature[1] = ((~bucket->signature[1]) & 1); \
signature[2] = ((~bucket->signature[2]) & 1); \
signature[3] = ((~bucket->signature[3]) & 1); \
\
xor[0][0] = key_in[0] ^ bucket->key[0][0]; \
xor[0][1] = key_in[1] ^ bucket->key[0][1]; \
xor[0][2] = key_in[2] ^ bucket->key[0][2]; \
xor[0][3] = key_in[3] ^ bucket->key[0][3]; \
\
xor[1][0] = key_in[0] ^ bucket->key[1][0]; \
xor[1][1] = key_in[1] ^ bucket->key[1][1]; \
xor[1][2] = key_in[2] ^ bucket->key[1][2]; \
xor[1][3] = key_in[3] ^ bucket->key[1][3]; \
\
xor[2][0] = key_in[0] ^ bucket->key[2][0]; \
xor[2][1] = key_in[1] ^ bucket->key[2][1]; \
xor[2][2] = key_in[2] ^ bucket->key[2][2]; \
xor[2][3] = key_in[3] ^ bucket->key[2][3]; \
\
xor[3][0] = key_in[0] ^ bucket->key[3][0]; \
xor[3][1] = key_in[1] ^ bucket->key[3][1]; \
xor[3][2] = key_in[2] ^ bucket->key[3][2]; \
xor[3][3] = key_in[3] ^ bucket->key[3][3]; \
\
or[0] = xor[0][0] | xor[0][1] | xor[0][2] | xor[0][3] | signature[0];\
or[1] = xor[1][0] | xor[1][1] | xor[1][2] | xor[1][3] | signature[1];\
or[2] = xor[2][0] | xor[2][1] | xor[2][2] | xor[2][3] | signature[2];\
or[3] = xor[3][0] | xor[3][1] | xor[3][2] | xor[3][3] | signature[3];\
\
pos = 4; \
if (or[0] == 0) \
pos = 0; \
if (or[1] == 0) \
pos = 1; \
if (or[2] == 0) \
pos = 2; \
if (or[3] == 0) \
pos = 3; \
}
#define lookup1_stage0(pkt0_index, mbuf0, pkts, pkts_mask, f) \
{ \
uint64_t pkt_mask; \
uint32_t key_offset = f->key_offset; \
\
pkt0_index = __builtin_ctzll(pkts_mask); \
pkt_mask = 1LLU << pkt0_index; \
pkts_mask &= ~pkt_mask; \
\
mbuf0 = pkts[pkt0_index]; \
rte_prefetch0(RTE_MBUF_METADATA_UINT8_PTR(mbuf0, key_offset));\
}
#define lookup1_stage1(mbuf1, bucket1, f) \
{ \
uint64_t signature; \
uint32_t bucket_index; \
\
signature = RTE_MBUF_METADATA_UINT32(mbuf1, f->signature_offset);\
bucket_index = signature & (f->n_buckets - 1); \
bucket1 = (struct rte_bucket_4_32 *) \
&f->memory[bucket_index * f->bucket_size]; \
rte_prefetch0(bucket1); \
rte_prefetch0((void *)(((uintptr_t) bucket1) + RTE_CACHE_LINE_SIZE));\
rte_prefetch0((void *)(((uintptr_t) bucket1) + 2 * RTE_CACHE_LINE_SIZE));\
}
#define lookup1_stage2_lru(pkt2_index, mbuf2, bucket2, \
pkts_mask_out, entries, f) \
{ \
void *a; \
uint64_t pkt_mask; \
uint64_t *key; \
uint32_t pos; \
\
key = RTE_MBUF_METADATA_UINT64_PTR(mbuf2, f->key_offset);\
\
lookup_key32_cmp(key, bucket2, pos); \
\
pkt_mask = (bucket2->signature[pos] & 1LLU) << pkt2_index;\
pkts_mask_out |= pkt_mask; \
\
a = (void *) &bucket2->data[pos * f->entry_size]; \
rte_prefetch0(a); \
entries[pkt2_index] = a; \
lru_update(bucket2, pos); \
}
#define lookup1_stage2_ext(pkt2_index, mbuf2, bucket2, pkts_mask_out,\
entries, buckets_mask, buckets, keys, f) \
{ \
struct rte_bucket_4_32 *bucket_next; \
void *a; \
uint64_t pkt_mask, bucket_mask; \
uint64_t *key; \
uint32_t pos; \
\
key = RTE_MBUF_METADATA_UINT64_PTR(mbuf2, f->key_offset);\
\
lookup_key32_cmp(key, bucket2, pos); \
\
pkt_mask = (bucket2->signature[pos] & 1LLU) << pkt2_index;\
pkts_mask_out |= pkt_mask; \
\
a = (void *) &bucket2->data[pos * f->entry_size]; \
rte_prefetch0(a); \
entries[pkt2_index] = a; \
\
bucket_mask = (~pkt_mask) & (bucket2->next_valid << pkt2_index);\
buckets_mask |= bucket_mask; \
bucket_next = bucket2->next; \
buckets[pkt2_index] = bucket_next; \
keys[pkt2_index] = key; \
}
#define lookup_grinder(pkt_index, buckets, keys, pkts_mask_out, \
entries, buckets_mask, f) \
{ \
struct rte_bucket_4_32 *bucket, *bucket_next; \
void *a; \
uint64_t pkt_mask, bucket_mask; \
uint64_t *key; \
uint32_t pos; \
\
bucket = buckets[pkt_index]; \
key = keys[pkt_index]; \
\
lookup_key32_cmp(key, bucket, pos); \
\
pkt_mask = (bucket->signature[pos] & 1LLU) << pkt_index;\
pkts_mask_out |= pkt_mask; \
\
a = (void *) &bucket->data[pos * f->entry_size]; \
rte_prefetch0(a); \
entries[pkt_index] = a; \
\
bucket_mask = (~pkt_mask) & (bucket->next_valid << pkt_index);\
buckets_mask |= bucket_mask; \
bucket_next = bucket->next; \
rte_prefetch0(bucket_next); \
rte_prefetch0((void *)(((uintptr_t) bucket_next) + RTE_CACHE_LINE_SIZE));\
rte_prefetch0((void *)(((uintptr_t) bucket_next) + \
2 * RTE_CACHE_LINE_SIZE)); \
buckets[pkt_index] = bucket_next; \
keys[pkt_index] = key; \
}
#define lookup2_stage0(pkt00_index, pkt01_index, mbuf00, mbuf01,\
pkts, pkts_mask, f) \
{ \
uint64_t pkt00_mask, pkt01_mask; \
uint32_t key_offset = f->key_offset; \
\
pkt00_index = __builtin_ctzll(pkts_mask); \
pkt00_mask = 1LLU << pkt00_index; \
pkts_mask &= ~pkt00_mask; \
\
mbuf00 = pkts[pkt00_index]; \
rte_prefetch0(RTE_MBUF_METADATA_UINT8_PTR(mbuf00, key_offset));\
\
pkt01_index = __builtin_ctzll(pkts_mask); \
pkt01_mask = 1LLU << pkt01_index; \
pkts_mask &= ~pkt01_mask; \
\
mbuf01 = pkts[pkt01_index]; \
rte_prefetch0(RTE_MBUF_METADATA_UINT8_PTR(mbuf01, key_offset));\
}
#define lookup2_stage0_with_odd_support(pkt00_index, pkt01_index,\
mbuf00, mbuf01, pkts, pkts_mask, f) \
{ \
uint64_t pkt00_mask, pkt01_mask; \
uint32_t key_offset = f->key_offset; \
\
pkt00_index = __builtin_ctzll(pkts_mask); \
pkt00_mask = 1LLU << pkt00_index; \
pkts_mask &= ~pkt00_mask; \
\
mbuf00 = pkts[pkt00_index]; \
rte_prefetch0(RTE_MBUF_METADATA_UINT8_PTR(mbuf00, key_offset)); \
\
pkt01_index = __builtin_ctzll(pkts_mask); \
if (pkts_mask == 0) \
pkt01_index = pkt00_index; \
\
pkt01_mask = 1LLU << pkt01_index; \
pkts_mask &= ~pkt01_mask; \
\
mbuf01 = pkts[pkt01_index]; \
rte_prefetch0(RTE_MBUF_METADATA_UINT8_PTR(mbuf01, key_offset)); \
}
#define lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f) \
{ \
uint64_t signature10, signature11; \
uint32_t bucket10_index, bucket11_index; \
\
signature10 = RTE_MBUF_METADATA_UINT32(mbuf10, f->signature_offset);\
bucket10_index = signature10 & (f->n_buckets - 1); \
bucket10 = (struct rte_bucket_4_32 *) \
&f->memory[bucket10_index * f->bucket_size]; \
rte_prefetch0(bucket10); \
rte_prefetch0((void *)(((uintptr_t) bucket10) + RTE_CACHE_LINE_SIZE));\
rte_prefetch0((void *)(((uintptr_t) bucket10) + 2 * RTE_CACHE_LINE_SIZE));\
\
signature11 = RTE_MBUF_METADATA_UINT32(mbuf11, f->signature_offset);\
bucket11_index = signature11 & (f->n_buckets - 1); \
bucket11 = (struct rte_bucket_4_32 *) \
&f->memory[bucket11_index * f->bucket_size]; \
rte_prefetch0(bucket11); \
rte_prefetch0((void *)(((uintptr_t) bucket11) + RTE_CACHE_LINE_SIZE));\
rte_prefetch0((void *)(((uintptr_t) bucket11) + 2 * RTE_CACHE_LINE_SIZE));\
}
#define lookup2_stage2_lru(pkt20_index, pkt21_index, mbuf20, mbuf21,\
bucket20, bucket21, pkts_mask_out, entries, f) \
{ \
void *a20, *a21; \
uint64_t pkt20_mask, pkt21_mask; \
uint64_t *key20, *key21; \
uint32_t pos20, pos21; \
\
key20 = RTE_MBUF_METADATA_UINT64_PTR(mbuf20, f->key_offset);\
key21 = RTE_MBUF_METADATA_UINT64_PTR(mbuf21, f->key_offset);\
\
lookup_key32_cmp(key20, bucket20, pos20); \
lookup_key32_cmp(key21, bucket21, pos21); \
\
pkt20_mask = (bucket20->signature[pos20] & 1LLU) << pkt20_index;\
pkt21_mask = (bucket21->signature[pos21] & 1LLU) << pkt21_index;\
pkts_mask_out |= pkt20_mask | pkt21_mask; \
\
a20 = (void *) &bucket20->data[pos20 * f->entry_size]; \
a21 = (void *) &bucket21->data[pos21 * f->entry_size]; \
rte_prefetch0(a20); \
rte_prefetch0(a21); \
entries[pkt20_index] = a20; \
entries[pkt21_index] = a21; \
lru_update(bucket20, pos20); \
lru_update(bucket21, pos21); \
}
#define lookup2_stage2_ext(pkt20_index, pkt21_index, mbuf20, mbuf21, bucket20, \
bucket21, pkts_mask_out, entries, buckets_mask, buckets, keys, f)\
{ \
struct rte_bucket_4_32 *bucket20_next, *bucket21_next; \
void *a20, *a21; \
uint64_t pkt20_mask, pkt21_mask, bucket20_mask, bucket21_mask;\
uint64_t *key20, *key21; \
uint32_t pos20, pos21; \
\
key20 = RTE_MBUF_METADATA_UINT64_PTR(mbuf20, f->key_offset);\
key21 = RTE_MBUF_METADATA_UINT64_PTR(mbuf21, f->key_offset);\
\
lookup_key32_cmp(key20, bucket20, pos20); \
lookup_key32_cmp(key21, bucket21, pos21); \
\
pkt20_mask = (bucket20->signature[pos20] & 1LLU) << pkt20_index;\
pkt21_mask = (bucket21->signature[pos21] & 1LLU) << pkt21_index;\
pkts_mask_out |= pkt20_mask | pkt21_mask; \
\
a20 = (void *) &bucket20->data[pos20 * f->entry_size]; \
a21 = (void *) &bucket21->data[pos21 * f->entry_size]; \
rte_prefetch0(a20); \
rte_prefetch0(a21); \
entries[pkt20_index] = a20; \
entries[pkt21_index] = a21; \
\
bucket20_mask = (~pkt20_mask) & (bucket20->next_valid << pkt20_index);\
bucket21_mask = (~pkt21_mask) & (bucket21->next_valid << pkt21_index);\
buckets_mask |= bucket20_mask | bucket21_mask; \
bucket20_next = bucket20->next; \
bucket21_next = bucket21->next; \
buckets[pkt20_index] = bucket20_next; \
buckets[pkt21_index] = bucket21_next; \
keys[pkt20_index] = key20; \
keys[pkt21_index] = key21; \
}
static int
rte_table_hash_lookup_key32_lru(
void *table,
struct rte_mbuf **pkts,
uint64_t pkts_mask,
uint64_t *lookup_hit_mask,
void **entries)
{
struct rte_table_hash *f = (struct rte_table_hash *) table;
struct rte_bucket_4_32 *bucket10, *bucket11, *bucket20, *bucket21;
struct rte_mbuf *mbuf00, *mbuf01, *mbuf10, *mbuf11, *mbuf20, *mbuf21;
uint32_t pkt00_index, pkt01_index, pkt10_index;
uint32_t pkt11_index, pkt20_index, pkt21_index;
uint64_t pkts_mask_out = 0;
__rte_unused uint32_t n_pkts_in = __builtin_popcountll(pkts_mask);
RTE_TABLE_HASH_KEY32_STATS_PKTS_IN_ADD(f, n_pkts_in);
/* Cannot run the pipeline with less than 5 packets */
if (__builtin_popcountll(pkts_mask) < 5) {
for ( ; pkts_mask; ) {
struct rte_bucket_4_32 *bucket;
struct rte_mbuf *mbuf;
uint32_t pkt_index;
lookup1_stage0(pkt_index, mbuf, pkts, pkts_mask, f);
lookup1_stage1(mbuf, bucket, f);
lookup1_stage2_lru(pkt_index, mbuf, bucket,
pkts_mask_out, entries, f);
}
*lookup_hit_mask = pkts_mask_out;
RTE_TABLE_HASH_KEY32_STATS_PKTS_LOOKUP_MISS(f, n_pkts_in - __builtin_popcountll(pkts_mask_out));
return 0;
}
/*
* Pipeline fill
*
*/
/* Pipeline stage 0 */
lookup2_stage0(pkt00_index, pkt01_index, mbuf00, mbuf01, pkts,
pkts_mask, f);
/* Pipeline feed */
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 0 */
lookup2_stage0(pkt00_index, pkt01_index, mbuf00, mbuf01, pkts,
pkts_mask, f);
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/*
* Pipeline run
*
*/
for ( ; pkts_mask; ) {
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 0 */
lookup2_stage0_with_odd_support(pkt00_index, pkt01_index,
mbuf00, mbuf01, pkts, pkts_mask, f);
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/* Pipeline stage 2 */
lookup2_stage2_lru(pkt20_index, pkt21_index,
mbuf20, mbuf21, bucket20, bucket21, pkts_mask_out,
entries, f);
}
/*
* Pipeline flush
*
*/
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/* Pipeline stage 2 */
lookup2_stage2_lru(pkt20_index, pkt21_index,
mbuf20, mbuf21, bucket20, bucket21, pkts_mask_out, entries, f);
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
/* Pipeline stage 2 */
lookup2_stage2_lru(pkt20_index, pkt21_index,
mbuf20, mbuf21, bucket20, bucket21, pkts_mask_out, entries, f);
*lookup_hit_mask = pkts_mask_out;
RTE_TABLE_HASH_KEY32_STATS_PKTS_LOOKUP_MISS(f, n_pkts_in - __builtin_popcountll(pkts_mask_out));
return 0;
} /* rte_table_hash_lookup_key32_lru() */
static int
rte_table_hash_lookup_key32_ext(
void *table,
struct rte_mbuf **pkts,
uint64_t pkts_mask,
uint64_t *lookup_hit_mask,
void **entries)
{
struct rte_table_hash *f = (struct rte_table_hash *) table;
struct rte_bucket_4_32 *bucket10, *bucket11, *bucket20, *bucket21;
struct rte_mbuf *mbuf00, *mbuf01, *mbuf10, *mbuf11, *mbuf20, *mbuf21;
uint32_t pkt00_index, pkt01_index, pkt10_index;
uint32_t pkt11_index, pkt20_index, pkt21_index;
uint64_t pkts_mask_out = 0, buckets_mask = 0;
struct rte_bucket_4_32 *buckets[RTE_PORT_IN_BURST_SIZE_MAX];
uint64_t *keys[RTE_PORT_IN_BURST_SIZE_MAX];
__rte_unused uint32_t n_pkts_in = __builtin_popcountll(pkts_mask);
RTE_TABLE_HASH_KEY32_STATS_PKTS_IN_ADD(f, n_pkts_in);
/* Cannot run the pipeline with less than 5 packets */
if (__builtin_popcountll(pkts_mask) < 5) {
for ( ; pkts_mask; ) {
struct rte_bucket_4_32 *bucket;
struct rte_mbuf *mbuf;
uint32_t pkt_index;
lookup1_stage0(pkt_index, mbuf, pkts, pkts_mask, f);
lookup1_stage1(mbuf, bucket, f);
lookup1_stage2_ext(pkt_index, mbuf, bucket,
pkts_mask_out, entries, buckets_mask, buckets,
keys, f);
}
goto grind_next_buckets;
}
/*
* Pipeline fill
*
*/
/* Pipeline stage 0 */
lookup2_stage0(pkt00_index, pkt01_index, mbuf00, mbuf01, pkts,
pkts_mask, f);
/* Pipeline feed */
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 0 */
lookup2_stage0(pkt00_index, pkt01_index, mbuf00, mbuf01, pkts,
pkts_mask, f);
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/*
* Pipeline run
*
*/
for ( ; pkts_mask; ) {
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 0 */
lookup2_stage0_with_odd_support(pkt00_index, pkt01_index,
mbuf00, mbuf01, pkts, pkts_mask, f);
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/* Pipeline stage 2 */
lookup2_stage2_ext(pkt20_index, pkt21_index, mbuf20, mbuf21,
bucket20, bucket21, pkts_mask_out, entries,
buckets_mask, buckets, keys, f);
}
/*
* Pipeline flush
*
*/
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
mbuf10 = mbuf00;
mbuf11 = mbuf01;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
pkt10_index = pkt00_index;
pkt11_index = pkt01_index;
/* Pipeline stage 1 */
lookup2_stage1(mbuf10, mbuf11, bucket10, bucket11, f);
/* Pipeline stage 2 */
lookup2_stage2_ext(pkt20_index, pkt21_index, mbuf20, mbuf21,
bucket20, bucket21, pkts_mask_out, entries,
buckets_mask, buckets, keys, f);
/* Pipeline feed */
bucket20 = bucket10;
bucket21 = bucket11;
mbuf20 = mbuf10;
mbuf21 = mbuf11;
pkt20_index = pkt10_index;
pkt21_index = pkt11_index;
/* Pipeline stage 2 */
lookup2_stage2_ext(pkt20_index, pkt21_index, mbuf20, mbuf21,
bucket20, bucket21, pkts_mask_out, entries,
buckets_mask, buckets, keys, f);
grind_next_buckets:
/* Grind next buckets */
for ( ; buckets_mask; ) {
uint64_t buckets_mask_next = 0;
for ( ; buckets_mask; ) {
uint64_t pkt_mask;
uint32_t pkt_index;
pkt_index = __builtin_ctzll(buckets_mask);
pkt_mask = 1LLU << pkt_index;
buckets_mask &= ~pkt_mask;
lookup_grinder(pkt_index, buckets, keys, pkts_mask_out,
entries, buckets_mask_next, f);
}
buckets_mask = buckets_mask_next;
}
*lookup_hit_mask = pkts_mask_out;
RTE_TABLE_HASH_KEY32_STATS_PKTS_LOOKUP_MISS(f, n_pkts_in - __builtin_popcountll(pkts_mask_out));
return 0;
} /* rte_table_hash_lookup_key32_ext() */
static int
rte_table_hash_key32_stats_read(void *table, struct rte_table_stats *stats, int clear)
{
struct rte_table_hash *t = table;
if (stats != NULL)
memcpy(stats, &t->stats, sizeof(t->stats));
if (clear)
memset(&t->stats, 0, sizeof(t->stats));
return 0;
}
struct rte_table_ops rte_table_hash_key32_lru_ops = {
.f_create = rte_table_hash_create_key32_lru,
.f_free = rte_table_hash_free_key32_lru,
.f_add = rte_table_hash_entry_add_key32_lru,
.f_delete = rte_table_hash_entry_delete_key32_lru,
.f_add_bulk = NULL,
.f_delete_bulk = NULL,
.f_lookup = rte_table_hash_lookup_key32_lru,
.f_stats = rte_table_hash_key32_stats_read,
};
struct rte_table_ops rte_table_hash_key32_ext_ops = {
.f_create = rte_table_hash_create_key32_ext,
.f_free = rte_table_hash_free_key32_ext,
.f_add = rte_table_hash_entry_add_key32_ext,
.f_delete = rte_table_hash_entry_delete_key32_ext,
.f_add_bulk = NULL,
.f_delete_bulk = NULL,
.f_lookup = rte_table_hash_lookup_key32_ext,
.f_stats = rte_table_hash_key32_stats_read,
};