numam-dpdk/lib/librte_lpm/rte_lpm.c

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2010-2014 Intel Corporation
*/
#include <string.h>
#include <stdint.h>
#include <errno.h>
#include <stdarg.h>
#include <stdio.h>
#include <sys/queue.h>
#include <rte_log.h>
#include <rte_branch_prediction.h>
#include <rte_common.h>
#include <rte_memory.h> /* for definition of RTE_CACHE_LINE_SIZE */
#include <rte_malloc.h>
#include <rte_eal.h>
#include <rte_eal_memconfig.h>
#include <rte_per_lcore.h>
#include <rte_string_fns.h>
#include <rte_errno.h>
#include <rte_rwlock.h>
#include <rte_spinlock.h>
#include <rte_tailq.h>
#include "rte_lpm.h"
TAILQ_HEAD(rte_lpm_list, rte_tailq_entry);
static struct rte_tailq_elem rte_lpm_tailq = {
.name = "RTE_LPM",
};
EAL_REGISTER_TAILQ(rte_lpm_tailq)
#define MAX_DEPTH_TBL24 24
enum valid_flag {
INVALID = 0,
VALID
};
/* Macro to enable/disable run-time checks. */
#if defined(RTE_LIBRTE_LPM_DEBUG)
#include <rte_debug.h>
#define VERIFY_DEPTH(depth) do { \
if ((depth == 0) || (depth > RTE_LPM_MAX_DEPTH)) \
rte_panic("LPM: Invalid depth (%u) at line %d", \
(unsigned)(depth), __LINE__); \
} while (0)
#else
#define VERIFY_DEPTH(depth)
#endif
/*
* Converts a given depth value to its corresponding mask value.
*
* depth (IN) : range = 1 - 32
* mask (OUT) : 32bit mask
*/
static uint32_t __attribute__((pure))
depth_to_mask(uint8_t depth)
{
VERIFY_DEPTH(depth);
/* To calculate a mask start with a 1 on the left hand side and right
* shift while populating the left hand side with 1's
*/
return (int)0x80000000 >> (depth - 1);
}
/*
* Converts given depth value to its corresponding range value.
*/
static uint32_t __attribute__((pure))
depth_to_range(uint8_t depth)
{
VERIFY_DEPTH(depth);
/*
* Calculate tbl24 range. (Note: 2^depth = 1 << depth)
*/
if (depth <= MAX_DEPTH_TBL24)
return 1 << (MAX_DEPTH_TBL24 - depth);
/* Else if depth is greater than 24 */
return 1 << (RTE_LPM_MAX_DEPTH - depth);
}
/*
* Find an existing lpm table and return a pointer to it.
*/
struct rte_lpm_v20 *
rte_lpm_find_existing_v20(const char *name)
{
struct rte_lpm_v20 *l = NULL;
struct rte_tailq_entry *te;
struct rte_lpm_list *lpm_list;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
rte_mcfg_tailq_read_lock();
TAILQ_FOREACH(te, lpm_list, next) {
l = te->data;
if (strncmp(name, l->name, RTE_LPM_NAMESIZE) == 0)
break;
}
rte_mcfg_tailq_read_unlock();
if (te == NULL) {
rte_errno = ENOENT;
return NULL;
}
return l;
}
VERSION_SYMBOL(rte_lpm_find_existing, _v20, 2.0);
struct rte_lpm *
rte_lpm_find_existing_v1604(const char *name)
{
struct rte_lpm *l = NULL;
struct rte_tailq_entry *te;
struct rte_lpm_list *lpm_list;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
rte_mcfg_tailq_read_lock();
TAILQ_FOREACH(te, lpm_list, next) {
l = te->data;
if (strncmp(name, l->name, RTE_LPM_NAMESIZE) == 0)
break;
}
rte_mcfg_tailq_read_unlock();
if (te == NULL) {
rte_errno = ENOENT;
return NULL;
}
return l;
}
BIND_DEFAULT_SYMBOL(rte_lpm_find_existing, _v1604, 16.04);
MAP_STATIC_SYMBOL(struct rte_lpm *rte_lpm_find_existing(const char *name),
rte_lpm_find_existing_v1604);
/*
* Allocates memory for LPM object
*/
struct rte_lpm_v20 *
rte_lpm_create_v20(const char *name, int socket_id, int max_rules,
__rte_unused int flags)
{
char mem_name[RTE_LPM_NAMESIZE];
struct rte_lpm_v20 *lpm = NULL;
struct rte_tailq_entry *te;
uint32_t mem_size;
struct rte_lpm_list *lpm_list;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
RTE_BUILD_BUG_ON(sizeof(struct rte_lpm_tbl_entry_v20) != 2);
/* Check user arguments. */
if ((name == NULL) || (socket_id < -1) || (max_rules == 0)) {
rte_errno = EINVAL;
return NULL;
}
snprintf(mem_name, sizeof(mem_name), "LPM_%s", name);
/* Determine the amount of memory to allocate. */
mem_size = sizeof(*lpm) + (sizeof(lpm->rules_tbl[0]) * max_rules);
rte_mcfg_tailq_write_lock();
/* guarantee there's no existing */
TAILQ_FOREACH(te, lpm_list, next) {
lpm = te->data;
if (strncmp(name, lpm->name, RTE_LPM_NAMESIZE) == 0)
break;
}
if (te != NULL) {
lpm = NULL;
rte_errno = EEXIST;
goto exit;
}
/* allocate tailq entry */
te = rte_zmalloc("LPM_TAILQ_ENTRY", sizeof(*te), 0);
if (te == NULL) {
RTE_LOG(ERR, LPM, "Failed to allocate tailq entry\n");
rte_errno = ENOMEM;
goto exit;
}
/* Allocate memory to store the LPM data structures. */
lpm = rte_zmalloc_socket(mem_name, mem_size,
RTE_CACHE_LINE_SIZE, socket_id);
if (lpm == NULL) {
RTE_LOG(ERR, LPM, "LPM memory allocation failed\n");
rte_free(te);
rte_errno = ENOMEM;
goto exit;
}
/* Save user arguments. */
lpm->max_rules = max_rules;
strlcpy(lpm->name, name, sizeof(lpm->name));
te->data = lpm;
TAILQ_INSERT_TAIL(lpm_list, te, next);
exit:
rte_mcfg_tailq_write_unlock();
return lpm;
}
VERSION_SYMBOL(rte_lpm_create, _v20, 2.0);
struct rte_lpm *
rte_lpm_create_v1604(const char *name, int socket_id,
const struct rte_lpm_config *config)
{
char mem_name[RTE_LPM_NAMESIZE];
struct rte_lpm *lpm = NULL;
struct rte_tailq_entry *te;
uint32_t mem_size, rules_size, tbl8s_size;
struct rte_lpm_list *lpm_list;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
RTE_BUILD_BUG_ON(sizeof(struct rte_lpm_tbl_entry) != 4);
/* Check user arguments. */
if ((name == NULL) || (socket_id < -1) || (config->max_rules == 0)
|| config->number_tbl8s > RTE_LPM_MAX_TBL8_NUM_GROUPS) {
rte_errno = EINVAL;
return NULL;
}
snprintf(mem_name, sizeof(mem_name), "LPM_%s", name);
/* Determine the amount of memory to allocate. */
mem_size = sizeof(*lpm);
rules_size = sizeof(struct rte_lpm_rule) * config->max_rules;
tbl8s_size = (sizeof(struct rte_lpm_tbl_entry) *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES * config->number_tbl8s);
rte_mcfg_tailq_write_lock();
/* guarantee there's no existing */
TAILQ_FOREACH(te, lpm_list, next) {
lpm = te->data;
if (strncmp(name, lpm->name, RTE_LPM_NAMESIZE) == 0)
break;
}
if (te != NULL) {
lpm = NULL;
rte_errno = EEXIST;
goto exit;
}
/* allocate tailq entry */
te = rte_zmalloc("LPM_TAILQ_ENTRY", sizeof(*te), 0);
if (te == NULL) {
RTE_LOG(ERR, LPM, "Failed to allocate tailq entry\n");
rte_errno = ENOMEM;
goto exit;
}
/* Allocate memory to store the LPM data structures. */
lpm = rte_zmalloc_socket(mem_name, mem_size,
RTE_CACHE_LINE_SIZE, socket_id);
if (lpm == NULL) {
RTE_LOG(ERR, LPM, "LPM memory allocation failed\n");
rte_free(te);
rte_errno = ENOMEM;
goto exit;
}
lpm->rules_tbl = rte_zmalloc_socket(NULL,
(size_t)rules_size, RTE_CACHE_LINE_SIZE, socket_id);
if (lpm->rules_tbl == NULL) {
RTE_LOG(ERR, LPM, "LPM rules_tbl memory allocation failed\n");
rte_free(lpm);
lpm = NULL;
rte_free(te);
rte_errno = ENOMEM;
goto exit;
}
lpm->tbl8 = rte_zmalloc_socket(NULL,
(size_t)tbl8s_size, RTE_CACHE_LINE_SIZE, socket_id);
if (lpm->tbl8 == NULL) {
RTE_LOG(ERR, LPM, "LPM tbl8 memory allocation failed\n");
rte_free(lpm->rules_tbl);
rte_free(lpm);
lpm = NULL;
rte_free(te);
rte_errno = ENOMEM;
goto exit;
}
/* Save user arguments. */
lpm->max_rules = config->max_rules;
lpm->number_tbl8s = config->number_tbl8s;
strlcpy(lpm->name, name, sizeof(lpm->name));
te->data = lpm;
TAILQ_INSERT_TAIL(lpm_list, te, next);
exit:
rte_mcfg_tailq_write_unlock();
return lpm;
}
BIND_DEFAULT_SYMBOL(rte_lpm_create, _v1604, 16.04);
MAP_STATIC_SYMBOL(
struct rte_lpm *rte_lpm_create(const char *name, int socket_id,
const struct rte_lpm_config *config), rte_lpm_create_v1604);
/*
* Deallocates memory for given LPM table.
*/
void
rte_lpm_free_v20(struct rte_lpm_v20 *lpm)
{
struct rte_lpm_list *lpm_list;
struct rte_tailq_entry *te;
/* Check user arguments. */
if (lpm == NULL)
return;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
rte_mcfg_tailq_write_lock();
/* find our tailq entry */
TAILQ_FOREACH(te, lpm_list, next) {
if (te->data == (void *) lpm)
break;
}
if (te != NULL)
TAILQ_REMOVE(lpm_list, te, next);
rte_mcfg_tailq_write_unlock();
rte_free(lpm);
rte_free(te);
}
VERSION_SYMBOL(rte_lpm_free, _v20, 2.0);
void
rte_lpm_free_v1604(struct rte_lpm *lpm)
{
struct rte_lpm_list *lpm_list;
struct rte_tailq_entry *te;
/* Check user arguments. */
if (lpm == NULL)
return;
lpm_list = RTE_TAILQ_CAST(rte_lpm_tailq.head, rte_lpm_list);
rte_mcfg_tailq_write_lock();
/* find our tailq entry */
TAILQ_FOREACH(te, lpm_list, next) {
if (te->data == (void *) lpm)
break;
}
if (te != NULL)
TAILQ_REMOVE(lpm_list, te, next);
rte_mcfg_tailq_write_unlock();
rte_free(lpm->tbl8);
rte_free(lpm->rules_tbl);
rte_free(lpm);
rte_free(te);
}
BIND_DEFAULT_SYMBOL(rte_lpm_free, _v1604, 16.04);
MAP_STATIC_SYMBOL(void rte_lpm_free(struct rte_lpm *lpm),
rte_lpm_free_v1604);
/*
* Adds a rule to the rule table.
*
* NOTE: The rule table is split into 32 groups. Each group contains rules that
* apply to a specific prefix depth (i.e. group 1 contains rules that apply to
* prefixes with a depth of 1 etc.). In the following code (depth - 1) is used
* to refer to depth 1 because even though the depth range is 1 - 32, depths
* are stored in the rule table from 0 - 31.
* NOTE: Valid range for depth parameter is 1 .. 32 inclusive.
*/
static int32_t
rule_add_v20(struct rte_lpm_v20 *lpm, uint32_t ip_masked, uint8_t depth,
uint8_t next_hop)
{
uint32_t rule_gindex, rule_index, last_rule;
int i;
VERIFY_DEPTH(depth);
/* Scan through rule group to see if rule already exists. */
if (lpm->rule_info[depth - 1].used_rules > 0) {
/* rule_gindex stands for rule group index. */
rule_gindex = lpm->rule_info[depth - 1].first_rule;
/* Initialise rule_index to point to start of rule group. */
rule_index = rule_gindex;
/* Last rule = Last used rule in this rule group. */
last_rule = rule_gindex + lpm->rule_info[depth - 1].used_rules;
for (; rule_index < last_rule; rule_index++) {
/* If rule already exists update its next_hop and return. */
if (lpm->rules_tbl[rule_index].ip == ip_masked) {
lpm->rules_tbl[rule_index].next_hop = next_hop;
return rule_index;
}
}
if (rule_index == lpm->max_rules)
return -ENOSPC;
} else {
/* Calculate the position in which the rule will be stored. */
rule_index = 0;
for (i = depth - 1; i > 0; i--) {
if (lpm->rule_info[i - 1].used_rules > 0) {
rule_index = lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules;
break;
}
}
if (rule_index == lpm->max_rules)
return -ENOSPC;
lpm->rule_info[depth - 1].first_rule = rule_index;
}
/* Make room for the new rule in the array. */
for (i = RTE_LPM_MAX_DEPTH; i > depth; i--) {
if (lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules == lpm->max_rules)
return -ENOSPC;
if (lpm->rule_info[i - 1].used_rules > 0) {
lpm->rules_tbl[lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules]
= lpm->rules_tbl[lpm->rule_info[i - 1].first_rule];
lpm->rule_info[i - 1].first_rule++;
}
}
/* Add the new rule. */
lpm->rules_tbl[rule_index].ip = ip_masked;
lpm->rules_tbl[rule_index].next_hop = next_hop;
/* Increment the used rules counter for this rule group. */
lpm->rule_info[depth - 1].used_rules++;
return rule_index;
}
static int32_t
rule_add_v1604(struct rte_lpm *lpm, uint32_t ip_masked, uint8_t depth,
uint32_t next_hop)
{
uint32_t rule_gindex, rule_index, last_rule;
int i;
VERIFY_DEPTH(depth);
/* Scan through rule group to see if rule already exists. */
if (lpm->rule_info[depth - 1].used_rules > 0) {
/* rule_gindex stands for rule group index. */
rule_gindex = lpm->rule_info[depth - 1].first_rule;
/* Initialise rule_index to point to start of rule group. */
rule_index = rule_gindex;
/* Last rule = Last used rule in this rule group. */
last_rule = rule_gindex + lpm->rule_info[depth - 1].used_rules;
for (; rule_index < last_rule; rule_index++) {
/* If rule already exists update its next_hop and return. */
if (lpm->rules_tbl[rule_index].ip == ip_masked) {
lpm->rules_tbl[rule_index].next_hop = next_hop;
return rule_index;
}
}
if (rule_index == lpm->max_rules)
return -ENOSPC;
} else {
/* Calculate the position in which the rule will be stored. */
rule_index = 0;
for (i = depth - 1; i > 0; i--) {
if (lpm->rule_info[i - 1].used_rules > 0) {
rule_index = lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules;
break;
}
}
if (rule_index == lpm->max_rules)
return -ENOSPC;
lpm->rule_info[depth - 1].first_rule = rule_index;
}
/* Make room for the new rule in the array. */
for (i = RTE_LPM_MAX_DEPTH; i > depth; i--) {
if (lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules == lpm->max_rules)
return -ENOSPC;
if (lpm->rule_info[i - 1].used_rules > 0) {
lpm->rules_tbl[lpm->rule_info[i - 1].first_rule
+ lpm->rule_info[i - 1].used_rules]
= lpm->rules_tbl[lpm->rule_info[i - 1].first_rule];
lpm->rule_info[i - 1].first_rule++;
}
}
/* Add the new rule. */
lpm->rules_tbl[rule_index].ip = ip_masked;
lpm->rules_tbl[rule_index].next_hop = next_hop;
/* Increment the used rules counter for this rule group. */
lpm->rule_info[depth - 1].used_rules++;
return rule_index;
}
/*
* Delete a rule from the rule table.
* NOTE: Valid range for depth parameter is 1 .. 32 inclusive.
*/
static void
rule_delete_v20(struct rte_lpm_v20 *lpm, int32_t rule_index, uint8_t depth)
{
int i;
VERIFY_DEPTH(depth);
lpm->rules_tbl[rule_index] =
lpm->rules_tbl[lpm->rule_info[depth - 1].first_rule
+ lpm->rule_info[depth - 1].used_rules - 1];
for (i = depth; i < RTE_LPM_MAX_DEPTH; i++) {
if (lpm->rule_info[i].used_rules > 0) {
lpm->rules_tbl[lpm->rule_info[i].first_rule - 1] =
lpm->rules_tbl[lpm->rule_info[i].first_rule
+ lpm->rule_info[i].used_rules - 1];
lpm->rule_info[i].first_rule--;
}
}
lpm->rule_info[depth - 1].used_rules--;
}
static void
rule_delete_v1604(struct rte_lpm *lpm, int32_t rule_index, uint8_t depth)
{
int i;
VERIFY_DEPTH(depth);
lpm->rules_tbl[rule_index] =
lpm->rules_tbl[lpm->rule_info[depth - 1].first_rule
+ lpm->rule_info[depth - 1].used_rules - 1];
for (i = depth; i < RTE_LPM_MAX_DEPTH; i++) {
if (lpm->rule_info[i].used_rules > 0) {
lpm->rules_tbl[lpm->rule_info[i].first_rule - 1] =
lpm->rules_tbl[lpm->rule_info[i].first_rule
+ lpm->rule_info[i].used_rules - 1];
lpm->rule_info[i].first_rule--;
}
}
lpm->rule_info[depth - 1].used_rules--;
}
/*
* Finds a rule in rule table.
* NOTE: Valid range for depth parameter is 1 .. 32 inclusive.
*/
static int32_t
rule_find_v20(struct rte_lpm_v20 *lpm, uint32_t ip_masked, uint8_t depth)
{
uint32_t rule_gindex, last_rule, rule_index;
VERIFY_DEPTH(depth);
rule_gindex = lpm->rule_info[depth - 1].first_rule;
last_rule = rule_gindex + lpm->rule_info[depth - 1].used_rules;
/* Scan used rules at given depth to find rule. */
for (rule_index = rule_gindex; rule_index < last_rule; rule_index++) {
/* If rule is found return the rule index. */
if (lpm->rules_tbl[rule_index].ip == ip_masked)
return rule_index;
}
/* If rule is not found return -EINVAL. */
return -EINVAL;
}
static int32_t
rule_find_v1604(struct rte_lpm *lpm, uint32_t ip_masked, uint8_t depth)
{
uint32_t rule_gindex, last_rule, rule_index;
VERIFY_DEPTH(depth);
rule_gindex = lpm->rule_info[depth - 1].first_rule;
last_rule = rule_gindex + lpm->rule_info[depth - 1].used_rules;
/* Scan used rules at given depth to find rule. */
for (rule_index = rule_gindex; rule_index < last_rule; rule_index++) {
/* If rule is found return the rule index. */
if (lpm->rules_tbl[rule_index].ip == ip_masked)
return rule_index;
}
/* If rule is not found return -EINVAL. */
return -EINVAL;
}
/*
* Find, clean and allocate a tbl8.
*/
static int32_t
tbl8_alloc_v20(struct rte_lpm_tbl_entry_v20 *tbl8)
{
uint32_t group_idx; /* tbl8 group index. */
struct rte_lpm_tbl_entry_v20 *tbl8_entry;
/* Scan through tbl8 to find a free (i.e. INVALID) tbl8 group. */
for (group_idx = 0; group_idx < RTE_LPM_TBL8_NUM_GROUPS;
group_idx++) {
tbl8_entry = &tbl8[group_idx * RTE_LPM_TBL8_GROUP_NUM_ENTRIES];
/* If a free tbl8 group is found clean it and set as VALID. */
if (!tbl8_entry->valid_group) {
memset(&tbl8_entry[0], 0,
RTE_LPM_TBL8_GROUP_NUM_ENTRIES *
sizeof(tbl8_entry[0]));
tbl8_entry->valid_group = VALID;
/* Return group index for allocated tbl8 group. */
return group_idx;
}
}
/* If there are no tbl8 groups free then return error. */
return -ENOSPC;
}
static int32_t
tbl8_alloc_v1604(struct rte_lpm_tbl_entry *tbl8, uint32_t number_tbl8s)
{
uint32_t group_idx; /* tbl8 group index. */
struct rte_lpm_tbl_entry *tbl8_entry;
/* Scan through tbl8 to find a free (i.e. INVALID) tbl8 group. */
for (group_idx = 0; group_idx < number_tbl8s; group_idx++) {
tbl8_entry = &tbl8[group_idx * RTE_LPM_TBL8_GROUP_NUM_ENTRIES];
/* If a free tbl8 group is found clean it and set as VALID. */
if (!tbl8_entry->valid_group) {
memset(&tbl8_entry[0], 0,
RTE_LPM_TBL8_GROUP_NUM_ENTRIES *
sizeof(tbl8_entry[0]));
tbl8_entry->valid_group = VALID;
/* Return group index for allocated tbl8 group. */
return group_idx;
}
}
/* If there are no tbl8 groups free then return error. */
return -ENOSPC;
}
static void
tbl8_free_v20(struct rte_lpm_tbl_entry_v20 *tbl8, uint32_t tbl8_group_start)
{
/* Set tbl8 group invalid*/
tbl8[tbl8_group_start].valid_group = INVALID;
}
static void
tbl8_free_v1604(struct rte_lpm_tbl_entry *tbl8, uint32_t tbl8_group_start)
{
/* Set tbl8 group invalid*/
tbl8[tbl8_group_start].valid_group = INVALID;
}
static __rte_noinline int32_t
add_depth_small_v20(struct rte_lpm_v20 *lpm, uint32_t ip, uint8_t depth,
uint8_t next_hop)
{
uint32_t tbl24_index, tbl24_range, tbl8_index, tbl8_group_end, i, j;
/* Calculate the index into Table24. */
tbl24_index = ip >> 8;
tbl24_range = depth_to_range(depth);
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
/*
* For invalid OR valid and non-extended tbl 24 entries set
* entry.
*/
if (!lpm->tbl24[i].valid || (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth)) {
struct rte_lpm_tbl_entry_v20 new_tbl24_entry = {
.valid = VALID,
.valid_group = 0,
.depth = depth,
};
new_tbl24_entry.next_hop = next_hop;
/* Setting tbl24 entry in one go to avoid race
* conditions
*/
lpm->tbl24[i] = new_tbl24_entry;
continue;
}
if (lpm->tbl24[i].valid_group == 1) {
/* If tbl24 entry is valid and extended calculate the
* index into tbl8.
*/
tbl8_index = lpm->tbl24[i].group_idx *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_group_end = tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < tbl8_group_end; j++) {
if (!lpm->tbl8[j].valid ||
lpm->tbl8[j].depth <= depth) {
struct rte_lpm_tbl_entry_v20
new_tbl8_entry = {
.valid = VALID,
.valid_group = VALID,
.depth = depth,
};
new_tbl8_entry.next_hop = next_hop;
/*
* Setting tbl8 entry in one go to avoid
* race conditions
*/
lpm->tbl8[j] = new_tbl8_entry;
continue;
}
}
}
}
return 0;
}
static __rte_noinline int32_t
add_depth_small_v1604(struct rte_lpm *lpm, uint32_t ip, uint8_t depth,
uint32_t next_hop)
{
#define group_idx next_hop
uint32_t tbl24_index, tbl24_range, tbl8_index, tbl8_group_end, i, j;
/* Calculate the index into Table24. */
tbl24_index = ip >> 8;
tbl24_range = depth_to_range(depth);
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
/*
* For invalid OR valid and non-extended tbl 24 entries set
* entry.
*/
if (!lpm->tbl24[i].valid || (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth)) {
struct rte_lpm_tbl_entry new_tbl24_entry = {
.next_hop = next_hop,
.valid = VALID,
.valid_group = 0,
.depth = depth,
};
/* Setting tbl24 entry in one go to avoid race
* conditions
*/
__atomic_store(&lpm->tbl24[i], &new_tbl24_entry,
__ATOMIC_RELEASE);
continue;
}
if (lpm->tbl24[i].valid_group == 1) {
/* If tbl24 entry is valid and extended calculate the
* index into tbl8.
*/
tbl8_index = lpm->tbl24[i].group_idx *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_group_end = tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < tbl8_group_end; j++) {
if (!lpm->tbl8[j].valid ||
lpm->tbl8[j].depth <= depth) {
struct rte_lpm_tbl_entry
new_tbl8_entry = {
.valid = VALID,
.valid_group = VALID,
.depth = depth,
.next_hop = next_hop,
};
/*
* Setting tbl8 entry in one go to avoid
* race conditions
*/
lpm->tbl8[j] = new_tbl8_entry;
continue;
}
}
}
}
#undef group_idx
return 0;
}
static __rte_noinline int32_t
add_depth_big_v20(struct rte_lpm_v20 *lpm, uint32_t ip_masked, uint8_t depth,
uint8_t next_hop)
{
uint32_t tbl24_index;
int32_t tbl8_group_index, tbl8_group_start, tbl8_group_end, tbl8_index,
tbl8_range, i;
tbl24_index = (ip_masked >> 8);
tbl8_range = depth_to_range(depth);
if (!lpm->tbl24[tbl24_index].valid) {
/* Search for a free tbl8 group. */
tbl8_group_index = tbl8_alloc_v20(lpm->tbl8);
/* Check tbl8 allocation was successful. */
if (tbl8_group_index < 0) {
return tbl8_group_index;
}
/* Find index into tbl8 and range. */
tbl8_index = (tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES) +
(ip_masked & 0xFF);
/* Set tbl8 entry. */
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
lpm->tbl8[i].depth = depth;
lpm->tbl8[i].next_hop = next_hop;
lpm->tbl8[i].valid = VALID;
}
/*
* Update tbl24 entry to point to new tbl8 entry. Note: The
* ext_flag and tbl8_index need to be updated simultaneously,
* so assign whole structure in one go
*/
struct rte_lpm_tbl_entry_v20 new_tbl24_entry = {
.group_idx = (uint8_t)tbl8_group_index,
.valid = VALID,
.valid_group = 1,
.depth = 0,
};
lpm->tbl24[tbl24_index] = new_tbl24_entry;
} /* If valid entry but not extended calculate the index into Table8. */
else if (lpm->tbl24[tbl24_index].valid_group == 0) {
/* Search for free tbl8 group. */
tbl8_group_index = tbl8_alloc_v20(lpm->tbl8);
if (tbl8_group_index < 0) {
return tbl8_group_index;
}
tbl8_group_start = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_group_end = tbl8_group_start +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
/* Populate new tbl8 with tbl24 value. */
for (i = tbl8_group_start; i < tbl8_group_end; i++) {
lpm->tbl8[i].valid = VALID;
lpm->tbl8[i].depth = lpm->tbl24[tbl24_index].depth;
lpm->tbl8[i].next_hop =
lpm->tbl24[tbl24_index].next_hop;
}
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
/* Insert new rule into the tbl8 entry. */
for (i = tbl8_index; i < tbl8_index + tbl8_range; i++) {
lpm->tbl8[i].valid = VALID;
lpm->tbl8[i].depth = depth;
lpm->tbl8[i].next_hop = next_hop;
}
/*
* Update tbl24 entry to point to new tbl8 entry. Note: The
* ext_flag and tbl8_index need to be updated simultaneously,
* so assign whole structure in one go.
*/
struct rte_lpm_tbl_entry_v20 new_tbl24_entry = {
.group_idx = (uint8_t)tbl8_group_index,
.valid = VALID,
.valid_group = 1,
.depth = 0,
};
lpm->tbl24[tbl24_index] = new_tbl24_entry;
} else { /*
* If it is valid, extended entry calculate the index into tbl8.
*/
tbl8_group_index = lpm->tbl24[tbl24_index].group_idx;
tbl8_group_start = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (!lpm->tbl8[i].valid ||
lpm->tbl8[i].depth <= depth) {
struct rte_lpm_tbl_entry_v20 new_tbl8_entry = {
.valid = VALID,
.depth = depth,
.valid_group = lpm->tbl8[i].valid_group,
};
new_tbl8_entry.next_hop = next_hop;
/*
* Setting tbl8 entry in one go to avoid race
* condition
*/
lpm->tbl8[i] = new_tbl8_entry;
continue;
}
}
}
return 0;
}
static __rte_noinline int32_t
add_depth_big_v1604(struct rte_lpm *lpm, uint32_t ip_masked, uint8_t depth,
uint32_t next_hop)
{
#define group_idx next_hop
uint32_t tbl24_index;
int32_t tbl8_group_index, tbl8_group_start, tbl8_group_end, tbl8_index,
tbl8_range, i;
tbl24_index = (ip_masked >> 8);
tbl8_range = depth_to_range(depth);
if (!lpm->tbl24[tbl24_index].valid) {
/* Search for a free tbl8 group. */
tbl8_group_index = tbl8_alloc_v1604(lpm->tbl8, lpm->number_tbl8s);
/* Check tbl8 allocation was successful. */
if (tbl8_group_index < 0) {
return tbl8_group_index;
}
/* Find index into tbl8 and range. */
tbl8_index = (tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES) +
(ip_masked & 0xFF);
/* Set tbl8 entry. */
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
lpm->tbl8[i].depth = depth;
lpm->tbl8[i].next_hop = next_hop;
lpm->tbl8[i].valid = VALID;
}
/*
* Update tbl24 entry to point to new tbl8 entry. Note: The
* ext_flag and tbl8_index need to be updated simultaneously,
* so assign whole structure in one go
*/
struct rte_lpm_tbl_entry new_tbl24_entry = {
.group_idx = tbl8_group_index,
.valid = VALID,
.valid_group = 1,
.depth = 0,
};
/* The tbl24 entry must be written only after the
* tbl8 entries are written.
*/
__atomic_store(&lpm->tbl24[tbl24_index], &new_tbl24_entry,
__ATOMIC_RELEASE);
} /* If valid entry but not extended calculate the index into Table8. */
else if (lpm->tbl24[tbl24_index].valid_group == 0) {
/* Search for free tbl8 group. */
tbl8_group_index = tbl8_alloc_v1604(lpm->tbl8, lpm->number_tbl8s);
if (tbl8_group_index < 0) {
return tbl8_group_index;
}
tbl8_group_start = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_group_end = tbl8_group_start +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
/* Populate new tbl8 with tbl24 value. */
for (i = tbl8_group_start; i < tbl8_group_end; i++) {
lpm->tbl8[i].valid = VALID;
lpm->tbl8[i].depth = lpm->tbl24[tbl24_index].depth;
lpm->tbl8[i].next_hop =
lpm->tbl24[tbl24_index].next_hop;
}
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
/* Insert new rule into the tbl8 entry. */
for (i = tbl8_index; i < tbl8_index + tbl8_range; i++) {
lpm->tbl8[i].valid = VALID;
lpm->tbl8[i].depth = depth;
lpm->tbl8[i].next_hop = next_hop;
}
/*
* Update tbl24 entry to point to new tbl8 entry. Note: The
* ext_flag and tbl8_index need to be updated simultaneously,
* so assign whole structure in one go.
*/
struct rte_lpm_tbl_entry new_tbl24_entry = {
.group_idx = tbl8_group_index,
.valid = VALID,
.valid_group = 1,
.depth = 0,
};
/* The tbl24 entry must be written only after the
* tbl8 entries are written.
*/
__atomic_store(&lpm->tbl24[tbl24_index], &new_tbl24_entry,
__ATOMIC_RELEASE);
} else { /*
* If it is valid, extended entry calculate the index into tbl8.
*/
tbl8_group_index = lpm->tbl24[tbl24_index].group_idx;
tbl8_group_start = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (!lpm->tbl8[i].valid ||
lpm->tbl8[i].depth <= depth) {
struct rte_lpm_tbl_entry new_tbl8_entry = {
.valid = VALID,
.depth = depth,
.next_hop = next_hop,
.valid_group = lpm->tbl8[i].valid_group,
};
/*
* Setting tbl8 entry in one go to avoid race
* condition
*/
lpm->tbl8[i] = new_tbl8_entry;
continue;
}
}
}
#undef group_idx
return 0;
}
/*
* Add a route
*/
int
rte_lpm_add_v20(struct rte_lpm_v20 *lpm, uint32_t ip, uint8_t depth,
uint8_t next_hop)
{
int32_t rule_index, status = 0;
uint32_t ip_masked;
/* Check user arguments. */
if ((lpm == NULL) || (depth < 1) || (depth > RTE_LPM_MAX_DEPTH))
return -EINVAL;
ip_masked = ip & depth_to_mask(depth);
/* Add the rule to the rule table. */
rule_index = rule_add_v20(lpm, ip_masked, depth, next_hop);
/* If the is no space available for new rule return error. */
if (rule_index < 0) {
return rule_index;
}
if (depth <= MAX_DEPTH_TBL24) {
status = add_depth_small_v20(lpm, ip_masked, depth, next_hop);
} else { /* If depth > RTE_LPM_MAX_DEPTH_TBL24 */
status = add_depth_big_v20(lpm, ip_masked, depth, next_hop);
/*
* If add fails due to exhaustion of tbl8 extensions delete
* rule that was added to rule table.
*/
if (status < 0) {
rule_delete_v20(lpm, rule_index, depth);
return status;
}
}
return 0;
}
VERSION_SYMBOL(rte_lpm_add, _v20, 2.0);
int
rte_lpm_add_v1604(struct rte_lpm *lpm, uint32_t ip, uint8_t depth,
uint32_t next_hop)
{
int32_t rule_index, status = 0;
uint32_t ip_masked;
/* Check user arguments. */
if ((lpm == NULL) || (depth < 1) || (depth > RTE_LPM_MAX_DEPTH))
return -EINVAL;
ip_masked = ip & depth_to_mask(depth);
/* Add the rule to the rule table. */
rule_index = rule_add_v1604(lpm, ip_masked, depth, next_hop);
/* If the is no space available for new rule return error. */
if (rule_index < 0) {
return rule_index;
}
if (depth <= MAX_DEPTH_TBL24) {
status = add_depth_small_v1604(lpm, ip_masked, depth, next_hop);
} else { /* If depth > RTE_LPM_MAX_DEPTH_TBL24 */
status = add_depth_big_v1604(lpm, ip_masked, depth, next_hop);
/*
* If add fails due to exhaustion of tbl8 extensions delete
* rule that was added to rule table.
*/
if (status < 0) {
rule_delete_v1604(lpm, rule_index, depth);
return status;
}
}
return 0;
}
BIND_DEFAULT_SYMBOL(rte_lpm_add, _v1604, 16.04);
MAP_STATIC_SYMBOL(int rte_lpm_add(struct rte_lpm *lpm, uint32_t ip,
uint8_t depth, uint32_t next_hop), rte_lpm_add_v1604);
/*
* Look for a rule in the high-level rules table
*/
int
rte_lpm_is_rule_present_v20(struct rte_lpm_v20 *lpm, uint32_t ip, uint8_t depth,
uint8_t *next_hop)
{
uint32_t ip_masked;
int32_t rule_index;
/* Check user arguments. */
if ((lpm == NULL) ||
(next_hop == NULL) ||
(depth < 1) || (depth > RTE_LPM_MAX_DEPTH))
return -EINVAL;
/* Look for the rule using rule_find. */
ip_masked = ip & depth_to_mask(depth);
rule_index = rule_find_v20(lpm, ip_masked, depth);
if (rule_index >= 0) {
*next_hop = lpm->rules_tbl[rule_index].next_hop;
return 1;
}
/* If rule is not found return 0. */
return 0;
}
VERSION_SYMBOL(rte_lpm_is_rule_present, _v20, 2.0);
int
rte_lpm_is_rule_present_v1604(struct rte_lpm *lpm, uint32_t ip, uint8_t depth,
uint32_t *next_hop)
{
uint32_t ip_masked;
int32_t rule_index;
/* Check user arguments. */
if ((lpm == NULL) ||
(next_hop == NULL) ||
(depth < 1) || (depth > RTE_LPM_MAX_DEPTH))
return -EINVAL;
/* Look for the rule using rule_find. */
ip_masked = ip & depth_to_mask(depth);
rule_index = rule_find_v1604(lpm, ip_masked, depth);
if (rule_index >= 0) {
*next_hop = lpm->rules_tbl[rule_index].next_hop;
return 1;
}
/* If rule is not found return 0. */
return 0;
}
BIND_DEFAULT_SYMBOL(rte_lpm_is_rule_present, _v1604, 16.04);
MAP_STATIC_SYMBOL(int rte_lpm_is_rule_present(struct rte_lpm *lpm, uint32_t ip,
uint8_t depth, uint32_t *next_hop), rte_lpm_is_rule_present_v1604);
static int32_t
find_previous_rule_v20(struct rte_lpm_v20 *lpm, uint32_t ip, uint8_t depth,
uint8_t *sub_rule_depth)
{
int32_t rule_index;
uint32_t ip_masked;
uint8_t prev_depth;
for (prev_depth = (uint8_t)(depth - 1); prev_depth > 0; prev_depth--) {
ip_masked = ip & depth_to_mask(prev_depth);
rule_index = rule_find_v20(lpm, ip_masked, prev_depth);
if (rule_index >= 0) {
*sub_rule_depth = prev_depth;
return rule_index;
}
}
return -1;
}
static int32_t
find_previous_rule_v1604(struct rte_lpm *lpm, uint32_t ip, uint8_t depth,
uint8_t *sub_rule_depth)
{
int32_t rule_index;
uint32_t ip_masked;
uint8_t prev_depth;
for (prev_depth = (uint8_t)(depth - 1); prev_depth > 0; prev_depth--) {
ip_masked = ip & depth_to_mask(prev_depth);
rule_index = rule_find_v1604(lpm, ip_masked, prev_depth);
if (rule_index >= 0) {
*sub_rule_depth = prev_depth;
return rule_index;
}
}
return -1;
}
static int32_t
delete_depth_small_v20(struct rte_lpm_v20 *lpm, uint32_t ip_masked,
uint8_t depth, int32_t sub_rule_index, uint8_t sub_rule_depth)
{
uint32_t tbl24_range, tbl24_index, tbl8_group_index, tbl8_index, i, j;
/* Calculate the range and index into Table24. */
tbl24_range = depth_to_range(depth);
tbl24_index = (ip_masked >> 8);
/*
* Firstly check the sub_rule_index. A -1 indicates no replacement rule
* and a positive number indicates a sub_rule_index.
*/
if (sub_rule_index < 0) {
/*
* If no replacement rule exists then invalidate entries
* associated with this rule.
*/
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
if (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth) {
lpm->tbl24[i].valid = INVALID;
} else if (lpm->tbl24[i].valid_group == 1) {
/*
* If TBL24 entry is extended, then there has
* to be a rule with depth >= 25 in the
* associated TBL8 group.
*/
tbl8_group_index = lpm->tbl24[i].group_idx;
tbl8_index = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < (tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES); j++) {
if (lpm->tbl8[j].depth <= depth)
lpm->tbl8[j].valid = INVALID;
}
}
}
} else {
/*
* If a replacement rule exists then modify entries
* associated with this rule.
*/
struct rte_lpm_tbl_entry_v20 new_tbl24_entry = {
.next_hop = lpm->rules_tbl[sub_rule_index].next_hop,
.valid = VALID,
.valid_group = 0,
.depth = sub_rule_depth,
};
struct rte_lpm_tbl_entry_v20 new_tbl8_entry = {
.valid = VALID,
.valid_group = VALID,
.depth = sub_rule_depth,
};
new_tbl8_entry.next_hop =
lpm->rules_tbl[sub_rule_index].next_hop;
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
if (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth) {
lpm->tbl24[i] = new_tbl24_entry;
} else if (lpm->tbl24[i].valid_group == 1) {
/*
* If TBL24 entry is extended, then there has
* to be a rule with depth >= 25 in the
* associated TBL8 group.
*/
tbl8_group_index = lpm->tbl24[i].group_idx;
tbl8_index = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < (tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES); j++) {
if (lpm->tbl8[j].depth <= depth)
lpm->tbl8[j] = new_tbl8_entry;
}
}
}
}
return 0;
}
static int32_t
delete_depth_small_v1604(struct rte_lpm *lpm, uint32_t ip_masked,
uint8_t depth, int32_t sub_rule_index, uint8_t sub_rule_depth)
{
#define group_idx next_hop
uint32_t tbl24_range, tbl24_index, tbl8_group_index, tbl8_index, i, j;
/* Calculate the range and index into Table24. */
tbl24_range = depth_to_range(depth);
tbl24_index = (ip_masked >> 8);
struct rte_lpm_tbl_entry zero_tbl24_entry = {0};
/*
* Firstly check the sub_rule_index. A -1 indicates no replacement rule
* and a positive number indicates a sub_rule_index.
*/
if (sub_rule_index < 0) {
/*
* If no replacement rule exists then invalidate entries
* associated with this rule.
*/
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
if (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth) {
__atomic_store(&lpm->tbl24[i],
&zero_tbl24_entry, __ATOMIC_RELEASE);
} else if (lpm->tbl24[i].valid_group == 1) {
/*
* If TBL24 entry is extended, then there has
* to be a rule with depth >= 25 in the
* associated TBL8 group.
*/
tbl8_group_index = lpm->tbl24[i].group_idx;
tbl8_index = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < (tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES); j++) {
if (lpm->tbl8[j].depth <= depth)
lpm->tbl8[j].valid = INVALID;
}
}
}
} else {
/*
* If a replacement rule exists then modify entries
* associated with this rule.
*/
struct rte_lpm_tbl_entry new_tbl24_entry = {
.next_hop = lpm->rules_tbl[sub_rule_index].next_hop,
.valid = VALID,
.valid_group = 0,
.depth = sub_rule_depth,
};
struct rte_lpm_tbl_entry new_tbl8_entry = {
.valid = VALID,
.valid_group = VALID,
.depth = sub_rule_depth,
.next_hop = lpm->rules_tbl
[sub_rule_index].next_hop,
};
for (i = tbl24_index; i < (tbl24_index + tbl24_range); i++) {
if (lpm->tbl24[i].valid_group == 0 &&
lpm->tbl24[i].depth <= depth) {
__atomic_store(&lpm->tbl24[i], &new_tbl24_entry,
__ATOMIC_RELEASE);
} else if (lpm->tbl24[i].valid_group == 1) {
/*
* If TBL24 entry is extended, then there has
* to be a rule with depth >= 25 in the
* associated TBL8 group.
*/
tbl8_group_index = lpm->tbl24[i].group_idx;
tbl8_index = tbl8_group_index *
RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
for (j = tbl8_index; j < (tbl8_index +
RTE_LPM_TBL8_GROUP_NUM_ENTRIES); j++) {
if (lpm->tbl8[j].depth <= depth)
lpm->tbl8[j] = new_tbl8_entry;
}
}
}
}
#undef group_idx
return 0;
}
/*
* Checks if table 8 group can be recycled.
*
* Return of -EEXIST means tbl8 is in use and thus can not be recycled.
* Return of -EINVAL means tbl8 is empty and thus can be recycled
* Return of value > -1 means tbl8 is in use but has all the same values and
* thus can be recycled
*/
static int32_t
tbl8_recycle_check_v20(struct rte_lpm_tbl_entry_v20 *tbl8,
uint32_t tbl8_group_start)
{
uint32_t tbl8_group_end, i;
tbl8_group_end = tbl8_group_start + RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
/*
* Check the first entry of the given tbl8. If it is invalid we know
* this tbl8 does not contain any rule with a depth < RTE_LPM_MAX_DEPTH
* (As they would affect all entries in a tbl8) and thus this table
* can not be recycled.
*/
if (tbl8[tbl8_group_start].valid) {
/*
* If first entry is valid check if the depth is less than 24
* and if so check the rest of the entries to verify that they
* are all of this depth.
*/
if (tbl8[tbl8_group_start].depth <= MAX_DEPTH_TBL24) {
for (i = (tbl8_group_start + 1); i < tbl8_group_end;
i++) {
if (tbl8[i].depth !=
tbl8[tbl8_group_start].depth) {
return -EEXIST;
}
}
/* If all entries are the same return the tb8 index */
return tbl8_group_start;
}
return -EEXIST;
}
/*
* If the first entry is invalid check if the rest of the entries in
* the tbl8 are invalid.
*/
for (i = (tbl8_group_start + 1); i < tbl8_group_end; i++) {
if (tbl8[i].valid)
return -EEXIST;
}
/* If no valid entries are found then return -EINVAL. */
return -EINVAL;
}
static int32_t
tbl8_recycle_check_v1604(struct rte_lpm_tbl_entry *tbl8,
uint32_t tbl8_group_start)
{
uint32_t tbl8_group_end, i;
tbl8_group_end = tbl8_group_start + RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
/*
* Check the first entry of the given tbl8. If it is invalid we know
* this tbl8 does not contain any rule with a depth < RTE_LPM_MAX_DEPTH
* (As they would affect all entries in a tbl8) and thus this table
* can not be recycled.
*/
if (tbl8[tbl8_group_start].valid) {
/*
* If first entry is valid check if the depth is less than 24
* and if so check the rest of the entries to verify that they
* are all of this depth.
*/
if (tbl8[tbl8_group_start].depth <= MAX_DEPTH_TBL24) {
for (i = (tbl8_group_start + 1); i < tbl8_group_end;
i++) {
if (tbl8[i].depth !=
tbl8[tbl8_group_start].depth) {
return -EEXIST;
}
}
/* If all entries are the same return the tb8 index */
return tbl8_group_start;
}
return -EEXIST;
}
/*
* If the first entry is invalid check if the rest of the entries in
* the tbl8 are invalid.
*/
for (i = (tbl8_group_start + 1); i < tbl8_group_end; i++) {
if (tbl8[i].valid)
return -EEXIST;
}
/* If no valid entries are found then return -EINVAL. */
return -EINVAL;
}
static int32_t
delete_depth_big_v20(struct rte_lpm_v20 *lpm, uint32_t ip_masked,
uint8_t depth, int32_t sub_rule_index, uint8_t sub_rule_depth)
{
uint32_t tbl24_index, tbl8_group_index, tbl8_group_start, tbl8_index,
tbl8_range, i;
int32_t tbl8_recycle_index;
/*
* Calculate the index into tbl24 and range. Note: All depths larger
* than MAX_DEPTH_TBL24 are associated with only one tbl24 entry.
*/
tbl24_index = ip_masked >> 8;
/* Calculate the index into tbl8 and range. */
tbl8_group_index = lpm->tbl24[tbl24_index].group_idx;
tbl8_group_start = tbl8_group_index * RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
tbl8_range = depth_to_range(depth);
if (sub_rule_index < 0) {
/*
* Loop through the range of entries on tbl8 for which the
* rule_to_delete must be removed or modified.
*/
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (lpm->tbl8[i].depth <= depth)
lpm->tbl8[i].valid = INVALID;
}
} else {
/* Set new tbl8 entry. */
struct rte_lpm_tbl_entry_v20 new_tbl8_entry = {
.valid = VALID,
.depth = sub_rule_depth,
.valid_group = lpm->tbl8[tbl8_group_start].valid_group,
};
new_tbl8_entry.next_hop =
lpm->rules_tbl[sub_rule_index].next_hop;
/*
* Loop through the range of entries on tbl8 for which the
* rule_to_delete must be modified.
*/
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (lpm->tbl8[i].depth <= depth)
lpm->tbl8[i] = new_tbl8_entry;
}
}
/*
* Check if there are any valid entries in this tbl8 group. If all
* tbl8 entries are invalid we can free the tbl8 and invalidate the
* associated tbl24 entry.
*/
tbl8_recycle_index = tbl8_recycle_check_v20(lpm->tbl8, tbl8_group_start);
if (tbl8_recycle_index == -EINVAL) {
/* Set tbl24 before freeing tbl8 to avoid race condition. */
lpm->tbl24[tbl24_index].valid = 0;
tbl8_free_v20(lpm->tbl8, tbl8_group_start);
} else if (tbl8_recycle_index > -1) {
/* Update tbl24 entry. */
struct rte_lpm_tbl_entry_v20 new_tbl24_entry = {
.next_hop = lpm->tbl8[tbl8_recycle_index].next_hop,
.valid = VALID,
.valid_group = 0,
.depth = lpm->tbl8[tbl8_recycle_index].depth,
};
/* Set tbl24 before freeing tbl8 to avoid race condition. */
lpm->tbl24[tbl24_index] = new_tbl24_entry;
tbl8_free_v20(lpm->tbl8, tbl8_group_start);
}
return 0;
}
static int32_t
delete_depth_big_v1604(struct rte_lpm *lpm, uint32_t ip_masked,
uint8_t depth, int32_t sub_rule_index, uint8_t sub_rule_depth)
{
#define group_idx next_hop
uint32_t tbl24_index, tbl8_group_index, tbl8_group_start, tbl8_index,
tbl8_range, i;
int32_t tbl8_recycle_index;
/*
* Calculate the index into tbl24 and range. Note: All depths larger
* than MAX_DEPTH_TBL24 are associated with only one tbl24 entry.
*/
tbl24_index = ip_masked >> 8;
/* Calculate the index into tbl8 and range. */
tbl8_group_index = lpm->tbl24[tbl24_index].group_idx;
tbl8_group_start = tbl8_group_index * RTE_LPM_TBL8_GROUP_NUM_ENTRIES;
tbl8_index = tbl8_group_start + (ip_masked & 0xFF);
tbl8_range = depth_to_range(depth);
if (sub_rule_index < 0) {
/*
* Loop through the range of entries on tbl8 for which the
* rule_to_delete must be removed or modified.
*/
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (lpm->tbl8[i].depth <= depth)
lpm->tbl8[i].valid = INVALID;
}
} else {
/* Set new tbl8 entry. */
struct rte_lpm_tbl_entry new_tbl8_entry = {
.valid = VALID,
.depth = sub_rule_depth,
.valid_group = lpm->tbl8[tbl8_group_start].valid_group,
.next_hop = lpm->rules_tbl[sub_rule_index].next_hop,
};
/*
* Loop through the range of entries on tbl8 for which the
* rule_to_delete must be modified.
*/
for (i = tbl8_index; i < (tbl8_index + tbl8_range); i++) {
if (lpm->tbl8[i].depth <= depth)
lpm->tbl8[i] = new_tbl8_entry;
}
}
/*
* Check if there are any valid entries in this tbl8 group. If all
* tbl8 entries are invalid we can free the tbl8 and invalidate the
* associated tbl24 entry.
*/
tbl8_recycle_index = tbl8_recycle_check_v1604(lpm->tbl8, tbl8_group_start);
if (tbl8_recycle_index == -EINVAL) {
/* Set tbl24 before freeing tbl8 to avoid race condition.
* Prevent the free of the tbl8 group from hoisting.
*/
lpm->tbl24[tbl24_index].valid = 0;
__atomic_thread_fence(__ATOMIC_RELEASE);
tbl8_free_v1604(lpm->tbl8, tbl8_group_start);
} else if (tbl8_recycle_index > -1) {
/* Update tbl24 entry. */
struct rte_lpm_tbl_entry new_tbl24_entry = {
.next_hop = lpm->tbl8[tbl8_recycle_index].next_hop,
.valid = VALID,
.valid_group = 0,
.depth = lpm->tbl8[tbl8_recycle_index].depth,
};
/* Set tbl24 before freeing tbl8 to avoid race condition.
* Prevent the free of the tbl8 group from hoisting.
*/
lpm->tbl24[tbl24_index] = new_tbl24_entry;
__atomic_thread_fence(__ATOMIC_RELEASE);
tbl8_free_v1604(lpm->tbl8, tbl8_group_start);
}
#undef group_idx
return 0;
}
/*
* Deletes a rule
*/
int
rte_lpm_delete_v20(struct rte_lpm_v20 *lpm, uint32_t ip, uint8_t depth)
{
int32_t rule_to_delete_index, sub_rule_index;
uint32_t ip_masked;
uint8_t sub_rule_depth;
/*
* Check input arguments. Note: IP must be a positive integer of 32
* bits in length therefore it need not be checked.
*/
if ((lpm == NULL) || (depth < 1) || (depth > RTE_LPM_MAX_DEPTH)) {
return -EINVAL;
}
ip_masked = ip & depth_to_mask(depth);
/*
* Find the index of the input rule, that needs to be deleted, in the
* rule table.
*/
rule_to_delete_index = rule_find_v20(lpm, ip_masked, depth);
/*
* Check if rule_to_delete_index was found. If no rule was found the
* function rule_find returns -EINVAL.
*/
if (rule_to_delete_index < 0)
return -EINVAL;
/* Delete the rule from the rule table. */
rule_delete_v20(lpm, rule_to_delete_index, depth);
/*
* Find rule to replace the rule_to_delete. If there is no rule to
* replace the rule_to_delete we return -1 and invalidate the table
* entries associated with this rule.
*/
sub_rule_depth = 0;
sub_rule_index = find_previous_rule_v20(lpm, ip, depth, &sub_rule_depth);
/*
* If the input depth value is less than 25 use function
* delete_depth_small otherwise use delete_depth_big.
*/
if (depth <= MAX_DEPTH_TBL24) {
return delete_depth_small_v20(lpm, ip_masked, depth,
sub_rule_index, sub_rule_depth);
} else { /* If depth > MAX_DEPTH_TBL24 */
return delete_depth_big_v20(lpm, ip_masked, depth, sub_rule_index,
sub_rule_depth);
}
}
VERSION_SYMBOL(rte_lpm_delete, _v20, 2.0);
int
rte_lpm_delete_v1604(struct rte_lpm *lpm, uint32_t ip, uint8_t depth)
{
int32_t rule_to_delete_index, sub_rule_index;
uint32_t ip_masked;
uint8_t sub_rule_depth;
/*
* Check input arguments. Note: IP must be a positive integer of 32
* bits in length therefore it need not be checked.
*/
if ((lpm == NULL) || (depth < 1) || (depth > RTE_LPM_MAX_DEPTH)) {
return -EINVAL;
}
ip_masked = ip & depth_to_mask(depth);
/*
* Find the index of the input rule, that needs to be deleted, in the
* rule table.
*/
rule_to_delete_index = rule_find_v1604(lpm, ip_masked, depth);
/*
* Check if rule_to_delete_index was found. If no rule was found the
* function rule_find returns -EINVAL.
*/
if (rule_to_delete_index < 0)
return -EINVAL;
/* Delete the rule from the rule table. */
rule_delete_v1604(lpm, rule_to_delete_index, depth);
/*
* Find rule to replace the rule_to_delete. If there is no rule to
* replace the rule_to_delete we return -1 and invalidate the table
* entries associated with this rule.
*/
sub_rule_depth = 0;
sub_rule_index = find_previous_rule_v1604(lpm, ip, depth, &sub_rule_depth);
/*
* If the input depth value is less than 25 use function
* delete_depth_small otherwise use delete_depth_big.
*/
if (depth <= MAX_DEPTH_TBL24) {
return delete_depth_small_v1604(lpm, ip_masked, depth,
sub_rule_index, sub_rule_depth);
} else { /* If depth > MAX_DEPTH_TBL24 */
return delete_depth_big_v1604(lpm, ip_masked, depth, sub_rule_index,
sub_rule_depth);
}
}
BIND_DEFAULT_SYMBOL(rte_lpm_delete, _v1604, 16.04);
MAP_STATIC_SYMBOL(int rte_lpm_delete(struct rte_lpm *lpm, uint32_t ip,
uint8_t depth), rte_lpm_delete_v1604);
/*
* Delete all rules from the LPM table.
*/
void
rte_lpm_delete_all_v20(struct rte_lpm_v20 *lpm)
{
/* Zero rule information. */
memset(lpm->rule_info, 0, sizeof(lpm->rule_info));
/* Zero tbl24. */
memset(lpm->tbl24, 0, sizeof(lpm->tbl24));
/* Zero tbl8. */
memset(lpm->tbl8, 0, sizeof(lpm->tbl8));
/* Delete all rules form the rules table. */
memset(lpm->rules_tbl, 0, sizeof(lpm->rules_tbl[0]) * lpm->max_rules);
}
VERSION_SYMBOL(rte_lpm_delete_all, _v20, 2.0);
void
rte_lpm_delete_all_v1604(struct rte_lpm *lpm)
{
/* Zero rule information. */
memset(lpm->rule_info, 0, sizeof(lpm->rule_info));
/* Zero tbl24. */
memset(lpm->tbl24, 0, sizeof(lpm->tbl24));
/* Zero tbl8. */
memset(lpm->tbl8, 0, sizeof(lpm->tbl8[0])
* RTE_LPM_TBL8_GROUP_NUM_ENTRIES * lpm->number_tbl8s);
/* Delete all rules form the rules table. */
memset(lpm->rules_tbl, 0, sizeof(lpm->rules_tbl[0]) * lpm->max_rules);
}
BIND_DEFAULT_SYMBOL(rte_lpm_delete_all, _v1604, 16.04);
MAP_STATIC_SYMBOL(void rte_lpm_delete_all(struct rte_lpm *lpm),
rte_lpm_delete_all_v1604);