1 /* SPDX-License-Identifier: BSD-3-Clause
2 * Copyright(c) 2016-2017 Intel Corporation
10 #include <sys/queue.h>
13 #include <rte_eal_memconfig.h>
14 #include <rte_errno.h>
15 #include <rte_malloc.h>
16 #include <rte_prefetch.h>
17 #include <rte_branch_prediction.h>
18 #include <rte_memcpy.h>
20 #include <rte_jhash.h>
21 #include <rte_hash_crc.h>
24 #if defined(RTE_ARCH_X86)
25 #include "rte_efd_x86.h"
26 #elif defined(RTE_ARCH_ARM64)
27 #include "rte_efd_arm64.h"
30 #define EFD_KEY(key_idx, table) (table->keys + ((key_idx) * table->key_len))
31 /** Hash function used to determine chunk_id and bin_id for a group */
32 #define EFD_HASH(key, table) \
33 (uint32_t)(rte_jhash(key, table->key_len, 0xbc9f1d34))
34 /** Hash function used as constant component of perfect hash search */
35 #define EFD_HASHFUNCA(key, table) \
36 (uint32_t)(rte_hash_crc(key, table->key_len, 0xbc9f1d35))
37 /** Hash function used as multiplicative component of perfect hash search */
38 #define EFD_HASHFUNCB(key, table) \
39 (uint32_t)(rte_hash_crc(key, table->key_len, 0xbc9f1d36))
41 /*************************************************************************
43 *************************************************************************/
45 /* These parameters are fixed by the efd_bin_to_group balancing table */
46 #define EFD_CHUNK_NUM_GROUPS (64)
47 #define EFD_CHUNK_NUM_BINS (256)
48 #define EFD_CHUNK_NUM_BIN_TO_GROUP_SETS \
49 (EFD_CHUNK_NUM_BINS / EFD_CHUNK_NUM_GROUPS)
52 * Target number of rules that each chunk is created to handle.
53 * Used when initially allocating the table
55 #define EFD_TARGET_CHUNK_NUM_RULES \
56 (EFD_CHUNK_NUM_GROUPS * EFD_TARGET_GROUP_NUM_RULES)
58 * Max number of rules that each chunk is created to handle.
59 * Used when initially allocating the table
61 #define EFD_TARGET_CHUNK_MAX_NUM_RULES \
62 (EFD_CHUNK_NUM_GROUPS * EFD_MAX_GROUP_NUM_RULES)
64 /** This is fixed based on the bin_to_group permutation array */
65 #define EFD_MAX_GROUP_NUM_BINS (16)
68 * The end of the chunks array needs some extra padding to ensure
69 * that vectorization over-reads on the last online chunk stay within
72 #define EFD_NUM_CHUNK_PADDING_BYTES (256)
74 /* All different internal lookup functions */
75 enum efd_lookup_internal_function {
76 EFD_LOOKUP_SCALAR = 0,
82 TAILQ_HEAD(rte_efd_list, rte_tailq_entry);
84 static struct rte_tailq_elem rte_efd_tailq = {
87 EAL_REGISTER_TAILQ(rte_efd_tailq);
89 /** Internal permutation array used to shuffle bins into pseudorandom groups */
90 const uint32_t efd_bin_to_group[EFD_CHUNK_NUM_BIN_TO_GROUP_SETS][EFD_CHUNK_NUM_BINS] = {
92 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3,
93 4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 7, 7, 7, 7,
94 8, 8, 8, 8, 9, 9, 9, 9, 10, 10, 10, 10, 11, 11, 11, 11,
95 12, 12, 12, 12, 13, 13, 13, 13, 14, 14, 14, 14, 15, 15, 15, 15,
96 16, 16, 16, 16, 17, 17, 17, 17, 18, 18, 18, 18, 19, 19, 19, 19,
97 20, 20, 20, 20, 21, 21, 21, 21, 22, 22, 22, 22, 23, 23, 23, 23,
98 24, 24, 24, 24, 25, 25, 25, 25, 26, 26, 26, 26, 27, 27, 27, 27,
99 28, 28, 28, 28, 29, 29, 29, 29, 30, 30, 30, 30, 31, 31, 31, 31,
100 32, 32, 32, 32, 33, 33, 33, 33, 34, 34, 34, 34, 35, 35, 35, 35,
101 36, 36, 36, 36, 37, 37, 37, 37, 38, 38, 38, 38, 39, 39, 39, 39,
102 40, 40, 40, 40, 41, 41, 41, 41, 42, 42, 42, 42, 43, 43, 43, 43,
103 44, 44, 44, 44, 45, 45, 45, 45, 46, 46, 46, 46, 47, 47, 47, 47,
104 48, 48, 48, 48, 49, 49, 49, 49, 50, 50, 50, 50, 51, 51, 51, 51,
105 52, 52, 52, 52, 53, 53, 53, 53, 54, 54, 54, 54, 55, 55, 55, 55,
106 56, 56, 56, 56, 57, 57, 57, 57, 58, 58, 58, 58, 59, 59, 59, 59,
107 60, 60, 60, 60, 61, 61, 61, 61, 62, 62, 62, 62, 63, 63, 63, 63
110 34, 33, 48, 59, 0, 21, 36, 18, 9, 49, 54, 38, 51, 23, 31, 5,
111 44, 23, 37, 52, 11, 4, 58, 20, 38, 40, 38, 22, 26, 28, 42, 6,
112 46, 16, 31, 28, 46, 14, 60, 0, 35, 53, 16, 58, 16, 29, 39, 7,
113 1, 54, 15, 11, 48, 3, 62, 9, 58, 5, 30, 43, 17, 7, 36, 34,
114 6, 36, 2, 14, 10, 1, 47, 47, 20, 45, 62, 56, 34, 25, 39, 18,
115 51, 41, 61, 25, 56, 40, 41, 37, 52, 35, 30, 57, 11, 42, 37, 27,
116 54, 19, 26, 13, 48, 31, 46, 15, 12, 10, 16, 20, 43, 17, 12, 55,
117 45, 18, 8, 41, 7, 31, 42, 63, 12, 14, 21, 57, 24, 40, 5, 41,
118 13, 44, 23, 59, 25, 57, 52, 50, 62, 1, 2, 49, 32, 57, 26, 43,
119 56, 60, 55, 5, 49, 6, 3, 50, 46, 39, 27, 33, 17, 4, 53, 13,
120 2, 19, 36, 51, 63, 0, 22, 33, 59, 28, 29, 23, 45, 33, 53, 27,
121 22, 21, 40, 56, 4, 18, 44, 47, 28, 17, 4, 50, 21, 62, 8, 39,
122 0, 8, 15, 24, 29, 24, 9, 11, 48, 61, 35, 55, 43, 1, 54, 42,
123 53, 60, 22, 3, 32, 52, 25, 8, 15, 60, 7, 55, 27, 63, 19, 10,
124 63, 24, 61, 19, 12, 38, 6, 29, 13, 37, 10, 3, 45, 32, 32, 30,
125 49, 61, 44, 14, 20, 58, 35, 30, 2, 26, 34, 51, 9, 59, 47, 50
128 32, 35, 32, 34, 55, 5, 6, 23, 49, 11, 6, 23, 52, 37, 29, 54,
129 55, 40, 63, 50, 29, 52, 61, 25, 12, 56, 39, 38, 29, 11, 46, 1,
130 40, 11, 19, 56, 7, 28, 51, 16, 15, 48, 21, 51, 60, 31, 14, 22,
131 41, 47, 59, 56, 53, 28, 58, 26, 43, 27, 41, 33, 24, 52, 44, 38,
132 13, 59, 48, 51, 60, 15, 3, 30, 15, 0, 10, 62, 44, 14, 28, 51,
133 38, 2, 41, 26, 25, 49, 10, 12, 55, 57, 27, 35, 19, 33, 0, 30,
134 5, 36, 47, 53, 5, 53, 20, 43, 34, 37, 52, 41, 21, 63, 59, 9,
135 24, 1, 45, 24, 39, 44, 45, 16, 9, 17, 7, 50, 57, 22, 18, 28,
136 25, 45, 2, 40, 58, 15, 17, 3, 1, 27, 61, 39, 19, 0, 19, 21,
137 57, 62, 54, 60, 54, 40, 48, 33, 36, 37, 4, 42, 1, 43, 58, 8,
138 13, 42, 10, 56, 35, 22, 48, 61, 63, 10, 49, 9, 24, 9, 25, 57,
139 33, 18, 13, 31, 42, 36, 36, 55, 30, 37, 53, 34, 59, 4, 4, 23,
140 8, 16, 58, 14, 30, 11, 12, 63, 49, 62, 2, 39, 47, 22, 2, 60,
141 18, 8, 46, 31, 6, 20, 32, 29, 46, 42, 20, 31, 32, 61, 34, 4,
142 47, 26, 20, 43, 26, 21, 7, 3, 16, 35, 18, 44, 27, 62, 13, 23,
143 6, 50, 12, 8, 45, 17, 3, 46, 50, 7, 14, 5, 17, 54, 38, 0
146 29, 56, 5, 7, 54, 48, 23, 37, 35, 44, 52, 40, 33, 49, 60, 0,
147 59, 51, 28, 12, 41, 26, 2, 23, 34, 5, 59, 40, 3, 19, 6, 26,
148 35, 53, 45, 49, 29, 57, 28, 62, 58, 59, 19, 53, 59, 62, 6, 54,
149 13, 15, 48, 50, 45, 21, 41, 12, 34, 40, 24, 56, 19, 21, 35, 18,
150 55, 45, 9, 61, 47, 61, 19, 15, 16, 39, 17, 31, 3, 51, 21, 50,
151 17, 25, 25, 11, 44, 16, 18, 28, 14, 2, 37, 61, 58, 27, 62, 4,
152 14, 17, 1, 9, 46, 28, 37, 0, 53, 43, 57, 7, 57, 46, 21, 41,
153 39, 14, 52, 60, 44, 53, 49, 60, 49, 63, 13, 11, 29, 1, 55, 47,
154 55, 12, 60, 43, 54, 37, 13, 6, 42, 10, 36, 13, 9, 8, 34, 51,
155 31, 32, 12, 7, 57, 2, 26, 14, 3, 30, 63, 3, 32, 1, 5, 11,
156 27, 24, 26, 44, 31, 23, 56, 38, 62, 0, 40, 30, 6, 23, 38, 2,
157 47, 5, 15, 27, 16, 10, 31, 25, 22, 63, 30, 25, 20, 33, 32, 50,
158 29, 43, 55, 10, 50, 45, 56, 20, 4, 7, 27, 46, 11, 16, 22, 52,
159 35, 20, 41, 54, 46, 33, 42, 18, 63, 8, 22, 58, 36, 4, 51, 42,
160 38, 32, 38, 22, 17, 0, 47, 8, 48, 8, 48, 1, 61, 36, 33, 20,
161 24, 39, 39, 18, 30, 36, 9, 43, 42, 24, 10, 58, 4, 15, 34, 52
165 /*************************************************************************
166 * Offline region structures
167 *************************************************************************/
169 /** Online group containing number of rules, values, keys and their bins
170 * for EFD_MAX_GROUP_NUM_RULES rules.
172 struct efd_offline_group_rules {
174 /**< Sum of the number of rules in all bins assigned to this group. */
176 uint32_t key_idx[EFD_MAX_GROUP_NUM_RULES];
177 /**< Array with all keys of the group. */
178 efd_value_t value[EFD_MAX_GROUP_NUM_RULES];
179 /**< Array with all values of the keys of the group. */
181 uint8_t bin_id[EFD_MAX_GROUP_NUM_RULES];
182 /**< Stores the bin for each correspending key to
183 * avoid having to recompute it
187 /** Offline chunk record, containing EFD_TARGET_CHUNK_NUM_RULES rules.
188 * Those rules are split into EFD_CHUNK_NUM_GROUPS groups per chunk.
190 struct efd_offline_chunk_rules {
192 /**< Number of rules in the entire chunk;
193 * used to detect unbalanced groups
196 struct efd_offline_group_rules group_rules[EFD_CHUNK_NUM_GROUPS];
197 /**< Array of all groups in the chunk. */
200 /*************************************************************************
201 * Online region structures
202 *************************************************************************/
204 /** Online group containing values for EFD_MAX_GROUP_NUM_RULES rules. */
205 struct efd_online_group_entry {
206 efd_hashfunc_t hash_idx[RTE_EFD_VALUE_NUM_BITS];
207 efd_lookuptbl_t lookup_table[RTE_EFD_VALUE_NUM_BITS];
208 } __attribute__((__packed__));
211 * A single chunk record, containing EFD_TARGET_CHUNK_NUM_RULES rules.
212 * Those rules are split into EFD_CHUNK_NUM_GROUPS groups per chunk.
214 struct efd_online_chunk {
215 uint8_t bin_choice_list[(EFD_CHUNK_NUM_BINS * 2 + 7) / 8];
216 /**< This is a packed indirection index into the 'groups' array.
217 * Each byte contains four two-bit values which index into
218 * the efd_bin_to_group array.
219 * The efd_bin_to_group array returns the index into the groups array
222 struct efd_online_group_entry groups[EFD_CHUNK_NUM_GROUPS];
223 /**< Array of all the groups in the chunk. */
224 } __attribute__((__packed__));
227 * EFD table structure
229 struct rte_efd_table {
230 char name[RTE_EFD_NAMESIZE]; /**< Name of the efd table. */
232 uint32_t key_len; /**< Length of the key stored offline */
234 uint32_t max_num_rules;
235 /**< Static maximum number of entries the table was constructed to hold. */
238 /**< Number of entries currently in the table . */
241 /**< Number of chunks in the table needed to support num_rules. */
243 uint32_t num_chunks_shift;
244 /**< Bits to shift to get chunk id, instead of dividing by num_chunk. */
246 enum efd_lookup_internal_function lookup_fn;
247 /**< Indicates which lookup function to use. */
249 struct efd_online_chunk *chunks[RTE_MAX_NUMA_NODES];
250 /**< Dynamic array of size num_chunks of chunk records. */
252 struct efd_offline_chunk_rules *offline_chunks;
253 /**< Dynamic array of size num_chunks of key-value pairs. */
255 struct rte_ring *free_slots;
256 /**< Ring that stores all indexes of the free slots in the key table */
258 uint8_t *keys; /**< Dynamic array of size max_num_rules of keys */
262 * Computes the chunk ID for a given key hash
265 * EFD table to reference
267 * 32-bit key hash returned by EFD_HASH
270 * chunk ID containing this key hash
272 static inline uint32_t
273 efd_get_chunk_id(const struct rte_efd_table * const table,
274 const uint32_t hashed_key)
276 return hashed_key & (table->num_chunks - 1);
280 * Computes the bin ID for a given key hash
283 * EFD table to reference
285 * 32-bit key hash returned by EFD_HASH
287 * @return bin ID containing this key hash
289 static inline uint32_t
290 efd_get_bin_id(const struct rte_efd_table * const table,
291 const uint32_t hashed_key)
293 return (hashed_key >> table->num_chunks_shift) & (EFD_CHUNK_NUM_BINS - 1);
297 * Looks up the current permutation choice for a particular bin in the online table
300 * EFD table to reference
302 * Socket ID to use to look up existing values (ideally caller's socket id)
304 * Chunk ID of bin to look up
309 * Currently active permutation choice in the online table
311 static inline uint8_t
312 efd_get_choice(const struct rte_efd_table * const table,
313 const unsigned int socket_id, const uint32_t chunk_id,
314 const uint32_t bin_id)
316 struct efd_online_chunk *chunk = &table->chunks[socket_id][chunk_id];
319 * Grab the chunk (byte) that contains the choices
320 * for four neighboring bins.
322 uint8_t choice_chunk =
323 chunk->bin_choice_list[bin_id / EFD_CHUNK_NUM_BIN_TO_GROUP_SETS];
326 * Compute the offset into the chunk that contains
327 * the group_id lookup position
329 int offset = (bin_id & 0x3) * 2;
331 /* Extract from the byte just the desired lookup position */
332 return (uint8_t) ((choice_chunk >> offset) & 0x3);
336 * Compute the chunk_id and bin_id for a given key
339 * EFD table to reference
341 * Key to hash and find location of
349 efd_compute_ids(const struct rte_efd_table * const table,
350 const void *key, uint32_t * const chunk_id, uint32_t * const bin_id)
352 /* Compute the position of the entry in the hash table */
353 uint32_t h = EFD_HASH(key, table);
355 /* Compute the chunk_id where that entry can be found */
356 *chunk_id = efd_get_chunk_id(table, h);
359 * Compute the bin within that chunk where the entry
360 * can be found (0 - 255)
362 *bin_id = efd_get_bin_id(table, h);
366 * Search for a hash function for a group that satisfies all group results
369 efd_search_hash(struct rte_efd_table * const table,
370 const struct efd_offline_group_rules * const off_group,
371 struct efd_online_group_entry * const on_group)
373 efd_hashfunc_t hash_idx;
374 efd_hashfunc_t start_hash_idx[RTE_EFD_VALUE_NUM_BITS];
375 efd_lookuptbl_t start_lookup_table[RTE_EFD_VALUE_NUM_BITS];
377 uint32_t i, j, rule_id;
378 uint32_t hash_val_a[EFD_MAX_GROUP_NUM_RULES];
379 uint32_t hash_val_b[EFD_MAX_GROUP_NUM_RULES];
380 uint32_t hash_val[EFD_MAX_GROUP_NUM_RULES];
383 rte_prefetch0(off_group->value);
386 * Prepopulate the hash_val tables by running the two hash functions
387 * for each provided rule
389 for (i = 0; i < off_group->num_rules; i++) {
390 void *key_stored = EFD_KEY(off_group->key_idx[i], table);
391 hash_val_b[i] = EFD_HASHFUNCB(key_stored, table);
392 hash_val_a[i] = EFD_HASHFUNCA(key_stored, table);
395 for (i = 0; i < RTE_EFD_VALUE_NUM_BITS; i++) {
396 hash_idx = on_group->hash_idx[i];
397 start_hash_idx[i] = hash_idx;
398 start_lookup_table[i] = on_group->lookup_table[i];
401 efd_lookuptbl_t lookup_table = 0;
402 efd_lookuptbl_t lookup_table_complement = 0;
404 for (rule_id = 0; rule_id < off_group->num_rules; rule_id++)
405 hash_val[rule_id] = hash_val_a[rule_id] + (hash_idx *
406 hash_val_b[rule_id]);
409 * The goal here is to find a hash function for this
410 * particular bit entry that meets the following criteria:
411 * The most significant bits of the hash result define a
412 * shift into the lookup table where the bit will be stored
415 /* Iterate over each provided rule */
416 for (rule_id = 0; rule_id < off_group->num_rules;
419 * Use the few most significant bits (number based on
420 * EFD_LOOKUPTBL_SIZE) to see what position the
421 * expected bit should be set in the lookup_table
423 uint32_t bucket_idx = hash_val[rule_id] >>
427 * Get the current bit of interest.
428 * This only find an appropriate hash function
429 * for one bit at a time of the rule
431 efd_lookuptbl_t expected =
432 (off_group->value[rule_id] >> i) & 0x1;
435 * Add the expected bit (if set) to a map
436 * (lookup_table). Also set its complement
437 * in lookup_table_complement
439 lookup_table |= expected << bucket_idx;
440 lookup_table_complement |= (1 - expected)
444 * If ever the hash function of two different
445 * elements result in different values at the
446 * same location in the lookup_table,
447 * the current hash_idx is not valid.
449 if (lookup_table & lookup_table_complement)
454 * Check if the previous loop completed without
457 if (rule_id == off_group->num_rules) {
459 * Current hash function worked, store it
460 * for the current group
462 on_group->hash_idx[i] = hash_idx;
463 on_group->lookup_table[i] = lookup_table;
466 * Make sure that the hash function has changed
467 * from the starting value
469 hash_idx = start_hash_idx[i] + 1;
474 } while (hash_idx != start_hash_idx[i]);
476 /* Failed to find perfect hash for this group */
477 if (hash_idx == start_hash_idx[i]) {
479 * Restore previous hash_idx and lookup_table
482 for (j = 0; j < i; j++) {
483 on_group->hash_idx[j] = start_hash_idx[j];
484 on_group->lookup_table[j] = start_lookup_table[j];
493 struct rte_efd_table *
494 rte_efd_create(const char *name, uint32_t max_num_rules, uint32_t key_len,
495 uint8_t online_cpu_socket_bitmask, uint8_t offline_cpu_socket)
497 struct rte_efd_table *table = NULL;
498 uint8_t *key_array = NULL;
499 uint32_t num_chunks, num_chunks_shift;
501 struct rte_efd_list *efd_list = NULL;
502 struct rte_tailq_entry *te;
503 uint64_t offline_table_size;
504 char ring_name[RTE_RING_NAMESIZE];
505 struct rte_ring *r = NULL;
508 efd_list = RTE_TAILQ_CAST(rte_efd_tailq.head, rte_efd_list);
510 if (online_cpu_socket_bitmask == 0) {
511 RTE_LOG(ERR, EFD, "At least one CPU socket must be enabled "
516 if (max_num_rules == 0) {
517 RTE_LOG(ERR, EFD, "Max num rules must be higher than 0\n");
522 * Compute the minimum number of chunks (smallest power of 2)
523 * that can hold all of the rules
525 if (max_num_rules % EFD_TARGET_CHUNK_NUM_RULES == 0)
526 num_chunks = rte_align32pow2(max_num_rules /
527 EFD_TARGET_CHUNK_NUM_RULES);
529 num_chunks = rte_align32pow2((max_num_rules /
530 EFD_TARGET_CHUNK_NUM_RULES) + 1);
532 num_chunks_shift = rte_bsf32(num_chunks);
534 rte_rwlock_write_lock(RTE_EAL_TAILQ_RWLOCK);
537 * Guarantee there's no existing: this is normally already checked
538 * by ring creation above
540 TAILQ_FOREACH(te, efd_list, next)
542 table = (struct rte_efd_table *) te->data;
543 if (strncmp(name, table->name, RTE_EFD_NAMESIZE) == 0)
551 goto error_unlock_exit;
554 te = rte_zmalloc("EFD_TAILQ_ENTRY", sizeof(*te), 0);
556 RTE_LOG(ERR, EFD, "tailq entry allocation failed\n");
557 goto error_unlock_exit;
560 /* Create a new EFD table management structure */
561 table = rte_zmalloc_socket(NULL,
562 sizeof(struct rte_efd_table),
566 RTE_LOG(ERR, EFD, "Allocating EFD table management structure"
567 " on socket %u failed\n",
569 goto error_unlock_exit;
573 RTE_LOG(DEBUG, EFD, "Allocated EFD table management structure "
574 "on socket %u\n", offline_cpu_socket);
576 table->max_num_rules = num_chunks * EFD_TARGET_CHUNK_MAX_NUM_RULES;
577 table->num_rules = 0;
578 table->num_chunks = num_chunks;
579 table->num_chunks_shift = num_chunks_shift;
580 table->key_len = key_len;
583 key_array = rte_zmalloc_socket(NULL,
584 table->max_num_rules * table->key_len,
587 if (key_array == NULL) {
588 RTE_LOG(ERR, EFD, "Allocating key array"
589 " on socket %u failed\n",
591 goto error_unlock_exit;
593 table->keys = key_array;
594 snprintf(table->name, sizeof(table->name), "%s", name);
596 RTE_LOG(DEBUG, EFD, "Creating an EFD table with %u chunks,"
597 " which potentially supports %u entries\n",
598 num_chunks, table->max_num_rules);
600 /* Make sure all the allocatable table pointers are NULL initially */
601 for (socket_id = 0; socket_id < RTE_MAX_NUMA_NODES; socket_id++)
602 table->chunks[socket_id] = NULL;
603 table->offline_chunks = NULL;
606 * Allocate one online table per socket specified
607 * in the user-supplied bitmask
609 uint64_t online_table_size = num_chunks * sizeof(struct efd_online_chunk) +
610 EFD_NUM_CHUNK_PADDING_BYTES;
612 for (socket_id = 0; socket_id < RTE_MAX_NUMA_NODES; socket_id++) {
613 if ((online_cpu_socket_bitmask >> socket_id) & 0x01) {
615 * Allocate all of the EFD table chunks (the online portion)
616 * as a continuous block
618 table->chunks[socket_id] =
624 if (table->chunks[socket_id] == NULL) {
626 "Allocating EFD online table on "
627 "socket %u failed\n",
629 goto error_unlock_exit;
632 "Allocated EFD online table of size "
633 "%"PRIu64" bytes (%.2f MB) on socket %u\n",
635 (float) online_table_size /
641 #if defined(RTE_ARCH_X86)
643 * For less than 4 bits, scalar function performs better
644 * than vectorised version
646 if (RTE_EFD_VALUE_NUM_BITS > 3 && rte_cpu_get_flag_enabled(RTE_CPUFLAG_AVX2))
647 table->lookup_fn = EFD_LOOKUP_AVX2;
650 #if defined(RTE_ARCH_ARM64)
652 * For less than or equal to 16 bits, scalar function performs better
653 * than vectorised version
655 if (RTE_EFD_VALUE_NUM_BITS > 16 &&
656 rte_cpu_get_flag_enabled(RTE_CPUFLAG_NEON))
657 table->lookup_fn = EFD_LOOKUP_NEON;
660 table->lookup_fn = EFD_LOOKUP_SCALAR;
663 * Allocate the EFD table offline portion (with the actual rules
664 * mapping keys to values) as a continuous block.
665 * This could be several gigabytes of memory.
667 offline_table_size = num_chunks * sizeof(struct efd_offline_chunk_rules);
668 table->offline_chunks =
669 rte_zmalloc_socket(NULL,
673 if (table->offline_chunks == NULL) {
674 RTE_LOG(ERR, EFD, "Allocating EFD offline table on socket %u "
675 "failed\n", offline_cpu_socket);
676 goto error_unlock_exit;
680 "Allocated EFD offline table of size %"PRIu64" bytes "
681 " (%.2f MB) on socket %u\n", offline_table_size,
682 (float) offline_table_size / (1024.0F * 1024.0F),
685 te->data = (void *) table;
686 TAILQ_INSERT_TAIL(efd_list, te, next);
687 rte_rwlock_write_unlock(RTE_EAL_TAILQ_RWLOCK);
689 snprintf(ring_name, sizeof(ring_name), "HT_%s", table->name);
690 /* Create ring (Dummy slot index is not enqueued) */
691 r = rte_ring_create(ring_name, rte_align32pow2(table->max_num_rules),
692 offline_cpu_socket, 0);
694 RTE_LOG(ERR, EFD, "memory allocation failed\n");
699 /* Populate free slots ring. Entry zero is reserved for key misses. */
700 for (i = 0; i < table->max_num_rules; i++)
701 rte_ring_sp_enqueue(r, (void *) ((uintptr_t) i));
703 table->free_slots = r;
707 rte_rwlock_write_unlock(RTE_EAL_TAILQ_RWLOCK);
713 struct rte_efd_table *
714 rte_efd_find_existing(const char *name)
716 struct rte_efd_table *table = NULL;
717 struct rte_tailq_entry *te;
718 struct rte_efd_list *efd_list;
720 efd_list = RTE_TAILQ_CAST(rte_efd_tailq.head, rte_efd_list);
722 rte_rwlock_read_lock(RTE_EAL_TAILQ_RWLOCK);
724 TAILQ_FOREACH(te, efd_list, next)
726 table = (struct rte_efd_table *) te->data;
727 if (strncmp(name, table->name, RTE_EFD_NAMESIZE) == 0)
730 rte_rwlock_read_unlock(RTE_EAL_TAILQ_RWLOCK);
740 rte_efd_free(struct rte_efd_table *table)
747 for (socket_id = 0; socket_id < RTE_MAX_NUMA_NODES; socket_id++)
748 rte_free(table->chunks[socket_id]);
750 rte_ring_free(table->free_slots);
751 rte_free(table->offline_chunks);
752 rte_free(table->keys);
757 * Applies a previously computed table entry to the specified table for all
758 * socket-local copies of the online table.
759 * Intended to apply an update for only a single change
760 * to a key/value pair at a time
763 * EFD table to reference
765 * Socket ID to use to lookup existing values (ideally caller's socket id)
767 * Chunk index to update
769 * Group index to update
771 * Bin within the group that this update affects
772 * @param new_bin_choice
773 * Newly chosen permutation which this bin should use - only lower 2 bits
774 * @param new_group_entry
775 * Previously computed updated chunk/group entry
778 efd_apply_update(struct rte_efd_table * const table, const unsigned int socket_id,
779 const uint32_t chunk_id, const uint32_t group_id,
780 const uint32_t bin_id, const uint8_t new_bin_choice,
781 const struct efd_online_group_entry * const new_group_entry)
784 struct efd_online_chunk *chunk = &table->chunks[socket_id][chunk_id];
785 uint8_t bin_index = bin_id / EFD_CHUNK_NUM_BIN_TO_GROUP_SETS;
788 * Grab the current byte that contains the choices
789 * for four neighboring bins
791 uint8_t choice_chunk =
792 chunk->bin_choice_list[bin_index];
795 /* Compute the offset into the chunk that needs to be updated */
796 int offset = (bin_id & 0x3) * 2;
798 /* Zero the two bits of interest and set them to new_bin_choice */
799 choice_chunk = (choice_chunk & (~(0x03 << offset)))
800 | ((new_bin_choice & 0x03) << offset);
802 /* Update the online table with the new data across all sockets */
803 for (i = 0; i < RTE_MAX_NUMA_NODES; i++) {
804 if (table->chunks[i] != NULL) {
805 memcpy(&(table->chunks[i][chunk_id].groups[group_id]),
807 sizeof(struct efd_online_group_entry));
808 table->chunks[i][chunk_id].bin_choice_list[bin_index] =
815 * Move the bin from prev group to the new group
818 move_groups(uint32_t bin_id, uint8_t bin_size,
819 struct efd_offline_group_rules *new_group,
820 struct efd_offline_group_rules * const current_group)
823 uint8_t empty_idx = 0;
826 if (new_group == current_group)
829 for (i = 0; i < current_group->num_rules; i++) {
831 * Move keys that belong to the same bin
834 if (current_group->bin_id[i] == bin_id) {
835 new_group->key_idx[new_group->num_rules] =
836 current_group->key_idx[i];
837 new_group->value[new_group->num_rules] =
838 current_group->value[i];
839 new_group->bin_id[new_group->num_rules] =
840 current_group->bin_id[i];
841 new_group->num_rules++;
843 if (i != empty_idx) {
845 * Need to move this key towards
846 * the top of the array
848 current_group->key_idx[empty_idx] =
849 current_group->key_idx[i];
850 current_group->value[empty_idx] =
851 current_group->value[i];
852 current_group->bin_id[empty_idx] =
853 current_group->bin_id[i];
859 current_group->num_rules -= bin_size;
863 * Revert group/s to their previous state before
864 * trying to insert/add a new key
867 revert_groups(struct efd_offline_group_rules *previous_group,
868 struct efd_offline_group_rules *current_group, uint8_t bin_size)
872 if (current_group == previous_group)
875 /* Move keys back to previous group */
876 for (i = current_group->num_rules - bin_size;
877 i < current_group->num_rules; i++) {
878 previous_group->key_idx[previous_group->num_rules] =
879 current_group->key_idx[i];
880 previous_group->value[previous_group->num_rules] =
881 current_group->value[i];
882 previous_group->bin_id[previous_group->num_rules] =
883 current_group->bin_id[i];
884 previous_group->num_rules++;
888 * Decrease number of rules after the move
891 current_group->num_rules -= bin_size;
895 * Computes an updated table entry where the supplied key points to a new host.
896 * If no entry exists, one is inserted.
898 * This function does NOT modify the online table(s)
899 * This function DOES modify the offline table
902 * EFD table to reference
904 * Socket ID to use to lookup existing values (ideally caller's socket id)
908 * Value to associate with key
910 * Chunk ID of the chunk that was modified
912 * Group ID of the group that was modified
914 * Bin ID that was modified
915 * @param new_bin_choice
916 * Newly chosen permutation which this bin will use
918 * Newly computed online entry to apply later with efd_apply_update
921 * RTE_EFD_UPDATE_WARN_GROUP_FULL
922 * Operation is insert, and the last available space in the
923 * key's group was just used. Future inserts may fail as groups fill up.
924 * This operation was still successful, and entry contains a valid update
925 * RTE_EFD_UPDATE_FAILED
926 * Either the EFD failed to find a suitable perfect hash or the group was full
927 * This is a fatal error, and the table is now in an indeterminate state
928 * RTE_EFD_UPDATE_NO_CHANGE
929 * Operation resulted in no change to the table (same value already exists)
931 * Insert or update was successful, and the new efd_online_group_entry
932 * is stored in *entry
935 * Note that entry will be UNCHANGED if the update has no effect, and thus any
936 * subsequent use of the entry content will likely be invalid
939 efd_compute_update(struct rte_efd_table * const table,
940 const unsigned int socket_id, const void *key,
941 const efd_value_t value, uint32_t * const chunk_id,
942 uint32_t * const group_id, uint32_t * const bin_id,
943 uint8_t * const new_bin_choice,
944 struct efd_online_group_entry * const entry)
949 void *new_k, *slot_id = NULL;
950 int status = EXIT_SUCCESS;
951 unsigned int found = 0;
953 efd_compute_ids(table, key, chunk_id, bin_id);
955 struct efd_offline_chunk_rules * const chunk =
956 &table->offline_chunks[*chunk_id];
957 struct efd_offline_group_rules *new_group;
959 uint8_t current_choice = efd_get_choice(table, socket_id,
961 uint32_t current_group_id = efd_bin_to_group[current_choice][*bin_id];
962 struct efd_offline_group_rules * const current_group =
963 &chunk->group_rules[current_group_id];
964 uint8_t bin_size = 0;
965 uint8_t key_changed_index = 0;
966 efd_value_t key_changed_previous_value = 0;
967 uint32_t key_idx_previous = 0;
969 /* Scan the current group and see if the key is already present */
970 for (i = 0; i < current_group->num_rules; i++) {
971 if (current_group->bin_id[i] == *bin_id)
976 void *key_stored = EFD_KEY(current_group->key_idx[i], table);
977 if (found == 0 && unlikely(memcmp(key_stored, key,
978 table->key_len) == 0)) {
979 /* Key is already present */
982 * If previous value is same as new value,
983 * no additional work is required
985 if (current_group->value[i] == value)
986 return RTE_EFD_UPDATE_NO_CHANGE;
988 key_idx_previous = current_group->key_idx[i];
989 key_changed_previous_value = current_group->value[i];
990 key_changed_index = i;
991 current_group->value[i] = value;
997 /* Key does not exist. Insert the rule into the bin/group */
998 if (unlikely(current_group->num_rules >= EFD_MAX_GROUP_NUM_RULES)) {
1000 "Fatal: No room remaining for insert into "
1001 "chunk %u group %u bin %u\n",
1003 current_group_id, *bin_id);
1004 return RTE_EFD_UPDATE_FAILED;
1007 if (unlikely(current_group->num_rules ==
1008 (EFD_MAX_GROUP_NUM_RULES - 1))) {
1009 RTE_LOG(INFO, EFD, "Warn: Insert into last "
1010 "available slot in chunk %u "
1011 "group %u bin %u\n", *chunk_id,
1012 current_group_id, *bin_id);
1013 status = RTE_EFD_UPDATE_WARN_GROUP_FULL;
1016 if (rte_ring_sc_dequeue(table->free_slots, &slot_id) != 0)
1017 return RTE_EFD_UPDATE_FAILED;
1019 new_k = RTE_PTR_ADD(table->keys, (uintptr_t) slot_id *
1021 rte_prefetch0(new_k);
1022 new_idx = (uint32_t) ((uintptr_t) slot_id);
1024 rte_memcpy(EFD_KEY(new_idx, table), key, table->key_len);
1025 current_group->key_idx[current_group->num_rules] = new_idx;
1026 current_group->value[current_group->num_rules] = value;
1027 current_group->bin_id[current_group->num_rules] = *bin_id;
1028 current_group->num_rules++;
1032 uint32_t last = current_group->num_rules - 1;
1033 /* Swap the key with the last key inserted*/
1034 current_group->key_idx[key_changed_index] =
1035 current_group->key_idx[last];
1036 current_group->value[key_changed_index] =
1037 current_group->value[last];
1038 current_group->bin_id[key_changed_index] =
1039 current_group->bin_id[last];
1042 * Key to be updated will always be available
1043 * at the end of the group
1045 current_group->key_idx[last] = key_idx_previous;
1046 current_group->value[last] = value;
1047 current_group->bin_id[last] = *bin_id;
1050 *new_bin_choice = current_choice;
1051 *group_id = current_group_id;
1052 new_group = current_group;
1054 /* Group need to be rebalanced when it starts to get loaded */
1055 if (current_group->num_rules > EFD_MIN_BALANCED_NUM_RULES) {
1058 * Subtract the number of entries in the bin from
1059 * the original group
1061 current_group->num_rules -= bin_size;
1064 * Figure out which of the available groups that this bin
1065 * can map to is the smallest (using the current group
1068 uint8_t smallest_choice = current_choice;
1069 uint8_t smallest_size = current_group->num_rules;
1070 uint32_t smallest_group_id = current_group_id;
1071 unsigned char choice;
1073 for (choice = 0; choice < EFD_CHUNK_NUM_BIN_TO_GROUP_SETS;
1075 uint32_t test_group_id =
1076 efd_bin_to_group[choice][*bin_id];
1077 uint32_t num_rules =
1078 chunk->group_rules[test_group_id].num_rules;
1079 if (num_rules < smallest_size) {
1080 smallest_choice = choice;
1081 smallest_size = num_rules;
1082 smallest_group_id = test_group_id;
1086 *new_bin_choice = smallest_choice;
1087 *group_id = smallest_group_id;
1088 new_group = &chunk->group_rules[smallest_group_id];
1089 current_group->num_rules += bin_size;
1095 if (current_group != new_group &&
1096 new_group->num_rules + bin_size >
1097 EFD_MAX_GROUP_NUM_RULES) {
1099 "Unable to move_groups to dest group "
1100 "containing %u entries."
1101 "bin_size:%u choice:%02x\n",
1102 new_group->num_rules, bin_size,
1106 move_groups(*bin_id, bin_size, new_group, current_group);
1108 * Recompute the hash function for the modified group,
1109 * and return it to the caller
1111 ret = efd_search_hash(table, new_group, entry);
1117 "Failed to find perfect hash for group "
1118 "containing %u entries. bin_size:%u choice:%02x\n",
1119 new_group->num_rules, bin_size, choice - 1);
1120 /* Restore groups modified to their previous state */
1121 revert_groups(current_group, new_group, bin_size);
1124 if (choice == EFD_CHUNK_NUM_BIN_TO_GROUP_SETS)
1126 *new_bin_choice = choice;
1127 *group_id = efd_bin_to_group[choice][*bin_id];
1128 new_group = &chunk->group_rules[*group_id];
1133 current_group->num_rules--;
1136 current_group->value[current_group->num_rules - 1] =
1137 key_changed_previous_value;
1138 return RTE_EFD_UPDATE_FAILED;
1142 rte_efd_update(struct rte_efd_table * const table, const unsigned int socket_id,
1143 const void *key, const efd_value_t value)
1145 uint32_t chunk_id = 0, group_id = 0, bin_id = 0;
1146 uint8_t new_bin_choice = 0;
1147 struct efd_online_group_entry entry;
1149 int status = efd_compute_update(table, socket_id, key, value,
1150 &chunk_id, &group_id, &bin_id,
1151 &new_bin_choice, &entry);
1153 if (status == RTE_EFD_UPDATE_NO_CHANGE)
1154 return EXIT_SUCCESS;
1156 if (status == RTE_EFD_UPDATE_FAILED)
1159 efd_apply_update(table, socket_id, chunk_id, group_id, bin_id,
1160 new_bin_choice, &entry);
1165 rte_efd_delete(struct rte_efd_table * const table, const unsigned int socket_id,
1166 const void *key, efd_value_t * const prev_value)
1169 uint32_t chunk_id, bin_id;
1170 uint8_t not_found = 1;
1172 efd_compute_ids(table, key, &chunk_id, &bin_id);
1174 struct efd_offline_chunk_rules * const chunk =
1175 &table->offline_chunks[chunk_id];
1177 uint8_t current_choice = efd_get_choice(table, socket_id,
1179 uint32_t current_group_id = efd_bin_to_group[current_choice][bin_id];
1180 struct efd_offline_group_rules * const current_group =
1181 &chunk->group_rules[current_group_id];
1184 * Search the current group for the specified key.
1185 * If it exists, remove it and re-pack the other values
1187 for (i = 0; i < current_group->num_rules; i++) {
1189 /* Found key that needs to be removed */
1190 if (memcmp(EFD_KEY(current_group->key_idx[i], table),
1191 key, table->key_len) == 0) {
1192 /* Store previous value if requested by caller */
1193 if (prev_value != NULL)
1194 *prev_value = current_group->value[i];
1197 rte_ring_sp_enqueue(table->free_slots,
1198 (void *)((uintptr_t)current_group->key_idx[i]));
1202 * If the desired key has been found,
1203 * need to shift other values up one
1206 /* Need to shift this entry back up one index */
1207 current_group->key_idx[i - 1] = current_group->key_idx[i];
1208 current_group->value[i - 1] = current_group->value[i];
1209 current_group->bin_id[i - 1] = current_group->bin_id[i];
1213 if (not_found == 0) {
1215 current_group->num_rules--;
1221 static inline efd_value_t
1222 efd_lookup_internal_scalar(const efd_hashfunc_t *group_hash_idx,
1223 const efd_lookuptbl_t *group_lookup_table,
1224 const uint32_t hash_val_a, const uint32_t hash_val_b)
1226 efd_value_t value = 0;
1229 for (i = 0; i < RTE_EFD_VALUE_NUM_BITS; i++) {
1231 uint32_t h = hash_val_a + (hash_val_b *
1232 group_hash_idx[RTE_EFD_VALUE_NUM_BITS - i - 1]);
1233 uint16_t bucket_idx = h >> EFD_LOOKUPTBL_SHIFT;
1234 value |= (group_lookup_table[
1235 RTE_EFD_VALUE_NUM_BITS - i - 1] >>
1243 static inline efd_value_t
1244 efd_lookup_internal(const struct efd_online_group_entry * const group,
1245 const uint32_t hash_val_a, const uint32_t hash_val_b,
1246 enum efd_lookup_internal_function lookup_fn)
1248 efd_value_t value = 0;
1250 switch (lookup_fn) {
1252 #if defined(RTE_ARCH_X86) && defined(CC_SUPPORT_AVX2)
1253 case EFD_LOOKUP_AVX2:
1254 return efd_lookup_internal_avx2(group->hash_idx,
1255 group->lookup_table,
1260 #if defined(RTE_ARCH_ARM64)
1261 case EFD_LOOKUP_NEON:
1262 return efd_lookup_internal_neon(group->hash_idx,
1263 group->lookup_table,
1268 case EFD_LOOKUP_SCALAR:
1271 return efd_lookup_internal_scalar(group->hash_idx,
1272 group->lookup_table,
1281 rte_efd_lookup(const struct rte_efd_table * const table,
1282 const unsigned int socket_id, const void *key)
1284 uint32_t chunk_id, group_id, bin_id;
1286 const struct efd_online_group_entry *group;
1287 const struct efd_online_chunk * const chunks = table->chunks[socket_id];
1289 /* Determine the chunk and group location for the given key */
1290 efd_compute_ids(table, key, &chunk_id, &bin_id);
1291 bin_choice = efd_get_choice(table, socket_id, chunk_id, bin_id);
1292 group_id = efd_bin_to_group[bin_choice][bin_id];
1293 group = &chunks[chunk_id].groups[group_id];
1295 return efd_lookup_internal(group,
1296 EFD_HASHFUNCA(key, table),
1297 EFD_HASHFUNCB(key, table),
1301 void rte_efd_lookup_bulk(const struct rte_efd_table * const table,
1302 const unsigned int socket_id, const int num_keys,
1303 const void **key_list, efd_value_t * const value_list)
1306 uint32_t chunk_id_list[RTE_EFD_BURST_MAX];
1307 uint32_t bin_id_list[RTE_EFD_BURST_MAX];
1308 uint8_t bin_choice_list[RTE_EFD_BURST_MAX];
1309 uint32_t group_id_list[RTE_EFD_BURST_MAX];
1310 struct efd_online_group_entry *group;
1312 struct efd_online_chunk *chunks = table->chunks[socket_id];
1314 for (i = 0; i < num_keys; i++) {
1315 efd_compute_ids(table, key_list[i], &chunk_id_list[i],
1317 rte_prefetch0(&chunks[chunk_id_list[i]].bin_choice_list);
1320 for (i = 0; i < num_keys; i++) {
1321 bin_choice_list[i] = efd_get_choice(table, socket_id,
1322 chunk_id_list[i], bin_id_list[i]);
1324 efd_bin_to_group[bin_choice_list[i]][bin_id_list[i]];
1325 group = &chunks[chunk_id_list[i]].groups[group_id_list[i]];
1326 rte_prefetch0(group);
1329 for (i = 0; i < num_keys; i++) {
1330 group = &chunks[chunk_id_list[i]].groups[group_id_list[i]];
1331 value_list[i] = efd_lookup_internal(group,
1332 EFD_HASHFUNCA(key_list[i], table),
1333 EFD_HASHFUNCB(key_list[i], table),