/* * Copyright (c) 2015 Cisco and/or its affiliates. * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef __included_vnet_classify_h__ #define __included_vnet_classify_h__ #include #include /* for API error numbers */ #include #include #include #include #include extern vlib_node_registration_t ip4_classify_node; extern vlib_node_registration_t ip6_classify_node; #define CLASSIFY_TRACE 0 /* * Classify table option to process packets * CLASSIFY_FLAG_USE_CURR_DATA: * - classify packets starting from VPP node’s current data pointer */ typedef enum vnet_classify_flags_t_ { CLASSIFY_FLAG_NONE = 0, CLASSIFY_FLAG_USE_CURR_DATA = (1 << 0), } __clib_packed vnet_classify_flags_t; /* * Classify session action * CLASSIFY_ACTION_SET_IP4_FIB_INDEX: * - Classified IP packets will be looked up * from the specified ipv4 fib table * CLASSIFY_ACTION_SET_IP6_FIB_INDEX: * - Classified IP packets will be looked up * from the specified ipv6 fib table */ typedef enum vnet_classify_action_t_ { CLASSIFY_ACTION_NONE = 0, CLASSIFY_ACTION_SET_IP4_FIB_INDEX = 1, CLASSIFY_ACTION_SET_IP6_FIB_INDEX = 2, CLASSIFY_ACTION_SET_METADATA = 3, } __clib_packed vnet_classify_action_t; struct _vnet_classify_main; typedef struct _vnet_classify_main vnet_classify_main_t; #define foreach_size_in_u32x4 \ _(1) \ _(2) \ _(3) \ _(4) \ _(5) typedef struct _vnet_classify_entry { /* put into vnet_buffer(b)->l2_classfy.opaque_index */ union { struct { u32 opaque_index; /* advance on hit, note it's a signed quantity... */ i32 advance; }; u64 opaque_count; }; /* Hit counter */ union { u64 hits; struct _vnet_classify_entry *next_free; }; /* last heard time */ f64 last_heard; /* Really only need 1 bit */ u8 flags; #define VNET_CLASSIFY_ENTRY_FREE (1<<0) vnet_classify_action_t action; u16 metadata; /* Graph node next index */ u32 next_index; /* Must be aligned to a 16-octet boundary */ u32x4 key[0]; } vnet_classify_entry_t; /** * Check there's no padding in the entry. the key lies on a 16 byte boundary. */ STATIC_ASSERT_OFFSET_OF (vnet_classify_entry_t, key, 32); static inline int vnet_classify_entry_is_free (vnet_classify_entry_t * e) { return e->flags & VNET_CLASSIFY_ENTRY_FREE; } static inline int vnet_classify_entry_is_busy (vnet_classify_entry_t * e) { return ((e->flags & VNET_CLASSIFY_ENTRY_FREE) == 0); } /* Need these to con the vector allocator */ #define _(size) \ typedef struct \ { \ vnet_classify_entry_t e; \ u32x4 key[size]; \ } __clib_packed vnet_classify_entry_##size##_t; foreach_size_in_u32x4; #undef _ typedef struct { union { struct { u32 offset; u8 linear_search; u8 pad[2]; u8 log2_pages; }; u64 as_u64; }; } vnet_classify_bucket_t; typedef struct { CLIB_CACHE_LINE_ALIGN_MARK (cacheline0); /* hash Buckets */ vnet_classify_bucket_t *buckets; /* Private allocation arena, protected by the writer lock, * where the entries are stored. */ void *mheap; /* User/client data associated with the table */ uword user_ctx; u32 nbuckets; u32 log2_nbuckets; u32 entries_per_page; u32 skip_n_vectors; u32 match_n_vectors; u16 load_mask; /* Index of next table to try */ u32 next_table_index; /* packet offsets */ i16 current_data_offset; vnet_classify_flags_t current_data_flag; /* Miss next index, return if next_table_index = 0 */ u32 miss_next_index; /** * All members accessed in the DP above here */ CLIB_CACHE_LINE_ALIGN_MARK (cacheline1); /* Config parameters */ u32 linear_buckets; u32 active_elements; u32 data_offset; /* Per-bucket working copies, one per thread */ vnet_classify_entry_t **working_copies; int *working_copy_lengths; vnet_classify_bucket_t saved_bucket; /* Free entry freelists */ vnet_classify_entry_t **freelists; /* Writer (only) lock for this table */ clib_spinlock_t writer_lock; CLIB_CACHE_LINE_ALIGN_MARK (cacheline2); /* Mask to apply after skipping N vectors */ u32x4 mask[8]; } vnet_classify_table_t; /** * Ensure DP fields don't spill over to cache-line 2 */ STATIC_ASSERT_OFFSET_OF (vnet_classify_table_t, cacheline1, CLIB_CACHE_LINE_BYTES); /** * The vector size for the classifier * in the add/del table 'match' is the number of vectors of this size */ #define VNET_CLASSIFY_VECTOR_SIZE \ sizeof (((vnet_classify_table_t *) 0)->mask[0]) struct _vnet_classify_main { /* Table pool */ vnet_classify_table_t *tables; /* Registered next-index, opaque unformat fcns */ unformat_function_t **unformat_l2_next_index_fns; unformat_function_t **unformat_ip_next_index_fns; unformat_function_t **unformat_acl_next_index_fns; unformat_function_t **unformat_policer_next_index_fns; unformat_function_t **unformat_opaque_index_fns; /* Per-interface filter table. [0] is used for pcap */ u32 *classify_table_index_by_sw_if_index; /* convenience variables */ vlib_main_t *vlib_main; vnet_main_t *vnet_main; }; extern vnet_classify_main_t vnet_classify_main; u8 *format_classify_table (u8 * s, va_list * args); u8 *format_vnet_classify_table (u8 *s, va_list *args); u64 vnet_classify_hash_packet (vnet_classify_table_t * t, u8 * h); static_always_inline vnet_classify_table_t * vnet_classify_table_get (u32 table_index) { vnet_classify_main_t *vcm = &vnet_classify_main; return (pool_elt_at_index (vcm->tables, table_index)); } static inline u64 vnet_classify_hash_packet_inline (vnet_classify_table_t *t, const u8 *h) { u64 xor_sum; ASSERT (t); h += t->skip_n_vectors * 16; #if defined(CLIB_HAVE_VEC512) && defined(CLIB_HAVE_VEC512_MASK_LOAD_STORE) u64x8 xor_sum_x8, *mask = (u64x8 *) t->mask; u16 load_mask = t->load_mask; u64x8u *data = (u64x8u *) h; xor_sum_x8 = u64x8_mask_load_zero (data, load_mask) & mask[0]; if (PREDICT_FALSE (load_mask >> 8)) xor_sum_x8 ^= u64x8_mask_load_zero (data + 1, load_mask >> 8) & mask[1]; xor_sum_x8 ^= u64x8_align_right (xor_sum_x8, xor_sum_x8, 4); xor_sum_x8 ^= u64x8_align_right (xor_sum_x8, xor_sum_x8, 2); xor_sum = xor_sum_x8[0] ^ xor_sum_x8[1]; #elif defined(CLIB_HAVE_VEC256) && defined(CLIB_HAVE_VEC256_MASK_LOAD_STORE) u64x4 xor_sum_x4, *mask = (u64x4 *) t->mask; u16 load_mask = t->load_mask; u64x4u *data = (u64x4u *) h; xor_sum_x4 = u64x4_mask_load_zero (data, load_mask) & mask[0]; xor_sum_x4 ^= u64x4_mask_load_zero (data + 1, load_mask >> 4) & mask[1]; if (PREDICT_FALSE (load_mask >> 8)) xor_sum_x4 ^= u64x4_mask_load_zero (data + 2, load_mask >> 8) & mask[2]; xor_sum_x4 ^= u64x4_align_right (xor_sum_x4, xor_sum_x4, 2); xor_sum = xor_sum_x4[0] ^ xor_sum_x4[1]; #elif defined(CLIB_HAVE_VEC128) u64x2 *mask = (u64x2 *) t->mask; u64x2u *data = (u64x2u *) h; u64x2 xor_sum_x2; xor_sum_x2 = data[0] & mask[0]; switch (t->match_n_vectors) { case 5: xor_sum_x2 ^= data[4] & mask[4]; /* FALLTHROUGH */ case 4: xor_sum_x2 ^= data[3] & mask[3]; /* FALLTHROUGH */ case 3: xor_sum_x2 ^= data[2] & mask[2]; /* FALLTHROUGH */ case 2: xor_sum_x2 ^= data[1] & mask[1]; /* FALLTHROUGH */ case 1: break; default: abort (); } xor_sum = xor_sum_x2[0] ^ xor_sum_x2[1]; #else u64 *data = (u64 *) h; u64 *mask = (u64 *) t->mask; xor_sum = (data[0] & mask[0]) ^ (data[1] & mask[1]); switch (t->match_n_vectors) { case 5: xor_sum ^= (data[8] & mask[8]) ^ (data[9] & mask[9]); /* FALLTHROUGH */ case 4: xor_sum ^= (data[6] & mask[6]) ^ (data[7] & mask[7]); /* FALLTHROUGH */ case 3: xor_sum ^= (data[4] & mask[4]) ^ (data[5] & mask[5]); /* FALLTHROUGH */ case 2: xor_sum ^= (data[2] & mask[2]) ^ (data[3] & mask[3]); /* FALLTHROUGH */ case 1: break; default: abort (); } #endif /* CLIB_HAVE_VEC128 */ #ifdef clib_crc32c_uses_intrinsics return clib_crc32c ((u8 *) & xor_sum, sizeof (xor_sum)); #else return clib_xxhash (xor_sum.as_u64[0] ^ xor_sum.as_u64[1]); #endif } static inline void vnet_classify_prefetch_bucket (vnet_classify_table_t * t, u64 hash) { u32 bucket_index; ASSERT (is_pow2 (t->nbuckets)); bucket_index = hash & (t->nbuckets - 1); clib_prefetch_load (&t->buckets[bucket_index]); } static inline vnet_classify_entry_t * vnet_classify_get_entry (vnet_classify_table_t * t, uword offset) { u8 *hp = clib_mem_get_heap_base (t->mheap); u8 *vp = hp + offset; return (vnet_classify_entry_t *) vp; } static inline uword vnet_classify_get_offset (vnet_classify_table_t * t, vnet_classify_entry_t * v) { u8 *hp, *vp; hp = (u8 *) clib_mem_get_heap_base (t->mheap); vp = (u8 *) v; ASSERT ((vp - hp) < 0x100000000ULL); return vp - hp; } static inline vnet_classify_entry_t * vnet_classify_entry_at_index (vnet_classify_table_t * t, vnet_classify_entry_t * e, u32 index) { u8 *eu8; eu8 = (u8 *) e; eu8 += index * (sizeof (vnet_classify_entry_t) + (t->match_n_vectors * sizeof (u32x4))); return (vnet_classify_entry_t *) eu8; } static inline void vnet_classify_prefetch_entry (vnet_classify_table_t * t, u64 hash) { u32 bucket_index; u32 value_index; vnet_classify_bucket_t *b; vnet_classify_entry_t *e; bucket_index = hash & (t->nbuckets - 1); b = &t->buckets[bucket_index]; if (b->offset == 0) return; hash >>= t->log2_nbuckets; e = vnet_classify_get_entry (t, b->offset); value_index = hash & ((1 << b->log2_pages) - 1); e = vnet_classify_entry_at_index (t, e, value_index); clib_prefetch_load (e); } vnet_classify_entry_t *vnet_classify_find_entry (vnet_classify_table_t * t, u8 * h, u64 hash, f64 now); static_always_inline int vnet_classify_entry_is_equal (vnet_classify_entry_t *v, const u8 *d, u8 *m, u32 match_n_vectors) { #ifdef CLIB_HAVE_VEC128 u64x2u *data = (u64x2 *) d; u64x2 *key = (u64x2 *) v->key; u64x2 *mask = (u64x2 *) m; u64x2 r; r = (data[0] & mask[0]) ^ key[0]; switch (match_n_vectors) { case 5: r |= (data[4] & mask[4]) ^ key[4]; /* fall through */ case 4: r |= (data[3] & mask[3]) ^ key[3]; /* fall through */ case 3: r |= (data[2] & mask[2]) ^ key[2]; /* fall through */ case 2: r |= (data[1] & mask[1]) ^ key[1]; /* fall through */ case 1: break; default: abort (); } if (u64x2_is_all_zero (r)) return 1; #else u64 *data = (u64 *) d; u64 *key = (u64 *) v->key; u64 *mask = (u64 *) m; u64 r; r = ((data[0] & mask[0]) ^ key[0]) | ((data[1] & mask[1]) ^ key[1]); switch (match_n_vectors) { case 5: r |= ((data[8] & mask[8]) ^ key[8]) | ((data[9] & mask[9]) ^ key[9]); /* fall through */ case 4: r |= ((data[6] & mask[6]) ^ key[6]) | ((data[7] & mask[7]) ^ key[7]); /* fall through */ case 3: r |= ((data[4] & mask[4]) ^ key[4]) | ((data[5] & mask[5]) ^ key[5]); /* fall through */ case 2: r |= ((data[2] & mask[2]) ^ key[2]) | ((data[3] & mask[3]) ^ key[3]); /* fall through */ case 1: break; default: abort (); } if (r == 0) return 1; #endif /* CLIB_HAVE_VEC128 */ return 0; } static inline vnet_classify_entry_t * vnet_classify_find_entry_inline (vnet_classify_table_t *t, const u8 *h, u64 hash, f64 now) { vnet_classify_entry_t *v; vnet_classify_bucket_t *b; u32 bucket_index, limit, pages, match_n_vectors = t->match_n_vectors; u8 *mask = (u8 *) t->mask; int i; bucket_index = hash & (t->nbuckets - 1); b = &t->buckets[bucket_index]; if (b->offset == 0) return 0; pages = 1 << b->log2_pages; v = vnet_classify_get_entry (t, b->offset); limit = t->entries_per_page; if (PREDICT_FALSE (b->linear_search)) { limit *= pages; v = vnet_classify_entry_at_index (t, v, 0); } else { hash >>= t->log2_nbuckets; v = vnet_classify_entry_at_index (t, v, hash & (pages - 1)); } h += t->skip_n_vectors * 16; for (i = 0; i < limit; i++) { if (vnet_classify_entry_is_equal (v, h, mask, match_n_vectors)) { if (PREDICT_TRUE (now)) { v->hits++; v->last_heard = now; } return (v); } v = vnet_classify_entry_at_index (t, v, 1); } return 0; } vnet_classify_table_t *vnet_classify_new_table (vnet_classify_main_t *cm, const u8 *mask, u32 nbuckets, u32 memory_size, u32 skip_n_vectors, u32 match_n_vectors); int vnet_classify_add_del_session (vnet_classify_main_t *cm, u32 table_index, const u8 *match, u32 hit_next_index, u32 opaque_index, i32 advance, u8 action, u16 metadata, int is_add); int vnet_classify_add_del_table (vnet_classify_main_t *cm, const u8 *mask, u32 nbuckets, u32 memory_size, u32 skip, u32 match, u32 next_table_index, u32 miss_next_index, u32 *table_index, u8 current_data_flag, i16 current_data_offset, int is_add, int del_chain); void vnet_classify_delete_table_index (vnet_classify_main_t *cm, u32 table_index, int del_chain); unformat_function_t unformat_ip4_mask; unformat_function_t unformat_ip6_mask; unformat_function_t unformat_l3_mask; unformat_function_t unformat_l2_mask; unformat_function_t unformat_classify_mask; unformat_function_t unformat_l2_next_index; unformat_function_t unformat_ip_next_index; unformat_function_t unformat_ip4_match; unformat_function_t unformat_ip6_match; unformat_function_t unformat_l3_match; unformat_function_t unformat_l4_match; unformat_function_t unformat_vlan_tag; unformat_function_t unformat_l2_match; unformat_function_t unformat_classify_match; void vnet_classify_register_unformat_ip_next_index_fn (unformat_function_t * fn); void vnet_classify_register_unformat_l2_next_index_fn (unformat_function_t * fn); void vnet_classify_register_unformat_acl_next_index_fn (unformat_function_t * fn); void vnet_classify_register_unformat_policer_next_index_fn (unformat_function_t * fn); void vnet_classify_register_unformat_opaque_index_fn (unformat_function_t * fn); u32 classify_get_pcap_chain (vnet_classify_main_t * cm, u32 sw_if_index); void classify_set_pcap_chain (vnet_classify_main_t * cm, u32 sw_if_index, u32 table_index); u32 classify_get_trace_chain (void); void classify_set_trace_chain (vnet_classify_main_t * cm, u32 table_index); u32 classify_sort_table_chain (vnet_classify_main_t * cm, u32 table_index); u32 classify_lookup_chain (u32 table_index, u8 * mask, u32 n_skip, u32 n_match); #endif /* __included_vnet_classify_h__ */ /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */