/* * 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. */ /* * buffer_funcs.h: VLIB buffer related functions/inlines * * Copyright (c) 2008 Eliot Dresselhaus * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE * LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION * OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #ifndef included_vlib_buffer_funcs_h #define included_vlib_buffer_funcs_h #include #include #include #include #include #include /** \file vlib buffer access methods. */ typedef void (vlib_buffer_enqueue_to_next_fn_t) (vlib_main_t *vm, vlib_node_runtime_t *node, u32 *buffers, u16 *nexts, uword count); typedef void (vlib_buffer_enqueue_to_single_next_fn_t) ( vlib_main_t *vm, vlib_node_runtime_t *node, u32 *ers, u16 next_index, u32 count); typedef u32 (vlib_buffer_enqueue_to_thread_fn_t) ( vlib_main_t *vm, vlib_node_runtime_t *node, u32 frame_queue_index, u32 *buffer_indices, u16 *thread_indices, u32 n_packets, int drop_on_congestion); typedef u32 (vlib_frame_queue_dequeue_fn_t) (vlib_main_t *vm, vlib_frame_queue_main_t *fqm); typedef struct { vlib_buffer_enqueue_to_next_fn_t *buffer_enqueue_to_next_fn; vlib_buffer_enqueue_to_single_next_fn_t *buffer_enqueue_to_single_next_fn; vlib_buffer_enqueue_to_thread_fn_t *buffer_enqueue_to_thread_fn; vlib_frame_queue_dequeue_fn_t *frame_queue_dequeue_fn; } vlib_buffer_func_main_t; extern vlib_buffer_func_main_t vlib_buffer_func_main; always_inline void vlib_buffer_validate (vlib_main_t * vm, vlib_buffer_t * b) { vlib_buffer_main_t *bm = vm->buffer_main; vlib_buffer_pool_t *bp; /* reference count in allocated buffer always must be 1 or higher */ ASSERT (b->ref_count > 0); /* verify that buffer pool index is valid */ bp = vec_elt_at_index (bm->buffer_pools, b->buffer_pool_index); ASSERT (pointer_to_uword (b) >= bp->start); ASSERT (pointer_to_uword (b) < bp->start + bp->size - (bp->data_size + sizeof (vlib_buffer_t))); } always_inline void * vlib_buffer_ptr_from_index (uword buffer_mem_start, u32 buffer_index, uword offset) { offset += ((uword) buffer_index) << CLIB_LOG2_CACHE_LINE_BYTES; return uword_to_pointer (buffer_mem_start + offset, vlib_buffer_t *); } /** \brief Translate buffer index into buffer pointer @param vm - (vlib_main_t *) vlib main data structure pointer @param buffer_index - (u32) buffer index @return - (vlib_buffer_t *) buffer pointer */ always_inline vlib_buffer_t * vlib_get_buffer (vlib_main_t * vm, u32 buffer_index) { vlib_buffer_main_t *bm = vm->buffer_main; vlib_buffer_t *b; b = vlib_buffer_ptr_from_index (bm->buffer_mem_start, buffer_index, 0); vlib_buffer_validate (vm, b); return b; } static_always_inline u32 vlib_buffer_get_default_data_size (vlib_main_t * vm) { return vm->buffer_main->default_data_size; } static_always_inline void vlib_buffer_copy_indices (u32 * dst, u32 * src, u32 n_indices) { clib_memcpy_u32 (dst, src, n_indices); } always_inline void vlib_buffer_copy_indices_from_ring (u32 * dst, u32 * ring, u32 start, u32 ring_size, u32 n_buffers) { ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) { vlib_buffer_copy_indices (dst, ring + start, n_buffers); } else { u32 n = ring_size - start; vlib_buffer_copy_indices (dst, ring + start, n); vlib_buffer_copy_indices (dst + n, ring, n_buffers - n); } } always_inline void vlib_buffer_copy_indices_to_ring (u32 * ring, u32 * src, u32 start, u32 ring_size, u32 n_buffers) { ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) { vlib_buffer_copy_indices (ring + start, src, n_buffers); } else { u32 n = ring_size - start; vlib_buffer_copy_indices (ring + start, src, n); vlib_buffer_copy_indices (ring, src + n, n_buffers - n); } } STATIC_ASSERT_OFFSET_OF (vlib_buffer_t, template_end, 64); static_always_inline void vlib_buffer_copy_template (vlib_buffer_t * b, vlib_buffer_t * bt) { #if defined CLIB_HAVE_VEC512 b->as_u8x64[0] = bt->as_u8x64[0]; #elif defined (CLIB_HAVE_VEC256) b->as_u8x32[0] = bt->as_u8x32[0]; b->as_u8x32[1] = bt->as_u8x32[1]; #elif defined (CLIB_HAVE_VEC128) b->as_u8x16[0] = bt->as_u8x16[0]; b->as_u8x16[1] = bt->as_u8x16[1]; b->as_u8x16[2] = bt->as_u8x16[2]; b->as_u8x16[3] = bt->as_u8x16[3]; #else clib_memcpy_fast (b, bt, 64); #endif } always_inline u8 vlib_buffer_pool_get_default_for_numa (vlib_main_t * vm, u32 numa_node) { ASSERT (numa_node < VLIB_BUFFER_MAX_NUMA_NODES); return vm->buffer_main->default_buffer_pool_index_for_numa[numa_node]; } /** \brief Translate array of buffer indices into buffer pointers with offset @param vm - (vlib_main_t *) vlib main data structure pointer @param bi - (u32 *) array of buffer indices @param b - (void **) array to store buffer pointers @param count - (uword) number of elements @param offset - (i32) offset applied to each pointer */ static_always_inline void vlib_get_buffers_with_offset (vlib_main_t * vm, u32 * bi, void **b, int count, i32 offset) { uword buffer_mem_start = vm->buffer_main->buffer_mem_start; #ifdef CLIB_HAVE_VEC512 u64x8 of8 = u64x8_splat (buffer_mem_start + offset); u64x4 off = u64x8_extract_lo (of8); /* if count is not const, compiler will not unroll while loop se we maintain two-in-parallel variant */ while (count >= 32) { u64x8 b0 = u64x8_from_u32x8 (u32x8_load_unaligned (bi)); u64x8 b1 = u64x8_from_u32x8 (u32x8_load_unaligned (bi + 8)); u64x8 b2 = u64x8_from_u32x8 (u32x8_load_unaligned (bi + 16)); u64x8 b3 = u64x8_from_u32x8 (u32x8_load_unaligned (bi + 24)); /* shift and add to get vlib_buffer_t pointer */ u64x8_store_unaligned ((b0 << CLIB_LOG2_CACHE_LINE_BYTES) + of8, b); u64x8_store_unaligned ((b1 << CLIB_LOG2_CACHE_LINE_BYTES) + of8, b + 8); u64x8_store_unaligned ((b2 << CLIB_LOG2_CACHE_LINE_BYTES) + of8, b + 16); u64x8_store_unaligned ((b3 << CLIB_LOG2_CACHE_LINE_BYTES) + of8, b + 24); b += 32; bi += 32; count -= 32; } while (count >= 8) { u64x8 b0 = u64x8_from_u32x8 (u32x8_load_unaligned (bi)); /* shift and add to get vlib_buffer_t pointer */ u64x8_store_unaligned ((b0 << CLIB_LOG2_CACHE_LINE_BYTES) + of8, b); b += 8; bi += 8; count -= 8; } #elif defined CLIB_HAVE_VEC256 u64x4 off = u64x4_splat (buffer_mem_start + offset); /* if count is not const, compiler will not unroll while loop se we maintain two-in-parallel variant */ while (count >= 32) { u64x4 b0 = u64x4_from_u32x4 (u32x4_load_unaligned (bi)); u64x4 b1 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 4)); u64x4 b2 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 8)); u64x4 b3 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 12)); u64x4 b4 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 16)); u64x4 b5 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 20)); u64x4 b6 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 24)); u64x4 b7 = u64x4_from_u32x4 (u32x4_load_unaligned (bi + 28)); /* shift and add to get vlib_buffer_t pointer */ u64x4_store_unaligned ((b0 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b); u64x4_store_unaligned ((b1 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 4); u64x4_store_unaligned ((b2 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 8); u64x4_store_unaligned ((b3 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 12); u64x4_store_unaligned ((b4 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 16); u64x4_store_unaligned ((b5 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 20); u64x4_store_unaligned ((b6 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 24); u64x4_store_unaligned ((b7 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 28); b += 32; bi += 32; count -= 32; } #endif while (count >= 4) { #ifdef CLIB_HAVE_VEC256 u64x4 b0 = u64x4_from_u32x4 (u32x4_load_unaligned (bi)); /* shift and add to get vlib_buffer_t pointer */ u64x4_store_unaligned ((b0 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b); #elif defined (CLIB_HAVE_VEC128) u64x2 off = u64x2_splat (buffer_mem_start + offset); u32x4 bi4 = u32x4_load_unaligned (bi); u64x2 b0 = u64x2_from_u32x4 ((u32x4) bi4); #if defined (__aarch64__) u64x2 b1 = u64x2_from_u32x4_high ((u32x4) bi4); #else bi4 = u32x4_shuffle (bi4, 2, 3, 0, 1); u64x2 b1 = u64x2_from_u32x4 ((u32x4) bi4); #endif u64x2_store_unaligned ((b0 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b); u64x2_store_unaligned ((b1 << CLIB_LOG2_CACHE_LINE_BYTES) + off, b + 2); #else b[0] = vlib_buffer_ptr_from_index (buffer_mem_start, bi[0], offset); b[1] = vlib_buffer_ptr_from_index (buffer_mem_start, bi[1], offset); b[2] = vlib_buffer_ptr_from_index (buffer_mem_start, bi[2], offset); b[3] = vlib_buffer_ptr_from_index (buffer_mem_start, bi[3], offset); #endif b += 4; bi += 4; count -= 4; } while (count) { b[0] = vlib_buffer_ptr_from_index (buffer_mem_start, bi[0], offset); b += 1; bi += 1; count -= 1; } } /** \brief Translate array of buffer indices into buffer pointers @param vm - (vlib_main_t *) vlib main data structure pointer @param bi - (u32 *) array of buffer indices @param b - (vlib_buffer_t **) array to store buffer pointers @param count - (uword) number of elements */ static_always_inline void vlib_get_buffers (vlib_main_t * vm, u32 * bi, vlib_buffer_t ** b, int count) { vlib_get_buffers_with_offset (vm, bi, (void **) b, count, 0); } /** \brief Translate buffer pointer into buffer index @param vm - (vlib_main_t *) vlib main data structure pointer @param p - (void *) buffer pointer @return - (u32) buffer index */ always_inline u32 vlib_get_buffer_index (vlib_main_t * vm, void *p) { vlib_buffer_main_t *bm = vm->buffer_main; uword offset = pointer_to_uword (p) - bm->buffer_mem_start; ASSERT (pointer_to_uword (p) >= bm->buffer_mem_start); ASSERT (offset < bm->buffer_mem_size); ASSERT ((offset % (1 << CLIB_LOG2_CACHE_LINE_BYTES)) == 0); return offset >> CLIB_LOG2_CACHE_LINE_BYTES; } /** \brief Translate array of buffer pointers into buffer indices with offset @param vm - (vlib_main_t *) vlib main data structure pointer @param b - (void **) array of buffer pointers @param bi - (u32 *) array to store buffer indices @param count - (uword) number of elements @param offset - (i32) offset applied to each pointer */ static_always_inline void vlib_get_buffer_indices_with_offset (vlib_main_t * vm, void **b, u32 * bi, uword count, i32 offset) { #ifdef CLIB_HAVE_VEC256 u32x8 mask = { 0, 2, 4, 6, 1, 3, 5, 7 }; u64x4 off4 = u64x4_splat (vm->buffer_main->buffer_mem_start - offset); while (count >= 8) { /* load 4 pointers into 256-bit register */ u64x4 v0 = u64x4_load_unaligned (b); u64x4 v1 = u64x4_load_unaligned (b + 4); u32x8 v2, v3; v0 -= off4; v1 -= off4; v0 >>= CLIB_LOG2_CACHE_LINE_BYTES; v1 >>= CLIB_LOG2_CACHE_LINE_BYTES; /* permute 256-bit register so lower u32s of each buffer index are * placed into lower 128-bits */ v2 = u32x8_permute ((u32x8) v0, mask); v3 = u32x8_permute ((u32x8) v1, mask); /* extract lower 128-bits and save them to the array of buffer indices */ u32x4_store_unaligned (u32x8_extract_lo (v2), bi); u32x4_store_unaligned (u32x8_extract_lo (v3), bi + 4); bi += 8; b += 8; count -= 8; } #endif while (count >= 4) { /* equivalent non-nector implementation */ bi[0] = vlib_get_buffer_index (vm, ((u8 *) b[0]) + offset); bi[1] = vlib_get_buffer_index (vm, ((u8 *) b[1]) + offset); bi[2] = vlib_get_buffer_index (vm, ((u8 *) b[2]) + offset); bi[3] = vlib_get_buffer_index (vm, ((u8 *) b[3]) + offset); bi += 4; b += 4; count -= 4; } while (count) { bi[0] = vlib_get_buffer_index (vm, ((u8 *) b[0]) + offset); bi += 1; b += 1; count -= 1; } } /** \brief Translate array of buffer pointers into buffer indices @param vm - (vlib_main_t *) vlib main data structure pointer @param b - (vlib_buffer_t **) array of buffer pointers @param bi - (u32 *) array to store buffer indices @param count - (uword) number of elements */ static_always_inline void vlib_get_buffer_indices (vlib_main_t * vm, vlib_buffer_t ** b, u32 * bi, uword count) { vlib_get_buffer_indices_with_offset (vm, (void **) b, bi, count, 0); } /** \brief Get next buffer in buffer linklist, or zero for end of list. @param vm - (vlib_main_t *) vlib main data structure pointer @param b - (void *) buffer pointer @return - (vlib_buffer_t *) next buffer, or NULL */ always_inline vlib_buffer_t * vlib_get_next_buffer (vlib_main_t * vm, vlib_buffer_t * b) { return (b->flags & VLIB_BUFFER_NEXT_PRESENT ? vlib_get_buffer (vm, b->next_buffer) : 0); } uword vlib_buffer_length_in_chain_slow_path (vlib_main_t * vm, vlib_buffer_t * b_first); /** \brief Get length in bytes of the buffer chain @param vm - (vlib_main_t *) vlib main data structure pointer @param b - (void *) buffer pointer @return - (uword) length of buffer chain */ always_inline uword vlib_buffer_length_in_chain (vlib_main_t * vm, vlib_buffer_t * b) { uword len = b->current_length; if (PREDICT_TRUE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0)) return len; if (PREDICT_TRUE (b->flags & VLIB_BUFFER_TOTAL_LENGTH_VALID)) return len + b->total_length_not_including_first_buffer; return vlib_buffer_length_in_chain_slow_path (vm, b); } /** \brief Get length in bytes of the buffer index buffer chain @param vm - (vlib_main_t *) vlib main data structure pointer @param bi - (u32) buffer index @return - (uword) length of buffer chain */ always_inline uword vlib_buffer_index_length_in_chain (vlib_main_t * vm, u32 bi) { vlib_buffer_t *b = vlib_get_buffer (vm, bi); return vlib_buffer_length_in_chain (vm, b); } /** \brief Copy buffer contents to memory @param vm - (vlib_main_t *) vlib main data structure pointer @param buffer_index - (u32) buffer index @param contents - (u8 *) memory, must be large enough @return - (uword) length of buffer chain */ always_inline uword vlib_buffer_contents (vlib_main_t * vm, u32 buffer_index, u8 * contents) { uword content_len = 0; uword l; vlib_buffer_t *b; while (1) { b = vlib_get_buffer (vm, buffer_index); l = b->current_length; clib_memcpy_fast (contents + content_len, b->data + b->current_data, l); content_len += l; if (!(b->flags & VLIB_BUFFER_NEXT_PRESENT)) break; buffer_index = b->next_buffer; } return content_len; } always_inline uword vlib_buffer_get_pa (vlib_main_t * vm, vlib_buffer_t * b) { return vlib_physmem_get_pa (vm, b->data); } always_inline uword vlib_buffer_get_current_pa (vlib_main_t * vm, vlib_buffer_t * b) { return vlib_buffer_get_pa expected_state); always_inline vlib_buffer_known_state_t vlib_buffer_is_known (vlib_main_t * vm, u32 buffer_index) { vlib_buffer_main_t *bm = vm->buffer_main; clib_spinlock_lock (&bm->buffer_known_hash_lockp); uword *p = hash_get (bm->buffer_known_hash, buffer_index); clib_spinlock_unlock (&bm->buffer_known_hash_lockp); return p ? p[0] : VLIB_BUFFER_UNKNOWN; } /* Validates sanity of a single buffer. Returns format'ed vector with error message if any. */ u8 *vlib_validate_buffer (vlib_main_t * vm, u32 buffer_index, uword follow_chain); u8 *vlib_validate_buffers (vlib_main_t * vm, u32 * buffers, uword next_buffer_stride, uword n_buffers, vlib_buffer_known_state_t known_state, uword follow_buffer_next); static_always_inline vlib_buffer_pool_t * vlib_get_buffer_pool (vlib_main_t * vm, u8 buffer_pool_index) { vlib_buffer_main_t *bm = vm->buffer_main; return vec_elt_at_index (bm->buffer_pools, buffer_pool_index); } static_always_inline __clib_warn_unused_result uword vlib_buffer_pool_get (vlib_main_t * vm, u8 buffer_pool_index, u32 * buffers, u32 n_buffers) { vlib_buffer_pool_t *bp = vlib_get_buffer_pool (vm, buffer_pool_index); u32 len; ASSERT (bp->buffers); clib_spinlock_lock (&bp->lock); len = bp->n_avail; if (PREDICT_TRUE (n_buffers < len)) { len -= n_buffers; vlib_buffer_copy_indices (buffers, bp->buffers + len, n_buffers); bp->n_avail = len; clib_spinlock_unlock (&bp->lock); return n_buffers; } else { vlib_buffer_copy_indices (buffers, bp->buffers, len); bp->n_avail = 0; clib_spinlock_unlock (&bp->lock); return len; } } /** \brief Allocate buffers from specific pool into supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index array @param n_buffers - (u32) number of buffers requested @return - (u32) number of buffers actually allocated, may be less than the number requested or zero */ always_inline __clib_warn_unused_result u32 vlib_buffer_alloc_from_pool (vlib_main_t * vm, u32 * buffers, u32 n_buffers, u8 buffer_pool_index) { vlib_buffer_main_t *bm = vm->buffer_main; vlib_buffer_pool_t *bp; vlib_buffer_pool_thread_t *bpt; u32 *src, *dst, len, n_left; /* If buffer allocation fault injection is configured */ if (VLIB_BUFFER_ALLOC_FAULT_INJECTOR > 0) { u32 vlib_buffer_alloc_may_fail (vlib_main_t *, u32); /* See how many buffers we're willing to allocate */ n_buffers = vlib_buffer_alloc_may_fail (vm, n_buffers); if (n_buffers == 0) return (n_buffers); } bp = vec_elt_at_index (bm->buffer_pools, buffer_pool_index); bpt = vec_elt_at_index (bp->threads, vm->thread_index); dst = buffers; n_left = n_buffers; len = bpt->n_cached; /* per-thread cache contains enough buffers */ if (len >= n_buffers) { src = bpt->cached_buffers + len - n_buffers; vlib_buffer_copy_indices (dst, src, n_buffers); bpt->n_cached -= n_buffers; if (CLIB_DEBUG > 0) vlib_buffer_validate_alloc_free (vm, buffers, n_buffers, VLIB_BUFFER_KNOWN_FREE); return n_buffers; } /* alloc bigger than cache - take buffers directly from main pool */ if (n_buffers >= VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ) { n_buffers = vlib_buffer_pool_get (vm, buffer_pool_index, buffers, n_buffers); if (CLIB_DEBUG > 0) vlib_buffer_validate_alloc_free (vm, buffers, n_buffers, VLIB_BUFFER_KNOWN_FREE); return n_buffers; } /* take everything available in the cache */ if (len) { vlib_buffer_copy_indices (dst, bpt->cached_buffers, len); bpt->n_cached = 0; dst += len; n_left -= len; } len = round_pow2 (n_left, 32); len = vlib_buffer_pool_get (vm, buffer_pool_index, bpt->cached_buffers, len); bpt->n_cached = len; if (len) { u32 n_copy = clib_min (len, n_left); src = bpt->cached_buffers + len - n_copy; vlib_buffer_copy_indices (dst, src, n_copy); bpt->n_cached -= n_copy; n_left -= n_copy; } n_buffers -= n_left; /* Verify that buffers are known free. */ if (CLIB_DEBUG > 0) vlib_buffer_validate_alloc_free (vm, buffers, n_buffers, VLIB_BUFFER_KNOWN_FREE); return n_buffers; } /** \brief Allocate buffers from specific numa node into supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index array @param n_buffers - (u32) number of buffers requested @param numa_node - (u32) numa node @return - (u32) number of buffers actually allocated, may be less than the number requested or zero */ always_inline __clib_warn_unused_result u32 vlib_buffer_alloc_on_numa (vlib_main_t * vm, u32 * buffers, u32 n_buffers, u32 numa_node) { u8 index = vlib_buffer_pool_get_default_for_numa (vm, numa_node); return vlib_buffer_alloc_from_pool (vm, buffers, n_buffers, index); } /** \brief Allocate buffers into supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index array @param n_buffers - (u32) number of buffers requested @return - (u32) number of buffers actually allocated, may be less than the number requested or zero */ always_inline __clib_warn_unused_result u32 vlib_buffer_alloc (vlib_main_t * vm, u32 * buffers, u32 n_buffers) { return vlib_buffer_alloc_on_numa (vm, buffers, n_buffers, vm->numa_node); } /** \brief Allocate buffers into ring @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index ring @param start - (u32) first slot in the ring @param ring_size - (u32) ring size @param n_buffers - (u32) number of buffers requested @return - (u32) number of buffers actually allocated, may be less than the number requested or zero */ always_inline __clib_warn_unused_result u32 vlib_buffer_alloc_to_ring (vlib_main_t * vm, u32 * ring, u32 start, u32 ring_size, u32 n_buffers) { u32 n_alloc; ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) return vlib_buffer_alloc (vm, ring + start, n_buffers); n_alloc = vlib_buffer_alloc (vm, ring + start, ring_size - start); if (PREDICT_TRUE (n_alloc == ring_size - start)) n_alloc += vlib_buffer_alloc (vm, ring, n_buffers - n_alloc); return n_alloc; } /** \brief Allocate buffers into ring from specific buffer pool @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index ring @param start - (u32) first slot in the ring @param ring_size - (u32) ring size @param n_buffers - (u32) number of buffers requested @return - (u32) number of buffers actually allocated, may be less than the number requested or zero */ always_inline __clib_warn_unused_result u32 vlib_buffer_alloc_to_ring_from_pool (vlib_main_t * vm, u32 * ring, u32 start, u32 ring_size, u32 n_buffers, u8 buffer_pool_index) { u32 n_alloc; ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) return vlib_buffer_alloc_from_pool (vm, ring + start, n_buffers, buffer_pool_index); n_alloc = vlib_buffer_alloc_from_pool (vm, ring + start, ring_size - start, buffer_pool_index); if (PREDICT_TRUE (n_alloc == ring_size - start)) n_alloc += vlib_buffer_alloc_from_pool (vm, ring, n_buffers - n_alloc, buffer_pool_index); return n_alloc; } static_always_inline void vlib_buffer_pool_put (vlib_main_t * vm, u8 buffer_pool_index, u32 * buffers, u32 n_buffers) { vlib_buffer_pool_t *bp = vlib_get_buffer_pool (vm, buffer_pool_index); vlib_buffer_pool_thread_t *bpt = vec_elt_at_index (bp->threads, vm->thread_index); u32 n_cached, n_empty; if (CLIB_DEBUG > 0) vlib_buffer_validate_alloc_free (vm, buffers, n_buffers, VLIB_BUFFER_KNOWN_ALLOCATED); n_cached = bpt->n_cached; n_empty = VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ - n_cached; if (n_buffers <= n_empty) { vlib_buffer_copy_indices (bpt->cached_buffers + n_cached, buffers, n_buffers); bpt->n_cached = n_cached + n_buffers; return; } vlib_buffer_copy_indices (bpt->cached_buffers + n_cached, buffers + n_buffers - n_empty, n_empty); bpt->n_cached = VLIB_BUFFER_POOL_PER_THREAD_CACHE_SZ; clib_spinlock_lock (&bp->lock); vlib_buffer_copy_indices (bp->buffers + bp->n_avail, buffers, n_buffers - n_empty); bp->n_avail += n_buffers - n_empty; clib_spinlock_unlock (&bp->lock); } static_always_inline void vlib_buffer_free_inline (vlib_main_t * vm, u32 * buffers, u32 n_buffers, int maybe_next) { const int queue_size = 128; vlib_buffer_pool_t *bp = 0; u8 buffer_pool_index = ~0; u32 n_queue = 0, queue[queue_size + 4]; vlib_buffer_t bt = { }; #if defined(CLIB_HAVE_VEC128) vlib_buffer_t bpi_mask = {.buffer_pool_index = ~0 }; vlib_buffer_t bpi_vec = {}; vlib_buffer_t flags_refs_mask = { .flags = VLIB_BUFFER_NEXT_PRESENT, .ref_count = ~1 }; #endif if (PREDICT_FALSE (n_buffers == 0)) return; vlib_buffer_t *b = vlib_get_buffer (vm, buffers[0]); buffer_pool_index = b->buffer_pool_index; bp = vlib_get_buffer_pool (vm, buffer_pool_index); vlib_buffer_copy_template (&bt, &bp->buffer_template); #if defined(CLIB_HAVE_VEC128) bpi_vec.buffer_pool_index = buffer_pool_index; #endif while (n_buffers) { vlib_buffer_t *b[8]; u32 bi, sum = 0, flags, next; if (n_buffers < 4) goto one_by_one; vlib_get_buffers (vm, buffers, b, 4); if (n_buffers >= 12) { vlib_get_buffers (vm, buffers + 8, b + 4, 4); vlib_prefetch_buffer_header (b[4], LOAD); vlib_prefetch_buffer_header (b[5], LOAD); vlib_prefetch_buffer_header (b[6], LOAD); vlib_prefetch_buffer_header (b[7], LOAD); } #if defined(CLIB_HAVE_VEC128) u8x16 p0, p1, p2, p3, r; p0 = u8x16_load_unaligned (b[0]); p1 = u8x16_load_unaligned (b[1]); p2 = u8x16_load_unaligned (b[2]); p3 = u8x16_load_unaligned (b[3]); r = p0 ^ bpi_vec.as_u8x16[0]; r |= p1 ^ bpi_vec.as_u8x16[0]; r |= p2 ^ bpi_vec.as_u8x16[0]; r |= p3 ^ bpi_vec.as_u8x16[0]; r &= bpi_mask.as_u8x16[0]; r |= (p0 | p1 | p2 | p3) & flags_refs_mask.as_u8x16[0]; sum = !u8x16_is_all_zero (r); #else sum |= b[0]->flags; sum |= b[1]->flags; sum |= b[2]->flags; sum |= b[3]->flags; sum &= VLIB_BUFFER_NEXT_PRESENT; sum += b[0]->ref_count - 1; sum += b[1]->ref_count - 1; sum += b[2]->ref_count - 1; sum += b[3]->ref_count - 1; sum |= b[0]->buffer_pool_index ^ buffer_pool_index; sum |= b[1]->buffer_pool_index ^ buffer_pool_index; sum |= b[2]->buffer_pool_index ^ buffer_pool_index; sum |= b[3]->buffer_pool_index ^ buffer_pool_index; #endif if (sum) goto one_by_one; vlib_buffer_copy_indices (queue + n_queue, buffers, 4); vlib_buffer_copy_template (b[0], &bt); vlib_buffer_copy_template (b[1], &bt); vlib_buffer_copy_template (b[2], &bt); vlib_buffer_copy_template (b[3], &bt); n_queue += 4; vlib_buffer_validate (vm, b[0]); vlib_buffer_validate (vm, b[1]); vlib_buffer_validate (vm, b[2]); vlib_buffer_validate (vm, b[3]); VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[0]); VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[1]); VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[2]); VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[3]); if (n_queue >= queue_size) { vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue); n_queue = 0; } buffers += 4; n_buffers -= 4; continue; one_by_one: bi = buffers[0]; next_in_chain: b[0] = vlib_get_buffer (vm, bi); flags = b[0]->flags; next = b[0]->next_buffer; if (PREDICT_FALSE (buffer_pool_index != b[0]->buffer_pool_index)) { if (n_queue) { vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue); n_queue = 0; } buffer_pool_index = b[0]->buffer_pool_index; #if defined(CLIB_HAVE_VEC128) bpi_vec.buffer_pool_index = buffer_pool_index; #endif bp = vlib_get_buffer_pool (vm, buffer_pool_index); vlib_buffer_copy_template (&bt, &bp->buffer_template); } vlib_buffer_validate (vm, b[0]); VLIB_BUFFER_TRACE_TRAJECTORY_INIT (b[0]); if (clib_atomic_sub_fetch (&b[0]->ref_count, 1) == 0) { vlib_buffer_copy_template (b[0], &bt); queue[n_queue++] = bi; } if (n_queue == queue_size) { vlib_buffer_pool_put (vm, buffer_pool_index, queue, queue_size); n_queue = 0; } if (maybe_next && (flags & VLIB_BUFFER_NEXT_PRESENT)) { bi = next; goto next_in_chain; } buffers++; n_buffers--; } if (n_queue) vlib_buffer_pool_put (vm, buffer_pool_index, queue, n_queue); } /** \brief Free buffers Frees the entire buffer chain for each buffer @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index array @param n_buffers - (u32) number of buffers to free */ always_inline void vlib_buffer_free (vlib_main_t * vm, /* pointer to first buffer */ u32 * buffers, /* number of buffers to free */ u32 n_buffers) { vlib_buffer_free_inline (vm, buffers, n_buffers, /* maybe next */ 1); } /** \brief Free buffers, does not free the buffer chain for each buffer @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index array @param n_buffers - (u32) number of buffers to free */ always_inline void vlib_buffer_free_no_next (vlib_main_t * vm, /* pointer to first buffer */ u32 * buffers, /* number of buffers to free */ u32 n_buffers) { vlib_buffer_free_inline (vm, buffers, n_buffers, /* maybe next */ 0); } /** \brief Free one buffer Shorthand to free a single buffer chain. @param vm - (vlib_main_t *) vlib main data structure pointer @param buffer_index - (u32) buffer index to free */ always_inline void vlib_buffer_free_one (vlib_main_t * vm, u32 buffer_index) { vlib_buffer_free_inline (vm, &buffer_index, 1, /* maybe next */ 1); } /** \brief Free buffers from ring @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index ring @param start - (u32) first slot in the ring @param ring_size - (u32) ring size @param n_buffers - (u32) number of buffers */ always_inline void vlib_buffer_free_from_ring (vlib_main_t * vm, u32 * ring, u32 start, u32 ring_size, u32 n_buffers) { ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) { vlib_buffer_free (vm, ring + start, n_buffers); } else { vlib_buffer_free (vm, ring + start, ring_size - start); vlib_buffer_free (vm, ring, n_buffers - (ring_size - start)); } } /** \brief Free buffers from ring without freeing tail buffers @param vm - (vlib_main_t *) vlib main data structure pointer @param buffers - (u32 * ) buffer index ring @param start - (u32) first slot in the ring @param ring_size - (u32) ring size @param n_buffers - (u32) number of buffers */ always_inline void vlib_buffer_free_from_ring_no_next (vlib_main_t * vm, u32 * ring, u32 start, u32 ring_size, u32 n_buffers) { ASSERT (n_buffers <= ring_size); if (PREDICT_TRUE (start + n_buffers <= ring_size)) { vlib_buffer_free_no_next (vm, ring + start, n_buffers); } else { vlib_buffer_free_no_next (vm, ring + start, ring_size - start); vlib_buffer_free_no_next (vm, ring, n_buffers - (ring_size - start)); } } /* Append given data to end of buffer, possibly allocating new buffers. */ int vlib_buffer_add_data (vlib_main_t * vm, u32 * buffer_index, void *data, u32 n_data_bytes); /* Define vlib_buffer and vnet_buffer flags bits preserved for copy/clone */ #define VLIB_BUFFER_COPY_CLONE_FLAGS_MASK \ (VLIB_BUFFER_NEXT_PRESENT | VLIB_BUFFER_TOTAL_LENGTH_VALID | \ VLIB_BUFFER_IS_TRACED | ~VLIB_BUFFER_FLAGS_ALL) /* duplicate all buffers in chain */ always_inline vlib_buffer_t * vlib_buffer_copy (vlib_main_t * vm, vlib_buffer_t * b) { vlib_buffer_t *s, *d, *fd; uword n_alloc, n_buffers = 1; u32 flag_mask = VLIB_BUFFER_COPY_CLONE_FLAGS_MASK; int i; s = b; while (s->flags & VLIB_BUFFER_NEXT_PRESENT) { n_buffers++; s = vlib_get_buffer (vm, s->next_buffer); } u32 new_buffers[n_buffers]; n_alloc = vlib_buffer_alloc (vm, new_buffers, n_buffers); /* No guarantee that we'll get all the buffers we asked for */ if (PREDICT_FALSE (n_alloc < n_buffers)) { if (n_alloc > 0) vlib_buffer_free (vm, new_buffers, n_alloc); return 0; } /* 1st segment */ s = b; fd = d = vlib_get_buffer (vm, new_buffers[0]); d->current_data = s->current_data; d->current_length = s->current_length; d->flags = s->flags & flag_mask; d->trace_handle = s->trace_handle; d->total_length_not_including_first_buffer = s->total_length_not_including_first_buffer; clib_memcpy_fast (d->opaque, s->opaque, sizeof (s->opaque)); clib_memcpy_fast (d->opaque2, s->opaque2, sizeof (s->opaque2)); clib_memcpy_fast (vlib_buffer_get_current (d), vlib_buffer_get_current (s), s->current_length); /* next segments */ for (i = 1; i < n_buffers; i++) { /* previous */ d->next_buffer = new_buffers[i]; /* current */ s = vlib_get_buffer (vm, s->next_buffer); d = vlib_get_buffer (vm, new_buffers[i]); d->current_data = s->current_data; d->current_length = s->current_length; clib_memcpy_fast (vlib_buffer_get_current (d), vlib_buffer_get_current (s), s->current_length); d->flags = s->flags & flag_mask; } return fd; } /* duplicate first buffer in chain */ always_inline vlib_buffer_t * vlib_buffer_copy_no_chain (vlib_main_t * vm, vlib_buffer_t * b, u32 * di) { vlib_buffer_t *d; if ((vlib_buffer_alloc (vm, di, 1)) != 1) return 0; d = vlib_get_buffer (vm, *di); /* 1st segment */ d->current_data = b->current_data; d->current_length = b->current_length; clib_memcpy_fast (d->opaque, b->opaque, sizeof (b->opaque)); clib_memcpy_fast (d->opaque2, b->opaque2, sizeof (b->opaque2)); clib_memcpy_fast (vlib_buffer_get_current (d), vlib_buffer_get_current (b), b->current_length); return d; } /* \brief Move packet from current position to offset position in buffer. Only work for small packet using one buffer with room to fit the move @param vm - (vlib_main_t *) vlib main data structure pointer @param b - (vlib_buffer_t *) pointer to buffer @param offset - (i16) position to move the packet in buffer */ always_inline void vlib_buffer_move (vlib_main_t * vm, vlib_buffer_t * b, i16 offset) { ASSERT ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0); ASSERT (offset + VLIB_BUFFER_PRE_DATA_SIZE >= 0); ASSERT (offset + b->current_length < vlib_buffer_get_default_data_size (vm)); u8 *source = vlib_buffer_get_current (b); b->current_data = offset; u8 *destination = vlib_buffer_get_current (b); u16 length = b->current_length; if (source + length <= destination) /* no overlap */ clib_memcpy_fast (destination, source, length); else memmove (destination, source, length); } /** \brief Create a maximum of 256 clones of buffer and store them in the supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param src_buffer - (u32) source buffer index @param buffers - (u32 * ) buffer index array @param n_buffers - (u16) number of buffer clones requested (<=256) @param head_end_offset - (u16) offset relative to current position where packet head ends @param offset - (i16) copy packet head at current position if 0, else at offset position to change headroom space as specified @return - (u16) number of buffers actually cloned, may be less than the number requested or zero */ always_inline u16 vlib_buffer_clone_256 (vlib_main_t * vm, u32 src_buffer, u32 * buffers, u16 n_buffers, u16 head_end_offset, i16 offset) { u16 i; vlib_buffer_t *s = vlib_get_buffer (vm, src_buffer); ASSERT (s->ref_count == 1); ASSERT (n_buffers); ASSERT (n_buffers <= 256); ASSERT (offset + VLIB_BUFFER_PRE_DATA_SIZE >= 0); ASSERT ((offset + head_end_offset) < vlib_buffer_get_default_data_size (vm)); if (s->current_length <= head_end_offset + CLIB_CACHE_LINE_BYTES * 2) { buffers[0] = src_buffer; if (offset) vlib_buffer_move (vm, s, offset); for (i = 1; i < n_buffers; i++) { vlib_buffer_t *d; d = vlib_buffer_copy (vm, s); if (d == 0) return i; buffers[i] = vlib_get_buffer_index (vm, d); } return n_buffers; } if (PREDICT_FALSE ((n_buffers == 1) && (offset == 0))) { buffers[0] = src_buffer; return 1; } n_buffers = vlib_buffer_alloc_from_pool (vm, buffers, n_buffers, s->buffer_pool_index); for (i = 0; i < n_buffers; i++) { vlib_buffer_t *d = vlib_get_buffer (vm, buffers[i]); if (offset) d->current_data = offset; else d->current_data = s->current_data; d->current_length = head_end_offset; ASSERT (d->buffer_pool_index == s->buffer_pool_index); d->total_length_not_including_first_buffer = s->current_length - head_end_offset; if (PREDICT_FALSE (s->flags & VLIB_BUFFER_NEXT_PRESENT)) { d->total_length_not_including_first_buffer += s->total_length_not_including_first_buffer; } d->flags = (s->flags & VLIB_BUFFER_COPY_CLONE_FLAGS_MASK) | VLIB_BUFFER_NEXT_PRESENT; d->trace_handle = s->trace_handle; clib_memcpy_fast (d->opaque, s->opaque, sizeof (s->opaque)); clib_memcpy_fast (d->opaque2, s->opaque2, sizeof (s->opaque2)); clib_memcpy_fast (vlib_buffer_get_current (d), vlib_buffer_get_current (s), head_end_offset); d->next_buffer = src_buffer; } vlib_buffer_advance (s, head_end_offset); s->ref_count = n_buffers ? n_buffers : s->ref_count; while (s->flags & VLIB_BUFFER_NEXT_PRESENT) { s = vlib_get_buffer (vm, s->next_buffer); s->ref_count = n_buffers ? n_buffers : s->ref_count; } return n_buffers; } /** \brief Create multiple clones of buffer and store them in the supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param src_buffer - (u32) source buffer index @param buffers - (u32 * ) buffer index array @param n_buffers - (u16) number of buffer clones requested (<=256) @param head_end_offset - (u16) offset relative to current position where packet head ends @param offset - (i16) copy packet head at current position if 0, else at offset position to change headroom space as specified @return - (u16) number of buffers actually cloned, may be less than the number requested or zero */ always_inline u16 vlib_buffer_clone_at_offset (vlib_main_t * vm, u32 src_buffer, u32 * buffers, u16 n_buffers, u16 head_end_offset, i16 offset) { vlib_buffer_t *s = vlib_get_buffer (vm, src_buffer); u16 n_cloned = 0; while (n_buffers > 256) { vlib_buffer_t *copy; copy = vlib_buffer_copy (vm, s); n_cloned += vlib_buffer_clone_256 (vm, vlib_get_buffer_index (vm, copy), (buffers + n_cloned), 256, head_end_offset, offset); n_buffers -= 256; } n_cloned += vlib_buffer_clone_256 (vm, src_buffer, buffers + n_cloned, n_buffers, head_end_offset, offset); return n_cloned; } /** \brief Create multiple clones of buffer and store them in the supplied array @param vm - (vlib_main_t *) vlib main data structure pointer @param src_buffer - (u32) source buffer index @param buffers - (u32 * ) buffer index array @param n_buffers - (u16) number of buffer clones requested (<=256) @param head_end_offset - (u16) offset relative to current position where packet head ends @return - (u16) number of buffers actually cloned, may be less than the number requested or zero */ always_inline u16 vlib_buffer_clone (vlib_main_t * vm, u32 src_buffer, u32 * buffers, u16 n_buffers, u16 head_end_offset) { return vlib_buffer_clone_at_offset (vm, src_buffer, buffers, n_buffers, head_end_offset, 0); } /** \brief Attach cloned tail to the buffer @param vm - (vlib_main_t *) vlib main data structure pointer @param head - (vlib_buffer_t *) head buffer @param tail - (Vlib buffer_t *) tail buffer to clone and attach to head */ always_inline void vlib_buffer_attach_clone (vlib_main_t * vm, vlib_buffer_t * head, vlib_buffer_t * tail) { ASSERT ((head->flags & VLIB_BUFFER_NEXT_PRESENT) == 0); ASSERT (head->buffer_pool_index == tail->buffer_pool_index); head->flags |= VLIB_BUFFER_NEXT_PRESENT; head->flags &= ~VLIB_BUFFER_TOTAL_LENGTH_VALID; head->flags &= ~VLIB_BUFFER_EXT_HDR_VALID; head->flags |= (tail->flags & VLIB_BUFFER_TOTAL_LENGTH_VALID); head->next_buffer = vlib_get_buffer_index (vm, tail); head->total_length_not_including_first_buffer = tail->current_length + tail->total_length_not_including_first_buffer; next_segment: clib_atomic_add_fetch (&tail->ref_count, 1); if (tail->flags & VLIB_BUFFER_NEXT_PRESENT) { tail = vlib_get_buffer (vm, tail->next_buffer); goto next_segment; } } /* Initializes the buffer as an empty packet with no chained buffers. */ always_inline void vlib_buffer_chain_init (vlib_buffer_t * first) { first->total_length_not_including_first_buffer = 0; first->current_length = 0; first->flags &= ~VLIB_BUFFER_NEXT_PRESENT; first->flags |= VLIB_BUFFER_TOTAL_LENGTH_VALID; } /* The provided next_bi buffer index is appended to the end of the packet. */ always_inline vlib_buffer_t * vlib_buffer_chain_buffer (vlib_main_t * vm, vlib_buffer_t * last, u32 next_bi) { vlib_buffer_t *next_buffer = vlib_get_buffer (vm, next_bi); last->next_buffer = next_bi; last->flags |= VLIB_BUFFER_NEXT_PRESENT; next_buffer->current_length = 0; next_buffer->flags &= ~VLIB_BUFFER_NEXT_PRESENT; return next_buffer; } /* Increases or decreases the packet length. * It does not allocate or deallocate new buffers. * Therefore, the added length must be compatible * with the last buffer. */ always_inline void vlib_buffer_chain_increase_length (vlib_buffer_t * first, vlib_buffer_t * last, i32 len) { last->current_length += len; if (first != last) first->total_length_not_including_first_buffer += len; } /* Copy data to the end of the packet and increases its length. * It does not allocate new buffers. * Returns the number of copied bytes. */ always_inline u16 vlib_buffer_chain_append_data (vlib_main_t * vm, vlib_buffer_t * first, vlib_buffer_t * last, void *data, u16 data_len) { u32 n_buffer_bytes = vlib_buffer_get_default_data_size (vm); ASSERT (n_buffer_bytes >= last->current_length + last->current_data); u16 len = clib_min (data_len, n_buffer_bytes - last->current_length - last->current_data); clib_memcpy_fast (vlib_buffer_get_current (last) + last->current_length, data, len); vlib_buffer_chain_increase_length (first, last, len); return len; } /* Copy data to the end of the packet and increases its length. * Allocates additional buffers from the free list if necessary. * Returns the number of copied bytes. * 'last' value is modified whenever new buffers are allocated and * chained and points to the last buffer in the chain. */ u16 vlib_buffer_chain_append_data_with_alloc (vlib_main_t * vm, vlib_buffer_t * first, vlib_buffer_t ** last, void *data, u16 data_len); void vlib_buffer_chain_validate (vlib_main_t * vm, vlib_buffer_t * first); format_function_t format_vlib_buffer, format_vlib_buffer_and_data, format_vlib_buffer_contents, format_vlib_buffer_no_chain; typedef struct { /* Vector of packet data. */ u8 *packet_data; /* Number of buffers to allocate in each call to allocator. */ u32 min_n_buffers_each_alloc; u8 *name; } vlib_packet_template_t; void vlib_packet_template_init (vlib_main_t * vm, vlib_packet_template_t * t, void *packet_data, uword n_packet_data_bytes, uword min_n_buffers_each_alloc, char *fmt, ...); void *vlib_packet_template_get_packet (vlib_main_t * vm, vlib_packet_template_t * t, u32 * bi_result); always_inline void vlib_packet_template_free (vlib_main_t * vm, vlib_packet_template_t * t) { vec_free (t->packet_data); } always_inline u32 vlib_buffer_space_left_at_end (vlib_main_t * vm, vlib_buffer_t * b) { return b->data + vlib_buffer_get_default_data_size (vm) - ((u8 *) vlib_buffer_get_current (b) + b->current_length); } always_inline u32 vlib_buffer_chain_linearize (vlib_main_t * vm, vlib_buffer_t * b) { vlib_buffer_t *db = b, *sb, *first = b; int is_cloned = 0; u32 bytes_left = 0, data_size; u16 src_left, dst_left, n_buffers = 1; u8 *dp, *sp; u32 to_free = 0; if (PREDICT_TRUE ((b->flags & VLIB_BUFFER_NEXT_PRESENT) == 0)) return 1; data_size = vlib_buffer_get_default_data_size (vm); dst_left = vlib_buffer_space_left_at_end (vm, b); while (b->flags & VLIB_BUFFER_NEXT_PRESENT) { b = vlib_get_buffer (vm, b->next_buffer); if (b->ref_count > 1) is_cloned = 1; bytes_left += b->current_length; n_buffers++; } /* if buffer is cloned, create completely new chain - unless everything fits * into one buffer */ if (is_cloned && bytes_left >= dst_left) { u32 len = 0; u32 space_needed = bytes_left - dst_left; u32 tail; if (vlib_buffer_alloc (vm, &tail, 1) == 0) return 0; ++n_buffers; len += data_size; b = vlib_get_buffer (vm, tail); while (len < space_needed) { u32 bi; if (vlib_buffer_alloc (vm, &bi, 1) == 0) { vlib_buffer_free_one (vm, tail); return 0; } b->flags = VLIB_BUFFER_NEXT_PRESENT; b->next_buffer = bi; b = vlib_get_buffer (vm, bi); len += data_size; n_buffers++; } sb = vlib_get_buffer (vm, first->next_buffer); to_free = first->next_buffer; first->next_buffer = tail; } else sb = vlib_get_buffer (vm, first->next_buffer); src_left = sb->current_length; sp = vlib_buffer_get_current (sb); dp = vlib_buffer_get_tail (db); while (bytes_left) { u16 bytes_to_copy; if (dst_left == 0) { db->current_length = dp - (u8 *) vlib_buffer_get_current (db); ASSERT (db->flags & VLIB_BUFFER_NEXT_PRESENT); db = vlib_get_buffer (vm, db->next_buffer); dst_left = data_size; if (db->current_data > 0) { db->current_data = 0; } else { dst_left += -db->current_data; } dp = vlib_buffer_get_current (db); } while (src_left == 0) { ASSERT (sb->flags & VLIB_BUFFER_NEXT_PRESENT); sb = vlib_get_buffer (vm, sb->next_buffer); src_left = sb->current_length; sp = vlib_buffer_get_current (sb); } bytes_to_copy = clib_min (dst_left, src_left); if (dp != sp) { if (sb == db) bytes_to_copy = clib_min (bytes_to_copy, sp - dp); clib_memcpy_fast (dp, sp, bytes_to_copy); } src_left -= bytes_to_copy; dst_left -= bytes_to_copy; dp += bytes_to_copy; sp += bytes_to_copy; bytes_left -= bytes_to_copy; } if (db != first) db->current_data = 0; db->current_length = dp - (u8 *) vlib_buffer_get_current (db); if (is_cloned && to_free) vlib_buffer_free_one (vm, to_free); else { if (db->flags & VLIB_BUFFER_NEXT_PRESENT) vlib_buffer_free_one (vm, db->next_buffer); db->flags &= ~VLIB_BUFFER_NEXT_PRESENT; b = first; n_buffers = 1; while (b->flags & VLIB_BUFFER_NEXT_PRESENT) { b = vlib_get_buffer (vm, b->next_buffer); ++n_buffers; } } first->flags &= ~VLIB_BUFFER_TOTAL_LENGTH_VALID; return n_buffers; } #endif /* included_vlib_buffer_funcs_h */ /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */