/* * 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.c: allocate/free network buffers. * * 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include phys_addr_t __attribute__ ((weak)) rte_mem_virt2phy(); int __attribute__ ((weak)) rte_eal_has_hugepages(); unsigned __attribute__ ((weak)) rte_socket_id(); struct rte_mempool * __attribute__ ((weak)) rte_mempool_create(); void __attribute__ ((weak)) rte_pktmbuf_init(); void __attribute__ ((weak)) rte_pktmbuf_pool_init(); uword vlib_buffer_length_in_chain_slow_path (vlib_main_t * vm, vlib_buffer_t * b_first) { vlib_buffer_t * b = b_first; uword l_first = b_first->current_length; uword l = 0; while (b->flags & VLIB_BUFFER_NEXT_PRESENT) { b = vlib_get_buffer (vm, b->next_buffer); l += b->current_length; } b_first->total_length_not_including_first_buffer = l; b_first->flags |= VLIB_BUFFER_TOTAL_LENGTH_VALID; return l + l_first; } u8 * format_vlib_buffer (u8 * s, va_list * args) { vlib_buffer_t * b = va_arg (*args, vlib_buffer_t *); uword indent = format_get_indent (s); s = format (s, "current data %d, length %d, free-list %d", b->current_data, b->current_length, b->free_list_index); if (b->flags & VLIB_BUFFER_TOTAL_LENGTH_VALID) s = format (s, ", totlen-nifb %d", b->total_length_not_including_first_buffer); if (b->flags & VLIB_BUFFER_IS_TRACED) s = format (s, ", trace 0x%x", b->trace_index); while (b->flags & VLIB_BUFFER_NEXT_PRESENT) { vlib_main_t * vm = vlib_get_main(); u32 next_buffer = b->next_buffer; b = vlib_get_buffer(vm, next_buffer); s = format (s, "\n%Unext-buffer 0x%x, segment length %d", format_white_space, indent, next_buffer, b->current_length); } return s; } u8 * format_vlib_buffer_and_data (u8 * s, va_list * args) { vlib_buffer_t * b = va_arg (*args, vlib_buffer_t *); s = format (s, "%U, %U", format_vlib_buffer, b, format_hex_bytes, vlib_buffer_get_current (b), 64); return s; } u8 * format_vlib_buffer_contents (u8 * s, va_list * va) { vlib_main_t * vm = va_arg (*va, vlib_main_t *); vlib_buffer_t * b = va_arg (*va, vlib_buffer_t *); while (1) { vec_add (s, vlib_buffer_get_current (b), b->current_length); if (! (b->flags & VLIB_BUFFER_NEXT_PRESENT)) break; b = vlib_get_buffer (vm, b->next_buffer); } return s; } vlib_main_t **vlib_mains; /* Aligned copy routine. */ void vlib_aligned_memcpy (void * _dst, void * _src, int n_bytes) { vlib_copy_unit_t * dst = _dst; vlib_copy_unit_t * src = _src; /* Arguments must be naturally aligned. */ ASSERT (pointer_to_uword (dst) % sizeof (dst[0]) == 0); ASSERT (pointer_to_uword (src) % sizeof (src[0]) == 0); ASSERT (n_bytes % sizeof (dst[0]) == 0); if (4 * sizeof (dst[0]) == CLIB_CACHE_LINE_BYTES) { CLIB_PREFETCH (dst + 0, 4 * sizeof (dst[0]), WRITE); CLIB_PREFETCH (src + 0, 4 * sizeof (src[0]), READ); while (n_bytes >= 4 * sizeof (dst[0])) { dst += 4; src += 4; n_bytes -= 4 * sizeof (dst[0]); CLIB_PREFETCH (dst, 4 * sizeof (dst[0]), WRITE); CLIB_PREFETCH (src, 4 * sizeof (src[0]), READ); dst[-4] = src[-4]; dst[-3] = src[-3]; dst[-2] = src[-2]; dst[-1] = src[-1]; } } else if (8 * sizeof (dst[0]) == CLIB_CACHE_LINE_BYTES) { CLIB_PREFETCH (dst + 0, 8 * sizeof (dst[0]), WRITE); CLIB_PREFETCH (src + 0, 8 * sizeof (src[0]), READ); while (n_bytes >= 8 * sizeof (dst[0])) { dst += 8; src += 8; n_bytes -= 8 * sizeof (dst[0]); CLIB_PREFETCH (dst, 8 * sizeof (dst[0]), WRITE); CLIB_PREFETCH (src, 8 * sizeof (src[0]), READ); dst[-8] = src[-8]; dst[-7] = src[-7]; dst[-6] = src[-6]; dst[-5] = src[-5]; dst[-4] = src[-4]; dst[-3] = src[-3]; dst[-2] = src[-2]; dst[-1] = src[-1]; } } else /* Cache line size unknown: fall back to slow version. */; while (n_bytes > 0) { *dst++ = *src++; n_bytes -= 1 * sizeof (dst[0]); } } #define BUFFERS_PER_COPY (sizeof (vlib_copy_unit_t) / sizeof (u32)) /* Make sure we have at least given number of unaligned buffers. */ static void fill_unaligned (vlib_main_t * vm, vlib_buffer_free_list_t * free_list, uword n_unaligned_buffers) { word la = vec_len (free_list->aligned_buffers); word lu = vec_len (free_list->unaligned_buffers); /* Aligned come in aligned copy-sized chunks. */ ASSERT (la % BUFFERS_PER_COPY == 0); ASSERT (la >= n_unaligned_buffers); while (lu < n_unaligned_buffers) { /* Copy 4 buffers from end of aligned vector to unaligned vector. */ vec_add (free_list->unaligned_buffers, free_list->aligned_buffers + la - BUFFERS_PER_COPY, BUFFERS_PER_COPY); la -= BUFFERS_PER_COPY; lu += BUFFERS_PER_COPY; } _vec_len (free_list->aligned_buffers) = la; } /* After free aligned buffers may not contain even sized chunks. */ static void trim_aligned (vlib_buffer_free_list_t * f) { uword l, n_trim; /* Add unaligned to aligned before trim. */ l = vec_len (f->unaligned_buffers); if (l > 0) { vec_add_aligned (f->aligned_buffers, f->unaligned_buffers, l, /* align */ sizeof (vlib_copy_unit_t)); _vec_len (f->unaligned_buffers) = 0; } /* Remove unaligned buffers from end of aligned vector and save for next trim. */ l = vec_len (f->aligned_buffers); n_trim = l % BUFFERS_PER_COPY; if (n_trim) { /* Trim aligned -> unaligned. */ vec_add (f->unaligned_buffers, f->aligned_buffers + l - n_trim, n_trim); /* Remove from aligned. */ _vec_len (f->aligned_buffers) = l - n_trim; } } static void merge_free_lists (vlib_buffer_free_list_t * dst, vlib_buffer_free_list_t * src) { uword l; u32 * d; trim_aligned (src); trim_aligned (dst); l = vec_len (src->aligned_buffers); if (l > 0) { vec_add2_aligned (dst->aligned_buffers, d, l, /* align */ sizeof (vlib_copy_unit_t)); vlib_aligned_memcpy (d, src->aligned_buffers, l * sizeof (d[0])); vec_free (src->aligned_buffers); } l = vec_len (src->unaligned_buffers); if (l > 0) { vec_add (dst->unaligned_buffers, src->unaligned_buffers, l); vec_free (src->unaligned_buffers); } } always_inline u32 vlib_buffer_get_free_list_with_size (vlib_main_t * vm, u32 size) { vlib_buffer_main_t * bm = vm->buffer_main; size = vlib_buffer_round_size (size); uword * p = hash_get (bm->free_list_by_size, size); return p ? p[0] : ~0; } /* Add buffer free list. */ static u32 vlib_buffer_create_free_list_helper (vlib_main_t * vm, u32 n_data_bytes, u32 is_public, u32 is_default, u8 * name) { vlib_buffer_main_t * bm = vm->buffer_main; vlib_buffer_free_list_t * f; if (! is_default && pool_elts (bm->buffer_free_list_pool) == 0) { u32 default_free_free_list_index; default_free_free_list_index = vlib_buffer_create_free_list_helper (vm, /* default buffer size */ VLIB_BUFFER_DEFAULT_FREE_LIST_BYTES, /* is_public */ 1, /* is_default */ 1, (u8 *) "default"); ASSERT (default_free_free_list_index == VLIB_BUFFER_DEFAULT_FREE_LIST_INDEX); if (n_data_bytes == VLIB_BUFFER_DEFAULT_FREE_LIST_BYTES && is_public) return default_free_free_list_index; } pool_get_aligned (bm->buffer_free_list_pool, f, CLIB_CACHE_LINE_BYTES); memset (f, 0, sizeof (f[0])); f->index = f - bm->buffer_free_list_pool; f->n_data_bytes = vlib_buffer_round_size (n_data_bytes); f->min_n_buffers_each_physmem_alloc = 16; f->name = clib_mem_is_heap_object (name) ? name : format (0, "%s", name); /* Setup free buffer template. */ f->buffer_init_template.free_list_index = f->index; if (is_public) { uword * p = hash_get (bm->free_list_by_size, f->n_data_bytes); if (! p) hash_set (bm->free_list_by_size, f->n_data_bytes, f->index); } return f->index; } u32 vlib_buffer_create_free_list (vlib_main_t * vm, u32 n_data_bytes, char * fmt, ...) { va_list va; u8 * name; va_start (va, fmt); name = va_format (0, fmt, &va); va_end (va); return vlib_buffer_create_free_list_helper (vm, n_data_bytes, /* is_public */ 0, /* is_default */ 0, name); } u32 vlib_buffer_get_or_create_free_list (vlib_main_t * vm, u32 n_data_bytes, char * fmt, ...) { u32 i = vlib_buffer_get_free_list_with_size (vm, n_data_bytes); if (i == ~0) { va_list va; u8 * name; va_start (va, fmt); name = va_format (0, fmt, &va); va_end (va); i = vlib_buffer_create_free_list_helper (vm, n_data_bytes, /* is_public */ 1, /* is_default */ 0, name); } return i; } static void del_free_list (vlib_main_t * vm, vlib_buffer_free_list_t * f) { u32 i; struct rte_mbuf *mb; vlib_buffer_t *b; for (i = 0; i < vec_len (f->unaligned_buffers); i++) { b = vlib_get_buffer (vm, f->unaligned_buffers[i]); mb = ((struct rte_mbuf *)b)-1; rte_pktmbuf_free (mb); } for (i = 0; i < vec_len (f->aligned_buffers); i++) { b = vlib_get_buffer (vm, f->aligned_buffers[i]); mb = ((struct rte_mbuf *)b)-1; rte_pktmbuf_free (mb); } vec_free (f->name); vec_free (f->unaligned_buffers); vec_free (f->aligned_buffers); } /* Add buffer free list. */ void vlib_buffer_delete_free_list (vlib_main_t * vm, u32 free_list_index) { vlib_buffer_main_t * bm = vm->buffer_main; vlib_buffer_free_list_t * f; u32 merge_index; f = vlib_buffer_get_free_list (vm, free_list_index); merge_index = vlib_buffer_get_free_list_with_size (vm, f->n_data_bytes); if (merge_index != ~0 && merge_index != free_list_index) { merge_free_lists (pool_elt_at_index (bm->buffer_free_list_pool, merge_index), f); } del_free_list (vm, f); /* Poison it. */ memset (f, 0xab, sizeof (f[0])); pool_put (bm->buffer_free_list_pool, f); } /* Make sure free list has at least given number of free buffers. */ static uword fill_free_list (vlib_main_t * vm, vlib_buffer_free_list_t * fl, uword min_free_buffers) { vlib_buffer_t * b; int n, i; u32 bi; u32 n_remaining, n_alloc; unsigned socket_id = rte_socket_id ? rte_socket_id() : 0; struct rte_mempool *rmp = vm->buffer_main->pktmbuf_pools[socket_id]; struct rte_mbuf *mb; /* Too early? */ if (PREDICT_FALSE(rmp == 0)) return 0; trim_aligned (fl); /* Already have enough free buffers on free list? */ n = min_free_buffers - vec_len (fl->aligned_buffers); if (n <= 0) return min_free_buffers; /* Always allocate round number of buffers. */ n = round_pow2 (n, BUFFERS_PER_COPY); /* Always allocate new buffers in reasonably large sized chunks. */ n = clib_max (n, fl->min_n_buffers_each_physmem_alloc); vec_validate (vm->mbuf_alloc_list, n-1); if (rte_mempool_get_bulk (rmp, vm->mbuf_alloc_list, n) < 0) return 0; _vec_len (vm->mbuf_alloc_list) = n; for (i = 0; i < n; i++) { mb = vm->mbuf_alloc_list[i]; ASSERT(rte_mbuf_refcnt_read(mb) == 0); rte_mbuf_refcnt_set(mb, 1); mb->next = NULL; mb->data_off = RTE_PKTMBUF_HEADROOM; mb->nb_segs = 1; b = (vlib_buffer_t *)(mb+1); bi = vlib_get_buffer_index (vm, b); vec_add1_aligned (fl->aligned_buffers, bi, sizeof (vlib_copy_unit_t)); n_alloc++; n_remaining--; vlib_buffer_init_for_free_list (b, fl); if (fl->buffer_init_function) fl->buffer_init_function (vm, fl, &bi, 1); } fl->n_alloc += n; return n; } always_inline uword copy_alignment (u32 * x) { return (pointer_to_uword (x) / sizeof (x[0])) % BUFFERS_PER_COPY; } static u32 alloc_from_free_list (vlib_main_t * vm, vlib_buffer_free_list_t * free_list, u32 * alloc_buffers, u32 n_alloc_buffers) { u32 * dst, * u_src; uword u_len, n_left; uword n_unaligned_start, n_unaligned_end, n_filled; n_left = n_alloc_buffers; dst = alloc_buffers; n_unaligned_start = ((BUFFERS_PER_COPY - copy_alignment (dst)) & (BUFFERS_PER_COPY - 1)); n_filled = fill_free_list (vm, free_list, n_alloc_buffers); if (n_filled == 0) return 0; n_left = n_filled < n_left ? n_filled : n_left; n_alloc_buffers = n_left; if (n_unaligned_start >= n_left) { n_unaligned_start = n_left; n_unaligned_end = 0; } else n_unaligned_end = copy_alignment (dst + n_alloc_buffers); fill_unaligned (vm, free_list, n_unaligned_start + n_unaligned_end); u_len = vec_len (free_list->unaligned_buffers); u_src = free_list->unaligned_buffers + u_len - 1; if (n_unaligned_start) { uword n_copy = n_unaligned_start; if (n_copy > n_left) n_copy = n_left; n_left -= n_copy; while (n_copy > 0) { *dst++ = *u_src--; n_copy--; u_len--; } /* Now dst should be aligned. */ if (n_left > 0) ASSERT (pointer_to_uword (dst) % sizeof (vlib_copy_unit_t) == 0); } /* Aligned copy. */ { vlib_copy_unit_t * d, * s; uword n_copy; if (vec_len(free_list->aligned_buffers) < ((n_left/BUFFERS_PER_COPY)*BUFFERS_PER_COPY)) abort(); n_copy = n_left / BUFFERS_PER_COPY; n_left = n_left % BUFFERS_PER_COPY; /* Remove buffers from aligned free list. */ _vec_len (free_list->aligned_buffers) -= n_copy * BUFFERS_PER_COPY; s = (vlib_copy_unit_t *) vec_end (free_list->aligned_buffers); d = (vlib_copy_unit_t *) dst; /* Fast path loop. */ while (n_copy >= 4) { d[0] = s[0]; d[1] = s[1]; d[2] = s[2]; d[3] = s[3]; n_copy -= 4; s += 4; d += 4; } while (n_copy >= 1) { d[0] = s[0]; n_copy -= 1; s += 1; d += 1; } dst = (void *) d; } /* Unaligned copy. */ ASSERT (n_unaligned_end == n_left); while (n_left > 0) { *dst++ = *u_src--; n_left--; u_len--; } if (! free_list->unaligned_buffers) ASSERT (u_len == 0); else _vec_len (free_list->unaligned_buffers) = u_len; return n_alloc_buffers; } /* Allocate a given number of buffers into given array. Returns number actually allocated which will be either zero or number requested. */ u32 vlib_buffer_alloc (vlib_main_t * vm, u32 * buffers, u32 n_buffers) { vlib_buffer_main_t * bm = vm->buffer_main; return alloc_from_free_list (vm, pool_elt_at_index (bm->buffer_free_list_pool, VLIB_BUFFER_DEFAULT_FREE_LIST_INDEX), buffers, n_buffers); } u32 vlib_buffer_alloc_from_free_list (vlib_main_t * vm, u32 * buffers, u32 n_buffers, u32 free_list_index) { vlib_buffer_main_t * bm = vm->buffer_main; vlib_buffer_free_list_t * f; f = pool_elt_at_index (bm->buffer_free_list_pool, free_list_index); return alloc_from_free_list (vm, f, buffers, n_buffers); } always_inline void add_buffer_to_free_list (vlib_main_t * vm, vlib_buffer_free_list_t * f, u32 buffer_index, u8 do_init) { vlib_buffer_t * b; b = vlib_get_buffer (vm, buffer_index); if (PREDICT_TRUE(do_init)) vlib_buffer_init_for_free_list (b, f); vec_add1_aligned (f->aligned_buffers, buffer_index, sizeof (vlib_copy_unit_t)); } always_inline vlib_buffer_free_list_t * buffer_get_free_list (vlib_main_t * vm, vlib_buffer_t * b, u32 * index) { vlib_buffer_main_t * bm = vm->buffer_main; u32 i; *index = i = b->free_list_index; return pool_elt_at_index (bm->buffer_free_list_pool, i); } void *vlib_set_buffer_free_callback (vlib_main_t *vm, void *fp) { vlib_buffer_main_t * bm = vm->buffer_main; void * rv = bm->buffer_free_callback; bm->buffer_free_callback = fp; return rv; } static_always_inline void vlib_buffer_free_inline (vlib_main_t * vm, u32 * buffers, u32 n_buffers, u32 follow_buffer_next) { vlib_buffer_main_t * bm = vm->buffer_main; vlib_buffer_free_list_t * fl; u32 fi; int i; u32 (*cb)(vlib_main_t * vm, u32 * buffers, u32 n_buffers, u32 follow_buffer_next); cb = bm->buffer_free_callback; if (PREDICT_FALSE (cb != 0)) n_buffers = (*cb)(vm, buffers, n_buffers, follow_buffer_next); if (! n_buffers) return; for (i = 0; i < n_buffers; i++) { vlib_buffer_t * b; struct rte_mbuf * mb; b = vlib_get_buffer (vm, buffers[i]); fl = buffer_get_free_list (vm, b, &fi); /* The only current use of this callback: multicast recycle */ if (PREDICT_FALSE (fl->buffers_added_to_freelist_function != 0)) { int j; add_buffer_to_free_list (vm, fl, buffers[i], b->clone_count == 0); for (j = 0; j < vec_len (bm->announce_list); j++) { if (fl == bm->announce_list[j]) goto already_announced; } vec_add1 (bm->announce_list, fl); already_announced: ; } else { mb = ((struct rte_mbuf *)b)-1; rte_pktmbuf_free (mb); } } if (vec_len(bm->announce_list)) { vlib_buffer_free_list_t * fl; for (i = 0; i < vec_len (bm->announce_list); i++) { fl = bm->announce_list[i]; fl->buffers_added_to_freelist_function (vm, fl); } _vec_len(bm->announce_list) = 0; } } void vlib_buffer_free (vlib_main_t * vm, u32 * buffers, u32 n_buffers) { vlib_buffer_free_inline (vm, buffers, n_buffers, /* follow_buffer_next */ 1); } void vlib_buffer_free_no_next (vlib_main_t * vm, u32 * buffers, u32 n_buffers) { vlib_buffer_free_inline (vm, buffers, n_buffers, /* follow_buffer_next */ 0); } /* Copy template packet data into buffers as they are allocated. */ __attribute__((unused)) static void vlib_packet_template_buffer_init (vlib_main_t * vm, vlib_buffer_free_list_t * fl, u32 * buffers, u32 n_buffers) { vlib_packet_template_t * t = uword_to_pointer (fl->buffer_init_function_opaque, vlib_packet_template_t *); uword i; for (i = 0; i < n_buffers; i++) { vlib_buffer_t * b = vlib_get_buffer (vm, buffers[i]); ASSERT (b->current_length == vec_len (t->packet_data)); memcpy (vlib_buffer_get_current (b), t->packet_data, b->current_length); } } 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_physmem_alloc, char * fmt, ...) { va_list va; __attribute__((unused)) u8 * name; va_start (va, fmt); name = va_format (0, fmt, &va); va_end (va); vlib_worker_thread_barrier_sync(vm); memset (t, 0, sizeof (t[0])); vec_add (t->packet_data, packet_data, n_packet_data_bytes); vlib_worker_thread_barrier_release(vm); } void * vlib_packet_template_get_packet (vlib_main_t * vm, vlib_packet_template_t * t, u32 * bi_result) { u32 bi; vlib_buffer_t * b; if (vlib_buffer_alloc (vm, &bi, 1) != 1) return 0; *bi_result = bi; b = vlib_get_buffer (vm, bi); memcpy (vlib_buffer_get_current (b), t->packet_data, vec_len(t->packet_data)); b->current_length = vec_len(t->packet_data); /* Fix up mbuf header length fields */ struct rte_mbuf * mb; mb = ((struct rte_mbuf *)b) - 1; mb->data_len = b->current_length; mb->pkt_len = b->current_length; return b->data; } /* Append given data to end of buffer, possibly allocating new buffers. */ u32 vlib_buffer_add_data (vlib_main_t * vm, u32 free_list_index, u32 buffer_index, void * data, u32 n_data_bytes) { u32 n_buffer_bytes, n_left, n_left_this_buffer, bi; vlib_buffer_t * b; void * d; bi = buffer_index; if (bi == 0 && 1 != vlib_buffer_alloc_from_free_list (vm, &bi, 1, free_list_index)) goto out_of_buffers; d = data; n_left = n_data_bytes; n_buffer_bytes = vlib_buffer_free_list_buffer_size (vm, free_list_index); b = vlib_get_buffer (vm, bi); b->flags &= ~VLIB_BUFFER_TOTAL_LENGTH_VALID; /* Get to the end of the chain before we try to append data...*/ while (b->flags & VLIB_BUFFER_NEXT_PRESENT) b = vlib_get_buffer (vm, b->next_buffer); while (1) { u32 n; ASSERT (n_buffer_bytes >= b->current_length); n_left_this_buffer = n_buffer_bytes - (b->current_data + b->current_length); n = clib_min (n_left_this_buffer, n_left); memcpy (vlib_buffer_get_current (b) + b->current_length, d, n); b->current_length += n; n_left -= n; if (n_left == 0) break; d += n; if (1 != vlib_buffer_alloc_from_free_list (vm, &b->next_buffer, 1, free_list_index)) goto out_of_buffers; b->flags |= VLIB_BUFFER_NEXT_PRESENT; b = vlib_get_buffer (vm, b->next_buffer); } return bi; out_of_buffers: clib_error ("out of buffers"); return bi; } clib_error_t * vlib_buffer_pool_create(vlib_main_t * vm, unsigned num_mbufs, unsigned mbuf_size, unsigned socket_id) { vlib_buffer_main_t * bm = vm->buffer_main; vlib_physmem_main_t * vpm = &vm->physmem_main; struct rte_mempool * rmp; uword new_start, new_size; int i; if (!rte_mempool_create) return clib_error_return (0, "not linked with DPDK"); vec_validate_aligned(bm->pktmbuf_pools, socket_id, CLIB_CACHE_LINE_BYTES); /* pool already exists, nothing to do */ if (bm->pktmbuf_pools[socket_id]) return 0; u8 * pool_name = format(0, "mbuf_pool_socket%u%c",socket_id, 0); rmp = rte_mempool_create((char *) pool_name, num_mbufs, mbuf_size, 512, sizeof(struct rte_pktmbuf_pool_private), rte_pktmbuf_pool_init, NULL, rte_pktmbuf_init, NULL, socket_id, 0); vec_free(pool_name); if (rmp) { new_start = pointer_to_uword(rmp); new_size = rmp->elt_va_end - new_start; if (vpm->virtual.size > 0) { ASSERT(new_start != vpm->virtual.start); if (new_start < vpm->virtual.start) { new_size = vpm->virtual.size + vpm->virtual.start - new_start; } else { new_size += new_start - vpm->virtual.start; new_start = vpm->virtual.start; } /* check if fits into buffer index range */ if (new_size > ( (uword) 1 << (32 + CLIB_LOG2_CACHE_LINE_BYTES))) rmp = 0; } } if (rmp) { bm->pktmbuf_pools[socket_id] = rmp; vpm->virtual.start = new_start; vpm->virtual.size = new_size; vpm->virtual.end = new_start + new_size; return 0; } /* no usable pool for this socket, try to use pool from another one */ for (i = 0; i < vec_len(bm->pktmbuf_pools); i++) { if(bm->pktmbuf_pools[i]) { clib_warning("WARNING: Failed to allocate mempool for CPU socket %u. " "Threads running on socket %u will use socket %u mempool.", socket_id, socket_id, i); bm->pktmbuf_pools[socket_id] = bm->pktmbuf_pools[i]; return 0; } } return clib_error_return (0, "failed to allocate mempool on socket %u", socket_id); } static void vlib_serialize_tx (serialize_main_header_t * m, serialize_stream_t * s) { vlib_main_t * vm; vlib_serialize_buffer_main_t * sm; uword n, n_bytes_to_write; vlib_buffer_t * last; n_bytes_to_write = s->current_buffer_index; sm = uword_to_pointer (s->data_function_opaque, vlib_serialize_buffer_main_t *); vm = sm->vlib_main; ASSERT (sm->tx.max_n_data_bytes_per_chain > 0); if (serialize_stream_is_end_of_stream (s) || sm->tx.n_total_data_bytes + n_bytes_to_write > sm->tx.max_n_data_bytes_per_chain) { vlib_process_t * p = vlib_get_current_process (vm); last = vlib_get_buffer (vm, sm->last_buffer); last->current_length = n_bytes_to_write; vlib_set_next_frame_buffer (vm, &p->node_runtime, sm->tx.next_index, sm->first_buffer); sm->first_buffer = sm->last_buffer = ~0; sm->tx.n_total_data_bytes = 0; } else if (n_bytes_to_write == 0 && s->n_buffer_bytes == 0) { ASSERT (sm->first_buffer == ~0); ASSERT (sm->last_buffer == ~0); n = vlib_buffer_alloc_from_free_list (vm, &sm->first_buffer, 1, sm->tx.free_list_index); if (n != 1) serialize_error (m, clib_error_create ("vlib_buffer_alloc_from_free_list fails")); sm->last_buffer = sm->first_buffer; s->n_buffer_bytes = vlib_buffer_free_list_buffer_size (vm, sm->tx.free_list_index); } if (n_bytes_to_write > 0) { vlib_buffer_t * prev = vlib_get_buffer (vm, sm->last_buffer); n = vlib_buffer_alloc_from_free_list (vm, &sm->last_buffer, 1, sm->tx.free_list_index); if (n != 1) serialize_error (m, clib_error_create ("vlib_buffer_alloc_from_free_list fails")); sm->tx.n_total_data_bytes += n_bytes_to_write; prev->current_length = n_bytes_to_write; prev->next_buffer = sm->last_buffer; prev->flags |= VLIB_BUFFER_NEXT_PRESENT; } if (sm->last_buffer != ~0) { last = vlib_get_buffer (vm, sm->last_buffer); s->buffer = vlib_buffer_get_current (last); s->current_buffer_index = 0; ASSERT (last->current_data == s->current_buffer_index); } } static void vlib_serialize_rx (serialize_main_header_t * m, serialize_stream_t * s) { vlib_main_t * vm; vlib_serialize_buffer_main_t * sm; vlib_buffer_t * last; sm = uword_to_pointer (s->data_function_opaque, vlib_serialize_buffer_main_t *); vm = sm->vlib_main; if (serialize_stream_is_end_of_stream (s)) return; if (sm->last_buffer != ~0) { last = vlib_get_buffer (vm, sm->last_buffer); if (last->flags & VLIB_BUFFER_NEXT_PRESENT) sm->last_buffer = last->next_buffer; else { vlib_buffer_free (vm, &sm->first_buffer, /* count */ 1); sm->first_buffer = sm->last_buffer = ~0; } } if (sm->last_buffer == ~0) { while (clib_fifo_elts (sm->rx.buffer_fifo) == 0) { sm->rx.ready_one_time_event = vlib_process_create_one_time_event (vm, vlib_current_process (vm), ~0); vlib_process_wait_for_one_time_event (vm, /* no event data */ 0, sm->rx.ready_one_time_event); } clib_fifo_sub1 (sm->rx.buffer_fifo, sm->first_buffer); sm->last_buffer = sm->first_buffer; } ASSERT (sm->last_buffer != ~0); last = vlib_get_buffer (vm, sm->last_buffer); s->current_buffer_index = 0; s->buffer = vlib_buffer_get_current (last); s->n_buffer_bytes = last->current_length; } static void serialize_open_vlib_helper (serialize_main_t * m, vlib_main_t * vm, vlib_serialize_buffer_main_t * sm, uword is_read) { /* Initialize serialize main but save overflow buffer for re-use between calls. */ { u8 * save = m->stream.overflow_buffer; memset (m, 0, sizeof (m[0])); m->stream.overflow_buffer = save; if (save) _vec_len (save) = 0; } sm->first_buffer = sm->last_buffer = ~0; if (is_read) clib_fifo_reset (sm->rx.buffer_fifo); else sm->tx.n_total_data_bytes = 0; sm->vlib_main = vm; m->header.data_function = is_read ? vlib_serialize_rx : vlib_serialize_tx; m->stream.data_function_opaque = pointer_to_uword (sm); } void serialize_open_vlib_buffer (serialize_main_t * m, vlib_main_t * vm, vlib_serialize_buffer_main_t * sm) { serialize_open_vlib_helper (m, vm, sm, /* is_read */ 0); } void unserialize_open_vlib_buffer (serialize_main_t * m, vlib_main_t * vm, vlib_serialize_buffer_main_t * sm) { serialize_open_vlib_helper (m, vm, sm, /* is_read */ 1); } u32 serialize_close_vlib_buffer (serialize_main_t * m) { vlib_serialize_buffer_main_t * sm = uword_to_pointer (m->stream.data_function_opaque, vlib_serialize_buffer_main_t *); vlib_buffer_t * last; serialize_stream_t * s = &m->stream; last = vlib_get_buffer (sm->vlib_main, sm->last_buffer); last->current_length = s->current_buffer_index; if (vec_len (s->overflow_buffer) > 0) { sm->last_buffer = vlib_buffer_add_data (sm->vlib_main, sm->tx.free_list_index, sm->last_buffer == ~0 ? 0 : sm->last_buffer, s->overflow_buffer, vec_len (s->overflow_buffer)); _vec_len (s->overflow_buffer) = 0; } return sm->first_buffer; } void unserialize_close_vlib_buffer (serialize_main_t * m) { vlib_serialize_buffer_main_t * sm = uword_to_pointer (m->stream.data_function_opaque, vlib_serialize_buffer_main_t *); if (sm->first_buffer != ~0) vlib_buffer_free_one (sm->vlib_main, sm->first_buffer); clib_fifo_reset (sm->rx.buffer_fifo); if (m->stream.overflow_buffer) _vec_len (m->stream.overflow_buffer) = 0; } static u8 * format_vlib_buffer_free_list (u8 * s, va_list * va) { vlib_buffer_free_list_t * f = va_arg (*va, vlib_buffer_free_list_t *); u32 threadnum= va_arg (*va, u32); uword bytes_alloc, bytes_free, n_free, size; if (! f) return format (s, "%=7s%=30s%=12s%=12s%=12s%=12s%=12s%=12s", "Thread", "Name", "Index", "Size", "Alloc", "Free", "#Alloc", "#Free"); size = sizeof (vlib_buffer_t) + f->n_data_bytes; n_free = vec_len (f->aligned_buffers) + vec_len (f->unaligned_buffers); bytes_alloc = size * f->n_alloc; bytes_free = size * n_free; s = format (s, "%7d%30s%12d%12d%=12U%=12U%=12d%=12d", threadnum, f->name, f->index, f->n_data_bytes, format_memory_size, bytes_alloc, format_memory_size, bytes_free, f->n_alloc, n_free); return s; } static clib_error_t * show_buffers (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { vlib_buffer_main_t * bm; vlib_buffer_free_list_t * f; vlib_main_t *curr_vm; u32 vm_index = 0; vlib_cli_output (vm, "%U", format_vlib_buffer_free_list, 0, 0); do { curr_vm = vec_len(vlib_mains) ? vlib_mains[vm_index] : vm; bm = curr_vm->buffer_main; pool_foreach (f, bm->buffer_free_list_pool, ({ vlib_cli_output (vm, "%U", format_vlib_buffer_free_list, f, vm_index); })); vm_index++; } while (vm_index < vec_len(vlib_mains)); return 0; } VLIB_CLI_COMMAND (show_buffers_command, static) = { .path = "show buffers", .short_help = "Show packet buffer allocation", .function = show_buffers, }; #if CLIB_DEBUG > 0 u32 * vlib_buffer_state_validation_lock; uword * vlib_buffer_state_validation_hash; void * vlib_buffer_state_heap; static clib_error_t * buffer_state_validation_init (vlib_main_t * vm) { void * oldheap; vlib_buffer_state_heap = mheap_alloc (0, 10<<20); oldheap = clib_mem_set_heap (vlib_buffer_state_heap); vlib_buffer_state_validation_hash = hash_create (0, sizeof(uword)); vec_validate_aligned (vlib_buffer_state_validation_lock, 0, CLIB_CACHE_LINE_BYTES); clib_mem_set_heap (oldheap); return 0; } VLIB_INIT_FUNCTION (buffer_state_validation_init); #endif