/* * 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. */ /* * main.c: main vector processing loop * * 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 /* Actually allocate a few extra slots of vector data to support speculative vector enqueues which overflow vector data in next frame. */ #define VLIB_FRAME_SIZE_ALLOC (VLIB_FRAME_SIZE + 4) always_inline u32 vlib_frame_bytes (u32 n_scalar_bytes, u32 n_vector_bytes) { u32 n_bytes; /* Make room for vlib_frame_t plus scalar arguments. */ n_bytes = vlib_frame_vector_byte_offset (n_scalar_bytes); /* Make room for vector arguments. Allocate a few extra slots of vector data to support speculative vector enqueues which overflow vector data in next frame. */ #define VLIB_FRAME_SIZE_EXTRA 4 n_bytes += (VLIB_FRAME_SIZE + VLIB_FRAME_SIZE_EXTRA) * n_vector_bytes; /* Magic number is first 32bit number after vector data. Used to make sure that vector data is never overrun. */ #define VLIB_FRAME_MAGIC (0xabadc0ed) n_bytes += sizeof (u32); /* Pad to cache line. */ n_bytes = round_pow2 (n_bytes, CLIB_CACHE_LINE_BYTES); return n_bytes; } always_inline u32 * vlib_frame_find_magic (vlib_frame_t * f, vlib_node_t * node) { void *p = f; p += vlib_frame_vector_byte_offset (node->scalar_size); p += (VLIB_FRAME_SIZE + VLIB_FRAME_SIZE_EXTRA) * node->vector_size; return p; } static inline vlib_frame_size_t * get_frame_size_info (vlib_node_main_t * nm, u32 n_scalar_bytes, u32 n_vector_bytes) { #ifdef VLIB_SUPPORTS_ARBITRARY_SCALAR_SIZES uword key = (n_scalar_bytes << 16) | n_vector_bytes; uword *p, i; p = hash_get (nm->frame_size_hash, key); if (p) i = p[0]; else { i = vec_len (nm->frame_sizes); vec_validate (nm->frame_sizes, i); hash_set (nm->frame_size_hash, key, i); } return vec_elt_at_index (nm->frame_sizes, i); #else ASSERT (vlib_frame_bytes (n_scalar_bytes, n_vector_bytes) == (vlib_frame_bytes (0, 4))); return vec_elt_at_index (nm->frame_sizes, 0); #endif } static vlib_frame_t * vlib_frame_alloc_to_node (vlib_main_t * vm, u32 to_node_index, u32 frame_flags) { vlib_node_main_t *nm = &vm->node_main; vlib_frame_size_t *fs; vlib_node_t *to_node; vlib_frame_t *f; u32 l, n, scalar_size, vector_size; ASSERT (vm == vlib_get_main ()); to_node = vlib_get_node (vm, to_node_index); scalar_size = to_node->scalar_size; vector_size = to_node->vector_size; fs = get_frame_size_info (nm, scalar_size, vector_size); n = vlib_frame_bytes (scalar_size, vector_size); if ((l = vec_len (fs->free_frames)) > 0) { /* Allocate from end of free list. */ f = fs->free_frames[l - 1]; _vec_len (fs->free_frames) = l - 1; } else { f = clib_mem_alloc_aligned_no_fail (n, VLIB_FRAME_ALIGN); } /* Poison frame when debugging. */ if (CLIB_DEBUG > 0) clib_memset (f, 0xfe, n); /* Insert magic number. */ { u32 *magic; magic = vlib_frame_find_magic (f, to_node); *magic = VLIB_FRAME_MAGIC; } f->frame_flags = VLIB_FRAME_IS_ALLOCATED | frame_flags; f->n_vectors = 0; f->scalar_size = scalar_size; f->vector_size = vector_size; f->flags = 0; fs->n_alloc_frames += 1; return f; } /* Allocate a frame for from FROM_NODE to TO_NODE via TO_NEXT_INDEX. Returns frame index. */ static vlib_frame_t * vlib_frame_alloc (vlib_main_t * vm, vlib_node_runtime_t * from_node_runtime, u32 to_next_index) { vlib_node_t *from_node; from_node = vlib_get_node (vm, from_node_runtime->node_index); ASSERT (to_next_index < vec_len (from_node->next_nodes)); return vlib_frame_alloc_to_node (vm, from_node->next_nodes[to_next_index], /* frame_flags */ 0); } vlib_frame_t * vlib_get_frame_to_node (vlib_main_t * vm, u32 to_node_index) { vlib_frame_t *f = vlib_frame_alloc_to_node (vm, to_node_index, /* frame_flags */ VLIB_FRAME_FREE_AFTER_DISPATCH); return vlib_get_frame (vm, f); } static inline void vlib_validate_frame_indices (vlib_frame_t * f) { if (CLIB_DEBUG > 0) { int i; u32 *from = vlib_frame_vector_args (f); /* Check for bad buffer index values */ for (i = 0; i < f->n_vectors; i++) { if (from[i] == 0) { clib_warning ("BUG: buffer index 0 at index %d", i); ASSERT (0); } else if (from[i] == 0xfefefefe) { clib_warning ("BUG: frame poison pattern at index %d", i); ASSERT (0); } } } } void vlib_put_frame_to_node (vlib_main_t * vm, u32 to_node_index, vlib_frame_t * f) { vlib_pending_frame_t *p; vlib_node_t *to_node; if (f->n_vectors == 0) return; ASSERT (vm == vlib_get_main ()); vlib_validate_frame_indices (f); to_node = vlib_get_node (vm, to_node_index); vec_add2 (vm->node_main.pending_frames, p, 1); f->frame_flags |= VLIB_FRAME_PENDING; p->frame = vlib_get_frame (vm, f); p->node_runtime_index = to_node->runtime_index; p->next_frame_index = VLIB_PENDING_FRAME_NO_NEXT_FRAME; } /* Free given frame. */ void vlib_frame_free (vlib_main_t * vm, vlib_node_runtime_t * r, vlib_frame_t * f) { vlib_node_main_t *nm = &vm->node_main; vlib_node_t *node; vlib_frame_size_t *fs; ASSERT (vm == vlib_get_main ()); ASSERT (f->frame_flags & VLIB_FRAME_IS_ALLOCATED); node = vlib_get_node (vm, r->node_index); fs = get_frame_size_info (nm, node->scalar_size, node->vector_size); ASSERT (f->frame_flags & VLIB_FRAME_IS_ALLOCATED); /* No next frames may point to freed frame. */ if (CLIB_DEBUG > 0) { vlib_next_frame_t *nf; vec_foreach (nf, vm->node_main.next_frames) ASSERT (nf->frame != f); } f->frame_flags &= ~(VLIB_FRAME_IS_ALLOCATED | VLIB_FRAME_NO_APPEND); vec_add1 (fs->free_frames, f); ASSERT (fs->n_alloc_frames > 0); fs->n_alloc_frames -= 1; } static clib_error_t * show_frame_stats (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { vlib_node_main_t *nm = &vm->node_main; vlib_frame_size_t *fs; vlib_cli_output (vm, "%=6s%=12s%=12s", "Size", "# Alloc", "# Free"); vec_foreach (fs, nm->frame_sizes) { u32 n_alloc = fs->n_alloc_frames; u32 n_free = vec_len (fs->free_frames); if (n_alloc + n_free > 0) vlib_cli_output (vm, "%=6d%=12d%=12d", fs - nm->frame_sizes, n_alloc, n_free); } return 0; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (show_frame_stats_cli, static) = { .path = "show vlib frame-allocation", .short_help = "Show node dispatch frame statistics", .function = show_frame_stats, }; /* *INDENT-ON* */ /* Change ownership of enqueue rights to given next node. */ static void vlib_next_frame_change_ownership (vlib_main_t * vm, vlib_node_runtime_t * node_runtime, u32 next_index) { vlib_node_main_t *nm = &vm->node_main; vlib_next_frame_t *next_frame; vlib_node_t *node, *next_node; node = vec_elt (nm->nodes, node_runtime->node_index); /* Only internal & input nodes are allowed to call other nodes. */ ASSERT (node->type == VLIB_NODE_TYPE_INTERNAL || node->type == VLIB_NODE_TYPE_INPUT || node->type == VLIB_NODE_TYPE_PROCESS); ASSERT (vec_len (node->next_nodes) == node_runtime->n_next_nodes); next_frame = vlib_node_runtime_get_next_frame (vm, node_runtime, next_index); next_node = vec_elt (nm->nodes, node->next_nodes[next_index]); if (next_node->owner_node_index != VLIB_INVALID_NODE_INDEX) { /* Get frame from previous owner. */ vlib_next_frame_t *owner_next_frame; vlib_next_frame_t tmp; owner_next_frame = vlib_node_get_next_frame (vm, next_node->owner_node_index, next_node->owner_next_index); /* Swap target next frame with owner's. */ tmp = owner_next_frame[0]; owner_next_frame[0] = next_frame[0]; next_frame[0] = tmp; /* * If next_frame is already pending, we have to track down * all pending frames and fix their next_frame_index fields. */ if (next_frame->flags & VLIB_FRAME_PENDING) { vlib_pending_frame_t *p; if (next_frame->frame != NULL) { vec_foreach (p, nm->pending_frames) { if (p->frame == next_frame->frame) { p->next_frame_index = next_frame - vm->node_main.next_frames; } } } } } else { /* No previous owner. Take ownership. */ next_frame->flags |= VLIB_FRAME_OWNER; } /* Record new owner. */ next_node->owner_node_index = node->index; next_node->owner_next_index = next_index; /* Now we should be owner. */ ASSERT (next_frame->flags & VLIB_FRAME_OWNER); } /* Make sure that magic number is still there. Otherwise, it is likely that caller has overrun frame arguments. */ always_inline void validate_frame_magic (vlib_main_t * vm, vlib_frame_t * f, vlib_node_t * n, uword next_index) { vlib_node_t *next_node = vlib_get_node (vm, n->next_nodes[next_index]); u32 *magic = vlib_frame_find_magic (f, next_node); ASSERT (VLIB_FRAME_MAGIC == magic[0]); } vlib_frame_t * vlib_get_next_frame_internal (vlib_main_t * vm, vlib_node_runtime_t * node, u32 next_index, u32 allocate_new_next_frame) { vlib_frame_t *f; vlib_next_frame_t *nf; u32 n_used; nf = vlib_node_runtime_get_next_frame (vm, node, next_index); /* Make sure this next frame owns right to enqueue to destination frame. */ if (PREDICT_FALSE (!(nf->flags & VLIB_FRAME_OWNER))) vlib_next_frame_change_ownership (vm, node, next_index); /* ??? Don't need valid flag: can use frame_index == ~0 */ if (PREDICT_FALSE (!(nf->flags & VLIB_FRAME_IS_ALLOCATED))) { nf->frame = vlib_frame_alloc (vm, node, next_index); nf->flags |= VLIB_FRAME_IS_ALLOCATED; } f = nf->frame; /* Has frame been removed from pending vector (e.g. finished dispatching)? If so we can reuse frame. */ if ((nf->flags & VLIB_FRAME_PENDING) && !(f->frame_flags & VLIB_FRAME_PENDING)) { nf->flags &= ~VLIB_FRAME_PENDING; f->n_vectors = 0; f->flags = 0; } /* Allocate new frame if current one is marked as no-append or it is already full. */ n_used = f->n_vectors; if (n_used >= VLIB_FRAME_SIZE || (allocate_new_next_frame && n_used > 0) || (f->frame_flags & VLIB_FRAME_NO_APPEND)) { /* Old frame may need to be freed after dispatch, since we'll have two redundant frames from node -> next node. */ if (!(nf->flags & VLIB_FRAME_NO_FREE_AFTER_DISPATCH)) { vlib_frame_t *f_old = vlib_get_frame (vm, nf->frame); f_old->frame_flags |= VLIB_FRAME_FREE_AFTER_DISPATCH; } /* Allocate new frame to replace full one. */ f = nf->frame = vlib_frame_alloc (vm, node, next_index); n_used = f->n_vectors; } /* Should have free vectors in frame now. */ ASSERT (n_used < VLIB_FRAME_SIZE); if (CLIB_DEBUG > 0) { validate_frame_magic (vm, f, vlib_get_node (vm, node->node_index), next_index); } return f; } static void vlib_put_next_frame_validate (vlib_main_t * vm, vlib_node_runtime_t * rt, u32 next_index, u32 n_vectors_left) { vlib_node_main_t *nm = &vm->node_main; vlib_next_frame_t *nf; vlib_frame_t *f; vlib_node_runtime_t *next_rt; vlib_node_t *next_node; u32 n_before, n_after; nf = vlib_node_runtime_get_next_frame (vm, rt, next_index); f = vlib_get_frame (vm, nf->frame); ASSERT (n_vectors_left <= VLIB_FRAME_SIZE); vlib_validate_frame_indices (f); n_after = VLIB_FRAME_SIZE - n_vectors_left; n_before = f->n_vectors; ASSERT (n_after >= n_before); next_rt = vec_elt_at_index (nm->nodes_by_type[VLIB_NODE_TYPE_INTERNAL], nf->node_runtime_index); next_node = vlib_get_node (vm, next_rt->node_index); if (n_after > 0 && next_node->validate_frame) { u8 *msg = next_node->validate_frame (vm, rt, f); if (msg) { clib_warning ("%v", msg); ASSERT (0); } vec_free (msg); } } void vlib_put_next_frame (vlib_main_t * vm, vlib_node_runtime_t * r, u32 next_index, u32 n_vectors_left) { vlib_node_main_t *nm = &vm->node_main; vlib_next_frame_t *nf; vlib_frame_t *f; u32 n_vectors_in_frame; if (CLIB_DEBUG > 0) vlib_put_next_frame_validate (vm, r, next_index, n_vectors_left); nf = vlib_node_runtime_get_next_frame (vm, r, next_index); f = vlib_get_frame (vm, nf->frame); /* Make sure that magic number is still there. Otherwise, caller has overrun frame meta data. */ if (CLIB_DEBUG > 0) { vlib_node_t *node = vlib_get_node (vm, r->node_index); validate_frame_magic (vm, f, node, next_index); } /* Convert # of vectors left -> number of vectors there. */ ASSERT (n_vectors_left <= VLIB_FRAME_SIZE); n_vectors_in_frame = VLIB_FRAME_SIZE - n_vectors_left; f->n_vectors = n_vectors_in_frame; /* If vectors were added to frame, add to pending vector. */ if (PREDICT_TRUE (n_vectors_in_frame > 0)) { vlib_pending_frame_t *p; u32 v0, v1; r->cached_next_index = next_index; if (!(f->frame_flags & VLIB_FRAME_PENDING)) { __attribute__ ((unused)) vlib_node_t *node; vlib_node_t *next_node; vlib_node_runtime_t *next_runtime; node = vlib_get_node (vm, r->node_index); next_node = vlib_get_next_node (vm, r->node_index, next_index); next_runtime = vlib_node_get_runtime (vm, next_node->index); vec_add2 (nm->pending_frames, p, 1); p->frame = nf->frame; p->node_runtime_index = nf->node_runtime_index; p->next_frame_index = nf - nm->next_frames; nf->flags |= VLIB_FRAME_PENDING; f->frame_flags |= VLIB_FRAME_PENDING; /* * If we're going to dispatch this frame on another thread, * force allocation of a new frame. Otherwise, we create * a dangling frame reference. Each thread has its own copy of * the next_frames vector. */ if (0 && r->thread_index != next_runtime->thread_index) { nf->frame = NULL; nf->flags &= ~(VLIB_FRAME_PENDING | VLIB_FRAME_IS_ALLOCATED); } } /* Copy trace flag from next_frame and from runtime. */ nf->flags |= (nf->flags & VLIB_NODE_FLAG_TRACE) | (r-> flags & VLIB_NODE_FLAG_TRACE); v0 = nf->vectors_since_last_overflow; v1 = v0 + n_vectors_in_frame; nf->vectors_since_last_overflow = v1; if (PREDICT_FALSE (v1 < v0)) { vlib_node_t *node = vlib_get_node (vm, r->node_index); vec_elt (node->n_vectors_by_next_node, next_index) += v0; } } } /* Sync up runtime (32 bit counters) and main node stats (64 bit counters). */ void vlib_node_runtime_sync_stats_node (vlib_node_t *n, vlib_node_runtime_t *r, uword n_calls, uword n_vectors, uword n_clocks) { n->stats_total.calls += n_calls + r->calls_since_last_overflow; n->stats_total.vectors += n_vectors + r->vectors_since_last_overflow; n->stats_total.clocks += n_clocks + r->clocks_since_last_overflow; n->stats_total.max_clock = r->max_clock; n->stats_total.max_clock_n = r->max_clock_n; r->calls_since_last_overflow = 0; r->vectors_since_last_overflow = 0; r->clocks_since_last_overflow = 0; } void vlib_node_runtime_sync_stats (vlib_main_t *vm, vlib_node_runtime_t *r, uword n_calls, uword n_vectors, uword n_clocks) { vlib_node_t *n = vlib_get_node (vm, r->node_index); vlib_node_runtime_sync_stats_node (n, r, n_calls, n_vectors, n_clocks); } always_inline void __attribute__ ((unused)) vlib_process_sync_stats (vlib_main_t * vm, vlib_process_t * p, uword n_calls, uword n_vectors, uword n_clocks) { vlib_node_runtime_t *rt = &p->node_runtime; vlib_node_t *n = vlib_get_node (vm, rt->node_index); vlib_node_runtime_sync_stats (vm, rt, n_calls, n_vectors, n_clocks); n->stats_total.suspends += p->n_suspends; p->n_suspends = 0; } void vlib_node_sync_stats (vlib_main_t * vm, vlib_node_t * n) { vlib_node_runtime_t *rt; if (n->type == VLIB_NODE_TYPE_PROCESS) { /* Nothing to do for PROCESS nodes except in main thread */ if (vm != vlib_get_first_main ()) return; vlib_process_t *p = vlib_get_process_from_node (vm, n); n->stats_total.suspends += p->n_suspends; p->n_suspends = 0; rt = &p->node_runtime; } else rt = vec_elt_at_index (vm->node_main.nodes_by_type[n->type], n->runtime_index); vlib_node_runtime_sync_stats (vm, rt, 0, 0, 0); /* Sync up runtime next frame vector counters with main node structure. */ { vlib_next_frame_t *nf; uword i; for (i = 0; i < rt->n_next_nodes; i++) { nf = vlib_node_runtime_get_next_frame (vm, rt, i); vec_elt (n->n_vectors_by_next_node, i) += nf->vectors_since_last_overflow; nf->vectors_since_last_overflow = 0; } } } always_inline u32 vlib_node_runtime_update_stats (vlib_main_t * vm, vlib_node_runtime_t * node, uword n_calls, uword n_vectors, uword n_clocks) { u32 ca0, ca1, v0, v1, cl0, cl1, r; cl0 = cl1 = node->clocks_since_last_overflow; ca0 = ca1 = node->calls_since_last_overflow; v0 = v1 = node->vectors_since_last_overflow; ca1 = ca0 + n_calls; v1 = v0 + n_vectors; cl1 = cl0 + n_clocks; node->calls_since_last_overflow = ca1; node->clocks_since_last_overflow = cl1; node->vectors_since_last_overflow = v1; node->max_clock_n = node->max_clock > n_clocks ? node->max_clock_n : n_vectors; node->max_clock = node->max_clock > n_clocks ? node->max_clock : n_clocks; r = vlib_node_runtime_update_main_loop_vector_stats (vm, node, n_vectors); if (PREDICT_FALSE (ca1 < ca0 || v1 < v0 || cl1 < cl0)) { node->calls_since_last_overflow = ca0; node->clocks_since_last_overflow = cl0; node->vectors_since_last_overflow = v0; vlib_node_runtime_sync_stats (vm, node, n_calls, n_vectors, n_clocks); } return r; } always_inline void vlib_process_update_stats (vlib_main_t * vm, vlib_process_t * p, uword n_calls, uword n_vectors, uword n_clocks) { vlib_node_runtime_update_stats (vm, &p->node_runtime, n_calls, n_vectors, n_clocks); } static clib_error_t * vlib_cli_elog_clear (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { elog_reset_buffer (&vlib_global_main.elog_main); return 0; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_clear_cli, static) = { .path = "event-logger clear", .short_help = "Clear the event log", .function = vlib_cli_elog_clear, }; /* *INDENT-ON* */ #ifdef CLIB_UNIX static clib_error_t * elog_save_buffer (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { elog_main_t *em = &vlib_global_main.elog_main; char *file, *chroot_file; clib_error_t *error = 0; if (!unformat (input, "%s", &file)) { vlib_cli_output (vm, "expected file name, got `%U'", format_unformat_error, input); return 0; } /* It's fairly hard to get "../oopsie" through unformat; just in case */ if (strstr (file, "..") || index (file, '/')) { vlib_cli_output (vm, "illegal characters in filename '%s'", file); return 0; } chroot_file = (char *) format (0, "/tmp/%s%c", file, 0); vec_free (file); vlib_cli_output (vm, "Saving %wd of %wd events to %s", elog_n_events_in_buffer (em), elog_buffer_capacity (em), chroot_file); vlib_worker_thread_barrier_sync (vm); error = elog_write_file (em, chroot_file, 1 /* flush ring */ ); vlib_worker_thread_barrier_release (vm); vec_free (chroot_file); return error; } void vlib_post_mortem_dump (void) { vlib_global_main_t *vgm = vlib_get_global_main (); for (int i = 0; i < vec_len (vgm->post_mortem_callbacks); i++) (vgm->post_mortem_callbacks[i]) (); } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_save_cli, static) = { .path = "event-logger save", .short_help = "event-logger save (saves log in /tmp/)", .function = elog_save_buffer, }; /* *INDENT-ON* */ static clib_error_t * elog_stop (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { elog_main_t *em = &vlib_global_main.elog_main; em->n_total_events_disable_limit = em->n_total_events; vlib_cli_output (vm, "Stopped the event logger..."); return 0; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_stop_cli, static) = { .path = "event-logger stop", .short_help = "Stop the event-logger", .function = elog_stop, }; /* *INDENT-ON* */ static clib_error_t * elog_restart (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { elog_main_t *em = &vlib_global_main.elog_main; em->n_total_events_disable_limit = ~0; vlib_cli_output (vm, "Restarted the event logger..."); return 0; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_restart_cli, static) = { .path = "event-logger restart", .short_help = "Restart the event-logger", .function = elog_restart, }; /* *INDENT-ON* */ static clib_error_t * elog_resize_command_fn (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { elog_main_t *em = &vlib_global_main.elog_main; u32 tmp; /* Stop the parade */ elog_reset_buffer (em); if (unformat (input, "%d", &tmp)) { elog_alloc (em, tmp); em->n_total_events_disable_limit = ~0; } else return clib_error_return (0, "Must specify how many events in the ring"); vlib_cli_output (vm, "Resized ring and restarted the event logger..."); return 0; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_resize_cli, static) = { .path = "event-logger resize", .short_help = "event-logger resize ", .function = elog_resize_command_fn, }; /* *INDENT-ON* */ #endif /* CLIB_UNIX */ static void elog_show_buffer_internal (vlib_main_t * vm, u32 n_events_to_show) { elog_main_t *em = &vlib_global_main.elog_main; elog_event_t *e, *es; f64 dt; /* Show events in VLIB time since log clock starts after VLIB clock. */ dt = (em->init_time.cpu - vm->clib_time.init_cpu_time) * vm->clib_time.seconds_per_clock; es = elog_peek_events (em); vlib_cli_output (vm, "%d of %d events in buffer, logger %s", vec_len (es), em->event_ring_size, em->n_total_events < em->n_total_events_disable_limit ? "running" : "stopped"); vec_foreach (e, es) { vlib_cli_output (vm, "%18.9f: %U", e->time + dt, format_elog_event, em, e); n_events_to_show--; if (n_events_to_show == 0) break; } vec_free (es); } static clib_error_t * elog_show_buffer (vlib_main_t * vm, unformat_input_t * input, vlib_cli_command_t * cmd) { u32 n_events_to_show; clib_error_t *error = 0; n_events_to_show = 250; while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT) { if (unformat (input, "%d", &n_events_to_show)) ; else if (unformat (input, "all")) n_events_to_show = ~0; else return unformat_parse_error (input); } elog_show_buffer_internal (vm, n_events_to_show); return error; } /* *INDENT-OFF* */ VLIB_CLI_COMMAND (elog_show_cli, static) = { .path = "show event-logger", .short_help = "Show event logger info", .function = elog_show_buffer, }; /* *INDENT-ON* */ void vlib_gdb_show_event_log (void) { elog_show_buffer_internal (vlib_get_main (), (u32) ~ 0); } static inline void vlib_elog_main_loop_event (vlib_main_t * vm, u32 node_index, u64 time, u32 n_vectors, u32 is_return) { vlib_main_t *evm = vlib_get_first_main (); elog_main_t *em = vlib_get_elog_main (); int enabled = evm->elog_trace_graph_dispatch | evm->elog_trace_graph_circuit; if (PREDICT_FALSE (enabled && n_vectors)) { if (PREDICT_FALSE (!elog_is_enabled (em))) { evm->elog_trace_graph_dispatch = 0; evm->elog_trace_graph_circuit = 0; return; } if (PREDICT_TRUE (evm->elog_trace_graph_dispatch || (evm->elog_trace_graph_circuit && node_index == evm->elog_trace_graph_circuit_node_index))) { elog_track (em, /* event type */ vec_elt_at_index (is_return ? evm->node_return_elog_event_types : evm->node_call_elog_event_types, node_index), /* track */ (vm->thread_index ? &vlib_worker_threads[vm->thread_index].elog_track : &em->default_track), /* data to log */ n_vectors); } } } #if VLIB_BUFFER_TRACE_TRAJECTORY > 0 void (*vlib_buffer_trace_trajectory_cb) (vlib_buffer_t * b, u32 node_index); void (*vlib_buffer_trace_trajectory_init_cb) (vlib_buffer_t * b); void vlib_buffer_trace_trajectory_init (vlib_buffer_t * b) { if (PREDICT_TRUE (vlib_buffer_trace_trajectory_init_cb != 0)) { (*vlib_buffer_trace_trajectory_init_cb) (b); } } #endif static inline void add_trajectory_trace (vlib_buffer_t * b, u32 node_index) { #if VLIB_BUFFER_TRACE_TRAJECTORY > 0 if (PREDICT_TRUE (vlib_buffer_trace_trajectory_cb != 0)) { (*vlib_buffer_trace_trajectory_cb) (b, node_index); } #endif } static_always_inline u64 dispatch_node (vlib_main_t * vm, vlib_node_runtime_t * node, vlib_node_type_t type, vlib_node_state_t dispatch_state, vlib_frame_t * frame, u64 last_time_stamp) { uword n, v; u64 t; vlib_node_main_t *nm = &vm->node_main; vlib_next_frame_t *nf; if (CLIB_DEBUG > 0) { vlib_node_t *n = vlib_get_node (vm, node->node_index); ASSERT (n->type == type); } /* Only non-internal nodes may be disabled. */ if (type != VLIB_NODE_TYPE_INTERNAL && node->state != dispatch_state) { ASSERT (type != VLIB_NODE_TYPE_INTERNAL); return last_time_stamp; } if ((type == VLIB_NODE_TYPE_PRE_INPUT || type == VLIB_NODE_TYPE_INPUT) && dispatch_state != VLIB_NODE_STATE_INTERRUPT) { u32 c = node->input_main_loops_per_call; /* Only call node when count reaches zero. */ if (c) { node->input_main_loops_per_call = c - 1; return last_time_stamp; } } /* Speculatively prefetch next frames. */ if (node->n_next_nodes > 0) { nf = vec_elt_at_index (nm->next_frames, node->next_frame_index); CLIB_PREFETCH (nf, 4 * sizeof (nf[0]), WRITE); } vm->cpu_time_last_node_dispatch = last_time_stamp; vlib_elog_main_loop_event (vm, node->node_index, last_time_stamp, frame ? frame->n_vectors : 0, /* is_after */ 0); vlib_node_runtime_perf_counter (vm, node, frame, 0, last_time_stamp, VLIB_NODE_RUNTIME_PERF_BEFORE); /* * Turn this on if you run into * "bad monkey" contexts, and you want to know exactly * which nodes they've visited... See ixge.c... */ if (VLIB_BUFFER_TRACE_TRAJECTORY && frame) { int i; u32 *from; from = vlib_frame_vector_args (frame); for (i = 0; i < frame->n_vectors; i++) { vlib_buffer_t *b = vlib_get_buffer (vm, from[i]); add_trajectory_trace (b, node->node_index); } if (PREDICT_TRUE (vm->dispatch_wrapper_fn == 0)) n = node->function (vm, node, frame); else n = vm->dispatch_wrapper_fn (vm, node, frame); } else { if (PREDICT_TRUE (vm->dispatch_wrapper_fn == 0)) n = node->function (vm, node, frame); else n = vm->dispatch_wrapper_fn (vm, node, frame); } t = clib_cpu_time_now (); vlib_node_runtime_perf_counter (vm, node, frame, n, t, VLIB_NODE_RUNTIME_PERF_AFTER); vlib_elog_main_loop_event (vm, node->node_index, t, n, 1 /* is_after */ ); vm->main_loop_vectors_processed += n; vm->main_loop_nodes_processed += n > 0; v = vlib_node_runtime_update_stats (vm, node, /* n_calls */ 1, /* n_vectors */ n, /* n_clocks */ t - last_time_stamp); /* When in adaptive mode and vector rate crosses threshold switch to polling mode and vice versa. */ if (PREDICT_FALSE (node->flags & VLIB_NODE_FLAG_ADAPTIVE_MODE)) { /* *INDENT-OFF* */ ELOG_TYPE_DECLARE (e) = { .function = (char *) __FUNCTION__, .format = "%s vector length %d, switching to %s", .format_args = "T4i4t4", .n_enum_strings = 2, .enum_strings = { "interrupt", "polling", }, }; /* *INDENT-ON* */ struct { u32 node_name, vector_length, is_polling; } *ed; if ((dispatch_state == VLIB_NODE_STATE_INTERRUPT && v >= nm->polling_threshold_vector_length) && !(node->flags & VLIB_NODE_FLAG_SWITCH_FROM_INTERRUPT_TO_POLLING_MODE)) { vlib_node_t *n = vlib_get_node (vm, node->node_index); n->state = VLIB_NODE_STATE_POLLING; node->state = VLIB_NODE_STATE_POLLING; node->flags &= ~VLIB_NODE_FLAG_SWITCH_FROM_POLLING_TO_INTERRUPT_MODE; node->flags |= VLIB_NODE_FLAG_SWITCH_FROM_INTERRUPT_TO_POLLING_MODE; nm->input_node_counts_by_state[VLIB_NODE_STATE_INTERRUPT] -= 1; nm->input_node_counts_by_state[VLIB_NODE_STATE_POLLING] += 1; if (PREDICT_FALSE ( vlib_get_first_main ()->elog_trace_graph_dispatch)) { vlib_worker_thread_t *w = vlib_worker_threads + vm->thread_index; ed = ELOG_TRACK_DATA (&vlib_global_main.elog_main, e, w->elog_track); ed->node_name = n->name_elog_string; ed->vector_length = v; ed->is_polling = 1; } } else if (dispatch_state == VLIB_NODE_STATE_POLLING && v <= nm->interrupt_threshold_vector_length) { vlib_node_t *n = vlib_get_node (vm, node->node_index); if (node->flags & VLIB_NODE_FLAG_SWITCH_FROM_POLLING_TO_INTERRUPT_MODE) { /* Switch to interrupt mode after dispatch in polling one more time. This allows driver to re-enable interrupts. */ n->state = VLIB_NODE_STATE_INTERRUPT; node->state = VLIB_NODE_STATE_INTERRUPT; node->flags &= ~VLIB_NODE_FLAG_SWITCH_FROM_INTERRUPT_TO_POLLING_MODE; nm->input_node_counts_by_state[VLIB_NODE_STATE_POLLING] -= 1; nm->input_node_counts_by_state[VLIB_NODE_STATE_INTERRUPT] += 1; } else { vlib_worker_thread_t *w = vlib_worker_threads + vm->thread_index; node->flags |= VLIB_NODE_FLAG_SWITCH_FROM_POLLING_TO_INTERRUPT_MODE; if (PREDICT_FALSE ( vlib_get_first_main ()->elog_trace_graph_dispatch)) { ed = ELOG_TRACK_DATA (&vlib_global_main.elog_main, e, w->elog_track); ed->node_name = n->name_elog_string; ed->vector_length = v; ed->is_polling = 0; } } } } return t; } static u64 dispatch_pending_node (vlib_main_t * vm, uword pending_frame_index, u64 last_time_stamp) { vlib_node_main_t *nm = &vm->node_main; vlib_frame_t *f; vlib_next_frame_t *nf, nf_placeholder; vlib_node_runtime_t *n; vlib_frame_t *restore_frame; vlib_pending_frame_t *p; /* See comment below about dangling references to nm->pending_frames */ p = nm->pending_frames + pending_frame_index; n = vec_elt_at_index (nm->nodes_by_type[VLIB_NODE_TYPE_INTERNAL], p->node_runtime_index); f = vlib_get_frame (vm, p->frame); if (p->next_frame_index == VLIB_PENDING_FRAME_NO_NEXT_FRAME) { /* No next frame: so use placeholder on stack. */ nf = &nf_placeholder; nf->flags = f->frame_flags & VLIB_NODE_FLAG_TRACE; nf->frame = NULL; } else nf = vec_elt_at_index (nm->next_frames, p->next_frame_index); ASSERT (f->frame_flags & VLIB_FRAME_IS_ALLOCATED); /* Force allocation of new frame while current frame is being dispatched. */ restore_frame = NULL; if (nf->frame == p->frame) { nf->frame = NULL; nf->flags &= ~VLIB_FRAME_IS_ALLOCATED; if (!(n->flags & VLIB_NODE_FLAG_FRAME_NO_FREE_AFTER_DISPATCH)) restore_frame = p->frame; } /* Frame must be pending. */ ASSERT (f->frame_flags & VLIB_FRAME_PENDING); ASSERT (f->n_vectors > 0); /* Copy trace flag from next frame to node. Trace flag indicates that at least one vector in the dispatched frame is traced. */ n->flags &= ~VLIB_NODE_FLAG_TRACE; n->flags |= (nf->flags & VLIB_FRAME_TRACE) ? VLIB_NODE_FLAG_TRACE : 0; nf->flags &= ~VLIB_FRAME_TRACE; last_time_stamp = dispatch_node (vm, n, VLIB_NODE_TYPE_INTERNAL, VLIB_NODE_STATE_POLLING, f, last_time_stamp); /* Internal node vector-rate accounting, for summary stats */ vm->internal_node_vectors += f->n_vectors; vm->internal_node_calls++; vm->internal_node_last_vectors_per_main_loop = (f->n_vectors > vm->internal_node_last_vectors_per_main_loop) ? f->n_vectors : vm->internal_node_last_vectors_per_main_loop; f->frame_flags &= ~(VLIB_FRAME_PENDING | VLIB_FRAME_NO_APPEND); /* Frame is ready to be used again, so restore it. */ if (restore_frame != NULL) { /* * We musn't restore a frame that is flagged to be freed. This * shouldn't happen since frames to be freed post dispatch are * those used when the to-node frame becomes full i.e. they form a * sort of queue of frames to a single node. If we get here then * the to-node frame and the pending frame *were* the same, and so * we removed the to-node frame. Therefore this frame is no * longer part of the queue for that node and hence it cannot be * it's overspill. */ ASSERT (!(f->frame_flags & VLIB_FRAME_FREE_AFTER_DISPATCH)); /* * NB: dispatching node n can result in the creation and scheduling * of new frames, and hence in the reallocation of nm->pending_frames. * Recompute p, or no supper. This was broken for more than 10 years. */ p = nm->pending_frames + pending_frame_index; /* * p->next_frame_index can change during node dispatch if node * function decides to change graph hook up. */ nf = vec_elt_at_index (nm->next_frames, p->next_frame_index); nf->flags |= VLIB_FRAME_IS_ALLOCATED; if (NULL == nf->frame) { /* no new frame has been assigned to this node, use the saved one */ nf->frame = restore_frame; f->n_vectors = 0; } else { /* The node has gained a frame, implying packets from the current frame were re-queued to this same node. we don't need the saved one anymore */ vlib_frame_free (vm, n, f); } } else { if (f->frame_flags & VLIB_FRAME_FREE_AFTER_DISPATCH) { ASSERT (!(n->flags & VLIB_NODE_FLAG_FRAME_NO_FREE_AFTER_DISPATCH)); vlib_frame_free (vm, n, f); } } return last_time_stamp; } always_inline uword vlib_process_stack_is_valid (vlib_process_t * p) { return p->stack[0] == VLIB_PROCESS_STACK_MAGIC; } typedef struct { vlib_main_t *vm; vlib_process_t *process; vlib_frame_t *frame; } vlib_process_bootstrap_args_t; /* Called in process stack. */ static uword vlib_process_bootstrap (uword _a) { vlib_process_bootstrap_args_t *a; vlib_main_t *vm; vlib_node_runtime_t *node; vlib_frame_t *f; vlib_process_t *p; uword n; a = uword_to_pointer (_a, vlib_process_bootstrap_args_t *); vm = a->vm; p = a->process; vlib_process_finish_switch_stack (vm); f = a->frame; node = &p->node_runtime; n = node->function (vm, node, f); ASSERT (vlib_process_stack_is_valid (p)); vlib_process_start_switch_stack (vm, 0); clib_longjmp (&p->return_longjmp, n); return n; } /* Called in main stack. */ static_always_inline uword vlib_process_startup (vlib_main_t * vm, vlib_process_t * p, vlib_frame_t * f) { vlib_process_bootstrap_args_t a; uword r; a.vm = vm; a.process = p; a.frame = f; r = clib_setjmp (&p->return_longjmp, VLIB_PROCESS_RETURN_LONGJMP_RETURN); if (r == VLIB_PROCESS_RETURN_LONGJMP_RETURN) { vlib_process_start_switch_stack (vm, p); r = clib_calljmp (vlib_process_bootstrap, pointer_to_uword (&a), (void *) p->stack + (1 << p->log2_n_stack_bytes)); } else vlib_process_finish_switch_stack (vm); return r; } static_always_inline uword vlib_process_resume (vlib_main_t * vm, vlib_process_t * p) { uword r; p->flags &= ~(VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_CLOCK | VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_EVENT | VLIB_PROCESS_RESUME_PENDING); r = clib_setjmp (&p->return_longjmp, VLIB_PROCESS_RETURN_LONGJMP_RETURN); if (r == VLIB_PROCESS_RETURN_LONGJMP_RETURN) { vlib_process_start_switch_stack (vm, p); clib_longjmp (&p->resume_longjmp, VLIB_PROCESS_RESUME_LONGJMP_RESUME); } else vlib_process_finish_switch_stack (vm); return r; } static u64 dispatch_process (vlib_main_t * vm, vlib_process_t * p, vlib_frame_t * f, u64 last_time_stamp) { vlib_node_main_t *nm = &vm->node_main; vlib_node_runtime_t *node_runtime = &p->node_runtime; vlib_node_t *node = vlib_get_node (vm, node_runtime->node_index); u32 old_process_index; u64 t; uword n_vectors, is_suspend; if (node->state != VLIB_NODE_STATE_POLLING || (p->flags & (VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_CLOCK | VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_EVENT))) return last_time_stamp; p->flags |= VLIB_PROCESS_IS_RUNNING; t = last_time_stamp; vlib_elog_main_loop_event (vm, node_runtime->node_index, t, f ? f->n_vectors : 0, /* is_after */ 0); /* Save away current process for suspend. */ old_process_index = nm->current_process_index; nm->current_process_index = node->runtime_index; vlib_node_runtime_perf_counter (vm, node_runtime, f, 0, last_time_stamp, VLIB_NODE_RUNTIME_PERF_BEFORE); n_vectors = vlib_process_startup (vm, p, f); nm->current_process_index = old_process_index; ASSERT (n_vectors != VLIB_PROCESS_RETURN_LONGJMP_RETURN); is_suspend = n_vectors == VLIB_PROCESS_RETURN_LONGJMP_SUSPEND; if (is_suspend) { vlib_pending_frame_t *pf; n_vectors = 0; pool_get (nm->suspended_process_frames, pf); pf->node_runtime_index = node->runtime_index; pf->frame = f; pf->next_frame_index = ~0; p->n_suspends += 1; p->suspended_process_frame_index = pf - nm->suspended_process_frames; if (p->flags & VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_CLOCK) { TWT (tw_timer_wheel) * tw = (TWT (tw_timer_wheel) *) nm->timing_wheel; p->stop_timer_handle = TW (tw_timer_start) (tw, vlib_timing_wheel_data_set_suspended_process (node->runtime_index) /* [sic] pool idex */ , 0 /* timer_id */ , p->resume_clock_interval); } } else p->flags &= ~VLIB_PROCESS_IS_RUNNING; t = clib_cpu_time_now (); vlib_elog_main_loop_event (vm, node_runtime->node_index, t, is_suspend, /* is_after */ 1); vlib_node_runtime_perf_counter (vm, node_runtime, f, n_vectors, t, VLIB_NODE_RUNTIME_PERF_AFTER); vlib_process_update_stats (vm, p, /* n_calls */ !is_suspend, /* n_vectors */ n_vectors, /* n_clocks */ t - last_time_stamp); return t; } void vlib_start_process (vlib_main_t * vm, uword process_index) { vlib_node_main_t *nm = &vm->node_main; vlib_process_t *p = vec_elt (nm->processes, process_index); dispatch_process (vm, p, /* frame */ 0, /* cpu_time_now */ 0); } static u64 dispatch_suspended_process (vlib_main_t * vm, uword process_index, u64 last_time_stamp) { vlib_node_main_t *nm = &vm->node_main; vlib_node_runtime_t *node_runtime; vlib_node_t *node; vlib_frame_t *f; vlib_process_t *p; vlib_pending_frame_t *pf; u64 t, n_vectors, is_suspend; t = last_time_stamp; p = vec_elt (nm->processes, process_index); if (PREDICT_FALSE (!(p->flags & VLIB_PROCESS_IS_RUNNING))) return last_time_stamp; ASSERT (p->flags & (VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_CLOCK | VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_EVENT)); pf = pool_elt_at_index (nm->suspended_process_frames, p->suspended_process_frame_index); node_runtime = &p->node_runtime; node = vlib_get_node (vm, node_runtime->node_index); f = pf->frame; vlib_elog_main_loop_event (vm, node_runtime->node_index, t, f ? f->n_vectors : 0, /* is_after */ 0); /* Save away current process for suspend. */ nm->current_process_index = node->runtime_index; vlib_node_runtime_perf_counter (vm, node_runtime, f, 0, last_time_stamp, VLIB_NODE_RUNTIME_PERF_BEFORE); n_vectors = vlib_process_resume (vm, p); t = clib_cpu_time_now (); nm->current_process_index = ~0; is_suspend = n_vectors == VLIB_PROCESS_RETURN_LONGJMP_SUSPEND; if (is_suspend) { /* Suspend it again. */ n_vectors = 0; p->n_suspends += 1; if (p->flags & VLIB_PROCESS_IS_SUSPENDED_WAITING_FOR_CLOCK) { p->stop_timer_handle = TW (tw_timer_start) ((TWT (tw_timer_wheel) *) nm->timing_wheel, vlib_timing_wheel_data_set_suspended_process (node->runtime_index) /* [sic] pool idex */ , 0 /* timer_id */ , p->resume_clock_interval); } } else { p->flags &= ~VLIB_PROCESS_IS_RUNNING; pool_put_index (nm->suspended_process_frames, p->suspended_process_frame_index); p->suspended_process_frame_index = ~0; } t = clib_cpu_time_now (); vlib_elog_main_loop_event (vm, node_runtime->node_index, t, !is_suspend, /* is_after */ 1); vlib_node_runtime_perf_counter (vm, node_runtime, f, n_vectors, t, VLIB_NODE_RUNTIME_PERF_AFTER); vlib_process_update_stats (vm, p, /* n_calls */ !is_suspend, /* n_vectors */ n_vectors, /* n_clocks */ t - last_time_stamp); return t; } void vl_api_send_pending_rpc_requests (vlib_main_t *) __attribute__ ((weak)); void vl_api_send_pending_rpc_requests (vlib_main_t * vm) { } static_always_inline void vlib_main_or_worker_loop (vlib_main_t * vm, int is_main) { vlib_node_main_t *nm = &vm->node_main; vlib_thread_main_t *tm = vlib_get_thread_main (); uword i; u64 cpu_time_now; f64 now; vlib_frame_queue_main_t *fqm; u32 frame_queue_check_counter = 0; /* Initialize pending node vector. */ if (is_main) { vec_resize (nm->pending_frames, 32); _vec_len (nm->pending_frames) = 0; } /* Mark time of main loop start. */ if (is_main) { cpu_time_now = vm->clib_time.last_cpu_time; vm->cpu_time_main_loop_start = cpu_time_now; } else cpu_time_now = clib_cpu_time_now (); /* Pre-allocate interupt runtime indices and lock. */ vec_alloc_aligned (nm->pending_interrupts, 1, CLIB_CACHE_LINE_BYTES); /* Pre-allocate expired nodes. */ if (!nm->polling_threshold_vector_length) nm->polling_threshold_vector_length = 10; if (!nm->interrupt_threshold_vector_length) nm->interrupt_threshold_vector_length = 5; vm->cpu_id = clib_get_current_cpu_id (); vm->numa_node = clib_get_current_numa_node (); os_set_numa_index (vm->numa_node); /* Start all processes. */ if (is_main) { uword i; /* * Perform an initial barrier sync. Pays no attention to * the barrier sync hold-down timer scheme, which won't work * at this point in time. */ vlib_worker_thread_initial_barrier_sync_and_release (vm); nm->current_process_index = ~0; for (i = 0; i < vec_len (nm->processes); i++) cpu_time_now = dispatch_process (vm, nm->processes[i], /* frame */ 0, cpu_time_now); } while (1) { vlib_node_runtime_t *n; if (PREDICT_FALSE (_vec_len (vm->pending_rpc_requests) > 0)) { if (!is_main) vl_api_send_pending_rpc_requests (vm); } if (!is_main) vlib_worker_thread_barrier_check (); if (PREDICT_FALSE (vm->check_frame_queues + frame_queue_check_counter)) { u32 processed = 0; if (vm->check_frame_queues) { frame_queue_check_counter = 100; vm->check_frame_queues = 0; } vec_foreach (fqm, tm->frame_queue_mains) processed += vlib_frame_queue_dequeue (vm, fqm); /* No handoff queue work found? */ if (processed) frame_queue_check_counter = 100; else frame_queue_check_counter--; } if (PREDICT_FALSE (vec_len (vm->worker_thread_main_loop_callbacks))) clib_call_callbacks (vm->worker_thread_main_loop_callbacks, vm, cpu_time_now); /* Process pre-input nodes. */ cpu_time_now = clib_cpu_time_now (); vec_foreach (n, nm->nodes_by_type[VLIB_NODE_TYPE_PRE_INPUT]) cpu_time_now = dispatch_node (vm, n, VLIB_NODE_TYPE_PRE_INPUT, VLIB_NODE_STATE_POLLING, /* frame */ 0, cpu_time_now); /* Next process input nodes. */ vec_foreach (n, nm->nodes_by_type[VLIB_NODE_TYPE_INPUT]) cpu_time_now = dispatch_node (vm, n, VLIB_NODE_TYPE_INPUT, VLIB_NODE_STATE_POLLING, /* frame */ 0, cpu_time_now); if (PREDICT_TRUE (is_main && vm->queue_signal_pending == 0)) vm->queue_signal_callback (vm); if (__atomic_load_n (nm->pending_interrupts, __ATOMIC_ACQUIRE)) { int int_num = -1; *nm->pending_interrupts = 0; while ((int_num = clib_interrupt_get_next (nm->interrupts, int_num)) != -1) { vlib_node_runtime_t *n; clib_interrupt_clear (nm->interrupts, int_num); n = vec_elt_at_index (nm->nodes_by_type[VLIB_NODE_TYPE_INPUT], int_num); cpu_time_now = dispatch_node (vm, n, VLIB_NODE_TYPE_INPUT, VLIB_NODE_STATE_INTERRUPT, /* frame */ 0, cpu_time_now); } } /* Input nodes may have added work to the pending vector. Process pending vector until there is nothing left. All pending vectors will be processed from input -> output. */ for (i = 0; i < _vec_len (nm->pending_frames); i++) cpu_time_now = dispatch_pending_node (vm, i, cpu_time_now); /* Reset pending vector for next iteration. */ _vec_len (nm->pending_frames) = 0; if (is_main) { /* *INDENT-OFF* */ ELOG_TYPE_DECLARE (es) = { .format = "process tw start", .format_args = "", }; ELOG_TYPE_DECLARE (ee) = { .format = "process tw end: %d", .format_args = "i4", }; /* *INDENT-ON* */ struct { int nready_procs; } *ed; /* Check if process nodes have expired from timing wheel. */ ASSERT (nm->data_from_advancing_timing_wheel != 0); if (PREDICT_FALSE (vm->elog_trace_graph_dispatch)) ed = ELOG_DATA (&vlib_global_main.elog_main, es); nm->data_from_advancing_timing_wheel = TW (tw_timer_expire_timers_vec) ((TWT (tw_timer_wheel) *) nm->timing_wheel, vlib_time_now (vm), nm->data_from_advancing_timing_wheel); ASSERT (nm->data_from_advancing_timing_wheel != 0); if (PREDICT_FALSE (vm->elog_trace_graph_dispatch)) { ed = ELOG_DATA (&vlib_global_main.elog_main, ee); ed->nready_procs = _vec_len (nm->data_from_advancing_timing_wheel); } if (PREDICT_FALSE (_vec_len (nm->data_from_advancing_timing_wheel) > 0)) { uword i; for (i = 0; i < _vec_len (nm->data_from_advancing_timing_wheel); i++) { u32 d = nm->data_from_advancing_timing_wheel[i]; u32 di = vlib_timing_wheel_data_get_index (d); if (vlib_timing_wheel_data_is_timed_event (d)) { vlib_signal_timed_event_data_t *te = pool_elt_at_index (nm->signal_timed_event_data_pool, di); vlib_node_t *n = vlib_get_node (vm, te->process_node_index); vlib_process_t *p = vec_elt (nm->processes, n->runtime_index); void *data; data = vlib_process_signal_event_helper (nm, n, p, te->event_type_index, te->n_data_elts, te->n_data_elt_bytes); if (te->n_data_bytes < sizeof (te->inline_event_data)) clib_memcpy_fast (data, te->inline_event_data, te->n_data_bytes); else { clib_memcpy_fast (data, te->event_data_as_vector, te->n_data_bytes); vec_free (te->event_data_as_vector); } pool_put (nm->signal_timed_event_data_pool, te); } else { cpu_time_now = clib_cpu_time_now (); cpu_time_now = dispatch_suspended_process (vm, di, cpu_time_now); } } _vec_len (nm->data_from_advancing_timing_wheel) = 0; } } vlib_increment_main_loop_counter (vm); /* Record time stamp in case there are no enabled nodes and above calls do not update time stamp. */ cpu_time_now = clib_cpu_time_now (); vm->loops_this_reporting_interval++; now = clib_time_now_internal (&vm->clib_time, cpu_time_now); /* Time to update loops_per_second? */ if (PREDICT_FALSE (now >= vm->loop_interval_end)) { /* Next sample ends in 20ms */ if (vm->loop_interval_start) { f64 this_loops_per_second; this_loops_per_second = ((f64) vm->loops_this_reporting_interval) / (now - vm->loop_interval_start); vm->loops_per_second = vm->loops_per_second * vm->damping_constant + (1.0 - vm->damping_constant) * this_loops_per_second; if (vm->loops_per_second != 0.0) vm->seconds_per_loop = 1.0 / vm->loops_per_second; else vm->seconds_per_loop = 0.0; } /* New interval starts now, and ends in 20ms */ vm->loop_interval_start = now; vm->loop_interval_end = now + 2e-4; vm->loops_this_reporting_interval = 0; } } } static void vlib_main_loop (vlib_main_t * vm) { vlib_main_or_worker_loop (vm, /* is_main */ 1); } void vlib_worker_loop (vlib_main_t * vm) { vlib_main_or_worker_loop (vm, /* is_main */ 0); } vlib_global_main_t vlib_global_main; void vlib_add_del_post_mortem_callback (void *cb, int is_add) { vlib_global_main_t *vgm = vlib_get_global_main (); int i; if (is_add == 0) { for (i = vec_len (vgm->post_mortem_callbacks) - 1; i >= 0; i--) if (vgm->post_mortem_callbacks[i] == cb) vec_del1 (vgm->post_mortem_callbacks, i); return; } for (i = 0; i < vec_len (vgm->post_mortem_callbacks); i++) if (vgm->post_mortem_callbacks[i] == cb) return; vec_add1 (vgm->post_mortem_callbacks, cb); } static void elog_post_mortem_dump (void) { elog_main_t *em = vlib_get_elog_main (); u8 *filename; clib_error_t *error; filename = format (0, "/tmp/elog_post_mortem.%d%c", getpid (), 0); error = elog_write_file (em, (char *) filename, 1 /* flush ring */); if (error) clib_error_report (error); /* * We're in the middle of crashing. Don't try to free the filename. */ } static clib_error_t * vlib_main_configure (vlib_main_t * vm, unformat_input_t * input) { vlib_global_main_t *vgm = vlib_get_global_main (); int turn_on_mem_trace = 0; while (unformat_check_input (input) != UNFORMAT_END_OF_INPUT) { if (unformat (input, "memory-trace")) turn_on_mem_trace = 1; else if (unformat (input, "elog-events %d", &vgm->configured_elog_ring_size)) vgm->configured_elog_ring_size = 1 << max_log2 (vgm->configured_elog_ring_size); else if (unformat (input, "elog-post-mortem-dump")) vlib_add_del_post_mortem_callback (elog_post_mortem_dump, /* is_add */ 1); else if (unformat (input, "buffer-alloc-success-rate %f", &vm->buffer_alloc_success_rate)) { if (VLIB_BUFFER_ALLOC_FAULT_INJECTOR == 0) return clib_error_return (0, "Buffer fault injection not configured"); } else if (unformat (input, "buffer-alloc-success-seed %u", &vm->buffer_alloc_success_seed)) { if (VLIB_BUFFER_ALLOC_FAULT_INJECTOR == 0) return clib_error_return (0, "Buffer fault injection not configured"); } else return unformat_parse_error (input); } unformat_free (input); /* Enable memory trace as early as possible. */ if (turn_on_mem_trace) clib_mem_trace (1); return 0; } VLIB_EARLY_CONFIG_FUNCTION (vlib_main_configure, "vlib"); static void placeholder_queue_signal_callback (vlib_main_t * vm) { } #define foreach_weak_reference_stub \ _(vlib_map_stat_segment_init) \ _(vpe_api_init) \ _(vlibmemory_init) \ _(map_api_segment_init) #define _(name) \ clib_error_t *name (vlib_main_t *vm) __attribute__((weak)); \ clib_error_t *name (vlib_main_t *vm) { return 0; } foreach_weak_reference_stub; #undef _ void vl_api_set_elog_main (elog_main_t * m) __attribute__ ((weak)); void vl_api_set_elog_main (elog_main_t * m) { clib_warning ("STUB"); } int vl_api_set_elog_trace_api_messages (int enable) __attribute__ ((weak)); int vl_api_set_elog_trace_api_messages (int enable) { clib_warning ("STUB"); return 0; } int vl_api_get_elog_trace_api_messages (void) __attribute__ ((weak)); int vl_api_get_elog_trace_api_messages (void) { clib_warning ("STUB"); return 0; } /* Main function. */ int vlib_main (vlib_main_t * volatile vm, unformat_input_t * input) { vlib_global_main_t *vgm = vlib_get_global_main (); clib_error_t *volatile error; vlib_node_main_t *nm = &vm->node_main; vm->queue_signal_callback = placeholder_queue_signal_callback; /* Reconfigure event log which is enabled very early */ if (vgm->configured_elog_ring_size && vgm->configured_elog_ring_size != vgm->elog_main.event_ring_size) elog_resize (&vgm->elog_main, vgm->configured_elog_ring_size); vl_api_set_elog_main (vlib_get_elog_main ()); (void) vl_api_set_elog_trace_api_messages (1); /* Default name. */ if (!vgm->name) vgm->name = "VLIB"; if ((error = vlib_physmem_init (vm))) { clib_error_report (error); goto done; } if ((error = vlib_map_stat_segment_init (vm))) { clib_error_report (error); goto done; } if ((error = vlib_buffer_main_init (vm))) { clib_error_report (error); goto done; } if ((error = vlib_thread_init (vm))) { clib_error_report (error); goto done; } /* Register node ifunction variants */ vlib_register_all_node_march_variants (vm); /* Register static nodes so that init functions may use them. */ vlib_register_all_static_nodes (vm); /* Set seed for random number generator. Allow user to specify seed to make random sequence deterministic. */ if (!unformat (input, "seed %wd", &vm->random_seed)) vm->random_seed = clib_cpu_time_now (); clib_random_buffer_init (&vm->random_buffer, vm->random_seed); /* Initialize node graph. */ if ((error = vlib_node_main_init (vm))) { /* Arrange for graph hook up error to not be fatal when debugging. */ if (CLIB_DEBUG > 0) clib_error_report (error); else goto done; } /* Direct call / weak reference, for vlib standalone use-cases */ if ((error = vpe_api_init (vm))) { clib_error_report (error); goto done; } if ((error = vlibmemory_init (vm))) { clib_error_report (error); goto done; } if ((error = map_api_segment_init (vm))) { clib_error_report (error); goto done; } /* See unix/main.c; most likely already set up */ if (vgm->init_functions_called == 0) vgm->init_functions_called = hash_create (0, /* value bytes */ 0); if ((error = vlib_call_all_init_functions (vm))) goto done; nm->timing_wheel = clib_mem_alloc_aligned (sizeof (TWT (tw_timer_wheel)), CLIB_CACHE_LINE_BYTES); vec_validate (nm->data_from_advancing_timing_wheel, 10); _vec_len (nm->data_from_advancing_timing_wheel) = 0; /* Create the process timing wheel */ TW (tw_timer_wheel_init) ((TWT (tw_timer_wheel) *) nm->timing_wheel, 0 /* no callback */ , 10e-6 /* timer period 10us */ , ~0 /* max expirations per call */ ); vec_validate (vm->pending_rpc_requests, 0); _vec_len (vm->pending_rpc_requests) = 0; vec_validate (vm->processing_rpc_requests, 0); _vec_len (vm->processing_rpc_requests) = 0; /* Default params for the buffer allocator fault injector, if configured */ if (VLIB_BUFFER_ALLOC_FAULT_INJECTOR > 0) { vm->buffer_alloc_success_seed = 0xdeaddabe; vm->buffer_alloc_success_rate = 0.80; } if ((error = vlib_call_all_config_functions (vm, input, 0 /* is_early */ ))) goto done; /* * Use exponential smoothing, with a half-life of 1 second * reported_rate(t) = reported_rate(t-1) * K + rate(t)*(1-K) * * Sample every 20ms, aka 50 samples per second * K = exp (-1.0/20.0); * K = 0.95 */ vm->damping_constant = exp (-1.0 / 20.0); /* Sort per-thread init functions before we start threads */ vlib_sort_init_exit_functions (&vgm->worker_init_function_registrations); /* Call all main loop enter functions. */ { clib_error_t *sub_error; sub_error = vlib_call_all_main_loop_enter_functions (vm); if (sub_error) clib_error_report (sub_error); } switch (clib_setjmp (&vm->main_loop_exit, VLIB_MAIN_LOOP_EXIT_NONE)) { case VLIB_MAIN_LOOP_EXIT_NONE: vm->main_loop_exit_set = 1; break; case VLIB_MAIN_LOOP_EXIT_CLI: goto done; default: error = vm->main_loop_error; goto done; } vlib_main_loop (vm); done: vlib_worker_thread_barrier_sync (vm); /* Call all exit functions. */ { clib_error_t *sub_error; sub_error = vlib_call_all_main_loop_exit_functions (vm); if (sub_error) clib_error_report (sub_error); } vlib_worker_thread_barrier_release (vm); if (error) clib_error_report (error); return 0; } vlib_main_t * vlib_get_main_not_inline (void) { return vlib_get_main (); } elog_main_t * vlib_get_elog_main_not_inline () { return &vlib_global_main.elog_main; } /* * fd.io coding-style-patch-verification: ON * * Local Variables: * eval: (c-set-style "gnu") * End: */