Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Jiri Olsa | 1400 | 76.71% | 15 | 55.56% |
Alexander Yarygin | 201 | 11.01% | 1 | 3.70% |
Arnaldo Carvalho de Melo | 174 | 9.53% | 8 | 29.63% |
Wang Nan | 42 | 2.30% | 1 | 3.70% |
David Carrillo-Cisneros | 7 | 0.38% | 1 | 3.70% |
Greg Kroah-Hartman | 1 | 0.05% | 1 | 3.70% |
Total | 1825 | 27 |
// SPDX-License-Identifier: GPL-2.0 #include <errno.h> #include <inttypes.h> #include <linux/list.h> #include <linux/compiler.h> #include <linux/string.h> #include "ordered-events.h" #include "session.h" #include "asm/bug.h" #include "debug.h" #define pr_N(n, fmt, ...) \ eprintf(n, debug_ordered_events, fmt, ##__VA_ARGS__) #define pr(fmt, ...) pr_N(1, pr_fmt(fmt), ##__VA_ARGS__) static void queue_event(struct ordered_events *oe, struct ordered_event *new) { struct ordered_event *last = oe->last; u64 timestamp = new->timestamp; struct list_head *p; ++oe->nr_events; oe->last = new; pr_oe_time2(timestamp, "queue_event nr_events %u\n", oe->nr_events); if (!last) { list_add(&new->list, &oe->events); oe->max_timestamp = timestamp; return; } /* * last event might point to some random place in the list as it's * the last queued event. We expect that the new event is close to * this. */ if (last->timestamp <= timestamp) { while (last->timestamp <= timestamp) { p = last->list.next; if (p == &oe->events) { list_add_tail(&new->list, &oe->events); oe->max_timestamp = timestamp; return; } last = list_entry(p, struct ordered_event, list); } list_add_tail(&new->list, &last->list); } else { while (last->timestamp > timestamp) { p = last->list.prev; if (p == &oe->events) { list_add(&new->list, &oe->events); return; } last = list_entry(p, struct ordered_event, list); } list_add(&new->list, &last->list); } } static union perf_event *__dup_event(struct ordered_events *oe, union perf_event *event) { union perf_event *new_event = NULL; if (oe->cur_alloc_size < oe->max_alloc_size) { new_event = memdup(event, event->header.size); if (new_event) oe->cur_alloc_size += event->header.size; } return new_event; } static union perf_event *dup_event(struct ordered_events *oe, union perf_event *event) { return oe->copy_on_queue ? __dup_event(oe, event) : event; } static void __free_dup_event(struct ordered_events *oe, union perf_event *event) { if (event) { oe->cur_alloc_size -= event->header.size; free(event); } } static void free_dup_event(struct ordered_events *oe, union perf_event *event) { if (oe->copy_on_queue) __free_dup_event(oe, event); } #define MAX_SAMPLE_BUFFER (64 * 1024 / sizeof(struct ordered_event)) static struct ordered_event *alloc_event(struct ordered_events *oe, union perf_event *event) { struct list_head *cache = &oe->cache; struct ordered_event *new = NULL; union perf_event *new_event; size_t size; new_event = dup_event(oe, event); if (!new_event) return NULL; /* * We maintain the following scheme of buffers for ordered * event allocation: * * to_free list -> buffer1 (64K) * buffer2 (64K) * ... * * Each buffer keeps an array of ordered events objects: * buffer -> event[0] * event[1] * ... * * Each allocated ordered event is linked to one of * following lists: * - time ordered list 'events' * - list of currently removed events 'cache' * * Allocation of the ordered event uses the following order * to get the memory: * - use recently removed object from 'cache' list * - use available object in current allocation buffer * - allocate new buffer if the current buffer is full * * Removal of ordered event object moves it from events to * the cache list. */ size = sizeof(*oe->buffer) + MAX_SAMPLE_BUFFER * sizeof(*new); if (!list_empty(cache)) { new = list_entry(cache->next, struct ordered_event, list); list_del(&new->list); } else if (oe->buffer) { new = &oe->buffer->event[oe->buffer_idx]; if (++oe->buffer_idx == MAX_SAMPLE_BUFFER) oe->buffer = NULL; } else if ((oe->cur_alloc_size + size) < oe->max_alloc_size) { oe->buffer = malloc(size); if (!oe->buffer) { free_dup_event(oe, new_event); return NULL; } pr("alloc size %" PRIu64 "B (+%zu), max %" PRIu64 "B\n", oe->cur_alloc_size, size, oe->max_alloc_size); oe->cur_alloc_size += size; list_add(&oe->buffer->list, &oe->to_free); oe->buffer_idx = 1; new = &oe->buffer->event[0]; } else { pr("allocation limit reached %" PRIu64 "B\n", oe->max_alloc_size); return NULL; } new->event = new_event; return new; } static struct ordered_event * ordered_events__new_event(struct ordered_events *oe, u64 timestamp, union perf_event *event) { struct ordered_event *new; new = alloc_event(oe, event); if (new) { new->timestamp = timestamp; queue_event(oe, new); } return new; } void ordered_events__delete(struct ordered_events *oe, struct ordered_event *event) { list_move(&event->list, &oe->cache); oe->nr_events--; free_dup_event(oe, event->event); event->event = NULL; } int ordered_events__queue(struct ordered_events *oe, union perf_event *event, u64 timestamp, u64 file_offset) { struct ordered_event *oevent; if (!timestamp || timestamp == ~0ULL) return -ETIME; if (timestamp < oe->last_flush) { pr_oe_time(timestamp, "out of order event\n"); pr_oe_time(oe->last_flush, "last flush, last_flush_type %d\n", oe->last_flush_type); oe->nr_unordered_events++; } oevent = ordered_events__new_event(oe, timestamp, event); if (!oevent) { ordered_events__flush(oe, OE_FLUSH__HALF); oevent = ordered_events__new_event(oe, timestamp, event); } if (!oevent) return -ENOMEM; oevent->file_offset = file_offset; return 0; } static int do_flush(struct ordered_events *oe, bool show_progress) { struct list_head *head = &oe->events; struct ordered_event *tmp, *iter; u64 limit = oe->next_flush; u64 last_ts = oe->last ? oe->last->timestamp : 0ULL; struct ui_progress prog; int ret; if (!limit) return 0; if (show_progress) ui_progress__init(&prog, oe->nr_events, "Processing time ordered events..."); list_for_each_entry_safe(iter, tmp, head, list) { if (session_done()) return 0; if (iter->timestamp > limit) break; ret = oe->deliver(oe, iter); if (ret) return ret; ordered_events__delete(oe, iter); oe->last_flush = iter->timestamp; if (show_progress) ui_progress__update(&prog, 1); } if (list_empty(head)) oe->last = NULL; else if (last_ts <= limit) oe->last = list_entry(head->prev, struct ordered_event, list); if (show_progress) ui_progress__finish(); return 0; } static int __ordered_events__flush(struct ordered_events *oe, enum oe_flush how, u64 timestamp) { static const char * const str[] = { "NONE", "FINAL", "ROUND", "HALF ", }; int err; bool show_progress = false; if (oe->nr_events == 0) return 0; switch (how) { case OE_FLUSH__FINAL: show_progress = true; __fallthrough; case OE_FLUSH__TOP: oe->next_flush = ULLONG_MAX; break; case OE_FLUSH__HALF: { struct ordered_event *first, *last; struct list_head *head = &oe->events; first = list_entry(head->next, struct ordered_event, list); last = oe->last; /* Warn if we are called before any event got allocated. */ if (WARN_ONCE(!last || list_empty(head), "empty queue")) return 0; oe->next_flush = first->timestamp; oe->next_flush += (last->timestamp - first->timestamp) / 2; break; } case OE_FLUSH__TIME: oe->next_flush = timestamp; show_progress = false; break; case OE_FLUSH__ROUND: case OE_FLUSH__NONE: default: break; }; pr_oe_time(oe->next_flush, "next_flush - ordered_events__flush PRE %s, nr_events %u\n", str[how], oe->nr_events); pr_oe_time(oe->max_timestamp, "max_timestamp\n"); err = do_flush(oe, show_progress); if (!err) { if (how == OE_FLUSH__ROUND) oe->next_flush = oe->max_timestamp; oe->last_flush_type = how; } pr_oe_time(oe->next_flush, "next_flush - ordered_events__flush POST %s, nr_events %u\n", str[how], oe->nr_events); pr_oe_time(oe->last_flush, "last_flush\n"); return err; } int ordered_events__flush(struct ordered_events *oe, enum oe_flush how) { return __ordered_events__flush(oe, how, 0); } int ordered_events__flush_time(struct ordered_events *oe, u64 timestamp) { return __ordered_events__flush(oe, OE_FLUSH__TIME, timestamp); } u64 ordered_events__first_time(struct ordered_events *oe) { struct ordered_event *event; if (list_empty(&oe->events)) return 0; event = list_first_entry(&oe->events, struct ordered_event, list); return event->timestamp; } void ordered_events__init(struct ordered_events *oe, ordered_events__deliver_t deliver, void *data) { INIT_LIST_HEAD(&oe->events); INIT_LIST_HEAD(&oe->cache); INIT_LIST_HEAD(&oe->to_free); oe->max_alloc_size = (u64) -1; oe->cur_alloc_size = 0; oe->deliver = deliver; oe->data = data; } static void ordered_events_buffer__free(struct ordered_events_buffer *buffer, unsigned int max, struct ordered_events *oe) { if (oe->copy_on_queue) { unsigned int i; for (i = 0; i < max; i++) __free_dup_event(oe, buffer->event[i].event); } free(buffer); } void ordered_events__free(struct ordered_events *oe) { struct ordered_events_buffer *buffer, *tmp; if (list_empty(&oe->to_free)) return; /* * Current buffer might not have all the events allocated * yet, we need to free only allocated ones ... */ if (oe->buffer) { list_del(&oe->buffer->list); ordered_events_buffer__free(oe->buffer, oe->buffer_idx, oe); } /* ... and continue with the rest */ list_for_each_entry_safe(buffer, tmp, &oe->to_free, list) { list_del(&buffer->list); ordered_events_buffer__free(buffer, MAX_SAMPLE_BUFFER, oe); } } void ordered_events__reinit(struct ordered_events *oe) { ordered_events__deliver_t old_deliver = oe->deliver; ordered_events__free(oe); memset(oe, '\0', sizeof(*oe)); ordered_events__init(oe, old_deliver, oe->data); }
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