#define _GNU_SOURCE #include #undef _GNU_SOURCE #include "../libslang.h" #include #include #include #include #include "../../hist.h" #include "../../pstack.h" #include "../../sort.h" #include "../../util.h" #include "../browser.h" #include "../helpline.h" #include "../util.h" #include "map.h" struct hist_browser { struct ui_browser b; struct hists *hists; struct hist_entry *he_selection; struct map_symbol *selection; }; static void hist_browser__refresh_dimensions(struct hist_browser *self) { /* 3 == +/- toggle symbol before actual hist_entry rendering */ self->b.width = 3 + (hists__sort_list_width(self->hists) + sizeof("[k]")); } static void hist_browser__reset(struct hist_browser *self) { self->b.nr_entries = self->hists->nr_entries; hist_browser__refresh_dimensions(self); ui_browser__reset_index(&self->b); } static char tree__folded_sign(bool unfolded) { return unfolded ? '-' : '+'; } static char map_symbol__folded(const struct map_symbol *self) { return self->has_children ? tree__folded_sign(self->unfolded) : ' '; } static char hist_entry__folded(const struct hist_entry *self) { return map_symbol__folded(&self->ms); } static char callchain_list__folded(const struct callchain_list *self) { return map_symbol__folded(&self->ms); } static void map_symbol__set_folding(struct map_symbol *self, bool unfold) { self->unfolded = unfold ? self->has_children : false; } static int callchain_node__count_rows_rb_tree(struct callchain_node *self) { int n = 0; struct rb_node *nd; for (nd = rb_first(&self->rb_root); nd; nd = rb_next(nd)) { struct callchain_node *child = rb_entry(nd, struct callchain_node, rb_node); struct callchain_list *chain; char folded_sign = ' '; /* No children */ list_for_each_entry(chain, &child->val, list) { ++n; /* We need this because we may not have children */ folded_sign = callchain_list__folded(chain); if (folded_sign == '+') break; } if (folded_sign == '-') /* Have children and they're unfolded */ n += callchain_node__count_rows_rb_tree(child); } return n; } static int callchain_node__count_rows(struct callchain_node *node) { struct callchain_list *chain; bool unfolded = false; int n = 0; list_for_each_entry(chain, &node->val, list) { ++n; unfolded = chain->ms.unfolded; } if (unfolded) n += callchain_node__count_rows_rb_tree(node); return n; } static int callchain__count_rows(struct rb_root *chain) { struct rb_node *nd; int n = 0; for (nd = rb_first(chain); nd; nd = rb_next(nd)) { struct callchain_node *node = rb_entry(nd, struct callchain_node, rb_node); n += callchain_node__count_rows(node); } return n; } static bool map_symbol__toggle_fold(struct map_symbol *self) { if (!self->has_children) return false; self->unfolded = !self->unfolded; return true; } static void callchain_node__init_have_children_rb_tree(struct callchain_node *self) { struct rb_node *nd = rb_first(&self->rb_root); for (nd = rb_first(&self->rb_root); nd; nd = rb_next(nd)) { struct callchain_node *child = rb_entry(nd, struct callchain_node, rb_node); struct callchain_list *chain; bool first = true; list_for_each_entry(chain, &child->val, list) { if (first) { first = false; chain->ms.has_children = chain->list.next != &child->val || !RB_EMPTY_ROOT(&child->rb_root); } else chain->ms.has_children = chain->list.next == &child->val && !RB_EMPTY_ROOT(&child->rb_root); } callchain_node__init_have_children_rb_tree(child); } } static void callchain_node__init_have_children(struct callchain_node *self) { struct callchain_list *chain; list_for_each_entry(chain, &self->val, list) chain->ms.has_children = !RB_EMPTY_ROOT(&self->rb_root); callchain_node__init_have_children_rb_tree(self); } static void callchain__init_have_children(struct rb_root *self) { struct rb_node *nd; for (nd = rb_first(self); nd; nd = rb_next(nd)) { struct callchain_node *node = rb_entry(nd, struct callchain_node, rb_node); callchain_node__init_have_children(node); } } static void hist_entry__init_have_children(struct hist_entry *self) { if (!self->init_have_children) { self->ms.has_children = !RB_EMPTY_ROOT(&self->sorted_chain); callchain__init_have_children(&self->sorted_chain); self->init_have_children = true; } } static bool hist_browser__toggle_fold(struct hist_browser *self) { if (map_symbol__toggle_fold(self->selection)) { struct hist_entry *he = self->he_selection; hist_entry__init_have_children(he); self->hists->nr_entries -= he->nr_rows; if (he->ms.unfolded) he->nr_rows = callchain__count_rows(&he->sorted_chain); else he->nr_rows = 0; self->hists->nr_entries += he->nr_rows; self->b.nr_entries = self->hists->nr_entries; return true; } /* If it doesn't have children, no toggling performed */ return false; } static int callchain_node__set_folding_rb_tree(struct callchain_node *self, bool unfold) { int n = 0; struct rb_node *nd; for (nd = rb_first(&self->rb_root); nd; nd = rb_next(nd)) { struct callchain_node *child = rb_entry(nd, struct callchain_node, rb_node); struct callchain_list *chain; bool has_children = false; list_for_each_entry(chain, &child->val, list) { ++n; map_symbol__set_folding(&chain->ms, unfold); has_children = chain->ms.has_children; } if (has_children) n += callchain_node__set_folding_rb_tree(child, unfold); } return n; } static int callchain_node__set_folding(struct callchain_node *node, bool unfold) { struct callchain_list *chain; bool has_children = false; int n = 0; list_for_each_entry(chain, &node->val, list) { ++n; map_symbol__set_folding(&chain->ms, unfold); has_children = chain->ms.has_children; } if (has_children) n += callchain_node__set_folding_rb_tree(node, unfold); return n; } static int callchain__set_folding(struct rb_root *chain, bool unfold) { struct rb_node *nd; int n = 0; for (nd = rb_first(chain); nd; nd = rb_next(nd)) { struct callchain_node *node = rb_entry(nd, struct callchain_node, rb_node); n += callchain_node__set_folding(node, unfold); } return n; } static void hist_entry__set_folding(struct hist_entry *self, bool unfold) { hist_entry__init_have_children(self); map_symbol__set_folding(&self->ms, unfold); if (self->ms.has_children) { int n = callchain__set_folding(&self->sorted_chain, unfold); self->nr_rows = unfold ? n : 0; } else self->nr_rows = 0; } static void hists__set_folding(struct hists *self, bool unfold) { struct rb_node *nd; self->nr_entries = 0; for (nd = rb_first(&self->entries); nd; nd = rb_next(nd)) { struct hist_entry *he = rb_entry(nd, struct hist_entry, rb_node); hist_entry__set_folding(he, unfold); self->nr_entries += 1 + he->nr_rows; } } static void hist_browser__set_folding(struct hist_browser *self, bool unfold) { hists__set_folding(self->hists, unfold); self->b.nr_entries = self->hists->nr_entries; /* Go to the start, we may be way after valid entries after a collapse */ ui_browser__reset_index(&self->b); } static int hist_browser__run(struct hist_browser *self, const char *title) { int key; int exit_keys[] = { 'a', '?', 'h', 'C', 'd', 'D', 'E', 't', NEWT_KEY_ENTER, NEWT_KEY_RIGHT, NEWT_KEY_LEFT, 0, }; self->b.entries = &self->hists->entries; self->b.nr_entries = self->hists->nr_entries; hist_browser__refresh_dimensions(self); if (ui_browser__show(&self->b, title, "Press '?' for help on key bindings") < 0) return -1; ui_browser__add_exit_keys(&self->b, exit_keys); while (1) { key = ui_browser__run(&self->b); switch (key) { case 'D': { /* Debug */ static int seq; struct hist_entry *h = rb_entry(self->b.top, struct hist_entry, rb_node); ui_helpline__pop(); ui_helpline__fpush("%d: nr_ent=(%d,%d), height=%d, idx=%d, fve: idx=%d, row_off=%d, nrows=%d", seq++, self->b.nr_entries, self->hists->nr_entries, self->b.height, self->b.index, self->b.top_idx, h->row_offset, h->nr_rows); } break; case 'C': /* Collapse the whole world. */ hist_browser__set_folding(self, false); break; case 'E': /* Expand the whole world. */ hist_browser__set_folding(self, true); break; case NEWT_KEY_ENTER: if (hist_browser__toggle_fold(self)) break; /* fall thru */ default: goto out; } } out: ui_browser__hide(&self->b); return key; } static char *callchain_list__sym_name(struct callchain_list *self, char *bf, size_t bfsize) { if (self->ms.sym) return self->ms.sym->name; snprintf(bf, bfsize, "%#" PRIx64, self->ip); return bf; } #define LEVEL_OFFSET_STEP 3 static int hist_browser__show_callchain_node_rb_tree(struct hist_browser *self, struct callchain_node *chain_node, u64 total, int level, unsigned short row, off_t *row_offset, bool *is_current_entry) { struct rb_node *node; int first_row = row, width, offset = level * LEVEL_OFFSET_STEP; u64 new_total, remaining; if (callchain_param.mode == CHAIN_GRAPH_REL) new_total = chain_node->children_hit; else new_total = total; remaining = new_total; node = rb_first(&chain_node->rb_root); while (node) { struct callchain_node *child = rb_entry(node, struct callchain_node, rb_node); struct rb_node *next = rb_next(node); u64 cumul = callchain_cumul_hits(child); struct callchain_list *chain; char folded_sign = ' '; int first = true; int extra_offset = 0; remaining -= cumul; list_for_each_entry(chain, &child->val, list) { char ipstr[BITS_PER_LONG / 4 + 1], *alloc_str; const char *str; int color; bool was_first = first; if (first) first = false; else extra_offset = LEVEL_OFFSET_STEP; folded_sign = callchain_list__folded(chain); if (*row_offset != 0) { --*row_offset; goto do_next; } alloc_str = NULL; str = callchain_list__sym_name(chain, ipstr, sizeof(ipstr)); if (was_first) { double percent = cumul * 100.0 / new_total; if (asprintf(&alloc_str, "%2.2f%% %s", percent, str) < 0) str = "Not enough memory!"; else str = alloc_str; } color = HE_COLORSET_NORMAL; width = self->b.width - (offset + extra_offset + 2); if (ui_browser__is_current_entry(&self->b, row)) { self->selection = &chain->ms; color = HE_COLORSET_SELECTED; *is_current_entry = true; } ui_browser__set_color(&self->b, color); ui_browser__gotorc(&self->b, row, 0); slsmg_write_nstring(" ", offset + extra_offset); slsmg_printf("%c ", folded_sign); slsmg_write_nstring(str, width); free(alloc_str); if (++row == self->b.height) goto out; do_next: if (folded_sign == '+') break; } if (folded_sign == '-') { const int new_level = level + (extra_offset ? 2 : 1); row += hist_browser__show_callchain_node_rb_tree(self, child, new_total, new_level, row, row_offset, is_current_entry); } if (row == self->b.height) goto out; node = next; } out: return row - first_row; } static int hist_browser__show_callchain_node(struct hist_browser *self, struct callchain_node *node, int level, unsigned short row, off_t *row_offset, bool *is_current_entry) { struct callchain_list *chain; int first_row = row, offset = level * LEVEL_OFFSET_STEP, width = self->b.width - offset; char folded_sign = ' '; list_for_each_entry(chain, &node->val, list) { char ipstr[BITS_PER_LONG / 4 + 1], *s; int color; folded_sign = callchain_list__folded(chain); if (*row_offset != 0) { --*row_offset; continue; } color = HE_COLORSET_NORMAL; if (ui_browser__is_current_entry(&self->b, row)) { self->selection = &chain->ms; color = HE_COLORSET_SELECTED; *is_current_entry = true; } s = callchain_list__sym_name(chain, ipstr, sizeof(ipstr)); ui_browser__gotorc(&self->b, row, 0); ui_browser__set_color(&self->b, color); slsmg_write_nstring(" ", offset); slsmg_printf("%c ", folded_sign); slsmg_write_nstring(s, width - 2); if (++row == self->b.height) goto out; } if (folded_sign == '-') row += hist_browser__show_callchain_node_rb_tree(self, node, self->hists->stats.total_period, level + 1, row, row_offset, is_current_entry); out: return row - first_row; } static int hist_browser__show_callchain(struct hist_browser *self, struct rb_root *chain, int level, unsigned short row, off_t *row_offset, bool *is_current_entry) { struct rb_node *nd; int first_row = row; for (nd = rb_first(chain); nd; nd = rb_next(nd)) { struct callchain_node *node = rb_entry(nd, struct callchain_node, rb_node); row += hist_browser__show_callchain_node(self, node, level, row, row_offset, is_current_entry); if (row == self->b.height) break; } return row - first_row; } static int hist_browser__show_entry(struct hist_browser *self, struct hist_entry *entry, unsigned short row) { char s[256]; double percent; int printed = 0; int color, width = self->b.width; char folded_sign = ' '; bool current_entry = ui_browser__is_current_entry(&self->b, row); off_t row_offset = entry->row_offset; if (current_entry) { self->he_selection = entry; self->selection = &entry->ms; } if (symbol_conf.use_callchain) { hist_entry__init_have_children(entry); folded_sign = hist_entry__folded(entry); } if (row_offset == 0) { hist_entry__snprintf(entry, s, sizeof(s), self->hists, NULL, false, 0, false, self->hists->stats.total_period); percent = (entry->period * 100.0) / self->hists->stats.total_period; color = HE_COLORSET_SELECTED; if (!current_entry) { if (percent >= MIN_RED) color = HE_COLORSET_TOP; else if (percent >= MIN_GREEN) color = HE_COLORSET_MEDIUM; else color = HE_COLORSET_NORMAL; } ui_browser__set_color(&self->b, color); ui_browser__gotorc(&self->b, row, 0); if (symbol_conf.use_callchain) { slsmg_printf("%c ", folded_sign); width -= 2; } slsmg_write_nstring(s, width); ++row; ++printed; } else --row_offset; if (folded_sign == '-' && row != self->b.height) { printed += hist_browser__show_callchain(self, &entry->sorted_chain, 1, row, &row_offset, ¤t_entry); if (current_entry) self->he_selection = entry; } return printed; } static unsigned int hist_browser__refresh(struct ui_browser *self) { unsigned row = 0; struct rb_node *nd; struct hist_browser *hb = container_of(self, struct hist_browser, b); if (self->top == NULL) self->top = rb_first(&hb->hists->entries); for (nd = self->top; nd; nd = rb_next(nd)) { struct hist_entry *h = rb_entry(nd, struct hist_entry, rb_node); if (h->filtered) continue; row += hist_browser__show_entry(hb, h, row); if (row == self->height) break; } return row; } static struct rb_node *hists__filter_entries(struct rb_node *nd) { while (nd != NULL) { struct hist_entry *h = rb_entry(nd, struct hist_entry, rb_node); if (!h->filtered) return nd; nd = rb_next(nd); } return NULL; } static struct rb_node *hists__filter_prev_entries(struct rb_node *nd) { while (nd != NULL) { struct hist_entry *h = rb_entry(nd, struct hist_entry, rb_node); if (!h->filtered) return nd; nd = rb_prev(nd); } return NULL; } static void ui_browser__hists_seek(struct ui_browser *self, off_t offset, int whence) { struct hist_entry *h; struct rb_node *nd; bool first = true; switch (whence) { case SEEK_SET: nd = hists__filter_entries(rb_first(self->entries)); break; case SEEK_CUR: nd = self->top; goto do_offset; case SEEK_END: nd = hists__filter_prev_entries(rb_last(self->entries)); first = false; break; default: return; } /* * Moves not relative to the first visible entry invalidates its * row_offset: */ h = rb_entry(self->top, struct hist_entry, rb_node); h->row_offset = 0; /* * Here we have to check if nd is expanded (+), if it is we can't go * the next top level hist_entry, instead we must compute an offset of * what _not_ to show and not change the first visible entry. * * This offset increments when we are going from top to bottom and * decreases when we're going from bottom to top. * * As we don't have backpointers to the top level in the callchains * structure, we need to always print the whole hist_entry callchain, * skipping the first ones that are before the first visible entry * and stop when we printed enough lines to fill the screen. */ do_offset: if (offset > 0) { do { h = rb_entry(nd, struct hist_entry, rb_node); if (h->ms.unfolded) { u16 remaining = h->nr_rows - h->row_offset; if (offset > remaining) { offset -= remaining; h->row_offset = 0; } else { h->row_offset += offset; offset = 0; self->top = nd; break; } } nd = hists__filter_entries(rb_next(nd)); if (nd == NULL) break; --offset; self->top = nd; } while (offset != 0); } else if (offset < 0) { while (1) { h = rb_entry(nd, struct hist_entry, rb_node); if (h->ms.unfolded) { if (first) { if (-offset > h->row_offset) { offset += h->row_offset; h->row_offset = 0; } else { h->row_offset += offset; offset = 0; self->top = nd; break; } } else { if (-offset > h->nr_rows) { offset += h->nr_rows; h->row_offset = 0; } else { h->row_offset = h->nr_rows + offset; offset = 0; self->top = nd; break; } } } nd = hists__filter_prev_entries(rb_prev(nd)); if (nd == NULL) break; ++offset; self->top = nd; if (offset == 0) { /* * Last unfiltered hist_entry, check if it is * unfolded, if it is then we should have * row_offset at its last entry. */ h = rb_entry(nd, struct hist_entry, rb_node); if (h->ms.unfolded) h->row_offset = h->nr_rows; break; } first = false; } } else { self->top = nd; h = rb_entry(nd, struct hist_entry, rb_node); h->row_offset = 0; } } static struct hist_browser *hist_browser__new(struct hists *hists) { struct hist_browser *self = zalloc(sizeof(*self)); if (self) { self->hists = hists; self->b.refresh = hist_browser__refresh; self->b.seek = ui_browser__hists_seek; } return self; } static void hist_browser__delete(struct hist_browser *self) { free(self); } static struct hist_entry *hist_browser__selected_entry(struct hist_browser *self) { return self->he_selection; } static struct thread *hist_browser__selected_thread(struct hist_browser *self) { return self->he_selection->thread; } static int hists__browser_title(struct hists *self, char *bf, size_t size, const char *ev_name, const struct dso *dso, const struct thread *thread) { char unit; int printed; unsigned long nr_events = self->stats.nr_events[PERF_RECORD_SAMPLE]; nr_events = convert_unit(nr_events, &unit); printed = snprintf(bf, size, "Events: %lu%c %s", nr_events, unit, ev_name); if (thread) printed += snprintf(bf + printed, size - printed, ", Thread: %s(%d)", (thread->comm_set ? thread->comm : ""), thread->pid); if (dso) printed += snprintf(bf + printed, size - printed, ", DSO: %s", dso->short_name); return printed; } int hists__browse(struct hists *self, const char *helpline, const char *ev_name) { struct hist_browser *browser = hist_browser__new(self); struct pstack *fstack; const struct thread *thread_filter = NULL; const struct dso *dso_filter = NULL; char msg[160]; int key = -1; if (browser == NULL) return -1; fstack = pstack__new(2); if (fstack == NULL) goto out; ui_helpline__push(helpline); hists__browser_title(self, msg, sizeof(msg), ev_name, dso_filter, thread_filter); while (1) { const struct thread *thread; const struct dso *dso; char *options[16]; int nr_options = 0, choice = 0, i, annotate = -2, zoom_dso = -2, zoom_thread = -2, browse_map = -2; key = hist_browser__run(browser, msg); thread = hist_browser__selected_thread(browser); dso = browser->selection->map ? browser->selection->map->dso : NULL; switch (key) { case NEWT_KEY_TAB: case NEWT_KEY_UNTAB: /* * Exit the browser, let hists__browser_tree * go to the next or previous */ goto out_free_stack; case 'a': if (browser->selection->map == NULL && browser->selection->map->dso->annotate_warned) continue; goto do_annotate; case 'd': goto zoom_dso; case 't': goto zoom_thread; case NEWT_KEY_F1: case 'h': case '?': ui__help_window("-> Zoom into DSO/Threads & Annotate current symbol\n" "<- Zoom out\n" "a Annotate current symbol\n" "h/?/F1 Show this window\n" "C Collapse all callchains\n" "E Expand all callchains\n" "d Zoom into current DSO\n" "t Zoom into current Thread\n" "q/CTRL+C Exit browser"); continue; case NEWT_KEY_ENTER: case NEWT_KEY_RIGHT: /* menu */ break; case NEWT_KEY_LEFT: { const void *top; if (pstack__empty(fstack)) continue; top = pstack__pop(fstack); if (top == &dso_filter) goto zoom_out_dso; if (top == &thread_filter) goto zoom_out_thread; continue; } case NEWT_KEY_ESCAPE: if (!ui__dialog_yesno("Do you really want to exit?")) continue; /* Fall thru */ default: goto out_free_stack; } if (browser->selection->sym != NULL && !browser->selection->map->dso->annotate_warned && asprintf(&options[nr_options], "Annotate %s", browser->selection->sym->name) > 0) annotate = nr_options++; if (thread != NULL && asprintf(&options[nr_options], "Zoom %s %s(%d) thread", (thread_filter ? "out of" : "into"), (thread->comm_set ? thread->comm : ""), thread->pid) > 0) zoom_thread = nr_options++; if (dso != NULL && asprintf(&options[nr_options], "Zoom %s %s DSO", (dso_filter ? "out of" : "into"), (dso->kernel ? "the Kernel" : dso->short_name)) > 0) zoom_dso = nr_options++; if (browser->selection->map != NULL && asprintf(&options[nr_options], "Browse map details") > 0) browse_map = nr_options++; options[nr_options++] = (char *)"Exit"; choice = ui__popup_menu(nr_options, options); for (i = 0; i < nr_options - 1; ++i) free(options[i]); if (choice == nr_options - 1) break; if (choice == -1) continue; if (choice == annotate) { struct hist_entry *he; do_annotate: if (browser->selection->map->dso->origin == DSO__ORIG_KERNEL) { browser->selection->map->dso->annotate_warned = 1; ui_helpline__puts("No vmlinux file found, can't " "annotate with just a " "kallsyms file"); continue; } he = hist_browser__selected_entry(browser); if (he == NULL) continue; hist_entry__tui_annotate(he); } else if (choice == browse_map) map__browse(browser->selection->map); else if (choice == zoom_dso) { zoom_dso: if (dso_filter) { pstack__remove(fstack, &dso_filter); zoom_out_dso: ui_helpline__pop(); dso_filter = NULL; } else { if (dso == NULL) continue; ui_helpline__fpush("To zoom out press <- or -> + \"Zoom out of %s DSO\"", dso->kernel ? "the Kernel" : dso->short_name); dso_filter = dso; pstack__push(fstack, &dso_filter); } hists__filter_by_dso(self, dso_filter); hists__browser_title(self, msg, sizeof(msg), ev_name, dso_filter, thread_filter); hist_browser__reset(browser); } else if (choice == zoom_thread) { zoom_thread: if (thread_filter) { pstack__remove(fstack, &thread_filter); zoom_out_thread: ui_helpline__pop(); thread_filter = NULL; } else { ui_helpline__fpush("To zoom out press <- or -> + \"Zoom out of %s(%d) thread\"", thread->comm_set ? thread->comm : "", thread->pid); thread_filter = thread; pstack__push(fstack, &thread_filter); } hists__filter_by_thread(self, thread_filter); hists__browser_title(self, msg, sizeof(msg), ev_name, dso_filter, thread_filter); hist_browser__reset(browser); } } out_free_stack: pstack__delete(fstack); out: hist_browser__delete(browser); return key; } int hists__tui_browse_tree(struct rb_root *self, const char *help) { struct rb_node *first = rb_first(self), *nd = first, *next; int key = 0; while (nd) { struct hists *hists = rb_entry(nd, struct hists, rb_node); const char *ev_name = __event_name(hists->type, hists->config); key = hists__browse(hists, help, ev_name); switch (key) { case NEWT_KEY_TAB: next = rb_next(nd); if (next) nd = next; break; case NEWT_KEY_UNTAB: if (nd == first) continue; nd = rb_prev(nd); default: return key; } } return key; }