/* * Copyright © 2016 Rob Clark * All Rights Reserved. * SPDX-License-Identifier: MIT */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include "drm/freedreno_drmif.h" #include "drm/freedreno_ringbuffer.h" #include "util/os_file.h" #include "freedreno_dt.h" #include "freedreno_perfcntr.h" #define MAX_CNTR_PER_GROUP 24 #define REFRESH_MS 500 static struct { int refresh_ms; bool dump; } options = { .refresh_ms = REFRESH_MS, .dump = false, }; /* NOTE first counter group should always be CP, since we unconditionally * use CP counter to measure the gpu freq. */ struct counter_group { const struct fd_perfcntr_group *group; struct { const struct fd_perfcntr_counter *counter; uint16_t select_val; bool is_gpufreq_counter; } counter[MAX_CNTR_PER_GROUP]; /* name of currently selected counters (for UI): */ const char *label[MAX_CNTR_PER_GROUP]; uint64_t value[MAX_CNTR_PER_GROUP]; uint64_t value_delta[MAX_CNTR_PER_GROUP]; uint64_t sample_time[MAX_CNTR_PER_GROUP]; uint64_t sample_time_delta[MAX_CNTR_PER_GROUP]; }; static struct { void *io; uint32_t min_freq; uint32_t max_freq; /* per-generation table of counters: */ unsigned ngroups; struct counter_group *groups; /* drm device (for writing select regs via ring): */ struct fd_device *dev; struct fd_pipe *pipe; const struct fd_dev_id *dev_id; struct fd_submit *submit; struct fd_ringbuffer *ring; } dev; static void config_save(void); static void config_restore(void); static void restore_counter_groups(void); /* * helpers */ static uint64_t gettime_us(void) { struct timespec ts; clock_gettime(CLOCK_MONOTONIC, &ts); return (ts.tv_sec * 1000000) + (ts.tv_nsec / 1000); } static void sleep_us(uint32_t us) { const struct timespec ts = { .tv_sec = us / 1000000, .tv_nsec = (us % 1000000) * 1000, }; clock_nanosleep(CLOCK_MONOTONIC, 0, &ts, NULL); } static uint64_t delta(uint64_t a, uint64_t b) { /* deal with rollover: */ if (a > b) return 0xffffffffffffffffull - a + b; else return b - a; } static void find_device(void) { int ret; dev.dev = fd_device_open(); if (!dev.dev) err(1, "could not open drm device"); dev.pipe = fd_pipe_new(dev.dev, FD_PIPE_3D); dev.dev_id = fd_pipe_dev_id(dev.pipe); if (!fd_dev_info_raw(dev.dev_id)) err(1, "unknown device"); printf("device: %s\n", fd_dev_name(dev.dev_id)); /* try MAX_FREQ first as that will work regardless of old dt * dt bindings vs upstream bindings: */ uint64_t val; ret = fd_pipe_get_param(dev.pipe, FD_MAX_FREQ, &val); if (ret) { printf("falling back to parsing DT bindings for freq\n"); if (!fd_dt_find_freqs(&dev.min_freq, &dev.max_freq)) err(1, "could not find GPU freqs"); } else { dev.min_freq = 0; dev.max_freq = val; } printf("min_freq=%u, max_freq=%u\n", dev.min_freq, dev.max_freq); dev.io = fd_dt_find_io(); if (!dev.io) { err(1, "could not map device"); } fd_pipe_set_param(dev.pipe, FD_SYSPROF, 1); } /* * perf-monitor */ static void flush_ring(void) { if (!dev.submit) return; struct fd_fence *fence = fd_submit_flush(dev.submit, -1, false); if (!fence) errx(1, "submit failed"); fd_fence_flush(fence); fd_fence_del(fence); fd_ringbuffer_del(dev.ring); fd_submit_del(dev.submit); dev.ring = NULL; dev.submit = NULL; } static void select_counter(struct counter_group *group, int ctr, int countable_val) { assert(ctr < group->group->num_counters); unsigned countable_idx = UINT32_MAX; for (unsigned i = 0; i < group->group->num_countables; i++) { if (countable_val != group->group->countables[i].selector) continue; countable_idx = i; break; } if (countable_idx >= group->group->num_countables) return; group->label[ctr] = group->group->countables[countable_idx].name; group->counter[ctr].select_val = countable_val; if (!dev.submit) { dev.submit = fd_submit_new(dev.pipe); dev.ring = fd_submit_new_ringbuffer( dev.submit, 0x1000, FD_RINGBUFFER_PRIMARY | FD_RINGBUFFER_GROWABLE); } /* bashing select register directly while gpu is active will end * in tears.. so we need to write it via the ring: * * TODO it would help startup time, if gpu is loaded, to batch * all the initial writes and do a single flush.. although that * makes things more complicated for capturing inital sample value */ struct fd_ringbuffer *ring = dev.ring; switch (fd_dev_gen(dev.dev_id)) { case 2: case 3: case 4: OUT_PKT3(ring, CP_WAIT_FOR_IDLE, 1); OUT_RING(ring, 0x00000000); if (group->group->counters[ctr].enable) { OUT_PKT0(ring, group->group->counters[ctr].enable, 1); OUT_RING(ring, 0); } if (group->group->counters[ctr].clear) { OUT_PKT0(ring, group->group->counters[ctr].clear, 1); OUT_RING(ring, 1); OUT_PKT0(ring, group->group->counters[ctr].clear, 1); OUT_RING(ring, 0); } OUT_PKT0(ring, group->group->counters[ctr].select_reg, 1); OUT_RING(ring, countable_val); if (group->group->counters[ctr].enable) { OUT_PKT0(ring, group->group->counters[ctr].enable, 1); OUT_RING(ring, 1); } break; case 5: case 6: case 7: OUT_PKT7(ring, CP_WAIT_FOR_IDLE, 0); if (group->group->counters[ctr].enable) { OUT_PKT4(ring, group->group->counters[ctr].enable, 1); OUT_RING(ring, 0); } if (group->group->counters[ctr].clear) { OUT_PKT4(ring, group->group->counters[ctr].clear, 1); OUT_RING(ring, 1); OUT_PKT4(ring, group->group->counters[ctr].clear, 1); OUT_RING(ring, 0); } OUT_PKT4(ring, group->group->counters[ctr].select_reg, 1); OUT_RING(ring, countable_val); if (group->group->counters[ctr].enable) { OUT_PKT4(ring, group->group->counters[ctr].enable, 1); OUT_RING(ring, 1); } break; } } static uint64_t load_counter_value(struct counter_group *group, int ctr) { /* We can read the counter register value as an uint64_t, as long as the * lo/hi addresses are neighboring and the lo address is 8-byte-aligned. * This currently holds for all counters exposed in perfcounter groups. */ const struct fd_perfcntr_counter *counter = group->counter[ctr].counter; assert(counter->counter_reg_lo + 1 == counter->counter_reg_hi); assert(!((counter->counter_reg_lo * 4) % 8)); return *((uint64_t *) (dev.io + counter->counter_reg_lo * 4)); } static void resample_counter(struct counter_group *group, int ctr, uint64_t sample_time) { uint64_t previous_value = group->value[ctr]; group->value[ctr] = load_counter_value(group, ctr); group->value_delta[ctr] = delta(previous_value, group->value[ctr]); uint64_t previous_sample_time = group->sample_time[ctr]; group->sample_time[ctr] = sample_time; group->sample_time_delta[ctr] = delta(previous_sample_time, sample_time); } /* sample all the counters: */ static void resample(void) { static uint64_t last_time; uint64_t current_time = gettime_us(); if ((current_time - last_time) < (options.refresh_ms * 1000 / 2)) return; last_time = current_time; for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; for (unsigned j = 0; j < group->group->num_counters; j++) { resample_counter(group, j, current_time); } } } /* * The UI */ #define COLOR_GROUP_HEADER 1 #define COLOR_FOOTER 2 #define COLOR_INVERSE 3 static int w, h; static int ctr_width; static int max_rows, current_cntr = 1; static void redraw_footer(WINDOW *win) { char footer[128]; int n = snprintf(footer, sizeof(footer), " fdperf: %s (%.2fMHz..%.2fMHz)", fd_dev_name(dev.dev_id), ((float)dev.min_freq) / 1000000.0, ((float)dev.max_freq) / 1000000.0); wmove(win, h - 1, 0); wattron(win, COLOR_PAIR(COLOR_FOOTER)); waddstr(win, footer); whline(win, ' ', w - n); wattroff(win, COLOR_PAIR(COLOR_FOOTER)); } static void redraw_group_header(WINDOW *win, int row, const char *name) { wmove(win, row, 0); wattron(win, A_BOLD); wattron(win, COLOR_PAIR(COLOR_GROUP_HEADER)); waddstr(win, name); whline(win, ' ', w - strlen(name)); wattroff(win, COLOR_PAIR(COLOR_GROUP_HEADER)); wattroff(win, A_BOLD); } static void redraw_counter_label(WINDOW *win, int row, const char *name, bool selected) { int n = strlen(name); assert(n <= ctr_width); wmove(win, row, 0); whline(win, ' ', ctr_width - n); wmove(win, row, ctr_width - n); if (selected) wattron(win, COLOR_PAIR(COLOR_INVERSE)); waddstr(win, name); if (selected) wattroff(win, COLOR_PAIR(COLOR_INVERSE)); waddstr(win, ": "); } static void redraw_counter_value_cycles(WINDOW *win, float val) { char str[32]; int x = getcurx(win); int valwidth = w - x; int barwidth, n; /* convert to fraction of max freq: */ val = val / (float)dev.max_freq; /* figure out percentage-bar width: */ barwidth = (int)(val * valwidth); /* sometimes things go over 100%.. idk why, could be * things running faster than base clock, or counter * summing up cycles in multiple cores? */ barwidth = MIN2(barwidth, valwidth - 1); n = snprintf(str, sizeof(str), "%.2f%%", 100.0 * val); wattron(win, COLOR_PAIR(COLOR_INVERSE)); waddnstr(win, str, barwidth); if (barwidth > n) { whline(win, ' ', barwidth - n); wmove(win, getcury(win), x + barwidth); } wattroff(win, COLOR_PAIR(COLOR_INVERSE)); if (barwidth < n) waddstr(win, str + barwidth); whline(win, ' ', w - getcurx(win)); } static void redraw_counter_value(WINDOW *win, int row, struct counter_group *group, int ctr) { char str[32]; int n = snprintf(str, sizeof(str), "%" PRIu64 " ", group->value_delta[ctr]); whline(win, ' ', 24 - n); wmove(win, row, getcurx(win) + 24 - n); waddstr(win, str); /* quick hack, if the label has "CYCLE" in the name, it is * probably a cycle counter ;-) * Perhaps add more info in rnndb schema to know how to * treat individual counters (ie. which are cycles, and * for those we want to present as a percentage do we * need to scale the result.. ie. is it running at some * multiple or divisor of core clk, etc) * * TODO it would be much more clever to get this from xml * Also.. in some cases I think we want to know how many * units the counter is counting for, ie. if a320 has 2x * shader as a306 we might need to scale the result.. */ if (strstr(group->label[ctr], "CYCLE") || strstr(group->label[ctr], "BUSY") || strstr(group->label[ctr], "IDLE")) { float cycles_val = (float) group->value_delta[ctr] * 1000000.0 / (float) group->sample_time_delta[ctr]; redraw_counter_value_cycles(win, cycles_val); } else { whline(win, ' ', w - getcurx(win)); } } static void redraw_counter(WINDOW *win, int row, struct counter_group *group, int ctr, bool selected) { redraw_counter_label(win, row, group->label[ctr], selected); redraw_counter_value(win, row, group, ctr); } static void redraw_gpufreq_counter(WINDOW *win, int row) { redraw_counter_label(win, row, "Freq (MHz)", false); struct counter_group *group = &dev.groups[0]; float freq_val = (float) group->value_delta[0] / (float) group->sample_time_delta[0]; char str[32]; snprintf(str, sizeof(str), "%.2f", freq_val); waddstr(win, str); whline(win, ' ', w - getcurx(win)); } static void redraw(WINDOW *win) { static int scroll = 0; int max, row = 0; w = getmaxx(win); h = getmaxy(win); max = h - 3; if ((current_cntr - scroll) > (max - 1)) { scroll = current_cntr - (max - 1); } else if ((current_cntr - 1) < scroll) { scroll = current_cntr - 1; } for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; unsigned j = 0; if (group->counter[0].is_gpufreq_counter) j++; if (j < group->group->num_counters) { if ((scroll <= row) && ((row - scroll) < max)) redraw_group_header(win, row - scroll, group->group->name); row++; } for (; j < group->group->num_counters; j++) { if ((scroll <= row) && ((row - scroll) < max)) redraw_counter(win, row - scroll, group, j, row == current_cntr); row++; } } /* convert back to physical (unscrolled) offset: */ row = max; redraw_group_header(win, row, "Status"); row++; /* Draw GPU freq row: */ redraw_gpufreq_counter(win, row); row++; redraw_footer(win); refresh(); } static struct counter_group * current_counter(int *ctr) { int n = 0; for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; unsigned j = 0; if (group->counter[0].is_gpufreq_counter) j++; /* account for group header: */ if (j < group->group->num_counters) { /* cannot select group header.. return null to indicate this * main_ui(): */ if (n == current_cntr) return NULL; n++; } for (; j < group->group->num_counters; j++) { if (n == current_cntr) { if (ctr) *ctr = j; return group; } n++; } } assert(0); return NULL; } static void counter_dialog(void) { WINDOW *dialog; struct counter_group *group; int cnt = 0, current = 0, scroll; /* figure out dialog size: */ int dh = h / 2; int dw = ctr_width + 2; group = current_counter(&cnt); /* find currently selected idx (note there can be discontinuities * so the selected value does not map 1:1 to current idx) */ uint32_t selected = group->counter[cnt].select_val; for (int i = 0; i < group->group->num_countables; i++) { if (group->group->countables[i].selector == selected) { current = i; break; } } /* scrolling offset, if dialog is too small for all the choices: */ scroll = 0; dialog = newwin(dh, dw, (h - dh) / 2, (w - dw) / 2); box(dialog, 0, 0); wrefresh(dialog); keypad(dialog, true); while (true) { int max = MIN2(dh - 2, group->group->num_countables); int selector = -1; if ((current - scroll) >= (dh - 3)) { scroll = current - (dh - 3); } else if (current < scroll) { scroll = current; } for (int i = 0; i < max; i++) { int n = scroll + i; wmove(dialog, i + 1, 1); if (n == current) { assert(n < group->group->num_countables); selector = group->group->countables[n].selector; wattron(dialog, COLOR_PAIR(COLOR_INVERSE)); } if (n < group->group->num_countables) waddstr(dialog, group->group->countables[n].name); whline(dialog, ' ', dw - getcurx(dialog) - 1); if (n == current) wattroff(dialog, COLOR_PAIR(COLOR_INVERSE)); } assert(selector >= 0); switch (wgetch(dialog)) { case KEY_UP: current = MAX2(0, current - 1); break; case KEY_DOWN: current = MIN2(group->group->num_countables - 1, current + 1); break; case KEY_LEFT: case KEY_ENTER: /* select new sampler */ select_counter(group, cnt, selector); flush_ring(); config_save(); goto out; case 'q': goto out; default: /* ignore */ break; } resample(); } out: wborder(dialog, ' ', ' ', ' ', ' ', ' ', ' ', ' ', ' '); delwin(dialog); } static void scroll_cntr(int amount) { if (amount < 0) { current_cntr = MAX2(1, current_cntr + amount); if (current_counter(NULL) == NULL) { current_cntr = MAX2(1, current_cntr - 1); } } else { current_cntr = MIN2(max_rows - 1, current_cntr + amount); if (current_counter(NULL) == NULL) current_cntr = MIN2(max_rows - 1, current_cntr + 1); } } static void main_ui(void) { WINDOW *mainwin; uint64_t last_time = gettime_us(); /* Run an initial sample to set up baseline counter values. */ resample(); /* curses setup: */ mainwin = initscr(); if (!mainwin) goto out; cbreak(); wtimeout(mainwin, options.refresh_ms); noecho(); keypad(mainwin, true); curs_set(0); start_color(); init_pair(COLOR_GROUP_HEADER, COLOR_WHITE, COLOR_GREEN); init_pair(COLOR_FOOTER, COLOR_WHITE, COLOR_BLUE); init_pair(COLOR_INVERSE, COLOR_BLACK, COLOR_WHITE); while (true) { switch (wgetch(mainwin)) { case KEY_UP: scroll_cntr(-1); break; case KEY_DOWN: scroll_cntr(+1); break; case KEY_NPAGE: /* page-down */ /* TODO figure out # of rows visible? */ scroll_cntr(+15); break; case KEY_PPAGE: /* page-up */ /* TODO figure out # of rows visible? */ scroll_cntr(-15); break; case KEY_RIGHT: counter_dialog(); break; case 'q': goto out; break; default: /* ignore */ break; } resample(); redraw(mainwin); /* restore the counters every 0.5s in case the GPU has suspended, * in which case the current selected countables will have reset: */ uint64_t t = gettime_us(); if (delta(last_time, t) > 500000) { restore_counter_groups(); flush_ring(); last_time = t; } } /* restore settings.. maybe we need an atexit()??*/ out: delwin(mainwin); endwin(); refresh(); } static void dump_counters(void) { resample(); sleep_us(options.refresh_ms * 1000); resample(); for (unsigned i = 0; i < dev.ngroups; i++) { const struct counter_group *group = &dev.groups[i]; for (unsigned j = 0; j < group->group->num_counters; j++) { const char *label = group->label[j]; float val = (float) group->value_delta[j] * 1000000.0 / (float) group->sample_time_delta[j]; int n = printf("%s: ", label) - 2; while (n++ < ctr_width) fputc(' ', stdout); n = printf("%" PRIu64, group->value_delta[j]); while (n++ < 24) fputc(' ', stdout); if (strstr(label, "CYCLE") || strstr(label, "BUSY") || strstr(label, "IDLE")) { val = val / dev.max_freq * 100.0f; printf(" %.2f%%\n", val); } else { printf("\n"); } } } } static void restore_counter_groups(void) { for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; for (unsigned j = 0; j < group->group->num_counters; j++) { /* This should also write the CP_ALWAYS_COUNT selectable value into * the reserved CP counter we use for GPU frequency measurement, * avoiding someone else writing a different value there. */ select_counter(group, j, group->counter[j].select_val); } } } static void setup_counter_groups(const struct fd_perfcntr_group *groups) { for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; group->group = &groups[i]; max_rows += group->group->num_counters + 1; /* We reserve the first counter of the CP group (first in the list) for * measuring GPU frequency that's displayed in the footer. */ if (i == 0) { /* We won't be displaying the private counter alongside others. We * also won't be displaying the group header if we're taking over * the only counter (e.g. on a2xx). */ max_rows--; if (groups[0].num_counters < 2) max_rows--; /* Enforce the CP_ALWAYS_COUNT countable for this counter. */ unsigned always_count_index = UINT32_MAX; for (unsigned i = 0; i < groups[0].num_countables; ++i) { if (strcmp(groups[0].countables[i].name, "PERF_CP_ALWAYS_COUNT")) continue; always_count_index = i; break; } if (always_count_index < groups[0].num_countables) { group->counter[0].select_val = groups[0].countables[always_count_index].selector; group->counter[0].is_gpufreq_counter = true; } } for (unsigned j = 0; j < group->group->num_counters; j++) { group->counter[j].counter = &group->group->counters[j]; if (!group->counter[j].is_gpufreq_counter) group->counter[j].select_val = j; } for (unsigned j = 0; j < group->group->num_countables; j++) { ctr_width = MAX2(ctr_width, strlen(group->group->countables[j].name) + 1); } } } /* * configuration / persistence */ static config_t cfg; static config_setting_t *setting; static void config_save(void) { for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; config_setting_t *sect = config_setting_get_member(setting, group->group->name); for (unsigned j = 0; j < group->group->num_counters; j++) { /* Don't save the GPU frequency measurement counter. */ if (group->counter[j].is_gpufreq_counter) continue; char name[] = "counter0000"; sprintf(name, "counter%d", j); config_setting_t *s = config_setting_lookup(sect, name); config_setting_set_int(s, group->counter[j].select_val); } } config_write_file(&cfg, "fdperf.cfg"); } static void config_restore(void) { config_init(&cfg); /* Read the file. If there is an error, report it and exit. */ if (!config_read_file(&cfg, "fdperf.cfg")) { warn("could not restore settings"); } config_setting_t *root = config_root_setting(&cfg); /* per device settings: */ char device_name[64]; snprintf(device_name, sizeof(device_name), "%s", fd_dev_name(dev.dev_id)); setting = config_setting_get_member(root, device_name); if (!setting) setting = config_setting_add(root, device_name, CONFIG_TYPE_GROUP); if (!setting) return; for (unsigned i = 0; i < dev.ngroups; i++) { struct counter_group *group = &dev.groups[i]; config_setting_t *sect = config_setting_get_member(setting, group->group->name); if (!sect) { sect = config_setting_add(setting, group->group->name, CONFIG_TYPE_GROUP); } for (unsigned j = 0; j < group->group->num_counters; j++) { /* Don't restore the GPU frequency measurement counter. */ if (group->counter[j].is_gpufreq_counter) continue; char name[] = "counter0000"; sprintf(name, "counter%d", j); config_setting_t *s = config_setting_lookup(sect, name); if (!s) { config_setting_add(sect, name, CONFIG_TYPE_INT); continue; } select_counter(group, j, config_setting_get_int(s)); } } } static void print_usage(const char *argv0) { fprintf(stderr, "Usage: %s [OPTION]...\n" "\n" " -r refresh every N milliseconds\n" " -d dump counters and exit\n" " -h show this message\n", argv0); exit(2); } static void parse_options(int argc, char **argv) { int c; while ((c = getopt(argc, argv, "r:d")) != -1) { switch (c) { case 'r': options.refresh_ms = atoi(optarg); break; case 'd': options.dump = true; break; default: print_usage(argv[0]); break; } } } /* * main */ int main(int argc, char **argv) { parse_options(argc, argv); find_device(); const struct fd_perfcntr_group *groups; groups = fd_perfcntrs(dev.dev_id, &dev.ngroups); if (!groups) { errx(1, "no perfcntr support"); } dev.groups = calloc(dev.ngroups, sizeof(struct counter_group)); setlocale(LC_NUMERIC, "en_US.UTF-8"); setup_counter_groups(groups); restore_counter_groups(); config_restore(); flush_ring(); if (options.dump) dump_counters(); else main_ui(); return 0; }