Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Daniel Bristot de Oliveira | 6348 | 98.02% | 27 | 84.38% |
John Kacur | 120 | 1.85% | 3 | 9.38% |
Wan Jiabing | 7 | 0.11% | 1 | 3.12% |
Alexandre Vicenzi | 1 | 0.02% | 1 | 3.12% |
Total | 6476 | 32 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2021 Red Hat Inc, Daniel Bristot de Oliveira <bristot@kernel.org> */ #define _GNU_SOURCE #include <getopt.h> #include <stdlib.h> #include <string.h> #include <signal.h> #include <unistd.h> #include <stdio.h> #include <time.h> #include <sched.h> #include <pthread.h> #include "utils.h" #include "osnoise.h" #include "timerlat.h" #include "timerlat_aa.h" #include "timerlat_u.h" struct timerlat_hist_params { char *cpus; cpu_set_t monitored_cpus; char *trace_output; char *cgroup_name; unsigned long long runtime; long long stop_us; long long stop_total_us; long long timerlat_period_us; long long print_stack; int sleep_time; int output_divisor; int duration; int set_sched; int dma_latency; int cgroup; int hk_cpus; int no_aa; int dump_tasks; int user_workload; int kernel_workload; int user_hist; cpu_set_t hk_cpu_set; struct sched_attr sched_param; struct trace_events *events; char no_irq; char no_thread; char no_header; char no_summary; char no_index; char with_zeros; int bucket_size; int entries; int warmup; int buffer_size; }; struct timerlat_hist_cpu { int *irq; int *thread; int *user; int irq_count; int thread_count; int user_count; unsigned long long min_irq; unsigned long long sum_irq; unsigned long long max_irq; unsigned long long min_thread; unsigned long long sum_thread; unsigned long long max_thread; unsigned long long min_user; unsigned long long sum_user; unsigned long long max_user; }; struct timerlat_hist_data { struct timerlat_hist_cpu *hist; int entries; int bucket_size; int nr_cpus; }; /* * timerlat_free_histogram - free runtime data */ static void timerlat_free_histogram(struct timerlat_hist_data *data) { int cpu; /* one histogram for IRQ and one for thread, per CPU */ for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (data->hist[cpu].irq) free(data->hist[cpu].irq); if (data->hist[cpu].thread) free(data->hist[cpu].thread); if (data->hist[cpu].user) free(data->hist[cpu].user); } /* one set of histograms per CPU */ if (data->hist) free(data->hist); free(data); } /* * timerlat_alloc_histogram - alloc runtime data */ static struct timerlat_hist_data *timerlat_alloc_histogram(int nr_cpus, int entries, int bucket_size) { struct timerlat_hist_data *data; int cpu; data = calloc(1, sizeof(*data)); if (!data) return NULL; data->entries = entries; data->bucket_size = bucket_size; data->nr_cpus = nr_cpus; /* one set of histograms per CPU */ data->hist = calloc(1, sizeof(*data->hist) * nr_cpus); if (!data->hist) goto cleanup; /* one histogram for IRQ and one for thread, per cpu */ for (cpu = 0; cpu < nr_cpus; cpu++) { data->hist[cpu].irq = calloc(1, sizeof(*data->hist->irq) * (entries + 1)); if (!data->hist[cpu].irq) goto cleanup; data->hist[cpu].thread = calloc(1, sizeof(*data->hist->thread) * (entries + 1)); if (!data->hist[cpu].thread) goto cleanup; data->hist[cpu].user = calloc(1, sizeof(*data->hist->user) * (entries + 1)); if (!data->hist[cpu].user) goto cleanup; } /* set the min to max */ for (cpu = 0; cpu < nr_cpus; cpu++) { data->hist[cpu].min_irq = ~0; data->hist[cpu].min_thread = ~0; data->hist[cpu].min_user = ~0; } return data; cleanup: timerlat_free_histogram(data); return NULL; } /* * timerlat_hist_update - record a new timerlat occurent on cpu, updating data */ static void timerlat_hist_update(struct osnoise_tool *tool, int cpu, unsigned long long context, unsigned long long latency) { struct timerlat_hist_params *params = tool->params; struct timerlat_hist_data *data = tool->data; int entries = data->entries; int bucket; int *hist; if (params->output_divisor) latency = latency / params->output_divisor; bucket = latency / data->bucket_size; if (!context) { hist = data->hist[cpu].irq; data->hist[cpu].irq_count++; update_min(&data->hist[cpu].min_irq, &latency); update_sum(&data->hist[cpu].sum_irq, &latency); update_max(&data->hist[cpu].max_irq, &latency); } else if (context == 1) { hist = data->hist[cpu].thread; data->hist[cpu].thread_count++; update_min(&data->hist[cpu].min_thread, &latency); update_sum(&data->hist[cpu].sum_thread, &latency); update_max(&data->hist[cpu].max_thread, &latency); } else { /* user */ hist = data->hist[cpu].user; data->hist[cpu].user_count++; update_min(&data->hist[cpu].min_user, &latency); update_sum(&data->hist[cpu].sum_user, &latency); update_max(&data->hist[cpu].max_user, &latency); } if (bucket < entries) hist[bucket]++; else hist[entries]++; } /* * timerlat_hist_handler - this is the handler for timerlat tracer events */ static int timerlat_hist_handler(struct trace_seq *s, struct tep_record *record, struct tep_event *event, void *data) { struct trace_instance *trace = data; unsigned long long context, latency; struct osnoise_tool *tool; int cpu = record->cpu; tool = container_of(trace, struct osnoise_tool, trace); tep_get_field_val(s, event, "context", record, &context, 1); tep_get_field_val(s, event, "timer_latency", record, &latency, 1); timerlat_hist_update(tool, cpu, context, latency); return 0; } /* * timerlat_hist_header - print the header of the tracer to the output */ static void timerlat_hist_header(struct osnoise_tool *tool) { struct timerlat_hist_params *params = tool->params; struct timerlat_hist_data *data = tool->data; struct trace_seq *s = tool->trace.seq; char duration[26]; int cpu; if (params->no_header) return; get_duration(tool->start_time, duration, sizeof(duration)); trace_seq_printf(s, "# RTLA timerlat histogram\n"); trace_seq_printf(s, "# Time unit is %s (%s)\n", params->output_divisor == 1 ? "nanoseconds" : "microseconds", params->output_divisor == 1 ? "ns" : "us"); trace_seq_printf(s, "# Duration: %s\n", duration); if (!params->no_index) trace_seq_printf(s, "Index"); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) trace_seq_printf(s, " IRQ-%03d", cpu); if (!params->no_thread) trace_seq_printf(s, " Thr-%03d", cpu); if (params->user_hist) trace_seq_printf(s, " Usr-%03d", cpu); } trace_seq_printf(s, "\n"); trace_seq_do_printf(s); trace_seq_reset(s); } /* * timerlat_print_summary - print the summary of the hist data to the output */ static void timerlat_print_summary(struct timerlat_hist_params *params, struct trace_instance *trace, struct timerlat_hist_data *data) { int cpu; if (params->no_summary) return; if (!params->no_index) trace_seq_printf(trace->seq, "count:"); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].irq_count); if (!params->no_thread) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].thread_count); if (params->user_hist) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].user_count); } trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "min: "); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) { if (data->hist[cpu].irq_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].min_irq); else trace_seq_printf(trace->seq, " - "); } if (!params->no_thread) { if (data->hist[cpu].thread_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].min_thread); else trace_seq_printf(trace->seq, " - "); } if (params->user_hist) { if (data->hist[cpu].user_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].min_user); else trace_seq_printf(trace->seq, " - "); } } trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "avg: "); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) { if (data->hist[cpu].irq_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].sum_irq / data->hist[cpu].irq_count); else trace_seq_printf(trace->seq, " - "); } if (!params->no_thread) { if (data->hist[cpu].thread_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].sum_thread / data->hist[cpu].thread_count); else trace_seq_printf(trace->seq, " - "); } if (params->user_hist) { if (data->hist[cpu].user_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].sum_user / data->hist[cpu].user_count); else trace_seq_printf(trace->seq, " - "); } } trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "max: "); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) { if (data->hist[cpu].irq_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].max_irq); else trace_seq_printf(trace->seq, " - "); } if (!params->no_thread) { if (data->hist[cpu].thread_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].max_thread); else trace_seq_printf(trace->seq, " - "); } if (params->user_hist) { if (data->hist[cpu].user_count) trace_seq_printf(trace->seq, "%9llu ", data->hist[cpu].max_user); else trace_seq_printf(trace->seq, " - "); } } trace_seq_printf(trace->seq, "\n"); trace_seq_do_printf(trace->seq); trace_seq_reset(trace->seq); } static void timerlat_print_stats_all(struct timerlat_hist_params *params, struct trace_instance *trace, struct timerlat_hist_data *data) { struct timerlat_hist_cpu *cpu_data; struct timerlat_hist_cpu sum; int cpu; if (params->no_summary) return; memset(&sum, 0, sizeof(sum)); sum.min_irq = ~0; sum.min_thread = ~0; sum.min_user = ~0; for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; cpu_data = &data->hist[cpu]; sum.irq_count += cpu_data->irq_count; update_min(&sum.min_irq, &cpu_data->min_irq); update_sum(&sum.sum_irq, &cpu_data->sum_irq); update_max(&sum.max_irq, &cpu_data->max_irq); sum.thread_count += cpu_data->thread_count; update_min(&sum.min_thread, &cpu_data->min_thread); update_sum(&sum.sum_thread, &cpu_data->sum_thread); update_max(&sum.max_thread, &cpu_data->max_thread); sum.user_count += cpu_data->user_count; update_min(&sum.min_user, &cpu_data->min_user); update_sum(&sum.sum_user, &cpu_data->sum_user); update_max(&sum.max_user, &cpu_data->max_user); } if (!params->no_index) trace_seq_printf(trace->seq, "ALL: "); if (!params->no_irq) trace_seq_printf(trace->seq, " IRQ"); if (!params->no_thread) trace_seq_printf(trace->seq, " Thr"); if (params->user_hist) trace_seq_printf(trace->seq, " Usr"); trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "count:"); if (!params->no_irq) trace_seq_printf(trace->seq, "%9d ", sum.irq_count); if (!params->no_thread) trace_seq_printf(trace->seq, "%9d ", sum.thread_count); if (params->user_hist) trace_seq_printf(trace->seq, "%9d ", sum.user_count); trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "min: "); if (!params->no_irq) trace_seq_printf(trace->seq, "%9llu ", sum.min_irq); if (!params->no_thread) trace_seq_printf(trace->seq, "%9llu ", sum.min_thread); if (params->user_hist) trace_seq_printf(trace->seq, "%9llu ", sum.min_user); trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "avg: "); if (!params->no_irq) trace_seq_printf(trace->seq, "%9llu ", sum.sum_irq / sum.irq_count); if (!params->no_thread) trace_seq_printf(trace->seq, "%9llu ", sum.sum_thread / sum.thread_count); if (params->user_hist) trace_seq_printf(trace->seq, "%9llu ", sum.sum_user / sum.user_count); trace_seq_printf(trace->seq, "\n"); if (!params->no_index) trace_seq_printf(trace->seq, "max: "); if (!params->no_irq) trace_seq_printf(trace->seq, "%9llu ", sum.max_irq); if (!params->no_thread) trace_seq_printf(trace->seq, "%9llu ", sum.max_thread); if (params->user_hist) trace_seq_printf(trace->seq, "%9llu ", sum.max_user); trace_seq_printf(trace->seq, "\n"); trace_seq_do_printf(trace->seq); trace_seq_reset(trace->seq); } /* * timerlat_print_stats - print data for each CPUs */ static void timerlat_print_stats(struct timerlat_hist_params *params, struct osnoise_tool *tool) { struct timerlat_hist_data *data = tool->data; struct trace_instance *trace = &tool->trace; int bucket, cpu; int total; timerlat_hist_header(tool); for (bucket = 0; bucket < data->entries; bucket++) { total = 0; if (!params->no_index) trace_seq_printf(trace->seq, "%-6d", bucket * data->bucket_size); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) { total += data->hist[cpu].irq[bucket]; trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].irq[bucket]); } if (!params->no_thread) { total += data->hist[cpu].thread[bucket]; trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].thread[bucket]); } if (params->user_hist) { total += data->hist[cpu].user[bucket]; trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].user[bucket]); } } if (total == 0 && !params->with_zeros) { trace_seq_reset(trace->seq); continue; } trace_seq_printf(trace->seq, "\n"); trace_seq_do_printf(trace->seq); trace_seq_reset(trace->seq); } if (!params->no_index) trace_seq_printf(trace->seq, "over: "); for (cpu = 0; cpu < data->nr_cpus; cpu++) { if (params->cpus && !CPU_ISSET(cpu, ¶ms->monitored_cpus)) continue; if (!data->hist[cpu].irq_count && !data->hist[cpu].thread_count) continue; if (!params->no_irq) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].irq[data->entries]); if (!params->no_thread) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].thread[data->entries]); if (params->user_hist) trace_seq_printf(trace->seq, "%9d ", data->hist[cpu].user[data->entries]); } trace_seq_printf(trace->seq, "\n"); trace_seq_do_printf(trace->seq); trace_seq_reset(trace->seq); timerlat_print_summary(params, trace, data); timerlat_print_stats_all(params, trace, data); } /* * timerlat_hist_usage - prints timerlat top usage message */ static void timerlat_hist_usage(char *usage) { int i; char *msg[] = { "", " usage: [rtla] timerlat hist [-h] [-q] [-d s] [-D] [-n] [-a us] [-p us] [-i us] [-T us] [-s us] \\", " [-t[file]] [-e sys[:event]] [--filter <filter>] [--trigger <trigger>] [-c cpu-list] [-H cpu-list]\\", " [-P priority] [-E N] [-b N] [--no-irq] [--no-thread] [--no-header] [--no-summary] \\", " [--no-index] [--with-zeros] [--dma-latency us] [-C[=cgroup_name]] [--no-aa] [--dump-task] [-u|-k]", " [--warm-up s]", "", " -h/--help: print this menu", " -a/--auto: set automatic trace mode, stopping the session if argument in us latency is hit", " -p/--period us: timerlat period in us", " -i/--irq us: stop trace if the irq latency is higher than the argument in us", " -T/--thread us: stop trace if the thread latency is higher than the argument in us", " -s/--stack us: save the stack trace at the IRQ if a thread latency is higher than the argument in us", " -c/--cpus cpus: run the tracer only on the given cpus", " -H/--house-keeping cpus: run rtla control threads only on the given cpus", " -C/--cgroup[=cgroup_name]: set cgroup, if no cgroup_name is passed, the rtla's cgroup will be inherited", " -d/--duration time[m|h|d]: duration of the session in seconds", " --dump-tasks: prints the task running on all CPUs if stop conditions are met (depends on !--no-aa)", " -D/--debug: print debug info", " -t/--trace[file]: save the stopped trace to [file|timerlat_trace.txt]", " -e/--event <sys:event>: enable the <sys:event> in the trace instance, multiple -e are allowed", " --filter <filter>: enable a trace event filter to the previous -e event", " --trigger <trigger>: enable a trace event trigger to the previous -e event", " -n/--nano: display data in nanoseconds", " --no-aa: disable auto-analysis, reducing rtla timerlat cpu usage", " -b/--bucket-size N: set the histogram bucket size (default 1)", " -E/--entries N: set the number of entries of the histogram (default 256)", " --no-irq: ignore IRQ latencies", " --no-thread: ignore thread latencies", " --no-header: do not print header", " --no-summary: do not print summary", " --no-index: do not print index", " --with-zeros: print zero only entries", " --dma-latency us: set /dev/cpu_dma_latency latency <us> to reduce exit from idle latency", " -P/--priority o:prio|r:prio|f:prio|d:runtime:period : set scheduling parameters", " o:prio - use SCHED_OTHER with prio", " r:prio - use SCHED_RR with prio", " f:prio - use SCHED_FIFO with prio", " d:runtime[us|ms|s]:period[us|ms|s] - use SCHED_DEADLINE with runtime and period", " in nanoseconds", " -u/--user-threads: use rtla user-space threads instead of kernel-space timerlat threads", " -k/--kernel-threads: use timerlat kernel-space threads instead of rtla user-space threads", " -U/--user-load: enable timerlat for user-defined user-space workload", " --warm-up s: let the workload run for s seconds before collecting data", " --trace-buffer-size kB: set the per-cpu trace buffer size in kB", NULL, }; if (usage) fprintf(stderr, "%s\n", usage); fprintf(stderr, "rtla timerlat hist: a per-cpu histogram of the timer latency (version %s)\n", VERSION); for (i = 0; msg[i]; i++) fprintf(stderr, "%s\n", msg[i]); if (usage) exit(EXIT_FAILURE); exit(EXIT_SUCCESS); } /* * timerlat_hist_parse_args - allocs, parse and fill the cmd line parameters */ static struct timerlat_hist_params *timerlat_hist_parse_args(int argc, char *argv[]) { struct timerlat_hist_params *params; struct trace_events *tevent; int auto_thresh; int retval; int c; params = calloc(1, sizeof(*params)); if (!params) exit(1); /* disabled by default */ params->dma_latency = -1; /* display data in microseconds */ params->output_divisor = 1000; params->bucket_size = 1; params->entries = 256; while (1) { static struct option long_options[] = { {"auto", required_argument, 0, 'a'}, {"cpus", required_argument, 0, 'c'}, {"cgroup", optional_argument, 0, 'C'}, {"bucket-size", required_argument, 0, 'b'}, {"debug", no_argument, 0, 'D'}, {"entries", required_argument, 0, 'E'}, {"duration", required_argument, 0, 'd'}, {"house-keeping", required_argument, 0, 'H'}, {"help", no_argument, 0, 'h'}, {"irq", required_argument, 0, 'i'}, {"nano", no_argument, 0, 'n'}, {"period", required_argument, 0, 'p'}, {"priority", required_argument, 0, 'P'}, {"stack", required_argument, 0, 's'}, {"thread", required_argument, 0, 'T'}, {"trace", optional_argument, 0, 't'}, {"user-threads", no_argument, 0, 'u'}, {"kernel-threads", no_argument, 0, 'k'}, {"user-load", no_argument, 0, 'U'}, {"event", required_argument, 0, 'e'}, {"no-irq", no_argument, 0, '0'}, {"no-thread", no_argument, 0, '1'}, {"no-header", no_argument, 0, '2'}, {"no-summary", no_argument, 0, '3'}, {"no-index", no_argument, 0, '4'}, {"with-zeros", no_argument, 0, '5'}, {"trigger", required_argument, 0, '6'}, {"filter", required_argument, 0, '7'}, {"dma-latency", required_argument, 0, '8'}, {"no-aa", no_argument, 0, '9'}, {"dump-task", no_argument, 0, '\1'}, {"warm-up", required_argument, 0, '\2'}, {"trace-buffer-size", required_argument, 0, '\3'}, {0, 0, 0, 0} }; /* getopt_long stores the option index here. */ int option_index = 0; c = getopt_long(argc, argv, "a:c:C::b:d:e:E:DhH:i:knp:P:s:t::T:uU0123456:7:8:9\1\2:\3", long_options, &option_index); /* detect the end of the options. */ if (c == -1) break; switch (c) { case 'a': auto_thresh = get_llong_from_str(optarg); /* set thread stop to auto_thresh */ params->stop_total_us = auto_thresh; params->stop_us = auto_thresh; /* get stack trace */ params->print_stack = auto_thresh; /* set trace */ params->trace_output = "timerlat_trace.txt"; break; case 'c': retval = parse_cpu_set(optarg, ¶ms->monitored_cpus); if (retval) timerlat_hist_usage("\nInvalid -c cpu list\n"); params->cpus = optarg; break; case 'C': params->cgroup = 1; if (!optarg) { /* will inherit this cgroup */ params->cgroup_name = NULL; } else if (*optarg == '=') { /* skip the = */ params->cgroup_name = ++optarg; } break; case 'b': params->bucket_size = get_llong_from_str(optarg); if ((params->bucket_size == 0) || (params->bucket_size >= 1000000)) timerlat_hist_usage("Bucket size needs to be > 0 and <= 1000000\n"); break; case 'D': config_debug = 1; break; case 'd': params->duration = parse_seconds_duration(optarg); if (!params->duration) timerlat_hist_usage("Invalid -D duration\n"); break; case 'e': tevent = trace_event_alloc(optarg); if (!tevent) { err_msg("Error alloc trace event"); exit(EXIT_FAILURE); } if (params->events) tevent->next = params->events; params->events = tevent; break; case 'E': params->entries = get_llong_from_str(optarg); if ((params->entries < 10) || (params->entries > 9999999)) timerlat_hist_usage("Entries must be > 10 and < 9999999\n"); break; case 'h': case '?': timerlat_hist_usage(NULL); break; case 'H': params->hk_cpus = 1; retval = parse_cpu_set(optarg, ¶ms->hk_cpu_set); if (retval) { err_msg("Error parsing house keeping CPUs\n"); exit(EXIT_FAILURE); } break; case 'i': params->stop_us = get_llong_from_str(optarg); break; case 'k': params->kernel_workload = 1; break; case 'n': params->output_divisor = 1; break; case 'p': params->timerlat_period_us = get_llong_from_str(optarg); if (params->timerlat_period_us > 1000000) timerlat_hist_usage("Period longer than 1 s\n"); break; case 'P': retval = parse_prio(optarg, ¶ms->sched_param); if (retval == -1) timerlat_hist_usage("Invalid -P priority"); params->set_sched = 1; break; case 's': params->print_stack = get_llong_from_str(optarg); break; case 'T': params->stop_total_us = get_llong_from_str(optarg); break; case 't': if (optarg) { if (optarg[0] == '=') params->trace_output = &optarg[1]; else params->trace_output = &optarg[0]; } else if (optind < argc && argv[optind][0] != '-') params->trace_output = argv[optind]; else params->trace_output = "timerlat_trace.txt"; break; case 'u': params->user_workload = 1; /* fallback: -u implies in -U */ case 'U': params->user_hist = 1; break; case '0': /* no irq */ params->no_irq = 1; break; case '1': /* no thread */ params->no_thread = 1; break; case '2': /* no header */ params->no_header = 1; break; case '3': /* no summary */ params->no_summary = 1; break; case '4': /* no index */ params->no_index = 1; break; case '5': /* with zeros */ params->with_zeros = 1; break; case '6': /* trigger */ if (params->events) { retval = trace_event_add_trigger(params->events, optarg); if (retval) { err_msg("Error adding trigger %s\n", optarg); exit(EXIT_FAILURE); } } else { timerlat_hist_usage("--trigger requires a previous -e\n"); } break; case '7': /* filter */ if (params->events) { retval = trace_event_add_filter(params->events, optarg); if (retval) { err_msg("Error adding filter %s\n", optarg); exit(EXIT_FAILURE); } } else { timerlat_hist_usage("--filter requires a previous -e\n"); } break; case '8': params->dma_latency = get_llong_from_str(optarg); if (params->dma_latency < 0 || params->dma_latency > 10000) { err_msg("--dma-latency needs to be >= 0 and < 10000"); exit(EXIT_FAILURE); } break; case '9': params->no_aa = 1; break; case '\1': params->dump_tasks = 1; break; case '\2': params->warmup = get_llong_from_str(optarg); break; case '\3': params->buffer_size = get_llong_from_str(optarg); break; default: timerlat_hist_usage("Invalid option"); } } if (geteuid()) { err_msg("rtla needs root permission\n"); exit(EXIT_FAILURE); } if (params->no_irq && params->no_thread) timerlat_hist_usage("no-irq and no-thread set, there is nothing to do here"); if (params->no_index && !params->with_zeros) timerlat_hist_usage("no-index set with with-zeros is not set - it does not make sense"); /* * Auto analysis only happens if stop tracing, thus: */ if (!params->stop_us && !params->stop_total_us) params->no_aa = 1; if (params->kernel_workload && params->user_workload) timerlat_hist_usage("--kernel-threads and --user-threads are mutually exclusive!"); return params; } /* * timerlat_hist_apply_config - apply the hist configs to the initialized tool */ static int timerlat_hist_apply_config(struct osnoise_tool *tool, struct timerlat_hist_params *params) { int retval, i; if (!params->sleep_time) params->sleep_time = 1; if (params->cpus) { retval = osnoise_set_cpus(tool->context, params->cpus); if (retval) { err_msg("Failed to apply CPUs config\n"); goto out_err; } } else { for (i = 0; i < sysconf(_SC_NPROCESSORS_CONF); i++) CPU_SET(i, ¶ms->monitored_cpus); } if (params->stop_us) { retval = osnoise_set_stop_us(tool->context, params->stop_us); if (retval) { err_msg("Failed to set stop us\n"); goto out_err; } } if (params->stop_total_us) { retval = osnoise_set_stop_total_us(tool->context, params->stop_total_us); if (retval) { err_msg("Failed to set stop total us\n"); goto out_err; } } if (params->timerlat_period_us) { retval = osnoise_set_timerlat_period_us(tool->context, params->timerlat_period_us); if (retval) { err_msg("Failed to set timerlat period\n"); goto out_err; } } if (params->print_stack) { retval = osnoise_set_print_stack(tool->context, params->print_stack); if (retval) { err_msg("Failed to set print stack\n"); goto out_err; } } if (params->hk_cpus) { retval = sched_setaffinity(getpid(), sizeof(params->hk_cpu_set), ¶ms->hk_cpu_set); if (retval == -1) { err_msg("Failed to set rtla to the house keeping CPUs\n"); goto out_err; } } else if (params->cpus) { /* * Even if the user do not set a house-keeping CPU, try to * move rtla to a CPU set different to the one where the user * set the workload to run. * * No need to check results as this is an automatic attempt. */ auto_house_keeping(¶ms->monitored_cpus); } /* * If the user did not specify a type of thread, try user-threads first. * Fall back to kernel threads otherwise. */ if (!params->kernel_workload && !params->user_workload) { retval = tracefs_file_exists(NULL, "osnoise/per_cpu/cpu0/timerlat_fd"); if (retval) { debug_msg("User-space interface detected, setting user-threads\n"); params->user_workload = 1; params->user_hist = 1; } else { debug_msg("User-space interface not detected, setting kernel-threads\n"); params->kernel_workload = 1; } } if (params->user_hist) { retval = osnoise_set_workload(tool->context, 0); if (retval) { err_msg("Failed to set OSNOISE_WORKLOAD option\n"); goto out_err; } } return 0; out_err: return -1; } /* * timerlat_init_hist - initialize a timerlat hist tool with parameters */ static struct osnoise_tool *timerlat_init_hist(struct timerlat_hist_params *params) { struct osnoise_tool *tool; int nr_cpus; nr_cpus = sysconf(_SC_NPROCESSORS_CONF); tool = osnoise_init_tool("timerlat_hist"); if (!tool) return NULL; tool->data = timerlat_alloc_histogram(nr_cpus, params->entries, params->bucket_size); if (!tool->data) goto out_err; tool->params = params; tep_register_event_handler(tool->trace.tep, -1, "ftrace", "timerlat", timerlat_hist_handler, tool); return tool; out_err: osnoise_destroy_tool(tool); return NULL; } static int stop_tracing; static void stop_hist(int sig) { stop_tracing = 1; } /* * timerlat_hist_set_signals - handles the signal to stop the tool */ static void timerlat_hist_set_signals(struct timerlat_hist_params *params) { signal(SIGINT, stop_hist); if (params->duration) { signal(SIGALRM, stop_hist); alarm(params->duration); } } int timerlat_hist_main(int argc, char *argv[]) { struct timerlat_hist_params *params; struct osnoise_tool *record = NULL; struct timerlat_u_params params_u; struct osnoise_tool *tool = NULL; struct osnoise_tool *aa = NULL; struct trace_instance *trace; int dma_latency_fd = -1; int return_value = 1; pthread_t timerlat_u; int retval; params = timerlat_hist_parse_args(argc, argv); if (!params) exit(1); tool = timerlat_init_hist(params); if (!tool) { err_msg("Could not init osnoise hist\n"); goto out_exit; } retval = timerlat_hist_apply_config(tool, params); if (retval) { err_msg("Could not apply config\n"); goto out_free; } trace = &tool->trace; retval = enable_timerlat(trace); if (retval) { err_msg("Failed to enable timerlat tracer\n"); goto out_free; } if (params->set_sched) { retval = set_comm_sched_attr("timerlat/", ¶ms->sched_param); if (retval) { err_msg("Failed to set sched parameters\n"); goto out_free; } } if (params->cgroup && !params->user_workload) { retval = set_comm_cgroup("timerlat/", params->cgroup_name); if (!retval) { err_msg("Failed to move threads to cgroup\n"); goto out_free; } } if (params->dma_latency >= 0) { dma_latency_fd = set_cpu_dma_latency(params->dma_latency); if (dma_latency_fd < 0) { err_msg("Could not set /dev/cpu_dma_latency.\n"); goto out_free; } } if (params->trace_output) { record = osnoise_init_trace_tool("timerlat"); if (!record) { err_msg("Failed to enable the trace instance\n"); goto out_free; } if (params->events) { retval = trace_events_enable(&record->trace, params->events); if (retval) goto out_hist; } if (params->buffer_size > 0) { retval = trace_set_buffer_size(&record->trace, params->buffer_size); if (retval) goto out_hist; } } if (!params->no_aa) { aa = osnoise_init_tool("timerlat_aa"); if (!aa) goto out_hist; retval = timerlat_aa_init(aa, params->dump_tasks); if (retval) { err_msg("Failed to enable the auto analysis instance\n"); goto out_hist; } retval = enable_timerlat(&aa->trace); if (retval) { err_msg("Failed to enable timerlat tracer\n"); goto out_hist; } } if (params->user_workload) { /* rtla asked to stop */ params_u.should_run = 1; /* all threads left */ params_u.stopped_running = 0; params_u.set = ¶ms->monitored_cpus; if (params->set_sched) params_u.sched_param = ¶ms->sched_param; else params_u.sched_param = NULL; params_u.cgroup_name = params->cgroup_name; retval = pthread_create(&timerlat_u, NULL, timerlat_u_dispatcher, ¶ms_u); if (retval) err_msg("Error creating timerlat user-space threads\n"); } if (params->warmup > 0) { debug_msg("Warming up for %d seconds\n", params->warmup); sleep(params->warmup); if (stop_tracing) goto out_hist; } /* * Start the tracers here, after having set all instances. * * Let the trace instance start first for the case of hitting a stop * tracing while enabling other instances. The trace instance is the * one with most valuable information. */ if (params->trace_output) trace_instance_start(&record->trace); if (!params->no_aa) trace_instance_start(&aa->trace); trace_instance_start(trace); tool->start_time = time(NULL); timerlat_hist_set_signals(params); while (!stop_tracing) { sleep(params->sleep_time); retval = tracefs_iterate_raw_events(trace->tep, trace->inst, NULL, 0, collect_registered_events, trace); if (retval < 0) { err_msg("Error iterating on events\n"); goto out_hist; } if (trace_is_off(&tool->trace, &record->trace)) break; /* is there still any user-threads ? */ if (params->user_workload) { if (params_u.stopped_running) { debug_msg("timerlat user-space threads stopped!\n"); break; } } } if (params->user_workload && !params_u.stopped_running) { params_u.should_run = 0; sleep(1); } timerlat_print_stats(params, tool); return_value = 0; if (trace_is_off(&tool->trace, &record->trace)) { printf("rtla timerlat hit stop tracing\n"); if (!params->no_aa) timerlat_auto_analysis(params->stop_us, params->stop_total_us); if (params->trace_output) { printf(" Saving trace to %s\n", params->trace_output); save_trace_to_file(record->trace.inst, params->trace_output); } } out_hist: timerlat_aa_destroy(); if (dma_latency_fd >= 0) close(dma_latency_fd); trace_events_destroy(&record->trace, params->events); params->events = NULL; out_free: timerlat_free_histogram(tool->data); osnoise_destroy_tool(aa); osnoise_destroy_tool(record); osnoise_destroy_tool(tool); free(params); out_exit: exit(return_value); }
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