// vim:ts=4:sw=4:expandtab #include #include #include #include #include #include #include #if defined(__FreeBSD__) || defined(__OpenBSD__) #include #include #include #if defined(__OpenBSD__) #include #else #include #endif #endif #if defined(__DragonFly__) #include #include #include #include #endif #if defined(__NetBSD__) #include #include #include #include #endif #include "i3status.h" struct cpu_usage { int user; int nice; int system; int idle; int total; }; static int cpu_count = 0; static struct cpu_usage prev_all = {0, 0, 0, 0, 0}; static struct cpu_usage *prev_cpus = NULL; static struct cpu_usage *curr_cpus = NULL; /* * Reads the CPU utilization from /proc/stat and returns the usage as a * percentage. * */ void print_cpu_usage(yajl_gen json_gen, char *buffer, const char *format, const char *format_above_threshold, const char *format_above_degraded_threshold, const char *path, const float max_threshold, const float degraded_threshold) { const char *selected_format = format; const char *walk; char *outwalk = buffer; struct cpu_usage curr_all = {0, 0, 0, 0, 0}; int diff_idle, diff_total, diff_usage; bool colorful_output = false; #if defined(LINUX) // Detecting if CPU count has changed int curr_cpu_count = get_nprocs_conf(); if (curr_cpu_count != cpu_count) { cpu_count = curr_cpu_count; free(prev_cpus); prev_cpus = (struct cpu_usage *)calloc(cpu_count, sizeof(struct cpu_usage)); free(curr_cpus); curr_cpus = (struct cpu_usage *)calloc(cpu_count, sizeof(struct cpu_usage)); } memcpy(curr_cpus, prev_cpus, cpu_count * sizeof(struct cpu_usage)); char buf[4096]; curr_cpu_count = get_nprocs(); if (!slurp(path, buf, sizeof(buf))) goto error; // Parsing all cpu values using strtok if (strtok(buf, "\n") == NULL) goto error; char *buf_itr = NULL; for (int idx = 0; idx < curr_cpu_count; ++idx) { buf_itr = strtok(NULL, "\n"); int cpu_idx, user, nice, system, idle; if (!buf_itr || sscanf(buf_itr, "cpu%d %d %d %d %d", &cpu_idx, &user, &nice, &system, &idle) != 5) { goto error; } if (cpu_idx < 0 || cpu_idx >= cpu_count) goto error; curr_cpus[cpu_idx].user = user; curr_cpus[cpu_idx].nice = nice; curr_cpus[cpu_idx].system = system; curr_cpus[cpu_idx].idle = idle; curr_cpus[cpu_idx].total = user + nice + system + idle; } for (int cpu_idx = 0; cpu_idx < cpu_count; cpu_idx++) { curr_all.user += curr_cpus[cpu_idx].user; curr_all.nice += curr_cpus[cpu_idx].nice; curr_all.system += curr_cpus[cpu_idx].system; curr_all.idle += curr_cpus[cpu_idx].idle; curr_all.total += curr_cpus[cpu_idx].total; } diff_idle = curr_all.idle - prev_all.idle; diff_total = curr_all.total - prev_all.total; diff_usage = (diff_total ? (1000 * (diff_total - diff_idle) / diff_total + 5) / 10 : 0); prev_all = curr_all; #elif defined(__FreeBSD__) || defined(__NetBSD__) || defined(__OpenBSD__) || defined(__DragonFly__) #if defined(__FreeBSD__) || defined(__DragonFly__) || defined(__NetBSD__) size_t size; long cp_time[CPUSTATES]; size = sizeof cp_time; if (sysctlbyname("kern.cp_time", &cp_time, &size, NULL, 0) < 0) goto error; #else /* This information is taken from the boot cpu, any other cpus are currently ignored. */ long cp_time[CPUSTATES]; int mib[2]; size_t size = sizeof(cp_time); mib[0] = CTL_KERN; mib[1] = KERN_CPTIME; if (sysctl(mib, 2, cp_time, &size, NULL, 0)) goto error; #endif curr_all.user = cp_time[CP_USER]; curr_all.nice = cp_time[CP_NICE]; curr_all.system = cp_time[CP_SYS]; curr_all.idle = cp_time[CP_IDLE]; curr_all.total = curr_all.user + curr_all.nice + curr_all.system + curr_all.idle; diff_idle = curr_all.idle - prev_all.idle; diff_total = curr_all.total - prev_all.total; diff_usage = (diff_total ? (1000 * (diff_total - diff_idle) / diff_total + 5) / 10 : 0); prev_all = curr_all; #else goto error; #endif if (diff_usage >= max_threshold) { START_COLOR("color_bad"); colorful_output = true; if (format_above_threshold != NULL) selected_format = format_above_threshold; } else if (diff_usage >= degraded_threshold) { START_COLOR("color_degraded"); colorful_output = true; if (format_above_degraded_threshold != NULL) selected_format = format_above_degraded_threshold; } for (walk = selected_format; *walk != '\0'; walk++) { if (*walk != '%') { *(outwalk++) = *walk; } else if (BEGINS_WITH(walk + 1, "usage")) { outwalk += sprintf(outwalk, "%02d%s", diff_usage, pct_mark); walk += strlen("usage"); } #if defined(LINUX) else if (BEGINS_WITH(walk + 1, "cpu")) { int number = -1; sscanf(walk + 1, "cpu%d", &number); if (number < 0 || number >= cpu_count) { fprintf(stderr, "provided CPU number '%d' above detected number of CPU %d\n", number, cpu_count); } else { int cpu_diff_idle = curr_cpus[number].idle - prev_cpus[number].idle; int cpu_diff_total = curr_cpus[number].total - prev_cpus[number].total; int cpu_diff_usage = (cpu_diff_total ? (1000 * (cpu_diff_total - cpu_diff_idle) / cpu_diff_total + 5) / 10 : 0); outwalk += sprintf(outwalk, "%02d%s", cpu_diff_usage, pct_mark); } int padding = 1; int step = 10; while (step <= number) { step *= 10; padding++; } walk += strlen("cpu") + padding; } #endif else { *(outwalk++) = '%'; } } struct cpu_usage *temp_cpus = prev_cpus; prev_cpus = curr_cpus; curr_cpus = temp_cpus; if (colorful_output) END_COLOR; OUTPUT_FULL_TEXT(buffer); return; error: OUTPUT_FULL_TEXT("cant read cpu usage"); (void)fputs("i3status: Cannot read CPU usage\n", stderr); }