// SPDX-License-Identifier: GPL-2.0-only /* * (C) 2004-2009 Dominik Brodowski <linux@dominikbrodowski.de> */ #include <unistd.h> #include <stdio.h> #include <errno.h> #include <stdlib.h> #include <string.h> #include <limits.h> #include <getopt.h> #include "cpufreq.h" #include "helpers/sysfs.h" #include "helpers/helpers.h" #include "helpers/bitmask.h" #define LINE_LEN 10 static unsigned int count_cpus(void) { FILE *fp; char value[LINE_LEN]; unsigned int ret = 0; unsigned int cpunr = 0; fp = fopen("/proc/stat", "r"); if (!fp) { printf(_("Couldn't count the number of CPUs (%s: %s), assuming 1\n"), "/proc/stat", strerror(errno)); return 1; } while (!feof(fp)) { if (!fgets(value, LINE_LEN, fp)) continue; value[LINE_LEN - 1] = '\0'; if (strlen(value) < (LINE_LEN - 2)) continue; if (strstr(value, "cpu ")) continue; if (sscanf(value, "cpu%d ", &cpunr) != 1) continue; if (cpunr > ret) ret = cpunr; } fclose(fp); /* cpu count starts from 0, on error return 1 (UP) */ return ret + 1; } static void proc_cpufreq_output(void) { unsigned int cpu, nr_cpus; struct cpufreq_policy *policy; unsigned int min_pctg = 0; unsigned int max_pctg = 0; unsigned long min, max; printf(_(" minimum CPU frequency - maximum CPU frequency - governor\n")); nr_cpus = count_cpus(); for (cpu = 0; cpu < nr_cpus; cpu++) { policy = cpufreq_get_policy(cpu); if (!policy) continue; if (cpufreq_get_hardware_limits(cpu, &min, &max)) { max = 0; } else { min_pctg = (policy->min * 100) / max; max_pctg = (policy->max * 100) / max; } printf("CPU%3d %9lu kHz (%3d %%) - %9lu kHz (%3d %%) - %s\n", cpu , policy->min, max ? min_pctg : 0, policy->max, max ? max_pctg : 0, policy->governor); cpufreq_put_policy(policy); } } static int no_rounding; static void print_duration(unsigned long duration) { unsigned long tmp; if (no_rounding) { if (duration > 1000000) printf("%u.%06u ms", ((unsigned int) duration/1000000), ((unsigned int) duration%1000000)); else if (duration > 100000) printf("%u us", ((unsigned int) duration/1000)); else if (duration > 1000) printf("%u.%03u us", ((unsigned int) duration/1000), ((unsigned int) duration%1000)); else printf("%lu ns", duration); } else { if (duration > 1000000) { tmp = duration%10000; if (tmp >= 5000) duration += 10000; printf("%u.%02u ms", ((unsigned int) duration/1000000), ((unsigned int) (duration%1000000)/10000)); } else if (duration > 100000) { tmp = duration%1000; if (tmp >= 500) duration += 1000; printf("%u us", ((unsigned int) duration / 1000)); } else if (duration > 1000) { tmp = duration%100; if (tmp >= 50) duration += 100; printf("%u.%01u us", ((unsigned int) duration/1000), ((unsigned int) (duration%1000)/100)); } else printf("%lu ns", duration); } return; } static int get_boost_mode_x86(unsigned int cpu) { int support, active, b_states = 0, ret, pstate_no, i; /* ToDo: Make this more global */ unsigned long pstates[MAX_HW_PSTATES] = {0,}; ret = cpufreq_has_boost_support(cpu, &support, &active, &b_states); if (ret) { printf(_("Error while evaluating Boost Capabilities" " on CPU %d -- are you root?\n"), cpu); return ret; } /* P state changes via MSR are identified via cpuid 80000007 on Intel and AMD, but we assume boost capable machines can do that if (cpuid_eax(0x80000000) >= 0x80000007 && (cpuid_edx(0x80000007) & (1 << 7))) */ printf(_(" boost state support:\n")); printf(_(" Supported: %s\n"), support ? _("yes") : _("no")); printf(_(" Active: %s\n"), active ? _("yes") : _("no")); if (cpupower_cpu_info.vendor == X86_VENDOR_AMD && cpupower_cpu_info.caps & CPUPOWER_CAP_AMD_PSTATE) { return 0; } else if ((cpupower_cpu_info.vendor == X86_VENDOR_AMD && cpupower_cpu_info.family >= 0x10) || cpupower_cpu_info.vendor == X86_VENDOR_HYGON) { ret = decode_pstates(cpu, b_states, pstates, &pstate_no); if (ret) return ret; printf(_(" Boost States: %d\n"), b_states); printf(_(" Total States: %d\n"), pstate_no); for (i = 0; i < pstate_no; i++) { if (!pstates[i]) continue; if (i < b_states) printf(_(" Pstate-Pb%d: %luMHz (boost state)" "\n"), i, pstates[i]); else printf(_(" Pstate-P%d: %luMHz\n"), i - b_states, pstates[i]); } } else if (cpupower_cpu_info.caps & CPUPOWER_CAP_HAS_TURBO_RATIO) { double bclk; unsigned long long intel_turbo_ratio = 0; unsigned int ratio; /* Any way to autodetect this ? */ if (cpupower_cpu_info.caps & CPUPOWER_CAP_IS_SNB) bclk = 100.00; else bclk = 133.33; intel_turbo_ratio = msr_intel_get_turbo_ratio(cpu); dprint (" Ratio: 0x%llx - bclk: %f\n", intel_turbo_ratio, bclk); ratio = (intel_turbo_ratio >> 24) & 0xFF; if (ratio) printf(_(" %.0f MHz max turbo 4 active cores\n"), ratio * bclk); ratio = (intel_turbo_ratio >> 16) & 0xFF; if (ratio) printf(_(" %.0f MHz max turbo 3 active cores\n"), ratio * bclk); ratio = (intel_turbo_ratio >> 8) & 0xFF; if (ratio) printf(_(" %.0f MHz max turbo 2 active cores\n"), ratio * bclk); ratio = (intel_turbo_ratio >> 0) & 0xFF; if (ratio) printf(_(" %.0f MHz max turbo 1 active cores\n"), ratio * bclk); } return 0; } /* --boost / -b */ static int get_boost_mode(unsigned int cpu) { struct cpufreq_available_frequencies *freqs; if (cpupower_cpu_info.vendor == X86_VENDOR_AMD || cpupower_cpu_info.vendor == X86_VENDOR_HYGON || cpupower_cpu_info.vendor == X86_VENDOR_INTEL) return get_boost_mode_x86(cpu); freqs = cpufreq_get_boost_frequencies(cpu); if (freqs) { printf(_(" boost frequency steps: ")); while (freqs->next) { print_speed(freqs->frequency, no_rounding); printf(", "); freqs = freqs->next; } print_speed(freqs->frequency, no_rounding); printf("\n"); cpufreq_put_available_frequencies(freqs); } return 0; } /* --freq / -f */ static int get_freq_kernel(unsigned int cpu, unsigned int human) { unsigned long freq = cpufreq_get_freq_kernel(cpu); printf(_(" current CPU frequency: ")); if (!freq) { printf(_(" Unable to call to kernel\n")); return -EINVAL; } if (human) { print_speed(freq, no_rounding); } else printf("%lu", freq); printf(_(" (asserted by call to kernel)\n")); return 0; } /* --hwfreq / -w */ static int get_freq_hardware(unsigned int cpu, unsigned int human) { unsigned long freq = cpufreq_get_freq_hardware(cpu); printf(_(" current CPU frequency: ")); if (!freq) { printf("Unable to call hardware\n"); return -EINVAL; } if (human) { print_speed(freq, no_rounding); } else printf("%lu", freq); printf(_(" (asserted by call to hardware)\n")); return 0; } /* --hwlimits / -l */ static int get_hardware_limits(unsigned int cpu, unsigned int human) { unsigned long min, max; if (cpufreq_get_hardware_limits(cpu, &min, &max)) { printf(_("Not Available\n")); return -EINVAL; } if (human) { printf(_(" hardware limits: ")); print_speed(min, no_rounding); printf(" - "); print_speed(max, no_rounding); printf("\n"); } else { printf("%lu %lu\n", min, max); } return 0; } /* --driver / -d */ static int get_driver(unsigned int cpu) { char *driver = cpufreq_get_driver(cpu); if (!driver) { printf(_(" no or unknown cpufreq driver is active on this CPU\n")); return -EINVAL; } printf(" driver: %s\n", driver); cpufreq_put_driver(driver); return 0; } /* --policy / -p */ static int get_policy(unsigned int cpu) { struct cpufreq_policy *policy = cpufreq_get_policy(cpu); if (!policy) { printf(_(" Unable to determine current policy\n")); return -EINVAL; } printf(_(" current policy: frequency should be within ")); print_speed(policy->min, no_rounding); printf(_(" and ")); print_speed(policy->max, no_rounding); printf(".\n "); printf(_("The governor \"%s\" may decide which speed to use\n" " within this range.\n"), policy->governor); cpufreq_put_policy(policy); return 0; } /* --governors / -g */ static int get_available_governors(unsigned int cpu) { struct cpufreq_available_governors *governors = cpufreq_get_available_governors(cpu); printf(_(" available cpufreq governors: ")); if (!governors) { printf(_("Not Available\n")); return -EINVAL; } while (governors->next) { printf("%s ", governors->governor); governors = governors->next; } printf("%s\n", governors->governor); cpufreq_put_available_governors(governors); return 0; } /* --affected-cpus / -a */ static int get_affected_cpus(unsigned int cpu) { struct cpufreq_affected_cpus *cpus = cpufreq_get_affected_cpus(cpu); printf(_(" CPUs which need to have their frequency coordinated by software: ")); if (!cpus) { printf(_("Not Available\n")); return -EINVAL; } while (cpus->next) { printf("%d ", cpus->cpu); cpus = cpus->next; } printf("%d\n", cpus->cpu); cpufreq_put_affected_cpus(cpus); return 0; } /* --related-cpus / -r */ static int get_related_cpus(unsigned int cpu) { struct cpufreq_affected_cpus *cpus = cpufreq_get_related_cpus(cpu); printf(_(" CPUs which run at the same hardware frequency: ")); if (!cpus) { printf(_("Not Available\n")); return -EINVAL; } while (cpus->next) { printf("%d ", cpus->cpu); cpus = cpus->next; } printf("%d\n", cpus->cpu); cpufreq_put_related_cpus(cpus); return 0; } /* --stats / -s */ static int get_freq_stats(unsigned int cpu, unsigned int human) { unsigned long total_trans = cpufreq_get_transitions(cpu); unsigned long long total_time; struct cpufreq_stats *stats = cpufreq_get_stats(cpu, &total_time); while (stats) { if (human) { print_speed(stats->frequency, no_rounding); printf(":%.2f%%", (100.0 * stats->time_in_state) / total_time); } else printf("%lu:%llu", stats->frequency, stats->time_in_state); stats = stats->next; if (stats) printf(", "); } cpufreq_put_stats(stats); if (total_trans) printf(" (%lu)\n", total_trans); return 0; } /* --latency / -y */ static int get_latency(unsigned int cpu, unsigned int human) { unsigned long latency = cpufreq_get_transition_latency(cpu); printf(_(" maximum transition latency: ")); if (!latency || latency == UINT_MAX) { printf(_(" Cannot determine or is not supported.\n")); return -EINVAL; } if (human) { print_duration(latency); printf("\n"); } else printf("%lu\n", latency); return 0; } /* --performance / -c */ static int get_perf_cap(unsigned int cpu) { if (cpupower_cpu_info.vendor == X86_VENDOR_AMD && cpupower_cpu_info.caps & CPUPOWER_CAP_AMD_PSTATE) amd_pstate_show_perf_and_freq(cpu, no_rounding); return 0; } static void debug_output_one(unsigned int cpu) { struct cpufreq_available_frequencies *freqs; get_driver(cpu); get_related_cpus(cpu); get_affected_cpus(cpu); get_latency(cpu, 1); get_hardware_limits(cpu, 1); freqs = cpufreq_get_available_frequencies(cpu); if (freqs) { printf(_(" available frequency steps: ")); while (freqs->next) { print_speed(freqs->frequency, no_rounding); printf(", "); freqs = freqs->next; } print_speed(freqs->frequency, no_rounding); printf("\n"); cpufreq_put_available_frequencies(freqs); } get_available_governors(cpu); get_policy(cpu); if (get_freq_hardware(cpu, 1) < 0) get_freq_kernel(cpu, 1); get_boost_mode(cpu); get_perf_cap(cpu); } static struct option info_opts[] = { {"debug", no_argument, NULL, 'e'}, {"boost", no_argument, NULL, 'b'}, {"freq", no_argument, NULL, 'f'}, {"hwfreq", no_argument, NULL, 'w'}, {"hwlimits", no_argument, NULL, 'l'}, {"driver", no_argument, NULL, 'd'}, {"policy", no_argument, NULL, 'p'}, {"governors", no_argument, NULL, 'g'}, {"related-cpus", no_argument, NULL, 'r'}, {"affected-cpus", no_argument, NULL, 'a'}, {"stats", no_argument, NULL, 's'}, {"latency", no_argument, NULL, 'y'}, {"proc", no_argument, NULL, 'o'}, {"human", no_argument, NULL, 'm'}, {"no-rounding", no_argument, NULL, 'n'}, {"performance", no_argument, NULL, 'c'}, { }, }; int cmd_freq_info(int argc, char **argv) { extern char *optarg; extern int optind, opterr, optopt; int ret = 0, cont = 1; unsigned int cpu = 0; unsigned int human = 0; int output_param = 0; do { ret = getopt_long(argc, argv, "oefwldpgrasmybnc", info_opts, NULL); switch (ret) { case '?': output_param = '?'; cont = 0; break; case -1: cont = 0; break; case 'b': case 'o': case 'a': case 'r': case 'g': case 'p': case 'd': case 'l': case 'w': case 'f': case 'e': case 's': case 'y': case 'c': if (output_param) { output_param = -1; cont = 0; break; } output_param = ret; break; case 'm': if (human) { output_param = -1; cont = 0; break; } human = 1; break; case 'n': no_rounding = 1; break; default: fprintf(stderr, "invalid or unknown argument\n"); return EXIT_FAILURE; } } while (cont); switch (output_param) { case 'o': if (!bitmask_isallclear(cpus_chosen)) { printf(_("The argument passed to this tool can't be " "combined with passing a --cpu argument\n")); return -EINVAL; } break; case 0: output_param = 'e'; } ret = 0; /* Default is: show output of base_cpu only */ if (bitmask_isallclear(cpus_chosen)) bitmask_setbit(cpus_chosen, base_cpu); switch (output_param) { case -1: printf(_("You can't specify more than one --cpu parameter and/or\n" "more than one output-specific argument\n")); return -EINVAL; case '?': printf(_("invalid or unknown argument\n")); return -EINVAL; case 'o': proc_cpufreq_output(); return EXIT_SUCCESS; } for (cpu = bitmask_first(cpus_chosen); cpu <= bitmask_last(cpus_chosen); cpu++) { if (!bitmask_isbitset(cpus_chosen, cpu)) continue; printf(_("analyzing CPU %d:\n"), cpu); if (sysfs_is_cpu_online(cpu) != 1) { printf(_(" *is offline\n")); printf("\n"); continue; } switch (output_param) { case 'b': get_boost_mode(cpu); break; case 'e': debug_output_one(cpu); break; case 'a': ret = get_affected_cpus(cpu); break; case 'r': ret = get_related_cpus(cpu); break; case 'g': ret = get_available_governors(cpu); break; case 'p': ret = get_policy(cpu); break; case 'd': ret = get_driver(cpu); break; case 'l': ret = get_hardware_limits(cpu, human); break; case 'w': ret = get_freq_hardware(cpu, human); break; case 'f': ret = get_freq_kernel(cpu, human); break; case 's': ret = get_freq_stats(cpu, human); break; case 'y': ret = get_latency(cpu, human); break; case 'c': ret = get_perf_cap(cpu); break; } if (ret) return ret; } return ret; }