/* * HardInfo - Displays System Information * Copyright (C) 2003-2006 L. A. F. Pereira * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, version 2 or later. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include "hardinfo.h" #include "devices.h" #include "cpu_util.h" #include "dt_util.h" #include "arm_data.h" #include "arm_data.c" enum { ARM_A32 = 0, ARM_A64 = 1, ARM_A32_ON_A64 = 2, }; static const gchar *arm_mode_str[] = { "A32", "A64", "A32 on A64", }; GSList * processor_scan(void) { GSList *procs = NULL; Processor *processor = NULL; FILE *cpuinfo; gchar buffer[128]; gchar *rep_pname = NULL; GSList *pi = NULL; dtr *dt = dtr_new(NULL); cpuinfo = fopen(PROC_CPUINFO, "r"); if (!cpuinfo) return NULL; #define CHECK_FOR(k) (g_str_has_prefix(tmp[0], k)) while (fgets(buffer, 128, cpuinfo)) { gchar **tmp = g_strsplit(buffer, ":", 2); if (tmp[0] && tmp[1]) { tmp[0] = g_strstrip(tmp[0]); tmp[1] = g_strstrip(tmp[1]); } else { g_strfreev(tmp); continue; } get_str("Processor", rep_pname); if ( CHECK_FOR("processor") ) { /* finish previous */ if (processor) { procs = g_slist_append(procs, processor); } /* start next */ processor = g_new0(Processor, 1); processor->id = atol(tmp[1]); if (rep_pname) processor->linux_name = g_strdup(rep_pname); g_strfreev(tmp); continue; } if (!processor && ( CHECK_FOR("model name") || CHECK_FOR("Features") || CHECK_FOR("BogoMIPS") ) ) { /* single proc/core may not have "processor : n" */ processor = g_new0(Processor, 1); processor->id = 0; if (rep_pname) processor->linux_name = g_strdup(rep_pname); } if (processor) { get_str("model name", processor->linux_name); get_str("Features", processor->flags); get_float("BogoMIPS", processor->bogomips); get_str("CPU implementer", processor->cpu_implementer); get_str("CPU architecture", processor->cpu_architecture); get_str("CPU variant", processor->cpu_variant); get_str("CPU part", processor->cpu_part); get_str("CPU revision", processor->cpu_revision); } g_strfreev(tmp); } if (processor) procs = g_slist_append(procs, processor); g_free(rep_pname); fclose(cpuinfo); /* re-duplicate missing data for /proc/cpuinfo variant that de-duplicated it */ #define REDUP(f) if (dproc->f && !processor->f) processor->f = g_strdup(dproc->f); Processor *dproc; GSList *l; l = procs = g_slist_reverse(procs); while (l) { processor = l->data; if (processor->flags) { dproc = processor; } else if (dproc) { REDUP(flags); REDUP(cpu_implementer); REDUP(cpu_architecture); REDUP(cpu_variant); REDUP(cpu_part); REDUP(cpu_revision); } l = g_slist_next(l); } procs = g_slist_reverse(procs); /* data not from /proc/cpuinfo */ for (pi = procs; pi; pi = pi->next) { processor = (Processor *) pi->data; /* strings can't be null or segfault later */ STRIFNULL(processor->linux_name, _("ARM Processor") ); EMPIFNULL(processor->flags); UNKIFNULL(processor->cpu_implementer); UNKIFNULL(processor->cpu_architecture); UNKIFNULL(processor->cpu_variant); UNKIFNULL(processor->cpu_part); UNKIFNULL(processor->cpu_revision); processor->model_name = arm_decoded_name( processor->cpu_implementer, processor->cpu_part, processor->cpu_variant, processor->cpu_revision, processor->cpu_architecture, processor->linux_name); UNKIFNULL(processor->model_name); /* topo & freq */ processor->cpufreq = cpufreq_new(processor->id); processor->cputopo = cputopo_new(processor->id); if (processor->cpufreq->cpukhz_max) processor->cpu_mhz = processor->cpufreq->cpukhz_max / 1000; else processor->cpu_mhz = 0.0f; /* Try OPP, although if it exists, it should have been available * via cpufreq. */ if (dt && processor->cpu_mhz == 0.0f) { gchar *dt_cpu_path = g_strdup_printf("/cpus/cpu@%d", processor->id); dt_opp_range *opp = dtr_get_opp_range(dt, dt_cpu_path); if (opp) { processor->cpu_mhz = (double)opp->khz_max / 1000; g_free(opp); } g_free(dt_cpu_path); } /* mode */ processor->mode = ARM_A32; if ( processor_has_flag(processor->flags, "pmull") || processor_has_flag(processor->flags, "crc32") ) { #ifdef __aarch64__ processor->mode = ARM_A64; #else processor->mode = ARM_A32_ON_A64; #endif } } dtr_free(dt); return procs; } gchar *processor_get_capabilities_from_flags(gchar * strflags) { gchar **flags, **old; gchar *tmp = NULL; gint j = 0; flags = g_strsplit(strflags, " ", 0); old = flags; while (flags[j]) { const gchar *meaning = arm_flag_meaning( flags[j] ); if (meaning) { tmp = h_strdup_cprintf("%s=%s\n", tmp, flags[j], meaning); } else { tmp = h_strdup_cprintf("%s=\n", tmp, flags[j]); } j++; } if (tmp == NULL || g_strcmp0(tmp, "") == 0) tmp = g_strdup_printf("%s=%s\n", "empty", _("Empty List")); g_strfreev(old); return tmp; } #define khzint_to_mhzdouble(k) (((double)k)/1000) #define cmp_clocks_test(f) if (a->f < b->f) return -1; if (a->f > b->f) return 1; static gint cmp_cpufreq_data(cpufreq_data *a, cpufreq_data *b) { gint i = 0; i = g_strcmp0(a->shared_list, b->shared_list); if (i!=0) return i; cmp_clocks_test(cpukhz_max); cmp_clocks_test(cpukhz_min); return 0; } static gint cmp_cpufreq_data_ignore_affected(cpufreq_data *a, cpufreq_data *b) { gint i = 0; cmp_clocks_test(cpukhz_max); cmp_clocks_test(cpukhz_min); return 0; } gchar *clocks_summary(GSList * processors) { gchar *ret = g_strdup_printf("[%s]\n", _("Clocks")); GSList *all_clocks = NULL, *uniq_clocks = NULL; GSList *tmp, *l; Processor *p; cpufreq_data *c, *cur = NULL; gint cur_count = 0, i = 0; /* create list of all clock references */ for (l = processors; l; l = l->next) { p = (Processor*)l->data; if (p->cpufreq && p->cpufreq->cpukhz_max > 0) { all_clocks = g_slist_prepend(all_clocks, p->cpufreq); } } if (g_slist_length(all_clocks) == 0) { ret = h_strdup_cprintf("%s=\n", ret, _("(Not Available)") ); g_slist_free(all_clocks); return ret; } /* ignore duplicate references */ all_clocks = g_slist_sort(all_clocks, (GCompareFunc)cmp_cpufreq_data); for (l = all_clocks; l; l = l->next) { c = (cpufreq_data*)l->data; if (!cur) { cur = c; } else { if (cmp_cpufreq_data(cur, c) != 0) { uniq_clocks = g_slist_prepend(uniq_clocks, cur); cur = c; } } } uniq_clocks = g_slist_prepend(uniq_clocks, cur); uniq_clocks = g_slist_reverse(uniq_clocks); cur = 0, cur_count = 0; /* count and list clocks */ for (l = uniq_clocks; l; l = l->next) { c = (cpufreq_data*)l->data; if (!cur) { cur = c; cur_count = 1; } else { if (cmp_cpufreq_data_ignore_affected(cur, c) != 0) { ret = h_strdup_cprintf(_("%.2f-%.2f %s=%dx\n"), ret, khzint_to_mhzdouble(cur->cpukhz_min), khzint_to_mhzdouble(cur->cpukhz_max), _("MHz"), cur_count); cur = c; cur_count = 1; } else { cur_count++; } } } ret = h_strdup_cprintf(_("%.2f-%.2f %s=%dx\n"), ret, khzint_to_mhzdouble(cur->cpukhz_min), khzint_to_mhzdouble(cur->cpukhz_max), _("MHz"), cur_count); g_slist_free(all_clocks); g_slist_free(uniq_clocks); return ret; } gchar * processor_get_detailed_info(Processor *processor) { gchar *tmp_flags, *tmp_imp = NULL, *tmp_part = NULL, *tmp_arch, *tmp_cpufreq, *tmp_topology, *ret; tmp_flags = processor_get_capabilities_from_flags(processor->flags); arm_part(processor->cpu_implementer, processor->cpu_part, &tmp_imp, &tmp_part); tmp_arch = (char*)arm_arch_more(processor->cpu_architecture); tmp_topology = cputopo_section_str(processor->cputopo); tmp_cpufreq = cpufreq_section_str(processor->cpufreq); ret = g_strdup_printf("[%s]\n" "%s=%s\n" /* linux name */ "%s=%s\n" /* decoded name */ "%s=%s\n" /* mode */ "%s=%.2f %s\n" /* frequency */ "%s=%.2f\n" /* bogomips */ "%s=%s\n" /* byte order */ "%s" /* topology */ "%s" /* frequency scaling */ "[%s]\n" /* ARM */ "%s=[%s] %s\n" /* implementer */ "%s=[%s] %s\n" /* part */ "%s=[%s] %s\n" /* architecture */ "%s=%s\n" /* variant */ "%s=%s\n" /* revision */ "[%s]\n" /* flags */ "%s" "%s", /* empty */ _("Processor"), _("Linux Name"), processor->linux_name, _("Decoded Name"), processor->model_name, _("Mode"), arm_mode_str[processor->mode], _("Frequency"), processor->cpu_mhz, _("MHz"), _("BogoMips"), processor->bogomips, _("Byte Order"), byte_order_str(), tmp_topology, tmp_cpufreq, _("ARM"), _("Implementer"), processor->cpu_implementer, (tmp_imp) ? tmp_imp : "", _("Part"), processor->cpu_part, (tmp_part) ? tmp_part : "", _("Architecture"), processor->cpu_architecture, (tmp_arch) ? tmp_arch : "", _("Variant"), processor->cpu_variant, _("Revision"), processor->cpu_revision, _("Capabilities"), tmp_flags, ""); g_free(tmp_flags); g_free(tmp_cpufreq); g_free(tmp_topology); return ret; } gchar *processor_name(GSList *processors) { /* compatible contains a list of compatible hardware, so be careful * with matching order. * ex: "ti,omap3-beagleboard-xm", "ti,omap3450", "ti,omap3"; * matches "omap3 family" first. * ex: "brcm,bcm2837", "brcm,bcm2836"; * would match 2836 when it is a 2837. */ #define UNKSOC "(Unknown)" /* don't translate this */ const struct { char *search_str; char *vendor; char *soc; } dt_compat_searches[] = { { "brcm,bcm2838", "Broadcom", "BCM2838" }, // RPi 4 { "brcm,bcm2837", "Broadcom", "BCM2837" }, // RPi 3 { "brcm,bcm2836", "Broadcom", "BCM2836" }, // RPi 2 { "brcm,bcm2835", "Broadcom", "BCM2835" }, // RPi 1 { "rockchip,rk3288", "Rockchip", "RK3288" }, // Asus Tinkerboard { "rockchip,rk3328", "Rockchip", "RK3328" }, // Firefly Renegade { "rockchip,rk3399", "Rockchip", "RK3399" }, // Firefly Renegade Elite { "rockchip,rk32", "Rockchip", "RK32xx-family" }, { "rockchip,rk33", "Rockchip", "RK33xx-family" }, { "ti,omap5432", "Texas Instruments", "OMAP5432" }, { "ti,omap5430", "Texas Instruments", "OMAP5430" }, { "ti,omap4470", "Texas Instruments", "OMAP4470" }, { "ti,omap4460", "Texas Instruments", "OMAP4460" }, { "ti,omap4430", "Texas Instruments", "OMAP4430" }, { "ti,omap3620", "Texas Instruments", "OMAP3620" }, { "ti,omap3450", "Texas Instruments", "OMAP3450" }, { "ti,omap5", "Texas Instruments", "OMAP5-family" }, { "ti,omap4", "Texas Instruments", "OMAP4-family" }, { "ti,omap3", "Texas Instruments", "OMAP3-family" }, { "ti,omap2", "Texas Instruments", "OMAP2-family" }, { "ti,omap1", "Texas Instruments", "OMAP1-family" }, { "mediatek,mt6799", "MediaTek", "MT6799 Helio X30" }, { "mediatek,mt6799", "MediaTek", "MT6799 Helio X30" }, { "mediatek,mt6797x", "MediaTek", "MT6797X Helio X27" }, { "mediatek,mt6797t", "MediaTek", "MT6797T Helio X25" }, { "mediatek,mt6797", "MediaTek", "MT6797 Helio X20" }, { "mediatek,mt6757T", "MediaTek", "MT6757T Helio P25" }, { "mediatek,mt6757", "MediaTek", "MT6757 Helio P20" }, { "mediatek,mt6795", "MediaTek", "MT6795 Helio X10" }, { "mediatek,mt6755", "MediaTek", "MT6755 Helio P10" }, { "mediatek,mt6750t", "MediaTek", "MT6750T" }, { "mediatek,mt6750", "MediaTek", "MT6750" }, { "mediatek,mt6753", "MediaTek", "MT6753" }, { "mediatek,mt6752", "MediaTek", "MT6752" }, { "mediatek,mt6738", "MediaTek", "MT6738" }, { "mediatek,mt6737t", "MediaTek", "MT6737T" }, { "mediatek,mt6735", "MediaTek", "MT6735" }, { "mediatek,mt6732", "MediaTek", "MT6732" }, { "qcom,msm8939", "Qualcomm", "Snapdragon 615"}, { "qcom,msm", "Qualcomm", "Snapdragon-family"}, { "nvidia,tegra", "nVidia", "Tegra-family" }, { "brcm,", "Broadcom", UNKSOC }, { "nvidia,", "nVidia", UNKSOC }, { "rockchip,", "Rockchip", UNKSOC }, { "ti,", "Texas Instruments", UNKSOC }, { "qcom,", "Qualcom", UNKSOC }, { "mediatek,", "MediaTek", UNKSOC }, { "amlogic,", "Amlogic", UNKSOC }, { "allwinner,", "Allwinner", UNKSOC }, { NULL, NULL } }; gchar *ret = NULL; gchar *compat = NULL; int i; compat = dtr_get_string("/compatible", 1); if (compat != NULL) { i = 0; while(dt_compat_searches[i].search_str != NULL) { if (strstr(compat, dt_compat_searches[i].search_str) != NULL) { ret = g_strdup_printf("%s %s", dt_compat_searches[i].vendor, dt_compat_searches[i].soc); break; } i++; } } g_free(compat); UNKIFNULL(ret); return ret; } gchar *processor_describe(GSList * processors) { return processor_describe_by_counting_names(processors); } gchar *processor_meta(GSList * processors) { gchar *meta_soc = processor_name(processors); gchar *meta_cpu_desc = processor_describe(processors); gchar *meta_cpu_topo = processor_describe_default(processors); gchar *meta_freq_desc = processor_frequency_desc(processors); gchar *meta_clocks = clocks_summary(processors); gchar *ret = NULL; UNKIFNULL(meta_cpu_desc); ret = g_strdup_printf("[%s]\n" "%s=%s\n" "%s=%s\n" "%s=%s\n" "%s=%s\n" "%s", _("SOC/Package"), _("Name"), meta_soc, _("Description"), meta_cpu_desc, _("Topology"), meta_cpu_topo, _("Logical CPU Config"), meta_freq_desc, meta_clocks ); g_free(meta_soc); g_free(meta_cpu_desc); g_free(meta_cpu_topo); g_free(meta_freq_desc); g_free(meta_clocks); return ret; } gchar *processor_get_info(GSList * processors) { Processor *processor; gchar *ret, *tmp, *hashkey; gchar *meta; /* becomes owned by more_info? no need to free? */ GSList *l; tmp = g_strdup_printf("$!CPU_META$%s=\n", _("SOC/Package Information") ); meta = processor_meta(processors); moreinfo_add_with_prefix("DEV", "CPU_META", meta); for (l = processors; l; l = l->next) { processor = (Processor *) l->data; tmp = g_strdup_printf("%s$CPU%d$%s=%.2f %s\n", tmp, processor->id, processor->model_name, processor->cpu_mhz, _("MHz")); hashkey = g_strdup_printf("CPU%d", processor->id); moreinfo_add_with_prefix("DEV", hashkey, processor_get_detailed_info(processor)); g_free(hashkey); } ret = g_strdup_printf("[$ShellParam$]\n" "ViewType=1\n" "[Processors]\n" "%s", tmp); g_free(tmp); return ret; }