/* fhandler_proc.cc: fhandler for /proc virtual filesystem This file is part of Cygwin. This software is a copyrighted work licensed under the terms of the Cygwin license. Please consult the file "CYGWIN_LICENSE" for details. */ #include "winsup.h" #include "miscfuncs.h" #include #include #include #include "cygerrno.h" #include "security.h" #include "path.h" #include "shared_info.h" #include "fhandler.h" #include "fhandler_virtual.h" #include "pinfo.h" #include "dtable.h" #include "cygheap.h" #include "tls_pbuf.h" #include #include #include #include "ntdll.h" #include #include #include #include "cpuid.h" #include "mount.h" #include #define _COMPILING_NEWLIB #include static off_t format_proc_loadavg (void *, char *&); static off_t format_proc_meminfo (void *, char *&); static off_t format_proc_stat (void *, char *&); static off_t format_proc_version (void *, char *&); static off_t format_proc_uptime (void *, char *&); static off_t format_proc_cpuinfo (void *, char *&); static off_t format_proc_partitions (void *, char *&); static off_t format_proc_self (void *, char *&); static off_t format_proc_cygdrive (void *, char *&); static off_t format_proc_mounts (void *, char *&); static off_t format_proc_filesystems (void *, char *&); static off_t format_proc_swaps (void *, char *&); static off_t format_proc_devices (void *, char *&); static off_t format_proc_misc (void *, char *&); /* names of objects in /proc */ static const virt_tab_t proc_tab[] = { { _VN ("."), FH_PROC, virt_directory, NULL }, { _VN (".."), FH_PROC, virt_directory, NULL }, { _VN ("cpuinfo"), FH_PROC, virt_file, format_proc_cpuinfo }, { _VN ("cygdrive"), FH_PROC, virt_symlink, format_proc_cygdrive }, { _VN ("devices"), FH_PROC, virt_file, format_proc_devices }, { _VN ("filesystems"), FH_PROC, virt_file, format_proc_filesystems }, { _VN ("loadavg"), FH_PROC, virt_file, format_proc_loadavg }, { _VN ("meminfo"), FH_PROC, virt_file, format_proc_meminfo }, { _VN ("misc"), FH_PROC, virt_file, format_proc_misc }, { _VN ("mounts"), FH_PROC, virt_symlink, format_proc_mounts }, { _VN ("net"), FH_PROCNET, virt_directory, NULL }, { _VN ("partitions"), FH_PROC, virt_file, format_proc_partitions }, { _VN ("registry"), FH_REGISTRY, virt_directory, NULL }, { _VN ("registry32"), FH_REGISTRY, virt_directory, NULL }, { _VN ("registry64"), FH_REGISTRY, virt_directory, NULL }, { _VN ("self"), FH_PROC, virt_symlink, format_proc_self }, { _VN ("stat"), FH_PROC, virt_file, format_proc_stat }, { _VN ("swaps"), FH_PROC, virt_file, format_proc_swaps }, { _VN ("sys"), FH_PROCSYS, virt_directory, NULL }, { _VN ("sysvipc"), FH_PROCSYSVIPC, virt_directory, NULL }, { _VN ("uptime"), FH_PROC, virt_file, format_proc_uptime }, { _VN ("version"), FH_PROC, virt_file, format_proc_version }, { NULL, 0, FH_NADA, virt_none, NULL } }; #define PROC_DIR_COUNT 4 static const int PROC_LINK_COUNT = (sizeof (proc_tab) / sizeof (virt_tab_t)) - 1; /* name of the /proc filesystem */ const char proc[] = "/proc"; const size_t proc_len = sizeof (proc) - 1; /* bsearch compare function. */ static int proc_tab_cmp (const void *key, const void *memb) { int ret = strncmp (((virt_tab_t *) key)->name, ((virt_tab_t *) memb)->name, ((virt_tab_t *) memb)->name_len); if (!ret && ((virt_tab_t *) key)->name[((virt_tab_t *) memb)->name_len] != '\0' && ((virt_tab_t *) key)->name[((virt_tab_t *) memb)->name_len] != '/') return 1; return ret; } /* Helper function to perform a binary search of the incoming pathname against the alpha-sorted virtual file table. */ virt_tab_t * virt_tab_search (const char *path, bool prefix, const virt_tab_t *table, size_t nelem) { virt_tab_t key = { path, 0, FH_NADA, virt_none, NULL }; virt_tab_t *entry = (virt_tab_t *) bsearch (&key, table, nelem, sizeof (virt_tab_t), proc_tab_cmp); if (entry && (path[entry->name_len] == '\0' || (prefix && path[entry->name_len] == '/'))) return entry; return NULL; } /* Auxillary function that returns the fhandler associated with the given path. */ fh_devices fhandler_proc::get_proc_fhandler (const char *path) { debug_printf ("get_proc_fhandler(%s)", path); path += proc_len; /* Since this method is called from path_conv::check we can't rely on it being normalised and therefore the path may have runs of slashes in it. */ while (isdirsep (*path)) path++; /* Check if this is the root of the virtual filesystem (i.e. /proc). */ if (*path == 0) return FH_PROC; virt_tab_t *entry = virt_tab_search (path, true, proc_tab, PROC_LINK_COUNT); if (entry) return entry->fhandler; char *e; pid_t pid = strtoul (path, &e, 10); if (*e != '/' && *e != '\0') return FH_NADA; pinfo p (pid); /* If p->pid != pid, then pid is actually the Windows PID for an execed Cygwin process, and the pinfo entry is the additional entry created at exec time. We don't want to enable the user to access a process entry by using the Win32 PID, though. */ if (p && p->pid == pid) { /* Check for entry in fd subdir */ if (!strncmp (++e, "fd/", 3) && e[3] != '\0') return FH_PROCESSFD; return FH_PROCESS; } bool has_subdir = false; while (*path) if (isdirsep (*path++)) { has_subdir = true; break; } if (has_subdir) /* The user is trying to access a non-existent subdirectory of /proc. */ return FH_NADA; else /* Return FH_PROC so that we can return EROFS if the user is trying to create a file. */ return FH_PROC; } virtual_ftype_t fhandler_proc::exists () { const char *path = get_name (); debug_printf ("exists (%s)", path); path += proc_len; if (*path == 0) return virt_rootdir; virt_tab_t *entry = virt_tab_search (path + 1, false, proc_tab, PROC_LINK_COUNT); if (entry) { fileid = entry - proc_tab; return entry->type; } return virt_none; } fhandler_proc::fhandler_proc (): fhandler_virtual () { } int __reg2 fhandler_proc::fstat (struct stat *buf) { const char *path = get_name (); debug_printf ("fstat (%s)", path); path += proc_len; fhandler_base::fstat (buf); buf->st_mode &= ~_IFMT & NO_W; if (!*path) { winpids pids ((DWORD) 0); buf->st_ino = 2; buf->st_mode |= S_IFDIR | S_IXUSR | S_IXGRP | S_IXOTH; buf->st_nlink = PROC_DIR_COUNT + 2 + pids.npids; return 0; } else { virt_tab_t *entry = virt_tab_search (path + 1, false, proc_tab, PROC_LINK_COUNT); if (entry) { if (entry->type == virt_directory) buf->st_mode |= S_IFDIR | S_IXUSR | S_IXGRP | S_IXOTH; else if (entry->type == virt_symlink) buf->st_mode = S_IFLNK | S_IRWXU | S_IRWXG | S_IRWXO; else { buf->st_mode &= NO_X; buf->st_mode |= S_IFREG; } return 0; } } set_errno (ENOENT); return -1; } DIR * fhandler_proc::opendir (int fd) { DIR *dir = fhandler_virtual::opendir (fd); if (dir && !(dir->__handle = (void *) new winpids ((DWORD) 0))) { free (dir); dir = NULL; set_errno (ENOMEM); } return dir; } int fhandler_proc::closedir (DIR *dir) { delete (winpids *) dir->__handle; return fhandler_virtual::closedir (dir); } int fhandler_proc::readdir (DIR *dir, dirent *de) { int res; if (dir->__d_position < PROC_LINK_COUNT) { strcpy (de->d_name, proc_tab[dir->__d_position].name); de->d_type = virt_ftype_to_dtype (proc_tab[dir->__d_position].type); dir->__d_position++; dir->__flags |= dirent_saw_dot | dirent_saw_dot_dot; res = 0; } else { winpids &pids = *(winpids *) dir->__handle; int found = 0; res = ENMFILE; for (unsigned i = 0; i < pids.npids; i++) if (found++ == dir->__d_position - PROC_LINK_COUNT) { __small_sprintf (de->d_name, "%d", pids[i]->pid); de->d_type = DT_DIR; dir->__d_position++; res = 0; break; } } syscall_printf ("%d = readdir(%p, %p) (%s)", res, dir, de, de->d_name); return res; } int fhandler_proc::open (int flags, mode_t mode) { int proc_file_no = -1; int res = fhandler_virtual::open (flags, mode); if (!res) goto out; nohandle (true); const char *path; path = get_name () + proc_len; if (!*path) { if ((flags & (O_CREAT | O_EXCL)) == (O_CREAT | O_EXCL)) { set_errno (EEXIST); res = 0; goto out; } else if (flags & O_WRONLY) { set_errno (EISDIR); res = 0; goto out; } else { flags |= O_DIROPEN; goto success; } } proc_file_no = -1; for (int i = 0; proc_tab[i].name; i++) if (path_prefix_p (proc_tab[i].name, path + 1, strlen (proc_tab[i].name), false)) { proc_file_no = i; if (proc_tab[i].fhandler != FH_PROC) { if ((flags & (O_CREAT | O_EXCL)) == (O_CREAT | O_EXCL)) { set_errno (EEXIST); res = 0; goto out; } else if (flags & O_WRONLY) { set_errno (EISDIR); res = 0; goto out; } else { flags |= O_DIROPEN; goto success; } } } if (proc_file_no == -1) { if (flags & O_CREAT) { set_errno (EROFS); res = 0; goto out; } else { set_errno (ENOENT); res = 0; goto out; } } if (flags & O_WRONLY) { set_errno (EROFS); res = 0; goto out; } fileid = proc_file_no; if (!fill_filebuf ()) { res = 0; goto out; } if (flags & O_APPEND) position = filesize; else position = 0; success: res = 1; set_flags ((flags & ~O_TEXT) | O_BINARY); set_open_status (); out: syscall_printf ("%d = fhandler_proc::open(%y, 0%o)", res, flags, mode); return res; } bool fhandler_proc::fill_filebuf () { if (fileid < PROC_LINK_COUNT && proc_tab[fileid].format_func) { filesize = proc_tab[fileid].format_func (NULL, filebuf); if (filesize > 0) return true; } return false; } extern "C" int uname_x (struct utsname *); static off_t format_proc_version (void *, char *&destbuf) { tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; struct utsname uts_name; uname_x (&uts_name); bufptr += __small_sprintf (bufptr, "%s version %s (%s@%s) (%s) %s\n", uts_name.sysname, uts_name.release, USERNAME, HOSTNAME, GCC_VERSION, uts_name.version); destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_loadavg (void *, char *&destbuf) { extern int get_process_state (DWORD dwProcessId); unsigned int running = 0; winpids pids ((DWORD) 0); for (unsigned i = 0; i < pids.npids; i++) switch (get_process_state (i)) { case 'O': case 'R': running++; break; } double loadavg[3] = { 0.0, 0.0, 0.0 }; getloadavg (loadavg, 3); #define HUNDRETHS(l) (int)((l - floor(l))*100) destbuf = (char *) crealloc_abort (destbuf, 48); return __small_sprintf (destbuf, "%u.%02u %u.%02u %u.%02u %u/%u\n", (int)loadavg[0], HUNDRETHS(loadavg[0]), (int)loadavg[1], HUNDRETHS(loadavg[1]), (int)loadavg[2], HUNDRETHS(loadavg[2]), running, (unsigned int)pids.npids); } static off_t format_proc_meminfo (void *, char *&destbuf) { unsigned long long mem_total, mem_free, swap_total, swap_free; struct sysinfo info; sysinfo (&info); mem_total = (unsigned long long) info.totalram * info.mem_unit; mem_free = (unsigned long long) info.freeram * info.mem_unit; swap_total = (unsigned long long) info.totalswap * info.mem_unit; swap_free = (unsigned long long) info.freeswap * info.mem_unit; destbuf = (char *) crealloc_abort (destbuf, 512); return sprintf (destbuf, "MemTotal: %10llu kB\n" "MemFree: %10llu kB\n" "HighTotal: 0 kB\n" "HighFree: 0 kB\n" "LowTotal: %10llu kB\n" "LowFree: %10llu kB\n" "SwapTotal: %10llu kB\n" "SwapFree: %10llu kB\n", mem_total >> 10, mem_free >> 10, mem_total >> 10, mem_free >> 10, swap_total >> 10, swap_free >> 10); } static off_t format_proc_uptime (void *, char *&destbuf) { unsigned long long uptime = 0ULL, idle_time = 0ULL; NTSTATUS status; SYSTEM_TIMEOFDAY_INFORMATION stodi; /* Sizeof SYSTEM_PERFORMANCE_INFORMATION on 64 bit systems. It appears to contain some trailing additional information from what I can tell after examining the content. FIXME: It would be nice if this could be verified somehow. */ const size_t sizeof_spi = sizeof (SYSTEM_PERFORMANCE_INFORMATION) + 16; PSYSTEM_PERFORMANCE_INFORMATION spi = (PSYSTEM_PERFORMANCE_INFORMATION) alloca (sizeof_spi); status = NtQuerySystemInformation (SystemTimeOfDayInformation, &stodi, sizeof stodi, NULL); if (NT_SUCCESS (status)) uptime = (stodi.CurrentTime.QuadPart - stodi.BootTime.QuadPart) / 100000ULL; else debug_printf ("NtQuerySystemInformation(SystemTimeOfDayInformation), " "status %y", status); if (NT_SUCCESS (NtQuerySystemInformation (SystemPerformanceInformation, spi, sizeof_spi, NULL))) idle_time = (spi->IdleTime.QuadPart / wincap.cpu_count ()) / 100000ULL; destbuf = (char *) crealloc_abort (destbuf, 80); return __small_sprintf (destbuf, "%U.%02u %U.%02u\n", uptime / 100, long (uptime % 100), idle_time / 100, long (idle_time % 100)); } static off_t format_proc_stat (void *, char *&destbuf) { unsigned long pages_in = 0UL, pages_out = 0UL, interrupt_count = 0UL, context_switches = 0UL, swap_in = 0UL, swap_out = 0UL; time_t boot_time = 0; NTSTATUS status; /* Sizeof SYSTEM_PERFORMANCE_INFORMATION on 64 bit systems. It appears to contain some trailing additional information from what I can tell after examining the content. FIXME: It would be nice if this could be verified somehow. */ const size_t sizeof_spi = sizeof (SYSTEM_PERFORMANCE_INFORMATION) + 16; PSYSTEM_PERFORMANCE_INFORMATION spi = (PSYSTEM_PERFORMANCE_INFORMATION) alloca (sizeof_spi); SYSTEM_TIMEOFDAY_INFORMATION stodi; tmp_pathbuf tp; char *buf = tp.c_get (); char *eobuf = buf; SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION spt[wincap.cpu_count ()]; status = NtQuerySystemInformation (SystemProcessorPerformanceInformation, (PVOID) spt, sizeof spt[0] * wincap.cpu_count (), NULL); if (!NT_SUCCESS (status)) debug_printf ("NtQuerySystemInformation(SystemProcessorPerformanceInformation), " "status %y", status); else { unsigned long long user_time = 0ULL, kernel_time = 0ULL, idle_time = 0ULL; for (unsigned long i = 0; i < wincap.cpu_count (); i++) { kernel_time += (spt[i].KernelTime.QuadPart - spt[i].IdleTime.QuadPart) * CLOCKS_PER_SEC / NS100PERSEC; user_time += spt[i].UserTime.QuadPart * CLOCKS_PER_SEC / NS100PERSEC; idle_time += spt[i].IdleTime.QuadPart * CLOCKS_PER_SEC / NS100PERSEC; } eobuf += __small_sprintf (eobuf, "cpu %U %U %U %U\n", user_time, 0ULL, kernel_time, idle_time); user_time = 0ULL, kernel_time = 0ULL, idle_time = 0ULL; for (unsigned long i = 0; i < wincap.cpu_count (); i++) { interrupt_count += spt[i].InterruptCount; kernel_time = (spt[i].KernelTime.QuadPart - spt[i].IdleTime.QuadPart) * CLOCKS_PER_SEC / NS100PERSEC; user_time = spt[i].UserTime.QuadPart * CLOCKS_PER_SEC / NS100PERSEC; idle_time = spt[i].IdleTime.QuadPart * CLOCKS_PER_SEC / NS100PERSEC; eobuf += __small_sprintf (eobuf, "cpu%d %U %U %U %U\n", i, user_time, 0ULL, kernel_time, idle_time); } status = NtQuerySystemInformation (SystemPerformanceInformation, (PVOID) spi, sizeof_spi, NULL); if (!NT_SUCCESS (status)) { debug_printf ("NtQuerySystemInformation(SystemPerformanceInformation)" ", status %y", status); memset (spi, 0, sizeof_spi); } status = NtQuerySystemInformation (SystemTimeOfDayInformation, (PVOID) &stodi, sizeof stodi, NULL); if (!NT_SUCCESS (status)) debug_printf ("NtQuerySystemInformation(SystemTimeOfDayInformation), " "status %y", status); } if (!NT_SUCCESS (status)) { __seterrno_from_nt_status (status); return 0; } pages_in = spi->PagesRead; pages_out = spi->PagefilePagesWritten + spi->MappedFilePagesWritten; /* Note: there is no distinction made in this structure between pages read from the page file and pages read from mapped files, but there is such a distinction made when it comes to writing. Goodness knows why. The value of swap_in, then, will obviously be wrong but its our best guess. */ swap_in = spi->PagesRead; swap_out = spi->PagefilePagesWritten; context_switches = spi->ContextSwitches; boot_time = to_time_t (&stodi.BootTime); eobuf += __small_sprintf (eobuf, "page %u %u\n" "swap %u %u\n" "intr %u\n" "ctxt %u\n" "btime %u\n", pages_in, pages_out, swap_in, swap_out, interrupt_count, context_switches, boot_time); destbuf = (char *) crealloc_abort (destbuf, eobuf - buf); memcpy (destbuf, buf, eobuf - buf); return eobuf - buf; } #define print(x) { bufptr = stpcpy (bufptr, (x)); } /* feature test bit position (0-32) and conditional print */ #define ftcprint(feat,bitno,msg) if ((feat) & (1 << (bitno))) { print (" " msg); } static inline uint32_t get_msb (uint32_t in) { return 32 - __builtin_clz (in); } static inline uint32_t mask_bits (uint32_t in) { uint32_t bits = get_msb (in) - 1; if (in & (in - 1)) ++bits; return bits; } static off_t format_proc_cpuinfo (void *, char *&destbuf) { WCHAR cpu_key[128], *cpu_num_p; DWORD orig_affinity_mask = 0; GROUP_AFFINITY orig_group_affinity; int cpu_number; const int BUFSIZE = 256; union { BYTE b[BUFSIZE]; char s[BUFSIZE]; WCHAR w[BUFSIZE / sizeof (WCHAR)]; DWORD d; uint32_t m[13]; } in_buf; tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; //WORD num_cpu_groups = 1; /* Pre Windows 7, only one group... */ WORD num_cpu_per_group = __get_cpus_per_group (); cpu_num_p = wcpcpy (cpu_key, L"\\Registry\\Machine\\HARDWARE\\DESCRIPTION" "\\System\\CentralProcessor\\"); for (cpu_number = 0; ; cpu_number++) { __small_swprintf (cpu_num_p, L"%d", cpu_number); if (!NT_SUCCESS (RtlCheckRegistryKey (RTL_REGISTRY_ABSOLUTE, cpu_key))) break; if (cpu_number) print ("\n"); WORD cpu_group = cpu_number / num_cpu_per_group; KAFFINITY cpu_mask = 1L << (cpu_number % num_cpu_per_group); if (wincap.has_processor_groups ()) { GROUP_AFFINITY affinity = { .Mask = cpu_mask, .Group = cpu_group, }; if (!SetThreadGroupAffinity (GetCurrentThread (), &affinity, &orig_group_affinity)) system_printf ("SetThreadGroupAffinity(%x,%d (%x/%d)) failed %E", cpu_mask, cpu_group, cpu_number, cpu_number); orig_affinity_mask = 1; /* Just mark success. */ } else { orig_affinity_mask = SetThreadAffinityMask (GetCurrentThread (), 1 << cpu_number); if (orig_affinity_mask == 0) debug_printf ("SetThreadAffinityMask failed %E"); } /* I'm not sure whether the thread changes processor immediately and I'm not sure whether this function will cause the thread to be rescheduled */ yield (); DWORD cpu_mhz = 0; union { LONG uc_len; /* -max size of buffer before call */ char uc_microcode[16]; } uc; RTL_QUERY_REGISTRY_TABLE tab[3] = { { NULL, RTL_QUERY_REGISTRY_DIRECT | RTL_QUERY_REGISTRY_NOSTRING, L"~Mhz", &cpu_mhz, REG_NONE, NULL, 0 }, { NULL, RTL_QUERY_REGISTRY_DIRECT | RTL_QUERY_REGISTRY_NOSTRING, L"Update Revision", &uc, REG_NONE, NULL, 0 }, { NULL, 0, NULL, NULL, 0, NULL, 0 } }; memset (&uc, 0, sizeof (uc.uc_microcode)); uc.uc_len = -16; /* -max size of microcode buffer */ RtlQueryRegistryValues (RTL_REGISTRY_ABSOLUTE, cpu_key, tab, NULL, NULL); cpu_mhz = ((cpu_mhz - 1) / 10 + 1) * 10; /* round up to multiple of 10 */ DWORD bogomips = cpu_mhz * 2; /* bogomips is double cpu MHz since MMX */ long long microcode = 0; /* at least 8 bytes for AMD */ memcpy (µcode, &uc, sizeof (microcode)); bufptr += __small_sprintf (bufptr, "processor\t: %d\n", cpu_number); uint32_t maxf, vendor_id[4], unused; cpuid (&maxf, &vendor_id[0], &vendor_id[2], &vendor_id[1], 0x00000000); maxf &= 0xffff; vendor_id[3] = 0; /* Vendor identification. */ bool is_amd = false, is_intel = false; if (!strcmp ((char*)vendor_id, "AuthenticAMD") || !strcmp((char*)vendor_id, "HygonGenuine")) is_amd = true; else if (!strcmp ((char*)vendor_id, "GenuineIntel")) is_intel = true; bufptr += __small_sprintf (bufptr, "vendor_id\t: %s\n", (char *)vendor_id); uint32_t features1, features2, extra_info, cpuid_sig; cpuid (&cpuid_sig, &extra_info, &features2, &features1, 0x00000001); uint32_t family = (cpuid_sig & 0x00000f00) >> 8, model = (cpuid_sig & 0x000000f0) >> 4, stepping = cpuid_sig & 0x0000000f, apic_id = (extra_info & 0xff000000) >> 24; if (family == 15) family += (cpuid_sig >> 20) & 0xff; if (family >= 6) model |= ((cpuid_sig >> 16) & 0x0f) << 4; /* ext model << 4 | model */ uint32_t maxe = 0; cpuid (&maxe, &unused, &unused, &unused, 0x80000000); if (maxe >= 0x80000004) { cpuid (&in_buf.m[0], &in_buf.m[1], &in_buf.m[2], &in_buf.m[3], 0x80000002); cpuid (&in_buf.m[4], &in_buf.m[5], &in_buf.m[6], &in_buf.m[7], 0x80000003); cpuid (&in_buf.m[8], &in_buf.m[9], &in_buf.m[10], &in_buf.m[11], 0x80000004); in_buf.m[12] = 0; } else { /* Could implement a lookup table here if someone needs it. */ strcpy (in_buf.s, "unknown"); } int cache_size = -1, clflush = 64, cache_alignment = 64; long (*get_cpu_cache) (int, uint32_t) = NULL; uint32_t max; if (features1 & (1 << 19)) /* CLFSH */ clflush = ((extra_info >> 8) & 0xff) << 3; if (is_intel && family == 15) cache_alignment = clflush * 2; if (is_intel) { extern long get_cpu_cache_intel (int sysc, uint32_t maxf); get_cpu_cache = get_cpu_cache_intel; max = maxf; /* Intel uses normal cpuid levels */ } else if (is_amd) { extern long get_cpu_cache_amd (int sysc, uint32_t maxe); get_cpu_cache = get_cpu_cache_amd; max = maxe; /* AMD uses extended cpuid levels */ } if (get_cpu_cache) { long cs; cs = get_cpu_cache (_SC_LEVEL3_CACHE_SIZE, max); if (cs <= 0) cs = get_cpu_cache (_SC_LEVEL2_CACHE_SIZE, max); if (cs <= 0) { cs = get_cpu_cache (_SC_LEVEL1_ICACHE_SIZE, max); if (cs > 0) cache_size = cs; cs = get_cpu_cache (_SC_LEVEL1_DCACHE_SIZE, max); if (cs > 0) cache_size += cs; } else cache_size = cs; if (cache_size > 0) cache_size >>= 10; } bufptr += __small_sprintf (bufptr, "cpu family\t: %d\n" "model\t\t: %d\n" "model name\t: %s\n" "stepping\t: %d\n" "microcode\t: 0x%x\n" "cpu MHz\t\t: %d.000\n", family, model, in_buf.s + strspn (in_buf.s, " "), stepping, microcode, cpu_mhz); if (cache_size >= 0) bufptr += __small_sprintf (bufptr, "cache size\t: %d KB\n", cache_size); /* Recognize multi-core CPUs. */ if (features1 & (1 << 28)) /* HTT */ { uint32_t siblings = 0; uint32_t cpu_cores = 0; uint32_t phys_id = 0; uint32_t core_id = 0; uint32_t initial_apic_id = apic_id; uint32_t logical_bits = 0; /* # of logical core bits in apicid. */ uint32_t ht_bits = 0; /* # of thread bits in apic_id. */ if (is_intel) { bool valid = false; if (maxf >= 0x0000000b) /* topoext supported? */ { uint32_t bits, logical, level, unused; /* Threads */ cpuid (&bits, &logical, &level, &unused, 0x0000000b, 0x00); /* Even if topoext is supposedly supported, it can return "invalid". */ if (bits != 0 && ((level >> 8) & 0xff) == 1) { valid = true; ht_bits = (bits & 0x1f); siblings = (logical & 0xffff); cpu_cores = siblings; for (uint32_t idx = 1; ; ++idx) { cpuid (&bits, &logical, &level, &initial_apic_id, 0x0000000b, idx); uint32_t level_type = ((level >> 8) & 0xff); if (level_type == 0) /* Invalid */ break; if (level_type == 2) /* Core */ { logical_bits = (bits & 0x1f); siblings = (logical & 0xffff); cpu_cores = siblings >> ht_bits; break; } } } } if (!valid && maxf >= 0x00000004) { uint32_t apic_reserved; cpuid (&apic_reserved, &unused, &unused, &unused, 0x00000004, 0x00); if (apic_reserved & 0x1f) { valid = true; cpu_cores = ((apic_reserved >> 26) & 0x3f) + 1; siblings = (extra_info >> 16) & 0xff; if (siblings <= 1) /* HT could be fused out */ { logical_bits = mask_bits (cpu_cores); ht_bits = 0; } else { logical_bits = mask_bits (siblings); ht_bits = mask_bits (siblings / cpu_cores); } } } if (!valid) /* single core, multi thread */ { cpu_cores = 1; siblings = (extra_info >> 16) & 0xff; logical_bits = mask_bits (siblings); ht_bits = logical_bits; } } else if (is_amd) { if (maxe >= 0x8000001e) { uint32_t cus, core_info; cpuid (&unused, &unused, &core_info, &unused, 0x80000008); cpuid (&unused, &cus, &unused, &unused, 0x8000001e); siblings = cpu_cores = (core_info & 0xff) + 1; logical_bits = (core_info >> 12) & 0xf; cus = ((cus >> 8) & 0x3) + 1; ht_bits = mask_bits (cus); } else if (maxe >= 0x80000008) { uint32_t core_info; cpuid (&unused, &unused, &core_info, &unused, 0x80000008); siblings = (core_info & 0xff) + 1; cpu_cores = siblings; logical_bits = (core_info >> 12) & 0xf; if (!logical_bits) logical_bits = mask_bits (siblings); ht_bits = 0; } else { siblings = (extra_info >> 16) & 0xff; cpu_cores = siblings; logical_bits = mask_bits (siblings); ht_bits = 0; } } phys_id = initial_apic_id >> logical_bits; core_id = (initial_apic_id & ((1 << logical_bits) - 1)) >> ht_bits; bufptr += __small_sprintf (bufptr, "physical id\t: %d\n", phys_id); if (siblings > 0) bufptr += __small_sprintf (bufptr, "siblings\t: %u\n", siblings); bufptr += __small_sprintf (bufptr, "core id\t\t: %d\n" "cpu cores\t: %d\n", core_id, cpu_cores); if (features1 & (1 << 9)) /* apic */ bufptr += __small_sprintf (bufptr, "apicid\t\t: %d\n" "initial apicid\t: %d\n", apic_id, initial_apic_id); } /* level is number of non-zero leafs exc. sub-leafs */ int level = maxf + 1 + (maxe & 0x7fffffff) + 1; for (uint32_t l = maxe; 0x80000001 < l; --l) { uint32_t a, b, c, d; cpuid (&a, &b, &c, &d, l); if (!(a | b | c | d)) --level; } for (uint32_t l = maxf; 1 < l; --l) { uint32_t a, b, c, d; cpuid (&a, &b, &c, &d, l); if (!(a | b | c | d)) --level; } bufptr += __small_sprintf (bufptr, "fpu\t\t: %s\n" "fpu_exception\t: %s\n" "cpuid level\t: %d\n" "wp\t\t: yes\n", (features1 & (1 << 0)) ? "yes" : "no", (features1 & (1 << 0)) ? "yes" : "no", level); print ("flags\t\t:"); /* cpuid 0x00000001 edx */ ftcprint (features1, 0, "fpu"); /* x87 floating point */ ftcprint (features1, 1, "vme"); /* VM enhancements */ ftcprint (features1, 2, "de"); /* debugging extensions */ ftcprint (features1, 3, "pse"); /* page size extensions */ ftcprint (features1, 4, "tsc"); /* rdtsc/p */ ftcprint (features1, 5, "msr"); /* rd/wrmsr */ ftcprint (features1, 6, "pae"); /* phy addr extensions */ ftcprint (features1, 7, "mce"); /* Machine check exception */ ftcprint (features1, 8, "cx8"); /* cmpxchg8b */ ftcprint (features1, 9, "apic"); /* APIC enabled */ ftcprint (features1, 11, "sep"); /* sysenter/sysexit */ ftcprint (features1, 12, "mtrr"); /* memory type range registers */ ftcprint (features1, 13, "pge"); /* page global extension */ ftcprint (features1, 14, "mca"); /* machine check architecture */ ftcprint (features1, 15, "cmov"); /* conditional move */ ftcprint (features1, 16, "pat"); /* page attribute table */ ftcprint (features1, 17, "pse36");/* 36 bit page size extensions */ ftcprint (features1, 18, "pn"); /* processor serial number */ ftcprint (features1, 19, "clflush"); /* clflush instruction */ ftcprint (features1, 21, "dts"); /* debug store */ ftcprint (features1, 22, "acpi"); /* ACPI via MSR */ ftcprint (features1, 23, "mmx"); /* multimedia extensions */ ftcprint (features1, 24, "fxsr"); /* fxsave/fxrstor */ ftcprint (features1, 25, "sse"); /* xmm */ ftcprint (features1, 26, "sse2"); /* xmm2 */ ftcprint (features1, 27, "ss"); /* CPU self snoop */ ftcprint (features1, 28, "ht"); /* hyper threading */ ftcprint (features1, 29, "tm"); /* acc automatic clock control */ ftcprint (features1, 30, "ia64"); /* IA 64 processor */ ftcprint (features1, 31, "pbe"); /* pending break enable */ /* AMD cpuid 0x80000001 edx */ if (is_amd && maxe >= 0x80000001) { cpuid (&unused, &unused, &unused, &features1, 0x80000001); ftcprint (features1, 11, "syscall"); /* syscall/sysret */ ftcprint (features1, 19, "mp"); /* MP capable */ ftcprint (features1, 20, "nx"); /* no-execute protection */ ftcprint (features1, 22, "mmxext"); /* MMX extensions */ ftcprint (features1, 25, "fxsr_opt"); /* fxsave/fxrstor optims */ ftcprint (features1, 26, "pdpe1gb"); /* GB large pages */ ftcprint (features1, 27, "rdtscp"); /* rdtscp */ ftcprint (features1, 29, "lm"); /* long mode (x86 64) */ ftcprint (features1, 30, "3dnowext"); /* 3DNow extensions */ ftcprint (features1, 31, "3dnow"); /* 3DNow */ } /* AMD cpuid 0x80000007 edx */ if (is_amd && maxe >= 0x80000007) { cpuid (&unused, &unused, &unused, &features1, 0x80000007); ftcprint (features1, 8, "constant_tsc"); /* TSC constant rate */ ftcprint (features1, 8, "nonstop_tsc"); /* nonstop C states */ } /* cpuid 0x00000006 ecx */ if (maxf >= 0x06) { cpuid (&unused, &unused, &features1, &unused, 0x06); ftcprint (features1, 0, "aperfmperf"); /* P state hw coord fb */ } /* cpuid 0x00000001 ecx */ ftcprint (features2, 0, "pni"); /* xmm3 sse3 */ ftcprint (features2, 1, "pclmuldq"); /* pclmulqdq instruction */ ftcprint (features2, 2, "dtes64"); /* 64-bit debug store */ ftcprint (features2, 3, "monitor"); /* monitor/mwait support */ ftcprint (features2, 4, "ds_cpl"); /* CPL-qual debug store */ ftcprint (features2, 5, "vmx"); /* hardware virtualization */ ftcprint (features2, 6, "smx"); /* safer mode extensions */ ftcprint (features2, 7, "est"); /* enhanced speedstep */ ftcprint (features2, 8, "tm2"); /* thermal monitor 2 */ ftcprint (features2, 9, "ssse3"); /* supplemental sse3 */ ftcprint (features2, 10, "cid"); /* context id */ ftcprint (features2, 11, "sdbg"); /* silicon debug */ ftcprint (features2, 12, "fma"); /* fused multiply add */ ftcprint (features2, 13, "cx16"); /* cmpxchg16b instruction */ ftcprint (features2, 14, "xtpr"); /* send task priority messages */ ftcprint (features2, 15, "pdcm"); /* perf/debug capabilities MSR */ ftcprint (features2, 17, "pcid"); /* process context identifiers */ ftcprint (features2, 18, "dca"); /* direct cache access */ ftcprint (features2, 19, "sse4_1"); /* xmm 4_1 sse 4.1 */ ftcprint (features2, 20, "sse4_2"); /* xmm 4_2 sse 4.2 */ ftcprint (features2, 21, "x2apic"); /* x2 APIC */ ftcprint (features2, 22, "movbe"); /* movbe instruction */ ftcprint (features2, 23, "popcnt"); /* popcnt instruction */ ftcprint (features2, 24, "tsc_deadline_timer"); /* TSC deadline timer */ ftcprint (features2, 25, "aes"); /* AES instructions */ ftcprint (features2, 26, "xsave"); /* xsave/xrstor/xsetbv/xgetbv */ /* ftcprint (features2, 27, "osxsave"); */ /* not output on Linux */ ftcprint (features2, 28, "avx"); /* advanced vector extensions */ ftcprint (features2, 29, "f16c"); /* 16 bit FP conversions */ ftcprint (features2, 30, "rdrand"); /* RNG rdrand instruction */ ftcprint (features2, 31, "hypervisor"); /* hypervisor guest */ /* cpuid 0x80000001 ecx */ if (maxe >= 0x80000001) { cpuid (&unused, &unused, &features1, &unused, 0x80000001); ftcprint (features1, 0, "lahf_lm"); /* l/sahf long mode */ ftcprint (features1, 1, "cmp_legacy"); /* HT not valid */ if (is_amd) { ftcprint (features1, 2, "svm"); /* secure VM */ ftcprint (features1, 3, "extapic"); /* ext APIC space */ ftcprint (features1, 4, "cr8_legacy"); /* CR8 32 bit mode */ ftcprint (features1, 5, "abm"); /* adv bit manip lzcnt */ ftcprint (features1, 6, "sse4a"); /* sse 4a */ ftcprint (features1, 7, "misalignsse"); /* misaligned SSE ok */ ftcprint (features1, 8, "3dnowprefetch"); /* 3DNow prefetch */ ftcprint (features1, 9, "osvw"); /* OS vis workaround */ } ftcprint (features1, 10, "ibs"); /* instr based sampling */ if (is_amd) { ftcprint (features1, 11, "xop"); /* sse 5 extended AVX */ ftcprint (features1, 12, "skinit"); /* skinit/stgi */ ftcprint (features1, 13, "wdt"); /* watchdog timer */ ftcprint (features1, 15, "lwp"); /* light weight prof */ ftcprint (features1, 16, "fma4"); /* 4 operand MAC */ ftcprint (features1, 17, "tce"); /* translat cache ext */ ftcprint (features1, 19, "nodeid_msr"); /* nodeid MSR */ ftcprint (features1, 21, "tbm"); /* trailing bit manip */ ftcprint (features1, 22, "topoext"); /* topology ext */ ftcprint (features1, 23, "perfctr_core"); /* core perf ctr ext */ ftcprint (features1, 24, "perfctr_nb"); /* NB perf ctr ext */ ftcprint (features1, 26, "bpext"); /* data brkpt ext */ ftcprint (features1, 27, "ptsc"); /* perf timestamp ctr */ ftcprint (features1, 28, "perfctr_llc"); /* ll cache perf ctr */ ftcprint (features1, 29, "mwaitx"); /* monitor/mwaitx ext */ } } /* features scattered in various CPUID levels. */ /* cpuid 0x80000007 edx */ if (maxf >= 0x07) { cpuid (&unused, &unused, &unused, &features1, 0x80000007); ftcprint (features1, 9, "cpb"); /* core performance boost */ } /* cpuid 0x00000006 ecx */ if (maxf >= 0x06) { cpuid (&unused, &unused, &features1, &unused, 0x06); ftcprint (features1, 3, "epb"); /* energy perf bias */ } /* cpuid 0x00000010 ebx */ if (maxf >= 0x10) { cpuid (&unused, &features1, &unused, &unused, 0x10); ftcprint (features1, 1, "cat_l3"); /* cache alloc tech l3 */ ftcprint (features1, 2, "cat_l2"); /* cache alloc tech l2 */ /* cpuid 0x00000010:1 ecx */ cpuid (&unused, &unused, &features1, &unused, 0x10, 1); ftcprint (features1, 2, "cdp_l3"); /* code data prior l3 */ } /* cpuid 0x80000007 edx */ if (maxe >= 0x80000007) { cpuid (&unused, &unused, &unused, &features1, 0x80000007); ftcprint (features1, 7, "hw_pstate"); /* hw P state */ ftcprint (features1, 11, "proc_feedback"); /* proc feedback interf */ } /* cpuid 0x8000001f eax */ if (maxe >= 0x8000001f) { cpuid (&features1, &unused, &unused, &unused, 0x8000001f); ftcprint (features1, 0, "sme"); /* secure memory encryption */ } /* cpuid 0x00000010:2 ecx */ if (maxf >= 0x10) { cpuid (&unused, &unused, &features1, &unused, 0x10, 2); ftcprint (features1, 2, "cdp_l2"); /* code data prior l2 */ /* cpuid 0x00000010 ebx */ cpuid (&unused, &features1, &unused, &unused, 0x10); ftcprint (features1, 3, "mba"); /* memory bandwidth alloc */ } /* cpuid 0x80000008 ebx */ if (maxe >= 0x80000008) { cpuid (&unused, &features1, &unused, &unused, 0x80000008); ftcprint (features1, 6, "mba"); /* memory bandwidth alloc */ } /* cpuid 0x8000001f eax */ if (maxe >= 0x8000001f) { cpuid (&features1, &unused, &unused, &unused, 0x8000001f); ftcprint (features1, 1, "sev"); /* secure encrypted virt */ } /* cpuid 0x00000007 ebx */ if (maxf >= 0x07) { cpuid (&unused, &features1, &unused, &unused, 0x07, 0); ftcprint (features1, 0, "fsgsbase"); /* rd/wr fs/gs base */ ftcprint (features1, 1, "tsc_adjust"); /* TSC adjustment MSR 0x3B */ ftcprint (features1, 3, "bmi1"); /* bit manip ext group 1 */ ftcprint (features1, 4, "hle"); /* hardware lock elision */ ftcprint (features1, 5, "avx2"); /* AVX ext instructions */ /* ftcprint (features1, 6, "fpdx"); */ /* FP data ptr upd on exc */ ftcprint (features1, 7, "smep"); /* super mode exec prot */ ftcprint (features1, 8, "bmi2"); /* bit manip ext group 2 */ ftcprint (features1, 9, "erms"); /* enh rep movsb/stosb */ ftcprint (features1, 10, "invpcid"); /* inv proc context id */ ftcprint (features1, 11, "rtm"); /* restricted txnal mem */ ftcprint (features1, 12, "cqm"); /* cache QoS monitoring */ /* ftcprint (features1, 13, "fpcsdsz"); */ /* zero FP cs/ds */ ftcprint (features1, 14, "mpx"); /* mem prot ext */ ftcprint (features1, 15, "rdt_a"); /* rsrc dir tech alloc */ ftcprint (features1, 16, "avx512f"); /* vec foundation */ ftcprint (features1, 17, "avx512dq"); /* vec dq granular */ ftcprint (features1, 18, "rdseed"); /* RNG rdseed instruction */ ftcprint (features1, 19, "adx"); /* adcx/adox */ ftcprint (features1, 20, "smap"); /* sec mode access prev */ ftcprint (features1, 21, "avx512ifma"); /* vec int FMA */ ftcprint (features1, 23, "clflushopt"); /* cache line flush opt */ ftcprint (features1, 24, "clwb"); /* cache line write back */ ftcprint (features1, 25, "intel_pt"); /* intel processor trace */ ftcprint (features1, 26, "avx512pf"); /* vec prefetch */ ftcprint (features1, 27, "avx512er"); /* vec exp/recip aprx */ ftcprint (features1, 28, "avx512cd"); /* vec conflict detect */ ftcprint (features1, 29, "sha_ni"); /* SHA extensions */ ftcprint (features1, 30, "avx512bw"); /* vec byte/word gran */ ftcprint (features1, 31, "avx512vl"); /* vec vec len ext */ } /* more random feature flags */ /* cpuid 0x0000000d:1 eax */ if (maxf >= 0x0d) { cpuid (&features1, &unused, &unused, &unused, 0x0d, 1); ftcprint (features1, 0, "xsaveopt"); /* xsaveopt instruction */ ftcprint (features1, 1, "xsavec"); /* xsavec instruction */ ftcprint (features1, 2, "xgetbv1"); /* xgetbv ecx 1 */ ftcprint (features1, 3, "xsaves"); /* xsaves/xrstors */ } /* cpuid 0x0000000f edx */ if (maxf >= 0x0f) { cpuid (&unused, &unused, &unused, &features1, 0x0f); ftcprint (features1, 1, "cqm_llc"); /* llc QoS */ /* cpuid 0x0000000f:1 edx */ cpuid (&unused, &unused, &unused, &features1, 0x0f, 1); ftcprint (features1, 0, "cqm_occup_llc"); /* llc occup monitor */ ftcprint (features1, 1, "cqm_mbm_total"); /* llc total MBM mon */ ftcprint (features1, 2, "cqm_mbm_local"); /* llc local MBM mon */ } /* cpuid 0x00000007:1 eax */ if (maxf >= 0x07) { cpuid (&features1, &unused, &unused, &unused, 0x07, 1); ftcprint (features1, 5, "avx512_bf16"); /* vec bfloat16 short */ } /* AMD cpuid 0x80000008 ebx */ if (is_amd && maxe >= 0x80000008) { cpuid (&unused, &features1, &unused, &unused, 0x80000008, 0); ftcprint (features1, 0, "clzero"); /* clzero instruction */ ftcprint (features1, 1, "irperf"); /* instr retired count */ ftcprint (features1, 2, "xsaveerptr"); /* save/rest FP err ptrs */ ftcprint (features1, 4, "rdpru"); /* user level rd proc reg */ /* ftcprint (features1, 6, "mba"); */ /* memory BW alloc */ ftcprint (features1, 9, "wbnoinvd"); /* wbnoinvd instruction */ /* ftcprint (features1, 12, "ibpb" ); */ /* ind br pred barrier */ /* ftcprint (features1, 14, "ibrs" ); */ /* ind br restricted spec */ /* ftcprint (features1, 15, "stibp"); */ /* 1 thread ind br pred */ /* ftcprint (features1, 17, "stibp_always_on"); */ /* stibp always on */ /* ftcprint (features1, 24, "ssbd"); */ /* spec store byp dis */ ftcprint (features1, 25, "virt_ssbd"); /* vir spec store byp dis */ /* ftcprint (features1, 26, "ssb_no"); */ /* ssb fixed in hardware */ } /* thermal & power cpuid 0x00000006 eax */ if (maxf >= 0x06) { cpuid (&features1, &unused, &features2, &unused, 0x06); ftcprint (features1, 0, "dtherm"); /* digital thermal sensor */ ftcprint (features1, 1, "ida"); /* Intel dynamic acceleration */ ftcprint (features1, 2, "arat"); /* always running APIC timer */ ftcprint (features1, 4, "pln"); /* power limit notification */ ftcprint (features1, 6, "pts"); /* package thermal status */ ftcprint (features1, 7, "hwp"); /* hardware P states */ ftcprint (features1, 8, "hwp_notify"); /* HWP notification */ ftcprint (features1, 9, "hwp_act_window"); /* HWP activity window */ ftcprint (features1, 10, "hwp_epp"); /* HWP energy perf pref */ ftcprint (features1, 11, "hwp_pkg_req"); /* HWP package level req */ } /* AMD SVM cpuid 0x8000000a edx */ if (is_amd && maxe >= 0x8000000a) { cpuid (&unused, &unused, &unused, &features1, 0x8000000a, 0); ftcprint (features1, 0, "npt"); /* nested paging */ ftcprint (features1, 1, "lbrv"); /* lbr virtualization */ ftcprint (features1, 2, "svm_lock"); /* SVM locking MSR */ ftcprint (features1, 3, "nrip_save"); /* SVM next rip save */ ftcprint (features1, 4, "tsc_scale"); /* TSC rate control */ ftcprint (features1, 5, "vmcb_clean"); /* VMCB clean bits */ ftcprint (features1, 6, "flushbyasid"); /* flush by ASID */ ftcprint (features1, 7, "decode_assists"); /* decode assists */ ftcprint (features1, 10, "pausefilter"); /* filt pause intrcpt */ ftcprint (features1, 12, "pfthreshold"); /* pause filt thresh */ ftcprint (features1, 13, "avic"); /* virt int control */ ftcprint (features1, 15, "v_vmsave_vmload"); /* virt vmsave vmload */ ftcprint (features1, 16, "vgif"); /* virt glb int flag */ } /* Intel cpuid 0x00000007 ecx */ if (is_intel && maxf >= 0x07) { cpuid (&unused, &unused, &features1, &unused, 0x07, 0); ftcprint (features1, 1, "avx512vbmi"); /* vec bit manip */ ftcprint (features1, 2, "umip"); /* user mode ins prot */ ftcprint (features1, 3, "pku"); /* prot key userspace */ ftcprint (features1, 4, "ospke"); /* OS prot keys en */ ftcprint (features1, 5, "waitpkg"); /* umon/umwait/tpause */ ftcprint (features1, 6, "avx512_vbmi2"); /* vec bit manip 2 */ ftcprint (features1, 8, "gfni"); /* Galois field instr */ ftcprint (features1, 9, "vaes"); /* vector AES */ ftcprint (features1, 10, "vpclmulqdq"); /* nc mul dbl quad */ ftcprint (features1, 11, "avx512_vnni"); /* vec neural net */ ftcprint (features1, 12, "avx512_bitalg"); /* vpopcnt/b/w vpshuf */ ftcprint (features1, 13, "tme"); /* total mem encrypt */ ftcprint (features1, 14, "avx512_vpopcntdq"); /* vec popcnt dw/qw */ ftcprint (features1, 16, "la57"); /* 5 level paging */ ftcprint (features1, 22, "rdpid"); /* rdpid instruction */ ftcprint (features1, 25, "cldemote"); /* cldemote instr */ ftcprint (features1, 27, "movdiri"); /* movdiri instr */ ftcprint (features1, 28, "movdir64b"); /* movdir64b instr */ } /* AMD MCA cpuid 0x80000007 ebx */ if (is_amd && maxe >= 0x80000007) { cpuid (&unused, &features1, &unused, &unused, 0x80000007, 0); ftcprint (features1, 0, "overflow_recov"); /* MCA oflow recovery */ ftcprint (features1, 1, "succor"); /* uncor err recovery */ ftcprint (features1, 3, "smca"); /* scalable MCA */ } /* Intel cpuid 0x00000007 edx */ if (is_intel && maxf >= 0x07) { cpuid (&unused, &unused, &unused, &features1, 0x07, 0); ftcprint (features1, 2, "avx512_4vnniw"); /* vec dot prod dw */ ftcprint (features1, 3, "avx512_4fmaps"); /* vec 4 FMA single */ ftcprint (features1, 8, "avx512_vp2intersect"); /* vec intcpt d/q */ ftcprint (features1, 10, "md_clear"); /* verw clear buf */ ftcprint (features1, 18, "pconfig"); /* platform config */ ftcprint (features1, 28, "flush_l1d"); /* flush l1d cache */ ftcprint (features1, 29, "arch_capabilities"); /* arch cap MSR */ } print ("\n"); bufptr += __small_sprintf (bufptr, "bogomips\t: %d.00\n", bogomips); bufptr += __small_sprintf (bufptr, "clflush size\t: %d\n" "cache_alignment\t: %d\n", clflush, cache_alignment); if (maxe >= 0x80000008) /* Address size. */ { uint32_t addr_size, phys, virt; cpuid (&addr_size, &unused, &unused, &unused, 0x80000008); phys = addr_size & 0xff; virt = (addr_size >> 8) & 0xff; /* Fix an errata on Intel CPUs */ if (is_intel && family == 15 && model == 3 && stepping == 4) phys = 36; bufptr += __small_sprintf (bufptr, "address sizes\t: " "%u bits physical, " "%u bits virtual\n", phys, virt); } /* cpuid 0x80000007 edx */ if (maxe >= 0x80000007) /* Advanced power management. */ { cpuid (&unused, &unused, &unused, &features1, 0x80000007); print ("power management:"); ftcprint (features1, 0, "ts"); /* temperature sensor */ ftcprint (features1, 1, "fid"); /* frequency id control */ ftcprint (features1, 2, "vid"); /* voltage id control */ ftcprint (features1, 3, "ttp"); /* thermal trip */ ftcprint (features1, 4, "tm"); /* hw thermal control */ ftcprint (features1, 5, "stc"); /* sw thermal control */ ftcprint (features1, 6, "100mhzsteps"); /* 100 MHz mult control */ ftcprint (features1, 7, "hwpstate"); /* hw P state control */ /* ftcprint (features1, 8, "invariant_tsc"); */ /* TSC invariant */ ftcprint (features1, 9, "cpb"); /* core performance boost */ ftcprint (features1, 10, "eff_freq_ro"); /* ro eff freq interface */ /* ftcprint (features1, 11, "proc_feedback"); */ /* proc feedback if */ /* ftcprint (features1, 12, "acc_power"); */ /* core power reporting */ /* ftcprint (features1, 13, "connstby"); */ /* connected standby */ /* ftcprint (features1, 14, "rapl"); */ /* running average power limit */ } if (orig_affinity_mask != 0) { if (wincap.has_processor_groups ()) SetThreadGroupAffinity (GetCurrentThread (), &orig_group_affinity, NULL); else SetThreadAffinityMask (GetCurrentThread (), orig_affinity_mask); } print ("\n"); } destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_partitions (void *, char *&destbuf) { OBJECT_ATTRIBUTES attr; IO_STATUS_BLOCK io; NTSTATUS status; HANDLE dirhdl; tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; char *ioctl_buf = tp.c_get (); PWCHAR mp_buf = tp.w_get (); WCHAR fpath[MAX_PATH]; WCHAR gpath[MAX_PATH]; DWORD len; /* Open \Device object directory. */ wchar_t wpath[MAX_PATH] = L"\\Device"; UNICODE_STRING upath = {14, 16, wpath}; InitializeObjectAttributes (&attr, &upath, OBJ_CASE_INSENSITIVE, NULL, NULL); status = NtOpenDirectoryObject (&dirhdl, DIRECTORY_QUERY, &attr); if (!NT_SUCCESS (status)) { debug_printf ("NtOpenDirectoryObject, status %y", status); __seterrno_from_nt_status (status); return 0; } /* Traverse \Device directory ... */ PDIRECTORY_BASIC_INFORMATION dbi = (PDIRECTORY_BASIC_INFORMATION) alloca (640); BOOLEAN restart = TRUE; bool got_one = false; ULONG context = 0; while (NT_SUCCESS (NtQueryDirectoryObject (dirhdl, dbi, 640, TRUE, restart, &context, NULL))) { HANDLE devhdl; PARTITION_INFORMATION_EX *pix = NULL; PARTITION_INFORMATION *pi = NULL; DWORD bytes_read; DWORD part_cnt = 0; unsigned long long size; restart = FALSE; /* ... and check for a "Harddisk[0-9]*" entry. */ if (dbi->ObjectName.Length < 9 * sizeof (WCHAR) || wcsncasecmp (dbi->ObjectName.Buffer, L"Harddisk", 8) != 0 || !iswdigit (dbi->ObjectName.Buffer[8])) continue; /* Got it. Now construct the path to the entire disk, which is "\\Device\\HarddiskX\\Partition0", and open the disk with minimum permissions. */ unsigned long drive_num = wcstoul (dbi->ObjectName.Buffer + 8, NULL, 10); wcscpy (wpath, dbi->ObjectName.Buffer); PWCHAR wpart = wpath + dbi->ObjectName.Length / sizeof (WCHAR); wcpcpy (wpart, L"\\Partition0"); upath.Length = dbi->ObjectName.Length + 22; upath.MaximumLength = upath.Length + sizeof (WCHAR); InitializeObjectAttributes (&attr, &upath, OBJ_CASE_INSENSITIVE, dirhdl, NULL); status = NtOpenFile (&devhdl, READ_CONTROL, &attr, &io, FILE_SHARE_VALID_FLAGS, 0); if (!NT_SUCCESS (status)) { debug_printf ("NtOpenFile(%S), status %y", &upath, status); __seterrno_from_nt_status (status); continue; } if (!got_one) { print ("major minor #blocks name win-mounts\n\n"); got_one = true; } /* Fetch partition info for the entire disk to get its size. */ if (DeviceIoControl (devhdl, IOCTL_DISK_GET_PARTITION_INFO_EX, NULL, 0, ioctl_buf, NT_MAX_PATH, &bytes_read, NULL)) { pix = (PARTITION_INFORMATION_EX *) ioctl_buf; size = pix->PartitionLength.QuadPart; } else if (DeviceIoControl (devhdl, IOCTL_DISK_GET_PARTITION_INFO, NULL, 0, ioctl_buf, NT_MAX_PATH, &bytes_read, NULL)) { pi = (PARTITION_INFORMATION *) ioctl_buf; size = pi->PartitionLength.QuadPart; } else { debug_printf ("DeviceIoControl (%S, " "IOCTL_DISK_GET_PARTITION_INFO{_EX}) %E", &upath); size = 0; } device dev (drive_num, 0); bufptr += __small_sprintf (bufptr, "%5d %5d %9U %s\n", dev.get_major (), dev.get_minor (), size >> 10, dev.name () + 5); /* Fetch drive layout info to get size of all partitions on the disk. */ if (DeviceIoControl (devhdl, IOCTL_DISK_GET_DRIVE_LAYOUT_EX, NULL, 0, ioctl_buf, NT_MAX_PATH, &bytes_read, NULL)) { PDRIVE_LAYOUT_INFORMATION_EX pdlix = (PDRIVE_LAYOUT_INFORMATION_EX) ioctl_buf; part_cnt = pdlix->PartitionCount; pix = pdlix->PartitionEntry; } else if (DeviceIoControl (devhdl, IOCTL_DISK_GET_DRIVE_LAYOUT, NULL, 0, ioctl_buf, NT_MAX_PATH, &bytes_read, NULL)) { PDRIVE_LAYOUT_INFORMATION pdli = (PDRIVE_LAYOUT_INFORMATION) ioctl_buf; part_cnt = pdli->PartitionCount; pi = pdli->PartitionEntry; } else debug_printf ("DeviceIoControl(%S, " "IOCTL_DISK_GET_DRIVE_LAYOUT{_EX}): %E", &upath); /* Loop over partitions. */ if (pix || pi) for (DWORD i = 0; i < part_cnt && i < 64; ++i) { DWORD part_num; if (pix) { size = pix->PartitionLength.QuadPart; part_num = pix->PartitionNumber; ++pix; } else { size = pi->PartitionLength.QuadPart; part_num = pi->PartitionNumber; ++pi; } /* A partition number of 0 denotes an extended partition or a filler entry as described in fhandler_dev_floppy::lock_partition. Just skip. */ if (part_num == 0) continue; device dev (drive_num, part_num); bufptr += __small_sprintf (bufptr, "%5d %5d %9U %s", dev.get_major (), dev.get_minor (), size >> 10, dev.name () + 5); /* Check if the partition is mounted in Windows and, if so, print the mount point list. */ __small_swprintf (fpath, L"\\\\?\\GLOBALROOT\\Device\\%S\\Partition%u\\", &dbi->ObjectName, part_num); if (GetVolumeNameForVolumeMountPointW (fpath, gpath, MAX_PATH) && GetVolumePathNamesForVolumeNameW (gpath, mp_buf, NT_MAX_PATH, &len)) { len = strlen (dev.name () + 5); while (len++ < 6) *bufptr++ = ' '; for (PWCHAR p = mp_buf; *p; p = wcschr (p, L'\0') + 1) bufptr += __small_sprintf (bufptr, " %W", p); } *bufptr++ = '\n'; } NtClose (devhdl); } NtClose (dirhdl); if (!got_one) return 0; destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_self (void *, char *&destbuf) { destbuf = (char *) crealloc_abort (destbuf, 16); return __small_sprintf (destbuf, "%d", getpid ()); } static off_t format_proc_cygdrive (void *, char *&destbuf) { destbuf = (char *) crealloc_abort (destbuf, mount_table->cygdrive_len + 1); char *dend = stpcpy (destbuf, mount_table->cygdrive); if (dend > destbuf + 1) /* cygdrive != "/"? */ *--dend = '\0'; return dend - destbuf; } static off_t format_proc_mounts (void *, char *&destbuf) { destbuf = (char *) crealloc_abort (destbuf, sizeof ("self/mounts")); return __small_sprintf (destbuf, "self/mounts"); } static off_t format_proc_filesystems (void *, char *&destbuf) { tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; /* start at 1 to skip type "none" */ for (int i = 1; fs_names[i].name; i++) bufptr += __small_sprintf(bufptr, "%s\t%s\n", fs_names[i].block_device ? "" : "nodev", fs_names[i].name); destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_swaps (void *, char *&destbuf) { unsigned long long total = 0ULL, used = 0ULL; PSYSTEM_PAGEFILE_INFORMATION spi = NULL; ULONG size = 512; NTSTATUS status = STATUS_SUCCESS; tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; spi = (PSYSTEM_PAGEFILE_INFORMATION) malloc (size); if (spi) { status = NtQuerySystemInformation (SystemPagefileInformation, (PVOID) spi, size, &size); if (status == STATUS_INFO_LENGTH_MISMATCH) { free (spi); spi = (PSYSTEM_PAGEFILE_INFORMATION) malloc (size); if (spi) status = NtQuerySystemInformation (SystemPagefileInformation, (PVOID) spi, size, &size); } } bufptr += __small_sprintf (bufptr, "Filename\t\t\t\tType\t\tSize\tUsed\tPriority\n"); if (spi && NT_SUCCESS (status)) { PSYSTEM_PAGEFILE_INFORMATION spp = spi; char *filename = tp.c_get (); do { total = (unsigned long long) spp->CurrentSize * wincap.page_size (); used = (unsigned long long) spp->TotalUsed * wincap.page_size (); cygwin_conv_path (CCP_WIN_W_TO_POSIX, spp->FileName.Buffer, filename, NT_MAX_PATH); bufptr += sprintf (bufptr, "%-40s%-16s%-8llu%-8llu%-8d\n", filename, "file", total >> 10, used >> 10, 0); } while (spp->NextEntryOffset && (spp = (PSYSTEM_PAGEFILE_INFORMATION) ((char *) spp + spp->NextEntryOffset))); } if (spi) free (spi); destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_devices (void *, char *&destbuf) { tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; bufptr += __small_sprintf (bufptr, "Character devices:\n" "%3d mem\n" "%3d cons\n" "%3d /dev/tty\n" "%3d /dev/console\n" "%3d /dev/ptmx\n" "%3d st\n" "%3d misc\n" "%3d sound\n" "%3d ttyS\n" "%3d tty\n" "\n" "Block devices:\n" "%3d fd\n" "%3d sd\n" "%3d sr\n" "%3d sd\n" "%3d sd\n" "%3d sd\n" "%3d sd\n" "%3d sd\n" "%3d sd\n" "%3d sd\n", DEV_MEM_MAJOR, DEV_CONS_MAJOR, _major (FH_TTY), _major (FH_CONSOLE), _major (FH_PTMX), DEV_TAPE_MAJOR, DEV_MISC_MAJOR, DEV_SOUND_MAJOR, DEV_SERIAL_MAJOR, DEV_PTYS_MAJOR, DEV_FLOPPY_MAJOR, DEV_SD_MAJOR, DEV_CDROM_MAJOR, DEV_SD1_MAJOR, DEV_SD2_MAJOR, DEV_SD3_MAJOR, DEV_SD4_MAJOR, DEV_SD5_MAJOR, DEV_SD6_MAJOR, DEV_SD7_MAJOR); destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } static off_t format_proc_misc (void *, char *&destbuf) { tmp_pathbuf tp; char *buf = tp.c_get (); char *bufptr = buf; bufptr += __small_sprintf (bufptr, "%3d clipboard\n" "%3d windows\n", _minor (FH_CLIPBOARD), _minor (FH_WINDOWS)); destbuf = (char *) crealloc_abort (destbuf, bufptr - buf); memcpy (destbuf, buf, bufptr - buf); return bufptr - buf; } #undef print