// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2022 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include // IWYU pragma: keep #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include // must go before a number of other headers #ifdef WIN32 #include #include #else #include #include #include #include #include #include #include #include #endif #if HAVE_DECL_GETIFADDRS && HAVE_DECL_FREEIFADDRS #include #endif #ifdef HAVE_SYSCTL #include #ifdef HAVE_VM_VM_PARAM_H #include #endif #ifdef HAVE_SYS_RESOURCES_H #include #endif #ifdef HAVE_SYS_VMMETER_H #include #endif #endif #if defined(HAVE_STRONG_GETAUXVAL) #include #endif #ifndef _MSC_VER extern char** environ; // NOLINT(readability-redundant-declaration): Necessary on some platforms #endif namespace { void RandAddSeedPerfmon(CSHA512& hasher) { #ifdef WIN32 // Seed with the entire set of perfmon data // This can take up to 2 seconds, so only do it every 10 minutes. // Initialize last_perfmon to 0 seconds, we don't skip the first call. static std::atomic last_perfmon{SteadyClock::time_point{0s}}; auto last_time = last_perfmon.load(); auto current_time = SteadyClock::now(); if (current_time < last_time + 10min) return; last_perfmon = current_time; std::vector vData(250000, 0); long ret = 0; unsigned long nSize = 0; const size_t nMaxSize = 10000000; // Bail out at more than 10MB of performance data while (true) { nSize = vData.size(); ret = RegQueryValueExA(HKEY_PERFORMANCE_DATA, "Global", nullptr, nullptr, vData.data(), &nSize); if (ret != ERROR_MORE_DATA || vData.size() >= nMaxSize) break; vData.resize(std::min((vData.size() * 3) / 2, nMaxSize)); // Grow size of buffer exponentially } RegCloseKey(HKEY_PERFORMANCE_DATA); if (ret == ERROR_SUCCESS) { hasher.Write(vData.data(), nSize); memory_cleanse(vData.data(), nSize); } else { // Performance data is only a best-effort attempt at improving the // situation when the OS randomness (and other sources) aren't // adequate. As a result, failure to read it is isn't considered critical, // so we don't call RandFailure(). // TODO: Add logging when the logger is made functional before global // constructors have been invoked. } #endif } /** Helper to easily feed data into a CSHA512. * * Note that this does not serialize the passed object (like stream.h's << operators do). * Its raw memory representation is used directly. */ template CSHA512& operator<<(CSHA512& hasher, const T& data) { static_assert(!std::is_same::type, char*>::value, "Calling operator<<(CSHA512, char*) is probably not what you want"); static_assert(!std::is_same::type, unsigned char*>::value, "Calling operator<<(CSHA512, unsigned char*) is probably not what you want"); static_assert(!std::is_same::type, const char*>::value, "Calling operator<<(CSHA512, const char*) is probably not what you want"); static_assert(!std::is_same::type, const unsigned char*>::value, "Calling operator<<(CSHA512, const unsigned char*) is probably not what you want"); hasher.Write((const unsigned char*)&data, sizeof(data)); return hasher; } #ifndef WIN32 void AddSockaddr(CSHA512& hasher, const struct sockaddr *addr) { if (addr == nullptr) return; switch (addr->sa_family) { case AF_INET: hasher.Write((const unsigned char*)addr, sizeof(sockaddr_in)); break; case AF_INET6: hasher.Write((const unsigned char*)addr, sizeof(sockaddr_in6)); break; default: hasher.Write((const unsigned char*)&addr->sa_family, sizeof(addr->sa_family)); } } void AddFile(CSHA512& hasher, const char *path) { struct stat sb = {}; int f = open(path, O_RDONLY); size_t total = 0; if (f != -1) { unsigned char fbuf[4096]; int n; hasher.Write((const unsigned char*)&f, sizeof(f)); if (fstat(f, &sb) == 0) hasher << sb; do { n = read(f, fbuf, sizeof(fbuf)); if (n > 0) hasher.Write(fbuf, n); total += n; /* not bothering with EINTR handling. */ } while (n == sizeof(fbuf) && total < 1048576); // Read only the first 1 Mbyte close(f); } } void AddPath(CSHA512& hasher, const char *path) { struct stat sb = {}; if (stat(path, &sb) == 0) { hasher.Write((const unsigned char*)path, strlen(path) + 1); hasher << sb; } } #endif #ifdef HAVE_SYSCTL template void AddSysctl(CSHA512& hasher) { int CTL[sizeof...(S)] = {S...}; unsigned char buffer[65536]; size_t siz = 65536; int ret = sysctl(CTL, sizeof...(S), buffer, &siz, nullptr, 0); if (ret == 0 || (ret == -1 && errno == ENOMEM)) { hasher << sizeof(CTL); hasher.Write((const unsigned char*)CTL, sizeof(CTL)); if (siz > sizeof(buffer)) siz = sizeof(buffer); hasher << siz; hasher.Write(buffer, siz); } } #endif #ifdef HAVE_GETCPUID void inline AddCPUID(CSHA512& hasher, uint32_t leaf, uint32_t subleaf, uint32_t& ax, uint32_t& bx, uint32_t& cx, uint32_t& dx) { GetCPUID(leaf, subleaf, ax, bx, cx, dx); hasher << leaf << subleaf << ax << bx << cx << dx; } void AddAllCPUID(CSHA512& hasher) { uint32_t ax, bx, cx, dx; // Iterate over all standard leaves AddCPUID(hasher, 0, 0, ax, bx, cx, dx); // Returns max leaf in ax uint32_t max = ax; for (uint32_t leaf = 1; leaf <= max && leaf <= 0xFF; ++leaf) { uint32_t maxsub = 0; for (uint32_t subleaf = 0; subleaf <= 0xFF; ++subleaf) { AddCPUID(hasher, leaf, subleaf, ax, bx, cx, dx); // Iterate subleafs for leaf values 4, 7, 11, 13 if (leaf == 4) { if ((ax & 0x1f) == 0) break; } else if (leaf == 7) { if (subleaf == 0) maxsub = ax; if (subleaf == maxsub) break; } else if (leaf == 11) { if ((cx & 0xff00) == 0) break; } else if (leaf == 13) { if (ax == 0 && bx == 0 && cx == 0 && dx == 0) break; } else { // For any other leaf, stop after subleaf 0. break; } } } // Iterate over all extended leaves AddCPUID(hasher, 0x80000000, 0, ax, bx, cx, dx); // Returns max extended leaf in ax uint32_t ext_max = ax; for (uint32_t leaf = 0x80000001; leaf <= ext_max && leaf <= 0x800000FF; ++leaf) { AddCPUID(hasher, leaf, 0, ax, bx, cx, dx); } } #endif } // namespace void RandAddDynamicEnv(CSHA512& hasher) { RandAddSeedPerfmon(hasher); // Various clocks #ifdef WIN32 FILETIME ftime; GetSystemTimeAsFileTime(&ftime); hasher << ftime; #else struct timespec ts = {}; # ifdef CLOCK_MONOTONIC clock_gettime(CLOCK_MONOTONIC, &ts); hasher << ts; # endif # ifdef CLOCK_REALTIME clock_gettime(CLOCK_REALTIME, &ts); hasher << ts; # endif # ifdef CLOCK_BOOTTIME clock_gettime(CLOCK_BOOTTIME, &ts); hasher << ts; # endif // gettimeofday is available on all UNIX systems, but only has microsecond precision. struct timeval tv = {}; gettimeofday(&tv, nullptr); hasher << tv; #endif // Probably redundant, but also use all the standard library clocks: hasher << std::chrono::system_clock::now().time_since_epoch().count(); hasher << std::chrono::steady_clock::now().time_since_epoch().count(); hasher << std::chrono::high_resolution_clock::now().time_since_epoch().count(); #ifndef WIN32 // Current resource usage. struct rusage usage = {}; if (getrusage(RUSAGE_SELF, &usage) == 0) hasher << usage; #endif #ifdef __linux__ AddFile(hasher, "/proc/diskstats"); AddFile(hasher, "/proc/vmstat"); AddFile(hasher, "/proc/schedstat"); AddFile(hasher, "/proc/zoneinfo"); AddFile(hasher, "/proc/meminfo"); AddFile(hasher, "/proc/softirqs"); AddFile(hasher, "/proc/stat"); AddFile(hasher, "/proc/self/schedstat"); AddFile(hasher, "/proc/self/status"); #endif #ifdef HAVE_SYSCTL # ifdef CTL_KERN # if defined(KERN_PROC) && defined(KERN_PROC_ALL) AddSysctl(hasher); # endif # endif # ifdef CTL_HW # ifdef HW_DISKSTATS AddSysctl(hasher); # endif # endif # ifdef CTL_VM # ifdef VM_LOADAVG AddSysctl(hasher); # endif # ifdef VM_TOTAL AddSysctl(hasher); # endif # ifdef VM_METER AddSysctl(hasher); # endif # endif #endif // Stack and heap location void* addr = malloc(4097); hasher << &addr << addr; free(addr); } void RandAddStaticEnv(CSHA512& hasher) { // Some compile-time static properties hasher << (CHAR_MIN < 0) << sizeof(void*) << sizeof(long) << sizeof(int); #if defined(__GNUC__) && defined(__GNUC_MINOR__) && defined(__GNUC_PATCHLEVEL__) hasher << __GNUC__ << __GNUC_MINOR__ << __GNUC_PATCHLEVEL__; #endif #ifdef _MSC_VER hasher << _MSC_VER; #endif hasher << __cplusplus; #ifdef _XOPEN_VERSION hasher << _XOPEN_VERSION; #endif #ifdef __VERSION__ const char* COMPILER_VERSION = __VERSION__; hasher.Write((const unsigned char*)COMPILER_VERSION, strlen(COMPILER_VERSION) + 1); #endif // Bitcoin client version hasher << CLIENT_VERSION; #if defined(HAVE_STRONG_GETAUXVAL) // Information available through getauxval() # ifdef AT_HWCAP hasher << getauxval(AT_HWCAP); # endif # ifdef AT_HWCAP2 hasher << getauxval(AT_HWCAP2); # endif # ifdef AT_RANDOM const unsigned char* random_aux = (const unsigned char*)getauxval(AT_RANDOM); if (random_aux) hasher.Write(random_aux, 16); # endif # ifdef AT_PLATFORM const char* platform_str = (const char*)getauxval(AT_PLATFORM); if (platform_str) hasher.Write((const unsigned char*)platform_str, strlen(platform_str) + 1); # endif # ifdef AT_EXECFN const char* exec_str = (const char*)getauxval(AT_EXECFN); if (exec_str) hasher.Write((const unsigned char*)exec_str, strlen(exec_str) + 1); # endif #endif // HAVE_STRONG_GETAUXVAL #ifdef HAVE_GETCPUID AddAllCPUID(hasher); #endif // Memory locations hasher << &hasher << &RandAddStaticEnv << &malloc << &errno << &environ; // Hostname #ifdef WIN32 constexpr DWORD max_size = MAX_COMPUTERNAME_LENGTH + 1; char hname[max_size]; DWORD size = max_size; if (GetComputerNameA(hname, &size) != 0) { hasher.Write(UCharCast(hname), size); } #else char hname[256]; if (gethostname(hname, 256) == 0) { hasher.Write((const unsigned char*)hname, strnlen(hname, 256)); } #endif #if HAVE_DECL_GETIFADDRS && HAVE_DECL_FREEIFADDRS // Network interfaces struct ifaddrs *ifad = nullptr; getifaddrs(&ifad); struct ifaddrs *ifit = ifad; while (ifit != nullptr) { hasher.Write((const unsigned char*)&ifit, sizeof(ifit)); hasher.Write((const unsigned char*)ifit->ifa_name, strlen(ifit->ifa_name) + 1); hasher.Write((const unsigned char*)&ifit->ifa_flags, sizeof(ifit->ifa_flags)); AddSockaddr(hasher, ifit->ifa_addr); AddSockaddr(hasher, ifit->ifa_netmask); AddSockaddr(hasher, ifit->ifa_dstaddr); ifit = ifit->ifa_next; } freeifaddrs(ifad); #endif #ifndef WIN32 // UNIX kernel information struct utsname name; if (uname(&name) != -1) { hasher.Write((const unsigned char*)&name.sysname, strlen(name.sysname) + 1); hasher.Write((const unsigned char*)&name.nodename, strlen(name.nodename) + 1); hasher.Write((const unsigned char*)&name.release, strlen(name.release) + 1); hasher.Write((const unsigned char*)&name.version, strlen(name.version) + 1); hasher.Write((const unsigned char*)&name.machine, strlen(name.machine) + 1); } /* Path and filesystem provided data */ AddPath(hasher, "/"); AddPath(hasher, "."); AddPath(hasher, "/tmp"); AddPath(hasher, "/home"); AddPath(hasher, "/proc"); #ifdef __linux__ AddFile(hasher, "/proc/cmdline"); AddFile(hasher, "/proc/cpuinfo"); AddFile(hasher, "/proc/version"); #endif AddFile(hasher, "/etc/passwd"); AddFile(hasher, "/etc/group"); AddFile(hasher, "/etc/hosts"); AddFile(hasher, "/etc/resolv.conf"); AddFile(hasher, "/etc/timezone"); AddFile(hasher, "/etc/localtime"); #endif // For MacOS/BSDs, gather data through sysctl instead of /proc. Not all of these // will exist on every system. #ifdef HAVE_SYSCTL # ifdef CTL_HW # ifdef HW_MACHINE AddSysctl(hasher); # endif # ifdef HW_MODEL AddSysctl(hasher); # endif # ifdef HW_NCPU AddSysctl(hasher); # endif # ifdef HW_PHYSMEM AddSysctl(hasher); # endif # ifdef HW_USERMEM AddSysctl(hasher); # endif # ifdef HW_MACHINE_ARCH AddSysctl(hasher); # endif # ifdef HW_REALMEM AddSysctl(hasher); # endif # ifdef HW_CPU_FREQ AddSysctl(hasher); # endif # ifdef HW_BUS_FREQ AddSysctl(hasher); # endif # ifdef HW_CACHELINE AddSysctl(hasher); # endif # endif # ifdef CTL_KERN # ifdef KERN_BOOTFILE AddSysctl(hasher); # endif # ifdef KERN_BOOTTIME AddSysctl(hasher); # endif # ifdef KERN_CLOCKRATE AddSysctl(hasher); # endif # ifdef KERN_HOSTID AddSysctl(hasher); # endif # ifdef KERN_HOSTUUID AddSysctl(hasher); # endif # ifdef KERN_HOSTNAME AddSysctl(hasher); # endif # ifdef KERN_OSRELDATE AddSysctl(hasher); # endif # ifdef KERN_OSRELEASE AddSysctl(hasher); # endif # ifdef KERN_OSREV AddSysctl(hasher); # endif # ifdef KERN_OSTYPE AddSysctl(hasher); # endif # ifdef KERN_POSIX1 AddSysctl(hasher); # endif # ifdef KERN_VERSION AddSysctl(hasher); # endif # endif #endif // Env variables if (environ) { for (size_t i = 0; environ[i]; ++i) { hasher.Write((const unsigned char*)environ[i], strlen(environ[i])); } } // Process, thread, user, session, group, ... ids. #ifdef WIN32 hasher << GetCurrentProcessId() << GetCurrentThreadId(); #else hasher << getpid() << getppid() << getsid(0) << getpgid(0) << getuid() << geteuid() << getgid() << getegid(); #endif hasher << std::this_thread::get_id(); }