utils/google-benchmark/src/sysinfo.cc - llvm-project/libcxx - Git at Google

 // Copyright 2015 Google Inc. All rights reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #include "internal_macros.h"

 #ifdef BENCHMARK_OS_WINDOWS
 #include <shlwapi.h>
 #undef StrCat  // Don't let StrCat in string_util.h be renamed to lstrcatA
 #include <versionhelpers.h>
 #include <windows.h>
 #include <codecvt>
 #else
 #include <fcntl.h>
 #ifndef BENCHMARK_OS_FUCHSIA
 #include <sys/resource.h>
 #endif
 #include <sys/time.h>
 #include <sys/types.h>  // this header must be included before 'sys/sysctl.h' to avoid compilation error on FreeBSD
 #include <unistd.h>
 #if defined BENCHMARK_OS_FREEBSD || defined BENCHMARK_OS_MACOSX || \
     defined BENCHMARK_OS_NETBSD || defined BENCHMARK_OS_OPENBSD || \
     defined BENCHMARK_OS_DRAGONFLY
 #define BENCHMARK_HAS_SYSCTL
 #include <sys/sysctl.h>
 #endif
 #endif
 #if defined(BENCHMARK_OS_SOLARIS)
 #include <kstat.h>
 #endif
 #if defined(BENCHMARK_OS_QNX)
 #include <sys/syspage.h>
 #endif

 #include <algorithm>
 #include <array>
 #include <bitset>
 #include <cerrno>
 #include <climits>
 #include <cstdint>
 #include <cstdio>
 #include <cstdlib>
 #include <cstring>
 #include <fstream>
 #include <iostream>
 #include <iterator>
 #include <limits>
 #include <memory>
 #include <sstream>
 #include <locale>
 #include <utility>

 #include "check.h"
 #include "cycleclock.h"
 #include "internal_macros.h"
 #include "log.h"
 #include "sleep.h"
 #include "string_util.h"

 namespace benchmark {
 namespace {

 void PrintImp(std::ostream& out) { out << std::endl; }

 template <class First, class... Rest>
 void PrintImp(std::ostream& out, First&& f, Rest&&... rest) {
   out << std::forward<First>(f);
   PrintImp(out, std::forward<Rest>(rest)...);
 }

 template <class... Args>
 BENCHMARK_NORETURN void PrintErrorAndDie(Args&&... args) {
   PrintImp(std::cerr, std::forward<Args>(args)...);
   std::exit(EXIT_FAILURE);
 }

 #ifdef BENCHMARK_HAS_SYSCTL

 /// ValueUnion - A type used to correctly alias the byte-for-byte output of
 /// `sysctl` with the result type it's to be interpreted as.
 struct ValueUnion {
   union DataT {
     uint32_t uint32_value;
     uint64_t uint64_value;
     // For correct aliasing of union members from bytes.
     char bytes[8];
   };
   using DataPtr = std::unique_ptr<DataT, decltype(&std::free)>;

   // The size of the data union member + its trailing array size.
   size_t Size;
   DataPtr Buff;

  public:
   ValueUnion() : Size(0), Buff(nullptr, &std::free) {}

   explicit ValueUnion(size_t BuffSize)
       : Size(sizeof(DataT) + BuffSize),
         Buff(::new (std::malloc(Size)) DataT(), &std::free) {}

   ValueUnion(ValueUnion&& other) = default;

   explicit operator bool() const { return bool(Buff); }

   char* data() const { return Buff->bytes; }

   std::string GetAsString() const { return std::string(data()); }

   int64_t GetAsInteger() const {
     if (Size == sizeof(Buff->uint32_value))
       return static_cast<int32_t>(Buff->uint32_value);
     else if (Size == sizeof(Buff->uint64_value))
       return static_cast<int64_t>(Buff->uint64_value);
     BENCHMARK_UNREACHABLE();
   }

   uint64_t GetAsUnsigned() const {
     if (Size == sizeof(Buff->uint32_value))
       return Buff->uint32_value;
     else if (Size == sizeof(Buff->uint64_value))
       return Buff->uint64_value;
     BENCHMARK_UNREACHABLE();
   }

   template <class T, int N>
   std::array<T, N> GetAsArray() {
     const int ArrSize = sizeof(T) * N;
     CHECK_LE(ArrSize, Size);
     std::array<T, N> Arr;
     std::memcpy(Arr.data(), data(), ArrSize);
     return Arr;
   }
 };

 ValueUnion GetSysctlImp(std::string const& Name) {
 #if defined BENCHMARK_OS_OPENBSD
   int mib[2];

   mib[0] = CTL_HW;
   if ((Name == "hw.ncpu") || (Name == "hw.cpuspeed")){
     ValueUnion buff(sizeof(int));

     if (Name == "hw.ncpu") {
       mib[1] = HW_NCPU;
     } else {
       mib[1] = HW_CPUSPEED;
     }

     if (sysctl(mib, 2, buff.data(), &buff.Size, nullptr, 0) == -1) {
       return ValueUnion();
     }
     return buff;
   }
   return ValueUnion();
 #else
   size_t CurBuffSize = 0;
   if (sysctlbyname(Name.c_str(), nullptr, &CurBuffSize, nullptr, 0) == -1)
     return ValueUnion();

   ValueUnion buff(CurBuffSize);
   if (sysctlbyname(Name.c_str(), buff.data(), &buff.Size, nullptr, 0) == 0)
     return buff;
   return ValueUnion();
 #endif
 }

 BENCHMARK_MAYBE_UNUSED
 bool GetSysctl(std::string const& Name, std::string* Out) {
   Out->clear();
   auto Buff = GetSysctlImp(Name);
   if (!Buff) return false;
   Out->assign(Buff.data());
   return true;
 }

 template <class Tp,
           class = typename std::enable_if<std::is_integral<Tp>::value>::type>
 bool GetSysctl(std::string const& Name, Tp* Out) {
   *Out = 0;
   auto Buff = GetSysctlImp(Name);
   if (!Buff) return false;
   *Out = static_cast<Tp>(Buff.GetAsUnsigned());
   return true;
 }

 template <class Tp, size_t N>
 bool GetSysctl(std::string const& Name, std::array<Tp, N>* Out) {
   auto Buff = GetSysctlImp(Name);
   if (!Buff) return false;
   *Out = Buff.GetAsArray<Tp, N>();
   return true;
 }
 #endif

 template <class ArgT>
 bool ReadFromFile(std::string const& fname, ArgT* arg) {
   *arg = ArgT();
   std::ifstream f(fname.c_str());
   if (!f.is_open()) return false;
   f >> *arg;
   return f.good();
 }

 CPUInfo::Scaling CpuScaling(int num_cpus) {
   // We don't have a valid CPU count, so don't even bother.
   if (num_cpus <= 0) return CPUInfo::Scaling::UNKNOWN;
 #ifdef BENCHMARK_OS_QNX
   return CPUInfo::Scaling::UNKNOWN;
 #endif
 #ifndef BENCHMARK_OS_WINDOWS
   // On Linux, the CPUfreq subsystem exposes CPU information as files on the
   // local file system. If reading the exported files fails, then we may not be
   // running on Linux, so we silently ignore all the read errors.
   std::string res;
   for (int cpu = 0; cpu < num_cpus; ++cpu) {
     std::string governor_file =
         StrCat("/sys/devices/system/cpu/cpu", cpu, "/cpufreq/scaling_governor");
     if (ReadFromFile(governor_file, &res) && res != "performance") return CPUInfo::Scaling::ENABLED;
   }
   return CPUInfo::Scaling::DISABLED;
 #endif
   return CPUInfo::Scaling::UNKNOWN;
 }

 int CountSetBitsInCPUMap(std::string Val) {
   auto CountBits = [](std::string Part) {
     using CPUMask = std::bitset<sizeof(std::uintptr_t) * CHAR_BIT>;
     Part = "0x" + Part;
     CPUMask Mask(benchmark::stoul(Part, nullptr, 16));
     return static_cast<int>(Mask.count());
   };
   size_t Pos;
   int total = 0;
   while ((Pos = Val.find(',')) != std::string::npos) {
     total += CountBits(Val.substr(0, Pos));
     Val = Val.substr(Pos + 1);
   }
   if (!Val.empty()) {
     total += CountBits(Val);
   }
   return total;
 }

 BENCHMARK_MAYBE_UNUSED
 std::vector<CPUInfo::CacheInfo> GetCacheSizesFromKVFS() {
   std::vector<CPUInfo::CacheInfo> res;
   std::string dir = "/sys/devices/system/cpu/cpu0/cache/";
   int Idx = 0;
   while (true) {
     CPUInfo::CacheInfo info;
     std::string FPath = StrCat(dir, "index", Idx++, "/");
     std::ifstream f(StrCat(FPath, "size").c_str());
     if (!f.is_open()) break;
     std::string suffix;
     f >> info.size;
     if (f.fail())
       PrintErrorAndDie("Failed while reading file '", FPath, "size'");
     if (f.good()) {
       f >> suffix;
       if (f.bad())
         PrintErrorAndDie(
             "Invalid cache size format: failed to read size suffix");
       else if (f && suffix != "K")
         PrintErrorAndDie("Invalid cache size format: Expected bytes ", suffix);
       else if (suffix == "K")
         info.size *= 1024;
     }
     if (!ReadFromFile(StrCat(FPath, "type"), &info.type))
       PrintErrorAndDie("Failed to read from file ", FPath, "type");
     if (!ReadFromFile(StrCat(FPath, "level"), &info.level))
       PrintErrorAndDie("Failed to read from file ", FPath, "level");
     std::string map_str;
     if (!ReadFromFile(StrCat(FPath, "shared_cpu_map"), &map_str))
       PrintErrorAndDie("Failed to read from file ", FPath, "shared_cpu_map");
     info.num_sharing = CountSetBitsInCPUMap(map_str);
     res.push_back(info);
   }

   return res;
 }

 #ifdef BENCHMARK_OS_MACOSX
 std::vector<CPUInfo::CacheInfo> GetCacheSizesMacOSX() {
   std::vector<CPUInfo::CacheInfo> res;
   std::array<uint64_t, 4> CacheCounts{{0, 0, 0, 0}};
   GetSysctl("hw.cacheconfig", &CacheCounts);

   struct {
     std::string name;
     std::string type;
     int level;
     uint64_t num_sharing;
   } Cases[] = {{"hw.l1dcachesize", "Data", 1, CacheCounts[1]},
                {"hw.l1icachesize", "Instruction", 1, CacheCounts[1]},
                {"hw.l2cachesize", "Unified", 2, CacheCounts[2]},
                {"hw.l3cachesize", "Unified", 3, CacheCounts[3]}};
   for (auto& C : Cases) {
     int val;
     if (!GetSysctl(C.name, &val)) continue;
     CPUInfo::CacheInfo info;
     info.type = C.type;
     info.level = C.level;
     info.size = val;
     info.num_sharing = static_cast<int>(C.num_sharing);
     res.push_back(std::move(info));
   }
   return res;
 }
 #elif defined(BENCHMARK_OS_WINDOWS)
 std::vector<CPUInfo::CacheInfo> GetCacheSizesWindows() {
   std::vector<CPUInfo::CacheInfo> res;
   DWORD buffer_size = 0;
   using PInfo = SYSTEM_LOGICAL_PROCESSOR_INFORMATION;
   using CInfo = CACHE_DESCRIPTOR;

   using UPtr = std::unique_ptr<PInfo, decltype(&std::free)>;
   GetLogicalProcessorInformation(nullptr, &buffer_size);
   UPtr buff((PInfo*)malloc(buffer_size), &std::free);
   if (!GetLogicalProcessorInformation(buff.get(), &buffer_size))
     PrintErrorAndDie("Failed during call to GetLogicalProcessorInformation: ",
                      GetLastError());

   PInfo* it = buff.get();
   PInfo* end = buff.get() + (buffer_size / sizeof(PInfo));

   for (; it != end; ++it) {
     if (it->Relationship != RelationCache) continue;
     using BitSet = std::bitset<sizeof(ULONG_PTR) * CHAR_BIT>;
     BitSet B(it->ProcessorMask);
     // To prevent duplicates, only consider caches where CPU 0 is specified
     if (!B.test(0)) continue;
     CInfo* Cache = &it->Cache;
     CPUInfo::CacheInfo C;
     C.num_sharing = static_cast<int>(B.count());
     C.level = Cache->Level;
     C.size = Cache->Size;
     switch (Cache->Type) {
       case CacheUnified:
         C.type = "Unified";
         break;
       case CacheInstruction:
         C.type = "Instruction";
         break;
       case CacheData:
         C.type = "Data";
         break;
       case CacheTrace:
         C.type = "Trace";
         break;
       default:
         C.type = "Unknown";
         break;
     }
     res.push_back(C);
   }
   return res;
 }
 #elif BENCHMARK_OS_QNX
 std::vector<CPUInfo::CacheInfo> GetCacheSizesQNX() {
   std::vector<CPUInfo::CacheInfo> res;
   struct cacheattr_entry *cache = SYSPAGE_ENTRY(cacheattr);
   uint32_t const elsize = SYSPAGE_ELEMENT_SIZE(cacheattr);
   int num = SYSPAGE_ENTRY_SIZE(cacheattr) / elsize ;
   for(int i = 0; i < num; ++i ) {
     CPUInfo::CacheInfo info;
     switch (cache->flags){
       case CACHE_FLAG_INSTR :
         info.type = "Instruction";
         info.level = 1;
         break;
       case CACHE_FLAG_DATA :
         info.type = "Data";
         info.level = 1;
         break;
       case CACHE_FLAG_UNIFIED :
         info.type = "Unified";
         info.level = 2;
         break;
       case CACHE_FLAG_SHARED :
         info.type = "Shared";
         info.level = 3;
         break;
       default :
         continue;
         break;
     }
     info.size = cache->line_size * cache->num_lines;
     info.num_sharing = 0;
     res.push_back(std::move(info));
     cache = SYSPAGE_ARRAY_ADJ_OFFSET(cacheattr, cache, elsize);
   }
   return res;
 }
 #endif

 std::vector<CPUInfo::CacheInfo> GetCacheSizes() {
 #ifdef BENCHMARK_OS_MACOSX
   return GetCacheSizesMacOSX();
 #elif defined(BENCHMARK_OS_WINDOWS)
   return GetCacheSizesWindows();
 #elif defined(BENCHMARK_OS_QNX)
   return GetCacheSizesQNX();
 #else
   return GetCacheSizesFromKVFS();
 #endif
 }

 std::string GetSystemName() {
 #if defined(BENCHMARK_OS_WINDOWS)
   std::string str;
   const unsigned COUNT = MAX_COMPUTERNAME_LENGTH+1;
   TCHAR  hostname[COUNT] = {'\0'};
   DWORD DWCOUNT = COUNT;
   if (!GetComputerName(hostname, &DWCOUNT))
     return std::string("");
 #ifndef UNICODE
   str = std::string(hostname, DWCOUNT);
 #else
   //Using wstring_convert, Is deprecated in C++17
   using convert_type = std::codecvt_utf8<wchar_t>;
   std::wstring_convert<convert_type, wchar_t> converter;
   std::wstring wStr(hostname, DWCOUNT);
   str = converter.to_bytes(wStr);
 #endif
   return str;
 #else // defined(BENCHMARK_OS_WINDOWS)
 #ifndef HOST_NAME_MAX
 #ifdef BENCHMARK_HAS_SYSCTL // BSD/Mac Doesnt have HOST_NAME_MAX defined
 #define HOST_NAME_MAX 64
 #elif defined(BENCHMARK_OS_NACL)
 #define HOST_NAME_MAX 64
 #elif defined(BENCHMARK_OS_QNX)
 #define HOST_NAME_MAX 154
 #elif defined(BENCHMARK_OS_RTEMS)
 #define HOST_NAME_MAX 256
 #else
 #warning "HOST_NAME_MAX not defined. using 64"
 #define HOST_NAME_MAX 64
 #endif
 #endif // def HOST_NAME_MAX
   char hostname[HOST_NAME_MAX];
   int retVal = gethostname(hostname, HOST_NAME_MAX);
   if (retVal != 0) return std::string("");
   return std::string(hostname);
 #endif // Catch-all POSIX block.
 }

 int GetNumCPUs() {
 #ifdef BENCHMARK_HAS_SYSCTL
   int NumCPU = -1;
   if (GetSysctl("hw.ncpu", &NumCPU)) return NumCPU;
   fprintf(stderr, "Err: %s\n", strerror(errno));
   std::exit(EXIT_FAILURE);
 #elif defined(BENCHMARK_OS_WINDOWS)
   SYSTEM_INFO sysinfo;
   // Use memset as opposed to = {} to avoid GCC missing initializer false
   // positives.
   std::memset(&sysinfo, 0, sizeof(SYSTEM_INFO));
   GetSystemInfo(&sysinfo);
   return sysinfo.dwNumberOfProcessors;  // number of logical
                                         // processors in the current
                                         // group
 #elif defined(BENCHMARK_OS_SOLARIS)
   // Returns -1 in case of a failure.
   int NumCPU = sysconf(_SC_NPROCESSORS_ONLN);
   if (NumCPU < 0) {
     fprintf(stderr,
             "sysconf(_SC_NPROCESSORS_ONLN) failed with error: %s\n",
             strerror(errno));
   }
   return NumCPU;
 #elif defined(BENCHMARK_OS_QNX)
   return static_cast<int>(_syspage_ptr->num_cpu);
 #else
   int NumCPUs = 0;
   int MaxID = -1;
   std::ifstream f("/proc/cpuinfo");
   if (!f.is_open()) {
     std::cerr << "failed to open /proc/cpuinfo\n";
     return -1;
   }
   const std::string Key = "processor";
   std::string ln;
   while (std::getline(f, ln)) {
     if (ln.empty()) continue;
     size_t SplitIdx = ln.find(':');
     std::string value;
 #if defined(__s390__)
     // s390 has another format in /proc/cpuinfo
     // it needs to be parsed differently
     if (SplitIdx != std::string::npos) value = ln.substr(Key.size()+1,SplitIdx-Key.size()-1);
 #else
     if (SplitIdx != std::string::npos) value = ln.substr(SplitIdx + 1);
 #endif
     if (ln.size() >= Key.size() && ln.compare(0, Key.size(), Key) == 0) {
       NumCPUs++;
       if (!value.empty()) {
         int CurID = benchmark::stoi(value);
         MaxID = std::max(CurID, MaxID);
       }
     }
   }
   if (f.bad()) {
     std::cerr << "Failure reading /proc/cpuinfo\n";
     return -1;
   }
   if (!f.eof()) {
     std::cerr << "Failed to read to end of /proc/cpuinfo\n";
     return -1;
   }
   f.close();

   if ((MaxID + 1) != NumCPUs) {
     fprintf(stderr,
             "CPU ID assignments in /proc/cpuinfo seem messed up."
             " This is usually caused by a bad BIOS.\n");
   }
   return NumCPUs;
 #endif
   BENCHMARK_UNREACHABLE();
 }

 double GetCPUCyclesPerSecond(CPUInfo::Scaling scaling) {
   // Currently, scaling is only used on linux path here,
   // suppress diagnostics about it being unused on other paths.
   (void)scaling;

 #if defined BENCHMARK_OS_LINUX || defined BENCHMARK_OS_CYGWIN
   long freq;

   // If the kernel is exporting the tsc frequency use that. There are issues
   // where cpuinfo_max_freq cannot be relied on because the BIOS may be
   // exporintg an invalid p-state (on x86) or p-states may be used to put the
   // processor in a new mode (turbo mode). Essentially, those frequencies
   // cannot always be relied upon. The same reasons apply to /proc/cpuinfo as
   // well.
   if (ReadFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz", &freq)
       // If CPU scaling is disabled, use the the *current* frequency.
       // Note that we specifically don't want to read cpuinfo_cur_freq,
       // because it is only readable by root.
       || (scaling == CPUInfo::Scaling::DISABLED &&
           ReadFromFile("/sys/devices/system/cpu/cpu0/cpufreq/scaling_cur_freq",
                        &freq))
       // Otherwise, if CPU scaling may be in effect, we want to use
       // the *maximum* frequency, not whatever CPU speed some random processor
       // happens to be using now.
       || ReadFromFile("/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
                       &freq)) {
     // The value is in kHz (as the file name suggests).  For example, on a
     // 2GHz warpstation, the file contains the value "2000000".
     return freq * 1000.0;
   }

   const double error_value = -1;
   double bogo_clock = error_value;

   std::ifstream f("/proc/cpuinfo");
   if (!f.is_open()) {
     std::cerr << "failed to open /proc/cpuinfo\n";
     return error_value;
   }

   auto startsWithKey = [](std::string const& Value, std::string const& Key) {
     if (Key.size() > Value.size()) return false;
     auto Cmp = [&](char X, char Y) {
       return std::tolower(X) == std::tolower(Y);
     };
     return std::equal(Key.begin(), Key.end(), Value.begin(), Cmp);
   };

   std::string ln;
   while (std::getline(f, ln)) {
     if (ln.empty()) continue;
     size_t SplitIdx = ln.find(':');
     std::string value;
     if (SplitIdx != std::string::npos) value = ln.substr(SplitIdx + 1);
     // When parsing the "cpu MHz" and "bogomips" (fallback) entries, we only
     // accept positive values. Some environments (virtual machines) report zero,
     // which would cause infinite looping in WallTime_Init.
     if (startsWithKey(ln, "cpu MHz")) {
       if (!value.empty()) {
         double cycles_per_second = benchmark::stod(value) * 1000000.0;
         if (cycles_per_second > 0) return cycles_per_second;
       }
     } else if (startsWithKey(ln, "bogomips")) {
       if (!value.empty()) {
         bogo_clock = benchmark::stod(value) * 1000000.0;
         if (bogo_clock < 0.0) bogo_clock = error_value;
       }
     }
   }
   if (f.bad()) {
     std::cerr << "Failure reading /proc/cpuinfo\n";
     return error_value;
   }
   if (!f.eof()) {
     std::cerr << "Failed to read to end of /proc/cpuinfo\n";
     return error_value;
   }
   f.close();
   // If we found the bogomips clock, but nothing better, we'll use it (but
   // we're not happy about it); otherwise, fallback to the rough estimation
   // below.
   if (bogo_clock >= 0.0) return bogo_clock;

 #elif defined BENCHMARK_HAS_SYSCTL
   constexpr auto* FreqStr =
 #if defined(BENCHMARK_OS_FREEBSD) || defined(BENCHMARK_OS_NETBSD)
       "machdep.tsc_freq";
 #elif defined BENCHMARK_OS_OPENBSD
       "hw.cpuspeed";
 #elif defined BENCHMARK_OS_DRAGONFLY
       "hw.tsc_frequency";
 #else
       "hw.cpufrequency";
 #endif
   unsigned long long hz = 0;
 #if defined BENCHMARK_OS_OPENBSD
   if (GetSysctl(FreqStr, &hz)) return hz * 1000000;
 #else
   if (GetSysctl(FreqStr, &hz)) return hz;
 #endif
   fprintf(stderr, "Unable to determine clock rate from sysctl: %s: %s\n",
           FreqStr, strerror(errno));

 #elif defined BENCHMARK_OS_WINDOWS
   // In NT, read MHz from the registry. If we fail to do so or we're in win9x
   // then make a crude estimate.
   DWORD data, data_size = sizeof(data);
   if (IsWindowsXPOrGreater() &&
       SUCCEEDED(
           SHGetValueA(HKEY_LOCAL_MACHINE,
                       "HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0",
                       "~MHz", nullptr, &data, &data_size)))
     return static_cast<double>((int64_t)data *
                                (int64_t)(1000 * 1000));  // was mhz
 #elif defined (BENCHMARK_OS_SOLARIS)
   kstat_ctl_t *kc = kstat_open();
   if (!kc) {
     std::cerr << "failed to open /dev/kstat\n";
     return -1;
   }
   kstat_t *ksp = kstat_lookup(kc, (char*)"cpu_info", -1, (char*)"cpu_info0");
   if (!ksp) {
     std::cerr << "failed to lookup in /dev/kstat\n";
     return -1;
   }
   if (kstat_read(kc, ksp, NULL) < 0) {
     std::cerr << "failed to read from /dev/kstat\n";
     return -1;
   }
   kstat_named_t *knp =
       (kstat_named_t*)kstat_data_lookup(ksp, (char*)"current_clock_Hz");
   if (!knp) {
     std::cerr << "failed to lookup data in /dev/kstat\n";
     return -1;
   }
   if (knp->data_type != KSTAT_DATA_UINT64) {
     std::cerr << "current_clock_Hz is of unexpected data type: "
               << knp->data_type << "\n";
     return -1;
   }
   double clock_hz = knp->value.ui64;
   kstat_close(kc);
   return clock_hz;
 #elif defined (BENCHMARK_OS_QNX)
   return static_cast<double>((int64_t)(SYSPAGE_ENTRY(cpuinfo)->speed) *
                              (int64_t)(1000 * 1000));
 #endif
   // If we've fallen through, attempt to roughly estimate the CPU clock rate.
   const int estimate_time_ms = 1000;
   const auto start_ticks = cycleclock::Now();
   SleepForMilliseconds(estimate_time_ms);
   return static_cast<double>(cycleclock::Now() - start_ticks);
 }

 std::vector<double> GetLoadAvg() {
 #if (defined BENCHMARK_OS_FREEBSD || defined(BENCHMARK_OS_LINUX) ||     \
      defined BENCHMARK_OS_MACOSX || defined BENCHMARK_OS_NETBSD ||      \
      defined BENCHMARK_OS_OPENBSD || defined BENCHMARK_OS_DRAGONFLY) && \
     !defined(__ANDROID__)
   constexpr int kMaxSamples = 3;
   std::vector<double> res(kMaxSamples, 0.0);
   const int nelem = getloadavg(res.data(), kMaxSamples);
   if (nelem < 1) {
     res.clear();
   } else {
     res.resize(nelem);
   }
   return res;
 #else
   return {};
 #endif
 }

 }  // end namespace

 const CPUInfo& CPUInfo::Get() {
   static const CPUInfo* info = new CPUInfo();
   return *info;
 }

 CPUInfo::CPUInfo()
     : num_cpus(GetNumCPUs()),
       scaling(CpuScaling(num_cpus)),
       cycles_per_second(GetCPUCyclesPerSecond(scaling)),
       caches(GetCacheSizes()),
       load_avg(GetLoadAvg()) {}

 const SystemInfo& SystemInfo::Get() {
   static const SystemInfo* info = new SystemInfo();
   return *info;
 }

 SystemInfo::SystemInfo() : name(GetSystemName()) {}
 }  // end namespace benchmark
	// Copyright 2015 Google Inc. All rights reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#include "internal_macros.h"

	#ifdef BENCHMARK_OS_WINDOWS
	#include <shlwapi.h>
	#undef StrCat // Don't let StrCat in string_util.h be renamed to lstrcatA
	#include <versionhelpers.h>
	#include <windows.h>
	#include <codecvt>
	#else
	#include <fcntl.h>
	#ifndef BENCHMARK_OS_FUCHSIA
	#include <sys/resource.h>
	#endif
	#include <sys/time.h>
	#include <sys/types.h> // this header must be included before 'sys/sysctl.h' to avoid compilation error on FreeBSD
	#include <unistd.h>
	#if defined BENCHMARK_OS_FREEBSD \|\| defined BENCHMARK_OS_MACOSX \|\| \
	defined BENCHMARK_OS_NETBSD \|\| defined BENCHMARK_OS_OPENBSD \|\| \
	defined BENCHMARK_OS_DRAGONFLY
	#define BENCHMARK_HAS_SYSCTL
	#include <sys/sysctl.h>
	#endif
	#endif
	#if defined(BENCHMARK_OS_SOLARIS)
	#include <kstat.h>
	#endif
	#if defined(BENCHMARK_OS_QNX)
	#include <sys/syspage.h>
	#endif

	#include <algorithm>
	#include <array>
	#include <bitset>
	#include <cerrno>
	#include <climits>
	#include <cstdint>
	#include <cstdio>
	#include <cstdlib>
	#include <cstring>
	#include <fstream>
	#include <iostream>
	#include <iterator>
	#include <limits>
	#include <memory>
	#include <sstream>
	#include <locale>
	#include <utility>

	#include "check.h"
	#include "cycleclock.h"
	#include "internal_macros.h"
	#include "log.h"
	#include "sleep.h"
	#include "string_util.h"

	namespace benchmark {
	namespace {

	void PrintImp(std::ostream& out) { out << std::endl; }

	template <class First, class... Rest>
	void PrintImp(std::ostream& out, First&& f, Rest&&... rest) {
	out << std::forward<First>(f);
	PrintImp(out, std::forward<Rest>(rest)...);
	}

	template <class... Args>
	BENCHMARK_NORETURN void PrintErrorAndDie(Args&&... args) {
	PrintImp(std::cerr, std::forward<Args>(args)...);
	std::exit(EXIT_FAILURE);
	}

	#ifdef BENCHMARK_HAS_SYSCTL

	/// ValueUnion - A type used to correctly alias the byte-for-byte output of
	/// `sysctl` with the result type it's to be interpreted as.
	struct ValueUnion {
	union DataT {
	uint32_t uint32_value;
	uint64_t uint64_value;
	// For correct aliasing of union members from bytes.
	char bytes[8];
	};
	using DataPtr = std::unique_ptr<DataT, decltype(&std::free)>;

	// The size of the data union member + its trailing array size.
	size_t Size;
	DataPtr Buff;

	public:
	ValueUnion() : Size(0), Buff(nullptr, &std::free) {}

	explicit ValueUnion(size_t BuffSize)
	: Size(sizeof(DataT) + BuffSize),
	Buff(::new (std::malloc(Size)) DataT(), &std::free) {}

	ValueUnion(ValueUnion&& other) = default;

	explicit operator bool() const { return bool(Buff); }

	char* data() const { return Buff->bytes; }

	std::string GetAsString() const { return std::string(data()); }

	int64_t GetAsInteger() const {
	if (Size == sizeof(Buff->uint32_value))
	return static_cast<int32_t>(Buff->uint32_value);
	else if (Size == sizeof(Buff->uint64_value))
	return static_cast<int64_t>(Buff->uint64_value);
	BENCHMARK_UNREACHABLE();
	}

	uint64_t GetAsUnsigned() const {
	if (Size == sizeof(Buff->uint32_value))
	return Buff->uint32_value;
	else if (Size == sizeof(Buff->uint64_value))
	return Buff->uint64_value;
	BENCHMARK_UNREACHABLE();
	}

	template <class T, int N>
	std::array<T, N> GetAsArray() {
	const int ArrSize = sizeof(T) * N;
	CHECK_LE(ArrSize, Size);
	std::array<T, N> Arr;
	std::memcpy(Arr.data(), data(), ArrSize);
	return Arr;
	}
	};

	ValueUnion GetSysctlImp(std::string const& Name) {
	#if defined BENCHMARK_OS_OPENBSD
	int mib[2];

	mib[0] = CTL_HW;
	if ((Name == "hw.ncpu") \|\| (Name == "hw.cpuspeed")){
	ValueUnion buff(sizeof(int));

	if (Name == "hw.ncpu") {
	mib[1] = HW_NCPU;
	} else {
	mib[1] = HW_CPUSPEED;
	}

	if (sysctl(mib, 2, buff.data(), &buff.Size, nullptr, 0) == -1) {
	return ValueUnion();
	}
	return buff;
	}
	return ValueUnion();
	#else
	size_t CurBuffSize = 0;
	if (sysctlbyname(Name.c_str(), nullptr, &CurBuffSize, nullptr, 0) == -1)
	return ValueUnion();

	ValueUnion buff(CurBuffSize);
	if (sysctlbyname(Name.c_str(), buff.data(), &buff.Size, nullptr, 0) == 0)
	return buff;
	return ValueUnion();
	#endif
	}

	BENCHMARK_MAYBE_UNUSED
	bool GetSysctl(std::string const& Name, std::string* Out) {
	Out->clear();
	auto Buff = GetSysctlImp(Name);
	if (!Buff) return false;
	Out->assign(Buff.data());
	return true;
	}

	template <class Tp,
	class = typename std::enable_if<std::is_integral<Tp>::value>::type>
	bool GetSysctl(std::string const& Name, Tp* Out) {
	*Out = 0;
	auto Buff = GetSysctlImp(Name);
	if (!Buff) return false;
	*Out = static_cast<Tp>(Buff.GetAsUnsigned());
	return true;
	}

	template <class Tp, size_t N>
	bool GetSysctl(std::string const& Name, std::array<Tp, N>* Out) {
	auto Buff = GetSysctlImp(Name);
	if (!Buff) return false;
	*Out = Buff.GetAsArray<Tp, N>();
	return true;
	}
	#endif

	template <class ArgT>
	bool ReadFromFile(std::string const& fname, ArgT* arg) {
	*arg = ArgT();
	std::ifstream f(fname.c_str());
	if (!f.is_open()) return false;
	f >> *arg;
	return f.good();
	}

	CPUInfo::Scaling CpuScaling(int num_cpus) {
	// We don't have a valid CPU count, so don't even bother.
	if (num_cpus <= 0) return CPUInfo::Scaling::UNKNOWN;
	#ifdef BENCHMARK_OS_QNX
	return CPUInfo::Scaling::UNKNOWN;
	#endif
	#ifndef BENCHMARK_OS_WINDOWS
	// On Linux, the CPUfreq subsystem exposes CPU information as files on the
	// local file system. If reading the exported files fails, then we may not be
	// running on Linux, so we silently ignore all the read errors.
	std::string res;
	for (int cpu = 0; cpu < num_cpus; ++cpu) {
	std::string governor_file =
	StrCat("/sys/devices/system/cpu/cpu", cpu, "/cpufreq/scaling_governor");
	if (ReadFromFile(governor_file, &res) && res != "performance") return CPUInfo::Scaling::ENABLED;
	}
	return CPUInfo::Scaling::DISABLED;
	#endif
	return CPUInfo::Scaling::UNKNOWN;
	}

	int CountSetBitsInCPUMap(std::string Val) {
	auto CountBits = [](std::string Part) {
	using CPUMask = std::bitset<sizeof(std::uintptr_t) * CHAR_BIT>;
	Part = "0x" + Part;
	CPUMask Mask(benchmark::stoul(Part, nullptr, 16));
	return static_cast<int>(Mask.count());
	};
	size_t Pos;
	int total = 0;
	while ((Pos = Val.find(',')) != std::string::npos) {
	total += CountBits(Val.substr(0, Pos));
	Val = Val.substr(Pos + 1);
	}
	if (!Val.empty()) {
	total += CountBits(Val);
	}
	return total;
	}

	BENCHMARK_MAYBE_UNUSED
	std::vector<CPUInfo::CacheInfo> GetCacheSizesFromKVFS() {
	std::vector<CPUInfo::CacheInfo> res;
	std::string dir = "/sys/devices/system/cpu/cpu0/cache/";
	int Idx = 0;
	while (true) {
	CPUInfo::CacheInfo info;
	std::string FPath = StrCat(dir, "index", Idx++, "/");
	std::ifstream f(StrCat(FPath, "size").c_str());
	if (!f.is_open()) break;
	std::string suffix;
	f >> info.size;
	if (f.fail())
	PrintErrorAndDie("Failed while reading file '", FPath, "size'");
	if (f.good()) {
	f >> suffix;
	if (f.bad())
	PrintErrorAndDie(
	"Invalid cache size format: failed to read size suffix");
	else if (f && suffix != "K")
	PrintErrorAndDie("Invalid cache size format: Expected bytes ", suffix);
	else if (suffix == "K")
	info.size *= 1024;
	}
	if (!ReadFromFile(StrCat(FPath, "type"), &info.type))
	PrintErrorAndDie("Failed to read from file ", FPath, "type");
	if (!ReadFromFile(StrCat(FPath, "level"), &info.level))
	PrintErrorAndDie("Failed to read from file ", FPath, "level");
	std::string map_str;
	if (!ReadFromFile(StrCat(FPath, "shared_cpu_map"), &map_str))
	PrintErrorAndDie("Failed to read from file ", FPath, "shared_cpu_map");
	info.num_sharing = CountSetBitsInCPUMap(map_str);
	res.push_back(info);
	}

	return res;
	}

	#ifdef BENCHMARK_OS_MACOSX
	std::vector<CPUInfo::CacheInfo> GetCacheSizesMacOSX() {
	std::vector<CPUInfo::CacheInfo> res;
	std::array<uint64_t, 4> CacheCounts{{0, 0, 0, 0}};
	GetSysctl("hw.cacheconfig", &CacheCounts);

	struct {
	std::string name;
	std::string type;
	int level;
	uint64_t num_sharing;
	} Cases[] = {{"hw.l1dcachesize", "Data", 1, CacheCounts[1]},
	{"hw.l1icachesize", "Instruction", 1, CacheCounts[1]},
	{"hw.l2cachesize", "Unified", 2, CacheCounts[2]},
	{"hw.l3cachesize", "Unified", 3, CacheCounts[3]}};
	for (auto& C : Cases) {
	int val;
	if (!GetSysctl(C.name, &val)) continue;
	CPUInfo::CacheInfo info;
	info.type = C.type;
	info.level = C.level;
	info.size = val;
	info.num_sharing = static_cast<int>(C.num_sharing);
	res.push_back(std::move(info));
	}
	return res;
	}
	#elif defined(BENCHMARK_OS_WINDOWS)
	std::vector<CPUInfo::CacheInfo> GetCacheSizesWindows() {
	std::vector<CPUInfo::CacheInfo> res;
	DWORD buffer_size = 0;
	using PInfo = SYSTEM_LOGICAL_PROCESSOR_INFORMATION;
	using CInfo = CACHE_DESCRIPTOR;

	using UPtr = std::unique_ptr<PInfo, decltype(&std::free)>;
	GetLogicalProcessorInformation(nullptr, &buffer_size);
	UPtr buff((PInfo*)malloc(buffer_size), &std::free);
	if (!GetLogicalProcessorInformation(buff.get(), &buffer_size))
	PrintErrorAndDie("Failed during call to GetLogicalProcessorInformation: ",
	GetLastError());

	PInfo* it = buff.get();
	PInfo* end = buff.get() + (buffer_size / sizeof(PInfo));

	for (; it != end; ++it) {
	if (it->Relationship != RelationCache) continue;
	using BitSet = std::bitset<sizeof(ULONG_PTR) * CHAR_BIT>;
	BitSet B(it->ProcessorMask);
	// To prevent duplicates, only consider caches where CPU 0 is specified
	if (!B.test(0)) continue;
	CInfo* Cache = &it->Cache;
	CPUInfo::CacheInfo C;
	C.num_sharing = static_cast<int>(B.count());
	C.level = Cache->Level;
	C.size = Cache->Size;
	switch (Cache->Type) {
	case CacheUnified:
	C.type = "Unified";
	break;
	case CacheInstruction:
	C.type = "Instruction";
	break;
	case CacheData:
	C.type = "Data";
	break;
	case CacheTrace:
	C.type = "Trace";
	break;
	default:
	C.type = "Unknown";
	break;
	}
	res.push_back(C);
	}
	return res;
	}
	#elif BENCHMARK_OS_QNX
	std::vector<CPUInfo::CacheInfo> GetCacheSizesQNX() {
	std::vector<CPUInfo::CacheInfo> res;
	struct cacheattr_entry *cache = SYSPAGE_ENTRY(cacheattr);
	uint32_t const elsize = SYSPAGE_ELEMENT_SIZE(cacheattr);
	int num = SYSPAGE_ENTRY_SIZE(cacheattr) / elsize ;
	for(int i = 0; i < num; ++i ) {
	CPUInfo::CacheInfo info;
	switch (cache->flags){
	case CACHE_FLAG_INSTR :
	info.type = "Instruction";
	info.level = 1;
	break;
	case CACHE_FLAG_DATA :
	info.type = "Data";
	info.level = 1;
	break;
	case CACHE_FLAG_UNIFIED :
	info.type = "Unified";
	info.level = 2;
	break;
	case CACHE_FLAG_SHARED :
	info.type = "Shared";
	info.level = 3;
	break;
	default :
	continue;
	break;
	}
	info.size = cache->line_size * cache->num_lines;
	info.num_sharing = 0;
	res.push_back(std::move(info));
	cache = SYSPAGE_ARRAY_ADJ_OFFSET(cacheattr, cache, elsize);
	}
	return res;
	}
	#endif

	std::vector<CPUInfo::CacheInfo> GetCacheSizes() {
	#ifdef BENCHMARK_OS_MACOSX
	return GetCacheSizesMacOSX();
	#elif defined(BENCHMARK_OS_WINDOWS)
	return GetCacheSizesWindows();
	#elif defined(BENCHMARK_OS_QNX)
	return GetCacheSizesQNX();
	#else
	return GetCacheSizesFromKVFS();
	#endif
	}

	std::string GetSystemName() {
	#if defined(BENCHMARK_OS_WINDOWS)
	std::string str;
	const unsigned COUNT = MAX_COMPUTERNAME_LENGTH+1;
	TCHAR hostname[COUNT] = {'\0'};
	DWORD DWCOUNT = COUNT;
	if (!GetComputerName(hostname, &DWCOUNT))
	return std::string("");
	#ifndef UNICODE
	str = std::string(hostname, DWCOUNT);
	#else
	//Using wstring_convert, Is deprecated in C++17
	using convert_type = std::codecvt_utf8<wchar_t>;
	std::wstring_convert<convert_type, wchar_t> converter;
	std::wstring wStr(hostname, DWCOUNT);
	str = converter.to_bytes(wStr);
	#endif
	return str;
	#else // defined(BENCHMARK_OS_WINDOWS)
	#ifndef HOST_NAME_MAX
	#ifdef BENCHMARK_HAS_SYSCTL // BSD/Mac Doesnt have HOST_NAME_MAX defined
	#define HOST_NAME_MAX 64
	#elif defined(BENCHMARK_OS_NACL)
	#define HOST_NAME_MAX 64
	#elif defined(BENCHMARK_OS_QNX)
	#define HOST_NAME_MAX 154
	#elif defined(BENCHMARK_OS_RTEMS)
	#define HOST_NAME_MAX 256
	#else
	#warning "HOST_NAME_MAX not defined. using 64"
	#define HOST_NAME_MAX 64
	#endif
	#endif // def HOST_NAME_MAX
	char hostname[HOST_NAME_MAX];
	int retVal = gethostname(hostname, HOST_NAME_MAX);
	if (retVal != 0) return std::string("");
	return std::string(hostname);
	#endif // Catch-all POSIX block.
	}

	int GetNumCPUs() {
	#ifdef BENCHMARK_HAS_SYSCTL
	int NumCPU = -1;
	if (GetSysctl("hw.ncpu", &NumCPU)) return NumCPU;
	fprintf(stderr, "Err: %s\n", strerror(errno));
	std::exit(EXIT_FAILURE);
	#elif defined(BENCHMARK_OS_WINDOWS)
	SYSTEM_INFO sysinfo;
	// Use memset as opposed to = {} to avoid GCC missing initializer false
	// positives.
	std::memset(&sysinfo, 0, sizeof(SYSTEM_INFO));
	GetSystemInfo(&sysinfo);
	return sysinfo.dwNumberOfProcessors; // number of logical
	// processors in the current
	// group
	#elif defined(BENCHMARK_OS_SOLARIS)
	// Returns -1 in case of a failure.
	int NumCPU = sysconf(_SC_NPROCESSORS_ONLN);
	if (NumCPU < 0) {
	fprintf(stderr,
	"sysconf(_SC_NPROCESSORS_ONLN) failed with error: %s\n",
	strerror(errno));
	}
	return NumCPU;
	#elif defined(BENCHMARK_OS_QNX)
	return static_cast<int>(_syspage_ptr->num_cpu);
	#else
	int NumCPUs = 0;
	int MaxID = -1;
	std::ifstream f("/proc/cpuinfo");
	if (!f.is_open()) {
	std::cerr << "failed to open /proc/cpuinfo\n";
	return -1;
	}
	const std::string Key = "processor";
	std::string ln;
	while (std::getline(f, ln)) {
	if (ln.empty()) continue;
	size_t SplitIdx = ln.find(':');
	std::string value;
	#if defined(__s390__)
	// s390 has another format in /proc/cpuinfo
	// it needs to be parsed differently
	if (SplitIdx != std::string::npos) value = ln.substr(Key.size()+1,SplitIdx-Key.size()-1);
	#else
	if (SplitIdx != std::string::npos) value = ln.substr(SplitIdx + 1);
	#endif
	if (ln.size() >= Key.size() && ln.compare(0, Key.size(), Key) == 0) {
	NumCPUs++;
	if (!value.empty()) {
	int CurID = benchmark::stoi(value);
	MaxID = std::max(CurID, MaxID);
	}
	}
	}
	if (f.bad()) {
	std::cerr << "Failure reading /proc/cpuinfo\n";
	return -1;
	}
	if (!f.eof()) {
	std::cerr << "Failed to read to end of /proc/cpuinfo\n";
	return -1;
	}
	f.close();

	if ((MaxID + 1) != NumCPUs) {
	fprintf(stderr,
	"CPU ID assignments in /proc/cpuinfo seem messed up."
	" This is usually caused by a bad BIOS.\n");
	}
	return NumCPUs;
	#endif
	BENCHMARK_UNREACHABLE();
	}

	double GetCPUCyclesPerSecond(CPUInfo::Scaling scaling) {
	// Currently, scaling is only used on linux path here,
	// suppress diagnostics about it being unused on other paths.
	(void)scaling;

	#if defined BENCHMARK_OS_LINUX \|\| defined BENCHMARK_OS_CYGWIN
	long freq;

	// If the kernel is exporting the tsc frequency use that. There are issues
	// where cpuinfo_max_freq cannot be relied on because the BIOS may be
	// exporintg an invalid p-state (on x86) or p-states may be used to put the
	// processor in a new mode (turbo mode). Essentially, those frequencies
	// cannot always be relied upon. The same reasons apply to /proc/cpuinfo as
	// well.
	if (ReadFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz", &freq)
	// If CPU scaling is disabled, use the the current frequency.
	// Note that we specifically don't want to read cpuinfo_cur_freq,
	// because it is only readable by root.
	\|\| (scaling == CPUInfo::Scaling::DISABLED &&
	ReadFromFile("/sys/devices/system/cpu/cpu0/cpufreq/scaling_cur_freq",
	&freq))
	// Otherwise, if CPU scaling may be in effect, we want to use
	// the maximum frequency, not whatever CPU speed some random processor
	// happens to be using now.
	\|\| ReadFromFile("/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
	&freq)) {
	// The value is in kHz (as the file name suggests). For example, on a
	// 2GHz warpstation, the file contains the value "2000000".
	return freq * 1000.0;
	}

	const double error_value = -1;
	double bogo_clock = error_value;

	std::ifstream f("/proc/cpuinfo");
	if (!f.is_open()) {
	std::cerr << "failed to open /proc/cpuinfo\n";
	return error_value;
	}

	auto startsWithKey = [](std::string const& Value, std::string const& Key) {
	if (Key.size() > Value.size()) return false;
	auto Cmp = [&](char X, char Y) {
	return std::tolower(X) == std::tolower(Y);
	};
	return std::equal(Key.begin(), Key.end(), Value.begin(), Cmp);
	};

	std::string ln;
	while (std::getline(f, ln)) {
	if (ln.empty()) continue;
	size_t SplitIdx = ln.find(':');
	std::string value;
	if (SplitIdx != std::string::npos) value = ln.substr(SplitIdx + 1);
	// When parsing the "cpu MHz" and "bogomips" (fallback) entries, we only
	// accept positive values. Some environments (virtual machines) report zero,
	// which would cause infinite looping in WallTime_Init.
	if (startsWithKey(ln, "cpu MHz")) {
	if (!value.empty()) {
	double cycles_per_second = benchmark::stod(value) * 1000000.0;
	if (cycles_per_second > 0) return cycles_per_second;
	}
	} else if (startsWithKey(ln, "bogomips")) {
	if (!value.empty()) {
	bogo_clock = benchmark::stod(value) * 1000000.0;
	if (bogo_clock < 0.0) bogo_clock = error_value;
	}
	}
	}
	if (f.bad()) {
	std::cerr << "Failure reading /proc/cpuinfo\n";
	return error_value;
	}
	if (!f.eof()) {
	std::cerr << "Failed to read to end of /proc/cpuinfo\n";
	return error_value;
	}
	f.close();
	// If we found the bogomips clock, but nothing better, we'll use it (but
	// we're not happy about it); otherwise, fallback to the rough estimation
	// below.
	if (bogo_clock >= 0.0) return bogo_clock;

	#elif defined BENCHMARK_HAS_SYSCTL
	constexpr auto* FreqStr =
	#if defined(BENCHMARK_OS_FREEBSD) \|\| defined(BENCHMARK_OS_NETBSD)
	"machdep.tsc_freq";
	#elif defined BENCHMARK_OS_OPENBSD
	"hw.cpuspeed";
	#elif defined BENCHMARK_OS_DRAGONFLY
	"hw.tsc_frequency";
	#else
	"hw.cpufrequency";
	#endif
	unsigned long long hz = 0;
	#if defined BENCHMARK_OS_OPENBSD
	if (GetSysctl(FreqStr, &hz)) return hz * 1000000;
	#else
	if (GetSysctl(FreqStr, &hz)) return hz;
	#endif
	fprintf(stderr, "Unable to determine clock rate from sysctl: %s: %s\n",
	FreqStr, strerror(errno));

	#elif defined BENCHMARK_OS_WINDOWS
	// In NT, read MHz from the registry. If we fail to do so or we're in win9x
	// then make a crude estimate.
	DWORD data, data_size = sizeof(data);
	if (IsWindowsXPOrGreater() &&
	SUCCEEDED(
	SHGetValueA(HKEY_LOCAL_MACHINE,
	"HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0",
	"~MHz", nullptr, &data, &data_size)))
	return static_cast<double>((int64_t)data *
	(int64_t)(1000 * 1000)); // was mhz
	#elif defined (BENCHMARK_OS_SOLARIS)
	kstat_ctl_t *kc = kstat_open();
	if (!kc) {
	std::cerr << "failed to open /dev/kstat\n";
	return -1;
	}
	kstat_t ksp = kstat_lookup(kc, (char)"cpu_info", -1, (char*)"cpu_info0");
	if (!ksp) {
	std::cerr << "failed to lookup in /dev/kstat\n";
	return -1;
	}
	if (kstat_read(kc, ksp, NULL) < 0) {
	std::cerr << "failed to read from /dev/kstat\n";
	return -1;
	}
	kstat_named_t *knp =
	(kstat_named_t)kstat_data_lookup(ksp, (char)"current_clock_Hz");
	if (!knp) {
	std::cerr << "failed to lookup data in /dev/kstat\n";
	return -1;
	}
	if (knp->data_type != KSTAT_DATA_UINT64) {
	std::cerr << "current_clock_Hz is of unexpected data type: "
	<< knp->data_type << "\n";
	return -1;
	}
	double clock_hz = knp->value.ui64;
	kstat_close(kc);
	return clock_hz;
	#elif defined (BENCHMARK_OS_QNX)
	return static_cast<double>((int64_t)(SYSPAGE_ENTRY(cpuinfo)->speed) *
	(int64_t)(1000 * 1000));
	#endif
	// If we've fallen through, attempt to roughly estimate the CPU clock rate.
	const int estimate_time_ms = 1000;
	const auto start_ticks = cycleclock::Now();
	SleepForMilliseconds(estimate_time_ms);
	return static_cast<double>(cycleclock::Now() - start_ticks);
	}

	std::vector<double> GetLoadAvg() {
	#if (defined BENCHMARK_OS_FREEBSD \|\| defined(BENCHMARK_OS_LINUX) \|\| \
	defined BENCHMARK_OS_MACOSX \|\| defined BENCHMARK_OS_NETBSD \|\| \
	defined BENCHMARK_OS_OPENBSD \|\| defined BENCHMARK_OS_DRAGONFLY) && \
	!defined(__ANDROID__)
	constexpr int kMaxSamples = 3;
	std::vector<double> res(kMaxSamples, 0.0);
	const int nelem = getloadavg(res.data(), kMaxSamples);
	if (nelem < 1) {
	res.clear();
	} else {
	res.resize(nelem);
	}
	return res;
	#else
	return {};
	#endif
	}

	} // end namespace

	const CPUInfo& CPUInfo::Get() {
	static const CPUInfo* info = new CPUInfo();
	return *info;
	}

	CPUInfo::CPUInfo()
	: num_cpus(GetNumCPUs()),
	scaling(CpuScaling(num_cpus)),
	cycles_per_second(GetCPUCyclesPerSecond(scaling)),
	caches(GetCacheSizes()),
	load_avg(GetLoadAvg()) {}

	const SystemInfo& SystemInfo::Get() {
	static const SystemInfo* info = new SystemInfo();
	return *info;
	}

	SystemInfo::SystemInfo() : name(GetSystemName()) {}
	} // end namespace benchmark