Abseil Common Libraries (C++) (grcp 依赖)
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507 lines
16 KiB
507 lines
16 KiB
// Copyright 2017 The Abseil Authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// https://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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#include "absl/base/internal/sysinfo.h" |
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#include "absl/base/attributes.h" |
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#ifdef _WIN32 |
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#include <windows.h> |
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#else |
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#include <fcntl.h> |
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#include <pthread.h> |
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#include <sys/stat.h> |
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#include <sys/types.h> |
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#include <unistd.h> |
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#endif |
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#ifdef __linux__ |
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#include <sys/syscall.h> |
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#endif |
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#if defined(__APPLE__) || defined(__FreeBSD__) |
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#include <sys/sysctl.h> |
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#endif |
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#if defined(__myriad2__) |
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#include <rtems.h> |
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#endif |
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#include <string.h> |
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#include <cassert> |
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#include <cstdint> |
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#include <cstdio> |
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#include <cstdlib> |
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#include <ctime> |
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#include <limits> |
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#include <thread> // NOLINT(build/c++11) |
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#include <utility> |
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#include <vector> |
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#include "absl/base/call_once.h" |
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#include "absl/base/config.h" |
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#include "absl/base/internal/raw_logging.h" |
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#include "absl/base/internal/spinlock.h" |
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#include "absl/base/internal/unscaledcycleclock.h" |
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#include "absl/base/thread_annotations.h" |
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namespace absl { |
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ABSL_NAMESPACE_BEGIN |
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namespace base_internal { |
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namespace { |
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#if defined(_WIN32) |
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// Returns number of bits set in `bitMask` |
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DWORD Win32CountSetBits(ULONG_PTR bitMask) { |
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for (DWORD bitSetCount = 0; ; ++bitSetCount) { |
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if (bitMask == 0) return bitSetCount; |
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bitMask &= bitMask - 1; |
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} |
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} |
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// Returns the number of logical CPUs using GetLogicalProcessorInformation(), or |
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// 0 if the number of processors is not available or can not be computed. |
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// https://docs.microsoft.com/en-us/windows/win32/api/sysinfoapi/nf-sysinfoapi-getlogicalprocessorinformation |
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int Win32NumCPUs() { |
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#pragma comment(lib, "kernel32.lib") |
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using Info = SYSTEM_LOGICAL_PROCESSOR_INFORMATION; |
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DWORD info_size = sizeof(Info); |
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Info* info(static_cast<Info*>(malloc(info_size))); |
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if (info == nullptr) return 0; |
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bool success = GetLogicalProcessorInformation(info, &info_size); |
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if (!success && GetLastError() == ERROR_INSUFFICIENT_BUFFER) { |
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free(info); |
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info = static_cast<Info*>(malloc(info_size)); |
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if (info == nullptr) return 0; |
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success = GetLogicalProcessorInformation(info, &info_size); |
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} |
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DWORD logicalProcessorCount = 0; |
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if (success) { |
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Info* ptr = info; |
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DWORD byteOffset = 0; |
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while (byteOffset + sizeof(Info) <= info_size) { |
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switch (ptr->Relationship) { |
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case RelationProcessorCore: |
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logicalProcessorCount += Win32CountSetBits(ptr->ProcessorMask); |
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break; |
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case RelationNumaNode: |
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case RelationCache: |
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case RelationProcessorPackage: |
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// Ignore other entries |
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break; |
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default: |
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// Ignore unknown entries |
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break; |
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} |
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byteOffset += sizeof(Info); |
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ptr++; |
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} |
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} |
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free(info); |
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return static_cast<int>(logicalProcessorCount); |
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} |
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#endif |
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} // namespace |
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static int GetNumCPUs() { |
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#if defined(__myriad2__) |
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return 1; |
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#elif defined(_WIN32) |
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const int hardware_concurrency = Win32NumCPUs(); |
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return hardware_concurrency ? hardware_concurrency : 1; |
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#elif defined(_AIX) |
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return sysconf(_SC_NPROCESSORS_ONLN); |
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#else |
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// Other possibilities: |
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// - Read /sys/devices/system/cpu/online and use cpumask_parse() |
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// - sysconf(_SC_NPROCESSORS_ONLN) |
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return std::thread::hardware_concurrency(); |
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#endif |
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} |
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#if defined(_WIN32) |
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static double GetNominalCPUFrequency() { |
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#if WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_APP) && \ |
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!WINAPI_FAMILY_PARTITION(WINAPI_PARTITION_DESKTOP) |
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// UWP apps don't have access to the registry and currently don't provide an |
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// API informing about CPU nominal frequency. |
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return 1.0; |
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#else |
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#pragma comment(lib, "advapi32.lib") // For Reg* functions. |
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HKEY key; |
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// Use the Reg* functions rather than the SH functions because shlwapi.dll |
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// pulls in gdi32.dll which makes process destruction much more costly. |
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if (RegOpenKeyExA(HKEY_LOCAL_MACHINE, |
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"HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0", 0, |
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KEY_READ, &key) == ERROR_SUCCESS) { |
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DWORD type = 0; |
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DWORD data = 0; |
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DWORD data_size = sizeof(data); |
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auto result = RegQueryValueExA(key, "~MHz", 0, &type, |
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reinterpret_cast<LPBYTE>(&data), &data_size); |
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RegCloseKey(key); |
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if (result == ERROR_SUCCESS && type == REG_DWORD && |
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data_size == sizeof(data)) { |
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return data * 1e6; // Value is MHz. |
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} |
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} |
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return 1.0; |
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#endif // WINAPI_PARTITION_APP && !WINAPI_PARTITION_DESKTOP |
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} |
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#elif defined(CTL_HW) && defined(HW_CPU_FREQ) |
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static double GetNominalCPUFrequency() { |
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unsigned freq; |
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size_t size = sizeof(freq); |
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int mib[2] = {CTL_HW, HW_CPU_FREQ}; |
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if (sysctl(mib, 2, &freq, &size, nullptr, 0) == 0) { |
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return static_cast<double>(freq); |
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} |
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return 1.0; |
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} |
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#else |
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// Helper function for reading a long from a file. Returns true if successful |
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// and the memory location pointed to by value is set to the value read. |
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static bool ReadLongFromFile(const char *file, long *value) { |
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bool ret = false; |
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int fd = open(file, O_RDONLY); |
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if (fd != -1) { |
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char line[1024]; |
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char *err; |
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memset(line, '\0', sizeof(line)); |
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int len = read(fd, line, sizeof(line) - 1); |
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if (len <= 0) { |
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ret = false; |
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} else { |
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const long temp_value = strtol(line, &err, 10); |
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if (line[0] != '\0' && (*err == '\n' || *err == '\0')) { |
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*value = temp_value; |
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ret = true; |
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} |
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} |
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close(fd); |
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} |
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return ret; |
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} |
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#if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY) |
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// Reads a monotonic time source and returns a value in |
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// nanoseconds. The returned value uses an arbitrary epoch, not the |
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// Unix epoch. |
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static int64_t ReadMonotonicClockNanos() { |
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struct timespec t; |
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#ifdef CLOCK_MONOTONIC_RAW |
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int rc = clock_gettime(CLOCK_MONOTONIC_RAW, &t); |
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#else |
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int rc = clock_gettime(CLOCK_MONOTONIC, &t); |
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#endif |
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if (rc != 0) { |
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perror("clock_gettime() failed"); |
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abort(); |
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} |
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return int64_t{t.tv_sec} * 1000000000 + t.tv_nsec; |
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} |
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class UnscaledCycleClockWrapperForInitializeFrequency { |
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public: |
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static int64_t Now() { return base_internal::UnscaledCycleClock::Now(); } |
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}; |
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struct TimeTscPair { |
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int64_t time; // From ReadMonotonicClockNanos(). |
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int64_t tsc; // From UnscaledCycleClock::Now(). |
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}; |
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// Returns a pair of values (monotonic kernel time, TSC ticks) that |
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// approximately correspond to each other. This is accomplished by |
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// doing several reads and picking the reading with the lowest |
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// latency. This approach is used to minimize the probability that |
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// our thread was preempted between clock reads. |
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static TimeTscPair GetTimeTscPair() { |
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int64_t best_latency = std::numeric_limits<int64_t>::max(); |
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TimeTscPair best; |
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for (int i = 0; i < 10; ++i) { |
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int64_t t0 = ReadMonotonicClockNanos(); |
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int64_t tsc = UnscaledCycleClockWrapperForInitializeFrequency::Now(); |
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int64_t t1 = ReadMonotonicClockNanos(); |
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int64_t latency = t1 - t0; |
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if (latency < best_latency) { |
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best_latency = latency; |
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best.time = t0; |
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best.tsc = tsc; |
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} |
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} |
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return best; |
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} |
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// Measures and returns the TSC frequency by taking a pair of |
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// measurements approximately `sleep_nanoseconds` apart. |
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static double MeasureTscFrequencyWithSleep(int sleep_nanoseconds) { |
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auto t0 = GetTimeTscPair(); |
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struct timespec ts; |
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ts.tv_sec = 0; |
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ts.tv_nsec = sleep_nanoseconds; |
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while (nanosleep(&ts, &ts) != 0 && errno == EINTR) {} |
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auto t1 = GetTimeTscPair(); |
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double elapsed_ticks = t1.tsc - t0.tsc; |
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double elapsed_time = (t1.time - t0.time) * 1e-9; |
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return elapsed_ticks / elapsed_time; |
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} |
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// Measures and returns the TSC frequency by calling |
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// MeasureTscFrequencyWithSleep(), doubling the sleep interval until the |
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// frequency measurement stabilizes. |
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static double MeasureTscFrequency() { |
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double last_measurement = -1.0; |
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int sleep_nanoseconds = 1000000; // 1 millisecond. |
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for (int i = 0; i < 8; ++i) { |
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double measurement = MeasureTscFrequencyWithSleep(sleep_nanoseconds); |
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if (measurement * 0.99 < last_measurement && |
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last_measurement < measurement * 1.01) { |
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// Use the current measurement if it is within 1% of the |
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// previous measurement. |
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return measurement; |
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} |
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last_measurement = measurement; |
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sleep_nanoseconds *= 2; |
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} |
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return last_measurement; |
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} |
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#endif // ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY |
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static double GetNominalCPUFrequency() { |
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long freq = 0; |
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// Google's production kernel has a patch to export the TSC |
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// frequency through sysfs. If the kernel is exporting the TSC |
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// frequency use that. There are issues where cpuinfo_max_freq |
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// cannot be relied on because the BIOS may be exporting an invalid |
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// p-state (on x86) or p-states may be used to put the processor in |
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// a new mode (turbo mode). Essentially, those frequencies cannot |
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// always be relied upon. The same reasons apply to /proc/cpuinfo as |
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// well. |
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if (ReadLongFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz", &freq)) { |
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return freq * 1e3; // Value is kHz. |
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} |
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#if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY) |
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// On these platforms, the TSC frequency is the nominal CPU |
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// frequency. But without having the kernel export it directly |
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// though /sys/devices/system/cpu/cpu0/tsc_freq_khz, there is no |
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// other way to reliably get the TSC frequency, so we have to |
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// measure it ourselves. Some CPUs abuse cpuinfo_max_freq by |
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// exporting "fake" frequencies for implementing new features. For |
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// example, Intel's turbo mode is enabled by exposing a p-state |
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// value with a higher frequency than that of the real TSC |
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// rate. Because of this, we prefer to measure the TSC rate |
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// ourselves on i386 and x86-64. |
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return MeasureTscFrequency(); |
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#else |
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// If CPU scaling is in effect, we want to use the *maximum* |
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// frequency, not whatever CPU speed some random processor happens |
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// to be using now. |
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if (ReadLongFromFile("/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq", |
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&freq)) { |
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return freq * 1e3; // Value is kHz. |
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} |
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return 1.0; |
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#endif // !ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY |
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} |
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#endif |
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ABSL_CONST_INIT static once_flag init_num_cpus_once; |
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ABSL_CONST_INIT static int num_cpus = 0; |
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// NumCPUs() may be called before main() and before malloc is properly |
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// initialized, therefore this must not allocate memory. |
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int NumCPUs() { |
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base_internal::LowLevelCallOnce( |
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&init_num_cpus_once, []() { num_cpus = GetNumCPUs(); }); |
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return num_cpus; |
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} |
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// A default frequency of 0.0 might be dangerous if it is used in division. |
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ABSL_CONST_INIT static once_flag init_nominal_cpu_frequency_once; |
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ABSL_CONST_INIT static double nominal_cpu_frequency = 1.0; |
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// NominalCPUFrequency() may be called before main() and before malloc is |
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// properly initialized, therefore this must not allocate memory. |
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double NominalCPUFrequency() { |
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base_internal::LowLevelCallOnce( |
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&init_nominal_cpu_frequency_once, |
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[]() { nominal_cpu_frequency = GetNominalCPUFrequency(); }); |
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return nominal_cpu_frequency; |
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} |
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#if defined(_WIN32) |
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pid_t GetTID() { |
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return pid_t{GetCurrentThreadId()}; |
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} |
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#elif defined(__linux__) |
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#ifndef SYS_gettid |
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#define SYS_gettid __NR_gettid |
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#endif |
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pid_t GetTID() { |
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return syscall(SYS_gettid); |
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} |
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#elif defined(__akaros__) |
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pid_t GetTID() { |
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// Akaros has a concept of "vcore context", which is the state the program |
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// is forced into when we need to make a user-level scheduling decision, or |
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// run a signal handler. This is analogous to the interrupt context that a |
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// CPU might enter if it encounters some kind of exception. |
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// |
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// There is no current thread context in vcore context, but we need to give |
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// a reasonable answer if asked for a thread ID (e.g., in a signal handler). |
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// Thread 0 always exists, so if we are in vcore context, we return that. |
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// |
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// Otherwise, we know (since we are using pthreads) that the uthread struct |
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// current_uthread is pointing to is the first element of a |
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// struct pthread_tcb, so we extract and return the thread ID from that. |
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// |
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// TODO(dcross): Akaros anticipates moving the thread ID to the uthread |
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// structure at some point. We should modify this code to remove the cast |
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// when that happens. |
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if (in_vcore_context()) |
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return 0; |
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return reinterpret_cast<struct pthread_tcb *>(current_uthread)->id; |
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} |
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#elif defined(__myriad2__) |
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pid_t GetTID() { |
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uint32_t tid; |
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rtems_task_ident(RTEMS_SELF, 0, &tid); |
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return tid; |
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} |
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#else |
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// Fallback implementation of GetTID using pthread_getspecific. |
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ABSL_CONST_INIT static once_flag tid_once; |
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ABSL_CONST_INIT static pthread_key_t tid_key; |
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ABSL_CONST_INIT static absl::base_internal::SpinLock tid_lock( |
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absl::kConstInit, base_internal::SCHEDULE_KERNEL_ONLY); |
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// We set a bit per thread in this array to indicate that an ID is in |
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// use. ID 0 is unused because it is the default value returned by |
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// pthread_getspecific(). |
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ABSL_CONST_INIT static std::vector<uint32_t> *tid_array |
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ABSL_GUARDED_BY(tid_lock) = nullptr; |
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static constexpr int kBitsPerWord = 32; // tid_array is uint32_t. |
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// Returns the TID to tid_array. |
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static void FreeTID(void *v) { |
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intptr_t tid = reinterpret_cast<intptr_t>(v); |
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int word = tid / kBitsPerWord; |
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uint32_t mask = ~(1u << (tid % kBitsPerWord)); |
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absl::base_internal::SpinLockHolder lock(&tid_lock); |
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assert(0 <= word && static_cast<size_t>(word) < tid_array->size()); |
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(*tid_array)[word] &= mask; |
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} |
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static void InitGetTID() { |
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if (pthread_key_create(&tid_key, FreeTID) != 0) { |
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// The logging system calls GetTID() so it can't be used here. |
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perror("pthread_key_create failed"); |
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abort(); |
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} |
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// Initialize tid_array. |
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absl::base_internal::SpinLockHolder lock(&tid_lock); |
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tid_array = new std::vector<uint32_t>(1); |
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(*tid_array)[0] = 1; // ID 0 is never-allocated. |
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} |
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// Return a per-thread small integer ID from pthread's thread-specific data. |
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pid_t GetTID() { |
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absl::call_once(tid_once, InitGetTID); |
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intptr_t tid = reinterpret_cast<intptr_t>(pthread_getspecific(tid_key)); |
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if (tid != 0) { |
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return tid; |
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} |
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int bit; // tid_array[word] = 1u << bit; |
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size_t word; |
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{ |
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// Search for the first unused ID. |
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absl::base_internal::SpinLockHolder lock(&tid_lock); |
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// First search for a word in the array that is not all ones. |
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word = 0; |
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while (word < tid_array->size() && ~(*tid_array)[word] == 0) { |
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++word; |
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} |
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if (word == tid_array->size()) { |
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tid_array->push_back(0); // No space left, add kBitsPerWord more IDs. |
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} |
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// Search for a zero bit in the word. |
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bit = 0; |
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while (bit < kBitsPerWord && (((*tid_array)[word] >> bit) & 1) != 0) { |
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++bit; |
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} |
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tid = (word * kBitsPerWord) + bit; |
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(*tid_array)[word] |= 1u << bit; // Mark the TID as allocated. |
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} |
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if (pthread_setspecific(tid_key, reinterpret_cast<void *>(tid)) != 0) { |
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perror("pthread_setspecific failed"); |
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abort(); |
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} |
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return static_cast<pid_t>(tid); |
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} |
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#endif |
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// GetCachedTID() caches the thread ID in thread-local storage (which is a |
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// userspace construct) to avoid unnecessary system calls. Without this caching, |
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// it can take roughly 98ns, while it takes roughly 1ns with this caching. |
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pid_t GetCachedTID() { |
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#ifdef ABSL_HAVE_THREAD_LOCAL |
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static thread_local pid_t thread_id = GetTID(); |
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return thread_id; |
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#else |
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return GetTID(); |
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#endif // ABSL_HAVE_THREAD_LOCAL |
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} |
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} // namespace base_internal |
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ABSL_NAMESPACE_END |
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} // namespace absl
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