absl/base/internal/sysinfo.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 // Copyright 2017 The Abseil Authors.
 //
 // 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 "absl/base/internal/sysinfo.h"

 #include "absl/base/attributes.h"

 #ifdef _WIN32
 #include <shlwapi.h>
 #include <windows.h>
 #else
 #include <fcntl.h>
 #include <pthread.h>
 #include <sys/stat.h>
 #include <sys/types.h>
 #include <unistd.h>
 #endif

 #ifdef __linux__
 #include <sys/syscall.h>
 #endif

 #if defined(__APPLE__) || defined(__FreeBSD__)
 #include <sys/sysctl.h>
 #endif

 #if defined(__myriad2__)
 #include <rtems.h>
 #endif

 #include <string.h>
 #include <cassert>
 #include <cstdint>
 #include <cstdio>
 #include <cstdlib>
 #include <ctime>
 #include <limits>
 #include <thread>  // NOLINT(build/c++11)
 #include <utility>
 #include <vector>

 #include "absl/base/call_once.h"
 #include "absl/base/internal/raw_logging.h"
 #include "absl/base/internal/spinlock.h"
 #include "absl/base/internal/unscaledcycleclock.h"

 namespace absl {
 namespace base_internal {

 static once_flag init_system_info_once;
 static int num_cpus = 0;
 static double nominal_cpu_frequency = 1.0;  // 0.0 might be dangerous.

 static int GetNumCPUs() {
 #if defined(__myriad2__)
   return 1;
 #else
   // Other possibilities:
   //  - Read /sys/devices/system/cpu/online and use cpumask_parse()
   //  - sysconf(_SC_NPROCESSORS_ONLN)
   return std::thread::hardware_concurrency();
 #endif
 }

 #if defined(_WIN32)

 static double GetNominalCPUFrequency() {
   DWORD data;
   DWORD data_size = sizeof(data);
   #pragma comment(lib, "shlwapi.lib")  // For SHGetValue().
   if (SUCCEEDED(
           SHGetValueA(HKEY_LOCAL_MACHINE,
                       "HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0",
                       "~MHz", nullptr, &data, &data_size))) {
     return data * 1e6;  // Value is MHz.
   }
   return 1.0;
 }

 #elif defined(CTL_HW) && defined(HW_CPU_FREQ)

 static double GetNominalCPUFrequency() {
   unsigned freq;
   size_t size = sizeof(freq);
   int mib[2] = {CTL_HW, HW_CPU_FREQ};
   if (sysctl(mib, 2, &freq, &size, nullptr, 0) == 0) {
     return static_cast<double>(freq);
   }
   return 1.0;
 }

 #else

 // Helper function for reading a long from a file. Returns true if successful
 // and the memory location pointed to by value is set to the value read.
 static bool ReadLongFromFile(const char *file, long *value) {
   bool ret = false;
   int fd = open(file, O_RDONLY);
   if (fd != -1) {
     char line[1024];
     char *err;
     memset(line, '\0', sizeof(line));
     int len = read(fd, line, sizeof(line) - 1);
     if (len <= 0) {
       ret = false;
     } else {
       const long temp_value = strtol(line, &err, 10);
       if (line[0] != '\0' && (*err == '\n' || *err == '\0')) {
         *value = temp_value;
         ret = true;
       }
     }
     close(fd);
   }
   return ret;
 }

 #if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY)

 // Reads a monotonic time source and returns a value in
 // nanoseconds. The returned value uses an arbitrary epoch, not the
 // Unix epoch.
 static int64_t ReadMonotonicClockNanos() {
   struct timespec t;
 #ifdef CLOCK_MONOTONIC_RAW
   int rc = clock_gettime(CLOCK_MONOTONIC_RAW, &t);
 #else
   int rc = clock_gettime(CLOCK_MONOTONIC, &t);
 #endif
   if (rc != 0) {
     perror("clock_gettime() failed");
     abort();
   }
   return int64_t{t.tv_sec} * 1000000000 + t.tv_nsec;
 }

 class UnscaledCycleClockWrapperForInitializeFrequency {
  public:
   static int64_t Now() { return base_internal::UnscaledCycleClock::Now(); }
 };

 struct TimeTscPair {
   int64_t time;  // From ReadMonotonicClockNanos().
   int64_t tsc;   // From UnscaledCycleClock::Now().
 };

 // Returns a pair of values (monotonic kernel time, TSC ticks) that
 // approximately correspond to each other.  This is accomplished by
 // doing several reads and picking the reading with the lowest
 // latency.  This approach is used to minimize the probability that
 // our thread was preempted between clock reads.
 static TimeTscPair GetTimeTscPair() {
   int64_t best_latency = std::numeric_limits<int64_t>::max();
   TimeTscPair best;
   for (int i = 0; i < 10; ++i) {
     int64_t t0 = ReadMonotonicClockNanos();
     int64_t tsc = UnscaledCycleClockWrapperForInitializeFrequency::Now();
     int64_t t1 = ReadMonotonicClockNanos();
     int64_t latency = t1 - t0;
     if (latency < best_latency) {
       best_latency = latency;
       best.time = t0;
       best.tsc = tsc;
     }
   }
   return best;
 }

 // Measures and returns the TSC frequency by taking a pair of
 // measurements approximately `sleep_nanoseconds` apart.
 static double MeasureTscFrequencyWithSleep(int sleep_nanoseconds) {
   auto t0 = GetTimeTscPair();
   struct timespec ts;
   ts.tv_sec = 0;
   ts.tv_nsec = sleep_nanoseconds;
   while (nanosleep(&ts, &ts) != 0 && errno == EINTR) {}
   auto t1 = GetTimeTscPair();
   double elapsed_ticks = t1.tsc - t0.tsc;
   double elapsed_time = (t1.time - t0.time) * 1e-9;
   return elapsed_ticks / elapsed_time;
 }

 // Measures and returns the TSC frequency by calling
 // MeasureTscFrequencyWithSleep(), doubling the sleep interval until the
 // frequency measurement stabilizes.
 static double MeasureTscFrequency() {
   double last_measurement = -1.0;
   int sleep_nanoseconds = 1000000;  // 1 millisecond.
   for (int i = 0; i < 8; ++i) {
     double measurement = MeasureTscFrequencyWithSleep(sleep_nanoseconds);
     if (measurement * 0.99 < last_measurement &&
         last_measurement < measurement * 1.01) {
       // Use the current measurement if it is within 1% of the
       // previous measurement.
       return measurement;
     }
     last_measurement = measurement;
     sleep_nanoseconds *= 2;
   }
   return last_measurement;
 }

 #endif  // ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY

 static double GetNominalCPUFrequency() {
   long freq = 0;

   // Google's production kernel has a patch to export the TSC
   // frequency through sysfs. 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 exporting 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 (ReadLongFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz", &freq)) {
     return freq * 1e3;  // Value is kHz.
   }

 #if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY)
   // On these platforms, the TSC frequency is the nominal CPU
   // frequency.  But without having the kernel export it directly
   // though /sys/devices/system/cpu/cpu0/tsc_freq_khz, there is no
   // other way to reliably get the TSC frequency, so we have to
   // measure it ourselves.  Some CPUs abuse cpuinfo_max_freq by
   // exporting "fake" frequencies for implementing new features. For
   // example, Intel's turbo mode is enabled by exposing a p-state
   // value with a higher frequency than that of the real TSC
   // rate. Because of this, we prefer to measure the TSC rate
   // ourselves on i386 and x86-64.
   return MeasureTscFrequency();
 #else

   // If CPU scaling is in effect, we want to use the *maximum*
   // frequency, not whatever CPU speed some random processor happens
   // to be using now.
   if (ReadLongFromFile("/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
                        &freq)) {
     return freq * 1e3;  // Value is kHz.
   }

   return 1.0;
 #endif  // !ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY
 }

 #endif

 // InitializeSystemInfo() may be called before main() and before
 // malloc is properly initialized, therefore this must not allocate
 // memory.
 static void InitializeSystemInfo() {
   num_cpus = GetNumCPUs();
   nominal_cpu_frequency = GetNominalCPUFrequency();
 }

 int NumCPUs() {
   base_internal::LowLevelCallOnce(&init_system_info_once, InitializeSystemInfo);
   return num_cpus;
 }

 double NominalCPUFrequency() {
   base_internal::LowLevelCallOnce(&init_system_info_once, InitializeSystemInfo);
   return nominal_cpu_frequency;
 }

 #if defined(_WIN32)

 pid_t GetTID() {
   return GetCurrentThreadId();
 }

 #elif defined(__linux__)

 #ifndef SYS_gettid
 #define SYS_gettid __NR_gettid
 #endif

 pid_t GetTID() {
   return syscall(SYS_gettid);
 }

 #elif defined(__akaros__)

 pid_t GetTID() {
   // Akaros has a concept of "vcore context", which is the state the program
   // is forced into when we need to make a user-level scheduling decision, or
   // run a signal handler.  This is analogous to the interrupt context that a
   // CPU might enter if it encounters some kind of exception.
   //
   // There is no current thread context in vcore context, but we need to give
   // a reasonable answer if asked for a thread ID (e.g., in a signal handler).
   // Thread 0 always exists, so if we are in vcore context, we return that.
   //
   // Otherwise, we know (since we are using pthreads) that the uthread struct
   // current_uthread is pointing to is the first element of a
   // struct pthread_tcb, so we extract and return the thread ID from that.
   //
   // TODO(dcross): Akaros anticipates moving the thread ID to the uthread
   // structure at some point. We should modify this code to remove the cast
   // when that happens.
   if (in_vcore_context())
     return 0;
   return reinterpret_cast<struct pthread_tcb *>(current_uthread)->id;
 }

 #elif defined(__myriad2__)

 pid_t GetTID() {
   uint32_t tid;
   rtems_task_ident(RTEMS_SELF, 0, &tid);
   return tid;
 }

 #else

 // Fallback implementation of GetTID using pthread_getspecific.
 static once_flag tid_once;
 static pthread_key_t tid_key;
 static absl::base_internal::SpinLock tid_lock(
     absl::base_internal::kLinkerInitialized);

 // We set a bit per thread in this array to indicate that an ID is in
 // use. ID 0 is unused because it is the default value returned by
 // pthread_getspecific().
 static std::vector<uint32_t>* tid_array GUARDED_BY(tid_lock) = nullptr;
 static constexpr int kBitsPerWord = 32;  // tid_array is uint32_t.

 // Returns the TID to tid_array.
 static void FreeTID(void *v) {
   intptr_t tid = reinterpret_cast<intptr_t>(v);
   int word = tid / kBitsPerWord;
   uint32_t mask = ~(1u << (tid % kBitsPerWord));
   absl::base_internal::SpinLockHolder lock(&tid_lock);
   assert(0 <= word && static_cast<size_t>(word) < tid_array->size());
   (*tid_array)[word] &= mask;
 }

 static void InitGetTID() {
   if (pthread_key_create(&tid_key, FreeTID) != 0) {
     // The logging system calls GetTID() so it can't be used here.
     perror("pthread_key_create failed");
     abort();
   }

   // Initialize tid_array.
   absl::base_internal::SpinLockHolder lock(&tid_lock);
   tid_array = new std::vector<uint32_t>(1);
   (*tid_array)[0] = 1;  // ID 0 is never-allocated.
 }

 // Return a per-thread small integer ID from pthread's thread-specific data.
 pid_t GetTID() {
   absl::call_once(tid_once, InitGetTID);

   intptr_t tid = reinterpret_cast<intptr_t>(pthread_getspecific(tid_key));
   if (tid != 0) {
     return tid;
   }

   int bit;  // tid_array[word] = 1u << bit;
   size_t word;
   {
     // Search for the first unused ID.
     absl::base_internal::SpinLockHolder lock(&tid_lock);
     // First search for a word in the array that is not all ones.
     word = 0;
     while (word < tid_array->size() && ~(*tid_array)[word] == 0) {
       ++word;
     }
     if (word == tid_array->size()) {
       tid_array->push_back(0);  // No space left, add kBitsPerWord more IDs.
     }
     // Search for a zero bit in the word.
     bit = 0;
     while (bit < kBitsPerWord && (((*tid_array)[word] >> bit) & 1) != 0) {
       ++bit;
     }
     tid = (word * kBitsPerWord) + bit;
     (*tid_array)[word] |= 1u << bit;  // Mark the TID as allocated.
   }

   if (pthread_setspecific(tid_key, reinterpret_cast<void *>(tid)) != 0) {
     perror("pthread_setspecific failed");
     abort();
   }

   return static_cast<pid_t>(tid);
 }

 #endif

 }  // namespace base_internal
 }  // namespace absl
	// Copyright 2017 The Abseil Authors.
	//
	// 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 "absl/base/internal/sysinfo.h"

	#include "absl/base/attributes.h"

	#ifdef _WIN32
	#include <shlwapi.h>
	#include <windows.h>
	#else
	#include <fcntl.h>
	#include <pthread.h>
	#include <sys/stat.h>
	#include <sys/types.h>
	#include <unistd.h>
	#endif

	#ifdef __linux__
	#include <sys/syscall.h>
	#endif

	#if defined(__APPLE__) \|\| defined(__FreeBSD__)
	#include <sys/sysctl.h>
	#endif

	#if defined(__myriad2__)
	#include <rtems.h>
	#endif

	#include <string.h>
	#include <cassert>
	#include <cstdint>
	#include <cstdio>
	#include <cstdlib>
	#include <ctime>
	#include <limits>
	#include <thread> // NOLINT(build/c++11)
	#include <utility>
	#include <vector>

	#include "absl/base/call_once.h"
	#include "absl/base/internal/raw_logging.h"
	#include "absl/base/internal/spinlock.h"
	#include "absl/base/internal/unscaledcycleclock.h"

	namespace absl {
	namespace base_internal {

	static once_flag init_system_info_once;
	static int num_cpus = 0;
	static double nominal_cpu_frequency = 1.0; // 0.0 might be dangerous.

	static int GetNumCPUs() {
	#if defined(__myriad2__)
	return 1;
	#else
	// Other possibilities:
	// - Read /sys/devices/system/cpu/online and use cpumask_parse()
	// - sysconf(_SC_NPROCESSORS_ONLN)
	return std::thread::hardware_concurrency();
	#endif
	}

	#if defined(_WIN32)

	static double GetNominalCPUFrequency() {
	DWORD data;
	DWORD data_size = sizeof(data);
	#pragma comment(lib, "shlwapi.lib") // For SHGetValue().
	if (SUCCEEDED(
	SHGetValueA(HKEY_LOCAL_MACHINE,
	"HARDWARE\\DESCRIPTION\\System\\CentralProcessor\\0",
	"~MHz", nullptr, &data, &data_size))) {
	return data * 1e6; // Value is MHz.
	}
	return 1.0;
	}

	#elif defined(CTL_HW) && defined(HW_CPU_FREQ)

	static double GetNominalCPUFrequency() {
	unsigned freq;
	size_t size = sizeof(freq);
	int mib[2] = {CTL_HW, HW_CPU_FREQ};
	if (sysctl(mib, 2, &freq, &size, nullptr, 0) == 0) {
	return static_cast<double>(freq);
	}
	return 1.0;
	}

	#else

	// Helper function for reading a long from a file. Returns true if successful
	// and the memory location pointed to by value is set to the value read.
	static bool ReadLongFromFile(const char file, long value) {
	bool ret = false;
	int fd = open(file, O_RDONLY);
	if (fd != -1) {
	char line[1024];
	char *err;
	memset(line, '\0', sizeof(line));
	int len = read(fd, line, sizeof(line) - 1);
	if (len <= 0) {
	ret = false;
	} else {
	const long temp_value = strtol(line, &err, 10);
	if (line[0] != '\0' && (err == '\n' \|\| err == '\0')) {
	*value = temp_value;
	ret = true;
	}
	}
	close(fd);
	}
	return ret;
	}

	#if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY)

	// Reads a monotonic time source and returns a value in
	// nanoseconds. The returned value uses an arbitrary epoch, not the
	// Unix epoch.
	static int64_t ReadMonotonicClockNanos() {
	struct timespec t;
	#ifdef CLOCK_MONOTONIC_RAW
	int rc = clock_gettime(CLOCK_MONOTONIC_RAW, &t);
	#else
	int rc = clock_gettime(CLOCK_MONOTONIC, &t);
	#endif
	if (rc != 0) {
	perror("clock_gettime() failed");
	abort();
	}
	return int64_t{t.tv_sec} * 1000000000 + t.tv_nsec;
	}

	class UnscaledCycleClockWrapperForInitializeFrequency {
	public:
	static int64_t Now() { return base_internal::UnscaledCycleClock::Now(); }
	};

	struct TimeTscPair {
	int64_t time; // From ReadMonotonicClockNanos().
	int64_t tsc; // From UnscaledCycleClock::Now().
	};

	// Returns a pair of values (monotonic kernel time, TSC ticks) that
	// approximately correspond to each other. This is accomplished by
	// doing several reads and picking the reading with the lowest
	// latency. This approach is used to minimize the probability that
	// our thread was preempted between clock reads.
	static TimeTscPair GetTimeTscPair() {
	int64_t best_latency = std::numeric_limits<int64_t>::max();
	TimeTscPair best;
	for (int i = 0; i < 10; ++i) {
	int64_t t0 = ReadMonotonicClockNanos();
	int64_t tsc = UnscaledCycleClockWrapperForInitializeFrequency::Now();
	int64_t t1 = ReadMonotonicClockNanos();
	int64_t latency = t1 - t0;
	if (latency < best_latency) {
	best_latency = latency;
	best.time = t0;
	best.tsc = tsc;
	}
	}
	return best;
	}

	// Measures and returns the TSC frequency by taking a pair of
	// measurements approximately `sleep_nanoseconds` apart.
	static double MeasureTscFrequencyWithSleep(int sleep_nanoseconds) {
	auto t0 = GetTimeTscPair();
	struct timespec ts;
	ts.tv_sec = 0;
	ts.tv_nsec = sleep_nanoseconds;
	while (nanosleep(&ts, &ts) != 0 && errno == EINTR) {}
	auto t1 = GetTimeTscPair();
	double elapsed_ticks = t1.tsc - t0.tsc;
	double elapsed_time = (t1.time - t0.time) * 1e-9;
	return elapsed_ticks / elapsed_time;
	}

	// Measures and returns the TSC frequency by calling
	// MeasureTscFrequencyWithSleep(), doubling the sleep interval until the
	// frequency measurement stabilizes.
	static double MeasureTscFrequency() {
	double last_measurement = -1.0;
	int sleep_nanoseconds = 1000000; // 1 millisecond.
	for (int i = 0; i < 8; ++i) {
	double measurement = MeasureTscFrequencyWithSleep(sleep_nanoseconds);
	if (measurement * 0.99 < last_measurement &&
	last_measurement < measurement * 1.01) {
	// Use the current measurement if it is within 1% of the
	// previous measurement.
	return measurement;
	}
	last_measurement = measurement;
	sleep_nanoseconds *= 2;
	}
	return last_measurement;
	}

	#endif // ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY

	static double GetNominalCPUFrequency() {
	long freq = 0;

	// Google's production kernel has a patch to export the TSC
	// frequency through sysfs. 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 exporting 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 (ReadLongFromFile("/sys/devices/system/cpu/cpu0/tsc_freq_khz", &freq)) {
	return freq * 1e3; // Value is kHz.
	}

	#if defined(ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY)
	// On these platforms, the TSC frequency is the nominal CPU
	// frequency. But without having the kernel export it directly
	// though /sys/devices/system/cpu/cpu0/tsc_freq_khz, there is no
	// other way to reliably get the TSC frequency, so we have to
	// measure it ourselves. Some CPUs abuse cpuinfo_max_freq by
	// exporting "fake" frequencies for implementing new features. For
	// example, Intel's turbo mode is enabled by exposing a p-state
	// value with a higher frequency than that of the real TSC
	// rate. Because of this, we prefer to measure the TSC rate
	// ourselves on i386 and x86-64.
	return MeasureTscFrequency();
	#else

	// If CPU scaling is in effect, we want to use the maximum
	// frequency, not whatever CPU speed some random processor happens
	// to be using now.
	if (ReadLongFromFile("/sys/devices/system/cpu/cpu0/cpufreq/cpuinfo_max_freq",
	&freq)) {
	return freq * 1e3; // Value is kHz.
	}

	return 1.0;
	#endif // !ABSL_INTERNAL_UNSCALED_CYCLECLOCK_FREQUENCY_IS_CPU_FREQUENCY
	}

	#endif

	// InitializeSystemInfo() may be called before main() and before
	// malloc is properly initialized, therefore this must not allocate
	// memory.
	static void InitializeSystemInfo() {
	num_cpus = GetNumCPUs();
	nominal_cpu_frequency = GetNominalCPUFrequency();
	}

	int NumCPUs() {
	base_internal::LowLevelCallOnce(&init_system_info_once, InitializeSystemInfo);
	return num_cpus;
	}

	double NominalCPUFrequency() {
	base_internal::LowLevelCallOnce(&init_system_info_once, InitializeSystemInfo);
	return nominal_cpu_frequency;
	}

	#if defined(_WIN32)

	pid_t GetTID() {
	return GetCurrentThreadId();
	}

	#elif defined(__linux__)

	#ifndef SYS_gettid
	#define SYS_gettid __NR_gettid
	#endif

	pid_t GetTID() {
	return syscall(SYS_gettid);
	}

	#elif defined(__akaros__)

	pid_t GetTID() {
	// Akaros has a concept of "vcore context", which is the state the program
	// is forced into when we need to make a user-level scheduling decision, or
	// run a signal handler. This is analogous to the interrupt context that a
	// CPU might enter if it encounters some kind of exception.
	//
	// There is no current thread context in vcore context, but we need to give
	// a reasonable answer if asked for a thread ID (e.g., in a signal handler).
	// Thread 0 always exists, so if we are in vcore context, we return that.
	//
	// Otherwise, we know (since we are using pthreads) that the uthread struct
	// current_uthread is pointing to is the first element of a
	// struct pthread_tcb, so we extract and return the thread ID from that.
	//
	// TODO(dcross): Akaros anticipates moving the thread ID to the uthread
	// structure at some point. We should modify this code to remove the cast
	// when that happens.
	if (in_vcore_context())
	return 0;
	return reinterpret_cast<struct pthread_tcb *>(current_uthread)->id;
	}

	#elif defined(__myriad2__)

	pid_t GetTID() {
	uint32_t tid;
	rtems_task_ident(RTEMS_SELF, 0, &tid);
	return tid;
	}

	#else

	// Fallback implementation of GetTID using pthread_getspecific.
	static once_flag tid_once;
	static pthread_key_t tid_key;
	static absl::base_internal::SpinLock tid_lock(
	absl::base_internal::kLinkerInitialized);

	// We set a bit per thread in this array to indicate that an ID is in
	// use. ID 0 is unused because it is the default value returned by
	// pthread_getspecific().
	static std::vector<uint32_t>* tid_array GUARDED_BY(tid_lock) = nullptr;
	static constexpr int kBitsPerWord = 32; // tid_array is uint32_t.

	// Returns the TID to tid_array.
	static void FreeTID(void *v) {
	intptr_t tid = reinterpret_cast<intptr_t>(v);
	int word = tid / kBitsPerWord;
	uint32_t mask = ~(1u << (tid % kBitsPerWord));
	absl::base_internal::SpinLockHolder lock(&tid_lock);
	assert(0 <= word && static_cast<size_t>(word) < tid_array->size());
	(*tid_array)[word] &= mask;
	}

	static void InitGetTID() {
	if (pthread_key_create(&tid_key, FreeTID) != 0) {
	// The logging system calls GetTID() so it can't be used here.
	perror("pthread_key_create failed");
	abort();
	}

	// Initialize tid_array.
	absl::base_internal::SpinLockHolder lock(&tid_lock);
	tid_array = new std::vector<uint32_t>(1);
	(*tid_array)[0] = 1; // ID 0 is never-allocated.
	}

	// Return a per-thread small integer ID from pthread's thread-specific data.
	pid_t GetTID() {
	absl::call_once(tid_once, InitGetTID);

	intptr_t tid = reinterpret_cast<intptr_t>(pthread_getspecific(tid_key));
	if (tid != 0) {
	return tid;
	}

	int bit; // tid_array[word] = 1u << bit;
	size_t word;
	{
	// Search for the first unused ID.
	absl::base_internal::SpinLockHolder lock(&tid_lock);
	// First search for a word in the array that is not all ones.
	word = 0;
	while (word < tid_array->size() && ~(*tid_array)[word] == 0) {
	++word;
	}
	if (word == tid_array->size()) {
	tid_array->push_back(0); // No space left, add kBitsPerWord more IDs.
	}
	// Search for a zero bit in the word.
	bit = 0;
	while (bit < kBitsPerWord && (((*tid_array)[word] >> bit) & 1) != 0) {
	++bit;
	}
	tid = (word * kBitsPerWord) + bit;
	(*tid_array)[word] \|= 1u << bit; // Mark the TID as allocated.
	}

	if (pthread_setspecific(tid_key, reinterpret_cast<void *>(tid)) != 0) {
	perror("pthread_setspecific failed");
	abort();
	}

	return static_cast<pid_t>(tid);
	}

	#endif

	} // namespace base_internal
	} // namespace absl