libcxx/utils/google-benchmark/src/cycleclock.h - llvm-project - Git at Google

 // ----------------------------------------------------------------------
 // CycleClock
 //    A CycleClock tells you the current time in Cycles.  The "time"
 //    is actually time since power-on.  This is like time() but doesn't
 //    involve a system call and is much more precise.
 //
 // NOTE: Not all cpu/platform/kernel combinations guarantee that this
 // clock increments at a constant rate or is synchronized across all logical
 // cpus in a system.
 //
 // If you need the above guarantees, please consider using a different
 // API. There are efforts to provide an interface which provides a millisecond
 // granularity and implemented as a memory read. A memory read is generally
 // cheaper than the CycleClock for many architectures.
 //
 // Also, in some out of order CPU implementations, the CycleClock is not
 // serializing. So if you're trying to count at cycles granularity, your
 // data might be inaccurate due to out of order instruction execution.
 // ----------------------------------------------------------------------

 #ifndef BENCHMARK_CYCLECLOCK_H_
 #define BENCHMARK_CYCLECLOCK_H_

 #include <cstdint>

 #include "benchmark/benchmark.h"
 #include "internal_macros.h"

 #if defined(BENCHMARK_OS_MACOSX)
 #include <mach/mach_time.h>
 #endif
 // For MSVC, we want to use '_asm rdtsc' when possible (since it works
 // with even ancient MSVC compilers), and when not possible the
 // __rdtsc intrinsic, declared in <intrin.h>.  Unfortunately, in some
 // environments, <windows.h> and <intrin.h> have conflicting
 // declarations of some other intrinsics, breaking compilation.
 // Therefore, we simply declare __rdtsc ourselves. See also
 // http://connect.microsoft.com/VisualStudio/feedback/details/262047
 #if defined(COMPILER_MSVC) && !defined(_M_IX86) && !defined(_M_ARM64)
 extern "C" uint64_t __rdtsc();
 #pragma intrinsic(__rdtsc)
 #endif

 #if !defined(BENCHMARK_OS_WINDOWS) || defined(BENCHMARK_OS_MINGW)
 #include <sys/time.h>
 #include <time.h>
 #endif

 #ifdef BENCHMARK_OS_EMSCRIPTEN
 #include <emscripten.h>
 #endif

 namespace benchmark {
 // NOTE: only i386 and x86_64 have been well tested.
 // PPC, sparc, alpha, and ia64 are based on
 //    http://peter.kuscsik.com/wordpress/?p=14
 // with modifications by m3b.  See also
 //    https://setisvn.ssl.berkeley.edu/svn/lib/fftw-3.0.1/kernel/cycle.h
 namespace cycleclock {
 // This should return the number of cycles since power-on.  Thread-safe.
 inline BENCHMARK_ALWAYS_INLINE int64_t Now() {
 #if defined(BENCHMARK_OS_MACOSX)
   // this goes at the top because we need ALL Macs, regardless of
   // architecture, to return the number of "mach time units" that
   // have passed since startup.  See sysinfo.cc where
   // InitializeSystemInfo() sets the supposed cpu clock frequency of
   // macs to the number of mach time units per second, not actual
   // CPU clock frequency (which can change in the face of CPU
   // frequency scaling).  Also note that when the Mac sleeps, this
   // counter pauses; it does not continue counting, nor does it
   // reset to zero.
   return mach_absolute_time();
 #elif defined(BENCHMARK_OS_EMSCRIPTEN)
   // this goes above x86-specific code because old versions of Emscripten
   // define __x86_64__, although they have nothing to do with it.
   return static_cast<int64_t>(emscripten_get_now() * 1e+6);
 #elif defined(__i386__)
   int64_t ret;
   __asm__ volatile("rdtsc" : "=A"(ret));
   return ret;
 #elif defined(__x86_64__) || defined(__amd64__)
   uint64_t low, high;
   __asm__ volatile("rdtsc" : "=a"(low), "=d"(high));
   return (high << 32) | low;
 #elif defined(__powerpc__) || defined(__ppc__)
   // This returns a time-base, which is not always precisely a cycle-count.
 #if defined(__powerpc64__) || defined(__ppc64__)
   int64_t tb;
   asm volatile("mfspr %0, 268" : "=r"(tb));
   return tb;
 #else
   uint32_t tbl, tbu0, tbu1;
   asm volatile(
       "mftbu %0\n"
       "mftb %1\n"
       "mftbu %2"
       : "=r"(tbu0), "=r"(tbl), "=r"(tbu1));
   tbl &= -static_cast<int32_t>(tbu0 == tbu1);
   // high 32 bits in tbu1; low 32 bits in tbl  (tbu0 is no longer needed)
   return (static_cast<uint64_t>(tbu1) << 32) | tbl;
 #endif
 #elif defined(__sparc__)
   int64_t tick;
   asm(".byte 0x83, 0x41, 0x00, 0x00");
   asm("mov   %%g1, %0" : "=r"(tick));
   return tick;
 #elif defined(__ia64__)
   int64_t itc;
   asm("mov %0 = ar.itc" : "=r"(itc));
   return itc;
 #elif defined(COMPILER_MSVC) && defined(_M_IX86)
   // Older MSVC compilers (like 7.x) don't seem to support the
   // __rdtsc intrinsic properly, so I prefer to use _asm instead
   // when I know it will work.  Otherwise, I'll use __rdtsc and hope
   // the code is being compiled with a non-ancient compiler.
   _asm rdtsc
 #elif defined(COMPILER_MSVC) && defined(_M_ARM64)
   // See https://docs.microsoft.com/en-us/cpp/intrinsics/arm64-intrinsics?view=vs-2019
   // and https://reviews.llvm.org/D53115
   int64_t virtual_timer_value;
   virtual_timer_value = _ReadStatusReg(ARM64_CNTVCT);
   return virtual_timer_value;
 #elif defined(COMPILER_MSVC)
   return __rdtsc();
 #elif defined(BENCHMARK_OS_NACL)
   // Native Client validator on x86/x86-64 allows RDTSC instructions,
   // and this case is handled above. Native Client validator on ARM
   // rejects MRC instructions (used in the ARM-specific sequence below),
   // so we handle it here. Portable Native Client compiles to
   // architecture-agnostic bytecode, which doesn't provide any
   // cycle counter access mnemonics.

   // Native Client does not provide any API to access cycle counter.
   // Use clock_gettime(CLOCK_MONOTONIC, ...) instead of gettimeofday
   // because is provides nanosecond resolution (which is noticable at
   // least for PNaCl modules running on x86 Mac & Linux).
   // Initialize to always return 0 if clock_gettime fails.
   struct timespec ts = {0, 0};
   clock_gettime(CLOCK_MONOTONIC, &ts);
   return static_cast<int64_t>(ts.tv_sec) * 1000000000 + ts.tv_nsec;
 #elif defined(__aarch64__)
   // System timer of ARMv8 runs at a different frequency than the CPU's.
   // The frequency is fixed, typically in the range 1-50MHz.  It can be
   // read at CNTFRQ special register.  We assume the OS has set up
   // the virtual timer properly.
   int64_t virtual_timer_value;
   asm volatile("mrs %0, cntvct_el0" : "=r"(virtual_timer_value));
   return virtual_timer_value;
 #elif defined(__ARM_ARCH)
   // V6 is the earliest arch that has a standard cyclecount
   // Native Client validator doesn't allow MRC instructions.
 #if (__ARM_ARCH >= 6)
   uint32_t pmccntr;
   uint32_t pmuseren;
   uint32_t pmcntenset;
   // Read the user mode perf monitor counter access permissions.
   asm volatile("mrc p15, 0, %0, c9, c14, 0" : "=r"(pmuseren));
   if (pmuseren & 1) {  // Allows reading perfmon counters for user mode code.
     asm volatile("mrc p15, 0, %0, c9, c12, 1" : "=r"(pmcntenset));
     if (pmcntenset & 0x80000000ul) {  // Is it counting?
       asm volatile("mrc p15, 0, %0, c9, c13, 0" : "=r"(pmccntr));
       // The counter is set up to count every 64th cycle
       return static_cast<int64_t>(pmccntr) * 64;  // Should optimize to << 6
     }
   }
 #endif
   struct timeval tv;
   gettimeofday(&tv, nullptr);
   return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
 #elif defined(__mips__) || defined(__m68k__)
   // mips apparently only allows rdtsc for superusers, so we fall
   // back to gettimeofday.  It's possible clock_gettime would be better.
   struct timeval tv;
   gettimeofday(&tv, nullptr);
   return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
 #elif defined(__loongarch__)
   struct timeval tv;
   gettimeofday(&tv, nullptr);
   return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
 #elif defined(__s390__)  // Covers both s390 and s390x.
   // Return the CPU clock.
   uint64_t tsc;
 #if defined(BENCHMARK_OS_ZOS) && defined(COMPILER_IBMXL)
   // z/OS XL compiler HLASM syntax.
   asm(" stck %0" : "=m"(tsc) : : "cc");
 #else
   asm("stck %0" : "=Q"(tsc) : : "cc");
 #endif
   return tsc;
 #elif defined(__riscv) // RISC-V
   // Use RDCYCLE (and RDCYCLEH on riscv32)
 #if __riscv_xlen == 32
   uint32_t cycles_lo, cycles_hi0, cycles_hi1;
   // This asm also includes the PowerPC overflow handling strategy, as above.
   // Implemented in assembly because Clang insisted on branching.
   asm volatile(
       "rdcycleh %0\n"
       "rdcycle %1\n"
       "rdcycleh %2\n"
       "sub %0, %0, %2\n"
       "seqz %0, %0\n"
       "sub %0, zero, %0\n"
       "and %1, %1, %0\n"
       : "=r"(cycles_hi0), "=r"(cycles_lo), "=r"(cycles_hi1));
   return (static_cast<uint64_t>(cycles_hi1) << 32) | cycles_lo;
 #else
   uint64_t cycles;
   asm volatile("rdcycle %0" : "=r"(cycles));
   return cycles;
 #endif
 #elif defined(__e2k__) || defined(__elbrus__)
   struct timeval tv;
   gettimeofday(&tv, nullptr);
   return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
 #else
 // The soft failover to a generic implementation is automatic only for ARM.
 // For other platforms the developer is expected to make an attempt to create
 // a fast implementation and use generic version if nothing better is available.
 #error You need to define CycleTimer for your OS and CPU
 #endif
 }
 }  // end namespace cycleclock
 }  // end namespace benchmark

 #endif  // BENCHMARK_CYCLECLOCK_H_
	// ----------------------------------------------------------------------
	// CycleClock
	// A CycleClock tells you the current time in Cycles. The "time"
	// is actually time since power-on. This is like time() but doesn't
	// involve a system call and is much more precise.
	//
	// NOTE: Not all cpu/platform/kernel combinations guarantee that this
	// clock increments at a constant rate or is synchronized across all logical
	// cpus in a system.
	//
	// If you need the above guarantees, please consider using a different
	// API. There are efforts to provide an interface which provides a millisecond
	// granularity and implemented as a memory read. A memory read is generally
	// cheaper than the CycleClock for many architectures.
	//
	// Also, in some out of order CPU implementations, the CycleClock is not
	// serializing. So if you're trying to count at cycles granularity, your
	// data might be inaccurate due to out of order instruction execution.
	// ----------------------------------------------------------------------

	#ifndef BENCHMARK_CYCLECLOCK_H_
	#define BENCHMARK_CYCLECLOCK_H_

	#include <cstdint>

	#include "benchmark/benchmark.h"
	#include "internal_macros.h"

	#if defined(BENCHMARK_OS_MACOSX)
	#include <mach/mach_time.h>
	#endif
	// For MSVC, we want to use '_asm rdtsc' when possible (since it works
	// with even ancient MSVC compilers), and when not possible the
	// __rdtsc intrinsic, declared in <intrin.h>. Unfortunately, in some
	// environments, <windows.h> and <intrin.h> have conflicting
	// declarations of some other intrinsics, breaking compilation.
	// Therefore, we simply declare __rdtsc ourselves. See also
	// http://connect.microsoft.com/VisualStudio/feedback/details/262047
	#if defined(COMPILER_MSVC) && !defined(_M_IX86) && !defined(_M_ARM64)
	extern "C" uint64_t __rdtsc();
	#pragma intrinsic(__rdtsc)
	#endif

	#if !defined(BENCHMARK_OS_WINDOWS) \|\| defined(BENCHMARK_OS_MINGW)
	#include <sys/time.h>
	#include <time.h>
	#endif

	#ifdef BENCHMARK_OS_EMSCRIPTEN
	#include <emscripten.h>
	#endif

	namespace benchmark {
	// NOTE: only i386 and x86_64 have been well tested.
	// PPC, sparc, alpha, and ia64 are based on
	// http://peter.kuscsik.com/wordpress/?p=14
	// with modifications by m3b. See also
	// https://setisvn.ssl.berkeley.edu/svn/lib/fftw-3.0.1/kernel/cycle.h
	namespace cycleclock {
	// This should return the number of cycles since power-on. Thread-safe.
	inline BENCHMARK_ALWAYS_INLINE int64_t Now() {
	#if defined(BENCHMARK_OS_MACOSX)
	// this goes at the top because we need ALL Macs, regardless of
	// architecture, to return the number of "mach time units" that
	// have passed since startup. See sysinfo.cc where
	// InitializeSystemInfo() sets the supposed cpu clock frequency of
	// macs to the number of mach time units per second, not actual
	// CPU clock frequency (which can change in the face of CPU
	// frequency scaling). Also note that when the Mac sleeps, this
	// counter pauses; it does not continue counting, nor does it
	// reset to zero.
	return mach_absolute_time();
	#elif defined(BENCHMARK_OS_EMSCRIPTEN)
	// this goes above x86-specific code because old versions of Emscripten
	// define __x86_64__, although they have nothing to do with it.
	return static_cast<int64_t>(emscripten_get_now() * 1e+6);
	#elif defined(__i386__)
	int64_t ret;
	__asm__ volatile("rdtsc" : "=A"(ret));
	return ret;
	#elif defined(__x86_64__) \|\| defined(__amd64__)
	uint64_t low, high;
	__asm__ volatile("rdtsc" : "=a"(low), "=d"(high));
	return (high << 32) \| low;
	#elif defined(__powerpc__) \|\| defined(__ppc__)
	// This returns a time-base, which is not always precisely a cycle-count.
	#if defined(__powerpc64__) \|\| defined(__ppc64__)
	int64_t tb;
	asm volatile("mfspr %0, 268" : "=r"(tb));
	return tb;
	#else
	uint32_t tbl, tbu0, tbu1;
	asm volatile(
	"mftbu %0\n"
	"mftb %1\n"
	"mftbu %2"
	: "=r"(tbu0), "=r"(tbl), "=r"(tbu1));
	tbl &= -static_cast<int32_t>(tbu0 == tbu1);
	// high 32 bits in tbu1; low 32 bits in tbl (tbu0 is no longer needed)
	return (static_cast<uint64_t>(tbu1) << 32) \| tbl;
	#endif
	#elif defined(__sparc__)
	int64_t tick;
	asm(".byte 0x83, 0x41, 0x00, 0x00");
	asm("mov %%g1, %0" : "=r"(tick));
	return tick;
	#elif defined(__ia64__)
	int64_t itc;
	asm("mov %0 = ar.itc" : "=r"(itc));
	return itc;
	#elif defined(COMPILER_MSVC) && defined(_M_IX86)
	// Older MSVC compilers (like 7.x) don't seem to support the
	// __rdtsc intrinsic properly, so I prefer to use _asm instead
	// when I know it will work. Otherwise, I'll use __rdtsc and hope
	// the code is being compiled with a non-ancient compiler.
	_asm rdtsc
	#elif defined(COMPILER_MSVC) && defined(_M_ARM64)
	// See https://docs.microsoft.com/en-us/cpp/intrinsics/arm64-intrinsics?view=vs-2019
	// and https://reviews.llvm.org/D53115
	int64_t virtual_timer_value;
	virtual_timer_value = _ReadStatusReg(ARM64_CNTVCT);
	return virtual_timer_value;
	#elif defined(COMPILER_MSVC)
	return __rdtsc();
	#elif defined(BENCHMARK_OS_NACL)
	// Native Client validator on x86/x86-64 allows RDTSC instructions,
	// and this case is handled above. Native Client validator on ARM
	// rejects MRC instructions (used in the ARM-specific sequence below),
	// so we handle it here. Portable Native Client compiles to
	// architecture-agnostic bytecode, which doesn't provide any
	// cycle counter access mnemonics.

	// Native Client does not provide any API to access cycle counter.
	// Use clock_gettime(CLOCK_MONOTONIC, ...) instead of gettimeofday
	// because is provides nanosecond resolution (which is noticable at
	// least for PNaCl modules running on x86 Mac & Linux).
	// Initialize to always return 0 if clock_gettime fails.
	struct timespec ts = {0, 0};
	clock_gettime(CLOCK_MONOTONIC, &ts);
	return static_cast<int64_t>(ts.tv_sec) * 1000000000 + ts.tv_nsec;
	#elif defined(__aarch64__)
	// System timer of ARMv8 runs at a different frequency than the CPU's.
	// The frequency is fixed, typically in the range 1-50MHz. It can be
	// read at CNTFRQ special register. We assume the OS has set up
	// the virtual timer properly.
	int64_t virtual_timer_value;
	asm volatile("mrs %0, cntvct_el0" : "=r"(virtual_timer_value));
	return virtual_timer_value;
	#elif defined(__ARM_ARCH)
	// V6 is the earliest arch that has a standard cyclecount
	// Native Client validator doesn't allow MRC instructions.
	#if (__ARM_ARCH >= 6)
	uint32_t pmccntr;
	uint32_t pmuseren;
	uint32_t pmcntenset;
	// Read the user mode perf monitor counter access permissions.
	asm volatile("mrc p15, 0, %0, c9, c14, 0" : "=r"(pmuseren));
	if (pmuseren & 1) { // Allows reading perfmon counters for user mode code.
	asm volatile("mrc p15, 0, %0, c9, c12, 1" : "=r"(pmcntenset));
	if (pmcntenset & 0x80000000ul) { // Is it counting?
	asm volatile("mrc p15, 0, %0, c9, c13, 0" : "=r"(pmccntr));
	// The counter is set up to count every 64th cycle
	return static_cast<int64_t>(pmccntr) * 64; // Should optimize to << 6
	}
	}
	#endif
	struct timeval tv;
	gettimeofday(&tv, nullptr);
	return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
	#elif defined(__mips__) \|\| defined(__m68k__)
	// mips apparently only allows rdtsc for superusers, so we fall
	// back to gettimeofday. It's possible clock_gettime would be better.
	struct timeval tv;
	gettimeofday(&tv, nullptr);
	return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
	#elif defined(__loongarch__)
	struct timeval tv;
	gettimeofday(&tv, nullptr);
	return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
	#elif defined(__s390__) // Covers both s390 and s390x.
	// Return the CPU clock.
	uint64_t tsc;
	#if defined(BENCHMARK_OS_ZOS) && defined(COMPILER_IBMXL)
	// z/OS XL compiler HLASM syntax.
	asm(" stck %0" : "=m"(tsc) : : "cc");
	#else
	asm("stck %0" : "=Q"(tsc) : : "cc");
	#endif
	return tsc;
	#elif defined(__riscv) // RISC-V
	// Use RDCYCLE (and RDCYCLEH on riscv32)
	#if __riscv_xlen == 32
	uint32_t cycles_lo, cycles_hi0, cycles_hi1;
	// This asm also includes the PowerPC overflow handling strategy, as above.
	// Implemented in assembly because Clang insisted on branching.
	asm volatile(
	"rdcycleh %0\n"
	"rdcycle %1\n"
	"rdcycleh %2\n"
	"sub %0, %0, %2\n"
	"seqz %0, %0\n"
	"sub %0, zero, %0\n"
	"and %1, %1, %0\n"
	: "=r"(cycles_hi0), "=r"(cycles_lo), "=r"(cycles_hi1));
	return (static_cast<uint64_t>(cycles_hi1) << 32) \| cycles_lo;
	#else
	uint64_t cycles;
	asm volatile("rdcycle %0" : "=r"(cycles));
	return cycles;
	#endif
	#elif defined(__e2k__) \|\| defined(__elbrus__)
	struct timeval tv;
	gettimeofday(&tv, nullptr);
	return static_cast<int64_t>(tv.tv_sec) * 1000000 + tv.tv_usec;
	#else
	// The soft failover to a generic implementation is automatic only for ARM.
	// For other platforms the developer is expected to make an attempt to create
	// a fast implementation and use generic version if nothing better is available.
	#error You need to define CycleTimer for your OS and CPU
	#endif
	}
	} // end namespace cycleclock
	} // end namespace benchmark

	#endif // BENCHMARK_CYCLECLOCK_H_