third_party/highway/hwy/timer.h - aom - Git at Google

 // Copyright 2023 Google LLC
 // SPDX-License-Identifier: Apache-2.0
 //
 // 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.

 #ifndef HIGHWAY_HWY_TIMER_H_
 #define HIGHWAY_HWY_TIMER_H_

 // Platform-specific timer functions. Provides Now() and functions for
 // interpreting and converting Ticks.

 #include <stdint.h>
 #include <time.h>  // clock_gettime

 #include "third_party/highway/hwy/base.h"

 #if defined(_WIN32) || defined(_WIN64)
 #ifndef NOMINMAX
 #define NOMINMAX
 #endif  // NOMINMAX
 #ifndef WIN32_LEAN_AND_MEAN
 #define WIN32_LEAN_AND_MEAN
 #endif  // WIN32_LEAN_AND_MEAN
 #include <windows.h>
 #endif

 #if defined(__APPLE__)
 #include <mach/mach.h>
 #include <mach/mach_time.h>
 #endif

 #if defined(__HAIKU__)
 #include <OS.h>
 #endif

 #if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
 #include <sys/platform/ppc.h>  // NOLINT __ppc_get_timebase_freq
 #endif

 #if HWY_ARCH_X86 && HWY_COMPILER_MSVC
 #include <intrin.h>
 #endif

 namespace hwy {
 namespace platform {

 // Returns current timestamp [in seconds] relative to an unspecified origin.
 // Features: monotonic (no negative elapsed time), steady (unaffected by system
 // time changes), high-resolution (on the order of microseconds).
 // Uses InvariantTicksPerSecond and the baseline version of timer::Start().
 HWY_DLLEXPORT double Now();

 // Functions related to `Ticks` below.

 // Returns whether it is safe to call timer::Stop without executing an illegal
 // instruction; if false, fills cpu100 (a pointer to a 100 character buffer)
 // via GetCpuString().
 HWY_DLLEXPORT bool HaveTimerStop(char* cpu100);

 // Returns tick rate, useful for converting timer::Ticks to seconds. Invariant
 // means the tick counter frequency is independent of CPU throttling or sleep.
 // This call may be expensive, callers should cache the result.
 HWY_DLLEXPORT double InvariantTicksPerSecond();

 // Returns ticks elapsed in back to back timer calls, i.e. a function of the
 // timer resolution (minimum measurable difference) and overhead.
 // This call is expensive, callers should cache the result.
 HWY_DLLEXPORT uint64_t TimerResolution();

 // Returns false if no detailed description is available, otherwise fills
 // `cpu100` with up to 100 characters (including \0) identifying the CPU model.
 HWY_DLLEXPORT bool GetCpuString(char* cpu100);

 }  // namespace platform

 struct Timestamp {
   Timestamp() { t = platform::Now(); }
   double t;
 };

 static inline double SecondsSince(const Timestamp& t0) {
   const Timestamp t1;
   return t1.t - t0.t;
 }

 // Low-level Start/Stop functions, previously in timer-inl.h.

 namespace timer {

 // Ticks := platform-specific timer values (CPU cycles on x86). Must be
 // unsigned to guarantee wraparound on overflow.
 using Ticks = uint64_t;

 // Start/Stop return absolute timestamps and must be placed immediately before
 // and after the region to measure. We provide separate Start/Stop functions
 // because they use different fences.
 //
 // Background: RDTSC is not 'serializing'; earlier instructions may complete
 // after it, and/or later instructions may complete before it. 'Fences' ensure
 // regions' elapsed times are independent of such reordering. The only
 // documented unprivileged serializing instruction is CPUID, which acts as a
 // full fence (no reordering across it in either direction). Unfortunately
 // the latency of CPUID varies wildly (perhaps made worse by not initializing
 // its EAX input). Because it cannot reliably be deducted from the region's
 // elapsed time, it must not be included in the region to measure (i.e.
 // between the two RDTSC).
 //
 // The newer RDTSCP is sometimes described as serializing, but it actually
 // only serves as a half-fence with release semantics. Although all
 // instructions in the region will complete before the final timestamp is
 // captured, subsequent instructions may leak into the region and increase the
 // elapsed time. Inserting another fence after the final `RDTSCP` would prevent
 // such reordering without affecting the measured region.
 //
 // Fortunately, such a fence exists. The LFENCE instruction is only documented
 // to delay later loads until earlier loads are visible. However, Intel's
 // reference manual says it acts as a full fence (waiting until all earlier
 // instructions have completed, and delaying later instructions until it
 // completes). AMD assigns the same behavior to MFENCE.
 //
 // We need a fence before the initial RDTSC to prevent earlier instructions
 // from leaking into the region, and arguably another after RDTSC to avoid
 // region instructions from completing before the timestamp is recorded.
 // When surrounded by fences, the additional `RDTSCP` half-fence provides no
 // benefit, so the initial timestamp can be recorded via RDTSC, which has
 // lower overhead than `RDTSCP` because it does not read TSC_AUX. In summary,
 // we define Start = LFENCE/RDTSC/LFENCE; Stop = RDTSCP/LFENCE.
 //
 // Using Start+Start leads to higher variance and overhead than Stop+Stop.
 // However, Stop+Stop includes an LFENCE in the region measurements, which
 // adds a delay dependent on earlier loads. The combination of Start+Stop
 // is faster than Start+Start and more consistent than Stop+Stop because
 // the first LFENCE already delayed subsequent loads before the measured
 // region. This combination seems not to have been considered in prior work:
 // http://akaros.cs.berkeley.edu/lxr/akaros/kern/arch/x86/rdtsc_test.c
 //
 // Note: performance counters can measure 'exact' instructions-retired or
 // (unhalted) cycle counts. The RDPMC instruction is not serializing and also
 // requires fences. Unfortunately, it is not accessible on all OSes and we
 // prefer to avoid kernel-mode drivers. Performance counters are also affected
 // by several under/over-count errata, so we use the TSC instead.

 // Returns a 64-bit timestamp in unit of 'ticks'; to convert to seconds,
 // divide by InvariantTicksPerSecond.
 static HWY_INLINE Ticks Start() {
   Ticks t;
 #if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
   asm volatile("mfspr %0, %1" : "=r"(t) : "i"(268));
 #elif HWY_ARCH_ARM_A64 && !HWY_COMPILER_MSVC
   // pmccntr_el0 is privileged but cntvct_el0 is accessible in Linux and QEMU.
   asm volatile("mrs %0, cntvct_el0" : "=r"(t));
 #elif HWY_ARCH_X86 && HWY_COMPILER_MSVC
   _ReadWriteBarrier();
   _mm_lfence();
   _ReadWriteBarrier();
   t = __rdtsc();
   _ReadWriteBarrier();
   _mm_lfence();
   _ReadWriteBarrier();
 #elif HWY_ARCH_X86_64
   asm volatile(
       "lfence\n\t"
       "rdtsc\n\t"
       "shl $32, %%rdx\n\t"
       "or %%rdx, %0\n\t"
       "lfence"
       : "=a"(t)
       :
       // "memory" avoids reordering. rdx = TSC >> 32.
       // "cc" = flags modified by SHL.
       : "rdx", "memory", "cc");
 #elif HWY_ARCH_RISCV
   asm volatile("fence; rdtime %0" : "=r"(t));
 #elif defined(_WIN32) || defined(_WIN64)
   LARGE_INTEGER counter;
   (void)QueryPerformanceCounter(&counter);
   t = counter.QuadPart;
 #elif defined(__APPLE__)
   t = mach_absolute_time();
 #elif defined(__HAIKU__)
   t = system_time_nsecs();  // since boot
 #else  // POSIX
   timespec ts;
   clock_gettime(CLOCK_MONOTONIC, &ts);
   t = static_cast<Ticks>(ts.tv_sec * 1000000000LL + ts.tv_nsec);
 #endif
   return t;
 }

 // WARNING: on x86, caller must check `HaveTimerStop()` before using this!
 static HWY_INLINE Ticks Stop() {
   uint64_t t;
 #if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
   asm volatile("mfspr %0, %1" : "=r"(t) : "i"(268));
 #elif HWY_ARCH_ARM_A64 && !HWY_COMPILER_MSVC
   // pmccntr_el0 is privileged but cntvct_el0 is accessible in Linux and QEMU.
   asm volatile("mrs %0, cntvct_el0" : "=r"(t));
 #elif HWY_ARCH_X86 && HWY_COMPILER_MSVC
   _ReadWriteBarrier();
   unsigned aux;
   t = __rdtscp(&aux);
   _ReadWriteBarrier();
   _mm_lfence();
   _ReadWriteBarrier();
 #elif HWY_ARCH_X86_64
   // Use inline asm because __rdtscp generates code to store TSC_AUX (ecx).
   asm volatile(
       "rdtscp\n\t"
       "shl $32, %%rdx\n\t"
       "or %%rdx, %0\n\t"
       "lfence"
       : "=a"(t)
       :
       // "memory" avoids reordering. rcx = TSC_AUX. rdx = TSC >> 32.
       // "cc" = flags modified by SHL.
       : "rcx", "rdx", "memory", "cc");
 #else
   t = Start();
 #endif
   return t;
 }

 }  // namespace timer

 }  // namespace hwy

 #endif  // HIGHWAY_HWY_TIMER_H_
	// Copyright 2023 Google LLC
	// SPDX-License-Identifier: Apache-2.0
	//
	// 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.

	#ifndef HIGHWAY_HWY_TIMER_H_
	#define HIGHWAY_HWY_TIMER_H_

	// Platform-specific timer functions. Provides Now() and functions for
	// interpreting and converting Ticks.

	#include <stdint.h>
	#include <time.h> // clock_gettime

	#include "third_party/highway/hwy/base.h"

	#if defined(_WIN32) \|\| defined(_WIN64)
	#ifndef NOMINMAX
	#define NOMINMAX
	#endif // NOMINMAX
	#ifndef WIN32_LEAN_AND_MEAN
	#define WIN32_LEAN_AND_MEAN
	#endif // WIN32_LEAN_AND_MEAN
	#include <windows.h>
	#endif

	#if defined(__APPLE__)
	#include <mach/mach.h>
	#include <mach/mach_time.h>
	#endif

	#if defined(__HAIKU__)
	#include <OS.h>
	#endif

	#if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
	#include <sys/platform/ppc.h> // NOLINT __ppc_get_timebase_freq
	#endif

	#if HWY_ARCH_X86 && HWY_COMPILER_MSVC
	#include <intrin.h>
	#endif

	namespace hwy {
	namespace platform {

	// Returns current timestamp [in seconds] relative to an unspecified origin.
	// Features: monotonic (no negative elapsed time), steady (unaffected by system
	// time changes), high-resolution (on the order of microseconds).
	// Uses InvariantTicksPerSecond and the baseline version of timer::Start().
	HWY_DLLEXPORT double Now();

	// Functions related to `Ticks` below.

	// Returns whether it is safe to call timer::Stop without executing an illegal
	// instruction; if false, fills cpu100 (a pointer to a 100 character buffer)
	// via GetCpuString().
	HWY_DLLEXPORT bool HaveTimerStop(char* cpu100);

	// Returns tick rate, useful for converting timer::Ticks to seconds. Invariant
	// means the tick counter frequency is independent of CPU throttling or sleep.
	// This call may be expensive, callers should cache the result.
	HWY_DLLEXPORT double InvariantTicksPerSecond();

	// Returns ticks elapsed in back to back timer calls, i.e. a function of the
	// timer resolution (minimum measurable difference) and overhead.
	// This call is expensive, callers should cache the result.
	HWY_DLLEXPORT uint64_t TimerResolution();

	// Returns false if no detailed description is available, otherwise fills
	// `cpu100` with up to 100 characters (including \0) identifying the CPU model.
	HWY_DLLEXPORT bool GetCpuString(char* cpu100);

	} // namespace platform

	struct Timestamp {
	Timestamp() { t = platform::Now(); }
	double t;
	};

	static inline double SecondsSince(const Timestamp& t0) {
	const Timestamp t1;
	return t1.t - t0.t;
	}

	// Low-level Start/Stop functions, previously in timer-inl.h.

	namespace timer {

	// Ticks := platform-specific timer values (CPU cycles on x86). Must be
	// unsigned to guarantee wraparound on overflow.
	using Ticks = uint64_t;

	// Start/Stop return absolute timestamps and must be placed immediately before
	// and after the region to measure. We provide separate Start/Stop functions
	// because they use different fences.
	//
	// Background: RDTSC is not 'serializing'; earlier instructions may complete
	// after it, and/or later instructions may complete before it. 'Fences' ensure
	// regions' elapsed times are independent of such reordering. The only
	// documented unprivileged serializing instruction is CPUID, which acts as a
	// full fence (no reordering across it in either direction). Unfortunately
	// the latency of CPUID varies wildly (perhaps made worse by not initializing
	// its EAX input). Because it cannot reliably be deducted from the region's
	// elapsed time, it must not be included in the region to measure (i.e.
	// between the two RDTSC).
	//
	// The newer RDTSCP is sometimes described as serializing, but it actually
	// only serves as a half-fence with release semantics. Although all
	// instructions in the region will complete before the final timestamp is
	// captured, subsequent instructions may leak into the region and increase the
	// elapsed time. Inserting another fence after the final `RDTSCP` would prevent
	// such reordering without affecting the measured region.
	//
	// Fortunately, such a fence exists. The LFENCE instruction is only documented
	// to delay later loads until earlier loads are visible. However, Intel's
	// reference manual says it acts as a full fence (waiting until all earlier
	// instructions have completed, and delaying later instructions until it
	// completes). AMD assigns the same behavior to MFENCE.
	//
	// We need a fence before the initial RDTSC to prevent earlier instructions
	// from leaking into the region, and arguably another after RDTSC to avoid
	// region instructions from completing before the timestamp is recorded.
	// When surrounded by fences, the additional `RDTSCP` half-fence provides no
	// benefit, so the initial timestamp can be recorded via RDTSC, which has
	// lower overhead than `RDTSCP` because it does not read TSC_AUX. In summary,
	// we define Start = LFENCE/RDTSC/LFENCE; Stop = RDTSCP/LFENCE.
	//
	// Using Start+Start leads to higher variance and overhead than Stop+Stop.
	// However, Stop+Stop includes an LFENCE in the region measurements, which
	// adds a delay dependent on earlier loads. The combination of Start+Stop
	// is faster than Start+Start and more consistent than Stop+Stop because
	// the first LFENCE already delayed subsequent loads before the measured
	// region. This combination seems not to have been considered in prior work:
	// http://akaros.cs.berkeley.edu/lxr/akaros/kern/arch/x86/rdtsc_test.c
	//
	// Note: performance counters can measure 'exact' instructions-retired or
	// (unhalted) cycle counts. The RDPMC instruction is not serializing and also
	// requires fences. Unfortunately, it is not accessible on all OSes and we
	// prefer to avoid kernel-mode drivers. Performance counters are also affected
	// by several under/over-count errata, so we use the TSC instead.

	// Returns a 64-bit timestamp in unit of 'ticks'; to convert to seconds,
	// divide by InvariantTicksPerSecond.
	static HWY_INLINE Ticks Start() {
	Ticks t;
	#if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
	asm volatile("mfspr %0, %1" : "=r"(t) : "i"(268));
	#elif HWY_ARCH_ARM_A64 && !HWY_COMPILER_MSVC
	// pmccntr_el0 is privileged but cntvct_el0 is accessible in Linux and QEMU.
	asm volatile("mrs %0, cntvct_el0" : "=r"(t));
	#elif HWY_ARCH_X86 && HWY_COMPILER_MSVC
	_ReadWriteBarrier();
	_mm_lfence();
	_ReadWriteBarrier();
	t = __rdtsc();
	_ReadWriteBarrier();
	_mm_lfence();
	_ReadWriteBarrier();
	#elif HWY_ARCH_X86_64
	asm volatile(
	"lfence\n\t"
	"rdtsc\n\t"
	"shl $32, %%rdx\n\t"
	"or %%rdx, %0\n\t"
	"lfence"
	: "=a"(t)
	:
	// "memory" avoids reordering. rdx = TSC >> 32.
	// "cc" = flags modified by SHL.
	: "rdx", "memory", "cc");
	#elif HWY_ARCH_RISCV
	asm volatile("fence; rdtime %0" : "=r"(t));
	#elif defined(_WIN32) \|\| defined(_WIN64)
	LARGE_INTEGER counter;
	(void)QueryPerformanceCounter(&counter);
	t = counter.QuadPart;
	#elif defined(__APPLE__)
	t = mach_absolute_time();
	#elif defined(__HAIKU__)
	t = system_time_nsecs(); // since boot
	#else // POSIX
	timespec ts;
	clock_gettime(CLOCK_MONOTONIC, &ts);
	t = static_cast<Ticks>(ts.tv_sec * 1000000000LL + ts.tv_nsec);
	#endif
	return t;
	}

	// WARNING: on x86, caller must check `HaveTimerStop()` before using this!
	static HWY_INLINE Ticks Stop() {
	uint64_t t;
	#if HWY_ARCH_PPC && defined(__GLIBC__) && defined(__powerpc64__)
	asm volatile("mfspr %0, %1" : "=r"(t) : "i"(268));
	#elif HWY_ARCH_ARM_A64 && !HWY_COMPILER_MSVC
	// pmccntr_el0 is privileged but cntvct_el0 is accessible in Linux and QEMU.
	asm volatile("mrs %0, cntvct_el0" : "=r"(t));
	#elif HWY_ARCH_X86 && HWY_COMPILER_MSVC
	_ReadWriteBarrier();
	unsigned aux;
	t = __rdtscp(&aux);
	_ReadWriteBarrier();
	_mm_lfence();
	_ReadWriteBarrier();
	#elif HWY_ARCH_X86_64
	// Use inline asm because __rdtscp generates code to store TSC_AUX (ecx).
	asm volatile(
	"rdtscp\n\t"
	"shl $32, %%rdx\n\t"
	"or %%rdx, %0\n\t"
	"lfence"
	: "=a"(t)
	:
	// "memory" avoids reordering. rcx = TSC_AUX. rdx = TSC >> 32.
	// "cc" = flags modified by SHL.
	: "rcx", "rdx", "memory", "cc");
	#else
	t = Start();
	#endif
	return t;
	}

	} // namespace timer

	} // namespace hwy

	#endif // HIGHWAY_HWY_TIMER_H_