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citra/externals/microprofile/microprofile.h
Tobias c557b290af
microprofile: Don't memset through std::atomic types (#5528) 
Two of the members of the MicroProfileThreadLog contains two std::atomic
instances. Given these aren't trivially-copyable types, we shouldn't be
memsetting the structure, given implementation details can contain other
members within it.

To avoid potential undefined behavior on platforms, we can use aggregate
initialization to zero out the members while still having well-defined
behavior.

While we're at it we can also silence some sign conversion warnings.

Co-authored-by: Lioncash <mathew1800@gmail.com>
2020-12-07 16:04:31 +01:00

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#pragma once
// This is free and unencumbered software released into the public domain.
// Anyone is free to copy, modify, publish, use, compile, sell, or
// distribute this software, either in source code form or as a compiled
// binary, for any purpose, commercial or non-commercial, and by any
// means.
// In jurisdictions that recognize copyright laws, the author or authors
// of this software dedicate any and all copyright interest in the
// software to the public domain. We make this dedication for the benefit
// of the public at large and to the detriment of our heirs and
// successors. We intend this dedication to be an overt act of
// relinquishment in perpetuity of all present and future rights to this
// software under copyright law.
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
// EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
// IN NO EVENT SHALL THE AUTHORS BE LIABLE FOR ANY CLAIM, DAMAGES OR
// OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
// ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
// OTHER DEALINGS IN THE SOFTWARE.
// For more information, please refer to <http://unlicense.org/>
//
// ***********************************************************************
//
//
//
//
// Howto:
// Call these functions from your code:
// MicroProfileOnThreadCreate
// MicroProfileMouseButton
// MicroProfileMousePosition
// MicroProfileModKey
// MicroProfileFlip <-- Call this once per frame
// MicroProfileDraw <-- Call this once per frame
// MicroProfileToggleDisplayMode <-- Bind to a key to toggle profiling
// MicroProfileTogglePause <-- Bind to a key to toggle pause
//
// Use these macros in your code in blocks you want to time:
//
// MICROPROFILE_DECLARE
// MICROPROFILE_DEFINE
// MICROPROFILE_DECLARE_GPU
// MICROPROFILE_DEFINE_GPU
// MICROPROFILE_SCOPE
// MICROPROFILE_SCOPEI
// MICROPROFILE_SCOPEGPU
// MICROPROFILE_SCOPEGPUI
// MICROPROFILE_META
//
//
// Usage:
//
// {
// MICROPROFILE_SCOPEI("GroupName", "TimerName", nColorRgb):
// ..Code to be timed..
// }
//
// MICROPROFILE_DECLARE / MICROPROFILE_DEFINE allows defining groups in a shared place, to ensure sorting of the timers
//
// (in global scope)
// MICROPROFILE_DEFINE(g_ProfileFisk, "Fisk", "Skalle", nSomeColorRgb);
//
// (in some other file)
// MICROPROFILE_DECLARE(g_ProfileFisk);
//
// void foo(){
// MICROPROFILE_SCOPE(g_ProfileFisk);
// }
//
// Once code is instrumented the gui is activeted by calling MicroProfileToggleDisplayMode or by clicking in the upper left corner of
// the screen
//
// The following functions must be implemented before the profiler is usable
// debug render:
// void MicroProfileDrawText(int nX, int nY, uint32_t nColor, const char* pText, uint32_t nNumCharacters);
// void MicroProfileDrawBox(int nX, int nY, int nX1, int nY1, uint32_t nColor, MicroProfileBoxType = MicroProfileBoxTypeFlat);
// void MicroProfileDrawLine2D(uint32_t nVertices, float* pVertices, uint32_t nColor);
// Gpu time stamps: (See below for d3d/opengl helper)
// uint32_t MicroProfileGpuInsertTimeStamp();
// uint64_t MicroProfileGpuGetTimeStamp(uint32_t nKey);
// uint64_t MicroProfileTicksPerSecondGpu();
// threading:
// const char* MicroProfileGetThreadName(); Threadnames in detailed view
//
// Default implementations of Gpu timestamp functions:
// Opengl:
// in .c file where MICROPROFILE_IMPL is defined:
// #define MICROPROFILE_GPU_TIMERS_GL
// call MicroProfileGpuInitGL() on startup
// D3D11:
// in .c file where MICROPROFILE_IMPL is defined:
// #define MICROPROFILE_GPU_TIMERS_D3D11
// call MICROPROFILE_GPU_TIMERS_D3D11(). Pass Device & ImmediateContext
//
// Limitations:
// GPU timestamps can only be inserted from one thread.
#ifndef MICROPROFILE_ENABLED
#define MICROPROFILE_ENABLED 1
#endif
#include <stdint.h>
typedef uint64_t MicroProfileToken;
typedef uint16_t MicroProfileGroupId;
#if 0 == MICROPROFILE_ENABLED
#define MICROPROFILE_DECLARE(var)
#define MICROPROFILE_DEFINE(var, group, name, color)
#define MICROPROFILE_REGISTER_GROUP(group, color, category)
#define MICROPROFILE_DECLARE_GPU(var)
#define MICROPROFILE_DEFINE_GPU(var, name, color)
#define MICROPROFILE_SCOPE(var) do{}while(0)
#define MICROPROFILE_SCOPEI(group, name, color) do{}while(0)
#define MICROPROFILE_SCOPEGPU(var) do{}while(0)
#define MICROPROFILE_SCOPEGPUI( name, color) do{}while(0)
#define MICROPROFILE_META_CPU(name, count)
#define MICROPROFILE_META_GPU(name, count)
#define MICROPROFILE_FORCEENABLECPUGROUP(s) do{} while(0)
#define MICROPROFILE_FORCEDISABLECPUGROUP(s) do{} while(0)
#define MICROPROFILE_FORCEENABLEGPUGROUP(s) do{} while(0)
#define MICROPROFILE_FORCEDISABLEGPUGROUP(s) do{} while(0)
#define MICROPROFILE_SCOPE_TOKEN(token)
#define MicroProfileGetTime(group, name) 0.f
#define MicroProfileOnThreadCreate(foo) do{}while(0)
#define MicroProfileFlip() do{}while(0)
#define MicroProfileSetAggregateFrames(a) do{}while(0)
#define MicroProfileGetAggregateFrames() 0
#define MicroProfileGetCurrentAggregateFrames() 0
#define MicroProfileTogglePause() do{}while(0)
#define MicroProfileToggleAllGroups() do{} while(0)
#define MicroProfileDumpTimers() do{}while(0)
#define MicroProfileShutdown() do{}while(0)
#define MicroProfileSetForceEnable(a) do{} while(0)
#define MicroProfileGetForceEnable() false
#define MicroProfileSetEnableAllGroups(a) do{} while(0)
#define MicroProfileEnableCategory(a) do{} while(0)
#define MicroProfileDisableCategory(a) do{} while(0)
#define MicroProfileGetEnableAllGroups() false
#define MicroProfileSetForceMetaCounters(a)
#define MicroProfileGetForceMetaCounters() 0
#define MicroProfileEnableMetaCounter(c) do{}while(0)
#define MicroProfileDisableMetaCounter(c) do{}while(0)
#define MicroProfileDumpFile(html,csv) do{} while(0)
#define MicroProfileWebServerPort() ((uint32_t)-1)
#else
#include <stdint.h>
#include <string.h>
#include <algorithm>
#include <array>
#include <atomic>
#include <mutex>
#include <thread>
#ifndef MICROPROFILE_API
#define MICROPROFILE_API
#endif
MICROPROFILE_API int64_t MicroProfileTicksPerSecondCpu();
#if defined(__APPLE__)
#include <mach/mach.h>
#include <mach/mach_time.h>
#include <unistd.h>
#include <libkern/OSAtomic.h>
#include <TargetConditionals.h>
#if TARGET_OS_IPHONE
#define MICROPROFILE_IOS
#endif
#define MP_TICK() mach_absolute_time()
inline int64_t MicroProfileTicksPerSecondCpu()
{
static int64_t nTicksPerSecond = 0;
if(nTicksPerSecond == 0)
{
mach_timebase_info_data_t sTimebaseInfo;
mach_timebase_info(&sTimebaseInfo);
nTicksPerSecond = 1000000000ll * sTimebaseInfo.denom / sTimebaseInfo.numer;
}
return nTicksPerSecond;
}
inline uint64_t MicroProfileGetCurrentThreadId()
{
uint64_t tid;
pthread_threadid_np(pthread_self(), &tid);
return tid;
}
#define MP_BREAK() __builtin_trap()
#define MP_THREAD_LOCAL __thread
#define MP_STRCASECMP strcasecmp
#define MP_GETCURRENTTHREADID() MicroProfileGetCurrentThreadId()
typedef uint64_t ThreadIdType;
#elif defined(_WIN32)
int64_t MicroProfileGetTick();
#define MP_TICK() MicroProfileGetTick()
#define MP_BREAK() __debugbreak()
#define MP_THREAD_LOCAL thread_local
#define MP_STRCASECMP _stricmp
#define MP_GETCURRENTTHREADID() GetCurrentThreadId()
typedef uint32_t ThreadIdType;
#elif !defined(_WIN32)
#include <unistd.h>
#include <time.h>
inline int64_t MicroProfileTicksPerSecondCpu()
{
return 1000000000ll;
}
inline int64_t MicroProfileGetTick()
{
timespec ts;
clock_gettime(CLOCK_REALTIME, &ts);
return 1000000000ll * ts.tv_sec + ts.tv_nsec;
}
#define MP_TICK() MicroProfileGetTick()
#define MP_BREAK() __builtin_trap()
#define MP_THREAD_LOCAL __thread
#define MP_STRCASECMP strcasecmp
#define MP_GETCURRENTTHREADID() (uint64_t)pthread_self()
typedef uint64_t ThreadIdType;
#endif
#ifndef MP_GETCURRENTTHREADID
#define MP_GETCURRENTTHREADID() 0
typedef uint32_t ThreadIdType;
#endif
#define MP_ASSERT(a) do{if(!(a)){MP_BREAK();} }while(0)
#define MICROPROFILE_DECLARE(var) extern MicroProfileToken g_mp_##var
#define MICROPROFILE_DEFINE(var, group, name, color) MicroProfileToken g_mp_##var = MicroProfileGetToken(group, name, color, MicroProfileTokenTypeCpu)
#define MICROPROFILE_REGISTER_GROUP(group, category, color) MicroProfileRegisterGroup(group, category, color)
#define MICROPROFILE_DECLARE_GPU(var) extern MicroProfileToken g_mp_##var
#define MICROPROFILE_DEFINE_GPU(var, name, color) MicroProfileToken g_mp_##var = MicroProfileGetToken("GPU", name, color, MicroProfileTokenTypeGpu)
#define MICROPROFILE_TOKEN_PASTE0(a, b) a ## b
#define MICROPROFILE_TOKEN_PASTE(a, b) MICROPROFILE_TOKEN_PASTE0(a,b)
#define MICROPROFILE_TOKEN(var) g_mp_##var
#define MICROPROFILE_SCOPE(var) MicroProfileScopeHandler MICROPROFILE_TOKEN_PASTE(foo, __LINE__)(g_mp_##var)
#define MICROPROFILE_SCOPE_TOKEN(token) MicroProfileScopeHandler MICROPROFILE_TOKEN_PASTE(foo, __LINE__)(token)
#define MICROPROFILE_SCOPEI(group, name, color) static MicroProfileToken MICROPROFILE_TOKEN_PASTE(g_mp,__LINE__) = MicroProfileGetToken(group, name, color, MicroProfileTokenTypeCpu); MicroProfileScopeHandler MICROPROFILE_TOKEN_PASTE(foo,__LINE__)( MICROPROFILE_TOKEN_PASTE(g_mp,__LINE__))
#define MICROPROFILE_SCOPEGPU(var) MicroProfileScopeGpuHandler MICROPROFILE_TOKEN_PASTE(foo, __LINE__)(g_mp_##var)
#define MICROPROFILE_SCOPEGPUI(name, color) static MicroProfileToken MICROPROFILE_TOKEN_PASTE(g_mp,__LINE__) = MicroProfileGetToken("GPU", name, color, MicroProfileTokenTypeGpu); MicroProfileScopeGpuHandler MICROPROFILE_TOKEN_PASTE(foo,__LINE__)( MICROPROFILE_TOKEN_PASTE(g_mp,__LINE__))
#define MICROPROFILE_META_CPU(name, count) static MicroProfileToken MICROPROFILE_TOKEN_PASTE(g_mp_meta,__LINE__) = MicroProfileGetMetaToken(name); MicroProfileMetaUpdate(MICROPROFILE_TOKEN_PASTE(g_mp_meta,__LINE__), count, MicroProfileTokenTypeCpu)
#define MICROPROFILE_META_GPU(name, count) static MicroProfileToken MICROPROFILE_TOKEN_PASTE(g_mp_meta,__LINE__) = MicroProfileGetMetaToken(name); MicroProfileMetaUpdate(MICROPROFILE_TOKEN_PASTE(g_mp_meta,__LINE__), count, MicroProfileTokenTypeGpu)
#ifndef MICROPROFILE_USE_THREAD_NAME_CALLBACK
#define MICROPROFILE_USE_THREAD_NAME_CALLBACK 0
#endif
#ifndef MICROPROFILE_PER_THREAD_BUFFER_SIZE
#define MICROPROFILE_PER_THREAD_BUFFER_SIZE (2048<<10)
#endif
#ifndef MICROPROFILE_MAX_FRAME_HISTORY
#define MICROPROFILE_MAX_FRAME_HISTORY 512
#endif
#ifndef MICROPROFILE_PRINTF
#define MICROPROFILE_PRINTF printf
#endif
#ifndef MICROPROFILE_META_MAX
#define MICROPROFILE_META_MAX 8
#endif
#ifndef MICROPROFILE_WEBSERVER_PORT
#define MICROPROFILE_WEBSERVER_PORT 1338
#endif
#ifndef MICROPROFILE_WEBSERVER
#define MICROPROFILE_WEBSERVER 1
#endif
#ifndef MICROPROFILE_WEBSERVER_MAXFRAMES
#define MICROPROFILE_WEBSERVER_MAXFRAMES 30
#endif
#ifndef MICROPROFILE_WEBSERVER_SOCKET_BUFFER_SIZE
#define MICROPROFILE_WEBSERVER_SOCKET_BUFFER_SIZE (16<<10)
#endif
#ifndef MICROPROFILE_GPU_TIMERS
#define MICROPROFILE_GPU_TIMERS 1
#endif
#ifndef MICROPROFILE_GPU_FRAME_DELAY
#define MICROPROFILE_GPU_FRAME_DELAY 3 //must be > 0
#endif
#ifndef MICROPROFILE_NAME_MAX_LEN
#define MICROPROFILE_NAME_MAX_LEN 64
#endif
#define MICROPROFILE_FORCEENABLECPUGROUP(s) MicroProfileForceEnableGroup(s, MicroProfileTokenTypeCpu)
#define MICROPROFILE_FORCEDISABLECPUGROUP(s) MicroProfileForceDisableGroup(s, MicroProfileTokenTypeCpu)
#define MICROPROFILE_FORCEENABLEGPUGROUP(s) MicroProfileForceEnableGroup(s, MicroProfileTokenTypeGpu)
#define MICROPROFILE_FORCEDISABLEGPUGROUP(s) MicroProfileForceDisableGroup(s, MicroProfileTokenTypeGpu)
#define MICROPROFILE_INVALID_TICK ((uint64_t)-1)
#define MICROPROFILE_GROUP_MASK_ALL 0xffffffffffff
#define MICROPROFILE_INVALID_TOKEN (uint64_t)-1
enum MicroProfileTokenType
{
MicroProfileTokenTypeCpu,
MicroProfileTokenTypeGpu,
};
enum MicroProfileBoxType
{
MicroProfileBoxTypeBar,
MicroProfileBoxTypeFlat,
};
struct MicroProfile;
MICROPROFILE_API void MicroProfileInit();
MICROPROFILE_API void MicroProfileShutdown();
MICROPROFILE_API MicroProfileToken MicroProfileFindToken(const char* sGroup, const char* sName);
MICROPROFILE_API MicroProfileToken MicroProfileGetToken(const char* sGroup, const char* sName, uint32_t nColor, MicroProfileTokenType Token = MicroProfileTokenTypeCpu);
MICROPROFILE_API MicroProfileToken MicroProfileGetMetaToken(const char* pName);
MICROPROFILE_API void MicroProfileMetaUpdate(MicroProfileToken, int nCount, MicroProfileTokenType eTokenType);
MICROPROFILE_API uint64_t MicroProfileEnter(MicroProfileToken nToken);
MICROPROFILE_API void MicroProfileLeave(MicroProfileToken nToken, uint64_t nTick);
MICROPROFILE_API uint64_t MicroProfileGpuEnter(MicroProfileToken nToken);
MICROPROFILE_API void MicroProfileGpuLeave(MicroProfileToken nToken, uint64_t nTick);
inline uint16_t MicroProfileGetTimerIndex(MicroProfileToken t){ return (t&0xffff); }
inline uint64_t MicroProfileGetGroupMask(MicroProfileToken t){ return ((t>>16)&MICROPROFILE_GROUP_MASK_ALL);}
inline MicroProfileToken MicroProfileMakeToken(uint64_t nGroupMask, uint16_t nTimer){ return (nGroupMask<<16) | nTimer;}
MICROPROFILE_API void MicroProfileFlip(); //! call once per frame.
MICROPROFILE_API void MicroProfileTogglePause();
MICROPROFILE_API void MicroProfileForceEnableGroup(const char* pGroup, MicroProfileTokenType Type);
MICROPROFILE_API void MicroProfileForceDisableGroup(const char* pGroup, MicroProfileTokenType Type);
MICROPROFILE_API float MicroProfileGetTime(const char* pGroup, const char* pName);
MICROPROFILE_API void MicroProfileContextSwitchSearch(uint32_t* pContextSwitchStart, uint32_t* pContextSwitchEnd, uint64_t nBaseTicksCpu, uint64_t nBaseTicksEndCpu);
MICROPROFILE_API void MicroProfileOnThreadCreate(const char* pThreadName); //should be called from newly created threads
MICROPROFILE_API void MicroProfileOnThreadExit(); //call on exit to reuse log
MICROPROFILE_API void MicroProfileInitThreadLog();
MICROPROFILE_API void MicroProfileSetForceEnable(bool bForceEnable);
MICROPROFILE_API bool MicroProfileGetForceEnable();
MICROPROFILE_API void MicroProfileSetEnableAllGroups(bool bEnable);
MICROPROFILE_API void MicroProfileEnableCategory(const char* pCategory);
MICROPROFILE_API void MicroProfileDisableCategory(const char* pCategory);
MICROPROFILE_API bool MicroProfileGetEnableAllGroups();
MICROPROFILE_API void MicroProfileSetForceMetaCounters(bool bEnable);
MICROPROFILE_API bool MicroProfileGetForceMetaCounters();
MICROPROFILE_API void MicroProfileEnableMetaCounter(const char* pMet);
MICROPROFILE_API void MicroProfileDisableMetaCounter(const char* pMet);
MICROPROFILE_API void MicroProfileSetAggregateFrames(int frames);
MICROPROFILE_API int MicroProfileGetAggregateFrames();
MICROPROFILE_API int MicroProfileGetCurrentAggregateFrames();
MICROPROFILE_API MicroProfile* MicroProfileGet();
MICROPROFILE_API void MicroProfileGetRange(uint32_t nPut, uint32_t nGet, uint32_t nRange[2][2]);
MICROPROFILE_API std::recursive_mutex& MicroProfileGetMutex();
MICROPROFILE_API void MicroProfileStartContextSwitchTrace();
MICROPROFILE_API void MicroProfileStopContextSwitchTrace();
MICROPROFILE_API bool MicroProfileIsLocalThread(uint32_t nThreadId);
#if MICROPROFILE_WEBSERVER
MICROPROFILE_API void MicroProfileDumpFile(const char* pHtml, const char* pCsv);
MICROPROFILE_API uint32_t MicroProfileWebServerPort();
#else
#define MicroProfileDumpFile(c) do{} while(0)
#define MicroProfileWebServerPort() ((uint32_t)-1)
#endif
#if MICROPROFILE_GPU_TIMERS
MICROPROFILE_API uint32_t MicroProfileGpuInsertTimeStamp();
MICROPROFILE_API uint64_t MicroProfileGpuGetTimeStamp(uint32_t nKey);
MICROPROFILE_API uint64_t MicroProfileTicksPerSecondGpu();
MICROPROFILE_API int MicroProfileGetGpuTickReference(int64_t* pOutCPU, int64_t* pOutGpu);
#else
#define MicroProfileGpuInsertTimeStamp() 1
#define MicroProfileGpuGetTimeStamp(a) 0
#define MicroProfileTicksPerSecondGpu() 1
#define MicroProfileGetGpuTickReference(a,b) 0
#endif
#if MICROPROFILE_GPU_TIMERS_D3D11
#define MICROPROFILE_D3D_MAX_QUERIES (8<<10)
MICROPROFILE_API void MicroProfileGpuInitD3D11(void* pDevice, void* pDeviceContext);
#endif
#if MICROPROFILE_GPU_TIMERS_GL
#define MICROPROFILE_GL_MAX_QUERIES (8<<10)
MICROPROFILE_API void MicroProfileGpuInitGL();
#endif
#if MICROPROFILE_USE_THREAD_NAME_CALLBACK
MICROPROFILE_API const char* MicroProfileGetThreadName();
#else
#define MicroProfileGetThreadName() "<implement MicroProfileGetThreadName to get threadnames>"
#endif
#if !defined(MICROPROFILE_THREAD_NAME_FROM_ID)
#define MICROPROFILE_THREAD_NAME_FROM_ID(a) ""
#endif
struct MicroProfileScopeHandler
{
MicroProfileToken nToken;
uint64_t nTick;
MicroProfileScopeHandler(MicroProfileToken Token):nToken(Token)
{
nTick = MicroProfileEnter(nToken);
}
~MicroProfileScopeHandler()
{
MicroProfileLeave(nToken, nTick);
}
};
struct MicroProfileScopeGpuHandler
{
MicroProfileToken nToken;
uint64_t nTick;
MicroProfileScopeGpuHandler(MicroProfileToken Token):nToken(Token)
{
nTick = MicroProfileGpuEnter(nToken);
}
~MicroProfileScopeGpuHandler()
{
MicroProfileGpuLeave(nToken, nTick);
}
};
#define MICROPROFILE_MAX_TIMERS 1024
#define MICROPROFILE_MAX_GROUPS 48 //dont bump! no. of bits used it bitmask
#define MICROPROFILE_MAX_CATEGORIES 16
#define MICROPROFILE_MAX_GRAPHS 5
#define MICROPROFILE_GRAPH_HISTORY 128
#define MICROPROFILE_BUFFER_SIZE ((MICROPROFILE_PER_THREAD_BUFFER_SIZE)/sizeof(MicroProfileLogEntry))
#define MICROPROFILE_MAX_CONTEXT_SWITCH_THREADS 256
#define MICROPROFILE_STACK_MAX 32
//#define MICROPROFILE_MAX_PRESETS 5
#define MICROPROFILE_ANIM_DELAY_PRC 0.5f
#define MICROPROFILE_GAP_TIME 50 //extra ms to fetch to close timers from earlier frames
#ifndef MICROPROFILE_MAX_THREADS
#define MICROPROFILE_MAX_THREADS 32
#endif
#ifndef MICROPROFILE_UNPACK_RED
#define MICROPROFILE_UNPACK_RED(c) ((c)>>16)
#endif
#ifndef MICROPROFILE_UNPACK_GREEN
#define MICROPROFILE_UNPACK_GREEN(c) ((c)>>8)
#endif
#ifndef MICROPROFILE_UNPACK_BLUE
#define MICROPROFILE_UNPACK_BLUE(c) ((c))
#endif
#ifndef MICROPROFILE_DEFAULT_PRESET
#define MICROPROFILE_DEFAULT_PRESET "Default"
#endif
#ifndef MICROPROFILE_CONTEXT_SWITCH_TRACE
#if defined(_WIN32)
#define MICROPROFILE_CONTEXT_SWITCH_TRACE 1
#elif defined(__APPLE__)
#define MICROPROFILE_CONTEXT_SWITCH_TRACE 0 //disabled until dtrace script is working.
#else
#define MICROPROFILE_CONTEXT_SWITCH_TRACE 0
#endif
#endif
#if MICROPROFILE_CONTEXT_SWITCH_TRACE
#define MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE (128*1024) //2mb with 16 byte entry size
#else
#define MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE (1)
#endif
#ifndef MICROPROFILE_MINIZ
#define MICROPROFILE_MINIZ 0
#endif
#ifdef _WIN32
#include <basetsd.h>
typedef UINT_PTR MpSocket;
#else
typedef int MpSocket;
#endif
#ifndef _WIN32
typedef pthread_t MicroProfileThread;
#elif defined(_MSC_VER)
typedef HANDLE MicroProfileThread;
#else
typedef std::thread* MicroProfileThread;
#endif
enum MicroProfileDrawMask
{
MP_DRAW_OFF = 0x0,
MP_DRAW_BARS = 0x1,
MP_DRAW_DETAILED = 0x2,
MP_DRAW_HIDDEN = 0x3,
};
enum MicroProfileDrawBarsMask
{
MP_DRAW_TIMERS = 0x1,
MP_DRAW_AVERAGE = 0x2,
MP_DRAW_MAX = 0x4,
MP_DRAW_CALL_COUNT = 0x8,
MP_DRAW_TIMERS_EXCLUSIVE = 0x10,
MP_DRAW_AVERAGE_EXCLUSIVE = 0x20,
MP_DRAW_MAX_EXCLUSIVE = 0x40,
MP_DRAW_META_FIRST = 0x80,
MP_DRAW_ALL = 0xffffffff,
};
typedef uint64_t MicroProfileLogEntry;
struct MicroProfileTimer
{
uint64_t nTicks;
uint32_t nCount;
};
struct MicroProfileCategory
{
char pName[MICROPROFILE_NAME_MAX_LEN];
uint64_t nGroupMask;
};
struct MicroProfileGroupInfo
{
char pName[MICROPROFILE_NAME_MAX_LEN];
uint32_t nNameLen;
uint32_t nGroupIndex;
uint32_t nNumTimers;
uint32_t nMaxTimerNameLen;
uint32_t nColor;
uint32_t nCategory;
MicroProfileTokenType Type;
};
struct MicroProfileTimerInfo
{
MicroProfileToken nToken;
uint32_t nTimerIndex;
uint32_t nGroupIndex;
char pName[MICROPROFILE_NAME_MAX_LEN];
uint32_t nNameLen;
uint32_t nColor;
bool bGraph;
};
struct MicroProfileGraphState
{
int64_t nHistory[MICROPROFILE_GRAPH_HISTORY];
MicroProfileToken nToken;
int32_t nKey;
};
struct MicroProfileContextSwitch
{
ThreadIdType nThreadOut;
ThreadIdType nThreadIn;
int64_t nCpu : 8;
int64_t nTicks : 56;
};
struct MicroProfileFrameState
{
int64_t nFrameStartCpu;
int64_t nFrameStartGpu;
uint32_t nLogStart[MICROPROFILE_MAX_THREADS];
};
struct MicroProfileThreadLog
{
std::array<MicroProfileLogEntry, MICROPROFILE_BUFFER_SIZE> Log{};
std::atomic<uint32_t> nPut{0};
std::atomic<uint32_t> nGet{0};
uint32_t nActive = 0;
uint32_t nGpu = 0;
ThreadIdType nThreadId{};
std::array<uint32_t, MICROPROFILE_STACK_MAX> nStack{};
std::array<int64_t, MICROPROFILE_STACK_MAX> nChildTickStack{};
uint32_t nStackPos = 0;
std::array<uint8_t, MICROPROFILE_MAX_GROUPS> nGroupStackPos{};
std::array<int64_t, MICROPROFILE_MAX_GROUPS> nGroupTicks{};
std::array<int64_t, MICROPROFILE_MAX_GROUPS> nAggregateGroupTicks{};
enum
{
THREAD_MAX_LEN = 64,
};
char ThreadName[64]{};
int nFreeListNext = 0;
void Reset() {
Log.fill({});
nPut = 0;
nGet = 0;
nActive = 0;
nGpu = 0;
nThreadId = {};
nStack.fill(0);
nChildTickStack.fill(0);
nStackPos = 0;
nGroupStackPos.fill(0);
nGroupTicks.fill(0);
nAggregateGroupTicks.fill(0);
std::fill(std::begin(ThreadName), std::end(ThreadName), '\0');
nFreeListNext = 0;
}
};
#if MICROPROFILE_GPU_TIMERS_D3D11
struct MicroProfileD3D11Frame
{
uint32_t m_nQueryStart;
uint32_t m_nQueryCount;
uint32_t m_nRateQueryStarted;
void* m_pRateQuery;
};
struct MicroProfileGpuTimerState
{
uint32_t bInitialized;
void* m_pDevice;
void* m_pDeviceContext;
void* m_pQueries[MICROPROFILE_D3D_MAX_QUERIES];
int64_t m_nQueryResults[MICROPROFILE_D3D_MAX_QUERIES];
uint32_t m_nQueryPut;
uint32_t m_nQueryGet;
uint32_t m_nQueryFrame;
int64_t m_nQueryFrequency;
MicroProfileD3D11Frame m_QueryFrames[MICROPROFILE_GPU_FRAME_DELAY];
};
#elif MICROPROFILE_GPU_TIMERS_GL
struct MicroProfileGpuTimerState
{
uint32_t GLTimers[MICROPROFILE_GL_MAX_QUERIES];
uint32_t GLTimerPos;
};
#else
struct MicroProfileGpuTimerState{};
#endif
struct MicroProfile
{
uint32_t nTotalTimers;
uint32_t nGroupCount;
uint32_t nCategoryCount;
uint32_t nAggregateClear;
uint32_t nAggregateFlip;
uint32_t nAggregateFlipCount;
uint32_t nAggregateFrames;
uint64_t nAggregateFlipTick;
uint32_t nDisplay;
uint32_t nBars;
uint64_t nActiveGroup;
uint32_t nActiveBars;
uint64_t nForceGroup;
uint32_t nForceEnable;
uint32_t nForceMetaCounters;
uint64_t nForceGroupUI;
uint64_t nActiveGroupWanted;
uint32_t nAllGroupsWanted;
uint32_t nAllThreadsWanted;
uint32_t nOverflow;
uint64_t nGroupMask;
uint32_t nRunning;
uint32_t nToggleRunning;
uint32_t nMaxGroupSize;
uint32_t nDumpFileNextFrame;
uint32_t nAutoClearFrames;
char HtmlDumpPath[512];
char CsvDumpPath[512];
int64_t nPauseTicks;
float fReferenceTime;
float fRcpReferenceTime;
MicroProfileCategory CategoryInfo[MICROPROFILE_MAX_CATEGORIES];
MicroProfileGroupInfo GroupInfo[MICROPROFILE_MAX_GROUPS];
MicroProfileTimerInfo TimerInfo[MICROPROFILE_MAX_TIMERS];
uint8_t TimerToGroup[MICROPROFILE_MAX_TIMERS];
MicroProfileTimer AccumTimers[MICROPROFILE_MAX_TIMERS];
uint64_t AccumMaxTimers[MICROPROFILE_MAX_TIMERS];
uint64_t AccumTimersExclusive[MICROPROFILE_MAX_TIMERS];
uint64_t AccumMaxTimersExclusive[MICROPROFILE_MAX_TIMERS];
MicroProfileTimer Frame[MICROPROFILE_MAX_TIMERS];
uint64_t FrameExclusive[MICROPROFILE_MAX_TIMERS];
MicroProfileTimer Aggregate[MICROPROFILE_MAX_TIMERS];
uint64_t AggregateMax[MICROPROFILE_MAX_TIMERS];
uint64_t AggregateExclusive[MICROPROFILE_MAX_TIMERS];
uint64_t AggregateMaxExclusive[MICROPROFILE_MAX_TIMERS];
uint64_t FrameGroup[MICROPROFILE_MAX_GROUPS];
uint64_t AccumGroup[MICROPROFILE_MAX_GROUPS];
uint64_t AccumGroupMax[MICROPROFILE_MAX_GROUPS];
uint64_t AggregateGroup[MICROPROFILE_MAX_GROUPS];
uint64_t AggregateGroupMax[MICROPROFILE_MAX_GROUPS];
struct
{
uint64_t nCounters[MICROPROFILE_MAX_TIMERS];
uint64_t nAccum[MICROPROFILE_MAX_TIMERS];
uint64_t nAccumMax[MICROPROFILE_MAX_TIMERS];
uint64_t nAggregate[MICROPROFILE_MAX_TIMERS];
uint64_t nAggregateMax[MICROPROFILE_MAX_TIMERS];
uint64_t nSum;
uint64_t nSumAccum;
uint64_t nSumAccumMax;
uint64_t nSumAggregate;
uint64_t nSumAggregateMax;
const char* pName;
} MetaCounters[MICROPROFILE_META_MAX];
MicroProfileGraphState Graph[MICROPROFILE_MAX_GRAPHS];
uint32_t nGraphPut;
uint32_t nThreadActive[MICROPROFILE_MAX_THREADS];
MicroProfileThreadLog* Pool[MICROPROFILE_MAX_THREADS];
uint32_t nNumLogs;
uint32_t nMemUsage;
int nFreeListHead;
uint32_t nFrameCurrent;
uint32_t nFrameCurrentIndex;
uint32_t nFramePut;
uint64_t nFramePutIndex;
MicroProfileFrameState Frames[MICROPROFILE_MAX_FRAME_HISTORY];
uint64_t nFlipTicks;
uint64_t nFlipAggregate;
uint64_t nFlipMax;
uint64_t nFlipAggregateDisplay;
uint64_t nFlipMaxDisplay;
MicroProfileThread ContextSwitchThread;
bool bContextSwitchRunning;
bool bContextSwitchStop;
bool bContextSwitchAllThreads;
bool bContextSwitchNoBars;
uint32_t nContextSwitchUsage;
uint32_t nContextSwitchLastPut;
int64_t nContextSwitchHoverTickIn;
int64_t nContextSwitchHoverTickOut;
uint32_t nContextSwitchHoverThread;
uint32_t nContextSwitchHoverThreadBefore;
uint32_t nContextSwitchHoverThreadAfter;
uint8_t nContextSwitchHoverCpu;
uint8_t nContextSwitchHoverCpuNext;
uint32_t nContextSwitchPut;
MicroProfileContextSwitch ContextSwitch[MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE];
MpSocket ListenerSocket;
uint32_t nWebServerPort;
char WebServerBuffer[MICROPROFILE_WEBSERVER_SOCKET_BUFFER_SIZE];
uint32_t WebServerPut;
uint64_t nWebServerDataSent;
MicroProfileGpuTimerState GPU;
};
#define MP_LOG_TICK_MASK 0x0000ffffffffffff
#define MP_LOG_INDEX_MASK 0x3fff000000000000
#define MP_LOG_BEGIN_MASK 0xc000000000000000
#define MP_LOG_GPU_EXTRA 0x3
#define MP_LOG_META 0x2
#define MP_LOG_ENTER 0x1
#define MP_LOG_LEAVE 0x0
inline int MicroProfileLogType(MicroProfileLogEntry Index)
{
return ((MP_LOG_BEGIN_MASK & Index)>>62) & 0x3;
}
inline uint64_t MicroProfileLogTimerIndex(MicroProfileLogEntry Index)
{
return (0x3fff&(Index>>48));
}
inline MicroProfileLogEntry MicroProfileMakeLogIndex(uint64_t nBegin, MicroProfileToken nToken, int64_t nTick)
{
MicroProfileLogEntry Entry = (nBegin<<62) | ((0x3fff&nToken)<<48) | (MP_LOG_TICK_MASK&nTick);
int t = MicroProfileLogType(Entry);
uint64_t nTimerIndex = MicroProfileLogTimerIndex(Entry);
MP_ASSERT(t == nBegin);
MP_ASSERT(nTimerIndex == (nToken&0x3fff));
return Entry;
}
inline int64_t MicroProfileLogTickDifference(MicroProfileLogEntry Start, MicroProfileLogEntry End)
{
uint64_t nStart = Start;
uint64_t nEnd = End;
int64_t nDifference = ((nEnd<<16) - (nStart<<16));
return nDifference >> 16;
}
inline int64_t MicroProfileLogGetTick(MicroProfileLogEntry e)
{
return MP_LOG_TICK_MASK & e;
}
inline int64_t MicroProfileLogSetTick(MicroProfileLogEntry e, int64_t nTick)
{
return (MP_LOG_TICK_MASK & nTick) | (e & ~MP_LOG_TICK_MASK);
}
template<typename T>
T MicroProfileMin(T a, T b)
{ return a < b ? a : b; }
template<typename T>
T MicroProfileMax(T a, T b)
{ return a > b ? a : b; }
inline int64_t MicroProfileMsToTick(float fMs, int64_t nTicksPerSecond)
{
return (int64_t)(fMs*0.001f*nTicksPerSecond);
}
inline float MicroProfileTickToMsMultiplier(int64_t nTicksPerSecond)
{
return 1000.f / nTicksPerSecond;
}
inline uint16_t MicroProfileGetGroupIndex(MicroProfileToken t)
{
return (uint16_t)MicroProfileGet()->TimerToGroup[MicroProfileGetTimerIndex(t)];
}
#ifdef MICROPROFILE_IMPL
#ifdef _WIN32
#include <windows.h>
#define snprintf _snprintf
#pragma warning(push)
#pragma warning(disable: 4244)
int64_t MicroProfileTicksPerSecondCpu()
{
static int64_t nTicksPerSecond = 0;
if(nTicksPerSecond == 0)
{
QueryPerformanceFrequency((LARGE_INTEGER*)&nTicksPerSecond);
}
return nTicksPerSecond;
}
int64_t MicroProfileGetTick()
{
int64_t ticks;
QueryPerformanceCounter((LARGE_INTEGER*)&ticks);
return ticks;
}
#endif
#if defined(MICROPROFILE_WEBSERVER) || defined(MICROPROFILE_CONTEXT_SWITCH_TRACE)
typedef void* (*MicroProfileThreadFunc)(void*);
#ifndef _WIN32
typedef pthread_t MicroProfileThread;
void MicroProfileThreadStart(MicroProfileThread* pThread, MicroProfileThreadFunc Func)
{
pthread_attr_t Attr;
int r = pthread_attr_init(&Attr);
MP_ASSERT(r == 0);
pthread_create(pThread, &Attr, Func, 0);
}
void MicroProfileThreadJoin(MicroProfileThread* pThread)
{
int r = pthread_join(*pThread, 0);
MP_ASSERT(r == 0);
}
#elif defined(_MSC_VER)
typedef HANDLE MicroProfileThread;
DWORD _stdcall ThreadTrampoline(void* pFunc)
{
MicroProfileThreadFunc F = (MicroProfileThreadFunc)pFunc;
// The return value of F will always return a void*, however, this is for
// compatibility with pthreads. The underlying "address" of the pointer
// is always a 32-bit value, so this cast is safe to perform.
return static_cast<DWORD>(reinterpret_cast<uint64_t>(F(0)));
}
void MicroProfileThreadStart(MicroProfileThread* pThread, MicroProfileThreadFunc Func)
{
*pThread = CreateThread(0, 0, ThreadTrampoline, Func, 0, 0);
}
void MicroProfileThreadJoin(MicroProfileThread* pThread)
{
WaitForSingleObject(*pThread, INFINITE);
CloseHandle(*pThread);
}
#else
#include <thread>
typedef std::thread* MicroProfileThread;
inline void MicroProfileThreadStart(MicroProfileThread* pThread, MicroProfileThreadFunc Func)
{
*pThread = new std::thread(Func, nullptr);
}
inline void MicroProfileThreadJoin(MicroProfileThread* pThread)
{
(*pThread)->join();
delete *pThread;
}
#endif
#endif
#if MICROPROFILE_WEBSERVER
#ifdef _WIN32
#define MP_INVALID_SOCKET(f) (f == INVALID_SOCKET)
#endif
#ifndef _WIN32
#include <sys/socket.h>
#include <netinet/in.h>
#include <fcntl.h>
#define MP_INVALID_SOCKET(f) (f < 0)
#endif
void MicroProfileWebServerStart();
void MicroProfileWebServerStop();
bool MicroProfileWebServerUpdate();
void MicroProfileDumpToFile();
#else
#define MicroProfileWebServerStart() do{}while(0)
#define MicroProfileWebServerStop() do{}while(0)
#define MicroProfileWebServerUpdate() false
#define MicroProfileDumpToFile() do{} while(0)
#endif
#if MICROPROFILE_GPU_TIMERS_D3D11
void MicroProfileGpuFlip();
void MicroProfileGpuShutdown();
#else
#define MicroProfileGpuFlip() do{}while(0)
#define MicroProfileGpuShutdown() do{}while(0)
#endif
#include <stdlib.h>
#include <stdio.h>
#include <math.h>
#include <algorithm>
#ifndef MICROPROFILE_DEBUG
#define MICROPROFILE_DEBUG 0
#endif
#define S g_MicroProfile
MicroProfile g_MicroProfile;
MicroProfileThreadLog* g_MicroProfileGpuLog = 0;
#ifdef MICROPROFILE_IOS
// iOS doesn't support __thread
static pthread_key_t g_MicroProfileThreadLogKey;
static pthread_once_t g_MicroProfileThreadLogKeyOnce = PTHREAD_ONCE_INIT;
static void MicroProfileCreateThreadLogKey()
{
pthread_key_create(&g_MicroProfileThreadLogKey, NULL);
}
#else
MP_THREAD_LOCAL MicroProfileThreadLog* g_MicroProfileThreadLog = 0;
#endif
static std::atomic<bool> g_bUseLock{false}; /// This is used because windows does not support using mutexes under dll init(which is where global initialization is handled)
MICROPROFILE_DEFINE(g_MicroProfileFlip, "MicroProfile", "MicroProfileFlip", 0x3355ee);
MICROPROFILE_DEFINE(g_MicroProfileThreadLoop, "MicroProfile", "ThreadLoop", 0x3355ee);
MICROPROFILE_DEFINE(g_MicroProfileClear, "MicroProfile", "Clear", 0x3355ee);
MICROPROFILE_DEFINE(g_MicroProfileAccumulate, "MicroProfile", "Accumulate", 0x3355ee);
MICROPROFILE_DEFINE(g_MicroProfileContextSwitchSearch,"MicroProfile", "ContextSwitchSearch", 0xDD7300);
inline std::recursive_mutex& MicroProfileMutex()
{
static std::recursive_mutex Mutex;
return Mutex;
}
std::recursive_mutex& MicroProfileGetMutex()
{
return MicroProfileMutex();
}
MICROPROFILE_API MicroProfile* MicroProfileGet()
{
return &g_MicroProfile;
}
MicroProfileThreadLog* MicroProfileCreateThreadLog(const char* pName);
void MicroProfileInit()
{
std::recursive_mutex& mutex = MicroProfileMutex();
bool bUseLock = g_bUseLock;
if(bUseLock)
mutex.lock();
static bool bOnce = true;
if(bOnce)
{
S.nMemUsage += sizeof(S);
bOnce = false;
memset(&S, 0, sizeof(S));
for(int i = 0; i < MICROPROFILE_MAX_GROUPS; ++i)
{
S.GroupInfo[i].pName[0] = '\0';
}
for(int i = 0; i < MICROPROFILE_MAX_CATEGORIES; ++i)
{
S.CategoryInfo[i].pName[0] = '\0';
S.CategoryInfo[i].nGroupMask = 0;
}
strcpy(&S.CategoryInfo[0].pName[0], "default");
S.nCategoryCount = 1;
for(int i = 0; i < MICROPROFILE_MAX_TIMERS; ++i)
{
S.TimerInfo[i].pName[0] = '\0';
}
S.nGroupCount = 0;
S.nAggregateFlipTick = MP_TICK();
S.nActiveGroup = 0;
S.nActiveBars = 0;
S.nForceGroup = 0;
S.nAllGroupsWanted = 0;
S.nActiveGroupWanted = 0;
S.nAllThreadsWanted = 1;
S.nAggregateFlip = 0;
S.nTotalTimers = 0;
for(uint32_t i = 0; i < MICROPROFILE_MAX_GRAPHS; ++i)
{
S.Graph[i].nToken = MICROPROFILE_INVALID_TOKEN;
}
S.nRunning = 1;
S.fReferenceTime = 33.33f;
S.fRcpReferenceTime = 1.f / S.fReferenceTime;
S.nFreeListHead = -1;
int64_t nTick = MP_TICK();
for(int i = 0; i < MICROPROFILE_MAX_FRAME_HISTORY; ++i)
{
S.Frames[i].nFrameStartCpu = nTick;
S.Frames[i].nFrameStartGpu = -1;
}
MicroProfileThreadLog* pGpu = MicroProfileCreateThreadLog("GPU");
g_MicroProfileGpuLog = pGpu;
MP_ASSERT(S.Pool[0] == pGpu);
pGpu->nGpu = 1;
pGpu->nThreadId = 0;
S.nWebServerDataSent = (uint64_t)-1;
}
if(bUseLock)
mutex.unlock();
}
void MicroProfileShutdown()
{
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
MicroProfileWebServerStop();
MicroProfileStopContextSwitchTrace();
MicroProfileGpuShutdown();
}
#ifdef MICROPROFILE_IOS
inline MicroProfileThreadLog* MicroProfileGetThreadLog()
{
pthread_once(&g_MicroProfileThreadLogKeyOnce, MicroProfileCreateThreadLogKey);
return (MicroProfileThreadLog*)pthread_getspecific(g_MicroProfileThreadLogKey);
}
inline void MicroProfileSetThreadLog(MicroProfileThreadLog* pLog)
{
pthread_once(&g_MicroProfileThreadLogKeyOnce, MicroProfileCreateThreadLogKey);
pthread_setspecific(g_MicroProfileThreadLogKey, pLog);
}
#else
MicroProfileThreadLog* MicroProfileGetThreadLog()
{
return g_MicroProfileThreadLog;
}
inline void MicroProfileSetThreadLog(MicroProfileThreadLog* pLog)
{
g_MicroProfileThreadLog = pLog;
}
#endif
MicroProfileThreadLog* MicroProfileCreateThreadLog(const char* pName)
{
MicroProfileThreadLog* pLog = 0;
if(S.nFreeListHead != -1)
{
pLog = S.Pool[S.nFreeListHead];
MP_ASSERT(pLog->nPut.load() == 0);
MP_ASSERT(pLog->nGet.load() == 0);
S.nFreeListHead = S.Pool[S.nFreeListHead]->nFreeListNext;
pLog->Reset();
}
else
{
pLog = new MicroProfileThreadLog;
S.nMemUsage += sizeof(MicroProfileThreadLog);
S.Pool[S.nNumLogs++] = pLog;
}
int len = (int)strlen(pName);
int maxlen = sizeof(pLog->ThreadName)-1;
len = len < maxlen ? len : maxlen;
memcpy(&pLog->ThreadName[0], pName, len);
pLog->ThreadName[len] = '\0';
pLog->nThreadId = MP_GETCURRENTTHREADID();
pLog->nFreeListNext = -1;
pLog->nActive = 1;
return pLog;
}
void MicroProfileOnThreadCreate(const char* pThreadName)
{
g_bUseLock = true;
MicroProfileInit();
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
MP_ASSERT(MicroProfileGetThreadLog() == 0);
MicroProfileThreadLog* pLog = MicroProfileCreateThreadLog(pThreadName ? pThreadName : MicroProfileGetThreadName());
MP_ASSERT(pLog);
MicroProfileSetThreadLog(pLog);
}
void MicroProfileOnThreadExit()
{
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
MicroProfileThreadLog* pLog = MicroProfileGetThreadLog();
if(pLog)
{
int32_t nLogIndex = -1;
for(int i = 0; i < MICROPROFILE_MAX_THREADS; ++i)
{
if(pLog == S.Pool[i])
{
nLogIndex = i;
break;
}
}
MP_ASSERT(nLogIndex < MICROPROFILE_MAX_THREADS && nLogIndex > 0);
pLog->nFreeListNext = S.nFreeListHead;
pLog->nActive = 0;
pLog->nPut.store(0);
pLog->nGet.store(0);
S.nFreeListHead = nLogIndex;
for(int i = 0; i < MICROPROFILE_MAX_FRAME_HISTORY; ++i)
{
S.Frames[i].nLogStart[nLogIndex] = 0;
}
pLog->nGroupStackPos.fill(0);
pLog->nGroupTicks.fill(0);
}
}
void MicroProfileInitThreadLog()
{
MicroProfileOnThreadCreate(nullptr);
}
struct MicroProfileScopeLock
{
bool bUseLock;
std::recursive_mutex& m;
MicroProfileScopeLock(std::recursive_mutex& m) : bUseLock(g_bUseLock), m(m)
{
if(bUseLock)
m.lock();
}
~MicroProfileScopeLock()
{
if(bUseLock)
m.unlock();
}
};
MicroProfileToken MicroProfileFindToken(const char* pGroup, const char* pName)
{
MicroProfileInit();
MicroProfileScopeLock L(MicroProfileMutex());
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
if(!MP_STRCASECMP(pName, S.TimerInfo[i].pName) && !MP_STRCASECMP(pGroup, S.GroupInfo[S.TimerToGroup[i]].pName))
{
return S.TimerInfo[i].nToken;
}
}
return MICROPROFILE_INVALID_TOKEN;
}
uint16_t MicroProfileGetGroup(const char* pGroup, MicroProfileTokenType Type)
{
for(uint32_t i = 0; i < S.nGroupCount; ++i)
{
if(!MP_STRCASECMP(pGroup, S.GroupInfo[i].pName))
{
return i;
}
}
uint16_t nGroupIndex = 0xffff;
uint32_t nLen = (uint32_t)strlen(pGroup);
if(nLen > MICROPROFILE_NAME_MAX_LEN-1)
nLen = MICROPROFILE_NAME_MAX_LEN-1;
memcpy(&S.GroupInfo[S.nGroupCount].pName[0], pGroup, nLen);
S.GroupInfo[S.nGroupCount].pName[nLen] = '\0';
S.GroupInfo[S.nGroupCount].nNameLen = nLen;
S.GroupInfo[S.nGroupCount].nNumTimers = 0;
S.GroupInfo[S.nGroupCount].nGroupIndex = S.nGroupCount;
S.GroupInfo[S.nGroupCount].Type = Type;
S.GroupInfo[S.nGroupCount].nMaxTimerNameLen = 0;
S.GroupInfo[S.nGroupCount].nColor = 0x88888888;
S.GroupInfo[S.nGroupCount].nCategory = 0;
S.CategoryInfo[0].nGroupMask |= (1ll << (uint64_t)S.nGroupCount);
nGroupIndex = S.nGroupCount++;
S.nGroupMask = (S.nGroupMask<<1)|1;
MP_ASSERT(nGroupIndex < MICROPROFILE_MAX_GROUPS);
return nGroupIndex;
}
void MicroProfileRegisterGroup(const char* pGroup, const char* pCategory, uint32_t nColor)
{
int nCategoryIndex = -1;
for(uint32_t i = 0; i < S.nCategoryCount; ++i)
{
if(!MP_STRCASECMP(pCategory, S.CategoryInfo[i].pName))
{
nCategoryIndex = (int)i;
break;
}
}
if(-1 == nCategoryIndex && S.nCategoryCount < MICROPROFILE_MAX_CATEGORIES)
{
MP_ASSERT(S.CategoryInfo[S.nCategoryCount].pName[0] == '\0');
nCategoryIndex = (int)S.nCategoryCount++;
uint32_t nLen = (uint32_t)strlen(pCategory);
if(nLen > MICROPROFILE_NAME_MAX_LEN-1)
nLen = MICROPROFILE_NAME_MAX_LEN-1;
memcpy(&S.CategoryInfo[nCategoryIndex].pName[0], pCategory, nLen);
S.CategoryInfo[nCategoryIndex].pName[nLen] = '\0';
}
uint16_t nGroup = MicroProfileGetGroup(pGroup, 0 != MP_STRCASECMP(pGroup, "gpu")?MicroProfileTokenTypeCpu : MicroProfileTokenTypeGpu);
S.GroupInfo[nGroup].nColor = nColor;
if(nCategoryIndex >= 0)
{
uint64_t nBit = 1ll << nGroup;
uint32_t nOldCategory = S.GroupInfo[nGroup].nCategory;
S.CategoryInfo[nOldCategory].nGroupMask &= ~nBit;
S.CategoryInfo[nCategoryIndex].nGroupMask |= nBit;
S.GroupInfo[nGroup].nCategory = nCategoryIndex;
}
}
MicroProfileToken MicroProfileGetToken(const char* pGroup, const char* pName, uint32_t nColor, MicroProfileTokenType Type)
{
MicroProfileInit();
MicroProfileScopeLock L(MicroProfileMutex());
MicroProfileToken ret = MicroProfileFindToken(pGroup, pName);
if(ret != MICROPROFILE_INVALID_TOKEN)
return ret;
uint16_t nGroupIndex = MicroProfileGetGroup(pGroup, Type);
uint16_t nTimerIndex = (uint16_t)(S.nTotalTimers++);
uint64_t nGroupMask = 1ll << nGroupIndex;
MicroProfileToken nToken = MicroProfileMakeToken(nGroupMask, nTimerIndex);
S.GroupInfo[nGroupIndex].nNumTimers++;
S.GroupInfo[nGroupIndex].nMaxTimerNameLen = MicroProfileMax(S.GroupInfo[nGroupIndex].nMaxTimerNameLen, (uint32_t)strlen(pName));
MP_ASSERT(S.GroupInfo[nGroupIndex].Type == Type); //dont mix cpu & gpu timers in the same group
S.nMaxGroupSize = MicroProfileMax(S.nMaxGroupSize, S.GroupInfo[nGroupIndex].nNumTimers);
S.TimerInfo[nTimerIndex].nToken = nToken;
uint32_t nLen = (uint32_t)strlen(pName);
if(nLen > MICROPROFILE_NAME_MAX_LEN-1)
nLen = MICROPROFILE_NAME_MAX_LEN-1;
memcpy(&S.TimerInfo[nTimerIndex].pName, pName, nLen);
S.TimerInfo[nTimerIndex].pName[nLen] = '\0';
S.TimerInfo[nTimerIndex].nNameLen = nLen;
S.TimerInfo[nTimerIndex].nColor = nColor&0xffffff;
S.TimerInfo[nTimerIndex].nGroupIndex = nGroupIndex;
S.TimerInfo[nTimerIndex].nTimerIndex = nTimerIndex;
S.TimerToGroup[nTimerIndex] = nGroupIndex;
return nToken;
}
MicroProfileToken MicroProfileGetMetaToken(const char* pName)
{
MicroProfileInit();
MicroProfileScopeLock L(MicroProfileMutex());
for(uint32_t i = 0; i < MICROPROFILE_META_MAX; ++i)
{
if(!S.MetaCounters[i].pName)
{
S.MetaCounters[i].pName = pName;
return i;
}
else if(!MP_STRCASECMP(pName, S.MetaCounters[i].pName))
{
return i;
}
}
MP_ASSERT(0);//out of slots, increase MICROPROFILE_META_MAX
return (MicroProfileToken)-1;
}
inline void MicroProfileLogPut(MicroProfileToken nToken_, uint64_t nTick, uint64_t nBegin, MicroProfileThreadLog* pLog)
{
MP_ASSERT(pLog != 0); //this assert is hit if MicroProfileOnCreateThread is not called
MP_ASSERT(pLog->nActive);
uint32_t nPos = pLog->nPut.load(std::memory_order_relaxed);
uint32_t nNextPos = (nPos+1) % MICROPROFILE_BUFFER_SIZE;
if(nNextPos == pLog->nGet.load(std::memory_order_relaxed))
{
S.nOverflow = 100;
}
else
{
pLog->Log[nPos] = MicroProfileMakeLogIndex(nBegin, nToken_, nTick);
pLog->nPut.store(nNextPos, std::memory_order_release);
}
}
uint64_t MicroProfileEnter(MicroProfileToken nToken_)
{
if(MicroProfileGetGroupMask(nToken_) & S.nActiveGroup)
{
if(!MicroProfileGetThreadLog())
{
MicroProfileInitThreadLog();
}
uint64_t nTick = MP_TICK();
MicroProfileLogPut(nToken_, nTick, MP_LOG_ENTER, MicroProfileGetThreadLog());
return nTick;
}
return MICROPROFILE_INVALID_TICK;
}
void MicroProfileMetaUpdate(MicroProfileToken nToken, int nCount, MicroProfileTokenType eTokenType)
{
if((MP_DRAW_META_FIRST<<nToken) & S.nActiveBars)
{
MicroProfileThreadLog* pLog = MicroProfileTokenTypeCpu == eTokenType ? MicroProfileGetThreadLog() : g_MicroProfileGpuLog;
if(pLog)
{
MP_ASSERT(nToken < MICROPROFILE_META_MAX);
MicroProfileLogPut(nToken, nCount, MP_LOG_META, pLog);
}
}
}
void MicroProfileLeave(MicroProfileToken nToken_, uint64_t nTickStart)
{
if(MICROPROFILE_INVALID_TICK != nTickStart)
{
if(!MicroProfileGetThreadLog())
{
MicroProfileInitThreadLog();
}
uint64_t nTick = MP_TICK();
MicroProfileThreadLog* pLog = MicroProfileGetThreadLog();
MicroProfileLogPut(nToken_, nTick, MP_LOG_LEAVE, pLog);
}
}
uint64_t MicroProfileGpuEnter(MicroProfileToken nToken_)
{
if(MicroProfileGetGroupMask(nToken_) & S.nActiveGroup)
{
uint64_t nTimer = MicroProfileGpuInsertTimeStamp();
MicroProfileLogPut(nToken_, nTimer, MP_LOG_ENTER, g_MicroProfileGpuLog);
MicroProfileLogPut(nToken_, MP_TICK(), MP_LOG_GPU_EXTRA, g_MicroProfileGpuLog);
return 1;
}
return 0;
}
void MicroProfileGpuLeave(MicroProfileToken nToken_, uint64_t nTickStart)
{
if(nTickStart)
{
uint64_t nTimer = MicroProfileGpuInsertTimeStamp();
MicroProfileLogPut(nToken_, nTimer, MP_LOG_LEAVE, g_MicroProfileGpuLog);
MicroProfileLogPut(nToken_, MP_TICK(), MP_LOG_GPU_EXTRA, g_MicroProfileGpuLog);
}
}
void MicroProfileContextSwitchPut(MicroProfileContextSwitch* pContextSwitch)
{
if(S.nRunning || pContextSwitch->nTicks <= S.nPauseTicks)
{
uint32_t nPut = S.nContextSwitchPut;
S.ContextSwitch[nPut] = *pContextSwitch;
S.nContextSwitchPut = (S.nContextSwitchPut+1) % MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE;
}
}
void MicroProfileGetRange(uint32_t nPut, uint32_t nGet, uint32_t nRange[2][2])
{
if(nPut > nGet)
{
nRange[0][0] = nGet;
nRange[0][1] = nPut;
nRange[1][0] = nRange[1][1] = 0;
}
else if(nPut != nGet)
{
MP_ASSERT(nGet != MICROPROFILE_BUFFER_SIZE);
uint32_t nCountEnd = MICROPROFILE_BUFFER_SIZE - nGet;
nRange[0][0] = nGet;
nRange[0][1] = nGet + nCountEnd;
nRange[1][0] = 0;
nRange[1][1] = nPut;
}
}
void MicroProfileFlip()
{
#if 0
//verify LogEntry wraps correctly
MicroProfileLogEntry c = MP_LOG_TICK_MASK-5000;
for(int i = 0; i < 10000; ++i, c += 1)
{
MicroProfileLogEntry l2 = (c+2500) & MP_LOG_TICK_MASK;
MP_ASSERT(2500 == MicroProfileLogTickDifference(c, l2));
}
#endif
MICROPROFILE_SCOPE(g_MicroProfileFlip);
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
MicroProfileGpuFlip();
if(S.nToggleRunning)
{
S.nRunning = !S.nRunning;
if(!S.nRunning)
S.nPauseTicks = MP_TICK();
S.nToggleRunning = 0;
for(uint32_t i = 0; i < MICROPROFILE_MAX_THREADS; ++i)
{
MicroProfileThreadLog* pLog = S.Pool[i];
if(pLog)
{
pLog->nStackPos = 0;
}
}
}
uint32_t nAggregateClear = S.nAggregateClear || S.nAutoClearFrames, nAggregateFlip = 0;
if(S.nDumpFileNextFrame)
{
MicroProfileDumpToFile();
S.nDumpFileNextFrame = 0;
S.nAutoClearFrames = MICROPROFILE_GPU_FRAME_DELAY + 3; //hide spike from dumping webpage
}
if(S.nWebServerDataSent == (uint64_t)-1)
{
MicroProfileWebServerStart();
S.nWebServerDataSent = 0;
}
if(MicroProfileWebServerUpdate())
{
S.nAutoClearFrames = MICROPROFILE_GPU_FRAME_DELAY + 3; //hide spike from dumping webpage
}
if(S.nAutoClearFrames)
{
nAggregateClear = 1;
nAggregateFlip = 1;
S.nAutoClearFrames -= 1;
}
if(S.nRunning || S.nForceEnable)
{
S.nFramePutIndex++;
S.nFramePut = (S.nFramePut+1) % MICROPROFILE_MAX_FRAME_HISTORY;
MP_ASSERT((S.nFramePutIndex % MICROPROFILE_MAX_FRAME_HISTORY) == S.nFramePut);
S.nFrameCurrent = (S.nFramePut + MICROPROFILE_MAX_FRAME_HISTORY - MICROPROFILE_GPU_FRAME_DELAY - 1) % MICROPROFILE_MAX_FRAME_HISTORY;
S.nFrameCurrentIndex++;
uint32_t nFrameNext = (S.nFrameCurrent+1) % MICROPROFILE_MAX_FRAME_HISTORY;
uint32_t nContextSwitchPut = S.nContextSwitchPut;
if(S.nContextSwitchLastPut < nContextSwitchPut)
{
S.nContextSwitchUsage = (nContextSwitchPut - S.nContextSwitchLastPut);
}
else
{
S.nContextSwitchUsage = MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE - S.nContextSwitchLastPut + nContextSwitchPut;
}
S.nContextSwitchLastPut = nContextSwitchPut;
MicroProfileFrameState* pFramePut = &S.Frames[S.nFramePut];
MicroProfileFrameState* pFrameCurrent = &S.Frames[S.nFrameCurrent];
MicroProfileFrameState* pFrameNext = &S.Frames[nFrameNext];
pFramePut->nFrameStartCpu = MP_TICK();
pFramePut->nFrameStartGpu = (uint32_t)MicroProfileGpuInsertTimeStamp();
if(pFrameNext->nFrameStartGpu != (uint64_t)-1)
pFrameNext->nFrameStartGpu = MicroProfileGpuGetTimeStamp((uint32_t)pFrameNext->nFrameStartGpu);
if(pFrameCurrent->nFrameStartGpu == (uint64_t)-1)
pFrameCurrent->nFrameStartGpu = pFrameNext->nFrameStartGpu + 1;
uint64_t nFrameStartCpu = pFrameCurrent->nFrameStartCpu;
uint64_t nFrameEndCpu = pFrameNext->nFrameStartCpu;
{
uint64_t nTick = nFrameEndCpu - nFrameStartCpu;
S.nFlipTicks = nTick;
S.nFlipAggregate += nTick;
S.nFlipMax = MicroProfileMax(S.nFlipMax, nTick);
}
uint8_t* pTimerToGroup = &S.TimerToGroup[0];
for(uint32_t i = 0; i < MICROPROFILE_MAX_THREADS; ++i)
{
MicroProfileThreadLog* pLog = S.Pool[i];
if(!pLog)
{
pFramePut->nLogStart[i] = 0;
}
else
{
uint32_t nPut = pLog->nPut.load(std::memory_order_acquire);
pFramePut->nLogStart[i] = nPut;
MP_ASSERT(nPut< MICROPROFILE_BUFFER_SIZE);
//need to keep last frame around to close timers. timers more than 1 frame old is ditched.
pLog->nGet.store(nPut, std::memory_order_relaxed);
}
}
if(S.nRunning)
{
uint64_t* pFrameGroup = &S.FrameGroup[0];
{
MICROPROFILE_SCOPE(g_MicroProfileClear);
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
S.Frame[i].nTicks = 0;
S.Frame[i].nCount = 0;
S.FrameExclusive[i] = 0;
}
for(uint32_t i = 0; i < MICROPROFILE_MAX_GROUPS; ++i)
{
pFrameGroup[i] = 0;
}
for(uint32_t j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName && 0 != (S.nActiveBars & (MP_DRAW_META_FIRST<<j)))
{
auto& Meta = S.MetaCounters[j];
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
Meta.nCounters[i] = 0;
}
}
}
}
{
MICROPROFILE_SCOPE(g_MicroProfileThreadLoop);
for(uint32_t i = 0; i < MICROPROFILE_MAX_THREADS; ++i)
{
MicroProfileThreadLog* pLog = S.Pool[i];
if(!pLog)
continue;
uint8_t* pGroupStackPos = &pLog->nGroupStackPos[0];
int64_t nGroupTicks[MICROPROFILE_MAX_GROUPS] = {0};
uint32_t nPut = pFrameNext->nLogStart[i];
uint32_t nGet = pFrameCurrent->nLogStart[i];
uint32_t nRange[2][2] = { {0, 0}, {0, 0}, };
MicroProfileGetRange(nPut, nGet, nRange);
//fetch gpu results.
if(pLog->nGpu)
{
for(uint32_t j = 0; j < 2; ++j)
{
uint32_t nStart = nRange[j][0];
uint32_t nEnd = nRange[j][1];
for(uint32_t k = nStart; k < nEnd; ++k)
{
MicroProfileLogEntry L = pLog->Log[k];
if(MicroProfileLogType(L) < MP_LOG_META)
{
pLog->Log[k] = MicroProfileLogSetTick(L, MicroProfileGpuGetTimeStamp((uint32_t)MicroProfileLogGetTick(L)));
}
}
}
}
uint32_t* pStack = &pLog->nStack[0];
int64_t* pChildTickStack = &pLog->nChildTickStack[0];
uint32_t nStackPos = pLog->nStackPos;
for(uint32_t j = 0; j < 2; ++j)
{
uint32_t nStart = nRange[j][0];
uint32_t nEnd = nRange[j][1];
for(uint32_t k = nStart; k < nEnd; ++k)
{
MicroProfileLogEntry LE = pLog->Log[k];
int nType = MicroProfileLogType(LE);
if(MP_LOG_ENTER == nType)
{
int nTimer = MicroProfileLogTimerIndex(LE);
uint8_t nGroup = pTimerToGroup[nTimer];
MP_ASSERT(nStackPos < MICROPROFILE_STACK_MAX);
MP_ASSERT(nGroup < MICROPROFILE_MAX_GROUPS);
pGroupStackPos[nGroup]++;
pStack[nStackPos++] = k;
pChildTickStack[nStackPos] = 0;
}
else if(MP_LOG_META == nType)
{
if(nStackPos)
{
int64_t nMetaIndex = MicroProfileLogTimerIndex(LE);
int64_t nMetaCount = MicroProfileLogGetTick(LE);
MP_ASSERT(nMetaIndex < MICROPROFILE_META_MAX);
int64_t nCounter = MicroProfileLogTimerIndex(pLog->Log[pStack[nStackPos-1]]);
S.MetaCounters[nMetaIndex].nCounters[nCounter] += nMetaCount;
}
}
else if(MP_LOG_LEAVE == nType)
{
int nTimer = MicroProfileLogTimerIndex(LE);
uint8_t nGroup = pTimerToGroup[nTimer];
MP_ASSERT(nGroup < MICROPROFILE_MAX_GROUPS);
if(nStackPos)
{
int64_t nTickStart = pLog->Log[pStack[nStackPos-1]];
int64_t nTicks = MicroProfileLogTickDifference(nTickStart, LE);
int64_t nChildTicks = pChildTickStack[nStackPos];
nStackPos--;
pChildTickStack[nStackPos] += nTicks;
uint32_t nTimerIndex = MicroProfileLogTimerIndex(LE);
S.Frame[nTimerIndex].nTicks += nTicks;
S.FrameExclusive[nTimerIndex] += (nTicks-nChildTicks);
S.Frame[nTimerIndex].nCount += 1;
MP_ASSERT(nGroup < MICROPROFILE_MAX_GROUPS);
uint8_t nGroupStackPos = pGroupStackPos[nGroup];
if(nGroupStackPos)
{
nGroupStackPos--;
if(0 == nGroupStackPos)
{
nGroupTicks[nGroup] += nTicks;
}
pGroupStackPos[nGroup] = nGroupStackPos;
}
}
}
}
}
for(uint32_t i = 0; i < MICROPROFILE_MAX_GROUPS; ++i)
{
pLog->nGroupTicks[i] += nGroupTicks[i];
pFrameGroup[i] += nGroupTicks[i];
}
pLog->nStackPos = nStackPos;
}
}
{
MICROPROFILE_SCOPE(g_MicroProfileAccumulate);
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
S.AccumTimers[i].nTicks += S.Frame[i].nTicks;
S.AccumTimers[i].nCount += S.Frame[i].nCount;
S.AccumMaxTimers[i] = MicroProfileMax(S.AccumMaxTimers[i], S.Frame[i].nTicks);
S.AccumTimersExclusive[i] += S.FrameExclusive[i];
S.AccumMaxTimersExclusive[i] = MicroProfileMax(S.AccumMaxTimersExclusive[i], S.FrameExclusive[i]);
}
for(uint32_t i = 0; i < MICROPROFILE_MAX_GROUPS; ++i)
{
S.AccumGroup[i] += pFrameGroup[i];
S.AccumGroupMax[i] = MicroProfileMax(S.AccumGroupMax[i], pFrameGroup[i]);
}
for(uint32_t j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName && 0 != (S.nActiveBars & (MP_DRAW_META_FIRST<<j)))
{
auto& Meta = S.MetaCounters[j];
uint64_t nSum = 0;;
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
uint64_t nCounter = Meta.nCounters[i];
Meta.nAccumMax[i] = MicroProfileMax(Meta.nAccumMax[i], nCounter);
Meta.nAccum[i] += nCounter;
nSum += nCounter;
}
Meta.nSumAccum += nSum;
Meta.nSumAccumMax = MicroProfileMax(Meta.nSumAccumMax, nSum);
}
}
}
for(uint32_t i = 0; i < MICROPROFILE_MAX_GRAPHS; ++i)
{
if(S.Graph[i].nToken != MICROPROFILE_INVALID_TOKEN)
{
MicroProfileToken nToken = S.Graph[i].nToken;
S.Graph[i].nHistory[S.nGraphPut] = S.Frame[MicroProfileGetTimerIndex(nToken)].nTicks;
}
}
S.nGraphPut = (S.nGraphPut+1) % MICROPROFILE_GRAPH_HISTORY;
}
if(S.nRunning && S.nAggregateFlip <= ++S.nAggregateFlipCount)
{
nAggregateFlip = 1;
if(S.nAggregateFlip) // if 0 accumulate indefinitely
{
nAggregateClear = 1;
}
}
}
if(nAggregateFlip)
{
memcpy(&S.Aggregate[0], &S.AccumTimers[0], sizeof(S.Aggregate[0]) * S.nTotalTimers);
memcpy(&S.AggregateMax[0], &S.AccumMaxTimers[0], sizeof(S.AggregateMax[0]) * S.nTotalTimers);
memcpy(&S.AggregateExclusive[0], &S.AccumTimersExclusive[0], sizeof(S.AggregateExclusive[0]) * S.nTotalTimers);
memcpy(&S.AggregateMaxExclusive[0], &S.AccumMaxTimersExclusive[0], sizeof(S.AggregateMaxExclusive[0]) * S.nTotalTimers);
memcpy(&S.AggregateGroup[0], &S.AccumGroup[0], sizeof(S.AggregateGroup));
memcpy(&S.AggregateGroupMax[0], &S.AccumGroupMax[0], sizeof(S.AggregateGroup));
for(uint32_t i = 0; i < MICROPROFILE_MAX_THREADS; ++i)
{
MicroProfileThreadLog* pLog = S.Pool[i];
if(!pLog)
continue;
memcpy(&pLog->nAggregateGroupTicks[0], &pLog->nGroupTicks[0], sizeof(pLog->nAggregateGroupTicks));
if(nAggregateClear)
{
memset(&pLog->nGroupTicks[0], 0, sizeof(pLog->nGroupTicks));
}
}
for(uint32_t j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName && 0 != (S.nActiveBars & (MP_DRAW_META_FIRST<<j)))
{
auto& Meta = S.MetaCounters[j];
memcpy(&Meta.nAggregateMax[0], &Meta.nAccumMax[0], sizeof(Meta.nAggregateMax[0]) * S.nTotalTimers);
memcpy(&Meta.nAggregate[0], &Meta.nAccum[0], sizeof(Meta.nAggregate[0]) * S.nTotalTimers);
Meta.nSumAggregate = Meta.nSumAccum;
Meta.nSumAggregateMax = Meta.nSumAccumMax;
if(nAggregateClear)
{
memset(&Meta.nAccumMax[0], 0, sizeof(Meta.nAccumMax[0]) * S.nTotalTimers);
memset(&Meta.nAccum[0], 0, sizeof(Meta.nAccum[0]) * S.nTotalTimers);
Meta.nSumAccum = 0;
Meta.nSumAccumMax = 0;
}
}
}
S.nAggregateFrames = S.nAggregateFlipCount;
S.nFlipAggregateDisplay = S.nFlipAggregate;
S.nFlipMaxDisplay = S.nFlipMax;
if(nAggregateClear)
{
memset(&S.AccumTimers[0], 0, sizeof(S.Aggregate[0]) * S.nTotalTimers);
memset(&S.AccumMaxTimers[0], 0, sizeof(S.AccumMaxTimers[0]) * S.nTotalTimers);
memset(&S.AccumTimersExclusive[0], 0, sizeof(S.AggregateExclusive[0]) * S.nTotalTimers);
memset(&S.AccumMaxTimersExclusive[0], 0, sizeof(S.AccumMaxTimersExclusive[0]) * S.nTotalTimers);
memset(&S.AccumGroup[0], 0, sizeof(S.AggregateGroup));
memset(&S.AccumGroupMax[0], 0, sizeof(S.AggregateGroup));
S.nAggregateFlipCount = 0;
S.nFlipAggregate = 0;
S.nFlipMax = 0;
S.nAggregateFlipTick = MP_TICK();
}
}
S.nAggregateClear = 0;
uint64_t nNewActiveGroup = 0;
if(S.nForceEnable || (S.nDisplay && S.nRunning))
nNewActiveGroup = S.nAllGroupsWanted ? S.nGroupMask : S.nActiveGroupWanted;
nNewActiveGroup |= S.nForceGroup;
nNewActiveGroup |= S.nForceGroupUI;
if(S.nActiveGroup != nNewActiveGroup)
S.nActiveGroup = nNewActiveGroup;
uint32_t nNewActiveBars = 0;
if(S.nDisplay && S.nRunning)
nNewActiveBars = S.nBars;
if(S.nForceMetaCounters)
{
for(int i = 0; i < MICROPROFILE_META_MAX; ++i)
{
if(S.MetaCounters[i].pName)
{
nNewActiveBars |= (MP_DRAW_META_FIRST<<i);
}
}
}
if(nNewActiveBars != S.nActiveBars)
S.nActiveBars = nNewActiveBars;
}
void MicroProfileSetForceEnable(bool bEnable)
{
S.nForceEnable = bEnable ? 1 : 0;
}
bool MicroProfileGetForceEnable()
{
return S.nForceEnable != 0;
}
void MicroProfileSetEnableAllGroups(bool bEnableAllGroups)
{
S.nAllGroupsWanted = bEnableAllGroups ? 1 : 0;
}
void MicroProfileEnableCategory(const char* pCategory, bool bEnabled)
{
int nCategoryIndex = -1;
for(uint32_t i = 0; i < S.nCategoryCount; ++i)
{
if(!MP_STRCASECMP(pCategory, S.CategoryInfo[i].pName))
{
nCategoryIndex = (int)i;
break;
}
}
if(nCategoryIndex >= 0)
{
if(bEnabled)
{
S.nActiveGroupWanted |= S.CategoryInfo[nCategoryIndex].nGroupMask;
}
else
{
S.nActiveGroupWanted &= ~S.CategoryInfo[nCategoryIndex].nGroupMask;
}
}
}
void MicroProfileEnableCategory(const char* pCategory)
{
MicroProfileEnableCategory(pCategory, true);
}
void MicroProfileDisableCategory(const char* pCategory)
{
MicroProfileEnableCategory(pCategory, false);
}
bool MicroProfileGetEnableAllGroups()
{
return 0 != S.nAllGroupsWanted;
}
void MicroProfileSetForceMetaCounters(bool bForce)
{
S.nForceMetaCounters = bForce ? 1 : 0;
}
bool MicroProfileGetForceMetaCounters()
{
return 0 != S.nForceMetaCounters;
}
void MicroProfileEnableMetaCounter(const char* pMeta)
{
for(uint32_t i = 0; i < MICROPROFILE_META_MAX; ++i)
{
if(S.MetaCounters[i].pName && 0 == MP_STRCASECMP(S.MetaCounters[i].pName, pMeta))
{
S.nBars |= (MP_DRAW_META_FIRST<<i);
return;
}
}
}
void MicroProfileDisableMetaCounter(const char* pMeta)
{
for(uint32_t i = 0; i < MICROPROFILE_META_MAX; ++i)
{
if(S.MetaCounters[i].pName && 0 == MP_STRCASECMP(S.MetaCounters[i].pName, pMeta))
{
S.nBars &= ~(MP_DRAW_META_FIRST<<i);
return;
}
}
}
void MicroProfileSetAggregateFrames(int nFrames)
{
S.nAggregateFlip = (uint32_t)nFrames;
if(0 == nFrames)
{
S.nAggregateClear = 1;
}
}
int MicroProfileGetAggregateFrames()
{
return S.nAggregateFlip;
}
int MicroProfileGetCurrentAggregateFrames()
{
return int(S.nAggregateFlip ? S.nAggregateFlip : S.nAggregateFlipCount);
}
void MicroProfileForceEnableGroup(const char* pGroup, MicroProfileTokenType Type)
{
MicroProfileInit();
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
uint16_t nGroup = MicroProfileGetGroup(pGroup, Type);
S.nForceGroup |= (1ll << nGroup);
}
void MicroProfileForceDisableGroup(const char* pGroup, MicroProfileTokenType Type)
{
MicroProfileInit();
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
uint16_t nGroup = MicroProfileGetGroup(pGroup, Type);
S.nForceGroup &= ~(1ll << nGroup);
}
void MicroProfileCalcAllTimers(float* pTimers, float* pAverage, float* pMax, float* pCallAverage, float* pExclusive, float* pAverageExclusive, float* pMaxExclusive, float* pTotal, uint32_t nSize)
{
for(uint32_t i = 0; i < S.nTotalTimers && i < nSize; ++i)
{
const uint32_t nGroupId = S.TimerInfo[i].nGroupIndex;
const float fToMs = MicroProfileTickToMsMultiplier(S.GroupInfo[nGroupId].Type == MicroProfileTokenTypeGpu ? MicroProfileTicksPerSecondGpu() : MicroProfileTicksPerSecondCpu());
uint32_t nTimer = i;
uint32_t nIdx = i * 2;
uint32_t nAggregateFrames = S.nAggregateFrames ? S.nAggregateFrames : 1;
uint32_t nAggregateCount = S.Aggregate[nTimer].nCount ? S.Aggregate[nTimer].nCount : 1;
float fToPrc = S.fRcpReferenceTime;
float fMs = fToMs * (S.Frame[nTimer].nTicks);
float fPrc = MicroProfileMin(fMs * fToPrc, 1.f);
float fAverageMs = fToMs * (S.Aggregate[nTimer].nTicks / nAggregateFrames);
float fAveragePrc = MicroProfileMin(fAverageMs * fToPrc, 1.f);
float fMaxMs = fToMs * (S.AggregateMax[nTimer]);
float fMaxPrc = MicroProfileMin(fMaxMs * fToPrc, 1.f);
float fCallAverageMs = fToMs * (S.Aggregate[nTimer].nTicks / nAggregateCount);
float fCallAveragePrc = MicroProfileMin(fCallAverageMs * fToPrc, 1.f);
float fMsExclusive = fToMs * (S.FrameExclusive[nTimer]);
float fPrcExclusive = MicroProfileMin(fMsExclusive * fToPrc, 1.f);
float fAverageMsExclusive = fToMs * (S.AggregateExclusive[nTimer] / nAggregateFrames);
float fAveragePrcExclusive = MicroProfileMin(fAverageMsExclusive * fToPrc, 1.f);
float fMaxMsExclusive = fToMs * (S.AggregateMaxExclusive[nTimer]);
float fMaxPrcExclusive = MicroProfileMin(fMaxMsExclusive * fToPrc, 1.f);
float fTotalMs = fToMs * S.Aggregate[nTimer].nTicks;
pTimers[nIdx] = fMs;
pTimers[nIdx+1] = fPrc;
pAverage[nIdx] = fAverageMs;
pAverage[nIdx+1] = fAveragePrc;
pMax[nIdx] = fMaxMs;
pMax[nIdx+1] = fMaxPrc;
pCallAverage[nIdx] = fCallAverageMs;
pCallAverage[nIdx+1] = fCallAveragePrc;
pExclusive[nIdx] = fMsExclusive;
pExclusive[nIdx+1] = fPrcExclusive;
pAverageExclusive[nIdx] = fAverageMsExclusive;
pAverageExclusive[nIdx+1] = fAveragePrcExclusive;
pMaxExclusive[nIdx] = fMaxMsExclusive;
pMaxExclusive[nIdx+1] = fMaxPrcExclusive;
pTotal[nIdx] = fTotalMs;
pTotal[nIdx+1] = 0.f;
}
}
void MicroProfileTogglePause()
{
S.nToggleRunning = 1;
}
float MicroProfileGetTime(const char* pGroup, const char* pName)
{
MicroProfileToken nToken = MicroProfileFindToken(pGroup, pName);
if(nToken == MICROPROFILE_INVALID_TOKEN)
{
return 0.f;
}
uint32_t nTimerIndex = MicroProfileGetTimerIndex(nToken);
uint32_t nGroupIndex = MicroProfileGetGroupIndex(nToken);
float fToMs = MicroProfileTickToMsMultiplier(S.GroupInfo[nGroupIndex].Type == MicroProfileTokenTypeGpu ? MicroProfileTicksPerSecondGpu() : MicroProfileTicksPerSecondCpu());
return S.Frame[nTimerIndex].nTicks * fToMs;
}
void MicroProfileContextSwitchSearch(uint32_t* pContextSwitchStart, uint32_t* pContextSwitchEnd, uint64_t nBaseTicksCpu, uint64_t nBaseTicksEndCpu)
{
MICROPROFILE_SCOPE(g_MicroProfileContextSwitchSearch);
uint32_t nContextSwitchPut = S.nContextSwitchPut;
uint64_t nContextSwitchStart, nContextSwitchEnd;
nContextSwitchStart = nContextSwitchEnd = (nContextSwitchPut + MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE - 1) % MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE;
int64_t nSearchEnd = nBaseTicksEndCpu + MicroProfileMsToTick(30.f, MicroProfileTicksPerSecondCpu());
int64_t nSearchBegin = nBaseTicksCpu - MicroProfileMsToTick(30.f, MicroProfileTicksPerSecondCpu());
for(uint32_t i = 0; i < MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE; ++i)
{
uint32_t nIndex = (nContextSwitchPut + MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE - (i+1)) % MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE;
MicroProfileContextSwitch& CS = S.ContextSwitch[nIndex];
if(CS.nTicks > nSearchEnd)
{
nContextSwitchEnd = nIndex;
}
if(CS.nTicks > nSearchBegin)
{
nContextSwitchStart = nIndex;
}
}
*pContextSwitchStart = nContextSwitchStart;
*pContextSwitchEnd = nContextSwitchEnd;
}
#if MICROPROFILE_WEBSERVER
#define MICROPROFILE_EMBED_HTML
extern const char* g_MicroProfileHtml_begin[];
extern size_t g_MicroProfileHtml_begin_sizes[];
extern size_t g_MicroProfileHtml_begin_count;
extern const char* g_MicroProfileHtml_end[];
extern size_t g_MicroProfileHtml_end_sizes[];
extern size_t g_MicroProfileHtml_end_count;
typedef void MicroProfileWriteCallback(void* Handle, size_t size, const char* pData);
uint32_t MicroProfileWebServerPort()
{
return S.nWebServerPort;
}
void MicroProfileDumpFile(const char* pHtml, const char* pCsv)
{
S.nDumpFileNextFrame = 0;
if(pHtml)
{
uint32_t nLen = strlen(pHtml);
if(nLen > sizeof(S.HtmlDumpPath)-1)
{
return;
}
memcpy(S.HtmlDumpPath, pHtml, nLen+1);
S.nDumpFileNextFrame |= 1;
}
if(pCsv)
{
uint32_t nLen = strlen(pCsv);
if(nLen > sizeof(S.CsvDumpPath)-1)
{
return;
}
memcpy(S.CsvDumpPath, pCsv, nLen+1);
S.nDumpFileNextFrame |= 2;
}
}
void MicroProfilePrintf(MicroProfileWriteCallback CB, void* Handle, const char* pFmt, ...)
{
char buffer[32*1024];
va_list args;
va_start (args, pFmt);
#ifdef _WIN32
size_t size = vsprintf_s(buffer, pFmt, args);
#else
size_t size = vsnprintf(buffer, sizeof(buffer)-1, pFmt, args);
#endif
CB(Handle, size, &buffer[0]);
va_end (args);
}
#define printf(...) MicroProfilePrintf(CB, Handle, __VA_ARGS__)
void MicroProfileDumpCsv(MicroProfileWriteCallback CB, void* Handle, int nMaxFrames)
{
uint32_t nAggregateFrames = S.nAggregateFrames ? S.nAggregateFrames : 1;
float fToMsCPU = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondCpu());
float fToMsGPU = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondGpu());
printf("frames,%d\n", nAggregateFrames);
printf("group,name,average,max,callaverage\n");
uint32_t nNumTimers = S.nTotalTimers;
uint32_t nBlockSize = 2 * nNumTimers;
float* pTimers = (float*)alloca(nBlockSize * 8 * sizeof(float));
float* pAverage = pTimers + nBlockSize;
float* pMax = pTimers + 2 * nBlockSize;
float* pCallAverage = pTimers + 3 * nBlockSize;
float* pTimersExclusive = pTimers + 4 * nBlockSize;
float* pAverageExclusive = pTimers + 5 * nBlockSize;
float* pMaxExclusive = pTimers + 6 * nBlockSize;
float* pTotal = pTimers + 7 * nBlockSize;
MicroProfileCalcAllTimers(pTimers, pAverage, pMax, pCallAverage, pTimersExclusive, pAverageExclusive, pMaxExclusive, pTotal, nNumTimers);
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
uint32_t nIdx = i * 2;
printf("\"%s\",\"%s\",%f,%f,%f\n", S.TimerInfo[i].pName, S.GroupInfo[S.TimerInfo[i].nGroupIndex].pName, pAverage[nIdx], pMax[nIdx], pCallAverage[nIdx]);
}
printf("\n\n");
printf("group,average,max,total\n");
for(uint32_t j = 0; j < MICROPROFILE_MAX_GROUPS; ++j)
{
const char* pGroupName = S.GroupInfo[j].pName;
float fToMs = S.GroupInfo[j].Type == MicroProfileTokenTypeGpu ? fToMsGPU : fToMsCPU;
if(pGroupName[0] != '\0')
{
printf("\"%s\",%.3f,%.3f,%.3f\n", pGroupName, fToMs * S.AggregateGroup[j] / nAggregateFrames, fToMs * S.AggregateGroup[j] / nAggregateFrames, fToMs * S.AggregateGroup[j]);
}
}
printf("\n\n");
printf("group,thread,average,total\n");
for(uint32_t j = 0; j < MICROPROFILE_MAX_GROUPS; ++j)
{
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
const char* pThreadName = &S.Pool[i]->ThreadName[0];
// MicroProfilePrintf(CB, Handle, "var ThreadGroupTime%d = [", i);
float fToMs = S.Pool[i]->nGpu ? fToMsGPU : fToMsCPU;
{
uint64_t nTicks = S.Pool[i]->nAggregateGroupTicks[j];
float fTime = nTicks / nAggregateFrames * fToMs;
float fTimeTotal = nTicks * fToMs;
if(fTimeTotal > 0.01f)
{
const char* pGroupName = S.GroupInfo[j].pName;
printf("\"%s\",\"%s\",%.3f,%.3f\n", pGroupName, pThreadName, fTime, fTimeTotal);
}
}
}
}
}
printf("\n\n");
printf("frametimecpu\n");
const uint32_t nCount = MICROPROFILE_MAX_FRAME_HISTORY - MICROPROFILE_GPU_FRAME_DELAY - 3;
const uint32_t nStart = S.nFrameCurrent;
for(uint32_t i = nCount; i > 0; i--)
{
uint32_t nFrame = (nStart + MICROPROFILE_MAX_FRAME_HISTORY - i) % MICROPROFILE_MAX_FRAME_HISTORY;
uint32_t nFrameNext = (nStart + MICROPROFILE_MAX_FRAME_HISTORY - i + 1) % MICROPROFILE_MAX_FRAME_HISTORY;
uint64_t nTicks = S.Frames[nFrameNext].nFrameStartCpu - S.Frames[nFrame].nFrameStartCpu;
printf("%f,", nTicks * fToMsCPU);
}
printf("\n");
printf("\n\n");
printf("frametimegpu\n");
for(uint32_t i = nCount; i > 0; i--)
{
uint32_t nFrame = (nStart + MICROPROFILE_MAX_FRAME_HISTORY - i) % MICROPROFILE_MAX_FRAME_HISTORY;
uint32_t nFrameNext = (nStart + MICROPROFILE_MAX_FRAME_HISTORY - i + 1) % MICROPROFILE_MAX_FRAME_HISTORY;
uint64_t nTicks = S.Frames[nFrameNext].nFrameStartGpu - S.Frames[nFrame].nFrameStartGpu;
printf("%f,", nTicks * fToMsGPU);
}
printf("\n\n");
printf("Meta\n");//only single frame snapshot
printf("name,average,max,total\n");
for(int j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName)
{
printf("\"%s\",%f,%lld,%lld\n",S.MetaCounters[j].pName, S.MetaCounters[j].nSumAggregate / (float)nAggregateFrames, S.MetaCounters[j].nSumAggregateMax,S.MetaCounters[j].nSumAggregate);
}
}
}
#undef printf
void MicroProfileDumpHtml(MicroProfileWriteCallback CB, void* Handle, int nMaxFrames, const char* pHost)
{
uint32_t nRunning = S.nRunning;
S.nRunning = 0;
//stall pushing of timers
uint64_t nActiveGroup = S.nActiveGroup;
S.nActiveGroup = 0;
S.nPauseTicks = MP_TICK();
for(size_t i = 0; i < g_MicroProfileHtml_begin_count; ++i)
{
CB(Handle, g_MicroProfileHtml_begin_sizes[i]-1, g_MicroProfileHtml_begin[i]);
}
//dump info
uint64_t nTicks = MP_TICK();
float fToMsCPU = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondCpu());
float fToMsGPU = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondGpu());
float fAggregateMs = fToMsCPU * (nTicks - S.nAggregateFlipTick);
MicroProfilePrintf(CB, Handle, "var DumpHost = '%s';\n", pHost ? pHost : "");
time_t CaptureTime;
time(&CaptureTime);
MicroProfilePrintf(CB, Handle, "var DumpUtcCaptureTime = %ld;\n", CaptureTime);
MicroProfilePrintf(CB, Handle, "var AggregateInfo = {'Frames':%d, 'Time':%f};\n", S.nAggregateFrames, fAggregateMs);
//categories
MicroProfilePrintf(CB, Handle, "var CategoryInfo = Array(%d);\n",S.nCategoryCount);
for(uint32_t i = 0; i < S.nCategoryCount; ++i)
{
MicroProfilePrintf(CB, Handle, "CategoryInfo[%d] = \"%s\";\n", i, S.CategoryInfo[i].pName);
}
//groups
MicroProfilePrintf(CB, Handle, "var GroupInfo = Array(%d);\n\n",S.nGroupCount);
uint32_t nAggregateFrames = S.nAggregateFrames ? S.nAggregateFrames : 1;
float fRcpAggregateFrames = 1.f / nAggregateFrames;
for(uint32_t i = 0; i < S.nGroupCount; ++i)
{
MP_ASSERT(i == S.GroupInfo[i].nGroupIndex);
float fToMs = S.GroupInfo[i].Type == MicroProfileTokenTypeCpu ? fToMsCPU : fToMsGPU;
MicroProfilePrintf(CB, Handle, "GroupInfo[%d] = MakeGroup(%d, \"%s\", %d, %d, %d, %f, %f, %f, '#%02x%02x%02x');\n",
S.GroupInfo[i].nGroupIndex,
S.GroupInfo[i].nGroupIndex,
S.GroupInfo[i].pName,
S.GroupInfo[i].nCategory,
S.GroupInfo[i].nNumTimers,
S.GroupInfo[i].Type == MicroProfileTokenTypeGpu?1:0,
fToMs * S.AggregateGroup[i],
fToMs * S.AggregateGroup[i] / nAggregateFrames,
fToMs * S.AggregateGroupMax[i],
MICROPROFILE_UNPACK_RED(S.GroupInfo[i].nColor) & 0xff,
MICROPROFILE_UNPACK_GREEN(S.GroupInfo[i].nColor) & 0xff,
MICROPROFILE_UNPACK_BLUE(S.GroupInfo[i].nColor) & 0xff);
}
//timers
uint32_t nNumTimers = S.nTotalTimers;
uint32_t nBlockSize = 2 * nNumTimers;
float* pTimers = (float*)alloca(nBlockSize * 8 * sizeof(float));
float* pAverage = pTimers + nBlockSize;
float* pMax = pTimers + 2 * nBlockSize;
float* pCallAverage = pTimers + 3 * nBlockSize;
float* pTimersExclusive = pTimers + 4 * nBlockSize;
float* pAverageExclusive = pTimers + 5 * nBlockSize;
float* pMaxExclusive = pTimers + 6 * nBlockSize;
float* pTotal = pTimers + 7 * nBlockSize;
MicroProfileCalcAllTimers(pTimers, pAverage, pMax, pCallAverage, pTimersExclusive, pAverageExclusive, pMaxExclusive, pTotal, nNumTimers);
MicroProfilePrintf(CB, Handle, "\nvar TimerInfo = Array(%d);\n\n", S.nTotalTimers);
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
uint32_t nIdx = i * 2;
MP_ASSERT(i == S.TimerInfo[i].nTimerIndex);
MicroProfilePrintf(CB, Handle, "var Meta%d = [", i);
bool bOnce = true;
for(int j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName)
{
uint32_t lala = S.MetaCounters[j].nCounters[i];
MicroProfilePrintf(CB, Handle, bOnce ? "%d" : ",%d", lala);
bOnce = false;
}
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var MetaAvg%d = [", i);
bOnce = true;
for(int j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName)
{
MicroProfilePrintf(CB, Handle, bOnce ? "%f" : ",%f", fRcpAggregateFrames * S.MetaCounters[j].nAggregate[i]);
bOnce = false;
}
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var MetaMax%d = [", i);
bOnce = true;
for(int j = 0; j < MICROPROFILE_META_MAX; ++j)
{
if(S.MetaCounters[j].pName)
{
MicroProfilePrintf(CB, Handle, bOnce ? "%d" : ",%d", S.MetaCounters[j].nAggregateMax[i]);
bOnce = false;
}
}
MicroProfilePrintf(CB, Handle, "];\n");
uint32_t nColor = S.TimerInfo[i].nColor;
uint32_t nColorDark = (nColor >> 1) & ~0x80808080;
MicroProfilePrintf(CB, Handle, "TimerInfo[%d] = MakeTimer(%d, \"%s\", %d, '#%02x%02x%02x','#%02x%02x%02x', %f, %f, %f, %f, %f, %d, %f, Meta%d, MetaAvg%d, MetaMax%d);\n", S.TimerInfo[i].nTimerIndex, S.TimerInfo[i].nTimerIndex, S.TimerInfo[i].pName, S.TimerInfo[i].nGroupIndex,
MICROPROFILE_UNPACK_RED(nColor) & 0xff,
MICROPROFILE_UNPACK_GREEN(nColor) & 0xff,
MICROPROFILE_UNPACK_BLUE(nColor) & 0xff,
MICROPROFILE_UNPACK_RED(nColorDark) & 0xff,
MICROPROFILE_UNPACK_GREEN(nColorDark) & 0xff,
MICROPROFILE_UNPACK_BLUE(nColorDark) & 0xff,
pAverage[nIdx],
pMax[nIdx],
pAverageExclusive[nIdx],
pMaxExclusive[nIdx],
pCallAverage[nIdx],
S.Aggregate[i].nCount,
pTotal[nIdx],
i,i,i);
}
MicroProfilePrintf(CB, Handle, "\nvar ThreadNames = [");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
MicroProfilePrintf(CB, Handle, "'%s',", S.Pool[i]->ThreadName);
}
else
{
MicroProfilePrintf(CB, Handle, "'Thread %d',", i);
}
}
MicroProfilePrintf(CB, Handle, "];\n\n");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
MicroProfilePrintf(CB, Handle, "var ThreadGroupTime%d = [", i);
float fToMs = S.Pool[i]->nGpu ? fToMsGPU : fToMsCPU;
for(uint32_t j = 0; j < MICROPROFILE_MAX_GROUPS; ++j)
{
MicroProfilePrintf(CB, Handle, "%f,", S.Pool[i]->nAggregateGroupTicks[j]/nAggregateFrames * fToMs);
}
MicroProfilePrintf(CB, Handle, "];\n");
}
}
MicroProfilePrintf(CB, Handle, "\nvar ThreadGroupTimeArray = [");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
MicroProfilePrintf(CB, Handle, "ThreadGroupTime%d,", i);
}
}
MicroProfilePrintf(CB, Handle, "];\n");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
MicroProfilePrintf(CB, Handle, "var ThreadGroupTimeTotal%d = [", i);
float fToMs = S.Pool[i]->nGpu ? fToMsGPU : fToMsCPU;
for(uint32_t j = 0; j < MICROPROFILE_MAX_GROUPS; ++j)
{
MicroProfilePrintf(CB, Handle, "%f,", S.Pool[i]->nAggregateGroupTicks[j] * fToMs);
}
MicroProfilePrintf(CB, Handle, "];\n");
}
}
MicroProfilePrintf(CB, Handle, "\nvar ThreadGroupTimeTotalArray = [");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
MicroProfilePrintf(CB, Handle, "ThreadGroupTimeTotal%d,", i);
}
}
MicroProfilePrintf(CB, Handle, "];");
MicroProfilePrintf(CB, Handle, "\nvar ThreadIds = [");
for(uint32_t i = 0; i < S.nNumLogs; ++i)
{
if(S.Pool[i])
{
ThreadIdType ThreadId = S.Pool[i]->nThreadId;
if(!ThreadId)
{
ThreadId = (ThreadIdType)-1;
}
MicroProfilePrintf(CB, Handle, "%d,", ThreadId);
}
else
{
MicroProfilePrintf(CB, Handle, "-1,", i);
}
}
MicroProfilePrintf(CB, Handle, "];\n\n");
MicroProfilePrintf(CB, Handle, "\nvar MetaNames = [");
for(int i = 0; i < MICROPROFILE_META_MAX; ++i)
{
if(S.MetaCounters[i].pName)
{
MicroProfilePrintf(CB, Handle, "'%s',", S.MetaCounters[i].pName);
}
}
MicroProfilePrintf(CB, Handle, "];\n\n");
uint32_t nNumFrames = (MICROPROFILE_MAX_FRAME_HISTORY - MICROPROFILE_GPU_FRAME_DELAY - 3); //leave a few to not overwrite
nNumFrames = MicroProfileMin(nNumFrames, (uint32_t)nMaxFrames);
uint32_t nFirstFrame = (S.nFrameCurrent + MICROPROFILE_MAX_FRAME_HISTORY - nNumFrames) % MICROPROFILE_MAX_FRAME_HISTORY;
uint32_t nLastFrame = (nFirstFrame + nNumFrames) % MICROPROFILE_MAX_FRAME_HISTORY;
MP_ASSERT(nLastFrame == (S.nFrameCurrent % MICROPROFILE_MAX_FRAME_HISTORY));
MP_ASSERT(nFirstFrame < MICROPROFILE_MAX_FRAME_HISTORY);
MP_ASSERT(nLastFrame < MICROPROFILE_MAX_FRAME_HISTORY);
const int64_t nTickStart = S.Frames[nFirstFrame].nFrameStartCpu;
const int64_t nTickEnd = S.Frames[nLastFrame].nFrameStartCpu;
int64_t nTickStartGpu = S.Frames[nFirstFrame].nFrameStartGpu;
int64_t nTickReferenceCpu, nTickReferenceGpu;
int64_t nTicksPerSecondCpu = MicroProfileTicksPerSecondCpu();
int64_t nTicksPerSecondGpu = MicroProfileTicksPerSecondGpu();
int nTickReference = 0;
if(MicroProfileGetGpuTickReference(&nTickReferenceCpu, &nTickReferenceGpu))
{
nTickStartGpu = (nTickStart - nTickReferenceCpu) * nTicksPerSecondGpu / nTicksPerSecondCpu + nTickReferenceGpu;
nTickReference = 1;
}
#if MICROPROFILE_DEBUG
printf("dumping %d frames\n", nNumFrames);
printf("dumping frame %d to %d\n", nFirstFrame, nLastFrame);
#endif
uint32_t* nTimerCounter = (uint32_t*)alloca(sizeof(uint32_t)* S.nTotalTimers);
memset(nTimerCounter, 0, sizeof(uint32_t) * S.nTotalTimers);
MicroProfilePrintf(CB, Handle, "var Frames = Array(%d);\n", nNumFrames);
for(uint32_t i = 0; i < nNumFrames; ++i)
{
uint32_t nFrameIndex = (nFirstFrame + i) % MICROPROFILE_MAX_FRAME_HISTORY;
uint32_t nFrameIndexNext = (nFrameIndex + 1) % MICROPROFILE_MAX_FRAME_HISTORY;
for(uint32_t j = 0; j < S.nNumLogs; ++j)
{
MicroProfileThreadLog* pLog = S.Pool[j];
int64_t nStartTickBase = pLog->nGpu ? nTickStartGpu : nTickStart;
uint32_t nLogStart = S.Frames[nFrameIndex].nLogStart[j];
uint32_t nLogEnd = S.Frames[nFrameIndexNext].nLogStart[j];
float fToMsCpu = MicroProfileTickToMsMultiplier(nTicksPerSecondCpu);
float fToMsBase = MicroProfileTickToMsMultiplier(pLog->nGpu ? nTicksPerSecondGpu : nTicksPerSecondCpu);
MicroProfilePrintf(CB, Handle, "var ts_%d_%d = [", i, j);
if(nLogStart != nLogEnd)
{
uint32_t k = nLogStart;
uint32_t nLogType = MicroProfileLogType(pLog->Log[k]);
float fToMs = nLogType == MP_LOG_GPU_EXTRA ? fToMsCpu : fToMsBase;
int64_t nStartTick = nLogType == MP_LOG_GPU_EXTRA ? nTickStart : nStartTickBase;
float fTime = nLogType == MP_LOG_META ? 0.f : MicroProfileLogTickDifference(nStartTick, pLog->Log[k]) * fToMs;
MicroProfilePrintf(CB, Handle, "%f", fTime);
for(k = (k+1) % MICROPROFILE_BUFFER_SIZE; k != nLogEnd; k = (k+1) % MICROPROFILE_BUFFER_SIZE)
{
uint32_t nLogType = MicroProfileLogType(pLog->Log[k]);
float fToMs = nLogType == MP_LOG_GPU_EXTRA ? fToMsCpu : fToMsBase;
nStartTick = nLogType == MP_LOG_GPU_EXTRA ? nTickStart : nStartTickBase;
float fTime = nLogType == MP_LOG_META ? 0.f : MicroProfileLogTickDifference(nStartTick, pLog->Log[k]) * fToMs;
MicroProfilePrintf(CB, Handle, ",%f", fTime);
}
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var tt_%d_%d = [", i, j);
if(nLogStart != nLogEnd)
{
uint32_t k = nLogStart;
MicroProfilePrintf(CB, Handle, "%d", MicroProfileLogType(pLog->Log[k]));
for(k = (k+1) % MICROPROFILE_BUFFER_SIZE; k != nLogEnd; k = (k+1) % MICROPROFILE_BUFFER_SIZE)
{
uint32_t nLogType = MicroProfileLogType(pLog->Log[k]);
if(nLogType == MP_LOG_META)
{
//for meta, store the count + 3, which is the tick part
nLogType = 3 + MicroProfileLogGetTick(pLog->Log[k]);
}
MicroProfilePrintf(CB, Handle, ",%d", nLogType);
}
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var ti_%d_%d = [", i, j);
if(nLogStart != nLogEnd)
{
uint32_t k = nLogStart;
MicroProfilePrintf(CB, Handle, "%d", (uint32_t)MicroProfileLogTimerIndex(pLog->Log[k]));
for(k = (k+1) % MICROPROFILE_BUFFER_SIZE; k != nLogEnd; k = (k+1) % MICROPROFILE_BUFFER_SIZE)
{
uint32_t nTimerIndex = (uint32_t)MicroProfileLogTimerIndex(pLog->Log[k]);
MicroProfilePrintf(CB, Handle, ",%d", nTimerIndex);
nTimerCounter[nTimerIndex]++;
}
}
MicroProfilePrintf(CB, Handle, "];\n");
}
MicroProfilePrintf(CB, Handle, "var ts%d = [", i);
for(uint32_t j = 0; j < S.nNumLogs; ++j)
{
MicroProfilePrintf(CB, Handle, "ts_%d_%d,", i, j);
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var tt%d = [", i);
for(uint32_t j = 0; j < S.nNumLogs; ++j)
{
MicroProfilePrintf(CB, Handle, "tt_%d_%d,", i, j);
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var ti%d = [", i);
for(uint32_t j = 0; j < S.nNumLogs; ++j)
{
MicroProfilePrintf(CB, Handle, "ti_%d_%d,", i, j);
}
MicroProfilePrintf(CB, Handle, "];\n");
int64_t nFrameStart = S.Frames[nFrameIndex].nFrameStartCpu;
int64_t nFrameEnd = S.Frames[nFrameIndexNext].nFrameStartCpu;
float fToMs = MicroProfileTickToMsMultiplier(nTicksPerSecondCpu);
float fFrameMs = MicroProfileLogTickDifference(nTickStart, nFrameStart) * fToMs;
float fFrameEndMs = MicroProfileLogTickDifference(nTickStart, nFrameEnd) * fToMs;
float fFrameGpuMs = 0;
float fFrameGpuEndMs = 0;
if(nTickReference)
{
fFrameGpuMs = MicroProfileLogTickDifference(nTickStartGpu, S.Frames[nFrameIndex].nFrameStartGpu) * fToMsGPU;
fFrameGpuEndMs = MicroProfileLogTickDifference(nTickStartGpu, S.Frames[nFrameIndexNext].nFrameStartGpu) * fToMsGPU;
}
MicroProfilePrintf(CB, Handle, "Frames[%d] = MakeFrame(%d, %f, %f, %f, %f, ts%d, tt%d, ti%d);\n", i, 0, fFrameMs, fFrameEndMs, fFrameGpuMs, fFrameGpuEndMs, i, i, i);
}
uint32_t nContextSwitchStart = 0;
uint32_t nContextSwitchEnd = 0;
MicroProfileContextSwitchSearch(&nContextSwitchStart, &nContextSwitchEnd, nTickStart, nTickEnd);
uint32_t nWrittenBefore = S.nWebServerDataSent;
MicroProfilePrintf(CB, Handle, "var CSwitchThreadInOutCpu = [");
for(uint32_t j = nContextSwitchStart; j != nContextSwitchEnd; j = (j+1) % MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE)
{
MicroProfileContextSwitch CS = S.ContextSwitch[j];
int nCpu = CS.nCpu;
MicroProfilePrintf(CB, Handle, "%d,%d,%d,", CS.nThreadIn, CS.nThreadOut, nCpu);
}
MicroProfilePrintf(CB, Handle, "];\n");
MicroProfilePrintf(CB, Handle, "var CSwitchTime = [");
float fToMsCpu = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondCpu());
for(uint32_t j = nContextSwitchStart; j != nContextSwitchEnd; j = (j+1) % MICROPROFILE_CONTEXT_SWITCH_BUFFER_SIZE)
{
MicroProfileContextSwitch CS = S.ContextSwitch[j];
float fTime = MicroProfileLogTickDifference(nTickStart, CS.nTicks) * fToMsCpu;
MicroProfilePrintf(CB, Handle, "%f,", fTime);
}
MicroProfilePrintf(CB, Handle, "];\n");
uint32_t nWrittenAfter = S.nWebServerDataSent;
MicroProfilePrintf(CB, Handle, "//CSwitch Size %d\n", nWrittenAfter - nWrittenBefore);
for(size_t i = 0; i < g_MicroProfileHtml_end_count; ++i)
{
CB(Handle, g_MicroProfileHtml_end_sizes[i]-1, g_MicroProfileHtml_end[i]);
}
uint32_t* nGroupCounter = (uint32_t*)alloca(sizeof(uint32_t)* S.nGroupCount);
memset(nGroupCounter, 0, sizeof(uint32_t) * S.nGroupCount);
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
uint32_t nGroupIndex = S.TimerInfo[i].nGroupIndex;
nGroupCounter[nGroupIndex] += nTimerCounter[i];
}
uint32_t* nGroupCounterSort = (uint32_t*)alloca(sizeof(uint32_t)* S.nGroupCount);
uint32_t* nTimerCounterSort = (uint32_t*)alloca(sizeof(uint32_t)* S.nTotalTimers);
for(uint32_t i = 0; i < S.nGroupCount; ++i)
{
nGroupCounterSort[i] = i;
}
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
nTimerCounterSort[i] = i;
}
std::sort(nGroupCounterSort, nGroupCounterSort + S.nGroupCount,
[nGroupCounter](const uint32_t l, const uint32_t r)
{
return nGroupCounter[l] > nGroupCounter[r];
}
);
std::sort(nTimerCounterSort, nTimerCounterSort + S.nTotalTimers,
[nTimerCounter](const uint32_t l, const uint32_t r)
{
return nTimerCounter[l] > nTimerCounter[r];
}
);
MicroProfilePrintf(CB, Handle, "\n<!--\nMarker Per Group\n");
for(uint32_t i = 0; i < S.nGroupCount; ++i)
{
uint32_t idx = nGroupCounterSort[i];
MicroProfilePrintf(CB, Handle, "%8d:%s\n", nGroupCounter[idx], S.GroupInfo[idx].pName);
}
MicroProfilePrintf(CB, Handle, "Marker Per Timer\n");
for(uint32_t i = 0; i < S.nTotalTimers; ++i)
{
uint32_t idx = nTimerCounterSort[i];
MicroProfilePrintf(CB, Handle, "%8d:%s(%s)\n", nTimerCounter[idx], S.TimerInfo[idx].pName, S.GroupInfo[S.TimerInfo[idx].nGroupIndex].pName);
}
MicroProfilePrintf(CB, Handle, "\n-->\n");
S.nActiveGroup = nActiveGroup;
S.nRunning = nRunning;
#if MICROPROFILE_DEBUG
int64_t nTicksEnd = MP_TICK();
float fMs = fToMsCpu * (nTicksEnd - S.nPauseTicks);
printf("html dump took %6.2fms\n", fMs);
#endif
}
void MicroProfileWriteFile(void* Handle, size_t nSize, const char* pData)
{
fwrite(pData, nSize, 1, (FILE*)Handle);
}
void MicroProfileDumpToFile()
{
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
if(S.nDumpFileNextFrame&1)
{
FILE* F = fopen(S.HtmlDumpPath, "w");
if(F)
{
MicroProfileDumpHtml(MicroProfileWriteFile, F, MICROPROFILE_WEBSERVER_MAXFRAMES, S.HtmlDumpPath);
fclose(F);
}
}
if(S.nDumpFileNextFrame&2)
{
FILE* F = fopen(S.CsvDumpPath, "w");
if(F)
{
MicroProfileDumpCsv(MicroProfileWriteFile, F, MICROPROFILE_WEBSERVER_MAXFRAMES);
fclose(F);
}
}
}
void MicroProfileFlushSocket(MpSocket Socket)
{
send(Socket, &S.WebServerBuffer[0], S.WebServerPut, 0);
S.WebServerPut = 0;
}
void MicroProfileWriteSocket(void* Handle, size_t nSize, const char* pData)
{
S.nWebServerDataSent += nSize;
MpSocket Socket = *(MpSocket*)Handle;
if(nSize > MICROPROFILE_WEBSERVER_SOCKET_BUFFER_SIZE / 2)
{
MicroProfileFlushSocket(Socket);
send(Socket, pData, nSize, 0);
}
else
{
memcpy(&S.WebServerBuffer[S.WebServerPut], pData, nSize);
S.WebServerPut += nSize;
if(S.WebServerPut > MICROPROFILE_WEBSERVER_SOCKET_BUFFER_SIZE/2)
{
MicroProfileFlushSocket(Socket);
}
}
}
#if MICROPROFILE_MINIZ
#ifndef MICROPROFILE_COMPRESS_BUFFER_SIZE
#define MICROPROFILE_COMPRESS_BUFFER_SIZE (256<<10)
#endif
#define MICROPROFILE_COMPRESS_CHUNK (MICROPROFILE_COMPRESS_BUFFER_SIZE/2)
struct MicroProfileCompressedSocketState
{
unsigned char DeflateOut[MICROPROFILE_COMPRESS_CHUNK];
unsigned char DeflateIn[MICROPROFILE_COMPRESS_CHUNK];
mz_stream Stream;
MpSocket Socket;
uint32_t nSize;
uint32_t nCompressedSize;
uint32_t nFlushes;
uint32_t nMemmoveBytes;
};
void MicroProfileCompressedSocketFlush(MicroProfileCompressedSocketState* pState)
{
mz_stream& Stream = pState->Stream;
unsigned char* pSendStart = &pState->DeflateOut[0];
unsigned char* pSendEnd = &pState->DeflateOut[MICROPROFILE_COMPRESS_CHUNK - Stream.avail_out];
if(pSendStart != pSendEnd)
{
send(pState->Socket, (const char*)pSendStart, pSendEnd - pSendStart, 0);
pState->nCompressedSize += pSendEnd - pSendStart;
}
Stream.next_out = &pState->DeflateOut[0];
Stream.avail_out = MICROPROFILE_COMPRESS_CHUNK;
}
void MicroProfileCompressedSocketStart(MicroProfileCompressedSocketState* pState, MpSocket Socket)
{
mz_stream& Stream = pState->Stream;
memset(&Stream, 0, sizeof(Stream));
Stream.next_out = &pState->DeflateOut[0];
Stream.avail_out = MICROPROFILE_COMPRESS_CHUNK;
Stream.next_in = &pState->DeflateIn[0];
Stream.avail_in = 0;
mz_deflateInit(&Stream, Z_DEFAULT_COMPRESSION);
pState->Socket = Socket;
pState->nSize = 0;
pState->nCompressedSize = 0;
pState->nFlushes = 0;
pState->nMemmoveBytes = 0;
}
void MicroProfileCompressedSocketFinish(MicroProfileCompressedSocketState* pState)
{
mz_stream& Stream = pState->Stream;
MicroProfileCompressedSocketFlush(pState);
int r = mz_deflate(&Stream, MZ_FINISH);
MP_ASSERT(r == MZ_STREAM_END);
MicroProfileCompressedSocketFlush(pState);
r = mz_deflateEnd(&Stream);
MP_ASSERT(r == MZ_OK);
}
void MicroProfileCompressedWriteSocket(void* Handle, size_t nSize, const char* pData)
{
MicroProfileCompressedSocketState* pState = (MicroProfileCompressedSocketState*)Handle;
mz_stream& Stream = pState->Stream;
const unsigned char* pDeflateInEnd = Stream.next_in + Stream.avail_in;
const unsigned char* pDeflateInStart = &pState->DeflateIn[0];
const unsigned char* pDeflateInRealEnd = &pState->DeflateIn[MICROPROFILE_COMPRESS_CHUNK];
pState->nSize += nSize;
if(nSize <= pDeflateInRealEnd - pDeflateInEnd)
{
memcpy((void*)pDeflateInEnd, pData, nSize);
Stream.avail_in += nSize;
MP_ASSERT(Stream.next_in + Stream.avail_in <= pDeflateInRealEnd);
return;
}
int Flush = 0;
while(nSize)
{
pDeflateInEnd = Stream.next_in + Stream.avail_in;
if(Flush)
{
pState->nFlushes++;
MicroProfileCompressedSocketFlush(pState);
pDeflateInRealEnd = &pState->DeflateIn[MICROPROFILE_COMPRESS_CHUNK];
if(pDeflateInEnd == pDeflateInRealEnd)
{
if(Stream.avail_in)
{
MP_ASSERT(pDeflateInStart != Stream.next_in);
memmove((void*)pDeflateInStart, Stream.next_in, Stream.avail_in);
pState->nMemmoveBytes += Stream.avail_in;
}
Stream.next_in = pDeflateInStart;
pDeflateInEnd = Stream.next_in + Stream.avail_in;
}
}
size_t nSpace = pDeflateInRealEnd - pDeflateInEnd;
size_t nBytes = MicroProfileMin(nSpace, nSize);
MP_ASSERT(nBytes + pDeflateInEnd <= pDeflateInRealEnd);
memcpy((void*)pDeflateInEnd, pData, nBytes);
Stream.avail_in += nBytes;
nSize -= nBytes;
pData += nBytes;
int r = mz_deflate(&Stream, MZ_NO_FLUSH);
Flush = r == MZ_BUF_ERROR || nBytes == 0 || Stream.avail_out == 0 ? 1 : 0;
MP_ASSERT(r == MZ_BUF_ERROR || r == MZ_OK);
if(r == MZ_BUF_ERROR)
{
r = mz_deflate(&Stream, MZ_SYNC_FLUSH);
}
}
}
#endif
#ifndef MicroProfileSetNonBlocking //fcntl doesnt work on a some unix like platforms..
void MicroProfileSetNonBlocking(MpSocket Socket, int NonBlocking)
{
#ifdef _WIN32
u_long nonBlocking = NonBlocking ? 1 : 0;
ioctlsocket(Socket, FIONBIO, &nonBlocking);
#else
int Options = fcntl(Socket, F_GETFL);
if(NonBlocking)
{
fcntl(Socket, F_SETFL, Options|O_NONBLOCK);
}
else
{
fcntl(Socket, F_SETFL, Options&(~O_NONBLOCK));
}
#endif
}
#endif
void MicroProfileWebServerStart()
{
#ifdef _WIN32
WSADATA wsa;
if(WSAStartup(MAKEWORD(2, 2), &wsa))
{
S.ListenerSocket = -1;
return;
}
#endif
S.ListenerSocket = socket(PF_INET, SOCK_STREAM, 6);
MP_ASSERT(!MP_INVALID_SOCKET(S.ListenerSocket));
MicroProfileSetNonBlocking(S.ListenerSocket, 1);
S.nWebServerPort = (uint32_t)-1;
struct sockaddr_in Addr;
Addr.sin_family = AF_INET;
Addr.sin_addr.s_addr = INADDR_ANY;
for(int i = 0; i < 20; ++i)
{
Addr.sin_port = htons(MICROPROFILE_WEBSERVER_PORT+i);
if(0 == bind(S.ListenerSocket, (sockaddr*)&Addr, sizeof(Addr)))
{
S.nWebServerPort = MICROPROFILE_WEBSERVER_PORT+i;
break;
}
}
listen(S.ListenerSocket, 8);
}
void MicroProfileWebServerStop()
{
#ifdef _WIN32
closesocket(S.ListenerSocket);
WSACleanup();
#else
close(S.ListenerSocket);
#endif
}
int MicroProfileParseGet(const char* pGet)
{
const char* pStart = pGet;
while(*pGet != '\0')
{
if(*pGet < '0' || *pGet > '9')
return 0;
pGet++;
}
int nFrames = atoi(pStart);
if(nFrames)
{
return nFrames;
}
else
{
return MICROPROFILE_WEBSERVER_MAXFRAMES;
}
}
bool MicroProfileWebServerUpdate()
{
MICROPROFILE_SCOPEI("MicroProfile", "Webserver-update", -1);
MpSocket Connection = accept(S.ListenerSocket, 0, 0);
bool bServed = false;
if(!MP_INVALID_SOCKET(Connection))
{
std::lock_guard<std::recursive_mutex> Lock(MicroProfileMutex());
char Req[8192];
MicroProfileSetNonBlocking(Connection, 0);
int nReceived = recv(Connection, Req, sizeof(Req)-1, 0);
if(nReceived > 0)
{
Req[nReceived] = '\0';
#if MICROPROFILE_MINIZ
#define MICROPROFILE_HTML_HEADER "HTTP/1.0 200 OK\r\nContent-Type: text/html\r\nContent-Encoding: deflate\r\nExpires: Tue, 01 Jan 2199 16:00:00 GMT\r\n\r\n"
#else
#define MICROPROFILE_HTML_HEADER "HTTP/1.0 200 OK\r\nContent-Type: text/html\r\nExpires: Tue, 01 Jan 2199 16:00:00 GMT\r\n\r\n"
#endif
char* pHttp = strstr(Req, "HTTP/");
char* pGet = strstr(Req, "GET /");
char* pHost = strstr(Req, "Host: ");
auto Terminate = [](char* pString)
{
char* pEnd = pString;
while(*pEnd != '\0')
{
if(*pEnd == '\r' || *pEnd == '\n' || *pEnd == ' ')
{
*pEnd = '\0';
return;
}
pEnd++;
}
};
if(pHost)
{
pHost += sizeof("Host: ")-1;
Terminate(pHost);
}
if(pHttp && pGet)
{
*pHttp = '\0';
pGet += sizeof("GET /")-1;
Terminate(pGet);
int nFrames = MicroProfileParseGet(pGet);
if(nFrames)
{
uint64_t nTickStart = MP_TICK();
send(Connection, MICROPROFILE_HTML_HEADER, sizeof(MICROPROFILE_HTML_HEADER)-1, 0);
uint64_t nDataStart = S.nWebServerDataSent;
S.WebServerPut = 0;
#if 0 == MICROPROFILE_MINIZ
MicroProfileDumpHtml(MicroProfileWriteSocket, &Connection, nFrames, pHost);
uint64_t nDataEnd = S.nWebServerDataSent;
uint64_t nTickEnd = MP_TICK();
uint64_t nDiff = (nTickEnd - nTickStart);
float fMs = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondCpu()) * nDiff;
int nKb = ((nDataEnd-nDataStart)>>10) + 1;
int nCompressedKb = nKb;
MicroProfilePrintf(MicroProfileWriteSocket, &Connection, "\n<!-- Sent %dkb in %.2fms-->\n\n",nKb, fMs);
MicroProfileFlushSocket(Connection);
#else
MicroProfileCompressedSocketState CompressState;
MicroProfileCompressedSocketStart(&CompressState, Connection);
MicroProfileDumpHtml(MicroProfileCompressedWriteSocket, &CompressState, nFrames, pHost);
S.nWebServerDataSent += CompressState.nSize;
uint64_t nDataEnd = S.nWebServerDataSent;
uint64_t nTickEnd = MP_TICK();
uint64_t nDiff = (nTickEnd - nTickStart);
float fMs = MicroProfileTickToMsMultiplier(MicroProfileTicksPerSecondCpu()) * nDiff;
int nKb = ((nDataEnd-nDataStart)>>10) + 1;
int nCompressedKb = ((CompressState.nCompressedSize)>>10) + 1;
MicroProfilePrintf(MicroProfileCompressedWriteSocket, &CompressState, "\n<!-- Sent %dkb(compressed %dkb) in %.2fms-->\n\n", nKb, nCompressedKb, fMs);
MicroProfileCompressedSocketFinish(&CompressState);
MicroProfileFlushSocket(Connection);
#endif
#if MICROPROFILE_DEBUG
printf("\n<!-- Sent %dkb(compressed %dkb) in %.2fms-->\n\n", nKb, nCompressedKb, fMs);
#endif
}
}
}
#ifdef _WIN32
closesocket(Connection);
#else
close(Connection);
#endif
}
return bServed;
}
#endif
#if MICROPROFILE_CONTEXT_SWITCH_TRACE
//functions that need to be implemented per platform.
void* MicroProfileTraceThread(void* unused);
bool MicroProfileIsLocalThread(uint32_t nThreadId);
void MicroProfileStartContextSwitchTrace()
{
if(!S.bContextSwitchRunning)
{
S.bContextSwitchRunning = true;
S.bContextSwitchStop = false;
MicroProfileThreadStart(&S.ContextSwitchThread, MicroProfileTraceThread);
}
}
void MicroProfileStopContextSwitchTrace()
{
if(S.bContextSwitchRunning)
{
S.bContextSwitchStop = true;
MicroProfileThreadJoin(&S.ContextSwitchThread);
}
}
#ifdef _WIN32
#define INITGUID
#include <evntrace.h>
#include <evntcons.h>
#include <strsafe.h>
static GUID g_MicroProfileThreadClassGuid = { 0x3d6fa8d1, 0xfe05, 0x11d0, 0x9d, 0xda, 0x00, 0xc0, 0x4f, 0xd7, 0xba, 0x7c };
struct MicroProfileSCSwitch
{
uint32_t NewThreadId;
uint32_t OldThreadId;
int8_t NewThreadPriority;
int8_t OldThreadPriority;
uint8_t PreviousCState;
int8_t SpareByte;
int8_t OldThreadWaitReason;
int8_t OldThreadWaitMode;
int8_t OldThreadState;
int8_t OldThreadWaitIdealProcessor;
uint32_t NewThreadWaitTime;
uint32_t Reserved;
};
VOID WINAPI MicroProfileContextSwitchCallback(PEVENT_TRACE pEvent)
{
if (pEvent->Header.Guid == g_MicroProfileThreadClassGuid)
{
if (pEvent->Header.Class.Type == 36)
{
MicroProfileSCSwitch* pCSwitch = (MicroProfileSCSwitch*) pEvent->MofData;
if ((pCSwitch->NewThreadId != 0) || (pCSwitch->OldThreadId != 0))
{
MicroProfileContextSwitch Switch;
Switch.nThreadOut = pCSwitch->OldThreadId;
Switch.nThreadIn = pCSwitch->NewThreadId;
Switch.nCpu = pEvent->BufferContext.ProcessorNumber;
Switch.nTicks = pEvent->Header.TimeStamp.QuadPart;
MicroProfileContextSwitchPut(&Switch);
}
}
}
}
ULONG WINAPI MicroProfileBufferCallback(PEVENT_TRACE_LOGFILE Buffer)
{
return (S.bContextSwitchStop || !S.bContextSwitchRunning) ? FALSE : TRUE;
}
struct MicroProfileKernelTraceProperties : public EVENT_TRACE_PROPERTIES
{
char dummy[sizeof(KERNEL_LOGGER_NAME)];
};
void MicroProfileContextSwitchShutdownTrace()
{
TRACEHANDLE SessionHandle = 0;
MicroProfileKernelTraceProperties sessionProperties;
ZeroMemory(&sessionProperties, sizeof(sessionProperties));
sessionProperties.Wnode.BufferSize = sizeof(sessionProperties);
sessionProperties.Wnode.Flags = WNODE_FLAG_TRACED_GUID;
sessionProperties.Wnode.ClientContext = 1; //QPC clock resolution
sessionProperties.Wnode.Guid = SystemTraceControlGuid;
sessionProperties.BufferSize = 1;
sessionProperties.NumberOfBuffers = 128;
sessionProperties.EnableFlags = EVENT_TRACE_FLAG_CSWITCH;
sessionProperties.LogFileMode = EVENT_TRACE_REAL_TIME_MODE;
sessionProperties.MaximumFileSize = 0;
sessionProperties.LoggerNameOffset = sizeof(EVENT_TRACE_PROPERTIES);
sessionProperties.LogFileNameOffset = 0;
EVENT_TRACE_LOGFILE log;
ZeroMemory(&log, sizeof(log));
log.LoggerName = KERNEL_LOGGER_NAME;
log.ProcessTraceMode = 0;
TRACEHANDLE hLog = OpenTrace(&log);
if (hLog)
{
ControlTrace(SessionHandle, KERNEL_LOGGER_NAME, &sessionProperties, EVENT_TRACE_CONTROL_STOP);
}
CloseTrace(hLog);
}
void* MicroProfileTraceThread(void* unused)
{
MicroProfileContextSwitchShutdownTrace();
ULONG status = ERROR_SUCCESS;
TRACEHANDLE SessionHandle = 0;
MicroProfileKernelTraceProperties sessionProperties;
ZeroMemory(&sessionProperties, sizeof(sessionProperties));
sessionProperties.Wnode.BufferSize = sizeof(sessionProperties);
sessionProperties.Wnode.Flags = WNODE_FLAG_TRACED_GUID;
sessionProperties.Wnode.ClientContext = 1; //QPC clock resolution
sessionProperties.Wnode.Guid = SystemTraceControlGuid;
sessionProperties.BufferSize = 1;
sessionProperties.NumberOfBuffers = 128;
sessionProperties.EnableFlags = EVENT_TRACE_FLAG_CSWITCH|EVENT_TRACE_FLAG_PROCESS;
sessionProperties.LogFileMode = EVENT_TRACE_REAL_TIME_MODE;
sessionProperties.MaximumFileSize = 0;
sessionProperties.LoggerNameOffset = sizeof(EVENT_TRACE_PROPERTIES);
sessionProperties.LogFileNameOffset = 0;
status = StartTrace((PTRACEHANDLE) &SessionHandle, KERNEL_LOGGER_NAME, &sessionProperties);
if (ERROR_SUCCESS != status)
{
S.bContextSwitchRunning = false;
return 0;
}
EVENT_TRACE_LOGFILE log;
ZeroMemory(&log, sizeof(log));
log.LoggerName = KERNEL_LOGGER_NAME;
log.ProcessTraceMode = PROCESS_TRACE_MODE_REAL_TIME | PROCESS_TRACE_MODE_RAW_TIMESTAMP;
log.EventCallback = MicroProfileContextSwitchCallback;
log.BufferCallback = MicroProfileBufferCallback;
TRACEHANDLE hLog = OpenTrace(&log);
ProcessTrace(&hLog, 1, 0, 0);
CloseTrace(hLog);
MicroProfileContextSwitchShutdownTrace();
S.bContextSwitchRunning = false;
return 0;
}
bool MicroProfileIsLocalThread(uint32_t nThreadId)
{
HANDLE h = OpenThread(THREAD_QUERY_LIMITED_INFORMATION, FALSE, nThreadId);
if(h == NULL)
return false;
DWORD hProcess = GetProcessIdOfThread(h);
CloseHandle(h);
return GetCurrentProcessId() == hProcess;
}
#elif defined(__APPLE__)
#include <sys/time.h>
void* MicroProfileTraceThread(void* unused)
{
FILE* pFile = fopen("mypipe", "r");
if(!pFile)
{
printf("CONTEXT SWITCH FAILED TO OPEN FILE: make sure to run dtrace script\n");
S.bContextSwitchRunning = false;
return 0;
}
printf("STARTING TRACE THREAD\n");
char* pLine = 0;
size_t cap = 0;
size_t len = 0;
struct timeval tv;
gettimeofday(&tv, NULL);
uint64_t nsSinceEpoch = ((uint64_t)(tv.tv_sec) * 1000000 + (uint64_t)(tv.tv_usec)) * 1000;
uint64_t nTickEpoch = MP_TICK();
uint32_t nLastThread[MICROPROFILE_MAX_CONTEXT_SWITCH_THREADS] = {0};
mach_timebase_info_data_t sTimebaseInfo;
mach_timebase_info(&sTimebaseInfo);
S.bContextSwitchRunning = true;
uint64_t nProcessed = 0;
uint64_t nProcessedLast = 0;
while((len = getline(&pLine, &cap, pFile))>0 && !S.bContextSwitchStop)
{
nProcessed += len;
if(nProcessed - nProcessedLast > 10<<10)
{
nProcessedLast = nProcessed;
printf("processed %llukb %llukb\n", (nProcessed-nProcessedLast)>>10,nProcessed >>10);
}
char* pX = strchr(pLine, 'X');
if(pX)
{
int cpu = atoi(pX+1);
char* pX2 = strchr(pX + 1, 'X');
char* pX3 = strchr(pX2 + 1, 'X');
int thread = atoi(pX2+1);
char* lala;
int64_t timestamp = strtoll(pX3 + 1, &lala, 10);
MicroProfileContextSwitch Switch;
//convert to ticks.
uint64_t nDeltaNsSinceEpoch = timestamp - nsSinceEpoch;
uint64_t nDeltaTickSinceEpoch = sTimebaseInfo.numer * nDeltaNsSinceEpoch / sTimebaseInfo.denom;
uint64_t nTicks = nDeltaTickSinceEpoch + nTickEpoch;
if(cpu < MICROPROFILE_MAX_CONTEXT_SWITCH_THREADS)
{
Switch.nThreadOut = nLastThread[cpu];
Switch.nThreadIn = thread;
nLastThread[cpu] = thread;
Switch.nCpu = cpu;
Switch.nTicks = nTicks;
MicroProfileContextSwitchPut(&Switch);
}
}
}
printf("EXITING TRACE THREAD\n");
S.bContextSwitchRunning = false;
return 0;
}
bool MicroProfileIsLocalThread(uint32_t nThreadId)
{
return false;
}
#endif
#else
bool MicroProfileIsLocalThread(uint32_t nThreadId){return false;}
void MicroProfileStopContextSwitchTrace(){}
void MicroProfileStartContextSwitchTrace(){}
#endif
#if MICROPROFILE_GPU_TIMERS_D3D11
uint32_t MicroProfileGpuInsertTimeStamp()
{
MicroProfileD3D11Frame& Frame = S.GPU.m_QueryFrames[S.GPU.m_nQueryFrame];
if(Frame.m_nRateQueryStarted)
{
uint32_t nCurrent = (Frame.m_nQueryStart + Frame.m_nQueryCount) % MICROPROFILE_D3D_MAX_QUERIES;
uint32_t nNext = (nCurrent + 1) % MICROPROFILE_D3D_MAX_QUERIES;
if(nNext != S.GPU.m_nQueryGet)
{
Frame.m_nQueryCount++;
ID3D11Query* pQuery = (ID3D11Query*)S.GPU.m_pQueries[nCurrent];
ID3D11DeviceContext* pContext = (ID3D11DeviceContext*)S.GPU.m_pDeviceContext;
pContext->End(pQuery);
S.GPU.m_nQueryPut = nNext;
return nCurrent;
}
}
return (uint32_t)-1;
}
uint64_t MicroProfileGpuGetTimeStamp(uint32_t nIndex)
{
if(nIndex == (uint32_t)-1)
{
return (uint64_t)-1;
}
int64_t nResult = S.GPU.m_nQueryResults[nIndex];
MP_ASSERT(nResult != -1);
return nResult;
}
bool MicroProfileGpuGetData(void* pQuery, void* pData, uint32_t nDataSize)
{
HRESULT hr;
do
{
hr = ((ID3D11DeviceContext*)S.GPU.m_pDeviceContext)->GetData((ID3D11Query*)pQuery, pData, nDataSize, 0);
}while(hr == S_FALSE);
switch(hr)
{
case DXGI_ERROR_DEVICE_REMOVED:
case DXGI_ERROR_INVALID_CALL:
case E_INVALIDARG:
MP_BREAK();
return false;
}
return true;
}
uint64_t MicroProfileTicksPerSecondGpu()
{
return S.GPU.m_nQueryFrequency;
}
void MicroProfileGpuFlip()
{
MicroProfileD3D11Frame& CurrentFrame = S.GPU.m_QueryFrames[S.GPU.m_nQueryFrame];
ID3D11DeviceContext* pContext = (ID3D11DeviceContext*)S.GPU.m_pDeviceContext;
if(CurrentFrame.m_nRateQueryStarted)
{
pContext->End((ID3D11Query*)CurrentFrame.m_pRateQuery);
}
uint32_t nNextFrame = (S.GPU.m_nQueryFrame + 1) % MICROPROFILE_GPU_FRAME_DELAY;
MicroProfileD3D11Frame& OldFrame = S.GPU.m_QueryFrames[nNextFrame];
if(OldFrame.m_nRateQueryStarted)
{
struct RateQueryResult
{
uint64_t nFrequency;
BOOL bDisjoint;
};
RateQueryResult Result;
if(MicroProfileGpuGetData(OldFrame.m_pRateQuery, &Result, sizeof(Result)))
{
if(S.GPU.m_nQueryFrequency != (int64_t)Result.nFrequency)
{
if(S.GPU.m_nQueryFrequency)
{
OutputDebugString("Query freq changing");
}
S.GPU.m_nQueryFrequency = Result.nFrequency;
}
uint32_t nStart = OldFrame.m_nQueryStart;
uint32_t nCount = OldFrame.m_nQueryCount;
for(uint32_t i = 0; i < nCount; ++i)
{
uint32_t nIndex = (i + nStart) % MICROPROFILE_D3D_MAX_QUERIES;
if(!MicroProfileGpuGetData(S.GPU.m_pQueries[nIndex], &S.GPU.m_nQueryResults[nIndex], sizeof(uint64_t)))
{
S.GPU.m_nQueryResults[nIndex] = -1;
}
}
}
else
{
uint32_t nStart = OldFrame.m_nQueryStart;
uint32_t nCount = OldFrame.m_nQueryCount;
for(uint32_t i = 0; i < nCount; ++i)
{
uint32_t nIndex = (i + nStart) % MICROPROFILE_D3D_MAX_QUERIES;
S.GPU.m_nQueryResults[nIndex] = -1;
}
}
S.GPU.m_nQueryGet = (OldFrame.m_nQueryStart + OldFrame.m_nQueryCount) % MICROPROFILE_D3D_MAX_QUERIES;
}
S.GPU.m_nQueryFrame = nNextFrame;
MicroProfileD3D11Frame& NextFrame = S.GPU.m_QueryFrames[nNextFrame];
pContext->Begin((ID3D11Query*)NextFrame.m_pRateQuery);
NextFrame.m_nQueryStart = S.GPU.m_nQueryPut;
NextFrame.m_nQueryCount = 0;
NextFrame.m_nRateQueryStarted = 1;
}
void MicroProfileGpuInitD3D11(void* pDevice_, void* pDeviceContext_)
{
ID3D11Device* pDevice = (ID3D11Device*)pDevice_;
ID3D11DeviceContext* pDeviceContext = (ID3D11DeviceContext*)pDeviceContext_;
S.GPU.m_pDeviceContext = pDeviceContext_;
D3D11_QUERY_DESC Desc;
Desc.MiscFlags = 0;
Desc.Query = D3D11_QUERY_TIMESTAMP;
for(uint32_t i = 0; i < MICROPROFILE_D3D_MAX_QUERIES; ++i)
{
HRESULT hr = pDevice->CreateQuery(&Desc, (ID3D11Query**)&S.GPU.m_pQueries[i]);
MP_ASSERT(hr == S_OK);
S.GPU.m_nQueryResults[i] = -1;
}
S.GPU.m_nQueryPut = 0;
S.GPU.m_nQueryGet = 0;
S.GPU.m_nQueryFrame = 0;
S.GPU.m_nQueryFrequency = 0;
Desc.Query = D3D11_QUERY_TIMESTAMP_DISJOINT;
for(uint32_t i = 0; i < MICROPROFILE_GPU_FRAME_DELAY; ++i)
{
S.GPU.m_QueryFrames[i].m_nQueryStart = 0;
S.GPU.m_QueryFrames[i].m_nQueryCount = 0;
S.GPU.m_QueryFrames[i].m_nRateQueryStarted = 0;
HRESULT hr = pDevice->CreateQuery(&Desc, (ID3D11Query**)&S.GPU.m_QueryFrames[i].m_pRateQuery);
MP_ASSERT(hr == S_OK);
}
}
void MicroProfileGpuShutdown()
{
for(uint32_t i = 0; i < MICROPROFILE_D3D_MAX_QUERIES; ++i)
{
((ID3D11Query*)&S.GPU.m_pQueries[i])->Release();
S.GPU.m_pQueries[i] = 0;
}
for(uint32_t i = 0; i < MICROPROFILE_GPU_FRAME_DELAY; ++i)
{
((ID3D11Query*)S.GPU.m_QueryFrames[i].m_pRateQuery)->Release();
S.GPU.m_QueryFrames[i].m_pRateQuery = 0;
}
}
int MicroProfileGetGpuTickReference(int64_t* pOutCPU, int64_t* pOutGpu)
{
return 0;
}
#elif MICROPROFILE_GPU_TIMERS_GL
void MicroProfileGpuInitGL()
{
S.GPU.GLTimerPos = 0;
glGenQueries(MICROPROFILE_GL_MAX_QUERIES, &S.GPU.GLTimers[0]);
}
uint32_t MicroProfileGpuInsertTimeStamp()
{
uint32_t nIndex = (S.GPU.GLTimerPos+1)%MICROPROFILE_GL_MAX_QUERIES;
glQueryCounter(S.GPU.GLTimers[nIndex], GL_TIMESTAMP);
S.GPU.GLTimerPos = nIndex;
return nIndex;
}
uint64_t MicroProfileGpuGetTimeStamp(uint32_t nKey)
{
uint64_t result;
glGetQueryObjectui64v(S.GPU.GLTimers[nKey], GL_QUERY_RESULT, &result);
return result;
}
uint64_t MicroProfileTicksPerSecondGpu()
{
return 1000000000ll;
}
int MicroProfileGetGpuTickReference(int64_t* pOutCpu, int64_t* pOutGpu)
{
int64_t nGpuTimeStamp;
glGetInteger64v(GL_TIMESTAMP, &nGpuTimeStamp);
if(nGpuTimeStamp)
{
*pOutCpu = MP_TICK();
*pOutGpu = nGpuTimeStamp;
#if 0 //debug test if timestamp diverges
static int64_t nTicksPerSecondCpu = MicroProfileTicksPerSecondCpu();
static int64_t nTicksPerSecondGpu = MicroProfileTicksPerSecondGpu();
static int64_t nGpuStart = 0;
static int64_t nCpuStart = 0;
if(!nCpuStart)
{
nCpuStart = *pOutCpu;
nGpuStart = *pOutGpu;
}
static int nCountDown = 100;
if(0 == nCountDown--)
{
int64_t nCurCpu = *pOutCpu;
int64_t nCurGpu = *pOutGpu;
double fDistanceCpu = (nCurCpu - nCpuStart) / (double)nTicksPerSecondCpu;
double fDistanceGpu = (nCurGpu - nGpuStart) / (double)nTicksPerSecondGpu;
char buf[254];
snprintf(buf, sizeof(buf)-1,"Distance %f %f diff %f\n", fDistanceCpu, fDistanceGpu, fDistanceCpu-fDistanceGpu);
OutputDebugString(buf);
nCountDown = 100;
}
#endif
return 1;
}
return 0;
}
#endif
#undef S
#ifdef _WIN32
#pragma warning(pop)
#endif
#endif
#endif
#ifdef MICROPROFILE_EMBED_HTML
#include "microprofile_html.h"
#endif
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