tracy/client/TracyProfiler.cpp

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#ifdef TRACY_ENABLE
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#ifdef _MSC_VER
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# ifndef NOMINMAX
# define NOMINMAX
# endif
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# include <winsock2.h>
# include <windows.h>
# include <tlhelp32.h>
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#else
# include <sys/time.h>
#endif
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#ifdef __CYGWIN__
# include <windows.h>
#endif
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#ifdef _GNU_SOURCE
# include <errno.h>
#endif
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#ifdef __linux__
# include <signal.h>
# include <dirent.h>
# include <sys/types.h>
# include <sys/syscall.h>
#endif
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#include <atomic>
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#include <assert.h>
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#include <chrono>
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#include <limits>
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#include <memory>
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#include <mutex>
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#include <stdlib.h>
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#include <string.h>
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#include "../common/TracyAlign.hpp"
#include "../common/TracyProtocol.hpp"
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#include "../common/TracySocket.hpp"
#include "../common/TracySystem.hpp"
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#include "tracy_rpmalloc.hpp"
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#include "TracyCallstack.hpp"
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#include "TracyScoped.hpp"
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#include "TracyProfiler.hpp"
#include "TracyThread.hpp"
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#include "../TracyC.h"
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#ifdef __GNUC__
#define init_order( val ) __attribute__ ((init_priority(val)))
#else
#define init_order(x)
#endif
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#if defined TRACY_HW_TIMER && __ARM_ARCH >= 6
# include <signal.h>
# include <setjmp.h>
#endif
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#if defined _MSC_VER || defined __CYGWIN__
# include <lmcons.h>
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extern "C" typedef LONG (WINAPI *t_RtlGetVersion)( PRTL_OSVERSIONINFOW );
# if _WIN32_WINNT >= _WIN32_WINNT_VISTA
# define TRACY_USE_INIT_ONCE
# endif
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#else
# include <unistd.h>
# include <limits.h>
#endif
#if defined __APPLE__
# include "TargetConditionals.h"
#endif
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#if defined __linux__
# include <sys/sysinfo.h>
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# include <sys/utsname.h>
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#endif
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namespace tracy
{
#if defined TRACY_USE_INIT_ONCE
namespace
{
BOOL CALLBACK InitOnceCallback(
PINIT_ONCE initOnce,
PVOID Parameter,
PVOID *Context)
{
rpmalloc_initialize();
return TRUE;
}
INIT_ONCE InitOnce = INIT_ONCE_STATIC_INIT;
}
#endif //if defined TRACY_USE_INIT_ONCE
struct RPMallocInit
{
RPMallocInit()
{
#if defined TRACY_USE_INIT_ONCE
InitOnceExecuteOnce(&InitOnce, InitOnceCallback, nullptr, nullptr);
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//We must call rpmalloc_thread_initialize() explicitly here since the InitOnceCallback might
//not be called on this thread if another thread has executed it earlier.
rpmalloc_thread_initialize();
#else
rpmalloc_initialize();
#endif //if defined TRACY_USE_INIT_ONCE
}
};
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struct RPMallocThreadInit
{
RPMallocThreadInit()
{
#if defined TRACY_USE_INIT_ONCE
InitOnceExecuteOnce(&InitOnce, InitOnceCallback, nullptr, nullptr);
#endif //if defined TRACY_USE_INIT_ONCE
rpmalloc_thread_initialize();
}
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};
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struct InitTimeWrapper
{
int64_t val;
};
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#if defined TRACY_HW_TIMER && __ARM_ARCH >= 6
int64_t (*GetTimeImpl)();
int64_t GetTimeImplFallback()
{
return std::chrono::duration_cast<std::chrono::nanoseconds>( std::chrono::high_resolution_clock::now().time_since_epoch() ).count();
}
int64_t GetTimeImplCntvct()
{
int64_t t;
# ifdef __aarch64__
asm volatile ( "mrs %0, cntvct_el0" : "=r" (t) );
# else
asm volatile ( "mrrc p15, 1, %Q0, %R0, c14" : "=r" (t) );
# endif
return t;
}
static sigjmp_buf SigIllEnv;
static int SetupHwTimerFailed()
{
return sigsetjmp( SigIllEnv, 1 );
}
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static void SetupHwTimerSigIllHandler( int /*signum*/ )
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{
siglongjmp( SigIllEnv, 1 );
}
static int64_t SetupHwTimer()
{
struct sigaction act, oldact;
memset( &act, 0, sizeof( act ) );
act.sa_handler = SetupHwTimerSigIllHandler;
if( sigaction( SIGILL, &act, &oldact ) )
{
GetTimeImpl = GetTimeImplFallback;
return Profiler::GetTime();
}
if( SetupHwTimerFailed() )
{
sigaction( SIGILL, &oldact, nullptr );
GetTimeImpl = GetTimeImplFallback;
return Profiler::GetTime();
}
GetTimeImplCntvct();
sigaction( SIGILL, &oldact, nullptr );
GetTimeImpl = GetTimeImplCntvct;
return Profiler::GetTime();
}
#else
static int64_t SetupHwTimer()
{
return Profiler::GetTime();
}
#endif
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static const char* GetProcessName()
{
const char* processName = "unknown";
#if defined _MSC_VER
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static char buf[_MAX_PATH];
GetModuleFileNameA( nullptr, buf, _MAX_PATH );
const char* ptr = buf;
while( *ptr != '\0' ) ptr++;
while( ptr > buf && *ptr != '\\' && *ptr != '/' ) ptr--;
if( ptr > buf ) ptr++;
processName = ptr;
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#elif defined __ANDROID__
# if __ANDROID_API__ >= 21
auto buf = getprogname();
if( buf ) processName = buf;
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# endif
#elif defined _GNU_SOURCE || defined __CYGWIN__
processName = program_invocation_short_name;
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#endif
return processName;
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}
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static const char* GetHostInfo()
{
static char buf[1024];
auto ptr = buf;
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#if defined _MSC_VER || defined __CYGWIN__
# ifdef UNICODE
t_RtlGetVersion RtlGetVersion = (t_RtlGetVersion)GetProcAddress( GetModuleHandle( L"ntdll.dll" ), "RtlGetVersion" );
# else
t_RtlGetVersion RtlGetVersion = (t_RtlGetVersion)GetProcAddress( GetModuleHandle( "ntdll.dll" ), "RtlGetVersion" );
# endif
if( !RtlGetVersion )
{
# ifndef __CYGWIN__
ptr += sprintf( ptr, "OS: Windows\n" );
# else
ptr += sprintf( ptr, "OS: Windows (Cygwin)\n" );
# endif
}
else
{
RTL_OSVERSIONINFOW ver = { sizeof( RTL_OSVERSIONINFOW ) };
RtlGetVersion( &ver );
# ifndef __CYGWIN__
ptr += sprintf( ptr, "OS: Windows %i.%i.%i\n", ver.dwMajorVersion, ver.dwMinorVersion, ver.dwBuildNumber );
# else
ptr += sprintf( ptr, "OS: Windows %i.%i.%i (Cygwin)\n", ver.dwMajorVersion, ver.dwMinorVersion, ver.dwBuildNumber );
# endif
}
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#elif defined __linux__
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struct utsname utsName;
uname( &utsName );
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# if defined __ANDROID__
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ptr += sprintf( ptr, "OS: Linux %s (Android)\n", utsName.release );
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# else
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ptr += sprintf( ptr, "OS: Linux %s\n", utsName.release );
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# endif
#elif defined __APPLE__
# if defined TARGET_OS_IPHONE
ptr += sprintf( ptr, "OS: Darwin (iOS)\n" );
# elif defined TARGET_OS_MAC
ptr += sprintf( ptr, "OS: Darwin (OSX)\n" );
# else
ptr += sprintf( ptr, "OS: Darwin (unknown)\n" );
# endif
#elif defined __DragonFly__
ptr += sprintf( ptr, "OS: BSD (DragonFly)\n" );
#elif defined __FreeBSD__
ptr += sprintf( ptr, "OS: BSD (FreeBSD)\n" );
#elif defined __NetBSD__
ptr += sprintf( ptr, "OS: BSD (NetBSD)\n" );
#elif defined __OpenBSD__
ptr += sprintf( ptr, "OS: BSD (OpenBSD)\n" );
#else
ptr += sprintf( ptr, "OS: unknown\n" );
#endif
#if defined _MSC_VER
ptr += sprintf( ptr, "Compiler: MSVC %i\n", _MSC_VER );
#elif defined __clang__
ptr += sprintf( ptr, "Compiler: clang %i.%i.%i\n", __clang_major__, __clang_minor__, __clang_patchlevel__ );
#elif defined __GNUC__
ptr += sprintf( ptr, "Compiler: gcc %i.%i\n", __GNUC__, __GNUC_MINOR__ );
#else
ptr += sprintf( ptr, "Compiler: unknown\n" );
#endif
#if defined _MSC_VER || defined __CYGWIN__
# ifndef __CYGWIN__
InitWinSock();
# endif
char hostname[512];
gethostname( hostname, 512 );
DWORD userSz = UNLEN+1;
char user[UNLEN+1];
GetUserNameA( user, &userSz );
ptr += sprintf( ptr, "User: %s@%s\n", user, hostname );
#else
char hostname[_POSIX_HOST_NAME_MAX]{};
char user[_POSIX_LOGIN_NAME_MAX]{};
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gethostname( hostname, _POSIX_HOST_NAME_MAX );
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# if defined __ANDROID__
const auto login = getlogin();
if( login )
{
strcpy( user, login );
}
else
{
memcpy( user, "(?)", 4 );
}
# else
getlogin_r( user, _POSIX_LOGIN_NAME_MAX );
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# endif
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ptr += sprintf( ptr, "User: %s@%s\n", user, hostname );
#endif
#if defined __i386 || defined _M_IX86
ptr += sprintf( ptr, "Arch: x86\n" );
#elif defined __x86_64__ || defined _M_X64
ptr += sprintf( ptr, "Arch: x64\n" );
#elif defined __aarch64__
ptr += sprintf( ptr, "Arch: ARM64\n" );
#elif defined __ARM_ARCH
ptr += sprintf( ptr, "Arch: ARM\n" );
#else
ptr += sprintf( ptr, "Arch: unknown\n" );
#endif
#if defined __i386 || defined _M_IX86 || defined __x86_64__ || defined _M_X64
uint32_t regs[4];
char cpuModel[4*4*3];
auto modelPtr = cpuModel;
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for( uint32_t i=0x80000002; i<0x80000005; ++i )
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{
# if defined _MSC_VER || defined __CYGWIN__
__cpuidex( (int*)regs, i, 0 );
# else
int zero = 0;
asm volatile ( "cpuid" : "=a" (regs[0]), "=b" (regs[1]), "=c" (regs[2]), "=d" (regs[3]) : "a" (i), "c" (zero) );
# endif
memcpy( modelPtr, regs, sizeof( regs ) ); modelPtr += sizeof( regs );
}
ptr += sprintf( ptr, "CPU: %s\n", cpuModel );
#else
ptr += sprintf( ptr, "CPU: unknown\n" );
#endif
#if defined _MSC_VER || defined __CYGWIN__
MEMORYSTATUSEX statex;
statex.dwLength = sizeof( statex );
GlobalMemoryStatusEx( &statex );
# ifdef _MSC_VER
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ptr += sprintf( ptr, "RAM: %I64u MB\n", statex.ullTotalPhys / 1024 / 1024 );
# else
ptr += sprintf( ptr, "RAM: %llu MB\n", statex.ullTotalPhys / 1024 / 1024 );
# endif
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#elif defined __linux__
struct sysinfo sysInfo;
sysinfo( &sysInfo );
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ptr += sprintf( ptr, "RAM: %lu MB\n", sysInfo.totalram / 1024 / 1024 );
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#else
ptr += sprintf( ptr, "RAM: unknown\n" );
#endif
return buf;
}
#ifdef _MSC_VER
static DWORD s_profilerThreadId = 0;
static char s_crashText[1024];
LONG WINAPI CrashFilter( PEXCEPTION_POINTERS pExp )
{
const auto ec = pExp->ExceptionRecord->ExceptionCode;
auto msgPtr = s_crashText;
switch( ec )
{
case EXCEPTION_ACCESS_VIOLATION:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_ACCESS_VIOLATION (0x%x). ", ec );
switch( pExp->ExceptionRecord->ExceptionInformation[0] )
{
case 0:
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msgPtr += sprintf( msgPtr, "Read violation at address 0x%Iu.", pExp->ExceptionRecord->ExceptionInformation[1] );
break;
case 1:
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msgPtr += sprintf( msgPtr, "Write violation at address 0x%Iu.", pExp->ExceptionRecord->ExceptionInformation[1] );
break;
case 8:
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msgPtr += sprintf( msgPtr, "DEP violation at address 0x%Iu.", pExp->ExceptionRecord->ExceptionInformation[1] );
break;
default:
break;
}
break;
case EXCEPTION_ARRAY_BOUNDS_EXCEEDED:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_ARRAY_BOUNDS_EXCEEDED (0x%x). ", ec );
break;
case EXCEPTION_DATATYPE_MISALIGNMENT:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_DATATYPE_MISALIGNMENT (0x%x). ", ec );
break;
case EXCEPTION_FLT_DIVIDE_BY_ZERO:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_FLT_DIVIDE_BY_ZERO (0x%x). ", ec );
break;
case EXCEPTION_ILLEGAL_INSTRUCTION:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_ILLEGAL_INSTRUCTION (0x%x). ", ec );
break;
case EXCEPTION_IN_PAGE_ERROR:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_IN_PAGE_ERROR (0x%x). ", ec );
break;
case EXCEPTION_INT_DIVIDE_BY_ZERO:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_INT_DIVIDE_BY_ZERO (0x%x). ", ec );
break;
case EXCEPTION_PRIV_INSTRUCTION:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_PRIV_INSTRUCTION (0x%x). ", ec );
break;
case EXCEPTION_STACK_OVERFLOW:
msgPtr += sprintf( msgPtr, "Exception EXCEPTION_STACK_OVERFLOW (0x%x). ", ec );
break;
default:
return EXCEPTION_CONTINUE_SEARCH;
}
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{
const auto thread = GetThreadHandle();
Magic magic;
auto& token = s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::CrashReport );
item->crashReport.time = Profiler::GetTime();
item->crashReport.thread = thread;
item->crashReport.text = (uint64_t)s_crashText;
tail.store( magic + 1, std::memory_order_release );
s_profiler.SendCallstack( 60, thread, "KiUserExceptionDispatcher" );
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}
HANDLE h = CreateToolhelp32Snapshot( TH32CS_SNAPTHREAD, 0 );
if( h == INVALID_HANDLE_VALUE ) return EXCEPTION_CONTINUE_SEARCH;
THREADENTRY32 te = { sizeof( te ) };
if( !Thread32First( h, &te ) )
{
CloseHandle( h );
return EXCEPTION_CONTINUE_SEARCH;
}
const auto pid = GetCurrentProcessId();
const auto tid = GetCurrentThreadId();
do
{
if( te.th32OwnerProcessID == pid && te.th32ThreadID != tid && te.th32ThreadID != s_profilerThreadId )
{
HANDLE th = OpenThread( THREAD_SUSPEND_RESUME, FALSE, te.th32ThreadID );
if( th != INVALID_HANDLE_VALUE )
{
SuspendThread( th );
CloseHandle( th );
}
}
}
while( Thread32Next( h, &te ) );
CloseHandle( h );
{
Magic magic;
auto& token = s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::Crash );
tail.store( magic + 1, std::memory_order_release );
}
std::this_thread::sleep_for( std::chrono::milliseconds( 500 ) );
s_profiler.RequestShutdown();
while( !s_profiler.HasShutdownFinished() ) { std::this_thread::sleep_for( std::chrono::milliseconds( 10 ) ); };
TerminateProcess( GetCurrentProcess(), 1 );
return EXCEPTION_CONTINUE_SEARCH;
}
#endif
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#ifdef __linux__
static long s_profilerTid = 0;
static char s_crashText[1024];
static std::atomic<bool> s_alreadyCrashed( false );
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static void ThreadFreezer( int signal )
{
for(;;) sleep( 1000 );
}
static inline void HexPrint( char*& ptr, uint64_t val )
{
if( val == 0 )
{
*ptr++ = '0';
return;
}
static const char HexTable[16] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' };
char buf[16];
auto bptr = buf;
do
{
*bptr++ = HexTable[val%16];
val /= 16;
}
while( val > 0 );
do
{
*ptr++ = *--bptr;
}
while( bptr != buf );
}
static void CrashHandler( int signal, siginfo_t* info, void* ucontext )
{
bool expected = false;
if( !s_alreadyCrashed.compare_exchange_strong( expected, true ) ) ThreadFreezer( signal );
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auto msgPtr = s_crashText;
switch( signal )
{
case SIGILL:
strcpy( msgPtr, "Illegal Instruction.\n" );
while( *msgPtr ) msgPtr++;
switch( info->si_code )
{
case ILL_ILLOPC:
strcpy( msgPtr, "Illegal opcode.\n" );
break;
case ILL_ILLOPN:
strcpy( msgPtr, "Illegal operand.\n" );
break;
case ILL_ILLADR:
strcpy( msgPtr, "Illegal addressing mode.\n" );
break;
case ILL_ILLTRP:
strcpy( msgPtr, "Illegal trap.\n" );
break;
case ILL_PRVOPC:
strcpy( msgPtr, "Privileged opcode.\n" );
break;
case ILL_PRVREG:
strcpy( msgPtr, "Privileged register.\n" );
break;
case ILL_COPROC:
strcpy( msgPtr, "Coprocessor error.\n" );
break;
case ILL_BADSTK:
strcpy( msgPtr, "Internal stack error.\n" );
break;
default:
break;
}
break;
case SIGFPE:
strcpy( msgPtr, "Floating-point exception.\n" );
while( *msgPtr ) msgPtr++;
switch( info->si_code )
{
case FPE_INTDIV:
strcpy( msgPtr, "Integer divide by zero.\n" );
break;
case FPE_INTOVF:
strcpy( msgPtr, "Integer overflow.\n" );
break;
case FPE_FLTDIV:
strcpy( msgPtr, "Floating-point divide by zero.\n" );
break;
case FPE_FLTOVF:
strcpy( msgPtr, "Floating-point overflow.\n" );
break;
case FPE_FLTUND:
strcpy( msgPtr, "Floating-point underflow.\n" );
break;
case FPE_FLTRES:
strcpy( msgPtr, "Floating-point inexact result.\n" );
break;
case FPE_FLTINV:
strcpy( msgPtr, "Floating-point invalid operation.\n" );
break;
case FPE_FLTSUB:
strcpy( msgPtr, "Subscript out of range.\n" );
break;
default:
break;
}
break;
case SIGSEGV:
strcpy( msgPtr, "Invalid memory reference.\n" );
while( *msgPtr ) msgPtr++;
switch( info->si_code )
{
case SEGV_MAPERR:
strcpy( msgPtr, "Address not mapped to object.\n" );
break;
case SEGV_ACCERR:
strcpy( msgPtr, "Invalid permissions for mapped object.\n" );
break;
# ifdef SEGV_BNDERR
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case SEGV_BNDERR:
strcpy( msgPtr, "Failed address bound checks.\n" );
break;
# endif
# ifdef SEGV_PKUERR
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case SEGV_PKUERR:
strcpy( msgPtr, "Access was denied by memory protection keys.\n" );
break;
# endif
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default:
break;
}
break;
case SIGPIPE:
strcpy( msgPtr, "Broken pipe.\n" );
while( *msgPtr ) msgPtr++;
break;
case SIGBUS:
strcpy( msgPtr, "Bus error.\n" );
while( *msgPtr ) msgPtr++;
switch( info->si_code )
{
case BUS_ADRALN:
strcpy( msgPtr, "Invalid address alignment.\n" );
break;
case BUS_ADRERR:
strcpy( msgPtr, "Nonexistent physical address.\n" );
break;
case BUS_OBJERR:
strcpy( msgPtr, "Object-specific hardware error.\n" );
break;
case BUS_MCEERR_AR:
strcpy( msgPtr, "Hardware memory error consumed on a machine check; action required.\n" );
break;
case BUS_MCEERR_AO:
strcpy( msgPtr, "Hardware memory error detected in process but not consumed; action optional.\n" );
break;
default:
break;
}
break;
default:
abort();
}
while( *msgPtr ) msgPtr++;
if( signal != SIGPIPE )
{
strcpy( msgPtr, "Fault address: 0x" );
while( *msgPtr ) msgPtr++;
HexPrint( msgPtr, uint64_t( info->si_addr ) );
*msgPtr++ = '\n';
}
{
const auto thread = GetThreadHandle();
Magic magic;
auto& token = s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::CrashReport );
item->crashReport.time = Profiler::GetTime();
item->crashReport.thread = thread;
item->crashReport.text = (uint64_t)s_crashText;
tail.store( magic + 1, std::memory_order_release );
s_profiler.SendCallstack( 60, thread, "__kernel_rt_sigreturn" );
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}
DIR* dp = opendir( "/proc/self/task" );
if( !dp ) abort();
const auto selfTid = syscall( SYS_gettid );
struct dirent* ep;
while( ( ep = readdir( dp ) ) != nullptr )
{
if( ep->d_name[0] == '.' ) continue;
int tid = atoi( ep->d_name );
if( tid != selfTid && tid != s_profilerTid )
{
syscall( SYS_tkill, tid, SIGPWR );
}
}
closedir( dp );
{
Magic magic;
auto& token = s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::Crash );
tail.store( magic + 1, std::memory_order_release );
}
std::this_thread::sleep_for( std::chrono::milliseconds( 500 ) );
s_profiler.RequestShutdown();
while( !s_profiler.HasShutdownFinished() ) { std::this_thread::sleep_for( std::chrono::milliseconds( 10 ) ); };
abort();
}
#endif
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enum { QueuePrealloc = 256 * 1024 };
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// MSVC static initialization order solution. gcc/clang uses init_order() to avoid all this.
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static Profiler* s_instance = nullptr;
static Thread* s_thread = nullptr;
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// 1a. But s_queue is needed for initialization of variables in point 2.
extern moodycamel::ConcurrentQueue<QueueItem> s_queue;
static thread_local RPMallocThreadInit init_order(106) s_rpmalloc_thread_init;
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// 2. If these variables would be in the .CRT$XCB section, they would be initialized only in main thread.
static thread_local moodycamel::ProducerToken init_order(107) s_token_detail( s_queue );
thread_local ProducerWrapper init_order(108) s_token { s_queue.get_explicit_producer( s_token_detail ) };
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#ifdef _MSC_VER
// 1. Initialize these static variables before all other variables.
# pragma warning( disable : 4075 )
# pragma init_seg( ".CRT$XCB" )
#endif
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static InitTimeWrapper init_order(101) s_initTime { SetupHwTimer() };
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static RPMallocInit init_order(102) s_rpmalloc_init;
moodycamel::ConcurrentQueue<QueueItem> init_order(103) s_queue( QueuePrealloc );
std::atomic<uint32_t> init_order(104) s_lockCounter( 0 );
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std::atomic<uint8_t> init_order(104) s_gpuCtxCounter( 0 );
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thread_local GpuCtxWrapper init_order(104) s_gpuCtx { nullptr };
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#ifdef TRACY_COLLECT_THREAD_NAMES
struct ThreadNameData;
static std::atomic<ThreadNameData*> init_order(104) s_threadNameDataInstance( nullptr );
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std::atomic<ThreadNameData*>& s_threadNameData = s_threadNameDataInstance;
#endif
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#ifdef TRACY_ON_DEMAND
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thread_local LuaZoneState init_order(104) s_luaZoneState { 0, false };
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#endif
static Profiler init_order(105) s_profilerInstance;
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Profiler& s_profiler = s_profilerInstance;
#ifdef _MSC_VER
# define DLL_EXPORT __declspec(dllexport)
#else
# define DLL_EXPORT __attribute__((visibility("default")))
#endif
// DLL exports to enable TracyClientDLL.cpp to retrieve the instances of Tracy objects and functions
DLL_EXPORT moodycamel::ConcurrentQueue<QueueItem>::ExplicitProducer* get_token()
{
return s_token.ptr;
}
DLL_EXPORT void*(*get_rpmalloc())(size_t size)
{
return rpmalloc;
}
DLL_EXPORT void(*get_rpfree())(void* ptr)
{
return rpfree;
}
#if defined TRACY_HW_TIMER && __ARM_ARCH >= 6
DLL_EXPORT int64_t(*get_GetTimeImpl())()
{
return GetTimeImpl;
}
#endif
DLL_EXPORT Profiler& get_profiler()
{
return s_profiler;
}
#ifdef TRACY_COLLECT_THREAD_NAMES
DLL_EXPORT std::atomic<ThreadNameData*>& get_threadNameData()
{
return s_threadNameData;
}
DLL_EXPORT void(*get_rpmalloc_thread_initialize())()
{
return rpmalloc_thread_initialize;
}
#endif
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enum { BulkSize = TargetFrameSize / QueueItemSize };
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Profiler::Profiler()
: m_timeBegin( 0 )
, m_mainThread( GetThreadHandle() )
, m_epoch( std::chrono::duration_cast<std::chrono::seconds>( std::chrono::system_clock::now().time_since_epoch() ).count() )
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, m_shutdown( false )
, m_shutdownManual( false )
, m_shutdownFinished( false )
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, m_sock( nullptr )
, m_noExit( false )
, m_zoneId( 1 )
, m_stream( LZ4_createStream() )
, m_buffer( (char*)tracy_malloc( TargetFrameSize*3 ) )
, m_bufferOffset( 0 )
, m_bufferStart( 0 )
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, m_itemBuf( (QueueItem*)tracy_malloc( sizeof( QueueItem ) * BulkSize ) )
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, m_lz4Buf( (char*)tracy_malloc( LZ4Size + sizeof( lz4sz_t ) ) )
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, m_serialQueue( 1024*1024 )
, m_serialDequeue( 1024*1024 )
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#ifdef TRACY_ON_DEMAND
, m_isConnected( false )
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, m_frameCount( 0 )
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, m_deferredQueue( 64*1024 )
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#endif
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{
assert( !s_instance );
s_instance = this;
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#ifdef _MSC_VER
// 3. But these variables need to be initialized in main thread within the .CRT$XCB section. Do it here.
s_token_detail = moodycamel::ProducerToken( s_queue );
s_token = ProducerWrapper { s_queue.get_explicit_producer( s_token_detail ) };
#endif
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CalibrateTimer();
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CalibrateDelay();
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#ifndef TRACY_NO_EXIT
const char* noExitEnv = getenv( "TRACY_NO_EXIT" );
if( noExitEnv && noExitEnv[0] == '1' )
{
m_noExit = true;
}
#endif
s_thread = (Thread*)tracy_malloc( sizeof( Thread ) );
new(s_thread) Thread( LaunchWorker, this );
SetThreadName( s_thread->Handle(), "Tracy Profiler" );
#ifdef _MSC_VER
s_profilerThreadId = GetThreadId( s_thread->Handle() );
AddVectoredExceptionHandler( 1, CrashFilter );
#endif
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#ifdef __linux__
struct sigaction threadFreezer = {};
threadFreezer.sa_handler = ThreadFreezer;
sigaction( SIGPWR, &threadFreezer, nullptr );
struct sigaction crashHandler = {};
crashHandler.sa_sigaction = CrashHandler;
crashHandler.sa_flags = SA_SIGINFO;
sigaction( SIGILL, &crashHandler, nullptr );
sigaction( SIGFPE, &crashHandler, nullptr );
sigaction( SIGSEGV, &crashHandler, nullptr );
sigaction( SIGPIPE, &crashHandler, nullptr );
sigaction( SIGBUS, &crashHandler, nullptr );
#endif
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#ifdef TRACY_HAS_CALLSTACK
InitCallstack();
#endif
m_timeBegin.store( GetTime(), std::memory_order_relaxed );
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}
Profiler::~Profiler()
{
m_shutdown.store( true, std::memory_order_relaxed );
s_thread->~Thread();
tracy_free( s_thread );
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tracy_free( m_lz4Buf );
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tracy_free( m_itemBuf );
tracy_free( m_buffer );
LZ4_freeStream( m_stream );
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if( m_sock )
{
m_sock->~Socket();
tracy_free( m_sock );
}
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assert( s_instance );
s_instance = nullptr;
}
bool Profiler::ShouldExit()
{
return s_instance->m_shutdown.load( std::memory_order_relaxed );
}
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void Profiler::Worker()
{
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#ifdef __linux__
s_profilerTid = syscall( SYS_gettid );
#endif
rpmalloc_thread_initialize();
const auto procname = GetProcessName();
const auto pnsz = std::min<size_t>( strlen( procname ), WelcomeMessageProgramNameSize - 1 );
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const auto hostinfo = GetHostInfo();
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const auto hisz = std::min<size_t>( strlen( hostinfo ), WelcomeMessageHostInfoSize - 1 );
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while( m_timeBegin.load( std::memory_order_relaxed ) == 0 ) std::this_thread::sleep_for( std::chrono::milliseconds( 10 ) );
#ifdef TRACY_ON_DEMAND
uint8_t onDemand = 1;
#else
uint8_t onDemand = 0;
#endif
WelcomeMessage welcome;
MemWrite( &welcome.timerMul, m_timerMul );
MemWrite( &welcome.initBegin, s_initTime.val );
MemWrite( &welcome.initEnd, m_timeBegin.load( std::memory_order_relaxed ) );
MemWrite( &welcome.delay, m_delay );
MemWrite( &welcome.resolution, m_resolution );
MemWrite( &welcome.epoch, m_epoch );
MemWrite( &welcome.onDemand, onDemand );
memcpy( welcome.programName, procname, pnsz );
memset( welcome.programName + pnsz, 0, WelcomeMessageProgramNameSize - pnsz );
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memcpy( welcome.hostInfo, hostinfo, hisz );
memset( welcome.hostInfo + hisz, 0, WelcomeMessageHostInfoSize - hisz );
moodycamel::ConsumerToken token( s_queue );
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ListenSocket listen;
if( !listen.Listen( "8086", 8 ) )
{
for(;;)
{
if( ShouldExit() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
ClearQueues( token );
}
}
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for(;;)
{
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for(;;)
{
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#ifndef TRACY_NO_EXIT
if( !m_noExit && ShouldExit() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
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#endif
m_sock = listen.Accept();
if( m_sock ) break;
}
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{
timeval tv;
tv.tv_sec = 2;
tv.tv_usec = 0;
char shibboleth[HandshakeShibbolethSize];
auto res = m_sock->ReadRaw( shibboleth, HandshakeShibbolethSize, &tv );
if( !res || memcmp( shibboleth, HandshakeShibboleth, HandshakeShibbolethSize ) != 0 )
{
m_sock->~Socket();
tracy_free( m_sock );
continue;
}
uint32_t protocolVersion;
res = m_sock->ReadRaw( &protocolVersion, sizeof( protocolVersion ), &tv );
if( !res )
{
m_sock->~Socket();
tracy_free( m_sock );
continue;
}
if( protocolVersion != ProtocolVersion )
{
HandshakeStatus status = HandshakeProtocolMismatch;
m_sock->Send( &status, sizeof( status ) );
m_sock->~Socket();
tracy_free( m_sock );
continue;
}
}
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#ifdef TRACY_ON_DEMAND
ClearQueues( token );
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m_isConnected.store( true, std::memory_order_relaxed );
#endif
HandshakeStatus handshake = HandshakeWelcome;
m_sock->Send( &handshake, sizeof( handshake ) );
LZ4_resetStream( m_stream );
m_sock->Send( &welcome, sizeof( welcome ) );
#ifdef TRACY_ON_DEMAND
OnDemandPayloadMessage onDemand;
onDemand.frames = m_frameCount.load( std::memory_order_relaxed );
m_sock->Send( &onDemand, sizeof( onDemand ) );
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m_deferredLock.lock();
for( auto& item : m_deferredQueue )
{
const auto idx = MemRead<uint8_t>( &item.hdr.idx );
AppendData( &item, QueueDataSize[idx] );
}
m_deferredLock.unlock();
#endif
int keepAlive = 0;
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for(;;)
{
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const auto status = Dequeue( token );
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const auto serialStatus = DequeueSerial();
if( status == ConnectionLost || serialStatus == ConnectionLost )
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{
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break;
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}
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else if( status == QueueEmpty && serialStatus == QueueEmpty )
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{
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if( ShouldExit() ) break;
if( m_bufferOffset != m_bufferStart )
{
if( !CommitData() ) break;
}
if( keepAlive == 500 )
{
QueueItem ka;
ka.hdr.type = QueueType::KeepAlive;
AppendData( &ka, QueueDataSize[ka.hdr.idx] );
if( !CommitData() ) break;
keepAlive = 0;
}
else
{
keepAlive++;
std::this_thread::sleep_for( std::chrono::milliseconds( 10 ) );
}
}
else
{
keepAlive = 0;
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}
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while( m_sock->HasData() )
{
if( !HandleServerQuery() ) break;
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}
}
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if( ShouldExit() ) break;
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#ifdef TRACY_ON_DEMAND
m_isConnected.store( false, std::memory_order_relaxed );
#endif
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m_sock->~Socket();
tracy_free( m_sock );
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#ifndef TRACY_ON_DEMAND
// Client is no longer available here
for(;;)
{
if( ShouldExit() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
2018-12-21 17:12:26 +00:00
ClearQueues( token );
m_sock = listen.Accept();
if( m_sock )
{
timeval tv;
tv.tv_sec = 1;
tv.tv_usec = 0;
char shibboleth[HandshakeShibbolethSize];
auto res = m_sock->ReadRaw( shibboleth, HandshakeShibbolethSize, &tv );
if( !res || memcmp( shibboleth, HandshakeShibboleth, HandshakeShibbolethSize ) != 0 )
{
m_sock->~Socket();
tracy_free( m_sock );
continue;
}
uint32_t protocolVersion;
res = m_sock->ReadRaw( &protocolVersion, sizeof( protocolVersion ), &tv );
if( !res )
{
m_sock->~Socket();
tracy_free( m_sock );
continue;
}
HandshakeStatus status = HandshakeNotAvailable;
m_sock->Send( &status, sizeof( status ) );
m_sock->~Socket();
tracy_free( m_sock );
}
}
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#endif
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}
for(;;)
{
const auto status = Dequeue( token );
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const auto serialStatus = DequeueSerial();
if( status == ConnectionLost || serialStatus == ConnectionLost )
{
break;
}
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else if( status == QueueEmpty && serialStatus == QueueEmpty )
{
if( m_bufferOffset != m_bufferStart ) CommitData();
break;
}
while( m_sock->HasData() )
{
if( !HandleServerQuery() ) break;
}
}
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QueueItem terminate;
MemWrite( &terminate.hdr.type, QueueType::Terminate );
if( !SendData( (const char*)&terminate, 1 ) )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
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for(;;)
{
if( m_sock->HasData() )
{
while( m_sock->HasData() )
{
if( !HandleServerQuery() )
{
if( m_bufferOffset != m_bufferStart ) CommitData();
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
}
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while( Dequeue( token ) == Success ) {}
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while( DequeueSerial() == Success ) {}
if( m_bufferOffset != m_bufferStart )
{
if( !CommitData() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
}
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}
else
{
if( m_bufferOffset != m_bufferStart ) CommitData();
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std::this_thread::sleep_for( std::chrono::milliseconds( 10 ) );
}
}
}
static void FreeAssociatedMemory( const QueueItem& item )
{
if( item.hdr.idx >= (int)QueueType::Terminate ) return;
uint64_t ptr;
switch( item.hdr.type )
{
case QueueType::ZoneText:
case QueueType::ZoneName:
ptr = MemRead<uint64_t>( &item.zoneText.text );
tracy_free( (void*)ptr );
break;
case QueueType::Message:
ptr = MemRead<uint64_t>( &item.message.text );
tracy_free( (void*)ptr );
break;
case QueueType::ZoneBeginAllocSrcLoc:
ptr = MemRead<uint64_t>( &item.zoneBegin.srcloc );
tracy_free( (void*)ptr );
break;
case QueueType::CallstackMemory:
ptr = MemRead<uint64_t>( &item.callstackMemory.ptr );
tracy_free( (void*)ptr );
break;
case QueueType::Callstack:
ptr = MemRead<uint64_t>( &item.callstack.ptr );
tracy_free( (void*)ptr );
break;
default:
assert( false );
break;
}
}
void Profiler::ClearQueues( moodycamel::ConsumerToken& token )
{
for(;;)
{
const auto sz = s_queue.try_dequeue_bulk( token, m_itemBuf, BulkSize );
if( sz == 0 ) break;
for( size_t i=0; i<sz; i++ ) FreeAssociatedMemory( m_itemBuf[i] );
}
{
bool lockHeld = true;
while( !m_serialLock.try_lock() )
{
if( m_shutdownManual.load( std::memory_order_relaxed ) )
{
lockHeld = false;
break;
}
}
for( auto& v : m_serialQueue ) FreeAssociatedMemory( v );
m_serialQueue.clear();
if( lockHeld )
{
m_serialLock.unlock();
}
}
for( auto& v : m_serialDequeue ) FreeAssociatedMemory( v );
m_serialDequeue.clear();
}
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Profiler::DequeueStatus Profiler::Dequeue( moodycamel::ConsumerToken& token )
{
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const auto sz = s_queue.try_dequeue_bulk( token, m_itemBuf, BulkSize );
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if( sz > 0 )
{
auto end = m_itemBuf + sz;
auto item = m_itemBuf;
while( item != end )
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{
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uint64_t ptr;
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const auto idx = MemRead<uint8_t>( &item->hdr.idx );
if( idx < (int)QueueType::Terminate )
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{
switch( (QueueType)idx )
{
case QueueType::ZoneText:
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case QueueType::ZoneName:
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ptr = MemRead<uint64_t>( &item->zoneText.text );
SendString( ptr, (const char*)ptr, QueueType::CustomStringData );
tracy_free( (void*)ptr );
break;
case QueueType::Message:
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ptr = MemRead<uint64_t>( &item->message.text );
SendString( ptr, (const char*)ptr, QueueType::CustomStringData );
tracy_free( (void*)ptr );
break;
case QueueType::ZoneBeginAllocSrcLoc:
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ptr = MemRead<uint64_t>( &item->zoneBegin.srcloc );
SendSourceLocationPayload( ptr );
tracy_free( (void*)ptr );
break;
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case QueueType::Callstack:
ptr = MemRead<uint64_t>( &item->callstack.ptr );
SendCallstackPayload( ptr );
tracy_free( (void*)ptr );
break;
default:
assert( false );
break;
}
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}
if( !AppendData( item, QueueDataSize[idx] ) ) return ConnectionLost;
item++;
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}
}
else
{
return QueueEmpty;
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}
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return Success;
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}
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Profiler::DequeueStatus Profiler::DequeueSerial()
{
{
bool lockHeld = true;
while( !m_serialLock.try_lock() )
{
if( m_shutdownManual.load( std::memory_order_relaxed ) )
{
lockHeld = false;
break;
}
}
m_serialQueue.swap( m_serialDequeue );
if( lockHeld )
{
m_serialLock.unlock();
}
}
const auto sz = m_serialDequeue.size();
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if( sz > 0 )
{
auto item = m_serialDequeue.data();
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auto end = item + sz;
while( item != end )
{
uint64_t ptr;
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const auto idx = MemRead<uint8_t>( &item->hdr.idx );
if( idx < (int)QueueType::Terminate )
{
switch( (QueueType)idx )
{
case QueueType::CallstackMemory:
ptr = MemRead<uint64_t>( &item->callstackMemory.ptr );
SendCallstackPayload( ptr );
tracy_free( (void*)ptr );
break;
default:
assert( false );
break;
}
}
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if( !AppendData( item, QueueDataSize[idx] ) ) return ConnectionLost;
item++;
}
m_serialDequeue.clear();
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}
else
{
return QueueEmpty;
}
return Success;
}
bool Profiler::AppendData( const void* data, size_t len )
{
auto ret = true;
ret = NeedDataSize( len );
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AppendDataUnsafe( data, len );
return ret;
}
bool Profiler::CommitData()
{
bool ret = SendData( m_buffer + m_bufferStart, m_bufferOffset - m_bufferStart );
if( m_bufferOffset > TargetFrameSize * 2 ) m_bufferOffset = 0;
m_bufferStart = m_bufferOffset;
return ret;
}
bool Profiler::NeedDataSize( size_t len )
{
bool ret = true;
if( m_bufferOffset - m_bufferStart + len > TargetFrameSize )
{
ret = CommitData();
}
return ret;
}
bool Profiler::SendData( const char* data, size_t len )
{
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const lz4sz_t lz4sz = LZ4_compress_fast_continue( m_stream, data, m_lz4Buf + sizeof( lz4sz_t ), (int)len, LZ4Size, 1 );
memcpy( m_lz4Buf, &lz4sz, sizeof( lz4sz ) );
return m_sock->Send( m_lz4Buf, lz4sz + sizeof( lz4sz_t ) ) != -1;
}
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void Profiler::SendString( uint64_t str, const char* ptr, QueueType type )
{
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assert( type == QueueType::StringData || type == QueueType::ThreadName || type == QueueType::CustomStringData || type == QueueType::PlotName || type == QueueType::FrameName );
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QueueItem item;
MemWrite( &item.hdr.type, type );
MemWrite( &item.stringTransfer.ptr, str );
auto len = strlen( ptr );
assert( len <= std::numeric_limits<uint16_t>::max() );
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auto l16 = uint16_t( len );
NeedDataSize( QueueDataSize[(int)type] + sizeof( l16 ) + l16 );
AppendDataUnsafe( &item, QueueDataSize[(int)type] );
AppendDataUnsafe( &l16, sizeof( l16 ) );
AppendDataUnsafe( ptr, l16 );
}
void Profiler::SendSourceLocation( uint64_t ptr )
{
auto srcloc = (const SourceLocationData*)ptr;
QueueItem item;
MemWrite( &item.hdr.type, QueueType::SourceLocation );
MemWrite( &item.srcloc.name, (uint64_t)srcloc->name );
MemWrite( &item.srcloc.file, (uint64_t)srcloc->file );
MemWrite( &item.srcloc.function, (uint64_t)srcloc->function );
MemWrite( &item.srcloc.line, srcloc->line );
MemWrite( &item.srcloc.r, uint8_t( ( srcloc->color ) & 0xFF ) );
MemWrite( &item.srcloc.g, uint8_t( ( srcloc->color >> 8 ) & 0xFF ) );
MemWrite( &item.srcloc.b, uint8_t( ( srcloc->color >> 16 ) & 0xFF ) );
AppendData( &item, QueueDataSize[(int)QueueType::SourceLocation] );
}
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void Profiler::SendSourceLocationPayload( uint64_t _ptr )
{
auto ptr = (const char*)_ptr;
QueueItem item;
MemWrite( &item.hdr.type, QueueType::SourceLocationPayload );
MemWrite( &item.stringTransfer.ptr, _ptr );
const auto len = *((uint32_t*)ptr);
assert( len <= std::numeric_limits<uint16_t>::max() );
assert( len > 4 );
const auto l16 = uint16_t( len - 4 );
NeedDataSize( QueueDataSize[(int)QueueType::SourceLocationPayload] + sizeof( l16 ) + l16 );
AppendDataUnsafe( &item, QueueDataSize[(int)QueueType::SourceLocationPayload] );
AppendDataUnsafe( &l16, sizeof( l16 ) );
AppendDataUnsafe( ptr + 4, l16 );
}
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void Profiler::SendCallstackPayload( uint64_t _ptr )
{
auto ptr = (uintptr_t*)_ptr;
QueueItem item;
MemWrite( &item.hdr.type, QueueType::CallstackPayload );
MemWrite( &item.stringTransfer.ptr, _ptr );
const auto sz = *ptr++;
const auto len = sz * sizeof( uint64_t );
const auto l16 = uint16_t( len );
NeedDataSize( QueueDataSize[(int)QueueType::CallstackPayload] + sizeof( l16 ) + l16 );
AppendDataUnsafe( &item, QueueDataSize[(int)QueueType::CallstackPayload] );
AppendDataUnsafe( &l16, sizeof( l16 ) );
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if( compile_time_condition<sizeof( uintptr_t ) == sizeof( uint64_t )>::value )
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{
AppendDataUnsafe( ptr, sizeof( uint64_t ) * sz );
}
else
{
for( uintptr_t i=0; i<sz; i++ )
{
const auto val = uint64_t( *ptr++ );
AppendDataUnsafe( &val, sizeof( uint64_t ) );
}
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}
}
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void Profiler::SendCallstackFrame( uint64_t ptr )
{
#ifdef TRACY_HAS_CALLSTACK
auto frame = DecodeCallstackPtr( ptr );
SendString( uint64_t( frame.name ), frame.name, QueueType::CustomStringData );
SendString( uint64_t( frame.file ), frame.file, QueueType::CustomStringData );
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QueueItem item;
MemWrite( &item.hdr.type, QueueType::CallstackFrame );
MemWrite( &item.callstackFrame.ptr, ptr );
MemWrite( &item.callstackFrame.name, (uint64_t)frame.name );
MemWrite( &item.callstackFrame.file, (uint64_t)frame.file );
MemWrite( &item.callstackFrame.line, frame.line );
AppendData( &item, QueueDataSize[(int)QueueType::CallstackFrame] );
tracy_free( (void*)frame.name );
tracy_free( (void*)frame.file );
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#endif
}
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static bool DontExit() { return false; }
bool Profiler::HandleServerQuery()
{
timeval tv;
tv.tv_sec = 0;
tv.tv_usec = 10000;
uint8_t type;
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if( !m_sock->Read( &type, sizeof( type ), &tv, DontExit ) ) return false;
uint64_t ptr;
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if( !m_sock->Read( &ptr, sizeof( ptr ), &tv, DontExit ) ) return false;
switch( type )
{
case ServerQueryString:
SendString( ptr, (const char*)ptr, QueueType::StringData );
break;
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case ServerQueryThreadString:
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if( ptr == m_mainThread )
{
SendString( ptr, "Main thread", QueueType::ThreadName );
}
else
{
SendString( ptr, GetThreadName( ptr ), QueueType::ThreadName );
}
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break;
case ServerQuerySourceLocation:
SendSourceLocation( ptr );
break;
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case ServerQueryPlotName:
SendString( ptr, (const char*)ptr, QueueType::PlotName );
break;
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case ServerQueryTerminate:
return false;
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case ServerQueryCallstackFrame:
SendCallstackFrame( ptr );
break;
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case ServerQueryFrameName:
SendString( ptr, (const char*)ptr, QueueType::FrameName );
break;
default:
assert( false );
break;
}
return true;
}
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void Profiler::CalibrateTimer()
{
#ifdef TRACY_HW_TIMER
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# if __ARM_ARCH >= 6
if( GetTimeImpl == GetTimeImplFallback )
{
m_timerMul = 1.;
return;
}
# endif
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std::atomic_signal_fence( std::memory_order_acq_rel );
const auto t0 = std::chrono::high_resolution_clock::now();
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const auto r0 = GetTime();
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std::atomic_signal_fence( std::memory_order_acq_rel );
std::this_thread::sleep_for( std::chrono::milliseconds( 200 ) );
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std::atomic_signal_fence( std::memory_order_acq_rel );
const auto t1 = std::chrono::high_resolution_clock::now();
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const auto r1 = GetTime();
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std::atomic_signal_fence( std::memory_order_acq_rel );
const auto dt = std::chrono::duration_cast<std::chrono::nanoseconds>( t1 - t0 ).count();
const auto dr = r1 - r0;
m_timerMul = double( dt ) / double( dr );
#else
m_timerMul = 1.;
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#endif
}
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class FakeZone
{
public:
FakeZone( const SourceLocationData* srcloc ) : m_id( (uint64_t)srcloc ) {}
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~FakeZone() {}
private:
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volatile uint64_t m_id;
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};
void Profiler::CalibrateDelay()
{
enum { Iterations = 50000 };
enum { Events = Iterations * 2 }; // start + end
static_assert( Events * 2 < QueuePrealloc, "Delay calibration loop will allocate memory in queue" );
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moodycamel::ProducerToken ptoken_detail( s_queue );
moodycamel::ConcurrentQueue<QueueItem>::ExplicitProducer* ptoken = s_queue.get_explicit_producer( ptoken_detail );
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for( int i=0; i<Iterations; i++ )
{
static const tracy::SourceLocationData __tracy_source_location { nullptr, __FUNCTION__, __FILE__, (uint32_t)__LINE__, 0 };
{
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Magic magic;
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auto& tail = ptoken->get_tail_index();
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auto item = ptoken->enqueue_begin<moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::ZoneBegin );
MemWrite( &item->zoneBegin.thread, GetThreadHandle() );
#ifdef TRACY_RDTSCP_OPT
MemWrite( &item->zoneBegin.time, Profiler::GetTime( item->zoneBegin.cpu ) );
#else
uint32_t cpu;
MemWrite( &item->zoneBegin.time, Profiler::GetTime( cpu ) );
MemWrite( &item->zoneBegin.cpu, cpu );
#endif
MemWrite( &item->zoneBegin.srcloc, (uint64_t)&__tracy_source_location );
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tail.store( magic + 1, std::memory_order_release );
}
{
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Magic magic;
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auto& tail = ptoken->get_tail_index();
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auto item = ptoken->enqueue_begin<moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::ZoneEnd );
MemWrite( &item->zoneEnd.thread, uint64_t( 0 ) );
#ifdef TRACY_RDTSCP_OPT
MemWrite( &item->zoneEnd.time, GetTime( item->zoneEnd.cpu ) );
#else
uint32_t cpu;
MemWrite( &item->zoneEnd.time, GetTime( cpu ) );
MemWrite( &item->zoneEnd.cpu, cpu );
#endif
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tail.store( magic + 1, std::memory_order_release );
}
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}
const auto f0 = GetTime();
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for( int i=0; i<Iterations; i++ )
{
static const tracy::SourceLocationData __tracy_source_location { nullptr, __FUNCTION__, __FILE__, (uint32_t)__LINE__, 0 };
FakeZone ___tracy_scoped_zone( &__tracy_source_location );
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}
const auto t0 = GetTime();
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for( int i=0; i<Iterations; i++ )
{
static const tracy::SourceLocationData __tracy_source_location { nullptr, __FUNCTION__, __FILE__, (uint32_t)__LINE__, 0 };
{
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Magic magic;
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auto& tail = ptoken->get_tail_index();
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auto item = ptoken->enqueue_begin<moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::ZoneBegin );
MemWrite( &item->zoneBegin.thread, GetThreadHandle() );
#ifdef TRACY_RDTSCP_OPT
MemWrite( &item->zoneBegin.time, Profiler::GetTime( item->zoneBegin.cpu ) );
#else
uint32_t cpu;
MemWrite( &item->zoneBegin.time, Profiler::GetTime( cpu ) );
MemWrite( &item->zoneBegin.cpu, cpu );
#endif
MemWrite( &item->zoneBegin.srcloc, (uint64_t)&__tracy_source_location );
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tail.store( magic + 1, std::memory_order_release );
}
{
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Magic magic;
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auto& tail = ptoken->get_tail_index();
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auto item = ptoken->enqueue_begin<moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::ZoneEnd );
MemWrite( &item->zoneEnd.thread, uint64_t( 0 ) );
#ifdef TRACY_RDTSCP_OPT
MemWrite( &item->zoneEnd.time, GetTime( item->zoneEnd.cpu ) );
#else
uint32_t cpu;
MemWrite( &item->zoneEnd.time, GetTime( cpu ) );
MemWrite( &item->zoneEnd.cpu, cpu );
#endif
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tail.store( magic + 1, std::memory_order_release );
}
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}
const auto t1 = GetTime();
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const auto dt = t1 - t0;
const auto df = t0 - f0;
m_delay = ( dt - df ) / Events;
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auto mindiff = std::numeric_limits<int64_t>::max();
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for( int i=0; i<Iterations * 10; i++ )
{
const auto t0i = GetTime();
const auto t1i = GetTime();
const auto dti = t1i - t0i;
if( dti > 0 && dti < mindiff ) mindiff = dti;
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}
m_resolution = mindiff;
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enum { Bulk = 1000 };
moodycamel::ConsumerToken token( s_queue );
int left = Events * 2;
QueueItem item[Bulk];
while( left != 0 )
{
const auto sz = s_queue.try_dequeue_bulk( token, item, std::min( left, (int)Bulk ) );
assert( sz > 0 );
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left -= (int)sz;
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}
}
void Profiler::SendCallstack( int depth, uint64_t thread, const char* skipBefore )
{
#ifdef TRACY_HAS_CALLSTACK
auto ptr = Callstack( depth );
auto data = (uintptr_t*)ptr;
const auto sz = *data++;
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uintptr_t i;
for( i=0; i<sz; i++ )
{
auto frame = DecodeCallstackPtr( uint64_t( data[i] ) );
const bool found = strcmp( frame.name, skipBefore ) == 0;
tracy_free( (void*)frame.name );
tracy_free( (void*)frame.file );
if( found )
{
i++;
break;
}
}
if( i != sz )
{
memmove( data, data + i, ( sz - i ) * sizeof( uintptr_t* ) );
*--data = sz - i;
}
Magic magic;
auto& token = s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
MemWrite( &item->hdr.type, QueueType::Callstack );
MemWrite( &item->callstack.ptr, ptr );
MemWrite( &item->callstack.thread, thread );
tail.store( magic + 1, std::memory_order_release );
#endif
}
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}
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#ifdef __cplusplus
extern "C" {
#endif
TracyCZoneCtx ___tracy_emit_zone_begin( const struct ___tracy_source_location_data* srcloc, int active )
{
___tracy_c_zone_context ctx;
#ifdef TRACY_ON_DEMAND
ctx.active = active && tracy::s_profiler.IsConnected();
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#else
ctx.active = active;
#endif
if( !ctx.active ) return ctx;
tracy::Magic magic;
auto& token = tracy::s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
tracy::MemWrite( &item->hdr.type, tracy::QueueType::ZoneBegin );
#ifdef TRACY_RDTSCP_OPT
tracy::MemWrite( &item->zoneBegin.time, tracy::Profiler::GetTime( item->zoneBegin.cpu ) );
#else
uint32_t cpu;
tracy::MemWrite( &item->zoneBegin.time, tracy::Profiler::GetTime( cpu ) );
tracy::MemWrite( &item->zoneBegin.cpu, cpu );
#endif
tracy::MemWrite( &item->zoneBegin.thread, tracy::GetThreadHandle() );
tracy::MemWrite( &item->zoneBegin.srcloc, (uint64_t)srcloc );
tail.store( magic + 1, std::memory_order_release );
return ctx;
}
TracyCZoneCtx ___tracy_emit_zone_begin_callstack( const struct ___tracy_source_location_data* srcloc, int depth, int active )
{
___tracy_c_zone_context ctx;
#ifdef TRACY_ON_DEMAND
ctx.active = active && tracy::s_profiler.IsConnected();
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#else
ctx.active = active;
#endif
if( !ctx.active ) return ctx;
const auto thread = tracy::GetThreadHandle();
tracy::Magic magic;
auto& token = tracy::s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
tracy::MemWrite( &item->hdr.type, tracy::QueueType::ZoneBeginCallstack );
#ifdef TRACY_RDTSCP_OPT
tracy::MemWrite( &item->zoneBegin.time, tracy::Profiler::GetTime( item->zoneBegin.cpu ) );
#else
uint32_t cpu;
tracy::MemWrite( &item->zoneBegin.time, tracy::Profiler::GetTime( cpu ) );
tracy::MemWrite( &item->zoneBegin.cpu, cpu );
#endif
tracy::MemWrite( &item->zoneBegin.thread, thread );
tracy::MemWrite( &item->zoneBegin.srcloc, (uint64_t)srcloc );
tail.store( magic + 1, std::memory_order_release );
tracy::s_profiler.SendCallstack( depth, thread );
return ctx;
}
void ___tracy_emit_zone_end( TracyCZoneCtx ctx )
{
if( !ctx.active ) return;
tracy::Magic magic;
auto& token = tracy::s_token.ptr;
auto& tail = token->get_tail_index();
auto item = token->enqueue_begin<tracy::moodycamel::CanAlloc>( magic );
tracy::MemWrite( &item->hdr.type, tracy::QueueType::ZoneEnd );
#ifdef TRACY_RDTSCP_OPT
tracy::MemWrite( &item->zoneEnd.time, tracy::Profiler::GetTime( item->zoneEnd.cpu ) );
#else
uint32_t cpu;
tracy::MemWrite( &item->zoneEnd.time, tracy::Profiler::GetTime( cpu ) );
tracy::MemWrite( &item->zoneEnd.cpu, cpu );
#endif
tracy::MemWrite( &item->zoneEnd.thread, tracy::GetThreadHandle() );
tail.store( magic + 1, std::memory_order_release );
}
#ifdef __cplusplus
}
#endif
#endif