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tracy/client/TracyProfiler.cpp
Bartosz Taudul 401ebd6f3d Use spin-lock in DequeueSerial. 
A thread freezed during crash processing may hold the lock and never
release it. The old behavior would cause deadlock in such situation. The
new one can be modified to work. Also, we don't want to use timed mutex.
2018-08-20 21:40:13 +02:00

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#ifdef TRACY_ENABLE
#ifdef _MSC_VER
# include <winsock2.h>
# include <windows.h>
# include <tlhelp32.h>
#else
# include <sys/time.h>
#endif
#ifdef __CYGWIN__
# include <windows.h>
#endif
#ifdef _GNU_SOURCE
# include <errno.h>
#endif
#ifdef __linux__
# include <signal.h>
# include <dirent.h>
# include <sys/types.h>
# include <sys/syscall.h>
#endif
#include <atomic>
#include <assert.h>
#include <chrono>
#include <limits>
#include <memory>
#include <mutex>
#include <stdlib.h>
#include <string.h>
#include "../common/TracyAlign.hpp"
#include "../common/TracyProtocol.hpp"
#include "../common/TracySocket.hpp"
#include "../common/TracySystem.hpp"
#include "tracy_rpmalloc.hpp"
#include "TracyCallstack.hpp"
#include "TracyScoped.hpp"
#include "TracyProfiler.hpp"
#include "TracyThread.hpp"
#ifdef __GNUC__
#define init_order( val ) __attribute__ ((init_priority(val)))
#else
#define init_order(x)
#endif
#if defined TRACY_HW_TIMER && __ARM_ARCH >= 6
# include <signal.h>
# include <setjmp.h>
#endif
#if defined _MSC_VER || defined __CYGWIN__
# include <lmcons.h>
extern "C" typedef LONG (WINAPI *t_RtlGetVersion)( PRTL_OSVERSIONINFOW );
#else
# include <unistd.h>
# include <limits.h>
#endif
#if defined __APPLE__
# include "TargetConditionals.h"
#endif
#if defined __linux__
# include <sys/sysinfo.h>
# include <sys/utsname.h>
#endif
namespace tracy
{
struct RPMallocInit
{
RPMallocInit() { rpmalloc_initialize(); }
};
struct RPMallocThreadInit
{
RPMallocThreadInit() { rpmalloc_thread_initialize(); }
};
struct InitTimeWrapper
{
int64_t val;
};
#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 );
}
static void SetupHwTimerSigIllHandler( int /*signum*/ )
{
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
static const char* GetProcessName()
{
const char* processName = "unknown";
#if defined _MSC_VER
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;
#elif defined __ANDROID__
# if __ANDROID_API__ >= 21
auto buf = getprogname();
if( buf ) processName = buf;
# endif
#elif defined _GNU_SOURCE || defined __CYGWIN__
processName = program_invocation_short_name;
#endif
return processName;
}
static const char* GetHostInfo()
{
static char buf[1024];
auto ptr = buf;
#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
}
#elif defined __linux__
struct utsname utsName;
uname( &utsName );
# if defined __ANDROID__
ptr += sprintf( ptr, "OS: Linux %s (Android)\n", utsName.release );
# else
ptr += sprintf( ptr, "OS: Linux %s\n", utsName.release );
# 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[HOST_NAME_MAX];
char user[LOGIN_NAME_MAX];
gethostname( hostname, HOST_NAME_MAX );
getlogin_r( user, LOGIN_NAME_MAX );
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;
for( uint32_t i=0x80000002; i<0x80000005; ++i )
{
# 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 );
ptr += sprintf( ptr, "RAM: %i MB\n", statex.ullTotalPhys / 1024 / 1024 );
#elif defined __linux__
struct sysinfo sysInfo;
sysinfo( &sysInfo );
ptr += sprintf( ptr, "RAM: %lu MB\n", sysInfo.totalram / 1024 / 1024 );
#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:
msgPtr += sprintf( msgPtr, "Read violation at address 0x%p.", pExp->ExceptionRecord->ExceptionInformation[1] );
break;
case 1:
msgPtr += sprintf( msgPtr, "Write violation at address 0x%p.", pExp->ExceptionRecord->ExceptionInformation[1] );
break;
case 8:
msgPtr += sprintf( msgPtr, "DEP violation at address 0x%p.", 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;
}
{
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 );
}
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
#ifdef __linux__
static long s_profilerTid = 0;
static char s_crashText[1024];
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 )
{
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;
case SEGV_BNDERR:
strcpy( msgPtr, "Failed address bound checks.\n" );
break;
case SEGV_PKUERR:
strcpy( msgPtr, "Access was denied by memory protection keys.\n" );
break;
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 );
}
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
enum { QueuePrealloc = 256 * 1024 };
// MSVC static initialization order solution. gcc/clang uses init_order() to avoid all this.
static Profiler* s_instance = nullptr;
static Thread* s_thread = nullptr;
// 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;
// 2. If these variables would be in the .CRT$XCB section, they would be initialized only in main thread.
static thread_local moodycamel::ProducerToken init_order(107) s_token_detail( s_queue );
thread_local ProducerWrapper init_order(108) s_token { s_queue.get_explicit_producer( s_token_detail ) };
#ifdef _MSC_VER
// 1. Initialize these static variables before all other variables.
# pragma warning( disable : 4075 )
# pragma init_seg( ".CRT$XCB" )
#endif
static InitTimeWrapper init_order(101) s_initTime { SetupHwTimer() };
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 );
std::atomic<uint8_t> init_order(104) s_gpuCtxCounter( 0 );
thread_local GpuCtxWrapper init_order(104) s_gpuCtx { nullptr };
VkCtxWrapper init_order(104) s_vkCtx { nullptr };
#ifdef TRACY_COLLECT_THREAD_NAMES
struct ThreadNameData;
static std::atomic<ThreadNameData*> init_order(104) s_threadNameDataInstance( nullptr );
std::atomic<ThreadNameData*>& s_threadNameData = s_threadNameDataInstance;
#endif
#ifdef TRACY_ON_DEMAND
thread_local LuaZoneState init_order(104) s_luaZoneState { 0, false };
#endif
static Profiler init_order(105) s_profilerInstance;
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
enum { BulkSize = TargetFrameSize / QueueItemSize };
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() )
, m_shutdown( false )
, m_shutdownFinished( false )
, m_sock( nullptr )
, m_noExit( false )
, m_stream( LZ4_createStream() )
, m_buffer( (char*)tracy_malloc( TargetFrameSize*3 ) )
, m_bufferOffset( 0 )
, m_bufferStart( 0 )
, m_itemBuf( (QueueItem*)tracy_malloc( sizeof( QueueItem ) * BulkSize ) )
, m_lz4Buf( (char*)tracy_malloc( LZ4Size + sizeof( lz4sz_t ) ) )
, m_serialQueue( 1024*1024 )
, m_serialDequeue( 1024*1024 )
#ifdef TRACY_ON_DEMAND
, m_isConnected( false )
, m_frameCount( 0 )
, m_deferredQueue( 64*1024 )
#endif
{
assert( !s_instance );
s_instance = this;
#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
CalibrateTimer();
CalibrateDelay();
#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
#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
#ifdef TRACY_HAS_CALLSTACK
InitCallstack();
#endif
m_timeBegin.store( GetTime(), std::memory_order_relaxed );
}
Profiler::~Profiler()
{
m_shutdown.store( true, std::memory_order_relaxed );
s_thread->~Thread();
tracy_free( s_thread );
tracy_free( m_lz4Buf );
tracy_free( m_itemBuf );
tracy_free( m_buffer );
LZ4_freeStream( m_stream );
if( m_sock )
{
m_sock->~Socket();
tracy_free( m_sock );
}
assert( s_instance );
s_instance = nullptr;
}
bool Profiler::ShouldExit()
{
return s_instance->m_shutdown.load( std::memory_order_relaxed );
}
void Profiler::Worker()
{
#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 );
const auto hostinfo = GetHostInfo();
const auto hisz = std::min<size_t>( strlen( hostinfo ), WelcomeMessageHostInfoSize - 1 );
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 );
memcpy( welcome.hostInfo, hostinfo, hisz );
memset( welcome.hostInfo + hisz, 0, WelcomeMessageHostInfoSize - hisz );
moodycamel::ConsumerToken token( s_queue );
ListenSocket listen;
listen.Listen( "8086", 8 );
for(;;)
{
for(;;)
{
#ifndef TRACY_NO_EXIT
if( !m_noExit && ShouldExit() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
#endif
m_sock = listen.Accept();
if( m_sock ) break;
}
#ifdef TRACY_ON_DEMAND
ClearQueues( token );
m_isConnected.store( true, std::memory_order_relaxed );
#endif
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 ) );
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;
for(;;)
{
const auto status = Dequeue( token );
const auto serialStatus = DequeueSerial();
if( status == ConnectionLost || serialStatus == ConnectionLost )
{
break;
}
else if( status == QueueEmpty && serialStatus == QueueEmpty )
{
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;
}
while( m_sock->HasData() )
{
if( !HandleServerQuery() ) break;
}
}
if( ShouldExit() ) break;
#ifdef TRACY_ON_DEMAND
m_isConnected.store( false, std::memory_order_relaxed );
#endif
}
for(;;)
{
const auto status = Dequeue( token );
const auto serialStatus = DequeueSerial();
if( status == ConnectionLost || serialStatus == ConnectionLost )
{
break;
}
else if( status == QueueEmpty && serialStatus == QueueEmpty )
{
if( m_bufferOffset != m_bufferStart ) CommitData();
break;
}
while( m_sock->HasData() )
{
if( !HandleServerQuery() ) break;
}
}
QueueItem terminate;
MemWrite( &terminate.hdr.type, QueueType::Terminate );
if( !SendData( (const char*)&terminate, 1 ) )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
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;
}
}
while( Dequeue( token ) == Success ) {}
while( DequeueSerial() == Success ) {}
if( m_bufferOffset != m_bufferStart )
{
if( !CommitData() )
{
m_shutdownFinished.store( true, std::memory_order_relaxed );
return;
}
}
}
else
{
if( m_bufferOffset != m_bufferStart ) CommitData();
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] );
}
std::lock_guard<TracyMutex> lock( m_serialLock );
for( auto& v : m_serialDequeue ) FreeAssociatedMemory( v );
m_serialDequeue.clear();
for( auto& v : m_serialQueue ) FreeAssociatedMemory( v );
m_serialQueue.clear();
}
Profiler::DequeueStatus Profiler::Dequeue( moodycamel::ConsumerToken& token )
{
const auto sz = s_queue.try_dequeue_bulk( token, m_itemBuf, BulkSize );
if( sz > 0 )
{
auto end = m_itemBuf + sz;
auto item = m_itemBuf;
while( item != end )
{
uint64_t ptr;
const auto idx = MemRead<uint8_t>( &item->hdr.idx );
if( idx < (int)QueueType::Terminate )
{
switch( (QueueType)idx )
{
case QueueType::ZoneText:
case QueueType::ZoneName:
ptr = MemRead<uint64_t>( &item->zoneText.text );
SendString( ptr, (const char*)ptr, QueueType::CustomStringData );
tracy_free( (void*)ptr );
break;
case QueueType::Message:
ptr = MemRead<uint64_t>( &item->message.text );
SendString( ptr, (const char*)ptr, QueueType::CustomStringData );
tracy_free( (void*)ptr );
break;
case QueueType::ZoneBeginAllocSrcLoc:
ptr = MemRead<uint64_t>( &item->zoneBegin.srcloc );
SendSourceLocationPayload( ptr );
tracy_free( (void*)ptr );
break;
case QueueType::Callstack:
ptr = MemRead<uint64_t>( &item->callstack.ptr );
SendCallstackPayload( ptr );
tracy_free( (void*)ptr );
break;
default:
assert( false );
break;
}
}
if( !AppendData( item, QueueDataSize[idx] ) ) return ConnectionLost;
item++;
}
}
else
{
return QueueEmpty;
}
return Success;
}
Profiler::DequeueStatus Profiler::DequeueSerial()
{
{
while( !m_serialLock.try_lock() ) {}
m_serialQueue.swap( m_serialDequeue );
m_serialLock.unlock();
}
const auto sz = m_serialDequeue.size();
if( sz > 0 )
{
auto item = m_serialDequeue.data();
auto end = item + sz;
while( item != end )
{
uint64_t ptr;
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;
}
}
if( !AppendData( item, QueueDataSize[idx] ) ) return ConnectionLost;
item++;
}
m_serialDequeue.clear();
}
else
{
return QueueEmpty;
}
return Success;
}
bool Profiler::AppendData( const void* data, size_t len )
{
auto ret = true;
ret = NeedDataSize( len );
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 )
{
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;
}
void Profiler::SendString( uint64_t str, const char* ptr, QueueType type )
{
assert( type == QueueType::StringData || type == QueueType::ThreadName || type == QueueType::CustomStringData || type == QueueType::PlotName || type == QueueType::FrameName );
QueueItem item;
MemWrite( &item.hdr.type, type );
MemWrite( &item.stringTransfer.ptr, str );
auto len = strlen( ptr );
assert( len <= std::numeric_limits<uint16_t>::max() );
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] );
}
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 );
}
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 ) );
if( compile_time_condition<sizeof( uintptr_t ) == sizeof( uint64_t )>::value )
{
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 ) );
}
}
}
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 );
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 );
#endif
}
static bool DontExit() { return false; }
bool Profiler::HandleServerQuery()
{
timeval tv;
tv.tv_sec = 0;
tv.tv_usec = 10000;
uint8_t type;
if( !m_sock->Read( &type, sizeof( type ), &tv, DontExit ) ) return false;
uint64_t ptr;
if( !m_sock->Read( &ptr, sizeof( ptr ), &tv, DontExit ) ) return false;
switch( type )
{
case ServerQueryString:
SendString( ptr, (const char*)ptr, QueueType::StringData );
break;
case ServerQueryThreadString:
if( ptr == m_mainThread )
{
SendString( ptr, "Main thread", QueueType::ThreadName );
}
else
{
SendString( ptr, GetThreadName( ptr ), QueueType::ThreadName );
}
break;
case ServerQuerySourceLocation:
SendSourceLocation( ptr );
break;
case ServerQueryPlotName:
SendString( ptr, (const char*)ptr, QueueType::PlotName );
break;
case ServerQueryTerminate:
return false;
case ServerQueryCallstackFrame:
SendCallstackFrame( ptr );
break;
case ServerQueryFrameName:
SendString( ptr, (const char*)ptr, QueueType::FrameName );
break;
default:
assert( false );
break;
}
return true;
}
void Profiler::CalibrateTimer()
{
#ifdef TRACY_HW_TIMER
# if __ARM_ARCH >= 6
if( GetTimeImpl == GetTimeImplFallback )
{
m_timerMul = 1.;
return;
}
# endif
std::atomic_signal_fence( std::memory_order_acq_rel );
const auto t0 = std::chrono::high_resolution_clock::now();
const auto r0 = GetTime();
std::atomic_signal_fence( std::memory_order_acq_rel );
std::this_thread::sleep_for( std::chrono::milliseconds( 200 ) );
std::atomic_signal_fence( std::memory_order_acq_rel );
const auto t1 = std::chrono::high_resolution_clock::now();
const auto r1 = GetTime();
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.;
#endif
}
class FakeZone
{
public:
FakeZone( const SourceLocationData* srcloc ) : m_id( (uint64_t)srcloc ) {}
~FakeZone() {}
private:
volatile uint64_t m_id;
};
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" );
moodycamel::ProducerToken ptoken_detail( s_queue );
moodycamel::ConcurrentQueue<QueueItem>::ExplicitProducer* ptoken = s_queue.get_explicit_producer( ptoken_detail );
for( int i=0; i<Iterations; i++ )
{
static const tracy::SourceLocationData __tracy_source_location { nullptr, __FUNCTION__, __FILE__, (uint32_t)__LINE__, 0 };
{
Magic magic;
auto& tail = ptoken->get_tail_index();
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 );
tail.store( magic + 1, std::memory_order_release );
}
{
Magic magic;
auto& tail = ptoken->get_tail_index();
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
tail.store( magic + 1, std::memory_order_release );
}
}
const auto f0 = GetTime();
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 );
}
const auto t0 = GetTime();
for( int i=0; i<Iterations; i++ )
{
static const tracy::SourceLocationData __tracy_source_location { nullptr, __FUNCTION__, __FILE__, (uint32_t)__LINE__, 0 };
{
Magic magic;
auto& tail = ptoken->get_tail_index();
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 );
tail.store( magic + 1, std::memory_order_release );
}
{
Magic magic;
auto& tail = ptoken->get_tail_index();
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
tail.store( magic + 1, std::memory_order_release );
}
}
const auto t1 = GetTime();
const auto dt = t1 - t0;
const auto df = t0 - f0;
m_delay = ( dt - df ) / Events;
auto mindiff = std::numeric_limits<int64_t>::max();
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;
}
m_resolution = mindiff;
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 );
left -= (int)sz;
}
}
}
#endif
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