/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage Inc., all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of the copyright holders may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the Intel Corporation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ #include "precomp.hpp" #ifdef _MSC_VER # if _MSC_VER >= 1700 # pragma warning(disable:4447) // Disable warning 'main' signature found without threading model # endif #endif #if defined WIN32 || defined _WIN32 || defined WINCE #ifndef _WIN32_WINNT // This is needed for the declaration of TryEnterCriticalSection in winbase.h with Visual Studio 2005 (and older?) #define _WIN32_WINNT 0x0400 // http://msdn.microsoft.com/en-us/library/ms686857(VS.85).aspx #endif #include #if (_WIN32_WINNT >= 0x0602) #include #endif #undef small #undef min #undef max #undef abs #include #if defined _MSC_VER #if _MSC_VER >= 1400 #include #elif defined _M_IX86 static void __cpuid(int* cpuid_data, int) { __asm { push ebx push edi mov edi, cpuid_data mov eax, 1 cpuid mov [edi], eax mov [edi + 4], ebx mov [edi + 8], ecx mov [edi + 12], edx pop edi pop ebx } } #endif #endif #ifdef HAVE_WINRT #include #ifndef __cplusplus_winrt #include #pragma comment(lib, "runtimeobject.lib") #endif std::wstring GetTempPathWinRT() { #ifdef __cplusplus_winrt return std::wstring(Windows::Storage::ApplicationData::Current->TemporaryFolder->Path->Data()); #else Microsoft::WRL::ComPtr appdataFactory; Microsoft::WRL::ComPtr appdataRef; Microsoft::WRL::ComPtr storagefolderRef; Microsoft::WRL::ComPtr storageitemRef; HSTRING str; HSTRING_HEADER hstrHead; std::wstring wstr; if (FAILED(WindowsCreateStringReference(RuntimeClass_Windows_Storage_ApplicationData, (UINT32)wcslen(RuntimeClass_Windows_Storage_ApplicationData), &hstrHead, &str))) return wstr; if (FAILED(RoGetActivationFactory(str, IID_PPV_ARGS(appdataFactory.ReleaseAndGetAddressOf())))) return wstr; if (FAILED(appdataFactory->get_Current(appdataRef.ReleaseAndGetAddressOf()))) return wstr; if (FAILED(appdataRef->get_TemporaryFolder(storagefolderRef.ReleaseAndGetAddressOf()))) return wstr; if (FAILED(storagefolderRef.As(&storageitemRef))) return wstr; str = NULL; if (FAILED(storageitemRef->get_Path(&str))) return wstr; wstr = WindowsGetStringRawBuffer(str, NULL); WindowsDeleteString(str); return wstr; #endif } std::wstring GetTempFileNameWinRT(std::wstring prefix) { wchar_t guidStr[40]; GUID g; CoCreateGuid(&g); wchar_t* mask = L"%08x_%04x_%04x_%02x%02x_%02x%02x%02x%02x%02x%02x"; swprintf(&guidStr[0], sizeof(guidStr)/sizeof(wchar_t), mask, g.Data1, g.Data2, g.Data3, UINT(g.Data4[0]), UINT(g.Data4[1]), UINT(g.Data4[2]), UINT(g.Data4[3]), UINT(g.Data4[4]), UINT(g.Data4[5]), UINT(g.Data4[6]), UINT(g.Data4[7])); return prefix + std::wstring(guidStr); } #endif #else #include #include #include #if defined __MACH__ && defined __APPLE__ #include #include #endif #endif #ifdef _OPENMP #include "omp.h" #endif #include #if defined __linux__ || defined __APPLE__ || defined __EMSCRIPTEN__ #include #include #include #if defined ANDROID #include #else #include #endif #endif #ifdef ANDROID # include #endif namespace cv { Exception::Exception() { code = 0; line = 0; } Exception::Exception(int _code, const String& _err, const String& _func, const String& _file, int _line) : code(_code), err(_err), func(_func), file(_file), line(_line) { formatMessage(); } Exception::~Exception() throw() {} /*! \return the error description and the context as a text string. */ const char* Exception::what() const throw() { return msg.c_str(); } void Exception::formatMessage() { if( func.size() > 0 ) msg = format("%s:%d: error: (%d) %s in function %s\n", file.c_str(), line, code, err.c_str(), func.c_str()); else msg = format("%s:%d: error: (%d) %s\n", file.c_str(), line, code, err.c_str()); } struct HWFeatures { enum { MAX_FEATURE = CV_HARDWARE_MAX_FEATURE }; HWFeatures(void) { memset( have, 0, sizeof(have) ); x86_family = 0; } static HWFeatures initialize(void) { HWFeatures f; int cpuid_data[4] = { 0, 0, 0, 0 }; #if defined _MSC_VER && (defined _M_IX86 || defined _M_X64) __cpuid(cpuid_data, 1); #elif defined __GNUC__ && (defined __i386__ || defined __x86_64__) #ifdef __x86_64__ asm __volatile__ ( "movl $1, %%eax\n\t" "cpuid\n\t" :[eax]"=a"(cpuid_data[0]),[ebx]"=b"(cpuid_data[1]),[ecx]"=c"(cpuid_data[2]),[edx]"=d"(cpuid_data[3]) : : "cc" ); #else asm volatile ( "pushl %%ebx\n\t" "movl $1,%%eax\n\t" "cpuid\n\t" "popl %%ebx\n\t" : "=a"(cpuid_data[0]), "=c"(cpuid_data[2]), "=d"(cpuid_data[3]) : : "cc" ); #endif #endif f.x86_family = (cpuid_data[0] >> 8) & 15; if( f.x86_family >= 6 ) { f.have[CV_CPU_MMX] = (cpuid_data[3] & (1 << 23)) != 0; f.have[CV_CPU_SSE] = (cpuid_data[3] & (1<<25)) != 0; f.have[CV_CPU_SSE2] = (cpuid_data[3] & (1<<26)) != 0; f.have[CV_CPU_SSE3] = (cpuid_data[2] & (1<<0)) != 0; f.have[CV_CPU_SSSE3] = (cpuid_data[2] & (1<<9)) != 0; f.have[CV_CPU_SSE4_1] = (cpuid_data[2] & (1<<19)) != 0; f.have[CV_CPU_SSE4_2] = (cpuid_data[2] & (1<<20)) != 0; f.have[CV_CPU_POPCNT] = (cpuid_data[2] & (1<<23)) != 0; f.have[CV_CPU_AVX] = (((cpuid_data[2] & (1<<28)) != 0)&&((cpuid_data[2] & (1<<27)) != 0));//OS uses XSAVE_XRSTORE and CPU support AVX } return f; } int x86_family; bool have[MAX_FEATURE+1]; }; static HWFeatures featuresEnabled = HWFeatures::initialize(), featuresDisabled = HWFeatures(); static HWFeatures* currentFeatures = &featuresEnabled; bool checkHardwareSupport(int feature) { CV_DbgAssert( 0 <= feature && feature <= CV_HARDWARE_MAX_FEATURE ); return currentFeatures->have[feature]; } volatile bool useOptimizedFlag = true; #ifdef HAVE_IPP struct IPPInitializer { IPPInitializer(void) { ippStaticInit(); } }; IPPInitializer ippInitializer; #endif volatile bool USE_SSE2 = featuresEnabled.have[CV_CPU_SSE2]; volatile bool USE_SSE4_2 = featuresEnabled.have[CV_CPU_SSE4_2]; volatile bool USE_AVX = featuresEnabled.have[CV_CPU_AVX]; void setUseOptimized( bool flag ) { useOptimizedFlag = flag; currentFeatures = flag ? &featuresEnabled : &featuresDisabled; USE_SSE2 = currentFeatures->have[CV_CPU_SSE2]; } bool useOptimized(void) { return useOptimizedFlag; } int64 getTickCount(void) { #if defined WIN32 || defined _WIN32 || defined WINCE LARGE_INTEGER counter; QueryPerformanceCounter( &counter ); return (int64)counter.QuadPart; #elif defined __linux || defined __linux__ struct timespec tp; clock_gettime(CLOCK_MONOTONIC, &tp); return (int64)tp.tv_sec*1000000000 + tp.tv_nsec; #elif defined __MACH__ && defined __APPLE__ return (int64)mach_absolute_time(); #else struct timeval tv; struct timezone tz; gettimeofday( &tv, &tz ); return (int64)tv.tv_sec*1000000 + tv.tv_usec; #endif } double getTickFrequency(void) { #if defined WIN32 || defined _WIN32 || defined WINCE LARGE_INTEGER freq; QueryPerformanceFrequency(&freq); return (double)freq.QuadPart; #elif defined __linux || defined __linux__ return 1e9; #elif defined __MACH__ && defined __APPLE__ static double freq = 0; if( freq == 0 ) { mach_timebase_info_data_t sTimebaseInfo; mach_timebase_info(&sTimebaseInfo); freq = sTimebaseInfo.denom*1e9/sTimebaseInfo.numer; } return freq; #else return 1e6; #endif } #if defined __GNUC__ && (defined __i386__ || defined __x86_64__ || defined __ppc__) #if defined(__i386__) int64 getCPUTickCount(void) { int64 x; __asm__ volatile (".byte 0x0f, 0x31" : "=A" (x)); return x; } #elif defined(__x86_64__) int64 getCPUTickCount(void) { unsigned hi, lo; __asm__ __volatile__ ("rdtsc" : "=a"(lo), "=d"(hi)); return (int64)lo | ((int64)hi << 32); } #elif defined(__ppc__) int64 getCPUTickCount(void) { int64 result = 0; unsigned upper, lower, tmp; __asm__ volatile( "0: \n" "\tmftbu %0 \n" "\tmftb %1 \n" "\tmftbu %2 \n" "\tcmpw %2,%0 \n" "\tbne 0b \n" : "=r"(upper),"=r"(lower),"=r"(tmp) ); return lower | ((int64)upper << 32); } #else #error "RDTSC not defined" #endif #elif defined _MSC_VER && defined WIN32 && defined _M_IX86 int64 getCPUTickCount(void) { __asm _emit 0x0f; __asm _emit 0x31; } #else #ifdef HAVE_IPP int64 getCPUTickCount(void) { return ippGetCpuClocks(); } #else int64 getCPUTickCount(void) { return getTickCount(); } #endif #endif const String& getBuildInformation() { static String build_info = #include "version_string.inc" ; return build_info; } String format( const char* fmt, ... ) { char buf[1024]; va_list va; va_start(va, fmt); int len = vsnprintf(buf, sizeof(buf), fmt, va); va_end(va); if (len >= (int)sizeof(buf)) { String s(len, '\0'); va_start(va, fmt); len = vsnprintf((char*)s.c_str(), len + 1, fmt, va); va_end(va); return s; } return String(buf, len); } String tempfile( const char* suffix ) { #ifdef HAVE_WINRT std::wstring temp_dir = L""; const wchar_t* opencv_temp_dir = _wgetenv(L"OPENCV_TEMP_PATH"); if (opencv_temp_dir) temp_dir = std::wstring(opencv_temp_dir); #else const char *temp_dir = getenv("OPENCV_TEMP_PATH"); String fname; #endif #if defined WIN32 || defined _WIN32 #ifdef HAVE_WINRT RoInitialize(RO_INIT_MULTITHREADED); std::wstring temp_dir2; if (temp_dir.empty()) temp_dir = GetTempPathWinRT(); std::wstring temp_file; temp_file = GetTempFileNameWinRT(L"ocv"); if (temp_file.empty()) return std::string(); temp_file = temp_dir + std::wstring(L"\\") + temp_file; DeleteFileW(temp_file.c_str()); char aname[MAX_PATH]; size_t copied = wcstombs(aname, temp_file.c_str(), MAX_PATH); CV_Assert((copied != MAX_PATH) && (copied != (size_t)-1)); fname = std::string(aname); RoUninitialize(); #else char temp_dir2[MAX_PATH] = { 0 }; char temp_file[MAX_PATH] = { 0 }; if (temp_dir == 0 || temp_dir[0] == 0) { ::GetTempPathA(sizeof(temp_dir2), temp_dir2); temp_dir = temp_dir2; } if(0 == ::GetTempFileNameA(temp_dir, "ocv", 0, temp_file)) return String(); DeleteFileA(temp_file); fname = temp_file; #endif # else # ifdef ANDROID //char defaultTemplate[] = "/mnt/sdcard/__opencv_temp.XXXXXX"; char defaultTemplate[] = "/data/local/tmp/__opencv_temp.XXXXXX"; # else char defaultTemplate[] = "/tmp/__opencv_temp.XXXXXX"; # endif if (temp_dir == 0 || temp_dir[0] == 0) fname = defaultTemplate; else { fname = temp_dir; char ech = fname[fname.size() - 1]; if(ech != '/' && ech != '\\') fname = fname + "/"; fname = fname + "__opencv_temp.XXXXXX"; } const int fd = mkstemp((char*)fname.c_str()); if (fd == -1) return String(); close(fd); remove(fname.c_str()); # endif if (suffix) { if (suffix[0] != '.') return fname + "." + suffix; else return fname + suffix; } return fname; } static CvErrorCallback customErrorCallback = 0; static void* customErrorCallbackData = 0; static bool breakOnError = false; bool setBreakOnError(bool value) { bool prevVal = breakOnError; breakOnError = value; return prevVal; } void error( const Exception& exc ) { if (customErrorCallback != 0) customErrorCallback(exc.code, exc.func.c_str(), exc.err.c_str(), exc.file.c_str(), exc.line, customErrorCallbackData); else { const char* errorStr = cvErrorStr(exc.code); char buf[1 << 16]; sprintf( buf, "OpenCV Error: %s (%s) in %s, file %s, line %d", errorStr, exc.err.c_str(), exc.func.size() > 0 ? exc.func.c_str() : "unknown function", exc.file.c_str(), exc.line ); fprintf( stderr, "%s\n", buf ); fflush( stderr ); # ifdef __ANDROID__ __android_log_print(ANDROID_LOG_ERROR, "cv::error()", "%s", buf); # endif } if(breakOnError) { static volatile int* p = 0; *p = 0; } throw exc; } void error(int _code, const String& _err, const char* _func, const char* _file, int _line) { error(cv::Exception(_code, _err, _func, _file, _line)); } CvErrorCallback redirectError( CvErrorCallback errCallback, void* userdata, void** prevUserdata) { if( prevUserdata ) *prevUserdata = customErrorCallbackData; CvErrorCallback prevCallback = customErrorCallback; customErrorCallback = errCallback; customErrorCallbackData = userdata; return prevCallback; } } CV_IMPL int cvCheckHardwareSupport(int feature) { CV_DbgAssert( 0 <= feature && feature <= CV_HARDWARE_MAX_FEATURE ); return cv::currentFeatures->have[feature]; } CV_IMPL int cvUseOptimized( int flag ) { int prevMode = cv::useOptimizedFlag; cv::setUseOptimized( flag != 0 ); return prevMode; } CV_IMPL int64 cvGetTickCount(void) { return cv::getTickCount(); } CV_IMPL double cvGetTickFrequency(void) { return cv::getTickFrequency()*1e-6; } CV_IMPL CvErrorCallback cvRedirectError( CvErrorCallback errCallback, void* userdata, void** prevUserdata) { return cv::redirectError(errCallback, userdata, prevUserdata); } CV_IMPL int cvNulDevReport( int, const char*, const char*, const char*, int, void* ) { return 0; } CV_IMPL int cvStdErrReport( int, const char*, const char*, const char*, int, void* ) { return 0; } CV_IMPL int cvGuiBoxReport( int, const char*, const char*, const char*, int, void* ) { return 0; } CV_IMPL int cvGetErrInfo( const char**, const char**, const char**, int* ) { return 0; } CV_IMPL const char* cvErrorStr( int status ) { static char buf[256]; switch (status) { case CV_StsOk : return "No Error"; case CV_StsBackTrace : return "Backtrace"; case CV_StsError : return "Unspecified error"; case CV_StsInternal : return "Internal error"; case CV_StsNoMem : return "Insufficient memory"; case CV_StsBadArg : return "Bad argument"; case CV_StsNoConv : return "Iterations do not converge"; case CV_StsAutoTrace : return "Autotrace call"; case CV_StsBadSize : return "Incorrect size of input array"; case CV_StsNullPtr : return "Null pointer"; case CV_StsDivByZero : return "Division by zero occured"; case CV_BadStep : return "Image step is wrong"; case CV_StsInplaceNotSupported : return "Inplace operation is not supported"; case CV_StsObjectNotFound : return "Requested object was not found"; case CV_BadDepth : return "Input image depth is not supported by function"; case CV_StsUnmatchedFormats : return "Formats of input arguments do not match"; case CV_StsUnmatchedSizes : return "Sizes of input arguments do not match"; case CV_StsOutOfRange : return "One of arguments\' values is out of range"; case CV_StsUnsupportedFormat : return "Unsupported format or combination of formats"; case CV_BadCOI : return "Input COI is not supported"; case CV_BadNumChannels : return "Bad number of channels"; case CV_StsBadFlag : return "Bad flag (parameter or structure field)"; case CV_StsBadPoint : return "Bad parameter of type CvPoint"; case CV_StsBadMask : return "Bad type of mask argument"; case CV_StsParseError : return "Parsing error"; case CV_StsNotImplemented : return "The function/feature is not implemented"; case CV_StsBadMemBlock : return "Memory block has been corrupted"; case CV_StsAssert : return "Assertion failed"; case CV_GpuNotSupported : return "No CUDA support"; case CV_GpuApiCallError : return "Gpu API call"; case CV_OpenGlNotSupported : return "No OpenGL support"; case CV_OpenGlApiCallError : return "OpenGL API call"; }; sprintf(buf, "Unknown %s code %d", status >= 0 ? "status":"error", status); return buf; } CV_IMPL int cvGetErrMode(void) { return 0; } CV_IMPL int cvSetErrMode(int) { return 0; } CV_IMPL int cvGetErrStatus(void) { return 0; } CV_IMPL void cvSetErrStatus(int) { } CV_IMPL void cvError( int code, const char* func_name, const char* err_msg, const char* file_name, int line ) { cv::error(cv::Exception(code, err_msg, func_name, file_name, line)); } /* function, which converts int to int */ CV_IMPL int cvErrorFromIppStatus( int status ) { switch (status) { case CV_BADSIZE_ERR: return CV_StsBadSize; case CV_BADMEMBLOCK_ERR: return CV_StsBadMemBlock; case CV_NULLPTR_ERR: return CV_StsNullPtr; case CV_DIV_BY_ZERO_ERR: return CV_StsDivByZero; case CV_BADSTEP_ERR: return CV_BadStep; case CV_OUTOFMEM_ERR: return CV_StsNoMem; case CV_BADARG_ERR: return CV_StsBadArg; case CV_NOTDEFINED_ERR: return CV_StsError; case CV_INPLACE_NOT_SUPPORTED_ERR: return CV_StsInplaceNotSupported; case CV_NOTFOUND_ERR: return CV_StsObjectNotFound; case CV_BADCONVERGENCE_ERR: return CV_StsNoConv; case CV_BADDEPTH_ERR: return CV_BadDepth; case CV_UNMATCHED_FORMATS_ERR: return CV_StsUnmatchedFormats; case CV_UNSUPPORTED_COI_ERR: return CV_BadCOI; case CV_UNSUPPORTED_CHANNELS_ERR: return CV_BadNumChannels; case CV_BADFLAG_ERR: return CV_StsBadFlag; case CV_BADRANGE_ERR: return CV_StsBadArg; case CV_BADCOEF_ERR: return CV_StsBadArg; case CV_BADFACTOR_ERR: return CV_StsBadArg; case CV_BADPOINT_ERR: return CV_StsBadPoint; default: return CV_StsError; } } namespace cv { bool __termination = false; } namespace cv { #if defined WIN32 || defined _WIN32 || defined WINCE struct Mutex::Impl { Impl() { #if (_WIN32_WINNT >= 0x0600) ::InitializeCriticalSectionEx(&cs, 1000, 0); #else ::InitializeCriticalSection(&cs); #endif refcount = 1; } ~Impl() { DeleteCriticalSection(&cs); } void lock() { EnterCriticalSection(&cs); } bool trylock() { return TryEnterCriticalSection(&cs) != 0; } void unlock() { LeaveCriticalSection(&cs); } CRITICAL_SECTION cs; int refcount; }; #else struct Mutex::Impl { Impl() { pthread_mutexattr_t attr; pthread_mutexattr_init(&attr); pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE); pthread_mutex_init(&mt, &attr); pthread_mutexattr_destroy(&attr); refcount = 1; } ~Impl() { pthread_mutex_destroy(&mt); } void lock() { pthread_mutex_lock(&mt); } bool trylock() { return pthread_mutex_trylock(&mt) == 0; } void unlock() { pthread_mutex_unlock(&mt); } pthread_mutex_t mt; int refcount; }; #endif Mutex::Mutex() { impl = new Mutex::Impl; } Mutex::~Mutex() { if( CV_XADD(&impl->refcount, -1) == 1 ) delete impl; impl = 0; } Mutex::Mutex(const Mutex& m) { impl = m.impl; CV_XADD(&impl->refcount, 1); } Mutex& Mutex::operator = (const Mutex& m) { CV_XADD(&m.impl->refcount, 1); if( CV_XADD(&impl->refcount, -1) == 1 ) delete impl; impl = m.impl; return *this; } void Mutex::lock() { impl->lock(); } void Mutex::unlock() { impl->unlock(); } bool Mutex::trylock() { return impl->trylock(); } //////////////////////////////// thread-local storage //////////////////////////////// class TLSStorage { std::vector tlsData_; public: TLSStorage() { tlsData_.reserve(16); } ~TLSStorage(); inline void* getData(int key) const { CV_DbgAssert(key >= 0); return (key < (int)tlsData_.size()) ? tlsData_[key] : NULL; } inline void setData(int key, void* data) { CV_DbgAssert(key >= 0); if (key >= (int)tlsData_.size()) { tlsData_.resize(key + 1, NULL); } tlsData_[key] = data; } inline static TLSStorage* get(); }; #ifdef WIN32 #pragma warning(disable:4505) // unreferenced local function has been removed #ifdef HAVE_WINRT // using C++11 thread attribute for local thread data static __declspec( thread ) TLSStorage* g_tlsdata = NULL; static void deleteThreadData() { if (g_tlsdata) { delete g_tlsdata; g_tlsdata = NULL; } } inline TLSStorage* TLSStorage::get() { if (!g_tlsdata) { g_tlsdata = new TLSStorage; } return g_tlsdata; } #else #ifdef WINCE # define TLS_OUT_OF_INDEXES ((DWORD)0xFFFFFFFF) #endif static DWORD tlsKey = TLS_OUT_OF_INDEXES; static void deleteThreadData() { if(tlsKey != TLS_OUT_OF_INDEXES) { delete (TLSStorage*)TlsGetValue(tlsKey); TlsSetValue(tlsKey, NULL); } } inline TLSStorage* TLSStorage::get() { if (tlsKey == TLS_OUT_OF_INDEXES) { tlsKey = TlsAlloc(); CV_Assert(tlsKey != TLS_OUT_OF_INDEXES); } TLSStorage* d = (TLSStorage*)TlsGetValue(tlsKey); if (!d) { d = new TLSStorage; TlsSetValue(tlsKey, d); } return d; } #endif //HAVE_WINRT #if defined CVAPI_EXPORTS && defined WIN32 && !defined WINCE #ifdef HAVE_WINRT #pragma warning(disable:4447) // Disable warning 'main' signature found without threading model #endif BOOL WINAPI DllMain(HINSTANCE, DWORD fdwReason, LPVOID); BOOL WINAPI DllMain(HINSTANCE, DWORD fdwReason, LPVOID) { if (fdwReason == DLL_THREAD_DETACH || fdwReason == DLL_PROCESS_DETACH) { cv::deleteThreadAllocData(); cv::deleteThreadRNGData(); cv::deleteThreadData(); } return TRUE; } #endif #else static pthread_key_t tlsKey = 0; static pthread_once_t tlsKeyOnce = PTHREAD_ONCE_INIT; static void deleteTLSStorage(void* data) { delete (TLSStorage*)data; } static void makeKey() { int errcode = pthread_key_create(&tlsKey, deleteTLSStorage); CV_Assert(errcode == 0); } inline TLSStorage* TLSStorage::get() { pthread_once(&tlsKeyOnce, makeKey); TLSStorage* d = (TLSStorage*)pthread_getspecific(tlsKey); if( !d ) { d = new TLSStorage; pthread_setspecific(tlsKey, d); } return d; } #endif class TLSContainerStorage { cv::Mutex mutex_; std::vector tlsContainers_; public: TLSContainerStorage() { } ~TLSContainerStorage() { for (size_t i = 0; i < tlsContainers_.size(); i++) { CV_DbgAssert(tlsContainers_[i] == NULL); // not all keys released tlsContainers_[i] = NULL; } } int allocateKey(TLSDataContainer* pContainer) { cv::AutoLock lock(mutex_); tlsContainers_.push_back(pContainer); return (int)tlsContainers_.size() - 1; } void releaseKey(int id, TLSDataContainer* pContainer) { cv::AutoLock lock(mutex_); CV_Assert(tlsContainers_[id] == pContainer); tlsContainers_[id] = NULL; // currently, we don't go into thread's TLSData and release data for this key } void destroyData(int key, void* data) { cv::AutoLock lock(mutex_); TLSDataContainer* k = tlsContainers_[key]; if (!k) return; try { k->deleteDataInstance(data); } catch (...) { CV_DbgAssert(k == NULL); // Debug this! } } }; static TLSContainerStorage tlsContainerStorage; TLSDataContainer::TLSDataContainer() : key_(-1) { key_ = tlsContainerStorage.allocateKey(this); } TLSDataContainer::~TLSDataContainer() { tlsContainerStorage.releaseKey(key_, this); key_ = -1; } void* TLSDataContainer::getData() const { CV_Assert(key_ >= 0); TLSStorage* tlsData = TLSStorage::get(); void* data = tlsData->getData(key_); if (!data) { data = this->createDataInstance(); CV_DbgAssert(data != NULL); tlsData->setData(key_, data); } return data; } TLSStorage::~TLSStorage() { for (int i = 0; i < (int)tlsData_.size(); i++) { void*& data = tlsData_[i]; if (data) { tlsContainerStorage.destroyData(i, data); data = NULL; } } tlsData_.clear(); } } // namespace cv //////////////////////////////// thread-local storage //////////////////////////////// namespace cv { TLSData::TLSData() { device = 0; useOpenCL = -1; } #ifdef WIN32 #ifdef HAVE_WINRT // using C++11 thread attribute for local thread data static __declspec( thread ) TLSData* g_tlsdata = NULL; static void deleteThreadRNGData() { if (g_tlsdata) delete g_tlsdata; } TLSData* TLSData::get() { if (!g_tlsdata) { g_tlsdata = new TLSData; } return g_tlsdata; } #else #ifdef WINCE # define TLS_OUT_OF_INDEXES ((DWORD)0xFFFFFFFF) #endif static DWORD tlsKey = TLS_OUT_OF_INDEXES; void deleteThreadData() { if( tlsKey != TLS_OUT_OF_INDEXES ) delete (TLSData*)TlsGetValue( tlsKey ); } TLSData* TLSData::get() { if( tlsKey == TLS_OUT_OF_INDEXES ) { tlsKey = TlsAlloc(); CV_Assert(tlsKey != TLS_OUT_OF_INDEXES); } TLSData* d = (TLSData*)TlsGetValue( tlsKey ); if( !d ) { d = new TLSData; TlsSetValue( tlsKey, d ); } return d; } #endif //HAVE_WINRT #else static pthread_key_t tlsKey = 0; static pthread_once_t tlsKeyOnce = PTHREAD_ONCE_INIT; static void deleteTLSData(void* data) { delete (TLSData*)data; } static void makeKey() { int errcode = pthread_key_create(&tlsKey, deleteTLSData); CV_Assert(errcode == 0); } TLSData* TLSData::get() { pthread_once(&tlsKeyOnce, makeKey); TLSData* d = (TLSData*)pthread_getspecific(tlsKey); if( !d ) { d = new TLSData; pthread_setspecific(tlsKey, d); } return d; } #endif } /* End of file. */