#ifdef _WIN32 #include #include #else #include #include #endif #include #include "openclwrapper.h" #include "oclkernels.h" // for micro-benchmark #include "otsuthr.h" #include "thresholder.h" #if ON_APPLE #include #include #endif #ifdef USE_OPENCL #include "opencl_device_selection.h" GPUEnv OpenclDevice::gpuEnv; bool OpenclDevice::deviceIsSelected = false; ds_device OpenclDevice::selectedDevice; int OpenclDevice::isInited = 0; struct tiff_transform { int vflip; /* if non-zero, image needs a vertical fip */ int hflip; /* if non-zero, image needs a horizontal flip */ int rotate; /* -1 -> counterclockwise 90-degree rotation, 0 -> no rotation 1 -> clockwise 90-degree rotation */ }; static struct tiff_transform tiff_orientation_transforms[] = { {0, 0, 0}, {0, 1, 0}, {1, 1, 0}, {1, 0, 0}, {0, 1, -1}, {0, 0, 1}, {0, 1, 1}, {0, 0, -1} }; static const l_int32 MAX_PAGES_IN_TIFF_FILE = 3000; cl_mem pixsCLBuffer, pixdCLBuffer, pixdCLIntermediate; //Morph operations buffers cl_mem pixThBuffer; //output from thresholdtopix calculation cl_int clStatus; KernelEnv rEnv; // substitute invalid characters in device name with _ void legalizeFileName( char *fileName) { //printf("fileName: %s\n", fileName); char *invalidChars = "/\?:*\"><| "; // space is valid but can cause headaches // for each invalid char for (int i = 0; i < strlen(invalidChars); i++) { char invalidStr[4]; invalidStr[0] = invalidChars[i]; invalidStr[1] = NULL; //printf("eliminating %s\n", invalidStr); //char *pos = strstr(fileName, invalidStr); // initial ./ is valid for present directory //if (*pos == '.') pos++; //if (*pos == '/') pos++; for ( char *pos = strstr(fileName, invalidStr); pos != NULL; pos = strstr(pos+1, invalidStr)) { //printf("\tfound: %s, ", pos); pos[0] = '_'; //printf("fileName: %s\n", fileName); } } } void populateGPUEnvFromDevice( GPUEnv *gpuInfo, cl_device_id device ) { //printf("[DS] populateGPUEnvFromDevice\n"); size_t size; gpuInfo->mnIsUserCreated = 1; // device gpuInfo->mpDevID = device; gpuInfo->mpArryDevsID = new cl_device_id[1]; gpuInfo->mpArryDevsID[0] = gpuInfo->mpDevID; clStatus = clGetDeviceInfo(gpuInfo->mpDevID, CL_DEVICE_TYPE , sizeof(cl_device_type), (void *) &gpuInfo->mDevType , &size); CHECK_OPENCL( clStatus, "populateGPUEnv::getDeviceInfo(TYPE)"); // platform clStatus = clGetDeviceInfo(gpuInfo->mpDevID, CL_DEVICE_PLATFORM , sizeof(cl_platform_id), (void *) &gpuInfo->mpPlatformID , &size); CHECK_OPENCL( clStatus, "populateGPUEnv::getDeviceInfo(PLATFORM)"); // context cl_context_properties props[3]; props[0] = CL_CONTEXT_PLATFORM; props[1] = (cl_context_properties) gpuInfo->mpPlatformID; props[2] = 0; gpuInfo->mpContext = clCreateContext(props, 1, &gpuInfo->mpDevID, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "populateGPUEnv::createContext"); // queue cl_command_queue_properties queueProperties = 0; gpuInfo->mpCmdQueue = clCreateCommandQueue( gpuInfo->mpContext, gpuInfo->mpDevID, queueProperties, &clStatus ); CHECK_OPENCL( clStatus, "populateGPUEnv::createCommandQueue"); } int OpenclDevice::LoadOpencl() { #ifdef WIN32 HINSTANCE HOpenclDll = NULL; void * OpenclDll = NULL; //fprintf(stderr, " LoadOpenclDllxx... \n"); OpenclDll = static_cast( HOpenclDll ); OpenclDll = LoadLibrary( "openCL.dll" ); if ( !static_cast( OpenclDll ) ) { fprintf(stderr, "[OD] Load opencl.dll failed!\n"); FreeLibrary( static_cast( OpenclDll ) ); return 0; } fprintf(stderr, "[OD] Load opencl.dll successful!\n"); #endif return 1; } int OpenclDevice::SetKernelEnv( KernelEnv *envInfo ) { envInfo->mpkContext = gpuEnv.mpContext; envInfo->mpkCmdQueue = gpuEnv.mpCmdQueue; envInfo->mpkProgram = gpuEnv.mpArryPrograms[0]; return 1; } cl_mem allocateZeroCopyBuffer(KernelEnv rEnv, l_uint32 *hostbuffer, size_t nElements, cl_mem_flags flags, cl_int *pStatus) { cl_mem membuffer = clCreateBuffer( rEnv.mpkContext, (cl_mem_flags) (flags), nElements * sizeof(l_uint32), hostbuffer, pStatus); return membuffer; } PIX* mapOutputCLBuffer(KernelEnv rEnv, cl_mem clbuffer, PIX* pixd, PIX* pixs, int elements, cl_mem_flags flags, bool memcopy = false, bool sync = true) { PROCNAME("mapOutputCLBuffer"); if (!pixd) { if (memcopy) { if ((pixd = pixCreateTemplate(pixs)) == NULL) (PIX *)ERROR_PTR("pixd not made", procName, NULL); } else { if ((pixd = pixCreateHeader(pixGetWidth(pixs), pixGetHeight(pixs), pixGetDepth(pixs))) == NULL) (PIX *)ERROR_PTR("pixd not made", procName, NULL); } } l_uint32 *pValues = (l_uint32 *)clEnqueueMapBuffer(rEnv.mpkCmdQueue, clbuffer, CL_TRUE, flags, 0, elements * sizeof(l_uint32), 0, NULL, NULL, NULL ); if (memcopy) { memcpy(pixGetData(pixd), pValues, elements * sizeof(l_uint32)); } else { pixSetData(pixd, pValues); } clEnqueueUnmapMemObject(rEnv.mpkCmdQueue,clbuffer,pValues,0,NULL,NULL); if (sync) { clFinish( rEnv.mpkCmdQueue ); } return pixd; } cl_mem allocateIntBuffer( KernelEnv rEnv, const l_uint32 *_pValues, size_t nElements, cl_int *pStatus , bool sync = false) { cl_mem xValues = clCreateBuffer( rEnv.mpkContext, (cl_mem_flags) (CL_MEM_READ_WRITE), nElements * sizeof(l_int32), NULL, pStatus); if (_pValues != NULL) { l_int32 *pValues = (l_int32 *)clEnqueueMapBuffer( rEnv.mpkCmdQueue, xValues, CL_TRUE, CL_MAP_WRITE, 0, nElements * sizeof(l_int32), 0, NULL, NULL, NULL ); memcpy(pValues, _pValues, nElements * sizeof(l_int32)); clEnqueueUnmapMemObject(rEnv.mpkCmdQueue,xValues,pValues,0,NULL,NULL); if (sync) clFinish( rEnv.mpkCmdQueue ); } return xValues; } void OpenclDevice::releaseMorphCLBuffers() { if (pixdCLIntermediate != NULL) clReleaseMemObject(pixdCLIntermediate); if (pixsCLBuffer != NULL) clReleaseMemObject(pixsCLBuffer); if (pixdCLBuffer != NULL) clReleaseMemObject(pixdCLBuffer); if (pixThBuffer != NULL) clReleaseMemObject(pixThBuffer); } int OpenclDevice::initMorphCLAllocations(l_int32 wpl, l_int32 h, PIX* pixs) { SetKernelEnv( &rEnv ); if (pixThBuffer != NULL) { pixsCLBuffer = allocateZeroCopyBuffer(rEnv, NULL, wpl*h, CL_MEM_ALLOC_HOST_PTR, &clStatus); //Get the output from ThresholdToPix operation clStatus = clEnqueueCopyBuffer(rEnv.mpkCmdQueue, pixThBuffer, pixsCLBuffer, 0, 0, sizeof(l_uint32) * wpl*h, 0, NULL, NULL); } else { //Get data from the source image l_uint32* srcdata = (l_uint32*) malloc(wpl*h*sizeof(l_uint32)); memcpy(srcdata, pixGetData(pixs), wpl*h*sizeof(l_uint32)); pixsCLBuffer = allocateZeroCopyBuffer(rEnv, srcdata, wpl*h, CL_MEM_USE_HOST_PTR, &clStatus); } pixdCLBuffer = allocateZeroCopyBuffer(rEnv, NULL, wpl*h, CL_MEM_ALLOC_HOST_PTR, &clStatus); pixdCLIntermediate = allocateZeroCopyBuffer(rEnv, NULL, wpl*h, CL_MEM_ALLOC_HOST_PTR, &clStatus); return (int)clStatus; } int OpenclDevice::InitEnv() { //PERF_COUNT_START("OD::InitEnv") // printf("[OD] OpenclDevice::InitEnv()\n"); #ifdef SAL_WIN32 while( 1 ) { if( 1 == LoadOpencl() ) break; } PERF_COUNT_SUB("LoadOpencl") #endif // sets up environment, compiles programs InitOpenclRunEnv_DeviceSelection( 0 ); //PERF_COUNT_SUB("called InitOpenclRunEnv_DS") //PERF_COUNT_END return 1; } int OpenclDevice::ReleaseOpenclRunEnv() { ReleaseOpenclEnv( &gpuEnv ); #ifdef SAL_WIN32 FreeOpenclDll(); #endif return 1; } inline int OpenclDevice::AddKernelConfig( int kCount, const char *kName ) { if ( kCount < 1 ) fprintf(stderr,"Error: ( KCount < 1 ) AddKernelConfig\n" ); strcpy( gpuEnv.mArrykernelNames[kCount-1], kName ); gpuEnv.mnKernelCount++; return 0; } int OpenclDevice::RegistOpenclKernel() { if ( !gpuEnv.mnIsUserCreated ) memset( &gpuEnv, 0, sizeof(gpuEnv) ); gpuEnv.mnFileCount = 0; //argc; gpuEnv.mnKernelCount = 0UL; AddKernelConfig( 1, (const char*) "oclAverageSub1" ); return 0; } int OpenclDevice::InitOpenclRunEnv_DeviceSelection( int argc ) { //PERF_COUNT_START("InitOpenclRunEnv_DS") if (!isInited) { // after programs compiled, selects best device //printf("[DS] InitOpenclRunEnv_DS::Calling performDeviceSelection()\n"); ds_device bestDevice_DS = getDeviceSelection( ); //PERF_COUNT_SUB("called getDeviceSelection()") cl_device_id bestDevice = bestDevice_DS.oclDeviceID; // overwrite global static GPUEnv with new device if (selectedDeviceIsOpenCL() ) { //printf("[DS] InitOpenclRunEnv_DS::Calling populateGPUEnvFromDevice() for selected device\n"); populateGPUEnvFromDevice( &gpuEnv, bestDevice ); gpuEnv.mnFileCount = 0; //argc; gpuEnv.mnKernelCount = 0UL; //PERF_COUNT_SUB("populate gpuEnv") CompileKernelFile(&gpuEnv, ""); //PERF_COUNT_SUB("CompileKernelFile") } else { //printf("[DS] InitOpenclRunEnv_DS::Skipping populateGPUEnvFromDevice() b/c native cpu selected\n"); } isInited = 1; } //PERF_COUNT_END return 0; } OpenclDevice::OpenclDevice() { //InitEnv(); } OpenclDevice::~OpenclDevice() { //ReleaseOpenclRunEnv(); } int OpenclDevice::ReleaseOpenclEnv( GPUEnv *gpuInfo ) { int i = 0; int clStatus = 0; if ( !isInited ) { return 1; } for ( i = 0; i < gpuEnv.mnFileCount; i++ ) { if ( gpuEnv.mpArryPrograms[i] ) { clStatus = clReleaseProgram( gpuEnv.mpArryPrograms[i] ); CHECK_OPENCL( clStatus, "clReleaseProgram" ); gpuEnv.mpArryPrograms[i] = NULL; } } if ( gpuEnv.mpCmdQueue ) { clReleaseCommandQueue( gpuEnv.mpCmdQueue ); gpuEnv.mpCmdQueue = NULL; } if ( gpuEnv.mpContext ) { clReleaseContext( gpuEnv.mpContext ); gpuEnv.mpContext = NULL; } isInited = 0; gpuInfo->mnIsUserCreated = 0; free( gpuInfo->mpArryDevsID ); return 1; } int OpenclDevice::BinaryGenerated( const char * clFileName, FILE ** fhandle ) { unsigned int i = 0; cl_int clStatus; int status = 0; char *str = NULL; FILE *fd = NULL; char fileName[256] = { 0 }, cl_name[128] = { 0 }; char deviceName[1024]; clStatus = clGetDeviceInfo( gpuEnv.mpArryDevsID[i], CL_DEVICE_NAME, sizeof(deviceName), deviceName, NULL ); CHECK_OPENCL( clStatus, "clGetDeviceInfo" ); str = (char*) strstr( clFileName, (char*) ".cl" ); memcpy( cl_name, clFileName, str - clFileName ); cl_name[str - clFileName] = '\0'; sprintf( fileName, "%s-%s.bin", cl_name, deviceName ); legalizeFileName(fileName); fd = fopen( fileName, "rb" ); status = ( fd != NULL ) ? 1 : 0; if ( fd != NULL ) { *fhandle = fd; } return status; } int OpenclDevice::CachedOfKernerPrg( const GPUEnv *gpuEnvCached, const char * clFileName ) { int i; for ( i = 0; i < gpuEnvCached->mnFileCount; i++ ) { if ( strcasecmp( gpuEnvCached->mArryKnelSrcFile[i], clFileName ) == 0 ) { if ( gpuEnvCached->mpArryPrograms[i] != NULL ) { return 1; } } } return 0; } int OpenclDevice::WriteBinaryToFile( const char* fileName, const char* birary, size_t numBytes ) { FILE *output = NULL; output = fopen( fileName, "wb" ); if ( output == NULL ) { return 0; } fwrite( birary, sizeof(char), numBytes, output ); fclose( output ); return 1; } int OpenclDevice::GeneratBinFromKernelSource( cl_program program, const char * clFileName ) { unsigned int i = 0; cl_int clStatus; size_t *binarySizes, numDevices=0; cl_device_id *mpArryDevsID; char **binaries, *str = NULL; clStatus = clGetProgramInfo( program, CL_PROGRAM_NUM_DEVICES, sizeof(numDevices), &numDevices, NULL ); CHECK_OPENCL( clStatus, "clGetProgramInfo" ); mpArryDevsID = (cl_device_id*) malloc( sizeof(cl_device_id) * numDevices ); if ( mpArryDevsID == NULL ) { return 0; } /* grab the handles to all of the devices in the program. */ clStatus = clGetProgramInfo( program, CL_PROGRAM_DEVICES, sizeof(cl_device_id) * numDevices, mpArryDevsID, NULL ); CHECK_OPENCL( clStatus, "clGetProgramInfo" ); /* figure out the sizes of each of the binaries. */ binarySizes = (size_t*) malloc( sizeof(size_t) * numDevices ); clStatus = clGetProgramInfo( program, CL_PROGRAM_BINARY_SIZES, sizeof(size_t) * numDevices, binarySizes, NULL ); CHECK_OPENCL( clStatus, "clGetProgramInfo" ); /* copy over all of the generated binaries. */ binaries = (char**) malloc( sizeof(char *) * numDevices ); if ( binaries == NULL ) { return 0; } for ( i = 0; i < numDevices; i++ ) { if ( binarySizes[i] != 0 ) { binaries[i] = (char*) malloc( sizeof(char) * binarySizes[i] ); if ( binaries[i] == NULL ) { return 0; } } else { binaries[i] = NULL; } } clStatus = clGetProgramInfo( program, CL_PROGRAM_BINARIES, sizeof(char *) * numDevices, binaries, NULL ); CHECK_OPENCL(clStatus,"clGetProgramInfo"); /* dump out each binary into its own separate file. */ for ( i = 0; i < numDevices; i++ ) { char fileName[256] = { 0 }, cl_name[128] = { 0 }; if ( binarySizes[i] != 0 ) { char deviceName[1024]; clStatus = clGetDeviceInfo(mpArryDevsID[i], CL_DEVICE_NAME, sizeof(deviceName), deviceName, NULL); CHECK_OPENCL( clStatus, "clGetDeviceInfo" ); str = (char*) strstr( clFileName, (char*) ".cl" ); memcpy( cl_name, clFileName, str - clFileName ); cl_name[str - clFileName] = '\0'; sprintf( fileName, "%s-%s.bin", cl_name, deviceName ); legalizeFileName(fileName); if ( !WriteBinaryToFile( fileName, binaries[i], binarySizes[i] ) ) { printf("[OD] write binary[%s] failed\n", fileName); return 0; } //else printf("[OD] write binary[%s] succesfully\n", fileName); } } // Release all resouces and memory for ( i = 0; i < numDevices; i++ ) { if ( binaries[i] != NULL ) { free( binaries[i] ); binaries[i] = NULL; } } if ( binaries != NULL ) { free( binaries ); binaries = NULL; } if ( binarySizes != NULL ) { free( binarySizes ); binarySizes = NULL; } if ( mpArryDevsID != NULL ) { free( mpArryDevsID ); mpArryDevsID = NULL; } return 1; } void copyIntBuffer( KernelEnv rEnv, cl_mem xValues, const l_uint32 *_pValues, size_t nElements, cl_int *pStatus ) { l_int32 *pValues = (l_int32 *)clEnqueueMapBuffer( rEnv.mpkCmdQueue, xValues, CL_TRUE, CL_MAP_WRITE, 0, nElements * sizeof(l_int32), 0, NULL, NULL, NULL ); clFinish( rEnv.mpkCmdQueue ); if (_pValues != NULL) { for ( int i = 0; i < (int)nElements; i++ ) pValues[i] = (l_int32)_pValues[i]; } clEnqueueUnmapMemObject(rEnv.mpkCmdQueue,xValues,pValues,0,NULL,NULL); //clFinish( rEnv.mpkCmdQueue ); return; } int OpenclDevice::CompileKernelFile( GPUEnv *gpuInfo, const char *buildOption ) { //PERF_COUNT_START("CompileKernelFile") cl_int clStatus = 0; size_t length; char *buildLog = NULL, *binary; const char *source; size_t source_size[1]; int b_error, binary_status, binaryExisted, idx; size_t numDevices; cl_device_id *mpArryDevsID; FILE *fd, *fd1; const char* filename = "kernel.cl"; //fprintf(stderr, "[OD] CompileKernelFile ... \n"); if ( CachedOfKernerPrg(gpuInfo, filename) == 1 ) { return 1; } idx = gpuInfo->mnFileCount; source = kernel_src; source_size[0] = strlen( source ); binaryExisted = 0; binaryExisted = BinaryGenerated( filename, &fd ); // don't check for binary during microbenchmark //PERF_COUNT_SUB("BinaryGenerated") if ( binaryExisted == 1 ) { clStatus = clGetContextInfo( gpuInfo->mpContext, CL_CONTEXT_NUM_DEVICES, sizeof(numDevices), &numDevices, NULL ); CHECK_OPENCL( clStatus, "clGetContextInfo" ); mpArryDevsID = (cl_device_id*) malloc( sizeof(cl_device_id) * numDevices ); if ( mpArryDevsID == NULL ) { return 0; } //PERF_COUNT_SUB("get numDevices") b_error = 0; length = 0; b_error |= fseek( fd, 0, SEEK_END ) < 0; b_error |= ( length = ftell(fd) ) <= 0; b_error |= fseek( fd, 0, SEEK_SET ) < 0; if ( b_error ) { return 0; } binary = (char*) malloc( length + 2 ); if ( !binary ) { return 0; } memset( binary, 0, length + 2 ); b_error |= fread( binary, 1, length, fd ) != length; fclose( fd ); //PERF_COUNT_SUB("read file") fd = NULL; // grab the handles to all of the devices in the context. clStatus = clGetContextInfo( gpuInfo->mpContext, CL_CONTEXT_DEVICES, sizeof( cl_device_id ) * numDevices, mpArryDevsID, NULL ); CHECK_OPENCL( clStatus, "clGetContextInfo" ); //PERF_COUNT_SUB("get devices") //fprintf(stderr, "[OD] Create kernel from binary\n"); gpuInfo->mpArryPrograms[idx] = clCreateProgramWithBinary( gpuInfo->mpContext,numDevices, mpArryDevsID, &length, (const unsigned char**) &binary, &binary_status, &clStatus ); CHECK_OPENCL( clStatus, "clCreateProgramWithBinary" ); //PERF_COUNT_SUB("clCreateProgramWithBinary") free( binary ); free( mpArryDevsID ); mpArryDevsID = NULL; //PERF_COUNT_SUB("binaryExisted") } else { // create a CL program using the kernel source //fprintf(stderr, "[OD] Create kernel from source\n"); gpuInfo->mpArryPrograms[idx] = clCreateProgramWithSource( gpuInfo->mpContext, 1, &source, source_size, &clStatus); CHECK_OPENCL( clStatus, "clCreateProgramWithSource" ); //PERF_COUNT_SUB("!binaryExisted") } if ( gpuInfo->mpArryPrograms[idx] == (cl_program) NULL ) { return 0; } //char options[512]; // create a cl program executable for all the devices specified //printf("[OD] BuildProgram.\n"); PERF_COUNT_START("OD::CompileKernel::clBuildProgram") if (!gpuInfo->mnIsUserCreated) { clStatus = clBuildProgram(gpuInfo->mpArryPrograms[idx], 1, gpuInfo->mpArryDevsID, buildOption, NULL, NULL); //PERF_COUNT_SUB("clBuildProgram notUserCreated") } else { clStatus = clBuildProgram(gpuInfo->mpArryPrograms[idx], 1, &(gpuInfo->mpDevID), buildOption, NULL, NULL); //PERF_COUNT_SUB("clBuildProgram isUserCreated") } PERF_COUNT_END if ( clStatus != CL_SUCCESS ) { printf ("BuildProgram error!\n"); if ( !gpuInfo->mnIsUserCreated ) { clStatus = clGetProgramBuildInfo( gpuInfo->mpArryPrograms[idx], gpuInfo->mpArryDevsID[0], CL_PROGRAM_BUILD_LOG, 0, NULL, &length ); } else { clStatus = clGetProgramBuildInfo( gpuInfo->mpArryPrograms[idx], gpuInfo->mpDevID, CL_PROGRAM_BUILD_LOG, 0, NULL, &length); } if ( clStatus != CL_SUCCESS ) { printf("opencl create build log fail\n"); return 0; } buildLog = (char*) malloc( length ); if ( buildLog == (char*) NULL ) { return 0; } if ( !gpuInfo->mnIsUserCreated ) { clStatus = clGetProgramBuildInfo( gpuInfo->mpArryPrograms[idx], gpuInfo->mpArryDevsID[0], CL_PROGRAM_BUILD_LOG, length, buildLog, &length ); } else { clStatus = clGetProgramBuildInfo( gpuInfo->mpArryPrograms[idx], gpuInfo->mpDevID, CL_PROGRAM_BUILD_LOG, length, buildLog, &length ); } if ( clStatus != CL_SUCCESS ) { printf("opencl program build info fail\n"); return 0; } fd1 = fopen( "kernel-build.log", "w+" ); if ( fd1 != NULL ) { fwrite( buildLog, sizeof(char), length, fd1 ); fclose( fd1 ); } free( buildLog ); //PERF_COUNT_SUB("build error log") return 0; } strcpy( gpuInfo->mArryKnelSrcFile[idx], filename ); //PERF_COUNT_SUB("strcpy") if ( binaryExisted == 0 ) { GeneratBinFromKernelSource( gpuInfo->mpArryPrograms[idx], filename ); PERF_COUNT_SUB("GenerateBinFromKernelSource") } gpuInfo->mnFileCount += 1; //PERF_COUNT_END return 1; } l_uint32* OpenclDevice::pixReadFromTiffKernel(l_uint32 *tiffdata,l_int32 w,l_int32 h,l_int32 wpl,l_uint32 *line) { PERF_COUNT_START("pixReadFromTiffKernel") cl_int clStatus; KernelEnv rEnv; size_t globalThreads[2]; size_t localThreads[2]; int gsize; cl_mem valuesCl; cl_mem outputCl; //global and local work dimensions for Horizontal pass gsize = (w + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; localThreads[0] = GROUPSIZE_X; localThreads[1] = GROUPSIZE_Y; SetKernelEnv( &rEnv ); l_uint32 *pResult = (l_uint32 *)malloc(w*h * sizeof(l_uint32)); rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "composeRGBPixel", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel"); //Allocate input and output OCL buffers valuesCl = allocateZeroCopyBuffer(rEnv, tiffdata, w*h, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, &clStatus); outputCl = allocateZeroCopyBuffer(rEnv, pResult, w*h, CL_MEM_WRITE_ONLY | CL_MEM_USE_HOST_PTR, &clStatus); //Kernel arguments clStatus = clSetKernelArg( rEnv.mpkKernel, 0, sizeof(cl_mem), (void *)&valuesCl ); CHECK_OPENCL( clStatus, "clSetKernelArg"); clStatus = clSetKernelArg( rEnv.mpkKernel, 1, sizeof(w), (void *)&w ); CHECK_OPENCL( clStatus, "clSetKernelArg" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 2, sizeof(h), (void *)&h ); CHECK_OPENCL( clStatus, "clSetKernelArg" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 3, sizeof(wpl), (void *)&wpl ); CHECK_OPENCL( clStatus, "clSetKernelArg" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 4, sizeof(cl_mem), (void *)&outputCl ); CHECK_OPENCL( clStatus, "clSetKernelArg"); //Kernel enqueue PERF_COUNT_SUB("before") clStatus = clEnqueueNDRangeKernel( rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL ); CHECK_OPENCL( clStatus, "clEnqueueNDRangeKernel" ); /* map results back from gpu */ void *ptr = clEnqueueMapBuffer(rEnv.mpkCmdQueue, outputCl, CL_TRUE, CL_MAP_READ, 0, w*h * sizeof(l_uint32), 0, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "clEnqueueMapBuffer outputCl"); clEnqueueUnmapMemObject(rEnv.mpkCmdQueue, outputCl, ptr, 0, NULL, NULL); //Sync clFinish( rEnv.mpkCmdQueue ); PERF_COUNT_SUB("kernel & map") PERF_COUNT_END return pResult; } PIX * OpenclDevice::pixReadTiffCl ( const char *filename, l_int32 n ) { PERF_COUNT_START("pixReadTiffCL") FILE *fp; PIX *pix; //printf("pixReadTiffCl file"); PROCNAME("pixReadTiff"); if (!filename) return (PIX *)ERROR_PTR("filename not defined", procName, NULL); if ((fp = fopenReadStream(filename)) == NULL) return (PIX *)ERROR_PTR("image file not found", procName, NULL); if ((pix = pixReadStreamTiffCl(fp, n)) == NULL) { fclose(fp); return (PIX *)ERROR_PTR("pix not read", procName, NULL); } fclose(fp); PERF_COUNT_END return pix; } TIFF * OpenclDevice::fopenTiffCl(FILE *fp, const char *modestring) { l_int32 fd; PROCNAME("fopenTiff"); if (!fp) return (TIFF *)ERROR_PTR("stream not opened", procName, NULL); if (!modestring) return (TIFF *)ERROR_PTR("modestring not defined", procName, NULL); if ((fd = fileno(fp)) < 0) return (TIFF *)ERROR_PTR("invalid file descriptor", procName, NULL); lseek(fd, 0, SEEK_SET); return TIFFFdOpen(fd, "TIFFstream", modestring); } l_int32 OpenclDevice::getTiffStreamResolutionCl(TIFF *tif, l_int32 *pxres, l_int32 *pyres) { l_uint16 resunit; l_int32 foundxres, foundyres; l_float32 fxres, fyres; PROCNAME("getTiffStreamResolution"); if (!tif) return ERROR_INT("tif not opened", procName, 1); if (!pxres || !pyres) return ERROR_INT("&xres and &yres not both defined", procName, 1); *pxres = *pyres = 0; TIFFGetFieldDefaulted(tif, TIFFTAG_RESOLUTIONUNIT, &resunit); foundxres = TIFFGetField(tif, TIFFTAG_XRESOLUTION, &fxres); foundyres = TIFFGetField(tif, TIFFTAG_YRESOLUTION, &fyres); if (!foundxres && !foundyres) return 1; if (!foundxres && foundyres) fxres = fyres; else if (foundxres && !foundyres) fyres = fxres; if (resunit == RESUNIT_CENTIMETER) { /* convert to ppi */ *pxres = (l_int32)(2.54 * fxres + 0.5); *pyres = (l_int32)(2.54 * fyres + 0.5); } else { *pxres = (l_int32)fxres; *pyres = (l_int32)fyres; } return 0; } struct L_Memstream { l_uint8 *buffer; /* expands to hold data when written to; */ /* fixed size when read from. */ size_t bufsize; /* current size allocated when written to; */ /* fixed size of input data when read from. */ size_t offset; /* byte offset from beginning of buffer. */ size_t hw; /* high-water mark; max bytes in buffer. */ l_uint8 **poutdata; /* input param for writing; data goes here. */ size_t *poutsize; /* input param for writing; data size goes here. */ }; typedef struct L_Memstream L_MEMSTREAM; /* These are static functions for memory I/O */ static L_MEMSTREAM *memstreamCreateForRead(l_uint8 *indata, size_t pinsize); static L_MEMSTREAM *memstreamCreateForWrite(l_uint8 **poutdata, size_t *poutsize); static tsize_t tiffReadCallback(thandle_t handle, tdata_t data, tsize_t length); static tsize_t tiffWriteCallback(thandle_t handle, tdata_t data, tsize_t length); static toff_t tiffSeekCallback(thandle_t handle, toff_t offset, l_int32 whence); static l_int32 tiffCloseCallback(thandle_t handle); static toff_t tiffSizeCallback(thandle_t handle); static l_int32 tiffMapCallback(thandle_t handle, tdata_t *data, toff_t *length); static void tiffUnmapCallback(thandle_t handle, tdata_t data, toff_t length); static L_MEMSTREAM * memstreamCreateForRead(l_uint8 *indata, size_t insize) { L_MEMSTREAM *mstream; mstream = (L_MEMSTREAM *)CALLOC(1, sizeof(L_MEMSTREAM)); mstream->buffer = indata; /* handle to input data array */ mstream->bufsize = insize; /* amount of input data */ mstream->hw = insize; /* high-water mark fixed at input data size */ mstream->offset = 0; /* offset always starts at 0 */ return mstream; } static L_MEMSTREAM * memstreamCreateForWrite(l_uint8 **poutdata, size_t *poutsize) { L_MEMSTREAM *mstream; mstream = (L_MEMSTREAM *)CALLOC(1, sizeof(L_MEMSTREAM)); mstream->buffer = (l_uint8 *)CALLOC(8 * 1024, 1); mstream->bufsize = 8 * 1024; mstream->poutdata = poutdata; /* used only at end of write */ mstream->poutsize = poutsize; /* ditto */ mstream->hw = mstream->offset = 0; return mstream; } static tsize_t tiffReadCallback(thandle_t handle, tdata_t data, tsize_t length) { L_MEMSTREAM *mstream; size_t amount; mstream = (L_MEMSTREAM *)handle; amount = L_MIN((size_t)length, mstream->hw - mstream->offset); memcpy(data, mstream->buffer + mstream->offset, amount); mstream->offset += amount; return amount; } static tsize_t tiffWriteCallback(thandle_t handle, tdata_t data, tsize_t length) { L_MEMSTREAM *mstream; size_t newsize; /* reallocNew() uses calloc to initialize the array. * If malloc is used instead, for some of the encoding methods, * not all the data in 'bufsize' bytes in the buffer will * have been initialized by the end of the compression. */ mstream = (L_MEMSTREAM *)handle; if (mstream->offset + length > mstream->bufsize) { newsize = 2 * (mstream->offset + length); mstream->buffer = (l_uint8 *)reallocNew((void **)&mstream->buffer, mstream->offset, newsize); mstream->bufsize = newsize; } memcpy(mstream->buffer + mstream->offset, data, length); mstream->offset += length; mstream->hw = L_MAX(mstream->offset, mstream->hw); return length; } static toff_t tiffSeekCallback(thandle_t handle, toff_t offset, l_int32 whence) { L_MEMSTREAM *mstream; PROCNAME("tiffSeekCallback"); mstream = (L_MEMSTREAM *)handle; switch (whence) { case SEEK_SET: /* fprintf(stderr, "seek_set: offset = %d\n", offset); */ mstream->offset = offset; break; case SEEK_CUR: /* fprintf(stderr, "seek_cur: offset = %d\n", offset); */ mstream->offset += offset; break; case SEEK_END: /* fprintf(stderr, "seek end: hw = %d, offset = %d\n", mstream->hw, offset); */ mstream->offset = mstream->hw - offset; /* offset >= 0 */ break; default: return (toff_t)ERROR_INT("bad whence value", procName, mstream->offset); } return mstream->offset; } static l_int32 tiffCloseCallback(thandle_t handle) { L_MEMSTREAM *mstream; mstream = (L_MEMSTREAM *)handle; if (mstream->poutdata) { /* writing: save the output data */ *mstream->poutdata = mstream->buffer; *mstream->poutsize = mstream->hw; } FREE(mstream); /* never free the buffer! */ return 0; } static toff_t tiffSizeCallback(thandle_t handle) { L_MEMSTREAM *mstream; mstream = (L_MEMSTREAM *)handle; return mstream->hw; } static l_int32 tiffMapCallback(thandle_t handle, tdata_t *data, toff_t *length) { L_MEMSTREAM *mstream; mstream = (L_MEMSTREAM *)handle; *data = mstream->buffer; *length = mstream->hw; return 0; } static void tiffUnmapCallback(thandle_t handle, tdata_t data, toff_t length) { return; } /*! * fopenTiffMemstream() * * Input: filename (for error output; can be "") * operation ("w" for write, "r" for read) * &data ( written data) * &datasize ( size of written data) * Return: tiff (data structure, opened for write to memory) * * Notes: * (1) This wraps up a number of callbacks for either: * * reading from tiff in memory buffer --> pix * * writing from pix --> tiff in memory buffer * (2) After use, the memstream is automatically destroyed when * TIFFClose() is called. TIFFCleanup() doesn't free the memstream. */ static TIFF * fopenTiffMemstream(const char *filename, const char *operation, l_uint8 **pdata, size_t *pdatasize) { L_MEMSTREAM *mstream; PROCNAME("fopenTiffMemstream"); if (!filename) return (TIFF *)ERROR_PTR("filename not defined", procName, NULL); if (!operation) return (TIFF *)ERROR_PTR("operation not defined", procName, NULL); if (!pdata) return (TIFF *)ERROR_PTR("&data not defined", procName, NULL); if (!pdatasize) return (TIFF *)ERROR_PTR("&datasize not defined", procName, NULL); if (!strcmp(operation, "r") && !strcmp(operation, "w")) return (TIFF *)ERROR_PTR("operation not 'r' or 'w'}", procName, NULL); if (!strcmp(operation, "r")) mstream = memstreamCreateForRead(*pdata, *pdatasize); else mstream = memstreamCreateForWrite(pdata, pdatasize); return TIFFClientOpen(filename, operation, mstream, tiffReadCallback, tiffWriteCallback, tiffSeekCallback, tiffCloseCallback, tiffSizeCallback, tiffMapCallback, tiffUnmapCallback); } PIX * OpenclDevice::pixReadMemTiffCl(const l_uint8 *data,size_t size,l_int32 n) { l_int32 i, pagefound; PIX *pix; TIFF *tif; //L_MEMSTREAM *memStream; PROCNAME("pixReadMemTiffCl"); if (!data) return (PIX *)ERROR_PTR("data pointer is NULL", procName, NULL); if ((tif = fopenTiffMemstream("", "r", (l_uint8 **)&data, &size)) == NULL) return (PIX *)ERROR_PTR("tif not opened", procName, NULL); pagefound = FALSE; pix = NULL; for (i = 0; i < MAX_PAGES_IN_TIFF_FILE; i++) { if (i == n) { pagefound = TRUE; if ((pix = pixReadFromTiffStreamCl(tif)) == NULL) { TIFFCleanup(tif); return (PIX *)ERROR_PTR("pix not read", procName, NULL); } break; } if (TIFFReadDirectory(tif) == 0) break; } if (pagefound == FALSE) { L_WARNING("tiff page %d not found", procName); TIFFCleanup(tif); return NULL; } TIFFCleanup(tif); return pix; } PIX * OpenclDevice::pixReadStreamTiffCl(FILE *fp, l_int32 n) { l_int32 i, pagefound; PIX *pix; TIFF *tif; PROCNAME("pixReadStreamTiff"); if (!fp) return (PIX *)ERROR_PTR("stream not defined", procName, NULL); if ((tif = fopenTiffCl(fp, "rb")) == NULL) return (PIX *)ERROR_PTR("tif not opened", procName, NULL); pagefound = FALSE; pix = NULL; for (i = 0; i < MAX_PAGES_IN_TIFF_FILE; i++) { if (i == n) { pagefound = TRUE; if ((pix = pixReadFromTiffStreamCl(tif)) == NULL) { TIFFCleanup(tif); return (PIX *)ERROR_PTR("pix not read", procName, NULL); } break; } if (TIFFReadDirectory(tif) == 0) break; } if (pagefound == FALSE) { L_WARNING("tiff page %d not found", procName, n); TIFFCleanup(tif); return NULL; } TIFFCleanup(tif); return pix; } static l_int32 getTiffCompressedFormat(l_uint16 tiffcomp) { l_int32 comptype; switch (tiffcomp) { case COMPRESSION_CCITTFAX4: comptype = IFF_TIFF_G4; break; case COMPRESSION_CCITTFAX3: comptype = IFF_TIFF_G3; break; case COMPRESSION_CCITTRLE: comptype = IFF_TIFF_RLE; break; case COMPRESSION_PACKBITS: comptype = IFF_TIFF_PACKBITS; break; case COMPRESSION_LZW: comptype = IFF_TIFF_LZW; break; case COMPRESSION_ADOBE_DEFLATE: comptype = IFF_TIFF_ZIP; break; default: comptype = IFF_TIFF; break; } return comptype; } void compare(l_uint32 *cpu, l_uint32 *gpu,int size) { for(int i=0;i 32) return (PIX *)ERROR_PTR("can't handle bpp > 32", procName, NULL); if (spp == 1) d = bps; else if (spp == 3 || spp == 4) d = 32; else return (PIX *)ERROR_PTR("spp not in set {1,3,4}", procName, NULL); TIFFGetField(tif, TIFFTAG_IMAGEWIDTH, &w); TIFFGetField(tif, TIFFTAG_IMAGELENGTH, &h); tiffbpl = TIFFScanlineSize(tif); if ((pix = pixCreate(w, h, d)) == NULL) return (PIX *)ERROR_PTR("pix not made", procName, NULL); data = (l_uint8 *)pixGetData(pix); wpl = pixGetWpl(pix); bpl = 4 * wpl; if (spp == 1) { if ((linebuf = (l_uint8 *)CALLOC(tiffbpl + 1, sizeof(l_uint8))) == NULL) return (PIX *)ERROR_PTR("calloc fail for linebuf", procName, NULL); for (i = 0 ; i < h ; i++) { if (TIFFReadScanline(tif, linebuf, i, 0) < 0) { FREE(linebuf); pixDestroy(&pix); return (PIX *)ERROR_PTR("line read fail", procName, NULL); } memcpy((char *)data, (char *)linebuf, tiffbpl); data += bpl; } if (bps <= 8) pixEndianByteSwap(pix); else pixEndianTwoByteSwap(pix); FREE(linebuf); } else { if ((tiffdata = (l_uint32 *)CALLOC(w * h, sizeof(l_uint32))) == NULL) { pixDestroy(&pix); return (PIX *)ERROR_PTR("calloc fail for tiffdata", procName, NULL); } if (!TIFFReadRGBAImageOriented(tif, w, h, (uint32 *)tiffdata, ORIENTATION_TOPLEFT, 0)) { FREE(tiffdata); pixDestroy(&pix); return (PIX *)ERROR_PTR("failed to read tiffdata", procName, NULL); } line = pixGetData(pix); //Invoke the OpenCL kernel for pixReadFromTiff l_uint32* output_gpu=pixReadFromTiffKernel(tiffdata,w,h,wpl,line); pixSetData(pix, output_gpu); // pix already has data allocated, it now points to output_gpu? FREE(tiffdata); FREE(line); //FREE(output_gpu); } if (getTiffStreamResolutionCl(tif, &xres, &yres) == 0) { pixSetXRes(pix, xres); pixSetYRes(pix, yres); } TIFFGetFieldDefaulted(tif, TIFFTAG_COMPRESSION, &tiffcomp); comptype = getTiffCompressedFormat(tiffcomp); pixSetInputFormat(pix, comptype); if (TIFFGetField(tif, TIFFTAG_COLORMAP, &redmap, &greenmap, &bluemap)) { if ((cmap = pixcmapCreate(bps)) == NULL) { pixDestroy(&pix); return (PIX *)ERROR_PTR("cmap not made", procName, NULL); } ncolors = 1 << bps; for (i = 0; i < ncolors; i++) pixcmapAddColor(cmap, redmap[i] >> 8, greenmap[i] >> 8, bluemap[i] >> 8); pixSetColormap(pix, cmap); } else { if (!TIFFGetField(tif, TIFFTAG_PHOTOMETRIC, &photometry)) { if (tiffcomp == COMPRESSION_CCITTFAX3 || tiffcomp == COMPRESSION_CCITTFAX4 || tiffcomp == COMPRESSION_CCITTRLE || tiffcomp == COMPRESSION_CCITTRLEW) { photometry = PHOTOMETRIC_MINISWHITE; } else photometry = PHOTOMETRIC_MINISBLACK; } if ((d == 1 && photometry == PHOTOMETRIC_MINISBLACK) || (d == 8 && photometry == PHOTOMETRIC_MINISWHITE)) pixInvert(pix, pix); } if (TIFFGetField(tif, TIFFTAG_ORIENTATION, &orientation)) { if (orientation >= 1 && orientation <= 8) { struct tiff_transform *transform = &tiff_orientation_transforms[orientation - 1]; if (transform->vflip) pixFlipTB(pix, pix); if (transform->hflip) pixFlipLR(pix, pix); if (transform->rotate) { PIX *oldpix = pix; pix = pixRotate90(oldpix, transform->rotate); pixDestroy(&oldpix); } } } return pix; } //Morphology Dilate operation for 5x5 structuring element. Invokes the relevant OpenCL kernels cl_int pixDilateCL_55(l_int32 wpl, l_int32 h) { size_t globalThreads[2]; cl_mem pixtemp; cl_int status; int gsize; size_t localThreads[2]; //Horizontal pass gsize = (wpl*h + GROUPSIZE_HMORX - 1)/ GROUPSIZE_HMORX * GROUPSIZE_HMORX; globalThreads[0] = gsize; globalThreads[1] = GROUPSIZE_HMORY; localThreads[0] = GROUPSIZE_HMORX; localThreads[1] = GROUPSIZE_HMORY; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoDilateHor_5x5", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); //Swap source and dest buffers pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; //Vertical gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; localThreads[0] = GROUPSIZE_X; localThreads[1] = GROUPSIZE_Y; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoDilateVer_5x5", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); return status; } //Morphology Erode operation for 5x5 structuring element. Invokes the relevant OpenCL kernels cl_int pixErodeCL_55(l_int32 wpl, l_int32 h) { size_t globalThreads[2]; cl_mem pixtemp; cl_int status; int gsize; l_uint32 fwmask, lwmask; size_t localThreads[2]; lwmask = lmask32[32 - 2]; fwmask = rmask32[32 - 2]; //Horizontal pass gsize = (wpl*h + GROUPSIZE_HMORX - 1)/ GROUPSIZE_HMORX * GROUPSIZE_HMORX; globalThreads[0] = gsize; globalThreads[1] = GROUPSIZE_HMORY; localThreads[0] = GROUPSIZE_HMORX; localThreads[1] = GROUPSIZE_HMORY; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoErodeHor_5x5", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); //Swap source and dest buffers pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; //Vertical gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; localThreads[0] = GROUPSIZE_X; localThreads[1] = GROUPSIZE_Y; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoErodeVer_5x5", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(fwmask), (const void *)&fwmask); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(lwmask), (const void *)&lwmask); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); return status; } //Morphology Dilate operation. Invokes the relevant OpenCL kernels cl_int pixDilateCL(l_int32 hsize, l_int32 vsize, l_int32 wpl, l_int32 h) { l_int32 xp, yp, xn, yn; SEL* sel; size_t globalThreads[2]; cl_mem pixtemp; cl_int status; int gsize; size_t localThreads[2]; char isEven; OpenclDevice::SetKernelEnv( &rEnv ); if (hsize == 5 && vsize == 5) { //Specific case for 5x5 status = pixDilateCL_55(wpl, h); return status; } sel = selCreateBrick(vsize, hsize, vsize / 2, hsize / 2, SEL_HIT); selFindMaxTranslations(sel, &xp, &yp, &xn, &yn); selDestroy(&sel); //global and local work dimensions for Horizontal pass gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; localThreads[0] = GROUPSIZE_X; localThreads[1] = GROUPSIZE_Y; if (xp > 31 || xn > 31) { //Generic case. rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoDilateHor", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(xp), (const void *)&xp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(xn), (const void *)&xn); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); if (yp > 0 || yn > 0) { pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; } } else if (xp > 0 || xn > 0 ) { //Specfic Horizontal pass kernel for half width < 32 rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoDilateHor_32word", &status ); isEven = (xp != xn); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(xp), (const void *)&xp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(isEven), (const void *)&isEven); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); if (yp > 0 || yn > 0) { pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; } } if (yp > 0 || yn > 0) { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoDilateVer", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(yp), (const void *)&yp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(yn), (const void *)&yn); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); } return status; } //Morphology Erode operation. Invokes the relevant OpenCL kernels cl_int pixErodeCL(l_int32 hsize, l_int32 vsize, l_uint32 wpl, l_uint32 h) { l_int32 xp, yp, xn, yn; SEL* sel; size_t globalThreads[2]; size_t localThreads[2]; cl_mem pixtemp; cl_int status; int gsize; char isAsymmetric = (MORPH_BC == ASYMMETRIC_MORPH_BC); l_uint32 rwmask, lwmask; char isEven; sel = selCreateBrick(vsize, hsize, vsize / 2, hsize / 2, SEL_HIT); selFindMaxTranslations(sel, &xp, &yp, &xn, &yn); selDestroy(&sel); OpenclDevice::SetKernelEnv( &rEnv ); if (hsize == 5 && vsize == 5 && isAsymmetric) { //Specific kernel for 5x5 status = pixErodeCL_55(wpl, h); return status; } rwmask = rmask32[32 - (xp & 31)]; lwmask = lmask32[32 - (xn & 31)]; //global and local work dimensions for Horizontal pass gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; localThreads[0] = GROUPSIZE_X; localThreads[1] = GROUPSIZE_Y; //Horizontal Pass if (xp > 31 || xn > 31 ) { //Generic case. rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoErodeHor", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(xp), (const void *)&xp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(xn), (const void *)&xn); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 6, sizeof(isAsymmetric), (const void *)&isAsymmetric); status = clSetKernelArg(rEnv.mpkKernel, 7, sizeof(rwmask), (const void *)&rwmask); status = clSetKernelArg(rEnv.mpkKernel, 8, sizeof(lwmask), (const void *)&lwmask); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); if (yp > 0 || yn > 0) { pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; } } else if (xp > 0 || xn > 0) { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoErodeHor_32word", &status ); isEven = (xp != xn); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(xp), (const void *)&xp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(isAsymmetric), (const void *)&isAsymmetric); status = clSetKernelArg(rEnv.mpkKernel, 6, sizeof(rwmask), (const void *)&rwmask); status = clSetKernelArg(rEnv.mpkKernel, 7, sizeof(lwmask), (const void *)&lwmask); status = clSetKernelArg(rEnv.mpkKernel, 8, sizeof(isEven), (const void *)&isEven); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); if (yp > 0 || yn > 0) { pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; } } //Vertical Pass if (yp > 0 || yn > 0) { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "morphoErodeVer", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &pixsCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &pixdCLBuffer); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(yp), (const void *)&yp); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clSetKernelArg(rEnv.mpkKernel, 5, sizeof(isAsymmetric), (const void *)&isAsymmetric); status = clSetKernelArg(rEnv.mpkKernel, 6, sizeof(yn), (const void *)&yn); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); } return status; } // OpenCL implementation of Morphology Dilate //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixDilateBrickCL(PIX *pixd, PIX *pixs, l_int32 hsize, l_int32 vsize, bool reqDataCopy = false) { l_uint32 wpl, h; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); clStatus = pixDilateCL(hsize, vsize, wpl, h); if (reqDataCopy) { pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs, wpl*h, CL_MAP_READ, false); } return pixd; } // OpenCL implementation of Morphology Erode //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixErodeBrickCL(PIX *pixd, PIX *pixs, l_int32 hsize, l_int32 vsize, bool reqDataCopy = false) { l_uint32 wpl, h; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); clStatus = pixErodeCL(hsize, vsize, wpl, h); if (reqDataCopy) { pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs, wpl*h, CL_MAP_READ); } return pixd; } //Morphology Open operation. Invokes the relevant OpenCL kernels cl_int pixOpenCL(l_int32 hsize, l_int32 vsize, l_int32 wpl, l_int32 h) { cl_int status; cl_mem pixtemp; //Erode followed by Dilate status = pixErodeCL(hsize, vsize, wpl, h); pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; status = pixDilateCL(hsize, vsize, wpl, h); return status; } //Morphology Close operation. Invokes the relevant OpenCL kernels cl_int pixCloseCL(l_int32 hsize, l_int32 vsize, l_int32 wpl, l_int32 h) { cl_int status; cl_mem pixtemp; //Dilate followed by Erode status = pixDilateCL(hsize, vsize, wpl, h); pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; status = pixErodeCL(hsize, vsize, wpl, h); return status; } // OpenCL implementation of Morphology Close //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixCloseBrickCL(PIX *pixd, PIX *pixs, l_int32 hsize, l_int32 vsize, bool reqDataCopy = false) { l_uint32 wpl, h; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); clStatus = pixCloseCL(hsize, vsize, wpl, h); if (reqDataCopy) { pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs, wpl*h, CL_MAP_READ); } return pixd; } // OpenCL implementation of Morphology Open //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixOpenBrickCL(PIX *pixd, PIX *pixs, l_int32 hsize, l_int32 vsize, bool reqDataCopy = false) { l_uint32 wpl, h; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); clStatus = pixOpenCL(hsize, vsize, wpl, h); if (reqDataCopy) { pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs, wpl*h, CL_MAP_READ); } return pixd; } //pix OR operation: outbuffer = buffer1 | buffer2 cl_int pixORCL_work(l_uint32 wpl, l_uint32 h, cl_mem buffer1, cl_mem buffer2, cl_mem outbuffer) { cl_int status; size_t globalThreads[2]; int gsize; size_t localThreads[] = {GROUPSIZE_X, GROUPSIZE_Y}; gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "pixOR", &status ); status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &buffer1); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &buffer2); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(cl_mem), &outbuffer); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); return status; } //pix AND operation: outbuffer = buffer1 & buffer2 cl_int pixANDCL_work(l_uint32 wpl, l_uint32 h, cl_mem buffer1, cl_mem buffer2, cl_mem outbuffer) { cl_int status; size_t globalThreads[2]; int gsize; size_t localThreads[] = {GROUPSIZE_X, GROUPSIZE_Y}; gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "pixAND", &status ); // Enqueue a kernel run call. status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &buffer1); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &buffer2); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(cl_mem), &outbuffer); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(h), (const void *)&h); status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); return status; } //output = buffer1 & ~(buffer2) cl_int pixSubtractCL_work(l_uint32 wpl, l_uint32 h, cl_mem buffer1, cl_mem buffer2, cl_mem outBuffer = NULL) { cl_int status; size_t globalThreads[2]; int gsize; size_t localThreads[] = {GROUPSIZE_X, GROUPSIZE_Y}; gsize = (wpl + GROUPSIZE_X - 1)/ GROUPSIZE_X * GROUPSIZE_X; globalThreads[0] = gsize; gsize = (h + GROUPSIZE_Y - 1)/ GROUPSIZE_Y * GROUPSIZE_Y; globalThreads[1] = gsize; if (outBuffer != NULL) { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "pixSubtract", &status ); } else { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "pixSubtract_inplace", &status ); } // Enqueue a kernel run call. status = clSetKernelArg(rEnv.mpkKernel, 0, sizeof(cl_mem), &buffer1); status = clSetKernelArg(rEnv.mpkKernel, 1, sizeof(cl_mem), &buffer2); status = clSetKernelArg(rEnv.mpkKernel, 2, sizeof(wpl), (const void *)&wpl); status = clSetKernelArg(rEnv.mpkKernel, 3, sizeof(h), (const void *)&h); if (outBuffer != NULL) { status = clSetKernelArg(rEnv.mpkKernel, 4, sizeof(cl_mem), (const void *)&outBuffer); } status = clEnqueueNDRangeKernel(rEnv.mpkCmdQueue, rEnv.mpkKernel, 2, NULL, globalThreads, localThreads, 0, NULL, NULL); return status; } // OpenCL implementation of Subtract pix //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixSubtractCL(PIX *pixd, PIX *pixs1, PIX *pixs2, bool reqDataCopy = false) { l_uint32 wpl, h; PROCNAME("pixSubtractCL"); if (!pixs1) return (PIX *)ERROR_PTR("pixs1 not defined", procName, pixd); if (!pixs2) return (PIX *)ERROR_PTR("pixs2 not defined", procName, pixd); if (pixGetDepth(pixs1) != pixGetDepth(pixs2)) return (PIX *)ERROR_PTR("depths of pixs* unequal", procName, pixd); #if EQUAL_SIZE_WARNING if (!pixSizesEqual(pixs1, pixs2)) L_WARNING("pixs1 and pixs2 not equal sizes", procName); #endif /* EQUAL_SIZE_WARNING */ wpl = pixGetWpl(pixs1); h = pixGetHeight(pixs1); clStatus = pixSubtractCL_work(wpl, h, pixdCLBuffer, pixsCLBuffer); if (reqDataCopy) { //Read back output data from OCL buffer to cpu pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs1, wpl*h, CL_MAP_READ); } return pixd; } // OpenCL implementation of Hollow pix //Note: Assumes the source and dest opencl buffer are initialized. No check done PIX* OpenclDevice::pixHollowCL(PIX *pixd, PIX *pixs, l_int32 close_hsize, l_int32 close_vsize, l_int32 open_hsize, l_int32 open_vsize, bool reqDataCopy = false) { l_uint32 wpl, h; cl_mem pixtemp; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); //First step : Close Morph operation: Dilate followed by Erode clStatus = pixCloseCL(close_hsize, close_vsize, wpl, h); //Store the output of close operation in an intermediate buffer //this will be later used for pixsubtract clStatus = clEnqueueCopyBuffer(rEnv.mpkCmdQueue, pixdCLBuffer, pixdCLIntermediate, 0, 0, sizeof(int) * wpl*h, 0, NULL, NULL); //Second step: Open Operation - Erode followed by Dilate pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; clStatus = pixOpenCL(open_hsize, open_vsize, wpl, h); //Third step: Subtract : (Close - Open) pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixdCLIntermediate; pixdCLIntermediate = pixtemp; clStatus = pixSubtractCL_work(wpl, h, pixdCLBuffer, pixsCLBuffer); if (reqDataCopy) { //Read back output data from OCL buffer to cpu pixd = mapOutputCLBuffer(rEnv, pixdCLBuffer, pixd, pixs, wpl*h, CL_MAP_READ); } return pixd; } // OpenCL implementation of Get Lines from pix function //Note: Assumes the source and dest opencl buffer are initialized. No check done void OpenclDevice::pixGetLinesCL(PIX *pixd, PIX *pixs, PIX** pix_vline, PIX** pix_hline, PIX** pixClosed, bool getpixClosed, l_int32 close_hsize, l_int32 close_vsize, l_int32 open_hsize, l_int32 open_vsize, l_int32 line_hsize, l_int32 line_vsize) { l_uint32 wpl, h; cl_mem pixtemp; wpl = pixGetWpl(pixs); h = pixGetHeight(pixs); //First step : Close Morph operation: Dilate followed by Erode clStatus = pixCloseCL(close_hsize, close_vsize, wpl, h); //Copy the Close output to CPU buffer if (getpixClosed) { *pixClosed = mapOutputCLBuffer(rEnv, pixdCLBuffer, *pixClosed, pixs, wpl*h, CL_MAP_READ, true, false); } //Store the output of close operation in an intermediate buffer //this will be later used for pixsubtract clStatus = clEnqueueCopyBuffer(rEnv.mpkCmdQueue, pixdCLBuffer, pixdCLIntermediate, 0, 0, sizeof(int) * wpl*h, 0, NULL, NULL); //Second step: Open Operation - Erode followed by Dilate pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; clStatus = pixOpenCL(open_hsize, open_vsize, wpl, h); //Third step: Subtract : (Close - Open) pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixdCLIntermediate; pixdCLIntermediate = pixtemp; clStatus = pixSubtractCL_work(wpl, h, pixdCLBuffer, pixsCLBuffer); //Store the output of Hollow operation in an intermediate buffer //this will be later used clStatus = clEnqueueCopyBuffer(rEnv.mpkCmdQueue, pixdCLBuffer, pixdCLIntermediate, 0, 0, sizeof(int) * wpl*h, 0, NULL, NULL); pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLBuffer; pixdCLBuffer = pixtemp; //Fourth step: Get vertical line //pixOpenBrick(NULL, pix_hollow, 1, min_line_length); clStatus = pixOpenCL(1, line_vsize, wpl, h); //Copy the vertical line output to CPU buffer *pix_vline = mapOutputCLBuffer(rEnv, pixdCLBuffer, *pix_vline, pixs, wpl*h, CL_MAP_READ, true, false); pixtemp = pixsCLBuffer; pixsCLBuffer = pixdCLIntermediate; pixdCLIntermediate = pixtemp; //Fifth step: Get horizontal line //pixOpenBrick(NULL, pix_hollow, min_line_length, 1); clStatus = pixOpenCL(line_hsize, 1, wpl, h); //Copy the horizontal line output to CPU buffer *pix_hline = mapOutputCLBuffer(rEnv, pixdCLBuffer, *pix_hline, pixs, wpl*h, CL_MAP_READ, true, true); return; } /************************************************************************* * HistogramRect * Otsu Thresholding Operations * histogramAllChannels is layed out as all channel 0, then all channel 1... * only supports 1 or 4 channels (bytes_per_pixel) ************************************************************************/ int OpenclDevice::HistogramRectOCL( const unsigned char* imageData, int bytes_per_pixel, int bytes_per_line, int left, // always 0 int top, // always 0 int width, int height, int kHistogramSize, int* histogramAllChannels) { PERF_COUNT_START("HistogramRectOCL") cl_int clStatus; int retVal= 0; KernelEnv histKern; SetKernelEnv( &histKern ); KernelEnv histRedKern; SetKernelEnv( &histRedKern ); /* map imagedata to device as read only */ // USE_HOST_PTR uses onion+ bus which is slowest option; also happens to be coherent which we don't need. // faster option would be to allocate initial image buffer // using a garlic bus memory type cl_mem imageBuffer = clCreateBuffer( histKern.mpkContext, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, width*height*bytes_per_pixel*sizeof(char), (void *)imageData, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer imageBuffer"); /* setup work group size parameters */ int block_size = 256; cl_uint numCUs; clStatus = clGetDeviceInfo( gpuEnv.mpDevID, CL_DEVICE_MAX_COMPUTE_UNITS, sizeof(numCUs), &numCUs, NULL); CHECK_OPENCL( clStatus, "clCreateBuffer imageBuffer"); int requestedOccupancy = 10; int numWorkGroups = numCUs * requestedOccupancy; int numThreads = block_size*numWorkGroups; size_t local_work_size[] = {block_size}; size_t global_work_size[] = {numThreads}; size_t red_global_work_size[] = {block_size*kHistogramSize*bytes_per_pixel}; /* map histogramAllChannels as write only */ int numBins = kHistogramSize*bytes_per_pixel*numWorkGroups; cl_mem histogramBuffer = clCreateBuffer( histKern.mpkContext, CL_MEM_READ_WRITE | CL_MEM_USE_HOST_PTR, kHistogramSize*bytes_per_pixel*sizeof(int), (void *)histogramAllChannels, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer histogramBuffer"); /* intermediate histogram buffer */ int histRed = 256; int tmpHistogramBins = kHistogramSize*bytes_per_pixel*histRed; cl_mem tmpHistogramBuffer = clCreateBuffer( histKern.mpkContext, CL_MEM_READ_WRITE, tmpHistogramBins*sizeof(cl_uint), NULL, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer tmpHistogramBuffer"); /* atomic sync buffer */ int *zeroBuffer = new int[1]; zeroBuffer[0] = 0; cl_mem atomicSyncBuffer = clCreateBuffer( histKern.mpkContext, CL_MEM_READ_WRITE | CL_MEM_COPY_HOST_PTR, sizeof(cl_int), (void *)zeroBuffer, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer atomicSyncBuffer"); delete[] zeroBuffer; //Create kernel objects based on bytes_per_pixel if (bytes_per_pixel == 1) { histKern.mpkKernel = clCreateKernel( histKern.mpkProgram, "kernel_HistogramRectOneChannel", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_HistogramRectOneChannel"); histRedKern.mpkKernel = clCreateKernel( histRedKern.mpkProgram, "kernel_HistogramRectOneChannelReduction", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_HistogramRectOneChannelReduction"); } else { histKern.mpkKernel = clCreateKernel( histKern.mpkProgram, "kernel_HistogramRectAllChannels", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_HistogramRectAllChannels"); histRedKern.mpkKernel = clCreateKernel( histRedKern.mpkProgram, "kernel_HistogramRectAllChannelsReduction", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_HistogramRectAllChannelsReduction"); } void *ptr; //Initialize tmpHistogramBuffer buffer ptr = clEnqueueMapBuffer(histKern.mpkCmdQueue, tmpHistogramBuffer, CL_TRUE, CL_MAP_WRITE, 0, tmpHistogramBins*sizeof(cl_uint), 0, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "clEnqueueMapBuffer tmpHistogramBuffer"); memset(ptr, 0, tmpHistogramBins*sizeof(cl_uint)); clEnqueueUnmapMemObject(histKern.mpkCmdQueue, tmpHistogramBuffer, ptr, 0, NULL, NULL); /* set kernel 1 arguments */ clStatus = clSetKernelArg( histKern.mpkKernel, 0, sizeof(cl_mem), (void *)&imageBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg imageBuffer"); cl_uint numPixels = width*height; clStatus = clSetKernelArg( histKern.mpkKernel, 1, sizeof(cl_uint), (void *)&numPixels ); CHECK_OPENCL( clStatus, "clSetKernelArg numPixels" ); clStatus = clSetKernelArg( histKern.mpkKernel, 2, sizeof(cl_mem), (void *)&tmpHistogramBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg tmpHistogramBuffer"); /* set kernel 2 arguments */ int n = numThreads/bytes_per_pixel; clStatus = clSetKernelArg( histRedKern.mpkKernel, 0, sizeof(cl_int), (void *)&n ); CHECK_OPENCL( clStatus, "clSetKernelArg imageBuffer"); clStatus = clSetKernelArg( histRedKern.mpkKernel, 1, sizeof(cl_mem), (void *)&tmpHistogramBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg tmpHistogramBuffer"); clStatus = clSetKernelArg( histRedKern.mpkKernel, 2, sizeof(cl_mem), (void *)&histogramBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg histogramBuffer"); /* launch histogram */ PERF_COUNT_SUB("before") clStatus = clEnqueueNDRangeKernel( histKern.mpkCmdQueue, histKern.mpkKernel, 1, NULL, global_work_size, local_work_size, 0, NULL, NULL ); CHECK_OPENCL( clStatus, "clEnqueueNDRangeKernel kernel_HistogramRectAllChannels" ); clFinish( histKern.mpkCmdQueue ); if(clStatus !=0) { retVal = -1; } /* launch histogram */ clStatus = clEnqueueNDRangeKernel( histRedKern.mpkCmdQueue, histRedKern.mpkKernel, 1, NULL, red_global_work_size, local_work_size, 0, NULL, NULL ); CHECK_OPENCL( clStatus, "clEnqueueNDRangeKernel kernel_HistogramRectAllChannelsReduction" ); clFinish( histRedKern.mpkCmdQueue ); if(clStatus !=0) { retVal = -1; } PERF_COUNT_SUB("redKernel") /* map results back from gpu */ ptr = clEnqueueMapBuffer(histRedKern.mpkCmdQueue, histogramBuffer, CL_TRUE, CL_MAP_READ, 0, kHistogramSize*bytes_per_pixel*sizeof(int), 0, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "clEnqueueMapBuffer histogramBuffer"); if(clStatus !=0) { retVal = -1; } clEnqueueUnmapMemObject(histRedKern.mpkCmdQueue, histogramBuffer, ptr, 0, NULL, NULL); clReleaseMemObject(histogramBuffer); clReleaseMemObject(imageBuffer); PERF_COUNT_SUB("after") PERF_COUNT_END return retVal; } /************************************************************************* * Threshold the rectangle, taking everything except the image buffer pointer * from the class, using thresholds/hi_values to the output IMAGE. * only supports 1 or 4 channels ************************************************************************/ int OpenclDevice::ThresholdRectToPixOCL( const unsigned char* imageData, int bytes_per_pixel, int bytes_per_line, const int* thresholds, const int* hi_values, Pix** pix, int height, int width, int top, int left) { PERF_COUNT_START("ThresholdRectToPixOCL") int retVal =0; /* create pix result buffer */ *pix = pixCreate(width, height, 1); uinT32* pixData = pixGetData(*pix); int wpl = pixGetWpl(*pix); int pixSize = wpl*height*sizeof(uinT32); // number of pixels cl_int clStatus; KernelEnv rEnv; SetKernelEnv( &rEnv ); /* setup work group size parameters */ int block_size = 256; cl_uint numCUs = 6; clStatus = clGetDeviceInfo( gpuEnv.mpDevID, CL_DEVICE_MAX_COMPUTE_UNITS, sizeof(numCUs), &numCUs, NULL); CHECK_OPENCL( clStatus, "clCreateBuffer imageBuffer"); int requestedOccupancy = 10; int numWorkGroups = numCUs * requestedOccupancy; int numThreads = block_size*numWorkGroups; size_t local_work_size[] = {(size_t) block_size}; size_t global_work_size[] = {(size_t) numThreads}; /* map imagedata to device as read only */ // USE_HOST_PTR uses onion+ bus which is slowest option; also happens to be coherent which we don't need. // faster option would be to allocate initial image buffer // using a garlic bus memory type cl_mem imageBuffer = clCreateBuffer( rEnv.mpkContext, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, width*height*bytes_per_pixel*sizeof(char), (void *)imageData, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer imageBuffer"); /* map pix as write only */ pixThBuffer = clCreateBuffer( rEnv.mpkContext, CL_MEM_READ_WRITE | CL_MEM_USE_HOST_PTR, pixSize, (void *)pixData, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer pix"); /* map thresholds and hi_values */ cl_mem thresholdsBuffer = clCreateBuffer( rEnv.mpkContext, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, bytes_per_pixel*sizeof(int), (void *)thresholds, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer thresholdBuffer"); cl_mem hiValuesBuffer = clCreateBuffer( rEnv.mpkContext, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, bytes_per_pixel*sizeof(int), (void *)hi_values, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer hiValuesBuffer"); /* compile kernel */ if (bytes_per_pixel == 4) { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "kernel_ThresholdRectToPix", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_ThresholdRectToPix"); } else { rEnv.mpkKernel = clCreateKernel( rEnv.mpkProgram, "kernel_ThresholdRectToPix_OneChan", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_ThresholdRectToPix_OneChan"); } /* set kernel arguments */ clStatus = clSetKernelArg( rEnv.mpkKernel, 0, sizeof(cl_mem), (void *)&imageBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg imageBuffer"); cl_uint numPixels = width*height; clStatus = clSetKernelArg( rEnv.mpkKernel, 1, sizeof(int), (void *)&height ); CHECK_OPENCL( clStatus, "clSetKernelArg height" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 2, sizeof(int), (void *)&width ); CHECK_OPENCL( clStatus, "clSetKernelArg width" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 3, sizeof(int), (void *)&wpl ); CHECK_OPENCL( clStatus, "clSetKernelArg wpl" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 4, sizeof(cl_mem), (void *)&thresholdsBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg thresholdsBuffer" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 5, sizeof(cl_mem), (void *)&hiValuesBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg hiValuesBuffer" ); clStatus = clSetKernelArg( rEnv.mpkKernel, 6, sizeof(cl_mem), (void *)&pixThBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg pixThBuffer"); /* launch kernel & wait */ PERF_COUNT_SUB("before") clStatus = clEnqueueNDRangeKernel( rEnv.mpkCmdQueue, rEnv.mpkKernel, 1, NULL, global_work_size, local_work_size, 0, NULL, NULL ); CHECK_OPENCL( clStatus, "clEnqueueNDRangeKernel kernel_ThresholdRectToPix" ); clFinish( rEnv.mpkCmdQueue ); PERF_COUNT_SUB("kernel") if(clStatus !=0) { printf("Setting return value to -1\n"); retVal = -1; } /* map results back from gpu */ void *ptr = clEnqueueMapBuffer(rEnv.mpkCmdQueue, pixThBuffer, CL_TRUE, CL_MAP_READ, 0, pixSize, 0, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "clEnqueueMapBuffer histogramBuffer"); clEnqueueUnmapMemObject(rEnv.mpkCmdQueue, pixThBuffer, ptr, 0, NULL, NULL); clReleaseMemObject(imageBuffer); clReleaseMemObject(thresholdsBuffer); clReleaseMemObject(hiValuesBuffer); PERF_COUNT_SUB("after") PERF_COUNT_END return retVal; } /****************************************************************************** * Data Types for Device Selection *****************************************************************************/ typedef struct _TessScoreEvaluationInputData { int height; int width; int numChannels; unsigned char *imageData; Pix *pix; } TessScoreEvaluationInputData; void populateTessScoreEvaluationInputData( TessScoreEvaluationInputData *input ) { srand(1); // 8.5x11 inches @ 300dpi rounded to clean multiples int height = 3328; // %256 int width = 2560; // %512 int numChannels = 4; input->height = height; input->width = width; input->numChannels = numChannels; unsigned char (*imageData4)[4] = (unsigned char (*)[4]) malloc(height*width*numChannels*sizeof(unsigned char)); // new unsigned char[4][height*width]; input->imageData = (unsigned char *) &imageData4[0]; // zero out image unsigned char pixelWhite[4] = { 0, 0, 0, 255}; unsigned char pixelBlack[4] = {255, 255, 255, 255}; for (int p = 0; p < height*width; p++) { //unsigned char tmp[4] = imageData4[0]; imageData4[p][0] = pixelWhite[0]; imageData4[p][1] = pixelWhite[1]; imageData4[p][2] = pixelWhite[2]; imageData4[p][3] = pixelWhite[3]; } // random lines to be eliminated int maxLineWidth = 64; // pixels wide int numLines = 10; // vertical lines for (int i = 0; i < numLines; i++) { int lineWidth = rand()%maxLineWidth; int vertLinePos = lineWidth + rand()%(width-2*lineWidth); //printf("[PI] VerticalLine @ %i (w=%i)\n", vertLinePos, lineWidth); for (int row = vertLinePos-lineWidth/2; row < vertLinePos+lineWidth/2; row++) { for (int col = 0; col < height; col++) { //imageData4[row*width+col] = pixelBlack; imageData4[row*width+col][0] = pixelBlack[0]; imageData4[row*width+col][1] = pixelBlack[1]; imageData4[row*width+col][2] = pixelBlack[2]; imageData4[row*width+col][3] = pixelBlack[3]; } } } // horizontal lines for (int i = 0; i < numLines; i++) { int lineWidth = rand()%maxLineWidth; int horLinePos = lineWidth + rand()%(height-2*lineWidth); //printf("[PI] HorizontalLine @ %i (w=%i)\n", horLinePos, lineWidth); for (int row = 0; row < width; row++) { for (int col = horLinePos-lineWidth/2; col < horLinePos+lineWidth/2; col++) { // for (int row = vertLinePos-lineWidth/2; row < vertLinePos+lineWidth/2; row++) { //printf("[PI] HoizLine pix @ (%3i, %3i)\n", row, col); //imageData4[row*width+col] = pixelBlack; imageData4[row*width+col][0] = pixelBlack[0]; imageData4[row*width+col][1] = pixelBlack[1]; imageData4[row*width+col][2] = pixelBlack[2]; imageData4[row*width+col][3] = pixelBlack[3]; } } } // spots (noise, squares) float fractionBlack = 0.1; // how much of the image should be blackened int numSpots = (height*width)*fractionBlack/(maxLineWidth*maxLineWidth/2/2); for (int i = 0; i < numSpots; i++) { int lineWidth = rand()%maxLineWidth; int col = lineWidth + rand()%(width-2*lineWidth); int row = lineWidth + rand()%(height-2*lineWidth); //printf("[PI] Spot[%i/%i] @ (%3i, %3i)\n", i, numSpots, row, col ); for (int r = row-lineWidth/2; r < row+lineWidth/2; r++) { for (int c = col-lineWidth/2; c < col+lineWidth/2; c++) { //printf("[PI] \tSpot[%i/%i] @ (%3i, %3i)\n", i, numSpots, r, c ); //imageData4[row*width+col] = pixelBlack; imageData4[r*width+c][0] = pixelBlack[0]; imageData4[r*width+c][1] = pixelBlack[1]; imageData4[r*width+c][2] = pixelBlack[2]; imageData4[r*width+c][3] = pixelBlack[3]; } } } input->pix = pixCreate(input->width, input->height, 1); } typedef struct _TessDeviceScore { float time; // small time means faster device bool clError; // were there any opencl errors bool valid; // was the correct response generated } TessDeviceScore; /****************************************************************************** * Micro Benchmarks for Device Selection *****************************************************************************/ double composeRGBPixelMicroBench( GPUEnv *env, TessScoreEvaluationInputData input, ds_device_type type ) { double time = 0; #if ON_WINDOWS LARGE_INTEGER freq, time_funct_start, time_funct_end; QueryPerformanceFrequency(&freq); #elif ON_APPLE mach_timebase_info_data_t info = { 0, 0 }; mach_timebase_info(&info); long long start,stop; #else timespec time_funct_start, time_funct_end; #endif // input data l_uint32 *tiffdata = (l_uint32 *)input.imageData;// same size and random data; data doesn't change workload // function call if (type == DS_DEVICE_OPENCL_DEVICE) { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif OpenclDevice::gpuEnv = *env; int wpl = pixGetWpl(input.pix); OpenclDevice::pixReadFromTiffKernel(tiffdata, input.width, input.height, wpl, NULL); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } else { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif Pix *pix = pixCreate(input.width, input.height, 32); l_uint32 *pixData = pixGetData(pix); int wpl = pixGetWpl(pix); //l_uint32* output_gpu=pixReadFromTiffKernel(tiffdata,w,h,wpl,line); //pixSetData(pix, output_gpu); int i, j; int idx = 0; for (i = 0; i < input.height ; i++) { for (j = 0; j < input.width; j++) { l_uint32 tiffword = tiffdata[i * input.width + j]; l_int32 rval = ((tiffword) & 0xff); l_int32 gval = (((tiffword) >> 8) & 0xff); l_int32 bval = (((tiffword) >> 16) & 0xff); l_uint32 value = (rval << 24) | (gval << 16) | (bval << 8); pixData[idx] = value; idx++; } } #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif pixDestroy(&pix); } // cleanup return time; } double histogramRectMicroBench( GPUEnv *env, TessScoreEvaluationInputData input, ds_device_type type ) { double time; #if ON_WINDOWS LARGE_INTEGER freq, time_funct_start, time_funct_end; QueryPerformanceFrequency(&freq); #elif ON_APPLE mach_timebase_info_data_t info = { 0, 0 }; mach_timebase_info(&info); long long start,stop; #else timespec time_funct_start, time_funct_end; #endif unsigned char pixelHi = (unsigned char)255; int left = 0; int top = 0; int kHistogramSize = 256; int bytes_per_line = input.width*input.numChannels; int *histogramAllChannels = new int[kHistogramSize*input.numChannels]; int retVal= 0; // function call if (type == DS_DEVICE_OPENCL_DEVICE) { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif OpenclDevice::gpuEnv = *env; int wpl = pixGetWpl(input.pix); retVal= OpenclDevice::HistogramRectOCL(input.imageData, input.numChannels, bytes_per_line, top, left, input.width, input.height, kHistogramSize, histogramAllChannels); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); if(retVal ==0) { time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; } else { time= FLT_MAX; } #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } else { int *histogram = new int[kHistogramSize]; #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif for (int ch = 0; ch < input.numChannels; ++ch) { tesseract::HistogramRect(input.pix, input.numChannels, left, top, input.width, input.height, histogram); } #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif delete[] histogram; } // cleanup delete[] histogramAllChannels; return time; } //Reproducing the ThresholdRectToPix native version void ThresholdRectToPix_Native(const unsigned char* imagedata, int bytes_per_pixel, int bytes_per_line, const int* thresholds, const int* hi_values, Pix** pix) { int top = 0; int left = 0; int width = pixGetWidth(*pix); int height = pixGetHeight(*pix); *pix = pixCreate(width, height, 1); uinT32* pixdata = pixGetData(*pix); int wpl = pixGetWpl(*pix); const unsigned char* srcdata = imagedata + top * bytes_per_line + left * bytes_per_pixel; for (int y = 0; y < height; ++y) { const uinT8* linedata = srcdata; uinT32* pixline = pixdata + y * wpl; for (int x = 0; x < width; ++x, linedata += bytes_per_pixel) { bool white_result = true; for (int ch = 0; ch < bytes_per_pixel; ++ch) { if (hi_values[ch] >= 0 && (linedata[ch] > thresholds[ch]) == (hi_values[ch] == 0)) { white_result = false; break; } } if (white_result) CLEAR_DATA_BIT(pixline, x); else SET_DATA_BIT(pixline, x); } srcdata += bytes_per_line; } } double thresholdRectToPixMicroBench( GPUEnv *env, TessScoreEvaluationInputData input, ds_device_type type ) { double time; int retVal =0; #if ON_WINDOWS LARGE_INTEGER freq, time_funct_start, time_funct_end; QueryPerformanceFrequency(&freq); #elif ON_APPLE mach_timebase_info_data_t info = { 0, 0 }; mach_timebase_info(&info); long long start,stop; #else timespec time_funct_start, time_funct_end; #endif // input data unsigned char pixelHi = (unsigned char)255; int* thresholds = new int[4]; thresholds[0] = pixelHi/2; thresholds[1] = pixelHi/2; thresholds[2] = pixelHi/2; thresholds[3] = pixelHi/2; int *hi_values = new int[4]; thresholds[0] = pixelHi; thresholds[1] = pixelHi; thresholds[2] = pixelHi; thresholds[3] = pixelHi; //Pix* pix = pixCreate(width, height, 1); int top = 0; int left = 0; int bytes_per_line = input.width*input.numChannels; // function call if (type == DS_DEVICE_OPENCL_DEVICE) { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif OpenclDevice::gpuEnv = *env; int wpl = pixGetWpl(input.pix); retVal= OpenclDevice::ThresholdRectToPixOCL(input.imageData, input.numChannels, bytes_per_line, thresholds, hi_values, &input.pix, input.height, input.width, top, left); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); if(retVal ==0) { time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9;; } else { time= FLT_MAX; } #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } else { tesseract::ImageThresholder thresholder; thresholder.SetImage( input.pix ); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif ThresholdRectToPix_Native( input.imageData, input.numChannels, bytes_per_line, thresholds, hi_values, &input.pix ); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } // cleanup delete[] thresholds; delete[] hi_values; return time; } double getLineMasksMorphMicroBench( GPUEnv *env, TessScoreEvaluationInputData input, ds_device_type type ) { double time = 0; #if ON_WINDOWS LARGE_INTEGER freq, time_funct_start, time_funct_end; QueryPerformanceFrequency(&freq); #elif ON_APPLE mach_timebase_info_data_t info = { 0, 0 }; mach_timebase_info(&info); long long start,stop; #else timespec time_funct_start, time_funct_end; #endif // input data int resolution = 300; int wpl = pixGetWpl(input.pix); int kThinLineFraction = 20; // tess constant int kMinLineLengthFraction = 4; // tess constant int max_line_width = resolution / kThinLineFraction; int min_line_length = resolution / kMinLineLengthFraction; int closing_brick = max_line_width / 3; // function call if (type == DS_DEVICE_OPENCL_DEVICE) { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif Pix *src_pix = input.pix; OpenclDevice::gpuEnv = *env; OpenclDevice::initMorphCLAllocations(wpl, input.height, input.pix); Pix *pix_vline = NULL, *pix_hline = NULL, *pix_closed = NULL; OpenclDevice::pixGetLinesCL(NULL, input.pix, &pix_vline, &pix_hline, &pix_closed, true, closing_brick, closing_brick, max_line_width, max_line_width, min_line_length, min_line_length); OpenclDevice::releaseMorphCLBuffers(); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } else { #if ON_WINDOWS QueryPerformanceCounter(&time_funct_start); #elif ON_APPLE start = mach_absolute_time(); #else clock_gettime( CLOCK_MONOTONIC, &time_funct_start ); #endif // native serial code Pix *src_pix = input.pix; Pix *pix_closed = pixCloseBrick(NULL, src_pix, closing_brick, closing_brick); Pix *pix_solid = pixOpenBrick(NULL, pix_closed, max_line_width, max_line_width); Pix *pix_hollow = pixSubtract(NULL, pix_closed, pix_solid); pixDestroy(&pix_solid); Pix *pix_vline = pixOpenBrick(NULL, pix_hollow, 1, min_line_length); Pix *pix_hline = pixOpenBrick(NULL, pix_hollow, min_line_length, 1); pixDestroy(&pix_hollow); #if ON_WINDOWS QueryPerformanceCounter(&time_funct_end); time = (time_funct_end.QuadPart-time_funct_start.QuadPart)/(double)(freq.QuadPart); #elif ON_APPLE stop = mach_absolute_time(); time = ((stop - start) * (double) info.numer / info.denom) / 1.0E9; #else clock_gettime( CLOCK_MONOTONIC, &time_funct_end ); time = (time_funct_end.tv_sec - time_funct_start.tv_sec)*1.0 + (time_funct_end.tv_nsec - time_funct_start.tv_nsec)/1000000000.0; #endif } return time; } /****************************************************************************** * Device Selection *****************************************************************************/ #include "stdlib.h" // encode score object as byte string ds_status serializeScore( ds_device* device, void **serializedScore, unsigned int* serializedScoreSize ) { *serializedScoreSize = sizeof(TessDeviceScore); *serializedScore = (void *) new unsigned char[*serializedScoreSize]; memcpy(*serializedScore, device->score, *serializedScoreSize); return DS_SUCCESS; } // parses byte string and stores in score object ds_status deserializeScore( ds_device* device, const unsigned char* serializedScore, unsigned int serializedScoreSize ) { // check that serializedScoreSize == sizeof(TessDeviceScore); device->score = new TessDeviceScore; memcpy(device->score, serializedScore, serializedScoreSize); return DS_SUCCESS; } ds_status releaseScore( void* score ) { delete[] score; return DS_SUCCESS; } // evaluate devices ds_status evaluateScoreForDevice( ds_device *device, void *inputData) { // overwrite statuc gpuEnv w/ current device // so native opencl calls can be used; they use static gpuEnv printf("\n[DS] Device: \"%s\" (%s) evaluation...\n", device->oclDeviceName, device->type==DS_DEVICE_OPENCL_DEVICE ? "OpenCL" : "Native" ); GPUEnv *env = NULL; if (device->type == DS_DEVICE_OPENCL_DEVICE) { env = new GPUEnv; //printf("[DS] populating tmp GPUEnv from device\n"); populateGPUEnvFromDevice( env, device->oclDeviceID); env->mnFileCount = 0; //argc; env->mnKernelCount = 0UL; //printf("[DS] compiling kernels for tmp GPUEnv\n"); OpenclDevice::gpuEnv = *env; OpenclDevice::CompileKernelFile(env, ""); } TessScoreEvaluationInputData *input = (TessScoreEvaluationInputData *)inputData; // pixReadTiff double composeRGBPixelTime = composeRGBPixelMicroBench( env, *input, device->type ); // HistogramRect double histogramRectTime = histogramRectMicroBench( env, *input, device->type ); // ThresholdRectToPix double thresholdRectToPixTime = thresholdRectToPixMicroBench( env, *input, device->type ); // getLineMasks double getLineMasksMorphTime = getLineMasksMorphMicroBench( env, *input, device->type ); // weigh times (% of cpu time) // these weights should be the % execution time that the native cpu code took float composeRGBPixelWeight = 1.2f; float histogramRectWeight = 2.4f; float thresholdRectToPixWeight = 4.5f; float getLineMasksMorphWeight = 5.0f; float weightedTime = composeRGBPixelWeight * composeRGBPixelTime + histogramRectWeight * histogramRectTime + thresholdRectToPixWeight * thresholdRectToPixTime + getLineMasksMorphWeight * getLineMasksMorphTime ; device->score = (void *)new TessDeviceScore; ((TessDeviceScore *)device->score)->time = weightedTime; printf("[DS] Device: \"%s\" (%s) evaluated\n", device->oclDeviceName, device->type==DS_DEVICE_OPENCL_DEVICE ? "OpenCL" : "Native" ); printf("[DS]%25s: %f (w=%.1f)\n", "composeRGBPixel", composeRGBPixelTime, composeRGBPixelWeight ); printf("[DS]%25s: %f (w=%.1f)\n", "HistogramRect", histogramRectTime, histogramRectWeight ); printf("[DS]%25s: %f (w=%.1f)\n", "ThresholdRectToPix", thresholdRectToPixTime, thresholdRectToPixWeight ); printf("[DS]%25s: %f (w=%.1f)\n", "getLineMasksMorph", getLineMasksMorphTime, getLineMasksMorphWeight ); printf("[DS]%25s: %f\n", "Score", ((TessDeviceScore *)device->score)->time ); return DS_SUCCESS; } // initial call to select device ds_device OpenclDevice::getDeviceSelection( ) { if (!deviceIsSelected) { PERF_COUNT_START("getDeviceSelection") // check if opencl is available at runtime if( 1 == LoadOpencl() ) { // opencl is available //PERF_COUNT_SUB("LoadOpencl") // setup devices ds_status status; ds_profile *profile; status = initDSProfile( &profile, "v0.1" ); PERF_COUNT_SUB("initDSProfile") // try reading scores from file char *fileName = "tesseract_opencl_profile_devices.dat"; status = readProfileFromFile( profile, deserializeScore, fileName); if (status != DS_SUCCESS) { // need to run evaluation printf("[DS] Profile file not available (%s); performing profiling.\n", fileName); // create input data TessScoreEvaluationInputData input; populateTessScoreEvaluationInputData( &input ); //PERF_COUNT_SUB("populateTessScoreEvaluationInputData") // perform evaluations unsigned int numUpdates; status = profileDevices( profile, DS_EVALUATE_ALL, evaluateScoreForDevice, (void *)&input, &numUpdates ); PERF_COUNT_SUB("profileDevices") // write scores to file if ( status == DS_SUCCESS ) { status = writeProfileToFile( profile, serializeScore, fileName); PERF_COUNT_SUB("writeProfileToFile") if ( status == DS_SUCCESS ) { printf("[DS] Scores written to file (%s).\n", fileName); } else { printf("[DS] Error saving scores to file (%s); scores not written to file.\n", fileName); } } else { printf("[DS] Unable to evaluate performance; scores not written to file.\n"); } } else { PERF_COUNT_SUB("readProfileFromFile") printf("[DS] Profile read from file (%s).\n", fileName); } // we now have device scores either from file or evaluation // select fastest using custom Tesseract selection algorithm float bestTime = FLT_MAX; // begin search with worst possible time int bestDeviceIdx = -1; for (int d = 0; d < profile->numDevices; d++) { ds_device device = profile->devices[d]; TessDeviceScore score = *(TessDeviceScore *)device.score; float time = score.time; printf("[DS] Device[%i] %i:%s score is %f\n", d+1, device.type, device.oclDeviceName, time); if (time < bestTime) { bestTime = time; bestDeviceIdx = d; } } printf("[DS] Selected Device[%i]: \"%s\" (%s)\n", bestDeviceIdx+1, profile->devices[bestDeviceIdx].oclDeviceName, profile->devices[bestDeviceIdx].type==DS_DEVICE_OPENCL_DEVICE ? "OpenCL" : "Native"); // cleanup // TODO: call destructor for profile object? bool overrided = false; char *overrideDeviceStr = getenv("TESSERACT_OPENCL_DEVICE"); if (overrideDeviceStr != NULL) { int overrideDeviceIdx = atoi(overrideDeviceStr); if (overrideDeviceIdx > 0 && overrideDeviceIdx <= profile->numDevices ) { printf("[DS] Overriding Device Selection (TESSERACT_OPENCL_DEVICE=%s, %i)\n", overrideDeviceStr, overrideDeviceIdx); bestDeviceIdx = overrideDeviceIdx - 1; overrided = true; } else { printf("[DS] Ignoring invalid TESSERACT_OPENCL_DEVICE=%s ([1,%i] are valid devices).\n", overrideDeviceStr, profile->numDevices); } } if (overrided) { printf("[DS] Overridden Device[%i]: \"%s\" (%s)\n", bestDeviceIdx+1, profile->devices[bestDeviceIdx].oclDeviceName, profile->devices[bestDeviceIdx].type==DS_DEVICE_OPENCL_DEVICE ? "OpenCL" : "Native"); } selectedDevice = profile->devices[bestDeviceIdx]; // cleanup releaseDSProfile(profile, releaseScore); } else { // opencl isn't available at runtime, select native cpu device printf("[DS] OpenCL runtime not available.\n"); selectedDevice.type = DS_DEVICE_NATIVE_CPU; selectedDevice.oclDeviceName = "(null)"; selectedDevice.score = NULL; selectedDevice.oclDeviceID = NULL; selectedDevice.oclDriverVersion = NULL; } deviceIsSelected = true; PERF_COUNT_SUB("select from Profile") PERF_COUNT_END } //PERF_COUNT_END return selectedDevice; } bool OpenclDevice::selectedDeviceIsOpenCL() { ds_device device = getDeviceSelection(); return (device.type == DS_DEVICE_OPENCL_DEVICE); } bool OpenclDevice::selectedDeviceIsNativeCPU() { ds_device device = getDeviceSelection(); return (device.type == DS_DEVICE_NATIVE_CPU); } /*! * pixConvertRGBToGray() from leptonica, converted to opencl kernel * * Input: pix (32 bpp RGB) * rwt, gwt, bwt (non-negative; these should add to 1.0, * or use 0.0 for default) * Return: 8 bpp pix, or null on error * * Notes: * (1) Use a weighted average of the RGB values. */ #define SET_DATA_BYTE( pdata, n, val ) (*(l_uint8 *)((l_uintptr_t)((l_uint8 *)(pdata) + (n)) ^ 3) = (val)) Pix * OpenclDevice::pixConvertRGBToGrayOCL( Pix *srcPix, // 32-bit source float rwt, float gwt, float bwt ) { PERF_COUNT_START("pixConvertRGBToGrayOCL") Pix *dstPix; // 8-bit destination if (rwt < 0.0 || gwt < 0.0 || bwt < 0.0) return NULL; if (rwt == 0.0 && gwt == 0.0 && bwt == 0.0) { // magic numbers from leptonica rwt = 0.3; gwt = 0.5; bwt = 0.2; } // normalize float sum = rwt + gwt + bwt; rwt /= sum; gwt /= sum; bwt /= sum; // source pix int w, h; pixGetDimensions(srcPix, &w, &h, NULL); //printf("Image is %i x %i\n", w, h); unsigned int *srcData = pixGetData(srcPix); int srcWPL = pixGetWpl(srcPix); int srcSize = srcWPL * h * sizeof(unsigned int); // destination pix if ((dstPix = pixCreate(w, h, 8)) == NULL) return NULL; pixCopyResolution(dstPix, srcPix); unsigned int *dstData = pixGetData(dstPix); int dstWPL = pixGetWpl(dstPix); int dstWords = dstWPL * h; int dstSize = dstWords * sizeof(unsigned int); //printf("dstSize = %i\n", dstSize); PERF_COUNT_SUB("pix setup") // opencl objects cl_int clStatus; KernelEnv kEnv; SetKernelEnv( &kEnv ); // source buffer cl_mem srcBuffer = clCreateBuffer( kEnv.mpkContext, CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR, srcSize, (void *)srcData, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer srcBuffer"); // destination buffer cl_mem dstBuffer = clCreateBuffer( kEnv.mpkContext, CL_MEM_WRITE_ONLY | CL_MEM_USE_HOST_PTR, dstSize, (void *)dstData, &clStatus ); CHECK_OPENCL( clStatus, "clCreateBuffer dstBuffer"); // setup work group size parameters int block_size = 256; int numWorkGroups = ((h*w+block_size-1) / block_size ); int numThreads = block_size*numWorkGroups; size_t local_work_size[] = {block_size}; size_t global_work_size[] = {numThreads}; //printf("Enqueueing %i threads for %i output pixels\n", numThreads, w*h); /* compile kernel */ kEnv.mpkKernel = clCreateKernel( kEnv.mpkProgram, "kernel_RGBToGray", &clStatus ); CHECK_OPENCL( clStatus, "clCreateKernel kernel_RGBToGray"); /* set kernel arguments */ clStatus = clSetKernelArg( kEnv.mpkKernel, 0, sizeof(cl_mem), (void *)&srcBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg srcBuffer"); clStatus = clSetKernelArg( kEnv.mpkKernel, 1, sizeof(cl_mem), (void *)&dstBuffer ); CHECK_OPENCL( clStatus, "clSetKernelArg dstBuffer"); clStatus = clSetKernelArg( kEnv.mpkKernel, 2, sizeof(int), (void *)&srcWPL ); CHECK_OPENCL( clStatus, "clSetKernelArg srcWPL" ); clStatus = clSetKernelArg( kEnv.mpkKernel, 3, sizeof(int), (void *)&dstWPL ); CHECK_OPENCL( clStatus, "clSetKernelArg dstWPL" ); clStatus = clSetKernelArg( kEnv.mpkKernel, 4, sizeof(int), (void *)&h ); CHECK_OPENCL( clStatus, "clSetKernelArg height" ); clStatus = clSetKernelArg( kEnv.mpkKernel, 5, sizeof(int), (void *)&w ); CHECK_OPENCL( clStatus, "clSetKernelArg width" ); clStatus = clSetKernelArg( kEnv.mpkKernel, 6, sizeof(float), (void *)&rwt ); CHECK_OPENCL( clStatus, "clSetKernelArg rwt" ); clStatus = clSetKernelArg( kEnv.mpkKernel, 7, sizeof(float), (void *)&gwt ); CHECK_OPENCL( clStatus, "clSetKernelArg gwt"); clStatus = clSetKernelArg( kEnv.mpkKernel, 8, sizeof(float), (void *)&bwt ); CHECK_OPENCL( clStatus, "clSetKernelArg bwt"); /* launch kernel & wait */ PERF_COUNT_SUB("before") clStatus = clEnqueueNDRangeKernel( kEnv.mpkCmdQueue, kEnv.mpkKernel, 1, NULL, global_work_size, local_work_size, 0, NULL, NULL ); CHECK_OPENCL( clStatus, "clEnqueueNDRangeKernel kernel_RGBToGray" ); clFinish( kEnv.mpkCmdQueue ); PERF_COUNT_SUB("kernel") /* map results back from gpu */ void *ptr = clEnqueueMapBuffer(kEnv.mpkCmdQueue, dstBuffer, CL_TRUE, CL_MAP_READ, 0, dstSize, 0, NULL, NULL, &clStatus); CHECK_OPENCL( clStatus, "clEnqueueMapBuffer dstBuffer"); clEnqueueUnmapMemObject(rEnv.mpkCmdQueue, dstBuffer, ptr, 0, NULL, NULL); #if 0 // validate: compute on cpu Pix *cpuPix = pixCreate(w, h, 8); pixCopyResolution(cpuPix, srcPix); unsigned int *cpuData = pixGetData(cpuPix); int cpuWPL = pixGetWpl(cpuPix); unsigned int *cpuLine, *srcLine; int i, j; for (i = 0, srcLine = srcData, cpuLine = cpuData; i < h; i++) { for (j = 0; j < w; j++) { unsigned int word = *(srcLine + j); int val = (l_int32)(rwt * ((word >> L_RED_SHIFT) & 0xff) + gwt * ((word >> L_GREEN_SHIFT) & 0xff) + bwt * ((word >> L_BLUE_SHIFT) & 0xff) + 0.5); SET_DATA_BYTE(cpuLine, j, val); } srcLine += srcWPL; cpuLine += cpuWPL; } // validate: compare printf("converted 32-bit -> 8-bit image\n"); for (int row = 0; row < h; row++) { for (int col = 0; col < w; col++) { int idx = row*w + col; unsigned int srcVal = srcData[idx]; unsigned char cpuVal = ((unsigned char *)cpuData)[idx]; unsigned char oclVal = ((unsigned char *)dstData)[idx]; if (srcVal > 0) { printf("%4i,%4i: %u, %u, %u\n", row, col, srcVal, cpuVal, oclVal); } } //printf("\n"); } #endif // release opencl objects clReleaseMemObject(srcBuffer); clReleaseMemObject(dstBuffer); PERF_COUNT_END // success return dstPix; } #endif