// // Copyright (c) 2017 The Khronos Group Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // #include "testBase.h" #if defined( __APPLE__ ) #include #else #include #endif const char *get_kernel_suffix( cl_image_format *format ) { switch( format->image_channel_data_type ) { case CL_UNORM_INT8: case CL_UNORM_INT16: case CL_UNORM_INT24: case CL_SNORM_INT8: case CL_SNORM_INT16: case CL_HALF_FLOAT: case CL_FLOAT: case CL_UNORM_INT_101010: return "f"; case CL_SIGNED_INT8: case CL_SIGNED_INT16: case CL_SIGNED_INT32: return "i"; case CL_UNSIGNED_INT8: case CL_UNSIGNED_INT16: case CL_UNSIGNED_INT32: return "ui"; default: log_error("Test error: unsupported kernel suffix for image_channel_data_type 0x%X\n",format->image_channel_data_type); return ""; } } ExplicitType get_read_kernel_type( cl_image_format *format ) { switch( format->image_channel_data_type ) { case CL_UNORM_INT8: case CL_UNORM_INT16: case CL_UNORM_INT24: case CL_SNORM_INT8: case CL_SNORM_INT16: case CL_HALF_FLOAT: case CL_FLOAT: case CL_UNORM_INT_101010: #ifdef GL_VERSION_3_2 case CL_DEPTH: #endif return kFloat; case CL_SIGNED_INT8: case CL_SIGNED_INT16: case CL_SIGNED_INT32: return kInt; case CL_UNSIGNED_INT8: case CL_UNSIGNED_INT16: case CL_UNSIGNED_INT32: return kUInt; default: log_error("Test error: unsupported kernel suffix for image_channel_data_type 0x%X\n",format->image_channel_data_type); return kNumExplicitTypes; } } ExplicitType get_write_kernel_type( cl_image_format *format ) { switch( format->image_channel_data_type ) { case CL_UNORM_INT8: return kFloat; case CL_UNORM_INT16: return kFloat; case CL_UNORM_INT24: return kFloat; case CL_SNORM_INT8: return kFloat; case CL_SNORM_INT16: return kFloat; case CL_HALF_FLOAT: return kHalf; case CL_FLOAT: return kFloat; case CL_SIGNED_INT8: return kChar; case CL_SIGNED_INT16: return kShort; case CL_SIGNED_INT32: return kInt; case CL_UNSIGNED_INT8: return kUChar; case CL_UNSIGNED_INT16: return kUShort; case CL_UNSIGNED_INT32: return kUInt; case CL_UNORM_INT_101010: return kFloat; #ifdef GL_VERSION_3_2 case CL_DEPTH: return kFloat; #endif default: return kInt; } } const char* get_write_conversion( cl_image_format *format, ExplicitType type ) { switch( format->image_channel_data_type ) { case CL_UNORM_INT8: case CL_UNORM_INT16: case CL_SNORM_INT8: case CL_SNORM_INT16: case CL_HALF_FLOAT: case CL_FLOAT: case CL_UNORM_INT_101010: case CL_UNORM_INT24: if(type != kFloat) return "convert_float4"; break; case CL_SIGNED_INT8: case CL_SIGNED_INT16: case CL_SIGNED_INT32: if(type != kInt) return "convert_int4"; break; case CL_UNSIGNED_INT8: case CL_UNSIGNED_INT16: case CL_UNSIGNED_INT32: if(type != kUInt) return "convert_uint4"; break; default: return ""; } return ""; } // The only three input types to this function are kInt, kUInt and kFloat, due to the way we set up our tests // The output types, though, are pretty much anything valid for GL to receive #define DOWNSCALE_INTEGER_CASE( enum, type, bitShift ) \ case enum: \ { \ cl_##type *dst = new cl_##type[ numPixels * 4 ]; \ for( size_t i = 0; i < numPixels * 4; i++ ) \ dst[ i ] = src[ i ]; \ return (char *)dst; \ } #define UPSCALE_FLOAT_CASE( enum, type, typeMax ) \ case enum: \ { \ cl_##type *dst = new cl_##type[ numPixels * 4 ]; \ for( size_t i = 0; i < numPixels * 4; i++ ) \ dst[ i ] = (cl_##type)( src[ i ] * typeMax ); \ return (char *)dst; \ } char * convert_to_expected( void * inputBuffer, size_t numPixels, ExplicitType inType, ExplicitType outType, size_t channelNum, GLenum glDataType ) { #ifdef DEBUG log_info( "- Converting from input type '%s' to output type '%s'\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); #endif if( inType == outType ) { char *outData = new char[ numPixels * channelNum * get_explicit_type_size(outType) ] ; // sizeof( cl_int ) ]; if (glDataType == GL_FLOAT_32_UNSIGNED_INT_24_8_REV) { for (size_t i = 0; i < numPixels; ++i) { ((cl_float*)outData)[i] = ((cl_float*)inputBuffer)[2 * i]; } } else { memcpy( outData, inputBuffer, numPixels * channelNum * get_explicit_type_size(inType) ); } return outData; } else if( inType == kChar ) { cl_char *src = (cl_char *)inputBuffer; switch( outType ) { case kInt: { cl_int *outData = new cl_int[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_int)((src[ i ])); } return (char *)outData; } case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)src[ i ] / 127.0f; } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kUChar ) { cl_uchar *src = (cl_uchar *)inputBuffer; switch( outType ) { case kUInt: { cl_uint *outData = new cl_uint[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_uint)((src[ i ])); } return (char *)outData; } case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)(src[ i ]) / 256.0f; } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kShort ) { cl_short *src = (cl_short *)inputBuffer; switch( outType ) { case kInt: { cl_int *outData = new cl_int[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_int)((src[ i ])); } return (char *)outData; } case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)src[ i ] / 32768.0f; } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kUShort ) { cl_ushort *src = (cl_ushort *)inputBuffer; switch( outType ) { case kUInt: { cl_uint *outData = new cl_uint[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_uint)((src[ i ])); } return (char *)outData; } case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)(src[ i ]) / 65535.0f; } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kInt ) { cl_int *src = (cl_int *)inputBuffer; switch( outType ) { DOWNSCALE_INTEGER_CASE( kShort, short, 16 ) DOWNSCALE_INTEGER_CASE( kChar, char, 24 ) case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)fmaxf( (float)src[ i ] / 2147483647.f, -1.f ); } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kUInt ) { cl_uint *src = (cl_uint *)inputBuffer; switch( outType ) { DOWNSCALE_INTEGER_CASE( kUShort, ushort, 16 ) DOWNSCALE_INTEGER_CASE( kUChar, uchar, 24 ) case kFloat: { // If we're converting to float, then CL decided that we should be normalized cl_float *outData = new cl_float[ numPixels * channelNum ]; const cl_float MaxValue = (glDataType == GL_UNSIGNED_INT_24_8) ? 16777215.f : 4294967295.f; const cl_uint ShiftBits = (glDataType == GL_UNSIGNED_INT_24_8) ? 8 : 0; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[ i ] = (cl_float)(src[ i ] >> ShiftBits) / MaxValue; } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else if( inType == kHalf ) { cl_half *src = (cl_half *)inputBuffer; switch( outType ) { case kFloat: { cl_float *outData = new cl_float[ numPixels * channelNum ]; for( size_t i = 0; i < numPixels * channelNum; i++ ) { outData[i] = cl_half_to_float(src[i]); } return (char *)outData; } default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } else { cl_float *src = (cl_float *)inputBuffer; switch( outType ) { UPSCALE_FLOAT_CASE( kChar, char, 127.f ) UPSCALE_FLOAT_CASE( kUChar, uchar, 255.f ) UPSCALE_FLOAT_CASE( kShort, short, 32767.f ) UPSCALE_FLOAT_CASE( kUShort, ushort, 65535.f ) UPSCALE_FLOAT_CASE( kInt, int, 2147483647.f ) UPSCALE_FLOAT_CASE( kUInt, uint, 4294967295.f ) default: log_error( "ERROR: Unsupported conversion from %s to %s!\n", get_explicit_type_name( inType ), get_explicit_type_name( outType ) ); return NULL; } } return NULL; } int validate_integer_results( void *expectedResults, void *actualResults, size_t width, size_t height, size_t sampleNum, size_t typeSize ) { return validate_integer_results( expectedResults, actualResults, width, height, sampleNum, 0, typeSize ); } int validate_integer_results( void *expectedResults, void *actualResults, size_t width, size_t height, size_t depth, size_t sampleNum, size_t typeSize ) { char *expected = (char *)expectedResults; char *actual = (char *)actualResults; for ( size_t s = 0; s < sampleNum; s++ ) { for( size_t z = 0; z < ( ( depth == 0 ) ? 1 : depth ); z++ ) { for( size_t y = 0; y < height; y++ ) { for( size_t x = 0; x < width; x++ ) { if( memcmp( expected, actual, typeSize * 4 ) != 0 ) { char scratch[ 1024 ]; if( depth == 0 ) log_error( "ERROR: Data sample %d,%d,%d did not validate!\n", (int)x, (int)y, (int)s ); else log_error( "ERROR: Data sample %d,%d,%d,%d did not validate!\n", (int)x, (int)y, (int)z, (int)s ); log_error( "\tExpected: %s\n", GetDataVectorString( expected, typeSize, 4, scratch ) ); log_error( "\t Actual: %s\n", GetDataVectorString( actual, typeSize, 4, scratch ) ); return -1; } expected += typeSize * 4; actual += typeSize * 4; } } } } return 0; } int validate_float_results( void *expectedResults, void *actualResults, size_t width, size_t height, size_t sampleNum, size_t channelNum ) { return validate_float_results( expectedResults, actualResults, width, height, sampleNum, 0, channelNum ); } int validate_float_results( void *expectedResults, void *actualResults, size_t width, size_t height, size_t depth, size_t sampleNum, size_t channelNum ) { cl_float *expected = (cl_float *)expectedResults; cl_float *actual = (cl_float *)actualResults; for ( size_t s = 0; s < sampleNum; s++ ) { for( size_t z = 0; z < ( ( depth == 0 ) ? 1 : depth ); z++ ) { for( size_t y = 0; y < height; y++ ) { for( size_t x = 0; x < width; x++ ) { float err = 0.f; for( size_t i = 0; i < channelNum; i++ ) { float error = fabsf( expected[ i ] - actual[ i ] ); if( error > err ) err = error; } if( err > 1.f / 127.f ) // Max expected range of error if we converted from an 8-bit integer to a normalized float { if( depth == 0 ) log_error( "ERROR: Data sample %d,%d,%d did not validate!\n", (int)x, (int)y, (int)s ); else log_error( "ERROR: Data sample %d,%d,%d,%d did not validate!\n", (int)x, (int)y, (int)z, (int)s ); if (channelNum == 4) { log_error( "\tExpected: %f %f %f %f\n", expected[ 0 ], expected[ 1 ], expected[ 2 ], expected[ 3 ] ); log_error( "\t : %a %a %a %a\n", expected[ 0 ], expected[ 1 ], expected[ 2 ], expected[ 3 ] ); log_error( "\t Actual: %f %f %f %f\n", actual[ 0 ], actual[ 1 ], actual[ 2 ], actual[ 3 ] ); log_error( "\t : %a %a %a %a\n", actual[ 0 ], actual[ 1 ], actual[ 2 ], actual[ 3 ] ); } else if(channelNum == 1) { log_error( "\tExpected: %f\n", expected[ 0 ] ); log_error( "\t : %a\n", expected[ 0 ] ); log_error( "\t Actual: %f\n", actual[ 0 ] ); log_error( "\t : %a\n", actual[ 0 ] ); } return -1; } expected += channelNum; actual += channelNum; } } } } return 0; } int validate_float_results_rgb_101010( void *expectedResults, void *actualResults, size_t width, size_t height, size_t sampleNum ) { return validate_float_results_rgb_101010( expectedResults, actualResults, width, height, sampleNum, 0 ); } int validate_float_results_rgb_101010( void *expectedResults, void *actualResults, size_t width, size_t height, size_t depth, size_t sampleNum ) { cl_float *expected = (cl_float *)expectedResults; cl_float *actual = (cl_float *)actualResults; for ( size_t s = 0; s < sampleNum; s++ ) { for( size_t z = 0; z < ( ( depth == 0 ) ? 1 : depth ); z++ ) { for( size_t y = 0; y < height; y++ ) { for( size_t x = 0; x < width; x++ ) { float err = 0.f; for( size_t i = 0; i < 3; i++ ) // skip the fourth channel { float error = fabsf( expected[ i ] - actual[ i ] ); if( error > err ) err = error; } if( err > 1.f / 127.f ) // Max expected range of error if we converted from an 8-bit integer to a normalized float { if( depth == 0 ) log_error( "ERROR: Data sample %d,%d,%d did not validate!\n", (int)x, (int)y, (int)s ); else log_error( "ERROR: Data sample %d,%d,%d,%d did not validate!\n", (int)x, (int)y, (int)z, (int)s ); log_error( "\tExpected: %f %f %f\n", expected[ 0 ], expected[ 1 ], expected[ 2 ] ); log_error( "\t : %a %a %a\n", expected[ 0 ], expected[ 1 ], expected[ 2 ] ); log_error( "\t Actual: %f %f %f\n", actual[ 0 ], actual[ 1 ], actual[ 2 ] ); log_error( "\t : %a %a %a\n", actual[ 0 ], actual[ 1 ], actual[ 2 ] ); return -1; } expected += 4; actual += 4; } } } } return 0; } int CheckGLObjectInfo(cl_mem mem, cl_gl_object_type expected_cl_gl_type, GLuint expected_gl_name, GLenum expected_cl_gl_texture_target, GLint expected_cl_gl_mipmap_level) { cl_gl_object_type object_type; GLuint object_name; GLenum texture_target; GLint mipmap_level; int error; error = (*clGetGLObjectInfo_ptr)(mem, &object_type, &object_name); test_error( error, "clGetGLObjectInfo failed"); if (object_type != expected_cl_gl_type) { log_error("clGetGLObjectInfo did not return expected object type: expected %d, got %d.\n", expected_cl_gl_type, object_type); return -1; } if (object_name != expected_gl_name) { log_error("clGetGLObjectInfo did not return expected object name: expected %d, got %d.\n", expected_gl_name, object_name); return -1; } // If we're dealing with a buffer or render buffer, we are done. if (object_type == CL_GL_OBJECT_BUFFER || object_type == CL_GL_OBJECT_RENDERBUFFER) { return 0; } // Otherwise, it's a texture-based object and requires a bit more checking. error = (*clGetGLTextureInfo_ptr)(mem, CL_GL_TEXTURE_TARGET, sizeof(texture_target), &texture_target, NULL); test_error( error, "clGetGLTextureInfo for CL_GL_TEXTURE_TARGET failed"); if (texture_target != expected_cl_gl_texture_target) { log_error("clGetGLTextureInfo did not return expected texture target: expected %d, got %d.\n", expected_cl_gl_texture_target, texture_target); return -1; } error = (*clGetGLTextureInfo_ptr)(mem, CL_GL_MIPMAP_LEVEL, sizeof(mipmap_level), &mipmap_level, NULL); test_error( error, "clGetGLTextureInfo for CL_GL_MIPMAP_LEVEL failed"); if (mipmap_level != expected_cl_gl_mipmap_level) { log_error("clGetGLTextureInfo did not return expected mipmap level: expected %d, got %d.\n", expected_cl_gl_mipmap_level, mipmap_level); return -1; } return 0; } bool CheckGLIntegerExtensionSupport() { // Get the OpenGL version and supported extensions const GLubyte *glVersion = glGetString(GL_VERSION); const GLubyte *glExtensionList = glGetString(GL_EXTENSIONS); // Check if the OpenGL vrsion is 3.0 or grater or GL_EXT_texture_integer is supported return (((glVersion[0] - '0') >= 3) || (strstr((const char*)glExtensionList, "GL_EXT_texture_integer"))); } int is_rgb_101010_supported( cl_context context, GLenum gl_target ) { cl_image_format formatList[ 128 ]; cl_uint formatCount = 0; unsigned int i; int error; cl_mem_object_type image_type; switch (get_base_gl_target(gl_target)) { case GL_TEXTURE_1D: image_type = CL_MEM_OBJECT_IMAGE1D; case GL_TEXTURE_BUFFER: image_type = CL_MEM_OBJECT_IMAGE1D_BUFFER; break; case GL_TEXTURE_RECTANGLE_EXT: case GL_TEXTURE_2D: case GL_COLOR_ATTACHMENT0: case GL_RENDERBUFFER: case GL_TEXTURE_CUBE_MAP: case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: image_type = CL_MEM_OBJECT_IMAGE2D; break; case GL_TEXTURE_3D: image_type = CL_MEM_OBJECT_IMAGE3D; case GL_TEXTURE_1D_ARRAY: image_type = CL_MEM_OBJECT_IMAGE1D_ARRAY; case GL_TEXTURE_2D_ARRAY: image_type = CL_MEM_OBJECT_IMAGE2D_ARRAY; break; default: image_type = CL_MEM_OBJECT_IMAGE2D; } if ((error = clGetSupportedImageFormats(context, CL_MEM_READ_WRITE, image_type, 128, formatList, &formatCount ))) { return error; } // Check if the RGB 101010 format is supported for( i = 0; i < formatCount; i++ ) { if( formatList[ i ].image_channel_data_type == CL_UNORM_INT_101010 ) { return 1; } } return 0; }