/* Copyright (c) 2010 - 2021 Advanced Micro Devices, Inc. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include "top.hpp" #include "hip/hip_runtime.h" #include "hip_internal.hpp" #include "cl_gl_amd.hpp" #include "cl_common.hpp" #include #include #include "hip_conversions.hpp" namespace amd { static std::once_flag interopOnce; } // Sets up GL context association with amd context. // NOTE: Refer to Context setup code in OCLTestImp.cpp void setupGLInteropOnce() { amd::Context* amdContext = hip::getCurrentDevice()->asContext(); //current context will be read in amdContext->create cl_context_properties properties[] = {CL_CONTEXT_PLATFORM, (cl_context_properties)AMD_PLATFORM, ROCCLR_HIP_GL_CONTEXT_KHR, (cl_context_properties) nullptr, #ifdef _WIN32 ROCCLR_HIP_WGL_HDC_KHR, (cl_context_properties) nullptr, #else ROCCLR_HIP_GLX_DISPLAY_KHR, (cl_context_properties) nullptr, #endif 0}; amd::Context::Info info; if (CL_SUCCESS != amd::Context::checkProperties(properties, &info)) { LogError("Context setup failed \n"); return; } amdContext->setInfo(info); if (CL_SUCCESS != amdContext->create(properties)) { LogError("Context setup failed \n"); } } static inline hipError_t hipSetInteropObjects(int num_objects, void** mem_objects, std::vector& interopObjects) { if ((num_objects == 0 && mem_objects != nullptr) || (num_objects != 0 && mem_objects == nullptr)) { return hipErrorUnknown; } while (num_objects-- > 0) { void* obj = *mem_objects++; if (obj == nullptr) { return hipErrorInvalidResourceHandle; } amd::Memory* mem = reinterpret_cast(obj); if (mem->getInteropObj() == nullptr) { return hipErrorInvalidResourceHandle; } interopObjects.push_back(mem); } return hipSuccess; } // NOTE: This method cooresponds to OpenCL functionality in clGetGLContextInfoKHR() hipError_t hipGLGetDevices(unsigned int* pHipDeviceCount, int* pHipDevices, unsigned int hipDeviceCount, hipGLDeviceList deviceList) { HIP_INIT_API(hipGLGetDevices, pHipDeviceCount, pHipDevices, hipDeviceCount, deviceList); std::call_once(amd::interopOnce, setupGLInteropOnce); static const bool VALIDATE_ONLY = true; if (deviceList == hipGLDeviceListNextFrame) { LogError(" hipGLDeviceListNextFrame not supported yet.\n"); HIP_RETURN(hipErrorNotSupported); } if (pHipDeviceCount == nullptr || pHipDevices == nullptr || hipDeviceCount == 0) { LogError(" Invalid Argument \n"); HIP_RETURN(hipErrorInvalidValue); } hipDeviceCount = std::min(hipDeviceCount, static_cast(g_devices.size())); amd::Context::Info info = hip::getCurrentDevice()->asContext()->info(); if (!(info.flags_ & amd::Context::GLDeviceKhr)) { LogError("Failed : Invalid Shared Group Reference \n"); HIP_RETURN(hipErrorInvalidValue); } amd::GLFunctions* glenv = hip::getCurrentDevice()->asContext()->glenv(); if (glenv != nullptr) { #ifdef _WIN32 info.hCtx_ = glenv->wglGetCurrentContext_(); #else info.hCtx_ = glenv->glXGetCurrentContext_(); #endif hip::getCurrentDevice()->asContext()->setInfo(info); glenv->update(reinterpret_cast(info.hCtx_)); } *pHipDeviceCount = 0; switch (deviceList) { case hipGLDeviceListCurrentFrame: for (int i = 0; i < hipDeviceCount; ++i) { const std::vector& devices = g_devices[i]->devices(); if (devices.size() > 0 && devices[0]->bindExternalDevice(info.flags_, info.hDev_, info.hCtx_, VALIDATE_ONLY)) { pHipDevices[0] = i; *pHipDeviceCount = 1; break; } } break; case hipGLDeviceListAll: { int foundDeviceCount = 0; for (int i = 0; i < hipDeviceCount; ++i) { const std::vector& devices = g_devices[i]->devices(); if (devices.size() > 0 && devices[0]->bindExternalDevice(info.flags_, info.hDev_, info.hCtx_, VALIDATE_ONLY)) { pHipDevices[foundDeviceCount++] = i; break; } } *pHipDeviceCount = foundDeviceCount; } break; default: LogWarning("Invalid deviceList value"); HIP_RETURN(hipErrorInvalidValue); } HIP_RETURN(*pHipDeviceCount > 0 ? hipSuccess : hipErrorNoDevice); } static inline void clearGLErrors(const amd::Context& amdContext) { GLenum glErr, glLastErr = GL_NO_ERROR; while (1) { glErr = amdContext.glenv()->glGetError_(); if (glErr == GL_NO_ERROR || glErr == glLastErr) { break; } glLastErr = glErr; LogWarning("GL error"); } } static inline GLenum checkForGLError(const amd::Context& amdContext) { GLenum glRetErr = GL_NO_ERROR; GLenum glErr; while (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { glRetErr = glErr; // Just return the last GL error LogWarning("Check GL error"); } return glRetErr; } hipError_t hipGraphicsSubResourceGetMappedArray(hipArray_t* array, hipGraphicsResource_t resource, unsigned int arrayIndex, unsigned int mipLevel) { HIP_INIT_API(hipGraphicsSubResourceGetMappedArray, array, resource, arrayIndex, mipLevel); amd::Context& amdContext = *(hip::getCurrentDevice()->asContext()); if (array == nullptr || resource == nullptr) { LogError("invalid array/resource"); HIP_RETURN(hipErrorInvalidValue); } amd::Image* image = (reinterpret_cast(resource))->asImage(); if (image == nullptr) { LogError("invalid resource/image"); HIP_RETURN(hipErrorInvalidValue); } // arrayIndex higher than zero not implmented assert(arrayIndex == 0) ; amd::Image * view = image->createView(amdContext, image->getImageFormat(), nullptr, mipLevel, 0); hipArray* myarray = new hipArray(); myarray->data = as_cl (view); myarray->width = view->getWidth(); myarray->height = view->getHeight(); myarray->depth = view->getDepth(); const cl_mem_object_type image_type = hip::getCLMemObjectType(myarray->width, myarray->height, myarray->depth, hipArrayDefault); myarray->type = image_type; amd::Image::Format f = image->getImageFormat(); myarray->Format = hip::getCL2hipArrayFormat(f.image_channel_data_type); myarray->desc = hip::getChannelFormatDesc(f.getNumChannels(), myarray->Format); myarray->NumChannels = hip::getNumChannels(myarray->desc); myarray->isDrv = 0; myarray->textureType = 0; *array = myarray; HIP_RETURN(hipSuccess); } hipError_t hipGraphicsGLRegisterImage(hipGraphicsResource** resource, GLuint image, GLenum target, unsigned int flags) { HIP_INIT_API(hipGraphicsGLRegisterImage, resource, image, target, flags); if (!((flags == hipGraphicsRegisterFlagsNone) || (flags == hipGraphicsRegisterFlagsReadOnly) || (flags == hipGraphicsRegisterFlagsWriteDiscard) || (flags == hipGraphicsRegisterFlagsSurfaceLoadStore) || (flags == hipGraphicsRegisterFlagsTextureGather))) { LogError("invalid parameter \"flags\""); HIP_RETURN(hipErrorInvalidValue); } if (resource == nullptr) { LogError("invalid resource"); HIP_RETURN(hipErrorInvalidValue); } GLint miplevel = 0; amd::Context& amdContext = *(hip::getCurrentDevice()->asContext()); if (amdContext.glenv() == nullptr) { LogError("invalid context, gl interop not initialized"); HIP_RETURN(hipErrorInvalidValue); } amd::GLFunctions::SetIntEnv ie(amdContext.glenv()); if (!ie.isValid()) { LogWarning("\"amdContext\" is not created from GL context or share list \n"); HIP_RETURN(hipErrorUnknown); } amd::ImageGL* pImageGL = NULL; GLenum glErr; GLenum glTarget = 0; GLenum glInternalFormat; cl_image_format clImageFormat; uint dim = 1; cl_mem_object_type clType; cl_gl_object_type clGLType; GLsizei numSamples = 1; GLint gliTexWidth = 1; GLint gliTexHeight = 1; GLint gliTexDepth = 1; // Verify GL texture object clearGLErrors(amdContext); if ((GL_FALSE == amdContext.glenv()->glIsTexture_(image)) || (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_()))) { LogWarning("\"texture\" is not a GL texture object"); HIP_RETURN(hipErrorUnknown); } bool isImage = true; // Check target value validity switch (target) { case GL_TEXTURE_BUFFER: glTarget = GL_TEXTURE_BUFFER; dim = 1; clType = CL_MEM_OBJECT_IMAGE1D_BUFFER; clGLType = CL_GL_OBJECT_TEXTURE_BUFFER; isImage = false; break; case GL_TEXTURE_1D: glTarget = GL_TEXTURE_1D; dim = 1; clType = CL_MEM_OBJECT_IMAGE1D; clGLType = CL_GL_OBJECT_TEXTURE1D; break; case GL_TEXTURE_CUBE_MAP_POSITIVE_X: case GL_TEXTURE_CUBE_MAP_NEGATIVE_X: case GL_TEXTURE_CUBE_MAP_POSITIVE_Y: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Y: case GL_TEXTURE_CUBE_MAP_POSITIVE_Z: case GL_TEXTURE_CUBE_MAP_NEGATIVE_Z: glTarget = GL_TEXTURE_CUBE_MAP; dim = 2; clType = CL_MEM_OBJECT_IMAGE2D; clGLType = CL_GL_OBJECT_TEXTURE2D; break; case GL_TEXTURE_1D_ARRAY: glTarget = GL_TEXTURE_1D_ARRAY; dim = 2; clType = CL_MEM_OBJECT_IMAGE1D_ARRAY; clGLType = CL_GL_OBJECT_TEXTURE1D_ARRAY; break; case GL_TEXTURE_2D: glTarget = GL_TEXTURE_2D; dim = 2; clType = CL_MEM_OBJECT_IMAGE2D; clGLType = CL_GL_OBJECT_TEXTURE2D; break; case GL_TEXTURE_2D_MULTISAMPLE: glTarget = GL_TEXTURE_2D_MULTISAMPLE; dim = 2; clType = CL_MEM_OBJECT_IMAGE2D; clGLType = CL_GL_OBJECT_TEXTURE2D; break; case GL_TEXTURE_RECTANGLE_ARB: glTarget = GL_TEXTURE_RECTANGLE_ARB; dim = 2; clType = CL_MEM_OBJECT_IMAGE2D; clGLType = CL_GL_OBJECT_TEXTURE2D; break; case GL_TEXTURE_2D_ARRAY: glTarget = GL_TEXTURE_2D_ARRAY; dim = 3; clType = CL_MEM_OBJECT_IMAGE2D_ARRAY; clGLType = CL_GL_OBJECT_TEXTURE2D_ARRAY; break; case GL_TEXTURE_3D: glTarget = GL_TEXTURE_3D; dim = 3; clType = CL_MEM_OBJECT_IMAGE3D; clGLType = CL_GL_OBJECT_TEXTURE3D; break; default: // wrong value LogWarning("invalid \"target\" value"); HIP_RETURN(hipErrorInvalidValue); break; } amdContext.glenv()->glBindTexture_(glTarget, image); // Check if size is available - data store is created if (isImage) { // Check mipmap level for "texture" name GLint gliTexBaseLevel; GLint gliTexMaxLevel; clearGLErrors(amdContext); amdContext.glenv()->glGetTexParameteriv_(glTarget, GL_TEXTURE_BASE_LEVEL, &gliTexBaseLevel); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get base mipmap level of a GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } clearGLErrors(amdContext); amdContext.glenv()->glGetTexParameteriv_(glTarget, GL_TEXTURE_MAX_LEVEL, &gliTexMaxLevel); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get max mipmap level of a GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } if ((gliTexBaseLevel > miplevel) || (miplevel > gliTexMaxLevel)) { LogWarning("\"miplevel\" is not a valid mipmap level of the GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } // Get GL texture format and check if it's compatible with CL format clearGLErrors(amdContext); amdContext.glenv()->glGetTexLevelParameteriv_(target, miplevel, GL_TEXTURE_INTERNAL_FORMAT, (GLint*)&glInternalFormat); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get internal format of \"miplevel\" of GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } amdContext.glenv()->glGetTexLevelParameteriv_(target, miplevel, GL_TEXTURE_SAMPLES, (GLint*)&numSamples); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get numbers of samples of GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } if (numSamples > 1) { LogWarning("MSAA \"texture\" object is not suppoerted for the device"); HIP_RETURN(hipErrorInvalidValue); } // Now get CL format from GL format and bytes per pixel int iBytesPerPixel = 0; if (!getCLFormatFromGL(amdContext, glInternalFormat, &clImageFormat, &iBytesPerPixel, 0)) { //clFlags)) { LogWarning("\"texture\" format does not map to an appropriate CL image format"); HIP_RETURN(hipErrorInvalidValue); } switch (dim) { case 3: clearGLErrors(amdContext); amdContext.glenv()->glGetTexLevelParameteriv_(target, miplevel, GL_TEXTURE_DEPTH, &gliTexDepth); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get the depth of \"miplevel\" of GL \"texure\""); HIP_RETURN(hipErrorInvalidValue); } // Fall trough to process other dimensions... case 2: clearGLErrors(amdContext); amdContext.glenv()->glGetTexLevelParameteriv_(target, miplevel, GL_TEXTURE_HEIGHT, &gliTexHeight); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get the height of \"miplevel\" of GL \"texure\""); HIP_RETURN(hipErrorInvalidValue); } // Fall trough to process other dimensions... case 1: clearGLErrors(amdContext); amdContext.glenv()->glGetTexLevelParameteriv_(target, miplevel, GL_TEXTURE_WIDTH, &gliTexWidth); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get the width of \"miplevel\" of GL \"texure\""); HIP_RETURN(hipErrorInvalidValue); } break; default: LogWarning("invalid \"target\" value"); HIP_RETURN(hipErrorInvalidValue); } } else { GLint size; // In case target is GL_TEXTURE_BUFFER GLint backingBuffer; clearGLErrors(amdContext); amdContext.glenv()->glGetTexLevelParameteriv_( glTarget, 0, GL_TEXTURE_BUFFER_DATA_STORE_BINDING, &backingBuffer); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get backing buffer for GL \"texture buffer\" object"); HIP_RETURN(hipErrorInvalidValue); } amdContext.glenv()->glBindBuffer_(glTarget, backingBuffer); // Get GL texture format and check if it's compatible with CL format clearGLErrors(amdContext); amdContext.glenv()->glGetIntegerv_(GL_TEXTURE_BUFFER_FORMAT_EXT, reinterpret_cast(&glInternalFormat)); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get internal format of \"miplevel\" of GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } // Now get CL format from GL format and bytes per pixel int iBytesPerPixel = 0; if (!getCLFormatFromGL(amdContext, glInternalFormat, &clImageFormat, &iBytesPerPixel, flags)) { LogWarning("\"texture\" format does not map to an appropriate CL image format"); HIP_RETURN(hipErrorInvalidValue); } clearGLErrors(amdContext); amdContext.glenv()->glGetBufferParameteriv_(glTarget, GL_BUFFER_SIZE, &size); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("Cannot get internal format of \"miplevel\" of GL \"texture\" object"); HIP_RETURN(hipErrorInvalidValue); } gliTexWidth = size / iBytesPerPixel; } size_t imageSize = (clType == CL_MEM_OBJECT_IMAGE1D_ARRAY) ? static_cast(gliTexHeight) : static_cast(gliTexDepth); if (!amd::Image::validateDimensions( amdContext.devices(), clType, static_cast(gliTexWidth), static_cast(gliTexHeight), static_cast(gliTexDepth), imageSize)) { LogWarning("The GL \"texture\" data store is not created or out of supported dimensions"); HIP_RETURN(hipErrorInvalidValue); } target = (glTarget == GL_TEXTURE_CUBE_MAP) ? target : 0; pImageGL = new (amdContext) amd::ImageGL(amdContext, clType, flags, clImageFormat, static_cast(gliTexWidth), static_cast(gliTexHeight), static_cast(gliTexDepth), glTarget, image, 0, glInternalFormat, clGLType, numSamples, target); if (!pImageGL) { LogWarning("Cannot create class ImageGL - out of memory?"); HIP_RETURN(hipErrorUnknown); } if (!pImageGL->create()) { pImageGL->release(); HIP_RETURN(hipErrorUnknown); } // Create interop object if (pImageGL->getInteropObj() == nullptr) { LogWarning("cannot create object of class BufferGL"); pImageGL->release(); HIP_RETURN(hipErrorUnknown); } // Fixme: If more than one device is present in the context, we choose the first device. // We should come up with a more elegant solution to handle this. assert(amdContext.devices().size() == 1); const amd::Device& dev = *(amdContext.devices()[0]); device::Memory* mem = pImageGL->getDeviceMemory(dev); if (nullptr == mem) { LogPrintfError("Can't allocate memory size - 0x%08X bytes!", pImageGL->getSize()); pImageGL->release(); HIP_RETURN(hipErrorUnknown); } mem->processGLResource(device::Memory::GLDecompressResource); *resource = reinterpret_cast(pImageGL); HIP_RETURN(hipSuccess); } hipError_t hipGraphicsGLRegisterBuffer(hipGraphicsResource** resource, GLuint buffer, unsigned int flags) { HIP_INIT_API(hipGraphicsGLRegisterBuffer, resource, buffer, flags); if (!((flags == hipGraphicsRegisterFlagsNone) || (flags == hipGraphicsRegisterFlagsReadOnly) || (flags == hipGraphicsRegisterFlagsWriteDiscard) || (flags == hipGraphicsRegisterFlagsSurfaceLoadStore) || (flags == hipGraphicsRegisterFlagsTextureGather))) { LogError("invalid parameter \"flags\""); HIP_RETURN(hipErrorInvalidValue); } if (resource == nullptr) { LogError("invalid resource"); HIP_RETURN(hipErrorInvalidValue); } amd::BufferGL* pBufferGL = nullptr; GLenum glErr; GLenum glTarget = GL_ARRAY_BUFFER; GLint gliSize = 0; GLint gliMapped = 0; amd::Context& amdContext = *(hip::getCurrentDevice()->asContext()); if (amdContext.glenv() == nullptr) { LogError("invalid context, gl interop not initialized"); HIP_RETURN(hipErrorInvalidValue); } // Add this scope to bound the scoped lock { amd::GLFunctions::SetIntEnv ie(amdContext.glenv()); if (!ie.isValid()) { LogWarning("\"amdContext\" is not created from GL context or share list \n"); HIP_RETURN(hipErrorUnknown); } // Verify GL buffer object clearGLErrors(amdContext); if ((GL_FALSE == amdContext.glenv()->glIsBuffer_(buffer)) || (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_()))) { LogWarning("\"buffer\" is not a GL buffer object \n"); HIP_RETURN(hipErrorInvalidResourceHandle); } // Check if size is available - data store is created amdContext.glenv()->glBindBuffer_(glTarget, buffer); clearGLErrors(amdContext); amdContext.glenv()->glGetBufferParameteriv_(glTarget, GL_BUFFER_SIZE, &gliSize); if (GL_NO_ERROR != (glErr = amdContext.glenv()->glGetError_())) { LogWarning("cannot get the GL buffer size \n"); HIP_RETURN(hipErrorInvalidResourceHandle); } if (gliSize == 0) { LogWarning("the GL buffer's data store is not created \n"); HIP_RETURN(hipErrorInvalidResourceHandle); } } // Release scoped lock // Now create BufferGL object pBufferGL = new (amdContext) amd::BufferGL(amdContext, flags, gliSize, 0, buffer); if (!pBufferGL) { LogWarning("cannot create object of class BufferGL"); HIP_RETURN(hipErrorUnknown); } if (!pBufferGL->create()) { pBufferGL->release(); HIP_RETURN(hipErrorUnknown); } // Create interop object if (pBufferGL->getInteropObj() == nullptr) { LogWarning("cannot create object of class BufferGL"); HIP_RETURN(hipErrorUnknown); } // Fixme: If more than one device is present in the context, we choose the first device. // We should come up with a more elegant solution to handle this. assert(amdContext.devices().size() == 1); const auto it = amdContext.devices().cbegin(); const amd::Device& dev = *(*it); device::Memory* mem = pBufferGL->getDeviceMemory(dev); if (nullptr == mem) { LogPrintfError("Can't allocate memory size - 0x%08X bytes!", pBufferGL->getSize()); HIP_RETURN(hipErrorUnknown); } mem->processGLResource(device::Memory::GLDecompressResource); *resource = reinterpret_cast(pBufferGL); HIP_RETURN(hipSuccess); } hipError_t hipGraphicsMapResources(int count, hipGraphicsResource_t* resources, hipStream_t stream) { HIP_INIT_API(hipGraphicsMapResources, count, resources, stream); amd::Context* amdContext = hip::getCurrentDevice()->asContext(); if (!amdContext || !amdContext->glenv()) { HIP_RETURN(hipErrorUnknown); } clearGLErrors(*amdContext); amdContext->glenv()->glFinish_(); if (checkForGLError(*amdContext) != GL_NO_ERROR) { HIP_RETURN(hipErrorUnknown); } amd::HostQueue* queue = hip::getQueue(stream); if (nullptr == queue) { HIP_RETURN(hipErrorUnknown); } amd::HostQueue& hostQueue = *queue; if (!hostQueue.context().glenv() || !hostQueue.context().glenv()->isAssociated()) { LogWarning("\"amdContext\" is not created from GL context or share list"); HIP_RETURN(hipErrorUnknown); } std::vector memObjects; hipError_t err = hipSetInteropObjects(count, reinterpret_cast(resources), memObjects); if (err != hipSuccess) { HIP_RETURN(err); } amd::Command::EventWaitList nullWaitList; //! Now create command and enqueue amd::AcquireExtObjectsCommand* command = new amd::AcquireExtObjectsCommand( hostQueue, nullWaitList, count, memObjects, CL_COMMAND_ACQUIRE_GL_OBJECTS); if (command == nullptr) { HIP_RETURN(hipErrorUnknown); } // Make sure we have memory for the command execution if (!command->validateMemory()) { delete command; HIP_RETURN(hipErrorUnknown); } command->enqueue(); // *not_null(event) = as_cl(&command->event()); if (as_cl(&command->event()) == nullptr) { command->release(); } HIP_RETURN(hipSuccess); } hipError_t hipGraphicsResourceGetMappedPointer(void** devPtr, size_t* size, hipGraphicsResource_t resource) { HIP_INIT_API(hipGraphicsResourceGetMappedPointer, devPtr, size, resource); amd::Context* amdContext = hip::getCurrentDevice()->asContext(); if (!amdContext || !amdContext->glenv()) { HIP_RETURN(hipErrorUnknown); } // Fixme: If more than one device is present in the context, we choose the first device. // We should come up with a more elegant solution to handle this. assert(amdContext->devices().size() == 1); const auto it = amdContext->devices().cbegin(); amd::Device* curDev = *it; amd::Memory* amdMem = reinterpret_cast(resource); *size = amdMem->getSize(); // Interop resources don't have svm allocations they are added to // amd::MemObjMap using device virtual address during creation. device::Memory* mem = reinterpret_cast(amdMem->getDeviceMemory(*curDev)); *devPtr = reinterpret_cast(static_cast(mem->virtualAddress())); HIP_RETURN(hipSuccess); } hipError_t hipGraphicsUnmapResources(int count, hipGraphicsResource_t* resources, hipStream_t stream) { HIP_INIT_API(hipGraphicsUnmapResources, count, resources, stream); if (!hip::isValid(stream)) { HIP_RETURN(hipErrorContextIsDestroyed); } // Wait for the current host queue hip::getQueue(stream)->finish(); amd::HostQueue* queue = hip::getQueue(stream); if (nullptr == queue) { HIP_RETURN(hipErrorUnknown); } amd::HostQueue& hostQueue = *queue; std::vector memObjects; hipError_t err = hipSetInteropObjects(count, reinterpret_cast(resources), memObjects); if (err != hipSuccess) { HIP_RETURN(err); } amd::Command::EventWaitList nullWaitList; // Now create command and enqueue amd::ReleaseExtObjectsCommand* command = new amd::ReleaseExtObjectsCommand( hostQueue, nullWaitList, count, memObjects, CL_COMMAND_RELEASE_GL_OBJECTS); if (command == nullptr) { HIP_RETURN(hipErrorUnknown); } // Make sure we have memory for the command execution if (!command->validateMemory()) { delete command; HIP_RETURN(hipErrorUnknown); } command->enqueue(); if (as_cl(&command->event()) == nullptr) { command->release(); } HIP_RETURN(hipSuccess); } hipError_t hipGraphicsUnregisterResource(hipGraphicsResource_t resource) { HIP_INIT_API(hipGraphicsUnregisterResource, resource); amd::BufferGL* pBufferGL = reinterpret_cast(resource); delete pBufferGL; HIP_RETURN(hipSuccess); }