#include "common.h" #include "kernel/vc4_packet.h" #include "../brcm/cle/v3d_decoder.h" #include "../brcm/clif/clif_dump.h" /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#commandbuffers-pools * Command pools are opaque objects that command buffer memory is allocated from, and which allow the implementation to amortize the * cost of resource creation across multiple command buffers. Command pools are externally synchronized, meaning that a command pool must * not be used concurrently in multiple threads. That includes use via recording commands on any command buffers allocated from the pool, * as well as operations that allocate, free, and reset command buffers or the pool itself. */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkCreateCommandPool( VkDevice device, const VkCommandPoolCreateInfo* pCreateInfo, const VkAllocationCallbacks* pAllocator, VkCommandPool* pCommandPool) { assert(device); assert(pCreateInfo); //TODO VK_COMMAND_POOL_CREATE_TRANSIENT_BIT //specifies that command buffers allocated from the pool will be short-lived, meaning that they will be reset or freed in a relatively short timeframe. //This flag may be used by the implementation to control memory allocation behavior within the pool. //--> definitely use pool allocator //TODO pool family ignored for now _commandPool* cp = ALLOCATE(sizeof(_commandPool), 1, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if(!cp) { return VK_ERROR_OUT_OF_HOST_MEMORY; } cp->queueFamilyIndex = pCreateInfo->queueFamilyIndex; cp->resetAble = pCreateInfo->flags & VK_COMMAND_POOL_CREATE_RESET_COMMAND_BUFFER_BIT; //TODO CTS fails as we can't allocate enough memory for some reason //tweak system allocation as root using: //make sure kernel denies memory allocation that it won't be able to serve //sysctl -w vm.overcommit_memory="2" //specify after how much memory used the kernel will start denying requests //sysctl -w vm.overcommit_ratio="80" // //initial number of command buffers to hold int numCommandBufs = 128; int consecutivePoolSize = ARM_PAGE_SIZE*128; int consecutiveBlockSize = ARM_PAGE_SIZE>>2; static int counter = 0; //if(pCreateInfo->flags & VK_COMMAND_POOL_CREATE_TRANSIENT_BIT) { //use pool allocator void* pamem = ALLOCATE(numCommandBufs * sizeof(_commandBuffer), 1, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if(!pamem) { return VK_ERROR_OUT_OF_HOST_MEMORY; } cp->pa = createPoolAllocator(pamem, sizeof(_commandBuffer), numCommandBufs * sizeof(_commandBuffer)); void* cpamem = ALLOCATE(consecutivePoolSize, 1, VK_SYSTEM_ALLOCATION_SCOPE_OBJECT); if(!cpamem) { return VK_ERROR_OUT_OF_HOST_MEMORY; } cp->cpa = createConsecutivePoolAllocator(cpamem, consecutiveBlockSize, consecutivePoolSize); } *pCommandPool = (VkCommandPool)cp; return VK_SUCCESS; } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#commandbuffer-allocation * vkAllocateCommandBuffers can be used to create multiple command buffers. If the creation of any of those command buffers fails, * the implementation must destroy all successfully created command buffer objects from this command, set all entries of the pCommandBuffers array to NULL and return the error. */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkAllocateCommandBuffers( VkDevice device, const VkCommandBufferAllocateInfo* pAllocateInfo, VkCommandBuffer* pCommandBuffers) { assert(device); assert(pAllocateInfo); assert(pCommandBuffers); VkResult res = VK_SUCCESS; _commandPool* cp = (_commandPool*)pAllocateInfo->commandPool; //TODO secondary command buffers //if(cp->usePoolAllocator) { for(int c = 0; c < pAllocateInfo->commandBufferCount; ++c) { pCommandBuffers[c] = poolAllocate(&cp->pa); if(!pCommandBuffers[c]) { res = VK_ERROR_OUT_OF_HOST_MEMORY; break; } set_loader_magic_value(&pCommandBuffers[c]->loaderData); pCommandBuffers[c]->dev = device; pCommandBuffers[c]->shaderRecCount = 0; pCommandBuffers[c]->usageFlags = 0; pCommandBuffers[c]->state = CMDBUF_STATE_INITIAL; pCommandBuffers[c]->cp = cp; clInit(&pCommandBuffers[c]->binCl, consecutivePoolAllocate(&cp->cpa, 1)); clInit(&pCommandBuffers[c]->handlesCl, consecutivePoolAllocate(&cp->cpa, 1)); clInit(&pCommandBuffers[c]->shaderRecCl, consecutivePoolAllocate(&cp->cpa, 1)); clInit(&pCommandBuffers[c]->uniformsCl, consecutivePoolAllocate(&cp->cpa, 1)); pCommandBuffers[c]->graphicsPipeline = 0; pCommandBuffers[c]->computePipeline = 0; pCommandBuffers[c]->numDrawCallsSubmitted = 0; pCommandBuffers[c]->indexBuffer = 0; pCommandBuffers[c]->indexBufferOffset = 0; pCommandBuffers[c]->vertexBufferDirty = 1; pCommandBuffers[c]->indexBufferDirty = 1; pCommandBuffers[c]->viewportDirty = 1; pCommandBuffers[c]->lineWidthDirty = 1; pCommandBuffers[c]->depthBiasDirty = 1; pCommandBuffers[c]->graphicsPipelineDirty = 1; pCommandBuffers[c]->computePipelineDirty = 1; pCommandBuffers[c]->subpassDirty = 1; pCommandBuffers[c]->blendConstantsDirty = 1; pCommandBuffers[c]->scissorDirty = 1; pCommandBuffers[c]->depthBoundsDirty = 1; pCommandBuffers[c]->stencilCompareMaskDirty = 1; pCommandBuffers[c]->stencilWriteMaskDirty = 1; pCommandBuffers[c]->stencilReferenceDirty = 1; pCommandBuffers[c]->descriptorSetDirty = 1; pCommandBuffers[c]->pushConstantDirty = 1; pCommandBuffers[c]->perfmonID = 0; if(!pCommandBuffers[c]->binCl.buffer) { res = VK_ERROR_OUT_OF_HOST_MEMORY; break; } if(!pCommandBuffers[c]->handlesCl.buffer) { res = VK_ERROR_OUT_OF_HOST_MEMORY; break; } if(!pCommandBuffers[c]->shaderRecCl.buffer) { res = VK_ERROR_OUT_OF_HOST_MEMORY; break; } if(!pCommandBuffers[c]->uniformsCl.buffer) { res = VK_ERROR_OUT_OF_HOST_MEMORY; break; } } } if(res != VK_SUCCESS) { //if(cp->usePoolAllocator) { for(int c = 0; c < pAllocateInfo->commandBufferCount; ++c) { consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->binCl, pCommandBuffers[c]->binCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->handlesCl, pCommandBuffers[c]->handlesCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->shaderRecCl, pCommandBuffers[c]->shaderRecCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->uniformsCl, pCommandBuffers[c]->uniformsCl.numBlocks); poolFree(&cp->pa, pCommandBuffers[c]); pCommandBuffers[c] = 0; } } } return res; } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkBeginCommandBuffer */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkBeginCommandBuffer( VkCommandBuffer commandBuffer, const VkCommandBufferBeginInfo* pBeginInfo) { assert(commandBuffer); assert(pBeginInfo); //TODO secondary command buffers //VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT //specifies that each recording of the command buffer will only be submitted once, and the command buffer will be reset and recorded again between each submission. //TODO VK_COMMAND_BUFFER_USAGE_RENDER_PASS_CONTINUE_BIT //specifies that a secondary command buffer is considered to be entirely inside a render pass. If this is a primary command buffer, then this bit is ignored //TODO VK_COMMAND_BUFFER_USAGE_SIMULTANEOUS_USE_BIT //specifies that a command buffer can be resubmitted to a queue while it is in the pending state, and recorded into multiple primary command buffers //When a command buffer begins recording, all state in that command buffer is undefined commandBuffer->usageFlags = pBeginInfo->flags; commandBuffer->state = CMDBUF_STATE_RECORDING; //TODO reset state? return VK_SUCCESS; } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkEndCommandBuffer * If there was an error during recording, the application will be notified by an unsuccessful return code returned by vkEndCommandBuffer. * If the application wishes to further use the command buffer, the command buffer must be reset. The command buffer must have been in the recording state, * and is moved to the executable state. */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkEndCommandBuffer( VkCommandBuffer commandBuffer) { assert(commandBuffer); commandBuffer->state = CMDBUF_STATE_EXECUTABLE; return VK_SUCCESS; } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkQueueSubmit * vkQueueSubmit is a queue submission command, with each batch defined by an element of pSubmits as an instance of the VkSubmitInfo structure. * Batches begin execution in the order they appear in pSubmits, but may complete out of order. * Fence and semaphore operations submitted with vkQueueSubmit have additional ordering constraints compared to other submission commands, * with dependencies involving previous and subsequent queue operations. Information about these additional constraints can be found in the semaphore and * fence sections of the synchronization chapter. * Details on the interaction of pWaitDstStageMask with synchronization are described in the semaphore wait operation section of the synchronization chapter. * The order that batches appear in pSubmits is used to determine submission order, and thus all the implicit ordering guarantees that respect it. * Other than these implicit ordering guarantees and any explicit synchronization primitives, these batches may overlap or otherwise execute out of order. * If any command buffer submitted to this queue is in the executable state, it is moved to the pending state. Once execution of all submissions of a command buffer complete, * it moves from the pending state, back to the executable state. If a command buffer was recorded with the VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT flag, * it instead moves back to the invalid state. * If vkQueueSubmit fails, it may return VK_ERROR_OUT_OF_HOST_MEMORY or VK_ERROR_OUT_OF_DEVICE_MEMORY. * If it does, the implementation must ensure that the state and contents of any resources or synchronization primitives referenced by the submitted command buffers and any semaphores * referenced by pSubmits is unaffected by the call or its failure. If vkQueueSubmit fails in such a way that the implementation is unable to make that guarantee, * the implementation must return VK_ERROR_DEVICE_LOST. See Lost Device. */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkQueueSubmit( VkQueue queue, uint32_t submitCount, const VkSubmitInfo* pSubmits, VkFence fence) { assert(queue); //TODO this is incorrect //see sync.c //TODO: deal with pSubmits->pWaitDstStageMask for(int c = 0; c < pSubmits->waitSemaphoreCount; ++c) { sem_wait((sem_t*)pSubmits->pWaitSemaphores[c]); } for(int c = 0; c < pSubmits->commandBufferCount; ++c) { if(pSubmits->pCommandBuffers[c]->state == CMDBUF_STATE_EXECUTABLE) { pSubmits->pCommandBuffers[c]->state = CMDBUF_STATE_PENDING; } } for(int c = 0; c < pSubmits->commandBufferCount; ++c) { VkCommandBuffer cmdbuf = pSubmits->pCommandBuffers[c]; if(!cmdbuf->binCl.currMarker) { //no markers recorded yet, skip continue; } //first entry is assumed to be a marker CLMarker* marker = cmdbuf->binCl.buffer; //a command buffer may contain multiple render passes //and commands outside render passes such as clear commands //each of these corresponds to a control list submit //submit each separate control list while(marker) { struct drm_vc4_submit_cl submitCl = { .color_read.hindex = ~0, .zs_read.hindex = ~0, .color_write.hindex = ~0, .msaa_color_write.hindex = ~0, .zs_write.hindex = ~0, .msaa_zs_write.hindex = ~0, }; _image* writeImage = marker->writeImage; _image* readImage = marker->readImage; _image* writeDepthStencilImage = marker->writeDepthStencilImage; _image* readDepthStencilImage = marker->readDepthStencilImage; _image* writeMSAAimage = marker->writeMSAAimage; _image* writeMSAAdepthStencilImage = marker->writeMSAAdepthStencilImage; uint32_t performResolve = marker->performResolve; uint32_t readMSAAimage = marker->readMSAAimage; uint32_t readMSAAdepthStencilImage = marker->readMSAAdepthStencilImage; //This should not result in an insertion! uint32_t writeImageIdx = writeImage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, writeImage->boundMem->bo) : 0; uint32_t readImageIdx = readImage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, readImage->boundMem->bo) : 0; uint32_t writeDepthStencilImageIdx = writeDepthStencilImage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, writeDepthStencilImage->boundMem->bo) : 0; uint32_t readDepthStencilImageIdx = readDepthStencilImage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, readDepthStencilImage->boundMem->bo) : 0; uint32_t writeMSAAimageIdx = writeMSAAimage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, writeMSAAimage->boundMem->bo) : 0; uint32_t writeMSAAdepthStencilImageIdx = writeMSAAdepthStencilImage ? clGetHandleIndex(&cmdbuf->handlesCl, marker->handlesBuf, marker->handlesSize, writeMSAAdepthStencilImage->boundMem->bo) : 0; // fprintf(stderr, "writeImage: %u\n", writeImage); // fprintf(stderr, "readImage: %u\n", readImage); // fprintf(stderr, "writeDepthStencilImage: %u\n", writeDepthStencilImage); // fprintf(stderr, "readDepthStencilImage: %u\n", readDepthStencilImage); // fprintf(stderr, "writeMSAAimage: %u\n", writeMSAAimage); // fprintf(stderr, "writeMSAAdepthStencilImage: %u\n", writeMSAAdepthStencilImage); // fprintf(stderr, "performResolve: %u\n", performResolve); // fprintf(stderr, "readMSAAimage: %u\n", readMSAAimage); // fprintf(stderr, "readMSAAdepthStencilImage: %u\n", readMSAAdepthStencilImage); // fprintf(stderr, "writeImageIdx: %u\n", writeImageIdx); // fprintf(stderr, "readImageIdx: %u\n", readImageIdx); // fprintf(stderr, "writeDepthStencilImageIdx: %u\n", writeDepthStencilImageIdx); // fprintf(stderr, "readDepthStencilImageIdx: %u\n", readDepthStencilImageIdx); // fprintf(stderr, "writeMSAAimageIdx: %u\n", writeMSAAimageIdx); // fprintf(stderr, "writeMSAAdepthStencilImageIdx: %u\n", writeMSAAdepthStencilImageIdx); submitCl.clear_color[0] = 0; submitCl.clear_color[1] = 0; submitCl.clear_z = 0; submitCl.clear_s = 0; //fill out submit cl fields if(writeImage) { submitCl.color_write.hindex = writeImageIdx; submitCl.color_write.offset = 0; submitCl.color_write.flags = 0; submitCl.color_write.bits = VC4_SET_FIELD(getRenderTargetFormatVC4(writeImage->format), VC4_RENDER_CONFIG_FORMAT) | VC4_SET_FIELD(writeImage->tiling, VC4_RENDER_CONFIG_MEMORY_FORMAT); if(performResolve) { submitCl.color_write.bits |= VC4_RENDER_CONFIG_MS_MODE_4X | VC4_RENDER_CONFIG_DECIMATE_MODE_4X; } } if(writeMSAAimage) { submitCl.msaa_color_write.hindex = writeMSAAimageIdx; submitCl.msaa_color_write.offset = 0; submitCl.msaa_color_write.flags = 0; submitCl.msaa_color_write.bits = VC4_RENDER_CONFIG_MS_MODE_4X; } if(readImage) { submitCl.color_read.hindex = readImageIdx; submitCl.color_read.offset = 0; submitCl.color_read.flags = readMSAAimage ? VC4_SUBMIT_RCL_SURFACE_READ_IS_FULL_RES : 0; submitCl.color_read.bits = VC4_SET_FIELD(getRenderTargetFormatVC4(readImage->format), VC4_RENDER_CONFIG_FORMAT) | VC4_SET_FIELD(readImage->tiling, VC4_RENDER_CONFIG_MEMORY_FORMAT); } if(writeDepthStencilImage) { submitCl.zs_write.hindex = writeDepthStencilImageIdx; submitCl.zs_write.offset = 0; submitCl.zs_write.flags = 0; submitCl.zs_write.bits = VC4_SET_FIELD(VC4_LOADSTORE_TILE_BUFFER_ZS, VC4_LOADSTORE_TILE_BUFFER_BUFFER) | VC4_SET_FIELD(writeDepthStencilImage->tiling, VC4_LOADSTORE_TILE_BUFFER_TILING); } if(writeMSAAdepthStencilImage) { submitCl.msaa_zs_write.hindex = writeMSAAdepthStencilImageIdx; submitCl.msaa_zs_write.offset = 0; submitCl.msaa_zs_write.flags = 0; submitCl.msaa_zs_write.bits = VC4_RENDER_CONFIG_MS_MODE_4X; } if(readDepthStencilImage) { submitCl.zs_read.hindex = readDepthStencilImageIdx; submitCl.zs_read.offset = 0; submitCl.zs_read.flags = readMSAAdepthStencilImage ? VC4_SUBMIT_RCL_SURFACE_READ_IS_FULL_RES : 0; //TODO is this valid? submitCl.zs_read.bits = VC4_SET_FIELD(getRenderTargetFormatVC4(readDepthStencilImage->format), VC4_RENDER_CONFIG_FORMAT) | VC4_SET_FIELD(readDepthStencilImage->tiling, VC4_RENDER_CONFIG_MEMORY_FORMAT); } submitCl.clear_color[0] = marker->clearColor[0]; submitCl.clear_color[1] = marker->clearColor[1]; submitCl.clear_z = marker->clearDepth; //0...1 -> 0...0xffffff submitCl.clear_s = marker->clearStencil; //0...0xff // fprintf(stderr, "submitCl.clear_color[0]: %u\n", submitCl.clear_color[0]); // fprintf(stderr, "submitCl.clear_color[1]: %u\n", submitCl.clear_color[1]); // fprintf(stderr, "submitCl.clear_z: %u\n", submitCl.clear_z); // fprintf(stderr, "submitCl.clear_s: %u\n", submitCl.clear_s); submitCl.min_x_tile = 0; submitCl.min_y_tile = 0; uint32_t tileSizeW = 64; uint32_t tileSizeH = 64; uint32_t widthInTiles = 0, heightInTiles = 0; uint32_t width = 0, height = 0, bpp = 0; if(writeImage) { width = writeImage->width; height = writeImage->height; bpp = getFormatBpp(writeImage->format); } else if(writeMSAAimage) { width = writeMSAAimage->width; height = writeMSAAimage->height; bpp = getFormatBpp(writeMSAAimage->format); } else if(writeDepthStencilImage) { width = writeDepthStencilImage->width; height = writeDepthStencilImage->height; } else if(writeMSAAdepthStencilImage) { width = writeMSAAdepthStencilImage->width; height = writeMSAAdepthStencilImage->height; } if(bpp == 64) { tileSizeH >>= 1; } if(performResolve || writeMSAAimage || writeMSAAdepthStencilImage) { tileSizeW >>= 1; tileSizeH >>= 1; } widthInTiles = divRoundUp(width, tileSizeW); heightInTiles = divRoundUp(height, tileSizeH); submitCl.max_x_tile = widthInTiles - 1; submitCl.max_y_tile = heightInTiles - 1; submitCl.width = width; submitCl.height = height; submitCl.flags |= marker->flags; submitCl.bo_handles = marker->handlesBuf; submitCl.bin_cl = ((uint8_t*)marker) + sizeof(CLMarker); submitCl.shader_rec = marker->shaderRecBuf; submitCl.uniforms = marker->uniformsBuf; if(marker->perfmonID) { uint32_t perfmonSelector = 0; uint32_t* perfmonIDptr = (uint32_t*)marker->perfmonID; if(pSubmits->pNext) { VkPerformanceQuerySubmitInfoKHR* perfQuerySubmitInfo = pSubmits->pNext; perfmonSelector = perfQuerySubmitInfo->counterPassIndex; } submitCl.perfmonid = *(perfmonIDptr + perfmonSelector); } //marker not closed yet //close here if(!marker->size) { clCloseCurrentMarker(&cmdbuf->binCl, &cmdbuf->handlesCl, &cmdbuf->shaderRecCl, cmdbuf->shaderRecCount, &cmdbuf->uniformsCl); } submitCl.bo_handle_count = marker->handlesSize / 4; submitCl.bin_cl_size = marker->size; submitCl.shader_rec_size = marker->shaderRecSize; submitCl.shader_rec_count = marker->shaderRecCount; submitCl.uniforms_size = marker->uniformsSize; /**/ printf("BCL:\n"); clDump(((uint8_t*)marker) + sizeof(CLMarker), marker->size); printf("BO handles: "); for(int d = 0; d < marker->handlesSize / 4; ++d) { printf("%u ", *((uint32_t*)(marker->handlesBuf)+d)); } printf("\nUniforms: "); for(int d = 0; d < marker->uniformsSize / 4; ++d) { printf("%u ", *((uint32_t*)(marker->uniformsBuf)+d)); } printf("\nShader recs: "); uint8_t* ptr = marker->shaderRecBuf + (3 + 1) * 4; for(int d = 0; d < marker->shaderRecCount; ++d) { uint8_t flags = *ptr; uint8_t fragmentShaderIsSingleThreaded = flags & (1 << 0); uint8_t pointSizeIncludedInShadedVertexData = (flags & (1 << 1)) >> 1; uint8_t enableClipping = (flags & (1 << 2)) >> 2; ptr += 2; uint8_t fragmentNumberOfUniforms = *ptr; ptr++; uint8_t fragmentNumberOfVaryings = *ptr; ptr++; uint32_t fragmentShaderCodeAddress = *(uint32_t*)ptr; ptr+=4; uint32_t fragmentShaderUniformAddress = *(uint32_t*)ptr; ptr+=4; uint16_t vertexNumberOfUniforms = *(uint16_t*)ptr; ptr+=2; uint8_t vertexAttribSelectBits = *ptr; ptr++; uint8_t vertexAttribTotalSize = *ptr; ptr++; uint32_t vertexShaderCodeAddress = *(uint32_t*)ptr; ptr+=4; uint32_t vertexShaderUniformAddress = *(uint32_t*)ptr; ptr+=4; uint16_t coordNumberOfUniforms = *(uint16_t*)ptr; ptr+=2; uint8_t coordAttribSelectBits = *ptr; ptr++; uint8_t coordAttribTotalSize = *ptr; ptr++; uint32_t coordShaderCodeAddress = *(uint32_t*)ptr; ptr+=4; uint32_t coordShaderUniformAddress = *(uint32_t*)ptr; ptr+=4; printf("\nfragmentShaderIsSingleThreaded: %i", fragmentShaderIsSingleThreaded); printf("\npointSizeIncludedInShadedVertexData: %i", pointSizeIncludedInShadedVertexData); printf("\nenableClipping: %i", enableClipping); printf("\nfragmentNumberOfUniforms: %i", fragmentNumberOfUniforms); printf("\nfragmentNumberOfVaryings: %i", fragmentNumberOfVaryings); printf("\nfragmentShaderCodeAddress: %i", fragmentShaderCodeAddress); printf("\nfragmentShaderUniformAddress: %i", fragmentShaderUniformAddress); printf("\nvertexNumberOfUniforms: %i", vertexNumberOfUniforms); printf("\nvertexAttribSelectBits: %i", vertexAttribSelectBits); printf("\nvertexAttribTotalSize: %i", vertexAttribTotalSize); printf("\nvertexShaderCodeAddress: %i", vertexShaderCodeAddress); printf("\nvertexShaderUniformAddress: %i", vertexShaderUniformAddress); printf("\ncoordNumberOfUniforms: %i", coordNumberOfUniforms); printf("\ncoordAttribSelectBits: %i", coordAttribSelectBits); printf("\ncoordAttribTotalSize: %i", coordAttribTotalSize); printf("\ncoordShaderCodeAddress: %i", coordShaderCodeAddress); printf("\ncoordShaderUniformAddress: %i", coordShaderUniformAddress); uint8_t numAttribs = 0; for(uint8_t e = 0; e < 8; ++e) { numAttribs += (vertexAttribSelectBits & (1 << e)) >> e; } for(uint8_t e = 0; e < numAttribs; ++e) { uint32_t attribBaseAddress = *(uint32_t*)ptr; ptr+=4; uint8_t attribNumBytes = *ptr; ptr++; uint8_t attribStride = *ptr; ptr++; uint8_t attribVsVPMOffset = *ptr; ptr++; uint8_t attribCsVPMOffset = *ptr; ptr++; printf("\nattrib \#%i", e); printf("\nattribBaseAddress: %i", attribBaseAddress); printf("\nattribNumBytes: %i", attribNumBytes); printf("\nattribStride: %i", attribStride); printf("\nattribVsVPMOffset: %i", attribVsVPMOffset); printf("\nattribCsVPMOffset: %i", attribCsVPMOffset); } } printf("\nwidth height: %u, %u\n", submitCl.width, submitCl.height); printf("tile min/max: %u,%u %u,%u\n", submitCl.min_x_tile, submitCl.min_y_tile, submitCl.max_x_tile, submitCl.max_y_tile); printf("color read surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.color_read.hindex, submitCl.color_read.offset, submitCl.color_read.bits, submitCl.color_read.flags); printf("color write surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.color_write.hindex, submitCl.color_write.offset, submitCl.color_write.bits, submitCl.color_write.flags); printf("zs read surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.zs_read.hindex, submitCl.zs_read.offset, submitCl.zs_read.bits, submitCl.zs_read.flags); printf("zs write surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.zs_write.hindex, submitCl.zs_write.offset, submitCl.zs_write.bits, submitCl.zs_write.flags); printf("msaa color write surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.msaa_color_write.hindex, submitCl.msaa_color_write.offset, submitCl.msaa_color_write.bits, submitCl.msaa_color_write.flags); printf("msaa zs write surf: hindex, offset, bits, flags %u %u %u %u\n", submitCl.msaa_zs_write.hindex, submitCl.msaa_zs_write.offset, submitCl.msaa_zs_write.bits, submitCl.msaa_zs_write.flags); printf("clear color packed rgba %u %u\n", submitCl.clear_color[0], submitCl.clear_color[1]); printf("clear z %u\n", submitCl.clear_z); printf("clear s %u\n", submitCl.clear_s); printf("flags %u\n", submitCl.flags); printf("perfmonID %u\n", submitCl.perfmonid); /**/ //TODO somehow store last finished globally //so waiting on fences is faster //eg. could be an atomic value static uint64_t lastFinishedSeqno = 0; //submit ioctl vc4_cl_submit(controlFd, &submitCl, &queue->lastEmitSeqno, &lastFinishedSeqno); //advance in linked list marker = marker->nextMarker; } } for(int c = 0; c < pSubmits->commandBufferCount; ++c) { if(pSubmits->pCommandBuffers[c]->state == CMDBUF_STATE_PENDING) { if(pSubmits->pCommandBuffers[c]->usageFlags & VK_COMMAND_BUFFER_USAGE_ONE_TIME_SUBMIT_BIT) { pSubmits->pCommandBuffers[c]->state = CMDBUF_STATE_INVALID; } else { pSubmits->pCommandBuffers[c]->state = CMDBUF_STATE_EXECUTABLE; } } } for(int c = 0; c < pSubmits->signalSemaphoreCount; ++c) { sem_post((sem_t*)pSubmits->pSignalSemaphores[c]); } _fence* f = fence; if(f) { f->seqno = queue->lastEmitSeqno; } return VK_SUCCESS; } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkFreeCommandBuffers * Any primary command buffer that is in the recording or executable state and has any element of pCommandBuffers recorded into it, becomes invalid. */ VKAPI_ATTR void VKAPI_CALL rpi_vkFreeCommandBuffers( VkDevice device, VkCommandPool commandPool, uint32_t commandBufferCount, const VkCommandBuffer* pCommandBuffers) { assert(device); assert(commandPool); assert(pCommandBuffers); _commandPool* cp = (_commandPool*)commandPool; for(int c = 0; c < commandBufferCount; ++c) { if(pCommandBuffers[c]) { consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->binCl, pCommandBuffers[c]->binCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->handlesCl, pCommandBuffers[c]->handlesCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->shaderRecCl, pCommandBuffers[c]->shaderRecCl.numBlocks); consecutivePoolFree(&cp->cpa, &pCommandBuffers[c]->uniformsCl, pCommandBuffers[c]->uniformsCl.numBlocks); poolFree(&cp->pa, pCommandBuffers[c]); } } } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkDestroyCommandPool * When a pool is destroyed, all command buffers allocated from the pool are freed. * Any primary command buffer allocated from another VkCommandPool that is in the recording or executable state and has a secondary command buffer * allocated from commandPool recorded into it, becomes invalid. */ VKAPI_ATTR void VKAPI_CALL rpi_vkDestroyCommandPool( VkDevice device, VkCommandPool commandPool, const VkAllocationCallbacks* pAllocator) { assert(device); _commandPool* cp = (_commandPool*)commandPool; if(cp) { FREE(cp->pa.buf); FREE(cp->cpa.buf); destroyPoolAllocator(&cp->pa); destroyConsecutivePoolAllocator(&cp->cpa); FREE(cp); } } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkTrimCommandPool */ VKAPI_ATTR void VKAPI_CALL rpi_vkTrimCommandPool( VkDevice device, VkCommandPool commandPool, VkCommandPoolTrimFlags flags) { assert(device); assert(commandPool); _commandPool* cp = commandPool; //TODO trim cp's pool allocator and consecutive pool allocator //by reallocating to just used size //kinda silly, as if you need memory afterwards we need to reallocate again... } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkResetCommandPool */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkResetCommandPool( VkDevice device, VkCommandPool commandPool, VkCommandPoolResetFlags flags) { assert(device); assert(commandPool); _commandPool* cp = commandPool; for(char* c = cp->pa.buf; c != cp->pa.buf + cp->pa.size; c += cp->pa.blockSize) { char* d = cp->pa.nextFreeBlock; while(d) { if(c == d) break; d = *(uint32_t*)d; } if(c == d) //block is free, as we found it in the free chain { continue; } else { //we found a valid block _commandBuffer* cb = c; assert(cb->state != CMDBUF_STATE_PENDING); cb->state = CMDBUF_STATE_INITIAL; } } //TODO secondary command buffers //TODO reset flag --> free all pool resources } /* * https://www.khronos.org/registry/vulkan/specs/1.1-extensions/html/vkspec.html#vkResetCommandBuffer */ VKAPI_ATTR VkResult VKAPI_CALL rpi_vkResetCommandBuffer( VkCommandBuffer commandBuffer, VkCommandBufferResetFlags flags) { assert(commandBuffer); _commandBuffer* cb = commandBuffer; assert(cb->state != CMDBUF_STATE_PENDING); assert(cb->cp->resetAble); if(cb->state == CMDBUF_STATE_RECORDING || cb->state == CMDBUF_STATE_EXECUTABLE) { cb->state = CMDBUF_STATE_INVALID; } else { cb->state = CMDBUF_STATE_INITIAL; } if(flags & VK_COMMAND_BUFFER_RESET_RELEASE_RESOURCES_BIT) { //TODO release resources } //TODO reset state? } VKAPI_ATTR void VKAPI_CALL rpi_vkCmdExecuteCommands( VkCommandBuffer commandBuffer, uint32_t commandBufferCount, const VkCommandBuffer* pCommandBuffers) { } VKAPI_ATTR void VKAPI_CALL rpi_vkCmdSetDeviceMask( VkCommandBuffer commandBuffer, uint32_t deviceMask) { UNSUPPORTED(rpi_vkCmdSetDeviceMask); }