/* Copyright (c) 2019 - 2022 Advanced Micro Devices, Inc. All rights reserved. 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 "internal_publishKernels.h" struct JitterbatchPDLocalData { RPPCommonHandle handle; rppHandle_t rppHandle; Rpp32u device_type; Rpp32u nbatchSize; RppiSize *srcDimensions; RppiSize maxSrcDimensions; Rpp32u *srcBatch_width; Rpp32u *srcBatch_height; RppPtr_t pSrc; RppPtr_t pDst; vx_uint32 *kernelSize; #if ENABLE_OPENCL cl_mem cl_pSrc; cl_mem cl_pDst; #elif ENABLE_HIP void *hip_pSrc; void *hip_pDst; #endif }; static vx_status VX_CALLBACK refreshJitterbatchPD(vx_node node, const vx_reference *parameters, vx_uint32 num, JitterbatchPDLocalData *data) { vx_status status = VX_SUCCESS; vx_status copy_status; STATUS_ERROR_CHECK(vxCopyArrayRange((vx_array)parameters[4], 0, data->nbatchSize, sizeof(vx_uint32), data->kernelSize, VX_READ_ONLY, VX_MEMORY_TYPE_HOST)); STATUS_ERROR_CHECK(vxReadScalarValue((vx_scalar)parameters[5], &data->nbatchSize)); STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_HEIGHT, &data->maxSrcDimensions.height, sizeof(data->maxSrcDimensions.height))); STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_WIDTH, &data->maxSrcDimensions.width, sizeof(data->maxSrcDimensions.width))); data->maxSrcDimensions.height = data->maxSrcDimensions.height / data->nbatchSize; STATUS_ERROR_CHECK(vxCopyArrayRange((vx_array)parameters[1], 0, data->nbatchSize, sizeof(Rpp32u), data->srcBatch_width, VX_READ_ONLY, VX_MEMORY_TYPE_HOST)); STATUS_ERROR_CHECK(vxCopyArrayRange((vx_array)parameters[2], 0, data->nbatchSize, sizeof(Rpp32u), data->srcBatch_height, VX_READ_ONLY, VX_MEMORY_TYPE_HOST)); for (int i = 0; i < data->nbatchSize; i++) { data->srcDimensions[i].width = data->srcBatch_width[i]; data->srcDimensions[i].height = data->srcBatch_height[i]; } if (data->device_type == AGO_TARGET_AFFINITY_GPU) { #if ENABLE_OPENCL STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_ATTRIBUTE_AMD_OPENCL_BUFFER, &data->cl_pSrc, sizeof(data->cl_pSrc))); STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[3], VX_IMAGE_ATTRIBUTE_AMD_OPENCL_BUFFER, &data->cl_pDst, sizeof(data->cl_pDst))); #elif ENABLE_HIP STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_ATTRIBUTE_AMD_HIP_BUFFER, &data->hip_pSrc, sizeof(data->hip_pSrc))); STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[3], VX_IMAGE_ATTRIBUTE_AMD_HIP_BUFFER, &data->hip_pDst, sizeof(data->hip_pDst))); #endif } if (data->device_type == AGO_TARGET_AFFINITY_CPU) { STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_ATTRIBUTE_AMD_HOST_BUFFER, &data->pSrc, sizeof(vx_uint8))); STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[3], VX_IMAGE_ATTRIBUTE_AMD_HOST_BUFFER, &data->pDst, sizeof(vx_uint8))); } return status; } static vx_status VX_CALLBACK validateJitterbatchPD(vx_node node, const vx_reference parameters[], vx_uint32 num, vx_meta_format metas[]) { vx_status status = VX_SUCCESS; vx_enum scalar_type; STATUS_ERROR_CHECK(vxQueryScalar((vx_scalar)parameters[5], VX_SCALAR_TYPE, &scalar_type, sizeof(scalar_type))); if (scalar_type != VX_TYPE_UINT32) return ERRMSG(VX_ERROR_INVALID_TYPE, "validate: Paramter: #5 type=%d (must be size)\n", scalar_type); STATUS_ERROR_CHECK(vxQueryScalar((vx_scalar)parameters[6], VX_SCALAR_TYPE, &scalar_type, sizeof(scalar_type))); if (scalar_type != VX_TYPE_UINT32) return ERRMSG(VX_ERROR_INVALID_TYPE, "validate: Paramter: #6 type=%d (must be size)\n", scalar_type); // Check for input parameters vx_parameter input_param; vx_image input; vx_df_image df_image; input_param = vxGetParameterByIndex(node, 0); STATUS_ERROR_CHECK(vxQueryParameter(input_param, VX_PARAMETER_ATTRIBUTE_REF, &input, sizeof(vx_image))); STATUS_ERROR_CHECK(vxQueryImage(input, VX_IMAGE_ATTRIBUTE_FORMAT, &df_image, sizeof(df_image))); if (df_image != VX_DF_IMAGE_U8 && df_image != VX_DF_IMAGE_RGB) { return ERRMSG(VX_ERROR_INVALID_FORMAT, "validate: JitterbatchPD: image: #0 format=%4.4s (must be RGB2 or U008)\n", (char *)&df_image); } // Check for output parameters vx_image output; vx_df_image format; vx_parameter output_param; vx_uint32 height, width; output_param = vxGetParameterByIndex(node, 3); STATUS_ERROR_CHECK(vxQueryParameter(output_param, VX_PARAMETER_ATTRIBUTE_REF, &output, sizeof(vx_image))); STATUS_ERROR_CHECK(vxQueryImage(output, VX_IMAGE_ATTRIBUTE_WIDTH, &width, sizeof(width))); STATUS_ERROR_CHECK(vxQueryImage(output, VX_IMAGE_ATTRIBUTE_HEIGHT, &height, sizeof(height))); STATUS_ERROR_CHECK(vxSetMetaFormatAttribute(metas[3], VX_IMAGE_ATTRIBUTE_WIDTH, &width, sizeof(width))); STATUS_ERROR_CHECK(vxSetMetaFormatAttribute(metas[3], VX_IMAGE_ATTRIBUTE_HEIGHT, &height, sizeof(height))); STATUS_ERROR_CHECK(vxSetMetaFormatAttribute(metas[3], VX_IMAGE_ATTRIBUTE_FORMAT, &df_image, sizeof(df_image))); vxReleaseImage(&input); vxReleaseImage(&output); vxReleaseParameter(&output_param); vxReleaseParameter(&input_param); return status; } static vx_status VX_CALLBACK processJitterbatchPD(vx_node node, const vx_reference *parameters, vx_uint32 num) { RppStatus rpp_status = RPP_SUCCESS; vx_status return_status = VX_SUCCESS; JitterbatchPDLocalData *data = NULL; STATUS_ERROR_CHECK(vxQueryNode(node, VX_NODE_LOCAL_DATA_PTR, &data, sizeof(data))); vx_df_image df_image = VX_DF_IMAGE_VIRT; STATUS_ERROR_CHECK(vxQueryImage((vx_image)parameters[0], VX_IMAGE_ATTRIBUTE_FORMAT, &df_image, sizeof(df_image))); if (data->device_type == AGO_TARGET_AFFINITY_GPU) { #if ENABLE_OPENCL refreshJitterbatchPD(node, parameters, num, data); if (df_image == VX_DF_IMAGE_U8) { rpp_status = rppi_jitter_u8_pln1_batchPD_gpu((void *)data->cl_pSrc, data->srcDimensions, data->maxSrcDimensions, (void *)data->cl_pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } else if (df_image == VX_DF_IMAGE_RGB) { rpp_status = rppi_jitter_u8_pkd3_batchPD_gpu((void *)data->cl_pSrc, data->srcDimensions, data->maxSrcDimensions, (void *)data->cl_pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } return_status = (rpp_status == RPP_SUCCESS) ? VX_SUCCESS : VX_FAILURE; #elif ENABLE_HIP refreshJitterbatchPD(node, parameters, num, data); if (df_image == VX_DF_IMAGE_U8) { rpp_status = rppi_jitter_u8_pln1_batchPD_gpu((void *)data->hip_pSrc, data->srcDimensions, data->maxSrcDimensions, (void *)data->hip_pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } else if (df_image == VX_DF_IMAGE_RGB) { rpp_status = rppi_jitter_u8_pkd3_batchPD_gpu((void *)data->hip_pSrc, data->srcDimensions, data->maxSrcDimensions, (void *)data->hip_pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } return_status = (rpp_status == RPP_SUCCESS) ? VX_SUCCESS : VX_FAILURE; #endif } if (data->device_type == AGO_TARGET_AFFINITY_CPU) { refreshJitterbatchPD(node, parameters, num, data); if (df_image == VX_DF_IMAGE_U8) { rpp_status = rppi_jitter_u8_pln1_batchPD_host(data->pSrc, data->srcDimensions, data->maxSrcDimensions, data->pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } else if (df_image == VX_DF_IMAGE_RGB) { rpp_status = rppi_jitter_u8_pkd3_batchPD_host(data->pSrc, data->srcDimensions, data->maxSrcDimensions, data->pDst, data->kernelSize, data->nbatchSize, data->rppHandle); } return_status = (rpp_status == RPP_SUCCESS) ? VX_SUCCESS : VX_FAILURE; } return return_status; } static vx_status VX_CALLBACK initializeJitterbatchPD(vx_node node, const vx_reference *parameters, vx_uint32 num) { JitterbatchPDLocalData *data = new JitterbatchPDLocalData; memset(data, 0, sizeof(*data)); #if ENABLE_OPENCL STATUS_ERROR_CHECK(vxQueryNode(node, VX_NODE_ATTRIBUTE_AMD_OPENCL_COMMAND_QUEUE, &data->handle.cmdq, sizeof(data->handle.cmdq))); #elif ENABLE_HIP STATUS_ERROR_CHECK(vxQueryNode(node, VX_NODE_ATTRIBUTE_AMD_HIP_STREAM, &data->handle.hipstream, sizeof(data->handle.hipstream))); #endif STATUS_ERROR_CHECK(vxCopyScalar((vx_scalar)parameters[6], &data->device_type, VX_READ_ONLY, VX_MEMORY_TYPE_HOST)); STATUS_ERROR_CHECK(vxReadScalarValue((vx_scalar)parameters[5], &data->nbatchSize)); data->kernelSize = (vx_uint32 *)malloc(sizeof(vx_uint32) * data->nbatchSize); data->srcDimensions = (RppiSize *)malloc(sizeof(RppiSize) * data->nbatchSize); data->srcBatch_width = (Rpp32u *)malloc(sizeof(Rpp32u) * data->nbatchSize); data->srcBatch_height = (Rpp32u *)malloc(sizeof(Rpp32u) * data->nbatchSize); refreshJitterbatchPD(node, parameters, num, data); #if ENABLE_OPENCL if (data->device_type == AGO_TARGET_AFFINITY_GPU) rppCreateWithStreamAndBatchSize(&data->rppHandle, data->handle.cmdq, data->nbatchSize); #elif ENABLE_HIP if (data->device_type == AGO_TARGET_AFFINITY_GPU) rppCreateWithStreamAndBatchSize(&data->rppHandle, data->handle.hipstream, data->nbatchSize); #endif if (data->device_type == AGO_TARGET_AFFINITY_CPU) rppCreateWithBatchSize(&data->rppHandle, data->nbatchSize); STATUS_ERROR_CHECK(vxSetNodeAttribute(node, VX_NODE_LOCAL_DATA_PTR, &data, sizeof(data))); return VX_SUCCESS; } static vx_status VX_CALLBACK uninitializeJitterbatchPD(vx_node node, const vx_reference *parameters, vx_uint32 num) { JitterbatchPDLocalData *data; STATUS_ERROR_CHECK(vxQueryNode(node, VX_NODE_LOCAL_DATA_PTR, &data, sizeof(data))); #if ENABLE_OPENCL || ENABLE_HIP if (data->device_type == AGO_TARGET_AFFINITY_GPU) rppDestroyGPU(data->rppHandle); #endif if (data->device_type == AGO_TARGET_AFFINITY_CPU) rppDestroyHost(data->rppHandle); free(data->srcDimensions); free(data->srcBatch_width); free(data->srcBatch_height); free(data->kernelSize); delete (data); return VX_SUCCESS; } //! \brief The kernel target support callback. // TODO::currently the node is setting the same affinity as context. This needs to change when we have hubrid modes in the same graph static vx_status VX_CALLBACK query_target_support(vx_graph graph, vx_node node, vx_bool use_opencl_1_2, // [input] false: OpenCL driver is 2.0+; true: OpenCL driver is 1.2 vx_uint32 &supported_target_affinity // [output] must be set to AGO_TARGET_AFFINITY_CPU or AGO_TARGET_AFFINITY_GPU or (AGO_TARGET_AFFINITY_CPU | AGO_TARGET_AFFINITY_GPU) ) { vx_context context = vxGetContext((vx_reference)graph); AgoTargetAffinityInfo affinity; vxQueryContext(context, VX_CONTEXT_ATTRIBUTE_AMD_AFFINITY, &affinity, sizeof(affinity)); if (affinity.device_type == AGO_TARGET_AFFINITY_GPU) supported_target_affinity = AGO_TARGET_AFFINITY_GPU; else supported_target_affinity = AGO_TARGET_AFFINITY_CPU; // hardcode the affinity to CPU for OpenCL backend to avoid VerifyGraph failure since there is no codegen callback for amd_rpp nodes #if ENABLE_OPENCL supported_target_affinity = AGO_TARGET_AFFINITY_CPU; #endif return VX_SUCCESS; } vx_status JitterbatchPD_Register(vx_context context) { vx_status status = VX_SUCCESS; // Add kernel to the context with callbacks vx_kernel kernel = vxAddUserKernel(context, "org.rpp.JitterbatchPD", VX_KERNEL_RPP_JITTERBATCHPD, processJitterbatchPD, 7, validateJitterbatchPD, initializeJitterbatchPD, uninitializeJitterbatchPD); ERROR_CHECK_OBJECT(kernel); AgoTargetAffinityInfo affinity; vxQueryContext(context, VX_CONTEXT_ATTRIBUTE_AMD_AFFINITY, &affinity, sizeof(affinity)); #if ENABLE_OPENCL || ENABLE_HIP // enable OpenCL buffer access since the kernel_f callback uses OpenCL buffers instead of host accessible buffers vx_bool enableBufferAccess = vx_true_e; if (affinity.device_type == AGO_TARGET_AFFINITY_GPU) STATUS_ERROR_CHECK(vxSetKernelAttribute(kernel, VX_KERNEL_ATTRIBUTE_AMD_GPU_BUFFER_ACCESS_ENABLE, &enableBufferAccess, sizeof(enableBufferAccess))); #else vx_bool enableBufferAccess = vx_false_e; #endif amd_kernel_query_target_support_f query_target_support_f = query_target_support; if (kernel) { STATUS_ERROR_CHECK(vxSetKernelAttribute(kernel, VX_KERNEL_ATTRIBUTE_AMD_QUERY_TARGET_SUPPORT, &query_target_support_f, sizeof(query_target_support_f))); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 0, VX_INPUT, VX_TYPE_IMAGE, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 1, VX_INPUT, VX_TYPE_ARRAY, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 2, VX_INPUT, VX_TYPE_ARRAY, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 3, VX_OUTPUT, VX_TYPE_IMAGE, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 4, VX_INPUT, VX_TYPE_ARRAY, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 5, VX_INPUT, VX_TYPE_SCALAR, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxAddParameterToKernel(kernel, 6, VX_INPUT, VX_TYPE_SCALAR, VX_PARAMETER_STATE_REQUIRED)); PARAM_ERROR_CHECK(vxFinalizeKernel(kernel)); } if (status != VX_SUCCESS) { exit: vxRemoveKernel(kernel); return VX_FAILURE; } return status; }