first commit

third_party/trt_yolov8/trt_yolov8_pose_detector.cpp

@@ -0,0 +1,217 @@
+
+#include "trt_yolov8_pose_detector.h"
+
+namespace trt_yolov8 {
+    using namespace nvinfer1;
+    void trt_yolov8_pose_detector::serialize_engine(std::string& wts_name, std::string& engine_name, int& is_p, std::string& sub_type, float& gd,
+                        float& gw, int& max_channels) {
+        IBuilder* builder = createInferBuilder(gLogger);
+        IBuilderConfig* config = builder->createBuilderConfig();
+        IHostMemory* serialized_engine = nullptr;
+
+        if (is_p == 6) {
+            serialized_engine = buildEngineYolov8PoseP6(builder, config, DataType::kFLOAT, wts_name, gd, gw, max_channels);
+        } else if (is_p == 2) {
+            std::cout << "p2 is not supported right now" << std::endl;
+        } else {
+            serialized_engine = buildEngineYolov8Pose(builder, config, DataType::kFLOAT, wts_name, gd, gw, max_channels);
+        }
+
+        assert(serialized_engine);
+        std::ofstream p(engine_name, std::ios::binary);
+        if (!p) {
+            std::cout << "could not open plan output file" << std::endl;
+            assert(false);
+        }
+        p.write(reinterpret_cast<const char*>(serialized_engine->data()), serialized_engine->size());
+
+        delete serialized_engine;
+        delete config;
+        delete builder;
+    }
+
+    void trt_yolov8_pose_detector::deserialize_engine(std::string& engine_name, IRuntime** runtime, ICudaEngine** engine,
+                            IExecutionContext** context) {
+        std::ifstream file(engine_name, std::ios::binary);
+        if (!file.good()) {
+            std::cerr << "read " << engine_name << " error!" << std::endl;
+            assert(false);
+        }
+        size_t size = 0;
+        file.seekg(0, file.end);
+        size = file.tellg();
+        file.seekg(0, file.beg);
+        char* serialized_engine = new char[size];
+        assert(serialized_engine);
+        file.read(serialized_engine, size);
+        file.close();
+
+        *runtime = createInferRuntime(gLogger);
+        assert(*runtime);
+        *engine = (*runtime)->deserializeCudaEngine(serialized_engine, size);
+        assert(*engine);
+        *context = (*engine)->createExecutionContext();
+        assert(*context);
+        delete[] serialized_engine;
+    }
+
+    void trt_yolov8_pose_detector::prepare_buffer(ICudaEngine* engine, float** input_buffer_device, float** output_buffer_device,
+                        float** output_buffer_host, float** decode_ptr_host, float** decode_ptr_device,
+                        std::string cuda_post_process) {
+        assert(engine->getNbBindings() == 2);
+        // In order to bind the buffers, we need to know the names of the input and output tensors.
+        // Note that indices are guaranteed to be less than IEngine::getNbBindings()
+        const int inputIndex = engine->getBindingIndex(kInputTensorName);
+        const int outputIndex = engine->getBindingIndex(kOutputTensorName);
+        assert(inputIndex == 0);
+        assert(outputIndex == 1);
+        // Create GPU buffers on device
+        CUDA_CHECK(cudaMalloc((void**)input_buffer_device, kBatchSize * 3 * kInputH * kInputW * sizeof(float)));
+        CUDA_CHECK(cudaMalloc((void**)output_buffer_device, kBatchSize * kOutputSize * sizeof(float)));
+        if (cuda_post_process == "c") {
+            *output_buffer_host = new float[kBatchSize * kOutputSize];
+        } else if (cuda_post_process == "g") {
+            if (kBatchSize > 1) {
+                std::cerr << "Do not yet support GPU post processing for multiple batches" << std::endl;
+                exit(0);
+            }
+            // Allocate memory for decode_ptr_host and copy to device
+            *decode_ptr_host = new float[1 + kMaxNumOutputBbox * bbox_element];
+            CUDA_CHECK(cudaMalloc((void**)decode_ptr_device, sizeof(float) * (1 + kMaxNumOutputBbox * bbox_element)));
+        }
+    }
+
+    void trt_yolov8_pose_detector::infer(IExecutionContext& context, cudaStream_t& stream, void** buffers, float* output, int batchsize,
+            float* decode_ptr_host, float* decode_ptr_device, int model_bboxes, std::string cuda_post_process) {
+        // infer on the batch asynchronously, and DMA output back to host
+        auto start = std::chrono::system_clock::now();
+        context.enqueue(batchsize, buffers, stream, nullptr);
+        if (cuda_post_process == "c") {
+            CUDA_CHECK(cudaMemcpyAsync(output, buffers[1], batchsize * kOutputSize * sizeof(float), cudaMemcpyDeviceToHost,
+                                    stream));
+                                    /*
+            auto end = std::chrono::system_clock::now();
+            std::cout << "inference time: " << std::chrono::duration_cast<std::chrono::milliseconds>(end - start).count()
+                    << "ms" << std::endl;*/
+        } else if (cuda_post_process == "g") {
+            CUDA_CHECK(
+                    cudaMemsetAsync(decode_ptr_device, 0, sizeof(float) * (1 + kMaxNumOutputBbox * bbox_element), stream));
+            cuda_decode((float*)buffers[1], model_bboxes, kConfThresh, decode_ptr_device, kMaxNumOutputBbox, stream);
+            cuda_nms(decode_ptr_device, kNmsThresh, kMaxNumOutputBbox, stream);  //cuda nms
+            CUDA_CHECK(cudaMemcpyAsync(decode_ptr_host, decode_ptr_device,
+                                    sizeof(float) * (1 + kMaxNumOutputBbox * bbox_element), cudaMemcpyDeviceToHost,
+                                    stream));
+                                    /*
+            auto end = std::chrono::system_clock::now();
+            std::cout << "inference and gpu postprocess time: "
+                    << std::chrono::duration_cast<std::chrono::milliseconds>(end - start).count() << "ms" << std::endl;*/
+        }
+
+        CUDA_CHECK(cudaStreamSynchronize(stream));
+    }
+
+    trt_yolov8_pose_detector::trt_yolov8_pose_detector(std::string model_path) {
+        if (model_path.empty()) {
+            return;
+        }
+
+        cudaSetDevice(kGpuId);
+        // Deserialize the engine from file
+        deserialize_engine(model_path, &runtime, &engine, &context);
+        CUDA_CHECK(cudaStreamCreate(&stream));
+        cuda_preprocess_init(kMaxInputImageSize);
+        auto out_dims = engine->getBindingDimensions(1);
+        model_bboxes = out_dims.d[0];
+    }
+    
+    trt_yolov8_pose_detector::~trt_yolov8_pose_detector() {
+        // Release stream and buffers
+        cudaStreamDestroy(stream);
+        cuda_preprocess_destroy();
+        // Destroy the engine
+        delete context;
+        delete engine;
+        delete runtime;
+    }
+
+    void trt_yolov8_pose_detector::detect(std::vector<cv::Mat> images, std::vector<std::vector<Detection>>& detections) {      
+        // Prepare cpu and gpu buffers        
+        float* device_buffers[2];
+        float* output_buffer_host = nullptr;
+        float* decode_ptr_host = nullptr;
+        float* decode_ptr_device = nullptr;
+
+        prepare_buffer(engine, &device_buffers[0], &device_buffers[1], &output_buffer_host, &decode_ptr_host,
+                    &decode_ptr_device, cuda_post_process);
+        // batch predict
+        for (size_t i = 0; i < images.size(); i += kBatchSize) {
+            // Get a batch of images
+            std::vector<cv::Mat> img_batch;
+            for (size_t j = i; j < i + kBatchSize && j < images.size(); j++) {
+                img_batch.push_back(images[j]);
+            }
+            // Preprocess
+            cuda_batch_preprocess(img_batch, device_buffers[0], kInputW, kInputH, stream);
+            // Run inference
+            infer(*context, stream, (void**)device_buffers, output_buffer_host, kBatchSize, decode_ptr_host,
+                decode_ptr_device, model_bboxes, cuda_post_process);
+            std::vector<std::vector<Detection>> res_batch;
+            if (cuda_post_process == "c") {
+                // NMS
+                batch_nms(res_batch, output_buffer_host, img_batch.size(), kOutputSize, kConfThresh, kNmsThresh);
+            } else if (cuda_post_process == "g") {
+                // Process gpu decode and nms results
+                // todo pose in gpu
+                std::cerr << "pose_postprocess is not support in gpu right now" << std::endl;
+            }
+
+            // push back to return
+            detections.insert(detections.end(), res_batch.begin(), res_batch.end());
+        }
+
+        CUDA_CHECK(cudaFree(device_buffers[0]));
+        CUDA_CHECK(cudaFree(device_buffers[1]));
+        CUDA_CHECK(cudaFree(decode_ptr_device));
+        delete[] decode_ptr_host;
+        delete[] output_buffer_host;
+    }
+
+    bool trt_yolov8_pose_detector::wts_2_engine(std::string wts_name, std::string engine_name, std::string sub_type) {
+        int is_p = 0;
+        float gd = 0.0f, gw = 0.0f;
+        int max_channels = 0;
+
+        if (sub_type[0] == 'n') {          // yolov8n
+            gd = 0.33;
+            gw = 0.25;
+            max_channels = 1024;
+        } else if (sub_type[0] == 's') {   // yolov8s
+            gd = 0.33;
+            gw = 0.50;
+            max_channels = 1024;
+        } else if (sub_type[0] == 'm') {   // yolov8m
+            gd = 0.67;
+            gw = 0.75;
+            max_channels = 576;
+        } else if (sub_type[0] == 'l') {   // yolov8l
+            gd = 1.0;
+            gw = 1.0;
+            max_channels = 512;
+        } else if (sub_type[0] == 'x') {   // yolov8x
+            gd = 1.0;
+            gw = 1.25;
+            max_channels = 640;
+        } else {
+            return false;  // not support
+        }
+        
+        if (sub_type.size() == 2 && sub_type[1] == '6') {         // yolov8n6/yolov8s6/yolov8m6/yolov8l6/yolov8x6
+            is_p = 6;
+        } else if (sub_type.size() == 2 && sub_type[1] == '2') {  // yolov8n2/yolov8s2/yolov8m2/yolov8l2/yolov8x2
+            is_p = 2;
+        }
+
+        serialize_engine(wts_name, engine_name, is_p, sub_type, gd, gw, max_channels);
+        return true;        
+    }
+}