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alex.cpp
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alex.cpp
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#include "NvInfer.h"
#include "cuda_runtime_api.h"
#include "logging.h"
#include <fstream>
#include <map>
#include <chrono>
#define CHECK(status) \
do\
{\
auto ret = (status);\
if (ret != 0)\
{\
std::cerr << "Cuda failure: " << ret << std::endl;\
abort();\
}\
} while (0)
// stuff we know about the network and the input/output blobs
static const int INPUT_H = 224;
static const int INPUT_W = 224;
static const int OUTPUT_SIZE = 1000;
const char* INPUT_BLOB_NAME = "data";
const char* OUTPUT_BLOB_NAME = "prob";
using namespace nvinfer1;
static Logger gLogger;
// Load weights from files shared with TensorRT samples.
// TensorRT weight files have a simple space delimited format:
// [type] [size] <data x size in hex>
std::map<std::string, Weights> loadWeights(const std::string file)
{
std::cout << "Loading weights: " << file << std::endl;
std::map<std::string, Weights> weightMap;
// Open weights file
std::ifstream input(file);
assert(input.is_open() && "Unable to load weight file.");
// Read number of weight blobs
int32_t count;
input >> count;
assert(count > 0 && "Invalid weight map file.");
while (count--)
{
Weights wt{DataType::kFLOAT, nullptr, 0};
uint32_t size;
// Read name and type of blob
std::string name;
input >> name >> std::dec >> size;
wt.type = DataType::kFLOAT;
// Load blob
uint32_t* val = reinterpret_cast<uint32_t*>(malloc(sizeof(val) * size));
for (uint32_t x = 0, y = size; x < y; ++x)
{
input >> std::hex >> val[x];
}
wt.values = val;
wt.count = size;
weightMap[name] = wt;
}
return weightMap;
}
// Creat the engine using only the API and not any parser.
ICudaEngine* createEngine(unsigned int maxBatchSize, IBuilder* builder, IBuilderConfig* config, DataType dt)
{
INetworkDefinition* network = builder->createNetworkV2(0U);
// Create input tensor of shape { 1, 1, 32, 32 } with name INPUT_BLOB_NAME
ITensor* data = network->addInput(INPUT_BLOB_NAME, dt, Dims3{3, INPUT_H, INPUT_W});
assert(data);
std::map<std::string, Weights> weightMap = loadWeights("../alexnet.wts");
Weights emptywts{DataType::kFLOAT, nullptr, 0};
IConvolutionLayer* conv1 = network->addConvolutionNd(*data, 64, DimsHW{11, 11}, weightMap["features.0.weight"], weightMap["features.0.bias"]);
assert(conv1);
conv1->setStrideNd(DimsHW{4, 4});
conv1->setPaddingNd(DimsHW{2, 2});
// Add activation layer using the ReLU algorithm.
IActivationLayer* relu1 = network->addActivation(*conv1->getOutput(0), ActivationType::kRELU);
assert(relu1);
// Add max pooling layer with stride of 2x2 and kernel size of 2x2.
IPoolingLayer* pool1 = network->addPoolingNd(*relu1->getOutput(0), PoolingType::kMAX, DimsHW{3, 3});
assert(pool1);
pool1->setStrideNd(DimsHW{2, 2});
IConvolutionLayer* conv2 = network->addConvolutionNd(*pool1->getOutput(0), 192, DimsHW{5, 5}, weightMap["features.3.weight"], weightMap["features.3.bias"]);
assert(conv2);
conv2->setPaddingNd(DimsHW{2, 2});
IActivationLayer* relu2 = network->addActivation(*conv2->getOutput(0), ActivationType::kRELU);
assert(relu2);
IPoolingLayer* pool2 = network->addPoolingNd(*relu2->getOutput(0), PoolingType::kMAX, DimsHW{3, 3});
assert(pool2);
pool2->setStrideNd(DimsHW{2, 2});
IConvolutionLayer* conv3 = network->addConvolutionNd(*pool2->getOutput(0), 384, DimsHW{3, 3}, weightMap["features.6.weight"], weightMap["features.6.bias"]);
assert(conv3);
conv3->setPaddingNd(DimsHW{1, 1});
IActivationLayer* relu3 = network->addActivation(*conv3->getOutput(0), ActivationType::kRELU);
assert(relu3);
IConvolutionLayer* conv4 = network->addConvolutionNd(*relu3->getOutput(0), 256, DimsHW{3, 3}, weightMap["features.8.weight"], weightMap["features.8.bias"]);
assert(conv4);
conv4->setPaddingNd(DimsHW{1, 1});
IActivationLayer* relu4 = network->addActivation(*conv4->getOutput(0), ActivationType::kRELU);
assert(relu4);
IConvolutionLayer* conv5 = network->addConvolutionNd(*relu4->getOutput(0), 256, DimsHW{3, 3}, weightMap["features.10.weight"], weightMap["features.10.bias"]);
assert(conv5);
conv5->setPaddingNd(DimsHW{1, 1});
IActivationLayer* relu5 = network->addActivation(*conv5->getOutput(0), ActivationType::kRELU);
assert(relu5);
IPoolingLayer* pool3 = network->addPoolingNd(*relu5->getOutput(0), PoolingType::kMAX, DimsHW{3, 3});
assert(pool3);
pool3->setStrideNd(DimsHW{2, 2});
IFullyConnectedLayer* fc1 = network->addFullyConnected(*pool3->getOutput(0), 4096, weightMap["classifier.1.weight"], weightMap["classifier.1.bias"]);
assert(fc1);
IActivationLayer* relu6 = network->addActivation(*fc1->getOutput(0), ActivationType::kRELU);
assert(relu6);
IFullyConnectedLayer* fc2 = network->addFullyConnected(*relu6->getOutput(0), 4096, weightMap["classifier.4.weight"], weightMap["classifier.4.bias"]);
assert(fc2);
IActivationLayer* relu7 = network->addActivation(*fc2->getOutput(0), ActivationType::kRELU);
assert(relu7);
IFullyConnectedLayer* fc3 = network->addFullyConnected(*relu7->getOutput(0), 1000, weightMap["classifier.6.weight"], weightMap["classifier.6.bias"]);
assert(fc3);
fc3->getOutput(0)->setName(OUTPUT_BLOB_NAME);
std::cout << "set name out" << std::endl;
network->markOutput(*fc3->getOutput(0));
// Build engine
builder->setMaxBatchSize(maxBatchSize);
config->setMaxWorkspaceSize(1 << 20);
ICudaEngine* engine = builder->buildEngineWithConfig(*network, *config);
std::cout << "build out" << std::endl;
// Don't need the network any more
network->destroy();
// Release host memory
for (auto& mem : weightMap)
{
free((void*) (mem.second.values));
}
return engine;
}
void APIToModel(unsigned int maxBatchSize, IHostMemory** modelStream)
{
// Create builder
IBuilder* builder = createInferBuilder(gLogger);
IBuilderConfig* config = builder->createBuilderConfig();
// Create model to populate the network, then set the outputs and create an engine
ICudaEngine* engine = createEngine(maxBatchSize, builder, config, DataType::kFLOAT);
assert(engine != nullptr);
// Serialize the engine
(*modelStream) = engine->serialize();
// Close everything down
engine->destroy();
builder->destroy();
}
void doInference(IExecutionContext& context, float* input, float* output, int batchSize)
{
const ICudaEngine& engine = context.getEngine();
// Pointers to input and output device buffers to pass to engine.
// Engine requires exactly IEngine::getNbBindings() number of buffers.
assert(engine.getNbBindings() == 2);
void* buffers[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(INPUT_BLOB_NAME);
const int outputIndex = engine.getBindingIndex(OUTPUT_BLOB_NAME);
// Create GPU buffers on device
CHECK(cudaMalloc(&buffers[inputIndex], batchSize * 3 * INPUT_H * INPUT_W * sizeof(float)));
CHECK(cudaMalloc(&buffers[outputIndex], batchSize * OUTPUT_SIZE * sizeof(float)));
// Create stream
cudaStream_t stream;
CHECK(cudaStreamCreate(&stream));
// DMA input batch data to device, infer on the batch asynchronously, and DMA output back to host
CHECK(cudaMemcpyAsync(buffers[inputIndex], input, batchSize * 3 * INPUT_H * INPUT_W * sizeof(float), cudaMemcpyHostToDevice, stream));
context.enqueue(batchSize, buffers, stream, nullptr);
CHECK(cudaMemcpyAsync(output, buffers[outputIndex], batchSize * OUTPUT_SIZE * sizeof(float), cudaMemcpyDeviceToHost, stream));
cudaStreamSynchronize(stream);
// Release stream and buffers
cudaStreamDestroy(stream);
CHECK(cudaFree(buffers[inputIndex]));
CHECK(cudaFree(buffers[outputIndex]));
}
int main(int argc, char** argv)
{
if (argc != 2) {
std::cerr << "arguments not right!" << std::endl;
std::cerr << "./alexnet -s // serialize model to plan file" << std::endl;
std::cerr << "./alexnet -d // deserialize plan file and run inference" << std::endl;
return -1;
}
// create a model using the API directly and serialize it to a stream
char *trtModelStream{nullptr};
size_t size{0};
if (std::string(argv[1]) == "-s") {
IHostMemory* modelStream{nullptr};
APIToModel(1, &modelStream);
assert(modelStream != nullptr);
std::ofstream p("alexnet.engine", std::ios::binary);
if (!p)
{
std::cerr << "could not open plan output file" << std::endl;
return -1;
}
p.write(reinterpret_cast<const char*>(modelStream->data()), modelStream->size());
modelStream->destroy();
return 1;
} else if (std::string(argv[1]) == "-d") {
std::ifstream file("alexnet.engine", std::ios::binary);
if (file.good()) {
file.seekg(0, file.end);
size = file.tellg();
file.seekg(0, file.beg);
trtModelStream = new char[size];
assert(trtModelStream);
file.read(trtModelStream, size);
file.close();
}
} else {
return -1;
}
// Subtract mean from image
float data[3 * INPUT_H * INPUT_W];
for (int i = 0; i < 3 * INPUT_H * INPUT_W; i++)
data[i] = 1;
IRuntime* runtime = createInferRuntime(gLogger);
assert(runtime != nullptr);
ICudaEngine* engine = runtime->deserializeCudaEngine(trtModelStream, size, nullptr);
assert(engine != nullptr);
IExecutionContext* context = engine->createExecutionContext();
assert(context != nullptr);
// Run inference
float prob[OUTPUT_SIZE];
for (int i = 0; i < 100; i++) {
auto start = std::chrono::system_clock::now();
doInference(*context, data, prob, 1);
auto end = std::chrono::system_clock::now();
std::cout << std::chrono::duration_cast<std::chrono::milliseconds>(end - start).count() << "ms" << std::endl;
}
// Destroy the engine
context->destroy();
engine->destroy();
runtime->destroy();
// Print histogram of the output distribution
std::cout << "\nOutput:\n\n";
for (unsigned int i = 0; i < OUTPUT_SIZE; i++)
{
std::cout << prob[i] << ", ";
if (i % 10 == 0) std::cout << i / 10 << std::endl;
}
std::cout << std::endl;
return 0;
}