mirror of
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1107 lines
41 KiB
C++
1107 lines
41 KiB
C++
// This file is part of OpenCV project.
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// It is subject to the license terms in the LICENSE file found in the top-level directory
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// of this distribution and at http://opencv.org/license.html.
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//
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// Copyright (C) 2020 Intel Corporation
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#include "../test_precomp.hpp"
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#ifdef HAVE_ONNX
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#include <stdexcept>
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#include <codecvt> // wstring_convert
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#include <onnxruntime_cxx_api.h>
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#include <ade/util/iota_range.hpp>
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#include <ade/util/algorithm.hpp>
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#include <opencv2/gapi/own/convert.hpp>
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#include <opencv2/gapi/infer/onnx.hpp>
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namespace {
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class TestMediaBGR final: public cv::MediaFrame::IAdapter {
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cv::Mat m_mat;
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using Cb = cv::MediaFrame::View::Callback;
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Cb m_cb;
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public:
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explicit TestMediaBGR(cv::Mat m, Cb cb = [](){})
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: m_mat(m), m_cb(cb) {
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}
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cv::GFrameDesc meta() const override {
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return cv::GFrameDesc{cv::MediaFormat::BGR, cv::Size(m_mat.cols, m_mat.rows)};
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}
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cv::MediaFrame::View access(cv::MediaFrame::Access) override {
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cv::MediaFrame::View::Ptrs pp = { m_mat.ptr(), nullptr, nullptr, nullptr };
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cv::MediaFrame::View::Strides ss = { m_mat.step, 0u, 0u, 0u };
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return cv::MediaFrame::View(std::move(pp), std::move(ss), Cb{m_cb});
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}
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};
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class TestMediaNV12 final: public cv::MediaFrame::IAdapter {
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cv::Mat m_y;
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cv::Mat m_uv;
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public:
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TestMediaNV12(cv::Mat y, cv::Mat uv) : m_y(y), m_uv(uv) {
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}
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cv::GFrameDesc meta() const override {
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return cv::GFrameDesc{cv::MediaFormat::NV12, cv::Size(m_y.cols, m_y.rows)};
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}
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cv::MediaFrame::View access(cv::MediaFrame::Access) override {
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cv::MediaFrame::View::Ptrs pp = {
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m_y.ptr(), m_uv.ptr(), nullptr, nullptr
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};
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cv::MediaFrame::View::Strides ss = {
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m_y.step, m_uv.step, 0u, 0u
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};
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return cv::MediaFrame::View(std::move(pp), std::move(ss));
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}
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};
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struct ONNXInitPath {
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ONNXInitPath() {
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const char* env_path = getenv("OPENCV_GAPI_ONNX_MODEL_PATH");
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if (env_path) {
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cvtest::addDataSearchPath(env_path);
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}
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}
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};
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static ONNXInitPath g_init_path;
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cv::Mat initMatrixRandU(const int type, const cv::Size& sz_in) {
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const cv::Mat in_mat1 = cv::Mat(sz_in, type);
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if (CV_MAT_DEPTH(type) < CV_32F) {
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cv::randu(in_mat1, cv::Scalar::all(0), cv::Scalar::all(255));
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} else {
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const int fscale = 256; // avoid bits near ULP, generate stable test input
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cv::Mat in_mat32s(in_mat1.size(), CV_MAKE_TYPE(CV_32S, CV_MAT_CN(type)));
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cv::randu(in_mat32s, cv::Scalar::all(0), cv::Scalar::all(255 * fscale));
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in_mat32s.convertTo(in_mat1, type, 1.0f / fscale, 0);
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}
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return in_mat1;
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}
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} // anonymous namespace
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namespace opencv_test
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{
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namespace {
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void initTestDataPath()
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{
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#ifndef WINRT
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static bool initialized = false;
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if (!initialized)
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{
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// Since G-API has no own test data (yet), it is taken from the common space
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const char* testDataPath = getenv("OPENCV_TEST_DATA_PATH");
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if (testDataPath) {
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cvtest::addDataSearchPath(testDataPath);
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}
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initialized = true;
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}
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#endif // WINRT
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}
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// FIXME: taken from the DNN module
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void normAssert(cv::InputArray& ref, cv::InputArray& test,
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const char *comment /*= ""*/,
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const double l1 = 0.00001, const double lInf = 0.0001) {
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const double normL1 = cvtest::norm(ref, test, cv::NORM_L1) / ref.getMat().total();
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EXPECT_LE(normL1, l1) << comment;
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const double normInf = cvtest::norm(ref, test, cv::NORM_INF);
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EXPECT_LE(normInf, lInf) << comment;
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}
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inline std::string findModel(const std::string &model_name) {
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return findDataFile("vision/" + model_name + ".onnx", false);
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}
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inline void toCHW(const cv::Mat& src, cv::Mat& dst) {
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dst.create(cv::Size(src.cols, src.rows * src.channels()), CV_32F);
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std::vector<cv::Mat> planes;
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for (int i = 0; i < src.channels(); ++i) {
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planes.push_back(dst.rowRange(i * src.rows, (i + 1) * src.rows));
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}
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cv::split(src, planes);
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}
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inline int toCV(ONNXTensorElementDataType prec) {
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switch (prec) {
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case ONNX_TENSOR_ELEMENT_DATA_TYPE_UINT8: return CV_8U;
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case ONNX_TENSOR_ELEMENT_DATA_TYPE_FLOAT: return CV_32F;
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case ONNX_TENSOR_ELEMENT_DATA_TYPE_INT32: return CV_32S;
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case ONNX_TENSOR_ELEMENT_DATA_TYPE_INT64: return CV_32S;
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default: GAPI_Assert(false && "Unsupported data type");
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}
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return -1;
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}
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void copyFromONNX(Ort::Value &v, cv::Mat& mat) {
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const auto info = v.GetTensorTypeAndShapeInfo();
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const auto prec = info.GetElementType();
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const auto shape = info.GetShape();
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const std::vector<int> dims(shape.begin(), shape.end());
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mat.create(dims, toCV(prec));
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switch (prec) {
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#define HANDLE(E,T) \
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case E: std::copy_n(v.GetTensorMutableData<T>(), \
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mat.total(), \
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reinterpret_cast<T*>(mat.data)); \
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break;
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HANDLE(ONNX_TENSOR_ELEMENT_DATA_TYPE_UINT8, uint8_t);
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HANDLE(ONNX_TENSOR_ELEMENT_DATA_TYPE_FLOAT, float);
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HANDLE(ONNX_TENSOR_ELEMENT_DATA_TYPE_INT32, int);
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#undef HANDLE
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case ONNX_TENSOR_ELEMENT_DATA_TYPE_INT64: {
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const auto o_ptr = v.GetTensorMutableData<int64_t>();
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const auto g_ptr = reinterpret_cast<int*>(mat.data);
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std::transform(o_ptr, o_ptr + mat.total(), g_ptr,
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[](int64_t el) { return static_cast<int>(el); });
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break;
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}
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default: GAPI_Assert(false && "ONNX. Unsupported data type");
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}
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}
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inline std::vector<int64_t> toORT(const cv::MatSize &sz) {
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return cv::to_own<int64_t>(sz);
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}
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inline std::vector<const char*> getCharNames(const std::vector<std::string>& names) {
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std::vector<const char*> out_ptrs;
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out_ptrs.reserve(names.size());
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ade::util::transform(names, std::back_inserter(out_ptrs),
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[](const std::string& name) { return name.c_str(); });
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return out_ptrs;
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}
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template<typename T>
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void copyToOut(const cv::Mat& onnx_out, const T end_mark, cv::Mat& gapi_out) {
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// This function is part of some remap__ function.
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// You can set graph output size (gapi_out) larger than real out from ONNX
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// so you have to add something for separate correct data and garbage.
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// For example, end of data can be marked with -1 (for positive values)
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// or you can put size of correct data at first/last element of output matrix.
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const size_t size = std::min(onnx_out.total(), gapi_out.total());
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std::copy(onnx_out.begin<T>(),
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onnx_out.begin<T>() + size,
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gapi_out.begin<T>());
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if (gapi_out.total() > onnx_out.total()) {
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T* gptr = gapi_out.ptr<T>();
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gptr[size] = end_mark;
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}
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}
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void remapYolo(const std::unordered_map<std::string, cv::Mat> &onnx,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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GAPI_Assert(onnx.size() == 1u);
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GAPI_Assert(gapi.size() == 1u);
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// Result from Run method
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const cv::Mat& in = onnx.begin()->second;
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GAPI_Assert(in.depth() == CV_32F);
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// Configured output
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cv::Mat& out = gapi.begin()->second;
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// Simple copy
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copyToOut<float>(in, -1.f, out);
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}
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void remapYoloV3(const std::unordered_map<std::string, cv::Mat> &onnx,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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// Simple copy for outputs
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const cv::Mat& in_boxes = onnx.at("yolonms_layer_1/ExpandDims_1:0");
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const cv::Mat& in_scores = onnx.at("yolonms_layer_1/ExpandDims_3:0");
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const cv::Mat& in_indices = onnx.at("yolonms_layer_1/concat_2:0");
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GAPI_Assert(in_boxes.depth() == CV_32F);
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GAPI_Assert(in_scores.depth() == CV_32F);
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GAPI_Assert(in_indices.depth() == CV_32S);
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cv::Mat& out_boxes = gapi.at("out1");
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cv::Mat& out_scores = gapi.at("out2");
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cv::Mat& out_indices = gapi.at("out3");
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copyToOut<float>(in_boxes, -1.f, out_boxes);
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copyToOut<float>(in_scores, -1.f, out_scores);
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copyToOut<int>(in_indices, -1, out_indices);
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}
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void remapToIESSDOut(const std::vector<cv::Mat> &detections,
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cv::Mat &ssd_output) {
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GAPI_Assert(detections.size() == 4u);
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for (const auto &det_el : detections) {
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GAPI_Assert(det_el.depth() == CV_32F);
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GAPI_Assert(!det_el.empty());
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}
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// SSD-MobilenetV1 structure check
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ASSERT_EQ(detections[0].total(), 1u);
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ASSERT_EQ(detections[2].total(), detections[0].total() * 100);
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ASSERT_EQ(detections[2].total(), detections[3].total());
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ASSERT_EQ((detections[2].total() * 4), detections[1].total());
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const int num_objects = static_cast<int>(detections[0].ptr<float>()[0]);
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GAPI_Assert(num_objects <= (ssd_output.size[2] - 1));
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const float *in_boxes = detections[1].ptr<float>();
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const float *in_scores = detections[2].ptr<float>();
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const float *in_classes = detections[3].ptr<float>();
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float *ptr = ssd_output.ptr<float>();
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for (int i = 0; i < num_objects; ++i) {
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ptr[0] = 0.f; // "image_id"
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ptr[1] = in_classes[i]; // "label"
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ptr[2] = in_scores[i]; // "confidence"
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ptr[3] = in_boxes[4 * i + 1]; // left
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ptr[4] = in_boxes[4 * i + 0]; // top
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ptr[5] = in_boxes[4 * i + 3]; // right
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ptr[6] = in_boxes[4 * i + 2]; // bottom
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ptr += 7;
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in_boxes += 4;
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}
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if (num_objects < ssd_output.size[2] - 1) {
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// put a -1 mark at the end of output blob if there is space left
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ptr[0] = -1.f;
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}
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}
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void remapSSDPorts(const std::unordered_map<std::string, cv::Mat> &onnx,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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// Assemble ONNX-processed outputs back to a single 1x1x200x7 blob
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// to preserve compatibility with OpenVINO-based SSD pipeline
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const cv::Mat &num_detections = onnx.at("num_detections:0");
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const cv::Mat &detection_boxes = onnx.at("detection_boxes:0");
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const cv::Mat &detection_scores = onnx.at("detection_scores:0");
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const cv::Mat &detection_classes = onnx.at("detection_classes:0");
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cv::Mat &ssd_output = gapi.at("detection_output");
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remapToIESSDOut({num_detections, detection_boxes, detection_scores, detection_classes}, ssd_output);
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}
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void reallocSSDPort(const std::unordered_map<std::string, cv::Mat> &/*onnx*/,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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gapi["detection_boxes"].create(1000, 3000, CV_32FC3);
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}
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void remapRCNNPortsC(const std::unordered_map<std::string, cv::Mat> &onnx,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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// Simple copy for outputs
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const cv::Mat& in_boxes = onnx.at("6379");
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const cv::Mat& in_labels = onnx.at("6381");
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const cv::Mat& in_scores = onnx.at("6383");
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GAPI_Assert(in_boxes.depth() == CV_32F);
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GAPI_Assert(in_labels.depth() == CV_32S);
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GAPI_Assert(in_scores.depth() == CV_32F);
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cv::Mat& out_boxes = gapi.at("out1");
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cv::Mat& out_labels = gapi.at("out2");
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cv::Mat& out_scores = gapi.at("out3");
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copyToOut<float>(in_boxes, -1.f, out_boxes);
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copyToOut<int>(in_labels, -1, out_labels);
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copyToOut<float>(in_scores, -1.f, out_scores);
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}
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void remapRCNNPortsDO(const std::unordered_map<std::string, cv::Mat> &onnx,
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std::unordered_map<std::string, cv::Mat> &gapi) {
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// Simple copy for outputs
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const cv::Mat& in_boxes = onnx.at("6379");
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const cv::Mat& in_scores = onnx.at("6383");
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GAPI_Assert(in_boxes.depth() == CV_32F);
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GAPI_Assert(in_scores.depth() == CV_32F);
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cv::Mat& out_boxes = gapi.at("out1");
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cv::Mat& out_scores = gapi.at("out2");
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copyToOut<float>(in_boxes, -1.f, out_boxes);
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copyToOut<float>(in_scores, -1.f, out_scores);
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}
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class ONNXtest : public ::testing::Test {
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public:
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std::string model_path;
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size_t num_in, num_out;
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std::vector<cv::Mat> out_gapi;
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std::vector<cv::Mat> out_onnx;
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cv::Mat in_mat1;
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ONNXtest() {
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initTestDataPath();
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env = Ort::Env(ORT_LOGGING_LEVEL_WARNING, "test");
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memory_info = Ort::MemoryInfo::CreateCpu(OrtArenaAllocator, OrtMemTypeDefault);
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out_gapi.resize(1);
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// FIXME: It should be an image from own (gapi) directory in opencv extra
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in_mat1 = cv::imread(findDataFile("cv/dpm/cat.png"));
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}
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template<typename T>
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void infer(const std::vector<cv::Mat>& ins,
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std::vector<cv::Mat>& outs,
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std::vector<std::string>&& custom_out_names = {}) {
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// Prepare session
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#ifndef _WIN32
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session = Ort::Session(env, model_path.c_str(), session_options);
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#else
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std::wstring_convert<std::codecvt_utf8<wchar_t>, wchar_t> converter;
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std::wstring w_model_path = converter.from_bytes(model_path.c_str());
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session = Ort::Session(env, w_model_path.c_str(), session_options);
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#endif
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num_in = session.GetInputCount();
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num_out = session.GetOutputCount();
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GAPI_Assert(num_in == ins.size());
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in_node_names.clear();
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out_node_names.clear();
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// Inputs Run params
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std::vector<Ort::Value> in_tensors;
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for(size_t i = 0; i < num_in; ++i) {
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char* in_node_name_p = session.GetInputName(i, allocator);
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in_node_names.emplace_back(in_node_name_p);
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allocator.Free(in_node_name_p);
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in_node_dims = toORT(ins[i].size);
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in_tensors.emplace_back(Ort::Value::CreateTensor<T>(memory_info,
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const_cast<T*>(ins[i].ptr<T>()),
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ins[i].total(),
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in_node_dims.data(),
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in_node_dims.size()));
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}
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// Outputs Run params
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if (custom_out_names.empty()) {
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for(size_t i = 0; i < num_out; ++i) {
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char* out_node_name_p = session.GetOutputName(i, allocator);
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out_node_names.emplace_back(out_node_name_p);
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allocator.Free(out_node_name_p);
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}
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} else {
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out_node_names = std::move(custom_out_names);
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}
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// Input/output order by names
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const auto in_run_names = getCharNames(in_node_names);
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const auto out_run_names = getCharNames(out_node_names);
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num_out = out_run_names.size();
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// Run
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auto result = session.Run(Ort::RunOptions{nullptr},
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in_run_names.data(),
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&in_tensors.front(),
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num_in,
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out_run_names.data(),
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num_out);
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// Copy outputs
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GAPI_Assert(result.size() == num_out);
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for (size_t i = 0; i < num_out; ++i) {
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const auto info = result[i].GetTensorTypeAndShapeInfo();
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const auto shape = info.GetShape();
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const auto type = toCV(info.GetElementType());
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const std::vector<int> dims(shape.begin(), shape.end());
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outs.emplace_back(dims, type);
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copyFromONNX(result[i], outs.back());
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}
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}
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// One input/output overload
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template<typename T>
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void infer(const cv::Mat& in, cv::Mat& out) {
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std::vector<cv::Mat> result;
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infer<T>(std::vector<cv::Mat>{in}, result);
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GAPI_Assert(result.size() == 1u);
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out = result.front();
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}
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// One input overload
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template<typename T>
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void infer(const cv::Mat& in,
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std::vector<cv::Mat>& outs,
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std::vector<std::string>&& custom_out_names = {}) {
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infer<T>(std::vector<cv::Mat>{in}, outs, std::move(custom_out_names));
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}
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void validate() {
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GAPI_Assert(!out_gapi.empty() && !out_onnx.empty());
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ASSERT_EQ(out_gapi.size(), out_onnx.size());
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const auto size = out_gapi.size();
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for (size_t i = 0; i < size; ++i) {
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normAssert(out_onnx[i], out_gapi[i], "Test outputs");
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}
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}
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void useModel(const std::string& model_name) {
|
|
model_path = findModel(model_name);
|
|
}
|
|
private:
|
|
Ort::Env env{nullptr};
|
|
Ort::MemoryInfo memory_info{nullptr};
|
|
Ort::AllocatorWithDefaultOptions allocator;
|
|
Ort::SessionOptions session_options;
|
|
Ort::Session session{nullptr};
|
|
|
|
std::vector<int64_t> in_node_dims;
|
|
std::vector<std::string> in_node_names;
|
|
std::vector<std::string> out_node_names;
|
|
};
|
|
|
|
class ONNXClassification : public ONNXtest {
|
|
public:
|
|
const cv::Scalar mean = { 0.485, 0.456, 0.406 };
|
|
const cv::Scalar std = { 0.229, 0.224, 0.225 };
|
|
|
|
// Rois for InferList, InferList2
|
|
const std::vector<cv::Rect> rois = {
|
|
cv::Rect(cv::Point{ 0, 0}, cv::Size{80, 120}),
|
|
cv::Rect(cv::Point{50, 100}, cv::Size{250, 360})
|
|
};
|
|
|
|
void preprocess(const cv::Mat& src, cv::Mat& dst) {
|
|
const int new_h = 224;
|
|
const int new_w = 224;
|
|
cv::Mat tmp, cvt, rsz;
|
|
cv::resize(src, rsz, cv::Size(new_w, new_h));
|
|
rsz.convertTo(cvt, CV_32F, 1.f / 255);
|
|
tmp = (cvt - mean) / std;
|
|
toCHW(tmp, dst);
|
|
dst = dst.reshape(1, {1, 3, new_h, new_w});
|
|
}
|
|
};
|
|
|
|
class ONNXMediaFrame : public ONNXClassification {
|
|
public:
|
|
const std::vector<cv::Rect> rois = {
|
|
cv::Rect(cv::Point{ 0, 0}, cv::Size{80, 120}),
|
|
cv::Rect(cv::Point{50, 100}, cv::Size{250, 360}),
|
|
cv::Rect(cv::Point{70, 10}, cv::Size{20, 260}),
|
|
cv::Rect(cv::Point{5, 15}, cv::Size{200, 160}),
|
|
};
|
|
cv::Mat m_in_y;
|
|
cv::Mat m_in_uv;
|
|
virtual void SetUp() {
|
|
cv::Size sz{640, 480};
|
|
m_in_y = initMatrixRandU(CV_8UC1, sz);
|
|
m_in_uv = initMatrixRandU(CV_8UC2, sz / 2);
|
|
}
|
|
};
|
|
|
|
class ONNXGRayScale : public ONNXtest {
|
|
public:
|
|
void preprocess(const cv::Mat& src, cv::Mat& dst) {
|
|
const int new_h = 64;
|
|
const int new_w = 64;
|
|
cv::Mat cvc, rsz, cvt;
|
|
cv::cvtColor(src, cvc, cv::COLOR_BGR2GRAY);
|
|
cv::resize(cvc, rsz, cv::Size(new_w, new_h));
|
|
rsz.convertTo(cvt, CV_32F);
|
|
toCHW(cvt, dst);
|
|
dst = dst.reshape(1, {1, 1, new_h, new_w});
|
|
}
|
|
};
|
|
|
|
class ONNXWithRemap : public ONNXtest {
|
|
private:
|
|
size_t step_by_outs = 0;
|
|
public:
|
|
// This function checks each next cv::Mat in out_gapi vector for next call.
|
|
// end_mark is edge of correct data
|
|
template <typename T>
|
|
void validate(const T end_mark) {
|
|
GAPI_Assert(!out_gapi.empty() && !out_onnx.empty());
|
|
ASSERT_EQ(out_gapi.size(), out_onnx.size());
|
|
GAPI_Assert(step_by_outs < out_gapi.size());
|
|
const T* op = out_onnx.at(step_by_outs).ptr<T>();
|
|
const T* gp = out_gapi.at(step_by_outs).ptr<T>();
|
|
// Checking that graph output larger than onnx output
|
|
const auto out_size = std::min(out_onnx.at(step_by_outs).total(), out_gapi.at(step_by_outs).total());
|
|
GAPI_Assert(out_size != 0u);
|
|
for (size_t d_idx = 0; d_idx < out_size; ++d_idx) {
|
|
if (gp[d_idx] == end_mark) break;
|
|
ASSERT_EQ(op[d_idx], gp[d_idx]);
|
|
}
|
|
++step_by_outs;
|
|
}
|
|
};
|
|
|
|
class ONNXRCNN : public ONNXWithRemap {
|
|
private:
|
|
const cv::Scalar rcnn_mean = { 102.9801, 115.9465, 122.7717 };
|
|
const float range_max = 1333;
|
|
const float range_min = 800;
|
|
public:
|
|
void preprocess(const cv::Mat& src, cv::Mat& dst) {
|
|
cv::Mat rsz, cvt, chw, mn;
|
|
const auto get_ratio = [&](const int dim) -> float {
|
|
return ((dim > range_max) || (dim < range_min))
|
|
? dim > range_max
|
|
? range_max / dim
|
|
: range_min / dim
|
|
: 1.f;
|
|
};
|
|
const auto ratio_h = get_ratio(src.rows);
|
|
const auto ratio_w = get_ratio(src.cols);
|
|
const auto new_h = static_cast<int>(ratio_h * src.rows);
|
|
const auto new_w = static_cast<int>(ratio_w * src.cols);
|
|
cv::resize(src, rsz, cv::Size(new_w, new_h));
|
|
rsz.convertTo(cvt, CV_32F, 1.f);
|
|
toCHW(cvt, chw);
|
|
mn = chw - rcnn_mean;
|
|
const int padded_h = std::ceil(new_h / 32.f) * 32;
|
|
const int padded_w = std::ceil(new_w / 32.f) * 32;
|
|
cv::Mat pad_im(cv::Size(padded_w, 3 * padded_h), CV_32F, 0.f);
|
|
pad_im(cv::Rect(0, 0, mn.cols, mn.rows)) += mn;
|
|
dst = pad_im.reshape(1, {3, padded_h, padded_w});
|
|
}
|
|
};
|
|
|
|
class ONNXYoloV3 : public ONNXWithRemap {
|
|
public:
|
|
std::vector<cv::Mat> ins;
|
|
|
|
private:
|
|
virtual void SetUp() {
|
|
const int yolo_in_h = 416;
|
|
const int yolo_in_w = 416;
|
|
cv::Mat yolov3_input, shape, prep_mat;
|
|
cv::resize(in_mat1, yolov3_input, cv::Size(yolo_in_w, yolo_in_h));
|
|
shape.create(cv::Size(2, 1), CV_32F);
|
|
float* ptr = shape.ptr<float>();
|
|
ptr[0] = in_mat1.cols;
|
|
ptr[1] = in_mat1.rows;
|
|
preprocess(yolov3_input, prep_mat);
|
|
ins = {prep_mat, shape};
|
|
}
|
|
|
|
void preprocess(const cv::Mat& src, cv::Mat& dst) {
|
|
cv::Mat cvt;
|
|
src.convertTo(cvt, CV_32F, 1.f / 255.f);
|
|
toCHW(cvt, dst);
|
|
dst = dst.reshape(1, {1, 3, 416, 416});
|
|
}
|
|
};
|
|
} // anonymous namespace
|
|
|
|
TEST_F(ONNXClassification, Infer)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
// ONNX_API code
|
|
cv::Mat processed_mat;
|
|
preprocess(in_mat1, processed_mat);
|
|
infer<float>(processed_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GMat in;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(in_mat1),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXClassification, InferTensor)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
// Create tensor
|
|
cv::Mat tensor;
|
|
preprocess(in_mat1, tensor);
|
|
// ONNX_API code
|
|
infer<float>(tensor, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GMat in;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path };
|
|
comp.apply(cv::gin(tensor),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXClassification, InferROI)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto ROI = rois.at(0);
|
|
// ONNX_API code
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(ROI), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GMat in;
|
|
cv::GOpaque<cv::Rect> rect;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(rect, in);
|
|
cv::GComputation comp(cv::GIn(in, rect), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(in_mat1, ROI),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXClassification, InferROIList)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
// ONNX_API code
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GMat in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer<SqueezNet>(rr, in);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(in_mat1, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXClassification, Infer2ROIList)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
// ONNX_API code
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GMat in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer2<SqueezNet>(in, rr);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(in_mat1, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXWithRemap, InferDynamicInputTensor)
|
|
{
|
|
useModel("object_detection_segmentation/tiny-yolov2/model/tinyyolov2-8");
|
|
// Create tensor
|
|
cv::Mat cvt, rsz, tensor;
|
|
cv::resize(in_mat1, rsz, cv::Size{416, 416});
|
|
rsz.convertTo(cvt, CV_32F, 1.f / 255.f);
|
|
toCHW(cvt, tensor);
|
|
tensor = tensor.reshape(1, {1, 3, 416, 416});
|
|
// ONNX_API code
|
|
infer<float>(tensor, out_onnx);
|
|
// G_API code
|
|
G_API_NET(YoloNet, <cv::GMat(cv::GMat)>, "YoloNet");
|
|
cv::GMat in;
|
|
cv::GMat out = cv::gapi::infer<YoloNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
auto net = cv::gapi::onnx::Params<YoloNet>{ model_path }
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {1, 125, 13, 13}}}, remapYolo)
|
|
.cfgOutputLayers({"out"});
|
|
comp.apply(cv::gin(tensor),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
}
|
|
|
|
TEST_F(ONNXGRayScale, InferImage)
|
|
{
|
|
useModel("body_analysis/emotion_ferplus/model/emotion-ferplus-8");
|
|
// ONNX_API code
|
|
cv::Mat prep_mat;
|
|
preprocess(in_mat1, prep_mat);
|
|
infer<float>(prep_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(EmotionNet, <cv::GMat(cv::GMat)>, "emotion-ferplus");
|
|
cv::GMat in;
|
|
cv::GMat out = cv::gapi::infer<EmotionNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
auto net = cv::gapi::onnx::Params<EmotionNet> { model_path }
|
|
.cfgNormalize({ false }); // model accepts 0..255 range in FP32;
|
|
comp.apply(cv::gin(in_mat1),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXWithRemap, InferMultiOutput)
|
|
{
|
|
useModel("object_detection_segmentation/ssd-mobilenetv1/model/ssd_mobilenet_v1_10");
|
|
// ONNX_API code
|
|
const auto prep_mat = in_mat1.reshape(1, {1, in_mat1.rows, in_mat1.cols, in_mat1.channels()});
|
|
infer<uint8_t>(prep_mat, out_onnx);
|
|
cv::Mat onnx_conv_out({1, 1, 200, 7}, CV_32F);
|
|
remapToIESSDOut({out_onnx[3], out_onnx[0], out_onnx[2], out_onnx[1]}, onnx_conv_out);
|
|
out_onnx.clear();
|
|
out_onnx.push_back(onnx_conv_out);
|
|
// G_API code
|
|
G_API_NET(MobileNet, <cv::GMat(cv::GMat)>, "ssd_mobilenet");
|
|
cv::GMat in;
|
|
cv::GMat out = cv::gapi::infer<MobileNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
auto net = cv::gapi::onnx::Params<MobileNet>{ model_path }
|
|
.cfgOutputLayers({"detection_output"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {1, 1, 200, 7}}}, remapSSDPorts);
|
|
comp.apply(cv::gin(in_mat1),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferBGR)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
// ONNX_API code
|
|
cv::Mat processed_mat;
|
|
preprocess(in_mat1, processed_mat);
|
|
infer<float>(processed_mat, out_onnx);
|
|
// G_API code
|
|
auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferYUV)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaNV12>(m_in_y, m_in_uv);
|
|
// ONNX_API code
|
|
cv::Mat pp;
|
|
cvtColorTwoPlane(m_in_y, m_in_uv, pp, cv::COLOR_YUV2BGR_NV12);
|
|
cv::Mat processed_mat;
|
|
preprocess(pp, processed_mat);
|
|
infer<float>(processed_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferROIBGR)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
|
|
// ONNX_API code
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(rois.front()), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GOpaque<cv::Rect> rect;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(rect, in);
|
|
cv::GComputation comp(cv::GIn(in, rect), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois.front()),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferROIYUV)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaNV12>(m_in_y, m_in_uv);
|
|
// ONNX_API code
|
|
cv::Mat pp;
|
|
cvtColorTwoPlane(m_in_y, m_in_uv, pp, cv::COLOR_YUV2BGR_NV12);
|
|
cv::Mat roi_mat;
|
|
preprocess(pp(rois.front()), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GOpaque<cv::Rect> rect;
|
|
cv::GMat out = cv::gapi::infer<SqueezNet>(rect, in);
|
|
cv::GComputation comp(cv::GIn(in, rect), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois.front()),
|
|
cv::gout(out_gapi.front()),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferListBGR)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
|
|
// ONNX_API code
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer<SqueezNet>(rr, in);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferListYUV)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaNV12>(m_in_y, m_in_uv);
|
|
// ONNX_API code
|
|
cv::Mat pp;
|
|
cvtColorTwoPlane(m_in_y, m_in_uv, pp, cv::COLOR_YUV2BGR_NV12);
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(pp(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer<SqueezNet>(rr, in);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
TEST_F(ONNXRCNN, InferWithDisabledOut)
|
|
{
|
|
useModel("object_detection_segmentation/faster-rcnn/model/FasterRCNN-10");
|
|
cv::Mat pp;
|
|
preprocess(in_mat1, pp);
|
|
// ONNX_API code
|
|
infer<float>(pp, out_onnx, {"6379", "6383"});
|
|
// G_API code
|
|
using FRCNNOUT = std::tuple<cv::GMat, cv::GMat>;
|
|
G_API_NET(FasterRCNN, <FRCNNOUT(cv::GMat)>, "FasterRCNN");
|
|
auto net = cv::gapi::onnx::Params<FasterRCNN>{model_path}
|
|
.cfgOutputLayers({"out1", "out2"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {7,4}},
|
|
cv::GMatDesc{CV_32F, {7}}}, remapRCNNPortsDO, {"6383", "6379"});
|
|
cv::GMat in, out1, out2;
|
|
std::tie(out1, out2) = cv::gapi::infer<FasterRCNN>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out1, out2));
|
|
out_gapi.resize(num_out);
|
|
comp.apply(cv::gin(pp),
|
|
cv::gout(out_gapi[0], out_gapi[1]),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
validate<float>(-1.f);
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferList2BGR)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
|
|
// ONNX_API code
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(in_mat1(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer2<SqueezNet>(in, rr);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXMediaFrame, InferList2YUV)
|
|
{
|
|
useModel("classification/squeezenet/model/squeezenet1.0-9");
|
|
const auto frame = MediaFrame::Create<TestMediaNV12>(m_in_y, m_in_uv);
|
|
// ONNX_API code
|
|
cv::Mat pp;
|
|
cvtColorTwoPlane(m_in_y, m_in_uv, pp, cv::COLOR_YUV2BGR_NV12);
|
|
for (size_t i = 0; i < rois.size(); ++i) {
|
|
cv::Mat roi_mat;
|
|
preprocess(pp(rois[i]), roi_mat);
|
|
infer<float>(roi_mat, out_onnx);
|
|
}
|
|
// G_API code
|
|
G_API_NET(SqueezNet, <cv::GMat(cv::GMat)>, "squeeznet");
|
|
cv::GFrame in;
|
|
cv::GArray<cv::Rect> rr;
|
|
cv::GArray<cv::GMat> out = cv::gapi::infer2<SqueezNet>(in, rr);
|
|
cv::GComputation comp(cv::GIn(in, rr), cv::GOut(out));
|
|
// NOTE: We have to normalize U8 tensor
|
|
// so cfgMeanStd() is here
|
|
auto net = cv::gapi::onnx::Params<SqueezNet> { model_path }.cfgMeanStd({ mean }, { std });
|
|
comp.apply(cv::gin(frame, rois),
|
|
cv::gout(out_gapi),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate();
|
|
}
|
|
|
|
TEST_F(ONNXYoloV3, InferConstInput)
|
|
{
|
|
useModel("object_detection_segmentation/yolov3/model/yolov3-10");
|
|
// ONNX_API code
|
|
infer<float>(ins, out_onnx);
|
|
// G_API code
|
|
using OUT = std::tuple<cv::GMat, cv::GMat, cv::GMat>;
|
|
G_API_NET(YoloNet, <OUT(cv::GMat)>, "yolov3");
|
|
auto net = cv::gapi::onnx::Params<YoloNet>{model_path}
|
|
.constInput("image_shape", ins[1])
|
|
.cfgInputLayers({"input_1"})
|
|
.cfgOutputLayers({"out1", "out2", "out3"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {1, 10000, 4}},
|
|
cv::GMatDesc{CV_32F, {1, 80, 10000}},
|
|
cv::GMatDesc{CV_32S, {5, 3}}}, remapYoloV3);
|
|
cv::GMat in, out1, out2, out3;
|
|
std::tie(out1, out2, out3) = cv::gapi::infer<YoloNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out1, out2, out3));
|
|
out_gapi.resize(num_out);
|
|
comp.apply(cv::gin(ins[0]),
|
|
cv::gout(out_gapi[0], out_gapi[1], out_gapi[2]),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
validate<float>(-1.f);
|
|
validate<int>(-1);
|
|
}
|
|
|
|
TEST_F(ONNXYoloV3, InferBSConstInput)
|
|
{
|
|
// This test checks the case when a const input is used
|
|
// and all input layer names are specified.
|
|
// Const input has the advantage. It is expected behavior.
|
|
useModel("object_detection_segmentation/yolov3/model/yolov3-10");
|
|
// Tensor with incorrect image size
|
|
// is used for check case when InputLayers and constInput have same names
|
|
cv::Mat bad_shape;
|
|
bad_shape.create(cv::Size(2, 1), CV_32F);
|
|
float* ptr = bad_shape.ptr<float>();
|
|
ptr[0] = 590;
|
|
ptr[1] = 12;
|
|
// ONNX_API code
|
|
infer<float>(ins, out_onnx);
|
|
// G_API code
|
|
using OUT = std::tuple<cv::GMat, cv::GMat, cv::GMat>;
|
|
G_API_NET(YoloNet, <OUT(cv::GMat, cv::GMat)>, "yolov3");
|
|
auto net = cv::gapi::onnx::Params<YoloNet>{model_path}
|
|
// Data from const input will be used to infer
|
|
.constInput("image_shape", ins[1])
|
|
// image_shape - const_input has same name
|
|
.cfgInputLayers({"input_1", "image_shape"})
|
|
.cfgOutputLayers({"out1", "out2", "out3"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {1, 10000, 4}},
|
|
cv::GMatDesc{CV_32F, {1, 80, 10000}},
|
|
cv::GMatDesc{CV_32S, {5, 3}}}, remapYoloV3);
|
|
cv::GMat in1, in2, out1, out2, out3;
|
|
std::tie(out1, out2, out3) = cv::gapi::infer<YoloNet>(in1, in2);
|
|
cv::GComputation comp(cv::GIn(in1, in2), cv::GOut(out1, out2, out3));
|
|
out_gapi.resize(num_out);
|
|
comp.apply(cv::gin(ins[0], bad_shape),
|
|
cv::gout(out_gapi[0], out_gapi[1], out_gapi[2]),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
validate<float>(-1.f);
|
|
validate<int>(-1);
|
|
}
|
|
|
|
TEST_F(ONNXRCNN, ConversionInt64to32)
|
|
{
|
|
useModel("object_detection_segmentation/faster-rcnn/model/FasterRCNN-10");
|
|
cv::Mat dst;
|
|
preprocess(in_mat1, dst);
|
|
// ONNX_API code
|
|
infer<float>(dst, out_onnx);
|
|
// G_API code
|
|
using FRCNNOUT = std::tuple<cv::GMat,cv::GMat,cv::GMat>;
|
|
G_API_NET(FasterRCNN, <FRCNNOUT(cv::GMat)>, "FasterRCNN");
|
|
auto net = cv::gapi::onnx::Params<FasterRCNN>{model_path}
|
|
.cfgOutputLayers({"out1", "out2", "out3"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {7,4}},
|
|
cv::GMatDesc{CV_32S, {7}},
|
|
cv::GMatDesc{CV_32F, {7}}}, remapRCNNPortsC);
|
|
cv::GMat in, out1, out2, out3;
|
|
std::tie(out1, out2, out3) = cv::gapi::infer<FasterRCNN>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out1, out2, out3));
|
|
out_gapi.resize(num_out);
|
|
comp.apply(cv::gin(dst),
|
|
cv::gout(out_gapi[0], out_gapi[1], out_gapi[2]),
|
|
cv::compile_args(cv::gapi::networks(net)));
|
|
// Validate
|
|
validate<float>(-1.f);
|
|
validate<int>(-1);
|
|
validate<float>(-1.f);
|
|
}
|
|
|
|
TEST_F(ONNXWithRemap, InferOutReallocation)
|
|
{
|
|
useModel("object_detection_segmentation/ssd-mobilenetv1/model/ssd_mobilenet_v1_10");
|
|
// G_API code
|
|
G_API_NET(MobileNet, <cv::GMat(cv::GMat)>, "ssd_mobilenet");
|
|
auto net = cv::gapi::onnx::Params<MobileNet>{model_path}
|
|
.cfgOutputLayers({"detection_boxes"})
|
|
.cfgPostProc({cv::GMatDesc{CV_32F, {1,100,4}}}, reallocSSDPort);
|
|
cv::GMat in;
|
|
cv::GMat out1;
|
|
out1 = cv::gapi::infer<MobileNet>(in);
|
|
cv::GComputation comp(cv::GIn(in), cv::GOut(out1));
|
|
EXPECT_THROW(comp.apply(cv::gin(in_mat1),
|
|
cv::gout(out_gapi[0]),
|
|
cv::compile_args(cv::gapi::networks(net))), std::exception);
|
|
}
|
|
|
|
} // namespace opencv_test
|
|
|
|
#endif // HAVE_ONNX
|