opencv/modules/gapi/test/infer/gapi_infer_onnx_test.cpp

739 lines
26 KiB
C++
Raw Normal View History

// This file is part of OpenCV project.
// It is subject to the license terms in the LICENSE file found in the top-level directory
// of this distribution and at http://opencv.org/license.html.
//
// Copyright (C) 2020 Intel Corporation
#include "../test_precomp.hpp"
#ifdef HAVE_ONNX
#include <stdexcept>
#include <onnxruntime_cxx_api.h>
#include <ade/util/iota_range.hpp>
#include <opencv2/gapi/own/convert.hpp>
#include <opencv2/gapi/infer/onnx.hpp>
namespace {
class TestMediaBGR final: public cv::MediaFrame::IAdapter {
cv::Mat m_mat;
using Cb = cv::MediaFrame::View::Callback;
Cb m_cb;
public:
explicit TestMediaBGR(cv::Mat m, Cb cb = [](){})
: m_mat(m), m_cb(cb) {
}
cv::GFrameDesc meta() const override {
return cv::GFrameDesc{cv::MediaFormat::BGR, cv::Size(m_mat.cols, m_mat.rows)};
}
cv::MediaFrame::View access(cv::MediaFrame::Access) override {
cv::MediaFrame::View::Ptrs pp = { m_mat.ptr(), nullptr, nullptr, nullptr };
cv::MediaFrame::View::Strides ss = { m_mat.step, 0u, 0u, 0u };
return cv::MediaFrame::View(std::move(pp), std::move(ss), Cb{m_cb});
}
};
class TestMediaNV12 final: public cv::MediaFrame::IAdapter {
cv::Mat m_y;
cv::Mat m_uv;
public:
TestMediaNV12(cv::Mat y, cv::Mat uv) : m_y(y), m_uv(uv) {
}
cv::GFrameDesc meta() const override {
return cv::GFrameDesc{cv::MediaFormat::NV12, cv::Size(m_y.cols, m_y.rows)};
}
cv::MediaFrame::View access(cv::MediaFrame::Access) override {
cv::MediaFrame::View::Ptrs pp = {
m_y.ptr(), m_uv.ptr(), nullptr, nullptr
};
cv::MediaFrame::View::Strides ss = {
m_y.step, m_uv.step, 0u, 0u
};
return cv::MediaFrame::View(std::move(pp), std::move(ss));
}
};
struct ONNXInitPath {
ONNXInitPath() {
const char* env_path = getenv("OPENCV_GAPI_ONNX_MODEL_PATH");
if (env_path) {
cvtest::addDataSearchPath(env_path);
}
}
};
static ONNXInitPath g_init_path;
cv::Mat initMatrixRandU(const int type, const cv::Size& sz_in) {
const cv::Mat in_mat1 = cv::Mat(sz_in, type);
if (CV_MAT_DEPTH(type) < CV_32F) {
cv::randu(in_mat1, cv::Scalar::all(0), cv::Scalar::all(255));
} else {
const int fscale = 256; // avoid bits near ULP, generate stable test input
cv::Mat in_mat32s(in_mat1.size(), CV_MAKE_TYPE(CV_32S, CV_MAT_CN(type)));
cv::randu(in_mat32s, cv::Scalar::all(0), cv::Scalar::all(255 * fscale));
in_mat32s.convertTo(in_mat1, type, 1.0f / fscale, 0);
}
return in_mat1;
}
} // anonymous namespace
namespace opencv_test
{
namespace {
// FIXME: taken from the DNN module
void normAssert(const cv::InputArray& ref, const cv::InputArray& test,
const char *comment /*= ""*/,
const double l1 = 0.00001, const double lInf = 0.0001) {
const double normL1 = cvtest::norm(ref, test, cv::NORM_L1) / ref.getMat().total();
EXPECT_LE(normL1, l1) << comment;
const double normInf = cvtest::norm(ref, test, cv::NORM_INF);
EXPECT_LE(normInf, lInf) << comment;
}
inline std::string findModel(const std::string &model_name) {
return findDataFile("vision/" + model_name + ".onnx", false);
}
inline void toCHW(const cv::Mat& src, cv::Mat& dst) {
dst.create(cv::Size(src.cols, src.rows * src.channels()), CV_32F);
std::vector<cv::Mat> planes;
for (int i = 0; i < src.channels(); ++i) {
planes.push_back(dst.rowRange(i * src.rows, (i + 1) * src.rows));
}
cv::split(src, planes);
}
inline int toCV(const ONNXTensorElementDataType prec) {
switch (prec) {
case ONNX_TENSOR_ELEMENT_DATA_TYPE_UINT8: return CV_8U;
case ONNX_TENSOR_ELEMENT_DATA_TYPE_FLOAT: return CV_32F;
default: GAPI_Assert(false && "Unsupported data type");
}
return -1;
}
inline std::vector<int64_t> toORT(const cv::MatSize &sz) {
return cv::to_own<int64_t>(sz);
}
inline std::vector<const char*> getCharNames(const std::vector<std::string>& names) {
std::vector<const char*> out_vec;
for (const auto& el : names) {
out_vec.push_back(el.data());
}
return out_vec;
}
inline void copyToOut(const cv::Mat& in, cv::Mat& out) {
GAPI_Assert(in.depth() == CV_32F);
GAPI_Assert(in.size == out.size);
const float* const inptr = in.ptr<float>();
float* const optr = out.ptr<float>();
const int size = in.total();
for (int i = 0; i < size; ++i) {
optr[i] = inptr[i];
}
}
void remapYolo(const std::unordered_map<std::string, cv::Mat> &onnx,
std::unordered_map<std::string, cv::Mat> &gapi) {
GAPI_Assert(onnx.size() == 1u);
GAPI_Assert(gapi.size() == 1u);
// Result from Run method
const cv::Mat& in = onnx.begin()->second;
// Configured output
cv::Mat& out = gapi.begin()->second;
// Simple copy
copyToOut(in, out);
}
void remapSsdPorts(const std::unordered_map<std::string, cv::Mat> &onnx,
std::unordered_map<std::string, cv::Mat> &gapi) {
// Result from Run method
const cv::Mat& in_num = onnx.at("num_detections:0");
const cv::Mat& in_boxes = onnx.at("detection_boxes:0");
const cv::Mat& in_scores = onnx.at("detection_scores:0");
const cv::Mat& in_classes = onnx.at("detection_classes:0");
// Configured outputs
cv::Mat& out_boxes = gapi.at("out1");
cv::Mat& out_classes = gapi.at("out2");
cv::Mat& out_scores = gapi.at("out3");
cv::Mat& out_num = gapi.at("out4");
// Simple copy for outputs
copyToOut(in_num, out_num);
copyToOut(in_boxes, out_boxes);
copyToOut(in_scores, out_scores);
copyToOut(in_classes, out_classes);
}
class ONNXtest : public ::testing::Test {
public:
std::string model_path;
size_t num_in, num_out;
std::vector<cv::Mat> out_gapi;
std::vector<cv::Mat> out_onnx;
cv::Mat in_mat1;
ONNXtest() {
env = Ort::Env(ORT_LOGGING_LEVEL_WARNING, "test");
memory_info = Ort::MemoryInfo::CreateCpu(OrtArenaAllocator, OrtMemTypeDefault);
out_gapi.resize(1);
out_onnx.resize(1);
// FIXME: All tests chek "random" image
// Ideally it should be a real image
in_mat1 = initMatrixRandU(CV_8UC3, cv::Size{640, 480});
}
template<typename T>
void infer(const std::vector<cv::Mat>& ins,
std::vector<cv::Mat>& outs) {
// Prepare session
session = Ort::Session(env, model_path.data(), session_options);
num_in = session.GetInputCount();
num_out = session.GetOutputCount();
GAPI_Assert(num_in == ins.size());
in_node_names.clear();
out_node_names.clear();
// Inputs Run params
std::vector<Ort::Value> in_tensors;
for(size_t i = 0; i < num_in; ++i) {
char* in_node_name_p = session.GetInputName(i, allocator);
in_node_names.push_back(std::string(in_node_name_p));
allocator.Free(in_node_name_p);
in_node_dims = toORT(ins[i].size);
in_tensors.emplace_back(Ort::Value::CreateTensor<T>(memory_info,
const_cast<T*>(ins[i].ptr<T>()),
ins[i].total(),
in_node_dims.data(),
in_node_dims.size()));
}
// Outputs Run params
for(size_t i = 0; i < num_out; ++i) {
char* out_node_name_p = session.GetOutputName(i, allocator);
out_node_names.push_back(std::string(out_node_name_p));
allocator.Free(out_node_name_p);
}
// Input/output order by names
const auto in_run_names = getCharNames(in_node_names);
const auto out_run_names = getCharNames(out_node_names);
// Run
auto result = session.Run(Ort::RunOptions{nullptr},
in_run_names.data(),
&in_tensors.front(),
num_in,
out_run_names.data(),
num_out);
// Copy outputs
GAPI_Assert(result.size() == num_out);
outs.resize(num_out);
for (size_t i = 0; i < num_out; ++i) {
const auto info = result[i].GetTensorTypeAndShapeInfo();
const auto shape = info.GetShape();
const auto type = info.GetElementType();
cv::Mat mt(std::vector<int>(shape.begin(), shape.end()), toCV(type),
reinterpret_cast<void*>(result[i].GetTensorMutableData<uint8_t*>()));
mt.copyTo(outs[i]);
}
}
// One input/output overload
template<typename T>
void infer(const cv::Mat& in, cv::Mat& out) {
std::vector<cv::Mat> result;
infer<T>({in}, result);
GAPI_Assert(result.size() == 1u);
out = result.front();
}
void validate() {
GAPI_Assert(!out_gapi.empty() && !out_onnx.empty());
ASSERT_EQ(out_gapi.size(), out_onnx.size());
const auto size = out_gapi.size();
for (size_t i = 0; i < size; ++i) {
normAssert(out_onnx[i], out_gapi[i], "Test outputs");
}
}
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 ONNXClassificationTest : public ONNXtest {
public:
const cv::Scalar mean = { 0.485, 0.456, 0.406 };
const cv::Scalar std = { 0.229, 0.224, 0.225 };
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 ONNXMediaFrameTest : public ONNXClassificationTest {
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 ONNXGRayScaleTest : 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});
}
};
} // anonymous namespace
TEST_F(ONNXClassificationTest, 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.front());
// 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(ONNXtest, InferTensor)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
// Create tensor
// FIXME: Test cheks "random" image
// Ideally it should be a real image
const cv::Mat rand_mat = initMatrixRandU(CV_32FC3, cv::Size{224, 224});
const std::vector<int> dims = {1, rand_mat.channels(), rand_mat.rows, rand_mat.cols};
const cv::Mat tensor(dims, CV_32F, rand_mat.data);
// ONNX_API code
infer<float>(tensor, out_onnx.front());
// 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(ONNXClassificationTest, InferROI)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
const cv::Rect ROI(cv::Point{0, 0}, cv::Size{250, 250});
// ONNX_API code
cv::Mat roi_mat;
preprocess(in_mat1(ROI), roi_mat);
infer<float>(roi_mat, out_onnx.front());
// 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(ONNXClassificationTest, InferROIList)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
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}),
};
// ONNX_API code
out_onnx.resize(rois.size());
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[i]);
}
// 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(ONNXClassificationTest, Infer2ROIList)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
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}),
};
// ONNX_API code
out_onnx.resize(rois.size());
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[i]);
}
// 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(ONNXtest, InferDynamicInputTensor)
{
useModel("object_detection_segmentation/tiny-yolov2/model/tinyyolov2-8");
// Create tensor
// FIXME: Test cheks "random" image
// Ideally it should be a real image
const cv::Mat rand_mat = initMatrixRandU(CV_32FC3, cv::Size{416, 416});
const std::vector<int> dims = {1, rand_mat.channels(), rand_mat.rows, rand_mat.cols};
cv::Mat tensor(dims, CV_32F, rand_mat.data);
const cv::Mat in_tensor = tensor / 255.f;
// ONNX_API code
infer<float>(in_tensor, out_onnx.front());
// 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(in_tensor),
cv::gout(out_gapi.front()),
cv::compile_args(cv::gapi::networks(net)));
// Validate
validate();
}
TEST_F(ONNXGRayScaleTest, 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.front());
// 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(ONNXtest, InferMultOutput)
{
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);
// G_API code
using SSDOut = std::tuple<cv::GMat, cv::GMat, cv::GMat, cv::GMat>;
G_API_NET(MobileNet, <SSDOut(cv::GMat)>, "ssd_mobilenet");
cv::GMat in;
cv::GMat out1, out2, out3, out4;
std::tie(out1, out2, out3, out4) = cv::gapi::infer<MobileNet>(in);
cv::GComputation comp(cv::GIn(in), cv::GOut(out1, out2, out3, out4));
auto net = cv::gapi::onnx::Params<MobileNet>{model_path}
.cfgOutputLayers({"out1", "out2", "out3", "out4"})
.cfgPostProc({cv::GMatDesc{CV_32F, {1, 100, 4}},
cv::GMatDesc{CV_32F, {1, 100}},
cv::GMatDesc{CV_32F, {1, 100}},
cv::GMatDesc{CV_32F, {1, 1}}}, remapSsdPorts);
out_gapi.resize(num_out);
comp.apply(cv::gin(in_mat1),
cv::gout(out_gapi[0], out_gapi[1], out_gapi[2], out_gapi[3]),
cv::compile_args(cv::gapi::networks(net)));
// Validate
validate();
}
TEST_F(ONNXMediaFrameTest, 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.front());
// 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(ONNXMediaFrameTest, 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.front());
// 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(ONNXMediaFrameTest, 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.front());
// 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(ONNXMediaFrameTest, 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.front());
// 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(ONNXMediaFrameTest, InferListBGR)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
const auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
// ONNX_API code
out_onnx.resize(rois.size());
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[i]);
}
// 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(ONNXMediaFrameTest, 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);
out_onnx.resize(rois.size());
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[i]);
}
// 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(ONNXMediaFrameTest, InferList2BGR)
{
useModel("classification/squeezenet/model/squeezenet1.0-9");
const auto frame = MediaFrame::Create<TestMediaBGR>(in_mat1);
// ONNX_API code
out_onnx.resize(rois.size());
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[i]);
}
// 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(ONNXMediaFrameTest, 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);
out_onnx.resize(rois.size());
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[i]);
}
// 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();
}
} // namespace opencv_test
#endif // HAVE_ONNX