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ebea65777f
opencv/modules/gapi/test/infer/gapi_infer_ov_tests.cpp
Daria Mityagina ebea65777f
Merge pull request #24938 from DariaMityagina:icv/dm/add-media-frame-support-to-govbackend 
G-API OV backend requires cv::MediaFrame #24938

### Pull Request Readiness Checklist

**Background_subtraction demo G-API issue. Update:**

Porting to API20 resulted in an error (both for CPU and NPU):
```
[ERROR] OpenCV(4.9.0-dev) /home/runner/work/open_model_zoo/open_model_zoo/cache/opencv/modules/gapi/src/backends/ov/govbackend.cpp:813: error: (-215: assertion not done ) cv::util::holds_alternative<cv::GMatDesc>(input_meta) in function 'cfgPreProcessing'
```

Adding cv::MediaFrame support to govbackend resulted in the following (tested with CPU):
<img width="941" alt="image" src="https://github.com/opencv/opencv/assets/52502732/3a003d61-bda7-4b1e-9117-3410cda1ba32">

### TODO

- [ ] **As part of the review process [this comment](https://github.com/opencv/opencv/pull/24938#discussion_r1487694043) was addressed which make it impossible to run the demo. I will bring those changes back in a separate PR [support `PartialShape`]**

See details at https://github.com/opencv/opencv/wiki/How_to_contribute#making-a-good-pull-request

- [x] I agree to contribute to the project under Apache 2 License.
- [x] To the best of my knowledge, the proposed patch is not based on a code under GPL or another license that is incompatible with OpenCV
- [x] The PR is proposed to the proper branch
- [x] There is a reference to the original bug report and related work
- [ ] There is accuracy test, performance test and test data in opencv_extra repository, if applicable
      Patch to opencv_extra has the same branch name.
- [ ] The feature is well documented and sample code can be built with the project CMake
2024-04-24 16:25:00 +03:00

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// 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) 2023 Intel Corporation
#if defined HAVE_INF_ENGINE && INF_ENGINE_RELEASE >= 2022010000
#include "../test_precomp.hpp"
#include "backends/ov/util.hpp"
#include <opencv2/gapi/infer/ov.hpp>
#include <openvino/openvino.hpp>
namespace opencv_test
{
namespace {
// FIXME: taken from DNN module
void initDLDTDataPath()
{
#ifndef WINRT
static bool initialized = false;
if (!initialized)
{
const char* omzDataPath = getenv("OPENCV_OPEN_MODEL_ZOO_DATA_PATH");
if (omzDataPath)
cvtest::addDataSearchPath(omzDataPath);
const char* dnnDataPath = getenv("OPENCV_DNN_TEST_DATA_PATH");
if (dnnDataPath) {
// Add the dnnDataPath itself - G-API is using some images there directly
cvtest::addDataSearchPath(dnnDataPath);
cvtest::addDataSearchPath(dnnDataPath + std::string("/omz_intel_models"));
}
initialized = true;
}
#endif // WINRT
}
static const std::string SUBDIR = "intel/age-gender-recognition-retail-0013/FP32/";
// FIXME: taken from the DNN module
void normAssert(cv::InputArray ref, cv::InputArray test,
const char *comment /*= ""*/,
double l1 = 0.00001, double lInf = 0.0001) {
double normL1 = cvtest::norm(ref, test, cv::NORM_L1) / ref.getMat().total();
EXPECT_LE(normL1, l1) << comment;
double normInf = cvtest::norm(ref, test, cv::NORM_INF);
EXPECT_LE(normInf, lInf) << comment;
}
// TODO: AGNetGenComp, AGNetTypedComp, AGNetOVComp, AGNetOVCompiled
// can be generalized to work with any model and used as parameters for tests.
struct AGNetGenParams {
static constexpr const char* tag = "age-gender-generic";
using Params = cv::gapi::ov::Params<cv::gapi::Generic>;
static Params params(const std::string &xml,
const std::string &bin,
const std::string &device) {
return {tag, xml, bin, device};
}
static Params params(const std::string &blob_path,
const std::string &device) {
return {tag, blob_path, device};
}
};
struct AGNetTypedParams {
using AGInfo = std::tuple<cv::GMat, cv::GMat>;
G_API_NET(AgeGender, <AGInfo(cv::GMat)>, "typed-age-gender");
using Params = cv::gapi::ov::Params<AgeGender>;
static Params params(const std::string &xml_path,
const std::string &bin_path,
const std::string &device) {
return Params {
xml_path, bin_path, device
}.cfgOutputLayers({ "age_conv3", "prob" });
}
};
struct AGNetTypedComp : AGNetTypedParams {
static cv::GComputation create() {
cv::GMat in;
cv::GMat age, gender;
std::tie(age, gender) = cv::gapi::infer<AgeGender>(in);
return cv::GComputation{cv::GIn(in), cv::GOut(age, gender)};
}
};
struct AGNetGenComp : public AGNetGenParams {
static cv::GComputation create() {
cv::GMat in;
GInferInputs inputs;
inputs["data"] = in;
auto outputs = cv::gapi::infer<cv::gapi::Generic>(tag, inputs);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
return cv::GComputation{cv::GIn(in), cv::GOut(age, gender)};
}
};
struct AGNetROIGenComp : AGNetGenParams {
static cv::GComputation create() {
cv::GMat in;
cv::GOpaque<cv::Rect> roi;
GInferInputs inputs;
inputs["data"] = in;
auto outputs = cv::gapi::infer<cv::gapi::Generic>(tag, roi, inputs);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
return cv::GComputation{cv::GIn(in, roi), cv::GOut(age, gender)};
}
};
struct AGNetListGenComp : AGNetGenParams {
static cv::GComputation create() {
cv::GMat in;
cv::GArray<cv::Rect> rois;
GInferInputs inputs;
inputs["data"] = in;
auto outputs = cv::gapi::infer<cv::gapi::Generic>(tag, rois, inputs);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
return cv::GComputation{cv::GIn(in, rois), cv::GOut(age, gender)};
}
};
struct AGNetList2GenComp : AGNetGenParams {
static cv::GComputation create() {
cv::GMat in;
cv::GArray<cv::Rect> rois;
GInferListInputs list;
list["data"] = rois;
auto outputs = cv::gapi::infer2<cv::gapi::Generic>(tag, in, list);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
return cv::GComputation{cv::GIn(in, rois), cv::GOut(age, gender)};
}
};
class AGNetOVCompiled {
public:
AGNetOVCompiled(ov::CompiledModel &&compiled_model)
: m_compiled_model(std::move(compiled_model)),
m_infer_request(m_compiled_model.create_infer_request()) {
}
void operator()(const cv::Mat &in_mat,
const cv::Rect &roi,
cv::Mat &age_mat,
cv::Mat &gender_mat) {
// FIXME: W & H could be extracted from model shape
// but it's anyway used only for Age Gender model.
// (Well won't work in case of reshape)
const int W = 62;
const int H = 62;
cv::Mat resized_roi;
cv::resize(in_mat(roi), resized_roi, cv::Size(W, H));
(*this)(resized_roi, age_mat, gender_mat);
}
void operator()(const cv::Mat &in_mat,
const std::vector<cv::Rect> &rois,
std::vector<cv::Mat> &age_mats,
std::vector<cv::Mat> &gender_mats) {
for (size_t i = 0; i < rois.size(); ++i) {
(*this)(in_mat, rois[i], age_mats[i], gender_mats[i]);
}
}
void operator()(const cv::Mat &in_mat,
cv::Mat &age_mat,
cv::Mat &gender_mat) {
auto input_tensor = m_infer_request.get_input_tensor();
cv::gapi::ov::util::to_ov(in_mat, input_tensor);
m_infer_request.infer();
auto age_tensor = m_infer_request.get_tensor("age_conv3");
age_mat.create(cv::gapi::ov::util::to_ocv(age_tensor.get_shape()),
cv::gapi::ov::util::to_ocv(age_tensor.get_element_type()));
cv::gapi::ov::util::to_ocv(age_tensor, age_mat);
auto gender_tensor = m_infer_request.get_tensor("prob");
gender_mat.create(cv::gapi::ov::util::to_ocv(gender_tensor.get_shape()),
cv::gapi::ov::util::to_ocv(gender_tensor.get_element_type()));
cv::gapi::ov::util::to_ocv(gender_tensor, gender_mat);
}
void export_model(const std::string &outpath) {
std::ofstream file{outpath, std::ios::out | std::ios::binary};
GAPI_Assert(file.is_open());
m_compiled_model.export_model(file);
}
private:
ov::CompiledModel m_compiled_model;
ov::InferRequest m_infer_request;
};
struct ImageInputPreproc {
void operator()(ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_layout(ov::Layout("NHWC"))
.set_element_type(ov::element::u8)
.set_shape({1, size.height, size.width, 3});
ppp.input().model().set_layout(ov::Layout("NCHW"));
ppp.input().preprocess().resize(::ov::preprocess::ResizeAlgorithm::RESIZE_LINEAR);
}
cv::Size size;
};
class AGNetOVComp {
public:
AGNetOVComp(const std::string &xml_path,
const std::string &bin_path,
const std::string &device)
: m_device(device) {
m_model = cv::gapi::ov::wrap::getCore()
.read_model(xml_path, bin_path);
}
using PrePostProcessF = std::function<void(ov::preprocess::PrePostProcessor&)>;
void cfgPrePostProcessing(PrePostProcessF f) {
ov::preprocess::PrePostProcessor ppp(m_model);
f(ppp);
m_model = ppp.build();
}
AGNetOVCompiled compile() {
auto compiled_model = cv::gapi::ov::wrap::getCore()
.compile_model(m_model, m_device);
return {std::move(compiled_model)};
}
void apply(const cv::Mat &in_mat,
cv::Mat &age_mat,
cv::Mat &gender_mat) {
compile()(in_mat, age_mat, gender_mat);
}
private:
std::string m_device;
std::shared_ptr<ov::Model> m_model;
};
struct BaseAgeGenderOV: public ::testing::Test {
BaseAgeGenderOV() {
initDLDTDataPath();
xml_path = findDataFile(SUBDIR + "age-gender-recognition-retail-0013.xml", false);
bin_path = findDataFile(SUBDIR + "age-gender-recognition-retail-0013.bin", false);
device = "CPU";
blob_path = "age-gender-recognition-retail-0013.blob";
}
cv::Mat getRandomImage(const cv::Size &sz) {
cv::Mat image(sz, CV_8UC3);
cv::randu(image, 0, 255);
return image;
}
cv::Mat getRandomTensor(const std::vector<int> &dims,
const int depth) {
cv::Mat tensor(dims, depth);
cv::randu(tensor, -1, 1);
return tensor;
}
std::string xml_path;
std::string bin_path;
std::string blob_path;
std::string device;
};
struct TestAgeGenderOV : public BaseAgeGenderOV {
cv::Mat ov_age, ov_gender, gapi_age, gapi_gender;
void validate() {
normAssert(ov_age, gapi_age, "Test age output" );
normAssert(ov_gender, gapi_gender, "Test gender output");
}
};
struct TestAgeGenderListOV : public BaseAgeGenderOV {
std::vector<cv::Mat> ov_age, ov_gender,
gapi_age, gapi_gender;
std::vector<cv::Rect> roi_list = {
cv::Rect(cv::Point{64, 60}, cv::Size{ 96, 96}),
cv::Rect(cv::Point{50, 32}, cv::Size{128, 160}),
};
TestAgeGenderListOV() {
ov_age.resize(roi_list.size());
ov_gender.resize(roi_list.size());
gapi_age.resize(roi_list.size());
gapi_gender.resize(roi_list.size());
}
void validate() {
ASSERT_EQ(ov_age.size(), ov_gender.size());
ASSERT_EQ(ov_age.size(), gapi_age.size());
ASSERT_EQ(ov_gender.size(), gapi_gender.size());
for (size_t i = 0; i < ov_age.size(); ++i) {
normAssert(ov_age[i], gapi_age[i], "Test age output");
normAssert(ov_gender[i], gapi_gender[i], "Test gender output");
}
}
};
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});
}
};
struct MediaFrameTestAgeGenderOV: public ::testing::Test {
MediaFrameTestAgeGenderOV() {
initDLDTDataPath();
xml_path = findDataFile(SUBDIR + "age-gender-recognition-retail-0013.xml", false);
bin_path = findDataFile(SUBDIR + "age-gender-recognition-retail-0013.bin", false);
device = "CPU";
blob_path = "age-gender-recognition-retail-0013.blob";
cv::Size sz{62, 62};
m_in_mat = cv::Mat(sz, CV_8UC3);
cv::resize(m_in_mat, m_in_mat, sz);
m_in_y = cv::Mat{sz, CV_8UC1};
cv::randu(m_in_y, 0, 255);
m_in_uv = cv::Mat{sz / 2, CV_8UC2};
cv::randu(m_in_uv, 0, 255);
}
cv::Mat m_in_y;
cv::Mat m_in_uv;
cv::Mat m_in_mat;
cv::Mat m_out_ov_age;
cv::Mat m_out_ov_gender;
cv::Mat m_out_gapi_age;
cv::Mat m_out_gapi_gender;
std::string xml_path;
std::string bin_path;
std::string blob_path;
std::string device;
std::string image_path;
using AGInfo = std::tuple<cv::GMat, cv::GMat>;
G_API_NET(AgeGender, <AGInfo(cv::GMat)>, "typed-age-gender");
void validate() {
normAssert(m_out_ov_age, m_out_gapi_age, "0: Test age output");
normAssert(m_out_ov_gender, m_out_gapi_gender, "0: Test gender output");
}
}; // MediaFrameTestAgeGenderOV
} // anonymous namespace
TEST_F(MediaFrameTestAgeGenderOV, InferMediaInputBGR)
{
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_element_type(ov::element::u8);
ppp.input().tensor().set_layout("NHWC");
});
ref.compile()(m_in_mat, m_out_ov_age, m_out_ov_gender);
// G-API
cv::GFrame in;
cv::GMat age, gender;
std::tie(age, gender) = cv::gapi::infer<AgeGender>(in);
cv::GComputation comp{cv::GIn(in), cv::GOut(age, gender)};
auto frame = MediaFrame::Create<TestMediaBGR>(m_in_mat);
auto pp = cv::gapi::ov::Params<AgeGender> {
xml_path, bin_path, device
}.cfgOutputLayers({ "age_conv3", "prob" });
comp.apply(cv::gin(frame),
cv::gout(m_out_gapi_age, m_out_gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
validate();
}
TEST_F(MediaFrameTestAgeGenderOV, InferROIGenericMediaInputBGR) {
// OpenVINO
cv::Rect roi(cv::Rect(cv::Point{20, 25}, cv::Size{16, 16}));
auto frame = MediaFrame::Create<TestMediaBGR>(m_in_mat);
static constexpr const char* tag = "age-gender-generic";
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_element_type(ov::element::u8);
ppp.input().tensor().set_layout("NHWC");
});
ref.compile()(m_in_mat, roi, m_out_ov_age, m_out_ov_gender);
// G-API
cv::GFrame in;
cv::GOpaque<cv::Rect> rr;
GInferInputs inputs;
inputs["data"] = in;
auto outputs = cv::gapi::infer<cv::gapi::Generic>(tag, rr, inputs);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
cv::GComputation comp{cv::GIn(in, rr), cv::GOut(age, gender)};
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(frame, roi), cv::gout(m_out_gapi_age, m_out_gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
validate();
}
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));
}
};
TEST_F(MediaFrameTestAgeGenderOV, TestMediaNV12AgeGenderOV)
{
cv::GFrame in;
cv::GOpaque<cv::Rect> rr;
GInferInputs inputs;
inputs["data"] = in;
static constexpr const char* tag = "age-gender-generic";
auto outputs = cv::gapi::infer<cv::gapi::Generic>(tag, rr, inputs);
auto age = outputs.at("age_conv3");
auto gender = outputs.at("prob");
cv::GComputation comp{cv::GIn(in, rr), cv::GOut(age, gender)};
auto frame = MediaFrame::Create<TestMediaNV12>(m_in_y, m_in_uv);
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
cv::Rect roi(cv::Rect(cv::Point{20, 25}, cv::Size{16, 16}));
EXPECT_NO_THROW(comp.apply(cv::gin(frame, roi),
cv::gout(m_out_gapi_age, m_out_gapi_gender),
cv::compile_args(cv::gapi::networks(pp))));
}
// TODO: Make all of tests below parmetrized to avoid code duplication
TEST_F(TestAgeGenderOV, Infer_Tensor) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetTypedComp::create();
auto pp = AGNetTypedComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, Infer_Image) {
const auto in_mat = getRandomImage({300, 300});
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing(ImageInputPreproc{in_mat.size()});
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetTypedComp::create();
auto pp = AGNetTypedComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_Tensor) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGenericImage) {
const auto in_mat = getRandomImage({300, 300});
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing(ImageInputPreproc{in_mat.size()});
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_ImageBlob) {
const auto in_mat = getRandomImage({300, 300});
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing(ImageInputPreproc{in_mat.size()});
auto cc_ref = ref.compile();
// NB: Output blob will contain preprocessing inside.
cc_ref.export_model(blob_path);
cc_ref(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(blob_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_TensorBlob) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
auto cc_ref = ref.compile();
cc_ref.export_model(blob_path);
cc_ref(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(blob_path, device);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_BothOutputsFP16) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp){
ppp.output(0).tensor().set_element_type(ov::element::f16);
ppp.output(1).tensor().set_element_type(ov::element::f16);
});
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(xml_path, bin_path, device);
pp.cfgOutputTensorPrecision(CV_16F);
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_OneOutputFP16) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
// OpenVINO
const std::string fp16_output_name = "prob";
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([&](ov::preprocess::PrePostProcessor &ppp){
ppp.output(fp16_output_name).tensor().set_element_type(ov::element::f16);
});
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(xml_path, bin_path, device);
pp.cfgOutputTensorPrecision({{fp16_output_name, CV_16F}});
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferGeneric_ThrowCfgOutputPrecForBlob) {
// OpenVINO (Just for blob compilation)
AGNetOVComp ref(xml_path, bin_path, device);
auto cc_ref = ref.compile();
cc_ref.export_model(blob_path);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(blob_path, device);
EXPECT_ANY_THROW(pp.cfgOutputTensorPrecision(CV_16F));
}
TEST_F(TestAgeGenderOV, InferGeneric_ThrowInvalidConfigIR) {
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(xml_path, bin_path, device);
pp.cfgPluginConfig({{"some_key", "some_value"}});
EXPECT_ANY_THROW(comp.compile(cv::GMatDesc{CV_8U,3,cv::Size{320, 240}},
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderOV, InferGeneric_ThrowInvalidConfigBlob) {
// OpenVINO (Just for blob compilation)
AGNetOVComp ref(xml_path, bin_path, device);
auto cc_ref = ref.compile();
cc_ref.export_model(blob_path);
// G-API
auto comp = AGNetGenComp::create();
auto pp = AGNetGenComp::params(blob_path, device);
pp.cfgPluginConfig({{"some_key", "some_value"}});
EXPECT_ANY_THROW(comp.compile(cv::GMatDesc{CV_8U,3,cv::Size{320, 240}},
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderOV, Infer_ThrowInvalidImageLayout) {
const auto in_mat = getRandomImage({300, 300});
auto comp = AGNetTypedComp::create();
auto pp = AGNetTypedComp::params(xml_path, bin_path, device);
pp.cfgInputTensorLayout("NCHW");
EXPECT_ANY_THROW(comp.compile(cv::descr_of(in_mat),
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderOV, Infer_TensorWithPreproc) {
const auto in_mat = getRandomTensor({1, 240, 320, 3}, CV_32F);
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
auto& input = ppp.input();
input.tensor().set_spatial_static_shape(240, 320)
.set_layout("NHWC");
input.preprocess().resize(ov::preprocess::ResizeAlgorithm::RESIZE_LINEAR);
});
ref.apply(in_mat, ov_age, ov_gender);
// G-API
auto comp = AGNetTypedComp::create();
auto pp = AGNetTypedComp::params(xml_path, bin_path, device);
pp.cfgResize(cv::INTER_LINEAR)
.cfgInputTensorLayout("NHWC");
comp.apply(cv::gin(in_mat), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferROIGeneric_Image) {
const auto in_mat = getRandomImage({300, 300});
cv::Rect roi(cv::Rect(cv::Point{64, 60}, cv::Size{96, 96}));
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_element_type(ov::element::u8);
ppp.input().tensor().set_layout("NHWC");
});
ref.compile()(in_mat, roi, ov_age, ov_gender);
// G-API
auto comp = AGNetROIGenComp::create();
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat, roi), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderOV, InferROIGeneric_ThrowIncorrectLayout) {
const auto in_mat = getRandomImage({300, 300});
cv::Rect roi(cv::Rect(cv::Point{64, 60}, cv::Size{96, 96}));
// G-API
auto comp = AGNetROIGenComp::create();
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
pp.cfgInputTensorLayout("NCHW");
EXPECT_ANY_THROW(comp.apply(cv::gin(in_mat, roi), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderOV, InferROIGeneric_ThrowTensorInput) {
const auto in_mat = getRandomTensor({1, 3, 62, 62}, CV_32F);
cv::Rect roi(cv::Rect(cv::Point{64, 60}, cv::Size{96, 96}));
// G-API
auto comp = AGNetROIGenComp::create();
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
EXPECT_ANY_THROW(comp.apply(cv::gin(in_mat, roi), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderOV, InferROIGeneric_ThrowExplicitResize) {
const auto in_mat = getRandomImage({300, 300});
cv::Rect roi(cv::Rect(cv::Point{64, 60}, cv::Size{96, 96}));
// G-API
auto comp = AGNetROIGenComp::create();
auto pp = AGNetROIGenComp::params(xml_path, bin_path, device);
pp.cfgResize(cv::INTER_LINEAR);
EXPECT_ANY_THROW(comp.apply(cv::gin(in_mat, roi), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp))));
}
TEST_F(TestAgeGenderListOV, InferListGeneric_Image) {
const auto in_mat = getRandomImage({300, 300});
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_element_type(ov::element::u8);
ppp.input().tensor().set_layout("NHWC");
});
ref.compile()(in_mat, roi_list, ov_age, ov_gender);
// G-API
auto comp = AGNetListGenComp::create();
auto pp = AGNetListGenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat, roi_list), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
TEST_F(TestAgeGenderListOV, InferList2Generic_Image) {
const auto in_mat = getRandomImage({300, 300});
// OpenVINO
AGNetOVComp ref(xml_path, bin_path, device);
ref.cfgPrePostProcessing([](ov::preprocess::PrePostProcessor &ppp) {
ppp.input().tensor().set_element_type(ov::element::u8);
ppp.input().tensor().set_layout("NHWC");
});
ref.compile()(in_mat, roi_list, ov_age, ov_gender);
// G-API
auto comp = AGNetList2GenComp::create();
auto pp = AGNetList2GenComp::params(xml_path, bin_path, device);
comp.apply(cv::gin(in_mat, roi_list), cv::gout(gapi_age, gapi_gender),
cv::compile_args(cv::gapi::networks(pp)));
// Assert
validate();
}
static ov::element::Type toOV(int depth) {
switch (depth) {
case CV_8U: return ov::element::u8;
case CV_32S: return ov::element::i32;
case CV_32F: return ov::element::f32;
case CV_16F: return ov::element::f16;
default: GAPI_Error("OV Backend: Unsupported data type");
}
return ov::element::undefined;
}
struct TestMeanScaleOV : public ::testing::TestWithParam<int>{
G_API_NET(IdentityNet, <cv::GMat(cv::GMat)>, "test-identity-net");
static cv::GComputation create() {
cv::GMat in;
cv::GMat out;
out = cv::gapi::infer<IdentityNet>(in);
return cv::GComputation{cv::GIn(in), cv::GOut(out)};
}
using Params = cv::gapi::ov::Params<IdentityNet>;
static Params params(const std::string &xml_path,
const std::string &bin_path,
const std::string &device) {
return Params {
xml_path, bin_path, device
}.cfgInputModelLayout("NHWC")
.cfgOutputLayers({ "output" });
}
TestMeanScaleOV() {
initDLDTDataPath();
m_model_path = findDataFile("gapi/ov/identity_net_100x100.xml");
m_weights_path = findDataFile("gapi/ov/identity_net_100x100.bin");
m_device_id = "CPU";
m_ov_model = cv::gapi::ov::wrap::getCore()
.read_model(m_model_path, m_weights_path);
auto input_depth = GetParam();
auto input = cv::imread(findDataFile("gapi/gapi_logo.jpg"));
input.convertTo(m_in_mat, input_depth);
}
void addPreprocToOV(
std::function<void(ov::preprocess::PrePostProcessor&)> f) {
auto input_depth = GetParam();
ov::preprocess::PrePostProcessor ppp(m_ov_model);
ppp.input().tensor().set_layout(ov::Layout("NHWC"))
.set_element_type(toOV(input_depth))
.set_shape({ 1, 100, 100, 3 });
ppp.input().model().set_layout(ov::Layout("NHWC"));
f(ppp);
m_ov_model = ppp.build();
}
void runOV() {
auto compiled_model = cv::gapi::ov::wrap::getCore()
.compile_model(m_ov_model, m_device_id);
auto infer_request = compiled_model.create_infer_request();
auto input_tensor = infer_request.get_input_tensor();
cv::gapi::ov::util::to_ov(m_in_mat, input_tensor);
infer_request.infer();
auto out_tensor = infer_request.get_tensor("output");
m_out_mat_ov.create(cv::gapi::ov::util::to_ocv(out_tensor.get_shape()),
cv::gapi::ov::util::to_ocv(out_tensor.get_element_type()));
cv::gapi::ov::util::to_ocv(out_tensor, m_out_mat_ov);
}
std::string m_model_path;
std::string m_weights_path;
std::string m_device_id;
std::shared_ptr<ov::Model> m_ov_model;
cv::Mat m_in_mat;
cv::Mat m_out_mat_gapi;
cv::Mat m_out_mat_ov;
};
TEST_P(TestMeanScaleOV, Mean)
{
int input_depth = GetParam();
std::vector<float> mean_values{ 220.1779, 218.9857, 217.8986 };
// Run OV reference pipeline:
{
addPreprocToOV([&](ov::preprocess::PrePostProcessor& ppp) {
if (input_depth == CV_8U || input_depth == CV_32S) {
ppp.input().preprocess().convert_element_type(ov::element::f32);
}
ppp.input().preprocess().mean(mean_values);
});
runOV();
}
// Run G-API
GComputation comp = create();
auto pp = params(m_model_path, m_weights_path, m_device_id);
pp.cfgMean(mean_values);
comp.apply(cv::gin(m_in_mat), cv::gout(m_out_mat_gapi),
cv::compile_args(cv::gapi::networks(pp)));
// Validate OV results against G-API ones:
normAssert(m_out_mat_ov, m_out_mat_gapi, "Test output");
}
TEST_P(TestMeanScaleOV, Scale)
{
int input_depth = GetParam();
std::vector<float> scale_values{ 2., 2., 2. };
// Run OV reference pipeline:
{
addPreprocToOV([&](ov::preprocess::PrePostProcessor& ppp) {
if (input_depth == CV_8U || input_depth == CV_32S) {
ppp.input().preprocess().convert_element_type(ov::element::f32);
}
ppp.input().preprocess().scale(scale_values);
});
runOV();
}
// Run G-API
GComputation comp = create();
auto pp = params(m_model_path, m_weights_path, m_device_id);
pp.cfgScale(scale_values);
comp.apply(cv::gin(m_in_mat), cv::gout(m_out_mat_gapi),
cv::compile_args(cv::gapi::networks(pp)));
// Validate OV results against G-API ones:
normAssert(m_out_mat_ov, m_out_mat_gapi, "Test output");
}
TEST_P(TestMeanScaleOV, MeanAndScale)
{
int input_depth = GetParam();
std::vector<float> mean_values{ 220.1779, 218.9857, 217.8986 };
std::vector<float> scale_values{ 2., 2., 2. };
// Run OV reference pipeline:
{
addPreprocToOV([&](ov::preprocess::PrePostProcessor& ppp) {
if (input_depth == CV_8U || input_depth == CV_32S) {
ppp.input().preprocess().convert_element_type(ov::element::f32);
}
ppp.input().preprocess().mean(mean_values);
ppp.input().preprocess().scale(scale_values);
});
runOV();
}
// Run G-API
GComputation comp = create();
auto pp = params(m_model_path, m_weights_path, m_device_id);
pp.cfgMean(mean_values);
pp.cfgScale(scale_values);
comp.apply(cv::gin(m_in_mat), cv::gout(m_out_mat_gapi),
cv::compile_args(cv::gapi::networks(pp)));
// Validate OV results against G-API ones:
normAssert(m_out_mat_ov, m_out_mat_gapi, "Test output");
}
INSTANTIATE_TEST_CASE_P(Instantiation, TestMeanScaleOV,
Values(CV_8U, CV_32S, CV_16F, CV_32F));
} // namespace opencv_test
#endif // HAVE_INF_ENGINE && INF_ENGINE_RELEASE >= 2022010000
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