Open Source Computer Vision Library https://opencv.org/
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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) 2018 Intel Corporation
#include "test_precomp.hpp"
#include "opencv2/gapi/core.hpp"
#include "opencv2/gapi/fluid/gfluidbuffer.hpp"
#include "opencv2/gapi/fluid/gfluidkernel.hpp"
// FIXME: move these tests with priv() to internal suite
#include "backends/fluid/gfluidbuffer_priv.hpp"
#include "gapi_fluid_test_kernels.hpp"
#include "logger.hpp"
namespace opencv_test
{
using namespace cv::gapi_test_kernels;
namespace
{
void WriteFunction(uint8_t* row, int nr, int w) {
for (int i = 0; i < w; i++)
row[i] = static_cast<uint8_t>(nr+i);
};
void ReadFunction1x1(const uint8_t* row, int w) {
for (int i = 0; i < w; i++)
std::cout << std::setw(4) << static_cast<int>(row[i]) << " ";
std::cout << "\n";
};
void ReadFunction3x3(const uint8_t* rows[3], int w) {
for (int i = 0; i < 3; i++) {
for (int j = -1; j < w+1; j++) {
std::cout << std::setw(4) << static_cast<int>(rows[i][j]) << " ";
}
std::cout << "\n";
}
std::cout << "\n";
};
}
TEST(FluidBuffer, InputTest)
{
const cv::Size buffer_size = {8,8};
cv::Mat in_mat = cv::Mat::eye(buffer_size, CV_8U);
cv::gapi::fluid::Buffer buffer(to_own(in_mat), true);
cv::gapi::fluid::View view = buffer.mkView(1, 0, {}, false);
view.priv().reset(1);
int this_y = 0;
while (this_y < buffer_size.height)
{
const uint8_t* rrow = view.InLine<uint8_t>(0);
ReadFunction1x1(rrow, buffer_size.width);
view.priv().readDone(1,1);
cv::Mat from_buffer(1, buffer_size.width, CV_8U, const_cast<uint8_t*>(rrow));
EXPECT_EQ(0, cv::countNonZero(in_mat.row(this_y) != from_buffer));
this_y++;
}
}
TEST(FluidBuffer, CircularTest)
{
const cv::Size buffer_size = {8,16};
cv::gapi::fluid::Buffer buffer(cv::GMatDesc{CV_8U,1,buffer_size}, 3, 1, 0, 1,
util::make_optional(cv::gapi::fluid::Border{cv::BORDER_CONSTANT, cv::gapi::own::Scalar(255)}));
cv::gapi::fluid::View view = buffer.mkView(3, 1, {}, false);
view.priv().reset(3);
buffer.debug(std::cout);
const auto whole_line_is = [](const uint8_t *line, int len, int value)
{
return std::all_of(line, line+len, [&](const uint8_t v){return v == value;});
};
// Store all read/written data in separate Mats to compare with
cv::Mat written_data(buffer_size, CV_8U);
// Simulate write/read process
int num_reads = 0, num_writes = 0;
while (num_reads < buffer_size.height)
{
if (num_writes < buffer_size.height)
{
uint8_t* wrow = buffer.OutLine<uint8_t>();
WriteFunction(wrow, num_writes, buffer_size.width);
buffer.priv().writeDone();
cv::Mat(1, buffer_size.width, CV_8U, wrow)
.copyTo(written_data.row(num_writes));
num_writes++;
}
buffer.debug(std::cout);
if (view.ready())
{
view.priv().prepareToRead();
const uint8_t* rrow[3] = {
view.InLine<uint8_t>(-1),
view.InLine<uint8_t>( 0),
view.InLine<uint8_t>( 1),
};
ReadFunction3x3(rrow, buffer_size.width);
view.priv().readDone(1,3);
buffer.debug(std::cout);
// Check borders right here
EXPECT_EQ(255u, rrow[0][-1]);
EXPECT_EQ(255u, rrow[0][buffer_size.width]);
if (num_reads == 0)
{
EXPECT_TRUE(whole_line_is(rrow[0]-1, buffer_size.width+2, 255u));
}
if (num_reads == buffer_size.height-1)
{
EXPECT_TRUE(whole_line_is(rrow[2]-1, buffer_size.width+2, 255u));
}
// Check window (without borders)
if (num_reads > 0 && num_reads < buffer_size.height-1)
{
// +1 everywhere since num_writes was just incremented above
cv::Mat written_lastLine2 = written_data.row(num_writes - (2+1));
cv::Mat written_lastLine1 = written_data.row(num_writes - (1+1));
cv::Mat written_lastLine0 = written_data.row(num_writes - (0+1));
cv::Mat read_prevLine(1, buffer_size.width, CV_8U, const_cast<uint8_t*>(rrow[0]));
cv::Mat read_thisLine(1, buffer_size.width, CV_8U, const_cast<uint8_t*>(rrow[1]));
cv::Mat read_nextLine(1, buffer_size.width, CV_8U, const_cast<uint8_t*>(rrow[2]));
EXPECT_EQ(0, cv::countNonZero(written_lastLine2 != read_prevLine));
EXPECT_EQ(0, cv::countNonZero(written_lastLine1 != read_thisLine));
EXPECT_EQ(0, cv::countNonZero(written_lastLine0 != read_nextLine));
}
num_reads++;
}
}
}
TEST(FluidBuffer, OutputTest)
{
const cv::Size buffer_size = {8,16};
cv::Mat out_mat = cv::Mat(buffer_size, CV_8U);
cv::gapi::fluid::Buffer buffer(to_own(out_mat), false);
int num_writes = 0;
while (num_writes < buffer_size.height)
{
uint8_t* wrow = buffer.OutLine<uint8_t>();
WriteFunction(wrow, num_writes, buffer_size.width);
buffer.priv().writeDone();
num_writes++;
}
GAPI_LOG_INFO(NULL, "\n" << out_mat);
// Validity check
for (int r = 0; r < buffer_size.height; r++)
{
for (int c = 0; c < buffer_size.width; c++)
{
EXPECT_EQ(r+c, out_mat.at<uint8_t>(r, c));
}
}
}
TEST(Fluid, AddC_WithScalar)
{
cv::GMat in;
cv::GScalar s;
cv::GComputation c(cv::GIn(in, s), cv::GOut(TAddScalar::on(in, s)));
cv::Mat in_mat = cv::Mat::eye(3, 3, CV_8UC1), out_mat(3, 3, CV_8UC1), ref_mat;
cv::Scalar in_s(100);
auto cc = c.compile(cv::descr_of(in_mat), cv::descr_of(in_s), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_mat, in_s), cv::gout(out_mat));
ref_mat = in_mat + in_s;
EXPECT_EQ(0, cv::countNonZero(out_mat != ref_mat));
}
TEST(Fluid, Scalar_In_Middle_Graph)
{
cv::GMat in;
cv::GScalar s;
cv::GComputation c(cv::GIn(in, s), cv::GOut(TAddScalar::on(TAddCSimple::on(in, 5), s)));
cv::Mat in_mat = cv::Mat::eye(3, 3, CV_8UC1), out_mat(3, 3, CV_8UC1), ref_mat;
cv::Scalar in_s(100);
auto cc = c.compile(cv::descr_of(in_mat), cv::descr_of(in_s), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_mat, in_s), cv::gout(out_mat));
ref_mat = (in_mat + 5) + in_s;
EXPECT_EQ(0, cv::countNonZero(out_mat != ref_mat));
}
TEST(Fluid, Add_Scalar_To_Mat)
{
cv::GMat in;
cv::GScalar s;
cv::GComputation c(cv::GIn(s, in), cv::GOut(TAddScalarToMat::on(s, in)));
cv::Mat in_mat = cv::Mat::eye(3, 3, CV_8UC1), out_mat(3, 3, CV_8UC1), ref_mat;
cv::Scalar in_s(100);
auto cc = c.compile(cv::descr_of(in_s), cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_s, in_mat), cv::gout(out_mat));
ref_mat = in_mat + in_s;
EXPECT_EQ(0, cv::countNonZero(out_mat != ref_mat));
}
TEST(Fluid, Sum_2_Mats_And_Scalar)
{
cv::GMat a, b;
cv::GScalar s;
cv::GComputation c(cv::GIn(a, s, b), cv::GOut(TSum2MatsAndScalar::on(a, s, b)));
cv::Mat in_mat1 = cv::Mat::eye(3, 3, CV_8UC1),
in_mat2 = cv::Mat::eye(3, 3, CV_8UC1),
out_mat(3, 3, CV_8UC1),
ref_mat;
cv::Scalar in_s(100);
auto cc = c.compile(cv::descr_of(in_mat1), cv::descr_of(in_s), cv::descr_of(in_mat2), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_mat1, in_s, in_mat2), cv::gout(out_mat));
ref_mat = in_mat1 + in_mat2 + in_s;
EXPECT_EQ(0, cv::countNonZero(out_mat != ref_mat));
}
TEST(Fluid, Split3)
{
cv::GMat bgr;
cv::GMat r,g,b;
std::tie(b,g,r) = cv::gapi::split3(bgr);
auto rr = TAddSimple::on(r, TId::on(b));
auto rrr = TAddSimple::on(TId::on(rr), g);
cv::GComputation c(bgr, TId::on(rrr));
cv::Size sz(5120, 5120);
cv::Mat eye_1 = cv::Mat::eye(sz, CV_8UC1);
std::vector<cv::Mat> eyes = {eye_1, eye_1, eye_1};
cv::Mat in_mat;
cv::merge(eyes, in_mat);
cv::Mat out_mat(sz, CV_8UC1);
// G-API
auto cc = c.compile(cv::descr_of(in_mat),
cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat);
// OCV
std::vector<cv::Mat> chans;
cv::split(in_mat, chans);
// Compare
EXPECT_EQ(0, cv::countNonZero(out_mat != (chans[2]*3)));
}
TEST(Fluid, ScratchTest)
{
cv::GMat in;
cv::GMat out = TPlusRow0::on(TPlusRow0::on(in));
cv::GComputation c(in, out);
cv::Size sz(8, 8);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat(sz, CV_8UC1);
// OpenCV (reference)
cv::Mat ref;
{
cv::Mat first_row = cv::Mat::zeros(1, sz.width, CV_8U);
cv::Mat remaining = cv::repeat(in_mat.row(0), sz.height-1, 1);
cv::Mat operand;
cv::vconcat(first_row, 2*remaining, operand);
ref = in_mat + operand;
}
GAPI_LOG_INFO(NULL, "\n" << ref);
// G-API
auto cc = c.compile(cv::descr_of(in_mat),
cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat);
GAPI_LOG_INFO(NULL, "\n" << out_mat);
EXPECT_EQ(0, cv::countNonZero(ref != out_mat));
cc(in_mat, out_mat);
GAPI_LOG_INFO(NULL, "\n" << out_mat);
EXPECT_EQ(0, cv::countNonZero(ref != out_mat));
}
TEST(Fluid, MultipleOutRowsTest)
{
cv::GMat in;
cv::GMat out = TAddCSimple::on(TAddCSimple::on(in, 1), 2);
cv::GComputation c(in, out);
cv::Size sz(4, 4);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat(sz, CV_8UC1);
auto cc = c.compile(cv::descr_of(in_mat),
cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat);
std::cout << out_mat << std::endl;
cv::Mat ocv_ref = in_mat + 1 + 2;
EXPECT_EQ(0, cv::countNonZero(ocv_ref != out_mat));
}
TEST(Fluid, LPIWindow)
{
cv::GMat in;
cv::GMat r,g,b;
std::tie(r,g,b) = cv::gapi::split3(in);
cv::GMat rr = TId7x7::on(r);
cv::GMat tmp = TAddSimple::on(rr, g);
cv::GMat out = TAddSimple::on(tmp, b);
cv::GComputation c(in, out);
cv::Size sz(8, 8);
cv::Mat eye_1 = cv::Mat::eye(sz, CV_8UC1);
std::vector<cv::Mat> eyes = {eye_1, eye_1, eye_1};
cv::Mat in_mat;
cv::merge(eyes, in_mat);
cv::Mat out_mat(sz, CV_8U);
auto cc = c.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat);
//std::cout << out_mat << std::endl;
// OpenCV reference
cv::Mat ocv_ref = eyes[0]+eyes[1]+eyes[2];
EXPECT_EQ(0, cv::countNonZero(ocv_ref != out_mat));
}
TEST(Fluid, MultipleReaders_SameLatency)
{
// in -> AddC -> a -> AddC -> b -> Add -> out
// '--> AddC -> c -'
//
// b and c have the same skew
cv::GMat in;
cv::GMat a = TAddCSimple::on(in, 1); // FIXME - align naming (G, non-G)
cv::GMat b = TAddCSimple::on(a, 2);
cv::GMat c = TAddCSimple::on(a, 3);
cv::GMat out = TAddSimple::on(b, c);
cv::GComputation comp(in, out);
const auto sz = cv::Size(32, 32);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat_gapi(sz, CV_8UC1);
cv::Mat out_mat_ocv (sz, CV_8UC1);
// Run G-API
auto cc = comp.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat_gapi);
// Check with OpenCV
cv::Mat tmp = in_mat + 1;
out_mat_ocv = (tmp+2) + (tmp+3);
EXPECT_EQ(0, cv::countNonZero(out_mat_gapi != out_mat_ocv));
}
TEST(Fluid, MultipleReaders_DifferentLatency)
{
// in1 -> AddC -> a -> AddC -------------> b -> Add -> out
// '--------------> Add --> c -'
// '--> Id7x7-> d -'
//
// b and c have different skew (due to latency introduced by Id7x7)
// a is ready by multiple views with different latency.
cv::GMat in;
cv::GMat a = TAddCSimple::on(in, 1); // FIXME - align naming (G, non-G)
cv::GMat b = TAddCSimple::on(a, 2);
cv::GMat d = TId7x7::on(a);
cv::GMat c = TAddSimple::on(a, d);
cv::GMat out = TAddSimple::on(b, c);
cv::GComputation comp(in, out);
const auto sz = cv::Size(32, 32);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat_gapi(sz, CV_8UC1);
// Run G-API
auto cc = comp.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat_gapi);
// Check with OpenCV
cv::Mat ocv_a = in_mat + 1;
cv::Mat ocv_b = ocv_a + 2;
cv::Mat ocv_d = ocv_a;
cv::Mat ocv_c = ocv_a + ocv_d;
cv::Mat out_mat_ocv = ocv_b + ocv_c;
EXPECT_EQ(0, cv::countNonZero(out_mat_gapi != out_mat_ocv));
}
TEST(Fluid, MultipleOutputs)
{
// in -> AddC -> a -> AddC ------------------> out1
// `--> Id7x7 --> b --> AddC -> out2
cv::GMat in;
cv::GMat a = TAddCSimple::on(in, 1);
cv::GMat b = TId7x7::on(a);
cv::GMat out1 = TAddCSimple::on(a, 2);
cv::GMat out2 = TAddCSimple::on(b, 7);
cv::GComputation comp(cv::GIn(in), cv::GOut(out1, out2));
const auto sz = cv::Size(32, 32);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat_gapi1(sz, CV_8UC1), out_mat_gapi2(sz, CV_8UC1);
cv::Mat out_mat_ocv1(sz, CV_8UC1), out_mat_ocv2(sz, CV_8UC1);
// Run G-API
auto cc = comp.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_mat), cv::gout(out_mat_gapi1, out_mat_gapi2));
// Check with OpenCV
out_mat_ocv1 = in_mat + 1 + 2;
out_mat_ocv2 = in_mat + 1 + 7;
EXPECT_EQ(0, cv::countNonZero(out_mat_gapi1 != out_mat_ocv1));
EXPECT_EQ(0, cv::countNonZero(out_mat_gapi2 != out_mat_ocv2));
}
TEST(Fluid, EmptyOutputMatTest)
{
cv::GMat in;
cv::GMat out = TAddCSimple::on(in, 2);
cv::GComputation c(in, out);
cv::Mat in_mat = cv::Mat::eye(cv::Size(32, 24), CV_8UC1);
cv::Mat out_mat;
auto cc = c.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(in_mat, out_mat);
EXPECT_EQ(CV_8UC1, out_mat.type());
EXPECT_EQ(32, out_mat.cols);
EXPECT_EQ(24, out_mat.rows);
EXPECT_TRUE(out_mat.ptr() != nullptr);
}
struct LPISequenceTest : public TestWithParam<int>{};
TEST_P(LPISequenceTest, LPISequenceTest)
{
// in -> AddC -> a -> Blur (2lpi) -> out
int kernelSize = GetParam();
cv::GMat in;
cv::GMat a = TAddCSimple::on(in, 1);
auto blur = kernelSize == 3 ? &TBlur3x3_2lpi::on : &TBlur5x5_2lpi::on;
cv::GMat out = blur(a, cv::BORDER_CONSTANT, cv::Scalar(0));
cv::GComputation comp(cv::GIn(in), cv::GOut(out));
const auto sz = cv::Size(8, 10);
cv::Mat in_mat = cv::Mat::eye(sz, CV_8UC1);
cv::Mat out_mat_gapi(sz, CV_8UC1);
cv::Mat out_mat_ocv(sz, CV_8UC1);
// Run G-API
auto cc = comp.compile(cv::descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(cv::gin(in_mat), cv::gout(out_mat_gapi));
// Check with OpenCV
cv::blur(in_mat + 1, out_mat_ocv, {kernelSize,kernelSize}, {-1,-1}, cv::BORDER_CONSTANT);
EXPECT_EQ(0, cv::countNonZero(out_mat_gapi != out_mat_ocv));
}
INSTANTIATE_TEST_CASE_P(Fluid, LPISequenceTest,
Values(3, 5));
struct InputImageBorderTest : public TestWithParam <std::tuple<int, int>> {};
TEST_P(InputImageBorderTest, InputImageBorderTest)
{
cv::Size sz_in = { 320, 240 };
int ks = 0;
int borderType = 0;
std::tie(ks, borderType) = GetParam();
cv::Mat in_mat1(sz_in, CV_8UC1);
cv::Scalar mean = cv::Scalar(127.0f);
cv::Scalar stddev = cv::Scalar(40.f);
cv::randn(in_mat1, mean, stddev);
cv::Size kernelSize = {ks, ks};
cv::Point anchor = {-1, -1};
cv::Scalar borderValue(0);
auto gblur = ks == 3 ? &TBlur3x3::on : &TBlur5x5::on;
GMat in;
auto out = gblur(in, borderType, borderValue);
Mat out_mat_gapi = Mat::zeros(sz_in, CV_8UC1);
GComputation c(GIn(in), GOut(out));
auto cc = c.compile(descr_of(in_mat1), cv::compile_args(fluidTestPackage));
cc(gin(in_mat1), gout(out_mat_gapi));
cv::Mat out_mat_ocv = Mat::zeros(sz_in, CV_8UC1);
cv::blur(in_mat1, out_mat_ocv, kernelSize, anchor, borderType);
EXPECT_EQ(0, countNonZero(out_mat_ocv != out_mat_gapi));
}
INSTANTIATE_TEST_CASE_P(Fluid, InputImageBorderTest,
Combine(Values(3, 5),
Values(BORDER_CONSTANT, BORDER_REPLICATE, BORDER_REFLECT_101)));
struct SequenceOfBlursTest : public TestWithParam <std::tuple<int>> {};
TEST_P(SequenceOfBlursTest, Test)
{
cv::Size sz_in = { 320, 240 };
int borderType = 0;;
std::tie(borderType) = GetParam();
cv::Mat in_mat(sz_in, CV_8UC1);
cv::Scalar mean = cv::Scalar(127.0f);
cv::Scalar stddev = cv::Scalar(40.f);
cv::randn(in_mat, mean, stddev);
cv::Point anchor = {-1, -1};
cv::Scalar borderValue(0);
GMat in;
auto mid = TBlur3x3::on(in, borderType, borderValue);
auto out = TBlur5x5::on(mid, borderType, borderValue);
Mat out_mat_gapi = Mat::zeros(sz_in, CV_8UC1);
GComputation c(GIn(in), GOut(out));
auto cc = c.compile(descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(gin(in_mat), gout(out_mat_gapi));
cv::Mat mid_mat_ocv = Mat::zeros(sz_in, CV_8UC1);
cv::Mat out_mat_ocv = Mat::zeros(sz_in, CV_8UC1);
cv::blur(in_mat, mid_mat_ocv, {3,3}, anchor, borderType);
cv::blur(mid_mat_ocv, out_mat_ocv, {5,5}, anchor, borderType);
EXPECT_EQ(0, countNonZero(out_mat_ocv != out_mat_gapi));
}
INSTANTIATE_TEST_CASE_P(Fluid, SequenceOfBlursTest,
Values(BORDER_CONSTANT, BORDER_REPLICATE, BORDER_REFLECT_101));
struct TwoBlursTest : public TestWithParam <std::tuple<int, int, int, int, int, int, bool>> {};
TEST_P(TwoBlursTest, Test)
{
cv::Size sz_in = { 320, 240 };
int kernelSize1 = 0, kernelSize2 = 0;
int borderType1 = -1, borderType2 = -1;
cv::Scalar borderValue1{}, borderValue2{};
bool readFromInput = false;
std::tie(kernelSize1, borderType1, borderValue1, kernelSize2, borderType2, borderValue2, readFromInput) = GetParam();
cv::Mat in_mat(sz_in, CV_8UC1);
cv::Scalar mean = cv::Scalar(127.0f);
cv::Scalar stddev = cv::Scalar(40.f);
cv::randn(in_mat, mean, stddev);
cv::Point anchor = {-1, -1};
auto blur1 = kernelSize1 == 3 ? &TBlur3x3::on : TBlur5x5::on;
auto blur2 = kernelSize2 == 3 ? &TBlur3x3::on : TBlur5x5::on;
GMat in, out1, out2;
if (readFromInput)
{
out1 = blur1(in, borderType1, borderValue1);
out2 = blur2(in, borderType2, borderValue2);
}
else
{
auto mid = TAddCSimple::on(in, 0);
out1 = blur1(mid, borderType1, borderValue1);
out2 = blur2(mid, borderType2, borderValue2);
}
Mat out_mat_gapi1 = Mat::zeros(sz_in, CV_8UC1);
Mat out_mat_gapi2 = Mat::zeros(sz_in, CV_8UC1);
GComputation c(GIn(in), GOut(out1, out2));
auto cc = c.compile(descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(gin(in_mat), gout(out_mat_gapi1, out_mat_gapi2));
cv::Mat out_mat_ocv1 = Mat::zeros(sz_in, CV_8UC1);
cv::Mat out_mat_ocv2 = Mat::zeros(sz_in, CV_8UC1);
cv::blur(in_mat, out_mat_ocv1, {kernelSize1, kernelSize1}, anchor, borderType1);
cv::blur(in_mat, out_mat_ocv2, {kernelSize2, kernelSize2}, anchor, borderType2);
EXPECT_EQ(0, countNonZero(out_mat_ocv1 != out_mat_gapi1));
EXPECT_EQ(0, countNonZero(out_mat_ocv2 != out_mat_gapi2));
}
INSTANTIATE_TEST_CASE_P(Fluid, TwoBlursTest,
Combine(Values(3, 5),
Values(cv::BORDER_CONSTANT, cv::BORDER_REPLICATE, cv::BORDER_REFLECT_101),
Values(0),
Values(3, 5),
Values(cv::BORDER_CONSTANT, cv::BORDER_REPLICATE, cv::BORDER_REFLECT_101),
Values(0),
testing::Bool())); // Read from input directly or place a copy node at start
struct TwoReadersTest : public TestWithParam <std::tuple<int, int, int, bool>> {};
TEST_P(TwoReadersTest, Test)
{
cv::Size sz_in = { 320, 240 };
int kernelSize = 0;
int borderType = -1;
cv::Scalar borderValue;
bool readFromInput = false;
std::tie(kernelSize, borderType, borderValue, readFromInput) = GetParam();
cv::Mat in_mat(sz_in, CV_8UC1);
cv::Scalar mean = cv::Scalar(127.0f);
cv::Scalar stddev = cv::Scalar(40.f);
cv::randn(in_mat, mean, stddev);
cv::Point anchor = {-1, -1};
auto blur = kernelSize == 3 ? &TBlur3x3::on : TBlur5x5::on;
GMat in, out1, out2;
if (readFromInput)
{
out1 = TAddCSimple::on(in, 0);
out2 = blur(in, borderType, borderValue);
}
else
{
auto mid = TAddCSimple::on(in, 0);
out1 = TAddCSimple::on(mid, 0);
out2 = blur(mid, borderType, borderValue);
}
Mat out_mat_gapi1 = Mat::zeros(sz_in, CV_8UC1);
Mat out_mat_gapi2 = Mat::zeros(sz_in, CV_8UC1);
GComputation c(GIn(in), GOut(out1, out2));
auto cc = c.compile(descr_of(in_mat), cv::compile_args(fluidTestPackage));
cc(gin(in_mat), gout(out_mat_gapi1, out_mat_gapi2));
cv::Mat out_mat_ocv1 = Mat::zeros(sz_in, CV_8UC1);
cv::Mat out_mat_ocv2 = Mat::zeros(sz_in, CV_8UC1);
out_mat_ocv1 = in_mat;
cv::blur(in_mat, out_mat_ocv2, {kernelSize, kernelSize}, anchor, borderType);
EXPECT_EQ(0, countNonZero(out_mat_ocv1 != out_mat_gapi1));
EXPECT_EQ(0, countNonZero(out_mat_ocv2 != out_mat_gapi2));
}
INSTANTIATE_TEST_CASE_P(Fluid, TwoReadersTest,
Combine(Values(3, 5),
Values(cv::BORDER_CONSTANT, cv::BORDER_REPLICATE, cv::BORDER_REFLECT_101),
Values(0),
testing::Bool())); // Read from input directly or place a copy node at start
TEST(FluidTwoIslands, SanityTest)
{
cv::Size sz_in{8,8};
GMat in1, in2;
auto out1 = TAddScalar::on(in1, {0});
auto out2 = TAddScalar::on(in2, {0});
cv::Mat in_mat1(sz_in, CV_8UC1);
cv::Mat in_mat2(sz_in, CV_8UC1);
cv::Scalar mean = cv::Scalar(127.0f);
cv::Scalar stddev = cv::Scalar(40.f);
cv::randn(in_mat1, mean, stddev);
cv::randn(in_mat2, mean, stddev);
Mat out_mat1 = Mat::zeros(sz_in, CV_8UC1);
Mat out_mat2 = Mat::zeros(sz_in, CV_8UC1);
GComputation c(GIn(in1, in2), GOut(out1, out2));
EXPECT_NO_THROW(c.apply(gin(in_mat1, in_mat2), gout(out_mat1, out_mat2), cv::compile_args(fluidTestPackage)));
EXPECT_EQ(0, countNonZero(in_mat1 != out_mat1));
EXPECT_EQ(0, countNonZero(in_mat2 != out_mat2));
}
} // namespace opencv_test