#include "../test_precomp.hpp" #include "backends/common/serialization.hpp" namespace opencv_test { struct S11N_Basic: public ::testing::Test { template void put(T &&t) { cv::gimpl::s11n::ByteMemoryOutStream os; os << t; m_buffer = os.data(); } template T get() { // FIXME: This stream API needs a fix-up cv::gimpl::s11n::ByteMemoryInStream is(m_buffer); T t{}; is >> t; return t; } private: std::vector m_buffer; }; TEST_F(S11N_Basic, Test_int_pos) { int x = 42; put(x); EXPECT_EQ(x, get()); } TEST_F(S11N_Basic, Test_int_neg) { int x = -42; put(x); EXPECT_EQ(x, get()); } TEST_F(S11N_Basic, Test_fp32) { float x = 3.14f; put(x); EXPECT_EQ(x, get()); } TEST_F(S11N_Basic, Test_fp64) { double x = 3.14; put(x); EXPECT_EQ(x, get()); } TEST_F(S11N_Basic, Test_vector_int) { std::vector v = {1,2,3}; put(v); EXPECT_EQ(v, get >()); } TEST_F(S11N_Basic, Test_vector_cvSize) { std::vector v = { cv::Size(640, 480), cv::Size(1280, 1024), }; put(v); EXPECT_EQ(v, get >()); } TEST_F(S11N_Basic, Test_vector_string) { std::vector v = { "hello", "world", "ok!" }; put(v); EXPECT_EQ(v, get >()); } TEST_F(S11N_Basic, Test_vector_empty) { std::vector v; put(v); EXPECT_EQ(v, get >()); } TEST_F(S11N_Basic, Test_variant) { using S = std::string; using V = cv::util::variant; V v1{42}, v2{S{"hey"}}; put(v1); EXPECT_EQ(v1, get()); put(v2); EXPECT_EQ(v2, get()); } TEST_F(S11N_Basic, Test_GArg_int) { const int x = 42; cv::GArg gs(x); put(gs); cv::GArg gd = get(); EXPECT_EQ(cv::detail::ArgKind::OPAQUE_VAL, gd.kind); EXPECT_EQ(cv::detail::OpaqueKind::CV_INT, gd.opaque_kind); EXPECT_EQ(x, gs.get()); } TEST_F(S11N_Basic, Test_GArg_Point) { const cv::Point pt{1,2}; cv::GArg gs(pt); put(gs); cv::GArg gd = get(); EXPECT_EQ(cv::detail::ArgKind::OPAQUE_VAL, gd.kind); EXPECT_EQ(cv::detail::OpaqueKind::CV_POINT, gd.opaque_kind); EXPECT_EQ(pt, gs.get()); } TEST_F(S11N_Basic, Test_Mat_full) { auto mat = cv::Mat::eye(cv::Size(64,64), CV_8UC3); put(mat); EXPECT_EQ(0, cv::norm(mat, get(), cv::NORM_INF)); } TEST_F(S11N_Basic, Test_Mat_view) { auto mat = cv::Mat::eye(cv::Size(320,240), CV_8UC3); auto view = mat(cv::Rect(10,15,123,70)); put(view); EXPECT_EQ(0, cv::norm(view, get(), cv::NORM_INF)); } TEST_F(S11N_Basic, Test_MatDesc) { cv::GMatDesc v = { CV_8U, 1, {320,240} }; put(v); EXPECT_EQ(v, get()); } TEST_F(S11N_Basic, Test_MetaArg_MatDesc) { cv::GMatDesc desc = { CV_8U, 1,{ 320,240 } }; auto v = cv::GMetaArg{ desc }; put(v); cv::GMetaArg out_v = get(); cv::GMatDesc out_desc = cv::util::get(out_v); EXPECT_EQ(desc, out_desc); } TEST_F(S11N_Basic, Test_MetaArgs_MatDesc) { cv::GMatDesc desc1 = { CV_8U, 1,{ 320,240 } }; cv::GMatDesc desc2 = { CV_8U, 1,{ 640,480 } }; GMetaArgs v; v.resize(2); v[0] = cv::GMetaArg{ desc1 }; v[1] = cv::GMetaArg{ desc2 }; put(v); cv::GMetaArgs out_v = get(); cv::GMatDesc out_desc1 = cv::util::get(out_v[0]); cv::GMatDesc out_desc2 = cv::util::get(out_v[1]); EXPECT_EQ(desc1, out_desc1); EXPECT_EQ(desc2, out_desc2); } TEST_F(S11N_Basic, Test_MetaArg_Monostate) { GMetaArg v; put(v); cv::GMetaArg out_v = get(); if (!util::holds_alternative(out_v)) { GTEST_FAIL(); } } TEST_F(S11N_Basic, Test_RunArg_Mat) { cv::Mat mat = cv::Mat::eye(cv::Size(64, 64), CV_8UC3); auto v = cv::GRunArg{ mat }; put(v); cv::GRunArg out_v = get(); cv::Mat out_mat = cv::util::get(out_v); EXPECT_EQ(0, cv::norm(mat, out_mat, cv::NORM_INF)); } TEST_F(S11N_Basic, Test_RunArgs_Mat) { cv::Mat mat1 = cv::Mat::eye(cv::Size(64, 64), CV_8UC3); cv::Mat mat2 = cv::Mat::eye(cv::Size(128, 128), CV_8UC3); GRunArgs v; v.resize(2); v[0] = cv::GRunArg{ mat1 }; v[1] = cv::GRunArg{ mat2 }; put(v); cv::GRunArgs out_v = get(); cv::Mat out_mat1 = cv::util::get(out_v[0]); cv::Mat out_mat2 = cv::util::get(out_v[1]); EXPECT_EQ(0, cv::norm(mat1, out_mat1, cv::NORM_INF)); EXPECT_EQ(0, cv::norm(mat2, out_mat2, cv::NORM_INF)); } TEST_F(S11N_Basic, Test_RunArg_Scalar) { cv::Scalar scalar = cv::Scalar(128, 33, 53); auto v = cv::GRunArg{ scalar }; put(v); cv::GRunArg out_v = get(); cv::Scalar out_scalar = cv::util::get(out_v); EXPECT_EQ(scalar, out_scalar); } TEST_F(S11N_Basic, Test_RunArgs_Scalar) { cv::Scalar scalar1 = cv::Scalar(128, 33, 53); cv::Scalar scalar2 = cv::Scalar(64, 15, 23); GRunArgs v; v.resize(2); v[0] = cv::GRunArg{ scalar1 }; v[1] = cv::GRunArg{ scalar2 }; put(v); cv::GRunArgs out_v = get(); cv::Scalar out_scalar1 = cv::util::get(out_v[0]); cv::Scalar out_scalar2 = cv::util::get(out_v[1]); EXPECT_EQ(scalar1, out_scalar1); EXPECT_EQ(scalar2, out_scalar2); } TEST_F(S11N_Basic, Test_RunArgs_MatScalar) { cv::Mat mat = cv::Mat::eye(cv::Size(64, 64), CV_8UC3); cv::Scalar scalar = cv::Scalar(128, 33, 53); GRunArgs v; v.resize(2); v[0] = cv::GRunArg{ mat }; v[1] = cv::GRunArg{ scalar }; put(v); cv::GRunArgs out_v = get(); unsigned int i = 0; for (auto it : out_v) { using T = cv::GRunArg; switch (it.index()) { case T::index_of() : { cv::Mat out_mat = cv::util::get(out_v[i]); EXPECT_EQ(0, cv::norm(mat, out_mat, cv::NORM_INF)); } break; case T::index_of() : { cv::Scalar out_scalar = cv::util::get(out_v[i]); EXPECT_EQ(scalar, out_scalar); } break; default: GAPI_Assert(false && "This value type is not supported!"); // ...maybe because of STANDALONE mode. break; } i++; } } TEST_F(S11N_Basic, Test_Bind_RunArgs_MatScalar) { cv::Mat mat = cv::Mat::eye(cv::Size(128, 64), CV_8UC3); cv::Scalar scalar = cv::Scalar(128, 33, 53); GRunArgs v; v.resize(2); v[0] = cv::GRunArg{ mat }; v[1] = cv::GRunArg{ scalar }; GRunArgsP output = cv::gapi::bind(v); std::cout << "output size " << output.size() << std::endl; unsigned int i = 0; for (auto it : output) { using T = cv::GRunArgP; switch (it.index()) { case T::index_of() : { cv::Mat* out_mat = cv::util::get(it); EXPECT_EQ(mat.size(), out_mat->size()); } break; case T::index_of() : { cv::Scalar* out_scalar = cv::util::get(it); EXPECT_EQ(out_scalar->val[0], scalar.val[0]); EXPECT_EQ(out_scalar->val[1], scalar.val[1]); EXPECT_EQ(out_scalar->val[2], scalar.val[2]); } break; default: GAPI_Assert(false && "This value type is not supported!"); // ...maybe because of STANDALONE mode. break; } i++; } } } // namespace opencv_test