// 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 #include #include "test_precomp.hpp" #include "opencv2/gapi/streaming/meta.hpp" #include "opencv2/gapi/streaming/cap.hpp" namespace opencv_test { TEST(GraphMeta, Trad_AccessInput) { cv::GMat in; cv::GMat out1 = cv::gapi::blur(in, cv::Size(3,3)); cv::GOpaque out2 = cv::gapi::streaming::meta(in, "foo"); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2)); cv::Mat in_mat = cv::Mat::eye(cv::Size(64, 64), CV_8UC1); cv::Mat out_mat; int out_meta = 0; // manually set metadata in the input fields auto inputs = cv::gin(in_mat); inputs[0].meta["foo"] = 42; graph.apply(std::move(inputs), cv::gout(out_mat, out_meta)); EXPECT_EQ(42, out_meta); } TEST(GraphMeta, Trad_AccessTmp) { cv::GMat in; cv::GMat tmp = cv::gapi::blur(in, cv::Size(3,3)); cv::GMat out1 = tmp+1; cv::GOpaque out2 = cv::gapi::streaming::meta(tmp, "bar"); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2)); cv::Mat in_mat = cv::Mat::eye(cv::Size(64, 64), CV_8UC1); cv::Mat out_mat; float out_meta = 0.f; // manually set metadata in the input fields auto inputs = cv::gin(in_mat); inputs[0].meta["bar"] = 1.f; graph.apply(std::move(inputs), cv::gout(out_mat, out_meta)); EXPECT_EQ(1.f, out_meta); } TEST(GraphMeta, Trad_AccessOutput) { cv::GMat in; cv::GMat out1 = cv::gapi::blur(in, cv::Size(3,3)); cv::GOpaque out2 = cv::gapi::streaming::meta(out1, "baz"); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2)); cv::Mat in_mat = cv::Mat::eye(cv::Size(64, 64), CV_8UC1); cv::Mat out_mat; std::string out_meta; // manually set metadata in the input fields auto inputs = cv::gin(in_mat); // NOTE: Assigning explicitly an std::string is important, // otherwise a "const char*" will be stored and won't be // translated properly by util::any since std::string is // used within the graph. inputs[0].meta["baz"] = std::string("opencv"); graph.apply(std::move(inputs), cv::gout(out_mat, out_meta)); EXPECT_EQ("opencv", out_meta); } TEST(GraphMeta, Streaming_AccessInput) { cv::GMat in; cv::GMat out1 = cv::gapi::blur(in, cv::Size(3,3)); cv::GOpaque out2 = cv::gapi::streaming::seq_id(in); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2)); auto ccomp = graph.compileStreaming(); const auto path = findDataFile("cv/video/768x576.avi"); try { ccomp.setSource(path); } catch(...) { throw SkipTestException("Video file can not be opened"); } ccomp.start(); cv::Mat out_mat; int64_t out_meta = 0; int64_t expected_counter = 0; while (ccomp.pull(cv::gout(out_mat, out_meta))) { EXPECT_EQ(expected_counter, out_meta); ++expected_counter; } } TEST(GraphMeta, Streaming_AccessOutput) { cv::GMat in; cv::GMat out1 = cv::gapi::blur(in, cv::Size(3,3)); cv::GOpaque out2 = cv::gapi::streaming::seq_id(out1); cv::GOpaque out3 = cv::gapi::streaming::timestamp(out1); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2, out3)); auto ccomp = graph.compileStreaming(); const auto path = findDataFile("cv/video/768x576.avi"); try { ccomp.setSource(path); } catch(...) { throw SkipTestException("Video file can not be opened"); } ccomp.start(); cv::Mat out_mat; int64_t out_meta = 0; int64_t out_timestamp = 0; int64_t expected_counter = 0; int64_t prev_timestamp = -1; while (ccomp.pull(cv::gout(out_mat, out_meta, out_timestamp))) { EXPECT_EQ(expected_counter, out_meta); ++expected_counter; EXPECT_NE(prev_timestamp, out_timestamp); prev_timestamp = out_timestamp; } } TEST(GraphMeta, Streaming_AccessDesync) { cv::GMat in; cv::GOpaque out1 = cv::gapi::streaming::seq_id(in); cv::GOpaque out2 = cv::gapi::streaming::timestamp(in); cv::GMat out3 = cv::gapi::blur(in, cv::Size(3,3)); cv::GMat tmp = cv::gapi::streaming::desync(in); cv::GScalar mean = cv::gapi::mean(tmp); cv::GOpaque out4 = cv::gapi::streaming::seq_id(mean); cv::GOpaque out5 = cv::gapi::streaming::timestamp(mean); cv::GComputation graph(cv::GIn(in), cv::GOut(out1, out2, out3, out4, out5)); auto ccomp = graph.compileStreaming(); const auto path = findDataFile("cv/video/768x576.avi"); try { ccomp.setSource(path); } catch(...) { throw SkipTestException("Video file can not be opened"); } ccomp.start(); cv::optional out_sync_id; cv::optional out_sync_ts; cv::optional out_sync_mat; cv::optional out_desync_id; cv::optional out_desync_ts; std::unordered_set sync_ids; std::unordered_set desync_ids; while (ccomp.pull(cv::gout(out_sync_id, out_sync_ts, out_sync_mat, out_desync_id, out_desync_ts))) { if (out_sync_id.has_value()) { CV_Assert(out_sync_ts.has_value()); CV_Assert(out_sync_mat.has_value()); sync_ids.insert(out_sync_id.value()); } if (out_desync_id.has_value()) { CV_Assert(out_desync_ts.has_value()); desync_ids.insert(out_desync_id.value()); } } // Visually report that everything is really ok std::cout << sync_ids.size() << " vs " << desync_ids.size() << std::endl; // Desync path should generate less objects than the synchronized one EXPECT_GE(sync_ids.size(), desync_ids.size()); // ..but all desynchronized IDs must be present in the synchronized set for (auto &&d_id : desync_ids) { EXPECT_TRUE(sync_ids.count(d_id) > 0); } } } // namespace opencv_test