#ifndef __OPENCV_GTESTCV_HPP__ #define __OPENCV_GTESTCV_HPP__ #include "opencv2/core/cvdef.h" #include // for va_list #include "cvconfig.h" #ifdef HAVE_WINRT #pragma warning(disable:4447) // Disable warning 'main' signature found without threading model #endif #ifdef _MSC_VER #pragma warning( disable: 4127 ) #endif #define GTEST_DONT_DEFINE_FAIL 0 #define GTEST_DONT_DEFINE_SUCCEED 0 #define GTEST_DONT_DEFINE_ASSERT_EQ 0 #define GTEST_DONT_DEFINE_ASSERT_NE 0 #define GTEST_DONT_DEFINE_ASSERT_LE 0 #define GTEST_DONT_DEFINE_ASSERT_LT 0 #define GTEST_DONT_DEFINE_ASSERT_GE 0 #define GTEST_DONT_DEFINE_ASSERT_GT 0 #define GTEST_DONT_DEFINE_TEST 0 #include "opencv2/ts/ts_gtest.h" #ifndef GTEST_USES_SIMPLE_RE # define GTEST_USES_SIMPLE_RE 0 #endif #ifndef GTEST_USES_POSIX_RE # define GTEST_USES_POSIX_RE 0 #endif #include "opencv2/core.hpp" #include "opencv2/core/utility.hpp" namespace cvtest { using std::vector; using std::string; using cv::RNG; using cv::Mat; using cv::Scalar; using cv::Size; using cv::Point; using cv::Rect; using cv::InputArray; using cv::noArray; class CV_EXPORTS TS; CV_EXPORTS int64 readSeed(const char* str); CV_EXPORTS void randUni( RNG& rng, Mat& a, const Scalar& param1, const Scalar& param2 ); inline unsigned randInt( RNG& rng ) { return (unsigned)rng; } inline double randReal( RNG& rng ) { return (double)rng; } CV_EXPORTS const char* getTypeName( int type ); CV_EXPORTS int typeByName( const char* type_name ); CV_EXPORTS string vec2str(const string& sep, const int* v, size_t nelems); inline int clipInt( int val, int min_val, int max_val ) { if( val < min_val ) val = min_val; if( val > max_val ) val = max_val; return val; } CV_EXPORTS double getMinVal(int depth); CV_EXPORTS double getMaxVal(int depth); CV_EXPORTS Size randomSize(RNG& rng, double maxSizeLog); CV_EXPORTS void randomSize(RNG& rng, int minDims, int maxDims, double maxSizeLog, vector& sz); CV_EXPORTS int randomType(RNG& rng, int typeMask, int minChannels, int maxChannels); CV_EXPORTS Mat randomMat(RNG& rng, Size size, int type, double minVal, double maxVal, bool useRoi); CV_EXPORTS Mat randomMat(RNG& rng, const vector& size, int type, double minVal, double maxVal, bool useRoi); CV_EXPORTS void add(const Mat& a, double alpha, const Mat& b, double beta, Scalar gamma, Mat& c, int ctype, bool calcAbs=false); CV_EXPORTS void multiply(const Mat& a, const Mat& b, Mat& c, double alpha=1); CV_EXPORTS void divide(const Mat& a, const Mat& b, Mat& c, double alpha=1); CV_EXPORTS void convert(const Mat& src, cv::OutputArray dst, int dtype, double alpha=1, double beta=0); CV_EXPORTS void copy(const Mat& src, Mat& dst, const Mat& mask=Mat(), bool invertMask=false); CV_EXPORTS void set(Mat& dst, const Scalar& gamma, const Mat& mask=Mat()); // working with multi-channel arrays CV_EXPORTS void extract( const Mat& a, Mat& plane, int coi ); CV_EXPORTS void insert( const Mat& plane, Mat& a, int coi ); // checks that the array does not have NaNs and/or Infs and all the elements are // within [min_val,max_val). idx is the index of the first "bad" element. CV_EXPORTS int check( const Mat& data, double min_val, double max_val, vector* idx ); // modifies values that are close to zero CV_EXPORTS void patchZeros( Mat& mat, double level ); CV_EXPORTS void transpose(const Mat& src, Mat& dst); CV_EXPORTS void erode(const Mat& src, Mat& dst, const Mat& _kernel, Point anchor=Point(-1,-1), int borderType=0, const Scalar& borderValue=Scalar()); CV_EXPORTS void dilate(const Mat& src, Mat& dst, const Mat& _kernel, Point anchor=Point(-1,-1), int borderType=0, const Scalar& borderValue=Scalar()); CV_EXPORTS void filter2D(const Mat& src, Mat& dst, int ddepth, const Mat& kernel, Point anchor, double delta, int borderType, const Scalar& borderValue=Scalar()); CV_EXPORTS void copyMakeBorder(const Mat& src, Mat& dst, int top, int bottom, int left, int right, int borderType, const Scalar& borderValue=Scalar()); CV_EXPORTS Mat calcSobelKernel2D( int dx, int dy, int apertureSize, int origin=0 ); CV_EXPORTS Mat calcLaplaceKernel2D( int aperture_size ); CV_EXPORTS void initUndistortMap( const Mat& a, const Mat& k, Size sz, Mat& mapx, Mat& mapy ); CV_EXPORTS void minMaxLoc(const Mat& src, double* minval, double* maxval, vector* minloc, vector* maxloc, const Mat& mask=Mat()); CV_EXPORTS double norm(InputArray src, int normType, InputArray mask=noArray()); CV_EXPORTS double norm(InputArray src1, InputArray src2, int normType, InputArray mask=noArray()); CV_EXPORTS Scalar mean(const Mat& src, const Mat& mask=Mat()); CV_EXPORTS double PSNR(InputArray src1, InputArray src2); CV_EXPORTS bool cmpUlps(const Mat& data, const Mat& refdata, int expMaxDiff, double* realMaxDiff, vector* idx); // compares two arrays. max_diff is the maximum actual difference, // success_err_level is maximum allowed difference, idx is the index of the first // element for which difference is >success_err_level // (or index of element with the maximum difference) CV_EXPORTS int cmpEps( const Mat& data, const Mat& refdata, double* max_diff, double success_err_level, vector* idx, bool element_wise_relative_error ); // a wrapper for the previous function. in case of error prints the message to log file. CV_EXPORTS int cmpEps2( TS* ts, const Mat& data, const Mat& refdata, double success_err_level, bool element_wise_relative_error, const char* desc ); CV_EXPORTS int cmpEps2_64f( TS* ts, const double* val, const double* refval, int len, double eps, const char* param_name ); CV_EXPORTS void logicOp(const Mat& src1, const Mat& src2, Mat& dst, char c); CV_EXPORTS void logicOp(const Mat& src, const Scalar& s, Mat& dst, char c); CV_EXPORTS void min(const Mat& src1, const Mat& src2, Mat& dst); CV_EXPORTS void min(const Mat& src, double s, Mat& dst); CV_EXPORTS void max(const Mat& src1, const Mat& src2, Mat& dst); CV_EXPORTS void max(const Mat& src, double s, Mat& dst); CV_EXPORTS void compare(const Mat& src1, const Mat& src2, Mat& dst, int cmpop); CV_EXPORTS void compare(const Mat& src, double s, Mat& dst, int cmpop); CV_EXPORTS void gemm(const Mat& src1, const Mat& src2, double alpha, const Mat& src3, double beta, Mat& dst, int flags); CV_EXPORTS void transform( const Mat& src, Mat& dst, const Mat& transmat, const Mat& shift ); CV_EXPORTS double crossCorr(const Mat& src1, const Mat& src2); struct CV_EXPORTS MatInfo { MatInfo(const Mat& _m) : m(&_m) {} const Mat* m; }; CV_EXPORTS std::ostream& operator << (std::ostream& out, const MatInfo& m); struct CV_EXPORTS MatComparator { public: MatComparator(double maxdiff, int context); ::testing::AssertionResult operator()(const char* expr1, const char* expr2, const Mat& m1, const Mat& m2); double maxdiff; double realmaxdiff; vector loc0; int context; }; class BaseTest; class TS; class CV_EXPORTS BaseTest { public: // constructor(s) and destructor BaseTest(); virtual ~BaseTest(); // the main procedure of the test virtual void run( int start_from ); // the wrapper for run that cares of exceptions virtual void safe_run( int start_from=0 ); const string& get_name() const { return name; } // returns true if and only if the different test cases do not depend on each other // (so that test system could get right to a problematic test case) virtual bool can_do_fast_forward(); // deallocates all the memory. // called by init() (before initialization) and by the destructor virtual void clear(); protected: int test_case_count; // the total number of test cases // read test params virtual int read_params( CvFileStorage* fs ); // returns the number of tests or -1 if it is unknown a-priori virtual int get_test_case_count(); // prepares data for the next test case. rng seed is updated by the function virtual int prepare_test_case( int test_case_idx ); // checks if the test output is valid and accurate virtual int validate_test_results( int test_case_idx ); // calls the tested function. the method is called from run_test_case() virtual void run_func(); // runs tested func(s) // updates progress bar virtual int update_progress( int progress, int test_case_idx, int count, double dt ); // finds test parameter const CvFileNode* find_param( CvFileStorage* fs, const char* param_name ); // name of the test (it is possible to locate a test by its name) string name; // pointer to the system that includes the test TS* ts; }; /*****************************************************************************************\ * Information about a failed test * \*****************************************************************************************/ struct TestInfo { TestInfo(); // pointer to the test BaseTest* test; // failure code (TS::FAIL_*) int code; // seed value right before the data for the failed test case is prepared. uint64 rng_seed; // seed value right before running the test uint64 rng_seed0; // index of test case, can be then passed to BaseTest::proceed_to_test_case() int test_case_idx; }; /*****************************************************************************************\ * Base Class for test system * \*****************************************************************************************/ // common parameters: struct CV_EXPORTS TSParams { TSParams(); // RNG seed, passed to and updated by every test executed. uint64 rng_seed; // whether to use IPP, MKL etc. or not bool use_optimized; // extensivity of the tests, scale factor for test_case_count double test_case_count_scale; }; class CV_EXPORTS TS { public: // constructor(s) and destructor TS(); virtual ~TS(); enum { NUL=0, SUMMARY_IDX=0, SUMMARY=1 << SUMMARY_IDX, LOG_IDX=1, LOG=1 << LOG_IDX, CSV_IDX=2, CSV=1 << CSV_IDX, CONSOLE_IDX=3, CONSOLE=1 << CONSOLE_IDX, MAX_IDX=4 }; static TS* ptr(); // initialize test system before running the first test virtual void init( const string& modulename ); // low-level printing functions that are used by individual tests and by the system itself virtual void printf( int streams, const char* fmt, ... ); virtual void vprintf( int streams, const char* fmt, va_list arglist ); // updates the context: current test, test case, rng state virtual void update_context( BaseTest* test, int test_case_idx, bool update_ts_context ); const TestInfo* get_current_test_info() { return ¤t_test_info; } // sets information about a failed test virtual void set_failed_test_info( int fail_code ); virtual void set_gtest_status(); // test error codes enum FailureCode { // everything is Ok OK=0, // generic error: stub value to be used // temporarily if the error's cause is unknown FAIL_GENERIC=-1, // the test is missing some essential data to proceed further FAIL_MISSING_TEST_DATA=-2, // the tested function raised an error via cxcore error handler FAIL_ERROR_IN_CALLED_FUNC=-3, // an exception has been raised; // for memory and arithmetic exception // there are two specialized codes (see below...) FAIL_EXCEPTION=-4, // a memory exception // (access violation, access to missed page, stack overflow etc.) FAIL_MEMORY_EXCEPTION=-5, // arithmetic exception (overflow, division by zero etc.) FAIL_ARITHM_EXCEPTION=-6, // the tested function corrupted memory (no exception have been raised) FAIL_MEMORY_CORRUPTION_BEGIN=-7, FAIL_MEMORY_CORRUPTION_END=-8, // the tested function (or test ifself) do not deallocate some memory FAIL_MEMORY_LEAK=-9, // the tested function returned invalid object, e.g. matrix, containing NaNs, // structure with NULL or out-of-range fields (while it should not) FAIL_INVALID_OUTPUT=-10, // the tested function returned valid object, but it does not match to // the original (or produced by the test) object FAIL_MISMATCH=-11, // the tested function returned valid object (a single number or numerical array), // but it differs too much from the original (or produced by the test) object FAIL_BAD_ACCURACY=-12, // the tested function hung. Sometimes, can be determined by unexpectedly long // processing time (in this case there should be possibility to interrupt such a function FAIL_HANG=-13, // unexpected response on passing bad arguments to the tested function // (the function crashed, proceed succesfully (while it should not), or returned // error code that is different from what is expected) FAIL_BAD_ARG_CHECK=-14, // the test data (in whole or for the particular test case) is invalid FAIL_INVALID_TEST_DATA=-15, // the test has been skipped because it is not in the selected subset of the tests to run, // because it has been run already within the same run with the same parameters, or because // of some other reason and this is not considered as an error. // Normally TS::run() (or overrided method in the derived class) takes care of what // needs to be run, so this code should not occur. SKIPPED=1 }; // get file storage CvFileStorage* get_file_storage(); // get RNG to generate random input data for a test RNG& get_rng() { return rng; } // returns the current error code TS::FailureCode get_err_code() { return TS::FailureCode(current_test_info.code); } // returns the test extensivity scale double get_test_case_count_scale() { return params.test_case_count_scale; } const string& get_data_path() const { return data_path; } // returns textual description of failure code static string str_from_code( const TS::FailureCode code ); protected: // these are allocated within a test to try keep them valid in case of stack corruption RNG rng; // information about the current test TestInfo current_test_info; // the path to data files used by tests string data_path; TSParams params; std::string output_buf[MAX_IDX]; }; /*****************************************************************************************\ * Subclass of BaseTest for testing functions that process dense arrays * \*****************************************************************************************/ class CV_EXPORTS ArrayTest : public BaseTest { public: // constructor(s) and destructor ArrayTest(); virtual ~ArrayTest(); virtual void clear(); protected: virtual int read_params( CvFileStorage* fs ); virtual int prepare_test_case( int test_case_idx ); virtual int validate_test_results( int test_case_idx ); virtual void prepare_to_validation( int test_case_idx ); virtual void get_test_array_types_and_sizes( int test_case_idx, vector >& sizes, vector >& types ); virtual void fill_array( int test_case_idx, int i, int j, Mat& arr ); virtual void get_minmax_bounds( int i, int j, int type, Scalar& low, Scalar& high ); virtual double get_success_error_level( int test_case_idx, int i, int j ); bool cvmat_allowed; bool iplimage_allowed; bool optional_mask; bool element_wise_relative_error; int min_log_array_size; int max_log_array_size; enum { INPUT, INPUT_OUTPUT, OUTPUT, REF_INPUT_OUTPUT, REF_OUTPUT, TEMP, MASK, MAX_ARR }; vector > test_array; vector > test_mat; float buf[4]; }; class CV_EXPORTS BadArgTest : public BaseTest { public: // constructor(s) and destructor BadArgTest(); virtual ~BadArgTest(); protected: virtual int run_test_case( int expected_code, const string& descr ); virtual void run_func(void) = 0; int test_case_idx; template int run_test_case( int expected_code, const string& _descr, F f) { int errcount = 0; bool thrown = false; const char* descr = _descr.c_str() ? _descr.c_str() : ""; try { f(); } catch(const cv::Exception& e) { thrown = true; if( e.code != expected_code ) { ts->printf(TS::LOG, "%s (test case #%d): the error code %d is different from the expected %d\n", descr, test_case_idx, e.code, expected_code); errcount = 1; } } catch(...) { thrown = true; ts->printf(TS::LOG, "%s (test case #%d): unknown exception was thrown (the function has likely crashed)\n", descr, test_case_idx); errcount = 1; } if(!thrown) { ts->printf(TS::LOG, "%s (test case #%d): no expected exception was thrown\n", descr, test_case_idx); errcount = 1; } test_case_idx++; return errcount; } }; struct CV_EXPORTS DefaultRngAuto { const uint64 old_state; DefaultRngAuto() : old_state(cv::theRNG().state) { cv::theRNG().state = (uint64)-1; } ~DefaultRngAuto() { cv::theRNG().state = old_state; } DefaultRngAuto& operator=(const DefaultRngAuto&); }; } namespace cvtest { // test images generation functions CV_EXPORTS void fillGradient(Mat& img, int delta = 5); CV_EXPORTS void smoothBorder(Mat& img, const Scalar& color, int delta = 3); CV_EXPORTS void printVersionInfo(bool useStdOut = true); } //namespace cvtest #ifndef __CV_TEST_EXEC_ARGS #if defined(_MSC_VER) && (_MSC_VER <= 1400) #define __CV_TEST_EXEC_ARGS(...) \ while (++argc >= (--argc,-1)) {__VA_ARGS__; break;} /*this ugly construction is needed for VS 2005*/ #else #define __CV_TEST_EXEC_ARGS(...) \ __VA_ARGS__; #endif #endif #if defined(HAVE_OPENCL) && !defined(CV_BUILD_OCL_MODULE) namespace cvtest { namespace ocl { void dumpOpenCLDevice(); }} #define TEST_DUMP_OCL_INFO cvtest::ocl::dumpOpenCLDevice(); #else #define TEST_DUMP_OCL_INFO #endif #define CV_TEST_MAIN(resourcesubdir, ...) \ int main(int argc, char **argv) \ { \ cvtest::TS::ptr()->init(resourcesubdir); \ ::testing::InitGoogleTest(&argc, argv); \ cvtest::printVersionInfo(); \ __CV_TEST_EXEC_ARGS(__VA_ARGS__) \ TEST_DUMP_OCL_INFO \ return RUN_ALL_TESTS(); \ } // This usually only makes sense in perf tests with several implementations, // some of which are not available. #define CV_TEST_FAIL_NO_IMPL() do { \ ::testing::Test::RecordProperty("custom_status", "noimpl"); \ FAIL() << "No equivalent implementation."; \ } while (0) #endif #include "opencv2/ts/ts_perf.hpp"