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# include "test_precomp.hpp"
# include "opencv2/ts/ocl_test.hpp"
using namespace opencv_test ;
using namespace testing ;
using namespace cv ;
namespace opencv_test {
namespace ocl {
# define UMAT_TEST_SIZES testing::Values(cv::Size(1, 1), cv::Size(1,128), cv::Size(128, 1), \
cv : : Size ( 128 , 128 ) , cv : : Size ( 640 , 480 ) , cv : : Size ( 751 , 373 ) , cv : : Size ( 1200 , 1200 ) )
/////////////////////////////// Basic Tests ////////////////////////////////
PARAM_TEST_CASE ( UMatBasicTests , int , int , Size , bool )
{
Mat a ;
UMat ua ;
int type ;
int depth ;
int cn ;
Size size ;
bool useRoi ;
Size roi_size ;
Rect roi ;
virtual void SetUp ( )
{
depth = GET_PARAM ( 0 ) ;
cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
useRoi = GET_PARAM ( 3 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
a = randomMat ( size , type , - 100 , 100 ) ;
a . copyTo ( ua ) ;
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
roi = Rect ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
}
} ;
TEST_P ( UMatBasicTests , createUMat )
{
if ( useRoi )
{
ua = UMat ( ua , roi ) ;
}
int dims = randomInt ( 2 , 6 ) ;
int _sz [ CV_MAX_DIM ] ;
for ( int i = 0 ; i < dims ; i + + )
{
_sz [ i ] = randomInt ( 1 , 50 ) ;
}
int * sz = _sz ;
int new_depth = randomInt ( CV_8S , CV_64F ) ;
int new_cn = randomInt ( 1 , 4 ) ;
ua . create ( dims , sz , CV_MAKE_TYPE ( new_depth , new_cn ) ) ;
for ( int i = 0 ; i < dims ; i + + )
{
ASSERT_EQ ( ua . size [ i ] , sz [ i ] ) ;
}
ASSERT_EQ ( ua . dims , dims ) ;
ASSERT_EQ ( ua . type ( ) , CV_MAKE_TYPE ( new_depth , new_cn ) ) ;
Size new_size = randomSize ( 1 , 1000 ) ;
ua . create ( new_size , CV_MAKE_TYPE ( new_depth , new_cn ) ) ;
ASSERT_EQ ( ua . size ( ) , new_size ) ;
ASSERT_EQ ( ua . type ( ) , CV_MAKE_TYPE ( new_depth , new_cn ) ) ;
ASSERT_EQ ( ua . dims , 2 ) ;
}
TEST_P ( UMatBasicTests , swap )
{
Mat b = randomMat ( size , type , - 100 , 100 ) ;
UMat ub ;
b . copyTo ( ub ) ;
if ( useRoi )
{
ua = UMat ( ua , roi ) ;
ub = UMat ( ub , roi ) ;
}
UMat uc = ua , ud = ub ;
swap ( ua , ub ) ;
EXPECT_MAT_NEAR ( ub , uc , 0 ) ;
EXPECT_MAT_NEAR ( ud , ua , 0 ) ;
}
TEST_P ( UMatBasicTests , base )
{
const int align_mask = 3 ;
roi . x & = ~ align_mask ;
roi . y & = ~ align_mask ;
roi . width = ( roi . width + align_mask ) & ~ align_mask ;
roi & = Rect ( 0 , 0 , ua . cols , ua . rows ) ;
if ( useRoi )
{
ua = UMat ( ua , roi ) ;
}
UMat ub = ua . clone ( ) ;
EXPECT_MAT_NEAR ( ub , ua , 0 ) ;
ASSERT_EQ ( ua . channels ( ) , cn ) ;
ASSERT_EQ ( ua . depth ( ) , depth ) ;
ASSERT_EQ ( ua . type ( ) , type ) ;
ASSERT_EQ ( ua . elemSize ( ) , a . elemSize ( ) ) ;
ASSERT_EQ ( ua . elemSize1 ( ) , a . elemSize1 ( ) ) ;
ASSERT_EQ ( ub . empty ( ) , ub . cols * ub . rows = = 0 ) ;
ub . release ( ) ;
ASSERT_TRUE ( ub . empty ( ) ) ;
if ( useRoi & & a . size ( ) ! = ua . size ( ) )
{
ASSERT_EQ ( ua . isSubmatrix ( ) , true ) ;
}
else
{
ASSERT_EQ ( ua . isSubmatrix ( ) , false ) ;
}
int dims = randomInt ( 2 , 6 ) ;
int sz [ CV_MAX_DIM ] ;
size_t total = 1 ;
for ( int i = 0 ; i < dims ; i + + )
{
sz [ i ] = randomInt ( 1 , 45 ) ;
total * = ( size_t ) sz [ i ] ;
}
int new_type = CV_MAKE_TYPE ( randomInt ( CV_8S , CV_64F ) , randomInt ( 1 , 4 ) ) ;
ub = UMat ( dims , sz , new_type ) ;
ASSERT_EQ ( ub . total ( ) , total ) ;
}
TEST_P ( UMatBasicTests , copyTo )
{
int i ;
if ( useRoi )
{
UMat roi_ua ;
Mat roi_a ;
roi_ua = UMat ( ua , roi ) ;
roi_a = Mat ( a , roi ) ;
roi_a . copyTo ( roi_ua ) ;
EXPECT_MAT_NEAR ( roi_a , roi_ua , 0 ) ;
roi_ua . copyTo ( roi_a ) ;
EXPECT_MAT_NEAR ( roi_ua , roi_a , 0 ) ;
roi_ua . copyTo ( ua ) ;
EXPECT_MAT_NEAR ( roi_ua , ua , 0 ) ;
ua . copyTo ( a ) ;
EXPECT_MAT_NEAR ( ua , a , 0 ) ;
}
{
UMat ub ;
ua . copyTo ( ub ) ;
EXPECT_MAT_NEAR ( ua , ub , 0 ) ;
}
{
UMat ub ;
i = randomInt ( 0 , ua . cols - 1 ) ;
a . col ( i ) . copyTo ( ub ) ;
EXPECT_MAT_NEAR ( a . col ( i ) , ub , 0 ) ;
}
{
UMat ub ;
ua . col ( i ) . copyTo ( ub ) ;
EXPECT_MAT_NEAR ( ua . col ( i ) , ub , 0 ) ;
}
{
Mat b ;
ua . col ( i ) . copyTo ( b ) ;
EXPECT_MAT_NEAR ( ua . col ( i ) , b , 0 ) ;
}
{
UMat ub ;
i = randomInt ( 0 , a . rows - 1 ) ;
ua . row ( i ) . copyTo ( ub ) ;
EXPECT_MAT_NEAR ( ua . row ( i ) , ub , 0 ) ;
}
{
UMat ub ;
a . row ( i ) . copyTo ( ub ) ;
EXPECT_MAT_NEAR ( a . row ( i ) , ub , 0 ) ;
}
{
Mat b ;
ua . row ( i ) . copyTo ( b ) ;
EXPECT_MAT_NEAR ( ua . row ( i ) , b , 0 ) ;
}
}
TEST_P ( UMatBasicTests , GetUMat )
{
if ( useRoi )
{
a = Mat ( a , roi ) ;
ua = UMat ( ua , roi ) ;
}
{
UMat ub ;
ub = a . getUMat ( ACCESS_RW ) ;
EXPECT_MAT_NEAR ( ub , ua , 0 ) ;
}
{
UMat u = a . getUMat ( ACCESS_RW ) ;
{
Mat b = u . getMat ( ACCESS_RW ) ;
EXPECT_MAT_NEAR ( b , a , 0 ) ;
}
}
{
Mat b ;
b = ua . getMat ( ACCESS_RW ) ;
EXPECT_MAT_NEAR ( b , a , 0 ) ;
}
{
Mat m = ua . getMat ( ACCESS_RW ) ;
{
UMat ub = m . getUMat ( ACCESS_RW ) ;
EXPECT_MAT_NEAR ( ub , ua , 0 ) ;
}
}
}
INSTANTIATE_TEST_CASE_P ( UMat , UMatBasicTests , Combine ( testing : : Values ( CV_8U , CV_64F ) , testing : : Values ( 1 , 2 ) ,
testing : : Values ( cv : : Size ( 1 , 1 ) , cv : : Size ( 1 , 128 ) , cv : : Size ( 128 , 1 ) , cv : : Size ( 128 , 128 ) , cv : : Size ( 640 , 480 ) ) , Bool ( ) ) ) ;
//////////////////////////////////////////////////////////////// Reshape ////////////////////////////////////////////////////////////////////////
PARAM_TEST_CASE ( UMatTestReshape , int , int , Size , bool )
{
Mat a ;
UMat ua , ub ;
int type ;
int depth ;
int cn ;
Size size ;
bool useRoi ;
Size roi_size ;
virtual void SetUp ( )
{
depth = GET_PARAM ( 0 ) ;
cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
useRoi = GET_PARAM ( 3 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
}
} ;
TEST_P ( UMatTestReshape , reshape )
{
a = randomMat ( size , type , - 100 , 100 ) ;
a . copyTo ( ua ) ;
if ( useRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
ua = UMat ( ua , roi ) . clone ( ) ;
a = Mat ( a , roi ) . clone ( ) ;
}
int nChannels = randomInt ( 1 , 4 ) ;
if ( ( ua . cols * ua . channels ( ) * ua . rows ) % nChannels ! = 0 )
{
EXPECT_ANY_THROW ( ua . reshape ( nChannels ) ) ;
}
else
{
ub = ua . reshape ( nChannels ) ;
ASSERT_EQ ( ub . channels ( ) , nChannels ) ;
ASSERT_EQ ( ub . channels ( ) * ub . cols * ub . rows , ua . channels ( ) * ua . cols * ua . rows ) ;
EXPECT_MAT_NEAR ( ua . reshape ( nChannels ) , a . reshape ( nChannels ) , 0 ) ;
int new_rows = randomInt ( 1 , INT_MAX ) ;
if ( ( ( int ) ua . total ( ) * ua . channels ( ) ) % ( new_rows * nChannels ) ! = 0 )
{
EXPECT_ANY_THROW ( ua . reshape ( nChannels , new_rows ) ) ;
}
else
{
EXPECT_NO_THROW ( ub = ua . reshape ( nChannels , new_rows ) ) ;
ASSERT_EQ ( ub . channels ( ) , nChannels ) ;
ASSERT_EQ ( ub . rows , new_rows ) ;
ASSERT_EQ ( ub . channels ( ) * ub . cols * ub . rows , ua . channels ( ) * ua . cols * ua . rows ) ;
EXPECT_MAT_NEAR ( ua . reshape ( nChannels , new_rows ) , a . reshape ( nChannels , new_rows ) , 0 ) ;
}
new_rows = ( int ) ua . total ( ) * ua . channels ( ) / ( nChannels * randomInt ( 1 , size . width * size . height ) ) ;
if ( new_rows = = 0 ) new_rows = 1 ;
int new_cols = ( int ) ua . total ( ) * ua . channels ( ) / ( new_rows * nChannels ) ;
int sz [ ] = { new_rows , new_cols } ;
if ( ( ( int ) ua . total ( ) * ua . channels ( ) ) % ( new_rows * new_cols ) ! = 0 )
{
EXPECT_ANY_THROW ( ua . reshape ( nChannels , ua . dims , sz ) ) ;
}
else
{
EXPECT_NO_THROW ( ub = ua . reshape ( nChannels , ua . dims , sz ) ) ;
ASSERT_EQ ( ub . channels ( ) , nChannels ) ;
ASSERT_EQ ( ub . rows , new_rows ) ;
ASSERT_EQ ( ub . cols , new_cols ) ;
ASSERT_EQ ( ub . channels ( ) * ub . cols * ub . rows , ua . channels ( ) * ua . cols * ua . rows ) ;
EXPECT_MAT_NEAR ( ua . reshape ( nChannels , ua . dims , sz ) , a . reshape ( nChannels , a . dims , sz ) , 0 ) ;
}
}
}
INSTANTIATE_TEST_CASE_P ( UMat , UMatTestReshape , Combine ( OCL_ALL_DEPTHS , OCL_ALL_CHANNELS , UMAT_TEST_SIZES , Bool ( ) ) ) ;
static void check_ndim_shape ( const cv : : UMat & mat , int cn , int ndims , const int * sizes )
{
EXPECT_EQ ( mat . channels ( ) , cn ) ;
EXPECT_EQ ( mat . dims , ndims ) ;
if ( mat . dims ! = ndims )
return ;
for ( int i = 0 ; i < ndims ; i + + )
EXPECT_EQ ( mat . size [ i ] , sizes [ i ] ) ;
}
TEST ( UMatTestReshape , reshape_ndims_2 )
{
const cv : : UMat A ( 8 , 16 , CV_8UC3 ) ;
cv : : UMat B ;
{
int new_sizes_mask [ ] = { 0 , 3 , 4 , 4 } ;
int new_sizes_real [ ] = { 8 , 3 , 4 , 4 } ;
ASSERT_NO_THROW ( B = A . reshape ( 1 , 4 , new_sizes_mask ) ) ;
check_ndim_shape ( B , 1 , 4 , new_sizes_real ) ;
}
{
int new_sizes [ ] = { 16 , 8 } ;
ASSERT_NO_THROW ( B = A . reshape ( 0 , 2 , new_sizes ) ) ;
check_ndim_shape ( B , 3 , 2 , new_sizes ) ;
EXPECT_EQ ( B . rows , new_sizes [ 0 ] ) ;
EXPECT_EQ ( B . cols , new_sizes [ 1 ] ) ;
}
{
int new_sizes [ ] = { 2 , 5 , 1 , 3 } ;
cv : : UMat A_sliced = A ( cv : : Range : : all ( ) , cv : : Range ( 0 , 15 ) ) ;
ASSERT_ANY_THROW ( A_sliced . reshape ( 4 , 4 , new_sizes ) ) ;
}
}
TEST ( UMatTestReshape , reshape_ndims_4 )
{
const int sizes [ ] = { 2 , 6 , 4 , 12 } ;
const cv : : UMat A ( 4 , sizes , CV_8UC3 ) ;
cv : : UMat B ;
{
int new_sizes_mask [ ] = { 0 , 864 } ;
int new_sizes_real [ ] = { 2 , 864 } ;
ASSERT_NO_THROW ( B = A . reshape ( 1 , 2 , new_sizes_mask ) ) ;
check_ndim_shape ( B , 1 , 2 , new_sizes_real ) ;
EXPECT_EQ ( B . rows , new_sizes_real [ 0 ] ) ;
EXPECT_EQ ( B . cols , new_sizes_real [ 1 ] ) ;
}
{
int new_sizes_mask [ ] = { 4 , 0 , 0 , 2 , 3 } ;
int new_sizes_real [ ] = { 4 , 6 , 4 , 2 , 3 } ;
ASSERT_NO_THROW ( B = A . reshape ( 0 , 5 , new_sizes_mask ) ) ;
check_ndim_shape ( B , 3 , 5 , new_sizes_real ) ;
}
{
int new_sizes_mask [ ] = { 1 , 1 } ;
ASSERT_ANY_THROW ( A . reshape ( 0 , 2 , new_sizes_mask ) ) ;
}
{
int new_sizes_mask [ ] = { 4 , 6 , 3 , 3 , 0 } ;
ASSERT_ANY_THROW ( A . reshape ( 0 , 5 , new_sizes_mask ) ) ;
}
}
////////////////////////////////////////////////////////////////// ROI testing ///////////////////////////////////////////////////////////////
PARAM_TEST_CASE ( UMatTestRoi , int , int , Size )
{
Mat a , roi_a ;
UMat ua , roi_ua ;
int type ;
int depth ;
int cn ;
Size size ;
Size roi_size ;
virtual void SetUp ( )
{
depth = GET_PARAM ( 0 ) ;
cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
}
} ;
TEST_P ( UMatTestRoi , createRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
a = randomMat ( size , type , - 100 , 100 ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
roi_a = Mat ( a , roi ) ;
a . copyTo ( ua ) ;
roi_ua = UMat ( ua , roi ) ;
EXPECT_MAT_NEAR ( roi_a , roi_ua , 0 ) ;
}
TEST_P ( UMatTestRoi , locateRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
a = randomMat ( size , type , - 100 , 100 ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
roi_a = Mat ( a , roi ) ;
a . copyTo ( ua ) ;
roi_ua = UMat ( ua , roi ) ;
Size sz , usz ;
Point p , up ;
roi_a . locateROI ( sz , p ) ;
roi_ua . locateROI ( usz , up ) ;
ASSERT_EQ ( sz , usz ) ;
ASSERT_EQ ( p , up ) ;
}
TEST_P ( UMatTestRoi , adjustRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
a = randomMat ( size , type , - 100 , 100 ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
a . copyTo ( ua ) ;
roi_ua = UMat ( ua , roi ) ;
int adjLeft = randomInt ( - ( roi_ua . cols / 2 ) , ( size . width - 1 ) / 2 ) ;
int adjRight = randomInt ( - ( roi_ua . cols / 2 ) , ( size . width - 1 ) / 2 ) ;
int adjTop = randomInt ( - ( roi_ua . rows / 2 ) , ( size . height - 1 ) / 2 ) ;
int adjBot = randomInt ( - ( roi_ua . rows / 2 ) , ( size . height - 1 ) / 2 ) ;
roi_ua . adjustROI ( adjTop , adjBot , adjLeft , adjRight ) ;
roi_shift_x = std : : max ( 0 , roi . x - adjLeft ) ;
roi_shift_y = std : : max ( 0 , roi . y - adjTop ) ;
Rect new_roi ( roi_shift_x , roi_shift_y , std : : min ( roi . width + adjRight + adjLeft , size . width - roi_shift_x ) , std : : min ( roi . height + adjBot + adjTop , size . height - roi_shift_y ) ) ;
UMat test_roi = UMat ( ua , new_roi ) ;
EXPECT_MAT_NEAR ( roi_ua , test_roi , 0 ) ;
}
INSTANTIATE_TEST_CASE_P ( UMat , UMatTestRoi , Combine ( OCL_ALL_DEPTHS , OCL_ALL_CHANNELS , UMAT_TEST_SIZES ) ) ;
TEST ( UMatTestRoi , adjustRoiOverflow )
{
UMat m ( 15 , 10 , CV_32S ) ;
UMat roi ( m , cv : : Range ( 2 , 10 ) , cv : : Range ( 3 , 6 ) ) ;
int rowsInROI = roi . rows ;
roi . adjustROI ( 1 , 0 , 0 , 0 ) ;
ASSERT_EQ ( roi . rows , rowsInROI + 1 ) ;
roi . adjustROI ( - m . rows , - m . rows , 0 , 0 ) ;
ASSERT_EQ ( roi . rows , m . rows ) ;
}
/////////////////////////////////////////////////////////////// Size ////////////////////////////////////////////////////////////////////
PARAM_TEST_CASE ( UMatTestSizeOperations , int , int , Size , bool )
{
Mat a , b , roi_a , roi_b ;
UMat ua , ub , roi_ua , roi_ub ;
int type ;
int depth ;
int cn ;
Size size ;
Size roi_size ;
bool useRoi ;
virtual void SetUp ( )
{
depth = GET_PARAM ( 0 ) ;
cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
useRoi = GET_PARAM ( 3 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
}
} ;
TEST_P ( UMatTestSizeOperations , copySize )
{
Size s = randomSize ( 1 , 300 ) ;
a = randomMat ( size , type , - 100 , 100 ) ;
b = randomMat ( s , type , - 100 , 100 ) ;
a . copyTo ( ua ) ;
b . copyTo ( ub ) ;
if ( useRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
ua = UMat ( ua , roi ) ;
roi_shift_x = randomInt ( 0 , s . width - 1 ) ;
roi_shift_y = randomInt ( 0 , s . height - 1 ) ;
roi_size = Size ( s . width - roi_shift_x , s . height - roi_shift_y ) ;
roi = Rect ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
ub = UMat ( ub , roi ) ;
}
ua . copySize ( ub ) ;
ASSERT_EQ ( ua . size , ub . size ) ;
}
INSTANTIATE_TEST_CASE_P ( UMat , UMatTestSizeOperations , Combine ( OCL_ALL_DEPTHS , OCL_ALL_CHANNELS , UMAT_TEST_SIZES , Bool ( ) ) ) ;
///////////////////////////////////////////////////////////////// UMat operations ////////////////////////////////////////////////////////////////////////////
PARAM_TEST_CASE ( UMatTestUMatOperations , int , int , Size , bool )
{
Mat a , b ;
UMat ua , ub ;
int type ;
int depth ;
int cn ;
Size size ;
Size roi_size ;
bool useRoi ;
virtual void SetUp ( )
{
depth = GET_PARAM ( 0 ) ;
cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
useRoi = GET_PARAM ( 3 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
}
} ;
TEST_P ( UMatTestUMatOperations , diag )
{
a = randomMat ( size , type , - 100 , 100 ) ;
a . copyTo ( ua ) ;
Mat new_diag ;
if ( useRoi )
{
int roi_shift_x = randomInt ( 0 , size . width - 1 ) ;
int roi_shift_y = randomInt ( 0 , size . height - 1 ) ;
roi_size = Size ( size . width - roi_shift_x , size . height - roi_shift_y ) ;
Rect roi ( roi_shift_x , roi_shift_y , roi_size . width , roi_size . height ) ;
ua = UMat ( ua , roi ) ;
a = Mat ( a , roi ) ;
}
int n = randomInt ( 0 , ua . cols - 1 ) ;
ub = ua . diag ( n ) ;
b = a . diag ( n ) ;
EXPECT_MAT_NEAR ( b , ub , 0 ) ;
new_diag = randomMat ( Size ( ua . rows , 1 ) , type , - 100 , 100 ) ;
new_diag . copyTo ( ub ) ;
ua = cv : : UMat : : diag ( ub ) ;
EXPECT_MAT_NEAR ( ua . diag ( ) , new_diag . t ( ) , 0 ) ;
}
INSTANTIATE_TEST_CASE_P ( UMat , UMatTestUMatOperations , Combine ( OCL_ALL_DEPTHS , OCL_ALL_CHANNELS , UMAT_TEST_SIZES , Bool ( ) ) ) ;
/////////////////////////////////////////////////////////////// getUMat -> GetMat ///////////////////////////////////////////////////////////////////
PARAM_TEST_CASE ( getUMat , int , int , Size , bool )
{
int type ;
Size size ;
virtual void SetUp ( )
{
int depth = GET_PARAM ( 0 ) ;
int cn = GET_PARAM ( 1 ) ;
size = GET_PARAM ( 2 ) ;
useOpenCL = GET_PARAM ( 3 ) ;
type = CV_MAKE_TYPE ( depth , cn ) ;
isOpenCL_enabled = cv : : ocl : : useOpenCL ( ) ;
cv : : ocl : : setUseOpenCL ( useOpenCL ) ;
}
virtual void TearDown ( )
{
cv : : ocl : : setUseOpenCL ( isOpenCL_enabled ) ;
}
// UMat created from user allocated host memory (USE_HOST_PTR)
void custom_ptr_test ( size_t align_base , size_t align_offset )
{
void * pData_allocated = new unsigned char [ size . area ( ) * CV_ELEM_SIZE ( type ) + ( align_base + align_offset ) ] ;
void * pData = ( char * ) alignPtr ( pData_allocated , ( int ) align_base ) + align_offset ;
size_t step = size . width * CV_ELEM_SIZE ( type ) ;
{
Mat m = Mat ( size , type , pData , step ) ;
m . setTo ( cv : : Scalar : : all ( 2 ) ) ;
UMat u = m . getUMat ( ACCESS_RW ) ;
cv : : add ( u , cv : : Scalar : : all ( 2 ) , u ) ;
Mat d = u . getMat ( ACCESS_READ ) ;
Mat expected ( m . size ( ) , m . type ( ) , cv : : Scalar : : all ( 4 ) ) ;
double norm = cvtest : : norm ( d , expected , NORM_INF ) ;
EXPECT_EQ ( 0 , norm ) ;
}
delete [ ] ( unsigned char * ) pData_allocated ;
}
private :
bool useOpenCL ;
bool isOpenCL_enabled ;
} ;
TEST_P ( getUMat , custom_ptr_align_4Kb )
{
custom_ptr_test ( 4096 , 0 ) ;
}
TEST_P ( getUMat , custom_ptr_align_64b )
{
custom_ptr_test ( 4096 , 64 ) ;
}
TEST_P ( getUMat , custom_ptr_align_none )
{
custom_ptr_test ( 4096 , cv : : alignSize ( CV_ELEM_SIZE ( type ) , 4 ) ) ;
}
TEST_P ( getUMat , self_allocated )
{
Mat m = Mat ( size , type ) ;
m . setTo ( cv : : Scalar : : all ( 2 ) ) ;
UMat u = m . getUMat ( ACCESS_RW ) ;
cv : : add ( u , cv : : Scalar : : all ( 2 ) , u ) ;
Mat d = u . getMat ( ACCESS_READ ) ;
Mat expected ( m . size ( ) , m . type ( ) , cv : : Scalar : : all ( 4 ) ) ;
double norm = cvtest : : norm ( d , expected , NORM_INF ) ;
EXPECT_EQ ( 0 , norm ) ;
}
INSTANTIATE_TEST_CASE_P ( UMat , getUMat , Combine (
Values ( CV_8U , CV_64F ) , // depth
Values ( 1 , 3 ) , // channels
Values ( cv : : Size ( 1 , 1 ) , cv : : Size ( 255 , 255 ) , cv : : Size ( 256 , 256 ) ) , // Size
Bool ( ) // useOpenCL
) ) ;
///////////////////////////////////////////////////////////////// OpenCL ////////////////////////////////////////////////////////////////////////////
# ifdef HAVE_OPENCL
TEST ( UMat , BufferPoolGrowing )
{
# ifdef _DEBUG
const int ITERATIONS = 100 ;
# else
const int ITERATIONS = 200 ;
# endif
const Size sz ( 1920 , 1080 ) ;
BufferPoolController * c = cv : : ocl : : getOpenCLAllocator ( ) - > getBufferPoolController ( ) ;
if ( c )
{
size_t oldMaxReservedSize = c - > getMaxReservedSize ( ) ;
c - > freeAllReservedBuffers ( ) ;
c - > setMaxReservedSize ( sz . area ( ) * 10 ) ;
for ( int i = 0 ; i < ITERATIONS ; i + + )
{
UMat um ( Size ( sz . width + i , sz . height + i ) , CV_8UC1 ) ;
UMat um2 ( Size ( sz . width + 2 * i , sz . height + 2 * i ) , CV_8UC1 ) ;
}
c - > setMaxReservedSize ( oldMaxReservedSize ) ;
c - > freeAllReservedBuffers ( ) ;
}
else
std : : cout < < " Skipped, no OpenCL " < < std : : endl ;
}
# endif
class CV_UMatTest :
public cvtest : : BaseTest
{
public :
CV_UMatTest ( ) { }
~ CV_UMatTest ( ) { }
protected :
void run ( int ) ;
struct test_excep
{
test_excep ( const string & _s = string ( " " ) ) : s ( _s ) { }
string s ;
} ;
bool TestUMat ( ) ;
void checkDiff ( const Mat & m1 , const Mat & m2 , const string & s )
{
if ( cvtest : : norm ( m1 , m2 , NORM_INF ) ! = 0 )
throw test_excep ( s ) ;
}
void checkDiffF ( const Mat & m1 , const Mat & m2 , const string & s )
{
if ( cvtest : : norm ( m1 , m2 , NORM_INF ) > 1e-5 )
throw test_excep ( s ) ;
}
} ;
# define STR(a) STR2(a)
# define STR2(a) #a
# define CHECK_DIFF(a, b) checkDiff(a, b, "(" #a ") != (" #b ") at l." STR(__LINE__))
# define CHECK_DIFF_FLT(a, b) checkDiffF(a, b, "(" #a ") !=(eps) (" #b ") at l." STR(__LINE__))
bool CV_UMatTest : : TestUMat ( )
{
try
{
Mat a ( 100 , 100 , CV_16SC2 ) , b , c ;
randu ( a , Scalar : : all ( - 100 ) , Scalar : : all ( 100 ) ) ;
Rect roi ( 1 , 3 , 5 , 4 ) ;
Mat ra ( a , roi ) , rb , rc , rc0 ;
UMat ua , ura , ub , urb , uc , urc ;
a . copyTo ( ua ) ;
ua . copyTo ( b ) ;
CHECK_DIFF ( a , b ) ;
ura = ua ( roi ) ;
ura . copyTo ( rb ) ;
CHECK_DIFF ( ra , rb ) ;
ra + = Scalar : : all ( 1.f ) ;
{
Mat temp = ura . getMat ( ACCESS_RW ) ;
temp + = Scalar : : all ( 1.f ) ;
}
ra . copyTo ( rb ) ;
CHECK_DIFF ( ra , rb ) ;
b = a . clone ( ) ;
ra = a ( roi ) ;
rb = b ( roi ) ;
randu ( b , Scalar : : all ( - 100 ) , Scalar : : all ( 100 ) ) ;
b . copyTo ( ub ) ;
urb = ub ( roi ) ;
/*std::cout << "==============================================\nbefore op (CPU):\n";
std : : cout < < " ra: " < < ra < < std : : endl ;
std : : cout < < " rb: " < < rb < < std : : endl ; */
ra . copyTo ( ura ) ;
rb . copyTo ( urb ) ;
ra . release ( ) ;
rb . release ( ) ;
ura . copyTo ( ra ) ;
urb . copyTo ( rb ) ;
/*std::cout << "==============================================\nbefore op (GPU):\n";
std : : cout < < " ra: " < < ra < < std : : endl ;
std : : cout < < " rb: " < < rb < < std : : endl ; */
cv : : max ( ra , rb , rc ) ;
cv : : max ( ura , urb , urc ) ;
urc . copyTo ( rc0 ) ;
/*std::cout << "==============================================\nafter op:\n";
std : : cout < < " rc: " < < rc < < std : : endl ;
std : : cout < < " rc0: " < < rc0 < < std : : endl ; */
CHECK_DIFF ( rc0 , rc ) ;
{
UMat tmp = rc0 . getUMat ( ACCESS_WRITE ) ;
cv : : max ( ura , urb , tmp ) ;
}
CHECK_DIFF ( rc0 , rc ) ;
ura . copyTo ( urc ) ;
cv : : max ( urc , urb , urc ) ;
urc . copyTo ( rc0 ) ;
CHECK_DIFF ( rc0 , rc ) ;
rc = ra ^ rb ;
cv : : bitwise_xor ( ura , urb , urc ) ;
urc . copyTo ( rc0 ) ;
/*std::cout << "==============================================\nafter op:\n";
std : : cout < < " ra: " < < rc0 < < std : : endl ;
std : : cout < < " rc: " < < rc < < std : : endl ; */
CHECK_DIFF ( rc0 , rc ) ;
rc = ra + rb ;
cv : : add ( ura , urb , urc ) ;
urc . copyTo ( rc0 ) ;
CHECK_DIFF ( rc0 , rc ) ;
cv : : subtract ( ra , Scalar : : all ( 5 ) , rc ) ;
cv : : subtract ( ura , Scalar : : all ( 5 ) , urc ) ;
urc . copyTo ( rc0 ) ;
CHECK_DIFF ( rc0 , rc ) ;
}
catch ( const test_excep & e )
{
ts - > printf ( cvtest : : TS : : LOG , " %s \n " , e . s . c_str ( ) ) ;
ts - > set_failed_test_info ( cvtest : : TS : : FAIL_MISMATCH ) ;
return false ;
}
return true ;
}
void CV_UMatTest : : run ( int /* start_from */ )
{
printf ( " Use OpenCL: %s \n Have OpenCL: %s \n " ,
cv : : ocl : : useOpenCL ( ) ? " TRUE " : " FALSE " ,
cv : : ocl : : haveOpenCL ( ) ? " TRUE " : " FALSE " ) ;
if ( ! TestUMat ( ) )
return ;
ts - > set_failed_test_info ( cvtest : : TS : : OK ) ;
}
TEST ( Core_UMat , base ) { CV_UMatTest test ; test . safe_run ( ) ; }
TEST ( Core_UMat , getUMat )
{
{
int a [ 3 ] = { 1 , 2 , 3 } ;
Mat m = Mat ( 1 , 1 , CV_32SC3 , a ) ;
UMat u = m . getUMat ( ACCESS_READ ) ;
EXPECT_NE ( ( void * ) NULL , u . u ) ;
}
{
Mat m ( 10 , 10 , CV_8UC1 ) , ref ;
for ( int y = 0 ; y < m . rows ; + + y )
{
uchar * const ptr = m . ptr < uchar > ( y ) ;
for ( int x = 0 ; x < m . cols ; + + x )
ptr [ x ] = ( uchar ) ( x + y * 2 ) ;
}
ref = m . clone ( ) ;
Rect r ( 1 , 1 , 8 , 8 ) ;
ref ( r ) . setTo ( 17 ) ;
{
UMat um = m ( r ) . getUMat ( ACCESS_WRITE ) ;
um . setTo ( 17 ) ;
}
double err = cvtest : : norm ( m , ref , NORM_INF ) ;
if ( err > 0 )
{
std : : cout < < " m: " < < std : : endl < < m < < std : : endl ;
std : : cout < < " ref: " < < std : : endl < < ref < < std : : endl ;
}
EXPECT_EQ ( 0. , err ) ;
}
}
TEST ( UMat , Sync )
{
UMat um ( 10 , 10 , CV_8UC1 ) ;
{
Mat m = um . getMat ( ACCESS_WRITE ) ;
m . setTo ( cv : : Scalar : : all ( 17 ) ) ;
}
um . setTo ( cv : : Scalar : : all ( 19 ) ) ;
EXPECT_EQ ( 0 , cvtest : : norm ( um . getMat ( ACCESS_READ ) , cv : : Mat ( um . size ( ) , um . type ( ) , 19 ) , NORM_INF ) ) ;
}
TEST ( UMat , SyncTemp )
{
Mat m ( 10 , 10 , CV_8UC1 ) ;
{
UMat um = m . getUMat ( ACCESS_WRITE ) ;
{
Mat m2 = um . getMat ( ACCESS_WRITE ) ;
m2 . setTo ( cv : : Scalar : : all ( 17 ) ) ;
}
um . setTo ( cv : : Scalar : : all ( 19 ) ) ;
EXPECT_EQ ( 0 , cvtest : : norm ( um . getMat ( ACCESS_READ ) , cv : : Mat ( um . size ( ) , um . type ( ) , 19 ) , NORM_INF ) ) ;
}
}
TEST ( UMat , CopyToIfDeviceCopyIsObsolete )
{
UMat um ( 7 , 2 , CV_8UC1 ) ;
Mat m ( um . size ( ) , um . type ( ) ) ;
m . setTo ( Scalar : : all ( 0 ) ) ;
{
// make obsolete device copy of UMat
Mat temp = um . getMat ( ACCESS_WRITE ) ;
temp . setTo ( Scalar : : all ( 10 ) ) ;
}
m . copyTo ( um ) ;
um . setTo ( Scalar : : all ( 17 ) ) ;
EXPECT_EQ ( 0 , cvtest : : norm ( um . getMat ( ACCESS_READ ) , Mat ( um . size ( ) , um . type ( ) , 17 ) , NORM_INF ) ) ;
}
TEST ( UMat , setOpenCL )
{
# ifndef HAVE_OPENCL
return ; // test skipped
# else
// save the current state
bool useOCL = cv : : ocl : : useOpenCL ( ) ;
Mat m = ( Mat_ < uchar > ( 3 , 3 ) < < 0 , 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 ) ;
cv : : ocl : : setUseOpenCL ( true ) ;
UMat um1 ;
m . copyTo ( um1 ) ;
cv : : ocl : : setUseOpenCL ( false ) ;
UMat um2 ;
m . copyTo ( um2 ) ;
cv : : ocl : : setUseOpenCL ( true ) ;
countNonZero ( um1 ) ;
countNonZero ( um2 ) ;
um1 . copyTo ( um2 ) ;
EXPECT_MAT_NEAR ( um1 , um2 , 0 ) ;
EXPECT_MAT_NEAR ( um1 , m , 0 ) ;
um2 . copyTo ( um1 ) ;
EXPECT_MAT_NEAR ( um1 , m , 0 ) ;
EXPECT_MAT_NEAR ( um1 , um2 , 0 ) ;
cv : : ocl : : setUseOpenCL ( false ) ;
countNonZero ( um1 ) ;
countNonZero ( um2 ) ;
um1 . copyTo ( um2 ) ;
EXPECT_MAT_NEAR ( um1 , um2 , 0 ) ;
EXPECT_MAT_NEAR ( um1 , m , 0 ) ;
um2 . copyTo ( um1 ) ;
EXPECT_MAT_NEAR ( um1 , um2 , 0 ) ;
EXPECT_MAT_NEAR ( um1 , m , 0 ) ;
// reset state to the previous one
cv : : ocl : : setUseOpenCL ( useOCL ) ;
# endif
}
TEST ( UMat , ReadBufferRect )
{
UMat m ( 1 , 10000 , CV_32FC2 , Scalar : : all ( - 1 ) ) ;
Mat t ( 1 , 9000 , CV_32FC2 , Scalar : : all ( - 200 ) ) , t2 ( 1 , 9000 , CV_32FC2 , Scalar : : all ( - 1 ) ) ;
m . colRange ( 0 , 9000 ) . copyTo ( t ) ;
EXPECT_MAT_NEAR ( t , t2 , 0 ) ;
}
// Use iGPU or OPENCV_OPENCL_DEVICE=:CPU: to catch problem
TEST ( UMat , synchronization_map_unmap )
{
class TestParallelLoopBody : public cv : : ParallelLoopBody
{
UMat u_ ;
public :
TestParallelLoopBody ( const UMat & u ) : u_ ( u ) { }
void operator ( ) ( const cv : : Range & range ) const
{
printf ( " range: %d, %d -- begin \n " , range . start , range . end ) ;
for ( int i = 0 ; i < 10 ; i + + )
{
printf ( " %d: %d map... \n " , range . start , i ) ;
Mat m = u_ . getMat ( cv : : ACCESS_READ ) ;
printf ( " %d: %d unmap... \n " , range . start , i ) ;
m . release ( ) ;
}
printf ( " range: %d, %d -- end \n " , range . start , range . end ) ;
}
} ;
try
{
UMat u ( 1000 , 1000 , CV_32FC1 , Scalar : : all ( 0 ) ) ;
parallel_for_ ( cv : : Range ( 0 , 2 ) , TestParallelLoopBody ( u ) ) ;
}
catch ( const cv : : Exception & e )
{
FAIL ( ) < < " Exception: " < < e . what ( ) ;
ADD_FAILURE ( ) ;
}
catch ( . . . )
{
FAIL ( ) < < " Exception! " ;
}
}
TEST ( UMat , async_unmap )
{
for ( int i = 0 ; i < 20 ; i + + )
{
try
{
Mat m = Mat ( 1000 , 1000 , CV_8UC1 , Scalar : : all ( 0 ) ) ;
UMat u = m . getUMat ( ACCESS_READ ) ;
UMat dst ;
cv : : add ( u , Scalar : : all ( 0 ) , dst ) ; // start async operation
u . release ( ) ;
m . release ( ) ;
}
catch ( const cv : : Exception & e )
{
printf ( " i = %d... %s \n " , i , e . what ( ) ) ;
ADD_FAILURE ( ) ;
}
catch ( . . . )
{
printf ( " i = %d... \n " , i ) ;
ADD_FAILURE ( ) ;
}
}
}
TEST ( UMat , unmap_in_class )
{
class Logic
{
public :
Logic ( ) { }
void processData ( InputArray input )
{
Mat m = input . getMat ( ) ;
{
Mat dst ;
m . convertTo ( dst , CV_32FC1 ) ;
// some additional CPU-based per-pixel processing into dst
intermediateResult = dst . getUMat ( ACCESS_READ ) ; // this violates lifetime of base(dst) / derived (intermediateResult) objects. Use copyTo?
std : : cout < < " data processed... " < < std : : endl ;
} // problem is here: dst::~Mat()
std : : cout < < " leave ProcessData() " < < std : : endl ;
}
UMat getResult ( ) const { return intermediateResult ; }
protected :
UMat intermediateResult ;
} ;
try
{
Mat m = Mat ( 1000 , 1000 , CV_8UC1 , Scalar : : all ( 0 ) ) ;
Logic l ;
l . processData ( m ) ;
UMat result = l . getResult ( ) ;
}
catch ( const cv : : Exception & e )
{
printf ( " exception... %s \n " , e . what ( ) ) ;
ADD_FAILURE ( ) ;
}
catch ( . . . )
{
printf ( " exception... \n " ) ;
ADD_FAILURE ( ) ;
}
}
TEST ( UMat , map_unmap_counting )
{
if ( ! cv : : ocl : : useOpenCL ( ) )
{
std : : cout < < " OpenCL is not enabled. Skip test " < < std : : endl ;
return ;
}
std : : cout < < " Host memory: " < < cv : : ocl : : Device : : getDefault ( ) . hostUnifiedMemory ( ) < < std : : endl ;
Mat m ( Size ( 10 , 10 ) , CV_8UC1 , Scalar : : all ( 0 ) ) ;
UMat um = m . getUMat ( ACCESS_RW ) ;
{
Mat d1 = um . getMat ( ACCESS_RW ) ;
Mat d2 = um . getMat ( ACCESS_RW ) ;
d1 . release ( ) ;
}
void * h = NULL ;
EXPECT_NO_THROW ( h = um . handle ( ACCESS_RW ) ) ;
std : : cout < < " Handle: " < < h < < std : : endl ;
}
static void process_with_async_cleanup ( Mat & frame )
{
UMat blurResult ;
{
UMat umat_buffer = frame . getUMat ( ACCESS_READ ) ;
cv : : blur ( umat_buffer , blurResult , Size ( 3 , 3 ) ) ; // UMat doesn't support inplace, this call is not synchronized
}
Mat result ;
blurResult . copyTo ( result ) ;
swap ( result , frame ) ;
// umat_buffer cleanup is done asynchronously, silence warning about original 'frame' cleanup here (through 'result')
// - release input 'frame' (as 'result')
// - release 'umat_buffer' asynchronously and silence warning about "parent" buffer (in debug builds)
}
TEST ( UMat , async_cleanup_without_call_chain_warning )
{
Mat frame ( Size ( 640 , 480 ) , CV_8UC1 , Scalar : : all ( 128 ) ) ;
for ( int i = 0 ; i < 10 ; i + + )
{
process_with_async_cleanup ( frame ) ;
}
}
///////////// oclCleanupCallback threadsafe check (#5062) /////////////////////
// Case 1: reuse of old src Mat in OCL pipe. Hard to catch!
OCL_TEST ( UMat , DISABLED_OCL_ThreadSafe_CleanupCallback_1_VeryLongTest )
{
if ( ! cv : : ocl : : useOpenCL ( ) )
{
std : : cout < < " OpenCL is not enabled. Skip test " < < std : : endl ;
return ;
}
for ( int j = 0 ; j < 100 ; j + + )
{
const Size srcSize ( 320 , 240 ) ;
const int type = CV_8UC1 ;
const int dtype = CV_16UC1 ;
Mat src ( srcSize , type , Scalar : : all ( 0 ) ) ;
Mat dst_ref ( srcSize , dtype ) ;
// Generate reference data as additional check
OCL_OFF ( src . convertTo ( dst_ref , dtype ) ) ;
cv : : ocl : : setUseOpenCL ( true ) ; // restore OpenCL state
UMat dst ( srcSize , dtype ) ;
// Use multiple iterations to increase chance of data race catching
for ( int k = 0 ; k < 10000 ; k + + )
{
UMat tmpUMat = src . getUMat ( ACCESS_RW ) ;
tmpUMat . convertTo ( dst , dtype ) ;
: : cv : : ocl : : finish ( ) ; // force kernel to complete to start cleanup sooner
}
EXPECT_MAT_NEAR ( dst_ref , dst , 1 ) ;
printf ( " . \n " ) ; fflush ( stdout ) ;
}
}
// Case 2: concurrent deallocation of UMatData between UMat and Mat deallocators. Hard to catch!
OCL_TEST ( UMat , DISABLED_OCL_ThreadSafe_CleanupCallback_2_VeryLongTest )
{
if ( ! cv : : ocl : : useOpenCL ( ) )
{
std : : cout < < " OpenCL is not enabled. Skip test " < < std : : endl ;
return ;
}
for ( int j = 0 ; j < 100 ; j + + )
{
const Size srcSize ( 320 , 240 ) ;
const int type = CV_8UC1 ;
const int dtype = CV_16UC1 ;
// This test is only relevant for OCL
UMat dst ( srcSize , dtype ) ;
// Use multiple iterations to increase chance of data race catching
for ( int k = 0 ; k < 10000 ; k + + )
{
Mat src ( srcSize , type , Scalar : : all ( 0 ) ) ; // Declare src inside loop now to catch its destruction on stack
{
UMat tmpUMat = src . getUMat ( ACCESS_RW ) ;
tmpUMat . convertTo ( dst , dtype ) ;
}
: : cv : : ocl : : finish ( ) ; // force kernel to complete to start cleanup sooner
}
printf ( " . \n " ) ; fflush ( stdout ) ;
}
}
TEST ( UMat , DISABLED_Test_same_behaviour_read_and_read )
{
bool exceptionDetected = false ;
try
{
UMat u ( Size ( 10 , 10 ) , CV_8UC1 , Scalar : : all ( 0 ) ) ;
Mat m = u . getMat ( ACCESS_READ ) ;
UMat dst ;
cv : : add ( u , Scalar : : all ( 1 ) , dst ) ;
}
catch ( . . . )
{
exceptionDetected = true ;
}
ASSERT_FALSE ( exceptionDetected ) ; // no data race, 2+ reads are valid
}
// VP: this test (and probably others from same_behaviour series) is not valid in my opinion.
TEST ( UMat , DISABLED_Test_same_behaviour_read_and_write )
{
bool exceptionDetected = false ;
try
{
UMat u ( Size ( 10 , 10 ) , CV_8UC1 , Scalar : : all ( 0 ) ) ;
Mat m = u . getMat ( ACCESS_READ ) ;
cv : : add ( u , Scalar : : all ( 1 ) , u ) ;
}
catch ( . . . )
{
exceptionDetected = true ;
}
ASSERT_TRUE ( exceptionDetected ) ; // data race
}
TEST ( UMat , DISABLED_Test_same_behaviour_write_and_read )
{
bool exceptionDetected = false ;
try
{
UMat u ( Size ( 10 , 10 ) , CV_8UC1 , Scalar : : all ( 0 ) ) ;
Mat m = u . getMat ( ACCESS_WRITE ) ;
UMat dst ;
cv : : add ( u , Scalar : : all ( 1 ) , dst ) ;
}
catch ( . . . )
{
exceptionDetected = true ;
}
ASSERT_TRUE ( exceptionDetected ) ; // data race
}
TEST ( UMat , DISABLED_Test_same_behaviour_write_and_write )
{
bool exceptionDetected = false ;
try
{
UMat u ( Size ( 10 , 10 ) , CV_8UC1 , Scalar : : all ( 0 ) ) ;
Mat m = u . getMat ( ACCESS_WRITE ) ;
cv : : add ( u , Scalar : : all ( 1 ) , u ) ;
}
catch ( . . . )
{
exceptionDetected = true ;
}
ASSERT_TRUE ( exceptionDetected ) ; // data race
}
TEST ( UMat , mat_umat_sync )
{
UMat u ( 10 , 10 , CV_8UC1 , Scalar ( 1 ) ) ;
{
Mat m = u . getMat ( ACCESS_RW ) . reshape ( 1 ) ;
m . setTo ( Scalar ( 255 ) ) ;
}
UMat uDiff ;
cv : : compare ( u , 255 , uDiff , CMP_NE ) ;
ASSERT_EQ ( 0 , countNonZero ( uDiff ) ) ;
}
TEST ( UMat , testTempObjects_UMat )
{
UMat u ( 10 , 10 , CV_8UC1 , Scalar ( 1 ) ) ;
{
UMat u2 = u . getMat ( ACCESS_RW ) . getUMat ( ACCESS_RW ) ;
u2 . setTo ( Scalar ( 255 ) ) ;
}
UMat uDiff ;
cv : : compare ( u , 255 , uDiff , CMP_NE ) ;
ASSERT_EQ ( 0 , countNonZero ( uDiff ) ) ;
}
TEST ( UMat , testTempObjects_Mat )
{
Mat m ( 10 , 10 , CV_8UC1 , Scalar ( 1 ) ) ;
{
Mat m2 ;
ASSERT_ANY_THROW ( {
// Below is unwrapped version of this invalid expression:
// m2 = m.getUMat(ACCESS_RW).getMat(ACCESS_RW)
UMat u = m . getUMat ( ACCESS_RW ) ;
m2 = u . getMat ( ACCESS_RW ) ;
u . release ( ) ;
} ) ;
}
}
TEST ( UMat , testWrongLifetime_UMat )
{
UMat u ( 10 , 10 , CV_8UC1 , Scalar ( 1 ) ) ;
{
UMat u2 = u . getMat ( ACCESS_RW ) . getUMat ( ACCESS_RW ) ;
u . release ( ) ; // base object
u2 . release ( ) ; // derived object, should show warning message
}
}
TEST ( UMat , testWrongLifetime_Mat )
{
Mat m ( 10 , 10 , CV_8UC1 , Scalar ( 1 ) ) ;
{
UMat u = m . getUMat ( ACCESS_RW ) ;
Mat m2 = u . getMat ( ACCESS_RW ) ;
m . release ( ) ; // base object
m2 . release ( ) ; // map of derived object
u . release ( ) ; // derived object, should show warning message
}
}
TEST ( UMat , DISABLED_regression_5991 )
{
int sz [ ] = { 2 , 3 , 2 } ;
UMat mat ( 3 , sz , CV_32F , Scalar ( 1 ) ) ;
ASSERT_NO_THROW ( mat . convertTo ( mat , CV_8U ) ) ;
EXPECT_EQ ( sz [ 0 ] , mat . size [ 0 ] ) ;
EXPECT_EQ ( sz [ 1 ] , mat . size [ 1 ] ) ;
EXPECT_EQ ( sz [ 2 ] , mat . size [ 2 ] ) ;
EXPECT_EQ ( 0 , cvtest : : norm ( mat . getMat ( ACCESS_READ ) , Mat ( 3 , sz , CV_8U , Scalar ( 1 ) ) , NORM_INF ) ) ;
}
TEST ( UMat , testTempObjects_Mat_issue_8693 )
{
UMat srcUMat ( 3 , 4 , CV_32FC1 ) ;
Mat srcMat ;
randu ( srcUMat , - 1.f , 1.f ) ;
srcUMat . copyTo ( srcMat ) ;
reduce ( srcUMat , srcUMat , 0 , REDUCE_SUM ) ;
reduce ( srcMat , srcMat , 0 , REDUCE_SUM ) ;
srcUMat . convertTo ( srcUMat , CV_64FC1 ) ;
srcMat . convertTo ( srcMat , CV_64FC1 ) ;
EXPECT_EQ ( 0 , cvtest : : norm ( srcUMat . getMat ( ACCESS_READ ) , srcMat , NORM_INF ) ) ;
}
TEST ( UMat , resize_Mat_issue_13577 )
{
// save the current state
bool useOCL = cv : : ocl : : useOpenCL ( ) ;
cv : : ocl : : setUseOpenCL ( false ) ;
UMat foo ( 10 , 10 , CV_32FC1 ) ;
cv : : resize ( foo , foo , cv : : Size ( ) , .5 , .5 ) ;
cv : : ocl : : setUseOpenCL ( useOCL ) ; // restore state
}
TEST ( UMat , exceptions_refcounts_issue_20594 )
{
if ( ! cv : : ocl : : useOpenCL ( ) )
{
// skip test, difficult to create exception scenario without OpenCL
std : : cout < < " OpenCL is not enabled. Skip test " < < std : : endl ;
return ;
}
UMat umat1 ( 10 , 10 , CV_8UC1 ) ;
EXPECT_EQ ( 0 , umat1 . u - > refcount ) ;
// cause exception in underlying allocator
void * const original_handle = umat1 . u - > handle ;
umat1 . u - > handle = NULL ;
try
{
Mat mat1 = umat1 . getMat ( ACCESS_RW ) ;
}
catch ( . . . )
{
// nothing
}
// check for correct refcount, and no change of intentional bad handle
EXPECT_EQ ( 0 , umat1 . u - > refcount ) ;
EXPECT_EQ ( NULL , umat1 . u - > handle ) ;
// reset UMat to good state
umat1 . u - > refcount = 0 ;
umat1 . u - > handle = original_handle ;
}
} } // namespace opencv_test::ocl