// 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) 2019 Intel Corporation
# include "test_precomp.hpp"
# include <opencv2/gapi/gcomputation_async.hpp>
# include <opencv2/gapi/gcompiled_async.hpp>
# include <opencv2/gapi/gasync_context.hpp>
# include <condition_variable>
# include <stdexcept>
namespace opencv_test
{
//Main idea behind these tests is to have the same test script that is parameterized in order to test all setups (GCompiled vs apply, callback vs future).
//So these differences are factored into devoted helper classes (mixins) which are then used by the common test script by help of CRTP.
//Actual GAPI Computation with parameters to run on is mixed into test via CRTP as well.
struct SumOfSum2x2 {
cv : : GComputation sum_of_sum ;
SumOfSum2x2 ( ) : sum_of_sum ( [ ] {
cv : : GMat in ;
cv : : GScalar out = cv : : gapi : : sum ( in + in ) ;
return GComputation { in , out } ;
} )
{ }
const cv : : Size sz { 2 , 2 } ;
cv : : Mat in_mat { sz , CV_8U , cv : : Scalar ( 1 ) } ;
cv : : Scalar out_sc ;
cv : : GCompiled compile ( ) {
return sum_of_sum . compile ( descr_of ( in_mat ) ) ;
}
cv : : GComputation & computation ( ) {
return sum_of_sum ;
}
cv : : GCompileArgs compile_args ( ) {
return { } ;
}
cv : : GRunArgs in_args ( ) {
return cv : : gin ( in_mat ) ;
}
cv : : GRunArgsP out_args ( ) {
return cv : : gout ( out_sc ) ;
}
void verify ( ) {
EXPECT_EQ ( 8 , out_sc [ 0 ] ) ;
}
} ;
namespace {
G_TYPED_KERNEL ( GThrow , < GMat ( GMat ) > , " org.opencv.test.throw " )
{
static GMatDesc outMeta ( GMatDesc in ) { return in ; }
} ;
struct gthrow_exception : std : : runtime_error {
using std : : runtime_error : : runtime_error ;
} ;
GAPI_OCV_KERNEL ( GThrowImpl , GThrow )
{
static void run ( const cv : : Mat & in , cv : : Mat & )
{
//this condition is needed to avoid "Unreachable code" warning on windows inside OCVCallHelper
if ( ! in . empty ( ) )
{
throw gthrow_exception { " test " } ;
}
}
} ;
//TODO: unify with callback helper code
struct cancel_struct {
std : : atomic < int > num_tasks_to_spawn ;
cv : : gapi : : wip : : GAsyncContext ctx ;
cancel_struct ( int tasks_to_spawn ) : num_tasks_to_spawn ( tasks_to_spawn ) { }
} ;
G_TYPED_KERNEL ( GCancelationAdHoc , < GMat ( GMat , cancel_struct * ) > , " org.opencv.test.cancel_ad_hoc " )
{
static GMatDesc outMeta ( GMatDesc in , cancel_struct * ) { return in ; }
} ;
GAPI_OCV_KERNEL ( GCancelationAdHocImpl , GCancelationAdHoc )
{
static void run ( const cv : : Mat & , cancel_struct * cancel_struct_p , cv : : Mat & ) {
auto & cancel_struct_ = * cancel_struct_p ;
auto num_tasks_to_spawn = - - cancel_struct_ . num_tasks_to_spawn ;
cancel_struct_ . ctx . cancel ( ) ;
EXPECT_GT ( num_tasks_to_spawn , 0 ) < < " Incorrect Test setup - to small number of tasks to feed the queue \n " ;
}
} ;
}
struct ExceptionOnExecution {
cv : : GComputation throwing_gcomp ;
ExceptionOnExecution ( ) : throwing_gcomp ( [ ] {
cv : : GMat in ;
auto gout = GThrow : : on ( in ) ;
return GComputation { in , gout } ;
} )
{ }
const cv : : Size sz { 2 , 2 } ;
cv : : Mat in_mat { sz , CV_8U , cv : : Scalar ( 1 ) } ;
cv : : Mat out ;
cv : : GCompiled compile ( ) {
return throwing_gcomp . compile ( descr_of ( in_mat ) , compile_args ( ) ) ;
}
cv : : GComputation & computation ( ) {
return throwing_gcomp ;
}
cv : : GRunArgs in_args ( ) {
return cv : : gin ( in_mat ) ;
}
cv : : GRunArgsP out_args ( ) {
return cv : : gout ( out ) ;
}
cv : : GCompileArgs compile_args ( ) {
auto pkg = cv : : gapi : : kernels < GThrowImpl > ( ) ;
return cv : : compile_args ( pkg ) ;
}
} ;
struct SelfCanceling {
cv : : GComputation self_cancel ;
SelfCanceling ( cancel_struct * cancel_struct_p ) : self_cancel ( [ cancel_struct_p ] {
cv : : GMat in ;
cv : : GMat out = GCancelationAdHoc : : on ( in , cancel_struct_p ) ;
return GComputation { in , out } ;
} )
{ }
const cv : : Size sz { 2 , 2 } ;
cv : : Mat in_mat { sz , CV_8U , cv : : Scalar ( 1 ) } ;
cv : : Mat out_mat ;
cv : : GCompiled compile ( ) {
return self_cancel . compile ( descr_of ( in_mat ) , compile_args ( ) ) ;
}
cv : : GComputation & computation ( ) {
return self_cancel ;
}
cv : : GRunArgs in_args ( ) {
return cv : : gin ( in_mat ) ;
}
cv : : GRunArgsP out_args ( ) {
return cv : : gout ( out_mat ) ;
}
cv : : GCompileArgs compile_args ( ) {
auto pkg = cv : : gapi : : kernels < GCancelationAdHocImpl > ( ) ;
return cv : : compile_args ( pkg ) ;
}
} ;
template < typename crtp_final_t >
struct crtp_cast {
template < typename crtp_base_t >
static crtp_final_t * crtp_cast_ ( crtp_base_t * this_ )
{
return static_cast < crtp_final_t * > ( this_ ) ;
}
} ;
//Test Mixin, hiding details of callback based notification
template < typename crtp_final_t >
struct CallBack : crtp_cast < crtp_final_t > {
std : : atomic < bool > callback_called = { false } ;
std : : mutex mtx ;
std : : exception_ptr ep ;
std : : condition_variable cv ;
std : : function < void ( std : : exception_ptr ) > callback ( ) {
return [ & ] ( std : : exception_ptr ep_ ) {
ep = ep_ ;
callback_called = true ;
mtx . lock ( ) ;
mtx . unlock ( ) ;
cv . notify_one ( ) ;
} ;
} ;
template < typename . . . Args >
void start_async ( Args & & . . . args ) {
this - > crtp_cast_ ( this ) - > async ( callback ( ) , std : : forward < Args > ( args ) . . . ) ;
}
template < typename . . . Args >
void start_async ( cv : : gapi : : wip : : GAsyncContext & ctx , Args & & . . . args ) {
this - > crtp_cast_ ( this ) - > async ( ctx , callback ( ) , std : : forward < Args > ( args ) . . . ) ;
}
void wait_for_result ( )
{
std : : unique_lock < std : : mutex > lck { mtx } ;
cv . wait ( lck , [ & ] { return callback_called = = true ; } ) ;
if ( ep )
{
std : : rethrow_exception ( ep ) ;
}
}
} ;
//Test Mixin, hiding details of future based notification
template < typename crtp_final_t >
struct Future : crtp_cast < crtp_final_t > {
std : : future < void > f ;
template < typename . . . Args >
void start_async ( Args & & . . . args ) {
f = this - > crtp_cast_ ( this ) - > async ( std : : forward < Args > ( args ) . . . ) ;
}
void wait_for_result ( )
{
f . get ( ) ;
}
} ;
//Test Mixin, hiding details of using compiled GAPI object
template < typename crtp_final_t >
struct AsyncCompiled : crtp_cast < crtp_final_t > {
template < typename . . . Args >
auto async ( Args & & . . . args ) - > decltype ( cv : : gapi : : wip : : async ( std : : declval < cv : : GCompiled & > ( ) , std : : forward < Args > ( args ) . . . ) ) {
auto gcmpld = this - > crtp_cast_ ( this ) - > compile ( ) ;
return cv : : gapi : : wip : : async ( gcmpld , std : : forward < Args > ( args ) . . . ) ;
}
template < typename . . . Args >
auto async ( cv : : gapi : : wip : : GAsyncContext & ctx , Args & & . . . args ) - >
decltype ( cv : : gapi : : wip : : async ( std : : declval < cv : : GCompiled & > ( ) , std : : forward < Args > ( args ) . . . , std : : declval < cv : : gapi : : wip : : GAsyncContext & > ( ) ) )
{
auto gcmpld = this - > crtp_cast_ ( this ) - > compile ( ) ;
return cv : : gapi : : wip : : async ( gcmpld , std : : forward < Args > ( args ) . . . , ctx ) ;
}
} ;
//Test Mixin, hiding details of calling apply (async_apply) on GAPI Computation object
template < typename crtp_final_t >
struct AsyncApply : crtp_cast < crtp_final_t > {
template < typename . . . Args >
auto async ( Args & & . . . args ) - >
decltype ( cv : : gapi : : wip : : async_apply ( std : : declval < cv : : GComputation & > ( ) , std : : forward < Args > ( args ) . . . , std : : declval < cv : : GCompileArgs > ( ) ) )
{
return cv : : gapi : : wip : : async_apply (
this - > crtp_cast_ ( this ) - > computation ( ) , std : : forward < Args > ( args ) . . . , this - > crtp_cast_ ( this ) - > compile_args ( )
) ;
}
template < typename . . . Args >
auto async ( cv : : gapi : : wip : : GAsyncContext & ctx , Args & & . . . args ) - >
decltype ( cv : : gapi : : wip : : async_apply ( std : : declval < cv : : GComputation & > ( ) , std : : forward < Args > ( args ) . . . , std : : declval < cv : : GCompileArgs > ( ) , std : : declval < cv : : gapi : : wip : : GAsyncContext & > ( ) ) )
{
return cv : : gapi : : wip : : async_apply (
this - > crtp_cast_ ( this ) - > computation ( ) , std : : forward < Args > ( args ) . . . , this - > crtp_cast_ ( this ) - > compile_args ( ) , ctx
) ;
}
} ;
template < typename case_t >
struct normal : : : testing : : Test , case_t { } ;
TYPED_TEST_CASE_P ( normal ) ;
TYPED_TEST_P ( normal , basic ) {
//Normal scenario: start function asynchronously and wait for the result, and verify it
this - > start_async ( this - > in_args ( ) , this - > out_args ( ) ) ;
this - > wait_for_result ( ) ;
this - > verify ( ) ;
}
REGISTER_TYPED_TEST_CASE_P ( normal ,
basic
) ;
template < typename case_t >
struct exception : : : testing : : Test , case_t { } ;
TYPED_TEST_CASE_P ( exception ) ;
TYPED_TEST_P ( exception , basic ) {
//Exceptional scenario: start function asynchronously and make sure exception is passed to the user
this - > start_async ( this - > in_args ( ) , this - > out_args ( ) ) ;
EXPECT_THROW ( this - > wait_for_result ( ) , gthrow_exception ) ;
}
REGISTER_TYPED_TEST_CASE_P ( exception ,
basic
) ;
template < typename case_t >
struct stress : : : testing : : Test { } ;
TYPED_TEST_CASE_P ( stress ) ;
TYPED_TEST_P ( stress , test ) {
//Some stress testing: use a number of threads to start a bunch of async requests
const std : : size_t request_per_thread = 10 ;
const std : : size_t number_of_threads = 4 ;
auto thread_body = [ & ] ( ) {
std : : vector < TypeParam > requests ( request_per_thread ) ;
for ( auto & & r : requests ) {
r . start_async ( r . in_args ( ) , r . out_args ( ) ) ;
}
for ( auto & & r : requests ) {
r . wait_for_result ( ) ;
r . verify ( ) ;
}
} ;
std : : vector < std : : thread > pool { number_of_threads } ;
for ( auto & & t : pool ) {
t = std : : thread { thread_body } ;
}
for ( auto & & t : pool ) {
t . join ( ) ;
}
}
REGISTER_TYPED_TEST_CASE_P ( stress , test ) ;
template < typename case_t >
struct cancel : : : testing : : Test { } ;
TYPED_TEST_CASE_P ( cancel ) ;
TYPED_TEST_P ( cancel , basic ) {
constexpr int num_tasks = 100 ;
cancel_struct cancel_struct_ { num_tasks } ;
std : : vector < TypeParam > requests ; requests . reserve ( num_tasks ) ;
for ( auto i = num_tasks ; i > 0 ; i - - ) {
requests . emplace_back ( & cancel_struct_ ) ;
}
for ( auto & & r : requests ) {
//first request will cancel other on it's execution
r . start_async ( cancel_struct_ . ctx , r . in_args ( ) , r . out_args ( ) ) ;
}
unsigned int canceled = 0 ;
for ( auto & & r : requests ) {
try {
r . wait_for_result ( ) ;
} catch ( cv : : gapi : : wip : : GAsyncCanceled & ) {
+ + canceled ;
}
}
ASSERT_GT ( canceled , 0u ) ;
}
namespace {
GRunArgs deep_copy_out_args ( const GRunArgsP & args ) {
GRunArgs result ; result . reserve ( args . size ( ) ) ;
for ( auto & & arg : args ) {
//FIXME: replace this switch with use of visit() on variant, when it will be available
switch ( arg . index ( ) ) {
case GRunArgP : : index_of < cv : : UMat * > ( ) : result . emplace_back ( * util : : get < cv : : UMat * > ( arg ) ) ; break ;
case GRunArgP : : index_of < cv : : Mat * > ( ) : result . emplace_back ( * util : : get < cv : : Mat * > ( arg ) ) ; break ;
case GRunArgP : : index_of < cv : : Scalar * > ( ) : result . emplace_back ( * util : : get < cv : : Scalar * > ( arg ) ) ; break ;
case GRunArgP : : index_of < cv : : detail : : VectorRef > ( ) : result . emplace_back ( util : : get < cv : : detail : : VectorRef > ( arg ) ) ; break ;
default : ;
}
}
return result ;
}
GRunArgsP args_p_from_args ( GRunArgs & args ) {
GRunArgsP result ; result . reserve ( args . size ( ) ) ;
for ( auto & & arg : args ) {
switch ( arg . index ( ) ) {
case GRunArg : : index_of < cv : : Mat > ( ) : result . emplace_back ( & util : : get < cv : : Mat > ( arg ) ) ; break ;
case GRunArg : : index_of < cv : : UMat > ( ) : result . emplace_back ( & util : : get < cv : : UMat > ( arg ) ) ; break ;
case GRunArg : : index_of < cv : : Scalar > ( ) : result . emplace_back ( & util : : get < cv : : Scalar > ( arg ) ) ; break ;
case GRunArg : : index_of < cv : : detail : : VectorRef > ( ) : result . emplace_back ( util : : get < cv : : detail : : VectorRef > ( arg ) ) ; break ;
default : ;
}
}
return result ;
}
}
REGISTER_TYPED_TEST_CASE_P ( cancel , basic ) ;
template < typename case_t >
struct output_args_lifetime : : : testing : : Test {
static constexpr const int num_of_requests = 20 ;
} ;
TYPED_TEST_CASE_P ( output_args_lifetime ) ;
//There are intentionally no actual checks (asserts and verify) in output_args_lifetime tests.
//They are more of example use-cases than real tests. (ASAN/valgrind can still catch issues here)
TYPED_TEST_P ( output_args_lifetime , callback ) {
std : : atomic < int > active_requests = { 0 } ;
for ( int i = 0 ; i < this - > num_of_requests ; i + + )
{
TypeParam r ;
//As output arguments are __captured by reference__ calling code
//__must__ ensure they live long enough to complete asynchronous activity.
//(i.e. live at least until callback is called)
auto out_args_ptr = std : : make_shared < cv : : GRunArgs > ( deep_copy_out_args ( r . out_args ( ) ) ) ;
//Extend lifetime of out_args_ptr content by capturing it into a callback
auto cb = [ & active_requests , out_args_ptr ] ( std : : exception_ptr ) {
- - active_requests ;
} ;
+ + active_requests ;
r . async ( cb , r . in_args ( ) , args_p_from_args ( * out_args_ptr ) ) ;
}
while ( active_requests ) {
std : : this_thread : : sleep_for ( std : : chrono : : milliseconds { 2 } ) ;
}
}
TYPED_TEST_P ( output_args_lifetime , future ) {
std : : vector < std : : future < void > > fs ( this - > num_of_requests ) ;
std : : vector < std : : shared_ptr < cv : : GRunArgs > > out_ptrs ( this - > num_of_requests ) ;
for ( int i = 0 ; i < this - > num_of_requests ; i + + )
{
TypeParam r ;
//As output arguments are __captured by reference__ calling code
//__must__ ensure they live long enough to complete asynchronous activity.
//(i.e. live at least until future.get()/wait() is returned)
auto out_args_ptr = std : : make_shared < cv : : GRunArgs > ( deep_copy_out_args ( r . out_args ( ) ) ) ;
//Extend lifetime of out_args_ptr content
out_ptrs [ i ] = out_args_ptr ;
fs [ i ] = r . async ( r . in_args ( ) , args_p_from_args ( * out_args_ptr ) ) ;
}
for ( auto const & ftr : fs ) {
ftr . wait ( ) ;
}
}
REGISTER_TYPED_TEST_CASE_P ( output_args_lifetime , callback , future ) ;
//little helpers to match up all combinations of setups
template < typename compute_fixture_t , template < typename > class . . . args_t >
struct Case
: compute_fixture_t ,
args_t < Case < compute_fixture_t , args_t . . . > > . . .
{
template < typename . . . Args >
Case ( Args & & . . . args ) : compute_fixture_t ( std : : forward < Args > ( args ) . . . ) { }
Case ( Case const & ) = default ;
Case ( Case & & ) = default ;
Case ( ) = default ;
} ;
template < typename computation_t >
using cases = : : testing : : Types <
Case < computation_t , CallBack , AsyncCompiled > ,
Case < computation_t , CallBack , AsyncApply > ,
Case < computation_t , Future , AsyncCompiled > ,
Case < computation_t , Future , AsyncApply >
> ;
INSTANTIATE_TYPED_TEST_CASE_P ( AsyncAPINormalFlow_ , normal , cases < SumOfSum2x2 > ) ;
INSTANTIATE_TYPED_TEST_CASE_P ( AsyncAPIExceptionHandling_ , exception , cases < ExceptionOnExecution > ) ;
INSTANTIATE_TYPED_TEST_CASE_P ( AsyncAPIStress , stress , cases < SumOfSum2x2 > ) ;
INSTANTIATE_TYPED_TEST_CASE_P ( AsyncAPICancelation , cancel , cases < SelfCanceling > ) ;
template < typename computation_t >
using explicit_wait_cases = : : testing : : Types <
Case < computation_t , AsyncCompiled > ,
Case < computation_t , AsyncApply > ,
Case < computation_t , AsyncCompiled > ,
Case < computation_t , AsyncApply >
> ;
INSTANTIATE_TYPED_TEST_CASE_P ( AsyncAPIOutArgsLifetTime , output_args_lifetime , explicit_wait_cases < SumOfSum2x2 > ) ;
} // namespace opencv_test