/* Copyright 2005-2014 Intel Corporation. All Rights Reserved. This file is part of Threading Building Blocks. Threading Building Blocks is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License version 2 as published by the Free Software Foundation. Threading Building Blocks is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Threading Building Blocks; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA As a special exception, you may use this file as part of a free software library without restriction. Specifically, if other files instantiate templates or use macros or inline functions from this file, or you compile this file and link it with other files to produce an executable, this file does not by itself cause the resulting executable to be covered by the GNU General Public License. This exception does not however invalidate any other reasons why the executable file might be covered by the GNU General Public License. */ #ifndef __TBB_task_group_H #define __TBB_task_group_H #include "task.h" #include "tbb_exception.h" #if __TBB_TASK_GROUP_CONTEXT namespace tbb { namespace internal { template class task_handle_task; } class task_group; class structured_task_group; template class task_handle : internal::no_assign { template friend class internal::task_handle_task; friend class task_group; friend class structured_task_group; static const intptr_t scheduled = 0x1; F my_func; intptr_t my_state; void mark_scheduled () { // The check here is intentionally lax to avoid the impact of interlocked operation if ( my_state & scheduled ) internal::throw_exception( internal::eid_invalid_multiple_scheduling ); my_state |= scheduled; } public: task_handle( const F& f ) : my_func(f), my_state(0) {} void operator() () const { my_func(); } }; enum task_group_status { not_complete, complete, canceled }; namespace internal { template class task_handle_task : public task { task_handle& my_handle; /*override*/ task* execute() { my_handle(); return NULL; } public: task_handle_task( task_handle& h ) : my_handle(h) { h.mark_scheduled(); } }; class task_group_base : internal::no_copy { protected: empty_task* my_root; task_group_context my_context; task& owner () { return *my_root; } template task_group_status internal_run_and_wait( F& f ) { __TBB_TRY { if ( !my_context.is_group_execution_cancelled() ) f(); } __TBB_CATCH( ... ) { my_context.register_pending_exception(); } return wait(); } template void internal_run( F& f ) { owner().spawn( *new( owner().allocate_additional_child_of(*my_root) ) Task(f) ); } public: task_group_base( uintptr_t traits = 0 ) : my_context(task_group_context::bound, task_group_context::default_traits | traits) { my_root = new( task::allocate_root(my_context) ) empty_task; my_root->set_ref_count(1); } ~task_group_base() { if( my_root->ref_count() > 1 ) { bool stack_unwinding_in_progress = std::uncaught_exception(); // Always attempt to do proper cleanup to avoid inevitable memory corruption // in case of missing wait (for the sake of better testability & debuggability) if ( !is_canceling() ) cancel(); __TBB_TRY { my_root->wait_for_all(); } __TBB_CATCH (...) { task::destroy(*my_root); __TBB_RETHROW(); } task::destroy(*my_root); if ( !stack_unwinding_in_progress ) internal::throw_exception( internal::eid_missing_wait ); } else { task::destroy(*my_root); } } template void run( task_handle& h ) { internal_run< task_handle, internal::task_handle_task >( h ); } task_group_status wait() { __TBB_TRY { my_root->wait_for_all(); } __TBB_CATCH( ... ) { my_context.reset(); __TBB_RETHROW(); } if ( my_context.is_group_execution_cancelled() ) { my_context.reset(); return canceled; } return complete; } bool is_canceling() { return my_context.is_group_execution_cancelled(); } void cancel() { my_context.cancel_group_execution(); } }; // class task_group_base } // namespace internal class task_group : public internal::task_group_base { public: task_group () : task_group_base( task_group_context::concurrent_wait ) {} #if TBB_DEPRECATED ~task_group() __TBB_TRY { __TBB_ASSERT( my_root->ref_count() != 0, NULL ); if( my_root->ref_count() > 1 ) my_root->wait_for_all(); } #if TBB_USE_EXCEPTIONS catch (...) { // Have to destroy my_root here as the base class destructor won't be called task::destroy(*my_root); throw; } #endif /* TBB_USE_EXCEPTIONS */ #endif /* TBB_DEPRECATED */ #if __SUNPRO_CC template void run( task_handle& h ) { internal_run< task_handle, internal::task_handle_task >( h ); } #else using task_group_base::run; #endif template void run( const F& f ) { internal_run< const F, internal::function_task >( f ); } template task_group_status run_and_wait( const F& f ) { return internal_run_and_wait( f ); } template task_group_status run_and_wait( task_handle& h ) { h.mark_scheduled(); return internal_run_and_wait< task_handle >( h ); } }; // class task_group class structured_task_group : public internal::task_group_base { public: template task_group_status run_and_wait ( task_handle& h ) { h.mark_scheduled(); return internal_run_and_wait< task_handle >( h ); } task_group_status wait() { task_group_status res = task_group_base::wait(); my_root->set_ref_count(1); return res; } }; // class structured_task_group inline bool is_current_task_group_canceling() { return task::self().is_cancelled(); } template task_handle make_task( const F& f ) { return task_handle( f ); } } // namespace tbb #endif /* __TBB_TASK_GROUP_CONTEXT */ #endif /* __TBB_task_group_H */