/*
    Copyright (c) 2005-2017 Intel Corporation

    Licensed under the Apache License, Version 2.0 (the "License");
    you may not use this file except in compliance with the License.
    You may obtain a copy of the License at

        http://www.apache.org/licenses/LICENSE-2.0

    Unless required by applicable law or agreed to in writing, software
    distributed under the License is distributed on an "AS IS" BASIS,
    WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
    See the License for the specific language governing permissions and
    limitations under the 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<typename F> class task_handle_task;
}

class task_group;
class structured_task_group;

template<typename F>
class task_handle : internal::no_assign {
    template<typename _F> 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<typename F>
class task_handle_task : public task {
    task_handle<F>& my_handle;
    task* execute() __TBB_override {
        my_handle();
        return NULL;
    }
public:
    task_handle_task( task_handle<F>& 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<typename F>
    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<typename F, typename Task>
    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() __TBB_NOEXCEPT(false) {
        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<typename F>
    void run( task_handle<F>& h ) {
        internal_run< task_handle<F>, internal::task_handle_task<F> >( 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() ) {
            // TODO: the reset method is not thread-safe. Ensure the correct behavior.
            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 __SUNPRO_CC
    template<typename F>
    void run( task_handle<F>& h ) {
        internal_run< task_handle<F>, internal::task_handle_task<F> >( h );
    }
#else
    using task_group_base::run;
#endif

    template<typename F>
    void run( const F& f ) {
        internal_run< const F, internal::function_task<F> >( f );
    }

    template<typename F>
    task_group_status run_and_wait( const F& f ) {
        return internal_run_and_wait<const F>( f );
    }

    template<typename F>
    task_group_status run_and_wait( task_handle<F>& h ) {
      h.mark_scheduled();
      return internal_run_and_wait< task_handle<F> >( h );
    }
}; // class task_group

class structured_task_group : public internal::task_group_base {
public:
    template<typename F>
    task_group_status run_and_wait ( task_handle<F>& h ) {
        h.mark_scheduled();
        return internal_run_and_wait< task_handle<F> >( 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<class F>
task_handle<F> make_task( const F& f ) {
    return task_handle<F>( f );
}

} // namespace tbb

#endif /* __TBB_TASK_GROUP_CONTEXT */

#endif /* __TBB_task_group_H */