Insane_DNS/libraries/asio-1.28.1/include/asio/impl/spawn.hpp

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//
// impl/spawn.hpp
// ~~~~~~~~~~~~~~
//
// Copyright (c) 2003-2023 Christopher M. Kohlhoff (chris at kohlhoff dot com)
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
//
#ifndef ASIO_IMPL_SPAWN_HPP
#define ASIO_IMPL_SPAWN_HPP
#if defined(_MSC_VER) && (_MSC_VER >= 1200)
# pragma once
#endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
#include "asio/detail/config.hpp"
#include "asio/associated_allocator.hpp"
#include "asio/associated_cancellation_slot.hpp"
#include "asio/associated_executor.hpp"
#include "asio/async_result.hpp"
#include "asio/bind_executor.hpp"
#include "asio/detail/atomic_count.hpp"
#include "asio/detail/bind_handler.hpp"
#include "asio/detail/handler_alloc_helpers.hpp"
#include "asio/detail/handler_cont_helpers.hpp"
#include "asio/detail/handler_invoke_helpers.hpp"
#include "asio/detail/memory.hpp"
#include "asio/detail/noncopyable.hpp"
#include "asio/detail/type_traits.hpp"
#include "asio/detail/utility.hpp"
#include "asio/detail/variadic_templates.hpp"
#include "asio/system_error.hpp"
#if defined(ASIO_HAS_STD_TUPLE)
# include <tuple>
#endif // defined(ASIO_HAS_STD_TUPLE)
#if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
# include <boost/context/fiber.hpp>
#endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
#include "asio/detail/push_options.hpp"
namespace asio {
namespace detail {
#if !defined(ASIO_NO_EXCEPTIONS)
inline void spawned_thread_rethrow(void* ex)
{
if (*static_cast<exception_ptr*>(ex))
rethrow_exception(*static_cast<exception_ptr*>(ex));
}
#endif // !defined(ASIO_NO_EXCEPTIONS)
#if defined(ASIO_HAS_BOOST_COROUTINE)
// Spawned thread implementation using Boost.Coroutine.
class spawned_coroutine_thread : public spawned_thread_base
{
public:
#if defined(BOOST_COROUTINES_UNIDIRECT) || defined(BOOST_COROUTINES_V2)
typedef boost::coroutines::pull_coroutine<void> callee_type;
typedef boost::coroutines::push_coroutine<void> caller_type;
#else
typedef boost::coroutines::coroutine<void()> callee_type;
typedef boost::coroutines::coroutine<void()> caller_type;
#endif
spawned_coroutine_thread(caller_type& caller)
: caller_(caller),
on_suspend_fn_(0),
on_suspend_arg_(0)
{
}
template <typename F>
static spawned_thread_base* spawn(ASIO_MOVE_ARG(F) f,
const boost::coroutines::attributes& attributes,
cancellation_slot parent_cancel_slot = cancellation_slot(),
cancellation_state cancel_state = cancellation_state())
{
spawned_coroutine_thread* spawned_thread = 0;
callee_type callee(entry_point<typename decay<F>::type>(
ASIO_MOVE_CAST(F)(f), &spawned_thread), attributes);
spawned_thread->callee_.swap(callee);
spawned_thread->parent_cancellation_slot_ = parent_cancel_slot;
spawned_thread->cancellation_state_ = cancel_state;
return spawned_thread;
}
template <typename F>
static spawned_thread_base* spawn(ASIO_MOVE_ARG(F) f,
cancellation_slot parent_cancel_slot = cancellation_slot(),
cancellation_state cancel_state = cancellation_state())
{
return spawn(ASIO_MOVE_CAST(F)(f), boost::coroutines::attributes(),
parent_cancel_slot, cancel_state);
}
void resume()
{
callee_();
if (on_suspend_fn_)
{
void (*fn)(void*) = on_suspend_fn_;
void* arg = on_suspend_arg_;
on_suspend_fn_ = 0;
fn(arg);
}
}
void suspend_with(void (*fn)(void*), void* arg)
{
if (throw_if_cancelled_)
if (!!cancellation_state_.cancelled())
throw_error(asio::error::operation_aborted, "yield");
has_context_switched_ = true;
on_suspend_fn_ = fn;
on_suspend_arg_ = arg;
caller_();
}
void destroy()
{
callee_type callee;
callee.swap(callee_);
if (terminal_)
callee();
}
private:
template <typename Function>
class entry_point
{
public:
template <typename F>
entry_point(ASIO_MOVE_ARG(F) f,
spawned_coroutine_thread** spawned_thread_out)
: function_(ASIO_MOVE_CAST(F)(f)),
spawned_thread_out_(spawned_thread_out)
{
}
void operator()(caller_type& caller)
{
Function function(ASIO_MOVE_CAST(Function)(function_));
spawned_coroutine_thread spawned_thread(caller);
*spawned_thread_out_ = &spawned_thread;
spawned_thread_out_ = 0;
spawned_thread.suspend();
#if !defined(ASIO_NO_EXCEPTIONS)
try
#endif // !defined(ASIO_NO_EXCEPTIONS)
{
function(&spawned_thread);
spawned_thread.terminal_ = true;
spawned_thread.suspend();
}
#if !defined(ASIO_NO_EXCEPTIONS)
catch (const boost::coroutines::detail::forced_unwind&)
{
throw;
}
catch (...)
{
exception_ptr ex = current_exception();
spawned_thread.terminal_ = true;
spawned_thread.suspend_with(spawned_thread_rethrow, &ex);
}
#endif // !defined(ASIO_NO_EXCEPTIONS)
}
private:
Function function_;
spawned_coroutine_thread** spawned_thread_out_;
};
caller_type& caller_;
callee_type callee_;
void (*on_suspend_fn_)(void*);
void* on_suspend_arg_;
};
#endif // defined(ASIO_HAS_BOOST_COROUTINE)
#if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
// Spawned thread implementation using Boost.Context's fiber.
class spawned_fiber_thread : public spawned_thread_base
{
public:
typedef boost::context::fiber fiber_type;
spawned_fiber_thread(ASIO_MOVE_ARG(fiber_type) caller)
: caller_(ASIO_MOVE_CAST(fiber_type)(caller)),
on_suspend_fn_(0),
on_suspend_arg_(0)
{
}
template <typename StackAllocator, typename F>
static spawned_thread_base* spawn(allocator_arg_t,
ASIO_MOVE_ARG(StackAllocator) stack_allocator,
ASIO_MOVE_ARG(F) f,
cancellation_slot parent_cancel_slot = cancellation_slot(),
cancellation_state cancel_state = cancellation_state())
{
spawned_fiber_thread* spawned_thread = 0;
fiber_type callee(allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
entry_point<typename decay<F>::type>(
ASIO_MOVE_CAST(F)(f), &spawned_thread));
callee = fiber_type(ASIO_MOVE_CAST(fiber_type)(callee)).resume();
spawned_thread->callee_ = ASIO_MOVE_CAST(fiber_type)(callee);
spawned_thread->parent_cancellation_slot_ = parent_cancel_slot;
spawned_thread->cancellation_state_ = cancel_state;
return spawned_thread;
}
template <typename F>
static spawned_thread_base* spawn(ASIO_MOVE_ARG(F) f,
cancellation_slot parent_cancel_slot = cancellation_slot(),
cancellation_state cancel_state = cancellation_state())
{
return spawn(allocator_arg_t(), boost::context::fixedsize_stack(),
ASIO_MOVE_CAST(F)(f), parent_cancel_slot, cancel_state);
}
void resume()
{
callee_ = fiber_type(ASIO_MOVE_CAST(fiber_type)(callee_)).resume();
if (on_suspend_fn_)
{
void (*fn)(void*) = on_suspend_fn_;
void* arg = on_suspend_arg_;
on_suspend_fn_ = 0;
fn(arg);
}
}
void suspend_with(void (*fn)(void*), void* arg)
{
if (throw_if_cancelled_)
if (!!cancellation_state_.cancelled())
throw_error(asio::error::operation_aborted, "yield");
has_context_switched_ = true;
on_suspend_fn_ = fn;
on_suspend_arg_ = arg;
caller_ = fiber_type(ASIO_MOVE_CAST(fiber_type)(caller_)).resume();
}
void destroy()
{
fiber_type callee = ASIO_MOVE_CAST(fiber_type)(callee_);
if (terminal_)
fiber_type(ASIO_MOVE_CAST(fiber_type)(callee)).resume();
}
private:
template <typename Function>
class entry_point
{
public:
template <typename F>
entry_point(ASIO_MOVE_ARG(F) f,
spawned_fiber_thread** spawned_thread_out)
: function_(ASIO_MOVE_CAST(F)(f)),
spawned_thread_out_(spawned_thread_out)
{
}
fiber_type operator()(ASIO_MOVE_ARG(fiber_type) caller)
{
Function function(ASIO_MOVE_CAST(Function)(function_));
spawned_fiber_thread spawned_thread(
ASIO_MOVE_CAST(fiber_type)(caller));
*spawned_thread_out_ = &spawned_thread;
spawned_thread_out_ = 0;
spawned_thread.suspend();
#if !defined(ASIO_NO_EXCEPTIONS)
try
#endif // !defined(ASIO_NO_EXCEPTIONS)
{
function(&spawned_thread);
spawned_thread.terminal_ = true;
spawned_thread.suspend();
}
#if !defined(ASIO_NO_EXCEPTIONS)
catch (const boost::context::detail::forced_unwind&)
{
throw;
}
catch (...)
{
exception_ptr ex = current_exception();
spawned_thread.terminal_ = true;
spawned_thread.suspend_with(spawned_thread_rethrow, &ex);
}
#endif // !defined(ASIO_NO_EXCEPTIONS)
return ASIO_MOVE_CAST(fiber_type)(spawned_thread.caller_);
}
private:
Function function_;
spawned_fiber_thread** spawned_thread_out_;
};
fiber_type caller_;
fiber_type callee_;
void (*on_suspend_fn_)(void*);
void* on_suspend_arg_;
};
#endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
#if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
typedef spawned_fiber_thread default_spawned_thread_type;
#elif defined(ASIO_HAS_BOOST_COROUTINE)
typedef spawned_coroutine_thread default_spawned_thread_type;
#else
# error No spawn() implementation available
#endif
// Helper class to perform the initial resume on the correct executor.
class spawned_thread_resumer
{
public:
explicit spawned_thread_resumer(spawned_thread_base* spawned_thread)
: spawned_thread_(spawned_thread)
{
#if !defined(ASIO_HAS_MOVE)
spawned_thread->detach();
spawned_thread->attach(&spawned_thread_);
#endif // !defined(ASIO_HAS_MOVE)
}
#if defined(ASIO_HAS_MOVE)
spawned_thread_resumer(spawned_thread_resumer&& other) ASIO_NOEXCEPT
: spawned_thread_(other.spawned_thread_)
{
other.spawned_thread_ = 0;
}
#else // defined(ASIO_HAS_MOVE)
spawned_thread_resumer(
const spawned_thread_resumer& other) ASIO_NOEXCEPT
: spawned_thread_(other.spawned_thread_)
{
spawned_thread_->detach();
spawned_thread_->attach(&spawned_thread_);
}
#endif // defined(ASIO_HAS_MOVE)
~spawned_thread_resumer()
{
if (spawned_thread_)
spawned_thread_->destroy();
}
void operator()()
{
#if defined(ASIO_HAS_MOVE)
spawned_thread_->attach(&spawned_thread_);
#endif // defined(ASIO_HAS_MOVE)
spawned_thread_->resume();
}
private:
spawned_thread_base* spawned_thread_;
};
// Helper class to ensure spawned threads are destroyed on the correct executor.
class spawned_thread_destroyer
{
public:
explicit spawned_thread_destroyer(spawned_thread_base* spawned_thread)
: spawned_thread_(spawned_thread)
{
spawned_thread->detach();
#if !defined(ASIO_HAS_MOVE)
spawned_thread->attach(&spawned_thread_);
#endif // !defined(ASIO_HAS_MOVE)
}
#if defined(ASIO_HAS_MOVE)
spawned_thread_destroyer(spawned_thread_destroyer&& other) ASIO_NOEXCEPT
: spawned_thread_(other.spawned_thread_)
{
other.spawned_thread_ = 0;
}
#else // defined(ASIO_HAS_MOVE)
spawned_thread_destroyer(
const spawned_thread_destroyer& other) ASIO_NOEXCEPT
: spawned_thread_(other.spawned_thread_)
{
spawned_thread_->detach();
spawned_thread_->attach(&spawned_thread_);
}
#endif // defined(ASIO_HAS_MOVE)
~spawned_thread_destroyer()
{
if (spawned_thread_)
spawned_thread_->destroy();
}
void operator()()
{
if (spawned_thread_)
{
spawned_thread_->destroy();
spawned_thread_ = 0;
}
}
private:
spawned_thread_base* spawned_thread_;
};
// Base class for all completion handlers associated with a spawned thread.
template <typename Executor>
class spawn_handler_base
{
public:
typedef Executor executor_type;
typedef cancellation_slot cancellation_slot_type;
spawn_handler_base(const basic_yield_context<Executor>& yield)
: yield_(yield),
spawned_thread_(yield.spawned_thread_)
{
spawned_thread_->detach();
#if !defined(ASIO_HAS_MOVE)
spawned_thread_->attach(&spawned_thread_);
#endif // !defined(ASIO_HAS_MOVE)
}
#if defined(ASIO_HAS_MOVE)
spawn_handler_base(spawn_handler_base&& other) ASIO_NOEXCEPT
: yield_(other.yield_),
spawned_thread_(other.spawned_thread_)
{
other.spawned_thread_ = 0;
}
#else // defined(ASIO_HAS_MOVE)
spawn_handler_base(const spawn_handler_base& other) ASIO_NOEXCEPT
: yield_(other.yield_),
spawned_thread_(other.spawned_thread_)
{
spawned_thread_->detach();
spawned_thread_->attach(&spawned_thread_);
}
#endif // defined(ASIO_HAS_MOVE)
~spawn_handler_base()
{
if (spawned_thread_)
(post)(yield_.executor_, spawned_thread_destroyer(spawned_thread_));
}
executor_type get_executor() const ASIO_NOEXCEPT
{
return yield_.executor_;
}
cancellation_slot_type get_cancellation_slot() const ASIO_NOEXCEPT
{
return spawned_thread_->get_cancellation_slot();
}
void resume()
{
spawned_thread_resumer resumer(spawned_thread_);
spawned_thread_ = 0;
resumer();
}
protected:
const basic_yield_context<Executor>& yield_;
spawned_thread_base* spawned_thread_;
};
// Completion handlers for when basic_yield_context is used as a token.
template <typename Executor, typename Signature>
class spawn_handler;
template <typename Executor, typename R>
class spawn_handler<Executor, R()>
: public spawn_handler_base<Executor>
{
public:
typedef void return_type;
struct result_type {};
spawn_handler(const basic_yield_context<Executor>& yield, result_type&)
: spawn_handler_base<Executor>(yield)
{
}
void operator()()
{
this->resume();
}
static return_type on_resume(result_type&)
{
}
};
template <typename Executor, typename R>
class spawn_handler<Executor, R(asio::error_code)>
: public spawn_handler_base<Executor>
{
public:
typedef void return_type;
typedef asio::error_code* result_type;
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
void operator()(asio::error_code ec)
{
if (this->yield_.ec_)
{
*this->yield_.ec_ = ec;
result_ = 0;
}
else
result_ = &ec;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result)
throw_error(*result);
}
private:
result_type& result_;
};
template <typename Executor, typename R>
class spawn_handler<Executor, R(exception_ptr)>
: public spawn_handler_base<Executor>
{
public:
typedef void return_type;
typedef exception_ptr* result_type;
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
void operator()(exception_ptr ex)
{
result_ = &ex;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result)
rethrow_exception(*result);
}
private:
result_type& result_;
};
template <typename Executor, typename R, typename T>
class spawn_handler<Executor, R(T)>
: public spawn_handler_base<Executor>
{
public:
typedef T return_type;
typedef return_type* result_type;
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
void operator()(T value)
{
result_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
return ASIO_MOVE_CAST(return_type)(*result);
}
private:
result_type& result_;
};
template <typename Executor, typename R, typename T>
class spawn_handler<Executor, R(asio::error_code, T)>
: public spawn_handler_base<Executor>
{
public:
typedef T return_type;
struct result_type
{
asio::error_code* ec_;
return_type* value_;
};
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
void operator()(asio::error_code ec, T value)
{
if (this->yield_.ec_)
{
*this->yield_.ec_ = ec;
result_.ec_ = 0;
}
else
result_.ec_ = &ec;
result_.value_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result.ec_)
throw_error(*result.ec_);
return ASIO_MOVE_CAST(return_type)(*result.value_);
}
private:
result_type& result_;
};
template <typename Executor, typename R, typename T>
class spawn_handler<Executor, R(exception_ptr, T)>
: public spawn_handler_base<Executor>
{
public:
typedef T return_type;
struct result_type
{
exception_ptr ex_;
return_type* value_;
};
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
void operator()(exception_ptr ex, T value)
{
result_.ex_ = &ex;
result_.value_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result.ex_)
rethrow_exception(*result.ex_);
return ASIO_MOVE_CAST(return_type)(*result.value_);
}
private:
result_type& result_;
};
#if defined(ASIO_HAS_VARIADIC_TEMPLATES) \
&& defined(ASIO_HAS_STD_TUPLE)
template <typename Executor, typename R, typename... Ts>
class spawn_handler<Executor, R(Ts...)>
: public spawn_handler_base<Executor>
{
public:
typedef std::tuple<Ts...> return_type;
typedef return_type* result_type;
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
template <typename... Args>
void operator()(ASIO_MOVE_ARG(Args)... args)
{
return_type value(ASIO_MOVE_CAST(Args)(args)...);
result_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
return ASIO_MOVE_CAST(return_type)(*result);
}
private:
result_type& result_;
};
template <typename Executor, typename R, typename... Ts>
class spawn_handler<Executor, R(asio::error_code, Ts...)>
: public spawn_handler_base<Executor>
{
public:
typedef std::tuple<Ts...> return_type;
struct result_type
{
asio::error_code* ec_;
return_type* value_;
};
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
template <typename... Args>
void operator()(asio::error_code ec,
ASIO_MOVE_ARG(Args)... args)
{
return_type value(ASIO_MOVE_CAST(Args)(args)...);
if (this->yield_.ec_)
{
*this->yield_.ec_ = ec;
result_.ec_ = 0;
}
else
result_.ec_ = &ec;
result_.value_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result.ec_)
throw_error(*result.ec_);
return ASIO_MOVE_CAST(return_type)(*result.value_);
}
private:
result_type& result_;
};
template <typename Executor, typename R, typename... Ts>
class spawn_handler<Executor, R(exception_ptr, Ts...)>
: public spawn_handler_base<Executor>
{
public:
typedef std::tuple<Ts...> return_type;
struct result_type
{
exception_ptr ex_;
return_type* value_;
};
spawn_handler(const basic_yield_context<Executor>& yield, result_type& result)
: spawn_handler_base<Executor>(yield),
result_(result)
{
}
template <typename... Args>
void operator()(exception_ptr ex, ASIO_MOVE_ARG(Args)... args)
{
return_type value(ASIO_MOVE_CAST(Args)(args)...);
result_.ex_ = &ex;
result_.value_ = &value;
this->resume();
}
static return_type on_resume(result_type& result)
{
if (result.ex_)
rethrow_exception(*result.ex_);
return ASIO_MOVE_CAST(return_type)(*result.value_);
}
private:
result_type& result_;
};
#endif // defined(ASIO_HAS_VARIADIC_TEMPLATES)
// && defined(ASIO_HAS_STD_TUPLE)
template <typename Executor, typename Signature>
inline bool asio_handler_is_continuation(spawn_handler<Executor, Signature>*)
{
return true;
}
} // namespace detail
template <typename Executor, typename Signature>
class async_result<basic_yield_context<Executor>, Signature>
{
public:
typedef typename detail::spawn_handler<Executor, Signature> handler_type;
typedef typename handler_type::return_type return_type;
#if defined(ASIO_HAS_VARIADIC_TEMPLATES)
# if defined(ASIO_HAS_VARIADIC_LAMBDA_CAPTURES)
template <typename Initiation, typename... InitArgs>
static return_type initiate(ASIO_MOVE_ARG(Initiation) init,
const basic_yield_context<Executor>& yield,
ASIO_MOVE_ARG(InitArgs)... init_args)
{
typename handler_type::result_type result
= typename handler_type::result_type();
yield.spawned_thread_->suspend_with(
[&]()
{
ASIO_MOVE_CAST(Initiation)(init)(
handler_type(yield, result),
ASIO_MOVE_CAST(InitArgs)(init_args)...);
});
return handler_type::on_resume(result);
}
# else // defined(ASIO_HAS_VARIADIC_LAMBDA_CAPTURES)
template <typename Initiation, typename... InitArgs>
struct suspend_with_helper
{
typename handler_type::result_type& result_;
ASIO_MOVE_ARG(Initiation) init_;
const basic_yield_context<Executor>& yield_;
std::tuple<ASIO_MOVE_ARG(InitArgs)...> init_args_;
template <std::size_t... I>
void do_invoke(detail::index_sequence<I...>)
{
ASIO_MOVE_CAST(Initiation)(init_)(
handler_type(yield_, result_),
ASIO_MOVE_CAST(InitArgs)(std::get<I>(init_args_))...);
}
void operator()()
{
this->do_invoke(detail::make_index_sequence<sizeof...(InitArgs)>());
}
};
template <typename Initiation, typename... InitArgs>
static return_type initiate(ASIO_MOVE_ARG(Initiation) init,
const basic_yield_context<Executor>& yield,
ASIO_MOVE_ARG(InitArgs)... init_args)
{
typename handler_type::result_type result
= typename handler_type::result_type();
yield.spawned_thread_->suspend_with(
suspend_with_helper<Initiation, InitArgs...>{
result, ASIO_MOVE_CAST(Initiation)(init), yield,
std::tuple<ASIO_MOVE_ARG(InitArgs)...>(
ASIO_MOVE_CAST(InitArgs)(init_args)...)});
return handler_type::on_resume(result);
}
# endif // defined(ASIO_HAS_VARIADIC_LAMBDA_CAPTURES)
#else // defined(ASIO_HAS_VARIADIC_TEMPLATES)
template <typename Initiation>
static return_type initiate(Initiation init,
const basic_yield_context<Executor>& yield)
{
typename handler_type::result_type result
= typename handler_type::result_type();
struct on_suspend
{
Initiation& init_;
const basic_yield_context<Executor>& yield_;
typename handler_type::result_type& result_;
void do_call()
{
ASIO_MOVE_CAST(Initiation)(init_)(
handler_type(yield_, result_));
}
static void call(void* arg)
{
static_cast<on_suspend*>(arg)->do_call();
}
} o = { init, yield, result };
yield.spawned_thread_->suspend_with(&on_suspend::call, &o);
return handler_type::on_resume(result);
}
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS(n) \
ASIO_PRIVATE_ON_SUSPEND_MEMBERS_##n
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_1 \
T1& x1;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_2 \
T1& x1; T2& x2;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_3 \
T1& x1; T2& x2; T3& x3;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_4 \
T1& x1; T2& x2; T3& x3; T4& x4;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_5 \
T1& x1; T2& x2; T3& x3; T4& x4; T5& x5;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_6 \
T1& x1; T2& x2; T3& x3; T4& x4; T5& x5; T6& x6;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_7 \
T1& x1; T2& x2; T3& x3; T4& x4; T5& x5; T6& x6; T7& x7;
#define ASIO_PRIVATE_ON_SUSPEND_MEMBERS_8 \
T1& x1; T2& x2; T3& x3; T4& x4; T5& x5; T6& x6; T7& x7; T8& x8;
#define ASIO_PRIVATE_INITIATE_DEF(n) \
template <typename Initiation, ASIO_VARIADIC_TPARAMS(n)> \
static return_type initiate(Initiation init, \
const basic_yield_context<Executor>& yield, \
ASIO_VARIADIC_BYVAL_PARAMS(n)) \
{ \
typename handler_type::result_type result \
= typename handler_type::result_type(); \
\
struct on_suspend \
{ \
Initiation& init; \
const basic_yield_context<Executor>& yield; \
typename handler_type::result_type& result; \
ASIO_PRIVATE_ON_SUSPEND_MEMBERS(n) \
\
void do_call() \
{ \
ASIO_MOVE_CAST(Initiation)(init)( \
handler_type(yield, result), \
ASIO_VARIADIC_MOVE_ARGS(n)); \
} \
\
static void call(void* arg) \
{ \
static_cast<on_suspend*>(arg)->do_call(); \
} \
} o = { init, yield, result, ASIO_VARIADIC_BYVAL_ARGS(n) }; \
\
yield.spawned_thread_->suspend_with(&on_suspend::call, &o); \
\
return handler_type::on_resume(result); \
} \
/**/
ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_INITIATE_DEF)
#undef ASIO_PRIVATE_INITIATE_DEF
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_1
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_2
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_3
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_4
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_5
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_6
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_7
#undef ASIO_PRIVATE_ON_SUSPEND_MEMBERS_8
#endif // defined(ASIO_HAS_VARIADIC_TEMPLATES)
};
namespace detail {
template <typename Executor, typename Function, typename Handler>
class spawn_entry_point
{
public:
template <typename F, typename H>
spawn_entry_point(const Executor& ex,
ASIO_MOVE_ARG(F) f, ASIO_MOVE_ARG(H) h)
: executor_(ex),
function_(ASIO_MOVE_CAST(F)(f)),
handler_(ASIO_MOVE_CAST(H)(h)),
work_(handler_, executor_)
{
}
void operator()(spawned_thread_base* spawned_thread)
{
const basic_yield_context<Executor> yield(spawned_thread, executor_);
this->call(yield,
void_type<typename result_of<Function(
basic_yield_context<Executor>)>::type>());
}
private:
void call(const basic_yield_context<Executor>& yield, void_type<void>)
{
#if !defined(ASIO_NO_EXCEPTIONS)
try
#endif // !defined(ASIO_NO_EXCEPTIONS)
{
function_(yield);
if (!yield.spawned_thread_->has_context_switched())
(post)(yield);
detail::binder1<Handler, exception_ptr>
handler(handler_, exception_ptr());
work_.complete(handler, handler.handler_);
}
#if !defined(ASIO_NO_EXCEPTIONS)
# if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
catch (const boost::context::detail::forced_unwind&)
{
throw;
}
# endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
# if defined(ASIO_HAS_BOOST_COROUTINE)
catch (const boost::coroutines::detail::forced_unwind&)
{
throw;
}
# endif // defined(ASIO_HAS_BOOST_COROUTINE)
catch (...)
{
exception_ptr ex = current_exception();
if (!yield.spawned_thread_->has_context_switched())
(post)(yield);
detail::binder1<Handler, exception_ptr> handler(handler_, ex);
work_.complete(handler, handler.handler_);
}
#endif // !defined(ASIO_NO_EXCEPTIONS)
}
template <typename T>
void call(const basic_yield_context<Executor>& yield, void_type<T>)
{
#if !defined(ASIO_NO_EXCEPTIONS)
try
#endif // !defined(ASIO_NO_EXCEPTIONS)
{
T result(function_(yield));
if (!yield.spawned_thread_->has_context_switched())
(post)(yield);
detail::binder2<Handler, exception_ptr, T>
handler(handler_, exception_ptr(), ASIO_MOVE_CAST(T)(result));
work_.complete(handler, handler.handler_);
}
#if !defined(ASIO_NO_EXCEPTIONS)
# if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
catch (const boost::context::detail::forced_unwind&)
{
throw;
}
# endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
# if defined(ASIO_HAS_BOOST_COROUTINE)
catch (const boost::coroutines::detail::forced_unwind&)
{
throw;
}
# endif // defined(ASIO_HAS_BOOST_COROUTINE)
catch (...)
{
exception_ptr ex = current_exception();
if (!yield.spawned_thread_->has_context_switched())
(post)(yield);
detail::binder2<Handler, exception_ptr, T> handler(handler_, ex, T());
work_.complete(handler, handler.handler_);
}
#endif // !defined(ASIO_NO_EXCEPTIONS)
}
Executor executor_;
Function function_;
Handler handler_;
handler_work<Handler, Executor> work_;
};
struct spawn_cancellation_signal_emitter
{
cancellation_signal* signal_;
cancellation_type_t type_;
void operator()()
{
signal_->emit(type_);
}
};
template <typename Handler, typename Executor, typename = void>
class spawn_cancellation_handler
{
public:
spawn_cancellation_handler(const Handler&, const Executor& ex)
: ex_(ex)
{
}
cancellation_slot slot()
{
return signal_.slot();
}
void operator()(cancellation_type_t type)
{
spawn_cancellation_signal_emitter emitter = { &signal_, type };
(dispatch)(ex_, emitter);
}
private:
cancellation_signal signal_;
Executor ex_;
};
template <typename Handler, typename Executor>
class spawn_cancellation_handler<Handler, Executor,
typename enable_if<
is_same<
typename associated_executor<Handler,
Executor>::asio_associated_executor_is_unspecialised,
void
>::value
>::type>
{
public:
spawn_cancellation_handler(const Handler&, const Executor&)
{
}
cancellation_slot slot()
{
return signal_.slot();
}
void operator()(cancellation_type_t type)
{
signal_.emit(type);
}
private:
cancellation_signal signal_;
};
template <typename Executor>
class initiate_spawn
{
public:
typedef Executor executor_type;
explicit initiate_spawn(const executor_type& ex)
: executor_(ex)
{
}
executor_type get_executor() const ASIO_NOEXCEPT
{
return executor_;
}
template <typename Handler, typename F>
void operator()(ASIO_MOVE_ARG(Handler) handler,
ASIO_MOVE_ARG(F) f) const
{
typedef typename decay<Handler>::type handler_type;
typedef typename decay<F>::type function_type;
typedef spawn_cancellation_handler<
handler_type, Executor> cancel_handler_type;
typename associated_cancellation_slot<handler_type>::type slot
= asio::get_associated_cancellation_slot(handler);
cancel_handler_type* cancel_handler = slot.is_connected()
? &slot.template emplace<cancel_handler_type>(handler, executor_)
: 0;
cancellation_slot proxy_slot(
cancel_handler
? cancel_handler->slot()
: cancellation_slot());
cancellation_state cancel_state(proxy_slot);
(dispatch)(executor_,
spawned_thread_resumer(
default_spawned_thread_type::spawn(
spawn_entry_point<Executor, function_type, handler_type>(
executor_, ASIO_MOVE_CAST(F)(f),
ASIO_MOVE_CAST(Handler)(handler)),
proxy_slot, cancel_state)));
}
#if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
template <typename Handler, typename StackAllocator, typename F>
void operator()(ASIO_MOVE_ARG(Handler) handler, allocator_arg_t,
ASIO_MOVE_ARG(StackAllocator) stack_allocator,
ASIO_MOVE_ARG(F) f) const
{
typedef typename decay<Handler>::type handler_type;
typedef typename decay<F>::type function_type;
typedef spawn_cancellation_handler<
handler_type, Executor> cancel_handler_type;
typename associated_cancellation_slot<handler_type>::type slot
= asio::get_associated_cancellation_slot(handler);
cancel_handler_type* cancel_handler = slot.is_connected()
? &slot.template emplace<cancel_handler_type>(handler, executor_)
: 0;
cancellation_slot proxy_slot(
cancel_handler
? cancel_handler->slot()
: cancellation_slot());
cancellation_state cancel_state(proxy_slot);
(dispatch)(executor_,
spawned_thread_resumer(
spawned_fiber_thread::spawn(allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
spawn_entry_point<Executor, function_type, handler_type>(
executor_, ASIO_MOVE_CAST(F)(f),
ASIO_MOVE_CAST(Handler)(handler)),
proxy_slot, cancel_state)));
}
#endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
private:
executor_type executor_;
};
} // namespace detail
template <typename Executor, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
spawn(const Executor& ex, ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
#if defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
!is_same<
typename decay<CompletionToken>::type,
boost::coroutines::attributes
>::value
>::type,
#endif // defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
is_executor<Executor>::value || execution::is_executor<Executor>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
declval<detail::initiate_spawn<Executor> >(),
token, ASIO_MOVE_CAST(F)(function))))
{
return async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
detail::initiate_spawn<Executor>(ex),
token, ASIO_MOVE_CAST(F)(function));
}
template <typename ExecutionContext, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type)
spawn(ExecutionContext& ctx, ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
#if defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
!is_same<
typename decay<CompletionToken>::type,
boost::coroutines::attributes
>::value
>::type,
#endif // defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
is_convertible<ExecutionContext&, execution_context&>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type>(
declval<detail::initiate_spawn<
typename ExecutionContext::executor_type> >(),
token, ASIO_MOVE_CAST(F)(function))))
{
return (spawn)(ctx.get_executor(), ASIO_MOVE_CAST(F)(function),
ASIO_MOVE_CAST(CompletionToken)(token));
}
template <typename Executor, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
spawn(const basic_yield_context<Executor>& ctx,
ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
#if defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
!is_same<
typename decay<CompletionToken>::type,
boost::coroutines::attributes
>::value
>::type,
#endif // defined(ASIO_HAS_BOOST_COROUTINE)
typename constraint<
is_executor<Executor>::value || execution::is_executor<Executor>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
declval<detail::initiate_spawn<Executor> >(),
token, ASIO_MOVE_CAST(F)(function))))
{
return (spawn)(ctx.get_executor(), ASIO_MOVE_CAST(F)(function),
ASIO_MOVE_CAST(CompletionToken)(token));
}
#if defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
template <typename Executor, typename StackAllocator, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
spawn(const Executor& ex, allocator_arg_t,
ASIO_MOVE_ARG(StackAllocator) stack_allocator,
ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
typename constraint<
is_executor<Executor>::value || execution::is_executor<Executor>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
declval<detail::initiate_spawn<Executor> >(),
token, allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function))))
{
return async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
detail::initiate_spawn<Executor>(ex), token, allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function));
}
template <typename ExecutionContext, typename StackAllocator, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type)
spawn(ExecutionContext& ctx, allocator_arg_t,
ASIO_MOVE_ARG(StackAllocator) stack_allocator,
ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
typename constraint<
is_convertible<ExecutionContext&, execution_context&>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<
typename ExecutionContext::executor_type>)>::type>::type>(
declval<detail::initiate_spawn<
typename ExecutionContext::executor_type> >(),
token, allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function))))
{
return (spawn)(ctx.get_executor(), allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function),
ASIO_MOVE_CAST(CompletionToken)(token));
}
template <typename Executor, typename StackAllocator, typename F,
ASIO_COMPLETION_TOKEN_FOR(typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
CompletionToken>
inline ASIO_INITFN_AUTO_RESULT_TYPE_PREFIX(CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type)
spawn(const basic_yield_context<Executor>& ctx, allocator_arg_t,
ASIO_MOVE_ARG(StackAllocator) stack_allocator,
ASIO_MOVE_ARG(F) function,
ASIO_MOVE_ARG(CompletionToken) token,
typename constraint<
is_executor<Executor>::value || execution::is_executor<Executor>::value
>::type)
ASIO_INITFN_AUTO_RESULT_TYPE_SUFFIX((
async_initiate<CompletionToken,
typename detail::spawn_signature<
typename result_of<F(basic_yield_context<Executor>)>::type>::type>(
declval<detail::initiate_spawn<Executor> >(),
token, allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function))))
{
return (spawn)(ctx.get_executor(), allocator_arg_t(),
ASIO_MOVE_CAST(StackAllocator)(stack_allocator),
ASIO_MOVE_CAST(F)(function),
ASIO_MOVE_CAST(CompletionToken)(token));
}
#endif // defined(ASIO_HAS_BOOST_CONTEXT_FIBER)
#if defined(ASIO_HAS_BOOST_COROUTINE)
namespace detail {
template <typename Executor, typename Function, typename Handler>
class old_spawn_entry_point
{
public:
template <typename F, typename H>
old_spawn_entry_point(const Executor& ex,
ASIO_MOVE_ARG(F) f, ASIO_MOVE_ARG(H) h)
: executor_(ex),
function_(ASIO_MOVE_CAST(F)(f)),
handler_(ASIO_MOVE_CAST(H)(h))
{
}
void operator()(spawned_thread_base* spawned_thread)
{
const basic_yield_context<Executor> yield(spawned_thread, executor_);
this->call(yield,
void_type<typename result_of<Function(
basic_yield_context<Executor>)>::type>());
}
private:
void call(const basic_yield_context<Executor>& yield, void_type<void>)
{
function_(yield);
ASIO_MOVE_OR_LVALUE(Handler)(handler_)();
}
template <typename T>
void call(const basic_yield_context<Executor>& yield, void_type<T>)
{
ASIO_MOVE_OR_LVALUE(Handler)(handler_)(function_(yield));
}
Executor executor_;
Function function_;
Handler handler_;
};
inline void default_spawn_handler() {}
} // namespace detail
template <typename Function>
inline void spawn(ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes)
{
typedef typename decay<Function>::type function_type;
typename associated_executor<function_type>::type ex(
(get_associated_executor)(function));
asio::spawn(ex, ASIO_MOVE_CAST(Function)(function), attributes);
}
template <typename Handler, typename Function>
void spawn(ASIO_MOVE_ARG(Handler) handler,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes,
typename constraint<
!is_executor<typename decay<Handler>::type>::value &&
!execution::is_executor<typename decay<Handler>::type>::value &&
!is_convertible<Handler&, execution_context&>::value>::type)
{
typedef typename decay<Handler>::type handler_type;
typedef typename decay<Function>::type function_type;
typedef typename associated_executor<handler_type>::type executor_type;
executor_type ex((get_associated_executor)(handler));
(dispatch)(ex,
detail::spawned_thread_resumer(
detail::spawned_coroutine_thread::spawn(
detail::old_spawn_entry_point<executor_type,
function_type, void (*)()>(
ex, ASIO_MOVE_CAST(Function)(function),
&detail::default_spawn_handler), attributes)));
}
template <typename Executor, typename Function>
void spawn(basic_yield_context<Executor> ctx,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes)
{
typedef typename decay<Function>::type function_type;
(dispatch)(ctx.get_executor(),
detail::spawned_thread_resumer(
detail::spawned_coroutine_thread::spawn(
detail::old_spawn_entry_point<Executor,
function_type, void (*)()>(ctx.get_executor(),
ASIO_MOVE_CAST(Function)(function),
&detail::default_spawn_handler), attributes)));
}
template <typename Function, typename Executor>
inline void spawn(const Executor& ex,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes,
typename constraint<
is_executor<Executor>::value || execution::is_executor<Executor>::value
>::type)
{
asio::spawn(asio::strand<Executor>(ex),
ASIO_MOVE_CAST(Function)(function), attributes);
}
template <typename Function, typename Executor>
inline void spawn(const strand<Executor>& ex,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes)
{
asio::spawn(asio::bind_executor(
ex, &detail::default_spawn_handler),
ASIO_MOVE_CAST(Function)(function), attributes);
}
#if !defined(ASIO_NO_TS_EXECUTORS)
template <typename Function>
inline void spawn(const asio::io_context::strand& s,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes)
{
asio::spawn(asio::bind_executor(
s, &detail::default_spawn_handler),
ASIO_MOVE_CAST(Function)(function), attributes);
}
#endif // !defined(ASIO_NO_TS_EXECUTORS)
template <typename Function, typename ExecutionContext>
inline void spawn(ExecutionContext& ctx,
ASIO_MOVE_ARG(Function) function,
const boost::coroutines::attributes& attributes,
typename constraint<is_convertible<
ExecutionContext&, execution_context&>::value>::type)
{
asio::spawn(ctx.get_executor(),
ASIO_MOVE_CAST(Function)(function), attributes);
}
#endif // defined(ASIO_HAS_BOOST_COROUTINE)
} // namespace asio
#include "asio/detail/pop_options.hpp"
#endif // ASIO_IMPL_SPAWN_HPP