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construct/include/ircd/ctx/promise.h

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// Matrix Construct
//
// Copyright (C) Matrix Construct Developers, Authors & Contributors
// Copyright (C) 2016-2018 Jason Volk <jason@zemos.net>
//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
// copyright notice and this permission notice is present in all copies. The
// full license for this software is available in the LICENSE file.
#pragma once
#define HAVE_IRCD_CTX_PROMISE_H
namespace ircd::ctx
{
struct promise_base;
template<class T = void> class promise;
template<> class promise<void>;
IRCD_EXCEPTION(future_error, no_state)
IRCD_EXCEPTION(future_error, broken_promise)
IRCD_EXCEPTION(future_error, promise_already_satisfied)
}
/// Abstract base type for ctx::promise. This dedupes most of the promissory
/// functionality with non-template definitions residing in ctx.cc.
///
/// In this system the promise is lightweight and maintains a pointer to the
/// shared_state object which generally resides within the future instance.
/// If the shared_state object moves or is destroyed the promise's pointer to
/// it must be updated. The shared_state object also has a pointer to the
/// promise; if the promise moves or is destroyed that pointer must be updated
/// as well. This is how the bi-directional relationship is maintained.
///
/// To further complicate things, this promise maintains a second pointer
/// to another instance of a promise implementing a linked-list semantic. All
/// of these promises are making the same promise to the same shared_state;
/// the list allows for copy semantics which are important for some callback
/// systems (like boost::asio). This solution is far more optimal than
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/// allocating the promise in a shared_ptr and refcounting... Note that the
/// same semantic exists on the future side to implement shared futures. Both
/// parties maintain a pointer to the head of a singly linked list of the
/// other party, and a pointer to the next instance of their own party.
struct ircd::ctx::promise_base
{
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static const promise_base *head(const shared_state_base &);
static const promise_base *head(const promise_base &);
static size_t refcount(const shared_state_base &);
static size_t refcount(const promise_base &);
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static promise_base *head(shared_state_base &);
static promise_base *head(promise_base &);
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shared_state_base *st {nullptr}; // the head of all sharing futures
promise_base *next {nullptr}; // next sharing promise
template<class T> const shared_state<T> &state() const noexcept;
template<class T> shared_state<T> &state() noexcept;
const shared_state_base &state() const noexcept;
shared_state_base &state() noexcept;
void check_pending() const;
void make_ready();
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void remove();
public:
bool valid() const noexcept;
bool operator!() const noexcept;
explicit operator bool() const noexcept;
void set_exception(std::exception_ptr);
protected:
promise_base() = default;
promise_base(const promise_base &);
promise_base(promise_base &&) noexcept;
promise_base &operator=(const promise_base &);
promise_base &operator=(promise_base &&) noexcept;
~promise_base() noexcept;
};
/// Value-oriented promise. The user creates an instance of this promise in
/// order to send a value to a future. After creating an instance of this
/// promise the user should construct a future with the matching template type
/// from this. The two will then be linked.
///
/// Space for the value will reside within the future instance and not the
/// promise instance. When the value is set it will be copied (or movied) there.
///
/// Full object semantics for this promise are supported; including copy
/// semantics. All copies of a promise are making the same promise thus
/// setting a value or exception for one invalidates all the copies.
///
/// Instances of this promise can safely destruct at any time. When all copies
/// of a promise destruct without setting a value or exception the future is
/// notified with a broken_promise exception.
template<class T>
struct ircd::ctx::promise
:promise_base
{
using value_type = typename shared_state<T>::value_type;
using pointer_type = typename shared_state<T>::pointer_type;
using reference_type = typename shared_state<T>::reference_type;
const shared_state<T> &state() const;
shared_state<T> &state();
public:
void set_value(const T &val);
void set_value(T&& val);
using promise_base::promise_base;
using promise_base::operator=;
};
/// Valueless promise. The user creates an instance of this promise in
/// order to notify a future of a success or set an exception for failure.
///
/// See docs for promise<T> for more information.
template<>
struct ircd::ctx::promise<void>
:promise_base
{
using value_type = typename shared_state<void>::value_type;
const shared_state<void> &state() const;
shared_state<void> &state();
public:
void set_value();
using promise_base::promise_base;
using promise_base::operator=;
};
//
// promise<T>
//
template<class T>
inline void
ircd::ctx::promise<T>::set_value(T&& val)
{
if(!valid())
return;
check_pending();
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auto *state
{
shared_state_base::head(*this)
};
assert(state);
if(shared_state_base::refcount(*state) > 1) do
{
assert(is(*state, future_state::PENDING));
static_cast<shared_state<T> &>(*state).val = val;
}
while((state = state->next)); else
{
assert(is(this->state(), future_state::PENDING));
this->state().val = std::move(val);
}
make_ready();
}
template<class T>
inline void
ircd::ctx::promise<T>::set_value(const T &val)
{
if(!valid())
return;
check_pending();
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auto *state(shared_state_base::head(*this)); do
{
assert(state);
assert(is(*state, future_state::PENDING));
static_cast<shared_state<T> &>(*state).val = val;
}
while((state = state->next));
make_ready();
}
template<class T>
inline ircd::ctx::shared_state<T> &
ircd::ctx::promise<T>::state()
{
return promise_base::state<T>();
}
template<class T>
inline const ircd::ctx::shared_state<T> &
ircd::ctx::promise<T>::state()
const
{
return promise_base::state<T>();
}
//
// promise_base
//
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inline void
ircd::ctx::promise_base::check_pending()
const
{
assert(valid());
if(unlikely(!is(state(), future_state::PENDING)))
throw promise_already_satisfied{};
}
inline bool
ircd::ctx::promise_base::operator!()
const noexcept
{
return !valid();
}
inline ircd::ctx::promise_base::operator
bool()
const noexcept
{
return valid();
}
inline bool
ircd::ctx::promise_base::valid()
const noexcept
{
return bool(st);
}
template<class T>
inline ircd::ctx::shared_state<T> &
ircd::ctx::promise_base::state()
noexcept
{
return static_cast<shared_state<T> &>(state());
}
template<class T>
inline const ircd::ctx::shared_state<T> &
ircd::ctx::promise_base::state()
const noexcept
{
return static_cast<const shared_state<T> &>(state());
}
inline ircd::ctx::shared_state_base &
ircd::ctx::promise_base::state()
noexcept
{
assert(valid());
return *st;
}
inline const ircd::ctx::shared_state_base &
ircd::ctx::promise_base::state()
const noexcept
{
assert(valid());
return *st;
}