0
0
Fork 0
mirror of https://github.com/matrix-construct/construct synced 2024-12-26 07:23:53 +01:00
construct/include/ircd/ctx/pool.h

172 lines
4.7 KiB
C++

// 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_POOL_H
namespace ircd::ctx
{
struct pool;
const string_view &name(const pool &);
void debug_stats(const pool &);
}
struct ircd::ctx::pool
{
struct opts;
using closure = std::function<void ()>;
static const string_view default_name;
static const opts default_opts;
string_view name {default_name};
const opts *opt {&default_opts};
size_t running {0};
size_t working {0};
dock q_max;
queue<closure> q;
std::vector<context> ctxs;
void work();
void main() noexcept;
public:
explicit operator const opts &() const;
// indicators
auto size() const { return ctxs.size(); }
auto queued() const { return q.size(); }
auto active() const { return working; }
auto avail() const { return running - active(); }
auto pending() const { return active() + queued(); }
bool wouldblock() const;
// dispatch to pool
template<class F, class... A> future_void<F, A...> async(F&&, A&&...);
template<class F, class... A> future_value<F, A...> async(F&&, A&&...);
void operator()(closure);
// control panel
void add(const size_t & = 1);
void del(const size_t & = 1);
void set(const size_t &);
void min(const size_t &);
void terminate();
void interrupt();
void join();
pool(const string_view &name = default_name,
const opts & = default_opts);
pool(pool &&) = delete;
pool(const pool &) = delete;
pool &operator=(pool &&) = delete;
pool &operator=(const pool &) = delete;
~pool() noexcept;
friend const string_view &name(const pool &);
friend void debug_stats(const pool &);
};
struct ircd::ctx::pool::opts
{
/// When the pool spawns a new context this will be the stack size it has.
size_t stack_size { DEFAULT_STACK_SIZE };
/// When the pool is constructed this will be how many contexts it spawns
/// This value may be ignored for static duration instances.
size_t initial_ctxs {0};
/// Hard-limit for jobs queued. A submit to the pool over this limit throws
/// an exception. Default is -1, effectively unlimited.
ssize_t queue_max_hard {-1};
/// Soft-limit for jobs queued. The behavior of the limit is configurable.
/// The default is 0, meaning if there is no context available to service
/// the request being submitted then the soft limit is immediately reached.
/// See the specific behavior options following this.
ssize_t queue_max_soft {0};
/// Yield a context submitting to the pool if it will violate the soft
/// limit. This is true by default. Note the default of 0 for the
/// soft-limit itself combined with this: by default there is no queueing
/// of jobs at all! This behavior purposely propagates flow control by
/// slowing down the submitting context and prevents flooding the queue.
/// This option has no effect if the submitter is not on any ircd::ctx.
bool queue_max_blocking {true};
/// Log a DWARNING (developer-warning level) when the soft limit is
/// exceeded. The soft-limit is never actually exceeded when contexts
/// are blocked from submitting (see: queue_max_blocking). This warning
/// will still be seen for submissions outside any ircd::ctx.
bool queue_max_dwarning {true};
/// IO priority nice value for contexts in this pool.
int8_t ionice {0};
/// Scheduler priority nice value for contexts in this pool.
int8_t nice {0};
};
template<class F,
class... A>
ircd::ctx::future_value<F, A...>
ircd::ctx::pool::async(F&& f,
A&&... a)
{
using R = typename std::result_of<F (A...)>::type;
auto func
{
std::bind(std::forward<F>(f), std::forward<A>(a)...)
};
promise<R> p;
future<R> ret{p};
operator()([p(std::move(p)), func(std::move(func))]
{
p.set_value(func());
});
return ret;
}
template<class F,
class... A>
ircd::ctx::future_void<F, A...>
ircd::ctx::pool::async(F&& f,
A&&... a)
{
using R = typename std::result_of<F (A...)>::type;
auto func
{
std::bind(std::forward<F>(f), std::forward<A>(a)...)
};
promise<R> p;
future<R> ret{p};
operator()([p(std::move(p)), func(std::move(func))]
{
func();
p.set_value();
});
return ret;
}
inline ircd::ctx::pool::operator
const opts &()
const
{
assert(opt);
return *opt;
}