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/**
* @file llcoros.h
* @author Nat Goodspeed
* @date 2009-06-02
* @brief Manage running boost::coroutine instances
*
* $LicenseInfo:firstyear=2009&license=viewerlgpl$
* Second Life Viewer Source Code
* Copyright (C) 2010, Linden Research, Inc.
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation;
* version 2.1 of the License only.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*
* Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA
* $/LicenseInfo$
*/
#if ! defined(LL_LLCOROS_H)
#define LL_LLCOROS_H
#include "llevents.h"
#include "llexception.h"
#include "llinstancetracker.h"
#include "llsingleton.h"
#include "mutex.h"
#include <boost/fiber/fss.hpp>
#include <boost/fiber/future/promise.hpp>
#include <boost/fiber/future/future.hpp>
#include <exception>
#include <functional>
#include <queue>
#include <string>
// e.g. #include LLCOROS_MUTEX_HEADER
#define LLCOROS_MUTEX_HEADER <boost/fiber/mutex.hpp>
#define LLCOROS_CONDVAR_HEADER <boost/fiber/condition_variable.hpp>
namespace boost {
namespace fibers {
class mutex;
enum class cv_status;
class condition_variable;
}
}
/**
* Registry of named Boost.Coroutine instances
*
* The Boost.Coroutine library supports the general case of a coroutine
* accepting arbitrary parameters and yielding multiple (sets of) results. For
* such use cases, it's natural for the invoking code to retain the coroutine
* instance: the consumer repeatedly calls into the coroutine, perhaps passing
* new parameter values, prompting it to yield its next result.
*
* Our typical coroutine usage is different, though. For us, coroutines
* provide an alternative to the @c Responder pattern. Our typical coroutine
* has @c void return, invoked in fire-and-forget mode: the handler for some
* user gesture launches the coroutine and promptly returns to the main loop.
* The coroutine initiates some action that will take multiple frames (e.g. a
* capability request), waits for its result, processes it and silently steals
* away.
*
* This usage poses two (related) problems:
*
* # Who should own the coroutine instance? If it's simply local to the
* handler code that launches it, return from the handler will destroy the
* coroutine object, terminating the coroutine.
* # Once the coroutine terminates, in whatever way, who's responsible for
* cleaning up the coroutine object?
*
* LLCoros is a Singleton collection of currently-active coroutine instances.
* Each has a name. You ask LLCoros to launch a new coroutine with a suggested
* name prefix; from your prefix it generates a distinct name, registers the
* new coroutine and returns the actual name.
*
* The name
* can provide diagnostic info: we can look up the name of the
* currently-running coroutine.
*/
class LL_COMMON_API LLCoros: public LLSingleton<LLCoros>
{
LLSINGLETON(LLCoros);
~LLCoros();
void cleanupSingleton() override;
public:
// For debugging, return true if on the main coroutine for the current thread
// Code that should not be executed from a coroutine should be protected by
// llassert(LLCoros::on_main_coro())
static bool on_main_coro();
// For debugging, return true if on the main thread and not in a coroutine
// Non-thread-safe code in the main loop should be protected by
// llassert(LLCoros::on_main_thread_main_coro())
static bool on_main_thread_main_coro();
/// The viewer's use of the term "coroutine" became deeply embedded before
/// the industry term "fiber" emerged to distinguish userland threads from
/// simpler, more transient kinds of coroutines. Semantically they've
/// always been fibers. But at this point in history, we're pretty much
/// stuck with the term "coroutine."
typedef boost::fibers::fiber coro;
/// Canonical callable type
typedef std::function<void()> callable_t;
/**
* Create and start running a new coroutine with specified name. The name
* string you pass is a suggestion; it will be tweaked for uniqueness. The
* actual name is returned to you.
*
* Usage looks like this, for (e.g.) two coroutine parameters:
* @code
* class MyClass
* {
* public:
* ...
* // Do NOT NOT NOT accept reference params!
* // Pass by value only!
* void myCoroutineMethod(std::string, LLSD);
* ...
* };
* ...
* std::string name = LLCoros::instance().launch(
* "mycoro", boost::bind(&MyClass::myCoroutineMethod, this,
* "somestring", LLSD(17));
* @endcode
*
* Your function/method can accept any parameters you want -- but ONLY BY
* VALUE! Reference parameters are a BAD IDEA! You Have Been Warned. See
* DEV-32777 comments for an explanation.
*
* Pass a nullary callable. It works to directly pass a nullary free
* function (or static method); for other cases use a lambda expression,
* std::bind() or boost::bind(). Of course, for a non-static class method,
* the first parameter must be the class instance. Any other parameters
* should be passed via the enclosing expression.
*
* launch() tweaks the suggested name so it won't collide with any
* existing coroutine instance, creates the coroutine instance, registers
* it with the tweaked name and runs it until its first wait. At that
* point it returns the tweaked name.
*/
std::string launch(const std::string& prefix, const callable_t& callable);
/**
* Ask the named coroutine to abort. Normally, when a coroutine either
* runs to completion or terminates with an exception, LLCoros quietly
* cleans it up. This is for use only when you must explicitly interrupt
* one prematurely. Returns @c true if the specified name was found and
* still running at the time.
*/
bool killreq(const std::string& name);
/**
* From within a coroutine, look up the (tweaked) name string by which
* this coroutine is registered. Returns the empty string if not found
* (e.g. if the coroutine was launched by hand rather than using
* LLCoros::launch()).
*/
static std::string getName();
/**
* rethrow() is called by the thread's main fiber to propagate an
* exception from any coroutine into the main fiber, where it can engage
* the normal unhandled-exception machinery, up to and including crash
* reporting.
*
* LLCoros maintains a queue of otherwise-uncaught exceptions from
* terminated coroutines. Each call to rethrow() pops the first of those
* and rethrows it. When the queue is empty (normal case), rethrow() is a
* no-op.
*/
void rethrow();
/**
* This variation returns a name suitable for log messages: the explicit
* name for an explicitly-launched coroutine, or "mainN" for the default
* coroutine on a thread.
*/
static std::string logname();
/**
* For delayed initialization. To be clear, this will only affect
* coroutines launched @em after this point. The underlying facility
* provides no way to alter the stack size of any running coroutine.
*/
void setStackSize(S32 stacksize);
/// diagnostic
void printActiveCoroutines(const std::string& when=std::string());
/// get the current coro::id for those who really really care
static coro::id get_self();
/**
* Most coroutines, most of the time, don't "consume" the events for which
* they're suspending. This way, an arbitrary number of listeners (whether
* coroutines or simple callbacks) can be registered on a particular
* LLEventPump, every listener responding to each of the events on that
* LLEventPump. But a particular coroutine can assert that it will consume
* each event for which it suspends. (See also llcoro::postAndSuspend(),
* llcoro::VoidListener)
*/
static void set_consuming(bool consuming);
static bool get_consuming();
/**
* RAII control of the consuming flag
*/
class OverrideConsuming
{
public:
OverrideConsuming(bool consuming):
mPrevConsuming(get_consuming())
{
set_consuming(consuming);
}
OverrideConsuming(const OverrideConsuming&) = delete;
~OverrideConsuming()
{
set_consuming(mPrevConsuming);
}
private:
bool mPrevConsuming;
};
/// set string coroutine status for diagnostic purposes
static void setStatus(const std::string& status);
static std::string getStatus();
/// RAII control of status
class TempStatus
{
public:
TempStatus(const std::string& status):
mOldStatus(getStatus())
{
setStatus(status);
}
TempStatus(const TempStatus&) = delete;
~TempStatus()
{
setStatus(mOldStatus);
}
private:
std::string mOldStatus;
};
/// thrown by checkStop()
// It may sound ironic that Stop is derived from LLContinueError, but the
// point is that LLContinueError is the category of exception that should
// not immediately crash the viewer. Stop and its subclasses are to tell
// coroutines to terminate, e.g. because the viewer is shutting down. We
// do not want any such exception to crash the viewer.
struct Stop: public LLContinueError
{
Stop(const std::string& what): LLContinueError(what) {}
};
/// someone wants to kill this specific coroutine
struct Killed: public Stop
{
Killed(const std::string& what): Stop(what) {}
};
/// early shutdown stages
struct Stopping: public Stop
{
Stopping(const std::string& what): Stop(what) {}
};
/// cleaning up
struct Stopped: public Stop
{
Stopped(const std::string& what): Stop(what) {}
};
/// cleaned up -- not much survives!
struct Shutdown: public Stop
{
Shutdown(const std::string& what): Stop(what) {}
};
/// Call this intermittently if there's a chance your coroutine might
/// still be running at application shutdown. Throws one of the Stop
/// subclasses if the caller needs to terminate. Pass a cleanup function
/// if you need to execute that cleanup before terminating.
/// Of course, if your cleanup function throws, that will be the exception
/// propagated by checkStop().
static void checkStop(callable_t cleanup={});
/// Call getStopListener() at the source end of a queue, promise or other
/// resource on which coroutines will wait, so that shutdown can wake up
/// consuming coroutines. @a caller should distinguish who's calling. The
/// passed @a cleanup function must close the queue, break the promise or
/// otherwise cause waiting consumers to wake up in an abnormal way. It's
/// advisable to store the returned LLBoundListener in an
/// LLTempBoundListener, or otherwise arrange to disconnect it.
static LLBoundListener getStopListener(const std::string& caller, LLVoidListener cleanup);
/// This getStopListener() overload is like the two-argument one, for use
/// when we know the name of the only coroutine that will wait on the
/// resource in question. Pass @a consumer as the empty string if the
/// consumer coroutine is the same as the calling coroutine. Unlike the
/// two-argument getStopListener(), this one also responds to
/// killreq(target).
static LLBoundListener getStopListener(const std::string& caller,
const std::string& consumer,
LLVoidListener cleanup);
/**
* Aliases for promise and future. An older underlying future implementation
* required us to wrap future; that's no longer needed. However -- if it's
* important to restore kill() functionality, we might need to provide a
* proxy, so continue using the aliases.
*/
template <typename T>
using Promise = boost::fibers::promise<T>;
template <typename T>
using Future = boost::fibers::future<T>;
template <typename T>
static Future<T> getFuture(Promise<T>& promise) { return promise.get_future(); }
// use mutex, lock, condition_variable suitable for coroutines
using Mutex = boost::fibers::mutex;
using LockType = std::unique_lock<Mutex>;
using cv_status = boost::fibers::cv_status;
using ConditionVariable = boost::fibers::condition_variable;
/// for data local to each running coroutine
template <typename T>
using local_ptr = boost::fibers::fiber_specific_ptr<T>;
private:
std::string generateDistinctName(const std::string& prefix) const;
void toplevel(std::string name, callable_t callable);
struct CoroData;
static CoroData& get_CoroData(const std::string& caller);
void saveException(const std::string& name, std::exception_ptr exc);
LLTempBoundListener mConn;
struct ExceptionData
{
ExceptionData(const std::string& nm, std::exception_ptr exc):
name(nm),
exception(exc)
{}
// name of coroutine that originally threw this exception
std::string name;
// the thrown exception
std::exception_ptr exception;
};
std::queue<ExceptionData> mExceptionQueue;
S32 mStackSize;
// coroutine-local storage, as it were: one per coro we track
struct CoroData: public LLInstanceTracker<CoroData, std::string>
{
CoroData(const std::string& name);
CoroData(int n);
// tweaked name of the current coroutine
const std::string mName;
// set_consuming() state -- don't consume events unless specifically directed
bool mConsuming{ false };
// killed by which coroutine
std::string mKilledBy;
// setStatus() state
std::string mStatus;
F64 mCreationTime; // since epoch
};
// Identify the current coroutine's CoroData. This local_ptr isn't static
// because it's a member of an LLSingleton, and we rely on it being
// cleaned up in proper dependency order.
local_ptr<CoroData> mCurrent;
};
namespace llcoro
{
inline
std::string logname() { return LLCoros::logname(); }
} // llcoro
#endif /* ! defined(LL_LLCOROS_H) */
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