xemu/include/io/task.h
Peter Xu a17536c594 qio: non-default context for threaded qtask
qio_task_run_in_thread() allows main thread to run blocking operations
in the background. However it has an assumption on that it's always
working with the default context. This patch tries to allow the threaded
QIO task framework to run with non-default gcontext.

Currently no functional change so far, so the QIOTasks are still always
running on main context.

Reviewed-by: Daniel P. Berrange <berrange@redhat.com>
Signed-off-by: Peter Xu <peterx@redhat.com>
Signed-off-by: Daniel P. Berrangé <berrange@redhat.com>
2018-03-06 10:19:05 +00:00

327 lines
10 KiB
C

/*
* QEMU I/O task
*
* Copyright (c) 2015 Red Hat, 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; either
* version 2 of the License, or (at your option) any later version.
*
* 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, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef QIO_TASK_H
#define QIO_TASK_H
#include "qemu-common.h"
#include "qom/object.h"
typedef struct QIOTask QIOTask;
typedef void (*QIOTaskFunc)(QIOTask *task,
gpointer opaque);
typedef void (*QIOTaskWorker)(QIOTask *task,
gpointer opaque);
/**
* QIOTask:
*
* The QIOTask object provides a simple mechanism for reporting
* success / failure of long running background operations.
*
* A object on which the operation is to be performed could have
* a public API which accepts a task callback:
*
* <example>
* <title>Task function signature</title>
* <programlisting>
* void myobject_operation(QMyObject *obj,
* QIOTaskFunc *func,
* gpointer opaque,
* GDestroyNotify notify);
* </programlisting>
* </example>
*
* The 'func' parameter is the callback to be invoked, and 'opaque'
* is data to pass to it. The optional 'notify' function is used
* to free 'opaque' when no longer needed.
*
* When the operation completes, the 'func' callback will be
* invoked, allowing the calling code to determine the result
* of the operation. An example QIOTaskFunc implementation may
* look like
*
* <example>
* <title>Task callback implementation</title>
* <programlisting>
* static void myobject_operation_notify(QIOTask *task,
* gpointer opaque)
* {
* Error *err = NULL;
* if (qio_task_propagate_error(task, &err)) {
* ...deal with the failure...
* error_free(err);
* } else {
* QMyObject *src = QMY_OBJECT(qio_task_get_source(task));
* ...deal with the completion...
* }
* }
* </programlisting>
* </example>
*
* Now, lets say the implementation of the method using the
* task wants to set a timer to run once a second checking
* for completion of some activity. It would do something
* like
*
* <example>
* <title>Task function implementation</title>
* <programlisting>
* void myobject_operation(QMyObject *obj,
* QIOTaskFunc *func,
* gpointer opaque,
* GDestroyNotify notify)
* {
* QIOTask *task;
*
* task = qio_task_new(OBJECT(obj), func, opaque, notify);
*
* g_timeout_add_full(G_PRIORITY_DEFAULT,
* 1000,
* myobject_operation_timer,
* task,
* NULL);
* }
* </programlisting>
* </example>
*
* It could equally have setup a watch on a file descriptor or
* created a background thread, or something else entirely.
* Notice that the source object is passed to the task, and
* QIOTask will hold a reference on that. This ensure that
* the QMyObject instance cannot be garbage collected while
* the async task is still in progress.
*
* In this case, myobject_operation_timer will fire after
* 3 secs and do
*
* <example>
* <title>Task timer function</title>
* <programlisting>
* gboolean myobject_operation_timer(gpointer opaque)
* {
* QIOTask *task = QIO_TASK(opaque);
* Error *err;*
*
* ...check something important...
* if (err) {
* qio_task_set_error(task, err);
* qio_task_complete(task);
* return FALSE;
* } else if (...work is completed ...) {
* qio_task_complete(task);
* return FALSE;
* }
* ...carry on polling ...
* return TRUE;
* }
* </programlisting>
* </example>
*
* The 'qio_task_complete' call in this method will trigger
* the callback func 'myobject_operation_notify' shown
* earlier to deal with the results.
*
* Once this function returns false, object_unref will be called
* automatically on the task causing it to be released and the
* ref on QMyObject dropped too.
*
* The QIOTask module can also be used to perform operations
* in a background thread context, while still reporting the
* results in the main event thread. This allows code which
* cannot easily be rewritten to be asychronous (such as DNS
* lookups) to be easily run non-blocking. Reporting the
* results in the main thread context means that the caller
* typically does not need to be concerned about thread
* safety wrt the QEMU global mutex.
*
* For example, the socket_listen() method will block the caller
* while DNS lookups take place if given a name, instead of IP
* address. The C library often do not provide a practical async
* DNS API, so the to get non-blocking DNS lookups in a portable
* manner requires use of a thread. So achieve a non-blocking
* socket listen using QIOTask would require:
*
* <example>
* static void myobject_listen_worker(QIOTask *task,
* gpointer opaque)
* {
* QMyObject obj = QMY_OBJECT(qio_task_get_source(task));
* SocketAddress *addr = opaque;
* Error *err = NULL;
*
* obj->fd = socket_listen(addr, &err);
*
qio_task_set_error(task, err);
* }
*
* void myobject_listen_async(QMyObject *obj,
* SocketAddress *addr,
* QIOTaskFunc *func,
* gpointer opaque,
* GDestroyNotify notify)
* {
* QIOTask *task;
* SocketAddress *addrCopy;
*
* addrCopy = QAPI_CLONE(SocketAddress, addr);
* task = qio_task_new(OBJECT(obj), func, opaque, notify);
*
* qio_task_run_in_thread(task, myobject_listen_worker,
* addrCopy,
* qapi_free_SocketAddress);
* }
* </example>
*
* NB, The 'func' callback passed into myobject_listen_async
* will be invoked from the main event thread, despite the
* actual operation being performed in a different thread.
*/
/**
* qio_task_new:
* @source: the object on which the operation is invoked
* @func: the callback to invoke when the task completes
* @opaque: opaque data to pass to @func when invoked
* @destroy: optional callback to free @opaque
*
* Creates a new task struct to track completion of a
* background operation running on the object @source.
* When the operation completes or fails, the callback
* @func will be invoked. The callback can access the
* 'err' attribute in the task object to determine if
* the operation was successful or not.
*
* The returned task will be released when qio_task_complete()
* is invoked.
*
* Returns: the task struct
*/
QIOTask *qio_task_new(Object *source,
QIOTaskFunc func,
gpointer opaque,
GDestroyNotify destroy);
/**
* qio_task_run_in_thread:
* @task: the task struct
* @worker: the function to invoke in a thread
* @opaque: opaque data to pass to @worker
* @destroy: function to free @opaque
* @context: the context to run the complete hook. If %NULL, the
* default context will be used.
*
* Run a task in a background thread. When @worker
* returns it will call qio_task_complete() in
* the event thread context that provided.
*/
void qio_task_run_in_thread(QIOTask *task,
QIOTaskWorker worker,
gpointer opaque,
GDestroyNotify destroy,
GMainContext *context);
/**
* qio_task_complete:
* @task: the task struct
*
* Invoke the completion callback for @task and
* then free its memory.
*/
void qio_task_complete(QIOTask *task);
/**
* qio_task_set_error:
* @task: the task struct
* @err: pointer to the error, or NULL
*
* Associate an error with the task, which can later
* be retrieved with the qio_task_propagate_error()
* method. This method takes ownership of @err, so
* it is not valid to access it after this call
* completes. If @err is NULL this is a no-op. If
* this is call multiple times, only the first
* provided @err will be recorded, later ones will
* be discarded and freed.
*/
void qio_task_set_error(QIOTask *task,
Error *err);
/**
* qio_task_propagate_error:
* @task: the task struct
* @errp: pointer to a NULL-initialized error object
*
* Propagate the error associated with @task
* into @errp.
*
* Returns: true if an error was propagated, false otherwise
*/
bool qio_task_propagate_error(QIOTask *task,
Error **errp);
/**
* qio_task_set_result_pointer:
* @task: the task struct
* @result: pointer to the result data
*
* Associate an opaque result with the task,
* which can later be retrieved with the
* qio_task_get_result_pointer() method
*
*/
void qio_task_set_result_pointer(QIOTask *task,
gpointer result,
GDestroyNotify notify);
/**
* qio_task_get_result_pointer:
* @task: the task struct
*
* Retrieve the opaque result data associated
* with the task, if any.
*
* Returns: the task result, or NULL
*/
gpointer qio_task_get_result_pointer(QIOTask *task);
/**
* qio_task_get_source:
* @task: the task struct
*
* Get the source object associated with the background
* task. The caller does not own a reference on the
* returned Object, and so should call object_ref()
* if it wants to keep the object pointer outside the
* lifetime of the QIOTask object.
*
* Returns: the source object
*/
Object *qio_task_get_source(QIOTask *task);
#endif /* QIO_TASK_H */