include/block/graph-lock.h - qemu - Git at Google

 /*
  * Graph lock: rwlock to protect block layer graph manipulations (add/remove
  * edges and nodes)
  *
  *  Copyright (c) 2022 Red Hat
  *
  * 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 2.1 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 GRAPH_LOCK_H
 #define GRAPH_LOCK_H

 #include "qemu/clang-tsa.h"

 /**
  * Graph Lock API
  * This API provides a rwlock used to protect block layer
  * graph modifications like edge (BdrvChild) and node (BlockDriverState)
  * addition and removal.
  * Currently we have 1 writer only, the Main loop, and many
  * readers, mostly coroutines running in other AioContext thus other threads.
  *
  * We distinguish between writer (main loop, under BQL) that modifies the
  * graph, and readers (all other coroutines running in various AioContext),
  * that go through the graph edges, reading
  * BlockDriverState ->parents and->children.
  *
  * The writer (main loop)  has an "exclusive" access, so it first waits for
  * current read to finish, and then prevents incoming ones from
  * entering while it has the exclusive access.
  *
  * The readers (coroutines in multiple AioContext) are free to
  * access the graph as long the writer is not modifying the graph.
  * In case it is, they go in a CoQueue and sleep until the writer
  * is done.
  *
  * If a coroutine changes AioContext, the counter in the original and new
  * AioContext are left intact, since the writer does not care where is the
  * reader, but only if there is one.
  * As a result, some AioContexts might have a negative reader count, to
  * balance the positive count of the AioContext that took the lock.
  * This also means that when an AioContext is deleted it may have a nonzero
  * reader count. In that case we transfer the count to a global shared counter
  * so that the writer is always aware of all readers.
  */
 typedef struct BdrvGraphRWlock BdrvGraphRWlock;

 /* Dummy lock object to use for Thread Safety Analysis (TSA) */
 typedef struct TSA_CAPABILITY("mutex") BdrvGraphLock {
 } BdrvGraphLock;

 extern BdrvGraphLock graph_lock;

 /*
  * clang doesn't check consistency in locking annotations between forward
  * declarations and the function definition. Having the annotation on the
  * definition, but not the declaration in a header file, may give the reader
  * a false sense of security because the condition actually remains unchecked
  * for callers in other source files.
  *
  * Therefore, as a convention, for public functions, GRAPH_RDLOCK and
  * GRAPH_WRLOCK annotations should be present only in the header file.
  */
 #define GRAPH_WRLOCK TSA_REQUIRES(graph_lock)
 #define GRAPH_RDLOCK TSA_REQUIRES_SHARED(graph_lock)
 #define GRAPH_UNLOCKED TSA_EXCLUDES(graph_lock)

 /*
  * TSA annotations are not part of function types, so checks are defeated when
  * using a function pointer. As a workaround, annotate function pointers with
  * this macro that will require that the lock is at least taken while reading
  * the pointer. In most cases this is equivalent to actually protecting the
  * function call.
  */
 #define GRAPH_RDLOCK_PTR TSA_GUARDED_BY(graph_lock)
 #define GRAPH_WRLOCK_PTR TSA_GUARDED_BY(graph_lock)
 #define GRAPH_UNLOCKED_PTR

 /*
  * register_aiocontext:
  * Add AioContext @ctx to the list of AioContext.
  * This list is used to obtain the total number of readers
  * currently running the graph.
  */
 void register_aiocontext(AioContext *ctx);

 /*
  * unregister_aiocontext:
  * Removes AioContext @ctx to the list of AioContext.
  */
 void unregister_aiocontext(AioContext *ctx);

 /*
  * bdrv_graph_wrlock:
  * Start an exclusive write operation to modify the graph. This means we are
  * adding or removing an edge or a node in the block layer graph. Nobody else
  * is allowed to access the graph.
  *
  * Must only be called from outside bdrv_graph_co_rdlock.
  *
  * The wrlock can only be taken from the main loop, with BQL held, as only the
  * main loop is allowed to modify the graph.
  */
 void no_coroutine_fn TSA_ACQUIRE(graph_lock) TSA_NO_TSA
 bdrv_graph_wrlock(void);

 /*
  * bdrv_graph_wrunlock:
  * Write finished, reset global has_writer to 0 and restart
  * all readers that are waiting.
  */
 void no_coroutine_fn TSA_RELEASE(graph_lock) TSA_NO_TSA
 bdrv_graph_wrunlock(void);

 /*
  * bdrv_graph_co_rdlock:
  * Read the bs graph. This usually means traversing all nodes in
  * the graph, therefore it can't happen while another thread is
  * modifying it.
  * Increases the reader counter of the current aiocontext,
  * and if has_writer is set, it means that the writer is modifying
  * the graph, therefore wait in a coroutine queue.
  * The writer will then wake this coroutine once it is done.
  *
  * This lock should be taken from Iothreads (IO_CODE() class of functions)
  * because it signals the writer that there are some
  * readers currently running, or waits until the current
  * write is finished before continuing.
  * Calling this function from the Main Loop with BQL held
  * is not necessary, since the Main Loop itself is the only
  * writer, thus won't be able to read and write at the same time.
  * The only exception to that is when we can't take the lock in the
  * function/coroutine itself, and need to delegate the caller (usually main
  * loop) to take it and wait that the coroutine ends, so that
  * we always signal that a reader is running.
  */
 void coroutine_fn TSA_ACQUIRE_SHARED(graph_lock) TSA_NO_TSA
 bdrv_graph_co_rdlock(void);

 /*
  * bdrv_graph_rdunlock:
  * Read terminated, decrease the count of readers in the current aiocontext.
  * If the writer is waiting for reads to finish (has_writer == 1), signal
  * the writer that we are done via aio_wait_kick() to let it continue.
  */
 void coroutine_fn TSA_RELEASE_SHARED(graph_lock) TSA_NO_TSA
 bdrv_graph_co_rdunlock(void);

 /*
  * bdrv_graph_rd{un}lock_main_loop:
  * Just a placeholder to mark where the graph rdlock should be taken
  * in the main loop. It is just asserting that we are not
  * in a coroutine and in GLOBAL_STATE_CODE.
  */
 void TSA_ACQUIRE_SHARED(graph_lock) TSA_NO_TSA
 bdrv_graph_rdlock_main_loop(void);

 void TSA_RELEASE_SHARED(graph_lock) TSA_NO_TSA
 bdrv_graph_rdunlock_main_loop(void);

 /*
  * assert_bdrv_graph_readable:
  * Make sure that the reader is either the main loop,
  * or there is at least a reader helding the rdlock.
  * In this way an incoming writer is aware of the read and waits.
  */
 void GRAPH_RDLOCK assert_bdrv_graph_readable(void);

 /*
  * assert_bdrv_graph_writable:
  * Make sure that the writer is the main loop and has set @has_writer,
  * so that incoming readers will pause.
  */
 void GRAPH_WRLOCK assert_bdrv_graph_writable(void);

 /*
  * Calling this function tells TSA that we know that the lock is effectively
  * taken even though we cannot prove it (yet) with GRAPH_RDLOCK. This can be
  * useful in intermediate stages of a conversion to using the GRAPH_RDLOCK
  * macro.
  */
 static inline void TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA
 assume_graph_lock(void)
 {
 }

 typedef struct GraphLockable { } GraphLockable;

 /*
  * In C, compound literals have the lifetime of an automatic variable.
  * In C++ it would be different, but then C++ wouldn't need QemuLockable
  * either...
  */
 #define GML_OBJ_() (&(GraphLockable) { })

 /*
  * This is not marked as TSA_ACQUIRE_SHARED() because TSA doesn't understand the
  * cleanup attribute and would therefore complain that the graph is never
  * unlocked. TSA_ASSERT_SHARED() makes sure that the following calls know that
  * we hold the lock while unlocking is left unchecked.
  */
 static inline GraphLockable * TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA coroutine_fn
 graph_lockable_auto_lock(GraphLockable *x)
 {
     bdrv_graph_co_rdlock();
     return x;
 }

 static inline void TSA_NO_TSA coroutine_fn
 graph_lockable_auto_unlock(GraphLockable *x)
 {
     bdrv_graph_co_rdunlock();
 }

 G_DEFINE_AUTOPTR_CLEANUP_FUNC(GraphLockable, graph_lockable_auto_unlock)

 #define WITH_GRAPH_RDLOCK_GUARD_(var)                                         \
     for (g_autoptr(GraphLockable) var = graph_lockable_auto_lock(GML_OBJ_()); \
          var;                                                                 \
          graph_lockable_auto_unlock(var), var = NULL)

 #define WITH_GRAPH_RDLOCK_GUARD() \
     WITH_GRAPH_RDLOCK_GUARD_(glue(graph_lockable_auto, __COUNTER__))

 #define GRAPH_RDLOCK_GUARD(x)                                       \
     g_autoptr(GraphLockable)                                        \
     glue(graph_lockable_auto, __COUNTER__) G_GNUC_UNUSED =          \
             graph_lockable_auto_lock(GML_OBJ_())


 typedef struct GraphLockableMainloop { } GraphLockableMainloop;

 /*
  * In C, compound literals have the lifetime of an automatic variable.
  * In C++ it would be different, but then C++ wouldn't need QemuLockable
  * either...
  */
 #define GMLML_OBJ_() (&(GraphLockableMainloop) { })

 /*
  * This is not marked as TSA_ACQUIRE_SHARED() because TSA doesn't understand the
  * cleanup attribute and would therefore complain that the graph is never
  * unlocked. TSA_ASSERT_SHARED() makes sure that the following calls know that
  * we hold the lock while unlocking is left unchecked.
  */
 static inline GraphLockableMainloop * TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA
 graph_lockable_auto_lock_mainloop(GraphLockableMainloop *x)
 {
     bdrv_graph_rdlock_main_loop();
     return x;
 }

 static inline void TSA_NO_TSA
 graph_lockable_auto_unlock_mainloop(GraphLockableMainloop *x)
 {
     bdrv_graph_rdunlock_main_loop();
 }

 G_DEFINE_AUTOPTR_CLEANUP_FUNC(GraphLockableMainloop,
                               graph_lockable_auto_unlock_mainloop)

 #define GRAPH_RDLOCK_GUARD_MAINLOOP(x)                              \
     g_autoptr(GraphLockableMainloop)                                \
     glue(graph_lockable_auto, __COUNTER__) G_GNUC_UNUSED =          \
             graph_lockable_auto_lock_mainloop(GMLML_OBJ_())

 #endif /* GRAPH_LOCK_H */
	/*
	* Graph lock: rwlock to protect block layer graph manipulations (add/remove
	* edges and nodes)
	*
	* Copyright (c) 2022 Red Hat
	*
	* 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 2.1 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 GRAPH_LOCK_H
	#define GRAPH_LOCK_H

	#include "qemu/clang-tsa.h"

	/**
	* Graph Lock API
	* This API provides a rwlock used to protect block layer
	* graph modifications like edge (BdrvChild) and node (BlockDriverState)
	* addition and removal.
	* Currently we have 1 writer only, the Main loop, and many
	* readers, mostly coroutines running in other AioContext thus other threads.
	*
	* We distinguish between writer (main loop, under BQL) that modifies the
	* graph, and readers (all other coroutines running in various AioContext),
	* that go through the graph edges, reading
	* BlockDriverState ->parents and->children.
	*
	* The writer (main loop) has an "exclusive" access, so it first waits for
	* current read to finish, and then prevents incoming ones from
	* entering while it has the exclusive access.
	*
	* The readers (coroutines in multiple AioContext) are free to
	* access the graph as long the writer is not modifying the graph.
	* In case it is, they go in a CoQueue and sleep until the writer
	* is done.
	*
	* If a coroutine changes AioContext, the counter in the original and new
	* AioContext are left intact, since the writer does not care where is the
	* reader, but only if there is one.
	* As a result, some AioContexts might have a negative reader count, to
	* balance the positive count of the AioContext that took the lock.
	* This also means that when an AioContext is deleted it may have a nonzero
	* reader count. In that case we transfer the count to a global shared counter
	* so that the writer is always aware of all readers.
	*/
	typedef struct BdrvGraphRWlock BdrvGraphRWlock;

	/* Dummy lock object to use for Thread Safety Analysis (TSA) */
	typedef struct TSA_CAPABILITY("mutex") BdrvGraphLock {
	} BdrvGraphLock;

	extern BdrvGraphLock graph_lock;

	/*
	* clang doesn't check consistency in locking annotations between forward
	* declarations and the function definition. Having the annotation on the
	* definition, but not the declaration in a header file, may give the reader
	* a false sense of security because the condition actually remains unchecked
	* for callers in other source files.
	*
	* Therefore, as a convention, for public functions, GRAPH_RDLOCK and
	* GRAPH_WRLOCK annotations should be present only in the header file.
	*/
	#define GRAPH_WRLOCK TSA_REQUIRES(graph_lock)
	#define GRAPH_RDLOCK TSA_REQUIRES_SHARED(graph_lock)
	#define GRAPH_UNLOCKED TSA_EXCLUDES(graph_lock)

	/*
	* TSA annotations are not part of function types, so checks are defeated when
	* using a function pointer. As a workaround, annotate function pointers with
	* this macro that will require that the lock is at least taken while reading
	* the pointer. In most cases this is equivalent to actually protecting the
	* function call.
	*/
	#define GRAPH_RDLOCK_PTR TSA_GUARDED_BY(graph_lock)
	#define GRAPH_WRLOCK_PTR TSA_GUARDED_BY(graph_lock)
	#define GRAPH_UNLOCKED_PTR

	/*
	* register_aiocontext:
	* Add AioContext @ctx to the list of AioContext.
	* This list is used to obtain the total number of readers
	* currently running the graph.
	*/
	void register_aiocontext(AioContext *ctx);

	/*
	* unregister_aiocontext:
	* Removes AioContext @ctx to the list of AioContext.
	*/
	void unregister_aiocontext(AioContext *ctx);

	/*
	* bdrv_graph_wrlock:
	* Start an exclusive write operation to modify the graph. This means we are
	* adding or removing an edge or a node in the block layer graph. Nobody else
	* is allowed to access the graph.
	*
	* Must only be called from outside bdrv_graph_co_rdlock.
	*
	* The wrlock can only be taken from the main loop, with BQL held, as only the
	* main loop is allowed to modify the graph.
	*/
	void no_coroutine_fn TSA_ACQUIRE(graph_lock) TSA_NO_TSA
	bdrv_graph_wrlock(void);

	/*
	* bdrv_graph_wrunlock:
	* Write finished, reset global has_writer to 0 and restart
	* all readers that are waiting.
	*/
	void no_coroutine_fn TSA_RELEASE(graph_lock) TSA_NO_TSA
	bdrv_graph_wrunlock(void);

	/*
	* bdrv_graph_co_rdlock:
	* Read the bs graph. This usually means traversing all nodes in
	* the graph, therefore it can't happen while another thread is
	* modifying it.
	* Increases the reader counter of the current aiocontext,
	* and if has_writer is set, it means that the writer is modifying
	* the graph, therefore wait in a coroutine queue.
	* The writer will then wake this coroutine once it is done.
	*
	* This lock should be taken from Iothreads (IO_CODE() class of functions)
	* because it signals the writer that there are some
	* readers currently running, or waits until the current
	* write is finished before continuing.
	* Calling this function from the Main Loop with BQL held
	* is not necessary, since the Main Loop itself is the only
	* writer, thus won't be able to read and write at the same time.
	* The only exception to that is when we can't take the lock in the
	* function/coroutine itself, and need to delegate the caller (usually main
	* loop) to take it and wait that the coroutine ends, so that
	* we always signal that a reader is running.
	*/
	void coroutine_fn TSA_ACQUIRE_SHARED(graph_lock) TSA_NO_TSA
	bdrv_graph_co_rdlock(void);

	/*
	* bdrv_graph_rdunlock:
	* Read terminated, decrease the count of readers in the current aiocontext.
	* If the writer is waiting for reads to finish (has_writer == 1), signal
	* the writer that we are done via aio_wait_kick() to let it continue.
	*/
	void coroutine_fn TSA_RELEASE_SHARED(graph_lock) TSA_NO_TSA
	bdrv_graph_co_rdunlock(void);

	/*
	* bdrv_graph_rd{un}lock_main_loop:
	* Just a placeholder to mark where the graph rdlock should be taken
	* in the main loop. It is just asserting that we are not
	* in a coroutine and in GLOBAL_STATE_CODE.
	*/
	void TSA_ACQUIRE_SHARED(graph_lock) TSA_NO_TSA
	bdrv_graph_rdlock_main_loop(void);

	void TSA_RELEASE_SHARED(graph_lock) TSA_NO_TSA
	bdrv_graph_rdunlock_main_loop(void);

	/*
	* assert_bdrv_graph_readable:
	* Make sure that the reader is either the main loop,
	* or there is at least a reader helding the rdlock.
	* In this way an incoming writer is aware of the read and waits.
	*/
	void GRAPH_RDLOCK assert_bdrv_graph_readable(void);

	/*
	* assert_bdrv_graph_writable:
	* Make sure that the writer is the main loop and has set @has_writer,
	* so that incoming readers will pause.
	*/
	void GRAPH_WRLOCK assert_bdrv_graph_writable(void);

	/*
	* Calling this function tells TSA that we know that the lock is effectively
	* taken even though we cannot prove it (yet) with GRAPH_RDLOCK. This can be
	* useful in intermediate stages of a conversion to using the GRAPH_RDLOCK
	* macro.
	*/
	static inline void TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA
	assume_graph_lock(void)
	{
	}

	typedef struct GraphLockable { } GraphLockable;

	/*
	* In C, compound literals have the lifetime of an automatic variable.
	* In C++ it would be different, but then C++ wouldn't need QemuLockable
	* either...
	*/
	#define GML_OBJ_() (&(GraphLockable) { })

	/*
	* This is not marked as TSA_ACQUIRE_SHARED() because TSA doesn't understand the
	* cleanup attribute and would therefore complain that the graph is never
	* unlocked. TSA_ASSERT_SHARED() makes sure that the following calls know that
	* we hold the lock while unlocking is left unchecked.
	*/
	static inline GraphLockable * TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA coroutine_fn
	graph_lockable_auto_lock(GraphLockable *x)
	{
	bdrv_graph_co_rdlock();
	return x;
	}

	static inline void TSA_NO_TSA coroutine_fn
	graph_lockable_auto_unlock(GraphLockable *x)
	{
	bdrv_graph_co_rdunlock();
	}

	G_DEFINE_AUTOPTR_CLEANUP_FUNC(GraphLockable, graph_lockable_auto_unlock)

	#define WITH_GRAPH_RDLOCK_GUARD_(var) \
	for (g_autoptr(GraphLockable) var = graph_lockable_auto_lock(GML_OBJ_()); \
	var; \
	graph_lockable_auto_unlock(var), var = NULL)

	#define WITH_GRAPH_RDLOCK_GUARD() \
	WITH_GRAPH_RDLOCK_GUARD_(glue(graph_lockable_auto, __COUNTER__))

	#define GRAPH_RDLOCK_GUARD(x) \
	g_autoptr(GraphLockable) \
	glue(graph_lockable_auto, __COUNTER__) G_GNUC_UNUSED = \
	graph_lockable_auto_lock(GML_OBJ_())


	typedef struct GraphLockableMainloop { } GraphLockableMainloop;

	/*
	* In C, compound literals have the lifetime of an automatic variable.
	* In C++ it would be different, but then C++ wouldn't need QemuLockable
	* either...
	*/
	#define GMLML_OBJ_() (&(GraphLockableMainloop) { })

	/*
	* This is not marked as TSA_ACQUIRE_SHARED() because TSA doesn't understand the
	* cleanup attribute and would therefore complain that the graph is never
	* unlocked. TSA_ASSERT_SHARED() makes sure that the following calls know that
	* we hold the lock while unlocking is left unchecked.
	*/
	static inline GraphLockableMainloop * TSA_ASSERT_SHARED(graph_lock) TSA_NO_TSA
	graph_lockable_auto_lock_mainloop(GraphLockableMainloop *x)
	{
	bdrv_graph_rdlock_main_loop();
	return x;
	}

	static inline void TSA_NO_TSA
	graph_lockable_auto_unlock_mainloop(GraphLockableMainloop *x)
	{
	bdrv_graph_rdunlock_main_loop();
	}

	G_DEFINE_AUTOPTR_CLEANUP_FUNC(GraphLockableMainloop,
	graph_lockable_auto_unlock_mainloop)

	#define GRAPH_RDLOCK_GUARD_MAINLOOP(x) \
	g_autoptr(GraphLockableMainloop) \
	glue(graph_lockable_auto, __COUNTER__) G_GNUC_UNUSED = \
	graph_lockable_auto_lock_mainloop(GMLML_OBJ_())

	#endif /* GRAPH_LOCK_H */