fbcc3e5004
This is complex, but I think it is reasonably documented in the source. Signed-off-by: Paolo Bonzini <pbonzini@redhat.com> Reviewed-by: Fam Zheng <famz@redhat.com> Reviewed-by: Stefan Hajnoczi <stefanha@redhat.com> Message-id: 20170112180800.21085-5-pbonzini@redhat.com Signed-off-by: Stefan Hajnoczi <stefanha@redhat.com>
278 lines
9.8 KiB
Plaintext
278 lines
9.8 KiB
Plaintext
DOCUMENTATION FOR LOCKED COUNTERS (aka QemuLockCnt)
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===================================================
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QEMU often uses reference counts to track data structures that are being
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accessed and should not be freed. For example, a loop that invoke
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callbacks like this is not safe:
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QLIST_FOREACH_SAFE(ioh, &io_handlers, next, pioh) {
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if (ioh->revents & G_IO_OUT) {
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ioh->fd_write(ioh->opaque);
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}
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}
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QLIST_FOREACH_SAFE protects against deletion of the current node (ioh)
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by stashing away its "next" pointer. However, ioh->fd_write could
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actually delete the next node from the list. The simplest way to
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avoid this is to mark the node as deleted, and remove it from the
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list in the above loop:
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QLIST_FOREACH_SAFE(ioh, &io_handlers, next, pioh) {
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if (ioh->deleted) {
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QLIST_REMOVE(ioh, next);
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g_free(ioh);
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} else {
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if (ioh->revents & G_IO_OUT) {
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ioh->fd_write(ioh->opaque);
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}
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}
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}
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If however this loop must also be reentrant, i.e. it is possible that
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ioh->fd_write invokes the loop again, some kind of counting is needed:
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walking_handlers++;
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QLIST_FOREACH_SAFE(ioh, &io_handlers, next, pioh) {
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if (ioh->deleted) {
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if (walking_handlers == 1) {
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QLIST_REMOVE(ioh, next);
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g_free(ioh);
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}
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} else {
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if (ioh->revents & G_IO_OUT) {
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ioh->fd_write(ioh->opaque);
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}
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}
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}
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walking_handlers--;
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One may think of using the RCU primitives, rcu_read_lock() and
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rcu_read_unlock(); effectively, the RCU nesting count would take
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the place of the walking_handlers global variable. Indeed,
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reference counting and RCU have similar purposes, but their usage in
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general is complementary:
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- reference counting is fine-grained and limited to a single data
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structure; RCU delays reclamation of *all* RCU-protected data
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structures;
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- reference counting works even in the presence of code that keeps
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a reference for a long time; RCU critical sections in principle
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should be kept short;
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- reference counting is often applied to code that is not thread-safe
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but is reentrant; in fact, usage of reference counting in QEMU predates
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the introduction of threads by many years. RCU is generally used to
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protect readers from other threads freeing memory after concurrent
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modifications to a data structure.
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- reclaiming data can be done by a separate thread in the case of RCU;
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this can improve performance, but also delay reclamation undesirably.
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With reference counting, reclamation is deterministic.
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This file documents QemuLockCnt, an abstraction for using reference
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counting in code that has to be both thread-safe and reentrant.
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QemuLockCnt concepts
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--------------------
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A QemuLockCnt comprises both a counter and a mutex; it has primitives
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to increment and decrement the counter, and to take and release the
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mutex. The counter notes how many visits to the data structures are
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taking place (the visits could be from different threads, or there could
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be multiple reentrant visits from the same thread). The basic rules
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governing the counter/mutex pair then are the following:
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- Data protected by the QemuLockCnt must not be freed unless the
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counter is zero and the mutex is taken.
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- A new visit cannot be started while the counter is zero and the
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mutex is taken.
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Most of the time, the mutex protects all writes to the data structure,
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not just frees, though there could be cases where this is not necessary.
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Reads, instead, can be done without taking the mutex, as long as the
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readers and writers use the same macros that are used for RCU, for
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example atomic_rcu_read, atomic_rcu_set, QLIST_FOREACH_RCU, etc. This is
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because the reads are done outside a lock and a set or QLIST_INSERT_HEAD
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can happen concurrently with the read. The RCU API ensures that the
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processor and the compiler see all required memory barriers.
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This could be implemented simply by protecting the counter with the
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mutex, for example:
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// (1)
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qemu_mutex_lock(&walking_handlers_mutex);
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walking_handlers++;
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qemu_mutex_unlock(&walking_handlers_mutex);
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...
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// (2)
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qemu_mutex_lock(&walking_handlers_mutex);
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if (--walking_handlers == 0) {
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QLIST_FOREACH_SAFE(ioh, &io_handlers, next, pioh) {
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if (ioh->deleted) {
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QLIST_REMOVE(ioh, next);
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g_free(ioh);
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}
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}
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}
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qemu_mutex_unlock(&walking_handlers_mutex);
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Here, no frees can happen in the code represented by the ellipsis.
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If another thread is executing critical section (2), that part of
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the code cannot be entered, because the thread will not be able
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to increment the walking_handlers variable. And of course
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during the visit any other thread will see a nonzero value for
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walking_handlers, as in the single-threaded code.
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Note that it is possible for multiple concurrent accesses to delay
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the cleanup arbitrarily; in other words, for the walking_handlers
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counter to never become zero. For this reason, this technique is
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more easily applicable if concurrent access to the structure is rare.
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However, critical sections are easy to forget since you have to do
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them for each modification of the counter. QemuLockCnt ensures that
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all modifications of the counter take the lock appropriately, and it
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can also be more efficient in two ways:
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- it avoids taking the lock for many operations (for example
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incrementing the counter while it is non-zero);
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- on some platforms, one can implement QemuLockCnt to hold the lock
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and the mutex in a single word, making the fast path no more expensive
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than simply managing a counter using atomic operations (see
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docs/atomics.txt). This can be very helpful if concurrent access to
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the data structure is expected to be rare.
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Using the same mutex for frees and writes can still incur some small
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inefficiencies; for example, a visit can never start if the counter is
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zero and the mutex is taken---even if the mutex is taken by a write,
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which in principle need not block a visit of the data structure.
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However, these are usually not a problem if any of the following
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assumptions are valid:
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- concurrent access is possible but rare
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- writes are rare
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- writes are frequent, but this kind of write (e.g. appending to a
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list) has a very small critical section.
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For example, QEMU uses QemuLockCnt to manage an AioContext's list of
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bottom halves and file descriptor handlers. Modifications to the list
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of file descriptor handlers are rare. Creation of a new bottom half is
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frequent and can happen on a fast path; however: 1) it is almost never
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concurrent with a visit to the list of bottom halves; 2) it only has
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three instructions in the critical path, two assignments and a smp_wmb().
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QemuLockCnt API
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---------------
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The QemuLockCnt API is described in include/qemu/thread.h.
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QemuLockCnt usage
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-----------------
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This section explains the typical usage patterns for QemuLockCnt functions.
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Setting a variable to a non-NULL value can be done between
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qemu_lockcnt_lock and qemu_lockcnt_unlock:
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qemu_lockcnt_lock(&xyz_lockcnt);
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if (!xyz) {
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new_xyz = g_new(XYZ, 1);
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...
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atomic_rcu_set(&xyz, new_xyz);
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}
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qemu_lockcnt_unlock(&xyz_lockcnt);
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Accessing the value can be done between qemu_lockcnt_inc and
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qemu_lockcnt_dec:
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qemu_lockcnt_inc(&xyz_lockcnt);
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if (xyz) {
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XYZ *p = atomic_rcu_read(&xyz);
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...
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/* Accesses can now be done through "p". */
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}
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qemu_lockcnt_dec(&xyz_lockcnt);
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Freeing the object can similarly use qemu_lockcnt_lock and
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qemu_lockcnt_unlock, but you also need to ensure that the count
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is zero (i.e. there is no concurrent visit). Because qemu_lockcnt_inc
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takes the QemuLockCnt's lock, the count cannot become non-zero while
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the object is being freed. Freeing an object looks like this:
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qemu_lockcnt_lock(&xyz_lockcnt);
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if (!qemu_lockcnt_count(&xyz_lockcnt)) {
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g_free(xyz);
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xyz = NULL;
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}
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qemu_lockcnt_unlock(&xyz_lockcnt);
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If an object has to be freed right after a visit, you can combine
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the decrement, the locking and the check on count as follows:
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qemu_lockcnt_inc(&xyz_lockcnt);
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if (xyz) {
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XYZ *p = atomic_rcu_read(&xyz);
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...
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/* Accesses can now be done through "p". */
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}
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if (qemu_lockcnt_dec_and_lock(&xyz_lockcnt)) {
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g_free(xyz);
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xyz = NULL;
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qemu_lockcnt_unlock(&xyz_lockcnt);
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}
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QemuLockCnt can also be used to access a list as follows:
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qemu_lockcnt_inc(&io_handlers_lockcnt);
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QLIST_FOREACH_RCU(ioh, &io_handlers, pioh) {
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if (ioh->revents & G_IO_OUT) {
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ioh->fd_write(ioh->opaque);
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}
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}
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if (qemu_lockcnt_dec_and_lock(&io_handlers_lockcnt)) {
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QLIST_FOREACH_SAFE(ioh, &io_handlers, next, pioh) {
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if (ioh->deleted) {
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QLIST_REMOVE(ioh, next);
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g_free(ioh);
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}
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}
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qemu_lockcnt_unlock(&io_handlers_lockcnt);
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}
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Again, the RCU primitives are used because new items can be added to the
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list during the walk. QLIST_FOREACH_RCU ensures that the processor and
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the compiler see the appropriate memory barriers.
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An alternative pattern uses qemu_lockcnt_dec_if_lock:
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qemu_lockcnt_inc(&io_handlers_lockcnt);
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QLIST_FOREACH_SAFE_RCU(ioh, &io_handlers, next, pioh) {
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if (ioh->deleted) {
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if (qemu_lockcnt_dec_if_lock(&io_handlers_lockcnt)) {
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QLIST_REMOVE(ioh, next);
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g_free(ioh);
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qemu_lockcnt_inc_and_unlock(&io_handlers_lockcnt);
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}
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} else {
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if (ioh->revents & G_IO_OUT) {
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ioh->fd_write(ioh->opaque);
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}
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}
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}
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qemu_lockcnt_dec(&io_handlers_lockcnt);
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Here you can use qemu_lockcnt_dec instead of qemu_lockcnt_dec_and_lock,
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because there is no special task to do if the count goes from 1 to 0.
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