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More explicitly state what is, and what is not guaranteed to those who iterate a list while protected by RCU. [ paulmck: Apply Joel Fernandes feedback. ] Signed-off-by: Matthew Wilcox (Oracle) <willy@infradead.org> Reviewed-by: Joel Fernandes (Google) <joel@joelfernandes.org> Signed-off-by: Paul E. McKenney <paulmck@kernel.org> Signed-off-by: Frederic Weisbecker <frederic@kernel.org>
510 lines
18 KiB
ReStructuredText
510 lines
18 KiB
ReStructuredText
.. _list_rcu_doc:
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Using RCU to Protect Read-Mostly Linked Lists
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=============================================
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One of the most common uses of RCU is protecting read-mostly linked lists
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(``struct list_head`` in list.h). One big advantage of this approach is
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that all of the required memory ordering is provided by the list macros.
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This document describes several list-based RCU use cases.
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When iterating a list while holding the rcu_read_lock(), writers may
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modify the list. The reader is guaranteed to see all of the elements
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which were added to the list before they acquired the rcu_read_lock()
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and are still on the list when they drop the rcu_read_unlock().
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Elements which are added to, or removed from the list may or may not
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be seen. If the writer calls list_replace_rcu(), the reader may see
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either the old element or the new element; they will not see both,
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nor will they see neither.
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Example 1: Read-mostly list: Deferred Destruction
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-------------------------------------------------
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A widely used usecase for RCU lists in the kernel is lockless iteration over
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all processes in the system. ``task_struct::tasks`` represents the list node that
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links all the processes. The list can be traversed in parallel to any list
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additions or removals.
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The traversal of the list is done using ``for_each_process()`` which is defined
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by the 2 macros::
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#define next_task(p) \
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list_entry_rcu((p)->tasks.next, struct task_struct, tasks)
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#define for_each_process(p) \
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for (p = &init_task ; (p = next_task(p)) != &init_task ; )
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The code traversing the list of all processes typically looks like::
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rcu_read_lock();
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for_each_process(p) {
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/* Do something with p */
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}
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rcu_read_unlock();
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The simplified and heavily inlined code for removing a process from a
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task list is::
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void release_task(struct task_struct *p)
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{
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write_lock(&tasklist_lock);
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list_del_rcu(&p->tasks);
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write_unlock(&tasklist_lock);
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call_rcu(&p->rcu, delayed_put_task_struct);
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}
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When a process exits, ``release_task()`` calls ``list_del_rcu(&p->tasks)``
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via __exit_signal() and __unhash_process() under ``tasklist_lock``
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writer lock protection. The list_del_rcu() invocation removes
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the task from the list of all tasks. The ``tasklist_lock``
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prevents concurrent list additions/removals from corrupting the
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list. Readers using ``for_each_process()`` are not protected with the
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``tasklist_lock``. To prevent readers from noticing changes in the list
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pointers, the ``task_struct`` object is freed only after one or more
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grace periods elapse, with the help of call_rcu(), which is invoked via
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put_task_struct_rcu_user(). This deferring of destruction ensures that
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any readers traversing the list will see valid ``p->tasks.next`` pointers
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and deletion/freeing can happen in parallel with traversal of the list.
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This pattern is also called an **existence lock**, since RCU refrains
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from invoking the delayed_put_task_struct() callback function until
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all existing readers finish, which guarantees that the ``task_struct``
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object in question will remain in existence until after the completion
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of all RCU readers that might possibly have a reference to that object.
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Example 2: Read-Side Action Taken Outside of Lock: No In-Place Updates
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----------------------------------------------------------------------
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Some reader-writer locking use cases compute a value while holding
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the read-side lock, but continue to use that value after that lock is
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released. These use cases are often good candidates for conversion
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to RCU. One prominent example involves network packet routing.
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Because the packet-routing data tracks the state of equipment outside
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of the computer, it will at times contain stale data. Therefore, once
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the route has been computed, there is no need to hold the routing table
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static during transmission of the packet. After all, you can hold the
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routing table static all you want, but that won't keep the external
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Internet from changing, and it is the state of the external Internet
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that really matters. In addition, routing entries are typically added
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or deleted, rather than being modified in place. This is a rare example
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of the finite speed of light and the non-zero size of atoms actually
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helping make synchronization be lighter weight.
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A straightforward example of this type of RCU use case may be found in
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the system-call auditing support. For example, a reader-writer locked
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implementation of ``audit_filter_task()`` might be as follows::
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static enum audit_state audit_filter_task(struct task_struct *tsk, char **key)
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{
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struct audit_entry *e;
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enum audit_state state;
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read_lock(&auditsc_lock);
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/* Note: audit_filter_mutex held by caller. */
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list_for_each_entry(e, &audit_tsklist, list) {
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if (audit_filter_rules(tsk, &e->rule, NULL, &state)) {
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if (state == AUDIT_STATE_RECORD)
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*key = kstrdup(e->rule.filterkey, GFP_ATOMIC);
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read_unlock(&auditsc_lock);
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return state;
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}
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}
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read_unlock(&auditsc_lock);
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return AUDIT_BUILD_CONTEXT;
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}
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Here the list is searched under the lock, but the lock is dropped before
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the corresponding value is returned. By the time that this value is acted
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on, the list may well have been modified. This makes sense, since if
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you are turning auditing off, it is OK to audit a few extra system calls.
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This means that RCU can be easily applied to the read side, as follows::
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static enum audit_state audit_filter_task(struct task_struct *tsk, char **key)
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{
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struct audit_entry *e;
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enum audit_state state;
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rcu_read_lock();
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/* Note: audit_filter_mutex held by caller. */
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list_for_each_entry_rcu(e, &audit_tsklist, list) {
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if (audit_filter_rules(tsk, &e->rule, NULL, &state)) {
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if (state == AUDIT_STATE_RECORD)
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*key = kstrdup(e->rule.filterkey, GFP_ATOMIC);
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rcu_read_unlock();
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return state;
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}
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}
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rcu_read_unlock();
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return AUDIT_BUILD_CONTEXT;
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}
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The read_lock() and read_unlock() calls have become rcu_read_lock()
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and rcu_read_unlock(), respectively, and the list_for_each_entry()
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has become list_for_each_entry_rcu(). The **_rcu()** list-traversal
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primitives add READ_ONCE() and diagnostic checks for incorrect use
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outside of an RCU read-side critical section.
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The changes to the update side are also straightforward. A reader-writer lock
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might be used as follows for deletion and insertion in these simplified
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versions of audit_del_rule() and audit_add_rule()::
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static inline int audit_del_rule(struct audit_rule *rule,
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struct list_head *list)
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{
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struct audit_entry *e;
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write_lock(&auditsc_lock);
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list_for_each_entry(e, list, list) {
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if (!audit_compare_rule(rule, &e->rule)) {
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list_del(&e->list);
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write_unlock(&auditsc_lock);
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return 0;
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}
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}
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write_unlock(&auditsc_lock);
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return -EFAULT; /* No matching rule */
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}
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static inline int audit_add_rule(struct audit_entry *entry,
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struct list_head *list)
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{
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write_lock(&auditsc_lock);
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if (entry->rule.flags & AUDIT_PREPEND) {
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entry->rule.flags &= ~AUDIT_PREPEND;
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list_add(&entry->list, list);
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} else {
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list_add_tail(&entry->list, list);
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}
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write_unlock(&auditsc_lock);
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return 0;
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}
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Following are the RCU equivalents for these two functions::
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static inline int audit_del_rule(struct audit_rule *rule,
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struct list_head *list)
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{
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struct audit_entry *e;
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/* No need to use the _rcu iterator here, since this is the only
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* deletion routine. */
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list_for_each_entry(e, list, list) {
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if (!audit_compare_rule(rule, &e->rule)) {
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list_del_rcu(&e->list);
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call_rcu(&e->rcu, audit_free_rule);
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return 0;
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}
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}
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return -EFAULT; /* No matching rule */
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}
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static inline int audit_add_rule(struct audit_entry *entry,
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struct list_head *list)
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{
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if (entry->rule.flags & AUDIT_PREPEND) {
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entry->rule.flags &= ~AUDIT_PREPEND;
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list_add_rcu(&entry->list, list);
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} else {
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list_add_tail_rcu(&entry->list, list);
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}
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return 0;
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}
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Normally, the write_lock() and write_unlock() would be replaced by a
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spin_lock() and a spin_unlock(). But in this case, all callers hold
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``audit_filter_mutex``, so no additional locking is required. The
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auditsc_lock can therefore be eliminated, since use of RCU eliminates the
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need for writers to exclude readers.
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The list_del(), list_add(), and list_add_tail() primitives have been
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replaced by list_del_rcu(), list_add_rcu(), and list_add_tail_rcu().
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The **_rcu()** list-manipulation primitives add memory barriers that are
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needed on weakly ordered CPUs. The list_del_rcu() primitive omits the
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pointer poisoning debug-assist code that would otherwise cause concurrent
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readers to fail spectacularly.
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So, when readers can tolerate stale data and when entries are either added or
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deleted, without in-place modification, it is very easy to use RCU!
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Example 3: Handling In-Place Updates
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------------------------------------
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The system-call auditing code does not update auditing rules in place. However,
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if it did, the reader-writer-locked code to do so might look as follows
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(assuming only ``field_count`` is updated, otherwise, the added fields would
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need to be filled in)::
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static inline int audit_upd_rule(struct audit_rule *rule,
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struct list_head *list,
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__u32 newaction,
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__u32 newfield_count)
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{
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struct audit_entry *e;
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struct audit_entry *ne;
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write_lock(&auditsc_lock);
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/* Note: audit_filter_mutex held by caller. */
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list_for_each_entry(e, list, list) {
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if (!audit_compare_rule(rule, &e->rule)) {
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e->rule.action = newaction;
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e->rule.field_count = newfield_count;
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write_unlock(&auditsc_lock);
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return 0;
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}
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}
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write_unlock(&auditsc_lock);
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return -EFAULT; /* No matching rule */
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}
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The RCU version creates a copy, updates the copy, then replaces the old
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entry with the newly updated entry. This sequence of actions, allowing
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concurrent reads while making a copy to perform an update, is what gives
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RCU (*read-copy update*) its name.
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The RCU version of audit_upd_rule() is as follows::
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static inline int audit_upd_rule(struct audit_rule *rule,
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struct list_head *list,
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__u32 newaction,
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__u32 newfield_count)
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{
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struct audit_entry *e;
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struct audit_entry *ne;
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list_for_each_entry(e, list, list) {
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if (!audit_compare_rule(rule, &e->rule)) {
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ne = kmalloc(sizeof(*entry), GFP_ATOMIC);
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if (ne == NULL)
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return -ENOMEM;
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audit_copy_rule(&ne->rule, &e->rule);
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ne->rule.action = newaction;
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ne->rule.field_count = newfield_count;
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list_replace_rcu(&e->list, &ne->list);
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call_rcu(&e->rcu, audit_free_rule);
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return 0;
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}
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}
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return -EFAULT; /* No matching rule */
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}
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Again, this assumes that the caller holds ``audit_filter_mutex``. Normally, the
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writer lock would become a spinlock in this sort of code.
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The update_lsm_rule() does something very similar, for those who would
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prefer to look at real Linux-kernel code.
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Another use of this pattern can be found in the openswitch driver's *connection
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tracking table* code in ``ct_limit_set()``. The table holds connection tracking
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entries and has a limit on the maximum entries. There is one such table
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per-zone and hence one *limit* per zone. The zones are mapped to their limits
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through a hashtable using an RCU-managed hlist for the hash chains. When a new
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limit is set, a new limit object is allocated and ``ct_limit_set()`` is called
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to replace the old limit object with the new one using list_replace_rcu().
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The old limit object is then freed after a grace period using kfree_rcu().
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Example 4: Eliminating Stale Data
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---------------------------------
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The auditing example above tolerates stale data, as do most algorithms
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that are tracking external state. After all, given there is a delay
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from the time the external state changes before Linux becomes aware
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of the change, and so as noted earlier, a small quantity of additional
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RCU-induced staleness is generally not a problem.
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However, there are many examples where stale data cannot be tolerated.
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One example in the Linux kernel is the System V IPC (see the shm_lock()
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function in ipc/shm.c). This code checks a *deleted* flag under a
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per-entry spinlock, and, if the *deleted* flag is set, pretends that the
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entry does not exist. For this to be helpful, the search function must
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return holding the per-entry spinlock, as shm_lock() does in fact do.
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.. _quick_quiz:
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Quick Quiz:
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For the deleted-flag technique to be helpful, why is it necessary
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to hold the per-entry lock while returning from the search function?
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:ref:`Answer to Quick Quiz <quick_quiz_answer>`
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If the system-call audit module were to ever need to reject stale data, one way
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to accomplish this would be to add a ``deleted`` flag and a ``lock`` spinlock to the
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``audit_entry`` structure, and modify audit_filter_task() as follows::
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static enum audit_state audit_filter_task(struct task_struct *tsk)
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{
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struct audit_entry *e;
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enum audit_state state;
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rcu_read_lock();
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list_for_each_entry_rcu(e, &audit_tsklist, list) {
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if (audit_filter_rules(tsk, &e->rule, NULL, &state)) {
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spin_lock(&e->lock);
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if (e->deleted) {
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spin_unlock(&e->lock);
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rcu_read_unlock();
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return AUDIT_BUILD_CONTEXT;
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}
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rcu_read_unlock();
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if (state == AUDIT_STATE_RECORD)
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*key = kstrdup(e->rule.filterkey, GFP_ATOMIC);
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return state;
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}
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}
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rcu_read_unlock();
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return AUDIT_BUILD_CONTEXT;
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}
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The ``audit_del_rule()`` function would need to set the ``deleted`` flag under the
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spinlock as follows::
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static inline int audit_del_rule(struct audit_rule *rule,
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struct list_head *list)
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{
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struct audit_entry *e;
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/* No need to use the _rcu iterator here, since this
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* is the only deletion routine. */
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list_for_each_entry(e, list, list) {
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if (!audit_compare_rule(rule, &e->rule)) {
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spin_lock(&e->lock);
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list_del_rcu(&e->list);
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e->deleted = 1;
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spin_unlock(&e->lock);
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call_rcu(&e->rcu, audit_free_rule);
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return 0;
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}
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}
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return -EFAULT; /* No matching rule */
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}
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This too assumes that the caller holds ``audit_filter_mutex``.
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Note that this example assumes that entries are only added and deleted.
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Additional mechanism is required to deal correctly with the update-in-place
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performed by audit_upd_rule(). For one thing, audit_upd_rule() would
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need to hold the locks of both the old ``audit_entry`` and its replacement
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while executing the list_replace_rcu().
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Example 5: Skipping Stale Objects
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---------------------------------
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For some use cases, reader performance can be improved by skipping
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stale objects during read-side list traversal, where stale objects
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are those that will be removed and destroyed after one or more grace
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periods. One such example can be found in the timerfd subsystem. When a
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``CLOCK_REALTIME`` clock is reprogrammed (for example due to setting
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of the system time) then all programmed ``timerfds`` that depend on
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this clock get triggered and processes waiting on them are awakened in
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advance of their scheduled expiry. To facilitate this, all such timers
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are added to an RCU-managed ``cancel_list`` when they are setup in
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``timerfd_setup_cancel()``::
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static void timerfd_setup_cancel(struct timerfd_ctx *ctx, int flags)
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{
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spin_lock(&ctx->cancel_lock);
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if ((ctx->clockid == CLOCK_REALTIME ||
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ctx->clockid == CLOCK_REALTIME_ALARM) &&
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(flags & TFD_TIMER_ABSTIME) && (flags & TFD_TIMER_CANCEL_ON_SET)) {
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if (!ctx->might_cancel) {
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ctx->might_cancel = true;
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spin_lock(&cancel_lock);
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list_add_rcu(&ctx->clist, &cancel_list);
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spin_unlock(&cancel_lock);
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}
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} else {
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__timerfd_remove_cancel(ctx);
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}
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spin_unlock(&ctx->cancel_lock);
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}
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When a timerfd is freed (fd is closed), then the ``might_cancel``
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flag of the timerfd object is cleared, the object removed from the
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``cancel_list`` and destroyed, as shown in this simplified and inlined
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version of timerfd_release()::
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int timerfd_release(struct inode *inode, struct file *file)
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{
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struct timerfd_ctx *ctx = file->private_data;
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spin_lock(&ctx->cancel_lock);
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if (ctx->might_cancel) {
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ctx->might_cancel = false;
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spin_lock(&cancel_lock);
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list_del_rcu(&ctx->clist);
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spin_unlock(&cancel_lock);
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}
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spin_unlock(&ctx->cancel_lock);
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if (isalarm(ctx))
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alarm_cancel(&ctx->t.alarm);
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else
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hrtimer_cancel(&ctx->t.tmr);
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kfree_rcu(ctx, rcu);
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return 0;
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}
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If the ``CLOCK_REALTIME`` clock is set, for example by a time server, the
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hrtimer framework calls ``timerfd_clock_was_set()`` which walks the
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``cancel_list`` and wakes up processes waiting on the timerfd. While iterating
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the ``cancel_list``, the ``might_cancel`` flag is consulted to skip stale
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objects::
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void timerfd_clock_was_set(void)
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{
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ktime_t moffs = ktime_mono_to_real(0);
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struct timerfd_ctx *ctx;
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unsigned long flags;
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rcu_read_lock();
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list_for_each_entry_rcu(ctx, &cancel_list, clist) {
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if (!ctx->might_cancel)
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continue;
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spin_lock_irqsave(&ctx->wqh.lock, flags);
|
|
if (ctx->moffs != moffs) {
|
|
ctx->moffs = KTIME_MAX;
|
|
ctx->ticks++;
|
|
wake_up_locked_poll(&ctx->wqh, EPOLLIN);
|
|
}
|
|
spin_unlock_irqrestore(&ctx->wqh.lock, flags);
|
|
}
|
|
rcu_read_unlock();
|
|
}
|
|
|
|
The key point is that because RCU-protected traversal of the
|
|
``cancel_list`` happens concurrently with object addition and removal,
|
|
sometimes the traversal can access an object that has been removed from
|
|
the list. In this example, a flag is used to skip such objects.
|
|
|
|
|
|
Summary
|
|
-------
|
|
|
|
Read-mostly list-based data structures that can tolerate stale data are
|
|
the most amenable to use of RCU. The simplest case is where entries are
|
|
either added or deleted from the data structure (or atomically modified
|
|
in place), but non-atomic in-place modifications can be handled by making
|
|
a copy, updating the copy, then replacing the original with the copy.
|
|
If stale data cannot be tolerated, then a *deleted* flag may be used
|
|
in conjunction with a per-entry spinlock in order to allow the search
|
|
function to reject newly deleted data.
|
|
|
|
.. _quick_quiz_answer:
|
|
|
|
Answer to Quick Quiz:
|
|
For the deleted-flag technique to be helpful, why is it necessary
|
|
to hold the per-entry lock while returning from the search function?
|
|
|
|
If the search function drops the per-entry lock before returning,
|
|
then the caller will be processing stale data in any case. If it
|
|
is really OK to be processing stale data, then you don't need a
|
|
*deleted* flag. If processing stale data really is a problem,
|
|
then you need to hold the per-entry lock across all of the code
|
|
that uses the value that was returned.
|
|
|
|
:ref:`Back to Quick Quiz <quick_quiz>`
|