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de1dbcee43
Document similar real world examples in the kernel corresponding to the second and third code snippets. Also correct an issue in release_referenced() in the code snippet example. Cc: oleg@redhat.com Cc: jannh@google.com Signed-off-by: Joel Fernandes (Google) <joel@joelfernandes.org> [ paulmck: Do a bit of wordsmithing. ] Signed-off-by: Paul E. McKenney <paulmck@linux.ibm.com>
152 lines
5.1 KiB
Plaintext
152 lines
5.1 KiB
Plaintext
Reference-count design for elements of lists/arrays protected by RCU.
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Please note that the percpu-ref feature is likely your first
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stop if you need to combine reference counts and RCU. Please see
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include/linux/percpu-refcount.h for more information. However, in
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those unusual cases where percpu-ref would consume too much memory,
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please read on.
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------------------------------------------------------------------------
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Reference counting on elements of lists which are protected by traditional
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reader/writer spinlocks or semaphores are straightforward:
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CODE LISTING A:
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1. 2.
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add() search_and_reference()
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{ {
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alloc_object read_lock(&list_lock);
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... search_for_element
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atomic_set(&el->rc, 1); atomic_inc(&el->rc);
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write_lock(&list_lock); ...
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add_element read_unlock(&list_lock);
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... ...
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write_unlock(&list_lock); }
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}
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3. 4.
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release_referenced() delete()
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{ {
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... write_lock(&list_lock);
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if(atomic_dec_and_test(&el->rc)) ...
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kfree(el);
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... remove_element
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} write_unlock(&list_lock);
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...
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if (atomic_dec_and_test(&el->rc))
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kfree(el);
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...
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}
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If this list/array is made lock free using RCU as in changing the
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write_lock() in add() and delete() to spin_lock() and changing read_lock()
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in search_and_reference() to rcu_read_lock(), the atomic_inc() in
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search_and_reference() could potentially hold reference to an element which
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has already been deleted from the list/array. Use atomic_inc_not_zero()
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in this scenario as follows:
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CODE LISTING B:
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1. 2.
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add() search_and_reference()
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{ {
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alloc_object rcu_read_lock();
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... search_for_element
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atomic_set(&el->rc, 1); if (!atomic_inc_not_zero(&el->rc)) {
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spin_lock(&list_lock); rcu_read_unlock();
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return FAIL;
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add_element }
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... ...
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spin_unlock(&list_lock); rcu_read_unlock();
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} }
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3. 4.
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release_referenced() delete()
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{ {
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... spin_lock(&list_lock);
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if (atomic_dec_and_test(&el->rc)) ...
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call_rcu(&el->head, el_free); remove_element
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... spin_unlock(&list_lock);
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} ...
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if (atomic_dec_and_test(&el->rc))
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call_rcu(&el->head, el_free);
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...
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}
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Sometimes, a reference to the element needs to be obtained in the
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update (write) stream. In such cases, atomic_inc_not_zero() might be
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overkill, since we hold the update-side spinlock. One might instead
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use atomic_inc() in such cases.
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It is not always convenient to deal with "FAIL" in the
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search_and_reference() code path. In such cases, the
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atomic_dec_and_test() may be moved from delete() to el_free()
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as follows:
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CODE LISTING C:
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1. 2.
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add() search_and_reference()
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{ {
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alloc_object rcu_read_lock();
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... search_for_element
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atomic_set(&el->rc, 1); atomic_inc(&el->rc);
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spin_lock(&list_lock); ...
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add_element rcu_read_unlock();
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... }
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spin_unlock(&list_lock); 4.
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} delete()
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3. {
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release_referenced() spin_lock(&list_lock);
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{ ...
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... remove_element
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if (atomic_dec_and_test(&el->rc)) spin_unlock(&list_lock);
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kfree(el); ...
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... call_rcu(&el->head, el_free);
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} ...
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5. }
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void el_free(struct rcu_head *rhp)
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{
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release_referenced();
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}
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The key point is that the initial reference added by add() is not removed
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until after a grace period has elapsed following removal. This means that
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search_and_reference() cannot find this element, which means that the value
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of el->rc cannot increase. Thus, once it reaches zero, there are no
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readers that can or ever will be able to reference the element. The
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element can therefore safely be freed. This in turn guarantees that if
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any reader finds the element, that reader may safely acquire a reference
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without checking the value of the reference counter.
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A clear advantage of the RCU-based pattern in listing C over the one
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in listing B is that any call to search_and_reference() that locates
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a given object will succeed in obtaining a reference to that object,
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even given a concurrent invocation of delete() for that same object.
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Similarly, a clear advantage of both listings B and C over listing A is
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that a call to delete() is not delayed even if there are an arbitrarily
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large number of calls to search_and_reference() searching for the same
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object that delete() was invoked on. Instead, all that is delayed is
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the eventual invocation of kfree(), which is usually not a problem on
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modern computer systems, even the small ones.
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In cases where delete() can sleep, synchronize_rcu() can be called from
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delete(), so that el_free() can be subsumed into delete as follows:
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4.
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delete()
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{
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spin_lock(&list_lock);
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...
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remove_element
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spin_unlock(&list_lock);
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...
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synchronize_rcu();
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if (atomic_dec_and_test(&el->rc))
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kfree(el);
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...
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}
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As additional examples in the kernel, the pattern in listing C is used by
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reference counting of struct pid, while the pattern in listing B is used by
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struct posix_acl.
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