[net-next-2.6.git] / Documentation / kref.txt


krefs allow you to add reference counters to your objects.  If you
have objects that are used in multiple places and passed around, and
you don't have refcounts, your code is almost certainly broken.  If
you want refcounts, krefs are the way to go.

To use a kref, add one to your data structures like:

struct my_data
{
	.
	.
	struct kref refcount;
	.
	.
};

The kref can occur anywhere within the data structure.

You must initialize the kref after you allocate it.  To do this, call
kref_init as so:

     struct my_data *data;

     data = kmalloc(sizeof(*data), GFP_KERNEL);
     if (!data)
            return -ENOMEM;
     kref_init(&data->refcount);

This sets the refcount in the kref to 1.

Once you have an initialized kref, you must follow the following
rules:

1) If you make a non-temporary copy of a pointer, especially if
   it can be passed to another thread of execution, you must
   increment the refcount with kref_get() before passing it off:
       kref_get(&data->refcount);
   If you already have a valid pointer to a kref-ed structure (the
   refcount cannot go to zero) you may do this without a lock.

2) When you are done with a pointer, you must call kref_put():
       kref_put(&data->refcount, data_release);
   If this is the last reference to the pointer, the release
   routine will be called.  If the code never tries to get
   a valid pointer to a kref-ed structure without already
   holding a valid pointer, it is safe to do this without
   a lock.

3) If the code attempts to gain a reference to a kref-ed structure
   without already holding a valid pointer, it must serialize access
   where a kref_put() cannot occur during the kref_get(), and the
   structure must remain valid during the kref_get().

For example, if you allocate some data and then pass it to another
thread to process:

void data_release(struct kref *ref)
{
	struct my_data *data = container_of(ref, struct my_data, refcount);
	kfree(data);
}

void more_data_handling(void *cb_data)
{
	struct my_data *data = cb_data;
	.
	. do stuff with data here
	.
	kref_put(&data->refcount, data_release);
}

int my_data_handler(void)
{
	int rv = 0;
	struct my_data *data;
	struct task_struct *task;
	data = kmalloc(sizeof(*data), GFP_KERNEL);
	if (!data)
		return -ENOMEM;
	kref_init(&data->refcount);

	kref_get(&data->refcount);
	task = kthread_run(more_data_handling, data, "more_data_handling");
	if (task == ERR_PTR(-ENOMEM)) {
		rv = -ENOMEM;
		goto out;
	}

	.
	. do stuff with data here
	.
 out:
	kref_put(&data->refcount, data_release);
	return rv;
}

This way, it doesn't matter what order the two threads handle the
data, the kref_put() handles knowing when the data is not referenced
any more and releasing it.  The kref_get() does not require a lock,
since we already have a valid pointer that we own a refcount for.  The
put needs no lock because nothing tries to get the data without
already holding a pointer.

Note that the "before" in rule 1 is very important.  You should never
do something like:

	task = kthread_run(more_data_handling, data, "more_data_handling");
	if (task == ERR_PTR(-ENOMEM)) {
		rv = -ENOMEM;
		goto out;
	} else
		/* BAD BAD BAD - get is after the handoff */
		kref_get(&data->refcount);

Don't assume you know what you are doing and use the above construct.
First of all, you may not know what you are doing.  Second, you may
know what you are doing (there are some situations where locking is
involved where the above may be legal) but someone else who doesn't
know what they are doing may change the code or copy the code.  It's
bad style.  Don't do it.

There are some situations where you can optimize the gets and puts.
For instance, if you are done with an object and enqueuing it for
something else or passing it off to something else, there is no reason
to do a get then a put:

	/* Silly extra get and put */
	kref_get(&obj->ref);
	enqueue(obj);
	kref_put(&obj->ref, obj_cleanup);

Just do the enqueue.  A comment about this is always welcome:

	enqueue(obj);
	/* We are done with obj, so we pass our refcount off
	   to the queue.  DON'T TOUCH obj AFTER HERE! */

The last rule (rule 3) is the nastiest one to handle.  Say, for
instance, you have a list of items that are each kref-ed, and you wish
to get the first one.  You can't just pull the first item off the list
and kref_get() it.  That violates rule 3 because you are not already
holding a valid pointer.  You must add a mutex (or some other lock).
For instance:

static DEFINE_MUTEX(mutex);
static LIST_HEAD(q);
struct my_data
{
	struct kref      refcount;
	struct list_head link;
};

static struct my_data *get_entry()
{
	struct my_data *entry = NULL;
	mutex_lock(&mutex);
	if (!list_empty(&q)) {
		entry = container_of(q.next, struct my_q_entry, link);
		kref_get(&entry->refcount);
	}
	mutex_unlock(&mutex);
	return entry;
}

static void release_entry(struct kref *ref)
{
	struct my_data *entry = container_of(ref, struct my_data, refcount);

	list_del(&entry->link);
	kfree(entry);
}

static void put_entry(struct my_data *entry)
{
	mutex_lock(&mutex);
	kref_put(&entry->refcount, release_entry);
	mutex_unlock(&mutex);
}

The kref_put() return value is useful if you do not want to hold the
lock during the whole release operation.  Say you didn't want to call
kfree() with the lock held in the example above (since it is kind of
pointless to do so).  You could use kref_put() as follows:

static void release_entry(struct kref *ref)
{
	/* All work is done after the return from kref_put(). */
}

static void put_entry(struct my_data *entry)
{
	mutex_lock(&mutex);
	if (kref_put(&entry->refcount, release_entry)) {
		list_del(&entry->link);
		mutex_unlock(&mutex);
		kfree(entry);
	} else
		mutex_unlock(&mutex);
}

This is really more useful if you have to call other routines as part
of the free operations that could take a long time or might claim the
same lock.  Note that doing everything in the release routine is still
preferred as it is a little neater.


Corey Minyard <minyard@acm.org>

A lot of this was lifted from Greg Kroah-Hartman's 2004 OLS paper and
presentation on krefs, which can be found at:
  http://www.kroah.com/linux/talks/ols_2004_kref_paper/Reprint-Kroah-Hartman-OLS2004.pdf
and:
  http://www.kroah.com/linux/talks/ols_2004_kref_talk/
Commit	Line	Data
5c11c520 CM	1
	2	krefs allow you to add reference counters to your objects. If you
	3	have objects that are used in multiple places and passed around, and
	4	you don't have refcounts, your code is almost certainly broken. If
	5	you want refcounts, krefs are the way to go.
	6
	7	To use a kref, add one to your data structures like:
	8
	9	struct my_data
	10	{
	11	.
	12	.
	13	struct kref refcount;
	14	.
	15	.
	16	};
	17
	18	The kref can occur anywhere within the data structure.
	19
	20	You must initialize the kref after you allocate it. To do this, call
	21	kref_init as so:
	22
	23	struct my_data *data;
	24
	25	data = kmalloc(sizeof(*data), GFP_KERNEL);
	26	if (!data)
	27	return -ENOMEM;
	28	kref_init(&data->refcount);
	29
	30	This sets the refcount in the kref to 1.
	31
	32	Once you have an initialized kref, you must follow the following
	33	rules:
	34
	35	1) If you make a non-temporary copy of a pointer, especially if
	36	it can be passed to another thread of execution, you must
	37	increment the refcount with kref_get() before passing it off:
	38	kref_get(&data->refcount);
	39	If you already have a valid pointer to a kref-ed structure (the
	40	refcount cannot go to zero) you may do this without a lock.
	41
	42	2) When you are done with a pointer, you must call kref_put():
	43	kref_put(&data->refcount, data_release);
	44	If this is the last reference to the pointer, the release
	45	routine will be called. If the code never tries to get
	46	a valid pointer to a kref-ed structure without already
	47	holding a valid pointer, it is safe to do this without
	48	a lock.
	49
	50	3) If the code attempts to gain a reference to a kref-ed structure
	51	without already holding a valid pointer, it must serialize access
	52	where a kref_put() cannot occur during the kref_get(), and the
	53	structure must remain valid during the kref_get().
	54
	55	For example, if you allocate some data and then pass it to another
	56	thread to process:
	57
	58	void data_release(struct kref *ref)
	59	{
	60	struct my_data *data = container_of(ref, struct my_data, refcount);
	61	kfree(data);
	62	}
	63
	64	void more_data_handling(void *cb_data)
65	{
66	struct my_data *data = cb_data;
67	.
68	. do stuff with data here
69	.
b7cc4a87	70	kref_put(&data->refcount, data_release);
5c11c520 CM	71	}
	72
	73	int my_data_handler(void)
	74	{
	75	int rv = 0;
	76	struct my_data *data;
	77	struct task_struct *task;
	78	data = kmalloc(sizeof(*data), GFP_KERNEL);
	79	if (!data)
	80	return -ENOMEM;
	81	kref_init(&data->refcount);
	82
	83	kref_get(&data->refcount);
	84	task = kthread_run(more_data_handling, data, "more_data_handling");
	85	if (task == ERR_PTR(-ENOMEM)) {
	86	rv = -ENOMEM;
5c11c520 CM	87	goto out;
	88	}
	89
	90	.
	91	. do stuff with data here
	92	.
	93	out:
	94	kref_put(&data->refcount, data_release);
	95	return rv;
	96	}
	97
	98	This way, it doesn't matter what order the two threads handle the
	99	data, the kref_put() handles knowing when the data is not referenced
	100	any more and releasing it. The kref_get() does not require a lock,
	101	since we already have a valid pointer that we own a refcount for. The
	102	put needs no lock because nothing tries to get the data without
	103	already holding a pointer.
	104
	105	Note that the "before" in rule 1 is very important. You should never
	106	do something like:
	107
	108	task = kthread_run(more_data_handling, data, "more_data_handling");
	109	if (task == ERR_PTR(-ENOMEM)) {
	110	rv = -ENOMEM;
	111	goto out;
	112	} else
	113	/* BAD BAD BAD - get is after the handoff */
	114	kref_get(&data->refcount);
	115
	116	Don't assume you know what you are doing and use the above construct.
	117	First of all, you may not know what you are doing. Second, you may
	118	know what you are doing (there are some situations where locking is
	119	involved where the above may be legal) but someone else who doesn't
	120	know what they are doing may change the code or copy the code. It's
	121	bad style. Don't do it.
	122
	123	There are some situations where you can optimize the gets and puts.
	124	For instance, if you are done with an object and enqueuing it for
	125	something else or passing it off to something else, there is no reason
	126	to do a get then a put:
	127
	128	/* Silly extra get and put */
	129	kref_get(&obj->ref);
	130	enqueue(obj);
	131	kref_put(&obj->ref, obj_cleanup);
	132
	133	Just do the enqueue. A comment about this is always welcome:
	134
	135	enqueue(obj);
	136	/* We are done with obj, so we pass our refcount off
	137	to the queue. DON'T TOUCH obj AFTER HERE! */
	138
	139	The last rule (rule 3) is the nastiest one to handle. Say, for
	140	instance, you have a list of items that are each kref-ed, and you wish
	141	to get the first one. You can't just pull the first item off the list
	142	and kref_get() it. That violates rule 3 because you are not already
1373bed3 DW	143	holding a valid pointer. You must add a mutex (or some other lock).
1373bed3 DW	144	For instance:
5c11c520	145
1373bed3	146	static DEFINE_MUTEX(mutex);
5c11c520 CM	147	static LIST_HEAD(q);
	148	struct my_data
	149	{
	150	struct kref refcount;
	151	struct list_head link;
	152	};
	153
	154	static struct my_data *get_entry()
	155	{
	156	struct my_data *entry = NULL;
1373bed3	157	mutex_lock(&mutex);
5c11c520 CM	158	if (!list_empty(&q)) {
	159	entry = container_of(q.next, struct my_q_entry, link);
	160	kref_get(&entry->refcount);
	161	}
1373bed3	162	mutex_unlock(&mutex);
5c11c520 CM	163	return entry;
	164	}
	165
	166	static void release_entry(struct kref *ref)
	167	{
	168	struct my_data *entry = container_of(ref, struct my_data, refcount);
	169
	170	list_del(&entry->link);
	171	kfree(entry);
	172	}
	173
	174	static void put_entry(struct my_data *entry)
	175	{
1373bed3	176	mutex_lock(&mutex);
5c11c520	177	kref_put(&entry->refcount, release_entry);
1373bed3	178	mutex_unlock(&mutex);
5c11c520 CM	179	}
	180
	181	The kref_put() return value is useful if you do not want to hold the
	182	lock during the whole release operation. Say you didn't want to call
	183	kfree() with the lock held in the example above (since it is kind of
	184	pointless to do so). You could use kref_put() as follows:
	185
	186	static void release_entry(struct kref *ref)
	187	{
	188	/* All work is done after the return from kref_put(). */
	189	}
	190
	191	static void put_entry(struct my_data *entry)
	192	{
1373bed3	193	mutex_lock(&mutex);
5c11c520 CM	194	if (kref_put(&entry->refcount, release_entry)) {
5c11c520 CM	195	list_del(&entry->link);
1373bed3	196	mutex_unlock(&mutex);
5c11c520 CM	197	kfree(entry);
5c11c520 CM	198	} else
1373bed3	199	mutex_unlock(&mutex);
5c11c520 CM	200	}
	201
	202	This is really more useful if you have to call other routines as part
	203	of the free operations that could take a long time or might claim the
	204	same lock. Note that doing everything in the release routine is still
	205	preferred as it is a little neater.
	206
	207
	208	Corey Minyard <minyard@acm.org>
	209
6f31e422 GKH	210	A lot of this was lifted from Greg Kroah-Hartman's 2004 OLS paper and
	211	presentation on krefs, which can be found at:
	212	http://www.kroah.com/linux/talks/ols_2004_kref_paper/Reprint-Kroah-Hartman-OLS2004.pdf
	213	and:
	214	http://www.kroah.com/linux/talks/ols_2004_kref_talk/
	215