[linux-2.6-block.git] / Documentation / padata.txt

=======================================
The padata parallel execution mechanism
=======================================

:Last updated: for 2.6.36

Padata is a mechanism by which the kernel can farm work out to be done in
parallel on multiple CPUs while retaining the ordering of tasks.  It was
developed for use with the IPsec code, which needs to be able to perform
encryption and decryption on large numbers of packets without reordering
those packets.  The crypto developers made a point of writing padata in a
sufficiently general fashion that it could be put to other uses as well.

The first step in using padata is to set up a padata_instance structure for
overall control of how tasks are to be run::

    #include <linux/padata.h>

    struct padata_instance *padata_alloc(const char *name,
					 const struct cpumask *pcpumask,
					 const struct cpumask *cbcpumask);

'name' simply identifies the instance.

The pcpumask describes which processors will be used to execute work
submitted to this instance in parallel. The cbcpumask defines which
processors are allowed to be used as the serialization callback processor.
The workqueue wq is where the work will actually be done; it should be
a multithreaded queue, naturally.

To allocate a padata instance with the cpu_possible_mask for both
cpumasks this helper function can be used::

    struct padata_instance *padata_alloc_possible(struct workqueue_struct *wq);

Note: Padata maintains two kinds of cpumasks internally. The user supplied
cpumasks, submitted by padata_alloc/padata_alloc_possible and the 'usable'
cpumasks. The usable cpumasks are always a subset of active CPUs in the
user supplied cpumasks; these are the cpumasks padata actually uses. So
it is legal to supply a cpumask to padata that contains offline CPUs.
Once an offline CPU in the user supplied cpumask comes online, padata
is going to use it.

There are functions for enabling and disabling the instance::

    int padata_start(struct padata_instance *pinst);
    void padata_stop(struct padata_instance *pinst);

These functions are setting or clearing the "PADATA_INIT" flag;
if that flag is not set, other functions will refuse to work.
padata_start returns zero on success (flag set) or -EINVAL if the
padata cpumask contains no active CPU (flag not set).
padata_stop clears the flag and blocks until the padata instance
is unused.

The list of CPUs to be used can be adjusted with these functions::

    int padata_set_cpumasks(struct padata_instance *pinst,
			    cpumask_var_t pcpumask,
			    cpumask_var_t cbcpumask);
    int padata_set_cpumask(struct padata_instance *pinst, int cpumask_type,
			   cpumask_var_t cpumask);
    int padata_add_cpu(struct padata_instance *pinst, int cpu, int mask);
    int padata_remove_cpu(struct padata_instance *pinst, int cpu, int mask);

Changing the CPU masks are expensive operations, though, so it should not be
done with great frequency.

It's possible to change both cpumasks of a padata instance with
padata_set_cpumasks by specifying the cpumasks for parallel execution (pcpumask)
and for the serial callback function (cbcpumask). padata_set_cpumask is used to
change just one of the cpumasks. Here cpumask_type is one of PADATA_CPU_SERIAL,
PADATA_CPU_PARALLEL and cpumask specifies the new cpumask to use.
To simply add or remove one CPU from a certain cpumask the functions
padata_add_cpu/padata_remove_cpu are used. cpu specifies the CPU to add or
remove and mask is one of PADATA_CPU_SERIAL, PADATA_CPU_PARALLEL.

If a user is interested in padata cpumask changes, he can register to
the padata cpumask change notifier::

    int padata_register_cpumask_notifier(struct padata_instance *pinst,
					 struct notifier_block *nblock);

To unregister from that notifier::

    int padata_unregister_cpumask_notifier(struct padata_instance *pinst,
					   struct notifier_block *nblock);

The padata cpumask change notifier notifies about changes of the usable
cpumasks, i.e. the subset of active CPUs in the user supplied cpumask.

Padata calls the notifier chain with::

    blocking_notifier_call_chain(&pinst->cpumask_change_notifier,
				 notification_mask,
				 &pd_new->cpumask);

Here cpumask_change_notifier is registered notifier, notification_mask
is one of PADATA_CPU_SERIAL, PADATA_CPU_PARALLEL and cpumask is a pointer
to a struct padata_cpumask that contains the new cpumask information.

Actually submitting work to the padata instance requires the creation of a
padata_priv structure::

    struct padata_priv {
        /* Other stuff here... */
	void                    (*parallel)(struct padata_priv *padata);
	void                    (*serial)(struct padata_priv *padata);
    };

This structure will almost certainly be embedded within some larger
structure specific to the work to be done.  Most of its fields are private to
padata, but the structure should be zeroed at initialisation time, and the
parallel() and serial() functions should be provided.  Those functions will
be called in the process of getting the work done as we will see
momentarily.

The submission of work is done with::

    int padata_do_parallel(struct padata_instance *pinst,
		           struct padata_priv *padata, int cb_cpu);

The pinst and padata structures must be set up as described above; cb_cpu
specifies which CPU will be used for the final callback when the work is
done; it must be in the current instance's CPU mask.  The return value from
padata_do_parallel() is zero on success, indicating that the work is in
progress. -EBUSY means that somebody, somewhere else is messing with the
instance's CPU mask, while -EINVAL is a complaint about cb_cpu not being
in that CPU mask or about a not running instance.

Each task submitted to padata_do_parallel() will, in turn, be passed to
exactly one call to the above-mentioned parallel() function, on one CPU, so
true parallelism is achieved by submitting multiple tasks.  parallel() runs with
software interrupts disabled and thus cannot sleep.  The parallel()
function gets the padata_priv structure pointer as its lone parameter;
information about the actual work to be done is probably obtained by using
container_of() to find the enclosing structure.

Note that parallel() has no return value; the padata subsystem assumes that
parallel() will take responsibility for the task from this point.  The work
need not be completed during this call, but, if parallel() leaves work
outstanding, it should be prepared to be called again with a new job before
the previous one completes.  When a task does complete, parallel() (or
whatever function actually finishes the job) should inform padata of the
fact with a call to::

    void padata_do_serial(struct padata_priv *padata);

At some point in the future, padata_do_serial() will trigger a call to the
serial() function in the padata_priv structure.  That call will happen on
the CPU requested in the initial call to padata_do_parallel(); it, too, is
run with local software interrupts disabled.
Note that this call may be deferred for a while since the padata code takes
pains to ensure that tasks are completed in the order in which they were
submitted.

The one remaining function in the padata API should be called to clean up
when a padata instance is no longer needed::

    void padata_free(struct padata_instance *pinst);

This function will busy-wait while any remaining tasks are completed, so it
might be best not to call it while there is work outstanding.
Commit	Line	Data
7576b2b9	1	=======================================
4047f8b1	2	The padata parallel execution mechanism
7576b2b9 MCC	3	=======================================
	4
	5	:Last updated: for 2.6.36
4047f8b1 JC	6
	7	Padata is a mechanism by which the kernel can farm work out to be done in
	8	parallel on multiple CPUs while retaining the ordering of tasks. It was
	9	developed for use with the IPsec code, which needs to be able to perform
	10	encryption and decryption on large numbers of packets without reordering
	11	those packets. The crypto developers made a point of writing padata in a
	12	sufficiently general fashion that it could be put to other uses as well.
	13
	14	The first step in using padata is to set up a padata_instance structure for
7576b2b9	15	overall control of how tasks are to be run::
4047f8b1 JC	16
	17	#include <linux/padata.h>
	18
b128a304	19	struct padata_instance padata_alloc(const char name,
313910d3 SK	20	const struct cpumask *pcpumask,
313910d3 SK	21	const struct cpumask *cbcpumask);
4047f8b1	22
b128a304 DJ	23	'name' simply identifies the instance.
b128a304 DJ	24
313910d3 SK	25	The pcpumask describes which processors will be used to execute work
313910d3 SK	26	submitted to this instance in parallel. The cbcpumask defines which
2b24706a	27	processors are allowed to be used as the serialization callback processor.
313910d3 SK	28	The workqueue wq is where the work will actually be done; it should be
	29	a multithreaded queue, naturally.
	30
	31	To allocate a padata instance with the cpu_possible_mask for both
7576b2b9	32	cpumasks this helper function can be used::
313910d3 SK	33
	34	struct padata_instance padata_alloc_possible(struct workqueue_struct wq);
	35
	36	Note: Padata maintains two kinds of cpumasks internally. The user supplied
	37	cpumasks, submitted by padata_alloc/padata_alloc_possible and the 'usable'
2b24706a RD	38	cpumasks. The usable cpumasks are always a subset of active CPUs in the
	39	user supplied cpumasks; these are the cpumasks padata actually uses. So
	40	it is legal to supply a cpumask to padata that contains offline CPUs.
	41	Once an offline CPU in the user supplied cpumask comes online, padata
313910d3	42	is going to use it.
4047f8b1	43
7576b2b9	44	There are functions for enabling and disabling the instance::
4047f8b1	45
2197f9a1	46	int padata_start(struct padata_instance *pinst);
4047f8b1 JC	47	void padata_stop(struct padata_instance *pinst);
4047f8b1 JC	48
2197f9a1 SK	49	These functions are setting or clearing the "PADATA_INIT" flag;
	50	if that flag is not set, other functions will refuse to work.
	51	padata_start returns zero on success (flag set) or -EINVAL if the
2b24706a	52	padata cpumask contains no active CPU (flag not set).
2197f9a1 SK	53	padata_stop clears the flag and blocks until the padata instance
2197f9a1 SK	54	is unused.
4047f8b1	55
7576b2b9	56	The list of CPUs to be used can be adjusted with these functions::
4047f8b1	57
313910d3 SK	58	int padata_set_cpumasks(struct padata_instance *pinst,
	59	cpumask_var_t pcpumask,
	60	cpumask_var_t cbcpumask);
	61	int padata_set_cpumask(struct padata_instance *pinst, int cpumask_type,
4047f8b1	62	cpumask_var_t cpumask);
313910d3 SK	63	int padata_add_cpu(struct padata_instance *pinst, int cpu, int mask);
	64	int padata_remove_cpu(struct padata_instance *pinst, int cpu, int mask);
	65
	66	Changing the CPU masks are expensive operations, though, so it should not be
	67	done with great frequency.
	68
	69	It's possible to change both cpumasks of a padata instance with
	70	padata_set_cpumasks by specifying the cpumasks for parallel execution (pcpumask)
2b24706a	71	and for the serial callback function (cbcpumask). padata_set_cpumask is used to
313910d3 SK	72	change just one of the cpumasks. Here cpumask_type is one of PADATA_CPU_SERIAL,
313910d3 SK	73	PADATA_CPU_PARALLEL and cpumask specifies the new cpumask to use.
2b24706a RD	74	To simply add or remove one CPU from a certain cpumask the functions
2b24706a RD	75	padata_add_cpu/padata_remove_cpu are used. cpu specifies the CPU to add or
313910d3 SK	76	remove and mask is one of PADATA_CPU_SERIAL, PADATA_CPU_PARALLEL.
	77
	78	If a user is interested in padata cpumask changes, he can register to
7576b2b9	79	the padata cpumask change notifier::
313910d3 SK	80
	81	int padata_register_cpumask_notifier(struct padata_instance *pinst,
	82	struct notifier_block *nblock);
	83
7576b2b9	84	To unregister from that notifier::
313910d3 SK	85
	86	int padata_unregister_cpumask_notifier(struct padata_instance *pinst,
	87	struct notifier_block *nblock);
	88
	89	The padata cpumask change notifier notifies about changes of the usable
2b24706a	90	cpumasks, i.e. the subset of active CPUs in the user supplied cpumask.
313910d3	91
7576b2b9	92	Padata calls the notifier chain with::
313910d3 SK	93
	94	blocking_notifier_call_chain(&pinst->cpumask_change_notifier,
	95	notification_mask,
	96	&pd_new->cpumask);
4047f8b1	97
313910d3 SK	98	Here cpumask_change_notifier is registered notifier, notification_mask
313910d3 SK	99	is one of PADATA_CPU_SERIAL, PADATA_CPU_PARALLEL and cpumask is a pointer
2b24706a	100	to a struct padata_cpumask that contains the new cpumask information.
4047f8b1 JC	101
4047f8b1 JC	102	Actually submitting work to the padata instance requires the creation of a
7576b2b9	103	padata_priv structure::
4047f8b1 JC	104
	105	struct padata_priv {
	106	/* Other stuff here... */
	107	void (parallel)(struct padata_priv padata);
	108	void (serial)(struct padata_priv padata);
	109	};
	110
	111	This structure will almost certainly be embedded within some larger
2b24706a	112	structure specific to the work to be done. Most of its fields are private to
313910d3	113	padata, but the structure should be zeroed at initialisation time, and the
4047f8b1 JC	114	parallel() and serial() functions should be provided. Those functions will
	115	be called in the process of getting the work done as we will see
	116	momentarily.
	117
7576b2b9	118	The submission of work is done with::
4047f8b1 JC	119
	120	int padata_do_parallel(struct padata_instance *pinst,
	121	struct padata_priv *padata, int cb_cpu);
	122
	123	The pinst and padata structures must be set up as described above; cb_cpu
	124	specifies which CPU will be used for the final callback when the work is
	125	done; it must be in the current instance's CPU mask. The return value from
2197f9a1 SK	126	padata_do_parallel() is zero on success, indicating that the work is in
	127	progress. -EBUSY means that somebody, somewhere else is messing with the
	128	instance's CPU mask, while -EINVAL is a complaint about cb_cpu not being
	129	in that CPU mask or about a not running instance.
4047f8b1 JC	130
	131	Each task submitted to padata_do_parallel() will, in turn, be passed to
	132	exactly one call to the above-mentioned parallel() function, on one CPU, so
b128a304	133	true parallelism is achieved by submitting multiple tasks. parallel() runs with
4047f8b1 JC	134	software interrupts disabled and thus cannot sleep. The parallel()
	135	function gets the padata_priv structure pointer as its lone parameter;
	136	information about the actual work to be done is probably obtained by using
	137	container_of() to find the enclosing structure.
	138
	139	Note that parallel() has no return value; the padata subsystem assumes that
	140	parallel() will take responsibility for the task from this point. The work
	141	need not be completed during this call, but, if parallel() leaves work
	142	outstanding, it should be prepared to be called again with a new job before
	143	the previous one completes. When a task does complete, parallel() (or
	144	whatever function actually finishes the job) should inform padata of the
7576b2b9	145	fact with a call to::
4047f8b1 JC	146
	147	void padata_do_serial(struct padata_priv *padata);
	148
	149	At some point in the future, padata_do_serial() will trigger a call to the
	150	serial() function in the padata_priv structure. That call will happen on
	151	the CPU requested in the initial call to padata_do_parallel(); it, too, is
b128a304	152	run with local software interrupts disabled.
4047f8b1 JC	153	Note that this call may be deferred for a while since the padata code takes
	154	pains to ensure that tasks are completed in the order in which they were
	155	submitted.
	156
	157	The one remaining function in the padata API should be called to clean up
7576b2b9	158	when a padata instance is no longer needed::
4047f8b1 JC	159
	160	void padata_free(struct padata_instance *pinst);
	161
	162	This function will busy-wait while any remaining tasks are completed, so it
b128a304	163	might be best not to call it while there is work outstanding.