[GitHub/mt8127/android_kernel_alcatel_ttab.git] / include / linux / iocontext.h

#ifndef IOCONTEXT_H
#define IOCONTEXT_H

#include <linux/radix-tree.h>
#include <linux/rcupdate.h>
#include <linux/workqueue.h>

enum {
	ICQ_IOPRIO_CHANGED,
	ICQ_CGROUP_CHANGED,
};

/*
 * An io_cq (icq) is association between an io_context (ioc) and a
 * request_queue (q).  This is used by elevators which need to track
 * information per ioc - q pair.
 *
 * Elevator can request use of icq by setting elevator_type->icq_size and
 * ->icq_align.  Both size and align must be larger than that of struct
 * io_cq and elevator can use the tail area for private information.  The
 * recommended way to do this is defining a struct which contains io_cq as
 * the first member followed by private members and using its size and
 * align.  For example,
 *
 *	struct snail_io_cq {
 *		struct io_cq	icq;
 *		int		poke_snail;
 *		int		feed_snail;
 *	};
 *
 *	struct elevator_type snail_elv_type {
 *		.ops =		{ ... },
 *		.icq_size =	sizeof(struct snail_io_cq),
 *		.icq_align =	__alignof__(struct snail_io_cq),
 *		...
 *	};
 *
 * If icq_size is set, block core will manage icq's.  All requests will
 * have its ->elv.icq field set before elevator_ops->elevator_set_req_fn()
 * is called and be holding a reference to the associated io_context.
 *
 * Whenever a new icq is created, elevator_ops->elevator_init_icq_fn() is
 * called and, on destruction, ->elevator_exit_icq_fn().  Both functions
 * are called with both the associated io_context and queue locks held.
 *
 * Elevator is allowed to lookup icq using ioc_lookup_icq() while holding
 * queue lock but the returned icq is valid only until the queue lock is
 * released.  Elevators can not and should not try to create or destroy
 * icq's.
 *
 * As icq's are linked from both ioc and q, the locking rules are a bit
 * complex.
 *
 * - ioc lock nests inside q lock.
 *
 * - ioc->icq_list and icq->ioc_node are protected by ioc lock.
 *   q->icq_list and icq->q_node by q lock.
 *
 * - ioc->icq_tree and ioc->icq_hint are protected by ioc lock, while icq
 *   itself is protected by q lock.  However, both the indexes and icq
 *   itself are also RCU managed and lookup can be performed holding only
 *   the q lock.
 *
 * - icq's are not reference counted.  They are destroyed when either the
 *   ioc or q goes away.  Each request with icq set holds an extra
 *   reference to ioc to ensure it stays until the request is completed.
 *
 * - Linking and unlinking icq's are performed while holding both ioc and q
 *   locks.  Due to the lock ordering, q exit is simple but ioc exit
 *   requires reverse-order double lock dance.
 */
struct io_cq {
	struct request_queue	*q;
	struct io_context	*ioc;

	/*
	 * q_node and ioc_node link io_cq through icq_list of q and ioc
	 * respectively.  Both fields are unused once ioc_exit_icq() is
	 * called and shared with __rcu_icq_cache and __rcu_head which are
	 * used for RCU free of io_cq.
	 */
	union {
		struct list_head	q_node;
		struct kmem_cache	*__rcu_icq_cache;
	};
	union {
		struct hlist_node	ioc_node;
		struct rcu_head		__rcu_head;
	};

	unsigned long		changed;
};

/*
 * I/O subsystem state of the associated processes.  It is refcounted
 * and kmalloc'ed. These could be shared between processes.
 */
struct io_context {
	atomic_long_t refcount;
	atomic_t nr_tasks;

	/* all the fields below are protected by this lock */
	spinlock_t lock;

	unsigned short ioprio;

	/*
	 * For request batching
	 */
	int nr_batch_requests;     /* Number of requests left in the batch */
	unsigned long last_waited; /* Time last woken after wait for request */

	struct radix_tree_root	icq_tree;
	struct io_cq __rcu	*icq_hint;
	struct hlist_head	icq_list;

	struct work_struct release_work;
};

static inline struct io_context *ioc_task_link(struct io_context *ioc)
{
	/*
	 * if ref count is zero, don't allow sharing (ioc is going away, it's
	 * a race).
	 */
	if (ioc && atomic_long_inc_not_zero(&ioc->refcount)) {
		atomic_inc(&ioc->nr_tasks);
		return ioc;
	}

	return NULL;
}

struct task_struct;
#ifdef CONFIG_BLOCK
void put_io_context(struct io_context *ioc, struct request_queue *locked_q);
void exit_io_context(struct task_struct *task);
struct io_context *get_task_io_context(struct task_struct *task,
				       gfp_t gfp_flags, int node);
void ioc_ioprio_changed(struct io_context *ioc, int ioprio);
void ioc_cgroup_changed(struct io_context *ioc);
#else
struct io_context;
static inline void put_io_context(struct io_context *ioc,
				  struct request_queue *locked_q) { }
static inline void exit_io_context(struct task_struct *task) { }
#endif

#endif
Commit	Line	Data
fd0928df JA	1	#ifndef IOCONTEXT_H
	2	#define IOCONTEXT_H
	3
4ac845a2	4	#include <linux/radix-tree.h>
34e6bbf2	5	#include <linux/rcupdate.h>
b2efa052	6	#include <linux/workqueue.h>
4ac845a2	7
dc86900e	8	enum {
c5869807 TH	9	ICQ_IOPRIO_CHANGED,
c5869807 TH	10	ICQ_CGROUP_CHANGED,
dc86900e TH	11	};
dc86900e TH	12
f1f8cc94 TH	13	/*
	14	* An io_cq (icq) is association between an io_context (ioc) and a
	15	* request_queue (q). This is used by elevators which need to track
	16	* information per ioc - q pair.
	17	*
	18	* Elevator can request use of icq by setting elevator_type->icq_size and
	19	* ->icq_align. Both size and align must be larger than that of struct
	20	* io_cq and elevator can use the tail area for private information. The
	21	* recommended way to do this is defining a struct which contains io_cq as
	22	* the first member followed by private members and using its size and
	23	* align. For example,
	24	*
	25	* struct snail_io_cq {
	26	* struct io_cq icq;
	27	* int poke_snail;
	28	* int feed_snail;
	29	* };
	30	*
	31	* struct elevator_type snail_elv_type {
	32	* .ops = { ... },
	33	* .icq_size = sizeof(struct snail_io_cq),
	34	* .icq_align = __alignof__(struct snail_io_cq),
	35	* ...
	36	* };
	37	*
	38	* If icq_size is set, block core will manage icq's. All requests will
	39	* have its ->elv.icq field set before elevator_ops->elevator_set_req_fn()
	40	* is called and be holding a reference to the associated io_context.
	41	*
	42	* Whenever a new icq is created, elevator_ops->elevator_init_icq_fn() is
	43	* called and, on destruction, ->elevator_exit_icq_fn(). Both functions
	44	* are called with both the associated io_context and queue locks held.
	45	*
	46	* Elevator is allowed to lookup icq using ioc_lookup_icq() while holding
	47	* queue lock but the returned icq is valid only until the queue lock is
	48	* released. Elevators can not and should not try to create or destroy
	49	* icq's.
	50	*
	51	* As icq's are linked from both ioc and q, the locking rules are a bit
	52	* complex.
	53	*
	54	* - ioc lock nests inside q lock.
	55	*
	56	* - ioc->icq_list and icq->ioc_node are protected by ioc lock.
	57	* q->icq_list and icq->q_node by q lock.
	58	*
	59	* - ioc->icq_tree and ioc->icq_hint are protected by ioc lock, while icq
	60	* itself is protected by q lock. However, both the indexes and icq
	61	* itself are also RCU managed and lookup can be performed holding only
	62	* the q lock.
	63	*
	64	* - icq's are not reference counted. They are destroyed when either the
	65	* ioc or q goes away. Each request with icq set holds an extra
	66	* reference to ioc to ensure it stays until the request is completed.
	67	*
	68	* - Linking and unlinking icq's are performed while holding both ioc and q
	69	* locks. Due to the lock ordering, q exit is simple but ioc exit
	70	* requires reverse-order double lock dance.
	71	*/
c5869807 TH	72	struct io_cq {
	73	struct request_queue *q;
	74	struct io_context *ioc;
fd0928df	75
7e5a8794 TH	76	/*
	77	* q_node and ioc_node link io_cq through icq_list of q and ioc
	78	* respectively. Both fields are unused once ioc_exit_icq() is
	79	* called and shared with __rcu_icq_cache and __rcu_head which are
	80	* used for RCU free of io_cq.
	81	*/
	82	union {
	83	struct list_head q_node;
	84	struct kmem_cache *__rcu_icq_cache;
	85	};
	86	union {
	87	struct hlist_node ioc_node;
	88	struct rcu_head __rcu_head;
	89	};
dc86900e	90
c5869807	91	unsigned long changed;
fd0928df JA	92	};
	93
	94	/*
d38ecf93 JA	95	* I/O subsystem state of the associated processes. It is refcounted
d38ecf93 JA	96	* and kmalloc'ed. These could be shared between processes.
fd0928df JA	97	*/
fd0928df JA	98	struct io_context {
d9c7d394	99	atomic_long_t refcount;
d38ecf93 JA	100	atomic_t nr_tasks;
	101
	102	/* all the fields below are protected by this lock */
	103	spinlock_t lock;
fd0928df JA	104
fd0928df JA	105	unsigned short ioprio;
31e4c28d	106
fd0928df JA	107	/*
	108	* For request batching
	109	*/
fd0928df	110	int nr_batch_requests; /* Number of requests left in the batch */
58c24a61	111	unsigned long last_waited; /* Time last woken after wait for request */
fd0928df	112
c5869807 TH	113	struct radix_tree_root icq_tree;
	114	struct io_cq __rcu *icq_hint;
	115	struct hlist_head icq_list;
b2efa052 TH	116
b2efa052 TH	117	struct work_struct release_work;
fd0928df JA	118	};
fd0928df JA	119
d38ecf93 JA	120	static inline struct io_context ioc_task_link(struct io_context ioc)
	121	{
	122	/*
	123	* if ref count is zero, don't allow sharing (ioc is going away, it's
	124	* a race).
	125	*/
d9c7d394	126	if (ioc && atomic_long_inc_not_zero(&ioc->refcount)) {
cbb4f264	127	atomic_inc(&ioc->nr_tasks);
d38ecf93	128	return ioc;
d237e5c7	129	}
d38ecf93 JA	130
	131	return NULL;
	132	}
	133
b69f2292	134	struct task_struct;
da9cbc87	135	#ifdef CONFIG_BLOCK
b2efa052	136	void put_io_context(struct io_context ioc, struct request_queue locked_q);
b69f2292	137	void exit_io_context(struct task_struct *task);
6e736be7 TH	138	struct io_context get_task_io_context(struct task_struct task,
6e736be7 TH	139	gfp_t gfp_flags, int node);
dc86900e TH	140	void ioc_ioprio_changed(struct io_context *ioc, int ioprio);
dc86900e TH	141	void ioc_cgroup_changed(struct io_context *ioc);
da9cbc87	142	#else
da9cbc87	143	struct io_context;
b2efa052 TH	144	static inline void put_io_context(struct io_context *ioc,
b2efa052 TH	145	struct request_queue *locked_q) { }
42ec57a8	146	static inline void exit_io_context(struct task_struct *task) { }
da9cbc87 JA	147	#endif
da9cbc87 JA	148
fd0928df	149	#endif