[linux.git] / drivers / md / dm-service-time.c

/*
 * Copyright (C) 2007-2009 NEC Corporation.  All Rights Reserved.
 *
 * Module Author: Kiyoshi Ueda
 *
 * This file is released under the GPL.
 *
 * Throughput oriented path selector.
 */

#include "dm.h"
#include "dm-path-selector.h"

#include <linux/slab.h>

#define DM_MSG_PREFIX	"multipath service-time"
#define ST_MIN_IO	1
#define ST_MAX_RELATIVE_THROUGHPUT	100
#define ST_MAX_RELATIVE_THROUGHPUT_SHIFT	7
#define ST_MAX_INFLIGHT_SIZE	((size_t)-1 >> ST_MAX_RELATIVE_THROUGHPUT_SHIFT)
#define ST_VERSION	"0.2.0"

struct selector {
	struct list_head valid_paths;
	struct list_head failed_paths;
};

struct path_info {
	struct list_head list;
	struct dm_path *path;
	unsigned repeat_count;
	unsigned relative_throughput;
	atomic_t in_flight_size;	/* Total size of in-flight I/Os */
};

static struct selector *alloc_selector(void)
{
	struct selector *s = kmalloc(sizeof(*s), GFP_KERNEL);

	if (s) {
		INIT_LIST_HEAD(&s->valid_paths);
		INIT_LIST_HEAD(&s->failed_paths);
	}

	return s;
}

static int st_create(struct path_selector *ps, unsigned argc, char **argv)
{
	struct selector *s = alloc_selector();

	if (!s)
		return -ENOMEM;

	ps->context = s;
	return 0;
}

static void free_paths(struct list_head *paths)
{
	struct path_info *pi, *next;

	list_for_each_entry_safe(pi, next, paths, list) {
		list_del(&pi->list);
		kfree(pi);
	}
}

static void st_destroy(struct path_selector *ps)
{
	struct selector *s = ps->context;

	free_paths(&s->valid_paths);
	free_paths(&s->failed_paths);
	kfree(s);
	ps->context = NULL;
}

static int st_status(struct path_selector *ps, struct dm_path *path,
		     status_type_t type, char *result, unsigned maxlen)
{
	unsigned sz = 0;
	struct path_info *pi;

	if (!path)
		DMEMIT("0 ");
	else {
		pi = path->pscontext;

		switch (type) {
		case STATUSTYPE_INFO:
			DMEMIT("%d %u ", atomic_read(&pi->in_flight_size),
			       pi->relative_throughput);
			break;
		case STATUSTYPE_TABLE:
			DMEMIT("%u %u ", pi->repeat_count,
			       pi->relative_throughput);
			break;
		}
	}

	return sz;
}

static int st_add_path(struct path_selector *ps, struct dm_path *path,
		       int argc, char **argv, char **error)
{
	struct selector *s = ps->context;
	struct path_info *pi;
	unsigned repeat_count = ST_MIN_IO;
	unsigned relative_throughput = 1;

	/*
	 * Arguments: [<repeat_count> [<relative_throughput>]]
	 * 	<repeat_count>: The number of I/Os before switching path.
	 * 			If not given, default (ST_MIN_IO) is used.
	 * 	<relative_throughput>: The relative throughput value of
	 *			the path among all paths in the path-group.
	 * 			The valid range: 0-<ST_MAX_RELATIVE_THROUGHPUT>
	 *			If not given, minimum value '1' is used.
	 *			If '0' is given, the path isn't selected while
	 * 			other paths having a positive value are
	 * 			available.
	 */
	if (argc > 2) {
		*error = "service-time ps: incorrect number of arguments";
		return -EINVAL;
	}

	if (argc && (sscanf(argv[0], "%u", &repeat_count) != 1)) {
		*error = "service-time ps: invalid repeat count";
		return -EINVAL;
	}

	if ((argc == 2) &&
	    (sscanf(argv[1], "%u", &relative_throughput) != 1 ||
	     relative_throughput > ST_MAX_RELATIVE_THROUGHPUT)) {
		*error = "service-time ps: invalid relative_throughput value";
		return -EINVAL;
	}

	/* allocate the path */
	pi = kmalloc(sizeof(*pi), GFP_KERNEL);
	if (!pi) {
		*error = "service-time ps: Error allocating path context";
		return -ENOMEM;
	}

	pi->path = path;
	pi->repeat_count = repeat_count;
	pi->relative_throughput = relative_throughput;
	atomic_set(&pi->in_flight_size, 0);

	path->pscontext = pi;

	list_add_tail(&pi->list, &s->valid_paths);

	return 0;
}

static void st_fail_path(struct path_selector *ps, struct dm_path *path)
{
	struct selector *s = ps->context;
	struct path_info *pi = path->pscontext;

	list_move(&pi->list, &s->failed_paths);
}

static int st_reinstate_path(struct path_selector *ps, struct dm_path *path)
{
	struct selector *s = ps->context;
	struct path_info *pi = path->pscontext;

	list_move_tail(&pi->list, &s->valid_paths);

	return 0;
}

/*
 * Compare the estimated service time of 2 paths, pi1 and pi2,
 * for the incoming I/O.
 *
 * Returns:
 * < 0 : pi1 is better
 * 0   : no difference between pi1 and pi2
 * > 0 : pi2 is better
 *
 * Description:
 * Basically, the service time is estimated by:
 *     ('pi->in-flight-size' + 'incoming') / 'pi->relative_throughput'
 * To reduce the calculation, some optimizations are made.
 * (See comments inline)
 */
static int st_compare_load(struct path_info *pi1, struct path_info *pi2,
			   size_t incoming)
{
	size_t sz1, sz2, st1, st2;

	sz1 = atomic_read(&pi1->in_flight_size);
	sz2 = atomic_read(&pi2->in_flight_size);

	/*
	 * Case 1: Both have same throughput value. Choose less loaded path.
	 */
	if (pi1->relative_throughput == pi2->relative_throughput)
		return sz1 - sz2;

	/*
	 * Case 2a: Both have same load. Choose higher throughput path.
	 * Case 2b: One path has no throughput value. Choose the other one.
	 */
	if (sz1 == sz2 ||
	    !pi1->relative_throughput || !pi2->relative_throughput)
		return pi2->relative_throughput - pi1->relative_throughput;

	/*
	 * Case 3: Calculate service time. Choose faster path.
	 *         Service time using pi1:
	 *             st1 = (sz1 + incoming) / pi1->relative_throughput
	 *         Service time using pi2:
	 *             st2 = (sz2 + incoming) / pi2->relative_throughput
	 *
	 *         To avoid the division, transform the expression to use
	 *         multiplication.
	 *         Because ->relative_throughput > 0 here, if st1 < st2,
	 *         the expressions below are the same meaning:
	 *             (sz1 + incoming) / pi1->relative_throughput <
	 *                 (sz2 + incoming) / pi2->relative_throughput
	 *             (sz1 + incoming) * pi2->relative_throughput <
	 *                 (sz2 + incoming) * pi1->relative_throughput
	 *         So use the later one.
	 */
	sz1 += incoming;
	sz2 += incoming;
	if (unlikely(sz1 >= ST_MAX_INFLIGHT_SIZE ||
		     sz2 >= ST_MAX_INFLIGHT_SIZE)) {
		/*
		 * Size may be too big for multiplying pi->relative_throughput
		 * and overflow.
		 * To avoid the overflow and mis-selection, shift down both.
		 */
		sz1 >>= ST_MAX_RELATIVE_THROUGHPUT_SHIFT;
		sz2 >>= ST_MAX_RELATIVE_THROUGHPUT_SHIFT;
	}
	st1 = sz1 * pi2->relative_throughput;
	st2 = sz2 * pi1->relative_throughput;
	if (st1 != st2)
		return st1 - st2;

	/*
	 * Case 4: Service time is equal. Choose higher throughput path.
	 */
	return pi2->relative_throughput - pi1->relative_throughput;
}

static struct dm_path *st_select_path(struct path_selector *ps,
				      unsigned *repeat_count, size_t nr_bytes)
{
	struct selector *s = ps->context;
	struct path_info *pi = NULL, *best = NULL;

	if (list_empty(&s->valid_paths))
		return NULL;

	/* Change preferred (first in list) path to evenly balance. */
	list_move_tail(s->valid_paths.next, &s->valid_paths);

	list_for_each_entry(pi, &s->valid_paths, list)
		if (!best || (st_compare_load(pi, best, nr_bytes) < 0))
			best = pi;

	if (!best)
		return NULL;

	*repeat_count = best->repeat_count;

	return best->path;
}

static int st_start_io(struct path_selector *ps, struct dm_path *path,
		       size_t nr_bytes)
{
	struct path_info *pi = path->pscontext;

	atomic_add(nr_bytes, &pi->in_flight_size);

	return 0;
}

static int st_end_io(struct path_selector *ps, struct dm_path *path,
		     size_t nr_bytes)
{
	struct path_info *pi = path->pscontext;

	atomic_sub(nr_bytes, &pi->in_flight_size);

	return 0;
}

static struct path_selector_type st_ps = {
	.name		= "service-time",
	.module		= THIS_MODULE,
	.table_args	= 2,
	.info_args	= 2,
	.create		= st_create,
	.destroy	= st_destroy,
	.status		= st_status,
	.add_path	= st_add_path,
	.fail_path	= st_fail_path,
	.reinstate_path	= st_reinstate_path,
	.select_path	= st_select_path,
	.start_io	= st_start_io,
	.end_io		= st_end_io,
};

static int __init dm_st_init(void)
{
	int r = dm_register_path_selector(&st_ps);

	if (r < 0)
		DMERR("register failed %d", r);

	DMINFO("version " ST_VERSION " loaded");

	return r;
}

static void __exit dm_st_exit(void)
{
	int r = dm_unregister_path_selector(&st_ps);

	if (r < 0)
		DMERR("unregister failed %d", r);
}

module_init(dm_st_init);
module_exit(dm_st_exit);

MODULE_DESCRIPTION(DM_NAME " throughput oriented path selector");
MODULE_AUTHOR("Kiyoshi Ueda <[email protected]>");
MODULE_LICENSE("GPL");
Commit	Line	Data
f392ba88 KU	1	/*
	2	* Copyright (C) 2007-2009 NEC Corporation. All Rights Reserved.
	3	*
	4	* Module Author: Kiyoshi Ueda
	5	*
	6	* This file is released under the GPL.
	7	*
	8	* Throughput oriented path selector.
	9	*/
	10
	11	#include "dm.h"
	12	#include "dm-path-selector.h"
	13
5a0e3ad6 TH	14	#include <linux/slab.h>
5a0e3ad6 TH	15
f392ba88 KU	16	#define DM_MSG_PREFIX "multipath service-time"
	17	#define ST_MIN_IO 1
	18	#define ST_MAX_RELATIVE_THROUGHPUT 100
	19	#define ST_MAX_RELATIVE_THROUGHPUT_SHIFT 7
	20	#define ST_MAX_INFLIGHT_SIZE ((size_t)-1 >> ST_MAX_RELATIVE_THROUGHPUT_SHIFT)
	21	#define ST_VERSION "0.2.0"
	22
	23	struct selector {
	24	struct list_head valid_paths;
	25	struct list_head failed_paths;
	26	};
	27
	28	struct path_info {
	29	struct list_head list;
	30	struct dm_path *path;
	31	unsigned repeat_count;
	32	unsigned relative_throughput;
	33	atomic_t in_flight_size; /* Total size of in-flight I/Os */
	34	};
	35
	36	static struct selector *alloc_selector(void)
	37	{
	38	struct selector s = kmalloc(sizeof(s), GFP_KERNEL);
	39
	40	if (s) {
	41	INIT_LIST_HEAD(&s->valid_paths);
	42	INIT_LIST_HEAD(&s->failed_paths);
	43	}
	44
	45	return s;
	46	}
	47
	48	static int st_create(struct path_selector ps, unsigned argc, char *argv)
	49	{
	50	struct selector *s = alloc_selector();
	51
	52	if (!s)
	53	return -ENOMEM;
	54
	55	ps->context = s;
	56	return 0;
	57	}
	58
	59	static void free_paths(struct list_head *paths)
	60	{
	61	struct path_info pi, next;
	62
	63	list_for_each_entry_safe(pi, next, paths, list) {
	64	list_del(&pi->list);
	65	kfree(pi);
	66	}
	67	}
	68
	69	static void st_destroy(struct path_selector *ps)
	70	{
	71	struct selector *s = ps->context;
	72
	73	free_paths(&s->valid_paths);
	74	free_paths(&s->failed_paths);
	75	kfree(s);
	76	ps->context = NULL;
	77	}
	78
	79	static int st_status(struct path_selector ps, struct dm_path path,
80	status_type_t type, char *result, unsigned maxlen)
81	{
82	unsigned sz = 0;
83	struct path_info *pi;
84
85	if (!path)
86	DMEMIT("0 ");
87	else {
88	pi = path->pscontext;
89
90	switch (type) {
91	case STATUSTYPE_INFO:
92	DMEMIT("%d %u ", atomic_read(&pi->in_flight_size),
93	pi->relative_throughput);
94	break;
95	case STATUSTYPE_TABLE:
96	DMEMIT("%u %u ", pi->repeat_count,
97	pi->relative_throughput);
98	break;
99	}
100	}
101
102	return sz;
103	}
104
105	static int st_add_path(struct path_selector ps, struct dm_path path,
106	int argc, char argv, char error)
107	{
108	struct selector *s = ps->context;
109	struct path_info *pi;
110	unsigned repeat_count = ST_MIN_IO;
111	unsigned relative_throughput = 1;
112
113	/*
114	* Arguments: [<repeat_count> [<relative_throughput>]]
115	* <repeat_count>: The number of I/Os before switching path.
116	* If not given, default (ST_MIN_IO) is used.
117	* <relative_throughput>: The relative throughput value of
118	* the path among all paths in the path-group.
119	* The valid range: 0-<ST_MAX_RELATIVE_THROUGHPUT>
120	* If not given, minimum value '1' is used.
121	* If '0' is given, the path isn't selected while
122	* other paths having a positive value are
123	* available.
124	*/
125	if (argc > 2) {
126	*error = "service-time ps: incorrect number of arguments";
127	return -EINVAL;
128	}
129
130	if (argc && (sscanf(argv[0], "%u", &repeat_count) != 1)) {
131	*error = "service-time ps: invalid repeat count";
132	return -EINVAL;
133	}
134
135	if ((argc == 2) &&
136	(sscanf(argv[1], "%u", &relative_throughput) != 1 \|\|
137	relative_throughput > ST_MAX_RELATIVE_THROUGHPUT)) {
138	*error = "service-time ps: invalid relative_throughput value";
139	return -EINVAL;
140	}
141
142	/* allocate the path */
143	pi = kmalloc(sizeof(*pi), GFP_KERNEL);
144	if (!pi) {
145	*error = "service-time ps: Error allocating path context";
146	return -ENOMEM;
147	}
148
149	pi->path = path;
150	pi->repeat_count = repeat_count;
151	pi->relative_throughput = relative_throughput;
152	atomic_set(&pi->in_flight_size, 0);
153
154	path->pscontext = pi;
155
156	list_add_tail(&pi->list, &s->valid_paths);
157
158	return 0;
159	}
160
161	static void st_fail_path(struct path_selector ps, struct dm_path path)
162	{
163	struct selector *s = ps->context;
164	struct path_info *pi = path->pscontext;
165
166	list_move(&pi->list, &s->failed_paths);
167	}
168
169	static int st_reinstate_path(struct path_selector ps, struct dm_path path)
170	{
171	struct selector *s = ps->context;
172	struct path_info *pi = path->pscontext;
173
174	list_move_tail(&pi->list, &s->valid_paths);
175
176	return 0;
177	}
178
179	/*
180	* Compare the estimated service time of 2 paths, pi1 and pi2,
181	* for the incoming I/O.
182	*
183	* Returns:
184	* < 0 : pi1 is better
185	* 0 : no difference between pi1 and pi2
186	* > 0 : pi2 is better
187	*
188	* Description:
189	* Basically, the service time is estimated by:
190	* ('pi->in-flight-size' + 'incoming') / 'pi->relative_throughput'
191	* To reduce the calculation, some optimizations are made.
192	* (See comments inline)
193	*/
194	static int st_compare_load(struct path_info pi1, struct path_info pi2,
195	size_t incoming)
196	{
197	size_t sz1, sz2, st1, st2;
198
199	sz1 = atomic_read(&pi1->in_flight_size);
200	sz2 = atomic_read(&pi2->in_flight_size);
201
202	/*
203	* Case 1: Both have same throughput value. Choose less loaded path.
204	*/
205	if (pi1->relative_throughput == pi2->relative_throughput)
206	return sz1 - sz2;
207
208	/*
209	* Case 2a: Both have same load. Choose higher throughput path.
210	* Case 2b: One path has no throughput value. Choose the other one.
211	*/
212	if (sz1 == sz2 \|\|
213	!pi1->relative_throughput \|\| !pi2->relative_throughput)
214	return pi2->relative_throughput - pi1->relative_throughput;
215
216	/*
217	* Case 3: Calculate service time. Choose faster path.
218	* Service time using pi1:
219	* st1 = (sz1 + incoming) / pi1->relative_throughput
220	* Service time using pi2:
221	* st2 = (sz2 + incoming) / pi2->relative_throughput
222	*
223	* To avoid the division, transform the expression to use
224	* multiplication.
225	* Because ->relative_throughput > 0 here, if st1 < st2,
226	* the expressions below are the same meaning:
227	* (sz1 + incoming) / pi1->relative_throughput <
228	* (sz2 + incoming) / pi2->relative_throughput
229	* (sz1 + incoming) * pi2->relative_throughput <
230	* (sz2 + incoming) * pi1->relative_throughput
231	* So use the later one.
232	*/
233	sz1 += incoming;
234	sz2 += incoming;
235	if (unlikely(sz1 >= ST_MAX_INFLIGHT_SIZE \|\|
236	sz2 >= ST_MAX_INFLIGHT_SIZE)) {
237	/*
238	* Size may be too big for multiplying pi->relative_throughput
239	* and overflow.
240	* To avoid the overflow and mis-selection, shift down both.
241	*/
242	sz1 >>= ST_MAX_RELATIVE_THROUGHPUT_SHIFT;
243	sz2 >>= ST_MAX_RELATIVE_THROUGHPUT_SHIFT;
244	}
245	st1 = sz1 * pi2->relative_throughput;
246	st2 = sz2 * pi1->relative_throughput;
247	if (st1 != st2)
248	return st1 - st2;
249
250	/*
251	* Case 4: Service time is equal. Choose higher throughput path.
252	*/
253	return pi2->relative_throughput - pi1->relative_throughput;
254	}
255
256	static struct dm_path st_select_path(struct path_selector ps,
257	unsigned *repeat_count, size_t nr_bytes)
258	{
259	struct selector *s = ps->context;
260	struct path_info pi = NULL, best = NULL;
261
262	if (list_empty(&s->valid_paths))
263	return NULL;
264
265	/* Change preferred (first in list) path to evenly balance. */
266	list_move_tail(s->valid_paths.next, &s->valid_paths);
267
268	list_for_each_entry(pi, &s->valid_paths, list)
269	if (!best \|\| (st_compare_load(pi, best, nr_bytes) < 0))
270	best = pi;
271
272	if (!best)
273	return NULL;
274
275	*repeat_count = best->repeat_count;
276
277	return best->path;
278	}
279
280	static int st_start_io(struct path_selector ps, struct dm_path path,
281	size_t nr_bytes)
282	{
283	struct path_info *pi = path->pscontext;
284
285	atomic_add(nr_bytes, &pi->in_flight_size);
286
287	return 0;
288	}
289
290	static int st_end_io(struct path_selector ps, struct dm_path path,
291	size_t nr_bytes)
292	{
293	struct path_info *pi = path->pscontext;
294
295	atomic_sub(nr_bytes, &pi->in_flight_size);
296
297	return 0;
298	}
299
300	static struct path_selector_type st_ps = {
301	.name = "service-time",
302	.module = THIS_MODULE,
303	.table_args = 2,
304	.info_args = 2,
305	.create = st_create,
306	.destroy = st_destroy,
307	.status = st_status,
308	.add_path = st_add_path,
309	.fail_path = st_fail_path,
310	.reinstate_path = st_reinstate_path,
311	.select_path = st_select_path,
312	.start_io = st_start_io,
313	.end_io = st_end_io,
314	};
315
316	static int __init dm_st_init(void)
317	{
318	int r = dm_register_path_selector(&st_ps);
319
320	if (r < 0)
321	DMERR("register failed %d", r);
322
323	DMINFO("version " ST_VERSION " loaded");
324
325	return r;
326	}
327
328	static void __exit dm_st_exit(void)
329	{
330	int r = dm_unregister_path_selector(&st_ps);
331
332	if (r < 0)
333	DMERR("unregister failed %d", r);
334	}
335
336	module_init(dm_st_init);
337	module_exit(dm_st_exit);
338
339	MODULE_DESCRIPTION(DM_NAME " throughput oriented path selector");
340	MODULE_AUTHOR("Kiyoshi Ueda <[email protected]>");
341	MODULE_LICENSE("GPL");