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[wrt350n-kernel.git] / include / xen / interface / io / ring.h
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1 /******************************************************************************
2 * ring.h
4 * Shared producer-consumer ring macros.
6 * Tim Deegan and Andrew Warfield November 2004.
7 */
9 #ifndef __XEN_PUBLIC_IO_RING_H__
10 #define __XEN_PUBLIC_IO_RING_H__
12 typedef unsigned int RING_IDX;
14 /* Round a 32-bit unsigned constant down to the nearest power of two. */
15 #define __RD2(_x) (((_x) & 0x00000002) ? 0x2 : ((_x) & 0x1))
16 #define __RD4(_x) (((_x) & 0x0000000c) ? __RD2((_x)>>2)<<2 : __RD2(_x))
17 #define __RD8(_x) (((_x) & 0x000000f0) ? __RD4((_x)>>4)<<4 : __RD4(_x))
18 #define __RD16(_x) (((_x) & 0x0000ff00) ? __RD8((_x)>>8)<<8 : __RD8(_x))
19 #define __RD32(_x) (((_x) & 0xffff0000) ? __RD16((_x)>>16)<<16 : __RD16(_x))
22 * Calculate size of a shared ring, given the total available space for the
23 * ring and indexes (_sz), and the name tag of the request/response structure.
24 * A ring contains as many entries as will fit, rounded down to the nearest
25 * power of two (so we can mask with (size-1) to loop around).
27 #define __RING_SIZE(_s, _sz) \
28 (__RD32(((_sz) - (long)&(_s)->ring + (long)(_s)) / sizeof((_s)->ring[0])))
31 * Macros to make the correct C datatypes for a new kind of ring.
33 * To make a new ring datatype, you need to have two message structures,
34 * let's say struct request, and struct response already defined.
36 * In a header where you want the ring datatype declared, you then do:
38 * DEFINE_RING_TYPES(mytag, struct request, struct response);
40 * These expand out to give you a set of types, as you can see below.
41 * The most important of these are:
43 * struct mytag_sring - The shared ring.
44 * struct mytag_front_ring - The 'front' half of the ring.
45 * struct mytag_back_ring - The 'back' half of the ring.
47 * To initialize a ring in your code you need to know the location and size
48 * of the shared memory area (PAGE_SIZE, for instance). To initialise
49 * the front half:
51 * struct mytag_front_ring front_ring;
52 * SHARED_RING_INIT((struct mytag_sring *)shared_page);
53 * FRONT_RING_INIT(&front_ring, (struct mytag_sring *)shared_page,
54 * PAGE_SIZE);
56 * Initializing the back follows similarly (note that only the front
57 * initializes the shared ring):
59 * struct mytag_back_ring back_ring;
60 * BACK_RING_INIT(&back_ring, (struct mytag_sring *)shared_page,
61 * PAGE_SIZE);
64 #define DEFINE_RING_TYPES(__name, __req_t, __rsp_t) \
66 /* Shared ring entry */ \
67 union __name##_sring_entry { \
68 __req_t req; \
69 __rsp_t rsp; \
70 }; \
72 /* Shared ring page */ \
73 struct __name##_sring { \
74 RING_IDX req_prod, req_event; \
75 RING_IDX rsp_prod, rsp_event; \
76 uint8_t pad[48]; \
77 union __name##_sring_entry ring[1]; /* variable-length */ \
78 }; \
80 /* "Front" end's private variables */ \
81 struct __name##_front_ring { \
82 RING_IDX req_prod_pvt; \
83 RING_IDX rsp_cons; \
84 unsigned int nr_ents; \
85 struct __name##_sring *sring; \
86 }; \
88 /* "Back" end's private variables */ \
89 struct __name##_back_ring { \
90 RING_IDX rsp_prod_pvt; \
91 RING_IDX req_cons; \
92 unsigned int nr_ents; \
93 struct __name##_sring *sring; \
97 * Macros for manipulating rings.
99 * FRONT_RING_whatever works on the "front end" of a ring: here
100 * requests are pushed on to the ring and responses taken off it.
102 * BACK_RING_whatever works on the "back end" of a ring: here
103 * requests are taken off the ring and responses put on.
105 * N.B. these macros do NO INTERLOCKS OR FLOW CONTROL.
106 * This is OK in 1-for-1 request-response situations where the
107 * requestor (front end) never has more than RING_SIZE()-1
108 * outstanding requests.
111 /* Initialising empty rings */
112 #define SHARED_RING_INIT(_s) do { \
113 (_s)->req_prod = (_s)->rsp_prod = 0; \
114 (_s)->req_event = (_s)->rsp_event = 1; \
115 memset((_s)->pad, 0, sizeof((_s)->pad)); \
116 } while(0)
118 #define FRONT_RING_INIT(_r, _s, __size) do { \
119 (_r)->req_prod_pvt = 0; \
120 (_r)->rsp_cons = 0; \
121 (_r)->nr_ents = __RING_SIZE(_s, __size); \
122 (_r)->sring = (_s); \
123 } while (0)
125 #define BACK_RING_INIT(_r, _s, __size) do { \
126 (_r)->rsp_prod_pvt = 0; \
127 (_r)->req_cons = 0; \
128 (_r)->nr_ents = __RING_SIZE(_s, __size); \
129 (_r)->sring = (_s); \
130 } while (0)
132 /* Initialize to existing shared indexes -- for recovery */
133 #define FRONT_RING_ATTACH(_r, _s, __size) do { \
134 (_r)->sring = (_s); \
135 (_r)->req_prod_pvt = (_s)->req_prod; \
136 (_r)->rsp_cons = (_s)->rsp_prod; \
137 (_r)->nr_ents = __RING_SIZE(_s, __size); \
138 } while (0)
140 #define BACK_RING_ATTACH(_r, _s, __size) do { \
141 (_r)->sring = (_s); \
142 (_r)->rsp_prod_pvt = (_s)->rsp_prod; \
143 (_r)->req_cons = (_s)->req_prod; \
144 (_r)->nr_ents = __RING_SIZE(_s, __size); \
145 } while (0)
147 /* How big is this ring? */
148 #define RING_SIZE(_r) \
149 ((_r)->nr_ents)
151 /* Number of free requests (for use on front side only). */
152 #define RING_FREE_REQUESTS(_r) \
153 (RING_SIZE(_r) - ((_r)->req_prod_pvt - (_r)->rsp_cons))
155 /* Test if there is an empty slot available on the front ring.
156 * (This is only meaningful from the front. )
158 #define RING_FULL(_r) \
159 (RING_FREE_REQUESTS(_r) == 0)
161 /* Test if there are outstanding messages to be processed on a ring. */
162 #define RING_HAS_UNCONSUMED_RESPONSES(_r) \
163 ((_r)->sring->rsp_prod - (_r)->rsp_cons)
165 #define RING_HAS_UNCONSUMED_REQUESTS(_r) \
166 ({ \
167 unsigned int req = (_r)->sring->req_prod - (_r)->req_cons; \
168 unsigned int rsp = RING_SIZE(_r) - \
169 ((_r)->req_cons - (_r)->rsp_prod_pvt); \
170 req < rsp ? req : rsp; \
173 /* Direct access to individual ring elements, by index. */
174 #define RING_GET_REQUEST(_r, _idx) \
175 (&((_r)->sring->ring[((_idx) & (RING_SIZE(_r) - 1))].req))
177 #define RING_GET_RESPONSE(_r, _idx) \
178 (&((_r)->sring->ring[((_idx) & (RING_SIZE(_r) - 1))].rsp))
180 /* Loop termination condition: Would the specified index overflow the ring? */
181 #define RING_REQUEST_CONS_OVERFLOW(_r, _cons) \
182 (((_cons) - (_r)->rsp_prod_pvt) >= RING_SIZE(_r))
184 #define RING_PUSH_REQUESTS(_r) do { \
185 wmb(); /* back sees requests /before/ updated producer index */ \
186 (_r)->sring->req_prod = (_r)->req_prod_pvt; \
187 } while (0)
189 #define RING_PUSH_RESPONSES(_r) do { \
190 wmb(); /* front sees responses /before/ updated producer index */ \
191 (_r)->sring->rsp_prod = (_r)->rsp_prod_pvt; \
192 } while (0)
195 * Notification hold-off (req_event and rsp_event):
197 * When queueing requests or responses on a shared ring, it may not always be
198 * necessary to notify the remote end. For example, if requests are in flight
199 * in a backend, the front may be able to queue further requests without
200 * notifying the back (if the back checks for new requests when it queues
201 * responses).
203 * When enqueuing requests or responses:
205 * Use RING_PUSH_{REQUESTS,RESPONSES}_AND_CHECK_NOTIFY(). The second argument
206 * is a boolean return value. True indicates that the receiver requires an
207 * asynchronous notification.
209 * After dequeuing requests or responses (before sleeping the connection):
211 * Use RING_FINAL_CHECK_FOR_REQUESTS() or RING_FINAL_CHECK_FOR_RESPONSES().
212 * The second argument is a boolean return value. True indicates that there
213 * are pending messages on the ring (i.e., the connection should not be put
214 * to sleep).
216 * These macros will set the req_event/rsp_event field to trigger a
217 * notification on the very next message that is enqueued. If you want to
218 * create batches of work (i.e., only receive a notification after several
219 * messages have been enqueued) then you will need to create a customised
220 * version of the FINAL_CHECK macro in your own code, which sets the event
221 * field appropriately.
224 #define RING_PUSH_REQUESTS_AND_CHECK_NOTIFY(_r, _notify) do { \
225 RING_IDX __old = (_r)->sring->req_prod; \
226 RING_IDX __new = (_r)->req_prod_pvt; \
227 wmb(); /* back sees requests /before/ updated producer index */ \
228 (_r)->sring->req_prod = __new; \
229 mb(); /* back sees new requests /before/ we check req_event */ \
230 (_notify) = ((RING_IDX)(__new - (_r)->sring->req_event) < \
231 (RING_IDX)(__new - __old)); \
232 } while (0)
234 #define RING_PUSH_RESPONSES_AND_CHECK_NOTIFY(_r, _notify) do { \
235 RING_IDX __old = (_r)->sring->rsp_prod; \
236 RING_IDX __new = (_r)->rsp_prod_pvt; \
237 wmb(); /* front sees responses /before/ updated producer index */ \
238 (_r)->sring->rsp_prod = __new; \
239 mb(); /* front sees new responses /before/ we check rsp_event */ \
240 (_notify) = ((RING_IDX)(__new - (_r)->sring->rsp_event) < \
241 (RING_IDX)(__new - __old)); \
242 } while (0)
244 #define RING_FINAL_CHECK_FOR_REQUESTS(_r, _work_to_do) do { \
245 (_work_to_do) = RING_HAS_UNCONSUMED_REQUESTS(_r); \
246 if (_work_to_do) break; \
247 (_r)->sring->req_event = (_r)->req_cons + 1; \
248 mb(); \
249 (_work_to_do) = RING_HAS_UNCONSUMED_REQUESTS(_r); \
250 } while (0)
252 #define RING_FINAL_CHECK_FOR_RESPONSES(_r, _work_to_do) do { \
253 (_work_to_do) = RING_HAS_UNCONSUMED_RESPONSES(_r); \
254 if (_work_to_do) break; \
255 (_r)->sring->rsp_event = (_r)->rsp_cons + 1; \
256 mb(); \
257 (_work_to_do) = RING_HAS_UNCONSUMED_RESPONSES(_r); \
258 } while (0)
260 #endif /* __XEN_PUBLIC_IO_RING_H__ */