diff options
author | Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com> | 2008-09-17 11:34:05 -0400 |
---|---|---|
committer | David Vrabel <dv02@dv02pc01.europe.root.pri> | 2008-09-17 11:54:23 -0400 |
commit | 34e95e41f1fd751e33a7eb3fa66594903b81f13d (patch) | |
tree | cd3ef1b848a1aab54426dfdcaf8adb37a20ecc9f /include/linux/uwb.h | |
parent | 99d368bc9e279a2a5e56f3afe32166260e90caa7 (diff) |
uwb: add the uwb include files
Signed-off-by: David Vrabel <david.vrabel@csr.com>
Diffstat (limited to 'include/linux/uwb.h')
-rw-r--r-- | include/linux/uwb.h | 761 |
1 files changed, 761 insertions, 0 deletions
diff --git a/include/linux/uwb.h b/include/linux/uwb.h new file mode 100644 index 000000000000..0cd35937e120 --- /dev/null +++ b/include/linux/uwb.h | |||
@@ -0,0 +1,761 @@ | |||
1 | /* | ||
2 | * Ultra Wide Band | ||
3 | * UWB API | ||
4 | * | ||
5 | * Copyright (C) 2005-2006 Intel Corporation | ||
6 | * Inaky Perez-Gonzalez <inaky.perez-gonzalez@intel.com> | ||
7 | * | ||
8 | * This program is free software; you can redistribute it and/or | ||
9 | * modify it under the terms of the GNU General Public License version | ||
10 | * 2 as published by the Free Software Foundation. | ||
11 | * | ||
12 | * This program is distributed in the hope that it will be useful, | ||
13 | * but WITHOUT ANY WARRANTY; without even the implied warranty of | ||
14 | * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the | ||
15 | * GNU General Public License for more details. | ||
16 | * | ||
17 | * You should have received a copy of the GNU General Public License | ||
18 | * along with this program; if not, write to the Free Software | ||
19 | * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA | ||
20 | * 02110-1301, USA. | ||
21 | * | ||
22 | * | ||
23 | * FIXME: doc: overview of the API, different parts and pointers | ||
24 | */ | ||
25 | |||
26 | #ifndef __LINUX__UWB_H__ | ||
27 | #define __LINUX__UWB_H__ | ||
28 | |||
29 | #include <linux/limits.h> | ||
30 | #include <linux/device.h> | ||
31 | #include <linux/mutex.h> | ||
32 | #include <linux/timer.h> | ||
33 | #include <linux/workqueue.h> | ||
34 | #include <linux/uwb/spec.h> | ||
35 | |||
36 | struct uwb_dev; | ||
37 | struct uwb_beca_e; | ||
38 | struct uwb_rc; | ||
39 | struct uwb_rsv; | ||
40 | struct uwb_dbg; | ||
41 | |||
42 | /** | ||
43 | * struct uwb_dev - a UWB Device | ||
44 | * @rc: UWB Radio Controller that discovered the device (kind of its | ||
45 | * parent). | ||
46 | * @bce: a beacon cache entry for this device; or NULL if the device | ||
47 | * is a local radio controller. | ||
48 | * @mac_addr: the EUI-48 address of this device. | ||
49 | * @dev_addr: the current DevAddr used by this device. | ||
50 | * @beacon_slot: the slot number the beacon is using. | ||
51 | * @streams: bitmap of streams allocated to reservations targeted at | ||
52 | * this device. For an RC, this is the streams allocated for | ||
53 | * reservations targeted at DevAddrs. | ||
54 | * | ||
55 | * A UWB device may either by a neighbor or part of a local radio | ||
56 | * controller. | ||
57 | */ | ||
58 | struct uwb_dev { | ||
59 | struct mutex mutex; | ||
60 | struct list_head list_node; | ||
61 | struct device dev; | ||
62 | struct uwb_rc *rc; /* radio controller */ | ||
63 | struct uwb_beca_e *bce; /* Beacon Cache Entry */ | ||
64 | |||
65 | struct uwb_mac_addr mac_addr; | ||
66 | struct uwb_dev_addr dev_addr; | ||
67 | int beacon_slot; | ||
68 | DECLARE_BITMAP(streams, UWB_NUM_STREAMS); | ||
69 | }; | ||
70 | #define to_uwb_dev(d) container_of(d, struct uwb_dev, dev) | ||
71 | |||
72 | /** | ||
73 | * UWB HWA/WHCI Radio Control {Command|Event} Block context IDs | ||
74 | * | ||
75 | * RC[CE]Bs have a 'context ID' field that matches the command with | ||
76 | * the event received to confirm it. | ||
77 | * | ||
78 | * Maximum number of context IDs | ||
79 | */ | ||
80 | enum { UWB_RC_CTX_MAX = 256 }; | ||
81 | |||
82 | |||
83 | /** Notification chain head for UWB generated events to listeners */ | ||
84 | struct uwb_notifs_chain { | ||
85 | struct list_head list; | ||
86 | struct mutex mutex; | ||
87 | }; | ||
88 | |||
89 | /** | ||
90 | * struct uwb_mas_bm - a bitmap of all MAS in a superframe | ||
91 | * @bm: a bitmap of length #UWB_NUM_MAS | ||
92 | */ | ||
93 | struct uwb_mas_bm { | ||
94 | DECLARE_BITMAP(bm, UWB_NUM_MAS); | ||
95 | }; | ||
96 | |||
97 | /** | ||
98 | * uwb_rsv_state - UWB Reservation state. | ||
99 | * | ||
100 | * NONE - reservation is not active (no DRP IE being transmitted). | ||
101 | * | ||
102 | * Owner reservation states: | ||
103 | * | ||
104 | * INITIATED - owner has sent an initial DRP request. | ||
105 | * PENDING - target responded with pending Reason Code. | ||
106 | * MODIFIED - reservation manager is modifying an established | ||
107 | * reservation with a different MAS allocation. | ||
108 | * ESTABLISHED - the reservation has been successfully negotiated. | ||
109 | * | ||
110 | * Target reservation states: | ||
111 | * | ||
112 | * DENIED - request is denied. | ||
113 | * ACCEPTED - request is accepted. | ||
114 | * PENDING - PAL has yet to make a decision to whether to accept or | ||
115 | * deny. | ||
116 | * | ||
117 | * FIXME: further target states TBD. | ||
118 | */ | ||
119 | enum uwb_rsv_state { | ||
120 | UWB_RSV_STATE_NONE, | ||
121 | UWB_RSV_STATE_O_INITIATED, | ||
122 | UWB_RSV_STATE_O_PENDING, | ||
123 | UWB_RSV_STATE_O_MODIFIED, | ||
124 | UWB_RSV_STATE_O_ESTABLISHED, | ||
125 | UWB_RSV_STATE_T_ACCEPTED, | ||
126 | UWB_RSV_STATE_T_DENIED, | ||
127 | UWB_RSV_STATE_T_PENDING, | ||
128 | |||
129 | UWB_RSV_STATE_LAST, | ||
130 | }; | ||
131 | |||
132 | enum uwb_rsv_target_type { | ||
133 | UWB_RSV_TARGET_DEV, | ||
134 | UWB_RSV_TARGET_DEVADDR, | ||
135 | }; | ||
136 | |||
137 | /** | ||
138 | * struct uwb_rsv_target - the target of a reservation. | ||
139 | * | ||
140 | * Reservations unicast and targeted at a single device | ||
141 | * (UWB_RSV_TARGET_DEV); or (e.g., in the case of WUSB) targeted at a | ||
142 | * specific (private) DevAddr (UWB_RSV_TARGET_DEVADDR). | ||
143 | */ | ||
144 | struct uwb_rsv_target { | ||
145 | enum uwb_rsv_target_type type; | ||
146 | union { | ||
147 | struct uwb_dev *dev; | ||
148 | struct uwb_dev_addr devaddr; | ||
149 | }; | ||
150 | }; | ||
151 | |||
152 | /* | ||
153 | * Number of streams reserved for reservations targeted at DevAddrs. | ||
154 | */ | ||
155 | #define UWB_NUM_GLOBAL_STREAMS 1 | ||
156 | |||
157 | typedef void (*uwb_rsv_cb_f)(struct uwb_rsv *rsv); | ||
158 | |||
159 | /** | ||
160 | * struct uwb_rsv - a DRP reservation | ||
161 | * | ||
162 | * Data structure management: | ||
163 | * | ||
164 | * @rc: the radio controller this reservation is for | ||
165 | * (as target or owner) | ||
166 | * @rc_node: a list node for the RC | ||
167 | * @pal_node: a list node for the PAL | ||
168 | * | ||
169 | * Owner and target parameters: | ||
170 | * | ||
171 | * @owner: the UWB device owning this reservation | ||
172 | * @target: the target UWB device | ||
173 | * @type: reservation type | ||
174 | * | ||
175 | * Owner parameters: | ||
176 | * | ||
177 | * @max_mas: maxiumum number of MAS | ||
178 | * @min_mas: minimum number of MAS | ||
179 | * @sparsity: owner selected sparsity | ||
180 | * @is_multicast: true iff multicast | ||
181 | * | ||
182 | * @callback: callback function when the reservation completes | ||
183 | * @pal_priv: private data for the PAL making the reservation | ||
184 | * | ||
185 | * Reservation status: | ||
186 | * | ||
187 | * @status: negotiation status | ||
188 | * @stream: stream index allocated for this reservation | ||
189 | * @mas: reserved MAS | ||
190 | * @drp_ie: the DRP IE | ||
191 | * @ie_valid: true iff the DRP IE matches the reservation parameters | ||
192 | * | ||
193 | * DRP reservations are uniquely identified by the owner, target and | ||
194 | * stream index. However, when using a DevAddr as a target (e.g., for | ||
195 | * a WUSB cluster reservation) the responses may be received from | ||
196 | * devices with different DevAddrs. In this case, reservations are | ||
197 | * uniquely identified by just the stream index. A number of stream | ||
198 | * indexes (UWB_NUM_GLOBAL_STREAMS) are reserved for this. | ||
199 | */ | ||
200 | struct uwb_rsv { | ||
201 | struct uwb_rc *rc; | ||
202 | struct list_head rc_node; | ||
203 | struct list_head pal_node; | ||
204 | |||
205 | struct uwb_dev *owner; | ||
206 | struct uwb_rsv_target target; | ||
207 | enum uwb_drp_type type; | ||
208 | int max_mas; | ||
209 | int min_mas; | ||
210 | int sparsity; | ||
211 | bool is_multicast; | ||
212 | |||
213 | uwb_rsv_cb_f callback; | ||
214 | void *pal_priv; | ||
215 | |||
216 | enum uwb_rsv_state state; | ||
217 | u8 stream; | ||
218 | struct uwb_mas_bm mas; | ||
219 | struct uwb_ie_drp *drp_ie; | ||
220 | bool ie_valid; | ||
221 | struct timer_list timer; | ||
222 | bool expired; | ||
223 | }; | ||
224 | |||
225 | static const | ||
226 | struct uwb_mas_bm uwb_mas_bm_zero = { .bm = { 0 } }; | ||
227 | |||
228 | static inline void uwb_mas_bm_copy_le(void *dst, const struct uwb_mas_bm *mas) | ||
229 | { | ||
230 | bitmap_copy_le(dst, mas->bm, UWB_NUM_MAS); | ||
231 | } | ||
232 | |||
233 | /** | ||
234 | * struct uwb_drp_avail - a radio controller's view of MAS usage | ||
235 | * @global: MAS unused by neighbors (excluding reservations targetted | ||
236 | * or owned by the local radio controller) or the beaon period | ||
237 | * @local: MAS unused by local established reservations | ||
238 | * @pending: MAS unused by local pending reservations | ||
239 | * @ie: DRP Availability IE to be included in the beacon | ||
240 | * @ie_valid: true iff @ie is valid and does not need to regenerated from | ||
241 | * @global and @local | ||
242 | * | ||
243 | * Each radio controller maintains a view of MAS usage or | ||
244 | * availability. MAS available for a new reservation are determined | ||
245 | * from the intersection of @global, @local, and @pending. | ||
246 | * | ||
247 | * The radio controller must transmit a DRP Availability IE that's the | ||
248 | * intersection of @global and @local. | ||
249 | * | ||
250 | * A set bit indicates the MAS is unused and available. | ||
251 | * | ||
252 | * rc->rsvs_mutex should be held before accessing this data structure. | ||
253 | * | ||
254 | * [ECMA-368] section 17.4.3. | ||
255 | */ | ||
256 | struct uwb_drp_avail { | ||
257 | DECLARE_BITMAP(global, UWB_NUM_MAS); | ||
258 | DECLARE_BITMAP(local, UWB_NUM_MAS); | ||
259 | DECLARE_BITMAP(pending, UWB_NUM_MAS); | ||
260 | struct uwb_ie_drp_avail ie; | ||
261 | bool ie_valid; | ||
262 | }; | ||
263 | |||
264 | |||
265 | const char *uwb_rsv_state_str(enum uwb_rsv_state state); | ||
266 | const char *uwb_rsv_type_str(enum uwb_drp_type type); | ||
267 | |||
268 | struct uwb_rsv *uwb_rsv_create(struct uwb_rc *rc, uwb_rsv_cb_f cb, | ||
269 | void *pal_priv); | ||
270 | void uwb_rsv_destroy(struct uwb_rsv *rsv); | ||
271 | |||
272 | int uwb_rsv_establish(struct uwb_rsv *rsv); | ||
273 | int uwb_rsv_modify(struct uwb_rsv *rsv, | ||
274 | int max_mas, int min_mas, int sparsity); | ||
275 | void uwb_rsv_terminate(struct uwb_rsv *rsv); | ||
276 | |||
277 | void uwb_rsv_accept(struct uwb_rsv *rsv, uwb_rsv_cb_f cb, void *pal_priv); | ||
278 | |||
279 | /** | ||
280 | * Radio Control Interface instance | ||
281 | * | ||
282 | * | ||
283 | * Life cycle rules: those of the UWB Device. | ||
284 | * | ||
285 | * @index: an index number for this radio controller, as used in the | ||
286 | * device name. | ||
287 | * @version: version of protocol supported by this device | ||
288 | * @priv: Backend implementation; rw with uwb_dev.dev.sem taken. | ||
289 | * @cmd: Backend implementation to execute commands; rw and call | ||
290 | * only with uwb_dev.dev.sem taken. | ||
291 | * @reset: Hardware reset of radio controller and any PAL controllers. | ||
292 | * @filter: Backend implementation to manipulate data to and from device | ||
293 | * to be compliant to specification assumed by driver (WHCI | ||
294 | * 0.95). | ||
295 | * | ||
296 | * uwb_dev.dev.mutex is used to execute commands and update | ||
297 | * the corresponding structures; can't use a spinlock | ||
298 | * because rc->cmd() can sleep. | ||
299 | * @ies: This is a dynamically allocated array cacheing the | ||
300 | * IEs (settable by the host) that the beacon of this | ||
301 | * radio controller is currently sending. | ||
302 | * | ||
303 | * In reality, we store here the full command we set to | ||
304 | * the radio controller (which is basically a command | ||
305 | * prefix followed by all the IEs the beacon currently | ||
306 | * contains). This way we don't have to realloc and | ||
307 | * memcpy when setting it. | ||
308 | * | ||
309 | * We set this up in uwb_rc_ie_setup(), where we alloc | ||
310 | * this struct, call get_ie() [so we know which IEs are | ||
311 | * currently being sent, if any]. | ||
312 | * | ||
313 | * @ies_capacity:Amount of space (in bytes) allocated in @ies. The | ||
314 | * amount used is given by sizeof(*ies) plus ies->wIELength | ||
315 | * (which is a little endian quantity all the time). | ||
316 | * @ies_mutex: protect the IE cache | ||
317 | * @dbg: information for the debug interface | ||
318 | */ | ||
319 | struct uwb_rc { | ||
320 | struct uwb_dev uwb_dev; | ||
321 | int index; | ||
322 | u16 version; | ||
323 | |||
324 | struct module *owner; | ||
325 | void *priv; | ||
326 | int (*start)(struct uwb_rc *rc); | ||
327 | void (*stop)(struct uwb_rc *rc); | ||
328 | int (*cmd)(struct uwb_rc *, const struct uwb_rccb *, size_t); | ||
329 | int (*reset)(struct uwb_rc *rc); | ||
330 | int (*filter_cmd)(struct uwb_rc *, struct uwb_rccb **, size_t *); | ||
331 | int (*filter_event)(struct uwb_rc *, struct uwb_rceb **, const size_t, | ||
332 | size_t *, size_t *); | ||
333 | |||
334 | spinlock_t neh_lock; /* protects neh_* and ctx_* */ | ||
335 | struct list_head neh_list; /* Open NE handles */ | ||
336 | unsigned long ctx_bm[UWB_RC_CTX_MAX / 8 / sizeof(unsigned long)]; | ||
337 | u8 ctx_roll; | ||
338 | |||
339 | int beaconing; /* Beaconing state [channel number] */ | ||
340 | int scanning; | ||
341 | enum uwb_scan_type scan_type:3; | ||
342 | unsigned ready:1; | ||
343 | struct uwb_notifs_chain notifs_chain; | ||
344 | |||
345 | struct uwb_drp_avail drp_avail; | ||
346 | struct list_head reservations; | ||
347 | struct mutex rsvs_mutex; | ||
348 | struct workqueue_struct *rsv_workq; | ||
349 | struct work_struct rsv_update_work; | ||
350 | |||
351 | struct mutex ies_mutex; | ||
352 | struct uwb_rc_cmd_set_ie *ies; | ||
353 | size_t ies_capacity; | ||
354 | |||
355 | spinlock_t pal_lock; | ||
356 | struct list_head pals; | ||
357 | |||
358 | struct uwb_dbg *dbg; | ||
359 | }; | ||
360 | |||
361 | |||
362 | /** | ||
363 | * struct uwb_pal - a UWB PAL | ||
364 | * @new_rsv: called when a peer requests a reservation (may be NULL if | ||
365 | * the PAL cannot accept reservation requests). | ||
366 | * | ||
367 | * A Protocol Adaptation Layer (PAL) is a user of the WiMedia UWB | ||
368 | * radio platform (e.g., WUSB, WLP or Bluetooth UWB AMP). | ||
369 | * | ||
370 | * The PALs using a radio controller must register themselves to | ||
371 | * permit the UWB stack to coordinate usage of the radio between the | ||
372 | * various PALs or to allow PALs to response to certain requests from | ||
373 | * peers. | ||
374 | * | ||
375 | * A struct uwb_pal should be embedded in a containing structure | ||
376 | * belonging to the PAL and initialized with uwb_pal_init()). Fields | ||
377 | * should be set appropriately by the PAL before registering the PAL | ||
378 | * with uwb_pal_register(). | ||
379 | */ | ||
380 | struct uwb_pal { | ||
381 | struct list_head node; | ||
382 | |||
383 | void (*new_rsv)(struct uwb_rsv *rsv); | ||
384 | }; | ||
385 | |||
386 | void uwb_pal_init(struct uwb_pal *pal); | ||
387 | int uwb_pal_register(struct uwb_rc *rc, struct uwb_pal *pal); | ||
388 | void uwb_pal_unregister(struct uwb_rc *rc, struct uwb_pal *pal); | ||
389 | |||
390 | /* | ||
391 | * General public API | ||
392 | * | ||
393 | * This API can be used by UWB device drivers or by those implementing | ||
394 | * UWB Radio Controllers | ||
395 | */ | ||
396 | struct uwb_dev *uwb_dev_get_by_devaddr(struct uwb_rc *rc, | ||
397 | const struct uwb_dev_addr *devaddr); | ||
398 | struct uwb_dev *uwb_dev_get_by_rc(struct uwb_dev *, struct uwb_rc *); | ||
399 | static inline void uwb_dev_get(struct uwb_dev *uwb_dev) | ||
400 | { | ||
401 | get_device(&uwb_dev->dev); | ||
402 | } | ||
403 | static inline void uwb_dev_put(struct uwb_dev *uwb_dev) | ||
404 | { | ||
405 | put_device(&uwb_dev->dev); | ||
406 | } | ||
407 | struct uwb_dev *uwb_dev_try_get(struct uwb_rc *rc, struct uwb_dev *uwb_dev); | ||
408 | |||
409 | /** | ||
410 | * Callback function for 'uwb_{dev,rc}_foreach()'. | ||
411 | * | ||
412 | * @dev: Linux device instance | ||
413 | * 'uwb_dev = container_of(dev, struct uwb_dev, dev)' | ||
414 | * @priv: Data passed by the caller to 'uwb_{dev,rc}_foreach()'. | ||
415 | * | ||
416 | * @returns: 0 to continue the iterations, any other val to stop | ||
417 | * iterating and return the value to the caller of | ||
418 | * _foreach(). | ||
419 | */ | ||
420 | typedef int (*uwb_dev_for_each_f)(struct device *dev, void *priv); | ||
421 | int uwb_dev_for_each(struct uwb_rc *rc, uwb_dev_for_each_f func, void *priv); | ||
422 | |||
423 | struct uwb_rc *uwb_rc_alloc(void); | ||
424 | struct uwb_rc *uwb_rc_get_by_dev(const struct uwb_dev_addr *); | ||
425 | struct uwb_rc *uwb_rc_get_by_grandpa(const struct device *); | ||
426 | void uwb_rc_put(struct uwb_rc *rc); | ||
427 | |||
428 | typedef void (*uwb_rc_cmd_cb_f)(struct uwb_rc *rc, void *arg, | ||
429 | struct uwb_rceb *reply, ssize_t reply_size); | ||
430 | |||
431 | int uwb_rc_cmd_async(struct uwb_rc *rc, const char *cmd_name, | ||
432 | struct uwb_rccb *cmd, size_t cmd_size, | ||
433 | u8 expected_type, u16 expected_event, | ||
434 | uwb_rc_cmd_cb_f cb, void *arg); | ||
435 | ssize_t uwb_rc_cmd(struct uwb_rc *rc, const char *cmd_name, | ||
436 | struct uwb_rccb *cmd, size_t cmd_size, | ||
437 | struct uwb_rceb *reply, size_t reply_size); | ||
438 | ssize_t uwb_rc_vcmd(struct uwb_rc *rc, const char *cmd_name, | ||
439 | struct uwb_rccb *cmd, size_t cmd_size, | ||
440 | u8 expected_type, u16 expected_event, | ||
441 | struct uwb_rceb **preply); | ||
442 | ssize_t uwb_rc_get_ie(struct uwb_rc *, struct uwb_rc_evt_get_ie **); | ||
443 | int uwb_bg_joined(struct uwb_rc *rc); | ||
444 | |||
445 | size_t __uwb_addr_print(char *, size_t, const unsigned char *, int); | ||
446 | |||
447 | int uwb_rc_dev_addr_set(struct uwb_rc *, const struct uwb_dev_addr *); | ||
448 | int uwb_rc_dev_addr_get(struct uwb_rc *, struct uwb_dev_addr *); | ||
449 | int uwb_rc_mac_addr_set(struct uwb_rc *, const struct uwb_mac_addr *); | ||
450 | int uwb_rc_mac_addr_get(struct uwb_rc *, struct uwb_mac_addr *); | ||
451 | int __uwb_mac_addr_assigned_check(struct device *, void *); | ||
452 | int __uwb_dev_addr_assigned_check(struct device *, void *); | ||
453 | |||
454 | /* Print in @buf a pretty repr of @addr */ | ||
455 | static inline size_t uwb_dev_addr_print(char *buf, size_t buf_size, | ||
456 | const struct uwb_dev_addr *addr) | ||
457 | { | ||
458 | return __uwb_addr_print(buf, buf_size, addr->data, 0); | ||
459 | } | ||
460 | |||
461 | /* Print in @buf a pretty repr of @addr */ | ||
462 | static inline size_t uwb_mac_addr_print(char *buf, size_t buf_size, | ||
463 | const struct uwb_mac_addr *addr) | ||
464 | { | ||
465 | return __uwb_addr_print(buf, buf_size, addr->data, 1); | ||
466 | } | ||
467 | |||
468 | /* @returns 0 if device addresses @addr2 and @addr1 are equal */ | ||
469 | static inline int uwb_dev_addr_cmp(const struct uwb_dev_addr *addr1, | ||
470 | const struct uwb_dev_addr *addr2) | ||
471 | { | ||
472 | return memcmp(addr1, addr2, sizeof(*addr1)); | ||
473 | } | ||
474 | |||
475 | /* @returns 0 if MAC addresses @addr2 and @addr1 are equal */ | ||
476 | static inline int uwb_mac_addr_cmp(const struct uwb_mac_addr *addr1, | ||
477 | const struct uwb_mac_addr *addr2) | ||
478 | { | ||
479 | return memcmp(addr1, addr2, sizeof(*addr1)); | ||
480 | } | ||
481 | |||
482 | /* @returns !0 if a MAC @addr is a broadcast address */ | ||
483 | static inline int uwb_mac_addr_bcast(const struct uwb_mac_addr *addr) | ||
484 | { | ||
485 | struct uwb_mac_addr bcast = { | ||
486 | .data = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff } | ||
487 | }; | ||
488 | return !uwb_mac_addr_cmp(addr, &bcast); | ||
489 | } | ||
490 | |||
491 | /* @returns !0 if a MAC @addr is all zeroes*/ | ||
492 | static inline int uwb_mac_addr_unset(const struct uwb_mac_addr *addr) | ||
493 | { | ||
494 | struct uwb_mac_addr unset = { | ||
495 | .data = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 } | ||
496 | }; | ||
497 | return !uwb_mac_addr_cmp(addr, &unset); | ||
498 | } | ||
499 | |||
500 | /* @returns !0 if the address is in use. */ | ||
501 | static inline unsigned __uwb_dev_addr_assigned(struct uwb_rc *rc, | ||
502 | struct uwb_dev_addr *addr) | ||
503 | { | ||
504 | return uwb_dev_for_each(rc, __uwb_dev_addr_assigned_check, addr); | ||
505 | } | ||
506 | |||
507 | /* | ||
508 | * UWB Radio Controller API | ||
509 | * | ||
510 | * This API is used (in addition to the general API) to implement UWB | ||
511 | * Radio Controllers. | ||
512 | */ | ||
513 | void uwb_rc_init(struct uwb_rc *); | ||
514 | int uwb_rc_add(struct uwb_rc *, struct device *dev, void *rc_priv); | ||
515 | void uwb_rc_rm(struct uwb_rc *); | ||
516 | void uwb_rc_neh_grok(struct uwb_rc *, void *, size_t); | ||
517 | void uwb_rc_neh_error(struct uwb_rc *, int); | ||
518 | void uwb_rc_reset_all(struct uwb_rc *rc); | ||
519 | |||
520 | /** | ||
521 | * uwb_rsv_is_owner - is the owner of this reservation the RC? | ||
522 | * @rsv: the reservation | ||
523 | */ | ||
524 | static inline bool uwb_rsv_is_owner(struct uwb_rsv *rsv) | ||
525 | { | ||
526 | return rsv->owner == &rsv->rc->uwb_dev; | ||
527 | } | ||
528 | |||
529 | /** | ||
530 | * Events generated by UWB that can be passed to any listeners | ||
531 | * | ||
532 | * Higher layers can register callback functions with the radio | ||
533 | * controller using uwb_notifs_register(). The radio controller | ||
534 | * maintains a list of all registered handlers and will notify all | ||
535 | * nodes when an event occurs. | ||
536 | */ | ||
537 | enum uwb_notifs { | ||
538 | UWB_NOTIF_BG_JOIN = 0, /* radio controller joined a beacon group */ | ||
539 | UWB_NOTIF_BG_LEAVE = 1, /* radio controller left a beacon group */ | ||
540 | UWB_NOTIF_ONAIR, | ||
541 | UWB_NOTIF_OFFAIR, | ||
542 | }; | ||
543 | |||
544 | /* Callback function registered with UWB */ | ||
545 | struct uwb_notifs_handler { | ||
546 | struct list_head list_node; | ||
547 | void (*cb)(void *, struct uwb_dev *, enum uwb_notifs); | ||
548 | void *data; | ||
549 | }; | ||
550 | |||
551 | int uwb_notifs_register(struct uwb_rc *, struct uwb_notifs_handler *); | ||
552 | int uwb_notifs_deregister(struct uwb_rc *, struct uwb_notifs_handler *); | ||
553 | |||
554 | |||
555 | /** | ||
556 | * UWB radio controller Event Size Entry (for creating entry tables) | ||
557 | * | ||
558 | * WUSB and WHCI define events and notifications, and they might have | ||
559 | * fixed or variable size. | ||
560 | * | ||
561 | * Each event/notification has a size which is not necessarily known | ||
562 | * in advance based on the event code. As well, vendor specific | ||
563 | * events/notifications will have a size impossible to determine | ||
564 | * unless we know about the device's specific details. | ||
565 | * | ||
566 | * It was way too smart of the spec writers not to think that it would | ||
567 | * be impossible for a generic driver to skip over vendor specific | ||
568 | * events/notifications if there are no LENGTH fields in the HEADER of | ||
569 | * each message...the transaction size cannot be counted on as the | ||
570 | * spec does not forbid to pack more than one event in a single | ||
571 | * transaction. | ||
572 | * | ||
573 | * Thus, we guess sizes with tables (or for events, when you know the | ||
574 | * size ahead of time you can use uwb_rc_neh_extra_size*()). We | ||
575 | * register tables with the known events and their sizes, and then we | ||
576 | * traverse those tables. For those with variable length, we provide a | ||
577 | * way to lookup the size inside the event/notification's | ||
578 | * payload. This allows device-specific event size tables to be | ||
579 | * registered. | ||
580 | * | ||
581 | * @size: Size of the payload | ||
582 | * | ||
583 | * @offset: if != 0, at offset @offset-1 starts a field with a length | ||
584 | * that has to be added to @size. The format of the field is | ||
585 | * given by @type. | ||
586 | * | ||
587 | * @type: Type and length of the offset field. Most common is LE 16 | ||
588 | * bits (that's why that is zero); others are there mostly to | ||
589 | * cover for bugs and weirdos. | ||
590 | */ | ||
591 | struct uwb_est_entry { | ||
592 | size_t size; | ||
593 | unsigned offset; | ||
594 | enum { UWB_EST_16 = 0, UWB_EST_8 = 1 } type; | ||
595 | }; | ||
596 | |||
597 | int uwb_est_register(u8 type, u8 code_high, u16 vendor, u16 product, | ||
598 | const struct uwb_est_entry *, size_t entries); | ||
599 | int uwb_est_unregister(u8 type, u8 code_high, u16 vendor, u16 product, | ||
600 | const struct uwb_est_entry *, size_t entries); | ||
601 | ssize_t uwb_est_find_size(struct uwb_rc *rc, const struct uwb_rceb *rceb, | ||
602 | size_t len); | ||
603 | |||
604 | /* -- Misc */ | ||
605 | |||
606 | enum { | ||
607 | EDC_MAX_ERRORS = 10, | ||
608 | EDC_ERROR_TIMEFRAME = HZ, | ||
609 | }; | ||
610 | |||
611 | /* error density counter */ | ||
612 | struct edc { | ||
613 | unsigned long timestart; | ||
614 | u16 errorcount; | ||
615 | }; | ||
616 | |||
617 | static inline | ||
618 | void edc_init(struct edc *edc) | ||
619 | { | ||
620 | edc->timestart = jiffies; | ||
621 | } | ||
622 | |||
623 | /* Called when an error occured. | ||
624 | * This is way to determine if the number of acceptable errors per time | ||
625 | * period has been exceeded. It is not accurate as there are cases in which | ||
626 | * this scheme will not work, for example if there are periodic occurences | ||
627 | * of errors that straddle updates to the start time. This scheme is | ||
628 | * sufficient for our usage. | ||
629 | * | ||
630 | * @returns 1 if maximum acceptable errors per timeframe has been exceeded. | ||
631 | */ | ||
632 | static inline int edc_inc(struct edc *err_hist, u16 max_err, u16 timeframe) | ||
633 | { | ||
634 | unsigned long now; | ||
635 | |||
636 | now = jiffies; | ||
637 | if (now - err_hist->timestart > timeframe) { | ||
638 | err_hist->errorcount = 1; | ||
639 | err_hist->timestart = now; | ||
640 | } else if (++err_hist->errorcount > max_err) { | ||
641 | err_hist->errorcount = 0; | ||
642 | err_hist->timestart = now; | ||
643 | return 1; | ||
644 | } | ||
645 | return 0; | ||
646 | } | ||
647 | |||
648 | |||
649 | /* Information Element handling */ | ||
650 | |||
651 | /* For representing the state of writing to a buffer when iterating */ | ||
652 | struct uwb_buf_ctx { | ||
653 | char *buf; | ||
654 | size_t bytes, size; | ||
655 | }; | ||
656 | |||
657 | typedef int (*uwb_ie_f)(struct uwb_dev *, const struct uwb_ie_hdr *, | ||
658 | size_t, void *); | ||
659 | struct uwb_ie_hdr *uwb_ie_next(void **ptr, size_t *len); | ||
660 | ssize_t uwb_ie_for_each(struct uwb_dev *uwb_dev, uwb_ie_f fn, void *data, | ||
661 | const void *buf, size_t size); | ||
662 | int uwb_ie_dump_hex(struct uwb_dev *, const struct uwb_ie_hdr *, | ||
663 | size_t, void *); | ||
664 | int uwb_rc_set_ie(struct uwb_rc *, struct uwb_rc_cmd_set_ie *); | ||
665 | struct uwb_ie_hdr *uwb_ie_next(void **ptr, size_t *len); | ||
666 | |||
667 | |||
668 | /* | ||
669 | * Transmission statistics | ||
670 | * | ||
671 | * UWB uses LQI and RSSI (one byte values) for reporting radio signal | ||
672 | * strength and line quality indication. We do quick and dirty | ||
673 | * averages of those. They are signed values, btw. | ||
674 | * | ||
675 | * For 8 bit quantities, we keep the min, the max, an accumulator | ||
676 | * (@sigma) and a # of samples. When @samples gets to 255, we compute | ||
677 | * the average (@sigma / @samples), place it in @sigma and reset | ||
678 | * @samples to 1 (so we use it as the first sample). | ||
679 | * | ||
680 | * Now, statistically speaking, probably I am kicking the kidneys of | ||
681 | * some books I have in my shelves collecting dust, but I just want to | ||
682 | * get an approx, not the Nobel. | ||
683 | * | ||
684 | * LOCKING: there is no locking per se, but we try to keep a lockless | ||
685 | * schema. Only _add_samples() modifies the values--as long as you | ||
686 | * have other locking on top that makes sure that no two calls of | ||
687 | * _add_sample() happen at the same time, then we are fine. Now, for | ||
688 | * resetting the values we just set @samples to 0 and that makes the | ||
689 | * next _add_sample() to start with defaults. Reading the values in | ||
690 | * _show() currently can race, so you need to make sure the calls are | ||
691 | * under the same lock that protects calls to _add_sample(). FIXME: | ||
692 | * currently unlocked (It is not ultraprecise but does the trick. Bite | ||
693 | * me). | ||
694 | */ | ||
695 | struct stats { | ||
696 | s8 min, max; | ||
697 | s16 sigma; | ||
698 | atomic_t samples; | ||
699 | }; | ||
700 | |||
701 | static inline | ||
702 | void stats_init(struct stats *stats) | ||
703 | { | ||
704 | atomic_set(&stats->samples, 0); | ||
705 | wmb(); | ||
706 | } | ||
707 | |||
708 | static inline | ||
709 | void stats_add_sample(struct stats *stats, s8 sample) | ||
710 | { | ||
711 | s8 min, max; | ||
712 | s16 sigma; | ||
713 | unsigned samples = atomic_read(&stats->samples); | ||
714 | if (samples == 0) { /* it was zero before, so we initialize */ | ||
715 | min = 127; | ||
716 | max = -128; | ||
717 | sigma = 0; | ||
718 | } else { | ||
719 | min = stats->min; | ||
720 | max = stats->max; | ||
721 | sigma = stats->sigma; | ||
722 | } | ||
723 | |||
724 | if (sample < min) /* compute new values */ | ||
725 | min = sample; | ||
726 | else if (sample > max) | ||
727 | max = sample; | ||
728 | sigma += sample; | ||
729 | |||
730 | stats->min = min; /* commit */ | ||
731 | stats->max = max; | ||
732 | stats->sigma = sigma; | ||
733 | if (atomic_add_return(1, &stats->samples) > 255) { | ||
734 | /* wrapped around! reset */ | ||
735 | stats->sigma = sigma / 256; | ||
736 | atomic_set(&stats->samples, 1); | ||
737 | } | ||
738 | } | ||
739 | |||
740 | static inline ssize_t stats_show(struct stats *stats, char *buf) | ||
741 | { | ||
742 | int min, max, avg; | ||
743 | int samples = atomic_read(&stats->samples); | ||
744 | if (samples == 0) | ||
745 | min = max = avg = 0; | ||
746 | else { | ||
747 | min = stats->min; | ||
748 | max = stats->max; | ||
749 | avg = stats->sigma / samples; | ||
750 | } | ||
751 | return scnprintf(buf, PAGE_SIZE, "%d %d %d\n", min, max, avg); | ||
752 | } | ||
753 | |||
754 | static inline ssize_t stats_store(struct stats *stats, const char *buf, | ||
755 | size_t size) | ||
756 | { | ||
757 | stats_init(stats); | ||
758 | return size; | ||
759 | } | ||
760 | |||
761 | #endif /* #ifndef __LINUX__UWB_H__ */ | ||