| blob | f915f404302d68f2457797fb38255d6920381255 |
1 /*
2 * Copyright (C) 2010 Bruno Randolf <br1@einfach.org>
3 *
4 * Permission to use, copy, modify, and/or distribute this software for any
5 * purpose with or without fee is hereby granted, provided that the above
6 * copyright notice and this permission notice appear in all copies.
7 *
8 * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
9 * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
10 * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
11 * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
12 * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
13 * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
14 * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
15 */
23 /**
24 * DOC: Basic ANI Operation
25 *
26 * Adaptive Noise Immunity (ANI) controls five noise immunity parameters
27 * depending on the amount of interference in the environment, increasing
28 * or reducing sensitivity as necessary.
29 *
30 * The parameters are:
31 * - "noise immunity"
32 * - "spur immunity"
33 * - "firstep level"
34 * - "OFDM weak signal detection"
35 * - "CCK weak signal detection"
36 *
37 * Basically we look at the amount of ODFM and CCK timing errors we get and then
38 * raise or lower immunity accordingly by setting one or more of these
39 * parameters.
40 * Newer chipsets have PHY error counters in hardware which will generate a MIB
41 * interrupt when they overflow. Older hardware has too enable PHY error frames
42 * by setting a RX flag and then count every single PHY error. When a specified
43 * threshold of errors has been reached we will raise immunity.
44 * Also we regularly check the amount of errors and lower or raise immunity as
45 * necessary.
46 */
49 /*** ANI parameter control ***/
51 /**
52 * ath5k_ani_set_noise_immunity_level() - Set noise immunity level
53 *
54 * @level: level between 0 and @ATH5K_ANI_MAX_NOISE_IMM_LVL
55 */
56 void
58 {
59 /* TODO:
60 * ANI documents suggest the following five levels to use, but the HAL
61 * and ath9k use only the last two levels, making this
62 * essentially an on/off option. There *may* be a reason for this (???),
63 * so i stick with the HAL version for now...
64 */
65 #if 0
70 #else
75 #endif
78 level);
80 }
93 }
96 /**
97 * ath5k_ani_set_spur_immunity_level() - Set spur immunity level
98 *
99 * @level: level between 0 and @max_spur_level (the maximum level is dependent
100 * on the chip revision).
101 */
102 void
104 {
110 level);
112 }
119 }
122 /**
123 * ath5k_ani_set_firstep_level() - Set "firstep" level
124 *
125 * @level: level between 0 and @ATH5K_ANI_MAX_FIRSTEP_LVL
126 */
127 void
129 {
135 }
142 }
145 /**
146 * ath5k_ani_set_ofdm_weak_signal_detection() - Control OFDM weak signal
147 * detection
148 *
149 * @on: turn on or off
150 */
151 void
153 {
176 AR5K_PHY_WEAK_OFDM_LOW_THR_SELFCOR_EN);
177 else
179 AR5K_PHY_WEAK_OFDM_LOW_THR_SELFCOR_EN);
184 }
187 /**
188 * ath5k_ani_set_cck_weak_signal_detection() - control CCK weak signal detection
189 *
190 * @on: turn on or off
191 */
192 void
194 {
201 }
204 /*** ANI algorithm ***/
206 /**
207 * ath5k_ani_raise_immunity() - Increase noise immunity
208 *
209 * @ofdm_trigger: If this is true we are called because of too many OFDM errors,
210 * the algorithm will tune more parameters then.
211 *
212 * Try to raise noise immunity (=decrease sensitivity) in several steps
213 * depending on the average RSSI of the beacons we received.
214 */
215 static void
218 {
224 /* first: raise noise immunity */
228 }
230 /* only OFDM: raise spur immunity level */
235 }
237 /* AP mode */
242 }
244 /* STA and IBSS mode */
246 /* TODO: for IBSS mode it would be better to keep a beacon RSSI average
247 * per each neighbour node and use the minimum of these, to make sure we
248 * don't shut out a remote node by raising immunity too high. */
253 /* only OFDM: beacon RSSI is high, we can disable ODFM weak
254 * signal detection */
259 }
260 /* as a last resort or CCK: raise firstep level */
264 }
266 /* beacon RSSI in mid range, we need OFDM weak signal detect,
267 * but can raise firstep level */
276 /* beacon RSSI is low. in B/G mode turn of OFDM weak signal
277 * detect and zero firstep level to maximize CCK sensitivity */
285 }
287 /* TODO: why not?:
288 if (as->cck_weak_sig == true) {
289 ath5k_ani_set_cck_weak_signal_detection(ah, false);
290 }
291 */
292 }
295 /**
296 * ath5k_ani_lower_immunity() - Decrease noise immunity
297 *
298 * Try to lower noise immunity (=increase sensitivity) in several steps
299 * depending on the average RSSI of the beacons we received.
300 */
301 static void
303 {
309 /* AP mode */
313 }
315 /* STA and IBSS mode (see TODO above) */
317 /* beacon signal is high, leave OFDM weak signal
318 * detection off or it may oscillate
319 * TODO: who said it's off??? */
321 /* beacon RSSI is mid-range: turn on ODFM weak signal
322 * detection and next, lower firstep level */
327 }
332 }
334 /* beacon signal is low: only reduce firstep level */
339 }
340 }
341 }
343 /* all modes */
347 }
349 /* finally, reduce noise immunity */
353 }
354 }
357 /**
358 * ath5k_hw_ani_get_listen_time() - Update counters and return listening time
359 *
360 * Return an approximation of the time spent "listening" in milliseconds (ms)
361 * since the last call of this function.
362 * Save a snapshot of the counter values for debugging/statistics.
363 */
364 static int
366 {
375 /* clears common->cc_ani */
381 }
384 /**
385 * ath5k_ani_save_and_clear_phy_errors() - Clear and save PHY error counters
386 *
387 * Clear the PHY error counters as soon as possible, since this might be called
388 * from a MIB interrupt and we want to make sure we don't get interrupted again.
389 * Add the count of CCK and OFDM errors to our internal state, so it can be used
390 * by the algorithm later.
391 *
392 * Will be called from interrupt and tasklet context.
393 * Returns 0 if both counters are zero.
394 */
395 static int
398 {
407 /* reset counters first, we might be in a hurry (interrupt) */
409 AR5K_PHYERR_CNT1);
411 AR5K_PHYERR_CNT2);
416 /* sometimes both can be zero, especially when there is a superfluous
417 * second interrupt. detect that here and return an error. */
421 /* avoid negative values should one of the registers overflow */
425 }
429 }
431 }
434 /**
435 * ath5k_ani_period_restart() - Restart ANI period
436 *
437 * Just reset counters, so they are clear for the next "ani period".
438 */
439 static void
441 {
442 /* keep last values for debugging */
450 }
453 /**
454 * ath5k_ani_calibration() - The main ANI calibration function
455 *
456 * We count OFDM and CCK errors relative to the time where we did not send or
457 * receive ("listen" time) and raise or lower immunity accordingly.
458 * This is called regularly (every second) from the calibration timer, but also
459 * when an error threshold has been reached.
460 *
461 * In order to synchronize access from different contexts, this should be
462 * called only indirectly by scheduling the ANI tasklet!
463 */
464 void
466 {
470 /* get listen time since last call and add it to the counter because we
471 * might not have restarted the "ani period" last time.
472 * always do this to calculate the busy time also in manual mode */
493 /* too many PHY errors - we have to raise immunity */
499 /* If more than 5 (TODO: why 5?) periods have passed and we got
500 * relatively little errors we can try to lower immunity */
509 }
510 }
513 /*** INTERRUPT HANDLER ***/
515 /**
516 * ath5k_ani_mib_intr() - Interrupt handler for ANI MIB counters
517 *
518 * Just read & reset the registers quickly, so they don't generate more
519 * interrupts, save the counters and schedule the tasklet to decide whether
520 * to raise immunity or not.
521 *
522 * We just need to handle PHY error counters, ath5k_hw_update_mib_counters()
523 * should take care of all "normal" MIB interrupts.
524 */
525 void
527 {
530 /* nothing to do here if HW does not have PHY error counters - they
531 * can't be the reason for the MIB interrupt then */
535 /* not in use but clear anyways */
542 /* If one of the errors triggered, we can get a superfluous second
543 * interrupt, even though we have already reset the register. The
544 * function detects that so we can return early. */
551 }
554 /**
555 * ath5k_ani_phy_error_report() - Used by older HW to report PHY errors
556 *
557 * This is used by hardware without PHY error counters to report PHY errors
558 * on a frame-by-frame basis, instead of the interrupt.
559 */
560 void
563 {
574 }
575 }
578 /*** INIT ***/
580 /**
581 * ath5k_enable_phy_err_counters() - Enable PHY error counters
582 *
583 * Enable PHY error counters for OFDM and CCK timing errors.
584 */
585 static void
587 {
589 AR5K_PHYERR_CNT1);
591 AR5K_PHYERR_CNT2);
595 /* not in use */
598 }
601 /**
602 * ath5k_disable_phy_err_counters() - Disable PHY error counters
603 *
604 * Disable PHY error counters for OFDM and CCK timing errors.
605 */
606 static void
608 {
614 /* not in use */
617 }
620 /**
621 * ath5k_ani_init() - Initialize ANI
622 * @mode: Which mode to use (auto, manual high, manual low, off)
623 *
624 * Initialize ANI according to mode.
625 */
626 void
628 {
629 /* ANI is only possible on 5212 and newer */
633 /* clear old state information */
636 /* older hardware has more spur levels than newer */
639 else
642 /* initial values for our ani parameters */
657 ATH5K_ANI_MAX_NOISE_IMM_LVL);
670 }
672 /* newer hardware has PHY error counter registers which we can use to
673 * get OFDM and CCK error counts. older hardware has to set rxfilter and
674 * report every single PHY error by calling ath5k_ani_phy_error_report()
675 */
679 else
681 AR5K_RX_FILTER_PHYERR);
685 else
688 }
691 }
694 /*** DEBUG ***/
696 #ifdef CONFIG_ATH5K_DEBUG
698 void
700 {
701 /* clears too */
711 /* no clear */
729 }
731 #endif