2 * carl9170 firmware - used by the ar9170 wireless device
4 * Interface to the WLAN part of the chip
6 * Copyright (c) 2000-2005 ZyDAS Technology Corporation
7 * Copyright (c) 2007-2009 Atheros Communications, Inc.
8 * Copyright 2009 Johannes Berg <johannes@sipsolutions.net>
9 * Copyright 2009-2011 Christian Lamparter <chunkeey@googlemail.com>
11 * This program is free software; you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License as published by
13 * the Free Software Foundation; either version 2 of the License, or
14 * (at your option) any later version.
16 * This program is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 * GNU General Public License for more details.
21 * You should have received a copy of the GNU General Public License along
22 * with this program; if not, write to the Free Software Foundation, Inc.,
23 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
27 #include "shared/phy.h"
33 #include "linux/ieee80211.h"
36 static void wlan_txunstuck(unsigned int queue)
38 set_wlan_txq_dma_addr(queue, ((uint32_t) fw.wlan.tx_queue[queue].head) | 1);
41 #ifdef CONFIG_CARL9170FW_DMA_QUEUE_BUMP
42 static void wlan_txupdate(unsigned int queue)
44 set_wlan_txq_dma_addr(queue, ((uint32_t) fw.wlan.tx_queue[queue].head));
47 static void wlan_dma_bump(unsigned int qidx)
49 unsigned int offset = qidx;
50 uint32_t status, trigger;
52 status = get(AR9170_MAC_REG_DMA_STATUS) >> 12;
53 trigger = get(AR9170_MAC_REG_DMA_TRIGGER) >> 12;
64 if ((trigger == 0xa) && (status == 0x8)) {
72 #endif /* CONFIG_CARL9170FW_DMA_QUEUE_BUMP */
74 #ifdef CONFIG_CARL9170FW_DEBUG
75 static void wlan_dump_queue(unsigned int qidx)
78 struct dma_desc *desc;
79 struct carl9170_tx_superframe *super;
82 __for_each_desc(desc, &fw.wlan.tx_queue[qidx]) {
83 super = get_super(desc);
84 DBG("%d: %p s:%x c:%x tl:%x ds:%x n:%p l:%p ", entries, desc,
85 desc->status, desc->ctrl, desc->totalLen,
86 desc->dataSize, desc->nextAddr, desc->lastAddr);
88 DBG("c:%x tr:%d ri:%d l:%x m:%x p:%x fc:%x",
89 super->s.cookie, super->s.cnt, super->s.rix,
90 super->f.hdr.length, super->f.hdr.mac.set,
91 (unsigned int) le32_to_cpu(super->f.hdr.phy.set),
92 super->f.data.i3e.frame_control);
97 desc = get_wlan_txq_addr(qidx);
99 DBG("Queue: %d: te:%d td:%d h:%p c:%p t:%p",
100 qidx, entries, queue_len(&fw.wlan.tx_queue[qidx]),
101 fw.wlan.tx_queue[qidx].head,
102 desc, fw.wlan.tx_queue[qidx].terminator);
104 DBG("HW: t:%x s:%x ac:%x c:%x",
105 (unsigned int) get(AR9170_MAC_REG_DMA_TRIGGER),
106 (unsigned int) get(AR9170_MAC_REG_DMA_STATUS),
107 (unsigned int) get(AR9170_MAC_REG_AMPDU_COUNT),
108 (unsigned int) get(AR9170_MAC_REG_DMA_TXQX_ADDR_CURR));
110 #endif /* CONFIG_CARL9170FW_DEBUG */
112 static void wlan_send_buffered_tx_status(void)
116 while (fw.wlan.tx_status_pending) {
117 len = min((unsigned int)fw.wlan.tx_status_pending,
118 CARL9170_RSP_TX_STATUS_NUM);
119 len = min(len, CARL9170_TX_STATUS_NUM - fw.wlan.tx_status_head_idx);
122 * rather than memcpy each individual request into a large buffer,
123 * we _splice_ them all together.
125 * The only downside is however that we have to be careful around
126 * the edges of the tx_status_cache.
129 * Each tx_status is about 2 bytes. However every command package
130 * must have a size which is a multiple of 4.
133 send_cmd_to_host((len * sizeof(struct carl9170_tx_status) + 3) & ~3,
134 CARL9170_RSP_TXCOMP, len, (void *)
135 &fw.wlan.tx_status_cache[fw.wlan.tx_status_head_idx]);
137 fw.wlan.tx_status_pending -= len;
138 fw.wlan.tx_status_head_idx += len;
139 fw.wlan.tx_status_head_idx %= CARL9170_TX_STATUS_NUM;
143 static struct carl9170_tx_status *wlan_get_tx_status_buffer(void)
145 struct carl9170_tx_status *tmp;
147 tmp = &fw.wlan.tx_status_cache[fw.wlan.tx_status_tail_idx++];
148 fw.wlan.tx_status_tail_idx %= CARL9170_TX_STATUS_NUM;
150 if (fw.wlan.tx_status_pending == CARL9170_TX_STATUS_NUM)
151 wlan_send_buffered_tx_status();
153 fw.wlan.tx_status_pending++;
158 /* generate _aggregated_ tx_status for the host */
159 void wlan_tx_complete(struct carl9170_tx_superframe *super,
162 struct carl9170_tx_status *status;
164 status = wlan_get_tx_status_buffer();
167 * The *unique* cookie and AC_ID is used by the driver for
170 status->cookie = super->s.cookie;
171 status->queue = super->s.queue;
175 * This field holds the number of tries of the rate in
176 * the rate index field (rix).
178 status->rix = super->s.rix;
179 status->tries = super->s.cnt;
180 status->success = (txs) ? 1 : 0;
183 static bool wlan_tx_consume_retry(struct carl9170_tx_superframe *super)
185 /* check if this was the last possible retry with this rate */
186 if (unlikely(super->s.cnt >= super->s.ri[super->s.rix].tries)) {
187 /* end of the road - indicate tx failure */
188 if (unlikely(super->s.rix == CARL9170_TX_MAX_RETRY_RATES))
191 /* check if there are alternative rates available */
192 if (!super->s.rr[super->s.rix].set)
195 /* try next retry rate */
196 super->f.hdr.phy.set = super->s.rr[super->s.rix].set;
198 /* finally - mark the old rate as USED */
201 /* update MAC flags */
202 super->f.hdr.mac.erp_prot = super->s.ri[super->s.rix].erp_prot;
203 super->f.hdr.mac.ampdu = super->s.ri[super->s.rix].ampdu;
205 /* reinitialize try counter */
208 /* just increase retry counter */
215 static inline u16 get_tid(struct ieee80211_hdr *hdr)
217 return (ieee80211_get_qos_ctl(hdr))[0] & IEEE80211_QOS_CTL_TID_MASK;
220 /* This function will only work on uint32_t-aligned pointers! */
221 static bool same_hdr(const void *_d0, const void *_d1)
223 const uint32_t *d0 = _d0;
224 const uint32_t *d1 = _d1;
226 /* BUG_ON((unsigned long)d0 & 3 || (unsigned long)d1 & 3)) */
227 return !((d0[0] ^ d1[0]) | /* FC + DU */
228 (d0[1] ^ d1[1]) | /* addr1 */
229 (d0[2] ^ d1[2]) | (d0[3] ^ d1[3]) | /* addr2 + addr3 */
230 (d0[4] ^ d1[4])); /* addr3 */
233 static inline bool same_aggr(struct ieee80211_hdr *a, struct ieee80211_hdr *b)
235 return (get_tid(a) == get_tid(b)) || same_hdr(a, b);
238 static void wlan_tx_ampdu_reset(unsigned int qidx)
240 fw.wlan.ampdu_prev[qidx] = NULL;
243 static void wlan_tx_ampdu_end(unsigned int qidx)
245 struct carl9170_tx_superframe *ht_prev = fw.wlan.ampdu_prev[qidx];
248 ht_prev->f.hdr.mac.ba_end = 1;
250 wlan_tx_ampdu_reset(qidx);
253 static void wlan_tx_ampdu(struct carl9170_tx_superframe *super)
255 unsigned int qidx = super->s.queue;
256 struct carl9170_tx_superframe *ht_prev = fw.wlan.ampdu_prev[qidx];
258 if (super->f.hdr.mac.ampdu) {
260 !same_aggr(&super->f.data.i3e, &ht_prev->f.data.i3e))
261 ht_prev->f.hdr.mac.ba_end = 1;
263 super->f.hdr.mac.ba_end = 0;
265 fw.wlan.ampdu_prev[qidx] = super;
267 wlan_tx_ampdu_end(qidx);
272 static void __wlan_tx(struct dma_desc *desc)
274 struct carl9170_tx_superframe *super = get_super(desc);
276 if (unlikely(super->s.fill_in_tsf)) {
277 struct ieee80211_mgmt *mgmt = (void *) &super->f.data.i3e;
278 uint32_t *tsf = (uint32_t *) &mgmt->u.probe_resp.timestamp;
281 * Truth be told: this is a hack.
283 * The *real* TSF is definitely going to be higher/older.
284 * But this hardware emulation code is head and shoulders
285 * above anything a driver can possibly do.
287 * (even, if it's got an accurate atomic clock source).
293 wlan_tx_ampdu(super);
295 #ifdef CONFIG_CARL9170FW_DEBUG
296 BUG_ON(fw.phy.psm.state != CARL9170_PSM_WAKE);
297 #endif /* CONFIG_CARL9170FW_DEBUG */
299 /* insert desc into the right queue */
300 dma_put(&fw.wlan.tx_queue[super->s.queue], desc);
303 static void wlan_assign_seq(struct ieee80211_hdr *hdr, unsigned int vif)
305 hdr->seq_ctrl &= cpu_to_le16(~IEEE80211_SCTL_SEQ);
306 hdr->seq_ctrl |= cpu_to_le16(fw.wlan.sequence[vif]);
308 if (ieee80211_is_first_frag(hdr->seq_ctrl))
309 fw.wlan.sequence[vif] += 0x10;
312 /* prepares frame for the first transmission */
313 static void _wlan_tx(struct dma_desc *desc)
315 struct carl9170_tx_superframe *super = get_super(desc);
317 if (unlikely(super->s.assign_seq))
318 wlan_assign_seq(&super->f.data.i3e, super->s.vif_id);
320 if (unlikely(super->s.ampdu_commit_density)) {
321 set(AR9170_MAC_REG_AMPDU_DENSITY,
322 MOD_VAL(AR9170_MAC_AMPDU_DENSITY,
323 get(AR9170_MAC_REG_AMPDU_DENSITY),
324 super->s.ampdu_density));
327 if (unlikely(super->s.ampdu_commit_factor)) {
328 set(AR9170_MAC_REG_AMPDU_FACTOR,
329 MOD_VAL(AR9170_MAC_AMPDU_FACTOR,
330 get(AR9170_MAC_REG_AMPDU_FACTOR),
331 8 << super->s.ampdu_factor));
335 /* propagate transmission status back to the driver */
336 static bool wlan_tx_status(struct dma_queue *queue,
337 struct dma_desc *desc)
339 struct carl9170_tx_superframe *super = get_super(desc);
340 unsigned int qidx = super->s.queue;
341 bool txfail = false, success;
345 /* update hangcheck */
346 fw.wlan.last_super_num[qidx] = 0;
348 if (!!(desc->ctrl & AR9170_CTRL_FAIL)) {
349 txfail = !!(desc->ctrl & AR9170_CTRL_TXFAIL);
351 /* reset retry indicator flags */
352 desc->ctrl &= ~(AR9170_CTRL_TXFAIL | AR9170_CTRL_BAFAIL);
355 * Note: wlan_tx_consume_retry will override the old
356 * phy [CCK,OFDM, HT, BW20/40, MCS...] and mac vectors
357 * [AMPDU,RTS/CTS,...] therefore be careful when they
360 if (wlan_tx_consume_retry(super)) {
362 * retry for simple and aggregated 802.11 frames.
364 * Note: We must not mess up the original frame
368 if (!super->f.hdr.mac.ampdu) {
370 * 802.11 - 7.1.3.1.5.
371 * set "Retry Field" for consecutive attempts
373 * Note: For AMPDU see:
374 * 802.11n 9.9.1.6 "Retransmit Procedures"
376 super->f.data.i3e.frame_control |=
377 cpu_to_le16(IEEE80211_FCTL_RETRY);
381 /* Normal TX Failure */
383 /* demise descriptor ownership back to the hardware */
387 * And this will get the queue going again.
388 * To understand why: you have to get the HW
389 * specs... But sadly I never saw them.
391 wlan_txunstuck(qidx);
393 /* abort cycle - this is necessary due to HW design */
396 /* (HT-) BlockACK failure */
399 * Unlink the failed attempt and put it into
400 * the retry queue. The caller routine must
401 * be aware of this so the frames don't get lost.
404 #ifndef CONFIG_CARL9170FW_DEBUG
405 dma_unlink_head(queue);
406 #else /* CONFIG_CARL9170FW_DEBUG */
407 BUG_ON(dma_unlink_head(queue) != desc);
408 #endif /* CONFIG_CARL9170FW_DEBUG */
409 dma_put(&fw.wlan.tx_retry, desc);
413 /* out of frame attempts - discard frame */
418 #ifndef CONFIG_CARL9170FW_DEBUG
419 dma_unlink_head(queue);
420 #else /* CONFIG_CARL9170FW_DEBUG */
421 BUG_ON(dma_unlink_head(queue) != desc);
422 #endif /* CONFIG_CARL9170FW_DEBUG */
425 * Issue the queue bump,
426 * We need to do this in case this was the frame's last
427 * possible retry attempt and it unfortunately: it failed.
430 wlan_txunstuck(qidx);
435 if (unlikely(super == fw.wlan.fw_desc_data)) {
436 fw.wlan.fw_desc = desc;
437 fw.wlan.fw_desc_available = 1;
439 if (fw.wlan.fw_desc_callback)
440 fw.wlan.fw_desc_callback(super, success);
445 #ifdef CONFIG_CARL9170FW_CAB_QUEUE
446 if (unlikely(super->s.cab))
447 fw.wlan.cab_queue_len[super->s.vif_id]--;
448 #endif /* CONFIG_CARL9170FW_CAB_QUEUE */
450 wlan_tx_complete(super, success);
452 /* recycle freed descriptors */
453 dma_reclaim(&fw.pta.down_queue, desc);
458 static void handle_tx_completion(void)
460 struct dma_desc *desc;
463 for (i = AR9170_TXQ_SPECIAL; i >= AR9170_TXQ0; i--) {
464 __while_desc_bits(desc, &fw.wlan.tx_queue[i], AR9170_OWN_BITS_SW) {
465 if (!wlan_tx_status(&fw.wlan.tx_queue[i], desc)) {
466 /* termination requested. */
471 wlan_tx_ampdu_reset(i);
473 for_each_desc(desc, &fw.wlan.tx_retry)
476 wlan_tx_ampdu_end(i);
477 if (!queue_empty(&fw.wlan.tx_queue[i]))
478 wlan_trigger(BIT(i));
482 void __hot wlan_tx(struct dma_desc *desc)
484 struct carl9170_tx_superframe *super = DESC_PAYLOAD(desc);
486 /* initialize rate control struct */
491 #ifdef CONFIG_CARL9170FW_CAB_QUEUE
492 if (unlikely(super->s.cab)) {
493 fw.wlan.cab_queue_len[super->s.vif_id]++;
494 dma_put(&fw.wlan.cab_queue[super->s.vif_id], desc);
497 #endif /* CONFIG_CARL9170FW_CAB_QUEUE */
501 wlan_trigger(BIT(super->s.queue));
504 void wlan_tx_fw(struct carl9170_tx_superdesc *super, fw_desc_callback_t cb)
506 if (!fw.wlan.fw_desc_available)
509 fw.wlan.fw_desc_available = 0;
511 /* Format BlockAck */
512 fw.wlan.fw_desc->ctrl = AR9170_CTRL_FS_BIT | AR9170_CTRL_LS_BIT;
513 fw.wlan.fw_desc->status = AR9170_OWN_BITS_SW;
515 fw.wlan.fw_desc->totalLen = fw.wlan.fw_desc->dataSize = super->len;
516 fw.wlan.fw_desc_data = fw.wlan.fw_desc->dataAddr = super;
517 fw.wlan.fw_desc->nextAddr = fw.wlan.fw_desc->lastAddr =
519 fw.wlan.fw_desc_callback = cb;
520 wlan_tx(fw.wlan.fw_desc);
523 static void wlan_send_buffered_ba(void)
525 struct carl9170_tx_ba_superframe *baf = &dma_mem.reserved.ba.ba;
526 struct ieee80211_ba *ba = (struct ieee80211_ba *) &baf->f.ba;
527 struct carl9170_bar_ctx *ctx;
529 if (likely(!fw.wlan.queued_ba))
532 /* there's no point to continue when the ba_desc is not available. */
533 if (!fw.wlan.fw_desc_available)
536 ctx = &fw.wlan.ba_cache[fw.wlan.ba_head_idx];
537 fw.wlan.ba_head_idx++;
538 fw.wlan.ba_head_idx %= CONFIG_CARL9170FW_BACK_REQS_NUM;
541 baf->s.len = sizeof(struct carl9170_tx_superdesc) +
542 sizeof(struct ar9170_tx_hwdesc) +
543 sizeof(struct ieee80211_ba);
544 baf->s.ri[0].tries = 1;
546 baf->s.queue = AR9170_TXQ_VO;
547 baf->f.hdr.length = sizeof(struct ieee80211_ba) + FCS_LEN;
549 baf->f.hdr.mac.no_ack = 1;
551 baf->f.hdr.phy.modulation = 1; /* OFDM */
552 baf->f.hdr.phy.tx_power = 34; /* 17 dBm */
553 baf->f.hdr.phy.chains = 1;
554 baf->f.hdr.phy.mcs = AR9170_TXRX_PHY_RATE_OFDM_6M;
556 /* format outgoing BA */
557 ba->frame_control = cpu_to_le16(IEEE80211_FTYPE_CTL | IEEE80211_STYPE_BACK);
558 ba->duration = cpu_to_le16(0);
559 memcpy(ba->ta, ctx->ta, 6);
560 memcpy(ba->ra, ctx->ra, 6);
563 * Unfortunately, we cannot look into the hardware's scoreboard.
564 * Therefore we have to proceed as described in 802.11n 9.10.7.5
565 * and send a null BlockAck.
567 memset(ba->bitmap, 0x0, sizeof(ba->bitmap));
569 ba->control = ctx->control;
570 ba->start_seq_num = ctx->start_seq_num;
571 wlan_tx_fw(&baf->s, NULL);
574 static struct carl9170_bar_ctx *wlan_get_bar_cache_buffer(void)
576 struct carl9170_bar_ctx *tmp;
578 tmp = &fw.wlan.ba_cache[fw.wlan.ba_tail_idx];
579 fw.wlan.ba_tail_idx++;
580 fw.wlan.ba_tail_idx %= CONFIG_CARL9170FW_BACK_REQS_NUM;
581 if (fw.wlan.queued_ba < CONFIG_CARL9170FW_BACK_REQS_NUM)
587 static void handle_bar(struct dma_desc *desc __unused, struct ieee80211_hdr *hdr,
588 unsigned int len, unsigned int mac_err)
590 struct ieee80211_bar *bar;
591 struct carl9170_bar_ctx *ctx;
593 if (unlikely(mac_err)) {
595 * This check does a number of things:
596 * 1. checks if the frame is in good nick
597 * 2. checks if the RA (MAC) matches
602 if (unlikely(len < (sizeof(struct ieee80211_bar) + FCS_LEN))) {
604 * Sneaky, corrupted BARs... but not with us!
612 if ((bar->control & cpu_to_le16(IEEE80211_BAR_CTRL_MULTI_TID)) ||
613 !(bar->control & cpu_to_le16(IEEE80211_BAR_CTRL_CBMTID_COMPRESSED_BA))) {
614 /* not implemented yet */
619 ctx = wlan_get_bar_cache_buffer();
621 /* Brilliant! The BAR provides all necessary MACs! */
622 memcpy(ctx->ra, bar->ta, 6);
623 memcpy(ctx->ta, bar->ra, 6);
624 ctx->control = bar->control;
625 ctx->start_seq_num = bar->start_seq_num;
628 static void wlan_check_rx_overrun(void)
630 uint32_t overruns, total;
632 fw.tally.rx_total += total = get(AR9170_MAC_REG_RX_TOTAL);
633 fw.tally.rx_overrun += overruns = get(AR9170_MAC_REG_RX_OVERRUN);
634 if (unlikely(overruns)) {
635 if (overruns == total) {
640 wlan_trigger(AR9170_DMA_TRIGGER_RXQ);
644 static unsigned int wlan_rx_filter(struct dma_desc *desc)
646 struct ieee80211_hdr *hdr;
647 unsigned int data_len;
648 unsigned int rx_filter;
649 unsigned int mac_err;
651 data_len = ar9170_get_rx_mpdu_len(desc);
652 mac_err = ar9170_get_rx_macstatus_error(desc);
654 #define AR9170_RX_ERROR_BAD (AR9170_RX_ERROR_FCS | AR9170_RX_ERROR_PLCP)
656 if (unlikely(data_len < (4 + 6 + FCS_LEN) ||
657 desc->totalLen > CONFIG_CARL9170FW_RX_FRAME_LEN) ||
658 mac_err & AR9170_RX_ERROR_BAD) {
660 * This frame is too damaged to do anything
664 return CARL9170_RX_FILTER_BAD;
668 if (mac_err & AR9170_RX_ERROR_WRONG_RA)
669 rx_filter |= CARL9170_RX_FILTER_OTHER_RA;
671 if (mac_err & AR9170_RX_ERROR_DECRYPT)
672 rx_filter |= CARL9170_RX_FILTER_DECRY_FAIL;
674 hdr = ar9170_get_rx_i3e(desc);
675 if (likely(ieee80211_is_data(hdr->frame_control))) {
676 rx_filter |= CARL9170_RX_FILTER_DATA;
677 } else if (ieee80211_is_ctl(hdr->frame_control)) {
678 switch (le16_to_cpu(hdr->frame_control) & IEEE80211_FCTL_STYPE) {
679 case IEEE80211_STYPE_BACK_REQ:
680 handle_bar(desc, hdr, data_len, mac_err);
682 rx_filter |= CARL9170_RX_FILTER_CTL_BACKR;
684 case IEEE80211_STYPE_PSPOLL:
685 rx_filter |= CARL9170_RX_FILTER_CTL_PSPOLL;
688 rx_filter |= CARL9170_RX_FILTER_CTL_OTHER;
692 /* ieee80211_is_mgmt */
693 rx_filter |= CARL9170_RX_FILTER_MGMT;
696 if (unlikely(fw.suspend_mode == CARL9170_HOST_SUSPENDED)) {
697 wol_rx(rx_filter, hdr, min(data_len,
698 (unsigned int)AR9170_BLOCK_SIZE));
701 #undef AR9170_RX_ERROR_BAD
706 static void handle_rx(void)
708 struct dma_desc *desc;
710 for_each_desc_not_bits(desc, &fw.wlan.rx_queue, AR9170_OWN_BITS_HW) {
711 if (!(wlan_rx_filter(desc) & fw.wlan.rx_filter)) {
712 dma_put(&fw.pta.up_queue, desc);
715 dma_reclaim(&fw.wlan.rx_queue, desc);
716 wlan_trigger(AR9170_DMA_TRIGGER_RXQ);
721 #ifdef CONFIG_CARL9170FW_CAB_QUEUE
722 void wlan_cab_flush_queue(const unsigned int vif)
724 struct dma_queue *cab_queue = &fw.wlan.cab_queue[vif];
725 struct dma_desc *desc;
727 /* move queued frames into the main tx queues */
728 for_each_desc(desc, cab_queue) {
729 struct carl9170_tx_superframe *super = get_super(desc);
730 if (!queue_empty(cab_queue)) {
732 * Set MOREDATA flag for all,
733 * but the last queued frame.
734 * see: 802.11-2007 11.2.1.5 f)
736 * This is actually the reason to why
737 * we need to prevent the reentry.
740 super->f.data.i3e.frame_control |=
741 cpu_to_le16(IEEE80211_FCTL_MOREDATA);
743 super->f.data.i3e.frame_control &=
744 cpu_to_le16(~IEEE80211_FCTL_MOREDATA);
750 wlan_trigger(BIT(super->s.queue));
754 static uint8_t *beacon_find_ie(uint8_t ie, void *addr,
755 const unsigned int len)
757 struct ieee80211_mgmt *mgmt = addr;
760 pos = mgmt->u.beacon.variable;
761 end = (uint8_t *) ((unsigned long)mgmt + (len - FCS_LEN));
763 if (pos + 2 + pos[1] > end)
775 void wlan_modify_beacon(const unsigned int vif,
776 const unsigned int addr, const unsigned int len)
779 struct ieee80211_tim_ie *ie;
781 _ie = beacon_find_ie(WLAN_EID_TIM, (void *)addr, len);
783 ie = (struct ieee80211_tim_ie *) &_ie[2];
785 if (!queue_empty(&fw.wlan.cab_queue[vif]) && (ie->dtim_count == 0)) {
786 /* schedule DTIM transfer */
787 fw.wlan.cab_flush_trigger[vif] = CARL9170_CAB_TRIGGER_ARMED;
788 } else if ((fw.wlan.cab_queue_len[vif] == 0) && (fw.wlan.cab_flush_trigger[vif])) {
789 /* undo all chances to the beacon structure */
790 ie->bitmap_ctrl &= ~0x1;
791 fw.wlan.cab_flush_trigger[vif] = CARL9170_CAB_TRIGGER_EMPTY;
794 /* Triggered by CARL9170_CAB_TRIGGER_ARMED || CARL9170_CAB_TRIGGER_DEFER */
795 if (fw.wlan.cab_flush_trigger[vif]) {
796 /* Set the almighty Multicast Traffic Indication Bit. */
797 ie->bitmap_ctrl |= 0x1;
802 * Ideally, the sequence number should be assigned by the TX arbiter
803 * hardware. But AFAIK that's not possible, so we have to go for the
804 * next best thing and write it into the beacon fifo during the open
805 * beacon update window.
808 wlan_assign_seq((struct ieee80211_hdr *)addr, vif);
811 static void wlan_send_buffered_cab(void)
815 for (i = 0; i < CARL9170_INTF_NUM; i++) {
816 if (unlikely(fw.wlan.cab_flush_trigger[i] == CARL9170_CAB_TRIGGER_ARMED)) {
818 * This is hardcoded into carl9170usb driver.
820 * The driver must set the PRETBTT event to beacon_interval -
821 * CARL9170_PRETBTT_KUS (usually 6) Kus.
823 * But still, we can only do so much about 802.11-2007 9.3.2.1 &
824 * 11.2.1.6. Let's hope the current solution is adequate enough.
827 if (is_after_msecs(fw.wlan.cab_flush_time, (CARL9170_TBTT_DELTA))) {
828 wlan_cab_flush_queue(i);
831 * This prevents the code from sending new BC/MC frames
832 * which were queued after the previous buffered traffic
833 * has been sent out... They will have to wait until the
834 * next DTIM beacon comes along.
836 fw.wlan.cab_flush_trigger[i] = CARL9170_CAB_TRIGGER_DEFER;
842 #endif /* CONFIG_CARL9170FW_CAB_QUEUE */
844 static void handle_beacon_config(void)
848 bcn_count = get(AR9170_MAC_REG_BCN_COUNT);
849 send_cmd_to_host(4, CARL9170_RSP_BEACON_CONFIG, 0x00,
850 (uint8_t *) &bcn_count);
853 static void handle_pretbtt(void)
855 #ifdef CONFIG_CARL9170FW_CAB_QUEUE
856 fw.wlan.cab_flush_time = get_clock_counter();
857 #endif /* CONFIG_CARL9170FW_CAB_QUEUE */
859 #ifdef CONFIG_CARL9170FW_RADIO_FUNCTIONS
862 send_cmd_to_host(4, CARL9170_RSP_PRETBTT, 0x00,
863 (uint8_t *) &fw.phy.psm.state);
864 #endif /* CONFIG_CARL9170FW_RADIO_FUNCTIONS */
867 static void handle_atim(void)
869 send_cmd_to_host(0, CARL9170_RSP_ATIM, 0x00, NULL);
872 #ifdef CONFIG_CARL9170FW_DEBUG
873 static void handle_qos(void)
876 * What is the QoS Bit used for?
877 * Is it only an indicator for TXOP & Burst, or
878 * should we do something here?
882 static void handle_radar(void)
884 send_cmd_to_host(0, CARL9170_RSP_RADAR, 0x00, NULL);
886 #endif /* CONFIG_CARL9170FW_DEBUG */
888 static void wlan_janitor(void)
890 #ifdef CONFIG_CARL9170FW_CAB_QUEUE
891 wlan_send_buffered_cab();
892 #endif /* CONFIG_CARL9170FW_CAB_QUEUE */
894 wlan_send_buffered_tx_status();
896 wlan_send_buffered_ba();
901 void handle_wlan(void)
905 intr = get(AR9170_MAC_REG_INT_CTRL);
907 set(AR9170_MAC_REG_INT_CTRL, intr);
909 #define HANDLER(intr, flag, func) \
911 if ((intr & flag) != 0) { \
916 intr |= fw.wlan.soft_int;
917 fw.wlan.soft_int = 0;
919 HANDLER(intr, AR9170_MAC_INT_PRETBTT, handle_pretbtt);
921 HANDLER(intr, AR9170_MAC_INT_ATIM, handle_atim);
923 HANDLER(intr, AR9170_MAC_INT_RXC, handle_rx);
925 HANDLER(intr, (AR9170_MAC_INT_TXC | AR9170_MAC_INT_RETRY_FAIL),
926 handle_tx_completion);
928 #ifdef CONFIG_CARL9170FW_DEBUG
929 HANDLER(intr, AR9170_MAC_INT_QOS, handle_qos);
931 HANDLER(intr, AR9170_MAC_INT_RADAR, handle_radar);
932 #endif /* CONFIG_CARL9170FW_DEBUG */
934 HANDLER(intr, AR9170_MAC_INT_CFG_BCN, handle_beacon_config);
937 DBG("Unhandled Interrupt %x\n", (unsigned int) intr);
945 CARL9170FW_TX_MAC_BUMP = 4,
946 CARL9170FW_TX_MAC_DEBUG = 6,
947 CARL9170FW_TX_MAC_RESET = 7,
950 static void wlan_check_hang(void)
952 struct dma_desc *desc;
955 for (i = AR9170_TXQ_SPECIAL; i >= AR9170_TXQ0; i--) {
956 if (queue_empty(&fw.wlan.tx_queue[i])) {
957 /* Nothing to do here... move along */
961 /* fetch the current DMA queue position */
962 desc = (struct dma_desc *)get_wlan_txq_addr(i);
964 /* Stuck frame detection */
965 if (unlikely(DESC_PAYLOAD(desc) == fw.wlan.last_super[i])) {
966 fw.wlan.last_super_num[i]++;
968 if (unlikely(fw.wlan.last_super_num[i] >= CARL9170FW_TX_MAC_RESET)) {
970 * schedule MAC reset (aka OFF/ON => dead)
972 * This will almost certainly kill
973 * the device for good, but it's the
974 * recommended thing to do...
980 #ifdef CONFIG_CARL9170FW_DEBUG
981 if (unlikely(fw.wlan.last_super_num[i] >= CARL9170FW_TX_MAC_DEBUG)) {
983 * Sigh, the queue is almost certainly
984 * dead. Dump the queue content to the
985 * user, maybe we find out why it got
991 #endif /* CONFIG_CARL9170FW_DEBUG */
993 #ifdef CONFIG_CARL9170FW_DMA_QUEUE_BUMP
994 if (unlikely(fw.wlan.last_super_num[i] >= CARL9170FW_TX_MAC_BUMP)) {
996 * Hrrm, bump the queue a bit.
997 * maybe this will get it going again.
1001 wlan_trigger(BIT(i));
1003 #endif /* CONFIG_CARL9170FW_DMA_QUEUE_BUMP */
1006 fw.wlan.last_super[i] = DESC_PAYLOAD(desc);
1007 fw.wlan.last_super_num[i] = 0;
1012 #ifdef CONFIG_CARL9170FW_FW_MAC_RESET
1014 * NB: Resetting the MAC is a two-edged sword.
1015 * On most occasions, it does what it is supposed to do.
1016 * But there is a chance that this will make it
1017 * even worse and the radio dies silently.
1019 static void wlan_mac_reset(void)
1022 uint32_t agg_wait_counter;
1023 uint32_t agg_density;
1024 uint32_t bcn_start_addr;
1025 uint32_t rctl, rcth;
1028 uint32_t rts_cts_tpc;
1029 uint32_t rts_cts_rate;
1032 #ifdef CONFIG_CARL9170FW_RADIO_FUNCTIONS
1034 #endif /* CONFIG_CARL9170FW_RADIO_FUNCTIONS */
1036 #ifdef CONFIG_CARL9170FW_NOISY_MAC_RESET
1038 #endif /* CONFIG_CARL9170FW_NOISY_MAC_RESET */
1040 /* Save aggregation parameters */
1041 agg_wait_counter = get(AR9170_MAC_REG_AMPDU_FACTOR);
1042 agg_density = get(AR9170_MAC_REG_AMPDU_DENSITY);
1044 bcn_start_addr = get(AR9170_MAC_REG_BCN_ADDR);
1046 cam_mode = get(AR9170_MAC_REG_CAM_MODE);
1047 rctl = get(AR9170_MAC_REG_CAM_ROLL_CALL_TBL_L);
1048 rcth = get(AR9170_MAC_REG_CAM_ROLL_CALL_TBL_H);
1050 ack_power = get(AR9170_MAC_REG_ACK_TPC);
1051 rts_cts_tpc = get(AR9170_MAC_REG_RTS_CTS_TPC);
1052 rts_cts_rate = get(AR9170_MAC_REG_RTS_CTS_RATE);
1054 #ifdef CONFIG_CARL9170FW_RADIO_FUNCTIONS
1055 /* 0x1c8960 write only */
1056 rx_BB = get(AR9170_PHY_REG_SWITCH_CHAIN_0);
1057 #endif /* CONFIG_CARL9170FW_RADIO_FUNCTIONS */
1059 /* TX/RX must be stopped by now */
1060 val = get(AR9170_MAC_REG_POWER_STATE_CTRL);
1062 val |= AR9170_MAC_POWER_STATE_CTRL_RESET;
1065 * Manipulate CCA threshold to stop transmission
1067 * set(AR9170_PHY_REG_CCA_THRESHOLD, 0x300);
1071 * check Rx state in 0(idle) 9(disable)
1073 * chState = (get(AR9170_MAC_REG_MISC_684) >> 16) & 0xf;
1074 * while( (chState != 0) && (chState != 9)) {
1075 * chState = (get(AR9170_MAC_REG_MISC_684) >> 16) & 0xf;
1079 set(AR9170_MAC_REG_POWER_STATE_CTRL, val);
1083 /* Restore aggregation parameters */
1084 set(AR9170_MAC_REG_AMPDU_FACTOR, agg_wait_counter);
1085 set(AR9170_MAC_REG_AMPDU_DENSITY, agg_density);
1087 set(AR9170_MAC_REG_BCN_ADDR, bcn_start_addr);
1088 set(AR9170_MAC_REG_CAM_MODE, cam_mode);
1089 set(AR9170_MAC_REG_CAM_ROLL_CALL_TBL_L, rctl);
1090 set(AR9170_MAC_REG_CAM_ROLL_CALL_TBL_H, rcth);
1092 set(AR9170_MAC_REG_RTS_CTS_TPC, rts_cts_tpc);
1093 set(AR9170_MAC_REG_ACK_TPC, ack_power);
1094 set(AR9170_MAC_REG_RTS_CTS_RATE, rts_cts_rate);
1096 #ifdef CONFIG_CARL9170FW_RADIO_FUNCTIONS
1097 set(AR9170_PHY_REG_SWITCH_CHAIN_2, rx_BB);
1098 #endif /* CONFIG_CARL9170FW_RADIO_FUNCTIONS */
1101 * Manipulate CCA threshold to resume transmission
1103 * set(AR9170_PHY_REG_CCA_THRESHOLD, 0x0);
1106 val = AR9170_DMA_TRIGGER_RXQ;
1107 /* Reinitialize all WLAN TX DMA queues. */
1108 for (i = AR9170_TXQ_SPECIAL; i >= AR9170_TXQ0; i--) {
1109 struct dma_desc *iter;
1111 __for_each_desc_bits(iter, &fw.wlan.tx_queue[i], AR9170_OWN_BITS_SW);
1113 /* kill the stuck frame */
1114 if (!is_terminator(&fw.wlan.tx_queue[i], iter) &&
1115 fw.wlan.last_super_num[i] >= CARL9170FW_TX_MAC_RESET &&
1116 fw.wlan.last_super[i] == DESC_PAYLOAD(iter)) {
1117 struct carl9170_tx_superframe *super = get_super(iter);
1119 iter->status = AR9170_OWN_BITS_SW;
1121 * Mark the frame as failed.
1122 * The BAFAIL flag allows the frame to sail through
1123 * wlan_tx_status without much "unstuck" trouble.
1125 iter->ctrl &= ~(AR9170_CTRL_FAIL);
1126 iter->ctrl |= AR9170_CTRL_BAFAIL;
1128 super->s.cnt = CARL9170_TX_MAX_RATE_TRIES;
1129 super->s.rix = CARL9170_TX_MAX_RETRY_RATES;
1131 fw.wlan.last_super_num[i] = 0;
1132 fw.wlan.last_super[i] = NULL;
1133 iter = iter->lastAddr->nextAddr;
1136 set_wlan_txq_dma_addr(i, (uint32_t) iter);
1137 if (!is_terminator(&fw.wlan.tx_queue[i], iter))
1140 DBG("Q:%d l:%d h:%p t:%p cu:%p it:%p ct:%x st:%x\n", i, queue_len(&fw.wlan.tx_queue[i]),
1141 fw.wlan.tx_queue[i].head, fw.wlan.tx_queue[i].terminator,
1142 get_wlan_txq_addr(i), iter, iter->ctrl, iter->status);
1145 fw.wlan.soft_int |= AR9170_MAC_INT_RXC | AR9170_MAC_INT_TXC |
1146 AR9170_MAC_INT_RETRY_FAIL;
1148 set(AR9170_MAC_REG_DMA_RXQ_ADDR, (uint32_t) fw.wlan.rx_queue.head);
1152 static void wlan_mac_reset(void)
1154 /* The driver takes care of reinitializing the device */
1157 #endif /* CONFIG_CARL9170FW_FW_MAC_RESET */
1159 void __cold wlan_timer(void)
1161 unsigned int cached_mac_reset;
1163 cached_mac_reset = fw.wlan.mac_reset;
1165 /* TX Queue Hang check */
1168 /* RX Overrun check */
1169 wlan_check_rx_overrun();
1171 if (unlikely(fw.wlan.mac_reset >= CARL9170_MAC_RESET_RESET)) {
1173 fw.wlan.mac_reset = CARL9170_MAC_RESET_OFF;
1175 if (fw.wlan.mac_reset && cached_mac_reset == fw.wlan.mac_reset)
1176 fw.wlan.mac_reset--;