hal_btcoex.c source code [linux/drivers/staging/rtl8723bs/hal/hal_btcoex.c]

1	// SPDX-License-Identifier: GPL-2.0
2	/******************************************************************************
3	*
4	* Copyright(c) 2013 Realtek Corporation. All rights reserved.
5	*
6	******************************************************************************/
7
8	#include <hal_data.h>
9	#include <rtw_debug.h>
10	#include <hal_btcoex.h>
11	#include <Mp_Precomp.h>
12
13	/ Global variables /
14
15	struct btc_coexist GLBtCoexist;
16	static u8 GLBtcWiFiInScanState;
17	static u8 GLBtcWiFiInIQKState;
18
19	/ /
20	/ Debug related function /
21	/ /
22	static u8 halbtcoutsrc_IsBtCoexistAvailable(struct btc_coexist *pBtCoexist)
23	{
24	if (!pBtCoexist->bBinded \|\| !pBtCoexist->Adapter)
25	return false;
26
27	return true;
28	}
29
30	static void halbtcoutsrc_LeaveLps(struct btc_coexist *pBtCoexist)
31	{
32	struct adapter *padapter;
33
34
35	padapter = pBtCoexist->Adapter;
36
37	pBtCoexist->btInfo.bBtCtrlLps = true;
38	pBtCoexist->btInfo.bBtLpsOn = false;
39
40	rtw_btcoex_LPS_Leave(padapter);
41	}
42
43	static void halbtcoutsrc_EnterLps(struct btc_coexist *pBtCoexist)
44	{
45	struct adapter *padapter;
46
47
48	padapter = pBtCoexist->Adapter;
49
50	pBtCoexist->btInfo.bBtCtrlLps = true;
51	pBtCoexist->btInfo.bBtLpsOn = true;
52
53	rtw_btcoex_LPS_Enter(padapter);
54	}
55
56	static void halbtcoutsrc_NormalLps(struct btc_coexist *pBtCoexist)
57	{
58	struct adapter *padapter;
59
60	padapter = pBtCoexist->Adapter;
61
62	if (pBtCoexist->btInfo.bBtCtrlLps) {
63	pBtCoexist->btInfo.bBtLpsOn = false;
64	rtw_btcoex_LPS_Leave(padapter);
65	pBtCoexist->btInfo.bBtCtrlLps = false;
66
67	/ recover the LPS state to the original /
68	}
69	}
70
71	/*
72	* Constraint:
73	* 1. this function will request pwrctrl->lock
74	*/
75	static void halbtcoutsrc_LeaveLowPower(struct btc_coexist *pBtCoexist)
76	{
77	struct adapter *padapter;
78	s32 ready;
79	unsigned long stime;
80	unsigned long utime;
81	u32 timeout; / unit: ms /
82
83
84	padapter = pBtCoexist->Adapter;
85	ready = _FAIL;
86	#ifdef LPS_RPWM_WAIT_MS
87	timeout = LPS_RPWM_WAIT_MS;
88	#else /* !LPS_RPWM_WAIT_MS */
89	timeout = `30`;
90	#endif /* !LPS_RPWM_WAIT_MS */
91
92	stime = jiffies;
93	do {
94	ready = rtw_register_task_alive(padapter, BTCOEX_ALIVE);
95	if (_SUCCESS == ready)
96	break;
97
98	utime = jiffies_to_msecs(j: jiffies - stime);
99	if (utime > timeout)
100	break;
101
102	msleep(msecs: `1`);
103	} while (`1`);
104	}
105
106	/*
107	* Constraint:
108	* 1. this function will request pwrctrl->lock
109	*/
110	static void halbtcoutsrc_NormalLowPower(struct btc_coexist *pBtCoexist)
111	{
112	struct adapter *padapter;
113
114
115	padapter = pBtCoexist->Adapter;
116	rtw_unregister_task_alive(padapter, BTCOEX_ALIVE);
117	}
118
119	static void halbtcoutsrc_DisableLowPower(struct btc_coexist *pBtCoexist, u8 bLowPwrDisable)
120	{
121	pBtCoexist->btInfo.bBtDisableLowPwr = bLowPwrDisable;
122	if (bLowPwrDisable)
123	halbtcoutsrc_LeaveLowPower(pBtCoexist); / leave 32k low power. /
124	else
125	halbtcoutsrc_NormalLowPower(pBtCoexist); / original 32k low power behavior. /
126	}
127
128	static void halbtcoutsrc_AggregationCheck(struct btc_coexist *pBtCoexist)
129	{
130	struct adapter *padapter;
131	bool bNeedToAct;
132
133
134	padapter = pBtCoexist->Adapter;
135	bNeedToAct = false;
136
137	if (pBtCoexist->btInfo.bRejectAggPkt) {
138	rtw_btcoex_RejectApAggregatedPacket(padapter, enable: true);
139	} else {
140	if (pBtCoexist->btInfo.bPreBtCtrlAggBufSize !=
141	pBtCoexist->btInfo.bBtCtrlAggBufSize) {
142	bNeedToAct = true;
143	pBtCoexist->btInfo.bPreBtCtrlAggBufSize = pBtCoexist->btInfo.bBtCtrlAggBufSize;
144	}
145
146	if (pBtCoexist->btInfo.bBtCtrlAggBufSize) {
147	if (pBtCoexist->btInfo.preAggBufSize !=
148	pBtCoexist->btInfo.aggBufSize){
149	bNeedToAct = true;
150	}
151	pBtCoexist->btInfo.preAggBufSize = pBtCoexist->btInfo.aggBufSize;
152	}
153
154	if (bNeedToAct) {
155	rtw_btcoex_RejectApAggregatedPacket(padapter, enable: true);
156	rtw_btcoex_RejectApAggregatedPacket(padapter, enable: false);
157	}
158	}
159	}
160
161	static u8 halbtcoutsrc_IsWifiBusy(struct adapter *padapter)
162	{
163	struct mlme_priv *pmlmepriv;
164
165
166	pmlmepriv = &padapter->mlmepriv;
167
168	if (check_fwstate(pmlmepriv, WIFI_ASOC_STATE) == true) {
169	if (check_fwstate(pmlmepriv, WIFI_AP_STATE) == true)
170	return true;
171	if (pmlmepriv->LinkDetectInfo.bBusyTraffic)
172	return true;
173	}
174
175	return false;
176	}
177
178	static u32 _halbtcoutsrc_GetWifiLinkStatus(struct adapter *padapter)
179	{
180	struct mlme_priv *pmlmepriv;
181	u8 bp2p;
182	u32 portConnectedStatus;
183
184
185	pmlmepriv = &padapter->mlmepriv;
186	bp2p = false;
187	portConnectedStatus = `0`;
188
189	if (check_fwstate(pmlmepriv, WIFI_ASOC_STATE) == true) {
190	if (check_fwstate(pmlmepriv, WIFI_AP_STATE) == true) {
191	if (bp2p)
192	portConnectedStatus \|= WIFI_P2P_GO_CONNECTED;
193	else
194	portConnectedStatus \|= WIFI_AP_CONNECTED;
195	} else {
196	if (bp2p)
197	portConnectedStatus \|= WIFI_P2P_GC_CONNECTED;
198	else
199	portConnectedStatus \|= WIFI_STA_CONNECTED;
200	}
201	}
202
203	return portConnectedStatus;
204	}
205
206	static u32 halbtcoutsrc_GetWifiLinkStatus(struct btc_coexist *pBtCoexist)
207	{
208	/ /
209	/ return value: /
210	/ [31:16]=> connected port number /
211	/ [15:0]=> port connected bit define /
212	/ /
213
214	struct adapter *padapter;
215	u32 retVal;
216	u32 portConnectedStatus, numOfConnectedPort;
217
218
219	padapter = pBtCoexist->Adapter;
220	portConnectedStatus = `0`;
221	numOfConnectedPort = `0`;
222
223	retVal = _halbtcoutsrc_GetWifiLinkStatus(padapter);
224	if (retVal) {
225	portConnectedStatus \|= retVal;
226	numOfConnectedPort++;
227	}
228
229	retVal = (numOfConnectedPort << `16`) \| portConnectedStatus;
230
231	return retVal;
232	}
233
234	static u32 halbtcoutsrc_GetBtPatchVer(struct btc_coexist *pBtCoexist)
235	{
236	return pBtCoexist->btInfo.btRealFwVer;
237	}
238
239	static s32 halbtcoutsrc_GetWifiRssi(struct adapter *padapter)
240	{
241	struct hal_com_data *pHalData = GET_HAL_DATA(padapter);
242
243	return pHalData->dmpriv.EntryMinUndecoratedSmoothedPWDB;
244	}
245
246	static u8 halbtcoutsrc_GetWifiScanAPNum(struct adapter *padapter)
247	{
248	struct mlme_ext_priv *pmlmeext;
249	static u8 scan_AP_num;
250
251	pmlmeext = &padapter->mlmeextpriv;
252
253	if (!GLBtcWiFiInScanState) {
254	if (pmlmeext->sitesurvey_res.bss_cnt > `0xFF`)
255	scan_AP_num = `0xFF`;
256	else
257	scan_AP_num = (u8)pmlmeext->sitesurvey_res.bss_cnt;
258	}
259
260	return scan_AP_num;
261	}
262
263	static u8 halbtcoutsrc_Get(void pBtcContext, u8 getType, void* *pOutBuf)
264	{
265	struct btc_coexist *pBtCoexist;
266	struct adapter *padapter;
267	struct hal_com_data *pHalData;
268	struct mlme_ext_priv *mlmeext;
269	u8 *pu8;
270	s32 *pS4Tmp;
271	u32 *pU4Tmp;
272	u8 ret;
273
274
275	pBtCoexist = (struct btc_coexist *)pBtcContext;
276	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
277	return false;
278
279	padapter = pBtCoexist->Adapter;
280	pHalData = GET_HAL_DATA(padapter);
281	mlmeext = &padapter->mlmeextpriv;
282	pu8 = pOutBuf;
283	pS4Tmp = pOutBuf;
284	pU4Tmp = pOutBuf;
285	ret = true;
286
287	switch (getType) {
288	case BTC_GET_BL_HS_OPERATION:
289	*pu8 = false;
290	ret = false;
291	break;
292
293	case BTC_GET_BL_HS_CONNECTING:
294	*pu8 = false;
295	ret = false;
296	break;
297
298	case BTC_GET_BL_WIFI_CONNECTED:
299	*pu8 = check_fwstate(pmlmepriv: &padapter->mlmepriv, WIFI_ASOC_STATE);
300	break;
301
302	case BTC_GET_BL_WIFI_BUSY:
303	*pu8 = halbtcoutsrc_IsWifiBusy(padapter);
304	break;
305
306	case BTC_GET_BL_WIFI_SCAN:
307	/ Use the value of the new variable GLBtcWiFiInScanState to judge whether WiFi is in scan state or not, since the originally used flag*
308	WIFI_SITE_MONITOR in fwstate may not be cleared in time /*
309	*pu8 = GLBtcWiFiInScanState;
310	break;
311
312	case BTC_GET_BL_WIFI_LINK:
313	*pu8 = check_fwstate(pmlmepriv: &padapter->mlmepriv, WIFI_UNDER_LINKING);
314	break;
315
316	case BTC_GET_BL_WIFI_ROAM:
317	*pu8 = check_fwstate(pmlmepriv: &padapter->mlmepriv, WIFI_UNDER_LINKING);
318	break;
319
320	case BTC_GET_BL_WIFI_4_WAY_PROGRESS:
321	*pu8 = false;
322	break;
323
324	case BTC_GET_BL_WIFI_AP_MODE_ENABLE:
325	*pu8 = check_fwstate(pmlmepriv: &padapter->mlmepriv, WIFI_AP_STATE);
326	break;
327
328	case BTC_GET_BL_WIFI_ENABLE_ENCRYPTION:
329	*pu8 = padapter->securitypriv.dot11PrivacyAlgrthm != `0`;
330	break;
331
332	case BTC_GET_BL_WIFI_UNDER_B_MODE:
333	if (mlmeext->cur_wireless_mode == WIRELESS_11B)
334	*pu8 = true;
335	else
336	*pu8 = false;
337	break;
338
339	case BTC_GET_BL_WIFI_IS_IN_MP_MODE:
340	*pu8 = false;
341	break;
342
343	case BTC_GET_BL_EXT_SWITCH:
344	*pu8 = false;
345	break;
346
347	case BTC_GET_S4_WIFI_RSSI:
348	*pS4Tmp = halbtcoutsrc_GetWifiRssi(padapter);
349	break;
350
351	case BTC_GET_S4_HS_RSSI:
352	*pS4Tmp = `0`;
353	ret = false;
354	break;
355
356	case BTC_GET_U4_WIFI_BW:
357	if (is_legacy_only(mlmeext->cur_wireless_mode))
358	*pU4Tmp = BTC_WIFI_BW_LEGACY;
359	else if (pHalData->CurrentChannelBW == CHANNEL_WIDTH_20)
360	*pU4Tmp = BTC_WIFI_BW_HT20;
361	else
362	*pU4Tmp = BTC_WIFI_BW_HT40;
363	break;
364
365	case BTC_GET_U4_WIFI_TRAFFIC_DIRECTION:
366	{
367	struct rt_link_detect_t *plinkinfo;
368	plinkinfo = &padapter->mlmepriv.LinkDetectInfo;
369
370	if (plinkinfo->NumTxOkInPeriod > plinkinfo->NumRxOkInPeriod)
371	*pU4Tmp = BTC_WIFI_TRAFFIC_TX;
372	else
373	*pU4Tmp = BTC_WIFI_TRAFFIC_RX;
374	}
375	break;
376
377	case BTC_GET_U4_WIFI_FW_VER:
378	*pU4Tmp = pHalData->FirmwareVersion << `16`;
379	*pU4Tmp \|= pHalData->FirmwareSubVersion;
380	break;
381
382	case BTC_GET_U4_WIFI_LINK_STATUS:
383	*pU4Tmp = halbtcoutsrc_GetWifiLinkStatus(pBtCoexist);
384	break;
385
386	case BTC_GET_U4_BT_PATCH_VER:
387	*pU4Tmp = halbtcoutsrc_GetBtPatchVer(pBtCoexist);
388	break;
389
390	case BTC_GET_U1_WIFI_DOT11_CHNL:
391	*pu8 = padapter->mlmeextpriv.cur_channel;
392	break;
393
394	case BTC_GET_U1_WIFI_CENTRAL_CHNL:
395	*pu8 = pHalData->CurrentChannel;
396	break;
397
398	case BTC_GET_U1_WIFI_HS_CHNL:
399	*pu8 = `0`;
400	ret = false;
401	break;
402
403	case BTC_GET_U1_MAC_PHY_MODE:
404	*pu8 = BTC_SMSP;
405	/ pU1Tmp = BTC_DMSP; /*
406	/ pU1Tmp = BTC_DMDP; /*
407	/ pU1Tmp = BTC_MP_UNKNOWN; /*
408	break;
409
410	case BTC_GET_U1_AP_NUM:
411	*pu8 = halbtcoutsrc_GetWifiScanAPNum(padapter);
412	break;
413
414	/ 1Ant =========== /
415	case BTC_GET_U1_LPS_MODE:
416	*pu8 = padapter->dvobj->pwrctl_priv.pwr_mode;
417	break;
418
419	default:
420	ret = false;
421	break;
422	}
423
424	return ret;
425	}
426
427	static u8 halbtcoutsrc_Set(void pBtcContext, u8 setType, void* *pInBuf)
428	{
429	struct btc_coexist *pBtCoexist;
430	struct adapter *padapter;
431	u8 *pu8;
432	u32 *pU4Tmp;
433	u8 ret;
434
435
436	pBtCoexist = (struct btc_coexist *)pBtcContext;
437	padapter = pBtCoexist->Adapter;
438	pu8 = pInBuf;
439	pU4Tmp = pInBuf;
440	ret = true;
441
442	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
443	return false;
444
445	switch (setType) {
446	/ set some u8 type variables. /
447	case BTC_SET_BL_BT_DISABLE:
448	pBtCoexist->btInfo.bBtDisabled = *pu8;
449	break;
450
451	case BTC_SET_BL_BT_TRAFFIC_BUSY:
452	pBtCoexist->btInfo.bBtBusy = *pu8;
453	break;
454
455	case BTC_SET_BL_BT_LIMITED_DIG:
456	pBtCoexist->btInfo.bLimitedDig = *pu8;
457	break;
458
459	case BTC_SET_BL_FORCE_TO_ROAM:
460	pBtCoexist->btInfo.bForceToRoam = *pu8;
461	break;
462
463	case BTC_SET_BL_TO_REJ_AP_AGG_PKT:
464	pBtCoexist->btInfo.bRejectAggPkt = *pu8;
465	break;
466
467	case BTC_SET_BL_BT_CTRL_AGG_SIZE:
468	pBtCoexist->btInfo.bBtCtrlAggBufSize = *pu8;
469	break;
470
471	case BTC_SET_BL_INC_SCAN_DEV_NUM:
472	pBtCoexist->btInfo.bIncreaseScanDevNum = *pu8;
473	break;
474
475	case BTC_SET_BL_BT_TX_RX_MASK:
476	pBtCoexist->btInfo.bBtTxRxMask = *pu8;
477	break;
478
479	/ set some u8 type variables. /
480	case BTC_SET_U1_RSSI_ADJ_VAL_FOR_AGC_TABLE_ON:
481	pBtCoexist->btInfo.rssiAdjustForAgcTableOn = *pu8;
482	break;
483
484	case BTC_SET_U1_AGG_BUF_SIZE:
485	pBtCoexist->btInfo.aggBufSize = *pu8;
486	break;
487
488	/ the following are some action which will be triggered /
489	case BTC_SET_ACT_GET_BT_RSSI:
490	ret = false;
491	break;
492
493	case BTC_SET_ACT_AGGREGATE_CTRL:
494	halbtcoutsrc_AggregationCheck(pBtCoexist);
495	break;
496
497	/ 1Ant =========== /
498	/ set some u8 type variables. /
499	case BTC_SET_U1_RSSI_ADJ_VAL_FOR_1ANT_COEX_TYPE:
500	pBtCoexist->btInfo.rssiAdjustFor1AntCoexType = *pu8;
501	break;
502
503	case BTC_SET_U1_LPS_VAL:
504	pBtCoexist->btInfo.lpsVal = *pu8;
505	break;
506
507	case BTC_SET_U1_RPWM_VAL:
508	pBtCoexist->btInfo.rpwmVal = *pu8;
509	break;
510
511	/ the following are some action which will be triggered /
512	case BTC_SET_ACT_LEAVE_LPS:
513	halbtcoutsrc_LeaveLps(pBtCoexist);
514	break;
515
516	case BTC_SET_ACT_ENTER_LPS:
517	halbtcoutsrc_EnterLps(pBtCoexist);
518	break;
519
520	case BTC_SET_ACT_NORMAL_LPS:
521	halbtcoutsrc_NormalLps(pBtCoexist);
522	break;
523
524	case BTC_SET_ACT_DISABLE_LOW_POWER:
525	halbtcoutsrc_DisableLowPower(pBtCoexist, bLowPwrDisable: *pu8);
526	break;
527
528	case BTC_SET_ACT_UPDATE_RAMASK:
529	pBtCoexist->btInfo.raMask = *pU4Tmp;
530
531	if (check_fwstate(pmlmepriv: &padapter->mlmepriv, WIFI_ASOC_STATE) == true) {
532	struct sta_info *psta;
533	struct wlan_bssid_ex *cur_network;
534
535	cur_network = &padapter->mlmeextpriv.mlmext_info.network;
536	psta = rtw_get_stainfo(pstapriv: &padapter->stapriv, hwaddr: cur_network->mac_address);
537	rtw_hal_update_ra_mask(psta, rssi_level: `0`);
538	}
539	break;
540
541	case BTC_SET_ACT_SEND_MIMO_PS:
542	ret = false;
543	break;
544
545	case BTC_SET_ACT_CTRL_BT_INFO:
546	ret = false;
547	break;
548
549	case BTC_SET_ACT_CTRL_BT_COEX:
550	ret = false;
551	break;
552	case BTC_SET_ACT_CTRL_8723B_ANT:
553	ret = false;
554	break;
555	/ /
556	default:
557	ret = false;
558	break;
559	}
560
561	return ret;
562	}
563
564	/ /
565	/ IO related function /
566	/ /
567	static u8 halbtcoutsrc_Read1Byte(void *pBtcContext, u32 RegAddr)
568	{
569	struct btc_coexist *pBtCoexist;
570	struct adapter *padapter;
571
572
573	pBtCoexist = (struct btc_coexist *)pBtcContext;
574	padapter = pBtCoexist->Adapter;
575
576	return rtw_read8(adapter: padapter, addr: RegAddr);
577	}
578
579	static u16 halbtcoutsrc_Read2Byte(void *pBtcContext, u32 RegAddr)
580	{
581	struct btc_coexist *pBtCoexist;
582	struct adapter *padapter;
583
584
585	pBtCoexist = (struct btc_coexist *)pBtcContext;
586	padapter = pBtCoexist->Adapter;
587
588	return rtw_read16(adapter: padapter, addr: RegAddr);
589	}
590
591	static u32 halbtcoutsrc_Read4Byte(void *pBtcContext, u32 RegAddr)
592	{
593	struct btc_coexist *pBtCoexist;
594	struct adapter *padapter;
595
596
597	pBtCoexist = (struct btc_coexist *)pBtcContext;
598	padapter = pBtCoexist->Adapter;
599
600	return rtw_read32(adapter: padapter, addr: RegAddr);
601	}
602
603	static void halbtcoutsrc_Write1Byte(void *pBtcContext, u32 RegAddr, u8 Data)
604	{
605	struct btc_coexist *pBtCoexist;
606	struct adapter *padapter;
607
608
609	pBtCoexist = (struct btc_coexist *)pBtcContext;
610	padapter = pBtCoexist->Adapter;
611
612	rtw_write8(adapter: padapter, addr: RegAddr, val: Data);
613	}
614
615	static void halbtcoutsrc_BitMaskWrite1Byte(void *pBtcContext, u32 regAddr, u8 bitMask, u8 data1b)
616	{
617	struct btc_coexist *pBtCoexist;
618	struct adapter *padapter;
619	u8 originalValue, bitShift;
620	u8 i;
621
622
623	pBtCoexist = (struct btc_coexist *)pBtcContext;
624	padapter = pBtCoexist->Adapter;
625	originalValue = `0`;
626	bitShift = `0`;
627
628	if (bitMask != `0xFF`) {
629	originalValue = rtw_read8(adapter: padapter, addr: regAddr);
630
631	for (i = `0`; i <= `7`; i++) {
632	if ((bitMask >> i) & `0x1`)
633	break;
634	}
635	bitShift = i;
636
637	data1b = (originalValue & ~bitMask) \| ((data1b << bitShift) & bitMask);
638	}
639
640	rtw_write8(adapter: padapter, addr: regAddr, val: data1b);
641	}
642
643	static void halbtcoutsrc_Write2Byte(void *pBtcContext, u32 RegAddr, u16 Data)
644	{
645	struct btc_coexist *pBtCoexist;
646	struct adapter *padapter;
647
648
649	pBtCoexist = (struct btc_coexist *)pBtcContext;
650	padapter = pBtCoexist->Adapter;
651
652	rtw_write16(adapter: padapter, addr: RegAddr, val: Data);
653	}
654
655	static void halbtcoutsrc_Write4Byte(void *pBtcContext, u32 RegAddr, u32 Data)
656	{
657	struct btc_coexist *pBtCoexist;
658	struct adapter *padapter;
659
660
661	pBtCoexist = (struct btc_coexist *)pBtcContext;
662	padapter = pBtCoexist->Adapter;
663
664	rtw_write32(adapter: padapter, addr: RegAddr, val: Data);
665	}
666
667	static void halbtcoutsrc_WriteLocalReg1Byte(void *pBtcContext, u32 RegAddr, u8 Data)
668	{
669	struct btc_coexist pBtCoexist = (struct* btc_coexist *)pBtcContext;
670	struct adapter *Adapter = pBtCoexist->Adapter;
671
672	if (BTC_INTF_SDIO == pBtCoexist->chipInterface)
673	rtw_write8(adapter: Adapter, SDIO_LOCAL_BASE \| RegAddr, val: Data);
674	else
675	rtw_write8(adapter: Adapter, addr: RegAddr, val: Data);
676	}
677
678	static void halbtcoutsrc_SetBbReg(void *pBtcContext, u32 RegAddr, u32 BitMask, u32 Data)
679	{
680	struct btc_coexist *pBtCoexist;
681	struct adapter *padapter;
682
683
684	pBtCoexist = (struct btc_coexist *)pBtcContext;
685	padapter = pBtCoexist->Adapter;
686
687	PHY_SetBBReg(padapter, RegAddr, BitMask, Data);
688	}
689
690
691	static u32 halbtcoutsrc_GetBbReg(void *pBtcContext, u32 RegAddr, u32 BitMask)
692	{
693	struct btc_coexist *pBtCoexist;
694	struct adapter *padapter;
695
696
697	pBtCoexist = (struct btc_coexist *)pBtcContext;
698	padapter = pBtCoexist->Adapter;
699
700	return PHY_QueryBBReg(padapter, RegAddr, BitMask);
701	}
702
703	static void halbtcoutsrc_SetRfReg(void *pBtcContext, u8 eRFPath, u32 RegAddr, u32 BitMask, u32 Data)
704	{
705	struct btc_coexist *pBtCoexist;
706	struct adapter *padapter;
707
708
709	pBtCoexist = (struct btc_coexist *)pBtcContext;
710	padapter = pBtCoexist->Adapter;
711
712	PHY_SetRFReg(padapter, eRFPath, RegAddr, BitMask, Data);
713	}
714
715	static u32 halbtcoutsrc_GetRfReg(void *pBtcContext, u8 eRFPath, u32 RegAddr, u32 BitMask)
716	{
717	struct btc_coexist *pBtCoexist;
718	struct adapter *padapter;
719
720
721	pBtCoexist = (struct btc_coexist *)pBtcContext;
722	padapter = pBtCoexist->Adapter;
723
724	return PHY_QueryRFReg(padapter, eRFPath, RegAddr, BitMask);
725	}
726
727	static void halbtcoutsrc_SetBtReg(void *pBtcContext, u8 RegType, u32 RegAddr, u32 Data)
728	{
729	struct btc_coexist *pBtCoexist;
730	struct adapter *padapter;
731	u8 CmdBuffer1[`4`] = {`0`};
732	u8 CmdBuffer2[`4`] = {`0`};
733	u8 AddrToSet = (u8 )&RegAddr;
734	u8 ValueToSet = (u8 )&Data;
735	u8 OperVer = `0`;
736	u8 ReqNum = `0`;
737
738	pBtCoexist = (struct btc_coexist *)pBtcContext;
739	padapter = pBtCoexist->Adapter;
740
741	CmdBuffer1[`0`] \|= (OperVer & `0x0f`); / Set OperVer /
742	CmdBuffer1[`0`] \|= ((ReqNum << `4`) & `0xf0`); / Set ReqNum /
743	CmdBuffer1[`1`] = `0x0d`; / Set OpCode to BT_LO_OP_WRITE_REG_VALUE /
744	CmdBuffer1[`2`] = ValueToSet[`0`]; / Set WriteRegValue /
745	rtw_hal_fill_h2c_cmd(padapter, ElementID: `0x67`, CmdLen: `4`, pCmdBuffer: &(CmdBuffer1[`0`]));
746
747	msleep(msecs: `200`);
748	ReqNum++;
749
750	CmdBuffer2[`0`] \|= (OperVer & `0x0f`); / Set OperVer /
751	CmdBuffer2[`0`] \|= ((ReqNum << `4`) & `0xf0`); / Set ReqNum /
752	CmdBuffer2[`1`] = `0x0c`; / Set OpCode of BT_LO_OP_WRITE_REG_ADDR /
753	CmdBuffer2[`3`] = AddrToSet[`0`]; / Set WriteRegAddr /
754	rtw_hal_fill_h2c_cmd(padapter, ElementID: `0x67`, CmdLen: `4`, pCmdBuffer: &(CmdBuffer2[`0`]));
755	}
756
757	static u32 halbtcoutsrc_GetBtReg(void *pBtcContext, u8 RegType, u32 RegAddr)
758	{
759	/ To be implemented. Always return 0 temporarily /
760	return `0`;
761	}
762
763	static void halbtcoutsrc_FillH2cCmd(void pBtcContext, u8 elementId, u32 cmdLen, u8 pCmdBuffer)
764	{
765	struct btc_coexist *pBtCoexist;
766	struct adapter *padapter;
767
768
769	pBtCoexist = (struct btc_coexist *)pBtcContext;
770	padapter = pBtCoexist->Adapter;
771
772	rtw_hal_fill_h2c_cmd(padapter, ElementID: elementId, CmdLen: cmdLen, pCmdBuffer);
773	}
774
775	/ /
776	/ Extern functions called by other module /
777	/ /
778	static u8 EXhalbtcoutsrc_BindBtCoexWithAdapter(void *padapter)
779	{
780	struct btc_coexist *pBtCoexist = &GLBtCoexist;
781
782	if (pBtCoexist->bBinded)
783	return false;
784	else
785	pBtCoexist->bBinded = true;
786
787	pBtCoexist->statistics.cntBind++;
788
789	pBtCoexist->Adapter = padapter;
790
791	pBtCoexist->stackInfo.bProfileNotified = false;
792
793	pBtCoexist->btInfo.bBtCtrlAggBufSize = false;
794	pBtCoexist->btInfo.aggBufSize = `5`;
795
796	pBtCoexist->btInfo.bIncreaseScanDevNum = false;
797
798	/ set default antenna position to main port /
799	pBtCoexist->boardInfo.btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT;
800
801	return true;
802	}
803
804	void hal_btcoex_Initialize(void *padapter)
805	{
806	struct btc_coexist *pBtCoexist;
807
808	memset(&GLBtCoexist, `0`, sizeof(GLBtCoexist));
809
810	pBtCoexist = &GLBtCoexist;
811
812	/ pBtCoexist->statistics.cntBind++; /
813
814	pBtCoexist->chipInterface = BTC_INTF_SDIO;
815
816	EXhalbtcoutsrc_BindBtCoexWithAdapter(padapter);
817
818	pBtCoexist->fBtcRead1Byte = halbtcoutsrc_Read1Byte;
819	pBtCoexist->fBtcWrite1Byte = halbtcoutsrc_Write1Byte;
820	pBtCoexist->fBtcWrite1ByteBitMask = halbtcoutsrc_BitMaskWrite1Byte;
821	pBtCoexist->fBtcRead2Byte = halbtcoutsrc_Read2Byte;
822	pBtCoexist->fBtcWrite2Byte = halbtcoutsrc_Write2Byte;
823	pBtCoexist->fBtcRead4Byte = halbtcoutsrc_Read4Byte;
824	pBtCoexist->fBtcWrite4Byte = halbtcoutsrc_Write4Byte;
825	pBtCoexist->fBtcWriteLocalReg1Byte = halbtcoutsrc_WriteLocalReg1Byte;
826
827	pBtCoexist->fBtcSetBbReg = halbtcoutsrc_SetBbReg;
828	pBtCoexist->fBtcGetBbReg = halbtcoutsrc_GetBbReg;
829
830	pBtCoexist->fBtcSetRfReg = halbtcoutsrc_SetRfReg;
831	pBtCoexist->fBtcGetRfReg = halbtcoutsrc_GetRfReg;
832
833	pBtCoexist->fBtcFillH2c = halbtcoutsrc_FillH2cCmd;
834
835	pBtCoexist->fBtcGet = halbtcoutsrc_Get;
836	pBtCoexist->fBtcSet = halbtcoutsrc_Set;
837	pBtCoexist->fBtcGetBtReg = halbtcoutsrc_GetBtReg;
838	pBtCoexist->fBtcSetBtReg = halbtcoutsrc_SetBtReg;
839
840	pBtCoexist->boardInfo.singleAntPath = `0`;
841
842	GLBtcWiFiInScanState = false;
843
844	GLBtcWiFiInIQKState = false;
845	}
846
847	void EXhalbtcoutsrc_PowerOnSetting(struct btc_coexist *pBtCoexist)
848	{
849	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
850	return;
851
852	/ Power on setting function is only added in 8723B currently /
853	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
854	EXhalbtc8723b2ant_PowerOnSetting(pBtCoexist);
855	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
856	EXhalbtc8723b1ant_PowerOnSetting(pBtCoexist);
857	}
858
859	void EXhalbtcoutsrc_InitHwConfig(struct btc_coexist *pBtCoexist, u8 bWifiOnly)
860	{
861	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
862	return;
863
864	pBtCoexist->statistics.cntInitHwConfig++;
865
866	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
867	EXhalbtc8723b2ant_InitHwConfig(pBtCoexist, bWifiOnly);
868	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
869	EXhalbtc8723b1ant_InitHwConfig(pBtCoexist, bWifiOnly);
870	}
871
872	void EXhalbtcoutsrc_InitCoexDm(struct btc_coexist *pBtCoexist)
873	{
874	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
875	return;
876
877	pBtCoexist->statistics.cntInitCoexDm++;
878
879	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
880	EXhalbtc8723b2ant_InitCoexDm(pBtCoexist);
881	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
882	EXhalbtc8723b1ant_InitCoexDm(pBtCoexist);
883
884	pBtCoexist->bInitilized = true;
885	}
886
887	void EXhalbtcoutsrc_IpsNotify(struct btc_coexist *pBtCoexist, u8 type)
888	{
889	u8 ipsType;
890
891	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
892	return;
893
894	pBtCoexist->statistics.cntIpsNotify++;
895	if (pBtCoexist->bManualControl)
896	return;
897
898	if (IPS_NONE == type)
899	ipsType = BTC_IPS_LEAVE;
900	else
901	ipsType = BTC_IPS_ENTER;
902
903	/ All notify is called in cmd thread, don't need to leave low power again /
904	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
905
906	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
907	EXhalbtc8723b2ant_IpsNotify(pBtCoexist, type: ipsType);
908	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
909	EXhalbtc8723b1ant_IpsNotify(pBtCoexist, type: ipsType);
910
911	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
912	}
913
914	void EXhalbtcoutsrc_LpsNotify(struct btc_coexist *pBtCoexist, u8 type)
915	{
916	u8 lpsType;
917
918
919	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
920	return;
921
922	pBtCoexist->statistics.cntLpsNotify++;
923	if (pBtCoexist->bManualControl)
924	return;
925
926	if (PS_MODE_ACTIVE == type)
927	lpsType = BTC_LPS_DISABLE;
928	else
929	lpsType = BTC_LPS_ENABLE;
930
931	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
932	EXhalbtc8723b2ant_LpsNotify(pBtCoexist, type: lpsType);
933	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
934	EXhalbtc8723b1ant_LpsNotify(pBtCoexist, type: lpsType);
935	}
936
937	void EXhalbtcoutsrc_ScanNotify(struct btc_coexist *pBtCoexist, u8 type)
938	{
939	u8 scanType;
940
941	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
942	return;
943	pBtCoexist->statistics.cntScanNotify++;
944	if (pBtCoexist->bManualControl)
945	return;
946
947	if (type) {
948	scanType = BTC_SCAN_START;
949	GLBtcWiFiInScanState = true;
950	} else {
951	scanType = BTC_SCAN_FINISH;
952	GLBtcWiFiInScanState = false;
953	}
954
955	/ All notify is called in cmd thread, don't need to leave low power again /
956	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
957
958	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
959	EXhalbtc8723b2ant_ScanNotify(pBtCoexist, type: scanType);
960	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
961	EXhalbtc8723b1ant_ScanNotify(pBtCoexist, type: scanType);
962
963	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
964	}
965
966	void EXhalbtcoutsrc_ConnectNotify(struct btc_coexist *pBtCoexist, u8 action)
967	{
968	u8 assoType;
969
970	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
971	return;
972	pBtCoexist->statistics.cntConnectNotify++;
973	if (pBtCoexist->bManualControl)
974	return;
975
976	if (action)
977	assoType = BTC_ASSOCIATE_START;
978	else
979	assoType = BTC_ASSOCIATE_FINISH;
980
981	/ All notify is called in cmd thread, don't need to leave low power again /
982	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
983
984	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
985	EXhalbtc8723b2ant_ConnectNotify(pBtCoexist, type: assoType);
986	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
987	EXhalbtc8723b1ant_ConnectNotify(pBtCoexist, type: assoType);
988
989	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
990	}
991
992	void EXhalbtcoutsrc_MediaStatusNotify(struct btc_coexist pBtCoexist, enum*
993	rt_media_status mediaStatus)
994	{
995	u8 mStatus;
996
997	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
998	return;
999
1000	pBtCoexist->statistics.cntMediaStatusNotify++;
1001	if (pBtCoexist->bManualControl)
1002	return;
1003
1004	if (RT_MEDIA_CONNECT == mediaStatus)
1005	mStatus = BTC_MEDIA_CONNECT;
1006	else
1007	mStatus = BTC_MEDIA_DISCONNECT;
1008
1009	/ All notify is called in cmd thread, don't need to leave low power again /
1010	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
1011
1012	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1013	EXhalbtc8723b2ant_MediaStatusNotify(pBtCoexist, type: mStatus);
1014	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1015	EXhalbtc8723b1ant_MediaStatusNotify(pBtCoexist, type: mStatus);
1016
1017	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
1018	}
1019
1020	void EXhalbtcoutsrc_SpecialPacketNotify(struct btc_coexist *pBtCoexist, u8 pktType)
1021	{
1022	u8 packetType;
1023
1024	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
1025	return;
1026	pBtCoexist->statistics.cntSpecialPacketNotify++;
1027	if (pBtCoexist->bManualControl)
1028	return;
1029
1030	if (PACKET_DHCP == pktType) {
1031	packetType = BTC_PACKET_DHCP;
1032	} else if (PACKET_EAPOL == pktType) {
1033	packetType = BTC_PACKET_EAPOL;
1034	} else if (PACKET_ARP == pktType) {
1035	packetType = BTC_PACKET_ARP;
1036	} else {
1037	return;
1038	}
1039
1040	/ All notify is called in cmd thread, don't need to leave low power again /
1041	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
1042
1043	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1044	EXhalbtc8723b2ant_SpecialPacketNotify(pBtCoexist, type: packetType);
1045	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1046	EXhalbtc8723b1ant_SpecialPacketNotify(pBtCoexist, type: packetType);
1047
1048	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
1049	}
1050
1051	void EXhalbtcoutsrc_BtInfoNotify(struct btc_coexist pBtCoexist, u8 tmpBuf, u8 length)
1052	{
1053	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
1054	return;
1055
1056	pBtCoexist->statistics.cntBtInfoNotify++;
1057
1058	/ All notify is called in cmd thread, don't need to leave low power again /
1059	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
1060
1061	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1062	EXhalbtc8723b2ant_BtInfoNotify(pBtCoexist, tmpBuf, length);
1063	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1064	EXhalbtc8723b1ant_BtInfoNotify(pBtCoexist, tmpBuf, length);
1065
1066	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
1067	}
1068
1069	void EXhalbtcoutsrc_HaltNotify(struct btc_coexist *pBtCoexist)
1070	{
1071	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
1072	return;
1073
1074	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1075	EXhalbtc8723b2ant_HaltNotify(pBtCoexist);
1076	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1077	EXhalbtc8723b1ant_HaltNotify(pBtCoexist);
1078
1079	pBtCoexist->bBinded = false;
1080	}
1081
1082	void EXhalbtcoutsrc_PnpNotify(struct btc_coexist *pBtCoexist, u8 pnpState)
1083	{
1084	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
1085	return;
1086
1087	/ /
1088	/ currently only 1ant we have to do the notification, /
1089	/ once pnp is notified to sleep state, we have to leave LPS that we can sleep normally. /
1090	/ /
1091
1092	if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1093	EXhalbtc8723b1ant_PnpNotify(pBtCoexist, pnpState);
1094	else if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1095	EXhalbtc8723b2ant_PnpNotify(pBtCoexist, pnpState);
1096	}
1097
1098	void EXhalbtcoutsrc_Periodical(struct btc_coexist *pBtCoexist)
1099	{
1100	if (!halbtcoutsrc_IsBtCoexistAvailable(pBtCoexist))
1101	return;
1102	pBtCoexist->statistics.cntPeriodical++;
1103
1104	/ Periodical should be called in cmd thread, /
1105	/ don't need to leave low power again /
1106	/ halbtcoutsrc_LeaveLowPower(pBtCoexist); /
1107
1108	if (pBtCoexist->boardInfo.btdmAntNum == `2`)
1109	EXhalbtc8723b2ant_Periodical(pBtCoexist);
1110	else if (pBtCoexist->boardInfo.btdmAntNum == `1`)
1111	EXhalbtc8723b1ant_Periodical(pBtCoexist);
1112
1113	/ halbtcoutsrc_NormalLowPower(pBtCoexist); /
1114	}
1115
1116	void EXhalbtcoutsrc_SetAntNum(u8 type, u8 antNum)
1117	{
1118	if (BT_COEX_ANT_TYPE_PG == type) {
1119	GLBtCoexist.boardInfo.pgAntNum = antNum;
1120	GLBtCoexist.boardInfo.btdmAntNum = antNum;
1121	} else if (BT_COEX_ANT_TYPE_ANTDIV == type) {
1122	GLBtCoexist.boardInfo.btdmAntNum = antNum;
1123	/ GLBtCoexist.boardInfo.btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT; /
1124	} else if (BT_COEX_ANT_TYPE_DETECTED == type) {
1125	GLBtCoexist.boardInfo.btdmAntNum = antNum;
1126	/ GLBtCoexist.boardInfo.btdmAntPos = BTC_ANTENNA_AT_MAIN_PORT; /
1127	}
1128	}
1129
1130	/ /
1131	/ Currently used by 8723b only, S0 or S1 /
1132	/ /
1133	void EXhalbtcoutsrc_SetSingleAntPath(u8 singleAntPath)
1134	{
1135	GLBtCoexist.boardInfo.singleAntPath = singleAntPath;
1136	}
1137
1138	/*
1139	* Description:
1140	*Run BT-Coexist mechanism or not
1141	*
1142	*/
1143	void hal_btcoex_SetBTCoexist(struct adapter *padapter, u8 bBtExist)
1144	{
1145	struct hal_com_data *pHalData;
1146
1147
1148	pHalData = GET_HAL_DATA(padapter);
1149	pHalData->bt_coexist.bBtExist = bBtExist;
1150	}
1151
1152	/*
1153	* Dewcription:
1154	*Check is co-exist mechanism enabled or not
1155	*
1156	* Return:
1157	*true Enable BT co-exist mechanism
1158	*false Disable BT co-exist mechanism
1159	*/
1160	bool hal_btcoex_IsBtExist(struct adapter *padapter)
1161	{
1162	struct hal_com_data *pHalData;
1163
1164
1165	pHalData = GET_HAL_DATA(padapter);
1166	return pHalData->bt_coexist.bBtExist;
1167	}
1168
1169	bool hal_btcoex_IsBtDisabled(struct adapter *padapter)
1170	{
1171	if (!hal_btcoex_IsBtExist(padapter))
1172	return true;
1173
1174	if (GLBtCoexist.btInfo.bBtDisabled)
1175	return true;
1176	else
1177	return false;
1178	}
1179
1180	void hal_btcoex_SetPgAntNum(struct adapter *padapter, u8 antNum)
1181	{
1182	struct hal_com_data *pHalData;
1183
1184
1185	pHalData = GET_HAL_DATA(padapter);
1186
1187	pHalData->bt_coexist.btTotalAntNum = antNum;
1188	EXhalbtcoutsrc_SetAntNum(BT_COEX_ANT_TYPE_PG, antNum);
1189	}
1190
1191	void hal_btcoex_SetSingleAntPath(struct adapter *padapter, u8 singleAntPath)
1192	{
1193	EXhalbtcoutsrc_SetSingleAntPath(singleAntPath);
1194	}
1195
1196	void hal_btcoex_PowerOnSetting(struct adapter *padapter)
1197	{
1198	EXhalbtcoutsrc_PowerOnSetting(pBtCoexist: &GLBtCoexist);
1199	}
1200
1201	void hal_btcoex_InitHwConfig(struct adapter *padapter, u8 bWifiOnly)
1202	{
1203	if (!hal_btcoex_IsBtExist(padapter))
1204	return;
1205
1206	EXhalbtcoutsrc_InitHwConfig(pBtCoexist: &GLBtCoexist, bWifiOnly);
1207	EXhalbtcoutsrc_InitCoexDm(pBtCoexist: &GLBtCoexist);
1208	}
1209
1210	void hal_btcoex_IpsNotify(struct adapter *padapter, u8 type)
1211	{
1212	EXhalbtcoutsrc_IpsNotify(pBtCoexist: &GLBtCoexist, type);
1213	}
1214
1215	void hal_btcoex_LpsNotify(struct adapter *padapter, u8 type)
1216	{
1217	EXhalbtcoutsrc_LpsNotify(pBtCoexist: &GLBtCoexist, type);
1218	}
1219
1220	void hal_btcoex_ScanNotify(struct adapter *padapter, u8 type)
1221	{
1222	EXhalbtcoutsrc_ScanNotify(pBtCoexist: &GLBtCoexist, type);
1223	}
1224
1225	void hal_btcoex_ConnectNotify(struct adapter *padapter, u8 action)
1226	{
1227	EXhalbtcoutsrc_ConnectNotify(pBtCoexist: &GLBtCoexist, action);
1228	}
1229
1230	void hal_btcoex_MediaStatusNotify(struct adapter *padapter, u8 mediaStatus)
1231	{
1232	EXhalbtcoutsrc_MediaStatusNotify(pBtCoexist: &GLBtCoexist, mediaStatus);
1233	}
1234
1235	void hal_btcoex_SpecialPacketNotify(struct adapter *padapter, u8 pktType)
1236	{
1237	EXhalbtcoutsrc_SpecialPacketNotify(pBtCoexist: &GLBtCoexist, pktType);
1238	}
1239
1240	void hal_btcoex_IQKNotify(struct adapter *padapter, u8 state)
1241	{
1242	GLBtcWiFiInIQKState = state;
1243	}
1244
1245	void hal_btcoex_BtInfoNotify(struct adapter padapter, u8 length, u8 tmpBuf)
1246	{
1247	if (GLBtcWiFiInIQKState)
1248	return;
1249
1250	EXhalbtcoutsrc_BtInfoNotify(pBtCoexist: &GLBtCoexist, tmpBuf, length);
1251	}
1252
1253	void hal_btcoex_SuspendNotify(struct adapter *padapter, u8 state)
1254	{
1255	if (state == `1`)
1256	state = BTC_WIFI_PNP_SLEEP;
1257	else
1258	state = BTC_WIFI_PNP_WAKE_UP;
1259
1260	EXhalbtcoutsrc_PnpNotify(pBtCoexist: &GLBtCoexist, pnpState: state);
1261	}
1262
1263	void hal_btcoex_HaltNotify(struct adapter *padapter)
1264	{
1265	EXhalbtcoutsrc_HaltNotify(pBtCoexist: &GLBtCoexist);
1266	}
1267
1268	void hal_btcoex_Handler(struct adapter *padapter)
1269	{
1270	EXhalbtcoutsrc_Periodical(pBtCoexist: &GLBtCoexist);
1271	}
1272
1273	s32 hal_btcoex_IsBTCoexCtrlAMPDUSize(struct adapter *padapter)
1274	{
1275	return (s32)GLBtCoexist.btInfo.bBtCtrlAggBufSize;
1276	}
1277
1278	bool hal_btcoex_IsBtControlLps(struct adapter *padapter)
1279	{
1280	if (!hal_btcoex_IsBtExist(padapter))
1281	return false;
1282
1283	if (GLBtCoexist.btInfo.bBtDisabled)
1284	return false;
1285
1286	if (GLBtCoexist.btInfo.bBtCtrlLps)
1287	return true;
1288
1289	return false;
1290	}
1291
1292	bool hal_btcoex_IsLpsOn(struct adapter *padapter)
1293	{
1294	if (!hal_btcoex_IsBtExist(padapter))
1295	return false;
1296
1297	if (GLBtCoexist.btInfo.bBtDisabled)
1298	return false;
1299
1300	if (GLBtCoexist.btInfo.bBtLpsOn)
1301	return true;
1302
1303	return false;
1304	}
1305
1306	u8 hal_btcoex_RpwmVal(struct adapter *padapter)
1307	{
1308	return GLBtCoexist.btInfo.rpwmVal;
1309	}
1310
1311	u8 hal_btcoex_LpsVal(struct adapter *padapter)
1312	{
1313	return GLBtCoexist.btInfo.lpsVal;
1314	}
1315
1316	u32 hal_btcoex_GetRaMask(struct adapter *padapter)
1317	{
1318	if (!hal_btcoex_IsBtExist(padapter))
1319	return `0`;
1320
1321	if (GLBtCoexist.btInfo.bBtDisabled)
1322	return `0`;
1323
1324	if (GLBtCoexist.boardInfo.btdmAntNum != `1`)
1325	return `0`;
1326
1327	return GLBtCoexist.btInfo.raMask;
1328	}
1329
1330	void hal_btcoex_RecordPwrMode(struct adapter padapter, u8 pCmdBuf, u8 cmdLen)
1331	{
1332	memcpy(GLBtCoexist.pwrModeVal, pCmdBuf, cmdLen);
1333	}
1334

source code of linux/drivers/staging/rtl8723bs/hal/hal_btcoex.c