xref: /wlan-driver/qca-wifi-host-cmn/hal/wifi3.0/hal_srng.c (revision 5113495b16420b49004c444715d2daae2066e7dc) !
1 /*
2  * Copyright (c) 2016-2021 The Linux Foundation. All rights reserved.
3  * Copyright (c) 2021-2024 Qualcomm Innovation Center, Inc. All rights reserved.
4  *
5  * Permission to use, copy, modify, and/or distribute this software for
6  * any purpose with or without fee is hereby granted, provided that the
7  * above copyright notice and this permission notice appear in all
8  * copies.
9  *
10  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL
11  * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED
12  * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE
13  * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL
14  * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR
15  * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER
16  * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR
17  * PERFORMANCE OF THIS SOFTWARE.
18  */
19 
20 #include "hal_hw_headers.h"
21 #include "hal_api.h"
22 #include "hal_reo.h"
23 #include "target_type.h"
24 #include "qdf_module.h"
25 #include "wcss_version.h"
26 #include <qdf_tracepoint.h>
27 #include "qdf_ssr_driver_dump.h"
28 
29 struct tcl_data_cmd gtcl_data_symbol __attribute__((used));
30 
31 #ifdef QCA_WIFI_QCA8074
32 void hal_qca6290_attach(struct hal_soc *hal);
33 #endif
34 #ifdef QCA_WIFI_QCA8074
35 void hal_qca8074_attach(struct hal_soc *hal);
36 #endif
37 #if defined(QCA_WIFI_QCA8074V2) || defined(QCA_WIFI_QCA6018) || \
38 	defined(QCA_WIFI_QCA9574)
39 void hal_qca8074v2_attach(struct hal_soc *hal);
40 #endif
41 #ifdef QCA_WIFI_QCA6390
42 void hal_qca6390_attach(struct hal_soc *hal);
43 #endif
44 #ifdef QCA_WIFI_QCA6490
45 void hal_qca6490_attach(struct hal_soc *hal);
46 #endif
47 #ifdef QCA_WIFI_QCN9000
48 void hal_qcn9000_attach(struct hal_soc *hal);
49 #endif
50 #ifdef QCA_WIFI_QCN9224
51 void hal_qcn9224v2_attach(struct hal_soc *hal);
52 #endif
53 #if defined(QCA_WIFI_QCN6122) || defined(QCA_WIFI_QCN9160)
54 void hal_qcn6122_attach(struct hal_soc *hal);
55 #endif
56 #ifdef QCA_WIFI_QCN6432
57 void hal_qcn6432_attach(struct hal_soc *hal);
58 #endif
59 #ifdef QCA_WIFI_QCA6750
60 void hal_qca6750_attach(struct hal_soc *hal);
61 #endif
62 #ifdef QCA_WIFI_QCA5018
63 void hal_qca5018_attach(struct hal_soc *hal);
64 #endif
65 #ifdef QCA_WIFI_QCA5332
66 void hal_qca5332_attach(struct hal_soc *hal);
67 #endif
68 #ifdef QCA_WIFI_KIWI
69 void hal_kiwi_attach(struct hal_soc *hal);
70 #endif
71 
72 #ifdef ENABLE_VERBOSE_DEBUG
73 bool is_hal_verbose_debug_enabled;
74 #endif
75 
76 #define HAL_REO_DESTINATION_RING_CTRL_IX_0_ADDR(x)	((x) + 0x4)
77 #define HAL_REO_DESTINATION_RING_CTRL_IX_1_ADDR(x)	((x) + 0x8)
78 #define HAL_REO_DESTINATION_RING_CTRL_IX_2_ADDR(x)	((x) + 0xc)
79 #define HAL_REO_DESTINATION_RING_CTRL_IX_3_ADDR(x)	((x) + 0x10)
80 
81 #ifdef ENABLE_HAL_REG_WR_HISTORY
82 struct hal_reg_write_fail_history hal_reg_wr_hist;
83 
hal_reg_wr_fail_history_add(struct hal_soc * hal_soc,uint32_t offset,uint32_t wr_val,uint32_t rd_val)84 void hal_reg_wr_fail_history_add(struct hal_soc *hal_soc,
85 				 uint32_t offset,
86 				 uint32_t wr_val, uint32_t rd_val)
87 {
88 	struct hal_reg_write_fail_entry *record;
89 	int idx;
90 
91 	idx = hal_history_get_next_index(&hal_soc->reg_wr_fail_hist->index,
92 					 HAL_REG_WRITE_HIST_SIZE);
93 
94 	record = &hal_soc->reg_wr_fail_hist->record[idx];
95 
96 	record->timestamp = qdf_get_log_timestamp();
97 	record->reg_offset = offset;
98 	record->write_val = wr_val;
99 	record->read_val = rd_val;
100 }
101 
hal_reg_write_fail_history_init(struct hal_soc * hal)102 static void hal_reg_write_fail_history_init(struct hal_soc *hal)
103 {
104 	hal->reg_wr_fail_hist = &hal_reg_wr_hist;
105 
106 	qdf_atomic_set(&hal->reg_wr_fail_hist->index, -1);
107 }
108 #else
hal_reg_write_fail_history_init(struct hal_soc * hal)109 static void hal_reg_write_fail_history_init(struct hal_soc *hal)
110 {
111 }
112 #endif
113 
114 /**
115  * hal_get_srng_ring_id() - get the ring id of a described ring
116  * @hal: hal_soc data structure
117  * @ring_type: type enum describing the ring
118  * @ring_num: which ring of the ring type
119  * @mac_id: which mac does the ring belong to (or 0 for non-lmac rings)
120  *
121  * Return: the ring id or -EINVAL if the ring does not exist.
122  */
hal_get_srng_ring_id(struct hal_soc * hal,int ring_type,int ring_num,int mac_id)123 static int hal_get_srng_ring_id(struct hal_soc *hal, int ring_type,
124 				int ring_num, int mac_id)
125 {
126 	struct hal_hw_srng_config *ring_config =
127 		HAL_SRNG_CONFIG(hal, ring_type);
128 	int ring_id;
129 
130 	if (ring_num >= ring_config->max_rings) {
131 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_INFO,
132 			  "%s: ring_num exceeded maximum no. of supported rings",
133 			  __func__);
134 		/* TODO: This is a programming error. Assert if this happens */
135 		return -EINVAL;
136 	}
137 
138 	/*
139 	 * Some DMAC rings share a common source ring, hence don't provide them
140 	 * with separate ring IDs per LMAC.
141 	 */
142 	if (ring_config->lmac_ring && !ring_config->dmac_cmn_ring) {
143 		ring_id = (ring_config->start_ring_id + ring_num +
144 			   (mac_id * HAL_MAX_RINGS_PER_LMAC));
145 	} else {
146 		ring_id = ring_config->start_ring_id + ring_num;
147 	}
148 
149 	return ring_id;
150 }
151 
hal_get_srng(struct hal_soc * hal,int ring_id)152 static struct hal_srng *hal_get_srng(struct hal_soc *hal, int ring_id)
153 {
154 	/* TODO: Should we allocate srng structures dynamically? */
155 	return &(hal->srng_list[ring_id]);
156 }
157 
158 #ifndef SHADOW_REG_CONFIG_DISABLED
159 #define HP_OFFSET_IN_REG_START 1
160 #define OFFSET_FROM_HP_TO_TP 4
hal_update_srng_hp_tp_address(struct hal_soc * hal_soc,int shadow_config_index,int ring_type,int ring_num)161 static void hal_update_srng_hp_tp_address(struct hal_soc *hal_soc,
162 					  int shadow_config_index,
163 					  int ring_type,
164 					  int ring_num)
165 {
166 	struct hal_srng *srng;
167 	int ring_id;
168 	struct hal_hw_srng_config *ring_config =
169 		HAL_SRNG_CONFIG(hal_soc, ring_type);
170 
171 	ring_id = hal_get_srng_ring_id(hal_soc, ring_type, ring_num, 0);
172 	if (ring_id < 0)
173 		return;
174 
175 	srng = hal_get_srng(hal_soc, ring_id);
176 
177 	if (ring_config->ring_dir == HAL_SRNG_DST_RING) {
178 		srng->u.dst_ring.tp_addr = SHADOW_REGISTER(shadow_config_index)
179 			+ hal_soc->dev_base_addr;
180 		hal_debug("tp_addr=%pK dev base addr %pK index %u",
181 			  srng->u.dst_ring.tp_addr, hal_soc->dev_base_addr,
182 			  shadow_config_index);
183 	} else {
184 		srng->u.src_ring.hp_addr = SHADOW_REGISTER(shadow_config_index)
185 			+ hal_soc->dev_base_addr;
186 		hal_debug("hp_addr=%pK dev base addr %pK index %u",
187 			  srng->u.src_ring.hp_addr,
188 			  hal_soc->dev_base_addr, shadow_config_index);
189 	}
190 
191 }
192 #endif
193 
194 #ifdef GENERIC_SHADOW_REGISTER_ACCESS_ENABLE
hal_set_one_target_reg_config(struct hal_soc * hal,uint32_t target_reg_offset,int list_index)195 void hal_set_one_target_reg_config(struct hal_soc *hal,
196 				   uint32_t target_reg_offset,
197 				   int list_index)
198 {
199 	int i = list_index;
200 
201 	qdf_assert_always(i < MAX_GENERIC_SHADOW_REG);
202 	hal->list_shadow_reg_config[i].target_register =
203 		target_reg_offset;
204 	hal->num_generic_shadow_regs_configured++;
205 }
206 
207 qdf_export_symbol(hal_set_one_target_reg_config);
208 
209 #define REO_R0_DESTINATION_RING_CTRL_ADDR_OFFSET 0x4
210 #define MAX_REO_REMAP_SHADOW_REGS 4
hal_set_shadow_regs(void * hal_soc)211 QDF_STATUS hal_set_shadow_regs(void *hal_soc)
212 {
213 	uint32_t target_reg_offset;
214 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
215 	int i;
216 	struct hal_hw_srng_config *srng_config =
217 		&hal->hw_srng_table[WBM2SW_RELEASE];
218 	uint32_t reo_reg_base;
219 
220 	reo_reg_base = hal_get_reo_reg_base_offset(hal_soc);
221 
222 	target_reg_offset =
223 		HAL_REO_DESTINATION_RING_CTRL_IX_0_ADDR(reo_reg_base);
224 
225 	for (i = 0; i < MAX_REO_REMAP_SHADOW_REGS; i++) {
226 		hal_set_one_target_reg_config(hal, target_reg_offset, i);
227 		target_reg_offset += REO_R0_DESTINATION_RING_CTRL_ADDR_OFFSET;
228 	}
229 
230 	target_reg_offset = srng_config->reg_start[HP_OFFSET_IN_REG_START];
231 	target_reg_offset += (srng_config->reg_size[HP_OFFSET_IN_REG_START]
232 			      * HAL_IPA_TX_COMP_RING_IDX);
233 
234 	hal_set_one_target_reg_config(hal, target_reg_offset, i);
235 	return QDF_STATUS_SUCCESS;
236 }
237 
238 qdf_export_symbol(hal_set_shadow_regs);
239 
hal_construct_shadow_regs(void * hal_soc)240 QDF_STATUS hal_construct_shadow_regs(void *hal_soc)
241 {
242 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
243 	int shadow_config_index = hal->num_shadow_registers_configured;
244 	int i;
245 	int num_regs = hal->num_generic_shadow_regs_configured;
246 
247 	for (i = 0; i < num_regs; i++) {
248 		qdf_assert_always(shadow_config_index < MAX_SHADOW_REGISTERS);
249 		hal->shadow_config[shadow_config_index].addr =
250 			hal->list_shadow_reg_config[i].target_register;
251 		hal->list_shadow_reg_config[i].shadow_config_index =
252 			shadow_config_index;
253 		hal->list_shadow_reg_config[i].va =
254 			SHADOW_REGISTER(shadow_config_index) +
255 			(uintptr_t)hal->dev_base_addr;
256 		hal_debug("target_reg %x, shadow register 0x%x shadow_index 0x%x",
257 			  hal->shadow_config[shadow_config_index].addr,
258 			  SHADOW_REGISTER(shadow_config_index),
259 			  shadow_config_index);
260 		shadow_config_index++;
261 		hal->num_shadow_registers_configured++;
262 	}
263 	return QDF_STATUS_SUCCESS;
264 }
265 
266 qdf_export_symbol(hal_construct_shadow_regs);
267 #endif
268 
269 #ifndef SHADOW_REG_CONFIG_DISABLED
270 
hal_set_one_shadow_config(void * hal_soc,int ring_type,int ring_num)271 QDF_STATUS hal_set_one_shadow_config(void *hal_soc,
272 				     int ring_type,
273 				     int ring_num)
274 {
275 	uint32_t target_register;
276 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
277 	struct hal_hw_srng_config *srng_config = &hal->hw_srng_table[ring_type];
278 	int shadow_config_index = hal->num_shadow_registers_configured;
279 
280 	if (shadow_config_index >= MAX_SHADOW_REGISTERS) {
281 		QDF_ASSERT(0);
282 		return QDF_STATUS_E_RESOURCES;
283 	}
284 
285 	hal->num_shadow_registers_configured++;
286 
287 	target_register = srng_config->reg_start[HP_OFFSET_IN_REG_START];
288 	target_register += (srng_config->reg_size[HP_OFFSET_IN_REG_START]
289 			    *ring_num);
290 
291 	/* if the ring is a dst ring, we need to shadow the tail pointer */
292 	if (srng_config->ring_dir == HAL_SRNG_DST_RING)
293 		target_register += OFFSET_FROM_HP_TO_TP;
294 
295 	hal->shadow_config[shadow_config_index].addr = target_register;
296 
297 	/* update hp/tp addr in the hal_soc structure*/
298 	hal_update_srng_hp_tp_address(hal_soc, shadow_config_index, ring_type,
299 				      ring_num);
300 
301 	hal_debug("target_reg %x, shadow register 0x%x shadow_index 0x%x, ring_type %d, ring num %d",
302 		  target_register,
303 		  SHADOW_REGISTER(shadow_config_index),
304 		  shadow_config_index,
305 		  ring_type, ring_num);
306 
307 	return QDF_STATUS_SUCCESS;
308 }
309 
310 qdf_export_symbol(hal_set_one_shadow_config);
311 
hal_construct_srng_shadow_regs(void * hal_soc)312 QDF_STATUS hal_construct_srng_shadow_regs(void *hal_soc)
313 {
314 	int ring_type, ring_num;
315 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
316 
317 	for (ring_type = 0; ring_type < MAX_RING_TYPES; ring_type++) {
318 		struct hal_hw_srng_config *srng_config =
319 			&hal->hw_srng_table[ring_type];
320 
321 		if (ring_type == CE_SRC ||
322 		    ring_type == CE_DST ||
323 		    ring_type == CE_DST_STATUS)
324 			continue;
325 
326 		if (srng_config->lmac_ring)
327 			continue;
328 
329 		for (ring_num = 0; ring_num < srng_config->max_rings;
330 		     ring_num++)
331 			hal_set_one_shadow_config(hal_soc, ring_type, ring_num);
332 	}
333 
334 	return QDF_STATUS_SUCCESS;
335 }
336 
337 qdf_export_symbol(hal_construct_srng_shadow_regs);
338 #else
339 
hal_construct_srng_shadow_regs(void * hal_soc)340 QDF_STATUS hal_construct_srng_shadow_regs(void *hal_soc)
341 {
342 	return QDF_STATUS_SUCCESS;
343 }
344 
345 qdf_export_symbol(hal_construct_srng_shadow_regs);
346 
hal_set_one_shadow_config(void * hal_soc,int ring_type,int ring_num)347 QDF_STATUS hal_set_one_shadow_config(void *hal_soc, int ring_type,
348 				     int ring_num)
349 {
350 	return QDF_STATUS_SUCCESS;
351 }
352 qdf_export_symbol(hal_set_one_shadow_config);
353 #endif
354 
hal_get_shadow_config(void * hal_soc,struct pld_shadow_reg_v2_cfg ** shadow_config,int * num_shadow_registers_configured)355 void hal_get_shadow_config(void *hal_soc,
356 	struct pld_shadow_reg_v2_cfg **shadow_config,
357 	int *num_shadow_registers_configured)
358 {
359 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
360 
361 	*shadow_config = &hal->shadow_config[0].v2;
362 	*num_shadow_registers_configured =
363 		hal->num_shadow_registers_configured;
364 }
365 qdf_export_symbol(hal_get_shadow_config);
366 
367 #ifdef CONFIG_SHADOW_V3
hal_get_shadow_v3_config(void * hal_soc,struct pld_shadow_reg_v3_cfg ** shadow_config,int * num_shadow_registers_configured)368 void hal_get_shadow_v3_config(void *hal_soc,
369 			      struct pld_shadow_reg_v3_cfg **shadow_config,
370 			      int *num_shadow_registers_configured)
371 {
372 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
373 
374 	*shadow_config = &hal->shadow_config[0].v3;
375 	*num_shadow_registers_configured =
376 		hal->num_shadow_registers_configured;
377 }
378 qdf_export_symbol(hal_get_shadow_v3_config);
379 #endif
380 
hal_validate_shadow_register(struct hal_soc * hal,uint32_t * destination,uint32_t * shadow_address)381 static bool hal_validate_shadow_register(struct hal_soc *hal,
382 					 uint32_t *destination,
383 					 uint32_t *shadow_address)
384 {
385 	unsigned int index;
386 	uint32_t *shadow_0_offset = SHADOW_REGISTER(0) + hal->dev_base_addr;
387 	int destination_ba_offset =
388 		((char *)destination) - (char *)hal->dev_base_addr;
389 
390 	index =	shadow_address - shadow_0_offset;
391 
392 	if (index >= MAX_SHADOW_REGISTERS) {
393 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR,
394 			"%s: index %x out of bounds", __func__, index);
395 		goto error;
396 	} else if (hal->shadow_config[index].addr != destination_ba_offset) {
397 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR,
398 			"%s: sanity check failure, expected %x, found %x",
399 			__func__, destination_ba_offset,
400 			hal->shadow_config[index].addr);
401 		goto error;
402 	}
403 	return true;
404 error:
405 	qdf_print("baddr %pK, destination %pK, shadow_address %pK s0offset %pK index %x",
406 		  hal->dev_base_addr, destination, shadow_address,
407 		  shadow_0_offset, index);
408 	QDF_BUG(0);
409 	return false;
410 }
411 
hal_target_based_configure(struct hal_soc * hal)412 static void hal_target_based_configure(struct hal_soc *hal)
413 {
414 	/*
415 	 * Indicate Initialization of srngs to avoid force wake
416 	 * as umac power collapse is not enabled yet
417 	 */
418 	hal->init_phase = true;
419 
420 	switch (hal->target_type) {
421 #ifdef QCA_WIFI_QCA6290
422 	case TARGET_TYPE_QCA6290:
423 		hal->use_register_windowing = true;
424 		hal_qca6290_attach(hal);
425 	break;
426 #endif
427 #ifdef QCA_WIFI_QCA6390
428 	case TARGET_TYPE_QCA6390:
429 		hal->use_register_windowing = true;
430 		hal_qca6390_attach(hal);
431 	break;
432 #endif
433 #ifdef QCA_WIFI_QCA6490
434 	case TARGET_TYPE_QCA6490:
435 		hal->use_register_windowing = true;
436 		hal_qca6490_attach(hal);
437 	break;
438 #endif
439 #ifdef QCA_WIFI_QCA6750
440 		case TARGET_TYPE_QCA6750:
441 			hal->use_register_windowing = true;
442 			hal->static_window_map = true;
443 			hal_qca6750_attach(hal);
444 		break;
445 #endif
446 #ifdef QCA_WIFI_KIWI
447 	case TARGET_TYPE_KIWI:
448 	case TARGET_TYPE_MANGO:
449 	case TARGET_TYPE_PEACH:
450 		hal->use_register_windowing = true;
451 		hal_kiwi_attach(hal);
452 		break;
453 #endif
454 #if defined(QCA_WIFI_QCA8074) && defined(WIFI_TARGET_TYPE_3_0)
455 	case TARGET_TYPE_QCA8074:
456 		hal_qca8074_attach(hal);
457 	break;
458 #endif
459 
460 #if defined(QCA_WIFI_QCA8074V2)
461 	case TARGET_TYPE_QCA8074V2:
462 		hal_qca8074v2_attach(hal);
463 	break;
464 #endif
465 
466 #if defined(QCA_WIFI_QCA6018)
467 	case TARGET_TYPE_QCA6018:
468 		hal_qca8074v2_attach(hal);
469 	break;
470 #endif
471 
472 #if defined(QCA_WIFI_QCA9574)
473 	case TARGET_TYPE_QCA9574:
474 		hal_qca8074v2_attach(hal);
475 	break;
476 #endif
477 
478 #if defined(QCA_WIFI_QCN6122)
479 	case TARGET_TYPE_QCN6122:
480 		hal->use_register_windowing = true;
481 		/*
482 		 * Static window map  is enabled for qcn9000 to use 2mb bar
483 		 * size and use multiple windows to write into registers.
484 		 */
485 		hal->static_window_map = true;
486 		hal_qcn6122_attach(hal);
487 		break;
488 #endif
489 
490 #if defined(QCA_WIFI_QCN9160)
491 	case TARGET_TYPE_QCN9160:
492 		hal->use_register_windowing = true;
493 		/*
494 		 * Static window map  is enabled for qcn9160 to use 2mb bar
495 		 * size and use multiple windows to write into registers.
496 		 */
497 		hal->static_window_map = true;
498 		hal_qcn6122_attach(hal);
499 		break;
500 #endif
501 
502 #if defined(QCA_WIFI_QCN6432)
503 	case TARGET_TYPE_QCN6432:
504 		hal->use_register_windowing = true;
505 		/*
506 		 * Static window map  is enabled for qcn6432 to use 2mb bar
507 		 * size and use multiple windows to write into registers.
508 		 */
509 		hal->static_window_map = true;
510 		hal_qcn6432_attach(hal);
511 		break;
512 #endif
513 
514 #ifdef QCA_WIFI_QCN9000
515 	case TARGET_TYPE_QCN9000:
516 		hal->use_register_windowing = true;
517 		/*
518 		 * Static window map  is enabled for qcn9000 to use 2mb bar
519 		 * size and use multiple windows to write into registers.
520 		 */
521 		hal->static_window_map = true;
522 		hal_qcn9000_attach(hal);
523 	break;
524 #endif
525 #ifdef QCA_WIFI_QCA5018
526 	case TARGET_TYPE_QCA5018:
527 		hal->use_register_windowing = true;
528 		hal->static_window_map = true;
529 		hal_qca5018_attach(hal);
530 	break;
531 #endif
532 #ifdef QCA_WIFI_QCN9224
533 	case TARGET_TYPE_QCN9224:
534 		hal->use_register_windowing = true;
535 		hal->static_window_map = true;
536 		if (hal->version == 1)
537 			qdf_assert_always(0);
538 		else
539 			hal_qcn9224v2_attach(hal);
540 	break;
541 #endif
542 #ifdef QCA_WIFI_QCA5332
543 	case TARGET_TYPE_QCA5332:
544 		hal->use_register_windowing = true;
545 		hal->static_window_map = true;
546 		hal_qca5332_attach(hal);
547 	break;
548 #endif
549 #ifdef QCA_WIFI_WCN6450
550 	case TARGET_TYPE_WCN6450:
551 		hal->use_register_windowing = true;
552 		hal->static_window_map = true;
553 		hal_wcn6450_attach(hal);
554 	break;
555 #endif
556 	default:
557 	break;
558 	}
559 }
560 
hal_get_target_type(hal_soc_handle_t hal_soc_hdl)561 uint32_t hal_get_target_type(hal_soc_handle_t hal_soc_hdl)
562 {
563 	struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
564 	struct hif_target_info *tgt_info =
565 		hif_get_target_info_handle(hal_soc->hif_handle);
566 
567 	return tgt_info->target_type;
568 }
569 
570 qdf_export_symbol(hal_get_target_type);
571 
572 #if defined(FEATURE_HAL_DELAYED_REG_WRITE)
573 /**
574  * hal_is_reg_write_tput_level_high() - throughput level for delayed reg writes
575  * @hal: hal_soc pointer
576  *
577  * Return: true if throughput is high, else false.
578  */
hal_is_reg_write_tput_level_high(struct hal_soc * hal)579 static inline bool hal_is_reg_write_tput_level_high(struct hal_soc *hal)
580 {
581 	int bw_level = hif_get_bandwidth_level(hal->hif_handle);
582 
583 	return (bw_level >= PLD_BUS_WIDTH_MEDIUM) ? true : false;
584 }
585 
586 static inline
hal_fill_reg_write_srng_stats(struct hal_srng * srng,char * buf,qdf_size_t size)587 char *hal_fill_reg_write_srng_stats(struct hal_srng *srng,
588 				    char *buf, qdf_size_t size)
589 {
590 	qdf_scnprintf(buf, size, "enq %u deq %u coal %u direct %u",
591 		      srng->wstats.enqueues, srng->wstats.dequeues,
592 		      srng->wstats.coalesces, srng->wstats.direct);
593 	return buf;
594 }
595 
596 /* bytes for local buffer */
597 #define HAL_REG_WRITE_SRNG_STATS_LEN 100
598 
599 #ifndef WLAN_SOFTUMAC_SUPPORT
hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl)600 void hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl)
601 {
602 	struct hal_srng *srng;
603 	char buf[HAL_REG_WRITE_SRNG_STATS_LEN];
604 	struct hal_soc *hal = (struct hal_soc *)hal_soc_hdl;
605 
606 	srng = hal_get_srng(hal, HAL_SRNG_SW2TCL1);
607 	hal_debug("SW2TCL1: %s",
608 		  hal_fill_reg_write_srng_stats(srng, buf, sizeof(buf)));
609 
610 	srng = hal_get_srng(hal, HAL_SRNG_WBM2SW0_RELEASE);
611 	hal_debug("WBM2SW0: %s",
612 		  hal_fill_reg_write_srng_stats(srng, buf, sizeof(buf)));
613 
614 	srng = hal_get_srng(hal, HAL_SRNG_REO2SW1);
615 	hal_debug("REO2SW1: %s",
616 		  hal_fill_reg_write_srng_stats(srng, buf, sizeof(buf)));
617 
618 	srng = hal_get_srng(hal, HAL_SRNG_REO2SW2);
619 	hal_debug("REO2SW2: %s",
620 		  hal_fill_reg_write_srng_stats(srng, buf, sizeof(buf)));
621 
622 	srng = hal_get_srng(hal, HAL_SRNG_REO2SW3);
623 	hal_debug("REO2SW3: %s",
624 		  hal_fill_reg_write_srng_stats(srng, buf, sizeof(buf)));
625 }
626 
hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl)627 void hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl)
628 {
629 	uint32_t *hist;
630 	struct hal_soc *hal = (struct hal_soc *)hal_soc_hdl;
631 
632 	hist = hal->stats.wstats.sched_delay;
633 	hal_debug("wstats: enq %u deq %u coal %u direct %u q_depth %u max_q %u sched-delay hist %u %u %u %u",
634 		  qdf_atomic_read(&hal->stats.wstats.enqueues),
635 		  hal->stats.wstats.dequeues,
636 		  qdf_atomic_read(&hal->stats.wstats.coalesces),
637 		  qdf_atomic_read(&hal->stats.wstats.direct),
638 		  qdf_atomic_read(&hal->stats.wstats.q_depth),
639 		  hal->stats.wstats.max_q_depth,
640 		  hist[REG_WRITE_SCHED_DELAY_SUB_100us],
641 		  hist[REG_WRITE_SCHED_DELAY_SUB_1000us],
642 		  hist[REG_WRITE_SCHED_DELAY_SUB_5000us],
643 		  hist[REG_WRITE_SCHED_DELAY_GT_5000us]);
644 }
645 #else
hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl)646 void hal_dump_reg_write_srng_stats(hal_soc_handle_t hal_soc_hdl)
647 {
648 }
649 
650 /* TODO: Need separate logic for Evros */
hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl)651 void hal_dump_reg_write_stats(hal_soc_handle_t hal_soc_hdl)
652 {
653 }
654 #endif
655 
hal_get_reg_write_pending_work(void * hal_soc)656 int hal_get_reg_write_pending_work(void *hal_soc)
657 {
658 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
659 
660 	return qdf_atomic_read(&hal->active_work_cnt);
661 }
662 
663 #endif
664 
665 #ifdef FEATURE_HAL_DELAYED_REG_WRITE
666 #ifdef MEMORY_DEBUG
667 /*
668  * Length of the queue(array) used to hold delayed register writes.
669  * Must be a multiple of 2.
670  */
671 #define HAL_REG_WRITE_QUEUE_LEN 128
672 #else
673 #define HAL_REG_WRITE_QUEUE_LEN 32
674 #endif
675 
676 #ifdef QCA_WIFI_QCA6750
677 
678 #define HAL_DEL_WRITE_FORCE_UPDATE_THRES 5
679 
hal_srng_update_last_hptp(struct hal_srng * srng)680 static inline void hal_srng_update_last_hptp(struct hal_srng *srng)
681 {
682 	if (srng->ring_dir == HAL_SRNG_SRC_RING)
683 		srng->updated_hp = srng->u.src_ring.hp;
684 	else
685 		srng->updated_tp = srng->u.dst_ring.tp;
686 
687 	srng->force_cnt = 0;
688 }
689 
690 /* If HP/TP register updates are delayed due to delayed reg
691  * write work not getting scheduled, hardware would see HP/TP
692  * delta and will fire interrupts until the HP/TP updates reach
693  * the hardware.
694  *
695  * When system is heavily stressed, this delay in HP/TP updates
696  * would result in IRQ storm further stressing the system. Force
697  * update HP/TP to the hardware under such scenarios to avoid this.
698  */
hal_srng_check_and_update_hptp(struct hal_soc * hal_soc,struct hal_srng * srng,bool update)699 void hal_srng_check_and_update_hptp(struct hal_soc *hal_soc,
700 				    struct hal_srng *srng, bool update)
701 {
702 	uint32_t value;
703 
704 	if (!update)
705 		return;
706 
707 	SRNG_LOCK(&srng->lock);
708 	if (srng->ring_dir == HAL_SRNG_SRC_RING) {
709 		value = srng->u.src_ring.hp;
710 
711 		if (value == srng->updated_hp ||
712 		    srng->force_cnt++ < HAL_DEL_WRITE_FORCE_UPDATE_THRES)
713 			goto out_unlock;
714 
715 		hal_write_address_32_mb(hal_soc, srng->u.src_ring.hp_addr,
716 					value, false);
717 	} else {
718 		value = srng->u.dst_ring.tp;
719 
720 		if (value == srng->updated_tp ||
721 		    srng->force_cnt++ < HAL_DEL_WRITE_FORCE_UPDATE_THRES)
722 			goto out_unlock;
723 
724 		hal_write_address_32_mb(hal_soc, srng->u.dst_ring.tp_addr,
725 					value, false);
726 	}
727 
728 	hal_srng_update_last_hptp(srng);
729 	hal_srng_reg_his_add(srng, value);
730 	qdf_atomic_inc(&hal_soc->stats.wstats.direct);
731 	srng->wstats.direct++;
732 
733 out_unlock:
734 	SRNG_UNLOCK(&srng->lock);
735 }
736 #else
hal_srng_update_last_hptp(struct hal_srng * srng)737 static inline void hal_srng_update_last_hptp(struct hal_srng *srng)
738 {
739 }
740 #endif /* QCA_WIFI_QCA6750 */
741 
742 /**
743  * hal_process_reg_write_q_elem() - process a register write queue element
744  * @hal: hal_soc pointer
745  * @q_elem: pointer to hal register write queue element
746  *
747  * Return: The value which was written to the address
748  */
749 static uint32_t
hal_process_reg_write_q_elem(struct hal_soc * hal,struct hal_reg_write_q_elem * q_elem)750 hal_process_reg_write_q_elem(struct hal_soc *hal,
751 			     struct hal_reg_write_q_elem *q_elem)
752 {
753 	struct hal_srng *srng = q_elem->srng;
754 	uint32_t write_val;
755 
756 	SRNG_LOCK(&srng->lock);
757 
758 	srng->reg_write_in_progress = false;
759 	srng->wstats.dequeues++;
760 
761 	if (srng->ring_dir == HAL_SRNG_SRC_RING) {
762 		q_elem->dequeue_val = srng->u.src_ring.hp;
763 		hal_write_address_32_mb(hal,
764 					srng->u.src_ring.hp_addr,
765 					srng->u.src_ring.hp, false);
766 		write_val = srng->u.src_ring.hp;
767 	} else {
768 		q_elem->dequeue_val = srng->u.dst_ring.tp;
769 		hal_write_address_32_mb(hal,
770 					srng->u.dst_ring.tp_addr,
771 					srng->u.dst_ring.tp, false);
772 		write_val = srng->u.dst_ring.tp;
773 	}
774 
775 	hal_srng_update_last_hptp(srng);
776 	hal_srng_reg_his_add(srng, write_val);
777 
778 	q_elem->valid = 0;
779 	srng->last_dequeue_time = q_elem->dequeue_time;
780 	SRNG_UNLOCK(&srng->lock);
781 
782 	return write_val;
783 }
784 
785 /**
786  * hal_reg_write_fill_sched_delay_hist() - fill reg write delay histogram in hal
787  * @hal: hal_soc pointer
788  * @delay_us: delay in us
789  *
790  * Return: None
791  */
hal_reg_write_fill_sched_delay_hist(struct hal_soc * hal,uint64_t delay_us)792 static inline void hal_reg_write_fill_sched_delay_hist(struct hal_soc *hal,
793 						       uint64_t delay_us)
794 {
795 	uint32_t *hist;
796 
797 	hist = hal->stats.wstats.sched_delay;
798 
799 	if (delay_us < 100)
800 		hist[REG_WRITE_SCHED_DELAY_SUB_100us]++;
801 	else if (delay_us < 1000)
802 		hist[REG_WRITE_SCHED_DELAY_SUB_1000us]++;
803 	else if (delay_us < 5000)
804 		hist[REG_WRITE_SCHED_DELAY_SUB_5000us]++;
805 	else
806 		hist[REG_WRITE_SCHED_DELAY_GT_5000us]++;
807 }
808 
809 #ifdef SHADOW_WRITE_DELAY
810 
811 #define SHADOW_WRITE_MIN_DELTA_US	5
812 #define SHADOW_WRITE_DELAY_US		50
813 
814 /*
815  * Never add those srngs which are performance relate.
816  * The delay itself will hit performance heavily.
817  */
818 #define IS_SRNG_MATCH(s)	((s)->ring_id == HAL_SRNG_CE_1_DST_STATUS || \
819 				 (s)->ring_id == HAL_SRNG_CE_1_DST)
820 
hal_reg_write_need_delay(struct hal_reg_write_q_elem * elem)821 static inline bool hal_reg_write_need_delay(struct hal_reg_write_q_elem *elem)
822 {
823 	struct hal_srng *srng = elem->srng;
824 	struct hal_soc *hal;
825 	qdf_time_t now;
826 	qdf_iomem_t real_addr;
827 
828 	if (qdf_unlikely(!srng))
829 		return false;
830 
831 	hal = srng->hal_soc;
832 	if (qdf_unlikely(!hal))
833 		return false;
834 
835 	/* Check if it is target srng, and valid shadow reg */
836 	if (qdf_likely(!IS_SRNG_MATCH(srng)))
837 		return false;
838 
839 	if (srng->ring_dir == HAL_SRNG_SRC_RING)
840 		real_addr = SRNG_SRC_ADDR(srng, HP);
841 	else
842 		real_addr = SRNG_DST_ADDR(srng, TP);
843 	if (!hal_validate_shadow_register(hal, real_addr, elem->addr))
844 		return false;
845 
846 	/* Check the time delta from last write of same srng */
847 	now = qdf_get_log_timestamp();
848 	if (qdf_log_timestamp_to_usecs(now - srng->last_dequeue_time) >
849 		SHADOW_WRITE_MIN_DELTA_US)
850 		return false;
851 
852 	/* Delay dequeue, and record */
853 	qdf_udelay(SHADOW_WRITE_DELAY_US);
854 
855 	srng->wstats.dequeue_delay++;
856 	hal->stats.wstats.dequeue_delay++;
857 
858 	return true;
859 }
860 #else
hal_reg_write_need_delay(struct hal_reg_write_q_elem * elem)861 static inline bool hal_reg_write_need_delay(struct hal_reg_write_q_elem *elem)
862 {
863 	return false;
864 }
865 #endif
866 
867 #define MAX_DELAYED_REG_WRITE_RETRY 5
868 
869 /**
870  * hal_reg_write_work() - Worker to process delayed writes
871  * @arg: hal_soc pointer
872  *
873  * Return: None
874  */
hal_reg_write_work(void * arg)875 static void hal_reg_write_work(void *arg)
876 {
877 	int32_t q_depth, write_val;
878 	struct hal_soc *hal = arg;
879 	struct hal_reg_write_q_elem *q_elem;
880 	uint64_t delta_us;
881 	uint8_t ring_id;
882 	uint32_t *addr;
883 	uint32_t num_processed = 0;
884 	uint8_t retry_count = 0;
885 
886 	q_elem = &hal->reg_write_queue[(hal->read_idx)];
887 	q_elem->work_scheduled_time = qdf_get_log_timestamp();
888 	q_elem->cpu_id = qdf_get_cpu();
889 
890 	/* Make sure q_elem consistent in the memory for multi-cores */
891 	qdf_rmb();
892 	if (!q_elem->valid)
893 		return;
894 
895 	q_depth = qdf_atomic_read(&hal->stats.wstats.q_depth);
896 	if (q_depth > hal->stats.wstats.max_q_depth)
897 		hal->stats.wstats.max_q_depth =  q_depth;
898 
899 	if (hif_prevent_link_low_power_states(hal->hif_handle)) {
900 		hal->stats.wstats.prevent_l1_fails++;
901 		return;
902 	}
903 
904 	while (true) {
905 		qdf_rmb();
906 		if (!q_elem->valid)
907 			break;
908 
909 		qdf_rmb();
910 		/* buy some more time to make sure all fields
911 		 * in q_elem is updated per different CPUs, in
912 		 * case wmb/rmb is not taken effect
913 		 */
914 		if (qdf_unlikely(!q_elem->srng ||
915 				 (qdf_atomic_read(&q_elem->ring_id) !=
916 				 q_elem->srng->ring_id))) {
917 			hal_err_rl("q_elem fields not up to date 0x%x 0x%x",
918 				   q_elem->srng ? q_elem->srng->ring_id : 0xDEAD,
919 				   qdf_atomic_read(&q_elem->ring_id));
920 			if (retry_count++ < MAX_DELAYED_REG_WRITE_RETRY) {
921 				/* Sleep for 1ms before retry */
922 				qdf_sleep(1);
923 				continue;
924 			}
925 			qdf_assert_always(0);
926 		}
927 
928 		q_elem->dequeue_time = qdf_get_log_timestamp();
929 		ring_id = q_elem->srng->ring_id;
930 		addr = q_elem->addr;
931 		delta_us = qdf_log_timestamp_to_usecs(q_elem->dequeue_time -
932 						      q_elem->enqueue_time);
933 		hal_reg_write_fill_sched_delay_hist(hal, delta_us);
934 
935 		hal->stats.wstats.dequeues++;
936 		qdf_atomic_dec(&hal->stats.wstats.q_depth);
937 
938 		if (hal_reg_write_need_delay(q_elem))
939 			hal_verbose_debug("Delay reg writer for srng 0x%x, addr 0x%pK",
940 					  q_elem->srng->ring_id, q_elem->addr);
941 
942 		write_val = hal_process_reg_write_q_elem(hal, q_elem);
943 		hal_verbose_debug("read_idx %u srng 0x%x, addr 0x%pK dequeue_val %u sched delay %llu us",
944 				  hal->read_idx, ring_id, addr, write_val, delta_us);
945 
946 		qdf_trace_dp_del_reg_write(ring_id, q_elem->enqueue_val,
947 					   q_elem->dequeue_val,
948 					   q_elem->enqueue_time,
949 					   q_elem->dequeue_time);
950 
951 		num_processed++;
952 		hal->read_idx = (hal->read_idx + 1) &
953 					(HAL_REG_WRITE_QUEUE_LEN - 1);
954 		q_elem = &hal->reg_write_queue[(hal->read_idx)];
955 		retry_count = 0;
956 	}
957 
958 	hif_allow_link_low_power_states(hal->hif_handle);
959 	/*
960 	 * Decrement active_work_cnt by the number of elements dequeued after
961 	 * hif_allow_link_low_power_states.
962 	 * This makes sure that hif_try_complete_tasks will wait till we make
963 	 * the bus access in hif_allow_link_low_power_states. This will avoid
964 	 * race condition between delayed register worker and bus suspend
965 	 * (system suspend or runtime suspend).
966 	 *
967 	 * The following decrement should be done at the end!
968 	 */
969 	qdf_atomic_sub(num_processed, &hal->active_work_cnt);
970 }
971 
__hal_flush_reg_write_work(struct hal_soc * hal)972 static void __hal_flush_reg_write_work(struct hal_soc *hal)
973 {
974 	qdf_flush_work(&hal->reg_write_work);
975 	qdf_disable_work(&hal->reg_write_work);
976 }
977 
hal_flush_reg_write_work(hal_soc_handle_t hal_handle)978 void hal_flush_reg_write_work(hal_soc_handle_t hal_handle)
979 {	__hal_flush_reg_write_work((struct hal_soc *)hal_handle);
980 }
981 
982 /**
983  * hal_reg_write_enqueue() - enqueue register writes into kworker
984  * @hal_soc: hal_soc pointer
985  * @srng: srng pointer
986  * @addr: iomem address of register
987  * @value: value to be written to iomem address
988  *
989  * This function executes from within the SRNG LOCK
990  *
991  * Return: None
992  */
hal_reg_write_enqueue(struct hal_soc * hal_soc,struct hal_srng * srng,void __iomem * addr,uint32_t value)993 static void hal_reg_write_enqueue(struct hal_soc *hal_soc,
994 				  struct hal_srng *srng,
995 				  void __iomem *addr,
996 				  uint32_t value)
997 {
998 	struct hal_reg_write_q_elem *q_elem;
999 	uint32_t write_idx;
1000 
1001 	if (srng->reg_write_in_progress) {
1002 		hal_verbose_debug("Already in progress srng ring id 0x%x addr 0x%pK val %u",
1003 				  srng->ring_id, addr, value);
1004 		qdf_atomic_inc(&hal_soc->stats.wstats.coalesces);
1005 		srng->wstats.coalesces++;
1006 		return;
1007 	}
1008 
1009 	write_idx = qdf_atomic_inc_return(&hal_soc->write_idx);
1010 
1011 	write_idx = write_idx & (HAL_REG_WRITE_QUEUE_LEN - 1);
1012 
1013 	q_elem = &hal_soc->reg_write_queue[write_idx];
1014 
1015 	if (q_elem->valid) {
1016 		hal_err("queue full");
1017 		QDF_BUG(0);
1018 		return;
1019 	}
1020 
1021 	qdf_atomic_inc(&hal_soc->stats.wstats.enqueues);
1022 	srng->wstats.enqueues++;
1023 
1024 	qdf_atomic_inc(&hal_soc->stats.wstats.q_depth);
1025 
1026 	q_elem->srng = srng;
1027 	q_elem->addr = addr;
1028 	qdf_atomic_set(&q_elem->ring_id, srng->ring_id);
1029 	q_elem->enqueue_val = value;
1030 	q_elem->enqueue_time = qdf_get_log_timestamp();
1031 
1032 	/*
1033 	 * Before the valid flag is set to true, all the other
1034 	 * fields in the q_elem needs to be updated in memory.
1035 	 * Else there is a chance that the dequeuing worker thread
1036 	 * might read stale entries and process incorrect srng.
1037 	 */
1038 	qdf_wmb();
1039 	q_elem->valid = true;
1040 
1041 	/*
1042 	 * After all other fields in the q_elem has been updated
1043 	 * in memory successfully, the valid flag needs to be updated
1044 	 * in memory in time too.
1045 	 * Else there is a chance that the dequeuing worker thread
1046 	 * might read stale valid flag and the work will be bypassed
1047 	 * for this round. And if there is no other work scheduled
1048 	 * later, this hal register writing won't be updated any more.
1049 	 */
1050 	qdf_wmb();
1051 
1052 	srng->reg_write_in_progress  = true;
1053 	qdf_atomic_inc(&hal_soc->active_work_cnt);
1054 
1055 	hal_verbose_debug("write_idx %u srng ring id 0x%x addr 0x%pK val %u",
1056 			  write_idx, srng->ring_id, addr, value);
1057 
1058 	qdf_queue_work(hal_soc->qdf_dev, hal_soc->reg_write_wq,
1059 		       &hal_soc->reg_write_work);
1060 }
1061 
1062 /**
1063  * hal_delayed_reg_write_init() - Initialization function for delayed reg writes
1064  * @hal: hal_soc pointer
1065  *
1066  * Initialize main data structures to process register writes in a delayed
1067  * workqueue.
1068  *
1069  * Return: QDF_STATUS_SUCCESS on success else a QDF error.
1070  */
hal_delayed_reg_write_init(struct hal_soc * hal)1071 static QDF_STATUS hal_delayed_reg_write_init(struct hal_soc *hal)
1072 {
1073 	hal->reg_write_wq =
1074 		qdf_alloc_high_prior_ordered_workqueue("hal_register_write_wq");
1075 	qdf_create_work(0, &hal->reg_write_work, hal_reg_write_work, hal);
1076 	hal->reg_write_queue = qdf_mem_malloc(HAL_REG_WRITE_QUEUE_LEN *
1077 					      sizeof(*hal->reg_write_queue));
1078 	if (!hal->reg_write_queue) {
1079 		hal_err("unable to allocate memory");
1080 		QDF_BUG(0);
1081 		return QDF_STATUS_E_NOMEM;
1082 	}
1083 
1084 	/* Initial value of indices */
1085 	hal->read_idx = 0;
1086 	qdf_atomic_set(&hal->write_idx, -1);
1087 	return QDF_STATUS_SUCCESS;
1088 }
1089 
1090 /**
1091  * hal_delayed_reg_write_deinit() - De-Initialize delayed reg write processing
1092  * @hal: hal_soc pointer
1093  *
1094  * De-initialize main data structures to process register writes in a delayed
1095  * workqueue.
1096  *
1097  * Return: None
1098  */
hal_delayed_reg_write_deinit(struct hal_soc * hal)1099 static void hal_delayed_reg_write_deinit(struct hal_soc *hal)
1100 {
1101 	__hal_flush_reg_write_work(hal);
1102 
1103 	qdf_flush_workqueue(0, hal->reg_write_wq);
1104 	qdf_destroy_workqueue(0, hal->reg_write_wq);
1105 	qdf_mem_free(hal->reg_write_queue);
1106 }
1107 
1108 #else
hal_delayed_reg_write_init(struct hal_soc * hal)1109 static inline QDF_STATUS hal_delayed_reg_write_init(struct hal_soc *hal)
1110 {
1111 	return QDF_STATUS_SUCCESS;
1112 }
1113 
hal_delayed_reg_write_deinit(struct hal_soc * hal)1114 static inline void hal_delayed_reg_write_deinit(struct hal_soc *hal)
1115 {
1116 }
1117 #endif
1118 
1119 #ifdef FEATURE_HAL_DELAYED_REG_WRITE
1120 #ifdef HAL_RECORD_SUSPEND_WRITE
1121 static struct hal_suspend_write_history
1122 		g_hal_suspend_write_history[HAL_SUSPEND_WRITE_HISTORY_MAX];
1123 
1124 static
hal_event_suspend_record(uint8_t ring_id,uint32_t value,uint32_t count)1125 void hal_event_suspend_record(uint8_t ring_id, uint32_t value, uint32_t count)
1126 {
1127 	uint32_t index = qdf_atomic_read(g_hal_suspend_write_history.index) &
1128 					(HAL_SUSPEND_WRITE_HISTORY_MAX - 1);
1129 	struct hal_suspend_write_record *cur_event =
1130 					&hal_suspend_write_event.record[index];
1131 
1132 	cur_event->ts = qdf_get_log_timestamp();
1133 	cur_event->ring_id = ring_id;
1134 	cur_event->value = value;
1135 	cur_event->direct_wcount = count;
1136 	qdf_atomic_inc(g_hal_suspend_write_history.index);
1137 }
1138 
1139 static inline
hal_record_suspend_write(uint8_t ring_id,uint32_t value,uint32_t count)1140 void hal_record_suspend_write(uint8_t ring_id, uint32_t value, uint32_t count)
1141 {
1142 	if (hif_rtpm_get_state() >= HIF_RTPM_STATE_SUSPENDING)
1143 		hal_event_suspend_record(ring_id, value, count);
1144 }
1145 #else
1146 static inline
hal_record_suspend_write(uint8_t ring_id,uint32_t value,uint32_t count)1147 void hal_record_suspend_write(uint8_t ring_id, uint32_t value, uint32_t count)
1148 {
1149 }
1150 #endif
1151 
1152 #ifdef QCA_WIFI_QCA6750
hal_delayed_reg_write(struct hal_soc * hal_soc,struct hal_srng * srng,void __iomem * addr,uint32_t value)1153 void hal_delayed_reg_write(struct hal_soc *hal_soc,
1154 			   struct hal_srng *srng,
1155 			   void __iomem *addr,
1156 			   uint32_t value)
1157 {
1158 	uint8_t vote_access;
1159 
1160 	switch (srng->ring_type) {
1161 	case CE_SRC:
1162 	case CE_DST:
1163 	case CE_DST_STATUS:
1164 		vote_access = hif_get_ep_vote_access(hal_soc->hif_handle,
1165 						     HIF_EP_VOTE_NONDP_ACCESS);
1166 		if ((vote_access == HIF_EP_VOTE_ACCESS_DISABLE) ||
1167 		    (vote_access == HIF_EP_VOTE_INTERMEDIATE_ACCESS &&
1168 		     PLD_MHI_STATE_L0 ==
1169 		     pld_get_mhi_state(hal_soc->qdf_dev->dev))) {
1170 			hal_write_address_32_mb(hal_soc, addr, value, false);
1171 			hal_srng_update_last_hptp(srng);
1172 			hal_srng_reg_his_add(srng, value);
1173 			qdf_atomic_inc(&hal_soc->stats.wstats.direct);
1174 			srng->wstats.direct++;
1175 		} else {
1176 			hal_reg_write_enqueue(hal_soc, srng, addr, value);
1177 		}
1178 		break;
1179 	default:
1180 		if (hif_get_ep_vote_access(hal_soc->hif_handle,
1181 		    HIF_EP_VOTE_DP_ACCESS) ==
1182 		    HIF_EP_VOTE_ACCESS_DISABLE ||
1183 		    hal_is_reg_write_tput_level_high(hal_soc) ||
1184 		    PLD_MHI_STATE_L0 ==
1185 		    pld_get_mhi_state(hal_soc->qdf_dev->dev)) {
1186 			hal_write_address_32_mb(hal_soc, addr, value, false);
1187 			hal_srng_reg_his_add(srng, value);
1188 			qdf_atomic_inc(&hal_soc->stats.wstats.direct);
1189 			srng->wstats.direct++;
1190 		} else {
1191 			hal_reg_write_enqueue(hal_soc, srng, addr, value);
1192 		}
1193 
1194 		break;
1195 	}
1196 }
1197 #else
hal_delayed_reg_write(struct hal_soc * hal_soc,struct hal_srng * srng,void __iomem * addr,uint32_t value)1198 void hal_delayed_reg_write(struct hal_soc *hal_soc,
1199 			   struct hal_srng *srng,
1200 			   void __iomem *addr,
1201 			   uint32_t value)
1202 {
1203 	if (hal_is_reg_write_tput_level_high(hal_soc) ||
1204 	    pld_is_device_awake(hal_soc->qdf_dev->dev)) {
1205 		qdf_atomic_inc(&hal_soc->stats.wstats.direct);
1206 		srng->wstats.direct++;
1207 		hal_write_address_32_mb(hal_soc, addr, value, false);
1208 		hal_srng_update_last_hptp(srng);
1209 		hal_srng_reg_his_add(srng, value);
1210 	} else {
1211 		hal_reg_write_enqueue(hal_soc, srng, addr, value);
1212 	}
1213 
1214 	hal_record_suspend_write(srng->ring_id, value, srng->wstats.direct);
1215 }
1216 #endif
1217 #endif
1218 
1219 #ifdef HAL_SRNG_REG_HIS_DEBUG
hal_free_srng_history(struct hal_soc * hal)1220 inline void hal_free_srng_history(struct hal_soc *hal)
1221 {
1222 	int i;
1223 
1224 	for (i = 0; i < HAL_SRNG_ID_MAX; i++)
1225 		qdf_mem_free(hal->srng_list[i].reg_his_ctx);
1226 }
1227 
hal_alloc_srng_history(struct hal_soc * hal)1228 inline bool hal_alloc_srng_history(struct hal_soc *hal)
1229 {
1230 	int i;
1231 
1232 	for (i = 0; i < HAL_SRNG_ID_MAX; i++) {
1233 		hal->srng_list[i].reg_his_ctx =
1234 			qdf_mem_malloc(sizeof(struct hal_srng_reg_his_ctx));
1235 		if (!hal->srng_list[i].reg_his_ctx) {
1236 			hal_err("srng_hist alloc failed");
1237 			hal_free_srng_history(hal);
1238 			return false;
1239 		}
1240 	}
1241 
1242 	return true;
1243 }
1244 #else
hal_free_srng_history(struct hal_soc * hal)1245 inline void hal_free_srng_history(struct hal_soc *hal)
1246 {
1247 }
1248 
hal_alloc_srng_history(struct hal_soc * hal)1249 inline bool hal_alloc_srng_history(struct hal_soc *hal)
1250 {
1251 	return true;
1252 }
1253 #endif
1254 
hal_attach(struct hif_opaque_softc * hif_handle,qdf_device_t qdf_dev)1255 void *hal_attach(struct hif_opaque_softc *hif_handle, qdf_device_t qdf_dev)
1256 {
1257 	struct hal_soc *hal;
1258 	int i;
1259 
1260 	hal = qdf_mem_common_alloc(sizeof(*hal));
1261 
1262 	if (!hal) {
1263 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR,
1264 			"%s: hal_soc allocation failed", __func__);
1265 		goto fail0;
1266 	}
1267 	hal->hif_handle = hif_handle;
1268 	hal->dev_base_addr = hif_get_dev_ba(hif_handle); /* UMAC */
1269 	hal->dev_base_addr_ce = hif_get_dev_ba_ce(hif_handle); /* CE */
1270 	hal->dev_base_addr_cmem = hif_get_dev_ba_cmem(hif_handle); /* CMEM */
1271 	hal->dev_base_addr_pmm = hif_get_dev_ba_pmm(hif_handle); /* PMM */
1272 	hal->qdf_dev = qdf_dev;
1273 	hal->shadow_rdptr_mem_vaddr = (uint32_t *)qdf_mem_alloc_consistent(
1274 		qdf_dev, qdf_dev->dev, sizeof(*(hal->shadow_rdptr_mem_vaddr)) *
1275 		HAL_SRNG_ID_MAX, &(hal->shadow_rdptr_mem_paddr));
1276 	if (!hal->shadow_rdptr_mem_paddr) {
1277 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR,
1278 			"%s: hal->shadow_rdptr_mem_paddr allocation failed",
1279 			__func__);
1280 		goto fail1;
1281 	}
1282 	qdf_mem_zero(hal->shadow_rdptr_mem_vaddr,
1283 		     sizeof(*(hal->shadow_rdptr_mem_vaddr)) * HAL_SRNG_ID_MAX);
1284 
1285 	hal->shadow_wrptr_mem_vaddr =
1286 		(uint32_t *)qdf_mem_alloc_consistent(qdf_dev, qdf_dev->dev,
1287 		sizeof(*(hal->shadow_wrptr_mem_vaddr)) * HAL_MAX_LMAC_RINGS,
1288 		&(hal->shadow_wrptr_mem_paddr));
1289 	if (!hal->shadow_wrptr_mem_vaddr) {
1290 		QDF_TRACE(QDF_MODULE_ID_TXRX, QDF_TRACE_LEVEL_ERROR,
1291 			"%s: hal->shadow_wrptr_mem_vaddr allocation failed",
1292 			__func__);
1293 		goto fail2;
1294 	}
1295 	qdf_mem_zero(hal->shadow_wrptr_mem_vaddr,
1296 		sizeof(*(hal->shadow_wrptr_mem_vaddr)) * HAL_MAX_LMAC_RINGS);
1297 
1298 	if (!hal_alloc_srng_history(hal))
1299 		goto fail2;
1300 
1301 	for (i = 0; i < HAL_SRNG_ID_MAX; i++) {
1302 		hal->srng_list[i].initialized = 0;
1303 		hal->srng_list[i].ring_id = i;
1304 	}
1305 
1306 	qdf_spinlock_create(&hal->register_access_lock);
1307 	hal->register_window = 0;
1308 	hal->target_type = hal_get_target_type(hal_soc_to_hal_soc_handle(hal));
1309 	hal->version = hif_get_soc_version(hif_handle);
1310 	hal->ops = qdf_mem_malloc(sizeof(*hal->ops));
1311 
1312 	if (!hal->ops) {
1313 		hal_err("unable to allocable memory for HAL ops");
1314 		goto fail3;
1315 	}
1316 
1317 	hal_target_based_configure(hal);
1318 
1319 	hal_reg_write_fail_history_init(hal);
1320 
1321 	qdf_minidump_log(hal, sizeof(*hal), "hal_soc");
1322 
1323 	qdf_ssr_driver_dump_register_region("hal_soc", hal, sizeof(*hal));
1324 
1325 	qdf_atomic_init(&hal->active_work_cnt);
1326 	if (hal_delayed_reg_write_init(hal) != QDF_STATUS_SUCCESS) {
1327 		hal_err("unable to initialize delayed reg write");
1328 		goto fail4;
1329 	}
1330 
1331 	hif_rtpm_register(HIF_RTPM_ID_HAL_REO_CMD, NULL);
1332 
1333 	return (void *)hal;
1334 fail4:
1335 	qdf_ssr_driver_dump_unregister_region("hal_soc");
1336 	qdf_minidump_remove(hal, sizeof(*hal), "hal_soc");
1337 	qdf_mem_free(hal->ops);
1338 fail3:
1339 	qdf_mem_free_consistent(qdf_dev, qdf_dev->dev,
1340 				sizeof(*hal->shadow_wrptr_mem_vaddr) *
1341 				HAL_MAX_LMAC_RINGS,
1342 				hal->shadow_wrptr_mem_vaddr,
1343 				hal->shadow_wrptr_mem_paddr, 0);
1344 fail2:
1345 	qdf_mem_free_consistent(qdf_dev, qdf_dev->dev,
1346 		sizeof(*(hal->shadow_rdptr_mem_vaddr)) * HAL_SRNG_ID_MAX,
1347 		hal->shadow_rdptr_mem_vaddr, hal->shadow_rdptr_mem_paddr, 0);
1348 fail1:
1349 	qdf_mem_common_free(hal);
1350 fail0:
1351 	return NULL;
1352 }
1353 qdf_export_symbol(hal_attach);
1354 
hal_get_meminfo(hal_soc_handle_t hal_soc_hdl,struct hal_mem_info * mem)1355 void hal_get_meminfo(hal_soc_handle_t hal_soc_hdl, struct hal_mem_info *mem)
1356 {
1357 	struct hal_soc *hal = (struct hal_soc *)hal_soc_hdl;
1358 	mem->dev_base_addr = (void *)hal->dev_base_addr;
1359         mem->shadow_rdptr_mem_vaddr = (void *)hal->shadow_rdptr_mem_vaddr;
1360 	mem->shadow_wrptr_mem_vaddr = (void *)hal->shadow_wrptr_mem_vaddr;
1361         mem->shadow_rdptr_mem_paddr = (void *)hal->shadow_rdptr_mem_paddr;
1362 	mem->shadow_wrptr_mem_paddr = (void *)hal->shadow_wrptr_mem_paddr;
1363 	hif_read_phy_mem_base((void *)hal->hif_handle,
1364 			      (qdf_dma_addr_t *)&mem->dev_base_paddr);
1365 	mem->lmac_srng_start_id = HAL_SRNG_LMAC1_ID_START;
1366 	return;
1367 }
1368 qdf_export_symbol(hal_get_meminfo);
1369 
hal_detach(void * hal_soc)1370 void hal_detach(void *hal_soc)
1371 {
1372 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1373 
1374 	hif_rtpm_deregister(HIF_RTPM_ID_HAL_REO_CMD);
1375 	hal_delayed_reg_write_deinit(hal);
1376 	hal_reo_shared_qaddr_detach((hal_soc_handle_t)hal);
1377 	qdf_ssr_driver_dump_unregister_region("hal_soc");
1378 	qdf_minidump_remove(hal, sizeof(*hal), "hal_soc");
1379 	qdf_mem_free(hal->ops);
1380 
1381 	hal_free_srng_history(hal);
1382 	qdf_mem_free_consistent(hal->qdf_dev, hal->qdf_dev->dev,
1383 		sizeof(*(hal->shadow_rdptr_mem_vaddr)) * HAL_SRNG_ID_MAX,
1384 		hal->shadow_rdptr_mem_vaddr, hal->shadow_rdptr_mem_paddr, 0);
1385 	qdf_mem_free_consistent(hal->qdf_dev, hal->qdf_dev->dev,
1386 		sizeof(*(hal->shadow_wrptr_mem_vaddr)) * HAL_MAX_LMAC_RINGS,
1387 		hal->shadow_wrptr_mem_vaddr, hal->shadow_wrptr_mem_paddr, 0);
1388 	qdf_mem_common_free(hal);
1389 
1390 	return;
1391 }
1392 qdf_export_symbol(hal_detach);
1393 
1394 #define HAL_CE_CHANNEL_DST_DEST_CTRL_ADDR(x)		((x) + 0x000000b0)
1395 #define HAL_CE_CHANNEL_DST_DEST_CTRL_DEST_MAX_LENGTH_BMSK	0x0000ffff
1396 #define HAL_CE_CHANNEL_DST_DEST_RING_CONSUMER_PREFETCH_TIMER_ADDR(x)	((x) + 0x00000040)
1397 #define HAL_CE_CHANNEL_DST_DEST_RING_CONSUMER_PREFETCH_TIMER_RMSK	0x00000007
1398 
1399 /**
1400  * hal_ce_dst_setup() - Initialize CE destination ring registers
1401  * @hal: HAL SOC handle
1402  * @srng: SRNG ring pointer
1403  * @ring_num: ring number
1404  */
hal_ce_dst_setup(struct hal_soc * hal,struct hal_srng * srng,int ring_num)1405 static inline void hal_ce_dst_setup(struct hal_soc *hal, struct hal_srng *srng,
1406 				    int ring_num)
1407 {
1408 	uint32_t reg_val = 0;
1409 	uint32_t reg_addr;
1410 	struct hal_hw_srng_config *ring_config =
1411 		HAL_SRNG_CONFIG(hal, CE_DST);
1412 
1413 	/* set DEST_MAX_LENGTH according to ce assignment */
1414 	reg_addr = HAL_CE_CHANNEL_DST_DEST_CTRL_ADDR(
1415 			ring_config->reg_start[R0_INDEX] +
1416 			(ring_num * ring_config->reg_size[R0_INDEX]));
1417 
1418 	reg_val = HAL_REG_READ(hal, reg_addr);
1419 	reg_val &= ~HAL_CE_CHANNEL_DST_DEST_CTRL_DEST_MAX_LENGTH_BMSK;
1420 	reg_val |= srng->u.dst_ring.max_buffer_length &
1421 		HAL_CE_CHANNEL_DST_DEST_CTRL_DEST_MAX_LENGTH_BMSK;
1422 	HAL_REG_WRITE(hal, reg_addr, reg_val);
1423 
1424 	if (srng->prefetch_timer) {
1425 		reg_addr = HAL_CE_CHANNEL_DST_DEST_RING_CONSUMER_PREFETCH_TIMER_ADDR(
1426 				ring_config->reg_start[R0_INDEX] +
1427 				(ring_num * ring_config->reg_size[R0_INDEX]));
1428 
1429 		reg_val = HAL_REG_READ(hal, reg_addr);
1430 		reg_val &= ~HAL_CE_CHANNEL_DST_DEST_RING_CONSUMER_PREFETCH_TIMER_RMSK;
1431 		reg_val |= srng->prefetch_timer;
1432 		HAL_REG_WRITE(hal, reg_addr, reg_val);
1433 		reg_val = HAL_REG_READ(hal, reg_addr);
1434 	}
1435 
1436 }
1437 
hal_reo_read_write_ctrl_ix(hal_soc_handle_t hal_soc_hdl,bool read,uint32_t * ix0,uint32_t * ix1,uint32_t * ix2,uint32_t * ix3)1438 void hal_reo_read_write_ctrl_ix(hal_soc_handle_t hal_soc_hdl, bool read,
1439 				uint32_t *ix0, uint32_t *ix1,
1440 				uint32_t *ix2, uint32_t *ix3)
1441 {
1442 	uint32_t reg_offset;
1443 	struct hal_soc *hal = (struct hal_soc *)hal_soc_hdl;
1444 	uint32_t reo_reg_base;
1445 
1446 	reo_reg_base = hal_get_reo_reg_base_offset(hal_soc_hdl);
1447 
1448 	if (read) {
1449 		if (ix0) {
1450 			reg_offset =
1451 				HAL_REO_DESTINATION_RING_CTRL_IX_0_ADDR(
1452 						reo_reg_base);
1453 			*ix0 = HAL_REG_READ(hal, reg_offset);
1454 		}
1455 
1456 		if (ix1) {
1457 			reg_offset =
1458 				HAL_REO_DESTINATION_RING_CTRL_IX_1_ADDR(
1459 						reo_reg_base);
1460 			*ix1 = HAL_REG_READ(hal, reg_offset);
1461 		}
1462 
1463 		if (ix2) {
1464 			reg_offset =
1465 				HAL_REO_DESTINATION_RING_CTRL_IX_2_ADDR(
1466 						reo_reg_base);
1467 			*ix2 = HAL_REG_READ(hal, reg_offset);
1468 		}
1469 
1470 		if (ix3) {
1471 			reg_offset =
1472 				HAL_REO_DESTINATION_RING_CTRL_IX_3_ADDR(
1473 						reo_reg_base);
1474 			*ix3 = HAL_REG_READ(hal, reg_offset);
1475 		}
1476 	} else {
1477 		if (ix0) {
1478 			reg_offset =
1479 				HAL_REO_DESTINATION_RING_CTRL_IX_0_ADDR(
1480 						reo_reg_base);
1481 			HAL_REG_WRITE_CONFIRM_RETRY(hal, reg_offset,
1482 						    *ix0, true);
1483 		}
1484 
1485 		if (ix1) {
1486 			reg_offset =
1487 				HAL_REO_DESTINATION_RING_CTRL_IX_1_ADDR(
1488 						reo_reg_base);
1489 			HAL_REG_WRITE_CONFIRM_RETRY(hal, reg_offset,
1490 						    *ix1, true);
1491 		}
1492 
1493 		if (ix2) {
1494 			reg_offset =
1495 				HAL_REO_DESTINATION_RING_CTRL_IX_2_ADDR(
1496 						reo_reg_base);
1497 			HAL_REG_WRITE_CONFIRM_RETRY(hal, reg_offset,
1498 						    *ix2, true);
1499 		}
1500 
1501 		if (ix3) {
1502 			reg_offset =
1503 				HAL_REO_DESTINATION_RING_CTRL_IX_3_ADDR(
1504 						reo_reg_base);
1505 			HAL_REG_WRITE_CONFIRM_RETRY(hal, reg_offset,
1506 						    *ix3, true);
1507 		}
1508 	}
1509 }
1510 
1511 qdf_export_symbol(hal_reo_read_write_ctrl_ix);
1512 
hal_srng_dst_set_hp_paddr_confirm(struct hal_srng * srng,uint64_t paddr)1513 void hal_srng_dst_set_hp_paddr_confirm(struct hal_srng *srng, uint64_t paddr)
1514 {
1515 	SRNG_DST_REG_WRITE_CONFIRM(srng, HP_ADDR_LSB, paddr & 0xffffffff);
1516 	SRNG_DST_REG_WRITE_CONFIRM(srng, HP_ADDR_MSB, paddr >> 32);
1517 }
1518 
1519 qdf_export_symbol(hal_srng_dst_set_hp_paddr_confirm);
1520 
hal_srng_dst_init_hp(struct hal_soc_handle * hal_soc,struct hal_srng * srng,uint32_t * vaddr)1521 void hal_srng_dst_init_hp(struct hal_soc_handle *hal_soc,
1522 			  struct hal_srng *srng,
1523 			  uint32_t *vaddr)
1524 {
1525 	uint32_t reg_offset;
1526 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1527 
1528 	if (!srng)
1529 		return;
1530 
1531 	srng->u.dst_ring.hp_addr = vaddr;
1532 	reg_offset = SRNG_DST_ADDR(srng, HP) - hal->dev_base_addr;
1533 	HAL_REG_WRITE_CONFIRM_RETRY(
1534 		hal, reg_offset, srng->u.dst_ring.cached_hp, true);
1535 
1536 	if (vaddr) {
1537 		*srng->u.dst_ring.hp_addr = srng->u.dst_ring.cached_hp;
1538 		QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG,
1539 			  "hp_addr=%pK, cached_hp=%d",
1540 			  (void *)srng->u.dst_ring.hp_addr,
1541 			  srng->u.dst_ring.cached_hp);
1542 	}
1543 }
1544 
1545 qdf_export_symbol(hal_srng_dst_init_hp);
1546 
hal_srng_dst_update_hp_addr(struct hal_soc_handle * hal_soc,hal_ring_handle_t hal_ring_hdl)1547 void hal_srng_dst_update_hp_addr(struct hal_soc_handle *hal_soc,
1548 				 hal_ring_handle_t hal_ring_hdl)
1549 {
1550 	struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
1551 	int32_t hw_hp;
1552 	int32_t hw_tp;
1553 
1554 	if (!srng)
1555 		return;
1556 
1557 	if (srng->u.dst_ring.hp_addr) {
1558 		hal_get_hw_hptp(hal_soc, hal_ring_hdl, &hw_hp, &hw_tp,
1559 				WBM2SW_RELEASE);
1560 		*srng->u.dst_ring.hp_addr = hw_hp;
1561 		QDF_TRACE(QDF_MODULE_ID_DP, QDF_TRACE_LEVEL_DEBUG,
1562 			  "hw_hp=%d", hw_hp);
1563 	}
1564 }
1565 
1566 qdf_export_symbol(hal_srng_dst_update_hp_addr);
1567 
1568 /**
1569  * hal_srng_hw_init - Private function to initialize SRNG HW
1570  * @hal: HAL SOC handle
1571  * @srng: SRNG ring pointer
1572  * @idle_check: Check if ring is idle
1573  * @idx: ring index
1574  */
hal_srng_hw_init(struct hal_soc * hal,struct hal_srng * srng,bool idle_check,uint32_t idx)1575 static inline void hal_srng_hw_init(struct hal_soc *hal,
1576 	struct hal_srng *srng, bool idle_check, uint32_t idx)
1577 {
1578 	if (srng->ring_dir == HAL_SRNG_SRC_RING)
1579 		hal_srng_src_hw_init(hal, srng, idle_check, idx);
1580 	else
1581 		hal_srng_dst_hw_init(hal, srng, idle_check, idx);
1582 }
1583 
1584 #ifdef WLAN_FEATURE_NEAR_FULL_IRQ
hal_srng_is_near_full_irq_supported(hal_soc_handle_t hal_soc,int ring_type,int ring_num)1585 bool hal_srng_is_near_full_irq_supported(hal_soc_handle_t hal_soc,
1586 					 int ring_type, int ring_num)
1587 {
1588 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1589 	struct hal_hw_srng_config *ring_config =
1590 		HAL_SRNG_CONFIG(hal, ring_type);
1591 
1592 	return ring_config->nf_irq_support;
1593 }
1594 
1595 /**
1596  * hal_srng_set_msi2_params() - Set MSI2 params to SRNG data structure from
1597  *				ring params
1598  * @srng: SRNG handle
1599  * @ring_params: ring params for this SRNG
1600  *
1601  * Return: None
1602  */
1603 static inline void
hal_srng_set_msi2_params(struct hal_srng * srng,struct hal_srng_params * ring_params)1604 hal_srng_set_msi2_params(struct hal_srng *srng,
1605 			 struct hal_srng_params *ring_params)
1606 {
1607 	srng->msi2_addr = ring_params->msi2_addr;
1608 	srng->msi2_data = ring_params->msi2_data;
1609 }
1610 
1611 /**
1612  * hal_srng_get_nf_params() - Get the near full MSI2 params from srng
1613  * @srng: SRNG handle
1614  * @ring_params: ring params for this SRNG
1615  *
1616  * Return: None
1617  */
1618 static inline void
hal_srng_get_nf_params(struct hal_srng * srng,struct hal_srng_params * ring_params)1619 hal_srng_get_nf_params(struct hal_srng *srng,
1620 		       struct hal_srng_params *ring_params)
1621 {
1622 	ring_params->msi2_addr = srng->msi2_addr;
1623 	ring_params->msi2_data = srng->msi2_data;
1624 }
1625 
1626 /**
1627  * hal_srng_set_nf_thresholds() - Set the near full thresholds in SRNG
1628  * @srng: SRNG handle where the params are to be set
1629  * @ring_params: ring params, from where threshold is to be fetched
1630  *
1631  * Return: None
1632  */
1633 static inline void
hal_srng_set_nf_thresholds(struct hal_srng * srng,struct hal_srng_params * ring_params)1634 hal_srng_set_nf_thresholds(struct hal_srng *srng,
1635 			   struct hal_srng_params *ring_params)
1636 {
1637 	srng->u.dst_ring.nf_irq_support = ring_params->nf_irq_support;
1638 	srng->u.dst_ring.high_thresh = ring_params->high_thresh;
1639 }
1640 #else
1641 static inline void
hal_srng_set_msi2_params(struct hal_srng * srng,struct hal_srng_params * ring_params)1642 hal_srng_set_msi2_params(struct hal_srng *srng,
1643 			 struct hal_srng_params *ring_params)
1644 {
1645 }
1646 
1647 static inline void
hal_srng_get_nf_params(struct hal_srng * srng,struct hal_srng_params * ring_params)1648 hal_srng_get_nf_params(struct hal_srng *srng,
1649 		       struct hal_srng_params *ring_params)
1650 {
1651 }
1652 
1653 static inline void
hal_srng_set_nf_thresholds(struct hal_srng * srng,struct hal_srng_params * ring_params)1654 hal_srng_set_nf_thresholds(struct hal_srng *srng,
1655 			   struct hal_srng_params *ring_params)
1656 {
1657 }
1658 #endif
1659 
1660 #if defined(CLEAR_SW2TCL_CONSUMED_DESC)
1661 /**
1662  * hal_srng_last_desc_cleared_init - Initialize SRNG last_desc_cleared ptr
1663  * @srng: Source ring pointer
1664  *
1665  * Return: None
1666  */
1667 static inline
hal_srng_last_desc_cleared_init(struct hal_srng * srng)1668 void hal_srng_last_desc_cleared_init(struct hal_srng *srng)
1669 {
1670 	srng->last_desc_cleared = srng->ring_size - srng->entry_size;
1671 }
1672 
1673 #else
1674 static inline
hal_srng_last_desc_cleared_init(struct hal_srng * srng)1675 void hal_srng_last_desc_cleared_init(struct hal_srng *srng)
1676 {
1677 }
1678 #endif /* CLEAR_SW2TCL_CONSUMED_DESC */
1679 
1680 #ifdef WLAN_DP_SRNG_USAGE_WM_TRACKING
hal_srng_update_high_wm_thresholds(struct hal_srng * srng)1681 static inline void hal_srng_update_high_wm_thresholds(struct hal_srng *srng)
1682 {
1683 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_90_to_100] =
1684 			((srng->num_entries * 90) / 100);
1685 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_80_to_90] =
1686 			((srng->num_entries * 80) / 100);
1687 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_70_to_80] =
1688 			((srng->num_entries * 70) / 100);
1689 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_60_to_70] =
1690 			((srng->num_entries * 60) / 100);
1691 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_50_to_60] =
1692 			((srng->num_entries * 50) / 100);
1693 	/* Below 50% threshold is not needed */
1694 	srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_BELOW_50_PERCENT] = 0;
1695 
1696 	hal_info("ring_id: %u, wm_thresh- <50:%u, 50-60:%u, 60-70:%u, 70-80:%u, 80-90:%u, 90-100:%u",
1697 		 srng->ring_id,
1698 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_BELOW_50_PERCENT],
1699 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_50_to_60],
1700 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_60_to_70],
1701 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_70_to_80],
1702 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_80_to_90],
1703 		 srng->high_wm.bin_thresh[HAL_SRNG_HIGH_WM_BIN_90_to_100]);
1704 }
1705 #else
hal_srng_update_high_wm_thresholds(struct hal_srng * srng)1706 static inline void hal_srng_update_high_wm_thresholds(struct hal_srng *srng)
1707 {
1708 }
1709 #endif
1710 
hal_srng_setup_idx(void * hal_soc,int ring_type,int ring_num,int mac_id,struct hal_srng_params * ring_params,bool idle_check,uint32_t idx)1711 void *hal_srng_setup_idx(void *hal_soc, int ring_type, int ring_num, int mac_id,
1712 			 struct hal_srng_params *ring_params, bool idle_check,
1713 			 uint32_t idx)
1714 {
1715 	int ring_id;
1716 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1717 	hal_soc_handle_t hal_hdl = (hal_soc_handle_t)hal;
1718 	struct hal_srng *srng;
1719 	struct hal_hw_srng_config *ring_config =
1720 		HAL_SRNG_CONFIG(hal, ring_type);
1721 	void *dev_base_addr;
1722 	int i;
1723 
1724 	ring_id = hal_get_srng_ring_id(hal_soc, ring_type, ring_num, mac_id);
1725 	if (ring_id < 0)
1726 		return NULL;
1727 
1728 	hal_verbose_debug("mac_id %d ring_id %d", mac_id, ring_id);
1729 
1730 	srng = hal_get_srng(hal_soc, ring_id);
1731 
1732 	if (srng->initialized) {
1733 		hal_verbose_debug("Ring (ring_type, ring_num) already initialized");
1734 		return NULL;
1735 	}
1736 
1737 	hal_srng_reg_his_init(srng);
1738 	dev_base_addr = hal->dev_base_addr;
1739 	srng->ring_id = ring_id;
1740 	srng->ring_type = ring_type;
1741 	srng->ring_dir = ring_config->ring_dir;
1742 	srng->ring_base_paddr = ring_params->ring_base_paddr;
1743 	srng->ring_base_vaddr = ring_params->ring_base_vaddr;
1744 	srng->entry_size = ring_config->entry_size;
1745 	srng->num_entries = ring_params->num_entries;
1746 	srng->ring_size = srng->num_entries * srng->entry_size;
1747 	srng->ring_size_mask = srng->ring_size - 1;
1748 	srng->ring_vaddr_end = srng->ring_base_vaddr + srng->ring_size;
1749 	srng->msi_addr = ring_params->msi_addr;
1750 	srng->msi_data = ring_params->msi_data;
1751 	srng->intr_timer_thres_us = ring_params->intr_timer_thres_us;
1752 	srng->intr_batch_cntr_thres_entries =
1753 		ring_params->intr_batch_cntr_thres_entries;
1754 	srng->pointer_timer_threshold =
1755 		ring_params->pointer_timer_threshold;
1756 	srng->pointer_num_threshold =
1757 		ring_params->pointer_num_threshold;
1758 
1759 	if (!idle_check)
1760 		srng->prefetch_timer = ring_params->prefetch_timer;
1761 	srng->hal_soc = hal_soc;
1762 	hal_srng_set_msi2_params(srng, ring_params);
1763 	hal_srng_update_high_wm_thresholds(srng);
1764 
1765 	for (i = 0 ; i < MAX_SRNG_REG_GROUPS; i++) {
1766 		srng->hwreg_base[i] = dev_base_addr + ring_config->reg_start[i]
1767 			+ (ring_num * ring_config->reg_size[i]);
1768 	}
1769 
1770 	/* Zero out the entire ring memory */
1771 	qdf_mem_zero(srng->ring_base_vaddr, (srng->entry_size *
1772 		srng->num_entries) << 2);
1773 
1774 	srng->flags = ring_params->flags;
1775 
1776 	/* For cached descriptors flush and invalidate the memory*/
1777 	if (srng->flags & HAL_SRNG_CACHED_DESC) {
1778 		qdf_nbuf_dma_clean_range(
1779 				srng->ring_base_vaddr,
1780 				srng->ring_base_vaddr +
1781 				((srng->entry_size * srng->num_entries)));
1782 		qdf_nbuf_dma_inv_range(
1783 				srng->ring_base_vaddr,
1784 				srng->ring_base_vaddr +
1785 				((srng->entry_size * srng->num_entries)));
1786 	}
1787 #ifdef BIG_ENDIAN_HOST
1788 		/* TODO: See if we should we get these flags from caller */
1789 	srng->flags |= HAL_SRNG_DATA_TLV_SWAP;
1790 	srng->flags |= HAL_SRNG_MSI_SWAP;
1791 	srng->flags |= HAL_SRNG_RING_PTR_SWAP;
1792 #endif
1793 
1794 	hal_srng_last_desc_cleared_init(srng);
1795 
1796 	if (srng->ring_dir == HAL_SRNG_SRC_RING) {
1797 		srng->u.src_ring.hp = 0;
1798 		srng->u.src_ring.reap_hp = srng->ring_size -
1799 			srng->entry_size;
1800 		srng->u.src_ring.tp_addr =
1801 			&(hal->shadow_rdptr_mem_vaddr[ring_id]);
1802 		srng->u.src_ring.low_threshold =
1803 			ring_params->low_threshold * srng->entry_size;
1804 
1805 		if (srng->u.src_ring.tp_addr)
1806 			qdf_mem_zero(srng->u.src_ring.tp_addr,
1807 				     sizeof(*hal->shadow_rdptr_mem_vaddr));
1808 
1809 		if (ring_config->lmac_ring) {
1810 			/* For LMAC rings, head pointer updates will be done
1811 			 * through FW by writing to a shared memory location
1812 			 */
1813 			srng->u.src_ring.hp_addr =
1814 				&(hal->shadow_wrptr_mem_vaddr[ring_id -
1815 					HAL_SRNG_LMAC1_ID_START]);
1816 			srng->flags |= HAL_SRNG_LMAC_RING;
1817 
1818 			if (srng->u.src_ring.hp_addr)
1819 				qdf_mem_zero(srng->u.src_ring.hp_addr,
1820 					sizeof(*hal->shadow_wrptr_mem_vaddr));
1821 
1822 		} else if (ignore_shadow || (srng->u.src_ring.hp_addr == 0)) {
1823 			srng->u.src_ring.hp_addr =
1824 				hal_get_window_address(hal,
1825 						SRNG_SRC_ADDR(srng, HP));
1826 
1827 			if (CHECK_SHADOW_REGISTERS) {
1828 				QDF_TRACE(QDF_MODULE_ID_TXRX,
1829 				    QDF_TRACE_LEVEL_ERROR,
1830 				    "%s: Ring (%d, %d) missing shadow config",
1831 				    __func__, ring_type, ring_num);
1832 			}
1833 		} else {
1834 			hal_validate_shadow_register(hal,
1835 						     SRNG_SRC_ADDR(srng, HP),
1836 						     srng->u.src_ring.hp_addr);
1837 		}
1838 	} else {
1839 		/* During initialization loop count in all the descriptors
1840 		 * will be set to zero, and HW will set it to 1 on completing
1841 		 * descriptor update in first loop, and increments it by 1 on
1842 		 * subsequent loops (loop count wraps around after reaching
1843 		 * 0xffff). The 'loop_cnt' in SW ring state is the expected
1844 		 * loop count in descriptors updated by HW (to be processed
1845 		 * by SW).
1846 		 */
1847 		hal_srng_set_nf_thresholds(srng, ring_params);
1848 		srng->u.dst_ring.loop_cnt = 1;
1849 		srng->u.dst_ring.tp = 0;
1850 		srng->u.dst_ring.hp_addr =
1851 			&(hal->shadow_rdptr_mem_vaddr[ring_id]);
1852 
1853 		if (srng->u.dst_ring.hp_addr)
1854 			qdf_mem_zero(srng->u.dst_ring.hp_addr,
1855 				     sizeof(*hal->shadow_rdptr_mem_vaddr));
1856 
1857 		if (ring_config->lmac_ring) {
1858 			/* For LMAC rings, tail pointer updates will be done
1859 			 * through FW by writing to a shared memory location
1860 			 */
1861 			srng->u.dst_ring.tp_addr =
1862 				&(hal->shadow_wrptr_mem_vaddr[ring_id -
1863 				HAL_SRNG_LMAC1_ID_START]);
1864 			srng->flags |= HAL_SRNG_LMAC_RING;
1865 
1866 			if (srng->u.dst_ring.tp_addr)
1867 				qdf_mem_zero(srng->u.dst_ring.tp_addr,
1868 					sizeof(*hal->shadow_wrptr_mem_vaddr));
1869 
1870 		} else if (ignore_shadow || srng->u.dst_ring.tp_addr == 0) {
1871 			srng->u.dst_ring.tp_addr =
1872 				hal_get_window_address(hal,
1873 						SRNG_DST_ADDR(srng, TP));
1874 
1875 			if (CHECK_SHADOW_REGISTERS) {
1876 				QDF_TRACE(QDF_MODULE_ID_TXRX,
1877 				    QDF_TRACE_LEVEL_ERROR,
1878 				    "%s: Ring (%d, %d) missing shadow config",
1879 				    __func__, ring_type, ring_num);
1880 			}
1881 		} else {
1882 			hal_validate_shadow_register(hal,
1883 						     SRNG_DST_ADDR(srng, TP),
1884 						     srng->u.dst_ring.tp_addr);
1885 		}
1886 	}
1887 
1888 	if (!(ring_config->lmac_ring)) {
1889 		/*
1890 		 * UMAC reset has idle check enabled.
1891 		 * During UMAC reset Tx ring halt is set
1892 		 * by Wi-Fi FW during pre-reset stage,
1893 		 * avoid Tx ring halt again.
1894 		 */
1895 		if (idle_check && idx) {
1896 			if (!hal->ops->hal_tx_ring_halt_get(hal_hdl)) {
1897 				qdf_print("\nTx ring halt not set:Ring(%d, %d)",
1898 					  ring_type, ring_num);
1899 				qdf_assert_always(0);
1900 			}
1901 			hal_srng_hw_init(hal, srng, idle_check, idx);
1902 			goto ce_setup;
1903 		}
1904 
1905 		if (idx) {
1906 			hal->ops->hal_tx_ring_halt_set(hal_hdl);
1907 			do {
1908 				hal_info("Waiting for ring reset");
1909 			} while (!(hal->ops->hal_tx_ring_halt_poll(hal_hdl)));
1910 		}
1911 		hal_srng_hw_init(hal, srng, idle_check, idx);
1912 
1913 		if (idx) {
1914 			hal->ops->hal_tx_ring_halt_reset(hal_hdl);
1915 		}
1916 
1917 ce_setup:
1918 		if (ring_type == CE_DST) {
1919 			srng->u.dst_ring.max_buffer_length = ring_params->max_buffer_length;
1920 			hal_ce_dst_setup(hal, srng, ring_num);
1921 		}
1922 	}
1923 
1924 	SRNG_LOCK_INIT(&srng->lock);
1925 
1926 	srng->srng_event = 0;
1927 
1928 	srng->initialized = true;
1929 
1930 	return (void *)srng;
1931 }
1932 qdf_export_symbol(hal_srng_setup_idx);
1933 
1934 /**
1935  * hal_srng_setup - Initialize HW SRNG ring.
1936  * @hal_soc: Opaque HAL SOC handle
1937  * @ring_type: one of the types from hal_ring_type
1938  * @ring_num: Ring number if there are multiple rings of same type (staring
1939  * from 0)
1940  * @mac_id: valid MAC Id should be passed if ring type is one of lmac rings
1941  * @ring_params: SRNG ring params in hal_srng_params structure.
1942  * @idle_check: Check if ring is idle
1943  *
1944  * Callers are expected to allocate contiguous ring memory of size
1945  * 'num_entries * entry_size' bytes and pass the physical and virtual base
1946  * addresses through 'ring_base_paddr' and 'ring_base_vaddr' in
1947  * hal_srng_params structure. Ring base address should be 8 byte aligned
1948  * and size of each ring entry should be queried using the API
1949  * hal_srng_get_entrysize
1950  *
1951  * Return: Opaque pointer to ring on success
1952  *		 NULL on failure (if given ring is not available)
1953  */
hal_srng_setup(void * hal_soc,int ring_type,int ring_num,int mac_id,struct hal_srng_params * ring_params,bool idle_check)1954 void *hal_srng_setup(void *hal_soc, int ring_type, int ring_num,
1955 		     int mac_id, struct hal_srng_params *ring_params,
1956 		     bool idle_check)
1957 {
1958 	return hal_srng_setup_idx(hal_soc, ring_type, ring_num, mac_id,
1959 				  ring_params, idle_check, 0);
1960 }
1961 qdf_export_symbol(hal_srng_setup);
1962 
hal_srng_cleanup(void * hal_soc,hal_ring_handle_t hal_ring_hdl,bool umac_reset_inprogress)1963 void hal_srng_cleanup(void *hal_soc, hal_ring_handle_t hal_ring_hdl,
1964 		      bool umac_reset_inprogress)
1965 {
1966 	struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
1967 	SRNG_LOCK_DESTROY(&srng->lock);
1968 	srng->initialized = 0;
1969 	if (umac_reset_inprogress)
1970 		hal_srng_hw_disable(hal_soc, srng);
1971 }
1972 qdf_export_symbol(hal_srng_cleanup);
1973 
hal_srng_get_entrysize(void * hal_soc,int ring_type)1974 uint32_t hal_srng_get_entrysize(void *hal_soc, int ring_type)
1975 {
1976 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1977 	struct hal_hw_srng_config *ring_config =
1978 		HAL_SRNG_CONFIG(hal, ring_type);
1979 	return ring_config->entry_size << 2;
1980 }
1981 qdf_export_symbol(hal_srng_get_entrysize);
1982 
hal_srng_max_entries(void * hal_soc,int ring_type)1983 uint32_t hal_srng_max_entries(void *hal_soc, int ring_type)
1984 {
1985 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1986 	struct hal_hw_srng_config *ring_config =
1987 		HAL_SRNG_CONFIG(hal, ring_type);
1988 
1989 	return ring_config->max_size / ring_config->entry_size;
1990 }
1991 qdf_export_symbol(hal_srng_max_entries);
1992 
hal_srng_get_dir(void * hal_soc,int ring_type)1993 enum hal_srng_dir hal_srng_get_dir(void *hal_soc, int ring_type)
1994 {
1995 	struct hal_soc *hal = (struct hal_soc *)hal_soc;
1996 	struct hal_hw_srng_config *ring_config =
1997 		HAL_SRNG_CONFIG(hal, ring_type);
1998 
1999 	return ring_config->ring_dir;
2000 }
2001 
hal_srng_dump(struct hal_srng * srng)2002 void hal_srng_dump(struct hal_srng *srng)
2003 {
2004 	if (srng->ring_dir == HAL_SRNG_SRC_RING) {
2005 		hal_debug("=== SRC RING %d ===", srng->ring_id);
2006 		hal_debug("hp %u, reap_hp %u, tp %u, cached tp %u",
2007 			  srng->u.src_ring.hp,
2008 			  srng->u.src_ring.reap_hp,
2009 			  *srng->u.src_ring.tp_addr,
2010 			  srng->u.src_ring.cached_tp);
2011 	} else {
2012 		hal_debug("=== DST RING %d ===", srng->ring_id);
2013 		hal_debug("tp %u, hp %u, cached tp %u, loop_cnt %u",
2014 			  srng->u.dst_ring.tp,
2015 			  *srng->u.dst_ring.hp_addr,
2016 			  srng->u.dst_ring.cached_hp,
2017 			  srng->u.dst_ring.loop_cnt);
2018 	}
2019 }
2020 
hal_get_srng_params(hal_soc_handle_t hal_soc_hdl,hal_ring_handle_t hal_ring_hdl,struct hal_srng_params * ring_params)2021 void hal_get_srng_params(hal_soc_handle_t hal_soc_hdl,
2022 			 hal_ring_handle_t hal_ring_hdl,
2023 			 struct hal_srng_params *ring_params)
2024 {
2025 	struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
2026 	int i =0;
2027 	ring_params->ring_id = srng->ring_id;
2028 	ring_params->ring_dir = srng->ring_dir;
2029 	ring_params->entry_size = srng->entry_size;
2030 
2031 	ring_params->ring_base_paddr = srng->ring_base_paddr;
2032 	ring_params->ring_base_vaddr = srng->ring_base_vaddr;
2033 	ring_params->num_entries = srng->num_entries;
2034 	ring_params->msi_addr = srng->msi_addr;
2035 	ring_params->msi_data = srng->msi_data;
2036 	ring_params->intr_timer_thres_us = srng->intr_timer_thres_us;
2037 	ring_params->intr_batch_cntr_thres_entries =
2038 		srng->intr_batch_cntr_thres_entries;
2039 	ring_params->low_threshold = srng->u.src_ring.low_threshold;
2040 	ring_params->flags = srng->flags;
2041 	ring_params->ring_id = srng->ring_id;
2042 	for (i = 0 ; i < MAX_SRNG_REG_GROUPS; i++)
2043 		ring_params->hwreg_base[i] = srng->hwreg_base[i];
2044 
2045 	hal_srng_get_nf_params(srng, ring_params);
2046 }
2047 qdf_export_symbol(hal_get_srng_params);
2048 
hal_set_low_threshold(hal_ring_handle_t hal_ring_hdl,uint32_t low_threshold)2049 void hal_set_low_threshold(hal_ring_handle_t hal_ring_hdl,
2050 				 uint32_t low_threshold)
2051 {
2052 	struct hal_srng *srng = (struct hal_srng *)hal_ring_hdl;
2053 	srng->u.src_ring.low_threshold = low_threshold * srng->entry_size;
2054 }
2055 qdf_export_symbol(hal_set_low_threshold);
2056 
2057 #ifdef FEATURE_RUNTIME_PM
2058 void
hal_srng_rtpm_access_end(hal_soc_handle_t hal_soc_hdl,hal_ring_handle_t hal_ring_hdl,uint32_t rtpm_id)2059 hal_srng_rtpm_access_end(hal_soc_handle_t hal_soc_hdl,
2060 			 hal_ring_handle_t hal_ring_hdl,
2061 			 uint32_t rtpm_id)
2062 {
2063 	struct hal_soc *hal_soc = (struct hal_soc *)hal_soc_hdl;
2064 
2065 	if (qdf_unlikely(!hal_ring_hdl)) {
2066 		qdf_print("Error: Invalid hal_ring\n");
2067 		return;
2068 	}
2069 
2070 	if (hif_rtpm_get(HIF_RTPM_GET_ASYNC, rtpm_id) == 0) {
2071 		if (hif_system_pm_state_check(hal_soc->hif_handle)) {
2072 			hal_srng_access_end_reap(hal_soc_hdl, hal_ring_hdl);
2073 			hal_srng_set_event(hal_ring_hdl, HAL_SRNG_FLUSH_EVENT);
2074 			hal_srng_inc_flush_cnt(hal_ring_hdl);
2075 		} else {
2076 			hal_srng_access_end(hal_soc_hdl, hal_ring_hdl);
2077 		}
2078 
2079 		hif_rtpm_put(HIF_RTPM_PUT_ASYNC, rtpm_id);
2080 	} else {
2081 		hal_srng_access_end_reap(hal_soc_hdl, hal_ring_hdl);
2082 		hal_srng_set_event(hal_ring_hdl, HAL_SRNG_FLUSH_EVENT);
2083 		hal_srng_inc_flush_cnt(hal_ring_hdl);
2084 	}
2085 }
2086 
2087 qdf_export_symbol(hal_srng_rtpm_access_end);
2088 #endif /* FEATURE_RUNTIME_PM */
2089 
2090 #ifdef FORCE_WAKE
hal_set_init_phase(hal_soc_handle_t soc,bool init_phase)2091 void hal_set_init_phase(hal_soc_handle_t soc, bool init_phase)
2092 {
2093 	struct hal_soc *hal_soc = (struct hal_soc *)soc;
2094 	hal_soc->init_phase = init_phase;
2095 }
2096 #endif /* FORCE_WAKE */
2097