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gerrit-public.fairphone.software / kernel / msm-4.9 / 78647cde29e1c058219b9a9f9b967bcb7d4a5df7 / . / drivers / gpu / drm / msm / sde / sde_hw_interrupts.c
blob: 99aa2e59dd859b572a6e2bc6bf6253fae73208e6 [file] [log] [blame]
Ben Chan78647cd2016-06-26 22:02:47 -0400[diff] [blame^]1/* Copyright (c) 2016, The Linux Foundation. All rights reserved.
2 *
3 * This program is free software; you can redistribute it and/or modify
4 * it under the terms of the GNU General Public License version 2 and
5 * only version 2 as published by the Free Software Foundation.
6 *
7 * This program is distributed in the hope that it will be useful,
8 * but WITHOUT ANY WARRANTY; without even the implied warranty of
9 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
10 * GNU General Public License for more details.
11 */
12
13#include <linux/bitops.h>
14#include <linux/slab.h>
15
16#include "sde_kms.h"
17#include "sde_hw_interrupts.h"
18#include "sde_hw_mdp_util.h"
19#include "sde_hw_mdss.h"
20
21/**
22 * Register offsets in MDSS register file for the interrupt registers
23 * w.r.t. to the MDSS base
24 */
25#define HW_INTR_STATUS 0x0010
26#define MDP_SSPP_TOP0_OFF 0x1000
27#define MDP_INTF_0_OFF 0x6B000
28#define MDP_INTF_1_OFF 0x6B800
29#define MDP_INTF_2_OFF 0x6C000
30#define MDP_INTF_3_OFF 0x6C800
31#define MDP_INTF_4_OFF 0x6D000
32
33/**
34 * WB interrupt status bit definitions
35 */
36#define SDE_INTR_WB_0_DONE BIT(0)
37#define SDE_INTR_WB_1_DONE BIT(1)
38#define SDE_INTR_WB_2_DONE BIT(4)
39
40/**
41 * WDOG timer interrupt status bit definitions
42 */
43#define SDE_INTR_WD_TIMER_0_DONE BIT(2)
44#define SDE_INTR_WD_TIMER_1_DONE BIT(3)
45#define SDE_INTR_WD_TIMER_2_DONE BIT(5)
46#define SDE_INTR_WD_TIMER_3_DONE BIT(6)
47#define SDE_INTR_WD_TIMER_4_DONE BIT(7)
48
49/**
50 * Pingpong interrupt status bit definitions
51 */
52#define SDE_INTR_PING_PONG_0_DONE BIT(8)
53#define SDE_INTR_PING_PONG_1_DONE BIT(9)
54#define SDE_INTR_PING_PONG_2_DONE BIT(10)
55#define SDE_INTR_PING_PONG_3_DONE BIT(11)
56#define SDE_INTR_PING_PONG_0_RD_PTR BIT(12)
57#define SDE_INTR_PING_PONG_1_RD_PTR BIT(13)
58#define SDE_INTR_PING_PONG_2_RD_PTR BIT(14)
59#define SDE_INTR_PING_PONG_3_RD_PTR BIT(15)
60#define SDE_INTR_PING_PONG_0_WR_PTR BIT(16)
61#define SDE_INTR_PING_PONG_1_WR_PTR BIT(17)
62#define SDE_INTR_PING_PONG_2_WR_PTR BIT(18)
63#define SDE_INTR_PING_PONG_3_WR_PTR BIT(19)
64#define SDE_INTR_PING_PONG_0_AUTOREFRESH_DONE BIT(20)
65#define SDE_INTR_PING_PONG_1_AUTOREFRESH_DONE BIT(21)
66#define SDE_INTR_PING_PONG_2_AUTOREFRESH_DONE BIT(22)
67#define SDE_INTR_PING_PONG_3_AUTOREFRESH_DONE BIT(23)
68
69/**
70 * Interface interrupt status bit definitions
71 */
72#define SDE_INTR_INTF_0_UNDERRUN BIT(24)
73#define SDE_INTR_INTF_1_UNDERRUN BIT(26)
74#define SDE_INTR_INTF_2_UNDERRUN BIT(28)
75#define SDE_INTR_INTF_3_UNDERRUN BIT(30)
76#define SDE_INTR_INTF_0_VSYNC BIT(25)
77#define SDE_INTR_INTF_1_VSYNC BIT(27)
78#define SDE_INTR_INTF_2_VSYNC BIT(29)
79#define SDE_INTR_INTF_3_VSYNC BIT(31)
80
81/**
82 * Pingpong Secondary interrupt status bit definitions
83 */
84#define SDE_INTR_PING_PONG_S0_AUTOREFRESH_DONE BIT(0)
85#define SDE_INTR_PING_PONG_S0_WR_PTR BIT(4)
86#define SDE_INTR_PING_PONG_S0_RD_PTR BIT(8)
87#define SDE_INTR_PING_PONG_S0_TEAR_DETECTED BIT(22)
88#define SDE_INTR_PING_PONG_S0_TE_DETECTED BIT(28)
89
90/**
91 * Pingpong TEAR detection interrupt status bit definitions
92 */
93#define SDE_INTR_PING_PONG_0_TEAR_DETECTED BIT(16)
94#define SDE_INTR_PING_PONG_1_TEAR_DETECTED BIT(17)
95#define SDE_INTR_PING_PONG_2_TEAR_DETECTED BIT(18)
96#define SDE_INTR_PING_PONG_3_TEAR_DETECTED BIT(19)
97
98/**
99 * Pingpong TE detection interrupt status bit definitions
100 */
101#define SDE_INTR_PING_PONG_0_TE_DETECTED BIT(24)
102#define SDE_INTR_PING_PONG_1_TE_DETECTED BIT(25)
103#define SDE_INTR_PING_PONG_2_TE_DETECTED BIT(26)
104#define SDE_INTR_PING_PONG_3_TE_DETECTED BIT(27)
105
106/**
107 * Concurrent WB overflow interrupt status bit definitions
108 */
109#define SDE_INTR_CWB_2_OVERFLOW BIT(14)
110#define SDE_INTR_CWB_3_OVERFLOW BIT(15)
111
112/**
113 * Histogram VIG done interrupt status bit definitions
114 */
115#define SDE_INTR_HIST_VIG_0_DONE BIT(0)
116#define SDE_INTR_HIST_VIG_1_DONE BIT(4)
117#define SDE_INTR_HIST_VIG_2_DONE BIT(8)
118#define SDE_INTR_HIST_VIG_3_DONE BIT(10)
119
120/**
121 * Histogram VIG reset Sequence done interrupt status bit definitions
122 */
123#define SDE_INTR_HIST_VIG_0_RSTSEQ_DONE BIT(1)
124#define SDE_INTR_HIST_VIG_1_RSTSEQ_DONE BIT(5)
125#define SDE_INTR_HIST_VIG_2_RSTSEQ_DONE BIT(9)
126#define SDE_INTR_HIST_VIG_3_RSTSEQ_DONE BIT(11)
127
128/**
129 * Histogram DSPP done interrupt status bit definitions
130 */
131#define SDE_INTR_HIST_DSPP_0_DONE BIT(12)
132#define SDE_INTR_HIST_DSPP_1_DONE BIT(16)
133#define SDE_INTR_HIST_DSPP_2_DONE BIT(20)
134#define SDE_INTR_HIST_DSPP_3_DONE BIT(22)
135
136/**
137 * Histogram DSPP reset Sequence done interrupt status bit definitions
138 */
139#define SDE_INTR_HIST_DSPP_0_RSTSEQ_DONE BIT(13)
140#define SDE_INTR_HIST_DSPP_1_RSTSEQ_DONE BIT(17)
141#define SDE_INTR_HIST_DSPP_2_RSTSEQ_DONE BIT(21)
142#define SDE_INTR_HIST_DSPP_3_RSTSEQ_DONE BIT(23)
143
144/**
145 * INTF interrupt status bit definitions
146 */
147#define SDE_INTR_VIDEO_INTO_STATIC BIT(0)
148#define SDE_INTR_VIDEO_OUTOF_STATIC BIT(1)
149#define SDE_INTR_DSICMD_0_INTO_STATIC BIT(2)
150#define SDE_INTR_DSICMD_0_OUTOF_STATIC BIT(3)
151#define SDE_INTR_DSICMD_1_INTO_STATIC BIT(4)
152#define SDE_INTR_DSICMD_1_OUTOF_STATIC BIT(5)
153#define SDE_INTR_DSICMD_2_INTO_STATIC BIT(6)
154#define SDE_INTR_DSICMD_2_OUTOF_STATIC BIT(7)
155#define SDE_INTR_PROG_LINE BIT(8)
156
157/**
158 * struct sde_intr_reg - array of SDE register sets
159 * @clr_off: offset to CLEAR reg
160 * @en_off: offset to ENABLE reg
161 * @status_off: offset to STATUS reg
162 */
163struct sde_intr_reg {
164 u32 clr_off;
165 u32 en_off;
166 u32 status_off;
167};
168
169/**
170 * struct sde_irq_type - maps each irq with i/f
171 * @intr_type: type of interrupt listed in sde_intr_type
172 * @instance_idx: instance index of the associated HW block in SDE
173 * @irq_mask: corresponding bit in the interrupt status reg
174 * @reg_idx: which reg set to use
175 */
176struct sde_irq_type {
177 u32 intr_type;
178 u32 instance_idx;
179 u32 irq_mask;
180 u32 reg_idx;
181};
182
183/**
184 * List of SDE interrupt registers
185 */
186static const struct sde_intr_reg sde_intr_set[] = {
187 {
188 MDP_SSPP_TOP0_OFF+INTR_CLEAR,
189 MDP_SSPP_TOP0_OFF+INTR_EN,
190 MDP_SSPP_TOP0_OFF+INTR_STATUS
191 },
192 {
193 MDP_SSPP_TOP0_OFF+INTR2_CLEAR,
194 MDP_SSPP_TOP0_OFF+INTR2_EN,
195 MDP_SSPP_TOP0_OFF+INTR2_STATUS
196 },
197 {
198 MDP_SSPP_TOP0_OFF+HIST_INTR_CLEAR,
199 MDP_SSPP_TOP0_OFF+HIST_INTR_EN,
200 MDP_SSPP_TOP0_OFF+HIST_INTR_STATUS
201 },
202 {
203 MDP_INTF_0_OFF+INTF_INTR_CLEAR,
204 MDP_INTF_0_OFF+INTF_INTR_EN,
205 MDP_INTF_0_OFF+INTF_INTR_STATUS
206 },
207 {
208 MDP_INTF_1_OFF+INTF_INTR_CLEAR,
209 MDP_INTF_1_OFF+INTF_INTR_EN,
210 MDP_INTF_1_OFF+INTF_INTR_STATUS
211 },
212 {
213 MDP_INTF_2_OFF+INTF_INTR_CLEAR,
214 MDP_INTF_2_OFF+INTF_INTR_EN,
215 MDP_INTF_2_OFF+INTF_INTR_STATUS
216 },
217 {
218 MDP_INTF_3_OFF+INTF_INTR_CLEAR,
219 MDP_INTF_3_OFF+INTF_INTR_EN,
220 MDP_INTF_3_OFF+INTF_INTR_STATUS
221 },
222 {
223 MDP_INTF_4_OFF+INTF_INTR_CLEAR,
224 MDP_INTF_4_OFF+INTF_INTR_EN,
225 MDP_INTF_4_OFF+INTF_INTR_STATUS
226 }
227};
228
229/**
230 * IRQ mapping table - use for lookup an irq_idx in this table that have
231 * a matching interface type and instance index.
232 */
233static const struct sde_irq_type sde_irq_map[] = {
234 /* BEGIN MAP_RANGE: 0-31, INTR */
235 /* irq_idx: 0-3 */
236 { SDE_IRQ_TYPE_WB_ROT_COMP, WB_0, SDE_INTR_WB_0_DONE, 0},
237 { SDE_IRQ_TYPE_WB_ROT_COMP, WB_1, SDE_INTR_WB_1_DONE, 0},
238 { SDE_IRQ_TYPE_WD_TIMER, WD_TIMER_0, SDE_INTR_WD_TIMER_0_DONE, 0},
239 { SDE_IRQ_TYPE_WD_TIMER, WD_TIMER_1, SDE_INTR_WD_TIMER_1_DONE, 0},
240 /* irq_idx: 4-7 */
241 { SDE_IRQ_TYPE_WB_WFD_COMP, WB_2, SDE_INTR_WB_2_DONE, 0},
242 { SDE_IRQ_TYPE_WD_TIMER, WD_TIMER_2, SDE_INTR_WD_TIMER_2_DONE, 0},
243 { SDE_IRQ_TYPE_WD_TIMER, WD_TIMER_3, SDE_INTR_WD_TIMER_3_DONE, 0},
244 { SDE_IRQ_TYPE_WD_TIMER, WD_TIMER_4, SDE_INTR_WD_TIMER_4_DONE, 0},
245 /* irq_idx: 8-11 */
246 { SDE_IRQ_TYPE_PING_PONG_COMP, PINGPONG_0,
247 SDE_INTR_PING_PONG_0_DONE, 0},
248 { SDE_IRQ_TYPE_PING_PONG_COMP, PINGPONG_1,
249 SDE_INTR_PING_PONG_1_DONE, 0},
250 { SDE_IRQ_TYPE_PING_PONG_COMP, PINGPONG_2,
251 SDE_INTR_PING_PONG_2_DONE, 0},
252 { SDE_IRQ_TYPE_PING_PONG_COMP, PINGPONG_3,
253 SDE_INTR_PING_PONG_3_DONE, 0},
254 /* irq_idx: 12-15 */
255 { SDE_IRQ_TYPE_PING_PONG_RD_PTR, PINGPONG_0,
256 SDE_INTR_PING_PONG_0_RD_PTR, 0},
257 { SDE_IRQ_TYPE_PING_PONG_RD_PTR, PINGPONG_1,
258 SDE_INTR_PING_PONG_1_RD_PTR, 0},
259 { SDE_IRQ_TYPE_PING_PONG_RD_PTR, PINGPONG_2,
260 SDE_INTR_PING_PONG_2_RD_PTR, 0},
261 { SDE_IRQ_TYPE_PING_PONG_RD_PTR, PINGPONG_3,
262 SDE_INTR_PING_PONG_3_RD_PTR, 0},
263 /* irq_idx: 16-19 */
264 { SDE_IRQ_TYPE_PING_PONG_WR_PTR, PINGPONG_0,
265 SDE_INTR_PING_PONG_0_WR_PTR, 0},
266 { SDE_IRQ_TYPE_PING_PONG_WR_PTR, PINGPONG_1,
267 SDE_INTR_PING_PONG_1_WR_PTR, 0},
268 { SDE_IRQ_TYPE_PING_PONG_WR_PTR, PINGPONG_2,
269 SDE_INTR_PING_PONG_2_WR_PTR, 0},
270 { SDE_IRQ_TYPE_PING_PONG_WR_PTR, PINGPONG_3,
271 SDE_INTR_PING_PONG_3_WR_PTR, 0},
272 /* irq_idx: 20-23 */
273 { SDE_IRQ_TYPE_PING_PONG_AUTO_REF, PINGPONG_0,
274 SDE_INTR_PING_PONG_0_AUTOREFRESH_DONE, 0},
275 { SDE_IRQ_TYPE_PING_PONG_AUTO_REF, PINGPONG_1,
276 SDE_INTR_PING_PONG_1_AUTOREFRESH_DONE, 0},
277 { SDE_IRQ_TYPE_PING_PONG_AUTO_REF, PINGPONG_2,
278 SDE_INTR_PING_PONG_2_AUTOREFRESH_DONE, 0},
279 { SDE_IRQ_TYPE_PING_PONG_AUTO_REF, PINGPONG_3,
280 SDE_INTR_PING_PONG_3_AUTOREFRESH_DONE, 0},
281 /* irq_idx: 24-27 */
282 { SDE_IRQ_TYPE_INTF_UNDER_RUN, INTF_0, SDE_INTR_INTF_0_UNDERRUN, 0},
283 { SDE_IRQ_TYPE_INTF_VSYNC, INTF_0, SDE_INTR_INTF_0_VSYNC, 0},
284 { SDE_IRQ_TYPE_INTF_UNDER_RUN, INTF_1, SDE_INTR_INTF_1_UNDERRUN, 0},
285 { SDE_IRQ_TYPE_INTF_VSYNC, INTF_1, SDE_INTR_INTF_1_VSYNC, 0},
286 /* irq_idx: 28-31 */
287 { SDE_IRQ_TYPE_INTF_UNDER_RUN, INTF_2, SDE_INTR_INTF_2_UNDERRUN, 0},
288 { SDE_IRQ_TYPE_INTF_VSYNC, INTF_2, SDE_INTR_INTF_2_VSYNC, 0},
289 { SDE_IRQ_TYPE_INTF_UNDER_RUN, INTF_3, SDE_INTR_INTF_3_UNDERRUN, 0},
290 { SDE_IRQ_TYPE_INTF_VSYNC, INTF_3, SDE_INTR_INTF_3_VSYNC, 0},
291
292 /* BEGIN MAP_RANGE: 32-64, INTR2 */
293 /* irq_idx: 32-35 */
294 { SDE_IRQ_TYPE_PING_PONG_AUTO_REF, PINGPONG_S0,
295 SDE_INTR_PING_PONG_S0_AUTOREFRESH_DONE, 1},
296 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
297 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
298 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
299 /* irq_idx: 36-39 */
300 { SDE_IRQ_TYPE_PING_PONG_WR_PTR, PINGPONG_S0,
301 SDE_INTR_PING_PONG_S0_WR_PTR, 1},
302 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
303 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
304 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
305 /* irq_idx: 40-43 */
306 { SDE_IRQ_TYPE_PING_PONG_RD_PTR, PINGPONG_S0,
307 SDE_INTR_PING_PONG_S0_RD_PTR, 1},
308 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
309 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
310 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
311 /* irq_idx: 44-47 */
312 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
313 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
314 { SDE_IRQ_TYPE_CWB_OVERFLOW, CWB_2, SDE_INTR_CWB_2_OVERFLOW, 1},
315 { SDE_IRQ_TYPE_CWB_OVERFLOW, CWB_3, SDE_INTR_CWB_3_OVERFLOW, 1},
316 /* irq_idx: 48-51 */
317 { SDE_IRQ_TYPE_PING_PONG_TEAR_CHECK, PINGPONG_0,
318 SDE_INTR_PING_PONG_0_TEAR_DETECTED, 1},
319 { SDE_IRQ_TYPE_PING_PONG_TEAR_CHECK, PINGPONG_1,
320 SDE_INTR_PING_PONG_1_TEAR_DETECTED, 1},
321 { SDE_IRQ_TYPE_PING_PONG_TEAR_CHECK, PINGPONG_2,
322 SDE_INTR_PING_PONG_2_TEAR_DETECTED, 1},
323 { SDE_IRQ_TYPE_PING_PONG_TEAR_CHECK, PINGPONG_3,
324 SDE_INTR_PING_PONG_3_TEAR_DETECTED, 1},
325 /* irq_idx: 52-55 */
326 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
327 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
328 { SDE_IRQ_TYPE_PING_PONG_TEAR_CHECK, PINGPONG_S0,
329 SDE_INTR_PING_PONG_S0_TEAR_DETECTED, 1},
330 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
331 /* irq_idx: 56-59 */
332 { SDE_IRQ_TYPE_PING_PONG_TE_CHECK, PINGPONG_0,
333 SDE_INTR_PING_PONG_0_TE_DETECTED, 1},
334 { SDE_IRQ_TYPE_PING_PONG_TE_CHECK, PINGPONG_1,
335 SDE_INTR_PING_PONG_1_TE_DETECTED, 1},
336 { SDE_IRQ_TYPE_PING_PONG_TE_CHECK, PINGPONG_2,
337 SDE_INTR_PING_PONG_2_TE_DETECTED, 1},
338 { SDE_IRQ_TYPE_PING_PONG_TE_CHECK, PINGPONG_3,
339 SDE_INTR_PING_PONG_3_TE_DETECTED, 1},
340 /* irq_idx: 60-63 */
341 { SDE_IRQ_TYPE_PING_PONG_TE_CHECK, PINGPONG_S0,
342 SDE_INTR_PING_PONG_S0_TE_DETECTED, 1},
343 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
344 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
345 { SDE_IRQ_TYPE_RESERVED, 0, 0, 1},
346
347 /* BEGIN MAP_RANGE: 64-95 HIST */
348 /* irq_idx: 64-67 */
349 { SDE_IRQ_TYPE_HIST_VIG_DONE, SSPP_VIG0, SDE_INTR_HIST_VIG_0_DONE, 2},
350 { SDE_IRQ_TYPE_HIST_VIG_RSTSEQ, SSPP_VIG0,
351 SDE_INTR_HIST_VIG_0_RSTSEQ_DONE, 2},
352 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
353 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
354 /* irq_idx: 68-71 */
355 { SDE_IRQ_TYPE_HIST_VIG_DONE, SSPP_VIG1, SDE_INTR_HIST_VIG_1_DONE, 2},
356 { SDE_IRQ_TYPE_HIST_VIG_RSTSEQ, SSPP_VIG1,
357 SDE_INTR_HIST_VIG_1_RSTSEQ_DONE, 2},
358 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
359 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
360 /* irq_idx: 68-71 */
361 { SDE_IRQ_TYPE_HIST_VIG_DONE, SSPP_VIG2, SDE_INTR_HIST_VIG_2_DONE, 2},
362 { SDE_IRQ_TYPE_HIST_VIG_RSTSEQ, SSPP_VIG2,
363 SDE_INTR_HIST_VIG_2_RSTSEQ_DONE, 2},
364 { SDE_IRQ_TYPE_HIST_VIG_DONE, SSPP_VIG3, SDE_INTR_HIST_VIG_3_DONE, 2},
365 { SDE_IRQ_TYPE_HIST_VIG_RSTSEQ, SSPP_VIG3,
366 SDE_INTR_HIST_VIG_3_RSTSEQ_DONE, 2},
367 /* irq_idx: 72-75 */
368 { SDE_IRQ_TYPE_HIST_DSPP_DONE, DSPP_0, SDE_INTR_HIST_DSPP_0_DONE, 2},
369 { SDE_IRQ_TYPE_HIST_DSPP_RSTSEQ, DSPP_0,
370 SDE_INTR_HIST_DSPP_0_RSTSEQ_DONE, 2},
371 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
372 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
373 /* irq_idx: 76-79 */
374 { SDE_IRQ_TYPE_HIST_DSPP_DONE, DSPP_1, SDE_INTR_HIST_DSPP_1_DONE, 2},
375 { SDE_IRQ_TYPE_HIST_DSPP_RSTSEQ, DSPP_1,
376 SDE_INTR_HIST_DSPP_1_RSTSEQ_DONE, 2},
377 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
378 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
379 /* irq_idx: 80-83 */
380 { SDE_IRQ_TYPE_HIST_DSPP_DONE, DSPP_2, SDE_INTR_HIST_DSPP_2_DONE, 2},
381 { SDE_IRQ_TYPE_HIST_DSPP_RSTSEQ, DSPP_2,
382 SDE_INTR_HIST_DSPP_2_RSTSEQ_DONE, 2},
383 { SDE_IRQ_TYPE_HIST_DSPP_DONE, DSPP_3, SDE_INTR_HIST_DSPP_3_DONE, 2},
384 { SDE_IRQ_TYPE_HIST_DSPP_RSTSEQ, DSPP_3,
385 SDE_INTR_HIST_DSPP_3_RSTSEQ_DONE, 2},
386 /* irq_idx: 84-87 */
387 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
388 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
389 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
390 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
391 /* irq_idx: 88-91 */
392 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
393 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
394 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
395 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
396 /* irq_idx: 92-95 */
397 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
398 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
399 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
400 { SDE_IRQ_TYPE_RESERVED, 0, 0, 2},
401
402 /* BEGIN MAP_RANGE: 96-127 INTF_0_INTR */
403 /* irq_idx: 96-99 */
404 { SDE_IRQ_TYPE_SFI_VIDEO_IN, INTF_0,
405 SDE_INTR_VIDEO_INTO_STATIC, 3},
406 { SDE_IRQ_TYPE_SFI_VIDEO_OUT, INTF_0,
407 SDE_INTR_VIDEO_OUTOF_STATIC, 3},
408 { SDE_IRQ_TYPE_SFI_CMD_0_IN, INTF_0,
409 SDE_INTR_DSICMD_0_INTO_STATIC, 3},
410 { SDE_IRQ_TYPE_SFI_CMD_0_OUT, INTF_0,
411 SDE_INTR_DSICMD_0_OUTOF_STATIC, 3},
412 /* irq_idx: 100-103 */
413 { SDE_IRQ_TYPE_SFI_CMD_1_IN, INTF_0,
414 SDE_INTR_DSICMD_1_INTO_STATIC, 3},
415 { SDE_IRQ_TYPE_SFI_CMD_1_OUT, INTF_0,
416 SDE_INTR_DSICMD_1_OUTOF_STATIC, 3},
417 { SDE_IRQ_TYPE_SFI_CMD_2_IN, INTF_0,
418 SDE_INTR_DSICMD_2_INTO_STATIC, 3},
419 { SDE_IRQ_TYPE_SFI_CMD_2_OUT, INTF_0,
420 SDE_INTR_DSICMD_2_OUTOF_STATIC, 3},
421 /* irq_idx: 104-107 */
422 { SDE_IRQ_TYPE_PROG_LINE, INTF_0, SDE_INTR_PROG_LINE, 3},
423 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
424 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
425 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
426 /* irq_idx: 108-111 */
427 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
428 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
429 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
430 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
431 /* irq_idx: 112-115 */
432 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
433 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
434 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
435 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
436 /* irq_idx: 116-119 */
437 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
438 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
439 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
440 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
441 /* irq_idx: 120-123 */
442 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
443 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
444 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
445 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
446 /* irq_idx: 124-127 */
447 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
448 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
449 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
450 { SDE_IRQ_TYPE_RESERVED, 0, 0, 3},
451
452 /* BEGIN MAP_RANGE: 128-159 INTF_1_INTR */
453 /* irq_idx: 128-131 */
454 { SDE_IRQ_TYPE_SFI_VIDEO_IN, INTF_1,
455 SDE_INTR_VIDEO_INTO_STATIC, 4},
456 { SDE_IRQ_TYPE_SFI_VIDEO_OUT, INTF_1,
457 SDE_INTR_VIDEO_OUTOF_STATIC, 4},
458 { SDE_IRQ_TYPE_SFI_CMD_0_IN, INTF_1,
459 SDE_INTR_DSICMD_0_INTO_STATIC, 4},
460 { SDE_IRQ_TYPE_SFI_CMD_0_OUT, INTF_1,
461 SDE_INTR_DSICMD_0_OUTOF_STATIC, 4},
462 /* irq_idx: 132-135 */
463 { SDE_IRQ_TYPE_SFI_CMD_1_IN, INTF_1,
464 SDE_INTR_DSICMD_1_INTO_STATIC, 4},
465 { SDE_IRQ_TYPE_SFI_CMD_1_OUT, INTF_1,
466 SDE_INTR_DSICMD_1_OUTOF_STATIC, 4},
467 { SDE_IRQ_TYPE_SFI_CMD_2_IN, INTF_1,
468 SDE_INTR_DSICMD_2_INTO_STATIC, 4},
469 { SDE_IRQ_TYPE_SFI_CMD_2_OUT, INTF_1,
470 SDE_INTR_DSICMD_2_OUTOF_STATIC, 4},
471 /* irq_idx: 136-139 */
472 { SDE_IRQ_TYPE_PROG_LINE, INTF_1, SDE_INTR_PROG_LINE, 4},
473 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
474 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
475 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
476 /* irq_idx: 140-143 */
477 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
478 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
479 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
480 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
481 /* irq_idx: 144-147 */
482 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
483 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
484 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
485 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
486 /* irq_idx: 148-151 */
487 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
488 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
489 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
490 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
491 /* irq_idx: 152-155 */
492 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
493 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
494 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
495 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
496 /* irq_idx: 156-159 */
497 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
498 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
499 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
500 { SDE_IRQ_TYPE_RESERVED, 0, 0, 4},
501
502 /* BEGIN MAP_RANGE: 160-191 INTF_2_INTR */
503 /* irq_idx: 160-163 */
504 { SDE_IRQ_TYPE_SFI_VIDEO_IN, INTF_2,
505 SDE_INTR_VIDEO_INTO_STATIC, 5},
506 { SDE_IRQ_TYPE_SFI_VIDEO_OUT, INTF_2,
507 SDE_INTR_VIDEO_OUTOF_STATIC, 5},
508 { SDE_IRQ_TYPE_SFI_CMD_0_IN, INTF_2,
509 SDE_INTR_DSICMD_0_INTO_STATIC, 5},
510 { SDE_IRQ_TYPE_SFI_CMD_0_OUT, INTF_2,
511 SDE_INTR_DSICMD_0_OUTOF_STATIC, 5},
512 /* irq_idx: 164-167 */
513 { SDE_IRQ_TYPE_SFI_CMD_1_IN, INTF_2,
514 SDE_INTR_DSICMD_1_INTO_STATIC, 5},
515 { SDE_IRQ_TYPE_SFI_CMD_1_OUT, INTF_2,
516 SDE_INTR_DSICMD_1_OUTOF_STATIC, 5},
517 { SDE_IRQ_TYPE_SFI_CMD_2_IN, INTF_2,
518 SDE_INTR_DSICMD_2_INTO_STATIC, 5},
519 { SDE_IRQ_TYPE_SFI_CMD_2_OUT, INTF_2,
520 SDE_INTR_DSICMD_2_OUTOF_STATIC, 5},
521 /* irq_idx: 168-171 */
522 { SDE_IRQ_TYPE_PROG_LINE, INTF_2, SDE_INTR_PROG_LINE, 5},
523 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
524 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
525 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
526 /* irq_idx: 172-175 */
527 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
528 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
529 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
530 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
531 /* irq_idx: 176-179 */
532 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
533 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
534 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
535 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
536 /* irq_idx: 180-183 */
537 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
538 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
539 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
540 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
541 /* irq_idx: 184-187 */
542 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
543 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
544 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
545 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
546 /* irq_idx: 188-191 */
547 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
548 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
549 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
550 { SDE_IRQ_TYPE_RESERVED, 0, 0, 5},
551
552 /* BEGIN MAP_RANGE: 192-223 INTF_3_INTR */
553 /* irq_idx: 192-195 */
554 { SDE_IRQ_TYPE_SFI_VIDEO_IN, INTF_3,
555 SDE_INTR_VIDEO_INTO_STATIC, 6},
556 { SDE_IRQ_TYPE_SFI_VIDEO_OUT, INTF_3,
557 SDE_INTR_VIDEO_OUTOF_STATIC, 6},
558 { SDE_IRQ_TYPE_SFI_CMD_0_IN, INTF_3,
559 SDE_INTR_DSICMD_0_INTO_STATIC, 6},
560 { SDE_IRQ_TYPE_SFI_CMD_0_OUT, INTF_3,
561 SDE_INTR_DSICMD_0_OUTOF_STATIC, 6},
562 /* irq_idx: 196-199 */
563 { SDE_IRQ_TYPE_SFI_CMD_1_IN, INTF_3,
564 SDE_INTR_DSICMD_1_INTO_STATIC, 6},
565 { SDE_IRQ_TYPE_SFI_CMD_1_OUT, INTF_3,
566 SDE_INTR_DSICMD_1_OUTOF_STATIC, 6},
567 { SDE_IRQ_TYPE_SFI_CMD_2_IN, INTF_3,
568 SDE_INTR_DSICMD_2_INTO_STATIC, 6},
569 { SDE_IRQ_TYPE_SFI_CMD_2_OUT, INTF_3,
570 SDE_INTR_DSICMD_2_OUTOF_STATIC, 6},
571 /* irq_idx: 200-203 */
572 { SDE_IRQ_TYPE_PROG_LINE, INTF_3, SDE_INTR_PROG_LINE, 6},
573 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
574 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
575 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
576 /* irq_idx: 204-207 */
577 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
578 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
579 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
580 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
581 /* irq_idx: 208-211 */
582 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
583 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
584 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
585 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
586 /* irq_idx: 212-215 */
587 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
588 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
589 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
590 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
591 /* irq_idx: 216-219 */
592 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
593 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
594 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
595 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
596 /* irq_idx: 220-223 */
597 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
598 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
599 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
600 { SDE_IRQ_TYPE_RESERVED, 0, 0, 6},
601
602 /* BEGIN MAP_RANGE: 224-255 INTF_4_INTR */
603 /* irq_idx: 224-227 */
604 { SDE_IRQ_TYPE_SFI_VIDEO_IN, INTF_4,
605 SDE_INTR_VIDEO_INTO_STATIC, 7},
606 { SDE_IRQ_TYPE_SFI_VIDEO_OUT, INTF_4,
607 SDE_INTR_VIDEO_OUTOF_STATIC, 7},
608 { SDE_IRQ_TYPE_SFI_CMD_0_IN, INTF_4,
609 SDE_INTR_DSICMD_0_INTO_STATIC, 7},
610 { SDE_IRQ_TYPE_SFI_CMD_0_OUT, INTF_4,
611 SDE_INTR_DSICMD_0_OUTOF_STATIC, 7},
612 /* irq_idx: 228-231 */
613 { SDE_IRQ_TYPE_SFI_CMD_1_IN, INTF_4,
614 SDE_INTR_DSICMD_1_INTO_STATIC, 7},
615 { SDE_IRQ_TYPE_SFI_CMD_1_OUT, INTF_4,
616 SDE_INTR_DSICMD_1_OUTOF_STATIC, 7},
617 { SDE_IRQ_TYPE_SFI_CMD_2_IN, INTF_4,
618 SDE_INTR_DSICMD_2_INTO_STATIC, 7},
619 { SDE_IRQ_TYPE_SFI_CMD_2_OUT, INTF_4,
620 SDE_INTR_DSICMD_2_OUTOF_STATIC, 7},
621 /* irq_idx: 232-235 */
622 { SDE_IRQ_TYPE_PROG_LINE, INTF_4, SDE_INTR_PROG_LINE, 7},
623 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
624 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
625 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
626 /* irq_idx: 236-239 */
627 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
628 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
629 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
630 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
631 /* irq_idx: 240-243 */
632 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
633 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
634 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
635 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
636 /* irq_idx: 244-247 */
637 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
638 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
639 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
640 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
641 /* irq_idx: 248-251 */
642 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
643 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
644 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
645 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
646 /* irq_idx: 252-255 */
647 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
648 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
649 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
650 { SDE_IRQ_TYPE_RESERVED, 0, 0, 7},
651};
652
653static int sde_hw_intr_irqidx_lookup(enum sde_intr_type intr_type,
654 u32 instance_idx)
655{
656 int i;
657
658 for (i = 0; i < ARRAY_SIZE(sde_irq_map); i++) {
659 if (intr_type == sde_irq_map[i].intr_type &&
660 instance_idx == sde_irq_map[i].instance_idx)
661 return i;
662 }
663
664 pr_debug("IRQ lookup fail!! intr_type=%d, instance_idx=%d\n",
665 intr_type, instance_idx);
666 return -EINVAL;
667}
668
669static void sde_hw_intr_set_mask(struct sde_hw_intr *intr, uint32_t reg_off,
670 uint32_t mask)
671{
672 SDE_REG_WRITE(&intr->hw, reg_off, mask);
673}
674
675static void sde_hw_intr_dispatch_irq(struct sde_hw_intr *intr,
676 void (*cbfunc)(void *, int),
677 void *arg)
678{
679 int reg_idx;
680 int irq_idx;
681 int start_idx;
682 int end_idx;
683 u32 irq_status;
684 unsigned long irq_flags;
685
686 /*
687 * The dispatcher will save the IRQ status before calling here.
688 * Now need to go through each IRQ status and find matching
689 * irq lookup index.
690 */
691 spin_lock_irqsave(&intr->status_lock, irq_flags);
692 for (reg_idx = 0; reg_idx < ARRAY_SIZE(sde_intr_set); reg_idx++) {
693 irq_status = intr->save_irq_status[reg_idx];
694
695 /*
696 * Each Interrupt register has a range of 32 indexes, and
697 * that is static for sde_irq_map.
698 */
699 start_idx = reg_idx * 32;
700 end_idx = start_idx + 32;
701
702 /*
703 * Search through matching intr status from irq map.
704 * start_idx and end_idx defined the search range in
705 * the sde_irq_map.
706 */
707 for (irq_idx = start_idx;
708 (irq_idx < end_idx) && irq_status;
709 irq_idx++)
710 if ((irq_status & sde_irq_map[irq_idx].irq_mask) &&
711 (sde_irq_map[irq_idx].reg_idx == reg_idx)) {
712 /*
713 * Once a match on irq mask, perform a callback
714 * to the given cbfunc. cbfunc will take care
715 * the interrupt status clearing. If cbfunc is
716 * not provided, then the interrupt clearing
717 * is here.
718 */
719 if (cbfunc)
720 cbfunc(arg, irq_idx);
721 else
722 intr->ops.clear_interrupt_status(
723 intr, irq_idx);
724
725 /*
726 * When callback finish, clear the irq_status
727 * with the matching mask. Once irq_status
728 * is all cleared, the search can be stopped.
729 */
730 irq_status &= ~sde_irq_map[irq_idx].irq_mask;
731 }
732 }
733 spin_unlock_irqrestore(&intr->status_lock, irq_flags);
734}
735
736static int sde_hw_intr_enable_irq(struct sde_hw_intr *intr, int irq_idx)
737{
738 int reg_idx;
739 unsigned long irq_flags;
740 const struct sde_intr_reg *reg;
741 const struct sde_irq_type *irq;
742 const char *dbgstr = NULL;
743 uint32_t cache_irq_mask;
744
745 if (irq_idx < 0 || irq_idx >= ARRAY_SIZE(sde_irq_map)) {
746 pr_err("invalid IRQ index: [%d]\n", irq_idx);
747 return -EINVAL;
748 }
749
750 irq = &sde_irq_map[irq_idx];
751 reg_idx = irq->reg_idx;
752 reg = &sde_intr_set[reg_idx];
753
754 spin_lock_irqsave(&intr->mask_lock, irq_flags);
755 cache_irq_mask = intr->cache_irq_mask[reg_idx];
756 if (cache_irq_mask & irq->irq_mask) {
757 dbgstr = "SDE IRQ already set:";
758 } else {
759 dbgstr = "SDE IRQ enabled:";
760
761 cache_irq_mask |= irq->irq_mask;
762 /* Cleaning any pending interrupt */
763 SDE_REG_WRITE(&intr->hw, reg->clr_off, irq->irq_mask);
764 /* Enabling interrupts with the new mask */
765 SDE_REG_WRITE(&intr->hw, reg->en_off, cache_irq_mask);
766
767 intr->cache_irq_mask[reg_idx] = cache_irq_mask;
768 }
769 spin_unlock_irqrestore(&intr->mask_lock, irq_flags);
770
771 pr_debug("%s MASK:0x%.8x, CACHE-MASK:0x%.8x\n", dbgstr,
772 irq->irq_mask, cache_irq_mask);
773
774 return 0;
775}
776
777static int sde_hw_intr_disable_irq(struct sde_hw_intr *intr, int irq_idx)
778{
779 int reg_idx;
780 unsigned long irq_flags;
781 const struct sde_intr_reg *reg;
782 const struct sde_irq_type *irq;
783 const char *dbgstr = NULL;
784 uint32_t cache_irq_mask;
785
786 if (irq_idx < 0 || irq_idx >= ARRAY_SIZE(sde_irq_map)) {
787 pr_err("invalid IRQ index: [%d]\n", irq_idx);
788 return -EINVAL;
789 }
790
791 irq = &sde_irq_map[irq_idx];
792 reg_idx = irq->reg_idx;
793 reg = &sde_intr_set[reg_idx];
794
795 spin_lock_irqsave(&intr->mask_lock, irq_flags);
796 cache_irq_mask = intr->cache_irq_mask[reg_idx];
797 if ((cache_irq_mask & irq->irq_mask) == 0) {
798 dbgstr = "SDE IRQ is already cleared:";
799 } else {
800 dbgstr = "SDE IRQ mask disable:";
801
802 cache_irq_mask &= ~irq->irq_mask;
803 /* Disable interrupts based on the new mask */
804 SDE_REG_WRITE(&intr->hw, reg->en_off, cache_irq_mask);
805 /* Cleaning any pending interrupt */
806 SDE_REG_WRITE(&intr->hw, reg->clr_off, irq->irq_mask);
807
808 intr->cache_irq_mask[reg_idx] = cache_irq_mask;
809 }
810 spin_unlock_irqrestore(&intr->mask_lock, irq_flags);
811
812 pr_debug("%s MASK:0x%.8x, CACHE-MASK:0x%.8x\n", dbgstr,
813 irq->irq_mask, cache_irq_mask);
814
815 return 0;
816}
817
818static int sde_hw_intr_clear_irqs(struct sde_hw_intr *intr)
819{
820 int i;
821
822 for (i = 0; i < ARRAY_SIZE(sde_intr_set); i++)
823 SDE_REG_WRITE(&intr->hw, sde_intr_set[i].clr_off, 0xffffffff);
824
825 return 0;
826}
827
828static int sde_hw_intr_disable_irqs(struct sde_hw_intr *intr)
829{
830 int i;
831
832 for (i = 0; i < ARRAY_SIZE(sde_intr_set); i++)
833 SDE_REG_WRITE(&intr->hw, sde_intr_set[i].en_off, 0x00000000);
834
835 return 0;
836}
837
838static int sde_hw_intr_get_valid_interrupts(struct sde_hw_intr *intr,
839 uint32_t *mask)
840{
841 *mask = IRQ_SOURCE_MDP | IRQ_SOURCE_DSI0 | IRQ_SOURCE_DSI1
842 | IRQ_SOURCE_HDMI | IRQ_SOURCE_EDP;
843 return 0;
844}
845
846static int sde_hw_intr_get_interrupt_sources(struct sde_hw_intr *intr,
847 uint32_t *sources)
848{
849 *sources = SDE_REG_READ(&intr->hw, HW_INTR_STATUS);
850 return 0;
851}
852
853static void sde_hw_intr_get_interrupt_statuses(struct sde_hw_intr *intr)
854{
855 int i;
856 u32 enable_mask;
857 unsigned long irq_flags;
858
859 spin_lock_irqsave(&intr->status_lock, irq_flags);
860 for (i = 0; i < ARRAY_SIZE(sde_intr_set); i++) {
861 /* Read interrupt status */
862 intr->save_irq_status[i] = SDE_REG_READ(&intr->hw,
863 sde_intr_set[i].status_off);
864
865 /* Read enable mask */
866 enable_mask = SDE_REG_READ(&intr->hw, sde_intr_set[i].en_off);
867
868 /* and clear the interrupt */
869 if (intr->save_irq_status[i])
870 SDE_REG_WRITE(&intr->hw, sde_intr_set[i].clr_off,
871 intr->save_irq_status[i]);
872
873 /* Finally update IRQ status based on enable mask */
874 intr->save_irq_status[i] &= enable_mask;
875 }
876 spin_unlock_irqrestore(&intr->status_lock, irq_flags);
877}
878
879static void sde_hw_intr_clear_interrupt_status(struct sde_hw_intr *intr,
880 int irq_idx)
881{
882 int reg_idx;
883 unsigned long irq_flags;
884
885 spin_lock_irqsave(&intr->mask_lock, irq_flags);
886
887 reg_idx = sde_irq_map[irq_idx].reg_idx;
888 SDE_REG_WRITE(&intr->hw, sde_intr_set[reg_idx].clr_off,
889 sde_irq_map[irq_idx].irq_mask);
890
891 spin_unlock_irqrestore(&intr->mask_lock, irq_flags);
892}
893
894
895static void __setup_intr_ops(struct sde_hw_intr_ops *ops)
896{
897 ops->set_mask = sde_hw_intr_set_mask;
898 ops->irq_idx_lookup = sde_hw_intr_irqidx_lookup;
899 ops->enable_irq = sde_hw_intr_enable_irq;
900 ops->disable_irq = sde_hw_intr_disable_irq;
901 ops->dispatch_irqs = sde_hw_intr_dispatch_irq;
902 ops->clear_all_irqs = sde_hw_intr_clear_irqs;
903 ops->disable_all_irqs = sde_hw_intr_disable_irqs;
904 ops->get_valid_interrupts = sde_hw_intr_get_valid_interrupts;
905 ops->get_interrupt_sources = sde_hw_intr_get_interrupt_sources;
906 ops->get_interrupt_statuses = sde_hw_intr_get_interrupt_statuses;
907 ops->clear_interrupt_status = sde_hw_intr_clear_interrupt_status;
908}
909
910static struct sde_mdss_base_cfg *__intr_offset(struct sde_mdss_cfg *m,
911 void __iomem *addr, struct sde_hw_blk_reg_map *hw)
912{
913 if (m->mdp_count == 0)
914 return NULL;
915
916 hw->base_off = addr;
917 hw->blk_off = m->mdss[0].base;
918 hw->hwversion = m->hwversion;
919 return &m->mdss[0];
920}
921
922struct sde_hw_intr *sde_hw_intr_init(void __iomem *addr,
923 struct sde_mdss_cfg *m)
924{
925 struct sde_hw_intr *intr = kzalloc(sizeof(*intr), GFP_KERNEL);
926 struct sde_mdss_base_cfg *cfg;
927
928 if (!intr)
929 return ERR_PTR(-ENOMEM);
930
931 cfg = __intr_offset(m, addr, &intr->hw);
932 if (!cfg) {
933 kfree(intr);
934 return ERR_PTR(-EINVAL);
935 }
936 __setup_intr_ops(&intr->ops);
937
938 intr->irq_idx_tbl_size = ARRAY_SIZE(sde_irq_map);
939
940 intr->cache_irq_mask = kcalloc(ARRAY_SIZE(sde_intr_set), sizeof(u32),
941 GFP_KERNEL);
942 if (intr->cache_irq_mask == NULL) {
943 kfree(intr);
944 return ERR_PTR(-ENOMEM);
945 }
946
947 intr->save_irq_status = kcalloc(ARRAY_SIZE(sde_intr_set), sizeof(u32),
948 GFP_KERNEL);
949 if (intr->save_irq_status == NULL) {
950 kfree(intr->cache_irq_mask);
951 kfree(intr);
952 return ERR_PTR(-ENOMEM);
953 }
954
955 spin_lock_init(&intr->mask_lock);
956 spin_lock_init(&intr->status_lock);
957
958 return intr;
959}
960
961void sde_hw_intr_destroy(struct sde_hw_intr *intr)
962{
963 if (intr) {
964 kfree(intr->cache_irq_mask);
965 kfree(intr->save_irq_status);
966 kfree(intr);
967 }
968}
969