xref: /dragonfly/sys/dev/drm/amd/display/dc/dcn10/dcn10_opp.c (revision 789731325bde747251c28a37e0a00ed4efb88c46)
1 /*
2  * Copyright 2012-15 Advanced Micro Devices, Inc.
3  *
4  * Permission is hereby granted, free of charge, to any person obtaining a
5  * copy of this software and associated documentation files (the "Software"),
6  * to deal in the Software without restriction, including without limitation
7  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8  * and/or sell copies of the Software, and to permit persons to whom the
9  * Software is furnished to do so, subject to the following conditions:
10  *
11  * The above copyright notice and this permission notice shall be included in
12  * all copies or substantial portions of the Software.
13  *
14  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
15  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
16  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
17  * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR
18  * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
19  * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
20  * OTHER DEALINGS IN THE SOFTWARE.
21  *
22  * Authors: AMD
23  *
24  */
25 
26 #include "dm_services.h"
27 #include "dcn10_opp.h"
28 #include "reg_helper.h"
29 
30 #define REG(reg) \
31           (oppn10->regs->reg)
32 
33 #undef FN
34 #define FN(reg_name, field_name) \
35           oppn10->opp_shift->field_name, oppn10->opp_mask->field_name
36 
37 #define CTX \
38           oppn10->base.ctx
39 
40 
41 /************* FORMATTER ************/
42 
43 /**
44  *        set_truncation
45  *        1) set truncation depth: 0 for 18 bpp or 1 for 24 bpp
46  *        2) enable truncation
47  *        3) HW remove 12bit FMT support for DCE11 power saving reason.
48  */
opp1_set_truncation(struct dcn10_opp * oppn10,const struct bit_depth_reduction_params * params)49 static void opp1_set_truncation(
50                     struct dcn10_opp *oppn10,
51                     const struct bit_depth_reduction_params *params)
52 {
53           REG_UPDATE_3(FMT_BIT_DEPTH_CONTROL,
54                     FMT_TRUNCATE_EN, params->flags.TRUNCATE_ENABLED,
55                     FMT_TRUNCATE_DEPTH, params->flags.TRUNCATE_DEPTH,
56                     FMT_TRUNCATE_MODE, params->flags.TRUNCATE_MODE);
57 }
58 
opp1_set_spatial_dither(struct dcn10_opp * oppn10,const struct bit_depth_reduction_params * params)59 static void opp1_set_spatial_dither(
60           struct dcn10_opp *oppn10,
61           const struct bit_depth_reduction_params *params)
62 {
63           /*Disable spatial (random) dithering*/
64           REG_UPDATE_7(FMT_BIT_DEPTH_CONTROL,
65                               FMT_SPATIAL_DITHER_EN, 0,
66                               FMT_SPATIAL_DITHER_MODE, 0,
67                               FMT_SPATIAL_DITHER_DEPTH, 0,
68                               FMT_TEMPORAL_DITHER_EN, 0,
69                               FMT_HIGHPASS_RANDOM_ENABLE, 0,
70                               FMT_FRAME_RANDOM_ENABLE, 0,
71                               FMT_RGB_RANDOM_ENABLE, 0);
72 
73 
74           /* only use FRAME_COUNTER_MAX if frameRandom == 1*/
75           if (params->flags.FRAME_RANDOM == 1) {
76                     if (params->flags.SPATIAL_DITHER_DEPTH == 0 || params->flags.SPATIAL_DITHER_DEPTH == 1) {
77                               REG_UPDATE_2(FMT_CONTROL,
78                                                   FMT_SPATIAL_DITHER_FRAME_COUNTER_MAX, 15,
79                                                   FMT_SPATIAL_DITHER_FRAME_COUNTER_BIT_SWAP, 2);
80                     } else if (params->flags.SPATIAL_DITHER_DEPTH == 2) {
81                               REG_UPDATE_2(FMT_CONTROL,
82                                                   FMT_SPATIAL_DITHER_FRAME_COUNTER_MAX, 3,
83                                                   FMT_SPATIAL_DITHER_FRAME_COUNTER_BIT_SWAP, 1);
84                     } else {
85                               return;
86                     }
87           } else {
88                     REG_UPDATE_2(FMT_CONTROL,
89                                         FMT_SPATIAL_DITHER_FRAME_COUNTER_MAX, 0,
90                                         FMT_SPATIAL_DITHER_FRAME_COUNTER_BIT_SWAP, 0);
91           }
92 
93           /*Set seed for random values for
94            * spatial dithering for R,G,B channels*/
95 
96           REG_SET(FMT_DITHER_RAND_R_SEED, 0,
97                               FMT_RAND_R_SEED, params->r_seed_value);
98 
99           REG_SET(FMT_DITHER_RAND_G_SEED, 0,
100                               FMT_RAND_G_SEED, params->g_seed_value);
101 
102           REG_SET(FMT_DITHER_RAND_B_SEED, 0,
103                               FMT_RAND_B_SEED, params->b_seed_value);
104 
105           /* FMT_OFFSET_R_Cr  31:16 0x0 Setting the zero
106            * offset for the R/Cr channel, lower 4LSB
107            * is forced to zeros. Typically set to 0
108            * RGB and 0x80000 YCbCr.
109            */
110           /* FMT_OFFSET_G_Y   31:16 0x0 Setting the zero
111            * offset for the G/Y  channel, lower 4LSB is
112            * forced to zeros. Typically set to 0 RGB
113            * and 0x80000 YCbCr.
114            */
115           /* FMT_OFFSET_B_Cb  31:16 0x0 Setting the zero
116            * offset for the B/Cb channel, lower 4LSB is
117            * forced to zeros. Typically set to 0 RGB and
118            * 0x80000 YCbCr.
119            */
120 
121           REG_UPDATE_6(FMT_BIT_DEPTH_CONTROL,
122                               /*Enable spatial dithering*/
123                               FMT_SPATIAL_DITHER_EN, params->flags.SPATIAL_DITHER_ENABLED,
124                               /* Set spatial dithering mode
125                                * (default is Seed patterrn AAAA...)
126                                */
127                               FMT_SPATIAL_DITHER_MODE, params->flags.SPATIAL_DITHER_MODE,
128                               /*Set spatial dithering bit depth*/
129                               FMT_SPATIAL_DITHER_DEPTH, params->flags.SPATIAL_DITHER_DEPTH,
130                               /*Disable High pass filter*/
131                               FMT_HIGHPASS_RANDOM_ENABLE, params->flags.HIGHPASS_RANDOM,
132                               /*Reset only at startup*/
133                               FMT_FRAME_RANDOM_ENABLE, params->flags.FRAME_RANDOM,
134                               /*Set RGB data dithered with x^28+x^3+1*/
135                               FMT_RGB_RANDOM_ENABLE, params->flags.RGB_RANDOM);
136 }
137 
opp1_program_bit_depth_reduction(struct output_pixel_processor * opp,const struct bit_depth_reduction_params * params)138 void opp1_program_bit_depth_reduction(
139           struct output_pixel_processor *opp,
140           const struct bit_depth_reduction_params *params)
141 {
142           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
143 
144           opp1_set_truncation(oppn10, params);
145           opp1_set_spatial_dither(oppn10, params);
146           /* TODO
147            * set_temporal_dither(oppn10, params);
148            */
149 }
150 
151 /**
152  *        set_pixel_encoding
153  *
154  *        Set Pixel Encoding
155  *                  0: RGB 4:4:4 or YCbCr 4:4:4 or YOnly
156  *                  1: YCbCr 4:2:2
157  */
opp1_set_pixel_encoding(struct dcn10_opp * oppn10,const struct clamping_and_pixel_encoding_params * params)158 static void opp1_set_pixel_encoding(
159           struct dcn10_opp *oppn10,
160           const struct clamping_and_pixel_encoding_params *params)
161 {
162           switch (params->pixel_encoding)         {
163 
164           case PIXEL_ENCODING_RGB:
165           case PIXEL_ENCODING_YCBCR444:
166                     REG_UPDATE(FMT_CONTROL, FMT_PIXEL_ENCODING, 0);
167                     break;
168           case PIXEL_ENCODING_YCBCR422:
169                     REG_UPDATE(FMT_CONTROL, FMT_PIXEL_ENCODING, 1);
170                     break;
171           case PIXEL_ENCODING_YCBCR420:
172                     REG_UPDATE(FMT_CONTROL, FMT_PIXEL_ENCODING, 2);
173                     break;
174           default:
175                     break;
176           }
177 }
178 
179 /**
180  *        Set Clamping
181  *        1) Set clamping format based on bpc - 0 for 6bpc (No clamping)
182  *                  1 for 8 bpc
183  *                  2 for 10 bpc
184  *                  3 for 12 bpc
185  *                  7 for programable
186  *        2) Enable clamp if Limited range requested
187  */
opp1_set_clamping(struct dcn10_opp * oppn10,const struct clamping_and_pixel_encoding_params * params)188 static void opp1_set_clamping(
189           struct dcn10_opp *oppn10,
190           const struct clamping_and_pixel_encoding_params *params)
191 {
192           REG_UPDATE_2(FMT_CLAMP_CNTL,
193                               FMT_CLAMP_DATA_EN, 0,
194                               FMT_CLAMP_COLOR_FORMAT, 0);
195 
196           switch (params->clamping_level) {
197           case CLAMPING_FULL_RANGE:
198                     REG_UPDATE_2(FMT_CLAMP_CNTL,
199                                         FMT_CLAMP_DATA_EN, 1,
200                                         FMT_CLAMP_COLOR_FORMAT, 0);
201                     break;
202           case CLAMPING_LIMITED_RANGE_8BPC:
203                     REG_UPDATE_2(FMT_CLAMP_CNTL,
204                                         FMT_CLAMP_DATA_EN, 1,
205                                         FMT_CLAMP_COLOR_FORMAT, 1);
206                     break;
207           case CLAMPING_LIMITED_RANGE_10BPC:
208                     REG_UPDATE_2(FMT_CLAMP_CNTL,
209                                         FMT_CLAMP_DATA_EN, 1,
210                                         FMT_CLAMP_COLOR_FORMAT, 2);
211 
212                     break;
213           case CLAMPING_LIMITED_RANGE_12BPC:
214                     REG_UPDATE_2(FMT_CLAMP_CNTL,
215                                         FMT_CLAMP_DATA_EN, 1,
216                                         FMT_CLAMP_COLOR_FORMAT, 3);
217                     break;
218           case CLAMPING_LIMITED_RANGE_PROGRAMMABLE:
219                     /* TODO */
220           default:
221                     break;
222           }
223 
224 }
225 
opp1_set_dyn_expansion(struct output_pixel_processor * opp,enum dc_color_space color_sp,enum dc_color_depth color_dpth,enum signal_type signal)226 void opp1_set_dyn_expansion(
227           struct output_pixel_processor *opp,
228           enum dc_color_space color_sp,
229           enum dc_color_depth color_dpth,
230           enum signal_type signal)
231 {
232           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
233 
234           REG_UPDATE_2(FMT_DYNAMIC_EXP_CNTL,
235                               FMT_DYNAMIC_EXP_EN, 0,
236                               FMT_DYNAMIC_EXP_MODE, 0);
237 
238           /*00 - 10-bit -> 12-bit dynamic expansion*/
239           /*01 - 8-bit  -> 12-bit dynamic expansion*/
240           if (signal == SIGNAL_TYPE_HDMI_TYPE_A ||
241                     signal == SIGNAL_TYPE_DISPLAY_PORT ||
242                     signal == SIGNAL_TYPE_DISPLAY_PORT_MST ||
243                     signal == SIGNAL_TYPE_VIRTUAL) {
244                     switch (color_dpth) {
245                     case COLOR_DEPTH_888:
246                               REG_UPDATE_2(FMT_DYNAMIC_EXP_CNTL,
247                                         FMT_DYNAMIC_EXP_EN, 1,
248                                         FMT_DYNAMIC_EXP_MODE, 1);
249                               break;
250                     case COLOR_DEPTH_101010:
251                               REG_UPDATE_2(FMT_DYNAMIC_EXP_CNTL,
252                                         FMT_DYNAMIC_EXP_EN, 1,
253                                         FMT_DYNAMIC_EXP_MODE, 0);
254                               break;
255                     case COLOR_DEPTH_121212:
256                               REG_UPDATE_2(FMT_DYNAMIC_EXP_CNTL,
257                                         FMT_DYNAMIC_EXP_EN, 1,/*otherwise last two bits are zero*/
258                                         FMT_DYNAMIC_EXP_MODE, 0);
259                               break;
260                     default:
261                               break;
262                     }
263           }
264 }
265 
opp1_program_clamping_and_pixel_encoding(struct output_pixel_processor * opp,const struct clamping_and_pixel_encoding_params * params)266 static void opp1_program_clamping_and_pixel_encoding(
267           struct output_pixel_processor *opp,
268           const struct clamping_and_pixel_encoding_params *params)
269 {
270           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
271 
272           opp1_set_clamping(oppn10, params);
273           opp1_set_pixel_encoding(oppn10, params);
274 }
275 
opp1_program_fmt(struct output_pixel_processor * opp,struct bit_depth_reduction_params * fmt_bit_depth,struct clamping_and_pixel_encoding_params * clamping)276 void opp1_program_fmt(
277           struct output_pixel_processor *opp,
278           struct bit_depth_reduction_params *fmt_bit_depth,
279           struct clamping_and_pixel_encoding_params *clamping)
280 {
281           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
282 
283           if (clamping->pixel_encoding == PIXEL_ENCODING_YCBCR420)
284                     REG_UPDATE(FMT_MAP420_MEMORY_CONTROL, FMT_MAP420MEM_PWR_FORCE, 0);
285 
286           /* dithering is affected by <CrtcSourceSelect>, hence should be
287            * programmed afterwards */
288           opp1_program_bit_depth_reduction(
289                     opp,
290                     fmt_bit_depth);
291 
292           opp1_program_clamping_and_pixel_encoding(
293                     opp,
294                     clamping);
295 
296           return;
297 }
298 
opp1_program_stereo(struct output_pixel_processor * opp,bool enable,const struct dc_crtc_timing * timing)299 void opp1_program_stereo(
300           struct output_pixel_processor *opp,
301           bool enable,
302           const struct dc_crtc_timing *timing)
303 {
304           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
305 
306           uint32_t active_width = timing->h_addressable - timing->h_border_right - timing->h_border_right;
307           uint32_t space1_size = timing->v_total - timing->v_addressable;
308           /* TODO: confirm computation of space2_size */
309           uint32_t space2_size = timing->v_total - timing->v_addressable;
310 
311           if (!enable) {
312                     active_width = 0;
313                     space1_size = 0;
314                     space2_size = 0;
315           }
316 
317           /* TODO: for which cases should FMT_STEREOSYNC_OVERRIDE be set? */
318           REG_UPDATE(FMT_CONTROL, FMT_STEREOSYNC_OVERRIDE, 0);
319 
320           REG_UPDATE(OPPBUF_CONTROL, OPPBUF_ACTIVE_WIDTH, active_width);
321 
322           /* Program OPPBUF_3D_VACT_SPACE1_SIZE and OPPBUF_VACT_SPACE2_SIZE registers
323            * In 3D progressive frames, Vactive space happens only in between the 2 frames,
324            * so only need to program OPPBUF_3D_VACT_SPACE1_SIZE
325            * In 3D alternative frames, left and right frames, top and bottom field.
326            */
327           if (timing->timing_3d_format == TIMING_3D_FORMAT_FRAME_ALTERNATE)
328                     REG_UPDATE(OPPBUF_3D_PARAMETERS_0, OPPBUF_3D_VACT_SPACE2_SIZE, space2_size);
329           else
330                     REG_UPDATE(OPPBUF_3D_PARAMETERS_0, OPPBUF_3D_VACT_SPACE1_SIZE, space1_size);
331 
332           /* TODO: Is programming of OPPBUF_DUMMY_DATA_R/G/B needed? */
333           /*
334           REG_UPDATE(OPPBUF_3D_PARAMETERS_0,
335                               OPPBUF_DUMMY_DATA_R, data_r);
336           REG_UPDATE(OPPBUF_3D_PARAMETERS_1,
337                               OPPBUF_DUMMY_DATA_G, data_g);
338           REG_UPDATE(OPPBUF_3D_PARAMETERS_1,
339                               OPPBUF_DUMMY_DATA_B, _data_b);
340           */
341 }
342 
343 #if 0
344 void opp1_program_oppbuf(
345           struct output_pixel_processor *opp,
346           struct oppbuf_params *oppbuf)
347 {
348           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
349 
350           /* Program the oppbuf active width to be the frame width from mpc */
351           REG_UPDATE(OPPBUF_CONTROL, OPPBUF_ACTIVE_WIDTH, oppbuf->active_width);
352 
353           /* Specifies the number of segments in multi-segment mode (DP-MSO operation)
354            * description  "In 1/2/4 segment mode, specifies the horizontal active width in pixels of the display panel.
355            * In 4 segment split left/right mode, specifies the horizontal 1/2 active width in pixels of the display panel.
356            * Used to determine segment boundaries in multi-segment mode. Used to determine the width of the vertical active space in 3D frame packed modes.
357            * OPPBUF_ACTIVE_WIDTH must be integer divisible by the total number of segments."
358            */
359           REG_UPDATE(OPPBUF_CONTROL, OPPBUF_DISPLAY_SEGMENTATION, oppbuf->mso_segmentation);
360 
361           /* description  "Specifies the number of overlap pixels (1-8 overlapping pixels supported), used in multi-segment mode (DP-MSO operation)" */
362           REG_UPDATE(OPPBUF_CONTROL, OPPBUF_OVERLAP_PIXEL_NUM, oppbuf->mso_overlap_pixel_num);
363 
364           /* description  "Specifies the number of times a pixel is replicated (0-15 pixel replications supported).
365            * A value of 0 disables replication. The total number of times a pixel is output is OPPBUF_PIXEL_REPETITION + 1."
366            */
367           REG_UPDATE(OPPBUF_CONTROL, OPPBUF_PIXEL_REPETITION, oppbuf->pixel_repetition);
368 
369 }
370 #endif
371 
opp1_pipe_clock_control(struct output_pixel_processor * opp,bool enable)372 void opp1_pipe_clock_control(struct output_pixel_processor *opp, bool enable)
373 {
374           struct dcn10_opp *oppn10 = TO_DCN10_OPP(opp);
375           uint32_t regval = enable ? 1 : 0;
376 
377           REG_UPDATE(OPP_PIPE_CONTROL, OPP_PIPE_CLOCK_EN, regval);
378 }
379 
380 /*****************************************/
381 /* Constructor, Destructor               */
382 /*****************************************/
383 
opp1_destroy(struct output_pixel_processor ** opp)384 void opp1_destroy(struct output_pixel_processor **opp)
385 {
386           kfree(TO_DCN10_OPP(*opp));
387           *opp = NULL;
388 }
389 
390 static const struct opp_funcs dcn10_opp_funcs = {
391                     .opp_set_dyn_expansion = opp1_set_dyn_expansion,
392                     .opp_program_fmt = opp1_program_fmt,
393                     .opp_program_bit_depth_reduction = opp1_program_bit_depth_reduction,
394                     .opp_program_stereo = opp1_program_stereo,
395                     .opp_pipe_clock_control = opp1_pipe_clock_control,
396                     .opp_destroy = opp1_destroy
397 };
398 
dcn10_opp_construct(struct dcn10_opp * oppn10,struct dc_context * ctx,uint32_t inst,const struct dcn10_opp_registers * regs,const struct dcn10_opp_shift * opp_shift,const struct dcn10_opp_mask * opp_mask)399 void dcn10_opp_construct(struct dcn10_opp *oppn10,
400           struct dc_context *ctx,
401           uint32_t inst,
402           const struct dcn10_opp_registers *regs,
403           const struct dcn10_opp_shift *opp_shift,
404           const struct dcn10_opp_mask *opp_mask)
405 {
406 
407           oppn10->base.ctx = ctx;
408           oppn10->base.inst = inst;
409           oppn10->base.funcs = &dcn10_opp_funcs;
410 
411           oppn10->regs = regs;
412           oppn10->opp_shift = opp_shift;
413           oppn10->opp_mask = opp_mask;
414 }
415