1 /*
2 * Copyright 2016-2023 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 "dc.h"
28 #include "mod_freesync.h"
29 #include "core_types.h"
30
31 #define MOD_FREESYNC_MAX_CONCURRENT_STREAMS 32
32
33 #define MIN_REFRESH_RANGE 10
34 /* Refresh rate ramp at a fixed rate of 65 Hz/second */
35 #define STATIC_SCREEN_RAMP_DELTA_REFRESH_RATE_PER_FRAME ((1000 / 60) * 65)
36 /* Number of elements in the render times cache array */
37 #define RENDER_TIMES_MAX_COUNT 10
38 /* Threshold to exit/exit BTR (to avoid frequent enter-exits at the lower limit) */
39 #define BTR_MAX_MARGIN 2500
40 /* Threshold to change BTR multiplier (to avoid frequent changes) */
41 #define BTR_DRIFT_MARGIN 2000
42 /* Threshold to exit fixed refresh rate */
43 #define FIXED_REFRESH_EXIT_MARGIN_IN_HZ 1
44 /* Number of consecutive frames to check before entering/exiting fixed refresh */
45 #define FIXED_REFRESH_ENTER_FRAME_COUNT 5
46 #define FIXED_REFRESH_EXIT_FRAME_COUNT 10
47 /* Flip interval workaround constants */
48 #define VSYNCS_BETWEEN_FLIP_THRESHOLD 2
49 #define FREESYNC_CONSEC_FLIP_AFTER_VSYNC 5
50 #define FREESYNC_VSYNC_TO_FLIP_DELTA_IN_US 500
51
52 struct core_freesync {
53 struct mod_freesync public;
54 struct dc *dc;
55 };
56
57 #define MOD_FREESYNC_TO_CORE(mod_freesync)\
58 container_of(mod_freesync, struct core_freesync, public)
59
mod_freesync_create(struct dc * dc)60 struct mod_freesync *mod_freesync_create(struct dc *dc)
61 {
62 struct core_freesync *core_freesync =
63 kzalloc(sizeof(struct core_freesync), GFP_KERNEL);
64
65 if (core_freesync == NULL)
66 goto fail_alloc_context;
67
68 if (dc == NULL)
69 goto fail_construct;
70
71 core_freesync->dc = dc;
72 return &core_freesync->public;
73
74 fail_construct:
75 kfree(core_freesync);
76
77 fail_alloc_context:
78 return NULL;
79 }
80
mod_freesync_destroy(struct mod_freesync * mod_freesync)81 void mod_freesync_destroy(struct mod_freesync *mod_freesync)
82 {
83 struct core_freesync *core_freesync = NULL;
84 if (mod_freesync == NULL)
85 return;
86 core_freesync = MOD_FREESYNC_TO_CORE(mod_freesync);
87 kfree(core_freesync);
88 }
89
90 #if 0 /* Unused currently */
91 static unsigned int calc_refresh_in_uhz_from_duration(
92 unsigned int duration_in_ns)
93 {
94 unsigned int refresh_in_uhz =
95 ((unsigned int)(div64_u64((1000000000ULL * 1000000),
96 duration_in_ns)));
97 return refresh_in_uhz;
98 }
99 #endif
100
calc_duration_in_us_from_refresh_in_uhz(unsigned int refresh_in_uhz)101 static unsigned int calc_duration_in_us_from_refresh_in_uhz(
102 unsigned int refresh_in_uhz)
103 {
104 unsigned int duration_in_us =
105 ((unsigned int)(div64_u64((1000000000ULL * 1000),
106 refresh_in_uhz)));
107 return duration_in_us;
108 }
109
calc_duration_in_us_from_v_total(const struct dc_stream_state * stream,const struct mod_vrr_params * in_vrr,unsigned int v_total)110 static unsigned int calc_duration_in_us_from_v_total(
111 const struct dc_stream_state *stream,
112 const struct mod_vrr_params *in_vrr,
113 unsigned int v_total)
114 {
115 unsigned int duration_in_us =
116 (unsigned int)(div64_u64(((unsigned long long)(v_total)
117 * 10000) * stream->timing.h_total,
118 stream->timing.pix_clk_100hz));
119
120 return duration_in_us;
121 }
122
mod_freesync_calc_v_total_from_refresh(const struct dc_stream_state * stream,unsigned int refresh_in_uhz)123 unsigned int mod_freesync_calc_v_total_from_refresh(
124 const struct dc_stream_state *stream,
125 unsigned int refresh_in_uhz)
126 {
127 unsigned int v_total;
128 unsigned int frame_duration_in_ns;
129
130 frame_duration_in_ns =
131 ((unsigned int)(div64_u64((1000000000ULL * 1000000),
132 refresh_in_uhz)));
133
134 v_total = div64_u64(div64_u64(((unsigned long long)(
135 frame_duration_in_ns) * (stream->timing.pix_clk_100hz / 10)),
136 stream->timing.h_total) + 500000, 1000000);
137
138 /* v_total cannot be less than nominal */
139 if (v_total < stream->timing.v_total) {
140 ASSERT(v_total < stream->timing.v_total);
141 v_total = stream->timing.v_total;
142 }
143
144 return v_total;
145 }
146
calc_v_total_from_duration(const struct dc_stream_state * stream,const struct mod_vrr_params * vrr,unsigned int duration_in_us)147 static unsigned int calc_v_total_from_duration(
148 const struct dc_stream_state *stream,
149 const struct mod_vrr_params *vrr,
150 unsigned int duration_in_us)
151 {
152 unsigned int v_total = 0;
153
154 if (duration_in_us < vrr->min_duration_in_us)
155 duration_in_us = vrr->min_duration_in_us;
156
157 if (duration_in_us > vrr->max_duration_in_us)
158 duration_in_us = vrr->max_duration_in_us;
159
160 if (dc_is_hdmi_signal(stream->signal)) {
161 uint32_t h_total_up_scaled;
162
163 h_total_up_scaled = stream->timing.h_total * 10000;
164 v_total = div_u64((unsigned long long)duration_in_us
165 * stream->timing.pix_clk_100hz + (h_total_up_scaled - 1),
166 h_total_up_scaled);
167 } else {
168 v_total = div64_u64(div64_u64(((unsigned long long)(
169 duration_in_us) * (stream->timing.pix_clk_100hz / 10)),
170 stream->timing.h_total), 1000);
171 }
172
173 /* v_total cannot be less than nominal */
174 if (v_total < stream->timing.v_total) {
175 ASSERT(v_total < stream->timing.v_total);
176 v_total = stream->timing.v_total;
177 }
178
179 return v_total;
180 }
181
update_v_total_for_static_ramp(struct core_freesync * core_freesync,const struct dc_stream_state * stream,struct mod_vrr_params * in_out_vrr)182 static void update_v_total_for_static_ramp(
183 struct core_freesync *core_freesync,
184 const struct dc_stream_state *stream,
185 struct mod_vrr_params *in_out_vrr)
186 {
187 unsigned int v_total = 0;
188 unsigned int current_duration_in_us =
189 calc_duration_in_us_from_v_total(
190 stream, in_out_vrr,
191 in_out_vrr->adjust.v_total_max);
192 unsigned int target_duration_in_us =
193 calc_duration_in_us_from_refresh_in_uhz(
194 in_out_vrr->fixed.target_refresh_in_uhz);
195 bool ramp_direction_is_up = (current_duration_in_us >
196 target_duration_in_us) ? true : false;
197
198 /* Calculate ratio between new and current frame duration with 3 digit */
199 unsigned int frame_duration_ratio = div64_u64(1000000,
200 (1000 + div64_u64(((unsigned long long)(
201 STATIC_SCREEN_RAMP_DELTA_REFRESH_RATE_PER_FRAME) *
202 current_duration_in_us),
203 1000000)));
204
205 /* Calculate delta between new and current frame duration in us */
206 unsigned int frame_duration_delta = div64_u64(((unsigned long long)(
207 current_duration_in_us) *
208 (1000 - frame_duration_ratio)), 1000);
209
210 /* Adjust frame duration delta based on ratio between current and
211 * standard frame duration (frame duration at 60 Hz refresh rate).
212 */
213 unsigned int ramp_rate_interpolated = div64_u64(((unsigned long long)(
214 frame_duration_delta) * current_duration_in_us), 16666);
215
216 /* Going to a higher refresh rate (lower frame duration) */
217 if (ramp_direction_is_up) {
218 /* Reduce frame duration */
219 current_duration_in_us -= ramp_rate_interpolated;
220
221 /* Adjust for frame duration below min */
222 if (current_duration_in_us <= target_duration_in_us) {
223 in_out_vrr->fixed.ramping_active = false;
224 in_out_vrr->fixed.ramping_done = true;
225 current_duration_in_us =
226 calc_duration_in_us_from_refresh_in_uhz(
227 in_out_vrr->fixed.target_refresh_in_uhz);
228 }
229 /* Going to a lower refresh rate (larger frame duration) */
230 } else {
231 /* Increase frame duration */
232 current_duration_in_us += ramp_rate_interpolated;
233
234 /* Adjust for frame duration above max */
235 if (current_duration_in_us >= target_duration_in_us) {
236 in_out_vrr->fixed.ramping_active = false;
237 in_out_vrr->fixed.ramping_done = true;
238 current_duration_in_us =
239 calc_duration_in_us_from_refresh_in_uhz(
240 in_out_vrr->fixed.target_refresh_in_uhz);
241 }
242 }
243
244 v_total = div64_u64(div64_u64(((unsigned long long)(
245 current_duration_in_us) * (stream->timing.pix_clk_100hz / 10)),
246 stream->timing.h_total), 1000);
247
248 /* v_total cannot be less than nominal */
249 if (v_total < stream->timing.v_total)
250 v_total = stream->timing.v_total;
251
252 in_out_vrr->adjust.v_total_min = v_total;
253 in_out_vrr->adjust.v_total_max = v_total;
254 }
255
apply_below_the_range(struct core_freesync * core_freesync,const struct dc_stream_state * stream,unsigned int last_render_time_in_us,struct mod_vrr_params * in_out_vrr)256 static void apply_below_the_range(struct core_freesync *core_freesync,
257 const struct dc_stream_state *stream,
258 unsigned int last_render_time_in_us,
259 struct mod_vrr_params *in_out_vrr)
260 {
261 unsigned int inserted_frame_duration_in_us = 0;
262 unsigned int mid_point_frames_ceil = 0;
263 unsigned int mid_point_frames_floor = 0;
264 unsigned int frame_time_in_us = 0;
265 unsigned int delta_from_mid_point_in_us_1 = 0xFFFFFFFF;
266 unsigned int delta_from_mid_point_in_us_2 = 0xFFFFFFFF;
267 unsigned int frames_to_insert = 0;
268 unsigned int delta_from_mid_point_delta_in_us;
269 unsigned int max_render_time_in_us =
270 in_out_vrr->max_duration_in_us - in_out_vrr->btr.margin_in_us;
271
272 /* Program BTR */
273 if ((last_render_time_in_us + in_out_vrr->btr.margin_in_us / 2) < max_render_time_in_us) {
274 /* Exit Below the Range */
275 if (in_out_vrr->btr.btr_active) {
276 in_out_vrr->btr.frame_counter = 0;
277 in_out_vrr->btr.btr_active = false;
278 }
279 } else if (last_render_time_in_us > (max_render_time_in_us + in_out_vrr->btr.margin_in_us / 2)) {
280 /* Enter Below the Range */
281 if (!in_out_vrr->btr.btr_active) {
282 in_out_vrr->btr.btr_active = true;
283 }
284 }
285
286 /* BTR set to "not active" so disengage */
287 if (!in_out_vrr->btr.btr_active) {
288 in_out_vrr->btr.inserted_duration_in_us = 0;
289 in_out_vrr->btr.frames_to_insert = 0;
290 in_out_vrr->btr.frame_counter = 0;
291
292 /* Restore FreeSync */
293 in_out_vrr->adjust.v_total_min =
294 mod_freesync_calc_v_total_from_refresh(stream,
295 in_out_vrr->max_refresh_in_uhz);
296 in_out_vrr->adjust.v_total_max =
297 mod_freesync_calc_v_total_from_refresh(stream,
298 in_out_vrr->min_refresh_in_uhz);
299 /* BTR set to "active" so engage */
300 } else {
301
302 /* Calculate number of midPoint frames that could fit within
303 * the render time interval - take ceil of this value
304 */
305 mid_point_frames_ceil = (last_render_time_in_us +
306 in_out_vrr->btr.mid_point_in_us - 1) /
307 in_out_vrr->btr.mid_point_in_us;
308
309 if (mid_point_frames_ceil > 0) {
310 frame_time_in_us = last_render_time_in_us /
311 mid_point_frames_ceil;
312 delta_from_mid_point_in_us_1 =
313 (in_out_vrr->btr.mid_point_in_us >
314 frame_time_in_us) ?
315 (in_out_vrr->btr.mid_point_in_us - frame_time_in_us) :
316 (frame_time_in_us - in_out_vrr->btr.mid_point_in_us);
317 }
318
319 /* Calculate number of midPoint frames that could fit within
320 * the render time interval - take floor of this value
321 */
322 mid_point_frames_floor = last_render_time_in_us /
323 in_out_vrr->btr.mid_point_in_us;
324
325 if (mid_point_frames_floor > 0) {
326
327 frame_time_in_us = last_render_time_in_us /
328 mid_point_frames_floor;
329 delta_from_mid_point_in_us_2 =
330 (in_out_vrr->btr.mid_point_in_us >
331 frame_time_in_us) ?
332 (in_out_vrr->btr.mid_point_in_us - frame_time_in_us) :
333 (frame_time_in_us - in_out_vrr->btr.mid_point_in_us);
334 }
335
336 /* Choose number of frames to insert based on how close it
337 * can get to the mid point of the variable range.
338 * - Delta for CEIL: delta_from_mid_point_in_us_1
339 * - Delta for FLOOR: delta_from_mid_point_in_us_2
340 */
341 if (mid_point_frames_ceil &&
342 (last_render_time_in_us / mid_point_frames_ceil) <
343 in_out_vrr->min_duration_in_us) {
344 /* Check for out of range.
345 * If using CEIL produces a value that is out of range,
346 * then we are forced to use FLOOR.
347 */
348 frames_to_insert = mid_point_frames_floor;
349 } else if (mid_point_frames_floor < 2) {
350 /* Check if FLOOR would result in non-LFC. In this case
351 * choose to use CEIL
352 */
353 frames_to_insert = mid_point_frames_ceil;
354 } else if (delta_from_mid_point_in_us_1 < delta_from_mid_point_in_us_2) {
355 /* If choosing CEIL results in a frame duration that is
356 * closer to the mid point of the range.
357 * Choose CEIL
358 */
359 frames_to_insert = mid_point_frames_ceil;
360 } else {
361 /* If choosing FLOOR results in a frame duration that is
362 * closer to the mid point of the range.
363 * Choose FLOOR
364 */
365 frames_to_insert = mid_point_frames_floor;
366 }
367
368 /* Prefer current frame multiplier when BTR is enabled unless it drifts
369 * too far from the midpoint
370 */
371 if (delta_from_mid_point_in_us_1 < delta_from_mid_point_in_us_2) {
372 delta_from_mid_point_delta_in_us = delta_from_mid_point_in_us_2 -
373 delta_from_mid_point_in_us_1;
374 } else {
375 delta_from_mid_point_delta_in_us = delta_from_mid_point_in_us_1 -
376 delta_from_mid_point_in_us_2;
377 }
378 if (in_out_vrr->btr.frames_to_insert != 0 &&
379 delta_from_mid_point_delta_in_us < BTR_DRIFT_MARGIN) {
380 if (((last_render_time_in_us / in_out_vrr->btr.frames_to_insert) <
381 max_render_time_in_us) &&
382 ((last_render_time_in_us / in_out_vrr->btr.frames_to_insert) >
383 in_out_vrr->min_duration_in_us))
384 frames_to_insert = in_out_vrr->btr.frames_to_insert;
385 }
386
387 /* Either we've calculated the number of frames to insert,
388 * or we need to insert min duration frames
389 */
390 if (frames_to_insert &&
391 (last_render_time_in_us / frames_to_insert) <
392 in_out_vrr->min_duration_in_us){
393 frames_to_insert -= (frames_to_insert > 1) ?
394 1 : 0;
395 }
396
397 if (frames_to_insert > 0)
398 inserted_frame_duration_in_us = last_render_time_in_us /
399 frames_to_insert;
400
401 if (inserted_frame_duration_in_us < in_out_vrr->min_duration_in_us)
402 inserted_frame_duration_in_us = in_out_vrr->min_duration_in_us;
403
404 /* Cache the calculated variables */
405 in_out_vrr->btr.inserted_duration_in_us =
406 inserted_frame_duration_in_us;
407 in_out_vrr->btr.frames_to_insert = frames_to_insert;
408 in_out_vrr->btr.frame_counter = frames_to_insert;
409 }
410 }
411
apply_fixed_refresh(struct core_freesync * core_freesync,const struct dc_stream_state * stream,unsigned int last_render_time_in_us,struct mod_vrr_params * in_out_vrr)412 static void apply_fixed_refresh(struct core_freesync *core_freesync,
413 const struct dc_stream_state *stream,
414 unsigned int last_render_time_in_us,
415 struct mod_vrr_params *in_out_vrr)
416 {
417 bool update = false;
418 unsigned int max_render_time_in_us = in_out_vrr->max_duration_in_us;
419
420 /* Compute the exit refresh rate and exit frame duration */
421 unsigned int exit_refresh_rate_in_milli_hz = ((1000000000/max_render_time_in_us)
422 + (1000*FIXED_REFRESH_EXIT_MARGIN_IN_HZ));
423 unsigned int exit_frame_duration_in_us = 1000000000/exit_refresh_rate_in_milli_hz;
424
425 if (last_render_time_in_us < exit_frame_duration_in_us) {
426 /* Exit Fixed Refresh mode */
427 if (in_out_vrr->fixed.fixed_active) {
428 in_out_vrr->fixed.frame_counter++;
429
430 if (in_out_vrr->fixed.frame_counter >
431 FIXED_REFRESH_EXIT_FRAME_COUNT) {
432 in_out_vrr->fixed.frame_counter = 0;
433 in_out_vrr->fixed.fixed_active = false;
434 in_out_vrr->fixed.target_refresh_in_uhz = 0;
435 update = true;
436 }
437 } else
438 in_out_vrr->fixed.frame_counter = 0;
439 } else if (last_render_time_in_us > max_render_time_in_us) {
440 /* Enter Fixed Refresh mode */
441 if (!in_out_vrr->fixed.fixed_active) {
442 in_out_vrr->fixed.frame_counter++;
443
444 if (in_out_vrr->fixed.frame_counter >
445 FIXED_REFRESH_ENTER_FRAME_COUNT) {
446 in_out_vrr->fixed.frame_counter = 0;
447 in_out_vrr->fixed.fixed_active = true;
448 in_out_vrr->fixed.target_refresh_in_uhz =
449 in_out_vrr->max_refresh_in_uhz;
450 update = true;
451 }
452 } else
453 in_out_vrr->fixed.frame_counter = 0;
454 }
455
456 if (update) {
457 if (in_out_vrr->fixed.fixed_active) {
458 in_out_vrr->adjust.v_total_min =
459 mod_freesync_calc_v_total_from_refresh(
460 stream, in_out_vrr->max_refresh_in_uhz);
461 in_out_vrr->adjust.v_total_max =
462 in_out_vrr->adjust.v_total_min;
463 } else {
464 in_out_vrr->adjust.v_total_min =
465 mod_freesync_calc_v_total_from_refresh(stream,
466 in_out_vrr->max_refresh_in_uhz);
467 in_out_vrr->adjust.v_total_max =
468 mod_freesync_calc_v_total_from_refresh(stream,
469 in_out_vrr->min_refresh_in_uhz);
470 }
471 }
472 }
473
determine_flip_interval_workaround_req(struct mod_vrr_params * in_vrr,unsigned int curr_time_stamp_in_us)474 static void determine_flip_interval_workaround_req(struct mod_vrr_params *in_vrr,
475 unsigned int curr_time_stamp_in_us)
476 {
477 in_vrr->flip_interval.vsync_to_flip_in_us = curr_time_stamp_in_us -
478 in_vrr->flip_interval.v_update_timestamp_in_us;
479
480 /* Determine conditions for stopping workaround */
481 if (in_vrr->flip_interval.flip_interval_workaround_active &&
482 in_vrr->flip_interval.vsyncs_between_flip < VSYNCS_BETWEEN_FLIP_THRESHOLD &&
483 in_vrr->flip_interval.vsync_to_flip_in_us > FREESYNC_VSYNC_TO_FLIP_DELTA_IN_US) {
484 in_vrr->flip_interval.flip_interval_detect_counter = 0;
485 in_vrr->flip_interval.program_flip_interval_workaround = true;
486 in_vrr->flip_interval.flip_interval_workaround_active = false;
487 } else {
488 /* Determine conditions for starting workaround */
489 if (in_vrr->flip_interval.vsyncs_between_flip >= VSYNCS_BETWEEN_FLIP_THRESHOLD &&
490 in_vrr->flip_interval.vsync_to_flip_in_us < FREESYNC_VSYNC_TO_FLIP_DELTA_IN_US) {
491 /* Increase flip interval counter we have 2 vsyncs between flips and
492 * vsync to flip interval is less than 500us
493 */
494 in_vrr->flip_interval.flip_interval_detect_counter++;
495 if (in_vrr->flip_interval.flip_interval_detect_counter > FREESYNC_CONSEC_FLIP_AFTER_VSYNC) {
496 /* Start workaround if we detect 5 consecutive instances of the above case */
497 in_vrr->flip_interval.program_flip_interval_workaround = true;
498 in_vrr->flip_interval.flip_interval_workaround_active = true;
499 }
500 } else {
501 /* Reset the flip interval counter if we condition is no longer met */
502 in_vrr->flip_interval.flip_interval_detect_counter = 0;
503 }
504 }
505
506 in_vrr->flip_interval.vsyncs_between_flip = 0;
507 }
508
vrr_settings_require_update(struct core_freesync * core_freesync,struct mod_freesync_config * in_config,unsigned int min_refresh_in_uhz,unsigned int max_refresh_in_uhz,struct mod_vrr_params * in_vrr)509 static bool vrr_settings_require_update(struct core_freesync *core_freesync,
510 struct mod_freesync_config *in_config,
511 unsigned int min_refresh_in_uhz,
512 unsigned int max_refresh_in_uhz,
513 struct mod_vrr_params *in_vrr)
514 {
515 if (in_vrr->state != in_config->state) {
516 return true;
517 } else if (in_vrr->state == VRR_STATE_ACTIVE_FIXED &&
518 in_vrr->fixed.target_refresh_in_uhz !=
519 in_config->fixed_refresh_in_uhz) {
520 return true;
521 } else if (in_vrr->min_refresh_in_uhz != min_refresh_in_uhz) {
522 return true;
523 } else if (in_vrr->max_refresh_in_uhz != max_refresh_in_uhz) {
524 return true;
525 }
526
527 return false;
528 }
529
mod_freesync_get_vmin_vmax(struct mod_freesync * mod_freesync,const struct dc_stream_state * stream,unsigned int * vmin,unsigned int * vmax)530 bool mod_freesync_get_vmin_vmax(struct mod_freesync *mod_freesync,
531 const struct dc_stream_state *stream,
532 unsigned int *vmin,
533 unsigned int *vmax)
534 {
535 *vmin = stream->adjust.v_total_min;
536 *vmax = stream->adjust.v_total_max;
537
538 return true;
539 }
540
mod_freesync_get_v_position(struct mod_freesync * mod_freesync,struct dc_stream_state * stream,unsigned int * nom_v_pos,unsigned int * v_pos)541 bool mod_freesync_get_v_position(struct mod_freesync *mod_freesync,
542 struct dc_stream_state *stream,
543 unsigned int *nom_v_pos,
544 unsigned int *v_pos)
545 {
546 struct core_freesync *core_freesync = NULL;
547 struct crtc_position position;
548
549 if (mod_freesync == NULL)
550 return false;
551
552 core_freesync = MOD_FREESYNC_TO_CORE(mod_freesync);
553
554 if (dc_stream_get_crtc_position(core_freesync->dc, &stream, 1,
555 &position.vertical_count,
556 &position.nominal_vcount)) {
557
558 *nom_v_pos = position.nominal_vcount;
559 *v_pos = position.vertical_count;
560
561 return true;
562 }
563
564 return false;
565 }
566
build_vrr_infopacket_data_v1(const struct mod_vrr_params * vrr,struct dc_info_packet * infopacket,bool freesync_on_desktop)567 static void build_vrr_infopacket_data_v1(const struct mod_vrr_params *vrr,
568 struct dc_info_packet *infopacket,
569 bool freesync_on_desktop)
570 {
571 /* PB1 = 0x1A (24bit AMD IEEE OUI (0x00001A) - Byte 0) */
572 infopacket->sb[1] = 0x1A;
573
574 /* PB2 = 0x00 (24bit AMD IEEE OUI (0x00001A) - Byte 1) */
575 infopacket->sb[2] = 0x00;
576
577 /* PB3 = 0x00 (24bit AMD IEEE OUI (0x00001A) - Byte 2) */
578 infopacket->sb[3] = 0x00;
579
580 /* PB4 = Reserved */
581
582 /* PB5 = Reserved */
583
584 /* PB6 = [Bits 7:3 = Reserved] */
585
586 /* PB6 = [Bit 0 = FreeSync Supported] */
587 if (vrr->state != VRR_STATE_UNSUPPORTED)
588 infopacket->sb[6] |= 0x01;
589
590 /* PB6 = [Bit 1 = FreeSync Enabled] */
591 if (vrr->state != VRR_STATE_DISABLED &&
592 vrr->state != VRR_STATE_UNSUPPORTED)
593 infopacket->sb[6] |= 0x02;
594
595 if (freesync_on_desktop) {
596 /* PB6 = [Bit 2 = FreeSync Active] */
597 if (vrr->state != VRR_STATE_DISABLED &&
598 vrr->state != VRR_STATE_UNSUPPORTED)
599 infopacket->sb[6] |= 0x04;
600 } else {
601 if (vrr->state == VRR_STATE_ACTIVE_VARIABLE ||
602 vrr->state == VRR_STATE_ACTIVE_FIXED)
603 infopacket->sb[6] |= 0x04;
604 }
605
606 // For v1 & 2 infoframes program nominal if non-fs mode, otherwise full range
607 /* PB7 = FreeSync Minimum refresh rate (Hz) */
608 if (vrr->state == VRR_STATE_ACTIVE_VARIABLE ||
609 vrr->state == VRR_STATE_ACTIVE_FIXED) {
610 infopacket->sb[7] = (unsigned char)((vrr->min_refresh_in_uhz + 500000) / 1000000);
611 } else {
612 infopacket->sb[7] = (unsigned char)((vrr->max_refresh_in_uhz + 500000) / 1000000);
613 }
614
615 /* PB8 = FreeSync Maximum refresh rate (Hz)
616 * Note: We should never go above the field rate of the mode timing set.
617 */
618 infopacket->sb[8] = (unsigned char)((vrr->max_refresh_in_uhz + 500000) / 1000000);
619 }
620
build_vrr_infopacket_data_v3(const struct mod_vrr_params * vrr,struct dc_info_packet * infopacket,bool freesync_on_desktop)621 static void build_vrr_infopacket_data_v3(const struct mod_vrr_params *vrr,
622 struct dc_info_packet *infopacket,
623 bool freesync_on_desktop)
624 {
625 unsigned int min_refresh;
626 unsigned int max_refresh;
627 unsigned int fixed_refresh;
628 unsigned int min_programmed;
629 unsigned int max_programmed;
630
631 /* PB1 = 0x1A (24bit AMD IEEE OUI (0x00001A) - Byte 0) */
632 infopacket->sb[1] = 0x1A;
633
634 /* PB2 = 0x00 (24bit AMD IEEE OUI (0x00001A) - Byte 1) */
635 infopacket->sb[2] = 0x00;
636
637 /* PB3 = 0x00 (24bit AMD IEEE OUI (0x00001A) - Byte 2) */
638 infopacket->sb[3] = 0x00;
639
640 /* PB4 = Reserved */
641
642 /* PB5 = Reserved */
643
644 /* PB6 = [Bits 7:3 = Reserved] */
645
646 /* PB6 = [Bit 0 = FreeSync Supported] */
647 if (vrr->state != VRR_STATE_UNSUPPORTED)
648 infopacket->sb[6] |= 0x01;
649
650 /* PB6 = [Bit 1 = FreeSync Enabled] */
651 if (vrr->state != VRR_STATE_DISABLED &&
652 vrr->state != VRR_STATE_UNSUPPORTED)
653 infopacket->sb[6] |= 0x02;
654
655 /* PB6 = [Bit 2 = FreeSync Active] */
656 if (freesync_on_desktop) {
657 if (vrr->state != VRR_STATE_DISABLED &&
658 vrr->state != VRR_STATE_UNSUPPORTED)
659 infopacket->sb[6] |= 0x04;
660 } else {
661 if (vrr->state == VRR_STATE_ACTIVE_VARIABLE ||
662 vrr->state == VRR_STATE_ACTIVE_FIXED)
663 infopacket->sb[6] |= 0x04;
664 }
665
666 min_refresh = (vrr->min_refresh_in_uhz + 500000) / 1000000;
667 max_refresh = (vrr->max_refresh_in_uhz + 500000) / 1000000;
668 fixed_refresh = (vrr->fixed_refresh_in_uhz + 500000) / 1000000;
669
670 min_programmed = (vrr->state == VRR_STATE_ACTIVE_FIXED) ? fixed_refresh :
671 (vrr->state == VRR_STATE_ACTIVE_VARIABLE) ? min_refresh :
672 (vrr->state == VRR_STATE_INACTIVE) ? min_refresh :
673 max_refresh; // Non-fs case, program nominal range
674
675 max_programmed = (vrr->state == VRR_STATE_ACTIVE_FIXED) ? fixed_refresh :
676 (vrr->state == VRR_STATE_ACTIVE_VARIABLE) ? max_refresh :
677 max_refresh;// Non-fs case, program nominal range
678
679 /* PB7 = FreeSync Minimum refresh rate (Hz) */
680 infopacket->sb[7] = min_programmed & 0xFF;
681
682 /* PB8 = FreeSync Maximum refresh rate (Hz) */
683 infopacket->sb[8] = max_programmed & 0xFF;
684
685 /* PB11 : MSB FreeSync Minimum refresh rate [Hz] - bits 9:8 */
686 infopacket->sb[11] = (min_programmed >> 8) & 0x03;
687
688 /* PB12 : MSB FreeSync Maximum refresh rate [Hz] - bits 9:8 */
689 infopacket->sb[12] = (max_programmed >> 8) & 0x03;
690
691 /* PB16 : Reserved bits 7:1, FixedRate bit 0 */
692 infopacket->sb[16] = (vrr->state == VRR_STATE_ACTIVE_FIXED) ? 1 : 0;
693 }
694
build_vrr_infopacket_fs2_data(enum color_transfer_func app_tf,struct dc_info_packet * infopacket)695 static void build_vrr_infopacket_fs2_data(enum color_transfer_func app_tf,
696 struct dc_info_packet *infopacket)
697 {
698 if (app_tf != TRANSFER_FUNC_UNKNOWN) {
699 infopacket->valid = true;
700
701 if (app_tf != TRANSFER_FUNC_PQ2084) {
702 infopacket->sb[6] |= 0x08; // PB6 = [Bit 3 = Native Color Active]
703 if (app_tf == TRANSFER_FUNC_GAMMA_22)
704 infopacket->sb[9] |= 0x04; // PB6 = [Bit 2 = Gamma 2.2 EOTF Active]
705 }
706 }
707 }
708
build_vrr_infopacket_header_v1(enum signal_type signal,struct dc_info_packet * infopacket,unsigned int * payload_size)709 static void build_vrr_infopacket_header_v1(enum signal_type signal,
710 struct dc_info_packet *infopacket,
711 unsigned int *payload_size)
712 {
713 if (dc_is_hdmi_signal(signal)) {
714
715 /* HEADER */
716
717 /* HB0 = Packet Type = 0x83 (Source Product
718 * Descriptor InfoFrame)
719 */
720 infopacket->hb0 = DC_HDMI_INFOFRAME_TYPE_SPD;
721
722 /* HB1 = Version = 0x01 */
723 infopacket->hb1 = 0x01;
724
725 /* HB2 = [Bits 7:5 = 0] [Bits 4:0 = Length = 0x08] */
726 infopacket->hb2 = 0x08;
727
728 *payload_size = 0x08;
729
730 } else if (dc_is_dp_signal(signal)) {
731
732 /* HEADER */
733
734 /* HB0 = Secondary-data Packet ID = 0 - Only non-zero
735 * when used to associate audio related info packets
736 */
737 infopacket->hb0 = 0x00;
738
739 /* HB1 = Packet Type = 0x83 (Source Product
740 * Descriptor InfoFrame)
741 */
742 infopacket->hb1 = DC_HDMI_INFOFRAME_TYPE_SPD;
743
744 /* HB2 = [Bits 7:0 = Least significant eight bits -
745 * For INFOFRAME, the value must be 1Bh]
746 */
747 infopacket->hb2 = 0x1B;
748
749 /* HB3 = [Bits 7:2 = INFOFRAME SDP Version Number = 0x1]
750 * [Bits 1:0 = Most significant two bits = 0x00]
751 */
752 infopacket->hb3 = 0x04;
753
754 *payload_size = 0x1B;
755 }
756 }
757
build_vrr_infopacket_header_v2(enum signal_type signal,struct dc_info_packet * infopacket,unsigned int * payload_size)758 static void build_vrr_infopacket_header_v2(enum signal_type signal,
759 struct dc_info_packet *infopacket,
760 unsigned int *payload_size)
761 {
762 if (dc_is_hdmi_signal(signal)) {
763
764 /* HEADER */
765
766 /* HB0 = Packet Type = 0x83 (Source Product
767 * Descriptor InfoFrame)
768 */
769 infopacket->hb0 = DC_HDMI_INFOFRAME_TYPE_SPD;
770
771 /* HB1 = Version = 0x02 */
772 infopacket->hb1 = 0x02;
773
774 /* HB2 = [Bits 7:5 = 0] [Bits 4:0 = Length = 0x09] */
775 infopacket->hb2 = 0x09;
776
777 *payload_size = 0x09;
778 } else if (dc_is_dp_signal(signal)) {
779
780 /* HEADER */
781
782 /* HB0 = Secondary-data Packet ID = 0 - Only non-zero
783 * when used to associate audio related info packets
784 */
785 infopacket->hb0 = 0x00;
786
787 /* HB1 = Packet Type = 0x83 (Source Product
788 * Descriptor InfoFrame)
789 */
790 infopacket->hb1 = DC_HDMI_INFOFRAME_TYPE_SPD;
791
792 /* HB2 = [Bits 7:0 = Least significant eight bits -
793 * For INFOFRAME, the value must be 1Bh]
794 */
795 infopacket->hb2 = 0x1B;
796
797 /* HB3 = [Bits 7:2 = INFOFRAME SDP Version Number = 0x2]
798 * [Bits 1:0 = Most significant two bits = 0x00]
799 */
800 infopacket->hb3 = 0x08;
801
802 *payload_size = 0x1B;
803 }
804 }
805
build_vrr_infopacket_header_v3(enum signal_type signal,struct dc_info_packet * infopacket,unsigned int * payload_size)806 static void build_vrr_infopacket_header_v3(enum signal_type signal,
807 struct dc_info_packet *infopacket,
808 unsigned int *payload_size)
809 {
810 unsigned char version;
811
812 version = 3;
813 if (dc_is_hdmi_signal(signal)) {
814
815 /* HEADER */
816
817 /* HB0 = Packet Type = 0x83 (Source Product
818 * Descriptor InfoFrame)
819 */
820 infopacket->hb0 = DC_HDMI_INFOFRAME_TYPE_SPD;
821
822 /* HB1 = Version = 0x03 */
823 infopacket->hb1 = version;
824
825 /* HB2 = [Bits 7:5 = 0] [Bits 4:0 = Length] */
826 infopacket->hb2 = 0x10;
827
828 *payload_size = 0x10;
829 } else if (dc_is_dp_signal(signal)) {
830
831 /* HEADER */
832
833 /* HB0 = Secondary-data Packet ID = 0 - Only non-zero
834 * when used to associate audio related info packets
835 */
836 infopacket->hb0 = 0x00;
837
838 /* HB1 = Packet Type = 0x83 (Source Product
839 * Descriptor InfoFrame)
840 */
841 infopacket->hb1 = DC_HDMI_INFOFRAME_TYPE_SPD;
842
843 /* HB2 = [Bits 7:0 = Least significant eight bits -
844 * For INFOFRAME, the value must be 1Bh]
845 */
846 infopacket->hb2 = 0x1B;
847
848 /* HB3 = [Bits 7:2 = INFOFRAME SDP Version Number = 0x2]
849 * [Bits 1:0 = Most significant two bits = 0x00]
850 */
851
852 infopacket->hb3 = (version & 0x3F) << 2;
853
854 *payload_size = 0x1B;
855 }
856 }
857
build_vrr_infopacket_checksum(unsigned int * payload_size,struct dc_info_packet * infopacket)858 static void build_vrr_infopacket_checksum(unsigned int *payload_size,
859 struct dc_info_packet *infopacket)
860 {
861 /* Calculate checksum */
862 unsigned int idx = 0;
863 unsigned char checksum = 0;
864
865 checksum += infopacket->hb0;
866 checksum += infopacket->hb1;
867 checksum += infopacket->hb2;
868 checksum += infopacket->hb3;
869
870 for (idx = 1; idx <= *payload_size; idx++)
871 checksum += infopacket->sb[idx];
872
873 /* PB0 = Checksum (one byte complement) */
874 infopacket->sb[0] = (unsigned char)(0x100 - checksum);
875
876 infopacket->valid = true;
877 }
878
build_vrr_infopacket_v1(enum signal_type signal,const struct mod_vrr_params * vrr,struct dc_info_packet * infopacket,bool freesync_on_desktop)879 static void build_vrr_infopacket_v1(enum signal_type signal,
880 const struct mod_vrr_params *vrr,
881 struct dc_info_packet *infopacket,
882 bool freesync_on_desktop)
883 {
884 /* SPD info packet for FreeSync */
885 unsigned int payload_size = 0;
886
887 build_vrr_infopacket_header_v1(signal, infopacket, &payload_size);
888 build_vrr_infopacket_data_v1(vrr, infopacket, freesync_on_desktop);
889 build_vrr_infopacket_checksum(&payload_size, infopacket);
890
891 infopacket->valid = true;
892 }
893
build_vrr_infopacket_v2(enum signal_type signal,const struct mod_vrr_params * vrr,enum color_transfer_func app_tf,struct dc_info_packet * infopacket,bool freesync_on_desktop)894 static void build_vrr_infopacket_v2(enum signal_type signal,
895 const struct mod_vrr_params *vrr,
896 enum color_transfer_func app_tf,
897 struct dc_info_packet *infopacket,
898 bool freesync_on_desktop)
899 {
900 unsigned int payload_size = 0;
901
902 build_vrr_infopacket_header_v2(signal, infopacket, &payload_size);
903 build_vrr_infopacket_data_v1(vrr, infopacket, freesync_on_desktop);
904
905 build_vrr_infopacket_fs2_data(app_tf, infopacket);
906
907 build_vrr_infopacket_checksum(&payload_size, infopacket);
908
909 infopacket->valid = true;
910 }
911
build_vrr_infopacket_v3(enum signal_type signal,const struct mod_vrr_params * vrr,enum color_transfer_func app_tf,struct dc_info_packet * infopacket,bool freesync_on_desktop)912 static void build_vrr_infopacket_v3(enum signal_type signal,
913 const struct mod_vrr_params *vrr,
914 enum color_transfer_func app_tf,
915 struct dc_info_packet *infopacket,
916 bool freesync_on_desktop)
917 {
918 unsigned int payload_size = 0;
919
920 build_vrr_infopacket_header_v3(signal, infopacket, &payload_size);
921 build_vrr_infopacket_data_v3(vrr, infopacket, freesync_on_desktop);
922
923 build_vrr_infopacket_fs2_data(app_tf, infopacket);
924
925 build_vrr_infopacket_checksum(&payload_size, infopacket);
926
927 infopacket->valid = true;
928 }
929
build_vrr_infopacket_sdp_v1_3(enum vrr_packet_type packet_type,struct dc_info_packet * infopacket)930 static void build_vrr_infopacket_sdp_v1_3(enum vrr_packet_type packet_type,
931 struct dc_info_packet *infopacket)
932 {
933 uint8_t idx = 0, size = 0;
934
935 size = ((packet_type == PACKET_TYPE_FS_V1) ? 0x08 :
936 (packet_type == PACKET_TYPE_FS_V3) ? 0x10 :
937 0x09);
938
939 for (idx = infopacket->hb2; idx > 1; idx--) // Data Byte Count: 0x1B
940 infopacket->sb[idx] = infopacket->sb[idx-1];
941
942 infopacket->sb[1] = size; // Length
943 infopacket->sb[0] = (infopacket->hb3 >> 2) & 0x3F;//Version
944 infopacket->hb3 = (0x13 << 2); // Header,SDP 1.3
945 infopacket->hb2 = 0x1D;
946 }
947
mod_freesync_build_vrr_infopacket(struct mod_freesync * mod_freesync,const struct dc_stream_state * stream,const struct mod_vrr_params * vrr,enum vrr_packet_type packet_type,enum color_transfer_func app_tf,struct dc_info_packet * infopacket,bool pack_sdp_v1_3)948 void mod_freesync_build_vrr_infopacket(struct mod_freesync *mod_freesync,
949 const struct dc_stream_state *stream,
950 const struct mod_vrr_params *vrr,
951 enum vrr_packet_type packet_type,
952 enum color_transfer_func app_tf,
953 struct dc_info_packet *infopacket,
954 bool pack_sdp_v1_3)
955 {
956 /* SPD info packet for FreeSync
957 * VTEM info packet for HdmiVRR
958 * Check if Freesync is supported. Return if false. If true,
959 * set the corresponding bit in the info packet
960 */
961 if (!vrr->send_info_frame)
962 return;
963
964 switch (packet_type) {
965 case PACKET_TYPE_FS_V3:
966 build_vrr_infopacket_v3(stream->signal, vrr, app_tf, infopacket, stream->freesync_on_desktop);
967 break;
968 case PACKET_TYPE_FS_V2:
969 build_vrr_infopacket_v2(stream->signal, vrr, app_tf, infopacket, stream->freesync_on_desktop);
970 break;
971 case PACKET_TYPE_VRR:
972 case PACKET_TYPE_FS_V1:
973 default:
974 build_vrr_infopacket_v1(stream->signal, vrr, infopacket, stream->freesync_on_desktop);
975 }
976
977 if (true == pack_sdp_v1_3 &&
978 true == dc_is_dp_signal(stream->signal) &&
979 packet_type != PACKET_TYPE_VRR &&
980 packet_type != PACKET_TYPE_VTEM)
981 build_vrr_infopacket_sdp_v1_3(packet_type, infopacket);
982 }
983
mod_freesync_build_vrr_params(struct mod_freesync * mod_freesync,const struct dc_stream_state * stream,struct mod_freesync_config * in_config,struct mod_vrr_params * in_out_vrr)984 void mod_freesync_build_vrr_params(struct mod_freesync *mod_freesync,
985 const struct dc_stream_state *stream,
986 struct mod_freesync_config *in_config,
987 struct mod_vrr_params *in_out_vrr)
988 {
989 struct core_freesync *core_freesync = NULL;
990 unsigned long long nominal_field_rate_in_uhz = 0;
991 unsigned long long rounded_nominal_in_uhz = 0;
992 unsigned int refresh_range = 0;
993 unsigned long long min_refresh_in_uhz = 0;
994 unsigned long long max_refresh_in_uhz = 0;
995 unsigned long long min_hardware_refresh_in_uhz = 0;
996
997 if (mod_freesync == NULL)
998 return;
999
1000 core_freesync = MOD_FREESYNC_TO_CORE(mod_freesync);
1001
1002 /* Calculate nominal field rate for stream */
1003 nominal_field_rate_in_uhz =
1004 mod_freesync_calc_nominal_field_rate(stream);
1005
1006 if (stream->ctx->dc->caps.max_v_total != 0 && stream->timing.h_total != 0) {
1007 min_hardware_refresh_in_uhz = div64_u64((stream->timing.pix_clk_100hz * 100000000ULL),
1008 (stream->timing.h_total * stream->ctx->dc->caps.max_v_total));
1009 }
1010 /* Limit minimum refresh rate to what can be supported by hardware */
1011 min_refresh_in_uhz = min_hardware_refresh_in_uhz > in_config->min_refresh_in_uhz ?
1012 min_hardware_refresh_in_uhz : in_config->min_refresh_in_uhz;
1013 max_refresh_in_uhz = in_config->max_refresh_in_uhz;
1014
1015 /* Full range may be larger than current video timing, so cap at nominal */
1016 if (max_refresh_in_uhz > nominal_field_rate_in_uhz)
1017 max_refresh_in_uhz = nominal_field_rate_in_uhz;
1018
1019 /* Full range may be larger than current video timing, so cap at nominal */
1020 if (min_refresh_in_uhz > max_refresh_in_uhz)
1021 min_refresh_in_uhz = max_refresh_in_uhz;
1022
1023 /* If a monitor reports exactly max refresh of 2x of min, enforce it on nominal */
1024 rounded_nominal_in_uhz =
1025 div_u64(nominal_field_rate_in_uhz + 50000, 100000) * 100000;
1026 if (in_config->max_refresh_in_uhz == (2 * in_config->min_refresh_in_uhz) &&
1027 in_config->max_refresh_in_uhz == rounded_nominal_in_uhz)
1028 min_refresh_in_uhz = div_u64(nominal_field_rate_in_uhz, 2);
1029
1030 if (!vrr_settings_require_update(core_freesync,
1031 in_config, (unsigned int)min_refresh_in_uhz, (unsigned int)max_refresh_in_uhz,
1032 in_out_vrr))
1033 return;
1034
1035 in_out_vrr->state = in_config->state;
1036 in_out_vrr->send_info_frame = in_config->vsif_supported;
1037
1038 if (in_config->state == VRR_STATE_UNSUPPORTED) {
1039 in_out_vrr->state = VRR_STATE_UNSUPPORTED;
1040 in_out_vrr->supported = false;
1041 in_out_vrr->adjust.v_total_min = stream->timing.v_total;
1042 in_out_vrr->adjust.v_total_max = stream->timing.v_total;
1043
1044 return;
1045
1046 } else {
1047 in_out_vrr->min_refresh_in_uhz = (unsigned int)min_refresh_in_uhz;
1048 in_out_vrr->max_duration_in_us =
1049 calc_duration_in_us_from_refresh_in_uhz(
1050 (unsigned int)min_refresh_in_uhz);
1051
1052 in_out_vrr->max_refresh_in_uhz = (unsigned int)max_refresh_in_uhz;
1053 in_out_vrr->min_duration_in_us =
1054 calc_duration_in_us_from_refresh_in_uhz(
1055 (unsigned int)max_refresh_in_uhz);
1056
1057 if (in_config->state == VRR_STATE_ACTIVE_FIXED)
1058 in_out_vrr->fixed_refresh_in_uhz = in_config->fixed_refresh_in_uhz;
1059 else
1060 in_out_vrr->fixed_refresh_in_uhz = 0;
1061
1062 refresh_range = div_u64(in_out_vrr->max_refresh_in_uhz + 500000, 1000000) -
1063 + div_u64(in_out_vrr->min_refresh_in_uhz + 500000, 1000000);
1064
1065 in_out_vrr->supported = true;
1066 }
1067
1068 in_out_vrr->fixed.ramping_active = in_config->ramping;
1069
1070 in_out_vrr->btr.btr_enabled = in_config->btr;
1071
1072 if (in_out_vrr->max_refresh_in_uhz < (2 * in_out_vrr->min_refresh_in_uhz))
1073 in_out_vrr->btr.btr_enabled = false;
1074 else {
1075 in_out_vrr->btr.margin_in_us = in_out_vrr->max_duration_in_us -
1076 2 * in_out_vrr->min_duration_in_us;
1077 if (in_out_vrr->btr.margin_in_us > BTR_MAX_MARGIN)
1078 in_out_vrr->btr.margin_in_us = BTR_MAX_MARGIN;
1079 }
1080
1081 in_out_vrr->btr.btr_active = false;
1082 in_out_vrr->btr.inserted_duration_in_us = 0;
1083 in_out_vrr->btr.frames_to_insert = 0;
1084 in_out_vrr->btr.frame_counter = 0;
1085 in_out_vrr->fixed.fixed_active = false;
1086 in_out_vrr->fixed.target_refresh_in_uhz = 0;
1087
1088 in_out_vrr->btr.mid_point_in_us =
1089 (in_out_vrr->min_duration_in_us +
1090 in_out_vrr->max_duration_in_us) / 2;
1091
1092 if (in_out_vrr->state == VRR_STATE_UNSUPPORTED) {
1093 in_out_vrr->adjust.v_total_min = stream->timing.v_total;
1094 in_out_vrr->adjust.v_total_max = stream->timing.v_total;
1095 } else if (in_out_vrr->state == VRR_STATE_DISABLED) {
1096 in_out_vrr->adjust.v_total_min = stream->timing.v_total;
1097 in_out_vrr->adjust.v_total_max = stream->timing.v_total;
1098 } else if (in_out_vrr->state == VRR_STATE_INACTIVE) {
1099 in_out_vrr->adjust.v_total_min = stream->timing.v_total;
1100 in_out_vrr->adjust.v_total_max = stream->timing.v_total;
1101 } else if (in_out_vrr->state == VRR_STATE_ACTIVE_VARIABLE &&
1102 refresh_range >= MIN_REFRESH_RANGE) {
1103
1104 in_out_vrr->adjust.v_total_min =
1105 mod_freesync_calc_v_total_from_refresh(stream,
1106 in_out_vrr->max_refresh_in_uhz);
1107 in_out_vrr->adjust.v_total_max =
1108 mod_freesync_calc_v_total_from_refresh(stream,
1109 in_out_vrr->min_refresh_in_uhz);
1110 } else if (in_out_vrr->state == VRR_STATE_ACTIVE_FIXED) {
1111 in_out_vrr->fixed.target_refresh_in_uhz =
1112 in_out_vrr->fixed_refresh_in_uhz;
1113 if (in_out_vrr->fixed.ramping_active &&
1114 in_out_vrr->fixed.fixed_active) {
1115 /* Do not update vtotals if ramping is already active
1116 * in order to continue ramp from current refresh.
1117 */
1118 in_out_vrr->fixed.fixed_active = true;
1119 } else {
1120 in_out_vrr->fixed.fixed_active = true;
1121 in_out_vrr->adjust.v_total_min =
1122 mod_freesync_calc_v_total_from_refresh(stream,
1123 in_out_vrr->fixed.target_refresh_in_uhz);
1124 in_out_vrr->adjust.v_total_max =
1125 in_out_vrr->adjust.v_total_min;
1126 }
1127 } else {
1128 in_out_vrr->state = VRR_STATE_INACTIVE;
1129 in_out_vrr->adjust.v_total_min = stream->timing.v_total;
1130 in_out_vrr->adjust.v_total_max = stream->timing.v_total;
1131 }
1132 }
1133
mod_freesync_handle_preflip(struct mod_freesync * mod_freesync,const struct dc_plane_state * plane,const struct dc_stream_state * stream,unsigned int curr_time_stamp_in_us,struct mod_vrr_params * in_out_vrr)1134 void mod_freesync_handle_preflip(struct mod_freesync *mod_freesync,
1135 const struct dc_plane_state *plane,
1136 const struct dc_stream_state *stream,
1137 unsigned int curr_time_stamp_in_us,
1138 struct mod_vrr_params *in_out_vrr)
1139 {
1140 struct core_freesync *core_freesync = NULL;
1141 unsigned int last_render_time_in_us = 0;
1142
1143 if (mod_freesync == NULL)
1144 return;
1145
1146 core_freesync = MOD_FREESYNC_TO_CORE(mod_freesync);
1147
1148 if (in_out_vrr->supported &&
1149 in_out_vrr->state == VRR_STATE_ACTIVE_VARIABLE) {
1150
1151 last_render_time_in_us = curr_time_stamp_in_us -
1152 plane->time.prev_update_time_in_us;
1153
1154 if (in_out_vrr->btr.btr_enabled) {
1155 apply_below_the_range(core_freesync,
1156 stream,
1157 last_render_time_in_us,
1158 in_out_vrr);
1159 } else {
1160 apply_fixed_refresh(core_freesync,
1161 stream,
1162 last_render_time_in_us,
1163 in_out_vrr);
1164 }
1165
1166 determine_flip_interval_workaround_req(in_out_vrr,
1167 curr_time_stamp_in_us);
1168
1169 }
1170 }
1171
mod_freesync_handle_v_update(struct mod_freesync * mod_freesync,const struct dc_stream_state * stream,struct mod_vrr_params * in_out_vrr)1172 void mod_freesync_handle_v_update(struct mod_freesync *mod_freesync,
1173 const struct dc_stream_state *stream,
1174 struct mod_vrr_params *in_out_vrr)
1175 {
1176 struct core_freesync *core_freesync = NULL;
1177 unsigned int cur_timestamp_in_us;
1178 unsigned long long cur_tick;
1179
1180 if ((mod_freesync == NULL) || (stream == NULL) || (in_out_vrr == NULL))
1181 return;
1182
1183 core_freesync = MOD_FREESYNC_TO_CORE(mod_freesync);
1184
1185 if (in_out_vrr->supported == false)
1186 return;
1187
1188 cur_tick = dm_get_timestamp(core_freesync->dc->ctx);
1189 cur_timestamp_in_us = (unsigned int)
1190 div_u64(dm_get_elapse_time_in_ns(core_freesync->dc->ctx, cur_tick, 0), 1000);
1191
1192 in_out_vrr->flip_interval.vsyncs_between_flip++;
1193 in_out_vrr->flip_interval.v_update_timestamp_in_us = cur_timestamp_in_us;
1194
1195 if (in_out_vrr->state == VRR_STATE_ACTIVE_VARIABLE &&
1196 (in_out_vrr->flip_interval.flip_interval_workaround_active ||
1197 (!in_out_vrr->flip_interval.flip_interval_workaround_active &&
1198 in_out_vrr->flip_interval.program_flip_interval_workaround))) {
1199 // set freesync vmin vmax to nominal for workaround
1200 in_out_vrr->adjust.v_total_min =
1201 mod_freesync_calc_v_total_from_refresh(
1202 stream, in_out_vrr->max_refresh_in_uhz);
1203 in_out_vrr->adjust.v_total_max =
1204 in_out_vrr->adjust.v_total_min;
1205 in_out_vrr->flip_interval.program_flip_interval_workaround = false;
1206 in_out_vrr->flip_interval.do_flip_interval_workaround_cleanup = true;
1207 return;
1208 }
1209
1210 if (in_out_vrr->state != VRR_STATE_ACTIVE_VARIABLE &&
1211 in_out_vrr->flip_interval.do_flip_interval_workaround_cleanup) {
1212 in_out_vrr->flip_interval.do_flip_interval_workaround_cleanup = false;
1213 in_out_vrr->flip_interval.flip_interval_detect_counter = 0;
1214 in_out_vrr->flip_interval.vsyncs_between_flip = 0;
1215 in_out_vrr->flip_interval.vsync_to_flip_in_us = 0;
1216 }
1217
1218 /* Below the Range Logic */
1219
1220 /* Only execute if in fullscreen mode */
1221 if (in_out_vrr->state == VRR_STATE_ACTIVE_VARIABLE &&
1222 in_out_vrr->btr.btr_active) {
1223 /* TODO: pass in flag for Pre-DCE12 ASIC
1224 * in order for frame variable duration to take affect,
1225 * it needs to be done one VSYNC early, which is at
1226 * frameCounter == 1.
1227 * For DCE12 and newer updates to V_TOTAL_MIN/MAX
1228 * will take affect on current frame
1229 */
1230 if (in_out_vrr->btr.frames_to_insert ==
1231 in_out_vrr->btr.frame_counter) {
1232 in_out_vrr->adjust.v_total_min =
1233 calc_v_total_from_duration(stream,
1234 in_out_vrr,
1235 in_out_vrr->btr.inserted_duration_in_us);
1236 in_out_vrr->adjust.v_total_max =
1237 in_out_vrr->adjust.v_total_min;
1238 }
1239
1240 if (in_out_vrr->btr.frame_counter > 0)
1241 in_out_vrr->btr.frame_counter--;
1242
1243 /* Restore FreeSync */
1244 if (in_out_vrr->btr.frame_counter == 0) {
1245 in_out_vrr->adjust.v_total_min =
1246 mod_freesync_calc_v_total_from_refresh(stream,
1247 in_out_vrr->max_refresh_in_uhz);
1248 in_out_vrr->adjust.v_total_max =
1249 mod_freesync_calc_v_total_from_refresh(stream,
1250 in_out_vrr->min_refresh_in_uhz);
1251 }
1252 }
1253
1254 /* If in fullscreen freesync mode or in video, do not program
1255 * static screen ramp values
1256 */
1257 if (in_out_vrr->state == VRR_STATE_ACTIVE_VARIABLE)
1258 in_out_vrr->fixed.ramping_active = false;
1259
1260 /* Gradual Static Screen Ramping Logic
1261 * Execute if ramp is active and user enabled freesync static screen
1262 */
1263 if (in_out_vrr->state == VRR_STATE_ACTIVE_FIXED &&
1264 in_out_vrr->fixed.ramping_active) {
1265 update_v_total_for_static_ramp(
1266 core_freesync, stream, in_out_vrr);
1267 }
1268 }
1269
mod_freesync_get_settings(struct mod_freesync * mod_freesync,const struct mod_vrr_params * vrr,unsigned int * v_total_min,unsigned int * v_total_max,unsigned int * event_triggers,unsigned int * window_min,unsigned int * window_max,unsigned int * lfc_mid_point_in_us,unsigned int * inserted_frames,unsigned int * inserted_duration_in_us)1270 void mod_freesync_get_settings(struct mod_freesync *mod_freesync,
1271 const struct mod_vrr_params *vrr,
1272 unsigned int *v_total_min, unsigned int *v_total_max,
1273 unsigned int *event_triggers,
1274 unsigned int *window_min, unsigned int *window_max,
1275 unsigned int *lfc_mid_point_in_us,
1276 unsigned int *inserted_frames,
1277 unsigned int *inserted_duration_in_us)
1278 {
1279 if (mod_freesync == NULL)
1280 return;
1281
1282 if (vrr->supported) {
1283 *v_total_min = vrr->adjust.v_total_min;
1284 *v_total_max = vrr->adjust.v_total_max;
1285 *event_triggers = 0;
1286 *lfc_mid_point_in_us = vrr->btr.mid_point_in_us;
1287 *inserted_frames = vrr->btr.frames_to_insert;
1288 *inserted_duration_in_us = vrr->btr.inserted_duration_in_us;
1289 }
1290 }
1291
mod_freesync_calc_nominal_field_rate(const struct dc_stream_state * stream)1292 unsigned long long mod_freesync_calc_nominal_field_rate(
1293 const struct dc_stream_state *stream)
1294 {
1295 unsigned long long nominal_field_rate_in_uhz = 0;
1296 unsigned int total = stream->timing.h_total * stream->timing.v_total;
1297
1298 /* Calculate nominal field rate for stream, rounded up to nearest integer */
1299 nominal_field_rate_in_uhz = stream->timing.pix_clk_100hz;
1300 nominal_field_rate_in_uhz *= 100000000ULL;
1301
1302 nominal_field_rate_in_uhz = div_u64(nominal_field_rate_in_uhz, total);
1303
1304 return nominal_field_rate_in_uhz;
1305 }
1306
mod_freesync_calc_field_rate_from_timing(unsigned int vtotal,unsigned int htotal,unsigned int pix_clk)1307 unsigned long long mod_freesync_calc_field_rate_from_timing(
1308 unsigned int vtotal, unsigned int htotal, unsigned int pix_clk)
1309 {
1310 unsigned long long field_rate_in_uhz = 0;
1311 unsigned int total = htotal * vtotal;
1312
1313 /* Calculate nominal field rate for stream, rounded up to nearest integer */
1314 field_rate_in_uhz = pix_clk;
1315 field_rate_in_uhz *= 1000000ULL;
1316
1317 field_rate_in_uhz = div_u64(field_rate_in_uhz, total);
1318
1319 return field_rate_in_uhz;
1320 }
1321
mod_freesync_get_freesync_enabled(struct mod_vrr_params * pVrr)1322 bool mod_freesync_get_freesync_enabled(struct mod_vrr_params *pVrr)
1323 {
1324 return (pVrr->state != VRR_STATE_UNSUPPORTED) && (pVrr->state != VRR_STATE_DISABLED);
1325 }
1326
mod_freesync_is_valid_range(uint32_t min_refresh_cap_in_uhz,uint32_t max_refresh_cap_in_uhz,uint32_t nominal_field_rate_in_uhz)1327 bool mod_freesync_is_valid_range(uint32_t min_refresh_cap_in_uhz,
1328 uint32_t max_refresh_cap_in_uhz,
1329 uint32_t nominal_field_rate_in_uhz)
1330 {
1331
1332 /* Typically nominal refresh calculated can have some fractional part.
1333 * Allow for some rounding error of actual video timing by taking floor
1334 * of caps and request. Round the nominal refresh rate.
1335 *
1336 * Dividing will convert everything to units in Hz although input
1337 * variable name is in uHz!
1338 *
1339 * Also note, this takes care of rounding error on the nominal refresh
1340 * so by rounding error we only expect it to be off by a small amount,
1341 * such as < 0.1 Hz. i.e. 143.9xxx or 144.1xxx.
1342 *
1343 * Example 1. Caps Min = 40 Hz, Max = 144 Hz
1344 * Request Min = 40 Hz, Max = 144 Hz
1345 * Nominal = 143.5x Hz rounded to 144 Hz
1346 * This function should allow this as valid request
1347 *
1348 * Example 2. Caps Min = 40 Hz, Max = 144 Hz
1349 * Request Min = 40 Hz, Max = 144 Hz
1350 * Nominal = 144.4x Hz rounded to 144 Hz
1351 * This function should allow this as valid request
1352 *
1353 * Example 3. Caps Min = 40 Hz, Max = 144 Hz
1354 * Request Min = 40 Hz, Max = 144 Hz
1355 * Nominal = 120.xx Hz rounded to 120 Hz
1356 * This function should return NOT valid since the requested
1357 * max is greater than current timing's nominal
1358 *
1359 * Example 4. Caps Min = 40 Hz, Max = 120 Hz
1360 * Request Min = 40 Hz, Max = 120 Hz
1361 * Nominal = 144.xx Hz rounded to 144 Hz
1362 * This function should return NOT valid since the nominal
1363 * is greater than the capability's max refresh
1364 */
1365 nominal_field_rate_in_uhz =
1366 div_u64(nominal_field_rate_in_uhz + 500000, 1000000);
1367 min_refresh_cap_in_uhz /= 1000000;
1368 max_refresh_cap_in_uhz /= 1000000;
1369
1370 /* Check nominal is within range */
1371 if (nominal_field_rate_in_uhz > max_refresh_cap_in_uhz ||
1372 nominal_field_rate_in_uhz < min_refresh_cap_in_uhz)
1373 return false;
1374
1375 /* If nominal is less than max, limit the max allowed refresh rate */
1376 if (nominal_field_rate_in_uhz < max_refresh_cap_in_uhz)
1377 max_refresh_cap_in_uhz = nominal_field_rate_in_uhz;
1378
1379 /* Check min is within range */
1380 if (min_refresh_cap_in_uhz > max_refresh_cap_in_uhz)
1381 return false;
1382
1383 /* For variable range, check for at least 10 Hz range */
1384 if (nominal_field_rate_in_uhz - min_refresh_cap_in_uhz < 10)
1385 return false;
1386
1387 return true;
1388 }
1389