1 // SPDX-License-Identifier: LGPL-2.1+
2 /*
3 * Copyright 2016 Tom aan de Wiel
4 * Copyright 2018 Cisco Systems, Inc. and/or its affiliates. All rights reserved.
5 *
6 * 8x8 Fast Walsh Hadamard Transform in sequency order based on the paper:
7 *
8 * A Recursive Algorithm for Sequency-Ordered Fast Walsh Transforms,
9 * R.D. Brown, 1977
10 */
11
12 #include <linux/string.h>
13 #include <linux/kernel.h>
14 #include <linux/videodev2.h>
15 #include "codec-fwht.h"
16
17 #define OVERFLOW_BIT BIT(14)
18
19 /*
20 * Note: bit 0 of the header must always be 0. Otherwise it cannot
21 * be guaranteed that the magic 8 byte sequence (see below) can
22 * never occur in the rlc output.
23 */
24 #define PFRAME_BIT BIT(15)
25 #define DUPS_MASK 0x1ffe
26
27 #define PBLOCK 0
28 #define IBLOCK 1
29
30 #define ALL_ZEROS 15
31
32 static const uint8_t zigzag[64] = {
33 0,
34 1, 8,
35 2, 9, 16,
36 3, 10, 17, 24,
37 4, 11, 18, 25, 32,
38 5, 12, 19, 26, 33, 40,
39 6, 13, 20, 27, 34, 41, 48,
40 7, 14, 21, 28, 35, 42, 49, 56,
41 15, 22, 29, 36, 43, 50, 57,
42 23, 30, 37, 44, 51, 58,
43 31, 38, 45, 52, 59,
44 39, 46, 53, 60,
45 47, 54, 61,
46 55, 62,
47 63,
48 };
49
50 /*
51 * noinline_for_stack to work around
52 * https://bugs.llvm.org/show_bug.cgi?id=38809
53 */
54 static int noinline_for_stack
rlc(const s16 * in,__be16 * output,int blocktype)55 rlc(const s16 *in, __be16 *output, int blocktype)
56 {
57 s16 block[8 * 8];
58 s16 *wp = block;
59 int i = 0;
60 int x, y;
61 int ret = 0;
62
63 /* read in block from framebuffer */
64 int lastzero_run = 0;
65 int to_encode;
66
67 for (y = 0; y < 8; y++) {
68 for (x = 0; x < 8; x++) {
69 *wp = in[x + y * 8];
70 wp++;
71 }
72 }
73
74 /* keep track of amount of trailing zeros */
75 for (i = 63; i >= 0 && !block[zigzag[i]]; i--)
76 lastzero_run++;
77
78 *output++ = (blocktype == PBLOCK ? htons(PFRAME_BIT) : 0);
79 ret++;
80
81 to_encode = 8 * 8 - (lastzero_run > 14 ? lastzero_run : 0);
82
83 i = 0;
84 while (i < to_encode) {
85 int cnt = 0;
86 int tmp;
87
88 /* count leading zeros */
89 while ((tmp = block[zigzag[i]]) == 0 && cnt < 14) {
90 cnt++;
91 i++;
92 if (i == to_encode) {
93 cnt--;
94 break;
95 }
96 }
97 /* 4 bits for run, 12 for coefficient (quantization by 4) */
98 *output++ = htons((cnt | tmp << 4));
99 i++;
100 ret++;
101 }
102 if (lastzero_run > 14) {
103 *output = htons(ALL_ZEROS | 0);
104 ret++;
105 }
106
107 return ret;
108 }
109
110 /*
111 * This function will worst-case increase rlc_in by 65*2 bytes:
112 * one s16 value for the header and 8 * 8 coefficients of type s16.
113 */
114 static noinline_for_stack u16
derlc(const __be16 ** rlc_in,s16 * dwht_out,const __be16 * end_of_input)115 derlc(const __be16 **rlc_in, s16 *dwht_out, const __be16 *end_of_input)
116 {
117 /* header */
118 const __be16 *input = *rlc_in;
119 u16 stat;
120 int dec_count = 0;
121 s16 block[8 * 8 + 16];
122 s16 *wp = block;
123 int i;
124
125 if (input > end_of_input)
126 return OVERFLOW_BIT;
127 stat = ntohs(*input++);
128
129 /*
130 * Now de-compress, it expands one byte to up to 15 bytes
131 * (or fills the remainder of the 64 bytes with zeroes if it
132 * is the last byte to expand).
133 *
134 * So block has to be 8 * 8 + 16 bytes, the '+ 16' is to
135 * allow for overflow if the incoming data was malformed.
136 */
137 while (dec_count < 8 * 8) {
138 s16 in;
139 int length;
140 int coeff;
141
142 if (input > end_of_input)
143 return OVERFLOW_BIT;
144 in = ntohs(*input++);
145 length = in & 0xf;
146 coeff = in >> 4;
147
148 /* fill remainder with zeros */
149 if (length == 15) {
150 for (i = 0; i < 64 - dec_count; i++)
151 *wp++ = 0;
152 break;
153 }
154
155 for (i = 0; i < length; i++)
156 *wp++ = 0;
157 *wp++ = coeff;
158 dec_count += length + 1;
159 }
160
161 wp = block;
162
163 for (i = 0; i < 64; i++) {
164 int pos = zigzag[i];
165 int y = pos / 8;
166 int x = pos % 8;
167
168 dwht_out[x + y * 8] = *wp++;
169 }
170 *rlc_in = input;
171 return stat;
172 }
173
174 static const int quant_table[] = {
175 2, 2, 2, 2, 2, 2, 2, 2,
176 2, 2, 2, 2, 2, 2, 2, 2,
177 2, 2, 2, 2, 2, 2, 2, 3,
178 2, 2, 2, 2, 2, 2, 3, 6,
179 2, 2, 2, 2, 2, 3, 6, 6,
180 2, 2, 2, 2, 3, 6, 6, 6,
181 2, 2, 2, 3, 6, 6, 6, 6,
182 2, 2, 3, 6, 6, 6, 6, 8,
183 };
184
185 static const int quant_table_p[] = {
186 3, 3, 3, 3, 3, 3, 3, 3,
187 3, 3, 3, 3, 3, 3, 3, 3,
188 3, 3, 3, 3, 3, 3, 3, 3,
189 3, 3, 3, 3, 3, 3, 3, 6,
190 3, 3, 3, 3, 3, 3, 6, 6,
191 3, 3, 3, 3, 3, 6, 6, 9,
192 3, 3, 3, 3, 6, 6, 9, 9,
193 3, 3, 3, 6, 6, 9, 9, 10,
194 };
195
quantize_intra(s16 * coeff,s16 * de_coeff,u16 qp)196 static void quantize_intra(s16 *coeff, s16 *de_coeff, u16 qp)
197 {
198 const int *quant = quant_table;
199 int i, j;
200
201 for (j = 0; j < 8; j++) {
202 for (i = 0; i < 8; i++, quant++, coeff++, de_coeff++) {
203 *coeff >>= *quant;
204 if (*coeff >= -qp && *coeff <= qp)
205 *coeff = *de_coeff = 0;
206 else
207 *de_coeff = *coeff << *quant;
208 }
209 }
210 }
211
dequantize_intra(s16 * coeff)212 static void dequantize_intra(s16 *coeff)
213 {
214 const int *quant = quant_table;
215 int i, j;
216
217 for (j = 0; j < 8; j++)
218 for (i = 0; i < 8; i++, quant++, coeff++)
219 *coeff <<= *quant;
220 }
221
quantize_inter(s16 * coeff,s16 * de_coeff,u16 qp)222 static void quantize_inter(s16 *coeff, s16 *de_coeff, u16 qp)
223 {
224 const int *quant = quant_table_p;
225 int i, j;
226
227 for (j = 0; j < 8; j++) {
228 for (i = 0; i < 8; i++, quant++, coeff++, de_coeff++) {
229 *coeff >>= *quant;
230 if (*coeff >= -qp && *coeff <= qp)
231 *coeff = *de_coeff = 0;
232 else
233 *de_coeff = *coeff << *quant;
234 }
235 }
236 }
237
dequantize_inter(s16 * coeff)238 static void dequantize_inter(s16 *coeff)
239 {
240 const int *quant = quant_table_p;
241 int i, j;
242
243 for (j = 0; j < 8; j++)
244 for (i = 0; i < 8; i++, quant++, coeff++)
245 *coeff <<= *quant;
246 }
247
fwht(const u8 * block,s16 * output_block,unsigned int stride,unsigned int input_step,bool intra)248 static void noinline_for_stack fwht(const u8 *block, s16 *output_block,
249 unsigned int stride,
250 unsigned int input_step, bool intra)
251 {
252 /* we'll need more than 8 bits for the transformed coefficients */
253 s32 workspace1[8], workspace2[8];
254 const u8 *tmp = block;
255 s16 *out = output_block;
256 int add = intra ? 256 : 0;
257 unsigned int i;
258
259 /* stage 1 */
260 for (i = 0; i < 8; i++, tmp += stride, out += 8) {
261 switch (input_step) {
262 case 1:
263 workspace1[0] = tmp[0] + tmp[1] - add;
264 workspace1[1] = tmp[0] - tmp[1];
265
266 workspace1[2] = tmp[2] + tmp[3] - add;
267 workspace1[3] = tmp[2] - tmp[3];
268
269 workspace1[4] = tmp[4] + tmp[5] - add;
270 workspace1[5] = tmp[4] - tmp[5];
271
272 workspace1[6] = tmp[6] + tmp[7] - add;
273 workspace1[7] = tmp[6] - tmp[7];
274 break;
275 case 2:
276 workspace1[0] = tmp[0] + tmp[2] - add;
277 workspace1[1] = tmp[0] - tmp[2];
278
279 workspace1[2] = tmp[4] + tmp[6] - add;
280 workspace1[3] = tmp[4] - tmp[6];
281
282 workspace1[4] = tmp[8] + tmp[10] - add;
283 workspace1[5] = tmp[8] - tmp[10];
284
285 workspace1[6] = tmp[12] + tmp[14] - add;
286 workspace1[7] = tmp[12] - tmp[14];
287 break;
288 case 3:
289 workspace1[0] = tmp[0] + tmp[3] - add;
290 workspace1[1] = tmp[0] - tmp[3];
291
292 workspace1[2] = tmp[6] + tmp[9] - add;
293 workspace1[3] = tmp[6] - tmp[9];
294
295 workspace1[4] = tmp[12] + tmp[15] - add;
296 workspace1[5] = tmp[12] - tmp[15];
297
298 workspace1[6] = tmp[18] + tmp[21] - add;
299 workspace1[7] = tmp[18] - tmp[21];
300 break;
301 default:
302 workspace1[0] = tmp[0] + tmp[4] - add;
303 workspace1[1] = tmp[0] - tmp[4];
304
305 workspace1[2] = tmp[8] + tmp[12] - add;
306 workspace1[3] = tmp[8] - tmp[12];
307
308 workspace1[4] = tmp[16] + tmp[20] - add;
309 workspace1[5] = tmp[16] - tmp[20];
310
311 workspace1[6] = tmp[24] + tmp[28] - add;
312 workspace1[7] = tmp[24] - tmp[28];
313 break;
314 }
315
316 /* stage 2 */
317 workspace2[0] = workspace1[0] + workspace1[2];
318 workspace2[1] = workspace1[0] - workspace1[2];
319 workspace2[2] = workspace1[1] - workspace1[3];
320 workspace2[3] = workspace1[1] + workspace1[3];
321
322 workspace2[4] = workspace1[4] + workspace1[6];
323 workspace2[5] = workspace1[4] - workspace1[6];
324 workspace2[6] = workspace1[5] - workspace1[7];
325 workspace2[7] = workspace1[5] + workspace1[7];
326
327 /* stage 3 */
328 out[0] = workspace2[0] + workspace2[4];
329 out[1] = workspace2[0] - workspace2[4];
330 out[2] = workspace2[1] - workspace2[5];
331 out[3] = workspace2[1] + workspace2[5];
332 out[4] = workspace2[2] + workspace2[6];
333 out[5] = workspace2[2] - workspace2[6];
334 out[6] = workspace2[3] - workspace2[7];
335 out[7] = workspace2[3] + workspace2[7];
336 }
337
338 out = output_block;
339
340 for (i = 0; i < 8; i++, out++) {
341 /* stage 1 */
342 workspace1[0] = out[0] + out[1 * 8];
343 workspace1[1] = out[0] - out[1 * 8];
344
345 workspace1[2] = out[2 * 8] + out[3 * 8];
346 workspace1[3] = out[2 * 8] - out[3 * 8];
347
348 workspace1[4] = out[4 * 8] + out[5 * 8];
349 workspace1[5] = out[4 * 8] - out[5 * 8];
350
351 workspace1[6] = out[6 * 8] + out[7 * 8];
352 workspace1[7] = out[6 * 8] - out[7 * 8];
353
354 /* stage 2 */
355 workspace2[0] = workspace1[0] + workspace1[2];
356 workspace2[1] = workspace1[0] - workspace1[2];
357 workspace2[2] = workspace1[1] - workspace1[3];
358 workspace2[3] = workspace1[1] + workspace1[3];
359
360 workspace2[4] = workspace1[4] + workspace1[6];
361 workspace2[5] = workspace1[4] - workspace1[6];
362 workspace2[6] = workspace1[5] - workspace1[7];
363 workspace2[7] = workspace1[5] + workspace1[7];
364 /* stage 3 */
365 out[0 * 8] = workspace2[0] + workspace2[4];
366 out[1 * 8] = workspace2[0] - workspace2[4];
367 out[2 * 8] = workspace2[1] - workspace2[5];
368 out[3 * 8] = workspace2[1] + workspace2[5];
369 out[4 * 8] = workspace2[2] + workspace2[6];
370 out[5 * 8] = workspace2[2] - workspace2[6];
371 out[6 * 8] = workspace2[3] - workspace2[7];
372 out[7 * 8] = workspace2[3] + workspace2[7];
373 }
374 }
375
376 /*
377 * Not the nicest way of doing it, but P-blocks get twice the range of
378 * that of the I-blocks. Therefore we need a type bigger than 8 bits.
379 * Furthermore values can be negative... This is just a version that
380 * works with 16 signed data
381 */
382 static void noinline_for_stack
fwht16(const s16 * block,s16 * output_block,int stride,int intra)383 fwht16(const s16 *block, s16 *output_block, int stride, int intra)
384 {
385 /* we'll need more than 8 bits for the transformed coefficients */
386 s32 workspace1[8], workspace2[8];
387 const s16 *tmp = block;
388 s16 *out = output_block;
389 int i;
390
391 for (i = 0; i < 8; i++, tmp += stride, out += 8) {
392 /* stage 1 */
393 workspace1[0] = tmp[0] + tmp[1];
394 workspace1[1] = tmp[0] - tmp[1];
395
396 workspace1[2] = tmp[2] + tmp[3];
397 workspace1[3] = tmp[2] - tmp[3];
398
399 workspace1[4] = tmp[4] + tmp[5];
400 workspace1[5] = tmp[4] - tmp[5];
401
402 workspace1[6] = tmp[6] + tmp[7];
403 workspace1[7] = tmp[6] - tmp[7];
404
405 /* stage 2 */
406 workspace2[0] = workspace1[0] + workspace1[2];
407 workspace2[1] = workspace1[0] - workspace1[2];
408 workspace2[2] = workspace1[1] - workspace1[3];
409 workspace2[3] = workspace1[1] + workspace1[3];
410
411 workspace2[4] = workspace1[4] + workspace1[6];
412 workspace2[5] = workspace1[4] - workspace1[6];
413 workspace2[6] = workspace1[5] - workspace1[7];
414 workspace2[7] = workspace1[5] + workspace1[7];
415
416 /* stage 3 */
417 out[0] = workspace2[0] + workspace2[4];
418 out[1] = workspace2[0] - workspace2[4];
419 out[2] = workspace2[1] - workspace2[5];
420 out[3] = workspace2[1] + workspace2[5];
421 out[4] = workspace2[2] + workspace2[6];
422 out[5] = workspace2[2] - workspace2[6];
423 out[6] = workspace2[3] - workspace2[7];
424 out[7] = workspace2[3] + workspace2[7];
425 }
426
427 out = output_block;
428
429 for (i = 0; i < 8; i++, out++) {
430 /* stage 1 */
431 workspace1[0] = out[0] + out[1*8];
432 workspace1[1] = out[0] - out[1*8];
433
434 workspace1[2] = out[2*8] + out[3*8];
435 workspace1[3] = out[2*8] - out[3*8];
436
437 workspace1[4] = out[4*8] + out[5*8];
438 workspace1[5] = out[4*8] - out[5*8];
439
440 workspace1[6] = out[6*8] + out[7*8];
441 workspace1[7] = out[6*8] - out[7*8];
442
443 /* stage 2 */
444 workspace2[0] = workspace1[0] + workspace1[2];
445 workspace2[1] = workspace1[0] - workspace1[2];
446 workspace2[2] = workspace1[1] - workspace1[3];
447 workspace2[3] = workspace1[1] + workspace1[3];
448
449 workspace2[4] = workspace1[4] + workspace1[6];
450 workspace2[5] = workspace1[4] - workspace1[6];
451 workspace2[6] = workspace1[5] - workspace1[7];
452 workspace2[7] = workspace1[5] + workspace1[7];
453
454 /* stage 3 */
455 out[0*8] = workspace2[0] + workspace2[4];
456 out[1*8] = workspace2[0] - workspace2[4];
457 out[2*8] = workspace2[1] - workspace2[5];
458 out[3*8] = workspace2[1] + workspace2[5];
459 out[4*8] = workspace2[2] + workspace2[6];
460 out[5*8] = workspace2[2] - workspace2[6];
461 out[6*8] = workspace2[3] - workspace2[7];
462 out[7*8] = workspace2[3] + workspace2[7];
463 }
464 }
465
466 static noinline_for_stack void
ifwht(const s16 * block,s16 * output_block,int intra)467 ifwht(const s16 *block, s16 *output_block, int intra)
468 {
469 /*
470 * we'll need more than 8 bits for the transformed coefficients
471 * use native unit of cpu
472 */
473 int workspace1[8], workspace2[8];
474 int inter = intra ? 0 : 1;
475 const s16 *tmp = block;
476 s16 *out = output_block;
477 int i;
478
479 for (i = 0; i < 8; i++, tmp += 8, out += 8) {
480 /* stage 1 */
481 workspace1[0] = tmp[0] + tmp[1];
482 workspace1[1] = tmp[0] - tmp[1];
483
484 workspace1[2] = tmp[2] + tmp[3];
485 workspace1[3] = tmp[2] - tmp[3];
486
487 workspace1[4] = tmp[4] + tmp[5];
488 workspace1[5] = tmp[4] - tmp[5];
489
490 workspace1[6] = tmp[6] + tmp[7];
491 workspace1[7] = tmp[6] - tmp[7];
492
493 /* stage 2 */
494 workspace2[0] = workspace1[0] + workspace1[2];
495 workspace2[1] = workspace1[0] - workspace1[2];
496 workspace2[2] = workspace1[1] - workspace1[3];
497 workspace2[3] = workspace1[1] + workspace1[3];
498
499 workspace2[4] = workspace1[4] + workspace1[6];
500 workspace2[5] = workspace1[4] - workspace1[6];
501 workspace2[6] = workspace1[5] - workspace1[7];
502 workspace2[7] = workspace1[5] + workspace1[7];
503
504 /* stage 3 */
505 out[0] = workspace2[0] + workspace2[4];
506 out[1] = workspace2[0] - workspace2[4];
507 out[2] = workspace2[1] - workspace2[5];
508 out[3] = workspace2[1] + workspace2[5];
509 out[4] = workspace2[2] + workspace2[6];
510 out[5] = workspace2[2] - workspace2[6];
511 out[6] = workspace2[3] - workspace2[7];
512 out[7] = workspace2[3] + workspace2[7];
513 }
514
515 out = output_block;
516
517 for (i = 0; i < 8; i++, out++) {
518 /* stage 1 */
519 workspace1[0] = out[0] + out[1 * 8];
520 workspace1[1] = out[0] - out[1 * 8];
521
522 workspace1[2] = out[2 * 8] + out[3 * 8];
523 workspace1[3] = out[2 * 8] - out[3 * 8];
524
525 workspace1[4] = out[4 * 8] + out[5 * 8];
526 workspace1[5] = out[4 * 8] - out[5 * 8];
527
528 workspace1[6] = out[6 * 8] + out[7 * 8];
529 workspace1[7] = out[6 * 8] - out[7 * 8];
530
531 /* stage 2 */
532 workspace2[0] = workspace1[0] + workspace1[2];
533 workspace2[1] = workspace1[0] - workspace1[2];
534 workspace2[2] = workspace1[1] - workspace1[3];
535 workspace2[3] = workspace1[1] + workspace1[3];
536
537 workspace2[4] = workspace1[4] + workspace1[6];
538 workspace2[5] = workspace1[4] - workspace1[6];
539 workspace2[6] = workspace1[5] - workspace1[7];
540 workspace2[7] = workspace1[5] + workspace1[7];
541
542 /* stage 3 */
543 if (inter) {
544 int d;
545
546 out[0 * 8] = workspace2[0] + workspace2[4];
547 out[1 * 8] = workspace2[0] - workspace2[4];
548 out[2 * 8] = workspace2[1] - workspace2[5];
549 out[3 * 8] = workspace2[1] + workspace2[5];
550 out[4 * 8] = workspace2[2] + workspace2[6];
551 out[5 * 8] = workspace2[2] - workspace2[6];
552 out[6 * 8] = workspace2[3] - workspace2[7];
553 out[7 * 8] = workspace2[3] + workspace2[7];
554
555 for (d = 0; d < 8; d++)
556 out[8 * d] >>= 6;
557 } else {
558 int d;
559
560 out[0 * 8] = workspace2[0] + workspace2[4];
561 out[1 * 8] = workspace2[0] - workspace2[4];
562 out[2 * 8] = workspace2[1] - workspace2[5];
563 out[3 * 8] = workspace2[1] + workspace2[5];
564 out[4 * 8] = workspace2[2] + workspace2[6];
565 out[5 * 8] = workspace2[2] - workspace2[6];
566 out[6 * 8] = workspace2[3] - workspace2[7];
567 out[7 * 8] = workspace2[3] + workspace2[7];
568
569 for (d = 0; d < 8; d++) {
570 out[8 * d] >>= 6;
571 out[8 * d] += 128;
572 }
573 }
574 }
575 }
576
fill_encoder_block(const u8 * input,s16 * dst,unsigned int stride,unsigned int input_step)577 static void fill_encoder_block(const u8 *input, s16 *dst,
578 unsigned int stride, unsigned int input_step)
579 {
580 int i, j;
581
582 for (i = 0; i < 8; i++) {
583 for (j = 0; j < 8; j++, input += input_step)
584 *dst++ = *input;
585 input += stride - 8 * input_step;
586 }
587 }
588
var_intra(const s16 * input)589 static int var_intra(const s16 *input)
590 {
591 int32_t mean = 0;
592 int32_t ret = 0;
593 const s16 *tmp = input;
594 int i;
595
596 for (i = 0; i < 8 * 8; i++, tmp++)
597 mean += *tmp;
598 mean /= 64;
599 tmp = input;
600 for (i = 0; i < 8 * 8; i++, tmp++)
601 ret += (*tmp - mean) < 0 ? -(*tmp - mean) : (*tmp - mean);
602 return ret;
603 }
604
var_inter(const s16 * old,const s16 * new)605 static int var_inter(const s16 *old, const s16 *new)
606 {
607 int32_t ret = 0;
608 int i;
609
610 for (i = 0; i < 8 * 8; i++, old++, new++)
611 ret += (*old - *new) < 0 ? -(*old - *new) : (*old - *new);
612 return ret;
613 }
614
615 static noinline_for_stack int
decide_blocktype(const u8 * cur,const u8 * reference,s16 * deltablock,unsigned int stride,unsigned int input_step)616 decide_blocktype(const u8 *cur, const u8 *reference, s16 *deltablock,
617 unsigned int stride, unsigned int input_step)
618 {
619 s16 tmp[64];
620 s16 old[64];
621 s16 *work = tmp;
622 unsigned int k, l;
623 int vari;
624 int vard;
625
626 fill_encoder_block(cur, tmp, stride, input_step);
627 fill_encoder_block(reference, old, 8, 1);
628 vari = var_intra(tmp);
629
630 for (k = 0; k < 8; k++) {
631 for (l = 0; l < 8; l++) {
632 *deltablock = *work - *reference;
633 deltablock++;
634 work++;
635 reference++;
636 }
637 }
638 deltablock -= 64;
639 vard = var_inter(old, tmp);
640 return vari <= vard ? IBLOCK : PBLOCK;
641 }
642
fill_decoder_block(u8 * dst,const s16 * input,int stride,unsigned int dst_step)643 static void fill_decoder_block(u8 *dst, const s16 *input, int stride,
644 unsigned int dst_step)
645 {
646 int i, j;
647
648 for (i = 0; i < 8; i++) {
649 for (j = 0; j < 8; j++, input++, dst += dst_step) {
650 if (*input < 0)
651 *dst = 0;
652 else if (*input > 255)
653 *dst = 255;
654 else
655 *dst = *input;
656 }
657 dst += stride - (8 * dst_step);
658 }
659 }
660
add_deltas(s16 * deltas,const u8 * ref,int stride,unsigned int ref_step)661 static void add_deltas(s16 *deltas, const u8 *ref, int stride,
662 unsigned int ref_step)
663 {
664 int k, l;
665
666 for (k = 0; k < 8; k++) {
667 for (l = 0; l < 8; l++) {
668 *deltas += *ref;
669 ref += ref_step;
670 /*
671 * Due to quantizing, it might possible that the
672 * decoded coefficients are slightly out of range
673 */
674 if (*deltas < 0)
675 *deltas = 0;
676 else if (*deltas > 255)
677 *deltas = 255;
678 deltas++;
679 }
680 ref += stride - (8 * ref_step);
681 }
682 }
683
encode_plane(u8 * input,u8 * refp,__be16 ** rlco,__be16 * rlco_max,struct fwht_cframe * cf,u32 height,u32 width,u32 stride,unsigned int input_step,bool is_intra,bool next_is_intra)684 static u32 encode_plane(u8 *input, u8 *refp, __be16 **rlco, __be16 *rlco_max,
685 struct fwht_cframe *cf, u32 height, u32 width,
686 u32 stride, unsigned int input_step,
687 bool is_intra, bool next_is_intra)
688 {
689 u8 *input_start = input;
690 __be16 *rlco_start = *rlco;
691 s16 deltablock[64];
692 __be16 pframe_bit = htons(PFRAME_BIT);
693 u32 encoding = 0;
694 unsigned int last_size = 0;
695 unsigned int i, j;
696
697 width = round_up(width, 8);
698 height = round_up(height, 8);
699
700 for (j = 0; j < height / 8; j++) {
701 input = input_start + j * 8 * stride;
702 for (i = 0; i < width / 8; i++) {
703 /* intra code, first frame is always intra coded. */
704 int blocktype = IBLOCK;
705 unsigned int size;
706
707 if (!is_intra)
708 blocktype = decide_blocktype(input, refp,
709 deltablock, stride, input_step);
710 if (blocktype == IBLOCK) {
711 fwht(input, cf->coeffs, stride, input_step, 1);
712 quantize_intra(cf->coeffs, cf->de_coeffs,
713 cf->i_frame_qp);
714 } else {
715 /* inter code */
716 encoding |= FWHT_FRAME_PCODED;
717 fwht16(deltablock, cf->coeffs, 8, 0);
718 quantize_inter(cf->coeffs, cf->de_coeffs,
719 cf->p_frame_qp);
720 }
721 if (!next_is_intra) {
722 ifwht(cf->de_coeffs, cf->de_fwht, blocktype);
723
724 if (blocktype == PBLOCK)
725 add_deltas(cf->de_fwht, refp, 8, 1);
726 fill_decoder_block(refp, cf->de_fwht, 8, 1);
727 }
728
729 input += 8 * input_step;
730 refp += 8 * 8;
731
732 size = rlc(cf->coeffs, *rlco, blocktype);
733 if (last_size == size &&
734 !memcmp(*rlco + 1, *rlco - size + 1, 2 * size - 2)) {
735 __be16 *last_rlco = *rlco - size;
736 s16 hdr = ntohs(*last_rlco);
737
738 if (!((*last_rlco ^ **rlco) & pframe_bit) &&
739 (hdr & DUPS_MASK) < DUPS_MASK)
740 *last_rlco = htons(hdr + 2);
741 else
742 *rlco += size;
743 } else {
744 *rlco += size;
745 }
746 if (*rlco >= rlco_max) {
747 encoding |= FWHT_FRAME_UNENCODED;
748 goto exit_loop;
749 }
750 last_size = size;
751 }
752 }
753
754 exit_loop:
755 if (encoding & FWHT_FRAME_UNENCODED) {
756 u8 *out = (u8 *)rlco_start;
757 u8 *p;
758
759 input = input_start;
760 /*
761 * The compressed stream should never contain the magic
762 * header, so when we copy the YUV data we replace 0xff
763 * by 0xfe. Since YUV is limited range such values
764 * shouldn't appear anyway.
765 */
766 for (j = 0; j < height; j++) {
767 for (i = 0, p = input; i < width; i++, p += input_step)
768 *out++ = (*p == 0xff) ? 0xfe : *p;
769 input += stride;
770 }
771 *rlco = (__be16 *)out;
772 encoding &= ~FWHT_FRAME_PCODED;
773 }
774 return encoding;
775 }
776
fwht_encode_frame(struct fwht_raw_frame * frm,struct fwht_raw_frame * ref_frm,struct fwht_cframe * cf,bool is_intra,bool next_is_intra,unsigned int width,unsigned int height,unsigned int stride,unsigned int chroma_stride)777 u32 fwht_encode_frame(struct fwht_raw_frame *frm,
778 struct fwht_raw_frame *ref_frm,
779 struct fwht_cframe *cf,
780 bool is_intra, bool next_is_intra,
781 unsigned int width, unsigned int height,
782 unsigned int stride, unsigned int chroma_stride)
783 {
784 unsigned int size = height * width;
785 __be16 *rlco = cf->rlc_data;
786 __be16 *rlco_max;
787 u32 encoding;
788
789 rlco_max = rlco + size / 2 - 256;
790 encoding = encode_plane(frm->luma, ref_frm->luma, &rlco, rlco_max, cf,
791 height, width, stride,
792 frm->luma_alpha_step, is_intra, next_is_intra);
793 if (encoding & FWHT_FRAME_UNENCODED)
794 encoding |= FWHT_LUMA_UNENCODED;
795 encoding &= ~FWHT_FRAME_UNENCODED;
796
797 if (frm->components_num >= 3) {
798 u32 chroma_h = height / frm->height_div;
799 u32 chroma_w = width / frm->width_div;
800 unsigned int chroma_size = chroma_h * chroma_w;
801
802 rlco_max = rlco + chroma_size / 2 - 256;
803 encoding |= encode_plane(frm->cb, ref_frm->cb, &rlco, rlco_max,
804 cf, chroma_h, chroma_w,
805 chroma_stride, frm->chroma_step,
806 is_intra, next_is_intra);
807 if (encoding & FWHT_FRAME_UNENCODED)
808 encoding |= FWHT_CB_UNENCODED;
809 encoding &= ~FWHT_FRAME_UNENCODED;
810 rlco_max = rlco + chroma_size / 2 - 256;
811 encoding |= encode_plane(frm->cr, ref_frm->cr, &rlco, rlco_max,
812 cf, chroma_h, chroma_w,
813 chroma_stride, frm->chroma_step,
814 is_intra, next_is_intra);
815 if (encoding & FWHT_FRAME_UNENCODED)
816 encoding |= FWHT_CR_UNENCODED;
817 encoding &= ~FWHT_FRAME_UNENCODED;
818 }
819
820 if (frm->components_num == 4) {
821 rlco_max = rlco + size / 2 - 256;
822 encoding |= encode_plane(frm->alpha, ref_frm->alpha, &rlco,
823 rlco_max, cf, height, width,
824 stride, frm->luma_alpha_step,
825 is_intra, next_is_intra);
826 if (encoding & FWHT_FRAME_UNENCODED)
827 encoding |= FWHT_ALPHA_UNENCODED;
828 encoding &= ~FWHT_FRAME_UNENCODED;
829 }
830
831 cf->size = (rlco - cf->rlc_data) * sizeof(*rlco);
832 return encoding;
833 }
834
decode_plane(struct fwht_cframe * cf,const __be16 ** rlco,u32 height,u32 width,const u8 * ref,u32 ref_stride,unsigned int ref_step,u8 * dst,unsigned int dst_stride,unsigned int dst_step,bool uncompressed,const __be16 * end_of_rlco_buf)835 static bool decode_plane(struct fwht_cframe *cf, const __be16 **rlco,
836 u32 height, u32 width, const u8 *ref, u32 ref_stride,
837 unsigned int ref_step, u8 *dst,
838 unsigned int dst_stride, unsigned int dst_step,
839 bool uncompressed, const __be16 *end_of_rlco_buf)
840 {
841 unsigned int copies = 0;
842 s16 copy[8 * 8];
843 u16 stat;
844 unsigned int i, j;
845 bool is_intra = !ref;
846
847 width = round_up(width, 8);
848 height = round_up(height, 8);
849
850 if (uncompressed) {
851 int i;
852
853 if (end_of_rlco_buf + 1 < *rlco + width * height / 2)
854 return false;
855 for (i = 0; i < height; i++) {
856 memcpy(dst, *rlco, width);
857 dst += dst_stride;
858 *rlco += width / 2;
859 }
860 return true;
861 }
862
863 /*
864 * When decoding each macroblock the rlco pointer will be increased
865 * by 65 * 2 bytes worst-case.
866 * To avoid overflow the buffer has to be 65/64th of the actual raw
867 * image size, just in case someone feeds it malicious data.
868 */
869 for (j = 0; j < height / 8; j++) {
870 for (i = 0; i < width / 8; i++) {
871 const u8 *refp = ref + j * 8 * ref_stride +
872 i * 8 * ref_step;
873 u8 *dstp = dst + j * 8 * dst_stride + i * 8 * dst_step;
874
875 if (copies) {
876 memcpy(cf->de_fwht, copy, sizeof(copy));
877 if ((stat & PFRAME_BIT) && !is_intra)
878 add_deltas(cf->de_fwht, refp,
879 ref_stride, ref_step);
880 fill_decoder_block(dstp, cf->de_fwht,
881 dst_stride, dst_step);
882 copies--;
883 continue;
884 }
885
886 stat = derlc(rlco, cf->coeffs, end_of_rlco_buf);
887 if (stat & OVERFLOW_BIT)
888 return false;
889 if ((stat & PFRAME_BIT) && !is_intra)
890 dequantize_inter(cf->coeffs);
891 else
892 dequantize_intra(cf->coeffs);
893
894 ifwht(cf->coeffs, cf->de_fwht,
895 ((stat & PFRAME_BIT) && !is_intra) ? 0 : 1);
896
897 copies = (stat & DUPS_MASK) >> 1;
898 if (copies)
899 memcpy(copy, cf->de_fwht, sizeof(copy));
900 if ((stat & PFRAME_BIT) && !is_intra)
901 add_deltas(cf->de_fwht, refp,
902 ref_stride, ref_step);
903 fill_decoder_block(dstp, cf->de_fwht, dst_stride,
904 dst_step);
905 }
906 }
907 return true;
908 }
909
fwht_decode_frame(struct fwht_cframe * cf,u32 hdr_flags,unsigned int components_num,unsigned int width,unsigned int height,const struct fwht_raw_frame * ref,unsigned int ref_stride,unsigned int ref_chroma_stride,struct fwht_raw_frame * dst,unsigned int dst_stride,unsigned int dst_chroma_stride)910 bool fwht_decode_frame(struct fwht_cframe *cf, u32 hdr_flags,
911 unsigned int components_num, unsigned int width,
912 unsigned int height, const struct fwht_raw_frame *ref,
913 unsigned int ref_stride, unsigned int ref_chroma_stride,
914 struct fwht_raw_frame *dst, unsigned int dst_stride,
915 unsigned int dst_chroma_stride)
916 {
917 const __be16 *rlco = cf->rlc_data;
918 const __be16 *end_of_rlco_buf = cf->rlc_data +
919 (cf->size / sizeof(*rlco)) - 1;
920
921 if (!decode_plane(cf, &rlco, height, width, ref->luma, ref_stride,
922 ref->luma_alpha_step, dst->luma, dst_stride,
923 dst->luma_alpha_step,
924 hdr_flags & V4L2_FWHT_FL_LUMA_IS_UNCOMPRESSED,
925 end_of_rlco_buf))
926 return false;
927
928 if (components_num >= 3) {
929 u32 h = height;
930 u32 w = width;
931
932 if (!(hdr_flags & V4L2_FWHT_FL_CHROMA_FULL_HEIGHT))
933 h /= 2;
934 if (!(hdr_flags & V4L2_FWHT_FL_CHROMA_FULL_WIDTH))
935 w /= 2;
936
937 if (!decode_plane(cf, &rlco, h, w, ref->cb, ref_chroma_stride,
938 ref->chroma_step, dst->cb, dst_chroma_stride,
939 dst->chroma_step,
940 hdr_flags & V4L2_FWHT_FL_CB_IS_UNCOMPRESSED,
941 end_of_rlco_buf))
942 return false;
943 if (!decode_plane(cf, &rlco, h, w, ref->cr, ref_chroma_stride,
944 ref->chroma_step, dst->cr, dst_chroma_stride,
945 dst->chroma_step,
946 hdr_flags & V4L2_FWHT_FL_CR_IS_UNCOMPRESSED,
947 end_of_rlco_buf))
948 return false;
949 }
950
951 if (components_num == 4)
952 if (!decode_plane(cf, &rlco, height, width, ref->alpha, ref_stride,
953 ref->luma_alpha_step, dst->alpha, dst_stride,
954 dst->luma_alpha_step,
955 hdr_flags & V4L2_FWHT_FL_ALPHA_IS_UNCOMPRESSED,
956 end_of_rlco_buf))
957 return false;
958 return true;
959 }
960