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linux/drivers/media/test-drivers/vicodec/codec-fwht.c
Nathan Chancellor 2947a4567f treewide: update LLVM Bugzilla links
LLVM moved their issue tracker from their own Bugzilla instance to GitHub
issues.  While all of the links are still valid, they may not necessarily
show the most up to date information around the issues, as all updates
will occur on GitHub, not Bugzilla.

Another complication is that the Bugzilla issue number is not always the
same as the GitHub issue number.  Thankfully, LLVM maintains this mapping
through two shortlinks:

  https://llvm.org/bz<num> -> https://bugs.llvm.org/show_bug.cgi?id=<num>
  https://llvm.org/pr<num> -> https://github.com/llvm/llvm-project/issues/<mapped_num>

Switch all "https://bugs.llvm.org/show_bug.cgi?id=<num>" links to the
"https://llvm.org/pr<num>" shortlink so that the links show the most up to
date information.  Each migrated issue links back to the Bugzilla entry,
so there should be no loss of fidelity of information here.

Link: https://lkml.kernel.org/r/20240109-update-llvm-links-v1-3-eb09b59db071@kernel.org
Signed-off-by: Nathan Chancellor <nathan@kernel.org>
Reviewed-by: Kees Cook <keescook@chromium.org>
Acked-by: Fangrui Song <maskray@google.com>
Cc: Alexei Starovoitov <ast@kernel.org>
Cc: Andrii Nakryiko <andrii@kernel.org>
Cc: Daniel Borkmann <daniel@iogearbox.net>
Cc: Mykola Lysenko <mykolal@fb.com>
Signed-off-by: Andrew Morton <akpm@linux-foundation.org>
2024-02-22 15:38:51 -08:00

960 lines
24 KiB
C

// SPDX-License-Identifier: LGPL-2.1+
/*
* Copyright 2016 Tom aan de Wiel
* Copyright 2018 Cisco Systems, Inc. and/or its affiliates. All rights reserved.
*
* 8x8 Fast Walsh Hadamard Transform in sequency order based on the paper:
*
* A Recursive Algorithm for Sequency-Ordered Fast Walsh Transforms,
* R.D. Brown, 1977
*/
#include <linux/string.h>
#include <linux/kernel.h>
#include <linux/videodev2.h>
#include "codec-fwht.h"
#define OVERFLOW_BIT BIT(14)
/*
* Note: bit 0 of the header must always be 0. Otherwise it cannot
* be guaranteed that the magic 8 byte sequence (see below) can
* never occur in the rlc output.
*/
#define PFRAME_BIT BIT(15)
#define DUPS_MASK 0x1ffe
#define PBLOCK 0
#define IBLOCK 1
#define ALL_ZEROS 15
static const uint8_t zigzag[64] = {
0,
1, 8,
2, 9, 16,
3, 10, 17, 24,
4, 11, 18, 25, 32,
5, 12, 19, 26, 33, 40,
6, 13, 20, 27, 34, 41, 48,
7, 14, 21, 28, 35, 42, 49, 56,
15, 22, 29, 36, 43, 50, 57,
23, 30, 37, 44, 51, 58,
31, 38, 45, 52, 59,
39, 46, 53, 60,
47, 54, 61,
55, 62,
63,
};
/*
* noinline_for_stack to work around
* https://llvm.org/pr38809
*/
static int noinline_for_stack
rlc(const s16 *in, __be16 *output, int blocktype)
{
s16 block[8 * 8];
s16 *wp = block;
int i = 0;
int x, y;
int ret = 0;
/* read in block from framebuffer */
int lastzero_run = 0;
int to_encode;
for (y = 0; y < 8; y++) {
for (x = 0; x < 8; x++) {
*wp = in[x + y * 8];
wp++;
}
}
/* keep track of amount of trailing zeros */
for (i = 63; i >= 0 && !block[zigzag[i]]; i--)
lastzero_run++;
*output++ = (blocktype == PBLOCK ? htons(PFRAME_BIT) : 0);
ret++;
to_encode = 8 * 8 - (lastzero_run > 14 ? lastzero_run : 0);
i = 0;
while (i < to_encode) {
int cnt = 0;
int tmp;
/* count leading zeros */
while ((tmp = block[zigzag[i]]) == 0 && cnt < 14) {
cnt++;
i++;
if (i == to_encode) {
cnt--;
break;
}
}
/* 4 bits for run, 12 for coefficient (quantization by 4) */
*output++ = htons((cnt | tmp << 4));
i++;
ret++;
}
if (lastzero_run > 14) {
*output = htons(ALL_ZEROS | 0);
ret++;
}
return ret;
}
/*
* This function will worst-case increase rlc_in by 65*2 bytes:
* one s16 value for the header and 8 * 8 coefficients of type s16.
*/
static noinline_for_stack u16
derlc(const __be16 **rlc_in, s16 *dwht_out, const __be16 *end_of_input)
{
/* header */
const __be16 *input = *rlc_in;
u16 stat;
int dec_count = 0;
s16 block[8 * 8 + 16];
s16 *wp = block;
int i;
if (input > end_of_input)
return OVERFLOW_BIT;
stat = ntohs(*input++);
/*
* Now de-compress, it expands one byte to up to 15 bytes
* (or fills the remainder of the 64 bytes with zeroes if it
* is the last byte to expand).
*
* So block has to be 8 * 8 + 16 bytes, the '+ 16' is to
* allow for overflow if the incoming data was malformed.
*/
while (dec_count < 8 * 8) {
s16 in;
int length;
int coeff;
if (input > end_of_input)
return OVERFLOW_BIT;
in = ntohs(*input++);
length = in & 0xf;
coeff = in >> 4;
/* fill remainder with zeros */
if (length == 15) {
for (i = 0; i < 64 - dec_count; i++)
*wp++ = 0;
break;
}
for (i = 0; i < length; i++)
*wp++ = 0;
*wp++ = coeff;
dec_count += length + 1;
}
wp = block;
for (i = 0; i < 64; i++) {
int pos = zigzag[i];
int y = pos / 8;
int x = pos % 8;
dwht_out[x + y * 8] = *wp++;
}
*rlc_in = input;
return stat;
}
static const int quant_table[] = {
2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2, 2, 2,
2, 2, 2, 2, 2, 2, 2, 3,
2, 2, 2, 2, 2, 2, 3, 6,
2, 2, 2, 2, 2, 3, 6, 6,
2, 2, 2, 2, 3, 6, 6, 6,
2, 2, 2, 3, 6, 6, 6, 6,
2, 2, 3, 6, 6, 6, 6, 8,
};
static const int quant_table_p[] = {
3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 3,
3, 3, 3, 3, 3, 3, 3, 6,
3, 3, 3, 3, 3, 3, 6, 6,
3, 3, 3, 3, 3, 6, 6, 9,
3, 3, 3, 3, 6, 6, 9, 9,
3, 3, 3, 6, 6, 9, 9, 10,
};
static void quantize_intra(s16 *coeff, s16 *de_coeff, u16 qp)
{
const int *quant = quant_table;
int i, j;
for (j = 0; j < 8; j++) {
for (i = 0; i < 8; i++, quant++, coeff++, de_coeff++) {
*coeff >>= *quant;
if (*coeff >= -qp && *coeff <= qp)
*coeff = *de_coeff = 0;
else
*de_coeff = *coeff << *quant;
}
}
}
static void dequantize_intra(s16 *coeff)
{
const int *quant = quant_table;
int i, j;
for (j = 0; j < 8; j++)
for (i = 0; i < 8; i++, quant++, coeff++)
*coeff <<= *quant;
}
static void quantize_inter(s16 *coeff, s16 *de_coeff, u16 qp)
{
const int *quant = quant_table_p;
int i, j;
for (j = 0; j < 8; j++) {
for (i = 0; i < 8; i++, quant++, coeff++, de_coeff++) {
*coeff >>= *quant;
if (*coeff >= -qp && *coeff <= qp)
*coeff = *de_coeff = 0;
else
*de_coeff = *coeff << *quant;
}
}
}
static void dequantize_inter(s16 *coeff)
{
const int *quant = quant_table_p;
int i, j;
for (j = 0; j < 8; j++)
for (i = 0; i < 8; i++, quant++, coeff++)
*coeff <<= *quant;
}
static void noinline_for_stack fwht(const u8 *block, s16 *output_block,
unsigned int stride,
unsigned int input_step, bool intra)
{
/* we'll need more than 8 bits for the transformed coefficients */
s32 workspace1[8], workspace2[8];
const u8 *tmp = block;
s16 *out = output_block;
int add = intra ? 256 : 0;
unsigned int i;
/* stage 1 */
for (i = 0; i < 8; i++, tmp += stride, out += 8) {
switch (input_step) {
case 1:
workspace1[0] = tmp[0] + tmp[1] - add;
workspace1[1] = tmp[0] - tmp[1];
workspace1[2] = tmp[2] + tmp[3] - add;
workspace1[3] = tmp[2] - tmp[3];
workspace1[4] = tmp[4] + tmp[5] - add;
workspace1[5] = tmp[4] - tmp[5];
workspace1[6] = tmp[6] + tmp[7] - add;
workspace1[7] = tmp[6] - tmp[7];
break;
case 2:
workspace1[0] = tmp[0] + tmp[2] - add;
workspace1[1] = tmp[0] - tmp[2];
workspace1[2] = tmp[4] + tmp[6] - add;
workspace1[3] = tmp[4] - tmp[6];
workspace1[4] = tmp[8] + tmp[10] - add;
workspace1[5] = tmp[8] - tmp[10];
workspace1[6] = tmp[12] + tmp[14] - add;
workspace1[7] = tmp[12] - tmp[14];
break;
case 3:
workspace1[0] = tmp[0] + tmp[3] - add;
workspace1[1] = tmp[0] - tmp[3];
workspace1[2] = tmp[6] + tmp[9] - add;
workspace1[3] = tmp[6] - tmp[9];
workspace1[4] = tmp[12] + tmp[15] - add;
workspace1[5] = tmp[12] - tmp[15];
workspace1[6] = tmp[18] + tmp[21] - add;
workspace1[7] = tmp[18] - tmp[21];
break;
default:
workspace1[0] = tmp[0] + tmp[4] - add;
workspace1[1] = tmp[0] - tmp[4];
workspace1[2] = tmp[8] + tmp[12] - add;
workspace1[3] = tmp[8] - tmp[12];
workspace1[4] = tmp[16] + tmp[20] - add;
workspace1[5] = tmp[16] - tmp[20];
workspace1[6] = tmp[24] + tmp[28] - add;
workspace1[7] = tmp[24] - tmp[28];
break;
}
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
out[0] = workspace2[0] + workspace2[4];
out[1] = workspace2[0] - workspace2[4];
out[2] = workspace2[1] - workspace2[5];
out[3] = workspace2[1] + workspace2[5];
out[4] = workspace2[2] + workspace2[6];
out[5] = workspace2[2] - workspace2[6];
out[6] = workspace2[3] - workspace2[7];
out[7] = workspace2[3] + workspace2[7];
}
out = output_block;
for (i = 0; i < 8; i++, out++) {
/* stage 1 */
workspace1[0] = out[0] + out[1 * 8];
workspace1[1] = out[0] - out[1 * 8];
workspace1[2] = out[2 * 8] + out[3 * 8];
workspace1[3] = out[2 * 8] - out[3 * 8];
workspace1[4] = out[4 * 8] + out[5 * 8];
workspace1[5] = out[4 * 8] - out[5 * 8];
workspace1[6] = out[6 * 8] + out[7 * 8];
workspace1[7] = out[6 * 8] - out[7 * 8];
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
out[0 * 8] = workspace2[0] + workspace2[4];
out[1 * 8] = workspace2[0] - workspace2[4];
out[2 * 8] = workspace2[1] - workspace2[5];
out[3 * 8] = workspace2[1] + workspace2[5];
out[4 * 8] = workspace2[2] + workspace2[6];
out[5 * 8] = workspace2[2] - workspace2[6];
out[6 * 8] = workspace2[3] - workspace2[7];
out[7 * 8] = workspace2[3] + workspace2[7];
}
}
/*
* Not the nicest way of doing it, but P-blocks get twice the range of
* that of the I-blocks. Therefore we need a type bigger than 8 bits.
* Furthermore values can be negative... This is just a version that
* works with 16 signed data
*/
static void noinline_for_stack
fwht16(const s16 *block, s16 *output_block, int stride, int intra)
{
/* we'll need more than 8 bits for the transformed coefficients */
s32 workspace1[8], workspace2[8];
const s16 *tmp = block;
s16 *out = output_block;
int i;
for (i = 0; i < 8; i++, tmp += stride, out += 8) {
/* stage 1 */
workspace1[0] = tmp[0] + tmp[1];
workspace1[1] = tmp[0] - tmp[1];
workspace1[2] = tmp[2] + tmp[3];
workspace1[3] = tmp[2] - tmp[3];
workspace1[4] = tmp[4] + tmp[5];
workspace1[5] = tmp[4] - tmp[5];
workspace1[6] = tmp[6] + tmp[7];
workspace1[7] = tmp[6] - tmp[7];
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
out[0] = workspace2[0] + workspace2[4];
out[1] = workspace2[0] - workspace2[4];
out[2] = workspace2[1] - workspace2[5];
out[3] = workspace2[1] + workspace2[5];
out[4] = workspace2[2] + workspace2[6];
out[5] = workspace2[2] - workspace2[6];
out[6] = workspace2[3] - workspace2[7];
out[7] = workspace2[3] + workspace2[7];
}
out = output_block;
for (i = 0; i < 8; i++, out++) {
/* stage 1 */
workspace1[0] = out[0] + out[1*8];
workspace1[1] = out[0] - out[1*8];
workspace1[2] = out[2*8] + out[3*8];
workspace1[3] = out[2*8] - out[3*8];
workspace1[4] = out[4*8] + out[5*8];
workspace1[5] = out[4*8] - out[5*8];
workspace1[6] = out[6*8] + out[7*8];
workspace1[7] = out[6*8] - out[7*8];
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
out[0*8] = workspace2[0] + workspace2[4];
out[1*8] = workspace2[0] - workspace2[4];
out[2*8] = workspace2[1] - workspace2[5];
out[3*8] = workspace2[1] + workspace2[5];
out[4*8] = workspace2[2] + workspace2[6];
out[5*8] = workspace2[2] - workspace2[6];
out[6*8] = workspace2[3] - workspace2[7];
out[7*8] = workspace2[3] + workspace2[7];
}
}
static noinline_for_stack void
ifwht(const s16 *block, s16 *output_block, int intra)
{
/*
* we'll need more than 8 bits for the transformed coefficients
* use native unit of cpu
*/
int workspace1[8], workspace2[8];
int inter = intra ? 0 : 1;
const s16 *tmp = block;
s16 *out = output_block;
int i;
for (i = 0; i < 8; i++, tmp += 8, out += 8) {
/* stage 1 */
workspace1[0] = tmp[0] + tmp[1];
workspace1[1] = tmp[0] - tmp[1];
workspace1[2] = tmp[2] + tmp[3];
workspace1[3] = tmp[2] - tmp[3];
workspace1[4] = tmp[4] + tmp[5];
workspace1[5] = tmp[4] - tmp[5];
workspace1[6] = tmp[6] + tmp[7];
workspace1[7] = tmp[6] - tmp[7];
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
out[0] = workspace2[0] + workspace2[4];
out[1] = workspace2[0] - workspace2[4];
out[2] = workspace2[1] - workspace2[5];
out[3] = workspace2[1] + workspace2[5];
out[4] = workspace2[2] + workspace2[6];
out[5] = workspace2[2] - workspace2[6];
out[6] = workspace2[3] - workspace2[7];
out[7] = workspace2[3] + workspace2[7];
}
out = output_block;
for (i = 0; i < 8; i++, out++) {
/* stage 1 */
workspace1[0] = out[0] + out[1 * 8];
workspace1[1] = out[0] - out[1 * 8];
workspace1[2] = out[2 * 8] + out[3 * 8];
workspace1[3] = out[2 * 8] - out[3 * 8];
workspace1[4] = out[4 * 8] + out[5 * 8];
workspace1[5] = out[4 * 8] - out[5 * 8];
workspace1[6] = out[6 * 8] + out[7 * 8];
workspace1[7] = out[6 * 8] - out[7 * 8];
/* stage 2 */
workspace2[0] = workspace1[0] + workspace1[2];
workspace2[1] = workspace1[0] - workspace1[2];
workspace2[2] = workspace1[1] - workspace1[3];
workspace2[3] = workspace1[1] + workspace1[3];
workspace2[4] = workspace1[4] + workspace1[6];
workspace2[5] = workspace1[4] - workspace1[6];
workspace2[6] = workspace1[5] - workspace1[7];
workspace2[7] = workspace1[5] + workspace1[7];
/* stage 3 */
if (inter) {
int d;
out[0 * 8] = workspace2[0] + workspace2[4];
out[1 * 8] = workspace2[0] - workspace2[4];
out[2 * 8] = workspace2[1] - workspace2[5];
out[3 * 8] = workspace2[1] + workspace2[5];
out[4 * 8] = workspace2[2] + workspace2[6];
out[5 * 8] = workspace2[2] - workspace2[6];
out[6 * 8] = workspace2[3] - workspace2[7];
out[7 * 8] = workspace2[3] + workspace2[7];
for (d = 0; d < 8; d++)
out[8 * d] >>= 6;
} else {
int d;
out[0 * 8] = workspace2[0] + workspace2[4];
out[1 * 8] = workspace2[0] - workspace2[4];
out[2 * 8] = workspace2[1] - workspace2[5];
out[3 * 8] = workspace2[1] + workspace2[5];
out[4 * 8] = workspace2[2] + workspace2[6];
out[5 * 8] = workspace2[2] - workspace2[6];
out[6 * 8] = workspace2[3] - workspace2[7];
out[7 * 8] = workspace2[3] + workspace2[7];
for (d = 0; d < 8; d++) {
out[8 * d] >>= 6;
out[8 * d] += 128;
}
}
}
}
static void fill_encoder_block(const u8 *input, s16 *dst,
unsigned int stride, unsigned int input_step)
{
int i, j;
for (i = 0; i < 8; i++) {
for (j = 0; j < 8; j++, input += input_step)
*dst++ = *input;
input += stride - 8 * input_step;
}
}
static int var_intra(const s16 *input)
{
int32_t mean = 0;
int32_t ret = 0;
const s16 *tmp = input;
int i;
for (i = 0; i < 8 * 8; i++, tmp++)
mean += *tmp;
mean /= 64;
tmp = input;
for (i = 0; i < 8 * 8; i++, tmp++)
ret += (*tmp - mean) < 0 ? -(*tmp - mean) : (*tmp - mean);
return ret;
}
static int var_inter(const s16 *old, const s16 *new)
{
int32_t ret = 0;
int i;
for (i = 0; i < 8 * 8; i++, old++, new++)
ret += (*old - *new) < 0 ? -(*old - *new) : (*old - *new);
return ret;
}
static noinline_for_stack int
decide_blocktype(const u8 *cur, const u8 *reference, s16 *deltablock,
unsigned int stride, unsigned int input_step)
{
s16 tmp[64];
s16 old[64];
s16 *work = tmp;
unsigned int k, l;
int vari;
int vard;
fill_encoder_block(cur, tmp, stride, input_step);
fill_encoder_block(reference, old, 8, 1);
vari = var_intra(tmp);
for (k = 0; k < 8; k++) {
for (l = 0; l < 8; l++) {
*deltablock = *work - *reference;
deltablock++;
work++;
reference++;
}
}
deltablock -= 64;
vard = var_inter(old, tmp);
return vari <= vard ? IBLOCK : PBLOCK;
}
static void fill_decoder_block(u8 *dst, const s16 *input, int stride,
unsigned int dst_step)
{
int i, j;
for (i = 0; i < 8; i++) {
for (j = 0; j < 8; j++, input++, dst += dst_step) {
if (*input < 0)
*dst = 0;
else if (*input > 255)
*dst = 255;
else
*dst = *input;
}
dst += stride - (8 * dst_step);
}
}
static void add_deltas(s16 *deltas, const u8 *ref, int stride,
unsigned int ref_step)
{
int k, l;
for (k = 0; k < 8; k++) {
for (l = 0; l < 8; l++) {
*deltas += *ref;
ref += ref_step;
/*
* Due to quantizing, it might possible that the
* decoded coefficients are slightly out of range
*/
if (*deltas < 0)
*deltas = 0;
else if (*deltas > 255)
*deltas = 255;
deltas++;
}
ref += stride - (8 * ref_step);
}
}
static u32 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)
{
u8 *input_start = input;
__be16 *rlco_start = *rlco;
s16 deltablock[64];
__be16 pframe_bit = htons(PFRAME_BIT);
u32 encoding = 0;
unsigned int last_size = 0;
unsigned int i, j;
width = round_up(width, 8);
height = round_up(height, 8);
for (j = 0; j < height / 8; j++) {
input = input_start + j * 8 * stride;
for (i = 0; i < width / 8; i++) {
/* intra code, first frame is always intra coded. */
int blocktype = IBLOCK;
unsigned int size;
if (!is_intra)
blocktype = decide_blocktype(input, refp,
deltablock, stride, input_step);
if (blocktype == IBLOCK) {
fwht(input, cf->coeffs, stride, input_step, 1);
quantize_intra(cf->coeffs, cf->de_coeffs,
cf->i_frame_qp);
} else {
/* inter code */
encoding |= FWHT_FRAME_PCODED;
fwht16(deltablock, cf->coeffs, 8, 0);
quantize_inter(cf->coeffs, cf->de_coeffs,
cf->p_frame_qp);
}
if (!next_is_intra) {
ifwht(cf->de_coeffs, cf->de_fwht, blocktype);
if (blocktype == PBLOCK)
add_deltas(cf->de_fwht, refp, 8, 1);
fill_decoder_block(refp, cf->de_fwht, 8, 1);
}
input += 8 * input_step;
refp += 8 * 8;
size = rlc(cf->coeffs, *rlco, blocktype);
if (last_size == size &&
!memcmp(*rlco + 1, *rlco - size + 1, 2 * size - 2)) {
__be16 *last_rlco = *rlco - size;
s16 hdr = ntohs(*last_rlco);
if (!((*last_rlco ^ **rlco) & pframe_bit) &&
(hdr & DUPS_MASK) < DUPS_MASK)
*last_rlco = htons(hdr + 2);
else
*rlco += size;
} else {
*rlco += size;
}
if (*rlco >= rlco_max) {
encoding |= FWHT_FRAME_UNENCODED;
goto exit_loop;
}
last_size = size;
}
}
exit_loop:
if (encoding & FWHT_FRAME_UNENCODED) {
u8 *out = (u8 *)rlco_start;
u8 *p;
input = input_start;
/*
* The compressed stream should never contain the magic
* header, so when we copy the YUV data we replace 0xff
* by 0xfe. Since YUV is limited range such values
* shouldn't appear anyway.
*/
for (j = 0; j < height; j++) {
for (i = 0, p = input; i < width; i++, p += input_step)
*out++ = (*p == 0xff) ? 0xfe : *p;
input += stride;
}
*rlco = (__be16 *)out;
encoding &= ~FWHT_FRAME_PCODED;
}
return encoding;
}
u32 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)
{
unsigned int size = height * width;
__be16 *rlco = cf->rlc_data;
__be16 *rlco_max;
u32 encoding;
rlco_max = rlco + size / 2 - 256;
encoding = encode_plane(frm->luma, ref_frm->luma, &rlco, rlco_max, cf,
height, width, stride,
frm->luma_alpha_step, is_intra, next_is_intra);
if (encoding & FWHT_FRAME_UNENCODED)
encoding |= FWHT_LUMA_UNENCODED;
encoding &= ~FWHT_FRAME_UNENCODED;
if (frm->components_num >= 3) {
u32 chroma_h = height / frm->height_div;
u32 chroma_w = width / frm->width_div;
unsigned int chroma_size = chroma_h * chroma_w;
rlco_max = rlco + chroma_size / 2 - 256;
encoding |= encode_plane(frm->cb, ref_frm->cb, &rlco, rlco_max,
cf, chroma_h, chroma_w,
chroma_stride, frm->chroma_step,
is_intra, next_is_intra);
if (encoding & FWHT_FRAME_UNENCODED)
encoding |= FWHT_CB_UNENCODED;
encoding &= ~FWHT_FRAME_UNENCODED;
rlco_max = rlco + chroma_size / 2 - 256;
encoding |= encode_plane(frm->cr, ref_frm->cr, &rlco, rlco_max,
cf, chroma_h, chroma_w,
chroma_stride, frm->chroma_step,
is_intra, next_is_intra);
if (encoding & FWHT_FRAME_UNENCODED)
encoding |= FWHT_CR_UNENCODED;
encoding &= ~FWHT_FRAME_UNENCODED;
}
if (frm->components_num == 4) {
rlco_max = rlco + size / 2 - 256;
encoding |= encode_plane(frm->alpha, ref_frm->alpha, &rlco,
rlco_max, cf, height, width,
stride, frm->luma_alpha_step,
is_intra, next_is_intra);
if (encoding & FWHT_FRAME_UNENCODED)
encoding |= FWHT_ALPHA_UNENCODED;
encoding &= ~FWHT_FRAME_UNENCODED;
}
cf->size = (rlco - cf->rlc_data) * sizeof(*rlco);
return encoding;
}
static bool 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)
{
unsigned int copies = 0;
s16 copy[8 * 8];
u16 stat;
unsigned int i, j;
bool is_intra = !ref;
width = round_up(width, 8);
height = round_up(height, 8);
if (uncompressed) {
int i;
if (end_of_rlco_buf + 1 < *rlco + width * height / 2)
return false;
for (i = 0; i < height; i++) {
memcpy(dst, *rlco, width);
dst += dst_stride;
*rlco += width / 2;
}
return true;
}
/*
* When decoding each macroblock the rlco pointer will be increased
* by 65 * 2 bytes worst-case.
* To avoid overflow the buffer has to be 65/64th of the actual raw
* image size, just in case someone feeds it malicious data.
*/
for (j = 0; j < height / 8; j++) {
for (i = 0; i < width / 8; i++) {
const u8 *refp = ref + j * 8 * ref_stride +
i * 8 * ref_step;
u8 *dstp = dst + j * 8 * dst_stride + i * 8 * dst_step;
if (copies) {
memcpy(cf->de_fwht, copy, sizeof(copy));
if ((stat & PFRAME_BIT) && !is_intra)
add_deltas(cf->de_fwht, refp,
ref_stride, ref_step);
fill_decoder_block(dstp, cf->de_fwht,
dst_stride, dst_step);
copies--;
continue;
}
stat = derlc(rlco, cf->coeffs, end_of_rlco_buf);
if (stat & OVERFLOW_BIT)
return false;
if ((stat & PFRAME_BIT) && !is_intra)
dequantize_inter(cf->coeffs);
else
dequantize_intra(cf->coeffs);
ifwht(cf->coeffs, cf->de_fwht,
((stat & PFRAME_BIT) && !is_intra) ? 0 : 1);
copies = (stat & DUPS_MASK) >> 1;
if (copies)
memcpy(copy, cf->de_fwht, sizeof(copy));
if ((stat & PFRAME_BIT) && !is_intra)
add_deltas(cf->de_fwht, refp,
ref_stride, ref_step);
fill_decoder_block(dstp, cf->de_fwht, dst_stride,
dst_step);
}
}
return true;
}
bool 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)
{
const __be16 *rlco = cf->rlc_data;
const __be16 *end_of_rlco_buf = cf->rlc_data +
(cf->size / sizeof(*rlco)) - 1;
if (!decode_plane(cf, &rlco, height, width, ref->luma, ref_stride,
ref->luma_alpha_step, dst->luma, dst_stride,
dst->luma_alpha_step,
hdr_flags & V4L2_FWHT_FL_LUMA_IS_UNCOMPRESSED,
end_of_rlco_buf))
return false;
if (components_num >= 3) {
u32 h = height;
u32 w = width;
if (!(hdr_flags & V4L2_FWHT_FL_CHROMA_FULL_HEIGHT))
h /= 2;
if (!(hdr_flags & V4L2_FWHT_FL_CHROMA_FULL_WIDTH))
w /= 2;
if (!decode_plane(cf, &rlco, h, w, ref->cb, ref_chroma_stride,
ref->chroma_step, dst->cb, dst_chroma_stride,
dst->chroma_step,
hdr_flags & V4L2_FWHT_FL_CB_IS_UNCOMPRESSED,
end_of_rlco_buf))
return false;
if (!decode_plane(cf, &rlco, h, w, ref->cr, ref_chroma_stride,
ref->chroma_step, dst->cr, dst_chroma_stride,
dst->chroma_step,
hdr_flags & V4L2_FWHT_FL_CR_IS_UNCOMPRESSED,
end_of_rlco_buf))
return false;
}
if (components_num == 4)
if (!decode_plane(cf, &rlco, height, width, ref->alpha, ref_stride,
ref->luma_alpha_step, dst->alpha, dst_stride,
dst->luma_alpha_step,
hdr_flags & V4L2_FWHT_FL_ALPHA_IS_UNCOMPRESSED,
end_of_rlco_buf))
return false;
return true;
}