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aomedia / aom / d45a86389501b99e882d7e19cc59f7400cca71e6 / . / common / y4minput.c
blob: abd4d0b86d193bc6f881a1a1def160b9e1a9d971 [file] [log] [blame]
/*
* Copyright (c) 2016, Alliance for Open Media. All rights reserved
*
* This source code is subject to the terms of the BSD 2 Clause License and
* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
* was not distributed with this source code in the LICENSE file, you can
* obtain it at www.aomedia.org/license/software. If the Alliance for Open
* Media Patent License 1.0 was not distributed with this source code in the
* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
*
* Based on code from the OggTheora software codec source code,
* Copyright (C) 2002-2010 The Xiph.Org Foundation and contributors.
*/
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include "aom/aom_integer.h"
#include "aom_ports/msvc.h"
#include "y4minput.h"
// Reads 'size' bytes from 'file' into 'buf' with some fault tolerance.
// Returns true on success.
static int file_read(void *buf, size_t size, FILE *file) {
const int kMaxRetries = 5;
int retry_count = 0;
int file_error;
size_t len = 0;
do {
const size_t n = fread((uint8_t *)buf + len, 1, size - len, file);
len += n;
file_error = ferror(file);
if (file_error) {
if (errno == EINTR || errno == EAGAIN) {
clearerr(file);
continue;
} else {
fprintf(stderr, "Error reading file: %u of %u bytes read, %d: %s\n",
(uint32_t)len, (uint32_t)size, errno, strerror(errno));
return 0;
}
}
} while (!feof(file) && len < size && ++retry_count < kMaxRetries);
if (!feof(file) && len != size) {
fprintf(stderr,
"Error reading file: %u of %u bytes read,"
" error: %d, retries: %d, %d: %s\n",
(uint32_t)len, (uint32_t)size, file_error, retry_count, errno,
strerror(errno));
}
return len == size;
}
// Stores the color range in 'y4m_ctx', returning 1 if successfully parsed,
// 0 otherwise.
static int parse_color_range(y4m_input *y4m_ctx, const char *buf) {
// Note that default is studio range.
if (strcmp(buf, "LIMITED") == 0) {
return 1;
}
if (strcmp(buf, "FULL") == 0) {
y4m_ctx->color_range = AOM_CR_FULL_RANGE;
return 1;
}
fprintf(stderr, "Unknown color range value: %s\n", buf);
return 0;
}
static int parse_metadata(y4m_input *y4m_ctx, const char *buf) {
if (strncmp(buf, "COLORRANGE=", 11) == 0) {
return parse_color_range(y4m_ctx, buf + 11);
}
return 1; // No support for other metadata, just ignore them.
}
static int y4m_parse_tags(y4m_input *_y4m, char *_tags) {
char *p;
char *q;
for (p = _tags;; p = q) {
/*Skip any leading spaces.*/
while (*p == ' ') p++;
/*If that's all we have, stop.*/
if (p[0] == '\0') break;
/*Find the end of this tag.*/
for (q = p + 1; *q != '\0' && *q != ' '; q++) {
}
/*Process the tag.*/
switch (p[0]) {
case 'W': {
if (sscanf(p + 1, "%d", &_y4m->pic_w) != 1) return -1;
} break;
case 'H': {
if (sscanf(p + 1, "%d", &_y4m->pic_h) != 1) return -1;
} break;
case 'F': {
if (sscanf(p + 1, "%d:%d", &_y4m->fps_n, &_y4m->fps_d) != 2) {
return -1;
}
} break;
case 'I': {
_y4m->interlace = p[1];
} break;
case 'A': {
if (sscanf(p + 1, "%d:%d", &_y4m->par_n, &_y4m->par_d) != 2) {
return -1;
}
} break;
case 'C': {
if (q - p > 16) return -1;
memcpy(_y4m->chroma_type, p + 1, q - p - 1);
_y4m->chroma_type[q - p - 1] = '\0';
} break;
case 'X': {
if (!parse_metadata(_y4m, p + 1)) return -1;
} break;
default: break; /*Ignore unknown tags.*/
}
}
return 0;
}
// Copy a single tag into the buffer, along with a null character.
// Returns 0 if any file IO errors occur.
static int copy_tag(char *buf, size_t buf_len, char *end_tag, FILE *file) {
size_t i;
assert(buf_len >= 1);
// Skip leading space characters.
do {
if (!file_read(buf, 1, file)) {
return 0;
}
} while (buf[0] == ' ');
// If we hit the newline, treat this as the "empty" tag.
if (buf[0] == '\n') {
buf[0] = '\0';
*end_tag = '\n';
return 1;
}
// Copy over characters until a space is hit, or the buffer is exhausted.
for (i = 1; i < buf_len; ++i) {
if (!file_read(buf + i, 1, file)) {
return 0;
}
if (buf[i] == ' ' || buf[i] == '\n') {
break;
}
}
if (i == buf_len) {
fprintf(stderr, "Error: Y4M header tags must be less than %lu characters\n",
(unsigned long)i);
return 0;
}
*end_tag = buf[i];
buf[i] = '\0';
return 1;
}
// Returns 1 if tags were parsed successfully, 0 otherwise.
static int parse_tags(y4m_input *y4m_ctx, FILE *file) {
char tag[256];
char end; // Character denoting the end of the tag, ' ' or '\n'.
// Set Y4M tags to defaults, updating them as processing occurs. Mandatory
// fields are marked with -1 and will be checked after the tags are parsed.
y4m_ctx->pic_w = -1;
y4m_ctx->pic_h = -1;
y4m_ctx->fps_n = -1; // Also serves as marker for fps_d
y4m_ctx->par_n = 0;
y4m_ctx->par_d = 0;
y4m_ctx->interlace = '?';
y4m_ctx->color_range = AOM_CR_STUDIO_RANGE;
snprintf(y4m_ctx->chroma_type, sizeof(y4m_ctx->chroma_type), "420");
// Find one tag at a time.
do {
if (!copy_tag(tag, sizeof(tag), &end, file)) {
return 0;
}
// y4m_parse_tags returns 0 on success.
if (y4m_parse_tags(y4m_ctx, tag)) {
return 0;
}
} while (end != '\n');
// Check the mandatory fields.
if (y4m_ctx->pic_w == -1) {
fprintf(stderr, "Width field missing\n");
return 0;
}
if (y4m_ctx->pic_h == -1) {
fprintf(stderr, "Height field missing\n");
return 0;
}
if (y4m_ctx->fps_n == -1) {
fprintf(stderr, "FPS field missing\n");
return 0;
}
return 1;
}
/*All anti-aliasing filters in the following conversion functions are based on
one of two window functions:
The 6-tap Lanczos window (for down-sampling and shifts):
sinc(\pi*t)*sinc(\pi*t/3), |t|<3 (sinc(t)==sin(t)/t)
0, |t|>=3
The 4-tap Mitchell window (for up-sampling):
7|t|^3-12|t|^2+16/3, |t|<1
-(7/3)|x|^3+12|x|^2-20|x|+32/3, |t|<2
0, |t|>=2
The number of taps is intentionally kept small to reduce computational
overhead and limit ringing.
The taps from these filters are scaled so that their sum is 1, and the
result is scaled by 128 and rounded to integers to create a filter whose
intermediate values fit inside 16 bits.
Coefficients are rounded in such a way as to ensure their sum is still 128,
which is usually equivalent to normal rounding.
Conversions which require both horizontal and vertical filtering could
have these steps pipelined, for less memory consumption and better cache
performance, but we do them separately for simplicity.*/
#define OC_MINI(_a, _b) ((_a) > (_b) ? (_b) : (_a))
#define OC_MAXI(_a, _b) ((_a) < (_b) ? (_b) : (_a))
#define OC_CLAMPI(_a, _b, _c) (OC_MAXI(_a, OC_MINI(_b, _c)))
/*420jpeg chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
420mpeg2 chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
BR | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
BR | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
We use a resampling filter to shift the site locations one quarter pixel (at
the chroma plane's resolution) to the right.
The 4:2:2 modes look exactly the same, except there are twice as many chroma
lines, and they are vertically co-sited with the luma samples in both the
mpeg2 and jpeg cases (thus requiring no vertical resampling).*/
static void y4m_42xmpeg2_42xjpeg_helper(unsigned char *_dst,
const unsigned char *_src, int _c_w,
int _c_h) {
int y;
int x;
for (y = 0; y < _c_h; y++) {
/*Filter: [4 -17 114 35 -9 1]/128, derived from a 6-tap Lanczos
window.*/
for (x = 0; x < OC_MINI(_c_w, 2); x++) {
_dst[x] = (unsigned char)OC_CLAMPI(
0,
(4 * _src[0] - 17 * _src[OC_MAXI(x - 1, 0)] + 114 * _src[x] +
35 * _src[OC_MINI(x + 1, _c_w - 1)] -
9 * _src[OC_MINI(x + 2, _c_w - 1)] + _src[OC_MINI(x + 3, _c_w - 1)] +
64) >>
7,
255);
}
for (; x < _c_w - 3; x++) {
_dst[x] = (unsigned char)OC_CLAMPI(
0,
(4 * _src[x - 2] - 17 * _src[x - 1] + 114 * _src[x] +
35 * _src[x + 1] - 9 * _src[x + 2] + _src[x + 3] + 64) >>
7,
255);
}
for (; x < _c_w; x++) {
_dst[x] = (unsigned char)OC_CLAMPI(
0,
(4 * _src[x - 2] - 17 * _src[x - 1] + 114 * _src[x] +
35 * _src[OC_MINI(x + 1, _c_w - 1)] -
9 * _src[OC_MINI(x + 2, _c_w - 1)] + _src[_c_w - 1] + 64) >>
7,
255);
}
_dst += _c_w;
_src += _c_w;
}
}
/*This format is only used for interlaced content, but is included for
completeness.
420jpeg chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
420paldv chroma samples are sited like:
YR------Y-------YR------Y-------
| | | |
| | | |
| | | |
YB------Y-------YB------Y-------
| | | |
| | | |
| | | |
YR------Y-------YR------Y-------
| | | |
| | | |
| | | |
YB------Y-------YB------Y-------
| | | |
| | | |
| | | |
We use a resampling filter to shift the site locations one quarter pixel (at
the chroma plane's resolution) to the right.
Then we use another filter to move the C_r location down one quarter pixel,
and the C_b location up one quarter pixel.*/
static void y4m_convert_42xpaldv_42xjpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
unsigned char *tmp;
int c_w;
int c_h;
int c_sz;
int pli;
int y;
int x;
/*Skip past the luma data.*/
_dst += _y4m->pic_w * _y4m->pic_h;
/*Compute the size of each chroma plane.*/
c_w = (_y4m->pic_w + 1) / 2;
c_h = (_y4m->pic_h + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h;
c_sz = c_w * c_h;
tmp = _aux + 2 * c_sz;
for (pli = 1; pli < 3; pli++) {
/*First do the horizontal re-sampling.
This is the same as the mpeg2 case, except that after the horizontal
case, we need to apply a second vertical filter.*/
y4m_42xmpeg2_42xjpeg_helper(tmp, _aux, c_w, c_h);
_aux += c_sz;
switch (pli) {
case 1: {
/*Slide C_b up a quarter-pel.
This is the same filter used above, but in the other order.*/
for (x = 0; x < c_w; x++) {
for (y = 0; y < OC_MINI(c_h, 3); y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(tmp[0] - 9 * tmp[OC_MAXI(y - 2, 0) * c_w] +
35 * tmp[OC_MAXI(y - 1, 0) * c_w] + 114 * tmp[y * c_w] -
17 * tmp[OC_MINI(y + 1, c_h - 1) * c_w] +
4 * tmp[OC_MINI(y + 2, c_h - 1) * c_w] + 64) >>
7,
255);
}
for (; y < c_h - 2; y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(tmp[(y - 3) * c_w] - 9 * tmp[(y - 2) * c_w] +
35 * tmp[(y - 1) * c_w] + 114 * tmp[y * c_w] -
17 * tmp[(y + 1) * c_w] + 4 * tmp[(y + 2) * c_w] + 64) >>
7,
255);
}
for (; y < c_h; y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(tmp[(y - 3) * c_w] - 9 * tmp[(y - 2) * c_w] +
35 * tmp[(y - 1) * c_w] + 114 * tmp[y * c_w] -
17 * tmp[OC_MINI(y + 1, c_h - 1) * c_w] +
4 * tmp[(c_h - 1) * c_w] + 64) >>
7,
255);
}
_dst++;
tmp++;
}
_dst += c_sz - c_w;
tmp -= c_w;
} break;
case 2: {
/*Slide C_r down a quarter-pel.
This is the same as the horizontal filter.*/
for (x = 0; x < c_w; x++) {
for (y = 0; y < OC_MINI(c_h, 2); y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(4 * tmp[0] - 17 * tmp[OC_MAXI(y - 1, 0) * c_w] +
114 * tmp[y * c_w] + 35 * tmp[OC_MINI(y + 1, c_h - 1) * c_w] -
9 * tmp[OC_MINI(y + 2, c_h - 1) * c_w] +
tmp[OC_MINI(y + 3, c_h - 1) * c_w] + 64) >>
7,
255);
}
for (; y < c_h - 3; y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(4 * tmp[(y - 2) * c_w] - 17 * tmp[(y - 1) * c_w] +
114 * tmp[y * c_w] + 35 * tmp[(y + 1) * c_w] -
9 * tmp[(y + 2) * c_w] + tmp[(y + 3) * c_w] + 64) >>
7,
255);
}
for (; y < c_h; y++) {
_dst[y * c_w] = (unsigned char)OC_CLAMPI(
0,
(4 * tmp[(y - 2) * c_w] - 17 * tmp[(y - 1) * c_w] +
114 * tmp[y * c_w] + 35 * tmp[OC_MINI(y + 1, c_h - 1) * c_w] -
9 * tmp[OC_MINI(y + 2, c_h - 1) * c_w] + tmp[(c_h - 1) * c_w] +
64) >>
7,
255);
}
_dst++;
tmp++;
}
} break;
}
/*For actual interlaced material, this would have to be done separately on
each field, and the shift amounts would be different.
C_r moves down 1/8, C_b up 3/8 in the top field, and C_r moves down 3/8,
C_b up 1/8 in the bottom field.
The corresponding filters would be:
Down 1/8 (reverse order for up): [3 -11 125 15 -4 0]/128
Down 3/8 (reverse order for up): [4 -19 98 56 -13 2]/128*/
}
}
/*Perform vertical filtering to reduce a single plane from 4:2:2 to 4:2:0.
This is used as a helper by several conversion routines.*/
static void y4m_422jpeg_420jpeg_helper(unsigned char *_dst,
const unsigned char *_src, int _c_w,
int _c_h) {
int y;
int x;
/*Filter: [3 -17 78 78 -17 3]/128, derived from a 6-tap Lanczos window.*/
for (x = 0; x < _c_w; x++) {
for (y = 0; y < OC_MINI(_c_h, 2); y += 2) {
_dst[(y >> 1) * _c_w] =
OC_CLAMPI(0,
(64 * _src[0] + 78 * _src[OC_MINI(1, _c_h - 1) * _c_w] -
17 * _src[OC_MINI(2, _c_h - 1) * _c_w] +
3 * _src[OC_MINI(3, _c_h - 1) * _c_w] + 64) >>
7,
255);
}
for (; y < _c_h - 3; y += 2) {
_dst[(y >> 1) * _c_w] =
OC_CLAMPI(0,
(3 * (_src[(y - 2) * _c_w] + _src[(y + 3) * _c_w]) -
17 * (_src[(y - 1) * _c_w] + _src[(y + 2) * _c_w]) +
78 * (_src[y * _c_w] + _src[(y + 1) * _c_w]) + 64) >>
7,
255);
}
for (; y < _c_h; y += 2) {
_dst[(y >> 1) * _c_w] = OC_CLAMPI(
0,
(3 * (_src[(y - 2) * _c_w] + _src[(_c_h - 1) * _c_w]) -
17 * (_src[(y - 1) * _c_w] + _src[OC_MINI(y + 2, _c_h - 1) * _c_w]) +
78 * (_src[y * _c_w] + _src[OC_MINI(y + 1, _c_h - 1) * _c_w]) +
64) >>
7,
255);
}
_src++;
_dst++;
}
}
/*420jpeg chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
422jpeg chroma samples are sited like:
Y---BR--Y-------Y---BR--Y-------
| | | |
| | | |
| | | |
Y---BR--Y-------Y---BR--Y-------
| | | |
| | | |
| | | |
Y---BR--Y-------Y---BR--Y-------
| | | |
| | | |
| | | |
Y---BR--Y-------Y---BR--Y-------
| | | |
| | | |
| | | |
We use a resampling filter to decimate the chroma planes by two in the
vertical direction.*/
static void y4m_convert_422jpeg_420jpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
int c_w;
int c_h;
int c_sz;
int dst_c_w;
int dst_c_h;
int dst_c_sz;
int pli;
/*Skip past the luma data.*/
_dst += _y4m->pic_w * _y4m->pic_h;
/*Compute the size of each chroma plane.*/
c_w = (_y4m->pic_w + _y4m->src_c_dec_h - 1) / _y4m->src_c_dec_h;
c_h = _y4m->pic_h;
dst_c_w = (_y4m->pic_w + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h;
dst_c_h = (_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v;
c_sz = c_w * c_h;
dst_c_sz = dst_c_w * dst_c_h;
for (pli = 1; pli < 3; pli++) {
y4m_422jpeg_420jpeg_helper(_dst, _aux, c_w, c_h);
_aux += c_sz;
_dst += dst_c_sz;
}
}
/*420jpeg chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
422 chroma samples are sited like:
YBR-----Y-------YBR-----Y-------
| | | |
| | | |
| | | |
YBR-----Y-------YBR-----Y-------
| | | |
| | | |
| | | |
YBR-----Y-------YBR-----Y-------
| | | |
| | | |
| | | |
YBR-----Y-------YBR-----Y-------
| | | |
| | | |
| | | |
We use a resampling filter to shift the original site locations one quarter
pixel (at the original chroma resolution) to the right.
Then we use a second resampling filter to decimate the chroma planes by two
in the vertical direction.*/
static void y4m_convert_422_420jpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
unsigned char *tmp;
int c_w;
int c_h;
int c_sz;
int dst_c_h;
int dst_c_sz;
int pli;
/*Skip past the luma data.*/
_dst += _y4m->pic_w * _y4m->pic_h;
/*Compute the size of each chroma plane.*/
c_w = (_y4m->pic_w + _y4m->src_c_dec_h - 1) / _y4m->src_c_dec_h;
c_h = _y4m->pic_h;
dst_c_h = (_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v;
c_sz = c_w * c_h;
dst_c_sz = c_w * dst_c_h;
tmp = _aux + 2 * c_sz;
for (pli = 1; pli < 3; pli++) {
/*In reality, the horizontal and vertical steps could be pipelined, for
less memory consumption and better cache performance, but we do them
separately for simplicity.*/
/*First do horizontal filtering (convert to 422jpeg)*/
y4m_42xmpeg2_42xjpeg_helper(tmp, _aux, c_w, c_h);
/*Now do the vertical filtering.*/
y4m_422jpeg_420jpeg_helper(_dst, tmp, c_w, c_h);
_aux += c_sz;
_dst += dst_c_sz;
}
}
/*420jpeg chroma samples are sited like:
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| BR | | BR |
| | | |
Y-------Y-------Y-------Y-------
| | | |
| | | |
| | | |
411 chroma samples are sited like:
YBR-----Y-------Y-------Y-------
| | | |
| | | |
| | | |
YBR-----Y-------Y-------Y-------
| | | |
| | | |
| | | |
YBR-----Y-------Y-------Y-------
| | | |
| | | |
| | | |
YBR-----Y-------Y-------Y-------
| | | |
| | | |
| | | |
We use a filter to resample at site locations one eighth pixel (at the source
chroma plane's horizontal resolution) and five eighths of a pixel to the
right.
Then we use another filter to decimate the planes by 2 in the vertical
direction.*/
static void y4m_convert_411_420jpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
unsigned char *tmp;
int c_w;
int c_h;
int c_sz;
int dst_c_w;
int dst_c_h;
int dst_c_sz;
int tmp_sz;
int pli;
int y;
int x;
/*Skip past the luma data.*/
_dst += _y4m->pic_w * _y4m->pic_h;
/*Compute the size of each chroma plane.*/
c_w = (_y4m->pic_w + _y4m->src_c_dec_h - 1) / _y4m->src_c_dec_h;
c_h = _y4m->pic_h;
dst_c_w = (_y4m->pic_w + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h;
dst_c_h = (_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v;
c_sz = c_w * c_h;
dst_c_sz = dst_c_w * dst_c_h;
tmp_sz = dst_c_w * c_h;
tmp = _aux + 2 * c_sz;
for (pli = 1; pli < 3; pli++) {
/*In reality, the horizontal and vertical steps could be pipelined, for
less memory consumption and better cache performance, but we do them
separately for simplicity.*/
/*First do horizontal filtering (convert to 422jpeg)*/
for (y = 0; y < c_h; y++) {
/*Filters: [1 110 18 -1]/128 and [-3 50 86 -5]/128, both derived from a
4-tap Mitchell window.*/
for (x = 0; x < OC_MINI(c_w, 1); x++) {
tmp[x << 1] = (unsigned char)OC_CLAMPI(
0,
(111 * _aux[0] + 18 * _aux[OC_MINI(1, c_w - 1)] -
_aux[OC_MINI(2, c_w - 1)] + 64) >>
7,
255);
tmp[x << 1 | 1] = (unsigned char)OC_CLAMPI(
0,
(47 * _aux[0] + 86 * _aux[OC_MINI(1, c_w - 1)] -
5 * _aux[OC_MINI(2, c_w - 1)] + 64) >>
7,
255);
}
for (; x < c_w - 2; x++) {
tmp[x << 1] =
(unsigned char)OC_CLAMPI(0,
(_aux[x - 1] + 110 * _aux[x] +
18 * _aux[x + 1] - _aux[x + 2] + 64) >>
7,
255);
tmp[x << 1 | 1] = (unsigned char)OC_CLAMPI(
0,
(-3 * _aux[x - 1] + 50 * _aux[x] + 86 * _aux[x + 1] -
5 * _aux[x + 2] + 64) >>
7,
255);
}
for (; x < c_w; x++) {
tmp[x << 1] = (unsigned char)OC_CLAMPI(
0,
(_aux[x - 1] + 110 * _aux[x] + 18 * _aux[OC_MINI(x + 1, c_w - 1)] -
_aux[c_w - 1] + 64) >>
7,
255);
if ((x << 1 | 1) < dst_c_w) {
tmp[x << 1 | 1] = (unsigned char)OC_CLAMPI(
0,
(-3 * _aux[x - 1] + 50 * _aux[x] +
86 * _aux[OC_MINI(x + 1, c_w - 1)] - 5 * _aux[c_w - 1] + 64) >>
7,
255);
}
}
tmp += dst_c_w;
_aux += c_w;
}
tmp -= tmp_sz;
/*Now do the vertical filtering.*/
y4m_422jpeg_420jpeg_helper(_dst, tmp, dst_c_w, c_h);
_dst += dst_c_sz;
}
}
/*Convert 444 to 420jpeg.*/
static void y4m_convert_444_420jpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
unsigned char *tmp;
int c_w;
int c_h;
int c_sz;
int dst_c_w;
int dst_c_h;
int dst_c_sz;
int tmp_sz;
int pli;
int y;
int x;
/*Skip past the luma data.*/
_dst += _y4m->pic_w * _y4m->pic_h;
/*Compute the size of each chroma plane.*/
c_w = (_y4m->pic_w + _y4m->src_c_dec_h - 1) / _y4m->src_c_dec_h;
c_h = _y4m->pic_h;
dst_c_w = (_y4m->pic_w + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h;
dst_c_h = (_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v;
c_sz = c_w * c_h;
dst_c_sz = dst_c_w * dst_c_h;
tmp_sz = dst_c_w * c_h;
tmp = _aux + 2 * c_sz;
for (pli = 1; pli < 3; pli++) {
/*Filter: [3 -17 78 78 -17 3]/128, derived from a 6-tap Lanczos window.*/
for (y = 0; y < c_h; y++) {
for (x = 0; x < OC_MINI(c_w, 2); x += 2) {
tmp[x >> 1] = OC_CLAMPI(0,
(64 * _aux[0] + 78 * _aux[OC_MINI(1, c_w - 1)] -
17 * _aux[OC_MINI(2, c_w - 1)] +
3 * _aux[OC_MINI(3, c_w - 1)] + 64) >>
7,
255);
}
for (; x < c_w - 3; x += 2) {
tmp[x >> 1] = OC_CLAMPI(0,
(3 * (_aux[x - 2] + _aux[x + 3]) -
17 * (_aux[x - 1] + _aux[x + 2]) +
78 * (_aux[x] + _aux[x + 1]) + 64) >>
7,
255);
}
for (; x < c_w; x += 2) {
tmp[x >> 1] =
OC_CLAMPI(0,
(3 * (_aux[x - 2] + _aux[c_w - 1]) -
17 * (_aux[x - 1] + _aux[OC_MINI(x + 2, c_w - 1)]) +
78 * (_aux[x] + _aux[OC_MINI(x + 1, c_w - 1)]) + 64) >>
7,
255);
}
tmp += dst_c_w;
_aux += c_w;
}
tmp -= tmp_sz;
/*Now do the vertical filtering.*/
y4m_422jpeg_420jpeg_helper(_dst, tmp, dst_c_w, c_h);
_dst += dst_c_sz;
}
}
/*The image is padded with empty chroma components at 4:2:0.*/
static void y4m_convert_mono_420jpeg(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
int c_sz;
(void)_aux;
_dst += _y4m->pic_w * _y4m->pic_h;
c_sz = ((_y4m->pic_w + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h) *
((_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v);
memset(_dst, 128, c_sz * 2);
}
/*No conversion function needed.*/
static void y4m_convert_null(y4m_input *_y4m, unsigned char *_dst,
unsigned char *_aux) {
(void)_y4m;
(void)_dst;
(void)_aux;
}
static const char TAG[] = "YUV4MPEG2";
int y4m_input_open(y4m_input *y4m_ctx, FILE *file, char *skip_buffer,
int num_skip, aom_chroma_sample_position_t csp,
int only_420) {
// File must start with |TAG|.
char tag_buffer[9]; // 9 == strlen(TAG)
// Read as much as possible from |skip_buffer|, which were characters
// that were previously read from the file to do input-type detection.
assert(num_skip >= 0 && num_skip <= 8);
if (num_skip > 0) {
memcpy(tag_buffer, skip_buffer, num_skip);
}
// Start reading from the file now that the |skip_buffer| is depleted.
if (!file_read(tag_buffer + num_skip, 9 - num_skip, file)) {
return -1;
}
if (memcmp(TAG, tag_buffer, 9) != 0) {
fprintf(stderr, "Error parsing header: must start with %s\n", TAG);
return -1;
}
// Next character must be a space.
if (!file_read(tag_buffer, 1, file) || tag_buffer[0] != ' ') {
fprintf(stderr, "Error parsing header: space must follow %s\n", TAG);
return -1;
}
if (!parse_tags(y4m_ctx, file)) {
fprintf(stderr, "Error parsing %s header.\n", TAG);
return -1;
}
if (y4m_ctx->interlace == '?') {
fprintf(stderr,
"Warning: Input video interlacing format unknown; "
"assuming progressive scan.\n");
} else if (y4m_ctx->interlace != 'p') {
fprintf(stderr,
"Input video is interlaced; "
"Only progressive scan handled.\n");
return -1;
}
/* Only support vertical chroma sample position if the input format is
* already 420mpeg2. Colocated is not supported in Y4M.
*/
if (csp == AOM_CSP_VERTICAL &&
strcmp(y4m_ctx->chroma_type, "420mpeg2") != 0) {
fprintf(stderr,
"Vertical chroma sample position only supported "
"for 420mpeg2 input\n");
return -1;
}
if (csp == AOM_CSP_COLOCATED) {
fprintf(stderr, "Colocated chroma sample position not supported in Y4M\n");
return -1;
}
y4m_ctx->aom_fmt = AOM_IMG_FMT_I420;
y4m_ctx->bps = 12;
y4m_ctx->bit_depth = 8;
y4m_ctx->aux_buf = NULL;
y4m_ctx->dst_buf = NULL;
if (strcmp(y4m_ctx->chroma_type, "420") == 0 ||
strcmp(y4m_ctx->chroma_type, "420jpeg") == 0 ||
strcmp(y4m_ctx->chroma_type, "420mpeg2") == 0) {
y4m_ctx->src_c_dec_h = y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_v =
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz =
y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * ((y4m_ctx->pic_h + 1) / 2);
/* Natively supported: no conversion required. */
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
} else if (strcmp(y4m_ctx->chroma_type, "420p10") == 0) {
y4m_ctx->src_c_dec_h = 2;
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 2;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz =
2 * (y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * ((y4m_ctx->pic_h + 1) / 2));
/* Natively supported: no conversion required. */
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
y4m_ctx->bit_depth = 10;
y4m_ctx->bps = 15;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I42016;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 420p10 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "420p12") == 0) {
y4m_ctx->src_c_dec_h = 2;
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 2;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz =
2 * (y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * ((y4m_ctx->pic_h + 1) / 2));
/* Natively supported: no conversion required. */
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
y4m_ctx->bit_depth = 12;
y4m_ctx->bps = 18;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I42016;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 420p12 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "420paldv") == 0) {
y4m_ctx->src_c_dec_h = y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_v =
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.
We need to make two filter passes, so we need some extra space in the
aux buffer.*/
y4m_ctx->aux_buf_sz =
3 * ((y4m_ctx->pic_w + 1) / 2) * ((y4m_ctx->pic_h + 1) / 2);
y4m_ctx->aux_buf_read_sz =
2 * ((y4m_ctx->pic_w + 1) / 2) * ((y4m_ctx->pic_h + 1) / 2);
y4m_ctx->convert = y4m_convert_42xpaldv_42xjpeg;
} else if (strcmp(y4m_ctx->chroma_type, "422jpeg") == 0) {
y4m_ctx->src_c_dec_h = y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.*/
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz =
2 * ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
y4m_ctx->convert = y4m_convert_422jpeg_420jpeg;
} else if (strcmp(y4m_ctx->chroma_type, "422") == 0) {
y4m_ctx->src_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 1;
if (only_420) {
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.
We need to make two filter passes, so we need some extra space in the
aux buffer.*/
y4m_ctx->aux_buf_read_sz =
2 * ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz +
((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
y4m_ctx->convert = y4m_convert_422_420jpeg;
} else {
y4m_ctx->aom_fmt = AOM_IMG_FMT_I422;
y4m_ctx->bps = 16;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz =
y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
/*Natively supported: no conversion required.*/
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
}
} else if (strcmp(y4m_ctx->chroma_type, "422p10") == 0) {
y4m_ctx->src_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I42216;
y4m_ctx->bps = 20;
y4m_ctx->bit_depth = 10;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz =
2 * (y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h);
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 422p10 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "422p12") == 0) {
y4m_ctx->src_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I42216;
y4m_ctx->bps = 24;
y4m_ctx->bit_depth = 12;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz =
2 * (y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h);
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 422p12 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "411") == 0) {
y4m_ctx->src_c_dec_h = 4;
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.
We need to make two filter passes, so we need some extra space in the
aux buffer.*/
y4m_ctx->aux_buf_read_sz = 2 * ((y4m_ctx->pic_w + 3) / 4) * y4m_ctx->pic_h;
y4m_ctx->aux_buf_sz =
y4m_ctx->aux_buf_read_sz + ((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
y4m_ctx->convert = y4m_convert_411_420jpeg;
} else if (strcmp(y4m_ctx->chroma_type, "444") == 0) {
y4m_ctx->src_c_dec_h = 1;
y4m_ctx->src_c_dec_v = 1;
if (only_420) {
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.
We need to make two filter passes, so we need some extra space in the
aux buffer.*/
y4m_ctx->aux_buf_read_sz = 2 * y4m_ctx->pic_w * y4m_ctx->pic_h;
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz +
((y4m_ctx->pic_w + 1) / 2) * y4m_ctx->pic_h;
y4m_ctx->convert = y4m_convert_444_420jpeg;
} else {
y4m_ctx->aom_fmt = AOM_IMG_FMT_I444;
y4m_ctx->bps = 24;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz = 3 * y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Natively supported: no conversion required.*/
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
}
} else if (strcmp(y4m_ctx->chroma_type, "444p10") == 0) {
y4m_ctx->src_c_dec_h = 1;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I44416;
y4m_ctx->bps = 30;
y4m_ctx->bit_depth = 10;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz = 2 * 3 * y4m_ctx->pic_w * y4m_ctx->pic_h;
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 444p10 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "444p12") == 0) {
y4m_ctx->src_c_dec_h = 1;
y4m_ctx->src_c_dec_v = 1;
y4m_ctx->aom_fmt = AOM_IMG_FMT_I44416;
y4m_ctx->bps = 36;
y4m_ctx->bit_depth = 12;
y4m_ctx->dst_c_dec_h = y4m_ctx->src_c_dec_h;
y4m_ctx->dst_c_dec_v = y4m_ctx->src_c_dec_v;
y4m_ctx->dst_buf_read_sz = 2 * 3 * y4m_ctx->pic_w * y4m_ctx->pic_h;
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_null;
if (only_420) {
fprintf(stderr, "Unsupported conversion from 444p12 to 420jpeg\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "444alpha") == 0) {
y4m_ctx->src_c_dec_h = 1;
y4m_ctx->src_c_dec_v = 1;
if (only_420) {
y4m_ctx->dst_c_dec_h = 2;
y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*Chroma filter required: read into the aux buf first.
We need to make two filter passes, so we need some extra space in the
aux buffer.
The extra plane also gets read into the aux buf.
It will be discarded.*/
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz =
3 * y4m_ctx->pic_w * y4m_ctx->pic_h;
y4m_ctx->convert = y4m_convert_444_420jpeg;
} else {
fprintf(stderr, "Unsupported format: 444A\n");
return -1;
}
} else if (strcmp(y4m_ctx->chroma_type, "mono") == 0) {
y4m_ctx->src_c_dec_h = y4m_ctx->src_c_dec_v = 0;
y4m_ctx->dst_c_dec_h = y4m_ctx->dst_c_dec_v = 2;
y4m_ctx->dst_buf_read_sz = y4m_ctx->pic_w * y4m_ctx->pic_h;
/*No extra space required, but we need to clear the chroma planes.*/
y4m_ctx->aux_buf_sz = y4m_ctx->aux_buf_read_sz = 0;
y4m_ctx->convert = y4m_convert_mono_420jpeg;
} else {
fprintf(stderr, "Unknown chroma sampling type: %s\n", y4m_ctx->chroma_type);
return -1;
}
/*The size of the final frame buffers is always computed from the
destination chroma decimation type.*/
y4m_ctx->dst_buf_sz =
y4m_ctx->pic_w * y4m_ctx->pic_h +
2 * ((y4m_ctx->pic_w + y4m_ctx->dst_c_dec_h - 1) / y4m_ctx->dst_c_dec_h) *
((y4m_ctx->pic_h + y4m_ctx->dst_c_dec_v - 1) / y4m_ctx->dst_c_dec_v);
if (y4m_ctx->bit_depth == 8)
y4m_ctx->dst_buf = (unsigned char *)malloc(y4m_ctx->dst_buf_sz);
else
y4m_ctx->dst_buf = (unsigned char *)malloc(2 * y4m_ctx->dst_buf_sz);
if (y4m_ctx->aux_buf_sz > 0)
y4m_ctx->aux_buf = (unsigned char *)malloc(y4m_ctx->aux_buf_sz);
return 0;
}
void y4m_input_close(y4m_input *_y4m) {
free(_y4m->dst_buf);
free(_y4m->aux_buf);
}
int y4m_input_fetch_frame(y4m_input *_y4m, FILE *_fin, aom_image_t *_img) {
char frame[6];
int pic_sz;
int c_w;
int c_h;
int c_sz;
int bytes_per_sample = _y4m->bit_depth > 8 ? 2 : 1;
/*Read and skip the frame header.*/
if (!file_read(frame, 6, _fin)) return 0;
if (memcmp(frame, "FRAME", 5)) {
fprintf(stderr, "Loss of framing in Y4M input data\n");
return -1;
}
if (frame[5] != '\n') {
char c;
int j;
for (j = 0; j < 79 && file_read(&c, 1, _fin) && c != '\n'; j++) {
}
if (j == 79) {
fprintf(stderr, "Error parsing Y4M frame header\n");
return -1;
}
}
/*Read the frame data that needs no conversion.*/
if (!file_read(_y4m->dst_buf, _y4m->dst_buf_read_sz, _fin)) {
fprintf(stderr, "Error reading Y4M frame data.\n");
return -1;
}
/*Read the frame data that does need conversion.*/
if (!file_read(_y4m->aux_buf, _y4m->aux_buf_read_sz, _fin)) {
fprintf(stderr, "Error reading Y4M frame data.\n");
return -1;
}
/*Now convert the just read frame.*/
(*_y4m->convert)(_y4m, _y4m->dst_buf, _y4m->aux_buf);
/*Fill in the frame buffer pointers.
We don't use aom_img_wrap() because it forces padding for odd picture
sizes, which would require a separate fread call for every row.*/
memset(_img, 0, sizeof(*_img));
/*Y4M has the planes in Y'CbCr order, which libaom calls Y, U, and V.*/
_img->fmt = _y4m->aom_fmt;
_img->w = _img->d_w = _y4m->pic_w;
_img->h = _img->d_h = _y4m->pic_h;
_img->x_chroma_shift = _y4m->dst_c_dec_h >> 1;
_img->y_chroma_shift = _y4m->dst_c_dec_v >> 1;
_img->bps = _y4m->bps;
/*Set up the buffer pointers.*/
pic_sz = _y4m->pic_w * _y4m->pic_h * bytes_per_sample;
c_w = (_y4m->pic_w + _y4m->dst_c_dec_h - 1) / _y4m->dst_c_dec_h;
c_w *= bytes_per_sample;
c_h = (_y4m->pic_h + _y4m->dst_c_dec_v - 1) / _y4m->dst_c_dec_v;
c_sz = c_w * c_h;
_img->stride[AOM_PLANE_Y] = _y4m->pic_w * bytes_per_sample;
_img->stride[AOM_PLANE_U] = _img->stride[AOM_PLANE_V] = c_w;
_img->planes[AOM_PLANE_Y] = _y4m->dst_buf;
_img->planes[AOM_PLANE_U] = _y4m->dst_buf + pic_sz;
_img->planes[AOM_PLANE_V] = _y4m->dst_buf + pic_sz + c_sz;
return 1;
}