/*****************************************************************************
* This file is part of Kvazaar HEVC encoder.
*
* Copyright (C) 2013-2014 Tampere University of Technology and others (see
* COPYING file).
*
* Kvazaar is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as published
* by the Free Software Foundation.
*
* Kvazaar is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Kvazaar. If not, see .
****************************************************************************/
/*
* \file
*/
#include "threads.h"
#include "image.h"
#include "strategyselector.h"
#include
#include
#include
#include
#include
#include "sao.h"
/**
* \brief Allocate new image
* \return image pointer
*/
image *image_alloc(const int32_t width, const int32_t height, const int32_t poc)
{
image *im = MALLOC(image, 1);
unsigned int luma_size = width * height;
unsigned int chroma_size = luma_size / 4;
//Assert that we have a well defined image
assert((width % 2) == 0);
assert((height % 2) == 0);
if (!im) return NULL;
im->width = width;
im->height = height;
im->stride = width;
im->base_image = im;
im->refcount = 1; //We give a reference to caller
im->poc = poc;
//Allocate memory
im->fulldata = MALLOC(pixel, (luma_size + 2*chroma_size));
im->y = im->data[COLOR_Y] = &im->fulldata[0];
im->u = im->data[COLOR_U] = &im->fulldata[luma_size];
im->v = im->data[COLOR_V] = &im->fulldata[luma_size + chroma_size];
return im;
}
/**
* \brief Free memory allocated to picture (if we have no reference left)
* \param pic picture pointer
* \return 1 on success, 0 on failure
*/
int image_free(image * const im)
{
//Either we are the base image, or we should have no references
assert(im->base_image == im || im->refcount == 0);
int32_t new_refcount = ATOMIC_DEC(&(im->base_image->refcount));
if (new_refcount > 0) return 1;
FREE_POINTER(im->fulldata);
//Just to make the program crash when using those values after the free
im->y = im->u = im->v = im->data[COLOR_Y] = im->data[COLOR_U] = im->data[COLOR_V] = NULL;
free(im);
return 1;
}
image *image_make_subimage(image * const orig_image, const unsigned int x_offset, const unsigned int y_offset, const unsigned int width, const unsigned int height)
{
image *im = MALLOC(image, 1);
if (!im) return NULL;
im->base_image = orig_image->base_image;
ATOMIC_INC(&(im->base_image->refcount));
assert(x_offset + width <= orig_image->width);
assert(y_offset + height <= orig_image->height);
//Assert that we have a well defined image
assert((width % 2) == 0);
assert((height % 2) == 0);
assert((x_offset % 2) == 0);
assert((y_offset % 2) == 0);
im->stride = orig_image->stride;
im->refcount = 0; //No references on subimages
im->width = width;
im->height = height;
im->y = im->data[COLOR_Y] = &orig_image->y[x_offset + y_offset * orig_image->stride];
im->u = im->data[COLOR_U] = &orig_image->u[x_offset/2 + y_offset/2 * orig_image->stride/2];
im->v = im->data[COLOR_V] = &orig_image->v[x_offset/2 + y_offset/2 * orig_image->stride/2];
return im;
}
yuv_t * yuv_t_alloc(int luma_size)
{
// Get buffers with separate mallocs in order to take advantage of
// automatic buffer overrun checks.
yuv_t *yuv = (yuv_t *)malloc(sizeof(*yuv));
yuv->y = (pixel *)malloc(luma_size * sizeof(*yuv->y));
yuv->u = (pixel *)malloc(luma_size / 2 * sizeof(*yuv->u));
yuv->v = (pixel *)malloc(luma_size / 2 * sizeof(*yuv->v));
yuv->size = luma_size;
return yuv;
}
void yuv_t_free(yuv_t * yuv)
{
free(yuv->y);
free(yuv->u);
free(yuv->v);
free(yuv);
}
/**
* \brief Diagonally interpolate SAD outside the frame.
*
* \param data1 Starting point of the first picture.
* \param data2 Starting point of the second picture.
* \param width Width of the region for which SAD is calculated.
* \param height Height of the region for which SAD is calculated.
* \param width Width of the pixel array.
*
* \returns Sum of Absolute Differences
*/
static unsigned cor_sad(const pixel *pic_data, const pixel *ref_data,
int block_width, int block_height, unsigned pic_width)
{
pixel ref = *ref_data;
int x, y;
unsigned sad = 0;
for (y = 0; y < block_height; ++y) {
for (x = 0; x < block_width; ++x) {
sad += abs(pic_data[y * pic_width + x] - ref);
}
}
return sad;
}
/**
* \brief Vertically interpolate SAD outside the frame.
*
* \param data1 Starting point of the first picture.
* \param data2 Starting point of the second picture.
* \param width Width of the region for which SAD is calculated.
* \param height Height of the region for which SAD is calculated.
* \param width Width of the pixel array.
*
* \returns Sum of Absolute Differences
*/
static unsigned ver_sad(const pixel *pic_data, const pixel *ref_data,
int block_width, int block_height, unsigned pic_width)
{
int x, y;
unsigned sad = 0;
for (y = 0; y < block_height; ++y) {
for (x = 0; x < block_width; ++x) {
sad += abs(pic_data[y * pic_width + x] - ref_data[x]);
}
}
return sad;
}
/**
* \brief Horizontally interpolate SAD outside the frame.
*
* \param data1 Starting point of the first picture.
* \param data2 Starting point of the second picture.
* \param width Width of the region for which SAD is calculated.
* \param height Height of the region for which SAD is calculated.
* \param width Width of the pixel array.
*
* \returns Sum of Absolute Differences
*/
static unsigned hor_sad(const pixel *pic_data, const pixel *ref_data,
int block_width, int block_height, unsigned pic_width, unsigned ref_width)
{
int x, y;
unsigned sad = 0;
for (y = 0; y < block_height; ++y) {
for (x = 0; x < block_width; ++x) {
sad += abs(pic_data[y * pic_width + x] - ref_data[y * ref_width]);
}
}
return sad;
}
/**
* \brief Handle special cases of comparing blocks that are not completely
* inside the frame.
*
* \param pic First frame.
* \param ref Second frame.
* \param pic_x X coordinate of the first block.
* \param pic_y Y coordinate of the first block.
* \param ref_x X coordinate of the second block.
* \param ref_y Y coordinate of the second block.
* \param block_width Width of the blocks.
* \param block_height Height of the blocks.
*/
static unsigned image_interpolated_sad(const image *pic, const image *ref,
int pic_x, int pic_y, int ref_x, int ref_y,
int block_width, int block_height)
{
pixel *pic_data, *ref_data;
int left, right, top, bottom;
int result = 0;
// Change the movement vector to point right next to the frame. This doesn't
// affect the result but removes some special cases.
if (ref_x > ref->width) ref_x = ref->width;
if (ref_y > ref->height) ref_y = ref->height;
if (ref_x + block_width < 0) ref_x = -block_width;
if (ref_y + block_height < 0) ref_y = -block_height;
// These are the number of pixels by how far the movement vector points
// outside the frame. They are always >= 0. If all of them are 0, the
// movement vector doesn't point outside the frame.
left = (ref_x < 0) ? -ref_x : 0;
top = (ref_y < 0) ? -ref_y : 0;
right = (ref_x + block_width > ref->width) ? ref_x + block_width - ref->width : 0;
bottom = (ref_y + block_height > ref->height) ? ref_y + block_height - ref->height : 0;
// Center picture to the current block and reference to the point where
// movement vector is pointing to. That point might be outside the buffer,
// but that is ok because we project the movement vector to the buffer
// before dereferencing the pointer.
pic_data = &pic->y[pic_y * pic->width + pic_x];
ref_data = &ref->y[ref_y * ref->width + ref_x];
// The handling of movement vectors that point outside the picture is done
// in the following way.
// - Correct the index of ref_data so that it points to the top-left
// of the area we want to compare against.
// - Correct the index of pic_data to point inside the current block, so
// that we compare the right part of the block to the ref_data.
// - Reduce block_width and block_height so that the the size of the area
// being compared is correct.
if (top && left) {
result += cor_sad(pic_data,
&ref_data[top * ref->width + left],
left, top, pic->width);
result += ver_sad(&pic_data[left],
&ref_data[top * ref->width + left],
block_width - left, top, pic->width);
result += hor_sad(&pic_data[top * pic->width],
&ref_data[top * ref->width + left],
left, block_height - top, pic->width, ref->width);
result += reg_sad(&pic_data[top * pic->width + left],
&ref_data[top * ref->width + left],
block_width - left, block_height - top, pic->width, ref->width);
} else if (top && right) {
result += ver_sad(pic_data,
&ref_data[top * ref->width],
block_width - right, top, pic->width);
result += cor_sad(&pic_data[block_width - right],
&ref_data[top * ref->width + (block_width - right - 1)],
right, top, pic->width);
result += reg_sad(&pic_data[top * pic->width],
&ref_data[top * ref->width],
block_width - right, block_height - top, pic->width, ref->width);
result += hor_sad(&pic_data[top * pic->width + (block_width - right)],
&ref_data[top * ref->width + (block_width - right - 1)],
right, block_height - top, pic->width, ref->width);
} else if (bottom && left) {
result += hor_sad(pic_data,
&ref_data[left],
left, block_height - bottom, pic->width, ref->width);
result += reg_sad(&pic_data[left],
&ref_data[left],
block_width - left, block_height - bottom, pic->width, ref->width);
result += cor_sad(&pic_data[(block_height - bottom) * pic->width],
&ref_data[(block_height - bottom - 1) * ref->width + left],
left, bottom, pic->width);
result += ver_sad(&pic_data[(block_height - bottom) * pic->width + left],
&ref_data[(block_height - bottom - 1) * ref->width + left],
block_width - left, bottom, pic->width);
} else if (bottom && right) {
result += reg_sad(pic_data,
ref_data,
block_width - right, block_height - bottom, pic->width, ref->width);
result += hor_sad(&pic_data[block_width - right],
&ref_data[block_width - right - 1],
right, block_height - bottom, pic->width, ref->width);
result += ver_sad(&pic_data[(block_height - bottom) * pic->width],
&ref_data[(block_height - bottom - 1) * ref->width],
block_width - right, bottom, pic->width);
result += cor_sad(&pic_data[(block_height - bottom) * pic->width + block_width - right],
&ref_data[(block_height - bottom - 1) * ref->width + block_width - right - 1],
right, bottom, pic->width);
} else if (top) {
result += ver_sad(pic_data,
&ref_data[top * ref->width],
block_width, top, pic->width);
result += reg_sad(&pic_data[top * pic->width],
&ref_data[top * ref->width],
block_width, block_height - top, pic->width, ref->width);
} else if (bottom) {
result += reg_sad(pic_data,
ref_data,
block_width, block_height - bottom, pic->width, ref->width);
result += ver_sad(&pic_data[(block_height - bottom) * pic->width],
&ref_data[(block_height - bottom - 1) * ref->width],
block_width, bottom, pic->width);
} else if (left) {
result += hor_sad(pic_data,
&ref_data[left],
left, block_height, pic->width, ref->width);
result += reg_sad(&pic_data[left],
&ref_data[left],
block_width - left, block_height, pic->width, ref->width);
} else if (right) {
result += reg_sad(pic_data,
ref_data,
block_width - right, block_height, pic->width, ref->width);
result += hor_sad(&pic_data[block_width - right],
&ref_data[block_width - right - 1],
right, block_height, pic->width, ref->width);
} else {
result += reg_sad(pic_data, ref_data, block_width, block_height, pic->width, ref->width);
}
return result;
}
unsigned image_calc_sad(const image *pic, const image *ref, int pic_x, int pic_y, int ref_x, int ref_y,
int block_width, int block_height) {
assert(pic_x >= 0 && pic_x <= pic->width - block_width);
assert(pic_y >= 0 && pic_y <= pic->height - block_height);
if (ref_x >= 0 && ref_x <= ref->width - block_width &&
ref_y >= 0 && ref_y <= ref->height - block_height)
{
// Reference block is completely inside the frame, so just calculate the
// SAD directly. This is the most common case, which is why it's first.
const pixel *pic_data = &pic->y[pic_y * pic->width + pic_x];
const pixel *ref_data = &ref->y[ref_y * ref->width + ref_x];
return reg_sad(pic_data, ref_data, block_width, block_height, pic->width, ref->width);
} else {
// Call a routine that knows how to interpolate pixels outside the frame.
return image_interpolated_sad(pic, ref, pic_x, pic_y, ref_x, ref_y, block_width, block_height);
}
}
/**
* \brief Calculate SATD between two 4x4 blocks inside bigger arrays.
* From HM 13.0
*/
static unsigned satd_16bit_4x4(const pixel *piOrg, const pixel *piCur)
{
int32_t k, satd = 0, diff[16], m[16], d[16];
for( k = 0; k < 16; ++k ) {
diff[k] = piOrg[k] - piCur[k];
}
/*===== hadamard transform =====*/
m[ 0] = diff[ 0] + diff[12];
m[ 1] = diff[ 1] + diff[13];
m[ 2] = diff[ 2] + diff[14];
m[ 3] = diff[ 3] + diff[15];
m[ 4] = diff[ 4] + diff[ 8];
m[ 5] = diff[ 5] + diff[ 9];
m[ 6] = diff[ 6] + diff[10];
m[ 7] = diff[ 7] + diff[11];
m[ 8] = diff[ 4] - diff[ 8];
m[ 9] = diff[ 5] - diff[ 9];
m[10] = diff[ 6] - diff[10];
m[11] = diff[ 7] - diff[11];
m[12] = diff[ 0] - diff[12];
m[13] = diff[ 1] - diff[13];
m[14] = diff[ 2] - diff[14];
m[15] = diff[ 3] - diff[15];
d[ 0] = m[ 0] + m[ 4];
d[ 1] = m[ 1] + m[ 5];
d[ 2] = m[ 2] + m[ 6];
d[ 3] = m[ 3] + m[ 7];
d[ 4] = m[ 8] + m[12];
d[ 5] = m[ 9] + m[13];
d[ 6] = m[10] + m[14];
d[ 7] = m[11] + m[15];
d[ 8] = m[ 0] - m[ 4];
d[ 9] = m[ 1] - m[ 5];
d[10] = m[ 2] - m[ 6];
d[11] = m[ 3] - m[ 7];
d[12] = m[12] - m[ 8];
d[13] = m[13] - m[ 9];
d[14] = m[14] - m[10];
d[15] = m[15] - m[11];
m[ 0] = d[ 0] + d[ 3];
m[ 1] = d[ 1] + d[ 2];
m[ 2] = d[ 1] - d[ 2];
m[ 3] = d[ 0] - d[ 3];
m[ 4] = d[ 4] + d[ 7];
m[ 5] = d[ 5] + d[ 6];
m[ 6] = d[ 5] - d[ 6];
m[ 7] = d[ 4] - d[ 7];
m[ 8] = d[ 8] + d[11];
m[ 9] = d[ 9] + d[10];
m[10] = d[ 9] - d[10];
m[11] = d[ 8] - d[11];
m[12] = d[12] + d[15];
m[13] = d[13] + d[14];
m[14] = d[13] - d[14];
m[15] = d[12] - d[15];
d[ 0] = m[ 0] + m[ 1];
d[ 1] = m[ 0] - m[ 1];
d[ 2] = m[ 2] + m[ 3];
d[ 3] = m[ 3] - m[ 2];
d[ 4] = m[ 4] + m[ 5];
d[ 5] = m[ 4] - m[ 5];
d[ 6] = m[ 6] + m[ 7];
d[ 7] = m[ 7] - m[ 6];
d[ 8] = m[ 8] + m[ 9];
d[ 9] = m[ 8] - m[ 9];
d[10] = m[10] + m[11];
d[11] = m[11] - m[10];
d[12] = m[12] + m[13];
d[13] = m[12] - m[13];
d[14] = m[14] + m[15];
d[15] = m[15] - m[14];
for (k=0; k<16; ++k) {
satd += abs(d[k]);
}
satd = ((satd+1)>>1);
return satd;
}
/**
* \brief Calculate SATD between two 8x8 blocks inside bigger arrays.
*/
unsigned satd_16bit_8x8_general(const pixel * piOrg, const int32_t iStrideOrg,
const pixel * piCur, const int32_t iStrideCur)
{
int32_t k, i, j, jj, sad=0;
int32_t diff[64], m1[8][8], m2[8][8], m3[8][8];
for (k = 0; k < 64; k += 8) {
diff[k+0] = piOrg[0] - piCur[0];
diff[k+1] = piOrg[1] - piCur[1];
diff[k+2] = piOrg[2] - piCur[2];
diff[k+3] = piOrg[3] - piCur[3];
diff[k+4] = piOrg[4] - piCur[4];
diff[k+5] = piOrg[5] - piCur[5];
diff[k+6] = piOrg[6] - piCur[6];
diff[k+7] = piOrg[7] - piCur[7];
piCur += iStrideCur;
piOrg += iStrideOrg;
}
// horizontal
for (j = 0; j < 8; ++j) {
jj = j << 3;
m2[j][0] = diff[jj ] + diff[jj+4];
m2[j][1] = diff[jj+1] + diff[jj+5];
m2[j][2] = diff[jj+2] + diff[jj+6];
m2[j][3] = diff[jj+3] + diff[jj+7];
m2[j][4] = diff[jj ] - diff[jj+4];
m2[j][5] = diff[jj+1] - diff[jj+5];
m2[j][6] = diff[jj+2] - diff[jj+6];
m2[j][7] = diff[jj+3] - diff[jj+7];
m1[j][0] = m2[j][0] + m2[j][2];
m1[j][1] = m2[j][1] + m2[j][3];
m1[j][2] = m2[j][0] - m2[j][2];
m1[j][3] = m2[j][1] - m2[j][3];
m1[j][4] = m2[j][4] + m2[j][6];
m1[j][5] = m2[j][5] + m2[j][7];
m1[j][6] = m2[j][4] - m2[j][6];
m1[j][7] = m2[j][5] - m2[j][7];
m2[j][0] = m1[j][0] + m1[j][1];
m2[j][1] = m1[j][0] - m1[j][1];
m2[j][2] = m1[j][2] + m1[j][3];
m2[j][3] = m1[j][2] - m1[j][3];
m2[j][4] = m1[j][4] + m1[j][5];
m2[j][5] = m1[j][4] - m1[j][5];
m2[j][6] = m1[j][6] + m1[j][7];
m2[j][7] = m1[j][6] - m1[j][7];
}
// vertical
for (i = 0; i < 8; ++i) {
m3[0][i] = m2[0][i] + m2[4][i];
m3[1][i] = m2[1][i] + m2[5][i];
m3[2][i] = m2[2][i] + m2[6][i];
m3[3][i] = m2[3][i] + m2[7][i];
m3[4][i] = m2[0][i] - m2[4][i];
m3[5][i] = m2[1][i] - m2[5][i];
m3[6][i] = m2[2][i] - m2[6][i];
m3[7][i] = m2[3][i] - m2[7][i];
m1[0][i] = m3[0][i] + m3[2][i];
m1[1][i] = m3[1][i] + m3[3][i];
m1[2][i] = m3[0][i] - m3[2][i];
m1[3][i] = m3[1][i] - m3[3][i];
m1[4][i] = m3[4][i] + m3[6][i];
m1[5][i] = m3[5][i] + m3[7][i];
m1[6][i] = m3[4][i] - m3[6][i];
m1[7][i] = m3[5][i] - m3[7][i];
m2[0][i] = m1[0][i] + m1[1][i];
m2[1][i] = m1[0][i] - m1[1][i];
m2[2][i] = m1[2][i] + m1[3][i];
m2[3][i] = m1[2][i] - m1[3][i];
m2[4][i] = m1[4][i] + m1[5][i];
m2[5][i] = m1[4][i] - m1[5][i];
m2[6][i] = m1[6][i] + m1[7][i];
m2[7][i] = m1[6][i] - m1[7][i];
}
for (i = 0; i < 64; ++i) {
sad += abs(((int*)m2)[i]);
}
sad = (sad + 2) >> 2;
return sad;
}
// Function macro for defining hadamard calculating functions
// for fixed size blocks. They calculate hadamard for integer
// multiples of 8x8 with the 8x8 hadamard function.
#define SATD_NXN(n, pixel_type, suffix) \
static unsigned satd_ ## suffix ## _ ## n ## x ## n( \
const pixel_type * const block1, const pixel_type * const block2) \
{ \
unsigned x, y; \
unsigned sum = 0; \
for (y = 0; y < (n); y += 8) { \
unsigned row = y * (n); \
for (x = 0; x < (n); x += 8) { \
sum += satd_16bit_8x8_general(&block1[row + x], (n), &block2[row + x], (n)); \
} \
} \
return sum; \
}
// These macros define sadt_16bit_NxN for N = 8, 16, 32, 64
SATD_NXN(8, pixel, 16bit)
SATD_NXN(16, pixel, 16bit)
SATD_NXN(32, pixel, 16bit)
SATD_NXN(64, pixel, 16bit)
// Function macro for defining SAD calculating functions
// for fixed size blocks.
#define SAD_NXN(n, pixel_type, suffix) \
static unsigned sad_ ## suffix ## _ ## n ## x ## n( \
const pixel_type * const block1, const pixel_type * const block2) \
{ \
unsigned i; \
unsigned sum = 0; \
for (i = 0; i < (n)*(n); ++i) { \
sum += abs(block1[i] - block2[i]); \
} \
return sum; \
}
// These macros define sad_16bit_nxn functions for n = 4, 8, 16, 32, 64
// with function signatures of cost_16bit_nxn_func.
// They are used through get_sad_16bit_nxn_func.
SAD_NXN(4, pixel, 16bit)
SAD_NXN(8, pixel, 16bit)
SAD_NXN(16, pixel, 16bit)
SAD_NXN(32, pixel, 16bit)
SAD_NXN(64, pixel, 16bit)
/**
* \brief Get a function that calculates SATD for NxN block.
*
* \param n Width of the region for which SATD is calculated.
*
* \returns Pointer to cost_16bit_nxn_func.
*/
cost_16bit_nxn_func get_satd_16bit_nxn_func(unsigned n)
{
switch (n) {
case 4:
return &satd_16bit_4x4;
case 8:
return &satd_16bit_8x8;
case 16:
return &satd_16bit_16x16;
case 32:
return &satd_16bit_32x32;
case 64:
return &satd_16bit_64x64;
default:
return NULL;
}
}
/**
* \brief Get a function that calculates SAD for NxN block.
*
* \param n Width of the region for which SAD is calculated.
*
* \returns Pointer to cost_16bit_nxn_func.
*/
cost_16bit_nxn_func get_sad_16bit_nxn_func(unsigned n)
{
switch (n) {
case 4:
return &sad_16bit_4x4;
case 8:
return &sad_16bit_8x8;
case 16:
return &sad_16bit_16x16;
case 32:
return &sad_16bit_32x32;
case 64:
return &sad_16bit_64x64;
default:
return NULL;
}
}
unsigned pixels_calc_ssd(const pixel *const ref, const pixel *const rec,
const int ref_stride, const int rec_stride,
const int width)
{
int ssd = 0;
int y, x;
for (y = 0; y < width; ++y) {
for (x = 0; x < width; ++x) {
int diff = ref[x + y * ref_stride] - rec[x + y * rec_stride];
ssd += diff * diff;
}
}
return ssd;
}
/**
* \brief BLock Image Transfer from one buffer to another.
*
* It's a stupidly simple loop that copies pixels.
*
* \param orig Start of the originating buffer.
* \param dst Start of the destination buffer.
* \param width Width of the copied region.
* \param height Height of the copied region.
* \param orig_stride Width of a row in the originating buffer.
* \param dst_stride Width of a row in the destination buffer.
*
* This should be inlined, but it's defined here for now to see if Visual
* Studios LTCG will inline it.
*/
void pixels_blit(const pixel * const orig, pixel * const dst,
const unsigned width, const unsigned height,
const unsigned orig_stride, const unsigned dst_stride)
{
unsigned y;
//There is absolutely no reason to have a width greater than the source or the destination stride.
assert(width <= orig_stride);
assert(width <= dst_stride);
for (y = 0; y < height; ++y) {
memcpy(&dst[y*dst_stride], &orig[y*orig_stride], width * sizeof(pixel));
}
}