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aomedia / aom / 365e644a71b4cfa26c / . / av1 / common / restoration.c
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/*
* 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.
*
*/
#include <math.h>
#include "./aom_config.h"
#include "./aom_dsp_rtcd.h"
#include "./aom_scale_rtcd.h"
#include "av1/common/onyxc_int.h"
#include "av1/common/restoration.h"
#include "aom_dsp/aom_dsp_common.h"
#include "aom_mem/aom_mem.h"
#include "aom_ports/mem.h"
const sgr_params_type sgr_params[SGRPROJ_PARAMS] = {
#if USE_HIGHPASS_IN_SGRPROJ
// corner, edge, r2, eps2
{ -1, 2, 1, 1 }, { -1, 2, 1, 2 }, { -1, 2, 1, 3 }, { -1, 2, 1, 4 },
{ -1, 2, 1, 5 }, { -2, 3, 1, 2 }, { -2, 3, 1, 3 }, { -2, 3, 1, 4 },
{ -2, 3, 1, 5 }, { -2, 3, 1, 6 }, { -3, 4, 1, 3 }, { -3, 4, 1, 4 },
{ -3, 4, 1, 5 }, { -3, 4, 1, 6 }, { -3, 4, 1, 7 }, { -3, 4, 1, 8 }
#else
// r1, eps1, r2, eps2
#if MAX_RADIUS == 2
{ 2, 12, 1, 4 }, { 2, 15, 1, 6 }, { 2, 18, 1, 8 }, { 2, 20, 1, 9 },
{ 2, 22, 1, 10 }, { 2, 25, 1, 11 }, { 2, 35, 1, 12 }, { 2, 45, 1, 13 },
{ 2, 55, 1, 14 }, { 2, 65, 1, 15 }, { 2, 75, 1, 16 }, { 2, 30, 1, 6 },
{ 2, 50, 1, 12 }, { 2, 60, 1, 13 }, { 2, 70, 1, 14 }, { 2, 80, 1, 15 },
#else
{ 2, 12, 1, 4 }, { 2, 15, 1, 6 }, { 2, 18, 1, 8 }, { 2, 20, 1, 9 },
{ 2, 22, 1, 10 }, { 2, 25, 1, 11 }, { 2, 35, 1, 12 }, { 2, 45, 1, 13 },
{ 2, 55, 1, 14 }, { 2, 65, 1, 15 }, { 2, 75, 1, 16 }, { 3, 30, 1, 10 },
{ 3, 50, 1, 12 }, { 3, 50, 2, 25 }, { 3, 60, 2, 35 }, { 3, 70, 2, 45 },
#endif // MAX_RADIUS == 2
#endif
};
typedef void (*restore_func_type)(uint8_t *data8, int width, int height,
int stride, RestorationInternal *rst,
uint8_t *dst8, int dst_stride);
#if CONFIG_HIGHBITDEPTH
typedef void (*restore_func_highbd_type)(uint8_t *data8, int width, int height,
int stride, RestorationInternal *rst,
int bit_depth, uint8_t *dst8,
int dst_stride);
#endif // CONFIG_HIGHBITDEPTH
int av1_alloc_restoration_struct(AV1_COMMON *cm, RestorationInfo *rst_info,
int width, int height) {
const int ntiles = av1_get_rest_ntiles(
width, height, rst_info->restoration_tilesize, NULL, NULL, NULL, NULL);
aom_free(rst_info->restoration_type);
CHECK_MEM_ERROR(cm, rst_info->restoration_type,
(RestorationType *)aom_malloc(
sizeof(*rst_info->restoration_type) * ntiles));
aom_free(rst_info->wiener_info);
CHECK_MEM_ERROR(
cm, rst_info->wiener_info,
(WienerInfo *)aom_memalign(16, sizeof(*rst_info->wiener_info) * ntiles));
memset(rst_info->wiener_info, 0, sizeof(*rst_info->wiener_info) * ntiles);
aom_free(rst_info->sgrproj_info);
CHECK_MEM_ERROR(
cm, rst_info->sgrproj_info,
(SgrprojInfo *)aom_malloc(sizeof(*rst_info->sgrproj_info) * ntiles));
return ntiles;
}
void av1_free_restoration_struct(RestorationInfo *rst_info) {
aom_free(rst_info->restoration_type);
rst_info->restoration_type = NULL;
aom_free(rst_info->wiener_info);
rst_info->wiener_info = NULL;
aom_free(rst_info->sgrproj_info);
rst_info->sgrproj_info = NULL;
}
// TODO(debargha): This table can be substantially reduced since only a few
// values are actually used.
int sgrproj_mtable[MAX_EPS][MAX_NELEM];
static void GenSgrprojVtable() {
int e, n;
for (e = 1; e <= MAX_EPS; ++e)
for (n = 1; n <= MAX_NELEM; ++n) {
const int n2e = n * n * e;
sgrproj_mtable[e - 1][n - 1] =
(((1 << SGRPROJ_MTABLE_BITS) + n2e / 2) / n2e);
}
}
void av1_loop_restoration_precal() { GenSgrprojVtable(); }
static void loop_restoration_init(RestorationInternal *rst, int kf) {
rst->keyframe = kf;
}
void extend_frame(uint8_t *data, int width, int height, int stride,
int border_horz, int border_vert) {
uint8_t *data_p;
int i;
for (i = 0; i < height; ++i) {
data_p = data + i * stride;
memset(data_p - border_horz, data_p[0], border_horz);
memset(data_p + width, data_p[width - 1], border_horz);
}
data_p = data - border_horz;
for (i = -border_vert; i < 0; ++i) {
memcpy(data_p + i * stride, data_p, width + 2 * border_horz);
}
for (i = height; i < height + border_vert; ++i) {
memcpy(data_p + i * stride, data_p + (height - 1) * stride,
width + 2 * border_horz);
}
}
#if CONFIG_STRIPED_LOOP_RESTORATION
// This function setup a processing stripe by replacing the vertical
// stripe boundary (2 lines above and 2 lines below) by data coming
// from the above/below buffers. Before doing so the original
// frame data is saved into a temporary buffer, such that it
// can be restored by the restore_processing_stripe_boundary
// function after the filtering of the processing stripe.
// Returns the height of the processing stripe
static int setup_processing_stripe_boundary(int y0, int v_end, int h_start,
int h_end, uint8_t *data,
int stride,
RestorationInternal *rst,
int use_highbd) {
int y, y_stripe_topmost, stripe_index, i;
int tile_offset = RESTORATION_TILE_OFFSET >> rst->subsampling_y;
int stripe_height = rst->rsi->procunit_height;
int comp = rst->component;
uint8_t *boundary_above_buf = rst->stripe_boundary_above[comp];
uint8_t *boundary_below_buf = rst->stripe_boundary_below[comp];
int boundary_stride = rst->stripe_boundary_stride[comp];
int x0 = h_start - RESTORATION_EXTRA_HORZ;
int x1 = h_end + RESTORATION_EXTRA_HORZ;
stripe_index = (y0 + tile_offset) / stripe_height;
y_stripe_topmost = stripe_index * stripe_height - tile_offset;
boundary_above_buf +=
((stripe_index - 1) * 2 * boundary_stride + RESTORATION_EXTRA_HORZ)
<< use_highbd;
boundary_below_buf +=
(stripe_index * 2 * boundary_stride + RESTORATION_EXTRA_HORZ)
<< use_highbd;
// setup the 2 lines above the stripe
for (i = 0; i < 2; i++) {
y = y_stripe_topmost - 2 + i;
if (y >= 0 && y < y0 && y >= y0 - 2) {
uint8_t *p = data + ((y * stride + x0) << use_highbd);
uint8_t *new_data =
boundary_above_buf + ((i * boundary_stride + x0) << use_highbd);
// printf("above %3d %3d: %08x %08x : %08x %08x\n", y, x0,
// ((uint32_t*)p)[0], ((uint32_t*)p)[1], ((uint32_t*)new_data)[0],
// ((uint32_t*)new_data)[1]);
// Save old pixels
memcpy(rst->tmp_save_above[i], p, (x1 - x0) << use_highbd);
// Replace width pixels from boundary_above_buf
memcpy(p, new_data, (x1 - x0) << use_highbd);
}
}
// setup the 2 lines below the stripe
for (i = 0; i < 2; i++) {
y = y_stripe_topmost + stripe_height + i;
if (y < v_end + 2) {
uint8_t *p = data + ((y * stride + x0) << use_highbd);
uint8_t *new_data =
boundary_below_buf + ((i * boundary_stride + x0) << use_highbd);
// printf("below %3d %3d: %08x %08x : %08x %08x\n", y, x0,
// ((uint32_t*)p)[0], ((uint32_t*)p)[1], ((uint32_t*)new_data)[0],
// ((uint32_t*)new_data)[1]);
// Save old pixels
memcpy(rst->tmp_save_below[i], p, (x1 - x0) << use_highbd);
// Replace width pixels from boundary_below_buf
memcpy(p, new_data, (x1 - x0) << use_highbd);
}
}
// Return actual stripe height
return AOMMIN(v_end, y_stripe_topmost + stripe_height) - y0;
}
// This function restores the boundary lines modified by
// setup_processing_stripe_boundary.
static void restore_processing_stripe_boundary(int y0, int v_end, int h_start,
int h_end, uint8_t *data,
int stride,
RestorationInternal *rst,
int use_highbd) {
int y, y_stripe_topmost, i, stripe_index;
int tile_offset = 8 >> rst->subsampling_y;
int stripe_height = rst->rsi->procunit_height;
int x0 = h_start - RESTORATION_EXTRA_HORZ;
int x1 = h_end + RESTORATION_EXTRA_HORZ;
stripe_index = (y0 + tile_offset) / stripe_height;
y_stripe_topmost = stripe_index * stripe_height - tile_offset;
// restore the 2 lines above the stripe
for (i = 0; i < 2; i++) {
y = y_stripe_topmost - 2 + i;
if (y >= 0 && y < y0 && y >= y0 - 2) {
uint8_t *p = data + ((y * stride + x0) << use_highbd);
memcpy(p, rst->tmp_save_above[i], (x1 - x0) << use_highbd);
}
}
// restore the 2 lines below the stripe
for (i = 0; i < 2; i++) {
y = y_stripe_topmost + stripe_height + i;
if (y < v_end + 2) {
uint8_t *p = data + ((y * stride + x0) << use_highbd);
memcpy(p, rst->tmp_save_below[i], (x1 - x0) << use_highbd);
}
}
}
#endif
static void loop_copy_tile(uint8_t *data, int tile_idx, int width, int height,
int stride, RestorationInternal *rst, uint8_t *dst,
int dst_stride) {
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
for (int i = limits.v_start; i < limits.v_end; ++i)
memcpy(dst + i * dst_stride + limits.h_start,
data + i * stride + limits.h_start, limits.h_end - limits.h_start);
}
static void stepdown_wiener_kernel(const InterpKernel orig, InterpKernel vert,
int boundary_dist, int istop) {
memcpy(vert, orig, sizeof(InterpKernel));
switch (boundary_dist) {
case 0:
vert[WIENER_HALFWIN] += vert[2] + vert[1] + vert[0];
vert[2] = vert[1] = vert[0] = 0;
break;
case 1:
vert[2] += vert[1] + vert[0];
vert[1] = vert[0] = 0;
break;
case 2:
vert[1] += vert[0];
vert[0] = 0;
break;
default: break;
}
if (!istop) {
int tmp;
tmp = vert[0];
vert[0] = vert[WIENER_WIN - 1];
vert[WIENER_WIN - 1] = tmp;
tmp = vert[1];
vert[1] = vert[WIENER_WIN - 2];
vert[WIENER_WIN - 2] = tmp;
tmp = vert[2];
vert[2] = vert[WIENER_WIN - 3];
vert[WIENER_WIN - 3] = tmp;
}
}
static void loop_wiener_filter_tile(uint8_t *data, int tile_idx, int width,
int height, int stride,
RestorationInternal *rst, uint8_t *dst,
int dst_stride) {
const int procunit_width = rst->rsi->procunit_width;
#if CONFIG_STRIPED_LOOP_RESTORATION
int procunit_height;
#else
const int procunit_height = rst->rsi->procunit_height;
#endif
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile(data, tile_idx, width, height, stride, rst, dst, dst_stride);
return;
}
InterpKernel vertical_topbot;
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
// Convolve the whole tile (done in blocks here to match the requirements
// of the vectorized convolve functions, but the result is equivalent)
for (int i = limits.v_start; i < limits.v_end; i += procunit_height) {
#if CONFIG_STRIPED_LOOP_RESTORATION
int h = setup_processing_stripe_boundary(
i, limits.v_end, limits.h_start, limits.h_end, data, stride, rst, 0);
h = ALIGN_POWER_OF_TWO(h, 1);
procunit_height = h;
#else
int h = AOMMIN(procunit_height, (limits.v_end - i + 15) & ~15);
#endif
for (int j = limits.h_start; j < limits.h_end; j += procunit_width) {
int w = AOMMIN(procunit_width, (limits.h_end - j + 15) & ~15);
const uint8_t *data_p = data + i * stride + j;
uint8_t *dst_p = dst + i * dst_stride + j;
// Note h is at least 16
for (int b = 0; b < WIENER_HALFWIN - WIENER_BORDER_VERT; ++b) {
stepdown_wiener_kernel(rst->rsi->wiener_info[tile_idx].vfilter,
vertical_topbot, WIENER_BORDER_VERT + b, 1);
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_convolve8_add_src_hip(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1);
#else
aom_convolve8_add_src(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride;
dst_p += dst_stride;
}
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_convolve8_add_src_hip(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
rst->rsi->wiener_info[tile_idx].vfilter, 16, w,
h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
#else
aom_convolve8_add_src(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
rst->rsi->wiener_info[tile_idx].vfilter, 16, w,
h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride * (h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
dst_p += dst_stride * (h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
for (int b = WIENER_HALFWIN - WIENER_BORDER_VERT - 1; b >= 0; --b) {
stepdown_wiener_kernel(rst->rsi->wiener_info[tile_idx].vfilter,
vertical_topbot, WIENER_BORDER_VERT + b, 0);
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_convolve8_add_src_hip(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1);
#else
aom_convolve8_add_src(data_p, stride, dst_p, dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride;
dst_p += dst_stride;
}
}
#if CONFIG_STRIPED_LOOP_RESTORATION
restore_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, data, stride, rst, 0);
#endif
}
}
static void loop_wiener_filter(uint8_t *data, int width, int height, int stride,
RestorationInternal *rst, uint8_t *dst,
int dst_stride) {
int tile_idx;
extend_frame(data, width, height, stride, WIENER_BORDER_HORZ,
WIENER_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
loop_wiener_filter_tile(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
}
}
/* Calculate windowed sums (if sqr=0) or sums of squares (if sqr=1)
over the input. The window is of size (2r + 1)x(2r + 1), and we
specialize to r = 1, 2, 3. A default function is used for r > 3.
Each loop follows the same format: We keep a window's worth of input
in individual variables and select data out of that as appropriate.
*/
static void boxsum1(int32_t *src, int width, int height, int src_stride,
int sqr, int32_t *dst, int dst_stride) {
int i, j, a, b, c;
// Vertical sum over 3-pixel regions, from src into dst.
if (!sqr) {
for (j = 0; j < width; ++j) {
a = src[j];
b = src[src_stride + j];
c = src[2 * src_stride + j];
dst[j] = a + b;
for (i = 1; i < height - 2; ++i) {
// Loop invariant: At the start of each iteration,
// a = src[(i - 1) * src_stride + j]
// b = src[(i ) * src_stride + j]
// c = src[(i + 1) * src_stride + j]
dst[i * dst_stride + j] = a + b + c;
a = b;
b = c;
c = src[(i + 2) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c;
dst[(i + 1) * dst_stride + j] = b + c;
}
} else {
for (j = 0; j < width; ++j) {
a = src[j] * src[j];
b = src[src_stride + j] * src[src_stride + j];
c = src[2 * src_stride + j] * src[2 * src_stride + j];
dst[j] = a + b;
for (i = 1; i < height - 2; ++i) {
dst[i * dst_stride + j] = a + b + c;
a = b;
b = c;
c = src[(i + 2) * src_stride + j] * src[(i + 2) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c;
dst[(i + 1) * dst_stride + j] = b + c;
}
}
// Horizontal sum over 3-pixel regions of dst
for (i = 0; i < height; ++i) {
a = dst[i * dst_stride];
b = dst[i * dst_stride + 1];
c = dst[i * dst_stride + 2];
dst[i * dst_stride] = a + b;
for (j = 1; j < width - 2; ++j) {
// Loop invariant: At the start of each iteration,
// a = src[i * src_stride + (j - 1)]
// b = src[i * src_stride + (j )]
// c = src[i * src_stride + (j + 1)]
dst[i * dst_stride + j] = a + b + c;
a = b;
b = c;
c = dst[i * dst_stride + (j + 2)];
}
dst[i * dst_stride + j] = a + b + c;
dst[i * dst_stride + (j + 1)] = b + c;
}
}
static void boxsum2(int32_t *src, int width, int height, int src_stride,
int sqr, int32_t *dst, int dst_stride) {
int i, j, a, b, c, d, e;
// Vertical sum over 5-pixel regions, from src into dst.
if (!sqr) {
for (j = 0; j < width; ++j) {
a = src[j];
b = src[src_stride + j];
c = src[2 * src_stride + j];
d = src[3 * src_stride + j];
e = src[4 * src_stride + j];
dst[j] = a + b + c;
dst[dst_stride + j] = a + b + c + d;
for (i = 2; i < height - 3; ++i) {
// Loop invariant: At the start of each iteration,
// a = src[(i - 2) * src_stride + j]
// b = src[(i - 1) * src_stride + j]
// c = src[(i ) * src_stride + j]
// d = src[(i + 1) * src_stride + j]
// e = src[(i + 2) * src_stride + j]
dst[i * dst_stride + j] = a + b + c + d + e;
a = b;
b = c;
c = d;
d = e;
e = src[(i + 3) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c + d + e;
dst[(i + 1) * dst_stride + j] = b + c + d + e;
dst[(i + 2) * dst_stride + j] = c + d + e;
}
} else {
for (j = 0; j < width; ++j) {
a = src[j] * src[j];
b = src[src_stride + j] * src[src_stride + j];
c = src[2 * src_stride + j] * src[2 * src_stride + j];
d = src[3 * src_stride + j] * src[3 * src_stride + j];
e = src[4 * src_stride + j] * src[4 * src_stride + j];
dst[j] = a + b + c;
dst[dst_stride + j] = a + b + c + d;
for (i = 2; i < height - 3; ++i) {
dst[i * dst_stride + j] = a + b + c + d + e;
a = b;
b = c;
c = d;
d = e;
e = src[(i + 3) * src_stride + j] * src[(i + 3) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c + d + e;
dst[(i + 1) * dst_stride + j] = b + c + d + e;
dst[(i + 2) * dst_stride + j] = c + d + e;
}
}
// Horizontal sum over 5-pixel regions of dst
for (i = 0; i < height; ++i) {
a = dst[i * dst_stride];
b = dst[i * dst_stride + 1];
c = dst[i * dst_stride + 2];
d = dst[i * dst_stride + 3];
e = dst[i * dst_stride + 4];
dst[i * dst_stride] = a + b + c;
dst[i * dst_stride + 1] = a + b + c + d;
for (j = 2; j < width - 3; ++j) {
// Loop invariant: At the start of each iteration,
// a = src[i * src_stride + (j - 2)]
// b = src[i * src_stride + (j - 1)]
// c = src[i * src_stride + (j )]
// d = src[i * src_stride + (j + 1)]
// e = src[i * src_stride + (j + 2)]
dst[i * dst_stride + j] = a + b + c + d + e;
a = b;
b = c;
c = d;
d = e;
e = dst[i * dst_stride + (j + 3)];
}
dst[i * dst_stride + j] = a + b + c + d + e;
dst[i * dst_stride + (j + 1)] = b + c + d + e;
dst[i * dst_stride + (j + 2)] = c + d + e;
}
}
static void boxsum3(int32_t *src, int width, int height, int src_stride,
int sqr, int32_t *dst, int dst_stride) {
int i, j, a, b, c, d, e, f, g;
// Vertical sum over 7-pixel regions, from src into dst.
if (!sqr) {
for (j = 0; j < width; ++j) {
a = src[j];
b = src[1 * src_stride + j];
c = src[2 * src_stride + j];
d = src[3 * src_stride + j];
e = src[4 * src_stride + j];
f = src[5 * src_stride + j];
g = src[6 * src_stride + j];
dst[j] = a + b + c + d;
dst[dst_stride + j] = a + b + c + d + e;
dst[2 * dst_stride + j] = a + b + c + d + e + f;
for (i = 3; i < height - 4; ++i) {
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
a = b;
b = c;
c = d;
d = e;
e = f;
f = g;
g = src[(i + 4) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
dst[(i + 1) * dst_stride + j] = b + c + d + e + f + g;
dst[(i + 2) * dst_stride + j] = c + d + e + f + g;
dst[(i + 3) * dst_stride + j] = d + e + f + g;
}
} else {
for (j = 0; j < width; ++j) {
a = src[j] * src[j];
b = src[1 * src_stride + j] * src[1 * src_stride + j];
c = src[2 * src_stride + j] * src[2 * src_stride + j];
d = src[3 * src_stride + j] * src[3 * src_stride + j];
e = src[4 * src_stride + j] * src[4 * src_stride + j];
f = src[5 * src_stride + j] * src[5 * src_stride + j];
g = src[6 * src_stride + j] * src[6 * src_stride + j];
dst[j] = a + b + c + d;
dst[dst_stride + j] = a + b + c + d + e;
dst[2 * dst_stride + j] = a + b + c + d + e + f;
for (i = 3; i < height - 4; ++i) {
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
a = b;
b = c;
c = d;
d = e;
e = f;
f = g;
g = src[(i + 4) * src_stride + j] * src[(i + 4) * src_stride + j];
}
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
dst[(i + 1) * dst_stride + j] = b + c + d + e + f + g;
dst[(i + 2) * dst_stride + j] = c + d + e + f + g;
dst[(i + 3) * dst_stride + j] = d + e + f + g;
}
}
// Horizontal sum over 7-pixel regions of dst
for (i = 0; i < height; ++i) {
a = dst[i * dst_stride];
b = dst[i * dst_stride + 1];
c = dst[i * dst_stride + 2];
d = dst[i * dst_stride + 3];
e = dst[i * dst_stride + 4];
f = dst[i * dst_stride + 5];
g = dst[i * dst_stride + 6];
dst[i * dst_stride] = a + b + c + d;
dst[i * dst_stride + 1] = a + b + c + d + e;
dst[i * dst_stride + 2] = a + b + c + d + e + f;
for (j = 3; j < width - 4; ++j) {
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
a = b;
b = c;
c = d;
d = e;
e = f;
f = g;
g = dst[i * dst_stride + (j + 4)];
}
dst[i * dst_stride + j] = a + b + c + d + e + f + g;
dst[i * dst_stride + (j + 1)] = b + c + d + e + f + g;
dst[i * dst_stride + (j + 2)] = c + d + e + f + g;
dst[i * dst_stride + (j + 3)] = d + e + f + g;
}
}
// Generic version for any r. To be removed after experiments are done.
static void boxsumr(int32_t *src, int width, int height, int src_stride, int r,
int sqr, int32_t *dst, int dst_stride) {
int32_t *tmp = aom_malloc(width * height * sizeof(*tmp));
int tmp_stride = width;
int i, j;
if (sqr) {
for (j = 0; j < width; ++j) tmp[j] = src[j] * src[j];
for (j = 0; j < width; ++j)
for (i = 1; i < height; ++i)
tmp[i * tmp_stride + j] =
tmp[(i - 1) * tmp_stride + j] +
src[i * src_stride + j] * src[i * src_stride + j];
} else {
memcpy(tmp, src, sizeof(*tmp) * width);
for (j = 0; j < width; ++j)
for (i = 1; i < height; ++i)
tmp[i * tmp_stride + j] =
tmp[(i - 1) * tmp_stride + j] + src[i * src_stride + j];
}
for (i = 0; i <= r; ++i)
memcpy(&dst[i * dst_stride], &tmp[(i + r) * tmp_stride],
sizeof(*tmp) * width);
for (i = r + 1; i < height - r; ++i)
for (j = 0; j < width; ++j)
dst[i * dst_stride + j] =
tmp[(i + r) * tmp_stride + j] - tmp[(i - r - 1) * tmp_stride + j];
for (i = height - r; i < height; ++i)
for (j = 0; j < width; ++j)
dst[i * dst_stride + j] = tmp[(height - 1) * tmp_stride + j] -
tmp[(i - r - 1) * tmp_stride + j];
for (i = 0; i < height; ++i) tmp[i * tmp_stride] = dst[i * dst_stride];
for (i = 0; i < height; ++i)
for (j = 1; j < width; ++j)
tmp[i * tmp_stride + j] =
tmp[i * tmp_stride + j - 1] + dst[i * src_stride + j];
for (j = 0; j <= r; ++j)
for (i = 0; i < height; ++i)
dst[i * dst_stride + j] = tmp[i * tmp_stride + j + r];
for (j = r + 1; j < width - r; ++j)
for (i = 0; i < height; ++i)
dst[i * dst_stride + j] =
tmp[i * tmp_stride + j + r] - tmp[i * tmp_stride + j - r - 1];
for (j = width - r; j < width; ++j)
for (i = 0; i < height; ++i)
dst[i * dst_stride + j] =
tmp[i * tmp_stride + width - 1] - tmp[i * tmp_stride + j - r - 1];
aom_free(tmp);
}
static void boxsum(int32_t *src, int width, int height, int src_stride, int r,
int sqr, int32_t *dst, int dst_stride) {
if (r == 1)
boxsum1(src, width, height, src_stride, sqr, dst, dst_stride);
else if (r == 2)
boxsum2(src, width, height, src_stride, sqr, dst, dst_stride);
else if (r == 3)
boxsum3(src, width, height, src_stride, sqr, dst, dst_stride);
else
boxsumr(src, width, height, src_stride, r, sqr, dst, dst_stride);
}
static void boxnum(int width, int height, int r, int8_t *num, int num_stride) {
int i, j;
for (i = 0; i <= r; ++i) {
for (j = 0; j <= r; ++j) {
num[i * num_stride + j] = (r + 1 + i) * (r + 1 + j);
num[i * num_stride + (width - 1 - j)] = num[i * num_stride + j];
num[(height - 1 - i) * num_stride + j] = num[i * num_stride + j];
num[(height - 1 - i) * num_stride + (width - 1 - j)] =
num[i * num_stride + j];
}
}
for (j = 0; j <= r; ++j) {
const int val = (2 * r + 1) * (r + 1 + j);
for (i = r + 1; i < height - r; ++i) {
num[i * num_stride + j] = val;
num[i * num_stride + (width - 1 - j)] = val;
}
}
for (i = 0; i <= r; ++i) {
const int val = (2 * r + 1) * (r + 1 + i);
for (j = r + 1; j < width - r; ++j) {
num[i * num_stride + j] = val;
num[(height - 1 - i) * num_stride + j] = val;
}
}
for (i = r + 1; i < height - r; ++i) {
for (j = r + 1; j < width - r; ++j) {
num[i * num_stride + j] = (2 * r + 1) * (2 * r + 1);
}
}
}
void decode_xq(int *xqd, int *xq) {
xq[0] = xqd[0];
xq[1] = (1 << SGRPROJ_PRJ_BITS) - xq[0] - xqd[1];
}
const int32_t x_by_xplus1[256] = {
0, 128, 171, 192, 205, 213, 219, 224, 228, 230, 233, 235, 236, 238, 239,
240, 241, 242, 243, 243, 244, 244, 245, 245, 246, 246, 247, 247, 247, 247,
248, 248, 248, 248, 249, 249, 249, 249, 249, 250, 250, 250, 250, 250, 250,
250, 251, 251, 251, 251, 251, 251, 251, 251, 251, 251, 252, 252, 252, 252,
252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 252, 253, 253,
253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253,
253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 253, 254, 254, 254,
254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254, 254,
254, 254, 254, 254, 254, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255,
256,
};
const int32_t one_by_x[MAX_NELEM] = {
4096, 2048, 1365, 1024, 819, 683, 585, 512, 455, 410, 372, 341, 315,
293, 273, 256, 241, 228, 216, 205, 195, 186, 178, 171, 164,
#if MAX_RADIUS > 2
158, 152, 146, 141, 137, 132, 128, 124, 120, 117, 114, 111, 108,
105, 102, 100, 98, 95, 93, 91, 89, 87, 85, 84
#endif // MAX_RADIUS > 2
};
static void av1_selfguided_restoration_internal(int32_t *dgd, int width,
int height, int dgd_stride,
int32_t *dst, int dst_stride,
int bit_depth, int r, int eps) {
const int width_ext = width + 2 * SGRPROJ_BORDER_HORZ;
const int height_ext = height + 2 * SGRPROJ_BORDER_VERT;
const int num_stride = width_ext;
// Adjusting the stride of A and B here appears to avoid bad cache effects,
// leading to a significant speed improvement.
// We also align the stride to a multiple of 16 bytes, for consistency
// with the SIMD version of this function.
int buf_stride = ((width_ext + 3) & ~3) + 16;
int32_t A_[RESTORATION_PROC_UNIT_PELS];
int32_t B_[RESTORATION_PROC_UNIT_PELS];
int32_t *A = A_;
int32_t *B = B_;
int8_t num_[RESTORATION_PROC_UNIT_PELS];
int8_t *num = num_ + SGRPROJ_BORDER_VERT * num_stride + SGRPROJ_BORDER_HORZ;
int i, j;
// Don't filter tiles with dimensions < 5 on any axis
if ((width < 5) || (height < 5)) return;
boxsum(dgd - dgd_stride * SGRPROJ_BORDER_VERT - SGRPROJ_BORDER_HORZ,
width_ext, height_ext, dgd_stride, r, 0, B, buf_stride);
boxsum(dgd - dgd_stride * SGRPROJ_BORDER_VERT - SGRPROJ_BORDER_HORZ,
width_ext, height_ext, dgd_stride, r, 1, A, buf_stride);
boxnum(width_ext, height_ext, r, num_, num_stride);
assert(r <= 3);
A += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
B += SGRPROJ_BORDER_VERT * buf_stride + SGRPROJ_BORDER_HORZ;
for (i = 0; i < height; ++i) {
for (j = 0; j < width; ++j) {
const int k = i * buf_stride + j;
const int n = num[i * num_stride + j];
// a < 2^16 * n < 2^22 regardless of bit depth
uint32_t a = ROUND_POWER_OF_TWO(A[k], 2 * (bit_depth - 8));
// b < 2^8 * n < 2^14 regardless of bit depth
uint32_t b = ROUND_POWER_OF_TWO(B[k], bit_depth - 8);
// Each term in calculating p = a * n - b * b is < 2^16 * n^2 < 2^28,
// and p itself satisfies p < 2^14 * n^2 < 2^26.
// Note: Sometimes, in high bit depth, we can end up with a*n < b*b.
// This is an artefact of rounding, and can only happen if all pixels
// are (almost) identical, so in this case we saturate to p=0.
uint32_t p = (a * n < b * b) ? 0 : a * n - b * b;
uint32_t s = sgrproj_mtable[eps - 1][n - 1];
// p * s < (2^14 * n^2) * round(2^20 / n^2 eps) < 2^34 / eps < 2^32
// as long as eps >= 4. So p * s fits into a uint32_t, and z < 2^12
// (this holds even after accounting for the rounding in s)
const uint32_t z = ROUND_POWER_OF_TWO(p * s, SGRPROJ_MTABLE_BITS);
A[k] = x_by_xplus1[AOMMIN(z, 255)]; // < 2^8
// SGRPROJ_SGR - A[k] < 2^8, B[k] < 2^(bit_depth) * n,
// one_by_x[n - 1] = round(2^12 / n)
// => the product here is < 2^(20 + bit_depth) <= 2^32,
// and B[k] is set to a value < 2^(8 + bit depth)
B[k] = (int32_t)ROUND_POWER_OF_TWO((uint32_t)(SGRPROJ_SGR - A[k]) *
(uint32_t)B[k] *
(uint32_t)one_by_x[n - 1],
SGRPROJ_RECIP_BITS);
}
}
i = 0;
j = 0;
{
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a =
3 * A[k] + 2 * A[k + 1] + 2 * A[k + buf_stride] + A[k + buf_stride + 1];
const int32_t b =
3 * B[k] + 2 * B[k + 1] + 2 * B[k + buf_stride] + B[k + buf_stride + 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
i = 0;
j = width - 1;
{
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a =
3 * A[k] + 2 * A[k - 1] + 2 * A[k + buf_stride] + A[k + buf_stride - 1];
const int32_t b =
3 * B[k] + 2 * B[k - 1] + 2 * B[k + buf_stride] + B[k + buf_stride - 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
i = height - 1;
j = 0;
{
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a =
3 * A[k] + 2 * A[k + 1] + 2 * A[k - buf_stride] + A[k - buf_stride + 1];
const int32_t b =
3 * B[k] + 2 * B[k + 1] + 2 * B[k - buf_stride] + B[k - buf_stride + 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
i = height - 1;
j = width - 1;
{
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a =
3 * A[k] + 2 * A[k - 1] + 2 * A[k - buf_stride] + A[k - buf_stride - 1];
const int32_t b =
3 * B[k] + 2 * B[k - 1] + 2 * B[k - buf_stride] + B[k - buf_stride - 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
i = 0;
for (j = 1; j < width - 1; ++j) {
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a = A[k] + 2 * (A[k - 1] + A[k + 1]) + A[k + buf_stride] +
A[k + buf_stride - 1] + A[k + buf_stride + 1];
const int32_t b = B[k] + 2 * (B[k - 1] + B[k + 1]) + B[k + buf_stride] +
B[k + buf_stride - 1] + B[k + buf_stride + 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
i = height - 1;
for (j = 1; j < width - 1; ++j) {
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a = A[k] + 2 * (A[k - 1] + A[k + 1]) + A[k - buf_stride] +
A[k - buf_stride - 1] + A[k - buf_stride + 1];
const int32_t b = B[k] + 2 * (B[k - 1] + B[k + 1]) + B[k - buf_stride] +
B[k - buf_stride - 1] + B[k - buf_stride + 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
j = 0;
for (i = 1; i < height - 1; ++i) {
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a = A[k] + 2 * (A[k - buf_stride] + A[k + buf_stride]) +
A[k + 1] + A[k - buf_stride + 1] + A[k + buf_stride + 1];
const int32_t b = B[k] + 2 * (B[k - buf_stride] + B[k + buf_stride]) +
B[k + 1] + B[k - buf_stride + 1] + B[k + buf_stride + 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
j = width - 1;
for (i = 1; i < height - 1; ++i) {
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 3;
const int32_t a = A[k] + 2 * (A[k - buf_stride] + A[k + buf_stride]) +
A[k - 1] + A[k - buf_stride - 1] + A[k + buf_stride - 1];
const int32_t b = B[k] + 2 * (B[k - buf_stride] + B[k + buf_stride]) +
B[k - 1] + B[k - buf_stride - 1] + B[k + buf_stride - 1];
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
for (i = 1; i < height - 1; ++i) {
for (j = 1; j < width - 1; ++j) {
const int k = i * buf_stride + j;
const int l = i * dgd_stride + j;
const int m = i * dst_stride + j;
const int nb = 5;
const int32_t a =
(A[k] + A[k - 1] + A[k + 1] + A[k - buf_stride] + A[k + buf_stride]) *
4 +
(A[k - 1 - buf_stride] + A[k - 1 + buf_stride] +
A[k + 1 - buf_stride] + A[k + 1 + buf_stride]) *
3;
const int32_t b =
(B[k] + B[k - 1] + B[k + 1] + B[k - buf_stride] + B[k + buf_stride]) *
4 +
(B[k - 1 - buf_stride] + B[k - 1 + buf_stride] +
B[k + 1 - buf_stride] + B[k + 1 + buf_stride]) *
3;
const int32_t v = a * dgd[l] + b;
dst[m] = ROUND_POWER_OF_TWO(v, SGRPROJ_SGR_BITS + nb - SGRPROJ_RST_BITS);
}
}
}
void av1_selfguided_restoration_c(uint8_t *dgd, int width, int height,
int stride, int32_t *dst, int dst_stride,
int r, int eps) {
int32_t dgd32_[RESTORATION_PROC_UNIT_PELS];
const int dgd32_stride = width + 2 * SGRPROJ_BORDER_HORZ;
int32_t *dgd32 =
dgd32_ + dgd32_stride * SGRPROJ_BORDER_VERT + SGRPROJ_BORDER_HORZ;
int i, j;
for (i = -SGRPROJ_BORDER_VERT; i < height + SGRPROJ_BORDER_VERT; ++i) {
for (j = -SGRPROJ_BORDER_HORZ; j < width + SGRPROJ_BORDER_HORZ; ++j) {
dgd32[i * dgd32_stride + j] = dgd[i * stride + j];
}
}
av1_selfguided_restoration_internal(dgd32, width, height, dgd32_stride, dst,
dst_stride, 8, r, eps);
}
void av1_highpass_filter_c(uint8_t *dgd, int width, int height, int stride,
int32_t *dst, int dst_stride, int corner, int edge) {
int i, j;
const int center = (1 << SGRPROJ_RST_BITS) - 4 * (corner + edge);
i = 0;
j = 0;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k + 1] + dgd[k + stride] + dgd[k] * 2) +
corner * (dgd[k + stride + 1] + dgd[k + 1] + dgd[k + stride] + dgd[k]);
}
i = 0;
j = width - 1;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k - 1] + dgd[k + stride] + dgd[k] * 2) +
corner * (dgd[k + stride - 1] + dgd[k - 1] + dgd[k + stride] + dgd[k]);
}
i = height - 1;
j = 0;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k + 1] + dgd[k - stride] + dgd[k] * 2) +
corner * (dgd[k - stride + 1] + dgd[k + 1] + dgd[k - stride] + dgd[k]);
}
i = height - 1;
j = width - 1;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k - 1] + dgd[k - stride] + dgd[k] * 2) +
corner * (dgd[k - stride - 1] + dgd[k - 1] + dgd[k - stride] + dgd[k]);
}
i = 0;
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - 1] + dgd[k + stride] + dgd[k + 1] + dgd[k]) +
corner * (dgd[k + stride - 1] + dgd[k + stride + 1] + dgd[k - 1] +
dgd[k + 1]);
}
i = height - 1;
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - 1] + dgd[k - stride] + dgd[k + 1] + dgd[k]) +
corner * (dgd[k - stride - 1] + dgd[k - stride + 1] + dgd[k - 1] +
dgd[k + 1]);
}
j = 0;
for (i = 1; i < height - 1; ++i) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - stride] + dgd[k + 1] + dgd[k + stride] + dgd[k]) +
corner * (dgd[k + stride + 1] + dgd[k - stride + 1] +
dgd[k - stride] + dgd[k + stride]);
}
j = width - 1;
for (i = 1; i < height - 1; ++i) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - stride] + dgd[k - 1] + dgd[k + stride] + dgd[k]) +
corner * (dgd[k + stride - 1] + dgd[k - stride - 1] +
dgd[k - stride] + dgd[k + stride]);
}
for (i = 1; i < height - 1; ++i) {
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] +
edge * (dgd[k - stride] + dgd[k - 1] + dgd[k + stride] + dgd[k + 1]) +
corner * (dgd[k + stride - 1] + dgd[k - stride - 1] +
dgd[k - stride + 1] + dgd[k + stride + 1]);
}
}
}
void apply_selfguided_restoration_c(uint8_t *dat, int width, int height,
int stride, int eps, int *xqd, uint8_t *dst,
int dst_stride, int32_t *tmpbuf) {
int xq[2];
int32_t *flt1 = tmpbuf;
int32_t *flt2 = flt1 + RESTORATION_TILEPELS_MAX;
int i, j;
assert(width * height <= RESTORATION_TILEPELS_MAX);
#if USE_HIGHPASS_IN_SGRPROJ
av1_highpass_filter_c(dat, width, height, stride, flt1, width,
sgr_params[eps].corner, sgr_params[eps].edge);
#else
av1_selfguided_restoration_c(dat, width, height, stride, flt1, width,
sgr_params[eps].r1, sgr_params[eps].e1);
#endif // USE_HIGHPASS_IN_SGRPROJ
av1_selfguided_restoration_c(dat, width, height, stride, flt2, width,
sgr_params[eps].r2, sgr_params[eps].e2);
decode_xq(xqd, xq);
for (i = 0; i < height; ++i) {
for (j = 0; j < width; ++j) {
const int k = i * width + j;
const int l = i * stride + j;
const int m = i * dst_stride + j;
const int32_t u = ((int32_t)dat[l] << SGRPROJ_RST_BITS);
const int32_t f1 = (int32_t)flt1[k] - u;
const int32_t f2 = (int32_t)flt2[k] - u;
const int32_t v = xq[0] * f1 + xq[1] * f2 + (u << SGRPROJ_PRJ_BITS);
const int16_t w =
(int16_t)ROUND_POWER_OF_TWO(v, SGRPROJ_PRJ_BITS + SGRPROJ_RST_BITS);
dst[m] = clip_pixel(w);
}
}
}
static void loop_sgrproj_filter_tile(uint8_t *data, int tile_idx, int width,
int height, int stride,
RestorationInternal *rst, uint8_t *dst,
int dst_stride) {
const int procunit_width = rst->rsi->procunit_width;
#if CONFIG_STRIPED_LOOP_RESTORATION
int procunit_height;
#else
const int procunit_height = rst->rsi->procunit_height;
#endif
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile(data, tile_idx, width, height, stride, rst, dst, dst_stride);
return;
}
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
for (int i = limits.v_start; i < limits.v_end; i += procunit_height) {
#if CONFIG_STRIPED_LOOP_RESTORATION
int h = setup_processing_stripe_boundary(
i, limits.v_end, limits.h_start, limits.h_end, data, stride, rst, 0);
procunit_height = h;
#else
int h = AOMMIN(procunit_height, limits.v_end - i);
#endif
for (int j = limits.h_start; j < limits.h_end; j += procunit_width) {
int w = AOMMIN(procunit_width, limits.h_end - j);
uint8_t *data_p = data + i * stride + j;
uint8_t *dst_p = dst + i * dst_stride + j;
apply_selfguided_restoration(
data_p, w, h, stride, rst->rsi->sgrproj_info[tile_idx].ep,
rst->rsi->sgrproj_info[tile_idx].xqd, dst_p, dst_stride, rst->tmpbuf);
}
#if CONFIG_STRIPED_LOOP_RESTORATION
restore_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, data, stride, rst, 0);
#endif
}
}
static void loop_sgrproj_filter(uint8_t *data, int width, int height,
int stride, RestorationInternal *rst,
uint8_t *dst, int dst_stride) {
int tile_idx;
extend_frame(data, width, height, stride, SGRPROJ_BORDER_HORZ,
SGRPROJ_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
loop_sgrproj_filter_tile(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
}
}
static void loop_switchable_filter(uint8_t *data, int width, int height,
int stride, RestorationInternal *rst,
uint8_t *dst, int dst_stride) {
int tile_idx;
extend_frame(data, width, height, stride, RESTORATION_BORDER_HORZ,
RESTORATION_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
} else if (rst->rsi->restoration_type[tile_idx] == RESTORE_WIENER) {
loop_wiener_filter_tile(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
} else if (rst->rsi->restoration_type[tile_idx] == RESTORE_SGRPROJ) {
loop_sgrproj_filter_tile(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
}
}
}
#if CONFIG_HIGHBITDEPTH
void extend_frame_highbd(uint16_t *data, int width, int height, int stride,
int border_horz, int border_vert) {
uint16_t *data_p;
int i, j;
for (i = 0; i < height; ++i) {
data_p = data + i * stride;
for (j = -border_horz; j < 0; ++j) data_p[j] = data_p[0];
for (j = width; j < width + border_horz; ++j) data_p[j] = data_p[width - 1];
}
data_p = data - border_horz;
for (i = -border_vert; i < 0; ++i) {
memcpy(data_p + i * stride, data_p,
(width + 2 * border_horz) * sizeof(uint16_t));
}
for (i = height; i < height + border_vert; ++i) {
memcpy(data_p + i * stride, data_p + (height - 1) * stride,
(width + 2 * border_horz) * sizeof(uint16_t));
}
}
static void loop_copy_tile_highbd(uint16_t *data, int tile_idx, int width,
int height, int stride,
RestorationInternal *rst, uint16_t *dst,
int dst_stride) {
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
for (int i = limits.v_start; i < limits.v_end; ++i)
memcpy(dst + i * dst_stride + limits.h_start,
data + i * stride + limits.h_start,
(limits.h_end - limits.h_start) * sizeof(*dst));
}
static void loop_wiener_filter_tile_highbd(uint16_t *data, int tile_idx,
int width, int height, int stride,
RestorationInternal *rst,
int bit_depth, uint16_t *dst,
int dst_stride) {
const int procunit_width = rst->rsi->procunit_width;
#if CONFIG_STRIPED_LOOP_RESTORATION
int procunit_height;
#else
const int procunit_height = rst->rsi->procunit_height;
#endif
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile_highbd(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
return;
}
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
InterpKernel vertical_topbot;
// Convolve the whole tile (done in blocks here to match the requirements
// of the vectorized convolve functions, but the result is equivalent)
for (int i = limits.v_start; i < limits.v_end; i += procunit_height) {
#if CONFIG_STRIPED_LOOP_RESTORATION
int h = setup_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, (uint8_t *)data,
stride, rst, 1);
h = ALIGN_POWER_OF_TWO(h, 1);
procunit_height = h;
#else
int h = AOMMIN(procunit_height, (limits.v_end - i + 15) & ~15);
#endif
for (int j = limits.h_start; j < limits.h_end; j += procunit_width) {
int w = AOMMIN(procunit_width, (limits.h_end - j + 15) & ~15);
const uint16_t *data_p = data + i * stride + j;
uint16_t *dst_p = dst + i * dst_stride + j;
// Note h is at least 16
for (int b = 0; b < WIENER_HALFWIN - WIENER_BORDER_VERT; ++b) {
stepdown_wiener_kernel(rst->rsi->wiener_info[tile_idx].vfilter,
vertical_topbot, WIENER_BORDER_VERT + b, 1);
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_highbd_convolve8_add_src_hip(
CONVERT_TO_BYTEPTR(data_p), stride, CONVERT_TO_BYTEPTR(dst_p),
dst_stride, rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1, bit_depth);
#else
aom_highbd_convolve8_add_src(CONVERT_TO_BYTEPTR(data_p), stride,
CONVERT_TO_BYTEPTR(dst_p), dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter,
16, vertical_topbot, 16, w, 1, bit_depth);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride;
dst_p += dst_stride;
}
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_highbd_convolve8_add_src_hip(
CONVERT_TO_BYTEPTR(data_p), stride, CONVERT_TO_BYTEPTR(dst_p),
dst_stride, rst->rsi->wiener_info[tile_idx].hfilter, 16,
rst->rsi->wiener_info[tile_idx].vfilter, 16, w,
h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2, bit_depth);
#else
aom_highbd_convolve8_add_src(
CONVERT_TO_BYTEPTR(data_p), stride, CONVERT_TO_BYTEPTR(dst_p),
dst_stride, rst->rsi->wiener_info[tile_idx].hfilter, 16,
rst->rsi->wiener_info[tile_idx].vfilter, 16, w,
h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2, bit_depth);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride * (h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
dst_p += dst_stride * (h - (WIENER_HALFWIN - WIENER_BORDER_VERT) * 2);
for (int b = WIENER_HALFWIN - WIENER_BORDER_VERT - 1; b >= 0; --b) {
stepdown_wiener_kernel(rst->rsi->wiener_info[tile_idx].vfilter,
vertical_topbot, WIENER_BORDER_VERT + b, 0);
#if USE_WIENER_HIGH_INTERMEDIATE_PRECISION
aom_highbd_convolve8_add_src_hip(
CONVERT_TO_BYTEPTR(data_p), stride, CONVERT_TO_BYTEPTR(dst_p),
dst_stride, rst->rsi->wiener_info[tile_idx].hfilter, 16,
vertical_topbot, 16, w, 1, bit_depth);
#else
aom_highbd_convolve8_add_src(CONVERT_TO_BYTEPTR(data_p), stride,
CONVERT_TO_BYTEPTR(dst_p), dst_stride,
rst->rsi->wiener_info[tile_idx].hfilter,
16, vertical_topbot, 16, w, 1, bit_depth);
#endif // USE_WIENER_HIGH_INTERMEDIATE_PRECISION
data_p += stride;
dst_p += dst_stride;
}
}
#if CONFIG_STRIPED_LOOP_RESTORATION
restore_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, (uint8_t *)data, stride,
rst, 1);
#endif
}
}
static void loop_wiener_filter_highbd(uint8_t *data8, int width, int height,
int stride, RestorationInternal *rst,
int bit_depth, uint8_t *dst8,
int dst_stride) {
uint16_t *data = CONVERT_TO_SHORTPTR(data8);
uint16_t *dst = CONVERT_TO_SHORTPTR(dst8);
int tile_idx;
extend_frame_highbd(data, width, height, stride, WIENER_BORDER_HORZ,
WIENER_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
loop_wiener_filter_tile_highbd(data, tile_idx, width, height, stride, rst,
bit_depth, dst, dst_stride);
}
}
void av1_selfguided_restoration_highbd_c(uint16_t *dgd, int width, int height,
int stride, int32_t *dst,
int dst_stride, int bit_depth, int r,
int eps) {
int32_t dgd32_[RESTORATION_PROC_UNIT_PELS];
const int dgd32_stride = width + 2 * SGRPROJ_BORDER_HORZ;
int32_t *dgd32 =
dgd32_ + dgd32_stride * SGRPROJ_BORDER_VERT + SGRPROJ_BORDER_HORZ;
int i, j;
for (i = -SGRPROJ_BORDER_VERT; i < height + SGRPROJ_BORDER_VERT; ++i) {
for (j = -SGRPROJ_BORDER_HORZ; j < width + SGRPROJ_BORDER_HORZ; ++j) {
dgd32[i * dgd32_stride + j] = dgd[i * stride + j];
}
}
av1_selfguided_restoration_internal(dgd32, width, height, dgd32_stride, dst,
dst_stride, bit_depth, r, eps);
}
void av1_highpass_filter_highbd_c(uint16_t *dgd, int width, int height,
int stride, int32_t *dst, int dst_stride,
int corner, int edge) {
int i, j;
const int center = (1 << SGRPROJ_RST_BITS) - 4 * (corner + edge);
i = 0;
j = 0;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k + 1] + dgd[k + stride] + dgd[k] * 2) +
corner * (dgd[k + stride + 1] + dgd[k + 1] + dgd[k + stride] + dgd[k]);
}
i = 0;
j = width - 1;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k - 1] + dgd[k + stride] + dgd[k] * 2) +
corner * (dgd[k + stride - 1] + dgd[k - 1] + dgd[k + stride] + dgd[k]);
}
i = height - 1;
j = 0;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k + 1] + dgd[k - stride] + dgd[k] * 2) +
corner * (dgd[k - stride + 1] + dgd[k + 1] + dgd[k - stride] + dgd[k]);
}
i = height - 1;
j = width - 1;
{
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] + edge * (dgd[k - 1] + dgd[k - stride] + dgd[k] * 2) +
corner * (dgd[k - stride - 1] + dgd[k - 1] + dgd[k - stride] + dgd[k]);
}
i = 0;
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - 1] + dgd[k + stride] + dgd[k + 1] + dgd[k]) +
corner * (dgd[k + stride - 1] + dgd[k + stride + 1] + dgd[k - 1] +
dgd[k + 1]);
}
i = height - 1;
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - 1] + dgd[k - stride] + dgd[k + 1] + dgd[k]) +
corner * (dgd[k - stride - 1] + dgd[k - stride + 1] + dgd[k - 1] +
dgd[k + 1]);
}
j = 0;
for (i = 1; i < height - 1; ++i) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - stride] + dgd[k + 1] + dgd[k + stride] + dgd[k]) +
corner * (dgd[k + stride + 1] + dgd[k - stride + 1] +
dgd[k - stride] + dgd[k + stride]);
}
j = width - 1;
for (i = 1; i < height - 1; ++i) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] = center * dgd[k] +
edge * (dgd[k - stride] + dgd[k - 1] + dgd[k + stride] + dgd[k]) +
corner * (dgd[k + stride - 1] + dgd[k - stride - 1] +
dgd[k - stride] + dgd[k + stride]);
}
for (i = 1; i < height - 1; ++i) {
for (j = 1; j < width - 1; ++j) {
const int k = i * stride + j;
const int l = i * dst_stride + j;
dst[l] =
center * dgd[k] +
edge * (dgd[k - stride] + dgd[k - 1] + dgd[k + stride] + dgd[k + 1]) +
corner * (dgd[k + stride - 1] + dgd[k - stride - 1] +
dgd[k - stride + 1] + dgd[k + stride + 1]);
}
}
}
void apply_selfguided_restoration_highbd_c(uint16_t *dat, int width, int height,
int stride, int bit_depth, int eps,
int *xqd, uint16_t *dst,
int dst_stride, int32_t *tmpbuf) {
int xq[2];
int32_t *flt1 = tmpbuf;
int32_t *flt2 = flt1 + RESTORATION_TILEPELS_MAX;
int i, j;
assert(width * height <= RESTORATION_TILEPELS_MAX);
#if USE_HIGHPASS_IN_SGRPROJ
av1_highpass_filter_highbd_c(dat, width, height, stride, flt1, width,
sgr_params[eps].corner, sgr_params[eps].edge);
#else
av1_selfguided_restoration_highbd_c(dat, width, height, stride, flt1, width,
bit_depth, sgr_params[eps].r1,
sgr_params[eps].e1);
#endif // USE_HIGHPASS_IN_SGRPROJ
av1_selfguided_restoration_highbd_c(dat, width, height, stride, flt2, width,
bit_depth, sgr_params[eps].r2,
sgr_params[eps].e2);
decode_xq(xqd, xq);
for (i = 0; i < height; ++i) {
for (j = 0; j < width; ++j) {
const int k = i * width + j;
const int l = i * stride + j;
const int m = i * dst_stride + j;
const int32_t u = ((int32_t)dat[l] << SGRPROJ_RST_BITS);
const int32_t f1 = (int32_t)flt1[k] - u;
const int32_t f2 = (int32_t)flt2[k] - u;
const int32_t v = xq[0] * f1 + xq[1] * f2 + (u << SGRPROJ_PRJ_BITS);
const int16_t w =
(int16_t)ROUND_POWER_OF_TWO(v, SGRPROJ_PRJ_BITS + SGRPROJ_RST_BITS);
dst[m] = (uint16_t)clip_pixel_highbd(w, bit_depth);
}
}
}
static void loop_sgrproj_filter_tile_highbd(uint16_t *data, int tile_idx,
int width, int height, int stride,
RestorationInternal *rst,
int bit_depth, uint16_t *dst,
int dst_stride) {
const int procunit_width = rst->rsi->procunit_width;
#if CONFIG_STRIPED_LOOP_RESTORATION
int procunit_height;
#else
const int procunit_height = rst->rsi->procunit_height;
#endif
const int tile_width = rst->tile_width;
const int tile_height = rst->tile_height;
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile_highbd(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
return;
}
RestorationTileLimits limits =
av1_get_rest_tile_limits(tile_idx, rst->nhtiles, rst->nvtiles, tile_width,
#if CONFIG_STRIPED_LOOP_RESTORATION
tile_height, width, height, rst->subsampling_y);
#else
tile_height, width, height);
#endif
for (int i = limits.v_start; i < limits.v_end; i += procunit_height) {
#if CONFIG_STRIPED_LOOP_RESTORATION
int h = setup_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, (uint8_t *)data,
stride, rst, 1);
procunit_height = h;
#else
int h = AOMMIN(procunit_height, limits.v_end - i);
#endif
for (int j = limits.h_start; j < limits.h_end; j += procunit_width) {
int w = AOMMIN(procunit_width, limits.h_end - j);
uint16_t *data_p = data + i * stride + j;
uint16_t *dst_p = dst + i * dst_stride + j;
apply_selfguided_restoration_highbd(
data_p, w, h, stride, bit_depth, rst->rsi->sgrproj_info[tile_idx].ep,
rst->rsi->sgrproj_info[tile_idx].xqd, dst_p, dst_stride, rst->tmpbuf);
}
#if CONFIG_STRIPED_LOOP_RESTORATION
restore_processing_stripe_boundary(i, limits.v_end, limits.h_start,
limits.h_end, (uint8_t *)data, stride,
rst, 1);
#endif
}
}
static void loop_sgrproj_filter_highbd(uint8_t *data8, int width, int height,
int stride, RestorationInternal *rst,
int bit_depth, uint8_t *dst8,
int dst_stride) {
int tile_idx;
uint16_t *data = CONVERT_TO_SHORTPTR(data8);
uint16_t *dst = CONVERT_TO_SHORTPTR(dst8);
extend_frame_highbd(data, width, height, stride, SGRPROJ_BORDER_HORZ,
SGRPROJ_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
loop_sgrproj_filter_tile_highbd(data, tile_idx, width, height, stride, rst,
bit_depth, dst, dst_stride);
}
}
static void loop_switchable_filter_highbd(uint8_t *data8, int width, int height,
int stride, RestorationInternal *rst,
int bit_depth, uint8_t *dst8,
int dst_stride) {
uint16_t *data = CONVERT_TO_SHORTPTR(data8);
uint16_t *dst = CONVERT_TO_SHORTPTR(dst8);
int tile_idx;
extend_frame_highbd(data, width, height, stride, RESTORATION_BORDER_HORZ,
RESTORATION_BORDER_VERT);
for (tile_idx = 0; tile_idx < rst->ntiles; ++tile_idx) {
if (rst->rsi->restoration_type[tile_idx] == RESTORE_NONE) {
loop_copy_tile_highbd(data, tile_idx, width, height, stride, rst, dst,
dst_stride);
} else if (rst->rsi->restoration_type[tile_idx] == RESTORE_WIENER) {
loop_wiener_filter_tile_highbd(data, tile_idx, width, height, stride, rst,
bit_depth, dst, dst_stride);
} else if (rst->rsi->restoration_type[tile_idx] == RESTORE_SGRPROJ) {
loop_sgrproj_filter_tile_highbd(data, tile_idx, width, height, stride,
rst, bit_depth, dst, dst_stride);
}
}
}
#endif // CONFIG_HIGHBITDEPTH
static void loop_restoration_rows(YV12_BUFFER_CONFIG *frame, AV1_COMMON *cm,
int start_mi_row, int end_mi_row,
int components_pattern, RestorationInfo *rsi,
YV12_BUFFER_CONFIG *dst) {
const int ywidth = frame->y_crop_width;
const int yheight = frame->y_crop_height;
const int uvwidth = frame->uv_crop_width;
const int uvheight = frame->uv_crop_height;
const int ystride = frame->y_stride;
const int uvstride = frame->uv_stride;
const int ystart = start_mi_row << MI_SIZE_LOG2;
const int uvstart = ystart >> cm->subsampling_y;
int yend = end_mi_row << MI_SIZE_LOG2;
int uvend = yend >> cm->subsampling_y;
restore_func_type restore_funcs[RESTORE_TYPES] = {
NULL, loop_wiener_filter, loop_sgrproj_filter, loop_switchable_filter
};
#if CONFIG_HIGHBITDEPTH
restore_func_highbd_type restore_funcs_highbd[RESTORE_TYPES] = {
NULL, loop_wiener_filter_highbd, loop_sgrproj_filter_highbd,
loop_switchable_filter_highbd
};
#endif // CONFIG_HIGHBITDEPTH
restore_func_type restore_func;
#if CONFIG_HIGHBITDEPTH
restore_func_highbd_type restore_func_highbd;
#endif // CONFIG_HIGHBITDEPTH
YV12_BUFFER_CONFIG dst_;
yend = AOMMIN(yend, yheight);
uvend = AOMMIN(uvend, uvheight);
if (components_pattern == (1 << AOM_PLANE_Y)) {
// Only y
if (rsi[0].frame_restoration_type == RESTORE_NONE) {
if (dst) aom_yv12_copy_y(frame, dst);
return;
}
} else if (components_pattern == (1 << AOM_PLANE_U)) {
// Only U
if (rsi[1].frame_restoration_type == RESTORE_NONE) {
if (dst) aom_yv12_copy_u(frame, dst);
return;
}
} else if (components_pattern == (1 << AOM_PLANE_V)) {
// Only V
if (rsi[2].frame_restoration_type == RESTORE_NONE) {
if (dst) aom_yv12_copy_v(frame, dst);
return;
}
} else if (components_pattern ==
((1 << AOM_PLANE_Y) | (1 << AOM_PLANE_U) | (1 << AOM_PLANE_V))) {
// All components
if (rsi[0].frame_restoration_type == RESTORE_NONE &&
rsi[1].frame_restoration_type == RESTORE_NONE &&
rsi[2].frame_restoration_type == RESTORE_NONE) {
if (dst) aom_yv12_copy_frame(frame, dst);
return;
}
}
if (!dst) {
dst = &dst_;
memset(dst, 0, sizeof(YV12_BUFFER_CONFIG));
if (aom_realloc_frame_buffer(
dst, ywidth, yheight, cm->subsampling_x, cm->subsampling_y,
#if CONFIG_HIGHBITDEPTH
cm->use_highbitdepth,
#endif
AOM_BORDER_IN_PIXELS, cm->byte_alignment, NULL, NULL, NULL) < 0)
aom_internal_error(&cm->error, AOM_CODEC_MEM_ERROR,
"Failed to allocate restoration dst buffer");
}
if ((components_pattern >> AOM_PLANE_Y) & 1) {
if (rsi[0].frame_restoration_type != RESTORE_NONE) {
cm->rst_internal.ntiles = av1_get_rest_ntiles(
ywidth, yheight, cm->rst_info[AOM_PLANE_Y].restoration_tilesize,
&cm->rst_internal.tile_width, &cm->rst_internal.tile_height,
&cm->rst_internal.nhtiles, &cm->rst_internal.nvtiles);
cm->rst_internal.rsi = &rsi[0];
#if CONFIG_STRIPED_LOOP_RESTORATION
cm->rst_internal.component = AOM_PLANE_Y;
cm->rst_internal.subsampling_y = 0;
#endif
restore_func =
restore_funcs[cm->rst_internal.rsi->frame_restoration_type];
#if CONFIG_HIGHBITDEPTH
restore_func_highbd =
restore_funcs_highbd[cm->rst_internal.rsi->frame_restoration_type];
if (cm->use_highbitdepth)
restore_func_highbd(
frame->y_buffer + ystart * ystride, ywidth, yend - ystart, ystride,
&cm->rst_internal, cm->bit_depth,
dst->y_buffer + ystart * dst->y_stride, dst->y_stride);
else
#endif // CONFIG_HIGHBITDEPTH
restore_func(frame->y_buffer + ystart * ystride, ywidth, yend - ystart,
ystride, &cm->rst_internal,
dst->y_buffer + ystart * dst->y_stride, dst->y_stride);
} else {
aom_yv12_copy_y(frame, dst);
}
}
if ((components_pattern >> AOM_PLANE_U) & 1) {
if (rsi[AOM_PLANE_U].frame_restoration_type != RESTORE_NONE) {
cm->rst_internal.ntiles = av1_get_rest_ntiles(
uvwidth, uvheight, cm->rst_info[AOM_PLANE_U].restoration_tilesize,
&cm->rst_internal.tile_width, &cm->rst_internal.tile_height,
&cm->rst_internal.nhtiles, &cm->rst_internal.nvtiles);
cm->rst_internal.rsi = &rsi[AOM_PLANE_U];
#if CONFIG_STRIPED_LOOP_RESTORATION
cm->rst_internal.component = AOM_PLANE_U;
cm->rst_internal.subsampling_y = cm->subsampling_y;
#endif
restore_func =
restore_funcs[cm->rst_internal.rsi->frame_restoration_type];
#if CONFIG_HIGHBITDEPTH
restore_func_highbd =
restore_funcs_highbd[cm->rst_internal.rsi->frame_restoration_type];
if (cm->use_highbitdepth)
restore_func_highbd(
frame->u_buffer + uvstart * uvstride, uvwidth, uvend - uvstart,
uvstride, &cm->rst_internal, cm->bit_depth,
dst->u_buffer + uvstart * dst->uv_stride, dst->uv_stride);
else
#endif // CONFIG_HIGHBITDEPTH
restore_func(frame->u_buffer + uvstart * uvstride, uvwidth,
uvend - uvstart, uvstride, &cm->rst_internal,
dst->u_buffer + uvstart * dst->uv_stride, dst->uv_stride);
} else {
aom_yv12_copy_u(frame, dst);
}
}
if ((components_pattern >> AOM_PLANE_V) & 1) {
if (rsi[AOM_PLANE_V].frame_restoration_type != RESTORE_NONE) {
cm->rst_internal.ntiles = av1_get_rest_ntiles(
uvwidth, uvheight, cm->rst_info[AOM_PLANE_V].restoration_tilesize,
&cm->rst_internal.tile_width, &cm->rst_internal.tile_height,
&cm->rst_internal.nhtiles, &cm->rst_internal.nvtiles);
cm->rst_internal.rsi = &rsi[AOM_PLANE_V];
#if CONFIG_STRIPED_LOOP_RESTORATION
cm->rst_internal.component = AOM_PLANE_V;
cm->rst_internal.subsampling_y = cm->subsampling_y;
#endif
restore_func =
restore_funcs[cm->rst_internal.rsi->frame_restoration_type];
#if CONFIG_HIGHBITDEPTH
restore_func_highbd =
restore_funcs_highbd[cm->rst_internal.rsi->frame_restoration_type];
if (cm->use_highbitdepth)
restore_func_highbd(
frame->v_buffer + uvstart * uvstride, uvwidth, uvend - uvstart,
uvstride, &cm->rst_internal, cm->bit_depth,
dst->v_buffer + uvstart * dst->uv_stride, dst->uv_stride);
else
#endif // CONFIG_HIGHBITDEPTH
restore_func(frame->v_buffer + uvstart * uvstride, uvwidth,
uvend - uvstart, uvstride, &cm->rst_internal,
dst->v_buffer + uvstart * dst->uv_stride, dst->uv_stride);
} else {
aom_yv12_copy_v(frame, dst);
}
}
if (dst == &dst_) {
if ((components_pattern >> AOM_PLANE_Y) & 1) aom_yv12_copy_y(dst, frame);
if ((components_pattern >> AOM_PLANE_U) & 1) aom_yv12_copy_u(dst, frame);
if ((components_pattern >> AOM_PLANE_V) & 1) aom_yv12_copy_v(dst, frame);
aom_free_frame_buffer(dst);
}
}
void av1_loop_restoration_frame(YV12_BUFFER_CONFIG *frame, AV1_COMMON *cm,
RestorationInfo *rsi, int components_pattern,
int partial_frame, YV12_BUFFER_CONFIG *dst) {
int start_mi_row, end_mi_row, mi_rows_to_filter;
start_mi_row = 0;
#if CONFIG_FRAME_SUPERRES
mi_rows_to_filter =
ALIGN_POWER_OF_TWO(cm->superres_upscaled_height, 3) >> MI_SIZE_LOG2;
#else
mi_rows_to_filter = cm->mi_rows;
#endif // CONFIG_FRAME_SUPERRES
if (partial_frame && mi_rows_to_filter > 8) {
start_mi_row = mi_rows_to_filter >> 1;
start_mi_row &= 0xfffffff8;
mi_rows_to_filter = AOMMAX(mi_rows_to_filter / 8, 8);
}
end_mi_row = start_mi_row + mi_rows_to_filter;
loop_restoration_init(&cm->rst_internal, cm->frame_type == KEY_FRAME);
loop_restoration_rows(frame, cm, start_mi_row, end_mi_row, components_pattern,
rsi, dst);
}
int av1_loop_restoration_corners_in_sb(const struct AV1Common *cm, int plane,
int mi_row, int mi_col, BLOCK_SIZE bsize,
int *rcol0, int *rcol1, int *rrow0,
int *rrow1, int *nhtiles) {
assert(rcol0 && rcol1 && rrow0 && rrow1 && nhtiles);
if (bsize != cm->sb_size) return 0;
#if CONFIG_FRAME_SUPERRES
const int frame_w = cm->superres_upscaled_width;
const int frame_h = cm->superres_upscaled_height;
const int mi_to_px = MI_SIZE * SCALE_NUMERATOR;
const int denom = cm->superres_scale_denominator;
#else
const int frame_w = cm->width;
const int frame_h = cm->height;
const int mi_to_px = MI_SIZE;
const int denom = 1;
#endif // CONFIG_FRAME_SUPERRES
const int ss_x = plane > 0 && cm->subsampling_x != 0;
const int ss_y = plane > 0 && cm->subsampling_y != 0;
const int ss_frame_w = (frame_w + ss_x) >> ss_x;
const int ss_frame_h = (frame_h + ss_y) >> ss_y;
int rtile_w, rtile_h, nvtiles;
av1_get_rest_ntiles(ss_frame_w, ss_frame_h,
cm->rst_info[plane].restoration_tilesize, &rtile_w,
&rtile_h, nhtiles, &nvtiles);
const int rnd_w = rtile_w * denom - 1;
const int rnd_h = rtile_h * denom - 1;
// rcol0/rrow0 should be the first column/row of rtiles that doesn't start
// left/below of mi_col/mi_row. For this calculation, we need to round up the
// division (if the sb starts at rtile column 10.1, the first matching rtile
// has column index 11)
*rcol0 = (mi_col * mi_to_px + rnd_w) / (rtile_w * denom);
*rrow0 = (mi_row * mi_to_px + rnd_h) / (rtile_h * denom);
// rcol1/rrow1 is the equivalent calculation, but for the superblock
// below-right. There are some slightly strange boundary effects. First, we
// need to clamp to nhtiles/nvtiles for the case where it appears there are,
// say, 2.4 restoration tiles horizontally. There we need a maximum mi_row1
// of 2 because tile 1 gets extended.
//
// Second, if mi_col1 >= cm->mi_cols then we must manually set *rcol1 to
// nhtiles. This is needed whenever the frame's width rounded up to the next
// toplevel superblock is smaller than nhtiles * rtile_w. The same logic is
// needed for rows.
const int mi_row1 = mi_row + mi_size_high[bsize];
const int mi_col1 = mi_col + mi_size_wide[bsize];
if (mi_col1 >= cm->mi_cols)
*rcol1 = *nhtiles;
else
*rcol1 = AOMMIN(*nhtiles, (mi_col1 * mi_to_px + rnd_w) / (rtile_w * denom));
if (mi_row1 >= cm->mi_rows)
*rrow1 = nvtiles;
else
*rrow1 = AOMMIN(nvtiles, (mi_row1 * mi_to_px + rnd_h) / (rtile_h * denom));
return *rcol0 < *rcol1 && *rrow0 < *rrow1;
}
#if CONFIG_STRIPED_LOOP_RESTORATION
// Extend to left and right
static void extend_line(uint8_t *buf, int width, int extend,
int use_highbitdepth) {
int i;
if (use_highbitdepth) {
uint16_t val, *buf16 = (uint16_t *)buf;
val = buf16[0];
for (i = 0; i < extend; i++) buf16[-1 - i] = val;
val = buf16[width - 1];
for (i = 0; i < extend; i++) buf16[width + i] = val;
} else {
uint8_t val;
val = buf[0];
for (i = 0; i < extend; i++) buf[-1 - i] = val;
val = buf[width - 1];
for (i = 0; i < extend; i++) buf[width + i] = val;
}
}
// For each 64 pixel high stripe, save 4 scan lines to be used as boundary in
// the loop restoration process. The lines are saved in
// rst_internal.stripe_boundary_lines
void av1_loop_restoration_save_boundary_lines(YV12_BUFFER_CONFIG *frame,
AV1_COMMON *cm) {
int p, boundary_stride;
int src_width, src_height, src_stride, stripe_height, stripe_offset, stripe_y,
yy;
uint8_t *src_buf, *boundary_below_buf, *boundary_above_buf;
int use_highbitdepth = 0;
for (p = 0; p < MAX_MB_PLANE; ++p) {
if (p == 0) {
src_buf = frame->y_buffer;
src_width = frame->y_crop_width;
src_height = frame->y_crop_height;
src_stride = frame->y_stride;
stripe_height = 64;
stripe_offset = 56 - 2; // offset of first line to copy
} else {
src_buf = p == 1 ? frame->u_buffer : frame->v_buffer;
src_width = frame->uv_crop_width;
src_height = frame->uv_crop_height;
src_stride = frame->uv_stride;
stripe_height = 64 >> cm->subsampling_y;
stripe_offset = (56 >> cm->subsampling_y) - 2;
}
boundary_above_buf = cm->rst_internal.stripe_boundary_above[p];
boundary_below_buf = cm->rst_internal.stripe_boundary_below[p];
boundary_stride = cm->rst_internal.stripe_boundary_stride[p];
#if CONFIG_HIGHBITDEPTH
use_highbitdepth = cm->use_highbitdepth;
if (use_highbitdepth) {
src_buf = (uint8_t *)CONVERT_TO_SHORTPTR(src_buf);
}
#endif
src_buf += (stripe_offset * src_stride) << use_highbitdepth;
boundary_above_buf += RESTORATION_EXTRA_HORZ << use_highbitdepth;
boundary_below_buf += RESTORATION_EXTRA_HORZ << use_highbitdepth;
// Loop over stripes
for (stripe_y = stripe_offset; stripe_y < src_height;
stripe_y += stripe_height) {
// Save 2 lines above the LR stripe (offset -9, -10)
for (yy = 0; yy < 2; yy++) {
if (stripe_y + yy < src_height) {
memcpy(boundary_above_buf, src_buf, src_width << use_highbitdepth);
extend_line(boundary_above_buf, src_width, RESTORATION_EXTRA_HORZ,
use_highbitdepth);
src_buf += src_stride << use_highbitdepth;
boundary_above_buf += boundary_stride << use_highbitdepth;
}
}
// Save 2 lines below the LR stripe (offset 56,57)
for (yy = 2; yy < 4; yy++) {
if (stripe_y + yy < src_height) {
memcpy(boundary_below_buf, src_buf, src_width << use_highbitdepth);
extend_line(boundary_below_buf, src_width, RESTORATION_EXTRA_HORZ,
use_highbitdepth);
src_buf += src_stride << use_highbitdepth;
boundary_below_buf += boundary_stride << use_highbitdepth;
}
}
// jump to next stripe
src_buf += ((stripe_height - 4) * src_stride) << use_highbitdepth;
}
}
}
#endif // CONFIG_STRIPED_LOOP_RESTORATION