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cobalt / cobalt / refs/heads/21.lts.stable / . / src / third_party / libvpx / vp9 / encoder / x86 / temporal_filter_sse4.c
blob: 437f49f5a0dbc6ebe288a8068c0b4ac7d6af6118 [file] [log] [blame]
/*
* Copyright (c) 2017 The WebM project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include <assert.h>
#include <smmintrin.h>
#include "./vp9_rtcd.h"
#include "./vpx_config.h"
#include "vpx/vpx_integer.h"
#include "vp9/encoder/vp9_encoder.h"
#include "vp9/encoder/vp9_temporal_filter.h"
#include "vp9/encoder/x86/temporal_filter_constants.h"
// Read in 8 pixels from a and b as 8-bit unsigned integers, compute the
// difference squared, and store as unsigned 16-bit integer to dst.
static INLINE void store_dist_8(const uint8_t *a, const uint8_t *b,
uint16_t *dst) {
const __m128i a_reg = _mm_loadl_epi64((const __m128i *)a);
const __m128i b_reg = _mm_loadl_epi64((const __m128i *)b);
const __m128i a_first = _mm_cvtepu8_epi16(a_reg);
const __m128i b_first = _mm_cvtepu8_epi16(b_reg);
__m128i dist_first;
dist_first = _mm_sub_epi16(a_first, b_first);
dist_first = _mm_mullo_epi16(dist_first, dist_first);
_mm_storeu_si128((__m128i *)dst, dist_first);
}
static INLINE void store_dist_16(const uint8_t *a, const uint8_t *b,
uint16_t *dst) {
const __m128i zero = _mm_setzero_si128();
const __m128i a_reg = _mm_loadu_si128((const __m128i *)a);
const __m128i b_reg = _mm_loadu_si128((const __m128i *)b);
const __m128i a_first = _mm_cvtepu8_epi16(a_reg);
const __m128i a_second = _mm_unpackhi_epi8(a_reg, zero);
const __m128i b_first = _mm_cvtepu8_epi16(b_reg);
const __m128i b_second = _mm_unpackhi_epi8(b_reg, zero);
__m128i dist_first, dist_second;
dist_first = _mm_sub_epi16(a_first, b_first);
dist_second = _mm_sub_epi16(a_second, b_second);
dist_first = _mm_mullo_epi16(dist_first, dist_first);
dist_second = _mm_mullo_epi16(dist_second, dist_second);
_mm_storeu_si128((__m128i *)dst, dist_first);
_mm_storeu_si128((__m128i *)(dst + 8), dist_second);
}
static INLINE void read_dist_8(const uint16_t *dist, __m128i *dist_reg) {
*dist_reg = _mm_loadu_si128((const __m128i *)dist);
}
static INLINE void read_dist_16(const uint16_t *dist, __m128i *reg_first,
__m128i *reg_second) {
read_dist_8(dist, reg_first);
read_dist_8(dist + 8, reg_second);
}
// Average the value based on the number of values summed (9 for pixels away
// from the border, 4 for pixels in corners, and 6 for other edge values).
//
// Add in the rounding factor and shift, clamp to 16, invert and shift. Multiply
// by weight.
static INLINE __m128i average_8(__m128i sum, const __m128i *mul_constants,
const int strength, const int rounding,
const __m128i *weight) {
// _mm_srl_epi16 uses the lower 64 bit value for the shift.
const __m128i strength_u128 = _mm_set_epi32(0, 0, 0, strength);
const __m128i rounding_u16 = _mm_set1_epi16(rounding);
const __m128i weight_u16 = *weight;
const __m128i sixteen = _mm_set1_epi16(16);
// modifier * 3 / index;
sum = _mm_mulhi_epu16(sum, *mul_constants);
sum = _mm_adds_epu16(sum, rounding_u16);
sum = _mm_srl_epi16(sum, strength_u128);
// The maximum input to this comparison is UINT16_MAX * NEIGHBOR_CONSTANT_4
// >> 16 (also NEIGHBOR_CONSTANT_4 -1) which is 49151 / 0xbfff / -16385
// So this needs to use the epu16 version which did not come until SSE4.
sum = _mm_min_epu16(sum, sixteen);
sum = _mm_sub_epi16(sixteen, sum);
return _mm_mullo_epi16(sum, weight_u16);
}
// Add 'sum_u16' to 'count'. Multiply by 'pred' and add to 'accumulator.'
static void accumulate_and_store_8(const __m128i sum_u16, const uint8_t *pred,
uint16_t *count, uint32_t *accumulator) {
const __m128i pred_u8 = _mm_loadl_epi64((const __m128i *)pred);
const __m128i zero = _mm_setzero_si128();
__m128i count_u16 = _mm_loadu_si128((const __m128i *)count);
__m128i pred_u16 = _mm_cvtepu8_epi16(pred_u8);
__m128i pred_0_u32, pred_1_u32;
__m128i accum_0_u32, accum_1_u32;
count_u16 = _mm_adds_epu16(count_u16, sum_u16);
_mm_storeu_si128((__m128i *)count, count_u16);
pred_u16 = _mm_mullo_epi16(sum_u16, pred_u16);
pred_0_u32 = _mm_cvtepu16_epi32(pred_u16);
pred_1_u32 = _mm_unpackhi_epi16(pred_u16, zero);
accum_0_u32 = _mm_loadu_si128((const __m128i *)accumulator);
accum_1_u32 = _mm_loadu_si128((const __m128i *)(accumulator + 4));
accum_0_u32 = _mm_add_epi32(pred_0_u32, accum_0_u32);
accum_1_u32 = _mm_add_epi32(pred_1_u32, accum_1_u32);
_mm_storeu_si128((__m128i *)accumulator, accum_0_u32);
_mm_storeu_si128((__m128i *)(accumulator + 4), accum_1_u32);
}
static INLINE void accumulate_and_store_16(const __m128i sum_0_u16,
const __m128i sum_1_u16,
const uint8_t *pred, uint16_t *count,
uint32_t *accumulator) {
const __m128i pred_u8 = _mm_loadu_si128((const __m128i *)pred);
const __m128i zero = _mm_setzero_si128();
__m128i count_0_u16 = _mm_loadu_si128((const __m128i *)count),
count_1_u16 = _mm_loadu_si128((const __m128i *)(count + 8));
__m128i pred_0_u16 = _mm_cvtepu8_epi16(pred_u8),
pred_1_u16 = _mm_unpackhi_epi8(pred_u8, zero);
__m128i pred_0_u32, pred_1_u32, pred_2_u32, pred_3_u32;
__m128i accum_0_u32, accum_1_u32, accum_2_u32, accum_3_u32;
count_0_u16 = _mm_adds_epu16(count_0_u16, sum_0_u16);
_mm_storeu_si128((__m128i *)count, count_0_u16);
count_1_u16 = _mm_adds_epu16(count_1_u16, sum_1_u16);
_mm_storeu_si128((__m128i *)(count + 8), count_1_u16);
pred_0_u16 = _mm_mullo_epi16(sum_0_u16, pred_0_u16);
pred_1_u16 = _mm_mullo_epi16(sum_1_u16, pred_1_u16);
pred_0_u32 = _mm_cvtepu16_epi32(pred_0_u16);
pred_1_u32 = _mm_unpackhi_epi16(pred_0_u16, zero);
pred_2_u32 = _mm_cvtepu16_epi32(pred_1_u16);
pred_3_u32 = _mm_unpackhi_epi16(pred_1_u16, zero);
accum_0_u32 = _mm_loadu_si128((const __m128i *)accumulator);
accum_1_u32 = _mm_loadu_si128((const __m128i *)(accumulator + 4));
accum_2_u32 = _mm_loadu_si128((const __m128i *)(accumulator + 8));
accum_3_u32 = _mm_loadu_si128((const __m128i *)(accumulator + 12));
accum_0_u32 = _mm_add_epi32(pred_0_u32, accum_0_u32);
accum_1_u32 = _mm_add_epi32(pred_1_u32, accum_1_u32);
accum_2_u32 = _mm_add_epi32(pred_2_u32, accum_2_u32);
accum_3_u32 = _mm_add_epi32(pred_3_u32, accum_3_u32);
_mm_storeu_si128((__m128i *)accumulator, accum_0_u32);
_mm_storeu_si128((__m128i *)(accumulator + 4), accum_1_u32);
_mm_storeu_si128((__m128i *)(accumulator + 8), accum_2_u32);
_mm_storeu_si128((__m128i *)(accumulator + 12), accum_3_u32);
}
// Read in 8 pixels from y_dist. For each index i, compute y_dist[i-1] +
// y_dist[i] + y_dist[i+1] and store in sum as 16-bit unsigned int.
static INLINE void get_sum_8(const uint16_t *y_dist, __m128i *sum) {
__m128i dist_reg, dist_left, dist_right;
dist_reg = _mm_loadu_si128((const __m128i *)y_dist);
dist_left = _mm_loadu_si128((const __m128i *)(y_dist - 1));
dist_right = _mm_loadu_si128((const __m128i *)(y_dist + 1));
*sum = _mm_adds_epu16(dist_reg, dist_left);
*sum = _mm_adds_epu16(*sum, dist_right);
}
// Read in 16 pixels from y_dist. For each index i, compute y_dist[i-1] +
// y_dist[i] + y_dist[i+1]. Store the result for first 8 pixels in sum_first and
// the rest in sum_second.
static INLINE void get_sum_16(const uint16_t *y_dist, __m128i *sum_first,
__m128i *sum_second) {
get_sum_8(y_dist, sum_first);
get_sum_8(y_dist + 8, sum_second);
}
// Read in a row of chroma values corresponds to a row of 16 luma values.
static INLINE void read_chroma_dist_row_16(int ss_x, const uint16_t *u_dist,
const uint16_t *v_dist,
__m128i *u_first, __m128i *u_second,
__m128i *v_first,
__m128i *v_second) {
if (!ss_x) {
// If there is no chroma subsampling in the horizontal direction, then we
// need to load 16 entries from chroma.
read_dist_16(u_dist, u_first, u_second);
read_dist_16(v_dist, v_first, v_second);
} else { // ss_x == 1
// Otherwise, we only need to load 8 entries
__m128i u_reg, v_reg;
read_dist_8(u_dist, &u_reg);
*u_first = _mm_unpacklo_epi16(u_reg, u_reg);
*u_second = _mm_unpackhi_epi16(u_reg, u_reg);
read_dist_8(v_dist, &v_reg);
*v_first = _mm_unpacklo_epi16(v_reg, v_reg);
*v_second = _mm_unpackhi_epi16(v_reg, v_reg);
}
}
// Horizontal add unsigned 16-bit ints in src and store them as signed 32-bit
// int in dst.
static INLINE void hadd_epu16(__m128i *src, __m128i *dst) {
const __m128i zero = _mm_setzero_si128();
const __m128i shift_right = _mm_srli_si128(*src, 2);
const __m128i odd = _mm_blend_epi16(shift_right, zero, 170);
const __m128i even = _mm_blend_epi16(*src, zero, 170);
*dst = _mm_add_epi32(even, odd);
}
// Add a row of luma distortion to 8 corresponding chroma mods.
static INLINE void add_luma_dist_to_8_chroma_mod(const uint16_t *y_dist,
int ss_x, int ss_y,
__m128i *u_mod,
__m128i *v_mod) {
__m128i y_reg;
if (!ss_x) {
read_dist_8(y_dist, &y_reg);
if (ss_y == 1) {
__m128i y_tmp;
read_dist_8(y_dist + DIST_STRIDE, &y_tmp);
y_reg = _mm_adds_epu16(y_reg, y_tmp);
}
} else {
__m128i y_first, y_second;
read_dist_16(y_dist, &y_first, &y_second);
if (ss_y == 1) {
__m128i y_tmp_0, y_tmp_1;
read_dist_16(y_dist + DIST_STRIDE, &y_tmp_0, &y_tmp_1);
y_first = _mm_adds_epu16(y_first, y_tmp_0);
y_second = _mm_adds_epu16(y_second, y_tmp_1);
}
hadd_epu16(&y_first, &y_first);
hadd_epu16(&y_second, &y_second);
y_reg = _mm_packus_epi32(y_first, y_second);
}
*u_mod = _mm_adds_epu16(*u_mod, y_reg);
*v_mod = _mm_adds_epu16(*v_mod, y_reg);
}
// Apply temporal filter to the luma components. This performs temporal
// filtering on a luma block of 16 X block_height. Use blk_fw as an array of
// size 4 for the weights for each of the 4 subblocks if blk_fw is not NULL,
// else use top_weight for top half, and bottom weight for bottom half.
static void vp9_apply_temporal_filter_luma_16(
const uint8_t *y_src, int y_src_stride, const uint8_t *y_pre,
int y_pre_stride, const uint8_t *u_src, const uint8_t *v_src,
int uv_src_stride, const uint8_t *u_pre, const uint8_t *v_pre,
int uv_pre_stride, unsigned int block_width, unsigned int block_height,
int ss_x, int ss_y, int strength, int use_whole_blk, uint32_t *y_accum,
uint16_t *y_count, const uint16_t *y_dist, const uint16_t *u_dist,
const uint16_t *v_dist, const int16_t *const *neighbors_first,
const int16_t *const *neighbors_second, int top_weight, int bottom_weight,
const int *blk_fw) {
const int rounding = (1 << strength) >> 1;
__m128i weight_first, weight_second;
__m128i mul_first, mul_second;
__m128i sum_row_1_first, sum_row_1_second;
__m128i sum_row_2_first, sum_row_2_second;
__m128i sum_row_3_first, sum_row_3_second;
__m128i u_first, u_second;
__m128i v_first, v_second;
__m128i sum_row_first;
__m128i sum_row_second;
// Loop variables
unsigned int h;
assert(strength >= 0);
assert(strength <= 6);
assert(block_width == 16);
(void)block_width;
// Initialize the weights
if (blk_fw) {
weight_first = _mm_set1_epi16(blk_fw[0]);
weight_second = _mm_set1_epi16(blk_fw[1]);
} else {
weight_first = _mm_set1_epi16(top_weight);
weight_second = weight_first;
}
// First row
mul_first = _mm_load_si128((const __m128i *)neighbors_first[0]);
mul_second = _mm_load_si128((const __m128i *)neighbors_second[0]);
// Add luma values
get_sum_16(y_dist, &sum_row_2_first, &sum_row_2_second);
get_sum_16(y_dist + DIST_STRIDE, &sum_row_3_first, &sum_row_3_second);
sum_row_first = _mm_adds_epu16(sum_row_2_first, sum_row_3_first);
sum_row_second = _mm_adds_epu16(sum_row_2_second, sum_row_3_second);
// Add chroma values
read_chroma_dist_row_16(ss_x, u_dist, v_dist, &u_first, &u_second, &v_first,
&v_second);
sum_row_first = _mm_adds_epu16(sum_row_first, u_first);
sum_row_second = _mm_adds_epu16(sum_row_second, u_second);
sum_row_first = _mm_adds_epu16(sum_row_first, v_first);
sum_row_second = _mm_adds_epu16(sum_row_second, v_second);
// Get modifier and store result
sum_row_first =
average_8(sum_row_first, &mul_first, strength, rounding, &weight_first);
sum_row_second = average_8(sum_row_second, &mul_second, strength, rounding,
&weight_second);
accumulate_and_store_16(sum_row_first, sum_row_second, y_pre, y_count,
y_accum);
y_src += y_src_stride;
y_pre += y_pre_stride;
y_count += y_pre_stride;
y_accum += y_pre_stride;
y_dist += DIST_STRIDE;
u_src += uv_src_stride;
u_pre += uv_pre_stride;
u_dist += DIST_STRIDE;
v_src += uv_src_stride;
v_pre += uv_pre_stride;
v_dist += DIST_STRIDE;
// Then all the rows except the last one
mul_first = _mm_load_si128((const __m128i *)neighbors_first[1]);
mul_second = _mm_load_si128((const __m128i *)neighbors_second[1]);
for (h = 1; h < block_height - 1; ++h) {
// Move the weight to bottom half
if (!use_whole_blk && h == block_height / 2) {
if (blk_fw) {
weight_first = _mm_set1_epi16(blk_fw[2]);
weight_second = _mm_set1_epi16(blk_fw[3]);
} else {
weight_first = _mm_set1_epi16(bottom_weight);
weight_second = weight_first;
}
}
// Shift the rows up
sum_row_1_first = sum_row_2_first;
sum_row_1_second = sum_row_2_second;
sum_row_2_first = sum_row_3_first;
sum_row_2_second = sum_row_3_second;
// Add luma values to the modifier
sum_row_first = _mm_adds_epu16(sum_row_1_first, sum_row_2_first);
sum_row_second = _mm_adds_epu16(sum_row_1_second, sum_row_2_second);
get_sum_16(y_dist + DIST_STRIDE, &sum_row_3_first, &sum_row_3_second);
sum_row_first = _mm_adds_epu16(sum_row_first, sum_row_3_first);
sum_row_second = _mm_adds_epu16(sum_row_second, sum_row_3_second);
// Add chroma values to the modifier
if (ss_y == 0 || h % 2 == 0) {
// Only calculate the new chroma distortion if we are at a pixel that
// corresponds to a new chroma row
read_chroma_dist_row_16(ss_x, u_dist, v_dist, &u_first, &u_second,
&v_first, &v_second);
u_src += uv_src_stride;
u_pre += uv_pre_stride;
u_dist += DIST_STRIDE;
v_src += uv_src_stride;
v_pre += uv_pre_stride;
v_dist += DIST_STRIDE;
}
sum_row_first = _mm_adds_epu16(sum_row_first, u_first);
sum_row_second = _mm_adds_epu16(sum_row_second, u_second);
sum_row_first = _mm_adds_epu16(sum_row_first, v_first);
sum_row_second = _mm_adds_epu16(sum_row_second, v_second);
// Get modifier and store result
sum_row_first =
average_8(sum_row_first, &mul_first, strength, rounding, &weight_first);
sum_row_second = average_8(sum_row_second, &mul_second, strength, rounding,
&weight_second);
accumulate_and_store_16(sum_row_first, sum_row_second, y_pre, y_count,
y_accum);
y_src += y_src_stride;
y_pre += y_pre_stride;
y_count += y_pre_stride;
y_accum += y_pre_stride;
y_dist += DIST_STRIDE;
}
// The last row
mul_first = _mm_load_si128((const __m128i *)neighbors_first[0]);
mul_second = _mm_load_si128((const __m128i *)neighbors_second[0]);
// Shift the rows up
sum_row_1_first = sum_row_2_first;
sum_row_1_second = sum_row_2_second;
sum_row_2_first = sum_row_3_first;
sum_row_2_second = sum_row_3_second;
// Add luma values to the modifier
sum_row_first = _mm_adds_epu16(sum_row_1_first, sum_row_2_first);
sum_row_second = _mm_adds_epu16(sum_row_1_second, sum_row_2_second);
// Add chroma values to the modifier
if (ss_y == 0) {
// Only calculate the new chroma distortion if we are at a pixel that
// corresponds to a new chroma row
read_chroma_dist_row_16(ss_x, u_dist, v_dist, &u_first, &u_second, &v_first,
&v_second);
}
sum_row_first = _mm_adds_epu16(sum_row_first, u_first);
sum_row_second = _mm_adds_epu16(sum_row_second, u_second);
sum_row_first = _mm_adds_epu16(sum_row_first, v_first);
sum_row_second = _mm_adds_epu16(sum_row_second, v_second);
// Get modifier and store result
sum_row_first =
average_8(sum_row_first, &mul_first, strength, rounding, &weight_first);
sum_row_second = average_8(sum_row_second, &mul_second, strength, rounding,
&weight_second);
accumulate_and_store_16(sum_row_first, sum_row_second, y_pre, y_count,
y_accum);
}
// Perform temporal filter for the luma component.
static void vp9_apply_temporal_filter_luma(
const uint8_t *y_src, int y_src_stride, const uint8_t *y_pre,
int y_pre_stride, const uint8_t *u_src, const uint8_t *v_src,
int uv_src_stride, const uint8_t *u_pre, const uint8_t *v_pre,
int uv_pre_stride, unsigned int block_width, unsigned int block_height,
int ss_x, int ss_y, int strength, const int *blk_fw, int use_whole_blk,
uint32_t *y_accum, uint16_t *y_count, const uint16_t *y_dist,
const uint16_t *u_dist, const uint16_t *v_dist) {
unsigned int blk_col = 0, uv_blk_col = 0;
const unsigned int blk_col_step = 16, uv_blk_col_step = 16 >> ss_x;
const unsigned int mid_width = block_width >> 1,
last_width = block_width - blk_col_step;
int top_weight = blk_fw[0],
bottom_weight = use_whole_blk ? blk_fw[0] : blk_fw[2];
const int16_t *const *neighbors_first;
const int16_t *const *neighbors_second;
if (block_width == 16) {
// Special Case: The blockwidth is 16 and we are operating on a row of 16
// chroma pixels. In this case, we can't use the usualy left-midle-right
// pattern. We also don't support splitting now.
neighbors_first = LUMA_LEFT_COLUMN_NEIGHBORS;
neighbors_second = LUMA_RIGHT_COLUMN_NEIGHBORS;
if (use_whole_blk) {
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, 16,
block_height, ss_x, ss_y, strength, use_whole_blk, y_accum + blk_col,
y_count + blk_col, y_dist + blk_col, u_dist + uv_blk_col,
v_dist + uv_blk_col, neighbors_first, neighbors_second, top_weight,
bottom_weight, NULL);
} else {
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, 16,
block_height, ss_x, ss_y, strength, use_whole_blk, y_accum + blk_col,
y_count + blk_col, y_dist + blk_col, u_dist + uv_blk_col,
v_dist + uv_blk_col, neighbors_first, neighbors_second, 0, 0, blk_fw);
}
return;
}
// Left
neighbors_first = LUMA_LEFT_COLUMN_NEIGHBORS;
neighbors_second = LUMA_MIDDLE_COLUMN_NEIGHBORS;
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride, u_pre + uv_blk_col,
v_pre + uv_blk_col, uv_pre_stride, 16, block_height, ss_x, ss_y, strength,
use_whole_blk, y_accum + blk_col, y_count + blk_col, y_dist + blk_col,
u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors_first,
neighbors_second, top_weight, bottom_weight, NULL);
blk_col += blk_col_step;
uv_blk_col += uv_blk_col_step;
// Middle First
neighbors_first = LUMA_MIDDLE_COLUMN_NEIGHBORS;
for (; blk_col < mid_width;
blk_col += blk_col_step, uv_blk_col += uv_blk_col_step) {
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, 16, block_height,
ss_x, ss_y, strength, use_whole_blk, y_accum + blk_col,
y_count + blk_col, y_dist + blk_col, u_dist + uv_blk_col,
v_dist + uv_blk_col, neighbors_first, neighbors_second, top_weight,
bottom_weight, NULL);
}
if (!use_whole_blk) {
top_weight = blk_fw[1];
bottom_weight = blk_fw[3];
}
// Middle Second
for (; blk_col < last_width;
blk_col += blk_col_step, uv_blk_col += uv_blk_col_step) {
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, 16, block_height,
ss_x, ss_y, strength, use_whole_blk, y_accum + blk_col,
y_count + blk_col, y_dist + blk_col, u_dist + uv_blk_col,
v_dist + uv_blk_col, neighbors_first, neighbors_second, top_weight,
bottom_weight, NULL);
}
// Right
neighbors_second = LUMA_RIGHT_COLUMN_NEIGHBORS;
vp9_apply_temporal_filter_luma_16(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride, u_pre + uv_blk_col,
v_pre + uv_blk_col, uv_pre_stride, 16, block_height, ss_x, ss_y, strength,
use_whole_blk, y_accum + blk_col, y_count + blk_col, y_dist + blk_col,
u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors_first,
neighbors_second, top_weight, bottom_weight, NULL);
}
// Apply temporal filter to the chroma components. This performs temporal
// filtering on a chroma block of 8 X uv_height. If blk_fw is not NULL, use
// blk_fw as an array of size 4 for the weights for each of the 4 subblocks,
// else use top_weight for top half, and bottom weight for bottom half.
static void vp9_apply_temporal_filter_chroma_8(
const uint8_t *y_src, int y_src_stride, const uint8_t *y_pre,
int y_pre_stride, const uint8_t *u_src, const uint8_t *v_src,
int uv_src_stride, const uint8_t *u_pre, const uint8_t *v_pre,
int uv_pre_stride, unsigned int uv_block_width,
unsigned int uv_block_height, int ss_x, int ss_y, int strength,
uint32_t *u_accum, uint16_t *u_count, uint32_t *v_accum, uint16_t *v_count,
const uint16_t *y_dist, const uint16_t *u_dist, const uint16_t *v_dist,
const int16_t *const *neighbors, int top_weight, int bottom_weight,
const int *blk_fw) {
const int rounding = (1 << strength) >> 1;
__m128i weight;
__m128i mul;
__m128i u_sum_row_1, u_sum_row_2, u_sum_row_3;
__m128i v_sum_row_1, v_sum_row_2, v_sum_row_3;
__m128i u_sum_row, v_sum_row;
// Loop variable
unsigned int h;
(void)uv_block_width;
// Initilize weight
if (blk_fw) {
weight = _mm_setr_epi16(blk_fw[0], blk_fw[0], blk_fw[0], blk_fw[0],
blk_fw[1], blk_fw[1], blk_fw[1], blk_fw[1]);
} else {
weight = _mm_set1_epi16(top_weight);
}
// First row
mul = _mm_load_si128((const __m128i *)neighbors[0]);
// Add chroma values
get_sum_8(u_dist, &u_sum_row_2);
get_sum_8(u_dist + DIST_STRIDE, &u_sum_row_3);
u_sum_row = _mm_adds_epu16(u_sum_row_2, u_sum_row_3);
get_sum_8(v_dist, &v_sum_row_2);
get_sum_8(v_dist + DIST_STRIDE, &v_sum_row_3);
v_sum_row = _mm_adds_epu16(v_sum_row_2, v_sum_row_3);
// Add luma values
add_luma_dist_to_8_chroma_mod(y_dist, ss_x, ss_y, &u_sum_row, &v_sum_row);
// Get modifier and store result
u_sum_row = average_8(u_sum_row, &mul, strength, rounding, &weight);
v_sum_row = average_8(v_sum_row, &mul, strength, rounding, &weight);
accumulate_and_store_8(u_sum_row, u_pre, u_count, u_accum);
accumulate_and_store_8(v_sum_row, v_pre, v_count, v_accum);
u_src += uv_src_stride;
u_pre += uv_pre_stride;
u_dist += DIST_STRIDE;
v_src += uv_src_stride;
v_pre += uv_pre_stride;
v_dist += DIST_STRIDE;
u_count += uv_pre_stride;
u_accum += uv_pre_stride;
v_count += uv_pre_stride;
v_accum += uv_pre_stride;
y_src += y_src_stride * (1 + ss_y);
y_pre += y_pre_stride * (1 + ss_y);
y_dist += DIST_STRIDE * (1 + ss_y);
// Then all the rows except the last one
mul = _mm_load_si128((const __m128i *)neighbors[1]);
for (h = 1; h < uv_block_height - 1; ++h) {
// Move the weight pointer to the bottom half of the blocks
if (h == uv_block_height / 2) {
if (blk_fw) {
weight = _mm_setr_epi16(blk_fw[2], blk_fw[2], blk_fw[2], blk_fw[2],
blk_fw[3], blk_fw[3], blk_fw[3], blk_fw[3]);
} else {
weight = _mm_set1_epi16(bottom_weight);
}
}
// Shift the rows up
u_sum_row_1 = u_sum_row_2;
u_sum_row_2 = u_sum_row_3;
v_sum_row_1 = v_sum_row_2;
v_sum_row_2 = v_sum_row_3;
// Add chroma values
u_sum_row = _mm_adds_epu16(u_sum_row_1, u_sum_row_2);
get_sum_8(u_dist + DIST_STRIDE, &u_sum_row_3);
u_sum_row = _mm_adds_epu16(u_sum_row, u_sum_row_3);
v_sum_row = _mm_adds_epu16(v_sum_row_1, v_sum_row_2);
get_sum_8(v_dist + DIST_STRIDE, &v_sum_row_3);
v_sum_row = _mm_adds_epu16(v_sum_row, v_sum_row_3);
// Add luma values
add_luma_dist_to_8_chroma_mod(y_dist, ss_x, ss_y, &u_sum_row, &v_sum_row);
// Get modifier and store result
u_sum_row = average_8(u_sum_row, &mul, strength, rounding, &weight);
v_sum_row = average_8(v_sum_row, &mul, strength, rounding, &weight);
accumulate_and_store_8(u_sum_row, u_pre, u_count, u_accum);
accumulate_and_store_8(v_sum_row, v_pre, v_count, v_accum);
u_src += uv_src_stride;
u_pre += uv_pre_stride;
u_dist += DIST_STRIDE;
v_src += uv_src_stride;
v_pre += uv_pre_stride;
v_dist += DIST_STRIDE;
u_count += uv_pre_stride;
u_accum += uv_pre_stride;
v_count += uv_pre_stride;
v_accum += uv_pre_stride;
y_src += y_src_stride * (1 + ss_y);
y_pre += y_pre_stride * (1 + ss_y);
y_dist += DIST_STRIDE * (1 + ss_y);
}
// The last row
mul = _mm_load_si128((const __m128i *)neighbors[0]);
// Shift the rows up
u_sum_row_1 = u_sum_row_2;
u_sum_row_2 = u_sum_row_3;
v_sum_row_1 = v_sum_row_2;
v_sum_row_2 = v_sum_row_3;
// Add chroma values
u_sum_row = _mm_adds_epu16(u_sum_row_1, u_sum_row_2);
v_sum_row = _mm_adds_epu16(v_sum_row_1, v_sum_row_2);
// Add luma values
add_luma_dist_to_8_chroma_mod(y_dist, ss_x, ss_y, &u_sum_row, &v_sum_row);
// Get modifier and store result
u_sum_row = average_8(u_sum_row, &mul, strength, rounding, &weight);
v_sum_row = average_8(v_sum_row, &mul, strength, rounding, &weight);
accumulate_and_store_8(u_sum_row, u_pre, u_count, u_accum);
accumulate_and_store_8(v_sum_row, v_pre, v_count, v_accum);
}
// Perform temporal filter for the chroma components.
static void vp9_apply_temporal_filter_chroma(
const uint8_t *y_src, int y_src_stride, const uint8_t *y_pre,
int y_pre_stride, const uint8_t *u_src, const uint8_t *v_src,
int uv_src_stride, const uint8_t *u_pre, const uint8_t *v_pre,
int uv_pre_stride, unsigned int block_width, unsigned int block_height,
int ss_x, int ss_y, int strength, const int *blk_fw, int use_whole_blk,
uint32_t *u_accum, uint16_t *u_count, uint32_t *v_accum, uint16_t *v_count,
const uint16_t *y_dist, const uint16_t *u_dist, const uint16_t *v_dist) {
const unsigned int uv_width = block_width >> ss_x,
uv_height = block_height >> ss_y;
unsigned int blk_col = 0, uv_blk_col = 0;
const unsigned int uv_blk_col_step = 8, blk_col_step = 8 << ss_x;
const unsigned int uv_mid_width = uv_width >> 1,
uv_last_width = uv_width - uv_blk_col_step;
int top_weight = blk_fw[0],
bottom_weight = use_whole_blk ? blk_fw[0] : blk_fw[2];
const int16_t *const *neighbors;
if (uv_width == 8) {
// Special Case: We are subsampling in x direction on a 16x16 block. Since
// we are operating on a row of 8 chroma pixels, we can't use the usual
// left-middle-right pattern.
assert(ss_x);
if (ss_y) {
neighbors = CHROMA_DOUBLE_SS_SINGLE_COLUMN_NEIGHBORS;
} else {
neighbors = CHROMA_SINGLE_SS_SINGLE_COLUMN_NEIGHBORS;
}
if (use_whole_blk) {
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, uv_width,
uv_height, ss_x, ss_y, strength, u_accum + uv_blk_col,
u_count + uv_blk_col, v_accum + uv_blk_col, v_count + uv_blk_col,
y_dist + blk_col, u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors,
top_weight, bottom_weight, NULL);
} else {
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, uv_width,
uv_height, ss_x, ss_y, strength, u_accum + uv_blk_col,
u_count + uv_blk_col, v_accum + uv_blk_col, v_count + uv_blk_col,
y_dist + blk_col, u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors,
0, 0, blk_fw);
}
return;
}
// Left
if (ss_x && ss_y) {
neighbors = CHROMA_DOUBLE_SS_LEFT_COLUMN_NEIGHBORS;
} else if (ss_x || ss_y) {
neighbors = CHROMA_SINGLE_SS_LEFT_COLUMN_NEIGHBORS;
} else {
neighbors = CHROMA_NO_SS_LEFT_COLUMN_NEIGHBORS;
}
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride, u_pre + uv_blk_col,
v_pre + uv_blk_col, uv_pre_stride, uv_width, uv_height, ss_x, ss_y,
strength, u_accum + uv_blk_col, u_count + uv_blk_col,
v_accum + uv_blk_col, v_count + uv_blk_col, y_dist + blk_col,
u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors, top_weight,
bottom_weight, NULL);
blk_col += blk_col_step;
uv_blk_col += uv_blk_col_step;
// Middle First
if (ss_x && ss_y) {
neighbors = CHROMA_DOUBLE_SS_MIDDLE_COLUMN_NEIGHBORS;
} else if (ss_x || ss_y) {
neighbors = CHROMA_SINGLE_SS_MIDDLE_COLUMN_NEIGHBORS;
} else {
neighbors = CHROMA_NO_SS_MIDDLE_COLUMN_NEIGHBORS;
}
for (; uv_blk_col < uv_mid_width;
blk_col += blk_col_step, uv_blk_col += uv_blk_col_step) {
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, uv_width,
uv_height, ss_x, ss_y, strength, u_accum + uv_blk_col,
u_count + uv_blk_col, v_accum + uv_blk_col, v_count + uv_blk_col,
y_dist + blk_col, u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors,
top_weight, bottom_weight, NULL);
}
if (!use_whole_blk) {
top_weight = blk_fw[1];
bottom_weight = blk_fw[3];
}
// Middle Second
for (; uv_blk_col < uv_last_width;
blk_col += blk_col_step, uv_blk_col += uv_blk_col_step) {
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride,
u_pre + uv_blk_col, v_pre + uv_blk_col, uv_pre_stride, uv_width,
uv_height, ss_x, ss_y, strength, u_accum + uv_blk_col,
u_count + uv_blk_col, v_accum + uv_blk_col, v_count + uv_blk_col,
y_dist + blk_col, u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors,
top_weight, bottom_weight, NULL);
}
// Right
if (ss_x && ss_y) {
neighbors = CHROMA_DOUBLE_SS_RIGHT_COLUMN_NEIGHBORS;
} else if (ss_x || ss_y) {
neighbors = CHROMA_SINGLE_SS_RIGHT_COLUMN_NEIGHBORS;
} else {
neighbors = CHROMA_NO_SS_RIGHT_COLUMN_NEIGHBORS;
}
vp9_apply_temporal_filter_chroma_8(
y_src + blk_col, y_src_stride, y_pre + blk_col, y_pre_stride,
u_src + uv_blk_col, v_src + uv_blk_col, uv_src_stride, u_pre + uv_blk_col,
v_pre + uv_blk_col, uv_pre_stride, uv_width, uv_height, ss_x, ss_y,
strength, u_accum + uv_blk_col, u_count + uv_blk_col,
v_accum + uv_blk_col, v_count + uv_blk_col, y_dist + blk_col,
u_dist + uv_blk_col, v_dist + uv_blk_col, neighbors, top_weight,
bottom_weight, NULL);
}
void vp9_apply_temporal_filter_sse4_1(
const uint8_t *y_src, int y_src_stride, const uint8_t *y_pre,
int y_pre_stride, const uint8_t *u_src, const uint8_t *v_src,
int uv_src_stride, const uint8_t *u_pre, const uint8_t *v_pre,
int uv_pre_stride, unsigned int block_width, unsigned int block_height,
int ss_x, int ss_y, int strength, const int *const blk_fw,
int use_whole_blk, uint32_t *y_accum, uint16_t *y_count, uint32_t *u_accum,
uint16_t *u_count, uint32_t *v_accum, uint16_t *v_count) {
const unsigned int chroma_height = block_height >> ss_y,
chroma_width = block_width >> ss_x;
DECLARE_ALIGNED(16, uint16_t, y_dist[BH * DIST_STRIDE]) = { 0 };
DECLARE_ALIGNED(16, uint16_t, u_dist[BH * DIST_STRIDE]) = { 0 };
DECLARE_ALIGNED(16, uint16_t, v_dist[BH * DIST_STRIDE]) = { 0 };
const int *blk_fw_ptr = blk_fw;
uint16_t *y_dist_ptr = y_dist + 1, *u_dist_ptr = u_dist + 1,
*v_dist_ptr = v_dist + 1;
const uint8_t *y_src_ptr = y_src, *u_src_ptr = u_src, *v_src_ptr = v_src;
const uint8_t *y_pre_ptr = y_pre, *u_pre_ptr = u_pre, *v_pre_ptr = v_pre;
// Loop variables
unsigned int row, blk_col;
assert(block_width <= BW && "block width too large");
assert(block_height <= BH && "block height too large");
assert(block_width % 16 == 0 && "block width must be multiple of 16");
assert(block_height % 2 == 0 && "block height must be even");
assert((ss_x == 0 || ss_x == 1) && (ss_y == 0 || ss_y == 1) &&
"invalid chroma subsampling");
assert(strength >= 0 && strength <= 6 && "invalid temporal filter strength");
assert(blk_fw[0] >= 0 && "filter weight must be positive");
assert(
(use_whole_blk || (blk_fw[1] >= 0 && blk_fw[2] >= 0 && blk_fw[3] >= 0)) &&
"subblock filter weight must be positive");
assert(blk_fw[0] <= 2 && "sublock filter weight must be less than 2");
assert(
(use_whole_blk || (blk_fw[1] <= 2 && blk_fw[2] <= 2 && blk_fw[3] <= 2)) &&
"subblock filter weight must be less than 2");
// Precompute the difference sqaured
for (row = 0; row < block_height; row++) {
for (blk_col = 0; blk_col < block_width; blk_col += 16) {
store_dist_16(y_src_ptr + blk_col, y_pre_ptr + blk_col,
y_dist_ptr + blk_col);
}
y_src_ptr += y_src_stride;
y_pre_ptr += y_pre_stride;
y_dist_ptr += DIST_STRIDE;
}
for (row = 0; row < chroma_height; row++) {
for (blk_col = 0; blk_col < chroma_width; blk_col += 8) {
store_dist_8(u_src_ptr + blk_col, u_pre_ptr + blk_col,
u_dist_ptr + blk_col);
store_dist_8(v_src_ptr + blk_col, v_pre_ptr + blk_col,
v_dist_ptr + blk_col);
}
u_src_ptr += uv_src_stride;
u_pre_ptr += uv_pre_stride;
u_dist_ptr += DIST_STRIDE;
v_src_ptr += uv_src_stride;
v_pre_ptr += uv_pre_stride;
v_dist_ptr += DIST_STRIDE;
}
y_dist_ptr = y_dist + 1;
u_dist_ptr = u_dist + 1;
v_dist_ptr = v_dist + 1;
vp9_apply_temporal_filter_luma(
y_src, y_src_stride, y_pre, y_pre_stride, u_src, v_src, uv_src_stride,
u_pre, v_pre, uv_pre_stride, block_width, block_height, ss_x, ss_y,
strength, blk_fw_ptr, use_whole_blk, y_accum, y_count, y_dist_ptr,
u_dist_ptr, v_dist_ptr);
vp9_apply_temporal_filter_chroma(
y_src, y_src_stride, y_pre, y_pre_stride, u_src, v_src, uv_src_stride,
u_pre, v_pre, uv_pre_stride, block_width, block_height, ss_x, ss_y,
strength, blk_fw_ptr, use_whole_blk, u_accum, u_count, v_accum, v_count,
y_dist_ptr, u_dist_ptr, v_dist_ptr);
}