Merge branch 'lcu-encoding'

This commit is contained in:
Ari Koivula 2014-03-21 16:46:02 +02:00
commit 5d50872ab3
10 changed files with 297 additions and 174 deletions

View file

@ -50,6 +50,9 @@ int8_t g_convert_to_bit[LCU_WIDTH + 1];
/* Local functions. */
static void add_checksum(encoder_control* encoder);
static void encode_VUI(encoder_control* encoder);
static void encode_sao(encoder_control *encoder,
unsigned x_lcu, uint16_t y_lcu,
sao_info *sao_luma, sao_info *sao_chroma);
/**
* Initialize g_sig_last_scan with scan positions for a transform block of
@ -383,11 +386,18 @@ static void write_aud(encoder_control* encoder)
void encode_one_frame(encoder_control* encoder)
{
yuv_t *hor_buf = alloc_yuv_t(encoder->in.width);
// Allocate 2 extra luma pixels so we get 1 extra chroma pixel for the
// for the extra pixel on the top right.
yuv_t *ver_buf = alloc_yuv_t(LCU_WIDTH + 2);
const int is_first_frame = (encoder->frame == 0);
const int is_i_radl = (encoder->cfg->intra_period == 1 && encoder->frame % 2 == 0);
const int is_p_radl = (encoder->cfg->intra_period > 1 && (encoder->frame % encoder->cfg->intra_period) == 0);
const int is_radl_frame = is_first_frame || is_i_radl || is_p_radl;
picture *pic = encoder->in.cur_pic;
// Initialize lambda value(s) to use in search
init_lambda(encoder);
@ -464,17 +474,91 @@ void encode_one_frame(encoder_control* encoder)
{
vector2d lcu;
const vector2d size = { encoder->in.width, encoder->in.height };
const vector2d size_lcu = { encoder->in.width_in_lcu, encoder->in.height_in_lcu };
for (lcu.y = 0; lcu.y < encoder->in.height_in_lcu; lcu.y++) {
for (lcu.x = 0; lcu.x < encoder->in.width_in_lcu; lcu.x++) {
const vector2d px = { lcu.x * LCU_WIDTH, lcu.y * LCU_WIDTH };
search_lcu(encoder, px.x, px.y);
// Handle partial LCUs on the right and bottom.
const vector2d lcu_dim = {
MIN(LCU_WIDTH, size.x - px.x), MIN(LCU_WIDTH, size.y - px.y)
};
const int right = px.x + lcu_dim.x;
const int bottom = px.y + lcu_dim.y;
search_lcu(encoder, px.x, px.y, hor_buf, ver_buf);
// Take the bottom right pixel from the LCU above and put it as the
// first pixel in this LCUs rightmost pixels.
if (lcu.y > 0) {
ver_buf->y[0] = hor_buf->y[right - 1];
ver_buf->u[0] = hor_buf->u[right / 2 - 1];
ver_buf->v[0] = hor_buf->v[right / 2 - 1];
}
// Take bottom and right pixels from this LCU to be used on the search of next LCU.
picture_blit_pixels(&pic->y_recdata[(bottom - 1) * size.x + px.x],
&hor_buf->y[px.x],
lcu_dim.x, 1, size.x, size.x);
picture_blit_pixels(&pic->u_recdata[(bottom / 2 - 1) * size.x / 2 + px.x / 2],
&hor_buf->u[px.x / 2],
lcu_dim.x / 2, 1, size.x / 2, size.x / 2);
picture_blit_pixels(&pic->v_recdata[(bottom / 2 - 1) * size.x / 2 + px.x / 2],
&hor_buf->v[px.x / 2],
lcu_dim.x / 2, 1, size.x / 2, size.x / 2);
picture_blit_pixels(&pic->y_recdata[px.y * size.x + right - 1],
&ver_buf->y[1],
1, lcu_dim.y, size.x, 1);
picture_blit_pixels(&pic->u_recdata[px.y * size.x / 4 + (right / 2) - 1],
&ver_buf->u[1],
1, lcu_dim.y / 2, size.x / 2, 1);
picture_blit_pixels(&pic->v_recdata[px.y * size.x / 4 + (right / 2) - 1],
&ver_buf->v[1],
1, lcu_dim.y / 2, size.x / 2, 1);
if (encoder->deblock_enable) {
filter_deblock_lcu(encoder, px.x, px.y);
}
if (encoder->sao_enable) {
const int stride = encoder->in.width_in_lcu;
sao_info *sao_luma = &pic->sao_luma[lcu.y * stride + lcu.x];
sao_info *sao_chroma = &pic->sao_chroma[lcu.y * stride + lcu.x];
init_sao_info(sao_luma);
init_sao_info(sao_chroma);
{
sao_info *sao_top = lcu. y != 0 ? &pic->sao_luma[(lcu.y - 1) * stride + lcu.x] : NULL;
sao_info *sao_left = lcu.x != 0 ? &pic->sao_luma[lcu.y * stride + lcu.x -1] : NULL;
sao_search_luma(encoder->in.cur_pic, lcu.x, lcu.y, sao_luma, sao_top, sao_left);
}
{
sao_info *sao_top = lcu.y != 0 ? &pic->sao_chroma[(lcu.y - 1) * stride + lcu.x] : NULL;
sao_info *sao_left = lcu.x != 0 ? &pic->sao_chroma[lcu.y * stride + lcu.x - 1] : NULL;
sao_search_chroma(encoder->in.cur_pic, lcu.x, lcu.y, sao_chroma, sao_top, sao_left);
}
// Merge only if both luma and chroma can be merged
sao_luma->merge_left_flag = sao_luma->merge_left_flag & sao_chroma->merge_left_flag;
sao_luma->merge_up_flag = sao_luma->merge_up_flag & sao_chroma->merge_up_flag;
encode_sao(encoder, lcu.x, lcu.y, sao_luma, sao_chroma);
}
encode_coding_tree(encoder, lcu.x << MAX_DEPTH, lcu.y << MAX_DEPTH, 0);
{
const int last_lcu = (lcu.x == size_lcu.x - 1 && lcu.y == size_lcu.y - 1);
cabac_encode_bin_trm(&cabac, last_lcu ? 1 : 0); // end_of_slice_segment_flag
}
}
}
}
encode_slice_data(encoder);
cabac_flush(&cabac);
bitstream_align(encoder->stream);
bitstream_flush(encoder->stream);
@ -491,10 +575,17 @@ void encode_one_frame(encoder_control* encoder)
bitstream_clear_buffer(encoder->stream);
if (encoder->sao_enable) {
sao_reconstruct_frame(encoder);
}
// Calculate checksum
add_checksum(encoder);
encoder->in.cur_pic->poc = encoder->poc;
dealloc_yuv_t(hor_buf);
dealloc_yuv_t(ver_buf);
}
static void fill_after_frame(unsigned height, unsigned array_width,
@ -1190,7 +1281,7 @@ static void encode_sao_merge_flags(sao_info *sao,
}
/**
* \brief Stub that encodes all LCU's as none type.
* \brief Encode SAO information.
*/
static void encode_sao(encoder_control *encoder,
unsigned x_lcu, uint16_t y_lcu,
@ -1207,82 +1298,6 @@ static void encode_sao(encoder_control *encoder,
}
}
void encode_slice_data(encoder_control* encoder)
{
uint16_t x_ctb, y_ctb;
picture *pic = encoder->in.cur_pic;
const vector2d size_lcu = { encoder->in.width_in_lcu, encoder->in.height_in_lcu };
// Filtering
if(encoder->deblock_enable) {
filter_deblock(encoder);
}
if (encoder->sao_enable) {
pixel *new_y_data = MALLOC(pixel, pic->width * pic->height);
pixel *new_u_data = MALLOC(pixel, (pic->width * pic->height) >> 2);
pixel *new_v_data = MALLOC(pixel, (pic->width * pic->height) >> 2);
memcpy(new_y_data, pic->y_recdata, sizeof(pixel) * pic->width * pic->height);
memcpy(new_u_data, pic->u_recdata, sizeof(pixel) * (pic->width * pic->height) >> 2);
memcpy(new_v_data, pic->v_recdata, sizeof(pixel) * (pic->width * pic->height) >> 2);
for (y_ctb = 0; y_ctb < encoder->in.height_in_lcu; y_ctb++) {
for (x_ctb = 0; x_ctb < encoder->in.width_in_lcu; x_ctb++) {
unsigned stride = encoder->in.width_in_lcu;
//Fetch luma top and left merge candidate
sao_info *sao_top = y_ctb!=0?&pic->sao_luma[(y_ctb-1) * stride + x_ctb]:NULL;
sao_info *sao_left = x_ctb!=0?&pic->sao_luma[y_ctb * stride + x_ctb -1]:NULL;
sao_info *sao_luma = &pic->sao_luma[y_ctb * stride + x_ctb];
sao_info *sao_chroma = &pic->sao_chroma[y_ctb * stride + x_ctb];
init_sao_info(sao_luma);
init_sao_info(sao_chroma);
sao_search_luma(encoder->in.cur_pic, x_ctb, y_ctb, sao_luma, sao_top, sao_left);
// Chroma top and left merge candidate
sao_top = y_ctb!=0?&pic->sao_chroma[(y_ctb-1) * stride + x_ctb]:NULL;
sao_left = x_ctb!=0?&pic->sao_chroma[y_ctb * stride + x_ctb -1]:NULL;
sao_search_chroma(encoder->in.cur_pic, x_ctb, y_ctb, sao_chroma, sao_top, sao_left);
// Merge only if both luma and chroma can be merged
sao_luma->merge_left_flag = sao_luma->merge_left_flag & sao_chroma->merge_left_flag;
sao_luma->merge_up_flag = sao_luma->merge_up_flag & sao_chroma->merge_up_flag;
// sao_do_rdo(encoder, x_ctb, y_ctb, sao_luma, sao_chroma);
sao_reconstruct(pic, new_y_data, x_ctb, y_ctb, sao_luma, COLOR_Y);
sao_reconstruct(pic, new_u_data, x_ctb, y_ctb, sao_chroma, COLOR_U);
sao_reconstruct(pic, new_v_data, x_ctb, y_ctb, sao_chroma, COLOR_V);
}
}
free(new_y_data);
free(new_u_data);
free(new_v_data);
}
// Loop through every LCU in the slice
for (y_ctb = 0; y_ctb < encoder->in.height_in_lcu; y_ctb++) {
for (x_ctb = 0; x_ctb < encoder->in.width_in_lcu; x_ctb++) {
uint8_t depth = 0;
const int last_lcu = (x_ctb == size_lcu.x - 1 && y_ctb == size_lcu.y - 1);
if (encoder->sao_enable) {
picture *pic = encoder->in.cur_pic;
unsigned stride = encoder->in.width_in_lcu;
sao_info sao_luma = pic->sao_luma[y_ctb * stride + x_ctb];
sao_info sao_chroma = pic->sao_chroma[y_ctb * stride + x_ctb];
encode_sao(encoder, x_ctb, y_ctb, &sao_luma, &sao_chroma);
}
// Recursive function for looping through all the sub-blocks
encode_coding_tree(encoder, x_ctb << MAX_DEPTH, y_ctb << MAX_DEPTH, depth);
cabac_encode_bin_trm(&cabac, last_lcu ? 1 : 0); // end_of_slice_segment_flag
}
}
}
void encode_coding_tree(encoder_control *encoder, uint16_t x_ctb,
uint16_t y_ctb, uint8_t depth)

View file

@ -109,7 +109,6 @@ int read_one_frame(FILE *file, encoder_control *encoder);
void encode_seq_parameter_set(encoder_control *encoder);
void encode_pic_parameter_set(encoder_control *encoder);
void encode_vid_parameter_set(encoder_control *encoder);
void encode_slice_data(encoder_control *encoder);
void encode_slice_header(encoder_control *encoder);
void encode_access_unit_delimiter(encoder_control* encoder);
void encode_prefix_sei_version(encoder_control* encoder);

View file

@ -166,6 +166,18 @@ void filter_deblock_edge_luma(encoder_control *encoder,
int32_t xpos, int32_t ypos,
int8_t depth, int8_t dir)
{
cu_info *cu_q = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(xpos>>MIN_SIZE) + (ypos>>MIN_SIZE) * (encoder->in.width_in_lcu << MAX_DEPTH)];
{
// Return if called with a coordinate which is not at CU or TU boundary.
// TODO: Add handling for asymmetric inter CU boundaries which do not coincide
// with transform boundaries.
const int tu_width = LCU_WIDTH >> cu_q->tr_depth;
if (dir == EDGE_HOR && (ypos & (tu_width - 1))) return;
if (dir == EDGE_VER && (xpos & (tu_width - 1))) return;
}
{
int32_t stride = encoder->in.cur_pic->width;
int32_t offset = stride;
int32_t beta_offset_div2 = encoder->beta_offset_div2;
@ -174,18 +186,10 @@ void filter_deblock_edge_luma(encoder_control *encoder,
pixel *orig_src = &encoder->in.cur_pic->y_recdata[xpos + ypos*stride];
pixel *src = orig_src;
int32_t step = 1;
cu_info *cu_q = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(xpos>>MIN_SIZE) + (ypos>>MIN_SIZE) * (encoder->in.width_in_lcu << MAX_DEPTH)];
cu_info *cu_p = NULL;
int16_t x_cu = xpos>>MIN_SIZE,y_cu = ypos>>MIN_SIZE;
int8_t strength = 0;
if(dir == EDGE_VER) {
offset = 1;
step = stride;
}
{
int32_t qp = encoder->QP;
int32_t bitdepth_scale = 1 << (g_bitdepth - 8);
int32_t b_index = CLIP(0, 51, qp + (beta_offset_div2 << 1));
@ -194,13 +198,30 @@ void filter_deblock_edge_luma(encoder_control *encoder,
uint32_t blocks_in_part = (LCU_WIDTH >> depth) / 4;
uint32_t block_idx;
int32_t tc_index,tc,thr_cut;
if (dir == EDGE_VER) {
offset = 1;
step = stride;
}
// TODO: add CU based QP calculation
// For each 4-pixel part in the edge
for (block_idx = 0; block_idx < blocks_in_part; ++block_idx) {
int32_t dp0, dq0, dp3, dq3, d0, d3, dp, dq, d;
if((block_idx & 1) == 0)
{
vector2d px = {
(dir == EDGE_HOR ? xpos + block_idx * 4 : xpos),
(dir == EDGE_VER ? ypos + block_idx * 4 : ypos)
};
// Don't deblock the last 4x4 block of the LCU. This will be deblocked
// when processing the next LCU.
if (block_idx > 0 && dir == EDGE_HOR && (px.x + 4) % 64 == 0 && (px.x + 4 != encoder->in.width)) {
continue;
}
// CU in the side we are filtering, update every 8-pixels
cu_p = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(x_cu - (dir == EDGE_VER) + (dir == EDGE_HOR ? block_idx>>1 : 0)) +
(y_cu - (dir == EDGE_HOR) + (dir == EDGE_VER ? block_idx>>1 : 0))
@ -269,6 +290,25 @@ void filter_deblock_edge_chroma(encoder_control *encoder,
int32_t x, int32_t y,
int8_t depth, int8_t dir)
{
cu_info *cu_q = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(x>>(MIN_SIZE-1)) + (y>>(MIN_SIZE-1)) * (encoder->in.width_in_lcu << MAX_DEPTH)];
// Chroma edges that do not lay on a 8x8 grid are not deblocked.
if (depth >= MAX_DEPTH) {
if (dir == EDGE_HOR && (y & (8 - 1))) return;
if (dir == EDGE_VER && (x & (8 - 1))) return;
}
{
// Return if called with a coordinate which is not at CU or TU boundary.
// TODO: Add handling for asymmetric inter CU boundaries which do not coincide
// with transform boundaries.
const int tu_width = (LCU_WIDTH / 2) >> cu_q->tr_depth;
if (dir == EDGE_HOR && (y & (tu_width - 1))) return;
if (dir == EDGE_VER && (x & (tu_width - 1))) return;
}
// For each subpart
{
int32_t stride = encoder->in.cur_pic->width >> 1;
int32_t tc_offset_div2 = encoder->tc_offset_div2;
// TODO: support 10+bits
@ -277,37 +317,41 @@ void filter_deblock_edge_chroma(encoder_control *encoder,
// Init offset and step to EDGE_HOR
int32_t offset = stride;
int32_t step = 1;
cu_info *cu_q = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(x>>(MIN_SIZE-1)) + (y>>(MIN_SIZE-1)) * (encoder->in.width_in_lcu << MAX_DEPTH)];
cu_info *cu_p = NULL;
int16_t x_cu = x>>(MIN_SIZE-1),y_cu = y>>(MIN_SIZE-1);
int8_t strength = 2;
// We cannot filter edges not on 8x8 grid
if((depth == MAX_DEPTH && (( (y & 0x7) && dir == EDGE_HOR ) || ( (x & 0x7) && dir == EDGE_VER ) ) ))
{
return;
}
if(dir == EDGE_VER)
{
offset = 1;
step = stride;
}
// For each subpart
{
int32_t QP = g_chroma_scale[encoder->QP];
int32_t bitdepth_scale = 1 << (g_bitdepth-8);
int32_t TC_index = CLIP(0, 51+2, (int32_t)(QP + 2*(strength-1) + (tc_offset_div2 << 1)));
int32_t Tc = g_tc_table_8x8[TC_index]*bitdepth_scale;
uint32_t blocks_in_part= (LCU_WIDTH>>(depth+1)) / 4;
// Special handling for depth 4. It's meaning is that we want to bypass
// last block in LCU check in order to deblock just that block.
uint32_t blocks_in_part= (LCU_WIDTH>>(depth == 4 ? depth : depth + 1)) / 4;
uint32_t blk_idx;
if(dir == EDGE_VER) {
offset = 1;
step = stride;
}
for (blk_idx = 0; blk_idx < blocks_in_part; ++blk_idx)
{
vector2d px = {
(dir == EDGE_HOR ? x + blk_idx * 4 : x),
(dir == EDGE_VER ? y + blk_idx * 4 : y)
};
cu_p = &encoder->in.cur_pic->cu_array[MAX_DEPTH][(x_cu - (dir == EDGE_VER) + (dir == EDGE_HOR ? blk_idx : 0)) +
(y_cu - (dir == EDGE_HOR) + (dir == EDGE_VER ? blk_idx : 0))
* (encoder->in.width_in_lcu << MAX_DEPTH)];
// Don't deblock the last 4x4 block of the LCU. This will be deblocked
// when processing the next LCU.
if (depth != 4 && dir == EDGE_HOR && (px.x + 4) % 32 == 0 && (px.x + 4 != encoder->in.width / 2)) {
continue;
}
// Only filter when strenght == 2 (one of the blocks is intra coded)
if (cu_q->type == CU_INTRA || cu_p->type == CU_INTRA) {
// Chroma U
@ -406,6 +450,40 @@ void filter_deblock(encoder_control* encoder)
}
/**
* \brief Deblock a single LCU without using data from right or down.
*
* Filter all the following edges:
* - All edges within the LCU, except for the last 4 pixels on the right when
* using horizontal filtering.
* - Left edge and top edge.
* - After vertical filtering the left edge, filter the last 4 pixels of
* horizontal edges in the LCU to the left.
*/
void filter_deblock_lcu(encoder_control *encoder, int x_px, int y_px)
{
const vector2d lcu = { x_px / LCU_WIDTH, y_px / LCU_WIDTH };
filter_deblock_cu(encoder, lcu.x << MAX_DEPTH, lcu.y << MAX_DEPTH, 0, EDGE_VER);
// Filter rightmost 4 pixels from last LCU now that they have been
// finally deblocked vertically.
if (lcu.x > 0) {
int y;
for (y = 0; y < 64; y += 8) {
if (lcu.y + y == 0) continue;
filter_deblock_edge_luma(encoder, lcu.x * 64 - 4, lcu.y * 64 + y, 4, EDGE_HOR);
}
for (y = 0; y < 32; y += 8) {
if (lcu.y + y == 0) continue;
filter_deblock_edge_chroma(encoder, lcu.x * 32 - 4, lcu.y * 32 + y, 4, EDGE_HOR);
}
}
filter_deblock_cu(encoder, lcu.x << MAX_DEPTH, lcu.y << MAX_DEPTH, 0, EDGE_HOR);
}
/**
* \brief Interpolation for chroma half-pixel
* \param src source image in integer pels (-2..width+3, -2..height+3)

View file

@ -32,7 +32,7 @@
//////////////////////////////////////////////////////////////////////////
// FUNCTIONS
// Deblocking
void filter_deblock_cu(encoder_control *encoder, int32_t x_cu, int32_t y_cu,
void filter_deblock_cu(encoder_control *encoder, int32_t x_px, int32_t y_px,
int8_t depth, int32_t edge);
void filter_deblock_edge_luma(encoder_control *encoder,
int32_t x_pos, int32_t y_pos,
@ -41,6 +41,7 @@ void filter_deblock_edge_chroma(encoder_control *encoder,
int32_t xpos, int32_t ypos,
int8_t depth, int8_t dir);
void filter_deblock(encoder_control *encoder);
void filter_deblock_lcu(encoder_control *encoder, int x_px, int y_px);
void filter_deblock_luma(pixel *src, int32_t offset, int32_t tc , int8_t sw,
int8_t part_p_nofilter, int8_t part_q_nofilter,
int32_t thr_cut,

View file

@ -33,6 +33,29 @@
#define PSNRMAX (255.0 * 255.0)
yuv_t * alloc_yuv_t(int luma_size)
{
// Get buffers with separate mallocs in order to take advantage of
// automatic buffer overrun checks.
yuv_t *yuv = (yuv_t *)malloc(sizeof(*yuv));
yuv->y = (pixel *)malloc(luma_size * sizeof(*yuv->y));
yuv->u = (pixel *)malloc(luma_size / 2 * sizeof(*yuv->u));
yuv->v = (pixel *)malloc(luma_size / 2 * sizeof(*yuv->v));
yuv->size = luma_size;
return yuv;
}
void dealloc_yuv_t(yuv_t * yuv)
{
free(yuv->y);
free(yuv->u);
free(yuv->v);
free(yuv);
}
/**
* \brief BLock Image Transfer from one buffer to another.
*

View file

@ -177,6 +177,13 @@ typedef struct {
pixel v[LCU_CHROMA_SIZE];
} lcu_yuv_t;
typedef struct {
int size;
pixel *y;
pixel *u;
pixel *v;
} yuv_t;
typedef struct {
lcu_ref_px_t top_ref; //!< Reference pixels from adjacent LCUs.
lcu_ref_px_t left_ref; //!< Reference pixels from adjacent LCUs.
@ -202,6 +209,9 @@ typedef struct {
//////////////////////////////////////////////////////////////////////////
// FUNCTIONS
yuv_t * alloc_yuv_t(int luma_size);
void dealloc_yuv_t(yuv_t * yuv);
picture * picture_init(int32_t width, int32_t height,
int32_t width_in_lcu, int32_t height_in_lcu);
int picture_destroy(picture *pic);

View file

@ -634,3 +634,36 @@ void sao_search_luma(const picture *pic, unsigned x_ctb, unsigned y_ctb, sao_inf
rec_list[0] = rec;
sao_search_best_mode(orig_list, rec_list, block_width, block_height, 1, sao, sao_top, sao_left);
}
void sao_reconstruct_frame(encoder_control *encoder)
{
vector2d lcu;
picture *pic = encoder->in.cur_pic;
// These are needed because SAO needs the pre-SAO pixels form left and
// top LCUs. Single pixel wide buffers, like what search_lcu takes, would
// be enough though.
pixel *new_y_data = MALLOC(pixel, pic->width * pic->height);
pixel *new_u_data = MALLOC(pixel, (pic->width * pic->height) >> 2);
pixel *new_v_data = MALLOC(pixel, (pic->width * pic->height) >> 2);
memcpy(new_y_data, pic->y_recdata, sizeof(pixel) * pic->width * pic->height);
memcpy(new_u_data, pic->u_recdata, sizeof(pixel) * (pic->width * pic->height) >> 2);
memcpy(new_v_data, pic->v_recdata, sizeof(pixel) * (pic->width * pic->height) >> 2);
for (lcu.y = 0; lcu.y < encoder->in.height_in_lcu; lcu.y++) {
for (lcu.x = 0; lcu.x < encoder->in.width_in_lcu; lcu.x++) {
unsigned stride = encoder->in.width_in_lcu;
sao_info *sao_luma = &pic->sao_luma[lcu.y * stride + lcu.x];
sao_info *sao_chroma = &pic->sao_chroma[lcu.y * stride + lcu.x];
// sao_do_rdo(encoder, lcu.x, lcu.y, sao_luma, sao_chroma);
sao_reconstruct(pic, new_y_data, lcu.x, lcu.y, sao_luma, COLOR_Y);
sao_reconstruct(pic, new_u_data, lcu.x, lcu.y, sao_chroma, COLOR_U);
sao_reconstruct(pic, new_v_data, lcu.x, lcu.y, sao_chroma, COLOR_V);
}
}
free(new_y_data);
free(new_u_data);
free(new_v_data);
}

View file

@ -51,5 +51,6 @@ void sao_search_luma(const picture *pic, unsigned x_ctb, unsigned y_ctb, sao_inf
void sao_reconstruct(picture *pic, const pixel *old_rec,
unsigned x_ctb, unsigned y_ctb,
const sao_info *sao, color_index color_i);
void sao_reconstruct_frame(encoder_control *encoder);
#endif

View file

@ -26,6 +26,7 @@
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include "config.h"
#include "bitstream.h"
@ -882,7 +883,7 @@ static int search_cu(encoder_control *encoder, int x, int y, int depth, lcu_t wo
* - Copy reference pixels from neighbouring LCUs.
* - Copy reference pixels from this LCU.
*/
static void init_lcu_t(encoder_control *encoder, const int x, const int y, lcu_t *lcu)
static void init_lcu_t(encoder_control *encoder, const int x, const int y, lcu_t *lcu, const yuv_t *hor_buf, const yuv_t *ver_buf)
{
// Copy reference cu_info structs from neighbouring LCUs.
{
@ -930,58 +931,33 @@ static void init_lcu_t(encoder_control *encoder, const int x, const int y, lcu_t
// Copy reference pixels.
{
const picture *pic = encoder->in.cur_pic;
const int pic_width = encoder->in.width;
const int pic_height = encoder->in.height;
const int ref_size = LCU_REF_PX_WIDTH;
const int pic_width_c = encoder->in.width / 2;
const int pic_height_c = encoder->in.height / 2;
const int ref_size_c = LCU_REF_PX_WIDTH / 2;
const int x_c = x / 2;
const int y_c = y / 2;
// Copy top reference pixels.
if (y > 0) {
int x_max = MIN(ref_size, pic_width - x);
int x_max_c = x_max / 2;
picture_blit_pixels(&pic->y_recdata[x + (y - 1) * pic_width],
&lcu->top_ref.y[1],
x_max, 1, pic_width, ref_size);
picture_blit_pixels(&pic->u_recdata[x_c + (y_c - 1) * pic_width_c],
&lcu->top_ref.u[1],
x_max, 1, pic_width_c, ref_size_c);
picture_blit_pixels(&pic->v_recdata[x_c + (y_c - 1) * pic_width_c],
&lcu->top_ref.v[1],
x_max, 1, pic_width_c, ref_size_c);
// hor_buf is of size pic_width so there might not be LCU_REF_PX_WIDTH
// number of allocated pixels left.
int x_max = MIN(LCU_REF_PX_WIDTH, pic_width - x);
memcpy(&lcu->top_ref.y[1], &hor_buf->y[x], x_max);
memcpy(&lcu->top_ref.u[1], &hor_buf->u[x / 2], x_max / 2);
memcpy(&lcu->top_ref.v[1], &hor_buf->v[x / 2], x_max / 2);
}
// Copy left reference pixels.
if (x > 0) {
int y_max = MIN(LCU_REF_PX_WIDTH, pic_height - y);
int y_max_c = y_max / 2;
picture_blit_pixels(&pic->y_recdata[(x - 1) + y * pic_width],
&lcu->left_ref.y[1],
1, y_max, pic_width, 1);
picture_blit_pixels(&pic->u_recdata[(x_c - 1) + (y_c) * pic_width_c],
&lcu->left_ref.u[1],
1, y_max_c, pic_width_c, 1);
picture_blit_pixels(&pic->v_recdata[(x_c - 1) + (y_c) * pic_width_c],
&lcu->left_ref.v[1],
1, y_max_c, pic_width_c, 1);
memcpy(&lcu->left_ref.y[1], &ver_buf->y[1], LCU_WIDTH);
memcpy(&lcu->left_ref.u[1], &ver_buf->u[1], LCU_WIDTH);
memcpy(&lcu->left_ref.v[1], &ver_buf->v[1], LCU_WIDTH);
}
// Copy top-left reference pixel.
if (x > 0 && y > 0) {
lcu->top_ref.y[0] = pic->y_recdata[(x - 1) + (y - 1) * pic_width];
lcu->left_ref.y[0] = pic->y_recdata[(x - 1) + (y - 1) * pic_width];
lcu->top_ref.y[0] = ver_buf->y[0];
lcu->left_ref.y[0] = ver_buf->y[0];
lcu->top_ref.u[0] = pic->u_recdata[(x_c - 1) + (y_c - 1) * pic_width_c];
lcu->left_ref.u[0] = pic->u_recdata[(x_c - 1) + (y_c - 1) * pic_width_c];
lcu->top_ref.u[0] = ver_buf->u[0];
lcu->left_ref.u[0] = ver_buf->u[0];
lcu->top_ref.v[0] = pic->v_recdata[(x_c - 1) + (y_c - 1) * pic_width_c];
lcu->left_ref.v[0] = pic->v_recdata[(x_c - 1) + (y_c - 1) * pic_width_c];
lcu->top_ref.v[0] = ver_buf->v[0];
lcu->left_ref.v[0] = ver_buf->v[0];
}
}
@ -1065,14 +1041,14 @@ static void copy_lcu_to_cu_data(encoder_control *encoder, int x_px, int y_px, co
* Search LCU for modes.
* - Best mode gets copied to current picture.
*/
void search_lcu(encoder_control *encoder, int x, int y)
void search_lcu(encoder_control *encoder, int x, int y, yuv_t *hor_buf, yuv_t *ver_buf)
{
lcu_t work_tree[MAX_PU_DEPTH + 1];
int depth;
// Initialize work tree.
for (depth = 0; depth <= MAX_PU_DEPTH; ++depth) {
memset(&work_tree[depth], 0, sizeof(work_tree[depth]));
init_lcu_t(encoder, x, y, &work_tree[depth]);
init_lcu_t(encoder, x, y, &work_tree[depth], hor_buf, ver_buf);
}
// Start search from depth 0.
@ -1080,17 +1056,3 @@ void search_lcu(encoder_control *encoder, int x, int y)
copy_lcu_to_cu_data(encoder, x, y, &work_tree[0]);
}
/**
* Perform mode search for every LCU in the current picture.
*/
static void search_frame(encoder_control *encoder)
{
int y_lcu, x_lcu;
for (y_lcu = 0; y_lcu < encoder->in.height_in_lcu; y_lcu++) {
for (x_lcu = 0; x_lcu < encoder->in.width_in_lcu; x_lcu++) {
search_lcu(encoder, x_lcu * LCU_WIDTH, y_lcu * LCU_WIDTH);
}
}
}

View file

@ -27,8 +27,9 @@
#include "global.h"
#include "encoder.h"
#include "picture.h"
void search_lcu(encoder_control *encoder, int x, int y);
void search_lcu(encoder_control *encoder, int x, int y, yuv_t *hor_buf, yuv_t *ver_buf);
#endif