/*****************************************************************************
* This file is part of Kvazaar HEVC encoder.
*
* Copyright (C) 2013-2015 Tampere University of Technology and others (see
* COPYING file).
*
* Kvazaar is free software: you can redistribute it and/or modify it under
* the terms of the GNU Lesser General Public License as published by the
* Free Software Foundation; either version 2.1 of the License, or (at your
* option) any later version.
*
* Kvazaar is distributed in the hope that it will be useful, but WITHOUT ANY
* WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
* FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License along
* with Kvazaar. If not, see .
****************************************************************************/
/*
* \file
*/
#include "transform.h"
#include
#include
#include
#include
#include "config.h"
#include "nal.h"
#include "rdo.h"
#include "strategies/strategies-dct.h"
//////////////////////////////////////////////////////////////////////////
// INITIALIZATIONS
//
const uint8_t g_chroma_scale[58]=
{
0, 1, 2, 3, 4, 5, 6, 7, 8, 9,10,11,12,13,14,15,16,
17,18,19,20,21,22,23,24,25,26,27,28,29,29,30,31,32,
33,33,34,34,35,35,36,36,37,37,38,39,40,41,42,43,44,
45,46,47,48,49,50,51
};
//////////////////////////////////////////////////////////////////////////
// FUNCTIONS
//
/**
* \brief Get scaled QP used in quantization
*
*/
int32_t get_scaled_qp(int8_t type, int8_t qp, int8_t qp_offset)
{
int32_t qp_scaled = 0;
if(type == 0) {
qp_scaled = qp + qp_offset;
} else {
qp_scaled = CLIP(-qp_offset, 57, qp);
if(qp_scaled < 0) {
qp_scaled = qp_scaled + qp_offset;
} else {
qp_scaled = g_chroma_scale[qp_scaled] + qp_offset;
}
}
return qp_scaled;
}
/**
* \brief NxN inverse transform (2D)
* \param coeff input data (transform coefficients)
* \param block output data (residual)
* \param block_size input data (width of transform)
*/
void transformskip(const encoder_control_t * const encoder, int16_t *block,int16_t *coeff, int8_t block_size)
{
uint32_t log2_tr_size = g_convert_to_bit[block_size] + 2;
int32_t shift = MAX_TR_DYNAMIC_RANGE - encoder->bitdepth - log2_tr_size;
int32_t j,k;
for (j = 0; j < block_size; j++) {
for(k = 0; k < block_size; k ++) {
coeff[j * block_size + k] = block[j * block_size + k] << shift;
}
}
}
/**
* \brief inverse transform skip
* \param coeff input data (transform coefficients)
* \param block output data (residual)
* \param block_size width of transform
*/
void itransformskip(const encoder_control_t * const encoder, int16_t *block,int16_t *coeff, int8_t block_size)
{
uint32_t log2_tr_size = g_convert_to_bit[block_size] + 2;
int32_t shift = MAX_TR_DYNAMIC_RANGE - encoder->bitdepth - log2_tr_size;
int32_t j,k;
int32_t offset;
offset = (1 << (shift -1)); // For rounding
for ( j = 0; j < block_size; j++ ) {
for(k = 0; k < block_size; k ++) {
block[j * block_size + k] = (coeff[j * block_size + k] + offset) >> shift;
}
}
}
/**
* \brief forward transform (2D)
* \param block input residual
* \param coeff transform coefficients
* \param block_size width of transform
*/
void transform2d(const encoder_control_t * const encoder, int16_t *block, int16_t *coeff, int8_t block_size, int32_t mode)
{
dct_func *dct_func = get_dct_func(block_size, mode);
dct_func(encoder->bitdepth, block, coeff);
}
void itransform2d(const encoder_control_t * const encoder, int16_t *block, int16_t *coeff, int8_t block_size, int32_t mode)
{
dct_func *idct_func = get_idct_func(block_size, mode);
idct_func(encoder->bitdepth, coeff, block);
}
#define QUANT_SHIFT 14
/**
* \brief quantize transformed coefficents
*
*/
void quant(const encoder_state_t * const state, int16_t *coef, int16_t *q_coef, int32_t width,
int32_t height, int8_t type, int8_t scan_idx, int8_t block_type )
{
const encoder_control_t * const encoder = state->encoder_control;
const uint32_t log2_block_size = g_convert_to_bit[ width ] + 2;
const uint32_t * const scan = g_sig_last_scan[ scan_idx ][ log2_block_size - 1 ];
int32_t qp_scaled = get_scaled_qp(type, state->global->QP, 0);
const uint32_t log2_tr_size = g_convert_to_bit[ width ] + 2;
const int32_t scalinglist_type = (block_type == CU_INTRA ? 0 : 3) + (int8_t)("\0\3\1\2"[type]);
const int32_t *quant_coeff = encoder->scaling_list.quant_coeff[log2_tr_size-2][scalinglist_type][qp_scaled%6];
const int32_t transform_shift = MAX_TR_DYNAMIC_RANGE - encoder->bitdepth - log2_tr_size; //!< Represents scaling through forward transform
const int32_t q_bits = QUANT_SHIFT + qp_scaled/6 + transform_shift;
const int32_t add = ((state->global->slicetype == SLICE_I) ? 171 : 85) << (q_bits - 9);
const int32_t q_bits8 = q_bits - 8;
uint32_t ac_sum = 0;
for (int32_t n = 0; n < width * height; n++) {
int32_t level;
int32_t sign;
level = coef[n];
sign = (level < 0 ? -1: 1);
level = ((int64_t)abs(level) * quant_coeff[n] + add) >> q_bits;
ac_sum += level;
level *= sign;
q_coef[n] = (int16_t)(CLIP( -32768, 32767, level));
}
if (!(encoder->sign_hiding && ac_sum >= 2)) return;
int32_t delta_u[LCU_WIDTH*LCU_WIDTH >> 2];
for (int32_t n = 0; n < width * height; n++) {
int32_t level;
level = coef[n];
level = ((int64_t)abs(level) * quant_coeff[n] + add) >> q_bits;
delta_u[n] = (int32_t)(((int64_t)abs(coef[n]) * quant_coeff[n] - (level << q_bits)) >> q_bits8);
}
if(ac_sum >= 2) {
#define SCAN_SET_SIZE 16
#define LOG2_SCAN_SET_SIZE 4
int32_t n,last_cg = -1, abssum = 0, subset, subpos;
for(subset = (width*height - 1)>>LOG2_SCAN_SET_SIZE; subset >= 0; subset--) {
int32_t first_nz_pos_in_cg = SCAN_SET_SIZE, last_nz_pos_in_cg=-1;
subpos = subset<= 0; n--) {
if (q_coef[scan[n + subpos]]) {
last_nz_pos_in_cg = n;
break;
}
}
// First coeff pos
for (n = 0; n = 0 && last_cg == -1) {
last_cg = 1;
}
if(last_nz_pos_in_cg - first_nz_pos_in_cg >= 4) {
int32_t signbit = (q_coef[scan[subpos + first_nz_pos_in_cg]] > 0 ? 0 : 1) ;
if(signbit != (abssum&0x1)) { // compare signbit with sum_parity
int32_t min_cost_inc = 0x7fffffff, min_pos =-1, cur_cost=0x7fffffff;
int16_t final_change = 0, cur_change=0;
for(n = (last_cg == 1 ? last_nz_pos_in_cg : SCAN_SET_SIZE - 1); n >= 0; n--) {
uint32_t blkPos = scan[n + subpos];
if(q_coef[blkPos] != 0) {
if(delta_u[blkPos] > 0) {
cur_cost = -delta_u[blkPos];
cur_change=1;
} else if(n == first_nz_pos_in_cg && abs(q_coef[blkPos]) == 1) {
cur_cost=0x7fffffff;
} else {
cur_cost = delta_u[blkPos];
cur_change =-1;
}
} else if(n < first_nz_pos_in_cg && ((coef[blkPos] >= 0)?0:1) != signbit) {
cur_cost = 0x7fffffff;
} else {
cur_cost = -delta_u[blkPos];
cur_change = 1;
}
if(cur_cost < min_cost_inc) {
min_cost_inc = cur_cost;
final_change = cur_change;
min_pos = blkPos;
}
} // CG loop
if(q_coef[min_pos] == 32767 || q_coef[min_pos] == -32768) {
final_change = -1;
}
if(coef[min_pos] >= 0) q_coef[min_pos] += final_change;
else q_coef[min_pos] -= final_change;
} // Hide
}
if (last_cg == 1) last_cg=0;
}
#undef SCAN_SET_SIZE
#undef LOG2_SCAN_SET_SIZE
}
}
/**
* \brief inverse quantize transformed and quantized coefficents
*
*/
void dequant(const encoder_state_t * const state, int16_t *q_coef, int16_t *coef, int32_t width, int32_t height,int8_t type, int8_t block_type)
{
const encoder_control_t * const encoder = state->encoder_control;
int32_t shift,add,coeff_q;
int32_t n;
int32_t transform_shift = 15 - encoder->bitdepth - (g_convert_to_bit[ width ] + 2);
int32_t qp_scaled = get_scaled_qp(type, state->global->QP, 0);
shift = 20 - QUANT_SHIFT - transform_shift;
if (encoder->scaling_list.enable)
{
uint32_t log2_tr_size = g_convert_to_bit[ width ] + 2;
int32_t scalinglist_type = (block_type == CU_INTRA ? 0 : 3) + (int8_t)("\0\3\1\2"[type]);
const int32_t *dequant_coef = encoder->scaling_list.de_quant_coeff[log2_tr_size-2][scalinglist_type][qp_scaled%6];
shift += 4;
if (shift >qp_scaled / 6) {
add = 1 << (shift - qp_scaled/6 - 1);
for (n = 0; n < width * height; n++) {
coeff_q = ((q_coef[n] * dequant_coef[n]) + add ) >> (shift - qp_scaled/6);
coef[n] = (int16_t)CLIP(-32768,32767,coeff_q);
}
} else {
for (n = 0; n < width * height; n++) {
// Clip to avoid possible overflow in following shift left operation
coeff_q = CLIP(-32768, 32767, q_coef[n] * dequant_coef[n]);
coef[n] = (int16_t)CLIP(-32768, 32767, coeff_q << (qp_scaled/6 - shift));
}
}
} else {
int32_t scale = g_inv_quant_scales[qp_scaled%6] << (qp_scaled/6);
add = 1 << (shift-1);
for (n = 0; n < width*height; n++) {
coeff_q = (q_coef[n] * scale + add) >> shift;
coef[n] = (int16_t)CLIP(-32768, 32767, coeff_q);
}
}
}
/**
* \brief Quantize residual and get both the reconstruction and coeffs.
*
* \param width Transform width.
* \param color Color.
* \param scan_order Coefficient scan order.
* \param use_trskip Whether transform skip is used.
* \param stride Stride for ref_in, pred_in rec_out and coeff_out.
* \param ref_in Reference pixels.
* \param pred_in Predicted pixels.
* \param rec_out Reconstructed pixels.
* \param coeff_out Coefficients used for reconstruction of rec_out.
*
* \returns Whether coeff_out contains any non-zero coefficients.
*/
int quantize_residual(encoder_state_t *const state,
const cu_info_t *const cur_cu, const int width, const color_t color,
const coeff_scan_order_t scan_order, const int use_trskip,
const int in_stride, const int out_stride,
const pixel_t *const ref_in, const pixel_t *const pred_in,
pixel_t *rec_out, coeff_t *coeff_out)
{
// Temporary arrays to pass data to and from quant and transform functions.
int16_t residual[TR_MAX_WIDTH * TR_MAX_WIDTH];
coeff_t quant_coeff[TR_MAX_WIDTH * TR_MAX_WIDTH];
coeff_t coeff[TR_MAX_WIDTH * TR_MAX_WIDTH];
int has_coeffs = 0;
assert(width <= TR_MAX_WIDTH);
assert(width >= TR_MIN_WIDTH);
// Get residual. (ref_in - pred_in -> residual)
{
int y, x;
for (y = 0; y < width; ++y) {
for (x = 0; x < width; ++x) {
residual[x + y * width] = (int16_t)(ref_in[x + y * in_stride] - pred_in[x + y * in_stride]);
}
}
}
// Transform residual. (residual -> coeff)
if (use_trskip) {
transformskip(state->encoder_control, residual, coeff, width);
} else {
transform2d(state->encoder_control, residual, coeff, width, (color == COLOR_Y ? 0 : 65535));
}
// Quantize coeffs. (coeff -> quant_coeff)
if (state->encoder_control->rdoq_enable) {
int8_t tr_depth = cur_cu->tr_depth - cur_cu->depth;
tr_depth += (cur_cu->part_size == SIZE_NxN ? 1 : 0);
rdoq(state, coeff, quant_coeff, width, width, (color == COLOR_Y ? 0 : 2),
scan_order, cur_cu->type, tr_depth);
} else {
quant(state, coeff, quant_coeff, width, width, (color == COLOR_Y ? 0 : 2),
scan_order, cur_cu->type);
}
// Check if there are any non-zero coefficients.
{
int i;
for (i = 0; i < width * width; ++i) {
if (quant_coeff[i] != 0) {
has_coeffs = 1;
break;
}
}
}
// Copy coefficients to coeff_out.
coefficients_blit(quant_coeff, coeff_out, width, width, width, out_stride);
// Do the inverse quantization and transformation and the reconstruction to
// rec_out.
if (has_coeffs) {
int y, x;
// Get quantized residual. (quant_coeff -> coeff -> residual)
dequant(state, quant_coeff, coeff, width, width, (color == COLOR_Y ? 0 : (color == COLOR_U ? 2 : 3)), cur_cu->type);
if (use_trskip) {
itransformskip(state->encoder_control, residual, coeff, width);
} else {
itransform2d(state->encoder_control, residual, coeff, width, (color == COLOR_Y ? 0 : 65535));
}
// Get quantized reconstruction. (residual + pred_in -> rec_out)
for (y = 0; y < width; ++y) {
for (x = 0; x < width; ++x) {
int16_t val = residual[x + y * width] + pred_in[x + y * in_stride];
rec_out[x + y * out_stride] = (uint8_t)CLIP(0, 255, val);
}
}
} else if (rec_out != pred_in) {
// With no coeffs and rec_out == pred_int we skip copying the coefficients
// because the reconstruction is just the prediction.
int y, x;
for (y = 0; y < width; ++y) {
for (x = 0; x < width; ++x) {
rec_out[x + y * out_stride] = pred_in[x + y * in_stride];
}
}
}
return has_coeffs;
}
/**
* \brief Like quantize_residual except that this uses trskip if that is better.
*
* Using this function saves one step of quantization and inverse quantization
* compared to doing the decision separately from the actual operation.
*
* \param width Transform width.
* \param color Color.
* \param scan_order Coefficient scan order.
* \param trskip_out Whether transform skip is used.
* \param stride Stride for ref_in, pred_in rec_out and coeff_out.
* \param ref_in Reference pixels.
* \param pred_in Predicted pixels.
* \param rec_out Reconstructed pixels.
* \param coeff_out Coefficients used for reconstruction of rec_out.
*
* \returns Whether coeff_out contains any non-zero coefficients.
*/
int quantize_residual_trskip(
encoder_state_t *const state,
const cu_info_t *const cur_cu, const int width, const color_t color,
const coeff_scan_order_t scan_order, int8_t *trskip_out,
const int in_stride, const int out_stride,
const pixel_t *const ref_in, const pixel_t *const pred_in,
pixel_t *rec_out, coeff_t *coeff_out)
{
struct {
pixel_t rec[4*4];
coeff_t coeff[4*4];
uint32_t cost;
int has_coeffs;
} skip, noskip, *best;
const int bit_cost = (int)(state->global->cur_lambda_cost+0.5);
noskip.has_coeffs = quantize_residual(
state, cur_cu, width, color, scan_order,
0, in_stride, 4,
ref_in, pred_in, noskip.rec, noskip.coeff);
noskip.cost = pixels_calc_ssd(ref_in, noskip.rec, in_stride, 4, 4);
noskip.cost += get_coeff_cost(state, noskip.coeff, 4, 0, scan_order) * bit_cost;
skip.cost += get_coeff_cost(state, skip.coeff, 4, 0, scan_order) * bit_cost;
if (noskip.cost <= skip.cost) {
*trskip_out = 0;
best = &noskip;
} else {
*trskip_out = 1;
best = &skip;
}
if (best->has_coeffs || rec_out != pred_in) {
// If there is no residual and reconstruction is already in rec_out,
// we can skip this.
pixels_blit(best->rec, rec_out, width, width, 4, out_stride);
}
coefficients_blit(best->coeff, coeff_out, width, width, 4, out_stride);
return best->has_coeffs;
}
/**
* This function calculates the residual coefficients for a region of the LCU
* (defined by x, y and depth) and updates the reconstruction with the
* kvantized residual.
*
* It handles recursion for transform split, but that is currently only work
* for 64x64 inter to 32x32 transform blocks.
*
* Inputs are:
* - lcu->rec pixels after prediction for the area
* - lcu->ref reference pixels for the area
* - lcu->cu for the area
*
* Outputs are:
* - lcu->rec reconstruction after quantized residual
* - lcu->coeff quantized coefficients for the area
* - lcu->cbf coded block flags for the area
* - lcu->cu.intra[].tr_skip for the area
*/
void quantize_lcu_luma_residual(encoder_state_t * const state, int32_t x, int32_t y, const uint8_t depth, cu_info_t *cur_cu, lcu_t* lcu)
{
// we have 64>>depth transform size
const vector2d_t lcu_px = {x & 0x3f, y & 0x3f};
const int pu_index = PU_INDEX(lcu_px.x / 4, lcu_px.y / 4);
if (cur_cu == NULL) {
cur_cu = &lcu->cu[LCU_CU_OFFSET + (lcu_px.x >> 3) + (lcu_px.y >> 3)*LCU_T_CU_WIDTH];
}
const int8_t width = LCU_WIDTH>>depth;
// Tell clang-analyzer what is up. For some reason it can't figure out from
// asserting just depth.
assert(width == 4 || width == 8 || width == 16 || width == 32 || width == 64);
// Split transform and increase depth
if (depth == 0 || cur_cu->tr_depth > depth) {
int offset = width / 2;
quantize_lcu_luma_residual(state, x, y, depth+1, NULL, lcu);
quantize_lcu_luma_residual(state, x + offset, y, depth+1, NULL, lcu);
quantize_lcu_luma_residual(state, x, y + offset, depth+1, NULL, lcu);
quantize_lcu_luma_residual(state, x + offset, y + offset, depth+1, NULL, lcu);
// Propagate coded block flags from child CUs to parent CU.
if (depth < MAX_DEPTH) {
cu_info_t *cu_a = &lcu->cu[LCU_CU_OFFSET + ((lcu_px.x + offset) >> 3) + (lcu_px.y >> 3) *LCU_T_CU_WIDTH];
cu_info_t *cu_b = &lcu->cu[LCU_CU_OFFSET + (lcu_px.x >> 3) + ((lcu_px.y + offset) >> 3)*LCU_T_CU_WIDTH];
cu_info_t *cu_c = &lcu->cu[LCU_CU_OFFSET + ((lcu_px.x + offset) >> 3) + ((lcu_px.y + offset) >> 3)*LCU_T_CU_WIDTH];
if (cbf_is_set(cu_a->cbf.y, depth+1) || cbf_is_set(cu_b->cbf.y, depth+1) || cbf_is_set(cu_c->cbf.y, depth+1)) {
cbf_set(&cur_cu->cbf.y, depth);
}
}
return;
}
{
const int luma_offset = lcu_px.x + lcu_px.y * LCU_WIDTH;
// Pointers to current location in arrays with prediction.
pixel_t *recbase_y = &lcu->rec.y[luma_offset];
// Pointers to current location in arrays with reference.
const pixel_t *base_y = &lcu->ref.y[luma_offset];
// Pointers to current location in arrays with kvantized coefficients.
coeff_t *orig_coeff_y = &lcu->coeff.y[luma_offset];
coeff_scan_order_t scan_idx_luma = get_scan_order(cur_cu->type, cur_cu->intra[pu_index].mode, depth);
#if OPTIMIZATION_SKIP_RESIDUAL_ON_THRESHOLD
uint32_t residual_sum = 0;
#endif
// Clear coded block flag structures for depths lower than current depth.
// This should ensure that the CBF data doesn't get corrupted if this function
// is called more than once.
cbf_clear(&cur_cu->cbf.y, depth + pu_index);
if (width == 4 &&
state->encoder_control->trskip_enable)
{
// Try quantization with trskip and use it if it's better.
int has_coeffs = quantize_residual_trskip(
state, cur_cu, width, COLOR_Y, scan_idx_luma,
&cur_cu->intra[pu_index].tr_skip,
LCU_WIDTH, LCU_WIDTH,
base_y, recbase_y, recbase_y, orig_coeff_y
);
if (has_coeffs) {
cbf_set(&cur_cu->cbf.y, depth + pu_index);
}
} else {
int has_coeffs = quantize_residual(
state, cur_cu, width, COLOR_Y, scan_idx_luma,
0,
LCU_WIDTH, LCU_WIDTH,
base_y, recbase_y, recbase_y, orig_coeff_y
);
if (has_coeffs) {
cbf_set(&cur_cu->cbf.y, depth + pu_index);
}
}
}
}
void quantize_lcu_chroma_residual(encoder_state_t * const state, int32_t x, int32_t y, const uint8_t depth, cu_info_t *cur_cu, lcu_t* lcu)
{
// we have 64>>depth transform size
const vector2d_t lcu_px = {x & 0x3f, y & 0x3f};
const int pu_index = PU_INDEX(lcu_px.x / 4, lcu_px.y / 4);
const int8_t width = LCU_WIDTH>>depth;
if (cur_cu == NULL) {
cur_cu = &lcu->cu[LCU_CU_OFFSET + (lcu_px.x >> 3) + (lcu_px.y >> 3)*LCU_T_CU_WIDTH];
}
// Tell clang-analyzer what is up. For some reason it can't figure out from
// asserting just depth.
assert(width == 4 || width == 8 || width == 16 || width == 32 || width == 64);
// Split transform and increase depth
if (depth == 0 || cur_cu->tr_depth > depth) {
int offset = width / 2;
quantize_lcu_chroma_residual(state, x, y, depth+1, NULL, lcu);
quantize_lcu_chroma_residual(state, x + offset, y, depth+1, NULL, lcu);
quantize_lcu_chroma_residual(state, x, y + offset, depth+1, NULL, lcu);
quantize_lcu_chroma_residual(state, x + offset, y + offset, depth+1, NULL, lcu);
// Propagate coded block flags from child CUs to parent CU.
if (depth < MAX_DEPTH) {
cu_info_t *cu_a = &lcu->cu[LCU_CU_OFFSET + ((lcu_px.x + offset) >> 3) + (lcu_px.y >> 3) *LCU_T_CU_WIDTH];
cu_info_t *cu_b = &lcu->cu[LCU_CU_OFFSET + (lcu_px.x >> 3) + ((lcu_px.y + offset) >> 3)*LCU_T_CU_WIDTH];
cu_info_t *cu_c = &lcu->cu[LCU_CU_OFFSET + ((lcu_px.x + offset) >> 3) + ((lcu_px.y + offset) >> 3)*LCU_T_CU_WIDTH];
if (cbf_is_set(cu_a->cbf.u, depth+1) || cbf_is_set(cu_b->cbf.u, depth+1) || cbf_is_set(cu_c->cbf.u, depth+1)) {
cbf_set(&cur_cu->cbf.u, depth);
}
if (cbf_is_set(cu_a->cbf.v, depth+1) || cbf_is_set(cu_b->cbf.v, depth+1) || cbf_is_set(cu_c->cbf.v, depth+1)) {
cbf_set(&cur_cu->cbf.v, depth);
}
}
return;
}
// If luma is 4x4, do chroma for the 8x8 luma area when handling the top
// left PU because the coordinates are correct.
if (depth <= MAX_DEPTH || pu_index == 0) {
cbf_clear(&cur_cu->cbf.u, depth);
cbf_clear(&cur_cu->cbf.v, depth);
const int chroma_offset = lcu_px.x / 2 + lcu_px.y / 2 * LCU_WIDTH_C;
pixel_t *recbase_u = &lcu->rec.u[chroma_offset];
pixel_t *recbase_v = &lcu->rec.v[chroma_offset];
const pixel_t *base_u = &lcu->ref.u[chroma_offset];
const pixel_t *base_v = &lcu->ref.v[chroma_offset];
coeff_t *orig_coeff_u = &lcu->coeff.u[chroma_offset];
coeff_t *orig_coeff_v = &lcu->coeff.v[chroma_offset];
coeff_scan_order_t scan_idx_chroma;
int tr_skip = 0;
int chroma_depth = (depth == MAX_PU_DEPTH ? depth - 1 : depth);
int chroma_width = LCU_WIDTH_C >> chroma_depth;
scan_idx_chroma = get_scan_order(cur_cu->type, cur_cu->intra[0].mode_chroma, depth);
if (quantize_residual(state, cur_cu, chroma_width, COLOR_U, scan_idx_chroma, tr_skip, LCU_WIDTH_C, LCU_WIDTH_C, base_u, recbase_u, recbase_u, orig_coeff_u)) {
cbf_set(&cur_cu->cbf.u, depth);
}
if (quantize_residual(state, cur_cu, chroma_width, COLOR_V, scan_idx_chroma, tr_skip, LCU_WIDTH_C, LCU_WIDTH_C, base_v, recbase_v, recbase_v, orig_coeff_v)) {
cbf_set(&cur_cu->cbf.v, depth);
}
}
}