257 lines
8.6 KiB
C
257 lines
8.6 KiB
C
/******************************************************************************
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*
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* Copyright (C) 2012 Ittiam Systems Pvt Ltd, Bangalore
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at:
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*
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******************************************************************************/
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/**
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*******************************************************************************
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* @file
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* ihevc_chroma_iquant_itrans_recon.c
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*
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* @brief
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* Contains function definitions for inverse quantization, inverse
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* transform and reconstruction of chroma interleaved data.
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*
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* @author
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* 100470
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*
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* @par List of Functions:
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* - ihevc_chroma_iquant_itrans_recon_4x4()
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*
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* @remarks
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* None
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*
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*******************************************************************************
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*/
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#include <stdio.h>
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#include <string.h>
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#include "ihevc_typedefs.h"
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#include "ihevc_macros.h"
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#include "ihevc_platform_macros.h"
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#include "ihevc_defs.h"
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#include "ihevc_trans_tables.h"
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#include "ihevc_chroma_iquant_itrans_recon.h"
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#include "ihevc_func_selector.h"
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#include "ihevc_trans_macros.h"
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/* All the functions work one component(U or V) of interleaved data depending upon pointers passed to it */
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/* Data visualization */
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/* U V U V U V U V */
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/* U V U V U V U V */
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/* U V U V U V U V */
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/* U V U V U V U V */
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/* If the pointer points to first byte of above stream (U) , functions will operate on U component */
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/* If the pointer points to second byte of above stream (V) , functions will operate on V component */
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/**
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*******************************************************************************
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*
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* @brief
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* This function performs inverse quantization, inverse transform and
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* reconstruction for 4x4 input block
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*
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* @par Description:
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* Performs inverse quantization , inverse transform and adds the
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* prediction data and clips output to 8 bit
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*
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* @param[in] pi2_src
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* Input 4x4 coefficients
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*
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* @param[in] pi2_tmp
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* Temporary 4x4 buffer for storing inverse transform
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* 1st stage output
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*
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* @param[in] pu1_pred
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* Prediction 4x4 block
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*
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* @param[in] pi2_dequant_coeff
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* Dequant Coeffs
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*
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* @param[out] pu1_dst
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* Output 4x4 block
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*
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* @param[in] qp_div
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* Quantization parameter / 6
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*
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* @param[in] qp_rem
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* Quantization parameter % 6
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*
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* @param[in] src_strd
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* Input stride
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*
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* @param[in] pred_strd
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* Prediction stride
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*
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* @param[in] dst_strd
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* Output Stride
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*
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* @param[in] zero_cols
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* Zero columns in pi2_src
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*
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* @param[in] zero_rows
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* Zero Rows in pi2_src
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*
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* @returns Void
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*
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* @remarks
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* None
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*
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*******************************************************************************
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*/
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void ihevc_chroma_iquant_itrans_recon_4x4(WORD16 *pi2_src,
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WORD16 *pi2_tmp,
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UWORD8 *pu1_pred,
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WORD16 *pi2_dequant_coeff,
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UWORD8 *pu1_dst,
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WORD32 qp_div, /* qpscaled / 6 */
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WORD32 qp_rem, /* qpscaled % 6 */
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WORD32 src_strd,
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WORD32 pred_strd,
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WORD32 dst_strd,
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WORD32 zero_cols,
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WORD32 zero_rows)
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{
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UNUSED(zero_rows);
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/* Inverse Transform */
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{
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WORD32 j;
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WORD32 e[2], o[2];
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WORD32 add;
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WORD32 shift;
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WORD16 *pi2_tmp_orig;
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WORD32 shift_iq;
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WORD32 trans_size;
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/* Inverse Quantization constants */
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{
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WORD32 log2_trans_size, bit_depth;
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log2_trans_size = 2;
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bit_depth = 8 + 0;
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shift_iq = bit_depth + log2_trans_size - 5;
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}
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trans_size = TRANS_SIZE_4;
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pi2_tmp_orig = pi2_tmp;
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/* Inverse Transform 1st stage */
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shift = IT_SHIFT_STAGE_1;
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add = 1 << (shift - 1);
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for(j = 0; j < trans_size; j++)
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{
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/* Checking for Zero Cols */
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if((zero_cols & 1) == 1)
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{
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memset(pi2_tmp, 0, trans_size * sizeof(WORD16));
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}
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else
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{
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WORD32 iq_tmp_1, iq_tmp_2;
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/* Utilizing symmetry properties to the maximum to minimize the number of multiplications */
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IQUANT_4x4(iq_tmp_1,
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pi2_src[1 * src_strd],
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pi2_dequant_coeff[1 * trans_size] * g_ihevc_iquant_scales[qp_rem],
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shift_iq, qp_div);
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IQUANT_4x4(iq_tmp_2,
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pi2_src[3 * src_strd],
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pi2_dequant_coeff[3 * trans_size] * g_ihevc_iquant_scales[qp_rem],
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shift_iq, qp_div);
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o[0] = g_ai2_ihevc_trans_4[1][0] * iq_tmp_1
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+ g_ai2_ihevc_trans_4[3][0] * iq_tmp_2;
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o[1] = g_ai2_ihevc_trans_4[1][1] * iq_tmp_1
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+ g_ai2_ihevc_trans_4[3][1] * iq_tmp_2;
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IQUANT_4x4(iq_tmp_1,
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pi2_src[0 * src_strd],
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pi2_dequant_coeff[0 * trans_size] * g_ihevc_iquant_scales[qp_rem],
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shift_iq, qp_div);
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IQUANT_4x4(iq_tmp_2,
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pi2_src[2 * src_strd],
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pi2_dequant_coeff[2 * trans_size] * g_ihevc_iquant_scales[qp_rem],
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shift_iq, qp_div);
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e[0] = g_ai2_ihevc_trans_4[0][0] * iq_tmp_1
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+ g_ai2_ihevc_trans_4[2][0] * iq_tmp_2;
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e[1] = g_ai2_ihevc_trans_4[0][1] * iq_tmp_1
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+ g_ai2_ihevc_trans_4[2][1] * iq_tmp_2;
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pi2_tmp[0] =
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CLIP_S16(((e[0] + o[0] + add) >> shift));
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pi2_tmp[1] =
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CLIP_S16(((e[1] + o[1] + add) >> shift));
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pi2_tmp[2] =
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CLIP_S16(((e[1] - o[1] + add) >> shift));
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pi2_tmp[3] =
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CLIP_S16(((e[0] - o[0] + add) >> shift));
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}
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pi2_src++;
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pi2_dequant_coeff++;
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pi2_tmp += trans_size;
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zero_cols = zero_cols >> 1;
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}
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pi2_tmp = pi2_tmp_orig;
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/* Inverse Transform 2nd stage */
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shift = IT_SHIFT_STAGE_2;
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add = 1 << (shift - 1);
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for(j = 0; j < trans_size; j++)
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{
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WORD32 itrans_out;
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/* Utilizing symmetry properties to the maximum to minimize the number of multiplications */
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o[0] = g_ai2_ihevc_trans_4[1][0] * pi2_tmp[trans_size]
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+ g_ai2_ihevc_trans_4[3][0]
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* pi2_tmp[3 * trans_size];
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o[1] = g_ai2_ihevc_trans_4[1][1] * pi2_tmp[trans_size]
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+ g_ai2_ihevc_trans_4[3][1]
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* pi2_tmp[3 * trans_size];
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e[0] = g_ai2_ihevc_trans_4[0][0] * pi2_tmp[0]
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+ g_ai2_ihevc_trans_4[2][0]
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* pi2_tmp[2 * trans_size];
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e[1] = g_ai2_ihevc_trans_4[0][1] * pi2_tmp[0]
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+ g_ai2_ihevc_trans_4[2][1]
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* pi2_tmp[2 * trans_size];
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itrans_out =
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CLIP_S16(((e[0] + o[0] + add) >> shift));
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pu1_dst[0 * 2] = CLIP_U8((itrans_out + pu1_pred[0 * 2]));
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itrans_out =
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CLIP_S16(((e[1] + o[1] + add) >> shift));
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pu1_dst[1 * 2] = CLIP_U8((itrans_out + pu1_pred[1 * 2]));
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itrans_out =
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CLIP_S16(((e[1] - o[1] + add) >> shift));
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pu1_dst[2 * 2] = CLIP_U8((itrans_out + pu1_pred[2 * 2]));
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itrans_out =
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CLIP_S16(((e[0] - o[0] + add) >> shift));
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pu1_dst[3 * 2] = CLIP_U8((itrans_out + pu1_pred[3 * 2]));
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pi2_tmp++;
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pu1_pred += pred_strd;
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pu1_dst += dst_strd;
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}
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}
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}
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