embdrv/sbc/encoder/srce/sbc_dct.c - platform/external/bluetooth/bluedroid - Git at Google

 /******************************************************************************
  *
  *  Copyright (C) 1999-2012 Broadcom Corporation
  *
  *  Licensed under the Apache License, Version 2.0 (the "License");
  *  you may not use this file except in compliance with the License.
  *  You may obtain a copy of the License at:
  *
  *  http://www.apache.org/licenses/LICENSE-2.0
  *
  *  Unless required by applicable law or agreed to in writing, software
  *  distributed under the License is distributed on an "AS IS" BASIS,
  *  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  *  See the License for the specific language governing permissions and
  *  limitations under the License.
  *
  ******************************************************************************/

 /******************************************************************************
  *
  *  source file for fast dct operations
  *
  ******************************************************************************/

 #include "sbc_encoder.h"
 #include "sbc_enc_func_declare.h"
 #include "sbc_dct.h"


 /*******************************************************************************
 **
 ** Function         SBC_FastIDCT8
 **
 ** Description      implementation of fast DCT algorithm by Feig and Winograd
 **
 **
 ** Returns          y = dct(pInVect)
 **
 **
 *******************************************************************************/

 #if (SBC_IS_64_MULT_IN_IDCT == FALSE)
 #define SBC_COS_PI_SUR_4            (0x00005a82)  /* ((0x8000) * 0.7071)     = cos(pi/4) */
 #define SBC_COS_PI_SUR_8            (0x00007641)  /* ((0x8000) * 0.9239)     = (cos(pi/8)) */
 #define SBC_COS_3PI_SUR_8           (0x000030fb)  /* ((0x8000) * 0.3827)     = (cos(3*pi/8)) */
 #define SBC_COS_PI_SUR_16           (0x00007d8a)  /* ((0x8000) * 0.9808))     = (cos(pi/16)) */
 #define SBC_COS_3PI_SUR_16          (0x00006a6d)  /* ((0x8000) * 0.8315))     = (cos(3*pi/16)) */
 #define SBC_COS_5PI_SUR_16          (0x0000471c)  /* ((0x8000) * 0.5556))     = (cos(5*pi/16)) */
 #define SBC_COS_7PI_SUR_16          (0x000018f8)  /* ((0x8000) * 0.1951))     = (cos(7*pi/16)) */
 #define SBC_IDCT_MULT(a,b,c) SBC_MULT_32_16_SIMPLIFIED(a,b,c)
 #else
 #define SBC_COS_PI_SUR_4            (0x5A827999)  /* ((0x80000000) * 0.707106781)      = (cos(pi/4)   ) */
 #define SBC_COS_PI_SUR_8            (0x7641AF3C)  /* ((0x80000000) * 0.923879533)      = (cos(pi/8)   ) */
 #define SBC_COS_3PI_SUR_8           (0x30FBC54D)  /* ((0x80000000) * 0.382683432)      = (cos(3*pi/8) ) */
 #define SBC_COS_PI_SUR_16           (0x7D8A5F3F)  /* ((0x80000000) * 0.98078528 ))     = (cos(pi/16)  ) */
 #define SBC_COS_3PI_SUR_16          (0x6A6D98A4)  /* ((0x80000000) * 0.831469612))     = (cos(3*pi/16)) */
 #define SBC_COS_5PI_SUR_16          (0x471CECE6)  /* ((0x80000000) * 0.555570233))     = (cos(5*pi/16)) */
 #define SBC_COS_7PI_SUR_16          (0x18F8B83C)  /* ((0x80000000) * 0.195090322))     = (cos(7*pi/16)) */
 #define SBC_IDCT_MULT(a,b,c) SBC_MULT_32_32(a,b,c)
 #endif /* SBC_IS_64_MULT_IN_IDCT */

 #if (SBC_FAST_DCT == FALSE)
 extern const SINT16 gas16AnalDCTcoeff8[];
 extern const SINT16 gas16AnalDCTcoeff4[];
 #endif

 void SBC_FastIDCT8(SINT32 *pInVect, SINT32 *pOutVect)
 {
 #if (SBC_FAST_DCT == TRUE)
 #if (SBC_ARM_ASM_OPT==TRUE)
 #else
 #if (SBC_IPAQ_OPT==TRUE)
 #if (SBC_IS_64_MULT_IN_IDCT == TRUE)
     SINT64 s64Temp;
 #endif
 #else
 #if (SBC_IS_64_MULT_IN_IDCT == TRUE)
     SINT32 s32HiTemp;
 #else
     SINT32 s32In2Temp;
     register SINT32 s32In1Temp;
 #endif
 #endif
 #endif

     register SINT32 x0, x1, x2, x3, x4, x5, x6, x7,temp;
     SINT32 res_even[4], res_odd[4];
     /*x0= (pInVect[4])/2 ;*/
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4,pInVect[4], x0);
     /*printf("x0 0x%x = %d = %d * %d\n", x0, x0, SBC_COS_PI_SUR_4, pInVect[4]);*/

     x1 = (pInVect[3] + pInVect[5])  >>1;
     x2 = (pInVect[2] + pInVect[6])  >>1;
     x3 = (pInVect[1] + pInVect[7])  >>1;
     x4 = (pInVect[0] + pInVect[8])  >>1;
     x5 = (pInVect[9] - pInVect[15]) >>1;
     x6 = (pInVect[10] - pInVect[14])>>1;
     x7 = (pInVect[11] - pInVect[13])>>1;

     /* 2-point IDCT of x0 and x4 as in (11) */
     temp = x0 ;
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4, ( x0 + x4 ), x0);          /*x0 = ( x0 + x4 ) * cos(1*pi/4) ; */
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4, ( temp - x4 ), x4);        /*x4 = ( temp - x4 ) * cos(1*pi/4) ; */

     /* rearrangement of x2 and x6 as in (15) */
     x2 -=x6;
     x6 <<= 1 ;

     /* 2-point IDCT of x2 and x6 and post-multiplication as in (15) */
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4,x6, x6); /*x6 = x6 * cos(1*pi/4) ; */
     temp = x2 ;
     SBC_IDCT_MULT(SBC_COS_PI_SUR_8,( x2 + x6 ), x2); /*x2 = ( x2 + x6 ) * cos(1*pi/8) ; */
     SBC_IDCT_MULT(SBC_COS_3PI_SUR_8,( temp - x6 ), x6); /*x6 = ( temp - x6 ) * cos(3*pi/8) ;*/

     /* 4-point IDCT of x0,x2,x4 and x6 as in (11) */
     res_even[ 0 ] = x0 + x2 ;
     res_even[ 1 ] = x4 + x6 ;
     res_even[ 2 ] = x4 - x6 ;
     res_even[ 3 ] = x0 - x2 ;


     /* rearrangement of x1,x3,x5,x7 as in (15) */
     x7 <<= 1 ;
     x5 = ( x5 <<1 ) - x7 ;
     x3 = ( x3 <<1 ) - x5 ;
     x1 -= x3 >>1 ;

     /* two-dimensional IDCT of x1 and x5 */
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4, x5, x5);          /*x5 = x5 * cos(1*pi/4) ; */
     temp = x1 ;
     x1 = x1 + x5 ;
     x5 = temp - x5 ;

     /* rearrangement of x3 and x7 as in (15) */
     x3 -= x7;
     x7 <<= 1 ;
     SBC_IDCT_MULT(SBC_COS_PI_SUR_4, x7, x7);          /*x7 = x7 * cos(1*pi/4) ; */

     /* 2-point IDCT of x3 and x7 and post-multiplication as in (15) */
     temp = x3 ;
     SBC_IDCT_MULT( SBC_COS_PI_SUR_8,( x3 + x7 ), x3);          /*x3 = ( x3 + x7 ) * cos(1*pi/8)  ; */
     SBC_IDCT_MULT( SBC_COS_3PI_SUR_8,( temp - x7 ), x7);          /*x7 = ( temp - x7 ) * cos(3*pi/8) ;*/

     /* 4-point IDCT of x1,x3,x5 and x7 and post multiplication by diagonal matrix as in (14) */
     SBC_IDCT_MULT((SBC_COS_PI_SUR_16),   ( x1 + x3 ) ,   res_odd[0]); /*res_odd[ 0 ] = ( x1 + x3 ) * cos(1*pi/16) ; */
     SBC_IDCT_MULT((SBC_COS_3PI_SUR_16),  ( x5 + x7 ) ,   res_odd[1]); /*res_odd[ 1 ] = ( x5 + x7 ) * cos(3*pi/16) ; */
     SBC_IDCT_MULT((SBC_COS_5PI_SUR_16),  ( x5 - x7 ) ,   res_odd[2]); /*res_odd[ 2 ] = ( x5 - x7 ) * cos(5*pi/16) ; */
     SBC_IDCT_MULT((SBC_COS_7PI_SUR_16),  ( x1 - x3 ) ,  res_odd[3]); /*res_odd[ 3 ] = ( x1 - x3 ) * cos(7*pi/16) ; */

     /* additions and subtractions as in (9) */
     pOutVect[0] = (res_even[ 0 ] + res_odd[ 0 ])  ;
     pOutVect[1] = (res_even[ 1 ] + res_odd[ 1 ])  ;
     pOutVect[2] = (res_even[ 2 ] + res_odd[ 2 ])  ;
     pOutVect[3] = (res_even[ 3 ] + res_odd[ 3 ])  ;
     pOutVect[7] = (res_even[ 0 ] - res_odd[ 0 ])  ;
     pOutVect[6] = (res_even[ 1 ] - res_odd[ 1 ])  ;
     pOutVect[5] = (res_even[ 2 ] - res_odd[ 2 ])  ;
     pOutVect[4] = (res_even[ 3 ] - res_odd[ 3 ])  ;
 #else
     UINT8 Index, k;
     SINT32 temp;
 	/*Calculate 4 subband samples by matrixing*/
     for(Index=0; Index<8; Index++)
     {
         temp = 0;
         for(k=0; k<16; k++)
         {
             /*temp += (SINT32)(((SINT64)M[(Index*strEncParams->numOfSubBands*2)+k] * Y[k]) >> 16 );*/
             temp += (gas16AnalDCTcoeff8[(Index*8*2)+k] * (pInVect[k] >> 16));
             temp += ((gas16AnalDCTcoeff8[(Index*8*2)+k] * (pInVect[k] & 0xFFFF)) >> 16);
         }
         pOutVect[Index] = temp;
     }
 #endif
 /*    printf("pOutVect: 0x%x;0x%x;0x%x;0x%x;0x%x;0x%x;0x%x;0x%x\n",\
         pOutVect[0],pOutVect[1],pOutVect[2],pOutVect[3],pOutVect[4],pOutVect[5],pOutVect[6],pOutVect[7]);*/
 }

 /*******************************************************************************
 **
 ** Function         SBC_FastIDCT4
 **
 ** Description      implementation of fast DCT algorithm by Feig and Winograd
 **
 **
 ** Returns          y = dct(x0)
 **
 **
 *******************************************************************************/
 void SBC_FastIDCT4(SINT32 *pInVect, SINT32 *pOutVect)
 {
 #if (SBC_FAST_DCT == TRUE)
 #if (SBC_ARM_ASM_OPT==TRUE)
 #else
 #if (SBC_IPAQ_OPT==TRUE)
 #if (SBC_IS_64_MULT_IN_IDCT == TRUE)
     SINT64 s64Temp;
 #endif
 #else
 #if (SBC_IS_64_MULT_IN_IDCT == TRUE)
     SINT32 s32HiTemp;
 #else
     UINT16 s32In2Temp;
     SINT32 s32In1Temp;
 #endif
 #endif
 #endif
     SINT32 temp,x2;
     SINT32 tmp[8];

     x2=pInVect[2]>>1;
     temp=(pInVect[0]+pInVect[4]);
     SBC_IDCT_MULT((SBC_COS_PI_SUR_4>>1), temp , tmp[0]);
     tmp[1]=x2-tmp[0];
     tmp[0]+=x2;
     temp=(pInVect[1]+pInVect[3]);
     SBC_IDCT_MULT((SBC_COS_3PI_SUR_8>>1), temp , tmp[3]);
     SBC_IDCT_MULT((SBC_COS_PI_SUR_8>>1), temp , tmp[2]);
     temp=(pInVect[5]-pInVect[7]);
     SBC_IDCT_MULT((SBC_COS_3PI_SUR_8>>1), temp , tmp[5]);
     SBC_IDCT_MULT((SBC_COS_PI_SUR_8>>1), temp , tmp[4]);
     tmp[6]=tmp[2]+tmp[5];
     tmp[7]=tmp[3]-tmp[4];
     pOutVect[0] = (tmp[0]+tmp[6]);
     pOutVect[1] = (tmp[1]+tmp[7]);
     pOutVect[2] = (tmp[1]-tmp[7]);
     pOutVect[3] = (tmp[0]-tmp[6]);
 #else
     UINT8 Index, k;
     SINT32 temp;
 	/*Calculate 4 subband samples by matrixing*/
     for(Index=0; Index<4; Index++)
     {
         temp = 0;
         for(k=0; k<8; k++)
         {
             /*temp += (SINT32)(((SINT64)M[(Index*strEncParams->numOfSubBands*2)+k] * Y[k]) >> 16 ); */
             temp += (gas16AnalDCTcoeff4[(Index*4*2)+k] * (pInVect[k] >> 16));
             temp += ((gas16AnalDCTcoeff4[(Index*4*2)+k] * (pInVect[k] & 0xFFFF)) >> 16);
         }
         pOutVect[Index] = temp;
     }
 #endif
 }
	/******************************************************************************
	*
	* Copyright (C) 1999-2012 Broadcom Corporation
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at:
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	******************************************************************************/

	/******************************************************************************
	*
	* source file for fast dct operations
	*
	******************************************************************************/

	#include "sbc_encoder.h"
	#include "sbc_enc_func_declare.h"
	#include "sbc_dct.h"



	/*******************************************************************************
	**
	** Function SBC_FastIDCT8
	**
	** Description implementation of fast DCT algorithm by Feig and Winograd
	**
	**
	** Returns y = dct(pInVect)
	**
	**
	*******************************************************************************/

	#if (SBC_IS_64_MULT_IN_IDCT == FALSE)
	#define SBC_COS_PI_SUR_4 (0x00005a82) /* ((0x8000) * 0.7071) = cos(pi/4) */
	#define SBC_COS_PI_SUR_8 (0x00007641) /* ((0x8000) * 0.9239) = (cos(pi/8)) */
	#define SBC_COS_3PI_SUR_8 (0x000030fb) /* ((0x8000) * 0.3827) = (cos(3pi/8)) /
	#define SBC_COS_PI_SUR_16 (0x00007d8a) /* ((0x8000) * 0.9808)) = (cos(pi/16)) */
	#define SBC_COS_3PI_SUR_16 (0x00006a6d) /* ((0x8000) * 0.8315)) = (cos(3pi/16)) /
	#define SBC_COS_5PI_SUR_16 (0x0000471c) /* ((0x8000) * 0.5556)) = (cos(5pi/16)) /
	#define SBC_COS_7PI_SUR_16 (0x000018f8) /* ((0x8000) * 0.1951)) = (cos(7pi/16)) /
	#define SBC_IDCT_MULT(a,b,c) SBC_MULT_32_16_SIMPLIFIED(a,b,c)
	#else
	#define SBC_COS_PI_SUR_4 (0x5A827999) /* ((0x80000000) * 0.707106781) = (cos(pi/4) ) */
	#define SBC_COS_PI_SUR_8 (0x7641AF3C) /* ((0x80000000) * 0.923879533) = (cos(pi/8) ) */
	#define SBC_COS_3PI_SUR_8 (0x30FBC54D) /* ((0x80000000) * 0.382683432) = (cos(3pi/8) ) /
	#define SBC_COS_PI_SUR_16 (0x7D8A5F3F) /* ((0x80000000) * 0.98078528 )) = (cos(pi/16) ) */
	#define SBC_COS_3PI_SUR_16 (0x6A6D98A4) /* ((0x80000000) * 0.831469612)) = (cos(3pi/16)) /
	#define SBC_COS_5PI_SUR_16 (0x471CECE6) /* ((0x80000000) * 0.555570233)) = (cos(5pi/16)) /
	#define SBC_COS_7PI_SUR_16 (0x18F8B83C) /* ((0x80000000) * 0.195090322)) = (cos(7pi/16)) /
	#define SBC_IDCT_MULT(a,b,c) SBC_MULT_32_32(a,b,c)
	#endif /* SBC_IS_64_MULT_IN_IDCT */

	#if (SBC_FAST_DCT == FALSE)
	extern const SINT16 gas16AnalDCTcoeff8[];
	extern const SINT16 gas16AnalDCTcoeff4[];
	#endif

	void SBC_FastIDCT8(SINT32 pInVect, SINT32 pOutVect)
	{
	#if (SBC_FAST_DCT == TRUE)
	#if (SBC_ARM_ASM_OPT==TRUE)
	#else
	#if (SBC_IPAQ_OPT==TRUE)
	#if (SBC_IS_64_MULT_IN_IDCT == TRUE)
	SINT64 s64Temp;
	#endif
	#else
	#if (SBC_IS_64_MULT_IN_IDCT == TRUE)
	SINT32 s32HiTemp;
	#else
	SINT32 s32In2Temp;
	register SINT32 s32In1Temp;
	#endif
	#endif
	#endif

	register SINT32 x0, x1, x2, x3, x4, x5, x6, x7,temp;
	SINT32 res_even[4], res_odd[4];
	/x0= (pInVect[4])/2 ;/
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4,pInVect[4], x0);
	/printf("x0 0x%x = %d = %d %d\n", x0, x0, SBC_COS_PI_SUR_4, pInVect[4]);*/

	x1 = (pInVect[3] + pInVect[5]) >>1;
	x2 = (pInVect[2] + pInVect[6]) >>1;
	x3 = (pInVect[1] + pInVect[7]) >>1;
	x4 = (pInVect[0] + pInVect[8]) >>1;
	x5 = (pInVect[9] - pInVect[15]) >>1;
	x6 = (pInVect[10] - pInVect[14])>>1;
	x7 = (pInVect[11] - pInVect[13])>>1;

	/* 2-point IDCT of x0 and x4 as in (11) */
	temp = x0 ;
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4, ( x0 + x4 ), x0); /x0 = ( x0 + x4 ) cos(1pi/4) ; /
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4, ( temp - x4 ), x4); /x4 = ( temp - x4 ) cos(1pi/4) ; /

	/* rearrangement of x2 and x6 as in (15) */
	x2 -=x6;
	x6 <<= 1 ;

	/* 2-point IDCT of x2 and x6 and post-multiplication as in (15) */
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4,x6, x6); /x6 = x6 cos(1pi/4) ; /
	temp = x2 ;
	SBC_IDCT_MULT(SBC_COS_PI_SUR_8,( x2 + x6 ), x2); /x2 = ( x2 + x6 ) cos(1pi/8) ; /
	SBC_IDCT_MULT(SBC_COS_3PI_SUR_8,( temp - x6 ), x6); /x6 = ( temp - x6 ) cos(3pi/8) ;/

	/* 4-point IDCT of x0,x2,x4 and x6 as in (11) */
	res_even[ 0 ] = x0 + x2 ;
	res_even[ 1 ] = x4 + x6 ;
	res_even[ 2 ] = x4 - x6 ;
	res_even[ 3 ] = x0 - x2 ;


	/* rearrangement of x1,x3,x5,x7 as in (15) */
	x7 <<= 1 ;
	x5 = ( x5 <<1 ) - x7 ;
	x3 = ( x3 <<1 ) - x5 ;
	x1 -= x3 >>1 ;

	/* two-dimensional IDCT of x1 and x5 */
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4, x5, x5); /x5 = x5 cos(1pi/4) ; /
	temp = x1 ;
	x1 = x1 + x5 ;
	x5 = temp - x5 ;

	/* rearrangement of x3 and x7 as in (15) */
	x3 -= x7;
	x7 <<= 1 ;
	SBC_IDCT_MULT(SBC_COS_PI_SUR_4, x7, x7); /x7 = x7 cos(1pi/4) ; /

	/* 2-point IDCT of x3 and x7 and post-multiplication as in (15) */
	temp = x3 ;
	SBC_IDCT_MULT( SBC_COS_PI_SUR_8,( x3 + x7 ), x3); /x3 = ( x3 + x7 ) cos(1pi/8) ; /
	SBC_IDCT_MULT( SBC_COS_3PI_SUR_8,( temp - x7 ), x7); /x7 = ( temp - x7 ) cos(3pi/8) ;/

	/* 4-point IDCT of x1,x3,x5 and x7 and post multiplication by diagonal matrix as in (14) */
	SBC_IDCT_MULT((SBC_COS_PI_SUR_16), ( x1 + x3 ) , res_odd[0]); /res_odd[ 0 ] = ( x1 + x3 ) cos(1pi/16) ; /
	SBC_IDCT_MULT((SBC_COS_3PI_SUR_16), ( x5 + x7 ) , res_odd[1]); /res_odd[ 1 ] = ( x5 + x7 ) cos(3pi/16) ; /
	SBC_IDCT_MULT((SBC_COS_5PI_SUR_16), ( x5 - x7 ) , res_odd[2]); /res_odd[ 2 ] = ( x5 - x7 ) cos(5pi/16) ; /
	SBC_IDCT_MULT((SBC_COS_7PI_SUR_16), ( x1 - x3 ) , res_odd[3]); /res_odd[ 3 ] = ( x1 - x3 ) cos(7pi/16) ; /

	/* additions and subtractions as in (9) */
	pOutVect[0] = (res_even[ 0 ] + res_odd[ 0 ]) ;
	pOutVect[1] = (res_even[ 1 ] + res_odd[ 1 ]) ;
	pOutVect[2] = (res_even[ 2 ] + res_odd[ 2 ]) ;
	pOutVect[3] = (res_even[ 3 ] + res_odd[ 3 ]) ;
	pOutVect[7] = (res_even[ 0 ] - res_odd[ 0 ]) ;
	pOutVect[6] = (res_even[ 1 ] - res_odd[ 1 ]) ;
	pOutVect[5] = (res_even[ 2 ] - res_odd[ 2 ]) ;
	pOutVect[4] = (res_even[ 3 ] - res_odd[ 3 ]) ;
	#else
	UINT8 Index, k;
	SINT32 temp;
	/Calculate 4 subband samples by matrixing/
	for(Index=0; Index<8; Index++)
	{
	temp = 0;
	for(k=0; k<16; k++)
	{
	/temp += (SINT32)(((SINT64)M[(IndexstrEncParams->numOfSubBands2)+k] Y[k]) >> 16 );*/
	temp += (gas16AnalDCTcoeff8[(Index82)+k] * (pInVect[k] >> 16));
	temp += ((gas16AnalDCTcoeff8[(Index82)+k] * (pInVect[k] & 0xFFFF)) >> 16);
	}
	pOutVect[Index] = temp;
	}
	#endif
	/* printf("pOutVect: 0x%x;0x%x;0x%x;0x%x;0x%x;0x%x;0x%x;0x%x\n",\
	pOutVect[0],pOutVect[1],pOutVect[2],pOutVect[3],pOutVect[4],pOutVect[5],pOutVect[6],pOutVect[7]);*/
	}

	/*******************************************************************************
	**
	** Function SBC_FastIDCT4
	**
	** Description implementation of fast DCT algorithm by Feig and Winograd
	**
	**
	** Returns y = dct(x0)
	**
	**
	*******************************************************************************/
	void SBC_FastIDCT4(SINT32 pInVect, SINT32 pOutVect)
	{
	#if (SBC_FAST_DCT == TRUE)
	#if (SBC_ARM_ASM_OPT==TRUE)
	#else
	#if (SBC_IPAQ_OPT==TRUE)
	#if (SBC_IS_64_MULT_IN_IDCT == TRUE)
	SINT64 s64Temp;
	#endif
	#else
	#if (SBC_IS_64_MULT_IN_IDCT == TRUE)
	SINT32 s32HiTemp;
	#else
	UINT16 s32In2Temp;
	SINT32 s32In1Temp;
	#endif
	#endif
	#endif
	SINT32 temp,x2;
	SINT32 tmp[8];

	x2=pInVect[2]>>1;
	temp=(pInVect[0]+pInVect[4]);
	SBC_IDCT_MULT((SBC_COS_PI_SUR_4>>1), temp , tmp[0]);
	tmp[1]=x2-tmp[0];
	tmp[0]+=x2;
	temp=(pInVect[1]+pInVect[3]);
	SBC_IDCT_MULT((SBC_COS_3PI_SUR_8>>1), temp , tmp[3]);
	SBC_IDCT_MULT((SBC_COS_PI_SUR_8>>1), temp , tmp[2]);
	temp=(pInVect[5]-pInVect[7]);
	SBC_IDCT_MULT((SBC_COS_3PI_SUR_8>>1), temp , tmp[5]);
	SBC_IDCT_MULT((SBC_COS_PI_SUR_8>>1), temp , tmp[4]);
	tmp[6]=tmp[2]+tmp[5];
	tmp[7]=tmp[3]-tmp[4];
	pOutVect[0] = (tmp[0]+tmp[6]);
	pOutVect[1] = (tmp[1]+tmp[7]);
	pOutVect[2] = (tmp[1]-tmp[7]);
	pOutVect[3] = (tmp[0]-tmp[6]);
	#else
	UINT8 Index, k;
	SINT32 temp;
	/Calculate 4 subband samples by matrixing/
	for(Index=0; Index<4; Index++)
	{
	temp = 0;
	for(k=0; k<8; k++)
	{
	/temp += (SINT32)(((SINT64)M[(IndexstrEncParams->numOfSubBands2)+k] Y[k]) >> 16 ); */
	temp += (gas16AnalDCTcoeff4[(Index42)+k] * (pInVect[k] >> 16));
	temp += ((gas16AnalDCTcoeff4[(Index42)+k] * (pInVect[k] & 0xFFFF)) >> 16);
	}
	pOutVect[Index] = temp;
	}
	#endif
	}