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-
-/* -----------------------------------------------------------------------------------------------------------
-Software License for The Fraunhofer FDK AAC Codec Library for Android
-
-© Copyright 1995 - 2013 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
- All rights reserved.
-
- 1. INTRODUCTION
-The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements
-the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio.
-This FDK AAC Codec software is intended to be used on a wide variety of Android devices.
-
-AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual
-audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by
-independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part
-of the MPEG specifications.
-
-Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer)
-may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners
-individually for the purpose of encoding or decoding bit streams in products that are compliant with
-the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license
-these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec
-software may already be covered under those patent licenses when it is used for those licensed purposes only.
-
-Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality,
-are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional
-applications information and documentation.
-
-2. COPYRIGHT LICENSE
-
-Redistribution and use in source and binary forms, with or without modification, are permitted without
-payment of copyright license fees provided that you satisfy the following conditions:
-
-You must retain the complete text of this software license in redistributions of the FDK AAC Codec or
-your modifications thereto in source code form.
-
-You must retain the complete text of this software license in the documentation and/or other materials
-provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form.
-You must make available free of charge copies of the complete source code of the FDK AAC Codec and your
-modifications thereto to recipients of copies in binary form.
-
-The name of Fraunhofer may not be used to endorse or promote products derived from this library without
-prior written permission.
-
-You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec
-software or your modifications thereto.
-
-Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software
-and the date of any change. For modified versions of the FDK AAC Codec, the term
-"Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term
-"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android."
-
-3. NO PATENT LICENSE
-
-NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer,
-ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with
-respect to this software.
-
-You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized
-by appropriate patent licenses.
-
-4. DISCLAIMER
-
-This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
-"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties
-of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR
-CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages,
-including but not limited to procurement of substitute goods or services; loss of use, data, or profits,
-or business interruption, however caused and on any theory of liability, whether in contract, strict
-liability, or tort (including negligence), arising in any way out of the use of this software, even if
-advised of the possibility of such damage.
-
-5. CONTACT INFORMATION
-
-Fraunhofer Institute for Integrated Circuits IIS
-Attention: Audio and Multimedia Departments - FDK AAC LL
-Am Wolfsmantel 33
-91058 Erlangen, Germany
-
-www.iis.fraunhofer.de/amm
-amm-info@iis.fraunhofer.de
------------------------------------------------------------------------------------------------------------ */
-
-/*************************** Fraunhofer IIS FDK Tools **********************
-
- Author(s): Josef Hoepfl, DSP Solutions
- Description: Fix point FFT
-
-******************************************************************************/
-
-#include "fft.h"
-
-#include "fft_rad2.h"
-#include "FDK_tools_rom.h"
-
-
-
-
-
-#define F3C(x) STC(x)
-
-#define C31 (F3C(0x91261468)) /* FL2FXCONST_DBL(-0.86602540) */
-
-/* Performs the FFT of length 3 according to the algorithm after winograd.
- No scaling of the input vector because the scaling is already done in the rotation vector. */
-static FORCEINLINE void fft3(FIXP_DBL *RESTRICT pDat)
-{
- FIXP_DBL r1,r2;
- FIXP_DBL s1,s2;
- /* real part */
- r1 = pDat[2] + pDat[4];
- r2 = fMult((pDat[2] - pDat[4]), C31);
- pDat[0] = pDat[0] + r1;
- r1 = pDat[0] - r1 - (r1>>1);
-
- /* imaginary part */
- s1 = pDat[3] + pDat[5];
- s2 = fMult((pDat[3] - pDat[5]), C31);
- pDat[1] = pDat[1] + s1;
- s1 = pDat[1] - s1 - (s1>>1);
-
- /* combination */
- pDat[2] = r1 - s2;
- pDat[4] = r1 + s2;
- pDat[3] = s1 + r2;
- pDat[5] = s1 - r2;
-}
-
-
-#define F5C(x) STC(x)
-
-#define C51 (F5C(0x79bc3854)) /* FL2FXCONST_DBL( 0.95105652) */
-#define C52 (F5C(0x9d839db0)) /* FL2FXCONST_DBL(-1.53884180/2) */
-#define C53 (F5C(0xd18053ce)) /* FL2FXCONST_DBL(-0.36327126) */
-#define C54 (F5C(0x478dde64)) /* FL2FXCONST_DBL( 0.55901699) */
-#define C55 (F5C(0xb0000001)) /* FL2FXCONST_DBL(-1.25/2) */
-
-/* performs the FFT of length 5 according to the algorithm after winograd */
-static FORCEINLINE void fft5(FIXP_DBL *RESTRICT pDat)
-{
- FIXP_DBL r1,r2,r3,r4;
- FIXP_DBL s1,s2,s3,s4;
- FIXP_DBL t;
-
- /* real part */
- r1 = pDat[2] + pDat[8];
- r4 = pDat[2] - pDat[8];
- r3 = pDat[4] + pDat[6];
- r2 = pDat[4] - pDat[6];
- t = fMult((r1-r3), C54);
- r1 = r1 + r3;
- pDat[0] = pDat[0] + r1;
- /* Bit shift left because of the constant C55 which was scaled with the factor 0.5 because of the representation of
- the values as fracts */
- r1 = pDat[0] + (fMultDiv2(r1, C55) <<(2));
- r3 = r1 - t;
- r1 = r1 + t;
- t = fMult((r4 + r2), C51);
- /* Bit shift left because of the constant C55 which was scaled with the factor 0.5 because of the representation of
- the values as fracts */
- r4 = t + (fMultDiv2(r4, C52) <<(2));
- r2 = t + fMult(r2, C53);
-
- /* imaginary part */
- s1 = pDat[3] + pDat[9];
- s4 = pDat[3] - pDat[9];
- s3 = pDat[5] + pDat[7];
- s2 = pDat[5] - pDat[7];
- t = fMult((s1 - s3), C54);
- s1 = s1 + s3;
- pDat[1] = pDat[1] + s1;
- /* Bit shift left because of the constant C55 which was scaled with the factor 0.5 because of the representation of
- the values as fracts */
- s1 = pDat[1] + (fMultDiv2(s1, C55) <<(2));
- s3 = s1 - t;
- s1 = s1 + t;
- t = fMult((s4 + s2), C51);
- /* Bit shift left because of the constant C55 which was scaled with the factor 0.5 because of the representation of
- the values as fracts */
- s4 = t + (fMultDiv2(s4, C52) <<(2));
- s2 = t + fMult(s2, C53);
-
- /* combination */
- pDat[2] = r1 + s2;
- pDat[8] = r1 - s2;
- pDat[4] = r3 - s4;
- pDat[6] = r3 + s4;
-
- pDat[3] = s1 - r2;
- pDat[9] = s1 + r2;
- pDat[5] = s3 + r4;
- pDat[7] = s3 - r4;
-}
-
-
-
-
-#define N3 3
-#define N5 5
-#define N6 6
-#define N15 15
-
-/* Performs the FFT of length 15. It is split into FFTs of length 3 and length 5. */
-static inline void fft15(FIXP_DBL *pInput)
-{
- FIXP_DBL aDst[2*N15];
- FIXP_DBL aDst1[2*N15];
- int i,k,l;
-
- /* Sort input vector for fft's of length 3
- input3(0:2) = [input(0) input(5) input(10)];
- input3(3:5) = [input(3) input(8) input(13)];
- input3(6:8) = [input(6) input(11) input(1)];
- input3(9:11) = [input(9) input(14) input(4)];
- input3(12:14) = [input(12) input(2) input(7)]; */
- {
- const FIXP_DBL *pSrc = pInput;
- FIXP_DBL *RESTRICT pDst = aDst;
- /* Merge 3 loops into one, skip call of fft3 */
- for(i=0,l=0,k=0; i<N5; i++, k+=6)
- {
- pDst[k+0] = pSrc[l];
- pDst[k+1] = pSrc[l+1];
- l += 2*N5;
- if (l >= (2*N15))
- l -= (2*N15);
-
- pDst[k+2] = pSrc[l];
- pDst[k+3] = pSrc[l+1];
- l += 2*N5;
- if (l >= (2*N15))
- l -= (2*N15);
- pDst[k+4] = pSrc[l];
- pDst[k+5] = pSrc[l+1];
- l += (2*N5) + (2*N3);
- if (l >= (2*N15))
- l -= (2*N15);
-
- /* fft3 merged with shift right by 2 loop */
- FIXP_DBL r1,r2,r3;
- FIXP_DBL s1,s2;
- /* real part */
- r1 = pDst[k+2] + pDst[k+4];
- r2 = fMult((pDst[k+2] - pDst[k+4]), C31);
- s1 = pDst[k+0];
- pDst[k+0] = (s1 + r1)>>2;
- r1 = s1 - (r1>>1);
-
- /* imaginary part */
- s1 = pDst[k+3] + pDst[k+5];
- s2 = fMult((pDst[k+3] - pDst[k+5]), C31);
- r3 = pDst[k+1];
- pDst[k+1] = (r3 + s1)>>2;
- s1 = r3 - (s1>>1);
-
- /* combination */
- pDst[k+2] = (r1 - s2)>>2;
- pDst[k+4] = (r1 + s2)>>2;
- pDst[k+3] = (s1 + r2)>>2;
- pDst[k+5] = (s1 - r2)>>2;
- }
- }
- /* Sort input vector for fft's of length 5
- input5(0:4) = [output3(0) output3(3) output3(6) output3(9) output3(12)];
- input5(5:9) = [output3(1) output3(4) output3(7) output3(10) output3(13)];
- input5(10:14) = [output3(2) output3(5) output3(8) output3(11) output3(14)]; */
- /* Merge 2 loops into one, brings about 10% */
- {
- const FIXP_DBL *pSrc = aDst;
- FIXP_DBL *RESTRICT pDst = aDst1;
- for(i=0,l=0,k=0; i<N3; i++, k+=10)
- {
- l = 2*i;
- pDst[k+0] = pSrc[l+0];
- pDst[k+1] = pSrc[l+1];
- pDst[k+2] = pSrc[l+0+(2*N3)];
- pDst[k+3] = pSrc[l+1+(2*N3)];
- pDst[k+4] = pSrc[l+0+(4*N3)];
- pDst[k+5] = pSrc[l+1+(4*N3)];
- pDst[k+6] = pSrc[l+0+(6*N3)];
- pDst[k+7] = pSrc[l+1+(6*N3)];
- pDst[k+8] = pSrc[l+0+(8*N3)];
- pDst[k+9] = pSrc[l+1+(8*N3)];
- fft5(&pDst[k]);
- }
- }
- /* Sort output vector of length 15
- output = [out5(0) out5(6) out5(12) out5(3) out5(9)
- out5(10) out5(1) out5(7) out5(13) out5(4)
- out5(5) out5(11) out5(2) out5(8) out5(14)]; */
- /* optimize clumsy loop, brings about 5% */
- {
- const FIXP_DBL *pSrc = aDst1;
- FIXP_DBL *RESTRICT pDst = pInput;
- for(i=0,l=0,k=0; i<N3; i++, k+=10)
- {
- pDst[k+0] = pSrc[l];
- pDst[k+1] = pSrc[l+1];
- l += (2*N6);
- if (l >= (2*N15))
- l -= (2*N15);
- pDst[k+2] = pSrc[l];
- pDst[k+3] = pSrc[l+1];
- l += (2*N6);
- if (l >= (2*N15))
- l -= (2*N15);
- pDst[k+4] = pSrc[l];
- pDst[k+5] = pSrc[l+1];
- l += (2*N6);
- if (l >= (2*N15))
- l -= (2*N15);
- pDst[k+6] = pSrc[l];
- pDst[k+7] = pSrc[l+1];
- l += (2*N6);
- if (l >= (2*N15))
- l -= (2*N15);
- pDst[k+8] = pSrc[l];
- pDst[k+9] = pSrc[l+1];
- l += 2; /* no modulo check needed, it cannot occur */
- }
- }
-}
-
-#define W_PiFOURTH STC(0x5a82799a)
-#ifndef SUMDIFF_PIFOURTH
-#define SUMDIFF_PIFOURTH(diff,sum,a,b) \
- { \
- FIXP_DBL wa, wb;\
- wa = fMultDiv2(a, W_PiFOURTH);\
- wb = fMultDiv2(b, W_PiFOURTH);\
- diff = wb - wa;\
- sum = wb + wa;\
- }
-#endif
-
-/* This version is more overflow save, but less cycle optimal. */
-#define SUMDIFF_EIGTH(x, y, ix, iy, vr, vi, ur, ui) \
- vr = (x[ 0 + ix]>>1) + (x[16 + ix]>>1); /* Re A + Re B */ \
- vi = (x[ 8 + ix]>>1) + (x[24 + ix]>>1); /* Re C + Re D */ \
- ur = (x[ 1 + ix]>>1) + (x[17 + ix]>>1); /* Im A + Im B */ \
- ui = (x[ 9 + ix]>>1) + (x[25 + ix]>>1); /* Im C + Im D */ \
- y[ 0 + iy] = vr + vi; /* Re A' = ReA + ReB +ReC + ReD */ \
- y[ 4 + iy] = vr - vi; /* Re C' = -(ReC+ReD) + (ReA+ReB) */ \
- y[ 1 + iy] = ur + ui; /* Im A' = sum of imag values */ \
- y[ 5 + iy] = ur - ui; /* Im C' = -Im C -Im D +Im A +Im B */ \
- vr -= x[16 + ix]; /* Re A - Re B */ \
- vi = vi - x[24 + ix]; /* Re C - Re D */ \
- ur -= x[17 + ix]; /* Im A - Im B */ \
- ui = ui - x[25 + ix]; /* Im C - Im D */ \
- y[ 2 + iy] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */ \
- y[ 6 + iy] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */ \
- y[ 3 + iy] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */ \
- y[ 7 + iy] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
-static const FIXP_STP fft16_w16[2] = { STCP(0x7641af3d, 0x30fbc54d), STCP(0x30fbc54d, 0x7641af3d) };
-
-LNK_SECTION_CODE_L1
-inline void fft_16(FIXP_DBL *RESTRICT x)
-{
- FIXP_DBL vr, vi, ur, ui;
- FIXP_DBL y[32];
-
- SUMDIFF_EIGTH(x, y, 0, 0, vr, vi, ur, ui);
- SUMDIFF_EIGTH(x, y, 4, 8, vr, vi, ur, ui);
- SUMDIFF_EIGTH(x, y, 2, 16, vr, vi, ur, ui);
- SUMDIFF_EIGTH(x, y, 6, 24, vr, vi, ur, ui);
-
-// xt1 = 0
-// xt2 = 8
- vr = y[ 8];
- vi = y[ 9];
- ur = y[ 0]>>1;
- ui = y[ 1]>>1;
- x[ 0] = ur + (vr>>1);
- x[ 1] = ui + (vi>>1);
- x[ 8] = ur - (vr>>1);
- x[ 9] = ui - (vi>>1);
-
-// xt1 = 4
-// xt2 = 12
- vr = y[13];
- vi = y[12];
- ur = y[ 4]>>1;
- ui = y[ 5]>>1;
- x[ 4] = ur + (vr>>1);
- x[ 5] = ui - (vi>>1);
- x[12] = ur - (vr>>1);
- x[13] = ui + (vi>>1);
-
-// xt1 = 16
-// xt2 = 24
- vr = y[24];
- vi = y[25];
- ur = y[16]>>1;
- ui = y[17]>>1;
- x[16] = ur + (vr>>1);
- x[17] = ui + (vi>>1);
- x[24] = ur - (vr>>1);
- x[25] = ui - (vi>>1);
-
-// xt1 = 20
-// xt2 = 28
- vr = y[29];
- vi = y[28];
- ur = y[20]>>1;
- ui = y[21]>>1;
- x[20] = ur + (vr>>1);
- x[21] = ui - (vi>>1);
- x[28] = ur - (vr>>1);
- x[29] = ui + (vi>>1);
-
- // xt1 = 2
-// xt2 = 10
- SUMDIFF_PIFOURTH(vi, vr, y[10], y[11])
- //vr = fMultDiv2((y[11] + y[10]),W_PiFOURTH);
- //vi = fMultDiv2((y[11] - y[10]),W_PiFOURTH);
- ur = y[ 2];
- ui = y[ 3];
- x[ 2] = (ur>>1) + vr;
- x[ 3] = (ui>>1) + vi;
- x[10] = (ur>>1) - vr;
- x[11] = (ui>>1) - vi;
-
-// xt1 = 6
-// xt2 = 14
- SUMDIFF_PIFOURTH(vr, vi, y[14], y[15])
- ur = y[ 6];
- ui = y[ 7];
- x[ 6] = (ur>>1) + vr;
- x[ 7] = (ui>>1) - vi;
- x[14] = (ur>>1) - vr;
- x[15] = (ui>>1) + vi;
-
-// xt1 = 18
-// xt2 = 26
- SUMDIFF_PIFOURTH(vi, vr, y[26], y[27])
- ur = y[18];
- ui = y[19];
- x[18] = (ur>>1) + vr;
- x[19] = (ui>>1) + vi;
- x[26] = (ur>>1) - vr;
- x[27] = (ui>>1) - vi;
-
-// xt1 = 22
-// xt2 = 30
- SUMDIFF_PIFOURTH(vr, vi, y[30], y[31])
- ur = y[22];
- ui = y[23];
- x[22] = (ur>>1) + vr;
- x[23] = (ui>>1) - vi;
- x[30] = (ur>>1) - vr;
- x[31] = (ui>>1) + vi;
-
-// xt1 = 0
-// xt2 = 16
- vr = x[16];
- vi = x[17];
- ur = x[ 0]>>1;
- ui = x[ 1]>>1;
- x[ 0] = ur + (vr>>1);
- x[ 1] = ui + (vi>>1);
- x[16] = ur - (vr>>1);
- x[17] = ui - (vi>>1);
-
-// xt1 = 8
-// xt2 = 24
- vi = x[24];
- vr = x[25];
- ur = x[ 8]>>1;
- ui = x[ 9]>>1;
- x[ 8] = ur + (vr>>1);
- x[ 9] = ui - (vi>>1);
- x[24] = ur - (vr>>1);
- x[25] = ui + (vi>>1);
-
-// xt1 = 2
-// xt2 = 18
- cplxMultDiv2(&vi, &vr, x[19], x[18], fft16_w16[0]);
- ur = x[ 2];
- ui = x[ 3];
- x[ 2] = (ur>>1) + vr;
- x[ 3] = (ui>>1) + vi;
- x[18] = (ur>>1) - vr;
- x[19] = (ui>>1) - vi;
-
-// xt1 = 10
-// xt2 = 26
- cplxMultDiv2(&vr, &vi, x[27], x[26], fft16_w16[0]);
- ur = x[10];
- ui = x[11];
- x[10] = (ur>>1) + vr;
- x[11] = (ui>>1) - vi;
- x[26] = (ur>>1) - vr;
- x[27] = (ui>>1) + vi;
-
-// xt1 = 4
-// xt2 = 20
- SUMDIFF_PIFOURTH(vi, vr, x[20], x[21])
- ur = x[ 4];
- ui = x[ 5];
- x[ 4] = (ur>>1) + vr;
- x[ 5] = (ui>>1) + vi;
- x[20] = (ur>>1) - vr;
- x[21] = (ui>>1) - vi;
-
-// xt1 = 12
-// xt2 = 28
- SUMDIFF_PIFOURTH(vr, vi, x[28], x[29])
- ur = x[12];
- ui = x[13];
- x[12] = (ur>>1) + vr;
- x[13] = (ui>>1) - vi;
- x[28] = (ur>>1) - vr;
- x[29] = (ui>>1) + vi;
-
-// xt1 = 6
-// xt2 = 22
- cplxMultDiv2(&vi, &vr, x[23], x[22], fft16_w16[1]);
- ur = x[ 6];
- ui = x[ 7];
- x[ 6] = (ur>>1) + vr;
- x[ 7] = (ui>>1) + vi;
- x[22] = (ur>>1) - vr;
- x[23] = (ui>>1) - vi;
-
-// xt1 = 14
-// xt2 = 30
- cplxMultDiv2(&vr, &vi, x[31], x[30], fft16_w16[1]);
- ur = x[14];
- ui = x[15];
- x[14] = (ur>>1) + vr;
- x[15] = (ui>>1) - vi;
- x[30] = (ur>>1) - vr;
- x[31] = (ui>>1) + vi;
-}
-
-#ifndef FUNCTION_fft_32
-static const FIXP_STP fft32_w32[6] =
-{
- STCP (0x7641af3d, 0x30fbc54d), STCP(0x30fbc54d, 0x7641af3d), STCP(0x7d8a5f40, 0x18f8b83c),
- STCP (0x6a6d98a4, 0x471cece7), STCP(0x471cece7, 0x6a6d98a4), STCP(0x18f8b83c, 0x7d8a5f40)
-};
-
-LNK_SECTION_CODE_L1
-inline void fft_32(FIXP_DBL *x)
-{
-
-#define W_PiFOURTH STC(0x5a82799a)
-
- FIXP_DBL vr,vi,ur,ui;
- FIXP_DBL y[64];
-
- /*
- * 1+2 stage radix 4
- */
-
-/////////////////////////////////////////////////////////////////////////////////////////
-
- // i = 0
- vr = (x[ 0] + x[32])>>1; /* Re A + Re B */
- vi = (x[16] + x[48]); /* Re C + Re D */
- ur = (x[ 1] + x[33])>>1; /* Im A + Im B */
- ui = (x[17] + x[49]); /* Im C + Im D */
-
- y[ 0] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[ 4] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[ 1] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[ 5] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[32]; /* Re A - Re B */
- vi = (vi>>1) - x[48]; /* Re C - Re D */
- ur -= x[33]; /* Im A - Im B */
- ui = (ui>>1) - x[49]; /* Im C - Im D */
-
- y[ 2] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[ 6] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[ 3] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[ 7] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=8
- vr = (x[ 8] + x[40])>>1; /* Re A + Re B */
- vi = (x[24] + x[56]); /* Re C + Re D */
- ur = (x[ 9] + x[41])>>1; /* Im A + Im B */
- ui = (x[25] + x[57]); /* Im C + Im D */
-
- y[ 8] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[12] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[ 9] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[13] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[40]; /* Re A - Re B */
- vi = (vi>>1) - x[56]; /* Re C - Re D */
- ur -= x[41]; /* Im A - Im B */
- ui = (ui>>1) - x[57]; /* Im C - Im D */
-
- y[10] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[14] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[11] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[15] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=16
- vr = (x[ 4] + x[36])>>1; /* Re A + Re B */
- vi = (x[20] + x[52]); /* Re C + Re D */
- ur = (x[ 5] + x[37])>>1; /* Im A + Im B */
- ui = (x[21] + x[53]); /* Im C + Im D */
-
- y[16] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[20] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[17] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[21] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[36]; /* Re A - Re B */
- vi = (vi>>1) - x[52]; /* Re C - Re D */
- ur -= x[37]; /* Im A - Im B */
- ui = (ui>>1) - x[53]; /* Im C - Im D */
-
- y[18] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[22] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[19] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[23] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=24
- vr = (x[12] + x[44])>>1; /* Re A + Re B */
- vi = (x[28] + x[60]); /* Re C + Re D */
- ur = (x[13] + x[45])>>1; /* Im A + Im B */
- ui = (x[29] + x[61]); /* Im C + Im D */
-
- y[24] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[28] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[25] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[29] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[44]; /* Re A - Re B */
- vi = (vi>>1) - x[60]; /* Re C - Re D */
- ur -= x[45]; /* Im A - Im B */
- ui = (ui>>1) - x[61]; /* Im C - Im D */
-
- y[26] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[30] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[27] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[31] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- // i = 32
- vr = (x[ 2] + x[34])>>1; /* Re A + Re B */
- vi = (x[18] + x[50]); /* Re C + Re D */
- ur = (x[ 3] + x[35])>>1; /* Im A + Im B */
- ui = (x[19] + x[51]); /* Im C + Im D */
-
- y[32] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[36] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[33] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[37] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[34]; /* Re A - Re B */
- vi = (vi>>1) - x[50]; /* Re C - Re D */
- ur -= x[35]; /* Im A - Im B */
- ui = (ui>>1) - x[51]; /* Im C - Im D */
-
- y[34] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[38] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[35] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[39] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=40
- vr = (x[10] + x[42])>>1; /* Re A + Re B */
- vi = (x[26] + x[58]); /* Re C + Re D */
- ur = (x[11] + x[43])>>1; /* Im A + Im B */
- ui = (x[27] + x[59]); /* Im C + Im D */
-
- y[40] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[44] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[41] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[45] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[42]; /* Re A - Re B */
- vi = (vi>>1) - x[58]; /* Re C - Re D */
- ur -= x[43]; /* Im A - Im B */
- ui = (ui>>1) - x[59]; /* Im C - Im D */
-
- y[42] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[46] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[43] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[47] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=48
- vr = (x[ 6] + x[38])>>1; /* Re A + Re B */
- vi = (x[22] + x[54]); /* Re C + Re D */
- ur = (x[ 7] + x[39])>>1; /* Im A + Im B */
- ui = (x[23] + x[55]); /* Im C + Im D */
-
- y[48] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[52] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[49] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[53] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[38]; /* Re A - Re B */
- vi = (vi>>1) - x[54]; /* Re C - Re D */
- ur -= x[39]; /* Im A - Im B */
- ui = (ui>>1) - x[55]; /* Im C - Im D */
-
- y[50] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[54] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[51] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[55] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
- //i=56
- vr = (x[14] + x[46])>>1; /* Re A + Re B */
- vi = (x[30] + x[62]); /* Re C + Re D */
- ur = (x[15] + x[47])>>1; /* Im A + Im B */
- ui = (x[31] + x[63]); /* Im C + Im D */
-
- y[56] = vr + (vi>>1); /* Re A' = ReA + ReB +ReC + ReD */
- y[60] = vr - (vi>>1); /* Re C' = -(ReC+ReD) + (ReA+ReB) */
- y[57] = ur + (ui>>1); /* Im A' = sum of imag values */
- y[61] = ur - (ui>>1); /* Im C' = -Im C -Im D +Im A +Im B */
-
- vr -= x[46]; /* Re A - Re B */
- vi = (vi>>1) - x[62]; /* Re C - Re D */
- ur -= x[47]; /* Im A - Im B */
- ui = (ui>>1) - x[63]; /* Im C - Im D */
-
- y[58] = ui + vr; /* Re B' = Im C - Im D + Re A - Re B */
- y[62] = vr - ui; /* Re D' = -Im C + Im D + Re A - Re B */
- y[59] = ur - vi; /* Im B'= -Re C + Re D + Im A - Im B */
- y[63] = vi + ur; /* Im D'= Re C - Re D + Im A - Im B */
-
-
- FIXP_DBL *xt = &x[0];
- FIXP_DBL *yt = &y[0];
-
- int j = 4;
- do
- {
- vr = yt[8];
- vi = yt[9];
- ur = yt[0]>>1;
- ui = yt[1]>>1;
- xt[ 0] = ur + (vr>>1);
- xt[ 1] = ui + (vi>>1);
- xt[ 8] = ur - (vr>>1);
- xt[ 9] = ui - (vi>>1);
-
- vr = yt[13];
- vi = yt[12];
- ur = yt[4]>>1;
- ui = yt[5]>>1;
- xt[ 4] = ur + (vr>>1);
- xt[ 5] = ui - (vi>>1);
- xt[12] = ur - (vr>>1);
- xt[13] = ui + (vi>>1);
-
- SUMDIFF_PIFOURTH(vi, vr, yt[10], yt[11])
- ur = yt[2];
- ui = yt[3];
- xt[ 2] = (ur>>1) + vr;
- xt[ 3] = (ui>>1) + vi;
- xt[10] = (ur>>1) - vr;
- xt[11] = (ui>>1) - vi;
-
- SUMDIFF_PIFOURTH(vr, vi, yt[14], yt[15])
- ur = yt[6];
- ui = yt[7];
-
- xt[ 6] = (ur>>1) + vr;
- xt[ 7] = (ui>>1) - vi;
- xt[14] = (ur>>1) - vr;
- xt[15] = (ui>>1) + vi;
- xt += 16;
- yt += 16;
- } while (--j != 0);
-
- vr = x[16];
- vi = x[17];
- ur = x[ 0]>>1;
- ui = x[ 1]>>1;
- x[ 0] = ur + (vr>>1);
- x[ 1] = ui + (vi>>1);
- x[16] = ur - (vr>>1);
- x[17] = ui - (vi>>1);
-
- vi = x[24];
- vr = x[25];
- ur = x[ 8]>>1;
- ui = x[ 9]>>1;
- x[ 8] = ur + (vr>>1);
- x[ 9] = ui - (vi>>1);
- x[24] = ur - (vr>>1);
- x[25] = ui + (vi>>1);
-
- vr = x[48];
- vi = x[49];
- ur = x[32]>>1;
- ui = x[33]>>1;
- x[32] = ur + (vr>>1);
- x[33] = ui + (vi>>1);
- x[48] = ur - (vr>>1);
- x[49] = ui - (vi>>1);
-
- vi = x[56];
- vr = x[57];
- ur = x[40]>>1;
- ui = x[41]>>1;
- x[40] = ur + (vr>>1);
- x[41] = ui - (vi>>1);
- x[56] = ur - (vr>>1);
- x[57] = ui + (vi>>1);
-
- cplxMultDiv2(&vi, &vr, x[19], x[18], fft32_w32[0]);
- ur = x[ 2];
- ui = x[ 3];
- x[ 2] = (ur>>1) + vr;
- x[ 3] = (ui>>1) + vi;
- x[18] = (ur>>1) - vr;
- x[19] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[27], x[26], fft32_w32[0]);
- ur = x[10];
- ui = x[11];
- x[10] = (ur>>1) + vr;
- x[11] = (ui>>1) - vi;
- x[26] = (ur>>1) - vr;
- x[27] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[51], x[50], fft32_w32[0]);
- ur = x[34];
- ui = x[35];
- x[34] = (ur>>1) + vr;
- x[35] = (ui>>1) + vi;
- x[50] = (ur>>1) - vr;
- x[51] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[59], x[58], fft32_w32[0]);
- ur = x[42];
- ui = x[43];
- x[42] = (ur>>1) + vr;
- x[43] = (ui>>1) - vi;
- x[58] = (ur>>1) - vr;
- x[59] = (ui>>1) + vi;
-
- SUMDIFF_PIFOURTH(vi, vr, x[20], x[21])
- ur = x[ 4];
- ui = x[ 5];
- x[ 4] = (ur>>1) + vr;
- x[ 5] = (ui>>1) + vi;
- x[20] = (ur>>1) - vr;
- x[21] = (ui>>1) - vi;
-
- SUMDIFF_PIFOURTH(vr, vi, x[28], x[29])
- ur = x[12];
- ui = x[13];
- x[12] = (ur>>1) + vr;
- x[13] = (ui>>1) - vi;
- x[28] = (ur>>1) - vr;
- x[29] = (ui>>1) + vi;
-
- SUMDIFF_PIFOURTH(vi, vr, x[52], x[53])
- ur = x[36];
- ui = x[37];
- x[36] = (ur>>1) + vr;
- x[37] = (ui>>1) + vi;
- x[52] = (ur>>1) - vr;
- x[53] = (ui>>1) - vi;
-
- SUMDIFF_PIFOURTH(vr, vi, x[60], x[61])
- ur = x[44];
- ui = x[45];
- x[44] = (ur>>1) + vr;
- x[45] = (ui>>1) - vi;
- x[60] = (ur>>1) - vr;
- x[61] = (ui>>1) + vi;
-
-
- cplxMultDiv2(&vi, &vr, x[23], x[22], fft32_w32[1]);
- ur = x[ 6];
- ui = x[ 7];
- x[ 6] = (ur>>1) + vr;
- x[ 7] = (ui>>1) + vi;
- x[22] = (ur>>1) - vr;
- x[23] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[31], x[30], fft32_w32[1]);
- ur = x[14];
- ui = x[15];
- x[14] = (ur>>1) + vr;
- x[15] = (ui>>1) - vi;
- x[30] = (ur>>1) - vr;
- x[31] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[55], x[54], fft32_w32[1]);
- ur = x[38];
- ui = x[39];
- x[38] = (ur>>1) + vr;
- x[39] = (ui>>1) + vi;
- x[54] = (ur>>1) - vr;
- x[55] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[63], x[62], fft32_w32[1]);
- ur = x[46];
- ui = x[47];
-
- x[46] = (ur>>1) + vr;
- x[47] = (ui>>1) - vi;
- x[62] = (ur>>1) - vr;
- x[63] = (ui>>1) + vi;
-
- vr = x[32];
- vi = x[33];
- ur = x[ 0]>>1;
- ui = x[ 1]>>1;
- x[ 0] = ur + (vr>>1);
- x[ 1] = ui + (vi>>1);
- x[32] = ur - (vr>>1);
- x[33] = ui - (vi>>1);
-
- vi = x[48];
- vr = x[49];
- ur = x[16]>>1;
- ui = x[17]>>1;
- x[16] = ur + (vr>>1);
- x[17] = ui - (vi>>1);
- x[48] = ur - (vr>>1);
- x[49] = ui + (vi>>1);
-
- cplxMultDiv2(&vi, &vr, x[35], x[34], fft32_w32[2]);
- ur = x[ 2];
- ui = x[ 3];
- x[ 2] = (ur>>1) + vr;
- x[ 3] = (ui>>1) + vi;
- x[34] = (ur>>1) - vr;
- x[35] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[51], x[50], fft32_w32[2]);
- ur = x[18];
- ui = x[19];
- x[18] = (ur>>1) + vr;
- x[19] = (ui>>1) - vi;
- x[50] = (ur>>1) - vr;
- x[51] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[37], x[36], fft32_w32[0]);
- ur = x[ 4];
- ui = x[ 5];
- x[ 4] = (ur>>1) + vr;
- x[ 5] = (ui>>1) + vi;
- x[36] = (ur>>1) - vr;
- x[37] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[53], x[52], fft32_w32[0]);
- ur = x[20];
- ui = x[21];
- x[20] = (ur>>1) + vr;
- x[21] = (ui>>1) - vi;
- x[52] = (ur>>1) - vr;
- x[53] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[39], x[38], fft32_w32[3]);
- ur = x[ 6];
- ui = x[ 7];
- x[ 6] = (ur>>1) + vr;
- x[ 7] = (ui>>1) + vi;
- x[38] = (ur>>1) - vr;
- x[39] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[55], x[54], fft32_w32[3]);
- ur = x[22];
- ui = x[23];
- x[22] = (ur>>1) + vr;
- x[23] = (ui>>1) - vi;
- x[54] = (ur>>1) - vr;
- x[55] = (ui>>1) + vi;
-
- SUMDIFF_PIFOURTH(vi, vr, x[40], x[41])
- ur = x[ 8];
- ui = x[ 9];
- x[ 8] = (ur>>1) + vr;
- x[ 9] = (ui>>1) + vi;
- x[40] = (ur>>1) - vr;
- x[41] = (ui>>1) - vi;
-
- SUMDIFF_PIFOURTH(vr, vi, x[56], x[57])
- ur = x[24];
- ui = x[25];
- x[24] = (ur>>1) + vr;
- x[25] = (ui>>1) - vi;
- x[56] = (ur>>1) - vr;
- x[57] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[43], x[42], fft32_w32[4]);
- ur = x[10];
- ui = x[11];
-
- x[10] = (ur>>1) + vr;
- x[11] = (ui>>1) + vi;
- x[42] = (ur>>1) - vr;
- x[43] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[59], x[58], fft32_w32[4]);
- ur = x[26];
- ui = x[27];
- x[26] = (ur>>1) + vr;
- x[27] = (ui>>1) - vi;
- x[58] = (ur>>1) - vr;
- x[59] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[45], x[44], fft32_w32[1]);
- ur = x[12];
- ui = x[13];
- x[12] = (ur>>1) + vr;
- x[13] = (ui>>1) + vi;
- x[44] = (ur>>1) - vr;
- x[45] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[61], x[60], fft32_w32[1]);
- ur = x[28];
- ui = x[29];
- x[28] = (ur>>1) + vr;
- x[29] = (ui>>1) - vi;
- x[60] = (ur>>1) - vr;
- x[61] = (ui>>1) + vi;
-
- cplxMultDiv2(&vi, &vr, x[47], x[46], fft32_w32[5]);
- ur = x[14];
- ui = x[15];
- x[14] = (ur>>1) + vr;
- x[15] = (ui>>1) + vi;
- x[46] = (ur>>1) - vr;
- x[47] = (ui>>1) - vi;
-
- cplxMultDiv2(&vr, &vi, x[63], x[62], fft32_w32[5]);
- ur = x[30];
- ui = x[31];
- x[30] = (ur>>1) + vr;
- x[31] = (ui>>1) - vi;
- x[62] = (ur>>1) - vr;
- x[63] = (ui>>1) + vi;
-}
-#endif /* #ifndef FUNCTION_fft_32 */
-
-
-/**
- * \brief Apply rotation vectors to a data buffer.
- * \param cl length of each row of input data.
- * \param l total length of input data.
- * \param pVecRe real part of rotation ceofficient vector.
- * \param pVecIm imaginary part of rotation ceofficient vector.
- */
-static inline void fft_apply_rot_vector(FIXP_DBL *RESTRICT pData, const int cl, const int l, const FIXP_STB *pVecRe, const FIXP_STB *pVecIm)
-{
- FIXP_DBL re, im;
- FIXP_STB vre, vim;
-
- int i, c;
-
- for(i=0; i<cl; i++) {
- re = pData[2*i];
- im = pData[2*i+1];
-
- pData[2*i] = re>>2; /* * 0.25 */
- pData[2*i+1] = im>>2; /* * 0.25 */
- }
- for(; i<l; i+=cl)
- {
- re = pData[2*i];
- im = pData[2*i+1];
-
- pData[2*i] = re>>2; /* * 0.25 */
- pData[2*i+1] = im>>2; /* * 0.25 */
-
- for (c=i+1; c<i+cl; c++)
- {
- re = pData[2*c]>>1;
- im = pData[2*c+1]>>1;
- vre = *pVecRe++;
- vim = *pVecIm++;
-
- cplxMultDiv2(&pData[2*c+1], &pData[2*c], im, re, vre, vim);
- }
- }
-}
-
-//FIXME:buggy for fft480
-//#define FFT_TWO_STAGE_MACRO_ENABLE
-
-
-#ifdef FFT_TWO_STAGE_MACRO_ENABLE
-
-#define fftN2(pInput, length, dim1, dim2, fft_func1, fft_func2, RotVectorReal, RotVectorImag) \
-{ \
- int i, j; \
- \
- C_ALLOC_SCRATCH_START(aDst, FIXP_DBL, length*2); \
- C_ALLOC_SCRATCH_START(aDst2, FIXP_DBL, dim2*2); \
- \
- FDK_ASSERT(length == dim1*dim2); \
- \
- /* Perform dim2 times the fft of length dim1. The input samples are at the address of pSrc and the \
- output samples are at the address of pDst. The input vector for the fft of length dim1 is built \
- of the interleaved samples in pSrc, the output samples are stored consecutively. \
- */ \
- { \
- const FIXP_DBL* pSrc = pInput; \
- FIXP_DBL *RESTRICT pDst = aDst; \
- \
- for(i=0; i<dim2; i++) \
- { \
- for(j=0; j<dim1; j++) \
- { \
- pDst[2*j] = pSrc[2*j*dim2]; \
- pDst[2*j+1] = pSrc[2*j*dim2+1]; \
- } \
- \
- fft_func1(pDst); \
- pSrc += 2; \
- pDst = pDst + 2*dim1; \
- } \
- } \
- \
- /* Perform the modulation of the output of the fft of length dim1 */ \
- fft_apply_rot_vector(aDst, dim1, length, RotVectorReal, RotVectorImag); \
- \
- /* Perform dim1 times the fft of length dim2. The input samples are at the address of aDst and the \
- output samples are at the address of pInput. The input vector for the fft of length dim2 is built \
- of the interleaved samples in aDst, the output samples are stored consecutively at the address \
- of pInput. \
- */ \
- { \
- const FIXP_DBL* pSrc = aDst; \
- FIXP_DBL *RESTRICT pDst = aDst2; \
- FIXP_DBL *RESTRICT pDstOut = pInput; \
- \
- for(i=0; i<dim1; i++) \
- { \
- for(j=0; j<dim2; j++) \
- { \
- pDst[2*j] = pSrc[2*j*dim1]; \
- pDst[2*j+1] = pSrc[2*j*dim1+1]; \
- } \
- \
- fft_func2(pDst); \
- \
- for(j=0; j<dim2; j++) \
- { \
- pDstOut[2*j*dim1] = pDst[2*j]; \
- pDstOut[2*j*dim1+1] = pDst[2*j+1]; \
- } \
- pSrc += 2; \
- pDstOut += 2; \
- } \
- } \
- \
- C_ALLOC_SCRATCH_END(aDst2, FIXP_DBL, dim2*2); \
- C_ALLOC_SCRATCH_END(aDst, FIXP_DBL, length*2); \
-} \
-
-#else /* FFT_TWO_STAGE_MACRO_ENABLE */
-
-/* select either switch case of function pointer. */
-#define FFT_TWO_STAGE_SWITCH_CASE
-
-static inline void fftN2(
- FIXP_DBL *pInput,
- const int length,
- const int dim1,
- const int dim2,
- void (* const fft1)(FIXP_DBL *),
- void (* const fft2)(FIXP_DBL *),
- const FIXP_STB *RotVectorReal,
- const FIXP_STB *RotVectorImag
- )
-{
- /* The real part of the input samples are at the addresses with even indices and the imaginary
- part of the input samples are at the addresses with odd indices. The output samples are stored
- at the address of pInput
- */
- FIXP_DBL *pSrc, *pDst, *pDstOut;
- int i, j;
-
- C_ALLOC_SCRATCH_START(aDst, FIXP_DBL, length*2);
- C_ALLOC_SCRATCH_START(aDst2, FIXP_DBL, dim2*2);
-
- FDK_ASSERT(length == dim1*dim2);
-
- /* Perform dim2 times the fft of length dim1. The input samples are at the address of pSrc and the
- output samples are at the address of pDst. The input vector for the fft of length dim1 is built
- of the interleaved samples in pSrc, the output samples are stored consecutively.
- */
- pSrc = pInput;
- pDst = aDst;
- for(i=0; i<length/dim1; i++)
- {
- for(j=0; j<length/dim2; j++)
- {
- pDst[2*j] = pSrc[2*j*dim2];
- pDst[2*j+1] = pSrc[2*j*dim2+1];
- }
-
- /* fft of size dim1 */
-#ifndef FFT_TWO_STAGE_SWITCH_CASE
- fft1(pDst);
-#else
- switch (dim1) {
- case 3: fft3(pDst); break;
- case 4: fft_4(pDst); break;
- case 5: fft5(pDst); break;
- case 8: fft_8(pDst); break;
- case 15: fft15(pDst); break;
- case 16: fft_16(pDst); break;
- case 32: fft_32(pDst); break;
- /*case 64: fft_64(pDst); break;*/
- /*case 128: fft_128(pDst); break;*/
- }
-#endif
- pSrc += 2;
- pDst = pDst + 2*length/dim2;
- }
-
- /* Perform the modulation of the output of the fft of length dim1 */
- pSrc=aDst;
- fft_apply_rot_vector(pSrc, length/dim2, length, RotVectorReal, RotVectorImag);
-
- /* Perform dim1 times the fft of length dim2. The input samples are at the address of aDst and the
- output samples are at the address of pInput. The input vector for the fft of length dim2 is built
- of the interleaved samples in aDst, the output samples are stored consecutively at the address
- of pInput.
- */
- pSrc = aDst;
- pDst = aDst2;
- pDstOut = pInput;
- for(i=0; i<length/dim2; i++)
- {
- for(j=0; j<length/dim1; j++)
- {
- pDst[2*j] = pSrc[2*j*dim1];
- pDst[2*j+1] = pSrc[2*j*dim1+1];
- }
-
-#ifndef FFT_TWO_STAGE_SWITCH_CASE
- fft2(pDst);
-#else
- switch (dim2) {
- case 3: fft3(pDst); break;
- case 4: fft_4(pDst); break;
- case 5: fft5(pDst); break;
- case 8: fft_8(pDst); break;
- case 15: fft15(pDst); break;
- case 16: fft_16(pDst); break;
- case 32: fft_32(pDst); break;
- /*case 64: fft_64(pDst); break;*/
- /*case 128: fft_128(pDst); break;*/
- }
-#endif
-
- for(j=0; j<length/dim1; j++)
- {
- pDstOut[2*j*dim1] = pDst[2*j];
- pDstOut[2*j*dim1+1] = pDst[2*j+1];
- }
- pSrc += 2;
- pDstOut += 2;
- }
-
- C_ALLOC_SCRATCH_END(aDst2, FIXP_DBL, dim2*2);
- C_ALLOC_SCRATCH_END(aDst, FIXP_DBL, length*2);
-}
-
-#endif /* FFT_TWO_STAGE_MACRO_ENABLE */
-
-
-
-
-
-
-
-
-
-
-
-
-#define SCALEFACTOR60 5
-/**
-The function performs the fft of length 60. It is splittet into fft's of length 4 and fft's of
-length 15. Between the fft's a modolation is calculated.
-*/
-static inline void fft60(FIXP_DBL *pInput, INT *pScalefactor)
-{
- fftN2(
- pInput, 60, 4, 15,
- fft_4, fft15,
- RotVectorReal60, RotVectorImag60
- );
- *pScalefactor += SCALEFACTOR60;
-}
-
-
-
-/* Fallback implementation in case of no better implementation available. */
-
-#define SCALEFACTOR240 7
-
-/**
-The function performs the fft of length 240. It is splittet into fft's of length 16 and fft's of
-length 15. Between the fft's a modulation is calculated.
-*/
-static inline void fft240(FIXP_DBL *pInput, INT *pScalefactor)
-{
- fftN2(
- pInput, 240, 16, 15,
- fft_16, fft15,
- RotVectorReal240, RotVectorImag240
- );
- *pScalefactor += SCALEFACTOR240;
-}
-
-
-#define SCALEFACTOR480 8
-#define N32 32
-#define TABLE_SIZE_16 (32/2)
-
-/**
-The function performs the fft of length 480. It is splittet into fft's of length 32 and fft's of
-length 15. Between the fft's a modulation is calculated.
-*/
-static inline void fft480(FIXP_DBL *pInput, INT *pScalefactor)
-{
- fftN2(
- pInput, 480, 32, 15,
- fft_32, fft15,
- RotVectorReal480, RotVectorImag480
- );
- *pScalefactor += SCALEFACTOR480;
-}
-
-void fft(int length, FIXP_DBL *pInput, INT *pScalefactor)
-{
- if (length == 32)
- {
- fft_32(pInput);
- *pScalefactor += SCALEFACTOR32;
- }
- else
- {
-
- switch (length) {
- case 16:
- fft_16(pInput);
- *pScalefactor += SCALEFACTOR16;
- break;
- case 8:
- fft_8(pInput);
- *pScalefactor += SCALEFACTOR8;
- break;
- case 3:
- fft3(pInput);
- break;
- case 4:
- fft_4(pInput);
- *pScalefactor += SCALEFACTOR4;
- break;
- case 5:
- fft5(pInput);
- break;
- case 15:
- fft15(pInput);
- *pScalefactor += 2;
- break;
- case 60:
- fft60(pInput, pScalefactor);
- break;
- case 64:
- dit_fft(pInput, 6, SineTable512, 512);
- *pScalefactor += SCALEFACTOR64;
- break;
- case 240:
- fft240(pInput, pScalefactor);
- break;
- case 256:
- dit_fft(pInput, 8, SineTable512, 512);
- *pScalefactor += SCALEFACTOR256;
- break;
- case 480:
- fft480(pInput, pScalefactor);
- break;
- case 512:
- dit_fft(pInput, 9, SineTable512, 512);
- *pScalefactor += SCALEFACTOR512;
- break;
- default:
- FDK_ASSERT(0); /* FFT length not supported! */
- break;
- }
- }
-}
-
-
-void ifft(int length, FIXP_DBL *pInput, INT *scalefactor)
-{
- switch (length) {
- default:
- FDK_ASSERT(0); /* IFFT length not supported! */
- break;
- }
-}
-
-