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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)
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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,
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This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors
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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
----------------------------------------------------------------------------------------------------------- */
/*!
\file dct.cpp
\brief DCT Implementations
Library functions to calculate standard DCTs. This will most likely be replaced by hand-optimized
functions for the specific target processor.
Three different implementations of the dct type II and the dct type III transforms are provided.
By default implementations which are based on a single, standard complex FFT-kernel are used (dctII_f() and dctIII_f()).
These are specifically helpful in cases where optimized FFT libraries are already available. The FFT used in these
implementation is FFT rad2 from FDK_tools.
Of course, one might also use DCT-libraries should they be available. The DCT and DST
type IV implementations are only available in a version based on a complex FFT kernel.
*/
#include "dct.h"
#include "FDK_tools_rom.h"
#include "fft.h"
#if defined(__arm__)
#include "arm/dct_arm.cpp"
#endif
#if !defined(FUNCTION_dct_III)
void dct_III(FIXP_DBL *pDat, /*!< pointer to input/output */
FIXP_DBL *tmp, /*!< pointer to temporal working buffer */
int L, /*!< lenght of transform */
int *pDat_e
)
{
FDK_ASSERT(L == 64 || L == 32);
int i;
FIXP_DBL xr, accu1, accu2;
int inc;
int M = L>>1;
int ld_M;
if (L == 64) ld_M = 5;
else ld_M = 4;
/* This loop performs multiplication for index i (i*inc) */
inc = (64/2) >> ld_M; /* 64/L */
FIXP_DBL *pTmp_0 = &tmp[2];
FIXP_DBL *pTmp_1 = &tmp[(M-1)*2];
for(i=1; i<M>>1; i++,pTmp_0+=2,pTmp_1-=2) {
FIXP_DBL accu3,accu4,accu5,accu6;
cplxMultDiv2(&accu2, &accu1, pDat[L - i], pDat[i], sin_twiddle_L64[i*inc]);
cplxMultDiv2(&accu4, &accu3, pDat[M+i], pDat[M-i], sin_twiddle_L64[(M-i)*inc]);
accu3 >>= 1; accu4 >>= 1;
/* This method is better for ARM926, that uses operand2 shifted right by 1 always */
cplxMultDiv2(&accu6, &accu5, (accu3 - (accu1>>1)), ((accu2>>1) + accu4), sin_twiddle_L64[(4*i)*inc]);
xr = (accu1>>1) + accu3;
pTmp_0[0] = (xr>>1) - accu5;
pTmp_1[0] = (xr>>1) + accu5;
xr = (accu2>>1) - accu4;
pTmp_0[1] = (xr>>1) - accu6;
pTmp_1[1] = -((xr>>1) + accu6);
}
xr = fMultDiv2(pDat[M], sin_twiddle_L64[64/2].v.re );/* cos((PI/(2*L))*M); */
tmp[0] = ((pDat[0]>>1) + xr)>>1;
tmp[1] = ((pDat[0]>>1) - xr)>>1;
cplxMultDiv2(&accu2, &accu1, pDat[L - (M/2)], pDat[M/2], sin_twiddle_L64[64/4]);
tmp[M] = accu1>>1;
tmp[M+1] = accu2>>1;
/* dit_fft expects 1 bit scaled input values */
fft(M, tmp, pDat_e);
/* ARM926: 12 cycles per 2-iteration, no overhead code by compiler */
pTmp_1 = &tmp[L];
for (i = M>>1; i--;)
{
FIXP_DBL tmp1, tmp2, tmp3, tmp4;
tmp1 = *tmp++;
tmp2 = *tmp++;
tmp3 = *--pTmp_1;
tmp4 = *--pTmp_1;
*pDat++ = tmp1;
*pDat++ = tmp3;
*pDat++ = tmp2;
*pDat++ = tmp4;
}
*pDat_e += 2;
}
#endif
#if !defined(FUNCTION_dct_II)
void dct_II(FIXP_DBL *pDat, /*!< pointer to input/output */
FIXP_DBL *tmp, /*!< pointer to temporal working buffer */
int L, /*!< lenght of transform */
int *pDat_e
)
{
FDK_ASSERT(L == 64 || L == 32);
FIXP_DBL accu1,accu2;
FIXP_DBL *pTmp_0, *pTmp_1;
int i;
int inc;
int M = L>>1;
int ld_M;
FDK_ASSERT(L == 64 || L == 32);
ld_M = 4 + (L >> 6); /* L=64: 5, L=32: 4 */
inc = (64/2) >> ld_M; /* L=64: 1, L=32: 2 */
FIXP_DBL *pdat = &pDat[0];
FIXP_DBL accu3, accu4;
pTmp_0 = &tmp[0];
pTmp_1 = &tmp[L-1];
for (i = M>>1; i--; )
{
accu1 = *pdat++;
accu2 = *pdat++;
accu3 = *pdat++;
accu4 = *pdat++;
accu1 >>= 1;
accu2 >>= 1;
accu3 >>= 1;
accu4 >>= 1;
*pTmp_0++ = accu1;
*pTmp_0++ = accu3;
*pTmp_1-- = accu2;
*pTmp_1-- = accu4;
}
fft(M, tmp, pDat_e);
pTmp_0 = &tmp[2];
pTmp_1 = &tmp[(M-1)*2];
for (i=1; i<M>>1; i++,pTmp_0+=2,pTmp_1-=2) {
FIXP_DBL a1,a2;
FIXP_DBL accu3, accu4;
a1 = ((pTmp_0[1]>>1) + (pTmp_1[1]>>1));
a2 = ((pTmp_1[0]>>1) - (pTmp_0[0]>>1));
cplxMultDiv2(&accu1, &accu2, a2, a1, sin_twiddle_L64[(4*i)*inc]);
accu1<<=1; accu2<<=1;
a1 = ((pTmp_0[0]>>1) + (pTmp_1[0]>>1));
a2 = ((pTmp_0[1]>>1) - (pTmp_1[1]>>1));
cplxMultDiv2(&accu3, &accu4, (a1 + accu2), -(accu1 + a2), sin_twiddle_L64[i*inc]);
pDat[L - i] = accu4;
pDat[i] = accu3;
cplxMultDiv2(&accu3, &accu4, (a1 - accu2), -(accu1 - a2), sin_twiddle_L64[(M-i)*inc]);
pDat[M + i] = accu4;
pDat[M - i] = accu3;
}
cplxMultDiv2(&accu1, &accu2, tmp[M], tmp[M+1], sin_twiddle_L64[(M/2)*inc]);
pDat[L - (M/2)] = accu2;
pDat[M/2] = accu1;
pDat[0] = (tmp[0]>>1)+(tmp[1]>>1);
pDat[M] = fMult(((tmp[0]>>1)-(tmp[1]>>1)), sin_twiddle_L64[64/2].v.re);/* cos((PI/(2*L))*M); */
*pDat_e += 2;
}
#endif
static
void getTables(const FIXP_WTP **twiddle, const FIXP_STP **sin_twiddle, int *sin_step, int length)
{
int ld2_length;
/* Get ld2 of length - 2 + 1
-2: because first table entry is window of size 4
+1: because we already include +1 because of ceil(log2(length)) */
ld2_length = DFRACT_BITS-1-fNormz((FIXP_DBL)length) - 1;
/* Extract sort of "eigenvalue" (the 4 left most bits) of length. */
switch ( (length) >> (ld2_length-1) ) {
case 0x4: /* radix 2 */
*sin_twiddle = SineTable512;
*sin_step = 1<<(9 - ld2_length);
*twiddle = windowSlopes[0][0][ld2_length-1];
break;
case 0x7: /* 10 ms */
*sin_twiddle = SineTable480;
*sin_step = 1<<(8 - ld2_length);
*twiddle = windowSlopes[0][1][ld2_length];
break;
default:
*sin_twiddle = NULL;
*sin_step = 0;
*twiddle = NULL;
break;
}
FDK_ASSERT(*twiddle != NULL);
FDK_ASSERT(*sin_step > 0);
}
#if !defined(FUNCTION_dct_IV)
void dct_IV(FIXP_DBL *pDat,
int L,
int *pDat_e)
{
int sin_step = 0;
int M = L >> 1;
const FIXP_WTP *twiddle;
const FIXP_STP *sin_twiddle;
FDK_ASSERT(L >= 4);
getTables(&twiddle, &sin_twiddle, &sin_step, L);
#ifdef FUNCTION_dct_IV_func1
if (M>=4 && (M&3) == 0) {
/* ARM926: 44 cycles for 2 iterations = 22 cycles/iteration */
dct_IV_func1(M>>2, twiddle, &pDat[0], &pDat[L-1]);
} else
#endif /* FUNCTION_dct_IV_func1 */
{
FIXP_DBL *RESTRICT pDat_0 = &pDat[0];
FIXP_DBL *RESTRICT pDat_1 = &pDat[L - 2];
register int i;
/* 29 cycles on ARM926 */
for (i = 0; i < M-1; i+=2,pDat_0+=2,pDat_1-=2)
{
register FIXP_DBL accu1,accu2,accu3,accu4;
accu1 = pDat_1[1]; accu2 = pDat_0[0];
accu3 = pDat_0[1]; accu4 = pDat_1[0];
cplxMultDiv2(&accu1, &accu2, accu1, accu2, twiddle[i]);
cplxMultDiv2(&accu3, &accu4, accu4, accu3, twiddle[i+1]);
pDat_0[0] = accu2; pDat_0[1] = accu1;
pDat_1[0] = accu4; pDat_1[1] = -accu3;
}
if (M&1)
{
register FIXP_DBL accu1,accu2;
accu1 = pDat_1[1]; accu2 = pDat_0[0];
cplxMultDiv2(&accu1, &accu2, accu1, accu2, twiddle[i]);
pDat_0[0] = accu2; pDat_0[1] = accu1;
}
}
fft(M, pDat, pDat_e);
#ifdef FUNCTION_dct_IV_func2
if (M>=4 && (M&3) == 0) {
/* ARM926: 42 cycles for 2 iterations = 21 cycles/iteration */
dct_IV_func2(M>>2, sin_twiddle, &pDat[0], &pDat[L], sin_step);
} else
#endif /* FUNCTION_dct_IV_func2 */
{
FIXP_DBL *RESTRICT pDat_0 = &pDat[0];
FIXP_DBL *RESTRICT pDat_1 = &pDat[L - 2];
register FIXP_DBL accu1,accu2,accu3,accu4;
int idx, i;
/* Sin and Cos values are 0.0f and 1.0f */
accu1 = pDat_1[0];
accu2 = pDat_1[1];
pDat_1[1] = -(pDat_0[1]>>1);
pDat_0[0] = (pDat_0[0]>>1);
/* 28 cycles for ARM926 */
for (idx = sin_step,i=1; i<(M+1)>>1; i++, idx+=sin_step)
{
FIXP_STP twd = sin_twiddle[idx];
cplxMultDiv2(&accu3, &accu4, accu1, accu2, twd);
pDat_0[1] = accu3;
pDat_1[0] = accu4;
pDat_0+=2;
pDat_1-=2;
cplxMultDiv2(&accu3, &accu4, pDat_0[1], pDat_0[0], twd);
accu1 = pDat_1[0];
accu2 = pDat_1[1];
pDat_1[1] = -accu3;
pDat_0[0] = accu4;
}
if ( (M&1) == 0 )
{
/* Last Sin and Cos value pair are the same */
accu1 = fMultDiv2(accu1, WTC(0x5a82799a));
accu2 = fMultDiv2(accu2, WTC(0x5a82799a));
pDat_1[0] = accu1 + accu2;
pDat_0[1] = accu1 - accu2;
}
}
/* Add twiddeling scale. */
*pDat_e += 2;
}
#endif /* defined (FUNCTION_dct_IV) */
#if !defined(FUNCTION_dst_IV)
void dst_IV(FIXP_DBL *pDat,
int L,
int *pDat_e )
{
int sin_step = 0;
int M = L >> 1;
const FIXP_WTP *twiddle;
const FIXP_STP *sin_twiddle;
#ifdef DSTIV2_ENABLE
if (L == 2) {
const FIXP_STP tab = STCP(0x7641AF3D, 0x30FB9452);
FIXP_DBL tmp1, tmp2;
cplxMultDiv2(&tmp2, &tmp1, pDat[0], pDat[1], tab);
pDat[0] = tmp1;
pDat[1] = tmp2;
*pDat_e += 1;
return;
}
#else
FDK_ASSERT(L >= 4);
#endif
getTables(&twiddle, &sin_twiddle, &sin_step, L);
#ifdef FUNCTION_dst_IV_func1
if ( (M>=4) && ((M&3) == 0) ) {
dst_IV_func1(M, twiddle, &pDat[0], &pDat[L]);
} else
#endif
{
FIXP_DBL *RESTRICT pDat_0 = &pDat[0];
FIXP_DBL *RESTRICT pDat_1 = &pDat[L - 2];
register int i;
/* 34 cycles on ARM926 */
for (i = 0; i < M-1; i+=2,pDat_0+=2,pDat_1-=2)
{
register FIXP_DBL accu1,accu2,accu3,accu4;
accu1 = pDat_1[1]; accu2 = -pDat_0[0];
accu3 = pDat_0[1]; accu4 = -pDat_1[0];
cplxMultDiv2(&accu1, &accu2, accu1, accu2, twiddle[i]);
cplxMultDiv2(&accu3, &accu4, accu4, accu3, twiddle[i+1]);
pDat_0[0] = accu2; pDat_0[1] = accu1;
pDat_1[0] = accu4; pDat_1[1] = -accu3;
}
if (M&1)
{
register FIXP_DBL accu1,accu2;
accu1 = pDat_1[1]; accu2 = -pDat_0[0];
cplxMultDiv2(&accu1, &accu2, accu1, accu2, twiddle[i]);
pDat_0[0] = accu2; pDat_0[1] = accu1;
}
}
fft(M, pDat, pDat_e);
#ifdef FUNCTION_dst_IV_func2
if ( (M>=4) && ((M&3) == 0) ) {
dst_IV_func2(M>>2, sin_twiddle + sin_step, &pDat[0], &pDat[L - 1], sin_step);
} else
#endif /* FUNCTION_dst_IV_func2 */
{
FIXP_DBL *RESTRICT pDat_0;
FIXP_DBL *RESTRICT pDat_1;
register FIXP_DBL accu1,accu2,accu3,accu4;
int idx, i;
pDat_0 = &pDat[0];
pDat_1 = &pDat[L - 2];
/* Sin and Cos values are 0.0f and 1.0f */
accu1 = pDat_1[0];
accu2 = pDat_1[1];
pDat_1[1] = -(pDat_0[0]>>1);
pDat_0[0] = (pDat_0[1]>>1);
for (idx = sin_step,i=1; i<(M+1)>>1; i++, idx+=sin_step)
{
FIXP_STP twd = sin_twiddle[idx];
cplxMultDiv2(&accu3, &accu4, accu1, accu2, twd);
pDat_1[0] = -accu3;
pDat_0[1] = -accu4;
pDat_0+=2;
pDat_1-=2;
cplxMultDiv2(&accu3, &accu4, pDat_0[1], pDat_0[0], twd);
accu1 = pDat_1[0];
accu2 = pDat_1[1];
pDat_0[0] = accu3;
pDat_1[1] = -accu4;
}
if ( (M&1) == 0 )
{
/* Last Sin and Cos value pair are the same */
accu1 = fMultDiv2(accu1, WTC(0x5a82799a));
accu2 = fMultDiv2(accu2, WTC(0x5a82799a));
pDat_0[1] = - accu1 - accu2;
pDat_1[0] = accu2 - accu1;
}
}
/* Add twiddeling scale. */
*pDat_e += 2;
}
#endif /* !defined(FUNCTION_dst_IV) */