ESP8266Audio/src/libmad/layer3.c

/*
   libmad - MPEG audio decoder library
   Copyright (C) 2000-2004 Underbit Technologies, Inc.

   This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 2 of the License, or
   (at your option) any later version.

   This program 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 General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

   $Id: layer3.c,v 1.43 2004/01/23 09:41:32 rob Exp $
*/

#pragma GCC optimize ("O3")
#pragma GCC diagnostic ignored "-Wstrict-aliasing"

#include <pgmspace.h>
#  include "config.h"

# include "global.h"

# include <stdlib.h>
# include <string.h>
# include <stdint.h>

# ifdef HAVE_ASSERT_H
#  include <assert.h>
# endif

# ifdef HAVE_LIMITS_H
#  include <limits.h>
# else
#  define CHAR_BIT  8
# endif

# include "fixed.h"
# include "bit.h"
# include "stream.h"
# include "frame.h"
# include "huffman.h"
# include "layer3.h"

/* --- Layer III ----------------------------------------------------------- */

enum {
  count1table_select = 0x01,
  scalefac_scale     = 0x02,
  preflag	     = 0x04,
  mixed_block_flag   = 0x08
};

enum {
  I_STEREO  = 0x1,
  MS_STEREO = 0x2
};

struct sideinfo {
  unsigned int main_data_begin;
  unsigned int private_bits;

  unsigned char scfsi[2];

  struct granule {
    struct channel {
      /* from side info */
      unsigned short part2_3_length;
      unsigned short big_values;
      unsigned short global_gain;
      unsigned short scalefac_compress;

      unsigned char flags;
      unsigned char block_type;
      unsigned char table_select[3];
      unsigned char subblock_gain[3];
      unsigned char region0_count;
      unsigned char region1_count;

      /* from main_data */
      unsigned char scalefac[39];	/* scalefac_l and/or scalefac_s */
    } ch[2];
  } gr[2];
};

/*
   scalefactor bit lengths
   derived from section 2.4.2.7 of ISO/IEC 11172-3
*/
static
struct {
  unsigned int slen1;
  unsigned int slen2;
} const sflen_table[16] PROGMEM = {
  { 0, 0 }, { 0, 1 }, { 0, 2 }, { 0, 3 },
  { 3, 0 }, { 1, 1 }, { 1, 2 }, { 1, 3 },
  { 2, 1 }, { 2, 2 }, { 2, 3 }, { 3, 1 },
  { 3, 2 }, { 3, 3 }, { 4, 2 }, { 4, 3 }
};

/*
   number of LSF scalefactor band values
   derived from section 2.4.3.2 of ISO/IEC 13818-3
*/
static
unsigned int const nsfb_table[6][3][4] PROGMEM = {
  { {  6,  5,  5, 5 },
    {  9,  9,  9, 9 },
    {  6,  9,  9, 9 }
  },

  { {  6,  5,  7, 3 },
    {  9,  9, 12, 6 },
    {  6,  9, 12, 6 }
  },

  { { 11, 10,  0, 0 },
    { 18, 18,  0, 0 },
    { 15, 18,  0, 0 }
  },

  { {  7,  7,  7, 0 },
    { 12, 12, 12, 0 },
    {  6, 15, 12, 0 }
  },

  { {  6,  6,  6, 3 },
    { 12,  9,  9, 6 },
    {  6, 12,  9, 6 }
  },

  { {  8,  8,  5, 0 },
    { 15, 12,  9, 0 },
    {  6, 18,  9, 0 }
  }
};

/*
   MPEG-1 scalefactor band widths
   derived from Table B.8 of ISO/IEC 11172-3
*/
static
unsigned int const sfb_48000_long[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  6,  6,  6,   8,  10,
  12, 16, 18, 22, 28, 34, 40, 46, 54,  54, 192
};

static
unsigned int const sfb_44100_long[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  6,  6,  8,   8,  10,
  12, 16, 20, 24, 28, 34, 42, 50, 54,  76, 158
};

static
unsigned int const sfb_32000_long[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  6,  6,  8,  10,  12,
  16, 20, 24, 30, 38, 46, 56, 68, 84, 102,  26
};

static
unsigned int const sfb_48000_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,
  6,  6,  6,  6,  6, 10, 10, 10, 12, 12, 12, 14, 14,
  14, 16, 16, 16, 20, 20, 20, 26, 26, 26, 66, 66, 66
};

static
unsigned int const sfb_44100_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,
  6,  6,  8,  8,  8, 10, 10, 10, 12, 12, 12, 14, 14,
  14, 18, 18, 18, 22, 22, 22, 30, 30, 30, 56, 56, 56
};

static
unsigned int const sfb_32000_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,
  6,  6,  8,  8,  8, 12, 12, 12, 16, 16, 16, 20, 20,
  20, 26, 26, 26, 34, 34, 34, 42, 42, 42, 12, 12, 12
};

static
unsigned int const sfb_48000_mixed[] PROGMEM = {
  /* long */   4,  4,  4,  4,  4,  4,  6,  6,
  /* short */  4,  4,  4,  6,  6,  6,  6,  6,  6, 10,
  10, 10, 12, 12, 12, 14, 14, 14, 16, 16,
  16, 20, 20, 20, 26, 26, 26, 66, 66, 66
};

static
unsigned int const sfb_44100_mixed[] PROGMEM = {
  /* long */   4,  4,  4,  4,  4,  4,  6,  6,
  /* short */  4,  4,  4,  6,  6,  6,  8,  8,  8, 10,
  10, 10, 12, 12, 12, 14, 14, 14, 18, 18,
  18, 22, 22, 22, 30, 30, 30, 56, 56, 56
};

static
unsigned int const sfb_32000_mixed[] PROGMEM = {
  /* long */   4,  4,  4,  4,  4,  4,  6,  6,
  /* short */  4,  4,  4,  6,  6,  6,  8,  8,  8, 12,
  12, 12, 16, 16, 16, 20, 20, 20, 26, 26,
  26, 34, 34, 34, 42, 42, 42, 12, 12, 12
};

/*
   MPEG-2 scalefactor band widths
   derived from Table B.2 of ISO/IEC 13818-3
*/
static
unsigned int const sfb_24000_long[] PROGMEM = {
  6,  6,  6,  6,  6,  6,  8, 10, 12,  14,  16,
  18, 22, 26, 32, 38, 46, 54, 62, 70,  76,  36
};

static
unsigned int const sfb_22050_long[] PROGMEM = {
  6,  6,  6,  6,  6,  6,  8, 10, 12,  14,  16,
  20, 24, 28, 32, 38, 46, 52, 60, 68,  58,  54
};

# define sfb_16000_long  sfb_22050_long

static
unsigned int const sfb_24000_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,  6,  6,  8,
  8,  8, 10, 10, 10, 12, 12, 12, 14, 14, 14, 18, 18,
  18, 24, 24, 24, 32, 32, 32, 44, 44, 44, 12, 12, 12
};

static
unsigned int const sfb_22050_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,  6,  6,  6,
  6,  6,  8,  8,  8, 10, 10, 10, 14, 14, 14, 18, 18,
  18, 26, 26, 26, 32, 32, 32, 42, 42, 42, 18, 18, 18
};

static
unsigned int const sfb_16000_short[] PROGMEM = {
  4,  4,  4,  4,  4,  4,  4,  4,  4,  6,  6,  6,  8,
  8,  8, 10, 10, 10, 12, 12, 12, 14, 14, 14, 18, 18,
  18, 24, 24, 24, 30, 30, 30, 40, 40, 40, 18, 18, 18
};

static
unsigned int const sfb_24000_mixed[] PROGMEM = {
  /* long */   6,  6,  6,  6,  6,  6,
  /* short */  6,  6,  6,  8,  8,  8, 10, 10, 10, 12,
  12, 12, 14, 14, 14, 18, 18, 18, 24, 24,
  24, 32, 32, 32, 44, 44, 44, 12, 12, 12
};

static
unsigned int const sfb_22050_mixed[] PROGMEM = {
  /* long */   6,  6,  6,  6,  6,  6,
  /* short */  6,  6,  6,  6,  6,  6,  8,  8,  8, 10,
  10, 10, 14, 14, 14, 18, 18, 18, 26, 26,
  26, 32, 32, 32, 42, 42, 42, 18, 18, 18
};

static
unsigned int const sfb_16000_mixed[] PROGMEM = {
  /* long */   6,  6,  6,  6,  6,  6,
  /* short */  6,  6,  6,  8,  8,  8, 10, 10, 10, 12,
  12, 12, 14, 14, 14, 18, 18, 18, 24, 24,
  24, 30, 30, 30, 40, 40, 40, 18, 18, 18
};

/*
   MPEG 2.5 scalefactor band widths
   derived from public sources
*/
# define sfb_12000_long  sfb_16000_long
# define sfb_11025_long  sfb_12000_long

static
unsigned int const sfb_8000_long[] PROGMEM = {
  12, 12, 12, 12, 12, 12, 16, 20, 24,  28,  32,
  40, 48, 56, 64, 76, 90,  2,  2,  2,   2,   2
};

# define sfb_12000_short  sfb_16000_short
# define sfb_11025_short  sfb_12000_short

static
unsigned int const sfb_8000_short[] PROGMEM = {
  8,  8,  8,  8,  8,  8,  8,  8,  8, 12, 12, 12, 16,
  16, 16, 20, 20, 20, 24, 24, 24, 28, 28, 28, 36, 36,
  36,  2,  2,  2,  2,  2,  2,  2,  2,  2, 26, 26, 26
};

# define sfb_12000_mixed  sfb_16000_mixed
# define sfb_11025_mixed  sfb_12000_mixed

/* the 8000 Hz short block scalefactor bands do not break after
   the first 36 frequency lines, so this is probably wrong */
static
unsigned int const sfb_8000_mixed[] PROGMEM = {
  /* long */  12, 12, 12,
  /* short */  4,  4,  4,  8,  8,  8, 12, 12, 12, 16, 16, 16,
  20, 20, 20, 24, 24, 24, 28, 28, 28, 36, 36, 36,
  2,  2,  2,  2,  2,  2,  2,  2,  2, 26, 26, 26
};

static
struct {
  unsigned int const *l;
  unsigned int const *s;
  unsigned int const *m;
} const sfbwidth_table[9] PROGMEM = {
  { sfb_48000_long, sfb_48000_short, sfb_48000_mixed },
  { sfb_44100_long, sfb_44100_short, sfb_44100_mixed },
  { sfb_32000_long, sfb_32000_short, sfb_32000_mixed },
  { sfb_24000_long, sfb_24000_short, sfb_24000_mixed },
  { sfb_22050_long, sfb_22050_short, sfb_22050_mixed },
  { sfb_16000_long, sfb_16000_short, sfb_16000_mixed },
  { sfb_12000_long, sfb_12000_short, sfb_12000_mixed },
  { sfb_11025_long, sfb_11025_short, sfb_11025_mixed },
  {  sfb_8000_long,  sfb_8000_short,  sfb_8000_mixed }
};

/*
   scalefactor band preemphasis (used only when preflag is set)
   derived from Table B.6 of ISO/IEC 11172-3
*/
static
unsigned int const pretab[22] PROGMEM = {
  0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 3, 3, 3, 2, 0
};

/*
   table for requantization

   rq_table[x].mantissa * 2^(rq_table[x].exponent) = x^(4/3)
*/
static
struct fixedfloat {
  unsigned long mantissa  : 27;
  unsigned short exponent :  5;
} const rq_table[8207] PROGMEM = {
# include "rq_table.dat.h"
};

/*
   fractional powers of two
   used for requantization and joint stereo decoding

   root_table[3 + x] = 2^(x/4)
*/
static mad_fixed_t const root_table_val[7] PROGMEM = {
  MAD_F(0x09837f05) /* 2^(-3/4) == 0.59460355750136 */,
  MAD_F(0x0b504f33) /* 2^(-2/4) == 0.70710678118655 */,
  MAD_F(0x0d744fcd) /* 2^(-1/4) == 0.84089641525371 */,
  MAD_F(0x10000000) /* 2^( 0/4) == 1.00000000000000 */,
  MAD_F(0x1306fe0a) /* 2^(+1/4) == 1.18920711500272 */,
  MAD_F(0x16a09e66) /* 2^(+2/4) == 1.41421356237310 */,
  MAD_F(0x1ae89f99) /* 2^(+3/4) == 1.68179283050743 */
};
static inline mad_fixed_t root_table(int i)
{
  return root_table_val[i];
}
/*
   coefficients for aliasing reduction
   derived from Table B.9 of ISO/IEC 11172-3

    c[]  = { -0.6, -0.535, -0.33, -0.185, -0.095, -0.041, -0.0142, -0.0037 }
   cs[i] =    1 / sqrt(1 + c[i]^2)
   ca[i] = c[i] / sqrt(1 + c[i]^2)
*/
static mad_fixed_t const cs_val[8] PROGMEM = {
  +MAD_F(0x0db84a81) /* +0.857492926 */, +MAD_F(0x0e1b9d7f) /* +0.881741997 */,
  +MAD_F(0x0f31adcf) /* +0.949628649 */, +MAD_F(0x0fbba815) /* +0.983314592 */,
  +MAD_F(0x0feda417) /* +0.995517816 */, +MAD_F(0x0ffc8fc8) /* +0.999160558 */,
  +MAD_F(0x0fff964c) /* +0.999899195 */, +MAD_F(0x0ffff8d3) /* +0.999993155 */
};
static inline mad_fixed_t cs(int i)
{
  return cs_val[i];
}

static mad_fixed_t const ca_val[8] PROGMEM = {
  -MAD_F(0x083b5fe7) /* -0.514495755 */, -MAD_F(0x078c36d2) /* -0.471731969 */,
  -MAD_F(0x05039814) /* -0.313377454 */, -MAD_F(0x02e91dd1) /* -0.181913200 */,
  -MAD_F(0x0183603a) /* -0.094574193 */, -MAD_F(0x00a7cb87) /* -0.040965583 */,
  -MAD_F(0x003a2847) /* -0.014198569 */, -MAD_F(0x000f27b4) /* -0.003699975 */
};
static inline mad_fixed_t ca(int i)
{
  return ca_val[i];
}

/*
   IMDCT coefficients for short blocks
   derived from section 2.4.3.4.10.2 of ISO/IEC 11172-3

   imdct_s[i/even][k] = cos((PI / 24) * (2 *       (i / 2) + 7) * (2 * k + 1))
   imdct_s[i /odd][k] = cos((PI / 24) * (2 * (6 + (i-1)/2) + 7) * (2 * k + 1))
*/
static
mad_fixed_t const imdct_s[6][6] PROGMEM  = {
# include "imdct_s.dat.h"
};

# if !defined(ASO_IMDCT)
/*
   windowing coefficients for long blocks
   derived from section 2.4.3.4.10.3 of ISO/IEC 11172-3

   window_l[i] = sin((PI / 36) * (i + 1/2))
*/
static mad_fixed_t const window_l_val[36] PROGMEM = {
  MAD_F(0x00b2aa3e) /* 0.043619387 */, MAD_F(0x0216a2a2) /* 0.130526192 */,
  MAD_F(0x03768962) /* 0.216439614 */, MAD_F(0x04cfb0e2) /* 0.300705800 */,
  MAD_F(0x061f78aa) /* 0.382683432 */, MAD_F(0x07635284) /* 0.461748613 */,
  MAD_F(0x0898c779) /* 0.537299608 */, MAD_F(0x09bd7ca0) /* 0.608761429 */,
  MAD_F(0x0acf37ad) /* 0.675590208 */, MAD_F(0x0bcbe352) /* 0.737277337 */,
  MAD_F(0x0cb19346) /* 0.793353340 */, MAD_F(0x0d7e8807) /* 0.843391446 */,

  MAD_F(0x0e313245) /* 0.887010833 */, MAD_F(0x0ec835e8) /* 0.923879533 */,
  MAD_F(0x0f426cb5) /* 0.953716951 */, MAD_F(0x0f9ee890) /* 0.976296007 */,
  MAD_F(0x0fdcf549) /* 0.991444861 */, MAD_F(0x0ffc19fd) /* 0.999048222 */,
  MAD_F(0x0ffc19fd) /* 0.999048222 */, MAD_F(0x0fdcf549) /* 0.991444861 */,
  MAD_F(0x0f9ee890) /* 0.976296007 */, MAD_F(0x0f426cb5) /* 0.953716951 */,
  MAD_F(0x0ec835e8) /* 0.923879533 */, MAD_F(0x0e313245) /* 0.887010833 */,

  MAD_F(0x0d7e8807) /* 0.843391446 */, MAD_F(0x0cb19346) /* 0.793353340 */,
  MAD_F(0x0bcbe352) /* 0.737277337 */, MAD_F(0x0acf37ad) /* 0.675590208 */,
  MAD_F(0x09bd7ca0) /* 0.608761429 */, MAD_F(0x0898c779) /* 0.537299608 */,
  MAD_F(0x07635284) /* 0.461748613 */, MAD_F(0x061f78aa) /* 0.382683432 */,
  MAD_F(0x04cfb0e2) /* 0.300705800 */, MAD_F(0x03768962) /* 0.216439614 */,
  MAD_F(0x0216a2a2) /* 0.130526192 */, MAD_F(0x00b2aa3e) /* 0.043619387 */,
};
static inline mad_fixed_t window_l(int i)
{
  return window_l_val[i];
}
# endif  /* ASO_IMDCT */

/*
   windowing coefficients for short blocks
   derived from section 2.4.3.4.10.3 of ISO/IEC 11172-3

   window_s[i] = sin((PI / 12) * (i + 1/2))
*/
static mad_fixed_t const window_s_val[12] PROGMEM = {
  MAD_F(0x0216a2a2) /* 0.130526192 */, MAD_F(0x061f78aa) /* 0.382683432 */,
  MAD_F(0x09bd7ca0) /* 0.608761429 */, MAD_F(0x0cb19346) /* 0.793353340 */,
  MAD_F(0x0ec835e8) /* 0.923879533 */, MAD_F(0x0fdcf549) /* 0.991444861 */,
  MAD_F(0x0fdcf549) /* 0.991444861 */, MAD_F(0x0ec835e8) /* 0.923879533 */,
  MAD_F(0x0cb19346) /* 0.793353340 */, MAD_F(0x09bd7ca0) /* 0.608761429 */,
  MAD_F(0x061f78aa) /* 0.382683432 */, MAD_F(0x0216a2a2) /* 0.130526192 */,
};
static inline mad_fixed_t window_s(int i)
{
  return window_s_val[i];
}

/*
   coefficients for intensity stereo processing
   derived from section 2.4.3.4.9.3 of ISO/IEC 11172-3

   is_ratio[i] = tan(i * (PI / 12))
   is_table[i] = is_ratio[i] / (1 + is_ratio[i])
*/
static mad_fixed_t const is_table_val[7] PROGMEM = {
  MAD_F(0x00000000) /* 0.000000000 */,
  MAD_F(0x0361962f) /* 0.211324865 */,
  MAD_F(0x05db3d74) /* 0.366025404 */,
  MAD_F(0x08000000) /* 0.500000000 */,
  MAD_F(0x0a24c28c) /* 0.633974596 */,
  MAD_F(0x0c9e69d1) /* 0.788675135 */,
  MAD_F(0x10000000) /* 1.000000000 */
};
static inline mad_fixed_t is_table(int i)
{
  return is_table_val[i];
}

/*
   coefficients for LSF intensity stereo processing
   derived from section 2.4.3.2 of ISO/IEC 13818-3

   is_lsf_table[0][i] = (1 / sqrt(sqrt(2)))^(i + 1)
   is_lsf_table[1][i] = (1 /      sqrt(2)) ^(i + 1)
*/
static
mad_fixed_t const is_lsf_table[2][15] PROGMEM = {
  {
    MAD_F(0x0d744fcd) /* 0.840896415 */,
    MAD_F(0x0b504f33) /* 0.707106781 */,
    MAD_F(0x09837f05) /* 0.594603558 */,
    MAD_F(0x08000000) /* 0.500000000 */,
    MAD_F(0x06ba27e6) /* 0.420448208 */,
    MAD_F(0x05a8279a) /* 0.353553391 */,
    MAD_F(0x04c1bf83) /* 0.297301779 */,
    MAD_F(0x04000000) /* 0.250000000 */,
    MAD_F(0x035d13f3) /* 0.210224104 */,
    MAD_F(0x02d413cd) /* 0.176776695 */,
    MAD_F(0x0260dfc1) /* 0.148650889 */,
    MAD_F(0x02000000) /* 0.125000000 */,
    MAD_F(0x01ae89fa) /* 0.105112052 */,
    MAD_F(0x016a09e6) /* 0.088388348 */,
    MAD_F(0x01306fe1) /* 0.074325445 */
  }, {
    MAD_F(0x0b504f33) /* 0.707106781 */,
    MAD_F(0x08000000) /* 0.500000000 */,
    MAD_F(0x05a8279a) /* 0.353553391 */,
    MAD_F(0x04000000) /* 0.250000000 */,
    MAD_F(0x02d413cd) /* 0.176776695 */,
    MAD_F(0x02000000) /* 0.125000000 */,
    MAD_F(0x016a09e6) /* 0.088388348 */,
    MAD_F(0x01000000) /* 0.062500000 */,
    MAD_F(0x00b504f3) /* 0.044194174 */,
    MAD_F(0x00800000) /* 0.031250000 */,
    MAD_F(0x005a827a) /* 0.022097087 */,
    MAD_F(0x00400000) /* 0.015625000 */,
    MAD_F(0x002d413d) /* 0.011048543 */,
    MAD_F(0x00200000) /* 0.007812500 */,
    MAD_F(0x0016a09e) /* 0.005524272 */
  }
};

/*
   NAME:	III_sideinfo()
   DESCRIPTION:	decode frame side information from a bitstream
*/
static
enum mad_error III_sideinfo(struct mad_bitptr *ptr, unsigned int nch,
                            int lsf, struct sideinfo *si,
                            unsigned int *data_bitlen,
                            unsigned int *priv_bitlen)
{
  unsigned int ngr, gr, ch, i;
  enum mad_error result = MAD_ERROR_NONE;
  stack(__FUNCTION__, __FILE__, __LINE__);

  *data_bitlen = 0;
  *priv_bitlen = lsf ? ((nch == 1) ? 1 : 2) : ((nch == 1) ? 5 : 3);

  si->main_data_begin = mad_bit_read(ptr, lsf ? 8 : 9);
  si->private_bits    = mad_bit_read(ptr, *priv_bitlen);

  ngr = 1;
  if (!lsf) {
    ngr = 2;

    for (ch = 0; ch < nch; ++ch)
      si->scfsi[ch] = mad_bit_read(ptr, 4);
  }

  for (gr = 0; gr < ngr; ++gr) {
    struct granule *granule = &si->gr[gr];

    for (ch = 0; ch < nch; ++ch) {
      struct channel *channel = &granule->ch[ch];

      channel->part2_3_length    = mad_bit_read(ptr, 12);
      channel->big_values        = mad_bit_read(ptr, 9);
      channel->global_gain       = mad_bit_read(ptr, 8);
      channel->scalefac_compress = mad_bit_read(ptr, lsf ? 9 : 4);

      *data_bitlen += channel->part2_3_length;

      if (channel->big_values > 288 && result == 0)
        result = MAD_ERROR_BADBIGVALUES;

      channel->flags = 0;

      /* window_switching_flag */
      if (mad_bit_read(ptr, 1)) {
        channel->block_type = mad_bit_read(ptr, 2);

        if (channel->block_type == 0 && result == 0)
          result = MAD_ERROR_BADBLOCKTYPE;

        if (!lsf && channel->block_type == 2 && si->scfsi[ch] && result == 0)
          result = MAD_ERROR_BADSCFSI;

        channel->region0_count = 7;
        channel->region1_count = 36;

        if (mad_bit_read(ptr, 1))
          channel->flags |= mixed_block_flag;
        else if (channel->block_type == 2)
          channel->region0_count = 8;

        for (i = 0; i < 2; ++i)
          channel->table_select[i] = mad_bit_read(ptr, 5);

# if defined(DEBUG)
        channel->table_select[2] = 4;  /* not used */
# endif

        for (i = 0; i < 3; ++i)
          channel->subblock_gain[i] = mad_bit_read(ptr, 3);
      }
      else {
        channel->block_type = 0;

        for (i = 0; i < 3; ++i)
          channel->table_select[i] = mad_bit_read(ptr, 5);

        channel->region0_count = mad_bit_read(ptr, 4);
        channel->region1_count = mad_bit_read(ptr, 3);
      }

      /* [preflag,] scalefac_scale, count1table_select */
      channel->flags |= mad_bit_read(ptr, lsf ? 2 : 3);
    }
  }

  return result;
}

/*
   NAME:	III_scalefactors_lsf()
   DESCRIPTION:	decode channel scalefactors for LSF from a bitstream
*/
static
unsigned int III_scalefactors_lsf(struct mad_bitptr *ptr,
                                  struct channel *channel,
                                  struct channel *gr1ch, int mode_extension)
{
  struct mad_bitptr start;
  unsigned int scalefac_compress, index, slen[4], part, n, i;
  unsigned int const *nsfb;
  stack(__FUNCTION__, __FILE__, __LINE__);

  start = *ptr;

  scalefac_compress = channel->scalefac_compress;
  index = (channel->block_type == 2) ?
          ((channel->flags & mixed_block_flag) ? 2 : 1) : 0;

  if (!((mode_extension & I_STEREO) && gr1ch)) {
    if (scalefac_compress < 400) {
      slen[0] = (scalefac_compress >> 4) / 5;
      slen[1] = (scalefac_compress >> 4) % 5;
      slen[2] = (scalefac_compress % 16) >> 2;
      slen[3] =  scalefac_compress %  4;

      nsfb = nsfb_table[0][index];
    }
    else if (scalefac_compress < 500) {
      scalefac_compress -= 400;

      slen[0] = (scalefac_compress >> 2) / 5;
      slen[1] = (scalefac_compress >> 2) % 5;
      slen[2] =  scalefac_compress %  4;
      slen[3] = 0;

      nsfb = nsfb_table[1][index];
    }
    else {
      scalefac_compress -= 500;

      slen[0] = scalefac_compress / 3;
      slen[1] = scalefac_compress % 3;
      slen[2] = 0;
      slen[3] = 0;

      channel->flags |= preflag;

      nsfb = nsfb_table[2][index];
    }

    n = 0;
    for (part = 0; part < 4; ++part) {
      for (i = 0; i < nsfb[part]; ++i)
        channel->scalefac[n++] = mad_bit_read(ptr, slen[part]);
    }

    while (n < 39)
      channel->scalefac[n++] = 0;
  }
  else {  /* (mode_extension & I_STEREO) && gr1ch (i.e. ch == 1) */
    scalefac_compress >>= 1;

    if (scalefac_compress < 180) {
      slen[0] =  scalefac_compress / 36;
      slen[1] = (scalefac_compress % 36) / 6;
      slen[2] = (scalefac_compress % 36) % 6;
      slen[3] = 0;

      nsfb = nsfb_table[3][index];
    }
    else if (scalefac_compress < 244) {
      scalefac_compress -= 180;

      slen[0] = (scalefac_compress % 64) >> 4;
      slen[1] = (scalefac_compress % 16) >> 2;
      slen[2] =  scalefac_compress %  4;
      slen[3] = 0;

      nsfb = nsfb_table[4][index];
    }
    else {
      scalefac_compress -= 244;

      slen[0] = scalefac_compress / 3;
      slen[1] = scalefac_compress % 3;
      slen[2] = 0;
      slen[3] = 0;

      nsfb = nsfb_table[5][index];
    }

    n = 0;
    for (part = 0; part < 4; ++part) {
      unsigned int max, is_pos;

      max = (1 << slen[part]) - 1;

      for (i = 0; i < nsfb[part]; ++i) {
        is_pos = mad_bit_read(ptr, slen[part]);

        channel->scalefac[n] = is_pos;
        gr1ch->scalefac[n++] = (is_pos == max);
      }
    }

    while (n < 39) {
      channel->scalefac[n] = 0;
      gr1ch->scalefac[n++] = 0;  /* apparently not illegal */
    }
  }

  return mad_bit_length(&start, ptr);
}

/*
   NAME:	III_scalefactors()
   DESCRIPTION:	decode channel scalefactors of one granule from a bitstream
*/
static
unsigned int III_scalefactors(struct mad_bitptr *ptr, struct channel *channel,
                              struct channel const *gr0ch, unsigned int scfsi)
{
  struct mad_bitptr start;
  unsigned int slen1, slen2, sfbi;
  stack(__FUNCTION__, __FILE__, __LINE__);

  start = *ptr;

  slen1 = sflen_table[channel->scalefac_compress].slen1;
  slen2 = sflen_table[channel->scalefac_compress].slen2;

  if (channel->block_type == 2) {
    unsigned int nsfb;

    sfbi = 0;

    nsfb = (channel->flags & mixed_block_flag) ? 8 + 3 * 3 : 6 * 3;
    while (nsfb--)
      channel->scalefac[sfbi++] = mad_bit_read(ptr, slen1);

    nsfb = 6 * 3;
    while (nsfb--)
      channel->scalefac[sfbi++] = mad_bit_read(ptr, slen2);

    nsfb = 1 * 3;
    while (nsfb--)
      channel->scalefac[sfbi++] = 0;
  }
  else {  /* channel->block_type != 2 */
    if (scfsi & 0x8) {
      for (sfbi = 0; sfbi < 6; ++sfbi)
        channel->scalefac[sfbi] = gr0ch->scalefac[sfbi];
    }
    else {
      for (sfbi = 0; sfbi < 6; ++sfbi)
        channel->scalefac[sfbi] = mad_bit_read(ptr, slen1);
    }

    if (scfsi & 0x4) {
      for (sfbi = 6; sfbi < 11; ++sfbi)
        channel->scalefac[sfbi] = gr0ch->scalefac[sfbi];
    }
    else {
      for (sfbi = 6; sfbi < 11; ++sfbi)
        channel->scalefac[sfbi] = mad_bit_read(ptr, slen1);
    }

    if (scfsi & 0x2) {
      for (sfbi = 11; sfbi < 16; ++sfbi)
        channel->scalefac[sfbi] = gr0ch->scalefac[sfbi];
    }
    else {
      for (sfbi = 11; sfbi < 16; ++sfbi)
        channel->scalefac[sfbi] = mad_bit_read(ptr, slen2);
    }

    if (scfsi & 0x1) {
      for (sfbi = 16; sfbi < 21; ++sfbi)
        channel->scalefac[sfbi] = gr0ch->scalefac[sfbi];
    }
    else {
      for (sfbi = 16; sfbi < 21; ++sfbi)
        channel->scalefac[sfbi] = mad_bit_read(ptr, slen2);
    }

    channel->scalefac[21] = 0;
  }

  return mad_bit_length(&start, ptr);
}

/*
   The Layer III formula for requantization and scaling is defined by
   section 2.4.3.4.7.1 of ISO/IEC 11172-3, as follows:

     long blocks:
     xr[i] = sign(is[i]) * abs(is[i])^(4/3)
             2^((1/4) * (global_gain - 210))
             2^-(scalefac_multiplier
                 (scalefac_l[sfb] + preflag * pretab[sfb]))

     short blocks:
     xr[i] = sign(is[i]) * abs(is[i])^(4/3)
             2^((1/4) * (global_gain - 210 - 8 * subblock_gain[w]))
             2^-(scalefac_multiplier * scalefac_s[sfb][w])

     where:
     scalefac_multiplier = (scalefac_scale + 1) / 2

   The routines III_exponents() and III_requantize() facilitate this
   calculation.
*/

/*
   NAME:	III_exponents()
   DESCRIPTION:	calculate scalefactor exponents
*/
static
void III_exponents(struct channel const *channel,
                   unsigned int const *sfbwidth, signed int exponents[39])
{
  signed int gain;
  unsigned int scalefac_multiplier, sfbi;
  stack(__FUNCTION__, __FILE__, __LINE__);

  gain = (signed int) channel->global_gain - 210;
  scalefac_multiplier = (channel->flags & scalefac_scale) ? 2 : 1;

  if (channel->block_type == 2) {
    unsigned int l;
    signed int gain0, gain1, gain2;

    sfbi = l = 0;

    if (channel->flags & mixed_block_flag) {
      unsigned int premask;

      premask = (channel->flags & preflag) ? ~0 : 0;

      /* long block subbands 0-1 */

      while (l < 36) {
        exponents[sfbi] = gain -
                          (signed int) ((channel->scalefac[sfbi] + (pretab[sfbi] & premask)) <<
                                        scalefac_multiplier);

        l += sfbwidth[sfbi++];
      }
    }

    /* this is probably wrong for 8000 Hz short/mixed blocks */

    gain0 = gain - 8 * (signed int) channel->subblock_gain[0];
    gain1 = gain - 8 * (signed int) channel->subblock_gain[1];
    gain2 = gain - 8 * (signed int) channel->subblock_gain[2];

    while (l < 576) {
      exponents[sfbi + 0] = gain0 -
                            (signed int) (channel->scalefac[sfbi + 0] << scalefac_multiplier);
      exponents[sfbi + 1] = gain1 -
                            (signed int) (channel->scalefac[sfbi + 1] << scalefac_multiplier);
      exponents[sfbi + 2] = gain2 -
                            (signed int) (channel->scalefac[sfbi + 2] << scalefac_multiplier);

      l    += 3 * sfbwidth[sfbi];
      sfbi += 3;
    }
  }
  else {  /* channel->block_type != 2 */
    if (channel->flags & preflag) {
      for (sfbi = 0; sfbi < 22; ++sfbi) {
        exponents[sfbi] = gain -
                          (signed int) ((channel->scalefac[sfbi] + pretab[sfbi]) <<
                                        scalefac_multiplier);
      }
    }
    else {
      for (sfbi = 0; sfbi < 22; ++sfbi) {
        exponents[sfbi] = gain -
                          (signed int) (channel->scalefac[sfbi] << scalefac_multiplier);
      }
    }
  }
}

/*
   NAME:	III_requantize()
   DESCRIPTION:	requantize one (positive) value
*/
static
mad_fixed_t III_requantize(unsigned int value, signed int exp)
{
  mad_fixed_t requantized;
  signed int frac;
  struct fixedfloat power;

  stack(__FUNCTION__, __FILE__, __LINE__);
  frac = exp % 4;  /* assumes sign(frac) == sign(exp) */
  exp /= 4;

#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wstrict-aliasing"
  *(uint32_t*)&power = *(uint32_t*)&rq_table[value]; //memcpy_P(&power, &rq_table[value], sizeof(power)); // Avoid byte access to PROGMEM
#pragma GCC diagnostic pop
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wuninitialized"
  requantized = power.mantissa;
  exp += power.exponent;
#pragma GCC diagnostic pop

  if (exp < 0) {
    if (-exp >= (int)(sizeof(mad_fixed_t) * CHAR_BIT)) {
      /* underflow */
      requantized = 0;
    }
    else {
      requantized += 1L << (-exp - 1);
      requantized >>= -exp;
    }
  }
  else {
    if (exp >= 5) {
      /* overflow */
# if 0 && defined(DEBUG)
      fprintf(stderr, "requantize overflow (%f * 2^%d)\n",
              mad_f_todouble(requantized), exp);
# endif
      requantized = MAD_F_MAX;
    }
    else
      requantized <<= exp;
  }
  return frac ? mad_f_mul(requantized, root_table(3 + frac)) : requantized;
}

/* we must take care that sz >= bits and sz < sizeof(long) lest bits == 0 */
# define MASK(cache, sz, bits)	\
  (((cache) >> ((sz) - (bits))) & ((1 << (bits)) - 1))
# define MASK1BIT(cache, sz)  \
  ((cache) & (1 << ((sz) - 1)))

/*
   NAME:	III_huffdecode()
   DESCRIPTION:	decode Huffman code words of one channel of one granule
*/
static
enum mad_error III_huffdecode(struct mad_bitptr *ptr, mad_fixed_t xr[576],
                              struct channel *channel,
                              unsigned int const *sfbwidth,
                              unsigned int part2_length)
{
  signed int exponents[39], exp;
  signed int const *expptr;
  struct mad_bitptr peek;
  signed int bits_left, cachesz;
  register mad_fixed_t *xrptr;
  mad_fixed_t const *sfbound;
  register unsigned long bitcache;

  stack(__FUNCTION__, __FILE__, __LINE__);
  bits_left = (signed) channel->part2_3_length - (signed) part2_length;
  if (bits_left < 0)
    return MAD_ERROR_BADPART3LEN;

  III_exponents(channel, sfbwidth, exponents);

  peek = *ptr;
  mad_bit_skip(ptr, bits_left);

  /* align bit reads to byte boundaries */
  cachesz  = mad_bit_bitsleft(&peek);
  cachesz += ((32 - 1 - 24) + (24 - cachesz)) & ~7;

  bitcache   = mad_bit_read(&peek, cachesz);
  bits_left -= cachesz;

  xrptr = &xr[0];

  /* big_values */
  {
    unsigned int region, rcount;
    struct hufftable const *entry;
    union huffpair const *table;
    unsigned int linbits, startbits, big_values, reqhits;
    mad_fixed_t reqcache[16];

    sfbound = xrptr + *sfbwidth++;
    rcount  = channel->region0_count + 1;

    entry     = &mad_huff_pair_table[channel->table_select[region = 0]];
    table     = entry->table;
    linbits   = entry->linbits;
    startbits = entry->startbits;

    if (table == 0)
      return MAD_ERROR_BADHUFFTABLE;

    expptr  = &exponents[0];
    exp     = *expptr++;
    reqhits = 0;

    big_values = channel->big_values;

    while (big_values-- && cachesz + bits_left > 0) {
      union huffpair const *pair;
      unsigned int clumpsz, value;
      register mad_fixed_t requantized;

      if (xrptr == sfbound) {
        sfbound += *sfbwidth++;

        /* change table if region boundary */

        if (--rcount == 0) {
          if (region == 0)
            rcount = channel->region1_count + 1;
          else
            rcount = 0;  /* all remaining */

          entry     = &mad_huff_pair_table[channel->table_select[++region]];
          table     = entry->table;
          linbits   = entry->linbits;
          startbits = entry->startbits;

          if (table == 0)
            return MAD_ERROR_BADHUFFTABLE;
        }

        if (exp != *expptr) {
          exp = *expptr;
          reqhits = 0;
        }

        ++expptr;
      }

      if (cachesz < 21) {
        unsigned int bits;

        bits       = ((32 - 1 - 21) + (21 - cachesz)) & ~7;
        bitcache   = (bitcache << bits) | mad_bit_read(&peek, bits);
        cachesz   += bits;
        bits_left -= bits;
      }

      /* hcod (0..19) */

      clumpsz = startbits;
      pair    = &table[MASK(bitcache, cachesz, clumpsz)];

      while (!pair->final) {
        cachesz -= clumpsz;

        clumpsz = pair->ptr.bits;
        pair    = &table[pair->ptr.offset + MASK(bitcache, cachesz, clumpsz)];
      }

      cachesz -= pair->value.hlen;

      if (linbits) {
        /* x (0..14) */

        value = pair->value.x;

        switch (value) {
          case 0:
            xrptr[0] = 0;
            break;

          case 15:
            if (cachesz < (int)(linbits + 2)) {
              bitcache   = (bitcache << 16) | mad_bit_read(&peek, 16);
              cachesz   += 16;
              bits_left -= 16;
            }

            value += MASK(bitcache, cachesz, linbits);
            cachesz -= linbits;

            requantized = III_requantize(value, exp);
            goto x_final;

          default:
            if (reqhits & (1 << value))
              requantized = reqcache[value];
            else {
              reqhits |= (1 << value);
              requantized = reqcache[value] = III_requantize(value, exp);
            }

x_final:
            xrptr[0] = MASK1BIT(bitcache, cachesz--) ?
                       -requantized : requantized;
        }

        /* y (0..14) */

        value = pair->value.y;

        switch (value) {
          case 0:
            xrptr[1] = 0;
            break;

          case 15:
            if (cachesz < (int)(linbits + 1)) {
              bitcache   = (bitcache << 16) | mad_bit_read(&peek, 16);
              cachesz   += 16;
              bits_left -= 16;
            }

            value += MASK(bitcache, cachesz, linbits);
            cachesz -= linbits;

            requantized = III_requantize(value, exp);
            goto y_final;

          default:
            if (reqhits & (1 << value))
              requantized = reqcache[value];
            else {
              reqhits |= (1 << value);
              requantized = reqcache[value] = III_requantize(value, exp);
            }

y_final:
            xrptr[1] = MASK1BIT(bitcache, cachesz--) ?
                       -requantized : requantized;
        }
      }
      else {
        /* x (0..1) */

        value = pair->value.x;

        if (value == 0)
          xrptr[0] = 0;
        else {
          if (reqhits & (1 << value))
            requantized = reqcache[value];
          else {
            reqhits |= (1 << value);
            requantized = reqcache[value] = III_requantize(value, exp);
          }

          xrptr[0] = MASK1BIT(bitcache, cachesz--) ?
                     -requantized : requantized;
        }

        /* y (0..1) */

        value = pair->value.y;

        if (value == 0)
          xrptr[1] = 0;
        else {
          if (reqhits & (1 << value))
            requantized = reqcache[value];
          else {
            reqhits |= (1 << value);
            requantized = reqcache[value] = III_requantize(value, exp);
          }

          xrptr[1] = MASK1BIT(bitcache, cachesz--) ?
                     -requantized : requantized;
        }
      }

      xrptr += 2;
    }
  }

  if (cachesz + bits_left < 0)
    return MAD_ERROR_BADHUFFDATA;  /* big_values overrun */

  /* count1 */
  {
    union huffquad const *table;
    register mad_fixed_t requantized;

    table = mad_huff_quad_table[channel->flags & count1table_select];

    requantized = III_requantize(1, exp);

    while (cachesz + bits_left > 0 && xrptr <= &xr[572]) {
      union huffquad const *quad;

      /* hcod (1..6) */

      if (cachesz < 10) {
        bitcache   = (bitcache << 16) | mad_bit_read(&peek, 16);
        cachesz   += 16;
        bits_left -= 16;
      }

      quad = &table[MASK(bitcache, cachesz, 4)];

      /* quad tables guaranteed to have at most one extra lookup */
      if (!quad->final) {
        cachesz -= 4;

        quad = &table[quad->ptr.offset +
                      MASK(bitcache, cachesz, quad->ptr.bits)];
      }

      cachesz -= quad->value.hlen;

      if (xrptr == sfbound) {
        sfbound += *sfbwidth++;

        if (exp != *expptr) {
          exp = *expptr;
          requantized = III_requantize(1, exp);
        }

        ++expptr;
      }

      /* v (0..1) */

      xrptr[0] = quad->value.v ?
                 (MASK1BIT(bitcache, cachesz--) ? -requantized : requantized) : 0;

      /* w (0..1) */

      xrptr[1] = quad->value.w ?
                 (MASK1BIT(bitcache, cachesz--) ? -requantized : requantized) : 0;

      xrptr += 2;

      if (xrptr == sfbound) {
        sfbound += *sfbwidth++;

        if (exp != *expptr) {
          exp = *expptr;
          requantized = III_requantize(1, exp);
        }

        ++expptr;
      }

      /* x (0..1) */

      xrptr[0] = quad->value.x ?
                 (MASK1BIT(bitcache, cachesz--) ? -requantized : requantized) : 0;

      /* y (0..1) */

      xrptr[1] = quad->value.y ?
                 (MASK1BIT(bitcache, cachesz--) ? -requantized : requantized) : 0;

      xrptr += 2;
    }

    if (cachesz + bits_left < 0) {
# if 0 && defined(DEBUG)
      fprintf(stderr, "huffman count1 overrun (%d bits)\n",
              -(cachesz + bits_left));
# endif

      /* technically the bitstream is misformatted, but apparently
        some encoders are just a bit sloppy with stuffing bits */

      xrptr -= 4;
    }
  }

  assert(-bits_left <= MAD_BUFFER_GUARD * CHAR_BIT);

# if 0 && defined(DEBUG)
  if (bits_left < 0)
    fprintf(stderr, "read %d bits too many\n", -bits_left);
  else if (cachesz + bits_left > 0)
    fprintf(stderr, "%d stuffing bits\n", cachesz + bits_left);
# endif

  /* rzero */
  while (xrptr < &xr[576]) {
    xrptr[0] = 0;
    xrptr[1] = 0;

    xrptr += 2;
  }

  return MAD_ERROR_NONE;
}

# undef MASK
# undef MASK1BIT

/*
   NAME:	III_reorder()
   DESCRIPTION:	reorder frequency lines of a short block into subband order
*/
static
enum mad_error III_reorder(mad_fixed_t xr[576], struct channel const *channel,
                 unsigned int const sfbwidth[39], mad_fixed_t tmp[576])
{
  unsigned int sb, l, f, w, sbw[3], sw[3];
//  mad_fixed_t *tmp; // [32][3][6]
  // See if we can allocate this buffer on the stack and save heap
//  char onstack = 0;
//  if (stackfree() > (int)(100 + sizeof(mad_fixed_t)*32*3*6)) {
//    onstack = 1;
//    tmp = alloca(sizeof(mad_fixed_t)*32*3*6);
//  } else {
//    tmp = (mad_fixed_t*)malloc(sizeof(mad_fixed_t)*32*3*6);
//    if (!tmp) return MAD_ERROR_NOMEM;
//  }

  stack(__FUNCTION__, __FILE__, __LINE__);

  /* this is probably wrong for 8000 Hz mixed blocks */

  sb = 0;
  if (channel->flags & mixed_block_flag) {
    sb = 2;

    l = 0;
    while (l < 36)
      l += *sfbwidth++;
  }

  for (w = 0; w < 3; ++w) {
    sbw[w] = sb;
    sw[w]  = 0;
  }

  f = *sfbwidth++;
  w = 0;

  for (l = 18 * sb; l < 576; ++l) {
    if (f-- == 0) {
      f = *sfbwidth++ - 1;
      w = (w + 1) % 3;
    }

    tmp[ (sbw[w]*3*6) + (w*6) + (sw[w]++) ] = xr[l];

    if (sw[w] == 6) {
      sw[w] = 0;
      ++sbw[w];
    }
  }

  memcpy(&xr[18 * sb], &tmp[sb * 3 * 6], (576 - 18 * sb) * sizeof(mad_fixed_t));

//  if (!onstack) free(tmp);
//  // If it's on the stack, it'll go away on the return
  return MAD_ERROR_NONE;
}

/*
   NAME:	III_stereo()
   DESCRIPTION:	perform joint stereo processing on a granule
*/
static
enum mad_error III_stereo(mad_fixed_t xr[2][576],
                          struct granule const *granule,
                          struct mad_header *header,
                          unsigned int const *sfbwidth)
{
  short modes[39];
  unsigned int sfbi, l, n, i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  if (granule->ch[0].block_type !=
      granule->ch[1].block_type ||
      (granule->ch[0].flags & mixed_block_flag) !=
      (granule->ch[1].flags & mixed_block_flag))
    return MAD_ERROR_BADSTEREO;

  for (i = 0; i < 39; ++i)
    modes[i] = header->mode_extension;

  /* intensity stereo */

  if (header->mode_extension & I_STEREO) {
    struct channel const *right_ch = &granule->ch[1];
    mad_fixed_t const *right_xr = xr[1];
    unsigned int is_pos;

    header->flags |= MAD_FLAG_I_STEREO;

    /* first determine which scalefactor bands are to be processed */

    if (right_ch->block_type == 2) {
      unsigned int lower, start, max, bound[3], w;

      lower = start = max = bound[0] = bound[1] = bound[2] = 0;

      sfbi = l = 0;

      if (right_ch->flags & mixed_block_flag) {
        while (l < 36) {
          n = sfbwidth[sfbi++];

          for (i = 0; i < n; ++i) {
            if (right_xr[i]) {
              lower = sfbi;
              break;
            }
          }

          right_xr += n;
          l += n;
        }

        start = sfbi;
      }

      w = 0;
      while (l < 576) {
        n = sfbwidth[sfbi++];

        for (i = 0; i < n; ++i) {
          if (right_xr[i]) {
            max = bound[w] = sfbi;
            break;
          }
        }

        right_xr += n;
        l += n;
        w = (w + 1) % 3;
      }

      if (max)
        lower = start;

      /* long blocks */

      for (i = 0; i < lower; ++i)
        modes[i] = header->mode_extension & ~I_STEREO;

      /* short blocks */

      w = 0;
      for (i = start; i < max; ++i) {
        if (i < bound[w])
          modes[i] = header->mode_extension & ~I_STEREO;

        w = (w + 1) % 3;
      }
    }
    else {  /* right_ch->block_type != 2 */
      unsigned int bound;

      bound = 0;
      for (sfbi = l = 0; l < 576; l += n) {
        n = sfbwidth[sfbi++];

        for (i = 0; i < n; ++i) {
          if (right_xr[i]) {
            bound = sfbi;
            break;
          }
        }

        right_xr += n;
      }

      for (i = 0; i < bound; ++i)
        modes[i] = header->mode_extension & ~I_STEREO;
    }

    /* now do the actual processing */

    if (header->flags & MAD_FLAG_LSF_EXT) {
      unsigned char const *illegal_pos = granule[1].ch[1].scalefac;
      mad_fixed_t const *lsf_scale;

      /* intensity_scale */
      lsf_scale = is_lsf_table[right_ch->scalefac_compress & 0x1];

      for (sfbi = l = 0; l < 576; ++sfbi, l += n) {
        n = sfbwidth[sfbi];

        if (!(modes[sfbi] & I_STEREO))
          continue;

        if (illegal_pos[sfbi]) {
          modes[sfbi] &= ~I_STEREO;
          continue;
        }

        is_pos = right_ch->scalefac[sfbi];

        for (i = 0; i < n; ++i) {
          register mad_fixed_t left;

          left = xr[0][l + i];

          if (is_pos == 0)
            xr[1][l + i] = left;
          else {
            register mad_fixed_t opposite;

            opposite = mad_f_mul(left, lsf_scale[(is_pos - 1) / 2]);

            if (is_pos & 1) {
              xr[0][l + i] = opposite;
              xr[1][l + i] = left;
            }
            else
              xr[1][l + i] = opposite;
          }
        }
      }
    }
    else {  /* !(header->flags & MAD_FLAG_LSF_EXT) */
      for (sfbi = l = 0; l < 576; ++sfbi, l += n) {
        n = sfbwidth[sfbi];

        if (!(modes[sfbi] & I_STEREO))
          continue;

        is_pos = right_ch->scalefac[sfbi];

        if (is_pos >= 7) {  /* illegal intensity position */
          modes[sfbi] &= ~I_STEREO;
          continue;
        }

        for (i = 0; i < n; ++i) {
          register mad_fixed_t left;

          left = xr[0][l + i];

          xr[0][l + i] = mad_f_mul(left, is_table(    is_pos));
          xr[1][l + i] = mad_f_mul(left, is_table(6 - is_pos));
        }
      }
    }
  }

  /* middle/side stereo */

  if (header->mode_extension & MS_STEREO) {
    register mad_fixed_t invsqrt2;

    header->flags |= MAD_FLAG_MS_STEREO;

    invsqrt2 = root_table(3 + -2);

    for (sfbi = l = 0; l < 576; ++sfbi, l += n) {
      n = sfbwidth[sfbi];

      if (modes[sfbi] != MS_STEREO)
        continue;

      for (i = 0; i < n; ++i) {
        register mad_fixed_t m, s;

        m = xr[0][l + i];
        s = xr[1][l + i];

        xr[0][l + i] = mad_f_mul(m + s, invsqrt2);  /* l = (m + s) / sqrt(2) */
        xr[1][l + i] = mad_f_mul(m - s, invsqrt2);  /* r = (m - s) / sqrt(2) */
      }
    }
  }

  return MAD_ERROR_NONE;
}

/*
   NAME:	III_aliasreduce()
   DESCRIPTION:	perform frequency line alias reduction
*/
static
void III_aliasreduce(mad_fixed_t xr[576], int lines)
{
  mad_fixed_t const *bound;
  int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  bound = &xr[lines];
  for (xr += 18; xr < bound; xr += 18) {
    for (i = 0; i < 8; ++i) {
      register mad_fixed_t a, b;
      register mad_fixed64hi_t hi;
      register mad_fixed64lo_t lo;

      a = xr[-1 - i];
      b = xr[     i];

# if defined(ASO_ZEROCHECK)
      if (a | b) {
# endif
        MAD_F_ML0(hi, lo,  a, cs(i));
        MAD_F_MLA(hi, lo, -b, ca(i));

        xr[-1 - i] = MAD_F_MLZ(hi, lo);

        MAD_F_ML0(hi, lo,  b, cs(i));
        MAD_F_MLA(hi, lo,  a, ca(i));

        xr[     i] = MAD_F_MLZ(hi, lo);
# if defined(ASO_ZEROCHECK)
      }
# endif
    }
  }
}

# if defined(ASO_IMDCT)
void III_imdct_l(mad_fixed_t const [18], mad_fixed_t [36], unsigned int);
# else
#  if 1
static
void fastsdct(mad_fixed_t const x[9], mad_fixed_t y[18])
{
  mad_fixed_t a0,  a1,  a2,  a3,  a4,  a5,  a6,  a7,  a8,  a9,  a10, a11, a12;
  mad_fixed_t a13, a14, a15, a16, a17, a18, a19, a20, a21, a22, a23, a24, a25;
  mad_fixed_t m0,  m1,  m2,  m3,  m4,  m5,  m6,  m7;

  enum {
    c0 =  MAD_F(0x1f838b8d),  /* 2 * cos( 1 * PI / 18) */
    c1 =  MAD_F(0x1bb67ae8),  /* 2 * cos( 3 * PI / 18) */
    c2 =  MAD_F(0x18836fa3),  /* 2 * cos( 4 * PI / 18) */
    c3 =  MAD_F(0x1491b752),  /* 2 * cos( 5 * PI / 18) */
    c4 =  MAD_F(0x0af1d43a),  /* 2 * cos( 7 * PI / 18) */
    c5 =  MAD_F(0x058e86a0),  /* 2 * cos( 8 * PI / 18) */
    c6 = -MAD_F(0x1e11f642)   /* 2 * cos(16 * PI / 18) */
  };

  a0 = x[3] + x[5];
  a1 = x[3] - x[5];
  a2 = x[6] + x[2];
  a3 = x[6] - x[2];
  a4 = x[1] + x[7];
  a5 = x[1] - x[7];
  a6 = x[8] + x[0];
  a7 = x[8] - x[0];

  a8  = a0  + a2;
  a9  = a0  - a2;
  a10 = a0  - a6;
  a11 = a2  - a6;
  a12 = a8  + a6;
  a13 = a1  - a3;
  a14 = a13 + a7;
  a15 = a3  + a7;
  a16 = a1  - a7;
  a17 = a1  + a3;

  m0 = mad_f_mul(a17, -c3);
  m1 = mad_f_mul(a16, -c0);
  m2 = mad_f_mul(a15, -c4);
  m3 = mad_f_mul(a14, -c1);
  m4 = mad_f_mul(a5,  -c1);
  m5 = mad_f_mul(a11, -c6);
  m6 = mad_f_mul(a10, -c5);
  m7 = mad_f_mul(a9,  -c2);

  a18 =     x[4] + a4;
  a19 = 2 * x[4] - a4;
  a20 = a19 + m5;
  a21 = a19 - m5;
  a22 = a19 + m6;
  a23 = m4  + m2;
  a24 = m4  - m2;
  a25 = m4  + m1;

  /* output to every other slot for convenience */

  y[ 0] = a18 + a12;
  y[ 2] = m0  - a25;
  y[ 4] = m7  - a20;
  y[ 6] = m3;
  y[ 8] = a21 - m6;
  y[10] = a24 - m1;
  y[12] = a12 - 2 * a18;
  y[14] = a23 + m0;
  y[16] = a22 + m7;
}

static inline
void sdctII(mad_fixed_t const x[18], mad_fixed_t X[18])
{
  mad_fixed_t tmp[9];
  int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  /* scale[i] = 2 * cos(PI * (2 * i + 1) / (2 * 18)) */
  static mad_fixed_t const scale[9] PROGMEM = {
    MAD_F(0x1fe0d3b4), MAD_F(0x1ee8dd47), MAD_F(0x1d007930),
    MAD_F(0x1a367e59), MAD_F(0x16a09e66), MAD_F(0x125abcf8),
    MAD_F(0x0d8616bc), MAD_F(0x08483ee1), MAD_F(0x02c9fad7)
  };

  /* divide the 18-point SDCT-II into two 9-point SDCT-IIs */

  /* even input butterfly */

  for (i = 0; i < 9; i += 3) {
    tmp[i + 0] = x[i + 0] + x[18 - (i + 0) - 1];
    tmp[i + 1] = x[i + 1] + x[18 - (i + 1) - 1];
    tmp[i + 2] = x[i + 2] + x[18 - (i + 2) - 1];
  }

  fastsdct(tmp, &X[0]);

  /* odd input butterfly and scaling */

  for (i = 0; i < 9; i += 3) {
    mad_fixed_t s;
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 0]; tmp[i + 0] = mad_f_mul(x[i + 0] - x[18 - (i + 0) - 1], s); //scale[i + 0]);
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 1]; tmp[i + 1] = mad_f_mul(x[i + 1] - x[18 - (i + 1) - 1], s); //scale[i + 1]);
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 2]; tmp[i + 2] = mad_f_mul(x[i + 2] - x[18 - (i + 2) - 1], s); //scale[i + 2]);
  }

#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wstringop-overflow"
  fastsdct(tmp, &X[1]);
#pragma GCC diagnostic pop

  /* output accumulation */

  for (i = 3; i < 18; i += 8) {
    X[i + 0] -= X[(i + 0) - 2];
    X[i + 2] -= X[(i + 2) - 2];
    X[i + 4] -= X[(i + 4) - 2];
    X[i + 6] -= X[(i + 6) - 2];
  }
}

static inline
void dctIV(mad_fixed_t const y[18], mad_fixed_t X[18])
{
  mad_fixed_t tmp[18];
  int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  /* scale[i] = 2 * cos(PI * (2 * i + 1) / (4 * 18)) */
  static mad_fixed_t const scale[18] PROGMEM = {
    MAD_F(0x1ff833fa), MAD_F(0x1fb9ea93), MAD_F(0x1f3dd120),
    MAD_F(0x1e84d969), MAD_F(0x1d906bcf), MAD_F(0x1c62648b),
    MAD_F(0x1afd100f), MAD_F(0x1963268b), MAD_F(0x1797c6a4),
    MAD_F(0x159e6f5b), MAD_F(0x137af940), MAD_F(0x11318ef3),
    MAD_F(0x0ec6a507), MAD_F(0x0c3ef153), MAD_F(0x099f61c5),
    MAD_F(0x06ed12c5), MAD_F(0x042d4544), MAD_F(0x0165547c)
  };

  /* scaling */

  for (i = 0; i < 18; i += 3) {
    mad_fixed_t s;
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 0]; tmp[i + 0] = mad_f_mul(y[i + 0], s); //scale[i + 0]);
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 1]; tmp[i + 1] = mad_f_mul(y[i + 1], s); //scale[i + 1]);
    s = *(volatile mad_fixed_t*)(volatile uint32_t*)&scale[i + 2]; tmp[i + 2] = mad_f_mul(y[i + 2], s); //scale[i + 2]);
  }

  /* SDCT-II */

  sdctII(tmp, X);

  /* scale reduction and output accumulation */

  X[0] /= 2;
  for (i = 1; i < 17; i += 4) {
    X[i + 0] = X[i + 0] / 2 - X[(i + 0) - 1];
    X[i + 1] = X[i + 1] / 2 - X[(i + 1) - 1];
    X[i + 2] = X[i + 2] / 2 - X[(i + 2) - 1];
    X[i + 3] = X[i + 3] / 2 - X[(i + 3) - 1];
  }
  X[17] = X[17] / 2 - X[16];
}

/*
   NAME:	imdct36
   DESCRIPTION:	perform X[18]->x[36] IMDCT using Szu-Wei Lee's fast algorithm
*/
static inline
void imdct36(mad_fixed_t const x[18], mad_fixed_t y[36])
{
  mad_fixed_t tmp[18];
  int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  /* DCT-IV */

  dctIV(x, tmp);

  /* convert 18-point DCT-IV to 36-point IMDCT */

  for (i =  0; i <  9; i += 3) {
    y[i + 0] =  tmp[9 + (i + 0)];
    y[i + 1] =  tmp[9 + (i + 1)];
    y[i + 2] =  tmp[9 + (i + 2)];
  }
  for (i =  9; i < 27; i += 3) {
    y[i + 0] = -tmp[36 - (9 + (i + 0)) - 1];
    y[i + 1] = -tmp[36 - (9 + (i + 1)) - 1];
    y[i + 2] = -tmp[36 - (9 + (i + 2)) - 1];
  }
  for (i = 27; i < 36; i += 3) {
    y[i + 0] = -tmp[(i + 0) - 27];
    y[i + 1] = -tmp[(i + 1) - 27];
    y[i + 2] = -tmp[(i + 2) - 27];
  }
}
#  else
/*
   NAME:	imdct36
   DESCRIPTION:	perform X[18]->x[36] IMDCT
*/
static inline
void imdct36(mad_fixed_t const X[18], mad_fixed_t x[36])
{
  mad_fixed_t t0, t1, t2,  t3,  t4,  t5,  t6,  t7;
  mad_fixed_t t8, t9, t10, t11, t12, t13, t14, t15;
  register mad_fixed64hi_t hi;
  register mad_fixed64lo_t lo;

  MAD_F_ML0(hi, lo, X[4],  MAD_F(0x0ec835e8));
  MAD_F_MLA(hi, lo, X[13], MAD_F(0x061f78aa));

  t6 = MAD_F_MLZ(hi, lo);

  MAD_F_MLA(hi, lo, (t14 = X[1] - X[10]), -MAD_F(0x061f78aa));
  MAD_F_MLA(hi, lo, (t15 = X[7] + X[16]), -MAD_F(0x0ec835e8));

  t0 = MAD_F_MLZ(hi, lo);

  MAD_F_MLA(hi, lo, (t8  = X[0] - X[11] - X[12]),  MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, (t9  = X[2] - X[9]  - X[14]),  MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, (t10 = X[3] - X[8]  - X[15]), -MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, (t11 = X[5] - X[6]  - X[17]), -MAD_F(0x0fdcf549));

  x[7]  = MAD_F_MLZ(hi, lo);
  x[10] = -x[7];

  MAD_F_ML0(hi, lo, t8,  -MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, t9,   MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, t10,  MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, t11, -MAD_F(0x09bd7ca0));

  x[19] = x[34] = MAD_F_MLZ(hi, lo) - t0;

  t12 = X[0] - X[3] + X[8] - X[11] - X[12] + X[15];
  t13 = X[2] + X[5] - X[6] - X[9]  - X[14] - X[17];

  MAD_F_ML0(hi, lo, t12, -MAD_F(0x0ec835e8));
  MAD_F_MLA(hi, lo, t13,  MAD_F(0x061f78aa));

  x[22] = x[31] = MAD_F_MLZ(hi, lo) + t0;

  MAD_F_ML0(hi, lo, X[1],  -MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, X[7],   MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, X[10], -MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, X[16],  MAD_F(0x0cb19346));

  t1 = MAD_F_MLZ(hi, lo) + t6;

  MAD_F_ML0(hi, lo, X[0],   MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[11],  MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0f9ee890));

  x[6]  = MAD_F_MLZ(hi, lo) + t1;
  x[11] = -x[6];

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[2],  -MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[17],  MAD_F(0x04cfb0e2));

  x[23] = x[30] = MAD_F_MLZ(hi, lo) + t1;

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[11],  MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0acf37ad));

  x[18] = x[35] = MAD_F_MLZ(hi, lo) - t1;

  MAD_F_ML0(hi, lo, X[4],   MAD_F(0x061f78aa));
  MAD_F_MLA(hi, lo, X[13], -MAD_F(0x0ec835e8));

  t7 = MAD_F_MLZ(hi, lo);

  MAD_F_MLA(hi, lo, X[1],  -MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, X[7],   MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, X[10],  MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, X[16], -MAD_F(0x09bd7ca0));

  t2 = MAD_F_MLZ(hi, lo);

  MAD_F_MLA(hi, lo, X[0],   MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[12],  MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[17],  MAD_F(0x0f426cb5));

  x[5]  = MAD_F_MLZ(hi, lo);
  x[12] = -x[5];

  MAD_F_ML0(hi, lo, X[0],   MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[2],  -MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[11],  MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0bcbe352));

  x[0]  = MAD_F_MLZ(hi, lo) + t2;
  x[17] = -x[0];

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[2],  -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[14], -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x03768962));

  x[24] = x[29] = MAD_F_MLZ(hi, lo) + t2;

  MAD_F_ML0(hi, lo, X[1],  -MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, X[7],  -MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, X[10],  MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, X[16],  MAD_F(0x0fdcf549));

  t3 = MAD_F_MLZ(hi, lo) + t7;

  MAD_F_ML0(hi, lo, X[0],   MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[12],  MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0ffc19fd));

  x[8] = MAD_F_MLZ(hi, lo) + t3;
  x[9] = -x[8];

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[14], -MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[17],  MAD_F(0x07635284));

  x[21] = x[32] = MAD_F_MLZ(hi, lo) + t3;

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[12],  MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0898c779));

  x[20] = x[33] = MAD_F_MLZ(hi, lo) - t3;

  MAD_F_ML0(hi, lo, t14, -MAD_F(0x0ec835e8));
  MAD_F_MLA(hi, lo, t15,  MAD_F(0x061f78aa));

  t4 = MAD_F_MLZ(hi, lo) - t7;

  MAD_F_ML0(hi, lo, t12, MAD_F(0x061f78aa));
  MAD_F_MLA(hi, lo, t13, MAD_F(0x0ec835e8));

  x[4]  = MAD_F_MLZ(hi, lo) + t4;
  x[13] = -x[4];

  MAD_F_ML0(hi, lo, t8,   MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, t9,  -MAD_F(0x0216a2a2));
  MAD_F_MLA(hi, lo, t10,  MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, t11, -MAD_F(0x0cb19346));

  x[1]  = MAD_F_MLZ(hi, lo) + t4;
  x[16] = -x[1];

  MAD_F_ML0(hi, lo, t8,  -MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, t9,  -MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, t10, -MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, t11, -MAD_F(0x0216a2a2));

  x[25] = x[28] = MAD_F_MLZ(hi, lo) + t4;

  MAD_F_ML0(hi, lo, X[1],  -MAD_F(0x0fdcf549));
  MAD_F_MLA(hi, lo, X[7],  -MAD_F(0x0cb19346));
  MAD_F_MLA(hi, lo, X[10], -MAD_F(0x09bd7ca0));
  MAD_F_MLA(hi, lo, X[16], -MAD_F(0x0216a2a2));

  t5 = MAD_F_MLZ(hi, lo) - t6;

  MAD_F_ML0(hi, lo, X[0],   MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[6],   MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[9],   MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[12],  MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[14], -MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[15],  MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x0d7e8807));

  x[2]  = MAD_F_MLZ(hi, lo) + t5;
  x[15] = -x[2];

  MAD_F_ML0(hi, lo, X[0],   MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[2],   MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[3],   MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[5],   MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x00b2aa3e));
  MAD_F_MLA(hi, lo, X[8],   MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[11],  MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[14],  MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[17],  MAD_F(0x0e313245));

  x[3]  = MAD_F_MLZ(hi, lo) + t5;
  x[14] = -x[3];

  MAD_F_ML0(hi, lo, X[0],  -MAD_F(0x0ffc19fd));
  MAD_F_MLA(hi, lo, X[2],  -MAD_F(0x0f9ee890));
  MAD_F_MLA(hi, lo, X[3],  -MAD_F(0x0f426cb5));
  MAD_F_MLA(hi, lo, X[5],  -MAD_F(0x0e313245));
  MAD_F_MLA(hi, lo, X[6],  -MAD_F(0x0d7e8807));
  MAD_F_MLA(hi, lo, X[8],  -MAD_F(0x0bcbe352));
  MAD_F_MLA(hi, lo, X[9],  -MAD_F(0x0acf37ad));
  MAD_F_MLA(hi, lo, X[11], -MAD_F(0x0898c779));
  MAD_F_MLA(hi, lo, X[12], -MAD_F(0x07635284));
  MAD_F_MLA(hi, lo, X[14], -MAD_F(0x04cfb0e2));
  MAD_F_MLA(hi, lo, X[15], -MAD_F(0x03768962));
  MAD_F_MLA(hi, lo, X[17], -MAD_F(0x00b2aa3e));

  x[26] = x[27] = MAD_F_MLZ(hi, lo) + t5;
}
#  endif

/*
   NAME:	III_imdct_l()
   DESCRIPTION:	perform IMDCT and windowing for long blocks
*/
static
void III_imdct_l(mad_fixed_t const X[18], mad_fixed_t z[36],
                 unsigned int block_type)
{
  unsigned int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

  /* IMDCT */

  imdct36(X, z);

  /* windowing */

  switch (block_type) {
    case 0:  /* normal window */
# if defined(ASO_INTERLEAVE1)
      {
        register mad_fixed_t tmp1, tmp2;

        tmp1 = window_l[0];
        tmp2 = window_l[1];

        for (i = 0; i < 34; i += 2) {
          z[i + 0] = mad_f_mul(z[i + 0], tmp1);
          tmp1 = window_l[i + 2];
          z[i + 1] = mad_f_mul(z[i + 1], tmp2);
          tmp2 = window_l[i + 3];
        }

        z[34] = mad_f_mul(z[34], tmp1);
        z[35] = mad_f_mul(z[35], tmp2);
      }
# elif defined(ASO_INTERLEAVE2)
      {
        register mad_fixed_t tmp1, tmp2;

        tmp1 = z[0];
        tmp2 = window_l[0];

        for (i = 0; i < 35; ++i) {
          z[i] = mad_f_mul(tmp1, tmp2);
          tmp1 = z[i + 1];
          tmp2 = window_l[i + 1];
        }

        z[35] = mad_f_mul(tmp1, tmp2);
      }
# elif 1
      for (i = 0; i < 36; i += 4) {
        z[i + 0] = mad_f_mul(z[i + 0], window_l(i + 0));
        z[i + 1] = mad_f_mul(z[i + 1], window_l(i + 1));
        z[i + 2] = mad_f_mul(z[i + 2], window_l(i + 2));
        z[i + 3] = mad_f_mul(z[i + 3], window_l(i + 3));
      }
# else
      for (i =  0; i < 36; ++i) z[i] = mad_f_mul(z[i], window_l[i]);
# endif
      break;

    case 1:  /* start block */
      for (i =  0; i < 18; i += 3) {
        z[i + 0] = mad_f_mul(z[i + 0], window_l(i + 0));
        z[i + 1] = mad_f_mul(z[i + 1], window_l(i + 1));
        z[i + 2] = mad_f_mul(z[i + 2], window_l(i + 2));
      }
      /*  (i = 18; i < 24; ++i) z[i] unchanged */
      for (i = 24; i < 30; ++i) z[i] = mad_f_mul(z[i], window_s(i - 18));
      for (i = 30; i < 36; ++i) z[i] = 0;
      break;

    case 3:  /* stop block */
      for (i =  0; i <  6; ++i) z[i] = 0;
      for (i =  6; i < 12; ++i) z[i] = mad_f_mul(z[i], window_s(i - 6));
      /*  (i = 12; i < 18; ++i) z[i] unchanged */
      for (i = 18; i < 36; i += 3) {
        z[i + 0] = mad_f_mul(z[i + 0], window_l(i + 0));
        z[i + 1] = mad_f_mul(z[i + 1], window_l(i + 1));
        z[i + 2] = mad_f_mul(z[i + 2], window_l(i + 2));
      }
      break;
  }
}
# endif  /* ASO_IMDCT */

/*
   NAME:	III_imdct_s()
   DESCRIPTION:	perform IMDCT and windowing for short blocks
*/
static
void III_imdct_s(mad_fixed_t const X[18], mad_fixed_t z[36])
{
  mad_fixed_t y[36], *yptr;
  int wptr; //mad_fixed_t const *wptr;
  int w, i;
  register mad_fixed64hi_t hi;
  register mad_fixed64lo_t lo;
  // MAD_F_MLA may produce non-32b aligned reads, so copy from progmem to stack and work from there...
  mad_fixed_t imdct_s_lcl[6][6];
  memcpy_P(imdct_s_lcl, imdct_s, sizeof(imdct_s));
  stack(__FUNCTION__, __FILE__, __LINE__);

  /* IMDCT */

  yptr = &y[0];

  for (w = 0; w < 3; ++w) {
    register mad_fixed_t (*s)[6];

    s = imdct_s_lcl;

    for (i = 0; i < 3; ++i) {
      MAD_F_ML0(hi, lo, X[0], (*s)[0]);
      MAD_F_MLA(hi, lo, X[1], (*s)[1]);
      MAD_F_MLA(hi, lo, X[2], (*s)[2]);
      MAD_F_MLA(hi, lo, X[3], (*s)[3]);
      MAD_F_MLA(hi, lo, X[4], (*s)[4]);
      MAD_F_MLA(hi, lo, X[5], (*s)[5]);

      yptr[i + 0] = MAD_F_MLZ(hi, lo);
      yptr[5 - i] = -yptr[i + 0];

      ++s;

      MAD_F_ML0(hi, lo, X[0], (*s)[0]);
      MAD_F_MLA(hi, lo, X[1], (*s)[1]);
      MAD_F_MLA(hi, lo, X[2], (*s)[2]);
      MAD_F_MLA(hi, lo, X[3], (*s)[3]);
      MAD_F_MLA(hi, lo, X[4], (*s)[4]);
      MAD_F_MLA(hi, lo, X[5], (*s)[5]);

      yptr[ i + 6] = MAD_F_MLZ(hi, lo);
      yptr[11 - i] = yptr[i + 6];

      ++s;
    }

    yptr += 12;
    X    += 6;
  }

  /* windowing, overlapping and concatenation */

  yptr = &y[0];
  wptr = 0; //wptr = &window_s[0];

  for (i = 0; i < 6; ++i) {
    z[i +  0] = 0;
    z[i +  6] = mad_f_mul(yptr[ 0 + 0], window_s(wptr + 0));

    MAD_F_ML0(hi, lo, yptr[ 0 + 6], window_s(wptr + 6));
    MAD_F_MLA(hi, lo, yptr[12 + 0], window_s(wptr + 0));

    z[i + 12] = MAD_F_MLZ(hi, lo);

    MAD_F_ML0(hi, lo, yptr[12 + 6], window_s(wptr + 6));
    MAD_F_MLA(hi, lo, yptr[24 + 0], window_s(wptr + 0));

    z[i + 18] = MAD_F_MLZ(hi, lo);

    z[i + 24] = mad_f_mul(yptr[24 + 6], window_s(wptr + 6));
    z[i + 30] = 0;

    ++yptr;
    ++wptr;
  }
}

/*
   NAME:	III_overlap()
   DESCRIPTION:	perform overlap-add of windowed IMDCT outputs
*/
static
void III_overlap(mad_fixed_t const output[36], mad_fixed_t overlap[18],
                 mad_fixed_t sample[18][32], unsigned int sb)
{
  unsigned int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

# if defined(ASO_INTERLEAVE2)
  {
    register mad_fixed_t tmp1, tmp2;

    tmp1 = overlap[0];
    tmp2 = overlap[1];

    for (i = 0; i < 16; i += 2) {
      sample[i + 0][sb] = output[i + 0 +  0] + tmp1;
      overlap[i + 0]    = output[i + 0 + 18];
      tmp1 = overlap[i + 2];

      sample[i + 1][sb] = output[i + 1 +  0] + tmp2;
      overlap[i + 1]    = output[i + 1 + 18];
      tmp2 = overlap[i + 3];
    }

    sample[16][sb] = output[16 +  0] + tmp1;
    overlap[16]    = output[16 + 18];
    sample[17][sb] = output[17 +  0] + tmp2;
    overlap[17]    = output[17 + 18];
  }
# elif 0
  for (i = 0; i < 18; i += 2) {
    sample[i + 0][sb] = output[i + 0 +  0] + overlap[i + 0];
    overlap[i + 0]    = output[i + 0 + 18];

    sample[i + 1][sb] = output[i + 1 +  0] + overlap[i + 1];
    overlap[i + 1]    = output[i + 1 + 18];
  }
# else
  for (i = 0; i < 18; ++i) {
    sample[i][sb] = output[i +  0] + overlap[i];
    overlap[i]    = output[i + 18];
  }
# endif
}

/*
   NAME:	III_overlap_z()
   DESCRIPTION:	perform "overlap-add" of zero IMDCT outputs
*/
static inline
void III_overlap_z(mad_fixed_t overlap[18],
                   mad_fixed_t sample[18][32], unsigned int sb)
{
  unsigned int i;

# if defined(ASO_INTERLEAVE2)
  {
    register mad_fixed_t tmp1, tmp2;

    tmp1 = overlap[0];
    tmp2 = overlap[1];

    for (i = 0; i < 16; i += 2) {
      sample[i + 0][sb] = tmp1;
      overlap[i + 0]    = 0;
      tmp1 = overlap[i + 2];

      sample[i + 1][sb] = tmp2;
      overlap[i + 1]    = 0;
      tmp2 = overlap[i + 3];
    }

    sample[16][sb] = tmp1;
    overlap[16]    = 0;
    sample[17][sb] = tmp2;
    overlap[17]    = 0;
  }
# else
  for (i = 0; i < 18; ++i) {
    sample[i][sb] = overlap[i];
    overlap[i]    = 0;
  }
# endif
}

/*
   NAME:	III_freqinver()
   DESCRIPTION:	perform subband frequency inversion for odd sample lines
*/
static
void III_freqinver(mad_fixed_t sample[18][32], unsigned int sb)
{
  unsigned int i;
  stack(__FUNCTION__, __FILE__, __LINE__);

# if 1 || defined(ASO_INTERLEAVE1) || defined(ASO_INTERLEAVE2)
  {
    register mad_fixed_t tmp1, tmp2;

    tmp1 = sample[1][sb];
    tmp2 = sample[3][sb];

    for (i = 1; i < 13; i += 4) {
      sample[i + 0][sb] = -tmp1;
      tmp1 = sample[i + 4][sb];
      sample[i + 2][sb] = -tmp2;
      tmp2 = sample[i + 6][sb];
    }

    sample[13][sb] = -tmp1;
    tmp1 = sample[17][sb];
    sample[15][sb] = -tmp2;
    sample[17][sb] = -tmp1;
  }
# else
  for (i = 1; i < 18; i += 2)
    sample[i][sb] = -sample[i][sb];
# endif
}

/*
   NAME:	III_decode()
   DESCRIPTION:	decode frame main_data
*/
static
enum mad_error III_decode(struct mad_bitptr *ptr, struct mad_frame *frame,
                          struct sideinfo *si, unsigned int nch)
{
  struct mad_header *header = &frame->header;
  mad_fixed_t *xr[2]; // Moved from stack to dynheap
//  mad_fixed_t *xr_raw; // [2][576]
  unsigned int sfreqi, ngr, gr;
//  xr_raw = (mad_fixed_t*)malloc(sizeof(mad_fixed_t) * 2 * 576);
//  if (!xr_raw)
//    return MAD_ERROR_NOMEM;
  xr[0] = frame->xr_raw; //xr_raw;
  xr[1] = frame->xr_raw + 576; //xr_raw + 576;

  stack(__FUNCTION__, __FILE__, __LINE__);
  {
    unsigned int sfreq;

    sfreq = header->samplerate;
    if (header->flags & MAD_FLAG_MPEG_2_5_EXT)
      sfreq *= 2;

    /* 48000 => 0, 44100 => 1, 32000 => 2,
       24000 => 3, 22050 => 4, 16000 => 5 */
    sfreqi = ((sfreq >>  7) & 0x000f) +
             ((sfreq >> 15) & 0x0001) - 8;

    if (header->flags & MAD_FLAG_MPEG_2_5_EXT)
      sfreqi += 3;
  }

  /* scalefactors, Huffman decoding, requantization */

  ngr = (header->flags & MAD_FLAG_LSF_EXT) ? 1 : 2;

  for (gr = 0; gr < ngr; ++gr) {
    struct granule *granule = &si->gr[gr];
    unsigned int const *sfbwidth[2];
    unsigned int ch;
    enum mad_error error;

    for (ch = 0; ch < nch; ++ch) {
      struct channel *channel = &granule->ch[ch];
      unsigned int part2_length;

      sfbwidth[ch] = sfbwidth_table[sfreqi].l;
      if (channel->block_type == 2) {
        sfbwidth[ch] = (channel->flags & mixed_block_flag) ?
                       sfbwidth_table[sfreqi].m : sfbwidth_table[sfreqi].s;
      }

      if (header->flags & MAD_FLAG_LSF_EXT) {
        part2_length = III_scalefactors_lsf(ptr, channel,
                                            ch == 0 ? 0 : &si->gr[1].ch[1],
                                            header->mode_extension);
      }
      else {
        part2_length = III_scalefactors(ptr, channel, &si->gr[0].ch[ch],
                                        gr == 0 ? 0 : si->scfsi[ch]);
      }

      error = III_huffdecode(ptr, xr[ch], channel, sfbwidth[ch], part2_length);
      if (error) {
//        free(xr_raw);
        return error;
      }
    }

    /* joint stereo processing */

    if (header->mode == MAD_MODE_JOINT_STEREO && header->mode_extension) {
      // (void*) below just to get rid of warning about passing in a * and not a [2][576]
      error = III_stereo((void*)frame->xr_raw, granule, header, sfbwidth[0]);
      if (error) {
//        free(xr_raw);
        return error;
      }
    }

    /* reordering, alias reduction, IMDCT, overlap-add, frequency inversion */

    for (ch = 0; ch < nch; ++ch) {
      struct channel const *channel = &granule->ch[ch];
      mad_fixed_t (*sample)[32] = &frame->sbsample[ch][18 * gr];
      unsigned int sb, l, i, sblimit;
      mad_fixed_t output[36];

      if (channel->block_type == 2) {
        error = III_reorder(xr[ch], channel, sfbwidth[ch], frame->tmp);
        if (error) {
//          free(xr_raw);
          return error;
        }

# if !defined(OPT_STRICT)
        /*
           According to ISO/IEC 11172-3, "Alias reduction is not applied for
           granules with block_type == 2 (short block)." However, other
           sources suggest alias reduction should indeed be performed on the
           lower two subbands of mixed blocks. Most other implementations do
           this, so by default we will too.
        */
        if (channel->flags & mixed_block_flag)
          III_aliasreduce(xr[ch], 36);
# endif
      }
      else
        III_aliasreduce(xr[ch], 576);

      l = 0;

      /* subbands 0-1 */

      if (channel->block_type != 2 || (channel->flags & mixed_block_flag)) {
        unsigned int block_type;

        block_type = channel->block_type;
        if (channel->flags & mixed_block_flag)
          block_type = 0;

        /* long blocks */
        for (sb = 0; sb < 2; ++sb, l += 18) {
          III_imdct_l(&xr[ch][l], output, block_type);
          III_overlap(output, frame->overlap[ch][sb], sample, sb);
        }
      }
      else {
        /* short blocks */
        for (sb = 0; sb < 2; ++sb, l += 18) {
          III_imdct_s(&xr[ch][l], output);
          III_overlap(output, frame->overlap[ch][sb], sample, sb);
        }
      }

      III_freqinver(sample, 1);

      /* (nonzero) subbands 2-31 */

      i = 576;
      while (i > 36 && xr[ch][i - 1] == 0)
        --i;

      sblimit = 32 - (576 - i) / 18;

      if (channel->block_type != 2) {
        /* long blocks */
        for (sb = 2; sb < sblimit; ++sb, l += 18) {
          III_imdct_l(&xr[ch][l], output, channel->block_type);
          III_overlap(output, frame->overlap[ch][sb], sample, sb);

          if (sb & 1)
            III_freqinver(sample, sb);
        }
      }
      else {
        /* short blocks */
        for (sb = 2; sb < sblimit; ++sb, l += 18) {
          III_imdct_s(&xr[ch][l], output);
          III_overlap(output, frame->overlap[ch][sb], sample, sb);

          if (sb & 1)
            III_freqinver(sample, sb);
        }
      }

      /* remaining (zero) subbands */

      for (sb = sblimit; sb < 32; ++sb) {
        III_overlap_z(frame->overlap[ch][sb], sample, sb);

        if (sb & 1)
          III_freqinver(sample, sb);
      }
    }
  }

//  free(xr_raw);
  return MAD_ERROR_NONE;
}

/*
   NAME:	layer->III()
   DESCRIPTION:	decode a single Layer III frame
*/
int mad_layer_III(struct mad_stream *stream, struct mad_frame *frame)
{
  struct mad_header *header = &frame->header;
  unsigned int nch, priv_bitlen, next_md_begin = 0;
  unsigned int si_len, data_bitlen, md_len;
  unsigned int frame_space, frame_used, frame_free;
  struct mad_bitptr ptr;
  struct sideinfo si;
  enum mad_error error;
  int result = 0;
  stack(__FUNCTION__, __FILE__, __LINE__);

  nch = MAD_NCHANNELS(header);
  si_len = (header->flags & MAD_FLAG_LSF_EXT) ?
           (nch == 1 ? 9 : 17) : (nch == 1 ? 17 : 32);

  /* check frame sanity */

  if (stream->next_frame - mad_bit_nextbyte(&stream->ptr) <
      (signed int) si_len) {
    stream->error = MAD_ERROR_BADFRAMELEN;
    stream->md_len = 0;
    return -1;
  }

  /* check CRC word */

  if (header->flags & MAD_FLAG_PROTECTION) {
    header->crc_check =
      mad_bit_crc(stream->ptr, si_len * CHAR_BIT, header->crc_check);

    if (header->crc_check != header->crc_target &&
        !(frame->options & MAD_OPTION_IGNORECRC)) {
      stream->error = MAD_ERROR_BADCRC;
      result = -1;
    }
  }

  /* decode frame side information */

  error = III_sideinfo(&stream->ptr, nch, header->flags & MAD_FLAG_LSF_EXT,
                       &si, &data_bitlen, &priv_bitlen);
  if (error && result == 0) {
    stream->error = error;
    result = -1;
  }

  header->flags        |= priv_bitlen;
  header->private_bits |= si.private_bits;

  /* find main_data of next frame */

  {
    struct mad_bitptr peek;
    unsigned long header;

    mad_bit_init(&peek, stream->next_frame);

    header = mad_bit_read(&peek, 32);
    if ((header & 0xffe60000L) /* syncword | layer */ == 0xffe20000L) {
      if (!(header & 0x00010000L))  /* protection_bit */
        mad_bit_skip(&peek, 16);  /* crc_check */

      next_md_begin =
        mad_bit_read(&peek, (header & 0x00080000L) /* ID */ ? 9 : 8);
    }

    mad_bit_finish(&peek);
  }

  /* find main_data of this frame */

  frame_space = stream->next_frame - mad_bit_nextbyte(&stream->ptr);

  if (next_md_begin > si.main_data_begin + frame_space)
    next_md_begin = 0;

  md_len = si.main_data_begin + frame_space - next_md_begin;

  frame_used = 0;

  if (si.main_data_begin == 0) {
    ptr = stream->ptr;
    stream->md_len = 0;

    frame_used = md_len;
  }
  else {
    if (si.main_data_begin > stream->md_len) {
      if (result == 0) {
        stream->error = MAD_ERROR_BADDATAPTR;
        result = -1;
      }
    }
    else {
      mad_bit_init(&ptr,
                   stream->main_data + stream->md_len - si.main_data_begin);

      if (md_len > si.main_data_begin) {
        assert(stream->md_len + md_len -
               si.main_data_begin <= MAD_BUFFER_MDLEN);

        memcpy(stream->main_data + stream->md_len,
               mad_bit_nextbyte(&stream->ptr),
               frame_used = md_len - si.main_data_begin);
        stream->md_len += frame_used;
      }
    }
  }

  frame_free = frame_space - frame_used;

  /* decode main_data */

  if (result == 0) {
    error = III_decode(&ptr, frame, &si, nch);
    if (error) {
      stream->error = error;
      result = -1;
    }

    /* designate ancillary bits */

    stream->anc_ptr    = ptr;
    stream->anc_bitlen = md_len * CHAR_BIT - data_bitlen;
  }

# if 0 && defined(DEBUG)
  fprintf(stderr,
          "main_data_begin:%u, md_len:%u, frame_free:%u, "
          "data_bitlen:%u, anc_bitlen: %u\n",
          si.main_data_begin, md_len, frame_free,
          data_bitlen, stream->anc_bitlen);
# endif

  /* preload main_data buffer with up to 511 bytes for next frame(s) */

  if (frame_free >= next_md_begin) {
    memcpy(stream->main_data,
           stream->next_frame - next_md_begin, next_md_begin);
    stream->md_len = next_md_begin;
  }
  else {
    if (md_len < si.main_data_begin) {
      unsigned int extra;

      extra = si.main_data_begin - md_len;
      if (extra + frame_free > next_md_begin)
        extra = next_md_begin - frame_free;

      if (extra < stream->md_len) {
        memmove(stream->main_data,
                stream->main_data + stream->md_len - extra, extra);
        stream->md_len = extra;
      }
    }
    else
      stream->md_len = 0;

    memcpy(stream->main_data + stream->md_len,
           stream->next_frame - frame_free, frame_free);
    stream->md_len += frame_free;
  }

  return result;
}