modules/third_party/g722/g722_decode.c - src/ - Git at Google

 /*
  * SpanDSP - a series of DSP components for telephony
  *
  * g722_decode.c - The ITU G.722 codec, decode part.
  *
  * Written by Steve Underwood <steveu@coppice.org>
  *
  * Copyright (C) 2005 Steve Underwood
  *
  *  Despite my general liking of the GPL, I place my own contributions
  *  to this code in the public domain for the benefit of all mankind -
  *  even the slimy ones who might try to proprietize my work and use it
  *  to my detriment.
  *
  * Based in part on a single channel G.722 codec which is:
  *
  * Copyright (c) CMU 1993
  * Computer Science, Speech Group
  * Chengxiang Lu and Alex Hauptmann
  *
  * $Id: g722_decode.c,v 1.15 2006/07/07 16:37:49 steveu Exp $
  *
  * Modifications for WebRtc, 2011/04/28, by tlegrand:
  * -Removed usage of inttypes.h and tgmath.h
  * -Changed to use WebRtc types
  * -Changed __inline__ to __inline
  * -Added saturation check on output
  */

 /*! \file */


 #include <memory.h>
 #include <stdio.h>
 #include <stdlib.h>

 #include "modules/third_party/g722/g722_enc_dec.h"

 #if !defined(FALSE)
 #define FALSE 0
 #endif
 #if !defined(TRUE)
 #define TRUE (!FALSE)
 #endif

 static __inline int16_t saturate(int32_t amp)
 {
     int16_t amp16;

     /* Hopefully this is optimised for the common case - not clipping */
     amp16 = (int16_t) amp;
     if (amp == amp16)
         return amp16;
     if (amp > WEBRTC_INT16_MAX)
         return  WEBRTC_INT16_MAX;
     return  WEBRTC_INT16_MIN;
 }
 /*- End of function --------------------------------------------------------*/

 static void block4(G722DecoderState *s, int band, int d);

 static void block4(G722DecoderState *s, int band, int d)
 {
     int wd1;
     int wd2;
     int wd3;
     int i;

     /* Block 4, RECONS */
     s->band[band].d[0] = d;
     s->band[band].r[0] = saturate(s->band[band].s + d);

     /* Block 4, PARREC */
     s->band[band].p[0] = saturate(s->band[band].sz + d);

     /* Block 4, UPPOL2 */
     for (i = 0;  i < 3;  i++)
         s->band[band].sg[i] = s->band[band].p[i] >> 15;
     wd1 = saturate(s->band[band].a[1] * 4);

     wd2 = (s->band[band].sg[0] == s->band[band].sg[1])  ?  -wd1  :  wd1;
     if (wd2 > 32767)
         wd2 = 32767;
     wd3 = (s->band[band].sg[0] == s->band[band].sg[2])  ?  128  :  -128;
     wd3 += (wd2 >> 7);
     wd3 += (s->band[band].a[2]*32512) >> 15;
     if (wd3 > 12288)
         wd3 = 12288;
     else if (wd3 < -12288)
         wd3 = -12288;
     s->band[band].ap[2] = wd3;

     /* Block 4, UPPOL1 */
     s->band[band].sg[0] = s->band[band].p[0] >> 15;
     s->band[band].sg[1] = s->band[band].p[1] >> 15;
     wd1 = (s->band[band].sg[0] == s->band[band].sg[1])  ?  192  :  -192;
     wd2 = (s->band[band].a[1]*32640) >> 15;

     s->band[band].ap[1] = saturate(wd1 + wd2);
     wd3 = saturate(15360 - s->band[band].ap[2]);
     if (s->band[band].ap[1] > wd3)
         s->band[band].ap[1] = wd3;
     else if (s->band[band].ap[1] < -wd3)
         s->band[band].ap[1] = -wd3;

     /* Block 4, UPZERO */
     wd1 = (d == 0)  ?  0  :  128;
     s->band[band].sg[0] = d >> 15;
     for (i = 1;  i < 7;  i++)
     {
         s->band[band].sg[i] = s->band[band].d[i] >> 15;
         wd2 = (s->band[band].sg[i] == s->band[band].sg[0])  ?  wd1  :  -wd1;
         wd3 = (s->band[band].b[i]*32640) >> 15;
         s->band[band].bp[i] = saturate(wd2 + wd3);
     }

     /* Block 4, DELAYA */
     for (i = 6;  i > 0;  i--)
     {
         s->band[band].d[i] = s->band[band].d[i - 1];
         s->band[band].b[i] = s->band[band].bp[i];
     }

     for (i = 2;  i > 0;  i--)
     {
         s->band[band].r[i] = s->band[band].r[i - 1];
         s->band[band].p[i] = s->band[band].p[i - 1];
         s->band[band].a[i] = s->band[band].ap[i];
     }

     /* Block 4, FILTEP */
     wd1 = saturate(s->band[band].r[1] + s->band[band].r[1]);
     wd1 = (s->band[band].a[1]*wd1) >> 15;
     wd2 = saturate(s->band[band].r[2] + s->band[band].r[2]);
     wd2 = (s->band[band].a[2]*wd2) >> 15;
     s->band[band].sp = saturate(wd1 + wd2);

     /* Block 4, FILTEZ */
     s->band[band].sz = 0;
     for (i = 6;  i > 0;  i--)
     {
         wd1 = saturate(s->band[band].d[i] + s->band[band].d[i]);
         s->band[band].sz += (s->band[band].b[i]*wd1) >> 15;
     }
     s->band[band].sz = saturate(s->band[band].sz);

     /* Block 4, PREDIC */
     s->band[band].s = saturate(s->band[band].sp + s->band[band].sz);
 }
 /*- End of function --------------------------------------------------------*/

 G722DecoderState* WebRtc_g722_decode_init(G722DecoderState* s,
                                           int rate,
                                           int options) {
     s = s ? s : malloc(sizeof(*s));
     memset(s, 0, sizeof(*s));
     if (rate == 48000)
         s->bits_per_sample = 6;
     else if (rate == 56000)
         s->bits_per_sample = 7;
     else
         s->bits_per_sample = 8;
     if ((options & G722_SAMPLE_RATE_8000))
         s->eight_k = TRUE;
     if ((options & G722_PACKED)  &&  s->bits_per_sample != 8)
         s->packed = TRUE;
     else
         s->packed = FALSE;
     s->band[0].det = 32;
     s->band[1].det = 8;
     return s;
 }
 /*- End of function --------------------------------------------------------*/

 int WebRtc_g722_decode_release(G722DecoderState *s)
 {
     free(s);
     return 0;
 }
 /*- End of function --------------------------------------------------------*/

 size_t WebRtc_g722_decode(G722DecoderState *s, int16_t amp[],
                           const uint8_t g722_data[], size_t len)
 {
     static const int wl[8] = {-60, -30, 58, 172, 334, 538, 1198, 3042 };
     static const int rl42[16] = {0, 7, 6, 5, 4, 3, 2, 1,
                                  7, 6, 5, 4, 3,  2, 1, 0 };
     static const int ilb[32] =
     {
         2048, 2093, 2139, 2186, 2233, 2282, 2332,
         2383, 2435, 2489, 2543, 2599, 2656, 2714,
         2774, 2834, 2896, 2960, 3025, 3091, 3158,
         3228, 3298, 3371, 3444, 3520, 3597, 3676,
         3756, 3838, 3922, 4008
     };
     static const int wh[3] = {0, -214, 798};
     static const int rh2[4] = {2, 1, 2, 1};
     static const int qm2[4] = {-7408, -1616,  7408,   1616};
     static const int qm4[16] =
     {
               0, -20456, -12896,  -8968,
           -6288,  -4240,  -2584,  -1200,
           20456,  12896,   8968,   6288,
            4240,   2584,   1200,      0
     };
     static const int qm5[32] =
     {
            -280,   -280, -23352, -17560,
          -14120, -11664,  -9752,  -8184,
           -6864,  -5712,  -4696,  -3784,
           -2960,  -2208,  -1520,   -880,
           23352,  17560,  14120,  11664,
            9752,   8184,   6864,   5712,
            4696,   3784,   2960,   2208,
            1520,    880,    280,   -280
     };
     static const int qm6[64] =
     {
            -136,   -136,   -136,   -136,
          -24808, -21904, -19008, -16704,
          -14984, -13512, -12280, -11192,
          -10232,  -9360,  -8576,  -7856,
           -7192,  -6576,  -6000,  -5456,
           -4944,  -4464,  -4008,  -3576,
           -3168,  -2776,  -2400,  -2032,
           -1688,  -1360,  -1040,   -728,
           24808,  21904,  19008,  16704,
           14984,  13512,  12280,  11192,
           10232,   9360,   8576,   7856,
            7192,   6576,   6000,   5456,
            4944,   4464,   4008,   3576,
            3168,   2776,   2400,   2032,
            1688,   1360,   1040,    728,
             432,    136,   -432,   -136
     };
     static const int qmf_coeffs[12] =
     {
            3,  -11,   12,   32, -210,  951, 3876, -805,  362, -156,   53,  -11,
     };

     int dlowt;
     int rlow;
     int ihigh;
     int dhigh;
     int rhigh;
     int xout1;
     int xout2;
     int wd1;
     int wd2;
     int wd3;
     int code;
     size_t outlen;
     int i;
     size_t j;

     outlen = 0;
     rhigh = 0;
     for (j = 0;  j < len;  )
     {
         if (s->packed)
         {
             /* Unpack the code bits */
             if (s->in_bits < s->bits_per_sample)
             {
                 s->in_buffer |= (g722_data[j++] << s->in_bits);
                 s->in_bits += 8;
             }
             code = s->in_buffer & ((1 << s->bits_per_sample) - 1);
             s->in_buffer >>= s->bits_per_sample;
             s->in_bits -= s->bits_per_sample;
         }
         else
         {
             code = g722_data[j++];
         }

         switch (s->bits_per_sample)
         {
         default:
         case 8:
             wd1 = code & 0x3F;
             ihigh = (code >> 6) & 0x03;
             wd2 = qm6[wd1];
             wd1 >>= 2;
             break;
         case 7:
             wd1 = code & 0x1F;
             ihigh = (code >> 5) & 0x03;
             wd2 = qm5[wd1];
             wd1 >>= 1;
             break;
         case 6:
             wd1 = code & 0x0F;
             ihigh = (code >> 4) & 0x03;
             wd2 = qm4[wd1];
             break;
         }
         /* Block 5L, LOW BAND INVQBL */
         wd2 = (s->band[0].det*wd2) >> 15;
         /* Block 5L, RECONS */
         rlow = s->band[0].s + wd2;
         /* Block 6L, LIMIT */
         if (rlow > 16383)
             rlow = 16383;
         else if (rlow < -16384)
             rlow = -16384;

         /* Block 2L, INVQAL */
         wd2 = qm4[wd1];
         dlowt = (s->band[0].det*wd2) >> 15;

         /* Block 3L, LOGSCL */
         wd2 = rl42[wd1];
         wd1 = (s->band[0].nb*127) >> 7;
         wd1 += wl[wd2];
         if (wd1 < 0)
             wd1 = 0;
         else if (wd1 > 18432)
             wd1 = 18432;
         s->band[0].nb = wd1;

         /* Block 3L, SCALEL */
         wd1 = (s->band[0].nb >> 6) & 31;
         wd2 = 8 - (s->band[0].nb >> 11);
         wd3 = (wd2 < 0)  ?  (ilb[wd1] << -wd2)  :  (ilb[wd1] >> wd2);
         s->band[0].det = wd3 << 2;

         block4(s, 0, dlowt);

         if (!s->eight_k)
         {
             /* Block 2H, INVQAH */
             wd2 = qm2[ihigh];
             dhigh = (s->band[1].det*wd2) >> 15;
             /* Block 5H, RECONS */
             rhigh = dhigh + s->band[1].s;
             /* Block 6H, LIMIT */
             if (rhigh > 16383)
                 rhigh = 16383;
             else if (rhigh < -16384)
                 rhigh = -16384;

             /* Block 2H, INVQAH */
             wd2 = rh2[ihigh];
             wd1 = (s->band[1].nb*127) >> 7;
             wd1 += wh[wd2];
             if (wd1 < 0)
                 wd1 = 0;
             else if (wd1 > 22528)
                 wd1 = 22528;
             s->band[1].nb = wd1;

             /* Block 3H, SCALEH */
             wd1 = (s->band[1].nb >> 6) & 31;
             wd2 = 10 - (s->band[1].nb >> 11);
             wd3 = (wd2 < 0)  ?  (ilb[wd1] << -wd2)  :  (ilb[wd1] >> wd2);
             s->band[1].det = wd3 << 2;

             block4(s, 1, dhigh);
         }

         if (s->itu_test_mode)
         {
             amp[outlen++] = (int16_t) (rlow << 1);
             amp[outlen++] = (int16_t) (rhigh << 1);
         }
         else
         {
             if (s->eight_k)
             {
                 amp[outlen++] = (int16_t) (rlow << 1);
             }
             else
             {
                 /* Apply the receive QMF */
                 for (i = 0;  i < 22;  i++)
                     s->x[i] = s->x[i + 2];
                 s->x[22] = rlow + rhigh;
                 s->x[23] = rlow - rhigh;

                 xout1 = 0;
                 xout2 = 0;
                 for (i = 0;  i < 12;  i++)
                 {
                     xout2 += s->x[2*i]*qmf_coeffs[i];
                     xout1 += s->x[2*i + 1]*qmf_coeffs[11 - i];
                 }
                 /* We shift by 12 to allow for the QMF filters (DC gain = 4096), less 1
                    to allow for the 15 bit input to the G.722 algorithm. */
                 /* WebRtc, tlegrand: added saturation */
                 amp[outlen++] = saturate(xout1 >> 11);
                 amp[outlen++] = saturate(xout2 >> 11);
             }
         }
     }
     return outlen;
 }
 /*- End of function --------------------------------------------------------*/
 /*- End of file ------------------------------------------------------------*/
	/*
	* SpanDSP - a series of DSP components for telephony
	*
	* g722_decode.c - The ITU G.722 codec, decode part.
	*
	* Written by Steve Underwood <steveu@coppice.org>
	*
	* Copyright (C) 2005 Steve Underwood
	*
	* Despite my general liking of the GPL, I place my own contributions
	* to this code in the public domain for the benefit of all mankind -
	* even the slimy ones who might try to proprietize my work and use it
	* to my detriment.
	*
	* Based in part on a single channel G.722 codec which is:
	*
	* Copyright (c) CMU 1993
	* Computer Science, Speech Group
	* Chengxiang Lu and Alex Hauptmann
	*
	* $Id: g722_decode.c,v 1.15 2006/07/07 16:37:49 steveu Exp $
	*
	* Modifications for WebRtc, 2011/04/28, by tlegrand:
	* -Removed usage of inttypes.h and tgmath.h
	* -Changed to use WebRtc types
	* -Changed __inline__ to __inline
	* -Added saturation check on output
	*/

	/! \file /


	#include <memory.h>
	#include <stdio.h>
	#include <stdlib.h>

	#include "modules/third_party/g722/g722_enc_dec.h"

	#if !defined(FALSE)
	#define FALSE 0
	#endif
	#if !defined(TRUE)
	#define TRUE (!FALSE)
	#endif

	static __inline int16_t saturate(int32_t amp)
	{
	int16_t amp16;

	/* Hopefully this is optimised for the common case - not clipping */
	amp16 = (int16_t) amp;
	if (amp == amp16)
	return amp16;
	if (amp > WEBRTC_INT16_MAX)
	return WEBRTC_INT16_MAX;
	return WEBRTC_INT16_MIN;
	}
	/- End of function --------------------------------------------------------/

	static void block4(G722DecoderState *s, int band, int d);

	static void block4(G722DecoderState *s, int band, int d)
	{
	int wd1;
	int wd2;
	int wd3;
	int i;

	/* Block 4, RECONS */
	s->band[band].d[0] = d;
	s->band[band].r[0] = saturate(s->band[band].s + d);

	/* Block 4, PARREC */
	s->band[band].p[0] = saturate(s->band[band].sz + d);

	/* Block 4, UPPOL2 */
	for (i = 0; i < 3; i++)
	s->band[band].sg[i] = s->band[band].p[i] >> 15;
	wd1 = saturate(s->band[band].a[1] * 4);

	wd2 = (s->band[band].sg[0] == s->band[band].sg[1]) ? -wd1 : wd1;
	if (wd2 > 32767)
	wd2 = 32767;
	wd3 = (s->band[band].sg[0] == s->band[band].sg[2]) ? 128 : -128;
	wd3 += (wd2 >> 7);
	wd3 += (s->band[band].a[2]*32512) >> 15;
	if (wd3 > 12288)
	wd3 = 12288;
	else if (wd3 < -12288)
	wd3 = -12288;
	s->band[band].ap[2] = wd3;

	/* Block 4, UPPOL1 */
	s->band[band].sg[0] = s->band[band].p[0] >> 15;
	s->band[band].sg[1] = s->band[band].p[1] >> 15;
	wd1 = (s->band[band].sg[0] == s->band[band].sg[1]) ? 192 : -192;
	wd2 = (s->band[band].a[1]*32640) >> 15;

	s->band[band].ap[1] = saturate(wd1 + wd2);
	wd3 = saturate(15360 - s->band[band].ap[2]);
	if (s->band[band].ap[1] > wd3)
	s->band[band].ap[1] = wd3;
	else if (s->band[band].ap[1] < -wd3)
	s->band[band].ap[1] = -wd3;

	/* Block 4, UPZERO */
	wd1 = (d == 0) ? 0 : 128;
	s->band[band].sg[0] = d >> 15;
	for (i = 1; i < 7; i++)
	{
	s->band[band].sg[i] = s->band[band].d[i] >> 15;
	wd2 = (s->band[band].sg[i] == s->band[band].sg[0]) ? wd1 : -wd1;
	wd3 = (s->band[band].b[i]*32640) >> 15;
	s->band[band].bp[i] = saturate(wd2 + wd3);
	}

	/* Block 4, DELAYA */
	for (i = 6; i > 0; i--)
	{
	s->band[band].d[i] = s->band[band].d[i - 1];
	s->band[band].b[i] = s->band[band].bp[i];
	}

	for (i = 2; i > 0; i--)
	{
	s->band[band].r[i] = s->band[band].r[i - 1];
	s->band[band].p[i] = s->band[band].p[i - 1];
	s->band[band].a[i] = s->band[band].ap[i];
	}

	/* Block 4, FILTEP */
	wd1 = saturate(s->band[band].r[1] + s->band[band].r[1]);
	wd1 = (s->band[band].a[1]*wd1) >> 15;
	wd2 = saturate(s->band[band].r[2] + s->band[band].r[2]);
	wd2 = (s->band[band].a[2]*wd2) >> 15;
	s->band[band].sp = saturate(wd1 + wd2);

	/* Block 4, FILTEZ */
	s->band[band].sz = 0;
	for (i = 6; i > 0; i--)
	{
	wd1 = saturate(s->band[band].d[i] + s->band[band].d[i]);
	s->band[band].sz += (s->band[band].b[i]*wd1) >> 15;
	}
	s->band[band].sz = saturate(s->band[band].sz);

	/* Block 4, PREDIC */
	s->band[band].s = saturate(s->band[band].sp + s->band[band].sz);
	}
	/- End of function --------------------------------------------------------/

	G722DecoderState* WebRtc_g722_decode_init(G722DecoderState* s,
	int rate,
	int options) {
	s = s ? s : malloc(sizeof(*s));
	memset(s, 0, sizeof(*s));
	if (rate == 48000)
	s->bits_per_sample = 6;
	else if (rate == 56000)
	s->bits_per_sample = 7;
	else
	s->bits_per_sample = 8;
	if ((options & G722_SAMPLE_RATE_8000))
	s->eight_k = TRUE;
	if ((options & G722_PACKED) && s->bits_per_sample != 8)
	s->packed = TRUE;
	else
	s->packed = FALSE;
	s->band[0].det = 32;
	s->band[1].det = 8;
	return s;
	}
	/- End of function --------------------------------------------------------/

	int WebRtc_g722_decode_release(G722DecoderState *s)
	{
	free(s);
	return 0;
	}
	/- End of function --------------------------------------------------------/

	size_t WebRtc_g722_decode(G722DecoderState *s, int16_t amp[],
	const uint8_t g722_data[], size_t len)
	{
	static const int wl[8] = {-60, -30, 58, 172, 334, 538, 1198, 3042 };
	static const int rl42[16] = {0, 7, 6, 5, 4, 3, 2, 1,
	7, 6, 5, 4, 3, 2, 1, 0 };
	static const int ilb[32] =
	{
	2048, 2093, 2139, 2186, 2233, 2282, 2332,
	2383, 2435, 2489, 2543, 2599, 2656, 2714,
	2774, 2834, 2896, 2960, 3025, 3091, 3158,
	3228, 3298, 3371, 3444, 3520, 3597, 3676,
	3756, 3838, 3922, 4008
	};
	static const int wh[3] = {0, -214, 798};
	static const int rh2[4] = {2, 1, 2, 1};
	static const int qm2[4] = {-7408, -1616, 7408, 1616};
	static const int qm4[16] =
	{
	0, -20456, -12896, -8968,
	-6288, -4240, -2584, -1200,
	20456, 12896, 8968, 6288,
	4240, 2584, 1200, 0
	};
	static const int qm5[32] =
	{
	-280, -280, -23352, -17560,
	-14120, -11664, -9752, -8184,
	-6864, -5712, -4696, -3784,
	-2960, -2208, -1520, -880,
	23352, 17560, 14120, 11664,
	9752, 8184, 6864, 5712,
	4696, 3784, 2960, 2208,
	1520, 880, 280, -280
	};
	static const int qm6[64] =
	{
	-136, -136, -136, -136,
	-24808, -21904, -19008, -16704,
	-14984, -13512, -12280, -11192,
	-10232, -9360, -8576, -7856,
	-7192, -6576, -6000, -5456,
	-4944, -4464, -4008, -3576,
	-3168, -2776, -2400, -2032,
	-1688, -1360, -1040, -728,
	24808, 21904, 19008, 16704,
	14984, 13512, 12280, 11192,
	10232, 9360, 8576, 7856,
	7192, 6576, 6000, 5456,
	4944, 4464, 4008, 3576,
	3168, 2776, 2400, 2032,
	1688, 1360, 1040, 728,
	432, 136, -432, -136
	};
	static const int qmf_coeffs[12] =
	{
	3, -11, 12, 32, -210, 951, 3876, -805, 362, -156, 53, -11,
	};

	int dlowt;
	int rlow;
	int ihigh;
	int dhigh;
	int rhigh;
	int xout1;
	int xout2;
	int wd1;
	int wd2;
	int wd3;
	int code;
	size_t outlen;
	int i;
	size_t j;

	outlen = 0;
	rhigh = 0;
	for (j = 0; j < len; )
	{
	if (s->packed)
	{
	/* Unpack the code bits */
	if (s->in_bits < s->bits_per_sample)
	{
	s->in_buffer \|= (g722_data[j++] << s->in_bits);
	s->in_bits += 8;
	}
	code = s->in_buffer & ((1 << s->bits_per_sample) - 1);
	s->in_buffer >>= s->bits_per_sample;
	s->in_bits -= s->bits_per_sample;
	}
	else
	{
	code = g722_data[j++];
	}

	switch (s->bits_per_sample)
	{
	default:
	case 8:
	wd1 = code & 0x3F;
	ihigh = (code >> 6) & 0x03;
	wd2 = qm6[wd1];
	wd1 >>= 2;
	break;
	case 7:
	wd1 = code & 0x1F;
	ihigh = (code >> 5) & 0x03;
	wd2 = qm5[wd1];
	wd1 >>= 1;
	break;
	case 6:
	wd1 = code & 0x0F;
	ihigh = (code >> 4) & 0x03;
	wd2 = qm4[wd1];
	break;
	}
	/* Block 5L, LOW BAND INVQBL */
	wd2 = (s->band[0].det*wd2) >> 15;
	/* Block 5L, RECONS */
	rlow = s->band[0].s + wd2;
	/* Block 6L, LIMIT */
	if (rlow > 16383)
	rlow = 16383;
	else if (rlow < -16384)
	rlow = -16384;

	/* Block 2L, INVQAL */
	wd2 = qm4[wd1];
	dlowt = (s->band[0].det*wd2) >> 15;

	/* Block 3L, LOGSCL */
	wd2 = rl42[wd1];
	wd1 = (s->band[0].nb*127) >> 7;
	wd1 += wl[wd2];
	if (wd1 < 0)
	wd1 = 0;
	else if (wd1 > 18432)
	wd1 = 18432;
	s->band[0].nb = wd1;

	/* Block 3L, SCALEL */
	wd1 = (s->band[0].nb >> 6) & 31;
	wd2 = 8 - (s->band[0].nb >> 11);
	wd3 = (wd2 < 0) ? (ilb[wd1] << -wd2) : (ilb[wd1] >> wd2);
	s->band[0].det = wd3 << 2;

	block4(s, 0, dlowt);

	if (!s->eight_k)
	{
	/* Block 2H, INVQAH */
	wd2 = qm2[ihigh];
	dhigh = (s->band[1].det*wd2) >> 15;
	/* Block 5H, RECONS */
	rhigh = dhigh + s->band[1].s;
	/* Block 6H, LIMIT */
	if (rhigh > 16383)
	rhigh = 16383;
	else if (rhigh < -16384)
	rhigh = -16384;

	/* Block 2H, INVQAH */
	wd2 = rh2[ihigh];
	wd1 = (s->band[1].nb*127) >> 7;
	wd1 += wh[wd2];
	if (wd1 < 0)
	wd1 = 0;
	else if (wd1 > 22528)
	wd1 = 22528;
	s->band[1].nb = wd1;

	/* Block 3H, SCALEH */
	wd1 = (s->band[1].nb >> 6) & 31;
	wd2 = 10 - (s->band[1].nb >> 11);
	wd3 = (wd2 < 0) ? (ilb[wd1] << -wd2) : (ilb[wd1] >> wd2);
	s->band[1].det = wd3 << 2;

	block4(s, 1, dhigh);
	}

	if (s->itu_test_mode)
	{
	amp[outlen++] = (int16_t) (rlow << 1);
	amp[outlen++] = (int16_t) (rhigh << 1);
	}
	else
	{
	if (s->eight_k)
	{
	amp[outlen++] = (int16_t) (rlow << 1);
	}
	else
	{
	/* Apply the receive QMF */
	for (i = 0; i < 22; i++)
	s->x[i] = s->x[i + 2];
	s->x[22] = rlow + rhigh;
	s->x[23] = rlow - rhigh;

	xout1 = 0;
	xout2 = 0;
	for (i = 0; i < 12; i++)
	{
	xout2 += s->x[2i]qmf_coeffs[i];
	xout1 += s->x[2i + 1]qmf_coeffs[11 - i];
	}
	/* We shift by 12 to allow for the QMF filters (DC gain = 4096), less 1
	to allow for the 15 bit input to the G.722 algorithm. */
	/* WebRtc, tlegrand: added saturation */
	amp[outlen++] = saturate(xout1 >> 11);
	amp[outlen++] = saturate(xout2 >> 11);
	}
	}
	}
	return outlen;
	}
	/- End of function --------------------------------------------------------/
	/- End of file ------------------------------------------------------------/