mdf.c

sloedgy open sip stack source code

/* Copyright (C) 2003-2006 Jean-Marc Valin

   File: mdf.c
   Echo canceller based on the MDF algorithm (see below)

   Redistribution and use in source and binary forms, with or without
   modification, are permitted provided that the following conditions are
   met:

   1. Redistributions of source code must retain the above copyright notice,
   this list of conditions and the following disclaimer.

   2. Redistributions in binary form must reproduce the above copyright
   notice, this list of conditions and the following disclaimer in the
   documentation and/or other materials provided with the distribution.

   3. The name of the author may not be used to endorse or promote products
   derived from this software without specific prior written permission.

   THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
   IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
   OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
   DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT,
   INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
   (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
   SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
   HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
   STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
   ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
   POSSIBILITY OF SUCH DAMAGE.
*/

/*
   The echo canceller is based on the MDF algorithm described in:

   J. S. Soo, K. K. Pang Multidelay block frequency adaptive filter, 
   IEEE Trans. Acoust. Speech Signal Process., Vol. ASSP-38, No. 2, 
   February 1990.
   
   We use the Alternatively Updated MDF (AUMDF) variant. Robustness to 
   double-talk is achieved using a variable learning rate as described in:
   
   Valin, J.-M., On Adjusting the Learning Rate in Frequency Domain Echo 
   Cancellation With Double-Talk. Submitted to IEEE Transactions on Speech 
   and Audio Processing, 2006.
   
   About the fixed-point version:
   All the signals are represented with 16-bit words. The filter weights 
   are represented with 32-bit words, but only the top 16 bits are used
   in most cases. The lower 16 bits are completely reliable (due to the
   fact that the update is done only on the top bits), but help in the
   adaptation -- probably by removing a "threshold effect" due to
   quantization when the gradient is small.
   
   Another kludge that seems to work good: when performing the weight
   update, we only move half the way toward the "goal" this seems to
   reduce the effect of quantization noise in the update phase.
   
 */
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#ifdef _WIN32
#pragma warning(disable:4305)
#pragma warning(disable:4127)
#endif


#ifdef _WIN32
#pragma warning(disable:4244)
#endif

#include "misc.h"
#include "speex_echo.h"
#include "smallft.h"
#include "fftwrap.h"
#include "pseudofloat.h"
#include "math_approx.h"

#ifndef M_PI
#define M_PI 3.14159265358979323846
#endif

#define min(a,b) ((a)<(b) ? (a) : (b))
#define max(a,b) ((a)>(b) ? (a) : (b))

#ifdef FIXED_POINT
#define WEIGHT_SHIFT 11
#define NORMALIZE_SCALEDOWN 5
#define NORMALIZE_SCALEUP 3
#else
#define WEIGHT_SHIFT 0
#endif

#ifdef FIXED_POINT
static const spx_float_t MAX_ALPHA = ((spx_float_t){16777, -21});
static const spx_float_t ALPHA0 = ((spx_float_t){26214, -19});
static const spx_float_t MIN_LEAK = ((spx_float_t){16777, -24});
#define TOP16(x) ((x)>>16)
#else
static const spx_float_t MAX_ALPHA = .008f;
static const spx_float_t ALPHA0 = .05f;
static const spx_float_t MIN_LEAK = .001f;
#define TOP16(x) (x)
#endif


/** Speex echo cancellation state. */
struct SpeexEchoState_ {
   int frame_size;           /**< Number of samples processed each time */
   int window_size;
   int M;
   int cancel_count;
   int adapted;
   spx_int32_t sampling_rate;
   spx_word16_t spec_average;
   spx_word16_t beta0;
   spx_word16_t beta_max;
   spx_word32_t sum_adapt;
   spx_word16_t *e;
   spx_word16_t *x;
   spx_word16_t *X;
   spx_word16_t *d;
   spx_word16_t *y;
   spx_word16_t *last_y;
   spx_word32_t *Yps;
   spx_word16_t *Y;
   spx_word16_t *E;
   spx_word32_t *PHI;
   spx_word32_t *W;
   spx_word32_t *power;
   spx_float_t *power_1;
   spx_word32_t *Rf;
   spx_word32_t *Yf;
   spx_word32_t *Xf;
   spx_word32_t *Eh;
   spx_word32_t *Yh;
   spx_float_t Pey;
   spx_float_t Pyy;
   spx_word16_t *window;
   void *fft_table;
   spx_word16_t memX, memD, memE;
   spx_word16_t preemph;
};

static spx_word32_t inner_prod(const spx_word16_t *x, const spx_word16_t *y, int len)
{
   spx_word32_t sum=0;
   len >>= 2;
   while(len--)
   {
      spx_word32_t part=0;
      part = MAC16_16(part,*x++,*y++);
      part = MAC16_16(part,*x++,*y++);
      part = MAC16_16(part,*x++,*y++);
      part = MAC16_16(part,*x++,*y++);
      /* HINT: If you had a 40-bit accumulator, you could shift only at the end */
      sum = ADD32(sum,SHR32(part,6));
   }
   return sum;
}

/** Compute power spectrum of a half-complex (packed) vector */
static void power_spectrum(spx_word16_t *X, spx_word32_t *ps, int N)
{
   int i, j;
   ps[0]=MULT16_16(X[0],X[0]);
   for (i=1,j=1;i<N-1;i+=2,j++)
   {
      ps[j] =  MULT16_16(X[i],X[i]) + MULT16_16(X[i+1],X[i+1]);
   }
   ps[j]=MULT16_16(X[i],X[i]);
}

/** Compute cross-power spectrum of a half-complex (packed) vectors and add to acc */
#ifdef FIXED_POINT
static inline void spectral_mul_accum(spx_word16_t *X, spx_word32_t *Y, spx_word16_t *acc, int N, int M)
{
   int i,j;
   spx_word32_t tmp1=0,tmp2=0;
   for (j=0;j<M;j++)
   {
      tmp1 = MAC16_16(tmp1, X[j*N],TOP16(Y[j*N]));
   }
   acc[0] = PSHR32(tmp1,WEIGHT_SHIFT);
   for (i=1;i<N-1;i+=2)
   {
      tmp1 = tmp2 = 0;
      for (j=0;j<M;j++)
      {
         tmp1 = SUB32(MAC16_16(tmp1, X[j*N+i],TOP16(Y[j*N+i])), MULT16_16(X[j*N+i+1],TOP16(Y[j*N+i+1])));
         tmp2 = MAC16_16(MAC16_16(tmp2, X[j*N+i+1],TOP16(Y[j*N+i])), X[j*N+i], TOP16(Y[j*N+i+1]));
      }
      acc[i] = PSHR32(tmp1,WEIGHT_SHIFT);
      acc[i+1] = PSHR32(tmp2,WEIGHT_SHIFT);
   }
   tmp1 = tmp2 = 0;
   for (j=0;j<M;j++)
   {
      tmp1 = MAC16_16(tmp1, X[(j+1)*N-1],TOP16(Y[(j+1)*N-1]));
   }
   acc[N-1] = PSHR32(tmp1,WEIGHT_SHIFT);
}
#else
static void spectral_mul_accum(spx_word16_t *X, spx_word32_t *Y, spx_word16_t *acc, int N, int M)
{
   int i,j;
   for (i=0;i<N;i++)
      acc[i] = 0;
   for (j=0;j<M;j++)
   {
      acc[0] += X[0]*Y[0];
      for (i=1;i<N-1;i+=2)
      {
         acc[i] += (X[i]*Y[i] - X[i+1]*Y[i+1]);
         acc[i+1] += (X[i+1]*Y[i] + X[i]*Y[i+1]);
      }
      acc[i] += X[i]*Y[i];
      X += N;
      Y += N;
   }
}
#endif

/** Compute weighted cross-power spectrum of a half-complex (packed) vector with conjugate */
static void weighted_spectral_mul_conj(spx_float_t *w, spx_word16_t *X, spx_word16_t *Y, spx_word32_t *prod, int N)
{
   int i, j;
   prod[0] = FLOAT_MUL32(w[0],MULT16_16(X[0],Y[0]));
   for (i=1,j=1;i<N-1;i+=2,j++)
   {
      prod[i] = FLOAT_MUL32(w[j],MAC16_16(MULT16_16(X[i],Y[i]), X[i+1],Y[i+1]));
      prod[i+1] = FLOAT_MUL32(w[j],MAC16_16(MULT16_16(-X[i+1],Y[i]), X[i],Y[i+1]));
   }
   prod[i] = FLOAT_MUL32(w[j],MULT16_16(X[i],Y[i]));
}


/** Creates a new echo canceller state */
SpeexEchoState *speex_echo_state_init(int frame_size, int filter_length)
{
   int i,N,M;
   SpeexEchoState *st = (SpeexEchoState *)speex_alloc(sizeof(SpeexEchoState));

   st->frame_size = frame_size;
   st->window_size = 2*frame_size;
   N = st->window_size;
   M = st->M = (filter_length+st->frame_size-1)/frame_size;
   st->cancel_count=0;
   st->sum_adapt = 0;
   /* FIXME: Make that an init option (new API call?) */
   st->sampling_rate = 8000;
   st->spec_average = DIV32_16(SHL32(st->frame_size, 15), st->sampling_rate);
#ifdef FIXED_POINT
   st->beta0 = DIV32_16(SHL32(st->frame_size, 16), st->sampling_rate);
   st->beta_max = DIV32_16(SHL32(st->frame_size, 14), st->sampling_rate);
#else
   st->beta0 = (2.0f*st->frame_size)/st->sampling_rate;
   st->beta_max = (.5f*st->frame_size)/st->sampling_rate;
#endif

   st->fft_table = spx_fft_init(N);
   
   st->e = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->x = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->d = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->y = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->Yps = (spx_word32_t*)speex_alloc(N*sizeof(spx_word32_t));
   st->last_y = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->Yf = (spx_word32_t*)speex_alloc((st->frame_size+1)*sizeof(spx_word32_t));
   st->Rf = (spx_word32_t*)speex_alloc((st->frame_size+1)*sizeof(spx_word32_t));
   st->Xf = (spx_word32_t*)speex_alloc((st->frame_size+1)*sizeof(spx_word32_t));
   st->Yh = (spx_word32_t*)speex_alloc((st->frame_size+1)*sizeof(spx_word32_t));
   st->Eh = (spx_word32_t*)speex_alloc((st->frame_size+1)*sizeof(spx_word32_t));

   st->X = (spx_word16_t*)speex_alloc(M*N*sizeof(spx_word16_t));
   st->Y = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->E = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
   st->W = (spx_word32_t*)speex_alloc(M*N*sizeof(spx_word32_t));
   st->PHI = (spx_word32_t*)speex_alloc(M*N*sizeof(spx_word32_t));
   st->power = (spx_word32_t*)speex_alloc((frame_size+1)*sizeof(spx_word32_t));
   st->power_1 = (spx_float_t*)speex_alloc((frame_size+1)*sizeof(spx_float_t));
   st->window = (spx_word16_t*)speex_alloc(N*sizeof(spx_word16_t));
#ifdef FIXED_POINT   
   for (i=0;i<N>>1;i++)
   {
      st->window[i] = (16383-SHL16(spx_cos(DIV32_16(MULT16_16(25736,i<<1),N)),1));
      st->window[N-i-1] = st->window[i];
   }
#else
   for (i=0;i<N;i++)
      st->window[i] = .5-.5*cos(2*M_PI*i/N);
#endif
   for (i=0;i<N*M;i++)
   {
      st->W[i] = st->PHI[i] = 0;
   }
   st->memX=st->memD=st->memE=0;
   st->preemph = QCONST16(.9,15);
   st->adapted = 0;
   st->Pey = st->Pyy = FLOAT_ONE;
   return st;
}

/** Resets echo canceller state */
void speex_echo_state_reset(SpeexEchoState *st)
{
   int i, M, N;
   st->cancel_count=0;
   N = st->window_size;
   M = st->M;
   for (i=0;i<N*M;i++)
   {
      st->W[i] = 0;
      st->X[i] = 0;
   }
   for (i=0;i<=st->frame_size;i++)
      st->power[i] = 0;
   
   st->adapted = 0;
   st->sum_adapt = 0;
   st->Pey = st->Pyy = FLOAT_ONE;

}

/** Destroys an echo canceller state */
void speex_echo_state_destroy(SpeexEchoState *st)
{
   spx_fft_destroy(st->fft_table);

   speex_free(st->e);
   speex_free(st->x);
   speex_free(st->d);
   speex_free(st->y);
   speex_free(st->last_y);
   speex_free(st->Yps);
   speex_free(st->Yf);