tweaked surround lowpass filter, included some new test code

git-svn-id: svn://svn.mplayerhq.hu/mplayer/trunk@3496 b3059339-0415-0410-9bf9-f77b7e298cf2
2001-12-14 21:25:49 +00:00 · 2001-12-14 21:25:49 +00:00 · d6d9a909f0
parent 3ea29912ef
commit d6d9a909f0
2 changed files with 81 additions and 13 deletions
--- a/libao2/firfilter.c
+++ b/libao2/firfilter.c
@ -1,6 +1,8 @@

+#include <math.h>
+
 static double desired_7kHz_lowpass[] = {1.0, 0.0};
-static double weights_7kHz_lowpass[] = {0.1, 0.1};
+static double weights_7kHz_lowpass[] = {0.2, 2.0};

 double *calc_coefficients_7kHz_lowpass(int rate)
 {
@ -18,16 +20,20 @@ double *calc_coefficients_7kHz_lowpass(int rate)

 #if 0

-int16_t firfilter(int16_t *buf, int pos, int len, int count, double *coefficients)
-{
-  double result = 0.0;
+static double desired_125Hz_lowpass[] = {1.0, 0.0};
+static double weights_125Hz_lowpass[] = {0.2, 2.0};
+
+double *calc_coefficients_125Hz_lowpass(int rate)
+{
+  double *result = (double *)malloc(256*sizeof(double));
+  double bands[4];
+
+  bands[0] = 0.0;  bands[1] = 125.0/rate;
+  bands[2] = 175.0/rate;  bands[3] = 0.5;
+
+  remez(result, 256, 2, bands,
+	desired_125Hz_lowpass, weights_125Hz_lowpass, BANDPASS);

-  // Back 32 samples, maybe wrapping in buffer.
-  pos = (pos+len-count)%len;
-  // And do the multiply-accumulate
-  while (count--) {
-    result += buf[pos++] * *coefficients++;  pos %= len;
-  }
  return result;
 }

@ -57,3 +63,59 @@ int16_t firfilter(int16_t *buf, int pos, int len, int count, double *coefficient
  while (count2--)  result += *buf++ * *coefficients++;
  return result;
 }
+
+void dump_filter_coefficients(double *coefficients)
+{
+  int i;
+  fprintf(stderr, "pl_surround: Filter coefficients are: \n");
+  for (i=0; (i<32); i++) {
+    fprintf(stderr, "  [%2d]: %23.20f\n", i, coefficients[i]);
+  }
+}
+
+#ifdef TESTING
+
+#define PI 3.1415926536
+
+// For testing purposes, fill a buffer with some sine-wave tone
+void sinewave(int16_t *output, int samples, int incr, int freq, double phase, int samplerate)
+{
+  double radians_per_sample = 2*PI / ((0.0+samplerate) / freq), r;
+
+  //fprintf(stderr, "samples=%d tone freq=%d, samplerate=%d, radians/sample=%f\n",
+  //	  samples, freq, samplerate, radians_per_sample);
+  r = phase;
+  while (samples--) {
+    *output = sin(r)*10000;  output = &output[incr];
+    r += radians_per_sample;
+  }
+}
+
+// Pass various frequencies through a FIR filter and report amplitudes
+void testfilter(double *coefficients, int count, int samplerate)
+{
+  int16_t wavein[8192]; //, waveout[2048];
+  int sample, samples, maxsample, minsample, totsample;
+  int nyquist=samplerate/2;
+  int freq, i;
+
+  for (freq=25; freq<nyquist; freq+=25) {
+    // Make input tone
+    sinewave(wavein, 8192, 1, freq, 0.0, samplerate);
+    //for (i=0; i<32; i++)
+    //  fprintf(stderr, "%5d\n", wavein[i]);
+    // Filter through the filter, measure results
+    maxsample=0;  minsample=1000000;  totsample=0;  samples=0;
+    for (i=2048; i<8192; i++) {
+      //waveout[i] = wavein[i];
+      sample = abs(firfilter(wavein, i, 8192, count, coefficients));
+      if (sample > maxsample) maxsample=sample;
+      if (sample < minsample) minsample=sample;
+      totsample += sample;  samples++;
+    }
+    // Report results
+    fprintf(stderr, "%5d  %5d  %5d  %5d  %f\n", freq, totsample/samples, maxsample, minsample, 10*log((totsample/samples)/6500.0));
+  }
+}
+
+#endif
--- a/libao2/pl_surround.c
+++ b/libao2/pl_surround.c
@ -115,7 +115,8 @@ static int init(){
  ao_plugin_data.sz_mult    /= 2;

  // Figure out buffer space (in int16_ts) needed for the 15msec delay
-  pl_surround.delaybuf_len = (pl_surround.rate * pl_surround.msecs / 1000);
+  // Extra 31 samples allow for lowpass filter delay (taps-1)
+  pl_surround.delaybuf_len = (pl_surround.rate * pl_surround.msecs / 1000) + 31;
  // Allocate delay buffers
  pl_surround.Ls_delaybuf=(void*)calloc(pl_surround.delaybuf_len,sizeof(int16_t));
  pl_surround.Rs_delaybuf=(void*)calloc(pl_surround.delaybuf_len,sizeof(int16_t));
@ -124,7 +125,8 @@ static int init(){
  pl_surround.delaybuf_pos = 0;
  // Surround filer coefficients
  pl_surround.filter_coefs_surround = calc_coefficients_7kHz_lowpass(pl_surround.rate);
-
+  //dump_filter_coefficients(pl_surround.filter_coefs_surround);
+  //testfilter(pl_surround.filter_coefs_surround, 32, pl_surround.rate);
  return 1;
 }

@ -164,8 +166,12 @@ static int play(){
  // fprintf(stderr, "pl_surround: play %d bytes, %d samples\n", ao_plugin_data.len, samples);

  samples  = ao_plugin_data.len / sizeof(int16_t) / pl_surround.input_channels;
-
  out = pl_surround.databuf;  in = (int16_t *)ao_plugin_data.data;
+
+  // Testing - place a 1kHz tone in the front channels in anti-phase
+  //sinewave(in, samples, pl_surround.input_channels, 1000, 0.0, pl_surround.rate);
+  //sinewave(&in[1], samples, pl_surround.input_channels, 1000, PI, pl_surround.rate);
+
  for (i=0; i<samples; i++) {

    // About volume balancing...