1 files changed, 310 insertions, 0 deletions

diff --git a/libtoolame-dab/subband.c b/libtoolame-dab/subband.c
new file mode 100644
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--- /dev/null
+++ b/libtoolame-dab/subband.c
@@ -0,0 +1,310 @@
+#include <stdio.h>
+#include <string.h>
+#include <math.h>
+#include "common.h"
+#include "encoder.h"
+#include "mem.h"
+#include "bitstream.h"
+#include "encode.h"
+#include "enwindow.h"
+#include "subband.h"
+
+
+#ifdef REFERENCECODE
+/************************************************************************
+*
+* window_subband()
+*
+* PURPOSE:  Overlapping window on PCM samples
+*
+* SEMANTICS:
+* 32 16-bit pcm samples are scaled to fractional 2's complement and
+* concatenated to the end of the window buffer #x#. The updated window
+* buffer #x# is then windowed by the analysis window #c# to produce the
+* windowed sample #z#
+*
+************************************************************************/
+
+void window_subband (short **buffer, double z[64], int k)
+{
+  typedef double XX[2][HAN_SIZE];
+  static XX *x;
+  double *xk;
+  int i;
+  static int off[2] = { 0, 0 };
+  static char init = 0;
+  double t;
+  double *ep0, *ep1, *ep2, *ep3, *ep4, *ep5, *ep6, *ep7;
+  if (!init) {
+    x = (XX *) mem_alloc (sizeof (XX), "x");
+    memset (x, 0, 2 * HAN_SIZE * sizeof (double));
+    init = 1;
+  }
+  xk = (*x)[k];
+
+  /* replace 32 oldest samples with 32 new samples */
+  for (i = 0; i < 32; i++)
+    xk[31 - i + off[k]] = (double) *(*buffer)++ / SCALE;
+
+  ep0 = &enwindow[0];
+  ep1 = &enwindow[64];
+  ep2 = &enwindow[128];
+  ep3 = &enwindow[192];
+  ep4 = &enwindow[256];
+  ep5 = &enwindow[320];
+  ep6 = &enwindow[384];
+  ep7 = &enwindow[448];
+
+  /* shift samples into proper window positions */
+  for (i = 0; i < 64; i++) {
+    t = xk[(i + off[k]) & (512 - 1)] * *ep0++;
+    t += xk[(i + 64 + off[k]) & (512 - 1)] * *ep1++;
+    t += xk[(i + 128 + off[k]) & (512 - 1)] * *ep2++;
+    t += xk[(i + 192 + off[k]) & (512 - 1)] * *ep3++;
+    t += xk[(i + 256 + off[k]) & (512 - 1)] * *ep4++;
+    t += xk[(i + 320 + off[k]) & (512 - 1)] * *ep5++;
+    t += xk[(i + 384 + off[k]) & (512 - 1)] * *ep6++;
+    t += xk[(i + 448 + off[k]) & (512 - 1)] * *ep7++;
+    z[i] = t;
+  }
+
+  off[k] += 480;		/*offset is modulo (HAN_SIZE-1) */
+  off[k] &= HAN_SIZE - 1;
+
+}
+
+
+/************************************************************************
+*
+* filter_subband()
+*
+* PURPOSE:  Calculates the analysis filter bank coefficients
+*
+* SEMANTICS:
+*      The windowed samples #z# is filtered by the digital filter matrix #m#
+* to produce the subband samples #s#. This done by first selectively
+* picking out values from the windowed samples, and then multiplying
+* them by the filter matrix, producing 32 subband samples.
+*
+************************************************************************/
+void filter_subband (double z[HAN_SIZE], double s[SBLIMIT])
+{
+  double yprime[32];
+  register int i, j;
+
+  static double m[16][32];
+  static int init = 0;
+
+  if (init == 0) {
+    init++;
+    create_dct_matrix (m);
+  }
+
+  yprime[0] = z[16];
+  for (i = 1; i <= 16; i++)
+    yprime[i] = z[i + 16] + z[16 - i];
+  for (i = 17; i <= 31; i++)
+    yprime[i] = z[i + 16] - z[80 - i];
+
+  for (i = 15; i >= 0; i--) {
+    register double s0 = 0.0, s1 = 0.0;
+    register double *mp = m[i];
+    register double *xinp = yprime;
+    for (j = 0; j < 8; j++) {
+      s0 += *mp++ * *xinp++;
+      s1 += *mp++ * *xinp++;
+      s0 += *mp++ * *xinp++;
+      s1 += *mp++ * *xinp++;
+    }
+    s[i] = s0 + s1;
+    s[31 - i] = s0 - s1;
+  }
+}
+#endif //REFERENCECODE
+
+void create_dct_matrix (double filter[16][32])
+{
+  register int i, k;
+
+  for (i = 0; i < 16; i++)
+    for (k = 0; k < 32; k++) {
+      if ((filter[i][k] = 1e9 * cos ((double) ((2 * i + 1) * k * PI64))) >= 0)
+	modf (filter[i][k] + 0.5, &filter[i][k]);
+      else
+	modf (filter[i][k] - 0.5, &filter[i][k]);
+      filter[i][k] *= 1e-9;
+    }
+}
+
+
+#ifdef NEWWS
+/***********************************************************************
+ An implementation of a modified window subband as seen in Kumar & Zubair's
+"A high performance software implentation of mpeg audio encoder"
+I think from IEEE ASCAP 1996 proceedings
+ 
+input: shift in 32*12 (384) new samples into a 864 point buffer.
+ch - which channel we're looking at.
+ 
+This routine basically does 12 calls to window subband all in one go.
+Not yet called in code. here for testing only.
+************************************************************************/
+void window_subband12 (short **buffer, int ch)
+{
+  static double x[2][864];	/* 2 channels, 864 buffer for each */
+  double *xk;
+  double t[12];			/* a temp buffer for summing values */
+  double y[12][64];		/* 12 output arrays of 64 values */
+  int i, j, k, m;
+  static double c[512];		/* enwindow array */
+  static int init = 0;
+  double c0;
+
+  xk = x[ch];			/* an easier way of referencing the array */
+
+  /* shift 384 new samples into the buffer */
+  for (i = 863; i >= 384; i--)
+    xk[i] = xk[i - 384];
+  for (i = 383; i >= 0; i--)
+    xk[i] = (double) *(*buffer)++ / SCALE;
+
+  for (j = 0; j < 64; j++) {
+    for (k = 0; k < 12; k++)
+      t[k] = 0;
+    for (i = 0; i < 8; i++) {
+      m = i * 64 + j;
+      c0 = c[m];
+      t[0] += c0 * xk[m + 352];
+      t[1] += c0 * xk[m + 320];
+      t[2] += c0 * xk[m + 288];
+      t[3] += c0 * xk[m + 256];
+      t[4] += c0 * xk[m + 224];
+      t[5] += c0 * xk[m + 192];
+      t[6] += c0 * xk[m + 160];
+      t[7] += c0 * xk[m + 128];
+      t[8] += c0 * xk[m + 96];
+      t[9] += c0 * xk[m + 64];
+      t[10] += c0 * xk[m + 32];
+      t[11] += c0 * xk[m];
+    }
+    for (i = 0; i < 12; i++) {
+      y[i][j] = t[i];
+    }
+  }
+}
+#endif /* NEWWS */
+
+
+//____________________________________________________________________________
+//____ WindowFilterSubband() _________________________________________
+//____ RS&A - Feb 2003 _______________________________________________________
+void WindowFilterSubband (short *pBuffer, int ch, double s[SBLIMIT])
+{
+  register int i, j;
+  int pa, pb, pc, pd, pe, pf, pg, ph;
+  double t;
+  double *dp, *dp2;
+  double *pEnw;
+  double y[64];
+  double yprime[32];
+
+  static double x[2][512];
+  static double m[16][32];
+  static int init = 0;
+  static int off[2];
+  static int half[2];
+
+  if (init == 0) {
+    init++;
+    off[0] = 0;
+    off[1] = 0;
+    half[0] = 0;
+    half[1] = 0;
+    for (i = 0; i < 2; i++)
+      for (j = 0; j < 512; j++)
+	x[i][j] = 0;
+    create_dct_matrix (m);
+  }
+
+  dp = x[ch] + off[ch] + half[ch] * 256;
+
+  /* replace 32 oldest samples with 32 new samples */
+  for (i = 0; i < 32; i++)
+    dp[(31 - i) * 8] = (double) pBuffer[i] / SCALE;
+
+  // looks like "school example" but does faster ...
+  dp = (x[ch] + half[ch] * 256);
+  pa = off[ch];
+  pb = (pa + 1) % 8;
+  pc = (pa + 2) % 8;
+  pd = (pa + 3) % 8;
+  pe = (pa + 4) % 8;
+  pf = (pa + 5) % 8;
+  pg = (pa + 6) % 8;
+  ph = (pa + 7) % 8;
+
+  for (i = 0; i < 32; i++) {
+    dp2 = dp + i * 8;
+    pEnw = enwindow + i;
+    t = dp2[pa] * pEnw[0];
+    t += dp2[pb] * pEnw[64];
+    t += dp2[pc] * pEnw[128];
+    t += dp2[pd] * pEnw[192];
+    t += dp2[pe] * pEnw[256];
+    t += dp2[pf] * pEnw[320];
+    t += dp2[pg] * pEnw[384];
+    t += dp2[ph] * pEnw[448];
+    y[i] = t;
+  }
+
+  yprime[0] = y[16];		// Michael Chenīs dct filter
+
+  dp = half[ch] ? x[ch] : (x[ch] + 256);
+  pa = half[ch] ? (off[ch] + 1) & 7 : off[ch];
+  pb = (pa + 1) % 8;
+  pc = (pa + 2) % 8;
+  pd = (pa + 3) % 8;
+  pe = (pa + 4) % 8;
+  pf = (pa + 5) % 8;
+  pg = (pa + 6) % 8;
+  ph = (pa + 7) % 8;
+
+  for (i = 0; i < 32; i++) {
+    dp2 = dp + i * 8;
+    pEnw = enwindow + i + 32;
+    t = dp2[pa] * pEnw[0];
+    t += dp2[pb] * pEnw[64];
+    t += dp2[pc] * pEnw[128];
+    t += dp2[pd] * pEnw[192];
+    t += dp2[pe] * pEnw[256];
+    t += dp2[pf] * pEnw[320];
+    t += dp2[pg] * pEnw[384];
+    t += dp2[ph] * pEnw[448];
+    y[i + 32] = t;
+    // 1st pass on Michael Chenīs dct filter
+    if (i > 0 && i < 17)
+      yprime[i] = y[i + 16] + y[16 - i];
+  }
+
+  // 2nd pass on Michael Chenīs dct filter
+  for (i = 17; i < 32; i++)
+    yprime[i] = y[i + 16] - y[80 - i];
+
+  for (i = 15; i >= 0; i--) {
+    register double s0 = 0.0, s1 = 0.0;
+    register double *mp = m[i];
+    register double *xinp = yprime;
+    for (j = 0; j < 8; j++) {
+      s0 += *mp++ * *xinp++;
+      s1 += *mp++ * *xinp++;
+      s0 += *mp++ * *xinp++;
+      s1 += *mp++ * *xinp++;
+    }
+    s[i] = s0 + s1;
+    s[31 - i] = s0 - s1;
+  }
+
+  half[ch] = (half[ch] + 1) & 1;
+  if (half[ch] == 1)
+    off[ch] = (off[ch] + 7) & 7;
+}