Chat-O-Matic/libs/libmsn/libsiren/dct4.cpp

/*
 * Siren Encoder/Decoder library
 *
 *   @author: Youness Alaoui <kakaroto@kakaroto.homelinux.net>
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Library General Public
 * License as published by the Free Software Foundation; either
 * version 2 of the License, or (at your option) any later version.
 *
 * This library 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
 * Library General Public License for more details.
 *
 * You should have received a copy of the GNU Library General Public
 * License along with this library; if not, write to the
 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
 * Boston, MA 02111-1307, USA.
 */


#include "siren7.h"


#define PI 3.1415926

typedef struct {
  float cos;
  float msin;
} dct_table_type;

static float dct_core_320[100];
static float dct_core_640[100];
static dct_table_type dct_table_5[5];
static dct_table_type dct_table_10[10];
static dct_table_type dct_table_20[20];
static dct_table_type dct_table_40[40];
static dct_table_type dct_table_80[80];
static dct_table_type dct_table_160[160];
static dct_table_type dct_table_320[320];
static dct_table_type dct_table_640[640];
static dct_table_type *dct_tables[8] = {dct_table_5,
                                        dct_table_10,
                                        dct_table_20,
                                        dct_table_40,
                                        dct_table_80,
                                        dct_table_160,
                                        dct_table_320,
                                        dct_table_640};

static int dct4_initialized = 0;

void siren_dct4_init() {
  int i, j = 0;
  double scale_320 = (float) sqrt(2.0/320);
  double scale_640 = (float) sqrt(2.0/640);
  double angle;
  double scale;

  /* set up dct4 tables */
  for(i = 0; i < 10; i++) {
    angle = (float) ((i + 0.5) *  PI);
    for (j = 0 ; j < 10; j++) {
      dct_core_320[(i*10)+j] = (float) (scale_320 * cos((j + 0.5) * angle / 10));
      dct_core_640[(i*10)+j] = (float) (scale_640 * cos((j + 0.5) * angle / 10));
    }
  }

  for(i = 0; i < 8; i++) {
    scale = (float) (PI / ((5 << i) * 4));
    for (j = 0 ; j < (5 << i); j++) {
      angle = (float) (j + 0.5) * scale;
      dct_tables[i][j].cos = (float) cos(angle);
      dct_tables[i][j].msin = (float)  -sin(angle);
    }
  }

  dct4_initialized = 1;
}


void siren_dct4(float *Source, float *Destination, int dct_length) {
  int log_length = 0;
  float * dct_core = NULL;
  dct_table_type ** dct_table_ptr_ptr = NULL;
  dct_table_type * dct_table_ptr = NULL;
  float OutBuffer1[640];
  float OutBuffer2[640];
  float *Out_ptr;
  float *NextOut_ptr;
  float *In_Ptr = NULL;
  float *In_Ptr_low = NULL;
  float *In_Ptr_high = NULL;
  float In_val_low;
  float In_val_high;
  float *Out_ptr_low = NULL;
  float *Out_ptr_high = NULL;
  float mult1, mult2, mult3, mult4, mult5, mult6, mult7, mult8, mult9, mult10;
  int i,j;

  if (dct4_initialized == 0)
    siren_dct4_init();

  if (dct_length == 640) {
    log_length = 5;
    dct_core = dct_core_640;
  } else {
    log_length = 4;
    dct_core = dct_core_320;
  }

  Out_ptr = OutBuffer1;
  NextOut_ptr = OutBuffer2;
  In_Ptr = Source;
  for (i = 0; i <= log_length; i++) {
    for (j = 0; j < (1 << i); j++) {
      Out_ptr_low = Out_ptr + (j * (dct_length >> i));
      Out_ptr_high = Out_ptr + ( (j+1) * (dct_length >> i));
      do {
        In_val_low = *In_Ptr++;
        In_val_high = *In_Ptr++;
        *Out_ptr_low++ = In_val_low + In_val_high;
        *--Out_ptr_high = In_val_low - In_val_high;
      } while (Out_ptr_low < Out_ptr_high);
    }

    In_Ptr = Out_ptr;
    Out_ptr = NextOut_ptr;
    NextOut_ptr = In_Ptr;
  }

  for (i = 0; i < (2 << log_length); i++) {
    for (j = 0 ; j < 10 ;  j ++) {
      mult1 = In_Ptr[(i*10)] * dct_core[j*10];
      mult2 = In_Ptr[(i*10) + 1] * dct_core[(j*10) + 1];
      mult3 = In_Ptr[(i*10) + 2] * dct_core[(j*10) + 2];
      mult4 = In_Ptr[(i*10) + 3] * dct_core[(j*10) + 3];
      mult5 = In_Ptr[(i*10) + 4] * dct_core[(j*10) + 4];
      mult6 = In_Ptr[(i*10) + 5] * dct_core[(j*10) + 5];
      mult7 = In_Ptr[(i*10) + 6] * dct_core[(j*10) + 6];
      mult8 = In_Ptr[(i*10) + 7] * dct_core[(j*10) + 7];
      mult9 = In_Ptr[(i*10) + 8] * dct_core[(j*10) + 8];
      mult10 = In_Ptr[(i*10) + 9] * dct_core[(j*10) + 9];
      Out_ptr[(i*10)+j] = mult1 + mult2 + mult3 + mult4 +
          mult5 + mult6 + mult7 + mult8 +
          mult9 + mult10;
    }
  }


  In_Ptr = Out_ptr;
  Out_ptr = NextOut_ptr;
  NextOut_ptr = In_Ptr;
  dct_table_ptr_ptr = dct_tables;
  for (i = log_length; i >= 0; i--) {
    dct_table_ptr_ptr++;
    for (j = 0; j < (1 << i); j++) {
      dct_table_ptr = *dct_table_ptr_ptr;
      if ( i == 0 )
        Out_ptr_low = Destination + (j * (dct_length >> i));
      else
        Out_ptr_low = Out_ptr + (j * (dct_length >> i));

      Out_ptr_high = Out_ptr_low + (dct_length >> i);

      In_Ptr_low = In_Ptr + (j * (dct_length >> i));
      In_Ptr_high = In_Ptr_low + (dct_length >> (i+1));
      do {
        *Out_ptr_low++ = (*In_Ptr_low * (*dct_table_ptr).cos) - (*In_Ptr_high * (*dct_table_ptr).msin);
        *--Out_ptr_high = (*In_Ptr_high++ * (*dct_table_ptr).cos) + (*In_Ptr_low++ * (*dct_table_ptr).msin);
        dct_table_ptr++;
        *Out_ptr_low++ = (*In_Ptr_low * (*dct_table_ptr).cos) + (*In_Ptr_high * (*dct_table_ptr).msin);
        *--Out_ptr_high = (*In_Ptr_low++ * (*dct_table_ptr).msin) - (*In_Ptr_high++ * (*dct_table_ptr).cos);
        dct_table_ptr++;
      } while (Out_ptr_low < Out_ptr_high);
    }

    In_Ptr = Out_ptr;
    Out_ptr = NextOut_ptr;
    NextOut_ptr = In_Ptr;
  }

}
ÂÂmoving libmsn code from branch to the Caya subproject 2010-09-24 08:48:01 -05:00			`/*`
			`* Siren Encoder/Decoder library`
			`*`
			`* @author: Youness Alaoui <kakaroto@kakaroto.homelinux.net>`
			`*`
			`* This library is free software; you can redistribute it and/or`
			`* modify it under the terms of the GNU Library General Public`
			`* License as published by the Free Software Foundation; either`
			`* version 2 of the License, or (at your option) any later version.`
			`*`
			`* This library 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`
			`* Library General Public License for more details.`
			`*`
			`* You should have received a copy of the GNU Library General Public`
			`* License along with this library; if not, write to the`
			`* Free Software Foundation, Inc., 59 Temple Place - Suite 330,`
			`* Boston, MA 02111-1307, USA.`
			`*/`


			`#include "siren7.h"`


			`#define PI 3.1415926`

			`typedef struct {`
			`float cos;`
			`float msin;`
			`} dct_table_type;`

			`static float dct_core_320[100];`
			`static float dct_core_640[100];`
			`static dct_table_type dct_table_5[5];`
			`static dct_table_type dct_table_10[10];`
			`static dct_table_type dct_table_20[20];`
			`static dct_table_type dct_table_40[40];`
			`static dct_table_type dct_table_80[80];`
			`static dct_table_type dct_table_160[160];`
			`static dct_table_type dct_table_320[320];`
			`static dct_table_type dct_table_640[640];`
			`static dct_table_type *dct_tables[8] = {dct_table_5,`
			`dct_table_10,`
			`dct_table_20,`
			`dct_table_40,`
			`dct_table_80,`
			`dct_table_160,`
			`dct_table_320,`
			`dct_table_640};`

			`static int dct4_initialized = 0;`

			`void siren_dct4_init() {`
			`int i, j = 0;`
			`double scale_320 = (float) sqrt(2.0/320);`
			`double scale_640 = (float) sqrt(2.0/640);`
			`double angle;`
			`double scale;`

			`/* set up dct4 tables */`
			`for(i = 0; i < 10; i++) {`
			`angle = (float) ((i + 0.5) * PI);`
			`for (j = 0 ; j < 10; j++) {`
			`dct_core_320[(i10)+j] = (float) (scale_320 cos((j + 0.5) * angle / 10));`
			`dct_core_640[(i10)+j] = (float) (scale_640 cos((j + 0.5) * angle / 10));`
			`}`
			`}`

			`for(i = 0; i < 8; i++) {`
			`scale = (float) (PI / ((5 << i) * 4));`
			`for (j = 0 ; j < (5 << i); j++) {`
			`angle = (float) (j + 0.5) * scale;`
			`dct_tables[i][j].cos = (float) cos(angle);`
			`dct_tables[i][j].msin = (float) -sin(angle);`
			`}`
			`}`

			`dct4_initialized = 1;`
			`}`


			`void siren_dct4(float Source, float Destination, int dct_length) {`
			`int log_length = 0;`
			`float * dct_core = NULL;`
			`dct_table_type ** dct_table_ptr_ptr = NULL;`
			`dct_table_type * dct_table_ptr = NULL;`
			`float OutBuffer1[640];`
			`float OutBuffer2[640];`
			`float *Out_ptr;`
			`float *NextOut_ptr;`
			`float *In_Ptr = NULL;`
			`float *In_Ptr_low = NULL;`
			`float *In_Ptr_high = NULL;`
			`float In_val_low;`
			`float In_val_high;`
			`float *Out_ptr_low = NULL;`
			`float *Out_ptr_high = NULL;`
			`float mult1, mult2, mult3, mult4, mult5, mult6, mult7, mult8, mult9, mult10;`
			`int i,j;`

			`if (dct4_initialized == 0)`
			`siren_dct4_init();`

			`if (dct_length == 640) {`
			`log_length = 5;`
			`dct_core = dct_core_640;`
			`} else {`
			`log_length = 4;`
			`dct_core = dct_core_320;`
			`}`

			`Out_ptr = OutBuffer1;`
			`NextOut_ptr = OutBuffer2;`
			`In_Ptr = Source;`
			`for (i = 0; i <= log_length; i++) {`
			`for (j = 0; j < (1 << i); j++) {`
			`Out_ptr_low = Out_ptr + (j * (dct_length >> i));`
			`Out_ptr_high = Out_ptr + ( (j+1) * (dct_length >> i));`
			`do {`
			`In_val_low = *In_Ptr++;`
			`In_val_high = *In_Ptr++;`
			`*Out_ptr_low++ = In_val_low + In_val_high;`
			`*--Out_ptr_high = In_val_low - In_val_high;`
			`} while (Out_ptr_low < Out_ptr_high);`
			`}`

			`In_Ptr = Out_ptr;`
			`Out_ptr = NextOut_ptr;`
			`NextOut_ptr = In_Ptr;`
			`}`

			`for (i = 0; i < (2 << log_length); i++) {`
			`for (j = 0 ; j < 10 ; j ++) {`
			`mult1 = In_Ptr[(i10)] dct_core[j*10];`
			`mult2 = In_Ptr[(i10) + 1] dct_core[(j*10) + 1];`
			`mult3 = In_Ptr[(i10) + 2] dct_core[(j*10) + 2];`
			`mult4 = In_Ptr[(i10) + 3] dct_core[(j*10) + 3];`
			`mult5 = In_Ptr[(i10) + 4] dct_core[(j*10) + 4];`
			`mult6 = In_Ptr[(i10) + 5] dct_core[(j*10) + 5];`
			`mult7 = In_Ptr[(i10) + 6] dct_core[(j*10) + 6];`
			`mult8 = In_Ptr[(i10) + 7] dct_core[(j*10) + 7];`
			`mult9 = In_Ptr[(i10) + 8] dct_core[(j*10) + 8];`
			`mult10 = In_Ptr[(i10) + 9] dct_core[(j*10) + 9];`
			`Out_ptr[(i*10)+j] = mult1 + mult2 + mult3 + mult4 +`
			`mult5 + mult6 + mult7 + mult8 +`
			`mult9 + mult10;`
			`}`
			`}`


			`In_Ptr = Out_ptr;`
			`Out_ptr = NextOut_ptr;`
			`NextOut_ptr = In_Ptr;`
			`dct_table_ptr_ptr = dct_tables;`
			`for (i = log_length; i >= 0; i--) {`
			`dct_table_ptr_ptr++;`
			`for (j = 0; j < (1 << i); j++) {`
			`dct_table_ptr = *dct_table_ptr_ptr;`
			`if ( i == 0 )`
			`Out_ptr_low = Destination + (j * (dct_length >> i));`
			`else`
			`Out_ptr_low = Out_ptr + (j * (dct_length >> i));`

			`Out_ptr_high = Out_ptr_low + (dct_length >> i);`

			`In_Ptr_low = In_Ptr + (j * (dct_length >> i));`
			`In_Ptr_high = In_Ptr_low + (dct_length >> (i+1));`
			`do {`
			`Out_ptr_low++ = (In_Ptr_low * (dct_table_ptr).cos) - (In_Ptr_high * (*dct_table_ptr).msin);`
			`--Out_ptr_high = (In_Ptr_high++ * (dct_table_ptr).cos) + (In_Ptr_low++ * (*dct_table_ptr).msin);`
			`dct_table_ptr++;`
			`Out_ptr_low++ = (In_Ptr_low * (dct_table_ptr).cos) + (In_Ptr_high * (*dct_table_ptr).msin);`
			`--Out_ptr_high = (In_Ptr_low++ * (dct_table_ptr).msin) - (In_Ptr_high++ * (*dct_table_ptr).cos);`
			`dct_table_ptr++;`
			`} while (Out_ptr_low < Out_ptr_high);`
			`}`

			`In_Ptr = Out_ptr;`
			`Out_ptr = NextOut_ptr;`
			`NextOut_ptr = In_Ptr;`
			`}`

			`}`