decoder/ixheaacd_tcx_fwd_mdct.c - platform/external/libxaac - Git at Google

 /******************************************************************************
  *                                                                            *
  * Copyright (C) 2018 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at:
  *
  * http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *****************************************************************************
  * Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore
 */
 #include <float.h>
 #include <stdlib.h>
 #include <stdio.h>
 #include <math.h>
 #include <string.h>

 #include "ixheaacd_cnst.h"
 #include <ixheaacd_type_def.h>
 #include "ixheaacd_bitbuffer.h"
 #include "ixheaacd_acelp_com.h"

 #include <ixheaacd_type_def.h>
 #include "ixheaacd_bitbuffer.h"
 #include "ixheaacd_interface.h"

 #include "ixheaacd_tns_usac.h"
 #include "ixheaacd_cnst.h"

 #include "ixheaacd_acelp_info.h"

 #include "ixheaacd_td_mdct.h"

 #include "ixheaacd_sbrdecsettings.h"
 #include "ixheaacd_info.h"
 #include "ixheaacd_sbr_common.h"
 #include "ixheaacd_drc_data_struct.h"
 #include "ixheaacd_drc_dec.h"
 #include "ixheaacd_sbrdecoder.h"
 #include "ixheaacd_mps_polyphase.h"
 #include "ixheaacd_sbr_const.h"

 #include "ixheaacd_constants.h"
 #include <ixheaacd_basic_ops32.h>
 #include <ixheaacd_basic_ops40.h>
 #include "ixheaacd_main.h"
 #include "ixheaacd_arith_dec.h"

 #define FREQ_MAX 6400.0f

 #define ABS(A) ((A) < 0 ? (-A) : (A))

 static VOID ixheaacd_compute_coeff_poly_f(FLOAT32 lsp[], FLOAT32 *f1,
                                           FLOAT32 *f2) {
   FLOAT32 b1, b2;
   FLOAT32 *ptr_lsp;
   WORD32 i, j;

   ptr_lsp = lsp;
   f1[0] = f2[0] = 1.0f;

   for (i = 1; i <= ORDER_BY_2; i++) {
     b1 = -2.0f * (*ptr_lsp++);
     b2 = -2.0f * (*ptr_lsp++);
     f1[i] = (b1 * f1[i - 1]) + (2.0f * f1[i - 2]);
     f2[i] = (b2 * f2[i - 1]) + (2.0f * f2[i - 2]);
     for (j = i - 1; j > 0; j--) {
       f1[j] += (b1 * f1[j - 1]) + f1[j - 2];
       f2[j] += (b2 * f2[j - 1]) + f2[j - 2];
     }
   }

   return;
 }
 VOID ixheaacd_lsp_to_lp_conversion(FLOAT32 *lsp, FLOAT32 *lp_flt_coff_a) {
   WORD32 i;
   FLOAT32 *ppoly_f1, *ppoly_f2;
   FLOAT32 *plp_flt_coff_a_bott, *plp_flt_coff_a_top;
   FLOAT32 poly1[ORDER_BY_2 + 2], poly2[ORDER_BY_2 + 2];

   poly1[0] = 0.0f;
   poly2[0] = 0.0f;

   ixheaacd_compute_coeff_poly_f(lsp, &poly1[1], &poly2[1]);

   ppoly_f1 = poly1 + ORDER_BY_2 + 1;
   ppoly_f2 = poly2 + ORDER_BY_2 + 1;

   for (i = 0; i < ORDER_BY_2; i++) {
     ppoly_f1[0] += ppoly_f1[-1];
     ppoly_f2[0] -= ppoly_f2[-1];
     ppoly_f1--;
     ppoly_f2--;
   }

   plp_flt_coff_a_bott = lp_flt_coff_a;
   *plp_flt_coff_a_bott++ = 1.0f;
   plp_flt_coff_a_top = lp_flt_coff_a + ORDER;
   ppoly_f1 = poly1 + 2;
   ppoly_f2 = poly2 + 2;
   for (i = 0; i < ORDER_BY_2; i++) {
     *plp_flt_coff_a_bott++ = 0.5f * (*ppoly_f1 + *ppoly_f2);
     *plp_flt_coff_a_top-- = 0.5f * (*ppoly_f1++ - *ppoly_f2++);
   }

   return;
 }

 VOID ixheaacd_lpc_to_td(float *coeff, WORD32 order, float *gains, WORD32 lg) {
   FLOAT32 data_r[LEN_SUPERFRAME * 2];
   FLOAT32 data_i[LEN_SUPERFRAME * 2];
   FLOAT64 avg_fac;
   WORD32 idata_r[LEN_SUPERFRAME * 2];
   WORD32 idata_i[LEN_SUPERFRAME * 2];
   WORD8 qshift;
   WORD32 preshift = 0;
   WORD32 itemp;
   FLOAT32 ftemp = 0;
   FLOAT32 tmp, qfac;
   WORD32 i, size_n;

   size_n = 2 * lg;
   avg_fac = PI / (FLOAT32)(size_n);

   for (i = 0; i < order + 1; i++) {
     tmp = (FLOAT32)(((FLOAT32)i) * avg_fac);
     data_r[i] = (FLOAT32)(coeff[i] * cos(tmp));
     data_i[i] = (FLOAT32)(-coeff[i] * sin(tmp));
   }
   for (; i < size_n; i++) {
     data_r[i] = 0.f;
     data_i[i] = 0.f;
   }

   for (i = 0; i < size_n; i++) {
     if (ABS(data_r[i]) > ftemp) ftemp = ABS(data_r[i]);
     if (ABS(data_i[i]) > ftemp) ftemp = ABS(data_i[i]);
   }

   itemp = (WORD32)ftemp;
   qshift = ixheaacd_norm32(itemp);

   for (i = 0; i < size_n; i++) {
     idata_r[i] = (WORD32)(data_r[i] * ((WORD64)1 << qshift));
     idata_i[i] = (WORD32)(data_i[i] * ((WORD64)1 << qshift));
   }

   ixheaacd_complex_fft(idata_r, idata_i, size_n, -1, &preshift);

   qfac = 1.0f / ((FLOAT32)((WORD64)1 << (qshift - preshift)));

   for (i = 0; i < size_n; i++) {
     data_r[i] = (FLOAT32)((FLOAT32)idata_r[i] * qfac);
     data_i[i] = (FLOAT32)((FLOAT32)idata_i[i] * qfac);
   }

   for (i = 0; i < size_n / 2; i++) {
     gains[i] =
         (FLOAT32)(1.0f / sqrt(data_r[i] * data_r[i] + data_i[i] * data_i[i]));
   }

   return;
 }

 VOID ixheaacd_noise_shaping(FLOAT32 r[], WORD32 lg, WORD32 M, FLOAT32 g1[],
                             FLOAT32 g2[]) {
   WORD32 i, k;
   FLOAT32 rr_prev, a = 0, b = 0;
   FLOAT32 rr[1024];

   k = lg / M;

   rr_prev = 0;

   memcpy(&rr, r, lg * sizeof(FLOAT32));

   for (i = 0; i < lg; i++) {
     if ((i % k) == 0) {
       a = 2.0f * g1[i / k] * g2[i / k] / (g1[i / k] + g2[i / k]);
       b = (g2[i / k] - g1[i / k]) / (g1[i / k] + g2[i / k]);
     }

     rr[i] = a * rr[i] + b * rr_prev;
     rr_prev = rr[i];
   }

   for (i = 0; i < lg / 2; i++) {
     r[i] = rr[2 * i];
     r[lg / 2 + i] = rr[lg - 2 * i - 1];
   }
   return;
 }

 VOID ixheaacd_lpc_coef_gen(FLOAT32 lsf_old[], FLOAT32 lsf_new[], FLOAT32 a[],
                            WORD32 nb_subfr, WORD32 m) {
   FLOAT32 lsf[ORDER], *ptr_a;
   FLOAT32 inc, fnew, fold;
   WORD32 i;

   ptr_a = a;

   inc = 1.0f / (FLOAT32)nb_subfr;
   fnew = 0.5f - (0.5f * inc);
   fold = 1.0f - fnew;

   for (i = 0; i < m; i++) {
     lsf[i] = (lsf_old[i] * fold) + (lsf_new[i] * fnew);
   }
   ixheaacd_lsp_to_lp_conversion(lsf, ptr_a);
   ptr_a += (m + 1);
   ixheaacd_lsp_to_lp_conversion(lsf_old, ptr_a);
   ptr_a += (m + 1);
   ixheaacd_lsp_to_lp_conversion(lsf_new, ptr_a);
   ptr_a += (m + 1);

   return;
 }

 VOID ixheaacd_interpolation_lsp_params(FLOAT32 lsp_old[], FLOAT32 lsp_new[],
                                        FLOAT32 lp_flt_coff_a[],
                                        WORD32 nb_subfr) {
   FLOAT32 lsp[ORDER];
   FLOAT32 factor;
   WORD32 i, k;
   FLOAT32 x_plus_y, x_minus_y;

   factor = 1.0f / (FLOAT32)nb_subfr;

   x_plus_y = 0.5f * factor;

   for (k = 0; k < nb_subfr; k++) {
     x_minus_y = 1.0f - x_plus_y;
     for (i = 0; i < ORDER; i++) {
       lsp[i] = (lsp_old[i] * x_minus_y) + (lsp_new[i] * x_plus_y);
     }
     x_plus_y += factor;

     ixheaacd_lsp_to_lp_conversion(lsp, lp_flt_coff_a);

     lp_flt_coff_a += (ORDER + 1);
   }

   ixheaacd_lsp_to_lp_conversion(lsp_new, lp_flt_coff_a);

   return;
 }
	/******************************************************************************
	* *
	* Copyright (C) 2018 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at:
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*****************************************************************************
	* Originally developed and contributed by Ittiam Systems Pvt. Ltd, Bangalore
	*/
	#include <float.h>
	#include <stdlib.h>
	#include <stdio.h>
	#include <math.h>
	#include <string.h>

	#include "ixheaacd_cnst.h"
	#include <ixheaacd_type_def.h>
	#include "ixheaacd_bitbuffer.h"
	#include "ixheaacd_acelp_com.h"

	#include <ixheaacd_type_def.h>
	#include "ixheaacd_bitbuffer.h"
	#include "ixheaacd_interface.h"

	#include "ixheaacd_tns_usac.h"
	#include "ixheaacd_cnst.h"

	#include "ixheaacd_acelp_info.h"

	#include "ixheaacd_td_mdct.h"

	#include "ixheaacd_sbrdecsettings.h"
	#include "ixheaacd_info.h"
	#include "ixheaacd_sbr_common.h"
	#include "ixheaacd_drc_data_struct.h"
	#include "ixheaacd_drc_dec.h"
	#include "ixheaacd_sbrdecoder.h"
	#include "ixheaacd_mps_polyphase.h"
	#include "ixheaacd_sbr_const.h"

	#include "ixheaacd_constants.h"
	#include <ixheaacd_basic_ops32.h>
	#include <ixheaacd_basic_ops40.h>
	#include "ixheaacd_main.h"
	#include "ixheaacd_arith_dec.h"

	#define FREQ_MAX 6400.0f

	#define ABS(A) ((A) < 0 ? (-A) : (A))

	static VOID ixheaacd_compute_coeff_poly_f(FLOAT32 lsp[], FLOAT32 *f1,
	FLOAT32 *f2) {
	FLOAT32 b1, b2;
	FLOAT32 *ptr_lsp;
	WORD32 i, j;

	ptr_lsp = lsp;
	f1[0] = f2[0] = 1.0f;

	for (i = 1; i <= ORDER_BY_2; i++) {
	b1 = -2.0f * (*ptr_lsp++);
	b2 = -2.0f * (*ptr_lsp++);
	f1[i] = (b1 * f1[i - 1]) + (2.0f * f1[i - 2]);
	f2[i] = (b2 * f2[i - 1]) + (2.0f * f2[i - 2]);
	for (j = i - 1; j > 0; j--) {
	f1[j] += (b1 * f1[j - 1]) + f1[j - 2];
	f2[j] += (b2 * f2[j - 1]) + f2[j - 2];
	}
	}

	return;
	}
	VOID ixheaacd_lsp_to_lp_conversion(FLOAT32 lsp, FLOAT32 lp_flt_coff_a) {
	WORD32 i;
	FLOAT32 ppoly_f1, ppoly_f2;
	FLOAT32 plp_flt_coff_a_bott, plp_flt_coff_a_top;
	FLOAT32 poly1[ORDER_BY_2 + 2], poly2[ORDER_BY_2 + 2];

	poly1[0] = 0.0f;
	poly2[0] = 0.0f;

	ixheaacd_compute_coeff_poly_f(lsp, &poly1[1], &poly2[1]);

	ppoly_f1 = poly1 + ORDER_BY_2 + 1;
	ppoly_f2 = poly2 + ORDER_BY_2 + 1;

	for (i = 0; i < ORDER_BY_2; i++) {
	ppoly_f1[0] += ppoly_f1[-1];
	ppoly_f2[0] -= ppoly_f2[-1];
	ppoly_f1--;
	ppoly_f2--;
	}

	plp_flt_coff_a_bott = lp_flt_coff_a;
	*plp_flt_coff_a_bott++ = 1.0f;
	plp_flt_coff_a_top = lp_flt_coff_a + ORDER;
	ppoly_f1 = poly1 + 2;
	ppoly_f2 = poly2 + 2;
	for (i = 0; i < ORDER_BY_2; i++) {
	plp_flt_coff_a_bott++ = 0.5f (ppoly_f1 + ppoly_f2);
	plp_flt_coff_a_top-- = 0.5f (ppoly_f1++ - ppoly_f2++);
	}

	return;
	}

	VOID ixheaacd_lpc_to_td(float coeff, WORD32 order, float gains, WORD32 lg) {
	FLOAT32 data_r[LEN_SUPERFRAME * 2];
	FLOAT32 data_i[LEN_SUPERFRAME * 2];
	FLOAT64 avg_fac;
	WORD32 idata_r[LEN_SUPERFRAME * 2];
	WORD32 idata_i[LEN_SUPERFRAME * 2];
	WORD8 qshift;
	WORD32 preshift = 0;
	WORD32 itemp;
	FLOAT32 ftemp = 0;
	FLOAT32 tmp, qfac;
	WORD32 i, size_n;

	size_n = 2 * lg;
	avg_fac = PI / (FLOAT32)(size_n);

	for (i = 0; i < order + 1; i++) {
	tmp = (FLOAT32)(((FLOAT32)i) * avg_fac);
	data_r[i] = (FLOAT32)(coeff[i] * cos(tmp));
	data_i[i] = (FLOAT32)(-coeff[i] * sin(tmp));
	}
	for (; i < size_n; i++) {
	data_r[i] = 0.f;
	data_i[i] = 0.f;
	}

	for (i = 0; i < size_n; i++) {
	if (ABS(data_r[i]) > ftemp) ftemp = ABS(data_r[i]);
	if (ABS(data_i[i]) > ftemp) ftemp = ABS(data_i[i]);
	}

	itemp = (WORD32)ftemp;
	qshift = ixheaacd_norm32(itemp);

	for (i = 0; i < size_n; i++) {
	idata_r[i] = (WORD32)(data_r[i] * ((WORD64)1 << qshift));
	idata_i[i] = (WORD32)(data_i[i] * ((WORD64)1 << qshift));
	}

	ixheaacd_complex_fft(idata_r, idata_i, size_n, -1, &preshift);

	qfac = 1.0f / ((FLOAT32)((WORD64)1 << (qshift - preshift)));

	for (i = 0; i < size_n; i++) {
	data_r[i] = (FLOAT32)((FLOAT32)idata_r[i] * qfac);
	data_i[i] = (FLOAT32)((FLOAT32)idata_i[i] * qfac);
	}

	for (i = 0; i < size_n / 2; i++) {
	gains[i] =
	(FLOAT32)(1.0f / sqrt(data_r[i] * data_r[i] + data_i[i] * data_i[i]));
	}

	return;
	}

	VOID ixheaacd_noise_shaping(FLOAT32 r[], WORD32 lg, WORD32 M, FLOAT32 g1[],
	FLOAT32 g2[]) {
	WORD32 i, k;
	FLOAT32 rr_prev, a = 0, b = 0;
	FLOAT32 rr[1024];

	k = lg / M;

	rr_prev = 0;

	memcpy(&rr, r, lg * sizeof(FLOAT32));

	for (i = 0; i < lg; i++) {
	if ((i % k) == 0) {
	a = 2.0f * g1[i / k] * g2[i / k] / (g1[i / k] + g2[i / k]);
	b = (g2[i / k] - g1[i / k]) / (g1[i / k] + g2[i / k]);
	}

	rr[i] = a * rr[i] + b * rr_prev;
	rr_prev = rr[i];
	}

	for (i = 0; i < lg / 2; i++) {
	r[i] = rr[2 * i];
	r[lg / 2 + i] = rr[lg - 2 * i - 1];
	}
	return;
	}

	VOID ixheaacd_lpc_coef_gen(FLOAT32 lsf_old[], FLOAT32 lsf_new[], FLOAT32 a[],
	WORD32 nb_subfr, WORD32 m) {
	FLOAT32 lsf[ORDER], *ptr_a;
	FLOAT32 inc, fnew, fold;
	WORD32 i;

	ptr_a = a;

	inc = 1.0f / (FLOAT32)nb_subfr;
	fnew = 0.5f - (0.5f * inc);
	fold = 1.0f - fnew;

	for (i = 0; i < m; i++) {
	lsf[i] = (lsf_old[i] * fold) + (lsf_new[i] * fnew);
	}
	ixheaacd_lsp_to_lp_conversion(lsf, ptr_a);
	ptr_a += (m + 1);
	ixheaacd_lsp_to_lp_conversion(lsf_old, ptr_a);
	ptr_a += (m + 1);
	ixheaacd_lsp_to_lp_conversion(lsf_new, ptr_a);
	ptr_a += (m + 1);

	return;
	}

	VOID ixheaacd_interpolation_lsp_params(FLOAT32 lsp_old[], FLOAT32 lsp_new[],
	FLOAT32 lp_flt_coff_a[],
	WORD32 nb_subfr) {
	FLOAT32 lsp[ORDER];
	FLOAT32 factor;
	WORD32 i, k;
	FLOAT32 x_plus_y, x_minus_y;

	factor = 1.0f / (FLOAT32)nb_subfr;

	x_plus_y = 0.5f * factor;

	for (k = 0; k < nb_subfr; k++) {
	x_minus_y = 1.0f - x_plus_y;
	for (i = 0; i < ORDER; i++) {
	lsp[i] = (lsp_old[i] * x_minus_y) + (lsp_new[i] * x_plus_y);
	}
	x_plus_y += factor;

	ixheaacd_lsp_to_lp_conversion(lsp, lp_flt_coff_a);

	lp_flt_coff_a += (ORDER + 1);
	}

	ixheaacd_lsp_to_lp_conversion(lsp_new, lp_flt_coff_a);

	return;
	}