av/media/libstagefright/codecs/amrwbenc/src/syn_filt.c - nest-cam/4320010/av - Git at Google

 /*
  ** Copyright 2003-2010, VisualOn, Inc.
  **
  ** 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.
  */

 /***********************************************************************
 *       File: syn_filt.c                                               *
 *                                                                      *
 *       Description: Do the synthesis filtering 1/A(z)                 *
 *                                                                      *
 ************************************************************************/

 #include "typedef.h"
 #include "basic_op.h"
 #include "math_op.h"
 #include "cnst.h"

 #define UNUSED(x) (void)(x)

 void Syn_filt(
         Word16 a[],                           /* (i) Q12 : a[m+1] prediction coefficients           */
         Word16 x[],                           /* (i)     : input signal                             */
         Word16 y[],                           /* (o)     : output signal                            */
         Word16 lg,                            /* (i)     : size of filtering                        */
         Word16 mem[],                         /* (i/o)   : memory associated with this filtering.   */
         Word16 update                         /* (i)     : 0=no update, 1=update of memory.         */
          )
 {
     Word32 i, a0;
     Word16 y_buf[L_SUBFR16k + M16k];
     Word32 L_tmp;
     Word16 *yy, *p1, *p2;
     yy = &y_buf[0];
     /* copy initial filter states into synthesis buffer */
     for (i = 0; i < 16; i++)
     {
         *yy++ = mem[i];
     }
     a0 = (a[0] >> 1);                     /* input / 2 */
     /* Do the filtering. */
     for (i = 0; i < lg; i++)
     {
         p1 = &a[1];
         p2 = &yy[i-1];
         L_tmp  = vo_mult32(a0, x[i]);
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1++), (*p2--));
         L_tmp -= vo_mult32((*p1), (*p2));

         L_tmp = L_shl2(L_tmp, 4);
         y[i] = yy[i] = extract_h(L_add(L_tmp, 0x8000));
     }
     /* Update memory if required */
     if (update)
         for (i = 0; i < 16; i++)
         {
             mem[i] = yy[lg - 16 + i];
         }
     return;
 }


 void Syn_filt_32(
         Word16 a[],                           /* (i) Q12 : a[m+1] prediction coefficients */
         Word16 m,                             /* (i)     : order of LP filter             */
         Word16 exc[],                         /* (i) Qnew: excitation (exc[i] >> Qnew)    */
         Word16 Qnew,                          /* (i)     : exc scaling = 0(min) to 8(max) */
         Word16 sig_hi[],                      /* (o) /16 : synthesis high                 */
         Word16 sig_lo[],                      /* (o) /16 : synthesis low                  */
         Word16 lg                             /* (i)     : size of filtering              */
         )
 {
     Word32 i,a0;
     Word32 L_tmp, L_tmp1;
     Word16 *p1, *p2, *p3;
         UNUSED(m);

     a0 = a[0] >> (4 + Qnew);          /* input / 16 and >>Qnew */
     /* Do the filtering. */
     for (i = 0; i < lg; i++)
     {
         L_tmp  = 0;
         L_tmp1 = 0;
         p1 = a;
         p2 = &sig_lo[i - 1];
         p3 = &sig_hi[i - 1];

         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));
         L_tmp  -= vo_mult32((*p2--), (*p1));
         L_tmp1 -= vo_mult32((*p3--), (*p1++));

         L_tmp = L_tmp >> 11;
         L_tmp += vo_L_mult(exc[i], a0);

         /* sig_hi = bit16 to bit31 of synthesis */
         L_tmp = L_tmp - (L_tmp1<<1);

         L_tmp = L_tmp >> 3;           /* ai in Q12 */
         sig_hi[i] = extract_h(L_tmp);

         /* sig_lo = bit4 to bit15 of synthesis */
         L_tmp >>= 4;           /* 4 : sig_lo[i] >> 4 */
         sig_lo[i] = (Word16)((L_tmp - (sig_hi[i] << 13)));
     }

     return;
 }
	/*
	** Copyright 2003-2010, VisualOn, Inc.
	**
	** 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.
	*/

	/***********************************************************************
	* File: syn_filt.c *
	* *
	* Description: Do the synthesis filtering 1/A(z) *
	* *
	************************************************************************/

	#include "typedef.h"
	#include "basic_op.h"
	#include "math_op.h"
	#include "cnst.h"

	#define UNUSED(x) (void)(x)

	void Syn_filt(
	Word16 a[], /* (i) Q12 : a[m+1] prediction coefficients */
	Word16 x[], /* (i) : input signal */
	Word16 y[], /* (o) : output signal */
	Word16 lg, /* (i) : size of filtering */
	Word16 mem[], /* (i/o) : memory associated with this filtering. */
	Word16 update /* (i) : 0=no update, 1=update of memory. */
	)
	{
	Word32 i, a0;
	Word16 y_buf[L_SUBFR16k + M16k];
	Word32 L_tmp;
	Word16 yy, p1, *p2;
	yy = &y_buf[0];
	/* copy initial filter states into synthesis buffer */
	for (i = 0; i < 16; i++)
	{
	*yy++ = mem[i];
	}
	a0 = (a[0] >> 1); /* input / 2 */
	/* Do the filtering. */
	for (i = 0; i < lg; i++)
	{
	p1 = &a[1];
	p2 = &yy[i-1];
	L_tmp = vo_mult32(a0, x[i]);
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1++), (p2--));
	L_tmp -= vo_mult32((p1), (p2));

	L_tmp = L_shl2(L_tmp, 4);
	y[i] = yy[i] = extract_h(L_add(L_tmp, 0x8000));
	}
	/* Update memory if required */
	if (update)
	for (i = 0; i < 16; i++)
	{
	mem[i] = yy[lg - 16 + i];
	}
	return;
	}


	void Syn_filt_32(
	Word16 a[], /* (i) Q12 : a[m+1] prediction coefficients */
	Word16 m, /* (i) : order of LP filter */
	Word16 exc[], /* (i) Qnew: excitation (exc[i] >> Qnew) */
	Word16 Qnew, /* (i) : exc scaling = 0(min) to 8(max) */
	Word16 sig_hi[], /* (o) /16 : synthesis high */
	Word16 sig_lo[], /* (o) /16 : synthesis low */
	Word16 lg /* (i) : size of filtering */
	)
	{
	Word32 i,a0;
	Word32 L_tmp, L_tmp1;
	Word16 p1, p2, *p3;
	UNUSED(m);

	a0 = a[0] >> (4 + Qnew); /* input / 16 and >>Qnew */
	/* Do the filtering. */
	for (i = 0; i < lg; i++)
	{
	L_tmp = 0;
	L_tmp1 = 0;
	p1 = a;
	p2 = &sig_lo[i - 1];
	p3 = &sig_hi[i - 1];

	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));
	L_tmp -= vo_mult32((p2--), (p1));
	L_tmp1 -= vo_mult32((p3--), (p1++));

	L_tmp = L_tmp >> 11;
	L_tmp += vo_L_mult(exc[i], a0);

	/* sig_hi = bit16 to bit31 of synthesis */
	L_tmp = L_tmp - (L_tmp1<<1);

	L_tmp = L_tmp >> 3; /* ai in Q12 */
	sig_hi[i] = extract_h(L_tmp);

	/* sig_lo = bit4 to bit15 of synthesis */
	L_tmp >>= 4; /* 4 : sig_lo[i] >> 4 */
	sig_lo[i] = (Word16)((L_tmp - (sig_hi[i] << 13)));
	}

	return;
	}