pjsip-pjproject/third_party/g7221/decode/dct4_s.c

505 lines
17 KiB
C

/********************************************************************************
**
** ITU-T G.722.1 (2005-05) - Fixed point implementation for main body and Annex C
** > Software Release 2.1 (2008-06)
** (Simple repackaging; no change from 2005-05 Release 2.0 code)
**
** © 2004 Polycom, Inc.
**
** All rights reserved.
**
********************************************************************************/
/********************************************************************************
* Filename: dct_type_iv_s.c
*
* Purpose: Discrete Cosine Transform, Type IV used for inverse MLT
*
* The basis functions are
*
* cos(PI*(t+0.5)*(k+0.5)/block_length)
*
* for time t and basis function number k. Due to the symmetry of the expression
* in t and k, it is clear that the forward and inverse transforms are the same.
*
*********************************************************************************/
/***************************************************************************
Include files
***************************************************************************/
#include "defs.h"
#include "count.h"
#include "dct4_s.h"
/***************************************************************************
External variable declarations
***************************************************************************/
extern Word16 syn_bias_7khz[DCT_LENGTH];
extern Word16 dither[DCT_LENGTH];
extern Word16 max_dither[MAX_DCT_LENGTH];
extern Word16 dct_core_s[DCT_LENGTH_DIV_32][DCT_LENGTH_DIV_32];
extern cos_msin_t s_cos_msin_2[DCT_LENGTH_DIV_32];
extern cos_msin_t s_cos_msin_4[DCT_LENGTH_DIV_16];
extern cos_msin_t s_cos_msin_8[DCT_LENGTH_DIV_8];
extern cos_msin_t s_cos_msin_16[DCT_LENGTH_DIV_4];
extern cos_msin_t s_cos_msin_32[DCT_LENGTH_DIV_2];
extern cos_msin_t s_cos_msin_64[DCT_LENGTH];
extern cos_msin_t *s_cos_msin_table[];
/********************************************************************************
Function: dct_type_iv_s
Syntax: void dct_type_iv_s (Word16 *input,Word16 *output,Word16 dct_length)
Description: Discrete Cosine Transform, Type IV used for inverse MLT
Design Notes:
WMOPS: 7kHz | 24kbit | 32kbit
-------|--------------|----------------
AVG | 1.74 | 1.74
-------|--------------|----------------
MAX | 1.74 | 1.74
-------|--------------|----------------
14kHz | 24kbit | 32kbit | 48kbit
-------|--------------|----------------|----------------
AVG | 3.62 | 3.62 | 3.62
-------|--------------|----------------|----------------
MAX | 3.62 | 3.62 | 3.62
-------|--------------|----------------|----------------
********************************************************************************/
void dct_type_iv_s (Word16 *input,Word16 *output,Word16 dct_length)
{
Word16 buffer_a[MAX_DCT_LENGTH], buffer_b[MAX_DCT_LENGTH], buffer_c[MAX_DCT_LENGTH];
Word16 *in_ptr, *in_ptr_low, *in_ptr_high, *next_in_base;
Word16 *out_ptr_low, *out_ptr_high, *next_out_base;
Word16 *out_buffer, *in_buffer, *buffer_swap;
Word16 in_val_low, in_val_high;
Word16 out_val_low, out_val_high;
Word16 in_low_even, in_low_odd;
Word16 in_high_even, in_high_odd;
Word16 out_low_even, out_low_odd;
Word16 out_high_even, out_high_odd;
Word16 *pair_ptr;
Word16 cos_even, cos_odd, msin_even, msin_odd;
Word16 set_span, set_count, set_count_log, pairs_left, sets_left;
Word16 i,k;
Word16 index;
Word16 dummy;
Word32 sum;
cos_msin_t **table_ptr_ptr, *cos_msin_ptr;
Word32 acca;
Word16 temp;
Word16 dct_length_log;
Word16 *dither_ptr;
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
/* Do the sum/difference butterflies, the first part of */
/* converting one N-point transform into 32 - 10 point transforms */
/* transforms, where N = 1 << DCT_LENGTH_LOG. */
/*++++++++++++++++++++++++++++++++++++++++++++++++++++++*/
test();
if (dct_length==DCT_LENGTH)
{
dct_length_log = DCT_LENGTH_LOG;
move16();
dither_ptr = dither;
move16();
}
else
{
dct_length_log = MAX_DCT_LENGTH_LOG;
move16();
dither_ptr = max_dither;
move16();
}
in_buffer = input;
move16();
out_buffer = buffer_a;
move16();
index=0;
move16();
i=0;
move16();
for (set_count_log = 0; set_count_log <= dct_length_log - 2; set_count_log++)
{
/*===========================================================*/
/* Initialization for the loop over sets at the current size */
/*===========================================================*/
/* set_span = 1 << (DCT_LENGTH_LOG - set_count_log); */
set_span = shr_nocheck(dct_length,set_count_log);
set_count = shl_nocheck(1,set_count_log);
in_ptr = in_buffer;
move16();
next_out_base = out_buffer;
move16();
/*=====================================*/
/* Loop over all the sets of this size */
/*=====================================*/
temp = sub(index,1);
test();
if(temp < 0)
{
for (sets_left = set_count;sets_left > 0;sets_left--)
{
/*||||||||||||||||||||||||||||||||||||||||||||*/
/* Set up output pointers for the current set */
/*||||||||||||||||||||||||||||||||||||||||||||*/
/* pointer arithmetic */
out_ptr_low = next_out_base;
move16();
next_out_base += set_span;
move16();
out_ptr_high = next_out_base;
move16();
/*||||||||||||||||||||||||||||||||||||||||||||||||||*/
/* Loop over all the butterflies in the current set */
/*||||||||||||||||||||||||||||||||||||||||||||||||||*/
do
{
in_val_low = *in_ptr++;
move16();
in_val_high = *in_ptr++;
move16();
/* BEST METHOD OF GETTING RID OF BIAS, BUT COMPUTATIONALLY UNPLEASANT */
/* ALTERNATIVE METHOD, SMEARS BIAS OVER THE ENTIRE FRAME, COMPUTATIONALLY SIMPLEST. */
/* IF THIS WORKS, IT'S PREFERABLE */
dummy = add(in_val_low,dither_ptr[i++]);
// blp: addition of two 16bits vars, there's no way
// they'll overflow a 32bit var
//acca = L_add(dummy,in_val_high);
acca = dummy + in_val_high;
out_val_low = extract_l(L_shr_nocheck(acca,1));
dummy = add(in_val_low,dither_ptr[i++]);
// blp: addition of two 16bits vars, there's no way
// they'll overflow a 32bit var
//acca = L_add(dummy,-in_val_high);
acca = dummy - in_val_high;
out_val_high = extract_l(L_shr_nocheck(acca,1));
*out_ptr_low++ = out_val_low;
move16();
*--out_ptr_high = out_val_high;
move16();
test();
/* this involves comparison of pointers */
/* pointer arithmetic */
} while (out_ptr_low < out_ptr_high);
} /* End of loop over sets of the current size */
}
else
{
for (sets_left = set_count; sets_left > 0; sets_left--)
{
/*||||||||||||||||||||||||||||||||||||||||||||*/
/* Set up output pointers for the current set */
/*||||||||||||||||||||||||||||||||||||||||||||*/
out_ptr_low = next_out_base;
move16();
next_out_base += set_span;
move16();
out_ptr_high = next_out_base;
move16();
/*||||||||||||||||||||||||||||||||||||||||||||||||||*/
/* Loop over all the butterflies in the current set */
/*||||||||||||||||||||||||||||||||||||||||||||||||||*/
do
{
in_val_low = *in_ptr++;
move16();
in_val_high = *in_ptr++;
move16();
out_val_low = add(in_val_low,in_val_high);
out_val_high = add(in_val_low,negate(in_val_high));
*out_ptr_low++ = out_val_low;
move16();
*--out_ptr_high = out_val_high;
move16();
test();
} while (out_ptr_low < out_ptr_high);
} /* End of loop over sets of the current size */
}
/*============================================================*/
/* Decide which buffers to use as input and output next time. */
/* Except for the first time (when the input buffer is the */
/* subroutine input) we just alternate the local buffers. */
/*============================================================*/
in_buffer = out_buffer;
move16();
test();
if (out_buffer == buffer_a)
{
out_buffer = buffer_b;
move16();
}
else
{
out_buffer = buffer_a;
move16();
}
index = add(index,1);
} /* End of loop over set sizes */
/*++++++++++++++++++++++++++++++++*/
/* Do 32 - 10 point transforms */
/*++++++++++++++++++++++++++++++++*/
pair_ptr = in_buffer;
move16();
buffer_swap = buffer_c;
move16();
for (pairs_left = 1 << (dct_length_log - 1); pairs_left > 0; pairs_left--)
{
for ( k=0; k<CORE_SIZE; k++ )
{
#if PJ_HAS_INT64
/* blp: danger danger! not really compatible but faster */
pj_int64_t sum64=0;
move32();
for ( i=0; i<CORE_SIZE; i++ )
{
sum64 += L_mult(pair_ptr[i], dct_core_s[i][k]);
}
sum = L_saturate(sum64);
#else
sum=0L;
move32();
for ( i=0; i<CORE_SIZE; i++ )
{
sum = L_mac(sum, pair_ptr[i],dct_core_s[i][k]);
}
#endif
buffer_swap[k] = itu_round(sum);
}
pair_ptr += CORE_SIZE;
move16();
buffer_swap += CORE_SIZE;
move16();
}
for (i=0;i<dct_length;i++)
{
in_buffer[i] = buffer_c[i];
move16();
}
table_ptr_ptr = s_cos_msin_table;
move16();
/*++++++++++++++++++++++++++++++*/
/* Perform rotation butterflies */
/*++++++++++++++++++++++++++++++*/
index=0;
move16();
for (set_count_log = dct_length_log - 2 ; set_count_log >= 0; set_count_log--)
{
/*===========================================================*/
/* Initialization for the loop over sets at the current size */
/*===========================================================*/
/* set_span = 1 << (DCT_LENGTH_LOG - set_count_log); */
set_span = shr_nocheck(dct_length,set_count_log);
set_count = shl_nocheck(1,set_count_log);
next_in_base = in_buffer;
move16();
test();
if (set_count_log == 0)
{
next_out_base = output;
move16();
}
else
{
next_out_base = out_buffer;
move16();
}
/*=====================================*/
/* Loop over all the sets of this size */
/*=====================================*/
for (sets_left = set_count; sets_left > 0; sets_left--)
{
/*|||||||||||||||||||||||||||||||||||||||||*/
/* Set up the pointers for the current set */
/*|||||||||||||||||||||||||||||||||||||||||*/
in_ptr_low = next_in_base;
move16();
temp = shr_nocheck(set_span,1);
in_ptr_high = in_ptr_low + temp;
move16();
next_in_base += set_span;
move16();
out_ptr_low = next_out_base;
move16();
next_out_base += set_span;
move16();
out_ptr_high = next_out_base;
move16();
cos_msin_ptr = *table_ptr_ptr;
move16();
/*||||||||||||||||||||||||||||||||||||||||||||||||||||||*/
/* Loop over all the butterfly pairs in the current set */
/*||||||||||||||||||||||||||||||||||||||||||||||||||||||*/
do
{
in_low_even = *in_ptr_low++;
move16();
in_low_odd = *in_ptr_low++;
move16();
in_high_even = *in_ptr_high++;
move16();
in_high_odd = *in_ptr_high++;
move16();
cos_even = cos_msin_ptr[0].cosine;
move16();
msin_even = cos_msin_ptr[0].minus_sine;
move16();
cos_odd = cos_msin_ptr[1].cosine;
move16();
msin_odd = cos_msin_ptr[1].minus_sine;
move16();
cos_msin_ptr += 2;
sum = 0L;
move32();
sum = L_mac(sum,cos_even,in_low_even);
sum = L_mac(sum,negate(msin_even),in_high_even);
out_low_even = itu_round(L_shl_nocheck(sum,1));
sum = 0L;
move32();
sum = L_mac(sum,msin_even,in_low_even);
sum = L_mac(sum,cos_even,in_high_even);
out_high_even = itu_round(L_shl_nocheck(sum,1));
sum = 0L;
move32();
sum = L_mac(sum,cos_odd,in_low_odd);
sum = L_mac(sum,msin_odd,in_high_odd);
out_low_odd = itu_round(L_shl_nocheck(sum,1));
sum = 0L;
move32();
sum = L_mac(sum,msin_odd,in_low_odd);
sum = L_mac(sum,negate(cos_odd),in_high_odd);
out_high_odd = itu_round(L_shl_nocheck(sum,1));
*out_ptr_low++ = out_low_even;
move16();
*--out_ptr_high = out_high_even;
move16();
*out_ptr_low++ = out_low_odd;
move16();
*--out_ptr_high = out_high_odd;
move16();
test();
} while (out_ptr_low < out_ptr_high);
} /* End of loop over sets of the current size */
/*=============================================*/
/* Swap input and output buffers for next time */
/*=============================================*/
buffer_swap = in_buffer;
move16();
in_buffer = out_buffer;
move16();
out_buffer = buffer_swap;
move16();
index = add(index,1);
table_ptr_ptr++;
}
/*------------------------------------
ADD IN BIAS FOR OUTPUT
-----------------------------------*/
if (dct_length==DCT_LENGTH)
{
for(i=0;i<320;i++)
{
// blp: addition of two 16bits vars, there's no way
// they'll overflow a 32bit var
//sum = L_add(output[i],syn_bias_7khz[i]);
sum = output[i] + syn_bias_7khz[i];
acca = L_sub(sum,32767);
test();
if (acca > 0)
{
sum = 32767L;
move32();
}
// blp: addition of two 16bits vars, there's no way
// they'll overflow 32bit var
//acca = L_add(sum,32768L);
acca = sum + 32768;
test();
if (acca < 0)
{
sum = -32768L;
move32();
}
output[i] = extract_l(sum);
}
}
}