/*
(c) Copyright 1998-2000 - Tord Jansson
======================================
This file is part of the BladeEnc MP3 Encoder, based on
ISO's reference code for MPEG Layer 3 compression, and might
contain smaller or larger sections that are directly taken
from ISO's reference code.
All changes to the ISO reference code herein are either
copyrighted by Tord Jansson (tord.jansson@swipnet.se)
or sublicensed to Tord Jansson by a third party.
BladeEnc is free software; you can redistribute this file
and/or modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
------------ Changes ------------
2000-12-11 Andre Piotrowski
- reformatted
*/
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <assert.h>
#include "common.h"
#include "l3side.h"
#include "loop.h"
#include "huffman.h"
#include "l3bitstream.h"
#include "reservoir.h"
/*
Layer3 bit reservoir:
Described in C.1.5.4.2.2 of the IS
*/
static int ResvSize = 0; /* in bits */
static int ResvMax = 0; /* in bits */
void fixStatic_reservoir (void)
{
ResvSize = 0;
ResvMax = 0;
}
/*
ResvFrameBegin:
Called at the beginning of a frame. Updates the maximum
size of the reservoir, and checks to make sure main_data_begin
was set properly by the formatter
*/
void ResvFrameBegin
(
frame_params *fr_ps,
III_side_info_t *l3_side,
int mean_bits,
int frameLength
)
{
layer *info;
int fullFrameBits, mode_gr;
int expectedResvSize, resvLimit;
info = fr_ps->header;
mode_gr = 2;
resvLimit = 4088; /* main_data_begin has 9 bits in MPEG 1 */
/*
main_data_begin was set by the formatter to the
expected value for the next call -- this should
agree with our reservoir size
*/
expectedResvSize = l3_side->main_data_begin * 8;
/* assert (expectedResvSize == ResvSize); */
fullFrameBits = mean_bits * mode_gr;
/*
determine maximum size of reservoir:
ResvMax + frameLength <= 7680;
limit max size to resvLimit bits because
main_data_begin cannot indicate a
larger value
*/
ResvMax = MIN(MAX (0, 7680-frameLength), resvLimit);
}
/*
ResvMaxBits:
Called at the beginning of each granule to get the max bit
allowance for the current granule based on reservoir size
and perceptual entropy.
*/
int ResvMaxBits
(
frame_params *fr_ps,
III_side_info_t *l3_side,
double *pe,
int mean_bits
)
{
int more_bits, max_bits, add_bits, over_bits;
mean_bits /= fr_ps->stereo;
max_bits = mean_bits;
if (ResvMax != 0)
{
more_bits = (int) (*pe * 3.1 - mean_bits);
if (more_bits > 100)
{
int frac = (ResvSize * 6) / 10;
add_bits = MIN(frac, more_bits);
}
else
add_bits = 0;
over_bits = ResvSize - ((ResvMax * 8) / 10) - add_bits;
if (over_bits > 0)
add_bits += over_bits;
max_bits += add_bits;
}
if (max_bits > 4095)
max_bits = 4095;
return max_bits;
}
/*
ResvAdjust:
Called after a granule's bit allocation. Readjusts the size of
the reservoir to reflect the granule's usage.
*/
void ResvAdjust
(
frame_params *fr_ps,
gr_info *cod_info,
III_side_info_t *l3_side,
int mean_bits
)
{
ResvSize += (mean_bits / fr_ps->stereo) - cod_info->part2_3_length;
}
/*
ResvFrameEnd:
Called after all granules in a frame have been allocated. Makes sure
that the reservoir size is within limits, possibly by adding stuffing
bits. Note that stuffing bits are added by increasing a granule's
part2_3_length. The bitstream formatter will detect this and write the
appropriate stuffing bits to the bitstream.
*/
void ResvFrameEnd
(
frame_params *fr_ps,
III_side_info_t *l3_side,
int mean_bits
)
{
layer *info;
gr_info *cod_info;
int mode_gr, gr, ch, stereo, ancillary_pad, stuffingBits;
int over_bits;
info = fr_ps->header;
stereo = fr_ps->stereo;
mode_gr = 2;
ancillary_pad = 0;
/* just in case mean_bits is odd, this is necessary... */
if ((stereo == 2) && (mean_bits & 1))
ResvSize ++;
stuffingBits = ancillary_pad;
if ((over_bits = ResvSize - ResvMax) > 0)
{
stuffingBits += over_bits;
ResvSize -= over_bits;
}
/* we must be byte aligned */
if ((over_bits = ResvSize % 8) != 0)
{
stuffingBits += over_bits;
ResvSize -= over_bits;
}
if (stuffingBits)
{
/*
plan a: put all into the first granule
This was preferred by someone designing a
real-time decoder...
*/
cod_info = &l3_side->gr[0].ch[0].tt;
if (cod_info->part2_3_length + stuffingBits < 4095)
cod_info->part2_3_length += stuffingBits;
else
{
/* plan b: distribute throughout the granules */
for (gr = 0; gr < mode_gr; gr++)
{
for (ch = 0; ch < stereo; ch++)
{
int extraBits, bitsThisGr;
gr_info *cod_info = &l3_side->gr[gr].ch[ch].tt;
if (stuffingBits == 0)
break;
extraBits = 4095 - cod_info->part2_3_length;
bitsThisGr = (extraBits < stuffingBits) ? extraBits : stuffingBits;
cod_info->part2_3_length += bitsThisGr;
stuffingBits -= bitsThisGr;
}
}
/*
If any stuffing bits remain, we elect to spill them
into ancillary data. The bitstream formatter will do this if
l3side->resvDrain is set
*/
l3_side->resvDrain = stuffingBits;
}
}
}
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