gstreamer/ext/mplex/lpcmstrm_in.cc
Wim Taymans 1496394c0f First stab at porting mplex
Original commit message from CVS:
First stab at porting mplex
2002-10-24 22:37:51 +00:00

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/*
* lpcmstrm_in.c: LPCM Audio strem class members handling scanning and
* buffering raw input stream.
*
* Copyright (C) 2001 Andrew Stevens <andrew.stevens@philips.com>
* Copyright (C) 2000,2001 Brent Byeler for original header-structure
* parsing code.
*
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of version 2 of the GNU General Public License
* as published by the Free Software Foundation.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#include <config.h>
#include <math.h>
#include <stdlib.h>
#include <string.h>
#include "audiostrm.hh"
#include "outputstream.hh"
LPCMStream::LPCMStream (IBitStream & ibs, OutputStream & into):
AudioStream (ibs, into)
{
}
bool LPCMStream::Probe (IBitStream & bs)
{
return true;
}
/*************************************************************************
*
* Reads initial stream parameters and displays feedback banner to users
*
*************************************************************************/
void
LPCMStream::Init (const int stream_num)
{
MuxStream::Init (PRIVATE_STR_1, 1, // Buffer scale
default_buffer_size,
muxinto.vcd_zero_stuffing,
muxinto.buffers_in_audio, muxinto.always_buffers_in_audio);
mjpeg_info ("Scanning for header info: LPCM Audio stream %02x", stream_num);
InitAUbuffer ();
AU_start = bs.bitcount ();
// This is a dummy debug version that simply assumes 48kHz
// two channel 16 bit sample LPCM
samples_per_second = 48000;
channels = 2;
bits_per_sample = 16;
bytes_per_frame =
samples_per_second * channels * bits_per_sample / 8 * ticks_per_frame_90kHz / 90000;
frame_index = 0;
dynamic_range_code = 0x80;
/* Presentation/decoding time-stamping */
access_unit.start = AU_start;
access_unit.length = bytes_per_frame;
access_unit.PTS = static_cast < clockticks > (decoding_order) *
(CLOCKS_per_90Kth_sec * ticks_per_frame_90kHz);
access_unit.DTS = access_unit.PTS;
access_unit.dorder = decoding_order;
decoding_order++;
aunits.append (access_unit);
OutputHdrInfo ();
}
unsigned int
LPCMStream::NominalBitRate ()
{
return samples_per_second * channels * bits_per_sample;
}
void
LPCMStream::FillAUbuffer (unsigned int frames_to_buffer)
{
last_buffered_AU += frames_to_buffer;
mjpeg_debug ("Scanning %d MPEG LPCM audio frames to frame %d",
frames_to_buffer, last_buffered_AU);
static int header_skip = 0; // Initially skipped past 5 bytes of header
int skip;
bool bad_last_frame = false;
while (!bs.eos () &&
decoding_order < last_buffered_AU) {
skip = access_unit.length - header_skip;
mjpeg_debug ("Buffering frame %d (%d bytes)\n", decoding_order - 1, skip);
if (skip & 0x1)
bs.getbits (8);
if (skip & 0x2)
bs.getbits (16);
skip = skip >> 2;
for (int i = 0; i < skip; i++) {
bs.getbits (32);
}
prev_offset = AU_start;
AU_start = bs.bitcount ();
if (AU_start - prev_offset != access_unit.length * 8) {
bad_last_frame = true;
break;
}
// Here we would check for header data but LPCM has no headers...
if (bs.eos ())
break;
access_unit.start = AU_start;
access_unit.length = bytes_per_frame;
access_unit.PTS = static_cast < clockticks > (decoding_order) *
(CLOCKS_per_90Kth_sec * ticks_per_frame_90kHz);
access_unit.DTS = access_unit.PTS;
access_unit.dorder = decoding_order;
decoding_order++;
aunits.append (access_unit);
num_frames[0]++;
num_syncword++;
if (num_syncword >= old_frames + 10) {
mjpeg_debug ("Got %d frame headers.", num_syncword);
old_frames = num_syncword;
}
mjpeg_debug ("Got frame %d\n", decoding_order);
}
if (bad_last_frame) {
mjpeg_error_exit1 ("Last LPCM frame ended prematurely!\n");
}
last_buffered_AU = decoding_order;
eoscan = bs.eos ();
}
void
LPCMStream::Close ()
{
stream_length = AU_start / 8;
mjpeg_info ("AUDIO_STATISTICS: %02x", stream_id);
mjpeg_info ("Audio stream length %lld bytes.", stream_length);
mjpeg_info ("Frames : %8u ", num_frames[0]);
bs.close ();
}
/*************************************************************************
OutputAudioInfo
gibt gesammelte Informationen zu den Audio Access Units aus.
Prints information on audio access units
*************************************************************************/
void
LPCMStream::OutputHdrInfo ()
{
mjpeg_info ("LPCM AUDIO STREAM:");
mjpeg_info ("Bit rate : %8u bytes/sec (%3u kbit/sec)",
NominalBitRate () / 8, NominalBitRate ());
mjpeg_info ("Channels : %d\n", channels);
mjpeg_info ("Bits per sample: %d\n", bits_per_sample);
mjpeg_info ("Frequency : %d Hz", samples_per_second);
}
unsigned int
LPCMStream::ReadPacketPayload (uint8_t * dst, unsigned int to_read)
{
unsigned int header_size = LPCMStream::StreamHeaderSize ();
unsigned int bytes_read = bs.read_buffered_bytes (dst + header_size,
to_read - header_size);
clockticks decode_time;
bool starting_frame_found = false;
uint8_t starting_frame_index = 0;
int starting_frame_offset = (new_au_next_sec || au_unsent > bytes_read)
? 0 : au_unsent;
unsigned int frames = 0;
unsigned int bytes_muxed = bytes_read;
if (bytes_muxed == 0 || MuxCompleted ()) {
goto completion;
}
/* Work through what's left of the current frames and the
following frames's updating the info until we reach a point where
an frame had to be split between packets.
The DTS/PTS field for the packet in this case would have been
given the that for the first AU to start in the packet.
*/
decode_time = RequiredDTS ();
while (au_unsent < bytes_muxed) {
assert (bytes_muxed > 1);
bufmodel.Queued (au_unsent, decode_time);
bytes_muxed -= au_unsent;
if (new_au_next_sec) {
++frames;
if (!starting_frame_found) {
starting_frame_index = static_cast < uint8_t > (au->dorder % 20);
starting_frame_found = true;
}
}
if (!NextAU ()) {
goto completion;
}
new_au_next_sec = true;
decode_time = RequiredDTS ();
};
// We've now reached a point where the current AU overran or
// fitted exactly. We need to distinguish the latter case so we
// can record whether the next packet starts with the tail end of
// // an already started frame or a new one. We need this info to
// decide what PTS/DTS info to write at the start of the next
// packet.
if (au_unsent > bytes_muxed) {
if (new_au_next_sec)
++frames;
bufmodel.Queued (bytes_muxed, decode_time);
au_unsent -= bytes_muxed;
new_au_next_sec = false;
} else // if (au_unsent == bytes_muxed)
{
bufmodel.Queued (bytes_muxed, decode_time);
if (new_au_next_sec)
++frames;
new_au_next_sec = NextAU ();
}
completion:
// Generate the LPCM header...
// Note the index counts from the low byte of the offset so
// the smallest value is 1!
dst[0] = LPCM_SUB_STR_0 + stream_num;
dst[1] = frames;
dst[2] = (starting_frame_offset + 1) >> 8;
dst[3] = (starting_frame_offset + 1) & 0xff;
unsigned int bps_code;
switch (bits_per_sample) {
case 16:
bps_code = 0;
break;
case 20:
bps_code = 1;
break;
case 24:
bps_code = 2;
break;
default:
bps_code = 3;
break;
}
dst[4] = starting_frame_index;
unsigned int bsf_code = (samples_per_second == 48000) ? 0 : 1;
unsigned int channels_code = channels - 1;
dst[5] = (bps_code << 6) | (bsf_code << 4) | channels_code;
dst[6] = dynamic_range_code;
return bytes_read + header_size;
}
/*
* Local variables:
* c-file-style: "stroustrup"
* tab-width: 4
* indent-tabs-mode: nil
* End:
*/