file_status_e
avi_reader_c::read_audio(avi_demuxer_t &demuxer) {
AVI_set_audio_track(m_avi, demuxer.m_aid);
while (true) {
int size = AVI_audio_size(m_avi, AVI_get_audio_position_index(m_avi));
if (-1 == size)
return flush_packetizer(demuxer.m_ptzr);
if (!size) {
AVI_set_audio_position_index(m_avi, AVI_get_audio_position_index(m_avi) + 1);
continue;
}
auto chunk = memory_c::alloc(size);
size = AVI_read_audio_chunk(m_avi, reinterpret_cast<char *>(chunk->get_buffer()));
if (0 >= size)
continue;
PTZR(demuxer.m_ptzr)->add_avi_block_size(size);
PTZR(demuxer.m_ptzr)->process(new packet_t(chunk));
m_bytes_processed += size;
return AVI_get_audio_position_index(m_avi) < AVI_max_audio_chunk(m_avi) ? FILE_STATUS_MOREDATA : flush_packetizer(demuxer.m_ptzr);
}
}
file_status_e
avi_reader_c::read_audio(avi_demuxer_t &demuxer) {
AVI_set_audio_track(m_avi, demuxer.m_aid);
while (true) {
int size = AVI_audio_size(m_avi, AVI_get_audio_position_index(m_avi));
// -1 indicates the last chunk.
if (-1 == size)
return flush_packetizer(demuxer.m_ptzr);
// Sanity check. Ignore chunks with obvious wrong size information
// (> 10 MB). Also skip 0-sized blocks. Those are officially
// skipped.
if (!size || (size > AVI_MAX_AUDIO_CHUNK_SIZE)) {
AVI_set_audio_position_index(m_avi, AVI_get_audio_position_index(m_avi) + 1);
continue;
}
auto chunk = memory_c::alloc(size);
size = AVI_read_audio_chunk(m_avi, reinterpret_cast<char *>(chunk->get_buffer()));
if (0 >= size)
continue;
PTZR(demuxer.m_ptzr)->process(new packet_t(chunk));
m_bytes_processed += size;
return AVI_get_audio_position_index(m_avi) < AVI_max_audio_chunk(m_avi) ? FILE_STATUS_MOREDATA : flush_packetizer(demuxer.m_ptzr);
}
}
generic_packetizer_c *
avi_reader_c::create_dts_packetizer(int aid) {
try {
AVI_set_audio_track(m_avi, aid);
long audio_position = AVI_get_audio_position_index(m_avi);
unsigned int num_read = 0;
int dts_position = -1;
byte_buffer_c buffer;
dts_header_t dtsheader;
while ((-1 == dts_position) && (10 > num_read)) {
int chunk_size = AVI_read_audio_chunk(m_avi, nullptr);
if (0 < chunk_size) {
memory_cptr chunk = memory_c::alloc(chunk_size);
AVI_read_audio_chunk(m_avi, reinterpret_cast<char *>(chunk->get_buffer()));
buffer.add(chunk);
dts_position = find_dts_header(buffer.get_buffer(), buffer.get_size(), &dtsheader);
} else {
dts_position = find_dts_header(buffer.get_buffer(), buffer.get_size(), &dtsheader, true);
break;
}
}
if (-1 == dts_position)
throw false;
AVI_set_audio_position_index(m_avi, audio_position);
return new dts_packetizer_c(this, m_ti, dtsheader);
} catch (...) {
mxerror_tid(m_ti.m_fname, aid + 1, Y("Could not find valid DTS headers in this track's first frames.\n"));
return nullptr;
}
}
/* for supported audio formats */
static int AV_synch_avi2avi(AVIData *data,
double vid_ms, double *aud_ms,
avi_t *in, avi_t *out)
{
long bytes = 0;
while (*aud_ms < vid_ms) {
bytes = AVI_read_audio_chunk(in, data->data);
if (bytes < 0) {
AVI_print_error("AVI audio read frame");
return -2;
}
if (out) {
if (AVI_write_audio(out, data->data, bytes) < 0) {
AVI_print_error("AVI write audio frame");
return -1;
}
}
// pass-through null frames (!?)
if (bytes == 0) {
*aud_ms = vid_ms;
break; // !?
}
if (data->vbr
&& tc_get_audio_header(data->data, bytes, data->format,
NULL, NULL, &(data->mp3rate)) < 0) {
// if this is the last frame of the file, slurp in audio chunks
//if (n == frames-1) continue;
*aud_ms = vid_ms;
} else {
if (data->vbr)
data->mp3rate *= 1000;
*aud_ms += (bytes*8.0*1000.0)/(double)data->mp3rate;
}
}
return 0;
}
/* for UNsupported audio formats */
static int AV_synch_avi2avi_raw(AVIData *data,
avi_t *in, avi_t *out)
{
long bytes = 0;
do {
bytes = AVI_read_audio_chunk(in, data->data);
if (bytes < 0) {
AVI_print_error("AVI audio read frame");
return -2;
}
if (out) {
if (AVI_write_audio(out, data->data, bytes) < 0) {
AVI_print_error("AVI write audio frame");
return -1;
}
}
} while (AVI_can_read_audio(in));
return 0;
}
void
avi_reader_c::add_audio_demuxer(int aid) {
for (auto &demuxer : m_audio_demuxers)
if (demuxer.m_aid == aid) // Demuxer already added?
return;
AVI_set_audio_track(m_avi, aid);
if (AVI_read_audio_chunk(m_avi, nullptr) < 0) {
mxwarn(boost::format(Y("Could not find an index for audio track %1% (avilib error message: %2%). Skipping track.\n")) % (aid + 1) % AVI_strerror());
return;
}
avi_demuxer_t demuxer;
generic_packetizer_c *packetizer = nullptr;
alWAVEFORMATEX *wfe = m_avi->wave_format_ex[aid];
uint32_t audio_format = AVI_audio_format(m_avi);
demuxer.m_aid = aid;
demuxer.m_ptzr = -1;
demuxer.m_samples_per_second = AVI_audio_rate(m_avi);
demuxer.m_channels = AVI_audio_channels(m_avi);
demuxer.m_bits_per_sample = AVI_audio_bits(m_avi);
m_ti.m_id = aid + 1; // ID for this audio track.
m_ti.m_avi_block_align = get_uint16_le(&wfe->n_block_align);
m_ti.m_avi_avg_bytes_per_sec = get_uint32_le(&wfe->n_avg_bytes_per_sec);
m_ti.m_avi_samples_per_chunk = get_uint32_le(&m_avi->stream_headers[aid].dw_scale);
m_ti.m_avi_sample_scale = get_uint32_le(&m_avi->stream_headers[aid].dw_rate);
m_ti.m_avi_samples_per_sec = demuxer.m_samples_per_second;
if ((0xfffe == audio_format) && (get_uint16_le(&wfe->cb_size) >= (sizeof(alWAVEFORMATEXTENSION)))) {
alWAVEFORMATEXTENSIBLE *ext = reinterpret_cast<alWAVEFORMATEXTENSIBLE *>(wfe);
audio_format = get_uint32_le(&ext->extension.guid.data1);
} else if (get_uint16_le(&wfe->cb_size) > 0)
m_ti.m_private_data = memory_c::clone(wfe + 1, get_uint16_le(&wfe->cb_size));
else
m_ti.m_private_data.reset();
switch(audio_format) {
case 0x0001: // raw PCM audio
case 0x0003: // raw PCM audio (float)
packetizer = new pcm_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, demuxer.m_bits_per_sample, 0x0003 == audio_format ? pcm_packetizer_c::ieee_float : pcm_packetizer_c::little_endian_integer);
break;
case 0x0050: // MP2
case 0x0055: // MP3
packetizer = new mp3_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, false);
break;
case 0x2000: // AC3
packetizer = new ac3_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, 0);
break;
case 0x2001: // DTS
packetizer = create_dts_packetizer(aid);
break;
case 0x00ff:
case 0x706d: // AAC
packetizer = create_aac_packetizer(aid, demuxer);
break;
case 0x566f: // Vorbis
packetizer = create_vorbis_packetizer(aid);
break;
default:
mxerror_tid(m_ti.m_fname, aid + 1, boost::format(Y("Unknown/unsupported audio format 0x%|1$04x| for this audio track.\n")) % audio_format);
}
show_packetizer_info(aid + 1, packetizer);
demuxer.m_ptzr = add_packetizer(packetizer);
m_audio_demuxers.push_back(demuxer);
int i, maxchunks = AVI_audio_chunks(m_avi);
for (i = 0; i < maxchunks; i++)
m_bytes_to_process += AVI_audio_size(m_avi, i);
}
void
avi_reader_c::add_audio_demuxer(int aid) {
for (auto &demuxer : m_audio_demuxers)
if (demuxer.m_aid == aid) // Demuxer already added?
return;
AVI_set_audio_track(m_avi, aid);
if (AVI_read_audio_chunk(m_avi, nullptr) < 0) {
mxwarn(boost::format(Y("Could not find an index for audio track %1% (avilib error message: %2%). Skipping track.\n")) % (aid + 1) % AVI_strerror());
return;
}
avi_demuxer_t demuxer;
generic_packetizer_c *packetizer = nullptr;
alWAVEFORMATEX *wfe = m_avi->wave_format_ex[aid];
uint32_t audio_format = AVI_audio_format(m_avi);
demuxer.m_aid = aid;
demuxer.m_ptzr = -1;
demuxer.m_samples_per_second = AVI_audio_rate(m_avi);
demuxer.m_channels = AVI_audio_channels(m_avi);
demuxer.m_bits_per_sample = AVI_audio_bits(m_avi);
m_ti.m_id = aid + 1; // ID for this audio track.
auto stream_header = &m_avi->stream_headers[aid];
auto dw_scale = static_cast<int64_t>(get_uint32_le(&stream_header->dw_scale));
auto dw_rate = static_cast<int64_t>(get_uint32_le(&stream_header->dw_rate));
auto dw_sample_size = static_cast<int64_t>(get_uint32_le(&stream_header->dw_sample_size));
m_ti.m_avi_audio_data_rate = dw_scale ? dw_rate * dw_sample_size / dw_scale : 0;
if ((0xfffe == audio_format) && (get_uint16_le(&wfe->cb_size) >= (sizeof(alWAVEFORMATEXTENSION)))) {
alWAVEFORMATEXTENSIBLE *ext = reinterpret_cast<alWAVEFORMATEXTENSIBLE *>(wfe);
audio_format = get_uint32_le(&ext->extension.guid.data1);
} else if (get_uint16_le(&wfe->cb_size) > 0)
m_ti.m_private_data = memory_c::clone(wfe + 1, get_uint16_le(&wfe->cb_size));
else
m_ti.m_private_data.reset();
demuxer.m_codec = codec_c::look_up_audio_format(audio_format);
if (demuxer.m_codec.is(codec_c::type_e::A_PCM))
packetizer = new pcm_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, demuxer.m_bits_per_sample, 0x0003 == audio_format ? pcm_packetizer_c::ieee_float : pcm_packetizer_c::little_endian_integer);
else if (demuxer.m_codec.is(codec_c::type_e::A_MP2) || demuxer.m_codec.is(codec_c::type_e::A_MP3))
packetizer = new mp3_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, false);
else if (demuxer.m_codec.is(codec_c::type_e::A_AC3))
packetizer = new ac3_packetizer_c(this, m_ti, demuxer.m_samples_per_second, demuxer.m_channels, 0);
else if (demuxer.m_codec.is(codec_c::type_e::A_DTS))
packetizer = create_dts_packetizer(aid);
else if (demuxer.m_codec.is(codec_c::type_e::A_AAC))
packetizer = create_aac_packetizer(aid, demuxer);
else if (demuxer.m_codec.is(codec_c::type_e::A_VORBIS))
packetizer = create_vorbis_packetizer(aid);
else
mxerror_tid(m_ti.m_fname, aid + 1, boost::format(Y("Unknown/unsupported audio format 0x%|1$04x| for this audio track.\n")) % audio_format);
packetizer->enable_avi_audio_sync(true);
show_packetizer_info(aid + 1, packetizer);
demuxer.m_ptzr = add_packetizer(packetizer);
m_audio_demuxers.push_back(demuxer);
int i, maxchunks = AVI_audio_chunks(m_avi);
for (i = 0; i < maxchunks; i++) {
auto size = AVI_audio_size(m_avi, i);
if (size < AVI_MAX_AUDIO_CHUNK_SIZE)
m_bytes_to_process += size;
}
}
int main(int argc, char *argv[])
{
avi_t *avifile1=NULL;
avi_t *avifile2=NULL;
avi_t *avifile3=NULL;
char *in_file=NULL, *out_file=NULL;
long frames, bytes;
double fps;
char *codec;
int track_num=0, aud_tracks;
int encode_null=0;
int i, j, n, key, shift=0;
int ch, preload=0;
long rate, mp3rate;
int width, height, format, chan, bits;
int be_quiet = 0;
FILE *status_fd = stderr;
/* for null frame encoding */
char nulls[32000];
long nullbytes=0;
char tmp0[] = "/tmp/nullfile.00.avi"; /* XXX: use mktemp*() */
buffer_list_t *ptr;
double vid_ms = 0.0, shift_ms = 0.0, one_vid_ms = 0.0;
double aud_ms [ AVI_MAX_TRACKS ];
int aud_bitrate = 0;
int aud_chunks = 0;
ac_init(AC_ALL);
if(argc==1) usage(EXIT_FAILURE);
while ((ch = getopt(argc, argv, "a:b:vi:o:n:Nq?h")) != -1)
{
switch (ch) {
case 'i':
if(optarg[0]=='-') usage(EXIT_FAILURE);
in_file=optarg;
break;
case 'a':
if(optarg[0]=='-') usage(EXIT_FAILURE);
track_num = atoi(optarg);
if(track_num<0) usage(EXIT_FAILURE);
break;
case 'b':
if(optarg[0]=='-') usage(EXIT_FAILURE);
is_vbr = atoi(optarg);
if(is_vbr<0) usage(EXIT_FAILURE);
break;
case 'o':
if(optarg[0]=='-') usage(EXIT_FAILURE);
out_file=optarg;
break;
case 'f':
if(optarg[0]=='-') usage(EXIT_FAILURE);
comfile = optarg;
break;
case 'n':
if(sscanf(optarg,"%d", &shift)!=1) {
fprintf(stderr, "invalid parameter for option -n\n");
usage(EXIT_FAILURE);
}
break;
case 'N':
encode_null=1;
break;
case 'q':
be_quiet = 1;
break;
case 'v':
version();
exit(0);
break;
case 'h':
usage(EXIT_SUCCESS);
default:
usage(EXIT_FAILURE);
}
}
// check
if(in_file==NULL || out_file == NULL) usage(EXIT_FAILURE);
if(shift == 0) fprintf(stderr, "no sync requested - exit");
memset (nulls, 0, sizeof(nulls));
// open file
if(NULL == (avifile1 = AVI_open_input_file(in_file,1))) {
AVI_print_error("AVI open");
exit(1);
}
if(strcmp(in_file, out_file)==0) {
printf("error: output filename conflicts with input filename\n");
exit(1);
}
if(NULL == (avifile2 = AVI_open_output_file(out_file))) {
AVI_print_error("AVI open");
exit(1);
}
if (be_quiet) {
if (!(status_fd = fopen("/dev/null", "w"))) {
fprintf(stderr, "Can't open /dev/null\n");
exit(1);
}
}
// read video info;
AVI_info(avifile1);
// read video info;
frames = AVI_video_frames(avifile1);
width = AVI_video_width(avifile1);
height = AVI_video_height(avifile1);
fps = AVI_frame_rate(avifile1);
codec = AVI_video_compressor(avifile1);
//set video in outputfile
AVI_set_video(avifile2, width, height, fps, codec);
if (comfile!=NULL)
AVI_set_comment_fd(avifile2, open(comfile, O_RDONLY));
aud_tracks = AVI_audio_tracks(avifile1);
for(j=0; j<aud_tracks; ++j) {
AVI_set_audio_track(avifile1, j);
rate = AVI_audio_rate(avifile1);
chan = AVI_audio_channels(avifile1);
bits = AVI_audio_bits(avifile1);
format = AVI_audio_format(avifile1);
mp3rate= AVI_audio_mp3rate(avifile1);
//set next track of output file
AVI_set_audio_track(avifile2, j);
AVI_set_audio(avifile2, chan, rate, bits, format, mp3rate);
AVI_set_audio_vbr(avifile2, is_vbr);
}
//switch to requested audio_channel
if(AVI_set_audio_track(avifile1, track_num)<0) {
fprintf(stderr, "invalid auto track\n");
}
AVI_set_audio_track(avifile2, track_num);
if (encode_null) {
char cmd[1024];
rate = AVI_audio_rate(avifile2);
chan = AVI_audio_channels(avifile2);
bits = AVI_audio_bits(avifile2);
format = AVI_audio_format(avifile2);
mp3rate= AVI_audio_mp3rate(avifile2);
if (bits==0) bits=16;
if (mp3rate%2) mp3rate++;
fprintf(status_fd, "Creating silent mp3 frame with current parameter\n");
memset (cmd, 0, sizeof(cmd));
tc_snprintf(cmd, sizeof(cmd), "transcode -i /dev/zero -o %s -x raw,raw"
" -n 0x1 -g 16x16 -y raw,raw -c 0-5 -e %ld,%d,%d -b %ld -q0",
tmp0, rate,bits,chan, mp3rate);
printf(cmd);
system(cmd);
if(NULL == (avifile3 = AVI_open_input_file(tmp0,1))) {
AVI_print_error("AVI open");
exit(1);
}
nullbytes = AVI_audio_size(avifile3, 3);
/* just read a few frames */
if(AVI_read_audio(avifile3, nulls, nullbytes) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
memset (nulls, 0, sizeof(nulls));
if(AVI_read_audio(avifile3, nulls, nullbytes) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
memset (nulls, 0, sizeof(nulls));
if(AVI_read_audio(avifile3, nulls, nullbytes) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
/*
printf("\nBytes (%ld): \n", nullbytes);
{
int asd=0;
for (asd=0; asd<nullbytes; asd++){
printf("%x ",(unsigned char)nulls[asd]);
}
printf("\n");
}
*/
}
vid_ms = 0.0;
shift_ms = 0.0;
for (n=0; n<AVI_MAX_TRACKS; ++n)
aud_ms[n] = 0.0;
// ---------------------------------------------------------------------
for (n=0; n<frames; ++n) {
// video unchanged
bytes = AVI_read_frame(avifile1, data, &key);
if(bytes < 0) {
AVI_print_error("AVI read video frame");
return(-1);
}
if(AVI_write_frame(avifile2, data, bytes, key)<0) {
AVI_print_error("AVI write video frame");
return(-1);
}
vid_ms = (n+1)*1000.0/fps;
// Pass-through all other audio tracks.
for(j=0; j<aud_tracks; ++j) {
// skip track we want to modify
if (j == track_num) continue;
// switch to track
AVI_set_audio_track(avifile1, j);
AVI_set_audio_track(avifile2, j);
sync_audio_video_avi2avi(vid_ms, &aud_ms[j], avifile1, avifile2);
}
//switch to requested audio_channel
if(AVI_set_audio_track(avifile1, track_num)<0) {
fprintf(stderr, "invalid auto track\n");
}
AVI_set_audio_track(avifile2, track_num);
shift_ms = (double)shift*1000.0/fps;
one_vid_ms = 1000.0/fps;
format = AVI_audio_format(avifile1);
rate = AVI_audio_rate(avifile1);
chan = AVI_audio_channels(avifile1);
bits = AVI_audio_bits(avifile1);
bits = bits==0?16:bits;
mp3rate= AVI_audio_mp3rate(avifile1);
if(shift>0) {
// for n < shift, shift audio frames are discarded
if(!preload) {
if (tc_format_ms_supported(format)) {
for(i=0;i<shift;++i) {
//fprintf (stderr, "shift (%d) i (%d) n (%d) a (%d)\n", shift, i, n, aud_chunks);
while (aud_ms[track_num] < vid_ms + one_vid_ms*(double)i) {
aud_bitrate = (format==0x1||format==0x2000)?1:0;
aud_chunks++;
if( (bytes = AVI_read_audio_chunk(avifile1, data)) <= 0) {
aud_ms[track_num] = vid_ms + one_vid_ms*i;
if (bytes == 0) continue;
AVI_print_error("AVI 2 audio read frame");
break;
}
if ( !aud_bitrate && tc_get_audio_header(data, bytes, format, NULL, NULL, &aud_bitrate)<0) {
// if this is the last frame of the file, slurp in audio chunks
if (n == frames-1) continue;
aud_ms[track_num] = vid_ms + one_vid_ms*i;
} else
aud_ms[track_num] += (bytes*8.0)/(format==0x1?((double)(rate*chan*bits)/1000.0):
(format==0x2000?(double)(mp3rate):aud_bitrate));
}
}
} else { // fallback
bytes=0;
for(i=0;i<shift;++i) {
do {
if( (bytes = AVI_read_audio_chunk(avifile1, data)) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
} while (AVI_can_read_audio(avifile1));
}
}
preload=1;
}
// copy rest of the track
if(n<frames-shift) {
if (tc_format_ms_supported(format)) {
while (aud_ms[track_num] < vid_ms + shift_ms) {
aud_chunks++;
aud_bitrate = (format==0x1||format==0x2000)?1:0;
if( (bytes = AVI_read_audio_chunk(avifile1, data)) < 0) {
aud_ms[track_num] = vid_ms + shift_ms;
AVI_print_error("AVI 3 audio read frame");
break;
}
if(AVI_write_audio(avifile2, data, bytes) < 0) {
AVI_print_error("AVI 3 write audio frame");
return(-1);
}
fprintf(status_fd, "V [%05d][%08.2f] | A [%05d][%08.2f] [%05ld]\r", n, vid_ms, aud_chunks, aud_ms[track_num], bytes);
if (bytes == 0) {
aud_ms[track_num] = vid_ms + shift_ms;
continue;
}
if(n>=frames-2*shift) {
// save audio frame for later
ptr = buffer_register(n);
if(ptr==NULL) {
fprintf(stderr,"buffer allocation failed\n");
break;
}
ac_memcpy(ptr->data, data, bytes);
ptr->size = bytes;
ptr->status = BUFFER_READY;
}
if ( !aud_bitrate && tc_get_audio_header(data, bytes, format, NULL, NULL, &aud_bitrate)<0) {
if (n == frames-1) continue;
aud_ms[track_num] = vid_ms + shift_ms;
} else
aud_ms[track_num] += (bytes*8.0)/(format==0x1?((double)(rate*chan*bits)/1000.0):
(format==0x2000?(double)(mp3rate):aud_bitrate));
}
} else { // fallback
bytes = AVI_audio_size(avifile1, n+shift-1);
do {
if( (bytes = AVI_read_audio_chunk(avifile1, data)) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
if(AVI_write_audio(avifile2, data, bytes) < 0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
fprintf(status_fd, "V [%05d] | A [%05d] [%05ld]\r", n, n+shift, bytes);
if(n>=frames-2*shift) {
// save audio frame for later
ptr = buffer_register(n);
if(ptr==NULL) {
fprintf(stderr,"buffer allocation failed\n");
break;
}
ac_memcpy(ptr->data, data, bytes);
ptr->size = bytes;
ptr->status = BUFFER_READY;
}
} while (AVI_can_read_audio(avifile1));
}
}
// padding at the end
if(n>=frames-shift) {
if (!ptrlen) {
ptr = buffer_retrieve();
ac_memcpy (ptrdata, ptr->data, ptr->size);
ptrlen = ptr->size;
}
if (tc_format_ms_supported(format)) {
while (aud_ms[track_num] < vid_ms + shift_ms) {
aud_bitrate = (format==0x1||format==0x2000)?1:0;
// mute this -- check if can mute (valid A header)!
if (tc_probe_audio_header(ptrdata, ptrlen) > 0)
tc_format_mute(ptrdata, ptrlen, format);
if(AVI_write_audio(avifile2, ptrdata, ptrlen) < 0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
fprintf(status_fd, " V [%05d][%08.2f] | A [%05d][%08.2f] [%05ld]\r", n, vid_ms, n+shift, aud_ms[track_num], bytes);
if ( !aud_bitrate && tc_get_audio_header(ptrdata, ptrlen, format, NULL, NULL, &aud_bitrate)<0) {
//if (n == frames-1) continue;
aud_ms[track_num] = vid_ms + shift_ms;
} else
aud_ms[track_num] += (ptrlen*8.0)/(format==0x1?((double)(rate*chan*bits)/1000.0):
(format==0x2000?(double)(mp3rate):aud_bitrate));
}
} else { // fallback
// get next audio frame
ptr = buffer_retrieve();
while (1) {
printf("ptr->id (%d) ptr->size (%d)\n", ptr->id, ptr->size);
if(ptr==NULL) {
fprintf(stderr,"no buffer found\n");
break;
}
if (encode_null) {
if(AVI_write_audio(avifile2, nulls, nullbytes)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
} else {
// simple keep old frames to force exact time delay
if(AVI_write_audio(avifile2, ptr->data, ptr->size)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
}
fprintf(status_fd, "V [%05d] | padding\r", n);
if (ptr->next && ptr->next->id == ptr->id) {
buffer_remove(ptr);
ptr = buffer_retrieve();
continue;
}
buffer_remove(ptr);
break;
} // 1
}
}
// *************************************
// negative shift (pad audio at start)
// *************************************
} else {
if (tc_format_ms_supported(format)) {
/*
fprintf(status_fd, "n(%d) -shift(%d) shift_ms (%.2lf) vid_ms(%.2lf) aud_ms[%d](%.2lf) v-s(%.2lf)\n",
n, -shift, shift_ms, vid_ms, track_num, aud_ms[track_num], vid_ms + shift_ms);
*/
// shift<0 -> shift_ms<0 !
while (aud_ms[track_num] < vid_ms) {
/*
fprintf(stderr, " 1 (%02d) %s frame_read len=%4ld (A/V) (%8.2f/%8.2f)\n",
n, format==0x55?"MP3":"AC3", bytes, aud_ms[track_num], vid_ms);
*/
aud_bitrate = (format==0x1||format==0x2000)?1:0;
if( (bytes = AVI_read_audio_chunk(avifile1, data)) < 0) {
AVI_print_error("AVI 2 audio read frame");
aud_ms[track_num] = vid_ms;
break;
//return(-1);
}
// save audio frame for later
ptr = buffer_register(n);
if(ptr==NULL) {
fprintf(stderr,"buffer allocation failed\n");
break;
}
ac_memcpy(ptr->data, data, bytes);
ptr->size = bytes;
ptr->status = BUFFER_READY;
if(n<-shift) {
// mute this -- check if can mute!
if (tc_probe_audio_header(data, bytes) > 0)
tc_format_mute(data, bytes, format);
// simple keep old frames to force exact time delay
if(AVI_write_audio(avifile2, data, bytes)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
fprintf(status_fd, "V [%05d] | padding\r", n);
} else {
if (n==-shift)
fprintf(status_fd, "\n");
// get next audio frame
ptr = buffer_retrieve();
if(ptr==NULL) {
fprintf(stderr,"no buffer found\n");
break;
}
if(AVI_write_audio(avifile2, ptr->data, ptr->size)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
bytes = ptr->size;
ac_memcpy (data, ptr->data, bytes);
fprintf(status_fd, "V [%05d] | A [%05d]\r", n, ptr->id);
buffer_remove(ptr);
}
if ( !aud_bitrate && tc_get_audio_header(data, bytes, format, NULL, NULL, &aud_bitrate)<0) {
if (n == frames-1) continue;
aud_ms[track_num] = vid_ms;
} else
aud_ms[track_num] += (bytes*8.0)/(format==0x1?((double)(rate*chan*bits)/1000.0):
(format==0x2000?(double)(mp3rate):aud_bitrate));
/*
fprintf(stderr, " 1 (%02d) %s frame_read len=%4ld (A/V) (%8.2f/%8.2f)\n",
n, format==0x55?"MP3":"AC3", bytes, aud_ms[track_num], vid_ms);
*/
}
} else { // no supported format
bytes = AVI_audio_size(avifile1, n);
if(bytes > SIZE_RGB_FRAME) {
fprintf(stderr, "invalid frame size\n");
return(-1);
}
if(AVI_read_audio(avifile1, data, bytes) < 0) {
AVI_print_error("AVI audio read frame");
return(-1);
}
// save audio frame for later
ptr = buffer_register(n);
if(ptr==NULL) {
fprintf(stderr,"buffer allocation failed\n");
break;
}
ac_memcpy(ptr->data, data, bytes);
ptr->size = bytes;
ptr->status = BUFFER_READY;
if(n<-shift) {
if (encode_null) {
if(AVI_write_audio(avifile2, nulls, nullbytes)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
} else {
// simple keep old frames to force exact time delay
if(AVI_write_audio(avifile2, data, bytes)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
}
fprintf(status_fd, "V [%05d] | padding\r", n);
} else {
// get next audio frame
ptr = buffer_retrieve();
if(ptr==NULL) {
fprintf(stderr,"no buffer found\n");
break;
}
if(AVI_write_audio(avifile2, ptr->data, ptr->size)<0) {
AVI_print_error("AVI write audio frame");
return(-1);
}
fprintf(status_fd, "V [%05d] | A [%05d]\r", n, ptr->id);
buffer_remove(ptr);
}
}
}
}
fprintf(status_fd, "\n");
if (be_quiet) {
fclose(status_fd);
}
AVI_close(avifile1);
AVI_close(avifile2);
if (avifile3) {
memset(nulls, 0, sizeof(nulls));
tc_snprintf(nulls, sizeof(nulls), "rm -f %s", tmp0);
system(nulls);
AVI_close(avifile3);
}
return(0);
}
