/*
This file is part of the HandBrake source code.
Homepage: .
It may be used under the terms of the GNU General Public License. */
#include
#include
#include
#include
#include
#include "hb.h"
struct start_and_end {
unsigned long start, end;
};
enum
{
k_state_inEntry,
k_state_inEntry_or_new,
k_state_potential_new_entry,
k_state_timecode,
};
typedef struct srt_entry_s {
long offset, duration;
long start, stop;
char text[1024];
int pos;
} srt_entry_t;
/*
* Store all context in the work private struct,
*/
struct hb_work_private_s
{
hb_job_t * job;
FILE * file;
char buf[1024];
int pos;
int end;
char utf8_buf[2048];
int utf8_pos;
int utf8_end;
int utf8_bom_skipped;
unsigned long current_time;
unsigned long number_of_entries;
unsigned long last_entry_number;
unsigned long current_state;
srt_entry_t current_entry;
iconv_t *iconv_context;
hb_subtitle_t *subtitle;
uint64_t start_time; // In HB time
uint64_t stop_time; // In HB time
};
static int
read_time_from_string( const char* timeString, struct start_and_end *result )
{
// for ex. 00:00:15,248 --> 00:00:16,545
long houres1, minutes1, seconds1, milliseconds1,
houres2, minutes2, seconds2, milliseconds2;
int scanned;
scanned = sscanf(timeString, "%ld:%ld:%ld,%ld --> %ld:%ld:%ld,%ld\n",
&houres1, &minutes1, &seconds1, &milliseconds1,
&houres2, &minutes2, &seconds2, &milliseconds2);
if (scanned != 8)
{
return 0;
}
result->start =
milliseconds1 + seconds1*1000 + minutes1*60*1000 + houres1*60*60*1000;
result->end =
milliseconds2 + seconds2*1000 + minutes2*60*1000 + houres2*60*60*1000;
return 1;
}
static int utf8_fill( hb_work_private_t * pv )
{
int bytes, conversion = 0;
size_t out_size;
/* Align utf8 data to beginning of the buffer so that we can
* fill the buffer to its maximum */
memmove( pv->utf8_buf, pv->utf8_buf + pv->utf8_pos, pv->utf8_end - pv->utf8_pos );
pv->utf8_end -= pv->utf8_pos;
pv->utf8_pos = 0;
out_size = 2048 - pv->utf8_end;
while( out_size )
{
char *p, *q;
size_t in_size, retval;
if( pv->end == pv->pos )
{
bytes = fread( pv->buf, 1, 1024, pv->file );
pv->pos = 0;
pv->end = bytes;
if( bytes == 0 )
{
if( conversion )
return 1;
else
return 0;
}
}
p = pv->buf + pv->pos;
q = pv->utf8_buf + pv->utf8_end;
in_size = pv->end - pv->pos;
retval = iconv( pv->iconv_context, &p, &in_size, &q, &out_size);
if( q != pv->utf8_buf + pv->utf8_pos )
conversion = 1;
pv->utf8_end = q - pv->utf8_buf;
pv->pos = p - pv->buf;
if ( !pv->utf8_bom_skipped )
{
uint8_t *buf = (uint8_t*)pv->utf8_buf;
if (buf[0] == 0xef && buf[1] == 0xbb && buf[2] == 0xbf)
{
pv->utf8_pos = 3;
}
pv->utf8_bom_skipped = 1;
}
if( ( retval == -1 ) && ( errno == EINVAL ) )
{
/* Incomplete multibyte sequence, read more data */
memmove( pv->buf, p, pv->end - pv->pos );
pv->end -= pv->pos;
pv->pos = 0;
bytes = fread( pv->buf + pv->end, 1, 1024 - pv->end, pv->file );
if( bytes == 0 )
{
if( !conversion )
return 0;
else
return 1;
}
pv->end += bytes;
} else if ( ( retval == -1 ) && ( errno == EILSEQ ) )
{
hb_error( "Invalid byte for codeset in input, discard byte" );
/* Try the next byte of the input */
pv->pos++;
} else if ( ( retval == -1 ) && ( errno == E2BIG ) )
{
/* buffer full */
return conversion;
}
}
return 1;
}
static int get_line( hb_work_private_t * pv, char *buf, int size )
{
int i;
char c;
/* Find newline in converted UTF-8 buffer */
for( i = 0; i < size - 1; i++ )
{
if( pv->utf8_pos >= pv->utf8_end )
{
if( !utf8_fill( pv ) )
{
if( i )
return 1;
else
return 0;
}
}
c = pv->utf8_buf[pv->utf8_pos++];
if( c == '\n' )
{
buf[i] = '\n';
buf[i+1] = '\0';
return 1;
}
buf[i] = c;
}
buf[0] = '\0';
return 1;
}
/*
* Read the SRT file and put the entries into the subtitle fifo for all to read
*/
static hb_buffer_t *srt_read( hb_work_private_t *pv )
{
char line_buffer[1024];
int reprocess = 0, resync = 0;
if( !pv->file )
{
return NULL;
}
while( reprocess || get_line( pv, line_buffer, sizeof( line_buffer ) ) )
{
reprocess = 0;
switch (pv->current_state)
{
case k_state_timecode:
{
struct start_and_end timing;
int result;
result = read_time_from_string( line_buffer, &timing );
if (!result)
{
resync = 1;
pv->current_state = k_state_potential_new_entry;
continue;
}
pv->current_entry.duration = timing.end - timing.start;
pv->current_entry.offset = timing.start - pv->current_time;
pv->current_time = timing.end;
pv->current_entry.start = timing.start;
pv->current_entry.stop = timing.end;
pv->current_state = k_state_inEntry;
continue;
}
case k_state_inEntry_or_new:
{
char *endpoint;
long entry_number;
/*
* Is this really new next entry begin?
*/
entry_number = strtol(line_buffer, &endpoint, 10);
if (endpoint == line_buffer ||
(endpoint && *endpoint != '\n' && *endpoint != '\r'))
{
/*
* Doesn't resemble an entry number
* must still be in an entry
*/
if (!resync)
{
reprocess = 1;
pv->current_state = k_state_inEntry;
}
continue;
}
reprocess = 1;
pv->current_state = k_state_potential_new_entry;
break;
}
case k_state_inEntry:
{
char *q;
int size, len;
// If the current line is empty, we assume this is the
// seperation betwene two entries. In case we are wrong,
// the mistake is corrected in the next state.
if (strcmp(line_buffer, "\n") == 0 || strcmp(line_buffer, "\r\n") == 0) {
pv->current_state = k_state_potential_new_entry;
continue;
}
q = pv->current_entry.text + pv->current_entry.pos;
len = strlen( line_buffer );
size = MIN(1024 - pv->current_entry.pos - 1, len );
memcpy(q, line_buffer, size);
pv->current_entry.pos += size;
pv->current_entry.text[pv->current_entry.pos] = '\0';
break;
}
case k_state_potential_new_entry:
{
char *endpoint;
long entry_number;
hb_buffer_t *buffer = NULL;
/*
* Is this really new next entry begin?
*/
entry_number = strtol(line_buffer, &endpoint, 10);
if (!resync && (*line_buffer == '\n' || *line_buffer == '\r'))
{
/*
* Well.. looks like we are in the wrong mode.. lets add the
* newline we misinterpreted...
*/
strncat(pv->current_entry.text, " ", 1024);
pv->current_state = k_state_inEntry_or_new;
continue;
}
if (endpoint == line_buffer ||
(endpoint && *endpoint != '\n' && *endpoint != '\r'))
{
/*
* Well.. looks like we are in the wrong mode.. lets add the
* line we misinterpreted...
*/
if (!resync)
{
reprocess = 1;
pv->current_state = k_state_inEntry;
}
continue;
}
/*
* We found the next entry - or a really rare error condition
*/
pv->last_entry_number = entry_number;
resync = 0;
if( *pv->current_entry.text )
{
long length;
char *p, *q;
int line = 1;
uint64_t start_time = ( pv->current_entry.start +
pv->subtitle->config.offset ) * 90;
uint64_t stop_time = ( pv->current_entry.stop +
pv->subtitle->config.offset ) * 90;
if( !( start_time > pv->start_time && stop_time < pv->stop_time ) )
{
hb_deep_log( 3, "Discarding SRT at time start %"PRId64", stop %"PRId64, start_time, stop_time);
memset( &pv->current_entry, 0, sizeof( srt_entry_t ) );
++(pv->number_of_entries);
pv->current_state = k_state_timecode;
continue;
}
length = strlen( pv->current_entry.text );
for( q = p = pv->current_entry.text; *p; p++)
{
if( *p == '\n' )
{
if ( line == 1 )
{
*q = *p;
line = 2;
}
else
{
*q = ' ';
}
q++;
}
else if( *p != '\r' )
{
*q = *p;
q++;
}
else
{
length--;
}
}
*q = '\0';
buffer = hb_buffer_init( length + 1 );
if( buffer )
{
buffer->start = start_time - pv->start_time;
buffer->stop = stop_time - pv->start_time;
memcpy( buffer->data, pv->current_entry.text, length + 1 );
}
}
memset( &pv->current_entry, 0, sizeof( srt_entry_t ) );
++(pv->number_of_entries);
pv->current_state = k_state_timecode;
if( buffer )
{
return buffer;
}
continue;
}
}
}
hb_buffer_t *buffer = NULL;
if( *pv->current_entry.text )
{
long length;
char *p, *q;
int line = 1;
uint64_t start_time = ( pv->current_entry.start +
pv->subtitle->config.offset ) * 90;
uint64_t stop_time = ( pv->current_entry.stop +
pv->subtitle->config.offset ) * 90;
if( !( start_time > pv->start_time && stop_time < pv->stop_time ) )
{
hb_deep_log( 3, "Discarding SRT at time start %"PRId64", stop %"PRId64, start_time, stop_time);
memset( &pv->current_entry, 0, sizeof( srt_entry_t ) );
return NULL;
}
length = strlen( pv->current_entry.text );
for( q = p = pv->current_entry.text; *p; p++)
{
if( *p == '\n' )
{
if ( line == 1 )
{
*q = *p;
line = 2;
}
else
{
*q = ' ';
}
q++;
}
else if( *p != '\r' )
{
*q = *p;
q++;
}
else
{
length--;
}
}
*q = '\0';
buffer = hb_buffer_init( length + 1 );
if( buffer )
{
buffer->start = start_time - pv->start_time;
buffer->stop = stop_time - pv->start_time;
memcpy( buffer->data, pv->current_entry.text, length + 1 );
}
}
memset( &pv->current_entry, 0, sizeof( srt_entry_t ) );
if( buffer )
{
return buffer;
}
return NULL;
}
static int decsrtInit( hb_work_object_t * w, hb_job_t * job )
{
int retval = 1;
hb_work_private_t * pv;
hb_buffer_t *buffer;
int i;
hb_chapter_t * chapter;
hb_title_t *title = job->title;
pv = calloc( 1, sizeof( hb_work_private_t ) );
if( pv )
{
w->private_data = pv;
pv->job = job;
buffer = hb_buffer_init( 0 );
hb_fifo_push( w->fifo_in, buffer);
pv->current_state = k_state_potential_new_entry;
pv->number_of_entries = 0;
pv->last_entry_number = 0;
pv->current_time = 0;
pv->subtitle = w->subtitle;
/*
* Figure out the start and stop times from teh chapters being
* encoded - drop subtitle not in this range.
*/
pv->start_time = 0;
for( i = 1; i < job->chapter_start; ++i )
{
chapter = hb_list_item( title->list_chapter, i - 1 );
if( chapter )
{
pv->start_time += chapter->duration;
} else {
hb_error( "Could not locate chapter %d for SRT start time", i );
retval = 0;
}
}
pv->stop_time = pv->start_time;
for( i = job->chapter_start; i <= job->chapter_end; ++i )
{
chapter = hb_list_item( title->list_chapter, i - 1 );
if( chapter )
{
pv->stop_time += chapter->duration;
} else {
hb_error( "Could not locate chapter %d for SRT start time", i );
retval = 0;
}
}
hb_deep_log( 3, "SRT Start time %"PRId64", stop time %"PRId64, pv->start_time, pv->stop_time);
pv->iconv_context = iconv_open( "utf-8", pv->subtitle->config.src_codeset );
if( pv->iconv_context == (iconv_t) -1 )
{
hb_error("Could not open the iconv library with those file formats\n");
} else {
memset( &pv->current_entry, 0, sizeof( srt_entry_t ) );
pv->file = fopen( w->subtitle->config.src_filename, "r" );
if( !pv->file )
{
hb_error("Could not open the SRT subtitle file '%s'\n",
w->subtitle->config.src_filename);
} else {
retval = 0;
}
}
}
return retval;
}
static int decsrtWork( hb_work_object_t * w, hb_buffer_t ** buf_in,
hb_buffer_t ** buf_out )
{
hb_work_private_t * pv = w->private_data;
hb_buffer_t * in = *buf_in;
hb_buffer_t * out = NULL;
out = srt_read( pv );
if( out )
{
/*
* Keep a buffer in our input fifo so that we get run.
*/
hb_fifo_push( w->fifo_in, in);
*buf_in = NULL;
*buf_out = out;
} else {
*buf_out = NULL;
return HB_WORK_OK;
}
return HB_WORK_OK;
}
static void decsrtClose( hb_work_object_t * w )
{
hb_work_private_t * pv = w->private_data;
fclose( pv->file );
iconv_close(pv->iconv_context);
free( w->private_data );
}
hb_work_object_t hb_decsrtsub =
{
WORK_DECSRTSUB,
"SRT Subtitle Decoder",
decsrtInit,
decsrtWork,
decsrtClose
};