static int avisynth_create_stream(AVFormatContext *s)
{
AviSynthContext *avs = s->priv_data;
AVStream *st;
int ret;
int id = 0;
if (avs_has_video(avs->vi)) {
st = avformat_new_stream(s, NULL);
if (!st)
return AVERROR_UNKNOWN;
st->id = id++;
if (ret = avisynth_create_stream_video(s, st))
return ret;
}
if (avs_has_audio(avs->vi)) {
st = avformat_new_stream(s, NULL);
if (!st)
return AVERROR_UNKNOWN;
st->id = id++;
if (ret = avisynth_create_stream_audio(s, st))
return ret;
}
return 0;
}
static int avisynth_read_packet(AVFormatContext *s, AVPacket *pkt)
{
AviSynthContext *avs = s->priv_data;
AVStream *st;
int discard = 0;
int ret;
if (avs->error)
return AVERROR_UNKNOWN;
/* If either stream reaches EOF, try to read the other one before
* giving up. */
avisynth_next_stream(s, &st, pkt, &discard);
if (st->codec->codec_type == AVMEDIA_TYPE_VIDEO) {
ret = avisynth_read_packet_video(s, pkt, discard);
if (ret == AVERROR_EOF && avs_has_audio(avs->vi)) {
avisynth_next_stream(s, &st, pkt, &discard);
return avisynth_read_packet_audio(s, pkt, discard);
}
} else {
ret = avisynth_read_packet_audio(s, pkt, discard);
if (ret == AVERROR_EOF && avs_has_video(avs->vi)) {
avisynth_next_stream(s, &st, pkt, &discard);
return avisynth_read_packet_video(s, pkt, discard);
}
}
return ret;
}
static int avisynth_read_seek(AVFormatContext *s, int stream_index, int64_t timestamp, int flags) {
AviSynthContext *avs = s->priv_data;
AVStream *st;
AVRational fps, samplerate;
if (avs->error)
return AVERROR_UNKNOWN;
fps = (AVRational) {avs->vi->fps_numerator, avs->vi->fps_denominator};
samplerate = (AVRational) {avs->vi->audio_samples_per_second, 1};
st = s->streams[stream_index];
if (st->codec->codec_type == AVMEDIA_TYPE_VIDEO) {
// AviSynth frame counts are signed int.
if ((timestamp >= avs->vi->num_frames) || (timestamp > INT_MAX) || (timestamp < 0))
return AVERROR_EOF;
avs->curr_frame = timestamp;
if (avs_has_audio(avs->vi))
avs->curr_sample = av_rescale_q(timestamp, samplerate, fps);
} else {
if ((timestamp >= avs->vi->num_audio_samples) || (timestamp < 0))
return AVERROR_EOF;
// Force frame granularity for seeking.
if (avs_has_video(avs->vi)) {
avs->curr_frame = av_rescale_q(timestamp, fps, samplerate);
avs->curr_sample = av_rescale_q(avs->curr_frame, samplerate, fps);
} else {
avs->curr_sample = timestamp;
}
}
return 0;
}
static int avisynth_read_packet_audio(AVFormatContext *s, AVPacket *pkt,
int discard)
{
AviSynthContext *avs = s->priv_data;
AVRational fps, samplerate;
int samples;
int64_t n;
const char *error;
if (avs->curr_sample >= avs->vi->num_audio_samples)
return AVERROR_EOF;
fps.num = avs->vi->fps_numerator;
fps.den = avs->vi->fps_denominator;
samplerate.num = avs->vi->audio_samples_per_second;
samplerate.den = 1;
if (avs_has_video(avs->vi)) {
if (avs->curr_frame < avs->vi->num_frames)
samples = av_rescale_q(avs->curr_frame, samplerate, fps) -
avs->curr_sample;
else
samples = av_rescale_q(1, samplerate, fps);
} else {
samples = 1000;
}
/* After seeking, audio may catch up with video. */
if (samples <= 0) {
pkt->size = 0;
pkt->data = NULL;
return 0;
}
if (avs->curr_sample + samples > avs->vi->num_audio_samples)
samples = avs->vi->num_audio_samples - avs->curr_sample;
/* This must happen even if the stream is discarded to prevent desync. */
n = avs->curr_sample;
avs->curr_sample += samples;
if (discard)
return 0;
pkt->size = avs_bytes_per_channel_sample(avs->vi) *
samples * avs->vi->nchannels;
if (!pkt->size)
return AVERROR_UNKNOWN;
if (av_new_packet(pkt, pkt->size) < 0)
return AVERROR(ENOMEM);
pkt->pts = n;
pkt->dts = n;
pkt->duration = samples;
pkt->stream_index = avs->curr_stream;
avs_library.avs_get_audio(avs->clip, pkt->data, n, samples);
error = avs_library.avs_clip_get_error(avs->clip);
if (error) {
av_log(s, AV_LOG_ERROR, "%s\n", error);
avs->error = 1;
av_packet_unref(pkt);
return AVERROR_UNKNOWN;
}
return 0;
}
static demuxer_t* demux_open_avs(demuxer_t* demuxer)
{
int found = 0;
AVS_T *AVS = demuxer->priv;
int audio_samplesize = 0;
AVS->frameno = 0;
AVS->sampleno = 0;
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: demux_open_avs()\n");
demuxer->seekable = 1;
AVS->clip = AVS->avs_take_clip(AVS->handler, AVS->avs_env);
if(!AVS->clip)
{
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: avs_take_clip() failed\n");
return NULL;
}
AVS->video_info = AVS->avs_get_video_info(AVS->clip);
if (!AVS->video_info)
{
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: avs_get_video_info() call failed\n");
return NULL;
}
if (!avs_is_yv12(AVS->video_info))
{
AVS->handler = AVS->avs_invoke(AVS->avs_env, "ConvertToYV12", avs_new_value_array(&AVS->handler, 1), 0);
if (avs_is_error(AVS->handler))
{
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: Cannot convert input video to YV12: %s\n", avs_as_string(AVS->handler));
return NULL;
}
AVS->clip = AVS->avs_take_clip(AVS->handler, AVS->avs_env);
if(!AVS->clip)
{
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: avs_take_clip() failed\n");
return NULL;
}
AVS->video_info = AVS->avs_get_video_info(AVS->clip);
if (!AVS->video_info)
{
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: avs_get_video_info() call failed\n");
return NULL;
}
}
// TODO check field-based ??
/* Video */
if (avs_has_video(AVS->video_info))
{
sh_video_t *sh_video = new_sh_video(demuxer, 0);
found = 1;
if (demuxer->video->id == -1) demuxer->video->id = 0;
if (demuxer->video->id == 0)
demuxer->video->sh = sh_video;
sh_video->ds = demuxer->video;
sh_video->disp_w = AVS->video_info->width;
sh_video->disp_h = AVS->video_info->height;
//sh_video->format = get_mmioFOURCC(AVS->video_info);
sh_video->format = mmioFOURCC('Y', 'V', '1', '2');
sh_video->fps = (double) AVS->video_info->fps_numerator / (double) AVS->video_info->fps_denominator;
sh_video->frametime = 1.0 / sh_video->fps;
sh_video->bih = malloc(sizeof(BITMAPINFOHEADER) + (256 * 4));
sh_video->bih->biCompression = sh_video->format;
sh_video->bih->biBitCount = avs_bits_per_pixel(AVS->video_info);
//sh_video->bih->biPlanes = 2;
sh_video->bih->biWidth = AVS->video_info->width;
sh_video->bih->biHeight = AVS->video_info->height;
sh_video->num_frames = 0;
sh_video->num_frames_decoded = 0;
}
/* Audio */
if (avs_has_audio(AVS->video_info))
switch (AVS->video_info->sample_type) {
case AVS_SAMPLE_INT8: audio_samplesize = 1; break;
case AVS_SAMPLE_INT16: audio_samplesize = 2; break;
case AVS_SAMPLE_INT24: audio_samplesize = 3; break;
case AVS_SAMPLE_INT32:
case AVS_SAMPLE_FLOAT: audio_samplesize = 4; break;
default:
mp_msg(MSGT_DEMUX, MSGL_ERR, "AVS: unknown audio type, disabling\n");
}
if (audio_samplesize)
{
sh_audio_t *sh_audio = new_sh_audio(demuxer, 0);
found = 1;
mp_msg(MSGT_DEMUX, MSGL_V, "AVS: Clip has audio -> Channels = %d - Freq = %d\n", AVS->video_info->nchannels, AVS->video_info->audio_samples_per_second);
if (demuxer->audio->id == -1) demuxer->audio->id = 0;
if (demuxer->audio->id == 0)
demuxer->audio->sh = sh_audio;
sh_audio->ds = demuxer->audio;
sh_audio->wf = malloc(sizeof(WAVEFORMATEX));
sh_audio->wf->wFormatTag = sh_audio->format =
(AVS->video_info->sample_type == AVS_SAMPLE_FLOAT) ? 0x3 : 0x1;
sh_audio->wf->nChannels = sh_audio->channels = AVS->video_info->nchannels;
sh_audio->wf->nSamplesPerSec = sh_audio->samplerate = AVS->video_info->audio_samples_per_second;
sh_audio->samplesize = audio_samplesize;
sh_audio->wf->nAvgBytesPerSec = sh_audio->channels * sh_audio->samplesize * sh_audio->samplerate;
sh_audio->wf->nBlockAlign = sh_audio->channels * sh_audio->samplesize;
sh_audio->wf->wBitsPerSample = sh_audio->samplesize * 8;
sh_audio->wf->cbSize = 0;
sh_audio->i_bps = sh_audio->wf->nAvgBytesPerSec;
}
AVS->init = 1;
if (found)
return demuxer;
else
return NULL;
}
static int open_file( char *psz_filename, hnd_t *p_handle, video_info_t *info, cli_input_opt_t *opt )
{
FILE *fh = x264_fopen( psz_filename, "r" );
if( !fh )
return -1;
int b_regular = x264_is_regular_file( fh );
fclose( fh );
FAIL_IF_ERROR( !b_regular, "AVS input is incompatible with non-regular file `%s'\n", psz_filename );
avs_hnd_t *h = calloc( 1, sizeof(avs_hnd_t) );
if( !h )
return -1;
FAIL_IF_ERROR( custom_avs_load_library( h ), "failed to load avisynth\n" );
h->env = h->func.avs_create_script_environment( AVS_INTERFACE_25 );
if( h->func.avs_get_error )
{
const char *error = h->func.avs_get_error( h->env );
FAIL_IF_ERROR( error, "%s\n", error );
}
float avs_version = get_avs_version( h );
if( avs_version <= 0 )
return -1;
x264_cli_log( "avs", X264_LOG_DEBUG, "using avisynth version %.2f\n", avs_version );
#ifdef _WIN32
/* Avisynth doesn't support Unicode filenames. */
char ansi_filename[MAX_PATH];
FAIL_IF_ERROR( !x264_ansi_filename( psz_filename, ansi_filename, MAX_PATH, 0 ), "invalid ansi filename\n" );
AVS_Value arg = avs_new_value_string( ansi_filename );
#else
AVS_Value arg = avs_new_value_string( psz_filename );
#endif
AVS_Value res;
char *filename_ext = get_filename_extension( psz_filename );
if( !strcasecmp( filename_ext, "avs" ) )
{
res = h->func.avs_invoke( h->env, "Import", arg, NULL );
FAIL_IF_ERROR( avs_is_error( res ), "%s\n", avs_as_error( res ) );
/* check if the user is using a multi-threaded script and apply distributor if necessary.
adapted from avisynth's vfw interface */
AVS_Value mt_test = h->func.avs_invoke( h->env, "GetMTMode", avs_new_value_bool( 0 ), NULL );
int mt_mode = avs_is_int( mt_test ) ? avs_as_int( mt_test ) : 0;
h->func.avs_release_value( mt_test );
if( mt_mode > 0 && mt_mode < 5 )
{
AVS_Value temp = h->func.avs_invoke( h->env, "Distributor", res, NULL );
h->func.avs_release_value( res );
res = temp;
}
}
else /* non script file */
{
/* cycle through known source filters to find one that works */
const char *filter[AVS_MAX_SEQUENCE+1] = { 0 };
avs_build_filter_sequence( filename_ext, filter );
int i;
for( i = 0; filter[i]; i++ )
{
x264_cli_log( "avs", X264_LOG_INFO, "trying %s... ", filter[i] );
if( !h->func.avs_function_exists( h->env, filter[i] ) )
{
x264_cli_printf( X264_LOG_INFO, "not found\n" );
continue;
}
if( !strncasecmp( filter[i], "FFmpegSource", 12 ) )
{
x264_cli_printf( X264_LOG_INFO, "indexing... " );
fflush( stderr );
}
res = h->func.avs_invoke( h->env, filter[i], arg, NULL );
if( !avs_is_error( res ) )
{
x264_cli_printf( X264_LOG_INFO, "succeeded\n" );
break;
}
x264_cli_printf( X264_LOG_INFO, "failed\n" );
}
FAIL_IF_ERROR( !filter[i], "unable to find source filter to open `%s'\n", psz_filename );
}
FAIL_IF_ERROR( !avs_is_clip( res ), "`%s' didn't return a video clip\n", psz_filename );
h->clip = h->func.avs_take_clip( res, h->env );
const AVS_VideoInfo *vi = h->func.avs_get_video_info( h->clip );
FAIL_IF_ERROR( !avs_has_video( vi ), "`%s' has no video data\n", psz_filename );
/* if the clip is made of fields instead of frames, call weave to make them frames */
if( avs_is_field_based( vi ) )
{
x264_cli_log( "avs", X264_LOG_WARNING, "detected fieldbased (separated) input, weaving to frames\n" );
AVS_Value tmp = h->func.avs_invoke( h->env, "Weave", res, NULL );
FAIL_IF_ERROR( avs_is_error( tmp ), "couldn't weave fields into frames: %s\n", avs_as_error( tmp ) );
res = update_clip( h, &vi, tmp, res );
info->interlaced = 1;
info->tff = avs_is_tff( vi );
}
#if !HAVE_SWSCALE
/* if swscale is not available, convert the CSP if necessary */
FAIL_IF_ERROR( avs_version < 2.6f && (opt->output_csp == X264_CSP_I400 || opt->output_csp == X264_CSP_I422 || opt->output_csp == X264_CSP_I444),
"avisynth >= 2.6 is required for i400/i422/i444 output\n" );
if( (opt->output_csp == X264_CSP_I400 && !AVS_IS_Y( vi )) ||
(opt->output_csp == X264_CSP_I420 && !AVS_IS_420( vi )) ||
(opt->output_csp == X264_CSP_I422 && !AVS_IS_422( vi )) ||
(opt->output_csp == X264_CSP_I444 && !AVS_IS_444( vi )) ||
(opt->output_csp == X264_CSP_RGB && !avs_is_rgb( vi )) )
{
const char *csp;
if( AVS_IS_AVISYNTHPLUS )
{
csp = opt->output_csp == X264_CSP_I400 ? "Y" :
opt->output_csp == X264_CSP_I420 ? "YUV420" :
opt->output_csp == X264_CSP_I422 ? "YUV422" :
opt->output_csp == X264_CSP_I444 ? "YUV444" :
"RGB";
}
else
{
csp = opt->output_csp == X264_CSP_I400 ? "Y8" :
opt->output_csp == X264_CSP_I420 ? "YV12" :
opt->output_csp == X264_CSP_I422 ? "YV16" :
opt->output_csp == X264_CSP_I444 ? "YV24" :
"RGB";
}
x264_cli_log( "avs", X264_LOG_WARNING, "converting input clip to %s\n", csp );
if( opt->output_csp != X264_CSP_I400 )
{
FAIL_IF_ERROR( opt->output_csp < X264_CSP_I444 && (vi->width&1),
"input clip width not divisible by 2 (%dx%d)\n", vi->width, vi->height );
FAIL_IF_ERROR( opt->output_csp == X264_CSP_I420 && info->interlaced && (vi->height&3),
"input clip height not divisible by 4 (%dx%d)\n", vi->width, vi->height );
FAIL_IF_ERROR( (opt->output_csp == X264_CSP_I420 || info->interlaced) && (vi->height&1),
"input clip height not divisible by 2 (%dx%d)\n", vi->width, vi->height );
}
char conv_func[16];
snprintf( conv_func, sizeof(conv_func), "ConvertTo%s", csp );
AVS_Value arg_arr[3];
const char *arg_name[3];
int arg_count = 1;
arg_arr[0] = res;
arg_name[0] = NULL;
if( opt->output_csp != X264_CSP_I400 )
{
arg_arr[arg_count] = avs_new_value_bool( info->interlaced );
arg_name[arg_count] = "interlaced";
arg_count++;
}
/* if doing a rgb <-> yuv conversion then range is handled via 'matrix'. though it's only supported in 2.56+ */
char matrix[7];
if( avs_version >= 2.56f && ((opt->output_csp == X264_CSP_RGB && avs_is_yuv( vi )) || (opt->output_csp != X264_CSP_RGB && avs_is_rgb( vi ))) )
{
// if converting from yuv, then we specify the matrix for the input, otherwise use the output's.
int use_pc_matrix = avs_is_yuv( vi ) ? opt->input_range == RANGE_PC : opt->output_range == RANGE_PC;
snprintf( matrix, sizeof(matrix), "%s601", use_pc_matrix ? "PC." : "Rec" ); /* FIXME: use correct coefficients */
arg_arr[arg_count] = avs_new_value_string( matrix );
arg_name[arg_count] = "matrix";
arg_count++;
// notification that the input range has changed to the desired one
opt->input_range = opt->output_range;
}
AVS_Value res2 = h->func.avs_invoke( h->env, conv_func, avs_new_value_array( arg_arr, arg_count ), arg_name );
FAIL_IF_ERROR( avs_is_error( res2 ), "couldn't convert input clip to %s: %s\n", csp, avs_as_error( res2 ) );
res = update_clip( h, &vi, res2, res );
}
/* if swscale is not available, change the range if necessary. This only applies to YUV-based CSPs however */
if( avs_is_yuv( vi ) && opt->output_range != RANGE_AUTO && ((opt->input_range == RANGE_PC) != opt->output_range) )
{
const char *levels = opt->output_range ? "TV->PC" : "PC->TV";
x264_cli_log( "avs", X264_LOG_WARNING, "performing %s conversion\n", levels );
AVS_Value arg_arr[2];
arg_arr[0] = res;
arg_arr[1] = avs_new_value_string( levels );
const char *arg_name[] = { NULL, "levels" };
AVS_Value res2 = h->func.avs_invoke( h->env, "ColorYUV", avs_new_value_array( arg_arr, 2 ), arg_name );
FAIL_IF_ERROR( avs_is_error( res2 ), "couldn't convert range: %s\n", avs_as_error( res2 ) );
res = update_clip( h, &vi, res2, res );
// notification that the input range has changed to the desired one
opt->input_range = opt->output_range;
}
#endif
h->func.avs_release_value( res );
info->width = vi->width;
info->height = vi->height;
info->fps_num = vi->fps_numerator;
info->fps_den = vi->fps_denominator;
h->num_frames = info->num_frames = vi->num_frames;
info->thread_safe = 1;
if( AVS_IS_RGB64( vi ) )
info->csp = X264_CSP_BGRA | X264_CSP_VFLIP | X264_CSP_HIGH_DEPTH;
else if( avs_is_rgb32( vi ) )
info->csp = X264_CSP_BGRA | X264_CSP_VFLIP;
else if( AVS_IS_RGB48( vi ) )
info->csp = X264_CSP_BGR | X264_CSP_VFLIP | X264_CSP_HIGH_DEPTH;
else if( avs_is_rgb24( vi ) )
info->csp = X264_CSP_BGR | X264_CSP_VFLIP;
else if( AVS_IS_YUV444P16( vi ) )
info->csp = X264_CSP_I444 | X264_CSP_HIGH_DEPTH;
else if( avs_is_yv24( vi ) )
info->csp = X264_CSP_I444;
else if( AVS_IS_YUV422P16( vi ) )
info->csp = X264_CSP_I422 | X264_CSP_HIGH_DEPTH;
else if( avs_is_yv16( vi ) )
info->csp = X264_CSP_I422;
else if( AVS_IS_YUV420P16( vi ) )
info->csp = X264_CSP_I420 | X264_CSP_HIGH_DEPTH;
else if( avs_is_yv12( vi ) )
info->csp = X264_CSP_I420;
else if( AVS_IS_Y16( vi ) )
info->csp = X264_CSP_I400 | X264_CSP_HIGH_DEPTH;
else if( avs_is_y8( vi ) )
info->csp = X264_CSP_I400;
else if( avs_is_yuy2( vi ) )
info->csp = X264_CSP_YUYV;
#if HAVE_SWSCALE
else if( avs_is_yv411( vi ) )
info->csp = AV_PIX_FMT_YUV411P | X264_CSP_OTHER;
#endif
else
{
AVS_Value pixel_type = h->func.avs_invoke( h->env, "PixelType", res, NULL );
const char *pixel_type_name = avs_is_string( pixel_type ) ? avs_as_string( pixel_type ) : "unknown";
FAIL_IF_ERROR( 1, "not supported pixel type: %s\n", pixel_type_name );
}
info->vfr = 0;
*p_handle = h;
return 0;
}
static int open_file( char *psz_filename, hnd_t *p_handle, video_info_t *info, cli_input_opt_t *opt )
{
FILE *fh = fopen( psz_filename, "r" );
if( !fh )
return -1;
FAIL_IF_ERROR( !x264_is_regular_file( fh ), "AVS input is incompatible with non-regular file `%s'\n", psz_filename );
fclose( fh );
avs_hnd_t *h = malloc( sizeof(avs_hnd_t) );
if( !h )
return -1;
FAIL_IF_ERROR( x264_avs_load_library( h ), "failed to load avisynth\n" )
h->env = h->func.avs_create_script_environment( AVS_INTERFACE_25 );
FAIL_IF_ERROR( !h->env, "failed to initiate avisynth\n" )
AVS_Value arg = avs_new_value_string( psz_filename );
AVS_Value res;
char *filename_ext = get_filename_extension( psz_filename );
if( !strcasecmp( filename_ext, "avs" ) )
{
res = h->func.avs_invoke( h->env, "Import", arg, NULL );
FAIL_IF_ERROR( avs_is_error( res ), "%s\n", avs_as_string( res ) )
/* check if the user is using a multi-threaded script and apply distributor if necessary.
adapted from avisynth's vfw interface */
AVS_Value mt_test = h->func.avs_invoke( h->env, "GetMTMode", avs_new_value_bool( 0 ), NULL );
int mt_mode = avs_is_int( mt_test ) ? avs_as_int( mt_test ) : 0;
h->func.avs_release_value( mt_test );
if( mt_mode > 0 && mt_mode < 5 )
{
AVS_Value temp = h->func.avs_invoke( h->env, "Distributor", res, NULL );
h->func.avs_release_value( res );
res = temp;
}
}
else /* non script file */
{
/* cycle through known source filters to find one that works */
const char *filter[AVS_MAX_SEQUENCE+1] = { 0 };
avs_build_filter_sequence( filename_ext, filter );
int i;
for( i = 0; filter[i]; i++ )
{
x264_cli_log( "avs", X264_LOG_INFO, "trying %s... ", filter[i] );
if( !h->func.avs_function_exists( h->env, filter[i] ) )
{
x264_cli_printf( X264_LOG_INFO, "not found\n" );
continue;
}
if( !strncasecmp( filter[i], "FFmpegSource", 12 ) )
{
x264_cli_printf( X264_LOG_INFO, "indexing... " );
fflush( stderr );
}
res = h->func.avs_invoke( h->env, filter[i], arg, NULL );
if( !avs_is_error( res ) )
{
x264_cli_printf( X264_LOG_INFO, "succeeded\n" );
break;
}
x264_cli_printf( X264_LOG_INFO, "failed\n" );
}
FAIL_IF_ERROR( !filter[i], "unable to find source filter to open `%s'\n", psz_filename )
}
FAIL_IF_ERROR( !avs_is_clip( res ), "`%s' didn't return a video clip\n", psz_filename )
h->clip = h->func.avs_take_clip( res, h->env );
const AVS_VideoInfo *vi = h->func.avs_get_video_info( h->clip );
FAIL_IF_ERROR( !avs_has_video( vi ), "`%s' has no video data\n", psz_filename )
/* if the clip is made of fields instead of frames, call weave to make them frames */
if( avs_is_field_based( vi ) )
{
x264_cli_log( "avs", X264_LOG_WARNING, "detected fieldbased (separated) input, weaving to frames\n" );
AVS_Value tmp = h->func.avs_invoke( h->env, "Weave", res, NULL );
FAIL_IF_ERROR( avs_is_error( tmp ), "couldn't weave fields into frames\n" )
res = update_clip( h, &vi, tmp, res );
info->interlaced = 1;
info->tff = avs_is_tff( vi );
}
#if !HAVE_SWSCALE
/* if swscale is not available, convert CSPs to yv12 */
if( !avs_is_yv12( vi ) )
{
x264_cli_log( "avs", X264_LOG_WARNING, "converting input clip to YV12\n" );
FAIL_IF_ERROR( vi->width&1 || vi->height&1, "input clip width or height not divisible by 2 (%dx%d)\n", vi->width, vi->height )
const char *arg_name[2] = { NULL, "interlaced" };
AVS_Value arg_arr[2] = { res, avs_new_value_bool( info->interlaced ) };
AVS_Value res2 = h->func.avs_invoke( h->env, "ConvertToYV12", avs_new_value_array( arg_arr, 2 ), arg_name );
FAIL_IF_ERROR( avs_is_error( res2 ), "couldn't convert input clip to YV12\n" )
res = update_clip( h, &vi, res2, res );
}
