Resize

resize.Bilinear(vnode clip[, int width, int height, int format, enum matrix, enum transfer, enum primaries, enum range, enum chromaloc, enum matrix_in, enum transfer_in, enum primaries_in, enum range_in, enum chromaloc_in, float filter_param_a, float filter_param_b, string resample_filter_uv, float filter_param_a_uv, float filter_param_b_uv, string dither_type="none", string cpu_type, float src_left, float src_top, float src_width, float src_height, float nominal_luminance])
resize.Bicubic(vnode clip[, ...])
resize.Point(vnode clip[, ...])
resize.Lanczos(vnode clip[, ...])
resize.Spline16(vnode clip[, ...])
resize.Spline36(vnode clip[, ...])
resize.Spline64(vnode clip[, ...])
resize.Bob(vnode clip, string filter="bicubic", bint tff[, ...])

In VapourSynth the resizers have several functions. In addition to scaling, they also do colorspace conversions and conversions to and from the compat formats. Resize converts a clip of known or unknown format to another clip of known or unknown format, changing only the parameters specified by the user. The resize filters can handle varying size and format input clips and turn them into constant format clips.

If you do not know which resizer to choose, then try Bicubic. It usually makes a good neutral default.

Bob can be used as a rudimentary deinterlacer.

Arguments denoted as type enum may be specified by numerical index (see ITU-T H.265 Annex E.3) or by name. Enums specified by name have their argument name suffixed with “_s”. For example, a destination matrix of BT 709 can be specified either with matrix=1 or with matrix_s="709".

Note that matrix is not an optional argument when converting to YUV. Also note that if no matrix is specified in an input YUV frame’s properties then matrix_in also needs to be set.

The function will return an error if the subsampling restrictions aren’t followed.

If you get an error like:

Resize error 3074: no path between colorspaces (2/2/2 => 1/1/1).
May need to specify additional colorspace parameters.

It usually means the matrix/transfer/primaries are unknown and you have to specify the input colorspace parameters yourself. Note: 2 means “unspecified” according to the ITU-T recommendation.

Resizing is performed per-field for interlaced images, as indicated by the _FieldBased frame property. Source filters may sometimes mark progressive video as interlaced, which can result in sub-optimal resampling quality unless _FieldBased is cleared.

clip:

Accepts all kinds of input.

width, height:

Output image dimensions.

filter:

Scaling method for deinterlacing. See resample_filter_uv for accepted values.

tff:

Field order for deinterlacing. Used when the _FieldBased property is not set.

format:

Output format id.

matrix, transfer, primaries:

Output colorspace specification. If not provided, the corresponding attributes from the input clip will be selected, except for YCoCg and RGB color families, where the corresponding matrix is set by default.

range:

Output pixel range. For integer formats, this allows selection of the legal code values. Even when set, out of range values (BTB/WTW) may be generated. If the input format is of a different color family, the default range is studio/limited for YUV and full-range for RGB.

chromaloc:

Output chroma location. For subsampled formats, specifies the chroma location. If the input format is 4:4:4 or RGB and the output is subsampled, the default location is left-aligned, as per MPEG. Possible chroma locations (ITU-T H.265 Figure E.1): left, center, top_left, top, bottom_left, bottom

matrix_in, transfer_in, primaries_in, range_in, chromaloc_in:

Input colorspace/format specification. If the corresponding frame property is set to a value other than unspecified, the frame property is used instead of this parameter. Default values are set for certain color families. See the equivalent output arguments for more information.

filter_param_a, filter_param_b:

Parameters for the scaler used for RGB and Y-channel. For the bicubic filter, filter_param_a/b represent the “b” and “c” parameters. For the lanczos filter, filter_param_a represents the number of taps.

resample_filter_uv:

Scaling method for UV channels. It defaults to the same as for the Y-channel. The following values can be used with resample_filter_uv: point, bilinear, bicubic, spline16, spline36, lanczos.

filter_param_a_uv, filter_param_b_uv:

Parameters for the scaler used for UV channels.

dither_type:

Dithering method. Dithering is used only for conversions resulting in an integer format. The following dithering methods are available: none, ordered, random, error_diffusion.

cpu_type:

Only used for testing.

src_left, src_top, src_width, src_height:

Used to select the source region of the input to use. Can also be used to shift the image. Defaults to the whole image.

nominal_luminance:

Determines the physical brightness of the value 1.0. The unit is in cd/m^2.

To convert to YV12:

Bicubic(clip=clip, format=vs.YUV420P8, matrix_s="709")

To resize and convert YUV with color information frame properties to planar RGB:

Bicubic(clip=clip, width=1920, height=1080, format=vs.RGB24)

To resize and convert YUV without color information frame properties to planar RGB:

Bicubic(clip=clip, width=1920, height=1080, format=vs.RGB24, matrix_in_s="709")

The following tables list values of selected colorspace enumerations and their abbreviated names. (Numerical value in parentheses.) For all possible values, see ITU-T H.265.

Matrix coefficients (ITU-T H.265 Table E.5):

rgb (0)        Identity
               The identity matrix.
               Typically used for GBR (often referred to as RGB);
               however, may also be used for YZX (often referred to as
               XYZ);
709 (1)        KR = 0.2126; KB = 0.0722
               ITU-R Rec. BT.709-5
unspec (2)     Unspecified
               Image characteristics are unknown or are determined by the
               application.
fcc (4)
470bg (5)      KR = 0.299; KB = 0.114
               ITU-R Rec. BT.470-6 System B, G (historical)
               (functionally the same as the value 6 (170m))
170m (6)       KR = 0.299; KB = 0.114
               SMPTE 170M (2004)
               (functionally the same as the value 5 (470bg))
240m (7)       SMPTE 240M
ycgco (8)      YCgCo
2020ncl (9)    KR = 0.2627; KB = 0.0593
               Rec. ITU-R BT.2020 non-constant luminance system
2020cl (10)    KR = 0.2627; KB = 0.0593
               Rec. ITU-R BT.2020 constant luminance system
chromancl (12) Chromaticity derived non-constant luminance system
chromacl (13)  Chromaticity derived constant luminance system
ictcp (14)     ICtCp

Transfer characteristics (ITU-T H.265 Table E.4):

709 (1)        V = a * Lc0.45 - ( a - 1 ) for 1 >= Lc >= b
               V = 4.500 * Lc for b > Lc >= 0
               Rec. ITU-R BT.709-5
               (functionally the same as the values 6 (601),
               14 (2020_10) and 15 (2020_12))
unspec (2)     Unspecified
               Image characteristics are unknown or are determined by the
               application.
470m (4)       ITU-R Rec. BT.470-6 System M
470bg (5)      ITU-R Rec. BT.470-6 System B, G (historical)
601 (6)        V = a * Lc0.45 - ( a - 1 ) for 1 >= Lc >= b
               V = 4.500 * Lc for b > Lc >= 0
               Rec. ITU-R BT.601-6 525 or 625
               (functionally the same as the values 1 (709),
               14 (2020_10) and 15 (2020_12))
240m (7)       SMPTE 240M
linear (8)     V = Lc for all values of Lc
               Linear transfer characteristics
log100 (9)     Log 1:100 contrast
log316 (10)    Log 1:316 contrast
xvycc (11)     IEC 61966-2-4
srgb (13)      IEC 61966-2-1
2020_10 (14)   V = a * Lc0.45 - ( a - 1 ) for 1 >= Lc >= b
               V = 4.500 * Lc for b > Lc >= 0
               Rec. ITU-R BT.2020
               (functionally the same as the values 1 (709),
               6 (601) and 15 (2020_12))
2020_12 (15)   V = a * Lc0.45 - ( a - 1 ) for 1 >= Lc >= b
               V = 4.500 * Lc for b > Lc >= 0
               Rec. ITU-R BT.2020
               (functionally the same as the values 1 (709),
               6 (601) and 14 (2020_10))
st2084 (16)    SMPTE ST 2084
std-b67 (18)   ARIB std-b67

Color primaries (ITU-T H.265 Table E.3):

709 (1)        primary x y
               green 0.300 0.600
               blue 0.150 0.060
               red 0.640 0.330
               white D65 0.3127 0.3290
               Rec. ITU-R BT.709-5
unspec (2)     Unspecified
               Image characteristics are unknown or are determined by the
               application.
470m (4)       ITU-R Rec. BT.470-6 System M
470bg (5)      ITU-R Rec. BT.470-6 System B, G (historical)
170m (6)       primary x y
               green 0.310 0.595
               blue 0.155 0.070
               red 0.630 0.340
               white D65 0.3127 0.3290
               SMPTE 170M (2004)
               (functionally the same as the value 7 (240m))
240m (7)       primary x y
               green 0.310 0.595
               blue 0.155 0.070
               red 0.630 0.340
               white D65 0.3127 0.3290
               SMPTE 240M (1999)
               (functionally the same as the value 6 (170m))
film (8)
2020 (9)       primary x y
               green 0.170 0.797
               blue 0.131 0.046
               red 0.708 0.292
               white D65 0.3127 0.3290
               Rec. ITU-R BT.2020
st428 (10)     Commonly known as xyz
xyz (10)       Alias for st428
st431-2 (11)   DCI-P3 with traditional white point
st432-1 (12)   DCI-P3
jedec-p22 (22) E.B.U. STANDARD FOR CHROMATICITY TOLERANCES FOR STUDIO MONITORS (3213-E)
               Also known as JEDEC P22

Pixel range (ITU-T H.265 Eq E-4 to E-15):

limited (0) Studio (TV) legal range, 16-235 in 8 bits.
            Y = Clip1Y( Round( ( 1 << ( BitDepthY - 8 ) ) *
                                      ( 219 * E'Y + 16 ) ) )
            Cb = Clip1C( Round( ( 1 << ( BitDepthC - 8 ) ) *
                                       ( 224 * E'PB + 128 ) ) )
            Cr = Clip1C( Round( ( 1 << ( BitDepthC - 8 ) ) *
                                       ( 224 * E'PR + 128 ) ) )

            R = Clip1Y( ( 1 << ( BitDepthY - 8 ) ) *
                               ( 219 * E'R + 16 ) )
            G = Clip1Y( ( 1 << ( BitDepthY - 8 ) ) *
                               ( 219 * E'G + 16 ) )
            B = Clip1Y( ( 1 << ( BitDepthY - 8 ) ) *
                               ( 219 * E'B + 16 ) )
full (1)    Full (PC) dynamic range, 0-255 in 8 bits.
            Y = Clip1Y( Round( ( ( 1 << BitDepthY ) - 1 ) * E'Y ) )
            Cb = Clip1C( Round( ( ( 1 << BitDepthC ) - 1 ) * E'PB +
                                  ( 1 << ( BitDepthC - 1 ) ) ) )
            Cr = Clip1C( Round( ( ( 1 << BitDepthC ) - 1 ) * E'PR +
                                  ( 1 << ( BitDepthC - 1 ) ) ) )

            R = Clip1Y( ( ( 1 << BitDepthY ) - 1 ) * E'R )
            G = Clip1Y( ( ( 1 << BitDepthY ) - 1 ) * E'G )
            B = Clip1Y( ( ( 1 << BitDepthY ) - 1 ) * E'B )