forked from KolibriOS/kolibrios
754f9336f0
git-svn-id: svn://kolibrios.org@4349 a494cfbc-eb01-0410-851d-a64ba20cac60
99 lines
4.6 KiB
Plaintext
99 lines
4.6 KiB
Plaintext
The official guide to swscale for confused developers.
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========================================================
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Current (simplified) Architecture:
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---------------------------------
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Input
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v
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_______OR_________
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/ \
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/ \
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special converter [Input to YUV converter]
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| (8bit YUV 4:4:4 / 4:2:2 / 4:2:0 / 4:0:0 )
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| v
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| Horizontal scaler
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| (15bit YUV 4:4:4 / 4:2:2 / 4:2:0 / 4:1:1 / 4:0:0 )
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| v
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| Vertical scaler and output converter
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v v
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output
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Swscale has 2 scaler paths. Each side must be capable of handling
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slices, that is, consecutive non-overlapping rectangles of dimension
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(0,slice_top) - (picture_width, slice_bottom).
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special converter
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These generally are unscaled converters of common
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formats, like YUV 4:2:0/4:2:2 -> RGB12/15/16/24/32. Though it could also
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in principle contain scalers optimized for specific common cases.
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Main path
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The main path is used when no special converter can be used. The code
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is designed as a destination line pull architecture. That is, for each
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output line the vertical scaler pulls lines from a ring buffer. When
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the ring buffer does not contain the wanted line, then it is pulled from
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the input slice through the input converter and horizontal scaler.
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The result is also stored in the ring buffer to serve future vertical
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scaler requests.
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When no more output can be generated because lines from a future slice
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would be needed, then all remaining lines in the current slice are
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converted, horizontally scaled and put in the ring buffer.
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[This is done for luma and chroma, each with possibly different numbers
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of lines per picture.]
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Input to YUV Converter
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When the input to the main path is not planar 8 bits per component YUV or
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8-bit gray, it is converted to planar 8-bit YUV. Two sets of converters
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exist for this currently: One performs horizontal downscaling by 2
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before the conversion, the other leaves the full chroma resolution,
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but is slightly slower. The scaler will try to preserve full chroma
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when the output uses it. It is possible to force full chroma with
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SWS_FULL_CHR_H_INP even for cases where the scaler thinks it is useless.
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Horizontal scaler
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There are several horizontal scalers. A special case worth mentioning is
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the fast bilinear scaler that is made of runtime-generated MMXEXT code
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using specially tuned pshufw instructions.
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The remaining scalers are specially-tuned for various filter lengths.
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They scale 8-bit unsigned planar data to 16-bit signed planar data.
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Future >8 bits per component inputs will need to add a new horizontal
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scaler that preserves the input precision.
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Vertical scaler and output converter
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There is a large number of combined vertical scalers + output converters.
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Some are:
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* unscaled output converters
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* unscaled output converters that average 2 chroma lines
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* bilinear converters (C, MMX and accurate MMX)
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* arbitrary filter length converters (C, MMX and accurate MMX)
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And
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* Plain C 8-bit 4:2:2 YUV -> RGB converters using LUTs
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* Plain C 17-bit 4:4:4 YUV -> RGB converters using multiplies
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* MMX 11-bit 4:2:2 YUV -> RGB converters
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* Plain C 16-bit Y -> 16-bit gray
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...
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RGB with less than 8 bits per component uses dither to improve the
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subjective quality and low-frequency accuracy.
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Filter coefficients:
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--------------------
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There are several different scalers (bilinear, bicubic, lanczos, area,
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sinc, ...). Their coefficients are calculated in initFilter().
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Horizontal filter coefficients have a 1.0 point at 1 << 14, vertical ones at
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1 << 12. The 1.0 points have been chosen to maximize precision while leaving
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a little headroom for convolutional filters like sharpening filters and
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minimizing SIMD instructions needed to apply them.
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It would be trivial to use a different 1.0 point if some specific scaler
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would benefit from it.
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Also, as already hinted at, initFilter() accepts an optional convolutional
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filter as input that can be used for contrast, saturation, blur, sharpening
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shift, chroma vs. luma shift, ...
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