Пример #1
0
// Save returns an Image compressed using the given SaveOptions as a byte slice.
func Save(image *vips.Image, options SaveOptions) ([]byte, error) {
	if options.Quality < 1 || options.Quality > 100 {
		options.Quality = DefaultQuality
	}

	if options.Compression < 1 || options.Compression > 9 {
		options.Compression = DefaultCompression
	}

	// Make a decision on image format and whether we're using lossless.
	if options.Format == Unknown {
		if options.AllowWebp {
			options.Format = Webp
		} else if image.HasAlpha() || useLossless(image, options) {
			options.Format = Png
		} else {
			options.Format = Jpeg
		}
	} else if options.Format == Webp && !useLossless(image, options) {
		options.Lossless = false
	}

	switch options.Format {
	case Jpeg:
		return jpegSave(image, options)
	case Png:
		return pngSave(image, options)
	case Webp:
		return webpSave(image, options)
	default:
		return nil, ErrInvalidSaveFormat
	}
}
Пример #2
0
// DetectOrientation detects the current Image Orientation from the EXIF header.
func DetectOrientation(image *vips.Image) Orientation {
	o, ok := image.ImageGetAsString(vips.ExifOrientation)
	if !ok || o == "" {
		return Undefined
	}

	orientation, err := strconv.Atoi(o[:1])
	if err != nil || orientation <= 0 || orientation >= len(orientationInfo) {
		return Undefined
	}

	return Orientation(orientation)
}
Пример #3
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func crop(image *vips.Image, ow, oh int) error {
	m := format.MetadataImage(image)

	// If we have nothing to do, return.
	if ow == m.Width && oh == m.Height {
		return nil
	}

	// Center horizontally
	x := (m.Width - ow + 1) / 2
	// Assume faces are higher up vertically
	y := (m.Height - oh + 1) / 4

	if x < 0 || y < 0 {
		panic("Bad crop offsets!")
	}

	return image.ExtractArea(m.Orientation.Crop(ow, oh, x, y, m.Width, m.Height))
}
Пример #4
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// Apply executes a set of operations to change the pixel ordering from
// orientation to TopLeft.
func (orientation Orientation) Apply(image *vips.Image) error {
	oi := &orientationInfo[orientation]

	if oi.apply == nil {
		return nil
	}

	// We want to stay sequential, so we copy memory here and execute
	// all work in the pipeline so far.
	if err := image.Write(); err != nil {
		return err
	}

	if err := oi.apply(image); err != nil {
		return err
	}

	_ = image.ImageRemove(vips.ExifOrientation)

	return nil
}
Пример #5
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// MetadataImage returns Metadata from an Image. Format is always unset.
func MetadataImage(image *vips.Image) Metadata {
	o := DetectOrientation(image)
	w, h := o.Dimensions(image.Xsize(), image.Ysize())
	if w <= 0 || h <= 0 {
		panic("Invalid image dimensions.")
	}
	return Metadata{Width: w, Height: h, Orientation: o, HasAlpha: image.HasAlpha()}
}
Пример #6
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func minTransparency(image *vips.Image) (float64, error) {
	if !image.HasAlpha() {
		return 1.0, nil
	}

	band, err := image.Copy()
	if err != nil {
		return 0, err
	}
	defer band.Close()

	if err := band.ExtractBand(band.ImageGetBands()-1, 1); err != nil {
		return 0, err
	}

	// If all pixels are at least 90% opaque, we can flatten.
	min, err := band.Min()
	if err != nil {
		return 0, err
	}

	return min / band.MaxAlpha(), nil
}
Пример #7
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func jpegSave(image *vips.Image, options SaveOptions) ([]byte, error) {
	// JPEG interlace saves 2-3%, but incurs a few hundred bytes of
	// overhead, requires buffering the image completely in RAM for
	// encoding and decoding, and takes over 3x the CPU.  This isn't
	// usually beneficial on small images and is too expensive for large
	// images.
	pixels := image.Xsize() * image.Ysize()
	interlace := pixels >= 200*200 && pixels <= 1024*1024

	// Strip and optimize both save space, enable them.
	return image.JpegsaveBuffer(true, options.Quality, true, interlace)
}
Пример #8
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func useLossless(image *vips.Image, options SaveOptions) bool {
	if !options.Lossless {
		return false
	}

	if !options.LossyIfPhoto {
		return true
	}

	// Mobile devices start being unwilling to load >= 3 megapixel PNGs.
	// Also we don't want to bother to edge detect on large images.
	if image.Xsize()*image.Ysize() >= 3*1024*1024 {
		return false
	}

	// Take a histogram of a Sobel edge detect of our image.  What's the
	// highest number of histogram values in a row that are more than 1%
	// of the maximum value? Above 16 indicates a photo.
	metric, err := image.PhotoMetric(0.01)
	return err != nil || metric < 16
}
Пример #9
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func pngSave(image *vips.Image, options SaveOptions) ([]byte, error) {
	// PNG interlace is larger; don't use it.
	return image.PngsaveBuffer(true, options.Compression, false)
}
Пример #10
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func transverse(image *vips.Image) error {
	if err := image.Flip(vips.DirectionVertical); err != nil {
		return err
	}
	return image.Rot(vips.Angle270)
}
Пример #11
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func rot270(image *vips.Image) error {
	return image.Rot(vips.Angle270)
}
Пример #12
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func rot180(image *vips.Image) error {
	return image.Rot(vips.Angle180)
}
Пример #13
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func rot90(image *vips.Image) error {
	return image.Rot(vips.Angle90)
}
Пример #14
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func flop(image *vips.Image) error {
	return image.Flip(vips.DirectionHorizontal)
}
Пример #15
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func flip(image *vips.Image) error {
	return image.Flip(vips.DirectionVertical)
}
Пример #16
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func webpSave(image *vips.Image, options SaveOptions) ([]byte, error) {
	return image.WebpsaveBuffer(options.Quality, options.Lossless)
}
Пример #17
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func resize(image *vips.Image, iw, ih int, fastResize bool, blurSigma float64, sharpen bool) error {
	m := format.MetadataImage(image)

	// Interpolation of RGB values with an alpha channel isn't safe
	// unless the values are pre-multiplied. Undo this later.
	// This also flattens fully transparent pixels to black.
	premultiply := image.HasAlpha()
	if premultiply {
		if err := image.Premultiply(); err != nil {
			return err
		}
	}

	// A box filter will quickly get us within 2x of the final size, at some quality cost.
	if fastResize {
		// Shrink factors can be passed independently here, which
		// may not be sane since Resize()'s blur and sharpening
		// steps expect a normal aspect ratio.
		wshrink := math.Floor(float64(m.Width) / float64(iw))
		hshrink := math.Floor(float64(m.Height) / float64(ih))
		if wshrink >= 2 || hshrink >= 2 {
			// Shrink rounds down the number of pixels.
			if err := image.Shrink(wshrink, hshrink); err != nil {
				return err
			}
			m = format.MetadataImage(image)
		}
	}

	// If necessary, do a high-quality resize to scale to final size.
	if iw < m.Width || ih < m.Height {
		// Vips 8.3 sometimes produces 1px smaller images than desired without the rounding help here.
		if err := image.Resize((float64(iw)+vips.ResizeOffset)/float64(m.Width), (float64(ih)+vips.ResizeOffset)/float64(m.Height)); err != nil {
			return err
		}
	}

	if blurSigma > 0.0 {
		if err := image.Gaussblur(blurSigma); err != nil {
			return err
		}
	}

	if sharpen {
		if err := image.MildSharpen(); err != nil {
			return err
		}
	}

	// Unpremultiply after all operations that touch adjacent pixels.
	if premultiply {
		if err := image.Unpremultiply(); err != nil {
			return err
		}
	}

	return nil
}
Пример #18
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func srgb(image *vips.Image) error {
	// Transform from embedded ICC profile if present or default profile
	// if CMYK.  Ignore errors.
	if image.ImageFieldExists(vips.MetaIccName) {
		_ = image.IccTransform(sRgbFile, "", vips.IntentRelative)
	} else if image.ImageGuessInterpretation() == vips.InterpretationCMYK {
		_ = image.IccTransform(sRgbFile, cmykFile, vips.IntentRelative)
	}

	space := image.ImageGuessInterpretation()
	if space != vips.InterpretationSRGB && space != vips.InterpretationBW {
		if err := image.Colourspace(vips.InterpretationSRGB); err != nil {
			return err
		}
	}

	return nil
}