// Copyright 2010 The Freetype-Go Authors. All rights reserved. // Use of this source code is governed by your choice of either the // FreeType License or the GNU General Public License version 2 (or // any later version), both of which can be found in the LICENSE file. package raster import ( "image" "image/color" "image/draw" "math" ) // A Span is a horizontal segment of pixels with constant alpha. X0 is an // inclusive bound and X1 is exclusive, the same as for slices. A fully opaque // Span has Alpha == 0xffff. type Span struct { Y, X0, X1 int Alpha uint32 } // A Painter knows how to paint a batch of Spans. Rasterization may involve // Painting multiple batches, and done will be true for the final batch. The // Spans' Y values are monotonically increasing during a rasterization. Paint // may use all of ss as scratch space during the call. type Painter interface { Paint(ss []Span, done bool) } // The PainterFunc type adapts an ordinary function to the Painter interface. type PainterFunc func(ss []Span, done bool) // Paint just delegates the call to f. func (f PainterFunc) Paint(ss []Span, done bool) { f(ss, done) } // An AlphaOverPainter is a Painter that paints Spans onto a *image.Alpha using // the Over Porter-Duff composition operator. type AlphaOverPainter struct { Image *image.Alpha } // Paint satisfies the Painter interface. func (r AlphaOverPainter) Paint(ss []Span, done bool) { b := r.Image.Bounds() for _, s := range ss { if s.Y < b.Min.Y { continue } if s.Y >= b.Max.Y { return } if s.X0 < b.Min.X { s.X0 = b.Min.X } if s.X1 > b.Max.X { s.X1 = b.Max.X } if s.X0 >= s.X1 { continue } base := (s.Y-r.Image.Rect.Min.Y)*r.Image.Stride - r.Image.Rect.Min.X p := r.Image.Pix[base+s.X0 : base+s.X1] a := int(s.Alpha >> 8) for i, c := range p { v := int(c) p[i] = uint8((v*255 + (255-v)*a) / 255) } } } // NewAlphaOverPainter creates a new AlphaOverPainter for the given image. func NewAlphaOverPainter(m *image.Alpha) AlphaOverPainter { return AlphaOverPainter{m} } // An AlphaSrcPainter is a Painter that paints Spans onto a *image.Alpha using // the Src Porter-Duff composition operator. type AlphaSrcPainter struct { Image *image.Alpha } // Paint satisfies the Painter interface. func (r AlphaSrcPainter) Paint(ss []Span, done bool) { b := r.Image.Bounds() for _, s := range ss { if s.Y < b.Min.Y { continue } if s.Y >= b.Max.Y { return } if s.X0 < b.Min.X { s.X0 = b.Min.X } if s.X1 > b.Max.X { s.X1 = b.Max.X } if s.X0 >= s.X1 { continue } base := (s.Y-r.Image.Rect.Min.Y)*r.Image.Stride - r.Image.Rect.Min.X p := r.Image.Pix[base+s.X0 : base+s.X1] color := uint8(s.Alpha >> 8) for i := range p { p[i] = color } } } // NewAlphaSrcPainter creates a new AlphaSrcPainter for the given image. func NewAlphaSrcPainter(m *image.Alpha) AlphaSrcPainter { return AlphaSrcPainter{m} } // An RGBAPainter is a Painter that paints Spans onto a *image.RGBA. type RGBAPainter struct { // Image is the image to compose onto. Image *image.RGBA // Op is the Porter-Duff composition operator. Op draw.Op // cr, cg, cb and ca are the 16-bit color to paint the spans. cr, cg, cb, ca uint32 } // Paint satisfies the Painter interface. func (r *RGBAPainter) Paint(ss []Span, done bool) { b := r.Image.Bounds() for _, s := range ss { if s.Y < b.Min.Y { continue } if s.Y >= b.Max.Y { return } if s.X0 < b.Min.X { s.X0 = b.Min.X } if s.X1 > b.Max.X { s.X1 = b.Max.X } if s.X0 >= s.X1 { continue } // This code mimics drawGlyphOver in $GOROOT/src/image/draw/draw.go. ma := s.Alpha const m = 1<<16 - 1 i0 := (s.Y-r.Image.Rect.Min.Y)*r.Image.Stride + (s.X0-r.Image.Rect.Min.X)*4 i1 := i0 + (s.X1-s.X0)*4 if r.Op == draw.Over { for i := i0; i < i1; i += 4 { dr := uint32(r.Image.Pix[i+0]) dg := uint32(r.Image.Pix[i+1]) db := uint32(r.Image.Pix[i+2]) da := uint32(r.Image.Pix[i+3]) a := (m - (r.ca * ma / m)) * 0x101 r.Image.Pix[i+0] = uint8((dr*a + r.cr*ma) / m >> 8) r.Image.Pix[i+1] = uint8((dg*a + r.cg*ma) / m >> 8) r.Image.Pix[i+2] = uint8((db*a + r.cb*ma) / m >> 8) r.Image.Pix[i+3] = uint8((da*a + r.ca*ma) / m >> 8) } } else { for i := i0; i < i1; i += 4 { r.Image.Pix[i+0] = uint8(r.cr * ma / m >> 8) r.Image.Pix[i+1] = uint8(r.cg * ma / m >> 8) r.Image.Pix[i+2] = uint8(r.cb * ma / m >> 8) r.Image.Pix[i+3] = uint8(r.ca * ma / m >> 8) } } } } // SetColor sets the color to paint the spans. func (r *RGBAPainter) SetColor(c color.Color) { r.cr, r.cg, r.cb, r.ca = c.RGBA() } // NewRGBAPainter creates a new RGBAPainter for the given image. func NewRGBAPainter(m *image.RGBA) *RGBAPainter { return &RGBAPainter{Image: m} } //An GrayPainter is a Painter that paints Spans onto a *image.Gray. type GrayPainter struct { // Image is the image to compose onto. Image *image.Gray //cy is the 8-bit color to paint the spans. cy uint8 } // Paint satisfies the Painter interface. func (r GrayPainter) Paint(ss []Span, done bool) { b := r.Image.Bounds() for _, s := range ss { if s.Y < b.Min.Y { continue } if s.Y >= b.Max.Y { return } if s.X0 < b.Min.X { s.X0 = b.Min.X } if s.X1 > b.Max.X { s.X1 = b.Max.X } if s.X0 >= s.X1 { continue } base := (s.Y-r.Image.Rect.Min.Y)*r.Image.Stride - r.Image.Rect.Min.X p := r.Image.Pix[base+s.X0 : base+s.X1] color := r.cy for i := range p { p[i] = color } } } // SetColor sets the color to paint the spans. func (r *GrayPainter) SetColor(c color.Color) { c1 := color.GrayModel.Convert(c).(color.Gray).Y r.cy = c1 } //NewGRAYPainter creates a new GrayPainter for the given image func NewGRAYPainter(m *image.Gray) *GrayPainter { return &GrayPainter{Image: m} } // A MonochromePainter wraps another Painter, quantizing each Span's alpha to // be either fully opaque or fully transparent. type MonochromePainter struct { Painter Painter y, x0, x1 int } // Paint delegates to the wrapped Painter after quantizing each Span's alpha // value and merging adjacent fully opaque Spans. func (m *MonochromePainter) Paint(ss []Span, done bool) { // We compact the ss slice, discarding any Spans whose alpha quantizes to zero. j := 0 for _, s := range ss { if s.Alpha >= 0x8000 { if m.y == s.Y && m.x1 == s.X0 { m.x1 = s.X1 } else { ss[j] = Span{m.y, m.x0, m.x1, 1<<16 - 1} j++ m.y, m.x0, m.x1 = s.Y, s.X0, s.X1 } } } if done { // Flush the accumulated Span. finalSpan := Span{m.y, m.x0, m.x1, 1<<16 - 1} if j < len(ss) { ss[j] = finalSpan j++ m.Painter.Paint(ss[:j], true) } else if j == len(ss) { m.Painter.Paint(ss, false) if cap(ss) > 0 { ss = ss[:1] } else { ss = make([]Span, 1) } ss[0] = finalSpan m.Painter.Paint(ss, true) } else { panic("unreachable") } // Reset the accumulator, so that this Painter can be re-used. m.y, m.x0, m.x1 = 0, 0, 0 } else { m.Painter.Paint(ss[:j], false) } } // NewMonochromePainter creates a new MonochromePainter that wraps the given // Painter. func NewMonochromePainter(p Painter) *MonochromePainter { return &MonochromePainter{Painter: p} } // A GammaCorrectionPainter wraps another Painter, performing gamma-correction // on each Span's alpha value. type GammaCorrectionPainter struct { // Painter is the wrapped Painter. Painter Painter // a is the precomputed alpha values for linear interpolation, with fully // opaque == 0xffff. a [256]uint16 // gammaIsOne is whether gamma correction is a no-op. gammaIsOne bool } // Paint delegates to the wrapped Painter after performing gamma-correction on // each Span. func (g *GammaCorrectionPainter) Paint(ss []Span, done bool) { if !g.gammaIsOne { const n = 0x101 for i, s := range ss { if s.Alpha == 0 || s.Alpha == 0xffff { continue } p, q := s.Alpha/n, s.Alpha%n // The resultant alpha is a linear interpolation of g.a[p] and g.a[p+1]. a := uint32(g.a[p])*(n-q) + uint32(g.a[p+1])*q ss[i].Alpha = (a + n/2) / n } } g.Painter.Paint(ss, done) } // SetGamma sets the gamma value. func (g *GammaCorrectionPainter) SetGamma(gamma float64) { g.gammaIsOne = gamma == 1 if g.gammaIsOne { return } for i := 0; i < 256; i++ { a := float64(i) / 0xff a = math.Pow(a, gamma) g.a[i] = uint16(0xffff * a) } } // NewGammaCorrectionPainter creates a new GammaCorrectionPainter that wraps // the given Painter. func NewGammaCorrectionPainter(p Painter, gamma float64) *GammaCorrectionPainter { g := &GammaCorrectionPainter{Painter: p} g.SetGamma(gamma) return g }