golang-freetype/freetype/truetype/glyph.go

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// 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 truetype
// A Point is a co-ordinate pair plus whether it is ``on'' a contour or an
// ``off'' control point.
type Point struct {
X, Y int16
// The Flags' LSB means whether or not this Point is ``on'' the contour.
// Other bits are reserved for internal use.
Flags uint8
}
// A GlyphBuf holds a glyph's contours. A GlyphBuf can be re-used to load a
// series of glyphs from a Font.
type GlyphBuf struct {
// The glyph's bounding box.
B Bounds
// Point contains all Points from all contours of the glyph.
Point []Point
// The length of End is the number of contours in the glyph. The i'th
// contour consists of points Point[End[i-1]:End[i]], where End[-1]
// is interpreted to mean zero.
End []int
}
// Flags for decoding a glyph's contours. These flags are documented at
// http://developer.apple.com/fonts/TTRefMan/RM06/Chap6glyf.html.
const (
flagOnCurve = 1 << iota
flagXShortVector
flagYShortVector
flagRepeat
flagPositiveXShortVector
flagPositiveYShortVector
)
// The same flag bits (0x10 and 0x20) are overloaded to have two meanings,
// dependent on the value of the flag{X,Y}ShortVector bits.
const (
flagThisXIsSame = flagPositiveXShortVector
flagThisYIsSame = flagPositiveYShortVector
)
// decodeFlags decodes a glyph's run-length encoded flags,
// and returns the remaining data.
func (g *GlyphBuf) decodeFlags(d data, np0 int) data {
for i := np0; i < len(g.Point); {
c := d.u8()
g.Point[i].Flags = c
i++
if c&flagRepeat != 0 {
count := d.u8()
for ; count > 0; count-- {
g.Point[i].Flags = c
i++
}
}
}
return d
}
// decodeCoords decodes a glyph's delta encoded co-ordinates.
func (g *GlyphBuf) decodeCoords(d data, np0 int) {
var x int16
for i := np0; i < len(g.Point); i++ {
f := g.Point[i].Flags
if f&flagXShortVector != 0 {
dx := int16(d.u8())
if f&flagPositiveXShortVector == 0 {
x -= dx
} else {
x += dx
}
} else if f&flagThisXIsSame == 0 {
x += int16(d.u16())
}
g.Point[i].X = x
}
var y int16
for i := np0; i < len(g.Point); i++ {
f := g.Point[i].Flags
if f&flagYShortVector != 0 {
dy := int16(d.u8())
if f&flagPositiveYShortVector == 0 {
y -= dy
} else {
y += dy
}
} else if f&flagThisYIsSame == 0 {
y += int16(d.u16())
}
g.Point[i].Y = y
}
}
// Load loads a glyph's contours from a Font, overwriting any previously
// loaded contours for this GlyphBuf.
func (g *GlyphBuf) Load(f *Font, i Index) error {
// Reset the GlyphBuf.
g.B = Bounds{}
g.Point = g.Point[0:0]
g.End = g.End[0:0]
return g.load(f, i, 0)
}
// loadCompound loads a glyph that is composed of other glyphs.
func (g *GlyphBuf) loadCompound(f *Font, d data, recursion int) error {
// Flags for decoding a compound glyph. These flags are documented at
// http://developer.apple.com/fonts/TTRefMan/RM06/Chap6glyf.html.
const (
flagArg1And2AreWords = 1 << iota
flagArgsAreXYValues
flagRoundXYToGrid
flagWeHaveAScale
flagUnused
flagMoreComponents
flagWeHaveAnXAndYScale
flagWeHaveATwoByTwo
flagWeHaveInstructions
flagUseMyMetrics
flagOverlapCompound
)
for {
flags := d.u16()
component := d.u16()
var dx, dy int16
if flags&flagArg1And2AreWords != 0 {
dx = int16(d.u16())
dy = int16(d.u16())
} else {
dx = int16(int8(d.u8()))
dy = int16(int8(d.u8()))
}
if flags&flagArgsAreXYValues == 0 {
return UnsupportedError("compound glyph transform vector")
}
if flags&(flagWeHaveAScale|flagWeHaveAnXAndYScale|flagWeHaveATwoByTwo) != 0 {
return UnsupportedError("compound glyph scale/transform")
}
b0, i0 := g.B, len(g.Point)
g.load(f, Index(component), recursion+1)
for i := i0; i < len(g.Point); i++ {
g.Point[i].X += dx
g.Point[i].Y += dy
}
if flags&flagUseMyMetrics == 0 {
g.B = b0
}
if flags&flagMoreComponents == 0 {
break
}
}
return nil
}
// load appends a glyph's contours to this GlyphBuf.
func (g *GlyphBuf) load(f *Font, i Index, recursion int) error {
if recursion >= 4 {
return UnsupportedError("excessive compound glyph recursion")
}
// Find the relevant slice of f.glyf.
var g0, g1 uint32
if f.locaOffsetFormat == locaOffsetFormatShort {
d := data(f.loca[2*int(i):])
g0 = 2 * uint32(d.u16())
g1 = 2 * uint32(d.u16())
} else {
d := data(f.loca[4*int(i):])
g0 = d.u32()
g1 = d.u32()
}
if g0 == g1 {
return nil
}
d := data(f.glyf[g0:g1])
// Decode the contour end indices.
ne := int(int16(d.u16()))
g.B.XMin = int16(d.u16())
g.B.YMin = int16(d.u16())
g.B.XMax = int16(d.u16())
g.B.YMax = int16(d.u16())
if ne == -1 {
return g.loadCompound(f, d, recursion)
} else if ne < 0 {
// http://developer.apple.com/fonts/TTRefMan/RM06/Chap6glyf.html says that
// "the values -2, -3, and so forth, are reserved for future use."
return UnsupportedError("negative number of contours")
}
ne0, np0 := len(g.End), len(g.Point)
ne += ne0
if ne <= cap(g.End) {
g.End = g.End[0:ne]
} else {
g.End = make([]int, ne, ne*2)
}
for i := ne0; i < ne; i++ {
g.End[i] = 1 + np0 + int(d.u16())
}
// Skip the TrueType hinting instructions.
instrLen := int(d.u16())
d.skip(instrLen)
// Decode the points.
np := int(g.End[ne-1])
if np <= cap(g.Point) {
g.Point = g.Point[0:np]
} else {
g.Point = make([]Point, np, np*2)
}
d = g.decodeFlags(d, np0)
g.decodeCoords(d, np0)
return nil
}
// NewGlyphBuf returns a newly allocated GlyphBuf.
func NewGlyphBuf() *GlyphBuf {
g := new(GlyphBuf)
g.Point = make([]Point, 0, 256)
g.End = make([]int, 0, 32)
return g
}