// Copyright 2015 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package plan9font implements font faces for the Plan 9 font and subfont file // formats. These formats are described at // http://plan9.bell-labs.com/magic/man2html/6/font package plan9font // import "golang.org/x/image/font/plan9font" import ( "bytes" "errors" "fmt" "image" "image/color" "log" "strconv" "strings" "golang.org/x/image/font" "golang.org/x/image/math/fixed" ) // fontchar describes one character glyph in a subfont. // // For more detail, look for "struct Fontchar" in // http://plan9.bell-labs.com/magic/man2html/2/cachechars type fontchar struct { x uint32 // X position in the image holding the glyphs. top uint8 // First non-zero scan line. bottom uint8 // Last non-zero scan line. left int8 // Offset of baseline. width uint8 // Width of baseline. } func parseFontchars(p []byte) []fontchar { fc := make([]fontchar, len(p)/6) for i := range fc { fc[i] = fontchar{ x: uint32(p[0]) | uint32(p[1])<<8, top: uint8(p[2]), bottom: uint8(p[3]), left: int8(p[4]), width: uint8(p[5]), } p = p[6:] } return fc } // subface implements font.Face for a Plan 9 subfont. type subface struct { firstRune rune // First rune in the subfont. n int // Number of characters in the subfont. height int // Inter-line spacing. ascent int // Height above the baseline. fontchars []fontchar // Character descriptions. img *image.Alpha // Image holding the glyphs. } func (f *subface) Close() error { return nil } func (f *subface) Kern(r0, r1 rune) fixed.Int26_6 { return 0 } func (f *subface) Metrics() font.Metrics { // Approximate XHeight with the ascent of lowercase 'x'. xbounds, _, _ := f.GlyphBounds('x') // The same applies to CapHeight, using the uppercase 'H'. hbounds, _, _ := f.GlyphBounds('H') return font.Metrics{ Height: fixed.I(f.height), Ascent: fixed.I(f.ascent), Descent: fixed.I(f.height - f.ascent), XHeight: -xbounds.Min.Y, CapHeight: -hbounds.Min.Y, } } func (f *subface) Glyph(dot fixed.Point26_6, r rune) ( dr image.Rectangle, mask image.Image, maskp image.Point, advance fixed.Int26_6, ok bool) { r -= f.firstRune if r < 0 || f.n <= int(r) { return image.Rectangle{}, nil, image.Point{}, 0, false } i := &f.fontchars[r+0] j := &f.fontchars[r+1] minX := int(dot.X+32)>>6 + int(i.left) minY := int(dot.Y+32)>>6 + int(i.top) - f.ascent dr = image.Rectangle{ Min: image.Point{ X: minX, Y: minY, }, Max: image.Point{ X: minX + int(j.x-i.x), Y: minY + int(i.bottom) - int(i.top), }, } return dr, f.img, image.Point{int(i.x), int(i.top)}, fixed.Int26_6(i.width) << 6, true } func (f *subface) GlyphBounds(r rune) (bounds fixed.Rectangle26_6, advance fixed.Int26_6, ok bool) { r -= f.firstRune if r < 0 || f.n <= int(r) { return fixed.Rectangle26_6{}, 0, false } i := &f.fontchars[r+0] j := &f.fontchars[r+1] bounds = fixed.R( int(i.left), int(i.top)-f.ascent, int(i.left)+int(j.x-i.x), int(i.bottom)-f.ascent, ) return bounds, fixed.Int26_6(i.width) << 6, true } func (f *subface) GlyphAdvance(r rune) (advance fixed.Int26_6, ok bool) { r -= f.firstRune if r < 0 || f.n <= int(r) { return 0, false } return fixed.Int26_6(f.fontchars[r].width) << 6, true } // runeRange maps a single rune range [lo, hi] to a lazily loaded subface. Both // ends of the range are inclusive. type runeRange struct { lo, hi rune offset rune // subfont index that the lo rune maps to. relFilename string subface *subface bad bool } // face implements font.Face for a Plan 9 font. // // It maps multiple rune ranges to *subface values. Rune ranges may overlap; // the first match wins. type face struct { height int ascent int readFile func(relFilename string) ([]byte, error) runeRanges []runeRange } func (f *face) Close() error { return nil } func (f *face) Kern(r0, r1 rune) fixed.Int26_6 { return 0 } func (f *face) Metrics() font.Metrics { xbounds, _, _ := f.GlyphBounds('x') hbounds, _, _ := f.GlyphBounds('H') return font.Metrics{ Height: fixed.I(f.height), Ascent: fixed.I(f.ascent), Descent: fixed.I(f.height - f.ascent), XHeight: -xbounds.Min.Y, CapHeight: -hbounds.Min.Y, } } func (f *face) Glyph(dot fixed.Point26_6, r rune) ( dr image.Rectangle, mask image.Image, maskp image.Point, advance fixed.Int26_6, ok bool) { if s, rr := f.subface(r); s != nil { return s.Glyph(dot, rr) } return image.Rectangle{}, nil, image.Point{}, 0, false } func (f *face) GlyphBounds(r rune) (bounds fixed.Rectangle26_6, advance fixed.Int26_6, ok bool) { if s, rr := f.subface(r); s != nil { return s.GlyphBounds(rr) } return fixed.Rectangle26_6{}, 0, false } func (f *face) GlyphAdvance(r rune) (advance fixed.Int26_6, ok bool) { if s, rr := f.subface(r); s != nil { return s.GlyphAdvance(rr) } return 0, false } // For subfont files, if reading the given file name fails, we try appending // ".n" where n is the log2 of the grayscale depth in bits (so at most 3) and // then work down to 0. This was done in Plan 9 when antialiased fonts were // introduced so that the 1-bit displays could keep using the 1-bit forms but // higher depth displays could use the antialiased forms. var subfontSuffixes = [...]string{ "", ".3", ".2", ".1", ".0", } func (f *face) readSubfontFile(name string) ([]byte, error) { var firstErr error for _, suffix := range subfontSuffixes { if b, err := f.readFile(name + suffix); err == nil { return b, nil } else if firstErr == nil { firstErr = err } } return nil, firstErr } func (f *face) subface(r rune) (*subface, rune) { // Fall back on U+FFFD if we can't find r. for _, rr := range [2]rune{r, '\ufffd'} { // We have to do linear, not binary search. plan9port's // lucsans/unicode.8.font says: // 0x2591 0x2593 ../luc/Altshades.7.0 // 0x2500 0x25ee ../luc/FormBlock.7.0 // and the rune ranges overlap. for i := range f.runeRanges { x := &f.runeRanges[i] if rr < x.lo || x.hi < rr || x.bad { continue } if x.subface == nil { data, err := f.readSubfontFile(x.relFilename) if err != nil { log.Printf("plan9font: couldn't read subfont %q: %v", x.relFilename, err) x.bad = true continue } sub, err := ParseSubfont(data, x.lo-x.offset) if err != nil { log.Printf("plan9font: couldn't parse subfont %q: %v", x.relFilename, err) x.bad = true continue } x.subface = sub.(*subface) } return x.subface, rr } } return nil, 0 } // ParseFont parses a Plan 9 font file. data is the contents of that font file, // which gives relative filenames for subfont files. readFile returns the // contents of those subfont files. It is similar to io/ioutil's ReadFile // function, except that it takes a relative filename instead of an absolute // one. func ParseFont(data []byte, readFile func(relFilename string) ([]byte, error)) (font.Face, error) { f := &face{ readFile: readFile, } // TODO: don't use strconv, to avoid the conversions from []byte to string? for first := true; len(data) > 0; first = false { i := bytes.IndexByte(data, '\n') if i < 0 { return nil, errors.New("plan9font: invalid font: no final newline") } row := string(data[:i]) data = data[i+1:] if first { height, s, ok := nextInt32(row) if !ok { return nil, fmt.Errorf("plan9font: invalid font: invalid header %q", row) } ascent, s, ok := nextInt32(s) if !ok { return nil, fmt.Errorf("plan9font: invalid font: invalid header %q", row) } if height < 0 || 0xffff < height || ascent < 0 || 0xffff < ascent { return nil, fmt.Errorf("plan9font: invalid font: invalid header %q", row) } f.height, f.ascent = int(height), int(ascent) continue } lo, s, ok := nextInt32(row) if !ok { return nil, fmt.Errorf("plan9font: invalid font: invalid row %q", row) } hi, s, ok := nextInt32(s) if !ok { return nil, fmt.Errorf("plan9font: invalid font: invalid row %q", row) } offset, s, _ := nextInt32(s) f.runeRanges = append(f.runeRanges, runeRange{ lo: lo, hi: hi, offset: offset, relFilename: s, }) } return f, nil } func nextInt32(s string) (ret int32, remaining string, ok bool) { i := 0 for ; i < len(s) && s[i] <= ' '; i++ { } j := i for ; j < len(s) && s[j] > ' '; j++ { } n, err := strconv.ParseInt(s[i:j], 0, 32) if err != nil { return 0, s, false } for ; j < len(s) && s[j] <= ' '; j++ { } return int32(n), s[j:], true } // ParseSubfont parses a Plan 9 subfont file. // // firstRune is the first rune in the subfont file. For example, the // Phonetic.6.0 subfont, containing glyphs in the range U+0250 to U+02E9, would // set firstRune to '\u0250'. func ParseSubfont(data []byte, firstRune rune) (font.Face, error) { data, m, err := parseImage(data) if err != nil { return nil, err } if len(data) < 3*12 { return nil, errors.New("plan9font: invalid subfont: header too short") } n := atoi(data[0*12:]) height := atoi(data[1*12:]) ascent := atoi(data[2*12:]) data = data[3*12:] if len(data) != 6*(n+1) { return nil, errors.New("plan9font: invalid subfont: data length mismatch") } // Convert from plan9Image to image.Alpha, as the standard library's // image/draw package works best when glyph masks are of that type. img := image.NewAlpha(m.Bounds()) for y := img.Rect.Min.Y; y < img.Rect.Max.Y; y++ { i := img.PixOffset(img.Rect.Min.X, y) for x := img.Rect.Min.X; x < img.Rect.Max.X; x++ { img.Pix[i] = m.at(x, y) i++ } } return &subface{ firstRune: firstRune, n: n, height: height, ascent: ascent, fontchars: parseFontchars(data), img: img, }, nil } // plan9Image implements that subset of the Plan 9 image feature set that is // used by this font file format. // // Some features, such as the repl bit and a clip rectangle, are omitted for // simplicity. type plan9Image struct { depth int // Depth of the pixels in bits. width int // Width in bytes of a single scan line. rect image.Rectangle // Extent of the image. pix []byte // Pixel bits. } func (m *plan9Image) byteoffset(x, y int) int { a := y * m.width if m.depth < 8 { // We need to always round down, but Go rounds toward zero. np := 8 / m.depth if x < 0 { return a + (x-np+1)/np } return a + x/np } return a + x*(m.depth/8) } func (m *plan9Image) Bounds() image.Rectangle { return m.rect } func (m *plan9Image) ColorModel() color.Model { return color.AlphaModel } func (m *plan9Image) At(x, y int) color.Color { if (image.Point{x, y}).In(m.rect) { return color.Alpha{m.at(x, y)} } return color.Alpha{0x00} } func (m *plan9Image) at(x, y int) uint8 { b := m.pix[m.byteoffset(x, y)] switch m.depth { case 1: // CGrey, 1. mask := uint8(1 << uint8(7-x&7)) if (b & mask) != 0 { return 0xff } return 0 case 2: // CGrey, 2. shift := uint(x&3) << 1 // Place pixel at top of word. y := b << shift y &= 0xc0 // Replicate throughout. y |= y >> 2 y |= y >> 4 return y } return 0 } var compressed = []byte("compressed\n") func parseImage(data []byte) (remainingData []byte, m *plan9Image, retErr error) { if !bytes.HasPrefix(data, compressed) { return nil, nil, errors.New("plan9font: unsupported uncompressed format") } data = data[len(compressed):] const hdrSize = 5 * 12 if len(data) < hdrSize { return nil, nil, errors.New("plan9font: invalid image: header too short") } hdr, data := data[:hdrSize], data[hdrSize:] // Distinguish new channel descriptor from old ldepth. Channel descriptors // have letters as well as numbers, while ldepths are a single digit // formatted as %-11d. new := false for m := 0; m < 10; m++ { if hdr[m] != ' ' { new = true break } } if hdr[11] != ' ' { return nil, nil, errors.New("plan9font: invalid image: bad header") } if !new { return nil, nil, errors.New("plan9font: unsupported ldepth format") } depth := 0 switch s := strings.TrimSpace(string(hdr[:1*12])); s { default: return nil, nil, fmt.Errorf("plan9font: unsupported pixel format %q", s) case "k1": depth = 1 case "k2": depth = 2 } r := ator(hdr[1*12:]) if r.Min.X > r.Max.X || r.Min.Y > r.Max.Y { return nil, nil, errors.New("plan9font: invalid image: bad rectangle") } width := bytesPerLine(r, depth) m = &plan9Image{ depth: depth, width: width, rect: r, pix: make([]byte, width*r.Dy()), } miny := r.Min.Y for miny != r.Max.Y { if len(data) < 2*12 { return nil, nil, errors.New("plan9font: invalid image: data band too short") } maxy := atoi(data[0*12:]) nb := atoi(data[1*12:]) data = data[2*12:] if len(data) < nb { return nil, nil, errors.New("plan9font: invalid image: data band length mismatch") } buf := data[:nb] data = data[nb:] if maxy <= miny || r.Max.Y < maxy { return nil, nil, fmt.Errorf("plan9font: bad maxy %d", maxy) } // An old-format image would flip the bits here, but we don't support // the old format. rr := r rr.Min.Y = miny rr.Max.Y = maxy if err := decompress(m, rr, buf); err != nil { return nil, nil, err } miny = maxy } return data, m, nil } // Compressed data are sequences of byte codes. If the first byte b has the // 0x80 bit set, the next (b^0x80)+1 bytes are data. Otherwise, these two bytes // specify a previous string to repeat. const ( compShortestMatch = 3 // shortest match possible. compWindowSize = 1024 // window size. ) var ( errDecompressBufferTooSmall = errors.New("plan9font: decompress: buffer too small") errDecompressPhaseError = errors.New("plan9font: decompress: phase error") ) func decompress(m *plan9Image, r image.Rectangle, data []byte) error { if !r.In(m.rect) { return errors.New("plan9font: decompress: bad rectangle") } bpl := bytesPerLine(r, m.depth) mem := make([]byte, compWindowSize) memi := 0 omemi := -1 y := r.Min.Y linei := m.byteoffset(r.Min.X, y) eline := linei + bpl datai := 0 for { if linei == eline { y++ if y == r.Max.Y { break } linei = m.byteoffset(r.Min.X, y) eline = linei + bpl } if datai == len(data) { return errDecompressBufferTooSmall } c := data[datai] datai++ if c >= 128 { for cnt := c - 128 + 1; cnt != 0; cnt-- { if datai == len(data) { return errDecompressBufferTooSmall } if linei == eline { return errDecompressPhaseError } m.pix[linei] = data[datai] linei++ mem[memi] = data[datai] memi++ datai++ if memi == len(mem) { memi = 0 } } } else { if datai == len(data) { return errDecompressBufferTooSmall } offs := int(data[datai]) + ((int(c) & 3) << 8) + 1 datai++ if memi < offs { omemi = memi + (compWindowSize - offs) } else { omemi = memi - offs } for cnt := (c >> 2) + compShortestMatch; cnt != 0; cnt-- { if linei == eline { return errDecompressPhaseError } m.pix[linei] = mem[omemi] linei++ mem[memi] = mem[omemi] memi++ omemi++ if omemi == len(mem) { omemi = 0 } if memi == len(mem) { memi = 0 } } } } return nil } func ator(b []byte) image.Rectangle { return image.Rectangle{atop(b), atop(b[2*12:])} } func atop(b []byte) image.Point { return image.Pt(atoi(b), atoi(b[12:])) } func atoi(b []byte) int { i := 0 for ; i < len(b) && b[i] == ' '; i++ { } n := 0 for ; i < len(b) && '0' <= b[i] && b[i] <= '9'; i++ { n = n*10 + int(b[i]) - '0' } return n } func bytesPerLine(r image.Rectangle, depth int) int { if depth <= 0 || 32 < depth { panic("invalid depth") } var l int if r.Min.X >= 0 { l = (r.Max.X*depth + 7) / 8 l -= (r.Min.X * depth) / 8 } else { // Make positive before divide. t := (-r.Min.X*depth + 7) / 8 l = t + (r.Max.X*depth+7)/8 } return l }