shiny/iconvg/buffer.go - exp - Git at Google

 // Copyright 2016 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 iconvg

 import (
 	"image/color"
 	"math"
 )

 // buffer holds an encoded IconVG graphic.
 //
 // The decodeXxx methods return the decoded value and an integer n, the number
 // of bytes that value was encoded in. They return n == 0 if an error occured.
 //
 // The encodeXxx methods append to the buffer, modifying the slice in place.
 type buffer []byte

 func (b buffer) decodeNatural() (u uint32, n int) {
 	if len(b) < 1 {
 		return 0, 0
 	}
 	x := b[0]
 	if x&0x01 == 0 {
 		return uint32(x) >> 1, 1
 	}
 	if x&0x02 == 0 {
 		if len(b) >= 2 {
 			y := uint16(b[0]) | uint16(b[1])<<8
 			return uint32(y) >> 2, 2
 		}
 		return 0, 0
 	}
 	if len(b) >= 4 {
 		y := uint32(b[0]) | uint32(b[1])<<8 | uint32(b[2])<<16 | uint32(b[3])<<24
 		return y >> 2, 4
 	}
 	return 0, 0
 }

 func (b buffer) decodeReal() (f float32, n int) {
 	switch u, n := b.decodeNatural(); n {
 	case 0:
 		return 0, n
 	case 1:
 		return float32(u), n
 	case 2:
 		return float32(u), n
 	default:
 		return math.Float32frombits(u << 2), n
 	}
 }

 func (b buffer) decodeCoordinate() (f float32, n int) {
 	switch u, n := b.decodeNatural(); n {
 	case 0:
 		return 0, n
 	case 1:
 		return float32(int32(u) - 64), n
 	case 2:
 		return float32(int32(u)-64*128) / 64, n
 	default:
 		return math.Float32frombits(u << 2), n
 	}
 }

 func (b buffer) decodeZeroToOne() (f float32, n int) {
 	switch u, n := b.decodeNatural(); n {
 	case 0:
 		return 0, n
 	case 1:
 		return float32(u) / 120, n
 	case 2:
 		return float32(u) / 15120, n
 	default:
 		return math.Float32frombits(u << 2), n
 	}
 }

 func (b buffer) decodeColor1() (c Color, n int) {
 	if len(b) < 1 {
 		return Color{}, 0
 	}
 	return decodeColor1(b[0]), 1
 }

 func (b buffer) decodeColor2() (c Color, n int) {
 	if len(b) < 2 {
 		return Color{}, 0
 	}
 	return RGBAColor(color.RGBA{
 		R: 0x11 * (b[0] >> 4),
 		G: 0x11 * (b[0] & 0x0f),
 		B: 0x11 * (b[1] >> 4),
 		A: 0x11 * (b[1] & 0x0f),
 	}), 2
 }

 func (b buffer) decodeColor3Direct() (c Color, n int) {
 	if len(b) < 3 {
 		return Color{}, 0
 	}
 	return RGBAColor(color.RGBA{
 		R: b[0],
 		G: b[1],
 		B: b[2],
 		A: 0xff,
 	}), 3
 }

 func (b buffer) decodeColor4() (c Color, n int) {
 	if len(b) < 4 {
 		return Color{}, 0
 	}
 	return RGBAColor(color.RGBA{
 		R: b[0],
 		G: b[1],
 		B: b[2],
 		A: b[3],
 	}), 4
 }

 func (b buffer) decodeColor3Indirect() (c Color, n int) {
 	if len(b) < 3 {
 		return Color{}, 0
 	}
 	return BlendColor(b[0], b[1], b[2]), 3
 }

 func (b *buffer) encodeNatural(u uint32) {
 	if u < 1<<7 {
 		u = (u << 1)
 		*b = append(*b, uint8(u))
 		return
 	}
 	if u < 1<<14 {
 		u = (u << 2) | 1
 		*b = append(*b, uint8(u), uint8(u>>8))
 		return
 	}
 	u = (u << 2) | 3
 	*b = append(*b, uint8(u), uint8(u>>8), uint8(u>>16), uint8(u>>24))
 }

 func (b *buffer) encodeReal(f float32) int {
 	if u := uint32(f); float32(u) == f && u < 1<<14 {
 		if u < 1<<7 {
 			u = (u << 1)
 			*b = append(*b, uint8(u))
 			return 1
 		}
 		u = (u << 2) | 1
 		*b = append(*b, uint8(u), uint8(u>>8))
 		return 2
 	}
 	b.encode4ByteReal(f)
 	return 4
 }

 func (b *buffer) encode4ByteReal(f float32) {
 	u := math.Float32bits(f)

 	// Round the fractional bits (the low 23 bits) to the nearest multiple of
 	// 4, being careful not to overflow into the upper bits.
 	v := u & 0x007fffff
 	if v < 0x007ffffe {
 		v += 2
 	}
 	u = (u & 0xff800000) | v

 	// A 4 byte encoding has the low two bits set.
 	u |= 0x03
 	*b = append(*b, uint8(u), uint8(u>>8), uint8(u>>16), uint8(u>>24))
 }

 func (b *buffer) encodeCoordinate(f float32) int {
 	if i := int32(f); -64 <= i && i < +64 && float32(i) == f {
 		u := uint32(i + 64)
 		u = (u << 1)
 		*b = append(*b, uint8(u))
 		return 1
 	}
 	if i := int32(f * 64); -128*64 <= i && i < +128*64 && float32(i) == f*64 {
 		u := uint32(i + 128*64)
 		u = (u << 2) | 1
 		*b = append(*b, uint8(u), uint8(u>>8))
 		return 2
 	}
 	b.encode4ByteReal(f)
 	return 4
 }

 func (b *buffer) encodeAngle(f float32) int {
 	// Normalize f to the range [0, 1).
 	g := float64(f)
 	g -= math.Floor(g)
 	return b.encodeZeroToOne(float32(g))
 }

 func (b *buffer) encodeZeroToOne(f float32) int {
 	if u := uint32(f * 15120); float32(u) == f*15120 && u < 15120 {
 		if u%126 == 0 {
 			u = ((u / 126) << 1)
 			*b = append(*b, uint8(u))
 			return 1
 		}
 		u = (u << 2) | 1
 		*b = append(*b, uint8(u), uint8(u>>8))
 		return 2
 	}
 	b.encode4ByteReal(f)
 	return 4
 }

 func (b *buffer) encodeColor1(c Color) {
 	if x, ok := encodeColor1(c); ok {
 		*b = append(*b, x)
 		return
 	}
 	// Default to opaque black.
 	*b = append(*b, 0x00)
 }

 func (b *buffer) encodeColor2(c Color) {
 	if x, ok := encodeColor2(c); ok {
 		*b = append(*b, x[0], x[1])
 		return
 	}
 	// Default to opaque black.
 	*b = append(*b, 0x00, 0x0f)
 }

 func (b *buffer) encodeColor3Direct(c Color) {
 	if x, ok := encodeColor3Direct(c); ok {
 		*b = append(*b, x[0], x[1], x[2])
 		return
 	}
 	// Default to opaque black.
 	*b = append(*b, 0x00, 0x00, 0x00)
 }

 func (b *buffer) encodeColor4(c Color) {
 	if x, ok := encodeColor4(c); ok {
 		*b = append(*b, x[0], x[1], x[2], x[3])
 		return
 	}
 	// Default to opaque black.
 	*b = append(*b, 0x00, 0x00, 0x00, 0xff)
 }

 func (b *buffer) encodeColor3Indirect(c Color) {
 	if x, ok := encodeColor3Indirect(c); ok {
 		*b = append(*b, x[0], x[1], x[2])
 		return
 	}
 	// Default to opaque black.
 	*b = append(*b, 0x00, 0x00, 0x00)
 }
	// Copyright 2016 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 iconvg

	import (
	"image/color"
	"math"
	)

	// buffer holds an encoded IconVG graphic.
	//
	// The decodeXxx methods return the decoded value and an integer n, the number
	// of bytes that value was encoded in. They return n == 0 if an error occured.
	//
	// The encodeXxx methods append to the buffer, modifying the slice in place.
	type buffer []byte

	func (b buffer) decodeNatural() (u uint32, n int) {
	if len(b) < 1 {
	return 0, 0
	}
	x := b[0]
	if x&0x01 == 0 {
	return uint32(x) >> 1, 1
	}
	if x&0x02 == 0 {
	if len(b) >= 2 {
	y := uint16(b[0]) \| uint16(b[1])<<8
	return uint32(y) >> 2, 2
	}
	return 0, 0
	}
	if len(b) >= 4 {
	y := uint32(b[0]) \| uint32(b[1])<<8 \| uint32(b[2])<<16 \| uint32(b[3])<<24
	return y >> 2, 4
	}
	return 0, 0
	}

	func (b buffer) decodeReal() (f float32, n int) {
	switch u, n := b.decodeNatural(); n {
	case 0:
	return 0, n
	case 1:
	return float32(u), n
	case 2:
	return float32(u), n
	default:
	return math.Float32frombits(u << 2), n
	}
	}

	func (b buffer) decodeCoordinate() (f float32, n int) {
	switch u, n := b.decodeNatural(); n {
	case 0:
	return 0, n
	case 1:
	return float32(int32(u) - 64), n
	case 2:
	return float32(int32(u)-64*128) / 64, n
	default:
	return math.Float32frombits(u << 2), n
	}
	}

	func (b buffer) decodeZeroToOne() (f float32, n int) {
	switch u, n := b.decodeNatural(); n {
	case 0:
	return 0, n
	case 1:
	return float32(u) / 120, n
	case 2:
	return float32(u) / 15120, n
	default:
	return math.Float32frombits(u << 2), n
	}
	}

	func (b buffer) decodeColor1() (c Color, n int) {
	if len(b) < 1 {
	return Color{}, 0
	}
	return decodeColor1(b[0]), 1
	}

	func (b buffer) decodeColor2() (c Color, n int) {
	if len(b) < 2 {
	return Color{}, 0
	}
	return RGBAColor(color.RGBA{
	R: 0x11 * (b[0] >> 4),
	G: 0x11 * (b[0] & 0x0f),
	B: 0x11 * (b[1] >> 4),
	A: 0x11 * (b[1] & 0x0f),
	}), 2
	}

	func (b buffer) decodeColor3Direct() (c Color, n int) {
	if len(b) < 3 {
	return Color{}, 0
	}
	return RGBAColor(color.RGBA{
	R: b[0],
	G: b[1],
	B: b[2],
	A: 0xff,
	}), 3
	}

	func (b buffer) decodeColor4() (c Color, n int) {
	if len(b) < 4 {
	return Color{}, 0
	}
	return RGBAColor(color.RGBA{
	R: b[0],
	G: b[1],
	B: b[2],
	A: b[3],
	}), 4
	}

	func (b buffer) decodeColor3Indirect() (c Color, n int) {
	if len(b) < 3 {
	return Color{}, 0
	}
	return BlendColor(b[0], b[1], b[2]), 3
	}

	func (b *buffer) encodeNatural(u uint32) {
	if u < 1<<7 {
	u = (u << 1)
	b = append(b, uint8(u))
	return
	}
	if u < 1<<14 {
	u = (u << 2) \| 1
	b = append(b, uint8(u), uint8(u>>8))
	return
	}
	u = (u << 2) \| 3
	b = append(b, uint8(u), uint8(u>>8), uint8(u>>16), uint8(u>>24))
	}

	func (b *buffer) encodeReal(f float32) int {
	if u := uint32(f); float32(u) == f && u < 1<<14 {
	if u < 1<<7 {
	u = (u << 1)
	b = append(b, uint8(u))
	return 1
	}
	u = (u << 2) \| 1
	b = append(b, uint8(u), uint8(u>>8))
	return 2
	}
	b.encode4ByteReal(f)
	return 4
	}

	func (b *buffer) encode4ByteReal(f float32) {
	u := math.Float32bits(f)

	// Round the fractional bits (the low 23 bits) to the nearest multiple of
	// 4, being careful not to overflow into the upper bits.
	v := u & 0x007fffff
	if v < 0x007ffffe {
	v += 2
	}
	u = (u & 0xff800000) \| v

	// A 4 byte encoding has the low two bits set.
	u \|= 0x03
	b = append(b, uint8(u), uint8(u>>8), uint8(u>>16), uint8(u>>24))
	}

	func (b *buffer) encodeCoordinate(f float32) int {
	if i := int32(f); -64 <= i && i < +64 && float32(i) == f {
	u := uint32(i + 64)
	u = (u << 1)
	b = append(b, uint8(u))
	return 1
	}
	if i := int32(f * 64); -12864 <= i && i < +12864 && float32(i) == f*64 {
	u := uint32(i + 128*64)
	u = (u << 2) \| 1
	b = append(b, uint8(u), uint8(u>>8))
	return 2
	}
	b.encode4ByteReal(f)
	return 4
	}

	func (b *buffer) encodeAngle(f float32) int {
	// Normalize f to the range [0, 1).
	g := float64(f)
	g -= math.Floor(g)
	return b.encodeZeroToOne(float32(g))
	}

	func (b *buffer) encodeZeroToOne(f float32) int {
	if u := uint32(f * 15120); float32(u) == f*15120 && u < 15120 {
	if u%126 == 0 {
	u = ((u / 126) << 1)
	b = append(b, uint8(u))
	return 1
	}
	u = (u << 2) \| 1
	b = append(b, uint8(u), uint8(u>>8))
	return 2
	}
	b.encode4ByteReal(f)
	return 4
	}

	func (b *buffer) encodeColor1(c Color) {
	if x, ok := encodeColor1(c); ok {
	b = append(b, x)
	return
	}
	// Default to opaque black.
	b = append(b, 0x00)
	}

	func (b *buffer) encodeColor2(c Color) {
	if x, ok := encodeColor2(c); ok {
	b = append(b, x[0], x[1])
	return
	}
	// Default to opaque black.
	b = append(b, 0x00, 0x0f)
	}

	func (b *buffer) encodeColor3Direct(c Color) {
	if x, ok := encodeColor3Direct(c); ok {
	b = append(b, x[0], x[1], x[2])
	return
	}
	// Default to opaque black.
	b = append(b, 0x00, 0x00, 0x00)
	}

	func (b *buffer) encodeColor4(c Color) {
	if x, ok := encodeColor4(c); ok {
	b = append(b, x[0], x[1], x[2], x[3])
	return
	}
	// Default to opaque black.
	b = append(b, 0x00, 0x00, 0x00, 0xff)
	}

	func (b *buffer) encodeColor3Indirect(c Color) {
	if x, ok := encodeColor3Indirect(c); ok {
	b = append(b, x[0], x[1], x[2])
	return
	}
	// Default to opaque black.
	b = append(b, 0x00, 0x00, 0x00)
	}