unicode/norm/forminfo.go - text - Git at Google

 // Copyright 2011 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 norm

 // This file contains Form-specific logic and wrappers for data in tables.go.

 // Rune info is stored in a separate trie per composing form. A composing form
 // and its corresponding decomposing form share the same trie.  Each trie maps
 // a rune to a uint16. The values take two forms.  For v >= 0x8000:
 //   bits
 //   15:    1 (inverse of NFD_QD bit of qcInfo)
 //   13..7: qcInfo (see below). isYesD is always true (no decompostion).
 //    6..0: ccc (compressed CCC value).
 // For v < 0x8000, the respective rune has a decomposition and v is an index
 // into a byte array of UTF-8 decomposition sequences and additional info and
 // has the form:
 //    <header> <decomp_byte>* [<tccc> [<lccc>]]
 // The header contains the number of bytes in the decomposition (excluding this
 // length byte). The two most significant bits of this length byte correspond
 // to bit 5 and 4 of qcInfo (see below).  The byte sequence itself starts at v+1.
 // The byte sequence is followed by a trailing and leading CCC if the values
 // for these are not zero.  The value of v determines which ccc are appended
 // to the sequences.  For v < firstCCC, there are none, for v >= firstCCC,
 // the sequence is followed by a trailing ccc, and for v >= firstLeadingCC
 // there is an additional leading ccc. The value of tccc itself is the
 // trailing CCC shifted left 2 bits. The two least-significant bits of tccc
 // are the number of trailing non-starters.

 const (
 	qcInfoMask      = 0x3F // to clear all but the relevant bits in a qcInfo
 	headerLenMask   = 0x3F // extract the length value from the header byte
 	headerFlagsMask = 0xC0 // extract the qcInfo bits from the header byte
 )

 // Properties provides access to normalization properties of a rune.
 type Properties struct {
 	pos   uint8  // start position in reorderBuffer; used in composition.go
 	size  uint8  // length of UTF-8 encoding of this rune
 	ccc   uint8  // leading canonical combining class (ccc if not decomposition)
 	tccc  uint8  // trailing canonical combining class (ccc if not decomposition)
 	nLead uint8  // number of leading non-starters.
 	flags qcInfo // quick check flags
 	index uint16
 }

 // functions dispatchable per form
 type lookupFunc func(b input, i int) Properties

 // formInfo holds Form-specific functions and tables.
 type formInfo struct {
 	form                     Form
 	composing, compatibility bool // form type
 	info                     lookupFunc
 	nextMain                 iterFunc
 }

 var formTable []*formInfo

 func init() {
 	formTable = make([]*formInfo, 4)

 	for i := range formTable {
 		f := &formInfo{}
 		formTable[i] = f
 		f.form = Form(i)
 		if Form(i) == NFKD || Form(i) == NFKC {
 			f.compatibility = true
 			f.info = lookupInfoNFKC
 		} else {
 			f.info = lookupInfoNFC
 		}
 		f.nextMain = nextDecomposed
 		if Form(i) == NFC || Form(i) == NFKC {
 			f.nextMain = nextComposed
 			f.composing = true
 		}
 	}
 }

 // We do not distinguish between boundaries for NFC, NFD, etc. to avoid
 // unexpected behavior for the user.  For example, in NFD, there is a boundary
 // after 'a'.  However, 'a' might combine with modifiers, so from the application's
 // perspective it is not a good boundary. We will therefore always use the
 // boundaries for the combining variants.

 // BoundaryBefore returns true if this rune starts a new segment and
 // cannot combine with any rune on the left.
 func (p Properties) BoundaryBefore() bool {
 	if p.ccc == 0 && !p.combinesBackward() {
 		return true
 	}
 	// We assume that the CCC of the first character in a decomposition
 	// is always non-zero if different from info.ccc and that we can return
 	// false at this point. This is verified by maketables.
 	return false
 }

 // BoundaryAfter returns true if runes cannot combine with or otherwise
 // interact with this or previous runes.
 func (p Properties) BoundaryAfter() bool {
 	// TODO: loosen these conditions.
 	return p.isInert()
 }

 // We pack quick check data in 4 bits:
 //   5:    Combines forward  (0 == false, 1 == true)
 //   4..3: NFC_QC Yes(00), No (10), or Maybe (11)
 //   2:    NFD_QC Yes (0) or No (1). No also means there is a decomposition.
 //   1..0: Number of trailing non-starters.
 //
 // When all 4 bits are zero, the character is inert, meaning it is never
 // influenced by normalization.
 type qcInfo uint8

 func (p Properties) isYesC() bool { return p.flags&0x10 == 0 }
 func (p Properties) isYesD() bool { return p.flags&0x4 == 0 }

 func (p Properties) combinesForward() bool  { return p.flags&0x20 != 0 }
 func (p Properties) combinesBackward() bool { return p.flags&0x8 != 0 } // == isMaybe
 func (p Properties) hasDecomposition() bool { return p.flags&0x4 != 0 } // == isNoD

 func (p Properties) isInert() bool {
 	return p.flags&qcInfoMask == 0 && p.ccc == 0
 }

 func (p Properties) multiSegment() bool {
 	return p.index >= firstMulti && p.index < endMulti
 }

 func (p Properties) nLeadingNonStarters() uint8 {
 	return p.nLead
 }

 func (p Properties) nTrailingNonStarters() uint8 {
 	return uint8(p.flags & 0x03)
 }

 // Decomposition returns the decomposition for the underlying rune
 // or nil if there is none.
 func (p Properties) Decomposition() []byte {
 	// TODO: create the decomposition for Hangul?
 	if p.index == 0 {
 		return nil
 	}
 	i := p.index
 	n := decomps[i] & headerLenMask
 	i++
 	return decomps[i : i+uint16(n)]
 }

 // Size returns the length of UTF-8 encoding of the rune.
 func (p Properties) Size() int {
 	return int(p.size)
 }

 // CCC returns the canonical combining class of the underlying rune.
 func (p Properties) CCC() uint8 {
 	if p.index >= firstCCCZeroExcept {
 		return 0
 	}
 	return ccc[p.ccc]
 }

 // LeadCCC returns the CCC of the first rune in the decomposition.
 // If there is no decomposition, LeadCCC equals CCC.
 func (p Properties) LeadCCC() uint8 {
 	return ccc[p.ccc]
 }

 // TrailCCC returns the CCC of the last rune in the decomposition.
 // If there is no decomposition, TrailCCC equals CCC.
 func (p Properties) TrailCCC() uint8 {
 	return ccc[p.tccc]
 }

 // Recomposition
 // We use 32-bit keys instead of 64-bit for the two codepoint keys.
 // This clips off the bits of three entries, but we know this will not
 // result in a collision. In the unlikely event that changes to
 // UnicodeData.txt introduce collisions, the compiler will catch it.
 // Note that the recomposition map for NFC and NFKC are identical.

 // combine returns the combined rune or 0 if it doesn't exist.
 func combine(a, b rune) rune {
 	key := uint32(uint16(a))<<16 + uint32(uint16(b))
 	return recompMap[key]
 }

 func lookupInfoNFC(b input, i int) Properties {
 	v, sz := b.charinfoNFC(i)
 	return compInfo(v, sz)
 }

 func lookupInfoNFKC(b input, i int) Properties {
 	v, sz := b.charinfoNFKC(i)
 	return compInfo(v, sz)
 }

 // Properties returns properties for the first rune in s.
 func (f Form) Properties(s []byte) Properties {
 	if f == NFC || f == NFD {
 		return compInfo(nfcData.lookup(s))
 	}
 	return compInfo(nfkcData.lookup(s))
 }

 // PropertiesString returns properties for the first rune in s.
 func (f Form) PropertiesString(s string) Properties {
 	if f == NFC || f == NFD {
 		return compInfo(nfcData.lookupString(s))
 	}
 	return compInfo(nfkcData.lookupString(s))
 }

 // compInfo converts the information contained in v and sz
 // to a Properties.  See the comment at the top of the file
 // for more information on the format.
 func compInfo(v uint16, sz int) Properties {
 	if v == 0 {
 		return Properties{size: uint8(sz)}
 	} else if v >= 0x8000 {
 		p := Properties{
 			size:  uint8(sz),
 			ccc:   uint8(v),
 			tccc:  uint8(v),
 			flags: qcInfo(v >> 8),
 		}
 		if p.ccc > 0 || p.combinesBackward() {
 			p.nLead = uint8(p.flags & 0x3)
 		}
 		return p
 	}
 	// has decomposition
 	h := decomps[v]
 	f := (qcInfo(h&headerFlagsMask) >> 2) | 0x4
 	p := Properties{size: uint8(sz), flags: f, index: v}
 	if v >= firstCCC {
 		v += uint16(h&headerLenMask) + 1
 		c := decomps[v]
 		p.tccc = c >> 2
 		p.flags |= qcInfo(c & 0x3)
 		if v >= firstLeadingCCC {
 			p.nLead = c & 0x3
 			if v >= firstStarterWithNLead {
 				// We were tricked. Remove the decomposition.
 				p.flags &= 0x03
 				p.index = 0
 				return p
 			}
 			p.ccc = decomps[v+1]
 		}
 	}
 	return p
 }
	// Copyright 2011 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 norm

	// This file contains Form-specific logic and wrappers for data in tables.go.

	// Rune info is stored in a separate trie per composing form. A composing form
	// and its corresponding decomposing form share the same trie. Each trie maps
	// a rune to a uint16. The values take two forms. For v >= 0x8000:
	// bits
	// 15: 1 (inverse of NFD_QD bit of qcInfo)
	// 13..7: qcInfo (see below). isYesD is always true (no decompostion).
	// 6..0: ccc (compressed CCC value).
	// For v < 0x8000, the respective rune has a decomposition and v is an index
	// into a byte array of UTF-8 decomposition sequences and additional info and
	// has the form:
	// <header> <decomp_byte>* [<tccc> [<lccc>]]
	// The header contains the number of bytes in the decomposition (excluding this
	// length byte). The two most significant bits of this length byte correspond
	// to bit 5 and 4 of qcInfo (see below). The byte sequence itself starts at v+1.
	// The byte sequence is followed by a trailing and leading CCC if the values
	// for these are not zero. The value of v determines which ccc are appended
	// to the sequences. For v < firstCCC, there are none, for v >= firstCCC,
	// the sequence is followed by a trailing ccc, and for v >= firstLeadingCC
	// there is an additional leading ccc. The value of tccc itself is the
	// trailing CCC shifted left 2 bits. The two least-significant bits of tccc
	// are the number of trailing non-starters.

	const (
	qcInfoMask = 0x3F // to clear all but the relevant bits in a qcInfo
	headerLenMask = 0x3F // extract the length value from the header byte
	headerFlagsMask = 0xC0 // extract the qcInfo bits from the header byte
	)

	// Properties provides access to normalization properties of a rune.
	type Properties struct {
	pos uint8 // start position in reorderBuffer; used in composition.go
	size uint8 // length of UTF-8 encoding of this rune
	ccc uint8 // leading canonical combining class (ccc if not decomposition)
	tccc uint8 // trailing canonical combining class (ccc if not decomposition)
	nLead uint8 // number of leading non-starters.
	flags qcInfo // quick check flags
	index uint16
	}

	// functions dispatchable per form
	type lookupFunc func(b input, i int) Properties

	// formInfo holds Form-specific functions and tables.
	type formInfo struct {
	form Form
	composing, compatibility bool // form type
	info lookupFunc
	nextMain iterFunc
	}

	var formTable []*formInfo

	func init() {
	formTable = make([]*formInfo, 4)

	for i := range formTable {
	f := &formInfo{}
	formTable[i] = f
	f.form = Form(i)
	if Form(i) == NFKD \|\| Form(i) == NFKC {
	f.compatibility = true
	f.info = lookupInfoNFKC
	} else {
	f.info = lookupInfoNFC
	}
	f.nextMain = nextDecomposed
	if Form(i) == NFC \|\| Form(i) == NFKC {
	f.nextMain = nextComposed
	f.composing = true
	}
	}
	}

	// We do not distinguish between boundaries for NFC, NFD, etc. to avoid
	// unexpected behavior for the user. For example, in NFD, there is a boundary
	// after 'a'. However, 'a' might combine with modifiers, so from the application's
	// perspective it is not a good boundary. We will therefore always use the
	// boundaries for the combining variants.

	// BoundaryBefore returns true if this rune starts a new segment and
	// cannot combine with any rune on the left.
	func (p Properties) BoundaryBefore() bool {
	if p.ccc == 0 && !p.combinesBackward() {
	return true
	}
	// We assume that the CCC of the first character in a decomposition
	// is always non-zero if different from info.ccc and that we can return
	// false at this point. This is verified by maketables.
	return false
	}

	// BoundaryAfter returns true if runes cannot combine with or otherwise
	// interact with this or previous runes.
	func (p Properties) BoundaryAfter() bool {
	// TODO: loosen these conditions.
	return p.isInert()
	}

	// We pack quick check data in 4 bits:
	// 5: Combines forward (0 == false, 1 == true)
	// 4..3: NFC_QC Yes(00), No (10), or Maybe (11)
	// 2: NFD_QC Yes (0) or No (1). No also means there is a decomposition.
	// 1..0: Number of trailing non-starters.
	//
	// When all 4 bits are zero, the character is inert, meaning it is never
	// influenced by normalization.
	type qcInfo uint8

	func (p Properties) isYesC() bool { return p.flags&0x10 == 0 }
	func (p Properties) isYesD() bool { return p.flags&0x4 == 0 }

	func (p Properties) combinesForward() bool { return p.flags&0x20 != 0 }
	func (p Properties) combinesBackward() bool { return p.flags&0x8 != 0 } // == isMaybe
	func (p Properties) hasDecomposition() bool { return p.flags&0x4 != 0 } // == isNoD

	func (p Properties) isInert() bool {
	return p.flags&qcInfoMask == 0 && p.ccc == 0
	}

	func (p Properties) multiSegment() bool {
	return p.index >= firstMulti && p.index < endMulti
	}

	func (p Properties) nLeadingNonStarters() uint8 {
	return p.nLead
	}

	func (p Properties) nTrailingNonStarters() uint8 {
	return uint8(p.flags & 0x03)
	}

	// Decomposition returns the decomposition for the underlying rune
	// or nil if there is none.
	func (p Properties) Decomposition() []byte {
	// TODO: create the decomposition for Hangul?
	if p.index == 0 {
	return nil
	}
	i := p.index
	n := decomps[i] & headerLenMask
	i++
	return decomps[i : i+uint16(n)]
	}

	// Size returns the length of UTF-8 encoding of the rune.
	func (p Properties) Size() int {
	return int(p.size)
	}

	// CCC returns the canonical combining class of the underlying rune.
	func (p Properties) CCC() uint8 {
	if p.index >= firstCCCZeroExcept {
	return 0
	}
	return ccc[p.ccc]
	}

	// LeadCCC returns the CCC of the first rune in the decomposition.
	// If there is no decomposition, LeadCCC equals CCC.
	func (p Properties) LeadCCC() uint8 {
	return ccc[p.ccc]
	}

	// TrailCCC returns the CCC of the last rune in the decomposition.
	// If there is no decomposition, TrailCCC equals CCC.
	func (p Properties) TrailCCC() uint8 {
	return ccc[p.tccc]
	}

	// Recomposition
	// We use 32-bit keys instead of 64-bit for the two codepoint keys.
	// This clips off the bits of three entries, but we know this will not
	// result in a collision. In the unlikely event that changes to
	// UnicodeData.txt introduce collisions, the compiler will catch it.
	// Note that the recomposition map for NFC and NFKC are identical.

	// combine returns the combined rune or 0 if it doesn't exist.
	func combine(a, b rune) rune {
	key := uint32(uint16(a))<<16 + uint32(uint16(b))
	return recompMap[key]
	}

	func lookupInfoNFC(b input, i int) Properties {
	v, sz := b.charinfoNFC(i)
	return compInfo(v, sz)
	}

	func lookupInfoNFKC(b input, i int) Properties {
	v, sz := b.charinfoNFKC(i)
	return compInfo(v, sz)
	}

	// Properties returns properties for the first rune in s.
	func (f Form) Properties(s []byte) Properties {
	if f == NFC \|\| f == NFD {
	return compInfo(nfcData.lookup(s))
	}
	return compInfo(nfkcData.lookup(s))
	}

	// PropertiesString returns properties for the first rune in s.
	func (f Form) PropertiesString(s string) Properties {
	if f == NFC \|\| f == NFD {
	return compInfo(nfcData.lookupString(s))
	}
	return compInfo(nfkcData.lookupString(s))
	}

	// compInfo converts the information contained in v and sz
	// to a Properties. See the comment at the top of the file
	// for more information on the format.
	func compInfo(v uint16, sz int) Properties {
	if v == 0 {
	return Properties{size: uint8(sz)}
	} else if v >= 0x8000 {
	p := Properties{
	size: uint8(sz),
	ccc: uint8(v),
	tccc: uint8(v),
	flags: qcInfo(v >> 8),
	}
	if p.ccc > 0 \|\| p.combinesBackward() {
	p.nLead = uint8(p.flags & 0x3)
	}
	return p
	}
	// has decomposition
	h := decomps[v]
	f := (qcInfo(h&headerFlagsMask) >> 2) \| 0x4
	p := Properties{size: uint8(sz), flags: f, index: v}
	if v >= firstCCC {
	v += uint16(h&headerLenMask) + 1
	c := decomps[v]
	p.tccc = c >> 2
	p.flags \|= qcInfo(c & 0x3)
	if v >= firstLeadingCCC {
	p.nLead = c & 0x3
	if v >= firstStarterWithNLead {
	// We were tricked. Remove the decomposition.
	p.flags &= 0x03
	p.index = 0
	return p
	}
	p.ccc = decomps[v+1]
	}
	}
	return p
	}