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276 lines
7.1 KiB
Go
276 lines
7.1 KiB
Go
// Copyright 2012 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package colltab
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import (
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"unicode/utf8"
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"golang.org/x/text/unicode/norm"
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)
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// Table holds all collation data for a given collation ordering.
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type Table struct {
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Index Trie // main trie
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// expansion info
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ExpandElem []uint32
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// contraction info
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ContractTries ContractTrieSet
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ContractElem []uint32
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MaxContractLen int
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VariableTop uint32
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}
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func (t *Table) AppendNext(w []Elem, b []byte) (res []Elem, n int) {
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return t.appendNext(w, source{bytes: b})
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}
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func (t *Table) AppendNextString(w []Elem, s string) (res []Elem, n int) {
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return t.appendNext(w, source{str: s})
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}
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func (t *Table) Start(p int, b []byte) int {
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// TODO: implement
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panic("not implemented")
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}
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func (t *Table) StartString(p int, s string) int {
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// TODO: implement
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panic("not implemented")
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}
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func (t *Table) Domain() []string {
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// TODO: implement
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panic("not implemented")
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}
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func (t *Table) Top() uint32 {
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return t.VariableTop
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}
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type source struct {
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str string
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bytes []byte
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}
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func (src *source) lookup(t *Table) (ce Elem, sz int) {
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if src.bytes == nil {
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return t.Index.lookupString(src.str)
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}
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return t.Index.lookup(src.bytes)
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}
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func (src *source) tail(sz int) {
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if src.bytes == nil {
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src.str = src.str[sz:]
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} else {
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src.bytes = src.bytes[sz:]
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}
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}
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func (src *source) nfd(buf []byte, end int) []byte {
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if src.bytes == nil {
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return norm.NFD.AppendString(buf[:0], src.str[:end])
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}
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return norm.NFD.Append(buf[:0], src.bytes[:end]...)
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}
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func (src *source) rune() (r rune, sz int) {
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if src.bytes == nil {
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return utf8.DecodeRuneInString(src.str)
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}
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return utf8.DecodeRune(src.bytes)
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}
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func (src *source) properties(f norm.Form) norm.Properties {
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if src.bytes == nil {
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return f.PropertiesString(src.str)
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}
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return f.Properties(src.bytes)
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}
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// appendNext appends the weights corresponding to the next rune or
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// contraction in s. If a contraction is matched to a discontinuous
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// sequence of runes, the weights for the interstitial runes are
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// appended as well. It returns a new slice that includes the appended
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// weights and the number of bytes consumed from s.
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func (t *Table) appendNext(w []Elem, src source) (res []Elem, n int) {
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ce, sz := src.lookup(t)
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tp := ce.ctype()
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if tp == ceNormal {
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if ce == 0 {
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r, _ := src.rune()
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const (
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hangulSize = 3
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firstHangul = 0xAC00
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lastHangul = 0xD7A3
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)
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if r >= firstHangul && r <= lastHangul {
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// TODO: performance can be considerably improved here.
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n = sz
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var buf [16]byte // Used for decomposing Hangul.
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for b := src.nfd(buf[:0], hangulSize); len(b) > 0; b = b[sz:] {
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ce, sz = t.Index.lookup(b)
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w = append(w, ce)
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}
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return w, n
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}
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ce = makeImplicitCE(implicitPrimary(r))
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}
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w = append(w, ce)
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} else if tp == ceExpansionIndex {
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w = t.appendExpansion(w, ce)
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} else if tp == ceContractionIndex {
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n := 0
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src.tail(sz)
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if src.bytes == nil {
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w, n = t.matchContractionString(w, ce, src.str)
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} else {
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w, n = t.matchContraction(w, ce, src.bytes)
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}
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sz += n
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} else if tp == ceDecompose {
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// Decompose using NFKD and replace tertiary weights.
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t1, t2 := splitDecompose(ce)
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i := len(w)
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nfkd := src.properties(norm.NFKD).Decomposition()
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for p := 0; len(nfkd) > 0; nfkd = nfkd[p:] {
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w, p = t.appendNext(w, source{bytes: nfkd})
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}
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w[i] = w[i].updateTertiary(t1)
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if i++; i < len(w) {
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w[i] = w[i].updateTertiary(t2)
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for i++; i < len(w); i++ {
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w[i] = w[i].updateTertiary(maxTertiary)
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}
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}
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}
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return w, sz
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}
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func (t *Table) appendExpansion(w []Elem, ce Elem) []Elem {
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i := splitExpandIndex(ce)
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n := int(t.ExpandElem[i])
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i++
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for _, ce := range t.ExpandElem[i : i+n] {
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w = append(w, Elem(ce))
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}
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return w
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}
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func (t *Table) matchContraction(w []Elem, ce Elem, suffix []byte) ([]Elem, int) {
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index, n, offset := splitContractIndex(ce)
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scan := t.ContractTries.scanner(index, n, suffix)
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buf := [norm.MaxSegmentSize]byte{}
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bufp := 0
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p := scan.scan(0)
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if !scan.done && p < len(suffix) && suffix[p] >= utf8.RuneSelf {
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// By now we should have filtered most cases.
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p0 := p
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bufn := 0
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rune := norm.NFD.Properties(suffix[p:])
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p += rune.Size()
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if rune.LeadCCC() != 0 {
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prevCC := rune.TrailCCC()
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// A gap may only occur in the last normalization segment.
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// This also ensures that len(scan.s) < norm.MaxSegmentSize.
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if end := norm.NFD.FirstBoundary(suffix[p:]); end != -1 {
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scan.s = suffix[:p+end]
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}
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for p < len(suffix) && !scan.done && suffix[p] >= utf8.RuneSelf {
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rune = norm.NFD.Properties(suffix[p:])
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if ccc := rune.LeadCCC(); ccc == 0 || prevCC >= ccc {
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break
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}
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prevCC = rune.TrailCCC()
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if pp := scan.scan(p); pp != p {
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// Copy the interstitial runes for later processing.
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bufn += copy(buf[bufn:], suffix[p0:p])
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if scan.pindex == pp {
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bufp = bufn
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}
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p, p0 = pp, pp
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} else {
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p += rune.Size()
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}
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}
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}
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}
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// Append weights for the matched contraction, which may be an expansion.
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i, n := scan.result()
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ce = Elem(t.ContractElem[i+offset])
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if ce.ctype() == ceNormal {
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w = append(w, ce)
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} else {
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w = t.appendExpansion(w, ce)
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}
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// Append weights for the runes in the segment not part of the contraction.
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for b, p := buf[:bufp], 0; len(b) > 0; b = b[p:] {
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w, p = t.appendNext(w, source{bytes: b})
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}
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return w, n
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}
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// TODO: unify the two implementations. This is best done after first simplifying
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// the algorithm taking into account the inclusion of both NFC and NFD forms
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// in the table.
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func (t *Table) matchContractionString(w []Elem, ce Elem, suffix string) ([]Elem, int) {
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index, n, offset := splitContractIndex(ce)
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scan := t.ContractTries.scannerString(index, n, suffix)
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buf := [norm.MaxSegmentSize]byte{}
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bufp := 0
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p := scan.scan(0)
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if !scan.done && p < len(suffix) && suffix[p] >= utf8.RuneSelf {
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// By now we should have filtered most cases.
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p0 := p
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bufn := 0
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rune := norm.NFD.PropertiesString(suffix[p:])
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p += rune.Size()
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if rune.LeadCCC() != 0 {
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prevCC := rune.TrailCCC()
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// A gap may only occur in the last normalization segment.
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// This also ensures that len(scan.s) < norm.MaxSegmentSize.
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if end := norm.NFD.FirstBoundaryInString(suffix[p:]); end != -1 {
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scan.s = suffix[:p+end]
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}
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for p < len(suffix) && !scan.done && suffix[p] >= utf8.RuneSelf {
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rune = norm.NFD.PropertiesString(suffix[p:])
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if ccc := rune.LeadCCC(); ccc == 0 || prevCC >= ccc {
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break
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}
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prevCC = rune.TrailCCC()
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if pp := scan.scan(p); pp != p {
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// Copy the interstitial runes for later processing.
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bufn += copy(buf[bufn:], suffix[p0:p])
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if scan.pindex == pp {
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bufp = bufn
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}
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p, p0 = pp, pp
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} else {
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p += rune.Size()
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}
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}
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}
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}
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// Append weights for the matched contraction, which may be an expansion.
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i, n := scan.result()
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ce = Elem(t.ContractElem[i+offset])
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if ce.ctype() == ceNormal {
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w = append(w, ce)
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} else {
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w = t.appendExpansion(w, ce)
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}
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// Append weights for the runes in the segment not part of the contraction.
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for b, p := buf[:bufp], 0; len(b) > 0; b = b[p:] {
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w, p = t.appendNext(w, source{bytes: b})
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}
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return w, n
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}
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