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https://github.com/superseriousbusiness/gotosocial.git
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2dc9fc1626
* start moving to bun * changing more stuff * more * and yet more * tests passing * seems stable now * more big changes * small fix * little fixes
817 lines
23 KiB
Go
817 lines
23 KiB
Go
// Copyright 2014 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 cases
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// This file contains the definitions of case mappings for all supported
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// languages. The rules for the language-specific tailorings were taken and
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// modified from the CLDR transform definitions in common/transforms.
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import (
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"strings"
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"unicode"
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"unicode/utf8"
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"golang.org/x/text/internal"
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"golang.org/x/text/language"
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"golang.org/x/text/transform"
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"golang.org/x/text/unicode/norm"
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)
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// A mapFunc takes a context set to the current rune and writes the mapped
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// version to the same context. It may advance the context to the next rune. It
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// returns whether a checkpoint is possible: whether the pDst bytes written to
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// dst so far won't need changing as we see more source bytes.
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type mapFunc func(*context) bool
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// A spanFunc takes a context set to the current rune and returns whether this
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// rune would be altered when written to the output. It may advance the context
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// to the next rune. It returns whether a checkpoint is possible.
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type spanFunc func(*context) bool
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// maxIgnorable defines the maximum number of ignorables to consider for
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// lookahead operations.
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const maxIgnorable = 30
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// supported lists the language tags for which we have tailorings.
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const supported = "und af az el lt nl tr"
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func init() {
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tags := []language.Tag{}
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for _, s := range strings.Split(supported, " ") {
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tags = append(tags, language.MustParse(s))
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}
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matcher = internal.NewInheritanceMatcher(tags)
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Supported = language.NewCoverage(tags)
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}
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var (
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matcher *internal.InheritanceMatcher
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Supported language.Coverage
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// We keep the following lists separate, instead of having a single per-
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// language struct, to give the compiler a chance to remove unused code.
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// Some uppercase mappers are stateless, so we can precompute the
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// Transformers and save a bit on runtime allocations.
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upperFunc = []struct {
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upper mapFunc
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span spanFunc
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}{
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{nil, nil}, // und
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{nil, nil}, // af
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{aztrUpper(upper), isUpper}, // az
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{elUpper, noSpan}, // el
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{ltUpper(upper), noSpan}, // lt
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{nil, nil}, // nl
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{aztrUpper(upper), isUpper}, // tr
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}
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undUpper transform.SpanningTransformer = &undUpperCaser{}
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undLower transform.SpanningTransformer = &undLowerCaser{}
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undLowerIgnoreSigma transform.SpanningTransformer = &undLowerIgnoreSigmaCaser{}
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lowerFunc = []mapFunc{
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nil, // und
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nil, // af
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aztrLower, // az
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nil, // el
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ltLower, // lt
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nil, // nl
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aztrLower, // tr
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}
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titleInfos = []struct {
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title mapFunc
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lower mapFunc
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titleSpan spanFunc
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rewrite func(*context)
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}{
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{title, lower, isTitle, nil}, // und
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{title, lower, isTitle, afnlRewrite}, // af
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{aztrUpper(title), aztrLower, isTitle, nil}, // az
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{title, lower, isTitle, nil}, // el
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{ltUpper(title), ltLower, noSpan, nil}, // lt
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{nlTitle, lower, nlTitleSpan, afnlRewrite}, // nl
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{aztrUpper(title), aztrLower, isTitle, nil}, // tr
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}
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)
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func makeUpper(t language.Tag, o options) transform.SpanningTransformer {
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_, i, _ := matcher.Match(t)
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f := upperFunc[i].upper
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if f == nil {
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return undUpper
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}
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return &simpleCaser{f: f, span: upperFunc[i].span}
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}
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func makeLower(t language.Tag, o options) transform.SpanningTransformer {
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_, i, _ := matcher.Match(t)
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f := lowerFunc[i]
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if f == nil {
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if o.ignoreFinalSigma {
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return undLowerIgnoreSigma
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}
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return undLower
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}
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if o.ignoreFinalSigma {
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return &simpleCaser{f: f, span: isLower}
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}
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return &lowerCaser{
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first: f,
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midWord: finalSigma(f),
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}
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}
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func makeTitle(t language.Tag, o options) transform.SpanningTransformer {
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_, i, _ := matcher.Match(t)
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x := &titleInfos[i]
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lower := x.lower
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if o.noLower {
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lower = (*context).copy
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} else if !o.ignoreFinalSigma {
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lower = finalSigma(lower)
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}
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return &titleCaser{
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title: x.title,
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lower: lower,
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titleSpan: x.titleSpan,
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rewrite: x.rewrite,
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}
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}
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func noSpan(c *context) bool {
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c.err = transform.ErrEndOfSpan
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return false
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}
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// TODO: consider a similar special case for the fast majority lower case. This
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// is a bit more involved so will require some more precise benchmarking to
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// justify it.
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type undUpperCaser struct{ transform.NopResetter }
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// undUpperCaser implements the Transformer interface for doing an upper case
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// mapping for the root locale (und). It eliminates the need for an allocation
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// as it prevents escaping by not using function pointers.
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func (t undUpperCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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c := context{dst: dst, src: src, atEOF: atEOF}
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for c.next() {
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upper(&c)
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c.checkpoint()
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}
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return c.ret()
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}
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func (t undUpperCaser) Span(src []byte, atEOF bool) (n int, err error) {
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c := context{src: src, atEOF: atEOF}
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for c.next() && isUpper(&c) {
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c.checkpoint()
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}
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return c.retSpan()
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}
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// undLowerIgnoreSigmaCaser implements the Transformer interface for doing
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// a lower case mapping for the root locale (und) ignoring final sigma
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// handling. This casing algorithm is used in some performance-critical packages
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// like secure/precis and x/net/http/idna, which warrants its special-casing.
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type undLowerIgnoreSigmaCaser struct{ transform.NopResetter }
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func (t undLowerIgnoreSigmaCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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c := context{dst: dst, src: src, atEOF: atEOF}
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for c.next() && lower(&c) {
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c.checkpoint()
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}
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return c.ret()
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}
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// Span implements a generic lower-casing. This is possible as isLower works
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// for all lowercasing variants. All lowercase variants only vary in how they
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// transform a non-lowercase letter. They will never change an already lowercase
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// letter. In addition, there is no state.
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func (t undLowerIgnoreSigmaCaser) Span(src []byte, atEOF bool) (n int, err error) {
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c := context{src: src, atEOF: atEOF}
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for c.next() && isLower(&c) {
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c.checkpoint()
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}
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return c.retSpan()
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}
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type simpleCaser struct {
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context
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f mapFunc
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span spanFunc
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}
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// simpleCaser implements the Transformer interface for doing a case operation
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// on a rune-by-rune basis.
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func (t *simpleCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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c := context{dst: dst, src: src, atEOF: atEOF}
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for c.next() && t.f(&c) {
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c.checkpoint()
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}
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return c.ret()
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}
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func (t *simpleCaser) Span(src []byte, atEOF bool) (n int, err error) {
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c := context{src: src, atEOF: atEOF}
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for c.next() && t.span(&c) {
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c.checkpoint()
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}
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return c.retSpan()
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}
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// undLowerCaser implements the Transformer interface for doing a lower case
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// mapping for the root locale (und) ignoring final sigma handling. This casing
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// algorithm is used in some performance-critical packages like secure/precis
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// and x/net/http/idna, which warrants its special-casing.
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type undLowerCaser struct{ transform.NopResetter }
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func (t undLowerCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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c := context{dst: dst, src: src, atEOF: atEOF}
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for isInterWord := true; c.next(); {
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if isInterWord {
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if c.info.isCased() {
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if !lower(&c) {
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break
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}
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isInterWord = false
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} else if !c.copy() {
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break
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}
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} else {
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if c.info.isNotCasedAndNotCaseIgnorable() {
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if !c.copy() {
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break
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}
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isInterWord = true
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} else if !c.hasPrefix("Σ") {
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if !lower(&c) {
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break
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}
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} else if !finalSigmaBody(&c) {
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break
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}
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}
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c.checkpoint()
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}
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return c.ret()
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}
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func (t undLowerCaser) Span(src []byte, atEOF bool) (n int, err error) {
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c := context{src: src, atEOF: atEOF}
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for c.next() && isLower(&c) {
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c.checkpoint()
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}
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return c.retSpan()
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}
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// lowerCaser implements the Transformer interface. The default Unicode lower
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// casing requires different treatment for the first and subsequent characters
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// of a word, most notably to handle the Greek final Sigma.
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type lowerCaser struct {
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undLowerIgnoreSigmaCaser
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context
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first, midWord mapFunc
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}
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func (t *lowerCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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t.context = context{dst: dst, src: src, atEOF: atEOF}
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c := &t.context
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for isInterWord := true; c.next(); {
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if isInterWord {
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if c.info.isCased() {
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if !t.first(c) {
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break
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}
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isInterWord = false
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} else if !c.copy() {
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break
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}
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} else {
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if c.info.isNotCasedAndNotCaseIgnorable() {
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if !c.copy() {
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break
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}
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isInterWord = true
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} else if !t.midWord(c) {
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break
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}
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}
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c.checkpoint()
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}
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return c.ret()
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}
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// titleCaser implements the Transformer interface. Title casing algorithms
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// distinguish between the first letter of a word and subsequent letters of the
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// same word. It uses state to avoid requiring a potentially infinite lookahead.
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type titleCaser struct {
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context
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// rune mappings used by the actual casing algorithms.
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title mapFunc
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lower mapFunc
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titleSpan spanFunc
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rewrite func(*context)
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}
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// Transform implements the standard Unicode title case algorithm as defined in
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// Chapter 3 of The Unicode Standard:
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// toTitlecase(X): Find the word boundaries in X according to Unicode Standard
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// Annex #29, "Unicode Text Segmentation." For each word boundary, find the
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// first cased character F following the word boundary. If F exists, map F to
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// Titlecase_Mapping(F); then map all characters C between F and the following
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// word boundary to Lowercase_Mapping(C).
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func (t *titleCaser) Transform(dst, src []byte, atEOF bool) (nDst, nSrc int, err error) {
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t.context = context{dst: dst, src: src, atEOF: atEOF, isMidWord: t.isMidWord}
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c := &t.context
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if !c.next() {
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return c.ret()
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}
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for {
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p := c.info
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if t.rewrite != nil {
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t.rewrite(c)
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}
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wasMid := p.isMid()
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// Break out of this loop on failure to ensure we do not modify the
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// state incorrectly.
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if p.isCased() {
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if !c.isMidWord {
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if !t.title(c) {
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break
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}
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c.isMidWord = true
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} else if !t.lower(c) {
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break
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}
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} else if !c.copy() {
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break
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} else if p.isBreak() {
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c.isMidWord = false
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}
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// As we save the state of the transformer, it is safe to call
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// checkpoint after any successful write.
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if !(c.isMidWord && wasMid) {
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c.checkpoint()
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}
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if !c.next() {
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break
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}
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if wasMid && c.info.isMid() {
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c.isMidWord = false
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}
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}
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return c.ret()
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}
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func (t *titleCaser) Span(src []byte, atEOF bool) (n int, err error) {
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t.context = context{src: src, atEOF: atEOF, isMidWord: t.isMidWord}
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c := &t.context
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if !c.next() {
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return c.retSpan()
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}
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for {
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p := c.info
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if t.rewrite != nil {
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t.rewrite(c)
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}
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wasMid := p.isMid()
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// Break out of this loop on failure to ensure we do not modify the
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// state incorrectly.
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if p.isCased() {
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if !c.isMidWord {
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if !t.titleSpan(c) {
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break
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}
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c.isMidWord = true
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} else if !isLower(c) {
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break
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}
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} else if p.isBreak() {
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c.isMidWord = false
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}
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// As we save the state of the transformer, it is safe to call
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// checkpoint after any successful write.
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if !(c.isMidWord && wasMid) {
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c.checkpoint()
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}
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if !c.next() {
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break
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}
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if wasMid && c.info.isMid() {
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c.isMidWord = false
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}
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}
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return c.retSpan()
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}
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// finalSigma adds Greek final Sigma handing to another casing function. It
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// determines whether a lowercased sigma should be σ or ς, by looking ahead for
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// case-ignorables and a cased letters.
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func finalSigma(f mapFunc) mapFunc {
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return func(c *context) bool {
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if !c.hasPrefix("Σ") {
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return f(c)
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}
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return finalSigmaBody(c)
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}
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}
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func finalSigmaBody(c *context) bool {
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// Current rune must be ∑.
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// ::NFD();
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// # 03A3; 03C2; 03A3; 03A3; Final_Sigma; # GREEK CAPITAL LETTER SIGMA
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// Σ } [:case-ignorable:]* [:cased:] → σ;
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// [:cased:] [:case-ignorable:]* { Σ → ς;
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// ::Any-Lower;
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// ::NFC();
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p := c.pDst
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c.writeString("ς")
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// TODO: we should do this here, but right now this will never have an
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// effect as this is called when the prefix is Sigma, whereas Dutch and
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// Afrikaans only test for an apostrophe.
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//
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// if t.rewrite != nil {
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// t.rewrite(c)
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// }
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// We need to do one more iteration after maxIgnorable, as a cased
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// letter is not an ignorable and may modify the result.
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wasMid := false
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for i := 0; i < maxIgnorable+1; i++ {
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if !c.next() {
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return false
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}
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if !c.info.isCaseIgnorable() {
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// All Midword runes are also case ignorable, so we are
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// guaranteed to have a letter or word break here. As we are
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// unreading the run, there is no need to unset c.isMidWord;
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// the title caser will handle this.
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if c.info.isCased() {
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// p+1 is guaranteed to be in bounds: if writing ς was
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// successful, p+1 will contain the second byte of ς. If not,
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// this function will have returned after c.next returned false.
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c.dst[p+1]++ // ς → σ
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}
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c.unreadRune()
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return true
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}
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// A case ignorable may also introduce a word break, so we may need
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// to continue searching even after detecting a break.
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isMid := c.info.isMid()
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if (wasMid && isMid) || c.info.isBreak() {
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c.isMidWord = false
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}
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wasMid = isMid
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c.copy()
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}
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return true
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}
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// finalSigmaSpan would be the same as isLower.
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// elUpper implements Greek upper casing, which entails removing a predefined
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// set of non-blocked modifiers. Note that these accents should not be removed
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// for title casing!
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// Example: "Οδός" -> "ΟΔΟΣ".
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func elUpper(c *context) bool {
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// From CLDR:
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// [:Greek:] [^[:ccc=Not_Reordered:][:ccc=Above:]]*? { [\u0313\u0314\u0301\u0300\u0306\u0342\u0308\u0304] → ;
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// [:Greek:] [^[:ccc=Not_Reordered:][:ccc=Iota_Subscript:]]*? { \u0345 → ;
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r, _ := utf8.DecodeRune(c.src[c.pSrc:])
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oldPDst := c.pDst
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if !upper(c) {
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return false
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}
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if !unicode.Is(unicode.Greek, r) {
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return true
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}
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i := 0
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// Take the properties of the uppercased rune that is already written to the
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// destination. This saves us the trouble of having to uppercase the
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// decomposed rune again.
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if b := norm.NFD.Properties(c.dst[oldPDst:]).Decomposition(); b != nil {
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// Restore the destination position and process the decomposed rune.
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r, sz := utf8.DecodeRune(b)
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if r <= 0xFF { // See A.6.1
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return true
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}
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c.pDst = oldPDst
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// Insert the first rune and ignore the modifiers. See A.6.2.
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c.writeBytes(b[:sz])
|
||
i = len(b[sz:]) / 2 // Greek modifiers are always of length 2.
|
||
}
|
||
|
||
for ; i < maxIgnorable && c.next(); i++ {
|
||
switch r, _ := utf8.DecodeRune(c.src[c.pSrc:]); r {
|
||
// Above and Iota Subscript
|
||
case 0x0300, // U+0300 COMBINING GRAVE ACCENT
|
||
0x0301, // U+0301 COMBINING ACUTE ACCENT
|
||
0x0304, // U+0304 COMBINING MACRON
|
||
0x0306, // U+0306 COMBINING BREVE
|
||
0x0308, // U+0308 COMBINING DIAERESIS
|
||
0x0313, // U+0313 COMBINING COMMA ABOVE
|
||
0x0314, // U+0314 COMBINING REVERSED COMMA ABOVE
|
||
0x0342, // U+0342 COMBINING GREEK PERISPOMENI
|
||
0x0345: // U+0345 COMBINING GREEK YPOGEGRAMMENI
|
||
// No-op. Gobble the modifier.
|
||
|
||
default:
|
||
switch v, _ := trie.lookup(c.src[c.pSrc:]); info(v).cccType() {
|
||
case cccZero:
|
||
c.unreadRune()
|
||
return true
|
||
|
||
// We don't need to test for IotaSubscript as the only rune that
|
||
// qualifies (U+0345) was already excluded in the switch statement
|
||
// above. See A.4.
|
||
|
||
case cccAbove:
|
||
return c.copy()
|
||
default:
|
||
// Some other modifier. We're still allowed to gobble Greek
|
||
// modifiers after this.
|
||
c.copy()
|
||
}
|
||
}
|
||
}
|
||
return i == maxIgnorable
|
||
}
|
||
|
||
// TODO: implement elUpperSpan (low-priority: complex and infrequent).
|
||
|
||
func ltLower(c *context) bool {
|
||
// From CLDR:
|
||
// # Introduce an explicit dot above when lowercasing capital I's and J's
|
||
// # whenever there are more accents above.
|
||
// # (of the accents used in Lithuanian: grave, acute, tilde above, and ogonek)
|
||
// # 0049; 0069 0307; 0049; 0049; lt More_Above; # LATIN CAPITAL LETTER I
|
||
// # 004A; 006A 0307; 004A; 004A; lt More_Above; # LATIN CAPITAL LETTER J
|
||
// # 012E; 012F 0307; 012E; 012E; lt More_Above; # LATIN CAPITAL LETTER I WITH OGONEK
|
||
// # 00CC; 0069 0307 0300; 00CC; 00CC; lt; # LATIN CAPITAL LETTER I WITH GRAVE
|
||
// # 00CD; 0069 0307 0301; 00CD; 00CD; lt; # LATIN CAPITAL LETTER I WITH ACUTE
|
||
// # 0128; 0069 0307 0303; 0128; 0128; lt; # LATIN CAPITAL LETTER I WITH TILDE
|
||
// ::NFD();
|
||
// I } [^[:ccc=Not_Reordered:][:ccc=Above:]]* [:ccc=Above:] → i \u0307;
|
||
// J } [^[:ccc=Not_Reordered:][:ccc=Above:]]* [:ccc=Above:] → j \u0307;
|
||
// I \u0328 (Į) } [^[:ccc=Not_Reordered:][:ccc=Above:]]* [:ccc=Above:] → i \u0328 \u0307;
|
||
// I \u0300 (Ì) → i \u0307 \u0300;
|
||
// I \u0301 (Í) → i \u0307 \u0301;
|
||
// I \u0303 (Ĩ) → i \u0307 \u0303;
|
||
// ::Any-Lower();
|
||
// ::NFC();
|
||
|
||
i := 0
|
||
if r := c.src[c.pSrc]; r < utf8.RuneSelf {
|
||
lower(c)
|
||
if r != 'I' && r != 'J' {
|
||
return true
|
||
}
|
||
} else {
|
||
p := norm.NFD.Properties(c.src[c.pSrc:])
|
||
if d := p.Decomposition(); len(d) >= 3 && (d[0] == 'I' || d[0] == 'J') {
|
||
// UTF-8 optimization: the decomposition will only have an above
|
||
// modifier if the last rune of the decomposition is in [U+300-U+311].
|
||
// In all other cases, a decomposition starting with I is always
|
||
// an I followed by modifiers that are not cased themselves. See A.2.
|
||
if d[1] == 0xCC && d[2] <= 0x91 { // A.2.4.
|
||
if !c.writeBytes(d[:1]) {
|
||
return false
|
||
}
|
||
c.dst[c.pDst-1] += 'a' - 'A' // lower
|
||
|
||
// Assumption: modifier never changes on lowercase. See A.1.
|
||
// Assumption: all modifiers added have CCC = Above. See A.2.3.
|
||
return c.writeString("\u0307") && c.writeBytes(d[1:])
|
||
}
|
||
// In all other cases the additional modifiers will have a CCC
|
||
// that is less than 230 (Above). We will insert the U+0307, if
|
||
// needed, after these modifiers so that a string in FCD form
|
||
// will remain so. See A.2.2.
|
||
lower(c)
|
||
i = 1
|
||
} else {
|
||
return lower(c)
|
||
}
|
||
}
|
||
|
||
for ; i < maxIgnorable && c.next(); i++ {
|
||
switch c.info.cccType() {
|
||
case cccZero:
|
||
c.unreadRune()
|
||
return true
|
||
case cccAbove:
|
||
return c.writeString("\u0307") && c.copy() // See A.1.
|
||
default:
|
||
c.copy() // See A.1.
|
||
}
|
||
}
|
||
return i == maxIgnorable
|
||
}
|
||
|
||
// ltLowerSpan would be the same as isLower.
|
||
|
||
func ltUpper(f mapFunc) mapFunc {
|
||
return func(c *context) bool {
|
||
// Unicode:
|
||
// 0307; 0307; ; ; lt After_Soft_Dotted; # COMBINING DOT ABOVE
|
||
//
|
||
// From CLDR:
|
||
// # Remove \u0307 following soft-dotteds (i, j, and the like), with possible
|
||
// # intervening non-230 marks.
|
||
// ::NFD();
|
||
// [:Soft_Dotted:] [^[:ccc=Not_Reordered:][:ccc=Above:]]* { \u0307 → ;
|
||
// ::Any-Upper();
|
||
// ::NFC();
|
||
|
||
// TODO: See A.5. A soft-dotted rune never has an exception. This would
|
||
// allow us to overload the exception bit and encode this property in
|
||
// info. Need to measure performance impact of this.
|
||
r, _ := utf8.DecodeRune(c.src[c.pSrc:])
|
||
oldPDst := c.pDst
|
||
if !f(c) {
|
||
return false
|
||
}
|
||
if !unicode.Is(unicode.Soft_Dotted, r) {
|
||
return true
|
||
}
|
||
|
||
// We don't need to do an NFD normalization, as a soft-dotted rune never
|
||
// contains U+0307. See A.3.
|
||
|
||
i := 0
|
||
for ; i < maxIgnorable && c.next(); i++ {
|
||
switch c.info.cccType() {
|
||
case cccZero:
|
||
c.unreadRune()
|
||
return true
|
||
case cccAbove:
|
||
if c.hasPrefix("\u0307") {
|
||
// We don't do a full NFC, but rather combine runes for
|
||
// some of the common cases. (Returning NFC or
|
||
// preserving normal form is neither a requirement nor
|
||
// a possibility anyway).
|
||
if !c.next() {
|
||
return false
|
||
}
|
||
if c.dst[oldPDst] == 'I' && c.pDst == oldPDst+1 && c.src[c.pSrc] == 0xcc {
|
||
s := ""
|
||
switch c.src[c.pSrc+1] {
|
||
case 0x80: // U+0300 COMBINING GRAVE ACCENT
|
||
s = "\u00cc" // U+00CC LATIN CAPITAL LETTER I WITH GRAVE
|
||
case 0x81: // U+0301 COMBINING ACUTE ACCENT
|
||
s = "\u00cd" // U+00CD LATIN CAPITAL LETTER I WITH ACUTE
|
||
case 0x83: // U+0303 COMBINING TILDE
|
||
s = "\u0128" // U+0128 LATIN CAPITAL LETTER I WITH TILDE
|
||
case 0x88: // U+0308 COMBINING DIAERESIS
|
||
s = "\u00cf" // U+00CF LATIN CAPITAL LETTER I WITH DIAERESIS
|
||
default:
|
||
}
|
||
if s != "" {
|
||
c.pDst = oldPDst
|
||
return c.writeString(s)
|
||
}
|
||
}
|
||
}
|
||
return c.copy()
|
||
default:
|
||
c.copy()
|
||
}
|
||
}
|
||
return i == maxIgnorable
|
||
}
|
||
}
|
||
|
||
// TODO: implement ltUpperSpan (low priority: complex and infrequent).
|
||
|
||
func aztrUpper(f mapFunc) mapFunc {
|
||
return func(c *context) bool {
|
||
// i→İ;
|
||
if c.src[c.pSrc] == 'i' {
|
||
return c.writeString("İ")
|
||
}
|
||
return f(c)
|
||
}
|
||
}
|
||
|
||
func aztrLower(c *context) (done bool) {
|
||
// From CLDR:
|
||
// # I and i-dotless; I-dot and i are case pairs in Turkish and Azeri
|
||
// # 0130; 0069; 0130; 0130; tr; # LATIN CAPITAL LETTER I WITH DOT ABOVE
|
||
// İ→i;
|
||
// # When lowercasing, remove dot_above in the sequence I + dot_above, which will turn into i.
|
||
// # This matches the behavior of the canonically equivalent I-dot_above
|
||
// # 0307; ; 0307; 0307; tr After_I; # COMBINING DOT ABOVE
|
||
// # When lowercasing, unless an I is before a dot_above, it turns into a dotless i.
|
||
// # 0049; 0131; 0049; 0049; tr Not_Before_Dot; # LATIN CAPITAL LETTER I
|
||
// I([^[:ccc=Not_Reordered:][:ccc=Above:]]*)\u0307 → i$1 ;
|
||
// I→ı ;
|
||
// ::Any-Lower();
|
||
if c.hasPrefix("\u0130") { // İ
|
||
return c.writeString("i")
|
||
}
|
||
if c.src[c.pSrc] != 'I' {
|
||
return lower(c)
|
||
}
|
||
|
||
// We ignore the lower-case I for now, but insert it later when we know
|
||
// which form we need.
|
||
start := c.pSrc + c.sz
|
||
|
||
i := 0
|
||
Loop:
|
||
// We check for up to n ignorables before \u0307. As \u0307 is an
|
||
// ignorable as well, n is maxIgnorable-1.
|
||
for ; i < maxIgnorable && c.next(); i++ {
|
||
switch c.info.cccType() {
|
||
case cccAbove:
|
||
if c.hasPrefix("\u0307") {
|
||
return c.writeString("i") && c.writeBytes(c.src[start:c.pSrc]) // ignore U+0307
|
||
}
|
||
done = true
|
||
break Loop
|
||
case cccZero:
|
||
c.unreadRune()
|
||
done = true
|
||
break Loop
|
||
default:
|
||
// We'll write this rune after we know which starter to use.
|
||
}
|
||
}
|
||
if i == maxIgnorable {
|
||
done = true
|
||
}
|
||
return c.writeString("ı") && c.writeBytes(c.src[start:c.pSrc+c.sz]) && done
|
||
}
|
||
|
||
// aztrLowerSpan would be the same as isLower.
|
||
|
||
func nlTitle(c *context) bool {
|
||
// From CLDR:
|
||
// # Special titlecasing for Dutch initial "ij".
|
||
// ::Any-Title();
|
||
// # Fix up Ij at the beginning of a "word" (per Any-Title, notUAX #29)
|
||
// [:^WB=ALetter:] [:WB=Extend:]* [[:WB=MidLetter:][:WB=MidNumLet:]]? { Ij } → IJ ;
|
||
if c.src[c.pSrc] != 'I' && c.src[c.pSrc] != 'i' {
|
||
return title(c)
|
||
}
|
||
|
||
if !c.writeString("I") || !c.next() {
|
||
return false
|
||
}
|
||
if c.src[c.pSrc] == 'j' || c.src[c.pSrc] == 'J' {
|
||
return c.writeString("J")
|
||
}
|
||
c.unreadRune()
|
||
return true
|
||
}
|
||
|
||
func nlTitleSpan(c *context) bool {
|
||
// From CLDR:
|
||
// # Special titlecasing for Dutch initial "ij".
|
||
// ::Any-Title();
|
||
// # Fix up Ij at the beginning of a "word" (per Any-Title, notUAX #29)
|
||
// [:^WB=ALetter:] [:WB=Extend:]* [[:WB=MidLetter:][:WB=MidNumLet:]]? { Ij } → IJ ;
|
||
if c.src[c.pSrc] != 'I' {
|
||
return isTitle(c)
|
||
}
|
||
if !c.next() || c.src[c.pSrc] == 'j' {
|
||
return false
|
||
}
|
||
if c.src[c.pSrc] != 'J' {
|
||
c.unreadRune()
|
||
}
|
||
return true
|
||
}
|
||
|
||
// Not part of CLDR, but see https://unicode.org/cldr/trac/ticket/7078.
|
||
func afnlRewrite(c *context) {
|
||
if c.hasPrefix("'") || c.hasPrefix("’") {
|
||
c.isMidWord = true
|
||
}
|
||
}
|