mirror of
https://github.com/go-gitea/gitea
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336 lines
11 KiB
Go
Vendored
336 lines
11 KiB
Go
Vendored
// Copyright 2015 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 bidi
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import (
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"container/list"
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"fmt"
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"sort"
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)
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// This file contains a port of the reference implementation of the
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// Bidi Parentheses Algorithm:
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// https://www.unicode.org/Public/PROGRAMS/BidiReferenceJava/BidiPBAReference.java
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//
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// The implementation in this file covers definitions BD14-BD16 and rule N0
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// of UAX#9.
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//
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// Some preprocessing is done for each rune before data is passed to this
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// algorithm:
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// - opening and closing brackets are identified
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// - a bracket pair type, like '(' and ')' is assigned a unique identifier that
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// is identical for the opening and closing bracket. It is left to do these
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// mappings.
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// - The BPA algorithm requires that bracket characters that are canonical
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// equivalents of each other be able to be substituted for each other.
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// It is the responsibility of the caller to do this canonicalization.
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//
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// In implementing BD16, this implementation departs slightly from the "logical"
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// algorithm defined in UAX#9. In particular, the stack referenced there
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// supports operations that go beyond a "basic" stack. An equivalent
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// implementation based on a linked list is used here.
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// Bidi_Paired_Bracket_Type
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// BD14. An opening paired bracket is a character whose
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// Bidi_Paired_Bracket_Type property value is Open.
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//
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// BD15. A closing paired bracket is a character whose
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// Bidi_Paired_Bracket_Type property value is Close.
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type bracketType byte
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const (
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bpNone bracketType = iota
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bpOpen
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bpClose
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)
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// bracketPair holds a pair of index values for opening and closing bracket
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// location of a bracket pair.
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type bracketPair struct {
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opener int
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closer int
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}
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func (b *bracketPair) String() string {
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return fmt.Sprintf("(%v, %v)", b.opener, b.closer)
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}
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// bracketPairs is a slice of bracketPairs with a sort.Interface implementation.
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type bracketPairs []bracketPair
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func (b bracketPairs) Len() int { return len(b) }
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func (b bracketPairs) Swap(i, j int) { b[i], b[j] = b[j], b[i] }
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func (b bracketPairs) Less(i, j int) bool { return b[i].opener < b[j].opener }
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// resolvePairedBrackets runs the paired bracket part of the UBA algorithm.
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//
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// For each rune, it takes the indexes into the original string, the class the
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// bracket type (in pairTypes) and the bracket identifier (pairValues). It also
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// takes the direction type for the start-of-sentence and the embedding level.
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//
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// The identifiers for bracket types are the rune of the canonicalized opening
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// bracket for brackets (open or close) or 0 for runes that are not brackets.
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func resolvePairedBrackets(s *isolatingRunSequence) {
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p := bracketPairer{
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sos: s.sos,
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openers: list.New(),
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codesIsolatedRun: s.types,
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indexes: s.indexes,
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}
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dirEmbed := L
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if s.level&1 != 0 {
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dirEmbed = R
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}
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p.locateBrackets(s.p.pairTypes, s.p.pairValues)
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p.resolveBrackets(dirEmbed, s.p.initialTypes)
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}
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type bracketPairer struct {
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sos Class // direction corresponding to start of sequence
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// The following is a restatement of BD 16 using non-algorithmic language.
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//
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// A bracket pair is a pair of characters consisting of an opening
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// paired bracket and a closing paired bracket such that the
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// Bidi_Paired_Bracket property value of the former equals the latter,
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// subject to the following constraints.
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// - both characters of a pair occur in the same isolating run sequence
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// - the closing character of a pair follows the opening character
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// - any bracket character can belong at most to one pair, the earliest possible one
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// - any bracket character not part of a pair is treated like an ordinary character
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// - pairs may nest properly, but their spans may not overlap otherwise
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// Bracket characters with canonical decompositions are supposed to be
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// treated as if they had been normalized, to allow normalized and non-
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// normalized text to give the same result. In this implementation that step
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// is pushed out to the caller. The caller has to ensure that the pairValue
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// slices contain the rune of the opening bracket after normalization for
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// any opening or closing bracket.
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openers *list.List // list of positions for opening brackets
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// bracket pair positions sorted by location of opening bracket
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pairPositions bracketPairs
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codesIsolatedRun []Class // directional bidi codes for an isolated run
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indexes []int // array of index values into the original string
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}
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// matchOpener reports whether characters at given positions form a matching
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// bracket pair.
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func (p *bracketPairer) matchOpener(pairValues []rune, opener, closer int) bool {
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return pairValues[p.indexes[opener]] == pairValues[p.indexes[closer]]
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}
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const maxPairingDepth = 63
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// locateBrackets locates matching bracket pairs according to BD16.
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//
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// This implementation uses a linked list instead of a stack, because, while
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// elements are added at the front (like a push) they are not generally removed
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// in atomic 'pop' operations, reducing the benefit of the stack archetype.
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func (p *bracketPairer) locateBrackets(pairTypes []bracketType, pairValues []rune) {
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// traverse the run
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// do that explicitly (not in a for-each) so we can record position
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for i, index := range p.indexes {
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// look at the bracket type for each character
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if pairTypes[index] == bpNone || p.codesIsolatedRun[i] != ON {
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// continue scanning
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continue
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}
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switch pairTypes[index] {
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case bpOpen:
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// check if maximum pairing depth reached
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if p.openers.Len() == maxPairingDepth {
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p.openers.Init()
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return
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}
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// remember opener location, most recent first
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p.openers.PushFront(i)
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case bpClose:
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// see if there is a match
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count := 0
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for elem := p.openers.Front(); elem != nil; elem = elem.Next() {
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count++
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opener := elem.Value.(int)
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if p.matchOpener(pairValues, opener, i) {
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// if the opener matches, add nested pair to the ordered list
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p.pairPositions = append(p.pairPositions, bracketPair{opener, i})
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// remove up to and including matched opener
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for ; count > 0; count-- {
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p.openers.Remove(p.openers.Front())
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}
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break
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}
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}
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sort.Sort(p.pairPositions)
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// if we get here, the closing bracket matched no openers
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// and gets ignored
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}
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}
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}
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// Bracket pairs within an isolating run sequence are processed as units so
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// that both the opening and the closing paired bracket in a pair resolve to
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// the same direction.
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//
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// N0. Process bracket pairs in an isolating run sequence sequentially in
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// the logical order of the text positions of the opening paired brackets
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// using the logic given below. Within this scope, bidirectional types EN
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// and AN are treated as R.
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//
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// Identify the bracket pairs in the current isolating run sequence
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// according to BD16. For each bracket-pair element in the list of pairs of
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// text positions:
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//
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// a Inspect the bidirectional types of the characters enclosed within the
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// bracket pair.
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//
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// b If any strong type (either L or R) matching the embedding direction is
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// found, set the type for both brackets in the pair to match the embedding
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// direction.
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//
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// o [ e ] o -> o e e e o
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//
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// o [ o e ] -> o e o e e
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//
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// o [ NI e ] -> o e NI e e
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//
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// c Otherwise, if a strong type (opposite the embedding direction) is
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// found, test for adjacent strong types as follows: 1 First, check
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// backwards before the opening paired bracket until the first strong type
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// (L, R, or sos) is found. If that first preceding strong type is opposite
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// the embedding direction, then set the type for both brackets in the pair
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// to that type. 2 Otherwise, set the type for both brackets in the pair to
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// the embedding direction.
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//
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// o [ o ] e -> o o o o e
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//
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// o [ o NI ] o -> o o o NI o o
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//
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// e [ o ] o -> e e o e o
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//
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// e [ o ] e -> e e o e e
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//
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// e ( o [ o ] NI ) e -> e e o o o o NI e e
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//
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// d Otherwise, do not set the type for the current bracket pair. Note that
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// if the enclosed text contains no strong types the paired brackets will
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// both resolve to the same level when resolved individually using rules N1
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// and N2.
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//
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// e ( NI ) o -> e ( NI ) o
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// getStrongTypeN0 maps character's directional code to strong type as required
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// by rule N0.
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//
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// TODO: have separate type for "strong" directionality.
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func (p *bracketPairer) getStrongTypeN0(index int) Class {
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switch p.codesIsolatedRun[index] {
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// in the scope of N0, number types are treated as R
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case EN, AN, AL, R:
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return R
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case L:
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return L
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default:
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return ON
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}
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}
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// classifyPairContent reports the strong types contained inside a Bracket Pair,
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// assuming the given embedding direction.
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//
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// It returns ON if no strong type is found. If a single strong type is found,
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// it returns this type. Otherwise it returns the embedding direction.
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//
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// TODO: use separate type for "strong" directionality.
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func (p *bracketPairer) classifyPairContent(loc bracketPair, dirEmbed Class) Class {
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dirOpposite := ON
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for i := loc.opener + 1; i < loc.closer; i++ {
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dir := p.getStrongTypeN0(i)
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if dir == ON {
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continue
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}
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if dir == dirEmbed {
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return dir // type matching embedding direction found
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}
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dirOpposite = dir
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}
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// return ON if no strong type found, or class opposite to dirEmbed
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return dirOpposite
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}
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// classBeforePair determines which strong types are present before a Bracket
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// Pair. Return R or L if strong type found, otherwise ON.
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func (p *bracketPairer) classBeforePair(loc bracketPair) Class {
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for i := loc.opener - 1; i >= 0; i-- {
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if dir := p.getStrongTypeN0(i); dir != ON {
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return dir
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}
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}
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// no strong types found, return sos
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return p.sos
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}
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// assignBracketType implements rule N0 for a single bracket pair.
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func (p *bracketPairer) assignBracketType(loc bracketPair, dirEmbed Class, initialTypes []Class) {
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// rule "N0, a", inspect contents of pair
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dirPair := p.classifyPairContent(loc, dirEmbed)
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// dirPair is now L, R, or N (no strong type found)
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// the following logical tests are performed out of order compared to
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// the statement of the rules but yield the same results
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if dirPair == ON {
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return // case "d" - nothing to do
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}
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if dirPair != dirEmbed {
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// case "c": strong type found, opposite - check before (c.1)
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dirPair = p.classBeforePair(loc)
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if dirPair == dirEmbed || dirPair == ON {
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// no strong opposite type found before - use embedding (c.2)
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dirPair = dirEmbed
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}
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}
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// else: case "b", strong type found matching embedding,
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// no explicit action needed, as dirPair is already set to embedding
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// direction
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// set the bracket types to the type found
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p.setBracketsToType(loc, dirPair, initialTypes)
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}
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func (p *bracketPairer) setBracketsToType(loc bracketPair, dirPair Class, initialTypes []Class) {
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p.codesIsolatedRun[loc.opener] = dirPair
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p.codesIsolatedRun[loc.closer] = dirPair
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for i := loc.opener + 1; i < loc.closer; i++ {
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index := p.indexes[i]
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if initialTypes[index] != NSM {
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break
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}
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p.codesIsolatedRun[i] = dirPair
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}
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for i := loc.closer + 1; i < len(p.indexes); i++ {
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index := p.indexes[i]
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if initialTypes[index] != NSM {
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break
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}
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p.codesIsolatedRun[i] = dirPair
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}
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}
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// resolveBrackets implements rule N0 for a list of pairs.
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func (p *bracketPairer) resolveBrackets(dirEmbed Class, initialTypes []Class) {
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for _, loc := range p.pairPositions {
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p.assignBracketType(loc, dirEmbed, initialTypes)
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}
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}
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