mirror of
https://github.com/Luzifer/mondash.git
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295 lines
8.5 KiB
Go
295 lines
8.5 KiB
Go
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// 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 build
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import (
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"fmt"
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"unicode"
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"golang.org/x/text/internal/colltab"
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)
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const (
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defaultSecondary = 0x20
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defaultTertiary = 0x2
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maxTertiary = 0x1F
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)
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type rawCE struct {
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w []int
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ccc uint8
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}
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func makeRawCE(w []int, ccc uint8) rawCE {
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ce := rawCE{w: make([]int, 4), ccc: ccc}
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copy(ce.w, w)
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return ce
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}
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// A collation element is represented as an uint32.
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// In the typical case, a rune maps to a single collation element. If a rune
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// can be the start of a contraction or expands into multiple collation elements,
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// then the collation element that is associated with a rune will have a special
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// form to represent such m to n mappings. Such special collation elements
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// have a value >= 0x80000000.
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const (
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maxPrimaryBits = 21
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maxSecondaryBits = 12
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maxTertiaryBits = 8
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)
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func makeCE(ce rawCE) (uint32, error) {
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v, e := colltab.MakeElem(ce.w[0], ce.w[1], ce.w[2], ce.ccc)
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return uint32(v), e
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}
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// For contractions, collation elements are of the form
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// 110bbbbb bbbbbbbb iiiiiiii iiiinnnn, where
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// - n* is the size of the first node in the contraction trie.
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// - i* is the index of the first node in the contraction trie.
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// - b* is the offset into the contraction collation element table.
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// See contract.go for details on the contraction trie.
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const (
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contractID = 0xC0000000
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maxNBits = 4
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maxTrieIndexBits = 12
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maxContractOffsetBits = 13
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)
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func makeContractIndex(h ctHandle, offset int) (uint32, error) {
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if h.n >= 1<<maxNBits {
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return 0, fmt.Errorf("size of contraction trie node too large: %d >= %d", h.n, 1<<maxNBits)
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}
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if h.index >= 1<<maxTrieIndexBits {
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return 0, fmt.Errorf("size of contraction trie offset too large: %d >= %d", h.index, 1<<maxTrieIndexBits)
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}
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if offset >= 1<<maxContractOffsetBits {
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return 0, fmt.Errorf("contraction offset out of bounds: %x >= %x", offset, 1<<maxContractOffsetBits)
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}
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ce := uint32(contractID)
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ce += uint32(offset << (maxNBits + maxTrieIndexBits))
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ce += uint32(h.index << maxNBits)
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ce += uint32(h.n)
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return ce, nil
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}
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// For expansions, collation elements are of the form
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// 11100000 00000000 bbbbbbbb bbbbbbbb,
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// where b* is the index into the expansion sequence table.
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const (
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expandID = 0xE0000000
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maxExpandIndexBits = 16
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)
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func makeExpandIndex(index int) (uint32, error) {
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if index >= 1<<maxExpandIndexBits {
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return 0, fmt.Errorf("expansion index out of bounds: %x >= %x", index, 1<<maxExpandIndexBits)
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}
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return expandID + uint32(index), nil
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}
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// Each list of collation elements corresponding to an expansion starts with
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// a header indicating the length of the sequence.
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func makeExpansionHeader(n int) (uint32, error) {
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return uint32(n), nil
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}
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// Some runes can be expanded using NFKD decomposition. Instead of storing the full
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// sequence of collation elements, we decompose the rune and lookup the collation
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// elements for each rune in the decomposition and modify the tertiary weights.
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// The collation element, in this case, is of the form
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// 11110000 00000000 wwwwwwww vvvvvvvv, where
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// - v* is the replacement tertiary weight for the first rune,
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// - w* is the replacement tertiary weight for the second rune,
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// Tertiary weights of subsequent runes should be replaced with maxTertiary.
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// See http://www.unicode.org/reports/tr10/#Compatibility_Decompositions for more details.
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const (
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decompID = 0xF0000000
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)
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func makeDecompose(t1, t2 int) (uint32, error) {
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if t1 >= 256 || t1 < 0 {
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return 0, fmt.Errorf("first tertiary weight out of bounds: %d >= 256", t1)
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}
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if t2 >= 256 || t2 < 0 {
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return 0, fmt.Errorf("second tertiary weight out of bounds: %d >= 256", t2)
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}
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return uint32(t2<<8+t1) + decompID, nil
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}
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const (
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// These constants were taken from http://www.unicode.org/versions/Unicode6.0.0/ch12.pdf.
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minUnified rune = 0x4E00
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maxUnified = 0x9FFF
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minCompatibility = 0xF900
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maxCompatibility = 0xFAFF
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minRare = 0x3400
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maxRare = 0x4DBF
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)
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const (
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commonUnifiedOffset = 0x10000
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rareUnifiedOffset = 0x20000 // largest rune in common is U+FAFF
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otherOffset = 0x50000 // largest rune in rare is U+2FA1D
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illegalOffset = otherOffset + int(unicode.MaxRune)
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maxPrimary = illegalOffset + 1
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)
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// implicitPrimary returns the primary weight for the a rune
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// for which there is no entry for the rune in the collation table.
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// We take a different approach from the one specified in
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// http://unicode.org/reports/tr10/#Implicit_Weights,
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// but preserve the resulting relative ordering of the runes.
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func implicitPrimary(r rune) int {
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if unicode.Is(unicode.Ideographic, r) {
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if r >= minUnified && r <= maxUnified {
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// The most common case for CJK.
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return int(r) + commonUnifiedOffset
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}
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if r >= minCompatibility && r <= maxCompatibility {
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// This will typically not hit. The DUCET explicitly specifies mappings
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// for all characters that do not decompose.
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return int(r) + commonUnifiedOffset
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}
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return int(r) + rareUnifiedOffset
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}
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return int(r) + otherOffset
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}
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// convertLargeWeights converts collation elements with large
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// primaries (either double primaries or for illegal runes)
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// to our own representation.
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// A CJK character C is represented in the DUCET as
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// [.FBxx.0020.0002.C][.BBBB.0000.0000.C]
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// We will rewrite these characters to a single CE.
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// We assume the CJK values start at 0x8000.
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// See http://unicode.org/reports/tr10/#Implicit_Weights
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func convertLargeWeights(elems []rawCE) (res []rawCE, err error) {
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const (
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cjkPrimaryStart = 0xFB40
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rarePrimaryStart = 0xFB80
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otherPrimaryStart = 0xFBC0
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illegalPrimary = 0xFFFE
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highBitsMask = 0x3F
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lowBitsMask = 0x7FFF
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lowBitsFlag = 0x8000
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shiftBits = 15
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)
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for i := 0; i < len(elems); i++ {
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ce := elems[i].w
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p := ce[0]
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if p < cjkPrimaryStart {
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continue
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}
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if p > 0xFFFF {
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return elems, fmt.Errorf("found primary weight %X; should be <= 0xFFFF", p)
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}
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if p >= illegalPrimary {
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ce[0] = illegalOffset + p - illegalPrimary
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} else {
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if i+1 >= len(elems) {
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return elems, fmt.Errorf("second part of double primary weight missing: %v", elems)
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}
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if elems[i+1].w[0]&lowBitsFlag == 0 {
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return elems, fmt.Errorf("malformed second part of double primary weight: %v", elems)
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}
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np := ((p & highBitsMask) << shiftBits) + elems[i+1].w[0]&lowBitsMask
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switch {
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case p < rarePrimaryStart:
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np += commonUnifiedOffset
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case p < otherPrimaryStart:
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np += rareUnifiedOffset
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default:
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p += otherOffset
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}
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ce[0] = np
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for j := i + 1; j+1 < len(elems); j++ {
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elems[j] = elems[j+1]
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}
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elems = elems[:len(elems)-1]
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}
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}
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return elems, nil
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}
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// nextWeight computes the first possible collation weights following elems
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// for the given level.
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func nextWeight(level colltab.Level, elems []rawCE) []rawCE {
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if level == colltab.Identity {
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next := make([]rawCE, len(elems))
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copy(next, elems)
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return next
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}
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next := []rawCE{makeRawCE(elems[0].w, elems[0].ccc)}
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next[0].w[level]++
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if level < colltab.Secondary {
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next[0].w[colltab.Secondary] = defaultSecondary
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}
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if level < colltab.Tertiary {
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next[0].w[colltab.Tertiary] = defaultTertiary
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}
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// Filter entries that cannot influence ordering.
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for _, ce := range elems[1:] {
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skip := true
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for i := colltab.Primary; i < level; i++ {
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skip = skip && ce.w[i] == 0
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}
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if !skip {
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next = append(next, ce)
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}
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}
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return next
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}
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func nextVal(elems []rawCE, i int, level colltab.Level) (index, value int) {
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for ; i < len(elems) && elems[i].w[level] == 0; i++ {
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}
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if i < len(elems) {
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return i, elems[i].w[level]
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}
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return i, 0
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}
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// compareWeights returns -1 if a < b, 1 if a > b, or 0 otherwise.
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// It also returns the collation level at which the difference is found.
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func compareWeights(a, b []rawCE) (result int, level colltab.Level) {
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for level := colltab.Primary; level < colltab.Identity; level++ {
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var va, vb int
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for ia, ib := 0, 0; ia < len(a) || ib < len(b); ia, ib = ia+1, ib+1 {
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ia, va = nextVal(a, ia, level)
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ib, vb = nextVal(b, ib, level)
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if va != vb {
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if va < vb {
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return -1, level
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} else {
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return 1, level
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}
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}
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}
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}
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return 0, colltab.Identity
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}
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func equalCE(a, b rawCE) bool {
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for i := 0; i < 3; i++ {
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if b.w[i] != a.w[i] {
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return false
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}
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}
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return true
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}
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func equalCEArrays(a, b []rawCE) bool {
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if len(a) != len(b) {
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return false
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}
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for i := range a {
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if !equalCE(a[i], b[i]) {
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return false
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}
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}
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return true
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}
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