9a18821cfc
From-SVN: r186026
169 lines
4.8 KiB
Go
169 lines
4.8 KiB
Go
// Copyright 2011 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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// This algorithm is based on "Faster Suffix Sorting"
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// by N. Jesper Larsson and Kunihiko Sadakane
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// paper: http://www.larsson.dogma.net/ssrev-tr.pdf
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// code: http://www.larsson.dogma.net/qsufsort.c
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// This algorithm computes the suffix array sa by computing its inverse.
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// Consecutive groups of suffixes in sa are labeled as sorted groups or
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// unsorted groups. For a given pass of the sorter, all suffixes are ordered
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// up to their first h characters, and sa is h-ordered. Suffixes in their
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// final positions and unambiguously sorted in h-order are in a sorted group.
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// Consecutive groups of suffixes with identical first h characters are an
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// unsorted group. In each pass of the algorithm, unsorted groups are sorted
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// according to the group number of their following suffix.
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// In the implementation, if sa[i] is negative, it indicates that i is
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// the first element of a sorted group of length -sa[i], and can be skipped.
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// An unsorted group sa[i:k] is given the group number of the index of its
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// last element, k-1. The group numbers are stored in the inverse slice (inv),
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// and when all groups are sorted, this slice is the inverse suffix array.
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package suffixarray
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import "sort"
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func qsufsort(data []byte) []int {
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// initial sorting by first byte of suffix
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sa := sortedByFirstByte(data)
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if len(sa) < 2 {
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return sa
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}
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// initialize the group lookup table
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// this becomes the inverse of the suffix array when all groups are sorted
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inv := initGroups(sa, data)
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// the index starts 1-ordered
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sufSortable := &suffixSortable{sa: sa, inv: inv, h: 1}
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for sa[0] > -len(sa) { // until all suffixes are one big sorted group
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// The suffixes are h-ordered, make them 2*h-ordered
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pi := 0 // pi is first position of first group
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sl := 0 // sl is negated length of sorted groups
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for pi < len(sa) {
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if s := sa[pi]; s < 0 { // if pi starts sorted group
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pi -= s // skip over sorted group
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sl += s // add negated length to sl
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} else { // if pi starts unsorted group
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if sl != 0 {
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sa[pi+sl] = sl // combine sorted groups before pi
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sl = 0
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}
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pk := inv[s] + 1 // pk-1 is last position of unsorted group
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sufSortable.sa = sa[pi:pk]
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sort.Sort(sufSortable)
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sufSortable.updateGroups(pi)
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pi = pk // next group
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}
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}
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if sl != 0 { // if the array ends with a sorted group
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sa[pi+sl] = sl // combine sorted groups at end of sa
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}
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sufSortable.h *= 2 // double sorted depth
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}
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for i := range sa { // reconstruct suffix array from inverse
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sa[inv[i]] = i
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}
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return sa
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}
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func sortedByFirstByte(data []byte) []int {
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// total byte counts
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var count [256]int
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for _, b := range data {
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count[b]++
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}
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// make count[b] equal index of first occurrence of b in sorted array
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sum := 0
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for b := range count {
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count[b], sum = sum, count[b]+sum
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}
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// iterate through bytes, placing index into the correct spot in sa
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sa := make([]int, len(data))
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for i, b := range data {
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sa[count[b]] = i
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count[b]++
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}
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return sa
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}
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func initGroups(sa []int, data []byte) []int {
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// label contiguous same-letter groups with the same group number
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inv := make([]int, len(data))
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prevGroup := len(sa) - 1
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groupByte := data[sa[prevGroup]]
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for i := len(sa) - 1; i >= 0; i-- {
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if b := data[sa[i]]; b < groupByte {
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if prevGroup == i+1 {
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sa[i+1] = -1
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}
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groupByte = b
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prevGroup = i
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}
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inv[sa[i]] = prevGroup
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if prevGroup == 0 {
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sa[0] = -1
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}
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}
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// Separate out the final suffix to the start of its group.
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// This is necessary to ensure the suffix "a" is before "aba"
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// when using a potentially unstable sort.
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lastByte := data[len(data)-1]
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s := -1
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for i := range sa {
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if sa[i] >= 0 {
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if data[sa[i]] == lastByte && s == -1 {
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s = i
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}
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if sa[i] == len(sa)-1 {
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sa[i], sa[s] = sa[s], sa[i]
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inv[sa[s]] = s
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sa[s] = -1 // mark it as an isolated sorted group
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break
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}
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}
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}
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return inv
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}
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type suffixSortable struct {
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sa []int
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inv []int
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h int
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buf []int // common scratch space
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}
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func (x *suffixSortable) Len() int { return len(x.sa) }
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func (x *suffixSortable) Less(i, j int) bool { return x.inv[x.sa[i]+x.h] < x.inv[x.sa[j]+x.h] }
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func (x *suffixSortable) Swap(i, j int) { x.sa[i], x.sa[j] = x.sa[j], x.sa[i] }
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func (x *suffixSortable) updateGroups(offset int) {
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bounds := x.buf[0:0]
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group := x.inv[x.sa[0]+x.h]
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for i := 1; i < len(x.sa); i++ {
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if g := x.inv[x.sa[i]+x.h]; g > group {
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bounds = append(bounds, i)
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group = g
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}
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}
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bounds = append(bounds, len(x.sa))
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x.buf = bounds
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// update the group numberings after all new groups are determined
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prev := 0
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for _, b := range bounds {
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for i := prev; i < b; i++ {
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x.inv[x.sa[i]] = offset + b - 1
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}
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if b-prev == 1 {
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x.sa[prev] = -1
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}
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prev = b
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}
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}
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