mirror of
https://github.com/NVIDIA/nvidia-container-toolkit
synced 2024-11-24 04:54:00 +00:00
95 lines
2.3 KiB
Go
95 lines
2.3 KiB
Go
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package smetrics
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import (
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"math"
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)
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// The Ukkonen algorithm for calculating the Levenshtein distance. The algorithm is described in http://www.cs.helsinki.fi/u/ukkonen/InfCont85.PDF, or in docs/InfCont85.PDF. It runs on O(t . min(m, n)) where t is the actual distance between strings a and b. It needs O(min(t, m, n)) space. This function might be preferred over WagnerFischer() for *very* similar strings. But test it out yourself.
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// The first two parameters are the two strings to be compared. The last three parameters are the insertion cost, the deletion cost and the substitution cost. These are normally defined as 1, 1 and 2 respectively.
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func Ukkonen(a, b string, icost, dcost, scost int) int {
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var lowerCost int
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if icost < dcost && icost < scost {
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lowerCost = icost
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} else if dcost < scost {
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lowerCost = dcost
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} else {
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lowerCost = scost
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}
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infinite := math.MaxInt32 / 2
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var r []int
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var k, kprime, p, t int
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var ins, del, sub int
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if len(a) > len(b) {
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t = (len(a) - len(b) + 1) * lowerCost
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} else {
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t = (len(b) - len(a) + 1) * lowerCost
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}
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for {
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if (t / lowerCost) < (len(b) - len(a)) {
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continue
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}
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// This is the right damn thing since the original Ukkonen
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// paper minimizes the expression result only, but the uncommented version
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// doesn't need to deal with floats so it's faster.
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// p = int(math.Floor(0.5*((float64(t)/float64(lowerCost)) - float64(len(b) - len(a)))))
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p = ((t / lowerCost) - (len(b) - len(a))) / 2
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k = -p
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kprime = k
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rowlength := (len(b) - len(a)) + (2 * p)
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r = make([]int, rowlength+2)
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for i := 0; i < rowlength+2; i++ {
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r[i] = infinite
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}
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for i := 0; i <= len(a); i++ {
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for j := 0; j <= rowlength; j++ {
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if i == j+k && i == 0 {
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r[j] = 0
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} else {
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if j-1 < 0 {
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ins = infinite
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} else {
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ins = r[j-1] + icost
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}
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del = r[j+1] + dcost
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sub = r[j] + scost
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if i-1 < 0 || i-1 >= len(a) || j+k-1 >= len(b) || j+k-1 < 0 {
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sub = infinite
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} else if a[i-1] == b[j+k-1] {
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sub = r[j]
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}
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if ins < del && ins < sub {
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r[j] = ins
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} else if del < sub {
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r[j] = del
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} else {
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r[j] = sub
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}
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}
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}
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k++
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}
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if r[(len(b)-len(a))+(2*p)+kprime] <= t {
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break
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} else {
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t *= 2
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}
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}
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return r[(len(b)-len(a))+(2*p)+kprime]
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}
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