mirror of
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203 lines
6.0 KiB
Go
203 lines
6.0 KiB
Go
// This file has been ported over from go 1.21.0 so that we can avoid
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// having to upgrade for basic comparison functions. Copyright notice
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// is preserved:
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// Copyright 2023 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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//go:generate go run $GOROOT/src/sort/gen_sort_variants.go -generic
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package slices
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import (
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"math/bits"
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"github.com/cockroachdb/pebble/shims/cmp"
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)
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// Sort sorts a slice of any ordered type in ascending order.
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// When sorting floating-point numbers, NaNs are ordered before other values.
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func Sort[S ~[]E, E cmp.Ordered](x S) {
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n := len(x)
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pdqsortOrdered(x, 0, n, bits.Len(uint(n)))
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}
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// SortFunc sorts the slice x in ascending order as determined by the cmp
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// function. This sort is not guaranteed to be stable.
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// cmp(a, b) should return a negative number when a < b, a positive number when
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// a > b and zero when a == b.
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//
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// SortFunc requires that cmp is a strict weak ordering.
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// See https://en.wikipedia.org/wiki/Weak_ordering#Strict_weak_orderings.
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func SortFunc[S ~[]E, E any](x S, cmp func(a, b E) int) {
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n := len(x)
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pdqsortCmpFunc(x, 0, n, bits.Len(uint(n)), cmp)
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}
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// SortStableFunc sorts the slice x while keeping the original order of equal
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// elements, using cmp to compare elements in the same way as [SortFunc].
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func SortStableFunc[S ~[]E, E any](x S, cmp func(a, b E) int) {
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stableCmpFunc(x, len(x), cmp)
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}
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// IsSorted reports whether x is sorted in ascending order.
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func IsSorted[S ~[]E, E cmp.Ordered](x S) bool {
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for i := len(x) - 1; i > 0; i-- {
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if cmp.Less(x[i], x[i-1]) {
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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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// IsSortedFunc reports whether x is sorted in ascending order, with cmp as the
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// comparison function as defined by [SortFunc].
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func IsSortedFunc[S ~[]E, E any](x S, cmp func(a, b E) int) bool {
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for i := len(x) - 1; i > 0; i-- {
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if cmp(x[i], x[i-1]) < 0 {
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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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// Min returns the minimal value in x. It panics if x is empty.
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// For floating-point numbers, Min propagates NaNs (any NaN value in x
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// forces the output to be NaN).
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func Min[S ~[]E, E cmp.Ordered](x S) E {
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if len(x) < 1 {
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panic("slices.Min: empty list")
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}
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m := x[0]
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for i := 1; i < len(x); i++ {
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if x[i] < m {
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m = x[i]
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}
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}
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return m
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}
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// MinFunc returns the minimal value in x, using cmp to compare elements.
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// It panics if x is empty. If there is more than one minimal element
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// according to the cmp function, MinFunc returns the first one.
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func MinFunc[S ~[]E, E any](x S, cmp func(a, b E) int) E {
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if len(x) < 1 {
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panic("slices.MinFunc: empty list")
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}
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m := x[0]
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for i := 1; i < len(x); i++ {
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if cmp(x[i], m) < 0 {
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m = x[i]
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}
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}
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return m
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}
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// Max returns the maximal value in x. It panics if x is empty.
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// For floating-point E, Max propagates NaNs (any NaN value in x
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// forces the output to be NaN).
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func Max[S ~[]E, E cmp.Ordered](x S) E {
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if len(x) < 1 {
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panic("slices.Max: empty list")
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}
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m := x[0]
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for i := 1; i < len(x); i++ {
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if x[i] > m {
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m = x[i]
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}
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}
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return m
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}
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// MaxFunc returns the maximal value in x, using cmp to compare elements.
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// It panics if x is empty. If there is more than one maximal element
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// according to the cmp function, MaxFunc returns the first one.
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func MaxFunc[S ~[]E, E any](x S, cmp func(a, b E) int) E {
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if len(x) < 1 {
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panic("slices.MaxFunc: empty list")
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}
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m := x[0]
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for i := 1; i < len(x); i++ {
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if cmp(x[i], m) > 0 {
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m = x[i]
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}
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}
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return m
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}
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// BinarySearch searches for target in a sorted slice and returns the position
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// where target is found, or the position where target would appear in the
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// sort order; it also returns a bool saying whether the target is really found
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// in the slice. The slice must be sorted in increasing order.
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func BinarySearch[S ~[]E, E cmp.Ordered](x S, target E) (int, bool) {
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// Inlining is faster than calling BinarySearchFunc with a lambda.
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n := len(x)
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// Define x[-1] < target and x[n] >= target.
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// Invariant: x[i-1] < target, x[j] >= target.
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i, j := 0, n
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for i < j {
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h := int(uint(i+j) >> 1) // avoid overflow when computing h
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// i ≤ h < j
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if cmp.Less(x[h], target) {
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i = h + 1 // preserves x[i-1] < target
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} else {
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j = h // preserves x[j] >= target
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}
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}
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// i == j, x[i-1] < target, and x[j] (= x[i]) >= target => answer is i.
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return i, i < n && (x[i] == target || (isNaN(x[i]) && isNaN(target)))
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}
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// BinarySearchFunc works like [BinarySearch], but uses a custom comparison
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// function. The slice must be sorted in increasing order, where "increasing"
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// is defined by cmp. cmp should return 0 if the slice element matches
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// the target, a negative number if the slice element precedes the target,
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// or a positive number if the slice element follows the target.
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// cmp must implement the same ordering as the slice, such that if
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// cmp(a, t) < 0 and cmp(b, t) >= 0, then a must precede b in the slice.
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func BinarySearchFunc[S ~[]E, E, T any](x S, target T, cmp func(E, T) int) (int, bool) {
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n := len(x)
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// Define cmp(x[-1], target) < 0 and cmp(x[n], target) >= 0 .
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// Invariant: cmp(x[i - 1], target) < 0, cmp(x[j], target) >= 0.
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i, j := 0, n
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for i < j {
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h := int(uint(i+j) >> 1) // avoid overflow when computing h
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// i ≤ h < j
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if cmp(x[h], target) < 0 {
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i = h + 1 // preserves cmp(x[i - 1], target) < 0
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} else {
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j = h // preserves cmp(x[j], target) >= 0
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}
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}
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// i == j, cmp(x[i-1], target) < 0, and cmp(x[j], target) (= cmp(x[i], target)) >= 0 => answer is i.
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return i, i < n && cmp(x[i], target) == 0
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}
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type sortedHint int // hint for pdqsort when choosing the pivot
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const (
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unknownHint sortedHint = iota
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increasingHint
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decreasingHint
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)
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// xorshift paper: https://www.jstatsoft.org/article/view/v008i14/xorshift.pdf
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type xorshift uint64
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func (r *xorshift) Next() uint64 {
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*r ^= *r << 13
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*r ^= *r >> 17
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*r ^= *r << 5
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return uint64(*r)
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}
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func nextPowerOfTwo(length int) uint {
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return 1 << bits.Len(uint(length))
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}
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// isNaN reports whether x is a NaN without requiring the math package.
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// This will always return false if T is not floating-point.
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func isNaN[T cmp.Ordered](x T) bool {
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return x != x
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}
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