// Copyright 2021 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package slices defines various functions useful with slices of any type. // Unless otherwise specified, these functions all apply to the elements // of a slice at index 0 <= i < len(s). // // Note that the less function in IsSortedFunc, SortFunc, SortStableFunc requires a // strict weak ordering (https://en.wikipedia.org/wiki/Weak_ordering#Strict_weak_orderings), // or the sorting may fail to sort correctly. A common case is when sorting slices of // floating-point numbers containing NaN values. package slices import "golang.org/x/exp/constraints" // Equal reports whether two slices are equal: the same length and all // elements equal. If the lengths are different, Equal returns false. // Otherwise, the elements are compared in increasing index order, and the // comparison stops at the first unequal pair. // Floating point NaNs are not considered equal. func Equal[E comparable](s1, s2 []E) bool { if len(s1) != len(s2) { return false } for i := range s1 { if s1[i] != s2[i] { return false } } return true } // EqualFunc reports whether two slices are equal using a comparison // function on each pair of elements. If the lengths are different, // EqualFunc returns false. Otherwise, the elements are compared in // increasing index order, and the comparison stops at the first index // for which eq returns false. func EqualFunc[E1, E2 any](s1 []E1, s2 []E2, eq func(E1, E2) bool) bool { if len(s1) != len(s2) { return false } for i, v1 := range s1 { v2 := s2[i] if !eq(v1, v2) { return false } } return true } // Compare compares the elements of s1 and s2. // The elements are compared sequentially, starting at index 0, // until one element is not equal to the other. // The result of comparing the first non-matching elements is returned. // If both slices are equal until one of them ends, the shorter slice is // considered less than the longer one. // The result is 0 if s1 == s2, -1 if s1 < s2, and +1 if s1 > s2. // Comparisons involving floating point NaNs are ignored. func Compare[E constraints.Ordered](s1, s2 []E) int { s2len := len(s2) for i, v1 := range s1 { if i >= s2len { return +1 } v2 := s2[i] switch { case v1 < v2: return -1 case v1 > v2: return +1 } } if len(s1) < s2len { return -1 } return 0 } // CompareFunc is like Compare but uses a comparison function // on each pair of elements. The elements are compared in increasing // index order, and the comparisons stop after the first time cmp // returns non-zero. // The result is the first non-zero result of cmp; if cmp always // returns 0 the result is 0 if len(s1) == len(s2), -1 if len(s1) < len(s2), // and +1 if len(s1) > len(s2). func CompareFunc[E1, E2 any](s1 []E1, s2 []E2, cmp func(E1, E2) int) int { s2len := len(s2) for i, v1 := range s1 { if i >= s2len { return +1 } v2 := s2[i] if c := cmp(v1, v2); c != 0 { return c } } if len(s1) < s2len { return -1 } return 0 } // Index returns the index of the first occurrence of v in s, // or -1 if not present. func Index[E comparable](s []E, v E) int { for i := range s { if v == s[i] { return i } } return -1 } // IndexFunc returns the first index i satisfying f(s[i]), // or -1 if none do. func IndexFunc[E any](s []E, f func(E) bool) int { for i := range s { if f(s[i]) { return i } } return -1 } // Contains reports whether v is present in s. func Contains[E comparable](s []E, v E) bool { return Index(s, v) >= 0 } // ContainsFunc reports whether at least one // element e of s satisfies f(e). func ContainsFunc[E any](s []E, f func(E) bool) bool { return IndexFunc(s, f) >= 0 } // Insert inserts the values v... into s at index i, // returning the modified slice. // In the returned slice r, r[i] == v[0]. // Insert panics if i is out of range. // This function is O(len(s) + len(v)). func Insert[S ~[]E, E any](s S, i int, v ...E) S { tot := len(s) + len(v) if tot <= cap(s) { s2 := s[:tot] copy(s2[i+len(v):], s[i:]) copy(s2[i:], v) return s2 } s2 := make(S, tot) copy(s2, s[:i]) copy(s2[i:], v) copy(s2[i+len(v):], s[i:]) return s2 } // Delete removes the elements s[i:j] from s, returning the modified slice. // Delete panics if s[i:j] is not a valid slice of s. // Delete modifies the contents of the slice s; it does not create a new slice. // Delete is O(len(s)-j), so if many items must be deleted, it is better to // make a single call deleting them all together than to delete one at a time. // Delete might not modify the elements s[len(s)-(j-i):len(s)]. If those // elements contain pointers you might consider zeroing those elements so that // objects they reference can be garbage collected. func Delete[S ~[]E, E any](s S, i, j int) S { _ = s[i:j] // bounds check return append(s[:i], s[j:]...) } // DeleteFunc removes any elements from s for which del returns true, // returning the modified slice. // When DeleteFunc removes m elements, it might not modify the elements // s[len(s)-m:len(s)]. If those elements contain pointers you might consider // zeroing those elements so that objects they reference can be garbage // collected. func DeleteFunc[S ~[]E, E any](s S, del func(E) bool) S { // Don't start copying elements until we find one to delete. for i, v := range s { if del(v) { j := i for i++; i < len(s); i++ { v = s[i] if !del(v) { s[j] = v j++ } } return s[:j] } } return s } // Replace replaces the elements s[i:j] by the given v, and returns the // modified slice. Replace panics if s[i:j] is not a valid slice of s. func Replace[S ~[]E, E any](s S, i, j int, v ...E) S { _ = s[i:j] // verify that i:j is a valid subslice tot := len(s[:i]) + len(v) + len(s[j:]) if tot <= cap(s) { s2 := s[:tot] copy(s2[i+len(v):], s[j:]) copy(s2[i:], v) return s2 } s2 := make(S, tot) copy(s2, s[:i]) copy(s2[i:], v) copy(s2[i+len(v):], s[j:]) return s2 } // Clone returns a copy of the slice. // The elements are copied using assignment, so this is a shallow clone. func Clone[S ~[]E, E any](s S) S { // Preserve nil in case it matters. if s == nil { return nil } return append(S([]E{}), s...) } // Compact replaces consecutive runs of equal elements with a single copy. // This is like the uniq command found on Unix. // Compact modifies the contents of the slice s; it does not create a new slice. // When Compact discards m elements in total, it might not modify the elements // s[len(s)-m:len(s)]. If those elements contain pointers you might consider // zeroing those elements so that objects they reference can be garbage collected. func Compact[S ~[]E, E comparable](s S) S { if len(s) < 2 { return s } i := 1 for k := 1; k < len(s); k++ { if s[k] != s[k-1] { if i != k { s[i] = s[k] } i++ } } return s[:i] } // CompactFunc is like Compact but uses a comparison function. func CompactFunc[S ~[]E, E any](s S, eq func(E, E) bool) S { if len(s) < 2 { return s } i := 1 for k := 1; k < len(s); k++ { if !eq(s[k], s[k-1]) { if i != k { s[i] = s[k] } i++ } } return s[:i] } // Grow increases the slice's capacity, if necessary, to guarantee space for // another n elements. After Grow(n), at least n elements can be appended // to the slice without another allocation. If n is negative or too large to // allocate the memory, Grow panics. func Grow[S ~[]E, E any](s S, n int) S { if n < 0 { panic("cannot be negative") } if n -= cap(s) - len(s); n > 0 { // TODO(https://go.dev/issue/53888): Make using []E instead of S // to workaround a compiler bug where the runtime.growslice optimization // does not take effect. Revert when the compiler is fixed. s = append([]E(s)[:cap(s)], make([]E, n)...)[:len(s)] } return s } // Clip removes unused capacity from the slice, returning s[:len(s):len(s)]. func Clip[S ~[]E, E any](s S) S { return s[:len(s):len(s)] }