src/sort/search.go - go - Git at Google

 // Copyright 2010 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.

 // This file implements binary search.

 package sort

 // Search uses binary search to find and return the smallest index i
 // in [0, n) at which f(i) is true, assuming that on the range [0, n),
 // f(i) == true implies f(i+1) == true. That is, Search requires that
 // f is false for some (possibly empty) prefix of the input range [0, n)
 // and then true for the (possibly empty) remainder; Search returns
 // the first true index. If there is no such index, Search returns n.
 // (Note that the "not found" return value is not -1 as in, for instance,
 // strings.Index.)
 // Search calls f(i) only for i in the range [0, n).
 //
 // A common use of Search is to find the index i for a value x in
 // a sorted, indexable data structure such as an array or slice.
 // In this case, the argument f, typically a closure, captures the value
 // to be searched for, and how the data structure is indexed and
 // ordered.
 //
 // For instance, given a slice data sorted in ascending order,
 // the call Search(len(data), func(i int) bool { return data[i] >= 23 })
 // returns the smallest index i such that data[i] >= 23. If the caller
 // wants to find whether 23 is in the slice, it must test data[i] == 23
 // separately.
 //
 // Searching data sorted in descending order would use the <=
 // operator instead of the >= operator.
 //
 // To complete the example above, the following code tries to find the value
 // x in an integer slice data sorted in ascending order:
 //
 //	x := 23
 //	i := sort.Search(len(data), func(i int) bool { return data[i] >= x })
 //	if i < len(data) && data[i] == x {
 //		// x is present at data[i]
 //	} else {
 //		// x is not present in data,
 //		// but i is the index where it would be inserted.
 //	}
 //
 // As a more whimsical example, this program guesses your number:
 //
 //	func GuessingGame() {
 //		var s string
 //		fmt.Printf("Pick an integer from 0 to 100.\n")
 //		answer := sort.Search(100, func(i int) bool {
 //			fmt.Printf("Is your number <= %d? ", i)
 //			fmt.Scanf("%s", &s)
 //			return s != "" && s[0] == 'y'
 //		})
 //		fmt.Printf("Your number is %d.\n", answer)
 //	}
 func Search(n int, f func(int) bool) int {
 	// Define f(-1) == false and f(n) == true.
 	// Invariant: f(i-1) == false, f(j) == true.
 	i, j := 0, n
 	for i < j {
 		h := int(uint(i+j) >> 1) // avoid overflow when computing h
 		// i ≤ h < j
 		if !f(h) {
 			i = h + 1 // preserves f(i-1) == false
 		} else {
 			j = h // preserves f(j) == true
 		}
 	}
 	// i == j, f(i-1) == false, and f(j) (= f(i)) == true  =>  answer is i.
 	return i
 }

 // Find uses binary search to find and return the smallest index i in [0, n)
 // at which cmp(i) <= 0. If there is no such index i, Find returns i = n.
 // The found result is true if i < n and cmp(i) == 0.
 // Find calls cmp(i) only for i in the range [0, n).
 //
 // To permit binary search, Find requires that cmp(i) > 0 for a leading
 // prefix of the range, cmp(i) == 0 in the middle, and cmp(i) < 0 for
 // the final suffix of the range. (Each subrange could be empty.)
 // The usual way to establish this condition is to interpret cmp(i)
 // as a comparison of a desired target value t against entry i in an
 // underlying indexed data structure x, returning <0, 0, and >0
 // when t < x[i], t == x[i], and t > x[i], respectively.
 //
 // For example, to look for a particular string in a sorted, random-access
 // list of strings:
 //
 //	i, found := sort.Find(x.Len(), func(i int) int {
 //	    return strings.Compare(target, x.At(i))
 //	})
 //	if found {
 //	    fmt.Printf("found %s at entry %d\n", target, i)
 //	} else {
 //	    fmt.Printf("%s not found, would insert at %d", target, i)
 //	}
 func Find(n int, cmp func(int) int) (i int, found bool) {
 	// The invariants here are similar to the ones in Search.
 	// Define cmp(-1) > 0 and cmp(n) <= 0
 	// Invariant: cmp(i-1) > 0, cmp(j) <= 0
 	i, j := 0, n
 	for i < j {
 		h := int(uint(i+j) >> 1) // avoid overflow when computing h
 		// i ≤ h < j
 		if cmp(h) > 0 {
 			i = h + 1 // preserves cmp(i-1) > 0
 		} else {
 			j = h // preserves cmp(j) <= 0
 		}
 	}
 	// i == j, cmp(i-1) > 0 and cmp(j) <= 0
 	return i, i < n && cmp(i) == 0
 }

 // Convenience wrappers for common cases.

 // SearchInts searches for x in a sorted slice of ints and returns the index
 // as specified by [Search]. The return value is the index to insert x if x is
 // not present (it could be len(a)).
 // The slice must be sorted in ascending order.
 func SearchInts(a []int, x int) int {
 	return Search(len(a), func(i int) bool { return a[i] >= x })
 }

 // SearchFloat64s searches for x in a sorted slice of float64s and returns the index
 // as specified by [Search]. The return value is the index to insert x if x is not
 // present (it could be len(a)).
 // The slice must be sorted in ascending order.
 func SearchFloat64s(a []float64, x float64) int {
 	return Search(len(a), func(i int) bool { return a[i] >= x })
 }

 // SearchStrings searches for x in a sorted slice of strings and returns the index
 // as specified by Search. The return value is the index to insert x if x is not
 // present (it could be len(a)).
 // The slice must be sorted in ascending order.
 func SearchStrings(a []string, x string) int {
 	return Search(len(a), func(i int) bool { return a[i] >= x })
 }

 // Search returns the result of applying [SearchInts] to the receiver and x.
 func (p IntSlice) Search(x int) int { return SearchInts(p, x) }

 // Search returns the result of applying [SearchFloat64s] to the receiver and x.
 func (p Float64Slice) Search(x float64) int { return SearchFloat64s(p, x) }

 // Search returns the result of applying [SearchStrings] to the receiver and x.
 func (p StringSlice) Search(x string) int { return SearchStrings(p, x) }
	// Copyright 2010 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.

	// This file implements binary search.

	package sort

	// Search uses binary search to find and return the smallest index i
	// in [0, n) at which f(i) is true, assuming that on the range [0, n),
	// f(i) == true implies f(i+1) == true. That is, Search requires that
	// f is false for some (possibly empty) prefix of the input range [0, n)
	// and then true for the (possibly empty) remainder; Search returns
	// the first true index. If there is no such index, Search returns n.
	// (Note that the "not found" return value is not -1 as in, for instance,
	// strings.Index.)
	// Search calls f(i) only for i in the range [0, n).
	//
	// A common use of Search is to find the index i for a value x in
	// a sorted, indexable data structure such as an array or slice.
	// In this case, the argument f, typically a closure, captures the value
	// to be searched for, and how the data structure is indexed and
	// ordered.
	//
	// For instance, given a slice data sorted in ascending order,
	// the call Search(len(data), func(i int) bool { return data[i] >= 23 })
	// returns the smallest index i such that data[i] >= 23. If the caller
	// wants to find whether 23 is in the slice, it must test data[i] == 23
	// separately.
	//
	// Searching data sorted in descending order would use the <=
	// operator instead of the >= operator.
	//
	// To complete the example above, the following code tries to find the value
	// x in an integer slice data sorted in ascending order:
	//
	// x := 23
	// i := sort.Search(len(data), func(i int) bool { return data[i] >= x })
	// if i < len(data) && data[i] == x {
	// // x is present at data[i]
	// } else {
	// // x is not present in data,
	// // but i is the index where it would be inserted.
	// }
	//
	// As a more whimsical example, this program guesses your number:
	//
	// func GuessingGame() {
	// var s string
	// fmt.Printf("Pick an integer from 0 to 100.\n")
	// answer := sort.Search(100, func(i int) bool {
	// fmt.Printf("Is your number <= %d? ", i)
	// fmt.Scanf("%s", &s)
	// return s != "" && s[0] == 'y'
	// })
	// fmt.Printf("Your number is %d.\n", answer)
	// }
	func Search(n int, f func(int) bool) int {
	// Define f(-1) == false and f(n) == true.
	// Invariant: f(i-1) == false, f(j) == true.
	i, j := 0, n
	for i < j {
	h := int(uint(i+j) >> 1) // avoid overflow when computing h
	// i ≤ h < j
	if !f(h) {
	i = h + 1 // preserves f(i-1) == false
	} else {
	j = h // preserves f(j) == true
	}
	}
	// i == j, f(i-1) == false, and f(j) (= f(i)) == true => answer is i.
	return i
	}

	// Find uses binary search to find and return the smallest index i in [0, n)
	// at which cmp(i) <= 0. If there is no such index i, Find returns i = n.
	// The found result is true if i < n and cmp(i) == 0.
	// Find calls cmp(i) only for i in the range [0, n).
	//
	// To permit binary search, Find requires that cmp(i) > 0 for a leading
	// prefix of the range, cmp(i) == 0 in the middle, and cmp(i) < 0 for
	// the final suffix of the range. (Each subrange could be empty.)
	// The usual way to establish this condition is to interpret cmp(i)
	// as a comparison of a desired target value t against entry i in an
	// underlying indexed data structure x, returning <0, 0, and >0
	// when t < x[i], t == x[i], and t > x[i], respectively.
	//
	// For example, to look for a particular string in a sorted, random-access
	// list of strings:
	//
	// i, found := sort.Find(x.Len(), func(i int) int {
	// return strings.Compare(target, x.At(i))
	// })
	// if found {
	// fmt.Printf("found %s at entry %d\n", target, i)
	// } else {
	// fmt.Printf("%s not found, would insert at %d", target, i)
	// }
	func Find(n int, cmp func(int) int) (i int, found bool) {
	// The invariants here are similar to the ones in Search.
	// Define cmp(-1) > 0 and cmp(n) <= 0
	// Invariant: cmp(i-1) > 0, cmp(j) <= 0
	i, j := 0, n
	for i < j {
	h := int(uint(i+j) >> 1) // avoid overflow when computing h
	// i ≤ h < j
	if cmp(h) > 0 {
	i = h + 1 // preserves cmp(i-1) > 0
	} else {
	j = h // preserves cmp(j) <= 0
	}
	}
	// i == j, cmp(i-1) > 0 and cmp(j) <= 0
	return i, i < n && cmp(i) == 0
	}

	// Convenience wrappers for common cases.

	// SearchInts searches for x in a sorted slice of ints and returns the index
	// as specified by [Search]. The return value is the index to insert x if x is
	// not present (it could be len(a)).
	// The slice must be sorted in ascending order.
	func SearchInts(a []int, x int) int {
	return Search(len(a), func(i int) bool { return a[i] >= x })
	}

	// SearchFloat64s searches for x in a sorted slice of float64s and returns the index
	// as specified by [Search]. The return value is the index to insert x if x is not
	// present (it could be len(a)).
	// The slice must be sorted in ascending order.
	func SearchFloat64s(a []float64, x float64) int {
	return Search(len(a), func(i int) bool { return a[i] >= x })
	}

	// SearchStrings searches for x in a sorted slice of strings and returns the index
	// as specified by Search. The return value is the index to insert x if x is not
	// present (it could be len(a)).
	// The slice must be sorted in ascending order.
	func SearchStrings(a []string, x string) int {
	return Search(len(a), func(i int) bool { return a[i] >= x })
	}

	// Search returns the result of applying [SearchInts] to the receiver and x.
	func (p IntSlice) Search(x int) int { return SearchInts(p, x) }

	// Search returns the result of applying [SearchFloat64s] to the receiver and x.
	func (p Float64Slice) Search(x float64) int { return SearchFloat64s(p, x) }

	// Search returns the result of applying [SearchStrings] to the receiver and x.
	func (p StringSlice) Search(x string) int { return SearchStrings(p, x) }