Files
gf/g/container/garray/garray_normal_string.go

395 lines
9.8 KiB
Go

// Copyright 2018 gf Author(https://gitee.com/johng/gf). All Rights Reserved.
//
// This Source Code Form is subject to the terms of the MIT License.
// If a copy of the MIT was not distributed with this file,
// You can obtain one at https://gitee.com/johng/gf.
package garray
import (
"gitee.com/johng/gf/g/internal/rwmutex"
"gitee.com/johng/gf/g/util/grand"
"math"
"sort"
"strings"
)
type StringArray struct {
mu *rwmutex.RWMutex // 互斥锁
cap int // 初始化设置的数组容量
size int // 初始化设置的数组大小
array []string // 底层数组
}
func NewStringArray(size int, cap int, unsafe...bool) *StringArray {
a := &StringArray{
mu : rwmutex.New(unsafe...),
}
a.size = size
if cap > 0 {
a.cap = cap
a.array = make([]string, size, cap)
} else {
a.array = make([]string, size)
}
return a
}
func NewStringArrayFrom(array []string, unsafe...bool) *StringArray {
return &StringArray {
mu : rwmutex.New(unsafe...),
array : array,
}
}
// 获取指定索引的数据项, 调用方注意判断数组边界
func (a *StringArray) Get(index int) string {
a.mu.RLock()
defer a.mu.RUnlock()
value := a.array[index]
return value
}
// 设置指定索引的数据项, 调用方注意判断数组边界
func (a *StringArray) Set(index int, value string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
a.array[index] = value
return a
}
// 设置底层数组变量.
func (a *StringArray) SetArray(array []string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
a.array = array
return a
}
// 将数组重新排序(从小到大).
func (a *StringArray) Sort() *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
sort.Strings(a.array)
return a
}
// 在当前索引位置前插入一个数据项, 调用方注意判断数组边界
func (a *StringArray) InsertBefore(index int, value string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
rear := append([]string{}, a.array[index : ]...)
a.array = append(a.array[0 : index], value)
a.array = append(a.array, rear...)
return a
}
// 在当前索引位置后插入一个数据项, 调用方注意判断数组边界
func (a *StringArray) InsertAfter(index int, value string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
rear := append([]string{}, a.array[index + 1:]...)
a.array = append(a.array[ 0: index + 1], value)
a.array = append(a.array, rear...)
return a
}
// 删除指定索引的数据项, 调用方注意判断数组边界
func (a *StringArray) Remove(index int) string {
a.mu.Lock()
defer a.mu.Unlock()
// 边界删除判断,以提高删除效率
if index == 0 {
value := a.array[0]
a.array = a.array[1 : ]
return value
} else if index == len(a.array) - 1 {
value := a.array[index]
a.array = a.array[: index]
return value
}
// 如果非边界删除,会涉及到数组创建,那么删除的效率差一些
value := a.array[index]
a.array = append(a.array[ : index], a.array[index + 1 : ]...)
return value
}
// 将数据项添加到数组的最左端(索引为0)
func (a *StringArray) PushLeft(value...string) *StringArray {
a.mu.Lock()
a.array = append(value, a.array...)
a.mu.Unlock()
return a
}
// 将数据项添加到数组的最右端(索引为length - 1), 等于: Append
func (a *StringArray) PushRight(value...string) *StringArray {
a.mu.Lock()
a.array = append(a.array, value...)
a.mu.Unlock()
return a
}
// 将最左端(索引为0)的数据项移出数组,并返回该数据项
func (a *StringArray) PopLeft() string {
a.mu.Lock()
defer a.mu.Unlock()
value := a.array[0]
a.array = a.array[1 : ]
return value
}
// 将最右端(索引为length - 1)的数据项移出数组,并返回该数据项
func (a *StringArray) PopRight() string {
a.mu.Lock()
defer a.mu.Unlock()
index := len(a.array) - 1
value := a.array[index]
a.array = a.array[: index]
return value
}
// 随机将一个数据项移出数组,并返回该数据项
func (a *StringArray) PopRand() string {
return a.Remove(grand.Intn(len(a.array)))
}
// 追加数据项
func (a *StringArray) Append(value...string) *StringArray {
a.mu.Lock()
a.array = append(a.array, value...)
a.mu.Unlock()
return a
}
// 数组长度
func (a *StringArray) Len() int {
a.mu.RLock()
length := len(a.array)
a.mu.RUnlock()
return length
}
// 返回原始数据数组
func (a *StringArray) Slice() []string {
array := ([]string)(nil)
if a.mu.IsSafe() {
a.mu.RLock()
defer a.mu.RUnlock()
array = make([]string, len(a.array))
copy(array, a.array)
} else {
array = a.array
}
return array
}
// 清空数据数组
func (a *StringArray) Clear() *StringArray {
a.mu.Lock()
if len(a.array) > 0 {
if a.cap > 0 {
a.array = make([]string, a.size, a.cap)
} else {
a.array = make([]string, a.size)
}
}
a.mu.Unlock()
return a
}
// 查找指定数值是否存在
func (a *StringArray) Contains(value string) bool {
return a.Search(value) != -1
}
// 查找指定数值的索引位置,返回索引位置,如果查找不到则返回-1
func (a *StringArray) Search(value string) int {
if len(a.array) == 0 {
return -1
}
a.mu.RLock()
result := -1
for index, v := range a.array {
if strings.Compare(v, value) == 0 {
result = index
break
}
}
a.mu.RUnlock()
return result
}
// 清理数组中重复的元素项
func (a *StringArray) Unique() *StringArray {
a.mu.Lock()
for i := 0; i < len(a.array) - 1; i++ {
for j := i + 1; j < len(a.array); j++ {
if a.array[i] == a.array[j] {
a.array = append(a.array[ : j], a.array[j + 1 : ]...)
}
}
}
a.mu.Unlock()
return a
}
// 使用自定义方法执行加锁修改操作
func (a *StringArray) LockFunc(f func(array []string)) *StringArray {
a.mu.Lock(true)
defer a.mu.Unlock(true)
f(a.array)
return a
}
// 使用自定义方法执行加锁读取操作
func (a *StringArray) RLockFunc(f func(array []string)) *StringArray {
a.mu.RLock(true)
defer a.mu.RUnlock(true)
f(a.array)
return a
}
// 合并两个数组.
func (a *StringArray) Merge(array *StringArray) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
if a != array {
array.mu.RLock()
defer array.mu.RUnlock()
}
a.array = append(a.array, array.array...)
return a
}
// Fills an array with num entries of the value of the value parameter, keys starting at the start_index parameter.
func (a *StringArray) Fill(startIndex int, num int, value string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
if startIndex < 0 {
startIndex = 0
}
for i := startIndex; i < startIndex + num; i++ {
if i > len(a.array) - 1 {
a.array = append(a.array, value)
} else {
a.array[i] = value
}
}
return a
}
// Chunks an array into arrays with size elements. The last chunk may contain less than size elements.
func (a *StringArray) Chunk(size int) [][]string {
if size < 1 {
panic("size: cannot be less than 1")
}
a.mu.RLock()
defer a.mu.RUnlock()
length := len(a.array)
chunks := int(math.Ceil(float64(length) / float64(size)))
var n [][]string
for i, end := 0, 0; chunks > 0; chunks-- {
end = (i + 1) * size
if end > length {
end = length
}
n = append(n, a.array[i*size : end])
i++
}
return n
}
// Pad array to the specified length with a value.
// If size is positive then the array is padded on the right,
// if it's negative then on the left.
// If the absolute value of size is less than or equal to the length of the array
// then no padding takes place.
func (a *StringArray) Pad(size int, value string) *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
if size == 0 || (size > 0 && size < len(a.array)) || (size < 0 && size > -len(a.array)) {
return a
}
n := size
if size < 0 {
n = -size
}
n -= len(a.array)
tmp := make([]string, n)
for i := 0; i < n; i++ {
tmp[i] = value
}
if size > 0 {
a.array = append(a.array, tmp...)
} else {
a.array = append(tmp, a.array...)
}
return a
}
// Extract a slice of the array(If in concurrent safe usage, it returns a copy of the slice; else a pointer).
// It returns the sequence of elements from the array array as specified by the offset and length parameters.
func (a *StringArray) SubSlice(offset, size int) []string {
a.mu.RLock()
defer a.mu.RUnlock()
if offset > len(a.array) {
return nil
}
if offset + size > len(a.array) {
size = len(a.array) - offset
}
if a.mu.IsSafe() {
s := make([]string, size)
copy(s, a.array[offset:])
return s
} else {
return a.array[offset:]
}
}
// Picks one or more random entries out of an array(a copy), and returns the key (or keys) of the random entries.
func (a *StringArray) Rand(size int) []string {
a.mu.RLock()
defer a.mu.RUnlock()
if size > len(a.array) {
size = len(a.array)
}
n := make([]string, size)
for i, v := range grand.Perm(len(a.array)) {
n[i] = a.array[v]
if i == size - 1 {
break
}
}
return n
}
// Randomly shuffles the array.
func (a *StringArray) Shuffle() *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
for i, v := range grand.Perm(len(a.array)) {
a.array[i], a.array[v] = a.array[v], a.array[i]
}
return a
}
// Make array with elements in reverse order.
func (a *StringArray) Reverse() *StringArray {
a.mu.Lock()
defer a.mu.Unlock()
for i, j := 0, len(a.array) - 1; i < j; i, j = i + 1, j - 1 {
a.array[i], a.array[j] = a.array[j], a.array[i]
}
return a
}
// Join array elements with a string.
func (a *StringArray) Join(glue string) string {
a.mu.RLock()
defer a.mu.RUnlock()
return strings.Join(a.array, glue)
}