1.冒泡排序
func bubble_sort(li []int) { for i := 0; i < len(li)-1; i++ { exchange := false for j := 0; j < len(li)-i-1; j++ { if li[j] > li[j+1] { li[j], li[j+1] = li[j+1], li[j] exchange = true } } if !exchange { return } } }
2.选择排序
func select_sort(li []int) { for i := 0; i < len(li)-1; i++ { pos := i for j := i + 1; j < len(li); j++ { if li[pos] > li[j] { pos = j } } li[i], li[pos] = li[pos], li[i] } }
3.插入排序
func insert_sort(li []int) { for i := 1; i < len(li); i++ { tmp := li[i] j := i - 1 for j >= 0 && tmp < li[j] { li[j+1] = li[j] j -- } li[j+1] = tmp } }
4.希尔排序
func shell_sort(li []int) { for gap := len(li) / 2; gap > 0; gap /= 2 { for i := gap; i < len(li); i++ { tmp := li[i] j := i - gap for j >= 0 && tmp < li[j] { li[j+gap] = li[j] j -= gap } li[j+gap] = tmp } } }
5.快速排序
func quick_sort(li []int, left, right int) { if left >= right { return } i := left j := right rand.Seed(time.Now().Unix()) r := rand.Intn(right-left) + left li[i], li[r] = li[r], li[i] tmp := li[i] for i < j { for i < j && li[j] >= tmp { j-- } li[i] = li[j] for i < j && li[i] <= tmp { i++ } li[j] = li[i] } li[i] = tmp quick_sort(li, left, i-1) quick_sort(li, i+1, right) }
6.堆排序
func sift(li []int, low, high int) { i := low j := 2*i + 1 tmp:=li[i] for j <= high { if j < high && li[j] < li[j+1] { j++ } if tmp < li[j] { li[i] = li[j] i = j j = 2*i + 1 } else { break } } li[i] = tmp } func heap_sort(li []int) { for i := len(li)/2 - 1; i >= 0; i-- { sift(li, i, len(li)-1) } for j := len(li) - 1; j > 0; j-- { li[0], li[j] = li[j], li[0] sift(li, 0, j-1) } }
7.归并排序
func merge(li []int, left, mid, right int) { i := left j := mid + 1 tmp := []int{} for i <= mid && j <= right { if li[i] <= li[j] { tmp = append(tmp, li[i]) i ++ } else { tmp = append(tmp, li[j]) j ++ } } if i <= mid { tmp = append(tmp, li[i:mid+1]...) } else { tmp = append(tmp, li[j:right+1]...) } for k := 0; k < len(tmp); k++ { li[left+k] = tmp[k] } } func merge_sort(li []int, left, right int) { if left < right { mid := (left + right) / 2 merge_sort(li, left, mid) merge_sort(li, mid+1, right) merge(li, left, mid, right) } }
8.计数排序
func count_sort(li []int) { max_num := li[0] for i := 1; i < len(li); i++ { if max_num < li[i] { max_num = li[i] } } arr := make([]int, max_num+1) for j := 0; j < len(li); j++ { arr[li[j]]++ } k := 0 for m, n := range arr { for p := 0; p < n; p++ { li[k] = m k++ } } }
9.桶排序
func bin_sort(li []int, bin_num int) { min_num, max_num := li[0], li[0] for i := 0; i < len(li); i++ { if min_num > li[i] { min_num = li[i] } if max_num < li[i] { max_num = li[i] } } bin := make([][]int, bin_num) for j := 0; j < len(li); j++ { n := (li[j] - min_num) / ((max_num - min_num + 1) / bin_num) bin[n] = append(bin[n], li[j]) k := len(bin[n]) - 2 for k >= 0 && li[j] < bin[n][k] { bin[n][k+1] = bin[n][k] k-- } bin[n][k+1] = li[j] } o := 0 for p, q := range bin { for t := 0; t < len(q); t++ { li[o] = bin[p][t] o++ } } }
10.基数排序
func radix_sort(li []int) { max_num := li[0] for i := 0; i < len(li); i++ { if max_num < li[i] { max_num = li[i] } } for j := 0; j < len(strconv.Itoa(max_num)); j++ { bin := make([][]int, 10) for k := 0; k < len(li); k++ { n := li[k] / int(math.Pow(10, float64(j))) % 10 bin[n] = append(bin[n], li[k]) } m := 0 for p := 0; p < len(bin); p++ { for q := 0; q < len(bin[p]); q++ { li[m] = bin[p][q] m++ } } } }
11.用堆排解决top_k问题,思路:
a.先取前k个数建小根堆,这样就能保证堆顶元素是整个堆的最小值;
b.然后遍历列表的k到最后,如果值比堆顶大,就和堆顶交换,交换完后再对堆建小根堆,这样就能保证交换完后,堆顶元素仍然是整个堆的最小值;
c.一直遍历到列表的最后一个值,这一步做完之后,就保证了整个列表最大的前k个数已经放进了堆里;
d.按数的大到小出堆;
func sift(li []int, low, high int) { i := low j := 2*i + 1 tmp := li[i] for j <= high { if j < high && li[j] > li[j+1] { j++ } if tmp > li[j] { li[i] = li[j] i = j j = 2*i + 1 } else { break } } li[i] = tmp } func top_k(li []int, k int) []int { for i := k/2 - 1; i >= 0; i-- { sift(li, i, k-1) } for j := k; j < len(li); j++ { if li[0] < li[j] { li[0], li[j] = li[j], li[0] sift(li, 0, k-1) } } for n := k - 1; n > 0; n-- { li[0], li[n] = li[n], li[0] sift(li, 0, n-1) } return li[:k] }