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Question
- leetcode: Permutations | LeetCode OJ
- lintcode: (15) Permutations
Problem Statement
Given a list of numbers, return all possible permutations.
Example
For nums = [1,2,3], the permutations are:
[[1,2,3],[1,3,2],[2,1,3],[2,3,1],[3,1,2],[3,2,1]]
Challenge
Do it without recursion.
题解1 - Recursion(using subsets template)
排列常见的有数字全排列,字符串排列等。
使用之前 Subsets 的模板,但是在取结果时只能取list.size() == nums.size()的解,且在添加list元素的时候需要注意除重以满足全排列的要求。此题假设前提为输入数据中无重复元素。
Python
class Solution:"""@param nums: A list of Integers.@return: A list of permutations."""def permute(self, nums):alist = []result = [];if not nums:return resultself.helper(nums, alist, result)return resultdef helper(self, nums, alist, ret):if len(alist) == len(nums):# new objectret.append([] + alist)returnfor i, item in enumerate(nums):if item not in alist:alist.append(item)self.helper(nums, alist, ret)alist.pop()
C++
class Solution {public:/*** @param nums: A list of integers.* @return: A list of permutations.*/vector<vector<int> > permute(vector<int> nums) {vector<vector<int> > result;if (nums.empty()) {return result;}vector<int> list;backTrack(result, list, nums);return result;}private:void backTrack(vector<vector<int> > &result, vector<int> &list, \vector<int> &nums) {if (list.size() == nums.size()) {result.push_back(list);return;}for (int i = 0; i != nums.size(); ++i) {// remove the element belongs to listif (find(list.begin(), list.end(), nums[i]) != list.end()) {continue;}list.push_back(nums[i]);backTrack(result, list, nums);list.pop_back();}}};
Java
public class Solution {public List<List<Integer>> permute(int[] nums) {List<List<Integer>> result = new ArrayList<List<Integer>>();if (nums == null || nums.length == 0) return result;List<Integer> list = new ArrayList<Integer>();dfs(nums, list, result);return result;}private void dfs(int[] nums, List<Integer> list, List<List<Integer>> result) {if (list.size() == nums.length) {result.add(new ArrayList<Integer>(list));return;}for (int i = 0; i < nums.length; i++) {if (list.contains(nums[i])) continue;list.add(nums[i]);dfs(nums, list, result);list.remove(list.size() - 1);}}}
源码分析
在除重时使用了标准库find(不可使用时间复杂度更低的binary_search,因为list中元素不一定有序),时间复杂度为 O(N), 也可使用hashmap记录nums中每个元素是否被添加到list中,这样一来空间复杂度为 O(N), 查找的时间复杂度为 O(1).
在list.size() == nums.size()时,已经找到需要的解,及时return避免后面不必要的for循环调用开销。
使用回溯法解题的关键在于如何确定正确解及排除不符条件的解(剪枝)。
复杂度分析
以状态数来分析,最终全排列个数应为 n!, 每个节点被遍历的次数为 (n-1)!, 故节点共被遍历的状态数为 O(n!), 此为时间复杂度的下界,因为这里只算了合法条件下的遍历状态数。若不对 list 中是否包含 nums[i] 进行检查,则总的状态数应为 n^n 种。
由于最终的排列结果中每个列表的长度都为 n, 各列表的相同元素并不共享,故时间复杂度的下界为 O(n \cdot n!), 上界为 n \cdot n^n. 实测helper中 for 循环的遍历次数在 O(2n \cdot n!) 以下,注意这里的时间复杂度并不考虑查找列表里是否包含重复元素。
题解2 - Recursion
与题解1基于 subsets 的模板不同,这里我们直接从全排列的数学定义本身出发,要求给定数组的全排列,可将其模拟为某个袋子里有编号为1到 n 的球,将其放入 n 个不同的盒子怎么放?基本思路就是从袋子里逐个拿球放入盒子,直到袋子里的球拿完为止,拿完时即为一种放法。
Python
class Solution:# @param {integer[]} nums# @return {integer[][]}def permute(self, nums):if nums is None:return [[]]elif len(nums) <= 1:return [nums]result = []for i, item in enumerate(nums):for p in self.permute(nums[:i] + nums[i + 1:]):result.append(p + [item])return resultclass Solution2:# 类似 subset的模版def permute(self, nums):if not nums:return []res = []self.helper(sorted(nums), res, [])return resdef helper(self, nums, res, tmp):if not nums:res.append(tmp[:])returnfor i, num in enumerate(nums, 1):self.helper(nums[:i] + nums[i + 1:], res, tmp + [num])
C++
class Solution {public:/*** @param nums: A list of integers.* @return: A list of permutations.*/vector<vector<int> > permute(vector<int>& nums) {vector<vector<int> > result;if (nums.size() == 1) {result.push_back(nums);return result;}for (int i = 0; i < nums.size(); ++i) {vector<int> nums_new = nums;nums_new.erase(nums_new.begin() + i);vector<vector<int> > res_tmp = permute(nums_new);for (int j = 0; j < res_tmp.size(); ++j) {vector<int> temp = res_tmp[j];temp.push_back(nums[i]);result.push_back(temp);}}return result;}};
Java
public class Solution {public List<List<Integer>> permute(int[] nums) {List<List<Integer>> result = new ArrayList<List<Integer>>();List<Integer> numsList = new ArrayList<Integer>();if (nums == null) {return result;} else {// convert int[] to List<Integer>for (int item : nums) numsList.add(item);}if (nums.length <= 1) {result.add(numsList);return result;}for (int i = 0; i < nums.length; i++) {int[] numsNew = new int[nums.length - 1];System.arraycopy(nums, 0, numsNew, 0, i);System.arraycopy(nums, i + 1, numsNew, i, nums.length - i - 1);List<List<Integer>> resTemp = permute(numsNew);for (List<Integer> temp : resTemp) {temp.add(nums[i]);result.add(temp);}}return result;}}
源码分析
Python 中使用len()时需要防止None, 递归终止条件为数组中仅剩一个元素或者为空,否则遍历nums数组,取出第i个元素并将其加入至最终结果。nums[:i] + nums[i + 1:]即为去掉第i个元素后的新列表。
Java 中 ArrayList 和 List 的类型转换需要特别注意。
复杂度分析
由于取的结果都是最终结果,无需去重判断,故时间复杂度为 O(n!), 但是由于nums[:i] + nums[i + 1:]会产生新的列表,实际运行会比第一种方法慢不少。
题解3 - Iteration
递归版的程序比较简单,咱们来个迭代的实现。非递归版的实现也有好几种,这里基于 C++ STL 中next_permutation的字典序实现方法。参考 Wikipedia 上的字典序算法,大致步骤如下:
- 从后往前寻找索引满足
a[k] < a[k + 1], 如果此条件不满足,则说明已遍历到最后一个。 - 从后往前遍历,找到第一个比
a[k]大的数a[l], 即a[k] < a[l]. - 交换
a[k]与a[l]. - 反转
k + 1 ~ n之间的元素。
Python
class Solution:# @param {integer[]} nums# @return {integer[][]}def permute(self, nums):if nums is None:return [[]]elif len(nums) <= 1:return [nums]# sort nums firstnums.sort()result = []while True:result.append([] + nums)# step1: find nums[i] < nums[i + 1], Loop backwardsi = 0for i in xrange(len(nums) - 2, -1, -1):if nums[i] < nums[i + 1]:breakelif i == 0:return result# step2: find nums[i] < nums[j], Loop backwardsj = 0for j in xrange(len(nums) - 1, i, -1):if nums[i] < nums[j]:break# step3: swap betwenn nums[i] and nums[j]nums[i], nums[j] = nums[j], nums[i]# step4: reverse between [i + 1, n - 1]nums[i + 1:len(nums)] = nums[len(nums) - 1:i:-1]return result
C++
class Solution {public:/*** @param nums: A list of integers.* @return: A list of permutations.*/vector<vector<int> > permute(vector<int>& nums) {vector<vector<int> > result;if (nums.empty() || nums.size() <= 1) {result.push_back(nums);return result;}// sort nums firstsort(nums.begin(), nums.end());for (;;) {result.push_back(nums);// step1: find nums[i] < nums[i + 1]int i = 0;for (i = nums.size() - 2; i >= 0; --i) {if (nums[i] < nums[i + 1]) {break;} else if (0 == i) {return result;}}// step2: find nums[i] < nums[j]int j = 0;for (j = nums.size() - 1; j > i; --j) {if (nums[i] < nums[j]) break;}// step3: swap betwenn nums[i] and nums[j]int temp = nums[j];nums[j] = nums[i];nums[i] = temp;// step4: reverse between [i + 1, n - 1]reverse(nums, i + 1, nums.size() - 1);}return result;}private:void reverse(vector<int>& nums, int start, int end) {for (int i = start, j = end; i < j; ++i, --j) {int temp = nums[i];nums[i] = nums[j];nums[j] = temp;}}};
Java - Array
class Solution {/*** @param nums: A list of integers.* @return: A list of permutations.*/public List<List<Integer>> permute(int[] nums) {List<List<Integer>> result = new ArrayList<List<Integer>>();if (nums == null || nums.length == 0) return result;// deep copy(do not change nums)int[] perm = Arrays.copyOf(nums, nums.length);// sort first!!!Arrays.sort(perm);while (true) {// step0: add perm into resultList<Integer> tempList = new ArrayList<Integer>();for (int i : perm) tempList.add(i);result.add(tempList);// step1: search the first perm[k] < perm[k+1] backwardint k = -1;for (int i = perm.length - 2; i >= 0; i--) {if (perm[i] < perm[i + 1]) {k = i;break;}}// if current rank is the largest, exit while loopif (k == -1) break;// step2: search the first perm[k] < perm[l] backwardint l = perm.length - 1;while (l > k && perm[l] <= perm[k]) l--;// step3: swap perm[k] with perm[l]int temp = perm[k];perm[k] = perm[l];perm[l] = temp;// step4: reverse between k+1 and perm.length-1;reverse(perm, k + 1, perm.length - 1);}return result;}private void reverse(int[] nums, int lb, int ub) {for (int i = lb, j = ub; i < j; i++, j--) {int temp = nums[i];nums[i] = nums[j];nums[j] = temp;}}}
Java - List
class Solution {/*** @param nums: A list of integers.* @return: A list of permutations.*/public ArrayList<ArrayList<Integer>> permute(ArrayList<Integer> nums) {ArrayList<ArrayList<Integer>> result = new ArrayList<ArrayList<Integer>>();if (nums == null || nums.size() == 0) return result;// deep copy(do not change nums)List<Integer> perm = new ArrayList<Integer>(nums);// sort first!!!Collections.sort(perm);while (true) {// step0: add perm into resultresult.add(new ArrayList<Integer>(perm));// step1: search the first num[k] < num[k+1] backwardint k = -1;for (int i = perm.size() - 2; i >= 0; i--) {if (perm.get(i) < perm.get(i + 1)) {k = i;break;}}// if current rank is the largest, exit while loopif (k == -1) break;// step2: search the first perm[k] < perm[l] backwardint l = perm.size() - 1;while (l > k && perm.get(l) <= perm.get(k)) l--;// step3: swap perm[k] with perm[l]Collections.swap(perm, k, l);// step4: reverse between k+1 and perm.size()-1;reverse(perm, k + 1, perm.size() - 1);}return result;}private void reverse(List<Integer> nums, int lb, int ub) {for (int i = lb, j = ub; i < j; i++, j--) {Collections.swap(nums, i, j);}}}
源码分析
注意好字典序算法的步骤即可,对于 Java 来说其实可以首先将数组转化为 List, 相应的方法多一些。吐槽下 Lintcode 上的接口设计,总是见到一长串的ArrayList, 个人觉得采用 Leetcode 上的List更灵活(代码更短,哈哈),不知道 Lintcode 那样的接口设计有什么其他考虑吗?
复杂度分析
除了将 n! 个元素添加至最终结果外,首先对元素排序,时间复杂度近似为 O(n \log n), 反转操作近似为 O(n), 故总的时间复杂度为 O(n!). 除了保存结果的result外,其他空间可忽略不计,所以此题用生成器来实现较为高效,扩展题可见底下的 Python itertools 中的实现,从 n 个元素中选出 m 个进行全排列。
Reference
- Permutation Generation - Robert Sedgewick 的大作,总结了诸多 Permutation 的产生方法。
- Next lexicographical permutation algorithm - 此题非递归方法更为详细的解释。
- Permutation - Wikipedia, the free encyclopedia - 字典序实现。
- Programming Interview Questions 11: All Permutations of String | Arden DertatArden Dertat
- algorithm - complexity of recursive string permutation function - Stack Overflow
- [leetcode]Permutations @ Python - 南郭子綦 - 博客园
- [leetcode] permutations的讨论 - tuantuanls的专栏 - 博客频道 - CSDN.NET
- 非递归排列算法(Permutation Generation)
- 闲谈permutations | HelloYou
- 9.7. itertools — Functions creating iterators for efficient looping — Python 2.7.10 documentation
