algorithm-reading
leetcode/lintcode题解/算法学习笔记
1. Part I - Basics
2. Data Structure
- 2.1. Linked List
- 2.2. Binary Tree
- 2.3. Binary Search Tree
- 2.4. Huffman Compression
- 2.5. Priority Queue
3. Basics Sorting
- 3.1. Bubble Sort
- 3.2. Selection Sort
- 3.3. Insertion Sort
- 3.4. Merge Sort
- 3.5. Quick Sort
- 3.6. Heap Sort
- 3.7. Bucket Sort
- 3.8. Counting Sort
- 3.9. Radix Sort
4. Basics Misc
- 4.1. Bit Manipulation
5. Part II - Coding
6. String - 字符串
- 6.1. strStr
- 6.2. Two Strings Are Anagrams
- 6.3. Compare Strings
- 6.4. Anagrams
- 6.5. Longest Common Substring
- 6.6. Rotate String
- 6.7. Reverse Words in a String
7. Integer Array - 整型数组
- 7.1. Remove Element
- 7.2. Zero Sum Subarray
- 7.3. Subarray Sum K
- 7.4. Subarray Sum Closest
- 7.5. Product of Array Exclude Itself
- 7.6. Partition Array
- 7.7. First Missing Positive
- 7.8. 2 Sum
- 7.9. 3 Sum
- 7.10. 3 Sum Closest
- 7.11. Remove Duplicates from Sorted Array
- 7.12. Remove Duplicates from Sorted Array II
- 7.13. Merge Sorted Array
- 7.14. Merge Sorted Array II
- 7.15. Median
8. Binary Search - 二分搜索
- 8.1. Binary Search
- 8.2. Search Insert Position
- 8.3. Search for a Range
- 8.4. First Bad Version
- 8.5. Search a 2D Matrix
- 8.6. Find Peak Element
- 8.7. Search in Rotated Sorted Array
- 8.8. Find Minimum in Rotated Sorted Array
- 8.9. Search a 2D Matrix II
- 8.10. Median of two Sorted Arrays
- 8.11. Sqrt x
- 8.12. Wood Cut
9. Math and Bit Manipulation - 数学技巧与位运算
- 9.1. Single Number
- 9.2. Single Number II
- 9.3. Single Number III
- 9.4. O1 Check Power of 2
- 9.5. Convert Integer A to Integer B
- 9.6. Factorial Trailing Zeroes
- 9.7. Unique Binary Search Trees
- 9.8. Update Bits
- 9.9. Fast Power
10. Linked List - 链表
- 10.1. Remove Duplicates from Sorted List
- 10.2. Remove Duplicates from Sorted List II
- 10.3. Remove Duplicates from Unsorted List
- 10.4. Partition List
- 10.5. Two Lists Sum
- 10.6. Two Lists Sum Advanced
- 10.7. Remove Nth Node From End of List
- 10.8. Linked List Cycle
- 10.9. Linked List Cycle II
- 10.10. Reverse Linked List
- 10.11. Reverse Linked List II
- 10.12. Merge Two Sorted Lists
- 10.13. Merge k Sorted Lists
- 10.14. Reorder List
- 10.15. Copy List with Random Pointer
- 10.16. Sort List
- 10.17. Insertion Sort List
- 10.18. Check if a singly linked list is palindrome
11. Reverse - 翻转法
- 11.1. Recover Rotated Sorted Array
12. Binary Tree - 二叉树
- 12.1. Binary Tree Preorder Traversal
- 12.2. Binary Tree Inorder Traversal
- 12.3. Binary Tree Postorder Traversal
- 12.4. Binary Tree Level Order Traversal
- 12.5. Maximum Depth of Binary Tree
- 12.6. Balanced Binary Tree
- 12.7. Binary Tree Maximum Path Sum
- 12.8. Lowest Common Ancestor
13. Binary Search Tree - 二叉搜索树
- 13.1. Insert Node in a Binary Search Tree
- 13.2. Validate Binary Search Tree
- 13.3. Search Range in Binary Search Tree
- 13.4. Convert Sorted Array to Binary Search Tree
- 13.5. Convert Sorted List to Binary Search Tree
- 13.6. Binary Search Tree Iterator
14. Exhaustive Search - 穷竭搜索
- 14.1. Subsets
- 14.2. Unique Subsets
- 14.3. Permutation
- 14.4. Unique Permutations
- 14.5. Unique Binary Search Trees II
15. Dynamic Programming - 动态规划
- 15.1. Triangle
- 15.2. Knapsack - 背包问题
  - 15.2.1. Backpack
- 15.3. Matrix
  - 15.3.1. Minimum Path Sum
  - 15.3.2. Unique Paths
- 15.4. Sequence
  - 15.4.1. Climbing Stairs
  - 15.4.2. Jump Game
- 15.5. Word Break
- 15.6. Longest Increasing Subsequence
- 15.7. Palindrome Partitioning II
- 15.8. Longest Common Subsequence
- 15.9. Edit Distance
16. Appendix I Interview and Resume
- 16.1. Interview
- 16.2. Resume

algorithm-reading

Convert Integer A to Integer B

Source

CC150, lintcode: (181) Convert Integer A to Integer B

Determine the number of bits required to convert integer A to integer B

Example
Given n = 31, m = 14,return 2

(31)10=(11111)2

(14)10=(01110)2

题解

比较两个数不同的比特位个数，显然容易想到可以使用异或处理两个整数，相同的位上为0，不同的位上为1，故接下来只需将异或后1的个数求出即可。容易想到的方法是移位后和1按位与得到最低位的结果，使用计数器记录这一结果，直至最后操作数为0时返回最终值。这种方法需要遍历元素的每一位，有咩有更为高效的做法呢？还记得之前做过的 O1 Check Power of 2 吗？x & (x - 1)既然可以检查2的整数次幂，那么如何才能进一步得到所有1的个数呢？——将异或得到的数分拆为若干个2的整数次幂，计算得到有多少个2的整数次幂即可。

以上的分析过程对于正数来说是毫无问题的，但问题就在于如果出现了负数如何破？不确定的时候就来个实例测测看，以-2为例，(-2) & (-2 - 1)的计算如下所示(简单起见这里以8位为准)：

 11111110 <==> -2   -2 <==> 11111110
+                          &
 11111111 <==> -1   -3 <==> 11111101
=                          =
 11111101                   11111100

细心的你也许发现了对于负数来说，其表现也是我们需要的——x & (x - 1)的含义即为将二进制比特位的值为1的最低位置零。逐步迭代直至最终值为0时返回。

C/C++ 和 Java 中左溢出时会直接将高位丢弃，正好方便了我们的计算，但是在 Python 中就没这么幸运了，因为溢出时会自动转换类型，Orz... 所以使用 Python 时需要对负数专门处理，转换为求其补数中0的个数。

Python

class Solution:
    """
    @param a, b: Two integer
    return: An integer
    """
    def bitSwapRequired(self, a, b):
        count = 0
        a_xor_b = a ^ b
        neg_flag = False
        if a_xor_b < 0:
            a_xor_b = abs(a_xor_b) - 1
            neg_flag = True
        while a_xor_b > 0:
            count += 1
            a_xor_b &= (a_xor_b - 1)

        # bit_wise = 32
        if neg_flag:
            count = 32 - count
        return count

C++

class Solution {
public:
    /**
     *@param a, b: Two integer
     *return: An integer
     */
    int bitSwapRequired(int a, int b) {
        int count = 0;
        int a_xor_b = a ^ b;
        while (a_xor_b != 0) {
            ++count;
            a_xor_b &= (a_xor_b - 1);
        }

        return count;
    }
};

Java

class Solution {
    /**
     *@param a, b: Two integer
     *return: An integer
     */
    public static int bitSwapRequired(int a, int b) {
        int count = 0;
        int a_xor_b = a ^ b;
        while (a_xor_b != 0) {
            ++count;
            a_xor_b &= (a_xor_b - 1);
        }

        return count;
    }
};

源码分析

Python 中 int 溢出时会自动变为 long 类型，故处理负数时需要求补数中0的个数，间接求得原异或得到的数中1的个数。

考虑到负数的可能，C/C++, Java 中循环终止条件为a_xor_b != 0，而不是a_xor_b > 0.

复杂度分析

取决于异或后数中1的个数，O(max(ones in a ^ b)).

关于 Python 中位运算的一些坑总结在参考链接中。