LintCode 83. Single Number II (Medium)

LeetCode 137. Single Number II (Medium)

以下算法的复杂度都是:

时间复杂度: O(n)

空间复杂度: O(1)

解法1. 32个计数器

最简单的思路是用32个计数器, 满3复位0.

class Solution {

public:

    int singleNumberII(vector<int> &A) {

        int cnt[32] = {0};

        int res = 0;

        for (int i = 0; i < 32; ++i) {

            for (int n : A) {

                cnt[i] += (n >> i) & 1;

                cnt[i] %= 3;

            }

            res |= cnt[i] << i;

        }

        return res;

    }

};

解法2. 找规律

我的思路是, 解法1中的计数其实只需要两个bit就够了. 所有的首个bit记做res, 所有的第二个bit记做carry, 找规律:

如果A[i]的第k位是0, 则res和carry的第k位保持原样.

如果A[i]的第k位是1, 则:

res	carry	res'	carry'
0	0	1	0
1	0	0	1
0	1	0	0

此时(A[i][k]=1时)的规律就是:

res'[k]=~res[k] & ~carry[k]

carry'[k]=res[k] & ~carry[k]

class Solution {

public:

    int singleNumberII(vector<int> &A) {

        int res = 0, carry = 0;

        for (int n : A) {

            for (int i = 0; i < 32; ++i) {

                int mask = (1 << i);

                int bit = n & mask;

                if (bit) {

                    int newRes = (~mask & res) + ((~res & mask) & (~carry & mask));

                    carry = (~mask & carry) + ((res & mask) & (~carry & mask));

                    res = newRes;

                }

            }

        }

        return res;

    }

};

解法2.1. 解法2的简化

解法2中, 将A[i][k]=0和=1的情况合并, 可以得到:

res'[k]=(A[i][k] & ~res[k] & ~carry[k]) | (~A[i][k] & res[k])

carry'[k]=(A[i][k] & res[k] & ~carry[k]) | (~A[i][k] & carry[k])

这样的好处是可以32位一起算, 而不用一位一位地算:

res'=(A[i] & ~res & ~carry) | (~A[i][k] & res)

carry'=(A[i] & res & ~carry) | (~A[i][k] & carry)

class Solution {

public:

    int singleNumberII(vector<int> &A) {

        int res = 0, carry = 0;

        for (int n : A) {

            int newRes = (n & (~res & ~carry)) | (~n & res);

            carry = (n & (res & ~carry)) | (~n & carry);

            res = newRes;

        }

        return res;

    }

};

解法3. one, two, three

Discuss中看到的解法, 自己实在想不出来. 用one, two和three三个int值作为bit flags.

循环对A[0]到A[n]进行考察, 当考察A[i]时:

记S[i]={A[0],...,A[i]},

若S[i]中所有数字的第k位bit的数目%3==1, 则one的第k位为1, 否则为0.

若S[i]中所有数字的第k位bit的数目%3==2, 则two的第k位为1, 否则为0.

而three是一个临时变量, 用于记录这一轮中, 哪些bit的数目恰巧是3的倍数.

two |= one & n;: 给two加上那些从1到2的数字.

one ^= n;: 这句比较巧妙, 既删掉了会变成2的那些1, 又加上了新的1.

three = one & two;: 1+2=3...

one&= ~three: 从1中刨去那些成为3的1.

two&= ~three: 从2中跑去那些成为3的2.

...如果你能解释得更清晰易懂, 欢迎留言!

class Solution {

public:

    int singleNumberII(vector<int> &A) {

        int one = 0, two = 0, three = 0;

        for (int n : A) {

            two |= one & n;

            one ^= n;

            three = one & two;

            one &= ~three;

            two &= ~three;

        }

        return one;

    }

};

解法3.1. 解法3的变形

自己没想出解法4, 但是参照它的思路, 写了一个对自己比较直观的算法.

three = two & n;: 算出从2变成3的那些2.

two = (two & ~three) | (one & n);: (two & ~three)是从2中刨去那些变为3的2, (one & n)是加上那些从1变成2的1.

one = (one & ~n) | (n & ~three & ~two);: (one & ~n)是从1中刨去那些变成2的1, (n & ~three & ~two)是加上那些没给"2变3"或"1变2"用过的1.

class Solution {

public:

    int singleNumberII(vector<int> &A) {

        int one = 0, two = 0;

        for (int n : A) {

            int three = two & n;

            two = (two & ~three) | (one & n);

            one = (one & ~n) | (n & ~three & ~two);

        }

        return one;

    }

};