FDS复习
树
二叉树
Complete: a binary tree that is completely filled, with the possible exception of the bottom level, which is filled from left to right. It is easy to show that a complete binary tree of height h has between 2h and 2h+1 - 1 nodes. This implies that the height of a complete binary tree is log n , which is clearly O(log n)
Firstchild-nextsibling
- 表示方法不唯一
树的计算
\(n=\sum_x \deg(x)+1\)
There exists a binary tree with 2016 nodes in total, and with 16 nodes having only one child.
设叶子节点有\(x\)个,则有\((2000-x)\)个度为2的节点
\(2(2000-x)+16+1=2016\)
\(2x=2017\), \(x\)不是正整数,所以无解
Given a tree of degree 3. Suppose that there are 3 nodes of degree 2 and 2 nodes of degree 3. Then the number of leaf nodes must be ____.
\(3\cdot 2+2\cdot 3+1\cdot y+1=x+y+5\),得\(x=8\)
Threaded binary trees
一个二叉树,2n个指向孩子的指针,只有n-1个非空。利用
- 如果x的左指针为空,就指向中序遍历中x的前一个元素
- 如果x的右指针为空,就指向中序遍历中x的下一个元素
- dummy head node。
Binary Search Tree
左子树的值<根节点<右子树
中序遍历得到顺序
堆
If a d-heap is stored as an array, for an entry located in position i, the parent, the first child and the last child are at:
\([(i+d-2)/d],(i-1)d+2,id+1\)
第j个孩子是\((i-1)d+2+j\)
二叉树,父节点是[i/2]
基本操作
如果是最小堆,就取两个儿子中最小的。如果是最大堆,就和两个儿子中最大的比较。
void percolateDown(int* h,int x,int n){
int maxchild=x;//最大堆
if(x*2<=n&&h[x*2]>h[maxchild]) maxchild=x*2;
if(x*2+1<=n&&h[x*2+1]>h[maxchild]) maxchild=x*2+1;
if(maxchild!=x){
swap(&h[x],&h[maxchild]);
percolateDown(h,maxchild,n);
}
}
线性建堆
从n/2到1 percolate down
Among the following binary trees, which one can possibly be the decision tree (the external nodes are excluded) for binary search?
图论
图的遍历
After the first run of Insertion Sort, it is possible that no element is placed in its final position.
如果是逆序,只有3个元素,则可以。T
3.Apply DFS to a directed acyclic graph, and output the vertex before the end of each recursion. The output sequence will be: A.unsorted
B.topologically sorted
C.reversely topologically sorted
D.None of the above
递归的顺序是遍历1->遍历2->遍历3->.....->遍历n->返回n->返回n-1...->返回3->返回2->返回1
返回的时候打印,因此是从最后一个结点开始打印到源点。是逆拓扑序。
Use simple insertion sort to sort 10 numbers from non-decreasing to non-increasing, the possible numbers of comparisons and movements are: A.100, 100
B.100, 54
C.54, 63
D.45, 44
看似好像很复杂:10个元素逆序的话:有C(10,2)=45的逆序对,因此交换的数目不会大于45 D
割点
articulation point: 去掉后增加连通分量的个数。 在边缘的单个点不算
最小生成树
Prim
Kruskal
时间复杂度: 排序\(O(E\log E)\), 并查集部分可以优化到\(O(E\alpha(n))\),但最终还是\(O(E\log E)\)
排序
插入排序
void insertionSort(int arr[], int n) {
for (int P = 1; P < n; ++P) {
int tmp = arr[P];
int i;
for (i = P; i > 0 && arr[i - 1] > tmp; --i)
arr[i] = arr[i - 1];
arr[i] = tmp;
}
}
逆序对有\(R(n)\)个 那么插入排序时间复杂度为\(O(R(n))\)
插入不一定每次都有1个元素到原来的位置
希尔排序
\(h_k-sort\) 每\(h_k\)取一个元素,进行插入排序
1-sort就是插入排序
\(h_k=h_{k+1}/2, h_t={n/2}\) 最坏\(O(n^2)\)
void shellSort(int arr[], int n) {
int i, j, tmp;
for (int inc = N/2; inc > 0; inc /= 2) {
//默认的increment sequence
for (i = inc; i < N; ++i) {
//插入排序,注意从第二个元素(inc)开始,第一个元素是0
tmp = arr[i];
for (j = i; j >= inc; j -= inc) {
if (tmp < arr[j - inc])
arr[j] = arr[j - inc];
else break;
}
a[j] = tmp;
}
}
}
Hibbard sequence:\(h_k=2^k-1\) 最坏\(O(n^{3/2})\) 平均\(O(n^{5/4})\)
Sedgewick's
堆排序
线性建堆法: 从最后一个非叶子节点(n/2)开始percolate down
-
朴素的实现,时间\(O(n\log n)\), 辅助空间\(O(n)\)
-
对空间优化到\(O(1)\)
建最大堆,将堆顶元素和最后一个元素交换(相当于删除最大元素,只不过把删除的元素放在了删除后留下的空间),并percolate down. 删除N-1次即可.
void percolateDown(int* h,int x,int heapSize){
int lson=x*2,rson=x*2+1;//heapSize随着删除会变
int maxchild=x;//最大堆
if(lson<=heapSize&&h[lson]>h[maxchild]) maxchild=lson;
if(rson<=heapSize&&h[rson]>h[maxchild]) maxchild=rson;
if(maxchild!=x){
swap(&h[x],&h[maxchild]);
percolateDown(h,maxchild,heapSize);
}
}
void heapSort(int *a,int n,int stopPos){//数组从1开始
for(int i=n/2;i>=1;i--){ //n/2
percolateDown(a,i,n);//线性建
}
for(int i=n;i>=2;i--){
swap(&a[1],&a[i]);//最大值换到最
percolateDown(a,1,i-1);//从根开始 //如果是下标0开始,这里是(a,0,i)
}
}
注意堆的索引是0开始还是1
快速排序
pivot
- random \(O(n\log n)\)
- median-of-three
无论pivot怎么选, Worse Case都是 \(O(n^2)\)
partition strategy
\(i\)移动的条件是是 \(a_i<pivot\) 还是 \(a_i\leq pivot\)?. 如果相等的时候i,j都不移动, 当元素全部相等的时候会不断交换i,j对应的元素. 但好处是两边分出的序列, 时间复杂度
small array
\(n<20\) 用insertion
sorting large structures
交换两个结构体代价太大. 对指针排序
During the sorting, processing every element which is not yet at its final position is called a "run". Which of the following cannot be the result after the second run of quicksort?
A.5, 2, 16, 12, 28, 60, 32, 72
B.2, 16, 5, 28, 12, 60, 32, 72
C.2, 12, 16, 5, 28, 32, 72, 60
D.5, 2, 12, 28, 16, 32, 72, 60
2, 5, 12, 16, 28, 32, 60, 72
快排每轮的pivot都会到最后的位置上. 快排2次, 3个pivot(如果第一轮pivot在边缘,就只有2个) 所以选D
基于比较的排序的下界
决策树 每种排序结果对应一个叶子, 共\(n!\)个叶子 每次比较相当于两个分支. 二叉树的深度为\(\log n!=O(n\log n)\)
桶排序
\(O(n+m)\)
基数排序
Least Significant digit:
1.建立0-9的桶
2.放置:将元素按照最后一个字符放入桶中
3.收集并更新桶:按照从0到9的桶序把桶中的元素按照第二字符放在对应的桶中(注意是从小到大取桶的,所以同一个桶里面十位相同,个位从小到大)
4.重复3直到字符排完
\(O(P(n+B))\)
哈希
separate chaining
对每个哈希值维护一个链表,存储哈希值为\(i\)的所有元素
- 插入和删除\(O(1)\) (因为是链表)
- 查找最坏\(O(n)\)
Given input {4371, 1323, 6173, 4199, 4344, 9679, 1989} and a hash function h(X)=X%10. If the collisions are solved by separate chaining with table size being 10, then the indices of the input numbers in the hash table are: (-1 means the insertion cannot be successful) A.1, 3, 3, 9, 4, 9, 9 (可以有相同的下标)
loading dencity factor: \(\boxed{\lambda=\frac{n}{bs}}\)
其中哈希函数有\(b\)个取值, 哈希表中元素个数\(n\), \(s\)是slot个数()
open addressing
当有冲突发生时,尝试选择其它单元,直到找到空的为止
void insert(int key){
index = hash(key);
while(collision at index)
index = (hash(key) + f(i)) % b;
table[index] = key;
}
linear probing
\(f(i)=i\) 如果冲突,就一个一个往后找,直到找到空位
void insert(int key) {
index = hash(key);
while(collision at index)
index = (index + 1) % b;//注意取模,是循环着遍历整个哈希表
table[index] = key;
}
quadratic probing
\(f(i)=i^2\) 相比线性探测,每次找的下标是\(h(x)+1,h(x)+4,h(x)+9 (\mod T)\dots\)
if the table size is prime and the table is at least half empty, a new element can always be inserted with quadratic probing
Given a hash table of size 13 and the hash function h(x)=x%13. Assume that quadratic probing is used to solve collisions. After filling in the hash table one by one with input sequence { 10, 23, 1, 36, 19, 5 }, which number is placed in the position of index 6?
36 (注意冲突了2次,i=3,(10+3^2)%9=6)
double hashing
\(f(i)=i*h_2(x), h_2(x)=R-(x\mod R)\) \(R\)是略小于tablesize的质数
- make sure the table size is prime
- 理论上
- 但二次探测已经足够了(因为计算哈希比较快)
Given input {4371, 1323, 6173, 4199, 4344, 9679, 1989} and a hash function h(X)=X%10. If the collisions are solved by open addressing hash table with second hash function h2(X)=7−(X%7) and table size being 10, then the indices of the input numbers in the hash table are: (-1 means the insertion cannot be successful)
Rehashing
把Tablesize扩大到原来的2倍,然后把原来哈希表里的元素插入。 哈希函数不变,但因为TableSize变了,哈希的情况也不同。
Suppose that the numbers {4371, 1323, 6173, 4199, 4344, 9679, 1989} are hashed into a table of size 10 with the hash function h(X)=X%10, and hence have indices {1, 3, 4, 9, 5, 0, 2}. What are their indices after rehashing using h(X)=X%TableSize with linear probing?
TableSize变为20 11, 3, 13, 19, 4, 0, 9