zoj 4049

Halting Problem

Time Limit: 1 Second Memory Limit: 65536 KB

In computability theory, the halting problem is the problem of determining, from a description of an arbitrary computer program, whether the program will finish running (i.e., halt) or continue to run forever.

Alan Turing proved in 1936 that a general algorithm to solve the halting problem cannot exist, but DreamGrid, our beloved algorithm scientist, declares that he has just found a solution to the halting problem in a specific programming language -- the Dream Language!

Dream Language is a programming language consists of only 5 types of instructions. All these instructions will read from or write to a 8-bit register $, whose value is initially set to 0. We now present the 5 types of instructions in the following table. Note that we denote the current instruction as the -th instruction.$

Instruction	Description
add	Add $to the register . As is a 8-bit register, this instruction actually calculates and stores the result into, i.e. . After that, go on to the -th instruction.$
beq	If the value of $is equal to, jump to the -th instruction, otherwise go on to the -th instruction.$
bne	If the value of $isn't equal to, jump to the -th instruction, otherwise go on to the -th instruction.$
blt	If the value of $is strictly smaller than, jump to the -th instruction, otherwise go on to the -th instruction.$
bgt	If the value of $is strictly larger than, jump to the -th instruction, otherwise go on to the -th instruction.$

A Dream Language program consisting of $instructions will always start executing from the 1st instruction, and will only halt (that is to say, stop executing) when the program tries to go on to the -th instruction.$

As DreamGrid's assistant, in order to help him win the Turing Award, you are asked to write a program to determine whether a given Dream Language program will eventually halt or not.

Input

There are multiple test cases. The first line of the input is an integer $, indicating the number of test cases. For each test case:$

The first line contains an integer $(), indicating the number of instructions in the following Dream Language program.$

For the following $lines, the -th line first contains a string (), indicating the type of the -th instruction of the program.$

If $equals to "add", an integer follows (), indicating the value added to the register;$
Otherwise, two integers $and follow (,), indicating the condition value and the destination of the jump.$

It's guaranteed that the sum of $of all test cases will not exceed .$

Output

For each test case output one line. If the program will eventually halt, output "Yes" (without quotes); If the program will continue to run forever, output "No" (without quotes).

Sample Input

4
2
add 1
blt 5 1
3
add 252
add 1
bgt 252 2
2
add 2
bne 7 1
3
add 1
bne 252 1
beq 252 1

Sample Output

Yes
Yes
No
No

Hint

For the second sample test case, note that $is a 8-bit register, so after four "add 1" instructions the value of will change from 252 to 0, and the program will halt.$

For the third sample test case, it's easy to discover that the value of $will always be even, so it's impossible for the value of to be equal to 7, and the program will run forever.$

Author: WENG, Caizhi
Source: The 2018 ACM-ICPC Asia Qingdao Regional Contest, Online

const int N =1e4+5; 
int vis[N][260];
int t,n;
struct Ma{
    char s[10];
    int v,k;
}ma[N];
void  init()
{
    for(int i=1;i<=n;i++)
    {
        for(int j=0;j<260;j++){//一开始写成了26
            vis[i][j]=0;
        }
    }
}
int  main()
{
    scanf("%d",&t);
    while(t--)
    {
        scanf("%d",&n);
        init();
        for(int i=1;i<=n;i++)
        {
            scanf("%s",ma[i].s);
            if(ma[i].s[0]=='a') {
                scanf("%d",&ma[i].v);
                ma[i].k=0;
            }
            else{
                scanf("%d%d",&ma[i].v,&ma[i].k);
            }
        }
        int pos=1,ret=0,flag=0;
        while(1)
        {
            if(pos==n+1) {
                flag=1;
                break;
            }
            if(vis[pos][ret]) {
                flag=0;
                break;
            }
            vis[pos][ret]++;//由ret到第pos个指令，若重复出现就会死循环
            if(ma[pos].s[0]=='a') {
                ret=(ret+ma[pos].v)%256;
                pos++;
            }
            else if(ma[pos].s[1]=='e'){
                if(ret==ma[pos].v){
                    pos=ma[pos].k;
                }
                else{
                    pos++;
                }
            }
            else if(ma[pos].s[1]=='n'){
                if(ret!=ma[pos].v){
                    pos=ma[pos].k;
                }
                else{
                    pos++;
                }
            }
            else if(ma[pos].s[1]=='l'){
                if(ret<ma[pos].v){
                    pos=ma[pos].k;
                }
                else{
                    pos++;
                }
            }
            else if(ma[pos].s[1]=='g'){
                if(ret>ma[pos].v){
                    pos=ma[pos].k;
                }
                else{
                    pos++;
                }
            }
        }
        printf("%s\n",flag==1?"Yes":"No");
    }
    return 0;
}

Input

Output

Sample Input

Sample Output

Hint

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