Lattice‘s basics in digital electronics
LATTICE is learning Digital Electronic Technology. He is talented, so he understood all those pieces of knowledge in 10^{-9}10−9 second. In the next 10^{-9}10−9 second, he built a data decoding device that decodes data encoded with his special binary coding rule to meaningful words.
His coding rule is called "prefix code", a type of code system (typically a variable-length code) distinguished by its possession of the "prefix property", which requires that there is no whole code word in the system that is a prefix (initial segment) of any other code word in the system. Note that his code is composed of only 00 and 11.
LATTICE‘s device only receives data that perfectly matches LATTICE‘s rules, in other words, people who send message to LATTICE will always obey his coding rule. However, in the process of receiving data, there are errors that cannot avoid, so LATTICE uses parity check to detect error bytes, after every 88-bit data there is 11 bit called parity bit, which should be ‘0‘
if there are odd number of ‘1‘
s in the previous 88 bits and should be ‘1‘
if there are even number of ‘1‘
s. If the parity bit does not meet the fact, then the whole 99 bits (including the parity bit) should be considered as invalid data and ignored. Data without parity bit is also considered as invalid data. Parity bits will be deleted after the parity check.
For example, consider the given data "101010101010101010101010"
, it should be divided into 33parts:"101010101"
,"010101010"
and "101010"
. For the first part, there are 44 ‘1‘
s in the first 88 bits, and parity bit is ‘1‘
, so this part passed the check. For the second part, there are 44 ‘1‘
s and parity bit is ‘0‘
, so this part failed the check. For the third part, it has less than 99 bits so it contains no parity bit, so this part also failed the check. The data after parity check is "10101010"
, which is the first 88 bits of first part.
Data passed the parity check will go into a process that decodes LATTICE‘s code. The process is described in the following example: consider a situation that, "010"
represents ‘A‘
and "1011"
represents ‘B‘
, if the data after parity check is "01010110101011010010"
, it can be divided into "010"
+"1011"
+"010"
+"1011"
+"010"
+"010"
, which means "ABABAA"
. LATTICE‘s device is so exquisite that it can decode all visible characters in the ASCII table .
LATTICE is famous for his Talk show, some reporters have sneaked into his mansion, they stole the data LATTICE to decode in hexadecimal, the coding rule consists of NN pairs of corresponding relations from a bit string S_iSi? to an ASCII code C_iCi?, and the message length MM, they want to peek his privacy so they come to you to write a program that decodes messages that LATTICE receives.
The first line an integer T\ (T<35)T (T<35) represents the number of test cases.
Every test case starts with one line containing two integers, M\ (0<M\leq100000)M (0<M≤100000), the number of original characters, and N\ (1\leq N \leq 256)N (1≤N≤256), then NN lines, every line contains an integer C_iCi?, and a string S_i(0<|S_i|\leq 10)Si?(0<∣Si?∣≤10), means that S_iSi? represents C_iCi?, the ASCII code to a visible character and S_iSi? only contains ‘0‘
or ‘1‘
and there are no two numbers ii and jj that S_iSi? is prefix of S_jSj?.
Then one line contains data that is going to be received in hexadecimal. (0<|data|<200000)(0<∣data∣<200000).
For each test case, output the decoded message in a new line, the length of the decoded message should be the same with the length of original characters, which means you can stop decoding having outputted MM characters. Input guarantees that it will have no less than MM valid characters and all given ASCII codes represent visible characters.
Lattice‘s encoding rule for test case 22:
ASCII code | character | lattice‘s code |
---|---|---|
4949 | 11 | 00010001 |
5050 | 22 | 0100101001 |
5151 | 33 | 011011 |
the device takes this input in hex
14DB24722698
input in binary
0001 0100 1101 1011 0010 0100 0111 0010 0010 0110 1001 1000
formatted into 66 lines, each line contains 88 data bits and one parity bit
00010100 1
10110110 0
10010001 1
10010001 0
01101001 1
000
parity check of the third line and the last line failed, so ignore those two lines.parity bits should also be ignored.
00010100
10110110
10010001
01101001
arrange those bits by the rules informed
0001 01001 011 011 01001 0001 011 01001
output the result
12332132
2 15 9 32 0100 33 11 100 1011 101 0110 104 1010 108 00 111 100 114 0111 119 0101 A6Fd021171c562Fde1 8 3 49 0001 50 01001 51 011 14DB24722698
hello world!!!! 12332132
大模拟,进制转换解码。900ms...多交几发就过了
#include<bits/stdc++.h> #define MAX 15 using namespace std; typedef long long ll; int x; char y[MAX]; string s,ss; map<string,int> mp; string bb(char x){ if(x==‘0‘) return "0000";if(x==‘8‘) return "1000"; if(x==‘1‘) return "0001";if(x==‘9‘) return "1001"; if(x==‘2‘) return "0010";if(x==‘A‘||x==‘a‘) return "1010"; if(x==‘3‘) return "0011";if(x==‘B‘||x==‘b‘) return "1011"; if(x==‘4‘) return "0100";if(x==‘C‘||x==‘c‘) return "1100"; if(x==‘5‘) return "0101";if(x==‘D‘||x==‘d‘) return "1101"; if(x==‘6‘) return "0110";if(x==‘E‘||x==‘e‘) return "1110"; if(x==‘7‘) return "0111";if(x==‘F‘||x==‘f‘) return "1111"; } int find(string s){ int c=0; for(int i=0;i<s.length();i++){ if(s[i]==‘1‘) c++; } return c; } int main() { int t,n,m,i,j; scanf("%d",&t); while(t--){ scanf("%d%d",&n,&m); mp.clear(); for(i=1;i<=m;i++){ scanf("%d %s",&x,y); mp[y]=x; } cin>>s; ss=""; int len=s.length(); for(i=0;i<len;i++){ ss+=bb(s[i]); } s=""; len=ss.length(); for(i=0;i<len;i+=9){ if(i+8>=len) break; if((find(ss.substr(i,8))&1)!=ss[i+8]-‘0‘) s+=ss.substr(i,8); } len=s.length(); for(i=0;i<len;i++){ if(n<=0) break; for(j=i;j<len;j++){ if(mp[s.substr(i,j-i+1)]){ printf("%c",mp[s.substr(i,j-i+1)]); n--;i=j; break; } } } printf("\n"); } return 0; }
ICPC2018沈阳网络赛 Lattice's basics in digital electronics(模拟)
原文:https://www.cnblogs.com/yzm10/p/9610209.html