我有一个类型为
std::stringstd::string是否有一个函数,如果找到字符串则返回 true,如果没有找到则返回 false?
std::string::findif (s1.find(s2) != std::string::npos) {
std::cout << "found!" << '\n';
}
注:“找到了!”如果
s2s1s1s2std::stringfindstd::string str ("There are two needles in this haystack.");
std::string str2 ("needle");
if (str.find(str2) != std::string::npos) {
//.. found.
}
从 C++23 开始,您可以使用 std::string::contains
#include <string>
const auto haystack = std::string("haystack with needles");
const auto needle = std::string("needle");
if (haystack.contains(needle))
{
// found!
}
实际上,你可以尝试使用boost库,我认为std::string没有提供足够的方法来完成所有常见的字符串操作。在boost中,你可以只使用
boost::algorithm::contains#include <string>
#include <boost/algorithm/string.hpp>
int main() {
std::string s("gengjiawen");
std::string t("geng");
bool b = boost::algorithm::contains(s, t);
std::cout << b << std::endl;
return 0;
}
你可以试试这个
string s1 = "Hello";
string s2 = "el";
if(strstr(s1.c_str(),s2.c_str()))
{
cout << " S1 Contains S2";
}
如果该功能对您的系统至关重要,那么使用旧的
strstrstd::searchalgorithm我用来计时整个过程的代码是
#include <string>
#include <cstring>
#include <iostream>
#include <algorithm>
#include <random>
#include <chrono>
std::string randomString( size_t len );
int main(int argc, char* argv[])
{
using namespace std::chrono;
const size_t haystacksCount = 200000;
std::string haystacks[haystacksCount];
std::string needle = "hello";
bool sink = true;
high_resolution_clock::time_point start, end;
duration<double> timespan;
int sizes[10] = { 10, 20, 40, 80, 160, 320, 640, 1280, 5120, 10240 };
for(int s=0; s<10; ++s)
{
std::cout << std::endl << "Generating " << haystacksCount << " random haystacks of size " << sizes[s] << std::endl;
for(size_t i=0; i<haystacksCount; ++i)
{
haystacks[i] = randomString(sizes[s]);
}
std::cout << "Starting std::string.find approach" << std::endl;
start = high_resolution_clock::now();
for(size_t i=0; i<haystacksCount; ++i)
{
if(haystacks[i].find(needle) != std::string::npos)
{
sink = !sink; // useless action
}
}
end = high_resolution_clock::now();
timespan = duration_cast<duration<double>>(end-start);
std::cout << "Processing of " << haystacksCount << " elements took " << timespan.count() << " seconds." << std::endl;
std::cout << "Starting strstr approach" << std::endl;
start = high_resolution_clock::now();
for(size_t i=0; i<haystacksCount; ++i)
{
if(strstr(haystacks[i].c_str(), needle.c_str()))
{
sink = !sink; // useless action
}
}
end = high_resolution_clock::now();
timespan = duration_cast<duration<double>>(end-start);
std::cout << "Processing of " << haystacksCount << " elements took " << timespan.count() << " seconds." << std::endl;
std::cout << "Starting std::search approach" << std::endl;
start = high_resolution_clock::now();
for(size_t i=0; i<haystacksCount; ++i)
{
if(std::search(haystacks[i].begin(), haystacks[i].end(), needle.begin(), needle.end()) != haystacks[i].end())
{
sink = !sink; // useless action
}
}
end = high_resolution_clock::now();
timespan = duration_cast<duration<double>>(end-start);
std::cout << "Processing of " << haystacksCount << " elements took " << timespan.count() << " seconds." << std::endl;
}
return 0;
}
std::string randomString( size_t len)
{
static const char charset[] = "abcdefghijklmnopqrstuvwxyz";
static const int charsetLen = sizeof(charset) - 1;
static std::default_random_engine rng(std::random_device{}());
static std::uniform_int_distribution<> dist(0, charsetLen);
auto randChar = [charset, &dist, &rng]() -> char
{
return charset[ dist(rng) ];
};
std::string result(len, 0);
std::generate_n(result.begin(), len, randChar);
return result;
}
在这里,我生成随机
haystacksneedle输出为:
Generating 200000 random haystacks of size 10
Starting std::string.find approach
Processing of 200000 elements took 0.00358503 seconds.
Starting strstr approach
Processing of 200000 elements took 0.0022727 seconds.
Starting std::search approach
Processing of 200000 elements took 0.0346258 seconds.
Generating 200000 random haystacks of size 20
Starting std::string.find approach
Processing of 200000 elements took 0.00480959 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00236199 seconds.
Starting std::search approach
Processing of 200000 elements took 0.0586416 seconds.
Generating 200000 random haystacks of size 40
Starting std::string.find approach
Processing of 200000 elements took 0.0082571 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00341435 seconds.
Starting std::search approach
Processing of 200000 elements took 0.0952996 seconds.
Generating 200000 random haystacks of size 80
Starting std::string.find approach
Processing of 200000 elements took 0.0148288 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00399263 seconds.
Starting std::search approach
Processing of 200000 elements took 0.175945 seconds.
Generating 200000 random haystacks of size 160
Starting std::string.find approach
Processing of 200000 elements took 0.0293496 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00504251 seconds.
Starting std::search approach
Processing of 200000 elements took 0.343452 seconds.
Generating 200000 random haystacks of size 320
Starting std::string.find approach
Processing of 200000 elements took 0.0522893 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00850485 seconds.
Starting std::search approach
Processing of 200000 elements took 0.64133 seconds.
Generating 200000 random haystacks of size 640
Starting std::string.find approach
Processing of 200000 elements took 0.102082 seconds.
Starting strstr approach
Processing of 200000 elements took 0.00925799 seconds.
Starting std::search approach
Processing of 200000 elements took 1.26321 seconds.
Generating 200000 random haystacks of size 1280
Starting std::string.find approach
Processing of 200000 elements took 0.208057 seconds.
Starting strstr approach
Processing of 200000 elements took 0.0105039 seconds.
Starting std::search approach
Processing of 200000 elements took 2.57404 seconds.
Generating 200000 random haystacks of size 5120
Starting std::string.find approach
Processing of 200000 elements took 0.798496 seconds.
Starting strstr approach
Processing of 200000 elements took 0.0137969 seconds.
Starting std::search approach
Processing of 200000 elements took 10.3573 seconds.
Generating 200000 random haystacks of size 10240
Starting std::string.find approach
Processing of 200000 elements took 1.58171 seconds.
Starting strstr approach
Processing of 200000 elements took 0.0143111 seconds.
Starting std::search approach
Processing of 200000 elements took 20.4163 seconds.
如果字符串的大小相对较大(数百字节或更多)并且 c++17 可用,您可能需要使用 Boyer-Moore-Horspool 搜索器(来自 cppreference.com 的示例):
#include <iostream>
#include <string>
#include <algorithm>
#include <functional>
int main()
{
std::string in = "Lorem ipsum dolor sit amet, consectetur adipiscing elit,"
" sed do eiusmod tempor incididunt ut labore et dolore magna aliqua";
std::string needle = "pisci";
auto it = std::search(in.begin(), in.end(),
std::boyer_moore_searcher(
needle.begin(), needle.end()));
if(it != in.end())
std::cout << "The string " << needle << " found at offset "
<< it - in.begin() << '\n';
else
std::cout << "The string " << needle << " not found\n";
}
那又如何
string response = "hello world";
string findMe = "world";
if(response.find(findMe) != string::npos)
{
//found
}
如果您不想使用标准库函数,下面是一种解决方案。
#include <iostream>
#include <string>
bool CheckSubstring(std::string firstString, std::string secondString){
if(secondString.size() > firstString.size())
return false;
for (int i = 0; i < firstString.size(); i++){
int j = 0;
// If the first characters match
if(firstString[i] == secondString[j]){
int k = i;
while (firstString[i] == secondString[j] && j < secondString.size()){
j++;
i++;
}
if (j == secondString.size())
return true;
else // Re-initialize i to its original value
i = k;
}
}
return false;
}
int main(){
std::string firstString, secondString;
std::cout << "Enter first string:";
std::getline(std::cin, firstString);
std::cout << "Enter second string:";
std::getline(std::cin, secondString);
if(CheckSubstring(firstString, secondString))
std::cout << "Second string is a substring of the frist string.\n";
else
std::cout << "Second string is not a substring of the first string.\n";
return 0;
}
也很好用
std::regex_search//THE STRING IN WHICH THE SUBSTRING TO BE FOUND.
std::string testString = "Find Something In This Test String";
//THE SUBSTRING TO BE FOUND.
auto pattern{ "In This Test" };
//std::regex_constants::icase - TO IGNORE CASE.
auto rx = std::regex{ pattern,std::regex_constants::icase };
//SEARCH THE STRING.
bool isStrExists = std::regex_search(testString, rx);
需要包含
#include <regex>出于某种原因,假设输入字符串被观察到类似“在这个示例字符串中查找某些内容”,并且有兴趣搜索“在这个测试中”或“在这个示例中”,那么可以通过简单地将模式调整为来增强搜索如下所示。
//THE SUBSTRING TO BE FOUND.
auto pattern{ "In This (Test|Example)" };
#include <algorithm> // std::search
#include <string>
using std::search; using std::count; using std::string;
int main() {
string mystring = "The needle in the haystack";
string str = "needle";
string::const_iterator it;
it = search(mystring.begin(), mystring.end(),
str.begin(), str.end()) != mystring.end();
// if string is found... returns iterator to str's first element in mystring
// if string is not found... returns iterator to mystring.end()
if (it != mystring.end())
// string is found
else
// not found
return 0;
}
从这个网站上的这么多答案中我没有找到明确的答案,所以在 5-10 分钟内我自己找到了答案。 但这可以在两种情况下完成:
所以,假设我们在字符串“abcde”中搜索子字符串“cd”,并且我们使用C++中最简单的substr内置函数
1 人:
#include <iostream>
#include <string>
using namespace std;
int i;
int main()
{
string a = "abcde";
string b = a.substr(2,2); // 2 will be c. Why? because we start counting from 0 in a string, not from 1.
cout << "substring of a is: " << b << endl;
return 0;
}
2人份:
#include <iostream>
#include <string>
using namespace std;
int i;
int main()
{
string a = "abcde";
for (i=0;i<a.length(); i++)
{
if (a.substr(i,2) == "cd")
{
cout << "substring of a is: " << a.substr(i,2) << endl; // i will iterate from 0 to 5 and will display the substring only when the condition is fullfilled
}
}
return 0;
}
这是一个简单的功能
bool find(string line, string sWord)
{
bool flag = false;
int index = 0, i, helper = 0;
for (i = 0; i < line.size(); i++)
{
if (sWord.at(index) == line.at(i))
{
if (flag == false)
{
flag = true;
helper = i;
}
index++;
}
else
{
flag = false;
index = 0;
}
if (index == sWord.size())
{
break;
}
}
if ((i+1-helper) == index)
{
return true;
}
return false;
}
注意:我知道这个问题需要一个函数,这意味着用户正在尝试找到更简单的东西。但我仍然发布它以防有人觉得有用。
使用后缀自动机的方法。它接受一个字符串(干草堆),之后你可以输入数十万个查询(针),响应会非常快,即使干草堆和/或针是很长的字符串。
了解此处使用的数据结构:https://en.wikipedia.org/wiki/Suffix_automaton
#include <bits/stdc++.h>
using namespace std;
struct State {
int len, link;
map<char, int> next;
};
struct SuffixAutomaton {
vector<State> st;
int sz = 1, last = 0;
SuffixAutomaton(string& s) {
st.assign(s.size() * 2, State());
st[0].len = 0;
st[0].link = -1;
for (char c : s) extend(c);
}
void extend(char c) {
int cur = sz++, p = last;
st[cur].len = st[last].len + 1;
while (p != -1 && !st[p].next.count(c)) st[p].next[c] = cur, p = st[p].link;
if (p == -1)
st[cur].link = 0;
else {
int q = st[p].next[c];
if (st[p].len + 1 == st[q].len)
st[cur].link = q;
else {
int clone = sz++;
st[clone].len = st[p].len + 1;
st[clone].next = st[q].next;
st[clone].link = st[q].link;
while (p != -1 && st[p].next[c] == q) st[p].next[c] = clone, p = st[p].link;
st[q].link = st[cur].link = clone;
}
}
last = cur;
}
};
bool is_substring(SuffixAutomaton& sa, string& query) {
int curr = 0;
for (char c : query)
if (sa.st[curr].next.count(c))
curr = sa.st[curr].next[c];
else
return false;
return true;
}
// How to use:
// Execute the code
// Type the first string so the program reads it. This will be the string
// to search substrings on.
// After that, type a substring. When pressing enter you'll get the message showing the
// result. Continue typing substrings.
int main() {
string S;
cin >> S;
SuffixAutomaton sa(S);
string query;
while (cin >> query) {
cout << "is substring? -> " << is_substring(sa, query) << endl;
}
}
您还可以使用系统命名空间。 然后你就可以使用 contains 方法了。
#include <iostream>
using namespace System;
int main(){
String ^ wholeString = "My name is Malindu";
if(wholeString->ToLower()->Contains("malindu")){
std::cout<<"Found";
}
else{
std::cout<<"Not Found";
}
}
我们可以用这个方法来代替。 只是我的项目中的一个例子。 参考代码。 还包括一些额外的内容。
查看 if 语句!
/*
Every C++ program should have an entry point. Usually, this is the main function.
Every C++ Statement ends with a ';' (semi-colon)
But, pre-processor statements do not have ';'s at end.
Also, every console program can be ended using "cin.get();" statement, so that the console won't exit instantly.
*/
#include <string>
#include <bits/stdc++.h> //Can Use instead of iostream. Also should be included to use the transform function.
using namespace std;
int main(){ //The main function. This runs first in every program.
string input;
while(input!="exit"){
cin>>input;
transform(input.begin(),input.end(),input.begin(),::tolower); //Converts to lowercase.
if(input.find("name") != std::string::npos){ //Gets a boolean value regarding the availability of the said text.
cout<<"My Name is AI \n";
}
if(input.find("age") != std::string::npos){
cout<<"My Age is 2 minutes \n";
}
}
}