Dev C++ String Functions
General Data Protection Regulation (GDPR) On May 25, 2018, a new privacy law called the General Data Protection Regulation (GDPR) takes effect in the European Union (EU). GDPR expands the privacy rights of EU individuals and places new obligations on all organizations that market, track, or handle EU personal data. Apr 12, 2012 C Tutorial 5 - Strings, Getline, Concatenation, and String Functions. We will also learn how to concatenate strings together as well as use some predefined string functions from the string.
Apr 20, 2016 Different methods to reverse a string in C/C Given a string, write a C/C program to reverse it. Write own reverse function by swapping characters: One simple solution is two write our own reverse function to reverse a string in C. Nov 19, 2018 C supports function pointers in the same manner as the C language. However a more type-safe alternative is usually to use a function object. It is recommended that typedef be used to declare an alias for the function pointer type if declaring a function that returns a function pointer type. C: Functions We've talked a little bit about functions in the past - they're pieces of code that can be executed on command. In fact we've been using functions right since the very start of this process, we just haven't really talked about them in depth - this is what this tutorial is all about.
C++Language | ||||
Standard Library Headers | ||||
Freestanding and hosted implementations | ||||
Named requirements | ||||
Language support library | ||||
Concepts library(C++20) | ||||
Diagnostics library | ||||
Utilities library | ||||
Strings library | ||||
Containers library | ||||
Iterators library | ||||
Ranges library(C++20) | ||||
Algorithms library | ||||
Numerics library | ||||
Input/output library | ||||
Localizations library | ||||
Regular expressions library(C++11) | ||||
Atomic operations library(C++11) | ||||
Thread support library(C++11) | ||||
Filesystem library(C++17) | ||||
Technical Specifications |
Null-terminated strings | ||||
Byte strings | ||||
Multibyte strings | ||||
Wide strings | ||||
Classes | ||||
(C++17) |
The C++ strings library includes support for three general types of strings:
- std::basic_string - a templated class designed to manipulate strings of any character type.
- std::basic_string_view(C++17) - a lightweight non-owning read-only view into a subsequence of a string.
- Null-terminated strings - arrays of characters terminated by a special null character.
Contents
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[edit]std::basic_string
The templated class std::basic_string generalizes how sequences of characters are manipulated and stored. String creation, manipulation, and destruction are all handled by a convenient set of class methods and related functions.
Several specializations of std::basic_string are provided for commonly-used types:
Type | Definition |
std::string | std::basic_string<char> |
std::wstring | std::basic_string<wchar_t> |
std::u8string(since C++20) | std::basic_string<char8_t> |
std::u16string(since C++11) | std::basic_string<char16_t> |
std::u32string(since C++11) | std::basic_string<char32_t> |
std::basic_string_viewThe templated class std::basic_string_view provides a lightweight object that offers read-only access to a string or a part of a string using an interface similar to the interface of std::basic_string. Several specializations of std::basic_string_view are provided for commonly-used types:
| (since C++17) |
[edit] Null-terminated strings
Null-terminated strings are arrays of characters that are terminated by a special null character. C++ provides functions to create, inspect, and modify null-terminated strings.
There are three types of null-terminated strings:
[edit] Additional support
[edit]std::char_traits
The string library also provides class template std::char_traits that defines types and functions for std::basic_stringand std::basic_string_view(since C++17). The following specializations are defined:
template<>class char_traits<char>; | |
template<>class char_traits<char8_t>; | (since C++20) |
(since C++11) | |
template<>class char_traits<char32_t>; | (since C++11) |
[edit]Conversions and classification
The localizations library provides support for string conversions (e.g. std::wstring_convert or std::toupper) as well as functions that classify characters (e.g. std::isspace or std::isdigit).
[edit]See also
C documentation for Strings library |
We've talked a little bit about functions in the past - they're pieces of code that can be executed on command. In fact we've been using functions right since the very start of this process, we just haven't really talked about them in depth - this is what this tutorial is all about.
As outlined earlier - a function is simply a piece of code (which may or may not need a value to work properly) that you can execute by 'calling' it. There are a bunch of functions built into the core language, but functions can also be created manually (we'll be learning about this a bit later on). The classic function notation looks like this: functionName();
. In the previous snippet we would be calling a function called functionName
which doesn't take any values to work properly (if it took any values - we'd put them in the brackets). A classic example of a function is the sqrt
function which is defined inside math.h
. We used this back in the basic mathematics tutorial, it simply square roots any value you pass to it. If we ever need to pass multiple values to a function, we separate them with a comma - so something like this: functionName(valueone, valuetwo, valuethree);
.With this under our belts - let's start learning how to create our very own functions that can execute any preset code for us. For this tutorial we are going to work on creating a function which can add two numbers together.
Believe it or not, you've already got one function in your basic program structure. The main function! Let's dissect it a little so we can use something similar to create custom functions. The first thing it consists of is the function's type - it's an int
in this case because the main function needs to be an int
to be the int main
that the compiler recognises as the program's entry point. The next thing (seperated from the type by a space) is the function's name - in this case it's main, and as I just alluded to, this is so the compiler recognises it as a point of entry. Next we have some empty brackets - these are here to illustrate that the function doesn't take any values, if we wanted a function to take values in (in the case of the function we want to create - we'll need to take two values so we can add them together) then we would put them inside the brackets. From here we simply have some curly brackets, inside which is the actual code we want the function to execute when called.
So firstly - why do functions need a type? Well, it's all to do with return
. If a function is of type int
, it must return an integer (e.g. return 0
which in the case of the main function illustrates that the program exited without any errors). Values that functions return essentially go in the place where the function was originally called - so the sqrt
function returns the result of the square root operation (hence when we put it in a cout
or something, the square root value get's inserted at the point we called it). Function can have the type of any version of our function, let's just create a function which can output some basic text - let's stick with the classics and make it output 'Hello World'. So firstly let's decide on a type and name - void
is probably a good choice here as we can just use cout
in the function rather than making it return anything. For the name, I'm going to go with 'say_hello'. So to make the function, we simply write a definition (the structure of which we've already talked about) before the main function in the code. It's important that it's before, otherwise the compiler won't know what you're talking about when you reference the function in main
. The following would work fine for our simply say_hello
function (I've just used the basic structure we've already discussed and put a cout
inside):
Alternatively, you could put the function definition below the main function and simply leave what is called a prototype before the main function (to tell the compiler not to worry when trying to call the function in main as we define it later). A prototype is essentially just the first line of our function definition (no curly brackets) with a semi-colon afterwards. So if we wanted to use the prototype approach instead of putting the function before (some people prefer doing things this way - a lot of it is down to personal preference), we could do something like this:
Now you've got the function setup (either before the main function, or after with a function prototype before) - you can go ahead and call it from the main function using the process we talked about earlier (while we're talking about this - it's worth noting that functions can call each other if you want this nested-like functionality with multiple functions).
So our code at the moment should look something like this (I'm not going to use prototypes in this example just to avoid confusing anyone who doesn't quite understand them): David cook dream big song download.
Dev C++ String Functions Diagram
On running the above program, you should see that our basic function works! Brilliant, now let's modify it a bit so that it can add two numbers. Firstly let's change its name from 'say_hello' to something more appropriate like 'add_two_integers'. For now we can leave it as void
and then make it simply do the addition in the cout
- but we'll change this later and make it instead use return
. Now let's make it take in two integer values, as it requires these to do its job properly (how else would it add two numbers?) - we write these just like variable definitions apart from they are inside the function definition's brackets (and inside the prototype brackets too if you're using a function prototype). If you want the function to take more than one value (like we do), then you can separate the values with commas. I'm going to call the parameters that my function takes (the proper terminology for the values it takes), 'value_one', and 'value_two'. Our function definition at the moment should look something like this:
From here, we can reference 'value_one' and 'value_two' (or whatever you called the 'variables' in the function definition) in our function and it will refer to whatever values the function was called with. It's important to note that if you try to call the function with two values that do not match the type of those that you put in the function definition (or you specify a different number of values) - the compiler should spit out an error telling you that it can't find the function you're talking about. So with the knowledge that we can reference variables that the function was passed, let's make our function output the addition of the two variables it was passed:
It's that simple, as long as we update our function call so that it uses the correct function name and passes the correct values, everything should work!
Excellent! The only problem is that our function for adding two integers isn't usable if we want to put the number in a more complex cout
, do more mathematics to it, or pass it to another function. Our function's name is also a little bit misleading as the function doesn't actually add two integers, it outputs the addition of two integers. To fix this, let's just change the function type and use return. Since the addition of two integers should always result in an integer, we can use the int
function type. Now we've done this we must make the function return a value or the compiler will (should) complain. Let's go ahead and remove the cout
line currently in there as it's getting in the way, and replace it instead with a line that return
s the addition.
All we need to do now is update the function call in main
so we actually use the value it returns somehow - I'm just going to multiply the addition of the two values by 2. The full source code should look something like the following:
And tada, we created our very own fully functional function! This is a very important technique when creating applications/programs using C++ and should be a process you get very used to in the creation process. If you fancy the challenge, try creating a basic function that takes three parameters - it adds the first two, and then multiplies the result by the third parameter if the third parameter is less than 100.
There are a few more things we should probably talk about before this tutorial is over, namely what we can do when some parameters are not specified. The first thing we can do is something called overloading functions. This is a key concept in C++ which allows you to write two or more functions with the same name that take different parameters!
At current, our 'add_two_integers' function will only be called when we pass it two integer values, however we could, if we wanted, write a function with the same name that takes different parameters or parameters of different types, and the compiler would call the correct function for the job depending on the parameters we passed in. Let's say, for example, that we also wanted a version of our function that added floats -- if we renamed the function to 'add_two_numbers' (so that the name makes more sense), we could write both versions of our function (one for integers and one for floats) like so:
In the example above, we could then call 'add_two_numbers' with either two integers or two floats without a problem, and the appropriate function would be called. Similarly, we could, if we wanted, make a function with the same name that just takes completely different parameters, and the compiler would choose the right one, spitting out an error if it can't find one which takes the parameters we're giving it. This concept is very important when creating bigger applications and is used all over the place in the world of C-programming.
The other way we could address the 'issue' of the wrong number of parameters being passed (although not the wrong type), is by using default parameters. This is essentially where we can just give a value to use for a parameter if none are specified, so in our 'add_two_numbers' function we might want to default the values to 0 and 0 if no parameters are passed to it -- this can be accomplished via an equals sign in the function parameter declaration brackets:
In the above we could just call add_two_numbers ();
with no problem. It's important to remember that after the first default parameter in a function declaration (e.g. int value_one = 0
), all preceding parameters must also have default values assigned to them (and if you think about it, this makes sense).
It heavily depends on usage situations, but function overloads are often preferable to default parameters in situations in which overloads don't cause a whole bunch of code repeating -- this is because mixing default parameters and function overloads can mess things up a little bit. Consider the following in which the compiler doesn't know which function to use:
Your compiler should spit out an error in cases like this - something along the lines of 'ambiguous call to overloaded function', but be careful as this can really mess up your code and cause a lot of confusion!
To tie off this tutorial, let's just touch on a concept called recursion. Recursion, in the context of functions, is where a function calls itself. This concept can seem a little bit confusing at first, however it shouldn't be totally alien to you. Usually it's best when people figure out recursion for themselves, so all I'm going to do to help you along is show you the following example of recursion:
String Functions In Dev C++
Recursion can be a little mind-bending, and in the above example isn't entirely necessary, but it's a very important topic when programming and is the best solution in a number of situations. If you don't understand the above code snippet, try running through the program line-by-line, starting from the 'countdown' call in 'main', and just do exactly what your program would do upon execution in your mind. We've covered a lot in this tutorial so you should be doing a lot of experimentation to test out the different things demonstrated -- none of the concepts covered should be hard as nails, but you need to make sure you fully understand them before moving on to the next tutorial (as is the case with most of the tutorials in this course - each tutorial builds on things learnt from the last).