Related
I must be misunderstanding something because I thought the two cases are the same:
#include <iostream>
void function() { std::cout << "Hi\n"; }
int main()
{
std::vector<void(*)()> funcPtrVec;
std::vector<void()> funcVec;
funcPtrVec.push_back(function); // Works
funcVec.push_back(function); // Works
auto lambdaFunc = []() { std::cout << "Hi\n"; };
funcPtrVec.push_back(lambdaFunc); // Works
funcVec.push_back(lambdaFunc); // Doesn't work
}
Now, in both cases my compiler says that the function signatures are the same, void function() and void lambdaFunc(). I really thought that when a lambda function doesn't capture anything it behaves like a free function, which the same signatures would seem to support. Also, I guess I'm confused even more due to the fact that in the following all seem to be treated the same, as if decaying to the same thing:
void function() { std::cout << "Hi\n"; }
void funcTakingFunc(void()) {}
void funcTakingFuncPtr(void(*)()) {}
int main()
{
auto lambdaFunc = []() { std::cout << "Hi\n"; };
void(*funcPtr)() = lambdaFunc; // Works
funcTakingFuncPtr(lambdaFunc); // Works
funcTakingFuncPtr(funcPtr); // Works
funcTakingFunc(lambdaFunc); // Works
funcTakingFunc(funcPtr); // Works
// They all work
}
So as far as I can see the only distinction between the function and the function pointer made is when given as a template argument to vector. This obviously means I don't understand templates well, but what's the reason for this? Because the two really seem the same from the examples I tried.
std::vector<void()> is not allowed; the type must be an object type, and a function type is not an object type.
There are various parts of the specification of vector requirements we could identify as being violated by a non-object type; the most obvious is the default allocator. In the table in [allocator.requirements]/2 it is specified that the type the allocator is for must be an object type.
I mean something like:
int main()
{
void a()
{
// code
}
a();
return 0;
}
Modern C++ - Yes with lambdas!
In current versions of c++ (C++11, C++14, and C++17), you can have functions inside functions in the form of a lambda:
int main() {
// This declares a lambda, which can be called just like a function
auto print_message = [](std::string message)
{
std::cout << message << "\n";
};
// Prints "Hello!" 10 times
for(int i = 0; i < 10; i++) {
print_message("Hello!");
}
}
Lambdas can also modify local variables through **capture-by-reference*. With capture-by-reference, the lambda has access to all local variables declared in the lambda's scope. It can modify and change them normally.
int main() {
int i = 0;
// Captures i by reference; increments it by one
auto addOne = [&] () {
i++;
};
while(i < 10) {
addOne(); //Add 1 to i
std::cout << i << "\n";
}
}
C++98 and C++03 - Not directly, but yes with static functions inside local classes
C++ doesn't support that directly.
That said, you can have local classes, and they can have functions (non-static or static), so you can get this to some extend, albeit it's a bit of a kludge:
int main() // it's int, dammit!
{
struct X { // struct's as good as class
static void a()
{
}
};
X::a();
return 0;
}
However, I'd question the praxis. Everyone knows (well, now that you do, anyway :)) C++ doesn't support local functions, so they are used to not having them. They are not used, however, to that kludge. I would spend quite a while on this code to make sure it's really only there to allow local functions. Not good.
For all intents and purposes, C++ supports this via lambdas:1
int main() {
auto f = []() { return 42; };
std::cout << "f() = " << f() << std::endl;
}
Here, f is a lambda object that acts as a local function in main. Captures can be specified to allow the function to access local objects.
Behind the scenes, f is a function object (i.e. an object of a type that provides an operator()). The function object type is created by the compiler based on the lambda.
1 since C++11
Local classes have already been mentioned, but here is a way to let them appear even more as local functions, using an operator() overload and an anonymous class:
int main() {
struct {
unsigned int operator() (unsigned int val) const {
return val<=1 ? 1 : val*(*this)(val-1);
}
} fac;
std::cout << fac(5) << '\n';
}
I don't advise on using this, it's just a funny trick (can do, but imho shouldn't).
2014 Update:
With the rise of C++11 a while back, you can now have local functions whose syntax is a little reminiscient of JavaScript:
auto fac = [] (unsigned int val) {
return val*42;
};
For a recursive function, compile-time type deduction is not supported:
function<int(int)> factorial{ [&](int n)
{
return (n == 1 || n == 0) ? 1 : factorial(n - 1) * n;
} };
You can't have local functions in C++. However, C++11 has lambdas. Lambdas are basically variables that work like functions.
A lambda has the type std::function (actually that's not quite true, but in most cases you can suppose it is). To use this type, you need to #include <functional>. std::function is a template, taking as template argument the return type and the argument types, with the syntax std::function<ReturnType(ArgumentTypes)>. For example, std::function<int(std::string, float)> is a lambda returning an int and taking two arguments, one std::string and one float. The most common one is std::function<void()>, which returns nothing and takes no arguments.
Once a lambda is declared, it is called just like a normal function, using the syntax lambda(arguments).
To define a lambda, use the syntax [captures](arguments){code} (there are other ways of doing it, but I won't mention them here). arguments is what arguments the lambda takes, and code is the code that should be run when the lambda is called. Usually you put [=] or [&] as captures. [=] means that you capture all variables in the scope in which the value is defined by value, which means that they will keep the value that they had when the lambda was declared. [&] means that you capture all variables in the scope by reference, which means that they will always have their current value, but if they are erased from memory the program will crash. Here are some examples:
#include <functional>
#include <iostream>
int main(){
int x = 1;
std::function<void()> lambda1 = [=](){
std::cout << x << std::endl;
};
std::function<void()> lambda2 = [&](){
std::cout << x << std::endl;
};
x = 2;
lambda1(); //Prints 1 since that was the value of x when it was captured and x was captured by value with [=]
lambda2(); //Prints 2 since that's the current value of x and x was captured by reference with [&]
std::function<void()> lambda3 = [](){}, lambda4 = [](){}; //I prefer to initialize these since calling an uninitialized lambda is undefined behavior.
//[](){} is the empty lambda.
{
int y = 3; //y will be deleted from the memory at the end of this scope
lambda3 = [=](){
std::cout << y << endl;
};
lambda4 = [&](){
std::cout << y << endl;
};
}
lambda3(); //Prints 3, since that's the value y had when it was captured
lambda4(); //Causes the program to crash, since y was captured by reference and y doesn't exist anymore.
//This is a bit like if you had a pointer to y which now points nowhere because y has been deleted from the memory.
//This is why you should be careful when capturing by reference.
return 0;
}
You can also capture specific variables by specifying their names. Just specifying their name will capture them by value, specifying their name with a & before will capture them by reference. For example, [=, &foo] will capture all variables by value except foo which will be captured by reference, and [&, foo] will capture all variables by reference except foo which will be captured by value. You can also capture only specific variables, for example [&foo] will capture foo by reference and will capture no other variables. You can also capture no variables at all by using []. If you try to use a variable in a lambda that you didn't capture, it won't compile. Here is an example:
#include <functional>
int main(){
int x = 4, y = 5;
std::function<void(int)> myLambda = [y](int z){
int xSquare = x * x; //Compiler error because x wasn't captured
int ySquare = y * y; //OK because y was captured
int zSquare = z * z; //OK because z is an argument of the lambda
};
return 0;
}
You can't change the value of a variable that was captured by value inside a lambda (variables captured by value have a const type inside the lambda). To do so, you need to capture the variable by reference. Here is an exampmle:
#include <functional>
int main(){
int x = 3, y = 5;
std::function<void()> myLambda = [x, &y](){
x = 2; //Compiler error because x is captured by value and so it's of type const int inside the lambda
y = 2; //OK because y is captured by reference
};
x = 2; //This is of course OK because we're not inside the lambda
return 0;
}
Also, calling uninitialized lambdas is undefined behavior and will usually cause the program to crash. For example, never do this:
std::function<void()> lambda;
lambda(); //Undefined behavior because lambda is uninitialized
Examples
Here is the code for what you wanted to do in your question using lambdas:
#include <functional> //Don't forget this, otherwise you won't be able to use the std::function type
int main(){
std::function<void()> a = [](){
// code
}
a();
return 0;
}
Here is a more advanced example of a lambda:
#include <functional> //For std::function
#include <iostream> //For std::cout
int main(){
int x = 4;
std::function<float(int)> divideByX = [x](int y){
return (float)y / (float)x; //x is a captured variable, y is an argument
}
std::cout << divideByX(3) << std::endl; //Prints 0.75
return 0;
}
No.
What are you trying to do?
workaround:
int main(void)
{
struct foo
{
void operator()() { int a = 1; }
};
foo b;
b(); // call the operator()
}
Starting with C++ 11 you can use proper lambdas. See the other answers for more details.
Old answer: You can, sort-of, but you have to cheat and use a dummy class:
void moo()
{
class dummy
{
public:
static void a() { printf("I'm in a!\n"); }
};
dummy::a();
dummy::a();
}
No, it's not allowed. Neither C nor C++ support this feature by default, however TonyK points out (in the comments) that there are extensions to the GNU C compiler that enable this behavior in C.
You cannot define a free function inside another in C++.
As others have mentioned, you can use nested functions by using the gnu language extensions in gcc. If you (or your project) sticks to the gcc toolchain, your code will be mostly portable across the different architectures targeted by the gcc compiler.
However, if there is a possible requirement that you might need to compile code with a different toolchain, then I'd stay away from such extensions.
I'd also tread with care when using nested functions. They are a beautiful solution for managing the structure of complex, yet cohesive blocks of code (the pieces of which are not meant for external/general use.) They are also very helpful in controlling namespace pollution (a very real concern with naturally complex/long classes in verbose languages.)
But like anything, they can be open to abuse.
It is sad that C/C++ does not support such features as an standard. Most pascal variants and Ada do (almost all Algol-based languages do). Same with JavaScript. Same with modern languages like Scala. Same with venerable languages like Erlang, Lisp or Python.
And just as with C/C++, unfortunately, Java (with which I earn most of my living) does not.
I mention Java here because I see several posters suggesting usage of classes and class' methods as alternatives to nested functions. And that's also the typical workaround in Java.
Short answer: No.
Doing so tend to introduce artificial, needless complexity on a class hierarchy. With all things being equal, the ideal is to have a class hierarchy (and its encompassing namespaces and scopes) representing an actual domain as simple as possible.
Nested functions help deal with "private", within-function complexity. Lacking those facilities, one should try to avoid propagating that "private" complexity out and into one's class model.
In software (and in any engineering discipline), modeling is a matter of trade-offs. Thus, in real life, there will be justified exceptions to those rules (or rather guidelines). Proceed with care, though.
All this tricks just look (more or less) as local functions, but they don't work like that. In a local function you can use local variables of it's super functions. It's kind of semi-globals. Non of these tricks can do that. The closest is the lambda trick from c++0x, but it's closure is bound in definition time, not the use time.
Let me post a solution here for C++03 that I consider the cleanest possible.*
#define DECLARE_LAMBDA(NAME, RETURN_TYPE, FUNCTION) \
struct { RETURN_TYPE operator () FUNCTION } NAME;
...
int main(){
DECLARE_LAMBDA(demoLambda, void, (){
cout<<"I'm a lambda!"<<endl;
});
demoLambda();
DECLARE_LAMBDA(plus, int, (int i, int j){
return i+j;
});
cout << "plus(1,2)=" << plus(1,2) << endl;
return 0;
}
(*) in the C++ world using macros is never considered clean.
But we can declare a function inside main():
int main()
{
void a();
}
Although the syntax is correct, sometimes it can lead to the "Most vexing parse":
#include <iostream>
struct U
{
U() : val(0) {}
U(int val) : val(val) {}
int val;
};
struct V
{
V(U a, U b)
{
std::cout << "V(" << a.val << ", " << b.val << ");\n";
}
~V()
{
std::cout << "~V();\n";
}
};
int main()
{
int five = 5;
V v(U(five), U());
}
=> no program output.
(Only Clang warning after compilation).
C++'s most vexing parse again
Yes, and you can do things with them that even C++20 Lambdas don't support. Namely, pure recursive calls to themselves & related functions.
For example, the Collatz Conjecture is that a certain simple recursive function will ultimately produce "1" for ANY positive integer N. Using an explicit local struct and functions, I can write a single self-contained function to run the test for any "N".
constexpr std::optional<int> testCollatzConjecture(int N) {
struct CollatzCallbacks {
constexpr static int onEven(int n) {
return recurse(n >> 1); // AKA "n/2"
}
constexpr static int onOdd(int n) {
if(n==1) return 1; // Break recursion. n==1 is only possible when n is odd.
return recurse(3 * n + 1);
}
constexpr static int recurse(int n) {
return (n%2) ? onOdd(n) : onEven(n); // (n%2) == 1 when n is odd
}
};
// Error check
if(N < 0) return {};
// Recursive call.
return CollatzCallbacks::recurse(N);
}
Notice some things that even c++20 lambdas couldn't do here:
I didn't need std::function<> glue OR lambda captures ("[&]") just to enable my local recursive functions call themselves, or each other. I needed 3 plain-old-functions with names, and that's all I had to write.
My code is more readable and (due to (1)) will also run much faster.
I cleanly separate the recursive logic in "CollatzCallbacks" from the rest of "testCollatzConjecture". It all runs in an isolated sandbox.
I was able to make everything "constexpr" and state-less, so it can all run at compile time for any constant value. AFAIK I'd need c++23 just to achieve the recursion part with state-less lambdas.
Remember: Lambda functions are really just compiler-generated local structs like "CollatzCallbacks", only they're unnamed and only have a single "operator()" member function. You can always write more complex local structs and functions directly, especially in cases like this where you really need them.
I wonder if it is possible to do this in C ++?
e.g:
varFunction = void TestFunction();
RunCode(varFunction);
With C++11 and higher, you can use the std::function to store function pointers and function objects.
But storing function pointers was available in C++ from the start. This means you can store the address of a function and call it later.
BTW, lambda expressions are also very useful (and the closure they are denoting could be assigned or passed as std::function-s)
Here is an example showing three different ways to achieve what did you asked for:
#include <iostream>
#include <functional>
void RunCode(const std::function<void()>& callable) {
callable();
}
void TestFunction() {
std::cout << "TestFunction is called..." << std::endl;
}
int main() {
std::function<void()> varFunction_1 = TestFunction;
void (*varFunction_2)() = TestFunction;
RunCode(varFunction_1);
RunCode(varFunction_2);
RunCode([]() { std::cout << "TestLambda is called..." << std::endl; });
return 0;
}
But this is just the tip of the iceberg, passing function pointers and function objects as parameters is very common in the algorithms library.
C++ provides several ways to do it.
For example, you can use std::function template: include <functional> and use the following syntax (demo):
std::function<void()> varFunction(TestFunction);
varFunction();
You can also use function pointers (Q&A on the topic).
For the sake of completeness, you can declare a C-style function type as follows:
typedef int (*inttoint)(int);
This creates a type inttoint that can store any function that takes an int as parameter and returns an int. You can use it as follows.
// Define a function
int square(int x) { return x*x; }
// Save the function in sq variable
inttoint sq { square };
// Execute the function
sq(4);
Since C++11, these variables can also store lambda functions, like so
inttoint half { [](int x) { return x/2; } };
And use it same as above.
The easiest way is to use a lambda expression like this:
auto add = [](int a, int b) { return a+b; };
cout << add(10, 20) << endl; // Output: 30
More info about how lambda expressions work: http://en.cppreference.com/w/cpp/language/lambda
I am trying to understand how explicit constructor call in main works using the following code.
#include<iostream>
using namespace std;
class Dependency1
{
bool init;
public:
Dependency1() : init(true) {
std::cout << "Dependency1 construction"
<< std::endl;
}
void print() const {
std::cout << "Dependency1 init: "
<< init << std::endl;
}
};
class Dependency2 {
Dependency1 d1;
public:
Dependency2(const Dependency1& dep1): d1(dep1){
std::cout << "Dependency2 construction ";
print();
}
void print() const { d1.print(); }
};
void test( const Dependency1& dd1)
{
cout << " inside Test \n";
dd1.print();
}
int main()
{
test(Dependency1());
Dependency2 D1(Dependency1()); // this line does not work
return 0;
}
Function test is being called where constructor Dependency1() is used as a function call instead of Dependency1::Dependency1( ) and the code runs perfectly fine.
Now if I use similar concept to create an object D1 of Dependency2, it does not work.
Seems I am doing something wrong here based on wrong understanding.
Need to know how the Compiler resolves Dependency1() call in main even if scope resolution is not used and why it does not work when I use it as a parameter in constructor of Dependency2
Thanks,
Anand
test(Dependency1())
This calls a function test and passes a temporary object of class Dependency1. Because the formal parameter in the definition of test is a reference to const and because temporaries can be bound to const references your code works.
Dependency2 D1(Dependency1()); // this line does not work
This is called C++ most vexing parse. D1 is interpreted as a function returning Dependency2 and taking an argument a pointer to function returning Dependency1.
Try Dependency2 D1((Dependency1())); and see the change in output.
Note: Putting an extra pair of parenthesis would make the compiler treat (Dependency1()) as an expression.
Dependency1() creates a temporary object of type Dependency1, that is passed to function test.
I mean something like:
int main()
{
void a()
{
// code
}
a();
return 0;
}
Modern C++ - Yes with lambdas!
In current versions of c++ (C++11, C++14, and C++17), you can have functions inside functions in the form of a lambda:
int main() {
// This declares a lambda, which can be called just like a function
auto print_message = [](std::string message)
{
std::cout << message << "\n";
};
// Prints "Hello!" 10 times
for(int i = 0; i < 10; i++) {
print_message("Hello!");
}
}
Lambdas can also modify local variables through **capture-by-reference*. With capture-by-reference, the lambda has access to all local variables declared in the lambda's scope. It can modify and change them normally.
int main() {
int i = 0;
// Captures i by reference; increments it by one
auto addOne = [&] () {
i++;
};
while(i < 10) {
addOne(); //Add 1 to i
std::cout << i << "\n";
}
}
C++98 and C++03 - Not directly, but yes with static functions inside local classes
C++ doesn't support that directly.
That said, you can have local classes, and they can have functions (non-static or static), so you can get this to some extend, albeit it's a bit of a kludge:
int main() // it's int, dammit!
{
struct X { // struct's as good as class
static void a()
{
}
};
X::a();
return 0;
}
However, I'd question the praxis. Everyone knows (well, now that you do, anyway :)) C++ doesn't support local functions, so they are used to not having them. They are not used, however, to that kludge. I would spend quite a while on this code to make sure it's really only there to allow local functions. Not good.
For all intents and purposes, C++ supports this via lambdas:1
int main() {
auto f = []() { return 42; };
std::cout << "f() = " << f() << std::endl;
}
Here, f is a lambda object that acts as a local function in main. Captures can be specified to allow the function to access local objects.
Behind the scenes, f is a function object (i.e. an object of a type that provides an operator()). The function object type is created by the compiler based on the lambda.
1 since C++11
Local classes have already been mentioned, but here is a way to let them appear even more as local functions, using an operator() overload and an anonymous class:
int main() {
struct {
unsigned int operator() (unsigned int val) const {
return val<=1 ? 1 : val*(*this)(val-1);
}
} fac;
std::cout << fac(5) << '\n';
}
I don't advise on using this, it's just a funny trick (can do, but imho shouldn't).
2014 Update:
With the rise of C++11 a while back, you can now have local functions whose syntax is a little reminiscient of JavaScript:
auto fac = [] (unsigned int val) {
return val*42;
};
For a recursive function, compile-time type deduction is not supported:
function<int(int)> factorial{ [&](int n)
{
return (n == 1 || n == 0) ? 1 : factorial(n - 1) * n;
} };
You can't have local functions in C++. However, C++11 has lambdas. Lambdas are basically variables that work like functions.
A lambda has the type std::function (actually that's not quite true, but in most cases you can suppose it is). To use this type, you need to #include <functional>. std::function is a template, taking as template argument the return type and the argument types, with the syntax std::function<ReturnType(ArgumentTypes)>. For example, std::function<int(std::string, float)> is a lambda returning an int and taking two arguments, one std::string and one float. The most common one is std::function<void()>, which returns nothing and takes no arguments.
Once a lambda is declared, it is called just like a normal function, using the syntax lambda(arguments).
To define a lambda, use the syntax [captures](arguments){code} (there are other ways of doing it, but I won't mention them here). arguments is what arguments the lambda takes, and code is the code that should be run when the lambda is called. Usually you put [=] or [&] as captures. [=] means that you capture all variables in the scope in which the value is defined by value, which means that they will keep the value that they had when the lambda was declared. [&] means that you capture all variables in the scope by reference, which means that they will always have their current value, but if they are erased from memory the program will crash. Here are some examples:
#include <functional>
#include <iostream>
int main(){
int x = 1;
std::function<void()> lambda1 = [=](){
std::cout << x << std::endl;
};
std::function<void()> lambda2 = [&](){
std::cout << x << std::endl;
};
x = 2;
lambda1(); //Prints 1 since that was the value of x when it was captured and x was captured by value with [=]
lambda2(); //Prints 2 since that's the current value of x and x was captured by reference with [&]
std::function<void()> lambda3 = [](){}, lambda4 = [](){}; //I prefer to initialize these since calling an uninitialized lambda is undefined behavior.
//[](){} is the empty lambda.
{
int y = 3; //y will be deleted from the memory at the end of this scope
lambda3 = [=](){
std::cout << y << endl;
};
lambda4 = [&](){
std::cout << y << endl;
};
}
lambda3(); //Prints 3, since that's the value y had when it was captured
lambda4(); //Causes the program to crash, since y was captured by reference and y doesn't exist anymore.
//This is a bit like if you had a pointer to y which now points nowhere because y has been deleted from the memory.
//This is why you should be careful when capturing by reference.
return 0;
}
You can also capture specific variables by specifying their names. Just specifying their name will capture them by value, specifying their name with a & before will capture them by reference. For example, [=, &foo] will capture all variables by value except foo which will be captured by reference, and [&, foo] will capture all variables by reference except foo which will be captured by value. You can also capture only specific variables, for example [&foo] will capture foo by reference and will capture no other variables. You can also capture no variables at all by using []. If you try to use a variable in a lambda that you didn't capture, it won't compile. Here is an example:
#include <functional>
int main(){
int x = 4, y = 5;
std::function<void(int)> myLambda = [y](int z){
int xSquare = x * x; //Compiler error because x wasn't captured
int ySquare = y * y; //OK because y was captured
int zSquare = z * z; //OK because z is an argument of the lambda
};
return 0;
}
You can't change the value of a variable that was captured by value inside a lambda (variables captured by value have a const type inside the lambda). To do so, you need to capture the variable by reference. Here is an exampmle:
#include <functional>
int main(){
int x = 3, y = 5;
std::function<void()> myLambda = [x, &y](){
x = 2; //Compiler error because x is captured by value and so it's of type const int inside the lambda
y = 2; //OK because y is captured by reference
};
x = 2; //This is of course OK because we're not inside the lambda
return 0;
}
Also, calling uninitialized lambdas is undefined behavior and will usually cause the program to crash. For example, never do this:
std::function<void()> lambda;
lambda(); //Undefined behavior because lambda is uninitialized
Examples
Here is the code for what you wanted to do in your question using lambdas:
#include <functional> //Don't forget this, otherwise you won't be able to use the std::function type
int main(){
std::function<void()> a = [](){
// code
}
a();
return 0;
}
Here is a more advanced example of a lambda:
#include <functional> //For std::function
#include <iostream> //For std::cout
int main(){
int x = 4;
std::function<float(int)> divideByX = [x](int y){
return (float)y / (float)x; //x is a captured variable, y is an argument
}
std::cout << divideByX(3) << std::endl; //Prints 0.75
return 0;
}
No.
What are you trying to do?
workaround:
int main(void)
{
struct foo
{
void operator()() { int a = 1; }
};
foo b;
b(); // call the operator()
}
Starting with C++ 11 you can use proper lambdas. See the other answers for more details.
Old answer: You can, sort-of, but you have to cheat and use a dummy class:
void moo()
{
class dummy
{
public:
static void a() { printf("I'm in a!\n"); }
};
dummy::a();
dummy::a();
}
No, it's not allowed. Neither C nor C++ support this feature by default, however TonyK points out (in the comments) that there are extensions to the GNU C compiler that enable this behavior in C.
You cannot define a free function inside another in C++.
As others have mentioned, you can use nested functions by using the gnu language extensions in gcc. If you (or your project) sticks to the gcc toolchain, your code will be mostly portable across the different architectures targeted by the gcc compiler.
However, if there is a possible requirement that you might need to compile code with a different toolchain, then I'd stay away from such extensions.
I'd also tread with care when using nested functions. They are a beautiful solution for managing the structure of complex, yet cohesive blocks of code (the pieces of which are not meant for external/general use.) They are also very helpful in controlling namespace pollution (a very real concern with naturally complex/long classes in verbose languages.)
But like anything, they can be open to abuse.
It is sad that C/C++ does not support such features as an standard. Most pascal variants and Ada do (almost all Algol-based languages do). Same with JavaScript. Same with modern languages like Scala. Same with venerable languages like Erlang, Lisp or Python.
And just as with C/C++, unfortunately, Java (with which I earn most of my living) does not.
I mention Java here because I see several posters suggesting usage of classes and class' methods as alternatives to nested functions. And that's also the typical workaround in Java.
Short answer: No.
Doing so tend to introduce artificial, needless complexity on a class hierarchy. With all things being equal, the ideal is to have a class hierarchy (and its encompassing namespaces and scopes) representing an actual domain as simple as possible.
Nested functions help deal with "private", within-function complexity. Lacking those facilities, one should try to avoid propagating that "private" complexity out and into one's class model.
In software (and in any engineering discipline), modeling is a matter of trade-offs. Thus, in real life, there will be justified exceptions to those rules (or rather guidelines). Proceed with care, though.
All this tricks just look (more or less) as local functions, but they don't work like that. In a local function you can use local variables of it's super functions. It's kind of semi-globals. Non of these tricks can do that. The closest is the lambda trick from c++0x, but it's closure is bound in definition time, not the use time.
Let me post a solution here for C++03 that I consider the cleanest possible.*
#define DECLARE_LAMBDA(NAME, RETURN_TYPE, FUNCTION) \
struct { RETURN_TYPE operator () FUNCTION } NAME;
...
int main(){
DECLARE_LAMBDA(demoLambda, void, (){
cout<<"I'm a lambda!"<<endl;
});
demoLambda();
DECLARE_LAMBDA(plus, int, (int i, int j){
return i+j;
});
cout << "plus(1,2)=" << plus(1,2) << endl;
return 0;
}
(*) in the C++ world using macros is never considered clean.
But we can declare a function inside main():
int main()
{
void a();
}
Although the syntax is correct, sometimes it can lead to the "Most vexing parse":
#include <iostream>
struct U
{
U() : val(0) {}
U(int val) : val(val) {}
int val;
};
struct V
{
V(U a, U b)
{
std::cout << "V(" << a.val << ", " << b.val << ");\n";
}
~V()
{
std::cout << "~V();\n";
}
};
int main()
{
int five = 5;
V v(U(five), U());
}
=> no program output.
(Only Clang warning after compilation).
C++'s most vexing parse again
Yes, and you can do things with them that even C++20 Lambdas don't support. Namely, pure recursive calls to themselves & related functions.
For example, the Collatz Conjecture is that a certain simple recursive function will ultimately produce "1" for ANY positive integer N. Using an explicit local struct and functions, I can write a single self-contained function to run the test for any "N".
constexpr std::optional<int> testCollatzConjecture(int N) {
struct CollatzCallbacks {
constexpr static int onEven(int n) {
return recurse(n >> 1); // AKA "n/2"
}
constexpr static int onOdd(int n) {
if(n==1) return 1; // Break recursion. n==1 is only possible when n is odd.
return recurse(3 * n + 1);
}
constexpr static int recurse(int n) {
return (n%2) ? onOdd(n) : onEven(n); // (n%2) == 1 when n is odd
}
};
// Error check
if(N < 0) return {};
// Recursive call.
return CollatzCallbacks::recurse(N);
}
Notice some things that even c++20 lambdas couldn't do here:
I didn't need std::function<> glue OR lambda captures ("[&]") just to enable my local recursive functions call themselves, or each other. I needed 3 plain-old-functions with names, and that's all I had to write.
My code is more readable and (due to (1)) will also run much faster.
I cleanly separate the recursive logic in "CollatzCallbacks" from the rest of "testCollatzConjecture". It all runs in an isolated sandbox.
I was able to make everything "constexpr" and state-less, so it can all run at compile time for any constant value. AFAIK I'd need c++23 just to achieve the recursion part with state-less lambdas.
Remember: Lambda functions are really just compiler-generated local structs like "CollatzCallbacks", only they're unnamed and only have a single "operator()" member function. You can always write more complex local structs and functions directly, especially in cases like this where you really need them.