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As I know we can create objects in runtime or in compile-time. For example

SomeType object1;
SomeType *object2 = new SomeType;

So I think that in the code here;

int main(){

    cout << "lalalal";
    SomeType object1;

A constructor should be called for object1 and then lalalal should appear at screen. Because compiler is allocating the memory before the program starts. So at what point I'm wrong?

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All objects are created at runtime. The location and semantics of it are what change. –  chris Jan 1 '13 at 21:42
Memory allocation for an object and construction of that object are two different things, and can occur in separate steps. When the memory allocation happens for a function local object is indeterminant, as far as the standard is concerned, but the object's construction happens at the point in the program where you declare it (at runtime). –  Benjamin Lindley Jan 1 '13 at 21:48
@chris: Objects with constexpr constructors and constexpr arguments can be created at compile-time –  K-ballo Jan 1 '13 at 21:54
@BenjaminLindley Not totally independent. Memory allocation must occur before the object is constructed. –  James Kanze Jan 1 '13 at 22:12
@K-ballo, That's a good point. I forgot about that, but it's very useful. –  chris Jan 1 '13 at 23:55

3 Answers 3

up vote 5 down vote accepted

As I know we can create objects in runtime or in compile-time.

Not really. In your code example, the first object is created with automatic storage duration (often described as "on the stack"), and the second with allocated dynamic storage duration (often described as "on the heap"). But these both happen at runtime.

A constructor should be called for object1 and then lalalal should appear at screen.

Statements in functions are executed from top-to-bottom (not including loops, obviously). So the object is created second.*

Because compiler is allocating the memory before the program starts.

Yes, it's possible that the memory is allocated ahead of time. But as far as observable effects are concerned, that's irrelevant.

* However, as you haven't included a newline character in your string, what you may be seeing is the effect of line-buffering; on many systems, output isn't displayed until newline characters are received, or until the program terminates.

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It's not allocated storage duration, but dynamic storage duration. And storage duration is not necessarily the same as object lifetime. In this case, the compiler can extend the storage duration of object1 as much as it wants, but the object lifetime must start at the definition, and end when the variable goes out of scope. –  James Kanze Jan 1 '13 at 22:09
And I don't understand your note. C++ doesn't have the concept of line buffered, so newlines in the output have absolutely no effect on when data is flushed. –  James Kanze Jan 1 '13 at 22:11
@JamesKanze: oh, maybe the terminology has changed between C and C++. And yes, you may be correct about iostreams. (This is very much a C answer ;)). An edit may occur shortly... –  Oliver Charlesworth Jan 1 '13 at 22:18
The C standard only talks about automatic and static storage duration, which make one wonder what the storage duration of an object created with malloc is. C++ talks about automatic, static and dynamic storage duration (which makes one wonder about the storage duration of temporaries or exceptions). –  James Kanze Jan 1 '13 at 22:31
@JamesKanze: Ok, you're right about the terminology (but note that C99 6.2.4 says "There are three storage durations: static, automatic, and allocated.") But a quick test has demonstrated that line-buffering can still apply to C++ iostreams. –  Oliver Charlesworth Jan 1 '13 at 22:31

No, object1 in your example is not 'created' at compile time, it is created in runtime just like the other object. Moreover, object1 is 'constructed' after the cout command is executed, and therefore the constructor of it is executed afterwards. The memory for it might have been allocated before that though.

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First, there are two separate concepts in C++: storage duration, and object lifetime. And while the storage duration cannot be shorter than the object lifetime, the reverse is not necessarily true. And second, both are runtime concepts, not compile time.

In this case, however, there is no real difference. Both the storage duration and the lifetime of the object object1 start when the definition is executed, and end when it goes out of scope. Most compiler will, in fact, allocate all of the memory for local variables at the top of the function, but only because there is no way a conforming program can tell that it wasn't allocated at the definition. Anything which affects the observable behavior of the program, however, must occur when the standard says it should occur.

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