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what's difference between

int i=0; 

and

int i(0);

int *p=new int; 

and

int *p=new int(0);

is int *p=new int is still copy initial style?

when to use int i=0; not new int(0)?

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closed as not a real question by 0x499602D2, luser droog, Nemo, Yogesh Suthar, Yan Sklyarenko Mar 12 '13 at 7:54

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3  
Your last question suggests you need to read about memory management in C++. –  Nemo Mar 12 '13 at 2:02

4 Answers 4

up vote 5 down vote accepted

I'm going to answer a slightly different question first.

Suppose you have a class or struct (they are pretty much the same) that looks like this:

struct Foo {
  int value; // Foo stores an int, called value
  Foo(int v):value(v) {}; // Foo can be constructed (created) from an int
  explicit Foo(double d):value(d) {}; // Foo can be constructed (created) from a double
  // ^^^ note that keyword.  It says that it can only be EXPLICITLY created from a double
};

now, this is much like an int, but there are a few differences.

Foo i = 0;

the above creates an int literal, then constructs Foo i with it using the Foo(int v) constructor.

Foo i(0);

the above creates an int literal, then constructs Foo i with it using the Foo(int v) constructor. Note that I just repeated myself.

Foo i = Foo(0);

the above creates an int literal, then constructs Foo i with it using the Foo(int v) constructor, then copy-constructs Foo i from it. However, the standard allows the compiler to "elide" (skip) the copy constructor, and instead just construct Foo i directly from the int literal 0.

Foo* i = new Foo;

this goes to the free store (typically implemented and called the heap), gets ahold of enough memory to store a Foo, then default constructs it. It then returns the address of this Foo object, which is then used to initialize the pointer Foo* i. Now, note that the default constructor of Foo leaves value uninitialized. This is a flaw in my implementation of Foo above (in my opinion), and except in special cases you will rarely want to do this.

Annoyingly, integer (char, int, long, unsigned char, etc), floating point (double or float) literals, and pointer literals all share this property -- by default, they are not initialized to any value.

So you should make sure they are explicitly initialized. In the case of Foo, adding a line:

Foo():value() {}

is enough to do it.

Foo* i = new Foo(0);

this goes to the free store (typically implemented and called the heap), gets ahold of enough memory to store a Foo, then constructs it with the integer literal 0. It then returns the address of this Foo object, which is then used to initialize the pointer Foo* i.

Now, memory in the free store generally stays reserved for your use once you ask for it until you get around to returning it, or your program shuts down. In order to return it, you call delete on the same pointer, which both cases the object (Foo in this case) to have its destructor called (Foo has no destructor, so this is skipped), and then the memory is handed back to the free store to be used by a later call to new.

Keeping track of this is a real pain, and a source of a whole bunch of errors, so you should avoid calling new. There are many ways to avoid calling new, including using std::vector to manage blocks of memory, or using shared_ptr and make_shared to create objects on the heap which manage their own lifetime via a technique known as RAII, or using unique_ptr when you want close control over the lifetime of a pointer (sadly, make_unique doesn't exist).

Now lets go further.

Foo i = 0.0;

This fails to compile. I said that the constructor for Foo(double) is explicit, and the above only chooses to call constructors that are non-explicit. On the other hand:

Foo i(0.0);
Foo i = Foo(0.0);

these both are willing to call explicit constructors, and work fine.

Next, C++11 brings us uniform initialization. Instead of putting what you want to initialize something with in (), you put it in {} -- a squiggly brace.

Foo i{0.0};
Foo i = {0};

etc. {} has a few differences compared to () based syntax -- most importantly it avoids most vexing parse problems. Other differences include initializer list behavior, dealing with explicitly trivially constructing something (int x() does not construct an int named x, but int x{} does).

Speaking of which, time to get back to your actual question.

int is different than my struct Foo in a few ways.

First, it is not a class or a struct. So its behavior instead of being determined by some code you write, is instead described extensively by the standard. As it happens, C++ tries to have primitive types like int behave a lot like a simple user defined type like Foo, which is useful.

So while no "copy constructor" is called, and int has no constructors nor destructors at all, int almost exactly behaves "as if" there where such constructors.

int i = 0;

creates the integer literal 0, then initializes int i with it. The compiler may elide this, and simply create the integer int i with the value 0 directly. For int, there is no way to observe the difference directly.

int i(0);

is identical to int i = 0, because int has no non-explicit constructors. It is just a different syntax.

Now, there is the problem of the most vexing parse. If you typed

int i = int();

you'd get the same as int i = 0, but if you typed

int i();

what would happen is that the compiler would say "that could be a function named i with takes zero arguments and returns int", and for various annoying reasons prefers that interpretation to a default-initialized int. So you get a forward-declared function named i instead of an integer.

As mentioned earlier, the way to avoid this is to always use this syntax:

int i{};

in C++11 compilers.

Next, we have

int* p = new int;

which creates a default constructed (uninitialized) int on the free store, and assigns a pointer to it to the variable int *p. A copy has occurred, but it is a copy of a pointer, not the int.

int *p=new int(0);

is much the same, but the free store int created has the value 0 instead of being uninitialized.

In both these cases, you are responsible for calling delete once and only once on the value returned by new. Failure to do so is known as a memory leak. Using the pointer value after you have done so results in undefined behavior, and typically memory corruption. You almost certainly won't be warned by the program that what you did is dangerous, but your program can now do utterly random things that make no sense and still be a valid C++ program. Aligning each new with exactly one delete, and making sure that nobody uses pointers after the delete, and calling delete as early as possible, is an annoying enough program that entire categories of programming languages have been developed whose main selling feature is that they free developers from having to deal with it.

So avoid calling new.

Oh, and because this isn't long enough, note that my use of the "most vexing parse" above is not quite right. The "most vexing parse" is actually:

int x(int());

rather than

int x();

because the first could be either a constructor call or a function, while the second cannot be a constructor call because the standard doesn't allow it.

However, I and most other people find the parsing rules that make int x();, so call it the penultimate vexing parse, and you won't be far wrong. It still doesn't do what you would naively think it should do (create a default constructed x), so it is plenty vexing.

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int i=0; 
int i(0);

these are the same, with two different initialization syntaxes (C-like the first, constructor-style the second); in line of principle they are slightly different when dealing with classes (the first one implies a - potentially elided - call to a copy constructor, the second doesn't), but for ints they are effectively the same.

int *p=new int; 
int *p=new int(0);

In the first one the int is not initialized (it will have whatever value happens to be at that memory location); in the second case, the int is initialized to 0.

But most importantly, these are two completely different beasts in respect to the first ones. You are not declaring an automatic variables of type int, but pointers to int, which point to two dynamically allocated ints.

The difference is deep: with int i=0 the memory is managed automatically (it has automatic storage duration), and the variable is destroyed when it goes out of scope; with new you allocate memory from the freestore (the so-called heap), which doesn't have an automatic deallocation method - you have to free it explicitly (with delete, although in modern C++ smart pointers are normally used to automatically manage the lifetime of dynamic objects).

new is normally used exactly for the cases of when automatic storage duration isn't a good choice (e.g. you want those ints to outlive the current scope, or be shared between several objects or whatever) or when you are allocating stuff that is too big to stay in a local variable (in typical implementation local variables go on the stack, which is limited in size; still, for two ints that's not a valid concern).

For "regular", local int variables that have to "die" with the current scope new usually isn't a good idea.

Still, for more information about dynamic allocation you should check your C++ book.

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If we're being pedantic, it will have whatever value happens to be at that memory location isn't strictly correct; it can't be known what value uninitialised variables have since it's implementation-specific. –  Seth Carnegie Mar 12 '13 at 4:12

in C and early C++ you could only use int i=0;

The int i(0); pattern is the same as a constructor for a general type

T i(0);

So it was added as an alternative to int i=0; which does not look like a general constructor pattern. This is useful when templates are used. So the template can use int as well as classes.

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new implies heap memory allocation (which can leak), so no, you don't want to be doing it all the time.

int i=0; and int i(0); are equivalent, but depending on the implementation the first may use an assignment operator while the second may be constructed with a value. This can let the compiler optimize for the target architecture. In the case of a class, the assignment method is probably slower since it will create a class (usually with default values) and then it will go through an assignment and wipe out all those default values it just spent time assigning.

Someone may chime in and reference the language spec for a more accurate answer.

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2  
This is incorrect. In C++, Foo f = 0; calls the constructor for Foo. If the relevant constructor(s) are marked explicit, the code fails to compile. Under no circumstances, regardless of the implementation, does it invoke the assignment operator for Foo. –  Nemo Mar 12 '13 at 2:00

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