How c++ compiler understands the pointer type? As I know pointer has a size equal to WORD of the OS (32 or 64). So does it store some info in that 32(or 64) bits about type? Just because you can not have a pointer on one type and assign to that pointer another pointer with a different type.

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    What's "dome info"? – T.J. Crowder Jun 14 '10 at 14:30
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    I think OP meant "some info." Edited. – John Dibling Jun 14 '10 at 14:34
  • Don't confuse compile time and runtime. At compile time all the type information is known and stored within the compiler. At runtime most of the type information has been discarded and is definitely not stored as part of the pointer (the generated code is done specifically for the type it knows is rehire without reference to the type at runtime) – Martin York Jun 14 '10 at 14:41
  • What about objects? Do they have type info runtime? – Narek Jun 14 '10 at 14:53
  • Sort of, some. But it is not generally used at runtime (exception is of course dynamic_cast). The code planted by the compiler is generally specific to a type deduced at compile time. There is some type information available on request but it is bad practice to use it in your code and not usually helpful. Type specific functionality is achieved at the language level via virtual functions and inheritance this functionality at runtime is accessed via method indirection (ie potentially using v-tables to call methods). – Martin York Jun 14 '10 at 16:12

A pointer is usually just a memory address on x86 based architectures (I don't know about other architectures). The compiler enforces type safety with different pointers at compile time - since it makes no sense to assign a pointer-to-char to a pointer-to-int, for example, especially since the objects pointed to are different sizes (so you'd be grabbing random memory if you accessed them). You can explicitly override this and assign any pointer to any other pointer with a reinterpret_cast<T>, or with other types of cast like static_cast<T> and dynamic_cast<T> (the latter two are generally recommended due to being 'safer' but each have their uses).

So at the machine level a memory address is just a memory address and the CPU will dutifully carry out any accesses or calls on that. However it's dangerous, since you can get types mixed up and possibly not know about it. The compile time checks help avoid that, but there is not usually any information about the actual types stored inside the pointer itself at runtime.

An advantage of using iterators (pointer wrappers provided by the STL) is that many implementations have a lot of additional checks which can be enabled at runtime: like checking you're using the right container, that when you compare them they're the same type of iterator, and so on. This is a major reason to use iterators over pointers - but it's not required by the standard, so check your implementation.

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    Use of reinterpret_cast is not unsafe. It's meaning is well defined and if used correctly is perfectly safe. If used incorrectly it is unsafe but the same can be said for anything that is used incorrectly. – Martin York Jun 14 '10 at 14:44
  • Also note there is no requirement for iterators to check that they from the same container when being compared or used in an algorithm and thus provide no more safety than pointers (though certain debug implementations of the STL do provide this functionality to help in debugging, but this functionality should not be relied upon) – Martin York Jun 14 '10 at 14:48
  • Good points, edited to try to clarify. – AshleysBrain Jun 14 '10 at 15:40
  • Historically, "a pointer is a memory address" has been correct. However, on modern OSes, the closest you get is a virtual memory address, and even that is just an implementation detail. – György Andrasek Jun 14 '10 at 15:48
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    @jurily: Unless we go back to 60's its always been a virtual memory address. But this is irrelevant and transparent to any application code (specifically its a hardware detail). – Martin York Jun 14 '10 at 16:08

The compiler knows what type a pointer is because the source code says what type the pointer is:

int* ip;   // ip is a pointer to an int

float* fp; // fp is a pointer to a float

void* vp;  // vp is a pointer to some unknown type; need to cast it to a pointer
           // to an actual type in order to access the pointed-at object
  • +1 And, of course, you can assign a pointer of one type to a pointer of another type, you just have to cast it. – T.J. Crowder Jun 14 '10 at 14:30
  • It's an int! Now it's a float! Now it's an int! Now it's an float! – corsiKa Jun 14 '10 at 14:34
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    @glowcoder: Relax, man. You're two pointers! (juvenile joke from WoW) – John Dibling Jun 14 '10 at 14:35
  • @John: Looked it up, turns out your joke is funny. +1 – Cam Jun 14 '10 at 14:39

As James said, the compiler "knows" what type a pointer is because you tell it.

Less flippantly, however, what happens under the covers (in a grossly-simplified explanation) is that the parser, while reading your code, annotates every significant piece of it with the information it needs to check up on and enforce the rules of the language it is recognizing. So given this example code:

int*    ip;
// do some stuff
double* dp = ip;

The compiler is going to do something like this behind the scenes (again in grossly simplified form):

Hmmm... There's this thing called "ip". I'd better make a note that it's an integer pointer. OK, here's this thing called "dp". I'd better make a note that it's a double pointer. OK, now, he wants to assign ip to dp. But... Hang on! ip is an integer and dp is a double. I can't do that!

...compiler vomit on screen...

The reality is simultaneously far simpler than the above (in that the computer doesn't think anything at all -- it's all very mechanical) and far more complicated (in that I've glossed over about a billion details in that mechanical process).

  • +1. Apologies if my answer sounded flippant; that wasn't my intent. – James McNellis Jun 14 '10 at 14:38
  • I didn't see it as maliciously flippant, just as a bit of a joke response. – JUST MY correct OPINION Jun 14 '10 at 14:56

This is part of the syntactic analysis in translating your source code into machine code. In the simplest examples, you can think of it as checking the types on both sides of an assignment:

dest = source
// make sure that type of source == type of dest

A pointer only holds a memory address, nothing more.

Realize that at the level of assembly (which all C / C++ code is translated to), there isn't really any notion of type the way that there is in a high-level language. ASM instructions all operate on binary values (bytes, words, dwords, etc) without caring too much about whether the program thinks that a given set of bits is an int, a char, or something else.

(Excepting of course for the fact that we have different instructions to operate on integer values vs. floating-point values, but that is not really the point of this discussion.)

So the short answer is that type is completely a compile-time construct and is stored in a symbol table inside the compiler program itself, mapping identifiers to types. In the program being compiled, types do not exist.


size equal to WORD of the OS

CPU word you wanted to say? Best of all do not use word to describe a type as the term is heavily overloaded and depending on reader's background might be easily misunderstood.

Just because you can not have a pointer on one type and assign to that pointer another pointer with a different type.

Depends. Read on: Von Neumann architecture


On modern architectures, there is no runtime information on whether a word of memory is a command, a number, a part of string or a pointer. All this information is lost after compilation is completed (although it may still be available in debug symbols). If a word is used as pointer by compiled code, then it must be a pointer - the CPU will not check for you.

Older, more exotic architectures used to maintain this information at run time. Take a look here: http://wapedia.mobi/en/Burroughs_large_systems?p=2

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