I've often used pointers to const objects, like so...

const int *p;

That simply means that you can't change the integer that p is pointing at through p. But I've also seen reference to const pointers, declared like this...

int* const p;

As I understand it, that means that the pointer variable itself is constant -- you can change the integer it points at all day long, but you can't make it point at something else.

What possible use would that have?

11 Answers 11


When you're designing C programs for embedded systems, or special purpose programs that need to refer to the same memory (multi-processor applications sharing memory) then you need constant pointers.

For instance, I have a 32 bit MIPs processor that has a little LCD attached to it. I have to write my LCD data to a specific port in memory, which then gets sent to the LCD controller.

I could #define that number, but then I also have to cast it as a pointer, and the C compiler doesn't have as many options when I do that.

Further, I might need it to be volatile, which can also be cast, but it's easier and clearer to use the syntax provided - a const pointer to a volatile memory location.

For PC programs, an example would be: If you design DOS VGA games (there are tutorials online which are fun to go through to learn basic low level graphics) then you need to write to the VGA memory, which might be referenced as an offset from a const pointer.


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    Minor nitpick: for memory mapped devices you certainly (not 'might') need to have the item marked as volatile - otherwise you couldn't be sure if or when the compiler would actually emit the read or write operation. – Michael Burr Oct 20 '08 at 21:46
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    You 'might' need volatile is correct. You can use barrier() and other semantics depending on the device. It is true that you need to handle the values carefully. Ie, cache/no-cache, barrier, etc. It depends on the type of device and volatile is not always the best option. – artless noise Feb 15 '13 at 16:12
  • @MichaelBurr: I agree with you that the volatile should certainly be in there; on the other hand, many compiler vendors' headers don't seem to bother--a fact which can be somewhat annoying (since even if the compilers usually do the right thing, they may ignore attempts to read a register but do nothing with the result). – supercat Apr 12 '13 at 21:59

It allows you to protect the pointer from being changed. This means you can protect assumptions you make based on the pointer never changing or from unintentional modification, for example:

int* const p = &i;


p++;     /* Compiler error, oops you meant */
(*p)++;  /* Increment the number */
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    I have never seen that before and I agree that it is a very useful trick. – Rob Oct 20 '08 at 21:30
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    It's not a trick :). I try to use const where possible with function arguments so that it is clear that the function won't modify the string or structure being passed in. – Andrew Johnson Oct 20 '08 at 21:35
  • The confusing thing is that const often appears twice in a declaration, and it may actually be in a few different positions. Commonly it might appear as something like const uint8 *const value. This declares that the pointer and the value it points to are not modifiable (but can be if casted). – James Wald Jun 7 '14 at 8:52

another example: if you know where it was initialized, you can avoid future NULL checks. The compiler guarantees you that the pointer never changed (to NULL)…

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    In C. In C++, in your particular case (i.e. non-NULL pointers), you use references instead. – paercebal Oct 21 '08 at 9:29

In any non-const C++ member function, the this pointer is of type C * const, where C is the class type -- you can change what it points to (i.e. its members), but you can't change it to point to a different instance of a C. For const member functions, this is of type const C * const. There are also (rarely encountered) volatile and const volatile member functions, for which this also has the volatile qualifier.


One use is in low-level (device driver or embedded) code where you need to reference a specific address that's mapped to an input/output device like a hardware pin. Some languages allow you to link variables at specific addresses (e.g. Ada has use at). In C the most idiomatic way to do this is to declare a constant pointer. Note that such usages should also have the volatile qualifier.

Other times it's just defensive coding. If you have a pointer that shouldn't change it's wise to declare it such that it cannot change. This will allow the compiler (and lint tools) to detect erroneous attempts to modify it.


I've always used them when I wanted to avoid unintended modification to the pointer (such as pointer arithmetic, or inside a function). You can also use them for Singleton patterns.

'this' is a hardcoded constant pointer.


Same as a "const int" ... if the compiler knows it's not going to change, it can be optimization assumptions based on that.

struct MyClass
    char* const ptr;
    MyClass(char* str) :ptr(str) {}

    void SomeFunc(MyOtherClass moc)
         for(int i=0; i < 100; ++i)
                 printf("%c", ptr[i]);

Now, the compiler could do quite a bit to optimize that loop --- provided it knows that SomeOtherFunc() does not change the value of ptr. With the const, the compiler knows that, and can make the assumptions. Without it, the compiler has to assume that SomeOtherFunc will change ptr.

  • Won't SomeOtherFunc have to be declared with a const pointer argument for this to compile? And won't that also be how the compiler would know that SomeOtherFunc won't change the pointer? So declaring the local pointer as const doesn't seem to help. – Andrew Johnson Oct 20 '08 at 21:38
  • Andrew: I think you're confusing ptr with this – Leon Timmermans Oct 20 '08 at 22:46
  • @Andrew: No. SomeOtherFunc is completely allowed to change any other part of MyClass object. – James Curran Oct 21 '08 at 11:04
  • How does const matter for optimisation? Any clever compiler can determine whether you modify a variable, and optimise if it can based on that, whether or not you said you would. – underscore_d May 23 '17 at 10:27
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    @underscore_d 1) ptr is a public member. It's very hard for a compiler to track the usage of a public variable across modules. Many won't even try, and will just treat it as a volatile 2) Compilers were dumber 9 years ago. – James Curran May 23 '17 at 13:36

I have seen some OLE code where you there was an object passed in from outside the code and to work with it, you had to access the specific memory that it passed in. So we used const pointers to make sure that functions always manipulated the values than came in through the OLE interface.


Several good reasons have been given as answers to this questions (memory-mapped devices and just plain old defensive coding), but I'd be willing to bet that most instances where you see this it's actually an error and that the intent was to have to item be a pointer-to-const.

I certainly have no data to back up this hunch, but I'd still make the bet.

  • i use it a lot for optimization. – DavidG Oct 21 '08 at 17:44
  • @DavidG How, precisely, does const matter for optimisation? Any clever compiler can determine whether you modify a variable, and optimise if it can based on that, whether or not you said you would. – underscore_d May 23 '17 at 10:24
  • it did back in 2008 on some devices when I wrote this comment... but the world has changed a lot since then, and now compilers have improved a lot. – DavidG May 24 '17 at 11:31

Think of type* and const type* as types themselves. Then, you can see why you might want to have a const of those types.

  • yeah, and that type is basically an int. – DavidG Oct 21 '08 at 17:45

always think of a pointer as an int. this means that

object* var;

actually can be thought of as

int var;

so, a const pointer simply means that:

const object* var;


const int var;

and hence u can't change the address that the pointer points too, and thats all. To prevent data change, u must make it a pointer to a const object.

  • Pointers are not ints, in multiple ways. Also, the question is very clearly stated as being about const pointers, not pointers to const objects. But you got them the wrong way around anyway. – underscore_d May 23 '17 at 10:26

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