When you learn C++, or at least when I learned it through C++ Primer, pointers were termed the "memory addresses" of the elements they point to. I'm wondering to what extent this is true.

For example, do two elements *p1 and *p2 have the property p2 = p1 + 1 or p1 = p2 + 1 if and only if they are adjacent in physical memory?

  • 13
    The memory we talk about in program is essentially virtual memory, whose address will be translated by the MMU of the operating system, to the actual physical memory address.
    – Haris
    Dec 29, 2015 at 14:09
  • 8
    Neither C nor C++ have a concept of "physicality". They only have memory, which is some abstract, addressable entity. How this memory is realized in practice depends on the platform and execution environment.
    – Kerrek SB
    Dec 29, 2015 at 14:17
  • 8
    There is no language called C/C++. Please choose at most one of C and C++ for this question.
    – fuz
    Dec 29, 2015 at 14:25
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    How the conditions given for pointers p1 and p2 are contradicting the fact pointers are actually memory addresses? Dec 29, 2015 at 14:27
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    @user5648283: C++ is not a strict superset of C.
    – MikeMB
    Dec 29, 2015 at 15:02

12 Answers 12


You should think of pointers as being addresses of virtual memory: modern consumer operating systems and runtime environments place at least one layer of abstraction between physical memory and what you see as a pointer value.

As for your final statement, you cannot make that assumption, even in a virtual memory address space. Pointer arithmetic is only valid within blocks of contiguous memory such as arrays. And whilst it is permissible (in both C and C++) to assign a pointer to one point past an array (or scalar), the behaviour on deferencing such a pointer is undefined. Hypothesising about adjacency in physical memory in the context of C and C++ is pointless.

  • 2
    Shouldn't pointer arithmetic be correct more generally on contiguous memory and not only on arrays? Dec 29, 2015 at 14:24
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    chance allocation of linked list nodes beside each other(just kidding).. BTW this is a better answer then the highest voted one. +1
    – Haris
    Dec 29, 2015 at 14:28
  • @terencehill: yes I was thinking about this. I don't think it's worth complicating this answer by restricting arithmetic to just arrays. I've reworded. Thank you.
    – Bathsheba
    Dec 29, 2015 at 14:29
  • p1 could be at the end of an mmu block and p2 the beginning of another, so that in virtual space they are adjacent (arrays are not relevant here), but in physical space they can be nowhere near each other. so the posters statement about being adjacent in physical space is just adding to their confusion.
    – old_timer
    Dec 29, 2015 at 14:52
  • 1
    modern consumer operating systems place at least one layer of abstraction. Almost all embedded os's have an option to use a flat memory space.
    – Sam
    Dec 29, 2015 at 20:10

Not at all.

C++ is an abstraction over the code that your computer will perform. We see this abstraction leak in a few places (class member references requiring storage, for example) but in general you will be better off if you code to the abstraction and nothing else.

Pointers are pointers. They point to things. Will they be implemented as memory addresses in reality? Maybe. They could also be optimised out, or (in the case of e.g. pointers-to-members) they could be somewhat more complex than a simple numeric address.

When you start thinking of pointers as integers that map to addresses in memory, you begin to forget for example that it's undefined to hold a pointer to an object that doesn't exist (you can't just increment and decrement a pointer willy nilly to any memory address you like).

  • "you can't just increment and decrement a pointer willy nilly to any memory address you like" - well, you can, it's just not a very good idea.
    – fluffy
    Dec 29, 2015 at 23:41
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    @fluffy: No it's more than "not a very good idea". It has undefined behaviour. So you "can" in the same way that you "can" read destroyed data through dangling pointers, "can" modify a const object using const_cast, and "can" murder a room full of people with a stanley knife. The standard does not allow a well-formed program to do any of those things. It's not just a style thing. Dec 29, 2015 at 23:46
  • Well, yeah, that was my point. It's possible - you can. It's just undefined behavior pretty much most of the time, although not always (such as memory-mapped I/O on embedded systems and the like, like Arduino or old-school real-mode DOS and the like).
    – fluffy
    Dec 29, 2015 at 23:49
  • @fluffy: This question is about what is acceptable in C++, not about what is physically possible on a computer. You can write programs that hack about with memory and take advantage of platform-specific trickery, but that no longer counts as writing C++. Dec 29, 2015 at 23:49

As many answers have already mentioned, they should not be thought of as memory addresses. Check out those answers and here to get an understanding of them. Addressing your last statement

*p1 and *p2 have the property p2 = p1 + 1 or p1 = p2 + 1 if and only if they are adjacent in physical memory

is only correct if p1 and p2 are of the same type, or pointing to types of the same size.

  • 3
    Not exactly. p1 and p2 must point to adjacent elements of the same array. Btw, this is not a property of *p1 and *p2
    – chqrlie
    Dec 29, 2015 at 14:26
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    If p1 and p2 point to different objects of the same type that are not part of the same array, there is no guarantee that p1 == p2 + 1 even if (uintptr_t)p1 == (uintptr_t)(p2 + 1).
    – chqrlie
    Dec 29, 2015 at 14:51
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    Now I change my mind. A pointer is not an address, in general. It may hold no-address ID.
    – haccks
    Dec 29, 2015 at 15:05
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    "It is indeed acceptable to think of pointers as memory addresses" No it's irresponsible. Dec 29, 2015 at 15:23
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    Lol well you're entitled to your opinion. I was just explaining my downvote because I hold a different opinion. Seems a bit weird to summarily invert your answer with all those votes on it? Oh well Dec 29, 2015 at 15:59

Absolutely right to think of pointers as memory addresses. That's what they are in ALL compilers that I have worked with - for a number of different processor architectures, manufactured by a number of different compiler producers.

However, the compiler does some interesting magic, to help you along with the fact that normal memory addresses [in all modern mainstream processors at least] are byte-addresses, and the object your pointer refers to may not be exactly one byte. So if we have T* ptr;, ptr++ will do ((char*)ptr) + sizeof(T); or ptr + n is ((char*)ptr) + n*sizeof(T). This also means that your p1 == p2 + 1 requires p1 and p2 to be of the same type T, since the +1 is actually +sizeof(T)*1.

There is ONE exception to the above "pointers are memory addresses", and that is member function pointers. They are "special", and for now, please just ignore how they are actually implemented, sufficient to say that they are not "just memory addresses".

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    "That's what they are in ALL compilers that I have worked with" You're throwing away the abstraction because all known implementations are the same. Might as well say "references are pointers". Dec 29, 2015 at 15:23
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    @LightnessRacesinOrbit: you seem to forget that many programmers need to think in terms of concrete things. It is difficult enough for most to understand the concept of pointers to throw away simple implementation examples that are easy to manipulate and play with. For most purposes, C++ references are implemented as pointers with implicit dereferencing. The nice feature about references besides the simpler syntax and convenience for operator overloading is the guarantee that they are not null.
    – chqrlie
    Dec 29, 2015 at 17:38
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    @chqrlie: "you seem to forget that many programmers need to think in terms of concrete things" IMO programmers must learn to think in abstractions in order to be effective at writing robust, reliable and reusable code. Thinking in terms of implementation details all the time is a starting point at best, certainly not a desirable end goal. Dec 29, 2015 at 17:40
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    @LightnessRacesinOrbit: I did not say that, I merely indicated that many beginners need concrete examples to grasp some concepts... C is not the best language to learn to program with abstractions. Lisp, OCaml, Prolog, F# are more appropriate for that. Programmers that understand implementation details have strong advantage to learn C concepts, simple ones but still out of reach for so many beginners.
    – chqrlie
    Dec 29, 2015 at 17:48
  • Can I just ask what that abstraction buys us? The possibility to build a compiler that doesn't do that, yes. But in practice, it's still true that compilers do indeed implement pointers as addresses. Not only in C and C++, but also in Pascal, Modula-{2,3} and any other language that I'm aware of that has a concept of pointers. And yes, to me, as a person that tries to understand what the compiler actually does, rather than see it as an opaque shield to defend me against the evils of hardware - as mentioned above, there are plenty of other languages that shield much better. Dec 29, 2015 at 21:20

The operating system provides an abstraction of the physical machine to your program (i.e. your program runs in a virtual machine). Thus, your program does not have access to any physical resource of your computer, be it CPU time, memory, etc; it merely has to ask the OS for these resources.

In the case of memory, your program works in a virtual address space, defined by the operating system. This address space has multiple regions, such as stack, heap, code, etc. The value of your pointers represent addresses in this virtual address space. Indeed, 2 pointers to consecutive addresses will point to consecutive locations in this address space.

However, this address space is splitted by the operating system into pages and segments, which are swapped in and out from memory as required, so your pointers may or may not point to consecutive physical memory locations and is impossible to tell at runtime if that is true or not. This also depends on the policy used by the operating system for paging and segmentation.

Bottom line is that pointers are memory addresses. However, they are addresses in a virtual memory space and it is up to the operating system to decide how this is mapped to the physical memory space.

As far as your program is concerned, this is not an issue. One reason for this abstraction is to make programs believe they are the only users of the machine. Imagine the nightmare you'd have to go through if you would need to consider the memory allocated by other processes when you write your program - you don't even know which processes are going to run concurrently with yours. Also, this is a good technique to enforce security: your process cannot (well, at least shouldn't be able to) access maliciously the memory space of another process since they run in 2 different (virtual) memory spaces.


Like other variables, pointer stores a data which can be an address of memory where other data is stored.

So, pointer is a variable that have an address and may hold an address.

Note that, it is not necessary that a pointer always holds an address. It may hold a non-address ID/handle etc. Therefore, saying pointer as an address is not a wise thing.

Regarding your second question:

Pointer arithmetic is valid for contiguous chunk of memory. If p2 = p1 + 1 and both pointers are of same type then p1 and p2 points to a contiguous chunk of memory. So, the addresses p1 and p2 holds are adjacent to each other.

  • "You can say that pointers are actually memory addresses." I know I can say that, but is it true? Dec 29, 2015 at 14:13
  • 2
    @user5648283: no it is not true, pointers are variables whose values are addresses.
    – chqrlie
    Dec 29, 2015 at 14:29
  • @chqrlie; Every variable has two aspects, when used as lvalue then it act as an address and when used as an rvalue then act as the value at memory address. For pointers, in both cases its a memory address.
    – haccks
    Dec 29, 2015 at 14:31
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    "A variable is named memory location where data is stored" Gross oversimplification. Ignores the entire abstraction and its purpose. Dec 29, 2015 at 15:22
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    @haccks: Right. And the answer is no :) You instead answered "yes" using the rationale "A variable is named memory location where data is stored" which is broken because it's a gross oversimplification that ignores the entire abstraction and its purpose Dec 29, 2015 at 15:59

I think this answer has the right idea but poor terminology. What C pointers provide are the exact opposite of abstraction.

An abstraction provides a mental model that's relatively easy to understand and reason about, even if the hardware is more complex and difficult to understand or harder to reason about.

C pointers are the opposite of that. They take possible difficulties of the hardware into account even when though the real hardware is often simpler and easier to reason about. They limit your reasoning to what's allowed by a union of the most complex parts of the most complex hardware regardless of how simple the hardware at hand may actually be.

C++ pointers add one thing that C doesn't include. It allows comparing all pointers of the same type for order, even if they're not in the same array. This allows a little more of a mental model, even if it doesn't match the hardware perfectly.

  • "the exact opposite of abstraction" is an interesting idea, but I can't wrap my mind around it. When you say "limiting one's reasoning" you're describing just one of key features of abstractions. It doesn't matter whether pointers are simpler than some possible hardware paradigms. What does matter is that what hardware does is always irrelevant - and that's abstraction. I agree that it may be perceived as counter-intuitive when the abstract model is not simpler than one architecture, but it's not the complexity that's being abstracted away - it's the details of all architectures.
    – BartoszKP
    Dec 29, 2015 at 23:09
  • @BartoszKP: Sorry, but I have to disagree. To qualify as an abstraction, it must provide a model that's more, well...abstract. In this case, the model is provides is less abstract than almost any current hardware provides. Just being different from the hardware doesn't make it an abstraction. Dec 30, 2015 at 5:36
  • Ignotum per ignotum ;p I didn't say that it's enough to be different - what I mean is, it's enough making some details irrelevant to qualify for an abstraction.
    – BartoszKP
    Dec 30, 2015 at 9:19
  • @BartoszKP: That's exactly what doesn't happen here though.Rather than making some details irrelevant, it forces one to take into account the union of all the details of all the architectures of which anybody was aware (i.e., essentially everything), regardless of the fact that most of them can't apply in any one case, and virtually none of them apply in most. Dec 30, 2015 at 12:33
  • These are different details, which look the same as the ones you speak of :) This may seem like a subtle game of words, but I think it's meaningful here: the details of the abstract model, perhaps make it more complex, but they allow you to ignore the fact whether corresponding details exist in the underlying architecture and in what configuration. You are not dependent on them whatsoever.
    – BartoszKP
    Dec 30, 2015 at 13:13

Somehow answers here fail to mention one specific family of pointers - that is, pointers-to-members. Those are certainly not memory addresses.

  • Pointers to members. Member pointers are not special by the virtue of being members.
    – SergeyA
    Dec 29, 2015 at 14:33
  • I think this refers to pointer to member functions (which I did cover in my answer) Dec 29, 2015 at 14:39
  • @MatsPetersson, pointers to non-function members are special as well.
    – SergeyA
    Dec 29, 2015 at 14:42
  • Technically, the C++ Standard refers to pointer-to-member operators and pointer to member of T for the specific thing you are referring to, which by the way can be members or not. This is a tad confusing, since one can also have pointer members, and pointers that point to members of a specific instance, both of which are actual pointers (they hold addresses).
    – chqrlie
    Dec 29, 2015 at 14:46

Unless pointers are optimized out by the compiler, they are integers that store memory addresses. Their lenght depends on the machine the code is being compiled for, but they can usually be treated as ints.

In fact, you can check that out by printing the actual number stored on them with printf().

Beware, however, that type * pointer increment/decrement operations are done by the sizeof(type). See for yourself with this code (tested online on Repl.it):

#include <stdio.h>

int main() {
    volatile int i1 = 1337;
    volatile int i2 = 31337;
    volatile double d1 = 1.337;
    volatile double d2 = 31.337;
    volatile int* pi = &i1;
    volatile double* pd = &d1;
    printf("ints: %d, %d\ndoubles: %f, %f\n", i1, i2, d1, d2);
    printf("0x%X = %d\n", pi, *pi);
    printf("0x%X = %d\n", pi-1, *(pi-1));
    printf("Difference: %d\n",(long)(pi)-(long)(pi-1));
    printf("0x%X = %f\n", pd, *pd);
    printf("0x%X = %f\n", pd-1, *(pd-1));
    printf("Difference: %d\n",(long)(pd)-(long)(pd-1));

All variables and pointers were declared volatile so as the compiler wouldn't optimize them out. Also notice that I used decrement, because the variables are placed in the function stack.

The output was:

ints: 1337, 31337
doubles: 1.337000, 31.337000
0xFAFF465C = 1337
0xFAFF4658 = 31337
Difference: 4
0xFAFF4650 = 1.337000
0xFAFF4648 = 31.337000
Difference: 8

Note that this code may not work on all compilers, specially if they do not store variables in the same order. However, what's important is that the pointer values can actually be read and printed and that decrements of one may/will decrement based on the size of the variable the pointer references.

Also note that the & and * are actual operators for reference ("get the memory address of this variable") and dereference ("get the contents of this memory address").

This may also be used for cool tricks like getting the IEEE 754 binary values for floats, by casting the float* as an int*:

#include <iostream>

int main() {
    float f = -9.5;
    int* p = (int*)&f;

    std::cout << "Binary contents:\n";
    int i = sizeof(f)*8;
    while(i) {
        std::cout << ((*p & (1 << i))?1:0);

Result is:

Binary contents:

Example taken from https://pt.wikipedia.org/wiki/IEEE_754. Check out on any converter.

  • Especially as the example exhibits undefined behavior
    – MikeMB
    Dec 29, 2015 at 23:01
  • It was just an example, like "hey, I can see the contents of a memory location as if it were any type I want". Jan 5, 2016 at 12:21

Pointers are memory addresses, but you shouldn't assume they reflect physical address. When you see addresses like 0x00ffb500 those are logical addresses that the MMU will translate to the corresponding physical address. This is the most probable scenario, since virtual memory is the most extended memory management system, but there could be systems that manage physical address directly


The particular example you give:

For example, do two elements *p1 and *p2 have the property p2 = p1 + 1 or p1 = p2 + 1 if and only if they are adjacent in physical memory?

would fail on platforms that do not have a flat address space, such as the PIC. To access physical memory on the PIC, you need both an address and a bank number, but the latter may be derived from extrinsic information such as the particular source file. So, doing arithmetic on pointers from different banks would give unexpected results.


According to the C++14 Standard, [expr.unary.op]/3:

The result of the unary & operator is a pointer to its operand. The operand shall be an lvalue or a qualified-id. If the operand is a qualified-id naming a non-static member m of some class C with type T, the result has type “pointer to member of class C of type T” and is a prvalue designating C::m. Otherwise, if the type of the expression is T, the result has type “pointer to T” and is a prvalue that is the address of the designated object or a pointer to the designated function. [Note: In particular, the address of an object of type “cv T” is “pointer to cv T, with the same cv-qualification. —end note ]

So this says clearly and unambiguously that pointers to object type (i.e. a T *, where T is not a function type) hold addresses.

"address" is defined by [intro.memory]/1:

The memory available to a C++ program consists of one or more sequences of contiguous bytes. Every byte has a unique address.

So an address may be anything which serves to uniquely identify a particular byte of memory.

Note: In the C++ standard terminology, memory only refers to space that is in use. It doesn't mean physical memory, or virtual memory, or anything like that. The memory is a disjoint set of allocations.

It is important to bear in mind that, although one possible way of uniquely identifying each byte in memory is to assign a unique integer to each byte of physical or virtual memory, that is not the only possible way.

To avoid writing non-portable code it is good to avoid assuming that an address is identical to an integer. The rules of arithmetic for pointers are different to the rules of arithmetic for integers anyway. Similarly, we would not say that 5.0f is the same as 1084227584 even though they have identical bit representations in memory (under IEEE754).

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