BRIEF SUMMARY
(which I will also put at the top):
(0) Thinking of pointers as addresses is often a good learning tool, and is often the actual implementation for pointers to ordinary data types.
(1) But on many, perhaps most, compilers pointers to functions are not addresses, but are bigger than an address (typically 2x, sometimes more), or are actually pointers to a struct in memory than contains the addresses of function and stuff like a constant pool.
(2) Pointers to data members and pointers to methods are often even stranger.
(3) Legacy x86 code with FAR and NEAR pointer issues
(4) Several examples, most notably the IBM AS/400, with secure "fat pointers".
I am sure you can find more.
DETAIL:
UMMPPHHH!!!!! Many of the answers so far are fairly typical "programmer weenie" answers - but not compiler weenie or hardware weenie. Since I pretend to be a hardware weenie, and often work with compiler weenies, let me throw in my two cents:
On many, probably most, C compilers, a pointer to data of type T
is, in fact, the address of T
.
Fine.
But, even on many of these compilers, certain pointers are NOT addresses. You can tell this by looking at sizeof(ThePointer)
.
For example, pointers to functions are sometimes quite a lot bigger than ordinary addresses. Or, they may involve a level of indirection. This article provides one description, involving the Intel Itanium processor, but I have seen others. Typically, to call a function you must know not only the address of the function code, but also the address of the function's constant pool - a region of memory from which constants are loaded with a single load instruction, rather than the compiler having to generate a 64 bit constant out of several Load Immediate and Shift and OR instructions. So, rather than a single 64 bit address, you need 2 64 bit addresses. Some ABIs (Application Binary Interfaces) move this around as 128 bits, whereas others use a level of indirection, with the function pointer actually being the address of a function descriptor that contains the 2 actual addresses just mentioned. Which is better? Depends on your point of view: performance, code size, and some compatibility issues - often code assumes that a pointer can be cast to a long or a long long, but may also assume that the long long is exactly 64 bits. Such code may not be standards compliant, but nevertheless customers may want it to work.
Many of us have painful memories of the old Intel x86 segmented architecture, with NEAR POINTERs and FAR POINTERS. Thankfully these are nearly extinct by now, so only a quick summary: in 16 bit real mode, the actual linear address was
LinearAddress = SegmentRegister[SegNum].base << 4 + Offset
Whereas in protected mode, it might be
LinearAddress = SegmentRegister[SegNum].base + offset
with the resulting address being checked against a limit set in the segment. Some programs used not really standard C/C++ FAR and NEAR pointer declarations, but many just said *T
--- but there were compiler and linker switches so, for example, code pointers might be near pointers, just a 32 bit offset against whatever is in the CS (Code Segment) register, while the data pointers might be FAR pointers, specifying both a 16 bit segment number and a 32 bit offset for a 48 bit value. Now, both of these quantities are certainly related to the address, but since they aren't the same size, which of them is the address? Moreover, the segments also carried permissions - read-only, read-write, executable - in addition to stuff related to the actual address.
A more interesting example, IMHO, is (or, perhaps, was) the IBM AS/400 family. This computer was one of the first to implement an OS in C++. Pointers on this machime were typically 2X the actual address size - e.g. as this presentation says, 128 bit pointers, but the actual addresses were 48-64 bits, and, again, some extra info, what is called a capability, that provided permissions such as read, write, as well as a limit to prevent buffer overflow. Yes: you can do this compatibly with C/C++ -- and if this were ubiquitous, the Chinese PLA and slavic mafia would not be hacking into so many Western computer systems. But historically most C/C++ programming has neglected security for performance. Most interestingly, the AS400 family allowed the operating system to create secure pointers, that could be given to unprivileged code, but which the unprivileged code could not forge or tamper with. Again, security, and while standards compliant, much sloppy non-standards compliant C/C++ code will not work in such a secure system. Again, there are official standards, and there are de-facto standards.
Now, I'll get off my security soapbox, and mention some other ways in which pointers (of various types) are often not really addresses: Pointers to data members, pointers to member functions methods, and the static versions thereof are bigger than an ordinary address. As this post says:
There are many ways of solving this [problems related to single versus multiple inheitance, and virtual inheritance]. Here's how the Visual Studio compiler decides to handle it: A pointer to a member function of a multiply-inherited class is really a structure."
And they go on to say "Casting a function pointer can change its size!".
As you can probably guess from my pontificating on (in)security, I've been involved in C/C++ hardware/software projects where a pointer was treated more like a capability than a raw address.
I could go on, but I hope you get the idea.
BRIEF SUMMARY
(which I will also put at the top):
(0) thinking of pointers as addresses is often a good learning tool, and is often the actual implementation for pointers to ordinary data types.
(1) But on many, perhaps most, compilers pointers to functions are not addresses, but are bigger than an address (typically 2X, sometimes more), or are actually pointers to a struct in memory than contains the addresses of function and stuff like a constant pool.
(2) Pointers to data members and pointers to methods are often even stranger.
(3) Legacy x86 code with FAR and NEAR pointer issues
(4) Several examples, most notably the IBM AS/400, with secure "fat pointers".
I am sure you can find more.