I am trying to understand 64-bit compiling, so I did a little test in C++ Builder:

  int i = 12345;
  int *pi = &i;

  Largeint li = 9223372036854775807;
  Largeint *pli = &li;

When I compile this program as 64 bit, the size of the pointer increases to 8 bytes (64 bits).

What is the advantage of the increased pointer size?

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    A 4-byte pointer can only address ~4GB of memory. That can run out fast in a modern program. – BoBTFish Nov 4 '15 at 8:14
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    The size of a pointer usually just reflects the underlying system. If you're on a 32-bit system, you get 32-bit pointers, and on a 64-bit system you get 64-bit pointers. It really doesn't make sense to have anything else. – Some programmer dude Nov 4 '15 at 8:15
  • Except of course that many 64 bits systems have 32 bits subsystems. That means a 4 GB limit per 32 bit process, but the total system memory can then be much more. – MSalters Nov 4 '15 at 11:56

A pointer can hold the address of a single byte in memory. Based on its size you can calculate the maximum number of different values a given pointer can store.

With a pointer of 4 bytes (32 bits) you are limited to address only 4GB of memory, since:

2^32 = 4294967296

On the other hand, a 8 bytes (64 bit) pointer is able to address a much wider range of 17179869184GB theoretically:

2^64 = 18446744073709551616

This are 16EB (exabytes).

In practice, it is much less than that, because of limitations on most processors and the physical size of the memory etc.

You can read more on this topic here:

  • "With a pointer of 4 bytes (32 bits) you are limited to address only 4GB of memory" good answer. But Why is there this limit ? – İsmail Kocacan Nov 4 '15 at 8:38
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    I added a little explanation on the top of my answer. is it clear now? with 32bits (4bytes) you have "only" 4294967296 possible values. So you can address 4294967296 different bytes in memory, which is 4gb – oo_miguel Nov 4 '15 at 8:41
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    more memory is always nice :), but even with my 8GB a 32bit pointer would be not sufficient. – oo_miguel Nov 4 '15 at 8:54
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    @İsmailKocacan you don't even necessarily need the physical RAM to benefit from this - in any modern OS, all your process memory is virtualised. you can run out of virtual address space long before you run out of physical RAM. For example, by default, a 32-bit application on 32-bit windows can only spawn about 2000 threads - even though each of those only takes around 4 kiB of your RAM, they also take around 1 MiB of your address space. Of course, you don't want 2000 threads anyway, but there are other places to take up address space without requiring RAM (and not just by using a paging file). – Luaan Nov 4 '15 at 10:12
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    @CodesInChaos: That's only if the kernel doesn't claim a virtual address space of its own. You clearly see this on 64 bits OS'es running a 32 bits application, where the virtual address space of the process is the wrong size for the kernel. That means there's only a small interfacing stub in the 32 bits address space, leaving 3.5+ GB for the application. – MSalters Nov 4 '15 at 12:01

Unless you want to go back to the old days of memory paging (remember those 16 bit Z80 machines in the 1980s with 128k RAM), or early DOS expanded memory, then you need more than a 32 bit pointer to address all the available memory on a modern machine.

A 64 bit pointer is a natural (though not a necessary) choice for a 64 bit architecture.

Note that pointers of different types do not have to be the same size: sizeof(double*) does not necessarily have to be the same as sizeof(int*), for example.

  • Z80 and such would have a 16-bit address range. – Mats Petersson Nov 4 '15 at 8:17
  • Amended. I remember those days well; lovingly! – Bathsheba Nov 4 '15 at 8:18
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    @Tonny You mean you never noticed it. That or you never programmed in C++, because the standard implementation for pointers to member functions (using adjustor thunks) means that those pointers can have varying sizes in a single program. Or more classical there were far and near pointers back in the good old days. – Voo Nov 4 '15 at 14:45
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    @Tonny While selectors certainly didn't make for a particularly nice programming model, to the best of my knowledge the correct technical term was still "far pointer" (what else would you call them?). And if you had more than one module you needed far pointers, so yes you would mix them (well use both kinds in one application) if you wanted say use the clipboard. – Voo Nov 4 '15 at 15:30
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    @Tonny Mixing different sized pointers was common in DOS programs that used larger amounts of memory. Note only NEAR vs FAR calls for code, but NEAR vs FAR data segments (not to mention HUGE "segments"). – Brian Knoblauch Nov 4 '15 at 16:05

As explained in the other answers, it is natural to have a pointer type that can uniformly and seamlessly indicate an arbitrary location in the memory.

Now if you have a complicated data structure that uses small objects and pointers between them (like a graph, a tree), the memory taken by the pointers will be doubled when you compile in 64 bits, which is a drawback (and this is probably why you asked the question).

Note that all these data structures (graph, tree, hash map, etc...) can also be implemented in contiguous arrays in memory, and accessed through indices (it is how FORTRAN programmers implement them for instance), and if you know in advance that you have less than 4 billion elements, then you can represent your indices as 32 bit integers, even when you compile in 64 bits mode (this is what I'm doing for a 3D mesh modeling software).

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