I understand that hardware will limit the amount of memory allocated during program execution. However, my question is without regard to hardware. Assuming that there was no limit to the amount of memory, would there be no limit to the array?

  • 2
    Actually software (OS) is the thing that will normally cause the memory limit seen by your C program. – TJD Feb 21 '12 at 23:33
  • 2
    Without a limit on memory, there is no limit on the pointer size. Without a limit on pointer size, all bets are off. – dasblinkenlight Feb 21 '12 at 23:34
  • 4
    it would be limited by the size of the pointer (32 bit versus 64 bit) – Mitch Wheat Feb 21 '12 at 23:34

There is no fixed limit to the size of an array in C.

The size of any single object, including of any array object, is limited by SIZE_MAX, the maximum value of type size_t, which is the result of the sizeof operator. (It's not entirely clear whether the C standard permits objects larger than SIZE_MAX bytes, but in practice such objects are not supported; see footnote.) Since SIZE_MAX is determined by the implementation, and cannot be modified by any program, that imposes an upper bound of SIZE_MAX bytes for any single object. (That's an upper bound, not a least upper bound; implementations may, and typically do, impose smaller limits.)

The width of the type void*, a generic pointer type, imposes an upper bound on the total size of all objects in an executing program (which may be larger than the maximum size of a single object).

The C standard imposes lower bounds, but not upper bounds, on these fixed sizes. No conforming C implementation can support infinite-sized objects, but it can in principle support objects of any finite size. Upper bounds are imposed by individual C implementations, by the environments in which they operate, and by physics, not by the language.

For example, a conforming implementation could have SIZE_MAX equal to 21024-1, which means it could in principle have objects up to 179769313486231590772930519078902473361797697894230657273430081157732675805500963132708477322407536021120113879871393357658789768814416622492847430639474124377767893424865485276302219601246094119453082952085005768838150682342462881473913110540827237163350510684586298239947245938479716304835356329624224137215 bytes.

Good luck finding hardware that actually supports such objects.

Footnote: There is no explicit rule that no object can be bigger than SIZE_MAX bytes. You couldn't usefully apply the sizeof operator to such an object, but like any other operator, sizeof can overflow; that doesn't mean you couldn't perform operations on such an object. But in practice, any sane implementation will make size_t big enough to represent the size of any object it supports.

  • 1
    @J.C.Leitão: In principle, I suppose a compiler could use an arbitrary precision library to implement very wide integer types. But you can't do that as a programmer; actual integer types (with literals, operators, and so forth) are limited to what the compiler provides. – Keith Thompson Nov 28 '12 at 6:08
  • 1
    does the existence of far pointers and the correspoing memory model change your answer in any way? – jfs Feb 17 '14 at 19:05
  • 1
    @caot: Your array is defined inside a function without the static keyword, so it has automatic storage duration. On most implementations, such objects are allocated on the stack. It's likely your system limits the size of the stack. Use static, or define it globally, or use malloc(). – Keith Thompson Apr 1 '17 at 0:03
  • 1
    @M.M: There's nothing in the standard that forbids objects bigger than SIZE_MAX bytes, but in practice any reasonable implementation that can support objects bigger than, say, 2**32 bytes will make size_t wider than 32 bits. An implementation that lets you define such large objects but doesn't bother to make size_t big enough to hold their size might be conforming, but it would be perverse. – Keith Thompson Apr 1 '17 at 0:06
  • 1
    Some implementations, like gcc, only support objects of half the pointer width or smaller, i.e. PTRDIFF_MAX bytes. This lets gcc implement pointer subtraction without keeping the carry-out from the integer sub of the pointers before scaling by the type width. But you can write a program where malloc succeeds for a size larger than that.. At least there's a warning when it's known at compile time. You (unintentionally?) imply that objects of SIZE_MAX should be supported. – Peter Cordes Mar 22 '18 at 15:14

C99 "Translation limits" minimal size

The implementation shall be able to translate and execute at least one program that contains at least one instance of every one of the following limits: 13)

  • 65535 bytes in an object (in a hosted environment only)

13) Implementations should avoid imposing fixed translation limits whenever possible.

This suggests that a conforming implementation could refuse to compile an object (which includes arrays) with more than short bytes.

PTRDIFF_MAX seems to be a practical limit for static array objects

The C99 standard 6.5.6 Additive operators says:

9 When two pointers are subtracted, both shall point to elements of the same array object, or one past the last element of the array object; the result is the difference of the subscripts of the two array elements. The size of the result is implementation-defined, and its type (a signed integer type) is ptrdiff_t defined in the <stddef.h> header. If the result is not representable in an object of that type, the behavior is undefined.

Which implies to me that arrays larger than ptrdiff_t are allowed in theory, but then you cannot take the difference of their addresses portabibly.

So perhaps for this reason, GCC just seems to limit you to ptrdiff_t. This is also mentioned at: Why is the maximum size of an array "too large"?

I have empirically verified this with main.c:

#include <stdint.h>

uint8_t a[(X)];

int main(void) {
    return 0;

and then in Ubunbu 17.10:

$ arm-linux-gnueabi-gcc --version
arm-linux-gnueabi-gcc (Ubuntu/Linaro 7.2.0-6ubuntu1) 7.2.0
Copyright (C) 2017 Free Software Foundation, Inc.
This is free software; see the source for copying conditions.  There is NO

$ printf '
> #include <stdint.h>
> ' | arm-linux-gnueabi-cpp | tail -n2
$ PTRDIFF_MAX == 2147483647 == 2^31 - 1
$ # 2lu << 30 == 2^31 == PTRDIFF_MAX + 1
$ arm-linux-gnueabi-gcc -std=c99 -DX='(2lu << 30)' main.c
a.c:5:9: error: size of array ‘a’ is too large
 uint8_t a[(X)];
$ arm-linux-gnueabi-gcc -std=c99 -DX='(2lu << 30) - 1lu' main.c

See also

  • gcc doesn't support dynamic arrays larger than half the pointer width either. Note that pointer-subtraction results are scaled by the object size, so in theory a 3GiB array of int on an ILP32 target should work, and end - start should give 3 * 1024**3 / 4, calculated without overflow, because the C standard says it's not UB if final result is representable. But gcc emits code that does subtraction with pointer width and then arithmetic right-shifts that, losing the carry-out from the subtraction. godbolt.org/g/NG6zZ6. – Peter Cordes Mar 22 '18 at 14:35
  • I tested with -m32 and got -536870896 (pointer subtraction) vs. 536870928 (manual). Glibc malloc did succeed for an allocation of 2GiB + 16, on in 32-bit user-space on x86 (under a 64-bit kernel). It failed for a 3GiB allocation, though. Anyway, apparently this is "not a bug", because gcc considers PTRDIFF_MAX the max object size: developers.redhat.com/blog/2017/02/22/…. -Walloc-size-larger-than=PTRDIFF_MAX is enabled by -Wall, and I got that warning while compiling my test program. – Peter Cordes Mar 22 '18 at 14:37
  • In fact there's already a (closed-invalid) gcc bug confirming that this is really how gcc works: gcc.gnu.org/bugzilla/show_bug.cgi?id=45779 – Peter Cordes Mar 22 '18 at 14:49

A 64-bit machine could theoretically address a maximum of 2^64 bytes of memory.

  • Good luck putting that amount of memory into a computer. Even with Moore's law that's a long time coming. – Mark Ransom Feb 21 '12 at 23:48
  • 1
    @AmigableClarkKant The entire earth is composed of less than 2^64 atoms (it weights only about 5*10^24 kg), so your expectations are very very overoptimistic. SCNR. – Durandal Mar 22 '13 at 15:14
  • 5
    @Durandal, wolframalpha.com/input/?i=number+of+atoms+in+the+earth says there are 1x10^50 atoms in the earth and 2^64 is 1*10^25. I am maybe overoptimistic though. :) Did not think this through... – Prof. Falken Mar 22 '13 at 15:46
  • 4
    @Durandal - I know you made this comment 2 years ago, but 2^64 bytes is only 16 exabytes, which is "only" 2^30 16GB RAM modules (or approximately 1 billion). Assuming a single RAM stick weighs about 10 grams with a capacity of 16GB then that's approximately 10,000 tonnes of RAM, which not a particularly notable part of Earth's mass -- you could fit it, and the required computing infrastructure, in a single extremely expensive data center. – Chris May 21 '15 at 6:51
  • 1
    @ChrisYoung Good thinking, a bit of looking revealed that current supercomputer clusters have in the order of dozens to hundreds of TB RAM. Scale one of those babies up by a factor of around a million and it would have in the region of 16EB RAM - certainly expensive, but plausibly possible with todays technology. It'll probably be approximately the size of a not so small city, so your assesment of "not a notable portion of earth's mass" would hold even if one includes all the necessary infrastructure around it (which I didn't originally anyway, I think). – Durandal May 21 '15 at 19:33

Without regard for memory, the maximum size of an array is limited by the type of integer used to index the array.

  • When an expression that has integer type is added to or subtracted from a pointer, the result has the type of the pointer operand (C11 n1570, section 6.5.6 Additive operators). So using an integer type wider than a pointer isn't allowed to give you access to more memory than you could access otherwise. (Recall that arr[idx] is exactly equivalent to *((arr) + (idx)), and that's in fact how the C standard defines the [] array subscript operator.) Anyway, that's a limit that all C implementations share, but in practice implementations have smaller limits, like PTRDIFF_MAX for gcc. – Peter Cordes Mar 22 '18 at 15:08

I guess the biggest theoretical array would be the max value of "unsigned long" (or whatever the biggest integer number the latest standard / your compiler supports)

  • Not if that's wider than a pointer. (e.g. long long on an implementation with 32-bit pointers). – Peter Cordes Mar 22 '18 at 15:10

The size of the pointer will limit the memory you are able to access. Even if the hardware offers support for unlimited memory, if the largest datatype you are able to use is 64 bit, you'll only be able to access 2^64 bytes of memory.


I was looking for a way to determine the maximum size for an array. This question seems to ask the same, so I want to share my findings.

Initially, C does not provide any function to determine the maximum number of elements allocable in an array in compilation time. This is because it will depend of the memory of available in the machine where it will be executed.

On the other hand, I have found, that memory allocation functions (calloc() and malloc()) enable to allocate larger arrays. Moreover, these functions allows you to handle runtime memory allocation errors.

Hope that helps.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.