I am reading article about size_t in C/C++ http://web.archive.org/web/20081006073410/http://www.embedded.com/columns/programmingpointers/200900195 (link found through Stackoverflow).

Quote from the article:

Type size_t is a typedef that's an alias for some unsigned integer type, typically unsigned int or unsigned long, but possibly even unsigned long long. Each Standard C implementation is supposed to choose the unsigned integer that's big enough--but no bigger than needed--to represent the size of the largest possible object on the target platform.

How can I determine the the size of the largest possible object on my machine ?

What affect the size of the largest object (aside from the processor) ?

Link on detailed explanation are welcomed.

  • 1
    The processor does not directly affect this, other than to say that its architecture will place limits on what can theoretically be addressed. But what actually can be addressed on your machine will be determined by your total available contiguous memory. – paddy Aug 18 '13 at 22:33
  • @paddy: I have an embedded system 16k on chip SRAM at one address space, 2Mb SRAM in another address space (not contiguous with the on-chip memory) and 128k of MRAM in another address space. So, what is my total contiguous memory? Can it all be addressed even though it is not contiguous? I also have Flash in another memory address space, not to mention FPGA registers in another address space. – Thomas Matthews Aug 18 '13 at 22:46

Edit: I think it's important to consider that this type doesn't strictly mean that you CAN have an object of that size - just that it's an integer that is LARGE ENOUGH to hold the size of the largest possible object - that doesn't mean that you can use SIZE_MAX to allocate memory. It just guarantees that the largest possible object can not be LARGER than SIZE_MAX.

This is an architectural decision by the implementation of the compiler (typically in turn based on the OS that the compiler is targetting, but the OS could offer MORE than the compiler does, or the compiler could support a theoretical amount that is more than the OS allows, just that it will fail when you ask for it).

In practical terms, it is nearly always the processor that determines this - size_t nearly always matches the bitness of the processor - e.g. it's 32 bits in a 32-bit processor, and 64 bits in a 64-bit processor. But it would be possible to design a system where it is 32-bits on a 64-bit processor - one "object" can't be bigger than 4GB isn't that big a limitation, really. It just means that you can't use one single vector of int to fill more than 4GB, so no more than 1G entries in the vector (or 4G char entries).

Of course, the other limiting factor is available memory - if you have a very old machine with 256MB of RAM, it's not going to allow you to allocate 4GB, even if the size_t allows it. But give the same machine more memory, and you can go to a much larger size.

On many 32-bit systems, the maximum memory allowed for an application is less than 4GB (the full 32-bit range), because some portion of memory is "reserved" for other uses. So again, the size_t is 32 bits, so would allow 4GB, but it doesn't actually support the full amount of memory to be used by a single application - on the other hand, a 32-bit machine could have more than 4GB of RAM, and dole it out between multiple applications.

Also, if the system was limited (for some architectural reasons), say, to 16MB of memory, size_t is most likely still a 32-bit unsigned integer - because most processors don't do 24-bit integers [some DSP's may do that, but regular 16 or 32 bit processors don't].

  • How does this compare with a 24-bit address space of a 16-bit process (one of the Intel chips does this)? Is size-t 24 bits or 16 or 32 bits? – Thomas Matthews Aug 18 '13 at 22:49
  • Old DOS used a 20-bit address space. OS/2 1.x used a 24-bit address space. And yes, that would have a 32-bit size_t in "large" mode. In "small" mode, size_t would be 16-bit. – Mats Petersson Aug 18 '13 at 22:53
  • Very detailed response !!! – newprint Aug 19 '13 at 1:00

It does not make sense for a compiler to give you the information “size of the largest possible object” because it depends on what else your program is and does. The size of one object may be limited to 231-1 bytes on a 32-bit architecture to avoid overflow issues with the signed type ptrdiff_t, or the implementors may have chosen to place no such arbitrary limit, in which case the size one object can have depends how much virtual space is reserved for the stack, for the code, for file-scope variables, what the OS' address randomization strategy is… There is no single exact “size of the largest object”, unless you mean an obvious upper bound such as the size of the virtual address space.

The type size_t is guaranteed to allow to represent the size of the largest object you can allocate under the best circumstances: small code, minimal stack, no waste to address space randomization, no other variables. For instance, I expect that some 64-bit kernels (on the x86-64 architecture) can leave the entire 4GiB of virtual address space to a 32-bit process such as a program generated by a 32-bit compiler with SIZE_MAX=232-1, in which case an object could be within a few megabytes of the theoretical limit. The largest I have observed in practice was 2.5GiB for a 32-bit size_t.

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