Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

Take this example

class A
  int a; 
  char b;
  int c;

Every compiler (for x86, 32 or 64 bit) I see allocates 12 bytes for class A, instead of 9. So they are aligning b to the integer boundary or bus boundary you can say. My question is if this is in C++ standard to do so and if there are any compilers who does not do like that.

share|improve this question
up vote 15 down vote accepted

The C++ standard specifies that:

  • objects have an alignment requirement of which their size is a multiple (so if int is 4 bytes wide, then it requires an alignment of 1, 2 or 4 bytes, depending on the implementation).
  • member objects (if they are not separated by access specifiers such as public) are all allocated in the order they're declared
  • and they are allocated respecting their alignment requirements.

So no, the standard doesn't say exactly that the class should have a size of 12 bytes.

But it does say that b should be allocated after a, and that c should be allocated after b.

On a platform where int is 4 bytes wide, and requires 4-byte alignment, this leaves 12 bytes as the smallest valid size:

  • a takes the first 4 bytes
  • b takes one byte
  • c needs 4 bytes, but must be allocated on a 4-byte boundary. b ended one byte past such a boundary, so the next valid position to place c at is found by inserting 3 bytes of padding.

So the total size of the class ends up being the size of the members (4 + 1 + 4 = 9) plus three bytes of padding, for a total of 12.

There is another rule which has no effect here, but which would matter if you had defined the members in the order a, c, b instead.

The containing class (A) inherits the alignment requirement from the strictest-aligned member object. That is, because it contains an int, it has the same alignment requirement as an int does. And because the object's total size must be a multiple of its alignment requirement, a class containing the members in the order a, b, c would still require 12 bytes of storage. It'd just shift the 3 bytes of padding to the end of the class, instead of between b and c.

However, in some other cases, reordering members in descending order of size can sometimes reduce the size of a class.

Suppose we'd had a class like this instead:

class B {
  char a;
  double b;
  int c;

This would have required 24 bytes of storage (1 bytes for a, 8 byte for b, and 4 bytes for c, but then to ensure b ends up on an 8-byte boundary, we'd need 7 bytes of padding between a and b, and to ensure that the whole class ends up with a size that is a multiple of 8, we need another 4 bytes after c.

But reordering the members according to size, like this:

class B {
  double b;
  int c;
  char a;

results in a class requiring only 16 bytes:

the same 1 + 4 + 8 bytes for the member objects themselves, but now c is already aligned on a 4-byte boundary (because it comes after b which ends on an 8-byte boundary), and a never needs any alignment, so the only alignment we need is to ensure that B has a size that is a multiple of 8. The members take 13 bytes, so we can add 3 bytes of padding, and the class ends up at 16 bytes, 33% smaller than the first version.

share|improve this answer
You might also point out that on most architectures, accessing a mis-aligned object will result in some sort of a bus error, which will cause the program to crash. On an Intel, the program won't crash, but it will still run a lot slower if the data is misaligned. – James Kanze Nov 8 '12 at 15:27

Standard allows the compilers to padd more bytes if necessary. It basically depends on the architecture of the host rather than compiler.

share|improve this answer

It is possible to control structure packing at compile-time, using pragma directives. See #Pragma Pack

For example, the following does not align the members, and places them right next to each other.

#pragma pack(push, 1)
struct A4
  char a;
  double b;
  char c;
#pragma pack(pop)

Example from here.

GCC also supports pragma pack. The directive isn't the part of some standard, but a lot of compilers do support it.

However, there shouldn't be a reason to do the above. The compiler aligns them to speed up access to members, and there should be no reason to change that.

share|improve this answer
Is #pragma pack portable? Does it work other compilers? – Alessandro Pezzato Nov 8 '12 at 14:07
But is it defined in C++ standard that the default case would to be to align to bus boundary. – pythonic Nov 8 '12 at 14:07
GCC supports a set of #pragma directives, but they support that because MS's compilers do as well. The pack directive isn't a part of any standard AFAIK. – Anirudh Ramanathan Nov 8 '12 at 14:13
In fact, #pragma anything is by definition not part of any standard. – MSalters Nov 8 '12 at 14:16
"There shouldn't be a reason to do the above" There are use cases for this, such as packing structures for network transport. – Justin ᚅᚔᚈᚄᚒᚔ Nov 8 '12 at 15:47

Yes, alignment is mentioned everywhere in the standard, mainly section 3.11 (Alignment). It is platform-dependent, so any program that depends on the actual size of an object is inherently non-portable.

share|improve this answer

In your case 'b' is always correctly aligned. It's padded to align c in 32-bit boundaries. Even though there is some room for specific implementations, most compilers follow the rule of aligning 2 and 4-byte variables to 2 and 4 byte boundaries.

In 32-bit systems also doubles and long ints (8 bytes) are aligned to 4-byte boundaries, but aligned to 8-byte in 64-bit systems.

share|improve this answer
How the systems aligns different types is very implementation dependent. I've used 32 bit systems where doubles were aligned on 8 byte boundaries, and I've seen all sorts of alignments for long double. – James Kanze Nov 8 '12 at 15:31
Well yes, maybe long double is pushing the limits of compatibility. – Aki Suihkonen Nov 8 '12 at 19:40

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

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