For any object type T is it always the case that sizeof(T) is at least as large as alignof(T)?

Intuitively it seems so, since even when you adjust the alignment of objects like:

struct small {
  char c;

above what it would normally be, their "size" is also adjusted upwards so that the relationship between objects in an array makes sense while maintaining alignment (at least in my testing. For example:

struct alignas(16) small16 {
  char c;

Has both a size and alignment of 16.

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    @tadman - for any architecture really. I'm asking what the standard guarantees or implies. Clearly in those two examples sizeof (12 and I*200, respectively) is larger than alignof (1 and I respectively), where I is sizeof(I). – BeeOnRope Sep 27 '17 at 21:27
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    @tadman - this isn't a question about x86 processors. When you say "these will be the same", what are "these"? – BeeOnRope Sep 27 '17 at 21:30
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    Well, if you start with an assumption such as "float is 4 bytes, sizeof( float ) returns 4, but the system architecture requires that a float be on an 8-byte boundary", where does that lead? Offhand, I think that means an array of float would be broken. – Andrew Henle Sep 27 '17 at 21:31
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    @tadman Of course is it not the case that sizeof(T) == alignof(T) in general. It is trivial to show that for example struct S { char a,b; }; usually has size 2 and alignof 1. My question is about >= not == though... – BeeOnRope Sep 27 '17 at 21:32
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    ... so while at the hardware level you might have weird stuff like 10 byte values that need to be 16-byte aligned, from the C++ point of view I think this must simply have sizeof 16. That's why I was asking @tadman for an example of a platform where sizeof(long double) is less than alignof(long double) - since it seems impossible for this to be a compliant implementation! – BeeOnRope Sep 27 '17 at 22:16

At least in standard C++, for anything you can make an array of (with length > 1), this will have to be true. If you have

Foo arr[2];

and alignof(Foo) > sizeof(Foo), then arr[0] and arr[1] can't both be aligned.

As Zalman Stern's example shows, though, at least some compilers will allow you to declare a type with alignment greater than its size, with the result that the compiler simply won't let you declare an array of that type. This is not standards-compliant C++ (it uses type attributes, which are a GCC extension), but it means that you can have alignof(T) > sizeof(T) in practice.

The array argument assumes sizeof(Foo) > 0, which is true for any type supported by the standard, but o11c shows an example where compiler extensions break that guarantee: some compilers allow 0-length arrays, with 0 sizeof and positive alignof.

  • I'm not sure there are any cases where this argument doesn't apply. Maybe an object type you can't make instances of at all, or a type so huge you can't fit two of them in the same address space? – user2357112 Sep 27 '17 at 21:54
  • Well Hans in the comments on the question seems to imply that it is allowed that sizeof(Foo[2]) > 2*sizeof(Foo) which would break your argument. I don't know if I believe it though. – BeeOnRope Sep 27 '17 at 22:22
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    @user2357112 You can't declare an array of an abstract class, or even a single instance. So its sizeof is not very useful. – curiousguy Sep 28 '17 at 5:20
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    @curiousguy: Well, you can have an instance of an abstract class as a base class subobject of an instance of a concrete subclass. I don't think there's any way to get an array of them, though, so that seems to be an example where the array argument fails even without compiler extensions. – user2357112 Sep 28 '17 at 6:10
  • "I don't know whether that's strictly conformant behavior" - it's not. Zalman's example uses a type attribute, __attribute__ ((aligned (64))). Type attributes are a GCC extension, and not part of the C or C++ standards. I edited to clarify - hope that's ok. – sleske Sep 28 '17 at 8:34
#include <iostream>

typedef double foo __attribute__ ((aligned (64)));
alignas(64) double bar;
double baz __attribute__ ((aligned (64)));

int main(int argc, char *argv[]) {
    std::cout << "foo sizeof: " << sizeof(foo) << " alignof: " << alignof(foo) << "\n";
    std::cout << "bar sizeof: " << sizeof(bar) << " alignof: " << alignof(decltype(bar)) << "\n";
    std::cout << "baz sizeof: " << sizeof(baz) << " alignof: " << alignof(decltype(baz)) << "\n";

Compile with:

clang++ -std=c++11 alignof_test.cpp -o alignof_test && ./alignof_test


foo sizeof: 8 alignof: 64
bar sizeof: 8 alignof: 8
baz sizeof: 8 alignof: 8

So strictly speaking, no, but the above argument re: arrays has to be preserved.

  • 1
    Try foo arr[2]; std::cout << sizeof( arr ) << "\n"; – Andrew Henle Sep 27 '17 at 22:10
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    error: alignment of array elements is greater than element size, so you just can't make an array of these. I wonder if that's strictly conformant behavior. – user2357112 Sep 27 '17 at 22:12
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    Updated to include use of the attribute version on an actual decl, which indeed does collapse. Points stands however that you can make types that violate the constraint, which might be important to know if one were depending on this in e.g. metaprogramming. – Zalman Stern Sep 27 '17 at 22:12
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    If you declare an object of type foo, it keeps the 64-byte alignof. It's interesting how the aligned attribute interacts differently with alignof if you attach it to a typedef and use the typedef compared to if you attach it to a variable declaration directly. – user2357112 Sep 27 '17 at 22:23
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    __attribute__ is a GCC extension. I haven't found a way to get the same results with alignof; I can create an object with alignof(obj) > sizeof(obj), but not a type. – user2357112 Sep 27 '17 at 23:03

According to the c++ 11 standard that introduced the alignof operator, sizeof is defined as following (see 5.3.3 expr.sizeof):

The sizeof operator yields the number of bytes in the object representation of its operand

Whereas alignof definition is (see 5.3.6 expr.alignof):

An alignof expression yields the alignment requirement of its operand type.

Since the defintion of alignof specifies a requirement, possibly made by the user, rather than a specification of the language, we can manipulate the compiler:

typedef uint32_t __attribute__ ((aligned (64))) aligned_uint32_t;
std::cout << sizeof(aligned_uint32_t) << " -> " << alignof(aligned_uint32_t);
// Output: 4 -> 64


As others have pointed out, such types cannot be used in arrays, e.g trying to compile the following:

aligned_uint32_t arr[2];

Results in error: alignment of array elements is greater than element size

Since arrays require the specified type to conform with the condition: sizeof(T) >= alignof(T)

  • 1
    Yes, but note that aligned_uinit32_t is not a type, despite the way you've named it. It's declaring a stack variable with different alignment. I know that in such a case the alignment is what you asked for and sizeof doesn't change. The question is whether you can make a type with this behavior wherever it is used. – BeeOnRope Sep 27 '17 at 22:27
  • @BeeOnRope, you are right, I accidentally posted intermediate code. I have adjusted my answer to show that a type can be declared in such a way. – Daniel Trugman Sep 27 '17 at 22:32

Many compilers allow arrays of size 0. The alignment remains the same as the alignment of the sole element.

(Among other things, this is useful for forcing a particular alignment in cases when you can't use a bitfield)

  • 2
    Oh yeah, 0-length arrays are a thing on some compilers. Having types of size 0 screws with a lot of things. – user2357112 Sep 28 '17 at 4:47
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    Only if you try to do pointer arithmetic, really. – o11c Sep 28 '17 at 4:53

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