I work with shared memory right now.

I can't understand alignof and alignas.

cppreference is unclear : alignof returns "alignment" but what is "alignment" ? number of bytes to add for the next block to be aligned ? padded size ? Stack overflow / blogs entries are unclear too.

Can someone explain clearly alignof and alignas ?

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    cppreference is trying to be a reference rather than a tutorial – Cubbi Jun 13 '13 at 18:21
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    @Cubbi: you can also check at cplusplus.com, there is debate wich site is better, for certain topics cplusplus is better, for other cppreference is better, I found that both sites certain times are not eonugh – CoffeDeveloper Jan 15 '14 at 20:38
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    @DarioOO I was only answering why cppreference doesn't explain the concept of alignment on the alignof page (it does now, on the work-in-progress object page). I don't see how cplusplus.com is relevant. – Cubbi Jan 15 '14 at 23:09
  • Also see Where can I use alignas() in C++11. – jww Jun 9 '16 at 2:53

Alignment is a restriction on which memory positions a value's first byte can be stored. (It is needed to improve performance on processors and to permit use of certain instructions that works only on data with particular alignment, for example SSE need to be aligned to 16 bytes, while AVX to 32 bytes.)

Alignment of 16 means that memory addresses that are a multiple of 16 are the only valid addresses.


force alignment to the required number of bytes. You can only align to powers of 2: 1, 2, 4, 8, 16, 32, 64, 128, ...

#include <cstdlib>
#include <iostream>

int main() {
    alignas(16) int a[4];
    alignas(1024) int b[4];
    printf("%p\n", a);
    printf("%p", b);

example output:

0xbfa49000  // note how many more "zeros" now.
// binary equivalent
1011 1111 1010 0100 1001 0011 1110 0000
1011 1111 1010 0100 1001 0000 0000 0000 // every zero is just a extra power of 2

the other keyword


is very convenient, you cannot do something like

int a[4];
assert(a % 16 == 0); // check if alignment is to 16 bytes: WRONG compiler error

but you can do

assert(alignof(a) == 16);
assert(alignof(b) == 1024);

note that in reality this is more strict than a simple "%" (modulus) operation. In fact we know that something aligned to 1024 bytes is necessarily aligned to 1, 2, 4, 8 bytes but

 assert(alignof(b) == 32); // fail.

So to be more precise, "alignof" returns the greatest power of 2 to wich something is aligned.

Also alignof is a nice way to know in advance minimum alignment requirement for basic datatypes (it will probably return 1 for chars, 4 for float etc.).

Still legal:

alignas(alignof(float)) float SqDistance;

Something with an alignment of 16 then will be placed on the next available address that is a multiple of 16 (there may be a implicit padding from last used address).

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    Unlike sizeof, alignof can only be applied to a type-id. – neverhoodboy Feb 2 '14 at 1:27
  • is alignof() (and the counterpart alignas()) evaluated at compile time , so no runtime overhead? – nonsensation Nov 30 '14 at 20:14
  • no. It is not possible, the compiler may do that as optimization in very few cases, but in general it will not know how memory addresses are aligned before evaluating the 2 functions. Just look at assembly generated by my example: goo.gl/ZbemBF – CoffeDeveloper Dec 1 '14 at 0:31
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    @Serthy To clarify alignof is a compile-time constant. alignas is not, and will have to be supported by your implementation of new (requirement of the standard), or by a custom std allocator. – Aidiakapi Jan 13 '16 at 18:40
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    Good answer, but it needs a treatment of struct and members of the struct that are static. alignas is turning out to be much more finicky than __attribute__((aligned)), especially under compilers like Clang. – jww Jun 9 '16 at 2:52

Alignment is not padding (although padding is sometimes introduced to satisfy alignment requirements). It is an intrisic property of a C++ type. To put it in standardese (3.11[basic.align])

Object types have alignment requirements (3.9.1, 3.9.2) which place restrictions on the addresses at which an object of that type may be allocated. An alignment is an implementation-defined integer value representing the number of bytes between successive addresses at which a given object can be allocated. An object type imposes an alignment requirement on every object of that type; stricter alignment can be requested using the alignment specifier (7.6.2).

  • 1
    Very interesting. Would you mind giving some examples ? Does alignof(struct X) == sizeof(struct X) ? Why not ? – Offirmo Jun 13 '13 at 23:08
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    @Offirmo no, except by concidence: struct X { char a; char b} has size 2 and alignment requirement 1, on sane systems (it can be allocated at any address because a char can be allocated at any address) – Cubbi Jun 14 '13 at 0:58
  • alignment req of 1 ???? Oh I get it : I thought that alignment was always on "natural" 32bits/64bits boundaries but apparently not. That explains things... So on usual machines, alignof() result will always max at 4 (32bits) or 8 (64bits) Am I right ? – Offirmo Jun 14 '13 at 7:42
  • @Offirmo "natural" alignof will max out at alignof(std::max_align_t), which is 16 on my linux (regardless of whether compiling -m32 or -m64), but you can make it stricter with alignas – Cubbi Jun 14 '13 at 12:54

Each type has an alignment requirement. Generally, this is so variables of the type can be accessed efficiently, without having to cause the CPU to generate more than one read/write access in order to reach any given member of the datatype. Furthermore, it also ensure efficient copying of the entire variable. alignof will return the alignment requirement for the given type.

alignas is used to force an alignment on a datatype (so long as it is not less stringent that what alignof said datatype would return)


Alignment is a property related with memory address. Simply we can say than if an address X is aligned to Z then x is a multiple of Z ,that is X = Zn+0. Here the important thing is Z is always a power of 2.

Alignment is a property of a memory address, expressed as the numeric address modulo a power of 2. For example, the address 0x0001103F modulo 4 is 3. That address is said to be aligned to 4n+3, where 4 indicates the chosen power of 2. The alignment of an address depends on the chosen power of 2. The same address modulo 8 is 7. An address is said to be aligned to X if its alignment is Xn+0.

The above statement is found on microsoft c++ reference .

If a data item is stored in the memory with an address which is aligned to its size , then that data item is said to be naturally aligned , else misaligned. For eg : if an integer variable with size 4 bytes is stored in an address which is aligned to 4 , then we can say that the variable is naturally aligned , that is the address of the variable should be a multiple of 4.

The compilers always tries to avoid misalignments . For simple datatypes the addresses are chosen such that it is a multiple of the size of the variable in bytes. The complier also pads suitably in the case of structures for natural alignment and access.Here the structure will be aligned to the maximum of the sizes of different data items in the structure.eg:

    struct abc
        int a;
        char b;

Here the structure abc is aligned to 4 which is the size of int member which is obviously greater than 1 byte(size of char member).


This specifier is used to align user defined types like structure , class etc to a particular value which is a power of 2.


This is a kind of operator to get the value to which the structure or class type is aligned. eg:

#include <iostream>
struct alignas(16) Bar
    int i; // 4 bytes
    int n; // 4 bytes
    short s; // 2 bytes
int main()
    std::cout << alignof(Bar) << std::endl; // output: 16

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