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Why does the 'sizeof' operator return a size larger for a structure than the total sizes of the structure's members?

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See this C FAQ on memory alighnment. – Richard Chambers Apr 26 '13 at 12:40
Anecdote: There was an actual computer virus that put its code within struct paddings in the host program. – Elazar Sep 2 '13 at 17:58

9 Answers 9

up vote 331 down vote accepted

This is because of padding added to satisfy alignment constraints. Data structure alignment impacts both performance and correctness of programs:

  • Mis-aligned access might be a hard error (often SIGBUS).
  • Mis-aligned access might be a soft error.
    • Either corrected in hardware, for a modest performance-degradation.
    • Or corrected by emulation in software, for a severe performance-degradation.
    • In addition, atomicity and other concurrency-guarantees might be broken, leading to subtle errors.

Here's an example using typical settings for an x86 processor (all used 32 and 64 bit modes):

struct X
    short s; /* 2 bytes */
             /* 2 padding bytes */
    int   i; /* 4 bytes */
    char  c; /* 1 byte */
             /* 3 padding bytes */

struct Y
    int   i; /* 4 bytes */
    char  c; /* 1 byte */
             /* 1 padding byte */
    short s; /* 2 bytes */

struct Z
    int   i; /* 4 bytes */
    short s; /* 2 bytes */
    char  c; /* 1 byte */
             /* 1 padding byte */

const int sizeX = sizeof(X); /* = 12 */
const int sizeY = sizeof(Y); /* = 8 */
const int sizeZ = sizeof(Z); /* = 8 */

One can minimize the size of structures by sorting members by alignment (sorting by size suffices for that in basic types) (like structure Z in the example above).

IMPORTANT NOTE: Both the C and C++ standards state that structure alignment is implementation-defined. Therefore each compiler may choose to align data differently, resulting in different and incompatible data layouts. For this reason, when dealing with libraries that will be used by different compilers, it is important to understand how the compilers align data. Some compilers have command-line settings and/or special #pragma statements to change the structure alignment settings.

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I want to make a note here: Most processors penalize you for unaligned memory access (as you mentioned), but you can't forget that many completely disallow it. Most MIPS chips, in particular, will throw an exception on an unaligned access. – Cody Brocious Sep 23 '08 at 4:27
The x86 chips are actually rather unique in that they allow unaligned access, albeit penalized; AFAIK most chips will throw exceptions, not just a few. PowerPC is another common example. – Dark Shikari Sep 23 '08 at 7:08
Enabling pragmas for unaligned accesses generally cause your code to balloon in size, on processors which throw misalignment faults, as code to fix up every misalignment has to be generated. ARM also throws misalignment faults. – Mike Dimmick Sep 23 '08 at 11:16
@Dark - totally agree. But most desktop processors are x86/x64, so most chips don't issue data alignment faults ;) – Aaron Sep 25 '08 at 21:53
Unaligned data access is typically a feature found in CISC architectures, and most RISC architectures do not include it (ARM, MIPS, PowerPC, Cell). In actually, most chips are NOT desktop processors, for embedded rule by numbers of chips and the vast majority of these are RISC architectures. – Lara Dougan Oct 19 '08 at 1:51

Packing and byte alignment... described in the C FAQ here

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+1 Things are always better understood with a visual representation (code alone sometimes is not enough) – AntonioCS Jun 30 '13 at 12:42

If you want the structure to have a certain size with GCC for example use __attribute__((packed)).

On Windows you can set the alignment to one byte when using the cl.exe compier with the /Zp option.

Usually it is easier for the CPU to access data that is a multiple of 4 (or 8), depending platform and also on the compiler.

So it is a matter of alignment basically.

You need to have good reasons to change it.

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"good reasons" Example: Keeping binary compatibility (padding) consistent between 32-bit and 64-bit systems for a complex struct in proof-of-concept demo code that's being showcased tomorrow. Sometimes necessity has to take precedence over propriety. – Mr.Ree Dec 8 '08 at 4:58
Everything is ok except when you mention the Operating System. This is an issue for the CPU speed, the OS is not involved at all. – Blaisorblade Jan 12 '09 at 2:51
Another good reason is if you're stuffing a datastream into a struct, e.g. when parsing network protocols. – ceo Oct 20 '09 at 15:18
@Blaisorblade While the CPU architecture is the most important point, the OS may also matter. Think about an x86 CPU running in real mode (MS-DOS) vs protected mode (Windows, Linux...). – dolmen Aug 20 '13 at 7:50
@dolmen I just pointed out that "it is easier for the Operatin System to access data" is incorrect, since the OS doesn't access data. – Blaisorblade Aug 24 '13 at 17:44

This can be due to byte alignment and padding so that the structure comes out to an even number of bytes (or words) on your platform. For example in C on Linux, the following 3 structures:

#include "stdio.h"

struct oneInt {
  int x;

struct twoInts {
  int x;
  int y;

struct someBits {
  int x:2;
  int y:6;

int main (int argc, char** argv) {
  printf("oneInt=%zu\n",sizeof(struct oneInt));
  printf("twoInts=%zu\n",sizeof(struct twoInts));
  printf("someBits=%zu\n",sizeof(struct someBits));
  return 0;

Have members who's sizes (in bytes) are 4 bytes (32 bits), 8 bytes (2x 32 bits) and 1 byte (2+6 bits) respectively. The above program (on Linux using gcc) prints the sizes as 4, 8, and 4 - where the last structure is padded so that it is a single word (4 x 8 bit bytes on my 32bit platform).

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"C on Linux using gcc" is not enough to describe your platform. Alignment mostly depend on the CPU architecture. – dolmen Aug 20 '13 at 7:46
Don't print size_t with the %d format specifier, it invokes undefined behavior. Use %zu instead. – user529758 Jan 8 '14 at 22:26

It can do so if you have implicitly or explicitly set the alignment of the struct. A struct that is aligned 4 will always be a multiple of 4 bytes even if the size of its members would be something that's not a multiple of 4 bytes.

Also a library may be compiled under x86 with 32-bit ints and you may be comparing its components on a 64-bit process would would give you a different result if you were doing this by hand.

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In addition to the other answers, a struct can (but usually doesn't) have virtual functions, in which case the size of the struct will also include the space for the vtbl.

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Not quite. In typical implementations, what is added to the struct is a vtable pointer. – Don Wakefield Oct 18 '08 at 3:16

See also:

for Microsoft Visual C:

and GCC claim compatibility with Microsoft's compiler.:

In addition to the previous answers, please note that regardless the packaging, there is no members-order-guarantee in C++. Compilers may (and certainly do) add virtual table pointer and base structures' members to the structure. Even the existence of virtual table is not ensured by the standard (virtual mechanism implementation is not specified) and therefore one can conclude that such guarantee is just impossible.

I'm quite sure member-order is grunted in C, but I wouldn't count on it, when writing a cross-platform or cross-compiler program.

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C language leaves compiler some freedom about the location of the structural elements in the memory:

  • memory holes may appear between any two components, and after the last component. It was due to the fact that certain types of objects on the target computer may be limited by the boundaries of addressing
  • "memory holes" size included in the result of sizeof operator. The sizeof only doesn't include size of the flexible array, which is available in C/C++
  • Some implementations of the language allow you to control the memory layout of structures through the pragma and compiler options

The C language provides some assurance to the programmer of the elements layout in the structure:

  • compilers required to assign a sequence of components increasing memory addresses
  • Address of the first component coincides with the start address of the structure
  • unnamed bit fields may be included in the structure to the required address alignments of adjacent elements

Problems related to the elements alignment:

  • Different computers line the edges of objects in different ways
  • Different restrictions on the width of the bit field
  • Computers differ on how to store the bytes in a word (Intel 80x86 and Motorola 68000)

How alignment works:

  • The volume occupied by the structure is calculated as the size of the aligned single element of an array of such structures. The structure should end so that the first element of the next following structure does not the violate requirements of alignment

p.s More detailed info are available here: "Samuel P.Harbison, Guy L.Steele C A Reference, (5.6.2 - 5.6.7)"

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The size of a structure is greater than the sum of its parts because of what is called packing. A particular processor has a preferred data size that it works with. Most modern processors' preferred size if 32-bits (4 bytes). Accessing the memory when data is on this kind of boundary is more efficient than things that straddle that size boundary.

For example. Consider the simple structure:

struct myStruct
   int a;
   char b;
   int c;
} data;

If the machine is a 32-bit machine and data is aligned on a 32-bit boundary, we see an immediate problem (assuming no structure alignment). In this example, let us assume that the structure data starts at address 1024 (0x400 - note that the lowest 2 bits are zero, so the data is aligned to a 32-bit boundary). The access to data.a will work fine because it starts on a boundary - 0x400. The access to data.b will also work fine, because it is at address 0x404 - another 32-bit boundary. But an unaligned structure would put data.c at address 0x405. The 4 bytes of data.c are at 0x405, 0x406, 0x407, 0x408. On a 32-bit machine, the system would read data.c during one memory cycle, but would only get 3 of the 4 bytes (the 4th byte is on the next boundary). So, the system would have to do a second memory access to get the 4th byte,

Now, if instead of putting data.c at address 0x405, the compiler padded the structure by 3 bytes and put data.c at address 0x408, then the system would only need 1 cycle to read the data, cutting access time to that data element by 50%. Padding swaps memory efficiency for processing efficiency. Given that computers can have huge amounts of memory (many gigabytes), the compilers feel that the swap (speed over size) is a reasonable one.

Unfortunately, this problem becomes a killer when you attempt to send structures over a network or even write the binary data to a binary file. The padding inserted between elements of a structure or class can disrupt the data sent to the file or network. In order to write portable code (one that will go to several different compilers), you will probably have to access each element of the structure separately to ensure the proper "packing".

On the other hand, different compilers have different abilities to manage data structure packing. For example, in Visual C/C++ the compiler supports the #pragma pack command. This will allow you to adjust data packing and alignment.

For example:

#pragma pack 1
struct MyStruct
    int a;
    char b;
    int c;
    short d;
} myData;

I = sizeof(myData);

I should now have the length of 11. Without the pragma, I could be anything from 11 to 14 (and for some systems, as much as 32), depending on the default packing of the compiler.

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This discusses the consequences of structure padding, but it does not answer the question. – Keith Thompson Jun 10 at 15:39
Keith, you are correct. I modified it to include the answer, the consequences and a couple of work arounds. – sid1138 Jun 12 at 15:56
"... because of what is called packing. ... -- I think you mean "padding". "Most modern processors' preferred size if 32-bits (4 bytes)" -- That's a bit of an oversimplification. Typically sizes of 8, 16, 32, and 64 bits are supported; often each size has its own alignment. And I'm not sure your answer adds any new information that's not already in the accepted answer. – Keith Thompson Jun 12 at 16:02
WhenI said packing, I meant how the compiler packs data into a structure (and it can do so by padding the small items, but it does not need to pad, but it always packs). As for size - I was talking about the system architecture, not what the system will support for data access (which is way different from the underlying bus architecture). As for your final comment, I gave a simplified and expanded explanation of one aspect of the tradeoff (speed versus size) - a major programming problem. I also describe a way to fix the problem - that was not in the accepted answer. – sid1138 Jun 12 at 21:12
"Packing" in this context usually refers to allocating members more tightly than the default, as with #pragma pack. If members are allocated on their default alignment, I'd generally say the structure is not packed. – Keith Thompson Jun 12 at 21:16

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