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In C, the compiler will lay out members of a struct in the order in which they're declared, with possible padding bytes inserted between members, or after the last member, to ensure that each member is aligned properly.

gcc provides a language extension, __attribute__(packed), which tells the compiler not to insert padding, allowing struct members to be misaligned. For example, if the system normally requires all int objects to have 4-byte alignment, `__attribute__(packed) can cause int struct members to be allocated at odd offsets.

Quoting the gcc documentation:

The `packed' attribute specifies that a variable or structure field should have the smallest possible alignment--one byte for a variable, and one bit for a field, unless you specify a larger value with the `aligned' attribute.

Obviously the use of this extension can result in smaller data requirements but slower code, as the compiler must (on some platforms) generate code to access a misaligned member a byte at a time.

But are there any cases where this is unsafe? Does the compiler always generate correct (though slower) code to access misaligned members of packed structs? Is it even possible for it to do so in all cases?

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4 Answers 4

up vote 74 down vote accepted

(Yes, I'm answering my own question.)

Yes, __attribute__((packed)) is potentially unsafe on some systems. The symptom probably won't show up on an x86, which just makes the problem more insidious; testing on x86 systems won't reveal the problem. (On the x86, misaligned accesses are handled in hardware; if you dereference an int* pointer that points to an odd address, it will be a little slower than if it were properly aligned, but you'll get the correct result.)

On some other systems, such as SPARC, attempting to access a misaligned int object causes a bus error, crashing the program.

There have also been systems where a misaligned access quietly ignores the low-order bits of the address, causing it to access the wrong chunk of memory.

Consider the following program:

#include <stdio.h>
#include <stddef.h>
int main(void)
    struct foo {
        char c;
        int x;
    } __attribute__((packed));
    struct foo arr[2] = { { 'a', 10 }, {'b', 20 } };
    int *p0 = &arr[0].x;
    int *p1 = &arr[1].x;
    printf("sizeof(struct foo)      = %d\n", (int)sizeof(struct foo));
    printf("offsetof(struct foo, c) = %d\n", (int)offsetof(struct foo, c));
    printf("offsetof(struct foo, x) = %d\n", (int)offsetof(struct foo, x));
    printf("arr[0].x = %d\n", arr[0].x);
    printf("arr[1].x = %d\n", arr[1].x);
    printf("p0 = %p\n", (void*)p0);
    printf("p1 = %p\n", (void*)p1);
    printf("*p0 = %d\n", *p0);
    printf("*p1 = %d\n", *p1);
    return 0;

On x86 Ubuntu with gcc 4.5.2, it produces the following output:

sizeof(struct foo)      = 5
offsetof(struct foo, c) = 0
offsetof(struct foo, x) = 1
arr[0].x = 10
arr[1].x = 20
p0 = 0xbffc104f
p1 = 0xbffc1054
*p0 = 10
*p1 = 20

On SPARC Solaris 9 with gcc 4.5.1, it produces the following:

sizeof(struct foo)      = 5
offsetof(struct foo, c) = 0
offsetof(struct foo, x) = 1
arr[0].x = 10
arr[1].x = 20
p0 = ffbff317
p1 = ffbff31c
Bus error

In both cases, the program is compiled with no extra options, just gcc packed.c -o packed.

(A program that uses a single struct rather than array doesn't reliably exhibit the problem, since the compiler can allocate the struct on an odd address so the x member is properly aligned. With an array of two struct foo objects, one or the other will have a misaligned x member.)

When referring to the member x of a struct foo by name, the compiler knows that x is potentially misaligned, and will generate additional code to access it correctly.

Once the address of arr[0].x or arr[1].x has been stored in a pointer object, neither the compiler nor the running program knows that it points to a misaligned int object. It just assumes that it's properly aligned, resulting (on some systems) in a bus error or similar other failure.

Fixing this in gcc would, I believe, be impractical. A general solution would require, for each attempt to dereference a pointer to any type with non-trivial alignment requirements either (a) proving at compile time that the pointer doesn't point to a misaligned member of a packed struct, or (b) generating bulkier and slower code that can handle either aligned or misaligned objects.

I've submitted a gcc bug report. As I said, I don't believe it's practical to fix it, but the documentation should mention it (it currently doesn't).

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is potentially misaligned, and will generate... what? –  Almo Dec 19 '11 at 22:32
misaligned struct elements on ARM does weird stuff: Some accesses cause faults, others cause the retrieved data to be rearranged counter-intuitively or incorporate adjacent unexpected data. –  wallyk Dec 19 '11 at 22:34
It seems that packing itself is safe, but how the packed members are used can be unsafe. Older ARM-based CPUs didn't support unaligned memory accesses either, newer versions do but I know Symbian OS still disallows unaligned accesses when running on these newer versions (the support is turned off). –  James Dec 19 '11 at 22:36
Another way to fix it within gcc would be to use the type system: require that pointers to members of packed structs can only be assigned to pointers that are themselves marked as packed (ie. potentially unaligned). But really: packed structs, just say no. –  caf Dec 19 '11 at 22:51
@Flavius: My main purpose was to get the information out there. See also… –  Keith Thompson Dec 19 '11 at 23:04

It's perfectly safe as long as you always access the values through the struct via the . (dot) or -> notation.

What's not safe is taking the pointer of unaligned data and then accessing it without taking that into account.

Also, even though each item in the struct is known to be unaligned, it's known to be unaligned in a particular way, so the struct as a whole must be aligned as the compiler expects or there'll be trouble (on some platforms, or in future if a new way is invented to optimise unaligned accesses).

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Hmm, I wonder what happens if you put one packed struct inside another packed struct where the alignment would be different? Interesting question, but it shouldn't change the answer. –  ams Dec 20 '11 at 10:56
GCC won't always align the structure itself either. For example: struct foo { int x; char c; } __attribute__((packed)); struct bar { char c; struct foo f; }; I found that bar::f::x will not be necessarily aligned, at least on certain flavors of MIPS. –  antonm Dec 3 '12 at 21:37
@antonm: Yes, a struct within a packed struct may well be unaligned, but, again, the compiler knows what the alignment of each field is, and it's perfectly safe as long as you don't try to use pointers into the struct. You should imagine a struct within a struct as one flat series of fields, with the extra name just for readability. –  ams Dec 4 '12 at 10:04

As ams said above, don't take a pointer to a member of a struct that's packed. This is simply playing with fire. When you say __attribute__((__packed__)) or #pragma pack(1), what you're really saying is "Hey gcc, I really know what I'm doing." When it turns out that you do not, you can't rightly blame the compiler.

Perhaps we can blame the compiler for it's complacency though. While gcc does have a -Wcast-align option, it isn't enabled by default nor with -Wall or -Wextra. This is apparently due to gcc developers considering this type of code to be a brain-dead "abomination" unworthy of addressing -- understandable disdain, but it doesn't help when an inexperienced programmer bumbles into it.

Consider the following:

struct  __attribute__((__packed__)) my_struct {
    char c;
    int i;

struct my_struct a = {'a', 123};
struct my_struct *b = &a;
int c = a.i;
int d = b->i;
int *e __attribute__((aligned(1))) = &a.i;
int *f = &a.i;

Here, the type of a is a packed struct (as defined above). Similarly, b is a pointer to a packed struct. The type of of the expression a.i is (basically) an int l-value with 1 byte alignment. c and d are both normal ints. When reading a.i, the compiler generates code for unaligned access. When you read b->i, b's type still knows it's packed, so no problem their either. e is a pointer to a one-byte-aligned int, so the compiler knows how to dereference that correctly as well. But when you make the assignment f = &a.i, you are storing the value of an unaligned int pointer in an aligned int pointer variable -- that's where you went wrong. And I agree, gcc should have this warning enabled by default (not even in -Wall or -Wextra).

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+1 for explaining how to use pointers with unaligned structs! –  Soumya Jun 28 '14 at 3:02
@Soumya Thanks for the points! :) Keep in mind however that __attribute__((aligned(1))) is a gcc extension and isn't portable. To my knowledge, the only really portable way to do unaligned access in C (with any compiler / hardware combination) is with a byte-wise memory copy (memcpy or similar). Some hardware does not even have instructions for unaligned access. My expertise is with arm and x86 which can do both, although the unaligned access is slower. So if you ever need to do this with high performance, you'll need to sniff the hardware and use arch-specific tricks. –  Daniel Santos Jul 1 '14 at 0:17
@Soumya Sadly, __attribute__((aligned(x))) now appears to be ignored when used for pointers. :( I don't yet have the full details of this, but using __builtin_assume_aligned(ptr, align) seems to get gcc to generate the correct code. When I a more concise answer (and hopefully a bug report) I'll update my answer. –  Daniel Santos Jul 30 '14 at 22:23

(The following is a very artificial example cooked up to illustrate.) One major use of packed structs is where you have a stream of data (say 256 bytes) to which you wish to supply meaning. If I take a smaller example, suppose I have a program running on my Arduino which sends via serial a packet of 16 bytes which have the following meaning:

0: message type (1 byte)
1: target address, MSB
2: target address, LSB
3: data (chars)
F: checksum (1 byte)

Then I can declare something like

typedef struct {
  uint8_t msgType;
  uint16_t targetAddr; // may have to bswap
  uint8_t data[12];
  uint8_t checksum;
} __attribute__((packed)) myStruct;

and then I can refer to the targetAddr bytes via aStruct.targetAddr rather than fiddling with pointer arithmetic.

Now with alignment stuff happening, taking a void* pointer in memory to the received data and casting it to a myStruct* will not work unless the compiler treats the struct as packed (that is, it stores data in the order specified and uses exactly 16 bytes for this example). There are performance penalties for unaligned reads, so using packed structs for data your program is actively working with is not necessarily a good idea. But when your program is supplied with a list of bytes, packed structs make it easier to write programs which access the contents.

Otherwise you end up using C++ and writing a class with accessor methods and stuff that does pointer arithmetic behind the scenes. In short, packed structs are for dealing efficiently with packed data, and packed data may be what your program is given to work with. For the most part, you code should read values out of the structure, work with them, and write them back when done. All else should be done outside the packed structure. Part of the problem is the low level stuff that C tries to hide from the programmer, and the hoop jumping that is needed if such things really do matter to the programmer. (You almost need a different 'data layout' construct in the language so that you can say 'this thing is 48 bytes long, foo refers to the data 13 bytes in, and should be interpreted thus'; and a separate structured data construct, where you say 'I want a structure containing two ints, called alice and bob, and a float called carol, and I don't care how you implement it' -- in C both these use cases are shoehorned into the struct construct.)

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Unless I'm missing something, this doesn't answer the question. You argue that structure packing is convenient (which it is), but you don't address the question of whether it's safe. Also, you assert that performance penalties for unaligned reads; that's true for x86, but not for all systems, as I demonstrated in my answer. –  Keith Thompson Aug 16 at 20:26

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