Regardless of how 'bad' the code is, and assuming that alignment etc are not an issue on the compiler/platform, is this undefined or broken behavior?

If I have a struct like this :-

struct data
    int a, b, c;

struct data thing;

Is it legal to access a, b and c as (&thing.a)[0], (&thing.a)[1], and (&thing.a)[2]?

In every case, on every compiler and platform I tried it on, with every setting I tried it 'worked'. I'm just worried that the compiler might not realize that b and thing[1] are the same thing and stores to 'b' might be put in a register and thing[1] reads the wrong value from memory (for example). In every case I tried it did the right thing though. (I realize of course that doesn't prove much)

This is not my code; it's code I have to work with, I'm interested in whether this is bad code or broken code as the different affects my priorities for changing it a great deal :)

Tagged C and C++ . I'm mostly interested in C++ but also C if it is different, just for interest.

  • 51
    No, it is not "legal". It is undefined behavior. Nov 14, 2016 at 13:47
  • 11
    It works for you in this very simple case because the compiler doesn't add any padding between the members. Try with structures using differently sized types and will come crashing down. Nov 14, 2016 at 13:50
  • 7
    Digging up the past - UB used to be nick-named nasal daemons. Nov 14, 2016 at 13:51
  • 21
    Well great, here I stumble in because I follow the C tag, read the question, then write an answer which only applies to C, because I didn't see the C++ tag. C and C++ are very different here! C allows type punning with unions, C++ does not.
    – Lundin
    Nov 14, 2016 at 14:04
  • 7
    If you need to access the elements as an array, define them as an array. If they need to have different names, use the names. Trying to have your cake and eat it will lead to indigestion eventually — probably at the most inconvenient imaginable time. (I think the index 0 is legal in C; the index 1 or 2 is not. There are contexts in which a single element is treated as an array of size 1.) Nov 14, 2016 at 14:12

10 Answers 10


It is illegal 1. That's an Undefined behavior in C++.

You are taking the members in an array fashion, but here is what the C++ standard says (emphasis mine):

[dcl.array/1]: ...An object of array type contains a contiguously allocated non-empty set of N subobjects of type T...

But, for members, there's no such contiguous requirement:

[class.mem/17]: ...;Implementation alignment requirements might cause two adjacent members not to be allocated immediately after each other...

While the above two quotes should be enough to hint why indexing into a struct as you did isn't a defined behavior by the C++ standard, let's pick one example: look at the expression (&thing.a)[2] - Regarding the subscript operator:

[expr.post//expr.sub/1]: A postfix expression followed by an expression in square brackets is a postfix expression. One of the expressions shall be a glvalue of type “array of T” or a prvalue of type “pointer to T” and the other shall be a prvalue of unscoped enumeration or integral type. The result is of type “T”. The type “T” shall be a completely-defined object type.66 The expression E1[E2] is identical (by definition) to ((E1)+(E2))

Digging into the bold text of the above quote: regarding adding an integral type to a pointer type (note the emphasis here)..

[expr.add/4]: When an expression that has integral type is added to or subtracted from a pointer, the result has the type of the pointer operand. If the expression P points to element x[i] of an array object x with n elements, the expressions P + J and J + P (where J has the value j) point to the (possibly-hypothetical) element x[i + j] if 0 ≤ i + j ≤ n; otherwise, the behavior is undefined. ...

Note the array requirement for the if clause; else the otherwise in the above quote. The expression (&thing.a)[2] obviously doesn't qualify for the if clause; Hence, Undefined Behavior.

On a side note: Though I have extensively experimented the code and its variations on various compilers and they don't introduce any padding here, (it works); from a maintenance view, the code is extremely fragile. you should still assert that the implementation allocated the members contiguously before doing this. And stay in-bounds :-). But its still Undefined behavior....

Some viable workarounds (with defined behavior) have been provided by other answers.

As rightly pointed out in the comments, [basic.lval/8], which was in my previous edit doesn't apply. Thanks @2501 and @M.M.

1: See @Barry's answer to this question for the only one legal case where you can access thing.a member of the struct via this parttern.

  • 1
    @jcoder It is defined in class.mem. See the last paragraph for the actual text. Nov 14, 2016 at 13:57
  • 4
    Strict alising isn't relevant here. The type int is contained within the aggregate type and this type may alias int. - an aggregate or union type that includes one of the aforementioned types among its elements or non-static data members (including, recursively, an element or non-static data member of a subaggregate or contained union),
    – 2501
    Nov 14, 2016 at 14:37
  • 1
    @The downvoters, care to comment? -- and to improve or point out where this answer is wrong?
    – WhiZTiM
    Nov 14, 2016 at 14:47
  • 4
    Strict aliasing is irrelevant to this. The padding is not part of the stored value of an object. Also this answer fails to address the most common case: what happens when there is no padding. Would recommend deleting this answer actually.
    – M.M
    Nov 15, 2016 at 8:01
  • 1
    Done! I've removed the paragraph about strict-aliasing.
    – WhiZTiM
    Nov 15, 2016 at 15:41

No. In C, this is undefined behavior even if there is no padding.

The thing that causes undefined behavior is out-of-bounds access1. When you have a scalar (members a,b,c in the struct) and try to use it as an array2 to access the next hypothetical element, you cause undefined behavior, even if there happens to be another object of the same type at that address.

However you may use the address of the struct object and calculate the offset into a specific member:

struct data thing = { 0 };
char* p = ( char* )&thing + offsetof( thing , b );
int* b = ( int* )p;
*b = 123;
assert( thing.b == 123 );

This has to be done for each member individually, but can be put into a function that resembles an array access.

1 (Quoted from: ISO/IEC 9899:201x 6.5.6 Additive operators 8)
If the result points one past the last element of the array object, it shall not be used as the operand of a unary * operator that is evaluated.

2 (Quoted from: ISO/IEC 9899:201x 6.5.6 Additive operators 7)
For the purposes of these operators, a pointer to an object that is not an element of an array behaves the same as a pointer to the first element of an array of length one with the type of the object as its element type.

  • 3
    Do note this only works if the class is a standard layout type. If not it is still UB. Nov 14, 2016 at 13:52
  • @NathanOliver I should mention that my answer only applies to C. Edited. This is one of the problems of such dual tag language questions.
    – 2501
    Nov 14, 2016 at 13:53
  • Thanks, and that's why I asked separately for C++ and C as it's interesting to klnow the differences
    – jcoder
    Nov 14, 2016 at 13:54
  • @NathanOliver The address of the first member is guaranteed to coincide with the address of the C++ class if it's standard layout. However, that neither guarantees that the access is well-defined nor implies that such accesses on other classes are undefined. Nov 14, 2016 at 14:22
  • would you say that char* p = ( char* )&thing.a + offsetof( thing , b ); leads to undefined behaviour?
    – M.M
    Nov 15, 2016 at 8:11

In C++ if you really need it - create operator[]:

struct data
    int a, b, c;
    int &operator[]( size_t idx ) {
        switch( idx ) {
            case 0 : return a;
            case 1 : return b;
            case 2 : return c;
            default: throw std::runtime_error( "bad index" );

data d;
d[0] = 123; // assign 123 to data.a

it is not only guaranteed to work but usage is simpler, you do not need to write unreadable expression (&thing.a)[0]

Note: this answer is given in assumption that you already have a structure with fields, and you need to add access via index. If speed is an issue and you can change the structure this could be more effective:

struct data 
     int array[3];
     int &a = array[0];
     int &b = array[1];
     int &c = array[2];

This solution would change size of structure so you can use methods as well:

struct data 
     int array[3];
     int &a() { return array[0]; }
     int &b() { return array[1]; }
     int &c() { return array[2]; }
  • 1
    I'd love to see the disassembly of this, versus the disassembly of a C program using type punning. But, but... C++ is as fast as C... right? Right?
    – Lundin
    Nov 14, 2016 at 14:27
  • 6
    @Lundin if you care about speed of this construction then data should be organized as an array in the first place, not as separate fields.
    – Slava
    Nov 14, 2016 at 14:44
  • 2
    @Lundin in both you mean unreadable and Undefined Behavior? No thanks.
    – Slava
    Nov 14, 2016 at 14:50
  • 1
    @Lundin Operator overloading is a compile-time syntactic feature that does not induce any overhead compared to normal functions. Take a look at godbolt.org/g/vqhREz to see what the compiler actually does when it compiles the C++ and C code. It's amazing what they do and what one expects them to do. I personally prefer better type-safety and expressiveness of C++ over C a million times. And it works all the time without relying on assumptions about padding.
    – Jens
    Nov 14, 2016 at 15:52
  • 2
    Those references will double the size of the thing at least. Just do thing.a().
    – T.C.
    Nov 14, 2016 at 17:21

For c++: If you need to access a member without knowing its name, you can use a pointer to member variable.

struct data {
  int a, b, c;

typedef int data::* data_int_ptr;

data_int_ptr arr[] = {&data::a, &data::b, &data::c};

data thing;
thing.*arr[0] = 123;
  • 1
    This is using the language facilities, and as a result is well-defined and, as I assume, efficient. Best answer. Nov 15, 2016 at 14:56
  • 2
    Assume efficient? I assume the opposite. Look at the generated code.
    – JDługosz
    Nov 15, 2016 at 23:21
  • 1
    @JDługosz, you are quite right. Taking a peek at the generated assembly, it seems gcc 6.2 creates code equivalent to using offsetoff in C. Nov 16, 2016 at 6:22
  • 3
    you can also improve things by making arr constexpr. This will create a single fixed lookup table in the data section rather than creating it on the fly.
    – Tim
    Nov 16, 2016 at 10:31

In ISO C99/C11, union-based type-punning is legal, so you can use that instead of indexing pointers to non-arrays (see various other answers).

ISO C++ doesn't allow union-based type-punning. GNU C++ does, as an extension, and I think some other compilers that don't support GNU extensions in general do support union type-punning. But that doesn't help you write strictly portable code.

With current versions of gcc and clang, writing a C++ member function using a switch(idx) to select a member will optimize away for compile-time constant indices, but will produce terrible branchy asm for runtime indices. There's nothing inherently wrong with switch() for this; this is simply a missed-optimization bug in current compilers. They could compiler Slava' switch() function efficiently.

The solution/workaround to this is to do it the other way: give your class/struct an array member, and write accessor functions to attach names to specific elements.

struct array_data
  int arr[3];

  int &operator[]( unsigned idx ) {
      // assert(idx <= 2);
      //idx = (idx > 2) ? 2 : idx;
      return arr[idx];
  int &a(){ return arr[0]; } // TODO: const versions
  int &b(){ return arr[1]; }
  int &c(){ return arr[2]; }

We can have a look at the asm output for different use-cases, on the Godbolt compiler explorer. These are complete x86-64 System V functions, with the trailing RET instruction omitted to better show what you'd get when they inline. ARM/MIPS/whatever would be similar.

# asm from g++6.2 -O3
int getb(array_data &d) { return d.b(); }
    mov     eax, DWORD PTR [rdi+4]

void setc(array_data &d, int val) { d.c() = val; }
    mov     DWORD PTR [rdi+8], esi

int getidx(array_data &d, int idx) { return d[idx]; }
    mov     esi, esi                   # zero-extend to 64-bit
    mov     eax, DWORD PTR [rdi+rsi*4]

By comparison, @Slava's answer using a switch() for C++ makes asm like this for a runtime-variable index. (Code in the previous Godbolt link).

int cpp(data *d, int idx) {
    return (*d)[idx];

    # gcc6.2 -O3, using `default: __builtin_unreachable()` to promise the compiler that idx=0..2,
    # avoiding an extra cmov for idx=min(idx,2), or an extra branch to a throw, or whatever
    cmp     esi, 1
    je      .L6
    cmp     esi, 2
    je      .L7
    mov     eax, DWORD PTR [rdi]
    mov     eax, DWORD PTR [rdi+4]
    mov     eax, DWORD PTR [rdi+8]

This is obviously terrible, compared to the C (or GNU C++) union-based type punning version:

c(type_t*, int):
    movsx   rsi, esi                   # sign-extend this time, since I didn't change idx to unsigned here
    mov     eax, DWORD PTR [rdi+rsi*4]
  • @M.M: good point. It's more of an answer to various comment, and an alternative to Slava's answer. I re-worded the opening bit, so it at least starts off as an answer to the original question. Thanks for pointing that out. Nov 15, 2016 at 8:06
  • While union-based type punning seems to work in gcc and clang while using the [] operator directly on a union member, the Standard defines array[index] as being equivalent to *((array)+(index)), and neither gcc nor clang will reliably recognize that an access to *((someUnion.array)+(index)) is an access to someUnion. The only explanation I can see is that someUnion.array[index] nor *((someUnion.array)+(index)) aren't defined by the Standard, but are merely a popular extensions, and gcc/clang have opted not to support the second but seem to support the first, at least for now.
    – supercat
    Jul 8, 2019 at 15:49

In C++, this is mostly undefined behavior (it depends on which index).

From [expr.unary.op]:

For purposes of pointer arithmetic (5.7) and comparison (5.9, 5.10), an object that is not an array element whose address is taken in this way is considered to belong to an array with one element of type T.

The expression &thing.a is thus considered to refer to an array of one int.

From [expr.sub]:

The expression E1[E2] is identical (by definition) to *((E1)+(E2))

And from [expr.add]:

When an expression that has integral type is added to or subtracted from a pointer, the result has the type of the pointer operand. If the expression P points to element x[i] of an array object x with n elements, the expressions P + J and J + P (where J has the value j) point to the (possibly-hypothetical) element x[i + j] if 0 <= i + j <= n; otherwise, the behavior is undefined.

(&thing.a)[0] is perfectly well-formed because &thing.a is considered an array of size 1 and we're taking that first index. That is an allowed index to take.

(&thing.a)[2] violates the precondition that 0 <= i + j <= n, since we have i == 0, j == 2, n == 1. Simply constructing the pointer &thing.a + 2 is undefined behavior.

(&thing.a)[1] is the interesting case. It doesn't actually violate anything in [expr.add]. We're allowed to take a pointer one past the end of the array - which this would be. Here, we turn to a note in [basic.compound]:

A value of a pointer type that is a pointer to or past the end of an object represents the address of the first byte in memory (1.7) occupied by the object53 or the first byte in memory after the end of the storage occupied by the object, respectively. [ Note: A pointer past the end of an object (5.7) is not considered to point to an unrelated object of the object’s type that might be located at that address.

Hence, taking the pointer &thing.a + 1 is defined behavior, but dereferencing it is undefined because it does not point to anything.

  • Evaluating (&thing.a) + 1 is just about legal because a pointer past the end of an array is legal; reading or writing the data stored there is undefined behaviour, comparing with &thing.b with <, >, <=, >= is undefined behaviour. (&thing.a) + 2 is absolutely illegal.
    – gnasher729
    Nov 16, 2016 at 11:51
  • @gnasher729 Yeah it's worth clarifying the answer some more.
    – Barry
    Nov 16, 2016 at 15:03
  • The (&thing.a + 1) is an interesting case I failed to cover. +1! ... Just curious, are you on the ISO C++ committee?
    – WhiZTiM
    Nov 16, 2016 at 15:51
  • It's also a very important case because otherwise every loop using pointers as a half-open interval would be UB.
    – Jens
    Nov 17, 2016 at 8:06
  • Regarding the last standard citation. C++ is must better specified than C here.
    – 2501
    Nov 18, 2016 at 21:17

This is undefined behavior.

There are lots of rules in C++ that attempt to give the compiler some hope of understanding what you are doing, so it can reason about it and optimize it.

There are rules about aliasing (accessing data through two different pointer types), array bounds, etc.

When you have a variable x, the fact that it isn't a member of an array means that the compiler can assume that no [] based array access can modify it. So it doesn't have to constantly reload the data from memory every time you use it; only if someone could have modified it from its name.

Thus (&thing.a)[1] can be assumed by the compiler to not refer to thing.b. It can use this fact to reorder reads and writes to thing.b, invalidating what you want it to do without invalidating what you actually told it to do.

A classic example of this is casting away const.

const int x = 7;
std::cout << x << '\n';
auto ptr = (int*)&x;
*ptr = 2;
std::cout << *ptr << "!=" << x << '\n';
std::cout << ptr << "==" << &x << '\n';

here you typically get a compiler saying 7 then 2 != 7, and then two identical pointers; despite the fact that ptr is pointing at x. The compiler takes the fact that x is a constant value to not bother reading it when you ask for the value of x.

But when you take the address of x, you force it to exist. You then cast away const, and modify it. So the actual location in memory where x is has been modified, the compiler is free to not actually read it when reading x!

The compiler may get smart enough to figure out how to even avoid following ptr to read *ptr, but often they are not. Feel free to go and use ptr = ptr+argc-1 or somesuch confusion if the optimizer is getting smarter than you.

You can provide a custom operator[] that gets the right item.

int& operator[](std::size_t);
int const& operator[](std::size_t) const;

having both is useful.

  • "the fact that it isn't a member of an array means that the compiler can assume that no [] based array access can modify it." - not true, e.g. (&thing.a)[0] may modify it
    – M.M
    Nov 15, 2016 at 8:06
  • I don't see how the const example has anything to do with the question. That fails only because there is a specific rule that a const object may not be modified, not any other reason.
    – M.M
    Nov 15, 2016 at 8:07
  • 1
    @M.M, it's not an example of indexing into a struct, but it's a very good illustration of how using undefined behavior to reference something by its apparent location in memory, can result in different output than expected, because the compiler can do something else with the UB than you wanted it to.
    – Wildcard
    Nov 15, 2016 at 9:44
  • @M.M Sorry, no array access other than a trivial one through a pointer to the object itself. And the second one is just an example of easy to see side effects of undefined behavior; the compiler optimizes out the reads to x because it knows you cannot change it in a defined way. Similar optimization could occur when you alter b via (&blah.a)[1] if the compiler can prove there was no defined access to b that could alter it; such a change could occur due to seeminly innocuous changes in compiler, surrounding code, or whatever. So even testing that it works isn't sufficient. Nov 15, 2016 at 14:52

Heres a way to use a proxy class to access elements in a member array by name. It is very C++, and has no benefit vs. ref-returning accessor functions, except for syntactic preference. This overloads the -> operator to access elements as members, so to be acceptable, one needs to both dislike the syntax of accessors (d.a() = 5;), as well as tolerate using -> with a non-pointer object. I expect this might also confuse readers not familiar with the code, so this might be more of a neat trick than something you want to put into production.

The Data struct in this code also includes overloads for the subscript operator, to access indexed elements inside its ar array member, as well as begin and end functions, for iteration. Also, all of these are overloaded with non-const and const versions, which I felt needed to be included for completeness.

When Data's -> is used to access an element by name (like this: my_data->b = 5;), a Proxy object is returned. Then, because this Proxy rvalue is not a pointer, its own -> operator is auto-chain-called, which returns a pointer to itself. This way, the Proxy object is instantiated and remains valid during evaluation of the initial expression.

Contruction of a Proxy object populates its 3 reference members a, b and c according to a pointer passed in the constructor, which is assumed to point to a buffer containing at least 3 values whose type is given as the template parameter T. So instead of using named references which are members of the Data class, this saves memory by populating the references at the point of access (but unfortunately, using -> and not the . operator).

In order to test how well the compiler's optimizer eliminates all of the indirection introduced by the use of Proxy, the code below includes 2 versions of main(). The #if 1 version uses the -> and [] operators, and the #if 0 version performs the equivalent set of procedures, but only by directly accessing Data::ar.

The Nci() function generates runtime integer values for initializing array elements, which prevents the optimizer from just plugging constant values directly into each std::cout << call.

For gcc 6.2, using -O3, both versions of main() generate the same assembly (toggle between #if 1 and #if 0 before the first main() to compare): https://godbolt.org/g/QqRWZb

#include <iostream>
#include <ctime>

template <typename T>
class Proxy {
    T &a, &b, &c;
    Proxy(T* par) : a(par[0]), b(par[1]), c(par[2]) {}
    Proxy* operator -> () { return this; }

struct Data {
    int ar[3];
    template <typename I> int& operator [] (I idx) { return ar[idx]; }
    template <typename I> const int& operator [] (I idx) const { return ar[idx]; }
    Proxy<int>       operator -> ()       { return Proxy<int>(ar); }
    Proxy<const int> operator -> () const { return Proxy<const int>(ar); }
    int* begin()             { return ar; }
    const int* begin() const { return ar; }
    int* end()             { return ar + sizeof(ar)/sizeof(int); }
    const int* end() const { return ar + sizeof(ar)/sizeof(int); }

// Nci returns an unpredictible int
inline int Nci() {
    static auto t = std::time(nullptr) / 100 * 100;
    return static_cast<int>(t++ % 1000);

#if 1
int main() {
    Data d = {Nci(), Nci(), Nci()};
    for(auto v : d) { std::cout << v << ' '; }
    std::cout << "\n";
    std::cout << d->b << "\n";
    d->b = -5;
    std::cout << d[1] << "\n";
    std::cout << "\n";

    const Data cd = {Nci(), Nci(), Nci()};
    for(auto v : cd) { std::cout << v << ' '; }
    std::cout << "\n";
    std::cout << cd->c << "\n";
    //cd->c = -5;  // error: assignment of read-only location
    std::cout << cd[2] << "\n";
int main() {
    Data d = {Nci(), Nci(), Nci()};
    for(auto v : d.ar) { std::cout << v << ' '; }
    std::cout << "\n";
    std::cout << d.ar[1] << "\n";
    d->b = -5;
    std::cout << d.ar[1] << "\n";
    std::cout << "\n";

    const Data cd = {Nci(), Nci(), Nci()};
    for(auto v : cd.ar) { std::cout << v << ' '; }
    std::cout << "\n";
    std::cout << cd.ar[2] << "\n";
    //cd.ar[2] = -5;
    std::cout << cd.ar[2] << "\n";
  • Nifty. Upvoted mainly because you proved that this optimizes away. BTW, you can do that much more easily by writing a very simple function, not a whole main() with timing functions! e.g. int getb(Data *d) { return (*d)->b; } compiles to just mov eax, DWORD PTR [rdi+4] / ret (godbolt.org/g/89d3Np). (Yes, Data &d would make the syntax easier, but I used a pointer instead of ref to highlight the weirdness of overloading -> this way.) Nov 15, 2016 at 8:21
  • Anyway, this is cool. Other ideas like int tmp[] = { a, b, c}; return tmp[idx]; don't optimize away, so it's neat that this one does. Nov 15, 2016 at 8:22
  • One more reason I miss operator. in C++17.
    – Jens
    Nov 15, 2016 at 21:58

If reading values is enough, and efficiency is not a concern, or if you trust your compiler to optimize things well, or if struct is just that 3 bytes, you can safely do this:

char index_data(const struct data *d, size_t index) {
  assert(sizeof(*d) == offsetoff(*d, c)+1);
  assert(index < sizeof(*d));
  char buf[sizeof(*d)];
  memcpy(buf, d, sizeof(*d));
  return buf[index];

For C++ only version, you would probably want to use static_assert to verify that struct data has standard layout, and perhaps throw exception on invalid index instead.


It is illegal, but there is a workaround:

struct data {
    union {
        struct {
            int a;
            int b;
            int c;
        int v[3];

Now you can index v:

  • 6
    Many c++ projects think downcasting all over the place is just fine. We still shouldn't preach bad practices. Nov 14, 2016 at 14:04
  • 2
    The union solves the strict aliasing issue in both languages. But type punning through unions is only fine in C, not in C++.
    – Lundin
    Nov 14, 2016 at 14:11
  • 1
    still, I wouldn't be surprised if this works on 100% of all c++ compilers. ever. Nov 14, 2016 at 14:30
  • 1
    You could try it in gcc with the most aggressive optimizer settings on.
    – Lundin
    Nov 14, 2016 at 14:43
  • 1
    @Lundin: union type punning is legal in GNU C++, as an extension over ISO C++. It doesn't seem to be stated very clearly in the manual, but I'm pretty sure about this. Still, this answer needs to explain where it's valid and where it isn't. Nov 14, 2016 at 17:13

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