While reading an article, I came across the following function:

SolidColor::SolidColor(unsigned width, Pixel color)
  : _width(width),
    _color(color) {}

Rasterizer::RasterInfo SolidColor::rasterize(unsigned, Pixel *target) {
  *target = _color;
  return {
    .offset = 0,
    .length = 1,
    .stretch_cycles = (_width - 1) * 4,
    .repeat_lines = 1000,

What is the author doing with the return statement? I haven't seen anything like that before, and I do not know how to search for it... Is it valid for plain C too?

Edit: link to the original article

  • 5
    Valid in C, non-standard extension of some compilers for C++ (as of C++11, this functionality is not in the C++ standard.) Jul 23, 2015 at 17:21
  • 2
    See the C standard, section Compound literals, point 10 (regarding designated initializers).
    – Michael
    Jul 23, 2015 at 17:21
  • 1
    I'm pretty sure that's valid for plain C, and not valid for C++.
    – davmac
    Jul 23, 2015 at 17:21
  • 1
    @ShafikYaghmour: there may be many duplicates, but the nominated one wasn't really (even close to) a duplicate--it was asking why C++ doesn't have designated intializers (and the answers were pretty much restricted to the question of why). This is asking about what the syntax means, not why it isn't present in C++. The one you've found is at least reasonably close to being a duplicate (but at least IMO, when closing as a duplicate, it's important not to just close, but to be sure the answers to the nominated duplicate really answer the question being asked here). Jul 23, 2015 at 17:32
  • 1
    @Michael: A compound literal would require a parenthtised type before the {. And desgnated initializers are not standard C++ (but - afaik - gcc allows them for C++, too as extension). Jul 23, 2015 at 17:37

2 Answers 2


This isn't valid C++.

It's (sort of) using a couple features from C known as "compound literals" and "designated initializers", which a few C++ compilers support as an extension. The "sort of" comes from that fact that to be a legitimate C compound literal, it should have syntax that looks like a cast, so you'd have something like:

return (RasterInfo) {
    .offset = 0,
    .length = 1,
    .stretch_cycles = (_width - 1) * 4,
    .repeat_lines = 1000,

Regardless of the difference in syntax, however, it's basically creating a temporary struct with members initialized as specified in the block, so this is roughly equivalent to:

// A possible definition of RasterInfo 
// (but the real one might have more members or different order).
struct RasterInfo {
    int offset;
    int length;
    int stretch_cycles;
    int repeat_lines;

RasterInfo rasterize(unsigned, Pixel *target) { 
    *target = color;
    RasterInfo r { 0, 1, (_width-1)*4, 1000};
    return r;

The big difference (as you can see) is that designated initializers allow you to use member names to specify what initializer goes to what member, rather than depending solely on the order/position.

  • Just return { 0, 1, (_width-1)*4, 1000}; in C++11 works, no need for r. Which brings the C++ syntax closer to the C99 syntax, and makes the fusion of the two be the syntax used above. Jul 23, 2015 at 18:26

It is a C99 compound literal. This feature is specific to C99, but gcc and clang choose to implement it in C++ as well(as extension).

6.26 Compound Literals

ISO C99 supports compound literals. A compound literal looks like a cast containing an initializer. Its value is an object of the type specified in the cast, containing the elements specified in the initializer; it is an lvalue. As an extension, GCC supports compound literals in C90 mode and in C++, though the semantics are somewhat different in C++.

  • 2
    Uhm, what? "... looks like a cast containing an initializer." How does that fit the question? -1.
    – Barry
    Jul 23, 2015 at 17:40
  • That is not compound initializer_! That would require a parenthetized type before the block. And the original code is C++ even which does not have designated initializers. Jul 23, 2015 at 17:44
  • This answer is incorrect. It's similar to a C99 compound literal but it definitely isn't one. Jul 23, 2015 at 22:54

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