What does this C++ setter/getter pattern break?

Using the GLSL syntax in C++

I wrote custom vector classes such as `vec2`, `vec3` etc. that mimic the GLSL types and look roughly like this:

``````struct vec3
{
inline vec3(float x, float y, float z)
: x(x), y(y), z(z) {}
union { float x, r, s; };
union { float y, g, t; };
union { float z, b, p; };
};
``````

Operations on vectors are implemented this way:

``````inline vec3 operator +(vec3 a, vec3 b)
{
return vec3(a.x + b.x, a.y + b.y, a.z + b.z);
}
``````

This allows me to create vectors and access their components using a GLSL-like syntax and perform operations on them almost as if they were numeric types. The unions allow me to refer to the first coordinate indifferently as `x` or as `r`, as is the case in GLSL. For instance:

``````vec3 point = vec3(1.f, 2.f, 3.f);
vec3 other = point + point;
point.x = other.b;
``````

The problem of swizzling

But GLSL also allows swizzled access, even with holes between components. For instance `p.yx` behaves like a `vec2` with `p`’s `x` and `y` swapped. When no component is repeated, it is also an lvalue. Some examples:

``````other = point.xyy; /* Note: xyy, not xyz */
other.xz = point.xz;
point.xy = other.xx + vec2(1.0f, 2.0f);
``````

Now this could be done using standard getters and setters such as `vec2 xy()` and `void xy(vec2 val)`. This is what the GLM library does.

Transparent getter and setter

However, I devised this pattern that lets me do exactly the same in C++. Since everything is a POD-struct, I can add more unions:

``````template<int I, int J> struct MagicVec2
{
friend struct vec2;
inline vec2 operator =(vec2 that);

private:
float ptr[1 + (I > J ? I : J)];
};

template<int I, int J>
inline vec2 MagicVec2<I, J>::operator =(vec2 that)
{
ptr[I] = that.x; ptr[J] = that.y;
return *this;
}
``````

And eg. the `vec3` class becomes (I simplified things a bit, for instance nothing prevents `xx` from being used as an lvalue here):

``````struct vec3
{
inline vec3(float x, float y, float z)
: x(x), y(y), z(z) {}

template<int I, int J, int K>
inline vec3(MagicVec3<I, J, K> const &v)
: x(v.ptr[I]), y(v.ptr[J]), z(v.ptr[K]) {}

union
{
struct { float x, y, z; };
struct { float r, g, b; };
struct { float s, t, p; };

MagicVec2<0,0> xx, rr, ss;
MagicVec2<0,1> xy, rg, st;
MagicVec2<0,2> xz, rb, sp;
MagicVec2<1,0> yx, gr, ts;
MagicVec2<1,1> yy, gg, tt;
MagicVec2<1,2> yz, gb, tp;
MagicVec2<2,0> zx, br, ps;
MagicVec2<2,1> zy, bg, pt;
MagicVec2<2,2> zz, bb, pp;
/* Also MagicVec3 and MagicVec4, of course */
};
};
``````

Basically: I use a union to mix the vector’s floating-point components with a magic object which is not really a `vec2` but can be cast implicitly to a `vec2` (because there’s a `vec2` constructor allowing it), and can be assigned a `vec2` (because of its overloaded assignment operator).

I am very satisfied with the result. The GLSL code above works and I believe I get decent type safety. And I can `#include` a GLSL shader in my C++ code.

Limitations

Of course there are limitations. I know of the following ones:

• `sizeof(point.xz)` will be `3*sizeof(float)` instead of the expected `2*sizeof(float)`. This is by design and I do not know whether this could be problematic.
• `&foo.xz` cannot be used as a `vec2*`. This should be OK because I only ever pass these objects by value.

So my question is: what may I have overlooked that will make my life difficult with this pattern? Also, I have not found this pattern anywhere else yet, so if anyone knows its name I am interested.

Note: I wish to stick to C++98, but I do rely on the compiler allowing type-punning through unions. My reason for not wanting C++11 yet is the lack of compiler support on several of my target platforms; all the compilers that are of interest to me support type punning, though.

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Because you're using C++98 (C++11 doesn't have this problem), you're invoking UB when you read a value from a union that was not the last value written in that union –  Seth Carnegie Jan 26 '12 at 1:18
@SethCarnegie: you are right, I do rely on the compiler explicitly supporting this; I am adding a note about it. –  Sam Hocevar Jan 26 '12 at 1:30
I don't see anything that would work as a proper getter here; given a `vec3 v1`, there appears to be no way for `v1.xz` to be assigned correctly to an actual `vec2 v2`, since it doesn't look like anything reorders the elements (`v1.z` would have to go into `v2.y`, which is a different offset into the vector). Did you leave that out of the post, or am I missing something? –  Michael Madsen Jan 26 '12 at 1:59
@MichaelMadsen: see how the reordering is done in the `vec3::vec3(MagicVec3<>const&)` constructor. I omitted it for brevity, but there is of course one for `vec2`, too. Since that constructor is not `explicit`, any method taking a `vec2` will also implicitly accept a `MagicVec2`. The conversion is therefore delayed until the contents are actually needed. –  Sam Hocevar Jan 26 '12 at 7:57
@SethCarnegie: all members of the union have the same type, hence their address may alias, so I think it's defined. What requires compiler support would be to read/write to differnet union members with a different type afaict. –  Pierre Habouzit Jan 26 '12 at 12:17
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In short: I think that it is difficult to make sure that this pattern works - that's why you are asking. Moreover, this pattern could be replaced by a standard proxy pattern, for which correctness is easier to guarantee. I have to admit though that the storage overhead of a proxy-based solution is a problem when the proxies are created statically.

Correctness of the above code

This is code where there is no obvious bug; but paraphrasing C. A. R. Hoare, this is not code where there is obviously no bug. Moreover, how hard is it to convince oneself that there is no bug? I do not see any reason why the pattern would not work - but it is not so easy to prove (even informally) that it will work. In fact, trying doing a proof could fail and point out to some problems. To be safe, I would disable all implicitly-generated constructors/assignment operators for `MagicVecN` classes, just to avoid considering all the associated complications (see subsection below); however doing that is forbidden, because for union members one cannot override the implicitly defined copy assignment operator, as explained by the standard draft I have and by GCC's error message:

``````member ‘MagicVec2<0, 0> vec3::<anonymous union>::xx’ with copy assignment operator not allowed in union
``````

In the attached gist, I instead provide an implementation manually to be safe.

Note that MagicVec2's assignment operator should accepts its parameter by const reference (see example below, where this works); implicit conversions still happen (the const reference will point to the created temporary; this would not work without the const qualifier).

Almost problems, but not quite

I thought a found a bug (which I didn't), but it is still somewhat interesting to consider - just to see how many cases must be covered to rule out potential bugs. Would `p.xz = p.zx` produce the correct results? I thought that `MagicVec2`'s implicit assignment operator would be invoked, leading to incorrect results; in fact, it isn't (I believe) because `I` and `J` are different and part of the type. What when the type is the same? `p.xx = q.rr` is safe, but `p.xx = p.rr` is tricky (even though it might be stupid, but it should still not corrupt memory): is the implicitly-generated assignment operator `memcpy`-based? The answer seems to be no, but if yes, this would be a `memcpy` between overlapping memory intervals, which is undefined behavior.

UPDATE: An actual problem

As noticed by the OP, the default copy assignment operator is also invoked for the expression `p.xz = q.xz`; in that case, it will in fact also copy the `.y` member. As mentioned above, the copy assignment operator cannot be disabled or modified for datatypes which are part of an union.

The proxy pattern

Moreover, I believe that there is a much simpler solution, namely the proxy pattern (which you are partially using). `MagicVecX` should contain a pointer to the containing class instead of `ptr`; this way you need no trick using unions.

``````template<int I, int J> struct MagicVec2
{
friend struct vec2;
inline MagicVec2(vec2* _this): ptr(_this) {}
inline vec2 operator=(const vec2& that);
private:
float *ptr;
};
``````

I tested this by compiling (but not linking) this code, which sketches the proposed solution: https://gist.github.com/1775054. Note that the code is not complete nor tested - one should also override the copy constructor of `MagicVecX`.

-
Well thanks a lot for the thorough analysis, suggestions and fixes! I am not sure I should update the code in the question, but I fixed `operator=` to take a const reference in my personal codebase, as per your suggestion. To answer a few of your points: `p.xz = p.zx` works because the compiler is forced to create a temporary `Vec2`. Assigning `p.xx` should be disallowed; I fixed that simply by marking `xx` and others `const`. But you raise the interesting point that `p.xz = q.xz` clobbers `p.y` because of the implicit assignment operator. This is indeed a real bug! –  Sam Hocevar Feb 9 '12 at 11:10
By the way, the reason I do not wish to use the proxy pattern is because it changes the object's size -- since on some platforms eg. `vec4` is aliased to a MMX or AltiVec vector of 4 floats, I cannot have its size be anything but 16 bytes. –  Sam Hocevar Feb 9 '12 at 13:36
Well it seems that the whole pattern collapses because C++98 won't let me disable the implicit assignment operator. Could you maybe make it clearer that `p.xz = q.xz` will fail, so that I can accept your answer? Thanks. –  Sam Hocevar Feb 9 '12 at 17:17
Actually I hadn't thought about 'p.xz = q.xz', although I did say that I feared the implicit assignment operator was a problem. –  Blaisorblade Feb 9 '12 at 23:31
I made a small update to the answer. Now it'd make sense to rewrite it, but it would take too much time. –  Blaisorblade Feb 9 '12 at 23:37

Okay, I have found one problem already, though not directly with the code above. If `vec3` is somehow made a template class in order to support eg. `int` in addition to `float`, and the `+` operator becomes:

``````template<typename T>
inline vec3<T> operator +(vec3<T> a, vec3<T> b)
{
return vec3<T>(a.x + b.x, a.y + b.y, a.z + b.z);
}
``````

Then this code will not work:

``````vec3<float> a, b, c;
...
c = a.xyz + b;
``````

The reason is that figuring the arguments for `+` will require both template argument deduction (`T = float`) and an implicit conversion (from `MagicVec3<T,0,1,2>` to `vec3<T>`, which is not allowed.

There is however a solution acceptable for me: write all possible explicit operators.

``````inline vec3<int> operator +(vec3<int> a, vec3<int> b)
{
return vec3<int>(a.x + b.x, a.y + b.y, a.z + b.z);
}

inline vec3<float> operator +(vec3<float> a, vec3<float> b)
{
return vec3<float>(a.x + b.x, a.y + b.y, a.z + b.z);
}
``````

This will also let me define rules for implicit promotion, for instance I can decide that `vec3<float> + vec3<int>` is legal and will return a `vec3<float>`.

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