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Let's say I have a bunch of well-known values, like this (but const char * is just an example, it could be more complicated):

const char *A = "A", *B = "B", *C = "C", *D = "D", *E = "E", *F = "F", *G = "G";

Now let's say I want to behave in a particular way if the result of some expression is in a subset of those:

if (some_complicated_expression_with_ugly_return_type == A ||
    some_complicated_expression_with_ugly_return_type == C ||
    some_complicated_expression_with_ugly_return_type == E ||
    some_complicated_expression_with_ugly_return_type == G)
{
    ...
}

I find myself typing this sort of thing often enough that I would like a shorthand for it.

If the language was Python, I could easily say:

if some_complicated_expression_with_ugly_return_type in [A, C, E, G]:
    ...

Is there a well-known, portable way for me to express this similarly in C++03?

Note that the return type is itself ugly (almost as ugly as the return type of lambda expressions), so I certainly don't want to store it in a local variable.

But the return type does not have to match that of the constants -- for example, if the return type was std::string, it would not be implicitly convertible to const char *, but operator == would be perfectly fine for the comparison.

So far, the best solution I have is to say something like:

const char *items[] = { A, C, E, G };
if (std::find(items, items + sizeof(items) / sizeof(*items),
              some_complicated_expression_with_ugly_return_type)
    != items + sizeof(items) / sizeof(*items))
{
    ...
}

but it's pretty darn ugly. Is there a better way, which also works for non-PODs?

share|improve this question
3  
Isn't switch (some_complicated_expression_with_ugly_return_type) { case A: case B: case E: do something;break; } enough? –  Benjamin Sep 2 '12 at 21:59
1  
Only for integral types, which aren't ugly, so probably aren't present here. –  Pete Becker Sep 2 '12 at 22:01
    
@Benjamin: That's only for integral types, like Pete said. –  Mehrdad Sep 2 '12 at 22:02
    
In your "best solution", you include the return type. If it's acceptable there, why is it not acceptable for a variable? –  hvd Sep 2 '12 at 22:03
1  
@Benjamin: Okay I'll fix the example, thanks for the feedback. –  Mehrdad Sep 2 '12 at 22:39

8 Answers 8

up vote 19 down vote accepted

You could factor your current best solution into a template:

template<class A, class B, size_t n>
inline bool is_in(const A &a, B (&bs)[n]) {
  return std::find(bs, bs + n, a) != bs + n;
}

which you can use like

X items[] = { A, C, E, G };
if (is_in(some_complicated_expression_with_ugly_return_type, items))
  …
share|improve this answer
    
Ahh, I like this... but it's still ugly with the return types. –  Mehrdad Sep 2 '12 at 22:16
3  
@Mehrdad, Which return types? The one from your expression I'm treating as a black box here, so there is little I can do about it here. The only type you explicitely have to name is X, the type of the values you compare against. As you already refer to those values using names, I assumed that these at least have some reasonably short type name. –  MvG Sep 2 '12 at 22:22
    
Oh my bad, you're right -- I confused X with the return type of the function. This looks pretty nice actually, I like this one the best so far! Thanks. :) –  Mehrdad Sep 2 '12 at 22:31

If you have C++11:

auto res = some_complicated_expression_with_ugly_return_type;
if (res == A
    || res == C
    || res == E
    || res == G) {
}

if not, you can still eliminate the type declaration by using a template function:

template <class T>
bool matches(T t) {
    return t == A || t == C || t == E || t == G;
}

if (matches(some_complicated_expression_with_ugly_return_type)) {
}
share|improve this answer
1  
I specifically mentioned I wanted to stay compatible with C++03... +1 though, since it might help others who have C++11. –  Mehrdad Sep 2 '12 at 22:06
2  
My answer also gives a solution that works with C++03. –  Pete Becker Sep 2 '12 at 22:06
    
Aren't you initialising res to expression == A || res == C || ...? –  hvd Sep 2 '12 at 22:07
1  
It solves the problem in your original sample code (although not the sample as it was edited after I posted my answer). And remember, these posts are for the benefit of other readers as well. If the answer isn't helpful to you, that doesn't mean it won't be helpful to others. –  Pete Becker Sep 3 '12 at 0:22
1  
@hvd: Er, what I've been telling you is that it's a bigger issue than just genericity/reusability. It's readability. MvG's answer leaves the logic coherent -- you don't have to suddenly go hunting for a random function every time you come across an if statement like this. This one does the opposite -- it creates spaghetti logic, branching your code into all sorts of functions scattered around the file (and good luck finding them). One of them is readable, the other isn't. If you don't understand what I mean then never mind; I don't know how else to explain it, sorry. –  Mehrdad Sep 3 '12 at 8:59

You could use a switch:

switch (some_complicated_expression_with_ugly_return_type) {
  case A: case C: case E: case G:
    // do something
  default:
    // no-op
}

This only works with integer and enum types, note.

For more complex types, you can use C++11's auto, or for C++03, boost's BOOST_AUTO:

auto tmp = some_complicated_expression_with_ugly_return_type;
// or
BOOST_AUTO(tmp, some_complicated_expression_with_ugly_return_type);

if (tmp == A || tmp == C || tmp == E || tmp == G) {
  // ...
}
share|improve this answer
    
The BOOST_AUTO in particular sounds like a very good match to what the OP asks. –  MvG Sep 2 '12 at 22:46

(Edit: Turns out my original trick with a dummy type didn't work, I was misled by a lucky accident in my tests. Let's try that again...)

With a couple of helper templates you can write a general solution for this kind of situation:

template <typename T1> class Matcher {
public:
    explicit Matcher(T1 t1): val(t1), flag(false) {}
    template <typename T2> Matcher& operator()(T2 t2)
        { flag |= val == t2; return *this; }
    operator bool() const { return flag; }
private:
    T1 val;
    bool flag;
};
template <typename T1> Matcher<T1> match(T1 t1) { return Matcher<T1>(t1); }

// example...
string s = whatever;
if (match(s)("foo")("bar")("zap")) { do_something(); }

You can match against as many arguments as you want.

share|improve this answer
    
Oooh I like this, can't wait to try it! Thanks! +1 –  Mehrdad Sep 3 '12 at 3:20
    
The original OR expression will finish once any condition meets, but Matcher will try all conditions which is vital difference. –  Chang Sep 4 '12 at 13:51
    
You can easily fix that by changing flag|=val==t2 to flag=flag||val==t2. –  Ross Smith Sep 4 '12 at 21:25

Expressions of the type

if (some_complicated_expression_with_ugly_return_type == A ||
    some_complicated_expression_with_ugly_return_type == C ||
    some_complicated_expression_with_ugly_return_type == E ||
    some_complicated_expression_with_ugly_return_type == G)
{
    ...
}

are quite common in code (well, a pre-computed expression is anyway). I think the best you can do for readability is pre-compute the expression and keep it as is.

ugly_return_type x = some_complicated_expression_with_ugly_return_type;
if (x == A ||
    x == C ||
    x == E ||
    x == G)
{
    ...
}

Developers are used to this type of syntax. This makes it a whole lot easier to understand when someone else is reading your code

It also expresses what you want perfectly. There's a reason this type of syntax is so widely used in existing code - because other alternatives are worse for readability.

Of course, you could wrap the condition in a function, but only if it's reusable and it logically makes sense (besides the point IMO).

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1  
It's not always easy to get the return type, esp if you're using bind/lambda and stuff. –  Macke Sep 4 '12 at 8:29

This can be done using variadic functions in c++03 as follows:

template <typename T>
bool MatchesOne( T _lhs, int _count, ...)
{
    va_list vl;
    va_start(vl,_count);
    for (int i=0;i<_count;i++)
    {
        int rhs=va_arg(vl,int);
        cout << "rhs = " << rhs << endl;
        if (_lhs == rhs) return true;
    }
    va_end(vl);
    return false;
}

int main(){
    float ff = 3.0;
    if (MatchesOne(ff, 5, 1, 2, 4, 5, 3))
    {
        cout << "Matches" << endl;
    }
    return 0;
}

If you know the types of all the expressions will have the same type as _lhs, you can change int rhs=va_arg(vl,int); to T rhs=va_arg(vl,T);

You can also do this elegantly using variadic templates in c++11:

template<typename T, typename T2>
bool one_equal(const T & _v1, const T2 & _v2)
{
    return _v1 == _v2;
}

template<typename T, typename T2, typename... Args>
bool one_equal(const T & _v1, const T2 & _v2, Args... args)
{
    return _v1 == _v2 || one_equal(_v1, args...);
}

...

if (one_equal(some_complicated_expression, v1, v2, v3, v4))
{

}

Okay one final hack-ish solution. It works, but makes the implementer of this function do a lot of repetitive work.

template <typename T1, typename T2>
bool match_one(T1 _v1, T2 _v2)
{
    return _v1 == _v2;
}

template <typename T1, typename T2, typename T3>
bool match_one(T1 _v1, T2 _v2, T3 _v3)
{
    return _v1 == _v3 || match_one(_v1, _v2);
}

template <typename T1, typename T2, typename T3, typename T4>
bool match_one(T1 _v1, T2 _v2, T3 _v3, T4 _v4)
{
    return _v1 == _v4 || match_one(_v1, _v2, _v3);
}

template <typename T1, typename T2, typename T3, typename T4, typename T5>
bool match_one(T1 _v1, T2 _v2, T3 _v3, T4 _v4, T5 _v5)
{
    return _v1 == _v5 || match_one(_v1, _v2, _v3, _v4);
}
share|improve this answer
    
Downvoter care to comment? –  Rollie Sep 2 '12 at 22:17
    
I wonder, too. Probably he has never seen variadic templates. –  JohnB Sep 2 '12 at 22:20
    
C couple notes... regarding the C++11 version: it's completely ignoring the fact that I said C++03 in the question. Regarding the C++03 version: varargs are very dangerous with non-PODs, and the code is error-prone, because it's quite easy for the count parameter to get out of sync with the rest of the args. –  Mehrdad Sep 2 '12 at 22:58
    
One more try added - c++03, no va_args. Requires a bit of busy work on your part, but if you are using it frequently throughout your program with a reasonably low number of comparisons, it won't take more than a few minutes to implement. Advantage over other solutions is that it allows comparisons of any type, so all the variables on the right hand side need not be of the same type (original question didn't stipulate one way or another). –  Rollie Sep 3 '12 at 0:25

If not switch, maybe something like this, I didn't use it, but may be a draft to something working?

template <class ReturnType>
bool average(ReturnType expression, int count, ...)
{
  va_list ap;
  va_start(ap, count); //Requires the last fixed parameter (to get the address)
  for(int j=0; j<count; j++)
    if(expression==va_arg(ap, ReturnType))
      return true;
    return false
  va_end(ap);
}
share|improve this answer
    
Varargs are very dangerous with non-PODs. –  Mehrdad Sep 2 '12 at 22:56

C++11:

template<typename T1, typename T2>
bool equalsOneOf (T1&& value, T2&& candidate) {
   return std::forward<T1>(value) == std::forward<T2>(candidate);
}

template<typename T1, typename T2, typename ...T>
bool equalsOneOf (T1&& value, T2&& firstCandidate, T&&...otherCandidates) {
   return (std::forward<T1>(value) == std::forward<T2>(firstCandidate))
     || equalsOneOf (std::forward<T1> (value), std::forward<T>(otherCandidates)...);
}

if (equalsOneOf (complexExpression, A, D, E)) { ... }

C++03:

template<typename T, typename C>
bool equalsOneOf (const T& value, const C& c) { return value == c; }

template<typename T, typename C1, typename C2>
bool equalsOneOf (const T& value, const C1& c1, const C2& c2) {
    return (value == c2) || equalsOneOf (value, c1);
}

template<typename T, typename C1, typename C2, typename C3>
bool equalsOneOf (const T& value, const C1& c1, const C2& c2, const C3& c3) {
    return (value == c3) || equalsOneOf (value, c1, c2);
}

template<typename T, typename C1, typename C2, typename C3, typename C4>
bool equalsOneOf (const T& value, const C1& c1, const C2& c2, const C3& c3, const C4& c4) {
    return (value == c4) || equalsOneOf (value, c1, c2, c3);
}

template<typename T, typename C1, typename C2, typename C3, typename C4, typename C5>
bool equalsOneOf (const T& value, const C1& c1, const C2& c2, const C3& c3, const C4& c4, const C5& c5) {
    return (value == c5) || equalsOneOf (value, c1, c2, c3, c4);
}

// and so on, as many as you need
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