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I've got a function

foo(int, int, int, int/long long/_int64/double/long double/char *, int ONLY IF previous char * - otherwise unneeded)

Problem is, char * implementation is different than the value types due to requiring a string copy. Yes, this is an interface to old code, so i cannot use std::string :/

Currently, I've got it as a template, and a function overload for char *, with the extra argument. However, all operations for the other types are also valid on char *, so if the caller forgets the last argument, the function silently matches the template instead, producing the wrong logic.

Is there any way I can force the usage of the overload/use default arguments in function templates/something that will allow for a different signature (extra argument) for a specific type without silently matching a lesser signature?

More: No access to C++11 yet, but I'm open to see a suggestion using it to help push for adoption. No boost, but same as above

I have also tried

return_type foo(int,int,int,typename std::enable_if<!std::is_pointer<T>::value, T>::type & value2update)

without any luck. It then claims that the call with a double & parameter fails to match.

share|improve this question
What exactly do you mean with "otherwise unneeded"? This should be implementable easily through overloading. – Xeo Mar 1 '13 at 23:42
I assume the extra int is a length? Could you take a StringPiece instead to avoid the need for special-casing entirely? – Scott Lamb Mar 1 '13 at 23:43
@Xeo, yeah I just wanted to avoid code duplication for each type so wanted to templatize the other types, which all share exactly the same code. @ Scott Lamb, yes, for sure that is a valid - and likely the best - option. However, this integration will happen in around 3000 places in the codebase, so having to add in the StringPiece creation logic in the calling code was something I would have liked to avoid. I was just hoping there was something I was doing wrong to force specialization - have to investigate Thomas' answer more thoroughly – im so confused Mar 4 '13 at 15:39
If this is how you wanted to go, you could look into clang tools for automatic refactoring. I hear it's awesome for this kind of tedious change, though I've never tried it myself. – Scott Lamb Mar 6 '13 at 7:17
up vote 2 down vote accepted

You could make the linker help you. Declare, but do not define, your function template and char* overload in a header:

template<typename T>
foo(int, int, int, T);
foo(int, int, int, char*, int);

In the implementation file (.cpp/.cc), implement both:

template<typename T>
foo(int, int, int, T) { ... }

foo(int, int, int, char*, int) { ... }

And explicitly instantiate versions for the types you want to accept:

foo(int, int, int, int);
foo(int, int, int, long long);
// etc.

If I'm understanding correctly, ScottLamb suggests something like this in the comments. Header:

foo(int, int, int, int);
foo(int, int, int, long long);
foo(int, int, int, char*, int);

Implementation file (.cpp/.cc):

namespace {
    template<typename T>
    foo_tmpl(int, int, int, T) { ... }

foo(int, int, int, int) { foo_tmpl(...); }
foo(int, int, int, long long) { foo_tmpl(...); }
foo(int, int, int, char*, int) { ... }

This is preferable from the perspective of someone using the header (they can see immediately which overloads are available) but takes slightly more work on the implementation side.

share|improve this answer
IMHO the header would be more straightforward/readable if you listed each supported overload. If the definition is non-trivial, you could delegate to a template function in an anonymous namespace in the implementation file to reduce duplication. – Scott Lamb Mar 2 '13 at 2:12
From the looks of it, this is the best answer. Just to be clear, are the explicit instantiations in the header or cpp file? @ScottLamb would you care to explain your comment? Are you saying the instantiations should be listed in the header as I just mentioned, and then define it in the cpp file? BTW this entire class is scoped in a namespace if that changes things – im so confused Mar 4 '13 at 15:56
Updated with what I think he means. – Thomas Mar 4 '13 at 17:18
Yes, that's what I meant, thanks! – Scott Lamb Mar 5 '13 at 19:05
@ScottLamb, Thomas, I've put in place the suggested format after the update. Thank you so much. As a quick note, my template function also makes use of a member function. For that reason I cannot wrap it in an anonymous namespace correct? I had to privately declare it in the header as well. – im so confused Mar 5 '13 at 20:33

Use a helper class string_ref that bundles the both parameters for you:

class string_ref {
  const char *str;
  std::size_t len;
  string_ref(std::string const& s)
    : str(s.c_str()), len(s.size()) {}

  string_ref(const char *c, std::size_t len)
    : str(c), len(len) {}

  const char * c_str() const { return str; }
  std::size_t size() const { return len; }

And then

foo(int, int, int, int/long long/_int64/double/long double/const char*, [int])

Just add

foo(int, int, int, string_ref)
   foo(int, int, int, c_str(), size());

A string_ref can be created from a const char* and int with no overhead and both can be extracted easily for further passing to C functions.

(The naming string_ref is not random.)

share|improve this answer
This is not safe! std::string::c_str() is only valid as long as the string object still exists and isn't modified. – Thomas Mar 1 '13 at 23:47
I don't see a problem if this is used with care. foo(..., string_ref(std::string("ok"))) for example should be fine. – ipc Mar 1 '13 at 23:49
I like this answer as it is sort of the way it should be done, i think - very close to just using std::string. In addition, I appreciate the comment on no overhead - that is of critical concern in this case, and in other situations, more elegant object-oriented solutions have been discarded for raw speed after profiling. Is it truly "no" overhead? I fail to see how the actual assignment assembler instructions are not generated for this string_ref object. – im so confused Mar 4 '13 at 16:51

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