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We are working with an inhouse library which features a StringBuilder class which is used to turn a list of VariableValue objects into a string. VariableValue objects can be constructed from arbitrary types (by specializing a convertVariable template function). Here's the code which describes the scenario:

struct VariableValue {
  // Construct a 'VariableValue' object, a variant type which can represent values of
  // one of four types: string, number (integer), boolean and floating point.
  explicit VariableValue( const std::string &serializedData );

  // Getters, typesafe; will yield an exception when calling the wrong getter.
  const std::string &asString() const;
  bool asBoolean() const;
  // ..  

  // Convert any VariableValue object into a string
  static std::string convertToString( const VariableValue &v );

// Template to be specialized so that user types can be casted into a
// VariableValue object
template <typename T>
VariableValue convertVariable( T v );

// Helper class to 'concatenate' multiple VariableValue objects into a single string.
class StringBuilder {
  const std::string &result() const;

  template <class T>
  StringBuilder &operator<<( T v ) {
    return *this << convertVariable( v );

  std::ostringstream m_stream;

template <>
inline StringBuilder &StringBuilder::operator<<( const VariableValue &v ) {
  m_stream << VariableValue::convertToString( v );
  return *this;

This all woreds very well. Clients just had to provide an appropriate specialization for the convertVariable template (our library already provides plenty of specializations for various types) and then StringBuilder can be used. Almost.

The problem with this is that it doesn't work with types which are not copyable. All template functions take their argument by value. And in the case of the convertVariable template it's quite expensive to change the signature (because there are quite a lot of specializations). So even though I can make the StringBuilder::operator<< template take a const T &, this won't help much since the convertVariable instantiation will be just called with a T (since the reference-to-const part is stripped while deducing the template types). If I fix this by specifying the type explicitely, as in:

class StringBuilder {
  // ...

  template <class T>
  StringBuilder &operator<<( const T &v ) {
    return *this << convertVariable<const T &>( v );

The linker will complain because it no longer finds the old specializations (like e.g. template <> VariableValue convertVariable( int )) since it looks for specializations which take a reference-to-const.

Does anybody know how I can adjust the StringBuilder class so that I can pass non-copyable objects (that is, objects whose type neither allows copy construction nor copy assignment) to the operator<< function?

share|improve this question
What it, for your non-copyable type Foo, you specialize convertVariable for const Foo& instead of Foo, and change StringBuilder::operator<< to take const T& always? As far as I can see, that should mean that the call to convertVariable(v) will pass by value if the user has provided a value specialization, and pass by reference if a reference specialization, so no need for a big disruptive change. I may have missed something. –  Steve Jessop Nov 15 '10 at 12:30
@Steve Jessop: Unfortunately not; it seems that my compiler (MSVC9) immediately bails out when it sees that convertVariable takes a T by value. Implementing your suggestion bails out when calling convertVariable from within operator<<. I can fix this by calling convertVariable as shown in my second code example (explicitely specifying const T & as the type to use) - but doing so breaks all the existing convertVariable specializations (e.g. there is no const int & specialization). –  Frerich Raabe Nov 15 '10 at 12:55
ah, OK. Yes, it chooses the "wrong" specialization to try to call. As icecrime says, overloads are the answer. –  Steve Jessop Nov 15 '10 at 13:42

2 Answers 2

up vote 3 down vote accepted

I'm not quite sure my answer will be of any help, but it's worth trying. From your post, I tend to think that the appropriate solution is to change the signature of convertVariable. You say that this is expensive because there are a lot of specialization, but I think it could actually be free depending on the way you chose to 'specialize'.

This article offers a nice guideline for these kind of things :

Moral #1: If you want to customize a function base template and want that customization to participate in overload resolution (or, to always be used in the case of exact match), make it a plain old function, not a specialization. And, if you do provide overloads, avoid also providing specializations.


For another thing, function template specializations don't overload. This means that any specializations you write will not affect which template gets used, which runs counter to what most people would intuitively expect. After all, if you had written a nontemplate function with the identical signature instead of a function template specialization, the nontemplate function would always be selected because it's always considered to be a better match than a template.

Indeed, instead of specializing for a type UncopyableClass, you could very well use overloading :

VariableValue convertVariable( const UncopyableClass &t ) { /* ... */ }

It's not a specialization but an overload, and it should work exactly as expected. Note however that StringBuilder::operator<< must take a const reference parameter.

share|improve this answer
+1: Nice! This seems to work; it didn't occur to me that you could overload a convertVariable function instead of specialization a template with the same name. Knowing this, I probably could've used overloading all the time. The only downside of this approach is that clients will have to know whether to specialize the convertVariable template, or whether to overload the convertVariable function. –  Frerich Raabe Nov 15 '10 at 13:12

I don't see any advantage into using this class versus simply using the std::ostream interface.

The soundest advise I have would be the dump the class and its bugs (std::string const& str() const for example) and simply go ahead with the stream class by overloading operator<< appropriately for those classes that need streaming.

share|improve this answer
Note that the StringBuilder class is actually implemented in terms of std::ostringstream. We don't use std::ostream directly since there are quite a lot of convertVariable specializations for which no operator<< overload (for use with std::ostream) is available. That side, I think it's actually quite nice not to inherit std::ostream but just reuse (and expose!) the interface we need. –  Frerich Raabe Nov 15 '10 at 13:00

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