doctest needs to be able to convert types you use in assertions and logging expressions into strings (for logging and reporting purposes). Most built-in types are supported out of the box but there are three ways that you can tell doctest how to convert your own types (or other, third-party types) into strings.
operator<<
overload for std::ostream
This is the standard way of providing string conversions in C++ - and the chances are you may already provide this for your own purposes. If you're not familiar with this idiom it involves writing a free function of the form:
std::ostream& operator<< (std::ostream& os, const T& value) { os << convertMyTypeToString(value); return os; }
(where T
is your type and convertMyTypeToString
is where you'll write whatever code is necessary to make your type printable - it doesn't have to be in another function).
You should put this function in the same namespace as your type.
Alternatively you may prefer to write it as a member function:
std::ostream& T::operator<<(std::ostream& os) const { os << convertMyTypeToString(*this); return os; }
doctest::toString
overloadIf you don't want to provide an operator<<
overload, or you want to convert your type differently for testing purposes, you can provide an overload for toString()
for your type which returns doctest::String
.
namespace user { struct udt {}; doctest::String toString(const udt& value) { return convertMyTypeToString(value); } }
Note that the function must be in the same namespace as your type. If the type is not in any namespace - then the overload should be in the global namespace as well. convertMyTypeToString
is where you'll write whatever code is necessary to make your type printable.
doctest::StringMaker<T>
specialisationThere are some cases where overloading toString
does not work as expected. Specialising StringMaker<T>
gives you more precise and reliable control - but at the cost of slightly more code and complexity:
namespace doctest { template<> struct StringMaker<T> { static String convert(const T& value) { return convertMyTypeToString(value); } }; }
By default all exceptions deriving from std::exception
will be translated to strings by calling the what() method. For exception types that do not derive from std::exception
- or if what()
does not return a suitable string - use REGISTER_EXCEPTION_TRANSLATOR
. This defines a function that takes your exception type and returns a doctest::String
. It can appear anywhere in the code - it doesn't have to be in the same translation unit. For example:
REGISTER_EXCEPTION_TRANSLATOR(MyType& ex) { return doctest::String(ex.message()); }
Note that the exception may be accepted without a reference but it is considered bad practice in C++.
An alternative way to register an exception translator is to do the following in some function - before executing any tests:
// adding a lambda - the signature required as a function pointer is `doctest::String(*)(exception_type)` doctest::registerExceptionTranslator<int>([](int in){ return doctest::String("int: ") + doctest::toString(in); });
The order of registering exception translators can be controlled - simply call the explicit function in the required order or list the exception translators with the macro in a top-to-bottom fashion in a single translation unit - everything that auto-registers in doctest works in a top-to-bottom way for a single translation unit (source file).
std::vector<T>
and other types/exceptions.String
is used when specializing StringMaker<T>
or overloading toString()
- it is the string type doctest works with. std::string
is not an option because doctest would have to include the <string>
header.operator<<(std::ostream&...
stringification the library has to offer a forward declaration of std::ostream
and that is what the library does - but it is forbidden by the standard. It currently works everywhere - on all tested compilers - but if the user wishes to be 100% standards compliant - then the DOCTEST_CONFIG_USE_IOSFWD
identifier can be used to force the inclusion of <iosfwd>
. The reason the header is not included by default is that on MSVC (for example) it drags a whole bunch of stuff with it - and after the preprocessor is finished the translation unit has grown to 42k lines of C++ code - while Clang and the libc++ are so well implemented that including <iosfwd>
there results in 400 lines of code.