50

I am trying to do unit testing (using the Boost unit testing framework) on a C++ class called VariableImpl. Here are the details.

class Variable
{
public:
  void UpdateStatistics (void) {
    // compute mean based on m_val and update m_mean;
    OtherClass::SendData (m_mean);
    m_val.clear ();
  }
  virtual void RecordData (double) = 0;

protected:
  std::vector<double> m_val;

private:
  double m_mean;
};

class VariableImpl : public Variable
{
public:
  virtual void RecordData (double d) {
    // Put data in m_val
  }
};

How can I check that the mean is computed correctly? Note that 1) m_mean is protected and 2) UpdateStatistics calls a method of another class and then clears the vector.

The only way I can see would be to add a getter (for instance, GetMean), but I don't like this solution at all, nor I think it is the most elegant.

How should I do?

And what should I do if I were to test a private method instead of a private variable?

9
  • I’ve been meaning to ask something very similar. But in my opinion unit testing and large classes simply doesn’t mix well. Commented Jul 21, 2011 at 15:34
  • Well, can't you see the effects in OtherClass? Commented Jul 21, 2011 at 15:35
  • You should read Enemies of Test Driven Development part I: encapsulation. Commented Jul 21, 2011 at 15:44
  • 5
    @André In fact, quite a few proponents of TDD say that encapsulation is outdated and shouldn’t be used. Infuriating. This post goes into the direction but stops just short of saying it outright. I’ve given an example in my answer (below) where using a private method that should be covered by tests is entirely reasonable. And then the author claims that “testability is a perfectly good reason to make something public” – no, it’s not. If a method shouldn’t be used by the consumer of the class (e.g. since it cannot be meaningfully used) it shouldn’t be public. Commented Jul 21, 2011 at 16:01
  • Take a look at some answers to a similar question here:stackoverflow.com/questions/249847/…
    – morechilli
    Commented Jul 21, 2011 at 16:28

8 Answers 8

69

Well, unit testing should test units and ideally every class is a self-contained unit – this follows directly from the single responsibility principle.

So testing private members of a class shouldn’t be necessary – the class is a black box that can be covered in a unit test as-is.

On the other hand, this isn’t always true, and sometimes with good reasons (for instance, several methods of the class could rely on a private utility function that should be tested). One very simple, very crufty but ultimately successful solution is to put the following into your unit-test file, before including the header that defines your class:

#define private public

Of course, this destroys encapsulation and is evil. But for testing, it serves the purpose.

19
  • 2
    It seems that this define is the least obtrusive solution. I guess the problems I'm facing are more due to the fact that my classes don't follow the single responsibility principle very well. Regarding the toy example I presented, would you suggest that I create a Mean class to be used as a private member of Variable? That way Mean could be tested without any problem. The downside, however, would be proliferation of classes.
    – Jir
    Commented Jul 22, 2011 at 7:24
  • @Jir In your case, shouldn’t it be enough to unit-test OtherClass::SendData since that computes the mean? Commented Jul 22, 2011 at 7:58
  • 6
    While this answer works on most compilers it is not standard compliant. You are not allowed to use #define statements that are identical to keywords. See C++98: section 17.4.3.1.1 Commented Nov 12, 2012 at 11:00
  • 1
    Wouldn't friendship more standard compliant than the evil define, and make the testing possible at a negligible encapsulation cost?
    – paercebal
    Commented Jun 14, 2013 at 15:36
  • 6
    methods that are before any public/private keywords won't became public, btw
    – RiaD
    Commented Sep 12, 2014 at 6:55
14

For a protected method/variable, inherit a Test class from the class and do your testing.

For a private, introduce a friend class. It isn't the best of solutions, but it can do the work for you.

Or this hack:

#define private public
5
  • 6
    Having a friend class is too intrusive in my opinion. Commented Jul 21, 2011 at 15:33
  • @Konrad Rudolph - Yes, that is why I said it isn't the best of solutions. And I would assume for testing it should not be that big of a deal.
    – DumbCoder
    Commented Jul 21, 2011 at 15:43
  • 3
    defining keywords is Undefined Behavior: stackoverflow.com/questions/27778908/…
    – bolov
    Commented Aug 23, 2016 at 8:48
  • @KonradRudolph I don't think that it's too intrusive because only your defined friend class (which is actually your test) will have access. And if you are talking about security aspect, it's a totally different story: private/protected/public does no save your code from injections/reverse engineering etc. at all, it provides protection only from misuse (i. e. improper coding), so it is also not an issue.
    – avtomaton
    Commented Aug 15, 2019 at 19:06
  • @avtomaton It’s not about security. The point is that the tested class needs to declare the test class as friend, which means that whenever you add a new unit test class you need to add your non-test code. Commented Aug 15, 2019 at 19:10
9

In general, I agree with what others have said on here - only the public interface should be unit tested.

Nevertheless, I've just had a case where I had to call a protected method first, to prepare for a specific test case. I first tried the #define protected public approach mentioned above; this worked with Linux/GCC, but failed with Windows and Visual Studio.

The reason was that changing protected to public also changed the mangled symbol name and thus gave me linker errors: the library provided a protected __declspec(dllexport) void Foo::bar() method, but with the #define in place, my test program expected a public __declspec(dllimport) void Foo::bar() method which gave me an unresolved symbol error.

For this reason, I switched to a friend based solution, doing the following in my class header:

// This goes in Foo.h
namespace unit_test {   // Name this anything you like
  struct FooTester; // Forward declaration for befriending
}

// Class to be tested
class Foo
{
  ...
private:
  bool somePrivateMethod(int bar);
  // Unit test access
  friend struct ::unit_test::FooTester;
};

And in my actual test case, I did this:

#include <Foo.h>
#include <boost/test/unit_test.hpp>

namespace unit_test {
  // Static wrappers for private/protected methods
  struct FooTester
  {
    static bool somePrivateMethod(Foo& foo, int bar)
    {
      return foo.somePrivateMethod(bar);
    }
  };
}

BOOST_AUTO_TEST_SUITE(FooTest);
BOOST_AUTO_TEST_CASE(TestSomePrivateMethod)
{
  // Just a silly example
  Foo foo;
  BOOST_CHECK_EQUAL(unit_test::FooTester::somePrivateMethod(foo, 42), true);
}
BOOST_AUTO_TEST_SUITE_END();

This works with Linux/GCC as well as Windows and Visual Studio.

4

A good approach to test the protected data in C++ is the assignment of a friend proxy class:

#define FRIEND_TEST(test_case_name, test_name)\
friend class test_case_name##_##test_name##_Test

class MyClass
{
    private:
        int MyMethod();
        FRIEND_TEST(MyClassTest, MyMethod);
};

class MyClassTest : public testing::Test
{
    public:
      // ...
        void Test1()
        {
            MyClass obj1;
            ASSERT_TRUE(obj1.MyMethod() == 0);
        }

        void Test2()
        {
            ASSERT_TRUE(obj2.MyMethod() == 0);
        }

        MyClass obj2;
};

TEST_F(MyClassTest, PrivateTests)
{
    Test1();
    Test2();
}

See more Google Test (gtest).

1

Unit test VariableImpl such that if its behavior is ensured, so is Variable.

Testing internals isn't the worst thing in the world, but the goal is that they can be anything as long as the interfaces contracts are ensured. If that means creating a bunch of weird mock implementations to test Variable, then that is reasonable.

If that seems like a lot, consider that implementation inheritance doesn't create great separation of concerns. If it is hard to unit test, then that is a pretty obvious code smell for me.

1

While in my opinion the need of testing private members/methods of a class is a code smell, I think that is technically feasible in C++.

As an example, suppose you have a Dog class with private members/methods except for the public constructor:

#include <iostream>
#include <string>

using namespace std;

class Dog {
  public:
    Dog(string name) { this->name = name; };

  private:
    string name;
    string bark() { return name + ": Woof!"; };
    static string Species;
    static int Legs() { return 4; };
};

string Dog::Species = "Canis familiaris";

Now for some reason you would like to test the private ones. You could use privablic to achieve that.

Include a header named privablic.h along with the desired implementation like that:

#include "privablic.h"
#include "dog.hpp"

then map some stubs according to types of any instance member

struct Dog_name { typedef string (Dog::*type); };
template class private_member<Dog_name, &Dog::name>;

...and instance method;

struct Dog_bark { typedef string (Dog::*type)(); };
template class private_method<Dog_bark, &Dog::bark>;

do the same with all static instance members

struct Dog_Species { typedef string *type; };
template class private_member<Dog_Species, &Dog::Species>;

...and static instance methods.

struct Dog_Legs { typedef int (*type)(); };
template class private_method<Dog_Legs, &Dog::Legs>;

Now you can test them all:

#include <assert.h>

int main()
{
    string name = "Fido";
    Dog fido = Dog(name);

    string fido_name = fido.*member<Dog_name>::value;
    assert (fido_name == name);

    string fido_bark = (&fido->*func<Dog_bark>::ptr)();
    string bark = "Fido: Woof!";
    assert( fido_bark == bark);

    string fido_species = *member<Dog_Species>::value;
    string species = "Canis familiaris";
    assert(fido_species == species);

    int fido_legs = (*func<Dog_Legs>::ptr)();
    int legs = 4;
    assert(fido_legs == legs);

    printf("all assertions passed\n");
};

Output:

$ ./main
all assertions passed

You can look at the sources of test_dog.cpp and dog.hpp.

DISCLAIMER: Thanks to insights of other clever people, I have assembled the aforementioned "library" able to access to private members and methods of a given C++ class without altering its definition or behaviour. In order to make it work it's (obviously) required to know and include the implementation of the class.

NOTE: I revised the content of this answer in order to follow directives suggested by reviewers.

1
0

I generally suggest testing the public interface of your classes, not the private/protected implementations. In this case, if it can't be observed from the outside world by a public method, then the unit test may not need to test it.

If the functionality requires a child class, either unit test the real derived class OR create your own test derived class that has an appropriate implementation.

0

Example from the Google testing framework:

// foo.h
#include "gtest/gtest_prod.h"
class Foo {
  ...
 private:
  FRIEND_TEST(FooTest, BarReturnsZeroOnNull);
  int Bar(void* x);
};

// foo_test.cc
...
TEST(FooTest, BarReturnsZeroOnNull) {
  Foo foo;
  EXPECT_EQ(0, foo.Bar(NULL));
  // Uses Foo's private member Bar().
}

The main idea is the use of the friend C++ keyword. You can extend this example as follows:

// foo.h
#ifdef TEST_FOO
#include "gtest/gtest_prod.h"
#endif

class Foo {
  ...
 private:
  #ifdef TEST_FOO
  FRIEND_TEST(FooTest, BarReturnsZeroOnNull);
  #endif
  int Bar(void* x);
};

You can define the TEST_FOO preprocessor symbol in two ways:

  1. within the CMakeLists.txt file

     option(TEST "Run test ?" ON)
     if (TEST)
       add_definitions(-DTEST_FOO)
     endif()
    
  2. as arguments to your compiler

     g++ -D TEST $your_args
    

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