The premise

Say I have a container class Box which provides inner classes const_iterator and iterator. Because I want an iterator to be castable to a const_iterator, the latter inherits from the former:

class Box {
  // ...
  class const_iterator : public std::iterator<std::random_access_iterator_tag, const int> { /* ... */ };
  class iterator : public const_iterator { /* ... */ };
  // ...

The problem

Now I want to test these classes using Google Test. Let's assert that the begin() and end() don't return the same thing:

const Box a;
EXPECT_NE(a.begin(), a.end());

Say hello to a compile error:

  • clang: no member named 'begin' in 'Box::const_iterator'
  • g++: ‘const class Box::const_iterator’ has no member named ‘begin’

The cause

Some research led me to this template in the Google Test source code (follow the link for expanded documentation):

typedef int IsContainer;
template <class C>
IsContainer IsContainerTest(int /* dummy */,
                            typename C::iterator* /* it */ = NULL,
                            typename C::const_iterator* /* const_it */ = NULL) {
  return 0;

The result of this template magic is that if arguments to EXPECT_* have iterator and const_iterator member classes, then the type is assumed to be a container class. Knowing this, Google Test can print pretty human-readable reports when expectations fail, which is nice.

However, there's this little detail:

// Note that we look for both C::iterator and C::const_iterator.  The
// reason is that C++ injects the name of a class as a member of the
// class itself (e.g. you can refer to class iterator as either
// 'iterator' or 'iterator::iterator').  If we look for C::iterator
// only, for example, we would mistakenly think that a class named
// iterator is an STL container.

so if I understand things right, this means that

  • Box::const_iterator has itself as a member class named const_iterator, and std::iterator as a memberclass named iterator.
  • Box::iterator has itself as a member class named iterator and Box::const_iterator as a member class named const_iterator.

Therefore both my iterator classes look like container classes to Google Test!

The question

How do I design my iterator classes to make them not look like containers?

Things I've tried:

  • Declaring the std::iterator superclass of const_iterator as private. This solves the problem for const_iterator by hiding the iterator member class, but it still doesn't let me pass a.begin() as a parameter to EXPECT_NE unless a is const. Seems like Google Test uses iterator begin() rather than const_iterator begin() const for some reason.
  • Removing the std::iterator superclass altogether. Is this a bad idea? I suppose I'll have to declare my std::iterator_traits manually, is there anything else I'll lose by not extending std::iterator?
  • Declaring the Box::const_iterator superclass of Box::iterator as private. This may or may not be an option since I'd have to redeclare methods I'd rather want to reuse (such as operator++).

Is there anything else I've overlooked?

The example

#include <memory> //unique_ptr<T>
#include <gtest/gtest.h>

class ThreeInts {
  std::unique_ptr<int[]> v;

  ThreeInts() : v(new int[3]) { v[0] = 0; v[1] = 1; v[2] = 2; };
  ThreeInts(int val) : ThreeInts() { v[0] = val; v[1] = val; v[2] = val; };

  bool operator==(const ThreeInts& other) const {
    return v[0] == other.v[0] && v[1] == other.v[1] && v[2] == other.v[2];

  class const_iterator : public std::iterator<std::random_access_iterator_tag, const int> {
    int* p;
    explicit const_iterator(int* p) : p(p) {}
    const_iterator& operator++() { ++p; return *this; }
    bool operator==(const const_iterator& rhs) const { return p == rhs.p; }
    bool operator!=(const const_iterator& rhs) const { return p != rhs.p; }
    int operator*() const { return *p; }

  class iterator : public const_iterator {
    explicit iterator(int* p) : const_iterator(p) {}
    int& operator*() const { return *p; }

  iterator begin() { return iterator(v.get()); }
  iterator end() { return iterator(v.get()+3); }
  const_iterator begin() const { return const_iterator(v.get()); }
  const_iterator end() const { return const_iterator(v.get()+3); }

TEST(ThreeInts, ThisTestCompilesAndPrettyFailureMessagesAreShown) {
  const ThreeInts a(1), b(2);
  ThreeInts c(1), d(2);
  EXPECT_EQ(a, b);
  EXPECT_EQ(a, c);
  EXPECT_EQ(c, d);

TEST(ThreeInts, ThisTestCompilesIfTheStdIteratorParentIsPrivate) {
  const ThreeInts a;
  EXPECT_NE(a.begin(), a.end());

TEST(ThreeInts, ThisTestAlsoCompilesIfTheStdIteratorParentIsPrivateButItIsAHassle) {
  ThreeInts a;
  ThreeInts::const_iterator beg = a.begin();
  ThreeInts::const_iterator end = a.end();
  //EXPECT_NE(beg, end); // Compile error unless the std::iterator superclass is private

TEST(ThreeInts, ThisTestDoesNotCompileEvenIfTheStdIteratorParentIsPrivate) {
  ThreeInts a;
  //EXPECT_NE(a.begin(), a.end());

int main(int argc, char **argv) {
  ::testing::InitGoogleTest(&argc, argv);
  return RUN_ALL_TESTS();
  • 2
    Name your iterator class ThreeIntsIterator or something - just not iterator. In ThreeInts, do typedef ThreeIntsIterator iterator; Oct 13 '14 at 19:10
  • The google test IsContainerTest is garbage - simple typedef(s) make no container - better is a test for the member functions begin() and end(), which has shortcomings, too
    – user2249683
    Oct 13 '14 at 19:15
  • You didn't understand that comment right. It looks for both C::iterator and C::const_iterator because if it were only to look for the former, then C might simply be iterator but not a container with sub-type iterator.
    – Walter
    Oct 13 '14 at 20:18
  • 1
    I would recommend filing a bug against Google Test. Clearly EXPECT_NE should never call begin() or end() on its arguments unless it can prove that they exist. And even that is questionable. This kind of template magic is a wonderful source of time consuming, subtle bugs - the Google people should made aware of the nonsense that their code attempts to do. Oct 20 '14 at 20:23
  • 1
    There are some problems in iterator inheriting const_iterator. Consider for instance operator++. You want to reuse it, but what does it return? Yes, a const_iterator& in both cases. This is not correct and will possibly break standard algorithms. Same is true for + and - you will want to implement. Better implement both iterator classes separately (possibly inheriting from a common parent using CRTP) and provide a conversion operator. Oct 21 '14 at 9:42

ThreeInts::iterator should not inherit from ThreeInts::const_iterator, instead they should be implemented separately.

class ThreeInts::iterator : public std::iterator< std::random_access_iterator_tag, int> { ... }
class ThreeInts::const_iterator : public std::iterator< std::random_access_iterator_tag, const int> { ... }

The problem seems to be that otherwise ThreeInts::const_iterator both has members named const_iterator and iterator (aka the constructors). Also making the iterator inherit from const_iterator is not const-correct as the const_iterator should only hold a pointer/similar to const data. STL containers also keep the two iterators separate.

In that code, it would probably be sufficient to instead of defining iterator classes, simply define

using iterator = int*;
using const_iterator = const int*;
  • You're right in that const_iterator should only hold const data, that detail had slipped me by. But couldn't I still have iterator inherit from const_iterator and just override the const data with non-const data? I'll have to try that out when I have the time. Thanks also for your suggestion to keep them separate. Now, a correction: the magic template used in gtest explicitly states typename, so the issue is that the classes embed themselves as members, not the constructors. Also, please don't get distracted by the implementation details of my ThreeInts example. Oct 21 '14 at 9:08

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