libs/function/test/function_n_test.cpp

// Boost.Function library
//  Copyright Douglas Gregor 2001-2003. Use, modification and
//  distribution is subject to the Boost Software License, Version
//  1.0. (See accompanying file LICENSE_1_0.txt or copy at
//  http://www.boost.org/LICENSE_1_0.txt)
// For more information, see http://www.boost.org
#include <boost/test/minimal.hpp>
#include <boost/function.hpp>
#include <functional>
#include <cassert>
#include <string>
using namespace boost;
using std::string;
using std::negate;
int global_int;
struct write_five_obj { void operator()() const { global_int = 5; } };
struct write_three_obj { int operator()() const { global_int = 3; return 7; }};
static void write_five() { global_int = 5; }
static void write_three() { global_int = 3; }
struct generate_five_obj { int operator()() const { return 5; } };
struct generate_three_obj { int operator()() const { return 3; } };
static int generate_five() { return 5; }
static int generate_three() { return 3; }
static string identity_str(const string& s) { return s; }
static string string_cat(const string& s1, const string& s2) { return s1+s2; }
static int sum_ints(int x, int y) { return x+y; }
struct write_const_1_nonconst_2
{
  void operator()() { global_int = 2; }
  void operator()() const { global_int = 1; }
};
struct add_to_obj
{
  add_to_obj(int v) : value(v) {}
  int operator()(int x) const { return value + x; }
  int value;
};
static void
test_zero_args()
{
  typedef function0<void> func_void_type;
  write_five_obj five = write_five_obj(); // Initialization for Borland C++ 5.5
  write_three_obj three = write_three_obj(); // Ditto
  // Default construction
  func_void_type v1;
  BOOST_CHECK(v1.empty());
  // Assignment to an empty function
  v1 = five;
  BOOST_CHECK(!v1.empty());
  // Invocation of a function
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 5);
  // clear() method
  v1.clear();
  BOOST_CHECK(!v1);
  // Assignment to an empty function
  v1 = three;
  BOOST_CHECK(!v1.empty());
  // Invocation and self-assignment
  global_int = 0;
  v1 = v1;
  v1();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v1 = five;
  // Invocation and self-assignment
  global_int = 0;
  v1 = (v1);
  v1();
  BOOST_CHECK(global_int == 5);
  // clear
  v1 = 0;
  BOOST_CHECK(v1.empty());
  // Assignment to an empty function from a free function
  v1 = &write_five;
  BOOST_CHECK(!v1.empty());
  // Invocation
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v1 = &write_three;
  BOOST_CHECK(!v1.empty());
  // Invocation
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 3);
  // Assignment
  v1 = five;
  BOOST_CHECK(!v1.empty());
  // Invocation
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v1 = write_three;
  BOOST_CHECK(!v1.empty());
  // Invocation
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 3);
  // Construction from another function (that is empty)
  v1.clear();
  func_void_type v2(v1);
  BOOST_CHECK(!v2? true : false);
  // Assignment to an empty function
  v2 = three;
  BOOST_CHECK(!v2.empty());
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v2 = (five);
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 5);
  v2.clear();
  BOOST_CHECK(v2.empty());
  // Assignment to an empty function from a free function
  v2 = (&write_five);
  BOOST_CHECK(v2? true : false);
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v2 = &write_three;
  BOOST_CHECK(!v2.empty());
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 3);
  // Swapping
  v1 = five;
  swap(v1, v2);
  v2();
  BOOST_CHECK(global_int == 5);
  v1();
  BOOST_CHECK(global_int == 3);
  swap(v1, v2);
  v1.clear();
  // Assignment
  v2 = five;
  BOOST_CHECK(!v2.empty());
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v2 = &write_three;
  BOOST_CHECK(!v2.empty());
  // Invocation
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 3);
  // Assignment to a function from an empty function
  v2 = v1;
  BOOST_CHECK(v2.empty());
  // Assignment to a function from a function with a functor
  v1 = three;
  v2 = v1;
  BOOST_CHECK(!v1.empty());
  BOOST_CHECK(!v2.empty());
  // Invocation
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 3);
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 3);
  // Assign to a function from a function with a function
  v2 = &write_five;
  v1 = v2;
  BOOST_CHECK(!v1.empty());
  BOOST_CHECK(!v2.empty());
  global_int = 0;
  v1();
  BOOST_CHECK(global_int == 5);
  global_int = 0;
  v2();
  BOOST_CHECK(global_int == 5);
  // Construct a function given another function containing a function
  func_void_type v3(v1);
  // Invocation of a function
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 5);
  // clear() method
  v3.clear();
  BOOST_CHECK(!v3? true : false);
  // Assignment to an empty function
  v3 = three;
  BOOST_CHECK(!v3.empty());
  // Invocation
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v3 = five;
  // Invocation
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 5);
  // clear()
  v3.clear();
  BOOST_CHECK(v3.empty());
  // Assignment to an empty function from a free function
  v3 = &write_five;
  BOOST_CHECK(!v3.empty());
  // Invocation
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v3 = &write_three;
  BOOST_CHECK(!v3.empty());
  // Invocation
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 3);
  // Assignment
  v3 = five;
  BOOST_CHECK(!v3.empty());
  // Invocation
  global_int = 0;
  v3();
  BOOST_CHECK(global_int == 5);
  // Construction of a function from a function containing a functor
  func_void_type v4(v3);
  // Invocation of a function
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 5);
  // clear() method
  v4.clear();
  BOOST_CHECK(v4.empty());
  // Assignment to an empty function
  v4 = three;
  BOOST_CHECK(!v4.empty());
  // Invocation
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v4 = five;
  // Invocation
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 5);
  // clear()
  v4.clear();
  BOOST_CHECK(v4.empty());
  // Assignment to an empty function from a free function
  v4 = &write_five;
  BOOST_CHECK(!v4.empty());
  // Invocation
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v4 = &write_three;
  BOOST_CHECK(!v4.empty());
  // Invocation
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 3);
  // Assignment
  v4 = five;
  BOOST_CHECK(!v4.empty());
  // Invocation
  global_int = 0;
  v4();
  BOOST_CHECK(global_int == 5);
  // Construction of a function from a functor
  func_void_type v5(five);
  // Invocation of a function
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 5);
  // clear() method
  v5.clear();
  BOOST_CHECK(v5.empty());
  // Assignment to an empty function
  v5 = three;
  BOOST_CHECK(!v5.empty());
  // Invocation
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v5 = five;
  // Invocation
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 5);
  // clear()
  v5.clear();
  BOOST_CHECK(v5.empty());
  // Assignment to an empty function from a free function
  v5 = &write_five;
  BOOST_CHECK(!v5.empty());
  // Invocation
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v5 = &write_three;
  BOOST_CHECK(!v5.empty());
  // Invocation
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 3);
  // Assignment
  v5 = five;
  BOOST_CHECK(!v5.empty());
  // Invocation
  global_int = 0;
  v5();
  BOOST_CHECK(global_int == 5);
  // Construction of a function from a function
  func_void_type v6(&write_five);
  // Invocation of a function
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 5);
  // clear() method
  v6.clear();
  BOOST_CHECK(v6.empty());
  // Assignment to an empty function
  v6 = three;
  BOOST_CHECK(!v6.empty());
  // Invocation
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 3);
  // Assignment to a non-empty function
  v6 = five;
  // Invocation
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 5);
  // clear()
  v6.clear();
  BOOST_CHECK(v6.empty());
  // Assignment to an empty function from a free function
  v6 = &write_five;
  BOOST_CHECK(!v6.empty());
  // Invocation
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 5);
  // Assignment to a non-empty function from a free function
  v6 = &write_three;
  BOOST_CHECK(!v6.empty());
  // Invocation
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 3);
  // Assignment
  v6 = five;
  BOOST_CHECK(!v6.empty());
  // Invocation
  global_int = 0;
  v6();
  BOOST_CHECK(global_int == 5);
  // Const vs. non-const
  // Initialization for Borland C++ 5.5
  write_const_1_nonconst_2 one_or_two = write_const_1_nonconst_2(); 
  const function0<void> v7(one_or_two);
  function0<void> v8(one_or_two);
  global_int = 0;
  v7();
  BOOST_CHECK(global_int == 2);
  global_int = 0;
  v8();
  BOOST_CHECK(global_int == 2);
  // Test construction from 0 and comparison to 0
  func_void_type v9(0);
  BOOST_CHECK(v9 == 0);
# if !defined(__SUNPRO_CC) || __SUNPRO_CC > 0x540 || defined(BOOST_STRICT_CONFIG)
  BOOST_CHECK(0 == v9);
#else
  BOOST_CHECK(v9.empty());
#endif
  // Test return values
  typedef function0<int> func_int_type;
  // Initialization for Borland C++ 5.5
  generate_five_obj gen_five = generate_five_obj();
  generate_three_obj gen_three = generate_three_obj();
  func_int_type i0(gen_five);
  BOOST_CHECK(i0() == 5);
  i0 = gen_three;
  BOOST_CHECK(i0() == 3);
  i0 = &generate_five;
  BOOST_CHECK(i0() == 5);
  i0 = &generate_three;
  BOOST_CHECK(i0() == 3);
  BOOST_CHECK(i0? true : false);
  i0.clear();
  BOOST_CHECK(!i0? true : false);
  // Test return values with compatible types
  typedef function0<long> func_long_type;
  func_long_type i1(gen_five);
  BOOST_CHECK(i1() == 5);
  i1 = gen_three;
  BOOST_CHECK(i1() == 3);
  i1 = &generate_five;
  BOOST_CHECK(i1() == 5);
  i1 = &generate_three;
  BOOST_CHECK(i1() == 3);
  BOOST_CHECK(i1? true : false);
  i1.clear();
  BOOST_CHECK(!i1? true : false);
}
static void
test_one_arg()
{
  negate<int> neg = negate<int>(); // Initialization for Borland C++ 5.5
  function1<int, int> f1(neg);
  BOOST_CHECK(f1(5) == -5);
  function1<string, string> id(&identity_str);
  BOOST_CHECK(id("str") == "str");
  function1<std::string, const char*> id2(&identity_str);
  BOOST_CHECK(id2("foo") == "foo");
  add_to_obj add_to(5);
  function1<int, int> f2(add_to);
  BOOST_CHECK(f2(3) == 8);
  const function1<int, int> cf2(add_to);
  BOOST_CHECK(cf2(3) == 8);
}
static void
test_two_args()
{
  function2<string, const string&, const string&> cat(&string_cat);
  BOOST_CHECK(cat("str", "ing") == "string");
  function2<int, short, short> sum(&sum_ints);
  BOOST_CHECK(sum(2, 3) == 5);
}
static void
test_emptiness()
{
  function0<float> f1;
  BOOST_CHECK(f1.empty());
  function0<float> f2;
  f2 = f1;
  BOOST_CHECK(f2.empty());
  function0<double> f3;
  f3 = f2;
  BOOST_CHECK(f3.empty());
}
struct X {
  X(int v) : value(v) {}
  int twice() const { return 2*value; }
  int plus(int v) { return value + v; }
  int value;
};
static void
test_member_functions()
{
  boost::function1<int, X*> f1(&X::twice);
  X one(1);
  X five(5);
  BOOST_CHECK(f1(&one) == 2);
  BOOST_CHECK(f1(&five) == 10);
  boost::function1<int, X*> f1_2;
  f1_2 = &X::twice;
  BOOST_CHECK(f1_2(&one) == 2);
  BOOST_CHECK(f1_2(&five) == 10);
  boost::function2<int, X&, int> f2(&X::plus);
  BOOST_CHECK(f2(one, 3) == 4);
  BOOST_CHECK(f2(five, 4) == 9);
}
struct add_with_throw_on_copy {
  int operator()(int x, int y) const { return x+y; }
  add_with_throw_on_copy() {}
  add_with_throw_on_copy(const add_with_throw_on_copy&)
  {
    throw std::runtime_error("But this CAN'T throw");
  }
  add_with_throw_on_copy& operator=(const add_with_throw_on_copy&)
  {
    throw std::runtime_error("But this CAN'T throw");
  }
};
static void
test_ref()
{
  add_with_throw_on_copy atc;
  try {
    boost::function2<int, int, int> f(ref(atc));
    BOOST_CHECK(f(1, 3) == 4);
  }
  catch(std::runtime_error e) {
    BOOST_ERROR("Nonthrowing constructor threw an exception");
  }
}
static unsigned construction_count = 0;
static unsigned destruction_count = 0;
struct MySmallFunctor {
  MySmallFunctor() { ++construction_count; }
  MySmallFunctor(const MySmallFunctor &) { ++construction_count; }
  ~MySmallFunctor() { ++destruction_count; }
  int operator()() { return 0; }
 };
struct MyLargeFunctor {
  MyLargeFunctor() { ++construction_count; }
  MyLargeFunctor(const MyLargeFunctor &) { ++construction_count; }
  ~MyLargeFunctor() { ++destruction_count; }
  int operator()() { return 0; }
  float data[128];
 };
void test_construct_destroy_count()
{
  {
    boost::function0<int> f;
    boost::function0<int> g;
    f = MySmallFunctor();
    g = MySmallFunctor();
    f.swap(g);
  }
  // MySmallFunctor objects should be constructed as many times as
  // they are destroyed.
  BOOST_CHECK(construction_count == destruction_count);
 
  construction_count = 0;
  destruction_count = 0;
  {
    boost::function0<int> f;
    boost::function0<int> g;
    f = MyLargeFunctor();
    g = MyLargeFunctor();
    f.swap(g);
   }
   // MyLargeFunctor objects should be constructed as many times as
   // they are destroyed.
   BOOST_CHECK(construction_count == destruction_count);
}
int test_main(int, char* [])
{
  test_zero_args();
  test_one_arg();
  test_two_args();
  test_emptiness();
  test_member_functions();
  test_ref();
  test_construct_destroy_count();
  return 0;
}