// Boost.Signals 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 #include #include #ifndef BOOST_NO_CXX11_VARIADIC_TEMPLATES int test_main(int, char* []) { return 0; } #else // BOOST_NO_CXX11_VARIADIC_TEMPLATES #include #include #include #include template struct max_or_default { typedef T result_type; template typename InputIterator::value_type operator()(InputIterator first, InputIterator last) const { boost::optional max; for (; first != last; ++first) { try { if(!max) max = *first; else max = (*first > max.get())? *first : max; } catch(const boost::bad_weak_ptr &) {} } if(max) return max.get(); return T(); } }; struct make_int { make_int(int n, int cn) : N(n), CN(n) {} int operator()() { return N; } int operator()() const { return CN; } int N; int CN; }; template struct make_increasing_int { make_increasing_int() : n(N) {} int operator()() const { return n++; } mutable int n; }; int get_37() { return 37; } static void test_zero_args() { make_int i42(42, 41); make_int i2(2, 1); make_int i72(72, 71); make_int i63(63, 63); make_int i62(62, 61); { boost::signals2::signal0, std::string> s0; boost::signals2::connection c2 = s0.connect(i2); boost::signals2::connection c72 = s0.connect("72", i72); boost::signals2::connection c62 = s0.connect("6x", i62); boost::signals2::connection c42 = s0.connect(i42); boost::signals2::connection c37 = s0.connect(&get_37); BOOST_CHECK(s0() == 72); s0.disconnect("72"); BOOST_CHECK(s0() == 62); c72.disconnect(); // Double-disconnect should be safe BOOST_CHECK(s0() == 62); s0.disconnect("72"); // Triple-disconect should be safe BOOST_CHECK(s0() == 62); // Also connect 63 in the same group as 62 s0.connect("6x", i63); BOOST_CHECK(s0() == 63); // Disconnect all of the 60's s0.disconnect("6x"); BOOST_CHECK(s0() == 42); c42.disconnect(); BOOST_CHECK(s0() == 37); c37.disconnect(); BOOST_CHECK(s0() == 2); c2.disconnect(); BOOST_CHECK(s0() == 0); } { boost::signals2::signal0 > s0; boost::signals2::connection c2 = s0.connect(i2); boost::signals2::connection c72 = s0.connect(i72); boost::signals2::connection c62 = s0.connect(i62); boost::signals2::connection c42 = s0.connect(i42); const boost::signals2::signal0 >& cs0 = s0; BOOST_CHECK(cs0() == 72); } { make_increasing_int<7> i7; make_increasing_int<10> i10; boost::signals2::signal0 > s0; boost::signals2::connection c7 = s0.connect(i7); boost::signals2::connection c10 = s0.connect(i10); BOOST_CHECK(s0() == 10); BOOST_CHECK(s0() == 11); } } static void test_one_arg() { boost::signals2::signal1 > s1; s1.connect(std::negate()); s1.connect(boost::bind(std::multiplies(), 2, _1)); BOOST_CHECK(s1(1) == 2); BOOST_CHECK(s1(-1) == 1); } static void test_signal_signal_connect() { typedef boost::signals2::signal1 > signal_type; signal_type s1; s1.connect(std::negate()); BOOST_CHECK(s1(3) == -3); { signal_type s2; s1.connect(s2); s2.connect(boost::bind(std::multiplies(), 2, _1)); s2.connect(boost::bind(std::multiplies(), -3, _1)); BOOST_CHECK(s2(-3) == 9); BOOST_CHECK(s1(3) == 6); } // s2 goes out of scope and disconnects BOOST_CHECK(s1(3) == -3); // test auto-track of signal wrapped in a reference_wrapper { signal_type s2; s1.connect(boost::cref(s2)); s2.connect(boost::bind(std::multiplies(), 2, _1)); s2.connect(boost::bind(std::multiplies(), -3, _1)); BOOST_CHECK(s2(-3) == 9); BOOST_CHECK(s1(3) == 6); } // s2 goes out of scope and disconnects BOOST_CHECK(s1(3) == -3); } struct EventCounter { EventCounter() : count(0) {} void operator()() { ++count; } int count; }; static void test_ref() { EventCounter ec; boost::signals2::signal0 s; { boost::signals2::scoped_connection c(s.connect(boost::ref(ec))); BOOST_CHECK(ec.count == 0); s(); BOOST_CHECK(ec.count == 1); } s(); BOOST_CHECK(ec.count == 1); } static void test_default_combiner() { boost::signals2::signal0 sig; boost::optional result; result = sig(); BOOST_CHECK(!result); sig.connect(make_int(0, 0)); result = sig(); BOOST_CHECK(result); BOOST_CHECK(*result == 0); sig.connect(make_int(1, 1)); result = sig(); BOOST_CHECK(result); BOOST_CHECK(*result == 1); } template ResultType disconnecting_slot(const boost::signals2::connection &conn, int) { conn.disconnect(); return ResultType(); } #ifdef BOOST_NO_VOID_RETURNS template<> void disconnecting_slot(const boost::signals2::connection &conn, int) { conn.disconnect(); return; } #endif template void test_extended_slot() { { typedef boost::signals2::signal1 signal_type; typedef typename signal_type::extended_slot_type slot_type; signal_type sig; // attempting to work around msvc 7.1 bug by explicitly assigning to a function pointer ResultType (*fp)(const boost::signals2::connection &conn, int) = &disconnecting_slot; slot_type myslot(fp); sig.connect_extended(myslot); BOOST_CHECK(sig.num_slots() == 1); sig(0); BOOST_CHECK(sig.num_slots() == 0); } { // test 0 arg signal typedef boost::signals2::signal0 signal_type; typedef typename signal_type::extended_slot_type slot_type; signal_type sig; // attempting to work around msvc 7.1 bug by explicitly assigning to a function pointer ResultType (*fp)(const boost::signals2::connection &conn, int) = &disconnecting_slot; slot_type myslot(fp, _1, 0); sig.connect_extended(myslot); BOOST_CHECK(sig.num_slots() == 1); sig(); BOOST_CHECK(sig.num_slots() == 0); } // test disconnection by slot { typedef boost::signals2::signal1 signal_type; typedef typename signal_type::extended_slot_type slot_type; signal_type sig; // attempting to work around msvc 7.1 bug by explicitly assigning to a function pointer ResultType (*fp)(const boost::signals2::connection &conn, int) = &disconnecting_slot; slot_type myslot(fp); sig.connect_extended(myslot); BOOST_CHECK(sig.num_slots() == 1); sig.disconnect(fp); BOOST_CHECK(sig.num_slots() == 0); } } class dummy_combiner { public: typedef int result_type; dummy_combiner(result_type return_value): _return_value(return_value) {} template result_type operator()(SlotIterator, SlotIterator) { return _return_value; } private: result_type _return_value; }; static void test_set_combiner() { typedef boost::signals2::signal0 signal_type; signal_type sig(dummy_combiner(0)); BOOST_CHECK(sig() == 0); BOOST_CHECK(sig.combiner()(0,0) == 0); sig.set_combiner(dummy_combiner(1)); BOOST_CHECK(sig() == 1); BOOST_CHECK(sig.combiner()(0,0) == 1); } static void test_swap() { typedef boost::signals2::signal0 signal_type; signal_type sig1(dummy_combiner(1)); BOOST_CHECK(sig1() == 1); signal_type sig2(dummy_combiner(2)); BOOST_CHECK(sig2() == 2); sig1.swap(sig2); BOOST_CHECK(sig1() == 2); BOOST_CHECK(sig2() == 1); using std::swap; swap(sig1, sig2); BOOST_CHECK(sig1() == 1); BOOST_CHECK(sig2() == 2); } int test_main(int, char* []) { test_zero_args(); test_one_arg(); test_signal_signal_connect(); test_ref(); test_default_combiner(); test_extended_slot(); test_extended_slot(); test_set_combiner(); test_swap(); return 0; } #endif // BOOST_NO_CXX11_VARIADIC_TEMPLATES