boost_1_45_0/libs/lambda/test/operator_tests_simple.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  operator_tests_simple.cpp  -- The Boost Lambda Library ---------------
 //
 // Copyright (C) 2000-2003 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
 // Copyright (C) 2000-2003 Gary Powell (powellg@amazon.com)
 //
 // Distributed under 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 www.boost.org

 // -----------------------------------------------------------------------


 #include <boost/test/minimal.hpp>    // see "Header Implementation Option"

 #include "boost/lambda/lambda.hpp"

 #include "boost/lambda/detail/suppress_unused.hpp"

 #include <boost/shared_ptr.hpp>

 #include <vector>
 #include <map>
 #include <set>
 #include <string>

 #include <iostream>

 #ifndef BOOST_NO_STRINGSTREAM
 #include <sstream>
 #endif

 using namespace std;
 using namespace boost;

 using namespace boost::lambda;


 class unary_plus_tester {};
 unary_plus_tester operator+(const unary_plus_tester& a) { return a; }

 void cout_tests()
 {
 #ifndef BOOST_NO_STRINGSTREAM
   using std::cout;
   ostringstream os;
   int i = 10;
   (os << _1)(i);

   (os << constant("FOO"))();

   BOOST_CHECK(os.str() == std::string("10FOO"));


   istringstream is("ABC 1");
   std::string s;
   int k;

   is >> s;
   is >> k;

   BOOST_CHECK(s == std::string("ABC"));
   BOOST_CHECK(k == 1);
   // test for constant, constant_ref and var
   i = 5;
   constant_type<int>::type ci(constant(i));
   var_type<int>::type vi(var(i));

   (vi = _1)(make_const(100));
   BOOST_CHECK((ci)() == 5);
   BOOST_CHECK(i == 100);

   int a;
   constant_ref_type<int>::type cr(constant_ref(i));
   (++vi, var(a) = cr)();
   BOOST_CHECK(i == 101);
 #endif
 }

 void arithmetic_operators() {
   int i = 1; int j = 2; int k = 3;

   using namespace std;
   using namespace boost::lambda;

   BOOST_CHECK((_1 + 1)(i)==2);
   BOOST_CHECK(((_1 + 1) * _2)(i, j)==4);
   BOOST_CHECK((_1 - 1)(i)==0);

   BOOST_CHECK((_1 * 2)(j)==4);
   BOOST_CHECK((_1 / 2)(j)==1);

   BOOST_CHECK((_1 % 2)(k)==1);

   BOOST_CHECK((-_1)(i) == -1);
   BOOST_CHECK((+_1)(i) == 1);

   // test that unary plus really does something
   unary_plus_tester u;
   unary_plus_tester up = (+_1)(u);

   boost::lambda::detail::suppress_unused_variable_warnings(up);
 }

 void bitwise_operators() {
   unsigned int ui = 2;

   BOOST_CHECK((_1 << 1)(ui)==(2 << 1));
   BOOST_CHECK((_1 >> 1)(ui)==(2 >> 1));

   BOOST_CHECK((_1 & 1)(ui)==(2 & 1));
   BOOST_CHECK((_1 | 1)(ui)==(2 | 1));
   BOOST_CHECK((_1 ^ 1)(ui)==(2 ^ 1));
   BOOST_CHECK((~_1)(ui)==~2u);
 }

 void comparison_operators() {
   int i = 0, j = 1;

   BOOST_CHECK((_1 < _2)(i, j) == true);
   BOOST_CHECK((_1 <= _2)(i, j) == true);
   BOOST_CHECK((_1 == _2)(i, j) == false);
   BOOST_CHECK((_1 != _2)(i, j) == true);
   BOOST_CHECK((_1 > _2)(i, j) == false);
   BOOST_CHECK((_1 >= _2)(i, j) == false);

   BOOST_CHECK((!(_1 < _2))(i, j) == false);
   BOOST_CHECK((!(_1 <= _2))(i, j) == false);
   BOOST_CHECK((!(_1 == _2))(i, j) == true);
   BOOST_CHECK((!(_1 != _2))(i, j) == false);
   BOOST_CHECK((!(_1 > _2))(i, j) == true);
   BOOST_CHECK((!(_1 >= _2))(i, j) == true);
 }

 void logical_operators() {

   bool t = true, f = false;
   BOOST_CHECK((_1 && _2)(t, t) == true);
   BOOST_CHECK((_1 && _2)(t, f) == false);
   BOOST_CHECK((_1 && _2)(f, t) == false);
   BOOST_CHECK((_1 && _2)(f, f) == false);

   BOOST_CHECK((_1 || _2)(t, t) == true);
   BOOST_CHECK((_1 || _2)(t, f) == true);
   BOOST_CHECK((_1 || _2)(f, t) == true);
   BOOST_CHECK((_1 || _2)(f, f) == false);

   BOOST_CHECK((!_1)(t) == false);
   BOOST_CHECK((!_1)(f) == true);

   // test short circuiting
   int i=0;

   (false && ++_1)(i);
   BOOST_CHECK(i==0);
   i = 0;

   (true && ++_1)(i);
   BOOST_CHECK(i==1);
   i = 0;

   (false || ++_1)(i);
   BOOST_CHECK(i==1);
   i = 0;

   (true || ++_1)(i);
   BOOST_CHECK(i==0);
   i = 0;
 }

 void unary_incs_and_decs() {
   int i = 0;

   BOOST_CHECK(_1++(i) == 0);
   BOOST_CHECK(i == 1);
   i = 0;

   BOOST_CHECK(_1--(i) == 0);
   BOOST_CHECK(i == -1);
   i = 0;

   BOOST_CHECK((++_1)(i) == 1);
   BOOST_CHECK(i == 1);
   i = 0;

   BOOST_CHECK((--_1)(i) == -1);
   BOOST_CHECK(i == -1);
   i = 0;

   // the result of prefix -- and ++ are lvalues
   (++_1)(i) = 10;
   BOOST_CHECK(i==10);
   i = 0;

   (--_1)(i) = 10;
   BOOST_CHECK(i==10);
   i = 0;
 }

 void compound_operators() {

   int i = 1;

   // normal variable as the left operand
   (i += _1)(make_const(1));
   BOOST_CHECK(i == 2);

   (i -= _1)(make_const(1));
   BOOST_CHECK(i == 1);

   (i *= _1)(make_const(10));
   BOOST_CHECK(i == 10);

   (i /= _1)(make_const(2));
   BOOST_CHECK(i == 5);

   (i %= _1)(make_const(2));
   BOOST_CHECK(i == 1);

   // lambda expression as a left operand
   (_1 += 1)(i);
   BOOST_CHECK(i == 2);

   (_1 -= 1)(i);
   BOOST_CHECK(i == 1);

   (_1 *= 10)(i);
   BOOST_CHECK(i == 10);

   (_1 /= 2)(i);
   BOOST_CHECK(i == 5);

   (_1 %= 2)(i);
   BOOST_CHECK(i == 1);

   // lambda expression as a left operand with rvalue on RHS
   (_1 += (0 + 1))(i);
   BOOST_CHECK(i == 2);

   (_1 -= (0 + 1))(i);
   BOOST_CHECK(i == 1);

   (_1 *= (0 + 10))(i);
   BOOST_CHECK(i == 10);

   (_1 /= (0 + 2))(i);
   BOOST_CHECK(i == 5);

   (_1 %= (0 + 2))(i);
   BOOST_CHECK(i == 1);

   // shifts
   unsigned int ui = 2;
   (_1 <<= 1)(ui);
   BOOST_CHECK(ui==(2 << 1));

   ui = 2;
   (_1 >>= 1)(ui);
   BOOST_CHECK(ui==(2 >> 1));

   ui = 2;
   (ui <<= _1)(make_const(1));
   BOOST_CHECK(ui==(2 << 1));

   ui = 2;
   (ui >>= _1)(make_const(1));
   BOOST_CHECK(ui==(2 >> 1));

   // and, or, xor
   ui = 2;
   (_1 &= 1)(ui);
   BOOST_CHECK(ui==(2 & 1));

   ui = 2;
   (_1 |= 1)(ui);
   BOOST_CHECK(ui==(2 | 1));

   ui = 2;
   (_1 ^= 1)(ui);
   BOOST_CHECK(ui==(2 ^ 1));

   ui = 2;
   (ui &= _1)(make_const(1));
   BOOST_CHECK(ui==(2 & 1));

   ui = 2;
   (ui |= _1)(make_const(1));
   BOOST_CHECK(ui==(2 | 1));

   ui = 2;
   (ui ^= _1)(make_const(1));
   BOOST_CHECK(ui==(2 ^ 1));

 }

 void assignment_and_subscript() {

   // assignment and subscript need to be defined as member functions.
   // Hence, if you wish to use a normal variable as the left hand argument,
   // you must wrap it with var to turn it into a lambda expression

   using std::string;
   string s;

   (_1 = "one")(s);
   BOOST_CHECK(s == string("one"));

   (var(s) = "two")();
   BOOST_CHECK(s == string("two"));

   BOOST_CHECK((var(s)[_1])(make_const(2)) == 'o');
   BOOST_CHECK((_1[2])(s) == 'o');
   BOOST_CHECK((_1[_2])(s, make_const(2)) == 'o');

   // subscript returns lvalue
   (var(s)[_1])(make_const(1)) = 'o';
   BOOST_CHECK(s == "too");

   (_1[1])(s) = 'a';
   BOOST_CHECK(s == "tao");

   (_1[_2])(s, make_const(0)) = 'm';
   BOOST_CHECK(s == "mao");

   // TODO: tests for vector, set, map, multimap
 }

 class A {};

 void address_of_and_dereference() {

   A a; int i = 42;

   BOOST_CHECK((&_1)(a) == &a);
   BOOST_CHECK((*&_1)(i) == 42);

   std::vector<int> vi; vi.push_back(1);
   std::vector<int>::iterator it = vi.begin();

   (*_1 = 7)(it);
   BOOST_CHECK(vi[0] == 7);
   const std::vector<int>::iterator cit(it);
   (*_1 = 8)(cit);
   BOOST_CHECK(vi[0] == 8);

   // TODO: Add tests for more complex iterator types

   boost::shared_ptr<int> ptr(new int(0));
   (*_1 = 7)(ptr);
   BOOST_CHECK(*ptr == 7);
   const boost::shared_ptr<int> cptr(ptr);
   (*_1 = 8)(cptr);
   BOOST_CHECK(*ptr == 8);
 }


 void comma() {

   int i = 100;
   BOOST_CHECK((_1 = 10, 2 * _1)(i) == 20);

   // TODO: that the return type is the exact type of the right argument
   // (that r/l valueness is preserved)

 }

 void pointer_arithmetic() {

   int ia[4] = { 1, 2, 3, 4 };
   int* ip = ia;
   int* ia_last = &ia[3];

   const int cia[4] = { 1, 2, 3, 4 };
   const int* cip = cia;
   const int* cia_last = &cia[3];


   // non-const array
   BOOST_CHECK((*(_1 + 1))(ia) == 2);

   // non-const pointer
   BOOST_CHECK((*(_1 + 1))(ip) == 2);

   BOOST_CHECK((*(_1 - 1))(ia_last) == 3);

   // const array
   BOOST_CHECK((*(_1 + 1))(cia) == 2);
   // const pointer
   BOOST_CHECK((*(_1 + 1))(cip) == 2);
   BOOST_CHECK((*(_1 - 1))(cia_last) == 3);

   // pointer arithmetic should not make non-consts const
     (*(_1 + 2))(ia) = 0;
     (*(_1 + 3))(ip) = 0;

   BOOST_CHECK(ia[2] == 0);
   BOOST_CHECK(ia[3] == 0);

   // pointer - pointer
   BOOST_CHECK((_1 - _2)(ia_last, ia) == 3);
   BOOST_CHECK((_1 - _2)(cia_last, cia) == 3);
   BOOST_CHECK((ia_last - _1)(ia) == 3);
   BOOST_CHECK((cia_last - _1)(cia) == 3);
   BOOST_CHECK((cia_last - _1)(cip) == 3);

 }

 int test_main(int, char *[]) {

   arithmetic_operators();
   bitwise_operators();
   comparison_operators();
   logical_operators();
   unary_incs_and_decs();
   compound_operators();
   assignment_and_subscript();
   address_of_and_dereference();
   comma();
   pointer_arithmetic();
   cout_tests();
   return 0;
 }
	// operator_tests_simple.cpp -- The Boost Lambda Library ---------------
	//
	// Copyright (C) 2000-2003 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
	// Copyright (C) 2000-2003 Gary Powell (powellg@amazon.com)
	//
	// Distributed under 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 www.boost.org

	// -----------------------------------------------------------------------



	#include <boost/test/minimal.hpp> // see "Header Implementation Option"

	#include "boost/lambda/lambda.hpp"

	#include "boost/lambda/detail/suppress_unused.hpp"

	#include <boost/shared_ptr.hpp>

	#include <vector>
	#include <map>
	#include <set>
	#include <string>

	#include <iostream>

	#ifndef BOOST_NO_STRINGSTREAM
	#include <sstream>
	#endif

	using namespace std;
	using namespace boost;

	using namespace boost::lambda;


	class unary_plus_tester {};
	unary_plus_tester operator+(const unary_plus_tester& a) { return a; }

	void cout_tests()
	{
	#ifndef BOOST_NO_STRINGSTREAM
	using std::cout;
	ostringstream os;
	int i = 10;
	(os << _1)(i);

	(os << constant("FOO"))();

	BOOST_CHECK(os.str() == std::string("10FOO"));


	istringstream is("ABC 1");
	std::string s;
	int k;

	is >> s;
	is >> k;

	BOOST_CHECK(s == std::string("ABC"));
	BOOST_CHECK(k == 1);
	// test for constant, constant_ref and var
	i = 5;
	constant_type<int>::type ci(constant(i));
	var_type<int>::type vi(var(i));

	(vi = _1)(make_const(100));
	BOOST_CHECK((ci)() == 5);
	BOOST_CHECK(i == 100);

	int a;
	constant_ref_type<int>::type cr(constant_ref(i));
	(++vi, var(a) = cr)();
	BOOST_CHECK(i == 101);
	#endif
	}

	void arithmetic_operators() {
	int i = 1; int j = 2; int k = 3;

	using namespace std;
	using namespace boost::lambda;

	BOOST_CHECK((_1 + 1)(i)==2);
	BOOST_CHECK(((_1 + 1) * _2)(i, j)==4);
	BOOST_CHECK((_1 - 1)(i)==0);

	BOOST_CHECK((_1 * 2)(j)==4);
	BOOST_CHECK((_1 / 2)(j)==1);

	BOOST_CHECK((_1 % 2)(k)==1);

	BOOST_CHECK((-_1)(i) == -1);
	BOOST_CHECK((+_1)(i) == 1);

	// test that unary plus really does something
	unary_plus_tester u;
	unary_plus_tester up = (+_1)(u);

	boost::lambda::detail::suppress_unused_variable_warnings(up);
	}

	void bitwise_operators() {
	unsigned int ui = 2;

	BOOST_CHECK((_1 << 1)(ui)==(2 << 1));
	BOOST_CHECK((_1 >> 1)(ui)==(2 >> 1));

	BOOST_CHECK((_1 & 1)(ui)==(2 & 1));
	BOOST_CHECK((_1 \| 1)(ui)==(2 \| 1));
	BOOST_CHECK((_1 ^ 1)(ui)==(2 ^ 1));
	BOOST_CHECK((~_1)(ui)==~2u);
	}

	void comparison_operators() {
	int i = 0, j = 1;

	BOOST_CHECK((_1 < _2)(i, j) == true);
	BOOST_CHECK((_1 <= _2)(i, j) == true);
	BOOST_CHECK((_1 == _2)(i, j) == false);
	BOOST_CHECK((_1 != _2)(i, j) == true);
	BOOST_CHECK((_1 > _2)(i, j) == false);
	BOOST_CHECK((_1 >= _2)(i, j) == false);

	BOOST_CHECK((!(_1 < _2))(i, j) == false);
	BOOST_CHECK((!(_1 <= _2))(i, j) == false);
	BOOST_CHECK((!(_1 == _2))(i, j) == true);
	BOOST_CHECK((!(_1 != _2))(i, j) == false);
	BOOST_CHECK((!(_1 > _2))(i, j) == true);
	BOOST_CHECK((!(_1 >= _2))(i, j) == true);
	}

	void logical_operators() {

	bool t = true, f = false;
	BOOST_CHECK((_1 && _2)(t, t) == true);
	BOOST_CHECK((_1 && _2)(t, f) == false);
	BOOST_CHECK((_1 && _2)(f, t) == false);
	BOOST_CHECK((_1 && _2)(f, f) == false);

	BOOST_CHECK((_1 \|\| _2)(t, t) == true);
	BOOST_CHECK((_1 \|\| _2)(t, f) == true);
	BOOST_CHECK((_1 \|\| _2)(f, t) == true);
	BOOST_CHECK((_1 \|\| _2)(f, f) == false);

	BOOST_CHECK((!_1)(t) == false);
	BOOST_CHECK((!_1)(f) == true);

	// test short circuiting
	int i=0;

	(false && ++_1)(i);
	BOOST_CHECK(i==0);
	i = 0;

	(true && ++_1)(i);
	BOOST_CHECK(i==1);
	i = 0;

	(false \|\| ++_1)(i);
	BOOST_CHECK(i==1);
	i = 0;

	(true \|\| ++_1)(i);
	BOOST_CHECK(i==0);
	i = 0;
	}

	void unary_incs_and_decs() {
	int i = 0;

	BOOST_CHECK(_1++(i) == 0);
	BOOST_CHECK(i == 1);
	i = 0;

	BOOST_CHECK(_1--(i) == 0);
	BOOST_CHECK(i == -1);
	i = 0;

	BOOST_CHECK((++_1)(i) == 1);
	BOOST_CHECK(i == 1);
	i = 0;

	BOOST_CHECK((--_1)(i) == -1);
	BOOST_CHECK(i == -1);
	i = 0;

	// the result of prefix -- and ++ are lvalues
	(++_1)(i) = 10;
	BOOST_CHECK(i==10);
	i = 0;

	(--_1)(i) = 10;
	BOOST_CHECK(i==10);
	i = 0;
	}

	void compound_operators() {

	int i = 1;

	// normal variable as the left operand
	(i += _1)(make_const(1));
	BOOST_CHECK(i == 2);

	(i -= _1)(make_const(1));
	BOOST_CHECK(i == 1);

	(i *= _1)(make_const(10));
	BOOST_CHECK(i == 10);

	(i /= _1)(make_const(2));
	BOOST_CHECK(i == 5);

	(i %= _1)(make_const(2));
	BOOST_CHECK(i == 1);

	// lambda expression as a left operand
	(_1 += 1)(i);
	BOOST_CHECK(i == 2);

	(_1 -= 1)(i);
	BOOST_CHECK(i == 1);

	(_1 *= 10)(i);
	BOOST_CHECK(i == 10);

	(_1 /= 2)(i);
	BOOST_CHECK(i == 5);

	(_1 %= 2)(i);
	BOOST_CHECK(i == 1);

	// lambda expression as a left operand with rvalue on RHS
	(_1 += (0 + 1))(i);
	BOOST_CHECK(i == 2);

	(_1 -= (0 + 1))(i);
	BOOST_CHECK(i == 1);

	(_1 *= (0 + 10))(i);
	BOOST_CHECK(i == 10);

	(_1 /= (0 + 2))(i);
	BOOST_CHECK(i == 5);

	(_1 %= (0 + 2))(i);
	BOOST_CHECK(i == 1);

	// shifts
	unsigned int ui = 2;
	(_1 <<= 1)(ui);
	BOOST_CHECK(ui==(2 << 1));

	ui = 2;
	(_1 >>= 1)(ui);
	BOOST_CHECK(ui==(2 >> 1));

	ui = 2;
	(ui <<= _1)(make_const(1));
	BOOST_CHECK(ui==(2 << 1));

	ui = 2;
	(ui >>= _1)(make_const(1));
	BOOST_CHECK(ui==(2 >> 1));

	// and, or, xor
	ui = 2;
	(_1 &= 1)(ui);
	BOOST_CHECK(ui==(2 & 1));

	ui = 2;
	(_1 \|= 1)(ui);
	BOOST_CHECK(ui==(2 \| 1));

	ui = 2;
	(_1 ^= 1)(ui);
	BOOST_CHECK(ui==(2 ^ 1));

	ui = 2;
	(ui &= _1)(make_const(1));
	BOOST_CHECK(ui==(2 & 1));

	ui = 2;
	(ui \|= _1)(make_const(1));
	BOOST_CHECK(ui==(2 \| 1));

	ui = 2;
	(ui ^= _1)(make_const(1));
	BOOST_CHECK(ui==(2 ^ 1));

	}

	void assignment_and_subscript() {

	// assignment and subscript need to be defined as member functions.
	// Hence, if you wish to use a normal variable as the left hand argument,
	// you must wrap it with var to turn it into a lambda expression

	using std::string;
	string s;

	(_1 = "one")(s);
	BOOST_CHECK(s == string("one"));

	(var(s) = "two")();
	BOOST_CHECK(s == string("two"));

	BOOST_CHECK((var(s)[_1])(make_const(2)) == 'o');
	BOOST_CHECK((_1[2])(s) == 'o');
	BOOST_CHECK((_1[_2])(s, make_const(2)) == 'o');

	// subscript returns lvalue
	(var(s)[_1])(make_const(1)) = 'o';
	BOOST_CHECK(s == "too");

	(_1[1])(s) = 'a';
	BOOST_CHECK(s == "tao");

	(_1[_2])(s, make_const(0)) = 'm';
	BOOST_CHECK(s == "mao");

	// TODO: tests for vector, set, map, multimap
	}

	class A {};

	void address_of_and_dereference() {

	A a; int i = 42;

	BOOST_CHECK((&_1)(a) == &a);
	BOOST_CHECK((*&_1)(i) == 42);

	std::vector<int> vi; vi.push_back(1);
	std::vector<int>::iterator it = vi.begin();

	(*_1 = 7)(it);
	BOOST_CHECK(vi[0] == 7);
	const std::vector<int>::iterator cit(it);
	(*_1 = 8)(cit);
	BOOST_CHECK(vi[0] == 8);

	// TODO: Add tests for more complex iterator types

	boost::shared_ptr<int> ptr(new int(0));
	(*_1 = 7)(ptr);
	BOOST_CHECK(*ptr == 7);
	const boost::shared_ptr<int> cptr(ptr);
	(*_1 = 8)(cptr);
	BOOST_CHECK(*ptr == 8);
	}



	void comma() {

	int i = 100;
	BOOST_CHECK((_1 = 10, 2 * _1)(i) == 20);

	// TODO: that the return type is the exact type of the right argument
	// (that r/l valueness is preserved)

	}

	void pointer_arithmetic() {

	int ia[4] = { 1, 2, 3, 4 };
	int* ip = ia;
	int* ia_last = &ia[3];

	const int cia[4] = { 1, 2, 3, 4 };
	const int* cip = cia;
	const int* cia_last = &cia[3];


	// non-const array
	BOOST_CHECK((*(_1 + 1))(ia) == 2);

	// non-const pointer
	BOOST_CHECK((*(_1 + 1))(ip) == 2);

	BOOST_CHECK((*(_1 - 1))(ia_last) == 3);

	// const array
	BOOST_CHECK((*(_1 + 1))(cia) == 2);
	// const pointer
	BOOST_CHECK((*(_1 + 1))(cip) == 2);
	BOOST_CHECK((*(_1 - 1))(cia_last) == 3);

	// pointer arithmetic should not make non-consts const
	(*(_1 + 2))(ia) = 0;
	(*(_1 + 3))(ip) = 0;

	BOOST_CHECK(ia[2] == 0);
	BOOST_CHECK(ia[3] == 0);

	// pointer - pointer
	BOOST_CHECK((_1 - _2)(ia_last, ia) == 3);
	BOOST_CHECK((_1 - _2)(cia_last, cia) == 3);
	BOOST_CHECK((ia_last - _1)(ia) == 3);
	BOOST_CHECK((cia_last - _1)(cia) == 3);
	BOOST_CHECK((cia_last - _1)(cip) == 3);

	}

	int test_main(int, char *[]) {

	arithmetic_operators();
	bitwise_operators();
	comparison_operators();
	logical_operators();
	unary_incs_and_decs();
	compound_operators();
	assignment_and_subscript();
	address_of_and_dereference();
	comma();
	pointer_arithmetic();
	cout_tests();
	return 0;
	}