boost_1_45_0/libs/smart_ptr/test/smart_ptr_test.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  smart pointer test program  ----------------------------------------------//

 //  Copyright Beman Dawes 1998, 1999.  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)

 //  See http://www.boost.org/libs/smart_ptr for documentation.

 //  Revision History
 //  24 May 01  use Boost test library for error detection, reporting, add tests
 //             for operations on incomplete types (Beman Dawes)
 //  29 Nov 99  added std::swap and associative container tests (Darin Adler)
 //  25 Sep 99  added swap tests
 //  20 Jul 99  header name changed to .hpp
 //  20 Apr 99  additional error tests added.

 #include <boost/config.hpp>

 #if defined(BOOST_MSVC)

 # pragma warning(disable: 4786)  // identifier truncated in debug info
 # pragma warning(disable: 4710)  // function not inlined
 # pragma warning(disable: 4711)  // function selected for automatic inline expansion
 # pragma warning(disable: 4514)  // unreferenced inline removed

 #if (BOOST_MSVC >= 1310)
 # pragma warning(disable: 4675)  // resolved overload found with Koenig lookup
 #endif

 #endif

 #ifdef __BORLANDC__
 # pragma warn -8092 // template argument passed to 'find' is not an iterator
 #endif

 #include <boost/scoped_ptr.hpp>
 #include <boost/scoped_array.hpp>
 #include <boost/shared_ptr.hpp>
 #include <boost/shared_array.hpp>

 #include <boost/detail/lightweight_test.hpp>

 #include <iostream>
 #include <set>
 #include <string.h>

 class Incomplete;

 Incomplete * get_ptr(  boost::shared_ptr<Incomplete>& incomplete )
 {
   return incomplete.get();
 }

 template<class T>
 void ck( const T* v1, T v2 ) { BOOST_TEST( *v1 == v2 ); }

 namespace {
   int UDT_use_count;  // independent of pointer maintained counts
   }

 //  user defined type  -------------------------------------------------------//

 class UDT {
   long value_;
  public:
   explicit UDT( long value=0 ) : value_(value) { ++UDT_use_count; }
   ~UDT() {
     --UDT_use_count;
     std::cout << "UDT with value " << value_ << " being destroyed\n";
     }
   long value() const { return value_; }
   void value( long v ) { value_ = v;; }
   };  // UDT

 //  tests on incomplete types  -----------------------------------------------//

 //  Certain smart pointer operations are specified to work on incomplete types,
 //  and some uses depend upon this feature.  These tests verify compilation
 //  only - the functions aren't actually invoked.

 class Incomplete;

 Incomplete * check_incomplete( boost::scoped_ptr<Incomplete>& incomplete )
 {
   return incomplete.get();
 }

 Incomplete * check_incomplete( boost::shared_ptr<Incomplete>& incomplete,
                                boost::shared_ptr<Incomplete>& i2 )
 {
   incomplete.swap(i2);
   std::cout << incomplete.use_count() << ' ' << incomplete.unique() << '\n';
   return incomplete.get();
 }

 //  This isn't a very systematic test; it just hits some of the basics.

 void test()
 {
     BOOST_TEST( UDT_use_count == 0 );  // reality check

     //  test scoped_ptr with a built-in type
     long * lp = new long;
     boost::scoped_ptr<long> sp ( lp );
     BOOST_TEST( sp.get() == lp );
     BOOST_TEST( lp == sp.get() );
     BOOST_TEST( &*sp == lp );

     *sp = 1234568901L;
     BOOST_TEST( *sp == 1234568901L );
     BOOST_TEST( *lp == 1234568901L );
     ck( static_cast<long*>(sp.get()), 1234568901L );
     ck( lp, *sp );

     sp.reset();
     BOOST_TEST( sp.get() == 0 );

     //  test scoped_ptr with a user defined type
     boost::scoped_ptr<UDT> udt_sp ( new UDT( 999888777 ) );
     BOOST_TEST( udt_sp->value() == 999888777 );
     udt_sp.reset();
     udt_sp.reset( new UDT( 111222333 ) );
     BOOST_TEST( udt_sp->value() == 111222333 );
     udt_sp.reset( new UDT( 333222111 ) );
     BOOST_TEST( udt_sp->value() == 333222111 );

     //  test scoped_array with a build-in type
     char * sap = new char [ 100 ];
     boost::scoped_array<char> sa ( sap );
     BOOST_TEST( sa.get() == sap );
     BOOST_TEST( sap == sa.get() );

     strcpy( sa.get(), "Hot Dog with mustard and relish" );
     BOOST_TEST( strcmp( sa.get(), "Hot Dog with mustard and relish" ) == 0 );
     BOOST_TEST( strcmp( sap, "Hot Dog with mustard and relish" ) == 0 );

     BOOST_TEST( sa[0] == 'H' );
     BOOST_TEST( sa[30] == 'h' );

     sa[0] = 'N';
     sa[4] = 'd';
     BOOST_TEST( strcmp( sap, "Not dog with mustard and relish" ) == 0 );

     sa.reset();
     BOOST_TEST( sa.get() == 0 );

     //  test shared_ptr with a built-in type
     int * ip = new int;
     boost::shared_ptr<int> cp ( ip );
     BOOST_TEST( ip == cp.get() );
     BOOST_TEST( cp.use_count() == 1 );

     *cp = 54321;
     BOOST_TEST( *cp == 54321 );
     BOOST_TEST( *ip == 54321 );
     ck( static_cast<int*>(cp.get()), 54321 );
     ck( static_cast<int*>(ip), *cp );

     boost::shared_ptr<int> cp2 ( cp );
     BOOST_TEST( ip == cp2.get() );
     BOOST_TEST( cp.use_count() == 2 );
     BOOST_TEST( cp2.use_count() == 2 );

     BOOST_TEST( *cp == 54321 );
     BOOST_TEST( *cp2 == 54321 );
     ck( static_cast<int*>(cp2.get()), 54321 );
     ck( static_cast<int*>(ip), *cp2 );

     boost::shared_ptr<int> cp3 ( cp );
     BOOST_TEST( cp.use_count() == 3 );
     BOOST_TEST( cp2.use_count() == 3 );
     BOOST_TEST( cp3.use_count() == 3 );
     cp.reset();
     BOOST_TEST( cp2.use_count() == 2 );
     BOOST_TEST( cp3.use_count() == 2 );
     cp.reset( new int );
     *cp =  98765;
     BOOST_TEST( *cp == 98765 );
     *cp3 = 87654;
     BOOST_TEST( *cp3 == 87654 );
     BOOST_TEST( *cp2 == 87654 );
     cp.swap( cp3 );
     BOOST_TEST( *cp == 87654 );
     BOOST_TEST( *cp2 == 87654 );
     BOOST_TEST( *cp3 == 98765 );
     cp.swap( cp3 );
     BOOST_TEST( *cp == 98765 );
     BOOST_TEST( *cp2 == 87654 );
     BOOST_TEST( *cp3 == 87654 );
     cp2 = cp2;
     BOOST_TEST( cp2.use_count() == 2 );
     BOOST_TEST( *cp2 == 87654 );
     cp = cp2;
     BOOST_TEST( cp2.use_count() == 3 );
     BOOST_TEST( *cp2 == 87654 );
     BOOST_TEST( cp.use_count() == 3 );
     BOOST_TEST( *cp == 87654 );

 #if defined( BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP )
     using boost::swap;
 #endif

     boost::shared_ptr<int> cp4;
     swap( cp2, cp4 );
     BOOST_TEST( cp4.use_count() == 3 );
     BOOST_TEST( *cp4 == 87654 );
     BOOST_TEST( cp2.get() == 0 );

     std::set< boost::shared_ptr<int> > scp;
     scp.insert(cp4);
     BOOST_TEST( scp.find(cp4) != scp.end() );
     BOOST_TEST( scp.find(cp4) == scp.find( boost::shared_ptr<int>(cp4) ) );

     //  test shared_array with a built-in type
     char * cap = new char [ 100 ];
     boost::shared_array<char> ca ( cap );
     BOOST_TEST( ca.get() == cap );
     BOOST_TEST( cap == ca.get() );
     BOOST_TEST( &ca[0] == cap );

     strcpy( ca.get(), "Hot Dog with mustard and relish" );
     BOOST_TEST( strcmp( ca.get(), "Hot Dog with mustard and relish" ) == 0 );
     BOOST_TEST( strcmp( cap, "Hot Dog with mustard and relish" ) == 0 );

     BOOST_TEST( ca[0] == 'H' );
     BOOST_TEST( ca[30] == 'h' );

     boost::shared_array<char> ca2 ( ca );
     boost::shared_array<char> ca3 ( ca2 );

     ca[0] = 'N';
     ca[4] = 'd';
     BOOST_TEST( strcmp( ca.get(), "Not dog with mustard and relish" ) == 0 );
     BOOST_TEST( strcmp( ca2.get(), "Not dog with mustard and relish" ) == 0 );
     BOOST_TEST( strcmp( ca3.get(), "Not dog with mustard and relish" ) == 0 );
     BOOST_TEST( ca.use_count() == 3 );
     BOOST_TEST( ca2.use_count() == 3 );
     BOOST_TEST( ca3.use_count() == 3 );
     ca2.reset();
     BOOST_TEST( ca.use_count() == 2 );
     BOOST_TEST( ca3.use_count() == 2 );
     BOOST_TEST( ca2.use_count() == 1 );

     ca.reset();
     BOOST_TEST( ca.get() == 0 );

     boost::shared_array<char> ca4;
     swap( ca3, ca4 );
     BOOST_TEST( ca4.use_count() == 1 );
     BOOST_TEST( strcmp( ca4.get(), "Not dog with mustard and relish" ) == 0 );
     BOOST_TEST( ca3.get() == 0 );

     std::set< boost::shared_array<char> > sca;
     sca.insert(ca4);
     BOOST_TEST( sca.find(ca4) != sca.end() );
     BOOST_TEST( sca.find(ca4) == sca.find( boost::shared_array<char>(ca4) ) );

     //  test shared_array with user defined type
     boost::shared_array<UDT> udta ( new UDT[3] );

     udta[0].value( 111 );
     udta[1].value( 222 );
     udta[2].value( 333 );
     boost::shared_array<UDT> udta2 ( udta );

     BOOST_TEST( udta[0].value() == 111 );
     BOOST_TEST( udta[1].value() == 222 );
     BOOST_TEST( udta[2].value() == 333 );
     BOOST_TEST( udta2[0].value() == 111 );
     BOOST_TEST( udta2[1].value() == 222 );
     BOOST_TEST( udta2[2].value() == 333 );
     udta2.reset();
     BOOST_TEST( udta2.get() == 0 );
     BOOST_TEST( udta.use_count() == 1 );
     BOOST_TEST( udta2.use_count() == 1 );

     BOOST_TEST( UDT_use_count == 4 );  // reality check

     //  test shared_ptr with a user defined type
     UDT * up = new UDT;
     boost::shared_ptr<UDT> sup ( up );
     BOOST_TEST( up == sup.get() );
     BOOST_TEST( sup.use_count() == 1 );

     sup->value( 54321 ) ;
     BOOST_TEST( sup->value() == 54321 );
     BOOST_TEST( up->value() == 54321 );

     boost::shared_ptr<UDT> sup2;
     sup2 = sup;
     BOOST_TEST( sup2->value() == 54321 );
     BOOST_TEST( sup.use_count() == 2 );
     BOOST_TEST( sup2.use_count() == 2 );
     sup2 = sup2;
     BOOST_TEST( sup2->value() == 54321 );
     BOOST_TEST( sup.use_count() == 2 );
     BOOST_TEST( sup2.use_count() == 2 );

     std::cout << "OK\n";

     new char[12345]; // deliberate memory leak to verify leaks detected
 }

 int main()
 {
     test();
     return boost::report_errors();
 }
	// smart pointer test program ----------------------------------------------//

	// Copyright Beman Dawes 1998, 1999. 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)

	// See http://www.boost.org/libs/smart_ptr for documentation.

	// Revision History
	// 24 May 01 use Boost test library for error detection, reporting, add tests
	// for operations on incomplete types (Beman Dawes)
	// 29 Nov 99 added std::swap and associative container tests (Darin Adler)
	// 25 Sep 99 added swap tests
	// 20 Jul 99 header name changed to .hpp
	// 20 Apr 99 additional error tests added.

	#include <boost/config.hpp>

	#if defined(BOOST_MSVC)

	# pragma warning(disable: 4786) // identifier truncated in debug info
	# pragma warning(disable: 4710) // function not inlined
	# pragma warning(disable: 4711) // function selected for automatic inline expansion
	# pragma warning(disable: 4514) // unreferenced inline removed

	#if (BOOST_MSVC >= 1310)
	# pragma warning(disable: 4675) // resolved overload found with Koenig lookup
	#endif

	#endif

	#ifdef __BORLANDC__
	# pragma warn -8092 // template argument passed to 'find' is not an iterator
	#endif

	#include <boost/scoped_ptr.hpp>
	#include <boost/scoped_array.hpp>
	#include <boost/shared_ptr.hpp>
	#include <boost/shared_array.hpp>

	#include <boost/detail/lightweight_test.hpp>

	#include <iostream>
	#include <set>
	#include <string.h>

	class Incomplete;

	Incomplete * get_ptr( boost::shared_ptr<Incomplete>& incomplete )
	{
	return incomplete.get();
	}

	template<class T>
	void ck( const T* v1, T v2 ) { BOOST_TEST( *v1 == v2 ); }

	namespace {
	int UDT_use_count; // independent of pointer maintained counts
	}

	// user defined type -------------------------------------------------------//

	class UDT {
	long value_;
	public:
	explicit UDT( long value=0 ) : value_(value) { ++UDT_use_count; }
	~UDT() {
	--UDT_use_count;
	std::cout << "UDT with value " << value_ << " being destroyed\n";
	}
	long value() const { return value_; }
	void value( long v ) { value_ = v;; }
	}; // UDT

	// tests on incomplete types -----------------------------------------------//

	// Certain smart pointer operations are specified to work on incomplete types,
	// and some uses depend upon this feature. These tests verify compilation
	// only - the functions aren't actually invoked.

	class Incomplete;

	Incomplete * check_incomplete( boost::scoped_ptr<Incomplete>& incomplete )
	{
	return incomplete.get();
	}

	Incomplete * check_incomplete( boost::shared_ptr<Incomplete>& incomplete,
	boost::shared_ptr<Incomplete>& i2 )
	{
	incomplete.swap(i2);
	std::cout << incomplete.use_count() << ' ' << incomplete.unique() << '\n';
	return incomplete.get();
	}

	// This isn't a very systematic test; it just hits some of the basics.

	void test()
	{
	BOOST_TEST( UDT_use_count == 0 ); // reality check

	// test scoped_ptr with a built-in type
	long * lp = new long;
	boost::scoped_ptr<long> sp ( lp );
	BOOST_TEST( sp.get() == lp );
	BOOST_TEST( lp == sp.get() );
	BOOST_TEST( &*sp == lp );

	*sp = 1234568901L;
	BOOST_TEST( *sp == 1234568901L );
	BOOST_TEST( *lp == 1234568901L );
	ck( static_cast<long*>(sp.get()), 1234568901L );
	ck( lp, *sp );

	sp.reset();
	BOOST_TEST( sp.get() == 0 );

	// test scoped_ptr with a user defined type
	boost::scoped_ptr<UDT> udt_sp ( new UDT( 999888777 ) );
	BOOST_TEST( udt_sp->value() == 999888777 );
	udt_sp.reset();
	udt_sp.reset( new UDT( 111222333 ) );
	BOOST_TEST( udt_sp->value() == 111222333 );
	udt_sp.reset( new UDT( 333222111 ) );
	BOOST_TEST( udt_sp->value() == 333222111 );

	// test scoped_array with a build-in type
	char * sap = new char [ 100 ];
	boost::scoped_array<char> sa ( sap );
	BOOST_TEST( sa.get() == sap );
	BOOST_TEST( sap == sa.get() );

	strcpy( sa.get(), "Hot Dog with mustard and relish" );
	BOOST_TEST( strcmp( sa.get(), "Hot Dog with mustard and relish" ) == 0 );
	BOOST_TEST( strcmp( sap, "Hot Dog with mustard and relish" ) == 0 );

	BOOST_TEST( sa[0] == 'H' );
	BOOST_TEST( sa[30] == 'h' );

	sa[0] = 'N';
	sa[4] = 'd';
	BOOST_TEST( strcmp( sap, "Not dog with mustard and relish" ) == 0 );

	sa.reset();
	BOOST_TEST( sa.get() == 0 );

	// test shared_ptr with a built-in type
	int * ip = new int;
	boost::shared_ptr<int> cp ( ip );
	BOOST_TEST( ip == cp.get() );
	BOOST_TEST( cp.use_count() == 1 );

	*cp = 54321;
	BOOST_TEST( *cp == 54321 );
	BOOST_TEST( *ip == 54321 );
	ck( static_cast<int*>(cp.get()), 54321 );
	ck( static_cast<int>(ip), cp );

	boost::shared_ptr<int> cp2 ( cp );
	BOOST_TEST( ip == cp2.get() );
	BOOST_TEST( cp.use_count() == 2 );
	BOOST_TEST( cp2.use_count() == 2 );

	BOOST_TEST( *cp == 54321 );
	BOOST_TEST( *cp2 == 54321 );
	ck( static_cast<int*>(cp2.get()), 54321 );
	ck( static_cast<int>(ip), cp2 );

	boost::shared_ptr<int> cp3 ( cp );
	BOOST_TEST( cp.use_count() == 3 );
	BOOST_TEST( cp2.use_count() == 3 );
	BOOST_TEST( cp3.use_count() == 3 );
	cp.reset();
	BOOST_TEST( cp2.use_count() == 2 );
	BOOST_TEST( cp3.use_count() == 2 );
	cp.reset( new int );
	*cp = 98765;
	BOOST_TEST( *cp == 98765 );
	*cp3 = 87654;
	BOOST_TEST( *cp3 == 87654 );
	BOOST_TEST( *cp2 == 87654 );
	cp.swap( cp3 );
	BOOST_TEST( *cp == 87654 );
	BOOST_TEST( *cp2 == 87654 );
	BOOST_TEST( *cp3 == 98765 );
	cp.swap( cp3 );
	BOOST_TEST( *cp == 98765 );
	BOOST_TEST( *cp2 == 87654 );
	BOOST_TEST( *cp3 == 87654 );
	cp2 = cp2;
	BOOST_TEST( cp2.use_count() == 2 );
	BOOST_TEST( *cp2 == 87654 );
	cp = cp2;
	BOOST_TEST( cp2.use_count() == 3 );
	BOOST_TEST( *cp2 == 87654 );
	BOOST_TEST( cp.use_count() == 3 );
	BOOST_TEST( *cp == 87654 );

	#if defined( BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP )
	using boost::swap;
	#endif

	boost::shared_ptr<int> cp4;
	swap( cp2, cp4 );
	BOOST_TEST( cp4.use_count() == 3 );
	BOOST_TEST( *cp4 == 87654 );
	BOOST_TEST( cp2.get() == 0 );

	std::set< boost::shared_ptr<int> > scp;
	scp.insert(cp4);
	BOOST_TEST( scp.find(cp4) != scp.end() );
	BOOST_TEST( scp.find(cp4) == scp.find( boost::shared_ptr<int>(cp4) ) );

	// test shared_array with a built-in type
	char * cap = new char [ 100 ];
	boost::shared_array<char> ca ( cap );
	BOOST_TEST( ca.get() == cap );
	BOOST_TEST( cap == ca.get() );
	BOOST_TEST( &ca[0] == cap );

	strcpy( ca.get(), "Hot Dog with mustard and relish" );
	BOOST_TEST( strcmp( ca.get(), "Hot Dog with mustard and relish" ) == 0 );
	BOOST_TEST( strcmp( cap, "Hot Dog with mustard and relish" ) == 0 );

	BOOST_TEST( ca[0] == 'H' );
	BOOST_TEST( ca[30] == 'h' );

	boost::shared_array<char> ca2 ( ca );
	boost::shared_array<char> ca3 ( ca2 );

	ca[0] = 'N';
	ca[4] = 'd';
	BOOST_TEST( strcmp( ca.get(), "Not dog with mustard and relish" ) == 0 );
	BOOST_TEST( strcmp( ca2.get(), "Not dog with mustard and relish" ) == 0 );
	BOOST_TEST( strcmp( ca3.get(), "Not dog with mustard and relish" ) == 0 );
	BOOST_TEST( ca.use_count() == 3 );
	BOOST_TEST( ca2.use_count() == 3 );
	BOOST_TEST( ca3.use_count() == 3 );
	ca2.reset();
	BOOST_TEST( ca.use_count() == 2 );
	BOOST_TEST( ca3.use_count() == 2 );
	BOOST_TEST( ca2.use_count() == 1 );

	ca.reset();
	BOOST_TEST( ca.get() == 0 );

	boost::shared_array<char> ca4;
	swap( ca3, ca4 );
	BOOST_TEST( ca4.use_count() == 1 );
	BOOST_TEST( strcmp( ca4.get(), "Not dog with mustard and relish" ) == 0 );
	BOOST_TEST( ca3.get() == 0 );

	std::set< boost::shared_array<char> > sca;
	sca.insert(ca4);
	BOOST_TEST( sca.find(ca4) != sca.end() );
	BOOST_TEST( sca.find(ca4) == sca.find( boost::shared_array<char>(ca4) ) );

	// test shared_array with user defined type
	boost::shared_array<UDT> udta ( new UDT[3] );

	udta[0].value( 111 );
	udta[1].value( 222 );
	udta[2].value( 333 );
	boost::shared_array<UDT> udta2 ( udta );

	BOOST_TEST( udta[0].value() == 111 );
	BOOST_TEST( udta[1].value() == 222 );
	BOOST_TEST( udta[2].value() == 333 );
	BOOST_TEST( udta2[0].value() == 111 );
	BOOST_TEST( udta2[1].value() == 222 );
	BOOST_TEST( udta2[2].value() == 333 );
	udta2.reset();
	BOOST_TEST( udta2.get() == 0 );
	BOOST_TEST( udta.use_count() == 1 );
	BOOST_TEST( udta2.use_count() == 1 );

	BOOST_TEST( UDT_use_count == 4 ); // reality check

	// test shared_ptr with a user defined type
	UDT * up = new UDT;
	boost::shared_ptr<UDT> sup ( up );
	BOOST_TEST( up == sup.get() );
	BOOST_TEST( sup.use_count() == 1 );

	sup->value( 54321 ) ;
	BOOST_TEST( sup->value() == 54321 );
	BOOST_TEST( up->value() == 54321 );

	boost::shared_ptr<UDT> sup2;
	sup2 = sup;
	BOOST_TEST( sup2->value() == 54321 );
	BOOST_TEST( sup.use_count() == 2 );
	BOOST_TEST( sup2.use_count() == 2 );
	sup2 = sup2;
	BOOST_TEST( sup2->value() == 54321 );
	BOOST_TEST( sup.use_count() == 2 );
	BOOST_TEST( sup2.use_count() == 2 );

	std::cout << "OK\n";

	new char[12345]; // deliberate memory leak to verify leaks detected
	}

	int main()
	{
	test();
	return boost::report_errors();
	}