/////////////////////////////////////////////////////////////////////////// // FILE: functional (Functional templates) // // Open Watcom Project // // Copyright (c) 2004-2008 The Open Watcom Contributors. All Rights Reserved. // // This file is automatically generated. Do not edit directly. // // ========================================================================= // // Description: This header is part of the C++ standard library. It // defines a number of functional-like templates and // associated binders and adaptors. /////////////////////////////////////////////////////////////////////////// #ifndef _FUNCTIONAL_INCLUDED #define _FUNCTIONAL_INCLUDED #if !defined(_ENABLE_AUTODEPEND) #pragma read_only_file; #endif #ifndef __cplusplus #error The header functional requires C++ #endif #ifndef _CSTDDEF_INCLUDED #include #endif namespace std { template< class Arg1, class Result > struct unary_function { typedef Arg1 argument_type; typedef Result result_type; }; template< class Arg1, class Arg2, class Result > struct binary_function { typedef Arg1 first_argument_type; typedef Arg2 second_argument_type; typedef Result result_type; }; template< class Type > struct plus : binary_function< Type, Type, Type > { Type operator( )( const Type &x, const Type &y ) const { return( x + y ); } }; template< class Type > struct minus : binary_function< Type, Type, Type > { Type operator( )( const Type &x, const Type &y ) const { return( x - y ); } }; template< class Type > struct multiplies : binary_function< Type, Type, Type > { Type operator( )( const Type &x, const Type &y ) const { return( x * y ); } }; template< class Type > struct divides : binary_function< Type, Type, Type > { Type operator( )( const Type &x, const Type &y ) const { return( x / y ); } }; template< class Type > struct modulus : binary_function< Type, Type, Type > { Type operator( )( const Type &x, const Type &y ) const { return( x % y ); } }; template< class Type > struct negate : unary_function< Type, Type > { Type operator( )( const Type &x ) const { return( -x ); } }; template< class Type > struct equal_to : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x == y ); } }; template< class Type > struct not_equal_to : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x != y ); } }; template< class Type > struct greater : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x > y ); } }; template< class Type > struct less : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x < y ); } }; template< class Type > struct greater_equal : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x >= y ); } }; template< class Type > struct less_equal : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x <= y ); } }; template< class Type > struct logical_and : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x && y ); } }; template< class Type > struct logical_or : binary_function< Type, Type, bool > { bool operator( )( const Type &x, const Type &y ) const { return( x || y ); } }; template< class Type > struct logical_not : unary_function< Type, bool > { bool operator( )( const Type &x ) const { return( !x ); } }; template< class Predicate > class unary_negate : public unary_function< typename Predicate::argument_type, bool > { const Predicate &pred; public: explicit unary_negate( const Predicate &p ) : pred( p ) { } bool operator( )( const typename Predicate::argument_type &x ) const { return( !pred( x ) ); } }; template< class Predicate > inline unary_negate< Predicate > not1( const Predicate &p ) { return( unary_negate< Predicate >( p ) ); } template< class Predicate > class binary_negate : public binary_function< typename Predicate::first_argument_type, typename Predicate::second_argument_type, bool > { const Predicate &pred; public: explicit binary_negate( const Predicate &p ) : pred( p ) { } bool operator( )( const typename Predicate::first_argument_type &x, const typename Predicate::second_argument_type &y ) const { return( !pred( x, y ) ); } }; template< class Predicate > inline binary_negate< Predicate > not2( const Predicate &p ) { return( binary_negate< Predicate >( p ) ); } template< class Operation > class binder1st : public unary_function< typename Operation::second_argument_type, typename Operation::result_type > { protected: Operation op; typename Operation::first_argument_type value; public: binder1st( const Operation &x, const typename Operation::first_argument_type &y ) : op( x ), value( y ) { } typename Operation::result_type operator( )( const typename Operation::second_argument_type &x ) const { return( op( value, x ) ); } }; template< class Operation, class Type > inline binder1st< Operation > bind1st( const Operation &x, const Type &y ) { return( binder1st< Operation >( x, typename Operation::first_argument_type( y ) ) ); } template< class Operation > class binder2nd : public unary_function< typename Operation::first_argument_type, typename Operation::result_type > { protected: Operation op; typename Operation::second_argument_type value; public: binder2nd( const Operation &x, const typename Operation::second_argument_type &y ) : op( x ), value( y ) { } typename Operation::result_type operator( )( const typename Operation::first_argument_type &x ) const { return( op( x, value ) ); } }; template< class Operation, class Type > inline binder2nd< Operation > bind2nd( const Operation &x, const Type &y ) { return( binder2nd< Operation >( x, typename Operation::second_argument_type( y ) ) ); } template< class Arg1, class Result > class pointer_to_unary_function : public unary_function< Arg1, Result > { Result ( *p )( Arg1 ); public: explicit pointer_to_unary_function( Result ( *f )( Arg1 ) ) : p( f ) { } Result operator( )( Arg1 x ) const { return( p( x ) ); } }; template< class Arg1, class Arg2, class Result > class pointer_to_binary_function : public binary_function< Arg1, Arg2, Result > { Result ( *p )( Arg1, Arg2 ); public: explicit pointer_to_binary_function( Result ( *f )( Arg1, Arg2 ) ) : p( f ) { } Result operator( )( Arg1 x, Arg2 y ) const { return( p( x, y ) ); } }; template< class Arg1, class Result > inline pointer_to_unary_function< Arg1, Result > ptr_fun( Result ( *f )( Arg1 ) ) { return( pointer_to_unary_function< Arg1, Result >( f ) ); } template< class Arg1, class Arg2, class Result > inline pointer_to_binary_function< Arg1, Arg2, Result > ptr_fun( Result ( *f )( Arg1, Arg2 ) ) { return( pointer_to_binary_function< Arg1, Arg2, Result >( f ) ); } template< class Result, class Klass > class mem_fun_t : public unary_function< Klass*, Result > { Result ( Klass::*p )( ); public: explicit mem_fun_t( Result ( Klass::*f )( ) ) : p( f ) { } Result operator( )( Klass *x ) const { return( ( x->*p )( ) ); } }; template< class Result, class Klass, class Arg > class mem_fun1_t : public binary_function< Klass*, Arg, Result > { Result ( Klass::*p )( Arg ); public: explicit mem_fun1_t( Result ( Klass::*f )( Arg ) ) : p( f ) { } Result operator( )( Klass *x, Arg y ) const { return( ( x->*p )( y ) ); } }; template< class Result, class Klass > inline mem_fun_t< Result, Klass > mem_fun( Result ( Klass::*f )( ) ) { return( mem_fun_t< Result, Klass >( f ) ); } template< class Result, class Klass, class Arg > inline mem_fun1_t< Result, Klass, Arg > mem_fun( Result ( Klass::*f )( Arg ) ) { return( mem_fun1_t< Result, Klass, Arg >( f ) ); } template< class Result, class Klass > class mem_fun_ref_t : public unary_function< Klass, Result > { Result ( Klass::*p )( ); public: explicit mem_fun_ref_t( Result ( Klass::*f )( ) ) : p( f ) { } Result operator( )( Klass &x ) const { return( ( x.*p )( ) ); } }; template< class Result, class Klass, class Arg > class mem_fun1_ref_t : public binary_function< Klass, Arg, Result > { Result ( Klass::*p )( Arg ); public: explicit mem_fun1_ref_t( Result ( Klass::*f )( Arg ) ) : p( f ) { } Result operator( )( Klass &x, Arg y ) const { return( ( x.*p )( y ) ); } }; template< class Result, class Klass > inline mem_fun_ref_t< Result, Klass > mem_fun_ref( Result ( Klass::*f )( ) ) { return( mem_fun_ref_t< Result, Klass >( f ) ); } template< class Result, class Klass, class Arg > inline mem_fun1_ref_t< Result, Klass, Arg > mem_fun_ref( Result ( Klass::*f )( Arg ) ) { return( mem_fun1_ref_t< Result, Klass, Arg >( f ) ); } template< class Result, class Klass > class const_mem_fun_t : public unary_function< const Klass*, Result > { Result ( Klass::*p )( ) const; public: explicit const_mem_fun_t( Result ( Klass::*f )( ) const ) : p( f ) { } Result operator( )( const Klass *x ) const { return( ( x->*p )( ) ); } }; template< class Result, class Klass, class Arg > class const_mem_fun1_t : public binary_function< const Klass*, Arg, Result > { Result ( Klass::*p )( Arg ) const; public: explicit const_mem_fun1_t( Result ( Klass::*f )( Arg ) const ) : p( f ) { } Result operator( )( const Klass *x, Arg y ) const { return( ( x->*p )( y ) ); } }; template< class Result, class Klass > inline const_mem_fun_t< Result, Klass > mem_fun( Result ( Klass::*f )( ) const ) { return( const_mem_fun_t< Result, Klass >( f ) ); } template< class Result, class Klass, class Arg > inline const_mem_fun1_t< Result, Klass, Arg > mem_fun( Result ( Klass::*f )( Arg ) const ) { return( const_mem_fun1_t< Result, Klass, Arg >( f ) ); } template< class Result, class Klass > class const_mem_fun_ref_t : public unary_function< Klass, Result > { Result ( Klass::*p )( ) const; public: explicit const_mem_fun_ref_t( Result ( Klass::*f )( ) const ) : p( f ) { } Result operator( )( const Klass &x ) const { return( ( x.*p )( ) ); } }; template< class Result, class Klass, class Arg > class const_mem_fun1_ref_t : public binary_function< Klass, Arg, Result > { Result ( Klass::*p )( Arg ) const; public: explicit const_mem_fun1_ref_t( Result ( Klass::*f )( Arg ) const ) : p( f ) { } Result operator( )( const Klass &x, Arg y ) const { return( ( x.*p )( y ) ); } }; template< class Result, class Klass > inline const_mem_fun_ref_t< Result, Klass > mem_fun_ref( Result ( Klass::*f )( ) const ) { return( const_mem_fun_ref_t< Result, Klass >( f ) ); } template< class Result, class Klass, class Arg > inline const_mem_fun1_ref_t< Result, Klass, Arg > mem_fun_ref( Result ( Klass::*f )( Arg ) const ) { return( const_mem_fun1_ref_t< Result, Klass, Arg >( f ) ); } // ================================ // struct hash with specializations // ================================ template< class Type > struct hash : public unary_function< Type, size_t > { size_t operator( )( Type value ) const; }; template< > struct hash< bool > : public unary_function< bool, size_t > { size_t operator( )( bool value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< char > : public unary_function< char, size_t > { size_t operator( )( char value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< signed char > : public unary_function< signed char, size_t > { size_t operator( )( signed char value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< unsigned char > : public unary_function< unsigned char, size_t > { size_t operator( )( unsigned char value ) const { return( static_cast< size_t >( value ) ); } }; // Assume wchar_t is not more than 16 bits. template< > struct hash< wchar_t > : public unary_function< wchar_t, size_t > { size_t operator( )( wchar_t value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< short > : public unary_function< short, size_t > { size_t operator( )( short value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< unsigned short > : public unary_function< unsigned short, size_t > { size_t operator( )( unsigned short value ) const { return( static_cast< size_t >( value ) ); } }; // Assume size_t is always at least as wide as int. template< > struct hash< int > : public unary_function< int, size_t > { size_t operator( )( int value ) const { return( static_cast< size_t >( value ) ); } }; // Assume size_t is always at least as wide as unsigned int. template< > struct hash< unsigned > : public unary_function< unsigned, size_t > { size_t operator( )( unsigned value ) const { return( static_cast< size_t >( value ) ); } }; #if defined(__386__) || defined(__AXP__) || defined (__PPC__) || defined(__MIPS__) template< > struct hash< long > : public unary_function< long, size_t > { size_t operator( )( long value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< unsigned long > : public unary_function< unsigned long, size_t > { size_t operator( )( unsigned long value ) const { return( static_cast< size_t >( value ) ); } }; template< > struct hash< long long > : public unary_function< long long, size_t > { size_t operator( )( long long value ) const { long long result = value; result ^= (value & 0xFFFFFFFF00000000ULL) >> 32; return( static_cast< size_t >( result ) ); } }; template< > struct hash< unsigned long long > : public unary_function< unsigned long long, size_t > { size_t operator( )( unsigned long long value ) const { unsigned long long result = value; result ^= (value & 0xFFFFFFFF00000000ULL) >> 32; return( static_cast< size_t >( result ) ); } }; #else // 16 bit template< > struct hash< long > : public unary_function< long, size_t > { size_t operator( )( long value ) const { long result = value; result ^= (value & 0xFFFF0000UL) >> 16; return( static_cast< size_t >( result ) ); } }; template< > struct hash< unsigned long > : public unary_function< unsigned long, size_t > { size_t operator( )( unsigned long value ) const { unsigned long result = value; result ^= (value & 0xFFFF0000UL) >> 16; return( static_cast< size_t >( result ) ); } }; template< > struct hash< long long > : public unary_function< long long, size_t > { size_t operator( )( long long value ) const { long long result = value; result ^= (value & 0x00000000FFFF0000ULL) >> 16; result ^= (value & 0x0000FFFF00000000ULL) >> 32; result ^= (value & 0xFFFF000000000000ULL) >> 48; return( static_cast< size_t >( result ) ); } }; template< > struct hash< unsigned long long > : public unary_function< unsigned long long, size_t > { size_t operator( )( unsigned long long value ) const { unsigned long long result = value; result ^= (value & 0x00000000FFFF0000ULL) >> 16; result ^= (value & 0x0000FFFF00000000ULL) >> 32; result ^= (value & 0xFFFF000000000000ULL) >> 48; return( static_cast< size_t >( result ) ); } }; #endif template< class Type > struct hash< Type * > : public unary_function< Type *, size_t > { size_t operator( )( Type *p ) const { return( static_cast< size_t >( p ) ); } }; } // End of namespace std. #endif