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/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* This file incorporates work covered by the following license notice:
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed
* with this work for additional information regarding copyright
* ownership. The ASF licenses this file to you under the Apache
* License, Version 2.0 (the "License"); you may not use this file
* except in compliance with the License. You may obtain a copy of
* the License at http://www.apache.org/licenses/LICENSE-2.0 .
*/
#ifndef INCLUDED_BASEBMP_ACCESSORFUNCTORS_HXX
#define INCLUDED_BASEBMP_ACCESSORFUNCTORS_HXX
#include <osl/diagnose.h>
#include <basebmp/metafunctions.hxx>
#include <functional>
namespace basebmp
{
// Some common accessor functors
/// combine two values via XOR
template< typename T > struct XorFunctor : public std::binary_function<T,T,T>
{
T operator()( T v1, T v2 ) const { return v1 ^ v2; }
};
/// Base class, passing on the arg types
template< typename T, typename M > struct MaskFunctorBase :
public TernaryFunctorBase<T,M,T,T> {};
/** Let a mask flag decide between two values
@tpl polarity
Mask polarity. When true, a false in the mask denotes
transparency, i.e. the original value will display. And vice
versa.
*/
template< typename T,
typename M,
bool polarity > struct GenericOutputMaskFunctor : public MaskFunctorBase<T,M>
{
/// Ternary mask operation - selects v1 for !m == polarity, v2 otherwise
T operator()( T v1, M m, T v2 ) const
{
return !m == polarity ? v1 : v2;
}
};
/** Let a mask bit decide between two values (specialization for
integer mask types)
*/
template< typename T,
typename M,
bool polarity > struct IntegerOutputMaskFunctor;
template< typename T,
typename M > struct IntegerOutputMaskFunctor<T,M,true> : public MaskFunctorBase<T,M>
{
/** Mask v with state of m
@return v2, if m != 0, v1 otherwise.
*/
T operator()( T v1, M m, T v2 ) const
{
typedef typename make_unsigned<T>::type unsigned_T;
// mask will be 0, iff m == 0, and 1 otherwise
const T mask( unsigned_cast<T>(m | -m) >> (sizeof(unsigned_T)*8 - 1) );
return v1*(M)(1-mask) + v2*mask;
}
};
template< typename T,
typename M > struct IntegerOutputMaskFunctor<T,M,false> : public MaskFunctorBase<T,M>
{
/** Mask v with state of m
@return v2, if m != 0, v1 otherwise.
*/
T operator()( T v1, M m, T v2 ) const
{
typedef typename make_unsigned<T>::type unsigned_T;
// mask will be 0, iff m == 0, and 1 otherwise
const T mask( unsigned_cast<T>(m | -m) >> (sizeof(unsigned_T)*8 - 1) );
return v1*mask + v2*(M)(1-mask);
}
};
/** Let a mask bit decide between two values (specialization for
binary-valued mask types)
*/
template< typename T, typename M, bool polarity > struct FastIntegerOutputMaskFunctor;
template< typename T, typename M > struct FastIntegerOutputMaskFunctor<T,M,true> :
public MaskFunctorBase<T,M>
{
/// Specialization, only valid if mask can only attain 0 or 1
T operator()( T v1, M m, T v2 ) const
{
OSL_ASSERT(m<=1);
return v1*(M)(1-m) + v2*m;
}
};
template< typename T, typename M > struct FastIntegerOutputMaskFunctor<T,M,false> :
public MaskFunctorBase<T,M>
{
/// Specialization, only valid if mask can only attain 0 or 1
T operator()( T v1, M m, T v2 ) const
{
OSL_ASSERT(m<=1);
return v1*m + v2*(M)(1-m);
}
};
/** Split a pair value from a JoinImageAccessorAdapter into its
individual values, and pass it on to a ternary functor
This wrapper is an adaptable binary functor, and can thus be used
with a BinarySetterFunctionAccessorAdapter. Useful e.g. for
out-of-image alpha channel, or a masked image.
@tpl Functor
An adaptable ternary functor (as can e.g. be passed to the
TernarySetterFunctionAccessorAdapter)
*/
template< typename Functor > struct BinaryFunctorSplittingWrapper :
public std::binary_function<typename Functor::first_argument_type,
std::pair<typename Functor::third_argument_type,
typename Functor::second_argument_type>,
typename Functor::result_type>
{
#ifndef BOOST_NO_MEMBER_TEMPLATE_FRIENDS
// making all members public, if no member template friends
private:
template<class A> friend struct BinaryFunctorSplittingWrapper;
#endif
Functor maFunctor;
public:
BinaryFunctorSplittingWrapper() : maFunctor() {}
template< class A > explicit
BinaryFunctorSplittingWrapper(
BinaryFunctorSplittingWrapper<A> const& src ) : maFunctor(src.maFunctor) {}
template< class F > explicit
BinaryFunctorSplittingWrapper( F const& func ) : maFunctor(func) {}
typename Functor::result_type operator()(
typename Functor::first_argument_type v1,
std::pair< typename Functor::third_argument_type,
typename Functor::second_argument_type > const& v2 ) const
{
return maFunctor( v1, v2.second, v2.first );
}
};
} // namespace basebmp
#endif /* INCLUDED_BASEBMP_ACCESSORFUNCTORS_HXX */
/* vim:set shiftwidth=4 softtabstop=4 expandtab: */
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