/*========================================================================= * * Copyright Insight Software Consortium * * Licensed 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.txt * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * *=========================================================================*/ #ifndef itkNumericTraitsFixedArrayPixel_h #define itkNumericTraitsFixedArrayPixel_h #include "itkNumericTraits.h" #include "itkFixedArray.h" namespace itk { /** * \brief Define numeric traits for FixedArray. * \tparam T Component type of the FixedArray * \tparam D Dimension of the FixedArray * * We provide here a generic implementation based on creating types of * FixedArray whose components are the types of the NumericTraits from * the original FixedArray components. This implementation require * support for partial specializations, since it is based on the * concept that: * NumericTraits > is defined piecewise by * FixedArray< NumericTraits< T > > * * \sa NumericTraits * \ingroup DataRepresentation * \ingroup ITKCommon */ template< typename T, unsigned int D > class NumericTraits< FixedArray< T, D > > { private: typedef typename NumericTraits< T >::AbsType ElementAbsType; typedef typename NumericTraits< T >::AccumulateType ElementAccumulateType; typedef typename NumericTraits< T >::FloatType ElementFloatType; typedef typename NumericTraits< T >::PrintType ElementPrintType; typedef typename NumericTraits< T >::RealType ElementRealType; public: /** Return the type of the native component type. */ typedef T ValueType; typedef FixedArray< T, D > Self; /** Unsigned component type */ typedef FixedArray< ElementAbsType, D > AbsType; /** Accumulation of addition and multiplication. */ typedef FixedArray< ElementAccumulateType, D > AccumulateType; /** Typedef for operations that use floating point instead of real precision */ typedef FixedArray< ElementFloatType, D > FloatType; /** Return the type that can be printed. */ typedef FixedArray< ElementPrintType, D > PrintType; /** Type for real-valued scalar operations. */ typedef FixedArray< ElementRealType, D > RealType; /** Type for real-valued scalar operations. */ typedef ElementRealType ScalarRealType; /** Measurement vector type */ typedef Self MeasurementVectorType; /** Component wise defined element * * \note minimum value for floating pointer types is defined as * minimum positive normalize value. */ static const Self max(const Self &) { return Self( NumericTraits< T >::max() ); } static const Self min(const Self &) { return Self( NumericTraits< T >::min() ); } static const Self max() { return Self( NumericTraits< T >::max() ); } static const Self min() { return Self( NumericTraits< T >::min() ); } static const Self NonpositiveMin() { return Self( NumericTraits< T >::NonpositiveMin() ); } static const Self ZeroValue() { return Self( NumericTraits< T >::ZeroValue() ); } static const Self OneValue() { return Self( NumericTraits< T >::OneValue() ); } static const Self NonpositiveMin(const Self &) { return NonpositiveMin(); } static const Self ZeroValue(const Self &) { return ZeroValue(); } static const Self OneValue(const Self &) { return OneValue(); } /** Fixed length vectors cannot be resized, so an exception will * be thrown if the input size is not valid. If the size is valid * the vector will be filled with zeros. */ static void SetLength(FixedArray< T, D > & m, const unsigned int s) { if ( s != D ) { itkGenericExceptionMacro(<< "Cannot set the size of a FixedArray of length " << D << " to " << s); } m.Fill(NumericTraits< T >::ZeroValue()); } /** Return the length of the array. */ static unsigned int GetLength(const FixedArray< T, D > &) { return D; } /** Return the length of the array. */ static unsigned int GetLength() { return D; } static void AssignToArray( const Self & v, MeasurementVectorType & mv ) { mv = v; } template static void AssignToArray( const Self & v, TArray & mv ) { for( unsigned int i=0; i \ ITKCommon_EXPORT const GENERIC_ARRAY< T, D > NumericTraits< GENERIC_ARRAY< T, D > >::Zero = GENERIC_ARRAY< T, D >( \ NumericTraits< T >::Zero); \ template< > \ ITKCommon_EXPORT const GENERIC_ARRAY< T, D > NumericTraits< GENERIC_ARRAY< T, D > >::One = GENERIC_ARRAY< T, D >( \ NumericTraits< T >::One); // // List here the array dimension specializations of these static // Traits: // #define itkStaticNumericTraitsGenericArrayDimensionsMacro(GENERIC_ARRAY, T) \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 1); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 2); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 3); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 4); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 5); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 6); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 7); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 8); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 9); \ itkStaticNumericTraitsGenericArrayMacro(GENERIC_ARRAY, T, 10); } // end namespace itk #endif // itkNumericTraitsFixedArrayPixel_h