/usr/include/trilinos/Teuchos_Array.hpp is in libtrilinos-teuchos-dev 12.10.1-3.
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// ***********************************************************************
//
// Teuchos: Common Tools Package
// Copyright (2004) Sandia Corporation
//
// Under terms of Contract DE-AC04-94AL85000, there is a non-exclusive
// license for use of this work by or on behalf of the U.S. Government.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// 1. Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
//
// 2. Redistributions in binary form must reproduce the above copyright
// notice, this list of conditions and the following disclaimer in the
// documentation and/or other materials provided with the distribution.
//
// 3. Neither the name of the Corporation nor the names of the
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY SANDIA CORPORATION "AS IS" AND ANY
// EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
// PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL SANDIA CORPORATION OR THE
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// EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
// PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
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// LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
// NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
// SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// Questions? Contact Michael A. Heroux (maherou@sandia.gov)
//
// ***********************************************************************
// @HEADER
#ifndef TEUCHOS_ARRAY_H
#define TEUCHOS_ARRAY_H
/*! \file Teuchos_Array.hpp
\brief Templated array class derived from the STL std::vector
*/
#include "Teuchos_ConfigDefs.hpp"
#include "Teuchos_Assert.hpp"
#include "Teuchos_TypeNameTraits.hpp"
#include "Teuchos_ArrayRCP.hpp"
#include "Teuchos_Tuple.hpp"
#include "Teuchos_Utils.hpp"
#include "Teuchos_Assert.hpp"
namespace Teuchos {
/** \brief .
*
* \ingroup teuchos_mem_mng_grp
*/
class InvalidArrayStringRepresentation : public std::logic_error
{public:InvalidArrayStringRepresentation(const std::string& what_arg) : std::logic_error(what_arg) {}};
template<typename T> class Array;
// 2007/11/30: rabartl: Below, I had to move the initial declaration of these
// non-member template functions outside of the Array class since the Sun
// compiler on sass9000 would not accept this. However, this did work on a
// number of other compilers such a g++, Intel C++ etc. The old in-class
// non-member friend definition is clearly ISO 98 C++ as shown in Item 46 of
// "Effective C++: Third Edition". This is not the end of the world but this
// is something to remember for this platform.
/** \brief Equality operator.
*
* \relates Array
*/
template<typename T> inline
bool operator==( const Array<T> &a1, const Array<T> &a2 );
/** \brief Non-equality operator.
*
* \relates Array
*/
template<typename T> inline
bool operator!=( const Array<T> &a1, const Array<T> &a2 );
/** \brief Non-member swap (specializes default std version).
*
* \relates Array
*/
template<typename T> inline
void swap( Array<T> &a1, Array<T> &a2 );
/** \brief Less-than operator.
*
* \relates Array
*/
template<typename T> inline
bool operator<( const Array<T> &a1, const Array<T> &a2 );
/** \brief Less-than-or-equal operator.
*
* \relates Array
*/
template<typename T> inline
bool operator<=( const Array<T> &a1, const Array<T> &a2 );
/** \brief Greater-than operator.
*
* \relates Array
*/
template<typename T> inline
bool operator>( const Array<T> &a1, const Array<T> &a2 );
/** \brief Greater-than-or-equal operator.
*
* \relates Array
*/
template<typename T> inline
bool operator>=( const Array<T> &a1, const Array<T> &a2 );
/** \brief Replacement for std::vector that is compatible with
* the Teuchos Memory Management classes.
* \tparam T The type of each entry in the array.
* \ingroup teuchos_mem_mng_grp
*
* This class implements a one-dimensional array, with a number of
* entries specified at run time. It can be used as a drop-in
* replacement for the C++98 version of std::vector<T>. It also has
* functions and methods for interacting with the other Teuchos Memory
* Management classes. For example, you can get a nonpersisting view
* of an Array's entries as an ArrayView, or a nonowning (weak)
* ArrayRCP.
*
* If the CMake configuration option Teuchos_ENABLE_DEBUG is ON at
* build time, Array will do bounds and iterator checking at run time.
* This has a nontrivial run-time cost, so it is off by default, but
* you may find it useful for debugging. Please note that if
* debugging is on, the types of Array's iterators change in order to
* implement these checks. Thus, you should always use Array's
* typedefs to get the iterator types, and not assume that they are
* raw pointers.
*
* \section Teuchos_Array_Tuple_sec Tuple Construction
*
* A user can create a Teuchos::Tuple object to initialize an Array object by
* using one of the the convenient overloaded Teuchos::tuple() non-member
* constructor functions. For example, see Array_test.cpp for how this is
* done.
*
* \section Teuchos_Array_DesignDiscussion_sec Design Discussion
*
* Currently, this class defines implicit conversions to ArrayView. An
* alternative design would be to have Array derive from ArrayView. This is a
* workable design but it would impart some extra storage and runtime
* overhead. Perhaps the most significant overhead would be having the reset
* the base ArrayView pointer and size on each and every change in the
* structure of the container. This would import extra overhead beyond a
* straight std::vector.
*
* The big advantage of deriving Array from ArrayView is that this would allow
* Array to be used to call some functions taking ArrayView without requiring
* an implicit conversion. While the implicit shallow conversion from Array
* to ArrayView is very cheap (just a pointer and int copy), it does cause
* problems where the compiler will refuse to perform an implicit conversion
* to call a templated function. However, note that an implicit conversion to
* an ArrayView<const T> would always have to be performed no matter what.
*
* In summary, having Array implicitly convert to ArrayView instead of having
* Array derive from ArrayView results in faster and simpler code at the
* expense of the compiler refusing the make implicit conversions in some
* cases when calling template functions. Such conversion problems can always
* be dealt with by using explicit template arguments.
*/
template<typename T>
class Array
{
public:
// 2007/11/30: rabartl: Below, note that the only reason that these
// functions are declared as friends is so that the compiler will do
// automatic type conversions as described in "Effective C++: Third Edition"
// Item 46.
/** \brief . */
template<typename T2>
friend bool Teuchos::operator==( const Array<T2> &a1, const Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend bool Teuchos::operator!=( const Array<T2> &a1, const Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend void swap( Array<T2> &a1, Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend bool Teuchos::operator<( const Array<T2> &a1, const Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend bool Teuchos::operator<=( const Array<T2> &a1, const Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend bool Teuchos::operator>( const Array<T2> &a1, const Array<T2> &a2 );
/** \brief . */
template<typename T2>
friend bool Teuchos::operator>=( const Array<T2> &a1, const Array<T2> &a2 );
/** \name std::vector typedefs */
//@{
//! The type of indices.
typedef Teuchos_Ordinal Ordinal;
//! The type of Array sizes and capacities.
typedef Ordinal size_type;
//! The type of the difference between two size_type values.
typedef Ordinal difference_type;
//! The type of an entry of the Array; for compatibility with std::vector.
typedef typename std::vector<T>::value_type value_type;
//! The type of a pointer to T; for compatibility with std::vector.
typedef typename std::vector<T>::pointer pointer;
//! The type of a const pointer to T; for compatibility with std::vector.
typedef typename std::vector<T>::const_pointer const_pointer;
//! The type of a reference to T; for compatibility with std::vector.
typedef typename std::vector<T>::reference reference;
//! The type of a const reference to T; for compatibility with std::vector.
typedef typename std::vector<T>::const_reference const_reference;
//! The allocator type; for compatibility with std::vector.
typedef typename std::vector<T>::allocator_type allocator_type;
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
//! The type of a forward iterator.
typedef ArrayRCP<T> iterator;
//! The type of a const forward iterator.
typedef ArrayRCP<const T> const_iterator;
//! The type of a reverse iterator.
typedef std::reverse_iterator<iterator> reverse_iterator;
//! The type of a const reverse iterator.
typedef std::reverse_iterator<const_iterator> const_reverse_iterator;
#else
//! The type of a forward iterator.
typedef typename std::vector<T>::iterator iterator;
//! The type of a const forward iterator.
typedef typename std::vector<T>::const_iterator const_iterator;
//! The type of a reverse iterator.
typedef typename std::vector<T>::reverse_iterator reverse_iterator;
//! The type of a const reverse iterator.
typedef typename std::vector<T>::const_reverse_iterator const_reverse_iterator;
#endif
//@}
/** \name All constructors */
//@{
//! Default constructor; creates an empty Array.
inline Array();
//! Create an array of length n, and fill it with the given value.
inline explicit Array(size_type n, const value_type& value = value_type());
//! Copy constructor (does a deep copy).
inline Array(const Array<T>& x);
//! Create an array, and fill it with values from the given iterator range.
template<typename InputIterator>
inline Array(InputIterator first, InputIterator last);
//! Create an Array which is a deep copy of the given ArrayView.
inline Array(const ArrayView<const T>& a);
//! Copy constructor from the given Tuple.
template<int N>
inline Array(const Tuple<T,N>& t);
//! Destructor.
inline ~Array();
//! Assignment operator (does a deep copy).
inline Array& operator=(const Array<T>& a);
//@}
/// \name Other std::vector functions
///
/// Array has mostly the same interface as std::vector. This allows
/// use of Array in place of std::vector, for gradual porting to use
/// the Teuchos Memory Management classes.
//@{
/** \brief . */
inline void assign(size_type n, const value_type& val);
/** \brief . */
template<typename InputIterator>
inline void assign(InputIterator first, InputIterator last);
/** \brief . */
inline iterator begin();
/** \brief . */
inline iterator end();
/** \brief . */
inline const_iterator begin() const;
/** \brief . */
inline const_iterator end() const;
/** \brief . */
inline reverse_iterator rbegin();
/** \brief . */
inline reverse_iterator rend();
/** \brief . */
inline const_reverse_iterator rbegin() const;
/** \brief . */
inline const_reverse_iterator rend() const;
/** \brief . */
inline size_type size() const;
/** \brief . */
inline size_type max_size() const;
/** \brief . */
inline void resize(size_type new_size, const value_type& x = value_type());
/** \brief . */
inline size_type capacity() const;
/** \brief . */
inline bool empty() const;
/** \brief . */
inline void reserve(size_type n);
/** \brief . */
inline reference operator[](size_type i);
/** \brief . */
inline const_reference operator[](size_type i) const;
/** \brief . */
inline reference at(size_type i);
/** \brief . */
inline const_reference at(size_type i) const;
/** \brief . */
inline reference front();
/** \brief . */
inline const_reference front() const;
/** \brief . */
inline reference back();
/** \brief . */
inline const_reference back() const;
/** \brief . */
inline void push_back(const value_type& x);
/** \brief . */
inline void pop_back();
/** \brief . */
inline iterator insert(iterator position, const value_type& x);
/** \brief . */
inline void insert(iterator position, size_type n, const value_type& x);
/** \brief . */
template<typename InputIterator>
inline void insert(iterator position, InputIterator first, InputIterator last);
/** \brief . */
inline iterator erase(iterator position);
/** \brief . */
inline iterator erase(iterator first, iterator last);
/** \brief . */
inline void swap(Array& x);
/** \brief . */
inline void clear();
//@}
/** \name General non-standard functions. */
//@{
/** \brief Add a new entry at the end of the array.
*
* Resize to allow space for the new entry.
*/
inline Array<T>& append(const T& x);
/** \brief Remove the i-th element from the array, with optional
* boundschecking.
*/
inline void remove(int i);
/** \brief Return number of elements in the array.
*
* Equivalent to size(), but * included for backwards compatibility.
*/
inline int length() const;
/** \brief Convert an Array to an <tt>std::string</tt> */
inline std::string toString() const;
/** \brief Return true if Array has been compiled with boundschecking on. */
inline static bool hasBoundsChecking();
/** \brief Return a raw pointer to beginning of array or NULL if unsized. */
inline T* getRawPtr();
/** \brief Return a const raw pointer to beginning of array or NULL if unsized. */
inline const T* getRawPtr() const;
//@}
/** \name Conversions to and from std::vector. */
//@{
//! Copy constructor from an std::vector (does a deep copy).
inline Array( const std::vector<T> &v );
/** \brief Explicit copy conversion to an std::vector. */
inline std::vector<T> toVector() const;
/** \brief Assignment operator for std::vector. */
inline Array& operator=( const std::vector<T> &v );
//@}
//! @name Views
//@{
/** \brief Return non-const view of a contiguous range of elements.
*
* <b>Preconditions:</b><ul>
* <li><tt>0 <= offset && offset + size <= this->size()</tt>
* </ul>
*
* <b>Postconditions:</b><ul>
* <li><tt>returnVal.size() == size</tt>
* </ul>
*
* NOTE: A <tt>size==0</tt> view of even an empty Array is allowed and
* returns a <tt>null</tt> view.
*/
inline ArrayView<T> view( size_type offset, size_type size );
/** \brief Return const view of a contiguous range of elements.
*
* <b>Preconditions:</b><ul>
* <li><tt>0 <= offset && offset + size <= this->size()</tt>
* </ul>
*
* <b>Postconditions:</b><ul>
* <li><tt>returnVal.size() == size</tt>
* </ul>
*
* NOTE: A <tt>size==0</tt> view of even an empty Array is allowed and
* returns a <tt>null</tt> view.
*/
inline ArrayView<const T> view( size_type offset, size_type size ) const;
/** \brief Return a non-const view of a contiguous range of elements (calls
* view(offset,size)).
*/
inline ArrayView<T> operator()( size_type offset, size_type size );
/** \brief Return a const view of a contiguous range of elements (calls
* view(offset,size)).
*/
inline ArrayView<const T> operator()( size_type offset, size_type size ) const;
/** \brief Return an non-const ArrayView of *this.
*
* NOTE: This will return a null ArrayView if this->size() == 0.
*/
inline ArrayView<T> operator()();
/** \brief Return an const ArrayView of *this.
*
* NOTE: This will return a null ArrayView if this->size() == 0.
*/
inline ArrayView<const T> operator()() const;
/** \brief Perform an implicit conversion to a non-const ArrayView (calls
* operator()()).
*/
inline operator ArrayView<T>();
/** \brief Perform an implicit conversion to a non-const ArrayView (calls
* operator()()).
*/
inline operator ArrayView<const T>() const;
//@}
private:
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
RCP<std::vector<T> > vec_;
mutable ArrayRCP<T> extern_arcp_;
mutable ArrayRCP<const T> extern_carcp_;
#else
std::vector<T> vec_;
#endif
inline std::vector<T>& vec(
bool isStructureBeingModified = false,
bool activeIter = false
);
inline const std::vector<T>& vec() const;
inline typename std::vector<T>::iterator
raw_position( iterator position );
inline void assertIndex(size_type i) const;
inline void assertNotNull() const;
};
/** \brief Wrap an <tt>RCP<Array<T> ></tt> object as an <tt>ArrayRCP<T></tt>
* object.
*
* \relates ArrayRCP
*/
template<class T>
ArrayRCP<T> arcp( const RCP<Array<T> > &v )
{
if ( is_null(v) || !v->size() )
return null;
return arcpWithEmbeddedObjPostDestroy<T,RCP<Array<T> > >(
&(*v)[0], 0, v->size(),
v, false
);
}
/** \brief Wrap a <tt>RCP<const Array<T> ></tt> object as an
* <tt>ArrayRCP<const T></tt> object.
*
* \relates ArrayRCP
*/
template<class T>
ArrayRCP<const T> arcp( const RCP<const Array<T> > &v )
{
if ( is_null(v) || !v->size() )
return null;
return arcpWithEmbeddedObjPostDestroy<const T,RCP<const Array<T> > >(
&(*v)[0], 0, v->size(),
v, false
);
}
/** \brief Wrap an <tt>Array<T></tt> object as a non-owning
* <tt>ArrayRCP<T></tt> object.
*
* \relates ArrayRCP
*/
template<class T>
ArrayRCP<T> arcpFromArray( Array<T> &a )
{
if (a.size() == 0)
return null;
#ifdef TEUCHOS_DEBUG
return a.begin(); // Catch dangling reference!
#else
return arcp(a.getRawPtr(), 0, a.size(), false);
#endif
}
/** \brief Wrap a <tt>const Array<T></tt> object as a non-owning
* <tt>ArrayRCP<T></tt> object.
*
* \relates ArrayRCP
*/
template<class T>
ArrayRCP<const T> arcpFromArray( const Array<T> &a )
{
if (a.size() == 0)
return null;
#ifdef TEUCHOS_DEBUG
return a.begin(); // Catch dangling reference!
#else
return arcp(a.getRawPtr(), 0, a.size(), false);
#endif
}
/** \brief Write an Array to an ostream.
*
* This prints arrays in the form:
\verbatim
{ 1.0, 2.0, 3.0 }
\endverbatim
* \relates Array
*/
template<typename T>
std::ostream& operator<<(std::ostream& os, const Array<T>& array);
/** \brief Return the hash code.
*
* \relates Array.
*/
template<typename T> inline
int hashCode(const Array<T>& array);
/** \brief Copy conversion to an std::vector.
*
* This function is included for consistency with ArrayView.
*
* \relates Array.
*/
template<typename T> inline
std::vector<T> createVector( const Array<T> &a );
/** \brief Convert an array to a string representation.
*
* \relates Array
*/
template<typename T>
std::string toString(const Array<T>& array);
/** \brief Converts from std::string representation (as created by
* <tt>toString()</tt>) back into the array object.
*
* \param arrayStr [in] The std::string representation of the array (see
* below).
*
* <b>Exceptions:</b> If the std::string representation is not valid, then an
* std::exception of type <tt>InvalidArrayStringRepresentation</tt> with be
* thrown with a decent error message attached.
*
* The formating of the std::string <tt>arrayStr</tt> must look like:
\verbatim
{ val[0], val[1], val[2], val[3], ..., val[n-1] }
\endverbatim
* Currently <tt>operator>>()</tt> is used to convert the entries from their
* std::string representation to objects of type <tt>T</tt>. White space is
* unimportant and the parser keys off of ',', '{' and '}' so even newlines
* are allowed. In the future, a traits class might be defined that will
* allow for finer-grained control of how the conversion from strings to
* values is performed in cases where <tt>operator>>()</tt> does not exist
* for certain types.
*
* <b>Warning!</b> Currently this function only supports reading in flat
* array objects for basic types like <tt>bool</tt>, <tt>int</tt>, and
* <tt>double</tt> and does not yet support nested arrays (i.e. no
* <tt>Array<Array<int> ></tt>) or other such fancy nested types. Support
* for nested arrays and other user defined types <tt>T</tt> can be added in
* the future with no impact on user code. Only the parser for the array
* needs to be improved. More specifically, the current implementation will
* not work for any types <tt>T</tt> who's std::string representation contains
* the characters <tt>','</tt> or <tt>'}'</tt>. This implementation can be
* modified to allow any such types by watching for the nesting of common
* enclosing structures like <tt>[...]</tt>, <tt>{...}</tt> or
* <tt>(...)</tt> within each entry of the std::string representation. However,
* this should all just work fine on most machines for the types
* <tt>int</tt>, <tt>bool</tt>, <tt>float</tt>, <tt>double</tt> etc.
*
* <b>Warning!</b> Trying to read in an array in std::string format of doubles in
* scientific notation such as <tt>{1e+2,3.53+6,...}</tt> into an array
* object such as <tt>Array<int></tt> will not yield the correct results.
* If one wants to allow a neutral std::string representation to be read in as an
* <tt>Array<double></tt> object or an <tt>Array<int></tt> object, then
* general formating such as <tt>{100,3530000,...}</tt> should be used.
* This templated function is unable to deal std::complex type conversion issues.
*
* \relates Array.
*/
template<typename T>
Array<T> fromStringToArray(const std::string& arrayStr);
/** \brief A wrapper around the \c fromStringToArray function
* which allows the operator>> to be used on Arrays.
*
* \relates Array
*/
template<typename T>
std::istringstream& operator>> (std::istringstream& in, Array<T>& array){
array = fromStringToArray<T>(in.str());
return in;
}
/** \brief Extracts data from an istringstream object
* \note This templated function is necessary for the proper extraction of
* data by the \c fromStringToArray function.
* \relates Array.
*/
template<typename T> inline
void extractDataFromISS( std::istringstream& iss, T& data )
{
iss >> data; // Assumes type has operator>>(...) defined!
}
/** \brief Extracts std::string data from an istringstream object
* \note This function overloads the templated \c extractDataFromISS function
and is necessary for the proper extraction of std::string objects
by the \c fromStringToArray function.
* \relates Array.
*/
inline
void extractDataFromISS( std::istringstream& iss, std::string& data )
{
// grab unformatted string.
data = iss.str();
// remove white space from beginning and end of string.
data = Utils::trimWhiteSpace(data);
}
/**
* \brief Get the format that is used for the specialization of the TypeName
* traits class for Array.
*
* The string returned will contain only one
* "*" character. The "*" character should then be replaced with the actual
* template type of the array.
* \relates Array.
*/
inline
std::string getArrayTypeNameTraitsFormat(){
return "Array(*)";
}
/** \brief TypeNameTraits specialization for Array.
*
* NOTE: Use of this class requires that either that the type T be
* defined or that a TypeNameTraits<T> specialization exists. In
* order not to restrict the use of Array<T> for undefined pointer
* types (where T=U*), this TypeNameTraits class specialization will
* not be used in core Array functionality.
*
* This matters because some MPI implementations use pointers to
* undefined structs. If you want to portably store these undefined
* struct pointers in an Array, then you can't use this traits class.
* This is a limitation of the C++ language itself.
*
* \ingroup teuchos_mem_mng_grp
*/
template<typename T>
class TEUCHOSCORE_LIB_DLL_EXPORT TypeNameTraits<Array<T> > {
public:
static std::string name(){
std::string formatString = getArrayTypeNameTraitsFormat();
size_t starPos = formatString.find("*");
std::string prefix = formatString.substr(0,starPos);
std::string postFix = formatString.substr(starPos+1);
return prefix+TypeNameTraits<T>::name()+postFix;
}
static std::string concreteName(const Array<T>&)
{ return name(); }
};
} // namespace Teuchos
//
// Implementation
//
namespace Teuchos {
// All constructors
template<typename T> inline
Array<T>::Array()
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
: vec_(rcp(new std::vector<T>()))
#endif
{}
template<typename T> inline
Array<T>::Array(size_type n, const value_type& value) :
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
vec_(rcp(new std::vector<T>(n,value)))
#else
vec_(n, value)
#endif
{}
template<typename T> inline
Array<T>::Array(const Array<T>& x) :
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
vec_(rcp(new std::vector<T>(*x.vec_)))
#else
vec_(x.vec_)
#endif
{}
template<typename T> template<typename InputIterator> inline
Array<T>::Array(InputIterator first, InputIterator last) :
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
vec_(rcp(new std::vector<T>(first, last)))
#else
vec_(first, last)
#endif
{}
template<typename T> inline
Array<T>::~Array()
{}
template<typename T> inline
Array<T>::Array(const ArrayView<const T>& a)
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
: vec_(rcp(new std::vector<T>()))
#endif
{
insert(begin(), a.begin(), a.end());
}
template<typename T>
template<int N>
inline
Array<T>::Array(const Tuple<T,N>& t)
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
: vec_(rcp(new std::vector<T>()))
#endif
{
insert(begin(), t.begin(), t.end());
}
template<typename T> inline
Array<T>& Array<T>::operator=(const Array& a)
{
vec(true) = a.vec();
return *this;
}
// Other std::vector functions
template<typename T> inline
void Array<T>::assign(size_type n, const value_type& val)
{
vec(true).assign(n,val);
}
template<typename T> template<typename InputIterator> inline
void Array<T>::assign(InputIterator first, InputIterator last)
{
vec(true).assign(first,last);
}
template<typename T> inline
typename Array<T>::iterator
Array<T>::begin()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
if (is_null(extern_arcp_)) {
// Here we must use the same RCP to avoid creating two unrelated RCPNodes!
extern_arcp_ = arcp(vec_); // Will be null if vec_ is sized!
}
// Returning a weak pointer will help to catch dangling references but still
// keep the same behavior as optimized code.
return extern_arcp_.create_weak();
#else
return vec().begin();
#endif
}
template<typename T> inline
typename Array<T>::iterator
Array<T>::end()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return begin() + size();
#else
return vec().end();
#endif
}
template<typename T> inline
typename Array<T>::const_iterator
Array<T>::begin() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
if (is_null(extern_carcp_)) {
extern_carcp_ = const_cast<Array<T>*>(this)->begin();
}
// Returning a weak pointer will help to catch dangling references but still
// keep the same behavior as optimized code.
return extern_carcp_.create_weak();
#else
return vec().begin();
#endif
}
template<typename T> inline
typename Array<T>::const_iterator
Array<T>::end() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return begin() + size();
#else
return vec().end();
#endif
}
template<typename T> inline
typename Array<T>::reverse_iterator
Array<T>::rbegin()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return reverse_iterator(end());
#else
return vec().rbegin();
#endif
}
template<typename T> inline
typename Array<T>::reverse_iterator
Array<T>::rend()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return reverse_iterator(begin());
#else
return vec().rend();
#endif
}
template<typename T> inline
typename Array<T>::const_reverse_iterator
Array<T>::rbegin() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return const_reverse_iterator(end());
#else
return vec().rbegin();
#endif
}
template<typename T> inline
typename Array<T>::const_reverse_iterator
Array<T>::rend() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return const_reverse_iterator(begin());
#else
return vec().rend();
#endif
}
template<typename T> inline
typename Array<T>::size_type
Array<T>::size() const
{
return vec().size();
}
template<typename T> inline
typename Array<T>::size_type
Array<T>::max_size() const
{
return std::numeric_limits<size_type>::max();
}
template<typename T> inline
void
Array<T>::resize(size_type new_size, const value_type& x)
{
vec(true).resize(new_size,x);
}
template<typename T> inline
typename Array<T>::size_type
Array<T>::capacity() const
{
return vec().capacity();
}
template<typename T> inline
bool Array<T>::empty() const
{
return vec().empty();
}
template<typename T> inline
void Array<T>::reserve(size_type n)
{
vec(true).reserve(n);
}
template<typename T> inline
typename Array<T>::reference
Array<T>::operator[](size_type i)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertIndex(i);
#endif
return vec()[i];
}
template<typename T> inline
typename Array<T>::const_reference
Array<T>::operator[](size_type i) const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertIndex(i);
#endif
return vec()[i];
}
template<typename T> inline
typename Array<T>::reference
Array<T>::at(size_type i)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertIndex(i);
#endif
return vec().at(i);
}
template<typename T> inline
typename Array<T>::const_reference
Array<T>::at(size_type i) const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertIndex(i);
#endif
return vec().at(i);
}
template<typename T> inline
typename Array<T>::reference
Array<T>::front()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
#endif
return vec().front();
}
template<typename T> inline
typename Array<T>::const_reference
Array<T>::front() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
#endif
return vec().front();
}
template<typename T> inline
typename Array<T>::reference
Array<T>::back()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
#endif
return vec().back();
}
template<typename T> inline
typename Array<T>::const_reference
Array<T>::back() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
#endif
return vec().back();
}
template<typename T> inline
void Array<T>::push_back(const value_type& x)
{
vec(true).push_back(x);
}
template<typename T> inline
void Array<T>::pop_back()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
#endif
vec(true).pop_back();
}
// 2009/11/13:: rabartl: After moving to a full RCPNode tracing and lookup
// model, I had to how modifying functions like insert(...) and erase(...)
// work which have active iterators controled by the client and yet need to
// allow the structure of the container change. The way these troublesome
// functions work is that first the raw std::vector iterator is extracted.
// The function vec(true, true) then deletes the strong iterators but there is
// still a weak ArrayRCP object that is owned by the client which is being
// passed into this function. The issue is that the design of ArrayRCP is
// such that the RCPNode object is not removed but instead remains in order to
// perform runtime checking.
template<typename T> inline
typename Array<T>::iterator
Array<T>::insert(iterator position, const value_type& x)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
// Assert a valid iterator and get vector iterator
const typename std::vector<T>::iterator raw_poss = raw_position(position);
const difference_type i = position - begin();
vec(true, true).insert(raw_poss, x);
return begin() + i;
#else
return vec_.insert(position, x);
#endif
}
template<typename T> inline
void Array<T>::insert(iterator position, size_type n, const value_type& x)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
const typename std::vector<T>::iterator raw_poss = raw_position(position);
vec(true, true).insert(raw_poss, n, x);
#else
vec_.insert(position, n, x);
#endif
}
template<typename T> template<typename InputIterator> inline
void Array<T>::insert(iterator position, InputIterator first, InputIterator last)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
const typename std::vector<T>::iterator raw_poss = raw_position(position);
vec(true, true).insert(raw_poss, first, last);
#else
vec_.insert(position, first, last);
#endif
}
template<typename T> inline
typename Array<T>::iterator
Array<T>::erase(iterator position)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertNotNull();
// Assert a valid iterator and get vector iterator
const typename std::vector<T>::iterator raw_poss = raw_position(position);
const difference_type i = position - begin();
vec(true, true).erase(raw_poss);
return begin() + i;
#else
return vec_.erase(position);
#endif
}
template<typename T> inline
typename Array<T>::iterator
Array<T>::erase(iterator first, iterator last)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
if (empty()) {
TEUCHOS_ASSERT(first == begin());
TEUCHOS_ASSERT(last == end());
return end();
}
assertNotNull();
// Assert a valid iterator and get vector iterator
const typename std::vector<T>::iterator raw_first = raw_position(first);
const typename std::vector<T>::iterator raw_last = raw_position(last);
const difference_type i = first - begin();
vec(true,true).erase(raw_first,raw_last);
return begin() + i;
#else
return vec_.erase(first,last);
#endif
}
template<typename T> inline
void Array<T>::swap(Array& x)
{
vec(true).swap(x.vec());
}
template<typename T> inline
void Array<T>::clear()
{
vec(true).clear();
}
// Non-standard functions
template<typename T> inline
Array<T>& Array<T>::append(const T& x)
{
this->push_back(x);
return *this;
}
template<typename T> inline
void Array<T>::remove(int i)
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
assertIndex(i);
#endif
// Erase the i-th element of this array.
this->erase( this->begin() + i );
}
template<typename T> inline
int Array<T>::length() const
{
return static_cast<int> (this->size ());
}
template<typename T> inline
std::string Array<T>::toString() const
{
return (*this)().toString(); // Use ArrayView<T>::toString()
}
template<typename T> inline
bool Array<T>::hasBoundsChecking()
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return true;
#else
return false;
#endif
}
template<typename T> inline
T* Array<T>::getRawPtr()
{
return ( size() ? &(*this)[0] : 0 );
}
template<typename T> inline
const T* Array<T>::getRawPtr() const
{
return ( size() ? &(*this)[0] : 0 );
}
// Conversions to and from std::vector
template<typename T> inline
Array<T>::Array( const std::vector<T> &v ) :
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
vec_(new std::vector<T>(v))
#else
vec_(v)
#endif
{}
template<typename T> inline
std::vector<T> Array<T>::toVector() const
{
if (!size())
return std::vector<T>();
std::vector<T> v(begin(),end());
return v;
}
template<typename T> inline
Array<T>& Array<T>::operator=( const std::vector<T> &v )
{
vec(true) = v;
return *this;
}
// Views
template<typename T> inline
ArrayView<T> Array<T>::view( size_type offset, size_type size_in )
{
if (size_in) {
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return ArrayView<T>(this->begin().persistingView(offset, size_in));
#else
return arrayView( &vec()[offset], size_in );
#endif
}
return Teuchos::null;
}
template<typename T> inline
ArrayView<const T> Array<T>::view( size_type offset, size_type size_in ) const
{
if (size_in) {
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return ArrayView<const T>(this->begin().persistingView(offset, size_in));
#else
return arrayView( &vec()[offset], size_in );
#endif
}
return Teuchos::null;
// NOTE: Above, we use a different implementation to call the const version
// of begin() instead of the non-const version. This sets up a different
// ArrayRCP object that gets checked.
}
template<typename T> inline
ArrayView<T> Array<T>::operator()( size_type offset, size_type size_in )
{
return view(offset, size_in);
}
template<typename T> inline
ArrayView<const T> Array<T>::operator()( size_type offset, size_type size_in ) const
{
return view(offset, size_in);
}
template<typename T> inline
ArrayView<T> Array<T>::operator()()
{
if (!size())
return null;
return this->view(0, size());
}
template<typename T> inline
ArrayView<const T> Array<T>::operator()() const
{
if (!size())
return null;
return this->view(0, size());
}
template<typename T> inline
Array<T>::operator ArrayView<T>()
{
return this->operator()();
}
template<typename T> inline
Array<T>::operator ArrayView<const T>() const
{
return this->operator()();
}
// private
template<typename T>
std::vector<T>&
Array<T>::vec( bool isStructureBeingModified, bool activeIter )
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
(void)activeIter;
if (isStructureBeingModified) {
// Give up my ArrayRCPs used for iterator access since the array we be
// getting modifed! Any clients that have views through weak pointers
// better not touch them!
extern_arcp_ = null;
extern_carcp_ = null;
}
return *vec_;
#else
// get rid of "unused parameter" warnings
(void)isStructureBeingModified;
(void)activeIter;
return vec_;
#endif
}
template<typename T> inline
const std::vector<T>&
Array<T>::vec() const
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
return *vec_;
#else
return vec_;
#endif
}
template<typename T> inline
typename std::vector<T>::iterator
Array<T>::raw_position( iterator position )
{
#ifdef HAVE_TEUCHOS_ARRAY_BOUNDSCHECK
const iterator first = this->begin();
const iterator last = this->end();
TEUCHOS_TEST_FOR_EXCEPTION(
!(first <= position && position <= last), DanglingReferenceError,
"Error, this iterator is no longer valid for this Aray!"
);
// Note, above operator<=(...) functions will throw
// IncompatibleIteratorsError if the iterators do not share the same
// RCP_node object!
return vec_->begin() + (position - this->begin());
#else
return position;
#endif
}
template<typename T> inline
void Array<T>::assertIndex(size_type i) const
{
TEUCHOS_TEST_FOR_EXCEPTION(
!( 0 <= i && i < size() ), RangeError,
"Array<T>::assertIndex(i): i="<<i<<" out of range [0, "<< size() << ")"
);
}
template<typename T> inline
void Array<T>::assertNotNull() const
{
TEUCHOS_TEST_FOR_EXCEPTION(
!size(), NullReferenceError,
typeName(*this)<<"::assertNotNull(): "
"Error, the array has size zero!"
);
}
} // namespace Teuchos
// Nonmember functions
template<typename T> inline
bool Teuchos::operator==( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() == a2.vec()); }
template<typename T> inline
bool Teuchos::operator!=( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() != a2.vec()); }
template<typename T> inline
void Teuchos::swap( Array<T> &a1, Array<T> &a2 )
{ a1.swap(a2); }
template<typename T> inline
bool Teuchos::operator<( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() < a2.vec()); }
template<typename T> inline
bool Teuchos::operator<=( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() <= a2.vec()); }
template<typename T> inline
bool Teuchos::operator>( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() > a2.vec()); }
template<typename T> inline
bool Teuchos::operator>=( const Array<T> &a1, const Array<T> &a2 )
{ return (a1.vec() >= a2.vec()); }
template<typename T> inline
std::ostream& Teuchos::operator<<(
std::ostream& os, const Array<T>& array
)
{
return os << Teuchos::toString(array);
}
template<typename T> inline
int Teuchos::hashCode(const Array<T>& array)
{
int rtn = hashCode(array.length());
for (int i=0; i<array.length(); i++)
{
rtn += hashCode(array[i]);
}
if (rtn < 0)
{
/* Convert the largest -ve int to zero and -1 to
* std::numeric_limits<int>::max()
* */
size_t maxIntBeforeWrap = std::numeric_limits<int>::max();
maxIntBeforeWrap ++;
rtn += maxIntBeforeWrap;
}
return rtn;
}
template<typename T> inline
std::vector<T> Teuchos::createVector( const Array<T> &a )
{
return a.toVector();
}
template<typename T> inline
std::string Teuchos::toString(const Array<T>& array)
{
return array.toString();
}
template<typename T>
Teuchos::Array<T>
Teuchos::fromStringToArray(const std::string& arrayStr)
{
const std::string str = Utils::trimWhiteSpace(arrayStr);
std::istringstream iss(str);
TEUCHOS_TEST_FOR_EXCEPTION(
( str[0]!='{' || str[str.length()-1] != '}' )
,InvalidArrayStringRepresentation
,"Error, the std::string:\n"
"----------\n"
<<str<<
"\n----------\n"
"is not a valid array represntation!"
);
char c;
c = iss.get(); // Read initial '{'
TEUCHOS_TEST_FOR_EXCEPT(c!='{'); // Should not throw!
// Now we are ready to begin reading the entries of the array!
Array<T> a;
while( !iss.eof() ) {
// Get the basic entry std::string
std::string entryStr;
std::getline(iss,entryStr,','); // Get next entry up to ,!
// ToDo: Above, we might have to be careful to look for the opening and
// closing of parentheses in order not to pick up an internal ',' in the
// middle of an entry (for a std::complex number for instance). The above
// implementation assumes that there will be no commas in the middle of
// the std::string representation of an entry. This is certainly true for
// the types bool, int, float, and double.
//
// Trim whitespace from beginning and end
entryStr = Utils::trimWhiteSpace(entryStr);
TEUCHOS_TEST_FOR_EXCEPTION(
0 == entryStr.length(),
InvalidArrayStringRepresentation,
"Error, the std::string:\n"
"----------\n"
<<str<<
"\n----------\n"
"is not a valid array represntation because it has an empty array entry!"
);
// Remove the final '}' if this is the last entry and we did not
// actually terminate the above getline(...) on ','
bool found_end = false;
if(entryStr[entryStr.length()-1]=='}') {
entryStr = entryStr.substr(0,entryStr.length()-1);
found_end = true;
if( entryStr.length()==0 && a.size()==0 )
return a; // This is the empty array "{}" (with any spaces in it!)
}
// Finally we can convert the entry and add it to the array!
std::istringstream entryiss(entryStr);
T entry;
Teuchos::extractDataFromISS( entryiss, entry );
// ToDo: We may need to define a traits class to allow us to specialized
// how conversion from a std::string to a object is done!
a.push_back(entry);
// At the end of the loop body here, if we have reached the last '}'
// then the input stream iss should be empty and iss.eof() should be
// true, so the loop should terminate. We put an std::exception test here
// just in case something has gone wrong.
TEUCHOS_TEST_FOR_EXCEPTION(
found_end && !iss.eof()
,InvalidArrayStringRepresentation
,"Error, the std::string:\n"
"----------\n"
<<str<<
"\n----------\n"
"is not a valid array represntation!"
);
}
return a;
}
#endif // TEUCHOS_ARRAY_H
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