src/math/tnt_array2d.hpp

/*
*
* Template Numerical Toolkit (TNT)
*
* Mathematical and Computational Sciences Division
* National Institute of Technology,
* Gaithersburg, MD USA
*
*
* This software was developed at the National Institute of Standards and
* Technology (NIST) by employees of the Federal Government in the course
* of their official duties. Pursuant to title 17 Section 105 of the
* United States Code, this software is not subject to copyright protection
* and is in the public domain. NIST assumes no responsibility whatsoever for
* its use by other parties, and makes no guarantees, expressed or implied,
* about its quality, reliability, or any other characteristic.
*
*/


#ifndef TNT_ARRAY2D_H
#define TNT_ARRAY2D_H

#include <cstdlib>
#include <iostream>
#ifdef TNT_BOUNDS_CHECK
#include <assert.h>
#endif

#include "tnt_array1d.hpp"

namespace TNT
{

template <class T>
class Array2D 
{


  private:


        Array1D<T> data_;
        Array1D<T*> v_;
        int m_;
    int n_;

  public:

    typedef         T   value_type;
               Array2D();
               Array2D(int m, int n);
               Array2D(int m, int n,  T *a);
               Array2D(int m, int n, const T &a);
    inline Array2D(const Array2D &A);
        inline operator T**();
        inline operator const T**();
        inline Array2D & operator=(const T &a);
        inline Array2D & operator=(const Array2D &A);
        inline Array2D & ref(const Array2D &A);
               Array2D copy() const;
                   Array2D & inject(const Array2D & A);
        inline T* operator[](int i);
        inline const T* operator[](int i) const;
        inline int dim1() const;
        inline int dim2() const;
     ~Array2D();

        /* extended interface (not part of the standard) */


        inline int ref_count();
        inline int ref_count_data();
        inline int ref_count_dim1();
        Array2D subarray(int i0, int i1, int j0, int j1);

};


template <class T>
Array2D<T>::Array2D() : data_(), v_(), m_(0), n_(0) {} 

template <class T>
Array2D<T>::Array2D(const Array2D<T> &A) : data_(A.data_), v_(A.v_), 
        m_(A.m_), n_(A.n_) {}


template <class T>
Array2D<T>::Array2D(int m, int n) : data_(m*n), v_(m), m_(m), n_(n)
{
        if (m>0 && n>0)
        {
                T* p = &(data_[0]);
                for (int i=0; i<m; i++)
                {
                        v_[i] = p;
                        p += n;
                }
        }
}


template <class T>
Array2D<T>::Array2D(int m, int n, const T &val) : data_(m*n), v_(m), 
                                                                                                        m_(m), n_(n) 
{
  if (m>0 && n>0)
  {
        data_ = val;
        T* p  = &(data_[0]);
        for (int i=0; i<m; i++)
        {
                        v_[i] = p;
                        p += n;
        }
  }
}

template <class T>
Array2D<T>::Array2D(int m, int n, T *a) : data_(m*n, a), v_(m), m_(m), n_(n)
{
  if (m>0 && n>0)
  {
        T* p = &(data_[0]);
        
        for (int i=0; i<m; i++)
        {
                        v_[i] = p;
                        p += n;
        }
  }
}


template <class T>
inline T* Array2D<T>::operator[](int i) 
{ 
#ifdef TNT_BOUNDS_CHECK
        assert(i >= 0);
        assert(i < m_);
#endif

return v_[i]; 

}


template <class T>
inline const T* Array2D<T>::operator[](int i) const
{ 
#ifdef TNT_BOUNDS_CHECK
        assert(i >= 0);
        assert(i < m_);
#endif

return v_[i]; 

}

template <class T>
Array2D<T> & Array2D<T>::operator=(const T &a)
{
        /* non-optimzied, but will work with subarrays in future verions */

        for (int i=0; i<m_; i++)
                for (int j=0; j<n_; j++)
                v_[i][j] = a;
        return *this;
}


template <class T>
Array2D<T> Array2D<T>::copy() const
{
        Array2D A(m_, n_);

        for (int i=0; i<m_; i++)
                for (int j=0; j<n_; j++)
                        A[i][j] = v_[i][j];


        return A;
}


template <class T>
Array2D<T> & Array2D<T>::inject(const Array2D &A)
{
        if (A.m_ == m_ &&  A.n_ == n_)
        {
                for (int i=0; i<m_; i++)
                        for (int j=0; j<n_; j++)
                                v_[i][j] = A[i][j];
        }
        return *this;
}


template <class T>
Array2D<T> & Array2D<T>::ref(const Array2D<T> &A)
{
        if (this != &A)
        {
                v_ = A.v_;
                data_ = A.data_;
                m_ = A.m_;
                n_ = A.n_;
                
        }
        return *this;
}


template <class T>
Array2D<T> & Array2D<T>::operator=(const Array2D<T> &A)
{
        return ref(A);
}

template <class T>
inline int Array2D<T>::dim1() const { return m_; }

template <class T>
inline int Array2D<T>::dim2() const { return n_; }


template <class T>
Array2D<T>::~Array2D() {}


template <class T>
inline Array2D<T>::operator T**()
{
        return &(v_[0]);
}
template <class T>
inline Array2D<T>::operator const T**()
{
        return &(v_[0]);
}

/* ............... extended interface ............... */
/**
        Create a new view to a subarray defined by the boundaries
        [i0][i0] and [i1][j1].  The size of the subarray is
        (i1-i0) by (j1-j0).  If either of these lengths are zero
        or negative, the subarray view is null.

*/
template <class T>
Array2D<T> Array2D<T>::subarray(int i0, int i1, int j0, int j1) 
{
        Array2D<T> A;
        int m = i1-i0+1;
        int n = j1-j0+1;

        /* if either length is zero or negative, this is an invalide
                subarray. return a null view.
        */
        if (m<1 || n<1)
                return A;

        A.data_ = data_;
        A.m_ = m;
        A.n_ = n;
        A.v_ = Array1D<T*>(m);
        T* p = &(data_[0]) + i0 *  n_ + j0;
        for (int i=0; i<m; i++)
        {
                A.v_[i] = p + i*n_;

        }       
        return A;
}

template <class T>
inline int Array2D<T>::ref_count()
{
        return ref_count_data();
}


template <class T>
inline int Array2D<T>::ref_count_data()
{
        return data_.ref_count();
}

template <class T>
inline int Array2D<T>::ref_count_dim1()
{
        return v_.ref_count();
}


} /* namespace TNT */

#endif
/* TNT_ARRAY2D_H */

Revision:	3495
Committed:	Tue Apr 7 20:16:26 2009 UTC (16 years ago) by gezelter
File size:	5175 byte(s)
Log Message:	adding jama and tnt libraries for various linear algebra routines
#	Content
1	/*
2	*
3	* Template Numerical Toolkit (TNT)
4	*
5	* Mathematical and Computational Sciences Division
6	* National Institute of Technology,
7	* Gaithersburg, MD USA
8	*
9	*
10	* This software was developed at the National Institute of Standards and
11	* Technology (NIST) by employees of the Federal Government in the course
12	* of their official duties. Pursuant to title 17 Section 105 of the
13	* United States Code, this software is not subject to copyright protection
14	* and is in the public domain. NIST assumes no responsibility whatsoever for
15	* its use by other parties, and makes no guarantees, expressed or implied,
16	* about its quality, reliability, or any other characteristic.
17	*
18	*/
19
20
21
22	#ifndef TNT_ARRAY2D_H
23	#define TNT_ARRAY2D_H
24
25	#include <cstdlib>
26	#include <iostream>
27	#ifdef TNT_BOUNDS_CHECK
28	#include <assert.h>
29	#endif
30
31	#include "tnt_array1d.hpp"
32
33	namespace TNT
34	{
35
36	template <class T>
37	class Array2D
38	{
39
40
41	private:
42
43
44
45	Array1D<T> data_;
46	Array1D<T*> v_;
47	int m_;
48	int n_;
49
50	public:
51
52	typedef T value_type;
53	Array2D();
54	Array2D(int m, int n);
55	Array2D(int m, int n, T *a);
56	Array2D(int m, int n, const T &a);
57	inline Array2D(const Array2D &A);
58	inline operator T**();
59	inline operator const T**();
60	inline Array2D & operator=(const T &a);
61	inline Array2D & operator=(const Array2D &A);
62	inline Array2D & ref(const Array2D &A);
63	Array2D copy() const;
64	Array2D & inject(const Array2D & A);
65	inline T* operator[](int i);
66	inline const T* operator[](int i) const;
67	inline int dim1() const;
68	inline int dim2() const;
69	~Array2D();
70
71	/* extended interface (not part of the standard) */
72
73
74	inline int ref_count();
75	inline int ref_count_data();
76	inline int ref_count_dim1();
77	Array2D subarray(int i0, int i1, int j0, int j1);
78
79	};
80
81
82	template <class T>
83	Array2D<T>::Array2D() : data_(), v_(), m_(0), n_(0) {}
84
85	template <class T>
86	Array2D<T>::Array2D(const Array2D<T> &A) : data_(A.data_), v_(A.v_),
87	m_(A.m_), n_(A.n_) {}
88
89
90
91
92	template <class T>
93	Array2D<T>::Array2D(int m, int n) : data_(m*n), v_(m), m_(m), n_(n)
94	{
95	if (m>0 && n>0)
96	{
97	T* p = &(data_[0]);
98	for (int i=0; i<m; i++)
99	{
100	v_[i] = p;
101	p += n;
102	}
103	}
104	}
105
106
107
108	template <class T>
109	Array2D<T>::Array2D(int m, int n, const T &val) : data_(m*n), v_(m),
110	m_(m), n_(n)
111	{
112	if (m>0 && n>0)
113	{
114	data_ = val;
115	T* p = &(data_[0]);
116	for (int i=0; i<m; i++)
117	{
118	v_[i] = p;
119	p += n;
120	}
121	}
122	}
123
124	template <class T>
125	Array2D<T>::Array2D(int m, int n, T a) : data_(mn, a), v_(m), m_(m), n_(n)
126	{
127	if (m>0 && n>0)
128	{
129	T* p = &(data_[0]);
130
131	for (int i=0; i<m; i++)
132	{
133	v_[i] = p;
134	p += n;
135	}
136	}
137	}
138
139
140	template <class T>
141	inline T* Array2D<T>::operator[](int i)
142	{
143	#ifdef TNT_BOUNDS_CHECK
144	assert(i >= 0);
145	assert(i < m_);
146	#endif
147
148	return v_[i];
149
150	}
151
152
153	template <class T>
154	inline const T* Array2D<T>::operator[](int i) const
155	{
156	#ifdef TNT_BOUNDS_CHECK
157	assert(i >= 0);
158	assert(i < m_);
159	#endif
160
161	return v_[i];
162
163	}
164
165	template <class T>
166	Array2D<T> & Array2D<T>::operator=(const T &a)
167	{
168	/* non-optimzied, but will work with subarrays in future verions */
169
170	for (int i=0; i<m_; i++)
171	for (int j=0; j<n_; j++)
172	v_[i][j] = a;
173	return *this;
174	}
175
176
177
178
179	template <class T>
180	Array2D<T> Array2D<T>::copy() const
181	{
182	Array2D A(m_, n_);
183
184	for (int i=0; i<m_; i++)
185	for (int j=0; j<n_; j++)
186	A[i][j] = v_[i][j];
187
188
189	return A;
190	}
191
192
193	template <class T>
194	Array2D<T> & Array2D<T>::inject(const Array2D &A)
195	{
196	if (A.m_ == m_ && A.n_ == n_)
197	{
198	for (int i=0; i<m_; i++)
199	for (int j=0; j<n_; j++)
200	v_[i][j] = A[i][j];
201	}
202	return *this;
203	}
204
205
206
207
208	template <class T>
209	Array2D<T> & Array2D<T>::ref(const Array2D<T> &A)
210	{
211	if (this != &A)
212	{
213	v_ = A.v_;
214	data_ = A.data_;
215	m_ = A.m_;
216	n_ = A.n_;
217
218	}
219	return *this;
220	}
221
222
223
224	template <class T>
225	Array2D<T> & Array2D<T>::operator=(const Array2D<T> &A)
226	{
227	return ref(A);
228	}
229
230	template <class T>
231	inline int Array2D<T>::dim1() const { return m_; }
232
233	template <class T>
234	inline int Array2D<T>::dim2() const { return n_; }
235
236
237	template <class T>
238	Array2D<T>::~Array2D() {}
239
240
241
242
243	template <class T>
244	inline Array2D<T>::operator T**()
245	{
246	return &(v_[0]);
247	}
248	template <class T>
249	inline Array2D<T>::operator const T**()
250	{
251	return &(v_[0]);
252	}
253
254	/* ............... extended interface ............... */
255	/**
256	Create a new view to a subarray defined by the boundaries
257	[i0][i0] and [i1][j1]. The size of the subarray is
258	(i1-i0) by (j1-j0). If either of these lengths are zero
259	or negative, the subarray view is null.
260
261	*/
262	template <class T>
263	Array2D<T> Array2D<T>::subarray(int i0, int i1, int j0, int j1)
264	{
265	Array2D<T> A;
266	int m = i1-i0+1;
267	int n = j1-j0+1;
268
269	/* if either length is zero or negative, this is an invalide
270	subarray. return a null view.
271	*/
272	if (m<1 \|\| n<1)
273	return A;
274
275	A.data_ = data_;
276	A.m_ = m;
277	A.n_ = n;
278	A.v_ = Array1D<T*>(m);
279	T* p = &(data_[0]) + i0 * n_ + j0;
280	for (int i=0; i<m; i++)
281	{
282	A.v_[i] = p + i*n_;
283
284	}
285	return A;
286	}
287
288	template <class T>
289	inline int Array2D<T>::ref_count()
290	{
291	return ref_count_data();
292	}
293
294
295
296	template <class T>
297	inline int Array2D<T>::ref_count_data()
298	{
299	return data_.ref_count();
300	}
301
302	template <class T>
303	inline int Array2D<T>::ref_count_dim1()
304	{
305	return v_.ref_count();
306	}
307
308
309
310
311	} /* namespace TNT */
312
313	#endif
314	/* TNT_ARRAY2D_H */
315