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indexed_view.cpp
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rDLMA Diffusion limited mixed aggregation
indexed_view.cpp
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// This file is part of Eigen, a lightweight C++ template library
// for linear algebra.
//
// Copyright (C) 2017 Gael Guennebaud <gael.guennebaud@inria.fr>
//
// 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/.
#ifdef EIGEN_TEST_PART_2
// Make sure we also check c++11 max implementation
#define EIGEN_MAX_CPP_VER 11
#endif
#ifdef EIGEN_TEST_PART_3
// Make sure we also check c++98 max implementation
#define EIGEN_MAX_CPP_VER 03
// We need to disable this warning when compiling with c++11 while limiting Eigen to c++98
// Ideally we would rather configure the compiler to build in c++98 mode but this needs
// to be done at the CMakeLists.txt level.
#if defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8))
#pragma GCC diagnostic ignored "-Wdeprecated"
#endif
#if defined(__GNUC__) && (__GNUC__ >=9)
#pragma GCC diagnostic ignored "-Wdeprecated-copy"
#endif
#if defined(__clang__) && (__clang_major__ >= 10)
#pragma clang diagnostic ignored "-Wdeprecated-copy"
#endif
#endif
#include <valarray>
#include <vector>
#include "main.h"
#if EIGEN_HAS_CXX11
#include <array>
#endif
typedef
std
::
pair
<
Index
,
Index
>
IndexPair
;
int
encode
(
Index
i
,
Index
j
)
{
return
int
(
i
*
100
+
j
);
}
IndexPair
decode
(
Index
ij
)
{
return
IndexPair
(
ij
/
100
,
ij
%
100
);
}
template
<
typename
T
>
bool
match
(
const
T
&
xpr
,
std
::
string
ref
,
std
::
string
str_xpr
=
""
)
{
EIGEN_UNUSED_VARIABLE
(
str_xpr
);
std
::
stringstream
str
;
str
<<
xpr
;
if
(
!
(
str
.
str
()
==
ref
))
std
::
cout
<<
str_xpr
<<
"
\n
"
<<
xpr
<<
"
\n\n
"
;
return
str
.
str
()
==
ref
;
}
#define MATCH(X,R) match(X, R, #X)
template
<
typename
T1
,
typename
T2
>
typename
internal
::
enable_if
<
internal
::
is_same
<
T1
,
T2
>::
value
,
bool
>::
type
is_same_eq
(
const
T1
&
a
,
const
T2
&
b
)
{
return
(
a
==
b
).
all
();
}
template
<
typename
T1
,
typename
T2
>
bool
is_same_seq
(
const
T1
&
a
,
const
T2
&
b
)
{
bool
ok
=
a
.
first
()
==
b
.
first
()
&&
a
.
size
()
==
b
.
size
()
&&
Index
(
a
.
incrObject
())
==
Index
(
b
.
incrObject
());;
if
(
!
ok
)
{
std
::
cerr
<<
"seqN("
<<
a
.
first
()
<<
", "
<<
a
.
size
()
<<
", "
<<
Index
(
a
.
incrObject
())
<<
") != "
;
std
::
cerr
<<
"seqN("
<<
b
.
first
()
<<
", "
<<
b
.
size
()
<<
", "
<<
Index
(
b
.
incrObject
())
<<
")
\n
"
;
}
return
ok
;
}
template
<
typename
T1
,
typename
T2
>
typename
internal
::
enable_if
<
internal
::
is_same
<
T1
,
T2
>::
value
,
bool
>::
type
is_same_seq_type
(
const
T1
&
a
,
const
T2
&
b
)
{
return
is_same_seq
(
a
,
b
);
}
#define VERIFY_EQ_INT(A,B) VERIFY_IS_APPROX(int(A),int(B))
// C++03 does not allow local or unnamed enums as index
enum
DummyEnum
{
XX
=
0
,
YY
=
1
};
void
check_indexed_view
()
{
Index
n
=
10
;
ArrayXd
a
=
ArrayXd
::
LinSpaced
(
n
,
0
,
n
-
1
);
Array
<
double
,
1
,
Dynamic
>
b
=
a
.
transpose
();
#if EIGEN_COMP_CXXVER>=14
ArrayXXi
A
=
ArrayXXi
::
NullaryExpr
(
n
,
n
,
std
::
ref
(
encode
));
#else
ArrayXXi
A
=
ArrayXXi
::
NullaryExpr
(
n
,
n
,
std
::
ptr_fun
(
&
encode
));
#endif
for
(
Index
i
=
0
;
i
<
n
;
++
i
)
for
(
Index
j
=
0
;
j
<
n
;
++
j
)
VERIFY
(
decode
(
A
(
i
,
j
))
==
IndexPair
(
i
,
j
)
);
Array4i
eii
(
4
);
eii
<<
3
,
1
,
6
,
5
;
std
::
valarray
<
int
>
vali
(
4
);
Map
<
ArrayXi
>
(
&
vali
[
0
],
4
)
=
eii
;
std
::
vector
<
int
>
veci
(
4
);
Map
<
ArrayXi
>
(
veci
.
data
(),
4
)
=
eii
;
VERIFY
(
MATCH
(
A
(
3
,
seq
(
9
,
3
,
-
1
)),
"309 308 307 306 305 304 303"
)
);
VERIFY
(
MATCH
(
A
(
seqN
(
2
,
5
),
seq
(
9
,
3
,
-
1
)),
"209 208 207 206 205 204 203
\n
"
"309 308 307 306 305 304 303
\n
"
"409 408 407 406 405 404 403
\n
"
"509 508 507 506 505 504 503
\n
"
"609 608 607 606 605 604 603"
)
);
VERIFY
(
MATCH
(
A
(
seqN
(
2
,
5
),
5
),
"205
\n
"
"305
\n
"
"405
\n
"
"505
\n
"
"605"
)
);
VERIFY
(
MATCH
(
A
(
seqN
(
last
,
5
,
-
1
),
seq
(
2
,
last
)),
"902 903 904 905 906 907 908 909
\n
"
"802 803 804 805 806 807 808 809
\n
"
"702 703 704 705 706 707 708 709
\n
"
"602 603 604 605 606 607 608 609
\n
"
"502 503 504 505 506 507 508 509"
)
);
VERIFY
(
MATCH
(
A
(
eii
,
veci
),
"303 301 306 305
\n
"
"103 101 106 105
\n
"
"603 601 606 605
\n
"
"503 501 506 505"
)
);
VERIFY
(
MATCH
(
A
(
eii
,
all
),
"300 301 302 303 304 305 306 307 308 309
\n
"
"100 101 102 103 104 105 106 107 108 109
\n
"
"600 601 602 603 604 605 606 607 608 609
\n
"
"500 501 502 503 504 505 506 507 508 509"
)
);
// take row number 3, and repeat it 5 times
VERIFY
(
MATCH
(
A
(
seqN
(
3
,
5
,
0
),
all
),
"300 301 302 303 304 305 306 307 308 309
\n
"
"300 301 302 303 304 305 306 307 308 309
\n
"
"300 301 302 303 304 305 306 307 308 309
\n
"
"300 301 302 303 304 305 306 307 308 309
\n
"
"300 301 302 303 304 305 306 307 308 309"
)
);
VERIFY
(
MATCH
(
a
(
seqN
(
3
,
3
),
0
),
"3
\n
4
\n
5"
)
);
VERIFY
(
MATCH
(
a
(
seq
(
3
,
5
)),
"3
\n
4
\n
5"
)
);
VERIFY
(
MATCH
(
a
(
seqN
(
3
,
3
,
1
)),
"3
\n
4
\n
5"
)
);
VERIFY
(
MATCH
(
a
(
seqN
(
5
,
3
,
-
1
)),
"5
\n
4
\n
3"
)
);
VERIFY
(
MATCH
(
b
(
0
,
seqN
(
3
,
3
)),
"3 4 5"
)
);
VERIFY
(
MATCH
(
b
(
seq
(
3
,
5
)),
"3 4 5"
)
);
VERIFY
(
MATCH
(
b
(
seqN
(
3
,
3
,
1
)),
"3 4 5"
)
);
VERIFY
(
MATCH
(
b
(
seqN
(
5
,
3
,
-
1
)),
"5 4 3"
)
);
VERIFY
(
MATCH
(
b
(
all
),
"0 1 2 3 4 5 6 7 8 9"
)
);
VERIFY
(
MATCH
(
b
(
eii
),
"3 1 6 5"
)
);
Array44i
B
;
B
.
setRandom
();
VERIFY
(
(
A
(
seqN
(
2
,
5
),
5
)).
ColsAtCompileTime
==
1
);
VERIFY
(
(
A
(
seqN
(
2
,
5
),
5
)).
RowsAtCompileTime
==
Dynamic
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
),
5
)).
InnerStrideAtCompileTime
,
A
.
InnerStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
),
5
)).
OuterStrideAtCompileTime
,
A
.
col
(
5
).
OuterStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
5
,
seqN
(
2
,
5
))).
InnerStrideAtCompileTime
,
A
.
row
(
5
).
InnerStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
5
,
seqN
(
2
,
5
))).
OuterStrideAtCompileTime
,
A
.
row
(
5
).
OuterStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
B
(
1
,
seqN
(
1
,
2
))).
InnerStrideAtCompileTime
,
B
.
row
(
1
).
InnerStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
B
(
1
,
seqN
(
1
,
2
))).
OuterStrideAtCompileTime
,
B
.
row
(
1
).
OuterStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
),
seq
(
1
,
3
))).
InnerStrideAtCompileTime
,
A
.
InnerStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
),
seq
(
1
,
3
))).
OuterStrideAtCompileTime
,
A
.
OuterStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
B
(
seqN
(
1
,
2
),
seq
(
1
,
3
))).
InnerStrideAtCompileTime
,
B
.
InnerStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
B
(
seqN
(
1
,
2
),
seq
(
1
,
3
))).
OuterStrideAtCompileTime
,
B
.
OuterStrideAtCompileTime
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
,
2
),
seq
(
1
,
3
,
2
))).
InnerStrideAtCompileTime
,
Dynamic
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
,
2
),
seq
(
1
,
3
,
2
))).
OuterStrideAtCompileTime
,
Dynamic
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
,
fix
<
2
>
),
seq
(
1
,
3
,
fix
<
3
>
))).
InnerStrideAtCompileTime
,
2
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
5
,
fix
<
2
>
),
seq
(
1
,
3
,
fix
<
3
>
))).
OuterStrideAtCompileTime
,
Dynamic
);
VERIFY_EQ_INT
(
(
B
(
seqN
(
1
,
2
,
fix
<
2
>
),
seq
(
1
,
3
,
fix
<
3
>
))).
InnerStrideAtCompileTime
,
2
);
VERIFY_EQ_INT
(
(
B
(
seqN
(
1
,
2
,
fix
<
2
>
),
seq
(
1
,
3
,
fix
<
3
>
))).
OuterStrideAtCompileTime
,
3
*
4
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
5
>
),
seqN
(
1
,
fix
<
3
>
))).
RowsAtCompileTime
,
5
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
5
>
),
seqN
(
1
,
fix
<
3
>
))).
ColsAtCompileTime
,
3
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
5
>
(
5
)),
seqN
(
1
,
fix
<
3
>
(
3
)))).
RowsAtCompileTime
,
5
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
5
>
(
5
)),
seqN
(
1
,
fix
<
3
>
(
3
)))).
ColsAtCompileTime
,
3
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
Dynamic
>
(
5
)),
seqN
(
1
,
fix
<
Dynamic
>
(
3
)))).
RowsAtCompileTime
,
Dynamic
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
Dynamic
>
(
5
)),
seqN
(
1
,
fix
<
Dynamic
>
(
3
)))).
ColsAtCompileTime
,
Dynamic
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
Dynamic
>
(
5
)),
seqN
(
1
,
fix
<
Dynamic
>
(
3
)))).
rows
(),
5
);
VERIFY_EQ_INT
(
(
A
(
seqN
(
2
,
fix
<
Dynamic
>
(
5
)),
seqN
(
1
,
fix
<
Dynamic
>
(
3
)))).
cols
(),
3
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
5
,
fix
<-
1
>
),
seqN
(
2
,
5
,
fix
<-
1
>
(
-
1
))
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
5
),
seqN
(
2
,
5
,
fix
<
1
>
(
1
))
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
5
,
3
),
seqN
(
2
,
5
,
fix
<
DynamicIndex
>
(
3
))
)
);
VERIFY
(
is_same_seq_type
(
seq
(
2
,
7
,
fix
<
3
>
),
seqN
(
2
,
2
,
fix
<
3
>
)
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
fix
<
Dynamic
>
(
5
),
3
),
seqN
(
2
,
5
,
fix
<
DynamicIndex
>
(
3
))
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
fix
<
5
>
(
5
),
fix
<-
2
>
),
seqN
(
2
,
fix
<
5
>
,
fix
<-
2
>
())
)
);
VERIFY
(
is_same_seq_type
(
seq
(
2
,
fix
<
5
>
),
seqN
(
2
,
4
)
)
);
#if EIGEN_HAS_CXX11
VERIFY
(
is_same_seq_type
(
seq
(
fix
<
2
>
,
fix
<
5
>
),
seqN
(
fix
<
2
>
,
fix
<
4
>
)
)
);
VERIFY
(
is_same_seq
(
seqN
(
2
,
std
::
integral_constant
<
int
,
5
>
(),
std
::
integral_constant
<
int
,
-
2
>
()),
seqN
(
2
,
fix
<
5
>
,
fix
<-
2
>
())
)
);
VERIFY
(
is_same_seq
(
seq
(
std
::
integral_constant
<
int
,
1
>
(),
std
::
integral_constant
<
int
,
5
>
(),
std
::
integral_constant
<
int
,
2
>
()),
seq
(
fix
<
1
>
,
fix
<
5
>
,
fix
<
2
>
())
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
std
::
integral_constant
<
int
,
5
>
(),
std
::
integral_constant
<
int
,
-
2
>
()),
seqN
(
2
,
fix
<
5
>
,
fix
<-
2
>
())
)
);
VERIFY
(
is_same_seq_type
(
seq
(
std
::
integral_constant
<
int
,
1
>
(),
std
::
integral_constant
<
int
,
5
>
(),
std
::
integral_constant
<
int
,
2
>
()),
seq
(
fix
<
1
>
,
fix
<
5
>
,
fix
<
2
>
())
)
);
VERIFY
(
is_same_seq_type
(
seqN
(
2
,
std
::
integral_constant
<
int
,
5
>
()),
seqN
(
2
,
fix
<
5
>
)
)
);
VERIFY
(
is_same_seq_type
(
seq
(
std
::
integral_constant
<
int
,
1
>
(),
std
::
integral_constant
<
int
,
5
>
()),
seq
(
fix
<
1
>
,
fix
<
5
>
)
)
);
#else
// sorry, no compile-time size recovery in c++98/03
VERIFY
(
is_same_seq
(
seq
(
fix
<
2
>
,
fix
<
5
>
),
seqN
(
fix
<
2
>
,
fix
<
4
>
)
)
);
#endif
VERIFY
(
(
A
(
seqN
(
2
,
fix
<
5
>
),
5
)).
RowsAtCompileTime
==
5
);
VERIFY
(
(
A
(
4
,
all
)).
ColsAtCompileTime
==
Dynamic
);
VERIFY
(
(
A
(
4
,
all
)).
RowsAtCompileTime
==
1
);
VERIFY
(
(
B
(
1
,
all
)).
ColsAtCompileTime
==
4
);
VERIFY
(
(
B
(
1
,
all
)).
RowsAtCompileTime
==
1
);
VERIFY
(
(
B
(
all
,
1
)).
ColsAtCompileTime
==
1
);
VERIFY
(
(
B
(
all
,
1
)).
RowsAtCompileTime
==
4
);
VERIFY
(
int
(
(
A
(
all
,
eii
)).
ColsAtCompileTime
)
==
int
(
eii
.
SizeAtCompileTime
));
VERIFY_EQ_INT
(
(
A
(
eii
,
eii
)).
Flags
&
DirectAccessBit
,
(
unsigned
int
)(
0
));
VERIFY_EQ_INT
(
(
A
(
eii
,
eii
)).
InnerStrideAtCompileTime
,
0
);
VERIFY_EQ_INT
(
(
A
(
eii
,
eii
)).
OuterStrideAtCompileTime
,
0
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
,
2
,
-
2
),
seqN
(
n
-
1
-
6
,
3
,
-
1
)),
A
(
seq
(
last
,
2
,
fix
<-
2
>
),
seqN
(
last
-
6
,
3
,
fix
<-
1
>
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
,
2
,
-
2
),
seqN
(
n
-
1
-
6
,
4
)),
A
(
seq
(
last
,
2
,
-
2
),
seqN
(
last
-
6
,
4
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
-
6
,
n
-
1
-
2
),
seqN
(
n
-
1
-
6
,
4
)),
A
(
seq
(
last
-
6
,
last
-
2
),
seqN
(
6
+
last
-
6
-
6
,
4
))
);
VERIFY_IS_APPROX
(
A
(
seq
((
n
-
1
)
/
2
,(
n
)
/
2
+
3
),
seqN
(
2
,
4
)),
A
(
seq
(
last
/
2
,(
last
+
1
)
/
2
+
3
),
seqN
(
last
+
2
-
last
,
4
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
2
,
2
,
-
2
),
seqN
(
n
-
8
,
4
)),
A
(
seq
(
lastp1
-
2
,
2
,
-
2
),
seqN
(
lastp1
-
8
,
4
))
);
// Check all combinations of seq:
VERIFY_IS_APPROX
(
A
(
seq
(
1
,
n
-
1
-
2
,
2
),
seq
(
1
,
n
-
1
-
2
,
2
)),
A
(
seq
(
1
,
last
-
2
,
2
),
seq
(
1
,
last
-
2
,
fix
<
2
>
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
-
5
,
n
-
1
-
2
,
2
),
seq
(
n
-
1
-
5
,
n
-
1
-
2
,
2
)),
A
(
seq
(
last
-
5
,
last
-
2
,
2
),
seq
(
last
-
5
,
last
-
2
,
fix
<
2
>
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
-
5
,
7
,
2
),
seq
(
n
-
1
-
5
,
7
,
2
)),
A
(
seq
(
last
-
5
,
7
,
2
),
seq
(
last
-
5
,
7
,
fix
<
2
>
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
1
,
n
-
1
-
2
),
seq
(
n
-
1
-
5
,
7
)),
A
(
seq
(
1
,
last
-
2
),
seq
(
last
-
5
,
7
))
);
VERIFY_IS_APPROX
(
A
(
seq
(
n
-
1
-
5
,
n
-
1
-
2
),
seq
(
n
-
1
-
5
,
n
-
1
-
2
)),
A
(
seq
(
last
-
5
,
last
-
2
),
seq
(
last
-
5
,
last
-
2
))
);
VERIFY_IS_APPROX
(
A
.
col
(
A
.
cols
()
-
1
),
A
(
all
,
last
)
);
VERIFY_IS_APPROX
(
A
(
A
.
rows
()
-
2
,
A
.
cols
()
/
2
),
A
(
last
-
1
,
lastp1
/
2
)
);
VERIFY_IS_APPROX
(
a
(
a
.
size
()
-
2
),
a
(
last
-
1
)
);
VERIFY_IS_APPROX
(
a
(
a
.
size
()
/
2
),
a
((
last
+
1
)
/
2
)
);
// Check fall-back to Block
{
VERIFY
(
is_same_eq
(
A
.
col
(
0
),
A
(
all
,
0
))
);
VERIFY
(
is_same_eq
(
A
.
row
(
0
),
A
(
0
,
all
))
);
VERIFY
(
is_same_eq
(
A
.
block
(
0
,
0
,
2
,
2
),
A
(
seqN
(
0
,
2
),
seq
(
0
,
1
)))
);
VERIFY
(
is_same_eq
(
A
.
middleRows
(
2
,
4
),
A
(
seqN
(
2
,
4
),
all
))
);
VERIFY
(
is_same_eq
(
A
.
middleCols
(
2
,
4
),
A
(
all
,
seqN
(
2
,
4
)))
);
VERIFY
(
is_same_eq
(
A
.
col
(
A
.
cols
()
-
1
),
A
(
all
,
last
))
);
const
ArrayXXi
&
cA
(
A
);
VERIFY
(
is_same_eq
(
cA
.
col
(
0
),
cA
(
all
,
0
))
);
VERIFY
(
is_same_eq
(
cA
.
row
(
0
),
cA
(
0
,
all
))
);
VERIFY
(
is_same_eq
(
cA
.
block
(
0
,
0
,
2
,
2
),
cA
(
seqN
(
0
,
2
),
seq
(
0
,
1
)))
);
VERIFY
(
is_same_eq
(
cA
.
middleRows
(
2
,
4
),
cA
(
seqN
(
2
,
4
),
all
))
);
VERIFY
(
is_same_eq
(
cA
.
middleCols
(
2
,
4
),
cA
(
all
,
seqN
(
2
,
4
)))
);
VERIFY
(
is_same_eq
(
a
.
head
(
4
),
a
(
seq
(
0
,
3
)))
);
VERIFY
(
is_same_eq
(
a
.
tail
(
4
),
a
(
seqN
(
last
-
3
,
4
)))
);
VERIFY
(
is_same_eq
(
a
.
tail
(
4
),
a
(
seq
(
lastp1
-
4
,
last
)))
);
VERIFY
(
is_same_eq
(
a
.
segment
<
4
>
(
3
),
a
(
seqN
(
3
,
fix
<
4
>
)))
);
}
ArrayXXi
A1
=
A
,
A2
=
ArrayXXi
::
Random
(
4
,
4
);
ArrayXi
range25
(
4
);
range25
<<
3
,
2
,
4
,
5
;
A1
(
seqN
(
3
,
4
),
seq
(
2
,
5
))
=
A2
;
VERIFY_IS_APPROX
(
A1
.
block
(
3
,
2
,
4
,
4
),
A2
);
A1
=
A
;
A2
.
setOnes
();
A1
(
seq
(
6
,
3
,
-
1
),
range25
)
=
A2
;
VERIFY_IS_APPROX
(
A1
.
block
(
3
,
2
,
4
,
4
),
A2
);
// check reverse
{
VERIFY
(
is_same_seq_type
(
seq
(
3
,
7
).
reverse
(),
seqN
(
7
,
5
,
fix
<-
1
>
)
)
);
VERIFY
(
is_same_seq_type
(
seq
(
7
,
3
,
fix
<-
2
>
).
reverse
(),
seqN
(
3
,
3
,
fix
<
2
>
)
)
);
VERIFY_IS_APPROX
(
a
(
seqN
(
2
,
last
/
2
).
reverse
()),
a
(
seqN
(
2
+
(
last
/
2
-
1
)
*
1
,
last
/
2
,
fix
<-
1
>
))
);
VERIFY_IS_APPROX
(
a
(
seqN
(
last
/
2
,
fix
<
4
>
).
reverse
()),
a
(
seqN
(
last
/
2
,
fix
<
4
>
)).
reverse
()
);
VERIFY_IS_APPROX
(
A
(
seq
(
last
-
5
,
last
-
1
,
2
).
reverse
(),
seqN
(
last
-
3
,
3
,
fix
<-
2
>
).
reverse
()),
A
(
seq
(
last
-
5
,
last
-
1
,
2
),
seqN
(
last
-
3
,
3
,
fix
<-
2
>
)).
reverse
()
);
}
#if EIGEN_HAS_CXX11
// check lastN
VERIFY_IS_APPROX
(
a
(
lastN
(
3
)),
a
.
tail
(
3
)
);
VERIFY
(
MATCH
(
a
(
lastN
(
3
)),
"7
\n
8
\n
9"
)
);
VERIFY_IS_APPROX
(
a
(
lastN
(
fix
<
3
>
())),
a
.
tail
<
3
>
()
);
VERIFY
(
MATCH
(
a
(
lastN
(
3
,
2
)),
"5
\n
7
\n
9"
)
);
VERIFY
(
MATCH
(
a
(
lastN
(
3
,
fix
<
2
>
())),
"5
\n
7
\n
9"
)
);
VERIFY
(
a
(
lastN
(
fix
<
3
>
())).
SizeAtCompileTime
==
3
);
VERIFY
(
(
A
(
all
,
std
::
array
<
int
,
4
>
{{
1
,
3
,
2
,
4
}})).
ColsAtCompileTime
==
4
);
VERIFY_IS_APPROX
(
(
A
(
std
::
array
<
int
,
3
>
{{
1
,
3
,
5
}},
std
::
array
<
int
,
4
>
{{
9
,
6
,
3
,
0
}})),
A
(
seqN
(
1
,
3
,
2
),
seqN
(
9
,
4
,
-
3
))
);
#if EIGEN_HAS_STATIC_ARRAY_TEMPLATE
VERIFY_IS_APPROX
(
A
({
3
,
1
,
6
,
5
},
all
),
A
(
std
::
array
<
int
,
4
>
{{
3
,
1
,
6
,
5
}},
all
)
);
VERIFY_IS_APPROX
(
A
(
all
,{
3
,
1
,
6
,
5
}),
A
(
all
,
std
::
array
<
int
,
4
>
{{
3
,
1
,
6
,
5
}})
);
VERIFY_IS_APPROX
(
A
({
1
,
3
,
5
},{
3
,
1
,
6
,
5
}),
A
(
std
::
array
<
int
,
3
>
{{
1
,
3
,
5
}},
std
::
array
<
int
,
4
>
{{
3
,
1
,
6
,
5
}})
);
VERIFY_IS_EQUAL
(
A
({
1
,
3
,
5
},{
3
,
1
,
6
,
5
}).
RowsAtCompileTime
,
3
);
VERIFY_IS_EQUAL
(
A
({
1
,
3
,
5
},{
3
,
1
,
6
,
5
}).
ColsAtCompileTime
,
4
);
VERIFY_IS_APPROX
(
a
({
3
,
1
,
6
,
5
}),
a
(
std
::
array
<
int
,
4
>
{{
3
,
1
,
6
,
5
}})
);
VERIFY_IS_EQUAL
(
a
({
1
,
3
,
5
}).
SizeAtCompileTime
,
3
);
VERIFY_IS_APPROX
(
b
({
3
,
1
,
6
,
5
}),
b
(
std
::
array
<
int
,
4
>
{{
3
,
1
,
6
,
5
}})
);
VERIFY_IS_EQUAL
(
b
({
1
,
3
,
5
}).
SizeAtCompileTime
,
3
);
#endif
#endif
// check mat(i,j) with weird types for i and j
{
VERIFY_IS_APPROX
(
A
(
B
.
RowsAtCompileTime
-
1
,
1
),
A
(
3
,
1
)
);
VERIFY_IS_APPROX
(
A
(
B
.
RowsAtCompileTime
,
1
),
A
(
4
,
1
)
);
VERIFY_IS_APPROX
(
A
(
B
.
RowsAtCompileTime
-
1
,
B
.
ColsAtCompileTime
-
1
),
A
(
3
,
3
)
);
VERIFY_IS_APPROX
(
A
(
B
.
RowsAtCompileTime
,
B
.
ColsAtCompileTime
),
A
(
4
,
4
)
);
const
Index
I_
=
3
,
J_
=
4
;
VERIFY_IS_APPROX
(
A
(
I_
,
J_
),
A
(
3
,
4
)
);
}
// check extended block API
{
VERIFY
(
is_same_eq
(
A
.
block
<
3
,
4
>
(
1
,
1
),
A
.
block
(
1
,
1
,
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
block
<
3
,
4
>
(
1
,
1
,
3
,
4
),
A
.
block
(
1
,
1
,
fix
<
3
>
(),
fix
<
4
>
(
4
)))
);
VERIFY
(
is_same_eq
(
A
.
block
<
3
,
Dynamic
>
(
1
,
1
,
3
,
4
),
A
.
block
(
1
,
1
,
fix
<
3
>
,
4
))
);
VERIFY
(
is_same_eq
(
A
.
block
<
Dynamic
,
4
>
(
1
,
1
,
3
,
4
),
A
.
block
(
1
,
1
,
fix
<
Dynamic
>
(
3
),
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
block
(
1
,
1
,
3
,
4
),
A
.
block
(
1
,
1
,
fix
<
Dynamic
>
(
3
),
fix
<
Dynamic
>
(
4
)))
);
VERIFY
(
is_same_eq
(
A
.
topLeftCorner
<
3
,
4
>
(),
A
.
topLeftCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
bottomLeftCorner
<
3
,
4
>
(),
A
.
bottomLeftCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
bottomRightCorner
<
3
,
4
>
(),
A
.
bottomRightCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
topRightCorner
<
3
,
4
>
(),
A
.
topRightCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
A
.
leftCols
<
3
>
(),
A
.
leftCols
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
A
.
rightCols
<
3
>
(),
A
.
rightCols
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
A
.
middleCols
<
3
>
(
1
),
A
.
middleCols
(
1
,
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
A
.
topRows
<
3
>
(),
A
.
topRows
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
A
.
bottomRows
<
3
>
(),
A
.
bottomRows
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
A
.
middleRows
<
3
>
(
1
),
A
.
middleRows
(
1
,
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
a
.
segment
<
3
>
(
1
),
a
.
segment
(
1
,
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
a
.
head
<
3
>
(),
a
.
head
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
a
.
tail
<
3
>
(),
a
.
tail
(
fix
<
3
>
))
);
const
ArrayXXi
&
cA
(
A
);
VERIFY
(
is_same_eq
(
cA
.
block
<
Dynamic
,
4
>
(
1
,
1
,
3
,
4
),
cA
.
block
(
1
,
1
,
fix
<
Dynamic
>
(
3
),
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
cA
.
topLeftCorner
<
3
,
4
>
(),
cA
.
topLeftCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
cA
.
bottomLeftCorner
<
3
,
4
>
(),
cA
.
bottomLeftCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
cA
.
bottomRightCorner
<
3
,
4
>
(),
cA
.
bottomRightCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
cA
.
topRightCorner
<
3
,
4
>
(),
cA
.
topRightCorner
(
fix
<
3
>
,
fix
<
4
>
))
);
VERIFY
(
is_same_eq
(
cA
.
leftCols
<
3
>
(),
cA
.
leftCols
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
cA
.
rightCols
<
3
>
(),
cA
.
rightCols
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
cA
.
middleCols
<
3
>
(
1
),
cA
.
middleCols
(
1
,
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
cA
.
topRows
<
3
>
(),
cA
.
topRows
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
cA
.
bottomRows
<
3
>
(),
cA
.
bottomRows
(
fix
<
3
>
))
);
VERIFY
(
is_same_eq
(
cA
.
middleRows
<
3
>
(
1
),
cA
.
middleRows
(
1
,
fix
<
3
>
))
);
}
// Check compilation of enums as index type:
a
(
XX
)
=
1
;
A
(
XX
,
YY
)
=
1
;
// Anonymous enums only work with C++11
#if EIGEN_HAS_CXX11
enum
{
X
=
0
,
Y
=
1
};
a
(
X
)
=
1
;
A
(
X
,
Y
)
=
1
;
A
(
XX
,
Y
)
=
1
;
A
(
X
,
YY
)
=
1
;
#endif
// Check compilation of varying integer types as index types:
Index
i
=
n
/
2
;
short
i_short
(
i
);
std
::
size_t
i_sizet
(
i
);
VERIFY_IS_EQUAL
(
a
(
i
),
a
.
coeff
(
i_short
)
);
VERIFY_IS_EQUAL
(
a
(
i
),
a
.
coeff
(
i_sizet
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i_short
,
i_short
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i_short
,
i
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i
,
i_short
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i
,
i_sizet
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i_sizet
,
i
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
i_sizet
,
i_short
)
);
VERIFY_IS_EQUAL
(
A
(
i
,
i
),
A
.
coeff
(
5
,
i_sizet
)
);
// Regression test for Max{Rows,Cols}AtCompileTime
{
Matrix3i
A3
=
Matrix3i
::
Random
();
ArrayXi
ind
(
5
);
ind
<<
1
,
1
,
1
,
1
,
1
;
VERIFY_IS_EQUAL
(
A3
(
ind
,
ind
).
eval
(),
MatrixXi
::
Constant
(
5
,
5
,
A3
(
1
,
1
))
);
}
// Regression for bug 1736
{
VERIFY_IS_APPROX
(
A
(
all
,
eii
).
col
(
0
).
eval
(),
A
.
col
(
eii
(
0
)));
A
(
all
,
eii
).
col
(
0
)
=
A
.
col
(
eii
(
0
));
}
// bug 1815: IndexedView should allow linear access
{
VERIFY
(
MATCH
(
b
(
eii
)(
0
),
"3"
)
);
VERIFY
(
MATCH
(
a
(
eii
)(
0
),
"3"
)
);
VERIFY
(
MATCH
(
A
(
1
,
eii
)(
0
),
"103"
));
VERIFY
(
MATCH
(
A
(
eii
,
1
)(
0
),
"301"
));
VERIFY
(
MATCH
(
A
(
1
,
all
)(
1
),
"101"
));
VERIFY
(
MATCH
(
A
(
all
,
1
)(
1
),
"101"
));
}
#if EIGEN_HAS_CXX11
//Bug IndexView with a single static row should be RowMajor:
{
// A(1, seq(0,2,1)).cwiseAbs().colwise().replicate(2).eval();
STATIC_CHECK
((
(
internal
::
evaluator
<
decltype
(
A
(
1
,
seq
(
0
,
2
,
1
))
)
>::
Flags
&
RowMajorBit
)
==
RowMajorBit
));
}
#endif
}
EIGEN_DECLARE_TEST
(
indexed_view
)
{
// for(int i = 0; i < g_repeat; i++) {
CALL_SUBTEST_1
(
check_indexed_view
()
);
CALL_SUBTEST_2
(
check_indexed_view
()
);
CALL_SUBTEST_3
(
check_indexed_view
()
);
// }
// static checks of some internals:
STATIC_CHECK
((
internal
::
is_valid_index_type
<
int
>::
value
));
STATIC_CHECK
((
internal
::
is_valid_index_type
<
unsigned
int
>::
value
));
STATIC_CHECK
((
internal
::
is_valid_index_type
<
short
>::
value
));
STATIC_CHECK
((
internal
::
is_valid_index_type
<
std
::
ptrdiff_t
>::
value
));
STATIC_CHECK
((
internal
::
is_valid_index_type
<
std
::
size_t
>::
value
));
STATIC_CHECK
((
!
internal
::
valid_indexed_view_overload
<
int
,
int
>::
value
));
STATIC_CHECK
((
!
internal
::
valid_indexed_view_overload
<
int
,
std
::
ptrdiff_t
>::
value
));
STATIC_CHECK
((
!
internal
::
valid_indexed_view_overload
<
std
::
ptrdiff_t
,
int
>::
value
));
STATIC_CHECK
((
!
internal
::
valid_indexed_view_overload
<
std
::
size_t
,
int
>::
value
));
}
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