Eigen  3.3.0
 
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Meta.h
1// This file is part of Eigen, a lightweight C++ template library
2// for linear algebra.
3//
4// Copyright (C) 2008-2015 Gael Guennebaud <gael.guennebaud@inria.fr>
5// Copyright (C) 2006-2008 Benoit Jacob <jacob.benoit.1@gmail.com>
6//
7// This Source Code Form is subject to the terms of the Mozilla
8// Public License v. 2.0. If a copy of the MPL was not distributed
9// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
10
11#ifndef EIGEN_META_H
12#define EIGEN_META_H
13
14#if defined(__CUDA_ARCH__)
15#include <cfloat>
16#include <math_constants.h>
17#endif
18
19#if EIGEN_COMP_ICC>=1600 && __cplusplus >= 201103L
20#include <cstdint>
21#endif
22
23namespace Eigen {
24
25typedef EIGEN_DEFAULT_DENSE_INDEX_TYPE DenseIndex;
26
33typedef EIGEN_DEFAULT_DENSE_INDEX_TYPE Index;
34
35namespace internal {
36
44// Only recent versions of ICC complain about using ptrdiff_t to hold pointers,
45// and older versions do not provide *intptr_t types.
46#if EIGEN_COMP_ICC>=1600 && __cplusplus >= 201103L
47typedef std::intptr_t IntPtr;
48typedef std::uintptr_t UIntPtr;
49#else
50typedef std::ptrdiff_t IntPtr;
51typedef std::size_t UIntPtr;
52#endif
53
54struct true_type { enum { value = 1 }; };
55struct false_type { enum { value = 0 }; };
56
57template<bool Condition, typename Then, typename Else>
58struct conditional { typedef Then type; };
59
60template<typename Then, typename Else>
61struct conditional <false, Then, Else> { typedef Else type; };
62
63template<typename T, typename U> struct is_same { enum { value = 0 }; };
64template<typename T> struct is_same<T,T> { enum { value = 1 }; };
65
66template<typename T> struct remove_reference { typedef T type; };
67template<typename T> struct remove_reference<T&> { typedef T type; };
68
69template<typename T> struct remove_pointer { typedef T type; };
70template<typename T> struct remove_pointer<T*> { typedef T type; };
71template<typename T> struct remove_pointer<T*const> { typedef T type; };
72
73template <class T> struct remove_const { typedef T type; };
74template <class T> struct remove_const<const T> { typedef T type; };
75template <class T> struct remove_const<const T[]> { typedef T type[]; };
76template <class T, unsigned int Size> struct remove_const<const T[Size]> { typedef T type[Size]; };
77
78template<typename T> struct remove_all { typedef T type; };
79template<typename T> struct remove_all<const T> { typedef typename remove_all<T>::type type; };
80template<typename T> struct remove_all<T const&> { typedef typename remove_all<T>::type type; };
81template<typename T> struct remove_all<T&> { typedef typename remove_all<T>::type type; };
82template<typename T> struct remove_all<T const*> { typedef typename remove_all<T>::type type; };
83template<typename T> struct remove_all<T*> { typedef typename remove_all<T>::type type; };
84
85template<typename T> struct is_arithmetic { enum { value = false }; };
86template<> struct is_arithmetic<float> { enum { value = true }; };
87template<> struct is_arithmetic<double> { enum { value = true }; };
88template<> struct is_arithmetic<long double> { enum { value = true }; };
89template<> struct is_arithmetic<bool> { enum { value = true }; };
90template<> struct is_arithmetic<char> { enum { value = true }; };
91template<> struct is_arithmetic<signed char> { enum { value = true }; };
92template<> struct is_arithmetic<unsigned char> { enum { value = true }; };
93template<> struct is_arithmetic<signed short> { enum { value = true }; };
94template<> struct is_arithmetic<unsigned short>{ enum { value = true }; };
95template<> struct is_arithmetic<signed int> { enum { value = true }; };
96template<> struct is_arithmetic<unsigned int> { enum { value = true }; };
97template<> struct is_arithmetic<signed long> { enum { value = true }; };
98template<> struct is_arithmetic<unsigned long> { enum { value = true }; };
99
100template<typename T> struct is_integral { enum { value = false }; };
101template<> struct is_integral<bool> { enum { value = true }; };
102template<> struct is_integral<char> { enum { value = true }; };
103template<> struct is_integral<signed char> { enum { value = true }; };
104template<> struct is_integral<unsigned char> { enum { value = true }; };
105template<> struct is_integral<signed short> { enum { value = true }; };
106template<> struct is_integral<unsigned short> { enum { value = true }; };
107template<> struct is_integral<signed int> { enum { value = true }; };
108template<> struct is_integral<unsigned int> { enum { value = true }; };
109template<> struct is_integral<signed long> { enum { value = true }; };
110template<> struct is_integral<unsigned long> { enum { value = true }; };
111
112template <typename T> struct add_const { typedef const T type; };
113template <typename T> struct add_const<T&> { typedef T& type; };
114
115template <typename T> struct is_const { enum { value = 0 }; };
116template <typename T> struct is_const<T const> { enum { value = 1 }; };
117
118template<typename T> struct add_const_on_value_type { typedef const T type; };
119template<typename T> struct add_const_on_value_type<T&> { typedef T const& type; };
120template<typename T> struct add_const_on_value_type<T*> { typedef T const* type; };
121template<typename T> struct add_const_on_value_type<T* const> { typedef T const* const type; };
122template<typename T> struct add_const_on_value_type<T const* const> { typedef T const* const type; };
123
124
125template<typename From, typename To>
126struct is_convertible_impl
127{
128private:
129 struct any_conversion
130 {
131 template <typename T> any_conversion(const volatile T&);
132 template <typename T> any_conversion(T&);
133 };
134 struct yes {int a[1];};
135 struct no {int a[2];};
136
137 static yes test(const To&, int);
138 static no test(any_conversion, ...);
139
140public:
141 static From ms_from;
142#ifdef __INTEL_COMPILER
143 #pragma warning push
144 #pragma warning ( disable : 2259 )
145#endif
146 enum { value = sizeof(test(ms_from, 0))==sizeof(yes) };
147#ifdef __INTEL_COMPILER
148 #pragma warning pop
149#endif
150};
151
152template<typename From, typename To>
153struct is_convertible
154{
155 enum { value = is_convertible_impl<typename remove_all<From>::type,
156 typename remove_all<To >::type>::value };
157};
158
162template<bool Condition, typename T=void> struct enable_if;
163
164template<typename T> struct enable_if<true,T>
165{ typedef T type; };
166
167#if defined(__CUDA_ARCH__)
168#if !defined(__FLT_EPSILON__)
169#define __FLT_EPSILON__ FLT_EPSILON
170#define __DBL_EPSILON__ DBL_EPSILON
171#endif
172
173namespace device {
174
175template<typename T> struct numeric_limits
176{
177 EIGEN_DEVICE_FUNC
178 static T epsilon() { return 0; }
179 static T (max)() { assert(false && "Highest not supported for this type"); }
180 static T (min)() { assert(false && "Lowest not supported for this type"); }
181 static T infinity() { assert(false && "Infinity not supported for this type"); }
182 static T quiet_NaN() { assert(false && "quiet_NaN not supported for this type"); }
183};
184template<> struct numeric_limits<float>
185{
186 EIGEN_DEVICE_FUNC
187 static float epsilon() { return __FLT_EPSILON__; }
188 EIGEN_DEVICE_FUNC
189 static float (max)() { return CUDART_MAX_NORMAL_F; }
190 EIGEN_DEVICE_FUNC
191 static float (min)() { return FLT_MIN; }
192 EIGEN_DEVICE_FUNC
193 static float infinity() { return CUDART_INF_F; }
194 EIGEN_DEVICE_FUNC
195 static float quiet_NaN() { return CUDART_NAN_F; }
196};
197template<> struct numeric_limits<double>
198{
199 EIGEN_DEVICE_FUNC
200 static double epsilon() { return __DBL_EPSILON__; }
201 EIGEN_DEVICE_FUNC
202 static double (max)() { return DBL_MAX; }
203 EIGEN_DEVICE_FUNC
204 static double (min)() { return DBL_MIN; }
205 EIGEN_DEVICE_FUNC
206 static double infinity() { return CUDART_INF; }
207 EIGEN_DEVICE_FUNC
208 static double quiet_NaN() { return CUDART_NAN; }
209};
210template<> struct numeric_limits<int>
211{
212 EIGEN_DEVICE_FUNC
213 static int epsilon() { return 0; }
214 EIGEN_DEVICE_FUNC
215 static int (max)() { return INT_MAX; }
216 EIGEN_DEVICE_FUNC
217 static int (min)() { return INT_MIN; }
218};
219template<> struct numeric_limits<unsigned int>
220{
221 EIGEN_DEVICE_FUNC
222 static unsigned int epsilon() { return 0; }
223 EIGEN_DEVICE_FUNC
224 static unsigned int (max)() { return UINT_MAX; }
225 EIGEN_DEVICE_FUNC
226 static unsigned int (min)() { return 0; }
227};
228template<> struct numeric_limits<long>
229{
230 EIGEN_DEVICE_FUNC
231 static long epsilon() { return 0; }
232 EIGEN_DEVICE_FUNC
233 static long (max)() { return LONG_MAX; }
234 EIGEN_DEVICE_FUNC
235 static long (min)() { return LONG_MIN; }
236};
237template<> struct numeric_limits<unsigned long>
238{
239 EIGEN_DEVICE_FUNC
240 static unsigned long epsilon() { return 0; }
241 EIGEN_DEVICE_FUNC
242 static unsigned long (max)() { return ULONG_MAX; }
243 EIGEN_DEVICE_FUNC
244 static unsigned long (min)() { return 0; }
245};
246template<> struct numeric_limits<long long>
247{
248 EIGEN_DEVICE_FUNC
249 static long long epsilon() { return 0; }
250 EIGEN_DEVICE_FUNC
251 static long long (max)() { return LLONG_MAX; }
252 EIGEN_DEVICE_FUNC
253 static long long (min)() { return LLONG_MIN; }
254};
255template<> struct numeric_limits<unsigned long long>
256{
257 EIGEN_DEVICE_FUNC
258 static unsigned long long epsilon() { return 0; }
259 EIGEN_DEVICE_FUNC
260 static unsigned long long (max)() { return ULLONG_MAX; }
261 EIGEN_DEVICE_FUNC
262 static unsigned long long (min)() { return 0; }
263};
264
265}
266
267#endif
268
272class noncopyable
273{
274 EIGEN_DEVICE_FUNC noncopyable(const noncopyable&);
275 EIGEN_DEVICE_FUNC const noncopyable& operator=(const noncopyable&);
276protected:
277 EIGEN_DEVICE_FUNC noncopyable() {}
278 EIGEN_DEVICE_FUNC ~noncopyable() {}
279};
280
288#if EIGEN_HAS_STD_RESULT_OF
289template<typename T> struct result_of {
290 typedef typename std::result_of<T>::type type1;
291 typedef typename remove_all<type1>::type type;
292};
293#else
294template<typename T> struct result_of { };
295
296struct has_none {int a[1];};
297struct has_std_result_type {int a[2];};
298struct has_tr1_result {int a[3];};
299
300template<typename Func, typename ArgType, int SizeOf=sizeof(has_none)>
301struct unary_result_of_select {typedef typename internal::remove_all<ArgType>::type type;};
302
303template<typename Func, typename ArgType>
304struct unary_result_of_select<Func, ArgType, sizeof(has_std_result_type)> {typedef typename Func::result_type type;};
305
306template<typename Func, typename ArgType>
307struct unary_result_of_select<Func, ArgType, sizeof(has_tr1_result)> {typedef typename Func::template result<Func(ArgType)>::type type;};
308
309template<typename Func, typename ArgType>
310struct result_of<Func(ArgType)> {
311 template<typename T>
312 static has_std_result_type testFunctor(T const *, typename T::result_type const * = 0);
313 template<typename T>
314 static has_tr1_result testFunctor(T const *, typename T::template result<T(ArgType)>::type const * = 0);
315 static has_none testFunctor(...);
316
317 // note that the following indirection is needed for gcc-3.3
318 enum {FunctorType = sizeof(testFunctor(static_cast<Func*>(0)))};
319 typedef typename unary_result_of_select<Func, ArgType, FunctorType>::type type;
320};
321
322template<typename Func, typename ArgType0, typename ArgType1, int SizeOf=sizeof(has_none)>
323struct binary_result_of_select {typedef typename internal::remove_all<ArgType0>::type type;};
324
325template<typename Func, typename ArgType0, typename ArgType1>
326struct binary_result_of_select<Func, ArgType0, ArgType1, sizeof(has_std_result_type)>
327{typedef typename Func::result_type type;};
328
329template<typename Func, typename ArgType0, typename ArgType1>
330struct binary_result_of_select<Func, ArgType0, ArgType1, sizeof(has_tr1_result)>
331{typedef typename Func::template result<Func(ArgType0,ArgType1)>::type type;};
332
333template<typename Func, typename ArgType0, typename ArgType1>
334struct result_of<Func(ArgType0,ArgType1)> {
335 template<typename T>
336 static has_std_result_type testFunctor(T const *, typename T::result_type const * = 0);
337 template<typename T>
338 static has_tr1_result testFunctor(T const *, typename T::template result<T(ArgType0,ArgType1)>::type const * = 0);
339 static has_none testFunctor(...);
340
341 // note that the following indirection is needed for gcc-3.3
342 enum {FunctorType = sizeof(testFunctor(static_cast<Func*>(0)))};
343 typedef typename binary_result_of_select<Func, ArgType0, ArgType1, FunctorType>::type type;
344};
345
346template<typename Func, typename ArgType0, typename ArgType1, typename ArgType2, int SizeOf=sizeof(has_none)>
347struct ternary_result_of_select {typedef typename internal::remove_all<ArgType0>::type type;};
348
349template<typename Func, typename ArgType0, typename ArgType1, typename ArgType2>
350struct ternary_result_of_select<Func, ArgType0, ArgType1, ArgType2, sizeof(has_std_result_type)>
351{typedef typename Func::result_type type;};
352
353template<typename Func, typename ArgType0, typename ArgType1, typename ArgType2>
354struct ternary_result_of_select<Func, ArgType0, ArgType1, ArgType2, sizeof(has_tr1_result)>
355{typedef typename Func::template result<Func(ArgType0,ArgType1,ArgType2)>::type type;};
356
357template<typename Func, typename ArgType0, typename ArgType1, typename ArgType2>
358struct result_of<Func(ArgType0,ArgType1,ArgType2)> {
359 template<typename T>
360 static has_std_result_type testFunctor(T const *, typename T::result_type const * = 0);
361 template<typename T>
362 static has_tr1_result testFunctor(T const *, typename T::template result<T(ArgType0,ArgType1,ArgType2)>::type const * = 0);
363 static has_none testFunctor(...);
364
365 // note that the following indirection is needed for gcc-3.3
366 enum {FunctorType = sizeof(testFunctor(static_cast<Func*>(0)))};
367 typedef typename ternary_result_of_select<Func, ArgType0, ArgType1, ArgType2, FunctorType>::type type;
368};
369#endif
370
371struct meta_yes { char a[1]; };
372struct meta_no { char a[2]; };
373
374// Check whether T::ReturnType does exist
375template <typename T>
376struct has_ReturnType
377{
378 template <typename C> static meta_yes testFunctor(typename C::ReturnType const *);
379 template <typename C> static meta_no testFunctor(...);
380
381 enum { value = sizeof(testFunctor<T>(0)) == sizeof(meta_yes) };
382};
383
384template<typename T> const T& return_ref();
385
386template <typename T, typename IndexType=Index>
387struct has_nullary_operator
388{
389 template <typename C> static meta_yes testFunctor(C const *,typename enable_if<(sizeof(return_ref<C>().operator()())>0)>::type * = 0);
390 static meta_no testFunctor(...);
391
392 enum { value = sizeof(testFunctor(static_cast<T*>(0))) == sizeof(meta_yes) };
393};
394
395template <typename T, typename IndexType=Index>
396struct has_unary_operator
397{
398 template <typename C> static meta_yes testFunctor(C const *,typename enable_if<(sizeof(return_ref<C>().operator()(IndexType(0)))>0)>::type * = 0);
399 static meta_no testFunctor(...);
400
401 enum { value = sizeof(testFunctor(static_cast<T*>(0))) == sizeof(meta_yes) };
402};
403
404template <typename T, typename IndexType=Index>
405struct has_binary_operator
406{
407 template <typename C> static meta_yes testFunctor(C const *,typename enable_if<(sizeof(return_ref<C>().operator()(IndexType(0),IndexType(0)))>0)>::type * = 0);
408 static meta_no testFunctor(...);
409
410 enum { value = sizeof(testFunctor(static_cast<T*>(0))) == sizeof(meta_yes) };
411};
412
416template<int Y,
417 int InfX = 0,
418 int SupX = ((Y==1) ? 1 : Y/2),
419 bool Done = ((SupX-InfX)<=1 ? true : ((SupX*SupX <= Y) && ((SupX+1)*(SupX+1) > Y))) >
420 // use ?: instead of || just to shut up a stupid gcc 4.3 warning
421class meta_sqrt
422{
423 enum {
424 MidX = (InfX+SupX)/2,
425 TakeInf = MidX*MidX > Y ? 1 : 0,
426 NewInf = int(TakeInf) ? InfX : int(MidX),
427 NewSup = int(TakeInf) ? int(MidX) : SupX
428 };
429 public:
430 enum { ret = meta_sqrt<Y,NewInf,NewSup>::ret };
431};
432
433template<int Y, int InfX, int SupX>
434class meta_sqrt<Y, InfX, SupX, true> { public: enum { ret = (SupX*SupX <= Y) ? SupX : InfX }; };
435
436
441template<int A, int B, int K=1, bool Done = ((A*K)%B)==0>
442struct meta_least_common_multiple
443{
444 enum { ret = meta_least_common_multiple<A,B,K+1>::ret };
445};
446template<int A, int B, int K>
447struct meta_least_common_multiple<A,B,K,true>
448{
449 enum { ret = A*K };
450};
451
453template<typename T, typename U> struct scalar_product_traits
454{
455 enum { Defined = 0 };
456};
457
458// FIXME quick workaround around current limitation of result_of
459// template<typename Scalar, typename ArgType0, typename ArgType1>
460// struct result_of<scalar_product_op<Scalar>(ArgType0,ArgType1)> {
461// typedef typename scalar_product_traits<typename remove_all<ArgType0>::type, typename remove_all<ArgType1>::type>::ReturnType type;
462// };
463
464} // end namespace internal
465
466namespace numext {
467
468#if defined(__CUDA_ARCH__)
469template<typename T> EIGEN_DEVICE_FUNC void swap(T &a, T &b) { T tmp = b; b = a; a = tmp; }
470#else
471template<typename T> EIGEN_STRONG_INLINE void swap(T &a, T &b) { std::swap(a,b); }
472#endif
473
474#if defined(__CUDA_ARCH__)
475using internal::device::numeric_limits;
476#else
477using std::numeric_limits;
478#endif
479
480// Integer division with rounding up.
481// T is assumed to be an integer type with a>=0, and b>0
482template<typename T>
483T div_ceil(const T &a, const T &b)
484{
485 return (a+b-1) / b;
486}
487
488} // end namespace numext
489
490} // end namespace Eigen
491
492#endif // EIGEN_META_H
Namespace containing all symbols from the Eigen library.
Definition: Core:287
EIGEN_DEFAULT_DENSE_INDEX_TYPE Index
The Index type as used for the API.
Definition: Meta.h:33