// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2008-2015 Gael Guennebaud // Copyright (C) 2006-2008 Benoit Jacob // // 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/. #ifndef EIGEN_META_H #define EIGEN_META_H // IWYU pragma: private #include "../InternalHeaderCheck.h" #if defined(EIGEN_GPU_COMPILE_PHASE) #include #if defined(EIGEN_CUDA_ARCH) #include #endif #if defined(EIGEN_HIP_DEVICE_COMPILE) #include "Eigen/src/Core/arch/HIP/hcc/math_constants.h" #endif #endif // Define portable (u)int{32,64} types #include namespace Eigen { namespace numext { typedef std::uint8_t uint8_t; typedef std::int8_t int8_t; typedef std::uint16_t uint16_t; typedef std::int16_t int16_t; typedef std::uint32_t uint32_t; typedef std::int32_t int32_t; typedef std::uint64_t uint64_t; typedef std::int64_t int64_t; template struct get_integer_by_size { typedef void signed_type; typedef void unsigned_type; }; template <> struct get_integer_by_size<1> { typedef int8_t signed_type; typedef uint8_t unsigned_type; }; template <> struct get_integer_by_size<2> { typedef int16_t signed_type; typedef uint16_t unsigned_type; }; template <> struct get_integer_by_size<4> { typedef int32_t signed_type; typedef uint32_t unsigned_type; }; template <> struct get_integer_by_size<8> { typedef int64_t signed_type; typedef uint64_t unsigned_type; }; } // namespace numext } // namespace Eigen namespace Eigen { typedef EIGEN_DEFAULT_DENSE_INDEX_TYPE DenseIndex; /** * \brief The Index type as used for the API. * \details To change this, \c \#define the preprocessor symbol \c EIGEN_DEFAULT_DENSE_INDEX_TYPE. * \sa \blank \ref TopicPreprocessorDirectives, StorageIndex. */ typedef EIGEN_DEFAULT_DENSE_INDEX_TYPE Index; namespace internal { /** \internal * \file Meta.h * This file contains generic metaprogramming classes which are not specifically related to Eigen. * \note In case you wonder, yes we're aware that Boost already provides all these features, * we however don't want to add a dependency to Boost. */ struct true_type { enum { value = 1 }; }; struct false_type { enum { value = 0 }; }; template struct bool_constant; template <> struct bool_constant : true_type {}; template <> struct bool_constant : false_type {}; // Third-party libraries rely on these. using std::conditional; using std::remove_const; using std::remove_pointer; using std::remove_reference; template struct remove_all { typedef T type; }; template struct remove_all { typedef typename remove_all::type type; }; template struct remove_all { typedef typename remove_all::type type; }; template struct remove_all { typedef typename remove_all::type type; }; template struct remove_all { typedef typename remove_all::type type; }; template struct remove_all { typedef typename remove_all::type type; }; template using remove_all_t = typename remove_all::type; template struct is_arithmetic { enum { value = false }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; // GPU devices treat `long double` as `double`. #ifndef EIGEN_GPU_COMPILE_PHASE template <> struct is_arithmetic { enum { value = true }; }; #endif template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; template struct is_same { enum { value = 0 }; }; template struct is_same { enum { value = 1 }; }; template struct is_void : is_same> {}; /** \internal * Implementation of std::void_t for SFINAE. * * Pre C++17: * Custom implementation. * * Post C++17: Uses std::void_t */ #if EIGEN_COMP_CXXVER >= 17 using std::void_t; #else template using void_t = void; #endif template <> struct is_arithmetic { enum { value = true }; }; template <> struct is_arithmetic { enum { value = true }; }; using std::is_integral; using std::make_unsigned; template struct is_const { enum { value = 0 }; }; template struct is_const { enum { value = 1 }; }; template struct add_const_on_value_type { typedef const T type; }; template struct add_const_on_value_type { typedef T const& type; }; template struct add_const_on_value_type { typedef T const* type; }; template struct add_const_on_value_type { typedef T const* const type; }; template struct add_const_on_value_type { typedef T const* const type; }; template using add_const_on_value_type_t = typename add_const_on_value_type::type; using std::is_convertible; /** \internal * A base class do disable default copy ctor and copy assignment operator. */ class noncopyable { EIGEN_DEVICE_FUNC noncopyable(const noncopyable&); EIGEN_DEVICE_FUNC const noncopyable& operator=(const noncopyable&); protected: EIGEN_DEVICE_FUNC noncopyable() {} EIGEN_DEVICE_FUNC ~noncopyable() {} }; /** \internal * Provides access to the number of elements in the object of as a compile-time constant expression. * It "returns" Eigen::Dynamic if the size cannot be resolved at compile-time (default). * * Similar to std::tuple_size, but more general. * * It currently supports: * - any types T defining T::SizeAtCompileTime * - plain C arrays as T[N] * - std::array (c++11) * - some internal types such as SingleRange and AllRange * * The second template parameter eases SFINAE-based specializations. */ template struct array_size { static constexpr Index value = Dynamic; }; template struct array_size> { static constexpr Index value = T::SizeAtCompileTime; }; template struct array_size { static constexpr Index value = N; }; template struct array_size { static constexpr Index value = N; }; template struct array_size> { static constexpr Index value = N; }; template struct array_size> { static constexpr Index value = N; }; /** \internal * Analogue of the std::ssize free function. * It returns the signed size of the container or view \a x of type \c T * * It currently supports: * - any types T defining a member T::size() const * - plain C arrays as T[N] * * For C++20, this function just forwards to `std::ssize`, or any ADL discoverable `ssize` function. */ #if EIGEN_COMP_CXXVER < 20 || EIGEN_GNUC_STRICT_LESS_THAN(10, 0, 0) template EIGEN_CONSTEXPR auto index_list_size(const T& x) { using R = std::common_type_t>; return static_cast(x.size()); } template EIGEN_CONSTEXPR std::ptrdiff_t index_list_size(const T (&)[N]) { return N; } #else template EIGEN_CONSTEXPR auto index_list_size(T&& x) { using std::ssize; return ssize(std::forward(x)); } #endif // EIGEN_COMP_CXXVER /** \internal * Convenient struct to get the result type of a nullary, unary, binary, or * ternary functor. * * Pre C++17: * This uses std::result_of. However, note the `type` member removes * const and converts references/pointers to their corresponding value type. * * Post C++17: Uses std::invoke_result */ #if EIGEN_HAS_STD_INVOKE_RESULT template struct result_of; template struct result_of { typedef typename std::invoke_result::type type1; typedef remove_all_t type; }; template struct invoke_result { typedef typename std::invoke_result::type type1; typedef remove_all_t type; }; #else template struct result_of { typedef typename std::result_of::type type1; typedef remove_all_t type; }; template struct invoke_result { typedef typename result_of::type type1; typedef remove_all_t type; }; #endif // Reduces a sequence of bools to true if all are true, false otherwise. template using reduce_all = std::is_same, std::integer_sequence>; // Reduces a sequence of bools to true if any are true, false if all false. template using reduce_any = std::integral_constant, std::integer_sequence>::value>; struct meta_yes { char a[1]; }; struct meta_no { char a[2]; }; // Check whether T::ReturnType does exist template struct has_ReturnType { template static meta_yes testFunctor(C const*, typename C::ReturnType const* = 0); template static meta_no testFunctor(...); enum { value = sizeof(testFunctor(static_cast(0))) == sizeof(meta_yes) }; }; template const T* return_ptr(); template struct has_nullary_operator { template static meta_yes testFunctor(C const*, std::enable_if_t<(sizeof(return_ptr()->operator()()) > 0)>* = 0); static meta_no testFunctor(...); enum { value = sizeof(testFunctor(static_cast(0))) == sizeof(meta_yes) }; }; template struct has_unary_operator { template static meta_yes testFunctor(C const*, std::enable_if_t<(sizeof(return_ptr()->operator()(IndexType(0))) > 0)>* = 0); static meta_no testFunctor(...); enum { value = sizeof(testFunctor(static_cast(0))) == sizeof(meta_yes) }; }; template struct has_binary_operator { template static meta_yes testFunctor( C const*, std::enable_if_t<(sizeof(return_ptr()->operator()(IndexType(0), IndexType(0))) > 0)>* = 0); static meta_no testFunctor(...); enum { value = sizeof(testFunctor(static_cast(0))) == sizeof(meta_yes) }; }; /** \internal In short, it computes int(sqrt(\a Y)) with \a Y an integer. * Usage example: \code meta_sqrt<1023>::ret \endcode */ template Y)))> class meta_sqrt { enum { MidX = (InfX + SupX) / 2, TakeInf = MidX * MidX > Y ? 1 : 0, NewInf = int(TakeInf) ? InfX : int(MidX), NewSup = int(TakeInf) ? int(MidX) : SupX }; public: enum { ret = meta_sqrt::ret }; }; template class meta_sqrt { public: enum { ret = (SupX * SupX <= Y) ? SupX : InfX }; }; /** \internal Computes the least common multiple of two positive integer A and B * at compile-time. */ template = B)> struct meta_least_common_multiple { enum { ret = meta_least_common_multiple::ret }; }; template struct meta_least_common_multiple { enum { ret = meta_least_common_multiple::ret }; }; template struct meta_least_common_multiple { enum { ret = A * K }; }; /** \internal determines whether the product of two numeric types is allowed and what the return type is */ template struct scalar_product_traits { enum { Defined = 0 }; }; // FIXME quick workaround around current limitation of result_of // template // struct result_of(ArgType0,ArgType1)> { // typedef typename scalar_product_traits, remove_all_t>::ReturnType type; // }; /** \internal Obtains a POD type suitable to use as storage for an object of a size * of at most Len bytes, aligned as specified by \c Align. */ template struct aligned_storage { struct type { EIGEN_ALIGN_TO_BOUNDARY(Align) unsigned char data[Len]; }; }; } // end namespace internal template struct NumTraits; namespace numext { #if defined(EIGEN_GPU_COMPILE_PHASE) template EIGEN_DEVICE_FUNC void swap(T& a, T& b) { T tmp = b; b = a; a = tmp; } #else template EIGEN_STRONG_INLINE void swap(T& a, T& b) { std::swap(a, b); } #endif using std::numeric_limits; // Handle integer comparisons of different signedness. template ::IsInteger, bool XIsSigned = NumTraits::IsSigned, bool YIsInteger = NumTraits::IsInteger, bool YIsSigned = NumTraits::IsSigned> struct equal_strict_impl { static EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool run(const X& x, const Y& y) { return x == y; } }; template struct equal_strict_impl { // X is an unsigned integer // Y is a signed integer // if Y is non-negative, it may be represented exactly as its unsigned counterpart. using UnsignedY = typename internal::make_unsigned::type; static EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool run(const X& x, const Y& y) { return y < Y(0) ? false : (x == static_cast(y)); } }; template struct equal_strict_impl { // X is a signed integer // Y is an unsigned integer static EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool run(const X& x, const Y& y) { return equal_strict_impl::run(y, x); } }; // The aim of the following functions is to bypass -Wfloat-equal warnings // when we really want a strict equality comparison on floating points. template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool equal_strict(const X& x, const Y& y) { return equal_strict_impl::run(x, y); } #if !defined(EIGEN_GPU_COMPILE_PHASE) || (!defined(EIGEN_CUDA_ARCH) && defined(EIGEN_CONSTEXPR_ARE_DEVICE_FUNC)) template <> EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool equal_strict(const float& x, const float& y) { return std::equal_to()(x, y); } template <> EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool equal_strict(const double& x, const double& y) { return std::equal_to()(x, y); } #endif /** * \internal Performs an exact comparison of x to zero, e.g. to decide whether a term can be ignored. * Use this to to bypass -Wfloat-equal warnings when exact zero is what needs to be tested. */ template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool is_exactly_zero(const X& x) { return equal_strict(x, typename NumTraits::Literal{0}); } /** * \internal Performs an exact comparison of x to one, e.g. to decide whether a factor needs to be multiplied. * Use this to to bypass -Wfloat-equal warnings when exact one is what needs to be tested. */ template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool is_exactly_one(const X& x) { return equal_strict(x, typename NumTraits::Literal{1}); } template EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool not_equal_strict(const X& x, const Y& y) { return !equal_strict_impl::run(x, y); } #if !defined(EIGEN_GPU_COMPILE_PHASE) || (!defined(EIGEN_CUDA_ARCH) && defined(EIGEN_CONSTEXPR_ARE_DEVICE_FUNC)) template <> EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool not_equal_strict(const float& x, const float& y) { return std::not_equal_to()(x, y); } template <> EIGEN_STRONG_INLINE EIGEN_DEVICE_FUNC bool not_equal_strict(const double& x, const double& y) { return std::not_equal_to()(x, y); } #endif } // end namespace numext namespace internal { template struct is_identically_zero_impl { static inline bool run(const Scalar& s) { return numext::is_exactly_zero(s); } }; template EIGEN_STRONG_INLINE bool is_identically_zero(const Scalar& s) { return is_identically_zero_impl::run(s); } /// \internal Returns true if its argument is of integer or enum type. /// FIXME this has the same purpose as `is_valid_index_type` in XprHelper.h template constexpr bool is_int_or_enum_v = std::is_enum::value || std::is_integral ::value; template inline constexpr void plain_enum_asserts(A, B) { static_assert(is_int_or_enum_v , "Argument a must be an integer or enum"); static_assert(is_int_or_enum_v, "Argument b must be an integer or enum"); } /// \internal Gets the minimum of two values which may be integers or enums template inline constexpr int plain_enum_min(A a, B b) { plain_enum_asserts(a, b); return ((int)a <= (int)b) ? (int)a : (int)b; } /// \internal Gets the maximum of two values which may be integers or enums template inline constexpr int plain_enum_max(A a, B b) { plain_enum_asserts(a, b); return ((int)a >= (int)b) ? (int)a : (int)b; } /** * \internal * `min_size_prefer_dynamic` gives the min between compile-time sizes. 0 has absolute priority, followed by 1, * followed by Dynamic, followed by other finite values. The reason for giving Dynamic the priority over * finite values is that min(3, Dynamic) should be Dynamic, since that could be anything between 0 and 3. */ template inline constexpr int min_size_prefer_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == 0 || (int)b == 0) return 0; if ((int)a == 1 || (int)b == 1) return 1; if ((int)a == Dynamic || (int)b == Dynamic) return Dynamic; return plain_enum_min(a, b); } /** * \internal * min_size_prefer_fixed is a variant of `min_size_prefer_dynamic` comparing MaxSizes. The difference is that finite * values now have priority over Dynamic, so that min(3, Dynamic) gives 3. Indeed, whatever the actual value is (between * 0 and 3), it is not more than 3. */ template inline constexpr int min_size_prefer_fixed(A a, B b) { plain_enum_asserts(a, b); if ((int)a == 0 || (int)b == 0) return 0; if ((int)a == 1 || (int)b == 1) return 1; if ((int)a == Dynamic && (int)b == Dynamic) return Dynamic; if ((int)a == Dynamic) return (int)b; if ((int)b == Dynamic) return (int)a; return plain_enum_min(a, b); } /// \internal see `min_size_prefer_fixed`. No need for a separate variant for MaxSizes here. template inline constexpr int max_size_prefer_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return Dynamic; return plain_enum_max(a, b); } template inline constexpr bool enum_eq_not_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return false; return (int)a == (int)b; } template inline constexpr bool enum_lt_not_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return false; return (int)a < (int)b; } template inline constexpr bool enum_le_not_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return false; return (int)a <= (int)b; } template inline constexpr bool enum_gt_not_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return false; return (int)a > (int)b; } template inline constexpr bool enum_ge_not_dynamic(A a, B b) { plain_enum_asserts(a, b); if ((int)a == Dynamic || (int)b == Dynamic) return false; return (int)a >= (int)b; } /// \internal Calculate logical XOR at compile time inline constexpr bool logical_xor(bool a, bool b) { return a != b; } /// \internal Calculate logical IMPLIES at compile time inline constexpr bool check_implication(bool a, bool b) { return !a || b; } /// \internal Provide fallback for std::is_constant_evaluated for pre-C++20. #if EIGEN_COMP_CXXVER >= 20 using std::is_constant_evaluated; #else constexpr bool is_constant_evaluated() { return false; } #endif } // end namespace internal } // end namespace Eigen #endif // EIGEN_META_H