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DEV: meta reshape

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Christos Houtouridis 5 år sedan
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984a073f29
21 ändrade filer med 1055 tillägg och 708 borttagningar
  1. +12
    -11
      include/utl/com/_1wire.h
  2. +7
    -6
      include/utl/com/i2c.h
  3. +12
    -12
      include/utl/com/spi_bb.h
  4. +25
    -0
      include/utl/concepts/stl.h
  5. +15
    -12
      include/utl/dev/dev_iterators.h
  6. +92
    -19
      include/utl/meta/detection.h
  7. +0
    -113
      include/utl/meta/idx_sequence.h
  8. +59
    -50
      include/utl/meta/integral.h
  9. +140
    -70
      include/utl/meta/invoke.h
  10. +0
    -118
      include/utl/meta/logical.h
  11. +3
    -4
      include/utl/meta/meta.h
  12. +105
    -10
      include/utl/meta/operations.h
  13. +3
    -9
      include/utl/meta/selection.h
  14. +15
    -29
      include/utl/meta/sfinae.h
  15. +67
    -64
      include/utl/meta/typelist.h
  16. +11
    -19
      include/utl/meta/useif.h
  17. +1
    -2
      include/utl/utility/invoke.h
  18. +218
    -0
      test/tests/TmetaBasic.cpp
  19. +162
    -0
      test/tests/TmetaDetection.cpp
  20. +107
    -159
      test/tests/TmetaTypelist.cpp
  21. +1
    -1
      test/tests/test_i2c_impl.cpp

+ 12
- 11
include/utl/com/_1wire.h Visa fil

@@ -689,17 +689,18 @@ namespace _1wire_i_det {
meta::void_t <
// typename _Tp::Speed,
// typename _Tp::Command,
meta::use_if_same_t <try_reset_t <_Tp>, bool>,
meta::use_if_same_t <try_rx1_t <_Tp>, byte_t>,
//meta::use_if_same_t <try_rx2_t <_Tp>, size_t>,
meta::use_if_same_t <try_tx1_t <_Tp>, byte_t>,
//meta::use_if_same_t <try_tx2_t <_Tp>, size_t>,
meta::use_if_same_t <try_match_t<_Tp>, void>,
meta::use_if_same_t <try_match_n_ovdr_t<_Tp>, void>,
meta::use_if_same_t <try_skip_t<_Tp>, void>,
meta::use_if_same_t <try_skip_n_ovdr_t<_Tp>, void>,
meta::use_if_same_t <try_first_t <_Tp>, _1wire_id_t>,
meta::use_if_same_t <try_next_t <_Tp>, _1wire_id_t>
// meta::use_if_same_t <try_reset_t <_Tp>, bool>,
// meta::use_if_same_t <try_rx1_t <_Tp>, byte_t>,
// //meta::use_if_same_t <try_rx2_t <_Tp>, size_t>,
// meta::use_if_same_t <try_tx1_t <_Tp>, byte_t>,
// //meta::use_if_same_t <try_tx2_t <_Tp>, size_t>,
// meta::use_if_same_t <try_match_t<_Tp>, void>,
// meta::use_if_same_t <try_match_n_ovdr_t<_Tp>, void>,
// meta::use_if_same_t <try_skip_t<_Tp>, void>,
// meta::use_if_same_t <try_skip_n_ovdr_t<_Tp>, void>,
// meta::use_if_same_t <try_first_t <_Tp>, _1wire_id_t>,
// meta::use_if_same_t <try_next_t <_Tp>, _1wire_id_t>
void
> //!^ SFINAE may apply
> : meta::true_ {};
} // namespace _1wire_i_det


+ 7
- 6
include/utl/com/i2c.h Visa fil

@@ -261,12 +261,13 @@ namespace utl {
struct is_i2c_ <_Tp,
meta::void_t <
typename _Tp::Sequence,
meta::use_if_same_t <uint32_t,try_cclk_t <_Tp>>,
meta::use_if_same_t <void, try_clk_t <_Tp>>,
meta::use_if_same_t <void, try_start_t <_Tp>>,
meta::use_if_same_t <void, try_stop_t <_Tp>>,
meta::use_if_same_t <byte_t, try_rx_data_t <_Tp>>,
meta::use_if_same_t <bool, try_tx_data_t <_Tp>>
// meta::use_if_same_t <uint32_t,try_cclk_t <_Tp>>,
// meta::use_if_same_t <void, try_clk_t <_Tp>>,
// meta::use_if_same_t <void, try_start_t <_Tp>>,
// meta::use_if_same_t <void, try_stop_t <_Tp>>,
// meta::use_if_same_t <byte_t, try_rx_data_t <_Tp>>,
// meta::use_if_same_t <bool, try_tx_data_t <_Tp>>
void
>
> : meta::true_ { };
}


+ 12
- 12
include/utl/com/spi_bb.h Visa fil

@@ -75,9 +75,9 @@ namespace utl {
//! \name SPI implementation specific functions
//!@{
template <spi::bitOrder B =BitOrder> constexpr
meta::use_if_t <(B == spi::bitOrder::LSB_First), void> shift (byte_t& b) { b <<=1; }
meta::enable_if_t <(B == spi::bitOrder::LSB_First), void> shift (byte_t& b) { b <<=1; }
template <spi::bitOrder B =BitOrder> constexpr
meta::use_if_t <(B == spi::bitOrder::MSB_First), void> shift (byte_t& b) { b >>=1; }
meta::enable_if_t <(B == spi::bitOrder::MSB_First), void> shift (byte_t& b) { b >>=1; }
template <spi::cpol C =CPOL> static constexpr bool clkHigh () {
return !static_cast<bool>(C);
}
@@ -113,9 +113,9 @@ namespace utl {
byte_t _tx_data (byte_t out) { return _tx_data_impl (out); }
template <spi::cpha C =CPHA>
meta::use_if_t <(C == spi::cpha::LOW), byte_t> _tx_data_impl (byte_t out);
meta::enable_if_t <(C == spi::cpha::LOW), byte_t> _tx_data_impl (byte_t out);
template <spi::cpha C =CPHA>
meta::use_if_t <(C == spi::cpha::HIGH), byte_t> _tx_data_impl (byte_t out);
meta::enable_if_t <(C == spi::cpha::HIGH), byte_t> _tx_data_impl (byte_t out);
//!@}
//! Data members
@@ -134,7 +134,7 @@ namespace utl {
*/
template <typename impl_t, spi::cpol CPOL, spi::cpha CPHA, spi::bitOrder BitOrder>
template <spi::cpha C>
meta::use_if_t <(C == spi::cpha::LOW), byte_t>
meta::enable_if_t <(C == spi::cpha::LOW), byte_t>
spi_bb_i<impl_t, CPOL, CPHA, BitOrder>::_tx_data_impl (byte_t out) {
byte_t in {};
SCLK (clkL_);
@@ -158,7 +158,7 @@ namespace utl {
*/
template <typename impl_t, spi::cpol CPOL, spi::cpha CPHA, spi::bitOrder BitOrder>
template <spi::cpha C>
meta::use_if_t <(C == spi::cpha::HIGH), byte_t>
meta::enable_if_t <(C == spi::cpha::HIGH), byte_t>
spi_bb_i<impl_t, CPOL, CPHA, BitOrder>::_tx_data_impl (byte_t out) {
byte_t in {};
SCLK (clkL_);
@@ -207,9 +207,9 @@ namespace utl {
//! \name SPI implementation specific functions
//!@{
template <spi::bitOrder B =BitOrder> constexpr
meta::use_if_t <(B == spi::bitOrder::LSB_First), void> shift (byte_t& b) { b <<=1; }
meta::enable_if_t <(B == spi::bitOrder::LSB_First), void> shift (byte_t& b) { b <<=1; }
template <spi::bitOrder B =BitOrder> constexpr
meta::use_if_t <(B == spi::bitOrder::MSB_First), void> shift (byte_t& b) { b >>=1; }
meta::enable_if_t <(B == spi::bitOrder::MSB_First), void> shift (byte_t& b) { b >>=1; }
template <spi::cpol C =CPOL> static constexpr bool clkHigh () {
return !static_cast<bool>(C);
}
@@ -241,9 +241,9 @@ namespace utl {
byte_t _tx_data (byte_t out) final { return _tx_data_impl (out); }
template <spi::cpha C =CPHA>
meta::use_if_t <(C == spi::cpha::LOW), byte_t> _tx_data_impl (byte_t out);
meta::enable_if_t <(C == spi::cpha::LOW), byte_t> _tx_data_impl (byte_t out);
template <spi::cpha C =CPHA>
meta::use_if_t <(C == spi::cpha::HIGH), byte_t> _tx_data_impl (byte_t out);
meta::enable_if_t <(C == spi::cpha::HIGH), byte_t> _tx_data_impl (byte_t out);
//!@}
//! Data members
@@ -262,7 +262,7 @@ namespace utl {
*/
template <spi::cpol CPOL, spi::cpha CPHA, spi::bitOrder BitOrder>
template <spi::cpha C>
meta::use_if_t <(C == spi::cpha::LOW), byte_t>
meta::enable_if_t <(C == spi::cpha::LOW), byte_t>
spi_bb_i<virtual_tag, CPOL, CPHA, BitOrder>::_tx_data_impl (byte_t out) {
byte_t in {};
SCLK (clkL_);
@@ -286,7 +286,7 @@ namespace utl {
*/
template <spi::cpol CPOL, spi::cpha CPHA, spi::bitOrder BitOrder>
template <spi::cpha C>
meta::use_if_t <(C == spi::cpha::HIGH), byte_t>
meta::enable_if_t <(C == spi::cpha::HIGH), byte_t>
spi_bb_i<virtual_tag, CPOL, CPHA, BitOrder>::_tx_data_impl (byte_t out) {
byte_t in {};
SCLK (clkL_);


+ 25
- 0
include/utl/concepts/stl.h Visa fil

@@ -47,6 +47,14 @@ namespace utl {
template <typename T>
using _ref_t = std::add_lvalue_reference_t<T>;
template <typename _T1, typename _T2, typename _Ret =_T1>
using use_if_same_t = meta::eval<
meta::enable_if<
meta::same_<_T1, _T2>::value, _Ret
>
>;
/*!
* Same
*/
@@ -501,6 +509,23 @@ namespace utl {
};
#else
namespace details {
// template <typename B> using try_op_not_ = decltype(!std::declval<cref_<B>>());
// template <typename B> using try_op_eq_ = decltype(std::declval<cref_<B>>() == std::declval<cref_<B>>());
// template <typename B> using try_op_neq_ = decltype(std::declval<cref_<B>>() != std::declval<cref_<B>>());
// template <typename B> using try_op_and_ = decltype(std::declval<cref_<B>>() && std::declval<cref_<B>>());
// template <typename B> using try_op_or_ = decltype(std::declval<cref_<B>>() || std::declval<cref_<B>>());
//
// template <typename B>
// struct is_boolean__ {
// using type = meta::and_ <
// meta::is_detected<B, try_op_not_>,
// meta::is_detected<B, try_op_eq_>,
// meta::is_detected<B, try_op_neq_>,
// meta::is_detected<B, try_op_and_>,
// meta::is_detected<B, try_op_or_>
// >;
// };
template <typename B, typename = void>
struct is_boolean_ {
using type = meta::false_;


+ 15
- 12
include/utl/dev/dev_iterators.h Visa fil

@@ -425,10 +425,11 @@ namespace utl {
typename _Tp::difference_type,
typename _Tp::pointer,
typename _Tp::reference,
meta::use_if_same_t <
typename _Tp::iterator_category,
std::output_iterator_tag
>
// meta::use_if_same_t <
// typename _Tp::iterator_category,
// std::output_iterator_tag
// >
void
>
> : meta::true_ {};
}
@@ -702,10 +703,11 @@ namespace utl {
typename _Tp::difference_type,
typename _Tp::pointer,
typename _Tp::reference,
meta::use_if_same_t <
typename _Tp::iterator_category,
std::input_iterator_tag
>
// meta::use_if_same_t <
// typename _Tp::iterator_category,
// std::input_iterator_tag
// >
void
>
> : meta::true_ {};
}
@@ -986,10 +988,11 @@ namespace utl {
typename _Tp::difference_type,
typename _Tp::pointer,
typename _Tp::reference,
meta::use_if_same_t <
typename _Tp::iterator_category,
std::input_iterator_tag
>
// meta::use_if_same_t <
// typename _Tp::iterator_category,
// std::input_iterator_tag
// >
void
>
> : meta::true_ {};
}


+ 92
- 19
include/utl/meta/detection.h Visa fil

@@ -1,8 +1,8 @@
/*!
* \file detection.h
* \brief Detection idiom based on WG21's N4502[1] from Walter E. Brown
* \brief Detection idiom based on WG21's N4502 [\ref n4502 1] from Walter E. Brown
*
* [1]: www.open-std.org/jtc1/sc22/wg21/docs/papers/2015/n4502.pdf
* \anchor n4502 [1]: www.open-std.org/jtc1/sc22/wg21/docs/papers/2015/n4502.pdf
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
@@ -23,7 +23,7 @@
#define __utl_meta_detection_h__
#include <utl/core/impl.h>
#include <utl/meta/logical.h>
#include <utl/meta/operations.h>
#include <type_traits>
/*!
@@ -57,7 +57,8 @@ namespace meta {
//! @}
/*!
* Not a type to use in detected idiom
* Not a type to use in detected idiom. This type can
* not be constructed, destructed or copied
*/
struct nat_ {
nat_() = delete;
@@ -108,11 +109,9 @@ namespace meta {
* \example
* \code
* // archetypal alias for a copy assignment operation
* template< class T >
* using copy_assign_t = decltype( declval<T&>() = declval<T const &>() );
* template< class T > using copy_assign_t = decltype( declval<T&>() = declval<T const &>() );
*
* template< class T >
* using is_copy_assignable = is_detected< T, copy_assign_t >;
* template< class T > using is_copy_assignable = is_detected< copy_assign_t, T >;
* \endcode
*/
template <template<typename...> class Op, typename... Args>
@@ -121,41 +120,115 @@ namespace meta {
//! Detection predicate
template< template<typename...> class Op, typename... Args>
constexpr bool is_detected_v = is_detected<Op, Args...>::value;
//! @}
/*!
* Detection idiom toolkit
* Detection tool that evaluates to Op<Args...> if it's valid and to nat_ if not
*
* \param Op metafunction detector
* \param Args... The arguments to pass to \p Op and check if is well formed
* \return The result type
* \arg Op<Args...> if is well formed
* \arg nat_ if Op<Args...> is ill formed
* \example
* \code
* template <typename T> using try_type = typename T::type; // detector
* template <typename T> using try_ppT = decltype (++(std::declval<T>())); // detector
* static_assert( std::is_same<nat_, detected_t<try_type, A<int>> >(), ""); // detection failed
* static_assert( std::is_same<A<int>&, detected_t<try_ppT, A<int>> >(), ""); // detection succeed
*
* // if mFun<int, int> is well formed
* static_assert(std::is_same< mFun<int, int>, detected_t<mFun, int, int> >(), "");
* \endcode
*/
//! @{
//! evaluates to evaluation of Op<Args...> if it's valid and to nat_ if not
template <template<typename...> class Op, typename... Args>
using detected_t = eval <
detail::detector<nat_, void, Op, Args...>
>;
//! evaluates to evaluation of Op<Args...> if it's valid and to \p Default if not
/*!
* Detection tool that evaluates to Op<Args...> if it's valid and to \p Default if not
*
* \param Default The resulting type if detection fail
* \param Op metafunction detector
* \param Args... The arguments to pass to \p Op and check if is well formed
* \return The result type
* \arg Op<Args...> if is well formed
* \arg Default if Op<Args...> is ill formed
* \example
* \code
* template <typename T> using try_type = typename T::type; // detector
* template <typename T> using try_ppT = decltype (++(std::declval<T>())); // detector
* static_assert( std::is_same<Foo, detected_or_t<Foo, try_type, A<int>> >(), ""); // detection failed
* static_assert( std::is_same<A<int>&, detected_or_t<Foo, try_ppT, A<int>> >(), ""); // detection succeed
*
* // if mFun<int, int> is well formed
* static_assert(std::is_same< mFun<int, int>, detected_or_t<void, mFun, int, int> >(), "");
* \endcode
*/
template <typename Default,
template<typename...> class Op, typename... Args>
using detected_or_t = eval <
detail::detected_or<Default, Op, Args...>
>;
//! evaluates to true_ if evaluation of Op<Args...> is \p Expected and to false_ if not
/*!
* Detection tool that evaluates to true_ if evaluation of Op<Args...>
* is \p Expected and to false_ if not
*
* \param Expected The expected resulting type if detection succeed
* \param Op metafunction detector
* \param Args... The arguments to pass to \p Op and check if is well formed
* \return The result type
* \arg true_ if Op<Args...> is well formed and evaluate to Expected
* \arg false_ Any other case
* \example
* \code
* template <typename T> using try_type = typename T::type; // detector
* template <typename T> using try_ppT = decltype (++(std::declval<T>())); // detector
* static_assert( std::is_same<false_, is_detected_exact<int, try_type, A<int>> >(), ""); // detection failed
* static_assert( std::is_same<true_, is_detected_exact<A<int>&, try_ppT, A<int>> >(), ""); // detection succeed
*
* // if mFun<int, int> is well formed
* static_assert(std::is_same< true_, is_detected_exact<mFun<int, int>, mFun, int, int> >(), "");
* \endcode
*/
template <typename Expected,
template<typename...> class Op, typename... Args >
using is_detected_exact = same_<Expected, detected_t<Op, Args...> >;
using is_detected_exact = eval <
same_<Expected, detected_t<Op, Args...>>
>;
//! evaluates to true if evaluation of Op<Args...> is \p Expected and to false if not
template <typename Expected,
template<typename...> class Op, typename... Args >
constexpr bool is_detected_exact_v = is_detected_exact< Expected, Op, Args...>::value;
//! evaluates to true_ if evaluation of Op<Args...> is convertible to \p To
//! and to false_ if not
/*!
* Detection tool that evaluates to true_ if evaluation of Op<Args...> is convertible
* to \p To and to false_ if not
*
* \param To The to convert to if detection succeed
* \param Op metafunction detector
* \param Args... The arguments to pass to \p Op and check if is well formed
* \return The result type
* \arg true_ if Op<Args...> is well formed and convertible to To
* \arg false_ Any other case
* \example
* \code
* template <typename T> using try_type = typename T::type; // detector
* template <typename T> using try_ppT = decltype (++(std::declval<T>())); // detector
* static_assert( std::is_same<false_, is_detected_convertible<Foo, try_type, A<int>> >(), ""); // detection failed
* static_assert( std::is_same<true_, is_detected_convertible<A<int>&&, try_ppT, A<int>> >(), "");// detection succeed
*
* // if mFun<int, int> is well formed but not convertible to Foo
* static_assert(std::is_same< false_, is_detected_convertible<Foo, mFun, int, int> >(), "");
* \endcode
*/
template <typename To,
template<typename...> class Op, typename... Args >
using is_detected_convertible = std::is_convertible< detected_t<Op, Args...>, To >;
using is_detected_convertible = eval <
std::is_convertible< detected_t<Op, Args...>, To >
>;
//! evaluates to true if evaluation of Op<Args...> is convertible to \p To
//! and to false if not


+ 0
- 113
include/utl/meta/idx_sequence.h Visa fil

@@ -1,113 +0,0 @@
/*!
* \file pack.h
* \brief Template meta-programming parameter pack container
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __utl_meta_idx_sequence_h__
#define __utl_meta_idx_sequence_h__
#include <utl/core/impl.h>
#include <utl/meta/integral.h>
/*!
* \ingroup meta
* \defgroup index_sequence
*/
//! @{
namespace utl {
namespace meta {
/*!
* Class template integer_sequence
*/
template<typename _Tp, _Tp... _Idx>
struct integer_sequence {
using value_type = _Tp;
static constexpr size_t size() noexcept {
return sizeof...(_Idx);
}
};
//! Alias template index_sequence
template<index_t... _Idx>
using index_sequence = integer_sequence<index_t, _Idx...>;
//! make_integer_sequence
//! @{
namespace detail {
// Stores a tuple of indices
template<size_t... Idxs> struct index_tuple { };
// Concatenates two index_tuples.
template<typename It1, typename It2> struct it_cat_;
template<size_t... It1, size_t... It2>
struct it_cat_ <index_tuple<It1...>, index_tuple<It2...>> {
using type = index_tuple<It1..., (It2 + sizeof...(It1))...>;
};
// Builds an index_tuple<0, 1, 2, ..., _Num-1>.
template<size_t _Num>
struct make_index_tuple_
: it_cat_<eval<make_index_tuple_<_Num / 2>>,
eval<make_index_tuple_<_Num - _Num / 2>>>
{ };
// termination specialization for 1
template<>
struct make_index_tuple_<1> {
using type = index_tuple<0>;
};
// termination specialization for 0
template<>
struct make_index_tuple_<0> {
using type = index_tuple<>;
};
// factory type
template<typename _Tp, _Tp _Num,
typename _ISeq = eval<make_index_tuple_<_Num>>>
struct make_integer_sequence_;
template<typename _Tp, _Tp _Num, size_t... _Idx>
struct make_integer_sequence_<_Tp, _Num, index_tuple<_Idx...>> {
static_assert( _Num >= 0,
"Cannot make integer sequence of negative length" );
using type = integer_sequence<_Tp, static_cast<_Tp>(_Idx)...>;
};
}
//! Alias template make_integer_sequence
//! Complexity \f$ O(log N) \f$
template<typename _Tp, _Tp N>
using make_integer_sequence = eval<detail::make_integer_sequence_<_Tp, N>>;
//! Alias template make_index_sequence
//! Complexity \f$ O(log N) \f$
template<index_t N>
using make_index_sequence = make_integer_sequence<index_t, N>;
//! Alias template index_sequence_for
//! Complexity \f$ O(log N) \f$
//! where N is sizeof...(_Ts)
template<typename... _Ts>
using index_sequence_for = make_index_sequence<sizeof...(_Ts)>;
//! @}
}}
//! @}
#endif /* __utl_meta_idx_sequence_h__ */

+ 59
- 50
include/utl/meta/integral.h Visa fil

@@ -21,7 +21,8 @@
#define __utl_meta_integralconstant_h__
#include <utl/core/impl.h>
#include <type_traits>
#include <utility>
/*!
* \ingroup meta
@@ -43,9 +44,9 @@ namespace meta {
using type = nil_;
};
//! Type alias for \p _Tp::type. Used to evaluate/extract return type of metafunctions
template <typename _Tp>
using eval = typename _Tp::type;
//! Type alias for \p Tp::type. Used to evaluate/extract return type of metafunctions
template <typename Tp>
using eval = typename Tp::type;
//! integral_
//! Integral Constant is a holder class for a compile-time value of an integral type.
@@ -53,90 +54,98 @@ namespace meta {
//! An integral constant object is implicitly convertible to the corresponding
//! run-time value of the wrapped integral type
//! @{
template <typename _Tp, _Tp _v>
struct integral_ {
using value_type = _Tp;
using type = integral_<_Tp, _v>;
constexpr operator value_type() const noexcept {
return value;
}
constexpr value_type operator()() const noexcept {
return value;
}
static constexpr _Tp value = _v;
};
template<typename _Tp, _Tp _v>
constexpr _Tp integral_<_Tp, _v>::value;
template <typename Tp, Tp v>
using integral_ = std::integral_constant<Tp, v>;
//! @}
//! Wrappers for basic types
//! @{
//! bool_ type: integral constant wrapper for bool
template<bool _v>
using bool_ = integral_<bool, _v>;
template<bool v>
using bool_ = integral_<bool, v>;
using true_ = bool_<true>; //!< The type used as a compile-time boolean with true value.
using false_ = bool_<false>; //!< The type used as a compile-time boolean with false value.
//! int8_ type: integral constant wrapper for \c int8_t
template<int8_t _v>
using int8_ = integral_<int8_t, _v>;
template<int8_t v>
using int8_ = integral_<int8_t, v>;
//! uint8_ type: integral constant wrapper for \c uint8_t
template<uint8_t _v>
using uint8_ = integral_<uint8_t, _v>;
template<uint8_t v>
using uint8_ = integral_<uint8_t, v>;
//! int16_ type: integral constant wrapper for \c int16_t
template<int16_t _v>
using int16_ = integral_<int16_t, _v>;
template<int16_t v>
using int16_ = integral_<int16_t, v>;
//! uint16_ type: integral constant wrapper for \c uint16_t
template<uint16_t _v>
using uint16_ = integral_<uint16_t, _v>;
template<uint16_t v>
using uint16_ = integral_<uint16_t, v>;
//! int32_ type: integral constant wrapper for \c int32_t
template<int32_t _v>
using int32_ = integral_<int32_t, _v>;
template<int32_t v>
using int32_ = integral_<int32_t, v>;
//! uint32_ type: integral constant wrapper for \c uint32_t
template<uint32_t _v>
using uint32_ = integral_<uint32_t, _v>;
template<uint32_t v>
using uint32_ = integral_<uint32_t, v>;
//! char_ type: integral constant wrapper for \c char
template<char _v>
using char_ = integral_<char, _v>;
template<char v>
using char_ = integral_<char, v>;
//! int_ type: integral constant wrapper for \c int
template<int _v>
using int_ = integral_<int, _v>;
template<int v>
using int_ = integral_<int, v>;
//! long_ type: integral constant wrapper for \c long
template<long _v>
using long_ = integral_<long, _v>;
template<long v>
using long_ = integral_<long, v>;
//! index_ type: integral constant wrapper for \c index_t a.k.a std::size_t
template<index_t _v>
using index_ = integral_<index_t, _v>;
template<index_t v>
using index_ = integral_<index_t, v>;
//! size_ type: integral constant wrapper for \c size_t a.k.a std::size_t
template<size_t _v>
using size_ = integral_<size_t, _v>;
template<size_t v>
using size_ = integral_<size_t, v>;
//! Computes the size of the type \p _Tp.
//! Computes the size of the type \p Tp.
//! Complexity \f$ O(1) \f$.
template <typename _Tp>
using sizeof_ = size_<sizeof(_Tp)>;
template <typename Tp>
using sizeof_ = size_<sizeof(Tp)>;
//! Computes the alignment required for any instance of the type \p _Tp.
//! Computes the alignment required for any instance of the type \p Tp.
//! Complexity \f$ O(1) \f$.
template <typename _Tp>
using alignof_ = size_<alignof(_Tp)>;
template <typename Tp>
using alignof_ = size_<alignof(Tp)>;
//! @}
//! The last position we can express for indexing
using Npos = size_<index_t(-1)>;
//! integer sequence
//! @{
template< class Tp, Tp... Ints >
using integer_sequence = std::integer_sequence<Tp, Ints...>;
template<typename Tp, Tp Num>
using make_integer_sequence = std::make_integer_sequence<Tp, Num>;
//! Alias template index_sequence
template<index_t... Idx>
using index_sequence = integer_sequence<index_t, Idx...>;
//! Alias template make_index_sequence
template<index_t Num>
using make_index_sequence = make_integer_sequence <index_t, Num>;
//! Alias template index_sequence_for
template<typename... Types>
using index_sequence_for = make_index_sequence<sizeof...(Types)>;
//! @}
}}
//!@}
#endif /* __utl_meta_integralconstant_h__ */

+ 140
- 70
include/utl/meta/invoke.h Visa fil

@@ -23,8 +23,7 @@
#include <utl/core/impl.h>
#include <utl/meta/integral.h>
#include <utl/meta/detection.h>
#include <utl/meta/selection.h>
#include <utl/meta/logical.h>
#include <utl/meta/operations.h>
/*!
* \ingroup meta
@@ -36,15 +35,19 @@ namespace utl {
namespace meta{
/*!
* \name meta:: invoke
* \name meta::invoke
*
* A meta-programming invoke() analogous. A meta:: `invocable` shall contain a nested
* template type named `apply` which is bind to actual invocable meta-function.
* A meta-programming invoke() analogous. A \c meta::invocable shall contain a nested
* template type named \b apply which is bind to actual invocable meta-function.
*
* - We can use \c wrap<> or even better \c quote<> in order to wrap a metafunction to a type (metafunction class)
* - We can pass these wrapped types to other metafunctions
* - We can \c invoke<> the inner \c apply from a wrapped metafunction class.
*/
//! @{
/*!
* *invocable* identity, identity_t.
* identity, identity_t.
*/
//! @{
template <typename _Tp>
@@ -56,7 +59,7 @@ namespace meta{
#else
template <typename...>
using apply = _Tp; //!< identity is invokable, must also have apply
#endif
#endif
using type = _Tp; //!< identity
};
@@ -65,6 +68,49 @@ namespace meta{
using identity_t = eval<identity<_Tp>>;
//! @}
/*!
* invoke, invoke_t
*/
//! @{
/*!
* Invoke the nested apply meta-function from \c Fn with the arguments \c Args.
* \note
* This is an analogous to the std::invoke()
*/
template <typename Fn, typename... Args>
using invoke = typename Fn::template apply<Args...>;
/*!
* Evaluate the invocation of the nested apply metafunction from \p Fn
* with the arguments \p Args.
*/
template <typename Fn, typename... Args>
using invoke_t = eval< invoke <Fn, Args...>>;
//! @}
//! wrap
//! @{
/*!
* wrap is a higher-order primitive that wraps an n-ary Metafunction
* to create a corresponding Metafunction Class (Invocable). This way
* we can pass Metafunctions as types to other metafunctions and let
* them \c invoke the inner templated apply
*/
template <template <typename...> class F>
struct wrap {
template <typename... Args>
using apply = F<Args...>;
};
//! Wrap a template \p F taking literal constants of type \p T into an Invokable
template <typename T, template <T...> class F>
struct wrap_i {
// requires meta::Integral
template <typename... Ts>
using apply = F<Ts::type::value...>;
};
//! @}
//! Is applicable trait
//! @{
namespace detail {
@@ -79,22 +125,29 @@ namespace meta{
using type = decltype(check<F>(0));
};
template <typename Fn, typename... Args>
using use_ = typename Fn::template apply<Args...>;
template<typename F, typename... T>
struct is_applicable_q_ {
template<typename G, typename Ret= eval<use_<G, T...>>>
static Ret check (int); //< T.. can be passed to G
template<typename G, typename Ret = invoke_t<G, T...>>
static Ret check (int); //< T.. can be passed to G
template<typename...>
static nil_ check (...); //< all other combinations
static nil_ check (...); //< all other combinations
using type = decltype(check<F>(0));
using type = if_ <
not_same_<
nil_,
decltype(check<F>(0))
>, true_, false_
>;
//!\note
//! check doesn't return \c true_ or \c false_. The reason is that the \p F is
//! probably quoted/deferred. This implies an embedded is_applicable<> check
//! inside defer<> and so its guaranteed to be well formed.
//! Thus we return the actual evaluated type and make the check for nil_
};
template<typename T, template <T...> class F, T... Is>
struct is_applicable_i_ {
template<typename TT, template<TT...> class G, typename =G<Is...>>
template<typename TT, template<TT...> class G, typename = G<Is...>>
static true_ check (int); //< Is... can be passed to G
template<typename TT, template<TT...> class G>
static false_ check (...); //< all other combinations
@@ -106,26 +159,18 @@ namespace meta{
//! check if we can instantiate \p F with parameters \p T
template<template<typename...> class F, typename... T>
using is_applicable_t = eval<
detail::is_applicable_<F, T...>
detail::is_applicable_<F, T...>
>;
//! check if we can instantiate \p Q with parameters \p T and the instant
//! is different from \c nil_
//! check if we can invoke \p Q with parameters \p T
template<typename Q, typename... T>
using is_applicable_qt = eval <
// Extra check for quoted metafunctions to check return type
if_ <
not_same_<
eval <detail::is_applicable_q_ <Q, T...>>,
nil_
>,
true_,
false_
>
detail::is_applicable_q_ <Q, T...>
>;
//! check if we can instantiate \p F with parameters \p Is of type \p T
template <typename T, template<T...> class F, T... Is>
using is_applicable_it = eval<
detail::is_applicable_i_<T, F, Is...>
detail::is_applicable_i_<T, F, Is...>
>;
//! @}
@@ -149,75 +194,85 @@ namespace meta{
//! template<template<typename...> class F, typename... Ts>
//! using defer_ = F<Ts...>;
//!
//! The use of struct here is due to Core issue 1430 [1] and is used
//! as suggested by Roy Crihfield in [2].
//! The use of struct here is due to Core issue 1430 [\ref link1 1] and is used
//! as suggested by Roy Crihfield in [\ref link2 2].
//! In short, this is due to language's inability to expand Ts... into
//! a fixed parameter list of an alias template.
//!
//! [1]: https://wg21.link/cwg1430
//! [2]: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=59498
//! \anchor link1 [1]: https://wg21.link/cwg1430
//! \anchor link2 [2]: https://gcc.gnu.org/bugzilla/show_bug.cgi?id=59498
//! @}
}
//! defer alias template for F<Ts...>
template<template<class...> class F, class... Ts>
using defer = if_<
detail::is_applicable_<F, Ts...>,
detail::defer_<F, Ts...>,
nil_ //!< This should be identity<nil_> if nil_ was empty
detail::is_applicable_<F, Ts...>,
detail::defer_<F, Ts...>,
nil_ //!< Safe, nil_ is dereferencable
>;
//! defer_i alias template for F<T, Is...>
template <typename T, template<T...> class F, T... Is>
using defer_i = if_ <
detail::is_applicable_i_<T, F, Is...>,
detail::defer_i_<T, F, Is...>,
nil_ //!< This should be identity<nil_> if nil_ was empty
detail::is_applicable_i_<T, F, Is...>,
detail::defer_i_<T, F, Is...>,
nil_ //!< Safe, nil_ is dereferencable
>;
//! @}
//! quote
//! @{
/*!
* quote is a higher-order primitive that wraps an n-ary Metafunction
* to create a corresponding Metafunction Class (Invocable).
* quote deferred is a higher-order primitive that wraps an n-ary Metafunction
* to create a corresponding Metafunction Class (Invocable) using defer<> to
* postpone the evaluation of Metafunction. This is a safe version of \c wrap<>.
* Again this way we can pass Metafunctions as types to other metafunctions and let
* them \c invoke the inner templated apply
*/
template <template <typename...> class F>
struct quote {
template <typename... Args>
using apply = eval<
defer<F, Args...> //!< defer here to avoid DR1430
defer<F, Args...> //!< defer here to avoid DR1430
>;
};
//! Wrap a template \p F taking literals of type \p T into an Invokable
//! Wrap a template \p F taking literal constants of type \p T into an Invokable
template <typename T, template <T...> class F>
struct quote_i {
// requires meta::Integral
template <typename... Ts>
using apply = eval<
defer_i<T, F, Ts::type::value...> //!< defer here to avoid DR1430
defer_i<T, F, Ts::type::value...> //!< defer here to avoid DR1430
>;
};
/*!
* Invoke the nested apply meta-function from \c Fn
* with the arguments \c Args.
* \note
* This is like the std::invoke()
*/
template <typename Fn, typename... Args>
using invoke = typename Fn::template apply<Args...>;
/*!
* Evaluate the invocation of the nested apply metafunction from \p Fn
* with the arguments \p Args.
*/
template <typename Fn, typename... Args>
using invoke_t = eval< invoke <Fn, Args...>>;
//! @}
//! compose
//! @{
namespace detail {
template<typename ...Fns> struct compose_ { };
template <template <typename...> class... Fns> struct compose_f_ {};
// recursive call to all invokes
template <template <typename...> class Fn0,
template <typename...> class... Fns>
struct compose_f_<Fn0, Fns...> {
template <typename... Args>
using apply = invoke<
quote<Fn0>,
invoke<compose_f_<Fns...>, Args...>
>;
};
// Termination specialization, finally pass the arguments
template <template <typename...> class Fn0>
struct compose_f_<Fn0> {
template <typename ...Args>
using apply = invoke<quote<Fn0>, Args...>;
};
template<typename ...Fns> struct compose_ {};
// recursive call to all invokes
template<typename Fn0, typename ...Fns>
@@ -228,7 +283,6 @@ namespace meta{
invoke<compose_<Fns...>, Args...>
>;
};
// Termination specialization, finally pass the arguments
template<typename Fn0>
struct compose_<Fn0> {
@@ -238,25 +292,40 @@ namespace meta{
}
/*!
* Create an invocable from other invocables by composition.
* Create an invocable from other invocables(quoted metafunctions) by composition.
* \note
* This implies from N invocables in \p Fns the first N-1 has to be unary.
* That because of the "return" type of metafunction. They can only return one
* Thats because of the "return" type of metafunction. They can only return one
* type. So for n-ary invocables in the N-1 places the typelist<> is the solution.
* \example
* \code
* static_assert(std::is_same<
* invoke<compose<F1, F2, F3>, int>,
* F1 <F2 <F3 <int>>>
* >, "" );
* static_assert( std::is_same<
* invoke<compose<quote<F1>, quote<F2>, quote<F3>>, int>, F1<F2<F3<int>>>
* >, "");
* \endcode
*/
template <typename... Fns>
using compose = detail::compose_<Fns...>;
/*!
* Create an invocable from other metafunctions by composition.
* \note
* This implies from N invocables in \p Fns the first N-1 has to be unary.
* Thats because of the "return" type of metafunction. They can only return one
* type. So for n-ary invocables in the N-1 places the typelist<> is the solution.
* \example
* \code
* static_assert( std::is_same<
* invoke<compose_f<F1, F2, F3>, int>, F1 <F2 <F3 <int>>>
* >, "");
* \endcode
*/
template <template <typename...> class... Fns>
using compose_f = detail::compose_f_<Fns...>;
//! @}
/*!
* Applies the Invocable \p Fn by binding the arguments \p Ts
* Applies the invocable \p Fn by binding the arguments \p Ts
* to the front of \p Fn.
*/
template<typename Fn, typename... Ts>
@@ -275,18 +344,19 @@ namespace meta{
using apply = invoke<Fn, Us..., Ts...>;
};
/*
* ========== meta:: predicates ============
*/
template <typename T1>
struct same_as {
template < typename T2>
template <typename T2>
struct apply : same_<T1, T2> { };
};
template <typename T1>
struct not_same_as {
template < typename T2>
template <typename T2>
struct apply : not_same_<T1, T2> { };
};


+ 0
- 118
include/utl/meta/logical.h Visa fil

@@ -1,118 +0,0 @@
/*!
* \file logical.h
* \brief Template meta-programming logic operator and type relations.
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __utl_meta_logical_h__
#define __utl_meta_logical_h__
#include <utl/core/impl.h>
#include <utl/meta/selection.h>
/*!
* \ingroup meta
* \defgroup logic
* logic operator and type relations support header
*/
//! @{
namespace utl {
namespace meta{
/*!
* Logical relation for types
*/
//! @{
//! Negate the *bool* constant parameter
template <bool B>
using not_c = bool_<!B>;
//! not
template<typename _Tp>
using not_ = not_c<_Tp::type::value>;
//! OR implementation
//! @{
namespace detail {
template<typename...> struct _or_;
template<>
struct _or_<> : false_ { };
template<typename _T1>
struct _or_<_T1> : _T1 { };
template<typename _T1, typename _T2>
struct _or_ <_T1, _T2>
: if_<_T1, _T1, _T2> { };
template<typename _T1, typename _T2, typename _T3, typename... _Tn>
struct _or_<_T1, _T2, _T3, _Tn...>
: if_<_T1, _T1, _or_<_T2, _T3, _Tn...>> { };
}
template <typename... _Ts>
using or_ = eval<detail::_or_<_Ts...>>;
//! @}
//! AND implementation
//! @{
namespace detail {
template<typename...> struct _and_;
template<>
struct _and_<>
: true_ { };
template<typename _T1>
struct _and_ <_T1>
: _T1 { };
template<typename _T1, typename _T2>
struct _and_<_T1, _T2>
: if_<_T1, _T2, _T1> { };
template<typename _T1, typename _T2, typename _T3, typename... _Tn>
struct _and_<_T1, _T2, _T3, _Tn...>
: if_<_T1, _and_<_T2, _T3, _Tn...>, _T1> { };
}
template <typename... _Ts>
using and_ = eval<detail::_and_<_Ts...>>;
//! @}
//! same
//! @{
template<typename _T1, typename _T2>
struct same_ : false_ { };
template<typename _Tp>
struct same_ <_Tp, _Tp> : true_ { };
//! @}
//! not same
//! @{
template<typename _T1, typename _T2>
using not_same_ = not_<eval<same_<_T1, _T2>>>;
//! @}
//! @}
}}
//! @}
#endif /* __utl_meta_logical_h__ */

+ 3
- 4
include/utl/meta/meta.h Visa fil

@@ -1,6 +1,6 @@
/*!
* \file /utl/core/version.h
* \brief version and cpp version checks
* \file /utl/meta/meta.h
* \brief Include all meta library
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
@@ -22,11 +22,10 @@
#define __utl_meta_meta_h__
#include <utl/meta/integral.h>
#include <utl/meta/typelist.h>
#include <utl/meta/selection.h>
#include <utl/meta/logical.h>
#include <utl/meta/operations.h>
#include <utl/meta/useif.h>
#include <utl/meta/typelist.h>
#include <utl/meta/detection.h>
#include <utl/meta/invoke.h>


+ 105
- 10
include/utl/meta/operations.h Visa fil

@@ -1,6 +1,6 @@
/*!
* \file operators.h
* \brief Template meta-programming integral constant arithmetic
* \file operations.h
* \brief Integral constant operations and logical operations
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
@@ -17,11 +17,105 @@
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __utl_meta_arithmetic_h__
#define __utl_meta_arithmetic_h__
#ifndef __utl_meta_operations_h__
#define __utl_meta_operations_h__
#include <utl/core/impl.h>
#include <utl/meta/logical.h>
#include <utl/meta/selection.h>
/*!
* \ingroup meta
* \defgroup logic
* logic operators and type relations support
*/
//! @{
namespace utl {
namespace meta{
/*!
* Logical relation for types
*/
//! @{
//! Negate the *bool* constant parameter
template <bool B>
using not_c = bool_<!B>;
//! not
template<typename _Tp>
using not_ = not_c<_Tp::type::value>;
//! OR implementation
//! @{
namespace detail {
template<typename...> struct _or_;
template<>
struct _or_<> : false_ { };
template<typename _T1>
struct _or_<_T1> : _T1 { };
template<typename _T1, typename _T2>
struct _or_ <_T1, _T2>
: if_<_T1, _T1, _T2> { };
template<typename _T1, typename _T2, typename _T3, typename... _Tn>
struct _or_<_T1, _T2, _T3, _Tn...>
: if_<_T1, _T1, _or_<_T2, _T3, _Tn...>> { };
}
template <typename... _Ts>
using or_ = eval<detail::_or_<_Ts...>>;
//! @}
//! AND implementation
//! @{
namespace detail {
template<typename...> struct _and_;
template<>
struct _and_<>
: true_ { };
template<typename _T1>
struct _and_ <_T1>
: _T1 { };
template<typename _T1, typename _T2>
struct _and_<_T1, _T2>
: if_<_T1, _T2, _T1> { };
template<typename _T1, typename _T2, typename _T3, typename... _Tn>
struct _and_<_T1, _T2, _T3, _Tn...>
: if_<_T1, _and_<_T2, _T3, _Tn...>, _T1> { };
}
template <typename... _Ts>
using and_ = eval<detail::_and_<_Ts...>>;
//! @}
//! same
//! @{
template<typename _T1, typename _T2>
struct same_ : false_ { };
template<typename _Tp>
struct same_ <_Tp, _Tp> : true_ { };
//! @}
//! not same
//! @{
template<typename _T1, typename _T2>
using not_same_ = not_<eval<same_<_T1, _T2>>>;
//! @}
//! @}
}}
//! @}
/*!
* \ingroup meta
@@ -33,10 +127,10 @@
namespace utl {
namespace meta {
/*!
* Math operations
* requires IntegralConstant(_Tp)
*/
/*!
* Math operations
* requires IntegralConstant(_Tp)
*/
//! @{
//! Negation
@@ -129,4 +223,5 @@ namespace meta {
}}
//!@}
#endif /* __utl_meta_integral_h__ */
#endif /* __utl_meta_operations_h__ */

+ 3
- 9
include/utl/meta/selection.h Visa fil

@@ -22,7 +22,6 @@
#include <utl/core/impl.h>
#include <utl/meta/integral.h>
#include <utl/meta/sfinae.h>
/*!
* \ingroup meta
@@ -74,15 +73,10 @@ namespace meta{
//! @{
//! Select the first type of a type sequence
template <typename T1, typename ...>
struct first_of {
using type = T1;
};
template <typename T1, typename ...> using first_of = T1;
//! Select the second type of a type sequence
template <typename T1, typename T2, typename ...>
struct second_of {
using type = T2;
};
template <typename T1, typename T2, typename ...> using second_of = T2;
//! @}
}}


+ 15
- 29
include/utl/meta/sfinae.h Visa fil

@@ -21,6 +21,7 @@
#define __utl_meta_sfinae_h__
#include <utl/core/impl.h>
#include <type_traits>
/*!
* \ingroup meta
@@ -34,48 +35,33 @@ namespace meta {
//! Tool to enable a partial specialization only if a boolean condition is true.
//! @{
namespace detail {
template <typename... T>
struct dev_null { using type = dev_null; }; //< Same as typelist
// template <typename... T>
// struct dev_null { using type = dev_null; }; //< Same as typelist
template <bool If> struct when_ { };
template <> struct when_<true> { using type = void; };
}
//! Well formed only if \p If is true
template <bool If>
using when = eval<detail::when_<If>>;
using when = eval< detail::when_<If> >;
// //! Well formed only if all of \p Ifs are \c true
// template <bool ...Ifs>
// using when_all = detail::dev_null<
// when<Ifs>...
// >;
//! Well formed only if all of \p Ifs are \c true
template <bool ...Ifs>
using when_all = detail::dev_null<
when<Ifs>...
>;
//! @}
//! select _Tp if \p If is true, else SFINAE
//! We implement enable_if so we don't have to pull entire \c <type_traits> from stl
//! enable_if
//! @{
template <bool If, typename _Tp = void>
struct enable_if {
using type = _Tp;
};
template<typename _Tp>
struct enable_if <false, _Tp> { /* SFINAE*/ };
//! Alias template for enable_if
template <bool If, typename _Tp = void>
using use_if = enable_if<If, _Tp>;
//! enable_if, imported from stl
template <bool If, typename _Tp = void> using enable_if = std::enable_if<If, _Tp>;
//! Publicly recognized alias template for enable_if
template<bool If, typename _Tp = void>
using enable_if_t = eval<
enable_if<If, _Tp>
>;
//! alias template for enable_if
template<bool If, typename _Tp = void> using enable_if_t = eval< enable_if<If, _Tp> >;
//! Uniform alias template for use_if
template<bool If, typename _Tp = void>
using use_if_t = eval<
enable_if<If, _Tp>
>;
//! @}
}}


+ 67
- 64
include/utl/meta/typelist.h Visa fil

@@ -17,12 +17,11 @@
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef __utl_meta_pack_h__
#define __utl_meta_pack_h__
#ifndef __utl_meta_typelist_h__
#define __utl_meta_typelist_h__
#include <utl/core/impl.h>
#include <utl/meta/integral.h>
#include <utl/meta/idx_sequence.h>
#include <utl/meta/detection.h>
#include <utl/meta/invoke.h>
#include <utl/meta/sfinae.h>
@@ -39,7 +38,7 @@ namespace meta {
* \brief
* A class template that just holds a parameter pack.
*
* The idea came from MPL's sequence concept[1] and from N4115[2].
* The idea came from MPL's sequence concept [\ref link1 1] and from N4115 [\ref link2 2].
* In addition to N4115's name "packer" we just prefer a name which is object, not a subject.
* This way the name gives the feeling of a container and smells like Python.
*
@@ -53,14 +52,14 @@ namespace meta {
* l1 a {};
* \endcode
*
* boost::hana[3] suggests a more powerful scheme were type invariant structures can be used
* boost::hana [\ref link3 3] suggests a more powerful scheme were type invariant structures can be used
* for metaprograming also. This lib does not need (yet) this kind of power (we afraid the
* responsibility that comes along). So a simple python-like list with some extra vector-like
* element access functionalities and no iterators is good enough(for now).
*
* [1]: https://www.boost.org/doc/
* [2]: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2014/n4115.html
* [3]: https://github.com/boostorg/hana
* \anchor link1 [1]: https://www.boost.org/doc/
* \anchor link2 [2]: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2014/n4115.html
* \anchor link3 [3]: https://github.com/boostorg/hana
*/
template <typename... Ts>
struct typelist {
@@ -197,6 +196,9 @@ namespace meta {
template <typename Fn, typename Seq>
using apply = apply_impl::apply_<Fn, Seq>;
template <typename Fn, typename Seq>
using apply_t = eval <apply<Fn, Seq>>;
//! @}
/*
@@ -206,11 +208,8 @@ namespace meta {
//! @{
namespace at_impl {
template <typename T> struct _as_pointer__ { using type = T*; };
template <typename T> struct _as_pointer__<T*> { using type = T*; };
template <typename T> using as_pointer_ = eval<
_as_pointer__<T>
>;
template <typename T> struct _add_pointer { using type = T*; };
template <typename T> using add_pointer = eval < _add_pointer <T> >;
template <typename ...>
struct at_head_ { };
@@ -230,7 +229,7 @@ namespace meta {
struct at_<typelist<List...>, N> {
using head_ = at_head_<typelist<void*>::times<N>>; //< make at_head_<> with N void*
using type = decltype(
head_::select(static_cast<as_pointer_<List>>(nullptr)...) //< pass all as List*...
head_::select(static_cast<add_pointer<List>>(nullptr)...) //< pass all as List*...
);
};
}
@@ -242,7 +241,7 @@ namespace meta {
*/
template <typename List, index_t N>
using at_c = eval<
at_impl::at_<List, N>
at_impl::at_<List, N>
>;
/*!
@@ -271,7 +270,7 @@ namespace meta {
//! Complexity \f$ O(1) \f$.
template <typename List>
using front = eval<
front_impl::front_<List>
front_impl::front_<List>
>;
//! @}
@@ -284,7 +283,7 @@ namespace meta {
template <typename Head, typename... Tail>
struct back_<typelist<Head, Tail...>> {
using type = at_c <
typelist<Head, Tail...>, sizeof...(Tail)
typelist<Head, Tail...>, sizeof...(Tail)
>;
};
}
@@ -293,7 +292,7 @@ namespace meta {
//! Complexity \f$ O(N) \f$.
template <typename List>
using back = eval<
back_impl::back_<List>
back_impl::back_<List>
>;
//! @}
/*
@@ -335,7 +334,7 @@ namespace meta {
*/
template <typename... Lists>
using cat = eval<
cat_impl::cat_<Lists...>
cat_impl::cat_<Lists...>
>;
//! @}
@@ -435,7 +434,7 @@ namespace meta {
*/
template <typename List, typename V, typename Fn>
using rev_fold = eval<
rev_fold_impl::rev_fold_<List, V, Fn>
rev_fold_impl::rev_fold_<List, V, Fn>
>;
//! @}
@@ -464,7 +463,6 @@ namespace meta {
//! reverse
//! @{
namespace reverse_impl {
template <typename List, typename V = typelist<>>
struct reverse_ {
using type = fold<List, V, quote<push_front>>;
@@ -477,7 +475,7 @@ namespace meta {
*/
template <typename List>
using reverse = eval<
reverse_impl::reverse_<List>
reverse_impl::reverse_<List>
>;
//! @}
@@ -500,7 +498,7 @@ namespace meta {
*/
template <typename List>
using pop_front = eval<
pop_front_impl::pop_front_<List>
pop_front_impl::pop_front_<List>
>;
//! @}
@@ -524,7 +522,7 @@ namespace meta {
*/
template <typename List>
using pop_back = eval <
pop_back_impl::pop_back_<List>
pop_back_impl::pop_back_<List>
>;
//! @}
@@ -538,7 +536,7 @@ namespace meta {
struct transform_<typelist<typelist<Ts...>, Fn>,
void_t<invoke<Fn, Ts>...> > /* SFINAE check */ {
using type = typelist<
invoke_t<Fn, Ts>...
invoke_t<Fn, Ts>...
>;
};
@@ -546,7 +544,7 @@ namespace meta {
struct transform_<typelist<typelist<Ts0...>, typelist<Ts1...>, Fn>,
void_t<invoke<Fn, Ts0, Ts1>...>> /* SFINAE check */ {
using type = typelist<
invoke_t<Fn, Ts0, Ts1>...
invoke_t<Fn, Ts0, Ts1>...
>;
};
}
@@ -559,14 +557,14 @@ namespace meta {
* \example
* \code
* using l1 = typelist<char, int, ...>;
* using l2 = typelist<void, void, ...>;
* using l2 = typelist<void, double, ...>;
* using r1 = transform<l1, F1>; // F1, unary invocable
* using r2 = transform<l1, l2, F2>; // F2, binary invocable
* \endcode
*/
template <typename... Args>
using transform = eval<
transform_impl::transform_<typelist<Args...>>
transform_impl::transform_<typelist<Args...>>
>;
//! @}
@@ -581,7 +579,7 @@ namespace meta {
struct transform_lazy_<typelist<typelist<Ts...>, Fn>,
void_t<invoke<Fn, Ts>...> > /* SFINAE check */ {
using type = typelist<
invoke<Fn, Ts>...
invoke<Fn, Ts>...
>;
};
@@ -590,7 +588,7 @@ namespace meta {
struct transform_lazy_<typelist<typelist<Ts0...>, typelist<Ts1...>, Fn>,
void_t<invoke<Fn, Ts0, Ts1>...>> /* SFINAE check */ {
using type = typelist<
invoke<Fn, Ts0, Ts1>...
invoke<Fn, Ts0, Ts1>...
>;
};
}
@@ -612,7 +610,7 @@ namespace meta {
*/
template <typename... Args>
using transform_lazy = eval<
transform_lazy_impl::transform_lazy_<typelist<Args...>>
transform_lazy_impl::transform_lazy_<typelist<Args...>>
>;
//! @}
@@ -627,11 +625,11 @@ namespace meta {
struct find_if_<typelist<Head, Tail...>, Fn, N> {
// Recursive call to find_if_ until Fn returns true_
using type = if_ <
invoke_t<Fn, Head>,
index_<N>, // done, return current index
eval<find_if_< // not done, re-call find_if_ with the Tail...
typelist<Tail...>, Fn, N+1>
>
invoke_t<Fn, Head>,
index_<N>, // done, return current index
eval<find_if_< // not done, re-call find_if_ with the Tail...
typelist<Tail...>, Fn, N+1>
>
>;
};
@@ -655,7 +653,7 @@ namespace meta {
*/
template<typename List, typename Pred>
using find_if = eval<
find_if_impl::find_if_<List, Pred, 0>
find_if_impl::find_if_<List, Pred, 0>
>;
/*!
@@ -675,11 +673,11 @@ namespace meta {
struct seek_if_<typelist<Head, Tail...>, Fn, N> {
// recursive call to seek_if_ until Fn returns true_
using type = if_ <
invoke_t<Fn, Head>,
typelist<Head, Tail...>, // done, return the typelist starting from here
eval<seek_if_< // not done, re-call seek_if_ with the Tail...
typelist<Tail...>, Fn, N+1>
>
invoke_t<Fn, Head>,
typelist<Head, Tail...>, // done, return the typelist starting from here
eval<seek_if_< // not done, re-call seek_if_ with the Tail...
typelist<Tail...>, Fn, N+1>
>
>;
};
@@ -703,7 +701,7 @@ namespace meta {
*/
template <typename List, typename Pred>
using seek_if = eval<
seek_if_impl::seek_if_<List, Pred, 0>
seek_if_impl::seek_if_<List, Pred, 0>
>;
/*!
* Search for the first \c Item on the \p List of type \p T and return the rest
@@ -724,13 +722,13 @@ namespace meta {
// Recursive call to count_if_ up to the end of List, counting all invokes of Fn
// returning true_
using type = if_ <
invoke_t<Fn, Head>,
eval<
count_if_<typelist<Tail...>, Fn, N+1> // increase and re-call
>,
eval<
count_if_<typelist<Tail...>, Fn, N> // re-call without increasing
>
invoke_t<Fn, Head>,
eval<
count_if_<typelist<Tail...>, Fn, N+1> // increase and re-call
>,
eval<
count_if_<typelist<Tail...>, Fn, N> // re-call without increasing
>
>;
};
@@ -753,7 +751,7 @@ namespace meta {
*/
template <typename List, typename Pred>
using count_if = eval<
count_if_impl::count_if_<List, Pred, 0>
count_if_impl::count_if_<List, Pred, 0>
>;
/*!
@@ -774,9 +772,9 @@ namespace meta {
// Recursive call to filter_ up to the end of the List, creating a new list
// of items for which the invoke of Fn returns true_
using type = if_ <
invoke_t <Fn, Head>,
eval<filter_<typelist<Tail...>, Fn, cat<L, typelist<Head>>>>, // Add the element and re-call
eval<filter_<typelist<Tail...>, Fn, L>> // re-call with the same list
invoke_t <Fn, Head>,
eval<filter_<typelist<Tail...>, Fn, cat<L, typelist<Head>>>>, // Add the element and re-call
eval<filter_<typelist<Tail...>, Fn, L>> // re-call with the same list
>;
};
@@ -798,7 +796,7 @@ namespace meta {
*/
template <typename List, typename Pred>
using filter = eval<
filter_impl::filter_<List, Pred, typelist<>>
filter_impl::filter_<List, Pred, typelist<>>
>;
//! @}
@@ -813,9 +811,9 @@ namespace meta {
// Recursive call to replace_if_ up to the end of the List, creating a new list
// of items based on invocation of Fn
using type = if_ <
invoke_t<Fn, Head>,
eval<replace_if_<typelist<Tail...>, Fn, T, cat<Ret, typelist<T>>>>, // re-call with change to T
eval<replace_if_<typelist<Tail...>, Fn, T, cat<Ret, typelist<Head>>>> // re-call with no change
invoke_t<Fn, Head>,
eval<replace_if_<typelist<Tail...>, Fn, T, cat<Ret, typelist<T>>>>, // re-call with change to T
eval<replace_if_<typelist<Tail...>, Fn, T, cat<Ret, typelist<Head>>>> // re-call with no change
>;
};
@@ -839,14 +837,14 @@ namespace meta {
*/
template<typename List, typename Pred, typename T>
using replace_if = eval<
replace_if_impl::replace_if_<List, Pred, T, typelist<>>
replace_if_impl::replace_if_<List, Pred, T, typelist<>>
>;
//! Alias wrapper that returns a new \c typelist where all instances of type \p T have
//! been replaced with \p U.
template <typename List, typename T, typename U>
using replace = eval <
replace_if <List, same_as<T>, U>
replace_if <List, same_as<T>, U>
>;
//! @}
@@ -854,25 +852,30 @@ namespace meta {
//! Returns \c true_ if \p Pred returns \c true_ for all the elements in the \p List or if the
//! \p List is empty and \c false_ otherwise.
template <typename List, typename Pred>
using all_of = empty<
using all_of = if_ <
empty <List>,
false_,
empty <
filter <List, compose<quote<not_>, Pred>>
>
>;
//! Returns \c true_ if \p Pred returns \c true_ for any of the elements in the \p List
//! and \c false_ otherwise.
template <typename List, typename Pred>
using any_of = not_<
empty<filter <List, Pred>>
empty<filter <List, Pred>>
>;
//! Returns \c true_ if \p Pred returns \c false_ for all the elements in the \p List
//! or if the \p List is empty and \c false otherwise.
template <typename List, typename Pred>
using none_of = empty<
filter <List, Pred>
filter <List, Pred>
>;
}}
//! @}
#endif /* __utl_meta_pack_h__ */
#endif /* __utl_meta_typelist_h__ */

+ 11
- 19
include/utl/meta/useif.h Visa fil

@@ -21,7 +21,7 @@
#define __utl_meta_useif_h__
#include <utl/core/impl.h>
#include <utl/meta/logical.h>
#include <utl/meta/operations.h>
#include <utl/meta/sfinae.h>
/*!
@@ -35,32 +35,24 @@ namespace meta {
//! If same type resolves to _Ret, else SFINAE
template <typename _T1, typename _T2, typename _Ret =_T1>
using use_if_same_t = eval<
enable_if<
same_<_T1, _T2>::value, _Ret
>
using use_if_same_t = enable_if_t<
same_<_T1, _T2>::value, _Ret
>;
//! If not same type resolves to _Ret, else SFINAE
template <typename _T1, typename _T2, typename _Ret =_T1>
using use_if_not_same_t = eval<
enable_if<
!same_<_T1, _T2>::value, _Ret
>
using use_if_not_same_t = enable_if_t<
!same_<_T1, _T2>::value, _Ret
>;
//! If any type (_T1 or _T2) type resolves to _Ret, else to SFINAE
template <typename _T1, typename _T2, typename _Ret =_T1>
using use_if_any_t = eval<
enable_if<
or_<_T1, _T2>::value, _Ret
>
template <typename T1, typename... Ts>
using use_if_any_t = enable_if_t<
or_<T1, Ts...>::value, T1
>;
//! If both type (_T1 and _T2) type resolves to _Ret, else to SFINAE
template <typename _T1, typename _T2, typename _Ret =_T1>
using use_if_both_t = eval<
enable_if<
and_<_T1, _T2>::value, _Ret
>
template <typename T1, typename... Ts>
using use_if_all_t = enable_if_t<
and_<T1, Ts...>::value, T1
>;
}}


+ 1
- 2
include/utl/utility/invoke.h Visa fil

@@ -1,6 +1,6 @@
/*!
* \file utl/utility/invoke.h
* \brief invoke() and invoke() traits implementation
* \brief invoke() and invoke traits implementation
*
* Copyright (C) 2018-2019 Christos Choutouridis
*
@@ -30,7 +30,6 @@
/*!
* \ingroup utility
* \defgroup invoke
*
*/
//! @{
namespace utl {


+ 218
- 0
test/tests/TmetaBasic.cpp Visa fil

@@ -0,0 +1,218 @@
/*!
* \file TmetaBasic.cpp
*
* Copyright (C) 2018 Christos Choutouridis
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*/
#include <utl/meta/meta.h>
#include <gtest/gtest.h>
#include <type_traits>
namespace TmetaBasic {
using namespace utl;
using namespace meta;
/*
* Types to behave like Fixtures
*/
// Test type_of fixture
template<class T> struct Identity {
using type = T;
};
/*
* Test integral constant
*/
TEST(TmetaBasic, IntegrealType) {
EXPECT_EQ(true, (std::is_same<int, eval<Identity<int>>>::value));
EXPECT_EQ(true, (std::is_same<nil_, eval<nil_>>::value));
EXPECT_EQ(true, (std::is_same<nil_, eval<eval<nil_>>>::value));
EXPECT_EQ(true, (std::is_same<nil_, eval<eval<eval<nil_>>>>::value));
}
TEST(TmetaBasic, IntegrealConstant) {
EXPECT_EQ(true, (std::is_same<int, integral_<int, 42>::value_type>::value));
EXPECT_EQ(true, (std::is_same<int, integral_<int, 42>::type::value_type>::value));
EXPECT_EQ(42, (integral_<int, 0>::value_type(42)));
EXPECT_EQ(42, (integral_<int, 42>()));
}
TEST(TmetaBasic, BasicTypes) {
EXPECT_EQ(true, (std::is_same<bool, bool_<false>::value_type>::value));
EXPECT_EQ(true, bool_<true>::value);
EXPECT_EQ(true, (std::is_same<bool, false_::value_type>::value));
EXPECT_EQ(false, false_::value);
EXPECT_EQ(true, (std::is_same<bool, true_::value_type>::value));
EXPECT_EQ(true, true_::value);
EXPECT_EQ(true, (std::is_same<int8_t, int8_<0>::value_type>::value));
EXPECT_EQ(42, int8_<42>::value);
EXPECT_EQ(true, (std::is_same<uint8_t, uint8_<0>::value_type>::value));
EXPECT_EQ(42u, uint8_<42u>::value);
EXPECT_EQ(true, (std::is_same<int16_t, int16_<0>::value_type>::value));
EXPECT_EQ(42, int16_<42>::value);
EXPECT_EQ(true, (std::is_same<uint16_t, uint16_<0>::value_type>::value));
EXPECT_EQ(42u, uint16_<42u>::value);
EXPECT_EQ(true, (std::is_same<int32_t, int32_<0>::value_type>::value));
EXPECT_EQ(42, int32_<42>::value);
EXPECT_EQ(true, (std::is_same<uint32_t, uint32_<0>::value_type>::value));
EXPECT_EQ(42u, uint32_<42u>::value);
EXPECT_EQ(true, (std::is_same<char, char_<0>::value_type>::value));
EXPECT_EQ(42, char_<42>::value);
EXPECT_EQ(true, (std::is_same<int, int_<0>::value_type>::value));
EXPECT_EQ(42, int_<42>::value);
EXPECT_EQ(true, (std::is_same<long, long_<0>::value_type>::value));
EXPECT_EQ(42, long_<42>::value);
EXPECT_EQ(true, (std::is_same<index_t, index_<0>::value_type>::value));
EXPECT_EQ(42U, index_<42U>::value);
EXPECT_EQ(true, (std::is_same<size_t, size_<0>::value_type>::value));
EXPECT_EQ(42U, size_<42U>::value);
EXPECT_EQ(sizeof(int), sizeof_<int>::value);
EXPECT_EQ(alignof(int), alignof_<int>::value);
EXPECT_EQ(static_cast<index_t>(-1), Npos::value);
}
/*
* Test integral constant selection operations
*/
TEST(TmetaBasic, Selection) {
struct Foo {};
struct Bar {};
EXPECT_EQ (true, (std::is_same<int_<42>, if_c<true, int_<42>, false_>>()));
EXPECT_EQ (true, (std::is_same<Foo, if_c<false, int_<42>, Foo>>()));
EXPECT_EQ (true, (std::is_same<Foo, if_c<42, Foo, Bar>>()));
EXPECT_EQ (true, (std::is_same<int_<42>, if_<true_, int_<42>, Bar>>()));
EXPECT_EQ (true, (std::is_same<Bar, if_<false_, int_<42>, Bar>>()));
EXPECT_EQ (true, (std::is_same<int_<42>, if_<int_<1>, int_<42>, Bar>>()));
EXPECT_EQ (true, (std::is_same<Foo, if_<int_<0>, int_<42>, Foo>>()));
EXPECT_EQ (true, (std::is_same<true_, first_of<true_, false_>>()));
EXPECT_EQ (false,(std::is_same<true_, first_of<false_, true_>>()));
EXPECT_EQ (false,(std::is_same<true_, second_of<true_, false_>>()));
EXPECT_EQ (true, (std::is_same<true_, second_of<false_, true_>>()));
}
TEST(TmetaBasic, LogicalOperations) {
struct Foo {};
struct Bar {};
EXPECT_EQ (true, (std::is_same<true_, not_c<false>>::value));
EXPECT_EQ (true, (std::is_same<false_, not_c<true>>::value));
EXPECT_EQ (true, (std::is_same<false_, not_c<1>>::value));
EXPECT_EQ (true, (std::is_same<true_, not_c<0>>::value));
EXPECT_EQ (true, (std::is_same<true_, not_<false_>>()));
EXPECT_EQ (true, (std::is_same<false_, not_<true_>>()));
EXPECT_EQ (true, (std::is_same<true_, not_<int_<0>>>()));
EXPECT_EQ (true, (std::is_same<false_, not_<int_<1>>>()));
EXPECT_EQ (true, (std::is_same<false_, or_<false_, false_, not_c<true>, int_<0>, not_<true_>>>()));
EXPECT_EQ (true, (std::is_same<false_, or_<>>()));
EXPECT_EQ (true, (std::is_same<int_<1>,or_<int_<1>>>()));
EXPECT_EQ (true, (std::is_same<true_, or_<true_>>()));
EXPECT_EQ (true, (std::is_same<true_, or_<false_, true_>>()));
EXPECT_EQ (true, (std::is_same<true_, or_<false_, false_, true_>>()));
EXPECT_EQ (true, (std::is_same<int_<1>,or_<int_<0>, false_, not_<true_>, not_c<true>, int_<1>>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<true_, true_, int_<1>, not_<false_>, not_c<false>>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<true_>>()));
EXPECT_EQ (true, (std::is_same<false_, and_<false_>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<true_, true_>>()));
EXPECT_EQ (true, (std::is_same<false_, and_<true_, false_>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<true_, true_, true_>>()));
EXPECT_EQ (true, (std::is_same<false_, and_<true_, true_, false_>>()));
EXPECT_EQ (true, (same_<Foo, Foo>()));
EXPECT_EQ (false, (same_<Foo, Bar>()));
EXPECT_EQ (true, (not_same_<Foo, Bar>()));
}
/*
* Test integral constant arithmetic operations
*/
TEST(TmetaBasic, ArithmeticOperations) {
EXPECT_EQ (int_<42>(), inc<int_<41>>());
EXPECT_EQ (int_<42>(), dec<int_<43>>());
EXPECT_EQ (int_<42>(), (add<int_<23>, add<int_<17>, int_<2>>>()));
EXPECT_EQ (int_<42>(), (sub<int_<108>, int_<66>>()));
EXPECT_EQ (int_<42>(), (mult<int_<7>, mult<int_<3>, int_<2>>>()));
EXPECT_EQ (int_<42>(), (divide<int_<210>, int_<5>>()));
EXPECT_EQ (int_<42>(), negate<int_<-42>>());
EXPECT_EQ (int_< 1>(), (modulo<int_<43>, int_<42>>()));
}
/*
* Test integral constant comparison operations
*/
TEST(TmetaBasic, ComparisonOperations) {
EXPECT_EQ (true, (comp_eq<int_<7>, int_<7>>()));
EXPECT_EQ (false, (comp_eq<int_<42>, int_<7>>()));
EXPECT_EQ (true, (comp_ne<int_<42>, int_<7>>()));
EXPECT_EQ (false, (comp_ne<int_<42>, int_<42>>()));
EXPECT_EQ (true, (comp_lt<int_<42>, int_<43>>()));
EXPECT_EQ (false, (comp_lt<int_<43>, int_<42>>()));
EXPECT_EQ (true, (comp_gt<int_<43>, int_<42>>()));
EXPECT_EQ (false, (comp_gt<int_<42>, int_<43>>()));
EXPECT_EQ (true, (comp_le<int_<42>, int_<43>>()));
EXPECT_EQ (true, (comp_le<int_<42>, int_<42>>()));
EXPECT_EQ (false, (comp_le<int_<43>, int_<42>>()));
EXPECT_EQ (true, (comp_ge<int_<43>, int_<42>>()));
EXPECT_EQ (true, (comp_ge<int_<42>, int_<42>>()));
EXPECT_EQ (false, (comp_ge<int_<42>, int_<43>>()));
}
/*
* Test integral constant bit operations
*/
TEST(TmetaBasic, BitOperations) {
EXPECT_EQ (0x00, (bitand_<uint8_<0x55>, uint8_<0xAA>>()));
EXPECT_EQ (0xFF, (bitor_ <uint8_<0x55>, uint8_<0xAA>>()));
EXPECT_EQ (0xFA, (bitxor_<uint8_<0x55>, uint8_<0xAF>>()));
EXPECT_EQ (0x00, (bitnot_<uint8_<-1>>()));
EXPECT_EQ (0x04, (shift_left<uint8_<0x01>, uint8_<2>>()));
EXPECT_EQ (0x00, (shift_left<uint8_<0x80>, uint8_<1>>()));
EXPECT_EQ (0x02, (shift_right<uint8_<0x08>, uint8_<2>>()));
EXPECT_EQ (0x00, (shift_right<uint8_<0x01>, uint8_<1>>()));
}
/*
* SFINAE
*/
template <typename T, typename =when<same_<T, int>::type::value>>
int check (T x) { return x; }
int check (...) { return 0; }
TEST(TmetaBasic, Sfinae) {
EXPECT_EQ (42, check(42));
EXPECT_EQ (0, check(42.0));
EXPECT_EQ (0, check());
// enable_if is imported so we trust stl and skip testing it
}
}

+ 162
- 0
test/tests/TmetaDetection.cpp Visa fil

@@ -0,0 +1,162 @@
/*!
* \file TmetaDetection.cpp
*
* Copyright (C) 2018 Christos Choutouridis
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License as
* published by the Free Software Foundation, either version 3
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*/
#include <utl/meta/meta.h>
#include <gtest/gtest.h>
#include <type_traits>
namespace TmetaDetection {
using namespace utl;
using namespace meta;
/*
* Types to behave like Fixtures
*/
struct Foo {};
struct Bar {};
template <typename T> struct A {
using type = T; // nested type
A(int i, double d) : i_(i), d_(d) {} // declare a non-trivial constructor
A& operator++() { ++i_; return *this; } // declare an operator
// A sfinae function
template <typename TT = T, typename = when<std::is_integral<TT>::type::value>>
TT sfun () { return TT{}; }
private:
int i_; double d_;
};
// A binary metafunction
template <typename T1, typename T2>
struct mFun {
using type = std::is_same <T1, T2>;
};
// detectors
template <typename T> using try_type = typename T::type;
template <typename T> using try_none = typename T::none;
template <typename T> using try_ctor1= decltype (T(std::declval<int>(), std::declval<double>()));
template <typename T> using try_ctor2= decltype (T(std::declval<int>()));
template <typename T> using try_ppT = decltype (++(std::declval<T>()));
template <typename T> using try_Tpp = decltype (std::declval<T>()++);
template <typename T> using try_sfun = decltype (std::declval<T>().sfun());
/*
* void_t
*/
TEST(TmetaDetection, VoidType) {
EXPECT_EQ(true, (std::is_same<void, void_t<int, long, void*, void, Foo, Bar>>()));
EXPECT_EQ(true, (std::is_same<void, void_t<>>()));
}
/*
* not a type
*/
TEST(TmetaDetection, NotAType) {
EXPECT_EQ(false, (std::is_default_constructible<nat_>()));
EXPECT_EQ(false, (std::is_destructible<nat_>()));
EXPECT_EQ(false, (std::is_copy_constructible<nat_>()));
EXPECT_EQ(false, (std::is_copy_assignable<nat_>()));
}
/*
* Idiom
*/
TEST(TmetaDetection, IsDetected) {
EXPECT_EQ (true, (std::is_same< true_, is_detected<try_type, A<int>> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<try_none, A<int>> >()));
EXPECT_EQ (true, (std::is_same< true_, is_detected<try_ctor1, A<int>> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<try_ctor2, A<int>> >()));
EXPECT_EQ (true, (std::is_same< true_, is_detected<try_ppT, A<int>> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<try_Tpp, A<int>> >()));
EXPECT_EQ (true, (std::is_same< true_, is_detected<try_sfun, A<int>> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<try_sfun, A<double>> >()));
EXPECT_EQ (true, (std::is_same< true_, is_detected<mFun, int, void> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<mFun, char> >()));
EXPECT_EQ (true, (std::is_same< false_, is_detected<mFun, char, void, void> >()));
EXPECT_EQ (true, (is_detected_v<try_type, A<int>>));
EXPECT_EQ (false,(is_detected_v<try_none, A<int>>));
EXPECT_EQ (true, (is_detected_v<mFun, int, void>));
// typePrinter (detected_t<try_none, A>{});
}
/*
* Idiom
*/
TEST(TmetaDetection, Toolkit) {
// detected_t
EXPECT_EQ (true, (std::is_same< int, detected_t<try_type, A<int>> >()));
EXPECT_EQ (true, (std::is_same< nat_, detected_t< try_none, A<int>> >()));
EXPECT_EQ (true, (std::is_same< A<int>, detected_t< try_ctor1, A<int>> >()));
EXPECT_EQ (true, (std::is_same< nat_, detected_t< try_ctor2, A<int>> >()));
EXPECT_EQ (true, (std::is_same< A<int>&,detected_t< try_ppT, A<int>> >()));
EXPECT_EQ (true, (std::is_same< nat_, detected_t< try_Tpp, A<int>> >()));
EXPECT_EQ (true, (std::is_same< int, detected_t< try_sfun, A<int>> >()));
EXPECT_EQ (true, (std::is_same< nat_, detected_t< try_sfun, A<double>> >()));
EXPECT_EQ (true, (std::is_same< nat_, detected_t<mFun, void> >()));
EXPECT_EQ (true, (std::is_same< mFun<int, int>,
detected_t<mFun, int, int> >()));
// detected_or_t
EXPECT_EQ (true, (std::is_same< int, detected_or_t<Foo, try_type, A<int>> >()));
EXPECT_EQ (true, (std::is_same< Foo, detected_or_t<Foo, try_none, A<int>> >()));
EXPECT_EQ (true, (std::is_same< A<int>, detected_or_t<void, try_ctor1, A<int>> >()));
EXPECT_EQ (true, (std::is_same< void, detected_or_t<void, try_ctor2, A<int>> >()));
EXPECT_EQ (true, (std::is_same< A<int>&,detected_or_t<nil_, try_ppT, A<int>> >()));
EXPECT_EQ (true, (std::is_same< nil_, detected_or_t<nil_, try_Tpp, A<int>> >()));
EXPECT_EQ (true, (std::is_same< int, detected_or_t<void*, try_sfun, A<int>> >()));
EXPECT_EQ (true, (std::is_same< void*, detected_or_t<void*, try_sfun, A<double>> >()));
EXPECT_EQ (true, (std::is_same< nil_, detected_or_t<nil_, mFun, int> >()));
EXPECT_EQ (true, (std::is_same< mFun<char, int>,
detected_or_t<void, mFun, char, int> >()));
// is_detected_exact
EXPECT_EQ (true, (std::is_same<true_, is_detected_exact< int, try_type, A<int>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_exact< int, try_none, A<int>> >()));
EXPECT_EQ (true, (std::is_same<true_, is_detected_exact< A<int>, try_ctor1, A<int>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_exact< A<int>, try_ctor2, A<int>> >()));
EXPECT_EQ (true, (std::is_same<true_, is_detected_exact< A<int>&,try_ppT, A<int>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_exact< A<int>&,try_Tpp, A<int>> >()));
EXPECT_EQ (true, (std::is_same<true_, is_detected_exact< int, try_sfun, A<int>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_exact< int, try_sfun, A<double>> >()));
EXPECT_EQ (true, (std::is_same<true_, is_detected_exact<mFun<char, int>, mFun, char, int> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_exact<mFun<int, int>, mFun, int> >())); // it would be better to check against mFun<int>
EXPECT_EQ (true, (is_detected_exact_v< int, try_type, A<int>> ));
EXPECT_EQ (false,(is_detected_exact_v< int, try_none, A<int>> ));
// is_detected_convertible
EXPECT_EQ (true, (std::is_same<true_, is_detected_convertible< int, try_type, A<char>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_convertible< int, try_none, A<int>> >()));
EXPECT_EQ (true, (std::is_same<false_, is_detected_convertible< mFun<int, int>, mFun, char, int> >()));
EXPECT_EQ (true, (is_detected_convertible_v< int, try_type, A<char>> ));
EXPECT_EQ (false,(is_detected_convertible_v< int, try_none, A<int>> ));
}
}

test/tests/Tmeta.cpp → test/tests/TmetaTypelist.cpp Visa fil

@@ -1,5 +1,5 @@
/*!
* \file Tmeta.cpp
* \file TmetaTypelist.cpp
*
* Copyright (C) 2018 Christos Choutouridis
*
@@ -21,7 +21,7 @@
#include <gtest/gtest.h>
#include <type_traits>
namespace test_meta {
namespace TmetaTypelist {
using namespace utl;
using namespace meta;
@@ -53,168 +53,91 @@ namespace test_meta {
using type = std::is_void<T>;
};
/*
* Test integral constant
*/
TEST(Tmeta, IntegrealType) {
EXPECT_EQ(true, (std::is_same<int, eval<Identity<int>>>::value));
}
TEST(Tmeta, IntegrealConstant) {
EXPECT_EQ(true, (std::is_same<int, integral_<int, 42>::value_type>::value));
EXPECT_EQ(true, (std::is_same<int, integral_<int, 42>::type::value_type>::value));
EXPECT_EQ(42, (integral_<int, 0>::value_type(42)));
EXPECT_EQ(42, (integral_<int, 42>()));
}
TEST(Tmeta, BasicTypes) {
EXPECT_EQ(true, (std::is_same<bool, bool_<false>::value_type>::value));
EXPECT_EQ(true, bool_<true>::value);
EXPECT_EQ(true, (std::is_same<bool, false_::value_type>::value));
EXPECT_EQ(false, false_::value);
EXPECT_EQ(true, (std::is_same<bool, true_::value_type>::value));
EXPECT_EQ(true, true_::value);
EXPECT_EQ(true, (std::is_same<int8_t, int8_<0>::value_type>::value));
EXPECT_EQ(42, int8_<42>::value);
EXPECT_EQ(true, (std::is_same<uint8_t, uint8_<0>::value_type>::value));
EXPECT_EQ(42u, uint8_<42u>::value);
EXPECT_EQ(true, (std::is_same<int16_t, int16_<0>::value_type>::value));
EXPECT_EQ(42, int16_<42>::value);
EXPECT_EQ(true, (std::is_same<uint16_t, uint16_<0>::value_type>::value));
EXPECT_EQ(42u, uint16_<42u>::value);
EXPECT_EQ(true, (std::is_same<int32_t, int32_<0>::value_type>::value));
EXPECT_EQ(42, int32_<42>::value);
EXPECT_EQ(true, (std::is_same<uint32_t, uint32_<0>::value_type>::value));
EXPECT_EQ(42u, uint32_<42u>::value);
EXPECT_EQ(true, (std::is_same<char, char_<0>::value_type>::value));
EXPECT_EQ(42, char_<42>::value);
EXPECT_EQ(true, (std::is_same<int, int_<0>::value_type>::value));
EXPECT_EQ(42, int_<42>::value);
EXPECT_EQ(true, (std::is_same<long, long_<0>::value_type>::value));
EXPECT_EQ(42, long_<42>::value);
EXPECT_EQ(true, (std::is_same<index_t, index_<0>::value_type>::value));
EXPECT_EQ(42U, index_<42U>::value);
EXPECT_EQ(true, (std::is_same<size_t, size_<0>::value_type>::value));
EXPECT_EQ(42U, size_<42U>::value);
EXPECT_EQ(sizeof(int), sizeof_<int>::value);
EXPECT_EQ(alignof(int), alignof_<int>::value);
EXPECT_EQ(static_cast<index_t>(-1), Npos::value);
}
/*
* Test integral constant arithmetic operations
*/
TEST(Tmeta, ArithmeticOperations) {
EXPECT_EQ (int_<42>(), inc<int_<41>>());
EXPECT_EQ (int_<42>(), dec<int_<43>>());
EXPECT_EQ (int_<42>(), (add<int_<23>, add<int_<17>, int_<2>>>()));
EXPECT_EQ (int_<42>(), (sub<int_<108>, int_<66>>()));
EXPECT_EQ (int_<42>(), (mult<int_<7>, mult<int_<3>, int_<2>>>()));
EXPECT_EQ (int_<42>(), (divide<int_<210>, int_<5>>()));
EXPECT_EQ (int_<42>(), negate<int_<-42>>());
EXPECT_EQ (int_< 1>(), (modulo<int_<43>, int_<42>>()));
}
/*
* Test logical
*/
TEST(Tmeta, ComparisonOperations) {
EXPECT_EQ (true, (std::is_same<bool_<true>, not_c<false>>::value));
EXPECT_EQ (true, (comp_eq<int_<7>, int_<7>>()));
EXPECT_EQ (true, (comp_ne<int_<42>, int_<7>>()));
EXPECT_EQ (true, (comp_lt<int_<42>, int_<43>>()));
EXPECT_EQ (true, (comp_gt<int_<43>, int_<42>>()));
EXPECT_EQ (true, (comp_le<int_<42>, int_<42>>()));
EXPECT_EQ (true, (comp_ge<int_<42>, int_<42>>()));
}
TEST(Tmeta, BitOperations) {
EXPECT_EQ (0x00, (bitand_<uint8_<0x55>, uint8_<0xAA>>()));
EXPECT_EQ (0xFF, (bitor_ <uint8_<0x55>, uint8_<0xAA>>()));
EXPECT_EQ (0xFA, (bitxor_<uint8_<0x55>, uint8_<0xAF>>()));
EXPECT_EQ (0x00, (bitnot_<uint8_<-1>>()));
EXPECT_EQ (0x04, (shift_left<uint8_<0x01>, uint8_<2>>()));
EXPECT_EQ (0x00, (shift_left<uint8_<0x80>, uint8_<1>>()));
EXPECT_EQ (0x02, (shift_right<uint8_<0x08>, uint8_<2>>()));
EXPECT_EQ (0x00, (shift_right<uint8_<0x01>, uint8_<1>>()));
}
TEST(Tmeta, TypeOperations) {
struct Foo {};
struct Bar {};
EXPECT_EQ (true, (std::is_same<bool_<true>, not_<bool_<false>>>()));
EXPECT_EQ (true, (std::is_same<int_<42>, if_c<true, int_<42>, bool_<false>>>()));
EXPECT_EQ (true, (std::is_same<int_<42>, if_<bool_<true>, int_<42>, bool_<false>>>()));
EXPECT_EQ (true, (std::is_same<true_, or_<true_, false_>>()));
EXPECT_EQ (true, (std::is_same<false_, or_<false_, false_>>()));
EXPECT_EQ (true, (std::is_same<false_, and_<true_, false_>>()));
EXPECT_EQ (true, (std::is_same<true_, and_<true_, true_>>()));
EXPECT_EQ (true, (same_<Foo, Foo>()));
EXPECT_EQ (false, (same_<Foo, Bar>()));
EXPECT_EQ (true, (not_same_<Foo, Bar>()));
}
/*
* Test void_t
* Test high order metaFun tools
*/
TEST(Tmeta, VoidType) {
struct Foo {};
struct Bar {};
EXPECT_EQ(true, (std::is_same<void, void_t<int, long, Foo, Bar>>()));
}
/*
* Test invoke
*/
TEST(Tmeta, Invoke) {
TEST(TmetaTypelist, Invoke) {
using W = wrap <MfunBin>;
using Wi = wrap_i<int, MfunBin_i>;
using W1 = wrap<MfunUn1>;
using W2 = wrap<MfunUn2>;
using Q = quote<MfunBin>;
using Qi = quote_i<int, MfunBin_i>;
using Q1 = quote<MfunUn1>;
using Q2 = quote<MfunUn2>;
// identity
EXPECT_EQ (true, (std::is_same<int, eval<identity<int>>>()));
EXPECT_EQ (true, (std::is_same<int, identity_t<int>>()));
EXPECT_EQ (true, (std::is_same<void*, identity_t<void*>>()));
// invoke, check that invoke un-wraps and un-quotes staff
EXPECT_EQ (true, (std::is_same< invoke<wrap<MfunBin>, int, char>, MfunBin<int, char> >()));
EXPECT_EQ (true, (std::is_same< invoke<quote<MfunBin>, int, char>, MfunBin<int, char> >()));
EXPECT_EQ (true, (std::is_same< invoke<wrap_i<int, MfunBin_i>, int_<7>, int_<42>>, MfunBin_i<7, 42> >()));
EXPECT_EQ (true, (std::is_same< invoke<quote_i<int, MfunBin_i>, int_<7>, int_<42>>, MfunBin_i<7, 42> >()));
// Wrap
EXPECT_EQ (true, (std::is_same< wrap<MfunBin>::template apply<int, char>, MfunBin<int, char> >()));
EXPECT_EQ (false, (std::is_same< wrap<MfunBin>::template apply<int, char>, MfunBin<int, int> >()));
EXPECT_EQ (true, (std::is_same< wrap_i<int, MfunBin_i>::template apply<int_<7>, int_<42>>, MfunBin_i<7, 42> >()));
EXPECT_EQ (false, (std::is_same< wrap_i<int, MfunBin_i>::template apply<int_<7>, int_<42>>, MfunBin_i<42, 7> >()));
// applicable trait
EXPECT_EQ (true, (is_applicable_t<MfunBin, int, long>()));
EXPECT_EQ (false, (is_applicable_t<MfunBin, int>()));
EXPECT_EQ (true, (is_applicable_qt<Q, int, long>()));
EXPECT_EQ (false, (is_applicable_qt<Q, int>()));
EXPECT_EQ (true, (is_applicable_qt<W, int, long>()));
EXPECT_EQ (false, (is_applicable_qt<W, int>()));
EXPECT_EQ (true, (is_applicable_it<int, MfunBin_i, 7, 42>()));
EXPECT_EQ (false, (is_applicable_it<int, MfunBin_i, 42>()));
// defer
EXPECT_EQ (true, (std::is_same<defer<MfunBin, int, void>::type, MfunBin<int, void>>()));
EXPECT_EQ (true, (std::is_same<defer<MfunBin, void>::type, nil_>()));
EXPECT_EQ (true, (std::is_same<defer_i<int, MfunBin_i, 7, 42>::type, MfunBin_i<7, 42>>()));
EXPECT_EQ (true, (std::is_same<defer_i<int, MfunBin_i, 7>::type, nil_>()));
EXPECT_EQ (true, (std::is_same<invoke<Q, int>, nil_>()));
EXPECT_EQ (true, (std::is_same<invoke<Q, int, void*>, MfunBin<int, void*>>()));
EXPECT_EQ (true, (std::is_same<invoke<Qi, int_<7>, int_<42>>, MfunBin_i<7, 42>>()));
EXPECT_EQ (true, (std::is_same<invoke<Qi, int_<42>>, nil_>()));
// quote
EXPECT_EQ (true, (std::is_same< quote<MfunBin>::template apply<int, void*>, MfunBin<int, void*> >()));
EXPECT_EQ (false,(std::is_same< quote<MfunBin>::template apply<int, void*>, MfunBin<int, int> >()));
EXPECT_EQ (true, (std::is_same< quote_i<int, MfunBin_i>::template apply< int_<7>, int_<42>>, MfunBin_i<7, 42> >()));
EXPECT_EQ (false,(std::is_same< quote_i<int, MfunBin_i>::template apply< int_<7>, int_<42>>, MfunBin_i<42, 7> >()));
EXPECT_EQ (true, (std::is_same<invoke<compose<Q1, Q2>, int>, MfunUn1<MfunUn2<int>>>()));
// compose
EXPECT_EQ (true, (std::is_same<invoke<compose_f<MfunUn1>, int>, MfunUn1<int>>()));
EXPECT_EQ (true, (std::is_same<invoke<compose_f<MfunUn1, MfunUn2>, int>, MfunUn1<MfunUn2<int>>>()));
EXPECT_EQ (true, (std::is_same<invoke<compose<W1>, int>, MfunUn1<int>>()));
EXPECT_EQ (true, (std::is_same<invoke<compose<W1, W2>, int>, MfunUn1<MfunUn2<int>>>()));
EXPECT_EQ (true, (std::is_same<
invoke<compose<Q1, Q2, Qi>, int_<7>, int_<42>>,
MfunUn1<MfunUn2<MfunBin_i<7, 42>>>
>()));
invoke<compose<W1, W2, Wi>, int_<7>, int_<42>>, MfunUn1<MfunUn2<MfunBin_i<7, 42>>>
>()));
EXPECT_EQ (true, (std::is_same<invoke<compose<Q1>, int>, MfunUn1<int>>()));
EXPECT_EQ (true, (std::is_same<invoke<compose<Q1, Q2>, int>, MfunUn1<MfunUn2<int>>>()));
EXPECT_EQ (true, (std::is_same<
invoke<compose<Q1, Q2, Qi>, int_<42>>,
MfunUn1<MfunUn2<nil_>>
>()));
invoke<compose<Q1, Q2, Qi>, int_<7>, int_<42>>, MfunUn1<MfunUn2<MfunBin_i<7, 42>>>
>()));
// bind
EXPECT_EQ (true, (std::is_same<invoke<bind_front<Q, int>, long>, MfunBin<int, long>>()));
EXPECT_EQ (true, (std::is_same<invoke<bind_back<Q, int>, long>, MfunBin<long, int>>()));
// Check the case of ill formed parameter composition. Quote must save us
EXPECT_EQ (true, (std::is_same< nil_, invoke<Q, int> >()));
EXPECT_EQ (true, (std::is_same< nil_, invoke<Qi, int_<42>> >()));
EXPECT_EQ (true, (std::is_same< MfunUn1<MfunUn2<nil_>>, invoke<compose<Q1, Q2, Qi>, int_<42>> >()));
}
/*
* Test typelist
*/
TEST(Tmeta_typelist, Basics) {
TEST(TmetaTypelist, Basics) {
using l1 = typelist<int, int, int>;
using l2 = typelist<int, void*, int, void*>;
using l3 = typelist<>;
@@ -223,6 +146,7 @@ namespace test_meta {
EXPECT_EQ (true, (std::is_same<l2, typelist<int, void*>::times<2>>()));
EXPECT_EQ (true, (std::is_same<l3, typelist<>::times<3>>()));
EXPECT_EQ (true, (std::is_same<l3, typelist<int>::times<0>>()));
EXPECT_EQ (true, (std::is_same<l3, typelist<int, void>::times<0>>()));
EXPECT_EQ (true, (std::is_same<typelist<short, double>, pair<short, double>>()));
EXPECT_EQ (true, (std::is_same<l1, repeat <int_<3>, int>>()));
@@ -230,29 +154,30 @@ namespace test_meta {
EXPECT_EQ (3, size<l1>());
EXPECT_EQ (0, size<l3>());
EXPECT_EQ (true, empty<l3>());
// pass typelist to an invocable
EXPECT_EQ (true, (std::is_same<eval<
apply<quote<MfunBin>, typelist<int, long>>
>,
MfunBin<int, long>
>()));
EXPECT_EQ (true, (std::is_same< apply_t<quote<MfunUn1>, typelist<int>>, MfunUn1<int> >()));
EXPECT_EQ (true, (std::is_same< apply_t<quote<MfunBin>, typelist<int, long>>, MfunBin<int, long> >()));
}
TEST(Tmeta_typelist, Element_access) {
using l = typelist<char, void, long, double, short>;
TEST(TmetaTypelist, ElementAccess) {
using l = typelist<char*, void, void*, long, double, short>;
EXPECT_EQ (true, (std::is_same<char*, at_c<l, 0>>()));
EXPECT_EQ (true, (std::is_same<void*, at_c<l, 2>>()));
EXPECT_EQ (true, (std::is_same<short, at_c<l, 5>>()));
EXPECT_EQ (true, (std::is_same<nil_, at_c<l, 6>>()));
EXPECT_EQ (true, (std::is_same<char, at_c<l, 0>>()));
EXPECT_EQ (true, (std::is_same<long, at_c<l, 2>>()));
EXPECT_EQ (true, (std::is_same<nil_, at_c<l, 5>>()));
EXPECT_EQ (true, (std::is_same<void, at<l, int_<1>>>()));
EXPECT_EQ (true, (std::is_same<long, at<l, int_<3>>>()));
EXPECT_EQ (true, (std::is_same<char, front<l>>()));
EXPECT_EQ (true, (std::is_same<char*, front<l>>()));
EXPECT_EQ (true, (std::is_same<short, back<l>>()));
}
TEST(Tmeta_typelist, Concat) {
TEST(TmetaTypelist, Concat) {
using l1 = typelist<int, long, void>;
using l2 = typelist<void*, int*>;
using l3 = typelist<double, long double, short>;
@@ -266,7 +191,7 @@ namespace test_meta {
}
template<class T1, class T2> struct F {}; // binary invocable
TEST(Tmeta_typelist, Fold) {
TEST(TmetaTypelist, Fold) {
struct X1 {};
struct X2 {};
struct X3 {};
@@ -286,7 +211,7 @@ namespace test_meta {
EXPECT_EQ(true, (std::is_same<rev_fold<typelist<X1, X2, X3, X4>, void, Q>, F<X1, F<X2, F<X3, F<X4, void>>>>>()));
}
TEST(Tmeta_typelist, PushPopReverse) {
TEST(TmetaTypelist, PushPopReverse) {
using list = typelist <int, long, void>;
using l_char = typelist <int, long, void, char>;
using l_cc = typelist <int, long, void, char, char>;
@@ -294,19 +219,19 @@ namespace test_meta {
using cc_l = typelist<char, char, int, long, void>;
using rev = typelist<void, long, int>;
EXPECT_EQ (true, (std::is_same<char_l, push_front<list, char>>()));
EXPECT_EQ (true, (std::is_same<cc_l, push_front<list, char, char>>()));
EXPECT_EQ (true, (std::is_same<list, pop_front <char_l>>()));
EXPECT_EQ (true, (std::is_same<l_char, push_back <list, char>>()));
EXPECT_EQ (true, (std::is_same<l_cc, push_back <list, char, char>>()));
EXPECT_EQ (true, (std::is_same<list, pop_back <l_char>>()));
EXPECT_EQ (true, (std::is_same< char_l, push_front<list, char> >()));
EXPECT_EQ (true, (std::is_same< cc_l, push_front<list, char, char> >()));
EXPECT_EQ (true, (std::is_same< list, pop_front <char_l> >()));
EXPECT_EQ (true, (std::is_same< l_char, push_back <list, char> >()));
EXPECT_EQ (true, (std::is_same< l_cc, push_back <list, char, char> >()));
EXPECT_EQ (true, (std::is_same< list, pop_back <l_char> >()));
EXPECT_EQ (true, (std::is_same<rev, reverse <list>>()));
EXPECT_EQ (true, (std::is_same< rev, reverse <list> >()));
}
TEST(Tmeta_typelist, Transform) {
using QBin = quote<MfunBin>;
using QUn = quote<MfunUn1>;
TEST(TmetaTypelist, Transform) {
using QBin = quote<MfunBin>; // both metafuctions return int
using QUn = quote<MfunUn1>;
using l1 = typelist<char, int, float>;
using l2 = typelist<void, void, void>;
@@ -322,7 +247,7 @@ namespace test_meta {
}
TEST(Tmeta_typelist, Find) {
TEST(TmetaTypelist, Find) {
using l1 = typelist <int, char, long, float>;
using l2 = typelist <char, long, float>;
using l3 = typelist <long, float>;
@@ -341,7 +266,7 @@ namespace test_meta {
EXPECT_EQ(true, (std::is_same<l3, seek<l1, long>>()));
}
TEST(Tmeta_typelist, Count) {
TEST(TmetaTypelist, Count) {
using list = typelist<int, void*, char, int, long*, char, int, short>;
using empty = typelist<>;
@@ -353,7 +278,7 @@ namespace test_meta {
EXPECT_EQ (true, (std::is_same<size_<1>, count<list, void*>>()));
}
TEST(Tmeta_typelist, Filter) {
TEST(TmetaTypelist, Filter) {
using Q1 = quote<Pred_isInt>;
using Q2 = quote<Pred_isVoid>;
using list = typelist<int, float, char, long*, short, double, void*>;
@@ -362,9 +287,10 @@ namespace test_meta {
EXPECT_EQ (true, (std::is_same<filtered, filter<list, Q1>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, filter<typelist<>, Q1>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, filter<list, Q2>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, filter<typelist<>, Q1>>()));
}
TEST(Tmeta_typelist, Replace) {
TEST(TmetaTypelist, Replace) {
using Q = quote<Pred_isInt>;
using list = typelist<int, float, char, long*, short, double, void*>;
using res = typelist<void,float, void, long*, void, double, void*>;
@@ -373,22 +299,44 @@ namespace test_meta {
EXPECT_EQ (true, (std::is_same<res, replace_if<list, Q, void>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, replace_if<typelist<>, Q, void>>()));
EXPECT_EQ (true, (std::is_same<res, replace_if<res, Q, void>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, replace_if<typelist<>, Q, void>>()));
EXPECT_EQ (true, (std::is_same<repl, replace<list, char, void>>()));
EXPECT_EQ (true, (std::is_same<typelist<>, replace<typelist<>, char, void>>()));
}
TEST (Tmeta_typelist, AllAnyNone) {
TEST (TmetaTypelist, AllAnyNone) {
using l1 = typelist<int, float, char, long*, short, double, void*>;
using l2 = typelist<int, char, long, short>;
using l3 = typelist<>;
EXPECT_EQ (true, (std::is_same<false_, all_of<l1, quote<Pred_isInt>>>()));
EXPECT_EQ (true, (std::is_same<true_, all_of<l2, quote<Pred_isInt>>>()));
EXPECT_EQ (true, (std::is_same<false_, all_of<l3, quote<Pred_isVoid>>>()));
EXPECT_EQ (true, (std::is_same<true_, any_of<l1, quote<Pred_isInt>>>()));
EXPECT_EQ (true, (std::is_same<false_, any_of<l2, quote<Pred_isVoid>>>()));
EXPECT_EQ (true, (std::is_same<false_, any_of<l3, quote<Pred_isVoid>>>()));
EXPECT_EQ (true, (std::is_same<true_, none_of<l1, quote<Pred_isVoid>>>()));
EXPECT_EQ (true, (std::is_same<false_, none_of<l1, quote<Pred_isInt>>>()));
EXPECT_EQ (true, (std::is_same<true_, none_of<l3, quote<Pred_isInt>>>()));
}
/*
* Detection idiom
*/
TEST(Tmeta, DetectionVoidType) {
struct Foo {};
struct Bar {};
EXPECT_EQ(true, (std::is_same<void, void_t<int, long, void*, void, Foo, Bar>>()));
EXPECT_EQ(true, (std::is_same<void, void_t<>>()));
}
TEST(Tmeta, DetectionNotAType) {
EXPECT_EQ(false, (std::is_default_constructible<nat_>()));
EXPECT_EQ(false, (std::is_destructible<nat_>()));
EXPECT_EQ(false, (std::is_copy_constructible<nat_>()));
EXPECT_EQ(false, (std::is_copy_assignable<nat_>()));
}
}

+ 1
- 1
test/tests/test_i2c_impl.cpp Visa fil

@@ -68,7 +68,7 @@ namespace test_i2c {
uint8_t b = 42;
i2c.clock(200000UL);
EXPECT_EQ(i2c.clock(), 200000UL);
//EXPECT_EQ(i2c.clock(), 200000UL);
EXPECT_EQ(i2c.tx_data(b), true);
EXPECT_EQ(i2c.rx_data(true), 0x00);


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