src/tint/utils/slice.h - tint - Git at Google

 // Copyright 2023 The Tint Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 #ifndef SRC_TINT_UTILS_SLICE_H_
 #define SRC_TINT_UTILS_SLICE_H_

 #include <cstdint>
 #include <iterator>

 #include "src/tint/castable.h"
 #include "src/tint/traits.h"
 #include "src/tint/utils/bitcast.h"

 namespace tint::utils {

 /// A type used to indicate an empty array.
 struct EmptyType {};

 /// An instance of the EmptyType.
 static constexpr EmptyType Empty;

 /// Mode enumerator for ReinterpretSlice
 enum class ReinterpretMode {
     /// Only upcasts of pointers are permitted
     kSafe,
     /// Potentially unsafe downcasts of pointers are also permitted
     kUnsafe,
 };

 namespace detail {

 template <typename TO, typename FROM>
 static constexpr bool ConstRemoved = std::is_const_v<FROM> && !std::is_const_v<TO>;

 /// Private implementation of tint::utils::CanReinterpretSlice.
 /// Specialized for the case of TO equal to FROM, which is the common case, and avoids inspection of
 /// the base classes, which can be troublesome if the slice is of an incomplete type.
 template <ReinterpretMode MODE, typename TO, typename FROM>
 struct CanReinterpretSlice {
   private:
     using TO_EL = std::remove_pointer_t<std::decay_t<TO>>;
     using FROM_EL = std::remove_pointer_t<std::decay_t<FROM>>;

   public:
     /// @see utils::CanReinterpretSlice
     static constexpr bool value =
         // const can only be applied, not removed
         !ConstRemoved<TO, FROM> &&

         // Both TO and FROM are the same type (ignoring const)
         (std::is_same_v<std::remove_const_t<TO>, std::remove_const_t<FROM>> ||

          // Both TO and FROM are pointers...
          ((std::is_pointer_v<TO> && std::is_pointer_v<FROM>)&&

           // const can only be applied to element type, not removed
           !ConstRemoved<TO_EL, FROM_EL> &&

           // Either:
           // * Both the pointer elements are of the same type (ignoring const)
           // * Both the pointer elements are both Castable, and MODE is kUnsafe, or FROM is of,
           // or
           //   derives from TO
           (std::is_same_v<std::remove_const_t<FROM_EL>, std::remove_const_t<TO_EL>> ||
            (IsCastable<FROM_EL, TO_EL> &&
             (MODE == ReinterpretMode::kUnsafe || traits::IsTypeOrDerived<FROM_EL, TO_EL>)))));
 };

 /// Specialization of 'CanReinterpretSlice' for when TO and FROM are equal types.
 template <typename T, ReinterpretMode MODE>
 struct CanReinterpretSlice<MODE, T, T> {
     /// Always `true` as TO and FROM are the same type.
     static constexpr bool value = true;
 };

 }  // namespace detail

 /// Evaluates whether a `Slice<FROM>` and be reinterpreted as a `Slice<TO>`.
 /// Slices can be reinterpreted if:
 ///  * TO has the same or more 'constness' than FROM.
 ///  * And either:
 ///  * `FROM` and `TO` are pointers to the same type
 ///  * `FROM` and `TO` are pointers to CastableBase (or derived), and the pointee type of `TO` is of
 ///     the same type as, or is an ancestor of the pointee type of `FROM`.
 template <ReinterpretMode MODE, typename TO, typename FROM>
 static constexpr bool CanReinterpretSlice = detail::CanReinterpretSlice<MODE, TO, FROM>::value;

 /// A slice represents a contigious array of elements of type T.
 template <typename T>
 struct Slice {
     /// Type of `T`.
     using value_type = T;

     /// The pointer to the first element in the slice
     T* data = nullptr;

     /// The total number of elements in the slice
     size_t len = 0;

     /// The total capacity of the backing store for the slice
     size_t cap = 0;

     /// Constructor
     Slice() = default;

     /// Constructor
     Slice(EmptyType) {}  // NOLINT

     /// Constructor
     /// @param d pointer to the first element in the slice
     /// @param l total number of elements in the slice
     /// @param c total capacity of the backing store for the slice
     Slice(T* d, size_t l, size_t c) : data(d), len(l), cap(c) {}

     /// Constructor
     /// @param elements c-array of elements
     template <size_t N>
     Slice(T (&elements)[N])  // NOLINT
         : data(elements), len(N), cap(N) {}

     /// Reinterprets this slice as `const Slice<TO>&`
     /// @returns the reinterpreted slice
     /// @see CanReinterpretSlice
     template <typename TO, ReinterpretMode MODE = ReinterpretMode::kSafe>
     const Slice<TO>& Reinterpret() const {
         static_assert(CanReinterpretSlice<MODE, TO, T>);
         return *Bitcast<const Slice<TO>*>(this);
     }

     /// Reinterprets this slice as `Slice<TO>&`
     /// @returns the reinterpreted slice
     /// @see CanReinterpretSlice
     template <typename TO, ReinterpretMode MODE = ReinterpretMode::kSafe>
     Slice<TO>& Reinterpret() {
         static_assert(CanReinterpretSlice<MODE, TO, T>);
         return *Bitcast<Slice<TO>*>(this);
     }

     /// @return true if the slice length is zero
     bool IsEmpty() const { return len == 0; }

     /// Index operator
     /// @param i the element index. Must be less than `len`.
     /// @returns a reference to the i'th element.
     T& operator[](size_t i) { return data[i]; }

     /// Index operator
     /// @param i the element index. Must be less than `len`.
     /// @returns a reference to the i'th element.
     const T& operator[](size_t i) const { return data[i]; }

     /// @returns a reference to the first element in the vector
     T& Front() { return data[0]; }

     /// @returns a reference to the first element in the vector
     const T& Front() const { return data[0]; }

     /// @returns a reference to the last element in the vector
     T& Back() { return data[len - 1]; }

     /// @returns a reference to the last element in the vector
     const T& Back() const { return data[len - 1]; }

     /// @returns a pointer to the first element in the vector
     T* begin() { return data; }

     /// @returns a pointer to the first element in the vector
     const T* begin() const { return data; }

     /// @returns a pointer to one past the last element in the vector
     T* end() { return data + len; }

     /// @returns a pointer to one past the last element in the vector
     const T* end() const { return data + len; }

     /// @returns a reverse iterator starting with the last element in the vector
     auto rbegin() { return std::reverse_iterator<T*>(end()); }

     /// @returns a reverse iterator starting with the last element in the vector
     auto rbegin() const { return std::reverse_iterator<const T*>(end()); }

     /// @returns the end for a reverse iterator
     auto rend() { return std::reverse_iterator<T*>(begin()); }

     /// @returns the end for a reverse iterator
     auto rend() const { return std::reverse_iterator<const T*>(begin()); }
 };

 /// Deduction guide for Slice from c-array
 template <typename T, size_t N>
 Slice(T (&elements)[N]) -> Slice<T>;

 }  // namespace tint::utils

 #endif  // SRC_TINT_UTILS_SLICE_H_
	// Copyright 2023 The Tint Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	#ifndef SRC_TINT_UTILS_SLICE_H_
	#define SRC_TINT_UTILS_SLICE_H_

	#include <cstdint>
	#include <iterator>

	#include "src/tint/castable.h"
	#include "src/tint/traits.h"
	#include "src/tint/utils/bitcast.h"

	namespace tint::utils {

	/// A type used to indicate an empty array.
	struct EmptyType {};

	/// An instance of the EmptyType.
	static constexpr EmptyType Empty;

	/// Mode enumerator for ReinterpretSlice
	enum class ReinterpretMode {
	/// Only upcasts of pointers are permitted
	kSafe,
	/// Potentially unsafe downcasts of pointers are also permitted
	kUnsafe,
	};

	namespace detail {

	template <typename TO, typename FROM>
	static constexpr bool ConstRemoved = std::is_const_v<FROM> && !std::is_const_v<TO>;

	/// Private implementation of tint::utils::CanReinterpretSlice.
	/// Specialized for the case of TO equal to FROM, which is the common case, and avoids inspection of
	/// the base classes, which can be troublesome if the slice is of an incomplete type.
	template <ReinterpretMode MODE, typename TO, typename FROM>
	struct CanReinterpretSlice {
	private:
	using TO_EL = std::remove_pointer_t<std::decay_t<TO>>;
	using FROM_EL = std::remove_pointer_t<std::decay_t<FROM>>;

	public:
	/// @see utils::CanReinterpretSlice
	static constexpr bool value =
	// const can only be applied, not removed
	!ConstRemoved<TO, FROM> &&

	// Both TO and FROM are the same type (ignoring const)
	(std::is_same_v<std::remove_const_t<TO>, std::remove_const_t<FROM>> \|\|

	// Both TO and FROM are pointers...
	((std::is_pointer_v<TO> && std::is_pointer_v<FROM>)&&

	// const can only be applied to element type, not removed
	!ConstRemoved<TO_EL, FROM_EL> &&

	// Either:
	// * Both the pointer elements are of the same type (ignoring const)
	// * Both the pointer elements are both Castable, and MODE is kUnsafe, or FROM is of,
	// or
	// derives from TO
	(std::is_same_v<std::remove_const_t<FROM_EL>, std::remove_const_t<TO_EL>> \|\|
	(IsCastable<FROM_EL, TO_EL> &&
	(MODE == ReinterpretMode::kUnsafe \|\| traits::IsTypeOrDerived<FROM_EL, TO_EL>)))));
	};

	/// Specialization of 'CanReinterpretSlice' for when TO and FROM are equal types.
	template <typename T, ReinterpretMode MODE>
	struct CanReinterpretSlice<MODE, T, T> {
	/// Always `true` as TO and FROM are the same type.
	static constexpr bool value = true;
	};

	} // namespace detail

	/// Evaluates whether a `Slice<FROM>` and be reinterpreted as a `Slice<TO>`.
	/// Slices can be reinterpreted if:
	/// * TO has the same or more 'constness' than FROM.
	/// * And either:
	/// * `FROM` and `TO` are pointers to the same type
	/// * `FROM` and `TO` are pointers to CastableBase (or derived), and the pointee type of `TO` is of
	/// the same type as, or is an ancestor of the pointee type of `FROM`.
	template <ReinterpretMode MODE, typename TO, typename FROM>
	static constexpr bool CanReinterpretSlice = detail::CanReinterpretSlice<MODE, TO, FROM>::value;

	/// A slice represents a contigious array of elements of type T.
	template <typename T>
	struct Slice {
	/// Type of `T`.
	using value_type = T;

	/// The pointer to the first element in the slice
	T* data = nullptr;

	/// The total number of elements in the slice
	size_t len = 0;

	/// The total capacity of the backing store for the slice
	size_t cap = 0;

	/// Constructor
	Slice() = default;

	/// Constructor
	Slice(EmptyType) {} // NOLINT

	/// Constructor
	/// @param d pointer to the first element in the slice
	/// @param l total number of elements in the slice
	/// @param c total capacity of the backing store for the slice
	Slice(T* d, size_t l, size_t c) : data(d), len(l), cap(c) {}

	/// Constructor
	/// @param elements c-array of elements
	template <size_t N>
	Slice(T (&elements)[N]) // NOLINT
	: data(elements), len(N), cap(N) {}

	/// Reinterprets this slice as `const Slice<TO>&`
	/// @returns the reinterpreted slice
	/// @see CanReinterpretSlice
	template <typename TO, ReinterpretMode MODE = ReinterpretMode::kSafe>
	const Slice<TO>& Reinterpret() const {
	static_assert(CanReinterpretSlice<MODE, TO, T>);
	return Bitcast<const Slice<TO>>(this);
	}

	/// Reinterprets this slice as `Slice<TO>&`
	/// @returns the reinterpreted slice
	/// @see CanReinterpretSlice
	template <typename TO, ReinterpretMode MODE = ReinterpretMode::kSafe>
	Slice<TO>& Reinterpret() {
	static_assert(CanReinterpretSlice<MODE, TO, T>);
	return Bitcast<Slice<TO>>(this);
	}

	/// @return true if the slice length is zero
	bool IsEmpty() const { return len == 0; }

	/// Index operator
	/// @param i the element index. Must be less than `len`.
	/// @returns a reference to the i'th element.
	T& operator[](size_t i) { return data[i]; }

	/// Index operator
	/// @param i the element index. Must be less than `len`.
	/// @returns a reference to the i'th element.
	const T& operator[](size_t i) const { return data[i]; }

	/// @returns a reference to the first element in the vector
	T& Front() { return data[0]; }

	/// @returns a reference to the first element in the vector
	const T& Front() const { return data[0]; }

	/// @returns a reference to the last element in the vector
	T& Back() { return data[len - 1]; }

	/// @returns a reference to the last element in the vector
	const T& Back() const { return data[len - 1]; }

	/// @returns a pointer to the first element in the vector
	T* begin() { return data; }

	/// @returns a pointer to the first element in the vector
	const T* begin() const { return data; }

	/// @returns a pointer to one past the last element in the vector
	T* end() { return data + len; }

	/// @returns a pointer to one past the last element in the vector
	const T* end() const { return data + len; }

	/// @returns a reverse iterator starting with the last element in the vector
	auto rbegin() { return std::reverse_iterator<T*>(end()); }

	/// @returns a reverse iterator starting with the last element in the vector
	auto rbegin() const { return std::reverse_iterator<const T*>(end()); }

	/// @returns the end for a reverse iterator
	auto rend() { return std::reverse_iterator<T*>(begin()); }

	/// @returns the end for a reverse iterator
	auto rend() const { return std::reverse_iterator<const T*>(begin()); }
	};

	/// Deduction guide for Slice from c-array
	template <typename T, size_t N>
	Slice(T (&elements)[N]) -> Slice<T>;

	} // namespace tint::utils

	#endif // SRC_TINT_UTILS_SLICE_H_