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	/***************************************************************************************************
	* Copyright (c) 2023 - 2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved.
	* SPDX-License-Identifier: BSD-3-Clause
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* 1. Redistributions of source code must retain the above copyright notice, this
	* list of conditions and the following disclaimer.
	*
	* 2. Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	*
	* 3. Neither the name of the copyright holder nor the names of its
	* contributors may be used to endorse or promote products derived from
	* this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
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	* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*
	**************************************************************************************************/

	#pragma once

	#include <cute/config.hpp> // CUTE_HOST_DEVICE
	#include <cute/pointer_base.hpp> // cute::iter_adaptor
	#include <cute/numeric/integral_constant.hpp> // cute::false_type, cute::true_type
	#include <cute/numeric/integral_ratio.hpp> // cute::ratio

	namespace cute
	{

	// A data type that holds one physical element meant to represent Sparsity number of logical elements
	// This class is purposely not compatible with anything -- know what you're doing if you attempt to use it
	template <int Sparsity, class T>
	struct sparse_elem
	{
	static constexpr int sparsity = Sparsity;
	using raw_type = T;
	T elem_;

	CUTE_HOST_DEVICE constexpr
	explicit sparse_elem(T const& elem = {}) : elem_(elem) {}

	CUTE_HOST_DEVICE constexpr friend bool operator==(sparse_elem const& a, sparse_elem const& b) { return a.elem_ == b.elem_; }
	CUTE_HOST_DEVICE constexpr friend bool operator!=(sparse_elem const& a, sparse_elem const& b) { return a.elem_ != b.elem_; }
	CUTE_HOST_DEVICE constexpr friend bool operator< (sparse_elem const& a, sparse_elem const& b) { return a.elem_ < b.elem_; }
	CUTE_HOST_DEVICE constexpr friend bool operator<=(sparse_elem const& a, sparse_elem const& b) { return a.elem_ <= b.elem_; }
	CUTE_HOST_DEVICE constexpr friend bool operator> (sparse_elem const& a, sparse_elem const& b) { return a.elem_ > b.elem_; }
	CUTE_HOST_DEVICE constexpr friend bool operator>=(sparse_elem const& a, sparse_elem const& b) { return a.elem_ >= b.elem_; }
	};

	template <class T>
	struct is_sparse : false_type {};
	template <class T>
	struct is_sparse<T const> : is_sparse<T> {};
	template <int S, class T>
	struct is_sparse<sparse_elem<S,T>> : true_type {};
	template<class T>
	static constexpr auto is_sparse_v = is_sparse<T>::value;

	// Overload sizeof_bits for sparse_elem.
	// Much like subbyte element types, this is the effective number of bits in a sparse_elem
	// rather than actual physical bits that may be used in storing one. Also like subbyte element
	// types, modified iterators are required to properly index and access sparse_elems.
	//
	// Defining sizeof_bits like this makes reasonable expressions like N * sizeof_bits_v<E> meaningful
	// even when E is subbyte or sparse. However, this also means that sparse_elem can rather easily be
	// confused with subbyte elements and special care should be taken with each.
	template <int S, class T>
	struct sizeof_bits<sparse_elem<S,T>> {
	// Simple implementation that conforms to sizeof_bits
	//static constexpr auto value = sizeof_bits<T>::value / S;
	//static_assert(value != 0, "sizeof_bits=0 detected. Sparsity is larger than width.");
	//static_assert((sizeof_bits<T>::value % S) == 0, "Width needs to be a multiple of sparsity.")

	// Interesting experiment that allows any sparsity level to be used by potentially presenting
	// an integral_ratio rather than size_t. This is valid in most integer expressions as well.
	static constexpr auto value = cute::ratio(cute::Int<cute::sizeof_bits_v<T>>{}, cute::Int<S>{});
	};

	//
	// sparse_ptr
	//

	template <class T, class = void>
	struct is_sparse_ptr : false_type {};
	template <class T>
	struct is_sparse_ptr<T, void_t<typename T::iterator>> : is_sparse_ptr<typename T::iterator> {};

	template <int Sparsity, class Iterator>
	struct sparse_ptr : iter_adaptor<Iterator, sparse_ptr<Sparsity, Iterator>>
	{
	using reference = typename iterator_traits<Iterator>::reference;
	using element_type = typename iterator_traits<Iterator>::element_type;
	using value_type = typename iterator_traits<Iterator>::value_type;

	// Sanity, for now
	static_assert(is_sparse<value_type>::value, "Enforce sparse value-type");
	static_assert(Sparsity == iter_value_t<Iterator>::sparsity, "Enforce sparsity S");
	static_assert(not is_sparse_ptr<Iterator>::value, "Enforce sparse singleton");

	template <class Index>
	CUTE_HOST_DEVICE constexpr
	sparse_ptr operator+(Index const& i) const {
	// Only allow offset by multiples of the sparsity factor,
	// else the misalignments become a bug. E.g. (sparse_ptr<8,I>{} + 7) + 7
	// Motivation for subsparse_iterator or generalization of subbyte_iterator?
	assert(i % Sparsity == 0);
	return {this->get() + i / Sparsity};
	}

	template <class Index>
	CUTE_HOST_DEVICE constexpr
	reference operator[](Index const& i) const {
	// Allow offset by any value and dereference.
	// Not implemented in terms of sparse_ptr::op+()
	return *(this->get() + i / Sparsity);
	}
	};

	template <int S, class I>
	struct is_sparse_ptr<sparse_ptr<S,I>> : true_type {};

	template <int Sparsity, class Iter>
	CUTE_HOST_DEVICE constexpr
	auto
	make_sparse_ptr(Iter const& iter) {
	if constexpr (Sparsity == 1) {
	return iter;
	} else {
	return sparse_ptr<Sparsity, Iter>{iter};
	}
	CUTE_GCC_UNREACHABLE;
	}

	template <class NewT, int S, class Iter>
	CUTE_HOST_DEVICE constexpr
	auto
	recast_ptr(sparse_ptr<S,Iter> const& ptr) {
	static_assert(not is_sparse<NewT>::value);
	return recast_ptr<NewT>(ptr.get());
	}

	//
	// Display utilities
	//

	template <int S, class Iter>
	CUTE_HOST_DEVICE void print(sparse_ptr<S,Iter> ptr)
	{
	printf("sparse<%d>_", S); print(ptr.get());
	}

	#if !defined(__CUDACC_RTC__)
	template <int S, class Iter>
	CUTE_HOST std::ostream& operator<<(std::ostream& os, sparse_ptr<S,Iter> ptr)
	{
	return os << "sparse<" << S << ">_" << ptr.get();
	}
	#endif

	} // end namespace cute