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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
	* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
	* 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, CUTE_GCC_UNREACHABLE
	#include <cute/layout.hpp> // cute::tuple
	#include <cute/numeric/integral_constant.hpp> // cute::true_type, cute::false_type, cute::Int

	/* This implements a ComposedLayout of the form
	* LayoutA o Offset o LayoutB
	* and is useful in cases where composition() does not or cannot apply to LayoutA and LayoutB.
	* For example, when the "divisibility condition" is violated in composition(LayoutA, LayoutB).
	*
	* This ComposedLayout provides similar functionality to Layout including tiling, partitioning,
	* coordinate-to-index mapping and layout manipulations, but is not considered a "normal" layout.
	* For example, this layout provides shape() and size() functions, but does not provide stride() functions.
	* Mostly, the similar functionality is accomplished by applying each operation to LayoutB only
	* as LayoutB defines the domain.
	*/

	namespace cute
	{

	// A Layout of non-trivially composable functions: F o I o L
	template <class LayoutA, class Offset, class LayoutB>
	struct ComposedLayout : private cute::tuple<LayoutA, Offset, LayoutB> // EBO for static layouts
	{
	CUTE_HOST_DEVICE constexpr
	ComposedLayout(LayoutA const& layoutA = {},
	Offset const& offset = {},
	LayoutB const& layoutB = {})
	: cute::tuple<LayoutA, Offset, LayoutB>(layoutA, offset, layoutB)
	{}

	//
	// Accessors
	//

	static constexpr int rank = LayoutB::rank;

	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	layout_a() const {
	return get<0>(static_cast<cute::tuple<LayoutA, Offset, LayoutB> const&>(*this));
	}

	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	offset() const {
	return get<1>(static_cast<cute::tuple<LayoutA, Offset, LayoutB> const&>(*this));
	}

	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	layout_b() const {
	return get<2>(static_cast<cute::tuple<LayoutA, Offset, LayoutB> const&>(*this));
	}

	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	layout() const {
	return *this;
	}

	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	shape() const {
	return layout_b().shape();
	}

	// Doesn't really make sense to ask for the strides of this "layout"
	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	stride() const = delete;

	//
	// Mappings
	//

	// Map a logical coordinate to a linear index (Coord has no Underscore slice operators)
	// OR
	// Slice the layout and return the sublayout (Coord has an Underscore slice op)
	template <class Coord>
	CUTE_HOST_DEVICE constexpr
	auto
	operator()(Coord const& coord) const {
	if constexpr (has_underscore<Coord>::value) {
	return slice(coord, *this);
	} else {
	return layout_a()(offset() + layout_b()(coord)); // (A o O o B)(c)
	}

	CUTE_GCC_UNREACHABLE;
	}

	// Convenience function for multi-dimensional coordinates
	template <class Coord0, class Coord1, class... Coords>
	CUTE_HOST_DEVICE constexpr
	auto
	operator()(Coord0 const& c0, Coord1 const& c1, Coords const&... cs) const {
	return operator()(make_coord(c0,c1,cs...));
	}

	//
	// Compose
	//

	template <class OtherLayout>
	CUTE_HOST_DEVICE constexpr
	auto
	compose(OtherLayout const& other) const {
	return composition(*this, other);
	}

	template <class... Layouts>
	CUTE_HOST_DEVICE constexpr
	auto
	compose(Layouts const&... layouts) const {
	return composition(*this, make_tile(layouts...));
	}

	template <class OtherShape>
	CUTE_HOST_DEVICE constexpr
	auto
	with_shape(OtherShape const& shape) const {
	return composition(*this, make_layout(shape));
	}

	template <class... Shapes>
	CUTE_HOST_DEVICE constexpr
	auto
	with_shape(Shapes const&... shapes) const {
	return composition(*this, make_layout(make_shape(shapes...)));
	}

	//
	// Tile
	//

	template <class OtherLayout>
	CUTE_HOST_DEVICE constexpr
	auto
	tile(OtherLayout const& other) const {
	return tiled_divide(*this, other);
	}

	template <class... Layouts>
	CUTE_HOST_DEVICE constexpr
	auto
	tile(Layouts const&... layouts) const {
	return tiled_divide(*this, make_tile(layouts...));
	}

	// Equality, return a static or dynamic boolean
	template <class... Args>
	CUTE_HOST_DEVICE constexpr
	auto
	operator==(ComposedLayout<Args...> const& other) const {
	return this->layout_a() == other.layout_a() &&
	this->layout_b() == other.layout_b() &&
	this->offset() == other.offset();
	}
	};

	template <class A, class O, class B>
	struct is_layout<ComposedLayout<A,O,B>> : true_type {};

	template <class T>
	struct is_composed_layout : false_type {};
	template <class A, class O, class B>
	struct is_composed_layout<ComposedLayout<A,O,B>> : true_type {};

	//
	// Constructors
	//

	template <class LayoutA, class Offset, class LayoutB>
	CUTE_HOST_DEVICE constexpr
	auto
	make_composed_layout(LayoutA const& layoutA,
	Offset const& offset,
	LayoutB const& layoutB)
	{
	return ComposedLayout<LayoutA, Offset, LayoutB>{layoutA, offset, layoutB};
	}

	//
	// Utilities
	//

	// Return the layout of a mode
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	layout(ComposedLayout<A,O,B> const& clayout)
	{
	return composition(clayout.layout_a(), clayout.offset(), layout<Is...>(clayout.layout_b()));
	}

	// Return the shape of a mode
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	shape(ComposedLayout<A,O,B> const& layout)
	{
	return shape<Is...>(layout.layout_b());
	}

	// Doesn't make sense to directly ask for the strides of this "layout"
	template <int... Is, class Fn, class O, class Layout>
	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	stride(ComposedLayout<Fn,O,Layout> const& layout) = delete;

	// Return the number of elements in a mode
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	decltype(auto)
	size(ComposedLayout<A,O,B> const& layout)
	{
	return size<Is...>(layout.layout_b());
	}

	// Return the number of modes
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	rank(ComposedLayout<A,O,B> const& layout)
	{
	return rank<Is...>(layout.layout_b());
	}

	// Return the depth of the layout
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	depth(ComposedLayout<A,O,B> const& layout)
	{
	return depth<Is...>(layout.layout_b());
	}

	// Return the codomain size of a mode
	template <int... Is, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	cosize(ComposedLayout<A,O,B> const& layout)
	{
	return cosize<Is...>(layout.layout_b());
	}

	//
	// Operations to manipulate Layouts like a tuple of pairs
	//

	template <size_t I, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	get(ComposedLayout<A,O,B> const& a)
	{
	return composition(a.layout_a(), a.offset(), get<I>(a.layout_b()));
	}

	template <int Begin, int End, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	take(ComposedLayout<A,O,B> const& a)
	{
	return composition(a.layout_a(), a.offset(), take<Begin,End>(a.layout_b()));
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	flatten(ComposedLayout<A,O,B> const& a)
	{
	return composition(a.layout_a(), a.offset(), flatten(a.layout_b()));
	}

	template <int N, class A, class O, class B, class X>
	CUTE_HOST_DEVICE constexpr
	auto
	append(ComposedLayout<A,O,B> const& a, X const& x)
	{
	return composition(a.layout_a(), a.offset(), append<N>(a.layout_b(), x));
	}

	template <int Begin, int End, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	group(ComposedLayout<A,O,B> const& a)
	{
	return composition(a.layout_a(), a.offset(), group<Begin,End>(a.layout_b()));
	}

	//
	// Slice a ComposedLayout
	//

	template <class Coord, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	slice_and_offset(Coord const& coord, ComposedLayout<A,O,B> const& layout)
	{
	auto [slice, offset] = slice_and_offset(coord, layout.layout_b());
	return cute::make_tuple(ComposedLayout{layout.layout_a(), layout.offset() + offset, slice}, Int<0>{});
	}

	template <class Coord, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	slice(Coord const& coord, ComposedLayout<A,O,B> const& layout)
	{
	return get<0>(slice_and_offset(coord, layout));
	}

	// Compute a pointer offset and (potentially modified) layout from a coordinate
	// For composed layout tensors the offset is accumulated in the layout itself while pointer is not updated
	template <class Coord, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	domain_offset(Coord const& coord, ComposedLayout<A,O,B> const& layout)
	{
	return cute::make_tuple(ComposedLayout{layout.layout_a(), layout.offset() + layout.layout_b()(coord), layout.layout_b()}, Int<0>{});
	}

	//
	// composition
	//

	template <class LayoutA,
	class Offset,
	class LayoutB>
	CUTE_HOST_DEVICE constexpr
	auto
	composition(LayoutA const& layoutA,
	Offset const& offset,
	LayoutB const& layoutB)
	{
	return ComposedLayout<LayoutA, Offset, LayoutB>{layoutA, offset, layoutB};
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	composition(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), composition(a.layout_b(), b));
	}

	template <class ShapeA, class StrideA,
	class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	composition(Layout<ShapeA,StrideA> const& a,
	ComposedLayout<A,O,B> const& b)
	{
	CUTE_STATIC_ASSERT_V(b.offset() == Int<0>{}, "Require offset == 0.");

	return composition(composition(a, b.layout_a()), b.layout_b());
	}

	//
	// complement
	//

	template <class A, class O, class B, class CoTarget>
	CUTE_HOST_DEVICE constexpr
	auto
	complement(ComposedLayout<A,O,B> const& layout, CoTarget const& cotarget)
	{
	return complement(layout.layout_b(), cotarget);
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	complement(ComposedLayout<A,O,B> const& layout)
	{
	return complement(layout, cosize(layout));
	}

	//
	// inverse
	//

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	right_inverse(ComposedLayout<A,O,B> const& layout)
	{
	return composition(right_inverse(layout.layout_b()), right_inverse(layout.offset()), right_inverse(layout.layout_a()));
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	left_inverse(ComposedLayout<A,O,B> const& layout)
	{
	return composition(left_inverse(layout.layout_b()), left_inverse(layout.offset()), left_inverse(layout.layout_a()));
	}

	//
	// Other operations
	//

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	zip(ComposedLayout<A,O,B> const& a)
	{
	return composition(a.layout_a(), a.offset(), zip(a.layout_b()));
	}

	// Partitions

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	logical_divide(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), logical_divide(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	tile_unzip(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), tile_unzip(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	tiled_divide(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), tiled_divide(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	zipped_divide(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), zipped_divide(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	flat_divide(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), flat_divide(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	logical_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), logical_product(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	zipped_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), zipped_product(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	tiled_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), tiled_product(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	flat_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), flat_product(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	blocked_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), blocked_product(a.layout_b(), b));
	}

	template <class A, class O, class B, class Tiler>
	CUTE_HOST_DEVICE constexpr
	auto
	raked_product(ComposedLayout<A,O,B> const& a,
	Tiler const& b)
	{
	return composition(a.layout_a(), a.offset(), raked_product(a.layout_b(), b));
	}

	template <class A, class O, class B,
	class Shape, class ModeOrder = GenColMajor>
	CUTE_HOST_DEVICE constexpr
	auto
	tile_to_shape(ComposedLayout<A,O,B> const& layout,
	Shape const& trg_shape,
	ModeOrder const& ord_shape = {})
	{
	return composition(layout.layout_a(), layout.offset(), tile_to_shape(layout.layout_b(), trg_shape, ord_shape));
	}

	template <class A, class O, class B,
	class Shape>
	CUTE_HOST_DEVICE constexpr
	auto
	filter(ComposedLayout<A,O,B> const& layout, Shape const& trg_profile)
	{
	return composition(layout.layout_a(), layout.offset(), filter(layout.layout_b(), trg_profile));
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	coalesce(ComposedLayout<A,O,B> const& layout)
	{
	return composition(layout.layout_a(), layout.offset(), coalesce(layout.layout_b()));
	}

	template <class A, class O, class B, class Shape>
	CUTE_HOST_DEVICE constexpr
	auto
	coalesce(ComposedLayout<A,O,B> const& layout, Shape const& trg_profile)
	{
	return composition(layout.layout_a(), layout.offset(), coalesce(layout.layout_b(), trg_profile));
	}


	//
	// Upcast and Downcast
	//

	template <int N, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	upcast(ComposedLayout<A,O,B> const& layout)
	{
	return composition(upcast<N>(layout.layout_a()), upcast<N>(layout.offset()), upcast<N>(layout.layout_b()));
	}

	template <int N, class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	downcast(ComposedLayout<A,O,B> const& layout)
	{
	return composition(downcast<N>(layout.layout_a()), downcast<N>(layout.offset()), downcast<N>(layout.layout_b()));
	}


	template <class OldType, class NewType,
	class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	recast_layout(ComposedLayout<A,O,B> const& layout)
	{
	using scale = decltype(trait_ratio(sizeof_bits<NewType>{}, sizeof_bits<OldType>{}));
	if constexpr (scale::num == 1 && scale::den == 1) {
	return layout;
	}
	else if constexpr (scale::num == 1) {
	return downcast<scale::den>(layout);
	}
	else if constexpr (scale::den == 1) {
	return upcast<scale::num>(layout);
	}
	else {
	return downcast<scale::den>(upcast<scale::num>(layout));
	}
	CUTE_GCC_UNREACHABLE;
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	max_alignment(ComposedLayout<A,O,B> const& layout)
	{
	// Do not attempt for general ComposedLayouts
	//return gcd(max_alignment(layout.layout_a()), max_alignment(layout.offset()), max_alignment(layout.layout_b()));
	return Int<1>{};
	}

	template <class A, class O, class B>
	CUTE_HOST_DEVICE constexpr
	auto
	nullspace(ComposedLayout<A,O,B> const& layout)
	{
	// Do not attempt for general ComposedLayouts
	return Layout<_1,_0>{};
	}

	//
	// Display utilities
	//

	template <class A, class O, class B>
	CUTE_HOST_DEVICE void print(ComposedLayout<A,O,B> const& layout)
	{
	print(layout.layout_a()); print(" o "); print(layout.offset()); print(" o "); print(layout.layout_b());
	}

	#if !defined(__CUDACC_RTC__)
	template <class A, class O, class B>
	CUTE_HOST std::ostream& operator<<(std::ostream& os, ComposedLayout<A,O,B> const& layout)
	{
	return os << layout.layout_a() << " o " << layout.offset() << " o " << layout.layout_b();
	}
	#endif

	} // end namespace cute