ginkgo-hpc/html/coo_8hpp_source.html

// SPDX-FileCopyrightText: 2017 - 2025 The Ginkgo authors

//

// SPDX-License-Identifier: BSD-3-Clause


#ifndef GKO_PUBLIC_CORE_MATRIX_COO_HPP_

#define GKO_PUBLIC_CORE_MATRIX_COO_HPP_


#include <ginkgo/core/base/array.hpp>

#include <ginkgo/core/base/lin_op.hpp>


namespace gko {

namespace matrix {


template <typename ValueType, typename IndexType>

class Csr;


template <typename ValueType>

class Dense;


template <typename ValueType, typename IndexType>

class CooBuilder;


template <typename ValueType, typename IndexType>

class Hybrid;


template <typename ValueType = default_precision, typename IndexType = int32>


class Coo : public EnableLinOp<Coo<ValueType, IndexType>>,

            public ConvertibleTo<Coo<next_precision<ValueType>, IndexType>>,

#if GINKGO_ENABLE_HALF || GINKGO_ENABLE_BFLOAT16

            public ConvertibleTo<Coo<next_precision<ValueType, 2>, IndexType>>,

#endif

#if GINKGO_ENABLE_HALF && GINKGO_ENABLE_BFLOAT16

            public ConvertibleTo<Coo<next_precision<ValueType, 3>, IndexType>>,

#endif

            public ConvertibleTo<Csr<ValueType, IndexType>>,

            public ConvertibleTo<Dense<ValueType>>,

            public DiagonalExtractable<ValueType>,

            public ReadableFromMatrixData<ValueType, IndexType>,

            public WritableToMatrixData<ValueType, IndexType>,

            public Transposable,

            public EnableAbsoluteComputation<

                remove_complex<Coo<ValueType, IndexType>>> {

    friend class EnablePolymorphicObject<Coo, LinOp>;

    friend class Csr<ValueType, IndexType>;

    friend class Dense<ValueType>;

    friend class CooBuilder<ValueType, IndexType>;

    friend class Coo<to_complex<ValueType>, IndexType>;

    friend class Hybrid<ValueType, IndexType>;

    GKO_ASSERT_SUPPORTED_VALUE_AND_INDEX_TYPE;


public:

    using EnableLinOp<Coo>::convert_to;

    using EnableLinOp<Coo>::move_to;

    using ConvertibleTo<Coo<next_precision<ValueType>, IndexType>>::convert_to;

    using ConvertibleTo<Coo<next_precision<ValueType>, IndexType>>::move_to;

    using ConvertibleTo<Csr<ValueType, IndexType>>::convert_to;

    using ConvertibleTo<Csr<ValueType, IndexType>>::move_to;

    using ConvertibleTo<Dense<ValueType>>::convert_to;

    using ConvertibleTo<Dense<ValueType>>::move_to;

    using ReadableFromMatrixData<ValueType, IndexType>::read;


    using value_type = ValueType;

    using index_type = IndexType;

    using transposed_type = Coo<ValueType, IndexType>;

    using mat_data = matrix_data<ValueType, IndexType>;

    using device_mat_data = device_matrix_data<ValueType, IndexType>;

    using absolute_type = remove_complex<Coo>;


    friend class Coo<previous_precision<ValueType>, IndexType>;


    void convert_to(

        Coo<next_precision<ValueType>, IndexType>* result) const override;


    void move_to(Coo<next_precision<ValueType>, IndexType>* result) override;


#if GINKGO_ENABLE_HALF || GINKGO_ENABLE_BFLOAT16

    friend class Coo<previous_precision<ValueType, 2>, IndexType>;

    using ConvertibleTo<

        Coo<next_precision<ValueType, 2>, IndexType>>::convert_to;

    using ConvertibleTo<Coo<next_precision<ValueType, 2>, IndexType>>::move_to;


    void convert_to(

        Coo<next_precision<ValueType, 2>, IndexType>* result) const override;


    void move_to(Coo<next_precision<ValueType, 2>, IndexType>* result) override;

#endif


#if GINKGO_ENABLE_HALF && GINKGO_ENABLE_BFLOAT16

    friend class Coo<previous_precision<ValueType, 3>, IndexType>;

    using ConvertibleTo<

        Coo<next_precision<ValueType, 3>, IndexType>>::convert_to;

    using ConvertibleTo<Coo<next_precision<ValueType, 3>, IndexType>>::move_to;


    void convert_to(

        Coo<next_precision<ValueType, 3>, IndexType>* result) const override;


    void move_to(Coo<next_precision<ValueType, 3>, IndexType>* result) override;

#endif


    void convert_to(Csr<ValueType, IndexType>* other) const override;


    void move_to(Csr<ValueType, IndexType>* other) override;


    void convert_to(Dense<ValueType>* other) const override;


    void move_to(Dense<ValueType>* other) override;


    void read(const mat_data& data) override;


    void read(const device_mat_data& data) override;


    void read(device_mat_data&& data) override;


    void write(mat_data& data) const override;


    std::unique_ptr<LinOp> transpose() const override;


    std::unique_ptr<LinOp> conj_transpose() const override;


    std::unique_ptr<Diagonal<ValueType>> extract_diagonal() const override;


    std::unique_ptr<absolute_type> compute_absolute() const override;


    void compute_absolute_inplace() override;


    value_type* get_values() noexcept { return values_.get_data(); }


    const value_type* get_const_values() const noexcept

    {

        return values_.get_const_data();

    }


    index_type* get_col_idxs() noexcept { return col_idxs_.get_data(); }


    const index_type* get_const_col_idxs() const noexcept

    {

        return col_idxs_.get_const_data();

    }


    index_type* get_row_idxs() noexcept { return row_idxs_.get_data(); }


    const index_type* get_const_row_idxs() const noexcept

    {

        return row_idxs_.get_const_data();

    }


    size_type get_num_stored_elements() const noexcept

    {

        return values_.get_size();

    }


    LinOp* apply2(ptr_param<const LinOp> b, ptr_param<LinOp> x);


    const LinOp* apply2(ptr_param<const LinOp> b, ptr_param<LinOp> x) const;


    LinOp* apply2(ptr_param<const LinOp> alpha, ptr_param<const LinOp> b,

                  ptr_param<LinOp> x);


    const LinOp* apply2(ptr_param<const LinOp> alpha, ptr_param<const LinOp> b,

                        ptr_param<LinOp> x) const;


    static std::unique_ptr<Coo> create(std::shared_ptr<const Executor> exec,

                                       const dim<2>& size = dim<2>{},

                                       size_type num_nonzeros = {});


    static std::unique_ptr<Coo> create(std::shared_ptr<const Executor> exec,

                                       const dim<2>& size,

                                       array<value_type> values,

                                       array<index_type> col_idxs,

                                       array<index_type> row_idxs);


    template <typename InputValueType, typename InputColumnIndexType,

              typename InputRowIndexType>

    GKO_DEPRECATED(

        "explicitly construct the gko::array argument instead of passing "

        "initializer lists")


    static std::unique_ptr<Coo> create(

        std::shared_ptr<const Executor> exec, const dim<2>& size,

        std::initializer_list<InputValueType> values,

        std::initializer_list<InputColumnIndexType> col_idxs,

        std::initializer_list<InputRowIndexType> row_idxs)

    {

        return create(exec, size, array<value_type>{exec, std::move(values)},

                      array<index_type>{exec, std::move(col_idxs)},

                      array<index_type>{exec, std::move(row_idxs)});

    }


    static std::unique_ptr<const Coo> create_const(

        std::shared_ptr<const Executor> exec, const dim<2>& size,

        gko::detail::const_array_view<ValueType>&& values,

        gko::detail::const_array_view<IndexType>&& col_idxs,

        gko::detail::const_array_view<IndexType>&& row_idxs);


protected:

    Coo(std::shared_ptr<const Executor> exec, const dim<2>& size = dim<2>{},

        size_type num_nonzeros = {});


    Coo(std::shared_ptr<const Executor> exec, const dim<2>& size,

        array<value_type> values, array<index_type> col_idxs,

        array<index_type> row_idxs);


    void resize(dim<2> new_size, size_type nnz);


    void apply_impl(const LinOp* b, LinOp* x) const override;


    void apply_impl(const LinOp* alpha, const LinOp* b, const LinOp* beta,

                    LinOp* x) const override;


    void apply2_impl(const LinOp* b, LinOp* x) const;


    void apply2_impl(const LinOp* alpha, const LinOp* b, LinOp* x) const;


private:

    array<value_type> values_;

    array<index_type> col_idxs_;

    array<index_type> row_idxs_;

};


}  // namespace matrix

}  // namespace gko


#endif  // GKO_PUBLIC_CORE_MATRIX_COO_HPP_

gko::DiagonalExtractable
The diagonal of a LinOp implementing this interface can be extracted.
Definition lin_op.hpp:743

gko::EnableAbsoluteComputation
The EnableAbsoluteComputation mixin provides the default implementations of compute_absolute_linop an...
Definition lin_op.hpp:794

gko::EnableLinOp
The EnableLinOp mixin can be used to provide sensible default implementations of the majority of the ...
Definition lin_op.hpp:879

gko::EnablePolymorphicObject
This mixin inherits from (a subclass of) PolymorphicObject and provides a base implementation of a ne...
Definition polymorphic_object.hpp:668

gko::Executor
The first step in using the Ginkgo library consists of creating an executor.
Definition executor.hpp:615

gko::LinOp
Definition lin_op.hpp:117

gko::ReadableFromMatrixData
A LinOp implementing this interface can read its data from a matrix_data structure.
Definition lin_op.hpp:605

gko::Transposable
Linear operators which support transposition should implement the Transposable interface.
Definition lin_op.hpp:433

gko::WritableToMatrixData
A LinOp implementing this interface can write its data to a matrix_data structure.
Definition lin_op.hpp:660

gko::array
An array is a container which encapsulates fixed-sized arrays, stored on the Executor tied to the arr...
Definition array.hpp:166

gko::device_matrix_data
This type is a device-side equivalent to matrix_data.
Definition device_matrix_data.hpp:36

gko::matrix::CooBuilder
Definition coo.hpp:29

gko::matrix::Coo::get_col_idxs
index_type * get_col_idxs() noexcept
Returns the column indexes of the matrix.
Definition coo.hpp:173

gko::matrix::Coo::transpose
std::unique_ptr< LinOp > transpose() const override
Returns a LinOp representing the transpose of the Transposable object.

gko::matrix::Coo::get_const_col_idxs
const index_type * get_const_col_idxs() const noexcept
Returns the column indexes of the matrix.
Definition coo.hpp:182

gko::matrix::Coo::create_const
static std::unique_ptr< const Coo > create_const(std::shared_ptr< const Executor > exec, const dim< 2 > &size, gko::detail::const_array_view< ValueType > &&values, gko::detail::const_array_view< IndexType > &&col_idxs, gko::detail::const_array_view< IndexType > &&row_idxs)
Creates a constant (immutable) Coo matrix from a set of constant arrays.

gko::matrix::Coo::apply2
const LinOp * apply2(ptr_param< const LinOp > alpha, ptr_param< const LinOp > b, ptr_param< LinOp > x) const

gko::matrix::Coo::conj_transpose
std::unique_ptr< LinOp > conj_transpose() const override
Returns a LinOp representing the conjugate transpose of the Transposable object.

gko::matrix::Coo::apply2
LinOp * apply2(ptr_param< const LinOp > b, ptr_param< LinOp > x)
Applies Coo matrix axpy to a vector (or a sequence of vectors).

gko::matrix::Coo::apply2
LinOp * apply2(ptr_param< const LinOp > alpha, ptr_param< const LinOp > b, ptr_param< LinOp > x)
Performs the operation x = alpha * Coo * b + x.

gko::matrix::Coo::compute_absolute_inplace
void compute_absolute_inplace() override
Compute absolute inplace on each element.

gko::matrix::Coo::get_const_values
const value_type * get_const_values() const noexcept
Returns the values of the matrix.
Definition coo.hpp:163

gko::matrix::Coo::get_const_row_idxs
const index_type * get_const_row_idxs() const noexcept
Definition coo.hpp:201

gko::matrix::Coo::apply2
const LinOp * apply2(ptr_param< const LinOp > b, ptr_param< LinOp > x) const

gko::matrix::Coo::compute_absolute
std::unique_ptr< absolute_type > compute_absolute() const override
Gets the AbsoluteLinOp.

gko::matrix::Coo::create
static std::unique_ptr< Coo > create(std::shared_ptr< const Executor > exec, const dim< 2 > &size=dim< 2 >{}, size_type num_nonzeros={})
Creates an uninitialized COO matrix of the specified size.

gko::matrix::Coo::get_num_stored_elements
size_type get_num_stored_elements() const noexcept
Returns the number of elements explicitly stored in the matrix.
Definition coo.hpp:211

gko::matrix::Coo::extract_diagonal
std::unique_ptr< Diagonal< ValueType > > extract_diagonal() const override
Extracts the diagonal entries of the matrix into a vector.

gko::matrix::Coo::get_row_idxs
index_type * get_row_idxs() noexcept
Returns the row indexes of the matrix.
Definition coo.hpp:192

gko::matrix::Coo::create
static std::unique_ptr< Coo > create(std::shared_ptr< const Executor > exec, const dim< 2 > &size, array< value_type > values, array< index_type > col_idxs, array< index_type > row_idxs)
Creates a COO matrix from already allocated (and initialized) row index, column index and value array...

gko::matrix::Coo::get_values
value_type * get_values() noexcept
Returns the values of the matrix.
Definition coo.hpp:154

gko::matrix::Csr
CSR is a matrix format which stores only the nonzero coefficients by compressing each row of the matr...
Definition csr.hpp:126

gko::matrix::Dense
Dense is a matrix format which explicitly stores all values of the matrix.
Definition dense.hpp:120

gko::matrix::Hybrid
HYBRID is a matrix format which splits the matrix into ELLPACK and COO format.
Definition hybrid.hpp:57

gko::ptr_param
This class is used for function parameters in the place of raw pointers.
Definition utils_helper.hpp:41

gko::matrix
The matrix namespace.
Definition dense_cache.hpp:24

gko
The Ginkgo namespace.
Definition abstract_factory.hpp:20

gko::remove_complex
typename detail::remove_complex_s< T >::type remove_complex
Obtain the type which removed the complex of complex/scalar type or the template parameter of class b...
Definition math.hpp:264

gko::to_complex
typename detail::to_complex_s< T >::type to_complex
Obtain the type which adds the complex of complex/scalar type or the template parameter of class by a...
Definition math.hpp:283

gko::size_type
std::size_t size_type
Integral type used for allocation quantities.
Definition types.hpp:90

gko::previous_precision
typename detail::find_precision_impl< T, -step >::type previous_precision
Obtains the previous move type of T in the singly-linked precision corresponding bfloat16/half.
Definition math.hpp:473

gko::next_precision
typename detail::find_precision_impl< T, step >::type next_precision
Obtains the next move type of T in the singly-linked precision corresponding bfloat16/half.
Definition math.hpp:466

std
STL namespace.

gko::dim
A type representing the dimensions of a multidimensional object.
Definition dim.hpp:26

gko::matrix_data
This structure is used as an intermediate data type to store a sparse matrix.
Definition matrix_data.hpp:126