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efa8726ff7
Fixes #738 The current check for conformability fails when given a 2D, 1xN or Nx1 input to a row-major or column-major, respectively, Eigen::Ref, leading to a copy-required state in the type_caster, but this later failed because the copy was also non-conformable because it had the same shape and strides (because a 1xN or Nx1 is both F and C contiguous). In such cases we can safely ignore the stride on the "1" dimension since it'll never be used: only the "N" dimension stride needs to match the Eigen::Ref stride, which both fixes the non-conformable copy problem, but also avoids a copy entirely as long as the "N" dimension has a compatible stride.
590 lines
28 KiB
C++
590 lines
28 KiB
C++
/*
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pybind11/eigen.h: Transparent conversion for dense and sparse Eigen matrices
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Copyright (c) 2016 Wenzel Jakob <wenzel.jakob@epfl.ch>
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All rights reserved. Use of this source code is governed by a
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BSD-style license that can be found in the LICENSE file.
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*/
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#pragma once
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#include "numpy.h"
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#if defined(__INTEL_COMPILER)
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# pragma warning(disable: 1682) // implicit conversion of a 64-bit integral type to a smaller integral type (potential portability problem)
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#elif defined(__GNUG__) || defined(__clang__)
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# pragma GCC diagnostic push
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# pragma GCC diagnostic ignored "-Wconversion"
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# pragma GCC diagnostic ignored "-Wdeprecated-declarations"
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# if __GNUC__ >= 7
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# pragma GCC diagnostic ignored "-Wint-in-bool-context"
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# endif
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#endif
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#include <Eigen/Core>
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#include <Eigen/SparseCore>
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#if defined(_MSC_VER)
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# pragma warning(push)
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# pragma warning(disable: 4127) // warning C4127: Conditional expression is constant
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#endif
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// Eigen prior to 3.2.7 doesn't have proper move constructors--but worse, some classes get implicit
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// move constructors that break things. We could detect this an explicitly copy, but an extra copy
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// of matrices seems highly undesirable.
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static_assert(EIGEN_VERSION_AT_LEAST(3,2,7), "Eigen support in pybind11 requires Eigen >= 3.2.7");
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NAMESPACE_BEGIN(pybind11)
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// Provide a convenience alias for easier pass-by-ref usage with fully dynamic strides:
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using EigenDStride = Eigen::Stride<Eigen::Dynamic, Eigen::Dynamic>;
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template <typename MatrixType> using EigenDRef = Eigen::Ref<MatrixType, 0, EigenDStride>;
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template <typename MatrixType> using EigenDMap = Eigen::Map<MatrixType, 0, EigenDStride>;
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NAMESPACE_BEGIN(detail)
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#if EIGEN_VERSION_AT_LEAST(3,3,0)
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using EigenIndex = Eigen::Index;
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#else
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using EigenIndex = EIGEN_DEFAULT_DENSE_INDEX_TYPE;
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#endif
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// Matches Eigen::Map, Eigen::Ref, blocks, etc:
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template <typename T> using is_eigen_dense_map = all_of<is_template_base_of<Eigen::DenseBase, T>, std::is_base_of<Eigen::MapBase<T, Eigen::ReadOnlyAccessors>, T>>;
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template <typename T> using is_eigen_mutable_map = std::is_base_of<Eigen::MapBase<T, Eigen::WriteAccessors>, T>;
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template <typename T> using is_eigen_dense_plain = all_of<negation<is_eigen_dense_map<T>>, is_template_base_of<Eigen::PlainObjectBase, T>>;
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template <typename T> using is_eigen_sparse = is_template_base_of<Eigen::SparseMatrixBase, T>;
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// Test for objects inheriting from EigenBase<Derived> that aren't captured by the above. This
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// basically covers anything that can be assigned to a dense matrix but that don't have a typical
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// matrix data layout that can be copied from their .data(). For example, DiagonalMatrix and
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// SelfAdjointView fall into this category.
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template <typename T> using is_eigen_other = all_of<
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is_template_base_of<Eigen::EigenBase, T>,
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negation<any_of<is_eigen_dense_map<T>, is_eigen_dense_plain<T>, is_eigen_sparse<T>>>
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>;
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// Captures numpy/eigen conformability status (returned by EigenProps::conformable()):
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template <bool EigenRowMajor> struct EigenConformable {
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bool conformable = false;
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EigenIndex rows = 0, cols = 0;
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EigenDStride stride{0, 0};
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EigenConformable(bool fits = false) : conformable{fits} {}
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// Matrix type:
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EigenConformable(EigenIndex r, EigenIndex c,
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EigenIndex rstride, EigenIndex cstride) :
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conformable{true}, rows{r}, cols{c},
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stride(EigenRowMajor ? rstride : cstride /* outer stride */,
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EigenRowMajor ? cstride : rstride /* inner stride */)
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{}
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// Vector type:
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EigenConformable(EigenIndex r, EigenIndex c, EigenIndex stride)
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: EigenConformable(r, c, r == 1 ? c*stride : stride, c == 1 ? r : r*stride) {}
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template <typename props> bool stride_compatible() const {
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// To have compatible strides, we need (on both dimensions) one of fully dynamic strides,
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// matching strides, or a dimension size of 1 (in which case the stride value is irrelevant)
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return
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(props::inner_stride == Eigen::Dynamic || props::inner_stride == stride.inner() ||
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(EigenRowMajor ? cols : rows) == 1) &&
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(props::outer_stride == Eigen::Dynamic || props::outer_stride == stride.outer() ||
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(EigenRowMajor ? rows : cols) == 1);
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}
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operator bool() const { return conformable; }
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};
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template <typename Type> struct eigen_extract_stride { using type = Type; };
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template <typename PlainObjectType, int MapOptions, typename StrideType>
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struct eigen_extract_stride<Eigen::Map<PlainObjectType, MapOptions, StrideType>> { using type = StrideType; };
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template <typename PlainObjectType, int Options, typename StrideType>
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struct eigen_extract_stride<Eigen::Ref<PlainObjectType, Options, StrideType>> { using type = StrideType; };
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// Helper struct for extracting information from an Eigen type
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template <typename Type_> struct EigenProps {
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using Type = Type_;
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using Scalar = typename Type::Scalar;
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using StrideType = typename eigen_extract_stride<Type>::type;
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static constexpr EigenIndex
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rows = Type::RowsAtCompileTime,
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cols = Type::ColsAtCompileTime,
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size = Type::SizeAtCompileTime;
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static constexpr bool
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row_major = Type::IsRowMajor,
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vector = Type::IsVectorAtCompileTime, // At least one dimension has fixed size 1
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fixed_rows = rows != Eigen::Dynamic,
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fixed_cols = cols != Eigen::Dynamic,
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fixed = size != Eigen::Dynamic, // Fully-fixed size
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dynamic = !fixed_rows && !fixed_cols; // Fully-dynamic size
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template <EigenIndex i, EigenIndex ifzero> using if_zero = std::integral_constant<EigenIndex, i == 0 ? ifzero : i>;
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static constexpr EigenIndex inner_stride = if_zero<StrideType::InnerStrideAtCompileTime, 1>::value,
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outer_stride = if_zero<StrideType::OuterStrideAtCompileTime,
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vector ? size : row_major ? cols : rows>::value;
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static constexpr bool dynamic_stride = inner_stride == Eigen::Dynamic && outer_stride == Eigen::Dynamic;
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static constexpr bool requires_row_major = !dynamic_stride && !vector && (row_major ? inner_stride : outer_stride) == 1;
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static constexpr bool requires_col_major = !dynamic_stride && !vector && (row_major ? outer_stride : inner_stride) == 1;
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// Takes an input array and determines whether we can make it fit into the Eigen type. If
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// the array is a vector, we attempt to fit it into either an Eigen 1xN or Nx1 vector
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// (preferring the latter if it will fit in either, i.e. for a fully dynamic matrix type).
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static EigenConformable<row_major> conformable(const array &a) {
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const auto dims = a.ndim();
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if (dims < 1 || dims > 2)
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return false;
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if (dims == 2) { // Matrix type: require exact match (or dynamic)
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EigenIndex
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np_rows = a.shape(0),
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np_cols = a.shape(1),
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np_rstride = a.strides(0) / sizeof(Scalar),
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np_cstride = a.strides(1) / sizeof(Scalar);
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if ((fixed_rows && np_rows != rows) || (fixed_cols && np_cols != cols))
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return false;
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return {np_rows, np_cols, np_rstride, np_cstride};
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}
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// Otherwise we're storing an n-vector. Only one of the strides will be used, but whichever
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// is used, we want the (single) numpy stride value.
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const EigenIndex n = a.shape(0),
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stride = a.strides(0) / sizeof(Scalar);
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if (vector) { // Eigen type is a compile-time vector
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if (fixed && size != n)
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return false; // Vector size mismatch
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return {rows == 1 ? 1 : n, cols == 1 ? 1 : n, stride};
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}
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else if (fixed) {
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// The type has a fixed size, but is not a vector: abort
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return false;
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}
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else if (fixed_cols) {
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// Since this isn't a vector, cols must be != 1. We allow this only if it exactly
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// equals the number of elements (rows is Dynamic, and so 1 row is allowed).
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if (cols != n) return false;
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return {1, n, stride};
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}
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else {
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// Otherwise it's either fully dynamic, or column dynamic; both become a column vector
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if (fixed_rows && rows != n) return false;
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return {n, 1, stride};
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}
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}
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static PYBIND11_DESCR descriptor() {
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constexpr bool show_writeable = is_eigen_dense_map<Type>::value && is_eigen_mutable_map<Type>::value;
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constexpr bool show_order = is_eigen_dense_map<Type>::value;
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constexpr bool show_c_contiguous = show_order && requires_row_major;
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constexpr bool show_f_contiguous = !show_c_contiguous && show_order && requires_col_major;
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return _("numpy.ndarray[") + npy_format_descriptor<Scalar>::name() +
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_("[") + _<fixed_rows>(_<(size_t) rows>(), _("m")) +
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_(", ") + _<fixed_cols>(_<(size_t) cols>(), _("n")) +
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_("]") +
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// For a reference type (e.g. Ref<MatrixXd>) we have other constraints that might need to be
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// satisfied: writeable=True (for a mutable reference), and, depending on the map's stride
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// options, possibly f_contiguous or c_contiguous. We include them in the descriptor output
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// to provide some hint as to why a TypeError is occurring (otherwise it can be confusing to
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// see that a function accepts a 'numpy.ndarray[float64[3,2]]' and an error message that you
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// *gave* a numpy.ndarray of the right type and dimensions.
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_<show_writeable>(", flags.writeable", "") +
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_<show_c_contiguous>(", flags.c_contiguous", "") +
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_<show_f_contiguous>(", flags.f_contiguous", "") +
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_("]");
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}
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};
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// Casts an Eigen type to numpy array. If given a base, the numpy array references the src data,
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// otherwise it'll make a copy. writeable lets you turn off the writeable flag for the array.
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template <typename props> handle eigen_array_cast(typename props::Type const &src, handle base = handle(), bool writeable = true) {
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constexpr size_t elem_size = sizeof(typename props::Scalar);
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std::vector<size_t> shape, strides;
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if (props::vector) {
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shape.push_back(src.size());
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strides.push_back(elem_size * src.innerStride());
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}
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else {
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shape.push_back(src.rows());
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shape.push_back(src.cols());
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strides.push_back(elem_size * src.rowStride());
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strides.push_back(elem_size * src.colStride());
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}
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array a(std::move(shape), std::move(strides), src.data(), base);
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if (!writeable)
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array_proxy(a.ptr())->flags &= ~detail::npy_api::NPY_ARRAY_WRITEABLE_;
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return a.release();
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}
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// Takes an lvalue ref to some Eigen type and a (python) base object, creating a numpy array that
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// reference the Eigen object's data with `base` as the python-registered base class (if omitted,
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// the base will be set to None, and lifetime management is up to the caller). The numpy array is
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// non-writeable if the given type is const.
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template <typename props, typename Type>
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handle eigen_ref_array(Type &src, handle parent = none()) {
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// none here is to get past array's should-we-copy detection, which currently always
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// copies when there is no base. Setting the base to None should be harmless.
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return eigen_array_cast<props>(src, parent, !std::is_const<Type>::value);
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}
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// Takes a pointer to some dense, plain Eigen type, builds a capsule around it, then returns a numpy
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// array that references the encapsulated data with a python-side reference to the capsule to tie
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// its destruction to that of any dependent python objects. Const-ness is determined by whether or
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// not the Type of the pointer given is const.
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template <typename props, typename Type, typename = enable_if_t<is_eigen_dense_plain<Type>::value>>
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handle eigen_encapsulate(Type *src) {
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capsule base(src, [](PyObject *o) { delete static_cast<Type *>(PyCapsule_GetPointer(o, nullptr)); });
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return eigen_ref_array<props>(*src, base);
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}
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// Type caster for regular, dense matrix types (e.g. MatrixXd), but not maps/refs/etc. of dense
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// types.
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template<typename Type>
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struct type_caster<Type, enable_if_t<is_eigen_dense_plain<Type>::value>> {
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using Scalar = typename Type::Scalar;
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using props = EigenProps<Type>;
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bool load(handle src, bool) {
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auto buf = array_t<Scalar>::ensure(src);
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if (!buf)
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return false;
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auto dims = buf.ndim();
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if (dims < 1 || dims > 2)
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return false;
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auto fits = props::conformable(buf);
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if (!fits)
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return false; // Non-comformable vector/matrix types
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value = Eigen::Map<const Type, 0, EigenDStride>(buf.data(), fits.rows, fits.cols, fits.stride);
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return true;
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}
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private:
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// Cast implementation
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template <typename CType>
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static handle cast_impl(CType *src, return_value_policy policy, handle parent) {
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switch (policy) {
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case return_value_policy::take_ownership:
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case return_value_policy::automatic:
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return eigen_encapsulate<props>(src);
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case return_value_policy::move:
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return eigen_encapsulate<props>(new CType(std::move(*src)));
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case return_value_policy::copy:
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return eigen_array_cast<props>(*src);
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case return_value_policy::reference:
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case return_value_policy::automatic_reference:
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return eigen_ref_array<props>(*src);
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case return_value_policy::reference_internal:
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return eigen_ref_array<props>(*src, parent);
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default:
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throw cast_error("unhandled return_value_policy: should not happen!");
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};
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}
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public:
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// Normal returned non-reference, non-const value:
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static handle cast(Type &&src, return_value_policy /* policy */, handle parent) {
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return cast_impl(&src, return_value_policy::move, parent);
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}
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// If you return a non-reference const, we mark the numpy array readonly:
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static handle cast(const Type &&src, return_value_policy /* policy */, handle parent) {
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return cast_impl(&src, return_value_policy::move, parent);
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}
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// lvalue reference return; default (automatic) becomes copy
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static handle cast(Type &src, return_value_policy policy, handle parent) {
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if (policy == return_value_policy::automatic || policy == return_value_policy::automatic_reference)
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policy = return_value_policy::copy;
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return cast_impl(&src, policy, parent);
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}
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// const lvalue reference return; default (automatic) becomes copy
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static handle cast(const Type &src, return_value_policy policy, handle parent) {
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if (policy == return_value_policy::automatic || policy == return_value_policy::automatic_reference)
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policy = return_value_policy::copy;
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return cast(&src, policy, parent);
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}
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// non-const pointer return
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static handle cast(Type *src, return_value_policy policy, handle parent) {
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return cast_impl(src, policy, parent);
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}
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// const pointer return
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static handle cast(const Type *src, return_value_policy policy, handle parent) {
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return cast_impl(src, policy, parent);
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}
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static PYBIND11_DESCR name() { return type_descr(props::descriptor()); }
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operator Type*() { return &value; }
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operator Type&() { return value; }
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template <typename T> using cast_op_type = cast_op_type<T>;
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private:
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Type value;
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};
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// Eigen Ref/Map classes have slightly different policy requirements, meaning we don't want to force
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// `move` when a Ref/Map rvalue is returned; we treat Ref<> sort of like a pointer (we care about
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// the underlying data, not the outer shell).
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template <typename Return>
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struct return_value_policy_override<Return, enable_if_t<is_eigen_dense_map<Return>::value>> {
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static return_value_policy policy(return_value_policy p) { return p; }
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};
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// Base class for casting reference/map/block/etc. objects back to python.
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template <typename MapType> struct eigen_map_caster {
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private:
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using props = EigenProps<MapType>;
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public:
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// Directly referencing a ref/map's data is a bit dangerous (whatever the map/ref points to has
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// to stay around), but we'll allow it under the assumption that you know what you're doing (and
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// have an appropriate keep_alive in place). We return a numpy array pointing directly at the
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// ref's data (The numpy array ends up read-only if the ref was to a const matrix type.) Note
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// that this means you need to ensure you don't destroy the object in some other way (e.g. with
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// an appropriate keep_alive, or with a reference to a statically allocated matrix).
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static handle cast(const MapType &src, return_value_policy policy, handle parent) {
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switch (policy) {
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case return_value_policy::copy:
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return eigen_array_cast<props>(src);
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case return_value_policy::reference_internal:
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return eigen_array_cast<props>(src, parent, is_eigen_mutable_map<MapType>::value);
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case return_value_policy::reference:
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case return_value_policy::automatic:
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case return_value_policy::automatic_reference:
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return eigen_array_cast<props>(src, none(), is_eigen_mutable_map<MapType>::value);
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default:
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// move, take_ownership don't make any sense for a ref/map:
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pybind11_fail("Invalid return_value_policy for Eigen Map/Ref/Block type");
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}
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}
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static PYBIND11_DESCR name() { return props::descriptor(); }
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// Explicitly delete these: support python -> C++ conversion on these (i.e. these can be return
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// types but not bound arguments). We still provide them (with an explicitly delete) so that
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// you end up here if you try anyway.
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bool load(handle, bool) = delete;
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operator MapType() = delete;
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template <typename> using cast_op_type = MapType;
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};
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// We can return any map-like object (but can only load Refs, specialized next):
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template <typename Type> struct type_caster<Type, enable_if_t<is_eigen_dense_map<Type>::value>>
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: eigen_map_caster<Type> {};
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// Loader for Ref<...> arguments. See the documentation for info on how to make this work without
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// copying (it requires some extra effort in many cases).
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template <typename PlainObjectType, typename StrideType>
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struct type_caster<
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Eigen::Ref<PlainObjectType, 0, StrideType>,
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enable_if_t<is_eigen_dense_map<Eigen::Ref<PlainObjectType, 0, StrideType>>::value>
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> : public eigen_map_caster<Eigen::Ref<PlainObjectType, 0, StrideType>> {
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private:
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using Type = Eigen::Ref<PlainObjectType, 0, StrideType>;
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using props = EigenProps<Type>;
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using Scalar = typename props::Scalar;
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using MapType = Eigen::Map<PlainObjectType, 0, StrideType>;
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using Array = array_t<Scalar, array::forcecast |
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((props::row_major ? props::inner_stride : props::outer_stride) == 1 ? array::c_style :
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(props::row_major ? props::outer_stride : props::inner_stride) == 1 ? array::f_style : 0)>;
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static constexpr bool need_writeable = is_eigen_mutable_map<Type>::value;
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// Delay construction (these have no default constructor)
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std::unique_ptr<MapType> map;
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std::unique_ptr<Type> ref;
|
|
// Our array. When possible, this is just a numpy array pointing to the source data, but
|
|
// sometimes we can't avoid copying (e.g. input is not a numpy array at all, has an incompatible
|
|
// layout, or is an array of a type that needs to be converted). Using a numpy temporary
|
|
// (rather than an Eigen temporary) saves an extra copy when we need both type conversion and
|
|
// storage order conversion. (Note that we refuse to use this temporary copy when loading an
|
|
// argument for a Ref<M> with M non-const, i.e. a read-write reference).
|
|
Array copy_or_ref;
|
|
public:
|
|
bool load(handle src, bool convert) {
|
|
// First check whether what we have is already an array of the right type. If not, we can't
|
|
// avoid a copy (because the copy is also going to do type conversion).
|
|
bool need_copy = !isinstance<Array>(src);
|
|
|
|
EigenConformable<props::row_major> fits;
|
|
if (!need_copy) {
|
|
// We don't need a converting copy, but we also need to check whether the strides are
|
|
// compatible with the Ref's stride requirements
|
|
Array aref = reinterpret_borrow<Array>(src);
|
|
|
|
if (aref && (!need_writeable || aref.writeable())) {
|
|
fits = props::conformable(aref);
|
|
if (!fits) return false; // Incompatible dimensions
|
|
if (!fits.template stride_compatible<props>())
|
|
need_copy = true;
|
|
else
|
|
copy_or_ref = std::move(aref);
|
|
}
|
|
else {
|
|
need_copy = true;
|
|
}
|
|
}
|
|
|
|
if (need_copy) {
|
|
// We need to copy: If we need a mutable reference, or we're not supposed to convert
|
|
// (either because we're in the no-convert overload pass, or because we're explicitly
|
|
// instructed not to copy (via `py::arg().noconvert()`) we have to fail loading.
|
|
if (!convert || need_writeable) return false;
|
|
|
|
Array copy = Array::ensure(src);
|
|
if (!copy) return false;
|
|
fits = props::conformable(copy);
|
|
if (!fits || !fits.template stride_compatible<props>())
|
|
return false;
|
|
copy_or_ref = std::move(copy);
|
|
}
|
|
|
|
ref.reset();
|
|
map.reset(new MapType(data(copy_or_ref), fits.rows, fits.cols, make_stride(fits.stride.outer(), fits.stride.inner())));
|
|
ref.reset(new Type(*map));
|
|
|
|
return true;
|
|
}
|
|
|
|
operator Type*() { return ref.get(); }
|
|
operator Type&() { return *ref; }
|
|
template <typename _T> using cast_op_type = pybind11::detail::cast_op_type<_T>;
|
|
|
|
private:
|
|
template <typename T = Type, enable_if_t<is_eigen_mutable_map<T>::value, int> = 0>
|
|
Scalar *data(Array &a) { return a.mutable_data(); }
|
|
|
|
template <typename T = Type, enable_if_t<!is_eigen_mutable_map<T>::value, int> = 0>
|
|
const Scalar *data(Array &a) { return a.data(); }
|
|
|
|
// Attempt to figure out a constructor of `Stride` that will work.
|
|
// If both strides are fixed, use a default constructor:
|
|
template <typename S> using stride_ctor_default = bool_constant<
|
|
S::InnerStrideAtCompileTime != Eigen::Dynamic && S::OuterStrideAtCompileTime != Eigen::Dynamic &&
|
|
std::is_default_constructible<S>::value>;
|
|
// Otherwise, if there is a two-index constructor, assume it is (outer,inner) like
|
|
// Eigen::Stride, and use it:
|
|
template <typename S> using stride_ctor_dual = bool_constant<
|
|
!stride_ctor_default<S>::value && std::is_constructible<S, EigenIndex, EigenIndex>::value>;
|
|
// Otherwise, if there is a one-index constructor, and just one of the strides is dynamic, use
|
|
// it (passing whichever stride is dynamic).
|
|
template <typename S> using stride_ctor_outer = bool_constant<
|
|
!any_of<stride_ctor_default<S>, stride_ctor_dual<S>>::value &&
|
|
S::OuterStrideAtCompileTime == Eigen::Dynamic && S::InnerStrideAtCompileTime != Eigen::Dynamic &&
|
|
std::is_constructible<S, EigenIndex>::value>;
|
|
template <typename S> using stride_ctor_inner = bool_constant<
|
|
!any_of<stride_ctor_default<S>, stride_ctor_dual<S>>::value &&
|
|
S::InnerStrideAtCompileTime == Eigen::Dynamic && S::OuterStrideAtCompileTime != Eigen::Dynamic &&
|
|
std::is_constructible<S, EigenIndex>::value>;
|
|
|
|
template <typename S = StrideType, enable_if_t<stride_ctor_default<S>::value, int> = 0>
|
|
static S make_stride(EigenIndex, EigenIndex) { return S(); }
|
|
template <typename S = StrideType, enable_if_t<stride_ctor_dual<S>::value, int> = 0>
|
|
static S make_stride(EigenIndex outer, EigenIndex inner) { return S(outer, inner); }
|
|
template <typename S = StrideType, enable_if_t<stride_ctor_outer<S>::value, int> = 0>
|
|
static S make_stride(EigenIndex outer, EigenIndex) { return S(outer); }
|
|
template <typename S = StrideType, enable_if_t<stride_ctor_inner<S>::value, int> = 0>
|
|
static S make_stride(EigenIndex, EigenIndex inner) { return S(inner); }
|
|
|
|
};
|
|
|
|
// type_caster for special matrix types (e.g. DiagonalMatrix), which are EigenBase, but not
|
|
// EigenDense (i.e. they don't have a data(), at least not with the usual matrix layout).
|
|
// load() is not supported, but we can cast them into the python domain by first copying to a
|
|
// regular Eigen::Matrix, then casting that.
|
|
template <typename Type>
|
|
struct type_caster<Type, enable_if_t<is_eigen_other<Type>::value>> {
|
|
protected:
|
|
using Matrix = Eigen::Matrix<typename Type::Scalar, Type::RowsAtCompileTime, Type::ColsAtCompileTime>;
|
|
using props = EigenProps<Matrix>;
|
|
public:
|
|
static handle cast(const Type &src, return_value_policy /* policy */, handle /* parent */) {
|
|
handle h = eigen_encapsulate<props>(new Matrix(src));
|
|
return h;
|
|
}
|
|
static handle cast(const Type *src, return_value_policy policy, handle parent) { return cast(*src, policy, parent); }
|
|
|
|
static PYBIND11_DESCR name() { return props::descriptor(); }
|
|
|
|
// Explicitly delete these: support python -> C++ conversion on these (i.e. these can be return
|
|
// types but not bound arguments). We still provide them (with an explicitly delete) so that
|
|
// you end up here if you try anyway.
|
|
bool load(handle, bool) = delete;
|
|
operator Type() = delete;
|
|
template <typename> using cast_op_type = Type;
|
|
};
|
|
|
|
template<typename Type>
|
|
struct type_caster<Type, enable_if_t<is_eigen_sparse<Type>::value>> {
|
|
typedef typename Type::Scalar Scalar;
|
|
typedef typename std::remove_reference<decltype(*std::declval<Type>().outerIndexPtr())>::type StorageIndex;
|
|
typedef typename Type::Index Index;
|
|
static constexpr bool rowMajor = Type::IsRowMajor;
|
|
|
|
bool load(handle src, bool) {
|
|
if (!src)
|
|
return false;
|
|
|
|
auto obj = reinterpret_borrow<object>(src);
|
|
object sparse_module = module::import("scipy.sparse");
|
|
object matrix_type = sparse_module.attr(
|
|
rowMajor ? "csr_matrix" : "csc_matrix");
|
|
|
|
if (obj.get_type() != matrix_type.ptr()) {
|
|
try {
|
|
obj = matrix_type(obj);
|
|
} catch (const error_already_set &) {
|
|
return false;
|
|
}
|
|
}
|
|
|
|
auto values = array_t<Scalar>((object) obj.attr("data"));
|
|
auto innerIndices = array_t<StorageIndex>((object) obj.attr("indices"));
|
|
auto outerIndices = array_t<StorageIndex>((object) obj.attr("indptr"));
|
|
auto shape = pybind11::tuple((pybind11::object) obj.attr("shape"));
|
|
auto nnz = obj.attr("nnz").cast<Index>();
|
|
|
|
if (!values || !innerIndices || !outerIndices)
|
|
return false;
|
|
|
|
value = Eigen::MappedSparseMatrix<Scalar, Type::Flags, StorageIndex>(
|
|
shape[0].cast<Index>(), shape[1].cast<Index>(), nnz,
|
|
outerIndices.mutable_data(), innerIndices.mutable_data(), values.mutable_data());
|
|
|
|
return true;
|
|
}
|
|
|
|
static handle cast(const Type &src, return_value_policy /* policy */, handle /* parent */) {
|
|
const_cast<Type&>(src).makeCompressed();
|
|
|
|
object matrix_type = module::import("scipy.sparse").attr(
|
|
rowMajor ? "csr_matrix" : "csc_matrix");
|
|
|
|
array data((size_t) src.nonZeros(), src.valuePtr());
|
|
array outerIndices((size_t) (rowMajor ? src.rows() : src.cols()) + 1, src.outerIndexPtr());
|
|
array innerIndices((size_t) src.nonZeros(), src.innerIndexPtr());
|
|
|
|
return matrix_type(
|
|
std::make_tuple(data, innerIndices, outerIndices),
|
|
std::make_pair(src.rows(), src.cols())
|
|
).release();
|
|
}
|
|
|
|
PYBIND11_TYPE_CASTER(Type, _<(Type::IsRowMajor) != 0>("scipy.sparse.csr_matrix[", "scipy.sparse.csc_matrix[")
|
|
+ npy_format_descriptor<Scalar>::name() + _("]"));
|
|
};
|
|
|
|
NAMESPACE_END(detail)
|
|
NAMESPACE_END(pybind11)
|
|
|
|
#if defined(__GNUG__) || defined(__clang__)
|
|
# pragma GCC diagnostic pop
|
|
#elif defined(_MSC_VER)
|
|
# pragma warning(pop)
|
|
#endif
|