#include "main.h"
namespace Eigen {
template <typename Lhs, typename Rhs>
const Product<Lhs, Rhs> prod(const Lhs& lhs, const Rhs& rhs) {
return Product<Lhs, Rhs>(lhs, rhs);
}
template <typename Lhs, typename Rhs>
const Product<Lhs, Rhs, LazyProduct> lazyprod(const Lhs& lhs, const Rhs& rhs) {
return Product<Lhs, Rhs, LazyProduct>(lhs, rhs);
}
template <typename DstXprType, typename SrcXprType>
EIGEN_STRONG_INLINE DstXprType& copy_using_evaluator(const EigenBase<DstXprType>& dst, const SrcXprType& src) {
call_assignment(dst.const_cast_derived(), src.derived(),
internal::assign_op<typename DstXprType::Scalar, typename SrcXprType::Scalar>());
return dst.const_cast_derived();
}
template <typename DstXprType, template <typename> class StorageBase, typename SrcXprType>
EIGEN_STRONG_INLINE const DstXprType& copy_using_evaluator(const NoAlias<DstXprType, StorageBase>& dst,
const SrcXprType& src) {
call_assignment(dst, src.derived(), internal::assign_op<typename DstXprType::Scalar, typename SrcXprType::Scalar>());
return dst.expression();
}
template <typename DstXprType, typename SrcXprType>
EIGEN_STRONG_INLINE DstXprType& copy_using_evaluator(const PlainObjectBase<DstXprType>& dst, const SrcXprType& src) {
#ifdef EIGEN_NO_AUTOMATIC_RESIZING
eigen_assert((dst.size() == 0 || (IsVectorAtCompileTime ? (dst.size() == src.size())
: (dst.rows() == src.rows() && dst.cols() == src.cols()))) &&
"Size mismatch. Automatic resizing is disabled because EIGEN_NO_AUTOMATIC_RESIZING is defined");
#else
dst.const_cast_derived().resizeLike(src.derived());
#endif
call_assignment(dst.const_cast_derived(), src.derived(),
internal::assign_op<typename DstXprType::Scalar, typename SrcXprType::Scalar>());
return dst.const_cast_derived();
}
template <typename DstXprType, typename SrcXprType>
void add_assign_using_evaluator(const DstXprType& dst, const SrcXprType& src) {
typedef typename DstXprType::Scalar Scalar;
call_assignment(const_cast<DstXprType&>(dst), src.derived(),
internal::add_assign_op<Scalar, typename SrcXprType::Scalar>());
}
template <typename DstXprType, typename SrcXprType>
void subtract_assign_using_evaluator(const DstXprType& dst, const SrcXprType& src) {
typedef typename DstXprType::Scalar Scalar;
call_assignment(const_cast<DstXprType&>(dst), src.derived(),
internal::sub_assign_op<Scalar, typename SrcXprType::Scalar>());
}
template <typename DstXprType, typename SrcXprType>
void multiply_assign_using_evaluator(const DstXprType& dst, const SrcXprType& src) {
typedef typename DstXprType::Scalar Scalar;
call_assignment(dst.const_cast_derived(), src.derived(),
internal::mul_assign_op<Scalar, typename SrcXprType::Scalar>());
}
template <typename DstXprType, typename SrcXprType>
void divide_assign_using_evaluator(const DstXprType& dst, const SrcXprType& src) {
typedef typename DstXprType::Scalar Scalar;
call_assignment(dst.const_cast_derived(), src.derived(),
internal::div_assign_op<Scalar, typename SrcXprType::Scalar>());
}
template <typename DstXprType, typename SrcXprType>
void swap_using_evaluator(const DstXprType& dst, const SrcXprType& src) {
typedef typename DstXprType::Scalar Scalar;
call_assignment(dst.const_cast_derived(), src.const_cast_derived(), internal::swap_assign_op<Scalar>());
}
namespace internal {
template <typename Dst, template <typename> class StorageBase, typename Src, typename Func>
EIGEN_DEVICE_FUNC void call_assignment(const NoAlias<Dst, StorageBase>& dst, const Src& src, const Func& func) {
call_assignment_no_alias(dst.expression(), src, func);
}
template <typename Dst, template <typename> class StorageBase, typename Src, typename Func>
EIGEN_DEVICE_FUNC void call_restricted_packet_assignment(const NoAlias<Dst, StorageBase>& dst, const Src& src,
const Func& func) {
call_restricted_packet_assignment_no_alias(dst.expression(), src, func);
}
} // namespace internal
} // namespace Eigen
template <typename XprType>
long get_cost(const XprType&) {
return Eigen::internal::evaluator<XprType>::CoeffReadCost;
}
using namespace std;
#define VERIFY_IS_APPROX_EVALUATOR(DEST, EXPR) VERIFY_IS_APPROX(copy_using_evaluator(DEST, (EXPR)), (EXPR).eval());
#define VERIFY_IS_APPROX_EVALUATOR2(DEST, EXPR, REF) VERIFY_IS_APPROX(copy_using_evaluator(DEST, (EXPR)), (REF).eval());
EIGEN_DECLARE_TEST(evaluators) {
// Testing Matrix evaluator and Transpose
Vector2d v = Vector2d::Random();
const Vector2d v_const(v);
Vector2d v2;
RowVector2d w;
VERIFY_IS_APPROX_EVALUATOR(v2, v);
VERIFY_IS_APPROX_EVALUATOR(v2, v_const);
// Testing Transpose
VERIFY_IS_APPROX_EVALUATOR(w, v.transpose()); // Transpose as rvalue
VERIFY_IS_APPROX_EVALUATOR(w, v_const.transpose());
copy_using_evaluator(w.transpose(), v); // Transpose as lvalue
VERIFY_IS_APPROX(w, v.transpose().eval());
copy_using_evaluator(w.transpose(), v_const);
VERIFY_IS_APPROX(w, v_const.transpose().eval());
// Testing Array evaluator
{
ArrayXXf a(2, 3);
ArrayXXf b(3, 2);
a << 1, 2, 3, 4, 5, 6;
const ArrayXXf a_const(a);
VERIFY_IS_APPROX_EVALUATOR(b, a.transpose());
VERIFY_IS_APPROX_EVALUATOR(b, a_const.transpose());
// Testing CwiseNullaryOp evaluator
copy_using_evaluator(w, RowVector2d::Random());
VERIFY((w.array() >= -1).all() && (w.array() <= 1).all()); // not easy to test ...
VERIFY_IS_APPROX_EVALUATOR(w, RowVector2d::Zero());
VERIFY_IS_APPROX_EVALUATOR(w, RowVector2d::Constant(3));
// mix CwiseNullaryOp and transpose
VERIFY_IS_APPROX_EVALUATOR(w, Vector2d::Zero().transpose());
}
{
// test product expressions
int s = internal::random<int>(1, 100);
MatrixXf a(s, s), b(s, s), c(s, s), d(s, s);
a.setRandom();
b.setRandom();
c.setRandom();
d.setRandom();
VERIFY_IS_APPROX_EVALUATOR(d, (a + b));
VERIFY_IS_APPROX_EVALUATOR(d, (a + b).transpose());
VERIFY_IS_APPROX_EVALUATOR2(d, prod(a, b), a * b);
VERIFY_IS_APPROX_EVALUATOR2(d.noalias(), prod(a, b), a * b);
VERIFY_IS_APPROX_EVALUATOR2(d, prod(a, b) + c, a * b + c);
VERIFY_IS_APPROX_EVALUATOR2(d, s * prod(a, b), s * a * b);
VERIFY_IS_APPROX_EVALUATOR2(d, prod(a, b).transpose(), (a * b).transpose());
VERIFY_IS_APPROX_EVALUATOR2(d, prod(a, b) + prod(b, c), a * b + b * c);
// check that prod works even with aliasing present
c = a * a;
copy_using_evaluator(a, prod(a, a));
VERIFY_IS_APPROX(a, c);
// check compound assignment of products
d = c;
add_assign_using_evaluator(c.noalias(), prod(a, b));
d.noalias() += a * b;
VERIFY_IS_APPROX(c, d);
d = c;
subtract_assign_using_evaluator(c.noalias(), prod(a, b));
d.noalias() -= a * b;
VERIFY_IS_APPROX(c, d);
}
{
// test product with all possible sizes
int s = internal::random<int>(1, 100);
Matrix<float, 1, 1> m11, res11;
m11.setRandom(1, 1);
Matrix<float, 1, 4> m14, res14;
m14.setRandom(1, 4);
Matrix<float, 1, Dynamic> m1X, res1X;
m1X.setRandom(1, s);
Matrix<float, 4, 1> m41, res41;
m41.setRandom(4, 1);
Matrix<float, 4, 4> m44, res44;
m44.setRandom(4, 4);
Matrix<float, 4, Dynamic> m4X, res4X;
m4X.setRandom(4, s);
Matrix<float, Dynamic, 1> mX1, resX1;
mX1.setRandom(s, 1);
Matrix<float, Dynamic, 4> mX4, resX4;
mX4.setRandom(s, 4);
Matrix<float, Dynamic, Dynamic> mXX, resXX;
mXX.setRandom(s, s);
VERIFY_IS_APPROX_EVALUATOR2(res11, prod(m11, m11), m11 * m11);
VERIFY_IS_APPROX_EVALUATOR2(res11, prod(m14, m41), m14 * m41);
VERIFY_IS_APPROX_EVALUATOR2(res11, prod(m1X, mX1), m1X * mX1);
VERIFY_IS_APPROX_EVALUATOR2(res14, prod(m11, m14), m11 * m14);
VERIFY_IS_APPROX_EVALUATOR2(res14, prod(m14, m44), m14 * m44);
VERIFY_IS_APPROX_EVALUATOR2(res14, prod(m1X, mX4), m1X * mX4);
VERIFY_IS_APPROX_EVALUATOR2(res1X, prod(m11, m1X), m11 * m1X);
VERIFY_IS_APPROX_EVALUATOR2(res1X, prod(m14, m4X), m14 * m4X);
VERIFY_IS_APPROX_EVALUATOR2(res1X, prod(m1X, mXX), m1X * mXX);
VERIFY_IS_APPROX_EVALUATOR2(res41, prod(m41, m11), m41 * m11);
VERIFY_IS_APPROX_EVALUATOR2(res41, prod(m44, m41), m44 * m41);
VERIFY_IS_APPROX_EVALUATOR2(res41, prod(m4X, mX1), m4X * mX1);
VERIFY_IS_APPROX_EVALUATOR2(res44, prod(m41, m14), m41 * m14);
VERIFY_IS_APPROX_EVALUATOR2(res44, prod(m44, m44), m44 * m44);
VERIFY_IS_APPROX_EVALUATOR2(res44, prod(m4X, mX4), m4X * mX4);
VERIFY_IS_APPROX_EVALUATOR2(res4X, prod(m41, m1X), m41 * m1X);
VERIFY_IS_APPROX_EVALUATOR2(res4X, prod(m44, m4X), m44 * m4X);
VERIFY_IS_APPROX_EVALUATOR2(res4X, prod(m4X, mXX), m4X * mXX);
VERIFY_IS_APPROX_EVALUATOR2(resX1, prod(mX1, m11), mX1 * m11);
VERIFY_IS_APPROX_EVALUATOR2(resX1, prod(mX4, m41), mX4 * m41);
VERIFY_IS_APPROX_EVALUATOR2(resX1, prod(mXX, mX1), mXX * mX1);
VERIFY_IS_APPROX_EVALUATOR2(resX4, prod(mX1, m14), mX1 * m14);
VERIFY_IS_APPROX_EVALUATOR2(resX4, prod(mX4, m44), mX4 * m44);
VERIFY_IS_APPROX_EVALUATOR2(resX4, prod(mXX, mX4), mXX * mX4);
VERIFY_IS_APPROX_EVALUATOR2(resXX, prod(mX1, m1X), mX1 * m1X);
VERIFY_IS_APPROX_EVALUATOR2(resXX, prod(mX4, m4X), mX4 * m4X);
VERIFY_IS_APPROX_EVALUATOR2(resXX, prod(mXX, mXX), mXX * mXX);
}
{
ArrayXXf a(2, 3);
ArrayXXf b(3, 2);
a << 1, 2, 3, 4, 5, 6;
const ArrayXXf a_const(a);
// this does not work because Random is eval-before-nested:
// copy_using_evaluator(w, Vector2d::Random().transpose());
// test CwiseUnaryOp
VERIFY_IS_APPROX_EVALUATOR(v2, 3 * v);
VERIFY_IS_APPROX_EVALUATOR(w, (3 * v).transpose());
VERIFY_IS_APPROX_EVALUATOR(b, (a + 3).transpose());
VERIFY_IS_APPROX_EVALUATOR(b, (2 * a_const + 3).transpose());
// test CwiseBinaryOp
VERIFY_IS_APPROX_EVALUATOR(v2, v + Vector2d::Ones());
VERIFY_IS_APPROX_EVALUATOR(w, (v + Vector2d::Ones()).transpose().cwiseProduct(RowVector2d::Constant(3)));
// dynamic matrices and arrays
MatrixXd mat1(6, 6), mat2(6, 6);
VERIFY_IS_APPROX_EVALUATOR(mat1, MatrixXd::Identity(6, 6));
VERIFY_IS_APPROX_EVALUATOR(mat2, mat1);
copy_using_evaluator(mat2.transpose(), mat1);
VERIFY_IS_APPROX(mat2.transpose(), mat1);
ArrayXXd arr1(6, 6), arr2(6, 6);
VERIFY_IS_APPROX_EVALUATOR(arr1, ArrayXXd::Constant(6, 6, 3.0));
VERIFY_IS_APPROX_EVALUATOR(arr2, arr1);
// test automatic resizing
mat2.resize(3, 3);
VERIFY_IS_APPROX_EVALUATOR(mat2, mat1);
arr2.resize(9, 9);
VERIFY_IS_APPROX_EVALUATOR(arr2, arr1);
// test direct traversal
Matrix3f m3;
Array33f a3;
VERIFY_IS_APPROX_EVALUATOR(m3, Matrix3f::Identity()); // matrix, nullary
// TODO: find a way to test direct traversal with array
VERIFY_IS_APPROX_EVALUATOR(m3.transpose(), Matrix3f::Identity().transpose()); // transpose
VERIFY_IS_APPROX_EVALUATOR(m3, 2 * Matrix3f::Identity()); // unary
VERIFY_IS_APPROX_EVALUATOR(m3, Matrix3f::Identity() + Matrix3f::Zero()); // binary
VERIFY_IS_APPROX_EVALUATOR(m3.block(0, 0, 2, 2), Matrix3f::Identity().block(1, 1, 2, 2)); // block
// test linear traversal
VERIFY_IS_APPROX_EVALUATOR(m3, Matrix3f::Zero()); // matrix, nullary
VERIFY_IS_APPROX_EVALUATOR(a3, Array33f::Zero()); // array
VERIFY_IS_APPROX_EVALUATOR(m3.transpose(), Matrix3f::Zero().transpose()); // transpose
VERIFY_IS_APPROX_EVALUATOR(m3, 2 * Matrix3f::Zero()); // unary
VERIFY_IS_APPROX_EVALUATOR(m3, Matrix3f::Zero() + m3); // binary
// test inner vectorization
Matrix4f m4, m4src = Matrix4f::Random();
Array44f a4, a4src = Matrix4f::Random();
VERIFY_IS_APPROX_EVALUATOR(m4, m4src); // matrix
VERIFY_IS_APPROX_EVALUATOR(a4, a4src); // array
VERIFY_IS_APPROX_EVALUATOR(m4.transpose(), m4src.transpose()); // transpose
// TODO: find out why Matrix4f::Zero() does not allow inner vectorization
VERIFY_IS_APPROX_EVALUATOR(m4, 2 * m4src); // unary
VERIFY_IS_APPROX_EVALUATOR(m4, m4src + m4src); // binary
// test linear vectorization
MatrixXf mX(6, 6), mXsrc = MatrixXf::Random(6, 6);
ArrayXXf aX(6, 6), aXsrc = ArrayXXf::Random(6, 6);
VERIFY_IS_APPROX_EVALUATOR(mX, mXsrc); // matrix
VERIFY_IS_APPROX_EVALUATOR(aX, aXsrc); // array
VERIFY_IS_APPROX_EVALUATOR(mX.transpose(), mXsrc.transpose()); // transpose
VERIFY_IS_APPROX_EVALUATOR(mX, MatrixXf::Zero(6, 6)); // nullary
VERIFY_IS_APPROX_EVALUATOR(mX, 2 * mXsrc); // unary
VERIFY_IS_APPROX_EVALUATOR(mX, mXsrc + mXsrc); // binary
// test blocks and slice vectorization
VERIFY_IS_APPROX_EVALUATOR(m4, (mXsrc.block<4, 4>(1, 0)));
VERIFY_IS_APPROX_EVALUATOR(aX, ArrayXXf::Constant(10, 10, 3.0).block(2, 3, 6, 6));
Matrix4f m4ref = m4;
copy_using_evaluator(m4.block(1, 1, 2, 3), m3.bottomRows(2));
m4ref.block(1, 1, 2, 3) = m3.bottomRows(2);
VERIFY_IS_APPROX(m4, m4ref);
mX.setIdentity(20, 20);
MatrixXf mXref = MatrixXf::Identity(20, 20);
mXsrc = MatrixXf::Random(9, 12);
copy_using_evaluator(mX.block(4, 4, 9, 12), mXsrc);
mXref.block(4, 4, 9, 12) = mXsrc;
VERIFY_IS_APPROX(mX, mXref);
// test Map
const float raw[3] = {1, 2, 3};
float buffer[3] = {0, 0, 0};
Vector3f v3;
Array3f a3f;
VERIFY_IS_APPROX_EVALUATOR(v3, Map<const Vector3f>(raw));
VERIFY_IS_APPROX_EVALUATOR(a3f, Map<const Array3f>(raw));
Vector3f::Map(buffer) = 2 * v3;
VERIFY(buffer[0] == 2);
VERIFY(buffer[1] == 4);
VERIFY(buffer[2] == 6);
// test CwiseUnaryView
mat1.setRandom();
mat2.setIdentity();
MatrixXcd matXcd(6, 6), matXcd_ref(6, 6);
copy_using_evaluator(matXcd.real(), mat1);
copy_using_evaluator(matXcd.imag(), mat2);
matXcd_ref.real() = mat1;
matXcd_ref.imag() = mat2;
VERIFY_IS_APPROX(matXcd, matXcd_ref);
// test Select
VERIFY_IS_APPROX_EVALUATOR(aX, (aXsrc > 0).select(aXsrc, -aXsrc));
// test Replicate
mXsrc = MatrixXf::Random(6, 6);
VectorXf vX = VectorXf::Random(6);
mX.resize(6, 6);
VERIFY_IS_APPROX_EVALUATOR(mX, mXsrc.colwise() + vX);
matXcd.resize(12, 12);
VERIFY_IS_APPROX_EVALUATOR(matXcd, matXcd_ref.replicate(2, 2));
VERIFY_IS_APPROX_EVALUATOR(matXcd, (matXcd_ref.replicate<2, 2>()));
// test partial reductions
VectorXd vec1(6);
VERIFY_IS_APPROX_EVALUATOR(vec1, mat1.rowwise().sum());
VERIFY_IS_APPROX_EVALUATOR(vec1, mat1.colwise().sum().transpose());
// test MatrixWrapper and ArrayWrapper
mat1.setRandom(6, 6);
arr1.setRandom(6, 6);
VERIFY_IS_APPROX_EVALUATOR(mat2, arr1.matrix());
VERIFY_IS_APPROX_EVALUATOR(arr2, mat1.array());
VERIFY_IS_APPROX_EVALUATOR(mat2, (arr1 + 2).matrix());
VERIFY_IS_APPROX_EVALUATOR(arr2, mat1.array() + 2);
mat2.array() = arr1 * arr1;
VERIFY_IS_APPROX(mat2, (arr1 * arr1).matrix());
arr2.matrix() = MatrixXd::Identity(6, 6);
VERIFY_IS_APPROX(arr2, MatrixXd::Identity(6, 6).array());
// test Reverse
VERIFY_IS_APPROX_EVALUATOR(arr2, arr1.reverse());
VERIFY_IS_APPROX_EVALUATOR(arr2, arr1.colwise().reverse());
VERIFY_IS_APPROX_EVALUATOR(arr2, arr1.rowwise().reverse());
arr2.reverse() = arr1;
VERIFY_IS_APPROX(arr2, arr1.reverse());
mat2.array() = mat1.array().reverse();
VERIFY_IS_APPROX(mat2.array(), mat1.array().reverse());
// test Diagonal
VERIFY_IS_APPROX_EVALUATOR(vec1, mat1.diagonal());
vec1.resize(5);
VERIFY_IS_APPROX_EVALUATOR(vec1, mat1.diagonal(1));
VERIFY_IS_APPROX_EVALUATOR(vec1, mat1.diagonal<-1>());
vec1.setRandom();
mat2 = mat1;
copy_using_evaluator(mat1.diagonal(1), vec1);
mat2.diagonal(1) = vec1;
VERIFY_IS_APPROX(mat1, mat2);
copy_using_evaluator(mat1.diagonal<-1>(), mat1.diagonal(1));
mat2.diagonal<-1>() = mat2.diagonal(1);
VERIFY_IS_APPROX(mat1, mat2);
}
{
// test swapping
MatrixXd mat1, mat2, mat1ref, mat2ref;
mat1ref = mat1 = MatrixXd::Random(6, 6);
mat2ref = mat2 = 2 * mat1 + MatrixXd::Identity(6, 6);
swap_using_evaluator(mat1, mat2);
mat1ref.swap(mat2ref);
VERIFY_IS_APPROX(mat1, mat1ref);
VERIFY_IS_APPROX(mat2, mat2ref);
swap_using_evaluator(mat1.block(0, 0, 3, 3), mat2.block(3, 3, 3, 3));
mat1ref.block(0, 0, 3, 3).swap(mat2ref.block(3, 3, 3, 3));
VERIFY_IS_APPROX(mat1, mat1ref);
VERIFY_IS_APPROX(mat2, mat2ref);
swap_using_evaluator(mat1.row(2), mat2.col(3).transpose());
mat1.row(2).swap(mat2.col(3).transpose());
VERIFY_IS_APPROX(mat1, mat1ref);
VERIFY_IS_APPROX(mat2, mat2ref);
}
{
// test compound assignment
const Matrix4d mat_const = Matrix4d::Random();
Matrix4d mat, mat_ref;
mat = mat_ref = Matrix4d::Identity();
add_assign_using_evaluator(mat, mat_const);
mat_ref += mat_const;
VERIFY_IS_APPROX(mat, mat_ref);
subtract_assign_using_evaluator(mat.row(1), 2 * mat.row(2));
mat_ref.row(1) -= 2 * mat_ref.row(2);
VERIFY_IS_APPROX(mat, mat_ref);
const ArrayXXf arr_const = ArrayXXf::Random(5, 3);
ArrayXXf arr, arr_ref;
arr = arr_ref = ArrayXXf::Constant(5, 3, 0.5);
multiply_assign_using_evaluator(arr, arr_const);
arr_ref *= arr_const;
VERIFY_IS_APPROX(arr, arr_ref);
divide_assign_using_evaluator(arr.row(1), arr.row(2) + 1);
arr_ref.row(1) /= (arr_ref.row(2) + 1);
VERIFY_IS_APPROX(arr, arr_ref);
}
{
// test triangular shapes
MatrixXd A = MatrixXd::Random(6, 6), B(6, 6), C(6, 6), D(6, 6);
A.setRandom();
B.setRandom();
VERIFY_IS_APPROX_EVALUATOR2(B, A.triangularView<Upper>(), MatrixXd(A.triangularView<Upper>()));
A.setRandom();
B.setRandom();
VERIFY_IS_APPROX_EVALUATOR2(B, A.triangularView<UnitLower>(), MatrixXd(A.triangularView<UnitLower>()));
A.setRandom();
B.setRandom();
VERIFY_IS_APPROX_EVALUATOR2(B, A.triangularView<UnitUpper>(), MatrixXd(A.triangularView<UnitUpper>()));
A.setRandom();
B.setRandom();
C = B;
C.triangularView<Upper>() = A;
copy_using_evaluator(B.triangularView<Upper>(), A);
VERIFY(B.isApprox(C) && "copy_using_evaluator(B.triangularView<Upper>(), A)");
A.setRandom();
B.setRandom();
C = B;
C.triangularView<Lower>() = A.triangularView<Lower>();
copy_using_evaluator(B.triangularView<Lower>(), A.triangularView<Lower>());
VERIFY(B.isApprox(C) && "copy_using_evaluator(B.triangularView<Lower>(), A.triangularView<Lower>())");
A.setRandom();
B.setRandom();
C = B;
C.triangularView<Lower>() = A.triangularView<Upper>().transpose();
copy_using_evaluator(B.triangularView<Lower>(), A.triangularView<Upper>().transpose());
VERIFY(B.isApprox(C) && "copy_using_evaluator(B.triangularView<Lower>(), A.triangularView<Lower>().transpose())");
A.setRandom();
B.setRandom();
C = B;
D = A;
C.triangularView<Upper>().swap(D.triangularView<Upper>());
swap_using_evaluator(B.triangularView<Upper>(), A.triangularView<Upper>());
VERIFY(B.isApprox(C) && "swap_using_evaluator(B.triangularView<Upper>(), A.triangularView<Upper>())");
VERIFY_IS_APPROX_EVALUATOR2(B, prod(A.triangularView<Upper>(), A), MatrixXd(A.triangularView<Upper>() * A));
VERIFY_IS_APPROX_EVALUATOR2(B, prod(A.selfadjointView<Upper>(), A), MatrixXd(A.selfadjointView<Upper>() * A));
}
{
// test diagonal shapes
VectorXd d = VectorXd::Random(6);
MatrixXd A = MatrixXd::Random(6, 6), B(6, 6);
A.setRandom();
B.setRandom();
VERIFY_IS_APPROX_EVALUATOR2(B, lazyprod(d.asDiagonal(), A), MatrixXd(d.asDiagonal() * A));
VERIFY_IS_APPROX_EVALUATOR2(B, lazyprod(A, d.asDiagonal()), MatrixXd(A * d.asDiagonal()));
}
{
// test CoeffReadCost
Matrix4d a, b;
VERIFY_IS_EQUAL(get_cost(a), 1);
VERIFY_IS_EQUAL(get_cost(a + b), 3);
VERIFY_IS_EQUAL(get_cost(2 * a + b), 4);
VERIFY_IS_EQUAL(get_cost(a * b), 1);
VERIFY_IS_EQUAL(get_cost(a.lazyProduct(b)), 15);
VERIFY_IS_EQUAL(get_cost(a * (a * b)), 1);
VERIFY_IS_EQUAL(get_cost(a.lazyProduct(a * b)), 15);
VERIFY_IS_EQUAL(get_cost(a * (a + b)), 1);
VERIFY_IS_EQUAL(get_cost(a.lazyProduct(a + b)), 15);
}
// regression test for PR 544 and bug 1622 (introduced in #71609c4)
{
// test restricted_packet_assignment with an unaligned destination
const size_t M = 2;
const size_t K = 2;
const size_t N = 5;
float* destMem = new float[(M * N) + 1];
// In case of no alignment, avoid division by zero.
constexpr int alignment = (std::max<int>)(EIGEN_MAX_ALIGN_BYTES, 1);
float* dest = (std::uintptr_t(destMem) % alignment) == 0 ? destMem + 1 : destMem;
const Matrix<float, Dynamic, Dynamic, RowMajor> a = Matrix<float, Dynamic, Dynamic, RowMajor>::Random(M, K);
const Matrix<float, Dynamic, Dynamic, RowMajor> b = Matrix<float, Dynamic, Dynamic, RowMajor>::Random(K, N);
Map<Matrix<float, Dynamic, Dynamic, RowMajor> > z(dest, M, N);
;
Product<Matrix<float, Dynamic, Dynamic, RowMajor>, Matrix<float, Dynamic, Dynamic, RowMajor>, LazyProduct> tmp(a,
b);
internal::call_restricted_packet_assignment(z.noalias(), tmp.derived(), internal::assign_op<float, float>());
VERIFY_IS_APPROX(z, a * b);
delete[] destMem;
}
}