namespace Eigen { /** \page TopicAliasing Aliasing In Eigen, aliasing refers to assignment statement in which the same matrix (or array or vector) appears on the left and on the right of the assignment operators. Statements like mat = 2 * mat; or mat = mat.transpose(); exhibit aliasing. The aliasing in the first example is harmless, but the aliasing in the second example leads to unexpected results. This page explains what aliasing is, when it is harmful, and what to do about it. Table of contents - \ref TopicAliasingExamples - \ref TopicAliasingSolution - \ref TopicAliasingCwise - \ref TopicAliasingMatrixMult - \ref TopicAliasingSummary \section TopicAliasingExamples Examples Here is a simple example exhibiting aliasing:
ExampleOutput
\include TopicAliasing_block.cpp \verbinclude TopicAliasing_block.out
The output is not what one would expect. The problem is the assignment \code mat.bottomRightCorner(2,2) = mat.topLeftCorner(2,2); \endcode This assignment exhibits aliasing: the coefficient \c mat(1,1) appears both in the block mat.bottomRightCorner(2,2) on the left-hand side of the assignment and the block mat.topLeftCorner(2,2) on the right-hand side. After the assignment, the (2,2) entry in the bottom right corner should have the value of \c mat(1,1) before the assignment, which is 5. However, the output shows that \c mat(2,2) is actually 1. The problem is that Eigen uses lazy evaluation (see \ref TopicEigenExpressionTemplates) for mat.topLeftCorner(2,2). The result is similar to \code mat(1,1) = mat(0,0); mat(1,2) = mat(0,1); mat(2,1) = mat(1,0); mat(2,2) = mat(1,1); \endcode Thus, \c mat(2,2) is assigned the \e new value of \c mat(1,1) instead of the old value. The next section explains how to solve this problem by calling \link DenseBase::eval() eval()\endlink. Note that if \c mat were a bigger, then the blocks would not overlap, and there would be no aliasing problem. This means that in general aliasing cannot be detected at compile time. However, Eigen does detect some instances of aliasing, albeit at run time. The following example exhibiting aliasing was mentioned in \ref TutorialMatrixArithmetic :
ExampleOutput
\include tut_arithmetic_transpose_aliasing.cpp \verbinclude tut_arithmetic_transpose_aliasing.out
Again, the output shows the aliasing issue. However, by default Eigen uses a run-time assertion to detect this and exits with a message like \verbatim void Eigen::DenseBase::checkTransposeAliasing(const OtherDerived&) const [with OtherDerived = Eigen::Transpose >, Derived = Eigen::Matrix]: Assertion `(!internal::check_transpose_aliasing_selector::IsTransposed,OtherDerived>::run(internal::extract_data(derived()), other)) && "aliasing detected during tranposition, use transposeInPlace() or evaluate the rhs into a temporary using .eval()"' failed. \endverbatim The user can turn Eigen's run-time assertions like the one to detect this aliasing problem off by defining the #EIGEN_NO_DEBUG macro, and the above program was compiled with this macro turned off in order to illustrate the aliasing problem. See \ref TopicAssertions for more information about Eigen's run-time assertions. \section TopicAliasingSolution Resolving aliasing issues If you understand the cause of the aliasing issue, then it is obvious what must happen to solve it: Eigen has to evaluate the right-hand side fully into a temporary matrix/array and then assign it to the left-hand side. The function \link DenseBase::eval() eval() \endlink does precisely that. For example, here is the corrected version of the first example above:
ExampleOutput
\include TopicAliasing_block_correct.cpp \verbinclude TopicAliasing_block_correct.out
Now, \c mat(2,2) equals 5 after the assignment, as it should be. The same solution also works for the second example, with the transpose: simply replace the line a = a.transpose(); with a = a.transpose().eval();. However, in this common case there is a better solution. Eigen provides the special-purpose function \link DenseBase::transposeInPlace() transposeInPlace() \endlink which replaces a matrix by its transpose. This is shown below:
ExampleOutput
\include tut_arithmetic_transpose_inplace.cpp \verbinclude tut_arithmetic_transpose_inplace.out
If an xxxInPlace() function is available, then it is best to use it, because it indicates more clearly what you are doing. This may also allow Eigen to optimize more aggressively. These are some of the xxxInPlace() functions provided:
Original functionIn-place function
MatrixBase::adjoint() MatrixBase::adjointInPlace()
DenseBase::reverse() DenseBase::reverseInPlace()
LDLT::solve() LDLT::solveInPlace()
LLT::solve() LLT::solveInPlace()
TriangularView::solve() TriangularView::solveInPlace()
DenseBase::transpose() DenseBase::transposeInPlace()
\section TopicAliasingCwise Aliasing and component-wise operations Synopsis: Things like mat = 2 * mat, matA = matA + matB and arr = arr.sin() are safe. \section TopicAliasingMatrixMult Aliasing and matrix multiplication Synopsis: %Matrix multiplication assumes aliasing by default. Use noalias() to improve performance if there is no aliasing. \section TopicAliasingSummary Summary Aliasing occurs when the same matrix or array coefficients appear both on the left- and the right-hand side of an assignment operator. - Aliasing is harmless with coefficient-wise computations; this includes scalar multiplication and matrix or array addition. - When you multiply two matrices, Eigen assumes that aliasing occurs. If you know that there is no aliasing, then you can use \link MatrixBase::noalias() noalias()\endlink. - In all other situations, Eigen assumes that there is no aliasing issue and thus gives the wrong result if aliasing does in fact occur. To prevent this, you have to use \link DenseBase::eval() eval() \endlink or one of the xxxInPlace() functions. */ }