fuchsia / third_party / eigen / bc25605ec2d13f9bd386b3d697d23d896d4c3a7b / . / doc / HiPerformance.dox

namespace Eigen { | |

/** \page TopicWritingEfficientProductExpression Writing efficient matrix product expressions | |

In general achieving good performance with Eigen does no require any special effort: | |

simply write your expressions in the most high level way. This is especially true | |

for small fixed size matrices. For large matrices, however, it might be useful to | |

take some care when writing your expressions in order to minimize useless evaluations | |

and optimize the performance. | |

In this page we will give a brief overview of the Eigen's internal mechanism to simplify | |

and evaluate complex product expressions, and discuss the current limitations. | |

In particular we will focus on expressions matching level 2 and 3 BLAS routines, i.e, | |

all kind of matrix products and triangular solvers. | |

Indeed, in Eigen we have implemented a set of highly optimized routines which are very similar | |

to BLAS's ones. Unlike BLAS, those routines are made available to user via a high level and | |

natural API. Each of these routines can compute in a single evaluation a wide variety of expressions. | |

Given an expression, the challenge is then to map it to a minimal set of routines. | |

As explained latter, this mechanism has some limitations, and knowing them will allow | |

you to write faster code by making your expressions more Eigen friendly. | |

\section GEMM General Matrix-Matrix product (GEMM) | |

Let's start with the most common primitive: the matrix product of general dense matrices. | |

In the BLAS world this corresponds to the GEMM routine. Our equivalent primitive can | |

perform the following operation: | |

\f$ C.noalias() += \alpha op1(A) op2(B) \f$ | |

where A, B, and C are column and/or row major matrices (or sub-matrices), | |

alpha is a scalar value, and op1, op2 can be transpose, adjoint, conjugate, or the identity. | |

When Eigen detects a matrix product, it analyzes both sides of the product to extract a | |

unique scalar factor alpha, and for each side, its effective storage order, shape, and conjugation states. | |

More precisely each side is simplified by iteratively removing trivial expressions such as scalar multiple, | |

negation and conjugation. Transpose and Block expressions are not evaluated and they only modify the storage order | |

and shape. All other expressions are immediately evaluated. | |

For instance, the following expression: | |

\code m1.noalias() -= s4 * (s1 * m2.adjoint() * (-(s3*m3).conjugate()*s2)) \endcode | |

is automatically simplified to: | |

\code m1.noalias() += (s1*s2*conj(s3)*s4) * m2.adjoint() * m3.conjugate() \endcode | |

which exactly matches our GEMM routine. | |

\subsection GEMM_Limitations Limitations | |

Unfortunately, this simplification mechanism is not perfect yet and not all expressions which could be | |

handled by a single GEMM-like call are correctly detected. | |

<table class="manual" style="width:100%"> | |

<tr> | |

<th>Not optimal expression</th> | |

<th>Evaluated as</th> | |

<th>Optimal version (single evaluation)</th> | |

<th>Comments</th> | |

</tr> | |

<tr> | |

<td>\code | |

m1 += m2 * m3; \endcode</td> | |

<td>\code | |

temp = m2 * m3; | |

m1 += temp; \endcode</td> | |

<td>\code | |

m1.noalias() += m2 * m3; \endcode</td> | |

<td>Use .noalias() to tell Eigen the result and right-hand-sides do not alias. | |

Otherwise the product m2 * m3 is evaluated into a temporary.</td> | |

</tr> | |

<tr class="alt"> | |

<td></td> | |

<td></td> | |

<td>\code | |

m1.noalias() += s1 * (m2 * m3); \endcode</td> | |

<td>This is a special feature of Eigen. Here the product between a scalar | |

and a matrix product does not evaluate the matrix product but instead it | |

returns a matrix product expression tracking the scalar scaling factor. <br> | |

Without this optimization, the matrix product would be evaluated into a | |

temporary as in the next example.</td> | |

</tr> | |

<tr> | |

<td>\code | |

m1.noalias() += (m2 * m3).adjoint(); \endcode</td> | |

<td>\code | |

temp = m2 * m3; | |

m1 += temp.adjoint(); \endcode</td> | |

<td>\code | |

m1.noalias() += m3.adjoint() | |

* * m2.adjoint(); \endcode</td> | |

<td>This is because the product expression has the EvalBeforeNesting bit which | |

enforces the evaluation of the product by the Tranpose expression.</td> | |

</tr> | |

<tr class="alt"> | |

<td>\code | |

m1 = m1 + m2 * m3; \endcode</td> | |

<td>\code | |

temp = m2 * m3; | |

m1 = m1 + temp; \endcode</td> | |

<td>\code m1.noalias() += m2 * m3; \endcode</td> | |

<td>Here there is no way to detect at compile time that the two m1 are the same, | |

and so the matrix product will be immediately evaluated.</td> | |

</tr> | |

<tr> | |

<td>\code | |

m1.noalias() = m4 + m2 * m3; \endcode</td> | |

<td>\code | |

temp = m2 * m3; | |

m1 = m4 + temp; \endcode</td> | |

<td>\code | |

m1 = m4; | |

m1.noalias() += m2 * m3; \endcode</td> | |

<td>First of all, here the .noalias() in the first expression is useless because | |

m2*m3 will be evaluated anyway. However, note how this expression can be rewritten | |

so that no temporary is required. (tip: for very small fixed size matrix | |

it is slighlty better to rewrite it like this: m1.noalias() = m2 * m3; m1 += m4;</td> | |

</tr> | |

<tr class="alt"> | |

<td>\code | |

m1.noalias() += (s1*m2).block(..) * m3; \endcode</td> | |

<td>\code | |

temp = (s1*m2).block(..); | |

m1 += temp * m3; \endcode</td> | |

<td>\code | |

m1.noalias() += s1 * m2.block(..) * m3; \endcode</td> | |

<td>This is because our expression analyzer is currently not able to extract trivial | |

expressions nested in a Block expression. Therefore the nested scalar | |

multiple cannot be properly extracted.</td> | |

</tr> | |

</table> | |

Of course all these remarks hold for all other kind of products involving triangular or selfadjoint matrices. | |

*/ | |

} |