LAPACK

LAPACK ("Linear Algebra Package") is a standard software library for numerical linear algebra. It provides routines for solving systems of linear equations and linear least squares, eigenvalue problems, and singular value decomposition. It also includes routines to implement the associated matrix factorizations such as LU, QR, Cholesky and Schur decomposition. LAPACK was originally written in FORTRAN 77, but moved to Fortran 90 in version 3.2 (2008). The routines handle both real and complex matrices in both single and double precision. LAPACK relies on an underlying BLAS implementation to provide efficient and portable computational building blocks for its routines.

LAPACK was designed as the successor to the linear equations and linear least-squares routines of LINPACK and the eigenvalue routines of EISPACK. LINPACK, written in the 1970s and 1980s, was designed to run on the then-modern vector computers with shared memory. LAPACK, in contrast, was designed to effectively exploit the caches on modern cache-based architectures and the instruction-level parallelism of modern superscalar processors, and thus can run orders of magnitude faster than LINPACK on such machines, given a well-tuned BLAS implementation. LAPACK has also been extended to run on distributed memory systems in later packages such as ScaLAPACK and PLAPACK.

Netlib LAPACK is licensed under a three-clause BSD style license, a permissive free software license with few restrictions.

Naming scheme
Subroutines in LAPACK have a naming convention which makes the identifiers very compact. This was necessary as the first Fortran standards only supported identifiers up to six characters long, so the names had to be shortened to fit into this limit.

A LAPACK subroutine name is in the form, where:


 * is a one-letter code denoting the type of numerical constants used.,   stand for real floating-point arithmetic respectively in single and double precision, while   and   stand for complex arithmetic with respectively single and double precision. The newer version, LAPACK95, uses generic subroutines in order to overcome the need to explicitly specify the data type.
 * is a two-letter code denoting the kind of matrix expected by the algorithm. The codes for the different kind of matrices are reported below; the actual data are stored in a different format depending on the specific kind; e.g., when the code  is given, the subroutine expects a vector of length   containing the elements on the diagonal, while when the code   is given, the subroutine expects an $n×n$ array containing the entries of the matrix.
 * is a one- to three-letter code describing the actual algorithm implemented in the subroutine, e.g.  denotes a subroutine to solve linear system, while   denotes a rank-1 update.

For example, the subroutine to solve a linear system with a general (non-structured) matrix using real double-precision arithmetic is called.

Use with other programming languages and libraries
Many programming environments today support the use of libraries with C binding, allowing LAPACK routines to be used directly so long as a few restrictions are observed. Additionally, many other software libraries and tools for scientific and numerical computing are built on top of LAPACK, such as R, MATLAB, and SciPy.

Several alternative language bindings are also available:


 * Armadillo for C++
 * IT++ for C++
 * LAPACK++ for C++
 * Lacaml for OCaml
 * CLapack for C
 * SciPy for Python
 * Gonum for Go
 * NLapack for .NET
 * CControl for C in embedded systems
 * lapack for rust

Implementations
As with BLAS, LAPACK is sometimes forked or rewritten to provide better performance on specific systems. Some of the implementations are:


 * Accelerate: Apple's framework for macOS and iOS, which includes tuned versions of BLAS and LAPACK.
 * Netlib LAPACK: The official LAPACK.
 * Netlib ScaLAPACK: Scalable (multicore) LAPACK, built on top of PBLAS.
 * Intel MKL: Intel's Math routines for their x86 CPUs.
 * OpenBLAS: Open-source reimplementation of BLAS and LAPACK.
 * Gonum LAPACK: A partial native Go implementation.

Since LAPACK typically calls underlying BLAS routines to perform the bulk of its computations, simply linking to a better-tuned BLAS implementation can be enough to significantly improve performance. As a result, LAPACK is not reimplemented as often as BLAS is.

Similar projects
These projects provide a similar functionality to LAPACK, but with a main interface differing from that of LAPACK:


 * Libflame: A dense linear algebra library. Has a LAPACK-compatible wrapper. Can be used with any BLAS, although BLIS is the preferred implementation.
 * Eigen: A header library for linear algebra. Has a BLAS and a partial LAPACK implementation for compatibility.
 * MAGMA: Matrix Algebra on GPU and Multicore Architectures (MAGMA) project develops a dense linear algebra library similar to LAPACK but for heterogeneous and hybrid architectures including multicore systems accelerated with GPGPUs.
 * PLASMA: The Parallel Linear Algebra for Scalable Multi-core Architectures (PLASMA) project is a modern replacement of LAPACK for multi-core architectures. PLASMA is a software framework for development of asynchronous operations and features out of order scheduling with a runtime scheduler called QUARK that may be used for any code that expresses its dependencies with a directed acyclic graph.