Introduction hwloc provides command line tools and a C API to obtain the hierarchical map of key computing elements, such as: NUMA memory nodes, shared caches, processor packages, processor cores, processing units (logical processors or "threads") and even I/O devices. hwloc also gathers various attributes such as cache and memory information, and is portable across a variety of different operating systems and platforms. Additionally it may assemble the topologies of multiple machines into a single one so as to let applications consult the topology of an entire fabric or cluster at once. hwloc primarily aims at helping high-performance computing (HPC) applications, but is also applicable to any project seeking to exploit code and/or data locality on modern computing platforms. hwloc supports the following operating systems: * Linux (including old kernels not having sysfs topology information, with knowledge of cpusets, ScaleMP vSMP and Kerrighed support, etc.) on all supported hardware, including Intel Xeon Phi and NumaScale NumaConnect. * Solaris (with support for processor sets and logical domains) * AIX * Darwin / OS X * FreeBSD and its variants (such as kFreeBSD/GNU) * NetBSD * OSF/1 (a.k.a., Tru64) * HP-UX * Microsoft Windows * IBM BlueGene/Q Compute Node Kernel (CNK) Since it uses standard Operating System information, hwloc's support is mostly independant from the processor type (x86, powerpc, ...) and just relies on the Operating System support. The main exception is BSD operating systems (NetBSD, FreeBSD, etc.) because they do not provide support topology information, hence hwloc uses an x86-only CPUID-based backend (which can be used for other OSes too, see the Components and plugins section). To check whether hwloc works on a particular machine, just try to build it and run lstopo or lstopo-no-graphics. If some things do not look right (e.g. bogus or missing cache information), see Questions and Bugs below. hwloc only reports the number of processors on unsupported operating systems; no topology information is available. For development and debugging purposes, hwloc also offers the ability to work on "fake" topologies: * Symmetrical tree of resources generated from a list of level arities, see Synthetic topologies. * Remote machine simulation through the gathering of topology as XML files, see Importing and exporting topologies from/to XML files. hwloc can display the topology in a human-readable format, either in graphical mode (X11), or by exporting in one of several different formats, including: plain text, PDF, PNG, and FIG (see Command-line Examples below). Note that some of the export formats require additional support libraries. hwloc offers a programming interface for manipulating topologies and objects. It also brings a powerful CPU bitmap API that is used to describe topology objects location on physical/logical processors. See the Programming Interface below. It may also be used to binding applications onto certain cores or memory nodes. Several utility programs are also provided to ease command-line manipulation of topology objects, binding of processes, and so on. Perl bindings are available from Bernd Kallies on CPAN. Python bindings are available from Guy Streeter: * Fedora RPM and tarball. * git tree (html). See https://www.open-mpi.org/projects/hwloc/doc/ for more hwloc documentation.