/* * Copyright © 2009 CNRS * Copyright © 2009-2022 Inria. All rights reserved. * Copyright © 2009-2012 Université Bordeaux * Copyright © 2009-2020 Cisco Systems, Inc. All rights reserved. * See COPYING in top-level directory. */ /*===================================================================== * PLEASE GO READ THE DOCUMENTATION! * ------------------------------------------------ * $tarball_directory/doc/doxygen-doc/ * or * https://www.open-mpi.org/projects/hwloc/doc/ *===================================================================== * * FAIR WARNING: Do NOT expect to be able to figure out all the * subtleties of hwloc by simply reading function prototypes and * constant descrptions here in this file. * * Hwloc has wonderful documentation in both PDF and HTML formats for * your reading pleasure. The formal documentation explains a LOT of * hwloc-specific concepts, provides definitions, and discusses the * "big picture" for many of the things that you'll find here in this * header file. * * The PDF/HTML documentation was generated via Doxygen; much of what * you'll see in there is also here in this file. BUT THERE IS A LOT * THAT IS IN THE PDF/HTML THAT IS ***NOT*** IN hwloc.h! * * There are entire paragraph-length descriptions, discussions, and * pretty pictures to explain subtle corner cases, provide concrete * examples, etc. * * Please, go read the documentation. :-) * * Moreover there are several examples of hwloc use under doc/examples * in the source tree. * *=====================================================================*/ /** \file * \brief The hwloc API. * * See hwloc/bitmap.h for bitmap specific macros. * See hwloc/helper.h for high-level topology traversal helpers. * See hwloc/inlines.h for the actual inline code of some functions below. * See hwloc/export.h for exporting topologies to XML or to synthetic descriptions. * See hwloc/distances.h for querying and modifying distances between objects. * See hwloc/diff.h for manipulating differences between similar topologies. */ #ifndef HWLOC_H #define HWLOC_H #include "hwloc/autogen/config.h" #include #include #include #include /* * Symbol transforms */ #include "hwloc/rename.h" /* * Bitmap definitions */ #include "hwloc/bitmap.h" #ifdef __cplusplus extern "C" { #endif /** \defgroup hwlocality_api_error_reporting Error reporting in the API * @{ * Most functions in the hwloc API return an integer value. * Unless documentated differently, they return 0 on success * and -1 on error. * Functions that return a pointer type return \c NULL on error. * * \p errno will be set to a meaningful value whenever possible. * This includes the usual \c EINVAL when invalid function parameters are passed * or \c ENOMEM when an internal allocation fails. * Some specific \c errno value are also used, for instance for binding * errors as documented in \ref hwlocality_cpubinding. * * Some modules describe return values of their functions * in their introduction, for instance in \ref hwlocality_bitmap. * @} */ /** \defgroup hwlocality_api_version API version * @{ */ /** \brief Indicate at build time which hwloc API version is being used. * * This number is updated to (X<<16)+(Y<<8)+Z when a new release X.Y.Z * actually modifies the API. * * Users may check for available features at build time using this number * (see \ref faq_version_api). * * \note This should not be confused with HWLOC_VERSION, the library version. * Two stable releases of the same series usually have the same ::HWLOC_API_VERSION * even if their HWLOC_VERSION are different. */ #define HWLOC_API_VERSION 0x00020800 /** \brief Indicate at runtime which hwloc API version was used at build time. * * Should be ::HWLOC_API_VERSION if running on the same version. * * \return the build-time version number. */ HWLOC_DECLSPEC unsigned hwloc_get_api_version(void); /** \brief Current component and plugin ABI version (see hwloc/plugins.h) */ #define HWLOC_COMPONENT_ABI 7 /** @} */ /** \defgroup hwlocality_object_sets Object Sets (hwloc_cpuset_t and hwloc_nodeset_t) * * Hwloc uses bitmaps to represent two distinct kinds of object sets: * CPU sets (::hwloc_cpuset_t) and NUMA node sets (::hwloc_nodeset_t). * These types are both typedefs to a common back end type * (::hwloc_bitmap_t), and therefore all the hwloc bitmap functions * are applicable to both ::hwloc_cpuset_t and ::hwloc_nodeset_t (see * \ref hwlocality_bitmap). * * The rationale for having two different types is that even though * the actions one wants to perform on these types are the same (e.g., * enable and disable individual items in the set/mask), they're used * in very different contexts: one for specifying which processors to * use and one for specifying which NUMA nodes to use. Hence, the * name difference is really just to reflect the intent of where the * type is used. * * @{ */ /** \brief A CPU set is a bitmap whose bits are set according to CPU * physical OS indexes. * * It may be consulted and modified with the bitmap API as any * ::hwloc_bitmap_t (see hwloc/bitmap.h). * * Each bit may be converted into a PU object using * hwloc_get_pu_obj_by_os_index(). */ typedef hwloc_bitmap_t hwloc_cpuset_t; /** \brief A non-modifiable ::hwloc_cpuset_t. */ typedef hwloc_const_bitmap_t hwloc_const_cpuset_t; /** \brief A node set is a bitmap whose bits are set according to NUMA * memory node physical OS indexes. * * It may be consulted and modified with the bitmap API as any * ::hwloc_bitmap_t (see hwloc/bitmap.h). * Each bit may be converted into a NUMA node object using * hwloc_get_numanode_obj_by_os_index(). * * When binding memory on a system without any NUMA node, * the single main memory bank is considered as NUMA node #0. * * See also \ref hwlocality_helper_nodeset_convert. */ typedef hwloc_bitmap_t hwloc_nodeset_t; /** \brief A non-modifiable ::hwloc_nodeset_t. */ typedef hwloc_const_bitmap_t hwloc_const_nodeset_t; /** @} */ /** \defgroup hwlocality_object_types Object Types * @{ */ /** \brief Type of topology object. * * \note Do not rely on the ordering or completeness of the values as new ones * may be defined in the future! If you need to compare types, use * hwloc_compare_types() instead. */ typedef enum { /** \cond */ #define HWLOC_OBJ_TYPE_MIN HWLOC_OBJ_MACHINE /* Sentinel value */ /** \endcond */ HWLOC_OBJ_MACHINE, /**< \brief Machine. * A set of processors and memory with cache * coherency. * * This type is always used for the root object of a topology, * and never used anywhere else. * Hence its parent is always \c NULL. */ HWLOC_OBJ_PACKAGE, /**< \brief Physical package. * The physical package that usually gets inserted * into a socket on the motherboard. * A processor package usually contains multiple cores, * and possibly some dies. */ HWLOC_OBJ_CORE, /**< \brief Core. * A computation unit (may be shared by several * PUs, aka logical processors). */ HWLOC_OBJ_PU, /**< \brief Processing Unit, or (Logical) Processor. * An execution unit (may share a core with some * other logical processors, e.g. in the case of * an SMT core). * * This is the smallest object representing CPU resources, * it cannot have any child except Misc objects. * * Objects of this kind are always reported and can * thus be used as fallback when others are not. */ HWLOC_OBJ_L1CACHE, /**< \brief Level 1 Data (or Unified) Cache. */ HWLOC_OBJ_L2CACHE, /**< \brief Level 2 Data (or Unified) Cache. */ HWLOC_OBJ_L3CACHE, /**< \brief Level 3 Data (or Unified) Cache. */ HWLOC_OBJ_L4CACHE, /**< \brief Level 4 Data (or Unified) Cache. */ HWLOC_OBJ_L5CACHE, /**< \brief Level 5 Data (or Unified) Cache. */ HWLOC_OBJ_L1ICACHE, /**< \brief Level 1 instruction Cache (filtered out by default). */ HWLOC_OBJ_L2ICACHE, /**< \brief Level 2 instruction Cache (filtered out by default). */ HWLOC_OBJ_L3ICACHE, /**< \brief Level 3 instruction Cache (filtered out by default). */ HWLOC_OBJ_GROUP, /**< \brief Group objects. * Objects which do not fit in the above but are * detected by hwloc and are useful to take into * account for affinity. For instance, some operating systems * expose their arbitrary processors aggregation this * way. And hwloc may insert such objects to group * NUMA nodes according to their distances. * See also \ref faq_groups. * * These objects are removed when they do not bring * any structure (see ::HWLOC_TYPE_FILTER_KEEP_STRUCTURE). */ HWLOC_OBJ_NUMANODE, /**< \brief NUMA node. * An object that contains memory that is directly * and byte-accessible to the host processors. * It is usually close to some cores (the corresponding objects * are descendants of the NUMA node object in the hwloc tree). * * This is the smallest object representing Memory resources, * it cannot have any child except Misc objects. * However it may have Memory-side cache parents. * * There is always at least one such object in the topology * even if the machine is not NUMA. * * Memory objects are not listed in the main children list, * but rather in the dedicated Memory children list. * * NUMA nodes have a special depth ::HWLOC_TYPE_DEPTH_NUMANODE * instead of a normal depth just like other objects in the * main tree. */ HWLOC_OBJ_BRIDGE, /**< \brief Bridge (filtered out by default). * Any bridge (or PCI switch) that connects the host or an I/O bus, * to another I/O bus. * * Bridges are not added to the topology unless their * filtering is changed (see hwloc_topology_set_type_filter() * and hwloc_topology_set_io_types_filter()). * * I/O objects are not listed in the main children list, * but rather in the dedicated io children list. * I/O objects have NULL CPU and node sets. */ HWLOC_OBJ_PCI_DEVICE, /**< \brief PCI device (filtered out by default). * * PCI devices are not added to the topology unless their * filtering is changed (see hwloc_topology_set_type_filter() * and hwloc_topology_set_io_types_filter()). * * I/O objects are not listed in the main children list, * but rather in the dedicated io children list. * I/O objects have NULL CPU and node sets. */ HWLOC_OBJ_OS_DEVICE, /**< \brief Operating system device (filtered out by default). * * OS devices are not added to the topology unless their * filtering is changed (see hwloc_topology_set_type_filter() * and hwloc_topology_set_io_types_filter()). * * I/O objects are not listed in the main children list, * but rather in the dedicated io children list. * I/O objects have NULL CPU and node sets. */ HWLOC_OBJ_MISC, /**< \brief Miscellaneous objects (filtered out by default). * Objects without particular meaning, that can e.g. be * added by the application for its own use, or by hwloc * for miscellaneous objects such as MemoryModule (DIMMs). * * They are not added to the topology unless their filtering * is changed (see hwloc_topology_set_type_filter()). * * These objects are not listed in the main children list, * but rather in the dedicated misc children list. * Misc objects may only have Misc objects as children, * and those are in the dedicated misc children list as well. * Misc objects have NULL CPU and node sets. */ HWLOC_OBJ_MEMCACHE, /**< \brief Memory-side cache (filtered out by default). * A cache in front of a specific NUMA node. * * This object always has at least one NUMA node as a memory child. * * Memory objects are not listed in the main children list, * but rather in the dedicated Memory children list. * * Memory-side cache have a special depth ::HWLOC_TYPE_DEPTH_MEMCACHE * instead of a normal depth just like other objects in the * main tree. */ HWLOC_OBJ_DIE, /**< \brief Die within a physical package. * A subpart of the physical package, that contains multiple cores. */ HWLOC_OBJ_TYPE_MAX /**< \private Sentinel value */ } hwloc_obj_type_t; /** \brief Cache type. */ typedef enum hwloc_obj_cache_type_e { HWLOC_OBJ_CACHE_UNIFIED, /**< \brief Unified cache. */ HWLOC_OBJ_CACHE_DATA, /**< \brief Data cache. */ HWLOC_OBJ_CACHE_INSTRUCTION /**< \brief Instruction cache (filtered out by default). */ } hwloc_obj_cache_type_t; /** \brief Type of one side (upstream or downstream) of an I/O bridge. */ typedef enum hwloc_obj_bridge_type_e { HWLOC_OBJ_BRIDGE_HOST, /**< \brief Host-side of a bridge, only possible upstream. */ HWLOC_OBJ_BRIDGE_PCI /**< \brief PCI-side of a bridge. */ } hwloc_obj_bridge_type_t; /** \brief Type of a OS device. */ typedef enum hwloc_obj_osdev_type_e { HWLOC_OBJ_OSDEV_BLOCK, /**< \brief Operating system block device, or non-volatile memory device. * For instance "sda" or "dax2.0" on Linux. */ HWLOC_OBJ_OSDEV_GPU, /**< \brief Operating system GPU device. * For instance ":0.0" for a GL display, * "card0" for a Linux DRM device. */ HWLOC_OBJ_OSDEV_NETWORK, /**< \brief Operating system network device. * For instance the "eth0" interface on Linux. */ HWLOC_OBJ_OSDEV_OPENFABRICS, /**< \brief Operating system openfabrics device. * For instance the "mlx4_0" InfiniBand HCA, * "hfi1_0" Omni-Path interface, * or "bxi0" Atos/Bull BXI HCA on Linux. */ HWLOC_OBJ_OSDEV_DMA, /**< \brief Operating system dma engine device. * For instance the "dma0chan0" DMA channel on Linux. */ HWLOC_OBJ_OSDEV_COPROC /**< \brief Operating system co-processor device. * For instance "opencl0d0" for a OpenCL device, * "cuda0" for a CUDA device. */ } hwloc_obj_osdev_type_t; /** \brief Compare the depth of two object types * * Types shouldn't be compared as they are, since newer ones may be added in * the future. * * \return A negative integer if \p type1 objects usually include \p type2 objects. * \return A positive integer if \p type1 objects are usually included in \p type2 objects. * \return 0 if \p type1 and \p type2 objects are the same. * \return ::HWLOC_TYPE_UNORDERED if objects cannot be compared * (because neither is usually contained in the other). * * \note Object types containing CPUs can always be compared * (usually, a machine contains packages, which contain caches, * which contain cores, which contain PUs). * * \note ::HWLOC_OBJ_PU will always be the deepest, * while ::HWLOC_OBJ_MACHINE is always the highest. * * \note This does not mean that the actual topology will respect that order: * e.g. as of today cores may also contain caches, and packages may also contain * nodes. This is thus just to be seen as a fallback comparison method. */ HWLOC_DECLSPEC int hwloc_compare_types (hwloc_obj_type_t type1, hwloc_obj_type_t type2) __hwloc_attribute_const; /** \brief Value returned by hwloc_compare_types() when types can not be compared. \hideinitializer */ #define HWLOC_TYPE_UNORDERED INT_MAX /** @} */ /** \defgroup hwlocality_objects Object Structure and Attributes * @{ */ union hwloc_obj_attr_u; /** \brief Structure of a topology object * * Applications must not modify any field except \p hwloc_obj.userdata. */ struct hwloc_obj { /* physical information */ hwloc_obj_type_t type; /**< \brief Type of object */ char *subtype; /**< \brief Subtype string to better describe the type field. */ unsigned os_index; /**< \brief OS-provided physical index number. * It is not guaranteed unique across the entire machine, * except for PUs and NUMA nodes. * Set to HWLOC_UNKNOWN_INDEX if unknown or irrelevant for this object. */ #define HWLOC_UNKNOWN_INDEX (unsigned)-1 char *name; /**< \brief Object-specific name if any. * Mostly used for identifying OS devices and Misc objects where * a name string is more useful than numerical indexes. */ hwloc_uint64_t total_memory; /**< \brief Total memory (in bytes) in NUMA nodes below this object. */ union hwloc_obj_attr_u *attr; /**< \brief Object type-specific Attributes, * may be \c NULL if no attribute value was found */ /* global position */ int depth; /**< \brief Vertical index in the hierarchy. * * For normal objects, this is the depth of the horizontal level * that contains this object and its cousins of the same type. * If the topology is symmetric, this is equal to the parent depth * plus one, and also equal to the number of parent/child links * from the root object to here. * * For special objects (NUMA nodes, I/O and Misc) that are not * in the main tree, this is a special negative value that * corresponds to their dedicated level, * see hwloc_get_type_depth() and ::hwloc_get_type_depth_e. * Those special values can be passed to hwloc functions such * hwloc_get_nbobjs_by_depth() as usual. */ unsigned logical_index; /**< \brief Horizontal index in the whole list of similar objects, * hence guaranteed unique across the entire machine. * Could be a "cousin_rank" since it's the rank within the "cousin" list below * Note that this index may change when restricting the topology * or when inserting a group. */ /* cousins are all objects of the same type (and depth) across the entire topology */ struct hwloc_obj *next_cousin; /**< \brief Next object of same type and depth */ struct hwloc_obj *prev_cousin; /**< \brief Previous object of same type and depth */ /* children of the same parent are siblings, even if they may have different type and depth */ struct hwloc_obj *parent; /**< \brief Parent, \c NULL if root (Machine object) */ unsigned sibling_rank; /**< \brief Index in parent's \c children[] array. Or the index in parent's Memory, I/O or Misc children list. */ struct hwloc_obj *next_sibling; /**< \brief Next object below the same parent (inside the same list of children). */ struct hwloc_obj *prev_sibling; /**< \brief Previous object below the same parent (inside the same list of children). */ /** @name List and array of normal children below this object (except Memory, I/O and Misc children). */ /**@{*/ unsigned arity; /**< \brief Number of normal children. * Memory, Misc and I/O children are not listed here * but rather in their dedicated children list. */ struct hwloc_obj **children; /**< \brief Normal children, \c children[0 .. arity -1] */ struct hwloc_obj *first_child; /**< \brief First normal child */ struct hwloc_obj *last_child; /**< \brief Last normal child */ /**@}*/ int symmetric_subtree; /**< \brief Set if the subtree of normal objects below this object is symmetric, * which means all normal children and their children have identical subtrees. * * Memory, I/O and Misc children are ignored. * * If set in the topology root object, lstopo may export the topology * as a synthetic string. */ /** @name List of Memory children below this object. */ /**@{*/ unsigned memory_arity; /**< \brief Number of Memory children. * These children are listed in \p memory_first_child. */ struct hwloc_obj *memory_first_child; /**< \brief First Memory child. * NUMA nodes and Memory-side caches are listed here * (\p memory_arity and \p memory_first_child) * instead of in the normal children list. * See also hwloc_obj_type_is_memory(). * * A memory hierarchy starts from a normal CPU-side object * (e.g. Package) and ends with NUMA nodes as leaves. * There might exist some memory-side caches between them * in the middle of the memory subtree. */ /**@}*/ /** @name List of I/O children below this object. */ /**@{*/ unsigned io_arity; /**< \brief Number of I/O children. * These children are listed in \p io_first_child. */ struct hwloc_obj *io_first_child; /**< \brief First I/O child. * Bridges, PCI and OS devices are listed here (\p io_arity and \p io_first_child) * instead of in the normal children list. * See also hwloc_obj_type_is_io(). */ /**@}*/ /** @name List of Misc children below this object. */ /**@{*/ unsigned misc_arity; /**< \brief Number of Misc children. * These children are listed in \p misc_first_child. */ struct hwloc_obj *misc_first_child; /**< \brief First Misc child. * Misc objects are listed here (\p misc_arity and \p misc_first_child) * instead of in the normal children list. */ /**@}*/ /* cpusets and nodesets */ hwloc_cpuset_t cpuset; /**< \brief CPUs covered by this object * * This is the set of CPUs for which there are PU objects in the topology * under this object, i.e. which are known to be physically contained in this * object and known how (the children path between this object and the PU * objects). * * If the ::HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED configuration flag is set, * some of these CPUs may be online but not allowed for binding, * see hwloc_topology_get_allowed_cpuset(). * * \note All objects have non-NULL CPU and node sets except Misc and I/O objects. * * \note Its value must not be changed, hwloc_bitmap_dup() must be used instead. */ hwloc_cpuset_t complete_cpuset; /**< \brief The complete CPU set of processors of this object, * * This may include not only the same as the cpuset field, but also some CPUs for * which topology information is unknown or incomplete, some offlines CPUs, and * the CPUs that are ignored when the ::HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED flag * is not set. * Thus no corresponding PU object may be found in the topology, because the * precise position is undefined. It is however known that it would be somewhere * under this object. * * \note Its value must not be changed, hwloc_bitmap_dup() must be used instead. */ hwloc_nodeset_t nodeset; /**< \brief NUMA nodes covered by this object or containing this object * * This is the set of NUMA nodes for which there are NUMA node objects in the * topology under or above this object, i.e. which are known to be physically * contained in this object or containing it and known how (the children path * between this object and the NUMA node objects). * * In the end, these nodes are those that are close to the current object. * Function hwloc_get_local_numanode_objs() may be used to list those NUMA * nodes more precisely. * * If the ::HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED configuration flag is set, * some of these nodes may be online but not allowed for allocation, * see hwloc_topology_get_allowed_nodeset(). * * If there are no NUMA nodes in the machine, all the memory is close to this * object, so only the first bit may be set in \p nodeset. * * \note All objects have non-NULL CPU and node sets except Misc and I/O objects. * * \note Its value must not be changed, hwloc_bitmap_dup() must be used instead. */ hwloc_nodeset_t complete_nodeset; /**< \brief The complete NUMA node set of this object, * * This may include not only the same as the nodeset field, but also some NUMA * nodes for which topology information is unknown or incomplete, some offlines * nodes, and the nodes that are ignored when the ::HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED * flag is not set. * Thus no corresponding NUMA node object may be found in the topology, because the * precise position is undefined. It is however known that it would be * somewhere under this object. * * If there are no NUMA nodes in the machine, all the memory is close to this * object, so only the first bit is set in \p complete_nodeset. * * \note Its value must not be changed, hwloc_bitmap_dup() must be used instead. */ struct hwloc_info_s *infos; /**< \brief Array of info attributes (name and value strings). */ unsigned infos_count; /**< \brief Size of infos array. */ /* misc */ void *userdata; /**< \brief Application-given private data pointer, * initialized to \c NULL, use it as you wish. * See hwloc_topology_set_userdata_export_callback() in hwloc/export.h * if you wish to export this field to XML. */ hwloc_uint64_t gp_index; /**< \brief Global persistent index. * Generated by hwloc, unique across the topology (contrary to os_index) * and persistent across topology changes (contrary to logical_index). * Mostly used internally, but could also be used by application to identify objects. */ }; /** * \brief Convenience typedef; a pointer to a struct hwloc_obj. */ typedef struct hwloc_obj * hwloc_obj_t; /** \brief Object type-specific Attributes */ union hwloc_obj_attr_u { /** \brief NUMA node-specific Object Attributes */ struct hwloc_numanode_attr_s { hwloc_uint64_t local_memory; /**< \brief Local memory (in bytes) */ unsigned page_types_len; /**< \brief Size of array \p page_types */ /** \brief Array of local memory page types, \c NULL if no local memory and \p page_types is 0. * * The array is sorted by increasing \p size fields. * It contains \p page_types_len slots. */ struct hwloc_memory_page_type_s { hwloc_uint64_t size; /**< \brief Size of pages */ hwloc_uint64_t count; /**< \brief Number of pages of this size */ } * page_types; } numanode; /** \brief Cache-specific Object Attributes */ struct hwloc_cache_attr_s { hwloc_uint64_t size; /**< \brief Size of cache in bytes */ unsigned depth; /**< \brief Depth of cache (e.g., L1, L2, ...etc.) */ unsigned linesize; /**< \brief Cache-line size in bytes. 0 if unknown */ int associativity; /**< \brief Ways of associativity, * -1 if fully associative, 0 if unknown */ hwloc_obj_cache_type_t type; /**< \brief Cache type */ } cache; /** \brief Group-specific Object Attributes */ struct hwloc_group_attr_s { unsigned depth; /**< \brief Depth of group object. * It may change if intermediate Group objects are added. */ unsigned kind; /**< \brief Internally-used kind of group. */ unsigned subkind; /**< \brief Internally-used subkind to distinguish different levels of groups with same kind */ unsigned char dont_merge; /**< \brief Flag preventing groups from being automatically merged with identical parent or children. */ } group; /** \brief PCI Device specific Object Attributes */ struct hwloc_pcidev_attr_s { #ifndef HWLOC_HAVE_32BITS_PCI_DOMAIN unsigned short domain; /* Only 16bits PCI domains are supported by default */ #else unsigned int domain; /* 32bits PCI domain support break the library ABI, hence it's disabled by default */ #endif unsigned char bus, dev, func; unsigned short class_id; unsigned short vendor_id, device_id, subvendor_id, subdevice_id; unsigned char revision; float linkspeed; /* in GB/s */ } pcidev; /** \brief Bridge specific Object Attributes */ struct hwloc_bridge_attr_s { union { struct hwloc_pcidev_attr_s pci; } upstream; hwloc_obj_bridge_type_t upstream_type; union { struct { #ifndef HWLOC_HAVE_32BITS_PCI_DOMAIN unsigned short domain; /* Only 16bits PCI domains are supported by default */ #else unsigned int domain; /* 32bits PCI domain support break the library ABI, hence it's disabled by default */ #endif unsigned char secondary_bus, subordinate_bus; } pci; } downstream; hwloc_obj_bridge_type_t downstream_type; unsigned depth; } bridge; /** \brief OS Device specific Object Attributes */ struct hwloc_osdev_attr_s { hwloc_obj_osdev_type_t type; } osdev; }; /** \brief Object info attribute (name and value strings) * * \sa hwlocality_info_attr */ struct hwloc_info_s { char *name; /**< \brief Info name */ char *value; /**< \brief Info value */ }; /** @} */ /** \defgroup hwlocality_creation Topology Creation and Destruction * @{ */ struct hwloc_topology; /** \brief Topology context * * To be initialized with hwloc_topology_init() and built with hwloc_topology_load(). */ typedef struct hwloc_topology * hwloc_topology_t; /** \brief Allocate a topology context. * * \param[out] topologyp is assigned a pointer to the new allocated context. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_init (hwloc_topology_t *topologyp); /** \brief Build the actual topology * * Build the actual topology once initialized with hwloc_topology_init() and * tuned with \ref hwlocality_configuration and \ref hwlocality_setsource routines. * No other routine may be called earlier using this topology context. * * \param topology is the topology to be loaded with objects. * * \return 0 on success, -1 on error. * * \note On failure, the topology is reinitialized. It should be either * destroyed with hwloc_topology_destroy() or configured and loaded again. * * \note This function may be called only once per topology. * * \note The binding of the current thread or process may temporarily change * during this call but it will be restored before it returns. * * \sa hwlocality_configuration and hwlocality_setsource */ HWLOC_DECLSPEC int hwloc_topology_load(hwloc_topology_t topology); /** \brief Terminate and free a topology context * * \param topology is the topology to be freed */ HWLOC_DECLSPEC void hwloc_topology_destroy (hwloc_topology_t topology); /** \brief Duplicate a topology. * * The entire topology structure as well as its objects * are duplicated into a new one. * * This is useful for keeping a backup while modifying a topology. * * \return 0 on success, -1 on error. * * \note Object userdata is not duplicated since hwloc does not know what it point to. * The objects of both old and new topologies will point to the same userdata. */ HWLOC_DECLSPEC int hwloc_topology_dup(hwloc_topology_t *newtopology, hwloc_topology_t oldtopology); /** \brief Verify that the topology is compatible with the current hwloc library. * * This is useful when using the same topology structure (in memory) * in different libraries that may use different hwloc installations * (for instance if one library embeds a specific version of hwloc, * while another library uses a default system-wide hwloc installation). * * If all libraries/programs use the same hwloc installation, this function * always returns success. * * \return \c 0 on success. * * \return \c -1 with \p errno set to \c EINVAL if incompatible. * * \note If sharing between processes with hwloc_shmem_topology_write(), * the relevant check is already performed inside hwloc_shmem_topology_adopt(). */ HWLOC_DECLSPEC int hwloc_topology_abi_check(hwloc_topology_t topology); /** \brief Run internal checks on a topology structure * * The program aborts if an inconsistency is detected in the given topology. * * \param topology is the topology to be checked * * \note This routine is only useful to developers. * * \note The input topology should have been previously loaded with * hwloc_topology_load(). */ HWLOC_DECLSPEC void hwloc_topology_check(hwloc_topology_t topology); /** @} */ /** \defgroup hwlocality_levels Object levels, depths and types * @{ * * Be sure to see the figure in \ref termsanddefs that shows a * complete topology tree, including depths, child/sibling/cousin * relationships, and an example of an asymmetric topology where one * package has fewer caches than its peers. */ /** \brief Get the depth of the hierarchical tree of objects. * * This is the depth of ::HWLOC_OBJ_PU objects plus one. * * \return the depth of the object tree. * * \note NUMA nodes, I/O and Misc objects are ignored when computing * the depth of the tree (they are placed on special levels). */ HWLOC_DECLSPEC int hwloc_topology_get_depth(hwloc_topology_t __hwloc_restrict topology) __hwloc_attribute_pure; /** \brief Returns the depth of objects of type \p type. * * \return The depth of objects of type \p type. * * \return A negative virtual depth if a NUMA node, I/O or Misc object type is given. * These objects are stored in special levels that are not CPU-related. * This virtual depth may be passed to other hwloc functions such as * hwloc_get_obj_by_depth() but it should not be considered as an actual * depth by the application. In particular, it should not be compared with * any other object depth or with the entire topology depth. * * \return ::HWLOC_TYPE_DEPTH_UNKNOWN * if no object of this type is present on the underlying architecture, * or if the OS doesn't provide this kind of information. * * \return ::HWLOC_TYPE_DEPTH_MULTIPLE if type ::HWLOC_OBJ_GROUP is given * and multiple levels of Groups exist. * * \note If the type is absent but a similar type is acceptable, see also * hwloc_get_type_or_below_depth() and hwloc_get_type_or_above_depth(). * * \sa hwloc_get_memory_parents_depth() for managing the depth of memory objects. * * \sa hwloc_type_sscanf_as_depth() for returning the depth of objects * whose type is given as a string. */ HWLOC_DECLSPEC int hwloc_get_type_depth (hwloc_topology_t topology, hwloc_obj_type_t type); enum hwloc_get_type_depth_e { HWLOC_TYPE_DEPTH_UNKNOWN = -1, /**< \brief No object of given type exists in the topology. \hideinitializer */ HWLOC_TYPE_DEPTH_MULTIPLE = -2, /**< \brief Objects of given type exist at different depth in the topology (only for Groups). \hideinitializer */ HWLOC_TYPE_DEPTH_NUMANODE = -3, /**< \brief Virtual depth for NUMA nodes. \hideinitializer */ HWLOC_TYPE_DEPTH_BRIDGE = -4, /**< \brief Virtual depth for bridge object level. \hideinitializer */ HWLOC_TYPE_DEPTH_PCI_DEVICE = -5, /**< \brief Virtual depth for PCI device object level. \hideinitializer */ HWLOC_TYPE_DEPTH_OS_DEVICE = -6, /**< \brief Virtual depth for software device object level. \hideinitializer */ HWLOC_TYPE_DEPTH_MISC = -7, /**< \brief Virtual depth for Misc object. \hideinitializer */ HWLOC_TYPE_DEPTH_MEMCACHE = -8 /**< \brief Virtual depth for MemCache object. \hideinitializer */ }; /** \brief Return the depth of parents where memory objects are attached. * * Memory objects have virtual negative depths because they are not part of * the main CPU-side hierarchy of objects. This depth should not be compared * with other level depths. * * If all Memory objects are attached to Normal parents at the same depth, * this parent depth may be compared to other as usual, for instance * for knowing whether NUMA nodes is attached above or below Packages. * * \return The depth of Normal parents of all memory children * if all these parents have the same depth. For instance the depth of * the Package level if all NUMA nodes are attached to Package objects. * * \return ::HWLOC_TYPE_DEPTH_MULTIPLE if Normal parents of all * memory children do not have the same depth. For instance if some * NUMA nodes are attached to Packages while others are attached to * Groups. */ HWLOC_DECLSPEC int hwloc_get_memory_parents_depth (hwloc_topology_t topology); /** \brief Returns the depth of objects of type \p type or below * * If no object of this type is present on the underlying architecture, the * function returns the depth of the first "present" object typically found * inside \p type. * * This function is only meaningful for normal object types. * If a memory, I/O or Misc object type is given, the corresponding virtual * depth is always returned (see hwloc_get_type_depth()). * * May return ::HWLOC_TYPE_DEPTH_MULTIPLE for ::HWLOC_OBJ_GROUP just like * hwloc_get_type_depth(). */ static __hwloc_inline int hwloc_get_type_or_below_depth (hwloc_topology_t topology, hwloc_obj_type_t type) __hwloc_attribute_pure; /** \brief Returns the depth of objects of type \p type or above * * If no object of this type is present on the underlying architecture, the * function returns the depth of the first "present" object typically * containing \p type. * * This function is only meaningful for normal object types. * If a memory, I/O or Misc object type is given, the corresponding virtual * depth is always returned (see hwloc_get_type_depth()). * * May return ::HWLOC_TYPE_DEPTH_MULTIPLE for ::HWLOC_OBJ_GROUP just like * hwloc_get_type_depth(). */ static __hwloc_inline int hwloc_get_type_or_above_depth (hwloc_topology_t topology, hwloc_obj_type_t type) __hwloc_attribute_pure; /** \brief Returns the type of objects at depth \p depth. * * \p depth should between 0 and hwloc_topology_get_depth()-1, * or a virtual depth such as ::HWLOC_TYPE_DEPTH_NUMANODE. * * \return The type of objects at depth \p depth. * \return (hwloc_obj_type_t)-1 if depth \p depth does not exist. */ HWLOC_DECLSPEC hwloc_obj_type_t hwloc_get_depth_type (hwloc_topology_t topology, int depth) __hwloc_attribute_pure; /** \brief Returns the width of level at depth \p depth. * * \return The number of objects at topology depth \p depth. * \return 0 if there are no objects at depth \p depth. */ HWLOC_DECLSPEC unsigned hwloc_get_nbobjs_by_depth (hwloc_topology_t topology, int depth) __hwloc_attribute_pure; /** \brief Returns the width of level type \p type * * \return The number of objects of type \p type. * \return -1 if there are multiple levels with objects of that type, e.g. ::HWLOC_OBJ_GROUP. * \return 0 if there are no objects at depth \p depth. */ static __hwloc_inline int hwloc_get_nbobjs_by_type (hwloc_topology_t topology, hwloc_obj_type_t type) __hwloc_attribute_pure; /** \brief Returns the top-object of the topology-tree. * * Its type is ::HWLOC_OBJ_MACHINE. * * This function cannot return \c NULL. */ static __hwloc_inline hwloc_obj_t hwloc_get_root_obj (hwloc_topology_t topology) __hwloc_attribute_pure; /** \brief Returns the topology object at logical index \p idx from depth \p depth * * \return The object if it exists. * \return \c NULL if there is no object with this index and depth. */ HWLOC_DECLSPEC hwloc_obj_t hwloc_get_obj_by_depth (hwloc_topology_t topology, int depth, unsigned idx) __hwloc_attribute_pure; /** \brief Returns the topology object at logical index \p idx with type \p type * * \return The object if it exists. * \return \c NULL if there is no object with this index and type. * \return \c NULL if there are multiple levels with objects of that type (e.g. ::HWLOC_OBJ_GROUP), * the caller may fallback to hwloc_get_obj_by_depth(). */ static __hwloc_inline hwloc_obj_t hwloc_get_obj_by_type (hwloc_topology_t topology, hwloc_obj_type_t type, unsigned idx) __hwloc_attribute_pure; /** \brief Returns the next object at depth \p depth. * * \return The first object at depth \p depth if \p prev is \c NULL. * \return The object after \p prev at depth \p depth if \p prev is not \c NULL. * \return \c NULL if there is no such object. */ static __hwloc_inline hwloc_obj_t hwloc_get_next_obj_by_depth (hwloc_topology_t topology, int depth, hwloc_obj_t prev); /** \brief Returns the next object of type \p type. * * \return The first object of type \p type if \p prev is \c NULL. * \return The object after \p prev of type \p type if \p prev is not \c NULL. * \return \c NULL if there is no such object. * \return \c NULL if there are multiple levels with objects of that type (e.g. ::HWLOC_OBJ_GROUP), * the caller may fallback to hwloc_get_obj_by_depth(). */ static __hwloc_inline hwloc_obj_t hwloc_get_next_obj_by_type (hwloc_topology_t topology, hwloc_obj_type_t type, hwloc_obj_t prev); /** @} */ /** \defgroup hwlocality_object_strings Converting between Object Types and Attributes, and Strings * @{ */ /** \brief Return a constant stringified object type. * * This function is the basic way to convert a generic type into a string. * The output string may be parsed back by hwloc_type_sscanf(). * * hwloc_obj_type_snprintf() may return a more precise output for a specific * object, but it requires the caller to provide the output buffer. * * \return A constant string containing the object type name or \c "Unknown". */ HWLOC_DECLSPEC const char * hwloc_obj_type_string (hwloc_obj_type_t type) __hwloc_attribute_const; /** \brief Stringify the type of a given topology object into a human-readable form. * * Contrary to hwloc_obj_type_string(), this function includes object-specific * attributes (such as the Group depth, the Bridge type, or OS device type) * in the output, and it requires the caller to provide the output buffer. * * The output is guaranteed to be the same for all objects of a same topology level. * * If \p verbose is 1, longer type names are used, e.g. L1Cache instead of L1. * * The output string may be parsed back by hwloc_type_sscanf(). * * If \p size is 0, \p string may safely be \c NULL. * * \return the number of characters that were actually written if not truncating, * or that would have been written (not including the ending \\0). */ HWLOC_DECLSPEC int hwloc_obj_type_snprintf(char * __hwloc_restrict string, size_t size, hwloc_obj_t obj, int verbose); /** \brief Stringify the attributes of a given topology object into a human-readable form. * * Attribute values are separated by \p separator. * * Only the major attributes are printed in non-verbose mode. * * If \p size is 0, \p string may safely be \c NULL. * * \return the number of characters that were actually written if not truncating, * or that would have been written (not including the ending \\0). */ HWLOC_DECLSPEC int hwloc_obj_attr_snprintf(char * __hwloc_restrict string, size_t size, hwloc_obj_t obj, const char * __hwloc_restrict separator, int verbose); /** \brief Return an object type and attributes from a type string. * * Convert strings such as "Package" or "L1iCache" into the corresponding types. * Matching is case-insensitive, and only the first letters are actually * required to match. * * The matched object type is set in \p typep (which cannot be \c NULL). * * Type-specific attributes, for instance Cache type, Cache depth, Group depth, * Bridge type or OS Device type may be returned in \p attrp. * Attributes that are not specified in the string (for instance "Group" * without a depth, or "L2Cache" without a cache type) are set to -1. * * \p attrp is only filled if not \c NULL and if its size specified in \p attrsize * is large enough. It should be at least as large as union hwloc_obj_attr_u. * * \return 0 if a type was correctly identified, otherwise -1. * * \note This function is guaranteed to match any string returned by * hwloc_obj_type_string() or hwloc_obj_type_snprintf(). * * \note This is an extended version of the now deprecated hwloc_obj_type_sscanf(). */ HWLOC_DECLSPEC int hwloc_type_sscanf(const char *string, hwloc_obj_type_t *typep, union hwloc_obj_attr_u *attrp, size_t attrsize); /** \brief Return an object type and its level depth from a type string. * * Convert strings such as "Package" or "L1iCache" into the corresponding types * and return in \p depthp the depth of the corresponding level in the * topology \p topology. * * If no object of this type is present on the underlying architecture, * ::HWLOC_TYPE_DEPTH_UNKNOWN is returned. * * If multiple such levels exist (for instance if giving Group without any depth), * the function may return ::HWLOC_TYPE_DEPTH_MULTIPLE instead. * * The matched object type is set in \p typep if \p typep is non \c NULL. * * \note This function is similar to hwloc_type_sscanf() followed * by hwloc_get_type_depth() but it also automatically disambiguates * multiple group levels etc. * * \note This function is guaranteed to match any string returned by * hwloc_obj_type_string() or hwloc_obj_type_snprintf(). */ HWLOC_DECLSPEC int hwloc_type_sscanf_as_depth(const char *string, hwloc_obj_type_t *typep, hwloc_topology_t topology, int *depthp); /** @} */ /** \defgroup hwlocality_info_attr Consulting and Adding Info Attributes * * @{ */ /** \brief Search the given name in object infos and return the corresponding value. * * If multiple info attributes match the given name, only the first one is returned. * * \return A pointer to the value string if it exists. * \return \c NULL if no such info attribute exists. * * \note The string should not be freed by the caller, it belongs to the hwloc library. */ static __hwloc_inline const char * hwloc_obj_get_info_by_name(hwloc_obj_t obj, const char *name) __hwloc_attribute_pure; /** \brief Add the given name and value pair to the given object info attributes. * * The info pair is appended to the existing info array even if another pair * with the same name already exists. * * The input strings are copied before being added in the object infos. * * \return \c 0 on success, \c -1 on error. * * \note This function may be used to enforce object colors in the lstopo * graphical output by adding "lstopoStyle" as a name and "Background=#rrggbb" * as a value. See CUSTOM COLORS in the lstopo(1) manpage for details. * * \note If \p name or \p value contain some non-printable characters, they will * be dropped when exporting to XML, see hwloc_topology_export_xml() in hwloc/export.h. */ HWLOC_DECLSPEC int hwloc_obj_add_info(hwloc_obj_t obj, const char *name, const char *value); /** @} */ /** \defgroup hwlocality_cpubinding CPU binding * * Some operating systems only support binding threads or processes to a single PU. * Others allow binding to larger sets such as entire Cores or Packages or * even random sets of individual PUs. In such operating system, the scheduler * is free to run the task on one of these PU, then migrate it to another PU, etc. * It is often useful to call hwloc_bitmap_singlify() on the target CPU set before * passing it to the binding function to avoid these expensive migrations. * See the documentation of hwloc_bitmap_singlify() for details. * * Some operating systems do not provide all hwloc-supported * mechanisms to bind processes, threads, etc. * hwloc_topology_get_support() may be used to query about the actual CPU * binding support in the currently used operating system. * * When the requested binding operation is not available and the * ::HWLOC_CPUBIND_STRICT flag was passed, the function returns -1. * \p errno is set to \c ENOSYS when it is not possible to bind the requested kind of object * processes/threads. errno is set to \c EXDEV when the requested cpuset * can not be enforced (e.g. some systems only allow one CPU, and some * other systems only allow one NUMA node). * * If ::HWLOC_CPUBIND_STRICT was not passed, the function may fail as well, * or the operating system may use a slightly different operation * (with side-effects, smaller binding set, etc.) * when the requested operation is not exactly supported. * * The most portable version that should be preferred over the others, * whenever possible, is the following one which just binds the current program, * assuming it is single-threaded: * * \code * hwloc_set_cpubind(topology, set, 0), * \endcode * * If the program may be multithreaded, the following one should be preferred * to only bind the current thread: * * \code * hwloc_set_cpubind(topology, set, HWLOC_CPUBIND_THREAD), * \endcode * * \sa Some example codes are available under doc/examples/ in the source tree. * * \note To unbind, just call the binding function with either a full cpuset or * a cpuset equal to the system cpuset. * * \note On some operating systems, CPU binding may have effects on memory binding, see * ::HWLOC_CPUBIND_NOMEMBIND * * \note Running lstopo \--top or hwloc-ps can be a very convenient tool to check * how binding actually happened. * @{ */ /** \brief Process/Thread binding flags. * * These bit flags can be used to refine the binding policy. * * The default (0) is to bind the current process, assumed to be * single-threaded, in a non-strict way. This is the most portable * way to bind as all operating systems usually provide it. * * \note Not all systems support all kinds of binding. See the * "Detailed Description" section of \ref hwlocality_cpubinding for a * description of errors that can occur. */ typedef enum { /** \brief Bind all threads of the current (possibly) multithreaded process. * \hideinitializer */ HWLOC_CPUBIND_PROCESS = (1<<0), /** \brief Bind current thread of current process. * \hideinitializer */ HWLOC_CPUBIND_THREAD = (1<<1), /** \brief Request for strict binding from the OS. * * By default, when the designated CPUs are all busy while other * CPUs are idle, operating systems may execute the thread/process * on those other CPUs instead of the designated CPUs, to let them * progress anyway. Strict binding means that the thread/process * will _never_ execute on other CPUs than the designated CPUs, even * when those are busy with other tasks and other CPUs are idle. * * \note Depending on the operating system, strict binding may not * be possible (e.g., the OS does not implement it) or not allowed * (e.g., for an administrative reasons), and the function will fail * in that case. * * When retrieving the binding of a process, this flag checks * whether all its threads actually have the same binding. If the * flag is not given, the binding of each thread will be * accumulated. * * \note This flag is meaningless when retrieving the binding of a * thread. * \hideinitializer */ HWLOC_CPUBIND_STRICT = (1<<2), /** \brief Avoid any effect on memory binding * * On some operating systems, some CPU binding function would also * bind the memory on the corresponding NUMA node. It is often not * a problem for the application, but if it is, setting this flag * will make hwloc avoid using OS functions that would also bind * memory. This will however reduce the support of CPU bindings, * i.e. potentially return -1 with errno set to \c ENOSYS in some * cases. * * This flag is only meaningful when used with functions that set * the CPU binding. It is ignored when used with functions that get * CPU binding information. * \hideinitializer */ HWLOC_CPUBIND_NOMEMBIND = (1<<3) } hwloc_cpubind_flags_t; /** \brief Bind current process or thread on CPUs given in physical bitmap \p set. * * \return 0 on success. * \return -1 with errno set to \c ENOSYS if the action is not supported. * \return -1 with errno set to \c EXDEV if the binding cannot be enforced. */ HWLOC_DECLSPEC int hwloc_set_cpubind(hwloc_topology_t topology, hwloc_const_cpuset_t set, int flags); /** \brief Get current process or thread binding. * * The CPU-set \p set (previously allocated by the caller) * is filled with the list of PUs which the process or * thread (according to \e flags) was last bound to. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_get_cpubind(hwloc_topology_t topology, hwloc_cpuset_t set, int flags); /** \brief Bind a process \p pid on CPUs given in physical bitmap \p set. * * \return 0 on success, -1 on error. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note As a special case on Linux, if a tid (thread ID) is supplied * instead of a pid (process ID) and ::HWLOC_CPUBIND_THREAD is passed in flags, * the binding is applied to that specific thread. * * \note On non-Linux systems, ::HWLOC_CPUBIND_THREAD can not be used in \p flags. */ HWLOC_DECLSPEC int hwloc_set_proc_cpubind(hwloc_topology_t topology, hwloc_pid_t pid, hwloc_const_cpuset_t set, int flags); /** \brief Get the current physical binding of process \p pid. * * The CPU-set \p set (previously allocated by the caller) * is filled with the list of PUs which the process * was last bound to. * * \return 0 on success, -1 on error. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note As a special case on Linux, if a tid (thread ID) is supplied * instead of a pid (process ID) and HWLOC_CPUBIND_THREAD is passed in flags, * the binding for that specific thread is returned. * * \note On non-Linux systems, HWLOC_CPUBIND_THREAD can not be used in \p flags. */ HWLOC_DECLSPEC int hwloc_get_proc_cpubind(hwloc_topology_t topology, hwloc_pid_t pid, hwloc_cpuset_t set, int flags); #ifdef hwloc_thread_t /** \brief Bind a thread \p thread on CPUs given in physical bitmap \p set. * * \return 0 on success, -1 on error. * * \note \p hwloc_thread_t is \p pthread_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note ::HWLOC_CPUBIND_PROCESS can not be used in \p flags. */ HWLOC_DECLSPEC int hwloc_set_thread_cpubind(hwloc_topology_t topology, hwloc_thread_t thread, hwloc_const_cpuset_t set, int flags); #endif #ifdef hwloc_thread_t /** \brief Get the current physical binding of thread \p tid. * * The CPU-set \p set (previously allocated by the caller) * is filled with the list of PUs which the thread * was last bound to. * * \return 0 on success, -1 on error. * * \note \p hwloc_thread_t is \p pthread_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note ::HWLOC_CPUBIND_PROCESS can not be used in \p flags. */ HWLOC_DECLSPEC int hwloc_get_thread_cpubind(hwloc_topology_t topology, hwloc_thread_t thread, hwloc_cpuset_t set, int flags); #endif /** \brief Get the last physical CPU where the current process or thread ran. * * The CPU-set \p set (previously allocated by the caller) * is filled with the list of PUs which the process or * thread (according to \e flags) last ran on. * * The operating system may move some tasks from one processor * to another at any time according to their binding, * so this function may return something that is already * outdated. * * \p flags can include either ::HWLOC_CPUBIND_PROCESS or ::HWLOC_CPUBIND_THREAD to * specify whether the query should be for the whole process (union of all CPUs * on which all threads are running), or only the current thread. If the * process is single-threaded, flags can be set to zero to let hwloc use * whichever method is available on the underlying OS. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_get_last_cpu_location(hwloc_topology_t topology, hwloc_cpuset_t set, int flags); /** \brief Get the last physical CPU where a process ran. * * The CPU-set \p set (previously allocated by the caller) * is filled with the list of PUs which the process * last ran on. * * The operating system may move some tasks from one processor * to another at any time according to their binding, * so this function may return something that is already * outdated. * * \return 0 on success, -1 on error. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note As a special case on Linux, if a tid (thread ID) is supplied * instead of a pid (process ID) and ::HWLOC_CPUBIND_THREAD is passed in flags, * the last CPU location of that specific thread is returned. * * \note On non-Linux systems, ::HWLOC_CPUBIND_THREAD can not be used in \p flags. */ HWLOC_DECLSPEC int hwloc_get_proc_last_cpu_location(hwloc_topology_t topology, hwloc_pid_t pid, hwloc_cpuset_t set, int flags); /** @} */ /** \defgroup hwlocality_membinding Memory binding * * Memory binding can be done three ways: * * - explicit memory allocation thanks to hwloc_alloc_membind() and friends: * the binding will have effect on the memory allocated by these functions. * - implicit memory binding through binding policy: hwloc_set_membind() and * friends only define the current policy of the process, which will be * applied to the subsequent calls to malloc() and friends. * - migration of existing memory ranges, thanks to hwloc_set_area_membind() * and friends, which move already-allocated data. * * Not all operating systems support all three ways. * hwloc_topology_get_support() may be used to query about the actual memory * binding support in the currently used operating system. * * When the requested binding operation is not available and the * ::HWLOC_MEMBIND_STRICT flag was passed, the function returns -1. * \p errno will be set to \c ENOSYS when the system does support * the specified action or policy * (e.g., some systems only allow binding memory on a per-thread * basis, whereas other systems only allow binding memory for all * threads in a process). * \p errno will be set to \c EXDEV when the requested set can not be enforced * (e.g., some systems only allow binding memory to a single NUMA node). * * If ::HWLOC_MEMBIND_STRICT was not passed, the function may fail as well, * or the operating system may use a slightly different operation * (with side-effects, smaller binding set, etc.) * when the requested operation is not exactly supported. * * The most portable form that should be preferred over the others * whenever possible is as follows. * It allocates some memory hopefully bound to the specified set. * To do so, hwloc will possibly have to change the current memory * binding policy in order to actually get the memory bound, if the OS * does not provide any other way to simply allocate bound memory * without changing the policy for all allocations. That is the * difference with hwloc_alloc_membind(), which will never change the * current memory binding policy. * * \code * hwloc_alloc_membind_policy(topology, size, set, * HWLOC_MEMBIND_BIND, 0); * \endcode * * Each hwloc memory binding function takes a bitmap argument that * is a CPU set by default, or a NUMA memory node set if the flag * ::HWLOC_MEMBIND_BYNODESET is specified. * See \ref hwlocality_object_sets and \ref hwlocality_bitmap for a * discussion of CPU sets and NUMA memory node sets. * It is also possible to convert between CPU set and node set using * hwloc_cpuset_to_nodeset() or hwloc_cpuset_from_nodeset(). * * Memory binding by CPU set cannot work for CPU-less NUMA memory nodes. * Binding by nodeset should therefore be preferred whenever possible. * * \sa Some example codes are available under doc/examples/ in the source tree. * * \note On some operating systems, memory binding affects the CPU * binding; see ::HWLOC_MEMBIND_NOCPUBIND * @{ */ /** \brief Memory binding policy. * * These constants can be used to choose the binding policy. Only one policy can * be used at a time (i.e., the values cannot be OR'ed together). * * Not all systems support all kinds of binding. * hwloc_topology_get_support() may be used to query about the actual memory * binding policy support in the currently used operating system. * See the "Detailed Description" section of \ref hwlocality_membinding * for a description of errors that can occur. */ typedef enum { /** \brief Reset the memory allocation policy to the system default. * Depending on the operating system, this may correspond to * ::HWLOC_MEMBIND_FIRSTTOUCH (Linux, FreeBSD), * or ::HWLOC_MEMBIND_BIND (AIX, HP-UX, Solaris, Windows). * This policy is never returned by get membind functions. * The nodeset argument is ignored. * \hideinitializer */ HWLOC_MEMBIND_DEFAULT = 0, /** \brief Allocate each memory page individually on the local NUMA * node of the thread that touches it. * * The given nodeset should usually be hwloc_topology_get_topology_nodeset() * so that the touching thread may run and allocate on any node in the system. * * On AIX, if the nodeset is smaller, pages are allocated locally (if the local * node is in the nodeset) or from a random non-local node (otherwise). * \hideinitializer */ HWLOC_MEMBIND_FIRSTTOUCH = 1, /** \brief Allocate memory on the specified nodes. * * The actual behavior may slightly vary between operating systems, * especially when (some of) the requested nodes are full. * On Linux, by default, the MPOL_PREFERRED_MANY (or MPOL_PREFERRED) policy * is used. However, if the hwloc strict flag is also given, the Linux * MPOL_BIND policy is rather used. * \hideinitializer */ HWLOC_MEMBIND_BIND = 2, /** \brief Allocate memory on the given nodes in an interleaved * / round-robin manner. The precise layout of the memory across * multiple NUMA nodes is OS/system specific. Interleaving can be * useful when threads distributed across the specified NUMA nodes * will all be accessing the whole memory range concurrently, since * the interleave will then balance the memory references. * \hideinitializer */ HWLOC_MEMBIND_INTERLEAVE = 3, /** \brief For each page bound with this policy, by next time * it is touched (and next time only), it is moved from its current * location to the local NUMA node of the thread where the memory * reference occurred (if it needs to be moved at all). * \hideinitializer */ HWLOC_MEMBIND_NEXTTOUCH = 4, /** \brief Returned by get_membind() functions when multiple * threads or parts of a memory area have differing memory binding * policies. * Also returned when binding is unknown because binding hooks are empty * when the topology is loaded from XML without HWLOC_THISSYSTEM=1, etc. * \hideinitializer */ HWLOC_MEMBIND_MIXED = -1 } hwloc_membind_policy_t; /** \brief Memory binding flags. * * These flags can be used to refine the binding policy. * All flags can be logically OR'ed together with the exception of * ::HWLOC_MEMBIND_PROCESS and ::HWLOC_MEMBIND_THREAD; * these two flags are mutually exclusive. * * Not all systems support all kinds of binding. * hwloc_topology_get_support() may be used to query about the actual memory * binding support in the currently used operating system. * See the "Detailed Description" section of \ref hwlocality_membinding * for a description of errors that can occur. */ typedef enum { /** \brief Set policy for all threads of the specified (possibly * multithreaded) process. This flag is mutually exclusive with * ::HWLOC_MEMBIND_THREAD. * \hideinitializer */ HWLOC_MEMBIND_PROCESS = (1<<0), /** \brief Set policy for a specific thread of the current process. * This flag is mutually exclusive with ::HWLOC_MEMBIND_PROCESS. * \hideinitializer */ HWLOC_MEMBIND_THREAD = (1<<1), /** Request strict binding from the OS. The function will fail if * the binding can not be guaranteed / completely enforced. * * This flag has slightly different meanings depending on which * function it is used with. * \hideinitializer */ HWLOC_MEMBIND_STRICT = (1<<2), /** \brief Migrate existing allocated memory. If the memory cannot * be migrated and the ::HWLOC_MEMBIND_STRICT flag is passed, an error * will be returned. * \hideinitializer */ HWLOC_MEMBIND_MIGRATE = (1<<3), /** \brief Avoid any effect on CPU binding. * * On some operating systems, some underlying memory binding * functions also bind the application to the corresponding CPU(s). * Using this flag will cause hwloc to avoid using OS functions that * could potentially affect CPU bindings. Note, however, that using * NOCPUBIND may reduce hwloc's overall memory binding * support. Specifically: some of hwloc's memory binding functions * may fail with errno set to \c ENOSYS when used with NOCPUBIND. * \hideinitializer */ HWLOC_MEMBIND_NOCPUBIND = (1<<4), /** \brief Consider the bitmap argument as a nodeset. * * The bitmap argument is considered a nodeset if this flag is given, * or a cpuset otherwise by default. * * Memory binding by CPU set cannot work for CPU-less NUMA memory nodes. * Binding by nodeset should therefore be preferred whenever possible. * \hideinitializer */ HWLOC_MEMBIND_BYNODESET = (1<<5) } hwloc_membind_flags_t; /** \brief Set the default memory binding policy of the current * process or thread to prefer the NUMA node(s) specified by \p set * * If neither ::HWLOC_MEMBIND_PROCESS nor ::HWLOC_MEMBIND_THREAD is * specified, the current process is assumed to be single-threaded. * This is the most portable form as it permits hwloc to use either * process-based OS functions or thread-based OS functions, depending * on which are available. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * \return 0 on success. * \return -1 with errno set to \c ENOSYS if the action is not supported. * \return -1 with errno set to \c EXDEV if the binding cannot be enforced. */ HWLOC_DECLSPEC int hwloc_set_membind(hwloc_topology_t topology, hwloc_const_bitmap_t set, hwloc_membind_policy_t policy, int flags); /** \brief Query the default memory binding policy and physical locality of the * current process or thread. * * The bitmap \p set (previously allocated by the caller) * is filled with the process or thread memory binding. * * This function has two output parameters: \p set and \p policy. * The values returned in these parameters depend on both the \p flags * passed in and the current memory binding policies and nodesets in * the queried target. * * Passing the ::HWLOC_MEMBIND_PROCESS flag specifies that the query * target is the current policies and nodesets for all the threads in * the current process. Passing ::HWLOC_MEMBIND_THREAD specifies that * the query target is the current policy and nodeset for only the * thread invoking this function. * * If neither of these flags are passed (which is the most portable * method), the process is assumed to be single threaded. This allows * hwloc to use either process-based OS functions or thread-based OS * functions, depending on which are available. * * ::HWLOC_MEMBIND_STRICT is only meaningful when ::HWLOC_MEMBIND_PROCESS * is also specified. In this case, hwloc will check the default * memory policies and nodesets for all threads in the process. If * they are not identical, -1 is returned and errno is set to \c EXDEV. * If they are identical, the values are returned in \p set and \p * policy. * * Otherwise, if ::HWLOC_MEMBIND_PROCESS is specified (and * ::HWLOC_MEMBIND_STRICT is \em not specified), the default set * from each thread is logically OR'ed together. * If all threads' default policies are the same, \p policy is set to * that policy. If they are different, \p policy is set to * ::HWLOC_MEMBIND_MIXED. * * In the ::HWLOC_MEMBIND_THREAD case (or when neither * ::HWLOC_MEMBIND_PROCESS or ::HWLOC_MEMBIND_THREAD is specified), there * is only one set and policy; they are returned in \p set and * \p policy, respectively. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * If any other flags are specified, -1 is returned and errno is set * to \c EINVAL. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_get_membind(hwloc_topology_t topology, hwloc_bitmap_t set, hwloc_membind_policy_t * policy, int flags); /** \brief Set the default memory binding policy of the specified * process to prefer the NUMA node(s) specified by \p set * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * \return 0 on success. * \return -1 with errno set to \c ENOSYS if the action is not supported. * \return -1 with errno set to \c EXDEV if the binding cannot be enforced. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. */ HWLOC_DECLSPEC int hwloc_set_proc_membind(hwloc_topology_t topology, hwloc_pid_t pid, hwloc_const_bitmap_t set, hwloc_membind_policy_t policy, int flags); /** \brief Query the default memory binding policy and physical locality of the * specified process. * * The bitmap \p set (previously allocated by the caller) * is filled with the process memory binding. * * This function has two output parameters: \p set and \p policy. * The values returned in these parameters depend on both the \p flags * passed in and the current memory binding policies and nodesets in * the queried target. * * Passing the ::HWLOC_MEMBIND_PROCESS flag specifies that the query * target is the current policies and nodesets for all the threads in * the specified process. If ::HWLOC_MEMBIND_PROCESS is not specified * (which is the most portable method), the process is assumed to be * single threaded. This allows hwloc to use either process-based OS * functions or thread-based OS functions, depending on which are * available. * * Note that it does not make sense to pass ::HWLOC_MEMBIND_THREAD to * this function. * * If ::HWLOC_MEMBIND_STRICT is specified, hwloc will check the default * memory policies and nodesets for all threads in the specified * process. If they are not identical, -1 is returned and errno is * set to \c EXDEV. If they are identical, the values are returned in \p * set and \p policy. * * Otherwise, \p set is set to the logical OR of all threads' * default set. If all threads' default policies * are the same, \p policy is set to that policy. If they are * different, \p policy is set to ::HWLOC_MEMBIND_MIXED. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * If any other flags are specified, -1 is returned and errno is set * to \c EINVAL. * * \return 0 on success, -1 on error. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. */ HWLOC_DECLSPEC int hwloc_get_proc_membind(hwloc_topology_t topology, hwloc_pid_t pid, hwloc_bitmap_t set, hwloc_membind_policy_t * policy, int flags); /** \brief Bind the already-allocated memory identified by (addr, len) * to the NUMA node(s) specified by \p set. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * \return 0 on success or if \p len is 0. * \return -1 with errno set to \c ENOSYS if the action is not supported. * \return -1 with errno set to \c EXDEV if the binding cannot be enforced. */ HWLOC_DECLSPEC int hwloc_set_area_membind(hwloc_topology_t topology, const void *addr, size_t len, hwloc_const_bitmap_t set, hwloc_membind_policy_t policy, int flags); /** \brief Query the CPUs near the physical NUMA node(s) and binding policy of * the memory identified by (\p addr, \p len ). * * The bitmap \p set (previously allocated by the caller) * is filled with the memory area binding. * * This function has two output parameters: \p set and \p policy. * The values returned in these parameters depend on both the \p flags * passed in and the memory binding policies and nodesets of the pages * in the address range. * * If ::HWLOC_MEMBIND_STRICT is specified, the target pages are first * checked to see if they all have the same memory binding policy and * nodeset. If they do not, -1 is returned and errno is set to \c EXDEV. * If they are identical across all pages, the set and policy are * returned in \p set and \p policy, respectively. * * If ::HWLOC_MEMBIND_STRICT is not specified, the union of all NUMA * node(s) containing pages in the address range is calculated. * If all pages in the target have the same policy, it is returned in * \p policy. Otherwise, \p policy is set to ::HWLOC_MEMBIND_MIXED. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * If any other flags are specified, -1 is returned and errno is set * to \c EINVAL. * * \return 0 on success. * \return -1 with errno set to \c EINVAL if \p len is 0. */ HWLOC_DECLSPEC int hwloc_get_area_membind(hwloc_topology_t topology, const void *addr, size_t len, hwloc_bitmap_t set, hwloc_membind_policy_t * policy, int flags); /** \brief Get the NUMA nodes where memory identified by (\p addr, \p len ) is physically allocated. * * The bitmap \p set (previously allocated by the caller) * is filled according to the NUMA nodes where the memory area pages * are physically allocated. If no page is actually allocated yet, * \p set may be empty. * * If pages spread to multiple nodes, it is not specified whether they spread * equitably, or whether most of them are on a single node, etc. * * The operating system may move memory pages from one processor * to another at any time according to their binding, * so this function may return something that is already * outdated. * * If ::HWLOC_MEMBIND_BYNODESET is specified in \p flags, set is * considered a nodeset. Otherwise it's a cpuset. * * If \p len is 0, \p set is emptied. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_get_area_memlocation(hwloc_topology_t topology, const void *addr, size_t len, hwloc_bitmap_t set, int flags); /** \brief Allocate some memory * * This is equivalent to malloc(), except that it tries to allocate * page-aligned memory from the OS. * * \return a pointer to the allocated area, or \c NULL on error. * * \note The allocated memory should be freed with hwloc_free(). */ HWLOC_DECLSPEC void *hwloc_alloc(hwloc_topology_t topology, size_t len); /** \brief Allocate some memory on NUMA memory nodes specified by \p set * * \return a pointer to the allocated area. * \return NULL with errno set to \c ENOSYS if the action is not supported * and ::HWLOC_MEMBIND_STRICT is given. * \return NULL with errno set to \c EXDEV if the binding cannot be enforced * and ::HWLOC_MEMBIND_STRICT is given. * \return NULL with errno set to \c ENOMEM if the memory allocation failed * even before trying to bind. * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * \note The allocated memory should be freed with hwloc_free(). */ HWLOC_DECLSPEC void *hwloc_alloc_membind(hwloc_topology_t topology, size_t len, hwloc_const_bitmap_t set, hwloc_membind_policy_t policy, int flags) __hwloc_attribute_malloc; /** \brief Allocate some memory on NUMA memory nodes specified by \p set * * First, try to allocate properly with hwloc_alloc_membind(). * On failure, the current process or thread memory binding policy * is changed with hwloc_set_membind() before allocating memory. * Thus this function works in more cases, at the expense of changing * the current state (possibly affecting future allocations that * would not specify any policy). * * If ::HWLOC_MEMBIND_BYNODESET is specified, set is considered a nodeset. * Otherwise it's a cpuset. * * \return a pointer to the allocated area, or \c NULL on error. */ static __hwloc_inline void * hwloc_alloc_membind_policy(hwloc_topology_t topology, size_t len, hwloc_const_bitmap_t set, hwloc_membind_policy_t policy, int flags) __hwloc_attribute_malloc; /** \brief Free memory that was previously allocated by hwloc_alloc() * or hwloc_alloc_membind(). * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_free(hwloc_topology_t topology, void *addr, size_t len); /** @} */ /** \defgroup hwlocality_setsource Changing the Source of Topology Discovery * * These functions must be called between hwloc_topology_init() and hwloc_topology_load(). * Otherwise, they will return -1 with errno set to \c EBUSY. * * If none of the functions below is called, the default is to detect all the objects * of the machine that the caller is allowed to access. * * This default behavior may also be modified through environment variables * if the application did not modify it already. * Setting HWLOC_XMLFILE in the environment enforces the discovery from a XML * file as if hwloc_topology_set_xml() had been called. * Setting HWLOC_SYNTHETIC enforces a synthetic topology as if * hwloc_topology_set_synthetic() had been called. * * Finally, HWLOC_THISSYSTEM enforces the return value of * hwloc_topology_is_thissystem(). * * @{ */ /** \brief Change which process the topology is viewed from. * * On some systems, processes may have different views of the machine, for * instance the set of allowed CPUs. By default, hwloc exposes the view from * the current process. Calling hwloc_topology_set_pid() permits to make it * expose the topology of the machine from the point of view of another * process. * * \note \p hwloc_pid_t is \p pid_t on Unix platforms, * and \p HANDLE on native Windows platforms. * * \note -1 is returned and errno is set to \c ENOSYS on platforms that do not * support this feature. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_pid(hwloc_topology_t __hwloc_restrict topology, hwloc_pid_t pid); /** \brief Enable synthetic topology. * * Gather topology information from the given \p description, * a space-separated string of describing * the object type and arity at each level. * All types may be omitted (space-separated string of numbers) so that * hwloc chooses all types according to usual topologies. * See also the \ref synthetic. * * Setting the environment variable HWLOC_SYNTHETIC * may also result in this behavior. * * If \p description was properly parsed and describes a valid topology * configuration, this function returns 0. * Otherwise -1 is returned and errno is set to \c EINVAL. * * Note that this function does not actually load topology * information; it just tells hwloc where to load it from. You'll * still need to invoke hwloc_topology_load() to actually load the * topology information. * * \return 0 on success. * \return -1 with errno set to \c EINVAL if the description was invalid. * * \note For convenience, this backend provides empty binding hooks which just * return success. * * \note On success, the synthetic component replaces the previously enabled * component (if any), but the topology is not actually modified until * hwloc_topology_load(). */ HWLOC_DECLSPEC int hwloc_topology_set_synthetic(hwloc_topology_t __hwloc_restrict topology, const char * __hwloc_restrict description); /** \brief Enable XML-file based topology. * * Gather topology information from the XML file given at \p xmlpath. * Setting the environment variable HWLOC_XMLFILE may also result in this behavior. * This file may have been generated earlier with hwloc_topology_export_xml() in hwloc/export.h, * or lstopo file.xml. * * Note that this function does not actually load topology * information; it just tells hwloc where to load it from. You'll * still need to invoke hwloc_topology_load() to actually load the * topology information. * * \return 0 on success. * \return -1 with errno set to \c EINVAL on failure to read the XML file. * * \note See also hwloc_topology_set_userdata_import_callback() * for importing application-specific object userdata. * * \note For convenience, this backend provides empty binding hooks which just * return success. To have hwloc still actually call OS-specific hooks, the * ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM has to be set to assert that the loaded * file is really the underlying system. * * \note On success, the XML component replaces the previously enabled * component (if any), but the topology is not actually modified until * hwloc_topology_load(). */ HWLOC_DECLSPEC int hwloc_topology_set_xml(hwloc_topology_t __hwloc_restrict topology, const char * __hwloc_restrict xmlpath); /** \brief Enable XML based topology using a memory buffer (instead of * a file, as with hwloc_topology_set_xml()). * * Gather topology information from the XML memory buffer given at \p * buffer and of length \p size. This buffer may have been filled * earlier with hwloc_topology_export_xmlbuffer() in hwloc/export.h. * * Note that this function does not actually load topology * information; it just tells hwloc where to load it from. You'll * still need to invoke hwloc_topology_load() to actually load the * topology information. * * \return 0 on success. * \return -1 with errno set to \c EINVAL on failure to read the XML buffer. * * \note See also hwloc_topology_set_userdata_import_callback() * for importing application-specific object userdata. * * \note For convenience, this backend provides empty binding hooks which just * return success. To have hwloc still actually call OS-specific hooks, the * ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM has to be set to assert that the loaded * file is really the underlying system. * * \note On success, the XML component replaces the previously enabled * component (if any), but the topology is not actually modified until * hwloc_topology_load(). */ HWLOC_DECLSPEC int hwloc_topology_set_xmlbuffer(hwloc_topology_t __hwloc_restrict topology, const char * __hwloc_restrict buffer, int size); /** \brief Flags to be passed to hwloc_topology_set_components() */ enum hwloc_topology_components_flag_e { /** \brief Blacklist the target component from being used. * \hideinitializer */ HWLOC_TOPOLOGY_COMPONENTS_FLAG_BLACKLIST = (1UL<<0) }; /** \brief Prevent a discovery component from being used for a topology. * * \p name is the name of the discovery component that should not be used * when loading topology \p topology. The name is a string such as "cuda". * * For components with multiple phases, it may also be suffixed with the name * of a phase, for instance "linux:io". * * \p flags should be ::HWLOC_TOPOLOGY_COMPONENTS_FLAG_BLACKLIST. * * This may be used to avoid expensive parts of the discovery process. * For instance, CUDA-specific discovery may be expensive and unneeded * while generic I/O discovery could still be useful. * * \return 0 on success. * \return -1 on error, for instance if flags are invalid. */ HWLOC_DECLSPEC int hwloc_topology_set_components(hwloc_topology_t __hwloc_restrict topology, unsigned long flags, const char * __hwloc_restrict name); /** @} */ /** \defgroup hwlocality_configuration Topology Detection Configuration and Query * * Several functions can optionally be called between hwloc_topology_init() and * hwloc_topology_load() to configure how the detection should be performed, * e.g. to ignore some objects types, define a synthetic topology, etc. * * @{ */ /** \brief Flags to be set onto a topology context before load. * * Flags should be given to hwloc_topology_set_flags(). * They may also be returned by hwloc_topology_get_flags(). */ enum hwloc_topology_flags_e { /** \brief Detect the whole system, ignore reservations, include disallowed objects. * * Gather all online resources, even if some were disabled by the administrator. * For instance, ignore Linux Cgroup/Cpusets and gather all processors and memory nodes. * However offline PUs and NUMA nodes are still ignored. * * When this flag is not set, PUs and NUMA nodes that are disallowed are not added to the topology. * Parent objects (package, core, cache, etc.) are added only if some of their children are allowed. * All existing PUs and NUMA nodes in the topology are allowed. * hwloc_topology_get_allowed_cpuset() and hwloc_topology_get_allowed_nodeset() * are equal to the root object cpuset and nodeset. * * When this flag is set, the actual sets of allowed PUs and NUMA nodes are given * by hwloc_topology_get_allowed_cpuset() and hwloc_topology_get_allowed_nodeset(). * They may be smaller than the root object cpuset and nodeset. * * If the current topology is exported to XML and reimported later, this flag * should be set again in the reimported topology so that disallowed resources * are reimported as well. * \hideinitializer */ HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED = (1UL<<0), /** \brief Assume that the selected backend provides the topology for the * system on which we are running. * * This forces hwloc_topology_is_thissystem() to return 1, i.e. makes hwloc assume that * the selected backend provides the topology for the system on which we are running, * even if it is not the OS-specific backend but the XML backend for instance. * This means making the binding functions actually call the OS-specific * system calls and really do binding, while the XML backend would otherwise * provide empty hooks just returning success. * * Setting the environment variable HWLOC_THISSYSTEM may also result in the * same behavior. * * This can be used for efficiency reasons to first detect the topology once, * save it to an XML file, and quickly reload it later through the XML * backend, but still having binding functions actually do bind. * \hideinitializer */ HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM = (1UL<<1), /** \brief Get the set of allowed resources from the local operating system even if the topology was loaded from XML or synthetic description. * * If the topology was loaded from XML or from a synthetic string, * restrict it by applying the current process restrictions such as * Linux Cgroup/Cpuset. * * This is useful when the topology is not loaded directly from * the local machine (e.g. for performance reason) and it comes * with all resources, while the running process is restricted * to only parts of the machine. * * This flag is ignored unless ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM is * also set since the loaded topology must match the underlying machine * where restrictions will be gathered from. * * Setting the environment variable HWLOC_THISSYSTEM_ALLOWED_RESOURCES * would result in the same behavior. * \hideinitializer */ HWLOC_TOPOLOGY_FLAG_THISSYSTEM_ALLOWED_RESOURCES = (1UL<<2), /** \brief Import support from the imported topology. * * When importing a XML topology from a remote machine, binding is * disabled by default (see ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM). * This disabling is also marked by putting zeroes in the corresponding * supported feature bits reported by hwloc_topology_get_support(). * * The flag ::HWLOC_TOPOLOGY_FLAG_IMPORT_SUPPORT actually imports * support bits from the remote machine. It also sets the flag * \p imported_support in the struct hwloc_topology_misc_support array. * If the imported XML did not contain any support information * (exporter hwloc is too old), this flag is not set. * * Note that these supported features are only relevant for the hwloc * installation that actually exported the XML topology * (it may vary with the operating system, or with how hwloc was compiled). * * Note that setting this flag however does not enable binding for the * locally imported hwloc topology, it only reports what the remote * hwloc and machine support. * */ HWLOC_TOPOLOGY_FLAG_IMPORT_SUPPORT = (1UL<<3), /** \brief Do not consider resources outside of the process CPU binding. * * If the binding of the process is limited to a subset of cores, * ignore the other cores during discovery. * * The resulting topology is identical to what a call to hwloc_topology_restrict() * would generate, but this flag also prevents hwloc from ever touching other * resources during the discovery. * * This flag especially tells the x86 backend to never temporarily * rebind a thread on any excluded core. This is useful on Windows * because such temporary rebinding can change the process binding. * Another use-case is to avoid cores that would not be able to * perform the hwloc discovery anytime soon because they are busy * executing some high-priority real-time tasks. * * If process CPU binding is not supported, * the thread CPU binding is considered instead if supported, * or the flag is ignored. * * This flag requires ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM as well * since binding support is required. */ HWLOC_TOPOLOGY_FLAG_RESTRICT_TO_CPUBINDING = (1UL<<4), /** \brief Do not consider resources outside of the process memory binding. * * If the binding of the process is limited to a subset of NUMA nodes, * ignore the other NUMA nodes during discovery. * * The resulting topology is identical to what a call to hwloc_topology_restrict() * would generate, but this flag also prevents hwloc from ever touching other * resources during the discovery. * * This flag is meant to be used together with * ::HWLOC_TOPOLOGY_FLAG_RESTRICT_TO_CPUBINDING when both cores * and NUMA nodes should be ignored outside of the process binding. * * If process memory binding is not supported, * the thread memory binding is considered instead if supported, * or the flag is ignored. * * This flag requires ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM as well * since binding support is required. */ HWLOC_TOPOLOGY_FLAG_RESTRICT_TO_MEMBINDING = (1UL<<5), /** \brief Do not ever modify the process or thread binding during discovery. * * This flag disables all hwloc discovery steps that require a change of * the process or thread binding. This currently only affects the x86 * backend which gets entirely disabled. * * This is useful when hwloc_topology_load() is called while the * application also creates additional threads or modifies the binding. * * This flag is also a strict way to make sure the process binding will * not change to due thread binding changes on Windows * (see ::HWLOC_TOPOLOGY_FLAG_RESTRICT_TO_CPUBINDING). */ HWLOC_TOPOLOGY_FLAG_DONT_CHANGE_BINDING = (1UL<<6), /** \brief Ignore distances. * * Ignore distance information from the operating systems (and from XML) * and hence do not use distances for grouping. */ HWLOC_TOPOLOGY_FLAG_NO_DISTANCES = (1UL<<7), /** \brief Ignore memory attributes. * * Ignore memory attribues from the operating systems (and from XML). */ HWLOC_TOPOLOGY_FLAG_NO_MEMATTRS = (1UL<<8), /** \brief Ignore CPU Kinds. * * Ignore CPU kind information from the operating systems (and from XML). */ HWLOC_TOPOLOGY_FLAG_NO_CPUKINDS = (1UL<<9) }; /** \brief Set OR'ed flags to non-yet-loaded topology. * * Set a OR'ed set of ::hwloc_topology_flags_e onto a topology that was not yet loaded. * * If this function is called multiple times, the last invocation will erase * and replace the set of flags that was previously set. * * By default, no flags are set (\c 0). * * The flags set in a topology may be retrieved with hwloc_topology_get_flags(). * * \return 0 on success. * \return -1 on error, for instance if flags are invalid. */ HWLOC_DECLSPEC int hwloc_topology_set_flags (hwloc_topology_t topology, unsigned long flags); /** \brief Get OR'ed flags of a topology. * * Get the OR'ed set of ::hwloc_topology_flags_e of a topology. * * If hwloc_topology_set_flags() was not called earlier, * no flags are set (\c 0 is returned). * * \return the flags previously set with hwloc_topology_set_flags(). * * \note This function may also be called after hwloc_topology_load(). */ HWLOC_DECLSPEC unsigned long hwloc_topology_get_flags (hwloc_topology_t topology); /** \brief Does the topology context come from this system? * * \return 1 if this topology context was built using the system * running this program. * \return 0 instead (for instance if using another file-system root, * a XML topology file, or a synthetic topology). * * \note This function may also be called after hwloc_topology_load(). */ HWLOC_DECLSPEC int hwloc_topology_is_thissystem(hwloc_topology_t __hwloc_restrict topology) __hwloc_attribute_pure; /** \brief Flags describing actual discovery support for this topology. */ struct hwloc_topology_discovery_support { /** \brief Detecting the number of PU objects is supported. */ unsigned char pu; /** \brief Detecting the number of NUMA nodes is supported. */ unsigned char numa; /** \brief Detecting the amount of memory in NUMA nodes is supported. */ unsigned char numa_memory; /** \brief Detecting and identifying PU objects that are not available to the current process is supported. */ unsigned char disallowed_pu; /** \brief Detecting and identifying NUMA nodes that are not available to the current process is supported. */ unsigned char disallowed_numa; /** \brief Detecting the efficiency of CPU kinds is supported, see \ref hwlocality_cpukinds. */ unsigned char cpukind_efficiency; }; /** \brief Flags describing actual PU binding support for this topology. * * A flag may be set even if the feature isn't supported in all cases * (e.g. binding to random sets of non-contiguous objects). */ struct hwloc_topology_cpubind_support { /** Binding the whole current process is supported. */ unsigned char set_thisproc_cpubind; /** Getting the binding of the whole current process is supported. */ unsigned char get_thisproc_cpubind; /** Binding a whole given process is supported. */ unsigned char set_proc_cpubind; /** Getting the binding of a whole given process is supported. */ unsigned char get_proc_cpubind; /** Binding the current thread only is supported. */ unsigned char set_thisthread_cpubind; /** Getting the binding of the current thread only is supported. */ unsigned char get_thisthread_cpubind; /** Binding a given thread only is supported. */ unsigned char set_thread_cpubind; /** Getting the binding of a given thread only is supported. */ unsigned char get_thread_cpubind; /** Getting the last processors where the whole current process ran is supported */ unsigned char get_thisproc_last_cpu_location; /** Getting the last processors where a whole process ran is supported */ unsigned char get_proc_last_cpu_location; /** Getting the last processors where the current thread ran is supported */ unsigned char get_thisthread_last_cpu_location; }; /** \brief Flags describing actual memory binding support for this topology. * * A flag may be set even if the feature isn't supported in all cases * (e.g. binding to random sets of non-contiguous objects). */ struct hwloc_topology_membind_support { /** Binding the whole current process is supported. */ unsigned char set_thisproc_membind; /** Getting the binding of the whole current process is supported. */ unsigned char get_thisproc_membind; /** Binding a whole given process is supported. */ unsigned char set_proc_membind; /** Getting the binding of a whole given process is supported. */ unsigned char get_proc_membind; /** Binding the current thread only is supported. */ unsigned char set_thisthread_membind; /** Getting the binding of the current thread only is supported. */ unsigned char get_thisthread_membind; /** Binding a given memory area is supported. */ unsigned char set_area_membind; /** Getting the binding of a given memory area is supported. */ unsigned char get_area_membind; /** Allocating a bound memory area is supported. */ unsigned char alloc_membind; /** First-touch policy is supported. */ unsigned char firsttouch_membind; /** Bind policy is supported. */ unsigned char bind_membind; /** Interleave policy is supported. */ unsigned char interleave_membind; /** Next-touch migration policy is supported. */ unsigned char nexttouch_membind; /** Migration flags is supported. */ unsigned char migrate_membind; /** Getting the last NUMA nodes where a memory area was allocated is supported */ unsigned char get_area_memlocation; }; /** \brief Flags describing miscellaneous features. */ struct hwloc_topology_misc_support { /** Support was imported when importing another topology, see ::HWLOC_TOPOLOGY_FLAG_IMPORT_SUPPORT. */ unsigned char imported_support; }; /** \brief Set of flags describing actual support for this topology. * * This is retrieved with hwloc_topology_get_support() and will be valid until * the topology object is destroyed. Note: the values are correct only after * discovery. */ struct hwloc_topology_support { struct hwloc_topology_discovery_support *discovery; struct hwloc_topology_cpubind_support *cpubind; struct hwloc_topology_membind_support *membind; struct hwloc_topology_misc_support *misc; }; /** \brief Retrieve the topology support. * * Each flag indicates whether a feature is supported. * If set to 0, the feature is not supported. * If set to 1, the feature is supported, but the corresponding * call may still fail in some corner cases. * * These features are also listed by hwloc-info \--support * * The reported features are what the current topology supports * on the current machine. If the topology was exported to XML * from another machine and later imported here, support still * describes what is supported for this imported topology after * import. By default, binding will be reported as unsupported * in this case (see ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM). * * Topology flag ::HWLOC_TOPOLOGY_FLAG_IMPORT_SUPPORT may be used * to report the supported features of the original remote machine * instead. If it was successfully imported, \p imported_support * will be set in the struct hwloc_topology_misc_support array. * * \return A pointer to a support structure. * * \note The function cannot return \c NULL. * \note The returned pointer should not be freed, it belongs to the hwloc library. * * \note This function may be called before or after hwloc_topology_load() * but the support structure only contains valid information after. */ HWLOC_DECLSPEC const struct hwloc_topology_support *hwloc_topology_get_support(hwloc_topology_t __hwloc_restrict topology); /** \brief Type filtering flags. * * By default, most objects are kept (::HWLOC_TYPE_FILTER_KEEP_ALL). * Instruction caches, I/O and Misc objects are ignored by default (::HWLOC_TYPE_FILTER_KEEP_NONE). * Die and Group levels are ignored unless they bring structure (::HWLOC_TYPE_FILTER_KEEP_STRUCTURE). * * Note that group objects are also ignored individually (without the entire level) * when they do not bring structure. */ enum hwloc_type_filter_e { /** \brief Keep all objects of this type. * * Cannot be set for ::HWLOC_OBJ_GROUP (groups are designed only to add more structure to the topology). * \hideinitializer */ HWLOC_TYPE_FILTER_KEEP_ALL = 0, /** \brief Ignore all objects of this type. * * The bottom-level type ::HWLOC_OBJ_PU, the ::HWLOC_OBJ_NUMANODE type, and * the top-level type ::HWLOC_OBJ_MACHINE may not be ignored. * \hideinitializer */ HWLOC_TYPE_FILTER_KEEP_NONE = 1, /** \brief Only ignore objects if their entire level does not bring any structure. * * Keep the entire level of objects if at least one of these objects adds * structure to the topology. An object brings structure when it has multiple * children and it is not the only child of its parent. * * If all objects in the level are the only child of their parent, and if none * of them has multiple children, the entire level is removed. * * Cannot be set for I/O and Misc objects since the topology structure does not matter there. * \hideinitializer */ HWLOC_TYPE_FILTER_KEEP_STRUCTURE = 2, /** \brief Only keep likely-important objects of the given type. * * It is only useful for I/O object types. * For ::HWLOC_OBJ_PCI_DEVICE and ::HWLOC_OBJ_OS_DEVICE, it means that only objects * of major/common kinds are kept (storage, network, OpenFabrics, CUDA, * OpenCL, RSMI, NVML, and displays). * Also, only OS devices directly attached on PCI (e.g. no USB) are reported. * For ::HWLOC_OBJ_BRIDGE, it means that bridges are kept only if they have children. * * This flag equivalent to ::HWLOC_TYPE_FILTER_KEEP_ALL for Normal, Memory and Misc types * since they are likely important. * \hideinitializer */ HWLOC_TYPE_FILTER_KEEP_IMPORTANT = 3 }; /** \brief Set the filtering for the given object type. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_type_filter(hwloc_topology_t topology, hwloc_obj_type_t type, enum hwloc_type_filter_e filter); /** \brief Get the current filtering for the given object type. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_get_type_filter(hwloc_topology_t topology, hwloc_obj_type_t type, enum hwloc_type_filter_e *filter); /** \brief Set the filtering for all object types. * * If some types do not support this filtering, they are silently ignored. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_all_types_filter(hwloc_topology_t topology, enum hwloc_type_filter_e filter); /** \brief Set the filtering for all CPU cache object types. * * Memory-side caches are not involved since they are not CPU caches. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_cache_types_filter(hwloc_topology_t topology, enum hwloc_type_filter_e filter); /** \brief Set the filtering for all CPU instruction cache object types. * * Memory-side caches are not involved since they are not CPU caches. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_icache_types_filter(hwloc_topology_t topology, enum hwloc_type_filter_e filter); /** \brief Set the filtering for all I/O object types. * * \return 0 on success, -1 on error. */ HWLOC_DECLSPEC int hwloc_topology_set_io_types_filter(hwloc_topology_t topology, enum hwloc_type_filter_e filter); /** \brief Set the topology-specific userdata pointer. * * Each topology may store one application-given private data pointer. * It is initialized to \c NULL. * hwloc will never modify it. * * Use it as you wish, after hwloc_topology_init() and until hwloc_topolog_destroy(). * * This pointer is not exported to XML. */ HWLOC_DECLSPEC void hwloc_topology_set_userdata(hwloc_topology_t topology, const void *userdata); /** \brief Retrieve the topology-specific userdata pointer. * * Retrieve the application-given private data pointer that was * previously set with hwloc_topology_set_userdata(). * * \return A pointer to the private-data if any. * \return \c NULL if no private-data was previoulsy set. */ HWLOC_DECLSPEC void * hwloc_topology_get_userdata(hwloc_topology_t topology); /** @} */ /** \defgroup hwlocality_tinker Modifying a loaded Topology * @{ */ /** \brief Flags to be given to hwloc_topology_restrict(). */ enum hwloc_restrict_flags_e { /** \brief Remove all objects that became CPU-less. * By default, only objects that contain no PU and no memory are removed. * This flag may not be used with ::HWLOC_RESTRICT_FLAG_BYNODESET. * \hideinitializer */ HWLOC_RESTRICT_FLAG_REMOVE_CPULESS = (1UL<<0), /** \brief Restrict by nodeset instead of CPU set. * Only keep objects whose nodeset is included or partially included in the given set. * This flag may not be used with ::HWLOC_RESTRICT_FLAG_REMOVE_CPULESS. */ HWLOC_RESTRICT_FLAG_BYNODESET = (1UL<<3), /** \brief Remove all objects that became Memory-less. * By default, only objects that contain no PU and no memory are removed. * This flag may only be used with ::HWLOC_RESTRICT_FLAG_BYNODESET. * \hideinitializer */ HWLOC_RESTRICT_FLAG_REMOVE_MEMLESS = (1UL<<4), /** \brief Move Misc objects to ancestors if their parents are removed during restriction. * If this flag is not set, Misc objects are removed when their parents are removed. * \hideinitializer */ HWLOC_RESTRICT_FLAG_ADAPT_MISC = (1UL<<1), /** \brief Move I/O objects to ancestors if their parents are removed during restriction. * If this flag is not set, I/O devices and bridges are removed when their parents are removed. * \hideinitializer */ HWLOC_RESTRICT_FLAG_ADAPT_IO = (1UL<<2) }; /** \brief Restrict the topology to the given CPU set or nodeset. * * Topology \p topology is modified so as to remove all objects that * are not included (or partially included) in the CPU set \p set. * All objects CPU and node sets are restricted accordingly. * * By default, \p set is a CPU set. It means that the set of PUs in * the topology is restricted. Once some PUs got removed, their parents * may also get removed recursively if they became child-less. * * If ::HWLOC_RESTRICT_FLAG_BYNODESET is passed in \p flags, * \p set is considered a nodeset instead of a CPU set. * It means that the set of NUMA nodes in the topology is restricted * (instead of PUs). Once some NUMA nodes got removed, their parents * may also get removed recursively if they became child-less. * * \p flags is a OR'ed set of ::hwloc_restrict_flags_e. * * \note Restricting the topology removes some locality information, * hence the remaining objects may get reordered (including PUs and NUMA nodes), * and their logical indexes may change. * * \note This call may not be reverted by restricting back to a larger * set. Once dropped during restriction, objects may not be brought * back, except by loading another topology with hwloc_topology_load(). * * \return 0 on success. * * \return -1 with errno set to \c EINVAL if the input set is invalid. * The topology is not modified in this case. * * \return -1 with errno set to \c ENOMEM on failure to allocate internal data. * The topology is reinitialized in this case. It should be either * destroyed with hwloc_topology_destroy() or configured and loaded again. */ HWLOC_DECLSPEC int hwloc_topology_restrict(hwloc_topology_t __hwloc_restrict topology, hwloc_const_bitmap_t set, unsigned long flags); /** \brief Flags to be given to hwloc_topology_allow(). */ enum hwloc_allow_flags_e { /** \brief Mark all objects as allowed in the topology. * * \p cpuset and \p nođeset given to hwloc_topology_allow() must be \c NULL. * \hideinitializer */ HWLOC_ALLOW_FLAG_ALL = (1UL<<0), /** \brief Only allow objects that are available to the current process. * * The topology must have ::HWLOC_TOPOLOGY_FLAG_IS_THISSYSTEM so that the set * of available resources can actually be retrieved from the operating system. * * \p cpuset and \p nođeset given to hwloc_topology_allow() must be \c NULL. * \hideinitializer */ HWLOC_ALLOW_FLAG_LOCAL_RESTRICTIONS = (1UL<<1), /** \brief Allow a custom set of objects, given to hwloc_topology_allow() as \p cpuset and/or \p nodeset parameters. * \hideinitializer */ HWLOC_ALLOW_FLAG_CUSTOM = (1UL<<2) }; /** \brief Change the sets of allowed PUs and NUMA nodes in the topology. * * This function only works if the ::HWLOC_TOPOLOGY_FLAG_INCLUDE_DISALLOWED * was set on the topology. It does not modify any object, it only changes * the sets returned by hwloc_topology_get_allowed_cpuset() and * hwloc_topology_get_allowed_nodeset(). * * It is notably useful when importing a topology from another process * running in a different Linux Cgroup. * * \p flags must be set to one flag among ::hwloc_allow_flags_e. * * \return 0 on success, -1 on error. * * \note Removing objects from a topology should rather be performed with * hwloc_topology_restrict(). */ HWLOC_DECLSPEC int hwloc_topology_allow(hwloc_topology_t __hwloc_restrict topology, hwloc_const_cpuset_t cpuset, hwloc_const_nodeset_t nodeset, unsigned long flags); /** \brief Add a MISC object as a leaf of the topology * * A new MISC object will be created and inserted into the topology at the * position given by parent. It is appended to the list of existing Misc children, * without ever adding any intermediate hierarchy level. This is useful for * annotating the topology without actually changing the hierarchy. * * \p name is supposed to be unique across all Misc objects in the topology. * It will be duplicated to setup the new object attributes. * * The new leaf object will not have any \p cpuset. * * \return the newly-created object * * \return \c NULL on error. * * \return \c NULL if Misc objects are filtered-out of the topology (::HWLOC_TYPE_FILTER_KEEP_NONE). * * \note If \p name contains some non-printable characters, they will * be dropped when exporting to XML, see hwloc_topology_export_xml() in hwloc/export.h. */ HWLOC_DECLSPEC hwloc_obj_t hwloc_topology_insert_misc_object(hwloc_topology_t topology, hwloc_obj_t parent, const char *name); /** \brief Allocate a Group object to insert later with hwloc_topology_insert_group_object(). * * This function returns a new Group object. * * The caller should (at least) initialize its sets before inserting * the object in the topology. See hwloc_topology_insert_group_object(). * * \return The allocated object on success. * \return \c NULL on error. */ HWLOC_DECLSPEC hwloc_obj_t hwloc_topology_alloc_group_object(hwloc_topology_t topology); /** \brief Add more structure to the topology by adding an intermediate Group * * The caller should first allocate a new Group object with hwloc_topology_alloc_group_object(). * Then it must setup at least one of its CPU or node sets to specify * the final location of the Group in the topology. * Then the object can be passed to this function for actual insertion in the topology. * * Either the cpuset or nodeset field (or both, if compatible) must be set * to a non-empty bitmap. The complete_cpuset or complete_nodeset may be set * instead if inserting with respect to the complete topology * (including disallowed, offline or unknown objects). * If grouping several objects, hwloc_obj_add_other_obj_sets() is an easy way * to build the Group sets iteratively. * These sets cannot be larger than the current topology, or they would get * restricted silently. * The core will setup the other sets after actual insertion. * * The \p subtype object attribute may be defined (to a dynamically * allocated string) to display something else than "Group" as the * type name for this object in lstopo. * Custom name-value info pairs may be added with hwloc_obj_add_info() after * insertion. * * The group \p dont_merge attribute may be set to \c 1 to prevent * the hwloc core from ever merging this object with another * hierarchically-identical object. * This is useful when the Group itself describes an important feature * that cannot be exposed anywhere else in the hierarchy. * * The group \p kind attribute may be set to a high value such * as \c 0xffffffff to tell hwloc that this new Group should always * be discarded in favor of any existing Group with the same locality. * * \note Inserting a group adds some locality information to the topology, * hence the existing objects may get reordered (including PUs and NUMA nodes), * and their logical indexes may change. * * \return The inserted object if it was properly inserted. * * \return An existing object if the Group was merged or discarded * because the topology already contained an object at the same * location (the Group did not add any hierarchy information). * * \return \c NULL if the insertion failed because of conflicting sets in topology tree. * * \return \c NULL if Group objects are filtered-out of the topology (::HWLOC_TYPE_FILTER_KEEP_NONE). * * \return \c NULL if the object was discarded because no set was * initialized in the Group before insert, or all of them were empty. */ HWLOC_DECLSPEC hwloc_obj_t hwloc_topology_insert_group_object(hwloc_topology_t topology, hwloc_obj_t group); /** \brief Setup object cpusets/nodesets by OR'ing another object's sets. * * For each defined cpuset or nodeset in \p src, allocate the corresponding set * in \p dst and add \p src to it by OR'ing sets. * * This function is convenient between hwloc_topology_alloc_group_object() * and hwloc_topology_insert_group_object(). It builds the sets of the new Group * that will be inserted as a new intermediate parent of several objects. * * \return 0 on success. * \return -1 with errno set to \c ENOMEM if some internal reallocation failed. */ HWLOC_DECLSPEC int hwloc_obj_add_other_obj_sets(hwloc_obj_t dst, hwloc_obj_t src); /** \brief Refresh internal structures after topology modification. * * Modifying the topology (by restricting, adding objects, modifying structures * such as distances or memory attributes, etc.) may cause some internal caches * to become invalid. These caches are automatically refreshed when accessed * but this refreshing is not thread-safe. * * This function is not thread-safe either, but it is a good way to end a * non-thread-safe phase of topology modification. Once this refresh is done, * multiple threads may concurrently consult the topology, objects, distances, * attributes, etc. * * See also \ref threadsafety * * \return 0 on success. * \return -1 on error, for instance if some internal reallocation failed. */ HWLOC_DECLSPEC int hwloc_topology_refresh(hwloc_topology_t topology); /** @} */ #ifdef __cplusplus } /* extern "C" */ #endif /* high-level helpers */ #include "hwloc/helper.h" /* inline code of some functions above */ #include "hwloc/inlines.h" /* memory attributes */ #include "hwloc/memattrs.h" /* kinds of CPU cores */ #include "hwloc/cpukinds.h" /* exporting to XML or synthetic */ #include "hwloc/export.h" /* distances */ #include "hwloc/distances.h" /* topology diffs */ #include "hwloc/diff.h" /* deprecated headers */ #include "hwloc/deprecated.h" #endif /* HWLOC_H */