diff options
author | Hans Wennborg <hans@hanshq.net> | 2019-02-27 18:49:24 +0000 |
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committer | Hans Wennborg <hans@hanshq.net> | 2019-02-27 18:49:24 +0000 |
commit | 78e6ab58a5a641e07f6d8dab15bdb16210f3afba (patch) | |
tree | 93c484acf8bc75deaf25f89921d757a15337cba4 /rc3/runtime/src/kmp_affinity.cpp | |
parent | d94992145eaea998bb8901485373e60cb079232c (diff) |
Creating release candidate rc3 from release_800 branch
git-svn-id: https://llvm.org/svn/llvm-project/openmp/tags/RELEASE_800@355016 91177308-0d34-0410-b5e6-96231b3b80d8
Diffstat (limited to 'rc3/runtime/src/kmp_affinity.cpp')
-rw-r--r-- | rc3/runtime/src/kmp_affinity.cpp | 5379 |
1 files changed, 5379 insertions, 0 deletions
diff --git a/rc3/runtime/src/kmp_affinity.cpp b/rc3/runtime/src/kmp_affinity.cpp new file mode 100644 index 0000000..f14cdf6 --- /dev/null +++ b/rc3/runtime/src/kmp_affinity.cpp @@ -0,0 +1,5379 @@ +/* + * kmp_affinity.cpp -- affinity management + */ + +//===----------------------------------------------------------------------===// +// +// The LLVM Compiler Infrastructure +// +// This file is dual licensed under the MIT and the University of Illinois Open +// Source Licenses. See LICENSE.txt for details. +// +//===----------------------------------------------------------------------===// + +#include "kmp.h" +#include "kmp_affinity.h" +#include "kmp_i18n.h" +#include "kmp_io.h" +#include "kmp_str.h" +#include "kmp_wrapper_getpid.h" +#if KMP_USE_HIER_SCHED +#include "kmp_dispatch_hier.h" +#endif + +// Store the real or imagined machine hierarchy here +static hierarchy_info machine_hierarchy; + +void __kmp_cleanup_hierarchy() { machine_hierarchy.fini(); } + +void __kmp_get_hierarchy(kmp_uint32 nproc, kmp_bstate_t *thr_bar) { + kmp_uint32 depth; + // The test below is true if affinity is available, but set to "none". Need to + // init on first use of hierarchical barrier. + if (TCR_1(machine_hierarchy.uninitialized)) + machine_hierarchy.init(NULL, nproc); + + // Adjust the hierarchy in case num threads exceeds original + if (nproc > machine_hierarchy.base_num_threads) + machine_hierarchy.resize(nproc); + + depth = machine_hierarchy.depth; + KMP_DEBUG_ASSERT(depth > 0); + + thr_bar->depth = depth; + thr_bar->base_leaf_kids = (kmp_uint8)machine_hierarchy.numPerLevel[0] - 1; + thr_bar->skip_per_level = machine_hierarchy.skipPerLevel; +} + +#if KMP_AFFINITY_SUPPORTED + +bool KMPAffinity::picked_api = false; + +void *KMPAffinity::Mask::operator new(size_t n) { return __kmp_allocate(n); } +void *KMPAffinity::Mask::operator new[](size_t n) { return __kmp_allocate(n); } +void KMPAffinity::Mask::operator delete(void *p) { __kmp_free(p); } +void KMPAffinity::Mask::operator delete[](void *p) { __kmp_free(p); } +void *KMPAffinity::operator new(size_t n) { return __kmp_allocate(n); } +void KMPAffinity::operator delete(void *p) { __kmp_free(p); } + +void KMPAffinity::pick_api() { + KMPAffinity *affinity_dispatch; + if (picked_api) + return; +#if KMP_USE_HWLOC + // Only use Hwloc if affinity isn't explicitly disabled and + // user requests Hwloc topology method + if (__kmp_affinity_top_method == affinity_top_method_hwloc && + __kmp_affinity_type != affinity_disabled) { + affinity_dispatch = new KMPHwlocAffinity(); + } else +#endif + { + affinity_dispatch = new KMPNativeAffinity(); + } + __kmp_affinity_dispatch = affinity_dispatch; + picked_api = true; +} + +void KMPAffinity::destroy_api() { + if (__kmp_affinity_dispatch != NULL) { + delete __kmp_affinity_dispatch; + __kmp_affinity_dispatch = NULL; + picked_api = false; + } +} + +#define KMP_ADVANCE_SCAN(scan) \ + while (*scan != '\0') { \ + scan++; \ + } + +// Print the affinity mask to the character array in a pretty format. +// The format is a comma separated list of non-negative integers or integer +// ranges: e.g., 1,2,3-5,7,9-15 +// The format can also be the string "{<empty>}" if no bits are set in mask +char *__kmp_affinity_print_mask(char *buf, int buf_len, + kmp_affin_mask_t *mask) { + int start = 0, finish = 0, previous = 0; + bool first_range; + KMP_ASSERT(buf); + KMP_ASSERT(buf_len >= 40); + KMP_ASSERT(mask); + char *scan = buf; + char *end = buf + buf_len - 1; + + // Check for empty set. + if (mask->begin() == mask->end()) { + KMP_SNPRINTF(scan, end - scan + 1, "{<empty>}"); + KMP_ADVANCE_SCAN(scan); + KMP_ASSERT(scan <= end); + return buf; + } + + first_range = true; + start = mask->begin(); + while (1) { + // Find next range + // [start, previous] is inclusive range of contiguous bits in mask + for (finish = mask->next(start), previous = start; + finish == previous + 1 && finish != mask->end(); + finish = mask->next(finish)) { + previous = finish; + } + + // The first range does not need a comma printed before it, but the rest + // of the ranges do need a comma beforehand + if (!first_range) { + KMP_SNPRINTF(scan, end - scan + 1, "%s", ","); + KMP_ADVANCE_SCAN(scan); + } else { + first_range = false; + } + // Range with three or more contiguous bits in the affinity mask + if (previous - start > 1) { + KMP_SNPRINTF(scan, end - scan + 1, "%d-%d", static_cast<int>(start), + static_cast<int>(previous)); + } else { + // Range with one or two contiguous bits in the affinity mask + KMP_SNPRINTF(scan, end - scan + 1, "%d", static_cast<int>(start)); + KMP_ADVANCE_SCAN(scan); + if (previous - start > 0) { + KMP_SNPRINTF(scan, end - scan + 1, ",%d", static_cast<int>(previous)); + } + } + KMP_ADVANCE_SCAN(scan); + // Start over with new start point + start = finish; + if (start == mask->end()) + break; + // Check for overflow + if (end - scan < 2) + break; + } + + // Check for overflow + KMP_ASSERT(scan <= end); + return buf; +} +#undef KMP_ADVANCE_SCAN + +// Print the affinity mask to the string buffer object in a pretty format +// The format is a comma separated list of non-negative integers or integer +// ranges: e.g., 1,2,3-5,7,9-15 +// The format can also be the string "{<empty>}" if no bits are set in mask +kmp_str_buf_t *__kmp_affinity_str_buf_mask(kmp_str_buf_t *buf, + kmp_affin_mask_t *mask) { + int start = 0, finish = 0, previous = 0; + bool first_range; + KMP_ASSERT(buf); + KMP_ASSERT(mask); + + __kmp_str_buf_clear(buf); + + // Check for empty set. + if (mask->begin() == mask->end()) { + __kmp_str_buf_print(buf, "%s", "{<empty>}"); + return buf; + } + + first_range = true; + start = mask->begin(); + while (1) { + // Find next range + // [start, previous] is inclusive range of contiguous bits in mask + for (finish = mask->next(start), previous = start; + finish == previous + 1 && finish != mask->end(); + finish = mask->next(finish)) { + previous = finish; + } + + // The first range does not need a comma printed before it, but the rest + // of the ranges do need a comma beforehand + if (!first_range) { + __kmp_str_buf_print(buf, "%s", ","); + } else { + first_range = false; + } + // Range with three or more contiguous bits in the affinity mask + if (previous - start > 1) { + __kmp_str_buf_print(buf, "%d-%d", static_cast<int>(start), + static_cast<int>(previous)); + } else { + // Range with one or two contiguous bits in the affinity mask + __kmp_str_buf_print(buf, "%d", static_cast<int>(start)); + if (previous - start > 0) { + __kmp_str_buf_print(buf, ",%d", static_cast<int>(previous)); + } + } + // Start over with new start point + start = finish; + if (start == mask->end()) + break; + } + return buf; +} + +void __kmp_affinity_entire_machine_mask(kmp_affin_mask_t *mask) { + KMP_CPU_ZERO(mask); + +#if KMP_GROUP_AFFINITY + + if (__kmp_num_proc_groups > 1) { + int group; + KMP_DEBUG_ASSERT(__kmp_GetActiveProcessorCount != NULL); + for (group = 0; group < __kmp_num_proc_groups; group++) { + int i; + int num = __kmp_GetActiveProcessorCount(group); + for (i = 0; i < num; i++) { + KMP_CPU_SET(i + group * (CHAR_BIT * sizeof(DWORD_PTR)), mask); + } + } + } else + +#endif /* KMP_GROUP_AFFINITY */ + + { + int proc; + for (proc = 0; proc < __kmp_xproc; proc++) { + KMP_CPU_SET(proc, mask); + } + } +} + +// When sorting by labels, __kmp_affinity_assign_child_nums() must first be +// called to renumber the labels from [0..n] and place them into the child_num +// vector of the address object. This is done in case the labels used for +// the children at one node of the hierarchy differ from those used for +// another node at the same level. Example: suppose the machine has 2 nodes +// with 2 packages each. The first node contains packages 601 and 602, and +// second node contains packages 603 and 604. If we try to sort the table +// for "scatter" affinity, the table will still be sorted 601, 602, 603, 604 +// because we are paying attention to the labels themselves, not the ordinal +// child numbers. By using the child numbers in the sort, the result is +// {0,0}=601, {0,1}=603, {1,0}=602, {1,1}=604. +static void __kmp_affinity_assign_child_nums(AddrUnsPair *address2os, + int numAddrs) { + KMP_DEBUG_ASSERT(numAddrs > 0); + int depth = address2os->first.depth; + unsigned *counts = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + unsigned *lastLabel = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + int labCt; + for (labCt = 0; labCt < depth; labCt++) { + address2os[0].first.childNums[labCt] = counts[labCt] = 0; + lastLabel[labCt] = address2os[0].first.labels[labCt]; + } + int i; + for (i = 1; i < numAddrs; i++) { + for (labCt = 0; labCt < depth; labCt++) { + if (address2os[i].first.labels[labCt] != lastLabel[labCt]) { + int labCt2; + for (labCt2 = labCt + 1; labCt2 < depth; labCt2++) { + counts[labCt2] = 0; + lastLabel[labCt2] = address2os[i].first.labels[labCt2]; + } + counts[labCt]++; + lastLabel[labCt] = address2os[i].first.labels[labCt]; + break; + } + } + for (labCt = 0; labCt < depth; labCt++) { + address2os[i].first.childNums[labCt] = counts[labCt]; + } + for (; labCt < (int)Address::maxDepth; labCt++) { + address2os[i].first.childNums[labCt] = 0; + } + } + __kmp_free(lastLabel); + __kmp_free(counts); +} + +// All of the __kmp_affinity_create_*_map() routines should set +// __kmp_affinity_masks to a vector of affinity mask objects of length +// __kmp_affinity_num_masks, if __kmp_affinity_type != affinity_none, and return +// the number of levels in the machine topology tree (zero if +// __kmp_affinity_type == affinity_none). +// +// All of the __kmp_affinity_create_*_map() routines should set +// *__kmp_affin_fullMask to the affinity mask for the initialization thread. +// They need to save and restore the mask, and it could be needed later, so +// saving it is just an optimization to avoid calling kmp_get_system_affinity() +// again. +kmp_affin_mask_t *__kmp_affin_fullMask = NULL; + +static int nCoresPerPkg, nPackages; +static int __kmp_nThreadsPerCore; +#ifndef KMP_DFLT_NTH_CORES +static int __kmp_ncores; +#endif +static int *__kmp_pu_os_idx = NULL; + +// __kmp_affinity_uniform_topology() doesn't work when called from +// places which support arbitrarily many levels in the machine topology +// map, i.e. the non-default cases in __kmp_affinity_create_cpuinfo_map() +// __kmp_affinity_create_x2apicid_map(). +inline static bool __kmp_affinity_uniform_topology() { + return __kmp_avail_proc == (__kmp_nThreadsPerCore * nCoresPerPkg * nPackages); +} + +// Print out the detailed machine topology map, i.e. the physical locations +// of each OS proc. +static void __kmp_affinity_print_topology(AddrUnsPair *address2os, int len, + int depth, int pkgLevel, + int coreLevel, int threadLevel) { + int proc; + + KMP_INFORM(OSProcToPhysicalThreadMap, "KMP_AFFINITY"); + for (proc = 0; proc < len; proc++) { + int level; + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + for (level = 0; level < depth; level++) { + if (level == threadLevel) { + __kmp_str_buf_print(&buf, "%s ", KMP_I18N_STR(Thread)); + } else if (level == coreLevel) { + __kmp_str_buf_print(&buf, "%s ", KMP_I18N_STR(Core)); + } else if (level == pkgLevel) { + __kmp_str_buf_print(&buf, "%s ", KMP_I18N_STR(Package)); + } else if (level > pkgLevel) { + __kmp_str_buf_print(&buf, "%s_%d ", KMP_I18N_STR(Node), + level - pkgLevel - 1); + } else { + __kmp_str_buf_print(&buf, "L%d ", level); + } + __kmp_str_buf_print(&buf, "%d ", address2os[proc].first.labels[level]); + } + KMP_INFORM(OSProcMapToPack, "KMP_AFFINITY", address2os[proc].second, + buf.str); + __kmp_str_buf_free(&buf); + } +} + +#if KMP_USE_HWLOC + +static void __kmp_affinity_print_hwloc_tp(AddrUnsPair *addrP, int len, + int depth, int *levels) { + int proc; + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + KMP_INFORM(OSProcToPhysicalThreadMap, "KMP_AFFINITY"); + for (proc = 0; proc < len; proc++) { + __kmp_str_buf_print(&buf, "%s %d ", KMP_I18N_STR(Package), + addrP[proc].first.labels[0]); + if (depth > 1) { + int level = 1; // iterate over levels + int label = 1; // iterate over labels + if (__kmp_numa_detected) + // node level follows package + if (levels[level++] > 0) + __kmp_str_buf_print(&buf, "%s %d ", KMP_I18N_STR(Node), + addrP[proc].first.labels[label++]); + if (__kmp_tile_depth > 0) + // tile level follows node if any, or package + if (levels[level++] > 0) + __kmp_str_buf_print(&buf, "%s %d ", KMP_I18N_STR(Tile), + addrP[proc].first.labels[label++]); + if (levels[level++] > 0) + // core level follows + __kmp_str_buf_print(&buf, "%s %d ", KMP_I18N_STR(Core), + addrP[proc].first.labels[label++]); + if (levels[level++] > 0) + // thread level is the latest + __kmp_str_buf_print(&buf, "%s %d ", KMP_I18N_STR(Thread), + addrP[proc].first.labels[label++]); + KMP_DEBUG_ASSERT(label == depth); + } + KMP_INFORM(OSProcMapToPack, "KMP_AFFINITY", addrP[proc].second, buf.str); + __kmp_str_buf_clear(&buf); + } + __kmp_str_buf_free(&buf); +} + +static int nNodePerPkg, nTilePerPkg, nTilePerNode, nCorePerNode, nCorePerTile; + +// This function removes the topology levels that are radix 1 and don't offer +// further information about the topology. The most common example is when you +// have one thread context per core, we don't want the extra thread context +// level if it offers no unique labels. So they are removed. +// return value: the new depth of address2os +static int __kmp_affinity_remove_radix_one_levels(AddrUnsPair *addrP, int nTh, + int depth, int *levels) { + int level; + int i; + int radix1_detected; + int new_depth = depth; + for (level = depth - 1; level > 0; --level) { + // Detect if this level is radix 1 + radix1_detected = 1; + for (i = 1; i < nTh; ++i) { + if (addrP[0].first.labels[level] != addrP[i].first.labels[level]) { + // There are differing label values for this level so it stays + radix1_detected = 0; + break; + } + } + if (!radix1_detected) + continue; + // Radix 1 was detected + --new_depth; + levels[level] = -1; // mark level as not present in address2os array + if (level == new_depth) { + // "turn off" deepest level, just decrement the depth that removes + // the level from address2os array + for (i = 0; i < nTh; ++i) { + addrP[i].first.depth--; + } + } else { + // For other levels, we move labels over and also reduce the depth + int j; + for (j = level; j < new_depth; ++j) { + for (i = 0; i < nTh; ++i) { + addrP[i].first.labels[j] = addrP[i].first.labels[j + 1]; + addrP[i].first.depth--; + } + levels[j + 1] -= 1; + } + } + } + return new_depth; +} + +// Returns the number of objects of type 'type' below 'obj' within the topology +// tree structure. e.g., if obj is a HWLOC_OBJ_PACKAGE object, and type is +// HWLOC_OBJ_PU, then this will return the number of PU's under the SOCKET +// object. +static int __kmp_hwloc_get_nobjs_under_obj(hwloc_obj_t obj, + hwloc_obj_type_t type) { + int retval = 0; + hwloc_obj_t first; + for (first = hwloc_get_obj_below_by_type(__kmp_hwloc_topology, obj->type, + obj->logical_index, type, 0); + first != NULL && + hwloc_get_ancestor_obj_by_type(__kmp_hwloc_topology, obj->type, first) == + obj; + first = hwloc_get_next_obj_by_type(__kmp_hwloc_topology, first->type, + first)) { + ++retval; + } + return retval; +} + +static int __kmp_hwloc_count_children_by_depth(hwloc_topology_t t, + hwloc_obj_t o, unsigned depth, + hwloc_obj_t *f) { + if (o->depth == depth) { + if (*f == NULL) + *f = o; // output first descendant found + return 1; + } + int sum = 0; + for (unsigned i = 0; i < o->arity; i++) + sum += __kmp_hwloc_count_children_by_depth(t, o->children[i], depth, f); + return sum; // will be 0 if no one found (as PU arity is 0) +} + +static int __kmp_hwloc_count_children_by_type(hwloc_topology_t t, hwloc_obj_t o, + hwloc_obj_type_t type, + hwloc_obj_t *f) { + if (!hwloc_compare_types(o->type, type)) { + if (*f == NULL) + *f = o; // output first descendant found + return 1; + } + int sum = 0; + for (unsigned i = 0; i < o->arity; i++) + sum += __kmp_hwloc_count_children_by_type(t, o->children[i], type, f); + return sum; // will be 0 if no one found (as PU arity is 0) +} + +static int __kmp_hwloc_process_obj_core_pu(AddrUnsPair *addrPair, + int &nActiveThreads, + int &num_active_cores, + hwloc_obj_t obj, int depth, + int *labels) { + hwloc_obj_t core = NULL; + hwloc_topology_t &tp = __kmp_hwloc_topology; + int NC = __kmp_hwloc_count_children_by_type(tp, obj, HWLOC_OBJ_CORE, &core); + for (int core_id = 0; core_id < NC; ++core_id, core = core->next_cousin) { + hwloc_obj_t pu = NULL; + KMP_DEBUG_ASSERT(core != NULL); + int num_active_threads = 0; + int NT = __kmp_hwloc_count_children_by_type(tp, core, HWLOC_OBJ_PU, &pu); + // int NT = core->arity; pu = core->first_child; // faster? + for (int pu_id = 0; pu_id < NT; ++pu_id, pu = pu->next_cousin) { + KMP_DEBUG_ASSERT(pu != NULL); + if (!KMP_CPU_ISSET(pu->os_index, __kmp_affin_fullMask)) + continue; // skip inactive (inaccessible) unit + Address addr(depth + 2); + KA_TRACE(20, ("Hwloc inserting %d (%d) %d (%d) %d (%d) into address2os\n", + obj->os_index, obj->logical_index, core->os_index, + core->logical_index, pu->os_index, pu->logical_index)); + for (int i = 0; i < depth; ++i) + addr.labels[i] = labels[i]; // package, etc. + addr.labels[depth] = core_id; // core + addr.labels[depth + 1] = pu_id; // pu + addrPair[nActiveThreads] = AddrUnsPair(addr, pu->os_index); + __kmp_pu_os_idx[nActiveThreads] = pu->os_index; + nActiveThreads++; + ++num_active_threads; // count active threads per core + } + if (num_active_threads) { // were there any active threads on the core? + ++__kmp_ncores; // count total active cores + ++num_active_cores; // count active cores per socket + if (num_active_threads > __kmp_nThreadsPerCore) + __kmp_nThreadsPerCore = num_active_threads; // calc maximum + } + } + return 0; +} + +// Check if NUMA node detected below the package, +// and if tile object is detected and return its depth +static int __kmp_hwloc_check_numa() { + hwloc_topology_t &tp = __kmp_hwloc_topology; + hwloc_obj_t hT, hC, hL, hN, hS; // hwloc objects (pointers to) + int depth; + + // Get some PU + hT = hwloc_get_obj_by_type(tp, HWLOC_OBJ_PU, 0); + if (hT == NULL) // something has gone wrong + return 1; + + // check NUMA node below PACKAGE + hN = hwloc_get_ancestor_obj_by_type(tp, HWLOC_OBJ_NUMANODE, hT); + hS = hwloc_get_ancestor_obj_by_type(tp, HWLOC_OBJ_PACKAGE, hT); + KMP_DEBUG_ASSERT(hS != NULL); + if (hN != NULL && hN->depth > hS->depth) { + __kmp_numa_detected = TRUE; // socket includes node(s) + if (__kmp_affinity_gran == affinity_gran_node) { + __kmp_affinity_gran == affinity_gran_numa; + } + } + + // check tile, get object by depth because of multiple caches possible + depth = hwloc_get_cache_type_depth(tp, 2, HWLOC_OBJ_CACHE_UNIFIED); + hL = hwloc_get_ancestor_obj_by_depth(tp, depth, hT); + hC = NULL; // not used, but reset it here just in case + if (hL != NULL && + __kmp_hwloc_count_children_by_type(tp, hL, HWLOC_OBJ_CORE, &hC) > 1) + __kmp_tile_depth = depth; // tile consists of multiple cores + return 0; +} + +static int __kmp_affinity_create_hwloc_map(AddrUnsPair **address2os, + kmp_i18n_id_t *const msg_id) { + hwloc_topology_t &tp = __kmp_hwloc_topology; // shortcut of a long name + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // Save the affinity mask for the current thread. + kmp_affin_mask_t *oldMask; + KMP_CPU_ALLOC(oldMask); + __kmp_get_system_affinity(oldMask, TRUE); + __kmp_hwloc_check_numa(); + + if (!KMP_AFFINITY_CAPABLE()) { + // Hack to try and infer the machine topology using only the data + // available from cpuid on the current thread, and __kmp_xproc. + KMP_ASSERT(__kmp_affinity_type == affinity_none); + + nCoresPerPkg = __kmp_hwloc_get_nobjs_under_obj( + hwloc_get_obj_by_type(tp, HWLOC_OBJ_PACKAGE, 0), HWLOC_OBJ_CORE); + __kmp_nThreadsPerCore = __kmp_hwloc_get_nobjs_under_obj( + hwloc_get_obj_by_type(tp, HWLOC_OBJ_CORE, 0), HWLOC_OBJ_PU); + __kmp_ncores = __kmp_xproc / __kmp_nThreadsPerCore; + nPackages = (__kmp_xproc + nCoresPerPkg - 1) / nCoresPerPkg; + if (__kmp_affinity_verbose) { + KMP_INFORM(AffNotCapableUseLocCpuidL11, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (__kmp_affinity_uniform_topology()) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + KMP_CPU_FREE(oldMask); + return 0; + } + + int depth = 3; + int levels[5] = {0, 1, 2, 3, 4}; // package, [node,] [tile,] core, thread + int labels[3] = {0}; // package [,node] [,tile] - head of lables array + if (__kmp_numa_detected) + ++depth; + if (__kmp_tile_depth) + ++depth; + + // Allocate the data structure to be returned. + AddrUnsPair *retval = + (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * __kmp_avail_proc); + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + + // When affinity is off, this routine will still be called to set + // __kmp_ncores, as well as __kmp_nThreadsPerCore, + // nCoresPerPkg, & nPackages. Make sure all these vars are set + // correctly, and return if affinity is not enabled. + + hwloc_obj_t socket, node, tile; + int nActiveThreads = 0; + int socket_id = 0; + // re-calculate globals to count only accessible resources + __kmp_ncores = nPackages = nCoresPerPkg = __kmp_nThreadsPerCore = 0; + nNodePerPkg = nTilePerPkg = nTilePerNode = nCorePerNode = nCorePerTile = 0; + for (socket = hwloc_get_obj_by_type(tp, HWLOC_OBJ_PACKAGE, 0); socket != NULL; + socket = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PACKAGE, socket), + socket_id++) { + labels[0] = socket_id; + if (__kmp_numa_detected) { + int NN; + int n_active_nodes = 0; + node = NULL; + NN = __kmp_hwloc_count_children_by_type(tp, socket, HWLOC_OBJ_NUMANODE, + &node); + for (int node_id = 0; node_id < NN; ++node_id, node = node->next_cousin) { + labels[1] = node_id; + if (__kmp_tile_depth) { + // NUMA + tiles + int NT; + int n_active_tiles = 0; + tile = NULL; + NT = __kmp_hwloc_count_children_by_depth(tp, node, __kmp_tile_depth, + &tile); + for (int tl_id = 0; tl_id < NT; ++tl_id, tile = tile->next_cousin) { + labels[2] = tl_id; + int n_active_cores = 0; + __kmp_hwloc_process_obj_core_pu(retval, nActiveThreads, + n_active_cores, tile, 3, labels); + if (n_active_cores) { // were there any active cores on the socket? + ++n_active_tiles; // count active tiles per node + if (n_active_cores > nCorePerTile) + nCorePerTile = n_active_cores; // calc maximum + } + } + if (n_active_tiles) { // were there any active tiles on the socket? + ++n_active_nodes; // count active nodes per package + if (n_active_tiles > nTilePerNode) + nTilePerNode = n_active_tiles; // calc maximum + } + } else { + // NUMA, no tiles + int n_active_cores = 0; + __kmp_hwloc_process_obj_core_pu(retval, nActiveThreads, + n_active_cores, node, 2, labels); + if (n_active_cores) { // were there any active cores on the socket? + ++n_active_nodes; // count active nodes per package + if (n_active_cores > nCorePerNode) + nCorePerNode = n_active_cores; // calc maximum + } + } + } + if (n_active_nodes) { // were there any active nodes on the socket? + ++nPackages; // count total active packages + if (n_active_nodes > nNodePerPkg) + nNodePerPkg = n_active_nodes; // calc maximum + } + } else { + if (__kmp_tile_depth) { + // no NUMA, tiles + int NT; + int n_active_tiles = 0; + tile = NULL; + NT = __kmp_hwloc_count_children_by_depth(tp, socket, __kmp_tile_depth, + &tile); + for (int tl_id = 0; tl_id < NT; ++tl_id, tile = tile->next_cousin) { + labels[1] = tl_id; + int n_active_cores = 0; + __kmp_hwloc_process_obj_core_pu(retval, nActiveThreads, + n_active_cores, tile, 2, labels); + if (n_active_cores) { // were there any active cores on the socket? + ++n_active_tiles; // count active tiles per package + if (n_active_cores > nCorePerTile) + nCorePerTile = n_active_cores; // calc maximum + } + } + if (n_active_tiles) { // were there any active tiles on the socket? + ++nPackages; // count total active packages + if (n_active_tiles > nTilePerPkg) + nTilePerPkg = n_active_tiles; // calc maximum + } + } else { + // no NUMA, no tiles + int n_active_cores = 0; + __kmp_hwloc_process_obj_core_pu(retval, nActiveThreads, n_active_cores, + socket, 1, labels); + if (n_active_cores) { // were there any active cores on the socket? + ++nPackages; // count total active packages + if (n_active_cores > nCoresPerPkg) + nCoresPerPkg = n_active_cores; // calc maximum + } + } + } + } + + // If there's only one thread context to bind to, return now. + KMP_DEBUG_ASSERT(nActiveThreads == __kmp_avail_proc); + KMP_ASSERT(nActiveThreads > 0); + if (nActiveThreads == 1) { + __kmp_ncores = nPackages = 1; + __kmp_nThreadsPerCore = nCoresPerPkg = 1; + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + + KMP_INFORM(AffUsingHwloc, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + + if (__kmp_affinity_type == affinity_none) { + __kmp_free(retval); + KMP_CPU_FREE(oldMask); + return 0; + } + + // Form an Address object which only includes the package level. + Address addr(1); + addr.labels[0] = retval[0].first.labels[0]; + retval[0].first = addr; + + if (__kmp_affinity_gran_levels < 0) { + __kmp_affinity_gran_levels = 0; + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(retval, 1, 1, 0, -1, -1); + } + + *address2os = retval; + KMP_CPU_FREE(oldMask); + return 1; + } + + // Sort the table by physical Id. + qsort(retval, nActiveThreads, sizeof(*retval), + __kmp_affinity_cmp_Address_labels); + + // Check to see if the machine topology is uniform + int nPUs = nPackages * __kmp_nThreadsPerCore; + if (__kmp_numa_detected) { + if (__kmp_tile_depth) { // NUMA + tiles + nPUs *= (nNodePerPkg * nTilePerNode * nCorePerTile); + } else { // NUMA, no tiles + nPUs *= (nNodePerPkg * nCorePerNode); + } + } else { + if (__kmp_tile_depth) { // no NUMA, tiles + nPUs *= (nTilePerPkg * nCorePerTile); + } else { // no NUMA, no tiles + nPUs *= nCoresPerPkg; + } + } + unsigned uniform = (nPUs == nActiveThreads); + + // Print the machine topology summary. + if (__kmp_affinity_verbose) { + char mask[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(mask, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", mask); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", mask); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (uniform) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + if (__kmp_numa_detected) { + if (__kmp_tile_depth) { // NUMA + tiles + KMP_INFORM(TopologyExtraNoTi, "KMP_AFFINITY", nPackages, nNodePerPkg, + nTilePerNode, nCorePerTile, __kmp_nThreadsPerCore, + __kmp_ncores); + } else { // NUMA, no tiles + KMP_INFORM(TopologyExtraNode, "KMP_AFFINITY", nPackages, nNodePerPkg, + nCorePerNode, __kmp_nThreadsPerCore, __kmp_ncores); + nPUs *= (nNodePerPkg * nCorePerNode); + } + } else { + if (__kmp_tile_depth) { // no NUMA, tiles + KMP_INFORM(TopologyExtraTile, "KMP_AFFINITY", nPackages, nTilePerPkg, + nCorePerTile, __kmp_nThreadsPerCore, __kmp_ncores); + } else { // no NUMA, no tiles + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + __kmp_str_buf_print(&buf, "%d", nPackages); + KMP_INFORM(TopologyExtra, "KMP_AFFINITY", buf.str, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + __kmp_str_buf_free(&buf); + } + } + } + + if (__kmp_affinity_type == affinity_none) { + __kmp_free(retval); + KMP_CPU_FREE(oldMask); + return 0; + } + + int depth_full = depth; // number of levels before compressing + // Find any levels with radiix 1, and remove them from the map + // (except for the package level). + depth = __kmp_affinity_remove_radix_one_levels(retval, nActiveThreads, depth, + levels); + KMP_DEBUG_ASSERT(__kmp_affinity_gran != affinity_gran_default); + if (__kmp_affinity_gran_levels < 0) { + // Set the granularity level based on what levels are modeled + // in the machine topology map. + __kmp_affinity_gran_levels = 0; // lowest level (e.g. fine) + if (__kmp_affinity_gran > affinity_gran_thread) { + for (int i = 1; i <= depth_full; ++i) { + if (__kmp_affinity_gran <= i) // only count deeper levels + break; + if (levels[depth_full - i] > 0) + __kmp_affinity_gran_levels++; + } + } + if (__kmp_affinity_gran > affinity_gran_package) + __kmp_affinity_gran_levels++; // e.g. granularity = group + } + + if (__kmp_affinity_verbose) + __kmp_affinity_print_hwloc_tp(retval, nActiveThreads, depth, levels); + + KMP_CPU_FREE(oldMask); + *address2os = retval; + return depth; +} +#endif // KMP_USE_HWLOC + +// If we don't know how to retrieve the machine's processor topology, or +// encounter an error in doing so, this routine is called to form a "flat" +// mapping of os thread id's <-> processor id's. +static int __kmp_affinity_create_flat_map(AddrUnsPair **address2os, + kmp_i18n_id_t *const msg_id) { + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // Even if __kmp_affinity_type == affinity_none, this routine might still + // called to set __kmp_ncores, as well as + // __kmp_nThreadsPerCore, nCoresPerPkg, & nPackages. + if (!KMP_AFFINITY_CAPABLE()) { + KMP_ASSERT(__kmp_affinity_type == affinity_none); + __kmp_ncores = nPackages = __kmp_xproc; + __kmp_nThreadsPerCore = nCoresPerPkg = 1; + if (__kmp_affinity_verbose) { + KMP_INFORM(AffFlatTopology, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + return 0; + } + + // When affinity is off, this routine will still be called to set + // __kmp_ncores, as well as __kmp_nThreadsPerCore, nCoresPerPkg, & nPackages. + // Make sure all these vars are set correctly, and return now if affinity is + // not enabled. + __kmp_ncores = nPackages = __kmp_avail_proc; + __kmp_nThreadsPerCore = nCoresPerPkg = 1; + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + __kmp_affin_fullMask); + + KMP_INFORM(AffCapableUseFlat, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + if (__kmp_affinity_type == affinity_none) { + int avail_ct = 0; + int i; + KMP_CPU_SET_ITERATE(i, __kmp_affin_fullMask) { + if (!KMP_CPU_ISSET(i, __kmp_affin_fullMask)) + continue; + __kmp_pu_os_idx[avail_ct++] = i; // suppose indices are flat + } + return 0; + } + + // Contruct the data structure to be returned. + *address2os = + (AddrUnsPair *)__kmp_allocate(sizeof(**address2os) * __kmp_avail_proc); + int avail_ct = 0; + int i; + KMP_CPU_SET_ITERATE(i, __kmp_affin_fullMask) { + // Skip this proc if it is not included in the machine model. + if (!KMP_CPU_ISSET(i, __kmp_affin_fullMask)) { + continue; + } + __kmp_pu_os_idx[avail_ct] = i; // suppose indices are flat + Address addr(1); + addr.labels[0] = i; + (*address2os)[avail_ct++] = AddrUnsPair(addr, i); + } + if (__kmp_affinity_verbose) { + KMP_INFORM(OSProcToPackage, "KMP_AFFINITY"); + } + + if (__kmp_affinity_gran_levels < 0) { + // Only the package level is modeled in the machine topology map, + // so the #levels of granularity is either 0 or 1. + if (__kmp_affinity_gran > affinity_gran_package) { + __kmp_affinity_gran_levels = 1; + } else { + __kmp_affinity_gran_levels = 0; + } + } + return 1; +} + +#if KMP_GROUP_AFFINITY + +// If multiple Windows* OS processor groups exist, we can create a 2-level +// topology map with the groups at level 0 and the individual procs at level 1. +// This facilitates letting the threads float among all procs in a group, +// if granularity=group (the default when there are multiple groups). +static int __kmp_affinity_create_proc_group_map(AddrUnsPair **address2os, + kmp_i18n_id_t *const msg_id) { + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // If we aren't affinity capable, then return now. + // The flat mapping will be used. + if (!KMP_AFFINITY_CAPABLE()) { + // FIXME set *msg_id + return -1; + } + + // Contruct the data structure to be returned. + *address2os = + (AddrUnsPair *)__kmp_allocate(sizeof(**address2os) * __kmp_avail_proc); + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + int avail_ct = 0; + int i; + KMP_CPU_SET_ITERATE(i, __kmp_affin_fullMask) { + // Skip this proc if it is not included in the machine model. + if (!KMP_CPU_ISSET(i, __kmp_affin_fullMask)) { + continue; + } + __kmp_pu_os_idx[avail_ct] = i; // suppose indices are flat + Address addr(2); + addr.labels[0] = i / (CHAR_BIT * sizeof(DWORD_PTR)); + addr.labels[1] = i % (CHAR_BIT * sizeof(DWORD_PTR)); + (*address2os)[avail_ct++] = AddrUnsPair(addr, i); + + if (__kmp_affinity_verbose) { + KMP_INFORM(AffOSProcToGroup, "KMP_AFFINITY", i, addr.labels[0], + addr.labels[1]); + } + } + + if (__kmp_affinity_gran_levels < 0) { + if (__kmp_affinity_gran == affinity_gran_group) { + __kmp_affinity_gran_levels = 1; + } else if ((__kmp_affinity_gran == affinity_gran_fine) || + (__kmp_affinity_gran == affinity_gran_thread)) { + __kmp_affinity_gran_levels = 0; + } else { + const char *gran_str = NULL; + if (__kmp_affinity_gran == affinity_gran_core) { + gran_str = "core"; + } else if (__kmp_affinity_gran == affinity_gran_package) { + gran_str = "package"; + } else if (__kmp_affinity_gran == affinity_gran_node) { + gran_str = "node"; + } else { + KMP_ASSERT(0); + } + + // Warning: can't use affinity granularity \"gran\" with group topology + // method, using "thread" + __kmp_affinity_gran_levels = 0; + } + } + return 2; +} + +#endif /* KMP_GROUP_AFFINITY */ + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + +static int __kmp_cpuid_mask_width(int count) { + int r = 0; + + while ((1 << r) < count) + ++r; + return r; +} + +class apicThreadInfo { +public: + unsigned osId; // param to __kmp_affinity_bind_thread + unsigned apicId; // from cpuid after binding + unsigned maxCoresPerPkg; // "" + unsigned maxThreadsPerPkg; // "" + unsigned pkgId; // inferred from above values + unsigned coreId; // "" + unsigned threadId; // "" +}; + +static int __kmp_affinity_cmp_apicThreadInfo_phys_id(const void *a, + const void *b) { + const apicThreadInfo *aa = (const apicThreadInfo *)a; + const apicThreadInfo *bb = (const apicThreadInfo *)b; + if (aa->pkgId < bb->pkgId) + return -1; + if (aa->pkgId > bb->pkgId) + return 1; + if (aa->coreId < bb->coreId) + return -1; + if (aa->coreId > bb->coreId) + return 1; + if (aa->threadId < bb->threadId) + return -1; + if (aa->threadId > bb->threadId) + return 1; + return 0; +} + +// On IA-32 architecture and Intel(R) 64 architecture, we attempt to use +// an algorithm which cycles through the available os threads, setting +// the current thread's affinity mask to that thread, and then retrieves +// the Apic Id for each thread context using the cpuid instruction. +static int __kmp_affinity_create_apicid_map(AddrUnsPair **address2os, + kmp_i18n_id_t *const msg_id) { + kmp_cpuid buf; + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // Check if cpuid leaf 4 is supported. + __kmp_x86_cpuid(0, 0, &buf); + if (buf.eax < 4) { + *msg_id = kmp_i18n_str_NoLeaf4Support; + return -1; + } + + // The algorithm used starts by setting the affinity to each available thread + // and retrieving info from the cpuid instruction, so if we are not capable of + // calling __kmp_get_system_affinity() and _kmp_get_system_affinity(), then we + // need to do something else - use the defaults that we calculated from + // issuing cpuid without binding to each proc. + if (!KMP_AFFINITY_CAPABLE()) { + // Hack to try and infer the machine topology using only the data + // available from cpuid on the current thread, and __kmp_xproc. + KMP_ASSERT(__kmp_affinity_type == affinity_none); + + // Get an upper bound on the number of threads per package using cpuid(1). + // On some OS/chps combinations where HT is supported by the chip but is + // disabled, this value will be 2 on a single core chip. Usually, it will be + // 2 if HT is enabled and 1 if HT is disabled. + __kmp_x86_cpuid(1, 0, &buf); + int maxThreadsPerPkg = (buf.ebx >> 16) & 0xff; + if (maxThreadsPerPkg == 0) { + maxThreadsPerPkg = 1; + } + + // The num cores per pkg comes from cpuid(4). 1 must be added to the encoded + // value. + // + // The author of cpu_count.cpp treated this only an upper bound on the + // number of cores, but I haven't seen any cases where it was greater than + // the actual number of cores, so we will treat it as exact in this block of + // code. + // + // First, we need to check if cpuid(4) is supported on this chip. To see if + // cpuid(n) is supported, issue cpuid(0) and check if eax has the value n or + // greater. + __kmp_x86_cpuid(0, 0, &buf); + if (buf.eax >= 4) { + __kmp_x86_cpuid(4, 0, &buf); + nCoresPerPkg = ((buf.eax >> 26) & 0x3f) + 1; + } else { + nCoresPerPkg = 1; + } + + // There is no way to reliably tell if HT is enabled without issuing the + // cpuid instruction from every thread, can correlating the cpuid info, so + // if the machine is not affinity capable, we assume that HT is off. We have + // seen quite a few machines where maxThreadsPerPkg is 2, yet the machine + // does not support HT. + // + // - Older OSes are usually found on machines with older chips, which do not + // support HT. + // - The performance penalty for mistakenly identifying a machine as HT when + // it isn't (which results in blocktime being incorrecly set to 0) is + // greater than the penalty when for mistakenly identifying a machine as + // being 1 thread/core when it is really HT enabled (which results in + // blocktime being incorrectly set to a positive value). + __kmp_ncores = __kmp_xproc; + nPackages = (__kmp_xproc + nCoresPerPkg - 1) / nCoresPerPkg; + __kmp_nThreadsPerCore = 1; + if (__kmp_affinity_verbose) { + KMP_INFORM(AffNotCapableUseLocCpuid, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (__kmp_affinity_uniform_topology()) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + return 0; + } + + // From here on, we can assume that it is safe to call + // __kmp_get_system_affinity() and __kmp_set_system_affinity(), even if + // __kmp_affinity_type = affinity_none. + + // Save the affinity mask for the current thread. + kmp_affin_mask_t *oldMask; + KMP_CPU_ALLOC(oldMask); + KMP_ASSERT(oldMask != NULL); + __kmp_get_system_affinity(oldMask, TRUE); + + // Run through each of the available contexts, binding the current thread + // to it, and obtaining the pertinent information using the cpuid instr. + // + // The relevant information is: + // - Apic Id: Bits 24:31 of ebx after issuing cpuid(1) - each thread context + // has a uniqie Apic Id, which is of the form pkg# : core# : thread#. + // - Max Threads Per Pkg: Bits 16:23 of ebx after issuing cpuid(1). The value + // of this field determines the width of the core# + thread# fields in the + // Apic Id. It is also an upper bound on the number of threads per + // package, but it has been verified that situations happen were it is not + // exact. In particular, on certain OS/chip combinations where Intel(R) + // Hyper-Threading Technology is supported by the chip but has been + // disabled, the value of this field will be 2 (for a single core chip). + // On other OS/chip combinations supporting Intel(R) Hyper-Threading + // Technology, the value of this field will be 1 when Intel(R) + // Hyper-Threading Technology is disabled and 2 when it is enabled. + // - Max Cores Per Pkg: Bits 26:31 of eax after issuing cpuid(4). The value + // of this field (+1) determines the width of the core# field in the Apic + // Id. The comments in "cpucount.cpp" say that this value is an upper + // bound, but the IA-32 architecture manual says that it is exactly the + // number of cores per package, and I haven't seen any case where it + // wasn't. + // + // From this information, deduce the package Id, core Id, and thread Id, + // and set the corresponding fields in the apicThreadInfo struct. + unsigned i; + apicThreadInfo *threadInfo = (apicThreadInfo *)__kmp_allocate( + __kmp_avail_proc * sizeof(apicThreadInfo)); + unsigned nApics = 0; + KMP_CPU_SET_ITERATE(i, __kmp_affin_fullMask) { + // Skip this proc if it is not included in the machine model. + if (!KMP_CPU_ISSET(i, __kmp_affin_fullMask)) { + continue; + } + KMP_DEBUG_ASSERT((int)nApics < __kmp_avail_proc); + + __kmp_affinity_dispatch->bind_thread(i); + threadInfo[nApics].osId = i; + + // The apic id and max threads per pkg come from cpuid(1). + __kmp_x86_cpuid(1, 0, &buf); + if (((buf.edx >> 9) & 1) == 0) { + __kmp_set_system_affinity(oldMask, TRUE); + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_ApicNotPresent; + return -1; + } + threadInfo[nApics].apicId = (buf.ebx >> 24) & 0xff; + threadInfo[nApics].maxThreadsPerPkg = (buf.ebx >> 16) & 0xff; + if (threadInfo[nApics].maxThreadsPerPkg == 0) { + threadInfo[nApics].maxThreadsPerPkg = 1; + } + + // Max cores per pkg comes from cpuid(4). 1 must be added to the encoded + // value. + // + // First, we need to check if cpuid(4) is supported on this chip. To see if + // cpuid(n) is supported, issue cpuid(0) and check if eax has the value n + // or greater. + __kmp_x86_cpuid(0, 0, &buf); + if (buf.eax >= 4) { + __kmp_x86_cpuid(4, 0, &buf); + threadInfo[nApics].maxCoresPerPkg = ((buf.eax >> 26) & 0x3f) + 1; + } else { + threadInfo[nApics].maxCoresPerPkg = 1; + } + + // Infer the pkgId / coreId / threadId using only the info obtained locally. + int widthCT = __kmp_cpuid_mask_width(threadInfo[nApics].maxThreadsPerPkg); + threadInfo[nApics].pkgId = threadInfo[nApics].apicId >> widthCT; + + int widthC = __kmp_cpuid_mask_width(threadInfo[nApics].maxCoresPerPkg); + int widthT = widthCT - widthC; + if (widthT < 0) { + // I've never seen this one happen, but I suppose it could, if the cpuid + // instruction on a chip was really screwed up. Make sure to restore the + // affinity mask before the tail call. + __kmp_set_system_affinity(oldMask, TRUE); + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + + int maskC = (1 << widthC) - 1; + threadInfo[nApics].coreId = (threadInfo[nApics].apicId >> widthT) & maskC; + + int maskT = (1 << widthT) - 1; + threadInfo[nApics].threadId = threadInfo[nApics].apicId & maskT; + + nApics++; + } + + // We've collected all the info we need. + // Restore the old affinity mask for this thread. + __kmp_set_system_affinity(oldMask, TRUE); + + // If there's only one thread context to bind to, form an Address object + // with depth 1 and return immediately (or, if affinity is off, set + // address2os to NULL and return). + // + // If it is configured to omit the package level when there is only a single + // package, the logic at the end of this routine won't work if there is only + // a single thread - it would try to form an Address object with depth 0. + KMP_ASSERT(nApics > 0); + if (nApics == 1) { + __kmp_ncores = nPackages = 1; + __kmp_nThreadsPerCore = nCoresPerPkg = 1; + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + + KMP_INFORM(AffUseGlobCpuid, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + + if (__kmp_affinity_type == affinity_none) { + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + return 0; + } + + *address2os = (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair)); + Address addr(1); + addr.labels[0] = threadInfo[0].pkgId; + (*address2os)[0] = AddrUnsPair(addr, threadInfo[0].osId); + + if (__kmp_affinity_gran_levels < 0) { + __kmp_affinity_gran_levels = 0; + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(*address2os, 1, 1, 0, -1, -1); + } + + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + return 1; + } + + // Sort the threadInfo table by physical Id. + qsort(threadInfo, nApics, sizeof(*threadInfo), + __kmp_affinity_cmp_apicThreadInfo_phys_id); + + // The table is now sorted by pkgId / coreId / threadId, but we really don't + // know the radix of any of the fields. pkgId's may be sparsely assigned among + // the chips on a system. Although coreId's are usually assigned + // [0 .. coresPerPkg-1] and threadId's are usually assigned + // [0..threadsPerCore-1], we don't want to make any such assumptions. + // + // For that matter, we don't know what coresPerPkg and threadsPerCore (or the + // total # packages) are at this point - we want to determine that now. We + // only have an upper bound on the first two figures. + // + // We also perform a consistency check at this point: the values returned by + // the cpuid instruction for any thread bound to a given package had better + // return the same info for maxThreadsPerPkg and maxCoresPerPkg. + nPackages = 1; + nCoresPerPkg = 1; + __kmp_nThreadsPerCore = 1; + unsigned nCores = 1; + + unsigned pkgCt = 1; // to determine radii + unsigned lastPkgId = threadInfo[0].pkgId; + unsigned coreCt = 1; + unsigned lastCoreId = threadInfo[0].coreId; + unsigned threadCt = 1; + unsigned lastThreadId = threadInfo[0].threadId; + + // intra-pkg consist checks + unsigned prevMaxCoresPerPkg = threadInfo[0].maxCoresPerPkg; + unsigned prevMaxThreadsPerPkg = threadInfo[0].maxThreadsPerPkg; + + for (i = 1; i < nApics; i++) { + if (threadInfo[i].pkgId != lastPkgId) { + nCores++; + pkgCt++; + lastPkgId = threadInfo[i].pkgId; + if ((int)coreCt > nCoresPerPkg) + nCoresPerPkg = coreCt; + coreCt = 1; + lastCoreId = threadInfo[i].coreId; + if ((int)threadCt > __kmp_nThreadsPerCore) + __kmp_nThreadsPerCore = threadCt; + threadCt = 1; + lastThreadId = threadInfo[i].threadId; + + // This is a different package, so go on to the next iteration without + // doing any consistency checks. Reset the consistency check vars, though. + prevMaxCoresPerPkg = threadInfo[i].maxCoresPerPkg; + prevMaxThreadsPerPkg = threadInfo[i].maxThreadsPerPkg; + continue; + } + + if (threadInfo[i].coreId != lastCoreId) { + nCores++; + coreCt++; + lastCoreId = threadInfo[i].coreId; + if ((int)threadCt > __kmp_nThreadsPerCore) + __kmp_nThreadsPerCore = threadCt; + threadCt = 1; + lastThreadId = threadInfo[i].threadId; + } else if (threadInfo[i].threadId != lastThreadId) { + threadCt++; + lastThreadId = threadInfo[i].threadId; + } else { + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_LegacyApicIDsNotUnique; + return -1; + } + + // Check to make certain that the maxCoresPerPkg and maxThreadsPerPkg + // fields agree between all the threads bounds to a given package. + if ((prevMaxCoresPerPkg != threadInfo[i].maxCoresPerPkg) || + (prevMaxThreadsPerPkg != threadInfo[i].maxThreadsPerPkg)) { + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_InconsistentCpuidInfo; + return -1; + } + } + nPackages = pkgCt; + if ((int)coreCt > nCoresPerPkg) + nCoresPerPkg = coreCt; + if ((int)threadCt > __kmp_nThreadsPerCore) + __kmp_nThreadsPerCore = threadCt; + + // When affinity is off, this routine will still be called to set + // __kmp_ncores, as well as __kmp_nThreadsPerCore, nCoresPerPkg, & nPackages. + // Make sure all these vars are set correctly, and return now if affinity is + // not enabled. + __kmp_ncores = nCores; + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + + KMP_INFORM(AffUseGlobCpuid, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (__kmp_affinity_uniform_topology()) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + KMP_DEBUG_ASSERT(nApics == (unsigned)__kmp_avail_proc); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + for (i = 0; i < nApics; ++i) { + __kmp_pu_os_idx[i] = threadInfo[i].osId; + } + if (__kmp_affinity_type == affinity_none) { + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + return 0; + } + + // Now that we've determined the number of packages, the number of cores per + // package, and the number of threads per core, we can construct the data + // structure that is to be returned. + int pkgLevel = 0; + int coreLevel = (nCoresPerPkg <= 1) ? -1 : 1; + int threadLevel = + (__kmp_nThreadsPerCore <= 1) ? -1 : ((coreLevel >= 0) ? 2 : 1); + unsigned depth = (pkgLevel >= 0) + (coreLevel >= 0) + (threadLevel >= 0); + + KMP_ASSERT(depth > 0); + *address2os = (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * nApics); + + for (i = 0; i < nApics; ++i) { + Address addr(depth); + unsigned os = threadInfo[i].osId; + int d = 0; + + if (pkgLevel >= 0) { + addr.labels[d++] = threadInfo[i].pkgId; + } + if (coreLevel >= 0) { + addr.labels[d++] = threadInfo[i].coreId; + } + if (threadLevel >= 0) { + addr.labels[d++] = threadInfo[i].threadId; + } + (*address2os)[i] = AddrUnsPair(addr, os); + } + + if (__kmp_affinity_gran_levels < 0) { + // Set the granularity level based on what levels are modeled in the machine + // topology map. + __kmp_affinity_gran_levels = 0; + if ((threadLevel >= 0) && (__kmp_affinity_gran > affinity_gran_thread)) { + __kmp_affinity_gran_levels++; + } + if ((coreLevel >= 0) && (__kmp_affinity_gran > affinity_gran_core)) { + __kmp_affinity_gran_levels++; + } + if ((pkgLevel >= 0) && (__kmp_affinity_gran > affinity_gran_package)) { + __kmp_affinity_gran_levels++; + } + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(*address2os, nApics, depth, pkgLevel, + coreLevel, threadLevel); + } + + __kmp_free(threadInfo); + KMP_CPU_FREE(oldMask); + return depth; +} + +// Intel(R) microarchitecture code name Nehalem, Dunnington and later +// architectures support a newer interface for specifying the x2APIC Ids, +// based on cpuid leaf 11. +static int __kmp_affinity_create_x2apicid_map(AddrUnsPair **address2os, + kmp_i18n_id_t *const msg_id) { + kmp_cpuid buf; + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // Check to see if cpuid leaf 11 is supported. + __kmp_x86_cpuid(0, 0, &buf); + if (buf.eax < 11) { + *msg_id = kmp_i18n_str_NoLeaf11Support; + return -1; + } + __kmp_x86_cpuid(11, 0, &buf); + if (buf.ebx == 0) { + *msg_id = kmp_i18n_str_NoLeaf11Support; + return -1; + } + + // Find the number of levels in the machine topology. While we're at it, get + // the default values for __kmp_nThreadsPerCore & nCoresPerPkg. We will try to + // get more accurate values later by explicitly counting them, but get + // reasonable defaults now, in case we return early. + int level; + int threadLevel = -1; + int coreLevel = -1; + int pkgLevel = -1; + __kmp_nThreadsPerCore = nCoresPerPkg = nPackages = 1; + + for (level = 0;; level++) { + if (level > 31) { + // FIXME: Hack for DPD200163180 + // + // If level is big then something went wrong -> exiting + // + // There could actually be 32 valid levels in the machine topology, but so + // far, the only machine we have seen which does not exit this loop before + // iteration 32 has fubar x2APIC settings. + // + // For now, just reject this case based upon loop trip count. + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + __kmp_x86_cpuid(11, level, &buf); + if (buf.ebx == 0) { + if (pkgLevel < 0) { + // Will infer nPackages from __kmp_xproc + pkgLevel = level; + level++; + } + break; + } + int kind = (buf.ecx >> 8) & 0xff; + if (kind == 1) { + // SMT level + threadLevel = level; + coreLevel = -1; + pkgLevel = -1; + __kmp_nThreadsPerCore = buf.ebx & 0xffff; + if (__kmp_nThreadsPerCore == 0) { + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + } else if (kind == 2) { + // core level + coreLevel = level; + pkgLevel = -1; + nCoresPerPkg = buf.ebx & 0xffff; + if (nCoresPerPkg == 0) { + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + } else { + if (level <= 0) { + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + if (pkgLevel >= 0) { + continue; + } + pkgLevel = level; + nPackages = buf.ebx & 0xffff; + if (nPackages == 0) { + *msg_id = kmp_i18n_str_InvalidCpuidInfo; + return -1; + } + } + } + int depth = level; + + // In the above loop, "level" was counted from the finest level (usually + // thread) to the coarsest. The caller expects that we will place the labels + // in (*address2os)[].first.labels[] in the inverse order, so we need to + // invert the vars saying which level means what. + if (threadLevel >= 0) { + threadLevel = depth - threadLevel - 1; + } + if (coreLevel >= 0) { + coreLevel = depth - coreLevel - 1; + } + KMP_DEBUG_ASSERT(pkgLevel >= 0); + pkgLevel = depth - pkgLevel - 1; + + // The algorithm used starts by setting the affinity to each available thread + // and retrieving info from the cpuid instruction, so if we are not capable of + // calling __kmp_get_system_affinity() and _kmp_get_system_affinity(), then we + // need to do something else - use the defaults that we calculated from + // issuing cpuid without binding to each proc. + if (!KMP_AFFINITY_CAPABLE()) { + // Hack to try and infer the machine topology using only the data + // available from cpuid on the current thread, and __kmp_xproc. + KMP_ASSERT(__kmp_affinity_type == affinity_none); + + __kmp_ncores = __kmp_xproc / __kmp_nThreadsPerCore; + nPackages = (__kmp_xproc + nCoresPerPkg - 1) / nCoresPerPkg; + if (__kmp_affinity_verbose) { + KMP_INFORM(AffNotCapableUseLocCpuidL11, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (__kmp_affinity_uniform_topology()) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + return 0; + } + + // From here on, we can assume that it is safe to call + // __kmp_get_system_affinity() and __kmp_set_system_affinity(), even if + // __kmp_affinity_type = affinity_none. + + // Save the affinity mask for the current thread. + kmp_affin_mask_t *oldMask; + KMP_CPU_ALLOC(oldMask); + __kmp_get_system_affinity(oldMask, TRUE); + + // Allocate the data structure to be returned. + AddrUnsPair *retval = + (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * __kmp_avail_proc); + + // Run through each of the available contexts, binding the current thread + // to it, and obtaining the pertinent information using the cpuid instr. + unsigned int proc; + int nApics = 0; + KMP_CPU_SET_ITERATE(proc, __kmp_affin_fullMask) { + // Skip this proc if it is not included in the machine model. + if (!KMP_CPU_ISSET(proc, __kmp_affin_fullMask)) { + continue; + } + KMP_DEBUG_ASSERT(nApics < __kmp_avail_proc); + + __kmp_affinity_dispatch->bind_thread(proc); + + // Extract labels for each level in the machine topology map from Apic ID. + Address addr(depth); + int prev_shift = 0; + + for (level = 0; level < depth; level++) { + __kmp_x86_cpuid(11, level, &buf); + unsigned apicId = buf.edx; + if (buf.ebx == 0) { + if (level != depth - 1) { + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_InconsistentCpuidInfo; + return -1; + } + addr.labels[depth - level - 1] = apicId >> prev_shift; + level++; + break; + } + int shift = buf.eax & 0x1f; + int mask = (1 << shift) - 1; + addr.labels[depth - level - 1] = (apicId & mask) >> prev_shift; + prev_shift = shift; + } + if (level != depth) { + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_InconsistentCpuidInfo; + return -1; + } + + retval[nApics] = AddrUnsPair(addr, proc); + nApics++; + } + + // We've collected all the info we need. + // Restore the old affinity mask for this thread. + __kmp_set_system_affinity(oldMask, TRUE); + + // If there's only one thread context to bind to, return now. + KMP_ASSERT(nApics > 0); + if (nApics == 1) { + __kmp_ncores = nPackages = 1; + __kmp_nThreadsPerCore = nCoresPerPkg = 1; + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + + KMP_INFORM(AffUseGlobCpuidL11, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + KMP_INFORM(Topology, "KMP_AFFINITY", nPackages, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + } + + if (__kmp_affinity_type == affinity_none) { + __kmp_free(retval); + KMP_CPU_FREE(oldMask); + return 0; + } + + // Form an Address object which only includes the package level. + Address addr(1); + addr.labels[0] = retval[0].first.labels[pkgLevel]; + retval[0].first = addr; + + if (__kmp_affinity_gran_levels < 0) { + __kmp_affinity_gran_levels = 0; + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(retval, 1, 1, 0, -1, -1); + } + + *address2os = retval; + KMP_CPU_FREE(oldMask); + return 1; + } + + // Sort the table by physical Id. + qsort(retval, nApics, sizeof(*retval), __kmp_affinity_cmp_Address_labels); + + // Find the radix at each of the levels. + unsigned *totals = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + unsigned *counts = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + unsigned *maxCt = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + unsigned *last = (unsigned *)__kmp_allocate(depth * sizeof(unsigned)); + for (level = 0; level < depth; level++) { + totals[level] = 1; + maxCt[level] = 1; + counts[level] = 1; + last[level] = retval[0].first.labels[level]; + } + + // From here on, the iteration variable "level" runs from the finest level to + // the coarsest, i.e. we iterate forward through + // (*address2os)[].first.labels[] - in the previous loops, we iterated + // backwards. + for (proc = 1; (int)proc < nApics; proc++) { + int level; + for (level = 0; level < depth; level++) { + if (retval[proc].first.labels[level] != last[level]) { + int j; + for (j = level + 1; j < depth; j++) { + totals[j]++; + counts[j] = 1; + // The line below causes printing incorrect topology information in + // case the max value for some level (maxCt[level]) is encountered + // earlier than some less value while going through the array. For + // example, let pkg0 has 4 cores and pkg1 has 2 cores. Then + // maxCt[1] == 2 + // whereas it must be 4. + // TODO!!! Check if it can be commented safely + // maxCt[j] = 1; + last[j] = retval[proc].first.labels[j]; + } + totals[level]++; + counts[level]++; + if (counts[level] > maxCt[level]) { + maxCt[level] = counts[level]; + } + last[level] = retval[proc].first.labels[level]; + break; + } else if (level == depth - 1) { + __kmp_free(last); + __kmp_free(maxCt); + __kmp_free(counts); + __kmp_free(totals); + __kmp_free(retval); + KMP_CPU_FREE(oldMask); + *msg_id = kmp_i18n_str_x2ApicIDsNotUnique; + return -1; + } + } + } + + // When affinity is off, this routine will still be called to set + // __kmp_ncores, as well as __kmp_nThreadsPerCore, nCoresPerPkg, & nPackages. + // Make sure all these vars are set correctly, and return if affinity is not + // enabled. + if (threadLevel >= 0) { + __kmp_nThreadsPerCore = maxCt[threadLevel]; + } else { + __kmp_nThreadsPerCore = 1; + } + nPackages = totals[pkgLevel]; + + if (coreLevel >= 0) { + __kmp_ncores = totals[coreLevel]; + nCoresPerPkg = maxCt[coreLevel]; + } else { + __kmp_ncores = nPackages; + nCoresPerPkg = 1; + } + + // Check to see if the machine topology is uniform + unsigned prod = maxCt[0]; + for (level = 1; level < depth; level++) { + prod *= maxCt[level]; + } + bool uniform = (prod == totals[level - 1]); + + // Print the machine topology summary. + if (__kmp_affinity_verbose) { + char mask[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(mask, KMP_AFFIN_MASK_PRINT_LEN, oldMask); + + KMP_INFORM(AffUseGlobCpuidL11, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", mask); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", mask); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (uniform) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + + __kmp_str_buf_print(&buf, "%d", totals[0]); + for (level = 1; level <= pkgLevel; level++) { + __kmp_str_buf_print(&buf, " x %d", maxCt[level]); + } + KMP_INFORM(TopologyExtra, "KMP_AFFINITY", buf.str, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + + __kmp_str_buf_free(&buf); + } + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + KMP_DEBUG_ASSERT(nApics == __kmp_avail_proc); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + for (proc = 0; (int)proc < nApics; ++proc) { + __kmp_pu_os_idx[proc] = retval[proc].second; + } + if (__kmp_affinity_type == affinity_none) { + __kmp_free(last); + __kmp_free(maxCt); + __kmp_free(counts); + __kmp_free(totals); + __kmp_free(retval); + KMP_CPU_FREE(oldMask); + return 0; + } + + // Find any levels with radiix 1, and remove them from the map + // (except for the package level). + int new_depth = 0; + for (level = 0; level < depth; level++) { + if ((maxCt[level] == 1) && (level != pkgLevel)) { + continue; + } + new_depth++; + } + + // If we are removing any levels, allocate a new vector to return, + // and copy the relevant information to it. + if (new_depth != depth) { + AddrUnsPair *new_retval = + (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * nApics); + for (proc = 0; (int)proc < nApics; proc++) { + Address addr(new_depth); + new_retval[proc] = AddrUnsPair(addr, retval[proc].second); + } + int new_level = 0; + int newPkgLevel = -1; + int newCoreLevel = -1; + int newThreadLevel = -1; + for (level = 0; level < depth; level++) { + if ((maxCt[level] == 1) && (level != pkgLevel)) { + // Remove this level. Never remove the package level + continue; + } + if (level == pkgLevel) { + newPkgLevel = new_level; + } + if (level == coreLevel) { + newCoreLevel = new_level; + } + if (level == threadLevel) { + newThreadLevel = new_level; + } + for (proc = 0; (int)proc < nApics; proc++) { + new_retval[proc].first.labels[new_level] = + retval[proc].first.labels[level]; + } + new_level++; + } + + __kmp_free(retval); + retval = new_retval; + depth = new_depth; + pkgLevel = newPkgLevel; + coreLevel = newCoreLevel; + threadLevel = newThreadLevel; + } + + if (__kmp_affinity_gran_levels < 0) { + // Set the granularity level based on what levels are modeled + // in the machine topology map. + __kmp_affinity_gran_levels = 0; + if ((threadLevel >= 0) && (__kmp_affinity_gran > affinity_gran_thread)) { + __kmp_affinity_gran_levels++; + } + if ((coreLevel >= 0) && (__kmp_affinity_gran > affinity_gran_core)) { + __kmp_affinity_gran_levels++; + } + if (__kmp_affinity_gran > affinity_gran_package) { + __kmp_affinity_gran_levels++; + } + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(retval, nApics, depth, pkgLevel, coreLevel, + threadLevel); + } + + __kmp_free(last); + __kmp_free(maxCt); + __kmp_free(counts); + __kmp_free(totals); + KMP_CPU_FREE(oldMask); + *address2os = retval; + return depth; +} + +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +#define osIdIndex 0 +#define threadIdIndex 1 +#define coreIdIndex 2 +#define pkgIdIndex 3 +#define nodeIdIndex 4 + +typedef unsigned *ProcCpuInfo; +static unsigned maxIndex = pkgIdIndex; + +static int __kmp_affinity_cmp_ProcCpuInfo_phys_id(const void *a, + const void *b) { + unsigned i; + const unsigned *aa = *(unsigned *const *)a; + const unsigned *bb = *(unsigned *const *)b; + for (i = maxIndex;; i--) { + if (aa[i] < bb[i]) + return -1; + if (aa[i] > bb[i]) + return 1; + if (i == osIdIndex) + break; + } + return 0; +} + +#if KMP_USE_HIER_SCHED +// Set the array sizes for the hierarchy layers +static void __kmp_dispatch_set_hierarchy_values() { + // Set the maximum number of L1's to number of cores + // Set the maximum number of L2's to to either number of cores / 2 for + // Intel(R) Xeon Phi(TM) coprocessor formally codenamed Knights Landing + // Or the number of cores for Intel(R) Xeon(R) processors + // Set the maximum number of NUMA nodes and L3's to number of packages + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_THREAD + 1] = + nPackages * nCoresPerPkg * __kmp_nThreadsPerCore; + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_L1 + 1] = __kmp_ncores; +#if KMP_ARCH_X86_64 && (KMP_OS_LINUX || KMP_OS_WINDOWS) + if (__kmp_mic_type >= mic3) + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_L2 + 1] = __kmp_ncores / 2; + else +#endif // KMP_ARCH_X86_64 && (KMP_OS_LINUX || KMP_OS_WINDOWS) + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_L2 + 1] = __kmp_ncores; + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_L3 + 1] = nPackages; + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_NUMA + 1] = nPackages; + __kmp_hier_max_units[kmp_hier_layer_e::LAYER_LOOP + 1] = 1; + // Set the number of threads per unit + // Number of hardware threads per L1/L2/L3/NUMA/LOOP + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_THREAD + 1] = 1; + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_L1 + 1] = + __kmp_nThreadsPerCore; +#if KMP_ARCH_X86_64 && (KMP_OS_LINUX || KMP_OS_WINDOWS) + if (__kmp_mic_type >= mic3) + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_L2 + 1] = + 2 * __kmp_nThreadsPerCore; + else +#endif // KMP_ARCH_X86_64 && (KMP_OS_LINUX || KMP_OS_WINDOWS) + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_L2 + 1] = + __kmp_nThreadsPerCore; + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_L3 + 1] = + nCoresPerPkg * __kmp_nThreadsPerCore; + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_NUMA + 1] = + nCoresPerPkg * __kmp_nThreadsPerCore; + __kmp_hier_threads_per[kmp_hier_layer_e::LAYER_LOOP + 1] = + nPackages * nCoresPerPkg * __kmp_nThreadsPerCore; +} + +// Return the index into the hierarchy for this tid and layer type (L1, L2, etc) +// i.e., this thread's L1 or this thread's L2, etc. +int __kmp_dispatch_get_index(int tid, kmp_hier_layer_e type) { + int index = type + 1; + int num_hw_threads = __kmp_hier_max_units[kmp_hier_layer_e::LAYER_THREAD + 1]; + KMP_DEBUG_ASSERT(type != kmp_hier_layer_e::LAYER_LAST); + if (type == kmp_hier_layer_e::LAYER_THREAD) + return tid; + else if (type == kmp_hier_layer_e::LAYER_LOOP) + return 0; + KMP_DEBUG_ASSERT(__kmp_hier_max_units[index] != 0); + if (tid >= num_hw_threads) + tid = tid % num_hw_threads; + return (tid / __kmp_hier_threads_per[index]) % __kmp_hier_max_units[index]; +} + +// Return the number of t1's per t2 +int __kmp_dispatch_get_t1_per_t2(kmp_hier_layer_e t1, kmp_hier_layer_e t2) { + int i1 = t1 + 1; + int i2 = t2 + 1; + KMP_DEBUG_ASSERT(i1 <= i2); + KMP_DEBUG_ASSERT(t1 != kmp_hier_layer_e::LAYER_LAST); + KMP_DEBUG_ASSERT(t2 != kmp_hier_layer_e::LAYER_LAST); + KMP_DEBUG_ASSERT(__kmp_hier_threads_per[i1] != 0); + // (nthreads/t2) / (nthreads/t1) = t1 / t2 + return __kmp_hier_threads_per[i2] / __kmp_hier_threads_per[i1]; +} +#endif // KMP_USE_HIER_SCHED + +// Parse /proc/cpuinfo (or an alternate file in the same format) to obtain the +// affinity map. +static int __kmp_affinity_create_cpuinfo_map(AddrUnsPair **address2os, + int *line, + kmp_i18n_id_t *const msg_id, + FILE *f) { + *address2os = NULL; + *msg_id = kmp_i18n_null; + + // Scan of the file, and count the number of "processor" (osId) fields, + // and find the highest value of <n> for a node_<n> field. + char buf[256]; + unsigned num_records = 0; + while (!feof(f)) { + buf[sizeof(buf) - 1] = 1; + if (!fgets(buf, sizeof(buf), f)) { + // Read errors presumably because of EOF + break; + } + + char s1[] = "processor"; + if (strncmp(buf, s1, sizeof(s1) - 1) == 0) { + num_records++; + continue; + } + + // FIXME - this will match "node_<n> <garbage>" + unsigned level; + if (KMP_SSCANF(buf, "node_%u id", &level) == 1) { + if (nodeIdIndex + level >= maxIndex) { + maxIndex = nodeIdIndex + level; + } + continue; + } + } + + // Check for empty file / no valid processor records, or too many. The number + // of records can't exceed the number of valid bits in the affinity mask. + if (num_records == 0) { + *line = 0; + *msg_id = kmp_i18n_str_NoProcRecords; + return -1; + } + if (num_records > (unsigned)__kmp_xproc) { + *line = 0; + *msg_id = kmp_i18n_str_TooManyProcRecords; + return -1; + } + + // Set the file pointer back to the begginning, so that we can scan the file + // again, this time performing a full parse of the data. Allocate a vector of + // ProcCpuInfo object, where we will place the data. Adding an extra element + // at the end allows us to remove a lot of extra checks for termination + // conditions. + if (fseek(f, 0, SEEK_SET) != 0) { + *line = 0; + *msg_id = kmp_i18n_str_CantRewindCpuinfo; + return -1; + } + + // Allocate the array of records to store the proc info in. The dummy + // element at the end makes the logic in filling them out easier to code. + unsigned **threadInfo = + (unsigned **)__kmp_allocate((num_records + 1) * sizeof(unsigned *)); + unsigned i; + for (i = 0; i <= num_records; i++) { + threadInfo[i] = + (unsigned *)__kmp_allocate((maxIndex + 1) * sizeof(unsigned)); + } + +#define CLEANUP_THREAD_INFO \ + for (i = 0; i <= num_records; i++) { \ + __kmp_free(threadInfo[i]); \ + } \ + __kmp_free(threadInfo); + + // A value of UINT_MAX means that we didn't find the field + unsigned __index; + +#define INIT_PROC_INFO(p) \ + for (__index = 0; __index <= maxIndex; __index++) { \ + (p)[__index] = UINT_MAX; \ + } + + for (i = 0; i <= num_records; i++) { + INIT_PROC_INFO(threadInfo[i]); + } + + unsigned num_avail = 0; + *line = 0; + while (!feof(f)) { + // Create an inner scoping level, so that all the goto targets at the end of + // the loop appear in an outer scoping level. This avoids warnings about + // jumping past an initialization to a target in the same block. + { + buf[sizeof(buf) - 1] = 1; + bool long_line = false; + if (!fgets(buf, sizeof(buf), f)) { + // Read errors presumably because of EOF + // If there is valid data in threadInfo[num_avail], then fake + // a blank line in ensure that the last address gets parsed. + bool valid = false; + for (i = 0; i <= maxIndex; i++) { + if (threadInfo[num_avail][i] != UINT_MAX) { + valid = true; + } + } + if (!valid) { + break; + } + buf[0] = 0; + } else if (!buf[sizeof(buf) - 1]) { + // The line is longer than the buffer. Set a flag and don't + // emit an error if we were going to ignore the line, anyway. + long_line = true; + +#define CHECK_LINE \ + if (long_line) { \ + CLEANUP_THREAD_INFO; \ + *msg_id = kmp_i18n_str_LongLineCpuinfo; \ + return -1; \ + } + } + (*line)++; + + char s1[] = "processor"; + if (strncmp(buf, s1, sizeof(s1) - 1) == 0) { + CHECK_LINE; + char *p = strchr(buf + sizeof(s1) - 1, ':'); + unsigned val; + if ((p == NULL) || (KMP_SSCANF(p + 1, "%u\n", &val) != 1)) + goto no_val; + if (threadInfo[num_avail][osIdIndex] != UINT_MAX) +#if KMP_ARCH_AARCH64 + // Handle the old AArch64 /proc/cpuinfo layout differently, + // it contains all of the 'processor' entries listed in a + // single 'Processor' section, therefore the normal looking + // for duplicates in that section will always fail. + num_avail++; +#else + goto dup_field; +#endif + threadInfo[num_avail][osIdIndex] = val; +#if KMP_OS_LINUX && !(KMP_ARCH_X86 || KMP_ARCH_X86_64) + char path[256]; + KMP_SNPRINTF( + path, sizeof(path), + "/sys/devices/system/cpu/cpu%u/topology/physical_package_id", + threadInfo[num_avail][osIdIndex]); + __kmp_read_from_file(path, "%u", &threadInfo[num_avail][pkgIdIndex]); + + KMP_SNPRINTF(path, sizeof(path), + "/sys/devices/system/cpu/cpu%u/topology/core_id", + threadInfo[num_avail][osIdIndex]); + __kmp_read_from_file(path, "%u", &threadInfo[num_avail][coreIdIndex]); + continue; +#else + } + char s2[] = "physical id"; + if (strncmp(buf, s2, sizeof(s2) - 1) == 0) { + CHECK_LINE; + char *p = strchr(buf + sizeof(s2) - 1, ':'); + unsigned val; + if ((p == NULL) || (KMP_SSCANF(p + 1, "%u\n", &val) != 1)) + goto no_val; + if (threadInfo[num_avail][pkgIdIndex] != UINT_MAX) + goto dup_field; + threadInfo[num_avail][pkgIdIndex] = val; + continue; + } + char s3[] = "core id"; + if (strncmp(buf, s3, sizeof(s3) - 1) == 0) { + CHECK_LINE; + char *p = strchr(buf + sizeof(s3) - 1, ':'); + unsigned val; + if ((p == NULL) || (KMP_SSCANF(p + 1, "%u\n", &val) != 1)) + goto no_val; + if (threadInfo[num_avail][coreIdIndex] != UINT_MAX) + goto dup_field; + threadInfo[num_avail][coreIdIndex] = val; + continue; +#endif // KMP_OS_LINUX && USE_SYSFS_INFO + } + char s4[] = "thread id"; + if (strncmp(buf, s4, sizeof(s4) - 1) == 0) { + CHECK_LINE; + char *p = strchr(buf + sizeof(s4) - 1, ':'); + unsigned val; + if ((p == NULL) || (KMP_SSCANF(p + 1, "%u\n", &val) != 1)) + goto no_val; + if (threadInfo[num_avail][threadIdIndex] != UINT_MAX) + goto dup_field; + threadInfo[num_avail][threadIdIndex] = val; + continue; + } + unsigned level; + if (KMP_SSCANF(buf, "node_%u id", &level) == 1) { + CHECK_LINE; + char *p = strchr(buf + sizeof(s4) - 1, ':'); + unsigned val; + if ((p == NULL) || (KMP_SSCANF(p + 1, "%u\n", &val) != 1)) + goto no_val; + KMP_ASSERT(nodeIdIndex + level <= maxIndex); + if (threadInfo[num_avail][nodeIdIndex + level] != UINT_MAX) + goto dup_field; + threadInfo[num_avail][nodeIdIndex + level] = val; + continue; + } + + // We didn't recognize the leading token on the line. There are lots of + // leading tokens that we don't recognize - if the line isn't empty, go on + // to the next line. + if ((*buf != 0) && (*buf != '\n')) { + // If the line is longer than the buffer, read characters + // until we find a newline. + if (long_line) { + int ch; + while (((ch = fgetc(f)) != EOF) && (ch != '\n')) + ; + } + continue; + } + + // A newline has signalled the end of the processor record. + // Check that there aren't too many procs specified. + if ((int)num_avail == __kmp_xproc) { + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_TooManyEntries; + return -1; + } + + // Check for missing fields. The osId field must be there, and we + // currently require that the physical id field is specified, also. + if (threadInfo[num_avail][osIdIndex] == UINT_MAX) { + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_MissingProcField; + return -1; + } + if (threadInfo[0][pkgIdIndex] == UINT_MAX) { + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_MissingPhysicalIDField; + return -1; + } + + // Skip this proc if it is not included in the machine model. + if (!KMP_CPU_ISSET(threadInfo[num_avail][osIdIndex], + __kmp_affin_fullMask)) { + INIT_PROC_INFO(threadInfo[num_avail]); + continue; + } + + // We have a successful parse of this proc's info. + // Increment the counter, and prepare for the next proc. + num_avail++; + KMP_ASSERT(num_avail <= num_records); + INIT_PROC_INFO(threadInfo[num_avail]); + } + continue; + + no_val: + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_MissingValCpuinfo; + return -1; + + dup_field: + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_DuplicateFieldCpuinfo; + return -1; + } + *line = 0; + +#if KMP_MIC && REDUCE_TEAM_SIZE + unsigned teamSize = 0; +#endif // KMP_MIC && REDUCE_TEAM_SIZE + + // check for num_records == __kmp_xproc ??? + + // If there's only one thread context to bind to, form an Address object with + // depth 1 and return immediately (or, if affinity is off, set address2os to + // NULL and return). + // + // If it is configured to omit the package level when there is only a single + // package, the logic at the end of this routine won't work if there is only a + // single thread - it would try to form an Address object with depth 0. + KMP_ASSERT(num_avail > 0); + KMP_ASSERT(num_avail <= num_records); + if (num_avail == 1) { + __kmp_ncores = 1; + __kmp_nThreadsPerCore = nCoresPerPkg = nPackages = 1; + if (__kmp_affinity_verbose) { + if (!KMP_AFFINITY_CAPABLE()) { + KMP_INFORM(AffNotCapableUseCpuinfo, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + __kmp_affin_fullMask); + KMP_INFORM(AffCapableUseCpuinfo, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } + int index; + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + __kmp_str_buf_print(&buf, "1"); + for (index = maxIndex - 1; index > pkgIdIndex; index--) { + __kmp_str_buf_print(&buf, " x 1"); + } + KMP_INFORM(TopologyExtra, "KMP_AFFINITY", buf.str, 1, 1, 1); + __kmp_str_buf_free(&buf); + } + + if (__kmp_affinity_type == affinity_none) { + CLEANUP_THREAD_INFO; + return 0; + } + + *address2os = (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair)); + Address addr(1); + addr.labels[0] = threadInfo[0][pkgIdIndex]; + (*address2os)[0] = AddrUnsPair(addr, threadInfo[0][osIdIndex]); + + if (__kmp_affinity_gran_levels < 0) { + __kmp_affinity_gran_levels = 0; + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(*address2os, 1, 1, 0, -1, -1); + } + + CLEANUP_THREAD_INFO; + return 1; + } + + // Sort the threadInfo table by physical Id. + qsort(threadInfo, num_avail, sizeof(*threadInfo), + __kmp_affinity_cmp_ProcCpuInfo_phys_id); + + // The table is now sorted by pkgId / coreId / threadId, but we really don't + // know the radix of any of the fields. pkgId's may be sparsely assigned among + // the chips on a system. Although coreId's are usually assigned + // [0 .. coresPerPkg-1] and threadId's are usually assigned + // [0..threadsPerCore-1], we don't want to make any such assumptions. + // + // For that matter, we don't know what coresPerPkg and threadsPerCore (or the + // total # packages) are at this point - we want to determine that now. We + // only have an upper bound on the first two figures. + unsigned *counts = + (unsigned *)__kmp_allocate((maxIndex + 1) * sizeof(unsigned)); + unsigned *maxCt = + (unsigned *)__kmp_allocate((maxIndex + 1) * sizeof(unsigned)); + unsigned *totals = + (unsigned *)__kmp_allocate((maxIndex + 1) * sizeof(unsigned)); + unsigned *lastId = + (unsigned *)__kmp_allocate((maxIndex + 1) * sizeof(unsigned)); + + bool assign_thread_ids = false; + unsigned threadIdCt; + unsigned index; + +restart_radix_check: + threadIdCt = 0; + + // Initialize the counter arrays with data from threadInfo[0]. + if (assign_thread_ids) { + if (threadInfo[0][threadIdIndex] == UINT_MAX) { + threadInfo[0][threadIdIndex] = threadIdCt++; + } else if (threadIdCt <= threadInfo[0][threadIdIndex]) { + threadIdCt = threadInfo[0][threadIdIndex] + 1; + } + } + for (index = 0; index <= maxIndex; index++) { + counts[index] = 1; + maxCt[index] = 1; + totals[index] = 1; + lastId[index] = threadInfo[0][index]; + ; + } + + // Run through the rest of the OS procs. + for (i = 1; i < num_avail; i++) { + // Find the most significant index whose id differs from the id for the + // previous OS proc. + for (index = maxIndex; index >= threadIdIndex; index--) { + if (assign_thread_ids && (index == threadIdIndex)) { + // Auto-assign the thread id field if it wasn't specified. + if (threadInfo[i][threadIdIndex] == UINT_MAX) { + threadInfo[i][threadIdIndex] = threadIdCt++; + } + // Apparently the thread id field was specified for some entries and not + // others. Start the thread id counter off at the next higher thread id. + else if (threadIdCt <= threadInfo[i][threadIdIndex]) { + threadIdCt = threadInfo[i][threadIdIndex] + 1; + } + } + if (threadInfo[i][index] != lastId[index]) { + // Run through all indices which are less significant, and reset the + // counts to 1. At all levels up to and including index, we need to + // increment the totals and record the last id. + unsigned index2; + for (index2 = threadIdIndex; index2 < index; index2++) { + totals[index2]++; + if (counts[index2] > maxCt[index2]) { + maxCt[index2] = counts[index2]; + } + counts[index2] = 1; + lastId[index2] = threadInfo[i][index2]; + } + counts[index]++; + totals[index]++; + lastId[index] = threadInfo[i][index]; + + if (assign_thread_ids && (index > threadIdIndex)) { + +#if KMP_MIC && REDUCE_TEAM_SIZE + // The default team size is the total #threads in the machine + // minus 1 thread for every core that has 3 or more threads. + teamSize += (threadIdCt <= 2) ? (threadIdCt) : (threadIdCt - 1); +#endif // KMP_MIC && REDUCE_TEAM_SIZE + + // Restart the thread counter, as we are on a new core. + threadIdCt = 0; + + // Auto-assign the thread id field if it wasn't specified. + if (threadInfo[i][threadIdIndex] == UINT_MAX) { + threadInfo[i][threadIdIndex] = threadIdCt++; + } + + // Aparrently the thread id field was specified for some entries and + // not others. Start the thread id counter off at the next higher + // thread id. + else if (threadIdCt <= threadInfo[i][threadIdIndex]) { + threadIdCt = threadInfo[i][threadIdIndex] + 1; + } + } + break; + } + } + if (index < threadIdIndex) { + // If thread ids were specified, it is an error if they are not unique. + // Also, check that we waven't already restarted the loop (to be safe - + // shouldn't need to). + if ((threadInfo[i][threadIdIndex] != UINT_MAX) || assign_thread_ids) { + __kmp_free(lastId); + __kmp_free(totals); + __kmp_free(maxCt); + __kmp_free(counts); + CLEANUP_THREAD_INFO; + *msg_id = kmp_i18n_str_PhysicalIDsNotUnique; + return -1; + } + + // If the thread ids were not specified and we see entries entries that + // are duplicates, start the loop over and assign the thread ids manually. + assign_thread_ids = true; + goto restart_radix_check; + } + } + +#if KMP_MIC && REDUCE_TEAM_SIZE + // The default team size is the total #threads in the machine + // minus 1 thread for every core that has 3 or more threads. + teamSize += (threadIdCt <= 2) ? (threadIdCt) : (threadIdCt - 1); +#endif // KMP_MIC && REDUCE_TEAM_SIZE + + for (index = threadIdIndex; index <= maxIndex; index++) { + if (counts[index] > maxCt[index]) { + maxCt[index] = counts[index]; + } + } + + __kmp_nThreadsPerCore = maxCt[threadIdIndex]; + nCoresPerPkg = maxCt[coreIdIndex]; + nPackages = totals[pkgIdIndex]; + + // Check to see if the machine topology is uniform + unsigned prod = totals[maxIndex]; + for (index = threadIdIndex; index < maxIndex; index++) { + prod *= maxCt[index]; + } + bool uniform = (prod == totals[threadIdIndex]); + + // When affinity is off, this routine will still be called to set + // __kmp_ncores, as well as __kmp_nThreadsPerCore, nCoresPerPkg, & nPackages. + // Make sure all these vars are set correctly, and return now if affinity is + // not enabled. + __kmp_ncores = totals[coreIdIndex]; + + if (__kmp_affinity_verbose) { + if (!KMP_AFFINITY_CAPABLE()) { + KMP_INFORM(AffNotCapableUseCpuinfo, "KMP_AFFINITY"); + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (uniform) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + } else { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + __kmp_affin_fullMask); + KMP_INFORM(AffCapableUseCpuinfo, "KMP_AFFINITY"); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_AFFINITY", buf); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_AFFINITY", buf); + } + KMP_INFORM(AvailableOSProc, "KMP_AFFINITY", __kmp_avail_proc); + if (uniform) { + KMP_INFORM(Uniform, "KMP_AFFINITY"); + } else { + KMP_INFORM(NonUniform, "KMP_AFFINITY"); + } + } + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + + __kmp_str_buf_print(&buf, "%d", totals[maxIndex]); + for (index = maxIndex - 1; index >= pkgIdIndex; index--) { + __kmp_str_buf_print(&buf, " x %d", maxCt[index]); + } + KMP_INFORM(TopologyExtra, "KMP_AFFINITY", buf.str, maxCt[coreIdIndex], + maxCt[threadIdIndex], __kmp_ncores); + + __kmp_str_buf_free(&buf); + } + +#if KMP_MIC && REDUCE_TEAM_SIZE + // Set the default team size. + if ((__kmp_dflt_team_nth == 0) && (teamSize > 0)) { + __kmp_dflt_team_nth = teamSize; + KA_TRACE(20, ("__kmp_affinity_create_cpuinfo_map: setting " + "__kmp_dflt_team_nth = %d\n", + __kmp_dflt_team_nth)); + } +#endif // KMP_MIC && REDUCE_TEAM_SIZE + + KMP_DEBUG_ASSERT(__kmp_pu_os_idx == NULL); + KMP_DEBUG_ASSERT(num_avail == (unsigned)__kmp_avail_proc); + __kmp_pu_os_idx = (int *)__kmp_allocate(sizeof(int) * __kmp_avail_proc); + for (i = 0; i < num_avail; ++i) { // fill the os indices + __kmp_pu_os_idx[i] = threadInfo[i][osIdIndex]; + } + + if (__kmp_affinity_type == affinity_none) { + __kmp_free(lastId); + __kmp_free(totals); + __kmp_free(maxCt); + __kmp_free(counts); + CLEANUP_THREAD_INFO; + return 0; + } + + // Count the number of levels which have more nodes at that level than at the + // parent's level (with there being an implicit root node of the top level). + // This is equivalent to saying that there is at least one node at this level + // which has a sibling. These levels are in the map, and the package level is + // always in the map. + bool *inMap = (bool *)__kmp_allocate((maxIndex + 1) * sizeof(bool)); + for (index = threadIdIndex; index < maxIndex; index++) { + KMP_ASSERT(totals[index] >= totals[index + 1]); + inMap[index] = (totals[index] > totals[index + 1]); + } + inMap[maxIndex] = (totals[maxIndex] > 1); + inMap[pkgIdIndex] = true; + + int depth = 0; + for (index = threadIdIndex; index <= maxIndex; index++) { + if (inMap[index]) { + depth++; + } + } + KMP_ASSERT(depth > 0); + + // Construct the data structure that is to be returned. + *address2os = (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * num_avail); + int pkgLevel = -1; + int coreLevel = -1; + int threadLevel = -1; + + for (i = 0; i < num_avail; ++i) { + Address addr(depth); + unsigned os = threadInfo[i][osIdIndex]; + int src_index; + int dst_index = 0; + + for (src_index = maxIndex; src_index >= threadIdIndex; src_index--) { + if (!inMap[src_index]) { + continue; + } + addr.labels[dst_index] = threadInfo[i][src_index]; + if (src_index == pkgIdIndex) { + pkgLevel = dst_index; + } else if (src_index == coreIdIndex) { + coreLevel = dst_index; + } else if (src_index == threadIdIndex) { + threadLevel = dst_index; + } + dst_index++; + } + (*address2os)[i] = AddrUnsPair(addr, os); + } + + if (__kmp_affinity_gran_levels < 0) { + // Set the granularity level based on what levels are modeled + // in the machine topology map. + unsigned src_index; + __kmp_affinity_gran_levels = 0; + for (src_index = threadIdIndex; src_index <= maxIndex; src_index++) { + if (!inMap[src_index]) { + continue; + } + switch (src_index) { + case threadIdIndex: + if (__kmp_affinity_gran > affinity_gran_thread) { + __kmp_affinity_gran_levels++; + } + + break; + case coreIdIndex: + if (__kmp_affinity_gran > affinity_gran_core) { + __kmp_affinity_gran_levels++; + } + break; + + case pkgIdIndex: + if (__kmp_affinity_gran > affinity_gran_package) { + __kmp_affinity_gran_levels++; + } + break; + } + } + } + + if (__kmp_affinity_verbose) { + __kmp_affinity_print_topology(*address2os, num_avail, depth, pkgLevel, + coreLevel, threadLevel); + } + + __kmp_free(inMap); + __kmp_free(lastId); + __kmp_free(totals); + __kmp_free(maxCt); + __kmp_free(counts); + CLEANUP_THREAD_INFO; + return depth; +} + +// Create and return a table of affinity masks, indexed by OS thread ID. +// This routine handles OR'ing together all the affinity masks of threads +// that are sufficiently close, if granularity > fine. +static kmp_affin_mask_t *__kmp_create_masks(unsigned *maxIndex, + unsigned *numUnique, + AddrUnsPair *address2os, + unsigned numAddrs) { + // First form a table of affinity masks in order of OS thread id. + unsigned depth; + unsigned maxOsId; + unsigned i; + + KMP_ASSERT(numAddrs > 0); + depth = address2os[0].first.depth; + + maxOsId = 0; + for (i = numAddrs - 1;; --i) { + unsigned osId = address2os[i].second; + if (osId > maxOsId) { + maxOsId = osId; + } + if (i == 0) + break; + } + kmp_affin_mask_t *osId2Mask; + KMP_CPU_ALLOC_ARRAY(osId2Mask, (maxOsId + 1)); + + // Sort the address2os table according to physical order. Doing so will put + // all threads on the same core/package/node in consecutive locations. + qsort(address2os, numAddrs, sizeof(*address2os), + __kmp_affinity_cmp_Address_labels); + + KMP_ASSERT(__kmp_affinity_gran_levels >= 0); + if (__kmp_affinity_verbose && (__kmp_affinity_gran_levels > 0)) { + KMP_INFORM(ThreadsMigrate, "KMP_AFFINITY", __kmp_affinity_gran_levels); + } + if (__kmp_affinity_gran_levels >= (int)depth) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffThreadsMayMigrate); + } + } + + // Run through the table, forming the masks for all threads on each core. + // Threads on the same core will have identical "Address" objects, not + // considering the last level, which must be the thread id. All threads on a + // core will appear consecutively. + unsigned unique = 0; + unsigned j = 0; // index of 1st thread on core + unsigned leader = 0; + Address *leaderAddr = &(address2os[0].first); + kmp_affin_mask_t *sum; + KMP_CPU_ALLOC_ON_STACK(sum); + KMP_CPU_ZERO(sum); + KMP_CPU_SET(address2os[0].second, sum); + for (i = 1; i < numAddrs; i++) { + // If this thread is sufficiently close to the leader (within the + // granularity setting), then set the bit for this os thread in the + // affinity mask for this group, and go on to the next thread. + if (leaderAddr->isClose(address2os[i].first, __kmp_affinity_gran_levels)) { + KMP_CPU_SET(address2os[i].second, sum); + continue; + } + + // For every thread in this group, copy the mask to the thread's entry in + // the osId2Mask table. Mark the first address as a leader. + for (; j < i; j++) { + unsigned osId = address2os[j].second; + KMP_DEBUG_ASSERT(osId <= maxOsId); + kmp_affin_mask_t *mask = KMP_CPU_INDEX(osId2Mask, osId); + KMP_CPU_COPY(mask, sum); + address2os[j].first.leader = (j == leader); + } + unique++; + + // Start a new mask. + leader = i; + leaderAddr = &(address2os[i].first); + KMP_CPU_ZERO(sum); + KMP_CPU_SET(address2os[i].second, sum); + } + + // For every thread in last group, copy the mask to the thread's + // entry in the osId2Mask table. + for (; j < i; j++) { + unsigned osId = address2os[j].second; + KMP_DEBUG_ASSERT(osId <= maxOsId); + kmp_affin_mask_t *mask = KMP_CPU_INDEX(osId2Mask, osId); + KMP_CPU_COPY(mask, sum); + address2os[j].first.leader = (j == leader); + } + unique++; + KMP_CPU_FREE_FROM_STACK(sum); + + *maxIndex = maxOsId; + *numUnique = unique; + return osId2Mask; +} + +// Stuff for the affinity proclist parsers. It's easier to declare these vars +// as file-static than to try and pass them through the calling sequence of +// the recursive-descent OMP_PLACES parser. +static kmp_affin_mask_t *newMasks; +static int numNewMasks; +static int nextNewMask; + +#define ADD_MASK(_mask) \ + { \ + if (nextNewMask >= numNewMasks) { \ + int i; \ + numNewMasks *= 2; \ + kmp_affin_mask_t *temp; \ + KMP_CPU_INTERNAL_ALLOC_ARRAY(temp, numNewMasks); \ + for (i = 0; i < numNewMasks / 2; i++) { \ + kmp_affin_mask_t *src = KMP_CPU_INDEX(newMasks, i); \ + kmp_affin_mask_t *dest = KMP_CPU_INDEX(temp, i); \ + KMP_CPU_COPY(dest, src); \ + } \ + KMP_CPU_INTERNAL_FREE_ARRAY(newMasks, numNewMasks / 2); \ + newMasks = temp; \ + } \ + KMP_CPU_COPY(KMP_CPU_INDEX(newMasks, nextNewMask), (_mask)); \ + nextNewMask++; \ + } + +#define ADD_MASK_OSID(_osId, _osId2Mask, _maxOsId) \ + { \ + if (((_osId) > _maxOsId) || \ + (!KMP_CPU_ISSET((_osId), KMP_CPU_INDEX((_osId2Mask), (_osId))))) { \ + if (__kmp_affinity_verbose || \ + (__kmp_affinity_warnings && \ + (__kmp_affinity_type != affinity_none))) { \ + KMP_WARNING(AffIgnoreInvalidProcID, _osId); \ + } \ + } else { \ + ADD_MASK(KMP_CPU_INDEX(_osId2Mask, (_osId))); \ + } \ + } + +// Re-parse the proclist (for the explicit affinity type), and form the list +// of affinity newMasks indexed by gtid. +static void __kmp_affinity_process_proclist(kmp_affin_mask_t **out_masks, + unsigned int *out_numMasks, + const char *proclist, + kmp_affin_mask_t *osId2Mask, + int maxOsId) { + int i; + const char *scan = proclist; + const char *next = proclist; + + // We use malloc() for the temporary mask vector, so that we can use + // realloc() to extend it. + numNewMasks = 2; + KMP_CPU_INTERNAL_ALLOC_ARRAY(newMasks, numNewMasks); + nextNewMask = 0; + kmp_affin_mask_t *sumMask; + KMP_CPU_ALLOC(sumMask); + int setSize = 0; + + for (;;) { + int start, end, stride; + + SKIP_WS(scan); + next = scan; + if (*next == '\0') { + break; + } + + if (*next == '{') { + int num; + setSize = 0; + next++; // skip '{' + SKIP_WS(next); + scan = next; + + // Read the first integer in the set. + KMP_ASSERT2((*next >= '0') && (*next <= '9'), "bad proclist"); + SKIP_DIGITS(next); + num = __kmp_str_to_int(scan, *next); + KMP_ASSERT2(num >= 0, "bad explicit proc list"); + + // Copy the mask for that osId to the sum (union) mask. + if ((num > maxOsId) || + (!KMP_CPU_ISSET(num, KMP_CPU_INDEX(osId2Mask, num)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, num); + } + KMP_CPU_ZERO(sumMask); + } else { + KMP_CPU_COPY(sumMask, KMP_CPU_INDEX(osId2Mask, num)); + setSize = 1; + } + + for (;;) { + // Check for end of set. + SKIP_WS(next); + if (*next == '}') { + next++; // skip '}' + break; + } + + // Skip optional comma. + if (*next == ',') { + next++; + } + SKIP_WS(next); + + // Read the next integer in the set. + scan = next; + KMP_ASSERT2((*next >= '0') && (*next <= '9'), "bad explicit proc list"); + + SKIP_DIGITS(next); + num = __kmp_str_to_int(scan, *next); + KMP_ASSERT2(num >= 0, "bad explicit proc list"); + + // Add the mask for that osId to the sum mask. + if ((num > maxOsId) || + (!KMP_CPU_ISSET(num, KMP_CPU_INDEX(osId2Mask, num)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, num); + } + } else { + KMP_CPU_UNION(sumMask, KMP_CPU_INDEX(osId2Mask, num)); + setSize++; + } + } + if (setSize > 0) { + ADD_MASK(sumMask); + } + + SKIP_WS(next); + if (*next == ',') { + next++; + } + scan = next; + continue; + } + + // Read the first integer. + KMP_ASSERT2((*next >= '0') && (*next <= '9'), "bad explicit proc list"); + SKIP_DIGITS(next); + start = __kmp_str_to_int(scan, *next); + KMP_ASSERT2(start >= 0, "bad explicit proc list"); + SKIP_WS(next); + + // If this isn't a range, then add a mask to the list and go on. + if (*next != '-') { + ADD_MASK_OSID(start, osId2Mask, maxOsId); + + // Skip optional comma. + if (*next == ',') { + next++; + } + scan = next; + continue; + } + + // This is a range. Skip over the '-' and read in the 2nd int. + next++; // skip '-' + SKIP_WS(next); + scan = next; + KMP_ASSERT2((*next >= '0') && (*next <= '9'), "bad explicit proc list"); + SKIP_DIGITS(next); + end = __kmp_str_to_int(scan, *next); + KMP_ASSERT2(end >= 0, "bad explicit proc list"); + + // Check for a stride parameter + stride = 1; + SKIP_WS(next); + if (*next == ':') { + // A stride is specified. Skip over the ':" and read the 3rd int. + int sign = +1; + next++; // skip ':' + SKIP_WS(next); + scan = next; + if (*next == '-') { + sign = -1; + next++; + SKIP_WS(next); + scan = next; + } + KMP_ASSERT2((*next >= '0') && (*next <= '9'), "bad explicit proc list"); + SKIP_DIGITS(next); + stride = __kmp_str_to_int(scan, *next); + KMP_ASSERT2(stride >= 0, "bad explicit proc list"); + stride *= sign; + } + + // Do some range checks. + KMP_ASSERT2(stride != 0, "bad explicit proc list"); + if (stride > 0) { + KMP_ASSERT2(start <= end, "bad explicit proc list"); + } else { + KMP_ASSERT2(start >= end, "bad explicit proc list"); + } + KMP_ASSERT2((end - start) / stride <= 65536, "bad explicit proc list"); + + // Add the mask for each OS proc # to the list. + if (stride > 0) { + do { + ADD_MASK_OSID(start, osId2Mask, maxOsId); + start += stride; + } while (start <= end); + } else { + do { + ADD_MASK_OSID(start, osId2Mask, maxOsId); + start += stride; + } while (start >= end); + } + + // Skip optional comma. + SKIP_WS(next); + if (*next == ',') { + next++; + } + scan = next; + } + + *out_numMasks = nextNewMask; + if (nextNewMask == 0) { + *out_masks = NULL; + KMP_CPU_INTERNAL_FREE_ARRAY(newMasks, numNewMasks); + return; + } + KMP_CPU_ALLOC_ARRAY((*out_masks), nextNewMask); + for (i = 0; i < nextNewMask; i++) { + kmp_affin_mask_t *src = KMP_CPU_INDEX(newMasks, i); + kmp_affin_mask_t *dest = KMP_CPU_INDEX((*out_masks), i); + KMP_CPU_COPY(dest, src); + } + KMP_CPU_INTERNAL_FREE_ARRAY(newMasks, numNewMasks); + KMP_CPU_FREE(sumMask); +} + +#if OMP_40_ENABLED + +/*----------------------------------------------------------------------------- +Re-parse the OMP_PLACES proc id list, forming the newMasks for the different +places. Again, Here is the grammar: + +place_list := place +place_list := place , place_list +place := num +place := place : num +place := place : num : signed +place := { subplacelist } +place := ! place // (lowest priority) +subplace_list := subplace +subplace_list := subplace , subplace_list +subplace := num +subplace := num : num +subplace := num : num : signed +signed := num +signed := + signed +signed := - signed +-----------------------------------------------------------------------------*/ + +static void __kmp_process_subplace_list(const char **scan, + kmp_affin_mask_t *osId2Mask, + int maxOsId, kmp_affin_mask_t *tempMask, + int *setSize) { + const char *next; + + for (;;) { + int start, count, stride, i; + + // Read in the starting proc id + SKIP_WS(*scan); + KMP_ASSERT2((**scan >= '0') && (**scan <= '9'), "bad explicit places list"); + next = *scan; + SKIP_DIGITS(next); + start = __kmp_str_to_int(*scan, *next); + KMP_ASSERT(start >= 0); + *scan = next; + + // valid follow sets are ',' ':' and '}' + SKIP_WS(*scan); + if (**scan == '}' || **scan == ',') { + if ((start > maxOsId) || + (!KMP_CPU_ISSET(start, KMP_CPU_INDEX(osId2Mask, start)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, start); + } + } else { + KMP_CPU_UNION(tempMask, KMP_CPU_INDEX(osId2Mask, start)); + (*setSize)++; + } + if (**scan == '}') { + break; + } + (*scan)++; // skip ',' + continue; + } + KMP_ASSERT2(**scan == ':', "bad explicit places list"); + (*scan)++; // skip ':' + + // Read count parameter + SKIP_WS(*scan); + KMP_ASSERT2((**scan >= '0') && (**scan <= '9'), "bad explicit places list"); + next = *scan; + SKIP_DIGITS(next); + count = __kmp_str_to_int(*scan, *next); + KMP_ASSERT(count >= 0); + *scan = next; + + // valid follow sets are ',' ':' and '}' + SKIP_WS(*scan); + if (**scan == '}' || **scan == ',') { + for (i = 0; i < count; i++) { + if ((start > maxOsId) || + (!KMP_CPU_ISSET(start, KMP_CPU_INDEX(osId2Mask, start)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, start); + } + break; // don't proliferate warnings for large count + } else { + KMP_CPU_UNION(tempMask, KMP_CPU_INDEX(osId2Mask, start)); + start++; + (*setSize)++; + } + } + if (**scan == '}') { + break; + } + (*scan)++; // skip ',' + continue; + } + KMP_ASSERT2(**scan == ':', "bad explicit places list"); + (*scan)++; // skip ':' + + // Read stride parameter + int sign = +1; + for (;;) { + SKIP_WS(*scan); + if (**scan == '+') { + (*scan)++; // skip '+' + continue; + } + if (**scan == '-') { + sign *= -1; + (*scan)++; // skip '-' + continue; + } + break; + } + SKIP_WS(*scan); + KMP_ASSERT2((**scan >= '0') && (**scan <= '9'), "bad explicit places list"); + next = *scan; + SKIP_DIGITS(next); + stride = __kmp_str_to_int(*scan, *next); + KMP_ASSERT(stride >= 0); + *scan = next; + stride *= sign; + + // valid follow sets are ',' and '}' + SKIP_WS(*scan); + if (**scan == '}' || **scan == ',') { + for (i = 0; i < count; i++) { + if ((start > maxOsId) || + (!KMP_CPU_ISSET(start, KMP_CPU_INDEX(osId2Mask, start)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, start); + } + break; // don't proliferate warnings for large count + } else { + KMP_CPU_UNION(tempMask, KMP_CPU_INDEX(osId2Mask, start)); + start += stride; + (*setSize)++; + } + } + if (**scan == '}') { + break; + } + (*scan)++; // skip ',' + continue; + } + + KMP_ASSERT2(0, "bad explicit places list"); + } +} + +static void __kmp_process_place(const char **scan, kmp_affin_mask_t *osId2Mask, + int maxOsId, kmp_affin_mask_t *tempMask, + int *setSize) { + const char *next; + + // valid follow sets are '{' '!' and num + SKIP_WS(*scan); + if (**scan == '{') { + (*scan)++; // skip '{' + __kmp_process_subplace_list(scan, osId2Mask, maxOsId, tempMask, setSize); + KMP_ASSERT2(**scan == '}', "bad explicit places list"); + (*scan)++; // skip '}' + } else if (**scan == '!') { + (*scan)++; // skip '!' + __kmp_process_place(scan, osId2Mask, maxOsId, tempMask, setSize); + KMP_CPU_COMPLEMENT(maxOsId, tempMask); + } else if ((**scan >= '0') && (**scan <= '9')) { + next = *scan; + SKIP_DIGITS(next); + int num = __kmp_str_to_int(*scan, *next); + KMP_ASSERT(num >= 0); + if ((num > maxOsId) || + (!KMP_CPU_ISSET(num, KMP_CPU_INDEX(osId2Mask, num)))) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffIgnoreInvalidProcID, num); + } + } else { + KMP_CPU_UNION(tempMask, KMP_CPU_INDEX(osId2Mask, num)); + (*setSize)++; + } + *scan = next; // skip num + } else { + KMP_ASSERT2(0, "bad explicit places list"); + } +} + +// static void +void __kmp_affinity_process_placelist(kmp_affin_mask_t **out_masks, + unsigned int *out_numMasks, + const char *placelist, + kmp_affin_mask_t *osId2Mask, + int maxOsId) { + int i, j, count, stride, sign; + const char *scan = placelist; + const char *next = placelist; + + numNewMasks = 2; + KMP_CPU_INTERNAL_ALLOC_ARRAY(newMasks, numNewMasks); + nextNewMask = 0; + + // tempMask is modified based on the previous or initial + // place to form the current place + // previousMask contains the previous place + kmp_affin_mask_t *tempMask; + kmp_affin_mask_t *previousMask; + KMP_CPU_ALLOC(tempMask); + KMP_CPU_ZERO(tempMask); + KMP_CPU_ALLOC(previousMask); + KMP_CPU_ZERO(previousMask); + int setSize = 0; + + for (;;) { + __kmp_process_place(&scan, osId2Mask, maxOsId, tempMask, &setSize); + + // valid follow sets are ',' ':' and EOL + SKIP_WS(scan); + if (*scan == '\0' || *scan == ',') { + if (setSize > 0) { + ADD_MASK(tempMask); + } + KMP_CPU_ZERO(tempMask); + setSize = 0; + if (*scan == '\0') { + break; + } + scan++; // skip ',' + continue; + } + + KMP_ASSERT2(*scan == ':', "bad explicit places list"); + scan++; // skip ':' + + // Read count parameter + SKIP_WS(scan); + KMP_ASSERT2((*scan >= '0') && (*scan <= '9'), "bad explicit places list"); + next = scan; + SKIP_DIGITS(next); + count = __kmp_str_to_int(scan, *next); + KMP_ASSERT(count >= 0); + scan = next; + + // valid follow sets are ',' ':' and EOL + SKIP_WS(scan); + if (*scan == '\0' || *scan == ',') { + stride = +1; + } else { + KMP_ASSERT2(*scan == ':', "bad explicit places list"); + scan++; // skip ':' + + // Read stride parameter + sign = +1; + for (;;) { + SKIP_WS(scan); + if (*scan == '+') { + scan++; // skip '+' + continue; + } + if (*scan == '-') { + sign *= -1; + scan++; // skip '-' + continue; + } + break; + } + SKIP_WS(scan); + KMP_ASSERT2((*scan >= '0') && (*scan <= '9'), "bad explicit places list"); + next = scan; + SKIP_DIGITS(next); + stride = __kmp_str_to_int(scan, *next); + KMP_DEBUG_ASSERT(stride >= 0); + scan = next; + stride *= sign; + } + + // Add places determined by initial_place : count : stride + for (i = 0; i < count; i++) { + if (setSize == 0) { + break; + } + // Add the current place, then build the next place (tempMask) from that + KMP_CPU_COPY(previousMask, tempMask); + ADD_MASK(previousMask); + KMP_CPU_ZERO(tempMask); + setSize = 0; + KMP_CPU_SET_ITERATE(j, previousMask) { + if (!KMP_CPU_ISSET(j, previousMask)) { + continue; + } + if ((j + stride > maxOsId) || (j + stride < 0) || + (!KMP_CPU_ISSET(j, __kmp_affin_fullMask)) || + (!KMP_CPU_ISSET(j + stride, + KMP_CPU_INDEX(osId2Mask, j + stride)))) { + if ((__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) && + i < count - 1) { + KMP_WARNING(AffIgnoreInvalidProcID, j + stride); + } + continue; + } + KMP_CPU_SET(j + stride, tempMask); + setSize++; + } + } + KMP_CPU_ZERO(tempMask); + setSize = 0; + + // valid follow sets are ',' and EOL + SKIP_WS(scan); + if (*scan == '\0') { + break; + } + if (*scan == ',') { + scan++; // skip ',' + continue; + } + + KMP_ASSERT2(0, "bad explicit places list"); + } + + *out_numMasks = nextNewMask; + if (nextNewMask == 0) { + *out_masks = NULL; + KMP_CPU_INTERNAL_FREE_ARRAY(newMasks, numNewMasks); + return; + } + KMP_CPU_ALLOC_ARRAY((*out_masks), nextNewMask); + KMP_CPU_FREE(tempMask); + KMP_CPU_FREE(previousMask); + for (i = 0; i < nextNewMask; i++) { + kmp_affin_mask_t *src = KMP_CPU_INDEX(newMasks, i); + kmp_affin_mask_t *dest = KMP_CPU_INDEX((*out_masks), i); + KMP_CPU_COPY(dest, src); + } + KMP_CPU_INTERNAL_FREE_ARRAY(newMasks, numNewMasks); +} + +#endif /* OMP_40_ENABLED */ + +#undef ADD_MASK +#undef ADD_MASK_OSID + +#if KMP_USE_HWLOC +static int __kmp_hwloc_skip_PUs_obj(hwloc_topology_t t, hwloc_obj_t o) { + // skip PUs descendants of the object o + int skipped = 0; + hwloc_obj_t hT = NULL; + int N = __kmp_hwloc_count_children_by_type(t, o, HWLOC_OBJ_PU, &hT); + for (int i = 0; i < N; ++i) { + KMP_DEBUG_ASSERT(hT); + unsigned idx = hT->os_index; + if (KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) { + KMP_CPU_CLR(idx, __kmp_affin_fullMask); + KC_TRACE(200, ("KMP_HW_SUBSET: skipped proc %d\n", idx)); + ++skipped; + } + hT = hwloc_get_next_obj_by_type(t, HWLOC_OBJ_PU, hT); + } + return skipped; // count number of skipped units +} + +static int __kmp_hwloc_obj_has_PUs(hwloc_topology_t t, hwloc_obj_t o) { + // check if obj has PUs present in fullMask + hwloc_obj_t hT = NULL; + int N = __kmp_hwloc_count_children_by_type(t, o, HWLOC_OBJ_PU, &hT); + for (int i = 0; i < N; ++i) { + KMP_DEBUG_ASSERT(hT); + unsigned idx = hT->os_index; + if (KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) + return 1; // found PU + hT = hwloc_get_next_obj_by_type(t, HWLOC_OBJ_PU, hT); + } + return 0; // no PUs found +} +#endif // KMP_USE_HWLOC + +static void __kmp_apply_thread_places(AddrUnsPair **pAddr, int depth) { + AddrUnsPair *newAddr; + if (__kmp_hws_requested == 0) + goto _exit; // no topology limiting actions requested, exit +#if KMP_USE_HWLOC + if (__kmp_affinity_dispatch->get_api_type() == KMPAffinity::HWLOC) { + // Number of subobjects calculated dynamically, this works fine for + // any non-uniform topology. + // L2 cache objects are determined by depth, other objects - by type. + hwloc_topology_t tp = __kmp_hwloc_topology; + int nS = 0, nN = 0, nL = 0, nC = 0, + nT = 0; // logical index including skipped + int nCr = 0, nTr = 0; // number of requested units + int nPkg = 0, nCo = 0, n_new = 0, n_old = 0, nCpP = 0, nTpC = 0; // counters + hwloc_obj_t hT, hC, hL, hN, hS; // hwloc objects (pointers to) + int L2depth, idx; + + // check support of extensions ---------------------------------- + int numa_support = 0, tile_support = 0; + if (__kmp_pu_os_idx) + hT = hwloc_get_pu_obj_by_os_index(tp, + __kmp_pu_os_idx[__kmp_avail_proc - 1]); + else + hT = hwloc_get_obj_by_type(tp, HWLOC_OBJ_PU, __kmp_avail_proc - 1); + if (hT == NULL) { // something's gone wrong + KMP_WARNING(AffHWSubsetUnsupported); + goto _exit; + } + // check NUMA node + hN = hwloc_get_ancestor_obj_by_type(tp, HWLOC_OBJ_NUMANODE, hT); + hS = hwloc_get_ancestor_obj_by_type(tp, HWLOC_OBJ_PACKAGE, hT); + if (hN != NULL && hN->depth > hS->depth) { + numa_support = 1; // 1 in case socket includes node(s) + } else if (__kmp_hws_node.num > 0) { + // don't support sockets inside NUMA node (no such HW found for testing) + KMP_WARNING(AffHWSubsetUnsupported); + goto _exit; + } + // check L2 cahce, get object by depth because of multiple caches + L2depth = hwloc_get_cache_type_depth(tp, 2, HWLOC_OBJ_CACHE_UNIFIED); + hL = hwloc_get_ancestor_obj_by_depth(tp, L2depth, hT); + if (hL != NULL && + __kmp_hwloc_count_children_by_type(tp, hL, HWLOC_OBJ_CORE, &hC) > 1) { + tile_support = 1; // no sense to count L2 if it includes single core + } else if (__kmp_hws_tile.num > 0) { + if (__kmp_hws_core.num == 0) { + __kmp_hws_core = __kmp_hws_tile; // replace L2 with core + __kmp_hws_tile.num = 0; + } else { + // L2 and core are both requested, but represent same object + KMP_WARNING(AffHWSubsetInvalid); + goto _exit; + } + } + // end of check of extensions ----------------------------------- + + // fill in unset items, validate settings ----------------------- + if (__kmp_hws_socket.num == 0) + __kmp_hws_socket.num = nPackages; // use all available sockets + if (__kmp_hws_socket.offset >= nPackages) { + KMP_WARNING(AffHWSubsetManySockets); + goto _exit; + } + if (numa_support) { + hN = NULL; + int NN = __kmp_hwloc_count_children_by_type(tp, hS, HWLOC_OBJ_NUMANODE, + &hN); // num nodes in socket + if (__kmp_hws_node.num == 0) + __kmp_hws_node.num = NN; // use all available nodes + if (__kmp_hws_node.offset >= NN) { + KMP_WARNING(AffHWSubsetManyNodes); + goto _exit; + } + if (tile_support) { + // get num tiles in node + int NL = __kmp_hwloc_count_children_by_depth(tp, hN, L2depth, &hL); + if (__kmp_hws_tile.num == 0) { + __kmp_hws_tile.num = NL + 1; + } // use all available tiles, some node may have more tiles, thus +1 + if (__kmp_hws_tile.offset >= NL) { + KMP_WARNING(AffHWSubsetManyTiles); + goto _exit; + } + int NC = __kmp_hwloc_count_children_by_type(tp, hL, HWLOC_OBJ_CORE, + &hC); // num cores in tile + if (__kmp_hws_core.num == 0) + __kmp_hws_core.num = NC; // use all available cores + if (__kmp_hws_core.offset >= NC) { + KMP_WARNING(AffHWSubsetManyCores); + goto _exit; + } + } else { // tile_support + int NC = __kmp_hwloc_count_children_by_type(tp, hN, HWLOC_OBJ_CORE, + &hC); // num cores in node + if (__kmp_hws_core.num == 0) + __kmp_hws_core.num = NC; // use all available cores + if (__kmp_hws_core.offset >= NC) { + KMP_WARNING(AffHWSubsetManyCores); + goto _exit; + } + } // tile_support + } else { // numa_support + if (tile_support) { + // get num tiles in socket + int NL = __kmp_hwloc_count_children_by_depth(tp, hS, L2depth, &hL); + if (__kmp_hws_tile.num == 0) + __kmp_hws_tile.num = NL; // use all available tiles + if (__kmp_hws_tile.offset >= NL) { + KMP_WARNING(AffHWSubsetManyTiles); + goto _exit; + } + int NC = __kmp_hwloc_count_children_by_type(tp, hL, HWLOC_OBJ_CORE, + &hC); // num cores in tile + if (__kmp_hws_core.num == 0) + __kmp_hws_core.num = NC; // use all available cores + if (__kmp_hws_core.offset >= NC) { + KMP_WARNING(AffHWSubsetManyCores); + goto _exit; + } + } else { // tile_support + int NC = __kmp_hwloc_count_children_by_type(tp, hS, HWLOC_OBJ_CORE, + &hC); // num cores in socket + if (__kmp_hws_core.num == 0) + __kmp_hws_core.num = NC; // use all available cores + if (__kmp_hws_core.offset >= NC) { + KMP_WARNING(AffHWSubsetManyCores); + goto _exit; + } + } // tile_support + } + if (__kmp_hws_proc.num == 0) + __kmp_hws_proc.num = __kmp_nThreadsPerCore; // use all available procs + if (__kmp_hws_proc.offset >= __kmp_nThreadsPerCore) { + KMP_WARNING(AffHWSubsetManyProcs); + goto _exit; + } + // end of validation -------------------------------------------- + + if (pAddr) // pAddr is NULL in case of affinity_none + newAddr = (AddrUnsPair *)__kmp_allocate(sizeof(AddrUnsPair) * + __kmp_avail_proc); // max size + // main loop to form HW subset ---------------------------------- + hS = NULL; + int NP = hwloc_get_nbobjs_by_type(tp, HWLOC_OBJ_PACKAGE); + for (int s = 0; s < NP; ++s) { + // Check Socket ----------------------------------------------- + hS = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PACKAGE, hS); + if (!__kmp_hwloc_obj_has_PUs(tp, hS)) + continue; // skip socket if all PUs are out of fullMask + ++nS; // only count objects those have PUs in affinity mask + if (nS <= __kmp_hws_socket.offset || + nS > __kmp_hws_socket.num + __kmp_hws_socket.offset) { + n_old += __kmp_hwloc_skip_PUs_obj(tp, hS); // skip socket + continue; // move to next socket + } + nCr = 0; // count number of cores per socket + // socket requested, go down the topology tree + // check 4 cases: (+NUMA+Tile), (+NUMA-Tile), (-NUMA+Tile), (-NUMA-Tile) + if (numa_support) { + nN = 0; + hN = NULL; + // num nodes in current socket + int NN = + __kmp_hwloc_count_children_by_type(tp, hS, HWLOC_OBJ_NUMANODE, &hN); + for (int n = 0; n < NN; ++n) { + // Check NUMA Node ---------------------------------------- + if (!__kmp_hwloc_obj_has_PUs(tp, hN)) { + hN = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_NUMANODE, hN); + continue; // skip node if all PUs are out of fullMask + } + ++nN; + if (nN <= __kmp_hws_node.offset || + nN > __kmp_hws_node.num + __kmp_hws_node.offset) { + // skip node as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hN); // skip node + hN = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_NUMANODE, hN); + continue; // move to next node + } + // node requested, go down the topology tree + if (tile_support) { + nL = 0; + hL = NULL; + int NL = __kmp_hwloc_count_children_by_depth(tp, hN, L2depth, &hL); + for (int l = 0; l < NL; ++l) { + // Check L2 (tile) ------------------------------------ + if (!__kmp_hwloc_obj_has_PUs(tp, hL)) { + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + continue; // skip tile if all PUs are out of fullMask + } + ++nL; + if (nL <= __kmp_hws_tile.offset || + nL > __kmp_hws_tile.num + __kmp_hws_tile.offset) { + // skip tile as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hL); // skip tile + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + continue; // move to next tile + } + // tile requested, go down the topology tree + nC = 0; + hC = NULL; + // num cores in current tile + int NC = __kmp_hwloc_count_children_by_type(tp, hL, + HWLOC_OBJ_CORE, &hC); + for (int c = 0; c < NC; ++c) { + // Check Core --------------------------------------- + if (!__kmp_hwloc_obj_has_PUs(tp, hC)) { + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // skip core if all PUs are out of fullMask + } + ++nC; + if (nC <= __kmp_hws_core.offset || + nC > __kmp_hws_core.num + __kmp_hws_core.offset) { + // skip node as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hC); // skip core + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // move to next node + } + // core requested, go down to PUs + nT = 0; + nTr = 0; + hT = NULL; + // num procs in current core + int NT = __kmp_hwloc_count_children_by_type(tp, hC, + HWLOC_OBJ_PU, &hT); + for (int t = 0; t < NT; ++t) { + // Check PU --------------------------------------- + idx = hT->os_index; + if (!KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) { + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // skip PU if not in fullMask + } + ++nT; + if (nT <= __kmp_hws_proc.offset || + nT > __kmp_hws_proc.num + __kmp_hws_proc.offset) { + // skip PU + KMP_CPU_CLR(idx, __kmp_affin_fullMask); + ++n_old; + KC_TRACE(200, ("KMP_HW_SUBSET: skipped proc %d\n", idx)); + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // move to next node + } + ++nTr; + if (pAddr) // collect requested thread's data + newAddr[n_new] = (*pAddr)[n_old]; + ++n_new; + ++n_old; + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + } // threads loop + if (nTr > 0) { + ++nCr; // num cores per socket + ++nCo; // total num cores + if (nTr > nTpC) + nTpC = nTr; // calc max threads per core + } + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + } // cores loop + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + } // tiles loop + } else { // tile_support + // no tiles, check cores + nC = 0; + hC = NULL; + // num cores in current node + int NC = + __kmp_hwloc_count_children_by_type(tp, hN, HWLOC_OBJ_CORE, &hC); + for (int c = 0; c < NC; ++c) { + // Check Core --------------------------------------- + if (!__kmp_hwloc_obj_has_PUs(tp, hC)) { + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // skip core if all PUs are out of fullMask + } + ++nC; + if (nC <= __kmp_hws_core.offset || + nC > __kmp_hws_core.num + __kmp_hws_core.offset) { + // skip node as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hC); // skip core + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // move to next node + } + // core requested, go down to PUs + nT = 0; + nTr = 0; + hT = NULL; + int NT = + __kmp_hwloc_count_children_by_type(tp, hC, HWLOC_OBJ_PU, &hT); + for (int t = 0; t < NT; ++t) { + // Check PU --------------------------------------- + idx = hT->os_index; + if (!KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) { + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // skip PU if not in fullMask + } + ++nT; + if (nT <= __kmp_hws_proc.offset || + nT > __kmp_hws_proc.num + __kmp_hws_proc.offset) { + // skip PU + KMP_CPU_CLR(idx, __kmp_affin_fullMask); + ++n_old; + KC_TRACE(200, ("KMP_HW_SUBSET: skipped proc %d\n", idx)); + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // move to next node + } + ++nTr; + if (pAddr) // collect requested thread's data + newAddr[n_new] = (*pAddr)[n_old]; + ++n_new; + ++n_old; + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + } // threads loop + if (nTr > 0) { + ++nCr; // num cores per socket + ++nCo; // total num cores + if (nTr > nTpC) + nTpC = nTr; // calc max threads per core + } + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + } // cores loop + } // tiles support + hN = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_NUMANODE, hN); + } // nodes loop + } else { // numa_support + // no NUMA support + if (tile_support) { + nL = 0; + hL = NULL; + // num tiles in current socket + int NL = __kmp_hwloc_count_children_by_depth(tp, hS, L2depth, &hL); + for (int l = 0; l < NL; ++l) { + // Check L2 (tile) ------------------------------------ + if (!__kmp_hwloc_obj_has_PUs(tp, hL)) { + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + continue; // skip tile if all PUs are out of fullMask + } + ++nL; + if (nL <= __kmp_hws_tile.offset || + nL > __kmp_hws_tile.num + __kmp_hws_tile.offset) { + // skip tile as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hL); // skip tile + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + continue; // move to next tile + } + // tile requested, go down the topology tree + nC = 0; + hC = NULL; + // num cores per tile + int NC = + __kmp_hwloc_count_children_by_type(tp, hL, HWLOC_OBJ_CORE, &hC); + for (int c = 0; c < NC; ++c) { + // Check Core --------------------------------------- + if (!__kmp_hwloc_obj_has_PUs(tp, hC)) { + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // skip core if all PUs are out of fullMask + } + ++nC; + if (nC <= __kmp_hws_core.offset || + nC > __kmp_hws_core.num + __kmp_hws_core.offset) { + // skip node as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hC); // skip core + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // move to next node + } + // core requested, go down to PUs + nT = 0; + nTr = 0; + hT = NULL; + // num procs per core + int NT = + __kmp_hwloc_count_children_by_type(tp, hC, HWLOC_OBJ_PU, &hT); + for (int t = 0; t < NT; ++t) { + // Check PU --------------------------------------- + idx = hT->os_index; + if (!KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) { + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // skip PU if not in fullMask + } + ++nT; + if (nT <= __kmp_hws_proc.offset || + nT > __kmp_hws_proc.num + __kmp_hws_proc.offset) { + // skip PU + KMP_CPU_CLR(idx, __kmp_affin_fullMask); + ++n_old; + KC_TRACE(200, ("KMP_HW_SUBSET: skipped proc %d\n", idx)); + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // move to next node + } + ++nTr; + if (pAddr) // collect requested thread's data + newAddr[n_new] = (*pAddr)[n_old]; + ++n_new; + ++n_old; + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + } // threads loop + if (nTr > 0) { + ++nCr; // num cores per socket + ++nCo; // total num cores + if (nTr > nTpC) + nTpC = nTr; // calc max threads per core + } + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + } // cores loop + hL = hwloc_get_next_obj_by_depth(tp, L2depth, hL); + } // tiles loop + } else { // tile_support + // no tiles, check cores + nC = 0; + hC = NULL; + // num cores in socket + int NC = + __kmp_hwloc_count_children_by_type(tp, hS, HWLOC_OBJ_CORE, &hC); + for (int c = 0; c < NC; ++c) { + // Check Core ------------------------------------------- + if (!__kmp_hwloc_obj_has_PUs(tp, hC)) { + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // skip core if all PUs are out of fullMask + } + ++nC; + if (nC <= __kmp_hws_core.offset || + nC > __kmp_hws_core.num + __kmp_hws_core.offset) { + // skip node as not requested + n_old += __kmp_hwloc_skip_PUs_obj(tp, hC); // skip core + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + continue; // move to next node + } + // core requested, go down to PUs + nT = 0; + nTr = 0; + hT = NULL; + // num procs per core + int NT = + __kmp_hwloc_count_children_by_type(tp, hC, HWLOC_OBJ_PU, &hT); + for (int t = 0; t < NT; ++t) { + // Check PU --------------------------------------- + idx = hT->os_index; + if (!KMP_CPU_ISSET(idx, __kmp_affin_fullMask)) { + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // skip PU if not in fullMask + } + ++nT; + if (nT <= __kmp_hws_proc.offset || + nT > __kmp_hws_proc.num + __kmp_hws_proc.offset) { + // skip PU + KMP_CPU_CLR(idx, __kmp_affin_fullMask); + ++n_old; + KC_TRACE(200, ("KMP_HW_SUBSET: skipped proc %d\n", idx)); + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + continue; // move to next node + } + ++nTr; + if (pAddr) // collect requested thread's data + newAddr[n_new] = (*pAddr)[n_old]; + ++n_new; + ++n_old; + hT = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_PU, hT); + } // threads loop + if (nTr > 0) { + ++nCr; // num cores per socket + ++nCo; // total num cores + if (nTr > nTpC) + nTpC = nTr; // calc max threads per core + } + hC = hwloc_get_next_obj_by_type(tp, HWLOC_OBJ_CORE, hC); + } // cores loop + } // tiles support + } // numa_support + if (nCr > 0) { // found cores? + ++nPkg; // num sockets + if (nCr > nCpP) + nCpP = nCr; // calc max cores per socket + } + } // sockets loop + + // check the subset is valid + KMP_DEBUG_ASSERT(n_old == __kmp_avail_proc); + KMP_DEBUG_ASSERT(nPkg > 0); + KMP_DEBUG_ASSERT(nCpP > 0); + KMP_DEBUG_ASSERT(nTpC > 0); + KMP_DEBUG_ASSERT(nCo > 0); + KMP_DEBUG_ASSERT(nPkg <= nPackages); + KMP_DEBUG_ASSERT(nCpP <= nCoresPerPkg); + KMP_DEBUG_ASSERT(nTpC <= __kmp_nThreadsPerCore); + KMP_DEBUG_ASSERT(nCo <= __kmp_ncores); + + nPackages = nPkg; // correct num sockets + nCoresPerPkg = nCpP; // correct num cores per socket + __kmp_nThreadsPerCore = nTpC; // correct num threads per core + __kmp_avail_proc = n_new; // correct num procs + __kmp_ncores = nCo; // correct num cores + // hwloc topology method end + } else +#endif // KMP_USE_HWLOC + { + int n_old = 0, n_new = 0, proc_num = 0; + if (__kmp_hws_node.num > 0 || __kmp_hws_tile.num > 0) { + KMP_WARNING(AffHWSubsetNoHWLOC); + goto _exit; + } + if (__kmp_hws_socket.num == 0) + __kmp_hws_socket.num = nPackages; // use all available sockets + if (__kmp_hws_core.num == 0) + __kmp_hws_core.num = nCoresPerPkg; // use all available cores + if (__kmp_hws_proc.num == 0 || __kmp_hws_proc.num > __kmp_nThreadsPerCore) + __kmp_hws_proc.num = __kmp_nThreadsPerCore; // use all HW contexts + if (!__kmp_affinity_uniform_topology()) { + KMP_WARNING(AffHWSubsetNonUniform); + goto _exit; // don't support non-uniform topology + } + if (depth > 3) { + KMP_WARNING(AffHWSubsetNonThreeLevel); + goto _exit; // don't support not-3-level topology + } + if (__kmp_hws_socket.offset + __kmp_hws_socket.num > nPackages) { + KMP_WARNING(AffHWSubsetManySockets); + goto _exit; + } + if (__kmp_hws_core.offset + __kmp_hws_core.num > nCoresPerPkg) { + KMP_WARNING(AffHWSubsetManyCores); + goto _exit; + } + // Form the requested subset + if (pAddr) // pAddr is NULL in case of affinity_none + newAddr = (AddrUnsPair *)__kmp_allocate( + sizeof(AddrUnsPair) * __kmp_hws_socket.num * __kmp_hws_core.num * + __kmp_hws_proc.num); + for (int i = 0; i < nPackages; ++i) { + if (i < __kmp_hws_socket.offset || + i >= __kmp_hws_socket.offset + __kmp_hws_socket.num) { + // skip not-requested socket + n_old += nCoresPerPkg * __kmp_nThreadsPerCore; + if (__kmp_pu_os_idx != NULL) { + // walk through skipped socket + for (int j = 0; j < nCoresPerPkg; ++j) { + for (int k = 0; k < __kmp_nThreadsPerCore; ++k) { + KMP_CPU_CLR(__kmp_pu_os_idx[proc_num], __kmp_affin_fullMask); + ++proc_num; + } + } + } + } else { + // walk through requested socket + for (int j = 0; j < nCoresPerPkg; ++j) { + if (j < __kmp_hws_core.offset || + j >= __kmp_hws_core.offset + + __kmp_hws_core.num) { // skip not-requested core + n_old += __kmp_nThreadsPerCore; + if (__kmp_pu_os_idx != NULL) { + for (int k = 0; k < __kmp_nThreadsPerCore; ++k) { + KMP_CPU_CLR(__kmp_pu_os_idx[proc_num], __kmp_affin_fullMask); + ++proc_num; + } + } + } else { + // walk through requested core + for (int k = 0; k < __kmp_nThreadsPerCore; ++k) { + if (k < __kmp_hws_proc.num) { + if (pAddr) // collect requested thread's data + newAddr[n_new] = (*pAddr)[n_old]; + n_new++; + } else { + if (__kmp_pu_os_idx != NULL) + KMP_CPU_CLR(__kmp_pu_os_idx[proc_num], __kmp_affin_fullMask); + } + n_old++; + ++proc_num; + } + } + } + } + } + KMP_DEBUG_ASSERT(n_old == nPackages * nCoresPerPkg * __kmp_nThreadsPerCore); + KMP_DEBUG_ASSERT(n_new == + __kmp_hws_socket.num * __kmp_hws_core.num * + __kmp_hws_proc.num); + nPackages = __kmp_hws_socket.num; // correct nPackages + nCoresPerPkg = __kmp_hws_core.num; // correct nCoresPerPkg + __kmp_nThreadsPerCore = __kmp_hws_proc.num; // correct __kmp_nThreadsPerCore + __kmp_avail_proc = n_new; // correct avail_proc + __kmp_ncores = nPackages * __kmp_hws_core.num; // correct ncores + } // non-hwloc topology method + if (pAddr) { + __kmp_free(*pAddr); + *pAddr = newAddr; // replace old topology with new one + } + if (__kmp_affinity_verbose) { + char m[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(m, KMP_AFFIN_MASK_PRINT_LEN, + __kmp_affin_fullMask); + if (__kmp_affinity_respect_mask) { + KMP_INFORM(InitOSProcSetRespect, "KMP_HW_SUBSET", m); + } else { + KMP_INFORM(InitOSProcSetNotRespect, "KMP_HW_SUBSET", m); + } + KMP_INFORM(AvailableOSProc, "KMP_HW_SUBSET", __kmp_avail_proc); + kmp_str_buf_t buf; + __kmp_str_buf_init(&buf); + __kmp_str_buf_print(&buf, "%d", nPackages); + KMP_INFORM(TopologyExtra, "KMP_HW_SUBSET", buf.str, nCoresPerPkg, + __kmp_nThreadsPerCore, __kmp_ncores); + __kmp_str_buf_free(&buf); + } +_exit: + if (__kmp_pu_os_idx != NULL) { + __kmp_free(__kmp_pu_os_idx); + __kmp_pu_os_idx = NULL; + } +} + +// This function figures out the deepest level at which there is at least one +// cluster/core with more than one processing unit bound to it. +static int __kmp_affinity_find_core_level(const AddrUnsPair *address2os, + int nprocs, int bottom_level) { + int core_level = 0; + + for (int i = 0; i < nprocs; i++) { + for (int j = bottom_level; j > 0; j--) { + if (address2os[i].first.labels[j] > 0) { + if (core_level < (j - 1)) { + core_level = j - 1; + } + } + } + } + return core_level; +} + +// This function counts number of clusters/cores at given level. +static int __kmp_affinity_compute_ncores(const AddrUnsPair *address2os, + int nprocs, int bottom_level, + int core_level) { + int ncores = 0; + int i, j; + + j = bottom_level; + for (i = 0; i < nprocs; i++) { + for (j = bottom_level; j > core_level; j--) { + if ((i + 1) < nprocs) { + if (address2os[i + 1].first.labels[j] > 0) { + break; + } + } + } + if (j == core_level) { + ncores++; + } + } + if (j > core_level) { + // In case of ( nprocs < __kmp_avail_proc ) we may end too deep and miss one + // core. May occur when called from __kmp_affinity_find_core(). + ncores++; + } + return ncores; +} + +// This function finds to which cluster/core given processing unit is bound. +static int __kmp_affinity_find_core(const AddrUnsPair *address2os, int proc, + int bottom_level, int core_level) { + return __kmp_affinity_compute_ncores(address2os, proc + 1, bottom_level, + core_level) - + 1; +} + +// This function finds maximal number of processing units bound to a +// cluster/core at given level. +static int __kmp_affinity_max_proc_per_core(const AddrUnsPair *address2os, + int nprocs, int bottom_level, + int core_level) { + int maxprocpercore = 0; + + if (core_level < bottom_level) { + for (int i = 0; i < nprocs; i++) { + int percore = address2os[i].first.labels[core_level + 1] + 1; + + if (percore > maxprocpercore) { + maxprocpercore = percore; + } + } + } else { + maxprocpercore = 1; + } + return maxprocpercore; +} + +static AddrUnsPair *address2os = NULL; +static int *procarr = NULL; +static int __kmp_aff_depth = 0; + +#if KMP_USE_HIER_SCHED +#define KMP_EXIT_AFF_NONE \ + KMP_ASSERT(__kmp_affinity_type == affinity_none); \ + KMP_ASSERT(address2os == NULL); \ + __kmp_apply_thread_places(NULL, 0); \ + __kmp_create_affinity_none_places(); \ + __kmp_dispatch_set_hierarchy_values(); \ + return; +#else +#define KMP_EXIT_AFF_NONE \ + KMP_ASSERT(__kmp_affinity_type == affinity_none); \ + KMP_ASSERT(address2os == NULL); \ + __kmp_apply_thread_places(NULL, 0); \ + __kmp_create_affinity_none_places(); \ + return; +#endif + +// Create a one element mask array (set of places) which only contains the +// initial process's affinity mask +static void __kmp_create_affinity_none_places() { + KMP_ASSERT(__kmp_affin_fullMask != NULL); + KMP_ASSERT(__kmp_affinity_type == affinity_none); + __kmp_affinity_num_masks = 1; + KMP_CPU_ALLOC_ARRAY(__kmp_affinity_masks, __kmp_affinity_num_masks); + kmp_affin_mask_t *dest = KMP_CPU_INDEX(__kmp_affinity_masks, 0); + KMP_CPU_COPY(dest, __kmp_affin_fullMask); +} + +static int __kmp_affinity_cmp_Address_child_num(const void *a, const void *b) { + const Address *aa = &(((const AddrUnsPair *)a)->first); + const Address *bb = &(((const AddrUnsPair *)b)->first); + unsigned depth = aa->depth; + unsigned i; + KMP_DEBUG_ASSERT(depth == bb->depth); + KMP_DEBUG_ASSERT((unsigned)__kmp_affinity_compact <= depth); + KMP_DEBUG_ASSERT(__kmp_affinity_compact >= 0); + for (i = 0; i < (unsigned)__kmp_affinity_compact; i++) { + int j = depth - i - 1; + if (aa->childNums[j] < bb->childNums[j]) + return -1; + if (aa->childNums[j] > bb->childNums[j]) + return 1; + } + for (; i < depth; i++) { + int j = i - __kmp_affinity_compact; + if (aa->childNums[j] < bb->childNums[j]) + return -1; + if (aa->childNums[j] > bb->childNums[j]) + return 1; + } + return 0; +} + +static void __kmp_aux_affinity_initialize(void) { + if (__kmp_affinity_masks != NULL) { + KMP_ASSERT(__kmp_affin_fullMask != NULL); + return; + } + + // Create the "full" mask - this defines all of the processors that we + // consider to be in the machine model. If respect is set, then it is the + // initialization thread's affinity mask. Otherwise, it is all processors that + // we know about on the machine. + if (__kmp_affin_fullMask == NULL) { + KMP_CPU_ALLOC(__kmp_affin_fullMask); + } + if (KMP_AFFINITY_CAPABLE()) { + if (__kmp_affinity_respect_mask) { + __kmp_get_system_affinity(__kmp_affin_fullMask, TRUE); + + // Count the number of available processors. + unsigned i; + __kmp_avail_proc = 0; + KMP_CPU_SET_ITERATE(i, __kmp_affin_fullMask) { + if (!KMP_CPU_ISSET(i, __kmp_affin_fullMask)) { + continue; + } + __kmp_avail_proc++; + } + if (__kmp_avail_proc > __kmp_xproc) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && + (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(ErrorInitializeAffinity); + } + __kmp_affinity_type = affinity_none; + KMP_AFFINITY_DISABLE(); + return; + } + } else { + __kmp_affinity_entire_machine_mask(__kmp_affin_fullMask); + __kmp_avail_proc = __kmp_xproc; + } + } + + if (__kmp_affinity_gran == affinity_gran_tile && + // check if user's request is valid + __kmp_affinity_dispatch->get_api_type() == KMPAffinity::NATIVE_OS) { + KMP_WARNING(AffTilesNoHWLOC, "KMP_AFFINITY"); + __kmp_affinity_gran = affinity_gran_package; + } + + int depth = -1; + kmp_i18n_id_t msg_id = kmp_i18n_null; + + // For backward compatibility, setting KMP_CPUINFO_FILE => + // KMP_TOPOLOGY_METHOD=cpuinfo + if ((__kmp_cpuinfo_file != NULL) && + (__kmp_affinity_top_method == affinity_top_method_all)) { + __kmp_affinity_top_method = affinity_top_method_cpuinfo; + } + + if (__kmp_affinity_top_method == affinity_top_method_all) { + // In the default code path, errors are not fatal - we just try using + // another method. We only emit a warning message if affinity is on, or the + // verbose flag is set, an the nowarnings flag was not set. + const char *file_name = NULL; + int line = 0; +#if KMP_USE_HWLOC + if (depth < 0 && + __kmp_affinity_dispatch->get_api_type() == KMPAffinity::HWLOC) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffUsingHwloc, "KMP_AFFINITY"); + } + if (!__kmp_hwloc_error) { + depth = __kmp_affinity_create_hwloc_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } else if (depth < 0 && __kmp_affinity_verbose) { + KMP_INFORM(AffIgnoringHwloc, "KMP_AFFINITY"); + } + } else if (__kmp_affinity_verbose) { + KMP_INFORM(AffIgnoringHwloc, "KMP_AFFINITY"); + } + } +#endif + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + + if (depth < 0) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffInfoStr, "KMP_AFFINITY", KMP_I18N_STR(Decodingx2APIC)); + } + + file_name = NULL; + depth = __kmp_affinity_create_x2apicid_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + + if (depth < 0) { + if (__kmp_affinity_verbose) { + if (msg_id != kmp_i18n_null) { + KMP_INFORM(AffInfoStrStr, "KMP_AFFINITY", + __kmp_i18n_catgets(msg_id), + KMP_I18N_STR(DecodingLegacyAPIC)); + } else { + KMP_INFORM(AffInfoStr, "KMP_AFFINITY", + KMP_I18N_STR(DecodingLegacyAPIC)); + } + } + + file_name = NULL; + depth = __kmp_affinity_create_apicid_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + } + } + +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + +#if KMP_OS_LINUX + + if (depth < 0) { + if (__kmp_affinity_verbose) { + if (msg_id != kmp_i18n_null) { + KMP_INFORM(AffStrParseFilename, "KMP_AFFINITY", + __kmp_i18n_catgets(msg_id), "/proc/cpuinfo"); + } else { + KMP_INFORM(AffParseFilename, "KMP_AFFINITY", "/proc/cpuinfo"); + } + } + + FILE *f = fopen("/proc/cpuinfo", "r"); + if (f == NULL) { + msg_id = kmp_i18n_str_CantOpenCpuinfo; + } else { + file_name = "/proc/cpuinfo"; + depth = + __kmp_affinity_create_cpuinfo_map(&address2os, &line, &msg_id, f); + fclose(f); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + } + } + +#endif /* KMP_OS_LINUX */ + +#if KMP_GROUP_AFFINITY + + if ((depth < 0) && (__kmp_num_proc_groups > 1)) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffWindowsProcGroupMap, "KMP_AFFINITY"); + } + + depth = __kmp_affinity_create_proc_group_map(&address2os, &msg_id); + KMP_ASSERT(depth != 0); + } + +#endif /* KMP_GROUP_AFFINITY */ + + if (depth < 0) { + if (__kmp_affinity_verbose && (msg_id != kmp_i18n_null)) { + if (file_name == NULL) { + KMP_INFORM(UsingFlatOS, __kmp_i18n_catgets(msg_id)); + } else if (line == 0) { + KMP_INFORM(UsingFlatOSFile, file_name, __kmp_i18n_catgets(msg_id)); + } else { + KMP_INFORM(UsingFlatOSFileLine, file_name, line, + __kmp_i18n_catgets(msg_id)); + } + } + // FIXME - print msg if msg_id = kmp_i18n_null ??? + + file_name = ""; + depth = __kmp_affinity_create_flat_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + KMP_ASSERT(depth > 0); + KMP_ASSERT(address2os != NULL); + } + } + +#if KMP_USE_HWLOC + else if (__kmp_affinity_top_method == affinity_top_method_hwloc) { + KMP_ASSERT(__kmp_affinity_dispatch->get_api_type() == KMPAffinity::HWLOC); + if (__kmp_affinity_verbose) { + KMP_INFORM(AffUsingHwloc, "KMP_AFFINITY"); + } + depth = __kmp_affinity_create_hwloc_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + } +#endif // KMP_USE_HWLOC + +// If the user has specified that a paricular topology discovery method is to be +// used, then we abort if that method fails. The exception is group affinity, +// which might have been implicitly set. + +#if KMP_ARCH_X86 || KMP_ARCH_X86_64 + + else if (__kmp_affinity_top_method == affinity_top_method_x2apicid) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffInfoStr, "KMP_AFFINITY", KMP_I18N_STR(Decodingx2APIC)); + } + + depth = __kmp_affinity_create_x2apicid_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + if (depth < 0) { + KMP_ASSERT(msg_id != kmp_i18n_null); + KMP_FATAL(MsgExiting, __kmp_i18n_catgets(msg_id)); + } + } else if (__kmp_affinity_top_method == affinity_top_method_apicid) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffInfoStr, "KMP_AFFINITY", KMP_I18N_STR(DecodingLegacyAPIC)); + } + + depth = __kmp_affinity_create_apicid_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + if (depth < 0) { + KMP_ASSERT(msg_id != kmp_i18n_null); + KMP_FATAL(MsgExiting, __kmp_i18n_catgets(msg_id)); + } + } + +#endif /* KMP_ARCH_X86 || KMP_ARCH_X86_64 */ + + else if (__kmp_affinity_top_method == affinity_top_method_cpuinfo) { + const char *filename; + if (__kmp_cpuinfo_file != NULL) { + filename = __kmp_cpuinfo_file; + } else { + filename = "/proc/cpuinfo"; + } + + if (__kmp_affinity_verbose) { + KMP_INFORM(AffParseFilename, "KMP_AFFINITY", filename); + } + + FILE *f = fopen(filename, "r"); + if (f == NULL) { + int code = errno; + if (__kmp_cpuinfo_file != NULL) { + __kmp_fatal(KMP_MSG(CantOpenFileForReading, filename), KMP_ERR(code), + KMP_HNT(NameComesFrom_CPUINFO_FILE), __kmp_msg_null); + } else { + __kmp_fatal(KMP_MSG(CantOpenFileForReading, filename), KMP_ERR(code), + __kmp_msg_null); + } + } + int line = 0; + depth = __kmp_affinity_create_cpuinfo_map(&address2os, &line, &msg_id, f); + fclose(f); + if (depth < 0) { + KMP_ASSERT(msg_id != kmp_i18n_null); + if (line > 0) { + KMP_FATAL(FileLineMsgExiting, filename, line, + __kmp_i18n_catgets(msg_id)); + } else { + KMP_FATAL(FileMsgExiting, filename, __kmp_i18n_catgets(msg_id)); + } + } + if (__kmp_affinity_type == affinity_none) { + KMP_ASSERT(depth == 0); + KMP_EXIT_AFF_NONE; + } + } + +#if KMP_GROUP_AFFINITY + + else if (__kmp_affinity_top_method == affinity_top_method_group) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffWindowsProcGroupMap, "KMP_AFFINITY"); + } + + depth = __kmp_affinity_create_proc_group_map(&address2os, &msg_id); + KMP_ASSERT(depth != 0); + if (depth < 0) { + KMP_ASSERT(msg_id != kmp_i18n_null); + KMP_FATAL(MsgExiting, __kmp_i18n_catgets(msg_id)); + } + } + +#endif /* KMP_GROUP_AFFINITY */ + + else if (__kmp_affinity_top_method == affinity_top_method_flat) { + if (__kmp_affinity_verbose) { + KMP_INFORM(AffUsingFlatOS, "KMP_AFFINITY"); + } + + depth = __kmp_affinity_create_flat_map(&address2os, &msg_id); + if (depth == 0) { + KMP_EXIT_AFF_NONE; + } + // should not fail + KMP_ASSERT(depth > 0); + KMP_ASSERT(address2os != NULL); + } + +#if KMP_USE_HIER_SCHED + __kmp_dispatch_set_hierarchy_values(); +#endif + + if (address2os == NULL) { + if (KMP_AFFINITY_CAPABLE() && + (__kmp_affinity_verbose || + (__kmp_affinity_warnings && (__kmp_affinity_type != affinity_none)))) { + KMP_WARNING(ErrorInitializeAffinity); + } + __kmp_affinity_type = affinity_none; + __kmp_create_affinity_none_places(); + KMP_AFFINITY_DISABLE(); + return; + } + + if (__kmp_affinity_gran == affinity_gran_tile +#if KMP_USE_HWLOC + && __kmp_tile_depth == 0 +#endif + ) { + // tiles requested but not detected, warn user on this + KMP_WARNING(AffTilesNoTiles, "KMP_AFFINITY"); + } + + __kmp_apply_thread_places(&address2os, depth); + + // Create the table of masks, indexed by thread Id. + unsigned maxIndex; + unsigned numUnique; + kmp_affin_mask_t *osId2Mask = + __kmp_create_masks(&maxIndex, &numUnique, address2os, __kmp_avail_proc); + if (__kmp_affinity_gran_levels == 0) { + KMP_DEBUG_ASSERT((int)numUnique == __kmp_avail_proc); + } + + // Set the childNums vector in all Address objects. This must be done before + // we can sort using __kmp_affinity_cmp_Address_child_num(), which takes into + // account the setting of __kmp_affinity_compact. + __kmp_affinity_assign_child_nums(address2os, __kmp_avail_proc); + + switch (__kmp_affinity_type) { + + case affinity_explicit: + KMP_DEBUG_ASSERT(__kmp_affinity_proclist != NULL); +#if OMP_40_ENABLED + if (__kmp_nested_proc_bind.bind_types[0] == proc_bind_intel) +#endif + { + __kmp_affinity_process_proclist( + &__kmp_affinity_masks, &__kmp_affinity_num_masks, + __kmp_affinity_proclist, osId2Mask, maxIndex); + } +#if OMP_40_ENABLED + else { + __kmp_affinity_process_placelist( + &__kmp_affinity_masks, &__kmp_affinity_num_masks, + __kmp_affinity_proclist, osId2Mask, maxIndex); + } +#endif + if (__kmp_affinity_num_masks == 0) { + if (__kmp_affinity_verbose || + (__kmp_affinity_warnings && (__kmp_affinity_type != affinity_none))) { + KMP_WARNING(AffNoValidProcID); + } + __kmp_affinity_type = affinity_none; + __kmp_create_affinity_none_places(); + return; + } + break; + + // The other affinity types rely on sorting the Addresses according to some + // permutation of the machine topology tree. Set __kmp_affinity_compact and + // __kmp_affinity_offset appropriately, then jump to a common code fragment + // to do the sort and create the array of affinity masks. + + case affinity_logical: + __kmp_affinity_compact = 0; + if (__kmp_affinity_offset) { + __kmp_affinity_offset = + __kmp_nThreadsPerCore * __kmp_affinity_offset % __kmp_avail_proc; + } + goto sortAddresses; + + case affinity_physical: + if (__kmp_nThreadsPerCore > 1) { + __kmp_affinity_compact = 1; + if (__kmp_affinity_compact >= depth) { + __kmp_affinity_compact = 0; + } + } else { + __kmp_affinity_compact = 0; + } + if (__kmp_affinity_offset) { + __kmp_affinity_offset = + __kmp_nThreadsPerCore * __kmp_affinity_offset % __kmp_avail_proc; + } + goto sortAddresses; + + case affinity_scatter: + if (__kmp_affinity_compact >= depth) { + __kmp_affinity_compact = 0; + } else { + __kmp_affinity_compact = depth - 1 - __kmp_affinity_compact; + } + goto sortAddresses; + + case affinity_compact: + if (__kmp_affinity_compact >= depth) { + __kmp_affinity_compact = depth - 1; + } + goto sortAddresses; + + case affinity_balanced: + if (depth <= 1) { + if (__kmp_affinity_verbose || __kmp_affinity_warnings) { + KMP_WARNING(AffBalancedNotAvail, "KMP_AFFINITY"); + } + __kmp_affinity_type = affinity_none; + __kmp_create_affinity_none_places(); + return; + } else if (!__kmp_affinity_uniform_topology()) { + // Save the depth for further usage + __kmp_aff_depth = depth; + + int core_level = __kmp_affinity_find_core_level( + address2os, __kmp_avail_proc, depth - 1); + int ncores = __kmp_affinity_compute_ncores(address2os, __kmp_avail_proc, + depth - 1, core_level); + int maxprocpercore = __kmp_affinity_max_proc_per_core( + address2os, __kmp_avail_proc, depth - 1, core_level); + + int nproc = ncores * maxprocpercore; + if ((nproc < 2) || (nproc < __kmp_avail_proc)) { + if (__kmp_affinity_verbose || __kmp_affinity_warnings) { + KMP_WARNING(AffBalancedNotAvail, "KMP_AFFINITY"); + } + __kmp_affinity_type = affinity_none; + return; + } + + procarr = (int *)__kmp_allocate(sizeof(int) * nproc); + for (int i = 0; i < nproc; i++) { + procarr[i] = -1; + } + + int lastcore = -1; + int inlastcore = 0; + for (int i = 0; i < __kmp_avail_proc; i++) { + int proc = address2os[i].second; + int core = + __kmp_affinity_find_core(address2os, i, depth - 1, core_level); + + if (core == lastcore) { + inlastcore++; + } else { + inlastcore = 0; + } + lastcore = core; + + procarr[core * maxprocpercore + inlastcore] = proc; + } + } + if (__kmp_affinity_compact >= depth) { + __kmp_affinity_compact = depth - 1; + } + + sortAddresses: + // Allocate the gtid->affinity mask table. + if (__kmp_affinity_dups) { + __kmp_affinity_num_masks = __kmp_avail_proc; + } else { + __kmp_affinity_num_masks = numUnique; + } + +#if OMP_40_ENABLED + if ((__kmp_nested_proc_bind.bind_types[0] != proc_bind_intel) && + (__kmp_affinity_num_places > 0) && + ((unsigned)__kmp_affinity_num_places < __kmp_affinity_num_masks)) { + __kmp_affinity_num_masks = __kmp_affinity_num_places; + } +#endif + + KMP_CPU_ALLOC_ARRAY(__kmp_affinity_masks, __kmp_affinity_num_masks); + + // Sort the address2os table according to the current setting of + // __kmp_affinity_compact, then fill out __kmp_affinity_masks. + qsort(address2os, __kmp_avail_proc, sizeof(*address2os), + __kmp_affinity_cmp_Address_child_num); + { + int i; + unsigned j; + for (i = 0, j = 0; i < __kmp_avail_proc; i++) { + if ((!__kmp_affinity_dups) && (!address2os[i].first.leader)) { + continue; + } + unsigned osId = address2os[i].second; + kmp_affin_mask_t *src = KMP_CPU_INDEX(osId2Mask, osId); + kmp_affin_mask_t *dest = KMP_CPU_INDEX(__kmp_affinity_masks, j); + KMP_ASSERT(KMP_CPU_ISSET(osId, src)); + KMP_CPU_COPY(dest, src); + if (++j >= __kmp_affinity_num_masks) { + break; + } + } + KMP_DEBUG_ASSERT(j == __kmp_affinity_num_masks); + } + break; + + default: + KMP_ASSERT2(0, "Unexpected affinity setting"); + } + + KMP_CPU_FREE_ARRAY(osId2Mask, maxIndex + 1); + machine_hierarchy.init(address2os, __kmp_avail_proc); +} +#undef KMP_EXIT_AFF_NONE + +void __kmp_affinity_initialize(void) { + // Much of the code above was written assumming that if a machine was not + // affinity capable, then __kmp_affinity_type == affinity_none. We now + // explicitly represent this as __kmp_affinity_type == affinity_disabled. + // There are too many checks for __kmp_affinity_type == affinity_none + // in this code. Instead of trying to change them all, check if + // __kmp_affinity_type == affinity_disabled, and if so, slam it with + // affinity_none, call the real initialization routine, then restore + // __kmp_affinity_type to affinity_disabled. + int disabled = (__kmp_affinity_type == affinity_disabled); + if (!KMP_AFFINITY_CAPABLE()) { + KMP_ASSERT(disabled); + } + if (disabled) { + __kmp_affinity_type = affinity_none; + } + __kmp_aux_affinity_initialize(); + if (disabled) { + __kmp_affinity_type = affinity_disabled; + } +} + +void __kmp_affinity_uninitialize(void) { + if (__kmp_affinity_masks != NULL) { + KMP_CPU_FREE_ARRAY(__kmp_affinity_masks, __kmp_affinity_num_masks); + __kmp_affinity_masks = NULL; + } + if (__kmp_affin_fullMask != NULL) { + KMP_CPU_FREE(__kmp_affin_fullMask); + __kmp_affin_fullMask = NULL; + } + __kmp_affinity_num_masks = 0; + __kmp_affinity_type = affinity_default; +#if OMP_40_ENABLED + __kmp_affinity_num_places = 0; +#endif + if (__kmp_affinity_proclist != NULL) { + __kmp_free(__kmp_affinity_proclist); + __kmp_affinity_proclist = NULL; + } + if (address2os != NULL) { + __kmp_free(address2os); + address2os = NULL; + } + if (procarr != NULL) { + __kmp_free(procarr); + procarr = NULL; + } +#if KMP_USE_HWLOC + if (__kmp_hwloc_topology != NULL) { + hwloc_topology_destroy(__kmp_hwloc_topology); + __kmp_hwloc_topology = NULL; + } +#endif + KMPAffinity::destroy_api(); +} + +void __kmp_affinity_set_init_mask(int gtid, int isa_root) { + if (!KMP_AFFINITY_CAPABLE()) { + return; + } + + kmp_info_t *th = (kmp_info_t *)TCR_SYNC_PTR(__kmp_threads[gtid]); + if (th->th.th_affin_mask == NULL) { + KMP_CPU_ALLOC(th->th.th_affin_mask); + } else { + KMP_CPU_ZERO(th->th.th_affin_mask); + } + + // Copy the thread mask to the kmp_info_t strucuture. If + // __kmp_affinity_type == affinity_none, copy the "full" mask, i.e. one that + // has all of the OS proc ids set, or if __kmp_affinity_respect_mask is set, + // then the full mask is the same as the mask of the initialization thread. + kmp_affin_mask_t *mask; + int i; + +#if OMP_40_ENABLED + if (KMP_AFFINITY_NON_PROC_BIND) +#endif + { + if ((__kmp_affinity_type == affinity_none) || + (__kmp_affinity_type == affinity_balanced)) { +#if KMP_GROUP_AFFINITY + if (__kmp_num_proc_groups > 1) { + return; + } +#endif + KMP_ASSERT(__kmp_affin_fullMask != NULL); + i = 0; + mask = __kmp_affin_fullMask; + } else { + KMP_DEBUG_ASSERT(__kmp_affinity_num_masks > 0); + i = (gtid + __kmp_affinity_offset) % __kmp_affinity_num_masks; + mask = KMP_CPU_INDEX(__kmp_affinity_masks, i); + } + } +#if OMP_40_ENABLED + else { + if ((!isa_root) || + (__kmp_nested_proc_bind.bind_types[0] == proc_bind_false)) { +#if KMP_GROUP_AFFINITY + if (__kmp_num_proc_groups > 1) { + return; + } +#endif + KMP_ASSERT(__kmp_affin_fullMask != NULL); + i = KMP_PLACE_ALL; + mask = __kmp_affin_fullMask; + } else { + // int i = some hash function or just a counter that doesn't + // always start at 0. Use gtid for now. + KMP_DEBUG_ASSERT(__kmp_affinity_num_masks > 0); + i = (gtid + __kmp_affinity_offset) % __kmp_affinity_num_masks; + mask = KMP_CPU_INDEX(__kmp_affinity_masks, i); + } + } +#endif + +#if OMP_40_ENABLED + th->th.th_current_place = i; + if (isa_root) { + th->th.th_new_place = i; + th->th.th_first_place = 0; + th->th.th_last_place = __kmp_affinity_num_masks - 1; + } else if (KMP_AFFINITY_NON_PROC_BIND) { + // When using a Non-OMP_PROC_BIND affinity method, + // set all threads' place-partition-var to the entire place list + th->th.th_first_place = 0; + th->th.th_last_place = __kmp_affinity_num_masks - 1; + } + + if (i == KMP_PLACE_ALL) { + KA_TRACE(100, ("__kmp_affinity_set_init_mask: binding T#%d to all places\n", + gtid)); + } else { + KA_TRACE(100, ("__kmp_affinity_set_init_mask: binding T#%d to place %d\n", + gtid, i)); + } +#else + if (i == -1) { + KA_TRACE( + 100, + ("__kmp_affinity_set_init_mask: binding T#%d to __kmp_affin_fullMask\n", + gtid)); + } else { + KA_TRACE(100, ("__kmp_affinity_set_init_mask: binding T#%d to mask %d\n", + gtid, i)); + } +#endif /* OMP_40_ENABLED */ + + KMP_CPU_COPY(th->th.th_affin_mask, mask); + + if (__kmp_affinity_verbose + /* to avoid duplicate printing (will be correctly printed on barrier) */ + && (__kmp_affinity_type == affinity_none || + (i != KMP_PLACE_ALL && __kmp_affinity_type != affinity_balanced))) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + th->th.th_affin_mask); + KMP_INFORM(BoundToOSProcSet, "KMP_AFFINITY", (kmp_int32)getpid(), + __kmp_gettid(), gtid, buf); + } + +#if KMP_OS_WINDOWS + // On Windows* OS, the process affinity mask might have changed. If the user + // didn't request affinity and this call fails, just continue silently. + // See CQ171393. + if (__kmp_affinity_type == affinity_none) { + __kmp_set_system_affinity(th->th.th_affin_mask, FALSE); + } else +#endif + __kmp_set_system_affinity(th->th.th_affin_mask, TRUE); +} + +#if OMP_40_ENABLED + +void __kmp_affinity_set_place(int gtid) { + if (!KMP_AFFINITY_CAPABLE()) { + return; + } + + kmp_info_t *th = (kmp_info_t *)TCR_SYNC_PTR(__kmp_threads[gtid]); + + KA_TRACE(100, ("__kmp_affinity_set_place: binding T#%d to place %d (current " + "place = %d)\n", + gtid, th->th.th_new_place, th->th.th_current_place)); + + // Check that the new place is within this thread's partition. + KMP_DEBUG_ASSERT(th->th.th_affin_mask != NULL); + KMP_ASSERT(th->th.th_new_place >= 0); + KMP_ASSERT((unsigned)th->th.th_new_place <= __kmp_affinity_num_masks); + if (th->th.th_first_place <= th->th.th_last_place) { + KMP_ASSERT((th->th.th_new_place >= th->th.th_first_place) && + (th->th.th_new_place <= th->th.th_last_place)); + } else { + KMP_ASSERT((th->th.th_new_place <= th->th.th_first_place) || + (th->th.th_new_place >= th->th.th_last_place)); + } + + // Copy the thread mask to the kmp_info_t strucuture, + // and set this thread's affinity. + kmp_affin_mask_t *mask = + KMP_CPU_INDEX(__kmp_affinity_masks, th->th.th_new_place); + KMP_CPU_COPY(th->th.th_affin_mask, mask); + th->th.th_current_place = th->th.th_new_place; + + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + th->th.th_affin_mask); + KMP_INFORM(BoundToOSProcSet, "OMP_PROC_BIND", (kmp_int32)getpid(), + __kmp_gettid(), gtid, buf); + } + __kmp_set_system_affinity(th->th.th_affin_mask, TRUE); +} + +#endif /* OMP_40_ENABLED */ + +int __kmp_aux_set_affinity(void **mask) { + int gtid; + kmp_info_t *th; + int retval; + + if (!KMP_AFFINITY_CAPABLE()) { + return -1; + } + + gtid = __kmp_entry_gtid(); + KA_TRACE(1000, ; { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + (kmp_affin_mask_t *)(*mask)); + __kmp_debug_printf( + "kmp_set_affinity: setting affinity mask for thread %d = %s\n", gtid, + buf); + }); + + if (__kmp_env_consistency_check) { + if ((mask == NULL) || (*mask == NULL)) { + KMP_FATAL(AffinityInvalidMask, "kmp_set_affinity"); + } else { + unsigned proc; + int num_procs = 0; + + KMP_CPU_SET_ITERATE(proc, ((kmp_affin_mask_t *)(*mask))) { + if (!KMP_CPU_ISSET(proc, __kmp_affin_fullMask)) { + KMP_FATAL(AffinityInvalidMask, "kmp_set_affinity"); + } + if (!KMP_CPU_ISSET(proc, (kmp_affin_mask_t *)(*mask))) { + continue; + } + num_procs++; + } + if (num_procs == 0) { + KMP_FATAL(AffinityInvalidMask, "kmp_set_affinity"); + } + +#if KMP_GROUP_AFFINITY + if (__kmp_get_proc_group((kmp_affin_mask_t *)(*mask)) < 0) { + KMP_FATAL(AffinityInvalidMask, "kmp_set_affinity"); + } +#endif /* KMP_GROUP_AFFINITY */ + } + } + + th = __kmp_threads[gtid]; + KMP_DEBUG_ASSERT(th->th.th_affin_mask != NULL); + retval = __kmp_set_system_affinity((kmp_affin_mask_t *)(*mask), FALSE); + if (retval == 0) { + KMP_CPU_COPY(th->th.th_affin_mask, (kmp_affin_mask_t *)(*mask)); + } + +#if OMP_40_ENABLED + th->th.th_current_place = KMP_PLACE_UNDEFINED; + th->th.th_new_place = KMP_PLACE_UNDEFINED; + th->th.th_first_place = 0; + th->th.th_last_place = __kmp_affinity_num_masks - 1; + + // Turn off 4.0 affinity for the current tread at this parallel level. + th->th.th_current_task->td_icvs.proc_bind = proc_bind_false; +#endif + + return retval; +} + +int __kmp_aux_get_affinity(void **mask) { + int gtid; + int retval; + kmp_info_t *th; + + if (!KMP_AFFINITY_CAPABLE()) { + return -1; + } + + gtid = __kmp_entry_gtid(); + th = __kmp_threads[gtid]; + KMP_DEBUG_ASSERT(th->th.th_affin_mask != NULL); + + KA_TRACE(1000, ; { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + th->th.th_affin_mask); + __kmp_printf("kmp_get_affinity: stored affinity mask for thread %d = %s\n", + gtid, buf); + }); + + if (__kmp_env_consistency_check) { + if ((mask == NULL) || (*mask == NULL)) { + KMP_FATAL(AffinityInvalidMask, "kmp_get_affinity"); + } + } + +#if !KMP_OS_WINDOWS + + retval = __kmp_get_system_affinity((kmp_affin_mask_t *)(*mask), FALSE); + KA_TRACE(1000, ; { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + (kmp_affin_mask_t *)(*mask)); + __kmp_printf("kmp_get_affinity: system affinity mask for thread %d = %s\n", + gtid, buf); + }); + return retval; + +#else + + KMP_CPU_COPY((kmp_affin_mask_t *)(*mask), th->th.th_affin_mask); + return 0; + +#endif /* KMP_OS_WINDOWS */ +} + +int __kmp_aux_get_affinity_max_proc() { + if (!KMP_AFFINITY_CAPABLE()) { + return 0; + } +#if KMP_GROUP_AFFINITY + if (__kmp_num_proc_groups > 1) { + return (int)(__kmp_num_proc_groups * sizeof(DWORD_PTR) * CHAR_BIT); + } +#endif + return __kmp_xproc; +} + +int __kmp_aux_set_affinity_mask_proc(int proc, void **mask) { + if (!KMP_AFFINITY_CAPABLE()) { + return -1; + } + + KA_TRACE(1000, ; { + int gtid = __kmp_entry_gtid(); + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + (kmp_affin_mask_t *)(*mask)); + __kmp_debug_printf("kmp_set_affinity_mask_proc: setting proc %d in " + "affinity mask for thread %d = %s\n", + proc, gtid, buf); + }); + + if (__kmp_env_consistency_check) { + if ((mask == NULL) || (*mask == NULL)) { + KMP_FATAL(AffinityInvalidMask, "kmp_set_affinity_mask_proc"); + } + } + + if ((proc < 0) || (proc >= __kmp_aux_get_affinity_max_proc())) { + return -1; + } + if (!KMP_CPU_ISSET(proc, __kmp_affin_fullMask)) { + return -2; + } + + KMP_CPU_SET(proc, (kmp_affin_mask_t *)(*mask)); + return 0; +} + +int __kmp_aux_unset_affinity_mask_proc(int proc, void **mask) { + if (!KMP_AFFINITY_CAPABLE()) { + return -1; + } + + KA_TRACE(1000, ; { + int gtid = __kmp_entry_gtid(); + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + (kmp_affin_mask_t *)(*mask)); + __kmp_debug_printf("kmp_unset_affinity_mask_proc: unsetting proc %d in " + "affinity mask for thread %d = %s\n", + proc, gtid, buf); + }); + + if (__kmp_env_consistency_check) { + if ((mask == NULL) || (*mask == NULL)) { + KMP_FATAL(AffinityInvalidMask, "kmp_unset_affinity_mask_proc"); + } + } + + if ((proc < 0) || (proc >= __kmp_aux_get_affinity_max_proc())) { + return -1; + } + if (!KMP_CPU_ISSET(proc, __kmp_affin_fullMask)) { + return -2; + } + + KMP_CPU_CLR(proc, (kmp_affin_mask_t *)(*mask)); + return 0; +} + +int __kmp_aux_get_affinity_mask_proc(int proc, void **mask) { + if (!KMP_AFFINITY_CAPABLE()) { + return -1; + } + + KA_TRACE(1000, ; { + int gtid = __kmp_entry_gtid(); + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, + (kmp_affin_mask_t *)(*mask)); + __kmp_debug_printf("kmp_get_affinity_mask_proc: getting proc %d in " + "affinity mask for thread %d = %s\n", + proc, gtid, buf); + }); + + if (__kmp_env_consistency_check) { + if ((mask == NULL) || (*mask == NULL)) { + KMP_FATAL(AffinityInvalidMask, "kmp_get_affinity_mask_proc"); + } + } + + if ((proc < 0) || (proc >= __kmp_aux_get_affinity_max_proc())) { + return -1; + } + if (!KMP_CPU_ISSET(proc, __kmp_affin_fullMask)) { + return 0; + } + + return KMP_CPU_ISSET(proc, (kmp_affin_mask_t *)(*mask)); +} + +// Dynamic affinity settings - Affinity balanced +void __kmp_balanced_affinity(kmp_info_t *th, int nthreads) { + KMP_DEBUG_ASSERT(th); + bool fine_gran = true; + int tid = th->th.th_info.ds.ds_tid; + + switch (__kmp_affinity_gran) { + case affinity_gran_fine: + case affinity_gran_thread: + break; + case affinity_gran_core: + if (__kmp_nThreadsPerCore > 1) { + fine_gran = false; + } + break; + case affinity_gran_package: + if (nCoresPerPkg > 1) { + fine_gran = false; + } + break; + default: + fine_gran = false; + } + + if (__kmp_affinity_uniform_topology()) { + int coreID; + int threadID; + // Number of hyper threads per core in HT machine + int __kmp_nth_per_core = __kmp_avail_proc / __kmp_ncores; + // Number of cores + int ncores = __kmp_ncores; + if ((nPackages > 1) && (__kmp_nth_per_core <= 1)) { + __kmp_nth_per_core = __kmp_avail_proc / nPackages; + ncores = nPackages; + } + // How many threads will be bound to each core + int chunk = nthreads / ncores; + // How many cores will have an additional thread bound to it - "big cores" + int big_cores = nthreads % ncores; + // Number of threads on the big cores + int big_nth = (chunk + 1) * big_cores; + if (tid < big_nth) { + coreID = tid / (chunk + 1); + threadID = (tid % (chunk + 1)) % __kmp_nth_per_core; + } else { // tid >= big_nth + coreID = (tid - big_cores) / chunk; + threadID = ((tid - big_cores) % chunk) % __kmp_nth_per_core; + } + + KMP_DEBUG_ASSERT2(KMP_AFFINITY_CAPABLE(), + "Illegal set affinity operation when not capable"); + + kmp_affin_mask_t *mask = th->th.th_affin_mask; + KMP_CPU_ZERO(mask); + + if (fine_gran) { + int osID = address2os[coreID * __kmp_nth_per_core + threadID].second; + KMP_CPU_SET(osID, mask); + } else { + for (int i = 0; i < __kmp_nth_per_core; i++) { + int osID; + osID = address2os[coreID * __kmp_nth_per_core + i].second; + KMP_CPU_SET(osID, mask); + } + } + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, mask); + KMP_INFORM(BoundToOSProcSet, "KMP_AFFINITY", (kmp_int32)getpid(), + __kmp_gettid(), tid, buf); + } + __kmp_set_system_affinity(mask, TRUE); + } else { // Non-uniform topology + + kmp_affin_mask_t *mask = th->th.th_affin_mask; + KMP_CPU_ZERO(mask); + + int core_level = __kmp_affinity_find_core_level( + address2os, __kmp_avail_proc, __kmp_aff_depth - 1); + int ncores = __kmp_affinity_compute_ncores(address2os, __kmp_avail_proc, + __kmp_aff_depth - 1, core_level); + int nth_per_core = __kmp_affinity_max_proc_per_core( + address2os, __kmp_avail_proc, __kmp_aff_depth - 1, core_level); + + // For performance gain consider the special case nthreads == + // __kmp_avail_proc + if (nthreads == __kmp_avail_proc) { + if (fine_gran) { + int osID = address2os[tid].second; + KMP_CPU_SET(osID, mask); + } else { + int core = __kmp_affinity_find_core(address2os, tid, + __kmp_aff_depth - 1, core_level); + for (int i = 0; i < __kmp_avail_proc; i++) { + int osID = address2os[i].second; + if (__kmp_affinity_find_core(address2os, i, __kmp_aff_depth - 1, + core_level) == core) { + KMP_CPU_SET(osID, mask); + } + } + } + } else if (nthreads <= ncores) { + + int core = 0; + for (int i = 0; i < ncores; i++) { + // Check if this core from procarr[] is in the mask + int in_mask = 0; + for (int j = 0; j < nth_per_core; j++) { + if (procarr[i * nth_per_core + j] != -1) { + in_mask = 1; + break; + } + } + if (in_mask) { + if (tid == core) { + for (int j = 0; j < nth_per_core; j++) { + int osID = procarr[i * nth_per_core + j]; + if (osID != -1) { + KMP_CPU_SET(osID, mask); + // For fine granularity it is enough to set the first available + // osID for this core + if (fine_gran) { + break; + } + } + } + break; + } else { + core++; + } + } + } + } else { // nthreads > ncores + // Array to save the number of processors at each core + int *nproc_at_core = (int *)KMP_ALLOCA(sizeof(int) * ncores); + // Array to save the number of cores with "x" available processors; + int *ncores_with_x_procs = + (int *)KMP_ALLOCA(sizeof(int) * (nth_per_core + 1)); + // Array to save the number of cores with # procs from x to nth_per_core + int *ncores_with_x_to_max_procs = + (int *)KMP_ALLOCA(sizeof(int) * (nth_per_core + 1)); + + for (int i = 0; i <= nth_per_core; i++) { + ncores_with_x_procs[i] = 0; + ncores_with_x_to_max_procs[i] = 0; + } + + for (int i = 0; i < ncores; i++) { + int cnt = 0; + for (int j = 0; j < nth_per_core; j++) { + if (procarr[i * nth_per_core + j] != -1) { + cnt++; + } + } + nproc_at_core[i] = cnt; + ncores_with_x_procs[cnt]++; + } + + for (int i = 0; i <= nth_per_core; i++) { + for (int j = i; j <= nth_per_core; j++) { + ncores_with_x_to_max_procs[i] += ncores_with_x_procs[j]; + } + } + + // Max number of processors + int nproc = nth_per_core * ncores; + // An array to keep number of threads per each context + int *newarr = (int *)__kmp_allocate(sizeof(int) * nproc); + for (int i = 0; i < nproc; i++) { + newarr[i] = 0; + } + + int nth = nthreads; + int flag = 0; + while (nth > 0) { + for (int j = 1; j <= nth_per_core; j++) { + int cnt = ncores_with_x_to_max_procs[j]; + for (int i = 0; i < ncores; i++) { + // Skip the core with 0 processors + if (nproc_at_core[i] == 0) { + continue; + } + for (int k = 0; k < nth_per_core; k++) { + if (procarr[i * nth_per_core + k] != -1) { + if (newarr[i * nth_per_core + k] == 0) { + newarr[i * nth_per_core + k] = 1; + cnt--; + nth--; + break; + } else { + if (flag != 0) { + newarr[i * nth_per_core + k]++; + cnt--; + nth--; + break; + } + } + } + } + if (cnt == 0 || nth == 0) { + break; + } + } + if (nth == 0) { + break; + } + } + flag = 1; + } + int sum = 0; + for (int i = 0; i < nproc; i++) { + sum += newarr[i]; + if (sum > tid) { + if (fine_gran) { + int osID = procarr[i]; + KMP_CPU_SET(osID, mask); + } else { + int coreID = i / nth_per_core; + for (int ii = 0; ii < nth_per_core; ii++) { + int osID = procarr[coreID * nth_per_core + ii]; + if (osID != -1) { + KMP_CPU_SET(osID, mask); + } + } + } + break; + } + } + __kmp_free(newarr); + } + + if (__kmp_affinity_verbose) { + char buf[KMP_AFFIN_MASK_PRINT_LEN]; + __kmp_affinity_print_mask(buf, KMP_AFFIN_MASK_PRINT_LEN, mask); + KMP_INFORM(BoundToOSProcSet, "KMP_AFFINITY", (kmp_int32)getpid(), + __kmp_gettid(), tid, buf); + } + __kmp_set_system_affinity(mask, TRUE); + } +} + +#if KMP_OS_LINUX +// We don't need this entry for Windows because +// there is GetProcessAffinityMask() api +// +// The intended usage is indicated by these steps: +// 1) The user gets the current affinity mask +// 2) Then sets the affinity by calling this function +// 3) Error check the return value +// 4) Use non-OpenMP parallelization +// 5) Reset the affinity to what was stored in step 1) +#ifdef __cplusplus +extern "C" +#endif + int + kmp_set_thread_affinity_mask_initial() +// the function returns 0 on success, +// -1 if we cannot bind thread +// >0 (errno) if an error happened during binding +{ + int gtid = __kmp_get_gtid(); + if (gtid < 0) { + // Do not touch non-omp threads + KA_TRACE(30, ("kmp_set_thread_affinity_mask_initial: " + "non-omp thread, returning\n")); + return -1; + } + if (!KMP_AFFINITY_CAPABLE() || !__kmp_init_middle) { + KA_TRACE(30, ("kmp_set_thread_affinity_mask_initial: " + "affinity not initialized, returning\n")); + return -1; + } + KA_TRACE(30, ("kmp_set_thread_affinity_mask_initial: " + "set full mask for thread %d\n", + gtid)); + KMP_DEBUG_ASSERT(__kmp_affin_fullMask != NULL); + return __kmp_set_system_affinity(__kmp_affin_fullMask, FALSE); +} +#endif + +#endif // KMP_AFFINITY_SUPPORTED |