/* * kmp_dispatch.cpp: dynamic scheduling - iteration initialization and dispatch. */ //===----------------------------------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// /* Dynamic scheduling initialization and dispatch. * * NOTE: __kmp_nth is a constant inside of any dispatch loop, however * it may change values between parallel regions. __kmp_max_nth * is the largest value __kmp_nth may take, 1 is the smallest. */ #include "kmp.h" #include "kmp_error.h" #include "kmp_i18n.h" #include "kmp_itt.h" #include "kmp_stats.h" #include "kmp_str.h" #if KMP_USE_X87CONTROL #include #endif #include "kmp_lock.h" #include "kmp_dispatch.h" #if KMP_USE_HIER_SCHED #include "kmp_dispatch_hier.h" #endif #if OMPT_SUPPORT #include "ompt-specific.h" #endif /* ------------------------------------------------------------------------ */ /* ------------------------------------------------------------------------ */ void __kmp_dispatch_deo_error(int *gtid_ref, int *cid_ref, ident_t *loc_ref) { kmp_info_t *th; KMP_DEBUG_ASSERT(gtid_ref); if (__kmp_env_consistency_check) { th = __kmp_threads[*gtid_ref]; if (th->th.th_root->r.r_active && (th->th.th_dispatch->th_dispatch_pr_current->pushed_ws != ct_none)) { #if KMP_USE_DYNAMIC_LOCK __kmp_push_sync(*gtid_ref, ct_ordered_in_pdo, loc_ref, NULL, 0); #else __kmp_push_sync(*gtid_ref, ct_ordered_in_pdo, loc_ref, NULL); #endif } } } void __kmp_dispatch_dxo_error(int *gtid_ref, int *cid_ref, ident_t *loc_ref) { kmp_info_t *th; if (__kmp_env_consistency_check) { th = __kmp_threads[*gtid_ref]; if (th->th.th_dispatch->th_dispatch_pr_current->pushed_ws != ct_none) { __kmp_pop_sync(*gtid_ref, ct_ordered_in_pdo, loc_ref); } } } // Returns either SCHEDULE_MONOTONIC or SCHEDULE_NONMONOTONIC static inline int __kmp_get_monotonicity(ident_t *loc, enum sched_type schedule, bool use_hier = false) { // Pick up the nonmonotonic/monotonic bits from the scheduling type // Nonmonotonic as default for dynamic schedule when no modifier is specified int monotonicity = SCHEDULE_NONMONOTONIC; // Let default be monotonic for executables // compiled with OpenMP* 4.5 or less compilers if (loc != NULL && loc->get_openmp_version() < 50) monotonicity = SCHEDULE_MONOTONIC; if (use_hier || __kmp_force_monotonic) monotonicity = SCHEDULE_MONOTONIC; else if (SCHEDULE_HAS_NONMONOTONIC(schedule)) monotonicity = SCHEDULE_NONMONOTONIC; else if (SCHEDULE_HAS_MONOTONIC(schedule)) monotonicity = SCHEDULE_MONOTONIC; return monotonicity; } #if KMP_STATIC_STEAL_ENABLED enum { // values for steal_flag (possible states of private per-loop buffer) UNUSED = 0, CLAIMED = 1, // owner thread started initialization READY = 2, // available for stealing THIEF = 3 // finished by owner, or claimed by thief // possible state changes: // 0 -> 1 owner only, sync // 0 -> 3 thief only, sync // 1 -> 2 owner only, async // 2 -> 3 owner only, async // 3 -> 2 owner only, async // 3 -> 0 last thread finishing the loop, async }; #endif // Initialize a dispatch_private_info_template buffer for a particular // type of schedule,chunk. The loop description is found in lb (lower bound), // ub (upper bound), and st (stride). nproc is the number of threads relevant // to the scheduling (often the number of threads in a team, but not always if // hierarchical scheduling is used). tid is the id of the thread calling // the function within the group of nproc threads. It will have a value // between 0 and nproc - 1. This is often just the thread id within a team, but // is not necessarily the case when using hierarchical scheduling. // loc is the source file location of the corresponding loop // gtid is the global thread id template void __kmp_dispatch_init_algorithm(ident_t *loc, int gtid, dispatch_private_info_template *pr, enum sched_type schedule, T lb, T ub, typename traits_t::signed_t st, #if USE_ITT_BUILD kmp_uint64 *cur_chunk, #endif typename traits_t::signed_t chunk, T nproc, T tid) { typedef typename traits_t::unsigned_t UT; typedef typename traits_t::floating_t DBL; int active; T tc; kmp_info_t *th; kmp_team_t *team; int monotonicity; bool use_hier; #ifdef KMP_DEBUG typedef typename traits_t::signed_t ST; { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_init_algorithm: T#%%d called " "pr:%%p lb:%%%s ub:%%%s st:%%%s " "schedule:%%d chunk:%%%s nproc:%%%s tid:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, pr, lb, ub, st, schedule, chunk, nproc, tid)); __kmp_str_free(&buff); } #endif /* setup data */ th = __kmp_threads[gtid]; team = th->th.th_team; active = !team->t.t_serialized; #if USE_ITT_BUILD int itt_need_metadata_reporting = __itt_metadata_add_ptr && __kmp_forkjoin_frames_mode == 3 && KMP_MASTER_GTID(gtid) && th->th.th_teams_microtask == NULL && team->t.t_active_level == 1; #endif #if KMP_USE_HIER_SCHED use_hier = pr->flags.use_hier; #else use_hier = false; #endif /* Pick up the nonmonotonic/monotonic bits from the scheduling type */ monotonicity = __kmp_get_monotonicity(loc, schedule, use_hier); schedule = SCHEDULE_WITHOUT_MODIFIERS(schedule); /* Pick up the nomerge/ordered bits from the scheduling type */ if ((schedule >= kmp_nm_lower) && (schedule < kmp_nm_upper)) { pr->flags.nomerge = TRUE; schedule = (enum sched_type)(((int)schedule) - (kmp_nm_lower - kmp_sch_lower)); } else { pr->flags.nomerge = FALSE; } pr->type_size = traits_t::type_size; // remember the size of variables if (kmp_ord_lower & schedule) { pr->flags.ordered = TRUE; schedule = (enum sched_type)(((int)schedule) - (kmp_ord_lower - kmp_sch_lower)); } else { pr->flags.ordered = FALSE; } // Ordered overrides nonmonotonic if (pr->flags.ordered) { monotonicity = SCHEDULE_MONOTONIC; } if (schedule == kmp_sch_static) { schedule = __kmp_static; } else { if (schedule == kmp_sch_runtime) { // Use the scheduling specified by OMP_SCHEDULE (or __kmp_sch_default if // not specified) schedule = team->t.t_sched.r_sched_type; monotonicity = __kmp_get_monotonicity(loc, schedule, use_hier); schedule = SCHEDULE_WITHOUT_MODIFIERS(schedule); if (pr->flags.ordered) // correct monotonicity for ordered loop if needed monotonicity = SCHEDULE_MONOTONIC; // Detail the schedule if needed (global controls are differentiated // appropriately) if (schedule == kmp_sch_guided_chunked) { schedule = __kmp_guided; } else if (schedule == kmp_sch_static) { schedule = __kmp_static; } // Use the chunk size specified by OMP_SCHEDULE (or default if not // specified) chunk = team->t.t_sched.chunk; #if USE_ITT_BUILD if (cur_chunk) *cur_chunk = chunk; #endif #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_init_algorithm: T#%%d new: " "schedule:%%d chunk:%%%s\n", traits_t::spec); KD_TRACE(10, (buff, gtid, schedule, chunk)); __kmp_str_free(&buff); } #endif } else { if (schedule == kmp_sch_guided_chunked) { schedule = __kmp_guided; } if (chunk <= 0) { chunk = KMP_DEFAULT_CHUNK; } } if (schedule == kmp_sch_auto) { // mapping and differentiation: in the __kmp_do_serial_initialize() schedule = __kmp_auto; #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_init_algorithm: kmp_sch_auto: T#%%d new: " "schedule:%%d chunk:%%%s\n", traits_t::spec); KD_TRACE(10, (buff, gtid, schedule, chunk)); __kmp_str_free(&buff); } #endif } #if KMP_STATIC_STEAL_ENABLED // map nonmonotonic:dynamic to static steal if (schedule == kmp_sch_dynamic_chunked) { if (monotonicity == SCHEDULE_NONMONOTONIC) schedule = kmp_sch_static_steal; } #endif /* guided analytical not safe for too many threads */ if (schedule == kmp_sch_guided_analytical_chunked && nproc > 1 << 20) { schedule = kmp_sch_guided_iterative_chunked; KMP_WARNING(DispatchManyThreads); } if (schedule == kmp_sch_runtime_simd) { // compiler provides simd_width in the chunk parameter schedule = team->t.t_sched.r_sched_type; monotonicity = __kmp_get_monotonicity(loc, schedule, use_hier); schedule = SCHEDULE_WITHOUT_MODIFIERS(schedule); // Detail the schedule if needed (global controls are differentiated // appropriately) if (schedule == kmp_sch_static || schedule == kmp_sch_auto || schedule == __kmp_static) { schedule = kmp_sch_static_balanced_chunked; } else { if (schedule == kmp_sch_guided_chunked || schedule == __kmp_guided) { schedule = kmp_sch_guided_simd; } chunk = team->t.t_sched.chunk * chunk; } #if USE_ITT_BUILD if (cur_chunk) *cur_chunk = chunk; #endif #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_init_algorithm: T#%%d new: schedule:%%d" " chunk:%%%s\n", traits_t::spec); KD_TRACE(10, (buff, gtid, schedule, chunk)); __kmp_str_free(&buff); } #endif } pr->u.p.parm1 = chunk; } KMP_ASSERT2((kmp_sch_lower < schedule && schedule < kmp_sch_upper), "unknown scheduling type"); pr->u.p.count = 0; if (__kmp_env_consistency_check) { if (st == 0) { __kmp_error_construct(kmp_i18n_msg_CnsLoopIncrZeroProhibited, (pr->flags.ordered ? ct_pdo_ordered : ct_pdo), loc); } } // compute trip count if (st == 1) { // most common case if (ub >= lb) { tc = ub - lb + 1; } else { // ub < lb tc = 0; // zero-trip } } else if (st < 0) { if (lb >= ub) { // AC: cast to unsigned is needed for loops like (i=2B; i>-2B; i-=1B), // where the division needs to be unsigned regardless of the result type tc = (UT)(lb - ub) / (-st) + 1; } else { // lb < ub tc = 0; // zero-trip } } else { // st > 0 if (ub >= lb) { // AC: cast to unsigned is needed for loops like (i=-2B; i<2B; i+=1B), // where the division needs to be unsigned regardless of the result type tc = (UT)(ub - lb) / st + 1; } else { // ub < lb tc = 0; // zero-trip } } #if KMP_STATS_ENABLED if (KMP_MASTER_GTID(gtid)) { KMP_COUNT_VALUE(OMP_loop_dynamic_total_iterations, tc); } #endif pr->u.p.lb = lb; pr->u.p.ub = ub; pr->u.p.st = st; pr->u.p.tc = tc; #if KMP_OS_WINDOWS pr->u.p.last_upper = ub + st; #endif /* KMP_OS_WINDOWS */ /* NOTE: only the active parallel region(s) has active ordered sections */ if (active) { if (pr->flags.ordered) { pr->ordered_bumped = 0; pr->u.p.ordered_lower = 1; pr->u.p.ordered_upper = 0; } } switch (schedule) { #if KMP_STATIC_STEAL_ENABLED case kmp_sch_static_steal: { T ntc, init; KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_static_steal case\n", gtid)); ntc = (tc % chunk ? 1 : 0) + tc / chunk; if (nproc > 1 && ntc >= nproc) { KMP_COUNT_BLOCK(OMP_LOOP_STATIC_STEAL); T id = tid; T small_chunk, extras; kmp_uint32 old = UNUSED; int claimed = pr->steal_flag.compare_exchange_strong(old, CLAIMED); if (traits_t::type_size > 4) { // AC: TODO: check if 16-byte CAS available and use it to // improve performance (probably wait for explicit request // before spending time on this). // For now use dynamically allocated per-private-buffer lock, // free memory in __kmp_dispatch_next when status==0. pr->u.p.steal_lock = (kmp_lock_t *)__kmp_allocate(sizeof(kmp_lock_t)); __kmp_init_lock(pr->u.p.steal_lock); } small_chunk = ntc / nproc; extras = ntc % nproc; init = id * small_chunk + (id < extras ? id : extras); pr->u.p.count = init; if (claimed) { // are we succeeded in claiming own buffer? pr->u.p.ub = init + small_chunk + (id < extras ? 1 : 0); // Other threads will inspect steal_flag when searching for a victim. // READY means other threads may steal from this thread from now on. KMP_ATOMIC_ST_REL(&pr->steal_flag, READY); } else { // other thread has stolen whole our range KMP_DEBUG_ASSERT(pr->steal_flag == THIEF); pr->u.p.ub = init; // mark there is no iterations to work on } pr->u.p.parm2 = ntc; // save number of chunks // parm3 is the number of times to attempt stealing which is // nproc (just a heuristics, could be optimized later on). pr->u.p.parm3 = nproc; pr->u.p.parm4 = (id + 1) % nproc; // remember neighbour tid break; } else { /* too few chunks: switching to kmp_sch_dynamic_chunked */ schedule = kmp_sch_dynamic_chunked; KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d switching to " "kmp_sch_dynamic_chunked\n", gtid)); goto dynamic_init; break; } // if } // case #endif case kmp_sch_static_balanced: { T init, limit; KD_TRACE( 100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_static_balanced case\n", gtid)); if (nproc > 1) { T id = tid; if (tc < nproc) { if (id < tc) { init = id; limit = id; pr->u.p.parm1 = (id == tc - 1); /* parm1 stores *plastiter */ } else { pr->u.p.count = 1; /* means no more chunks to execute */ pr->u.p.parm1 = FALSE; break; } } else { T small_chunk = tc / nproc; T extras = tc % nproc; init = id * small_chunk + (id < extras ? id : extras); limit = init + small_chunk - (id < extras ? 0 : 1); pr->u.p.parm1 = (id == nproc - 1); } } else { if (tc > 0) { init = 0; limit = tc - 1; pr->u.p.parm1 = TRUE; } else { // zero trip count pr->u.p.count = 1; /* means no more chunks to execute */ pr->u.p.parm1 = FALSE; break; } } #if USE_ITT_BUILD // Calculate chunk for metadata report if (itt_need_metadata_reporting) if (cur_chunk) *cur_chunk = limit - init + 1; #endif if (st == 1) { pr->u.p.lb = lb + init; pr->u.p.ub = lb + limit; } else { // calculated upper bound, "ub" is user-defined upper bound T ub_tmp = lb + limit * st; pr->u.p.lb = lb + init * st; // adjust upper bound to "ub" if needed, so that MS lastprivate will match // it exactly if (st > 0) { pr->u.p.ub = (ub_tmp + st > ub ? ub : ub_tmp); } else { pr->u.p.ub = (ub_tmp + st < ub ? ub : ub_tmp); } } if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } break; } // case case kmp_sch_static_balanced_chunked: { // similar to balanced, but chunk adjusted to multiple of simd width T nth = nproc; KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d runtime(simd:static)" " -> falling-through to static_greedy\n", gtid)); schedule = kmp_sch_static_greedy; if (nth > 1) pr->u.p.parm1 = ((tc + nth - 1) / nth + chunk - 1) & ~(chunk - 1); else pr->u.p.parm1 = tc; break; } // case case kmp_sch_guided_simd: case kmp_sch_guided_iterative_chunked: { KD_TRACE( 100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_guided_iterative_chunked" " case\n", gtid)); if (nproc > 1) { if ((2L * chunk + 1) * nproc >= tc) { /* chunk size too large, switch to dynamic */ schedule = kmp_sch_dynamic_chunked; goto dynamic_init; } else { // when remaining iters become less than parm2 - switch to dynamic pr->u.p.parm2 = guided_int_param * nproc * (chunk + 1); *(double *)&pr->u.p.parm3 = guided_flt_param / (double)nproc; // may occupy parm3 and parm4 } } else { KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d falling-through to " "kmp_sch_static_greedy\n", gtid)); schedule = kmp_sch_static_greedy; /* team->t.t_nproc == 1: fall-through to kmp_sch_static_greedy */ KD_TRACE( 100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_static_greedy case\n", gtid)); pr->u.p.parm1 = tc; } // if } // case break; case kmp_sch_guided_analytical_chunked: { KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d " "kmp_sch_guided_analytical_chunked case\n", gtid)); if (nproc > 1) { if ((2L * chunk + 1) * nproc >= tc) { /* chunk size too large, switch to dynamic */ schedule = kmp_sch_dynamic_chunked; goto dynamic_init; } else { /* commonly used term: (2 nproc - 1)/(2 nproc) */ DBL x; #if KMP_USE_X87CONTROL /* Linux* OS already has 64-bit computation by default for long double, and on Windows* OS on Intel(R) 64, /Qlong_double doesn't work. On Windows* OS on IA-32 architecture, we need to set precision to 64-bit instead of the default 53-bit. Even though long double doesn't work on Windows* OS on Intel(R) 64, the resulting lack of precision is not expected to impact the correctness of the algorithm, but this has not been mathematically proven. */ // save original FPCW and set precision to 64-bit, as // Windows* OS on IA-32 architecture defaults to 53-bit unsigned int oldFpcw = _control87(0, 0); _control87(_PC_64, _MCW_PC); // 0,0x30000 #endif /* value used for comparison in solver for cross-over point */ KMP_ASSERT(tc > 0); long double target = ((long double)chunk * 2 + 1) * nproc / tc; /* crossover point--chunk indexes equal to or greater than this point switch to dynamic-style scheduling */ UT cross; /* commonly used term: (2 nproc - 1)/(2 nproc) */ x = 1.0 - 0.5 / (double)nproc; #ifdef KMP_DEBUG { // test natural alignment struct _test_a { char a; union { char b; DBL d; }; } t; ptrdiff_t natural_alignment = (ptrdiff_t)&t.b - (ptrdiff_t)&t - (ptrdiff_t)1; //__kmp_warn( " %llx %llx %lld", (long long)&t.d, (long long)&t, (long // long)natural_alignment ); KMP_DEBUG_ASSERT( (((ptrdiff_t)&pr->u.p.parm3) & (natural_alignment)) == 0); } #endif // KMP_DEBUG /* save the term in thread private dispatch structure */ *(DBL *)&pr->u.p.parm3 = x; /* solve for the crossover point to the nearest integer i for which C_i <= chunk */ { UT left, right, mid; long double p; /* estimate initial upper and lower bound */ /* doesn't matter what value right is as long as it is positive, but it affects performance of the solver */ right = 229; p = __kmp_pow(x, right); if (p > target) { do { p *= p; right <<= 1; } while (p > target && right < (1 << 27)); /* lower bound is previous (failed) estimate of upper bound */ left = right >> 1; } else { left = 0; } /* bisection root-finding method */ while (left + 1 < right) { mid = (left + right) / 2; if (__kmp_pow(x, mid) > target) { left = mid; } else { right = mid; } } // while cross = right; } /* assert sanity of computed crossover point */ KMP_ASSERT(cross && __kmp_pow(x, cross - 1) > target && __kmp_pow(x, cross) <= target); /* save the crossover point in thread private dispatch structure */ pr->u.p.parm2 = cross; // C75803 #if ((KMP_OS_LINUX || KMP_OS_WINDOWS) && KMP_ARCH_X86) && (!defined(KMP_I8)) #define GUIDED_ANALYTICAL_WORKAROUND (*(DBL *)&pr->u.p.parm3) #else #define GUIDED_ANALYTICAL_WORKAROUND (x) #endif /* dynamic-style scheduling offset */ pr->u.p.count = tc - __kmp_dispatch_guided_remaining( tc, GUIDED_ANALYTICAL_WORKAROUND, cross) - cross * chunk; #if KMP_USE_X87CONTROL // restore FPCW _control87(oldFpcw, _MCW_PC); #endif } // if } else { KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d falling-through to " "kmp_sch_static_greedy\n", gtid)); schedule = kmp_sch_static_greedy; /* team->t.t_nproc == 1: fall-through to kmp_sch_static_greedy */ pr->u.p.parm1 = tc; } // if } // case break; case kmp_sch_static_greedy: KD_TRACE( 100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_static_greedy case\n", gtid)); pr->u.p.parm1 = (nproc > 1) ? (tc + nproc - 1) / nproc : tc; break; case kmp_sch_static_chunked: case kmp_sch_dynamic_chunked: dynamic_init: if (tc == 0) break; if (pr->u.p.parm1 <= 0) pr->u.p.parm1 = KMP_DEFAULT_CHUNK; else if (pr->u.p.parm1 > tc) pr->u.p.parm1 = tc; // Store the total number of chunks to prevent integer overflow during // bounds calculations in the get next chunk routine. pr->u.p.parm2 = (tc / pr->u.p.parm1) + (tc % pr->u.p.parm1 ? 1 : 0); KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d " "kmp_sch_static_chunked/kmp_sch_dynamic_chunked cases\n", gtid)); break; case kmp_sch_trapezoidal: { /* TSS: trapezoid self-scheduling, minimum chunk_size = parm1 */ T parm1, parm2, parm3, parm4; KD_TRACE(100, ("__kmp_dispatch_init_algorithm: T#%d kmp_sch_trapezoidal case\n", gtid)); parm1 = chunk; /* F : size of the first cycle */ parm2 = (tc / (2 * nproc)); if (parm2 < 1) { parm2 = 1; } /* L : size of the last cycle. Make sure the last cycle is not larger than the first cycle. */ if (parm1 < 1) { parm1 = 1; } else if (parm1 > parm2) { parm1 = parm2; } /* N : number of cycles */ parm3 = (parm2 + parm1); parm3 = (2 * tc + parm3 - 1) / parm3; if (parm3 < 2) { parm3 = 2; } /* sigma : decreasing incr of the trapezoid */ parm4 = (parm3 - 1); parm4 = (parm2 - parm1) / parm4; // pointless check, because parm4 >= 0 always // if ( parm4 < 0 ) { // parm4 = 0; //} pr->u.p.parm1 = parm1; pr->u.p.parm2 = parm2; pr->u.p.parm3 = parm3; pr->u.p.parm4 = parm4; } // case break; default: { __kmp_fatal(KMP_MSG(UnknownSchedTypeDetected), // Primary message KMP_HNT(GetNewerLibrary), // Hint __kmp_msg_null // Variadic argument list terminator ); } break; } // switch pr->schedule = schedule; } #if KMP_USE_HIER_SCHED template inline void __kmp_dispatch_init_hier_runtime(ident_t *loc, T lb, T ub, typename traits_t::signed_t st); template <> inline void __kmp_dispatch_init_hier_runtime(ident_t *loc, kmp_int32 lb, kmp_int32 ub, kmp_int32 st) { __kmp_dispatch_init_hierarchy( loc, __kmp_hier_scheds.size, __kmp_hier_scheds.layers, __kmp_hier_scheds.scheds, __kmp_hier_scheds.small_chunks, lb, ub, st); } template <> inline void __kmp_dispatch_init_hier_runtime(ident_t *loc, kmp_uint32 lb, kmp_uint32 ub, kmp_int32 st) { __kmp_dispatch_init_hierarchy( loc, __kmp_hier_scheds.size, __kmp_hier_scheds.layers, __kmp_hier_scheds.scheds, __kmp_hier_scheds.small_chunks, lb, ub, st); } template <> inline void __kmp_dispatch_init_hier_runtime(ident_t *loc, kmp_int64 lb, kmp_int64 ub, kmp_int64 st) { __kmp_dispatch_init_hierarchy( loc, __kmp_hier_scheds.size, __kmp_hier_scheds.layers, __kmp_hier_scheds.scheds, __kmp_hier_scheds.large_chunks, lb, ub, st); } template <> inline void __kmp_dispatch_init_hier_runtime(ident_t *loc, kmp_uint64 lb, kmp_uint64 ub, kmp_int64 st) { __kmp_dispatch_init_hierarchy( loc, __kmp_hier_scheds.size, __kmp_hier_scheds.layers, __kmp_hier_scheds.scheds, __kmp_hier_scheds.large_chunks, lb, ub, st); } // free all the hierarchy scheduling memory associated with the team void __kmp_dispatch_free_hierarchies(kmp_team_t *team) { int num_disp_buff = team->t.t_max_nproc > 1 ? __kmp_dispatch_num_buffers : 2; for (int i = 0; i < num_disp_buff; ++i) { // type does not matter here so use kmp_int32 auto sh = reinterpret_cast volatile *>( &team->t.t_disp_buffer[i]); if (sh->hier) { sh->hier->deallocate(); __kmp_free(sh->hier); } } } #endif // UT - unsigned flavor of T, ST - signed flavor of T, // DBL - double if sizeof(T)==4, or long double if sizeof(T)==8 template static void __kmp_dispatch_init(ident_t *loc, int gtid, enum sched_type schedule, T lb, T ub, typename traits_t::signed_t st, typename traits_t::signed_t chunk, int push_ws) { typedef typename traits_t::unsigned_t UT; int active; kmp_info_t *th; kmp_team_t *team; kmp_uint32 my_buffer_index; dispatch_private_info_template *pr; dispatch_shared_info_template volatile *sh; KMP_BUILD_ASSERT(sizeof(dispatch_private_info_template) == sizeof(dispatch_private_info)); KMP_BUILD_ASSERT(sizeof(dispatch_shared_info_template) == sizeof(dispatch_shared_info)); __kmp_assert_valid_gtid(gtid); if (!TCR_4(__kmp_init_parallel)) __kmp_parallel_initialize(); __kmp_resume_if_soft_paused(); #if INCLUDE_SSC_MARKS SSC_MARK_DISPATCH_INIT(); #endif #ifdef KMP_DEBUG typedef typename traits_t::signed_t ST; { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_init: T#%%d called: schedule:%%d " "chunk:%%%s lb:%%%s ub:%%%s st:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, schedule, chunk, lb, ub, st)); __kmp_str_free(&buff); } #endif /* setup data */ th = __kmp_threads[gtid]; team = th->th.th_team; active = !team->t.t_serialized; th->th.th_ident = loc; // Any half-decent optimizer will remove this test when the blocks are empty // since the macros expand to nothing // when statistics are disabled. if (schedule == __kmp_static) { KMP_COUNT_BLOCK(OMP_LOOP_STATIC); } else { KMP_COUNT_BLOCK(OMP_LOOP_DYNAMIC); } #if KMP_USE_HIER_SCHED // Initialize the scheduling hierarchy if requested in OMP_SCHEDULE envirable // Hierarchical scheduling does not work with ordered, so if ordered is // detected, then revert back to threaded scheduling. bool ordered; enum sched_type my_sched = schedule; my_buffer_index = th->th.th_dispatch->th_disp_index; pr = reinterpret_cast *>( &th->th.th_dispatch ->th_disp_buffer[my_buffer_index % __kmp_dispatch_num_buffers]); my_sched = SCHEDULE_WITHOUT_MODIFIERS(my_sched); if ((my_sched >= kmp_nm_lower) && (my_sched < kmp_nm_upper)) my_sched = (enum sched_type)(((int)my_sched) - (kmp_nm_lower - kmp_sch_lower)); ordered = (kmp_ord_lower & my_sched); if (pr->flags.use_hier) { if (ordered) { KD_TRACE(100, ("__kmp_dispatch_init: T#%d ordered loop detected. " "Disabling hierarchical scheduling.\n", gtid)); pr->flags.use_hier = FALSE; } } if (schedule == kmp_sch_runtime && __kmp_hier_scheds.size > 0) { // Don't use hierarchical for ordered parallel loops and don't // use the runtime hierarchy if one was specified in the program if (!ordered && !pr->flags.use_hier) __kmp_dispatch_init_hier_runtime(loc, lb, ub, st); } #endif // KMP_USE_HIER_SCHED #if USE_ITT_BUILD kmp_uint64 cur_chunk = chunk; int itt_need_metadata_reporting = __itt_metadata_add_ptr && __kmp_forkjoin_frames_mode == 3 && KMP_MASTER_GTID(gtid) && th->th.th_teams_microtask == NULL && team->t.t_active_level == 1; #endif if (!active) { pr = reinterpret_cast *>( th->th.th_dispatch->th_disp_buffer); /* top of the stack */ } else { KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); my_buffer_index = th->th.th_dispatch->th_disp_index++; /* What happens when number of threads changes, need to resize buffer? */ pr = reinterpret_cast *>( &th->th.th_dispatch ->th_disp_buffer[my_buffer_index % __kmp_dispatch_num_buffers]); sh = reinterpret_cast volatile *>( &team->t.t_disp_buffer[my_buffer_index % __kmp_dispatch_num_buffers]); KD_TRACE(10, ("__kmp_dispatch_init: T#%d my_buffer_index:%d\n", gtid, my_buffer_index)); if (sh->buffer_index != my_buffer_index) { // too many loops in progress? KD_TRACE(100, ("__kmp_dispatch_init: T#%d before wait: my_buffer_index:%d" " sh->buffer_index:%d\n", gtid, my_buffer_index, sh->buffer_index)); __kmp_wait(&sh->buffer_index, my_buffer_index, __kmp_eq USE_ITT_BUILD_ARG(NULL)); // Note: KMP_WAIT() cannot be used there: buffer index and // my_buffer_index are *always* 32-bit integers. KD_TRACE(100, ("__kmp_dispatch_init: T#%d after wait: my_buffer_index:%d " "sh->buffer_index:%d\n", gtid, my_buffer_index, sh->buffer_index)); } } __kmp_dispatch_init_algorithm(loc, gtid, pr, schedule, lb, ub, st, #if USE_ITT_BUILD &cur_chunk, #endif chunk, (T)th->th.th_team_nproc, (T)th->th.th_info.ds.ds_tid); if (active) { if (pr->flags.ordered == 0) { th->th.th_dispatch->th_deo_fcn = __kmp_dispatch_deo_error; th->th.th_dispatch->th_dxo_fcn = __kmp_dispatch_dxo_error; } else { th->th.th_dispatch->th_deo_fcn = __kmp_dispatch_deo; th->th.th_dispatch->th_dxo_fcn = __kmp_dispatch_dxo; } th->th.th_dispatch->th_dispatch_pr_current = (dispatch_private_info_t *)pr; th->th.th_dispatch->th_dispatch_sh_current = CCAST(dispatch_shared_info_t *, (volatile dispatch_shared_info_t *)sh); #if USE_ITT_BUILD if (pr->flags.ordered) { __kmp_itt_ordered_init(gtid); } // Report loop metadata if (itt_need_metadata_reporting) { // Only report metadata by primary thread of active team at level 1 kmp_uint64 schedtype = 0; switch (schedule) { case kmp_sch_static_chunked: case kmp_sch_static_balanced: // Chunk is calculated in the switch above break; case kmp_sch_static_greedy: cur_chunk = pr->u.p.parm1; break; case kmp_sch_dynamic_chunked: schedtype = 1; break; case kmp_sch_guided_iterative_chunked: case kmp_sch_guided_analytical_chunked: case kmp_sch_guided_simd: schedtype = 2; break; default: // Should we put this case under "static"? // case kmp_sch_static_steal: schedtype = 3; break; } __kmp_itt_metadata_loop(loc, schedtype, pr->u.p.tc, cur_chunk); } #if KMP_USE_HIER_SCHED if (pr->flags.use_hier) { pr->u.p.count = 0; pr->u.p.ub = pr->u.p.lb = pr->u.p.st = pr->u.p.tc = 0; } #endif // KMP_USER_HIER_SCHED #endif /* USE_ITT_BUILD */ } #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_init: T#%%d returning: schedule:%%d ordered:%%%s " "lb:%%%s ub:%%%s" " st:%%%s tc:%%%s count:%%%s\n\tordered_lower:%%%s ordered_upper:%%%s" " parm1:%%%s parm2:%%%s parm3:%%%s parm4:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, pr->schedule, pr->flags.ordered, pr->u.p.lb, pr->u.p.ub, pr->u.p.st, pr->u.p.tc, pr->u.p.count, pr->u.p.ordered_lower, pr->u.p.ordered_upper, pr->u.p.parm1, pr->u.p.parm2, pr->u.p.parm3, pr->u.p.parm4)); __kmp_str_free(&buff); } #endif #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt_enabled.ompt_callback_work) { ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); ompt_task_info_t *task_info = __ompt_get_task_info_object(0); ompt_callbacks.ompt_callback(ompt_callback_work)( ompt_work_loop, ompt_scope_begin, &(team_info->parallel_data), &(task_info->task_data), pr->u.p.tc, OMPT_LOAD_RETURN_ADDRESS(gtid)); } #endif KMP_PUSH_PARTITIONED_TIMER(OMP_loop_dynamic); } /* For ordered loops, either __kmp_dispatch_finish() should be called after * every iteration, or __kmp_dispatch_finish_chunk() should be called after * every chunk of iterations. If the ordered section(s) were not executed * for this iteration (or every iteration in this chunk), we need to set the * ordered iteration counters so that the next thread can proceed. */ template static void __kmp_dispatch_finish(int gtid, ident_t *loc) { typedef typename traits_t::signed_t ST; __kmp_assert_valid_gtid(gtid); kmp_info_t *th = __kmp_threads[gtid]; KD_TRACE(100, ("__kmp_dispatch_finish: T#%d called\n", gtid)); if (!th->th.th_team->t.t_serialized) { dispatch_private_info_template *pr = reinterpret_cast *>( th->th.th_dispatch->th_dispatch_pr_current); dispatch_shared_info_template volatile *sh = reinterpret_cast volatile *>( th->th.th_dispatch->th_dispatch_sh_current); KMP_DEBUG_ASSERT(pr); KMP_DEBUG_ASSERT(sh); KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); if (pr->ordered_bumped) { KD_TRACE( 1000, ("__kmp_dispatch_finish: T#%d resetting ordered_bumped to zero\n", gtid)); pr->ordered_bumped = 0; } else { UT lower = pr->u.p.ordered_lower; #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_finish: T#%%d before wait: " "ordered_iteration:%%%s lower:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, sh->u.s.ordered_iteration, lower)); __kmp_str_free(&buff); } #endif __kmp_wait(&sh->u.s.ordered_iteration, lower, __kmp_ge USE_ITT_BUILD_ARG(NULL)); KMP_MB(); /* is this necessary? */ #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_finish: T#%%d after wait: " "ordered_iteration:%%%s lower:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, sh->u.s.ordered_iteration, lower)); __kmp_str_free(&buff); } #endif test_then_inc((volatile ST *)&sh->u.s.ordered_iteration); } // if } // if KD_TRACE(100, ("__kmp_dispatch_finish: T#%d returned\n", gtid)); } #ifdef KMP_GOMP_COMPAT template static void __kmp_dispatch_finish_chunk(int gtid, ident_t *loc) { typedef typename traits_t::signed_t ST; __kmp_assert_valid_gtid(gtid); kmp_info_t *th = __kmp_threads[gtid]; KD_TRACE(100, ("__kmp_dispatch_finish_chunk: T#%d called\n", gtid)); if (!th->th.th_team->t.t_serialized) { dispatch_private_info_template *pr = reinterpret_cast *>( th->th.th_dispatch->th_dispatch_pr_current); dispatch_shared_info_template volatile *sh = reinterpret_cast volatile *>( th->th.th_dispatch->th_dispatch_sh_current); KMP_DEBUG_ASSERT(pr); KMP_DEBUG_ASSERT(sh); KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); UT lower = pr->u.p.ordered_lower; UT upper = pr->u.p.ordered_upper; UT inc = upper - lower + 1; if (pr->ordered_bumped == inc) { KD_TRACE( 1000, ("__kmp_dispatch_finish: T#%d resetting ordered_bumped to zero\n", gtid)); pr->ordered_bumped = 0; } else { inc -= pr->ordered_bumped; #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_finish_chunk: T#%%d before wait: " "ordered_iteration:%%%s lower:%%%s upper:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, sh->u.s.ordered_iteration, lower, upper)); __kmp_str_free(&buff); } #endif __kmp_wait(&sh->u.s.ordered_iteration, lower, __kmp_ge USE_ITT_BUILD_ARG(NULL)); KMP_MB(); /* is this necessary? */ KD_TRACE(1000, ("__kmp_dispatch_finish_chunk: T#%d resetting " "ordered_bumped to zero\n", gtid)); pr->ordered_bumped = 0; //!!!!! TODO check if the inc should be unsigned, or signed??? #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_finish_chunk: T#%%d after wait: " "ordered_iteration:%%%s inc:%%%s lower:%%%s upper:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, sh->u.s.ordered_iteration, inc, lower, upper)); __kmp_str_free(&buff); } #endif test_then_add((volatile ST *)&sh->u.s.ordered_iteration, inc); } // } } KD_TRACE(100, ("__kmp_dispatch_finish_chunk: T#%d returned\n", gtid)); } #endif /* KMP_GOMP_COMPAT */ template int __kmp_dispatch_next_algorithm(int gtid, dispatch_private_info_template *pr, dispatch_shared_info_template volatile *sh, kmp_int32 *p_last, T *p_lb, T *p_ub, typename traits_t::signed_t *p_st, T nproc, T tid) { typedef typename traits_t::unsigned_t UT; typedef typename traits_t::signed_t ST; typedef typename traits_t::floating_t DBL; int status = 0; bool last = false; T start; ST incr; UT limit, trip, init; kmp_info_t *th = __kmp_threads[gtid]; kmp_team_t *team = th->th.th_team; KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); KMP_DEBUG_ASSERT(pr); KMP_DEBUG_ASSERT(sh); KMP_DEBUG_ASSERT(tid >= 0 && tid < nproc); #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_next_algorithm: T#%%d called pr:%%p " "sh:%%p nproc:%%%s tid:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, pr, sh, nproc, tid)); __kmp_str_free(&buff); } #endif // zero trip count if (pr->u.p.tc == 0) { KD_TRACE(10, ("__kmp_dispatch_next_algorithm: T#%d early exit trip count is " "zero status:%d\n", gtid, status)); return 0; } switch (pr->schedule) { #if KMP_STATIC_STEAL_ENABLED case kmp_sch_static_steal: { T chunk = pr->u.p.parm1; UT nchunks = pr->u.p.parm2; KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_static_steal case\n", gtid)); trip = pr->u.p.tc - 1; if (traits_t::type_size > 4) { // use lock for 8-byte induction variable. // TODO (optional): check presence and use 16-byte CAS kmp_lock_t *lck = pr->u.p.steal_lock; KMP_DEBUG_ASSERT(lck != NULL); if (pr->u.p.count < (UT)pr->u.p.ub) { KMP_DEBUG_ASSERT(pr->steal_flag == READY); __kmp_acquire_lock(lck, gtid); // try to get own chunk of iterations init = (pr->u.p.count)++; status = (init < (UT)pr->u.p.ub); __kmp_release_lock(lck, gtid); } else { status = 0; // no own chunks } if (!status) { // try to steal kmp_lock_t *lckv; // victim buffer's lock T while_limit = pr->u.p.parm3; T while_index = 0; int idx = (th->th.th_dispatch->th_disp_index - 1) % __kmp_dispatch_num_buffers; // current loop index // note: victim thread can potentially execute another loop KMP_ATOMIC_ST_REL(&pr->steal_flag, THIEF); // mark self buffer inactive while ((!status) && (while_limit != ++while_index)) { dispatch_private_info_template *v; T remaining; T victimId = pr->u.p.parm4; T oldVictimId = victimId ? victimId - 1 : nproc - 1; v = reinterpret_cast *>( &team->t.t_dispatch[victimId].th_disp_buffer[idx]); KMP_DEBUG_ASSERT(v); while ((v == pr || KMP_ATOMIC_LD_RLX(&v->steal_flag) == THIEF) && oldVictimId != victimId) { victimId = (victimId + 1) % nproc; v = reinterpret_cast *>( &team->t.t_dispatch[victimId].th_disp_buffer[idx]); KMP_DEBUG_ASSERT(v); } if (v == pr || KMP_ATOMIC_LD_RLX(&v->steal_flag) == THIEF) { continue; // try once more (nproc attempts in total) } if (KMP_ATOMIC_LD_RLX(&v->steal_flag) == UNUSED) { kmp_uint32 old = UNUSED; // try to steal whole range from inactive victim status = v->steal_flag.compare_exchange_strong(old, THIEF); if (status) { // initialize self buffer with victim's whole range of chunks T id = victimId; T small_chunk, extras; small_chunk = nchunks / nproc; // chunks per thread extras = nchunks % nproc; init = id * small_chunk + (id < extras ? id : extras); __kmp_acquire_lock(lck, gtid); pr->u.p.count = init + 1; // exclude one we execute immediately pr->u.p.ub = init + small_chunk + (id < extras ? 1 : 0); __kmp_release_lock(lck, gtid); pr->u.p.parm4 = (id + 1) % nproc; // remember neighbour tid // no need to reinitialize other thread invariants: lb, st, etc. #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d stolen chunks from T#%%d, " "count:%%%s ub:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, id, pr->u.p.count, pr->u.p.ub)); __kmp_str_free(&buff); } #endif // activate non-empty buffer and let others steal from us if (pr->u.p.count < (UT)pr->u.p.ub) KMP_ATOMIC_ST_REL(&pr->steal_flag, READY); break; } } if (KMP_ATOMIC_LD_ACQ(&v->steal_flag) != READY || v->u.p.count >= (UT)v->u.p.ub) { pr->u.p.parm4 = (victimId + 1) % nproc; // shift start victim tid continue; // no chunks to steal, try next victim } lckv = v->u.p.steal_lock; KMP_ASSERT(lckv != NULL); __kmp_acquire_lock(lckv, gtid); limit = v->u.p.ub; // keep initial ub if (v->u.p.count >= limit) { __kmp_release_lock(lckv, gtid); pr->u.p.parm4 = (victimId + 1) % nproc; // shift start victim tid continue; // no chunks to steal, try next victim } // stealing succeded, reduce victim's ub by 1/4 of undone chunks // TODO: is this heuristics good enough?? remaining = limit - v->u.p.count; if (remaining > 7) { // steal 1/4 of remaining KMP_COUNT_DEVELOPER_VALUE(FOR_static_steal_stolen, remaining >> 2); init = (v->u.p.ub -= (remaining >> 2)); } else { // steal 1 chunk of 1..7 remaining KMP_COUNT_DEVELOPER_VALUE(FOR_static_steal_stolen, 1); init = (v->u.p.ub -= 1); } __kmp_release_lock(lckv, gtid); #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d stolen chunks from T#%%d, " "count:%%%s ub:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, victimId, init, limit)); __kmp_str_free(&buff); } #endif KMP_DEBUG_ASSERT(init + 1 <= limit); pr->u.p.parm4 = victimId; // remember victim to steal from status = 1; // now update own count and ub with stolen range excluding init chunk __kmp_acquire_lock(lck, gtid); pr->u.p.count = init + 1; pr->u.p.ub = limit; __kmp_release_lock(lck, gtid); // activate non-empty buffer and let others steal from us if (init + 1 < limit) KMP_ATOMIC_ST_REL(&pr->steal_flag, READY); } // while (search for victim) } // if (try to find victim and steal) } else { // 4-byte induction variable, use 8-byte CAS for pair (count, ub) // as all operations on pair (count, ub) must be done atomically typedef union { struct { UT count; T ub; } p; kmp_int64 b; } union_i4; union_i4 vold, vnew; if (pr->u.p.count < (UT)pr->u.p.ub) { KMP_DEBUG_ASSERT(pr->steal_flag == READY); vold.b = *(volatile kmp_int64 *)(&pr->u.p.count); vnew.b = vold.b; vnew.p.count++; // get chunk from head of self range while (!KMP_COMPARE_AND_STORE_REL64( (volatile kmp_int64 *)&pr->u.p.count, *VOLATILE_CAST(kmp_int64 *) & vold.b, *VOLATILE_CAST(kmp_int64 *) & vnew.b)) { KMP_CPU_PAUSE(); vold.b = *(volatile kmp_int64 *)(&pr->u.p.count); vnew.b = vold.b; vnew.p.count++; } init = vold.p.count; status = (init < (UT)vold.p.ub); } else { status = 0; // no own chunks } if (!status) { // try to steal T while_limit = pr->u.p.parm3; T while_index = 0; int idx = (th->th.th_dispatch->th_disp_index - 1) % __kmp_dispatch_num_buffers; // current loop index // note: victim thread can potentially execute another loop KMP_ATOMIC_ST_REL(&pr->steal_flag, THIEF); // mark self buffer inactive while ((!status) && (while_limit != ++while_index)) { dispatch_private_info_template *v; T remaining; T victimId = pr->u.p.parm4; T oldVictimId = victimId ? victimId - 1 : nproc - 1; v = reinterpret_cast *>( &team->t.t_dispatch[victimId].th_disp_buffer[idx]); KMP_DEBUG_ASSERT(v); while ((v == pr || KMP_ATOMIC_LD_RLX(&v->steal_flag) == THIEF) && oldVictimId != victimId) { victimId = (victimId + 1) % nproc; v = reinterpret_cast *>( &team->t.t_dispatch[victimId].th_disp_buffer[idx]); KMP_DEBUG_ASSERT(v); } if (v == pr || KMP_ATOMIC_LD_RLX(&v->steal_flag) == THIEF) { continue; // try once more (nproc attempts in total) } if (KMP_ATOMIC_LD_RLX(&v->steal_flag) == UNUSED) { kmp_uint32 old = UNUSED; // try to steal whole range from inactive victim status = v->steal_flag.compare_exchange_strong(old, THIEF); if (status) { // initialize self buffer with victim's whole range of chunks T id = victimId; T small_chunk, extras; small_chunk = nchunks / nproc; // chunks per thread extras = nchunks % nproc; init = id * small_chunk + (id < extras ? id : extras); vnew.p.count = init + 1; vnew.p.ub = init + small_chunk + (id < extras ? 1 : 0); // write pair (count, ub) at once atomically #if KMP_ARCH_X86 KMP_XCHG_FIXED64((volatile kmp_int64 *)(&pr->u.p.count), vnew.b); #else *(volatile kmp_int64 *)(&pr->u.p.count) = vnew.b; #endif pr->u.p.parm4 = (id + 1) % nproc; // remember neighbour tid // no need to initialize other thread invariants: lb, st, etc. #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d stolen chunks from T#%%d, " "count:%%%s ub:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, id, pr->u.p.count, pr->u.p.ub)); __kmp_str_free(&buff); } #endif // activate non-empty buffer and let others steal from us if (pr->u.p.count < (UT)pr->u.p.ub) KMP_ATOMIC_ST_REL(&pr->steal_flag, READY); break; } } while (1) { // CAS loop with check if victim still has enough chunks // many threads may be stealing concurrently from same victim vold.b = *(volatile kmp_int64 *)(&v->u.p.count); if (KMP_ATOMIC_LD_ACQ(&v->steal_flag) != READY || vold.p.count >= (UT)vold.p.ub) { pr->u.p.parm4 = (victimId + 1) % nproc; // shift start victim id break; // no chunks to steal, try next victim } vnew.b = vold.b; remaining = vold.p.ub - vold.p.count; // try to steal 1/4 of remaining // TODO: is this heuristics good enough?? if (remaining > 7) { vnew.p.ub -= remaining >> 2; // steal from tail of victim's range } else { vnew.p.ub -= 1; // steal 1 chunk of 1..7 remaining } KMP_DEBUG_ASSERT(vnew.p.ub * (UT)chunk <= trip); if (KMP_COMPARE_AND_STORE_REL64( (volatile kmp_int64 *)&v->u.p.count, *VOLATILE_CAST(kmp_int64 *) & vold.b, *VOLATILE_CAST(kmp_int64 *) & vnew.b)) { // stealing succedded #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d stolen chunks from T#%%d, " "count:%%%s ub:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, victimId, vnew.p.ub, vold.p.ub)); __kmp_str_free(&buff); } #endif KMP_COUNT_DEVELOPER_VALUE(FOR_static_steal_stolen, vold.p.ub - vnew.p.ub); status = 1; pr->u.p.parm4 = victimId; // keep victim id // now update own count and ub init = vnew.p.ub; vold.p.count = init + 1; #if KMP_ARCH_X86 KMP_XCHG_FIXED64((volatile kmp_int64 *)(&pr->u.p.count), vold.b); #else *(volatile kmp_int64 *)(&pr->u.p.count) = vold.b; #endif // activate non-empty buffer and let others steal from us if (vold.p.count < (UT)vold.p.ub) KMP_ATOMIC_ST_REL(&pr->steal_flag, READY); break; } // if (check CAS result) KMP_CPU_PAUSE(); // CAS failed, repeatedly attempt } // while (try to steal from particular victim) } // while (search for victim) } // if (try to find victim and steal) } // if (4-byte induction variable) if (!status) { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } else { start = pr->u.p.lb; init *= chunk; limit = chunk + init - 1; incr = pr->u.p.st; KMP_COUNT_DEVELOPER_VALUE(FOR_static_steal_chunks, 1); KMP_DEBUG_ASSERT(init <= trip); // keep track of done chunks for possible early exit from stealing // TODO: count executed chunks locally with rare update of shared location // test_then_inc((volatile ST *)&sh->u.s.iteration); if ((last = (limit >= trip)) != 0) limit = trip; if (p_st != NULL) *p_st = incr; if (incr == 1) { *p_lb = start + init; *p_ub = start + limit; } else { *p_lb = start + init * incr; *p_ub = start + limit * incr; } } // if break; } // case #endif // KMP_STATIC_STEAL_ENABLED case kmp_sch_static_balanced: { KD_TRACE( 10, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_static_balanced case\n", gtid)); /* check if thread has any iteration to do */ if ((status = !pr->u.p.count) != 0) { pr->u.p.count = 1; *p_lb = pr->u.p.lb; *p_ub = pr->u.p.ub; last = (pr->u.p.parm1 != 0); if (p_st != NULL) *p_st = pr->u.p.st; } else { /* no iterations to do */ pr->u.p.lb = pr->u.p.ub + pr->u.p.st; } } // case break; case kmp_sch_static_greedy: /* original code for kmp_sch_static_greedy was merged here */ case kmp_sch_static_chunked: { T parm1; KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d " "kmp_sch_static_[affinity|chunked] case\n", gtid)); parm1 = pr->u.p.parm1; trip = pr->u.p.tc - 1; init = parm1 * (pr->u.p.count + tid); if ((status = (init <= trip)) != 0) { start = pr->u.p.lb; incr = pr->u.p.st; limit = parm1 + init - 1; if ((last = (limit >= trip)) != 0) limit = trip; if (p_st != NULL) *p_st = incr; pr->u.p.count += nproc; if (incr == 1) { *p_lb = start + init; *p_ub = start + limit; } else { *p_lb = start + init * incr; *p_ub = start + limit * incr; } if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } // if } // if } // case break; case kmp_sch_dynamic_chunked: { UT chunk_number; UT chunk_size = pr->u.p.parm1; UT nchunks = pr->u.p.parm2; KD_TRACE( 100, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_dynamic_chunked case\n", gtid)); chunk_number = test_then_inc_acq((volatile ST *)&sh->u.s.iteration); status = (chunk_number < nchunks); if (!status) { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } else { init = chunk_size * chunk_number; trip = pr->u.p.tc - 1; start = pr->u.p.lb; incr = pr->u.p.st; if ((last = (trip - init < (UT)chunk_size))) limit = trip; else limit = chunk_size + init - 1; if (p_st != NULL) *p_st = incr; if (incr == 1) { *p_lb = start + init; *p_ub = start + limit; } else { *p_lb = start + init * incr; *p_ub = start + limit * incr; } if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } // if } // if } // case break; case kmp_sch_guided_iterative_chunked: { T chunkspec = pr->u.p.parm1; KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_guided_chunked " "iterative case\n", gtid)); trip = pr->u.p.tc; // Start atomic part of calculations while (1) { ST remaining; // signed, because can be < 0 init = sh->u.s.iteration; // shared value remaining = trip - init; if (remaining <= 0) { // AC: need to compare with 0 first // nothing to do, don't try atomic op status = 0; break; } if ((T)remaining < pr->u.p.parm2) { // compare with K*nproc*(chunk+1), K=2 by default // use dynamic-style schedule // atomically increment iterations, get old value init = test_then_add(RCAST(volatile ST *, &sh->u.s.iteration), (ST)chunkspec); remaining = trip - init; if (remaining <= 0) { status = 0; // all iterations got by other threads } else { // got some iterations to work on status = 1; if ((T)remaining > chunkspec) { limit = init + chunkspec - 1; } else { last = true; // the last chunk limit = init + remaining - 1; } // if } // if break; } // if limit = init + (UT)((double)remaining * *(double *)&pr->u.p.parm3); // divide by K*nproc if (compare_and_swap(RCAST(volatile ST *, &sh->u.s.iteration), (ST)init, (ST)limit)) { // CAS was successful, chunk obtained status = 1; --limit; break; } // if } // while if (status != 0) { start = pr->u.p.lb; incr = pr->u.p.st; if (p_st != NULL) *p_st = incr; *p_lb = start + init * incr; *p_ub = start + limit * incr; if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } // if } else { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } // if } // case break; case kmp_sch_guided_simd: { // same as iterative but curr-chunk adjusted to be multiple of given // chunk T chunk = pr->u.p.parm1; KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_guided_simd case\n", gtid)); trip = pr->u.p.tc; // Start atomic part of calculations while (1) { ST remaining; // signed, because can be < 0 init = sh->u.s.iteration; // shared value remaining = trip - init; if (remaining <= 0) { // AC: need to compare with 0 first status = 0; // nothing to do, don't try atomic op break; } KMP_DEBUG_ASSERT(chunk && init % chunk == 0); // compare with K*nproc*(chunk+1), K=2 by default if ((T)remaining < pr->u.p.parm2) { // use dynamic-style schedule // atomically increment iterations, get old value init = test_then_add(RCAST(volatile ST *, &sh->u.s.iteration), (ST)chunk); remaining = trip - init; if (remaining <= 0) { status = 0; // all iterations got by other threads } else { // got some iterations to work on status = 1; if ((T)remaining > chunk) { limit = init + chunk - 1; } else { last = true; // the last chunk limit = init + remaining - 1; } // if } // if break; } // if // divide by K*nproc UT span; __kmp_type_convert((double)remaining * (*(double *)&pr->u.p.parm3), &span); UT rem = span % chunk; if (rem) // adjust so that span%chunk == 0 span += chunk - rem; limit = init + span; if (compare_and_swap(RCAST(volatile ST *, &sh->u.s.iteration), (ST)init, (ST)limit)) { // CAS was successful, chunk obtained status = 1; --limit; break; } // if } // while if (status != 0) { start = pr->u.p.lb; incr = pr->u.p.st; if (p_st != NULL) *p_st = incr; *p_lb = start + init * incr; *p_ub = start + limit * incr; if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } // if } else { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } // if } // case break; case kmp_sch_guided_analytical_chunked: { T chunkspec = pr->u.p.parm1; UT chunkIdx; #if KMP_USE_X87CONTROL /* for storing original FPCW value for Windows* OS on IA-32 architecture 8-byte version */ unsigned int oldFpcw; unsigned int fpcwSet = 0; #endif KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d " "kmp_sch_guided_analytical_chunked case\n", gtid)); trip = pr->u.p.tc; KMP_DEBUG_ASSERT(nproc > 1); KMP_DEBUG_ASSERT((2UL * chunkspec + 1) * (UT)nproc < trip); while (1) { /* this while loop is a safeguard against unexpected zero chunk sizes */ chunkIdx = test_then_inc_acq((volatile ST *)&sh->u.s.iteration); if (chunkIdx >= (UT)pr->u.p.parm2) { --trip; /* use dynamic-style scheduling */ init = chunkIdx * chunkspec + pr->u.p.count; /* need to verify init > 0 in case of overflow in the above * calculation */ if ((status = (init > 0 && init <= trip)) != 0) { limit = init + chunkspec - 1; if ((last = (limit >= trip)) != 0) limit = trip; } break; } else { /* use exponential-style scheduling */ /* The following check is to workaround the lack of long double precision on Windows* OS. This check works around the possible effect that init != 0 for chunkIdx == 0. */ #if KMP_USE_X87CONTROL /* If we haven't already done so, save original FPCW and set precision to 64-bit, as Windows* OS on IA-32 architecture defaults to 53-bit */ if (!fpcwSet) { oldFpcw = _control87(0, 0); _control87(_PC_64, _MCW_PC); fpcwSet = 0x30000; } #endif if (chunkIdx) { init = __kmp_dispatch_guided_remaining( trip, *(DBL *)&pr->u.p.parm3, chunkIdx); KMP_DEBUG_ASSERT(init); init = trip - init; } else init = 0; limit = trip - __kmp_dispatch_guided_remaining( trip, *(DBL *)&pr->u.p.parm3, chunkIdx + 1); KMP_ASSERT(init <= limit); if (init < limit) { KMP_DEBUG_ASSERT(limit <= trip); --limit; status = 1; break; } // if } // if } // while (1) #if KMP_USE_X87CONTROL /* restore FPCW if necessary AC: check fpcwSet flag first because oldFpcw can be uninitialized here */ if (fpcwSet && (oldFpcw & fpcwSet)) _control87(oldFpcw, _MCW_PC); #endif if (status != 0) { start = pr->u.p.lb; incr = pr->u.p.st; if (p_st != NULL) *p_st = incr; *p_lb = start + init * incr; *p_ub = start + limit * incr; if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } } else { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } } // case break; case kmp_sch_trapezoidal: { UT index; T parm2 = pr->u.p.parm2; T parm3 = pr->u.p.parm3; T parm4 = pr->u.p.parm4; KD_TRACE(100, ("__kmp_dispatch_next_algorithm: T#%d kmp_sch_trapezoidal case\n", gtid)); index = test_then_inc((volatile ST *)&sh->u.s.iteration); init = (index * ((2 * parm2) - (index - 1) * parm4)) / 2; trip = pr->u.p.tc - 1; if ((status = ((T)index < parm3 && init <= trip)) == 0) { *p_lb = 0; *p_ub = 0; if (p_st != NULL) *p_st = 0; } else { start = pr->u.p.lb; limit = ((index + 1) * (2 * parm2 - index * parm4)) / 2 - 1; incr = pr->u.p.st; if ((last = (limit >= trip)) != 0) limit = trip; if (p_st != NULL) *p_st = incr; if (incr == 1) { *p_lb = start + init; *p_ub = start + limit; } else { *p_lb = start + init * incr; *p_ub = start + limit * incr; } if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; } // if } // if } // case break; default: { status = 0; // to avoid complaints on uninitialized variable use __kmp_fatal(KMP_MSG(UnknownSchedTypeDetected), // Primary message KMP_HNT(GetNewerLibrary), // Hint __kmp_msg_null // Variadic argument list terminator ); } break; } // switch if (p_last) *p_last = last; #ifdef KMP_DEBUG if (pr->flags.ordered) { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_next_algorithm: T#%%d " "ordered_lower:%%%s ordered_upper:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, pr->u.p.ordered_lower, pr->u.p.ordered_upper)); __kmp_str_free(&buff); } { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next_algorithm: T#%%d exit status:%%d p_last:%%d " "p_lb:%%%s p_ub:%%%s p_st:%%%s\n", traits_t::spec, traits_t::spec, traits_t::spec); KMP_DEBUG_ASSERT(p_last); KMP_DEBUG_ASSERT(p_st); KD_TRACE(10, (buff, gtid, status, *p_last, *p_lb, *p_ub, *p_st)); __kmp_str_free(&buff); } #endif return status; } /* Define a macro for exiting __kmp_dispatch_next(). If status is 0 (no more work), then tell OMPT the loop is over. In some cases kmp_dispatch_fini() is not called. */ #if OMPT_SUPPORT && OMPT_OPTIONAL #define OMPT_LOOP_END \ if (status == 0) { \ if (ompt_enabled.ompt_callback_work) { \ ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); \ ompt_task_info_t *task_info = __ompt_get_task_info_object(0); \ ompt_callbacks.ompt_callback(ompt_callback_work)( \ ompt_work_loop, ompt_scope_end, &(team_info->parallel_data), \ &(task_info->task_data), 0, codeptr); \ } \ } #define OMPT_LOOP_DISPATCH(lb, ub, st, status) \ if (ompt_enabled.ompt_callback_dispatch && status) { \ ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); \ ompt_task_info_t *task_info = __ompt_get_task_info_object(0); \ ompt_dispatch_chunk_t chunk; \ ompt_data_t instance = ompt_data_none; \ OMPT_GET_DISPATCH_CHUNK(chunk, lb, ub, st); \ instance.ptr = &chunk; \ ompt_callbacks.ompt_callback(ompt_callback_dispatch)( \ &(team_info->parallel_data), &(task_info->task_data), \ ompt_dispatch_ws_loop_chunk, instance); \ } // TODO: implement count #else #define OMPT_LOOP_END // no-op #define OMPT_LOOP_DISPATCH(lb, ub, st, status) // no-op #endif #if KMP_STATS_ENABLED #define KMP_STATS_LOOP_END \ { \ kmp_int64 u, l, t, i; \ l = (kmp_int64)(*p_lb); \ u = (kmp_int64)(*p_ub); \ i = (kmp_int64)(pr->u.p.st); \ if (status == 0) { \ t = 0; \ KMP_POP_PARTITIONED_TIMER(); \ } else if (i == 1) { \ if (u >= l) \ t = u - l + 1; \ else \ t = 0; \ } else if (i < 0) { \ if (l >= u) \ t = (l - u) / (-i) + 1; \ else \ t = 0; \ } else { \ if (u >= l) \ t = (u - l) / i + 1; \ else \ t = 0; \ } \ KMP_COUNT_VALUE(OMP_loop_dynamic_iterations, t); \ } #else #define KMP_STATS_LOOP_END /* Nothing */ #endif template static int __kmp_dispatch_next(ident_t *loc, int gtid, kmp_int32 *p_last, T *p_lb, T *p_ub, typename traits_t::signed_t *p_st #if OMPT_SUPPORT && OMPT_OPTIONAL , void *codeptr #endif ) { typedef typename traits_t::unsigned_t UT; typedef typename traits_t::signed_t ST; // This is potentially slightly misleading, schedule(runtime) will appear here // even if the actual runtime schedule is static. (Which points out a // disadvantage of schedule(runtime): even when static scheduling is used it // costs more than a compile time choice to use static scheduling would.) KMP_TIME_PARTITIONED_BLOCK(OMP_loop_dynamic_scheduling); int status; dispatch_private_info_template *pr; __kmp_assert_valid_gtid(gtid); kmp_info_t *th = __kmp_threads[gtid]; kmp_team_t *team = th->th.th_team; KMP_DEBUG_ASSERT(p_lb && p_ub && p_st); // AC: these cannot be NULL KD_TRACE( 1000, ("__kmp_dispatch_next: T#%d called p_lb:%p p_ub:%p p_st:%p p_last: %p\n", gtid, p_lb, p_ub, p_st, p_last)); if (team->t.t_serialized) { /* NOTE: serialize this dispatch because we are not at the active level */ pr = reinterpret_cast *>( th->th.th_dispatch->th_disp_buffer); /* top of the stack */ KMP_DEBUG_ASSERT(pr); if ((status = (pr->u.p.tc != 0)) == 0) { *p_lb = 0; *p_ub = 0; // if ( p_last != NULL ) // *p_last = 0; if (p_st != NULL) *p_st = 0; if (__kmp_env_consistency_check) { if (pr->pushed_ws != ct_none) { pr->pushed_ws = __kmp_pop_workshare(gtid, pr->pushed_ws, loc); } } } else if (pr->flags.nomerge) { kmp_int32 last; T start; UT limit, trip, init; ST incr; T chunk = pr->u.p.parm1; KD_TRACE(100, ("__kmp_dispatch_next: T#%d kmp_sch_dynamic_chunked case\n", gtid)); init = chunk * pr->u.p.count++; trip = pr->u.p.tc - 1; if ((status = (init <= trip)) == 0) { *p_lb = 0; *p_ub = 0; // if ( p_last != NULL ) // *p_last = 0; if (p_st != NULL) *p_st = 0; if (__kmp_env_consistency_check) { if (pr->pushed_ws != ct_none) { pr->pushed_ws = __kmp_pop_workshare(gtid, pr->pushed_ws, loc); } } } else { start = pr->u.p.lb; limit = chunk + init - 1; incr = pr->u.p.st; if ((last = (limit >= trip)) != 0) { limit = trip; #if KMP_OS_WINDOWS pr->u.p.last_upper = pr->u.p.ub; #endif /* KMP_OS_WINDOWS */ } if (p_last != NULL) *p_last = last; if (p_st != NULL) *p_st = incr; if (incr == 1) { *p_lb = start + init; *p_ub = start + limit; } else { *p_lb = start + init * incr; *p_ub = start + limit * incr; } if (pr->flags.ordered) { pr->u.p.ordered_lower = init; pr->u.p.ordered_upper = limit; #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmp_dispatch_next: T#%%d " "ordered_lower:%%%s ordered_upper:%%%s\n", traits_t::spec, traits_t::spec); KD_TRACE(1000, (buff, gtid, pr->u.p.ordered_lower, pr->u.p.ordered_upper)); __kmp_str_free(&buff); } #endif } // if } // if } else { pr->u.p.tc = 0; *p_lb = pr->u.p.lb; *p_ub = pr->u.p.ub; #if KMP_OS_WINDOWS pr->u.p.last_upper = *p_ub; #endif /* KMP_OS_WINDOWS */ if (p_last != NULL) *p_last = TRUE; if (p_st != NULL) *p_st = pr->u.p.st; } // if #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d serialized case: p_lb:%%%s " "p_ub:%%%s p_st:%%%s p_last:%%p %%d returning:%%d\n", traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, *p_lb, *p_ub, *p_st, p_last, (p_last ? *p_last : 0), status)); __kmp_str_free(&buff); } #endif #if INCLUDE_SSC_MARKS SSC_MARK_DISPATCH_NEXT(); #endif OMPT_LOOP_DISPATCH(*p_lb, *p_ub, pr->u.p.st, status); OMPT_LOOP_END; KMP_STATS_LOOP_END; return status; } else { kmp_int32 last = 0; dispatch_shared_info_template volatile *sh; KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); pr = reinterpret_cast *>( th->th.th_dispatch->th_dispatch_pr_current); KMP_DEBUG_ASSERT(pr); sh = reinterpret_cast volatile *>( th->th.th_dispatch->th_dispatch_sh_current); KMP_DEBUG_ASSERT(sh); #if KMP_USE_HIER_SCHED if (pr->flags.use_hier) status = sh->hier->next(loc, gtid, pr, &last, p_lb, p_ub, p_st); else #endif // KMP_USE_HIER_SCHED status = __kmp_dispatch_next_algorithm(gtid, pr, sh, &last, p_lb, p_ub, p_st, th->th.th_team_nproc, th->th.th_info.ds.ds_tid); // status == 0: no more iterations to execute if (status == 0) { ST num_done; num_done = test_then_inc(&sh->u.s.num_done); #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d increment num_done:%%%s\n", traits_t::spec); KD_TRACE(10, (buff, gtid, sh->u.s.num_done)); __kmp_str_free(&buff); } #endif #if KMP_USE_HIER_SCHED pr->flags.use_hier = FALSE; #endif if (num_done == th->th.th_team_nproc - 1) { #if KMP_STATIC_STEAL_ENABLED if (pr->schedule == kmp_sch_static_steal) { int i; int idx = (th->th.th_dispatch->th_disp_index - 1) % __kmp_dispatch_num_buffers; // current loop index // loop complete, safe to destroy locks used for stealing for (i = 0; i < th->th.th_team_nproc; ++i) { dispatch_private_info_template *buf = reinterpret_cast *>( &team->t.t_dispatch[i].th_disp_buffer[idx]); KMP_ASSERT(buf->steal_flag == THIEF); // buffer must be inactive KMP_ATOMIC_ST_RLX(&buf->steal_flag, UNUSED); if (traits_t::type_size > 4) { // destroy locks used for stealing kmp_lock_t *lck = buf->u.p.steal_lock; KMP_ASSERT(lck != NULL); __kmp_destroy_lock(lck); __kmp_free(lck); buf->u.p.steal_lock = NULL; } } } #endif /* NOTE: release shared buffer to be reused */ KMP_MB(); /* Flush all pending memory write invalidates. */ sh->u.s.num_done = 0; sh->u.s.iteration = 0; /* TODO replace with general release procedure? */ if (pr->flags.ordered) { sh->u.s.ordered_iteration = 0; } sh->buffer_index += __kmp_dispatch_num_buffers; KD_TRACE(100, ("__kmp_dispatch_next: T#%d change buffer_index:%d\n", gtid, sh->buffer_index)); KMP_MB(); /* Flush all pending memory write invalidates. */ } // if if (__kmp_env_consistency_check) { if (pr->pushed_ws != ct_none) { pr->pushed_ws = __kmp_pop_workshare(gtid, pr->pushed_ws, loc); } } th->th.th_dispatch->th_deo_fcn = NULL; th->th.th_dispatch->th_dxo_fcn = NULL; th->th.th_dispatch->th_dispatch_sh_current = NULL; th->th.th_dispatch->th_dispatch_pr_current = NULL; } // if (status == 0) #if KMP_OS_WINDOWS else if (last) { pr->u.p.last_upper = pr->u.p.ub; } #endif /* KMP_OS_WINDOWS */ if (p_last != NULL && status != 0) *p_last = last; } // if #ifdef KMP_DEBUG { char *buff; // create format specifiers before the debug output buff = __kmp_str_format( "__kmp_dispatch_next: T#%%d normal case: " "p_lb:%%%s p_ub:%%%s p_st:%%%s p_last:%%p (%%d) returning:%%d\n", traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(10, (buff, gtid, *p_lb, *p_ub, p_st ? *p_st : 0, p_last, (p_last ? *p_last : 0), status)); __kmp_str_free(&buff); } #endif #if INCLUDE_SSC_MARKS SSC_MARK_DISPATCH_NEXT(); #endif OMPT_LOOP_DISPATCH(*p_lb, *p_ub, pr->u.p.st, status); OMPT_LOOP_END; KMP_STATS_LOOP_END; return status; } /*! @ingroup WORK_SHARING @param loc source location information @param global_tid global thread number @return Zero if the parallel region is not active and this thread should execute all sections, non-zero otherwise. Beginning of sections construct. There are no implicit barriers in the "sections" calls, rather the compiler should introduce an explicit barrier if it is required. This implementation is based on __kmp_dispatch_init, using same constructs for shared data (we can't have sections nested directly in omp for loop, there should be a parallel region in between) */ kmp_int32 __kmpc_sections_init(ident_t *loc, kmp_int32 gtid) { int active; kmp_info_t *th; kmp_team_t *team; kmp_uint32 my_buffer_index; dispatch_shared_info_template volatile *sh; KMP_DEBUG_ASSERT(__kmp_init_serial); if (!TCR_4(__kmp_init_parallel)) __kmp_parallel_initialize(); __kmp_resume_if_soft_paused(); /* setup data */ th = __kmp_threads[gtid]; team = th->th.th_team; active = !team->t.t_serialized; th->th.th_ident = loc; KMP_COUNT_BLOCK(OMP_SECTIONS); KD_TRACE(10, ("__kmpc_sections: called by T#%d\n", gtid)); if (active) { // Setup sections in the same way as dynamic scheduled loops. // We need one shared data: which section is to execute next. // (in case parallel is not active, all sections will be executed on the // same thread) KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); my_buffer_index = th->th.th_dispatch->th_disp_index++; // reuse shared data structures from dynamic sched loops: sh = reinterpret_cast volatile *>( &team->t.t_disp_buffer[my_buffer_index % __kmp_dispatch_num_buffers]); KD_TRACE(10, ("__kmpc_sections_init: T#%d my_buffer_index:%d\n", gtid, my_buffer_index)); th->th.th_dispatch->th_deo_fcn = __kmp_dispatch_deo_error; th->th.th_dispatch->th_dxo_fcn = __kmp_dispatch_dxo_error; KD_TRACE(100, ("__kmpc_sections_init: T#%d before wait: my_buffer_index:%d " "sh->buffer_index:%d\n", gtid, my_buffer_index, sh->buffer_index)); __kmp_wait(&sh->buffer_index, my_buffer_index, __kmp_eq USE_ITT_BUILD_ARG(NULL)); // Note: KMP_WAIT() cannot be used there: buffer index and // my_buffer_index are *always* 32-bit integers. KMP_MB(); KD_TRACE(100, ("__kmpc_sections_init: T#%d after wait: my_buffer_index:%d " "sh->buffer_index:%d\n", gtid, my_buffer_index, sh->buffer_index)); th->th.th_dispatch->th_dispatch_pr_current = nullptr; // sections construct doesn't need private data th->th.th_dispatch->th_dispatch_sh_current = CCAST(dispatch_shared_info_t *, (volatile dispatch_shared_info_t *)sh); } #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt_enabled.ompt_callback_work) { ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); ompt_task_info_t *task_info = __ompt_get_task_info_object(0); ompt_callbacks.ompt_callback(ompt_callback_work)( ompt_work_sections, ompt_scope_begin, &(team_info->parallel_data), &(task_info->task_data), 0, OMPT_GET_RETURN_ADDRESS(0)); } #endif KMP_PUSH_PARTITIONED_TIMER(OMP_sections); return active; } /*! @ingroup WORK_SHARING @param loc source location information @param global_tid global thread number @param numberOfSections number of sections in the 'sections' construct @return unsigned [from 0 to n) - number (id) of the section to execute next on this thread. n (or any other number not in range) - nothing to execute on this thread */ kmp_int32 __kmpc_next_section(ident_t *loc, kmp_int32 gtid, kmp_int32 numberOfSections) { KMP_TIME_PARTITIONED_BLOCK(OMP_sections_overhead); kmp_info_t *th = __kmp_threads[gtid]; #ifdef KMP_DEBUG kmp_team_t *team = th->th.th_team; #endif KD_TRACE(1000, ("__kmp_dispatch_next: T#%d; number of sections:%d\n", gtid, numberOfSections)); // For serialized case we should not call this function: KMP_DEBUG_ASSERT(!team->t.t_serialized); dispatch_shared_info_template volatile *sh; KMP_DEBUG_ASSERT(th->th.th_dispatch == &th->th.th_team->t.t_dispatch[th->th.th_info.ds.ds_tid]); KMP_DEBUG_ASSERT(!(th->th.th_dispatch->th_dispatch_pr_current)); sh = reinterpret_cast volatile *>( th->th.th_dispatch->th_dispatch_sh_current); KMP_DEBUG_ASSERT(sh); kmp_int32 sectionIndex = 0; bool moreSectionsToExecute = true; // Find section to execute: sectionIndex = test_then_inc((kmp_int32 *)&sh->u.s.iteration); if (sectionIndex >= numberOfSections) { moreSectionsToExecute = false; } // status == 0: no more sections to execute; // OMPTODO: __kmpc_end_sections could be bypassed? if (!moreSectionsToExecute) { kmp_int32 num_done; num_done = test_then_inc((kmp_int32 *)(&sh->u.s.num_done)); if (num_done == th->th.th_team_nproc - 1) { /* NOTE: release this buffer to be reused */ KMP_MB(); /* Flush all pending memory write invalidates. */ sh->u.s.num_done = 0; sh->u.s.iteration = 0; KMP_MB(); /* Flush all pending memory write invalidates. */ sh->buffer_index += __kmp_dispatch_num_buffers; KD_TRACE(100, ("__kmpc_next_section: T#%d change buffer_index:%d\n", gtid, sh->buffer_index)); KMP_MB(); /* Flush all pending memory write invalidates. */ } // if th->th.th_dispatch->th_deo_fcn = NULL; th->th.th_dispatch->th_dxo_fcn = NULL; th->th.th_dispatch->th_dispatch_sh_current = NULL; th->th.th_dispatch->th_dispatch_pr_current = NULL; #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt_enabled.ompt_callback_dispatch) { ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); ompt_task_info_t *task_info = __ompt_get_task_info_object(0); ompt_data_t instance = ompt_data_none; instance.ptr = OMPT_GET_RETURN_ADDRESS(0); ompt_callbacks.ompt_callback(ompt_callback_dispatch)( &(team_info->parallel_data), &(task_info->task_data), ompt_dispatch_section, instance); } #endif } return sectionIndex; } /*! @ingroup WORK_SHARING @param loc source location information @param global_tid global thread number End of "sections" construct. Don't need to wait here: barrier is added separately when needed. */ void __kmpc_end_sections(ident_t *loc, kmp_int32 gtid) { kmp_info_t *th = __kmp_threads[gtid]; int active = !th->th.th_team->t.t_serialized; KD_TRACE(100, ("__kmpc_end_sections: T#%d called\n", gtid)); if (!active) { // In active case call finalization is done in __kmpc_next_section #if OMPT_SUPPORT && OMPT_OPTIONAL if (ompt_enabled.ompt_callback_work) { ompt_team_info_t *team_info = __ompt_get_teaminfo(0, NULL); ompt_task_info_t *task_info = __ompt_get_task_info_object(0); ompt_callbacks.ompt_callback(ompt_callback_work)( ompt_work_sections, ompt_scope_end, &(team_info->parallel_data), &(task_info->task_data), 0, OMPT_GET_RETURN_ADDRESS(0)); } #endif } KMP_POP_PARTITIONED_TIMER(); KD_TRACE(100, ("__kmpc_end_sections: T#%d returned\n", gtid)); } template static void __kmp_dist_get_bounds(ident_t *loc, kmp_int32 gtid, kmp_int32 *plastiter, T *plower, T *pupper, typename traits_t::signed_t incr) { typedef typename traits_t::unsigned_t UT; kmp_uint32 team_id; kmp_uint32 nteams; UT trip_count; kmp_team_t *team; kmp_info_t *th; KMP_DEBUG_ASSERT(plastiter && plower && pupper); KE_TRACE(10, ("__kmpc_dist_get_bounds called (%d)\n", gtid)); #ifdef KMP_DEBUG typedef typename traits_t::signed_t ST; { char *buff; // create format specifiers before the debug output buff = __kmp_str_format("__kmpc_dist_get_bounds: T#%%d liter=%%d " "iter=(%%%s, %%%s, %%%s) signed?<%s>\n", traits_t::spec, traits_t::spec, traits_t::spec, traits_t::spec); KD_TRACE(100, (buff, gtid, *plastiter, *plower, *pupper, incr)); __kmp_str_free(&buff); } #endif if (__kmp_env_consistency_check) { if (incr == 0) { __kmp_error_construct(kmp_i18n_msg_CnsLoopIncrZeroProhibited, ct_pdo, loc); } if (incr > 0 ? (*pupper < *plower) : (*plower < *pupper)) { // The loop is illegal. // Some zero-trip loops maintained by compiler, e.g.: // for(i=10;i<0;++i) // lower >= upper - run-time check // for(i=0;i>10;--i) // lower <= upper - run-time check // for(i=0;i>10;++i) // incr > 0 - compile-time check // for(i=10;i<0;--i) // incr < 0 - compile-time check // Compiler does not check the following illegal loops: // for(i=0;i<10;i+=incr) // where incr<0 // for(i=10;i>0;i-=incr) // where incr<0 __kmp_error_construct(kmp_i18n_msg_CnsLoopIncrIllegal, ct_pdo, loc); } } __kmp_assert_valid_gtid(gtid); th = __kmp_threads[gtid]; team = th->th.th_team; KMP_DEBUG_ASSERT(th->th.th_teams_microtask); // we are in the teams construct nteams = th->th.th_teams_size.nteams; team_id = team->t.t_master_tid; KMP_DEBUG_ASSERT(nteams == (kmp_uint32)team->t.t_parent->t.t_nproc); // compute global trip count if (incr == 1) { trip_count = *pupper - *plower + 1; } else if (incr == -1) { trip_count = *plower - *pupper + 1; } else if (incr > 0) { // upper-lower can exceed the limit of signed type trip_count = (UT)(*pupper - *plower) / incr + 1; } else { trip_count = (UT)(*plower - *pupper) / (-incr) + 1; } if (trip_count <= nteams) { KMP_DEBUG_ASSERT( __kmp_static == kmp_sch_static_greedy || __kmp_static == kmp_sch_static_balanced); // Unknown static scheduling type. // only some teams get single iteration, others get nothing if (team_id < trip_count) { *pupper = *plower = *plower + team_id * incr; } else { *plower = *pupper + incr; // zero-trip loop } if (plastiter != NULL) *plastiter = (team_id == trip_count - 1); } else { if (__kmp_static == kmp_sch_static_balanced) { UT chunk = trip_count / nteams; UT extras = trip_count % nteams; *plower += incr * (team_id * chunk + (team_id < extras ? team_id : extras)); *pupper = *plower + chunk * incr - (team_id < extras ? 0 : incr); if (plastiter != NULL) *plastiter = (team_id == nteams - 1); } else { T chunk_inc_count = (trip_count / nteams + ((trip_count % nteams) ? 1 : 0)) * incr; T upper = *pupper; KMP_DEBUG_ASSERT(__kmp_static == kmp_sch_static_greedy); // Unknown static scheduling type. *plower += team_id * chunk_inc_count; *pupper = *plower + chunk_inc_count - incr; // Check/correct bounds if needed if (incr > 0) { if (*pupper < *plower) *pupper = traits_t::max_value; if (plastiter != NULL) *plastiter = *plower <= upper && *pupper > upper - incr; if (*pupper > upper) *pupper = upper; // tracker C73258 } else { if (*pupper > *plower) *pupper = traits_t::min_value; if (plastiter != NULL) *plastiter = *plower >= upper && *pupper < upper - incr; if (*pupper < upper) *pupper = upper; // tracker C73258 } } } } //----------------------------------------------------------------------------- // Dispatch routines // Transfer call to template< type T > // __kmp_dispatch_init( ident_t *loc, int gtid, enum sched_type schedule, // T lb, T ub, ST st, ST chunk ) extern "C" { /*! @ingroup WORK_SHARING @{ @param loc Source location @param gtid Global thread id @param schedule Schedule type @param lb Lower bound @param ub Upper bound @param st Step (or increment if you prefer) @param chunk The chunk size to block with This function prepares the runtime to start a dynamically scheduled for loop, saving the loop arguments. These functions are all identical apart from the types of the arguments. */ void __kmpc_dispatch_init_4(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 lb, kmp_int32 ub, kmp_int32 st, kmp_int32 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } /*! See @ref __kmpc_dispatch_init_4 */ void __kmpc_dispatch_init_4u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_uint32 lb, kmp_uint32 ub, kmp_int32 st, kmp_int32 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } /*! See @ref __kmpc_dispatch_init_4 */ void __kmpc_dispatch_init_8(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int64 lb, kmp_int64 ub, kmp_int64 st, kmp_int64 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } /*! See @ref __kmpc_dispatch_init_4 */ void __kmpc_dispatch_init_8u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_uint64 lb, kmp_uint64 ub, kmp_int64 st, kmp_int64 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } /*! See @ref __kmpc_dispatch_init_4 Difference from __kmpc_dispatch_init set of functions is these functions are called for composite distribute parallel for construct. Thus before regular iterations dispatching we need to calc per-team iteration space. These functions are all identical apart from the types of the arguments. */ void __kmpc_dist_dispatch_init_4(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 *p_last, kmp_int32 lb, kmp_int32 ub, kmp_int32 st, kmp_int32 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dist_get_bounds(loc, gtid, p_last, &lb, &ub, st); __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } void __kmpc_dist_dispatch_init_4u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 *p_last, kmp_uint32 lb, kmp_uint32 ub, kmp_int32 st, kmp_int32 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dist_get_bounds(loc, gtid, p_last, &lb, &ub, st); __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } void __kmpc_dist_dispatch_init_8(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 *p_last, kmp_int64 lb, kmp_int64 ub, kmp_int64 st, kmp_int64 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dist_get_bounds(loc, gtid, p_last, &lb, &ub, st); __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } void __kmpc_dist_dispatch_init_8u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 *p_last, kmp_uint64 lb, kmp_uint64 ub, kmp_int64 st, kmp_int64 chunk) { KMP_DEBUG_ASSERT(__kmp_init_serial); #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif __kmp_dist_get_bounds(loc, gtid, p_last, &lb, &ub, st); __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, true); } /*! @param loc Source code location @param gtid Global thread id @param p_last Pointer to a flag set to one if this is the last chunk or zero otherwise @param p_lb Pointer to the lower bound for the next chunk of work @param p_ub Pointer to the upper bound for the next chunk of work @param p_st Pointer to the stride for the next chunk of work @return one if there is work to be done, zero otherwise Get the next dynamically allocated chunk of work for this thread. If there is no more work, then the lb,ub and stride need not be modified. */ int __kmpc_dispatch_next_4(ident_t *loc, kmp_int32 gtid, kmp_int32 *p_last, kmp_int32 *p_lb, kmp_int32 *p_ub, kmp_int32 *p_st) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif return __kmp_dispatch_next(loc, gtid, p_last, p_lb, p_ub, p_st #if OMPT_SUPPORT && OMPT_OPTIONAL , OMPT_LOAD_RETURN_ADDRESS(gtid) #endif ); } /*! See @ref __kmpc_dispatch_next_4 */ int __kmpc_dispatch_next_4u(ident_t *loc, kmp_int32 gtid, kmp_int32 *p_last, kmp_uint32 *p_lb, kmp_uint32 *p_ub, kmp_int32 *p_st) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif return __kmp_dispatch_next(loc, gtid, p_last, p_lb, p_ub, p_st #if OMPT_SUPPORT && OMPT_OPTIONAL , OMPT_LOAD_RETURN_ADDRESS(gtid) #endif ); } /*! See @ref __kmpc_dispatch_next_4 */ int __kmpc_dispatch_next_8(ident_t *loc, kmp_int32 gtid, kmp_int32 *p_last, kmp_int64 *p_lb, kmp_int64 *p_ub, kmp_int64 *p_st) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif return __kmp_dispatch_next(loc, gtid, p_last, p_lb, p_ub, p_st #if OMPT_SUPPORT && OMPT_OPTIONAL , OMPT_LOAD_RETURN_ADDRESS(gtid) #endif ); } /*! See @ref __kmpc_dispatch_next_4 */ int __kmpc_dispatch_next_8u(ident_t *loc, kmp_int32 gtid, kmp_int32 *p_last, kmp_uint64 *p_lb, kmp_uint64 *p_ub, kmp_int64 *p_st) { #if OMPT_SUPPORT && OMPT_OPTIONAL OMPT_STORE_RETURN_ADDRESS(gtid); #endif return __kmp_dispatch_next(loc, gtid, p_last, p_lb, p_ub, p_st #if OMPT_SUPPORT && OMPT_OPTIONAL , OMPT_LOAD_RETURN_ADDRESS(gtid) #endif ); } /*! @param loc Source code location @param gtid Global thread id Mark the end of a dynamic loop. */ void __kmpc_dispatch_fini_4(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish(gtid, loc); } /*! See @ref __kmpc_dispatch_fini_4 */ void __kmpc_dispatch_fini_8(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish(gtid, loc); } /*! See @ref __kmpc_dispatch_fini_4 */ void __kmpc_dispatch_fini_4u(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish(gtid, loc); } /*! See @ref __kmpc_dispatch_fini_4 */ void __kmpc_dispatch_fini_8u(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish(gtid, loc); } /*! @} */ //----------------------------------------------------------------------------- // Non-template routines from kmp_dispatch.cpp used in other sources kmp_uint32 __kmp_eq_4(kmp_uint32 value, kmp_uint32 checker) { return value == checker; } kmp_uint32 __kmp_neq_4(kmp_uint32 value, kmp_uint32 checker) { return value != checker; } kmp_uint32 __kmp_lt_4(kmp_uint32 value, kmp_uint32 checker) { return value < checker; } kmp_uint32 __kmp_ge_4(kmp_uint32 value, kmp_uint32 checker) { return value >= checker; } kmp_uint32 __kmp_le_4(kmp_uint32 value, kmp_uint32 checker) { return value <= checker; } kmp_uint32 __kmp_wait_4(volatile kmp_uint32 *spinner, kmp_uint32 checker, kmp_uint32 (*pred)(kmp_uint32, kmp_uint32), void *obj // Higher-level synchronization object, or NULL. ) { // note: we may not belong to a team at this point volatile kmp_uint32 *spin = spinner; kmp_uint32 check = checker; kmp_uint32 spins; kmp_uint32 (*f)(kmp_uint32, kmp_uint32) = pred; kmp_uint32 r; kmp_uint64 time; KMP_FSYNC_SPIN_INIT(obj, CCAST(kmp_uint32 *, spin)); KMP_INIT_YIELD(spins); KMP_INIT_BACKOFF(time); // main wait spin loop while (!f(r = TCR_4(*spin), check)) { KMP_FSYNC_SPIN_PREPARE(obj); /* GEH - remove this since it was accidentally introduced when kmp_wait was split. It causes problems with infinite recursion because of exit lock */ /* if ( TCR_4(__kmp_global.g.g_done) && __kmp_global.g.g_abort) __kmp_abort_thread(); */ KMP_YIELD_OVERSUB_ELSE_SPIN(spins, time); } KMP_FSYNC_SPIN_ACQUIRED(obj); return r; } void __kmp_wait_4_ptr(void *spinner, kmp_uint32 checker, kmp_uint32 (*pred)(void *, kmp_uint32), void *obj // Higher-level synchronization object, or NULL. ) { // note: we may not belong to a team at this point void *spin = spinner; kmp_uint32 check = checker; kmp_uint32 spins; kmp_uint32 (*f)(void *, kmp_uint32) = pred; kmp_uint64 time; KMP_FSYNC_SPIN_INIT(obj, spin); KMP_INIT_YIELD(spins); KMP_INIT_BACKOFF(time); // main wait spin loop while (!f(spin, check)) { KMP_FSYNC_SPIN_PREPARE(obj); /* if we have waited a bit, or are noversubscribed, yield */ /* pause is in the following code */ KMP_YIELD_OVERSUB_ELSE_SPIN(spins, time); } KMP_FSYNC_SPIN_ACQUIRED(obj); } } // extern "C" #ifdef KMP_GOMP_COMPAT void __kmp_aux_dispatch_init_4(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int32 lb, kmp_int32 ub, kmp_int32 st, kmp_int32 chunk, int push_ws) { __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, push_ws); } void __kmp_aux_dispatch_init_4u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_uint32 lb, kmp_uint32 ub, kmp_int32 st, kmp_int32 chunk, int push_ws) { __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, push_ws); } void __kmp_aux_dispatch_init_8(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_int64 lb, kmp_int64 ub, kmp_int64 st, kmp_int64 chunk, int push_ws) { __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, push_ws); } void __kmp_aux_dispatch_init_8u(ident_t *loc, kmp_int32 gtid, enum sched_type schedule, kmp_uint64 lb, kmp_uint64 ub, kmp_int64 st, kmp_int64 chunk, int push_ws) { __kmp_dispatch_init(loc, gtid, schedule, lb, ub, st, chunk, push_ws); } void __kmp_aux_dispatch_fini_chunk_4(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish_chunk(gtid, loc); } void __kmp_aux_dispatch_fini_chunk_8(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish_chunk(gtid, loc); } void __kmp_aux_dispatch_fini_chunk_4u(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish_chunk(gtid, loc); } void __kmp_aux_dispatch_fini_chunk_8u(ident_t *loc, kmp_int32 gtid) { __kmp_dispatch_finish_chunk(gtid, loc); } #endif /* KMP_GOMP_COMPAT */ /* ------------------------------------------------------------------------ */