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| /*
* kmp_taskdeps.cpp
*/
//===----------------------------------------------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
//#define KMP_SUPPORT_GRAPH_OUTPUT 1
#include "kmp.h"
#include "kmp_io.h"
#include "kmp_wait_release.h"
#include "kmp_taskdeps.h"
#if OMPT_SUPPORT
#include "ompt-specific.h"
#endif
// TODO: Improve memory allocation? keep a list of pre-allocated structures?
// allocate in blocks? re-use list finished list entries?
// TODO: don't use atomic ref counters for stack-allocated nodes.
// TODO: find an alternate to atomic refs for heap-allocated nodes?
// TODO: Finish graph output support
// TODO: kmp_lock_t seems a tad to big (and heavy weight) for this. Check other
// runtime locks
// TODO: Any ITT support needed?
#ifdef KMP_SUPPORT_GRAPH_OUTPUT
static std::atomic<kmp_int32> kmp_node_id_seed = ATOMIC_VAR_INIT(0);
#endif
static void __kmp_init_node(kmp_depnode_t *node) {
node->dn.successors = NULL;
node->dn.task = NULL; // will point to the rigth task
// once dependences have been processed
for (int i = 0; i < MAX_MTX_DEPS; ++i)
node->dn.mtx_locks[i] = NULL;
node->dn.mtx_num_locks = 0;
__kmp_init_lock(&node->dn.lock);
KMP_ATOMIC_ST_RLX(&node->dn.nrefs, 1); // init creates the first reference
#ifdef KMP_SUPPORT_GRAPH_OUTPUT
node->dn.id = KMP_ATOMIC_INC(&kmp_node_id_seed);
#endif
}
static inline kmp_depnode_t *__kmp_node_ref(kmp_depnode_t *node) {
KMP_ATOMIC_INC(&node->dn.nrefs);
return node;
}
enum { KMP_DEPHASH_OTHER_SIZE = 97, KMP_DEPHASH_MASTER_SIZE = 997 };
size_t sizes[] = { 997, 2003, 4001, 8191, 16001, 32003, 64007, 131071, 270029 };
const size_t MAX_GEN = 8;
static inline kmp_int32 __kmp_dephash_hash(kmp_intptr_t addr, size_t hsize) {
// TODO alternate to try: set = (((Addr64)(addrUsefulBits * 9.618)) %
// m_num_sets );
return ((addr >> 6) ^ (addr >> 2)) % hsize;
}
static kmp_dephash_t *__kmp_dephash_extend(kmp_info_t *thread,
kmp_dephash_t *current_dephash) {
kmp_dephash_t *h;
size_t gen = current_dephash->generation + 1;
if (gen >= MAX_GEN)
return current_dephash;
size_t new_size = sizes[gen];
kmp_int32 size_to_allocate =
new_size * sizeof(kmp_dephash_entry_t *) + sizeof(kmp_dephash_t);
#if USE_FAST_MEMORY
h = (kmp_dephash_t *)__kmp_fast_allocate(thread, size_to_allocate);
#else
h = (kmp_dephash_t *)__kmp_thread_malloc(thread, size_to_allocate);
#endif
h->size = new_size;
h->nelements = current_dephash->nelements;
h->buckets = (kmp_dephash_entry **)(h + 1);
h->generation = gen;
h->nconflicts = 0;
// insert existing elements in the new table
for (size_t i = 0; i < current_dephash->size; i++) {
kmp_dephash_entry_t *next, *entry;
for (entry = current_dephash->buckets[i]; entry; entry = next) {
next = entry->next_in_bucket;
// Compute the new hash using the new size, and insert the entry in
// the new bucket.
kmp_int32 new_bucket = __kmp_dephash_hash(entry->addr, h->size);
entry->next_in_bucket = h->buckets[new_bucket];
if (entry->next_in_bucket) {
h->nconflicts++;
}
h->buckets[new_bucket] = entry;
}
}
// Free old hash table
#if USE_FAST_MEMORY
__kmp_fast_free(thread, current_dephash);
#else
__kmp_thread_free(thread, current_dephash);
#endif
return h;
}
static kmp_dephash_t *__kmp_dephash_create(kmp_info_t *thread,
kmp_taskdata_t *current_task) {
kmp_dephash_t *h;
size_t h_size;
if (current_task->td_flags.tasktype == TASK_IMPLICIT)
h_size = KMP_DEPHASH_MASTER_SIZE;
else
h_size = KMP_DEPHASH_OTHER_SIZE;
kmp_int32 size =
h_size * sizeof(kmp_dephash_entry_t *) + sizeof(kmp_dephash_t);
#if USE_FAST_MEMORY
h = (kmp_dephash_t *)__kmp_fast_allocate(thread, size);
#else
h = (kmp_dephash_t *)__kmp_thread_malloc(thread, size);
#endif
h->size = h_size;
h->generation = 0;
h->nelements = 0;
h->nconflicts = 0;
h->buckets = (kmp_dephash_entry **)(h + 1);
for (size_t i = 0; i < h_size; i++)
h->buckets[i] = 0;
return h;
}
#define ENTRY_LAST_INS 0
#define ENTRY_LAST_MTXS 1
static kmp_dephash_entry *
__kmp_dephash_find(kmp_info_t *thread, kmp_dephash_t **hash, kmp_intptr_t addr) {
kmp_dephash_t *h = *hash;
if (h->nelements != 0
&& h->nconflicts/h->size >= 1) {
*hash = __kmp_dephash_extend(thread, h);
h = *hash;
}
kmp_int32 bucket = __kmp_dephash_hash(addr, h->size);
kmp_dephash_entry_t *entry;
for (entry = h->buckets[bucket]; entry; entry = entry->next_in_bucket)
if (entry->addr == addr)
break;
if (entry == NULL) {
// create entry. This is only done by one thread so no locking required
#if USE_FAST_MEMORY
entry = (kmp_dephash_entry_t *)__kmp_fast_allocate(
thread, sizeof(kmp_dephash_entry_t));
#else
entry = (kmp_dephash_entry_t *)__kmp_thread_malloc(
thread, sizeof(kmp_dephash_entry_t));
#endif
entry->addr = addr;
entry->last_out = NULL;
entry->last_ins = NULL;
entry->last_mtxs = NULL;
entry->last_flag = ENTRY_LAST_INS;
entry->mtx_lock = NULL;
entry->next_in_bucket = h->buckets[bucket];
h->buckets[bucket] = entry;
h->nelements++;
if (entry->next_in_bucket)
h->nconflicts++;
}
return entry;
}
static kmp_depnode_list_t *__kmp_add_node(kmp_info_t *thread,
kmp_depnode_list_t *list,
kmp_depnode_t *node) {
kmp_depnode_list_t *new_head;
#if USE_FAST_MEMORY
new_head = (kmp_depnode_list_t *)__kmp_fast_allocate(
thread, sizeof(kmp_depnode_list_t));
#else
new_head = (kmp_depnode_list_t *)__kmp_thread_malloc(
thread, sizeof(kmp_depnode_list_t));
#endif
new_head->node = __kmp_node_ref(node);
new_head->next = list;
return new_head;
}
static inline void __kmp_track_dependence(kmp_depnode_t *source,
kmp_depnode_t *sink,
kmp_task_t *sink_task) {
#ifdef KMP_SUPPORT_GRAPH_OUTPUT
kmp_taskdata_t *task_source = KMP_TASK_TO_TASKDATA(source->dn.task);
// do not use sink->dn.task as that is only filled after the dependencies
// are already processed!
kmp_taskdata_t *task_sink = KMP_TASK_TO_TASKDATA(sink_task);
__kmp_printf("%d(%s) -> %d(%s)\n", source->dn.id,
task_source->td_ident->psource, sink->dn.id,
task_sink->td_ident->psource);
#endif
#if OMPT_SUPPORT && OMPT_OPTIONAL
/* OMPT tracks dependences between task (a=source, b=sink) in which
task a blocks the execution of b through the ompt_new_dependence_callback
*/
if (ompt_enabled.ompt_callback_task_dependence) {
kmp_taskdata_t *task_source = KMP_TASK_TO_TASKDATA(source->dn.task);
kmp_taskdata_t *task_sink = KMP_TASK_TO_TASKDATA(sink_task);
ompt_callbacks.ompt_callback(ompt_callback_task_dependence)(
&(task_source->ompt_task_info.task_data),
&(task_sink->ompt_task_info.task_data));
}
#endif /* OMPT_SUPPORT && OMPT_OPTIONAL */
}
static inline kmp_int32
__kmp_depnode_link_successor(kmp_int32 gtid, kmp_info_t *thread,
kmp_task_t *task, kmp_depnode_t *node,
kmp_depnode_list_t *plist) {
if (!plist)
return 0;
kmp_int32 npredecessors = 0;
// link node as successor of list elements
for (kmp_depnode_list_t *p = plist; p; p = p->next) {
kmp_depnode_t *dep = p->node;
if (dep->dn.task) {
KMP_ACQUIRE_DEPNODE(gtid, dep);
if (dep->dn.task) {
__kmp_track_dependence(dep, node, task);
dep->dn.successors = __kmp_add_node(thread, dep->dn.successors, node);
KA_TRACE(40, ("__kmp_process_deps: T#%d adding dependence from %p to "
"%p\n",
gtid, KMP_TASK_TO_TASKDATA(dep->dn.task),
KMP_TASK_TO_TASKDATA(task)));
npredecessors++;
}
KMP_RELEASE_DEPNODE(gtid, dep);
}
}
return npredecessors;
}
static inline kmp_int32 __kmp_depnode_link_successor(kmp_int32 gtid,
kmp_info_t *thread,
kmp_task_t *task,
kmp_depnode_t *source,
kmp_depnode_t *sink) {
if (!sink)
return 0;
kmp_int32 npredecessors = 0;
if (sink->dn.task) {
// synchronously add source to sink' list of successors
KMP_ACQUIRE_DEPNODE(gtid, sink);
if (sink->dn.task) {
__kmp_track_dependence(sink, source, task);
sink->dn.successors = __kmp_add_node(thread, sink->dn.successors, source);
KA_TRACE(40, ("__kmp_process_deps: T#%d adding dependence from %p to "
"%p\n",
gtid, KMP_TASK_TO_TASKDATA(sink->dn.task),
KMP_TASK_TO_TASKDATA(task)));
npredecessors++;
}
KMP_RELEASE_DEPNODE(gtid, sink);
}
return npredecessors;
}
template <bool filter>
static inline kmp_int32
__kmp_process_deps(kmp_int32 gtid, kmp_depnode_t *node, kmp_dephash_t **hash,
bool dep_barrier, kmp_int32 ndeps,
kmp_depend_info_t *dep_list, kmp_task_t *task) {
KA_TRACE(30, ("__kmp_process_deps<%d>: T#%d processing %d dependencies : "
"dep_barrier = %d\n",
filter, gtid, ndeps, dep_barrier));
kmp_info_t *thread = __kmp_threads[gtid];
kmp_int32 npredecessors = 0;
for (kmp_int32 i = 0; i < ndeps; i++) {
const kmp_depend_info_t *dep = &dep_list[i];
if (filter && dep->base_addr == 0)
continue; // skip filtered entries
kmp_dephash_entry_t *info =
__kmp_dephash_find(thread, hash, dep->base_addr);
kmp_depnode_t *last_out = info->last_out;
kmp_depnode_list_t *last_ins = info->last_ins;
kmp_depnode_list_t *last_mtxs = info->last_mtxs;
if (dep->flags.out) { // out --> clean lists of ins and mtxs if any
if (last_ins || last_mtxs) {
if (info->last_flag == ENTRY_LAST_INS) { // INS were last
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_ins);
} else { // MTXS were last
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_mtxs);
}
__kmp_depnode_list_free(thread, last_ins);
__kmp_depnode_list_free(thread, last_mtxs);
info->last_ins = NULL;
info->last_mtxs = NULL;
} else {
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_out);
}
__kmp_node_deref(thread, last_out);
if (dep_barrier) {
// if this is a sync point in the serial sequence, then the previous
// outputs are guaranteed to be completed after the execution of this
// task so the previous output nodes can be cleared.
info->last_out = NULL;
} else {
info->last_out = __kmp_node_ref(node);
}
} else if (dep->flags.in) {
// in --> link node to either last_out or last_mtxs, clean earlier deps
if (last_mtxs) {
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_mtxs);
__kmp_node_deref(thread, last_out);
info->last_out = NULL;
if (info->last_flag == ENTRY_LAST_MTXS && last_ins) { // MTXS were last
// clean old INS before creating new list
__kmp_depnode_list_free(thread, last_ins);
info->last_ins = NULL;
}
} else {
// link node as successor of the last_out if any
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_out);
}
info->last_flag = ENTRY_LAST_INS;
info->last_ins = __kmp_add_node(thread, info->last_ins, node);
} else {
KMP_DEBUG_ASSERT(dep->flags.mtx == 1);
// mtx --> link node to either last_out or last_ins, clean earlier deps
if (last_ins) {
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_ins);
__kmp_node_deref(thread, last_out);
info->last_out = NULL;
if (info->last_flag == ENTRY_LAST_INS && last_mtxs) { // INS were last
// clean old MTXS before creating new list
__kmp_depnode_list_free(thread, last_mtxs);
info->last_mtxs = NULL;
}
} else {
// link node as successor of the last_out if any
npredecessors +=
__kmp_depnode_link_successor(gtid, thread, task, node, last_out);
}
info->last_flag = ENTRY_LAST_MTXS;
info->last_mtxs = __kmp_add_node(thread, info->last_mtxs, node);
if (info->mtx_lock == NULL) {
info->mtx_lock = (kmp_lock_t *)__kmp_allocate(sizeof(kmp_lock_t));
__kmp_init_lock(info->mtx_lock);
}
KMP_DEBUG_ASSERT(node->dn.mtx_num_locks < MAX_MTX_DEPS);
kmp_int32 m;
// Save lock in node's array
for (m = 0; m < MAX_MTX_DEPS; ++m) {
// sort pointers in decreasing order to avoid potential livelock
if (node->dn.mtx_locks[m] < info->mtx_lock) {
KMP_DEBUG_ASSERT(node->dn.mtx_locks[node->dn.mtx_num_locks] == NULL);
for (int n = node->dn.mtx_num_locks; n > m; --n) {
// shift right all lesser non-NULL pointers
KMP_DEBUG_ASSERT(node->dn.mtx_locks[n - 1] != NULL);
node->dn.mtx_locks[n] = node->dn.mtx_locks[n - 1];
}
node->dn.mtx_locks[m] = info->mtx_lock;
break;
}
}
KMP_DEBUG_ASSERT(m < MAX_MTX_DEPS); // must break from loop
node->dn.mtx_num_locks++;
}
}
KA_TRACE(30, ("__kmp_process_deps<%d>: T#%d found %d predecessors\n", filter,
gtid, npredecessors));
return npredecessors;
}
#define NO_DEP_BARRIER (false)
#define DEP_BARRIER (true)
// returns true if the task has any outstanding dependence
static bool __kmp_check_deps(kmp_int32 gtid, kmp_depnode_t *node,
kmp_task_t *task, kmp_dephash_t **hash,
bool dep_barrier, kmp_int32 ndeps,
kmp_depend_info_t *dep_list,
kmp_int32 ndeps_noalias,
kmp_depend_info_t *noalias_dep_list) {
int i, n_mtxs = 0;
#if KMP_DEBUG
kmp_taskdata_t *taskdata = KMP_TASK_TO_TASKDATA(task);
#endif
KA_TRACE(20, ("__kmp_check_deps: T#%d checking dependencies for task %p : %d "
"possibly aliased dependencies, %d non-aliased depedencies : "
"dep_barrier=%d .\n",
gtid, taskdata, ndeps, ndeps_noalias, dep_barrier));
// Filter deps in dep_list
// TODO: Different algorithm for large dep_list ( > 10 ? )
for (i = 0; i < ndeps; i++) {
if (dep_list[i].base_addr != 0) {
for (int j = i + 1; j < ndeps; j++) {
if (dep_list[i].base_addr == dep_list[j].base_addr) {
dep_list[i].flags.in |= dep_list[j].flags.in;
dep_list[i].flags.out |=
(dep_list[j].flags.out ||
(dep_list[i].flags.in && dep_list[j].flags.mtx) ||
(dep_list[i].flags.mtx && dep_list[j].flags.in));
dep_list[i].flags.mtx =
dep_list[i].flags.mtx | dep_list[j].flags.mtx &&
!dep_list[i].flags.out;
dep_list[j].base_addr = 0; // Mark j element as void
}
}
if (dep_list[i].flags.mtx) {
// limit number of mtx deps to MAX_MTX_DEPS per node
if (n_mtxs < MAX_MTX_DEPS && task != NULL) {
++n_mtxs;
} else {
dep_list[i].flags.in = 1; // downgrade mutexinoutset to inout
dep_list[i].flags.out = 1;
dep_list[i].flags.mtx = 0;
}
}
}
}
// doesn't need to be atomic as no other thread is going to be accessing this
// node just yet.
// npredecessors is set -1 to ensure that none of the releasing tasks queues
// this task before we have finished processing all the dependencies
node->dn.npredecessors = -1;
// used to pack all npredecessors additions into a single atomic operation at
// the end
int npredecessors;
npredecessors = __kmp_process_deps<true>(gtid, node, hash, dep_barrier, ndeps,
dep_list, task);
npredecessors += __kmp_process_deps<false>(
gtid, node, hash, dep_barrier, ndeps_noalias, noalias_dep_list, task);
node->dn.task = task;
KMP_MB();
// Account for our initial fake value
npredecessors++;
// Update predecessors and obtain current value to check if there are still
// any outstandig dependences (some tasks may have finished while we processed
// the dependences)
npredecessors =
node->dn.npredecessors.fetch_add(npredecessors) + npredecessors;
KA_TRACE(20, ("__kmp_check_deps: T#%d found %d predecessors for task %p \n",
gtid, npredecessors, taskdata));
// beyond this point the task could be queued (and executed) by a releasing
// task...
return npredecessors > 0 ? true : false;
}
/*!
@ingroup TASKING
@param loc_ref location of the original task directive
@param gtid Global Thread ID of encountering thread
@param new_task task thunk allocated by __kmp_omp_task_alloc() for the ''new
task''
@param ndeps Number of depend items with possible aliasing
@param dep_list List of depend items with possible aliasing
@param ndeps_noalias Number of depend items with no aliasing
@param noalias_dep_list List of depend items with no aliasing
@return Returns either TASK_CURRENT_NOT_QUEUED if the current task was not
suspendend and queued, or TASK_CURRENT_QUEUED if it was suspended and queued
Schedule a non-thread-switchable task with dependences for execution
*/
kmp_int32 __kmpc_omp_task_with_deps(ident_t *loc_ref, kmp_int32 gtid,
kmp_task_t *new_task, kmp_int32 ndeps,
kmp_depend_info_t *dep_list,
kmp_int32 ndeps_noalias,
kmp_depend_info_t *noalias_dep_list) {
kmp_taskdata_t *new_taskdata = KMP_TASK_TO_TASKDATA(new_task);
KA_TRACE(10, ("__kmpc_omp_task_with_deps(enter): T#%d loc=%p task=%p\n", gtid,
loc_ref, new_taskdata));
kmp_info_t *thread = __kmp_threads[gtid];
kmp_taskdata_t *current_task = thread->th.th_current_task;
#if OMPT_SUPPORT
if (ompt_enabled.enabled) {
OMPT_STORE_RETURN_ADDRESS(gtid);
if (!current_task->ompt_task_info.frame.enter_frame.ptr)
current_task->ompt_task_info.frame.enter_frame.ptr =
OMPT_GET_FRAME_ADDRESS(0);
if (ompt_enabled.ompt_callback_task_create) {
ompt_data_t task_data = ompt_data_none;
ompt_callbacks.ompt_callback(ompt_callback_task_create)(
current_task ? &(current_task->ompt_task_info.task_data) : &task_data,
current_task ? &(current_task->ompt_task_info.frame) : NULL,
&(new_taskdata->ompt_task_info.task_data),
ompt_task_explicit | TASK_TYPE_DETAILS_FORMAT(new_taskdata), 1,
OMPT_LOAD_RETURN_ADDRESS(gtid));
}
new_taskdata->ompt_task_info.frame.enter_frame.ptr = OMPT_GET_FRAME_ADDRESS(0);
}
#if OMPT_OPTIONAL
/* OMPT grab all dependences if requested by the tool */
if (ndeps + ndeps_noalias > 0 &&
ompt_enabled.ompt_callback_dependences) {
kmp_int32 i;
new_taskdata->ompt_task_info.ndeps = ndeps + ndeps_noalias;
new_taskdata->ompt_task_info.deps =
(ompt_dependence_t *)KMP_OMPT_DEPS_ALLOC(
thread, (ndeps + ndeps_noalias) * sizeof(ompt_dependence_t));
KMP_ASSERT(new_taskdata->ompt_task_info.deps != NULL);
for (i = 0; i < ndeps; i++) {
new_taskdata->ompt_task_info.deps[i].variable.ptr =
(void *)dep_list[i].base_addr;
if (dep_list[i].flags.in && dep_list[i].flags.out)
new_taskdata->ompt_task_info.deps[i].dependence_type =
ompt_dependence_type_inout;
else if (dep_list[i].flags.out)
new_taskdata->ompt_task_info.deps[i].dependence_type =
ompt_dependence_type_out;
else if (dep_list[i].flags.in)
new_taskdata->ompt_task_info.deps[i].dependence_type =
ompt_dependence_type_in;
}
for (i = 0; i < ndeps_noalias; i++) {
new_taskdata->ompt_task_info.deps[ndeps + i].variable.ptr =
(void *)noalias_dep_list[i].base_addr;
if (noalias_dep_list[i].flags.in && noalias_dep_list[i].flags.out)
new_taskdata->ompt_task_info.deps[ndeps + i].dependence_type =
ompt_dependence_type_inout;
else if (noalias_dep_list[i].flags.out)
new_taskdata->ompt_task_info.deps[ndeps + i].dependence_type =
ompt_dependence_type_out;
else if (noalias_dep_list[i].flags.in)
new_taskdata->ompt_task_info.deps[ndeps + i].dependence_type =
ompt_dependence_type_in;
}
ompt_callbacks.ompt_callback(ompt_callback_dependences)(
&(new_taskdata->ompt_task_info.task_data),
new_taskdata->ompt_task_info.deps, new_taskdata->ompt_task_info.ndeps);
/* We can now free the allocated memory for the dependencies */
/* For OMPD we might want to delay the free until task_end */
KMP_OMPT_DEPS_FREE(thread, new_taskdata->ompt_task_info.deps);
new_taskdata->ompt_task_info.deps = NULL;
new_taskdata->ompt_task_info.ndeps = 0;
}
#endif /* OMPT_OPTIONAL */
#endif /* OMPT_SUPPORT */
bool serial = current_task->td_flags.team_serial ||
current_task->td_flags.tasking_ser ||
current_task->td_flags.final;
kmp_task_team_t *task_team = thread->th.th_task_team;
serial = serial && !(task_team && task_team->tt.tt_found_proxy_tasks);
if (!serial && (ndeps > 0 || ndeps_noalias > 0)) {
/* if no dependencies have been tracked yet, create the dependence hash */
if (current_task->td_dephash == NULL)
current_task->td_dephash = __kmp_dephash_create(thread, current_task);
#if USE_FAST_MEMORY
kmp_depnode_t *node =
(kmp_depnode_t *)__kmp_fast_allocate(thread, sizeof(kmp_depnode_t));
#else
kmp_depnode_t *node =
(kmp_depnode_t *)__kmp_thread_malloc(thread, sizeof(kmp_depnode_t));
#endif
__kmp_init_node(node);
new_taskdata->td_depnode = node;
if (__kmp_check_deps(gtid, node, new_task, ¤t_task->td_dephash,
NO_DEP_BARRIER, ndeps, dep_list, ndeps_noalias,
noalias_dep_list)) {
KA_TRACE(10, ("__kmpc_omp_task_with_deps(exit): T#%d task had blocking "
"dependencies: "
"loc=%p task=%p, return: TASK_CURRENT_NOT_QUEUED\n",
gtid, loc_ref, new_taskdata));
#if OMPT_SUPPORT
if (ompt_enabled.enabled) {
current_task->ompt_task_info.frame.enter_frame = ompt_data_none;
}
#endif
return TASK_CURRENT_NOT_QUEUED;
}
} else {
KA_TRACE(10, ("__kmpc_omp_task_with_deps(exit): T#%d ignored dependencies "
"for task (serialized)"
"loc=%p task=%p\n",
gtid, loc_ref, new_taskdata));
}
KA_TRACE(10, ("__kmpc_omp_task_with_deps(exit): T#%d task had no blocking "
"dependencies : "
"loc=%p task=%p, transferring to __kmp_omp_task\n",
gtid, loc_ref, new_taskdata));
kmp_int32 ret = __kmp_omp_task(gtid, new_task, true);
#if OMPT_SUPPORT
if (ompt_enabled.enabled) {
current_task->ompt_task_info.frame.enter_frame = ompt_data_none;
}
#endif
return ret;
}
/*!
@ingroup TASKING
@param loc_ref location of the original task directive
@param gtid Global Thread ID of encountering thread
@param ndeps Number of depend items with possible aliasing
@param dep_list List of depend items with possible aliasing
@param ndeps_noalias Number of depend items with no aliasing
@param noalias_dep_list List of depend items with no aliasing
Blocks the current task until all specifies dependencies have been fulfilled.
*/
void __kmpc_omp_wait_deps(ident_t *loc_ref, kmp_int32 gtid, kmp_int32 ndeps,
kmp_depend_info_t *dep_list, kmp_int32 ndeps_noalias,
kmp_depend_info_t *noalias_dep_list) {
KA_TRACE(10, ("__kmpc_omp_wait_deps(enter): T#%d loc=%p\n", gtid, loc_ref));
if (ndeps == 0 && ndeps_noalias == 0) {
KA_TRACE(10, ("__kmpc_omp_wait_deps(exit): T#%d has no dependencies to "
"wait upon : loc=%p\n",
gtid, loc_ref));
return;
}
kmp_info_t *thread = __kmp_threads[gtid];
kmp_taskdata_t *current_task = thread->th.th_current_task;
// We can return immediately as:
// - dependences are not computed in serial teams (except with proxy tasks)
// - if the dephash is not yet created it means we have nothing to wait for
bool ignore = current_task->td_flags.team_serial ||
current_task->td_flags.tasking_ser ||
current_task->td_flags.final;
ignore = ignore && thread->th.th_task_team != NULL &&
thread->th.th_task_team->tt.tt_found_proxy_tasks == FALSE;
ignore = ignore || current_task->td_dephash == NULL;
if (ignore) {
KA_TRACE(10, ("__kmpc_omp_wait_deps(exit): T#%d has no blocking "
"dependencies : loc=%p\n",
gtid, loc_ref));
return;
}
kmp_depnode_t node = {0};
__kmp_init_node(&node);
if (!__kmp_check_deps(gtid, &node, NULL, ¤t_task->td_dephash,
DEP_BARRIER, ndeps, dep_list, ndeps_noalias,
noalias_dep_list)) {
KA_TRACE(10, ("__kmpc_omp_wait_deps(exit): T#%d has no blocking "
"dependencies : loc=%p\n",
gtid, loc_ref));
return;
}
int thread_finished = FALSE;
kmp_flag_32 flag((std::atomic<kmp_uint32> *)&node.dn.npredecessors, 0U);
while (node.dn.npredecessors > 0) {
flag.execute_tasks(thread, gtid, FALSE,
&thread_finished USE_ITT_BUILD_ARG(NULL),
__kmp_task_stealing_constraint);
}
KA_TRACE(10, ("__kmpc_omp_wait_deps(exit): T#%d finished waiting : loc=%p\n",
gtid, loc_ref));
}
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