Mercurial > hg > CbC > CbC_gcc
view libitm/beginend.cc @ 143:76e1cf5455ef
add cbc_gc test
| author | Shinji KONO <kono@ie.u-ryukyu.ac.jp> |
|---|---|
| date | Sun, 23 Dec 2018 19:24:05 +0900 |
| parents | 84e7813d76e9 |
| children | 1830386684a0 |
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/* Copyright (C) 2008-2018 Free Software Foundation, Inc. Contributed by Richard Henderson <rth@redhat.com>. This file is part of the GNU Transactional Memory Library (libitm). Libitm is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. Libitm is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. Under Section 7 of GPL version 3, you are granted additional permissions described in the GCC Runtime Library Exception, version 3.1, as published by the Free Software Foundation. You should have received a copy of the GNU General Public License and a copy of the GCC Runtime Library Exception along with this program; see the files COPYING3 and COPYING.RUNTIME respectively. If not, see <http://www.gnu.org/licenses/>. */ #include "libitm_i.h" #include <pthread.h> using namespace GTM; #if !defined(HAVE_ARCH_GTM_THREAD) || !defined(HAVE_ARCH_GTM_THREAD_DISP) extern __thread gtm_thread_tls _gtm_thr_tls; #endif // Put this at the start of a cacheline so that serial_lock's writers and // htm_fastpath fields are on the same cacheline, so that HW transactions // only have to pay one cacheline capacity to monitor both. gtm_rwlock GTM::gtm_thread::serial_lock __attribute__((aligned(HW_CACHELINE_SIZE))); gtm_thread *GTM::gtm_thread::list_of_threads = 0; unsigned GTM::gtm_thread::number_of_threads = 0; /* ??? Move elsewhere when we figure out library initialization. */ uint64_t GTM::gtm_spin_count_var = 1000; #ifdef HAVE_64BIT_SYNC_BUILTINS static atomic<_ITM_transactionId_t> global_tid; #else static _ITM_transactionId_t global_tid; static pthread_mutex_t global_tid_lock = PTHREAD_MUTEX_INITIALIZER; #endif // Provides a on-thread-exit callback used to release per-thread data. static pthread_key_t thr_release_key; static pthread_once_t thr_release_once = PTHREAD_ONCE_INIT; /* Allocate a transaction structure. */ void * GTM::gtm_thread::operator new (size_t s) { void *tx; assert(s == sizeof(gtm_thread)); tx = xmalloc (sizeof (gtm_thread), true); memset (tx, 0, sizeof (gtm_thread)); return tx; } /* Free the given transaction. Raises an error if the transaction is still in use. */ void GTM::gtm_thread::operator delete(void *tx) { free(tx); } static void thread_exit_handler(void *) { gtm_thread *thr = gtm_thr(); if (thr) delete thr; set_gtm_thr(0); } static void thread_exit_init() { if (pthread_key_create(&thr_release_key, thread_exit_handler)) GTM_fatal("Creating thread release TLS key failed."); } GTM::gtm_thread::~gtm_thread() { if (nesting > 0) GTM_fatal("Thread exit while a transaction is still active."); // Deregister this transaction. serial_lock.write_lock (); gtm_thread **prev = &list_of_threads; for (; *prev; prev = &(*prev)->next_thread) { if (*prev == this) { *prev = (*prev)->next_thread; break; } } number_of_threads--; number_of_threads_changed(number_of_threads + 1, number_of_threads); serial_lock.write_unlock (); } GTM::gtm_thread::gtm_thread () { // This object's memory has been set to zero by operator new, so no need // to initialize any of the other primitive-type members that do not have // constructors. shared_state.store(-1, memory_order_relaxed); // Register this transaction with the list of all threads' transactions. serial_lock.write_lock (); next_thread = list_of_threads; list_of_threads = this; number_of_threads++; number_of_threads_changed(number_of_threads - 1, number_of_threads); serial_lock.write_unlock (); init_cpp_exceptions (); if (pthread_once(&thr_release_once, thread_exit_init)) GTM_fatal("Initializing thread release TLS key failed."); // Any non-null value is sufficient to trigger destruction of this // transaction when the current thread terminates. if (pthread_setspecific(thr_release_key, this)) GTM_fatal("Setting thread release TLS key failed."); } static inline uint32_t choose_code_path(uint32_t prop, abi_dispatch *disp) { if ((prop & pr_uninstrumentedCode) && disp->can_run_uninstrumented_code()) return a_runUninstrumentedCode; else return a_runInstrumentedCode; } #ifdef TARGET_BEGIN_TRANSACTION_ATTRIBUTE /* This macro can be used to define target specific attributes for this function. For example, S/390 requires floating point to be disabled in begin_transaction. */ TARGET_BEGIN_TRANSACTION_ATTRIBUTE #endif uint32_t GTM::gtm_thread::begin_transaction (uint32_t prop, const gtm_jmpbuf *jb) { static const _ITM_transactionId_t tid_block_size = 1 << 16; gtm_thread *tx; abi_dispatch *disp; uint32_t ret; // ??? pr_undoLogCode is not properly defined in the ABI. Are barriers // omitted because they are not necessary (e.g., a transaction on thread- // local data) or because the compiler thinks that some kind of global // synchronization might perform better? if (unlikely(prop & pr_undoLogCode)) GTM_fatal("pr_undoLogCode not supported"); #ifdef USE_HTM_FASTPATH // HTM fastpath. Only chosen in the absence of transaction_cancel to allow // using an uninstrumented code path. // The fastpath is enabled only by dispatch_htm's method group, which uses // serial-mode methods as fallback. Serial-mode transactions cannot execute // concurrently with HW transactions because the latter monitor the serial // lock's writer flag and thus abort if another thread is or becomes a // serial transaction. Therefore, if the fastpath is enabled, then a // transaction is not executing as a HW transaction iff the serial lock is // write-locked. Also, HW transactions monitor the fastpath control // variable, so that they will only execute if dispatch_htm is still the // current method group. This allows us to use htm_fastpath and the serial // lock's writers flag to reliable determine whether the current thread runs // a HW transaction, and thus we do not need to maintain this information in // per-thread state. // If an uninstrumented code path is not available, we can still run // instrumented code from a HW transaction because the HTM fastpath kicks // in early in both begin and commit, and the transaction is not canceled. // HW transactions might get requests to switch to serial-irrevocable mode, // but these can be ignored because the HTM provides all necessary // correctness guarantees. Transactions cannot detect whether they are // indeed in serial mode, and HW transactions should never need serial mode // for any internal changes (e.g., they never abort visibly to the STM code // and thus do not trigger the standard retry handling). #ifndef HTM_CUSTOM_FASTPATH if (likely(serial_lock.get_htm_fastpath() && (prop & pr_hasNoAbort))) { // Note that the snapshot of htm_fastpath that we take here could be // outdated, and a different method group than dispatch_htm may have // been chosen in the meantime. Therefore, take care not not touch // anything besides the serial lock, which is independent of method // groups. for (uint32_t t = serial_lock.get_htm_fastpath(); t; t--) { uint32_t ret = htm_begin(); if (htm_begin_success(ret)) { // We are executing a transaction now. // Monitor the writer flag in the serial-mode lock, and abort // if there is an active or waiting serial-mode transaction. // Also checks that htm_fastpath is still nonzero and thus // HW transactions are allowed to run. // Note that this can also happen due to an enclosing // serial-mode transaction; we handle this case below. if (unlikely(serial_lock.htm_fastpath_disabled())) htm_abort(); else // We do not need to set a_saveLiveVariables because of HTM. return (prop & pr_uninstrumentedCode) ? a_runUninstrumentedCode : a_runInstrumentedCode; } // The transaction has aborted. Don't retry if it's unlikely that // retrying the transaction will be successful. if (!htm_abort_should_retry(ret)) break; // Check whether the HTM fastpath has been disabled. if (!serial_lock.get_htm_fastpath()) break; // Wait until any concurrent serial-mode transactions have finished. // This is an empty critical section, but won't be elided. if (serial_lock.htm_fastpath_disabled()) { tx = gtm_thr(); if (unlikely(tx == NULL)) { // See below. tx = new gtm_thread(); set_gtm_thr(tx); } // Check whether there is an enclosing serial-mode transaction; // if so, we just continue as a nested transaction and don't // try to use the HTM fastpath. This case can happen when an // outermost relaxed transaction calls unsafe code that starts // a transaction. if (tx->nesting > 0) break; // Another thread is running a serial-mode transaction. Wait. serial_lock.read_lock(tx); serial_lock.read_unlock(tx); // TODO We should probably reset the retry count t here, unless // we have retried so often that we should go serial to avoid // starvation. } } } #else // If we have a custom HTM fastpath in ITM_beginTransaction, we implement // just the retry policy here. We communicate with the custom fastpath // through additional property bits and return codes, and either transfer // control back to the custom fastpath or run the fallback mechanism. The // fastpath synchronization algorithm itself is the same. // pr_HTMRetryableAbort states that a HW transaction started by the custom // HTM fastpath aborted, and that we thus have to decide whether to retry // the fastpath (returning a_tryHTMFastPath) or just proceed with the // fallback method. if (likely(serial_lock.get_htm_fastpath() && (prop & pr_HTMRetryableAbort))) { tx = gtm_thr(); if (unlikely(tx == NULL)) { // See below. tx = new gtm_thread(); set_gtm_thr(tx); } // If this is the first abort, reset the retry count. We abuse // restart_total for the retry count, which is fine because our only // other fallback will use serial transactions, which don't use // restart_total but will reset it when committing. if (!(prop & pr_HTMRetriedAfterAbort)) tx->restart_total = gtm_thread::serial_lock.get_htm_fastpath(); if (--tx->restart_total > 0) { // Wait until any concurrent serial-mode transactions have finished. // Essentially the same code as above. if (!serial_lock.get_htm_fastpath()) goto stop_custom_htm_fastpath; if (serial_lock.htm_fastpath_disabled()) { if (tx->nesting > 0) goto stop_custom_htm_fastpath; serial_lock.read_lock(tx); serial_lock.read_unlock(tx); } // Let ITM_beginTransaction retry the custom HTM fastpath. return a_tryHTMFastPath; } } stop_custom_htm_fastpath: #endif #endif tx = gtm_thr(); if (unlikely(tx == NULL)) { // Create the thread object. The constructor will also set up automatic // deletion on thread termination. tx = new gtm_thread(); set_gtm_thr(tx); } if (tx->nesting > 0) { // This is a nested transaction. // Check prop compatibility: // The ABI requires pr_hasNoFloatUpdate, pr_hasNoVectorUpdate, // pr_hasNoIrrevocable, pr_aWBarriersOmitted, pr_RaRBarriersOmitted, and // pr_hasNoSimpleReads to hold for the full dynamic scope of a // transaction. We could check that these are set for the nested // transaction if they are also set for the parent transaction, but the // ABI does not require these flags to be set if they could be set, // so the check could be too strict. // ??? For pr_readOnly, lexical or dynamic scope is unspecified. if (prop & pr_hasNoAbort) { // We can use flat nesting, so elide this transaction. if (!(prop & pr_instrumentedCode)) { if (!(tx->state & STATE_SERIAL) || !(tx->state & STATE_IRREVOCABLE)) tx->serialirr_mode(); } // Increment nesting level after checking that we have a method that // allows us to continue. tx->nesting++; return choose_code_path(prop, abi_disp()); } // The transaction might abort, so use closed nesting if possible. // pr_hasNoAbort has lexical scope, so the compiler should really have // generated an instrumented code path. assert(prop & pr_instrumentedCode); // Create a checkpoint of the current transaction. gtm_transaction_cp *cp = tx->parent_txns.push(); cp->save(tx); new (&tx->alloc_actions) aa_tree<uintptr_t, gtm_alloc_action>(); // Check whether the current method actually supports closed nesting. // If we can switch to another one, do so. // If not, we assume that actual aborts are infrequent, and rather // restart in _ITM_abortTransaction when we really have to. disp = abi_disp(); if (!disp->closed_nesting()) { // ??? Should we elide the transaction if there is no alternative // method that supports closed nesting? If we do, we need to set // some flag to prevent _ITM_abortTransaction from aborting the // wrong transaction (i.e., some parent transaction). abi_dispatch *cn_disp = disp->closed_nesting_alternative(); if (cn_disp) { disp = cn_disp; set_abi_disp(disp); } } } else { // Outermost transaction disp = tx->decide_begin_dispatch (prop); set_abi_disp (disp); } // Initialization that is common for outermost and nested transactions. tx->prop = prop; tx->nesting++; tx->jb = *jb; // As long as we have not exhausted a previously allocated block of TIDs, // we can avoid an atomic operation on a shared cacheline. if (tx->local_tid & (tid_block_size - 1)) tx->id = tx->local_tid++; else { #ifdef HAVE_64BIT_SYNC_BUILTINS // We don't really care which block of TIDs we get but only that we // acquire one atomically; therefore, relaxed memory order is // sufficient. tx->id = global_tid.fetch_add(tid_block_size, memory_order_relaxed); tx->local_tid = tx->id + 1; #else pthread_mutex_lock (&global_tid_lock); global_tid += tid_block_size; tx->id = global_tid; tx->local_tid = tx->id + 1; pthread_mutex_unlock (&global_tid_lock); #endif } // Log the number of uncaught exceptions if we might have to roll back this // state. if (tx->cxa_uncaught_count_ptr != 0) tx->cxa_uncaught_count = *tx->cxa_uncaught_count_ptr; // Run dispatch-specific restart code. Retry until we succeed. GTM::gtm_restart_reason rr; while ((rr = disp->begin_or_restart()) != NO_RESTART) { tx->decide_retry_strategy(rr); disp = abi_disp(); } // Determine the code path to run. Only irrevocable transactions cannot be // restarted, so all other transactions need to save live variables. ret = choose_code_path(prop, disp); if (!(tx->state & STATE_IRREVOCABLE)) ret |= a_saveLiveVariables; return ret; } void GTM::gtm_transaction_cp::save(gtm_thread* tx) { // Save everything that we might have to restore on restarts or aborts. jb = tx->jb; undolog_size = tx->undolog.size(); /* FIXME! Assignment of an aatree like alloc_actions is unsafe; if either *this or *tx is destroyed, the other ends up pointing to a freed node. */ #pragma GCC diagnostic warning "-Wdeprecated-copy" alloc_actions = tx->alloc_actions; user_actions_size = tx->user_actions.size(); id = tx->id; prop = tx->prop; cxa_catch_count = tx->cxa_catch_count; cxa_uncaught_count = tx->cxa_uncaught_count; disp = abi_disp(); nesting = tx->nesting; } void GTM::gtm_transaction_cp::commit(gtm_thread* tx) { // Restore state that is not persistent across commits. Exception handling, // information, nesting level, and any logs do not need to be restored on // commits of nested transactions. Allocation actions must be committed // before committing the snapshot. tx->jb = jb; tx->alloc_actions = alloc_actions; tx->id = id; tx->prop = prop; } void GTM::gtm_thread::rollback (gtm_transaction_cp *cp, bool aborting) { // The undo log is special in that it used for both thread-local and shared // data. Because of the latter, we have to roll it back before any // dispatch-specific rollback (which handles synchronization with other // transactions). undolog.rollback (this, cp ? cp->undolog_size : 0); // Perform dispatch-specific rollback. abi_disp()->rollback (cp); // Roll back all actions that are supposed to happen around the transaction. rollback_user_actions (cp ? cp->user_actions_size : 0); commit_allocations (true, (cp ? &cp->alloc_actions : 0)); revert_cpp_exceptions (cp); if (cp) { // We do not yet handle restarts of nested transactions. To do that, we // would have to restore some state (jb, id, prop, nesting) not to the // checkpoint but to the transaction that was started from this // checkpoint (e.g., nesting = cp->nesting + 1); assert(aborting); // Roll back the rest of the state to the checkpoint. jb = cp->jb; id = cp->id; prop = cp->prop; if (cp->disp != abi_disp()) set_abi_disp(cp->disp); alloc_actions = cp->alloc_actions; nesting = cp->nesting; } else { // Roll back to the outermost transaction. // Restore the jump buffer and transaction properties, which we will // need for the longjmp used to restart or abort the transaction. if (parent_txns.size() > 0) { jb = parent_txns[0].jb; id = parent_txns[0].id; prop = parent_txns[0].prop; } // Reset the transaction. Do not reset this->state, which is handled by // the callers. Note that if we are not aborting, we reset the // transaction to the point after having executed begin_transaction // (we will return from it), so the nesting level must be one, not zero. nesting = (aborting ? 0 : 1); parent_txns.clear(); } if (this->eh_in_flight) { _Unwind_DeleteException ((_Unwind_Exception *) this->eh_in_flight); this->eh_in_flight = NULL; } } void ITM_REGPARM _ITM_abortTransaction (_ITM_abortReason reason) { gtm_thread *tx = gtm_thr(); assert (reason == userAbort || reason == (userAbort | outerAbort)); assert ((tx->prop & pr_hasNoAbort) == 0); if (tx->state & gtm_thread::STATE_IRREVOCABLE) abort (); // Roll back to innermost transaction. if (tx->parent_txns.size() > 0 && !(reason & outerAbort)) { // If the current method does not support closed nesting but we are // nested and must only roll back the innermost transaction, then // restart with a method that supports closed nesting. abi_dispatch *disp = abi_disp(); if (!disp->closed_nesting()) tx->restart(RESTART_CLOSED_NESTING); // The innermost transaction is a closed nested transaction. gtm_transaction_cp *cp = tx->parent_txns.pop(); uint32_t longjmp_prop = tx->prop; gtm_jmpbuf longjmp_jb = tx->jb; tx->rollback (cp, true); // Jump to nested transaction (use the saved jump buffer). GTM_longjmp (a_abortTransaction | a_restoreLiveVariables, &longjmp_jb, longjmp_prop); } else { // There is no nested transaction or an abort of the outermost // transaction was requested, so roll back to the outermost transaction. tx->rollback (0, true); // Aborting an outermost transaction finishes execution of the whole // transaction. Therefore, reset transaction state. if (tx->state & gtm_thread::STATE_SERIAL) gtm_thread::serial_lock.write_unlock (); else gtm_thread::serial_lock.read_unlock (tx); tx->state = 0; GTM_longjmp (a_abortTransaction | a_restoreLiveVariables, &tx->jb, tx->prop); } } bool GTM::gtm_thread::trycommit () { nesting--; // Skip any real commit for elided transactions. if (nesting > 0 && (parent_txns.size() == 0 || nesting > parent_txns[parent_txns.size() - 1].nesting)) return true; if (nesting > 0) { // Commit of a closed-nested transaction. Remove one checkpoint and add // any effects of this transaction to the parent transaction. gtm_transaction_cp *cp = parent_txns.pop(); commit_allocations(false, &cp->alloc_actions); cp->commit(this); return true; } // Commit of an outermost transaction. gtm_word priv_time = 0; if (abi_disp()->trycommit (priv_time)) { // The transaction is now finished but we will still access some shared // data if we have to ensure privatization safety. bool do_read_unlock = false; if (state & gtm_thread::STATE_SERIAL) { gtm_thread::serial_lock.write_unlock (); // There are no other active transactions, so there's no need to // enforce privatization safety. priv_time = 0; } else { // If we have to ensure privatization safety, we must not yet // release the read lock and become inactive because (1) we still // have to go through the list of all transactions, which can be // modified by serial mode threads, and (2) we interpret each // transactions' shared_state in the context of what we believe to // be the current method group (and serial mode transactions can // change the method group). Therefore, if we have to ensure // privatization safety, delay becoming inactive but set a maximum // snapshot time (we have committed and thus have an empty snapshot, // so it will always be most recent). Use release MO so that this // synchronizes with other threads observing our snapshot time. if (priv_time) { do_read_unlock = true; shared_state.store((~(typeof gtm_thread::shared_state)0) - 1, memory_order_release); } else gtm_thread::serial_lock.read_unlock (this); } state = 0; // We can commit the undo log after dispatch-specific commit and after // making the transaction inactive because we only have to reset // gtm_thread state. undolog.commit (); // Reset further transaction state. cxa_catch_count = 0; restart_total = 0; // Ensure privatization safety, if necessary. if (priv_time) { // There must be a seq_cst fence between the following loads of the // other transactions' shared_state and the dispatch-specific stores // that signal updates by this transaction (e.g., lock // acquisitions). This ensures that if we read prior to other // reader transactions setting their shared_state to 0, then those // readers will observe our updates. We can reuse the seq_cst fence // in serial_lock.read_unlock() if we performed that; if not, we // issue the fence. if (do_read_unlock) atomic_thread_fence (memory_order_seq_cst); // TODO Don't just spin but also block using cond vars / futexes // here. Should probably be integrated with the serial lock code. for (gtm_thread *it = gtm_thread::list_of_threads; it != 0; it = it->next_thread) { if (it == this) continue; // We need to load other threads' shared_state using acquire // semantics (matching the release semantics of the respective // updates). This is necessary to ensure that the other // threads' memory accesses happen before our actions that // assume privatization safety. // TODO Are there any platform-specific optimizations (e.g., // merging barriers)? while (it->shared_state.load(memory_order_acquire) < priv_time) cpu_relax(); } } // After ensuring privatization safety, we are now truly inactive and // thus can release the read lock. We will also execute potentially // privatizing actions (e.g., calling free()). User actions are first. if (do_read_unlock) gtm_thread::serial_lock.read_unlock (this); commit_user_actions (); commit_allocations (false, 0); return true; } return false; } void ITM_NORETURN GTM::gtm_thread::restart (gtm_restart_reason r, bool finish_serial_upgrade) { // Roll back to outermost transaction. Do not reset transaction state because // we will continue executing this transaction. rollback (); // If we have to restart while an upgrade of the serial lock is happening, // we need to finish this here, after rollback (to ensure privatization // safety despite undo writes) and before deciding about the retry strategy // (which could switch to/from serial mode). if (finish_serial_upgrade) gtm_thread::serial_lock.write_upgrade_finish(this); decide_retry_strategy (r); // Run dispatch-specific restart code. Retry until we succeed. abi_dispatch* disp = abi_disp(); GTM::gtm_restart_reason rr; while ((rr = disp->begin_or_restart()) != NO_RESTART) { decide_retry_strategy(rr); disp = abi_disp(); } GTM_longjmp (choose_code_path(prop, disp) | a_restoreLiveVariables, &jb, prop); } void ITM_REGPARM _ITM_commitTransaction(void) { #if defined(USE_HTM_FASTPATH) // HTM fastpath. If we are not executing a HW transaction, then we will be // a serial-mode transaction. If we are, then there will be no other // concurrent serial-mode transaction. // See gtm_thread::begin_transaction. if (likely(!gtm_thread::serial_lock.htm_fastpath_disabled())) { htm_commit(); return; } #endif gtm_thread *tx = gtm_thr(); if (!tx->trycommit ()) tx->restart (RESTART_VALIDATE_COMMIT); } void ITM_REGPARM _ITM_commitTransactionEH(void *exc_ptr) { #if defined(USE_HTM_FASTPATH) // See _ITM_commitTransaction. if (likely(!gtm_thread::serial_lock.htm_fastpath_disabled())) { htm_commit(); return; } #endif gtm_thread *tx = gtm_thr(); if (!tx->trycommit ()) { tx->eh_in_flight = exc_ptr; tx->restart (RESTART_VALIDATE_COMMIT); } }