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Like in r12-7519-g027e30414492d50feb2854aff38227b14300dc4b, I've done git grep -v 'long long\|optab optab\|template template\|double double' | grep ' \([a-zA-Z]\+\) \1 ' This is just part of the changes, mostly for non-gcc directories. I'll try to get to the rest soon. Obviously, the above command also finds cases which are correct as is and shouldn't be changed, so one needs to manually inspect everything. I'd hope most of it is pretty obvious, but the config/ and libstdc++-v3/ hunks include a tweak in a license wording, though other copies of the similar license have the wording right. 2024-04-02 Jakub Jelinek <jakub@redhat.com> * Makefile.tpl: Fix duplicated words; returns returns -> returns. config/ * lcmessage.m4: Fix duplicated words; can can -> can, package package -> package. libdecnumber/ * decCommon.c (decFinalize): Fix duplicated words in comment; the the -> the. libgcc/ * unwind-dw2-fde.c (struct fde_accumulator): Fix duplicated words in comment; is is -> is. libgfortran/ * configure.host: Fix duplicated words; the the -> the. libgm2/ * configure.host: Fix duplicated words; the the -> the. libgomp/ * libgomp.texi (OpenMP 5.2): Fix duplicated words; with with -> with. (omp_target_associate_ptr): Fix duplicated words; either either -> either. (omp_init_allocator): Fix duplicated words; be be -> be. (omp_realloc): Fix duplicated words; is is -> is. (OMP_ALLOCATOR): Fix duplicated words; other other -> other. * priority_queue.h (priority_queue_multi_p): Fix duplicated words; to to -> to. libiberty/ * regex.c (byte_re_match_2_internal): Fix duplicated words in comment; next next -> next. * dyn-string.c (dyn_string_init): Fix duplicated words in comment; of of -> of. libitm/ * beginend.cc (GTM::gtm_thread::begin_transaction): Fix duplicated words in comment; not not -> not to. libobjc/ * init.c (duplicate_classes): Fix duplicated words in comment; in in -> in. * sendmsg.c (__objc_prepare_dtable_for_class): Fix duplicated words in comment; the the -> the. * encoding.c (objc_layout_structure): Likewise. libstdc++-v3/ * acinclude.m4: Fix duplicated words; file file -> file can. * configure.host: Fix duplicated words; the the -> the. libvtv/ * vtv_rts.cc (vtv_fail): Fix duplicated words; to to -> to. * vtv_fail.cc (vtv_fail): Likewise.
749 lines
26 KiB
C++
749 lines
26 KiB
C++
/* Copyright (C) 2008-2024 Free Software Foundation, Inc.
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Contributed by Richard Henderson <rth@redhat.com>.
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This file is part of the GNU Transactional Memory Library (libitm).
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Libitm is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by
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the Free Software Foundation; either version 3 of the License, or
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(at your option) any later version.
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Libitm is distributed in the hope that it will be useful, but WITHOUT ANY
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WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
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FOR A PARTICULAR PURPOSE. See the GNU General Public License for
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more details.
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Under Section 7 of GPL version 3, you are granted additional
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permissions described in the GCC Runtime Library Exception, version
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3.1, as published by the Free Software Foundation.
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You should have received a copy of the GNU General Public License and
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a copy of the GCC Runtime Library Exception along with this program;
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see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
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<http://www.gnu.org/licenses/>. */
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#include "libitm_i.h"
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#include <pthread.h>
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using namespace GTM;
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#if !defined(HAVE_ARCH_GTM_THREAD) || !defined(HAVE_ARCH_GTM_THREAD_DISP)
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extern __thread gtm_thread_tls _gtm_thr_tls;
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#endif
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// Put this at the start of a cacheline so that serial_lock's writers and
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// htm_fastpath fields are on the same cacheline, so that HW transactions
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// only have to pay one cacheline capacity to monitor both.
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gtm_rwlock GTM::gtm_thread::serial_lock
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__attribute__((aligned(HW_CACHELINE_SIZE)));
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gtm_thread *GTM::gtm_thread::list_of_threads = 0;
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unsigned GTM::gtm_thread::number_of_threads = 0;
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/* ??? Move elsewhere when we figure out library initialization. */
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uint64_t GTM::gtm_spin_count_var = 1000;
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#ifdef HAVE_64BIT_SYNC_BUILTINS
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static atomic<_ITM_transactionId_t> global_tid;
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#else
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static _ITM_transactionId_t global_tid;
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static pthread_mutex_t global_tid_lock = PTHREAD_MUTEX_INITIALIZER;
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#endif
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// Provides a on-thread-exit callback used to release per-thread data.
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static pthread_key_t thr_release_key;
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static pthread_once_t thr_release_once = PTHREAD_ONCE_INIT;
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/* Allocate a transaction structure. */
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void *
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GTM::gtm_thread::operator new (size_t s)
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{
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void *tx;
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assert(s == sizeof(gtm_thread));
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tx = xmalloc (sizeof (gtm_thread), true);
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memset (tx, 0, sizeof (gtm_thread));
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return tx;
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}
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/* Free the given transaction. Raises an error if the transaction is still
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in use. */
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void
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GTM::gtm_thread::operator delete(void *tx)
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{
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free(tx);
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}
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static void
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thread_exit_handler(void *)
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{
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gtm_thread *thr = gtm_thr();
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if (thr)
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delete thr;
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set_gtm_thr(0);
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}
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static void
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thread_exit_init()
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{
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if (pthread_key_create(&thr_release_key, thread_exit_handler))
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GTM_fatal("Creating thread release TLS key failed.");
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}
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GTM::gtm_thread::~gtm_thread()
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{
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if (nesting > 0)
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GTM_fatal("Thread exit while a transaction is still active.");
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// Deregister this transaction.
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serial_lock.write_lock ();
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gtm_thread **prev = &list_of_threads;
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for (; *prev; prev = &(*prev)->next_thread)
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{
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if (*prev == this)
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{
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*prev = (*prev)->next_thread;
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break;
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}
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}
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number_of_threads--;
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number_of_threads_changed(number_of_threads + 1, number_of_threads);
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serial_lock.write_unlock ();
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}
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GTM::gtm_thread::gtm_thread ()
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{
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// This object's memory has been set to zero by operator new, so no need
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// to initialize any of the other primitive-type members that do not have
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// constructors.
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shared_state.store(-1, memory_order_relaxed);
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// Register this transaction with the list of all threads' transactions.
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serial_lock.write_lock ();
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next_thread = list_of_threads;
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list_of_threads = this;
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number_of_threads++;
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number_of_threads_changed(number_of_threads - 1, number_of_threads);
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serial_lock.write_unlock ();
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init_cpp_exceptions ();
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if (pthread_once(&thr_release_once, thread_exit_init))
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GTM_fatal("Initializing thread release TLS key failed.");
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// Any non-null value is sufficient to trigger destruction of this
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// transaction when the current thread terminates.
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if (pthread_setspecific(thr_release_key, this))
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GTM_fatal("Setting thread release TLS key failed.");
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}
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static inline uint32_t
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choose_code_path(uint32_t prop, abi_dispatch *disp)
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{
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if ((prop & pr_uninstrumentedCode) && disp->can_run_uninstrumented_code())
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return a_runUninstrumentedCode;
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else
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return a_runInstrumentedCode;
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}
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#ifdef TARGET_BEGIN_TRANSACTION_ATTRIBUTE
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/* This macro can be used to define target specific attributes for this
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function. For example, S/390 requires floating point to be disabled in
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begin_transaction. */
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TARGET_BEGIN_TRANSACTION_ATTRIBUTE
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#endif
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uint32_t
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GTM::gtm_thread::begin_transaction (uint32_t prop, const gtm_jmpbuf *jb)
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{
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static const _ITM_transactionId_t tid_block_size = 1 << 16;
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gtm_thread *tx;
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abi_dispatch *disp;
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uint32_t ret;
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// ??? pr_undoLogCode is not properly defined in the ABI. Are barriers
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// omitted because they are not necessary (e.g., a transaction on thread-
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// local data) or because the compiler thinks that some kind of global
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// synchronization might perform better?
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if (unlikely(prop & pr_undoLogCode))
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GTM_fatal("pr_undoLogCode not supported");
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#ifdef USE_HTM_FASTPATH
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// HTM fastpath. Only chosen in the absence of transaction_cancel to allow
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// using an uninstrumented code path.
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// The fastpath is enabled only by dispatch_htm's method group, which uses
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// serial-mode methods as fallback. Serial-mode transactions cannot execute
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// concurrently with HW transactions because the latter monitor the serial
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// lock's writer flag and thus abort if another thread is or becomes a
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// serial transaction. Therefore, if the fastpath is enabled, then a
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// transaction is not executing as a HW transaction iff the serial lock is
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// write-locked. Also, HW transactions monitor the fastpath control
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// variable, so that they will only execute if dispatch_htm is still the
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// current method group. This allows us to use htm_fastpath and the serial
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// lock's writers flag to reliable determine whether the current thread runs
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// a HW transaction, and thus we do not need to maintain this information in
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// per-thread state.
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// If an uninstrumented code path is not available, we can still run
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// instrumented code from a HW transaction because the HTM fastpath kicks
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// in early in both begin and commit, and the transaction is not canceled.
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// HW transactions might get requests to switch to serial-irrevocable mode,
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// but these can be ignored because the HTM provides all necessary
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// correctness guarantees. Transactions cannot detect whether they are
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// indeed in serial mode, and HW transactions should never need serial mode
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// for any internal changes (e.g., they never abort visibly to the STM code
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// and thus do not trigger the standard retry handling).
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#ifndef HTM_CUSTOM_FASTPATH
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if (likely(serial_lock.get_htm_fastpath() && (prop & pr_hasNoAbort)))
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{
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// Note that the snapshot of htm_fastpath that we take here could be
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// outdated, and a different method group than dispatch_htm may have
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// been chosen in the meantime. Therefore, take care not to touch
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// anything besides the serial lock, which is independent of method
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// groups.
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for (uint32_t t = serial_lock.get_htm_fastpath(); t; t--)
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{
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uint32_t ret = htm_begin();
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if (htm_begin_success(ret))
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{
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// We are executing a transaction now.
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// Monitor the writer flag in the serial-mode lock, and abort
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// if there is an active or waiting serial-mode transaction.
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// Also checks that htm_fastpath is still nonzero and thus
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// HW transactions are allowed to run.
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// Note that this can also happen due to an enclosing
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// serial-mode transaction; we handle this case below.
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if (unlikely(serial_lock.htm_fastpath_disabled()))
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htm_abort();
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else
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// We do not need to set a_saveLiveVariables because of HTM.
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return (prop & pr_uninstrumentedCode) ?
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a_runUninstrumentedCode : a_runInstrumentedCode;
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}
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// The transaction has aborted. Don't retry if it's unlikely that
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// retrying the transaction will be successful.
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if (!htm_abort_should_retry(ret))
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break;
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// Check whether the HTM fastpath has been disabled.
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if (!serial_lock.get_htm_fastpath())
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break;
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// Wait until any concurrent serial-mode transactions have finished.
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// This is an empty critical section, but won't be elided.
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if (serial_lock.htm_fastpath_disabled())
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{
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tx = gtm_thr();
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if (unlikely(tx == NULL))
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{
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// See below.
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tx = new gtm_thread();
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set_gtm_thr(tx);
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}
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// Check whether there is an enclosing serial-mode transaction;
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// if so, we just continue as a nested transaction and don't
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// try to use the HTM fastpath. This case can happen when an
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// outermost relaxed transaction calls unsafe code that starts
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// a transaction.
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if (tx->nesting > 0)
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break;
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// Another thread is running a serial-mode transaction. Wait.
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serial_lock.read_lock(tx);
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serial_lock.read_unlock(tx);
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// TODO We should probably reset the retry count t here, unless
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// we have retried so often that we should go serial to avoid
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// starvation.
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}
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}
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}
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#else
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// If we have a custom HTM fastpath in ITM_beginTransaction, we implement
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// just the retry policy here. We communicate with the custom fastpath
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// through additional property bits and return codes, and either transfer
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// control back to the custom fastpath or run the fallback mechanism. The
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// fastpath synchronization algorithm itself is the same.
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// pr_HTMRetryableAbort states that a HW transaction started by the custom
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// HTM fastpath aborted, and that we thus have to decide whether to retry
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// the fastpath (returning a_tryHTMFastPath) or just proceed with the
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// fallback method.
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if (likely(serial_lock.get_htm_fastpath() && (prop & pr_HTMRetryableAbort)))
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{
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tx = gtm_thr();
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if (unlikely(tx == NULL))
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{
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// See below.
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tx = new gtm_thread();
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set_gtm_thr(tx);
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}
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// If this is the first abort, reset the retry count. We abuse
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// restart_total for the retry count, which is fine because our only
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// other fallback will use serial transactions, which don't use
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// restart_total but will reset it when committing.
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if (!(prop & pr_HTMRetriedAfterAbort))
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tx->restart_total = gtm_thread::serial_lock.get_htm_fastpath();
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if (--tx->restart_total > 0)
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{
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// Wait until any concurrent serial-mode transactions have finished.
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// Essentially the same code as above.
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if (!serial_lock.get_htm_fastpath())
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goto stop_custom_htm_fastpath;
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if (serial_lock.htm_fastpath_disabled())
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{
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if (tx->nesting > 0)
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goto stop_custom_htm_fastpath;
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serial_lock.read_lock(tx);
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serial_lock.read_unlock(tx);
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}
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// Let ITM_beginTransaction retry the custom HTM fastpath.
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return a_tryHTMFastPath;
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}
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}
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stop_custom_htm_fastpath:
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#endif
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#endif
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tx = gtm_thr();
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if (unlikely(tx == NULL))
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{
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// Create the thread object. The constructor will also set up automatic
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// deletion on thread termination.
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tx = new gtm_thread();
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set_gtm_thr(tx);
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}
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if (tx->nesting > 0)
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{
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// This is a nested transaction.
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// Check prop compatibility:
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// The ABI requires pr_hasNoFloatUpdate, pr_hasNoVectorUpdate,
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// pr_hasNoIrrevocable, pr_aWBarriersOmitted, pr_RaRBarriersOmitted, and
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// pr_hasNoSimpleReads to hold for the full dynamic scope of a
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// transaction. We could check that these are set for the nested
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// transaction if they are also set for the parent transaction, but the
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// ABI does not require these flags to be set if they could be set,
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// so the check could be too strict.
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// ??? For pr_readOnly, lexical or dynamic scope is unspecified.
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if (prop & pr_hasNoAbort)
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{
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// We can use flat nesting, so elide this transaction.
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if (!(prop & pr_instrumentedCode))
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{
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if (!(tx->state & STATE_SERIAL) ||
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!(tx->state & STATE_IRREVOCABLE))
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tx->serialirr_mode();
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}
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// Increment nesting level after checking that we have a method that
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// allows us to continue.
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tx->nesting++;
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return choose_code_path(prop, abi_disp());
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}
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// The transaction might abort, so use closed nesting if possible.
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// pr_hasNoAbort has lexical scope, so the compiler should really have
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// generated an instrumented code path.
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assert(prop & pr_instrumentedCode);
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// Create a checkpoint of the current transaction.
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gtm_transaction_cp *cp = tx->parent_txns.push();
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cp->save(tx);
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new (&tx->alloc_actions) aa_tree<uintptr_t, gtm_alloc_action>();
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// Check whether the current method actually supports closed nesting.
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// If we can switch to another one, do so.
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// If not, we assume that actual aborts are infrequent, and rather
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// restart in _ITM_abortTransaction when we really have to.
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disp = abi_disp();
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if (!disp->closed_nesting())
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{
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// ??? Should we elide the transaction if there is no alternative
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// method that supports closed nesting? If we do, we need to set
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// some flag to prevent _ITM_abortTransaction from aborting the
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// wrong transaction (i.e., some parent transaction).
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abi_dispatch *cn_disp = disp->closed_nesting_alternative();
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if (cn_disp)
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{
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disp = cn_disp;
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set_abi_disp(disp);
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}
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}
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}
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else
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{
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// Outermost transaction
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disp = tx->decide_begin_dispatch (prop);
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set_abi_disp (disp);
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}
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// Initialization that is common for outermost and nested transactions.
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tx->prop = prop;
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tx->nesting++;
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tx->jb = *jb;
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// As long as we have not exhausted a previously allocated block of TIDs,
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// we can avoid an atomic operation on a shared cacheline.
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if (tx->local_tid & (tid_block_size - 1))
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tx->id = tx->local_tid++;
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else
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{
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#ifdef HAVE_64BIT_SYNC_BUILTINS
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// We don't really care which block of TIDs we get but only that we
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// acquire one atomically; therefore, relaxed memory order is
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// sufficient.
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tx->id = global_tid.fetch_add(tid_block_size, memory_order_relaxed);
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tx->local_tid = tx->id + 1;
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#else
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pthread_mutex_lock (&global_tid_lock);
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global_tid += tid_block_size;
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tx->id = global_tid;
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tx->local_tid = tx->id + 1;
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pthread_mutex_unlock (&global_tid_lock);
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#endif
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}
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// Log the number of uncaught exceptions if we might have to roll back this
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// state.
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if (tx->cxa_uncaught_count_ptr != 0)
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tx->cxa_uncaught_count = *tx->cxa_uncaught_count_ptr;
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// Run dispatch-specific restart code. Retry until we succeed.
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GTM::gtm_restart_reason rr;
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while ((rr = disp->begin_or_restart()) != NO_RESTART)
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{
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tx->decide_retry_strategy(rr);
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disp = abi_disp();
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}
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// Determine the code path to run. Only irrevocable transactions cannot be
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// restarted, so all other transactions need to save live variables.
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ret = choose_code_path(prop, disp);
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if (!(tx->state & STATE_IRREVOCABLE))
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ret |= a_saveLiveVariables;
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return ret;
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}
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void
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GTM::gtm_transaction_cp::save(gtm_thread* tx)
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{
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// Save everything that we might have to restore on restarts or aborts.
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jb = tx->jb;
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undolog_size = tx->undolog.size();
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/* FIXME! Assignment of an aatree like alloc_actions is unsafe; if either
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*this or *tx is destroyed, the other ends up pointing to a freed node. */
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#pragma GCC diagnostic warning "-Wdeprecated-copy"
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alloc_actions = tx->alloc_actions;
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user_actions_size = tx->user_actions.size();
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id = tx->id;
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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);
|
|
}
|
|
}
|