gcc/libitm/libitm_i.h

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/* Copyright (C) 2008-2015 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/>. */
/* The following are internal implementation functions and definitions.
To distinguish them from those defined by the Intel ABI, they all
begin with GTM/gtm. */
#ifndef LIBITM_I_H
#define LIBITM_I_H 1
#include "libitm.h"
#include "config.h"
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include <unwind.h>
#include "local_type_traits"
#include "local_atomic"
/* Don't require libgcc_s.so for exceptions. */
extern void _Unwind_DeleteException (_Unwind_Exception*) __attribute__((weak));
#include "common.h"
namespace GTM HIDDEN {
using namespace std;
// A helper template for accessing an unsigned integral of SIZE bytes.
template<size_t SIZE> struct sized_integral { };
template<> struct sized_integral<1> { typedef uint8_t type; };
template<> struct sized_integral<2> { typedef uint16_t type; };
template<> struct sized_integral<4> { typedef uint32_t type; };
template<> struct sized_integral<8> { typedef uint64_t type; };
typedef unsigned int gtm_word __attribute__((mode (word)));
// These values are given to GTM_restart_transaction and indicate the
// reason for the restart. The reason is used to decide what STM
// implementation should be used during the next iteration.
enum gtm_restart_reason
{
RESTART_REALLOCATE,
RESTART_LOCKED_READ,
RESTART_LOCKED_WRITE,
RESTART_VALIDATE_READ,
RESTART_VALIDATE_WRITE,
RESTART_VALIDATE_COMMIT,
RESTART_SERIAL_IRR,
RESTART_NOT_READONLY,
RESTART_CLOSED_NESTING,
RESTART_INIT_METHOD_GROUP,
NUM_RESTARTS,
NO_RESTART = NUM_RESTARTS
};
} // namespace GTM
#include "target.h"
#include "rwlock.h"
#include "aatree.h"
#include "cacheline.h"
#include "stmlock.h"
#include "dispatch.h"
#include "containers.h"
#ifdef __USER_LABEL_PREFIX__
# define UPFX UPFX1(__USER_LABEL_PREFIX__)
# define UPFX1(t) UPFX2(t)
# define UPFX2(t) #t
#else
# define UPFX
#endif
namespace GTM HIDDEN {
// A log of (de)allocation actions. We defer handling of some actions until
// a commit of the outermost transaction. We also rely on potentially having
// both an allocation and a deallocation for the same piece of memory in the
// log; the order in which such entries are processed does not matter because
// the actions are not in conflict (see below).
// This type is private to alloc.c, but needs to be defined so that
// the template used inside gtm_thread can instantiate.
struct gtm_alloc_action
{
// Iff free_fn_sz is nonzero, it must be used instead of free_fn.
union
{
void (*free_fn)(void *);
void (*free_fn_sz)(void *, size_t);
};
size_t sz;
// If true, this is an allocation; we discard the log entry on outermost
// commit, and deallocate on abort. If false, this is a deallocation and
// we deallocate on outermost commit and discard the log entry on abort.
bool allocated;
};
struct gtm_thread;
// A transaction checkpoint: data that has to saved and restored when doing
// closed nesting.
struct gtm_transaction_cp
{
gtm_jmpbuf jb;
size_t undolog_size;
aa_tree<uintptr_t, gtm_alloc_action> alloc_actions;
size_t user_actions_size;
_ITM_transactionId_t id;
uint32_t prop;
uint32_t cxa_catch_count;
unsigned int cxa_uncaught_count;
// We might want to use a different but compatible dispatch method for
// a nested transaction.
abi_dispatch *disp;
// Nesting level of this checkpoint (1 means that this is a checkpoint of
// the outermost transaction).
uint32_t nesting;
void save(gtm_thread* tx);
void commit(gtm_thread* tx);
};
// An undo log for writes.
struct gtm_undolog
{
vector<gtm_word> undolog;
// Log the previous value at a certain address.
// The easiest way to inline this is to just define this here.
void log(const void *ptr, size_t len)
{
size_t words = (len + sizeof(gtm_word) - 1) / sizeof(gtm_word);
gtm_word *undo = undolog.push(words + 2);
memcpy(undo, ptr, len);
undo[words] = len;
undo[words + 1] = (gtm_word) ptr;
}
void commit () { undolog.clear(); }
size_t size() const { return undolog.size(); }
// In local.cc
void rollback (gtm_thread* tx, size_t until_size = 0);
};
// An entry of a read or write log. Used by multi-lock TM methods.
struct gtm_rwlog_entry
{
atomic<gtm_word> *orec;
gtm_word value;
};
// Contains all thread-specific data required by the entire library.
// This includes all data relevant to a single transaction. Because most
// thread-specific data is about the current transaction, we also refer to
// the transaction-specific parts of gtm_thread as "the transaction" (the
// same applies to names of variables and arguments).
// All but the shared part of this data structure are thread-local data.
// gtm_thread could be split into transaction-specific structures and other
// per-thread data (with those parts then nested in gtm_thread), but this
// would make it harder to later rearrange individual members to optimize data
// accesses. Thus, for now we keep one flat object, and will only split it if
// the code gets too messy.
struct gtm_thread
{
struct user_action
{
_ITM_userCommitFunction fn;
void *arg;
bool on_commit;
_ITM_transactionId_t resuming_id;
};
// The jump buffer by which GTM_longjmp restarts the transaction.
// This field *must* be at the beginning of the transaction.
gtm_jmpbuf jb;
// Data used by local.c for the undo log for both local and shared memory.
gtm_undolog undolog;
// Read and write logs. Used by multi-lock TM methods.
vector<gtm_rwlog_entry> readlog;
vector<gtm_rwlog_entry> writelog;
// Data used by alloc.c for the malloc/free undo log.
aa_tree<uintptr_t, gtm_alloc_action> alloc_actions;
// Data used by useraction.c for the user-defined commit/abort handlers.
vector<user_action> user_actions;
// A numerical identifier for this transaction.
_ITM_transactionId_t id;
// The _ITM_codeProperties of this transaction as given by the compiler.
uint32_t prop;
// The nesting depth for subsequently started transactions. This variable
// will be set to 1 when starting an outermost transaction.
uint32_t nesting;
// Set if this transaction owns the serial write lock.
// Can be reset only when restarting the outermost transaction.
static const uint32_t STATE_SERIAL = 0x0001;
// Set if the serial-irrevocable dispatch table is installed.
// Implies that no logging is being done, and abort is not possible.
// Can be reset only when restarting the outermost transaction.
static const uint32_t STATE_IRREVOCABLE = 0x0002;
// A bitmask of the above.
uint32_t state;
// In order to reduce cacheline contention on global_tid during
// beginTransaction, we allocate a block of 2**N ids to the thread
// all at once. This number is the next value to be allocated from
// the block, or 0 % 2**N if no such block is allocated.
_ITM_transactionId_t local_tid;
// Data used by eh_cpp.c for managing exceptions within the transaction.
uint32_t cxa_catch_count;
// If cxa_uncaught_count_ptr is 0, we don't need to roll back exceptions.
unsigned int *cxa_uncaught_count_ptr;
unsigned int cxa_uncaught_count;
void *eh_in_flight;
// Checkpoints for closed nesting.
vector<gtm_transaction_cp> parent_txns;
// Data used by retry.c for deciding what STM implementation should
// be used for the next iteration of the transaction.
// Only restart_total is reset to zero when the transaction commits, the
// other counters are total values for all previously executed transactions.
// restart_total is also used by the HTM fastpath in a different way.
uint32_t restart_reason[NUM_RESTARTS];
uint32_t restart_total;
// *** The shared part of gtm_thread starts here. ***
// Shared state is on separate cachelines to avoid false sharing with
// thread-local parts of gtm_thread.
// Points to the next thread in the list of all threads.
gtm_thread *next_thread __attribute__((__aligned__(HW_CACHELINE_SIZE)));
// If this transaction is inactive, shared_state is ~0. Otherwise, this is
// an active or serial transaction.
atomic<gtm_word> shared_state;
// The lock that provides access to serial mode. Non-serialized
// transactions acquire read locks; a serialized transaction aquires
// a write lock.
// Accessed from assembly language, thus the "asm" specifier on
// the name, avoiding complex name mangling.
static gtm_rwlock serial_lock __asm__(UPFX "gtm_serial_lock");
// The head of the list of all threads' transactions.
static gtm_thread *list_of_threads;
// The number of all registered threads.
static unsigned number_of_threads;
// In alloc.cc
void commit_allocations (bool, aa_tree<uintptr_t, gtm_alloc_action>*);
void record_allocation (void *, void (*)(void *));
void forget_allocation (void *, void (*)(void *));
void forget_allocation (void *, size_t, void (*)(void *, size_t));
void discard_allocation (const void *ptr)
{
alloc_actions.erase((uintptr_t) ptr);
}
// In beginend.cc
void rollback (gtm_transaction_cp *cp = 0, bool aborting = false);
bool trycommit ();
void restart (gtm_restart_reason, bool finish_serial_upgrade = false)
ITM_NORETURN;
gtm_thread();
~gtm_thread();
static void *operator new(size_t);
static void operator delete(void *);
// Invoked from assembly language, thus the "asm" specifier on
// the name, avoiding complex name mangling.
static uint32_t begin_transaction(uint32_t, const gtm_jmpbuf *)
__asm__(UPFX "GTM_begin_transaction") ITM_REGPARM;
// In eh_cpp.cc
void init_cpp_exceptions ();
void revert_cpp_exceptions (gtm_transaction_cp *cp = 0);
// In retry.cc
// Must be called outside of transactions (i.e., after rollback).
void decide_retry_strategy (gtm_restart_reason);
abi_dispatch* decide_begin_dispatch (uint32_t prop);
void number_of_threads_changed(unsigned previous, unsigned now);
// Must be called from serial mode. Does not call set_abi_disp().
void set_default_dispatch(abi_dispatch* disp);
// In method-serial.cc
void serialirr_mode ();
// In useraction.cc
void rollback_user_actions (size_t until_size = 0);
void commit_user_actions ();
};
} // namespace GTM
#include "tls.h"
namespace GTM HIDDEN {
// An unscaled count of the number of times we should spin attempting to
// acquire locks before we block the current thread and defer to the OS.
// This variable isn't used when the standard POSIX lock implementations
// are used.
extern uint64_t gtm_spin_count_var;
extern "C" uint32_t GTM_longjmp (uint32_t, const gtm_jmpbuf *, uint32_t)
ITM_NORETURN ITM_REGPARM;
extern "C" void GTM_LB (const void *, size_t) ITM_REGPARM;
extern void GTM_error (const char *fmt, ...)
__attribute__((format (printf, 1, 2)));
extern void GTM_fatal (const char *fmt, ...)
__attribute__((noreturn, format (printf, 1, 2)));
extern abi_dispatch *dispatch_serial();
extern abi_dispatch *dispatch_serialirr();
extern abi_dispatch *dispatch_serialirr_onwrite();
extern abi_dispatch *dispatch_gl_wt();
extern abi_dispatch *dispatch_ml_wt();
extern abi_dispatch *dispatch_htm();
extern gtm_cacheline_mask gtm_mask_stack(gtm_cacheline *, gtm_cacheline_mask);
// Control variable for the HTM fastpath that uses serial mode as fallback.
// Non-zero if the HTM fastpath is enabled. See gtm_thread::begin_transaction.
// Accessed from assembly language, thus the "asm" specifier on
// the name, avoiding complex name mangling.
extern uint32_t htm_fastpath __asm__(UPFX "gtm_htm_fastpath");
} // namespace GTM
#endif // LIBITM_I_H