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nexedi
cython
Commits
3de2efaf
Commit
3de2efaf
authored
Jun 20, 2019
by
gsamain
Committed by
Xavier Thompson
Aug 17, 2020
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CyObjects utility for locks
parent
ef4bbc54
Changes
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Cython/Utility/CyObjects.cpp
Cython/Utility/CyObjects.cpp
+288
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Cython/Utility/CyObjects.cpp
View file @
3de2efaf
...
...
@@ -17,14 +17,60 @@
using
namespace
std
;
#define CyObject_ATOMIC_REFCOUNT_TYPE atomic_int
#include <pthread.h>
#include <sys/types.h>
#include <unistd.h>
#include <sys/syscall.h>
#include <vector>
struct
ThreadStorage
{
pid_t
thread_id
;
unsigned
int
read_count
;
unsigned
int
write_count
;
};
class
RecursiveUpgradeableRWLock
{
pthread_rwlock_t
rw_lock
;
pthread_mutex_t
upgrade_lock
;
// Notes: This could be a rw_lock
pthread_mutex_t
thread_count_lock
;
std
::
vector
<
ThreadStorage
>
thread_count
;
protected:
ThreadStorage
&
get_or_init_thread_count
(
pid_t
thread_id
);
public:
RecursiveUpgradeableRWLock
()
{
pthread_rwlock_init
(
&
this
->
rw_lock
,
NULL
);
pthread_mutex_init
(
&
this
->
upgrade_lock
,
NULL
);
pthread_mutex_init
(
&
this
->
thread_count_lock
,
NULL
);
// Reserve space for up to 8 threads
this
->
thread_count
.
reserve
(
8
);
}
void
wlock
();
void
rlock
();
void
unlock
();
int
tryrlock
();
int
trywlock
();
};
class
CyObject
{
private:
CyObject_ATOMIC_REFCOUNT_TYPE
ob_refcnt
;
//pthread_rwlock_t ob_lock;
RecursiveUpgradeableRWLock
ob_lock
;
public:
CyObject
()
:
ob_refcnt
(
1
)
{}
virtual
~
CyObject
()
{}
void
CyObject_INCREF
();
int
CyObject_DECREF
();
void
CyObject_RLOCK
();
void
CyObject_WLOCK
();
void
CyObject_UNLOCK
();
int
CyObject_TRYRLOCK
();
int
CyObject_TRYWLOCK
();
};
static
inline
int
_Cy_DECREF
(
CyObject
*
op
)
{
...
...
@@ -35,6 +81,26 @@
op
->
CyObject_INCREF
();
}
static
inline
void
_Cy_RLOCK
(
CyObject
*
op
)
{
op
->
CyObject_RLOCK
();
}
static
inline
void
_Cy_WLOCK
(
CyObject
*
op
)
{
op
->
CyObject_WLOCK
();
}
static
inline
void
_Cy_UNLOCK
(
CyObject
*
op
)
{
if
(
op
!=
NULL
)
op
->
CyObject_UNLOCK
();
}
static
inline
int
_Cy_TRYRLOCK
(
CyObject
*
op
)
{
return
op
->
CyObject_TRYRLOCK
();
}
static
inline
int
_Cy_TRYWLOCK
(
CyObject
*
op
)
{
return
op
->
CyObject_TRYWLOCK
();
}
/* Cast argument to CyObject* type. */
#define _CyObject_CAST(op) op
...
...
@@ -45,6 +111,11 @@
#define Cy_XGOTREF(op)
#define Cy_GIVEREF(op)
#define Cy_XGIVEREF(op)
#define Cy_RLOCK(op) _Cy_RLOCK(op)
#define Cy_WLOCK(op) _Cy_WLOCK(op)
#define Cy_UNLOCK(op) _Cy_UNLOCK(op)
#define Cy_TRYRLOCK(op) _Cy_TRYRLOCK(op)
#define Cy_TRYWLOCK(op) _Cy_TRYWLOCK(op)
#endif
#endif
...
...
@@ -60,6 +131,198 @@
#error C++ needed for cython+ nogil classes
#endif
/* __cplusplus */
ThreadStorage
&
RecursiveUpgradeableRWLock
::
get_or_init_thread_count
(
pid_t
thread_id
)
{
int
first_empty_index
=
-
1
;
int
match_index
=
-
1
;
pthread_mutex_lock
(
&
this
->
thread_count_lock
);
for
(
unsigned
int
i
=
0
;
i
<
this
->
thread_count
.
size
();
++
i
)
{
if
(
this
->
thread_count
[
i
].
thread_id
==
thread_id
)
match_index
=
i
;
if
(
first_empty_index
<
0
&&
this
->
thread_count
[
i
].
thread_id
==
0
)
first_empty_index
=
i
;
}
if
(
match_index
<
0
)
{
// We must get a new entry. The question is: do we have to reallocate space ?
// First, create the temporary entry
ThreadStorage
tmp_thread_entry
;
tmp_thread_entry
.
thread_id
=
thread_id
;
tmp_thread_entry
.
read_count
=
0
;
tmp_thread_entry
.
write_count
=
0
;
if
(
first_empty_index
<
0
)
{
// We have to reallocate space
match_index
=
this
->
thread_count
.
size
();
this
->
thread_count
.
push_back
(
tmp_thread_entry
);
}
else
{
// We can reuse an existing and empty cell
match_index
=
first_empty_index
;
this
->
thread_count
[
match_index
]
=
tmp_thread_entry
;
}
}
pthread_mutex_unlock
(
&
this
->
thread_count_lock
);
return
this
->
thread_count
[
match_index
];
}
void
RecursiveUpgradeableRWLock
::
wlock
()
{
pid_t
my_tid
=
syscall
(
SYS_gettid
);
ThreadStorage
&
my_counts
=
this
->
get_or_init_thread_count
(
my_tid
);
bool
has_read_lock
=
my_counts
.
read_count
;
bool
has_write_lock
=
my_counts
.
write_count
;
int
mutex_trylock_error
=
-
1
;
if
(
!
has_write_lock
)
{
if
(
has_read_lock
)
{
mutex_trylock_error
=
pthread_mutex_trylock
(
&
this
->
upgrade_lock
);
// As you may have noticed, this is a trylock above, not a blocking lock.
// This is because we could generate a deadlock:
// Imagine 2 threads T1 and T2, both holding a read lock on the same lock.
// Now, T1 tries to upgrade. So it holds the mutex, then unlock it's read lock,
// then tries to take a write lock. As T2 still has a read lock, T1 blocks,
// waiting for T2 to release it's read lock.
// Now, imagine that, instead of releasing, T2 tries to upgrade.
// It will first try to take the mutex. And won't succeed, as T1 holds it.
// This annoying mutex is here to avoid snatching when upgrading.
// Indeed, if you imagine T1 holding a read lock, T1 tries to upgrade,
// and right after T3 tries to write-lock (from nothing).
// As T1 is releasing then taking the write lock, T3 could take the write lock
// before T1, which is not really what's intented for an upgradable lock.
// The strategy here is to allow an "all is right" case by trying to lock
// first in a non-blocking manner. If it succeeds, hurray, our lock
// won't be snatched, we can continue by releasing the read lock.
// If it doesn't, to avoid a potential deadlock, we first release the read lock
// then try to hold the mutex again. Our lock will be snatched.
// So, in either case, we unlock the read lock here.
pthread_rwlock_unlock
(
&
this
->
rw_lock
);
}
if
(
mutex_trylock_error
!=
0
)
// Two cases: failed upgrading, or trying to acquire a write lock without previous lock.
// In both situations, we're trying here to acquire a write lock from nothing,
// as we already dropped read lock in the failed upgrading case,
// so blocking is allowed here (can't deadlock as we don't own other locks)
pthread_mutex_lock
(
&
this
->
upgrade_lock
);
pthread_rwlock_wrlock
(
&
this
->
rw_lock
);
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
}
// If we already have the write lock we directly jump here
++
my_counts
.
write_count
;
}
void
RecursiveUpgradeableRWLock
::
rlock
()
{
pid_t
my_tid
=
syscall
(
SYS_gettid
);
ThreadStorage
&
my_counts
=
this
->
get_or_init_thread_count
(
my_tid
);
bool
has_read_lock
=
my_counts
.
read_count
;
bool
has_write_lock
=
my_counts
.
write_count
;
if
(
!
has_write_lock
&&
!
has_read_lock
)
{
pthread_mutex_lock
(
&
this
->
upgrade_lock
);
pthread_rwlock_rdlock
(
&
this
->
rw_lock
);
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
}
// If we already have a lock (read or write), we directly jump here
++
my_counts
.
read_count
;
}
void
RecursiveUpgradeableRWLock
::
unlock
()
{
pid_t
my_tid
=
syscall
(
SYS_gettid
);
ThreadStorage
&
my_counts
=
this
->
get_or_init_thread_count
(
my_tid
);
bool
has_read_lock
=
my_counts
.
read_count
;
bool
has_write_lock
=
my_counts
.
write_count
;
if
(
has_read_lock
)
{
--
my_counts
.
read_count
;
}
else
if
(
has_write_lock
)
{
--
my_counts
.
write_count
;
}
if
(
!
my_counts
.
write_count
&&
!
my_counts
.
read_count
)
{
pthread_rwlock_unlock
(
&
this
->
rw_lock
);
my_counts
.
thread_id
=
0
;
}
}
int
RecursiveUpgradeableRWLock
::
tryrlock
()
{
int
rw_trylock_error
;
pid_t
my_tid
=
syscall
(
SYS_gettid
);
ThreadStorage
&
my_counts
=
this
->
get_or_init_thread_count
(
my_tid
);
bool
has_read_lock
=
my_counts
.
read_count
;
bool
has_write_lock
=
my_counts
.
write_count
;
if
(
!
has_write_lock
&&
!
has_read_lock
)
{
pthread_mutex_lock
(
&
this
->
upgrade_lock
);
rw_trylock_error
=
pthread_rwlock_tryrdlock
(
&
this
->
rw_lock
);
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
if
(
rw_trylock_error
)
return
rw_trylock_error
;
}
++
my_counts
.
read_count
;
return
0
;
}
int
RecursiveUpgradeableRWLock
::
trywlock
()
{
int
rw_trylock_error
;
int
mutex_trylock_error
;
pid_t
my_tid
=
syscall
(
SYS_gettid
);
ThreadStorage
&
my_counts
=
this
->
get_or_init_thread_count
(
my_tid
);
bool
has_read_lock
=
my_counts
.
read_count
;
bool
has_write_lock
=
my_counts
.
write_count
;
if
(
!
has_write_lock
)
{
if
(
has_read_lock
)
{
mutex_trylock_error
=
pthread_mutex_trylock
(
&
this
->
upgrade_lock
);
if
(
mutex_trylock_error
)
{
// In contrast to the blocking write lock,
// if we fail here we do want to keep the read lock.
return
mutex_trylock_error
;
}
// Here, we have the lock -> try to upgrade
pthread_rwlock_unlock
(
&
this
->
rw_lock
);
rw_trylock_error
=
pthread_rwlock_trywrlock
(
&
this
->
rw_lock
);
if
(
rw_trylock_error
)
{
// Get the read lock again. As we have the mutex, no one
// is trying to upgrade nor to acquire a lock,
// so the call here should return immediately
pthread_rwlock_rdlock
(
&
this
->
rw_lock
);
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
return
rw_trylock_error
;
}
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
}
mutex_trylock_error
=
pthread_mutex_trylock
(
&
this
->
upgrade_lock
);
if
(
mutex_trylock_error
)
{
// Keep previous state, so we will indeed keep read-lock
// if we had one.
return
mutex_trylock_error
;
}
if
(
has_read_lock
)
pthread_rwlock_unlock
(
&
this
->
rw_lock
);
rw_trylock_error
=
pthread_rwlock_trywrlock
(
&
this
->
rw_lock
);
if
(
rw_trylock_error
)
{
if
(
has_read_lock
)
{
// Get the read lock again. As we have the mutex, no one
// is trying to upgrade nor to acquire a lock,
// so the call here should return immediately
pthread_rwlock_rdlock
(
&
this
->
rw_lock
);
}
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
return
rw_trylock_error
;
}
pthread_mutex_unlock
(
&
this
->
upgrade_lock
);
}
++
my_counts
.
write_count
;
return
0
;
}
void
CyObject
::
CyObject_INCREF
()
{
atomic_fetch_add
(
&
(
this
->
ob_refcnt
),
1
);
...
...
@@ -73,3 +336,28 @@ int CyObject::CyObject_DECREF()
}
return
0
;
}
void
CyObject
::
CyObject_RLOCK
()
{
this
->
ob_lock
.
rlock
();
}
void
CyObject
::
CyObject_WLOCK
()
{
this
->
ob_lock
.
wlock
();
}
void
CyObject
::
CyObject_UNLOCK
()
{
this
->
ob_lock
.
unlock
();
}
int
CyObject
::
CyObject_TRYRLOCK
()
{
return
this
->
ob_lock
.
tryrlock
();
}
int
CyObject
::
CyObject_TRYWLOCK
()
{
return
this
->
ob_lock
.
trywlock
();
}
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