cpython/Python/ceval_gil.c

1269 lines
40 KiB
C

#include "Python.h"
#include "pycore_ceval.h" // _PyEval_SignalReceived()
#include "pycore_initconfig.h" // _PyStatus_OK()
#include "pycore_interp.h" // _Py_RunGC()
#include "pycore_pyerrors.h" // _PyErr_GetRaisedException()
#include "pycore_pylifecycle.h" // _PyErr_Print()
#include "pycore_pymem.h" // _PyMem_IsPtrFreed()
#include "pycore_pystats.h" // _Py_PrintSpecializationStats()
/*
Notes about the implementation:
- The GIL is just a boolean variable (locked) whose access is protected
by a mutex (gil_mutex), and whose changes are signalled by a condition
variable (gil_cond). gil_mutex is taken for short periods of time,
and therefore mostly uncontended.
- In the GIL-holding thread, the main loop (PyEval_EvalFrameEx) must be
able to release the GIL on demand by another thread. A volatile boolean
variable (gil_drop_request) is used for that purpose, which is checked
at every turn of the eval loop. That variable is set after a wait of
`interval` microseconds on `gil_cond` has timed out.
[Actually, another volatile boolean variable (eval_breaker) is used
which ORs several conditions into one. Volatile booleans are
sufficient as inter-thread signalling means since Python is run
on cache-coherent architectures only.]
- A thread wanting to take the GIL will first let pass a given amount of
time (`interval` microseconds) before setting gil_drop_request. This
encourages a defined switching period, but doesn't enforce it since
opcodes can take an arbitrary time to execute.
The `interval` value is available for the user to read and modify
using the Python API `sys.{get,set}switchinterval()`.
- When a thread releases the GIL and gil_drop_request is set, that thread
ensures that another GIL-awaiting thread gets scheduled.
It does so by waiting on a condition variable (switch_cond) until
the value of last_holder is changed to something else than its
own thread state pointer, indicating that another thread was able to
take the GIL.
This is meant to prohibit the latency-adverse behaviour on multi-core
machines where one thread would speculatively release the GIL, but still
run and end up being the first to re-acquire it, making the "timeslices"
much longer than expected.
(Note: this mechanism is enabled with FORCE_SWITCHING above)
*/
// GH-89279: Force inlining by using a macro.
#if defined(_MSC_VER) && SIZEOF_INT == 4
#define _Py_atomic_load_relaxed_int32(ATOMIC_VAL) (assert(sizeof((ATOMIC_VAL)->_value) == 4), *((volatile int*)&((ATOMIC_VAL)->_value)))
#else
#define _Py_atomic_load_relaxed_int32(ATOMIC_VAL) _Py_atomic_load_relaxed(ATOMIC_VAL)
#endif
// Atomically copy the bits indicated by mask between two values.
static inline void
copy_eval_breaker_bits(uintptr_t *from, uintptr_t *to, uintptr_t mask)
{
uintptr_t from_bits = _Py_atomic_load_uintptr_relaxed(from) & mask;
uintptr_t old_value = _Py_atomic_load_uintptr_relaxed(to);
uintptr_t to_bits = old_value & mask;
if (from_bits == to_bits) {
return;
}
uintptr_t new_value;
do {
new_value = (old_value & ~mask) | from_bits;
} while (!_Py_atomic_compare_exchange_uintptr(to, &old_value, new_value));
}
// When attaching a thread, set the global instrumentation version and
// _PY_CALLS_TO_DO_BIT from the current state of the interpreter.
static inline void
update_eval_breaker_for_thread(PyInterpreterState *interp, PyThreadState *tstate)
{
#ifdef Py_GIL_DISABLED
// Free-threaded builds eagerly update the eval_breaker on *all* threads as
// needed, so this function doesn't apply.
return;
#endif
int32_t npending = _Py_atomic_load_int32_relaxed(
&interp->ceval.pending.npending);
if (npending) {
_Py_set_eval_breaker_bit(tstate, _PY_CALLS_TO_DO_BIT);
}
else if (_Py_IsMainThread()) {
npending = _Py_atomic_load_int32_relaxed(
&_PyRuntime.ceval.pending_mainthread.npending);
if (npending) {
_Py_set_eval_breaker_bit(tstate, _PY_CALLS_TO_DO_BIT);
}
}
// _PY_CALLS_TO_DO_BIT was derived from other state above, so the only bits
// we copy from our interpreter's state are the instrumentation version.
copy_eval_breaker_bits(&interp->ceval.instrumentation_version,
&tstate->eval_breaker,
~_PY_EVAL_EVENTS_MASK);
}
/*
* Implementation of the Global Interpreter Lock (GIL).
*/
#include <stdlib.h>
#include <errno.h>
#include "condvar.h"
#define MUTEX_INIT(mut) \
if (PyMUTEX_INIT(&(mut))) { \
Py_FatalError("PyMUTEX_INIT(" #mut ") failed"); };
#define MUTEX_FINI(mut) \
if (PyMUTEX_FINI(&(mut))) { \
Py_FatalError("PyMUTEX_FINI(" #mut ") failed"); };
#define MUTEX_LOCK(mut) \
if (PyMUTEX_LOCK(&(mut))) { \
Py_FatalError("PyMUTEX_LOCK(" #mut ") failed"); };
#define MUTEX_UNLOCK(mut) \
if (PyMUTEX_UNLOCK(&(mut))) { \
Py_FatalError("PyMUTEX_UNLOCK(" #mut ") failed"); };
#define COND_INIT(cond) \
if (PyCOND_INIT(&(cond))) { \
Py_FatalError("PyCOND_INIT(" #cond ") failed"); };
#define COND_FINI(cond) \
if (PyCOND_FINI(&(cond))) { \
Py_FatalError("PyCOND_FINI(" #cond ") failed"); };
#define COND_SIGNAL(cond) \
if (PyCOND_SIGNAL(&(cond))) { \
Py_FatalError("PyCOND_SIGNAL(" #cond ") failed"); };
#define COND_WAIT(cond, mut) \
if (PyCOND_WAIT(&(cond), &(mut))) { \
Py_FatalError("PyCOND_WAIT(" #cond ") failed"); };
#define COND_TIMED_WAIT(cond, mut, microseconds, timeout_result) \
{ \
int r = PyCOND_TIMEDWAIT(&(cond), &(mut), (microseconds)); \
if (r < 0) \
Py_FatalError("PyCOND_WAIT(" #cond ") failed"); \
if (r) /* 1 == timeout, 2 == impl. can't say, so assume timeout */ \
timeout_result = 1; \
else \
timeout_result = 0; \
} \
#define DEFAULT_INTERVAL 5000
static void _gil_initialize(struct _gil_runtime_state *gil)
{
gil->locked = -1;
gil->interval = DEFAULT_INTERVAL;
}
static int gil_created(struct _gil_runtime_state *gil)
{
if (gil == NULL) {
return 0;
}
return (_Py_atomic_load_int_acquire(&gil->locked) >= 0);
}
static void create_gil(struct _gil_runtime_state *gil)
{
MUTEX_INIT(gil->mutex);
#ifdef FORCE_SWITCHING
MUTEX_INIT(gil->switch_mutex);
#endif
COND_INIT(gil->cond);
#ifdef FORCE_SWITCHING
COND_INIT(gil->switch_cond);
#endif
_Py_atomic_store_ptr_relaxed(&gil->last_holder, 0);
_Py_ANNOTATE_RWLOCK_CREATE(&gil->locked);
_Py_atomic_store_int_release(&gil->locked, 0);
}
static void destroy_gil(struct _gil_runtime_state *gil)
{
/* some pthread-like implementations tie the mutex to the cond
* and must have the cond destroyed first.
*/
COND_FINI(gil->cond);
MUTEX_FINI(gil->mutex);
#ifdef FORCE_SWITCHING
COND_FINI(gil->switch_cond);
MUTEX_FINI(gil->switch_mutex);
#endif
_Py_atomic_store_int_release(&gil->locked, -1);
_Py_ANNOTATE_RWLOCK_DESTROY(&gil->locked);
}
#ifdef HAVE_FORK
static void recreate_gil(struct _gil_runtime_state *gil)
{
_Py_ANNOTATE_RWLOCK_DESTROY(&gil->locked);
/* XXX should we destroy the old OS resources here? */
create_gil(gil);
}
#endif
static void
drop_gil_impl(struct _gil_runtime_state *gil)
{
MUTEX_LOCK(gil->mutex);
_Py_ANNOTATE_RWLOCK_RELEASED(&gil->locked, /*is_write=*/1);
_Py_atomic_store_int_relaxed(&gil->locked, 0);
COND_SIGNAL(gil->cond);
MUTEX_UNLOCK(gil->mutex);
}
static void
drop_gil(PyInterpreterState *interp, PyThreadState *tstate)
{
struct _ceval_state *ceval = &interp->ceval;
/* If tstate is NULL, the caller is indicating that we're releasing
the GIL for the last time in this thread. This is particularly
relevant when the current thread state is finalizing or its
interpreter is finalizing (either may be in an inconsistent
state). In that case the current thread will definitely
never try to acquire the GIL again. */
// XXX It may be more correct to check tstate->_status.finalizing.
// XXX assert(tstate == NULL || !tstate->_status.cleared);
struct _gil_runtime_state *gil = ceval->gil;
#ifdef Py_GIL_DISABLED
if (!_Py_atomic_load_int_relaxed(&gil->enabled)) {
return;
}
#endif
if (!_Py_atomic_load_int_relaxed(&gil->locked)) {
Py_FatalError("drop_gil: GIL is not locked");
}
/* tstate is allowed to be NULL (early interpreter init) */
if (tstate != NULL) {
/* Sub-interpreter support: threads might have been switched
under our feet using PyThreadState_Swap(). Fix the GIL last
holder variable so that our heuristics work. */
_Py_atomic_store_ptr_relaxed(&gil->last_holder, tstate);
}
drop_gil_impl(gil);
#ifdef FORCE_SWITCHING
/* We check tstate first in case we might be releasing the GIL for
the last time in this thread. In that case there's a possible
race with tstate->interp getting deleted after gil->mutex is
unlocked and before the following code runs, leading to a crash.
We can use (tstate == NULL) to indicate the thread is done with
the GIL, and that's the only time we might delete the
interpreter, so checking tstate first prevents the crash.
See https://github.com/python/cpython/issues/104341. */
if (tstate != NULL &&
_Py_eval_breaker_bit_is_set(tstate, _PY_GIL_DROP_REQUEST_BIT)) {
MUTEX_LOCK(gil->switch_mutex);
/* Not switched yet => wait */
if (((PyThreadState*)_Py_atomic_load_ptr_relaxed(&gil->last_holder)) == tstate)
{
assert(_PyThreadState_CheckConsistency(tstate));
_Py_unset_eval_breaker_bit(tstate, _PY_GIL_DROP_REQUEST_BIT);
/* NOTE: if COND_WAIT does not atomically start waiting when
releasing the mutex, another thread can run through, take
the GIL and drop it again, and reset the condition
before we even had a chance to wait for it. */
COND_WAIT(gil->switch_cond, gil->switch_mutex);
}
MUTEX_UNLOCK(gil->switch_mutex);
}
#endif
}
/* Take the GIL.
The function saves errno at entry and restores its value at exit.
tstate must be non-NULL.
Returns 1 if the GIL was acquired, or 0 if not. */
static int
take_gil(PyThreadState *tstate)
{
int err = errno;
assert(tstate != NULL);
/* We shouldn't be using a thread state that isn't viable any more. */
// XXX It may be more correct to check tstate->_status.finalizing.
// XXX assert(!tstate->_status.cleared);
if (_PyThreadState_MustExit(tstate)) {
/* bpo-39877: If Py_Finalize() has been called and tstate is not the
thread which called Py_Finalize(), exit immediately the thread.
This code path can be reached by a daemon thread after Py_Finalize()
completes. In this case, tstate is a dangling pointer: points to
PyThreadState freed memory. */
PyThread_exit_thread();
}
assert(_PyThreadState_CheckConsistency(tstate));
PyInterpreterState *interp = tstate->interp;
struct _gil_runtime_state *gil = interp->ceval.gil;
#ifdef Py_GIL_DISABLED
if (!_Py_atomic_load_int_relaxed(&gil->enabled)) {
return 0;
}
#endif
/* Check that _PyEval_InitThreads() was called to create the lock */
assert(gil_created(gil));
MUTEX_LOCK(gil->mutex);
int drop_requested = 0;
while (_Py_atomic_load_int_relaxed(&gil->locked)) {
unsigned long saved_switchnum = gil->switch_number;
unsigned long interval = (gil->interval >= 1 ? gil->interval : 1);
int timed_out = 0;
COND_TIMED_WAIT(gil->cond, gil->mutex, interval, timed_out);
/* If we timed out and no switch occurred in the meantime, it is time
to ask the GIL-holding thread to drop it. */
if (timed_out &&
_Py_atomic_load_int_relaxed(&gil->locked) &&
gil->switch_number == saved_switchnum)
{
PyThreadState *holder_tstate =
(PyThreadState*)_Py_atomic_load_ptr_relaxed(&gil->last_holder);
if (_PyThreadState_MustExit(tstate)) {
MUTEX_UNLOCK(gil->mutex);
// gh-96387: If the loop requested a drop request in a previous
// iteration, reset the request. Otherwise, drop_gil() can
// block forever waiting for the thread which exited. Drop
// requests made by other threads are also reset: these threads
// may have to request again a drop request (iterate one more
// time).
if (drop_requested) {
_Py_unset_eval_breaker_bit(holder_tstate, _PY_GIL_DROP_REQUEST_BIT);
}
PyThread_exit_thread();
}
assert(_PyThreadState_CheckConsistency(tstate));
_Py_set_eval_breaker_bit(holder_tstate, _PY_GIL_DROP_REQUEST_BIT);
drop_requested = 1;
}
}
#ifdef Py_GIL_DISABLED
if (!_Py_atomic_load_int_relaxed(&gil->enabled)) {
// Another thread disabled the GIL between our check above and
// now. Don't take the GIL, signal any other waiting threads, and
// return 0.
COND_SIGNAL(gil->cond);
MUTEX_UNLOCK(gil->mutex);
return 0;
}
#endif
#ifdef FORCE_SWITCHING
/* This mutex must be taken before modifying gil->last_holder:
see drop_gil(). */
MUTEX_LOCK(gil->switch_mutex);
#endif
/* We now hold the GIL */
_Py_atomic_store_int_relaxed(&gil->locked, 1);
_Py_ANNOTATE_RWLOCK_ACQUIRED(&gil->locked, /*is_write=*/1);
if (tstate != (PyThreadState*)_Py_atomic_load_ptr_relaxed(&gil->last_holder)) {
_Py_atomic_store_ptr_relaxed(&gil->last_holder, tstate);
++gil->switch_number;
}
#ifdef FORCE_SWITCHING
COND_SIGNAL(gil->switch_cond);
MUTEX_UNLOCK(gil->switch_mutex);
#endif
if (_PyThreadState_MustExit(tstate)) {
/* bpo-36475: If Py_Finalize() has been called and tstate is not
the thread which called Py_Finalize(), exit immediately the
thread.
This code path can be reached by a daemon thread which was waiting
in take_gil() while the main thread called
wait_for_thread_shutdown() from Py_Finalize(). */
MUTEX_UNLOCK(gil->mutex);
/* Passing NULL to drop_gil() indicates that this thread is about to
terminate and will never hold the GIL again. */
drop_gil(interp, NULL);
PyThread_exit_thread();
}
assert(_PyThreadState_CheckConsistency(tstate));
_Py_unset_eval_breaker_bit(tstate, _PY_GIL_DROP_REQUEST_BIT);
update_eval_breaker_for_thread(interp, tstate);
MUTEX_UNLOCK(gil->mutex);
errno = err;
return 1;
}
void _PyEval_SetSwitchInterval(unsigned long microseconds)
{
PyInterpreterState *interp = _PyInterpreterState_GET();
struct _gil_runtime_state *gil = interp->ceval.gil;
assert(gil != NULL);
gil->interval = microseconds;
}
unsigned long _PyEval_GetSwitchInterval(void)
{
PyInterpreterState *interp = _PyInterpreterState_GET();
struct _gil_runtime_state *gil = interp->ceval.gil;
assert(gil != NULL);
return gil->interval;
}
int
_PyEval_ThreadsInitialized(void)
{
/* XXX This is only needed for an assert in PyGILState_Ensure(),
* which currently does not work with subinterpreters.
* Thus we only use the main interpreter. */
PyInterpreterState *interp = _PyInterpreterState_Main();
if (interp == NULL) {
return 0;
}
struct _gil_runtime_state *gil = interp->ceval.gil;
return gil_created(gil);
}
// Function removed in the Python 3.13 API but kept in the stable ABI.
PyAPI_FUNC(int)
PyEval_ThreadsInitialized(void)
{
return _PyEval_ThreadsInitialized();
}
#ifndef NDEBUG
static inline int
current_thread_holds_gil(struct _gil_runtime_state *gil, PyThreadState *tstate)
{
if (((PyThreadState*)_Py_atomic_load_ptr_relaxed(&gil->last_holder)) != tstate) {
return 0;
}
return _Py_atomic_load_int_relaxed(&gil->locked);
}
#endif
static void
init_shared_gil(PyInterpreterState *interp, struct _gil_runtime_state *gil)
{
assert(gil_created(gil));
interp->ceval.gil = gil;
interp->ceval.own_gil = 0;
}
static void
init_own_gil(PyInterpreterState *interp, struct _gil_runtime_state *gil)
{
assert(!gil_created(gil));
#ifdef Py_GIL_DISABLED
const PyConfig *config = _PyInterpreterState_GetConfig(interp);
gil->enabled = config->enable_gil == _PyConfig_GIL_ENABLE ? INT_MAX : 0;
#endif
create_gil(gil);
assert(gil_created(gil));
interp->ceval.gil = gil;
interp->ceval.own_gil = 1;
}
void
_PyEval_InitGIL(PyThreadState *tstate, int own_gil)
{
assert(tstate->interp->ceval.gil == NULL);
if (!own_gil) {
/* The interpreter will share the main interpreter's instead. */
PyInterpreterState *main_interp = _PyInterpreterState_Main();
assert(tstate->interp != main_interp);
struct _gil_runtime_state *gil = main_interp->ceval.gil;
init_shared_gil(tstate->interp, gil);
assert(!current_thread_holds_gil(gil, tstate));
}
else {
PyThread_init_thread();
init_own_gil(tstate->interp, &tstate->interp->_gil);
}
// Lock the GIL and mark the current thread as attached.
_PyThreadState_Attach(tstate);
}
void
_PyEval_FiniGIL(PyInterpreterState *interp)
{
struct _gil_runtime_state *gil = interp->ceval.gil;
if (gil == NULL) {
/* It was already finalized (or hasn't been initialized yet). */
assert(!interp->ceval.own_gil);
return;
}
else if (!interp->ceval.own_gil) {
#ifdef Py_DEBUG
PyInterpreterState *main_interp = _PyInterpreterState_Main();
assert(main_interp != NULL && interp != main_interp);
assert(interp->ceval.gil == main_interp->ceval.gil);
#endif
interp->ceval.gil = NULL;
return;
}
if (!gil_created(gil)) {
/* First Py_InitializeFromConfig() call: the GIL doesn't exist
yet: do nothing. */
return;
}
destroy_gil(gil);
assert(!gil_created(gil));
interp->ceval.gil = NULL;
}
void
PyEval_InitThreads(void)
{
/* Do nothing: kept for backward compatibility */
}
void
_PyEval_Fini(void)
{
#ifdef Py_STATS
_Py_PrintSpecializationStats(1);
#endif
}
// Function removed in the Python 3.13 API but kept in the stable ABI.
PyAPI_FUNC(void)
PyEval_AcquireLock(void)
{
PyThreadState *tstate = _PyThreadState_GET();
_Py_EnsureTstateNotNULL(tstate);
take_gil(tstate);
}
// Function removed in the Python 3.13 API but kept in the stable ABI.
PyAPI_FUNC(void)
PyEval_ReleaseLock(void)
{
PyThreadState *tstate = _PyThreadState_GET();
/* This function must succeed when the current thread state is NULL.
We therefore avoid PyThreadState_Get() which dumps a fatal error
in debug mode. */
drop_gil(tstate->interp, tstate);
}
int
_PyEval_AcquireLock(PyThreadState *tstate)
{
_Py_EnsureTstateNotNULL(tstate);
return take_gil(tstate);
}
void
_PyEval_ReleaseLock(PyInterpreterState *interp, PyThreadState *tstate)
{
/* If tstate is NULL then we do not expect the current thread
to acquire the GIL ever again. */
assert(tstate == NULL || tstate->interp == interp);
drop_gil(interp, tstate);
}
void
PyEval_AcquireThread(PyThreadState *tstate)
{
_Py_EnsureTstateNotNULL(tstate);
_PyThreadState_Attach(tstate);
}
void
PyEval_ReleaseThread(PyThreadState *tstate)
{
assert(_PyThreadState_CheckConsistency(tstate));
_PyThreadState_Detach(tstate);
}
#ifdef HAVE_FORK
/* This function is called from PyOS_AfterFork_Child to re-initialize the
GIL and pending calls lock. */
PyStatus
_PyEval_ReInitThreads(PyThreadState *tstate)
{
assert(tstate->interp == _PyInterpreterState_Main());
struct _gil_runtime_state *gil = tstate->interp->ceval.gil;
if (!gil_created(gil)) {
return _PyStatus_OK();
}
recreate_gil(gil);
take_gil(tstate);
struct _pending_calls *pending = &tstate->interp->ceval.pending;
_PyMutex_at_fork_reinit(&pending->mutex);
return _PyStatus_OK();
}
#endif
PyThreadState *
PyEval_SaveThread(void)
{
PyThreadState *tstate = _PyThreadState_GET();
_PyThreadState_Detach(tstate);
return tstate;
}
void
PyEval_RestoreThread(PyThreadState *tstate)
{
#ifdef MS_WINDOWS
int err = GetLastError();
#endif
_Py_EnsureTstateNotNULL(tstate);
_PyThreadState_Attach(tstate);
#ifdef MS_WINDOWS
SetLastError(err);
#endif
}
void
_PyEval_SignalReceived(void)
{
_Py_set_eval_breaker_bit(_PyRuntime.main_tstate, _PY_SIGNALS_PENDING_BIT);
}
#ifndef Py_GIL_DISABLED
static void
signal_active_thread(PyInterpreterState *interp, uintptr_t bit)
{
struct _gil_runtime_state *gil = interp->ceval.gil;
// If a thread from the targeted interpreter is holding the GIL, signal
// that thread. Otherwise, the next thread to run from the targeted
// interpreter will have its bit set as part of taking the GIL.
MUTEX_LOCK(gil->mutex);
if (_Py_atomic_load_int_relaxed(&gil->locked)) {
PyThreadState *holder = (PyThreadState*)_Py_atomic_load_ptr_relaxed(&gil->last_holder);
if (holder->interp == interp) {
_Py_set_eval_breaker_bit(holder, bit);
}
}
MUTEX_UNLOCK(gil->mutex);
}
#endif
/* Mechanism whereby asynchronously executing callbacks (e.g. UNIX
signal handlers or Mac I/O completion routines) can schedule calls
to a function to be called synchronously.
The synchronous function is called with one void* argument.
It should return 0 for success or -1 for failure -- failure should
be accompanied by an exception.
If registry succeeds, the registry function returns 0; if it fails
(e.g. due to too many pending calls) it returns -1 (without setting
an exception condition).
Note that because registry may occur from within signal handlers,
or other asynchronous events, calling malloc() is unsafe!
Any thread can schedule pending calls, but only the main thread
will execute them.
There is no facility to schedule calls to a particular thread, but
that should be easy to change, should that ever be required. In
that case, the static variables here should go into the python
threadstate.
*/
/* Push one item onto the queue while holding the lock. */
static int
_push_pending_call(struct _pending_calls *pending,
_Py_pending_call_func func, void *arg, int flags)
{
if (pending->npending == pending->max) {
return _Py_ADD_PENDING_FULL;
}
assert(pending->npending < pending->max);
int i = pending->next;
assert(pending->calls[i].func == NULL);
pending->calls[i].func = func;
pending->calls[i].arg = arg;
pending->calls[i].flags = flags;
assert(pending->npending < PENDINGCALLSARRAYSIZE);
_Py_atomic_add_int32(&pending->npending, 1);
pending->next = (i + 1) % PENDINGCALLSARRAYSIZE;
assert(pending->next != pending->first
|| pending->npending == pending->max);
return _Py_ADD_PENDING_SUCCESS;
}
static int
_next_pending_call(struct _pending_calls *pending,
int (**func)(void *), void **arg, int *flags)
{
int i = pending->first;
if (pending->npending == 0) {
/* Queue empty */
assert(i == pending->next);
assert(pending->calls[i].func == NULL);
return -1;
}
*func = pending->calls[i].func;
*arg = pending->calls[i].arg;
*flags = pending->calls[i].flags;
return i;
}
/* Pop one item off the queue while holding the lock. */
static void
_pop_pending_call(struct _pending_calls *pending,
int (**func)(void *), void **arg, int *flags)
{
int i = _next_pending_call(pending, func, arg, flags);
if (i >= 0) {
pending->calls[i] = (struct _pending_call){0};
pending->first = (i + 1) % PENDINGCALLSARRAYSIZE;
assert(pending->npending > 0);
_Py_atomic_add_int32(&pending->npending, -1);
}
}
/* This implementation is thread-safe. It allows
scheduling to be made from any thread, and even from an executing
callback.
*/
_Py_add_pending_call_result
_PyEval_AddPendingCall(PyInterpreterState *interp,
_Py_pending_call_func func, void *arg, int flags)
{
struct _pending_calls *pending = &interp->ceval.pending;
int main_only = (flags & _Py_PENDING_MAINTHREADONLY) != 0;
if (main_only) {
/* The main thread only exists in the main interpreter. */
assert(_Py_IsMainInterpreter(interp));
pending = &_PyRuntime.ceval.pending_mainthread;
}
PyMutex_Lock(&pending->mutex);
_Py_add_pending_call_result result =
_push_pending_call(pending, func, arg, flags);
PyMutex_Unlock(&pending->mutex);
if (main_only) {
_Py_set_eval_breaker_bit(_PyRuntime.main_tstate, _PY_CALLS_TO_DO_BIT);
}
else {
#ifdef Py_GIL_DISABLED
_Py_set_eval_breaker_bit_all(interp, _PY_CALLS_TO_DO_BIT);
#else
signal_active_thread(interp, _PY_CALLS_TO_DO_BIT);
#endif
}
return result;
}
int
Py_AddPendingCall(_Py_pending_call_func func, void *arg)
{
/* Legacy users of this API will continue to target the main thread
(of the main interpreter). */
PyInterpreterState *interp = _PyInterpreterState_Main();
_Py_add_pending_call_result r =
_PyEval_AddPendingCall(interp, func, arg, _Py_PENDING_MAINTHREADONLY);
if (r == _Py_ADD_PENDING_FULL) {
return -1;
}
else {
assert(r == _Py_ADD_PENDING_SUCCESS);
return 0;
}
}
static int
handle_signals(PyThreadState *tstate)
{
assert(_PyThreadState_CheckConsistency(tstate));
_Py_unset_eval_breaker_bit(tstate, _PY_SIGNALS_PENDING_BIT);
if (!_Py_ThreadCanHandleSignals(tstate->interp)) {
return 0;
}
if (_PyErr_CheckSignalsTstate(tstate) < 0) {
/* On failure, re-schedule a call to handle_signals(). */
_Py_set_eval_breaker_bit(tstate, _PY_SIGNALS_PENDING_BIT);
return -1;
}
return 0;
}
static int
_make_pending_calls(struct _pending_calls *pending, int32_t *p_npending)
{
int res = 0;
int32_t npending = -1;
assert(sizeof(pending->max) <= sizeof(size_t)
&& ((size_t)pending->max) <= Py_ARRAY_LENGTH(pending->calls));
int32_t maxloop = pending->maxloop;
if (maxloop == 0) {
maxloop = pending->max;
}
assert(maxloop > 0 && maxloop <= pending->max);
/* perform a bounded number of calls, in case of recursion */
for (int i=0; i<maxloop; i++) {
_Py_pending_call_func func = NULL;
void *arg = NULL;
int flags = 0;
/* pop one item off the queue while holding the lock */
PyMutex_Lock(&pending->mutex);
_pop_pending_call(pending, &func, &arg, &flags);
npending = pending->npending;
PyMutex_Unlock(&pending->mutex);
/* Check if there are any more pending calls. */
if (func == NULL) {
assert(npending == 0);
break;
}
/* having released the lock, perform the callback */
res = func(arg);
if ((flags & _Py_PENDING_RAWFREE) && arg != NULL) {
PyMem_RawFree(arg);
}
if (res != 0) {
res = -1;
goto finally;
}
}
finally:
*p_npending = npending;
return res;
}
static void
signal_pending_calls(PyThreadState *tstate, PyInterpreterState *interp)
{
#ifdef Py_GIL_DISABLED
_Py_set_eval_breaker_bit_all(interp, _PY_CALLS_TO_DO_BIT);
#else
_Py_set_eval_breaker_bit(tstate, _PY_CALLS_TO_DO_BIT);
#endif
}
static void
unsignal_pending_calls(PyThreadState *tstate, PyInterpreterState *interp)
{
#ifdef Py_GIL_DISABLED
_Py_unset_eval_breaker_bit_all(interp, _PY_CALLS_TO_DO_BIT);
#else
_Py_unset_eval_breaker_bit(tstate, _PY_CALLS_TO_DO_BIT);
#endif
}
static int
make_pending_calls(PyThreadState *tstate)
{
PyInterpreterState *interp = tstate->interp;
struct _pending_calls *pending = &interp->ceval.pending;
struct _pending_calls *pending_main = &_PyRuntime.ceval.pending_mainthread;
/* Only one thread (per interpreter) may run the pending calls
at once. In the same way, we don't do recursive pending calls. */
PyMutex_Lock(&pending->mutex);
if (pending->handling_thread != NULL) {
/* A pending call was added after another thread was already
handling the pending calls (and had already "unsignaled").
Once that thread is done, it may have taken care of all the
pending calls, or there might be some still waiting.
To avoid all threads constantly stopping on the eval breaker,
we clear the bit for this thread and make sure it is set
for the thread currently handling the pending call. */
_Py_set_eval_breaker_bit(pending->handling_thread, _PY_CALLS_TO_DO_BIT);
_Py_unset_eval_breaker_bit(tstate, _PY_CALLS_TO_DO_BIT);
PyMutex_Unlock(&pending->mutex);
return 0;
}
pending->handling_thread = tstate;
PyMutex_Unlock(&pending->mutex);
/* unsignal before starting to call callbacks, so that any callback
added in-between re-signals */
unsignal_pending_calls(tstate, interp);
int32_t npending;
if (_make_pending_calls(pending, &npending) != 0) {
pending->handling_thread = NULL;
/* There might not be more calls to make, but we play it safe. */
signal_pending_calls(tstate, interp);
return -1;
}
if (npending > 0) {
/* We hit pending->maxloop. */
signal_pending_calls(tstate, interp);
}
if (_Py_IsMainThread() && _Py_IsMainInterpreter(interp)) {
if (_make_pending_calls(pending_main, &npending) != 0) {
pending->handling_thread = NULL;
/* There might not be more calls to make, but we play it safe. */
signal_pending_calls(tstate, interp);
return -1;
}
if (npending > 0) {
/* We hit pending_main->maxloop. */
signal_pending_calls(tstate, interp);
}
}
pending->handling_thread = NULL;
return 0;
}
void
_Py_set_eval_breaker_bit_all(PyInterpreterState *interp, uintptr_t bit)
{
_PyRuntimeState *runtime = &_PyRuntime;
HEAD_LOCK(runtime);
for (PyThreadState *tstate = interp->threads.head; tstate != NULL; tstate = tstate->next) {
_Py_set_eval_breaker_bit(tstate, bit);
}
HEAD_UNLOCK(runtime);
}
void
_Py_unset_eval_breaker_bit_all(PyInterpreterState *interp, uintptr_t bit)
{
_PyRuntimeState *runtime = &_PyRuntime;
HEAD_LOCK(runtime);
for (PyThreadState *tstate = interp->threads.head; tstate != NULL; tstate = tstate->next) {
_Py_unset_eval_breaker_bit(tstate, bit);
}
HEAD_UNLOCK(runtime);
}
void
_Py_FinishPendingCalls(PyThreadState *tstate)
{
assert(PyGILState_Check());
assert(_PyThreadState_CheckConsistency(tstate));
if (make_pending_calls(tstate) < 0) {
PyObject *exc = _PyErr_GetRaisedException(tstate);
PyErr_BadInternalCall();
_PyErr_ChainExceptions1(exc);
_PyErr_Print(tstate);
}
}
int
_PyEval_MakePendingCalls(PyThreadState *tstate)
{
int res;
if (_Py_IsMainThread() && _Py_IsMainInterpreter(tstate->interp)) {
/* Python signal handler doesn't really queue a callback:
it only signals that a signal was received,
see _PyEval_SignalReceived(). */
res = handle_signals(tstate);
if (res != 0) {
return res;
}
}
res = make_pending_calls(tstate);
if (res != 0) {
return res;
}
return 0;
}
/* Py_MakePendingCalls() is a simple wrapper for the sake
of backward-compatibility. */
int
Py_MakePendingCalls(void)
{
assert(PyGILState_Check());
PyThreadState *tstate = _PyThreadState_GET();
assert(_PyThreadState_CheckConsistency(tstate));
/* Only execute pending calls on the main thread. */
if (!_Py_IsMainThread() || !_Py_IsMainInterpreter(tstate->interp)) {
return 0;
}
return _PyEval_MakePendingCalls(tstate);
}
void
_PyEval_InitState(PyInterpreterState *interp)
{
_gil_initialize(&interp->_gil);
}
#ifdef Py_GIL_DISABLED
int
_PyEval_EnableGILTransient(PyThreadState *tstate)
{
const PyConfig *config = _PyInterpreterState_GetConfig(tstate->interp);
if (config->enable_gil != _PyConfig_GIL_DEFAULT) {
return 0;
}
struct _gil_runtime_state *gil = tstate->interp->ceval.gil;
int enabled = _Py_atomic_load_int_relaxed(&gil->enabled);
if (enabled == INT_MAX) {
// The GIL is already enabled permanently.
return 0;
}
if (enabled == INT_MAX - 1) {
Py_FatalError("Too many transient requests to enable the GIL");
}
if (enabled > 0) {
// If enabled is nonzero, we know we hold the GIL. This means that no
// other threads are attached, and nobody else can be concurrently
// mutating it.
_Py_atomic_store_int_relaxed(&gil->enabled, enabled + 1);
return 0;
}
// Enabling the GIL changes what it means to be an "attached" thread. To
// safely make this transition, we:
// 1. Detach the current thread.
// 2. Stop the world to detach (and suspend) all other threads.
// 3. Enable the GIL, if nobody else did between our check above and when
// our stop-the-world begins.
// 4. Start the world.
// 5. Attach the current thread. Other threads may attach and hold the GIL
// before this thread, which is harmless.
_PyThreadState_Detach(tstate);
// This could be an interpreter-local stop-the-world in situations where we
// know that this interpreter's GIL is not shared, and that it won't become
// shared before the stop-the-world begins. For now, we always stop all
// interpreters for simplicity.
_PyEval_StopTheWorldAll(&_PyRuntime);
enabled = _Py_atomic_load_int_relaxed(&gil->enabled);
int this_thread_enabled = enabled == 0;
_Py_atomic_store_int_relaxed(&gil->enabled, enabled + 1);
_PyEval_StartTheWorldAll(&_PyRuntime);
_PyThreadState_Attach(tstate);
return this_thread_enabled;
}
int
_PyEval_EnableGILPermanent(PyThreadState *tstate)
{
const PyConfig *config = _PyInterpreterState_GetConfig(tstate->interp);
if (config->enable_gil != _PyConfig_GIL_DEFAULT) {
return 0;
}
struct _gil_runtime_state *gil = tstate->interp->ceval.gil;
assert(current_thread_holds_gil(gil, tstate));
int enabled = _Py_atomic_load_int_relaxed(&gil->enabled);
if (enabled == INT_MAX) {
return 0;
}
_Py_atomic_store_int_relaxed(&gil->enabled, INT_MAX);
return 1;
}
int
_PyEval_DisableGIL(PyThreadState *tstate)
{
const PyConfig *config = _PyInterpreterState_GetConfig(tstate->interp);
if (config->enable_gil != _PyConfig_GIL_DEFAULT) {
return 0;
}
struct _gil_runtime_state *gil = tstate->interp->ceval.gil;
assert(current_thread_holds_gil(gil, tstate));
int enabled = _Py_atomic_load_int_relaxed(&gil->enabled);
if (enabled == INT_MAX) {
return 0;
}
assert(enabled >= 1);
enabled--;
// Disabling the GIL is much simpler than enabling it, since we know we are
// the only attached thread. Other threads may start free-threading as soon
// as this store is complete, if it sets gil->enabled to 0.
_Py_atomic_store_int_relaxed(&gil->enabled, enabled);
if (enabled == 0) {
// We're attached, so we know the GIL will remain disabled until at
// least the next time we detach, which must be after this function
// returns.
//
// Drop the GIL, which will wake up any threads waiting in take_gil()
// and let them resume execution without the GIL.
drop_gil_impl(gil);
return 1;
}
return 0;
}
#endif
/* Do periodic things, like check for signals and async I/0.
* We need to do reasonably frequently, but not too frequently.
* All loops should include a check of the eval breaker.
* We also check on return from any builtin function.
*
* ## More Details ###
*
* The eval loop (this function) normally executes the instructions
* of a code object sequentially. However, the runtime supports a
* number of out-of-band execution scenarios that may pause that
* sequential execution long enough to do that out-of-band work
* in the current thread using the current PyThreadState.
*
* The scenarios include:
*
* - cyclic garbage collection
* - GIL drop requests
* - "async" exceptions
* - "pending calls" (some only in the main thread)
* - signal handling (only in the main thread)
*
* When the need for one of the above is detected, the eval loop
* pauses long enough to handle the detected case. Then, if doing
* so didn't trigger an exception, the eval loop resumes executing
* the sequential instructions.
*
* To make this work, the eval loop periodically checks if any
* of the above needs to happen. The individual checks can be
* expensive if computed each time, so a while back we switched
* to using pre-computed, per-interpreter variables for the checks,
* and later consolidated that to a single "eval breaker" variable
* (now a PyInterpreterState field).
*
* For the longest time, the eval breaker check would happen
* frequently, every 5 or so times through the loop, regardless
* of what instruction ran last or what would run next. Then, in
* early 2021 (gh-18334, commit 4958f5d), we switched to checking
* the eval breaker less frequently, by hard-coding the check to
* specific places in the eval loop (e.g. certain instructions).
* The intent then was to check after returning from calls
* and on the back edges of loops.
*
* In addition to being more efficient, that approach keeps
* the eval loop from running arbitrary code between instructions
* that don't handle that well. (See gh-74174.)
*
* Currently, the eval breaker check happens on back edges in
* the control flow graph, which pretty much applies to all loops,
* and most calls.
* (See bytecodes.c for exact information.)
*
* One consequence of this approach is that it might not be obvious
* how to force any specific thread to pick up the eval breaker,
* or for any specific thread to not pick it up. Mostly this
* involves judicious uses of locks and careful ordering of code,
* while avoiding code that might trigger the eval breaker
* until so desired.
*/
int
_Py_HandlePending(PyThreadState *tstate)
{
uintptr_t breaker = _Py_atomic_load_uintptr_relaxed(&tstate->eval_breaker);
/* Stop-the-world */
if ((breaker & _PY_EVAL_PLEASE_STOP_BIT) != 0) {
_Py_unset_eval_breaker_bit(tstate, _PY_EVAL_PLEASE_STOP_BIT);
_PyThreadState_Suspend(tstate);
/* The attach blocks until the stop-the-world event is complete. */
_PyThreadState_Attach(tstate);
}
/* Pending signals */
if ((breaker & _PY_SIGNALS_PENDING_BIT) != 0) {
if (handle_signals(tstate) != 0) {
return -1;
}
}
/* Pending calls */
if ((breaker & _PY_CALLS_TO_DO_BIT) != 0) {
if (make_pending_calls(tstate) != 0) {
return -1;
}
}
#ifdef Py_GIL_DISABLED
/* Objects with refcounts to merge */
if ((breaker & _PY_EVAL_EXPLICIT_MERGE_BIT) != 0) {
_Py_unset_eval_breaker_bit(tstate, _PY_EVAL_EXPLICIT_MERGE_BIT);
_Py_brc_merge_refcounts(tstate);
}
#endif
/* GC scheduled to run */
if ((breaker & _PY_GC_SCHEDULED_BIT) != 0) {
_Py_unset_eval_breaker_bit(tstate, _PY_GC_SCHEDULED_BIT);
_Py_RunGC(tstate);
}
/* GIL drop request */
if ((breaker & _PY_GIL_DROP_REQUEST_BIT) != 0) {
/* Give another thread a chance */
_PyThreadState_Detach(tstate);
/* Other threads may run now */
_PyThreadState_Attach(tstate);
}
/* Check for asynchronous exception. */
if ((breaker & _PY_ASYNC_EXCEPTION_BIT) != 0) {
_Py_unset_eval_breaker_bit(tstate, _PY_ASYNC_EXCEPTION_BIT);
PyObject *exc = _Py_atomic_exchange_ptr(&tstate->async_exc, NULL);
if (exc != NULL) {
_PyErr_SetNone(tstate, exc);
Py_DECREF(exc);
return -1;
}
}
return 0;
}