from libcpp cimport bool cdef extern from "" namespace "std" nogil: # For all these mutex classes, we strongly recommend you do not use any # blocking lock function while holding the GIL (try_lock should be fine though). cppclass mutex: # may not be present, and we know nothing about it cppclass native_handle_type: pass void lock() except+ bool try_lock() void unlock() native_handle_type native_handle() except+ cppclass timed_mutex: # may not be present, and we know nothing about it cppclass native_handle_type: pass void lock() except+ bool try_lock() bool try_lock_for[T](const T& duration) except+ bool try_lock_until[T](const T& time_point) except+ void unlock() native_handle_type native_handle() except+ # We strongly recommend not mixing recursive_mutex and the GIL at all. # Because "unlock" may not actually unlock it, it's pretty hard to reason about # avoiding deadlocks. cppclass recursive_mutex: # may not be present, and we know nothing about it cppclass native_handle_type: pass void lock() except+ bool try_lock() void unlock() native_handle_type native_handle() except+ # We strongly recommend not mixing timed_recursive_mutex and the GIL at all. # Because "unlock" may not actually unlock it, it's pretty hard to reason about # avoiding deadlocks. cppclass timed_recursive_mutex: # may not be present, and we know nothing about it cppclass native_handle_type: pass void lock() except+ bool try_lock() bool try_lock_for[T](const T& duration) except+ bool try_lock_until[T](const T& time_point) except+ void unlock() native_handle_type native_handle() except+ # tags cppclass defer_lock_t: pass defer_lock_t defer_lock cppclass try_to_lock_t: pass try_to_lock_t try_to_lock cppclass adopt_lock_t: pass adopt_lock_t adopt_lock # lock_guard is probably unusable without cpp_locals because it # can't be default-constructed or moved. # We strongly recommend you do not use this while holding the GIL. cppclass lock_guard[T]: ctypedef T mutex_type lock_guard(mutex_type&) except+ lock_guard(mutex_type&, adopt_lock_t) # We strongly recommend that you do not use any blocking lock function with the GIL. # (try_lock is fine though). cppclass unique_lock[T]: ctypedef T mutex_type unique_lock() # This covers both the plain regular constructor, the 3 versions with tags # and two std::chrono constructors. The two templated chrono versions stop # us from declaring the overloads explicitly. unique_lock(mutex_type&, ...) except+ #unique_lock(mutex_type&, defer_lock_t) #unique_lock(mutex_type&, try_to_lock_t) except+ ## this feels like it should be noexcet, but cppreference implies it isn't #unique_lock(mutex_type&, adopt_lock_t) except+ void lock() except+ bool try_lock() except+ bool try_lock_for[T](const T& duration) except+ bool try_lock_until[T](const T& time_point) except+ void unlock() except+ void swap(unique_lock& other) # "release" is definitely not the same as unlock. Noted here because # DW always makes this mistake and regrets it and wants to save you # from the same fate. mutex_type* release() mutex_type* mutex() bool owns_lock() bool operator bool() # scoped lock is probably unusable without cpp_locals. # It's also a variadic template type so can take potentially unlimited number of # arguments. Cython doesn't support this, so if you want more than 26 arguments, # you're on your own. # We strongly recommend that you do not use this while holding the GIL. cppclass scoped_lock[A=*, B=*, C=*, D=*, E=*, F=*, G=*, H=*, I=*, J=*, K=*, L=*, M=*, N=*, O=*, P=*, Q=*, R=*, S=*, T=*, U=*, V=*, W=*, X=*, Y=*, Z=*]: scoped_lock(...) except+ cppclass once_flag: pass bool try_lock(...) except+ # We strongly recommend that you do not call "lock" while holding the GIL. void lock(...) except+ # We can't enforce this in the interface, but you need to make sure that Callable # doesn't require the GIL and doesn't throw Python exceptions. # You should also not call this with the GIL held. void call_once[Callable](once_flag&, Callable& callable, ...) except +