2004-03-06 22:43:57 +01:00
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Copyright 2001, 2002, 2003, 2004 Red Hat Inc., Christopher Faylor
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2001-09-14 18:57:32 +02:00
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2004-03-06 22:43:57 +01:00
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[note that the following discussion is still incomplete]
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2001-09-03 22:36:52 +02:00
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2004-03-06 22:43:57 +01:00
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How do signals work?
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2001-09-03 22:36:52 +02:00
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2004-03-06 22:43:57 +01:00
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On process startup, cygwin starts a secondary thread which deals with
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signals. This thread contains a loop which blocks waiting for
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information to show up on a pipe whose handle (sendsig) is currently
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stored in _pinfo (this may change).
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Communication on the sendsig pipe is via the 'sigpacket' structure.
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This structure is filled out by the sig_send function with information
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about the signal being sent, such as (as of this writing) the signal
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number, the originating pid, the originating thread, and the address of
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the mask to use (this may change).
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Any cygwin function which calls a win32 api function is wrapped by the
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assembly functions "_sigfe" and "_sigbe". These functions maintain a
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cygwin "signal stack" which is used by the signal thread to control
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handling of signal interrupts. Cygwin functions which need to be
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wrapped by these functions (the majority) are labelled by the SIGFE
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option in the file cygwin.din.
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The cygwin.din function is translated into a standard cygwin.def file by
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the perl script "gendef". This function notices exported cygwin
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functions which are labelled as SIGFE and generates a front end assembly
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file "sigfe.s" which contains the wrapper glue necessary for every
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function to call sigfe prior to actually dispatching to the real cygwin
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function. This generated function contains low-level signal related
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functions: _sigfe, _sigbe, sigdelayed, sigreturn, longjmp, and setjmp.
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The signal stack maintained by sigfe/sigbe and friends is a secondary
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shadow stack. Addresses from this stack are swapped into the "real"
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stack as needed to control program flow. The intent is that executing
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cygwin functions will still see roughly the same stack layout and will
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be able to retrieve arguments from the stack but will always return
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to the _sigbe routine so that any signal handlers will be properly
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called.
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Upon receipt of a "non-special" (see below) signal, the function
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sigpacket::process is called. This function determines what action, if
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any, to take on the signal. Possible actions are: Ignore the signal (e.g.,
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SIGUSR1), terminate the program (SIGKILL, SIGTERM), stop the program
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(SIGSTOP, SIGTSTP, etc.), wake up a sigwait or sigwaitinfo in a
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targetted thread, or call a signal handler (possibly in a thread).
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If no thread information has been sent to sigpacket::process, it determines
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the correct thread to use based on various heuristics, as per UNIX.
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Signals sent via the UNIX kill() function are normally sent to the
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main thread. Ditto signals sent as the result of pressing tty keys,
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like CTRL-C.
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Signals which stop a process are handled by a special internal handler:
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sig_handle_tty_stop. Some signals (e.g., SIGKILL, SIGSTOP) are
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uncatchable, as on UNIX.
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2001-09-03 22:36:52 +02:00
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If the signal has an associated signal handler, then the setup_handler
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function is eventually called. It is passed the signal, the address of
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2004-03-06 22:43:57 +01:00
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the handler, a standard UNIX sigaction structure, and a pointer to the
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thread's "_cygtls" information. The meat of signal processing is in
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setup_handler.
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2001-09-03 22:36:52 +02:00
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setup_handler has a "simple" task. It tries to stop the appropriate
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2004-03-06 22:43:57 +01:00
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thread and either redirect its execution to the signal handler function,
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flag that a signal has been received (sigwait) or both (sigpause).
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To accomplish its task, setup_handler first inspects the target thread's
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local storage (_cygtls) structure. This structure contains information
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on any not-yet-handled signals that may have been set up by a previous
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call to setup_handler but not yet dispatched in the target thread. If this
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structure seems to be "active", then setup_handler returns, notifying it's
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parent via a false value. Otherwise processing continues.
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(For pending signals, the theory is that the signal handler thread will
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be forced to be rerun by having some strategic cygwin function call
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sig_send with a __SIGFLUSH "argument" to it. This causes the signal
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handler to rescan the signal array looking for pending signals.)
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After determining that it's ok to send a signal, setup_handler will lock
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the cygtls stack to ensure that it has complete access. It will then
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inspect the thread's 'incyg' element. If this is true, the thread is
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currently executing a cygwin function. If it is false, the thread is
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unlocked and it is assumed that the thread is executing "user" code.
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The actions taken by setup_handler differ based on whether the program
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is executing a cygwin routine or not.
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If the program is executing a cygwin routine, then the
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interrupt_on_return function is called which sets the address of the
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'sigdelayed' function is pushed onto the thread's signal stack, and the
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signal's mask and handler is saved in the tls structure. Then the
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'signal_arrived' event is signalled, as well as any thread-specific wait
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event.
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Since the sigdelayed function was saved on the thread's signal stack,
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when the cygwin functio returns, it will eventually return to the
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sigdelayed "front end". The sigdelayed function will save a lot of
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state on the stack and set the signal mask as appropriate for POSIX.
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It uses information from the _cygtls structure which has been filled in
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by interrupt_setup, as called by setup_handler. sigdelayed pushes a
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"call" to the function "sigreturn" on the thread's signal stack. This
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will be the return address eventually seen by the signal handler. After
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setting up the return value, modifying the signal mask, and saving other
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information on the stack, sigreturn clears the signal number in the
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_cygtls structure so that setup_handler can use it and jumps to the
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2001-09-15 02:47:44 +02:00
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signal handler function. And, so a UNIX signal handler function is
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emulated.
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The signal handler function operates as normal for UNIX but, upon
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return, it does not go directly back to the return address of the
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original cygwin function. Instead it returns to the previously
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mentioned 'sigreturn' assembly language function.
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sigreturn resets the process mask to its state prior to calling the
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2004-03-06 22:43:57 +01:00
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signal handler. It checks to see if a cygwin routine has set a special
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"restore this errno on returning from a signal" value and sets errno to
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this, if so. It pops the signal stack, places the new return address on
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the real stack, restores all of the register values that were in effect
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when sigdelayed was called, and then returns.
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Ok. That is more or less how cygwin interrupts a process which is
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executing a cygwin function. We are almost ready to talk about how
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cygwin interrupts user code but there is one more thing to talk about:
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SA_RESTART.
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UNIX allows some blocking functions to be interrupted by a signal
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handler and then return to blocking. In cygwin, so far, only
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read/readv() operate in this fashion. To accommodate this behavior,
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readv notices when a signal comes in and then calls the _cygtls function
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'call_signal_handler_now'. 'call_signal_handler_now' emulates the
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behavior of both sigdelayed and sigreturn. It sets the appropriate
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masks and calls the handler, returning true to the caller if SA_RESTART
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is active. If SA_RESTART is active, readv will loop. Otherwise
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it will return -1 and set the errno to EINTR.
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Phew. So, now we turn to the case where cygwin needs to interrupt the
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program when it is not executing a cygwin function. In this scenario,
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we rely on the win32 "SuspendThread" function. Cygwin will suspend the
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thread using this function and then inspect the location at which the
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thread is executing using the win32 "GetThreadContext" call. In theory,
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the program should not be executing in a win32 api since attempts to
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suspend a process executing a win32 call can cause disastrous results,
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especially on Win9x.
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If the process is executing in an unsafe location then setup_handler
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will return false as in the case above. Otherwise, the current location
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of the thread is pushed on the thread's signal stack and the thread is
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redirected to the sigdelayed function via the win32 "SetThreadContext"
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call. Then the thread is restarted using the win32 "ResumeThread" call
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and things proceed as per the sigdelayed discussion above.
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2001-09-17 20:10:02 +02:00
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This leads us to the sig_send function. This is the "client side" part
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of the signal manipulation process. sig_send is the low-level function
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2004-03-06 22:43:57 +01:00
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called by a high level process like kill() or pthread_kill().
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