0readmeAsynchIO.txt - emulators/simh - Rivoreo Source Code Repositories

 SIM_ASYNCH_IO

 Theory of operation.

 Features.
    - Optional Use.  Build with or without SIM_ASYNCH_IO defined and
      simulators will still build and perform correctly when run.
      Additionmally, a simulator built with SIM_ASYNCH_IO defined can
      dynamically disable and reenable asynchronous operation with
      the scp commands SET NOASYNCH and SET ASYNCH respectively.
    - Consistent Save/Restore state.  The state of a simulator saved
      on a simulator with (or without) Asynch support can be restored
      on any simulator of the same version with or without Asynch
      support.
    - Optimal behavior/performance with simulator running with or
      without CPU idling enabled.
    - Consistent minimum instruction scheduling delays when operating
      with or without SIM_ASYNCH_IO.  When SIM_ASYNCH_IO is emabled,
      any operation which would have been scheduled to occurr in 'n'
      instructions will still occur (from the simulated computer's
      point of view) at least 'n' instructions after it was initiated.

 Benefits.
    Allows a simulator to execute simulated instructions concurrently
    with I/O operations which may take numerous milliseconds to perform.
    Allows a simulated device to potentially avoid polling for the arrival
    of data.  Polling consumes host processor CPU cycles which may better
    be spent executing simulated instructions or letting other host
    processes run.  Measurements made of available instruction execution
    easily demonstrate the benefits of parallel instruction and I/O
    activities.  A VAX simulator with a process running a disk intensive
    application in one process was able to process 11 X the number of
    Dhrystone operations with Asynch I/O enabled.

 Asynch I/O is provided through a callback model.
 SimH Libraries which provide Asynch I/O support:
    sim_disk
    sim_tape
    sim_ether

 Requirements to use:
 The Simulator's instruction loop needs to be modified to include a single
 line which checks for asynchronouzly arrived events.  The vax_cpu.c
 module added the following line indicated by >>>:

 		/* Main instruction loop */

         for ( ;; ) {

         [...]
 >>>	        AIO_CHECK_EVENT;
         	if (sim_interval <= 0) {                /* chk clock queue */
         		temp = sim_process_event ();
         		if (temp)
         			ABORT (temp);
         		SET_IRQL;                           /* update interrupts */
         		}

 A global variable (sim_asynch_latency) is used to indicate the "interrupt
 dispatch latency".  This variable is the number of nanoseconds between checks
 for completed asynchronous I/O.  The default value is 4000 (4 usec) which
 corresponds reasonably with simulated hardware.  This variable controls
 the computation of sim_asynch_inst_latency which is the number of simulated
 instructions in the sim_asynch_latency interval.  We are trying to avoid
 checking for completed asynchronous I/O after every instruction since the
 actual checking every instruction can slow down execution.  Periodic checks
 provide a balance which allows response similar to real hardware while also
 providing minimal impact on actual instruction execution.  Meanwhile, if
 maximal response is desired, then the value of sim_asynch_latency can be
 set sufficiently low to assure that sim_asynch_inst_latency computes to 1.
 The sim_asynch_inst_latency is dynamically updated once per second in the
 sim_rtcn_calb routine where clock to instruction execution is dynamically
 determined.  A simulator would usually add register definitions
 to enable viewing and setting of these variables via scp:

 #if defined (SIM_ASYNCH_IO)
     { DRDATA (LATENCY, sim_asynch_latency, 32), PV_LEFT },
     { DRDATA (INST_LATENCY, sim_asynch_inst_latency, 32), PV_LEFT },
 #endif


 Naming conventions:
 All of the routines implemented in sim_disk and sim_tape have been kept
 in place.  All routines which perform I/O have a variant routine available
 with a "_a" appended to the the routine name with the addition of a single
 parameter which indicates the asynch completion callback routine.  For
 example there now exists the routines:
   t_stat sim_tape_rdrecf (UNIT *uptr, uint8 *buf, t_mtrlnt *bc, t_mtrlnt max);
   t_stat sim_tape_rdrecf_a (UNIT *uptr, uint8 *buf, t_mtrlnt *bc, t_mtrlnt max, TAPE_PCALLBACK callback);

 The Purpose of the callback function is to record the I/O completion status
 and then to schedule the activation of the unit.

 Considerations:
 Avoiding multiple concurrent users of the unit structure.  While asynch
 I/O is pending on a Unit, the unit should not otherwise be on the event
 queue.  The I/O completion will cause the Unit to be scheduled to run
 immediately to actually dispatch control flow to the callback routine.
 The callback routine is always called in the same thread which is
 executing instructions.  Since all simulator device data structures are
 only referenced from this thread there are no host multi-processor cache
 coherency issues to be concerned about.

 Arguments to the callback routine:
 UNIT *, and IO Status
 Requirements of the Callback routine.
 The callback routine must save the I/O completion status in a place
 which the next invocation of the unit service routine will reference
 and act on it.  This allows device code to return error conditions
 back to scp in a consistent way without regard to how the callback
 routine (and the actual I/O) may have been executed.

 Required change in device coding.
 Devices which wish to leverage the benefits of asynch I/O must rearrange
 the code which implements the unit service routine.  This rearrangement
 usually entails breaking the activities into two phases.  The first phase
 (I'll call the top half) involves performing whatever is needed to
 initiate a call to perform an I/O operation with a callback argument.
 Control is then immediately returned to the scp event dispatcher.
 The callback routine needs to be coded to stash away the io completion
 status and some indicator that an I/O has completed.
 The top/bottom half separation of the unit service routine would be
 coded to examine the I/O completion indicator and invoke the bottom half
 code upon completion.  The bottom half code should clear the I/O
 completion indicator and then perform any activities which normally
 need to occur after the I/O completes.  Care should be taken while
 performing these top/bottom half activities to return to the scp event
 dispatcher with either SCPE_OK or an appropriate error code when needed.
 The need to return error indications to the scp event dispatcher is why
 the bottom half activities can't simply be performed in the
 callback routine (the callback routine does not return a status).
 Care should also be taken to realize that local variables in the
 unit service routine will not directly survive between the separate
 top and bottom half calls to the unit service routine.  If any such
 information must be referenced in both the top and bottom half code paths
 then it must either be recomputed prior to the top/bottom half check
 or not stored in local variables of the unit service routine.

 Run time requirements to use SIM_ASYNCH_IO.
 The Posix threads API (pthreads) is required for asynchronous execution.
 Most *nix platforms have these APIs available and on these platforms
 simh is typically built with these available since on these platforms,
 pthreads is required for simh networking support.  Windows can also
 utilize the pthreads APIs if the compile and run time support for the
 win32Pthreads package has been installed on the build system.

 Sample Asynch I/O device implementations.
 The pdp11_rq.c module has been refactored to leverage the asynch I/O
 features of the sim_disk library.  The impact to this code to adopt the
 asynch I/O paradigm was quite minimal.
 The pdp11_rp.c module has also been refactored to leverage the asynch I/O
 features of the sim_disk library.
 The pdp11_tq.c module has been refactored to leverage the asynch I/O
 features of the sim_tape library.  The impact to this code to adopt the
 asynch I/O paradigm was very significant. This was due to the two facts:
 1) there are many different operations which can be requested of tape
 devices and 2) some of the tmscp operations required many separate
 operations on the physical device layer to perform a single tmscp request.
 This issue was addressed by adding additional routines to the physical
 device layer (in sim_tape.c) which combined these multiple operations.
 This approach will dovetail well with a potential future addition of
 operations on physical tapes as yet another supported tape format.
	SIM_ASYNCH_IO

	Theory of operation.

	Features.
	- Optional Use. Build with or without SIM_ASYNCH_IO defined and
	simulators will still build and perform correctly when run.
	Additionmally, a simulator built with SIM_ASYNCH_IO defined can
	dynamically disable and reenable asynchronous operation with
	the scp commands SET NOASYNCH and SET ASYNCH respectively.
	- Consistent Save/Restore state. The state of a simulator saved
	on a simulator with (or without) Asynch support can be restored
	on any simulator of the same version with or without Asynch
	support.
	- Optimal behavior/performance with simulator running with or
	without CPU idling enabled.
	- Consistent minimum instruction scheduling delays when operating
	with or without SIM_ASYNCH_IO. When SIM_ASYNCH_IO is emabled,
	any operation which would have been scheduled to occurr in 'n'
	instructions will still occur (from the simulated computer's
	point of view) at least 'n' instructions after it was initiated.

	Benefits.
	Allows a simulator to execute simulated instructions concurrently
	with I/O operations which may take numerous milliseconds to perform.
	Allows a simulated device to potentially avoid polling for the arrival
	of data. Polling consumes host processor CPU cycles which may better
	be spent executing simulated instructions or letting other host
	processes run. Measurements made of available instruction execution
	easily demonstrate the benefits of parallel instruction and I/O
	activities. A VAX simulator with a process running a disk intensive
	application in one process was able to process 11 X the number of
	Dhrystone operations with Asynch I/O enabled.

	Asynch I/O is provided through a callback model.
	SimH Libraries which provide Asynch I/O support:
	sim_disk
	sim_tape
	sim_ether

	Requirements to use:
	The Simulator's instruction loop needs to be modified to include a single
	line which checks for asynchronouzly arrived events. The vax_cpu.c
	module added the following line indicated by >>>:

	/* Main instruction loop */

	for ( ;; ) {

	[...]
	>>> AIO_CHECK_EVENT;
	if (sim_interval <= 0) { /* chk clock queue */
	temp = sim_process_event ();
	if (temp)
	ABORT (temp);
	SET_IRQL; /* update interrupts */
	}

	A global variable (sim_asynch_latency) is used to indicate the "interrupt
	dispatch latency". This variable is the number of nanoseconds between checks
	for completed asynchronous I/O. The default value is 4000 (4 usec) which
	corresponds reasonably with simulated hardware. This variable controls
	the computation of sim_asynch_inst_latency which is the number of simulated
	instructions in the sim_asynch_latency interval. We are trying to avoid
	checking for completed asynchronous I/O after every instruction since the
	actual checking every instruction can slow down execution. Periodic checks
	provide a balance which allows response similar to real hardware while also
	providing minimal impact on actual instruction execution. Meanwhile, if
	maximal response is desired, then the value of sim_asynch_latency can be
	set sufficiently low to assure that sim_asynch_inst_latency computes to 1.
	The sim_asynch_inst_latency is dynamically updated once per second in the
	sim_rtcn_calb routine where clock to instruction execution is dynamically
	determined. A simulator would usually add register definitions
	to enable viewing and setting of these variables via scp:

	#if defined (SIM_ASYNCH_IO)
	{ DRDATA (LATENCY, sim_asynch_latency, 32), PV_LEFT },
	{ DRDATA (INST_LATENCY, sim_asynch_inst_latency, 32), PV_LEFT },
	#endif


	Naming conventions:
	All of the routines implemented in sim_disk and sim_tape have been kept
	in place. All routines which perform I/O have a variant routine available
	with a "_a" appended to the the routine name with the addition of a single
	parameter which indicates the asynch completion callback routine. For
	example there now exists the routines:
	t_stat sim_tape_rdrecf (UNIT uptr, uint8 buf, t_mtrlnt *bc, t_mtrlnt max);
	t_stat sim_tape_rdrecf_a (UNIT uptr, uint8 buf, t_mtrlnt *bc, t_mtrlnt max, TAPE_PCALLBACK callback);

	The Purpose of the callback function is to record the I/O completion status
	and then to schedule the activation of the unit.

	Considerations:
	Avoiding multiple concurrent users of the unit structure. While asynch
	I/O is pending on a Unit, the unit should not otherwise be on the event
	queue. The I/O completion will cause the Unit to be scheduled to run
	immediately to actually dispatch control flow to the callback routine.
	The callback routine is always called in the same thread which is
	executing instructions. Since all simulator device data structures are
	only referenced from this thread there are no host multi-processor cache
	coherency issues to be concerned about.

	Arguments to the callback routine:
	UNIT *, and IO Status
	Requirements of the Callback routine.
	The callback routine must save the I/O completion status in a place
	which the next invocation of the unit service routine will reference
	and act on it. This allows device code to return error conditions
	back to scp in a consistent way without regard to how the callback
	routine (and the actual I/O) may have been executed.

	Required change in device coding.
	Devices which wish to leverage the benefits of asynch I/O must rearrange
	the code which implements the unit service routine. This rearrangement
	usually entails breaking the activities into two phases. The first phase
	(I'll call the top half) involves performing whatever is needed to
	initiate a call to perform an I/O operation with a callback argument.
	Control is then immediately returned to the scp event dispatcher.
	The callback routine needs to be coded to stash away the io completion
	status and some indicator that an I/O has completed.
	The top/bottom half separation of the unit service routine would be
	coded to examine the I/O completion indicator and invoke the bottom half
	code upon completion. The bottom half code should clear the I/O
	completion indicator and then perform any activities which normally
	need to occur after the I/O completes. Care should be taken while
	performing these top/bottom half activities to return to the scp event
	dispatcher with either SCPE_OK or an appropriate error code when needed.
	The need to return error indications to the scp event dispatcher is why
	the bottom half activities can't simply be performed in the
	callback routine (the callback routine does not return a status).
	Care should also be taken to realize that local variables in the
	unit service routine will not directly survive between the separate
	top and bottom half calls to the unit service routine. If any such
	information must be referenced in both the top and bottom half code paths
	then it must either be recomputed prior to the top/bottom half check
	or not stored in local variables of the unit service routine.

	Run time requirements to use SIM_ASYNCH_IO.
	The Posix threads API (pthreads) is required for asynchronous execution.
	Most *nix platforms have these APIs available and on these platforms
	simh is typically built with these available since on these platforms,
	pthreads is required for simh networking support. Windows can also
	utilize the pthreads APIs if the compile and run time support for the
	win32Pthreads package has been installed on the build system.

	Sample Asynch I/O device implementations.
	The pdp11_rq.c module has been refactored to leverage the asynch I/O
	features of the sim_disk library. The impact to this code to adopt the
	asynch I/O paradigm was quite minimal.
	The pdp11_rp.c module has also been refactored to leverage the asynch I/O
	features of the sim_disk library.
	The pdp11_tq.c module has been refactored to leverage the asynch I/O
	features of the sim_tape library. The impact to this code to adopt the
	asynch I/O paradigm was very significant. This was due to the two facts:
	1) there are many different operations which can be requested of tape
	devices and 2) some of the tmscp operations required many separate
	operations on the physical device layer to perform a single tmscp request.
	This issue was addressed by adding additional routines to the physical
	device layer (in sim_tape.c) which combined these multiple operations.
	This approach will dovetail well with a potential future addition of
	operations on physical tapes as yet another supported tape format.