ext/systemc/src/sysc/qt/README.PORT - testing/jenkins-gem5-prod - Git at Google

 Date: Tue, 11 Jan 94 13:23:11 -0800
 From: "pardo@cs.washington.edu" <pardo@meitner.cs.washington.edu>

 >[What's needed to get `qt' on an i860-based machine?]

 Almost certainly "some assembly required" (pun accepted).

 To write a cswap port, you need to understand the context switching
 model.  Turn to figure 2 in the QT TR.  Here's about what the assembly
 code looks like to implement that:

 	qt_cswap:
 		adjust stack pointer
 		save callee-save registers on to old's stack
 		argument register <- old sp
 		sp <- new sp
 		(*helper)(args...)
 		restore callee-save registers from new's stack
 		unadjust stack pointer
 		return

 Once more in slow motion:

 	- `old' thread calls context switch routine (new, a0, a1, h)
 	- cswap routine saves registers that have useful values
 	- cswap routine switches to new stack
 	- cswap routine calls helper function (*h)(old, a0, a1)
 	- when helper returns, cswap routine restores registers
 	  that were saved the last time `new' was suspended
 	- cswap routine returns to whatever `new' routine called the
 	  context switch routine

 There's a few tricks here.  First, how do you start a thread running
 for the very first time?  Answer is: fake some stuff on the stack
 so it *looks* like it was called from the middle of some routine.
 When the new thread is restarted, it is treated like any other
 thread.  It just so happens that it's never really run before, but
 you can't tell that because the saved state makes it look like like
 it's been run.  The return pc is set to point at a little stub of
 assembly code that loads up registers with the right values and
 then calls `only'.

 Second, I advise you to forget about varargs routines (at least
 until you get single-arg routines up and running).

 Third, on most machines `qt_abort' is the same as `qt_cswap' except
 that it need not save any callee-save registers.

 Fourth, `qt_cswap' needs to save and restore any floating-point
 registers that are callee-save (see your processor handbook).  On
 some machines, *no* floating-point registers are callee-save, so
 `qt_cswap' is exactly the same as the integer-only cswap routine.

 I suggest staring at the MIPS code for a few minutes.  It's "mostly"
 generic RISC code, so it gets a lot of the flavor across without
 getting too bogged down in little nitty details.


 Now for a bit more detail:  The stack is laid out to hold callee-save
 registers.  On many machines, I implemented fp cswap as save fp
 regs, call integer cswap, and when integer cswap returns (when the
 thread wakes up again), restore fp regs.

 For thread startup, I figure out some callee-save registers that
 I use to hold parameters to the startup routine (`only').  When
 the thread is being started it doesn't have any saved registers
 that need to be restored, but I go ahead and let the integer context
 switch routine restore some registers then "return" to the stub
 code.  The stub code then copies the "callee save" registers to
 argument registers and calls the startup routine.  That keeps the
 stub code pretty darn simple.

 For each machine I need to know the machine's procedure calling
 convention before I write a port.  I figure out how many callee-save
 registers are there and allocate enough stack space for those
 registers.  I also figure out how parameters are passed, since I
 will need to call the helper function.  On most RISC machines, I
 just need to put the old sp in the 0'th arg register and then call
 indirect through the 3rd arg register; the 1st and 2nd arg registers
 are already set up correctly.  Likewise, I don't touch the return
 value register between the helper's return and the context switch
 routine's return.

 I have a bunch of macros set up to do the stack initialization.
 The easiest way to debug this stuff is to go ahead and write a C
 routine to do stack initialization.  Once you're happy with it you
 can turn it in to a macro.

 In general there's a lot of ugly macros, but most of them do simple
 things like return constants, etc.  Any time you're looking at it
 and it looks confusing you just need to remember "this is actually
 simple code, the only tricky thing is calling the helper between
 the stack switch and the new thread's register restore."


 You will almost certainly need to write the assembly code fragment
 that starts a thread.  You might be able to do a lot of the context
 switch code with `setjmp' and `longjmp', if they *happen* to have
 the "right" implementation.  But getting all the details right (the
 helper can return a value to the new thread's cswap routine caller)
 is probaby trickier than writing code that does the minimum and
 thus doesn't have any extra instructions (or generality) to cause
 problems.

 I don't know of any ports besides those included with the source
 code distribution.   If you send me a port I will hapily add it to
 the distribution.

 Let me know as you have questions and/or comments.

 	;-D on  ( Now *that*'s a switch... )  Pardo
	Date: Tue, 11 Jan 94 13:23:11 -0800
	From: "pardo@cs.washington.edu" <pardo@meitner.cs.washington.edu>

	>[What's needed to get `qt' on an i860-based machine?]

	Almost certainly "some assembly required" (pun accepted).

	To write a cswap port, you need to understand the context switching
	model. Turn to figure 2 in the QT TR. Here's about what the assembly
	code looks like to implement that:

	qt_cswap:
	adjust stack pointer
	save callee-save registers on to old's stack
	argument register <- old sp
	sp <- new sp
	(*helper)(args...)
	restore callee-save registers from new's stack
	unadjust stack pointer
	return

	Once more in slow motion:

	- `old' thread calls context switch routine (new, a0, a1, h)
	- cswap routine saves registers that have useful values
	- cswap routine switches to new stack
	- cswap routine calls helper function (*h)(old, a0, a1)
	- when helper returns, cswap routine restores registers
	that were saved the last time `new' was suspended
	- cswap routine returns to whatever `new' routine called the
	context switch routine

	There's a few tricks here. First, how do you start a thread running
	for the very first time? Answer is: fake some stuff on the stack
	so it looks like it was called from the middle of some routine.
	When the new thread is restarted, it is treated like any other
	thread. It just so happens that it's never really run before, but
	you can't tell that because the saved state makes it look like like
	it's been run. The return pc is set to point at a little stub of
	assembly code that loads up registers with the right values and
	then calls `only'.

	Second, I advise you to forget about varargs routines (at least
	until you get single-arg routines up and running).

	Third, on most machines `qt_abort' is the same as `qt_cswap' except
	that it need not save any callee-save registers.

	Fourth, `qt_cswap' needs to save and restore any floating-point
	registers that are callee-save (see your processor handbook). On
	some machines, no floating-point registers are callee-save, so
	`qt_cswap' is exactly the same as the integer-only cswap routine.

	I suggest staring at the MIPS code for a few minutes. It's "mostly"
	generic RISC code, so it gets a lot of the flavor across without
	getting too bogged down in little nitty details.



	Now for a bit more detail: The stack is laid out to hold callee-save
	registers. On many machines, I implemented fp cswap as save fp
	regs, call integer cswap, and when integer cswap returns (when the
	thread wakes up again), restore fp regs.

	For thread startup, I figure out some callee-save registers that
	I use to hold parameters to the startup routine (`only'). When
	the thread is being started it doesn't have any saved registers
	that need to be restored, but I go ahead and let the integer context
	switch routine restore some registers then "return" to the stub
	code. The stub code then copies the "callee save" registers to
	argument registers and calls the startup routine. That keeps the
	stub code pretty darn simple.

	For each machine I need to know the machine's procedure calling
	convention before I write a port. I figure out how many callee-save
	registers are there and allocate enough stack space for those
	registers. I also figure out how parameters are passed, since I
	will need to call the helper function. On most RISC machines, I
	just need to put the old sp in the 0'th arg register and then call
	indirect through the 3rd arg register; the 1st and 2nd arg registers
	are already set up correctly. Likewise, I don't touch the return
	value register between the helper's return and the context switch
	routine's return.

	I have a bunch of macros set up to do the stack initialization.
	The easiest way to debug this stuff is to go ahead and write a C
	routine to do stack initialization. Once you're happy with it you
	can turn it in to a macro.

	In general there's a lot of ugly macros, but most of them do simple
	things like return constants, etc. Any time you're looking at it
	and it looks confusing you just need to remember "this is actually
	simple code, the only tricky thing is calling the helper between
	the stack switch and the new thread's register restore."


	You will almost certainly need to write the assembly code fragment
	that starts a thread. You might be able to do a lot of the context
	switch code with `setjmp' and `longjmp', if they happen to have
	the "right" implementation. But getting all the details right (the
	helper can return a value to the new thread's cswap routine caller)
	is probaby trickier than writing code that does the minimum and
	thus doesn't have any extra instructions (or generality) to cause
	problems.

	I don't know of any ports besides those included with the source
	code distribution. If you send me a port I will hapily add it to
	the distribution.

	Let me know as you have questions and/or comments.

	;-D on ( Now that's a switch... ) Pardo