Ravenbrook / Projects / Memory Pool System / Master Product Sources / Design Documents

Memory Pool System Project


                                 TRACER
                            design.mps.trace
                           incomplete design
                             drj 1996-09-25


ARCHITECTURE:

.instance.limit: There will be a limit on the number of traces that can be 
created at any one time.  This effectively limits the number of concurrent 
traces.  This limitation is expressed in the symbol TRACE_MAX [currently set to 
1, see request.mps.160020 "Multiple traces would not work"  drj 1998-06-15].

.rate: [see mail.nickb.1997-07-31.14-37].  [Now revised?  See 
request.epcore.160062 and change.epcore.minnow.160062.  drj 1998-06-15]

.exact.legal: Exact references should either point outside the arena (to 
non-managed address space) or to a tract allocated to a pool.  Exact references 
that are to addresses which the arena has reserved but hasn't allocated memory 
to are illegal (the exact reference couldn't possibly refer to a real object).  
Depending on the future semantics of PoolDestroy we might need to adjust our 
strategy here.  See mail.dsm.1996-02-14.18-18 for a strategy of coping 
gracefully with PoolDestroy.  We check that this is the case in the fixer.  It 
may be sensible to make this check CRITICAL in certain configurations.

.fix.fixed.all: ss->fixedSummary is accumulated (in the fixer) for all the 
pointers whether or not they are genuine references.  We could accumulate fewer 
pointers here; if a pointer fails the TractOfAddr test then we know it isn't a 
reference, so we needn't accumulate it into the fixed summary.  The design 
allows this, but it breaks a useful post-condition on scanning (if the 
accumulation of ss->fixedSummary was moved the accuracy of ss->fixedSummary 
would vary according to the "width" of the white summary).  See 
mail.pekka.1998-02-04.16-48 for improvement suggestions.


ANALYSIS:

.fix.copy-fail: Fixing can always succeed, even if copying the referenced 
object has failed (due to lack of memory, for example), by backing off to 
treating a reference as ambiguous.  Assuming that fixing an ambiguous reference 
doesn't allocate memory (which is no longer true for AMC for example).  See 
request.dylan.170560 for a slightly more sophisticated way to proceed when you 
can no longer allocate memory for copying.


IDEAS:

.flip.after: To avoid excessive barrier impact on the mutator immediately after 
flip, we could scan during flip other objects which are "near" the roots, or 
otherwise known to be likely to be accessed in the near future.


IMPLEMENTATION:

Speed

.fix: The fix path is critical to garbage collection speed.  Abstractly fix is 
applied to all the references in the non-white heap and all the references in 
the copied heap.  Remembered sets cut down the number of segments we have to 
scan.  The zone test cuts down the number of references we call fix on.  The 
speed of the remainder of the fix path is still critical to system 
performance.  Various modifications to and aspects of the system are concerned 
with maintaining the speed along this path.

.fix.tractofaddr: TractOfAddr is called on every reference that passes the zone 
test and is on the critical path, to determine whether the segment is white. 
There is no need to examine the segment to perform this test, since whiteness 
information is duplicated in tracts, specifically to optimize this test.  
TractOfAddr itself is a simple class dispatch function (which dispatches to the 
arena class's TractOfAddr method).  Inlining the dispatch and inlining the 
functions called by VMTractOfAddr makes a small but noticable difference to the 
speed of the dylan compiler.

.fix.noaver: AVERs in the code add bulk to the code (reducing I-cache efficacy) 
and add branches to the path (polluting the branch pedictors) resulting in a 
slow down.  Removing all the AVERs from the fix path improves the overall speed 
of the dylan compiler by as much as 9%.

.fix.nocopy: AMCFix used to copy objects by using the format's copy method.  
This involved a function call (through an indirection) and in dylan_copy a call 
to dylan_skip (to recompute the length) and call to memcpy with general 
parameters.  Replacing this with a direct call to memcpy removes these 
overheads and the call to memcpy now has aligned parameters.  The call to 
memcpy is inlined by the (C) compiler.  This change results in a 4-5% speed-up 
in the dylan compiler.

.reclaim: Because the reclaim phase of the trace (implemented by TraceReclaim) 
examines every segment it is fairly time intensive.  rit's profiles presented 
in request.dylan.170551 show a gap between the two varieties variety.hi and 
variety.wi.

.reclaim.noaver: Converting AVERs in the loops of TraceReclaim, PoolReclaim, 
AMCReclaim (LOReclaim? AWLReclaim) will result in a noticeable speed 
improvement [insert actual speed improvement here].

A. References

B. Document History

2002-06-07 RB Converted from MMInfo database design document.

C. Copyright and License

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