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1da177e4c3
Initial git repository build. I'm not bothering with the full history, even though we have it. We can create a separate "historical" git archive of that later if we want to, and in the meantime it's about 3.2GB when imported into git - space that would just make the early git days unnecessarily complicated, when we don't have a lot of good infrastructure for it. Let it rip!
226 lines
7.2 KiB
ArmAsm
226 lines
7.2 KiB
ArmAsm
/*
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* arch/alpha/lib/ev6-clear_user.S
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* 21264 version contributed by Rick Gorton <rick.gorton@alpha-processor.com>
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*
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* Zero user space, handling exceptions as we go.
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*
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* We have to make sure that $0 is always up-to-date and contains the
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* right "bytes left to zero" value (and that it is updated only _after_
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* a successful copy). There is also some rather minor exception setup
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* stuff.
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*
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* NOTE! This is not directly C-callable, because the calling semantics
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* are different:
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*
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* Inputs:
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* length in $0
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* destination address in $6
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* exception pointer in $7
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* return address in $28 (exceptions expect it there)
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*
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* Outputs:
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* bytes left to copy in $0
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*
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* Clobbers:
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* $1,$2,$3,$4,$5,$6
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*
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* Much of the information about 21264 scheduling/coding comes from:
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* Compiler Writer's Guide for the Alpha 21264
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* abbreviated as 'CWG' in other comments here
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* ftp.digital.com/pub/Digital/info/semiconductor/literature/dsc-library.html
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* Scheduling notation:
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* E - either cluster
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* U - upper subcluster; U0 - subcluster U0; U1 - subcluster U1
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* L - lower subcluster; L0 - subcluster L0; L1 - subcluster L1
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* Try not to change the actual algorithm if possible for consistency.
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* Determining actual stalls (other than slotting) doesn't appear to be easy to do.
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* From perusing the source code context where this routine is called, it is
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* a fair assumption that significant fractions of entire pages are zeroed, so
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* it's going to be worth the effort to hand-unroll a big loop, and use wh64.
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* ASSUMPTION:
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* The believed purpose of only updating $0 after a store is that a signal
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* may come along during the execution of this chunk of code, and we don't
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* want to leave a hole (and we also want to avoid repeating lots of work)
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*/
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/* Allow an exception for an insn; exit if we get one. */
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#define EX(x,y...) \
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99: x,##y; \
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.section __ex_table,"a"; \
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.long 99b - .; \
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lda $31, $exception-99b($31); \
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.previous
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.set noat
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.set noreorder
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.align 4
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.globl __do_clear_user
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.ent __do_clear_user
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.frame $30, 0, $28
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.prologue 0
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# Pipeline info : Slotting & Comments
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__do_clear_user:
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and $6, 7, $4 # .. E .. .. : find dest head misalignment
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beq $0, $zerolength # U .. .. .. : U L U L
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addq $0, $4, $1 # .. .. .. E : bias counter
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and $1, 7, $2 # .. .. E .. : number of misaligned bytes in tail
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# Note - we never actually use $2, so this is a moot computation
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# and we can rewrite this later...
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srl $1, 3, $1 # .. E .. .. : number of quadwords to clear
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beq $4, $headalign # U .. .. .. : U L U L
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/*
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* Head is not aligned. Write (8 - $4) bytes to head of destination
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* This means $6 is known to be misaligned
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*/
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EX( ldq_u $5, 0($6) ) # .. .. .. L : load dst word to mask back in
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beq $1, $onebyte # .. .. U .. : sub-word store?
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mskql $5, $6, $5 # .. U .. .. : take care of misaligned head
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addq $6, 8, $6 # E .. .. .. : L U U L
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EX( stq_u $5, -8($6) ) # .. .. .. L :
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subq $1, 1, $1 # .. .. E .. :
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addq $0, $4, $0 # .. E .. .. : bytes left -= 8 - misalignment
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subq $0, 8, $0 # E .. .. .. : U L U L
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.align 4
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/*
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* (The .align directive ought to be a moot point)
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* values upon initial entry to the loop
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* $1 is number of quadwords to clear (zero is a valid value)
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* $2 is number of trailing bytes (0..7) ($2 never used...)
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* $6 is known to be aligned 0mod8
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*/
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$headalign:
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subq $1, 16, $4 # .. .. .. E : If < 16, we can not use the huge loop
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and $6, 0x3f, $2 # .. .. E .. : Forward work for huge loop
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subq $2, 0x40, $3 # .. E .. .. : bias counter (huge loop)
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blt $4, $trailquad # U .. .. .. : U L U L
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/*
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* We know that we're going to do at least 16 quads, which means we are
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* going to be able to use the large block clear loop at least once.
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* Figure out how many quads we need to clear before we are 0mod64 aligned
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* so we can use the wh64 instruction.
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*/
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nop # .. .. .. E
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nop # .. .. E ..
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nop # .. E .. ..
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beq $3, $bigalign # U .. .. .. : U L U L : Aligned 0mod64
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$alignmod64:
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EX( stq_u $31, 0($6) ) # .. .. .. L
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addq $3, 8, $3 # .. .. E ..
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subq $0, 8, $0 # .. E .. ..
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nop # E .. .. .. : U L U L
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nop # .. .. .. E
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subq $1, 1, $1 # .. .. E ..
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addq $6, 8, $6 # .. E .. ..
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blt $3, $alignmod64 # U .. .. .. : U L U L
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$bigalign:
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/*
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* $0 is the number of bytes left
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* $1 is the number of quads left
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* $6 is aligned 0mod64
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* we know that we'll be taking a minimum of one trip through
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* CWG Section 3.7.6: do not expect a sustained store rate of > 1/cycle
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* We are _not_ going to update $0 after every single store. That
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* would be silly, because there will be cross-cluster dependencies
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* no matter how the code is scheduled. By doing it in slightly
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* staggered fashion, we can still do this loop in 5 fetches
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* The worse case will be doing two extra quads in some future execution,
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* in the event of an interrupted clear.
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* Assumes the wh64 needs to be for 2 trips through the loop in the future
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* The wh64 is issued on for the starting destination address for trip +2
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* through the loop, and if there are less than two trips left, the target
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* address will be for the current trip.
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*/
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nop # E :
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nop # E :
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nop # E :
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bis $6,$6,$3 # E : U L U L : Initial wh64 address is dest
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/* This might actually help for the current trip... */
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$do_wh64:
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wh64 ($3) # .. .. .. L1 : memory subsystem hint
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subq $1, 16, $4 # .. .. E .. : Forward calculation - repeat the loop?
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EX( stq_u $31, 0($6) ) # .. L .. ..
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subq $0, 8, $0 # E .. .. .. : U L U L
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addq $6, 128, $3 # E : Target address of wh64
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EX( stq_u $31, 8($6) ) # L :
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EX( stq_u $31, 16($6) ) # L :
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subq $0, 16, $0 # E : U L L U
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nop # E :
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EX( stq_u $31, 24($6) ) # L :
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EX( stq_u $31, 32($6) ) # L :
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subq $0, 168, $5 # E : U L L U : two trips through the loop left?
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/* 168 = 192 - 24, since we've already completed some stores */
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subq $0, 16, $0 # E :
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EX( stq_u $31, 40($6) ) # L :
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EX( stq_u $31, 48($6) ) # L :
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cmovlt $5, $6, $3 # E : U L L U : Latency 2, extra mapping cycle
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subq $1, 8, $1 # E :
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subq $0, 16, $0 # E :
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EX( stq_u $31, 56($6) ) # L :
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nop # E : U L U L
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nop # E :
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subq $0, 8, $0 # E :
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addq $6, 64, $6 # E :
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bge $4, $do_wh64 # U : U L U L
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$trailquad:
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# zero to 16 quadwords left to store, plus any trailing bytes
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# $1 is the number of quadwords left to go.
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#
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nop # .. .. .. E
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nop # .. .. E ..
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nop # .. E .. ..
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beq $1, $trailbytes # U .. .. .. : U L U L : Only 0..7 bytes to go
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$onequad:
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EX( stq_u $31, 0($6) ) # .. .. .. L
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subq $1, 1, $1 # .. .. E ..
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subq $0, 8, $0 # .. E .. ..
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nop # E .. .. .. : U L U L
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nop # .. .. .. E
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nop # .. .. E ..
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addq $6, 8, $6 # .. E .. ..
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bgt $1, $onequad # U .. .. .. : U L U L
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# We have an unknown number of bytes left to go.
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$trailbytes:
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nop # .. .. .. E
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nop # .. .. E ..
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nop # .. E .. ..
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beq $0, $zerolength # U .. .. .. : U L U L
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# $0 contains the number of bytes left to copy (0..31)
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# so we will use $0 as the loop counter
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# We know for a fact that $0 > 0 zero due to previous context
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$onebyte:
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EX( stb $31, 0($6) ) # .. .. .. L
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subq $0, 1, $0 # .. .. E .. :
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addq $6, 1, $6 # .. E .. .. :
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bgt $0, $onebyte # U .. .. .. : U L U L
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$zerolength:
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$exception: # Destination for exception recovery(?)
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nop # .. .. .. E :
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nop # .. .. E .. :
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nop # .. E .. .. :
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ret $31, ($28), 1 # L0 .. .. .. : L U L U
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.end __do_clear_user
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