glibc/sysdeps/hppa/hppa1.1/mul_1.S

100 lines
2.9 KiB
ArmAsm

;! HP-PA-1.1 __mpn_mul_1 -- Multiply a limb vector with a limb and store
;! the result in a second limb vector.
;! Copyright (C) 1992-2016 Free Software Foundation, Inc.
;! This file is part of the GNU MP Library.
;! The GNU MP Library is free software; you can redistribute it and/or modify
;! it under the terms of the GNU Lesser General Public License as published by
;! the Free Software Foundation; either version 2.1 of the License, or (at your
;! option) any later version.
;! The GNU MP Library is distributed in the hope that it will be useful, but
;! WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
;! or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public
;! License for more details.
;! You should have received a copy of the GNU Lesser General Public License
;! along with the GNU MP Library. If not, see
;! <http://www.gnu.org/licenses/>.
;! INPUT PARAMETERS
;! res_ptr r26
;! s1_ptr r25
;! size r24
;! s2_limb r23
;! This runs at 9 cycles/limb on a PA7000. With the used instructions, it can
;! not become faster due to data cache contention after a store. On the
;! PA7100 it runs at 7 cycles/limb, and that can not be improved either, since
;! only the xmpyu does not need the integer pipeline, so the only dual-issue
;! we will get are addc+xmpyu. Unrolling would not help either CPU.
;! We could use fldds to read two limbs at a time from the S1 array, and that
;! could bring down the times to 8.5 and 6.5 cycles/limb for the PA7000 and
;! PA7100, respectively. We don't do that since it does not seem worth the
;! (alignment) troubles...
;! At least the PA7100 is rumored to be able to deal with cache-misses
;! without stalling instruction issue. If this is true, and the cache is
;! actually also lockup-free, we should use a deeper software pipeline, and
;! load from S1 very early; (The loads and stores to -12(sp) will surely be
;! in the cache.)
.text
.export __mpn_mul_1
__mpn_mul_1:
.proc
.callinfo frame=64,no_calls
.entry
ldo 64(%r30),%r30
fldws,ma 4(%r25),%fr5
stw %r23,-16(%r30) ;! move s2_limb ...
addib,= -1,%r24,L$just_one_limb
fldws -16(%r30),%fr4 ;! ... into fr4
add %r0,%r0,%r0 ;! clear carry
xmpyu %fr4,%fr5,%fr6
fldws,ma 4(%r25),%fr7
fstds %fr6,-16(%r30)
xmpyu %fr4,%fr7,%fr8
ldw -12(%r30),%r20 ;! least significant limb in product
ldw -16(%r30),%r28
fstds %fr8,-16(%r30)
addib,= -1,%r24,L$end
ldw -12(%r30),%r1
;! Main loop
L$loop:
fldws,ma 4(%r25),%fr5
stws,ma %r20,4(%r26)
addc %r28,%r1,%r20
xmpyu %fr4,%fr5,%fr6
ldw -16(%r30),%r28
fstds %fr6,-16(%r30)
addib,<> -1,%r24,L$loop
ldw -12(%r30),%r1
L$end:
stws,ma %r20,4(%r26)
addc %r28,%r1,%r20
ldw -16(%r30),%r28
stws,ma %r20,4(%r26)
addc %r0,%r28,%r28
bv 0(%r2)
ldo -64(%r30),%r30
L$just_one_limb:
xmpyu %fr4,%fr5,%fr6
fstds %fr6,-16(%r30)
ldw -16(%r30),%r28
ldo -64(%r30),%r30
bv 0(%r2)
fstws %fr6R,0(%r26)
.exit
.procend