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We stopped adding "Contributed by" or similar lines in sources in 2012 in favour of git logs and keeping the Contributors section of the glibc manual up to date. Removing these lines makes the license header a bit more consistent across files and also removes the possibility of error in attribution when license blocks or files are copied across since the contributed-by lines don't actually reflect reality in those cases. Move all "Contributed by" and similar lines (Written by, Test by, etc.) into a new file CONTRIBUTED-BY to retain record of these contributions. These contributors are also mentioned in manual/contrib.texi, so we just maintain this additional record as a courtesy to the earlier developers. The following scripts were used to filter a list of files to edit in place and to clean up the CONTRIBUTED-BY file respectively. These were not added to the glibc sources because they're not expected to be of any use in future given that this is a one time task: https://gist.github.com/siddhesh/b5ecac94eabfd72ed2916d6d8157e7dc https://gist.github.com/siddhesh/15ea1f5e435ace9774f485030695ee02 Reviewed-by: Carlos O'Donell <carlos@redhat.com>
313 lines
7.8 KiB
ArmAsm
313 lines
7.8 KiB
ArmAsm
/* Optimized version of the standard bzero() function.
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This file is part of the GNU C Library.
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Copyright (C) 2000-2021 Free Software Foundation, Inc.
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The GNU C Library is free software; you can redistribute it and/or
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modify it under the terms of the GNU Lesser General Public
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License as published by the Free Software Foundation; either
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version 2.1 of the License, or (at your option) any later version.
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The GNU C Library is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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Lesser General Public License for more details.
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You should have received a copy of the GNU Lesser General Public
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License along with the GNU C Library; if not, see
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<https://www.gnu.org/licenses/>. */
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/* Return: dest
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Inputs:
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in0: dest
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in1: count
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The algorithm is fairly straightforward: set byte by byte until we
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we get to a 16B-aligned address, then loop on 128 B chunks using an
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early store as prefetching, then loop on 32B chucks, then clear remaining
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words, finally clear remaining bytes.
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Since a stf.spill f0 can store 16B in one go, we use this instruction
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to get peak speed. */
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#include <sysdep.h>
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#undef ret
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#define dest in0
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#define cnt in1
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#define tmp r31
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#define save_lc r30
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#define ptr0 r29
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#define ptr1 r28
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#define ptr2 r27
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#define ptr3 r26
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#define ptr9 r24
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#define loopcnt r23
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#define linecnt r22
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#define bytecnt r21
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// This routine uses only scratch predicate registers (p6 - p15)
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#define p_scr p6 // default register for same-cycle branches
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#define p_unalgn p9
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#define p_y p11
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#define p_n p12
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#define p_yy p13
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#define p_nn p14
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#define movi0 mov
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#define MIN1 15
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#define MIN1P1HALF 8
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#define LINE_SIZE 128
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#define LSIZE_SH 7 // shift amount
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#define PREF_AHEAD 8
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#define USE_FLP
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#if defined(USE_INT)
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#define store st8
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#define myval r0
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#elif defined(USE_FLP)
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#define store stf8
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#define myval f0
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#endif
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.align 64
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ENTRY(bzero)
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{ .mmi
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.prologue
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alloc tmp = ar.pfs, 2, 0, 0, 0
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lfetch.nt1 [dest]
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.save ar.lc, save_lc
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movi0 save_lc = ar.lc
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} { .mmi
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.body
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mov ret0 = dest // return value
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nop.m 0
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cmp.eq p_scr, p0 = cnt, r0
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;; }
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{ .mmi
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and ptr2 = -(MIN1+1), dest // aligned address
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and tmp = MIN1, dest // prepare to check for alignment
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tbit.nz p_y, p_n = dest, 0 // Do we have an odd address? (M_B_U)
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} { .mib
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mov ptr1 = dest
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nop.i 0
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(p_scr) br.ret.dpnt.many rp // return immediately if count = 0
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;; }
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{ .mib
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cmp.ne p_unalgn, p0 = tmp, r0
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} { .mib // NB: # of bytes to move is 1
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sub bytecnt = (MIN1+1), tmp // higher than loopcnt
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cmp.gt p_scr, p0 = 16, cnt // is it a minimalistic task?
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(p_scr) br.cond.dptk.many .move_bytes_unaligned // go move just a few (M_B_U)
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;; }
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{ .mmi
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(p_unalgn) add ptr1 = (MIN1+1), ptr2 // after alignment
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(p_unalgn) add ptr2 = MIN1P1HALF, ptr2 // after alignment
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(p_unalgn) tbit.nz.unc p_y, p_n = bytecnt, 3 // should we do a st8 ?
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;; }
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{ .mib
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(p_y) add cnt = -8, cnt
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(p_unalgn) tbit.nz.unc p_yy, p_nn = bytecnt, 2 // should we do a st4 ?
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} { .mib
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(p_y) st8 [ptr2] = r0,-4
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(p_n) add ptr2 = 4, ptr2
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;; }
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{ .mib
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(p_yy) add cnt = -4, cnt
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(p_unalgn) tbit.nz.unc p_y, p_n = bytecnt, 1 // should we do a st2 ?
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} { .mib
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(p_yy) st4 [ptr2] = r0,-2
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(p_nn) add ptr2 = 2, ptr2
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;; }
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{ .mmi
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mov tmp = LINE_SIZE+1 // for compare
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(p_y) add cnt = -2, cnt
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(p_unalgn) tbit.nz.unc p_yy, p_nn = bytecnt, 0 // should we do a st1 ?
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} { .mmi
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nop.m 0
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(p_y) st2 [ptr2] = r0,-1
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(p_n) add ptr2 = 1, ptr2
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;; }
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{ .mmi
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(p_yy) st1 [ptr2] = r0
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cmp.gt p_scr, p0 = tmp, cnt // is it a minimalistic task?
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} { .mbb
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(p_yy) add cnt = -1, cnt
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(p_scr) br.cond.dpnt.many .fraction_of_line // go move just a few
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;; }
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{ .mib
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nop.m 0
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shr.u linecnt = cnt, LSIZE_SH
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nop.b 0
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;; }
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.align 32
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.l1b: // ------------------// L1B: store ahead into cache lines; fill later
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{ .mmi
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and tmp = -(LINE_SIZE), cnt // compute end of range
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mov ptr9 = ptr1 // used for prefetching
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and cnt = (LINE_SIZE-1), cnt // remainder
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} { .mmi
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mov loopcnt = PREF_AHEAD-1 // default prefetch loop
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cmp.gt p_scr, p0 = PREF_AHEAD, linecnt // check against actual value
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;; }
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{ .mmi
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(p_scr) add loopcnt = -1, linecnt
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add ptr2 = 16, ptr1 // start of stores (beyond prefetch stores)
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add ptr1 = tmp, ptr1 // first address beyond total range
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;; }
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{ .mmi
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add tmp = -1, linecnt // next loop count
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movi0 ar.lc = loopcnt
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;; }
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.pref_l1b:
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{ .mib
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stf.spill [ptr9] = f0, 128 // Do stores one cache line apart
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nop.i 0
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br.cloop.dptk.few .pref_l1b
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;; }
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{ .mmi
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add ptr0 = 16, ptr2 // Two stores in parallel
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movi0 ar.lc = tmp
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;; }
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.l1bx:
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{ .mmi
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stf.spill [ptr2] = f0, 32
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stf.spill [ptr0] = f0, 32
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;; }
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{ .mmi
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stf.spill [ptr2] = f0, 32
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stf.spill [ptr0] = f0, 32
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;; }
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{ .mmi
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stf.spill [ptr2] = f0, 32
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stf.spill [ptr0] = f0, 64
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cmp.lt p_scr, p0 = ptr9, ptr1 // do we need more prefetching?
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;; }
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{ .mmb
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stf.spill [ptr2] = f0, 32
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(p_scr) stf.spill [ptr9] = f0, 128
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br.cloop.dptk.few .l1bx
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;; }
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{ .mib
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cmp.gt p_scr, p0 = 8, cnt // just a few bytes left ?
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(p_scr) br.cond.dpnt.many .move_bytes_from_alignment
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;; }
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.fraction_of_line:
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{ .mib
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add ptr2 = 16, ptr1
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shr.u loopcnt = cnt, 5 // loopcnt = cnt / 32
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;; }
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{ .mib
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cmp.eq p_scr, p0 = loopcnt, r0
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add loopcnt = -1, loopcnt
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(p_scr) br.cond.dpnt.many .store_words
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;; }
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{ .mib
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and cnt = 0x1f, cnt // compute the remaining cnt
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movi0 ar.lc = loopcnt
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;; }
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.align 32
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.l2: // -----------------------------// L2A: store 32B in 2 cycles
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{ .mmb
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store [ptr1] = myval, 8
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store [ptr2] = myval, 8
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;; } { .mmb
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store [ptr1] = myval, 24
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store [ptr2] = myval, 24
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br.cloop.dptk.many .l2
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;; }
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.store_words:
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{ .mib
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cmp.gt p_scr, p0 = 8, cnt // just a few bytes left ?
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(p_scr) br.cond.dpnt.many .move_bytes_from_alignment // Branch
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;; }
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{ .mmi
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store [ptr1] = myval, 8 // store
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cmp.le p_y, p_n = 16, cnt //
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add cnt = -8, cnt // subtract
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;; }
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{ .mmi
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(p_y) store [ptr1] = myval, 8 // store
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(p_y) cmp.le.unc p_yy, p_nn = 16, cnt
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(p_y) add cnt = -8, cnt // subtract
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;; }
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{ .mmi // store
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(p_yy) store [ptr1] = myval, 8
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(p_yy) add cnt = -8, cnt // subtract
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;; }
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.move_bytes_from_alignment:
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{ .mib
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cmp.eq p_scr, p0 = cnt, r0
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tbit.nz.unc p_y, p0 = cnt, 2 // should we terminate with a st4 ?
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(p_scr) br.cond.dpnt.few .restore_and_exit
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;; }
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{ .mib
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(p_y) st4 [ptr1] = r0,4
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tbit.nz.unc p_yy, p0 = cnt, 1 // should we terminate with a st2 ?
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;; }
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{ .mib
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(p_yy) st2 [ptr1] = r0,2
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tbit.nz.unc p_y, p0 = cnt, 0 // should we terminate with a st1 ?
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;; }
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{ .mib
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(p_y) st1 [ptr1] = r0
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;; }
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.restore_and_exit:
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{ .mib
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nop.m 0
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movi0 ar.lc = save_lc
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br.ret.sptk.many rp
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;; }
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.move_bytes_unaligned:
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{ .mmi
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.pred.rel "mutex",p_y, p_n
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.pred.rel "mutex",p_yy, p_nn
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(p_n) cmp.le p_yy, p_nn = 4, cnt
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(p_y) cmp.le p_yy, p_nn = 5, cnt
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(p_n) add ptr2 = 2, ptr1
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} { .mmi
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(p_y) add ptr2 = 3, ptr1
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(p_y) st1 [ptr1] = r0, 1 // fill 1 (odd-aligned) byte
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(p_y) add cnt = -1, cnt // [15, 14 (or less) left]
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;; }
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{ .mmi
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(p_yy) cmp.le.unc p_y, p0 = 8, cnt
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add ptr3 = ptr1, cnt // prepare last store
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movi0 ar.lc = save_lc
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} { .mmi
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(p_yy) st2 [ptr1] = r0, 4 // fill 2 (aligned) bytes
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(p_yy) st2 [ptr2] = r0, 4 // fill 2 (aligned) bytes
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(p_yy) add cnt = -4, cnt // [11, 10 (o less) left]
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;; }
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{ .mmi
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(p_y) cmp.le.unc p_yy, p0 = 8, cnt
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add ptr3 = -1, ptr3 // last store
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tbit.nz p_scr, p0 = cnt, 1 // will there be a st2 at the end ?
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} { .mmi
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(p_y) st2 [ptr1] = r0, 4 // fill 2 (aligned) bytes
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(p_y) st2 [ptr2] = r0, 4 // fill 2 (aligned) bytes
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(p_y) add cnt = -4, cnt // [7, 6 (or less) left]
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;; }
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{ .mmi
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(p_yy) st2 [ptr1] = r0, 4 // fill 2 (aligned) bytes
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(p_yy) st2 [ptr2] = r0, 4 // fill 2 (aligned) bytes
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// [3, 2 (or less) left]
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tbit.nz p_y, p0 = cnt, 0 // will there be a st1 at the end ?
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} { .mmi
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(p_yy) add cnt = -4, cnt
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;; }
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{ .mmb
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(p_scr) st2 [ptr1] = r0 // fill 2 (aligned) bytes
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(p_y) st1 [ptr3] = r0 // fill last byte (using ptr3)
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br.ret.sptk.many rp
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;; }
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END(bzero)
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