i386: Replace assembly versions of e_exp2f with generic e_exp2f.c

[glibc.git] / sysdeps / ia64 / memchr.S

/* Optimized version of the standard memchr() function.
   This file is part of the GNU C Library.
   Copyright (C) 2000-2017 Free Software Foundation, Inc.
   Contributed by Dan Pop <Dan.Pop@cern.ch>.

   The GNU C 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 C 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 C Library; if not, see
   <http://www.gnu.org/licenses/>.  */

/* Return: the address of the first occurence of chr in str or NULL

   Inputs:
        in0:    str
        in1:    chr
        in2:    byte count

   This implementation assumes little endian mode.  For big endian mode,
   the instruction czx1.r should be replaced by czx1.l.

   The algorithm is fairly straightforward: search byte by byte until we
   we get to a word aligned address, then search word by word as much as
   possible; the remaining few bytes are searched one at a time.

   The word by word search is performed by xor-ing the word with a word
   containing chr in every byte.  If there is a hit, the result will
   contain a zero byte in the corresponding position.  The presence and
   position of that zero byte is detected with a czx instruction.

   All the loops in this function could have had the internal branch removed
   if br.ctop and br.cloop could be predicated :-(.  */

#include <sysdep.h>
#undef ret

#define saved_pr        r15
#define saved_lc        r16
#define chr             r17
#define len             r18
#define last            r20
#define val             r21
#define tmp             r24
#define chrx8           r25
#define loopcnt         r30

#define str             in0

ENTRY(__memchr)
        .prologue
        alloc r2 = ar.pfs, 3, 0, 29, 32
#include "softpipe.h"
        .rotr   value[MEMLAT+1], addr[MEMLAT+3], aux[2], poschr[2]
        .rotp   p[MEMLAT+3]
        .save ar.lc, saved_lc
        mov     saved_lc = ar.lc        // save the loop counter
        .save pr, saved_pr
        mov     saved_pr = pr           // save the predicates
        .body
        mov     ret0 = str
        add     last = str, in2         // last byte
        and     tmp = 7, str            // tmp = str % 8
        cmp.ne  p7, p0 = r0, r0         // clear p7
        extr.u  chr = in1, 0, 8         // chr = (unsigned char) in1
        mov     len = in2
        cmp.gtu p6, p0 = 16, in2        // use a simple loop for short
(p6)    br.cond.spnt .srchfew ;;        // searches
        sub     loopcnt = 8, tmp        // loopcnt = 8 - tmp
        cmp.eq  p6, p0 = tmp, r0
(p6)    br.cond.sptk    .str_aligned;;
        sub     len = len, loopcnt
        adds    loopcnt = -1, loopcnt;;
        mov     ar.lc = loopcnt
.l1:
        ld1     val = [ret0], 1
        ;;
        cmp.eq  p6, p0 = val, chr
(p6)    br.cond.spnt    .foundit
        br.cloop.sptk   .l1 ;;
.str_aligned:
        cmp.ne  p6, p0 = r0, r0         // clear p6
        shr.u   loopcnt = len, 3        // loopcnt = len / 8
        and     len = 7, len ;;         // remaining len = len & 7
        adds    loopcnt = -1, loopcnt
        mov     ar.ec = MEMLAT + 3
        mux1    chrx8 = chr, @brcst ;;  // get a word full of chr
        mov     ar.lc = loopcnt
        mov     pr.rot = 1 << 16 ;;
.l2:
(p[0])          mov     addr[0] = ret0
(p[0])          ld8.s   value[0] = [ret0], 8     // speculative load
(p[MEMLAT])     chk.s   value[MEMLAT], .recovery // check and recovery
(p[MEMLAT])     xor     aux[0] = value[MEMLAT], chrx8
(p[MEMLAT+1])   czx1.r  poschr[0] = aux[1]
(p[MEMLAT+2])   cmp.ne  p7, p0 = 8, poschr[1]
(p7)            br.cond.dpnt .foundit
                br.ctop.dptk .l2
.srchfew:
        adds    loopcnt = -1, len
        cmp.eq  p6, p0 = len, r0
(p6)    br.cond.spnt .notfound ;;
        mov     ar.lc = loopcnt
.l3:
        ld1     val = [ret0], 1
        ;;
        cmp.eq  p6, p0 = val, chr
(p6)    br.cond.dpnt    .foundit
        br.cloop.sptk   .l3 ;;
.notfound:
        cmp.ne  p6, p0 = r0, r0 // clear p6 (p7 was already 0 when we got here)
        mov     ret0 = r0 ;;    // return NULL
.foundit:
        .pred.rel "mutex" p6, p7
(p6)    adds    ret0 = -1, ret0                    // if we got here from l1 or l3
(p7)    add     ret0 = addr[MEMLAT+2], poschr[1]   // if we got here from l2
        mov     pr = saved_pr, -1
        mov     ar.lc = saved_lc
        br.ret.sptk.many b0

.recovery:
#if MEMLAT != 6
# error "MEMLAT must be 6!"
#endif
(p[MEMLAT-6])   add     ret0 = -8, ret0;;
(p[MEMLAT-5])   add     ret0 = -8, ret0;;
(p[MEMLAT-4])   add     ret0 = -8, ret0;;
(p[MEMLAT-3])   add     ret0 = -8, ret0;;
(p[MEMLAT-2])   add     ret0 = -8, ret0;;
(p[MEMLAT-1])   add     ret0 = -8, ret0;;
(p[MEMLAT])     add     ret0 = -8, ret0;;
(p[MEMLAT+1])   add     ret0 = -8, ret0;;
(p[MEMLAT+2])   add     ret0 = -8, ret0;;
.l4:
        mov     addr[MEMLAT+2] = ret0
        ld8     tmp = [ret0];;          // load the first unchecked 8byte
        xor     aux[1] = tmp, chrx8;;
        czx1.r  poschr[1] = aux[1];;
        cmp.ne  p7, p0 = 8, poschr[1];;
(p7)    add     ret0 = addr[MEMLAT+2], poschr[1];;
(p7)    cmp.geu p6, p7 = ret0, last     // don't go over the last byte
(p6)    br.cond.spnt    .notfound;;
(p7)    br.cond.spnt    .foundit;;
        adds    ret0 = 8, ret0          // load the next unchecked 8byte
        br.sptk .l4;;

END(__memchr)

weak_alias (__memchr, memchr)
libc_hidden_builtin_def (memchr)