dnl x86 mpn_mul_basecase -- Multiply two limb vectors and store the result dnl in a third limb vector. dnl Copyright 1996, 1997, 1998, 1999, 2000, 2001, 2002 Free Software dnl Foundation, Inc. dnl dnl This file is part of the GNU MP Library. dnl dnl The GNU MP Library is free software; you can redistribute it and/or dnl modify it under the terms of the GNU Lesser General Public License as dnl published by the Free Software Foundation; either version 2.1 of the dnl License, or (at your option) any later version. dnl dnl The GNU MP Library is distributed in the hope that it will be useful, dnl but WITHOUT ANY WARRANTY; without even the implied warranty of dnl MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU dnl Lesser General Public License for more details. dnl dnl You should have received a copy of the GNU Lesser General Public dnl License along with the GNU MP Library; see the file COPYING.LIB. If dnl not, write to the Free Software Foundation, Inc., 51 Franklin Street, dnl Fifth Floor, Boston, MA 02110-1301, USA. include(`../config.m4') C cycles/crossproduct C P5: 15 C P6: 7.5 C K6: 12.5 C K7: 5.5 C P4: 24 C void mpn_mul_basecase (mp_ptr wp, C mp_srcptr xp, mp_size_t xsize, C mp_srcptr yp, mp_size_t ysize); C C This was written in a haste since the Pentium optimized code that was used C for all x86 machines was slow for the Pentium II. This code would benefit C from some cleanup. C C To shave off some percentage of the run-time, one should make 4 variants C of the Louter loop, for the four different outcomes of un mod 4. That C would avoid Loop0 altogether. Code expansion would be > 4-fold for that C part of the function, but since it is not very large, that would be C acceptable. C C The mul loop (at L(oopM)) might need some tweaking. It's current speed is C unknown. defframe(PARAM_YSIZE,20) defframe(PARAM_YP, 16) defframe(PARAM_XSIZE,12) defframe(PARAM_XP, 8) defframe(PARAM_WP, 4) defframe(VAR_MULTIPLIER, -4) defframe(VAR_COUNTER, -8) deflit(VAR_STACK_SPACE, 8) TEXT ALIGN(8) PROLOGUE(mpn_mul_basecase) deflit(`FRAME',0) subl $VAR_STACK_SPACE,%esp pushl %esi pushl %ebp pushl %edi deflit(`FRAME',eval(VAR_STACK_SPACE+12)) movl PARAM_XP,%esi movl PARAM_WP,%edi movl PARAM_YP,%ebp movl (%esi),%eax C load xp[0] mull (%ebp) C multiply by yp[0] movl %eax,(%edi) C store to wp[0] movl PARAM_XSIZE,%ecx C xsize decl %ecx C If xsize = 1, ysize = 1 too jz L(done) pushl %ebx FRAME_pushl() movl %edx,%ebx leal 4(%esi),%esi leal 4(%edi),%edi L(oopM): movl (%esi),%eax C load next limb at xp[j] leal 4(%esi),%esi mull (%ebp) addl %ebx,%eax movl %edx,%ebx adcl $0,%ebx movl %eax,(%edi) leal 4(%edi),%edi decl %ecx jnz L(oopM) movl %ebx,(%edi) C most significant limb of product addl $4,%edi C increment wp movl PARAM_XSIZE,%eax shll $2,%eax subl %eax,%edi subl %eax,%esi movl PARAM_YSIZE,%eax C ysize decl %eax jz L(skip) movl %eax,VAR_COUNTER C set index i to ysize L(outer): movl PARAM_YP,%ebp C yp addl $4,%ebp C make ebp point to next v limb movl %ebp,PARAM_YP movl (%ebp),%eax C copy y limb ... movl %eax,VAR_MULTIPLIER C ... to stack slot movl PARAM_XSIZE,%ecx xorl %ebx,%ebx andl $3,%ecx jz L(end0) L(oop0): movl (%esi),%eax mull VAR_MULTIPLIER leal 4(%esi),%esi addl %ebx,%eax movl $0,%ebx adcl %ebx,%edx addl %eax,(%edi) adcl %edx,%ebx C propagate carry into cylimb leal 4(%edi),%edi decl %ecx jnz L(oop0) L(end0): movl PARAM_XSIZE,%ecx shrl $2,%ecx jz L(endX) ALIGN(8) L(oopX): movl (%esi),%eax mull VAR_MULTIPLIER addl %eax,%ebx movl $0,%ebp adcl %edx,%ebp movl 4(%esi),%eax mull VAR_MULTIPLIER addl %ebx,(%edi) adcl %eax,%ebp C new lo + cylimb movl $0,%ebx adcl %edx,%ebx movl 8(%esi),%eax mull VAR_MULTIPLIER addl %ebp,4(%edi) adcl %eax,%ebx C new lo + cylimb movl $0,%ebp adcl %edx,%ebp movl 12(%esi),%eax mull VAR_MULTIPLIER addl %ebx,8(%edi) adcl %eax,%ebp C new lo + cylimb movl $0,%ebx adcl %edx,%ebx addl %ebp,12(%edi) adcl $0,%ebx C propagate carry into cylimb leal 16(%esi),%esi leal 16(%edi),%edi decl %ecx jnz L(oopX) L(endX): movl %ebx,(%edi) addl $4,%edi C we incremented wp and xp in the loop above; compensate movl PARAM_XSIZE,%eax shll $2,%eax subl %eax,%edi subl %eax,%esi movl VAR_COUNTER,%eax decl %eax movl %eax,VAR_COUNTER jnz L(outer) L(skip): popl %ebx popl %edi popl %ebp popl %esi addl $8,%esp ret L(done): movl %edx,4(%edi) C store to wp[1] popl %edi popl %ebp popl %esi addl $8,%esp ret EPILOGUE()