dnl core2 mpn_mul_basecase dnl Copyright 2008,2009 Jason Moxham dnl This file is part of the MPIR Library. dnl The MPIR Library is free software; you can redistribute it and/or modify dnl it under the terms of the GNU Lesser General Public License as published dnl by the Free Software Foundation; either version 2.1 of the License, or (at dnl your option) any later version. dnl The MPIR Library is distributed in the hope that it will be useful, but dnl WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY dnl or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public dnl License for more details. dnl You should have received a copy of the GNU Lesser General Public License dnl along with the MPIR Library; see the file COPYING.LIB. If not, write dnl to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, dnl Boston, MA 02110-1301, USA. include(`../config.m4') C (rdi,rdx+r8)=(rsi,rdx)*(rcx,r8) # Version 1.0.5 # same as the addmul for now # changes from standard mul # change r8 to r12 and rcx to r13 # reemove ret and write last limb define(`MULLOOP',` ALIGN(16) mulloop$1: mov `$'0,%r10 mul %r13 mov %r12,(%rdi,%r11,8) add %rax,%r9 .byte 0x26 adc %rdx,%r10 mov 16(%rsi,%r11,8),%rax mul %r13 mov %r9,8(%rdi,%r11,8) add %rax,%r10 mov `$'0,%ebx adc %rdx,%rbx mov 24(%rsi,%r11,8),%rax mov `$'0,%r12 mov `$'0,%r9 mul %r13 mov %r10,16(%rdi,%r11,8) .byte 0x26 add %rax,%rbx .byte 0x26 adc %rdx,%r12 mov 32(%rsi,%r11,8),%rax mul %r13 mov %rbx,24(%rdi,%r11,8) .byte 0x26 add %rax,%r12 .byte 0x26 adc %rdx,%r9 add `$'4,%r11 mov 8(%rsi,%r11,8),%rax jnc mulloop$1 ') define(`MULNEXT0',` mov 16(%rsi,%r11,8),%rax mul %r13 mov %r9,8(%rdi,%r11,8) add %rax,%r10 mov `$'0,%ebx adc %rdx,%rbx mov 24(%rsi,%r11,8),%rax mov `$'0,%r12d mul %r13 mov %r10,16(%rdi,%r11,8) add %rax,%rbx adc %rdx,%r12 mov 32(%rsi,%r11,8),%rax mul %r13 mov %rbx,24(%rdi,%r11,8) add %rax,%r12 adc `$'0,%rdx mov %r12,32(%rdi,%r11,8) mov %rdx,40(%rdi,%r11,8) #inc %r8 add `$'1,%r8 mov (%rsi,%r14,8),%rax mov %r14,%r11 ') define(`MULNEXT1',` mov 16(%rsi,%r11,8),%rax mul %r13 mov %r9,8(%rdi,%r11,8) add %rax,%r10 mov `$'0,%r12d adc %rdx,%r12 mov 24(%rsi,%r11,8),%rax mul %r13 mov %r10,16(%rdi,%r11,8) add %rax,%r12 adc `$'0,%rdx mov %r12,24(%rdi,%r11,8) mov %rdx,32(%rdi,%r11,8) #inc %r8 add `$'1,%r8 lea 8(%rdi),%rdi ') define(`MULNEXT2',` mov 16(%rsi,%r11,8),%rax mul %r13 mov %r9,8(%rdi,%r11,8) add %rax,%r10 mov `$'0,%ebx adc %rdx,%rbx mov %r10,16(%rdi,%r11,8) mov %rbx,24(%rdi,%r11,8) #inc %r8 add `$'1,%r8 mov (%rsi,%r14,8),%rax mov %r14,%r11 ') define(`MULNEXT3',` mov %r9,8(%rdi,%r11,8) mov %r10,16(%rdi,%r11,8) #inc %r8 add `$'1,%r8 lea 8(%rdi),%rdi ') # changes from standard addmul # change r8 to r12 and rcx to r13 # reemove ret and write last limb define(`ADDMULLOOP',` ALIGN(16) addmulloop$1: mov `$'0,%r10 mul %r13 add %r12,(%rdi,%r11,8) adc %rax,%r9 .byte 0x26 adc %rdx,%r10 mov 16(%rsi,%r11,8),%rax mul %r13 add %r9,8(%rdi,%r11,8) adc %rax,%r10 mov `$'0,%ebx adc %rdx,%rbx mov 24(%rsi,%r11,8),%rax mov `$'0,%r12 mov `$'0,%r9 mul %r13 add %r10,16(%rdi,%r11,8) .byte 0x26 adc %rax,%rbx .byte 0x26 adc %rdx,%r12 mov 32(%rsi,%r11,8),%rax mul %r13 add %rbx,24(%rdi,%r11,8) .byte 0x26 adc %rax,%r12 .byte 0x26 adc %rdx,%r9 add `$'4,%r11 mov 8(%rsi,%r11,8),%rax jnc addmulloop$1 ') define(`ADDMULPRO0',` #mov (%rsi,%r14,8),%rax mov (%rcx,%r8,8),%r13 lea 8(%rdi),%rdi #mov %r14,%r11 mul %r13 mov %rax,%r12 mov 8(%rsi,%r14,8),%rax mov %rdx,%r9 cmp `$'0,%r14 ') define(`ADDMULNEXT0',` mov `$'0,%r10d mul %r13 add %r12,(%rdi,%r11,8) adc %rax,%r9 adc %rdx,%r10 mov 16(%rsi,%r11,8),%rax mul %r13 add %r9,8(%rdi,%r11,8) adc %rax,%r10 mov `$'0,%ebx adc %rdx,%rbx mov 24(%rsi,%r11,8),%rax mov `$'0,%r12d mul %r13 add %r10,16(%rdi,%r11,8) adc %rax,%rbx adc %rdx,%r12 mov 32(%rsi,%r11,8),%rax mul %r13 add %rbx,24(%rdi,%r11,8) adc %rax,%r12 adc `$'0,%rdx add %r12,32(%rdi,%r11,8) mov (%rsi,%r14,8),%rax adc `$'0,%rdx #inc %r8 add `$'1,%r8 mov %rdx,40(%rdi,%r11,8) mov %r14,%r11 #lea 8(%rdi),%rdi ') define(`ADDMULPRO1',` mov (%rsi,%r14,8),%rax mov (%rcx,%r8,8),%r13 mov %r14,%r11 mul %r13 mov %rax,%r12 mov 8(%rsi,%r14,8),%rax mov %rdx,%r9 cmp `$'0,%r14 ') define(`ADDMULNEXT1',` mov `$'0,%r10d mul %r13 add %r12,(%rdi,%r11,8) adc %rax,%r9 adc %rdx,%r10 mov 16(%rsi,%r11,8),%rax mul %r13 add %r9,8(%rdi,%r11,8) adc %rax,%r10 mov `$'0,%r12d adc %rdx,%r12 mov 24(%rsi,%r11,8),%rax mul %r13 add %r10,16(%rdi,%r11,8) adc %rax,%r12 adc `$'0,%rdx add %r12,24(%rdi,%r11,8) adc `$'0,%rdx mov %rdx,32(%rdi,%r11,8) #inc %r8 add `$'1,%r8 lea 8(%rdi),%rdi ') define(`ADDMULPRO2',` mov (%rcx,%r8,8),%r13 lea 8(%rdi),%rdi mul %r13 mov %rax,%r12 mov 8(%rsi,%r14,8),%rax mov %rdx,%r9 cmp `$'0,%r14 ') define(`ADDMULNEXT2',` mov `$'0,%r10d mul %r13 add %r12,(%rdi,%r11,8) adc %rax,%r9 adc %rdx,%r10 mov 16(%rsi,%r11,8),%rax mul %r13 mov `$'0,%ebx add %r9,8(%rdi,%r11,8) adc %rax,%r10 adc %rdx,%rbx mov (%rsi,%r14,8),%rax add %r10,16(%rdi,%r11,8) adc `$'0,%rbx mov %rbx,24(%rdi,%r11,8) #inc %r8 add `$'1,%r8 mov %r14,%r11 ') define(`ADDMULPRO3',` mov (%rsi,%r14,8),%rax mov (%rcx,%r8,8),%r13 mov %r14,%r11 mul %r13 mov %rax,%r12 mov 8(%rsi,%r14,8),%rax mov %rdx,%r9 cmp `$'0,%r14 ') define(`ADDMULNEXT3',` mul %r13 add %r12,(%rdi,%r11,8) adc %rax,%r9 mov `$'0,%r10d adc %rdx,%r10 add %r9,8(%rdi,%r11,8) adc `$'0,%r10 mov %r10,16(%rdi,%r11,8) #inc %r8 add `$'1,%r8 lea 8(%rdi),%rdi ') define(`MPN_MULADDMUL_1_INT',` MULNEXT$1 jz end$1 ALIGN(16) loopaddmul$1: ADDMULPRO$1 jge addmulskiploop$1 ADDMULLOOP($1) addmulskiploop$1: ADDMULNEXT$1 jnz loopaddmul$1 end$1: mov -8(%rsp),%r13 mov -16(%rsp),%r14 mov -24(%rsp),%rbx mov -32(%rsp),%r12 ret ') ASM_START() PROLOGUE(mpn_mul_basecase) # the current mul does not handle case one cmp $2,%rdx jz two jb one mov %r13,-8(%rsp) mov %r14,-16(%rsp) mov %rbx,-24(%rsp) mov %r12,-32(%rsp) mov $5,%r14 sub %rdx,%r14 lea -40(%rdi,%rdx,8),%rdi lea (%rcx,%r8,8),%rcx neg %r8 lea -40(%rsi,%rdx,8),%rsi mov (%rsi,%r14,8),%rax mov (%rcx,%r8,8),%r13 mov %r14,%r11 mul %r13 mov %rax,%r12 mov 8(%rsi,%r14,8),%rax mov %rdx,%r9 cmp $0,%r14 jge mulskiploop MULLOOP(1) mulskiploop: mov $0,%r10d mul %r13 mov %r12,(%rdi,%r11,8) add %rax,%r9 adc %rdx,%r10 cmp $2,%r11 ja case3 jz case2 jp case1 case0: MPN_MULADDMUL_1_INT(0) ALIGN(16) case1: MPN_MULADDMUL_1_INT(1) ALIGN(16) case2: MPN_MULADDMUL_1_INT(2) ALIGN(16) case3: MPN_MULADDMUL_1_INT(3) ALIGN(16) one: mov (%rsi),%rax mulq (%rcx) mov %rax,(%rdi) mov %rdx,8(%rdi) ret ALIGN(16) two: mov (%rcx),%r10 mov (%rsi),%rax mul %r10 mov %rax,(%rdi) mov 8(%rsi),%rax mov %rdx,%r9 mul %r10 add %rax,%r9 adc $0,%rdx mov %r9,8(%rdi) mov %rdx,16(%rdi) cmp $2,%r8 jz twobytwo ret twobytwo: mov $0,%r9d mov 8(%rcx),%r10 mov (%rsi),%rax mul %r10 add %rax,8(%rdi) mov 8(%rsi),%rax adc %rdx,%r9 mul %r10 add %rax,%r9 adc $0,%rdx add %r9,16(%rdi) adc $0,%rdx mov %rdx,24(%rdi) ret EPILOGUE()