dnl X86-64 mpn_redc_1 optimised for Intel Atom. dnl Contributed to the GNU project by Torbjörn Granlund. dnl Copyright 2003-2005, 2007, 2008, 2011-2013 Free Software Foundation, Inc. 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 modify dnl it under the terms of either: dnl dnl * the GNU Lesser General Public License as published by the Free dnl Software Foundation; either version 3 of the License, or (at your dnl option) any later version. dnl dnl or dnl dnl * the GNU General Public License as published by the Free Software dnl Foundation; either version 2 of the License, or (at your option) any dnl later version. dnl dnl or both in parallel, as here. dnl dnl The GNU MP 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 General Public License dnl for more details. dnl dnl You should have received copies of the GNU General Public License and the dnl GNU Lesser General Public License along with the GNU MP Library. If not, dnl see https://www.gnu.org/licenses/. include(`../config.m4') C cycles/limb C AMD K8,K9 ? C AMD K10 ? C AMD bull ? C AMD pile ? C AMD steam ? C AMD bobcat 5.0 C AMD jaguar ? C Intel P4 ? C Intel core ? C Intel NHM ? C Intel SBR ? C Intel IBR ? C Intel HWL ? C Intel BWL ? C Intel atom ? C VIA nano ? C TODO C * Micro-optimise, none performed thus far. C * Consider inlining mpn_add_n. C * Single basecases out before the pushes. C * Make lead-in code for the inner loops be more similar. C When playing with pointers, set this to $2 to fall back to conservative C indexing in wind-down code. define(`I',`$1') define(`rp', `%rdi') C rcx define(`up', `%rsi') C rdx define(`mp_param', `%rdx') C r8 define(`n', `%rcx') C r9 define(`u0inv', `%r8') C stack define(`i', `%r14') define(`j', `%r15') define(`mp', `%r12') define(`q0', `%r13') define(`w0', `%rbp') define(`w1', `%r9') define(`w2', `%r10') define(`w3', `%r11') C rax rbx rcx rdx rdi rsi rbp r8 r9 r10 r11 r12 r13 r14 r15 ABI_SUPPORT(DOS64) ABI_SUPPORT(STD64) define(`ALIGNx', `ALIGN(16)') ASM_START() TEXT ALIGN(32) PROLOGUE(mpn_redc_1) FUNC_ENTRY(4) IFDOS(` mov 56(%rsp), %r8 ') push %rbx push %rbp push %r12 push %r13 push %r14 push %r15 mov (up), q0 mov n, j C outer loop induction var lea (mp_param,n,8), mp lea (up,n,8), up neg n imul u0inv, q0 C first iteration q0 test $1, R8(n) jz L(bx0) L(bx1): test $2, R8(n) jz L(b3) L(b1): cmp $-1, R32(n) jz L(n1) L(otp1):lea 1(n), i mov (mp,n,8), %rax mul q0 mov %rax, %rbp mov 8(mp,n,8), %rax mov %rdx, %r9 mul q0 mov %rax, %rbx mov 16(mp,n,8), %rax mov %rdx, %r10 mul q0 add (up,n,8), %rbp mov %rax, %rbp adc %r9, %rbx mov 24(mp,n,8), %rax adc $0, %r10 mov %rdx, %r9 mul q0 add 8(up,n,8), %rbx mov %rbx, 8(up,n,8) mov %rax, %r11 adc %r10, %rbp mov 32(mp,n,8), %rax adc $0, %r9 imul u0inv, %rbx C next q limb jmp L(e1) ALIGNx L(tp1): mul q0 add %rbp, -24(up,i,8) mov %rax, %rbp mov (mp,i,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 mul q0 add %r11, -16(up,i,8) mov %rax, %r11 mov 8(mp,i,8), %rax adc %r10, %rbp mov %rdx, %r10 adc $0, %r9 mul q0 add %rbp, -8(up,i,8) mov %rax, %rbp adc %r9, %r11 mov 16(mp,i,8), %rax adc $0, %r10 mov %rdx, %r9 mul q0 add %r11, (up,i,8) mov %rax, %r11 adc %r10, %rbp mov 24(mp,i,8), %rax adc $0, %r9 L(e1): add $4, i mov %rdx, %r10 js L(tp1) L(ed1): mul q0 add %rbp, I(-24(up),-24(up,i,8)) adc %r9, %r11 adc $0, %r10 add %r11, I(-16(up),-16(up,i,8)) adc %r10, %rax adc $0, %rdx add %rax, I(-8(up),-8(up,i,8)) adc $0, %rdx mov %rdx, (up,n,8) C up[0] mov %rbx, q0 C previously computed q limb -> q0 lea 8(up), up C up++ dec j jnz L(otp1) jmp L(cj) L(b3): cmp $-3, R32(n) jz L(n3) L(otp3):lea 3(n), i mov (mp,n,8), %rax mul q0 mov %rax, %rbp mov 8(mp,n,8), %rax mov %rdx, %r9 mul q0 mov %rax, %rbx mov 16(mp,n,8), %rax mov %rdx, %r10 mul q0 add (up,n,8), %rbp mov %rax, %rbp mov 24(mp,n,8), %rax adc %r9, %rbx mov %rdx, %r9 adc $0, %r10 mul q0 add 8(up,n,8), %rbx mov %rbx, 8(up,n,8) mov %rax, %r11 mov 32(mp,n,8), %rax adc %r10, %rbp mov %rdx, %r10 adc $0, %r9 imul u0inv, %rbx C next q limb jmp L(e3) ALIGNx L(tp3): mul q0 add %rbp, -24(up,i,8) mov %rax, %rbp mov (mp,i,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 mul q0 add %r11, -16(up,i,8) mov %rax, %r11 mov 8(mp,i,8), %rax adc %r10, %rbp mov %rdx, %r10 adc $0, %r9 L(e3): mul q0 add %rbp, -8(up,i,8) mov %rax, %rbp adc %r9, %r11 mov 16(mp,i,8), %rax adc $0, %r10 mov %rdx, %r9 mul q0 add %r11, (up,i,8) mov %rax, %r11 adc %r10, %rbp mov 24(mp,i,8), %rax adc $0, %r9 add $4, i mov %rdx, %r10 js L(tp3) L(ed3): mul q0 add %rbp, I(-24(up),-24(up,i,8)) adc %r9, %r11 adc $0, %r10 add %r11, I(-16(up),-16(up,i,8)) adc %r10, %rax adc $0, %rdx add %rax, I(-8(up),-8(up,i,8)) adc $0, %rdx mov %rdx, (up,n,8) C up[0] mov %rbx, q0 C previously computed q limb -> q0 lea 8(up), up C up++ dec j jnz L(otp3) C jmp L(cj) L(cj): IFSTD(` lea (up,n,8), up C param 2: up lea (up,n,8), %rdx C param 3: up - n neg R32(n) ') C param 4: n IFDOS(` lea (up,n,8), %rdx C param 2: up lea (%rdx,n,8), %r8 C param 3: up - n neg R32(n) mov n, %r9 C param 4: n mov rp, %rcx ') C param 1: rp IFSTD(` sub $8, %rsp ') IFDOS(` sub $40, %rsp ') ASSERT(nz, `test $15, %rsp') CALL( mpn_add_n) IFSTD(` add $8, %rsp ') IFDOS(` add $40, %rsp ') L(ret): pop %r15 pop %r14 pop %r13 pop %r12 pop %rbp pop %rbx FUNC_EXIT() ret L(bx0): test $2, R8(n) jnz L(b2) L(b0): cmp $-4, R32(n) jz L(n4) L(otp0):lea 4(n), i mov (mp,n,8), %rax mul q0 mov %rax, %r11 mov 8(mp,n,8), %rax mov %rdx, %r10 mul q0 mov %rax, %rbx mov 16(mp,n,8), %rax mov %rdx, %r9 mul q0 add (up,n,8), %r11 mov %rax, %r11 adc %r10, %rbx mov 24(mp,n,8), %rax adc $0, %r9 mov %rdx, %r10 mul q0 add 8(up,n,8), %rbx mov %rbx, 8(up,n,8) mov %rax, %rbp mov 32(mp,n,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 imul u0inv, %rbx C next q limb jmp L(e0) ALIGNx L(tp0): mul q0 add %rbp, -24(up,i,8) mov %rax, %rbp mov (mp,i,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 L(e0): mul q0 add %r11, -16(up,i,8) mov %rax, %r11 mov 8(mp,i,8), %rax adc %r10, %rbp mov %rdx, %r10 adc $0, %r9 mul q0 add %rbp, -8(up,i,8) mov %rax, %rbp adc %r9, %r11 mov 16(mp,i,8), %rax adc $0, %r10 mov %rdx, %r9 mul q0 add %r11, (up,i,8) mov %rax, %r11 adc %r10, %rbp mov 24(mp,i,8), %rax adc $0, %r9 add $4, i mov %rdx, %r10 js L(tp0) L(ed0): mul q0 add %rbp, I(-24(up),-24(up,i,8)) adc %r9, %r11 adc $0, %r10 add %r11, I(-16(up),-16(up,i,8)) adc %r10, %rax adc $0, %rdx add %rax, I(-8(up),-8(up,i,8)) adc $0, %rdx mov %rdx, (up,n,8) C up[0] mov %rbx, q0 C previously computed q limb -> q0 lea 8(up), up C up++ dec j jnz L(otp0) jmp L(cj) L(b2): cmp $-2, R32(n) jz L(n2) L(otp2):lea 2(n), i mov (mp,n,8), %rax mul q0 mov %rax, %r11 mov 8(mp,n,8), %rax mov %rdx, %r10 mul q0 mov %rax, %rbx mov 16(mp,n,8), %rax mov %rdx, %r9 mul q0 add (up,n,8), %r11 mov %rax, %r11 adc %r10, %rbx mov 24(mp,n,8), %rax adc $0, %r9 mov %rdx, %r10 mul q0 add 8(up,n,8), %rbx mov %rbx, 8(up,n,8) mov %rax, %rbp mov 32(mp,n,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 imul u0inv, %rbx C next q limb jmp L(e2) ALIGNx L(tp2): mul q0 add %rbp, -24(up,i,8) mov %rax, %rbp mov (mp,i,8), %rax adc %r9, %r11 mov %rdx, %r9 adc $0, %r10 mul q0 add %r11, -16(up,i,8) mov %rax, %r11 mov 8(mp,i,8), %rax adc %r10, %rbp mov %rdx, %r10 adc $0, %r9 mul q0 add %rbp, -8(up,i,8) mov %rax, %rbp adc %r9, %r11 mov 16(mp,i,8), %rax adc $0, %r10 mov %rdx, %r9 L(e2): mul q0 add %r11, (up,i,8) mov %rax, %r11 adc %r10, %rbp mov 24(mp,i,8), %rax adc $0, %r9 add $4, i mov %rdx, %r10 js L(tp2) L(ed2): mul q0 add %rbp, I(-24(up),-24(up,i,8)) adc %r9, %r11 adc $0, %r10 add %r11, I(-16(up),-16(up,i,8)) adc %r10, %rax adc $0, %rdx add %rax, I(-8(up),-8(up,i,8)) adc $0, %rdx mov %rdx, (up,n,8) C up[0] mov %rbx, q0 C previously computed q limb -> q0 lea 8(up), up C up++ dec j jnz L(otp2) jmp L(cj) L(n1): mov (mp_param), %rax mul q0 add -8(up), %rax adc (up), %rdx mov %rdx, (rp) mov $0, R32(%rax) adc R32(%rax), R32(%rax) jmp L(ret) L(n2): mov (mp_param), %rax mov -16(up), %rbp mul q0 add %rax, %rbp mov %rdx, %r9 adc $0, %r9 mov -8(mp), %rax mov -8(up), %r10 mul q0 add %rax, %r10 mov %rdx, %r11 adc $0, %r11 add %r9, %r10 adc $0, %r11 mov %r10, q0 imul u0inv, q0 C next q0 mov -16(mp), %rax mul q0 add %rax, %r10 mov %rdx, %r9 adc $0, %r9 mov -8(mp), %rax mov (up), %r14 mul q0 add %rax, %r14 adc $0, %rdx add %r9, %r14 adc $0, %rdx xor R32(%rax), R32(%rax) add %r11, %r14 adc 8(up), %rdx mov %r14, (rp) mov %rdx, 8(rp) adc R32(%rax), R32(%rax) jmp L(ret) ALIGNx L(n3): mov -24(mp), %rax mov -24(up), %r10 mul q0 add %rax, %r10 mov -16(mp), %rax mov %rdx, %r11 adc $0, %r11 mov -16(up), %rbp mul q0 add %rax, %rbp mov %rdx, %r9 adc $0, %r9 mov -8(mp), %rax add %r11, %rbp mov -8(up), %r10 adc $0, %r9 mul q0 mov %rbp, q0 imul u0inv, q0 C next q0 add %rax, %r10 mov %rdx, %r11 adc $0, %r11 mov %rbp, -16(up) add %r9, %r10 adc $0, %r11 mov %r10, -8(up) mov %r11, -24(up) C up[0] lea 8(up), up C up++ dec j jnz L(n3) mov -48(up), %rdx mov -40(up), %rbx xor R32(%rax), R32(%rax) add %rbp, %rdx adc %r10, %rbx adc -8(up), %r11 mov %rdx, (rp) mov %rbx, 8(rp) mov %r11, 16(rp) adc R32(%rax), R32(%rax) jmp L(ret) L(n4): mov -32(mp), %rax mul q0 mov %rax, %r11 mov -24(mp), %rax mov %rdx, %r10 mul q0 mov %rax, %rbx mov -16(mp), %rax mov %rdx, %r9 mul q0 add -32(up), %r11 mov %rax, %r11 adc %r10, %rbx mov -8(mp), %rax adc $0, %r9 mov %rdx, %r10 mul q0 add -24(up), %rbx mov %rbx, -24(up) adc %r9, %r11 adc $0, %r10 imul u0inv, %rbx C next q limb add %r11, -16(up) adc %r10, %rax adc $0, %rdx add %rax, -8(up) adc $0, %rdx mov %rdx, -32(up) C up[0] mov %rbx, q0 C previously computed q limb -> q0 dec j lea 8(up), up C up++ jnz L(n4) jmp L(cj) EPILOGUE() ASM_END() CF_PROT