head 1.1; branch 1.1.1; access; symbols netbsd-11-0-RC5:1.1.1.2 netbsd-11-0-RC4:1.1.1.2 netbsd-11-0-RC3:1.1.1.2 netbsd-11-0-RC2:1.1.1.2 netbsd-11-0-RC1:1.1.1.2 perseant-exfatfs-base-20250801:1.1.1.2 netbsd-11:1.1.1.2.0.18 netbsd-11-base:1.1.1.2 netbsd-10-1-RELEASE:1.1.1.2 perseant-exfatfs-base-20240630:1.1.1.2 perseant-exfatfs:1.1.1.2.0.16 perseant-exfatfs-base:1.1.1.2 netbsd-8-3-RELEASE:1.1.1.1 netbsd-9-4-RELEASE:1.1.1.2 netbsd-10-0-RELEASE:1.1.1.2 netbsd-10-0-RC6:1.1.1.2 netbsd-10-0-RC5:1.1.1.2 netbsd-10-0-RC4:1.1.1.2 netbsd-10-0-RC3:1.1.1.2 netbsd-10-0-RC2:1.1.1.2 netbsd-10-0-RC1:1.1.1.2 netbsd-10:1.1.1.2.0.14 netbsd-10-base:1.1.1.2 netbsd-9-3-RELEASE:1.1.1.2 gmp-6-2-1:1.1.1.2 cjep_sun2x-base1:1.1.1.2 cjep_sun2x:1.1.1.2.0.12 cjep_sun2x-base:1.1.1.2 cjep_staticlib_x-base1:1.1.1.2 netbsd-9-2-RELEASE:1.1.1.2 cjep_staticlib_x:1.1.1.2.0.10 cjep_staticlib_x-base:1.1.1.2 netbsd-9-1-RELEASE:1.1.1.2 gmp-6-2-0:1.1.1.2 phil-wifi-20200421:1.1.1.2 phil-wifi-20200411:1.1.1.2 is-mlppp:1.1.1.2.0.8 is-mlppp-base:1.1.1.2 phil-wifi-20200406:1.1.1.2 netbsd-8-2-RELEASE:1.1.1.1 netbsd-9-0-RELEASE:1.1.1.2 netbsd-9-0-RC2:1.1.1.2 netbsd-9-0-RC1:1.1.1.2 phil-wifi-20191119:1.1.1.2 netbsd-9:1.1.1.2.0.6 netbsd-9-base:1.1.1.2 phil-wifi-20190609:1.1.1.2 netbsd-8-1-RELEASE:1.1.1.1 netbsd-8-1-RC1:1.1.1.1 pgoyette-compat-merge-20190127:1.1.1.2 pgoyette-compat-20190127:1.1.1.2 pgoyette-compat-20190118:1.1.1.2 pgoyette-compat-1226:1.1.1.2 pgoyette-compat-1126:1.1.1.2 pgoyette-compat-1020:1.1.1.2 pgoyette-compat-0930:1.1.1.2 pgoyette-compat-0906:1.1.1.2 netbsd-7-2-RELEASE:1.1.1.1 pgoyette-compat-0728:1.1.1.2 netbsd-8-0-RELEASE:1.1.1.1 phil-wifi:1.1.1.2.0.4 phil-wifi-base:1.1.1.2 pgoyette-compat-0625:1.1.1.2 netbsd-8-0-RC2:1.1.1.1 pgoyette-compat-0521:1.1.1.2 pgoyette-compat-0502:1.1.1.2 pgoyette-compat-0422:1.1.1.2 netbsd-8-0-RC1:1.1.1.1 pgoyette-compat-0415:1.1.1.2 pgoyette-compat-0407:1.1.1.2 pgoyette-compat-0330:1.1.1.2 pgoyette-compat-0322:1.1.1.2 pgoyette-compat-0315:1.1.1.2 netbsd-7-1-2-RELEASE:1.1.1.1 pgoyette-compat:1.1.1.2.0.2 pgoyette-compat-base:1.1.1.2 netbsd-7-1-1-RELEASE:1.1.1.1 matt-nb8-mediatek:1.1.1.1.0.38 matt-nb8-mediatek-base:1.1.1.1 gmp-6-1-2:1.1.1.2 perseant-stdc-iso10646:1.1.1.1.0.36 perseant-stdc-iso10646-base:1.1.1.1 netbsd-8:1.1.1.1.0.34 netbsd-8-base:1.1.1.1 prg-localcount2-base3:1.1.1.1 prg-localcount2-base2:1.1.1.1 prg-localcount2-base1:1.1.1.1 prg-localcount2:1.1.1.1.0.32 prg-localcount2-base:1.1.1.1 pgoyette-localcount-20170426:1.1.1.1 bouyer-socketcan-base1:1.1.1.1 pgoyette-localcount-20170320:1.1.1.1 netbsd-7-1:1.1.1.1.0.30 netbsd-7-1-RELEASE:1.1.1.1 netbsd-7-1-RC2:1.1.1.1 netbsd-7-nhusb-base-20170116:1.1.1.1 bouyer-socketcan:1.1.1.1.0.28 bouyer-socketcan-base:1.1.1.1 pgoyette-localcount-20170107:1.1.1.1 netbsd-7-1-RC1:1.1.1.1 pgoyette-localcount-20161104:1.1.1.1 netbsd-7-0-2-RELEASE:1.1.1.1 localcount-20160914:1.1.1.1 netbsd-7-nhusb:1.1.1.1.0.26 netbsd-7-nhusb-base:1.1.1.1 pgoyette-localcount-20160806:1.1.1.1 pgoyette-localcount-20160726:1.1.1.1 pgoyette-localcount:1.1.1.1.0.24 pgoyette-localcount-base:1.1.1.1 netbsd-7-0-1-RELEASE:1.1.1.1 netbsd-7-0:1.1.1.1.0.22 netbsd-7-0-RELEASE:1.1.1.1 netbsd-7-0-RC3:1.1.1.1 netbsd-7-0-RC2:1.1.1.1 netbsd-7-0-RC1:1.1.1.1 netbsd-6-0-6-RELEASE:1.1.1.1 netbsd-6-1-5-RELEASE:1.1.1.1 netbsd-7:1.1.1.1.0.20 netbsd-7-base:1.1.1.1 yamt-pagecache-base9:1.1.1.1 yamt-pagecache-tag8:1.1.1.1 netbsd-6-1-4-RELEASE:1.1.1.1 netbsd-6-0-5-RELEASE:1.1.1.1 tls-earlyentropy:1.1.1.1.0.18 tls-earlyentropy-base:1.1.1.1 riastradh-xf86-video-intel-2-7-1-pre-2-21-15:1.1.1.1 riastradh-drm2-base3:1.1.1.1 netbsd-6-1-3-RELEASE:1.1.1.1 netbsd-6-0-4-RELEASE:1.1.1.1 gmp-5-1-3:1.1.1.1 netbsd-6-1-2-RELEASE:1.1.1.1 netbsd-6-0-3-RELEASE:1.1.1.1 netbsd-6-1-1-RELEASE:1.1.1.1 riastradh-drm2-base2:1.1.1.1 riastradh-drm2-base1:1.1.1.1 riastradh-drm2:1.1.1.1.0.12 riastradh-drm2-base:1.1.1.1 netbsd-6-1:1.1.1.1.0.16 netbsd-6-0-2-RELEASE:1.1.1.1 netbsd-6-1-RELEASE:1.1.1.1 netbsd-6-1-RC4:1.1.1.1 netbsd-6-1-RC3:1.1.1.1 agc-symver:1.1.1.1.0.14 agc-symver-base:1.1.1.1 netbsd-6-1-RC2:1.1.1.1 netbsd-6-1-RC1:1.1.1.1 yamt-pagecache-base8:1.1.1.1 netbsd-6-0-1-RELEASE:1.1.1.1 yamt-pagecache-base7:1.1.1.1 matt-nb6-plus-nbase:1.1.1.1 yamt-pagecache-base6:1.1.1.1 netbsd-6-0:1.1.1.1.0.10 netbsd-6-0-RELEASE:1.1.1.1 netbsd-6-0-RC2:1.1.1.1 tls-maxphys:1.1.1.1.0.8 tls-maxphys-base:1.1.1.1 matt-nb6-plus:1.1.1.1.0.6 matt-nb6-plus-base:1.1.1.1 netbsd-6-0-RC1:1.1.1.1 yamt-pagecache-base5:1.1.1.1 yamt-pagecache-base4:1.1.1.1 netbsd-6:1.1.1.1.0.4 netbsd-6-base:1.1.1.1 yamt-pagecache-base3:1.1.1.1 yamt-pagecache-base2:1.1.1.1 yamt-pagecache:1.1.1.1.0.2 yamt-pagecache-base:1.1.1.1 gmp-5-0-2:1.1.1.1 gmp:1.1.1; locks; strict; comment @;; @; 1.1 date 2011.06.20.05.54.43; author mrg; state Exp; branches 1.1.1.1; next ; 1.1.1.1 date 2011.06.20.05.54.43; author mrg; state Exp; branches; next 1.1.1.2; 1.1.1.2 date 2017.08.22.09.40.49; author mrg; state Exp; branches; next ; commitid W5kmAIk8hwVpSb4A; desc @@ 1.1 log @Initial revision @ text @dnl mpn_sqr_basecase for Pentium 4 and P6 models with SSE2 (i.e., 9,D,E,F). dnl Copyright 2001, 2002, 2007 Free Software 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 modify dnl it under the terms of the GNU Lesser General Public License as published dnl by the Free Software Foundation; either version 3 of the License, or (at dnl your option) any later version. 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 Lesser General Public dnl License for more details. dnl dnl You should have received a copy of the GNU Lesser General Public License dnl along with the GNU MP Library. If not, see http://www.gnu.org/licenses/. include(`../config.m4') C TODO: C * Improve ad-hoc outer loop code and register handling. Some feed-in C scheduling could improve things by several cycles per outer iteration. C * In Lam3...Lam1 code for, keep accumulation operands in registers, without C storing intermediates to rp. C * We might want to keep 32 in a free mm register, since the register form is C 3 bytes and the immediate form is 4 bytes. About 80 bytes to save. C * Look into different loop alignment, we now expand the code about 50 bytes C with possibly needless alignment. C * Use OSP, should solve feed-in latency problems. C * Address relative slowness for un<=3 for Pentium M. The old code is there C considerably faster. (1:20/14, 2:34:32, 3:66/57) C INPUT PARAMETERS C rp sp + 4 C up sp + 8 C un sp + 12 TEXT ALIGN(16) PROLOGUE(mpn_sqr_basecase) mov 4(%esp), %edx C rp mov 8(%esp), %eax C up mov 12(%esp), %ecx C un cmp $2, %ecx jc L(un1) jz L(un2) cmp $4, %ecx jc L(un3) jz L(un4) jmp L(big) L(un1): mov (%eax), %eax mov %edx, %ecx mul %eax mov %eax, (%ecx) mov %edx, 4(%ecx) ret L(un2): movd (%eax), %mm0 C un=2 movd (%eax), %mm2 C un=2 movd 4(%eax), %mm1 C un=2 pmuludq %mm0, %mm0 C 64b weight 0 un=2 pmuludq %mm1, %mm2 C 64b weight 32 un=2 pmuludq %mm1, %mm1 C 64b weight 64 un=2 movd %mm0, (%edx) C un=2 psrlq $32, %mm0 C 32b weight 32 un=2 pcmpeqd %mm7, %mm7 C un=2 psrlq $33, %mm7 C 0x000000007FFFFFFF un=2 pand %mm2, %mm7 C 31b weight 32 un=2 psrlq $31, %mm2 C 33b weight 65 un=2 psllq $1, %mm7 C 31b weight 33 un=2 paddq %mm7, %mm0 C un=2 movd %mm0, 4(%edx) C un=2 psrlq $32, %mm0 C un=2 paddq %mm2, %mm1 C un=2 paddq %mm0, %mm1 C un=2 movd %mm1, 8(%edx) C un=2 psrlq $32, %mm1 C un=2 movd %mm1, 12(%edx) C un=2 emms ret L(un3): movd (%eax), %mm7 C un=3 movd 4(%eax), %mm6 C un=3 pmuludq %mm7, %mm6 C un=3 movd 8(%eax), %mm2 C un=3 pmuludq %mm7, %mm2 C un=3 movd %mm6, 4(%edx) C un=3 psrlq $32, %mm6 C un=3 paddq %mm2, %mm6 C un=3 movd %mm6, 8(%edx) C un=3 psrlq $32, %mm6 C un=3 movd %mm6, 12(%edx) C un=3 lea 4(%edx), %edx C un=3 lea 4(%eax), %eax C un=3 jmp L(am1) L(un4): movd (%eax), %mm7 C un=4 movd 4(%eax), %mm6 C un=4 pmuludq %mm7, %mm6 C un=4 movd 8(%eax), %mm0 C un=4 pmuludq %mm7, %mm0 C un=4 movd 12(%eax), %mm1 C un=4 pmuludq %mm7, %mm1 C un=4 movd %mm6, 4(%edx) C un=4 psrlq $32, %mm6 C un=4 paddq %mm0, %mm6 C un=4 movd %mm6, 8(%edx) C un=4 psrlq $32, %mm6 C un=4 paddq %mm1, %mm6 C un=4 movd %mm6, 12(%edx) C un=4 psrlq $32, %mm6 C un=4 movd %mm6, 16(%edx) C un=4 lea 4(%edx), %edx C un=4 lea 4(%eax), %eax C un=4 jmp L(am2) L(big): push %esi push %ebx push %edi pxor %mm6, %mm6 movd (%eax), %mm7 C lea 4(%eax), %esi C init up, up++ lea 4(%eax), %eax C up2++ FIXME: should fix offsets lea 4(%edx), %edi C init rp, rp++ lea 4(%edx), %edx C rp2++ lea -4(%ecx), %ebx C loop count and $3, %ecx jz L(3m) cmp $2, %ecx ja L(2m) jb L(0m) L(1m): movd (%eax), %mm4 C m 1 lea (%ebx), %ecx C inner loop count m 1 pmuludq %mm7, %mm4 C m 1 movd 4(%eax), %mm3 C m 1 pmuludq %mm7, %mm3 C m 1 movd 8(%eax), %mm0 C m 1 jmp L(m01) C m 1 ALIGN(16) C m 1 L(lpm1): pmuludq %mm7, %mm4 C m 1 paddq %mm0, %mm6 C m 1 movd 4(%eax), %mm3 C m 1 movd %mm6, -8(%edx) C m 1 psrlq $32, %mm6 C m 1 pmuludq %mm7, %mm3 C m 1 paddq %mm1, %mm6 C m 1 movd 8(%eax), %mm0 C m 1 movd %mm6, -4(%edx) C m 1 psrlq $32, %mm6 C m 1 L(m01): pmuludq %mm7, %mm0 C m 1 paddq %mm4, %mm6 C m 1 movd 12(%eax), %mm1 C m 1 movd %mm6, (%edx) C m 1 psrlq $32, %mm6 C m 1 pmuludq %mm7, %mm1 C m 1 paddq %mm3, %mm6 C m 1 movd 16(%eax), %mm4 C m 1 movd %mm6, 4(%edx) C m 1 psrlq $32, %mm6 C m 1 lea 16(%eax), %eax C m 1 lea 16(%edx), %edx C m 1 sub $4, %ecx C m 1 ja L(lpm1) C m 1 pmuludq %mm7, %mm4 C m 1 paddq %mm0, %mm6 C m 1 movd %mm6, -8(%edx) C m 1 psrlq $32, %mm6 C m 1 paddq %mm1, %mm6 C m 1 jmp L(0) L(2m): movd (%eax), %mm1 C m 2 lea (%ebx), %ecx C inner loop count m 2 pmuludq %mm7, %mm1 C m 2 movd 4(%eax), %mm4 C m 2 pmuludq %mm7, %mm4 C m 2 movd 8(%eax), %mm3 C m 2 jmp L(m10) C m 2 ALIGN(16) C m 2 L(lpm2): pmuludq %mm7, %mm4 C m 2 paddq %mm0, %mm6 C m 2 movd 8(%eax), %mm3 C m 2 movd %mm6, -4(%edx) C m 2 psrlq $32, %mm6 C m 2 L(m10): pmuludq %mm7, %mm3 C m 2 paddq %mm1, %mm6 C m 2 movd 12(%eax), %mm0 C m 2 movd %mm6, (%edx) C m 2 psrlq $32, %mm6 C m 2 pmuludq %mm7, %mm0 C m 2 paddq %mm4, %mm6 C m 2 movd 16(%eax), %mm1 C m 2 movd %mm6, 4(%edx) C m 2 psrlq $32, %mm6 C m 2 pmuludq %mm7, %mm1 C m 2 paddq %mm3, %mm6 C m 2 movd 20(%eax), %mm4 C m 2 movd %mm6, 8(%edx) C m 2 psrlq $32, %mm6 C m 2 lea 16(%eax), %eax C m 2 lea 16(%edx), %edx C m 2 sub $4, %ecx C m 2 ja L(lpm2) C m 2 pmuludq %mm7, %mm4 C m 2 paddq %mm0, %mm6 C m 2 movd %mm6, -4(%edx) C m 2 psrlq $32, %mm6 C m 2 paddq %mm1, %mm6 C m 2 jmp L(1) L(3m): movd (%eax), %mm0 C m 3 lea (%ebx), %ecx C inner loop count m 3 pmuludq %mm7, %mm0 C m 3 movd 4(%eax), %mm1 C m 3 pmuludq %mm7, %mm1 C m 3 movd 8(%eax), %mm4 C m 3 jmp L(lpm3) C m 3 ALIGN(16) C m 3 L(lpm3): pmuludq %mm7, %mm4 C m 3 paddq %mm0, %mm6 C m 3 movd 12(%eax), %mm3 C m 3 movd %mm6, (%edx) C m 3 psrlq $32, %mm6 C m 3 pmuludq %mm7, %mm3 C m 3 paddq %mm1, %mm6 C m 3 movd 16(%eax), %mm0 C m 3 movd %mm6, 4(%edx) C m 3 psrlq $32, %mm6 C m 3 pmuludq %mm7, %mm0 C m 3 paddq %mm4, %mm6 C m 3 movd 20(%eax), %mm1 C m 3 movd %mm6, 8(%edx) C m 3 psrlq $32, %mm6 C m 3 pmuludq %mm7, %mm1 C m 3 paddq %mm3, %mm6 C m 3 movd 24(%eax), %mm4 C m 3 movd %mm6, 12(%edx) C m 3 psrlq $32, %mm6 C m 3 lea 16(%eax), %eax C m 3 lea 16(%edx), %edx C m 3 sub $4, %ecx C m 3 ja L(lpm3) C m 3 pmuludq %mm7, %mm4 C m 3 paddq %mm0, %mm6 C m 3 movd %mm6, (%edx) C m 3 psrlq $32, %mm6 C m 3 paddq %mm1, %mm6 C m 3 jmp L(2) L(0m): movd (%eax), %mm3 C m 0 lea (%ebx), %ecx C inner loop count m 0 pmuludq %mm7, %mm3 C m 0 movd 4(%eax), %mm0 C m 0 pmuludq %mm7, %mm0 C m 0 movd 8(%eax), %mm1 C m 0 jmp L(m00) C m 0 ALIGN(16) C m 0 L(lpm0): pmuludq %mm7, %mm4 C m 0 paddq %mm0, %mm6 C m 0 movd (%eax), %mm3 C m 0 movd %mm6, -12(%edx) C m 0 psrlq $32, %mm6 C m 0 pmuludq %mm7, %mm3 C m 0 paddq %mm1, %mm6 C m 0 movd 4(%eax), %mm0 C m 0 movd %mm6, -8(%edx) C m 0 psrlq $32, %mm6 C m 0 pmuludq %mm7, %mm0 C m 0 paddq %mm4, %mm6 C m 0 movd 8(%eax), %mm1 C m 0 movd %mm6, -4(%edx) C m 0 psrlq $32, %mm6 C m 0 L(m00): pmuludq %mm7, %mm1 C m 0 paddq %mm3, %mm6 C m 0 movd 12(%eax), %mm4 C m 0 movd %mm6, (%edx) C m 0 psrlq $32, %mm6 C m 0 lea 16(%eax), %eax C m 0 lea 16(%edx), %edx C m 0 sub $4, %ecx C m 0 ja L(lpm0) C m 0 pmuludq %mm7, %mm4 C m 0 paddq %mm0, %mm6 C m 0 movd %mm6, -12(%edx) C m 0 psrlq $32, %mm6 C m 0 paddq %mm1, %mm6 C m 0 jmp L(3) L(outer): lea 8(%edi), %edi C rp += 2 movd (%esi), %mm7 C am 3 mov %edi, %edx C rp2 = rp am 3 lea 4(%esi), %esi C up++ am 3 lea (%esi), %eax C up2 = up am 3 movd (%eax), %mm0 C am 3 lea (%ebx), %ecx C inner loop count am 3 pxor %mm6, %mm6 C am 3 pmuludq %mm7, %mm0 C am 3 movd 4(%eax), %mm1 C am 3 movd (%edx), %mm4 C am 3 pmuludq %mm7, %mm1 C am 3 movd 8(%eax), %mm2 C am 3 paddq %mm0, %mm4 C am 3 movd 4(%edx), %mm5 C am 3 jmp L(lam3) C am 3 ALIGN(16) C am 3 L(lam3): pmuludq %mm7, %mm2 C am 3 paddq %mm4, %mm6 C am 3 movd 12(%eax), %mm3 C am 3 paddq %mm1, %mm5 C am 3 movd 8(%edx), %mm4 C am 3 movd %mm6, (%edx) C am 3 psrlq $32, %mm6 C am 3 pmuludq %mm7, %mm3 C am 3 paddq %mm5, %mm6 C am 3 movd 16(%eax), %mm0 C am 3 paddq %mm2, %mm4 C am 3 movd 12(%edx), %mm5 C am 3 movd %mm6, 4(%edx) C am 3 psrlq $32, %mm6 C am 3 pmuludq %mm7, %mm0 C am 3 paddq %mm4, %mm6 C am 3 movd 20(%eax), %mm1 C am 3 paddq %mm3, %mm5 C am 3 movd 16(%edx), %mm4 C am 3 movd %mm6, 8(%edx) C am 3 psrlq $32, %mm6 C am 3 pmuludq %mm7, %mm1 C am 3 paddq %mm5, %mm6 C am 3 movd 24(%eax), %mm2 C am 3 paddq %mm0, %mm4 C am 3 movd 20(%edx), %mm5 C am 3 movd %mm6, 12(%edx) C am 3 psrlq $32, %mm6 C am 3 lea 16(%eax), %eax C am 3 lea 16(%edx), %edx C am 3 sub $4, %ecx C am 3 ja L(lam3) C am 3 pmuludq %mm7, %mm2 C am 3 paddq %mm4, %mm6 C am 3 paddq %mm1, %mm5 C am 3 movd 8(%edx), %mm4 C am 3 movd %mm6, (%edx) C am 3 psrlq $32, %mm6 C am 3 paddq %mm5, %mm6 C am 3 paddq %mm2, %mm4 C am 3 L(2): movd %mm6, 4(%edx) C am 3 psrlq $32, %mm6 C am 3 paddq %mm4, %mm6 C am 3 movd %mm6, 8(%edx) C am 3 psrlq $32, %mm6 C am 3 movd %mm6, 12(%edx) C am 3 lea 8(%edi), %edi C rp += 2 movd (%esi), %mm7 C am 2 mov %edi, %edx C rp2 = rp am 2 lea 4(%esi), %esi C up++ am 2 lea (%esi), %eax C up2 = up am 2 movd (%eax), %mm1 C am 2 lea (%ebx), %ecx C inner loop count am 2 pxor %mm6, %mm6 C am 2 pmuludq %mm7, %mm1 C am 2 movd 4(%eax), %mm2 C am 2 movd (%edx), %mm5 C am 2 pmuludq %mm7, %mm2 C am 2 movd 8(%eax), %mm3 C am 2 paddq %mm1, %mm5 C am 2 movd 4(%edx), %mm4 C am 2 jmp L(am10) C am 2 ALIGN(16) C am 2 L(lam2): pmuludq %mm7, %mm2 C am 2 paddq %mm4, %mm6 C am 2 movd 8(%eax), %mm3 C am 2 paddq %mm1, %mm5 C am 2 movd 4(%edx), %mm4 C am 2 movd %mm6, -4(%edx) C am 2 psrlq $32, %mm6 C am 2 L(am10): pmuludq %mm7, %mm3 C am 2 paddq %mm5, %mm6 C am 2 movd 12(%eax), %mm0 C am 2 paddq %mm2, %mm4 C am 2 movd 8(%edx), %mm5 C am 2 movd %mm6, (%edx) C am 2 psrlq $32, %mm6 C am 2 pmuludq %mm7, %mm0 C am 2 paddq %mm4, %mm6 C am 2 movd 16(%eax), %mm1 C am 2 paddq %mm3, %mm5 C am 2 movd 12(%edx), %mm4 C am 2 movd %mm6, 4(%edx) C am 2 psrlq $32, %mm6 C am 2 pmuludq %mm7, %mm1 C am 2 paddq %mm5, %mm6 C am 2 movd 20(%eax), %mm2 C am 2 paddq %mm0, %mm4 C am 2 movd 16(%edx), %mm5 C am 2 movd %mm6, 8(%edx) C am 2 psrlq $32, %mm6 C am 2 lea 16(%eax), %eax C am 2 lea 16(%edx), %edx C am 2 sub $4, %ecx C am 2 ja L(lam2) C am 2 pmuludq %mm7, %mm2 C am 2 paddq %mm4, %mm6 C am 2 paddq %mm1, %mm5 C am 2 movd 4(%edx), %mm4 C am 2 movd %mm6, -4(%edx) C am 2 psrlq $32, %mm6 C am 2 paddq %mm5, %mm6 C am 2 paddq %mm2, %mm4 C am 2 L(1): movd %mm6, (%edx) C am 2 psrlq $32, %mm6 C am 2 paddq %mm4, %mm6 C am 2 movd %mm6, 4(%edx) C am 2 psrlq $32, %mm6 C am 2 movd %mm6, 8(%edx) C am 2 lea 8(%edi), %edi C rp += 2 movd (%esi), %mm7 C am 1 mov %edi, %edx C rp2 = rp am 1 lea 4(%esi), %esi C up++ am 1 lea (%esi), %eax C up2 = up am 1 movd (%eax), %mm2 C am 1 lea (%ebx), %ecx C inner loop count am 1 pxor %mm6, %mm6 C am 1 pmuludq %mm7, %mm2 C am 1 movd 4(%eax), %mm3 C am 1 movd (%edx), %mm4 C am 1 pmuludq %mm7, %mm3 C am 1 movd 8(%eax), %mm0 C am 1 paddq %mm2, %mm4 C am 1 movd 4(%edx), %mm5 C am 1 jmp L(am01) C am 1 ALIGN(16) C am 1 L(lam1): pmuludq %mm7, %mm2 C am 1 paddq %mm4, %mm6 C am 1 movd 4(%eax), %mm3 C am 1 paddq %mm1, %mm5 C am 1 movd (%edx), %mm4 C am 1 movd %mm6, -8(%edx) C am 1 psrlq $32, %mm6 C am 1 pmuludq %mm7, %mm3 C am 1 paddq %mm5, %mm6 C am 1 movd 8(%eax), %mm0 C am 1 paddq %mm2, %mm4 C am 1 movd 4(%edx), %mm5 C am 1 movd %mm6, -4(%edx) C am 1 psrlq $32, %mm6 C am 1 L(am01): pmuludq %mm7, %mm0 C am 1 paddq %mm4, %mm6 C am 1 movd 12(%eax), %mm1 C am 1 paddq %mm3, %mm5 C am 1 movd 8(%edx), %mm4 C am 1 movd %mm6, (%edx) C am 1 psrlq $32, %mm6 C am 1 pmuludq %mm7, %mm1 C am 1 paddq %mm5, %mm6 C am 1 movd 16(%eax), %mm2 C am 1 paddq %mm0, %mm4 C am 1 movd 12(%edx), %mm5 C am 1 movd %mm6, 4(%edx) C am 1 psrlq $32, %mm6 C am 1 lea 16(%eax), %eax C am 1 lea 16(%edx), %edx C am 1 sub $4, %ecx C am 1 ja L(lam1) C am 1 pmuludq %mm7, %mm2 C am 1 paddq %mm4, %mm6 C am 1 paddq %mm1, %mm5 C am 1 movd (%edx), %mm4 C am 1 movd %mm6, -8(%edx) C am 1 psrlq $32, %mm6 C am 1 paddq %mm5, %mm6 C am 1 paddq %mm2, %mm4 C am 1 L(0): movd %mm6, -4(%edx) C am 1 psrlq $32, %mm6 C am 1 paddq %mm4, %mm6 C am 1 movd %mm6, (%edx) C am 1 psrlq $32, %mm6 C am 1 movd %mm6, 4(%edx) C am 1 lea 8(%edi), %edi C rp += 2 movd (%esi), %mm7 C am 0 mov %edi, %edx C rp2 = rp am 0 lea 4(%esi), %esi C up++ am 0 lea (%esi), %eax C up2 = up am 0 movd (%eax), %mm3 C am 0 lea (%ebx), %ecx C inner loop count am 0 pxor %mm6, %mm6 C am 0 pmuludq %mm7, %mm3 C am 0 movd 4(%eax), %mm0 C am 0 movd (%edx), %mm5 C am 0 pmuludq %mm7, %mm0 C am 0 movd 8(%eax), %mm1 C am 0 paddq %mm3, %mm5 C am 0 movd 4(%edx), %mm4 C am 0 jmp L(am00) C am 0 ALIGN(16) C am 0 L(lam0): pmuludq %mm7, %mm2 C am 0 paddq %mm4, %mm6 C am 0 movd (%eax), %mm3 C am 0 paddq %mm1, %mm5 C am 0 movd -4(%edx), %mm4 C am 0 movd %mm6, -12(%edx) C am 0 psrlq $32, %mm6 C am 0 pmuludq %mm7, %mm3 C am 0 paddq %mm5, %mm6 C am 0 movd 4(%eax), %mm0 C am 0 paddq %mm2, %mm4 C am 0 movd (%edx), %mm5 C am 0 movd %mm6, -8(%edx) C am 0 psrlq $32, %mm6 C am 0 pmuludq %mm7, %mm0 C am 0 paddq %mm4, %mm6 C am 0 movd 8(%eax), %mm1 C am 0 paddq %mm3, %mm5 C am 0 movd 4(%edx), %mm4 C am 0 movd %mm6, -4(%edx) C am 0 psrlq $32, %mm6 C am 0 L(am00): pmuludq %mm7, %mm1 C am 0 paddq %mm5, %mm6 C am 0 movd 12(%eax), %mm2 C am 0 paddq %mm0, %mm4 C am 0 movd 8(%edx), %mm5 C am 0 movd %mm6, (%edx) C am 0 psrlq $32, %mm6 C am 0 lea 16(%eax), %eax C am 0 lea 16(%edx), %edx C am 0 sub $4, %ecx C am 0 ja L(lam0) C am 0 pmuludq %mm7, %mm2 C am 0 paddq %mm4, %mm6 C am 0 paddq %mm1, %mm5 C am 0 movd -4(%edx), %mm4 C am 0 movd %mm6, -12(%edx) C am 0 psrlq $32, %mm6 C am 0 paddq %mm5, %mm6 C am 0 paddq %mm2, %mm4 C am 0 L(3): movd %mm6, -8(%edx) C am 0 psrlq $32, %mm6 C am 0 paddq %mm4, %mm6 C am 0 movd %mm6, -4(%edx) C am 0 psrlq $32, %mm6 C am 0 movd %mm6, (%edx) C am 0 sub $4, %ebx C am 0 ja L(outer) C am 0 mov %edi, %edx mov %esi, %eax pop %edi pop %ebx pop %esi L(am3): C up[un-1..un-3] x up[un-4] lea 8(%edx), %edx C rp2 += 2 movd (%eax), %mm7 movd 4(%eax), %mm1 movd 8(%eax), %mm2 movd 12(%eax), %mm3 movd (%edx), %mm4 pmuludq %mm7, %mm1 movd 4(%edx), %mm5 pmuludq %mm7, %mm2 movd 8(%edx), %mm6 pmuludq %mm7, %mm3 paddq %mm1, %mm4 paddq %mm2, %mm5 paddq %mm3, %mm6 movd %mm4, (%edx) psrlq $32, %mm4 paddq %mm5, %mm4 movd %mm4, 4(%edx) psrlq $32, %mm4 paddq %mm6, %mm4 movd %mm4, 8(%edx) psrlq $32, %mm4 movd %mm4, 12(%edx) C FIXME feed through! lea 4(%eax), %eax L(am2): C up[un-1..un-2] x up[un-3] lea 8(%edx), %edx C rp2 += 2 movd (%eax), %mm7 movd 4(%eax), %mm1 movd 8(%eax), %mm2 movd (%edx), %mm4 movd 4(%edx), %mm5 pmuludq %mm7, %mm1 pmuludq %mm7, %mm2 paddq %mm1, %mm4 paddq %mm2, %mm5 movd %mm4, (%edx) psrlq $32, %mm4 paddq %mm5, %mm4 movd %mm4, 4(%edx) psrlq $32, %mm4 movd %mm4, 8(%edx) C FIXME feed through! lea 4(%eax), %eax L(am1): C up[un-1] x up[un-2] lea 8(%edx), %edx C rp2 += 2 movd (%eax), %mm7 movd 4(%eax), %mm2 movd (%edx), %mm4 pmuludq %mm7, %mm2 paddq %mm2, %mm4 movd %mm4, (%edx) psrlq $32, %mm4 movd %mm4, 4(%edx) C *** diag stuff, use elementary code for now mov 4(%esp), %edx C rp mov 8(%esp), %eax C up mov 12(%esp), %ecx C un movd (%eax), %mm2 pmuludq %mm2, %mm2 C src[0]^2 pcmpeqd %mm7, %mm7 psrlq $32, %mm7 movd 4(%edx), %mm3 C dst[1] movd %mm2, (%edx) psrlq $32, %mm2 psllq $1, %mm3 C 2*dst[1] paddq %mm3, %mm2 movd %mm2, 4(%edx) psrlq $32, %mm2 sub $2, %ecx L(diag): movd 4(%eax), %mm0 C src limb add $4, %eax pmuludq %mm0, %mm0 movq %mm7, %mm1 pand %mm0, %mm1 C diagonal low psrlq $32, %mm0 C diagonal high movd 8(%edx), %mm3 psllq $1, %mm3 C 2*dst[i] paddq %mm3, %mm1 paddq %mm1, %mm2 movd %mm2, 8(%edx) psrlq $32, %mm2 movd 12(%edx), %mm3 psllq $1, %mm3 C 2*dst[i+1] paddq %mm3, %mm0 paddq %mm0, %mm2 movd %mm2, 12(%edx) add $8, %edx psrlq $32, %mm2 sub $1, %ecx jnz L(diag) movd 4(%eax), %mm0 C src[size-1] pmuludq %mm0, %mm0 pand %mm0, %mm7 C diagonal low psrlq $32, %mm0 C diagonal high movd 8(%edx), %mm3 C dst[2*size-2] psllq $1, %mm3 paddq %mm3, %mm7 paddq %mm7, %mm2 movd %mm2, 8(%edx) psrlq $32, %mm2 paddq %mm0, %mm2 movd %mm2, 12(%edx) C dst[2*size-1] emms ret EPILOGUE() @ 1.1.1.1 log @initial import of GMP 5.0.2. GNU MP is a library for arbitrary precision arithmetic, operating on signed integers, rational numbers, and floating point numbers. It has a rich set of functions, and the functions have a regular interface. GMP is necessary for GCC >= 4.2. @ text @@ 1.1.1.2 log @initial import of GMP 6.1.2. main changes from 5.1.3 below. notes: - support for thumb-less ARM chips was in our port of 5.1.3, but a similar method has been provided upstream now - someone should look at the AVX failure reports, and fix them Changes between GMP version 6.1.0 and 6.1.1 FEATURES * Work around faulty cpuid on some recent Intel chips (this allows GMP to run on Skylake Pentiums). * Support thumb-less ARM chips. Changes between GMP version 6.0.* and 6.1.0 BUGS FIXED * The public function mpn_com is now correctly declared in gmp.h. * Healed possible failures of mpn_sec_sqr for non-cryptographic sizes for some obsolete CPUs. * Various problems related to precision for mpf have been fixed. * Fixed ABI incompatible stack alignment in calls from assembly code. * Fixed PIC bug in popcount affecting Intel processors using the 32-bit ABI. SPEEDUPS * Speedup for Intel Broadwell and Skylake through assembly code making use of new ADX instructions. * Square root is now faster when the remainder is not needed. Also the speed to compute the k-th root improved, for small sizes. FEATURES * New C++ functions gcd and lcm for mpz_class. * New public mpn functions mpn_divexact_1, mpn_zero_p, and mpn_cnd_swap. * New public mpq_cmp_z function, to efficiently compare rationals with integers. * Support for more 32-bit arm processors. * Support for AVX-less modern x86 CPUs. (Such support might be missing either because the CPU vendor chose to disable AVX, or because the running kernel lacks AVX context switch support.) * Support for NetBSD under Xen; we switch off AVX unconditionally under NetBSD since a bug in NetBSD makes AVX fail under Xen. MISC * Tuned values for FFT multiplications are provided for larger number on many platforms. Changes between GMP version 5.1.* and 6.0.0 BUGS FIXED * The function mpz_invert now considers any number invertible in Z/1Z. * The mpn multiply code now handles operands of more than 2^31 limbs correctly. (Note however that the mpz code is limited to 2^32 bits on 32-bit hosts and 2^37 bits on 64-bit hosts.) SPEEDUPS * Plain division of large operands is faster and more monotonous in operand size. * Major speedup for ARM, in particular ARM Cortex-A15, thanks to improved assembly. * Speedup for Intel Sandy Bridge, Ivy Bridge, Haswell, thanks to rewritten and vastly expanded assembly support. Speedup also for the older Core 2 and Nehalem. * Faster mixed arithmetic between mpq_class and double. FEATURES * Support for new Intel and AMD CPUs. * New public functions mpn_sec_mul and mpn_sec_sqr, implementing side-channel silent multiplication and squaring. * New public functions mpn_sec_div_qr and mpn_sec_div_r, implementing side-channel silent division. * New public functions mpn_cnd_add_n and mpn_cnd_sub_n. Side-channel silent conditional addition and subtraction. * New public function mpn_sec_powm, implementing side-channel silent modexp. * New public function mpn_sec_invert, implementing side-channel silent modular inversion. * Better support for applications which use the mpz_t type, but nevertheless need to call some of the lower-level mpn functions. See the documentation for mpz_limbs_read and related functions. @ text @d4 1 a4 1 d8 3 a10 13 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. d14 2 a15 2 dnl or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License dnl for more details. d17 2 a18 3 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/. @