nb_kernel030_ia32_sse2.intel_syntax.s

来自「最著名最快的分子模拟软件」· S 代码 · 共 1,389 行 · 第 1/3 页
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;#;# $Id: nb_kernel030_ia32_sse2.intel_syntax.s,v 1.1.2.2 2007/11/28 18:35:33 spoel Exp $;#;# Gromacs 4.0                         Copyright (c) 1991-2003 ;# David van der Spoel, Erik Lindahl;#;# This program is free software; you can redistribute it and/or;# modify it under the terms of the GNU General Public License;# as published by the Free Software Foundation; either version 2;# of the License, or (at your option) any later version.;#;# To help us fund GROMACS development, we humbly ask that you cite;# the research papers on the package. Check out http://www.gromacs.org;# ;# And Hey:;# Gnomes, ROck Monsters And Chili Sauce;#;# These files require GNU binutils 2.10 or later, since we;# use intel syntax for portability, or a recent version ;# of NASM that understands Extended 3DNow and SSE2 instructions.;# (NASM is normally only used with MS Visual C++).;# Since NASM and gnu as disagree on some definitions and use ;# completely different preprocessing options I have to introduce a;# trick: NASM uses ';' for comments, while gnu as uses '#' on x86.;# Gnu as treats ';' as a line break, i.e. ignores it. This is the;# reason why all comments need both symbols...;# The source is written for GNU as, with intel syntax. When you use;# NASM we redefine a couple of things. The false if-statement around ;# the following code is seen by GNU as, but NASM doesn't see it, so ;# the code inside is read by NASM but not gcc.; .if 0    # block below only read by NASM%define .section	section%define .long		dd%define .align		align%define .globl		global;# NASM only wants 'dword', not 'dword ptr'.%define ptr.equiv          .equiv                  2   %1 equ %2%endmacro; .endif                   # End of NASM-specific block; .intel_syntax noprefix   # Line only read by gnu as.globl nb_kernel030_ia32_sse2.globl _nb_kernel030_ia32_sse2nb_kernel030_ia32_sse2:	_nb_kernel030_ia32_sse2:	.equiv          nb030_p_nri,            8.equiv          nb030_iinr,             12.equiv          nb030_jindex,           16.equiv          nb030_jjnr,             20.equiv          nb030_shift,            24.equiv          nb030_shiftvec,         28.equiv          nb030_fshift,           32.equiv          nb030_gid,              36.equiv          nb030_pos,              40.equiv          nb030_faction,          44.equiv          nb030_charge,           48.equiv          nb030_p_facel,          52.equiv          nb030_argkrf,           56.equiv          nb030_argcrf,           60.equiv          nb030_Vc,               64.equiv          nb030_type,             68.equiv          nb030_p_ntype,          72.equiv          nb030_vdwparam,         76.equiv          nb030_Vvdw,             80.equiv          nb030_p_tabscale,       84.equiv          nb030_VFtab,            88.equiv          nb030_invsqrta,         92.equiv          nb030_dvda,             96.equiv          nb030_p_gbtabscale,     100.equiv          nb030_GBtab,            104.equiv          nb030_p_nthreads,       108.equiv          nb030_count,            112.equiv          nb030_mtx,              116.equiv          nb030_outeriter,        120.equiv          nb030_inneriter,        124.equiv          nb030_work,             128	;# stack offsets for local variables  	;# bottom of stack is cache-aligned for sse2 use .equiv          nb030_ix,               0.equiv          nb030_iy,               16.equiv          nb030_iz,               32.equiv          nb030_dx,               48.equiv          nb030_dy,               64.equiv          nb030_dz,               80.equiv          nb030_two,              96.equiv          nb030_tsc,              112.equiv          nb030_c6,               128.equiv          nb030_c12,              144.equiv          nb030_fscal,            160.equiv          nb030_Vvdwtot,          176.equiv          nb030_fix,              192.equiv          nb030_fiy,              208.equiv          nb030_fiz,              224.equiv          nb030_half,             240.equiv          nb030_three,            256.equiv          nb030_is3,              272.equiv          nb030_ii3,              276.equiv          nb030_ntia,             280.equiv          nb030_innerjjnr,        284.equiv          nb030_innerk,           288.equiv          nb030_n,                292.equiv          nb030_nn1,              296.equiv          nb030_nri,              300.equiv          nb030_ntype,            304.equiv          nb030_nouter,           308.equiv          nb030_ninner,           312.equiv          nb030_salign,           316	push ebp	mov ebp,esp	    	push eax    	push ebx    	push ecx    	push edx	push esi	push edi	sub esp, 320		;# local stack space 	mov  eax, esp	and  eax, 0xf	sub esp, eax	mov [esp + nb030_salign], eax	emms	;# Move args passed by reference to stack	mov ecx, [ebp + nb030_p_nri]	mov edi, [ebp + nb030_p_ntype]	mov ecx, [ecx]	mov edi, [edi]	mov [esp + nb030_nri], ecx	mov [esp + nb030_ntype], edi	;# zero iteration counters	mov eax, 0	mov [esp + nb030_nouter], eax	mov [esp + nb030_ninner], eax	;# create constant floating-point factors on stack	mov eax, 0x00000000     ;# lower half of double 0.5 IEEE (hex)	mov ebx, 0x3fe00000	mov [esp + nb030_half], eax	mov [esp + nb030_half+4], ebx	movsd xmm1, [esp + nb030_half]	shufpd xmm1, xmm1, 0    ;# splat to all elements	movapd xmm3, xmm1	addpd  xmm3, xmm3       ;# 1.0	movapd xmm2, xmm3	addpd  xmm2, xmm2       ;# 2.0	addpd  xmm3, xmm2	;# 3.0	movapd [esp + nb030_half], xmm1	movapd [esp + nb030_two],  xmm2	movapd [esp + nb030_three], xmm3	mov eax, [ebp + nb030_p_tabscale]	movsd xmm3, [eax]	shufpd xmm3, xmm3, 0	movapd [esp + nb030_tsc], xmm3.nb030_threadloop:        mov   esi, [ebp + nb030_count]          ;# pointer to sync counter        mov   eax, [esi].nb030_spinlock:        mov   ebx, eax                          ;# ebx=*count=nn0        add   ebx, 1                           ;# ebx=nn1=nn0+10        lock        cmpxchg [esi], ebx                      ;# write nn1 to *counter,                                                ;# if it hasnt changed.                                                ;# or reread *counter to eax.        pause                                   ;# -> better p4 performance        jnz .nb030_spinlock        ;# if(nn1>nri) nn1=nri        mov ecx, [esp + nb030_nri]        mov edx, ecx        sub ecx, ebx        cmovle ebx, edx                         ;# if(nn1>nri) nn1=nri        ;# Cleared the spinlock if we got here.        ;# eax contains nn0, ebx contains nn1.        mov [esp + nb030_n], eax        mov [esp + nb030_nn1], ebx        sub ebx, eax                            ;# calc number of outer lists	mov esi, eax				;# copy n to esi        jg  .nb030_outerstart        jmp .nb030_end.nb030_outerstart:	;# ebx contains number of outer iterations	add ebx, [esp + nb030_nouter]	mov [esp + nb030_nouter], ebx.nb030_outer:	mov   eax, [ebp + nb030_shift]      ;# eax = pointer into shift[] 	mov   ebx, [eax + esi*4]		;# ebx=shift[n] 		lea   ebx, [ebx + ebx*2]    ;# ebx=3*is 	mov   [esp + nb030_is3],ebx    	;# store is3 	mov   eax, [ebp + nb030_shiftvec]   ;# eax = base of shiftvec[] 	movsd xmm0, [eax + ebx*8]	movsd xmm1, [eax + ebx*8 + 8]	movsd xmm2, [eax + ebx*8 + 16] 	mov   ecx, [ebp + nb030_iinr]       ;# ecx = pointer into iinr[] 		mov   ebx, [ecx + esi*4]	    ;# ebx =ii     	mov   edx, [ebp + nb030_type]     	mov   edx, [edx + ebx*4]    	imul  edx, [esp + nb030_ntype]    	shl   edx, 1    	mov   [esp + nb030_ntia], edx			lea   ebx, [ebx + ebx*2]	;# ebx = 3*ii=ii3 	mov   eax, [ebp + nb030_pos]    ;# eax = base of pos[]  	addsd xmm0, [eax + ebx*8]	addsd xmm1, [eax + ebx*8 + 8]	addsd xmm2, [eax + ebx*8 + 16]		shufpd xmm0, xmm0, 0	shufpd xmm1, xmm1, 0	shufpd xmm2, xmm2, 0	movapd [esp + nb030_ix], xmm0	movapd [esp + nb030_iy], xmm1	movapd [esp + nb030_iz], xmm2	mov   [esp + nb030_ii3], ebx		;# clear tot potential and i forces 	xorpd xmm4, xmm4	movapd [esp + nb030_Vvdwtot], xmm4	movapd [esp + nb030_fix], xmm4	movapd [esp + nb030_fiy], xmm4	movapd [esp + nb030_fiz], xmm4		mov   eax, [ebp + nb030_jindex]	mov   ecx, [eax + esi*4]	     ;# jindex[n] 	mov   edx, [eax + esi*4 + 4]	     ;# jindex[n+1] 	sub   edx, ecx               ;# number of innerloop atoms 	mov   esi, [ebp + nb030_pos]	mov   edi, [ebp + nb030_faction]		mov   eax, [ebp + nb030_jjnr]	shl   ecx, 2	add   eax, ecx	mov   [esp + nb030_innerjjnr], eax     ;# pointer to jjnr[nj0] 	mov   ecx, edx	sub   edx,  2	add   ecx, [esp + nb030_ninner]	mov   [esp + nb030_ninner], ecx	add   edx, 0	mov   [esp + nb030_innerk], edx    ;# number of innerloop atoms 	jge   .nb030_unroll_loop	jmp   .nb030_checksingle.nb030_unroll_loop:		;# twice unrolled innerloop here 	mov   edx, [esp + nb030_innerjjnr]     ;# pointer to jjnr[k] 	mov   eax, [edx]		mov   ebx, [edx + 4]	add dword ptr [esp + nb030_innerjjnr],  8 ;# advance pointer (unrolled 2) 	movd  mm0, eax		;# use mmx registers as temp storage 	movd  mm1, ebx		mov esi, [ebp + nb030_type]	mov eax, [esi + eax*4]	mov ebx, [esi + ebx*4]	mov esi, [ebp + nb030_vdwparam]	shl eax, 1		shl ebx, 1		mov edi, [esp + nb030_ntia]	add eax, edi	add ebx, edi	movlpd xmm6, [esi + eax*8]	;# c6a	movlpd xmm7, [esi + ebx*8]	;# c6b	movhpd xmm6, [esi + eax*8 + 8]	;# c6a c12a 	movhpd xmm7, [esi + ebx*8 + 8]	;# c6b c12b 	movapd xmm4, xmm6	unpcklpd xmm4, xmm7	unpckhpd xmm6, xmm7		movd  eax, mm0			movd  ebx, mm1	movapd [esp + nb030_c6], xmm4	movapd [esp + nb030_c12], xmm6		mov esi, [ebp + nb030_pos]		;# base of pos[] 	lea   eax, [eax + eax*2]	;# replace jnr with j3 	lea   ebx, [ebx + ebx*2]		;# move two coordinates to xmm0-xmm2 		movlpd xmm0, [esi + eax*8]	movlpd xmm1, [esi + eax*8 + 8]	movlpd xmm2, [esi + eax*8 + 16]	movhpd xmm0, [esi + ebx*8]	movhpd xmm1, [esi + ebx*8 + 8]	movhpd xmm2, [esi + ebx*8 + 16]	;# move nb030_ix-iz to xmm4-xmm6 	movapd xmm4, [esp + nb030_ix]	movapd xmm5, [esp + nb030_iy]	movapd xmm6, [esp + nb030_iz]	;# calc dr 	subpd xmm4, xmm0	subpd xmm5, xmm1	subpd xmm6, xmm2	;# store dr 	movapd [esp + nb030_dx], xmm4	movapd [esp + nb030_dy], xmm5	movapd [esp + nb030_dz], xmm6	;# square it 	mulpd xmm4,xmm4	mulpd xmm5,xmm5	mulpd xmm6,xmm6	addpd xmm4, xmm5	addpd xmm4, xmm6	;# rsq in xmm4 	cvtpd2ps xmm5, xmm4		rsqrtps xmm5, xmm5	cvtps2pd xmm2, xmm5	;# lu in low xmm2 	;# lookup seed in xmm2 	movapd xmm5, xmm2	;# copy of lu 	mulpd xmm2, xmm2	;# lu*lu 	movapd xmm1, [esp + nb030_three]	mulpd xmm2, xmm4	;# rsq*lu*lu 				movapd xmm0, [esp + nb030_half]	subpd xmm1, xmm2	;# 30-rsq*lu*lu 	mulpd xmm1, xmm5		mulpd xmm1, xmm0	;# xmm0=iter1 of rinv (new lu) 	movapd xmm5, xmm1	;# copy of lu 	mulpd xmm1, xmm1	;# lu*lu 	movapd xmm2, [esp + nb030_three]	mulpd xmm1, xmm4	;# rsq*lu*lu 				movapd xmm0, [esp + nb030_half]	subpd xmm2, xmm1	;# 30-rsq*lu*lu 	mulpd xmm2, xmm5		mulpd xmm0, xmm2	;# xmm0=iter2 of rinv (new lu) 		mulpd xmm4, xmm0	;# xmm4=r 	mulpd xmm4, [esp + nb030_tsc]		cvttpd2pi mm6, xmm4	;# mm6 = lu idx 	cvtpi2pd xmm5, mm6	subpd xmm4, xmm5	movapd xmm1, xmm4	;# xmm1=eps 	movapd xmm2, xmm1		mulpd  xmm2, xmm2	;# xmm2=eps2 	pslld mm6, 3		;# idx *= 8 		movd mm0, eax		movd mm1, ebx	mov  esi, [ebp + nb030_VFtab]	movd eax, mm6	psrlq mm6, 32	movd ebx, mm6	;# dispersion 	movlpd xmm4, [esi + eax*8]	;# Y1 		movlpd xmm3, [esi + ebx*8]	;# Y2 	movhpd xmm4, [esi + eax*8 + 8]	;# Y1 F1 		movhpd xmm3, [esi + ebx*8 + 8]	;# Y2 F2 	movapd xmm5, xmm4	unpcklpd xmm4, xmm3	;# Y1 Y2 	unpckhpd xmm5, xmm3	;# F1 F2 	movlpd xmm6, [esi + eax*8 + 16]	;# G1	movlpd xmm3, [esi + ebx*8 + 16]	;# G2	movhpd xmm6, [esi + eax*8 + 24]	;# G1 H1 		movhpd xmm3, [esi + ebx*8 + 24]	;# G2 H2 	movapd xmm7, xmm6	unpcklpd xmm6, xmm3	;# G1 G2 	unpckhpd xmm7, xmm3	;# H1 H2 	;# dispersion table ready, in xmm4-xmm7 		mulpd  xmm6, xmm1	;# xmm6=Geps 	mulpd  xmm7, xmm2	;# xmm7=Heps2 	addpd  xmm5, xmm6	addpd  xmm5, xmm7	;# xmm5=Fp 		mulpd  xmm7, [esp + nb030_two]	;# two*Heps2 	addpd  xmm7, xmm6	addpd  xmm7, xmm5 ;# xmm7=FF 	mulpd  xmm5, xmm1 ;# xmm5=eps*Fp 	addpd  xmm5, xmm4 ;# xmm5=VV 	movapd xmm4, [esp + nb030_c6]	mulpd  xmm7, xmm4	 ;# fijD 	mulpd  xmm5, xmm4	 ;# Vvdw6 	;# put scalar force on stack Update Vvdwtot directly 	addpd  xmm5, [esp + nb030_Vvdwtot]	movapd [esp + nb030_fscal], xmm7	movapd [esp + nb030_Vvdwtot], xmm5	;# repulsion 	movlpd xmm4, [esi + eax*8 + 32]	;# Y1 		movlpd xmm3, [esi + ebx*8 + 32]	;# Y2 	movhpd xmm4, [esi + eax*8 + 40]	;# Y1 F1 		movhpd xmm3, [esi + ebx*8 + 40]	;# Y2 F2 	movapd xmm5, xmm4	unpcklpd xmm4, xmm3	;# Y1 Y2 	unpckhpd xmm5, xmm3	;# F1 F2 	movlpd xmm6, [esi + eax*8 + 48]	;# G1	movlpd xmm3, [esi + ebx*8 + 48]	;# G2	movhpd xmm6, [esi + eax*8 + 56]	;# G1 H1 		movhpd xmm3, [esi + ebx*8 + 56]	;# G2 H2 	movapd xmm7, xmm6	unpcklpd xmm6, xmm3	;# G1 G2 	unpckhpd xmm7, xmm3	;# H1 H2 		;# table ready, in xmm4-xmm7 		mulpd  xmm6, xmm1	;# xmm6=Geps 	mulpd  xmm7, xmm2	;# xmm7=Heps2 	addpd  xmm5, xmm6	addpd  xmm5, xmm7	;# xmm5=Fp 		mulpd  xmm7, [esp + nb030_two]	;# two*Heps2 	addpd  xmm7, xmm6	addpd  xmm7, xmm5 ;# xmm7=FF 	mulpd  xmm5, xmm1 ;# xmm5=eps*Fp 	addpd  xmm5, xmm4 ;# xmm5=VV 		movapd xmm4, [esp + nb030_c12]	mulpd  xmm7, xmm4 	mulpd  xmm5, xmm4  	addpd  xmm7, [esp + nb030_fscal] 		addpd  xmm5, [esp + nb030_Vvdwtot]	movapd [esp + nb030_Vvdwtot], xmm5	xorpd  xmm4, xmm4	mulpd xmm7, [esp + nb030_tsc]	mulpd xmm7, xmm0	subpd  xmm4, xmm7	movapd xmm0, [esp + nb030_dx]	movapd xmm1, [esp + nb030_dy]	movapd xmm2, [esp + nb030_dz]	movd eax, mm0		movd ebx, mm1	mov    edi, [ebp + nb030_faction]	mulpd  xmm0, xmm4	mulpd  xmm1, xmm4	mulpd  xmm2, xmm4
nb_kernel030_ia32_sse2.intel_syntax.s - 源码说明

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