nb_kernel030_x86_64_sse2.s
来自「最著名最快的分子模拟软件」· S 代码 · 共 1,282 行 · 第 1/3 页
S
1,282 行
addpd %xmm9,%xmm3 addpd %xmm10,%xmm4 addpd %xmm11,%xmm5 movlpd %xmm3,(%rdi,%rax,8) movlpd %xmm4,8(%rdi,%rax,8) movlpd %xmm5,16(%rdi,%rax,8) movhpd %xmm3,(%rdi,%rbx,8) movhpd %xmm4,8(%rdi,%rbx,8) movhpd %xmm5,16(%rdi,%rbx,8) ## should we do one more iteration? subl $2,nb030_innerk(%rsp) jl _nb_kernel030_x86_64_sse2.nb030_checksingle jmp _nb_kernel030_x86_64_sse2.nb030_unroll_loop_nb_kernel030_x86_64_sse2.nb030_checksingle: movl nb030_innerk(%rsp),%edx andl $1,%edx jnz _nb_kernel030_x86_64_sse2.nb030_dosingle jmp _nb_kernel030_x86_64_sse2.nb030_updateouterdata_nb_kernel030_x86_64_sse2.nb030_dosingle: movq nb030_innerjjnr(%rsp),%rdx ## pointer to jjnr[k] movl (%rdx),%eax movq nb030_type(%rbp),%rsi movl (%rsi,%rax,4),%r8d movq nb030_vdwparam(%rbp),%rsi shll %r8d movl nb030_ntia(%rsp),%edi addl %edi,%r8d movsd (%rsi,%r8,8),%xmm4 movsd 8(%rsi,%r8,8),%xmm6 movapd %xmm4,nb030_c6(%rsp) movapd %xmm6,nb030_c12(%rsp) movq nb030_pos(%rbp),%rsi ## base of pos[] lea (%rax,%rax,2),%rax ## replace jnr with j3 ## move two coordinates to xmm4-xmm6 movsd (%rsi,%rax,8),%xmm4 movsd 8(%rsi,%rax,8),%xmm5 movsd 16(%rsi,%rax,8),%xmm6 ## calc dr subsd nb030_ix(%rsp),%xmm4 subsd nb030_iy(%rsp),%xmm5 subsd nb030_iz(%rsp),%xmm6 ## store dr movapd %xmm4,nb030_dx(%rsp) movapd %xmm5,nb030_dy(%rsp) movapd %xmm6,nb030_dz(%rsp) ## square it mulsd %xmm4,%xmm4 mulsd %xmm5,%xmm5 mulsd %xmm6,%xmm6 addsd %xmm5,%xmm4 addsd %xmm6,%xmm4 ## rsq in xmm4 cvtsd2ss %xmm4,%xmm5 rsqrtss %xmm5,%xmm5 cvtss2sd %xmm5,%xmm2 ## lu in low xmm2 ## lookup seed in xmm2 movapd %xmm2,%xmm5 ## copy of lu mulsd %xmm2,%xmm2 ## lu*lu movapd nb030_three(%rsp),%xmm1 mulsd %xmm4,%xmm2 ## rsq*lu*lu movapd nb030_half(%rsp),%xmm0 subsd %xmm2,%xmm1 ## 30-rsq*lu*lu mulsd %xmm5,%xmm1 mulsd %xmm0,%xmm1 ## xmm0=iter1 of rinv (new lu) movapd %xmm1,%xmm5 ## copy of lu mulsd %xmm1,%xmm1 ## lu*lu movapd nb030_three(%rsp),%xmm2 mulsd %xmm4,%xmm1 ## rsq*lu*lu movapd nb030_half(%rsp),%xmm0 subsd %xmm1,%xmm2 ## 30-rsq*lu*lu mulsd %xmm5,%xmm2 mulsd %xmm0,%xmm2 ## xmm0=iter2 of rinv (new lu) mulsd %xmm2,%xmm4 ## xmm4=r mulsd nb030_tsc(%rsp),%xmm4 cvttsd2si %xmm4,%r10d ## mm6 = lu idx cvtsi2sd %r10d,%xmm5 subsd %xmm5,%xmm4 movapd %xmm4,%xmm1 ## xmm1=eps ## xmm2=rinv movapd %xmm4,%xmm3 ## eps shll $3,%r10d ## idx *= 8 movq nb030_VFtab(%rbp),%rsi ## indices in r10, r11. Load dispersion and repulsion tables in parallel. movsd (%rsi,%r10,8),%xmm4 movsd 8(%rsi,%r10,8),%xmm5 movsd 16(%rsi,%r10,8),%xmm6 movsd 24(%rsi,%r10,8),%xmm7 movsd 32(%rsi,%r10,8),%xmm8 movsd 40(%rsi,%r10,8),%xmm9 movsd 48(%rsi,%r10,8),%xmm10 movsd 56(%rsi,%r10,8),%xmm11 ## tables ready, in xmm4-xmm7 and xmm8-xmm11 mulsd %xmm1,%xmm7 ## Heps mulsd %xmm1,%xmm11 mulsd %xmm1,%xmm6 ## Geps mulsd %xmm1,%xmm10 mulsd %xmm1,%xmm7 ## Heps2 mulsd %xmm1,%xmm11 addsd %xmm6,%xmm5 ## F+Geps addsd %xmm10,%xmm9 addsd %xmm7,%xmm5 ## F+Geps+Heps2 = Fp addsd %xmm11,%xmm9 addsd %xmm7,%xmm7 ## 2*Heps2 addsd %xmm11,%xmm11 addsd %xmm6,%xmm7 ## 2*Heps2+Geps addsd %xmm10,%xmm11 addsd %xmm5,%xmm7 ## FF = Fp + 2*Heps2 + Geps addsd %xmm9,%xmm11 mulsd %xmm1,%xmm5 ## eps*Fp mulsd %xmm1,%xmm9 movapd nb030_c6(%rsp),%xmm12 movapd nb030_c12(%rsp),%xmm13 addsd %xmm4,%xmm5 ## VV addsd %xmm8,%xmm9 mulsd %xmm12,%xmm5 ## VV*c6 = vnb6 mulsd %xmm13,%xmm9 ## VV*c12 = vnb12 addsd %xmm9,%xmm5 addsd nb030_Vvdwtot(%rsp),%xmm5 movsd %xmm5,nb030_Vvdwtot(%rsp) mulsd %xmm12,%xmm7 ## FF*c6 = fnb6 mulsd %xmm13,%xmm11 ## FF*c12 = fnb12 addsd %xmm11,%xmm7 mulsd nb030_tsc(%rsp),%xmm7 mulsd %xmm2,%xmm7 xorpd %xmm9,%xmm9 subsd %xmm7,%xmm9 movapd %xmm9,%xmm10 movapd %xmm9,%xmm11 movapd nb030_fix(%rsp),%xmm12 movapd nb030_fiy(%rsp),%xmm13 movapd nb030_fiz(%rsp),%xmm14 mulsd nb030_dx(%rsp),%xmm9 mulsd nb030_dy(%rsp),%xmm10 mulsd nb030_dz(%rsp),%xmm11 ## accumulate i forces addsd %xmm9,%xmm12 addsd %xmm10,%xmm13 addsd %xmm11,%xmm14 movsd %xmm12,nb030_fix(%rsp) movsd %xmm13,nb030_fiy(%rsp) movsd %xmm14,nb030_fiz(%rsp) ## the fj's - start by accumulating forces from memory movq nb030_faction(%rbp),%rdi addsd (%rdi,%rax,8),%xmm9 addsd 8(%rdi,%rax,8),%xmm10 addsd 16(%rdi,%rax,8),%xmm11 movsd %xmm9,(%rdi,%rax,8) movsd %xmm10,8(%rdi,%rax,8) movsd %xmm11,16(%rdi,%rax,8)_nb_kernel030_x86_64_sse2.nb030_updateouterdata: movl nb030_ii3(%rsp),%ecx movq nb030_faction(%rbp),%rdi movq nb030_fshift(%rbp),%rsi movl nb030_is3(%rsp),%edx ## accumulate i forces in xmm0, xmm1, xmm2 movapd nb030_fix(%rsp),%xmm0 movapd nb030_fiy(%rsp),%xmm1 movapd nb030_fiz(%rsp),%xmm2 movhlps %xmm0,%xmm3 movhlps %xmm1,%xmm4 movhlps %xmm2,%xmm5 addsd %xmm3,%xmm0 addsd %xmm4,%xmm1 addsd %xmm5,%xmm2 ## sum is in low xmm0-xmm2 ## increment i force movsd (%rdi,%rcx,8),%xmm3 movsd 8(%rdi,%rcx,8),%xmm4 movsd 16(%rdi,%rcx,8),%xmm5 subsd %xmm0,%xmm3 subsd %xmm1,%xmm4 subsd %xmm2,%xmm5 movsd %xmm3,(%rdi,%rcx,8) movsd %xmm4,8(%rdi,%rcx,8) movsd %xmm5,16(%rdi,%rcx,8) ## increment fshift force movsd (%rsi,%rdx,8),%xmm3 movsd 8(%rsi,%rdx,8),%xmm4 movsd 16(%rsi,%rdx,8),%xmm5 subsd %xmm0,%xmm3 subsd %xmm1,%xmm4 subsd %xmm2,%xmm5 movsd %xmm3,(%rsi,%rdx,8) movsd %xmm4,8(%rsi,%rdx,8) movsd %xmm5,16(%rsi,%rdx,8) ## get n from stack movl nb030_n(%rsp),%esi ## get group index for i particle movq nb030_gid(%rbp),%rdx ## base of gid[] movl (%rdx,%rsi,4),%edx ## ggid=gid[n] ## accumulate total lj energy and update it movapd nb030_Vvdwtot(%rsp),%xmm7 ## accumulate movhlps %xmm7,%xmm6 addsd %xmm6,%xmm7 ## low xmm7 has the sum now ## add earlier value from mem movq nb030_Vvdw(%rbp),%rax addsd (%rax,%rdx,8),%xmm7 ## move back to mem movsd %xmm7,(%rax,%rdx,8) ## finish if last movl nb030_nn1(%rsp),%ecx ## esi already loaded with n incl %esi subl %esi,%ecx jz _nb_kernel030_x86_64_sse2.nb030_outerend ## not last, iterate outer loop once more! movl %esi,nb030_n(%rsp) jmp _nb_kernel030_x86_64_sse2.nb030_outer_nb_kernel030_x86_64_sse2.nb030_outerend: ## check if more outer neighborlists remain movl nb030_nri(%rsp),%ecx ## esi already loaded with n above subl %esi,%ecx jz _nb_kernel030_x86_64_sse2.nb030_end ## non-zero, do one more workunit jmp _nb_kernel030_x86_64_sse2.nb030_threadloop_nb_kernel030_x86_64_sse2.nb030_end: movl nb030_nouter(%rsp),%eax movl nb030_ninner(%rsp),%ebx movq nb030_outeriter(%rbp),%rcx movq nb030_inneriter(%rbp),%rdx movl %eax,(%rcx) movl %ebx,(%rdx) addq $376,%rsp emms pop %r15 pop %r14 pop %r13 pop %r12 pop %rbx pop %rbp ret.globl nb_kernel030nf_x86_64_sse2.globl _nb_kernel030nf_x86_64_sse2nb_kernel030nf_x86_64_sse2: _nb_kernel030nf_x86_64_sse2: ## Room for return address and rbp (16 bytes).set nb030nf_fshift, 16.set nb030nf_gid, 24.set nb030nf_pos, 32.set nb030nf_faction, 40.set nb030nf_charge, 48.set nb030nf_p_facel, 56.set nb030nf_argkrf, 64.set nb030nf_argcrf, 72.set nb030nf_Vc, 80.set nb030nf_type, 88.set nb030nf_p_ntype, 96.set nb030nf_vdwparam, 104.set nb030nf_Vvdw, 112.set nb030nf_p_tabscale, 120.set nb030nf_VFtab, 128.set nb030nf_invsqrta, 136.set nb030nf_dvda, 144.set nb030nf_p_gbtabscale, 152.set nb030nf_GBtab, 160.set nb030nf_p_nthreads, 168.set nb030nf_count, 176.set nb030nf_mtx, 184.set nb030nf_outeriter, 192.set nb030nf_inneriter, 200.set nb030nf_work, 208 ## stack offsets for local variables ## bottom of stack is cache-aligned for sse use .set nb030nf_ix, 0.set nb030nf_iy, 16.set nb030nf_iz, 32.set nb030nf_tsc, 48.set nb030nf_c6, 64.set nb030nf_c12, 80.set nb030nf_Vvdwtot, 96.set nb030nf_half, 112.set nb030nf_three, 128.set nb030nf_is3, 144.set nb030nf_ii3, 148.set nb030nf_nri, 152.set nb030nf_iinr, 160.set nb030nf_jindex, 168.set nb030nf_jjnr, 176.set nb030nf_shift, 184.set nb030nf_shiftvec, 192.set nb030nf_innerjjnr, 200.set nb030nf_ntia, 208.set nb030nf_innerk, 212.set nb030nf_n, 216.set nb030nf_nn1, 220.set nb030nf_ntype, 224.set nb030nf_nouter, 228.set nb030nf_ninner, 232 push %rbp movq %rsp,%rbp push %rbx emms push %r12 push %r13 push %r14 push %r15 subq $248,%rsp ## local variable stack space (n*16+8) ## zero 32-bit iteration counters movl $0,%eax movl %eax,nb030nf_nouter(%rsp) movl %eax,nb030nf_ninner(%rsp) movl (%rdi),%edi movl %edi,nb030nf_nri(%rsp) movq %rsi,nb030nf_iinr(%rsp) movq %rdx,nb030nf_jindex(%rsp) movq %rcx,nb030nf_jjnr(%rsp) movq %r8,nb030nf_shift(%rsp) movq %r9,nb030nf_shiftvec(%rsp) movq nb030nf_p_ntype(%rbp),%rdi movl (%rdi),%edi movl %edi,nb030nf_ntype(%rsp) movq nb030nf_p_tabscale(%rbp),%rax movsd (%rax),%xmm3 shufpd $0,%xmm3,%xmm3 movapd %xmm3,nb030nf_tsc(%rsp) ## create constant floating-point factors on stack ## create constant floating-point factors on stack movl $0x00000000,%eax ## lower half of double half IEEE (hex) movl $0x3fe00000,%ebx movl %eax,nb030nf_half(%rsp) movl %ebx,nb030nf_half+4(%rsp) movsd nb030nf_half(%rsp),%xmm1 shufpd $0,%xmm1,%xmm1 ## splat to all elements movapd %xmm1,%xmm3 addpd %xmm3,%xmm3 ## one movapd %xmm3,%xmm2 addpd %xmm2,%xmm2 ## two addpd %xmm2,%xmm3 ## three movapd %xmm1,nb030nf_half(%rsp) movapd %xmm3,nb030nf_three(%rsp)_nb_kernel030nf_x86_64_sse2.nb030nf_threadloop: movq nb030nf_count(%rbp),%rsi ## pointer to sync counter movl (%rsi),%eax_nb_kernel030nf_x86_64_sse2.nb030nf_spinlock: movl %eax,%ebx ## ebx=*count=nn0 addl $1,%ebx ## ebx=nn1=nn0+10 lock cmpxchgl %ebx,(%rsi) ## write nn1 to *counter, ## if it hasnt changed. ## or reread *counter to eax. pause ## -> better p4 performance jnz _nb_kernel030nf_x86_64_sse2.nb030nf_spinlock ## if(nn1>nri) nn1=nri movl nb030nf_nri(%rsp),%ecx movl %ecx,%edx subl %ebx,%ecx cmovlel %edx,%ebx ## if(nn1>nri) nn1=nri ## Cleared the spinlock if we got here. ## eax contains nn0, ebx contains nn1. movl %eax,nb030nf_n(%rsp) movl %ebx,nb030nf_nn1(%rsp) subl %eax,%ebx ## calc number of outer lists movl %eax,%esi ## copy n to esi jg _nb_kernel030nf_x86_64_sse2.nb030nf_outerstart jmp _nb_kernel030nf_x86_64_sse2.nb030nf_end_nb_kernel030nf_x86_64_sse2.nb030nf_outerstart: ## ebx contains number of outer iterations addl nb030nf_nouter(%rsp),%ebx movl %ebx,nb030nf_nouter(%rsp)_nb_kernel030nf_x86_64_sse2.nb030nf_outer: movq nb030nf_shift(%rsp),%rax ## rax = pointer into shift[] movl (%rax,%rsi,4),%ebx ## rbx=shift[n] lea (%rbx,%rbx,2),%rbx ## rbx=3*is
⌨️ 快捷键说明
复制代码Ctrl + C
搜索代码Ctrl + F
全屏模式F11
增大字号Ctrl + =
减小字号Ctrl + -
显示快捷键?