c program ognca7 c c file name /zeartha2/eartha14.f c eartha14.f modified leap-frog scheme c ogtac.cntl(ogncb77) from ognc.cntl(ogncd75) c 3d mhd simulation of 1/4 earth's magnetosphere c cartesian coordinate finite resistivity 45 degree boudary c 1990.10.22 modified 1986.06.16 by tatsuki ogino c implicit real*8 (a-h,o-z) c parameter (npe=2) !hpf$ processors pe(npe) c parameter (nx=320,ny= 80,nz=160,nxp=100) parameter (nx=500,ny=100,nz=200,nxp=190) c parameter (nx=640,ny=160,nz=320,nxp=200) c parameter (nx=800,ny=200,nz=400,nxp=250) c parameter (nx=800,ny=200,nz=478,nxp=250) c parameter (nx=800,ny=200,nz=670,nxp=250) parameter (n1=nx+2,n2=n1*(ny+2),n3=n2*(nz+2)) parameter (nb=8,nbb=11,n4=n3*nb,n5=n3*nbb,n6=n3*18) c parameter (last=7680,nil=2,lll=18,ibig=0) c parameter (iiq0=8,iip0= 32,iis0=7680,thx=4.00) c parameter (last=1280,nil=2,lll=18,ibig=0) c parameter (last=2560,nil=2,lll=18,ibig=0) c parameter (last=5120,nil=2,lll=18,ibig=0) c parameter (last=512,nil=2,lll=18,ibig=0) c parameter (last= 32,nil=2,lll=18,ibig=0) parameter (last= 1,nil=2,lll=18,ibig=0) c parameter (last=1920,nil=2,lll=18,ibig=0) c parameter (last=3840,nil=2,lll=18,ibig=0) c parameter (last=7680,nil=2,lll=18,ibig=0) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=4.00) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=3.50) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=3.00) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=2.50) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=2.00) c parameter (iiq0=8,iip0= 32,iis0=1280,thx=2.00) c parameter (iiq0=8,iip0= 32,iis0=2560,thx=1.00) c parameter (iiq0=8,iip0= 32,iis0=5120,thx=0.50) c parameter (iiq0=8,iip0= 32,iis0=512,thx=0.50) c parameter (iiq0=8,iip0= 32,iis0= 32,thx=0.50) parameter (iiq0=1,iip0= 1,iis0= 1,thx=0.50) c parameter (iiq0=8,iip0= 32,iis0=3840,thx=1.50) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=2.00) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=1.50) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=1.00) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=0.75) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=0.50) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=0.33333333) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=0.25) c parameter (iiq0=8,iip0= 32,iis0=1920,thx=0.16666667) c parameter (rmuu=0.0020,eud0=0.0000,ro01=5.0e-4,pr01=3.56e-8) parameter (rmuu=0.0020,eud0=0.0000,ro01=5.0e-4,pr01=3.56e-8) c parameter (rmuu=0.0010,eud0=0.0000,ro01=5.0e-4,pr01=3.56e-8) c parameter (rmuu=0.0010,eud0=0.0010,ro01=5.0e-4,pr01=3.56e-8) parameter (aruu=30.0,pmu0=1.0,dfu0=1.0) c parameter (eatt=0.0010,rrat=0.1,rra1=0.1) c parameter (eatt=0.0020,rrat=0.2,rra1=0.2) parameter (eatt=0.0020,rrat=0.1,rra1=0.1) c parameter (eatt=0.0010,rrat=0.2,rra1=0.2) parameter (nx1=nx+1,nx2=nx+2,ny1=ny+1,ny2=ny+2) parameter (nz1=nz+1,nz2=nz+2,nz3=nz+3) parameter (nin=1,itap=1) parameter (k2=n2*2,k3=n2*3,k4=n2*4,k5=n2*5,k6=n2*6) parameter (k7=n2*7,k8=n2*8,k9=n2*9,k10=n2*10,k11=n2*11) c parameter (orid= 45.375,ths0=0.0,kk8=k3*8) c parameter (orid= 90.375,ths0=0.0,kk8=k3*8) c parameter (orid=270.375,ths0=0.0,kk8=k3*8) parameter (orid=270.750,ths0=0.0,kk8=k3*8) c parameter (orid=270.1875,ths0=0.0,kk8=k3*8) c parameter (mfd=6,nfd=1441,iinob=last*12*0,ttno=128.0) c parameter (mfd=6,nfd=1441,iinob=last*12*2,ttno=256.0) c parameter (mfd=6,nfd=1441,iinob=last*24*4,ttno=256.0) c parameter (mfd=6,nfd=1441,iinob=last*6*19,ttno=256.0) c parameter (mfd=6,nfd=1441,iinob=last*6*20,ttno=512.0) c parameter (mfd=6,nfd=1441,iinob=last*780,ttno=512.0) parameter (mfd=6,nfd=1441,iinob=last*840,ttno=512.0) c parameter (mfd=6,nfd=1441,iinob=last*12*1,ttno=512.0) double precision zt0,zt1,zt2,zt3,zt c dimension f(nx2,ny2,nz2,nb),u(nx2,ny2,nz2,nb), 1 ff(nx2,ny2,nz2,nb),p(nx2,ny2,nz2,nbb), 2 pp(nx2,ny2,nz2,3),fdd(mfd,nfd) c dimension gf(nx2,ny2,nz2,nb),gu(nx2,ny2,nz2,nb), c 1 gff(nx2,ny2,nz2,nb),gpp(nx2,ny2,nz2,3), c 2 gfdd(mfd,nfd) c dimension gf(nx2,ny2,nz2,nb),gfdd(mfd,nfd) dimension gf(nx2,ny2),gfdd(mfd,nfd) dimension hhx(n1),fbb(16), 1 cj(10),cp(11),v(n2) c !hpf$ distribute f(*,*,block,*) onto pe !hpf$ distribute u(*,*,block,*) onto pe !hpf$ distribute pp(*,*,block,*) onto pe !hpf$ distribute ff(*,*,block,*) onto pe !hpf$ distribute p(*,*,block,*) onto pe !hpf$ shadow f(0,0,1:1,0) !hpf$ shadow u(0,0,1:1,0) !hpf$ shadow pp(0,0,1:1,0) !hpf$ shadow ff(0,0,1:1,0) !hpf$ shadow p(0,0,1:1,0) !hpf$ asyncid id1 c !xocl global gf,gu,gff,gpp,gfdd c equivalence (gf,f),(gff,ff),(gu,u),(gpp,pp) c equivalence (gfdd,fdd) c common /blk/f,pp c m 1ro 2vr 3vo 4vz 5pr 6br 7bo 8bz 9jr 10jo 11jz c c cj r1 dr dz b0 rm a2 aid ar1 gam gra data cj/10.0,1.2,0.5,1.0,1.9,-0.01,0.7,0.8,0.9,1.0/ c c cp xl yl zl ra vo0 p0 gra 07 vsw ibr ibz c data cp/161.0,41.0,51.0,4.0,6.81,2.68,1.35,7.0,.044,9.0,-0.0/ c data cp/128.4,32.4,64.4,4.0,0.00,2.68,1.35,7.0,.044,0.0,-0.0/ c data cp/160.5,40.5,80.5,4.0,0.00,2.68,1.35,7.0,.044,0.0,-0.0/ data cp/250.5,50.5,100.5,4.0,0.00,2.68,1.35,7.0,.044,0.0,-0.0/ c c c do 300 iii=1,5 c do 300 iii=1,30 c do 300 iii=1,4 do 300 iii=1,1 bisz=1.5 c bisz=3.0 c bisz=0.0 ntap=10+iii c cp(11)=bisz*float(iii-2) cp(11)=bisz c eat0=eatt rmu0=rmuu rmu0=rmuu aru=aruu pi=3.1415926 gam=5.0/3.0 gm1=2.0/(gam-1.0) gm2=0.5*(gam-1.0) cp(6)=10.0*(gam-1.0)*cp(7)/gam gra=cp(7)*1.0e-6 po0=cp(6)*1.0e-7 bis=cp(11)*1.0e-4 c th=0.0+ths0*float(last) c th=orid*th*pi/180.0 th=orid*pi/180.0 c th=(orid+15.0*float(iii))*pi/180.0 bisy=bis*cos(th) bisz=bis*sin(th) cp(11)=0.0 c cp(11)=cp(11) vsw=cp(9) ar1=cp(4) ar2=ar1*ar1 hx=cp(1)/float(nx1) hy=cp(2)/float(ny1) hz=cp(3)/float(nz1) t=0.5*hx*thx t1=0.5*t cj(8)=ar1 cj(9)=gam cj(10)=gra c dx1=0.25*t1/hx dy1=0.25*t1/hy dz1=0.25*t1/hz dx2=0.25*t/hx dy2=0.25*t/hy dz2=0.25*t/hz dx3=t1/(hx*hx) dy3=t1/(hy*hy) dz3=t1/(hz*hz) dx4=t/(hx*hx) dy4=t/(hy*hy) dz4=t/(hz*hz) c rmu=t*rmu0*ro01 pmu=t*rmu0*pmu0 dfu=t*rmu0*dfu0 eud=eud0 ro02=rrat*ro01 pr02=rrat*pr01 c write (6,12) iii,last,nx,ny,nz,n1,n2,n3,n4,n5,n6,eat0,rmu0,aru, 1 eud,rrat,hx,hy,hz,t,t1,ro01,pr01,gra,dx2,dy2,dz2,dx4,dy4,dz4, 2 bis,orid,th,bisy,bisz,(cp(i),i=1,11),(cj(j),j=1,10) 12 format(1h ,5x,11i10/(1h ,5x,1p8e15.5)) c if(iii.ge.2) go to 400 c do 20 m=1,nb c !hpf$ independent,new(i,j,k) do 22 k=1,nz2 !hpf$ on home(u(:,:,k,:)),local(u,f,i,j,m) begin do 2211 j=1,ny2 do 2211 i=1,nx2 u(i,j,k,m)=0.0 f(i,j,k,m)=0.0 2211 continue !hpf$ end on 22 continue 20 continue c do 221 i=1,n1 221 hhx(i)=hx*float(i) do 222 i=1,nb fbb(i+nb)=1.0 222 fbb(i)=1.0 fbb(4)=-1.0 fbb(6)=-1.0 fbb(7)=-1.0 fbb(3+nb)=-1.0 fbb(4+nb)=-1.0 fbb(6+nb)=-1.0 c c initial condition c call equib7(f,pp,nxp,ro01,pr01,rra1,cj,cp) if(iii.eq.1) 1 call equib8(f,pp,nxp,ro01,pr01,rra1,cj,cp) c go to 882 c write(6,212) (f(i),i=1,n4) 212 format(1h ,2x,1p10e12.4) c 882 continue c c c initial condition c c read(10) f c if(i.eq.1) write(ntap) f if(nin.eq.0) go to 400 if(iii.ge.2) go to 400 c do 410 ii=1,itap c do 174 m=1,nb c do 174 k=1,nz2 c read(10) ((gf(i,j,k,m),i=1,nx2),j=1,ny2) c 174 continue c 410 continue c 400 continue c c!hpf$ asynchronous(id1),nobuffer begin c f(1:nx2,1:ny2,1:nz2,1:nb)=gf(1:nx2,1:ny2,1:nz2,1:nb) c!hpf$ end asynchronous c!hpf$ asyncwait(id1) c do 410 ii=1,itap do 174 m=1,nb do 174 k=1,nz2 c read(10) gf c!hpf$ asynchronous(id1),nobuffer begin c f(1:nx2,1:ny2,k,m) = gf(1:nx2,1:ny2) c!hpf$ end asynchronous c!hpf$ asyncwait(id1) 174 continue 410 continue 400 continue c c c c three dimensional cartesian model time=0.0 iiq=0 iip=0 iis=0 vmax=0.0 c call clock(zt0) call clock(zt1) c do 100 ii=1,last c iiq=iiq+1 iip=iip+1 iis=iis+1 c boundary condition at nz=1 and nz=nz2 c boundary condition at ny=1 and ny=ny2 xx4=0.5*hx*float(2*nxp-nx1-2) xx3=hhx(nx1)+xx4 c c !hpf$ independent,new(i,j,k,m) do 31 k=1,nz2 !hpf$ on home(f(:,:,k,:)),local(f,i,j,m,x,xx,xx3,xx4, !hpf$* hhx) begin do 30 m=1,nb if(k.eq.1) then do 311 j=2,ny1 c f(2,j,1,m)=f(1,j,2,m) f(2,j,k,m)=f(1,j,k+1,m) do 311 i=3,nx1 x=hhx(i)+xx4 x=1.0-x/xx3 x=amin1(x,1.0) x=1.0+x/3.0 xx=1.0-x c f(i,j,1,m)=x*f(i-1,j,2,m)+xx*f(i-2,j,3,m) f(i,j,k,m)=x*f(i-1,j,k+1,m)+xx*f(i-2,j,k+2,m) 311 continue else if(k.eq.nz2) then do 312 j=2,ny1 c f(2,j,nz2,m)=f(1,j,nz1,m) f(2,j,k,m)=f(1,j,k-1,m) do 312 i=3,nx1 x=hhx(i)+xx4 x=1.0-x/xx3 x=amin1(x,1.0) x=1.0+x/3.0 xx=1.0-x c f(i,j,nz2,m)=x*f(i-1,j,nz1,m)+xx*f(i-2,j,nz,m) f(i,j,k,m)=x*f(i-1,j,k-1,m)+xx*f(i-2,j,k-2,m) 312 continue end if 30 continue !hpf$ end on 31 continue c c c!hpf$ independent,new(k) c do k=1,nz2 c f(2:nx1,1,k,1:nb) = f(2:nx1,2,-k+nz3,1:nb) c end do c !hpf$ asynchronous(id1),nobuffer begin c f(2:nx1,1, 1,m) = f(2:nx1,2,1+nz,m) c f(1:nx2,1:ny2,nz2,m) = f(1:nx2,1:ny2, 2,m) c f(2:nx1,1,1:nz2,1:nb) = f(2:nx1,2,nz2:1:-1,1:nb) f(2:nx1,1,nz2:1:-1,1:nb) = f(2:nx1,2,1:nz2,1:nb) c f(2:nx1,1,1:nz2,m) = f(2:nx1,2,nz2:1:-1,m) !hpf$ end asynchronous !hpf$ asyncwait(id1) c c !hpf$ independent,new(i,j,k,m) do 32 k=1,nz2 !hpf$ on home(f(:,:,k,:)),local(f,u,fbb,i,j,m,x,xx, !hpf$* xx3,xx4,hhx,pr02,ro02) begin do 3311 m=1,nb f(2,ny2,k,m)=f(1,ny1,k,m) c f(2,1,k,m)=f(2,2,k,m)*fbb(m+nb) f(2,1,k,m)=f(2,1,k,m)*fbb(m+nb) do 3211 i=3,nx1 x=hhx(i)+xx4 x=1.0-x/xx3 x=amin1(x,1.0) x=1.0+x/3.0 xx=1.0-x f(i,ny2,k,m)=x*f(i-1,ny1,k,m)+xx*f(i-2,ny,k,m) c f(i,1,k,m)=f(i,2,k,m)*fbb(m+nb) f(i,1,k,m)=f(i,1,k,m)*fbb(m+nb) 3211 continue c c boundary condition at nx=nx2 do 3311 j=1,ny2 f(nx2,j,k,m)=f(nx1,j,k,m) 3311 continue c c do 3411 j=1,ny2 do 3411 i=1,nx2 f(i,j,k,5)=amax1(f(i,j,k,5),pr02) f(i,j,k,1)=amax1(f(i,j,k,1),ro02) u(i,j,k,5)=amax1(u(i,j,k,5),pr02) u(i,j,k,1)=amax1(u(i,j,k,1),ro02) 3411 continue !hpf$ end on 32 continue c c !hpf$ reflect f c if(ii.ne.1.and.iiq.ne.iiq0) go to 172 c do 372 m=1,nb !hpf$ independent,new(i,j,k,m) do 371 k=1,nz1 !hpf$ on home(u(:,:,k,:)),local(f,u,i,j,m) begin do 3711 m=1,nb do 3711 j=1,ny1 do 3711 i=1,nx1 u(i,j,k,m)=0.125*(f(i,j,k,m)+f(i+1,j,k,m) 1 +f(i,j+1,k,m)+f(i+1,j+1,k,m) 2 +f(i,j,k+1,m)+f(i+1,j,k+1,m) 3 +f(i,j+1,k+1,m)+f(i+1,j+1,k+1,m)) 3711 continue !hpf$ end on 371 continue c c 372 continue t1=0.5*t dx1=0.25*t1/hx dy1=0.25*t1/hy dz1=0.25*t1/hz dx3=t1/(hx*hx) dy3=t1/(hy*hy) dz3=t1/(hz*hz) c c if(nin.ne.0.or.ii.ne.1) go to 172 c do 171 m=1,nb c do 171 k=1,nz2 c write(ntap) ((gf(i,j,k,m),i=1,nx2),j=1,ny2) c 171 continue 172 continue c c c c if(vmax.gt.1.0) go to 402 c if(iiq.ne.iiq0) go to 401 iiq=0 c 401 if(iip.ne.iip0) go to 403 iip=0 c c th=float(ii)+ths0*float(last) c th=orid*th*pi/180.0 c th=orid*pi/180.0 ith=ii+last*(iii-1) th1=180.0*float(ith)/float(last*4) th2=orid+th1 if(th2.gt.360.0) th2=th2-360.0 th=th2*pi/180.0 bisy=bis*cos(th) bisz=bis*sin(th) c iino=ii+last*(iii-1)+iinob jjno=ifix(float(iino)/ttno)+1 x2=2.0 x1=2.0*x2 nx11=nx1-2*nxp roo1=fdd(2,jjno) vswx=-fdd(3,jjno) pro1=fdd(4,jjno) bisy=-fdd(5,jjno) bisz=fdd(6,jjno) c !hpf$ independent,new(i,j,k) do 102 k=1,nz2 !hpf$ on home(f(:,:,k,:)),local(f,i,j,m,nx11,x,x1,hx,hhx, !hpf$* bis,bisz,bisy,pro1,vswx,roo1) begin do 1021 j=1,ny2 do 1021 i=1,nx2 x=(2.0*hhx(i)/hx-float(2+nx11))/float(nx11) x=(x1+1.0)*x+x1 x=-x x=amax1(x,0.0) x=amin1(x,1.0) x=x*x c f(i,j,k,8)=(1.0-x)*f(i,j,k,8)+bis*x f(i,j,k,8)=(1.0-x)*f(i,j,k,8)+bisz*x f(i,j,k,7)=(1.0-x)*f(i,j,k,7)+bisy*x f(i,j,k,6)=(1.0-x)*f(i,j,k,6) f(i,j,k,5)=(1.0-x)*f(i,j,k,5)+pro1*x f(i,j,k,4)=(1.0-x)*f(i,j,k,4) f(i,j,k,3)=(1.0-x)*f(i,j,k,3) f(i,j,k,2)=(1.0-x)*f(i,j,k,2)+vswx*x f(i,j,k,1)=(1.0-x)*f(i,j,k,1)+roo1*x 1021 continue !hpf$ end on 102 continue c !hpf$ independent,new(i,j,k) do 104 k=1,nz1 !hpf$ on home(u(:,:,k,:)),local(u,i,j,m,nx11,x,x1,hx,hhx, !hpf$* bis,bisz,bisy,pro1,vswx,roo1) begin do 1041 j=1,ny1 do 1041 i=1,nx1 x=(2.0*hhx(i)/hx-float(1+nx11))/float(nx11) x=(x1+1.0)*x+x1 x=-x x=amax1(x,0.0) x=amin1(x,1.0) x=x*x c u(i,j,k,8)=(1.0-x)*u(i,j,k,8)+bis*x u(i,j,k,8)=(1.0-x)*u(i,j,k,8)+bisz*x u(i,j,k,7)=(1.0-x)*u(i,j,k,7)+bisy*x u(i,j,k,6)=(1.0-x)*u(i,j,k,6) u(i,j,k,5)=(1.0-x)*u(i,j,k,5)+pro1*x u(i,j,k,4)=(1.0-x)*u(i,j,k,4) u(i,j,k,3)=(1.0-x)*u(i,j,k,3) u(i,j,k,2)=(1.0-x)*u(i,j,k,2)+vswx*x u(i,j,k,1)=(1.0-x)*u(i,j,k,1)+roo1*x 1041 continue !hpf$ end on 104 continue c c 403 if(iis.ne.iis0) go to 100 iis=0 402 continue call clock(zt2) c if(ii.lt.1024) go to 100 c c c c!hpf$ asynchronous(id1),nobuffer begin c gf(1:nx2,1:ny2,1:nz2,1:nb)=f(1:nx2,1:ny2,1:nz2,1:nb) c!hpf$ end asynchronous c!hpf$ asyncwait(id1) c c write(ntap) f do 173 m=1,nb do 173 k=1,nz2 c!hpf$ asynchronous(id1),nobuffer begin c gf(1:nx2,1:ny2)=f(1:nx2,1:ny2,k,m) c!hpf$ end asynchronous c!hpf$ asyncwait(id1) c write(ntap) gf 173 continue write(6,661) ii,last,iii,ith,nin,itap,th2,th,x2,vmax 661 format(1h ,1x,6i10/1x,1p4e15.7) c call clock(zt3) zt1=zt1-zt0 zt2=zt2-zt0 zt3=zt3-zt0 zt=zt2-zt1 write(6,404) ii,zt0,zt1,zt2,zt3,zt 404 format(1h , i6,1pe12.3,4(0pf12.5)) zt1=zt3+zt0 c if(vmax.gt.1.0) go to 9 c 100 continue 300 continue 9 continue c!xocl end parallel c rewind 12 stop end subroutine equib8(f,pp,nxp,ro01,pr01,rrat,cj,cp) c implicit real*8 (a-h,o-z) parameter (npe=2) !hpf$ processors pe(npe) c parameter (nx=320,ny= 80,nz=160,nb=8) parameter (nx=500,ny=100,nz=200,nb=8) c parameter (nx=800,ny=200,nz=478,nb=8) c parameter (nx=800,ny=200,nz=670,nb=8) parameter (nx1=nx+1,nx2=nx+2,ny1=ny+1,ny2=ny+2) parameter (nz1=nz+1,nz2=nz+2) c dimension f(nx2,ny2,nz2,nb),pp(nx2,ny2,nz2,3) c dimension gf(nx2,ny2,nz2,nb),gpp(nx2,ny2,nz2,3) c dimension gf(nx2,ny2,nz2,nb) dimension cj(1),cp(1) !hpf$ distribute f(*,*,block,*) onto pe !hpf$ distribute pp(*,*,block,*) onto pe !hpf$ shadow f(0,0,1:1,0) !hpf$ shadow pp(0,0,1:1,0) c !xocl global gf,gpp c equivalence (gf,f),(gpp,pp) c common /blk/f,pp c cj 1-r1 2-dr 3-dz 4-b0 5-rm 6-a2 7-aid 8-ar1 9-gam 10-gra c cp 1-r0 2-z0 3-ra 4-vo0 5-p0 6-gra 7-07 8-vsw 9-09 10-10 c c aid=cj(7) ar1=cj(8) gam=cj(9) gra=cj(10) p0=(gam-1.0)*gra/gam bis=cp(11)*1.0e-4 x1=1.0/(gam-1.0) x2=gam*x1 b0=cj(4) ro02=rrat*ro01 pr02=pr01 c ic0=4 icd=6 pi=3.1415926 n1=nx2 n2=n1*ny2 n3=n2*nz2 hx=cp(1)/float(nx1) hy=cp(2)/float(ny1) hz=cp(3)/float(nz1) vsw=cp(9) alp=cj(1) bet=cj(2) alp1=1.0/sqrt(alp) xm=(2.0*alp*b0*b0/(ro01*vsw*vsw))**(1.0/6.0) xm=-xm c !hpf$ independent,new(i,j,k) do 10 k=1,nz2 !hpf$ on home(f(:,:,k,:)),local(f,i,j,m,nxp,x,y,z, !hpf$* dn1,dv1,ax1,vr1,vsw,x1m,xm,ro1,ro2,ro3, !hpf$* hx,hy,hz,dn,ro1m,ro2m,ro3m,x1,ro02,pr02, !hpf$* cp,cj,p0,b0) begin do 101 j=1,ny2 vr1=vsw do 101 i=1,nx2 x=0.5*hx*float(2*i-nx2-1+2*nxp) y=0.5*hy*float(2*j-3) z=0.5*hz*float(2*k-nz2-1) x1m=x-2.0*xm ro2=x*x+y*y+z*z ro1=sqrt(ro2) ro3=ro1*ro2 ro2m=x1m*x1m+y*y+z*z ro1m=sqrt(ro2m) ro3m=ro1m*ro2m f(i,j,k,1)=1.0/ro3 c f(i,j,k,1)=ro1**(-x1) if(f(i,j,k,1).lt.ro02) f(i,j,k,1)=ro02 f(i,j,k,5)=1.0e-7*cp(6)/ro2 c f(i,j,k,5)=p0*ro1**(-x2) if(f(i,j,k,5).lt.pr02) f(i,j,k,5)=pr02 f(i,j,k,6)=-2.0*b0*x*z/(ro2*ro2) f(i,j,k,7)=-2.0*b0*y*z/(ro2*ro2) f(i,j,k,8)=b0*(x*x+y*y-z*z)/(ro2*ro2) f(i,j,k,6)=-3.0*b0*x*z/(ro2*ro3) f(i,j,k,7)=-3.0*b0*y*z/(ro2*ro3) f(i,j,k,8)=b0*(x*x+y*y-2.0*z*z)/(ro2*ro3) 101 continue !hpf$ end on 10 continue c c c current !hpf$ reflect f !hpf$ independent,new(i,j,k) do 38 k=1,nz1 !hpf$ on home(pp(:,:,k,:)),local(pp,f,i,j,m,hx,hy,hz) begin do 381 j=1,ny1 do 381 i=1,nx1 pp(i,j,k,3)=0.25*((f(i+1,j+1,k+1,7)+f(i+1,j,k+1,7) 1 +f(i+1,j+1,k,7)+f(i+1,j,k,7) 2 -f(i,j+1,k+1,7)-f(i,j,k+1,7)-f(i,j+1,k,7)-f(i,j,k,7))/hx 3 -(f(i+1,j+1,k+1,6)-f(i+1,j,k+1,6)+f(i+1,j+1,k,6)-f(i+1,j,k,6) 4 +f(i,j+1,k+1,6)-f(i,j,k+1,6)+f(i,j+1,k,6)-f(i,j,k,6))/hy) pp(i,j,k,2)=0.25*((f(i+1,j+1,k+1,6)+f(i+1,j,k+1,6) 1 -f(i+1,j+1,k,6)-f(i+1,j,k,6) 2 +f(i,j+1,k+1,6)+f(i,j,k+1,6)-f(i,j+1,k,6)-f(i,j,k,6))/hz 3 -(f(i+1,j+1,k+1,8)+f(i+1,j,k+1,8)+f(i+1,j+1,k,8)+f(i+1,j,k,8) 4 -f(i,j+1,k+1,8)-f(i,j,k+1,8)-f(i,j+1,k,8)-f(i,j,k,8))/hx) pp(i,j,k,1)=0.25*((f(i+1,j+1,k+1,8)-f(i+1,j,k+1,8) 1 +f(i+1,j+1,k,8)-f(i+1,j,k,8) 2 +f(i,j+1,k+1,8)-f(i,j,k+1,8)+f(i,j+1,k,8)-f(i,j,k,8))/hy 3 -(f(i+1,j+1,k+1,7)+f(i+1,j,k+1,7)-f(i+1,j+1,k,7)-f(i+1,j,k,7) 4 +f(i,j+1,k+1,7)+f(i,j,k+1,7)-f(i,j+1,k,7)-f(i,j,k,7))/hz) 381 continue !hpf$ end on 38 continue c c !hpf$ independent,new(i,j,k) do 40 k=1,nz2 !hpf$ on home(f(:,:,k,:)),local(f,i,j,m,nxp,x,y,z, !hpf$* dn1,dv1,ax1,vr1,vsw,x1m,xm,ro1,ro2,ro3, !hpf$* hx,hy,hz,dn,ro1m,ro2m,ro3m,x1,ro02,pr02, !hpf$* cp,cj,p0,b0,bx1,bx2,by1,by2,bz1,bz2,y1, !hpf$* alp1,bet,px1,ro01,pr01,xx,bis) begin do 401 j=1,ny2 c vr1=vsw do 401 i=1,nx2 x=0.5*hx*float(2*i-nx2-1+2*nxp) y=0.5*hy*float(2*j-3) z=0.5*hz*float(2*k-nz2-1) x1m=x-2.0*xm ro2=x*x+y*y+z*z ro1=sqrt(ro2) ro3=ro1*ro2 ro2m=x1m*x1m+y*y+z*z ro1m=sqrt(ro2m) ro3m=ro1m*ro2m f(i,j,k,1)=1.0/ro3 c f(i,j,k,1)=ro1**(-x1) if(f(i,j,k,1).lt.ro02) f(i,j,k,1)=ro02 f(i,j,k,5)=1.0e-7*cp(6)/ro2 c f(i,j,k,5)=p0*ro1**(-x2) if(f(i,j,k,5).lt.pr02) f(i,j,k,5)=pr02 f(i,j,k,6)=-2.0*b0*x*z/(ro2*ro2) f(i,j,k,7)=-2.0*b0*y*z/(ro2*ro2) f(i,j,k,8)=b0*(x*x+y*y-z*z)/(ro2*ro2) bx1=-3.0*b0*x*z/(ro2*ro3) by1=-3.0*b0*y*z/(ro2*ro3) bz1=b0*(x*x+y*y-2.0*z*z)/(ro2*ro3) bx2=-3.0*b0*x1m*z/(ro2m*ro3m) by2=-3.0*b0*y*z/(ro2m*ro3m) bz2=b0*(x1m*x1m+y*y-2.0*z*z)/(ro2m*ro3m) f(i,j,k,6)=bx1+bx2 f(i,j,k,7)=by1+by2 f(i,j,k,8)=bz1+bz2 if(x.lt.xm) f(i,j,k,6)=0.0 if(x.lt.xm) f(i,j,k,7)=0.0 if(x.lt.xm) f(i,j,k,8)=0.0 y1=alp1+(1.0-alp1)*(x-xm)/(bet-1.0)/xm if(x.gt.xm) y1=0.0 y1=amax1(y1,0.0) y1=amin1(y1,1.0) vr1=vsw*y1 c px1=sqrt(f(i,j,k,6)*f(i,j,k,6)+f(i,j,k,7)*f(i,j,k,7) 1 +f(i,j,k,8)*f(i,j,k,8)) if(abs(vsw).lt.1.0e-8) go to 401 c y1=(ro01-cj(1)*(px1/vsw)**2)/ro01 c if(y1.le.0.0) y1=0.0 c y1=vsw*sqrt(y1) c vr1=amin1(vr1,y1) f(i,j,k,2)=vr1 xx=vr1/vsw f(i,j,k,5)=f(i,j,k,5)+(pr01-pr02)*xx f(i,j,k,8)=f(i,j,k,8)+bis*y1 401 continue !hpf$ end on 40 continue c return end subroutine clock(ti) real*8 ti,ti1 c call gettod(ti1) call fjhpf_gettod(ti1) ti=1.0d-6*ti1 return end