! read secondary structure prediction from JPRED here!
! read(isecpred,'(A80)',err=100,end=100) line
! read(line,'(f10.3)',err=110) ftors
- read(isecpred,'(f10.3)',err=110) ftors
+ read(isecpred,'(f10.3)',err=110) ftors(1)
- write (iout,*) 'FTORS factor =',ftors
+ write (iout,*) 'FTORS factor =',ftors(1)
! initialize secstruc to any
do i=1,nres
secstruc(i) ='-'
ii=0
do i=1,nres
+ ftors(i)=ftors(1)
if ( secstruc(i) .eq. 'H') then
! Helix restraints for this residue
ii=ii+1
character(len=1) :: toronelet(-2:2) = (/"p","a","G","A","P"/)
logical :: lprint,LaTeX
real(kind=8),dimension(3,3,maxlob) :: blower !(3,3,maxlob)
- real(kind=8),dimension(13) :: b
+ real(kind=8),dimension(13) :: buse
character(len=3) :: lancuch !,ucase
!el local variables
integer :: m,n,l,i,j,k,iblock,lll,llll,ll,nlobi,mm
- integer :: maxinter,junk,kk,ii
+ integer :: maxinter,junk,kk,ii,ncatprotparm
real(kind=8) :: v0ijsccor,v0ijsccor1,v0ijsccor2,v0ijsccor3,si,&
dwa16,rjunk,akl,v0ij,rri,epsij,rrij,sigeps,sigt1sq,&
sigt2sq,sigii1,sigii2,ratsig1,ratsig2,rsum_max,r_augm,&
allocate(nbondterm(ntyp)) !(ntyp)
allocate(vbldsc0(maxbondterm,ntyp)) !(maxbondterm,ntyp)
allocate(aksc(maxbondterm,ntyp)) !(maxbondterm,ntyp)
- allocate(msc(ntyp+1,5)) !(ntyp+1)
- allocate(isc(ntyp+1,5)) !(ntyp+1)
- allocate(restok(ntyp+1,5)) !(ntyp+1)
allocate(abond0(maxbondterm,ntyp)) !(maxbondterm,ntyp)
allocate(long_r_sidechain(ntyp))
allocate(short_r_sidechain(ntyp))
dsc_inv(:)=0.0d0
#ifdef CRYST_BOND
+ allocate(msc(ntyp+1)) !(ntyp+1)
+ allocate(isc(ntyp+1)) !(ntyp+1)
+ allocate(restok(ntyp+1)) !(ntyp+1)
+
read (ibond,*) vbldp0,akp,mp,ip,pstok
do i=1,ntyp
nbondterm(i)=1
endif
enddo
#else
+ mp(:)=0.0d0
+ ip(:)=0.0d0
+ msc(:,:)=0.0d0
+ isc(:,:)=0.0d0
+
+ allocate(msc(ntyp+1,5)) !(ntyp+1)
+ allocate(isc(ntyp+1,5)) !(ntyp+1)
+ allocate(restok(ntyp+1,5)) !(ntyp+1)
+
read (ibond,*) junk,vbldp0,vbldpDUM,akp,rjunk,mp(1),ip(1),pstok(1)
do i=1,ntyp_molec(1)
read (ibond,*) nbondterm(i),(vbldsc0(j,i),aksc(j,i),abond0(j,i),&
enddo
enddo
endif
+ do i=1,ntyp_molec(5)
+ read(iion,*) msc(i,5),restok(i,5)
+ print *,msc(i,5),restok(i,5)
+ enddo
+ ip(5)=0.2
+! isc(5)=0.2
+ read (iion,*) ncatprotparm
+ allocate(catprm(ncatprotparm,4))
+ do k=1,4
+ read (iion,*) (catprm(i,k),i=1,ncatprotparm)
+ enddo
+ print *, catprm
+! read (iion,*) (vcatprm(k),k=1,ncatprotpram)
!----------------------------------------------------
allocate(a0thet(-ntyp:ntyp),theta0(-ntyp:ntyp))
allocate(sig0(-ntyp:ntyp),sigc0(-ntyp:ntyp)) !(-ntyp:ntyp)
enddo
endif
enddo
+!---------reading nucleic acid parameters for rotamers-------------------
+ allocate(sc_parmin_nucl(9,ntyp_molec(2))) !(maxsccoef,ntyp)
+ do i=1,ntyp_molec(2)
+ read (irotam_nucl,*,end=112,err=112)
+ do j=1,9
+ read(irotam_nucl,*,end=112,err=112) sc_parmin_nucl(j,i)
+ enddo
+ enddo
+ close(irotam_nucl)
+ if (lprint) then
+ write (iout,*)
+ write (iout,*) "Base rotamer parameters"
+ do i=1,ntyp_molec(2)
+ write (iout,'(a)') restyp(i,2)
+ write (iout,'(i5,f10.5)') (i,sc_parmin_nucl(j,i),j=1,9)
+ enddo
+ endif
+
!
! Read the parameters of the probability distribution/energy expression
! of the side chains.
#endif
if (lprint) then
+ l=3
write (iout,'(/a/)') 'Torsional constants:'
do i=1,nsccortyp
do j=1,nsccortyp
do i=0,nloctyp-1
read (ifourier,*,end=115,err=115)
- read (ifourier,*,end=115,err=115) (b(ii),ii=1,13)
+ read (ifourier,*,end=115,err=115) (buse(ii),ii=1,13)
if (lprint) then
write (iout,*) 'Type',i
- write (iout,'(a,i2,a,f10.5)') ('b(',ii,')=',b(ii),ii=1,13)
+ write (iout,'(a,i2,a,f10.5)') ('buse(',ii,')=',buse(ii),ii=1,13)
endif
- B1(1,i) = b(3)
- B1(2,i) = b(5)
- B1(1,-i) = b(3)
- B1(2,-i) = -b(5)
-! b1(1,i)=0.0d0
-! b1(2,i)=0.0d0
- B1tilde(1,i) = b(3)
- B1tilde(2,i) =-b(5)
- B1tilde(1,-i) =-b(3)
- B1tilde(2,-i) =b(5)
-! b1tilde(1,i)=0.0d0
-! b1tilde(2,i)=0.0d0
- B2(1,i) = b(2)
- B2(2,i) = b(4)
- B2(1,-i) =b(2)
- B2(2,-i) =-b(4)
-
-! b2(1,i)=0.0d0
-! b2(2,i)=0.0d0
- CC(1,1,i)= b(7)
- CC(2,2,i)=-b(7)
- CC(2,1,i)= b(9)
- CC(1,2,i)= b(9)
- CC(1,1,-i)= b(7)
- CC(2,2,-i)=-b(7)
- CC(2,1,-i)=-b(9)
- CC(1,2,-i)=-b(9)
+ B1(1,i) = buse(3)
+ B1(2,i) = buse(5)
+ B1(1,-i) = buse(3)
+ B1(2,-i) = -buse(5)
+! buse1(1,i)=0.0d0
+! buse1(2,i)=0.0d0
+ B1tilde(1,i) = buse(3)
+ B1tilde(2,i) =-buse(5)
+ B1tilde(1,-i) =-buse(3)
+ B1tilde(2,-i) =buse(5)
+! buse1tilde(1,i)=0.0d0
+! buse1tilde(2,i)=0.0d0
+ B2(1,i) = buse(2)
+ B2(2,i) = buse(4)
+ B2(1,-i) =buse(2)
+ B2(2,-i) =-buse(4)
+
+! buse2(1,i)=0.0d0
+! buse2(2,i)=0.0d0
+ CC(1,1,i)= buse(7)
+ CC(2,2,i)=-buse(7)
+ CC(2,1,i)= buse(9)
+ CC(1,2,i)= buse(9)
+ CC(1,1,-i)= buse(7)
+ CC(2,2,-i)=-buse(7)
+ CC(2,1,-i)=-buse(9)
+ CC(1,2,-i)=-buse(9)
! CC(1,1,i)=0.0d0
! CC(2,2,i)=0.0d0
! CC(2,1,i)=0.0d0
! CC(1,2,i)=0.0d0
- Ctilde(1,1,i)=b(7)
- Ctilde(1,2,i)=b(9)
- Ctilde(2,1,i)=-b(9)
- Ctilde(2,2,i)=b(7)
- Ctilde(1,1,-i)=b(7)
- Ctilde(1,2,-i)=-b(9)
- Ctilde(2,1,-i)=b(9)
- Ctilde(2,2,-i)=b(7)
+ Ctilde(1,1,i)=buse(7)
+ Ctilde(1,2,i)=buse(9)
+ Ctilde(2,1,i)=-buse(9)
+ Ctilde(2,2,i)=buse(7)
+ Ctilde(1,1,-i)=buse(7)
+ Ctilde(1,2,-i)=-buse(9)
+ Ctilde(2,1,-i)=buse(9)
+ Ctilde(2,2,-i)=buse(7)
! Ctilde(1,1,i)=0.0d0
! Ctilde(1,2,i)=0.0d0
! Ctilde(2,1,i)=0.0d0
! Ctilde(2,2,i)=0.0d0
- DD(1,1,i)= b(6)
- DD(2,2,i)=-b(6)
- DD(2,1,i)= b(8)
- DD(1,2,i)= b(8)
- DD(1,1,-i)= b(6)
- DD(2,2,-i)=-b(6)
- DD(2,1,-i)=-b(8)
- DD(1,2,-i)=-b(8)
+ DD(1,1,i)= buse(6)
+ DD(2,2,i)=-buse(6)
+ DD(2,1,i)= buse(8)
+ DD(1,2,i)= buse(8)
+ DD(1,1,-i)= buse(6)
+ DD(2,2,-i)=-buse(6)
+ DD(2,1,-i)=-buse(8)
+ DD(1,2,-i)=-buse(8)
! DD(1,1,i)=0.0d0
! DD(2,2,i)=0.0d0
! DD(2,1,i)=0.0d0
! DD(1,2,i)=0.0d0
- Dtilde(1,1,i)=b(6)
- Dtilde(1,2,i)=b(8)
- Dtilde(2,1,i)=-b(8)
- Dtilde(2,2,i)=b(6)
- Dtilde(1,1,-i)=b(6)
- Dtilde(1,2,-i)=-b(8)
- Dtilde(2,1,-i)=b(8)
- Dtilde(2,2,-i)=b(6)
+ Dtilde(1,1,i)=buse(6)
+ Dtilde(1,2,i)=buse(8)
+ Dtilde(2,1,i)=-buse(8)
+ Dtilde(2,2,i)=buse(6)
+ Dtilde(1,1,-i)=buse(6)
+ Dtilde(1,2,-i)=-buse(8)
+ Dtilde(2,1,-i)=buse(8)
+ Dtilde(2,2,-i)=buse(6)
! Dtilde(1,1,i)=0.0d0
! Dtilde(1,2,i)=0.0d0
! Dtilde(2,1,i)=0.0d0
! Dtilde(2,2,i)=0.0d0
- EE(1,1,i)= b(10)+b(11)
- EE(2,2,i)=-b(10)+b(11)
- EE(2,1,i)= b(12)-b(13)
- EE(1,2,i)= b(12)+b(13)
- EE(1,1,-i)= b(10)+b(11)
- EE(2,2,-i)=-b(10)+b(11)
- EE(2,1,-i)=-b(12)+b(13)
- EE(1,2,-i)=-b(12)-b(13)
+ EE(1,1,i)= buse(10)+buse(11)
+ EE(2,2,i)=-buse(10)+buse(11)
+ EE(2,1,i)= buse(12)-buse(13)
+ EE(1,2,i)= buse(12)+buse(13)
+ EE(1,1,-i)= buse(10)+buse(11)
+ EE(2,2,-i)=-buse(10)+buse(11)
+ EE(2,1,-i)=-buse(12)+buse(13)
+ EE(1,2,-i)=-buse(12)-buse(13)
! ee(1,1,i)=1.0d0
! ee(2,2,i)=1.0d0
!---------------------- GB or BP potential -----------------------------
case(3:4)
! 30 do i=1,ntyp
+! print *,"I AM in SCELE",scelemode
+ if (scelemode.eq.0) then
do i=1,ntyp
read (isidep,*,end=117,err=117)(eps(i,j),j=i,ntyp)
enddo
write (iout,'(a3,6x,4f10.5)') (restyp(i,1),sigma0(i),sigii(i),&
chip(i),alp(i),i=1,ntyp)
endif
+ else
+! print *,ntyp,"NTYP"
+ allocate(icharge(ntyp1))
+! print *,ntyp,icharge(i)
+ icharge(:)=0
+ read (isidep,*) (icharge(i),i=1,ntyp)
+ print *,ntyp,icharge(i)
+! if(.not.allocated(eps)) allocate(eps(-ntyp
+!c write (2,*) "icharge",(icharge(i),i=1,ntyp)
+ allocate(alphapol(ntyp,ntyp),epshead(ntyp,ntyp),sig0head(ntyp,ntyp))
+ allocate(sigiso1(ntyp,ntyp),rborn(ntyp,ntyp),sigmap1(ntyp,ntyp))
+ allocate(sigmap2(ntyp,ntyp),sigiso2(ntyp,ntyp))
+ allocate(chis(ntyp,ntyp),wquad(ntyp,ntyp),chipp(ntyp,ntyp))
+ allocate(epsintab(ntyp,ntyp))
+ allocate(dtail(2,ntyp,ntyp))
+ allocate(alphasur(4,ntyp,ntyp),alphiso(4,ntyp,ntyp))
+ allocate(wqdip(2,ntyp,ntyp))
+ allocate(wstate(4,ntyp,ntyp))
+ allocate(dhead(2,2,ntyp,ntyp))
+ allocate(nstate(ntyp,ntyp))
+ if (.not.allocated(sigma)) allocate(sigma(0:ntyp1,0:ntyp1))
+ if (.not.allocated(chi)) allocate(chi(ntyp1,ntyp1)) !(ntyp,ntyp)
+ do i=1,ntyp
+ do j=1,i
+! write (*,*) "Im in ALAB", i, " ", j
+ read(isidep,*) &
+ eps(i,j),sigma(i,j),chi(i,j),chi(j,i),chipp(i,j),chipp(j,i), &
+ (alphasur(k,i,j),k=1,4),sigmap1(i,j),sigmap2(i,j), &
+ chis(i,j),chis(j,i), &
+ nstate(i,j),(wstate(k,i,j),k=1,4), &
+ dhead(1,1,i,j),dhead(1,2,i,j),dhead(2,1,i,j),dhead(2,2,i,j),&
+ dtail(1,i,j),dtail(2,i,j), &
+ epshead(i,j),sig0head(i,j), &
+ rborn(i,j),rborn(j,i),(wqdip(k,i,j),k=1,2),wquad(i,j), &
+ alphapol(i,j),alphapol(j,i), &
+ (alphiso(k,i,j),k=1,4),sigiso1(i,j),sigiso2(i,j),epsintab(i,j)
+! print *,eps(i,j),sigma(i,j),"SIGMAP",i,j,sigmap1(i,j),sigmap2(j,i)
+ END DO
+ END DO
+ DO i = 1, ntyp
+ DO j = i+1, ntyp
+ eps(i,j) = eps(j,i)
+ sigma(i,j) = sigma(j,i)
+ sigmap1(i,j)=sigmap1(j,i)
+ sigmap2(i,j)=sigmap2(j,i)
+ sigiso1(i,j)=sigiso1(j,i)
+ sigiso2(i,j)=sigiso2(j,i)
+! print *,"ATU",sigma(j,i),sigma(i,j),i,j
+ nstate(i,j) = nstate(j,i)
+ dtail(1,i,j) = dtail(1,j,i)
+ dtail(2,i,j) = dtail(2,j,i)
+ DO k = 1, 4
+ alphasur(k,i,j) = alphasur(k,j,i)
+ wstate(k,i,j) = wstate(k,j,i)
+ alphiso(k,i,j) = alphiso(k,j,i)
+ END DO
+
+ dhead(2,1,i,j) = dhead(1,1,j,i)
+ dhead(2,2,i,j) = dhead(1,2,j,i)
+ dhead(1,1,i,j) = dhead(2,1,j,i)
+ dhead(1,2,i,j) = dhead(2,2,j,i)
+
+ epshead(i,j) = epshead(j,i)
+ sig0head(i,j) = sig0head(j,i)
+
+ DO k = 1, 2
+ wqdip(k,i,j) = wqdip(k,j,i)
+ END DO
+
+ wquad(i,j) = wquad(j,i)
+ epsintab(i,j) = epsintab(j,i)
+! if (epsintab(i,j).ne.1.0) print *,"WHAT?",i,j,epsintab(i,j)
+ END DO
+ END DO
+ endif
! goto 50
!--------------------- GBV potential -----------------------------------
case(5)
! Calculate the "working" parameters of SC interactions.
!el from module energy - COMMON.INTERACT-------
- allocate(aa_aq(ntyp1,ntyp1),bb_aq(ntyp1,ntyp1),chi(ntyp1,ntyp1)) !(ntyp,ntyp)
+ allocate(aa_aq(ntyp1,ntyp1),bb_aq(ntyp1,ntyp1))
+ if (.not.allocated(chi)) allocate(chi(ntyp1,ntyp1)) !(ntyp,ntyp)
allocate(aa_lip(ntyp1,ntyp1),bb_lip(ntyp1,ntyp1)) !(ntyp,ntyp)
- allocate(sigma(0:ntyp1,0:ntyp1),r0(ntyp1,ntyp1)) !(0:ntyp1,0:ntyp1)
+ if (.not.allocated(sigma)) allocate(sigma(0:ntyp1,0:ntyp1))
+ allocate(r0(ntyp1,ntyp1)) !(0:ntyp1,0:ntyp1)
allocate(acavtub(ntyp1),bcavtub(ntyp1),ccavtub(ntyp1),&
dcavtub(ntyp1))
allocate(sc_aa_tube_par(ntyp1),sc_bb_tube_par(ntyp1),&
bb_aq(:,:)=0.0D0
aa_lip(:,:)=0.0D0
bb_lip(:,:)=0.0D0
+ if (scelemode.eq.0) then
chi(:,:)=0.0D0
sigma(:,:)=0.0D0
r0(:,:)=0.0D0
+ endif
acavtub(:)=0.0d0
bcavtub(:)=0.0d0
ccavtub(:)=0.0d0
epslip(i,j)=epslip(j,i)
enddo
enddo
+ if (scelemode.eq.0) then
do i=1,ntyp
do j=i,ntyp
sigma(i,j)=dsqrt(sigma0(i)**2+sigma0(j)**2)
rs0(j,i)=rs0(i,j)
enddo
enddo
+ endif
if (lprint) write (iout,'(/a/10x,7a/72(1h-))') &
'Working parameters of the SC interactions:',&
' a ',' b ',' augm ',' sigma ',' r0 ',&
epsij=eps(i,j)
if (ipot.eq.1 .or. ipot.eq.3 .or. ipot.eq.4) then
rrij=sigma(i,j)
+! print *,"SIGMA ZLA?",sigma(i,j)
else
rrij=rr0(i)+rr0(j)
endif
sigeps=dsign(1.0D0,epsij)
epsij=dabs(epsij)
aa_aq(i,j)=epsij*rrij*rrij
+ print *,"ADASKO",epsij,rrij,expon
bb_aq(i,j)=-sigeps*epsij*rrij
aa_aq(j,i)=aa_aq(i,j)
bb_aq(j,i)=bb_aq(i,j)
aa_lip(j,i)=aa_lip(i,j)
bb_lip(j,i)=bb_lip(i,j)
!C write(iout,*) aa_lip
- if (ipot.gt.2) then
+ if ((ipot.gt.2).and. (scelemode.eq.0)) then
sigt1sq=sigma0(i)**2
sigt2sq=sigma0(j)**2
sigii1=sigii(i)
sc_bb_tube_par(i)=-sigeps*4.0d0*epssctube*sigmasctube
write(iout,*) sc_aa_tube_par(i), sc_bb_tube_par(i),tubetranene(i)
enddo
+!-----------------READING SC BASE POTENTIALS-----------------------------
+ allocate(eps_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(sigma_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(chi_scbase(ntyp_molec(1),ntyp_molec(2),2))
+ allocate(chipp_scbase(ntyp_molec(1),ntyp_molec(2),2))
+ allocate(alphasur_scbase(4,ntyp_molec(1),ntyp_molec(2)))
+ allocate(sigmap1_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(sigmap2_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(chis_scbase(ntyp_molec(1),ntyp_molec(2),2))
+ allocate(dhead_scbasei(ntyp_molec(1),ntyp_molec(2)))
+ allocate(dhead_scbasej(ntyp_molec(1),ntyp_molec(2)))
+ allocate(rborn_scbasei(ntyp_molec(1),ntyp_molec(2)))
+ allocate(rborn_scbasej(ntyp_molec(1),ntyp_molec(2)))
+ allocate(wdipdip_scbase(3,ntyp_molec(1),ntyp_molec(2)))
+ allocate(wqdip_scbase(2,ntyp_molec(1),ntyp_molec(2)))
+ allocate(alphapol_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(epsintab_scbase(ntyp_molec(1),ntyp_molec(2)))
+
+
+ do i=1,ntyp_molec(1)
+ do j=1,ntyp_molec(2)-1 ! without U then we will take T for U
+ write (*,*) "Im in ", i, " ", j
+ read(isidep_scbase,*) &
+ eps_scbase(i,j),sigma_scbase(i,j),chi_scbase(i,j,1),&
+ chi_scbase(i,j,2),chipp_scbase(i,j,1),chipp_scbase(i,j,2)
+ write(*,*) "eps",eps_scbase(i,j)
+ read(isidep_scbase,*) &
+ (alphasur_scbase(k,i,j),k=1,4),sigmap1_scbase(i,j),sigmap2_scbase(i,j), &
+ chis_scbase(i,j,1),chis_scbase(i,j,2)
+ read(isidep_scbase,*) &
+ dhead_scbasei(i,j), &
+ dhead_scbasej(i,j), &
+ rborn_scbasei(i,j),rborn_scbasej(i,j)
+ read(isidep_scbase,*) &
+ (wdipdip_scbase(k,i,j),k=1,3), &
+ (wqdip_scbase(k,i,j),k=1,2)
+ read(isidep_scbase,*) &
+ alphapol_scbase(i,j), &
+ epsintab_scbase(i,j)
+ END DO
+ END DO
+ allocate(aa_scbase(ntyp_molec(1),ntyp_molec(2)))
+ allocate(bb_scbase(ntyp_molec(1),ntyp_molec(2)))
+
+ do i=1,ntyp_molec(1)
+ do j=1,ntyp_molec(2)-1
+ epsij=eps_scbase(i,j)
+ rrij=sigma_scbase(i,j)
+! r0(i,j)=rrij
+! r0(j,i)=rrij
+ rrij=rrij**expon
+! epsij=eps(i,j)
+ sigeps=dsign(1.0D0,epsij)
+ epsij=dabs(epsij)
+ aa_scbase(i,j)=epsij*rrij*rrij
+ bb_scbase(i,j)=-sigeps*epsij*rrij
+ enddo
+ enddo
+!-----------------READING PEP BASE POTENTIALS-------------------
+ allocate(eps_pepbase(ntyp_molec(2)))
+ allocate(sigma_pepbase(ntyp_molec(2)))
+ allocate(chi_pepbase(ntyp_molec(2),2))
+ allocate(chipp_pepbase(ntyp_molec(2),2))
+ allocate(alphasur_pepbase(4,ntyp_molec(2)))
+ allocate(sigmap1_pepbase(ntyp_molec(2)))
+ allocate(sigmap2_pepbase(ntyp_molec(2)))
+ allocate(chis_pepbase(ntyp_molec(2),2))
+ allocate(wdipdip_pepbase(3,ntyp_molec(2)))
+
+
+ do j=1,ntyp_molec(2)-1 ! without U then we will take T for U
+ write (*,*) "Im in ", i, " ", j
+ read(isidep_pepbase,*) &
+ eps_pepbase(j),sigma_pepbase(j),chi_pepbase(j,1),&
+ chi_pepbase(j,2),chipp_pepbase(j,1),chipp_pepbase(j,2)
+ write(*,*) "eps",eps_pepbase(j)
+ read(isidep_pepbase,*) &
+ (alphasur_pepbase(k,j),k=1,4),sigmap1_pepbase(j),sigmap2_pepbase(j), &
+ chis_pepbase(j,1),chis_pepbase(j,2)
+ read(isidep_pepbase,*) &
+ (wdipdip_pepbase(k,j),k=1,3)
+ END DO
+ allocate(aa_pepbase(ntyp_molec(2)))
+ allocate(bb_pepbase(ntyp_molec(2)))
+
+ do j=1,ntyp_molec(2)-1
+ epsij=eps_pepbase(j)
+ rrij=sigma_pepbase(j)
+! r0(i,j)=rrij
+! r0(j,i)=rrij
+ rrij=rrij**expon
+! epsij=eps(i,j)
+ sigeps=dsign(1.0D0,epsij)
+ epsij=dabs(epsij)
+ aa_pepbase(j)=epsij*rrij*rrij
+ bb_pepbase(j)=-sigeps*epsij*rrij
+ enddo
+!--------------READING SC PHOSPHATE-------------------------------------
+ allocate(eps_scpho(ntyp_molec(1)))
+ allocate(sigma_scpho(ntyp_molec(1)))
+ allocate(chi_scpho(ntyp_molec(1),2))
+ allocate(chipp_scpho(ntyp_molec(1),2))
+ allocate(alphasur_scpho(4,ntyp_molec(1)))
+ allocate(sigmap1_scpho(ntyp_molec(1)))
+ allocate(sigmap2_scpho(ntyp_molec(1)))
+ allocate(chis_scpho(ntyp_molec(1),2))
+ allocate(wqq_scpho(ntyp_molec(1)))
+ allocate(wqdip_scpho(2,ntyp_molec(1)))
+ allocate(alphapol_scpho(ntyp_molec(1)))
+ allocate(epsintab_scpho(ntyp_molec(1)))
+ allocate(dhead_scphoi(ntyp_molec(1)))
+ allocate(rborn_scphoi(ntyp_molec(1)))
+ allocate(rborn_scphoj(ntyp_molec(1)))
+ allocate(alphi_scpho(ntyp_molec(1)))
+
+
+! j=1
+ do j=1,ntyp_molec(1) ! without U then we will take T for U
+ write (*,*) "Im in scpho ", i, " ", j
+ read(isidep_scpho,*) &
+ eps_scpho(j),sigma_scpho(j),chi_scpho(j,1),&
+ chi_scpho(j,2),chipp_scpho(j,1),chipp_scpho(j,2)
+ write(*,*) "eps",eps_scpho(j)
+ read(isidep_scpho,*) &
+ (alphasur_scpho(k,j),k=1,4),sigmap1_scpho(j),sigmap2_scpho(j), &
+ chis_scpho(j,1),chis_scpho(j,2)
+ read(isidep_scpho,*) &
+ (wqdip_scpho(k,j),k=1,2),wqq_scpho(j),dhead_scphoi(j)
+ read(isidep_scpho,*) &
+ epsintab_scpho(j),alphapol_scpho(j),rborn_scphoi(j),rborn_scphoj(j), &
+ alphi_scpho(j)
+
+ END DO
+ allocate(aa_scpho(ntyp_molec(1)))
+ allocate(bb_scpho(ntyp_molec(1)))
+
+ do j=1,ntyp_molec(1)
+ epsij=eps_scpho(j)
+ rrij=sigma_scpho(j)
+! r0(i,j)=rrij
+! r0(j,i)=rrij
+ rrij=rrij**expon
+! epsij=eps(i,j)
+ sigeps=dsign(1.0D0,epsij)
+ epsij=dabs(epsij)
+ aa_scpho(j)=epsij*rrij*rrij
+ bb_scpho(j)=-sigeps*epsij*rrij
+ enddo
+
+
+ read(isidep_peppho,*) &
+ eps_peppho,sigma_peppho
+ read(isidep_peppho,*) &
+ (alphasur_peppho(k),k=1,4),sigmap1_peppho,sigmap2_peppho
+ read(isidep_peppho,*) &
+ (wqdip_peppho(k),k=1,2)
+
+ epsij=eps_peppho
+ rrij=sigma_peppho
+! r0(i,j)=rrij
+! r0(j,i)=rrij
+ rrij=rrij**expon
+! epsij=eps(i,j)
+ sigeps=dsign(1.0D0,epsij)
+ epsij=dabs(epsij)
+ aa_peppho=epsij*rrij*rrij
+ bb_peppho=-sigeps*epsij*rrij
+
allocate(aad(ntyp,2),bad(ntyp,2)) !(ntyp,2)
bad(:,:)=0.0D0
use control_data
use compare_data
use MPI_data
- use control, only: rescode,sugarcode
+! use control, only: rescode,sugarcode
! implicit real*8 (a-h,o-z)
! include 'DIMENSIONS'
! include 'COMMON.LOCAL'
character(len=80) :: card
real(kind=8),dimension(3,20) :: sccor
integer :: kkk,lll,icha,kupa,molecule,counter,seqalingbegin !rescode,
- integer :: isugar,molecprev
+ integer :: isugar,molecprev,firstion
character*1 :: sugar
real(kind=8) :: cou
real(kind=8),dimension(3) :: ccc
! write (2,*) "UNRES_PDB",unres_pdb
ires=0
ires_old=0
+#ifdef WHAM_RUN
+ do i=1,nres
+ do j=1,5
+ itype(i,j)=0
+ enddo
+ enddo
+#endif
nres=0
iii=0
lsecondary=.false.
nhfrag=0
nbfrag=0
+ do j=1,5
+ nres_molec(j)=0
+ enddo
+
+
!-----------------------------
allocate(hfrag(2,maxres/3)) !(2,maxres/3)
allocate(bfrag(4,maxres/3)) !(4,maxres/3)
-
+ if(.not. allocated(istype)) allocate(istype(maxres))
do i=1,100000
read (ipdbin,'(a80)',end=10) card
-! write (iout,'(a)') card
+ write (iout,'(a)') card
if (card(:5).eq.'HELIX') then
nhfrag=nhfrag+1
lsecondary=.true.
if (atom.eq.'CA '.or.atom.eq.'N ') then
molecule=1
itype(ires,molecule)=rescode(ires,res,0,molecule)
+ firstion=0
! nres_molec(molecule)=nres_molec(molecule)+1
else
molecule=2
- itype(ires,molecule)=rescode(ires,res(2:4),0,molecule)
+ itype(ires,molecule)=rescode(ires,res(2:3),0,molecule)
! nres_molec(molecule)=nres_molec(molecule)+1
read (card(19:19),'(a1)') sugar
isugar=sugarcode(sugar,ires)
do j=1,3
c(j,ires)=c(j,ires)+ccc(j)/5.0
enddo
+ print *,counter,molecule
if (counter.eq.5) then
! iii=iii+1
nres_molec(molecule)=nres_molec(molecule)+1
+ firstion=0
! do j=1,3
! sccor(j,iii)=c(j,ires)
! enddo
! print *,ires,istype(ires)
endif
if (unres_pdb) then
+ molecule=2
+! print *,"nres_molec(molecule)",nres_molec(molecule),ires
read(card(31:54),'(3f8.3)') (c(j,ires),j=1,3)
+ nres_molec(molecule)=nres_molec(molecule)+1
+ print *,"nres_molec(molecule)",nres_molec(molecule),ires
+
else
iii=iii+1
read(card(31:54),'(3f8.3)') (sccor(j,iii),j=1,3)
endif
+ else if ((atom.eq."C1'").and.unres_pdb) then
+ iii=iii+1
+ read(card(31:54),'(3f8.3)') (sccor(j,iii),j=1,3)
! write (*,*) card(23:27),ires,itype(ires,1)
else if (atom.ne.'O'.and.atom(1:1).ne.'H' .and. &
atom.ne.'N' .and. atom.ne.'C' .and. &
endif
endif
else if ((ions).and.(card(1:6).eq.'HETATM')) then
-
+ if (firstion.eq.0) then
+ firstion=1
+ if (unres_pdb) then
+ do j=1,3
+ dc(j,ires)=sccor(j,iii)
+ enddo
+ else
+ call sccenter(ires,iii,sccor)
+ endif
+ endif
read (card(12:16),*) atom
print *,"HETATOM", atom
read (card(18:20),'(a3)') res
if (molecule.ne.5) molecprev=molecule
molecule=5
nres_molec(molecule)=nres_molec(molecule)+1
- itype(ires,molecule)=rescode(ires,res(2:4),0,molecule)
+ print *,"HERE",nres_molec(molecule)
+ res=res(2:3)//' '
+ itype(ires,molecule)=rescode(ires,res,0,molecule)
read(card(31:54),'(3f8.3)') (c(j,ires),j=1,3)
endif
endif !atom
! Calculate dummy residue coordinates inside the "chain" of a multichain
! system
nres=ires
- if (ires_old.ne.ires) nres_molec(molecule)=nres_molec(molecule)-2
-! print *,'I have', nres_molec(:)
+ if (((ires_old.ne.ires).and.(molecule.ne.5)) &
+ ) &
+ nres_molec(molecule)=nres_molec(molecule)-2
+ print *,'I have',nres, nres_molec(:)
do k=1,4 ! ions are without dummy
if (nres_molec(k).eq.0) cycle
! 16/01/2014 by Adasko: Adding to dummy atoms in the chain
! first is connected prevous chain (itype(i+1,1).eq.ntyp1)=true
! second dummy atom is conected to next chain itype(i+1,1).eq.ntyp1=false
- if (unres_pdb) then
+! if (unres_pdb) then
! 2/15/2013 by Adam: corrected insertion of the last dummy residue
! print *,i,'tu dochodze'
- call refsys(i-3,i-2,i-1,e1,e2,e3,fail)
- if (fail) then
- e2(1)=0.0d0
- e2(2)=1.0d0
- e2(3)=0.0d0
- endif !fail
+! call refsys(i-3,i-2,i-1,e1,e2,e3,fail)
+! if (fail) then
+! e2(1)=0.0d0
+! e2(2)=1.0d0
+! e2(3)=0.0d0
+! endif !fail
! print *,i,'a tu?'
- do j=1,3
- c(j,i)=c(j,i-1)-1.9d0*e2(j)
- enddo
- else !unres_pdb
+! do j=1,3
+! c(j,i)=c(j,i-1)-1.9d0*e2(j)
+! enddo
+! else !unres_pdb
do j=1,3
dcj=(c(j,i-2)-c(j,i-3))/2.0
if (dcj.eq.0) dcj=1.23591524223
c(j,i)=c(j,i-1)+dcj
c(j,nres+i)=c(j,i)
enddo
- endif !unres_pdb
+! endif !unres_pdb
else !itype(i+1,1).eq.ntyp1
- if (unres_pdb) then
+! if (unres_pdb) then
! 2/15/2013 by Adam: corrected insertion of the first dummy residue
- call refsys(i+1,i+2,i+3,e1,e2,e3,fail)
- if (fail) then
- e2(1)=0.0d0
- e2(2)=1.0d0
- e2(3)=0.0d0
- endif
+! call refsys(i+1,i+2,i+3,e1,e2,e3,fail)
+! if (fail) then
+! e2(1)=0.0d0
+! e2(2)=1.0d0
+! e2(3)=0.0d0
+! endif
do j=1,3
c(j,i)=c(j,i+1)-1.9d0*e2(j)
enddo
- else !unres_pdb
+! else !unres_pdb
do j=1,3
dcj=(c(j,i+3)-c(j,i+2))/2.0
if (dcj.eq.0) dcj=1.23591524223
c(j,i)=c(j,i+1)-dcj
c(j,nres+i)=c(j,i)
enddo
- endif !unres_pdb
+! endif !unres_pdb
endif !itype(i+1,1).eq.ntyp1
endif !itype.eq.ntyp1
if (molecule.eq.5) molecule=molecprev
itype(nres,molecule)=ntyp1_molec(molecule)
nres_molec(molecule)=nres_molec(molecule)+1
- if (unres_pdb) then
+! if (unres_pdb) then
! 2/15/2013 by Adam: corrected insertion of the last dummy residue
- call refsys(nres-3,nres-2,nres-1,e1,e2,e3,fail)
- if (fail) then
- e2(1)=0.0d0
- e2(2)=1.0d0
- e2(3)=0.0d0
- endif
- do j=1,3
- c(j,nres)=c(j,nres-1)-1.9d0*e2(j)
- enddo
- else
+! call refsys(nres-3,nres-2,nres-1,e1,e2,e3,fail)
+! if (fail) then
+! e2(1)=0.0d0
+! e2(2)=1.0d0
+! e2(3)=0.0d0
+! endif
+! do j=1,3
+! c(j,nres)=c(j,nres-1)-1.9d0*e2(j)
+! enddo
+! else
do j=1,3
dcj=(c(j,nres-2)-c(j,nres-3))/2.0
c(j,nres)=c(j,nres-1)+dcj
c(j,2*nres)=c(j,nres)
enddo
- endif
+! endif
endif
! print *,'I have',nres, nres_molec(:)
if (lprn) then
write (iout,'(/a)') &
"Cartesian coordinates of the reference structure"
- write (iout,'(a,3(3x,a5),5x,3(3x,a5))') &
+ write (iout,'(a,16x,3(3x,a5),5x,3(3x,a5))') &
"Residue","X(CA)","Y(CA)","Z(CA)","X(SC)","Y(SC)","Z(SC)"
do ires=1,nres
- write (iout,'(5(a3,1x),i3,3f8.3,5x,3f8.3)') &
+ write (iout,'(5(a3,1x),i5,3f8.3,5x,3f8.3)') &
(restyp(itype(ires,j),j),j=1,5),ires,(c(j,ires),j=1,3),&
(c(j,ires+nres),j=1,3)
enddo
write (iout,'(a)') &
"Backbone and SC coordinates as read from the PDB"
do ires=1,nres
- write (iout,'(2i3,2x,a,3f8.3,5x,3f8.3)') &
+ write (iout,'(i5,i3,2x,a,3f8.3,5x,3f8.3)') &
ires,itype(ires,1),restyp(itype(ires,1),1),(c(j,ires),j=1,3),&
(c(j,nres+ires),j=1,3)
enddo
! NOW LETS ROCK! SORTING
allocate(c_temporary(3,2*nres))
allocate(itype_temporary(nres,5))
- allocate(molnum(nres))
+ if (.not.allocated(molnum)) allocate(molnum(nres+1))
+ if (.not.allocated(istype)) write(iout,*) &
+ "SOMETHING WRONG WITH ISTYTPE"
allocate(istype_temp(nres))
itype_temporary(:,:)=0
seqalingbegin=1
enddo
itype_temporary(seqalingbegin,k)=itype(i,k)
+ print *,i,k,itype(i,k),itype_temporary(seqalingbegin,k),seqalingbegin
istype_temp(seqalingbegin)=istype(i)
molnum(seqalingbegin)=k
seqalingbegin=seqalingbegin+1
istype(i)=istype_temp(i)
enddo
enddo
- if (itype(1,1).eq.ntyp1) then
- nsup=nsup-1
- nstart_sup=2
- if (unres_pdb) then
+! if (itype(1,1).eq.ntyp1) then
+! nsup=nsup-1
+! nstart_sup=2
+! if (unres_pdb) then
! 2/15/2013 by Adam: corrected insertion of the first dummy residue
- call refsys(2,3,4,e1,e2,e3,fail)
- if (fail) then
- e2(1)=0.0d0
- e2(2)=1.0d0
- e2(3)=0.0d0
- endif
- do j=1,3
- c(j,1)=c(j,2)-1.9d0*e2(j)
- enddo
- else
- do j=1,3
- dcj=(c(j,4)-c(j,3))/2.0
- c(j,1)=c(j,2)-dcj
- c(j,nres+1)=c(j,1)
- enddo
- endif
- endif
+! call refsys(2,3,4,e1,e2,e3,fail)
+! if (fail) then
+! e2(1)=0.0d0
+! e2(2)=1.0d0
+! e2(3)=0.0d0
+! endif
+! do j=1,3
+! c(j,1)=c(j,2)-1.9d0*e2(j)
+! enddo
+! else
+! do j=1,3
+! dcj=(c(j,4)-c(j,3))/2.0
+! c(j,1)=c(j,2)-dcj
+! c(j,nres+1)=c(j,1)
+! enddo
+! endif
+! endif
if (lprn) then
write (iout,'(/a)') &
"Cartesian coordinates of the reference structure after sorting"
- write (iout,'(a,3(3x,a5),5x,3(3x,a5))') &
+ write (iout,'(a,16x,3(3x,a5),5x,3(3x,a5))') &
"Residue","X(CA)","Y(CA)","Z(CA)","X(SC)","Y(SC)","Z(SC)"
do ires=1,nres
- write (iout,'(5(a3,1x),i3,3f8.3,5x,3f8.3)') &
+ write (iout,'(5(a3,1x),i5,3f8.3,5x,3f8.3)') &
(restyp(itype(ires,j),j),j=1,5),ires,(c(j,ires),j=1,3),&
(c(j,ires+nres),j=1,3)
enddo
write (iout,*) "symetr", symetr
do i=1,nres
lll=lll+1
-!c write (iout,*) "spraw lancuchy",(c(j,i),j=1,3)
+! write (iout,*) "spraw lancuchy",(c(j,i),j=1,3)
if (i.gt.1) then
if ((itype(i-1,1).eq.ntyp1).and.(i.gt.2)) then
chain_length=lll-1
! write (iout,*) "spraw lancuchy",chain_length,symetr
! do i=1,4
! do kkk=1,chain_length
-! write (iout,*) itype(kkk),(chain_rep(j,kkk,i), j=1,3)
+! write (iout,*) itype(kkk,1),(chain_rep(j,kkk,i), j=1,3)
! enddo
! enddo
! enddiagnostic
cou=0
do kkk=1,symetr
icha=tabperm(i,kkk)
-! write (iout,*) i,icha
+ write (iout,*) i,icha
do lll=1,chain_length
cou=cou+1
if (cou.le.nres) then
kupa=mod(lll,chain_length)
iprzes=(kkk-1)*chain_length+lll
if (kupa.eq.0) kupa=chain_length
-! write (iout,*) "kupa", kupa
+ write (iout,*) "kupa", kupa
cref(j,iprzes,i)=chain_rep(j,kupa,icha)
cref(j,iprzes+nres,i)=chain_rep(j,kupa+nres,icha)
enddo
cref(3,i,kkk),cref(1,nres+i,kkk),&
cref(2,nres+i,kkk),cref(3,nres+i,kkk)
enddo
- 100 format (//' alpha-carbon coordinates ',&
+ 100 format (//' alpha-carbon coordinates ',&
' centroid coordinates'/ &
' ', 6X,'X',11X,'Y',11X,'Z', &
10X,'X',11X,'Y',11X,'Z')
- 110 format (a,'(',i3,')',6f12.5)
+ 110 format (a,'(',i5,')',6f12.5)
enddo
!c enddiag
call reada(controlcard,'BOXY',boxysize,100.0d0)
call reada(controlcard,'BOXZ',boxzsize,100.0d0)
call readi(controlcard,'TUBEMOD',tubemode,0)
+ print *,"SCELE",scelemode
+ call readi(controlcard,"SCELEMODE",scelemode,0)
+ print *,"SCELE",scelemode
+
+! elemode = 0 is orignal UNRES electrostatics
+! elemode = 1 is "Momo" potentials in progress
+! elemode = 2 is in development EVALD
write (iout,*) TUBEmode,"TUBEMODE"
if (TUBEmode.gt.0) then
call reada(controlcard,"XTUBE",tubecenter(1),0.0d0)
! character(len=80) :: ucase
character(len=320) :: controlcard
!el local variables
- integer :: i
+ integer :: i,j
real(kind=8) :: eta
call card_concat(controlcard,.true.)
large = index(controlcard,"LARGE").gt.0
print_compon = index(controlcard,"PRINT_COMPON").gt.0
rattle = index(controlcard,"RATTLE").gt.0
+ preminim=(index(controlcard,'PREMINIM').gt.0)
+ write (iout,*) "PREMINIM ",preminim
+ dccart=(index(controlcard,'CART').gt.0)
+ if (preminim) call read_minim
! if performing umbrella sampling, fragments constrained are read from the fragment file
nset=0
if(usampl) then
if(me.eq.king.or..not.out1file) &
write(iout,'(a60,f10.5)')"Eta of the solvent in natural units:",&
eta
- gamp=scal_fric*(pstok(i)+rwat)*eta
- stdfp=dsqrt(2*Rb*t_bath/d_time)
- allocate(gamsc(ntyp1),stdfsc(ntyp1)) !(ntyp1)
+! allocate(gamp
+ do j=1,5 !types of molecules
+ gamp(j)=scal_fric*(pstok(j)+rwat)*eta
+ stdfp(j)=dsqrt(2*Rb*t_bath/d_time)
+ enddo
+ allocate(gamsc(ntyp1,5),stdfsc(ntyp1,5)) !(ntyp1)
+ do j=1,5 !types of molecules
do i=1,ntyp
- gamsc(i)=scal_fric*(restok(i,1)+rwat)*eta
- stdfsc(i)=dsqrt(2*Rb*t_bath/d_time)
+ gamsc(i,j)=scal_fric*(restok(i,j)+rwat)*eta
+ stdfsc(i,j)=dsqrt(2*Rb*t_bath/d_time)
enddo
+ enddo
+
if(me.eq.king.or..not.out1file)then
write (iout,'(/2a/)') &
"Radii of site types and friction coefficients and std's of",&
" stochastic forces of fully exposed sites"
- write (iout,'(a5,f5.2,2f10.5)')'p',pstok,gamp,stdfp*dsqrt(gamp)
+ write (iout,'(a5,f5.2,2f10.5)')'p',pstok,gamp(1),stdfp*dsqrt(gamp(1))
do i=1,ntyp
write (iout,'(a5,f5.2,2f10.5)') restyp(i,1),restok(i,1),&
- gamsc(i),stdfsc(i)*dsqrt(gamsc(i))
+ gamsc(i,1),stdfsc(i,1)*dsqrt(gamsc(i,1))
enddo
endif
else if (tbf) then
open (iliptranpar,file=liptranname,status='old',action='read')
call getenv_loc('TUBEPAR',tubename)
open (itube,file=tubename,status='old',action='read')
+ call getenv_loc('IONPAR',ionname)
+ open (iion,file=ionname,status='old',action='read')
! print *,"Processor",myrank," opened file ISIDEP"
! print *,"Processor",myrank," opened parameter files"
open (iliptranpar,file=liptranname,status='old')
call getenv_loc('TUBEPAR',tubename)
open (itube,file=tubename,status='old')
+ call getenv_loc('IONPAR',ionname)
+ open (iion,file=ionname,status='old')
#else
open(1,file=pref_orig(:ilen(pref_orig))//'.inp',status='old',&
readonly)
open (itordp_nucl,file=tordname_nucl,status='old',action='read')
call getenv_loc('SIDEPAR_NUCL',sidename_nucl)
open (isidep_nucl,file=sidename_nucl,status='old',action='read')
+ call getenv_loc('SIDEPAR_SCBASE',sidename_scbase)
+ open (isidep_scbase,file=sidename_scbase,status='old',action='read')
+ call getenv_loc('PEPPAR_PEPBASE',pepname_pepbase)
+ open (isidep_pepbase,file=pepname_pepbase,status='old',action='read')
+ call getenv_loc('SCPAR_PHOSPH',pepname_scpho)
+ open (isidep_scpho,file=pepname_scpho,status='old',action='read')
+ call getenv_loc('PEPPAR_PHOSPH',pepname_peppho)
+ open (isidep_peppho,file=pepname_peppho,status='old',action='read')
+
call getenv_loc('LIPTRANPAR',liptranname)
open (iliptranpar,file=liptranname,status='old',action='read')
call getenv_loc('TUBEPAR',tubename)
open (itube,file=tubename,status='old',action='read')
+ call getenv_loc('IONPAR',ionname)
+ open (iion,file=ionname,status='old',action='read')
#ifndef CRYST_SC
call getenv_loc('ROTPARPDB',rotname_pdb)