[ViewVC] Diff of: group/trunk/OOPSE-4/src/UseTheForce/doForces.F90

Comparing trunk/OOPSE-4/src/UseTheForce/doForces.F90 (file contents):
Revision 2301 by gezelter, Thu Sep 15 22:05:21 2005 UTC vs.
Revision 2411 by chrisfen, Wed Nov 2 21:01:21 2005 UTC

#	Line 45 \| Line 45
45
46		!! @author Charles F. Vardeman II
47		!! @author Matthew Meineke
48	<	!! @version $Id: doForces.F90,v 1.44 2005-09-15 22:05:17 gezelter Exp $, $Date: 2005-09-15 22:05:17 $, $Name: not supported by cvs2svn $, $Revision: 1.44 $
48	>	!! @version $Id: doForces.F90,v 1.67 2005-11-02 21:01:18 chrisfen Exp $, $Date: 2005-11-02 21:01:18 $, $Name: not supported by cvs2svn $, $Revision: 1.67 $
49
50
51		module doForces
#	Line 58 \| Line 58 \| module doForces
58		use lj
59		use sticky
60		use electrostatic_module
61	<	use reaction_field_module
62	<	use gb_pair
61	>	use gayberne
62		use shapes
63		use vector_class
64		use eam
#	Line 75 \| Line 74 \| module doForces
74		#include "UseTheForce/fSwitchingFunction.h"
75		#include "UseTheForce/fCutoffPolicy.h"
76		#include "UseTheForce/DarkSide/fInteractionMap.h"
77	+	#include "UseTheForce/DarkSide/fElectrostaticSummationMethod.h"
78
79
80		INTEGER, PARAMETER:: PREPAIR_LOOP = 1
#	Line 85 \| Line 85 \| module doForces
85		logical, save :: haveSaneForceField = .false.
86		logical, save :: haveInteractionHash = .false.
87		logical, save :: haveGtypeCutoffMap = .false.
88	+	logical, save :: haveDefaultCutoffs = .false.
89		logical, save :: haveRlist = .false.
90
91		logical, save :: FF_uses_DirectionalAtoms
92		logical, save :: FF_uses_Dipoles
93		logical, save :: FF_uses_GayBerne
94		logical, save :: FF_uses_EAM
94	–	logical, save :: FF_uses_RF
95
96		logical, save :: SIM_uses_DirectionalAtoms
97		logical, save :: SIM_uses_EAM
98	–	logical, save :: SIM_uses_RF
98		logical, save :: SIM_requires_postpair_calc
99		logical, save :: SIM_requires_prepair_calc
100		logical, save :: SIM_uses_PBC
101
102	<	integer, save :: corrMethod
102	>	integer, save :: electrostaticSummationMethod
103
104		public :: init_FF
105		public :: setDefaultCutoffs
#	Line 124 \| Line 123 \| module doForces
123		! Bit hash to determine pair-pair interactions.
124		integer, dimension(:,:), allocatable :: InteractionHash
125		real(kind=dp), dimension(:), allocatable :: atypeMaxCutoff
126	<	real(kind=dp), dimension(:), allocatable :: groupMaxCutoff
127	<	integer, dimension(:), allocatable :: groupToGtype
128	<	real(kind=dp), dimension(:), allocatable :: gtypeMaxCutoff
126	>	real(kind=dp), dimension(:), allocatable, target :: groupMaxCutoffRow
127	>	real(kind=dp), dimension(:), pointer :: groupMaxCutoffCol
128	>
129	>	integer, dimension(:), allocatable, target :: groupToGtypeRow
130	>	integer, dimension(:), pointer :: groupToGtypeCol => null()
131	>
132	>	real(kind=dp), dimension(:), allocatable,target :: gtypeMaxCutoffRow
133	>	real(kind=dp), dimension(:), pointer :: gtypeMaxCutoffCol
134		type ::gtypeCutoffs
135		real(kind=dp) :: rcut
136		real(kind=dp) :: rcutsq
#	Line 136 \| Line 140 \| module doForces
140
141		integer, save :: cutoffPolicy = TRADITIONAL_CUTOFF_POLICY
142		real(kind=dp),save :: defaultRcut, defaultRsw, defaultRlist
143	<	real(kind=dp),save :: rcuti
143	>	real(kind=dp),save :: listSkin
144
145		contains
146
#	Line 180 \| Line 184 \| contains
184
185		if (.not. allocated(InteractionHash)) then
186		allocate(InteractionHash(nAtypes,nAtypes))
187	+	else
188	+	deallocate(InteractionHash)
189	+	allocate(InteractionHash(nAtypes,nAtypes))
190		endif
191
192		if (.not. allocated(atypeMaxCutoff)) then
193		allocate(atypeMaxCutoff(nAtypes))
194	+	else
195	+	deallocate(atypeMaxCutoff)
196	+	allocate(atypeMaxCutoff(nAtypes))
197		endif
198
199		do i = 1, nAtypes
#	Line 260 \| Line 270 \| contains
270		logical :: GtypeFound
271
272		integer :: myStatus, nAtypes, i, j, istart, iend, jstart, jend
273	<	integer :: n_in_i, me_i, ia, g, atom1, nGroupTypes
273	>	integer :: n_in_i, me_i, ia, g, atom1, ja, n_in_j,me_j
274		integer :: nGroupsInRow
275	<	real(kind=dp):: thisSigma, bigSigma, thisRcut, tol, skin
275	>	integer :: nGroupsInCol
276	>	integer :: nGroupTypesRow,nGroupTypesCol
277	>	real(kind=dp):: thisSigma, bigSigma, thisRcut, tradRcut, tol, skin
278		real(kind=dp) :: biggestAtypeCutoff
279
280		stat = 0
#	Line 276 \| Line 288 \| contains
288		endif
289		#ifdef IS_MPI
290		nGroupsInRow = getNgroupsInRow(plan_group_row)
291	+	nGroupsInCol = getNgroupsInCol(plan_group_col)
292		#endif
293		nAtypes = getSize(atypes)
294		! Set all of the initial cutoffs to zero.
#	Line 291 \| Line 304 \| contains
304		call getElementProperty(atypes, i, "is_Shape", i_is_Shape)
305
306
307	<	if (i_is_LJ) then
308	<	thisRcut = getSigma(i) * 2.5_dp
309	<	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
310	<	endif
311	<	if (i_is_Elect) then
312	<	thisRcut = defaultRcut
313	<	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
314	<	endif
315	<	if (i_is_Sticky) then
316	<	thisRcut = getStickyCut(i)
317	<	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
307	>	if (haveDefaultCutoffs) then
308	>	atypeMaxCutoff(i) = defaultRcut
309	>	else
310	>	if (i_is_LJ) then
311	>	thisRcut = getSigma(i) * 2.5_dp
312	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
313	>	endif
314	>	if (i_is_Elect) then
315	>	thisRcut = defaultRcut
316	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
317	>	endif
318	>	if (i_is_Sticky) then
319	>	thisRcut = getStickyCut(i)
320	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
321	>	endif
322	>	if (i_is_StickyP) then
323	>	thisRcut = getStickyPowerCut(i)
324	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
325	>	endif
326	>	if (i_is_GB) then
327	>	thisRcut = getGayBerneCut(i)
328	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
329	>	endif
330	>	if (i_is_EAM) then
331	>	thisRcut = getEAMCut(i)
332	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
333	>	endif
334	>	if (i_is_Shape) then
335	>	thisRcut = getShapeCut(i)
336	>	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
337	>	endif
338		endif
306	–	if (i_is_StickyP) then
307	–	thisRcut = getStickyPowerCut(i)
308	–	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
309	–	endif
310	–	if (i_is_GB) then
311	–	thisRcut = getGayBerneCut(i)
312	–	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
313	–	endif
314	–	if (i_is_EAM) then
315	–	thisRcut = getEAMCut(i)
316	–	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
317	–	endif
318	–	if (i_is_Shape) then
319	–	thisRcut = getShapeCut(i)
320	–	if (thisRCut .gt. atypeMaxCutoff(i)) atypeMaxCutoff(i) = thisRCut
321	–	endif
339
340	+
341		if (atypeMaxCutoff(i).gt.biggestAtypeCutoff) then
342		biggestAtypeCutoff = atypeMaxCutoff(i)
343		endif
344	+
345		endif
346		enddo
347
348	<	nGroupTypes = 0
348	>
349
350		istart = 1
351	+	jstart = 1
352		#ifdef IS_MPI
353		iend = nGroupsInRow
354	+	jend = nGroupsInCol
355		#else
356		iend = nGroups
357	+	jend = nGroups
358		#endif
359
360		!! allocate the groupToGtype and gtypeMaxCutoff here.
361	<	if(.not.allocated(groupToGtype)) then
362	<	allocate(groupToGtype(iend))
363	<	allocate(groupMaxCutoff(iend))
364	<	allocate(gtypeMaxCutoff(iend))
365	<	groupMaxCutoff = 0.0_dp
366	<	gtypeMaxCutoff = 0.0_dp
361	>	if(.not.allocated(groupToGtypeRow)) then
362	>	! allocate(groupToGtype(iend))
363	>	allocate(groupToGtypeRow(iend))
364	>	else
365	>	deallocate(groupToGtypeRow)
366	>	allocate(groupToGtypeRow(iend))
367		endif
368	+	if(.not.allocated(groupMaxCutoffRow)) then
369	+	allocate(groupMaxCutoffRow(iend))
370	+	else
371	+	deallocate(groupMaxCutoffRow)
372	+	allocate(groupMaxCutoffRow(iend))
373	+	end if
374	+
375	+	if(.not.allocated(gtypeMaxCutoffRow)) then
376	+	allocate(gtypeMaxCutoffRow(iend))
377	+	else
378	+	deallocate(gtypeMaxCutoffRow)
379	+	allocate(gtypeMaxCutoffRow(iend))
380	+	endif
381	+
382	+
383	+	#ifdef IS_MPI
384	+	! We only allocate new storage if we are in MPI because Ncol /= Nrow
385	+	if(.not.associated(groupToGtypeCol)) then
386	+	allocate(groupToGtypeCol(jend))
387	+	else
388	+	deallocate(groupToGtypeCol)
389	+	allocate(groupToGtypeCol(jend))
390	+	end if
391	+
392	+	if(.not.associated(groupToGtypeCol)) then
393	+	allocate(groupToGtypeCol(jend))
394	+	else
395	+	deallocate(groupToGtypeCol)
396	+	allocate(groupToGtypeCol(jend))
397	+	end if
398	+	if(.not.associated(gtypeMaxCutoffCol)) then
399	+	allocate(gtypeMaxCutoffCol(jend))
400	+	else
401	+	deallocate(gtypeMaxCutoffCol)
402	+	allocate(gtypeMaxCutoffCol(jend))
403	+	end if
404	+
405	+	groupMaxCutoffCol = 0.0_dp
406	+	gtypeMaxCutoffCol = 0.0_dp
407	+
408	+	#endif
409	+	groupMaxCutoffRow = 0.0_dp
410	+	gtypeMaxCutoffRow = 0.0_dp
411	+
412	+
413		!! first we do a single loop over the cutoff groups to find the
414		!! largest cutoff for any atypes present in this group. We also
415		!! create gtypes at this point.
416
417		tol = 1.0d-6
418	<
418	>	nGroupTypesRow = 0
419	>
420		do i = istart, iend
421		n_in_i = groupStartRow(i+1) - groupStartRow(i)
422	<	groupMaxCutoff(i) = 0.0_dp
422	>	groupMaxCutoffRow(i) = 0.0_dp
423		do ia = groupStartRow(i), groupStartRow(i+1)-1
424		atom1 = groupListRow(ia)
425		#ifdef IS_MPI
#	Line 359 \| Line 427 \| contains
427		#else
428		me_i = atid(atom1)
429		#endif
430	<	if (atypeMaxCutoff(me_i).gt.groupMaxCutoff(i)) then
431	<	groupMaxCutoff(i)=atypeMaxCutoff(me_i)
430	>	if (atypeMaxCutoff(me_i).gt.groupMaxCutoffRow(i)) then
431	>	groupMaxCutoffRow(i)=atypeMaxCutoff(me_i)
432		endif
433		enddo
434
435	<	if (nGroupTypes.eq.0) then
436	<	nGroupTypes = nGroupTypes + 1
437	<	gtypeMaxCutoff(nGroupTypes) = groupMaxCutoff(i)
438	<	groupToGtype(i) = nGroupTypes
435	>	if (nGroupTypesRow.eq.0) then
436	>	nGroupTypesRow = nGroupTypesRow + 1
437	>	gtypeMaxCutoffRow(nGroupTypesRow) = groupMaxCutoffRow(i)
438	>	groupToGtypeRow(i) = nGroupTypesRow
439		else
440		GtypeFound = .false.
441	<	do g = 1, nGroupTypes
442	<	if ( abs(groupMaxCutoff(i) - gtypeMaxCutoff(g)).lt.tol) then
443	<	groupToGtype(i) = g
441	>	do g = 1, nGroupTypesRow
442	>	if ( abs(groupMaxCutoffRow(i) - gtypeMaxCutoffRow(g)).lt.tol) then
443	>	groupToGtypeRow(i) = g
444		GtypeFound = .true.
445		endif
446		enddo
447		if (.not.GtypeFound) then
448	<	nGroupTypes = nGroupTypes + 1
449	<	gtypeMaxCutoff(nGroupTypes) = groupMaxCutoff(i)
450	<	groupToGtype(i) = nGroupTypes
448	>	nGroupTypesRow = nGroupTypesRow + 1
449	>	gtypeMaxCutoffRow(nGroupTypesRow) = groupMaxCutoffRow(i)
450	>	groupToGtypeRow(i) = nGroupTypesRow
451	>	endif
452	>	endif
453	>	enddo
454	>
455	>	#ifdef IS_MPI
456	>	do j = jstart, jend
457	>	n_in_j = groupStartCol(j+1) - groupStartCol(j)
458	>	groupMaxCutoffCol(j) = 0.0_dp
459	>	do ja = groupStartCol(j), groupStartCol(j+1)-1
460	>	atom1 = groupListCol(ja)
461	>
462	>	me_j = atid_col(atom1)
463	>
464	>	if (atypeMaxCutoff(me_j).gt.groupMaxCutoffCol(j)) then
465	>	groupMaxCutoffCol(j)=atypeMaxCutoff(me_j)
466	>	endif
467	>	enddo
468	>
469	>	if (nGroupTypesCol.eq.0) then
470	>	nGroupTypesCol = nGroupTypesCol + 1
471	>	gtypeMaxCutoffCol(nGroupTypesCol) = groupMaxCutoffCol(j)
472	>	groupToGtypeCol(j) = nGroupTypesCol
473	>	else
474	>	GtypeFound = .false.
475	>	do g = 1, nGroupTypesCol
476	>	if ( abs(groupMaxCutoffCol(j) - gtypeMaxCutoffCol(g)).lt.tol) then
477	>	groupToGtypeCol(j) = g
478	>	GtypeFound = .true.
479	>	endif
480	>	enddo
481	>	if (.not.GtypeFound) then
482	>	nGroupTypesCol = nGroupTypesCol + 1
483	>	gtypeMaxCutoffCol(nGroupTypesCol) = groupMaxCutoffCol(j)
484	>	groupToGtypeCol(j) = nGroupTypesCol
485		endif
486		endif
487		enddo
488
489	+	#else
490	+	! Set pointers to information we just found
491	+	nGroupTypesCol = nGroupTypesRow
492	+	groupToGtypeCol => groupToGtypeRow
493	+	gtypeMaxCutoffCol => gtypeMaxCutoffRow
494	+	groupMaxCutoffCol => groupMaxCutoffRow
495	+	#endif
496	+
497	+
498	+
499	+
500	+
501		!! allocate the gtypeCutoffMap here.
502	<	allocate(gtypeCutoffMap(nGroupTypes,nGroupTypes))
502	>	allocate(gtypeCutoffMap(nGroupTypesRow,nGroupTypesCol))
503		!! then we do a double loop over all the group TYPES to find the cutoff
504		!! map between groups of two types
505	<
506	<	do i = 1, nGroupTypes
507	<	do j = 1, nGroupTypes
505	>	tradRcut = max(maxval(gtypeMaxCutoffRow),maxval(gtypeMaxCutoffCol))
506	>
507	>	do i = 1, nGroupTypesRow
508	>	do j = 1, nGroupTypesCol
509
510		select case(cutoffPolicy)
511		case(TRADITIONAL_CUTOFF_POLICY)
512	<	thisRcut = maxval(gtypeMaxCutoff)
512	>	thisRcut = tradRcut
513		case(MIX_CUTOFF_POLICY)
514	<	thisRcut = 0.5_dp * (gtypeMaxCutoff(i) + gtypeMaxCutoff(j))
514	>	thisRcut = 0.5_dp * (gtypeMaxCutoffRow(i) + gtypeMaxCutoffCol(j))
515		case(MAX_CUTOFF_POLICY)
516	<	thisRcut = max(gtypeMaxCutoff(i), gtypeMaxCutoff(j))
516	>	thisRcut = max(gtypeMaxCutoffRow(i), gtypeMaxCutoffCol(j))
517		case default
518		call handleError("createGtypeCutoffMap", "Unknown Cutoff Policy")
519		return
#	Line 406 \| Line 521 \| contains
521		gtypeCutoffMap(i,j)%rcut = thisRcut
522		gtypeCutoffMap(i,j)%rcutsq = thisRcut*thisRcut
523		skin = defaultRlist - defaultRcut
524	+	listSkin = skin ! set neighbor list skin thickness
525		gtypeCutoffMap(i,j)%rlistsq = (thisRcut + skin)**2
526
527	+	! sanity check
528	+
529	+	if (haveDefaultCutoffs) then
530	+	if (abs(gtypeCutoffMap(i,j)%rcut - defaultRcut).gt.0.0001) then
531	+	call handleError("createGtypeCutoffMap", "user-specified rCut does not match computed group Cutoff")
532	+	endif
533	+	endif
534		enddo
535		enddo
536	+	if(allocated(gtypeMaxCutoffRow)) deallocate(gtypeMaxCutoffRow)
537	+	if(allocated(groupMaxCutoffRow)) deallocate(groupMaxCutoffRow)
538	+	if(allocated(atypeMaxCutoff)) deallocate(atypeMaxCutoff)
539	+	#ifdef IS_MPI
540	+	if(associated(groupMaxCutoffCol)) deallocate(groupMaxCutoffCol)
541	+	if(associated(gtypeMaxCutoffCol)) deallocate(gtypeMaxCutoffCol)
542	+	#endif
543	+	groupMaxCutoffCol => null()
544	+	gtypeMaxCutoffCol => null()
545
546		haveGtypeCutoffMap = .true.
547		end subroutine createGtypeCutoffMap
#	Line 422 \| Line 554 \| contains
554		defaultRsw = defRsw
555		defaultRlist = defRlist
556		cutoffPolicy = cutPolicy
557	<	rcuti = 1.0_dp / defaultRcut
557	>
558	>	haveDefaultCutoffs = .true.
559		end subroutine setDefaultCutoffs
560
561		subroutine setCutoffPolicy(cutPolicy)
#	Line 439 \| Line 572 \| contains
572		SIM_requires_postpair_calc = SimRequiresPostpairCalc()
573		SIM_requires_prepair_calc = SimRequiresPrepairCalc()
574		SIM_uses_PBC = SimUsesPBC()
442	–	SIM_uses_RF = SimUsesRF()
575
576		haveSIMvariables = .true.
577
#	Line 506 \| Line 638 \| contains
638		end subroutine doReadyCheck
639
640
641	<	subroutine init_FF(use_RF, correctionMethod, dampingAlpha, thisStat)
641	>	subroutine init_FF(thisESM, thisStat)
642
643	<	logical, intent(in) :: use_RF
512	<	integer, intent(in) :: correctionMethod
513	<	real(kind=dp), intent(in) :: dampingAlpha
643	>	integer, intent(in) :: thisESM
644		integer, intent(out) :: thisStat
645		integer :: my_status, nMatches
646		integer, pointer :: MatchList(:) => null()
517	–	real(kind=dp) :: rcut, rrf, rt, dielect
647
648		!! assume things are copacetic, unless they aren't
649		thisStat = 0
650
651	<	!! Fortran's version of a cast:
523	<	FF_uses_RF = use_RF
651	>	electrostaticSummationMethod = thisESM
652
525	–
653		!! init_FF is called after all of the atom types have been
654		!! defined in atype_module using the new_atype subroutine.
655		!!
#	Line 552 \| Line 679 \| contains
679
680		haveSaneForceField = .true.
681
555	–	!! check to make sure the FF_uses_RF setting makes sense
556	–
557	–	if (FF_uses_Dipoles) then
558	–	if (FF_uses_RF) then
559	–	dielect = getDielect()
560	–	call initialize_rf(dielect)
561	–	endif
562	–	else
563	–	if ((corrMethod == 3) .or. FF_uses_RF) then
564	–	write(default_error,*) 'Using Reaction Field with no dipoles? Huh?'
565	–	thisStat = -1
566	–	haveSaneForceField = .false.
567	–	return
568	–	endif
569	–	endif
570	–
682		if (FF_uses_EAM) then
683		call init_EAM_FF(my_status)
684		if (my_status /= 0) then
#	Line 576 \| Line 687 \| contains
687		haveSaneForceField = .false.
688		return
689		end if
579	–	endif
580	–
581	–	if (FF_uses_GayBerne) then
582	–	call check_gb_pair_FF(my_status)
583	–	if (my_status .ne. 0) then
584	–	thisStat = -1
585	–	haveSaneForceField = .false.
586	–	return
587	–	endif
690		endif
691
692		if (.not. haveNeighborList) then
#	Line 620 \| Line 722 \| contains
722
723		!! Stress Tensor
724		real( kind = dp), dimension(9) :: tau
725	<	real ( kind = dp ) :: pot
725	>	real ( kind = dp ),dimension(LR_POT_TYPES) :: pot
726		logical ( kind = 2) :: do_pot_c, do_stress_c
727		logical :: do_pot
728		logical :: do_stress
729		logical :: in_switching_region
730		#ifdef IS_MPI
731	<	real( kind = DP ) :: pot_local
731	>	real( kind = DP ), dimension(LR_POT_TYPES) :: pot_local
732		integer :: nAtomsInRow
733		integer :: nAtomsInCol
734		integer :: nprocs
#	Line 641 \| Line 743 \| contains
743		integer :: nlist
744		real( kind = DP ) :: ratmsq, rgrpsq, rgrp, vpair, vij
745		real( kind = DP ) :: sw, dswdr, swderiv, mf
746	+	real( kind = DP ) :: rVal
747		real(kind=dp),dimension(3) :: d_atm, d_grp, fpair, fij
748		real(kind=dp) :: rfpot, mu_i, virial
749		integer :: me_i, me_j, n_in_i, n_in_j
#	Line 651 \| Line 754 \| contains
754		integer :: propPack_i, propPack_j
755		integer :: loopStart, loopEnd, loop
756		integer :: iHash
757	<	real(kind=dp) :: listSkin = 1.0
757	>	integer :: i1
758	>
759
760		!! initialize local variables
761
#	Line 776 \| Line 880 \| contains
880		me_j = atid(j)
881		call get_interatomic_vector(q_group(:,i), &
882		q_group(:,j), d_grp, rgrpsq)
883	<	#endif
883	>	#endif
884
885	<	if (rgrpsq < gtypeCutoffMap(groupToGtype(i),groupToGtype(j))%rListsq) then
885	>	if (rgrpsq < gtypeCutoffMap(groupToGtypeRow(i),groupToGtypeCol(j))%rListsq) then
886		if (update_nlist) then
887		nlist = nlist + 1
888
#	Line 798 \| Line 902 \| contains
902
903		list(nlist) = j
904		endif
905	+
906	+	if (rgrpsq < gtypeCutoffMap(groupToGtypeRow(i),groupToGtypeCol(j))%rCutsq) then
907
908	<	if (loop .eq. PAIR_LOOP) then
909	<	vij = 0.0d0
910	<	fij(1:3) = 0.0d0
911	<	endif
912	<
913	<	call get_switch(rgrpsq, sw, dswdr, rgrp, group_switch, &
914	<	in_switching_region)
915	<
916	<	n_in_j = groupStartCol(j+1) - groupStartCol(j)
917	<
918	<	do ia = groupStartRow(i), groupStartRow(i+1)-1
919	<
920	<	atom1 = groupListRow(ia)
921	<
922	<	inner: do jb = groupStartCol(j), groupStartCol(j+1)-1
923	<
924	<	atom2 = groupListCol(jb)
925	<
926	<	if (skipThisPair(atom1, atom2)) cycle inner
927	<
928	<	if ((n_in_i .eq. 1).and.(n_in_j .eq. 1)) then
929	<	d_atm(1:3) = d_grp(1:3)
930	<	ratmsq = rgrpsq
931	<	else
908	>	if (loop .eq. PAIR_LOOP) then
909	>	vij = 0.0d0
910	>	fij(1:3) = 0.0d0
911	>	endif
912	>
913	>	call get_switch(rgrpsq, sw, dswdr, rgrp, group_switch, &
914	>	in_switching_region)
915	>
916	>	n_in_j = groupStartCol(j+1) - groupStartCol(j)
917	>
918	>	do ia = groupStartRow(i), groupStartRow(i+1)-1
919	>
920	>	atom1 = groupListRow(ia)
921	>
922	>	inner: do jb = groupStartCol(j), groupStartCol(j+1)-1
923	>
924	>	atom2 = groupListCol(jb)
925	>
926	>	if (skipThisPair(atom1, atom2)) cycle inner
927	>
928	>	if ((n_in_i .eq. 1).and.(n_in_j .eq. 1)) then
929	>	d_atm(1:3) = d_grp(1:3)
930	>	ratmsq = rgrpsq
931	>	else
932		#ifdef IS_MPI
933	<	call get_interatomic_vector(q_Row(:,atom1), &
934	<	q_Col(:,atom2), d_atm, ratmsq)
933	>	call get_interatomic_vector(q_Row(:,atom1), &
934	>	q_Col(:,atom2), d_atm, ratmsq)
935		#else
936	<	call get_interatomic_vector(q(:,atom1), &
937	<	q(:,atom2), d_atm, ratmsq)
936	>	call get_interatomic_vector(q(:,atom1), &
937	>	q(:,atom2), d_atm, ratmsq)
938		#endif
939	<	endif
940	<
941	<	if (loop .eq. PREPAIR_LOOP) then
939	>	endif
940	>
941	>	if (loop .eq. PREPAIR_LOOP) then
942		#ifdef IS_MPI
943	<	call do_prepair(atom1, atom2, ratmsq, d_atm, sw, &
944	<	rgrpsq, d_grp, do_pot, do_stress, &
945	<	eFrame, A, f, t, pot_local)
943	>	call do_prepair(atom1, atom2, ratmsq, d_atm, sw, &
944	>	rgrpsq, d_grp, do_pot, do_stress, &
945	>	eFrame, A, f, t, pot_local)
946		#else
947	<	call do_prepair(atom1, atom2, ratmsq, d_atm, sw, &
948	<	rgrpsq, d_grp, do_pot, do_stress, &
949	<	eFrame, A, f, t, pot)
947	>	call do_prepair(atom1, atom2, ratmsq, d_atm, sw, &
948	>	rgrpsq, d_grp, do_pot, do_stress, &
949	>	eFrame, A, f, t, pot)
950		#endif
951	<	else
951	>	else
952		#ifdef IS_MPI
953	<	call do_pair(atom1, atom2, ratmsq, d_atm, sw, &
954	<	do_pot, &
955	<	eFrame, A, f, t, pot_local, vpair, fpair)
953	>	call do_pair(atom1, atom2, ratmsq, d_atm, sw, &
954	>	do_pot, eFrame, A, f, t, pot_local, vpair, &
955	>	fpair, d_grp, rgrp)
956		#else
957	<	call do_pair(atom1, atom2, ratmsq, d_atm, sw, &
958	<	do_pot, &
959	<	eFrame, A, f, t, pot, vpair, fpair)
957	>	call do_pair(atom1, atom2, ratmsq, d_atm, sw, &
958	>	do_pot, eFrame, A, f, t, pot, vpair, fpair, &
959	>	d_grp, rgrp)
960		#endif
961	+	vij = vij + vpair
962	+	fij(1:3) = fij(1:3) + fpair(1:3)
963	+	endif
964	+	enddo inner
965	+	enddo
966
967	<	vij = vij + vpair
968	<	fij(1:3) = fij(1:3) + fpair(1:3)
969	<	endif
970	<	enddo inner
971	<	enddo
972	<
973	<	if (loop .eq. PAIR_LOOP) then
974	<	if (in_switching_region) then
975	<	swderiv = vij*dswdr/rgrp
976	<	fij(1) = fij(1) + swderiv*d_grp(1)
866	<	fij(2) = fij(2) + swderiv*d_grp(2)
867	<	fij(3) = fij(3) + swderiv*d_grp(3)
868	<
869	<	do ia=groupStartRow(i), groupStartRow(i+1)-1
870	<	atom1=groupListRow(ia)
871	<	mf = mfactRow(atom1)
967	>	if (loop .eq. PAIR_LOOP) then
968	>	if (in_switching_region) then
969	>	swderiv = vij*dswdr/rgrp
970	>	fij(1) = fij(1) + swderiv*d_grp(1)
971	>	fij(2) = fij(2) + swderiv*d_grp(2)
972	>	fij(3) = fij(3) + swderiv*d_grp(3)
973	>
974	>	do ia=groupStartRow(i), groupStartRow(i+1)-1
975	>	atom1=groupListRow(ia)
976	>	mf = mfactRow(atom1)
977		#ifdef IS_MPI
978	<	f_Row(1,atom1) = f_Row(1,atom1) + swderivd_grp(1)mf
979	<	f_Row(2,atom1) = f_Row(2,atom1) + swderivd_grp(2)mf
980	<	f_Row(3,atom1) = f_Row(3,atom1) + swderivd_grp(3)mf
978	>	f_Row(1,atom1) = f_Row(1,atom1) + swderivd_grp(1)mf
979	>	f_Row(2,atom1) = f_Row(2,atom1) + swderivd_grp(2)mf
980	>	f_Row(3,atom1) = f_Row(3,atom1) + swderivd_grp(3)mf
981		#else
982	<	f(1,atom1) = f(1,atom1) + swderivd_grp(1)mf
983	<	f(2,atom1) = f(2,atom1) + swderivd_grp(2)mf
984	<	f(3,atom1) = f(3,atom1) + swderivd_grp(3)mf
982	>	f(1,atom1) = f(1,atom1) + swderivd_grp(1)mf
983	>	f(2,atom1) = f(2,atom1) + swderivd_grp(2)mf
984	>	f(3,atom1) = f(3,atom1) + swderivd_grp(3)mf
985		#endif
986	<	enddo
987	<
988	<	do jb=groupStartCol(j), groupStartCol(j+1)-1
989	<	atom2=groupListCol(jb)
990	<	mf = mfactCol(atom2)
986	>	enddo
987	>
988	>	do jb=groupStartCol(j), groupStartCol(j+1)-1
989	>	atom2=groupListCol(jb)
990	>	mf = mfactCol(atom2)
991		#ifdef IS_MPI
992	<	f_Col(1,atom2) = f_Col(1,atom2) - swderivd_grp(1)mf
993	<	f_Col(2,atom2) = f_Col(2,atom2) - swderivd_grp(2)mf
994	<	f_Col(3,atom2) = f_Col(3,atom2) - swderivd_grp(3)mf
992	>	f_Col(1,atom2) = f_Col(1,atom2) - swderivd_grp(1)mf
993	>	f_Col(2,atom2) = f_Col(2,atom2) - swderivd_grp(2)mf
994	>	f_Col(3,atom2) = f_Col(3,atom2) - swderivd_grp(3)mf
995		#else
996	<	f(1,atom2) = f(1,atom2) - swderivd_grp(1)mf
997	<	f(2,atom2) = f(2,atom2) - swderivd_grp(2)mf
998	<	f(3,atom2) = f(3,atom2) - swderivd_grp(3)mf
996	>	f(1,atom2) = f(1,atom2) - swderivd_grp(1)mf
997	>	f(2,atom2) = f(2,atom2) - swderivd_grp(2)mf
998	>	f(3,atom2) = f(3,atom2) - swderivd_grp(3)mf
999		#endif
1000	<	enddo
1001	<	endif
1000	>	enddo
1001	>	endif
1002
1003	<	if (do_stress) call add_stress_tensor(d_grp, fij)
1003	>	if (do_stress) call add_stress_tensor(d_grp, fij)
1004	>	endif
1005		endif
1006	<	end if
1006	>	endif
1007		enddo
1008	+
1009		enddo outer
1010
1011		if (update_nlist) then
#	Line 958 \| Line 1065 \| contains
1065
1066		if (do_pot) then
1067		! scatter/gather pot_row into the members of my column
1068	<	call scatter(pot_Row, pot_Temp, plan_atom_row)
1069	<
1068	>	do i = 1,LR_POT_TYPES
1069	>	call scatter(pot_Row(i,:), pot_Temp(i,:), plan_atom_row)
1070	>	end do
1071		! scatter/gather pot_local into all other procs
1072		! add resultant to get total pot
1073		do i = 1, nlocal
1074	<	pot_local = pot_local + pot_Temp(i)
1074	>	pot_local(1:LR_POT_TYPES) = pot_local(1:LR_POT_TYPES) &
1075	>	+ pot_Temp(1:LR_POT_TYPES,i)
1076		enddo
1077
1078		pot_Temp = 0.0_DP
1079	<
1080	<	call scatter(pot_Col, pot_Temp, plan_atom_col)
1079	>	do i = 1,LR_POT_TYPES
1080	>	call scatter(pot_Col(i,:), pot_Temp(i,:), plan_atom_col)
1081	>	end do
1082		do i = 1, nlocal
1083	<	pot_local = pot_local + pot_Temp(i)
1083	>	pot_local(1:LR_POT_TYPES) = pot_local(1:LR_POT_TYPES)&
1084	>	+ pot_Temp(1:LR_POT_TYPES,i)
1085		enddo
1086
1087		endif
1088		#endif
1089
1090	<	if (FF_RequiresPostpairCalc() .and. SIM_requires_postpair_calc) then
1090	>	if (SIM_requires_postpair_calc) then
1091	>	do i = 1, nlocal
1092	>
1093	>	! we loop only over the local atoms, so we don't need row and column
1094	>	! lookups for the types
1095	>
1096	>	me_i = atid(i)
1097	>
1098	>	! is the atom electrostatic? See if it would have an
1099	>	! electrostatic interaction with itself
1100	>	iHash = InteractionHash(me_i,me_i)
1101
1102	<	if ((FF_uses_RF .and. SIM_uses_RF) .or. (corrMethod == 3)) then
982	<
1102	>	if ( iand(iHash, ELECTROSTATIC_PAIR).ne.0 ) then
1103		#ifdef IS_MPI
1104	<	call scatter(rf_Row,rf,plan_atom_row_3d)
1105	<	call scatter(rf_Col,rf_Temp,plan_atom_col_3d)
986	<	do i = 1,nlocal
987	<	rf(1:3,i) = rf(1:3,i) + rf_Temp(1:3,i)
988	<	end do
989	<	#endif
990	<
991	<	do i = 1, nLocal
992	<
993	<	rfpot = 0.0_DP
994	<	#ifdef IS_MPI
995	<	me_i = atid_row(i)
1104	>	call self_self(i, eFrame, pot_local(ELECTROSTATIC_POT), &
1105	>	t, do_pot)
1106		#else
1107	<	me_i = atid(i)
1107	>	call self_self(i, eFrame, pot(ELECTROSTATIC_POT), &
1108	>	t, do_pot)
1109		#endif
1110	<	iHash = InteractionHash(me_i,me_j)
1110	>	endif
1111	>
1112	>
1113	>	if (electrostaticSummationMethod.eq.REACTION_FIELD) then
1114
1115	<	if ( iand(iHash, ELECTROSTATIC_PAIR).ne.0 ) then
1116	<
1117	<	mu_i = getDipoleMoment(me_i)
1118	<
1119	<	!! The reaction field needs to include a self contribution
1120	<	!! to the field:
1121	<	call accumulate_self_rf(i, mu_i, eFrame)
1122	<	!! Get the reaction field contribution to the
1123	<	!! potential and torques:
1124	<	call reaction_field_final(i, mu_i, eFrame, rfpot, t, do_pot)
1115	>	! loop over the excludes to accumulate RF stuff we've
1116	>	! left out of the normal pair loop
1117	>
1118	>	do i1 = 1, nSkipsForAtom(i)
1119	>	j = skipsForAtom(i, i1)
1120	>
1121	>	! prevent overcounting of the skips
1122	>	if (i.lt.j) then
1123	>	call get_interatomic_vector(q(:,i), &
1124	>	q(:,j), d_atm, ratmsq)
1125	>	rVal = dsqrt(ratmsq)
1126	>	call get_switch(ratmsq, sw, dswdr, rVal, group_switch, &
1127	>	in_switching_region)
1128		#ifdef IS_MPI
1129	<	pot_local = pot_local + rfpot
1129	>	call rf_self_excludes(i, j, sw, eFrame, d_atm, rVal, &
1130	>	vpair, pot_local(ELECTROSTATIC_POT), f, t, do_pot)
1131		#else
1132	<	pot = pot + rfpot
1133	<
1132	>	call rf_self_excludes(i, j, sw, eFrame, d_atm, rVal, &
1133	>	vpair, pot(ELECTROSTATIC_POT), f, t, do_pot)
1134		#endif
1135	<	endif
1136	<	enddo
1137	<	endif
1135	>	endif
1136	>	enddo
1137	>	endif
1138	>	enddo
1139		endif
1140	<
1022	<
1140	>
1141		#ifdef IS_MPI
1142	<
1142	>
1143		if (do_pot) then
1144	<	pot = pot + pot_local
1145	<	!! we assume the c code will do the allreduce to get the total potential
1028	<	!! we could do it right here if we needed to...
1144	>	call mpi_allreduce(pot_local, pot, LR_POT_TYPES,mpi_double_precision,mpi_sum, &
1145	>	mpi_comm_world,mpi_err)
1146		endif
1147	<
1147	>
1148		if (do_stress) then
1149		call mpi_allreduce(tau_Temp, tau, 9,mpi_double_precision,mpi_sum, &
1150		mpi_comm_world,mpi_err)
1151		call mpi_allreduce(virial_Temp, virial,1,mpi_double_precision,mpi_sum, &
1152		mpi_comm_world,mpi_err)
1153		endif
1154	<
1154	>
1155		#else
1156	<
1156	>
1157		if (do_stress) then
1158		tau = tau_Temp
1159		virial = virial_Temp
1160		endif
1161	<
1161	>
1162		#endif
1163	<
1163	>
1164		end subroutine do_force_loop
1165
1166		subroutine do_pair(i, j, rijsq, d, sw, do_pot, &
1167	<	eFrame, A, f, t, pot, vpair, fpair)
1167	>	eFrame, A, f, t, pot, vpair, fpair, d_grp, r_grp)
1168
1169	<	real( kind = dp ) :: pot, vpair, sw
1169	>	real( kind = dp ) :: vpair, sw
1170	>	real( kind = dp ), dimension(LR_POT_TYPES) :: pot
1171		real( kind = dp ), dimension(3) :: fpair
1172		real( kind = dp ), dimension(nLocal) :: mfact
1173		real( kind = dp ), dimension(9,nLocal) :: eFrame
#	Line 1060 \| Line 1178 \| contains
1178		logical, intent(inout) :: do_pot
1179		integer, intent(in) :: i, j
1180		real ( kind = dp ), intent(inout) :: rijsq
1181	<	real ( kind = dp ) :: r
1181	>	real ( kind = dp ), intent(inout) :: r_grp
1182		real ( kind = dp ), intent(inout) :: d(3)
1183	+	real ( kind = dp ), intent(inout) :: d_grp(3)
1184	+	real ( kind = dp ) :: r
1185		integer :: me_i, me_j
1186
1187		integer :: iHash
#	Line 1079 \| Line 1199 \| contains
1199		#endif
1200
1201		iHash = InteractionHash(me_i, me_j)
1202	<
1202	>
1203		if ( iand(iHash, LJ_PAIR).ne.0 ) then
1204	<	call do_lj_pair(i, j, d, r, rijsq, sw, vpair, fpair, pot, f, do_pot)
1204	>	call do_lj_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1205	>	pot(VDW_POT), f, do_pot)
1206		endif
1207	<
1207	>
1208		if ( iand(iHash, ELECTROSTATIC_PAIR).ne.0 ) then
1209		call doElectrostaticPair(i, j, d, r, rijsq, sw, vpair, fpair, &
1210	<	pot, eFrame, f, t, do_pot, corrMethod, rcuti)
1090	<
1091	<	if ((FF_uses_RF .and. SIM_uses_RF) .or. (corrMethod == 3)) then
1092	<
1093	<	! CHECK ME (RF needs to know about all electrostatic types)
1094	<	call accumulate_rf(i, j, r, eFrame, sw)
1095	<	call rf_correct_forces(i, j, d, r, eFrame, sw, f, fpair)
1096	<	endif
1097	<
1210	>	pot(ELECTROSTATIC_POT), eFrame, f, t, do_pot)
1211		endif
1212	<
1212	>
1213		if ( iand(iHash, STICKY_PAIR).ne.0 ) then
1214		call do_sticky_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1215	<	pot, A, f, t, do_pot)
1215	>	pot(HB_POT), A, f, t, do_pot)
1216		endif
1217	<
1217	>
1218		if ( iand(iHash, STICKYPOWER_PAIR).ne.0 ) then
1219		call do_sticky_power_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1220	<	pot, A, f, t, do_pot)
1220	>	pot(HB_POT), A, f, t, do_pot)
1221		endif
1222	<
1222	>
1223		if ( iand(iHash, GAYBERNE_PAIR).ne.0 ) then
1224		call do_gb_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1225	<	pot, A, f, t, do_pot)
1225	>	pot(VDW_POT), A, f, t, do_pot)
1226		endif
1227
1228		if ( iand(iHash, GAYBERNE_LJ).ne.0 ) then
1229	<	! call do_gblj_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1230	<	! pot, A, f, t, do_pot)
1229	>	call do_gb_lj_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1230	>	pot(VDW_POT), A, f, t, do_pot)
1231		endif
1232	<
1232	>
1233		if ( iand(iHash, EAM_PAIR).ne.0 ) then
1234	<	call do_eam_pair(i, j, d, r, rijsq, sw, vpair, fpair, pot, f, &
1235	<	do_pot)
1234	>	call do_eam_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1235	>	pot(METALLIC_POT), f, do_pot)
1236		endif
1237	<
1237	>
1238		if ( iand(iHash, SHAPE_PAIR).ne.0 ) then
1239		call do_shape_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1240	<	pot, A, f, t, do_pot)
1240	>	pot(VDW_POT), A, f, t, do_pot)
1241		endif
1242	<
1242	>
1243		if ( iand(iHash, SHAPE_LJ).ne.0 ) then
1244		call do_shape_pair(i, j, d, r, rijsq, sw, vpair, fpair, &
1245	<	pot, A, f, t, do_pot)
1245	>	pot(VDW_POT), A, f, t, do_pot)
1246		endif
1247	<
1247	>
1248		end subroutine do_pair
1249
1250		subroutine do_prepair(i, j, rijsq, d, sw, rcijsq, dc, &
1251		do_pot, do_stress, eFrame, A, f, t, pot)
1252
1253	<	real( kind = dp ) :: pot, sw
1253	>	real( kind = dp ) :: sw
1254	>	real( kind = dp ), dimension(LR_POT_TYPES) :: pot
1255		real( kind = dp ), dimension(9,nLocal) :: eFrame
1256		real (kind=dp), dimension(9,nLocal) :: A
1257		real (kind=dp), dimension(3,nLocal) :: f
#	Line 1172 \| Line 1286 \| contains
1286
1287		subroutine do_preforce(nlocal,pot)
1288		integer :: nlocal
1289	<	real( kind = dp ) :: pot
1289	>	real( kind = dp ),dimension(LR_POT_TYPES) :: pot
1290
1291		if (FF_uses_EAM .and. SIM_uses_EAM) then
1292	<	call calc_EAM_preforce_Frho(nlocal,pot)
1292	>	call calc_EAM_preforce_Frho(nlocal,pot(METALLIC_POT))
1293		endif
1294
1295
#	Line 1260 \| Line 1374 \| contains
1374		pot_Row = 0.0_dp
1375		pot_Col = 0.0_dp
1376		pot_Temp = 0.0_dp
1263	–
1264	–	rf_Row = 0.0_dp
1265	–	rf_Col = 0.0_dp
1266	–	rf_Temp = 0.0_dp
1377
1378		#endif
1379
#	Line 1271 \| Line 1381 \| contains
1381		call clean_EAM()
1382		endif
1383
1274	–	rf = 0.0_dp
1384		tau_Temp = 0.0_dp
1385		virial_Temp = 0.0_dp
1386		end subroutine zero_work_arrays
#	Line 1368 \| Line 1477 \| contains
1477		doesit = FF_uses_EAM
1478		end function FF_RequiresPrepairCalc
1479
1371	–	function FF_RequiresPostpairCalc() result(doesit)
1372	–	logical :: doesit
1373	–	doesit = FF_uses_RF
1374	–	if (corrMethod == 3) doesit = .true.
1375	–	end function FF_RequiresPostpairCalc
1376	–
1480		#ifdef PROFILE
1481		function getforcetime() result(totalforcetime)
1482		real(kind=dp) :: totalforcetime

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Comparing trunk/OOPSE-4/src/UseTheForce/doForces.F90 (file contents): Revision 2301 by gezelter, Thu Sep 15 22:05:21 2005 UTC vs. Revision 2411 by chrisfen, Wed Nov 2 21:01:21 2005 UTC

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Comparing trunk/OOPSE-4/src/UseTheForce/doForces.F90 (file contents):
Revision 2301 by gezelter, Thu Sep 15 22:05:21 2005 UTC vs.
Revision 2411 by chrisfen, Wed Nov 2 21:01:21 2005 UTC