[ViewVC] Diff of: group/trunk/OOPSE_old/src/mdtools/libmdCode/do

Comparing trunk/OOPSE_old/src/mdtools/libmdCode/do_Forces.F90 (file contents):
Revision 298 by chuckv, Fri Mar 7 18:26:30 2003 UTC vs.
Revision 329 by gezelter, Wed Mar 12 22:27:59 2003 UTC

#	Line 1 \| Line 1
1	+	!! do_Forces.F90
2	+	!! module do_Forces
3		!! Calculates Long Range forces.
4	+
5		!! @author Charles F. Vardeman II
6		!! @author Matthew Meineke
7	<	!! @version $Id: do_Forces.F90,v 1.5 2003-03-07 18:26:30 chuckv Exp $, $Date: 2003-03-07 18:26:30 $, $Name: not supported by cvs2svn $, $Revision: 1.5 $
7	>	!! @version $Id: do_Forces.F90,v 1.15 2003-03-12 22:27:59 gezelter Exp $, $Date: 2003-03-12 22:27:59 $, $Name: not supported by cvs2svn $, $Revision: 1.15 $
8
9
10
11		module do_Forces
12		use simulation
13		use definitions
14	<	use forceGlobals
15	<	use atype_typedefs
13	<	use neighborLists
14	<
15	<
14	>	use atype_module
15	>	use neighborLists
16		use lj_FF
17		use sticky_FF
18	<	use dp_FF
18	>	use dipole_dipole
19		use gb_FF
20
21		#ifdef IS_MPI
#	Line 24 \| Line 24 \| public :: do_force_loop
24		implicit none
25		PRIVATE
26
27	<	public :: do_force_loop
27	>	logical, save :: do_forces_initialized = .false.
28	>	logical, save :: FF_uses_LJ
29	>	logical, save :: FF_uses_sticky
30	>	logical, save :: FF_uses_dipoles
31	>	logical, save :: FF_uses_RF
32	>	logical, save :: FF_uses_GB
33	>	logical, save :: FF_uses_EAM
34
29	–	contains
35
36	<	!! FORCE routine Calculates Lennard Jones forces.
37	<	!------------------------------------------------------------->
33	<	subroutine do_force_loop(q,A,mu,u_l,f,t,tau,potE,do_pot,FFerror)
34	<	!! Position array provided by C, dimensioned by getNlocal
35	<	real ( kind = dp ), dimension(3,getNlocal()) :: q
36	<	!! Rotation Matrix for each long range particle in simulation.
37	<	real( kind = dp), dimension(9,getNlocal()) :: A
36	>	public :: init_FF
37	>	public :: do_forces
38
39	<	!! Magnitude dipole moment
40	<	real( kind = dp ), dimension(3,getNlocal()) :: mu
41	<	!! Unit vectors for dipoles (lab frame)
42	<	real( kind = dp ), dimension(3,getNlocal()) :: u_l
43	<	!! Force array provided by C, dimensioned by getNlocal
44	<	real ( kind = dp ), dimension(3,getNlocal()) :: f
45	<	!! Torsion array provided by C, dimensioned by getNlocal
46	<	real( kind = dp ), dimension(3,getNlocal()) :: t
39	>	contains
40
41	<	!! Stress Tensor
42	<	real( kind = dp), dimension(9) :: tau
41	>	subroutine init_FF(thisStat)
42	>
43	>	integer, intent(out) :: my_status
44	>	integer :: thisStat = 0
45
46	<	real ( kind = dp ) :: potE
52	<	logical ( kind = 2) :: do_pot
53	<	integer :: FFerror
46	>	! be a smarter subroutine.
47
48
49	<	type(atype), pointer :: Atype_i
50	<	type(atype), pointer :: Atype_j
49	>	call init_lj_FF(my_status)
50	>	if (my_status /= 0) then
51	>	thisStat = -1
52	>	return
53	>	end if
54	>
55	>	call check_sticky_FF(my_status)
56	>	if (my_status /= 0) then
57	>	thisStat = -1
58	>	return
59	>	end if
60	>
61	>	do_forces_initialized = .true.
62	>
63	>	end subroutine init_FF
64
65
66
67	<
68	<
69	<
67	>	!! Does force loop over i,j pairs. Calls do_pair to calculates forces.
68	>	!------------------------------------------------------------->
69	>	subroutine do_force_loop(q, A, u_l, f, t, tau, pot, do_pot_c, do_stress_c, &
70	>	error)
71	>	!! Position array provided by C, dimensioned by getNlocal
72	>	real ( kind = dp ), dimension(3,getNlocal()) :: q
73	>	!! Rotation Matrix for each long range particle in simulation.
74	>	real( kind = dp), dimension(9,getNlocal()) :: A
75	>	!! Unit vectors for dipoles (lab frame)
76	>	real( kind = dp ), dimension(3,getNlocal()) :: u_l
77	>	!! Force array provided by C, dimensioned by getNlocal
78	>	real ( kind = dp ), dimension(3,getNlocal()) :: f
79	>	!! Torsion array provided by C, dimensioned by getNlocal
80	>	real( kind = dp ), dimension(3,getNlocal()) :: t
81	>	!! Stress Tensor
82	>	real( kind = dp), dimension(9) :: tau
83	>	real ( kind = dp ) :: pot
84	>	logical ( kind = 2) :: do_pot_c, do_stress_c
85	>	logical :: do_pot
86	>	logical :: do_stress
87		#ifdef IS_MPI
88	<	real( kind = DP ) :: pot_local
89	<
90	<	!! Local arrays needed for MPI
91	<
69	<	#endif
70	<
71	<
72	<
73	<	real( kind = DP ) :: pe
74	<	logical :: update_nlist
75	<
76	<
77	<	integer :: i, j, jbeg, jend, jnab, idim, jdim, idim2, jdim2, dim, dim2
78	<	integer :: nlist
79	<	integer :: j_start
80	<
81	<	real( kind = DP ) :: r_ij, pot, ftmp, dudr, d2, drdx1, kt1, kt2, kt3, ktmp
82	<
83	<	real( kind = DP ) :: rx_ij, ry_ij, rz_ij, rijsq
84	<	real( kind = DP ) :: rlistsq, rcutsq,rlist,rcut
85	<
86	<	real( kind = DP ) :: dielectric = 0.0_dp
87	<
88	<	! a rig that need to be fixed.
89	<	#ifdef IS_MPI
90	<	real( kind = dp ) :: pe_local
91	<	integer :: nlocal
88	>	real( kind = DP ) :: pot_local
89	>	integer :: nlocal
90	>	integer :: nrow
91	>	integer :: ncol
92		#endif
93	<	integer :: nrow
94	<	integer :: ncol
95	<	integer :: natoms
96	<	integer :: neighborListSize
97	<	integer :: listerror
98	<	!! should we calculate the stress tensor
99	<	logical :: do_stress = .false.
93	>	integer :: natoms
94	>	logical :: update_nlist
95	>	integer :: i, j, jbeg, jend, jnab
96	>	integer :: nlist
97	>	real( kind = DP ) :: rijsq, rlistsq, rcutsq, rlist, rcut
98	>	integer :: neighborListSize
99	>	integer :: listerror
100
101	+	!! initialize local variables
102
102	–	FFerror = 0
103	–
104	–	! Make sure we are properly initialized.
105	–	if (.not. isFFInit) then
106	–	write(default_error,*) "ERROR: lj_FF has not been properly initialized"
107	–	FFerror = -1
108	–	return
109	–	endif
103		#ifdef IS_MPI
104	<	if (.not. isMPISimSet()) then
105	<	write(default_error,*) "ERROR: mpiSimulation has not been properly initialized"
106	<	FFerror = -1
107	<	return
108	<	endif
104	>	nlocal = getNlocal()
105	>	nrow = getNrow(plan_row)
106	>	ncol = getNcol(plan_col)
107	>	#else
108	>	nlocal = getNlocal()
109	>	natoms = nlocal
110		#endif
111
112	<	!! initialize local variables
113	<	natoms = getNlocal()
114	<	call getRcut(rcut,rcut2=rcutsq)
115	<	call getRlist(rlist,rlistsq)
112	>	call getRcut(rcut,rcut2=rcutsq)
113	>	call getRlist(rlist,rlistsq)
114	>
115	>	call check_initialization()
116	>	call zero_work_arrays()
117
118	<	!! Find ensemble
119	<	if (isEnsemble("NPT")) do_stress = .true.
125	<	!! set to wrap
126	<	if (isPBC()) wrap = .true.
118	>	do_pot = do_pot_c
119	>	do_stress = do_stress_c
120
121	<
122	<
130	<
131	<	!! See if we need to update neighbor lists
132	<	call check(q,update_nlist)
133	<
134	<	!--------------WARNING...........................
135	<	! Zero variables, NOTE:::: Forces are zeroed in C
136	<	! Zeroing them here could delete previously computed
137	<	! Forces.
138	<	!------------------------------------------------
139	<	call zero_module_variables()
140	<
141	<
142	<	! communicate MPI positions
121	>	! Gather all information needed by all force loops:
122	>
123		#ifdef IS_MPI
144	–	call gather(q,qRow,plan_row3d)
145	–	call gather(q,qCol,plan_col3d)
124
125	<	call gather(mu,muRow,plan_row3d)
126	<	call gather(mu,muCol,plan_col3d)
127	<
128	<	call gather(u_l,u_lRow,plan_row3d)
129	<	call gather(u_l,u_lCol,plan_col3d)
130	<
131	<	call gather(A,ARow,plan_row_rotation)
132	<	call gather(A,ACol,plan_col_rotation)
125	>	call gather(q,q_Row,plan_row3d)
126	>	call gather(q,q_Col,plan_col3d)
127	>
128	>	if (FF_UsesDirectionalAtoms() .and. SimUsesDirectionalAtoms()) then
129	>	call gather(u_l,u_l_Row,plan_row3d)
130	>	call gather(u_l,u_l_Col,plan_col3d)
131	>
132	>	call gather(A,A_Row,plan_row_rotation)
133	>	call gather(A,A_Col,plan_col_rotation)
134	>	endif
135	>
136		#endif
137	<
138	<
137	>
138	>	if (FF_RequiresPrepairCalc() .and. SimRequiresPrepairCalc()) then
139	>	!! See if we need to update neighbor lists
140	>	call checkNeighborList(nlocal, q, rcut, rlist, update_nlist)
141	>	!! if_mpi_gather_stuff_for_prepair
142	>	!! do_prepair_loop_if_needed
143	>	!! if_mpi_scatter_stuff_from_prepair
144	>	!! if_mpi_gather_stuff_from_prepair_to_main_loop
145	>	else
146	>	!! See if we need to update neighbor lists
147	>	call checkNeighborList(nlocal, q, rcut, rlist, update_nlist)
148	>	endif
149	>
150		#ifdef IS_MPI
151
152		if (update_nlist) then
153
154	<	! save current configuration, contruct neighbor list,
155	<	! and calculate forces
154	>	!! save current configuration, construct neighbor list,
155	>	!! and calculate forces
156		call save_neighborList(q)
157
158		neighborListSize = getNeighborListSize()
159	<	nlist = 0
159	>	nlist = 0
160
169	–	nrow = getNrow(plan_row)
170	–	ncol = getNcol(plan_col)
171	–	nlocal = getNlocal()
172	–
161		do i = 1, nrow
162		point(i) = nlist + 1
175	–	Atype_i => identPtrListRow(i)%this
163
164		inner: do j = 1, ncol
178	–	Atype_j => identPtrListColumn(j)%this
165
166	<	call get_interatomic_vector(i,j,qRow(:,i),qCol(:,j),&
181	<	rxij,ryij,rzij,rijsq,r)
166	>	if (check_exclude(i,j)) cycle inner:
167
168	<	! skip the loop if the atoms are identical
169	<	if (mpi_cycle_jLoop(i,j)) cycle inner:
185	<
168	>	call get_interatomic_vector(q_Row(:,i), q_Col(:,j), d, rijsq)
169	>
170		if (rijsq < rlistsq) then
171
172		nlist = nlist + 1
173
174		if (nlist > neighborListSize) then
175	<	call expandList(listerror)
175	>	call expandNeighborList(nlocal, listerror)
176		if (listerror /= 0) then
177	<	FFerror = -1
177	>	error = -1
178		write(DEFAULT_ERROR,*) "ERROR: nlist > list size and max allocations exceeded."
179		return
180		end if
181		endif
182
183		list(nlist) = j
184	<
201	<
184	>
185		if (rijsq < rcutsq) then
186	<	call do_pair(Atype_i,Atype_j,i,j,r,rxij,ryij,rzij)
186	>	call do_pair(i, j, rijsq, d, do_pot, do_stress)
187		endif
188		endif
189		enddo inner
#	Line 208 \| Line 191 \| contains
191
192		point(nrow + 1) = nlist + 1
193
194	<	else !! (update)
194	>	else !! (of update_check)
195
196		! use the list to find the neighbors
197		do i = 1, nrow
#	Line 216 \| Line 199 \| contains
199		JEND = POINT(i+1) - 1
200		! check thiat molecule i has neighbors
201		if (jbeg .le. jend) then
202	<
220	<	Atype_i => identPtrListRow(i)%this
202	>
203		do jnab = jbeg, jend
204		j = list(jnab)
205	<	Atype_j = identPtrListColumn(j)%this
206	<	call get_interatomic_vector(i,j,qRow(:,i),qCol(:,j),&
207	<	rxij,ryij,rzij,rijsq,r)
208	<
227	<	call do_pair(Atype_i,Atype_j,i,j,r,rxij,ryij,rzij)
205	>
206	>	call get_interatomic_vector(q_Row(:,i), q_Col(:,j), d, rijsq)
207	>	call do_pair(i, j, rijsq, d, do_pot, do_stress)
208	>
209		enddo
210		endif
211		enddo
212		endif
213	<
213	>
214		#else
215
216		if (update_nlist) then
#	Line 241 \| Line 222 \| contains
222		neighborListSize = getNeighborListSize()
223		nlist = 0
224
244	–
225		do i = 1, natoms-1
226		point(i) = nlist + 1
227	<	Atype_i => identPtrList(i)%this
248	<
227	>
228		inner: do j = i+1, natoms
229	<	Atype_j => identPtrList(j)%this
230	<	call get_interatomic_vector(i,j,q(:,i),q(:,j),&
231	<	rxij,ryij,rzij,rijsq,r)
229	>
230	>	if (check_exclude(i,j)) cycle inner:
231	>
232	>	call get_interatomic_vector(q(:,i), q(:,j), d, rijsq)
233
234		if (rijsq < rlistsq) then
235	<
235	>
236		nlist = nlist + 1
237
238		if (nlist > neighborListSize) then
239	<	call expandList(listerror)
239	>	call expandList(natoms, listerror)
240		if (listerror /= 0) then
241	<	FFerror = -1
241	>	error = -1
242		write(DEFAULT_ERROR,*) "ERROR: nlist > list size and max allocations exceeded."
243		return
244		end if
245		endif
246
247		list(nlist) = j
248	<
269	<
248	>
249		if (rijsq < rcutsq) then
250	<	call do_pair(Atype_i,Atype_j,i,j,r,rxij,ryij,rzij)
250	>	call do_pair(i, j, rijsq, d, do_pot, do_stress)
251		endif
252		endif
253		enddo inner
#	Line 285 \| Line 264 \| contains
264		! check thiat molecule i has neighbors
265		if (jbeg .le. jend) then
266
288	–	Atype_i => identPtrList(i)%this
267		do jnab = jbeg, jend
268		j = list(jnab)
269	<	Atype_j = identPtrList(j)%this
270	<	call get_interatomic_vector(i,j,q(:,i),q(:,j),&
271	<	rxij,ryij,rzij,rijsq,r)
272	<	call do_pair(Atype_i,Atype_j,i,j,r,rxij,ryij,rzij)
269	>
270	>	call get_interatomic_vector(q(:,i), q(:,j), d, rijsq)
271	>	call do_pair(i, j, rijsq, d, do_pot, do_stress)
272	>
273		enddo
274		endif
275		enddo
276		endif
277	<
277	>
278		#endif
279	<
280	<
279	>
280	>	! phew, done with main loop.
281	>
282		#ifdef IS_MPI
304	–	!! distribute all reaction field stuff (or anything for post-pair):
305	–	call scatter(rflRow,rflTemp1,plan_row3d)
306	–	call scatter(rflCol,rflTemp2,plan_col3d)
307	–	do i = 1,nlocal
308	–	rflTemp(1:3,i) = rflTemp1(1:3,i) + rflTemp2(1:3,i)
309	–	end do
310	–	#endif
311	–
312	–	! This is the post-pair loop:
313	–	#ifdef IS_MPI
314	–
315	–	if (system_has_postpair_atoms) then
316	–	do i = 1, nlocal
317	–	Atype_i => identPtrListRow(i)%this
318	–	call do_postpair(i, Atype_i)
319	–	enddo
320	–	endif
321	–
322	–	#else
323	–
324	–	if (system_has_postpair_atoms) then
325	–	do i = 1, natoms
326	–	Atype_i => identPtr(i)%this
327	–	call do_postpair(i, Atype_i)
328	–	enddo
329	–	endif
330	–
331	–	#endif
332	–
333	–
334	–
335	–
336	–	#ifdef IS_MPI
283		!!distribute forces
284	<
285	<	call scatter(fRow,fTemp1,plan_row3d)
286	<	call scatter(fCol,fTemp2,plan_col3d)
341	<
342	<
284	>
285	>	call scatter(f_Row,f,plan_row3d)
286	>	call scatter(f_Col,f_temp,plan_col3d)
287		do i = 1,nlocal
288	<	fTemp(1:3,i) = fTemp1(1:3,i) + fTemp2(1:3,i)
288	>	f(1:3,i) = f(1:3,i) + f_temp(1:3,i)
289		end do
346	–
347	–	if (do_torque) then
348	–	call scatter(tRow,tTemp1,plan_row3d)
349	–	call scatter(tCol,tTemp2,plan_col3d)
290
291	+	if (FF_UsesDirectionalAtoms() .and. SimUsesDirectionalAtoms()) then
292	+	call scatter(t_Row,t,plan_row3d)
293	+	call scatter(t_Col,t_temp,plan_col3d)
294	+
295		do i = 1,nlocal
296	<	tTemp(1:3,i) = tTemp1(1:3,i) + tTemp2(1:3,i)
296	>	t(1:3,i) = t(1:3,i) + t_temp(1:3,i)
297		end do
298		endif
299	<
299	>
300		if (do_pot) then
301		! scatter/gather pot_row into the members of my column
302	<	call scatter(eRow,eTemp,plan_row)
302	>	call scatter(pot_Row, pot_Temp, plan_row)
303
304		! scatter/gather pot_local into all other procs
305		! add resultant to get total pot
306		do i = 1, nlocal
307	<	pe_local = pe_local + eTemp(i)
307	>	pot_local = pot_local + pot_Temp(i)
308		enddo
309
310	<	eTemp = 0.0E0_DP
311	<	call scatter(eCol,eTemp,plan_col)
310	>	pot_Temp = 0.0_DP
311	>
312	>	call scatter(pot_Col, pot_Temp, plan_col)
313		do i = 1, nlocal
314	<	pe_local = pe_local + eTemp(i)
314	>	pot_local = pot_local + pot_Temp(i)
315		enddo
316
372	–	pe = pe_local
317		endif
318	<	#else
319	<	! Copy local array into return array for c
320	<	f = f+fTemp
321	<	t = t+tTemp
318	>
319	>	if (FF_RequiresPostpairCalc() .and. SimRequiresPostpairCalc()) then
320	>
321	>	if (FF_uses_RF .and. SimUsesRF()) then
322	>
323	>	#ifdef IS_MPI
324	>	call scatter(rf_Row,rf,plan_row3d)
325	>	call scatter(rf_Col,rf_Temp,plan_col3d)
326	>	do i = 1,nlocal
327	>	rf(1:3,i) = rf(1:3,i) + rf_Temp(1:3,i)
328	>	end do
329		#endif
330	+
331	+	do i = 1, getNlocal()
332
380	–	potE = pe
381	–
382	–
383	–	if (do_stress) then
333		#ifdef IS_MPI
334	<	mpi_allreduce = (tau,tauTemp,9,mpi_double_precision,mpi_sum, &
386	<	mpi_comm_world,mpi_err)
334	>	me_i = atid_row(i)
335		#else
336	<	tau = tauTemp
337	<	#endif
336	>	me_i = atid(i)
337	>	#endif
338	>	call getElementProperty(atypes, me_i, "is_DP", is_DP_i)
339	>	if ( is_DP_i ) then
340	>	call getElementProperty(atypes, me_i, "dipole_moment", mu_i)
341	>	!! The reaction field needs to include a self contribution
342	>	!! to the field:
343	>	call accumulate_self_rf(i, mu_i, u_l)
344	>	!! Get the reaction field contribution to the
345	>	!! potential and torques:
346	>	call reaction_field(i, mu_i, u_l, rfpot, t, do_pot)
347	>	#ifdef IS_MPI
348	>	pot_local = pot_local + rfpot
349	>	#else
350	>	pot = pot + rfpot
351	>	#endif
352	>	endif
353	>	enddo
354	>	endif
355		endif
356
392	–	end subroutine do_force_loop
357
358	+	#ifdef IS_MPI
359
360	+	if (do_pot) then
361	+	pot = pot_local
362	+	!! we assume the c code will do the allreduce to get the total potential
363	+	!! we could do it right here if we needed to...
364	+	endif
365
366	+	if (do_stress) then
367	+	mpi_allreduce(tau, tau_Temp,9,mpi_double_precision,mpi_sum, &
368	+	mpi_comm_world,mpi_err)
369	+	mpi_allreduce(virial, virial_Temp,1,mpi_double_precision,mpi_sum, &
370	+	mpi_comm_world,mpi_err)
371	+	endif
372
373	+	#else
374
375	+	if (do_stress) then
376	+	tau = tau_Temp
377	+	virial = virial_Temp
378	+	endif
379
380	+	#endif
381	+
382	+	end subroutine do_force_loop
383
384
401	–
402	–
385		!! Calculate any pre-force loop components and update nlist if necessary.
386		subroutine do_preForce(updateNlist)
387		logical, intent(inout) :: updateNlist
#	Line 408 \| Line 390 \| contains
390
391		end subroutine do_preForce
392
411	–
412	–
413	–
414	–
415	–
416	–
417	–
418	–
419	–
420	–
421	–
422	–
393		!! Calculate any post force loop components, i.e. reaction field, etc.
394		subroutine do_postForce()
395
#	Line 427 \| Line 397 \| contains
397
398		end subroutine do_postForce
399
400	+	subroutine do_pair(i, j, rijsq, d, do_pot, do_stress)
401
402	+	logical, intent(inout) :: do_pot, do_stress
403	+	integer, intent(in) :: i, j
404	+	real ( kind = dp ), intent(in) :: rijsq
405	+	real ( kind = dp ) :: r
406	+	real ( kind = dp ), intent(inout) :: d(3)
407
408	<
433	<
434	<
435	<
436	<
437	<
438	<
439	<
440	<
441	<
442	<
443	<
444	<
445	<
446	<	subroutine do_pair(atype_i,atype_j,i,j,r_ij,rx_ij,ry_ij,rz_ij)
447	<	type (atype ), pointer, intent(inout) :: atype_i
448	<	type (atype ), pointer, intent(inout) :: atype_j
449	<	integer :: i
450	<	integer :: j
451	<	real ( kind = dp ), intent(inout) :: rx_ij
452	<	real ( kind = dp ), intent(inout) :: ry_ij
453	<	real ( kind = dp ), intent(inout) :: rz_ij
454	<
455	<
456	<	real( kind = dp ) :: fx = 0.0_dp
457	<	real( kind = dp ) :: fy = 0.0_dp
458	<	real( kind = dp ) :: fz = 0.0_dp
459	<
460	<	real( kind = dp ) :: drdx = 0.0_dp
461	<	real( kind = dp ) :: drdy = 0.0_dp
462	<	real( kind = dp ) :: drdz = 0.0_dp
408	>	r = sqrt(rijsq)
409
410	+	logical :: is_LJ_i, is_LJ_j
411	+	logical :: is_DP_i, is_DP_j
412	+	logical :: is_Sticky_i, is_Sticky_j
413	+	integer :: me_i, me_j
414
415	<	if (Atype_i%is_LJ .and. Atype_j%is_LJ) then
466	<	call getLJForce(r,pot,dudr,ljAtype_i,ljAtype_j,fx,fy,fz)
467	<	endif
415	>	#ifdef IS_MPI
416
417	<	if (Atype_i%is_dp .and. Atype_j%is_dp) then
417	>	me_i = atid_row(i)
418	>	me_j = atid_col(j)
419
471	–	#ifdef IS_MPI
472	–	call dipole_dipole(i, j, atype_i, atype_j, rx_ij, ry_ij, rz_ij, r_ij, &
473	–	ulRow(:,i), ulCol(:,j), rt, rrf, pot)
420		#else
475	–	call dipole_dipole(i, j, atype_i, atype_j, rx_ij, ry_ij, rz_ij, r_ij, &
476	–	ul(:,i), ul(:,j), rt, rrf, pot)
477	–	#endif
421
422	<	if (do_reaction_field) then
423	<	#ifdef IS_MPI
424	<	call accumulate_rf(i, j, r_ij, rflRow(:,i), rflCol(:j), &
482	<	ulRow(:i), ulCol(:,j), rt, rrf)
483	<	#else
484	<	call accumulate_rf(i, j, r_ij, rfl(:,i), rfl(:j), &
485	<	ul(:,i), ul(:,j), rt, rrf)
422	>	me_i = atid(i)
423	>	me_j = atid(j)
424	>
425		#endif
487	–	endif
426
427
428	+	if (FF_uses_LJ .and. SimUsesLJ()) then
429	+	call getElementProperty(atypes, me_i, "is_LJ", is_LJ_i)
430	+	call getElementProperty(atypes, me_j, "is_LJ", is_LJ_j)
431	+
432	+	if ( is_LJ_i .and. is_LJ_j ) &
433	+	call do_lj_pair(i, j, d, r, rijsq, pot, f, do_pot, do_stress)
434		endif
435	+
436
437	<	if (Atype_i%is_sticky .and. Atype_j%is_sticky) then
438	<	call getstickyforce(r,pot,dudr,ljAtype_i,ljAtype_j)
439	<	endif
495	<
437	>	if (FF_uses_DP .and. SimUsesDP()) then
438	>	call getElementProperty(atypes, me_i, "is_DP", is_DP_i)
439	>	call getElementProperty(atypes, me_j, "is_DP", is_DP_j)
440
441	<	#ifdef IS_MPI
442	<	eRow(i) = eRow(i) + pot*0.5
443	<	eCol(i) = eCol(i) + pot*0.5
444	<	#else
445	<	pe = pe + pot
502	<	#endif
441	>	if ( is_DP_i .and. is_DP_j ) then
442	>
443	>	call do_dipole_pair(i, j, d, r, pot, u_l, f, t, do_pot, do_stress)
444	>
445	>	if (FF_uses_RF .and. SimUsesRF()) then
446
447	<	drdx = -rxij / r
448	<	drdy = -ryij / r
449	<	drdz = -rzij / r
450	<
451	<	fx = dudr * drdx
452	<	fy = dudr * drdy
453	<	fz = dudr * drdz
447	>	call accumulate_rf(i, j, r, u_l)
448	>	call rf_correct_forces(i, j, d, r, u_l, f, do_stress)
449	>
450	>	endif
451	>
452	>	endif
453	>	endif
454
455	+	if (FF_uses_Sticky .and. SimUsesSticky()) then
456
457	<
458	<
459	<
460	<
461	<
462	<	#ifdef IS_MPI
463	<	fCol(1,j) = fCol(1,j) - fx
464	<	fCol(2,j) = fCol(2,j) - fy
465	<	fCol(3,j) = fCol(3,j) - fz
522	<
523	<	fRow(1,j) = fRow(1,j) + fx
524	<	fRow(2,j) = fRow(2,j) + fy
525	<	fRow(3,j) = fRow(3,j) + fz
526	<	#else
527	<	fTemp(1,j) = fTemp(1,j) - fx
528	<	fTemp(2,j) = fTemp(2,j) - fy
529	<	fTemp(3,j) = fTemp(3,j) - fz
530	<	fTemp(1,i) = fTemp(1,i) + fx
531	<	fTemp(2,i) = fTemp(2,i) + fy
532	<	fTemp(3,i) = fTemp(3,i) + fz
533	<	#endif
534	<
535	<	if (do_stress) then
536	<	tauTemp(1) = tauTemp(1) + fx * rxij
537	<	tauTemp(2) = tauTemp(2) + fx * ryij
538	<	tauTemp(3) = tauTemp(3) + fx * rzij
539	<	tauTemp(4) = tauTemp(4) + fy * rxij
540	<	tauTemp(5) = tauTemp(5) + fy * ryij
541	<	tauTemp(6) = tauTemp(6) + fy * rzij
542	<	tauTemp(7) = tauTemp(7) + fz * rxij
543	<	tauTemp(8) = tauTemp(8) + fz * ryij
544	<	tauTemp(9) = tauTemp(9) + fz * rzij
545	<	endif
546	<
547	<
548	<
457	>	call getElementProperty(atypes, me_i, "is_Sticky", is_Sticky_i)
458	>	call getElementProperty(atypes, me_j, "is_Sticky", is_Sticky_j)
459	>
460	>	if ( is_Sticky_i .and. is_Sticky_j ) then
461	>	call do_sticky_pair(i, j, d, r, rijsq, A, pot, f, t, &
462	>	do_pot, do_stress)
463	>	endif
464	>	endif
465	>
466		end subroutine do_pair
467
468
469	<
470	<
554	<
555	<
556	<
557	<
558	<
559	<
560	<
561	<
562	<
563	<
564	<
565	<
566	<	subroutine get_interatomic_vector(q_i,q_j,rx_ij,ry_ij,rz_ij,r_sq,r_ij)
567	<	!---------------- Arguments-------------------------------
568	<	!! index i
569	<
570	<	!! Position array
469	>	subroutine get_interatomic_vector(q_i, q_j, d, r_sq)
470	>
471		real (kind = dp), dimension(3) :: q_i
472		real (kind = dp), dimension(3) :: q_j
573	–	!! x component of vector between i and j
574	–	real ( kind = dp ), intent(out) :: rx_ij
575	–	!! y component of vector between i and j
576	–	real ( kind = dp ), intent(out) :: ry_ij
577	–	!! z component of vector between i and j
578	–	real ( kind = dp ), intent(out) :: rz_ij
579	–	!! magnitude of r squared
473		real ( kind = dp ), intent(out) :: r_sq
581	–	!! magnitude of vector r between atoms i and j.
582	–	real ( kind = dp ), intent(out) :: r_ij
583	–	!! wrap into periodic box.
584	–	logical, intent(in) :: wrap
585	–
586	–	!--------------- Local Variables---------------------------
587	–	!! Distance between i and j
474		real( kind = dp ) :: d(3)
589	–	!---------------- END DECLARATIONS-------------------------
475
591	–
592	–	! Find distance between i and j
476		d(1:3) = q_i(1:3) - q_j(1:3)
477	<
478	<	! Wrap back into periodic box if necessary
479	<	if ( wrap ) then
477	>
478	>	! Wrap back into periodic box if necessary
479	>	if ( isPBC() ) then
480		d(1:3) = d(1:3) - thisSim%box(1:3) * sign(1.0_dp,thisSim%box(1:3)) * &
481		int(abs(d(1:3)/thisSim%box(1:3) + 0.5_dp)
482	<	end if
482	>	endif
483
601	–	! Find Magnitude of the vector
484		r_sq = dot_product(d,d)
485	<	r_ij = sqrt(r_sq)
485	>
486	>	end subroutine get_interatomic_vector
487
488	<	! Set each component for force calculation
489	<	rx_ij = d(1)
607	<	ry_ij = d(2)
608	<	rz_ij = d(3)
488	>	subroutine check_initialization(error)
489	>	integer, intent(out) :: error
490
491	+	error = 0
492	+	! Make sure we are properly initialized.
493	+	if (.not. do_Forces_initialized) then
494	+	write(default_error,*) "ERROR: do_Forces has not been initialized!"
495	+	error = -1
496	+	return
497	+	endif
498	+	#ifdef IS_MPI
499	+	if (.not. isMPISimSet()) then
500	+	write(default_error,*) "ERROR: mpiSimulation has not been initialized!"
501	+	error = -1
502	+	return
503	+	endif
504	+	#endif
505
506	<	end subroutine get_interatomic_vector
506	>	return
507	>	end subroutine check_initialization
508
509	<	subroutine zero_module_variables()
509	>
510	>	subroutine zero_work_arrays()
511	>
512	>	#ifdef IS_MPI
513
514	<	#ifndef IS_MPI
515	<
617	<	pe = 0.0E0_DP
618	<	tauTemp = 0.0_dp
619	<	fTemp = 0.0_dp
620	<	tTemp = 0.0_dp
621	<	#else
622	<	qRow = 0.0_dp
623	<	qCol = 0.0_dp
514	>	q_Row = 0.0_dp
515	>	q_Col = 0.0_dp
516
517	<	muRow = 0.0_dp
518	<	muCol = 0.0_dp
517	>	u_l_Row = 0.0_dp
518	>	u_l_Col = 0.0_dp
519
520	<	u_lRow = 0.0_dp
521	<	u_lCol = 0.0_dp
520	>	A_Row = 0.0_dp
521	>	A_Col = 0.0_dp
522
523	<	ARow = 0.0_dp
524	<	ACol = 0.0_dp
525	<
526	<	fRow = 0.0_dp
527	<	fCol = 0.0_dp
528	<
529	<
638	<	tRow = 0.0_dp
639	<	tCol = 0.0_dp
523	>	f_Row = 0.0_dp
524	>	f_Col = 0.0_dp
525	>	f_Temp = 0.0_dp
526	>
527	>	t_Row = 0.0_dp
528	>	t_Col = 0.0_dp
529	>	t_Temp = 0.0_dp
530
531	<
531	>	pot_Row = 0.0_dp
532	>	pot_Col = 0.0_dp
533	>	pot_Temp = 0.0_dp
534
643	–	eRow = 0.0_dp
644	–	eCol = 0.0_dp
645	–	eTemp = 0.0_dp
535		#endif
536
537	<	end subroutine zero_module_variables
537	>	tau_Temp = 0.0_dp
538	>	virial_Temp = 0.0_dp
539	>
540	>	end subroutine zero_work_arrays
541	>
542
650	–	#ifdef IS_MPI
543		!! Function to properly build neighbor lists in MPI using newtons 3rd law.
544		!! We don't want 2 processors doing the same i j pair twice.
545		!! Also checks to see if i and j are the same particle.
546	<	function mpi_cycle_jLoop(i,j) result(do_cycle)
546	>	function checkExcludes(atom1,atom2) result(do_cycle)
547		!--------------- Arguments--------------------------
548		! Index i
549	<	integer,intent(in) :: i
549	>	integer,intent(in) :: atom1
550		! Index j
551	<	integer,intent(in) :: j
551	>	integer,intent(in), optional :: atom2
552		! Result do_cycle
553		logical :: do_cycle
554		!--------------- Local variables--------------------
555		integer :: tag_i
556		integer :: tag_j
557	<	!--------------- END DECLARATIONS------------------
558	<	tag_i = tagRow(i)
557	>	integer :: i
558	>	!--------------- END DECLARATIONS------------------
559	>	do_cycle = .false.
560	>
561	>	#ifdef IS_MPI
562	>	tag_i = tagRow(atom1)
563	>	#else
564	>	tag_i = tag(atom1)
565	>	#endif
566	>
567	>	!! Check global excludes first
568	>	if (.not. present(atom2)) then
569	>	do i = 1,nGlobalExcludes
570	>	if (excludeGlobal(i) == tag_i) then
571	>	do_cycle = .true.
572	>	return
573	>	end if
574	>	end do
575	>	return !! return after checking globals
576	>	end if
577	>
578	>	!! we return if j not present here.
579		tag_j = tagColumn(j)
580
581	<	do_cycle = .false.
581	>
582
583		if (tag_i == tag_j) then
584		do_cycle = .true.
#	Line 679 \| Line 591 \| contains
591		else
592		if (mod(tag_i + tag_j,2) == 1) do_cycle = .true.
593		endif
682	–	end function mpi_cycle_jLoop
683	–	#endif
594
595	+
596	+
597	+	do i = 1, nLocalExcludes
598	+	if (tag_i = excludes(1,i) .and. excludes(2,i) < 0) then
599	+	do_cycle = .true.
600	+	return
601	+	end if
602	+	end do
603	+
604	+
605	+	end function checkExcludes
606	+
607	+	function FF_UsesDirectionalAtoms() result(doesit)
608	+	logical :: doesit
609	+	doesit = FF_uses_dipoles .or. FF_uses_sticky .or. &
610	+	FF_uses_GB .or. FF_uses_RF
611	+	end function FF_UsesDirectionalAtoms
612	+
613	+	function FF_RequiresPrepairCalc() result(doesit)
614	+	logical :: doesit
615	+	doesit = FF_uses_EAM
616	+	end function FF_RequiresPrepairCalc
617	+
618	+	function FF_RequiresPostpairCalc() result(doesit)
619	+	logical :: doesit
620	+	doesit = FF_uses_RF
621	+	end function FF_RequiresPostpairCalc
622	+
623		end module do_Forces

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Comparing trunk/OOPSE_old/src/mdtools/libmdCode/do_Forces.F90 (file contents): Revision 298 by chuckv, Fri Mar 7 18:26:30 2003 UTC vs. Revision 329 by gezelter, Wed Mar 12 22:27:59 2003 UTC

Diff Legend

Comparing trunk/OOPSE_old/src/mdtools/libmdCode/do_Forces.F90 (file contents):
Revision 298 by chuckv, Fri Mar 7 18:26:30 2003 UTC vs.
Revision 329 by gezelter, Wed Mar 12 22:27:59 2003 UTC