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mirror of https://gitlab.com/scemama/qmcchem.git synced 2024-11-07 06:33:38 +01:00

Forgot srmc_step.irp.f file in previous commit

This commit is contained in:
Anthony Scemama 2016-01-18 20:31:24 +01:00
parent c56c3ea851
commit 97c663e520

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! Providers of *_srmc_block_walk
!==============================
BEGIN_SHELL [ /usr/bin/python ]
from properties import *
t = """
BEGIN_PROVIDER [ $T, $X_srmc_block_walk $D1 ]
&BEGIN_PROVIDER [ $T, $X_srmc_block_walk_kahan $D2 ]
&BEGIN_PROVIDER [ $T, $X_2_srmc_block_walk $D1 ]
&BEGIN_PROVIDER [ $T, $X_2_srmc_block_walk_kahan $D2 ]
implicit none
BEGIN_DOC
! SRMC averages of $X. Computed in E_loc_srmc_block_walk
END_DOC
$X_srmc_block_walk = 0.d0
$X_srmc_block_walk_kahan = 0.d0
$X_2_srmc_block_walk = 0.d0
$X_2_srmc_block_walk_kahan = 0.d0
END_PROVIDER
"""
for p in properties:
if p[1] != 'e_loc':
if p[2] == "":
D1 = ""
D2 = ", (3)"
else:
D1 = ", ("+p[2][1:-1]+")"
D2 = ", ("+p[2][1:-1]+",3)"
print t.replace("$X",p[1]).replace("$T",p[0]).replace("$D1",D1).replace("$D2",D2)
END_SHELL
BEGIN_PROVIDER [ double precision, E_loc_srmc_block_walk ]
&BEGIN_PROVIDER [ double precision, E_loc_2_srmc_block_walk ]
&BEGIN_PROVIDER [ double precision, E_loc_srmc_block_walk_kahan, (3) ]
&BEGIN_PROVIDER [ double precision, E_loc_2_srmc_block_walk_kahan, (3) ]
implicit none
include '../types.F'
BEGIN_DOC
! Properties averaged over the block using the SRMC method
END_DOC
real, allocatable :: elec_coord_tmp(:,:,:)
integer :: mod_align
double precision :: E_loc_save(walk_num_dmc_max)
double precision :: E_loc_save_tmp(walk_num_dmc_max)
double precision :: psi_value_save(walk_num)
double precision :: psi_value_save_tmp(walk_num)
double precision :: srmc_weight(walk_num)
!DIR$ ATTRIBUTES ALIGN : $IRP_ALIGN :: E_loc_save
!DIR$ ATTRIBUTES ALIGN : $IRP_ALIGN :: E_loc_save_tmp
!DIR$ ATTRIBUTES ALIGN : $IRP_ALIGN :: psi_value_save
!DIR$ ATTRIBUTES ALIGN : $IRP_ALIGN :: psi_value_save_tmp
!DIR$ ATTRIBUTES ALIGN : $IRP_ALIGN :: srmc_weight
allocate ( elec_coord_tmp(mod_align(elec_num+1),3,walk_num) )
psi_value_save = 0.d0
psi_value_save_tmp = 0.d0
srmc_weight = 1.d0
! Initialization
if (vmc_algo /= t_Brownian) then
call abrt(irp_here,'SRMC should run with Brownian algorithm')
endif
integer :: k, i_walk, i_step
BEGIN_SHELL [ /usr/bin/python ]
from properties import *
t = """
if (calc_$X) then
!DIR$ VECTOR ALIGNED
$X_srmc_block_walk = 0.d0
!DIR$ VECTOR ALIGNED
$X_srmc_block_walk_kahan = 0.d0
!DIR$ VECTOR ALIGNED
$X_2_srmc_block_walk = 0.d0
!DIR$ VECTOR ALIGNED
$X_2_srmc_block_walk_kahan = 0.d0
endif
"""
for p in properties:
print t.replace("$X",p[1])
END_SHELL
logical :: loop
integer*8 :: cpu0, cpu1, cpu2, count_rate, count_max
loop = .True.
call system_clock(cpu0, count_rate, count_max)
cpu2 = cpu0
block_weight = 0.d0
real, external :: accep_rate
double precision :: delta, thr
thr = 2.d0/time_step_sq
do while (loop)
! Every walker makes a step
do i_walk=1,walk_num
integer :: i,j,l
do l=1,3
do i=1,elec_num+1
elec_coord(i,l) = elec_coord_full(i,l,i_walk)
enddo
enddo
TOUCH elec_coord
double precision :: p,q
real :: delta_x
logical :: accepted
call brownian_step(p,q,accepted,delta_x)
if ( psi_value * psi_value_save(i_walk) >= 0.d0 ) then
delta = ((E_loc+E_loc_save(i_walk))*0.5d0 - E_ref) * p
if ( delta > thr ) then
srmc_weight(i_walk) = dexp(-dtime_step*thr)
else if ( delta < -thr ) then
srmc_weight(i_walk) = dexp(dtime_step*thr)
else
srmc_weight(i_walk) = dexp(-dtime_step*delta)
endif
else
srmc_weight(i_walk) = 0.d0
endif
elec_coord(elec_num+1,1) += p*time_step
elec_coord(elec_num+1,2) = E_loc
elec_coord(elec_num+1,3) = srmc_weight(i_walk)
do l=1,3
do i=1,elec_num+1
elec_coord_full(i,l,i_walk) = elec_coord(i,l)
enddo
enddo
psi_value_save(i_walk) = psi_value
E_loc_save(i_walk) = E_loc
BEGIN_SHELL [ /usr/bin/python ]
from properties import *
t = """
if (calc_$X) then
! Kahan's summation algorithm to compute these sums reducing the rounding error:
! $X_srmc_block_walk += $X * pop_weight_mult * srmc_weight(i_walk)
! $X_2_srmc_block_walk += $X_2 * pop_weight_mult * srmc_weight(i_walk)
! see http://en.wikipedia.org/wiki/Kahan_summation_algorithm
$X_srmc_block_walk_kahan($D2 3) = $X * pop_weight_mult * srmc_weight(i_walk) - $X_srmc_block_walk_kahan($D2 1)
$X_srmc_block_walk_kahan($D2 2) = $X_srmc_block_walk $D1 + $X_srmc_block_walk_kahan($D2 3)
$X_srmc_block_walk_kahan($D2 1) = ($X_srmc_block_walk_kahan($D2 2) - $X_srmc_block_walk $D1 ) &
- $X_srmc_block_walk_kahan($D2 3)
$X_srmc_block_walk $D1 = $X_srmc_block_walk_kahan($D2 2)
$X_2_srmc_block_walk_kahan($D2 3) = $X_2 * pop_weight_mult * srmc_weight(i_walk) - $X_2_srmc_block_walk_kahan($D2 1)
$X_2_srmc_block_walk_kahan($D2 2) = $X_2_srmc_block_walk $D1 + $X_2_srmc_block_walk_kahan($D2 3)
$X_2_srmc_block_walk_kahan($D2 1) = ($X_2_srmc_block_walk_kahan($D2 2) - $X_2_srmc_block_walk $D1 ) &
- $X_2_srmc_block_walk_kahan($D2 3)
$X_2_srmc_block_walk $D1 = $X_2_srmc_block_walk_kahan($D2 2)
endif
"""
for p in properties:
if p[2] == "":
D1 = ""
D2 = ""
else:
D1 = "("+":"*(p[2].count(',')+1)+")"
D2 = ":"*(p[2].count(',')+1)+","
print t.replace("$X",p[1]).replace("$D1",D1).replace("$D2",D2)
END_SHELL
block_weight += pop_weight_mult * srmc_weight(i_walk)
enddo
! Move to the next projection step
if (srmc_projection > 0) then
srmc_projection_step = mod(srmc_projection_step,srmc_projection)+1
else
srmc_projection_step = 1
endif
! Eventually, recompute the weight of the population
if (srmc_projection_step == 1) then
pop_weight_mult = 1.d0
do k=1,srmc_projection
pop_weight_mult *= pop_weight(k)
enddo
endif
! Remove contribution of the old value of the weight at the new
! projection step
pop_weight_mult *= 1.d0/pop_weight(srmc_projection_step)
! Compute the new weight of the population
double precision :: sum_weight
sum_weight = 0.d0
do k=1,walk_num
sum_weight += srmc_weight(k)
enddo
pop_weight(srmc_projection_step) = sum_weight/dble(walk_num)
! Update the running population weight
pop_weight_mult *= pop_weight(srmc_projection_step)
! Reconfiguration
integer :: ipos(walk_num)
call reconfigure(ipos,srmc_weight)
do k=1,walk_num
do l=1,3
do i=1,elec_num+1
elec_coord_tmp(i,l,k) = elec_coord_full(i,l,k)
enddo
enddo
psi_value_save_tmp(k) = psi_value_save(k)
E_loc_save_tmp(k) = E_loc_save(k)
enddo
integer :: ipm
do k=1,walk_num
ipm = ipos(k)
do l=1,3
do i=1,elec_num+1
elec_coord_full(i,l,k) = elec_coord_tmp(i,l,ipm)
enddo
enddo
psi_value_save(k) = psi_value_save_tmp(ipm)
E_loc_save(k) = E_loc_save_tmp(ipm)
enddo
call system_clock(cpu1, count_rate, count_max)
if (cpu1 < cpu0) then
cpu1 = cpu1+cpu0
endif
loop = dble(cpu1-cpu0) < dble(block_time)*dble(count_rate)
if (cpu1-cpu2 > count_rate) then
integer :: do_run
call get_running(do_run)
loop = do_run == t_Running
cpu2 = cpu1
endif
SOFT_TOUCH elec_coord_full psi_value psi_grad_psi_inv_x psi_grad_psi_inv_y psi_grad_psi_inv_z elec_coord pop_weight_mult
enddo
double precision :: factor
factor = 1.d0/block_weight
SOFT_TOUCH block_weight
BEGIN_SHELL [ /usr/bin/python ]
from properties import *
t = """
if (calc_$X) then
$X_srmc_block_walk *= factor
$X_2_srmc_block_walk *= factor
endif
"""
for p in properties:
print t.replace("$X",p[1])
END_SHELL
deallocate ( elec_coord_tmp )
END_PROVIDER
BEGIN_PROVIDER [ double precision, pop_weight_mult ]
implicit none
BEGIN_DOC
! Population weight of SRMC
END_DOC
pop_weight_mult = pop_weight(srmc_projection)
END_PROVIDER
BEGIN_PROVIDER [ integer, srmc_projection ]
&BEGIN_PROVIDER [ integer, srmc_projection_step ]
implicit none
BEGIN_DOC
! Number of projection steps for SRMC
END_DOC
real :: srmc_projection_time
srmc_projection_time = 1.
call get_simulation_srmc_projection_time(srmc_projection_time)
srmc_projection = int( srmc_projection_time/time_step)
srmc_projection_step = 0
END_PROVIDER
BEGIN_PROVIDER [ double precision, pop_weight, (0:srmc_projection+1) ]
implicit none
BEGIN_DOC
! Population weight of SRMC
END_DOC
pop_weight = 1.d0
END_PROVIDER