Commit 59dbed39 authored by Andrea Hanke's avatar Andrea Hanke

Merge branch 'develop' of iffgit.fz-juelich.de:fleur/fleur into develop

parents dc8b472e 4e17db7e
init/compileinfo.h
io/xml/inputSchema.h
Testing/*
*~
\#*
build
......
......@@ -16,7 +16,7 @@ build-gfortran-hdf5:
paths:
- build
script:
- cd /builds/fleur/fleur; ./configure.sh GITLAB; cd build; make
- cd /builds/fleur/fleur; ./configure.sh GITLAB; cd build; make -j 4
# only:
# - schedules
# - triggers
......@@ -100,7 +100,7 @@ build-intel:
- build.intel
script:
- set +e && source compilervars.sh intel64 && set -e ; ulimit -s unlimited
- cd /builds/fleur/fleur; FC=mpiifort FLEUR_LIBRARIES="-lmkl_scalapack_lp64;-lmkl_blacs_intelmpi_lp64" ./configure.sh -t -l intel INTEL_MPI ; cd build.intel; make
- cd /builds/fleur/fleur; FC=mpiifort FLEUR_LIBRARIES="-lmkl_scalapack_lp64;-lmkl_blacs_intelmpi_lp64" ./configure.sh -t -l intel INTEL_MPI ; cd build.intel; make -j 4
only:
- schedules
- triggers
......@@ -133,7 +133,7 @@ gfortran-coverage:
paths:
- build
script:
- cd /builds/fleur/fleur; ./configure.sh -l coverage -flags --coverage GITLAB; cd build.coverage; make
- cd /builds/fleur/fleur; ./configure.sh -l coverage -flags --coverage GITLAB; cd build.coverage; make -j 4
- lcov --capture --initial -d CMakeFiles -o baseline.info
- ulimit -s unlimited ;export juDFT_MPI="mpirun -n 2 --allow-run-as-root ";ctest
- lcov --capture -d CMakeFiles -o after.info
......
......@@ -134,7 +134,7 @@ SUBROUTINE cdnval(eig_id, mpi,kpts,jspin,noco,input,banddos,cell,atoms,enpara,st
CALL denCoeffs%init(atoms,sphhar,jsp_start,jsp_end)
! The last entry in denCoeffsOffdiag%init is l_fmpl. It is meant as a switch to a plot of the full magnet.
! density without the atomic sphere approximation for the magnet. density. It is not completely implemented (lo's missing).
CALL denCoeffsOffdiag%init(atoms,noco,sphhar,.FALSE.)
CALL denCoeffsOffdiag%init(atoms,noco,sphhar,noco%l_mtnocopot)
CALL force%init1(input,atoms)
CALL orb%init(atoms,noco,jsp_start,jsp_end)
......
......@@ -34,7 +34,7 @@ SUBROUTINE genNewNocoInp(input,atoms,noco,noco_new)
alphdiff = 2.0*pi_const*(noco%qss(1)*atoms%taual(1,iAtom) + &
noco%qss(2)*atoms%taual(2,iAtom) + &
noco%qss(3)*atoms%taual(3,iAtom) )
noco_new%alph(iType) = noco%alph(iType) - alphdiff
noco_new%alph(iType) = noco_new%alph(iType) - alphdiff
DO WHILE (noco_new%alph(iType) > +pi_const)
noco_new%alph(iType)= noco_new%alph(iType) - 2.0*pi_const
END DO
......@@ -42,12 +42,12 @@ SUBROUTINE genNewNocoInp(input,atoms,noco,noco_new)
noco_new%alph(iType)= noco_new%alph(iType) + 2.0*pi_const
END DO
ELSE
noco_new%alph(iType) = noco%alph(iType)
noco_new%alph(iType) = noco_new%alph(iType)
END IF
iatom= iatom + atoms%neq(iType)
END DO
OPEN (24,file='nocoinp',form='formatted', status='old')
OPEN (24,file='nocoinp',form='formatted', status='unknown')
REWIND (24)
CALL rw_noco_write(atoms,noco_new, input)
CLOSE (24)
......
......@@ -41,7 +41,7 @@ CONTAINS
! .. Intrinsic Functions ..
INTRINSIC conjg
qal21=0.0
!---> l-decomposed density for each occupied state
states : DO i = 1, noccbd
nt1 = 1
......
......@@ -62,7 +62,6 @@ CONTAINS
ENDIF
!$OMP PARALLEL DEFAULT(none) &
!$OMP SHARED(usdus,rho,moments,qmtl) &
!$OMP SHARED(atoms,jsp_start,jsp_end,enpara,vr,denCoeffs,sphhar)&
!$OMP SHARED(orb,noco,denCoeffsOffdiag,jspd)&
......
......@@ -22,10 +22,10 @@ CONTAINS
! .. Array Arguments ..
REAL, INTENT(IN) :: we(:)!(nobd)
COMPLEX, INTENT(INOUT) :: uu21(atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: ud21(atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: du21(atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: dd21(atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: uu21(0:atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: ud21(0:atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: du21(0:atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: dd21(0:atoms%lmaxd,atoms%ntype)
COMPLEX, INTENT(INOUT) :: uulo21(atoms%nlod,atoms%ntype)
COMPLEX, INTENT(INOUT) :: dulo21(atoms%nlod,atoms%ntype)
COMPLEX, INTENT(INOUT) :: ulou21(atoms%nlod,atoms%ntype)
......
......@@ -55,17 +55,17 @@ io/calculator.f global/ss_sym.f global/soc_sym.f math/inv3.f io/rw_symfile.f
kpoints/kptgen_hybrid.f kpoints/od_kptsgen.f kpoints/bravais.f kpoints/divi.f kpoints/brzone.f
kpoints/kptmop.f kpoints/kpttet.f init/bandstr1.F kpoints/ordstar.f kpoints/fulstar.f kpoints/kprep.f
kpoints/tetcon.f kpoints/kvecon.f init/boxdim.f global/radsra.f math/intgr.F global/differ.f math/inwint.f
math/outint.f xc-pot/gaunt.f math/grule.f
math/outint.f math/grule.f
)
set(inpgen_F90 ${inpgen_F90} global/constants.f90 io/xsf_io.f90
eigen/orthoglo.F90 juDFT/usage_data.F90 math/ylm4.F90
global/sort.f90 global/chkmt.f90 inpgen/inpgen.f90 inpgen/set_inp.f90 inpgen/inpgen_help.f90 io/rw_inp.f90 juDFT/juDFT.F90 global/find_enpara.f90
inpgen/closure.f90 inpgen/inpgen_arguments.F90
juDFT/info.F90 juDFT/stop.F90 juDFT/args.F90 juDFT/time.F90 juDFT/init.F90 juDFT/sysinfo.F90 io/w_inpXML.f90 kpoints/julia.f90 global/utility.F90
juDFT/info.F90 juDFT/stop.F90 juDFT/args.F90 juDFT/time.F90 juDFT/init.F90 juDFT/sysinfo.F90 juDFT/string.f90 io/w_inpXML.f90 kpoints/julia.f90 global/utility.F90
init/compile_descr.F90 kpoints/kpoints.f90 io/xmlOutput.F90 kpoints/brzone2.f90 cdn/slab_dim.f90 cdn/slabgeom.f90 dos/nstm3.f90 cdn/int_21.f90
cdn/int_21lo.f90 cdn_mt/rhomt21.f90 cdn_mt/rhonmt21.f90 force/force_a21.F90 force/force_a21_lo.f90 force/force_a21_U.f90 force/force_a12.f90
eigen/tlmplm_store.F90 kpoints/unfoldBandKPTS.f90)
eigen/tlmplm_store.F90 xc-pot/gaunt.f90 kpoints/unfoldBandKPTS.f90)
set(fleur_SRC ${fleur_F90} ${fleur_F77})
......
......@@ -12,7 +12,7 @@ if (${CMAKE_Fortran_COMPILER_ID} MATCHES "Intel")
set(CMAKE_Fortran_FLAGS "${CMAKE_Fortran_FLAGS} -mkl -r8 -qopenmp -assume byterecl")
endif()
set(CMAKE_Fortran_FLAGS_RELEASE "${CMAKE_Fortran_FLAGS_RELEASE} -xHost -O2 -g")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -C -traceback -O0 -g -ftrapuv -check uninit -check pointers -CB ")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -C -traceback -O0 -g -ftrapuv -check uninit -check pointers -CB -DCPP_DEBUG")
elseif(${CMAKE_Fortran_COMPILER_ID} MATCHES "PGI")
message("PGI Fortran detected")
set(CMAKE_SHARED_LIBRARY_LINK_Fortran_FLAGS "") #fix problem in cmake
......@@ -24,12 +24,12 @@ elseif(${CMAKE_Fortran_COMPILER_ID} MATCHES "PGI")
#set(CMAKE_Fortran_FLAGS "${CMAKE_Fortran_FLAGS} -mp -Mr8 -Mr8intrinsics -Mcuda:cuda9.0,cc70 -DUSE_STREAMS -DNUM_STREAMS=${N_STREAMS} -Minfo=accel -acc")
#set(CMAKE_Fortran_FLAGS_RELEASE "${CMAKE_Fortran_FLAGS_RELEASE} -fast -O3")
set(CMAKE_Fortran_FLAGS_RELEASE "-O1 ") # to prevent cmake from putting -fast which auses problems with PGI18.4
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -C -traceback -O0 -g -Mchkstk -Mchkptr -Ktrap=fp")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -C -traceback -O0 -g -Mchkstk -Mchkptr -Ktrap=fp -DCPP_DEBUG")
elseif(${CMAKE_Fortran_COMPILER_ID} MATCHES "XL")
message("IBM/BG Fortran detected")
set(CMAKE_Fortran_FLAGS "${CMAKE_Fortran_FLAGS} -qsmp=omp -qnosave -qarch=qp -qtune=qp -qrealsize=8 -qfixed -qsuppress=1520-022 -qessl")
set(CMAKE_Fortran_FLAGS_RELEASE "${CMAKE_Fortran_FLAGS_RELEASE} -O4 -qsuppress=1500-036")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -O0 -g")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -O0 -g -DCPP_DEBUG")
set(CMAKE_C_FLAGS "${CMAKE_C_FLAGS} -I/bgsys/local/libxml2/include/libxml2")
set(FLEUR_DEFINITIONS ${FLEUR_DEFINITIONS} "CPP_AIX")
set(FLEUR_MPI_DEFINITIONS ${FLEUR_MPI_DEFINITIONS} "CPP_AIX")
......@@ -39,6 +39,6 @@ elseif(${CMAKE_Fortran_COMPILER_ID} MATCHES "GNU")
message(FATAL_ERROR "Only modern versions of gfortran >6.3 will be able to compile FLEUR\nYou need to specify a different compiler.\nSee the docs at www.flapw.de.\n")
endif()
set(CMAKE_Fortran_FLAGS "${CMAKE_Fortran_FLAGS} -ffree-line-length-none -fopenmp -fdefault-real-8 ")
set(CMAKE_Fortran_FLAGS_RELEASE "${CMAKE_Fortran_FLAGS_RELEASE} -O1")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -fdump-core -Wall -Wextra -Warray-temporaries -fbacktrace -fcheck=all -finit-real=nan -O0 -g")
set(CMAKE_Fortran_FLAGS_RELEASE "${CMAKE_Fortran_FLAGS_RELEASE} -O2")
set(CMAKE_Fortran_FLAGS_DEBUG "${CMAKE_Fortran_FLAGS_DEBUG} -fdump-core -Wall -Wextra -Warray-temporaries -fbacktrace -fcheck=all -finit-real=nan -O0 -g -DCPP_DEBUG")
endif()
......@@ -3,11 +3,11 @@
echo "set(compile_user $USER)" >config.cmake
#Some freqeuntly used Environment variables
if [ -n "$HDF5_ROOT" ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_ROOT/lib" ; FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_ROOT/include" ; fi
if [ -n "$HDF5_DIR"} ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_DIR/lib" ; FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_DIR/include" ; fi
if [ -n "$HDF5_LIB" ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_LIB" ; fi
if [ -n "$HDF5_INCLUDE" ] ; then FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_INCLUDE" ; fi
if [ -n "$HDF5_MODULES" ] ; then FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_MODULES" ; fi
if [ ! -z ${HDF5_ROOT+x} ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_ROOT/lib" ; FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_ROOT/include" ; fi
if [ ! -z ${HDF5_DIR+x} ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_DIR/lib" ; FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_DIR/include" ; fi
if [ ! -z ${HDF5_LIB+x} ] ; then FLEUR_LIBDIR="$FLEUR_LIBDIR $HDF5_LIB" ; fi
if [ ! -z ${HDF5_INCLUDE+x} ] ; then FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_INCLUDE" ; fi
if [ ! -z ${HDF5_MODULES+x} ] ; then FLEUR_INCLUDEDIR="$FLEUR_INCLUDEDIR $HDF5_MODULES" ; fi
......
MODULE m_cored
CONTAINS
SUBROUTINE cored(&
& input,jspin,atoms,&
& rho,DIMENSION,&
& sphhar,&
& vr,&
& qint,rhc,tec,seig)
SUBROUTINE cored(&
& input,jspin,atoms,&
& rho,DIMENSION,&
& sphhar,&
& vr,&
& qint,rhc,tec,seig)
! *******************************************************
! ***** set up the core densities for compounds. *****
! ***** d.d.koelling *****
! *******************************************************
USE m_juDFT
USE m_intgr, ONLY : intgr3,intgr0,intgr1
USE m_constants, ONLY : c_light,sfp_const
USE m_setcor
USE m_differ
USE m_types
USE m_xmlOutput
IMPLICIT NONE
TYPE(t_dimension),INTENT(IN) :: DIMENSION
TYPE(t_input),INTENT(IN) :: input
TYPE(t_sphhar),INTENT(IN) :: sphhar
TYPE(t_atoms),INTENT(IN) :: atoms
!
! .. Scalar Arguments ..
INTEGER, INTENT (IN) :: jspin
REAL, INTENT (OUT) :: seig
! ..
! .. Array Arguments ..
REAL, INTENT(IN) :: vr(atoms%jmtd,atoms%ntype)
REAL, INTENT(INOUT) :: rho(atoms%jmtd,0:sphhar%nlhd,atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: rhc(DIMENSION%msh,atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: qint(atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: tec(atoms%ntype,input%jspins)
! ..
! .. Local Scalars ..
REAL e,fj,fl,fn,q,rad,rhos,rhs,sea,sume,t2
REAL d,dxx,rn,rnot,z,t1,rr,r,lambd,c,bmu,weight
INTEGER i,j,jatom,korb,n,ncmsh,nm,nm1,nst ,l,ierr
! ..
! .. Local Arrays ..
REAL rhcs(DIMENSION%msh),rhoc(DIMENSION%msh),rhoss(DIMENSION%msh),vrd(DIMENSION%msh),f(0:3)
REAL occ(DIMENSION%nstd),a(DIMENSION%msh),b(DIMENSION%msh),ain(DIMENSION%msh),ahelp(DIMENSION%msh)
REAL occ_h(DIMENSION%nstd,2)
INTEGER kappa(DIMENSION%nstd),nprnc(DIMENSION%nstd)
CHARACTER(LEN=20) :: attributes(6)
REAL stateEnergies(29)
! ..
c = c_light(1.0)
seig = 0.
!
IF (input%frcor) THEN
DO n = 1,atoms%ntype
rnot = atoms%rmsh(1,n) ; dxx = atoms%dx(n)
ncmsh = NINT( LOG( (atoms%rmt(n)+10.0)/rnot ) / dxx + 1 )
ncmsh = MIN( ncmsh, DIMENSION%msh )
! ---> update spherical charge density
DO i = 1,atoms%jri(n)
rhoc(i) = rhc(i,n,jspin)
rho(i,0,n,jspin) = rho(i,0,n,jspin) + rhoc(i)/sfp_const
ENDDO
! ---> for total energy calculations, determine the sum of the
! ---> eigenvalues by requiring that the core kinetic energy
! ---> remains constant.
DO i = 1,atoms%jri(n)
rhoc(i) = rhoc(i)*vr(i,n)/atoms%rmsh(i,n)
ENDDO
nm = atoms%jri(n)
CALL intgr3(rhoc,atoms%rmsh(1,n),atoms%dx(n),nm,rhos)
sea = tec(n,jspin) + rhos
WRITE (16,FMT=8030) n,jspin,tec(n,jspin),sea
WRITE (6,FMT=8030) n,jspin,tec(n,jspin),sea
seig = seig + atoms%neq(n)*sea
ENDDO
RETURN
END IF
! *******************************************************
! ***** set up the core densities for compounds. *****
! ***** d.d.koelling *****
! *******************************************************
USE m_juDFT
USE m_intgr, ONLY : intgr3,intgr0,intgr1
USE m_constants, ONLY : c_light,sfp_const
USE m_setcor
USE m_differ
USE m_types
USE m_xmlOutput
IMPLICIT NONE
TYPE(t_dimension),INTENT(IN) :: DIMENSION
TYPE(t_input),INTENT(IN) :: input
TYPE(t_sphhar),INTENT(IN) :: sphhar
TYPE(t_atoms),INTENT(IN) :: atoms
!
! .. Scalar Arguments ..
INTEGER, INTENT (IN) :: jspin
REAL, INTENT (OUT) :: seig
! ..
! .. Array Arguments ..
REAL, INTENT(IN) :: vr(atoms%jmtd,atoms%ntype)
REAL, INTENT(INOUT) :: rho(atoms%jmtd,0:sphhar%nlhd,atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: rhc(DIMENSION%msh,atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: qint(atoms%ntype,input%jspins)
REAL, INTENT(INOUT) :: tec(atoms%ntype,input%jspins)
! ..
! .. Local Scalars ..
REAL e,fj,fl,fn,q,rad,rhos,rhs,sea,sume,t2
REAL d,dxx,rn,rnot,z,t1,rr,r,lambd,c,bmu,weight
INTEGER i,j,jatom,korb,n,ncmsh,nm,nm1,nst ,l,ierr
! ..
! .. Local Arrays ..
! ---> set up densities
DO jatom = 1,atoms%ntype
sume = 0.
z = atoms%zatom(jatom)
! rn = rmt(jatom)
dxx = atoms%dx(jatom)
bmu = 0.0
CALL setcor(jatom,input%jspins,atoms,input,bmu,nst,kappa,nprnc,occ_h)
IF ((bmu > 99.)) THEN
occ(1:nst) = input%jspins * occ_h(1:nst,jspin)
ELSE
occ(1:nst) = occ_h(1:nst,1)
ENDIF
rnot = atoms%rmsh(1,jatom)
d = EXP(atoms%dx(jatom))
ncmsh = NINT( LOG( (atoms%rmt(jatom)+10.0)/rnot ) / dxx + 1 )
ncmsh = MIN( ncmsh, DIMENSION%msh )
rn = rnot* (d** (ncmsh-1))
WRITE (6,FMT=8000) z,rnot,dxx,atoms%jri(jatom)
WRITE (16,FMT=8000) z,rnot,dxx,atoms%jri(jatom)
DO j = 1,atoms%jri(jatom)
rhoss(j) = 0.
vrd(j) = vr(j,jatom)
ENDDO
!
IF (input%l_core_confpot) THEN
!---> linear extension of the potential with slope t1 / a.u.
t1=0.125
t1 = MAX( (vrd(atoms%jri(jatom)) - vrd(atoms%jri(jatom)-1)*d)*&
d / (atoms%rmt(jatom)**2 * (d-1) ) , t1)
t2=vrd(atoms%jri(jatom))/atoms%rmt(jatom)-atoms%rmt(jatom)*t1
rr = atoms%rmt(jatom)
ELSE
t2 = vrd(atoms%jri(jatom)) / ( atoms%jri(jatom) - ncmsh )
ENDIF
IF ( atoms%jri(jatom) < ncmsh) THEN
DO i = atoms%jri(jatom) + 1,ncmsh
rhoss(i) = 0.
IF (input%l_core_confpot) THEN
rr = d*rr
vrd(i) = rr*( t2 + rr*t1 )
! vrd(i) = 2*vrd(jri(jatom)) - rr*( t2 + rr*t1 )
ELSE
vrd(i) = vrd(atoms%jri(jatom)) + t2* (i-atoms%jri(jatom))
ENDIF
!
ENDDO
END IF
REAL rhcs(DIMENSION%msh),rhoc(DIMENSION%msh),rhoss(DIMENSION%msh),vrd(DIMENSION%msh),f(0:3)
REAL occ(DIMENSION%nstd),a(DIMENSION%msh),b(DIMENSION%msh),ain(DIMENSION%msh),ahelp(DIMENSION%msh)
REAL occ_h(DIMENSION%nstd,2)
INTEGER kappa(DIMENSION%nstd),nprnc(DIMENSION%nstd)
CHARACTER(LEN=20) :: attributes(6)
REAL stateEnergies(29)
! ..
c = c_light(1.0)
seig = 0.
!
IF (input%frcor) THEN
DO n = 1,atoms%ntype
rnot = atoms%rmsh(1,n) ; dxx = atoms%dx(n)
ncmsh = NINT( LOG( (atoms%rmt(n)+10.0)/rnot ) / dxx + 1 )
ncmsh = MIN( ncmsh, DIMENSION%msh )
! ---> update spherical charge density
DO i = 1,atoms%jri(n)
rhoc(i) = rhc(i,n,jspin)
rho(i,0,n,jspin) = rho(i,0,n,jspin) + rhoc(i)/sfp_const
ENDDO
! ---> for total energy calculations, determine the sum of the
! ---> eigenvalues by requiring that the core kinetic energy
! ---> remains constant.
DO i = 1,atoms%jri(n)
rhoc(i) = rhoc(i)*vr(i,n)/atoms%rmsh(i,n)
ENDDO
nm = atoms%jri(n)
CALL intgr3(rhoc,atoms%rmsh(1,n),atoms%dx(n),nm,rhos)
sea = tec(n,jspin) + rhos
WRITE (16,FMT=8030) n,jspin,tec(n,jspin),sea
WRITE (6,FMT=8030) n,jspin,tec(n,jspin),sea
seig = seig + atoms%neq(n)*sea
ENDDO
RETURN
END IF
nst = atoms%ncst(jatom) ! for lda+U
! ---> set up densities
DO jatom = 1,atoms%ntype
sume = 0.
z = atoms%zatom(jatom)
! rn = rmt(jatom)
dxx = atoms%dx(jatom)
bmu = 0.0
CALL setcor(jatom,input%jspins,atoms,input,bmu,nst,kappa,nprnc,occ_h)
IF ((bmu > 99.)) THEN
occ(1:nst) = input%jspins * occ_h(1:nst,jspin)
ELSE
occ(1:nst) = occ_h(1:nst,1)
ENDIF
rnot = atoms%rmsh(1,jatom)
d = EXP(atoms%dx(jatom))
ncmsh = NINT( LOG( (atoms%rmt(jatom)+10.0)/rnot ) / dxx + 1 )
ncmsh = MIN( ncmsh, DIMENSION%msh )
rn = rnot* (d** (ncmsh-1))
WRITE (6,FMT=8000) z,rnot,dxx,atoms%jri(jatom)
WRITE (16,FMT=8000) z,rnot,dxx,atoms%jri(jatom)
DO j = 1,atoms%jri(jatom)
rhoss(j) = 0.
vrd(j) = vr(j,jatom)
ENDDO
!
IF (input%l_core_confpot) THEN
!---> linear extension of the potential with slope t1 / a.u.
t1=0.125
t1 = MAX( (vrd(atoms%jri(jatom)) - vrd(atoms%jri(jatom)-1)*d)*&
d / (atoms%rmt(jatom)**2 * (d-1) ) , t1)
t2=vrd(atoms%jri(jatom))/atoms%rmt(jatom)-atoms%rmt(jatom)*t1
rr = atoms%rmt(jatom)
ELSE
t2 = vrd(atoms%jri(jatom)) / ( atoms%jri(jatom) - ncmsh )
ENDIF
IF ( atoms%jri(jatom) < ncmsh) THEN
DO i = atoms%jri(jatom) + 1,ncmsh
rhoss(i) = 0.
IF (input%l_core_confpot) THEN
rr = d*rr
vrd(i) = rr*( t2 + rr*t1 )
! vrd(i) = 2*vrd(jri(jatom)) - rr*( t2 + rr*t1 )
ELSE
vrd(i) = vrd(atoms%jri(jatom)) + t2* (i-atoms%jri(jatom))
ENDIF
!
ENDDO
END IF
IF (input%gw==1 .OR. input%gw==3)&
& WRITE(15) nst,atoms%rmsh(1:atoms%jri(jatom),jatom)
nst = atoms%ncst(jatom) ! for lda+U
stateEnergies = 0.0
DO korb = 1,nst
IF (occ(korb) /= 0.0) THEN
fn = nprnc(korb)
fj = iabs(kappa(korb)) - .5e0
weight = 2*fj + 1.e0
IF (bmu > 99.) weight = occ(korb)
fl = fj + (.5e0)*isign(1,kappa(korb))
e = -2* (z/ (fn+fl))**2
CALL differ(fn,fl,fj,c,z,dxx,rnot,rn,d,ncmsh,vrd, e, a,b,ierr)
stateEnergies(korb) = e
WRITE (6,FMT=8010) fn,fl,fj,e,weight
WRITE (16,FMT=8010) fn,fl,fj,e,weight
IF (ierr/=0) CALL juDFT_error("error in core-level routine" ,calledby ="cored")
IF (input%gw==1 .OR. input%gw==3) WRITE (15) NINT(fl),weight,e,&
a(1:atoms%jri(jatom)),b(1:atoms%jri(jatom))
IF (input%gw==1 .OR. input%gw==3)&
& WRITE(15) nst,atoms%rmsh(1:atoms%jri(jatom),jatom)
sume = sume + weight*e/input%jspins
DO j = 1,ncmsh
rhcs(j) = weight* (a(j)**2+b(j)**2)
rhoss(j) = rhoss(j) + rhcs(j)
ENDDO
ENDIF
ENDDO
stateEnergies = 0.0
DO korb = 1,nst
IF (occ(korb) /= 0.0) THEN
fn = nprnc(korb)
fj = iabs(kappa(korb)) - .5e0
weight = 2*fj + 1.e0
IF (bmu > 99.) weight = occ(korb)
fl = fj + (.5e0)*isign(1,kappa(korb))
e = -2* (z/ (fn+fl))**2
CALL differ(fn,fl,fj,c,z,dxx,rnot,rn,d,ncmsh,vrd, e, a,b,ierr)
stateEnergies(korb) = e
WRITE (6,FMT=8010) fn,fl,fj,e,weight
WRITE (16,FMT=8010) fn,fl,fj,e,weight
IF (ierr/=0) CALL juDFT_error("error in core-level routine" ,calledby ="cored")
IF (input%gw==1 .OR. input%gw==3) WRITE (15) NINT(fl),weight,e,&
a(1:atoms%jri(jatom)),b(1:atoms%jri(jatom))
sume = sume + weight*e/input%jspins
DO j = 1,ncmsh
rhcs(j) = weight* (a(j)**2+b(j)**2)
rhoss(j) = rhoss(j) + rhcs(j)
ENDDO
ENDIF
ENDDO
! ---->update spherical charge density rho with the core density.
! ---->for spin-polarized (jspins=2), take only half the density
nm = atoms%jri(jatom)
DO j = 1,nm
rhoc(j) = rhoss(j)/input%jspins
rho(j,0,jatom,jspin) = rho(j,0,jatom,jspin) + rhoc(j)/sfp_const
ENDDO
! ---->update spherical charge density rho with the core density.
! ---->for spin-polarized (jspins=2), take only half the density
nm = atoms%jri(jatom)
DO j = 1,nm
rhoc(j) = rhoss(j)/input%jspins
rho(j,0,jatom,jspin) = rho(j,0,jatom,jspin) + rhoc(j)/sfp_const
ENDDO
rhc(1:ncmsh,jatom,jspin) = rhoss(1:ncmsh) / input%jspins
rhc(ncmsh+1:DIMENSION%msh,jatom,jspin) = 0.0
rhc(1:ncmsh,jatom,jspin) = rhoss(1:ncmsh) / input%jspins
rhc(ncmsh+1:DIMENSION%msh,jatom,jspin) = 0.0
seig = seig + atoms%neq(jatom)*sume
DO i = 1,nm
rhoc(i) = rhoc(i)*vr(i,jatom)/atoms%rmsh(i,jatom)
ENDDO
CALL intgr3(rhoc,atoms%rmsh(1,jatom),atoms%dx(jatom),nm,rhs)
tec(jatom,jspin) = sume - rhs
WRITE (6,FMT=8030) jatom,jspin,tec(jatom,jspin),sume
WRITE (16,FMT=8030) jatom,jspin,tec(jatom,jspin),sume
seig = seig + atoms%neq(jatom)*sume
DO i = 1,nm
rhoc(i) = rhoc(i)*vr(i,jatom)/atoms%rmsh(i,jatom)
ENDDO
CALL intgr3(rhoc,atoms%rmsh(1,jatom),atoms%dx(jatom),nm,rhs)
tec(jatom,jspin) = sume - rhs
WRITE (6,FMT=8030) jatom,jspin,tec(jatom,jspin),sume
WRITE (16,FMT=8030) jatom,jspin,tec(jatom,jspin),sume
! ---> simpson integration
rad = atoms%rmt(jatom)
q = rad*rhoss(nm)/2.
DO nm1 = nm + 1,ncmsh - 1,2
rad = d*rad
q = q + 2*rad*rhoss(nm1)
rad = d*rad
q = q + rad*rhoss(nm1+1)
ENDDO
q = 2*q*dxx/3
!+sb
WRITE (6,FMT=8020) q/input%jspins
WRITE (16,FMT=8020) q/input%jspins
!-sb
qint(jatom,jspin) = q*atoms%neq(jatom)
attributes = ''
WRITE(attributes(1),'(i0)') jatom
WRITE(attributes(2),'(i0)') NINT(z)
WRITE(attributes(3),'(i0)') jspin
WRITE(attributes(4),'(f18.10)') tec(jatom,jspin)
WRITE(attributes(5),'(f18.10)') sume
WRITE(attributes(6),'(f9.6)') q/input%jspins
CALL openXMLElementForm('coreStates',(/'atomType ','atomicNumber ','spin ','kinEnergy ',&
'eigValSum ','lostElectrons'/),&
attributes,RESHAPE((/8,12,4,9,9,13,6,3,1,18,18,9/),(/6,2/)))
DO korb = 1, atoms%ncst(jatom)
fj = iabs(kappa(korb)) - .5e0
weight = 2*fj + 1.e0
IF (bmu > 99.) weight = occ(korb)
fl = fj + (.5e0)*isign(1,kappa(korb))
attributes = ''
WRITE(attributes(1),'(i0)') nprnc(korb)
WRITE(attributes(2),'(i0)') NINT(fl)
WRITE(attributes(3),'(f4.1)') fj
WRITE(attributes(4),'(f20.10)') stateEnergies(korb)
WRITE(attributes(5),'(f15.10)') weight
CALL writeXMLElementForm('state',(/'n ','l ','j ','energy','weight'/),&
attributes(1:5),RESHAPE((/1,1,1,6,6,2,2,4,20,15/),(/5,2/)))
END DO
CALL closeXMLElement('coreStates')
ENDDO
! ---> simpson integration
rad = atoms%rmt(jatom)
q = rad*rhoss(nm)/2.
DO nm1 = nm + 1,ncmsh - 1,2
rad = d*rad
q = q + 2*rad*rhoss(nm1)
rad = d*rad
q = q + rad*rhoss(nm1+1)
ENDDO
q = 2*q*dxx/3
!+sb
WRITE (6,FMT=8020) q/input%jspins
WRITE (16,FMT=8020) q/input%jspins
!-sb
qint(jatom,jspin) = q*atoms%neq(jatom)
attributes = ''
WRITE(attributes(1),'(i0)') jatom
WRITE(attributes(2),'(i0)') NINT(z)
WRITE(attributes(3),'(i0)') jspin
WRITE(attributes(4),'(f18.10)') tec(jatom,jspin)
WRITE(attributes(5),'(f18.10)') sume
WRITE(attributes(6),'(f9.6)') q/input%jspins
CALL openXMLElementForm('coreStates',(/'atomType ','atomicNumber ','spin ','kinEnergy ',&
'eigValSum ','lostElectrons'/),&
attributes,RESHAPE((/8,12,4,9,9,13,