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mlwf.patch
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mlwf.patch
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diff -bruN src/mlwf.F ../vasp.5.4.4_mod/src/mlwf.F
--- src/mlwf.F 2017-04-20 10:03:58.000000000 +0100
+++ ../vasp.5.4.4_mod/src/mlwf.F 2020-07-05 21:52:18.430979695 +0100
@@ -6,12 +6,26 @@
! write the wave functions to UNK files
LOGICAL, PRIVATE, SAVE :: WRITE_UNK
+ LOGICAL, PRIVATE, SAVE :: UNK_FMTED
+ LOGICAL, PRIVATE, SAVE :: REDUCE_UNK
+
+ ! write the wave functions to UNK files
+ LOGICAL, PRIVATE, SAVE :: WRITE_SPN
+ LOGICAL, PRIVATE, SAVE :: SPN_FMTED
+
! write the mmn and amn files when WANNIER90 runs in lib mode
- LOGICAL, PRIVATE, SAVE :: WRITE_MMN_AMN
+ LOGICAL, PRIVATE, SAVE :: CALC_MMN
+ LOGICAL, PRIVATE, SAVE :: CALC_AMN
+ LOGICAL, PRIVATE, SAVE :: WRITE_MMN
+ LOGICAL, PRIVATE, SAVE :: WRITE_AMN
+ LOGICAL, PRIVATE, SAVE :: WRITE_EIG
! read amn file instead of computing it
LOGICAL, PRIVATE, SAVE :: READ_AMN
+ ! which collinear spin channel do we want?
+ INTEGER, PRIVATE, SAVE :: W90_SPIN
+
! wannier90_run variables: output
COMPLEX(q), ALLOCATABLE, SAVE :: U_matrix(:,:,:,:)
COMPLEX(q), ALLOCATABLE, SAVE :: U_matrix_opt(:,:,:,:)
@@ -185,6 +199,20 @@
! Switch on the PEAD routines
CALL PEAD_REQUEST
+ ! spin channel
+ W90_SPIN=0
+ CALL RDATAB(.FALSE.,INCAR,IU5,'W90_SPIN','=','#',';','I', &
+ & W90_SPIN,RDUM,CDUM,LDUM,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LWRITE_UNK'' from file INCAR.'
+ W90_SPIN=0
+ IF (W90_SPIN/=0 .AND. W90_SPIN/=1 .AND. W90_SPIN/=2) &
+ WRITE(IU0,*)'Error reading item ''LWRITE_UNK'' from file INCAR.'
+ W90_SPIN=0
+ ENDIF
+
! Do we want to write UNK files?
WRITE_UNK=.FALSE.
CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_UNK','=','#',';','L', &
@@ -195,17 +223,119 @@
WRITE(IU0,*)'Error reading item ''LWRITE_UNK'' from file INCAR.'
WRITE_UNK=.FALSE.
ENDIF
+
+ ! 2020-06-22 CCX: added to determine UNK is formatted or not
+ UNK_FMTED=.FALSE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LUNK_FMTED','=','#',';','L', &
+ & IDUM,RDUM,CDUM,UNK_FMTED,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LUNK_FMTED'' from file INCAR.'
+ UNK_FMTED=.FALSE.
+ ENDIF
+
+ ! 2020-07-04 CCX: added to determine UNK is formatted or not
+ REDUCE_UNK=.FALSE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LREDUCE_UNK','=','#',';','L', &
+ & IDUM,RDUM,CDUM,REDUCE_UNK,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LREDUCE_UNK'' from file INCAR.'
+ REDUCE_UNK=.FALSE.
+ ENDIF
+
+ ! 2020-06-25 CCX: Do we want to write the spn file?
+ WRITE_SPN=.FALSE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_SPN','=','#',';','L', &
+ & IDUM,RDUM,CDUM,WRITE_SPN,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LWRITE_SPN'' from file INCAR.'
+ WRITE_SPN=.FALSE.
+ ENDIF
+
+ ! 2020-06-25 CCX: Do we want to write the spn file?
+ SPN_FMTED=.FALSE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LSPN_FMTED','=','#',';','L', &
+ & IDUM,RDUM,CDUM,SPN_FMTED,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LSPN_FMTED'' from file INCAR.'
+ SPN_FMTED=.FALSE.
+ ENDIF
+
+
! Do we want to write the mmn and amn files
! even though WANNIER90 runs in library mode?
- WRITE_MMN_AMN=.NOT.LWANNIER90_RUN
- CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_MMN_AMN','=','#',';','L', &
- & IDUM,RDUM,CDUM,WRITE_MMN_AMN,CHARAC,N,1,IERR)
+ ! 2020-07-04 CCX: do we really need to calculate MMN AMN and write EIG?
+ CALC_MMN=.TRUE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LCALC_MMN','=','#',';','L', &
+ & IDUM,RDUM,CDUM,CALC_MMN,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LCALC_MMN'' from file INCAR.'
+ ! this is counterintuitive, we want to calculate MMN by default
+ CALC_MMN=.TRUE.
+ ENDIF
+ ! if wannier90_run, we need mmn calculation
+ IF ((LWANNIER90_RUN) .AND. (.NOT.CALC_MMN)) CALC_MMN=.TRUE.
+
+
+ WRITE_MMN=.NOT.LWANNIER90_RUN
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_MMN','=','#',';','L', &
+ & IDUM,RDUM,CDUM,WRITE_MMN,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LWRITE_MMN'' from file INCAR.'
+ WRITE_MMN=.NOT.LWANNIER90_RUN
+ ENDIF
+ ! if we dont calculate mmn, we cannot write amn...
+ IF (.NOT.CALC_MMN) WRITE_MMN=.FALSE.
+
+
+ CALC_AMN=.TRUE.
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LCALC_AMN','=','#',';','L', &
+ & IDUM,RDUM,CDUM,CALC_AMN,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LCALC_AMN'' from file INCAR.'
+ ! this is counterintuitive, we want to calculate MMN by default
+ CALC_AMN=.TRUE.
+ ENDIF
+ ! if wannier90_run, we need amn calculation
+ IF ((LWANNIER90_RUN) .AND. (.NOT.CALC_AMN)) CALC_AMN=.TRUE.
+
+ WRITE_AMN=.NOT.LWANNIER90_RUN
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_AMN','=','#',';','L', &
+ & IDUM,RDUM,CDUM,WRITE_AMN,CHARAC,N,1,IERR)
IF (((IERR/=0).AND.(IERR/=3)).OR. &
& ((IERR==0).AND.(N<1))) THEN
IF (IU0>=0) &
- WRITE(IU0,*)'Error reading item ''LWRITE_MMN_AMN'' from file INCAR.'
- WRITE_MMN_AMN=.NOT.LWANNIER90_RUN
+ WRITE(IU0,*)'Error reading item ''LWRITE_AMN'' from file INCAR.'
+ WRITE_AMN=.NOT.LWANNIER90_RUN
ENDIF
+ ! if we dont calculate amn, we cannot write amn...
+ IF (.NOT.CALC_AMN) WRITE_AMN=.FALSE.
+
+
+ WRITE_EIG=.NOT.LWANNIER90_RUN
+ CALL RDATAB(.FALSE.,INCAR,IU5,'LWRITE_EIG','=','#',';','L', &
+ & IDUM,RDUM,CDUM,WRITE_EIG,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IU0>=0) &
+ WRITE(IU0,*)'Error reading item ''LWRITE_EIG'' from file INCAR.'
+ WRITE_EIG=.NOT.LWANNIER90_RUN
+ ENDIF
+
+
! Do we want to read the amn file instead of
! computing it anew?
READ_AMN=.FALSE.
@@ -320,6 +450,9 @@
REAL(q), ALLOCATABLE :: proj_x(:,:)
REAL(q), ALLOCATABLE :: proj_zona(:)
INTEGER, ALLOCATABLE :: exclude_bands(:)
+ ! CCX_2019-05-05: define proj_s and proj_s_qaxis
+ INTEGER, ALLOCATABLE :: proj_s(:)
+ REAL(q), ALLOCATABLE :: proj_s_qaxis(:,:)
! wannier90_run variables: input
COMPLEX(q), ALLOCATABLE :: M_matrix(:,:,:,:,:)
COMPLEX(q), ALLOCATABLE :: A_matrix(:,:,:,:)
@@ -329,6 +462,12 @@
INTEGER NI,MI,NK,NKP,ICNTR
INTEGER NKI,NKJ,ISP,ISPINOR,L,M,N,NP
INTEGER NEXCLB,NPROJ
+ ! CCX_2019-05-06: spin quantization local variables
+ LOGICAL spin_z_pos,spin_z_neg
+ COMPLEX(q) FAC(2)
+ REAL(q) :: eps6=0.000001_q
+ REAL(q) xnorm
+ ! CCX_2019-05-06: end definition
REAL(q) POS(3)
REAL(q) KI(3),KJ(3)
INTEGER IDUM,IERR
@@ -347,6 +486,13 @@
REAL(q), ALLOCATABLE :: ROTYLM(:,:)
REAL(q), ALLOCATABLE :: HYBRID_ORBITAL(:)
+ ! 2020-06-25 CCX added for spn matrix calc
+ GDEF, ALLOCATABLE :: SPN(:,:,:)
+ GDEF, ALLOCATABLE :: spin_mat(:,:)
+ INTEGER :: spn_counter
+ CHARACTER (len=60) :: SPN_header
+ ! CCX_2019-05-06: end definition
+
LOGICAL, ALLOCATABLE :: EXCLUDE_BAND(:)
LOGICAL LUSE_BLOCH_PHASES
@@ -357,20 +503,38 @@
INTEGER num_bands_on_file,num_kpts_on_file,NPROJ_on_file
IF (.NOT.WANNIER90()) RETURN
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "*---------------------------------------*"
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "* VASP2WANNIER90 *"
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "*---------------------------------------*"
-#ifdef MPI
+ ! 2020-06-28 CCX: I moved this to here so we can have control over collinear spin channels.
+ ! loop over spin
+ spin: DO ISP=1,WDES%ISPIN
+
+ IF ((.not. WDES%LNONCOLLINEAR) .AND. (W90_SPIN==2) .AND. (ISP==1)) CYCLE spin
+ IF ((.not. WDES%LNONCOLLINEAR) .AND. (W90_SPIN==1) .AND. (ISP==2)) CYCLE spin
+ IF ((.not. WDES%LNONCOLLINEAR) .AND. (WDES%ISPIN==2) .AND. (IO%IU0>=0)) &
+ WRITE(IO%IU0,*)'* Collinear spin -> '//SP(ISP)//' *'
+ IF ((WDES%LNONCOLLINEAR) .AND. (IO%IU0>=0)) &
+ WRITE(IO%IU0,*)'* Non-collinear spin *'
+ IF ((.not. WDES%LNONCOLLINEAR) .AND. (WDES%ISPIN==1) .AND. (IO%IU0>=0)) &
+ WRITE(IO%IU0,*)'* No spin polarization *'
+
+!#ifdef MPI
! IF (WDES%COMM_KINTER%NCPU.NE.1) THEN
! CALLMPI( M_stop('MLWF_WANNIER90: KPAR>1 not implemented, sorry.') )
! STOP
! END IF
-#endif
+!#endif
+
+! 2020-06-22 CCX: wannier90 CAN plot spinors.
! WANNIER90 cannot plot spinors
- IF (WRITE_UNK.AND.WDES%LNONCOLLINEAR) THEN
- IF (IO%IU0>=0) WRITE(IO%IU0,*) &
- & 'MLWF_WANNIER90: ERROR: will not write spinors to UNK files, sorry ...'
- WRITE_UNK=.FALSE.
- ENDIF
-!
+! IF (WRITE_UNK.AND.WDES%LNONCOLLINEAR) THEN
+! IF (IO%IU0>=0) WRITE(IO%IU0,*) &
+! & 'MLWF_WANNIER90: ERROR: will not write spinors to UNK files, sorry ...'
+! WRITE_UNK=.FALSE.
+! ENDIF
+
! allocation
ALLOCATE(S(WDES%NB_TOT,WDES%NB_TOT))
@@ -422,8 +586,25 @@
! A minimal wannier90.win file must exist; it must at least
! contain the keyword "num_wann"
IF (IO%IU6>=0) THEN
+ IF ((.not. spinors) .AND. (WDES%ISPIN==2)) THEN
+ INQUIRE(FILE=seed_name//'.'//SP(ISP)//'.win',EXIST=LWIN_FOUND)
+ ELSE
INQUIRE(FILE=seed_name//'.win',EXIST=LWIN_FOUND)
+ ENDIF
+
IF (LWIN_FOUND) THEN
+ IF ((.not. spinors) .AND. (WDES%ISPIN==2)) THEN
+ OPEN(UNIT=99,FILE=seed_name//'.'//SP(ISP)//'.win',STATUS='OLD')
+ CALL RDATAB(.FALSE.,seed_name//'.'//SP(ISP)//'.win',99,'num_wann','=','#',';','I', &
+ & IDUM,RDUM,CDUM,LDUM,CHARAC,N,1,IERR)
+ IF (((IERR/=0).AND.(IERR/=3)).OR. &
+ & ((IERR==0).AND.(N<1))) THEN
+ IF (IO%IU0>=0) &
+ WRITE(IO%IU0,*)'Error reading item ''num_wann'' from file '//seed_name//'.win'
+ STOP
+ ENDIF
+ IF (IERR==3) WRITE(99,'(A,I6,2X,A)') ' num_wann =',WDES%NB_TOT,'! set to NBANDS by VASP'
+ ELSE
OPEN(UNIT=99,FILE=seed_name//'.win',STATUS='OLD')
CALL RDATAB(.FALSE.,seed_name//'.win',99,'num_wann','=','#',';','I', &
& IDUM,RDUM,CDUM,LDUM,CHARAC,N,1,IERR)
@@ -434,10 +615,16 @@
STOP
ENDIF
IF (IERR==3) WRITE(99,'(A,I6,2X,A)') ' num_wann =',WDES%NB_TOT,'! set to NBANDS by VASP'
+ ENDIF
+ ELSE
+ IF ((.not. spinors) .AND. (WDES%ISPIN==2)) THEN
+ OPEN(UNIT=99,FILE=seed_name//'.'//SP(ISP)//'.win',STATUS='REPLACE')
+ WRITE(99,'(A,I6,2X,A)') ' num_wann =',WDES%NB_TOT,'! set to NBANDS by VASP'
ELSE
OPEN(UNIT=99,FILE=seed_name//'.win',STATUS='REPLACE')
WRITE(99,'(A,I6,2X,A)') ' num_wann =',WDES%NB_TOT,'! set to NBANDS by VASP'
ENDIF
+ ENDIF
CLOSE(99)
ENDIF
@@ -449,18 +636,47 @@
ALLOCATE(proj_site(3,num_bands_tot),proj_l(num_bands_tot),proj_m(num_bands_tot), &
& proj_radial(num_bands_tot),proj_z(3,num_bands_tot),proj_x(3,num_bands_tot), &
- & proj_zona(num_bands_tot),exclude_bands(num_bands_tot))
+ & proj_zona(num_bands_tot),exclude_bands(num_bands_tot), &
+#ifdef VASP2WANNIER90v2
+! CCX_2019-05-05: allocate proj_s and proj_s_qaxis.
+ & proj_s(num_bands_tot),proj_s_qaxis(3,num_bands_tot) &
+#endif
+ & )
proj_site=0; proj_l=0; proj_m=0; proj_radial=0; proj_z=0; proj_x=0; proj_zona=0; exclude_bands=0
+! CCX_2019-05-05: initialize proj_s and proj_s_qaxis.
+#ifdef VASP2WANNIER90v2
+ proj_s=0; proj_s_qaxis=0
+#endif
+
! Only one node will do the actual work,
! otherwise all will write to wannier90.wout
#ifdef VASP2WANNIER90
- IF (IO%IU6>=0) &
+ IF (IO%IU6>=0) THEN
+ IF ((.not.spinors) .AND. (WDES%ISPIN==2)) THEN
+ CALL wannier_setup(seed_name//'.'//SP(ISP),mp_grid,num_kpts,real_lattice,recip_lattice, &
+ & kpt_latt,num_bands_tot,num_atoms,atom_symbols,atoms_cart, &
+ & gamma_only,spinors,nntot,nnlist,nncell,num_bands,num_wann, &
+ & proj_site,proj_l,proj_m,proj_radial,proj_z,proj_x,proj_zona, &
+ & exclude_bands, &
+#ifdef VASP2WANNIER90v2
+! CCX_2019-05-05: call wannier_setup to calculate proj_s and proj_s_qaxis
+ & proj_s,proj_s_qaxis &
+#endif
+ & )
+ ELSE
CALL wannier_setup(seed_name,mp_grid,num_kpts,real_lattice,recip_lattice, &
& kpt_latt,num_bands_tot,num_atoms,atom_symbols,atoms_cart, &
& gamma_only,spinors,nntot,nnlist,nncell,num_bands,num_wann, &
& proj_site,proj_l,proj_m,proj_radial,proj_z,proj_x,proj_zona, &
- & exclude_bands)
+ & exclude_bands, &
+#ifdef VASP2WANNIER90v2
+! CCX_2019-05-05: call wannier_setup to calculate proj_s and proj_s_qaxis
+ & proj_s,proj_s_qaxis &
+#endif
+ & )
+ ENDIF
+ ENDIF
#endif
! Now communicate the output to the other nodes
CALLMPI( M_sum_i(WDES%COMM,nntot,1) )
@@ -476,6 +692,11 @@
CALLMPI( M_sum_d(WDES%COMM,proj_x,3*num_bands_tot) )
CALLMPI( M_sum_d(WDES%COMM,proj_zona,num_bands_tot) )
CALLMPI( M_sum_i(WDES%COMM,exclude_bands,num_bands_tot) )
+! CCX_2019-05-05: bcast proj_s and proj_s_qaxis
+#ifdef VASP2WANNIER90v2
+ CALLMPI( M_sum_i(WDES%COMM,proj_s,num_bands_tot) )
+ CALLMPI( M_sum_d(WDES%COMM,proj_s_qaxis,3*num_bands_tot) )
+#endif
ALLOCATE(EXCLUDE_BAND(num_bands_tot))
EXCLUDE_BAND=.FALSE. ; NEXCLB=0
@@ -530,10 +751,7 @@
! nullify pointers by default
R%R=>NULL(); R%SI=>NULL()
- ! loop over spin
- spin: DO ISP=1,WDES%ISPIN
-
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) THEN
+ IF (IO%IU6>=0.AND.WRITE_MMN) THEN
IF (WDES%ISPIN==1) THEN
OPEN(UNIT=99,FILE=seed_name//'.mmn',STATUS='REPLACE')
ELSE
@@ -542,6 +760,9 @@
WRITE(99,'(A)') 'File generated by VASP: '//INFO%SZNAM1
WRITE(99,'(3I12)') num_bands,num_kpts,nntot
ENDIF
+
+ ! 2020-07-04 CCX: do we want to calculate mmn matrix
+ IF (CALC_MMN) THEN
! runs over all k-points
ki_loop: DO NKI=1,num_kpts
KI(:)=kpt_latt(:,NKI)
@@ -553,7 +774,7 @@
#endif
CALL PEAD_CALC_OVERLAP(W,KI,KJ,ISP,P,CQIJ,LATT_CUR,T_INFO,S,LQIJB=.TRUE.)
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) WRITE(99,'(5I5)') NKI,nnlist(NKI,NKJ),nncell(:,NKI,NKJ)
+ IF (IO%IU6>=0.AND.WRITE_MMN) WRITE(99,'(5I5)') NKI,nnlist(NKI,NKJ),nncell(:,NKI,NKJ)
NI=0
n_loop: DO N=1,WDES%NB_TOT
@@ -563,7 +784,7 @@
IF (EXCLUDE_BAND(M)) CYCLE m_loop
MI=MI+1
M_matrix(MI,NI,NKJ,NKI,ISP)=S(M,N)
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) WRITE(99,'(2F18.12)') S(M,N)
+ IF (IO%IU6>=0.AND.WRITE_MMN) WRITE(99,'(2F18.12)') S(M,N)
ENDDO m_loop
ENDDO n_loop
! check consistency
@@ -575,7 +796,82 @@
ENDDO kj_loop
ENDDO ki_loop
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) CLOSE(99)
+ IF (IO%IU6>=0.AND.WRITE_MMN) CLOSE(99)
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "* MMN calculated. *"
+ !2020-07-04
+ ENDIF
+
+
+ ! 2020-06-25 CCX: write SPN matrix
+ IF (WRITE_SPN .AND. (.NOT. spinors)) THEN
+ IF (IO%IU0>=0) WRITE(*,*) 'MLWF_WANNIER90: WRITE_SPN only works in non-collinear, skipping.'
+ WRITE_SPN=.FALSE.
+ ENDIF
+
+ IF (WRITE_SPN .AND. WDES%COMM%NCPU.NE.1) THEN
+ IF (IO%IU0>=0) WRITE(*,*) 'MLWF_WANNIER90: WRITE_SPN only works in serial, skipping.'
+ WRITE_SPN=.FALSE.
+ ENDIF
+
+ IF (IO%IU6>=0.AND.WRITE_SPN) THEN
+ IF (WDES%NRSPINORS==1) THEN
+ IF (IO%IU0>=0) WRITE(*,*) 'MLWF_WANNIER90: ERROR: WRITE_SPN specified, but collinear calculation.'
+ STOP
+ ELSE
+ IF (SPN_FMTED) THEN
+ OPEN(UNIT=99,FILE=seed_name//'.spn',FORM="FORMATTED",STATUS='REPLACE')
+ SPN_header = 'File generated by VASP: '//INFO%SZNAM1
+ WRITE(99,'(A)') SPN_header
+ WRITE(99,'(3I12)') num_bands,num_kpts
+ ELSE
+ OPEN(UNIT=99,FILE=seed_name//'.spn',FORM="UNFORMATTED",STATUS='REPLACE')
+ SPN_header = 'File generated by VASP: '//INFO%SZNAM1
+ WRITE(99) SPN_header
+ WRITE(99) num_bands,num_kpts
+ ENDIF
+ ENDIF
+ ENDIF
+
+ IF (WDES%NRSPINORS/=1.AND.WRITE_SPN) THEN
+ ALLOCATE(spin_mat((num_bands+1)*num_bands/2,3))
+ ALLOCATE(SPN(WDES%NB_TOT,WDES%NB_TOT,3))
+ ! runs over all k-points
+ spn_ki_loop: DO NKI=1,num_kpts
+ KI(:)=kpt_latt(:,NKI)
+
+ CALL CALC_SPN_EXP(W,KI,P,CQIJ,LATT_CUR,T_INFO,SPN)
+
+ !now, we nned to exclude some bands.
+ NI=0
+ spn_n_loop: DO N=1,WDES%NB_TOT
+ IF (EXCLUDE_BAND(N)) CYCLE spn_n_loop
+ spn_m_loop: DO M=1,N
+ IF (EXCLUDE_BAND(M)) CYCLE spn_m_loop
+ NI=NI+1
+ DO spn_counter=1,3
+ spin_mat(NI,spn_counter)=SPN(M,N,spn_counter)
+ ENDDO
+ ENDDO spn_m_loop
+ ENDDO spn_n_loop
+
+ ! writing spn matrix to file
+ IF (SPN_FMTED) THEN
+ DO N=1,(num_bands+1)*num_bands/2
+ IF (IO%IU6>=0.AND.WRITE_SPN) WRITE(99,'(2ES26.16)') (spin_mat(N,spn_counter), spn_counter=1,3)
+ ENDDO
+ ELSE
+ IF (IO%IU6>=0.AND.WRITE_SPN) WRITE(99) ((spin_mat(N,spn_counter), spn_counter=1,3), N=1,(num_bands+1)*num_bands/2)
+ ENDIF
+ ENDDO spn_ki_loop
+
+ ! some deallocation for spn mat
+ DEALLOCATE(spin_mat)
+ DEALLOCATE(SPN)
+
+ IF (IO%IU6>=0.AND.WRITE_SPN) CLOSE(99)
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "* SPN calculated. *"
+ ENDIF
+ ! 2020-06-25 CCX: spin matrix calculated
! and we might want to read an existing amn file
IF (READ_AMN) THEN
@@ -584,9 +880,16 @@
DO ISPINOR=1,WDES%NRSPINORS
DO ICNTR=1,num_bands_tot
IF (proj_l(ICNTR)==0.AND.proj_m(ICNTR)==0.AND.proj_radial(ICNTR)==0) CYCLE
+! CCX_2019-05-05: only calculate corresponding spin channel
+#ifdef VASP2WANNIER90v2
+ IF (WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==1.AND.ISPINOR==2) CYCLE
+ IF (WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==-1.AND.ISPINOR==1) CYCLE
+#endif
+
NPROJ=NPROJ+1
ENDDO
ENDDO
+
! check if amn file exists
IF (WDES%ISPIN==1) THEN
INQUIRE(FILE=seed_name//'.amn',EXIST=LAMN_FOUND)
@@ -627,7 +930,8 @@
ENDIF
ENDIF ! finished reading A_matrix
- IF (.NOT.READ_AMN) THEN
+ ! 2020-07-04 CCX: added to control amn calculaiton
+ IF ( .NOT. READ_AMN .AND. CALC_AMN) THEN
! we need to calculate the projection of the wave functions
! onto a set of trial functions {g}: A(m,n,i) = < \psi_m,k_i | g_n >
! A(m,n,i) is then written to the file seed_name.amn
@@ -643,11 +947,36 @@
ALLOCATE(ROTYLM((LMAX+1)**2,(LMAX+1)**2),HYBRID_ORBITAL((LMAX+1)**2))
NPROJ=0
-! CALL START_TIMING("T1")
+ ! CCX_2020-06-15: initialize A matrix
+ A_matrix=0
! runs over all projector sites
- spinor: DO ISPINOR=1,WDES%NRSPINORS
sites : DO ICNTR=1,num_bands_tot
IF (proj_l(ICNTR)==0.AND.proj_m(ICNTR)==0.AND.proj_radial(ICNTR)==0) CYCLE sites
+ ! CCX_2019-05-06: determin spin quantization axis along z axis or not.
+ spin_z_pos=.false.
+ spin_z_neg=.false.
+ ! CCX_2019-06-10: renormalize spin quantization axis
+ xnorm=SQRT(proj_s_qaxis(1,ICNTR)*proj_s_qaxis(1,ICNTR)+proj_s_qaxis(2,ICNTR)*proj_s_qaxis(2,ICNTR)+proj_s_qaxis(3,ICNTR)*proj_s_qaxis(3,ICNTR))
+ proj_s_qaxis(1,ICNTR)=proj_s_qaxis(1,ICNTR)/xnorm
+ proj_s_qaxis(2,ICNTR)=proj_s_qaxis(2,ICNTR)/xnorm
+ proj_s_qaxis(3,ICNTR)=proj_s_qaxis(3,ICNTR)/xnorm
+
+ IF ((abs(proj_s_qaxis(1,ICNTR)-0.0d0)<eps6).and.(abs(proj_s_qaxis(2,ICNTR)-0.0d0)<eps6) &
+ .and.(abs(proj_s_qaxis(3,ICNTR)-1.0d0)<eps6)) then
+ spin_z_pos=.true.
+ ELSEIF(abs(proj_s_qaxis(1,ICNTR)-0.0d0)<eps6.and.abs(proj_s_qaxis(2,ICNTR)-0.0d0)<eps6 &
+ .and.abs(proj_s_qaxis(3,ICNTR)+1.0d0)<eps6) then
+ spin_z_neg=.true.
+ ENDIF
+ ! CCX_2019-05-06: [start] if proj_s_qaxis lies along z, normal projections are done.
+ IF (spin_z_pos .OR. spin_z_neg .OR. WDES%NRSPINORS==1) THEN ! if not spinor, still use this routine.
+ spinor1: DO ISPINOR=1,WDES%NRSPINORS
+ IF (spin_z_pos.AND.WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==1.AND.ISPINOR==2) CYCLE spinor1
+ IF (spin_z_pos.AND.WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==-1.AND.ISPINOR==1) CYCLE spinor1
+ ! if neg then swap up and down definition
+ IF (spin_z_neg.AND.WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==1.AND.ISPINOR==1) CYCLE spinor1
+ IF (spin_z_neg.AND.WDES%NRSPINORS/=1.AND.proj_s(ICNTR)==-1.AND.ISPINOR==2) CYCLE spinor1
+
NPROJ=NPROJ+1
! setup the Ylm rotation matrix in accordance with proj_z and proj_x
CALL SETROTYLM(proj_x(:,ICNTR),proj_z(:,ICNTR),LMAX,ROTYLM)
@@ -673,9 +1002,9 @@
ENDDO
-! CALL START_TIMING("T2")
+ ! CALL START_TIMING("T2")
! runs over all k-points
- kpoints : DO NKI=1,num_kpts
+ kpoints1 : DO NKI=1,num_kpts
CALL CALC_OVERLAP_GN( &
& LMAX,FG,proj_site(:,ICNTR),W,kpt_latt(:,NKI),ISP,ISPINOR,P,CQIJ,LATT_CUR,T_INFO,A)
! and rotate them in accordance with proj_z and proj_x
@@ -712,15 +1041,111 @@
A_matrix(MI,NPROJ,NKI,ISP)=CPROJ
ENDDO
+ ENDDO kpoints1
+
+ DEALLOCATE(FTMP,FR,FGTMP,FG)
+
+ IF (IO%IU0>=0) WRITE(IO%IU0,'(X,A,I3,A)') '* Projection ',NPROJ,' done. *'
+ ! CALL STOP_TIMING("T2",IO%IU6,' OVL')
+ ! CALL STOP_TIMING("T1",IO%IU6,'ICNTR')
+ ENDDO spinor1
+ ! CCX_2019-05-06: [end] end normal routine.
+
+ ELSE ! CCX_2019-05-06: quantization axis does not lies along z axis, do special projection routine.
+ ! CCX_2019-05-06: generate spinor eigenvectors.
+ ! CCX_2019-06-10: renormalize spin quantization axis
+ xnorm=SQRT(proj_s_qaxis(1,ICNTR)*proj_s_qaxis(1,ICNTR)+proj_s_qaxis(2,ICNTR)*proj_s_qaxis(2,ICNTR)+proj_s_qaxis(3,ICNTR)*proj_s_qaxis(3,ICNTR))
+ proj_s_qaxis(1,ICNTR)=proj_s_qaxis(1,ICNTR)/xnorm
+ proj_s_qaxis(2,ICNTR)=proj_s_qaxis(2,ICNTR)/xnorm
+ proj_s_qaxis(3,ICNTR)=proj_s_qaxis(3,ICNTR)/xnorm
+
+ IF (proj_s(ICNTR)==1) THEN ! up channel
+ FAC(1)=(1.0d0/SQRT(1+proj_s_qaxis(3,ICNTR)))*(proj_s_qaxis(3,ICNTR)+1)*CMPLX(1.0d0,0.0d0,q)
+ FAC(2)=(1.0d0/SQRT(1+proj_s_qaxis(3,ICNTR)))*CMPLX(proj_s_qaxis(1,ICNTR),proj_s_qaxis(2,ICNTR),q)
+ NPROJ=NPROJ+1
+ ELSE ! down channel
+ FAC(1)=(1.0d0/SQRT(1-proj_s_qaxis(3,ICNTR)))*(proj_s_qaxis(3,ICNTR)-1)*CMPLX(1.0d0,0.0d0,q)
+ FAC(2)=(1.0d0/SQRT(1-proj_s_qaxis(3,ICNTR)))*CMPLX(proj_s_qaxis(1,ICNTR),proj_s_qaxis(2,ICNTR),q)
+ NPROJ=NPROJ+1
+ ENDIF
+
+ ! 2020-06-15 CCX: we no longer need ISPINOR loop since we are using full spinor guiding functions.
+ !spinor: DO ISPINOR=1,WDES%NRSPINORS
+ ! setup the Ylm rotation matrix in accordance with proj_z and proj_x
+ CALL SETROTYLM(proj_x(:,ICNTR),proj_z(:,ICNTR),LMAX,ROTYLM)
+#ifdef debug
+ IF (IO%IU6>=0) THEN
+ WRITE(*,'(I4,3F14.7)') ICNTR,proj_site(1:3,ICNTR)
+ DO N=10,MIN((LMAX+1)**2,16)
+ WRITE(*,'(9F10.5)') (ROTYLM(N,M),M=10,MIN((LMAX+1)**2,16))
+ ENDDO
+ ENDIF
+#endif
+ ! translate between VASP and the orbital definition of wannier90
+ CALL WANNIER90_ORBITAL_DEFINITIONS(proj_l(ICNTR),proj_m(ICNTR),HYBRID_ORBITAL)
+
+ ! setup the radial functions (real space)
+ CALL SETRGRID(RSTART/proj_zona(ICNTR),REND,H,R)
+ ALLOCATE(FTMP(R%NMAX),FR(R%NMAX,LMAX+1))
+ ALLOCATE(FGTMP(NMAX,5),FG(NMAX,5,LMAX+1))
+
+ ! For now we use the same radial function for all L
+ DO L=0,LMAX
+ CALL RADIAL_FUNCTION(proj_radial(ICNTR),R,proj_zona(ICNTR),FTMP)
+ CALL BESSEL_TRANSFORM_RADIAL_FUNCTION(L,R,FTMP,REAL(SQRT(2._q*INFO%ENMAX/HSQDTM)/NMAX,KIND=q),FGTMP)
+ FR(:,L+1)=FTMP; FG(:,:,L+1)=FGTMP
+ ENDDO
+
+ ! CALL START_TIMING("T2")
+ ! runs over all k-points
+ kpoints : DO NKI=1,num_kpts
+ CALL CALC_OVERLAP_GN_ALL( &
+ & LMAX,FG,proj_site(:,ICNTR),W,kpt_latt(:,NKI),ISP,FAC,P,CQIJ,LATT_CUR,T_INFO,A)
+ ! and rotate them in accordance with proj_z and proj_x
+ AP=0
+ DO M=1,WDES%NB_TOT
+ DO N=1,(LMAX+1)**2
+ DO NP=1,(LMAX+1)**2
+ AP(M,N)=AP(M,N)+A(M,NP)*ROTYLM(N,NP)
+ ENDDO
+ ENDDO
+ ENDDO
+#ifdef debug
+ IF (IO%IU6>=0) THEN
+ WRITE(*,'(I4,3F14.7)') NKI,kpt_latt(1:3,NKI)
+ DO M=1,WDES%NB_TOT
+ WRITE(*,'(4(2F14.7,2X))') (A(M,N),N=1,4)
+ ENDDO
+ WRITE(*,*)
+ DO M=1,WDES%NB_TOT
+ WRITE(*,'(4(2F14.7,2X))') (AP(M,N),N=1,4)
+ ENDDO
+ WRITE(*,*)
+ ENDIF
+#endif
+ ! Make the desired linear combinations
+ MI=0
+ DO M=1,WDES%NB_TOT
+ IF (EXCLUDE_BAND(M)) CYCLE
+ CPROJ=0
+ DO N=1,(LMAX+1)**2
+ CPROJ=CPROJ+AP(M,N)*HYBRID_ORBITAL(N)
+ ENDDO
+ MI=MI+1
+ A_matrix(MI,NPROJ,NKI,ISP)=CPROJ
+ ENDDO
+
ENDDO kpoints
DEALLOCATE(FTMP,FR,FGTMP,FG)
- IF (IO%IU0>=0) WRITE(IO%IU0,'(X,A,I3,A)') 'Projection ',NPROJ,' done.'
-! CALL STOP_TIMING("T2",IO%IU6,' OVL')
-! CALL STOP_TIMING("T1",IO%IU6,'ICNTR')
+ ! IF (IO%IU0>=0) WRITE(IO%IU0,'(X,A,I3,A,I3,A)') 'Spin channel',ISPINOR,' done.'
+ ! CALL STOP_TIMING("T2",IO%IU6,' OVL')
+ ! CALL STOP_TIMING("T1",IO%IU6,'ICNTR')
+ !ENDDO spinor
+ IF (IO%IU0>=0) WRITE(IO%IU0,'(X,A,I3,A)') '* Projection ',NPROJ,' done. [q_axis changed] *'
+ ENDIF ! quantization IF
ENDDO sites
- ENDDO spinor
DEALLOCATE(A,AP,ROTYLM,HYBRID_ORBITAL)
@@ -733,13 +1158,14 @@
IF (IO%IU0>=0) WRITE(*,*) 'MLWF_WANNIER90: ERROR: number of projections not equal to num_wann',NPROJ,num_wann
STOP
ENDIF
-
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "* AMN calculated. *"
ENDIF ! finished computing A_matrix
+ IF (WRITE_AMN) THEN
! write A_matrix to file
LUSE_BLOCH_PHASES=.FALSE.
IF (NPROJ/=0) THEN
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN.AND..NOT.READ_AMN) THEN
+ IF (IO%IU6>=0.AND.WRITE_AMN.AND..NOT.READ_AMN) THEN
IF (WDES%ISPIN==1) THEN
OPEN(UNIT=99,FILE=seed_name//'.amn',STATUS='REPLACE')
ELSE
@@ -781,10 +1207,13 @@
IF (NPROJ==0.AND.(.NOT.LUSE_BLOCH_PHASES).AND.WANNIER90RUN()) THEN
!
ENDIF
+ ! 2020-07-04
+ ENDIF
+
! and ...
! we should write the eigenvalues onto seed_name.eig
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) THEN
+ IF (IO%IU6>=0.AND.WRITE_EIG) THEN
IF (WDES%ISPIN==1) THEN
OPEN(UNIT=99,FILE=seed_name//'.eig',STATUS='REPLACE')
ELSE
@@ -792,6 +1221,8 @@
ENDIF
ENDIF
+ ! actually write eig file
+ IF (WRITE_EIG) THEN
DO NKI=1,num_kpts
NK=KPOINT_IN_FULL_GRID(kpt_latt(:,NKI),KPOINTS_FULL)
NK=KPOINTS_FULL%NEQUIV(NK)
@@ -800,10 +1231,13 @@
IF (EXCLUDE_BAND(M)) CYCLE
MI=MI+1
eigenvalues(MI,NKI,ISP)=REAL(W%CELTOT(M,NK,ISP))
- IF (IO%IU6>0.AND.WRITE_MMN_AMN) WRITE(99,'(2I12,F22.12)') MI,NKI,REAL(W%CELTOT(M,NK,ISP))
+ IF (IO%IU6>0.AND.WRITE_EIG) WRITE(99,'(2I12,F22.12)') MI,NKI,REAL(W%CELTOT(M,NK,ISP))
ENDDO
ENDDO
- IF (IO%IU6>=0.AND.WRITE_MMN_AMN) CLOSE(99)
+ IF (IO%IU6>=0.AND.WRITE_EIG) CLOSE(99)
+ IF (IO%IU0>=0.AND.WRITE_EIG) WRITE(IO%IU0,*) "* EIG written. *"
+ !2020-07-04
+ ENDIF
! and last but not least we may need to write UNK files
! which is a bit tricky since the bands at a certain k-point
@@ -811,23 +1245,47 @@
! to make matters worse, WANNIER90 works with the full k-mesh
! whereas VASP uses the symmetry reduced one.
100 FORMAT('UNK',I5.5,'.',I1)
+ 101 FORMAT('UNK',I5.5,'.NC')
IF (WRITE_UNK) THEN
DO NKI=1,num_kpts
IF (IO%IU6>=0) THEN
+ IF (W%WDES%NRSPINORS/=1) THEN
+ WRITE(UNKFILE,101) NKI
+ ELSE
WRITE(UNKFILE,100) NKI,ISP
+ ENDIF
+ IF (UNK_FMTED) THEN
+ OPEN(UNIT=99,FILE=UNKFILE,FORM='FORMATTED',STATUS='REPLACE')
+ IF (REDUCE_UNK) THEN
+ WRITE(99,*) (W%WDES%GRID%NGX+1)/2,(W%WDES%GRID%NGY+1)/2,(W%WDES%GRID%NGZ+1)/2,NKI,num_bands
+ ELSE
+ WRITE(99,*) W%WDES%GRID%NGX,W%WDES%GRID%NGY,W%WDES%GRID%NGZ,NKI,num_bands
+ ENDIF
+ ELSE
OPEN(UNIT=99,FILE=UNKFILE,FORM='UNFORMATTED',STATUS='REPLACE')
+ IF (REDUCE_UNK) THEN
+ WRITE(99) (W%WDES%GRID%NGX+1)/2,(W%WDES%GRID%NGY+1)/2,(W%WDES%GRID%NGZ+1)/2,NKI,num_bands
+ ELSE
WRITE(99) W%WDES%GRID%NGX,W%WDES%GRID%NGY,W%WDES%GRID%NGZ,NKI,num_bands
ENDIF
- CALL WRITE_WAVE_FUNCTIONS(W,kpt_latt(:,NKI),ISP,EXCLUDE_BAND,P,LATT_CUR,99)
+ ENDIF
+ ENDIF
+ CALL WRITE_WAVE_FUNCTIONS(W,kpt_latt(:,NKI),ISP,EXCLUDE_BAND,P,LATT_CUR,UNK_FMTED,REDUCE_UNK,99)
IF (IO%IU6>=0) CLOSE(99)
ENDDO
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "* UNK written. *"
ENDIF
-
- ENDDO spin
+ IF (IO%IU0>=0) WRITE(IO%IU0,*) "*---------------------------------------*"
! Write information on seed_name.win
IF (IO%IU6>=0) THEN
+ IF ((.NOT. spinors) .AND. (WDES%ISPIN==2)) THEN
+ OPEN(UNIT=99,FILE=seed_name//'.'//SP(ISP)//'.win',STATUS='OLD')
+! ELSEIF ((.NOT. spinors) .AND. (WDES%RSPIN==1)) THEN
+! OPEN(UNIT=99,FILE=seed_name//'.win',STATUS='OLD')
+ ELSE
OPEN(UNIT=99,FILE=seed_name//'.win',STATUS='OLD')
+ ENDIF
IF (spinors) THEN
CALL OCCURS_IN_FILE(99,'spinors',N)
@@ -919,9 +1377,9 @@
& U_matrix(:,:,:,1),U_matrix_opt(:,:,:,1),lwindow(:,:,1), &
& wann_centres(:,:,1),wann_spreads(:,1),spread(:,1))
ELSE
- DO ISP=1,WDES%ISPIN
+ !DO ISP=1,WDES%ISPIN
! copy wannier90.win to wannier90.(up/dn).win
- CALL COPYFILE(seed_name//'.win',seed_name//'.'//SP(ISP)//'.win')
+ !CALL COPYFILE(seed_name//'.win',seed_name//'.'//SP(ISP)//'.win')
! run wannier90 for spin component ISP
CALL wannier_run(seed_name//'.'//SP(ISP), &
@@ -932,7 +1390,7 @@
& U_matrix(:,:,:,ISP),U_matrix_opt(:,:,:,ISP),lwindow(:,:,ISP), &
& wann_centres(:,:,ISP),wann_spreads(:,ISP),spread(:,ISP))
- ENDDO
+ !ENDDO
ENDIF
ENDIF
#endif
@@ -955,13 +1413,21 @@
ENDIF
ENDIF
- DEALLOCATE(atom_symbols,atoms_cart)
DEALLOCATE(nnlist,nncell)
DEALLOCATE(proj_site,proj_l,proj_m,proj_radial,proj_z,proj_x,proj_zona,exclude_bands)
+#ifdef VASP2WANNIER90v2
+! CCX_2019-05-05: deall
+ DEALLOCATE(proj_s,proj_s_qaxis)
+#endif
+
+ DEALLOCATE(atom_symbols,atoms_cart)
DEALLOCATE(EXCLUDE_BAND)
DEALLOCATE(M_matrix,A_matrix,eigenvalues)
DEALLOCATE(S)
+ ! 2020-06-27 CCX: I moved this here so we can have total control of collinear spin channels.
+ ENDDO spin
+
IF (ASSOCIATED(R%R)) THEN
DEALLOCATE(R%R); NULLIFY(R%R)
ENDIF
@@ -1880,6 +2346,186 @@
RETURN
END SUBROUTINE CALC_OVERLAP_GN
+!******************** SUBROUTINE CALC_OVERLAP_GN_ALL *******************
+! 2020-06-15 CCX: added to use CONSTRUCT_FUNCTION_RYlm_ALL
+! for spin_quantization calculations
+!***********************************************************************
+ SUBROUTINE CALC_OVERLAP_GN_ALL( &
+ & L,FG,POS,W,K,ISP,SPIN_FAC,P,CQIJ,LATT_CUR,T_INFO,S &
+ &)
+ USE pead
+ USE poscar
+ USE pseudo
+ USE lattice
+ USE full_kpoints
+ USE wave_high
+ USE nonl_high
+ IMPLICIT NONE
+ TYPE(wavespin) W
+ TYPE(potcar) P(:)
+ TYPE(latt) LATT_CUR
+ TYPE(type_info) T_INFO
+ INTEGER L
+ INTEGER ISP
+ ! 2020-06-15 CCX: read in SPIN_FAC
+ COMPLEX(q) SPIN_FAC(2)
+ REAL(q) K(3)
+ REAL(q) FG(:,:,:)
+ REAL(q) POS(3)
+ OVERLAP CQIJ(:,:,:,:)
+ GDEF S(W%WDES%NB_TOT,(L+1)**2)
+ ! local variables
+ TYPE(wavespin) WP
+ TYPE(wavefuna) WK,WRYlm
+ TYPE(wavedes1), TARGET :: WDESK
+ TYPE(nonl_struct) NONL_S
+
+ TYPE(rotation_handle), POINTER :: ROT_HANDLE
+
+ GDEF C
+ REAL(q) WSCAL
+ INTEGER NK,NB,N,NYLM
+
+ WP=W
+ WP%WDES=>WDES_FULL_PEAD
+
+ CALL CHECK_FULL_KPOINTS
+
+ NULLIFY(ROT_HANDLE)
+
+ NYLM=(L+1)**2
+
+ ! search for kpoint k in BZ
+ NK=KPOINT_IN_FULL_GRID(K,KPOINTS_FULL)
+ CALL SETWDES(WP%WDES,WDESK,NK)
+ IF (NK==KPOINTS_FULL%NEQUIV(NK)) THEN
+ ! k is a kpoint in the IBZ
+ WK=ELEMENTS(WP,WDESK,ISP)
+ ELSE
+ ! k is not a kpoint in the IBZ
+ CALL NEWWAVA(WK,WDESK,WDESK%NBANDS)
+ CALL PEAD_WA_ROTATE(WP,P,LATT_CUR,ISP,WK)
+ ENDIF
+
+ CALL NONL_ALLOC(NONL_S,T_INFO,P,WP%WDES,.FALSE.)
+ CALL SPHER(WP%WDES%GRID,NONL_S,P,WP%WDES,LATT_CUR,1,NK)
+ CALL PHASE(WP%WDES,NONL_S,NK)
+
+ CALL NEWWAVA(WRYlm,WDESK,NYLM)
+ WRYlm%CW=0
+ !WRITE(*,*) WRYlm%WDES1%LOVERL, WRYlm%WDES1%NPROD
+ ! 2020-06-15 CCX: use CONSTRUCT_FUNCTION_RYlm_ALL.
+ CALL CONSTRUCT_FUNCTION_RYlm_ALL(L,FG,LATT_CUR,POS,NONL_S,SPIN_FAC,WRYlm)
+ ! and normalize the functions WRYlm
+ DO N=1,NYLM
+ CALL CNORMN(ELEMENT(WRYlm,N),CQIJ,1,WSCAL)
+ ENDDO
+
+ ! calculate overlap between Wk and WRYlm: < w_{m,k1} | S | RYlm >
+ S=0
+ DO NB=1,WP%WDES%NBANDS
+ DO N=1,NYLM
+ C=W1_DOT(ELEMENT(WK,NB),ELEMENT(WRYlm,N),CQIJ)
+ S(WDESK%NB_LOW+WDESK%NB_PAR*(NB-1),N)=C
+! WRITE(*,*) WDESK%NB_LOW+WDESK%NB_PAR*(NB-1),N,C
+ ENDDO
+ ENDDO
+
+ CALLMPI( M_sum_g(WDESK%COMM_INTER,S(1,1),WDESK%NB_TOT*NYLM) )
+
+ ! some deallocation to be done
+ CALL DEALLOCATE_ROT_HANDLE(ROT_HANDLE)
+
+ CALL DELWAVA(WRYlm)
+ IF (NK/=KPOINTS_FULL%NEQUIV(NK)) CALL DELWAVA(WK)
+
+ CALL NONL_DEALLOC(NONL_S)
+
+ RETURN
+ END SUBROUTINE CALC_OVERLAP_GN_ALL
+
+!******************** SUBROUTINE CALC_SPN_EXP ***********************
+! 2020-06-15 CCX: a modified version of CALC_OVERLAP_GN
+! calculates expectation value of the
+! Pauli Matrix. Uses W1_SPN_DOT in wave_high.F
+! Note: This routine only works in serial.
+!***********************************************************************
+ SUBROUTINE CALC_SPN_EXP( &
+ & W,K,P,CQIJ,LATT_CUR,T_INFO,S &
+ &)
+ USE pead
+ USE poscar
+ USE pseudo
+ USE lattice
+ USE full_kpoints
+ USE wave_high
+ USE nonl_high
+ IMPLICIT NONE
+ TYPE(wavespin) W
+ TYPE(potcar) P(:)
+ TYPE(latt) LATT_CUR
+ TYPE(type_info) T_INFO
+ ! INTEGER L
+ ! INTEGER ISP
+ ! INTEGER ISPINOR
+ REAL(q) K(3)
+ ! REAL(q) FG(:,:,:)
+ ! REAL(q) POS(3)
+ OVERLAP CQIJ(:,:,:,:)
+ GDEF S(W%WDES%NB_TOT,W%WDES%NB_TOT,3)
+ ! local variables
+ TYPE(wavespin) WP
+ TYPE(wavefuna) WK
+ TYPE(wavedes1), TARGET :: WDESK
+
+ TYPE(rotation_handle), POINTER :: ROT_HANDLE
+
+ GDEF C(3)
+ REAL(q) WSCAL
+ INTEGER NK,NB,N,NYLM
+
+ WP=W
+ WP%WDES=>WDES_FULL_PEAD
+
+ CALL CHECK_FULL_KPOINTS
+
+ NULLIFY(ROT_HANDLE)
+
+ ! search for kpoint k in BZ
+ NK=KPOINT_IN_FULL_GRID(K,KPOINTS_FULL)
+ CALL SETWDES(WP%WDES,WDESK,NK)
+ IF (NK==KPOINTS_FULL%NEQUIV(NK)) THEN
+ ! k is a kpoint in the IBZ
+ WK=ELEMENTS(WP,WDESK,1)
+ ELSE
+ ! k is not a kpoint in the IBZ
+ CALL NEWWAVA(WK,WDESK,WDESK%NBANDS)
+ CALL PEAD_WA_ROTATE(WP,P,LATT_CUR,1,WK)
+ ENDIF
+ ! calculate overlap between W1 and W2: < w_{m,k1} | sigma | w_{n,k1} >
+ ! everything is in W1_SPNDOT
+ S=0