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mirror of https://github.com/QuantumPackage/qp2.git synced 2024-11-14 10:03:47 +01:00

updated converter

This commit is contained in:
Kevin Gasperich 2020-03-31 14:20:20 -05:00
parent 4a31254d6b
commit 1277f78d72
2 changed files with 53 additions and 36 deletions

View File

@ -553,14 +553,25 @@ def df_ao_to_mo_test(j3ao,mo_coef):
np.einsum('mij,ik,jl->mkl',j3ao[idx2_tri((ki,kj))],mo_coef[ki].conj(),mo_coef[kj])
for ki,kj in product(range(Nk),repeat=2) if (ki>=kj)])
def pyscf2QP2_mo(cell,mf,kpts,kmesh=None,cas_idx=None, int_threshold = 1E-8,qph5path='qpdat.h5'):
pyscf2QP2(cell,mf,kpts,kmesh,cas_idx,int_threshold,qph5path,
print_ao_ints_df=False,
print_mo_ints_df=True,
print_ao_ints_mono=False,
print_mo_ints_mono=True)
return
def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
qph5path = 'qpdat.h5',
print_ao_ints_bi=False,
print_mo_ints_bi=False,
print_ao_ints_df=True,
print_mo_ints_df=False,
print_ao_ints_mono=True,
print_mo_ints_mono=False):
print_mo_ints_mono=False,
print_debug=False):
'''
kpts = List of kpoints coordinates. Cannot be null, for gamma is other script
kmesh = Mesh of kpoints (optional)
@ -582,7 +593,7 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
thresh_mono = int_threshold
qph5path = 'qpdat.h5'
# qph5path = 'qpdat.h5'
# create hdf5 file, delete old data if exists
with h5py.File(qph5path,'w') as qph5:
qph5.create_group('nuclei')
@ -685,14 +696,15 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
mo_coef_f = np.array(mo_k.transpose((0,2,1)),order='c')
mo_coef_blocked=block_diag(*mo_k)
mo_coef_blocked_f = block_diag(*mo_coef_f)
qph5.create_dataset('mo_basis/mo_coef_real',data=mo_coef_blocked.real)
qph5.create_dataset('mo_basis/mo_coef_imag',data=mo_coef_blocked.imag)
qph5.create_dataset('mo_basis/mo_coef_kpts_real',data=mo_k.real)
qph5.create_dataset('mo_basis/mo_coef_kpts_imag',data=mo_k.imag)
#qph5.create_dataset('mo_basis/mo_coef_real',data=mo_coef_blocked.real)
#qph5.create_dataset('mo_basis/mo_coef_imag',data=mo_coef_blocked.imag)
#qph5.create_dataset('mo_basis/mo_coef_kpts_real',data=mo_k.real)
#qph5.create_dataset('mo_basis/mo_coef_kpts_imag',data=mo_k.imag)
qph5.create_dataset('mo_basis/mo_coef_complex',data=mo_coef_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nao,2)))
qph5.create_dataset('mo_basis/mo_coef_kpts',data=mo_coef_f.view(dtype=np.float64).reshape((Nk,nmo,nao,2)))
print_kpts_unblocked(mo_k,'C.qp',mo_coef_threshold)
if print_debug:
print_kpts_unblocked(mo_k,'C.qp',mo_coef_threshold)
##########################################
# #
@ -719,23 +731,24 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
ovlp_ao_blocked_f = block_diag(*ovlp_ao_f)
ne_ao_blocked_f = block_diag(*ne_ao_f)
qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic_real',data=kin_ao_blocked.real)
qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic_imag',data=kin_ao_blocked.imag)
qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap_real',data=ovlp_ao_blocked.real)
qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap_imag',data=ovlp_ao_blocked.imag)
qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e_real', data=ne_ao_blocked.real)
qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e_imag', data=ne_ao_blocked.imag)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic_real',data=kin_ao_blocked.real)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic_imag',data=kin_ao_blocked.imag)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap_real',data=ovlp_ao_blocked.real)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap_imag',data=ovlp_ao_blocked.imag)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e_real', data=ne_ao_blocked.real)
#qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e_imag', data=ne_ao_blocked.imag)
qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic',data=kin_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap',data=ovlp_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e', data=ne_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
#qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic',data=kin_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
#qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap',data=ovlp_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
#qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e', data=ne_ao_blocked_f.view(dtype=np.float64).reshape((Nk*nao,Nk*nao,2)))
qph5.create_dataset('ao_one_e_ints/ao_integrals_kinetic_kpts',data=kin_ao_f.view(dtype=np.float64).reshape((Nk,nao,nao,2)))
qph5.create_dataset('ao_one_e_ints/ao_integrals_overlap_kpts',data=ovlp_ao_f.view(dtype=np.float64).reshape((Nk,nao,nao,2)))
qph5.create_dataset('ao_one_e_ints/ao_integrals_n_e_kpts', data=ne_ao_f.view(dtype=np.float64).reshape((Nk,nao,nao,2)))
for fname,ints in zip(('S.qp','V.qp','T.qp'),
(ovlp_ao, ne_ao, kin_ao)):
print_kpts_unblocked_upper(ints,fname,thresh_mono)
if print_debug:
for fname,ints in zip(('S.qp','V.qp','T.qp'),
(ovlp_ao, ne_ao, kin_ao)):
print_kpts_unblocked_upper(ints,fname,thresh_mono)
if print_mo_ints_mono:
kin_mo = ao_to_mo_1e(kin_ao,mo_k)
@ -754,23 +767,24 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
kin_mo_blocked_f = block_diag(*kin_mo_f)
ovlp_mo_blocked_f = block_diag(*ovlp_mo_f)
ne_mo_blocked_f = block_diag(*ne_mo_f)
qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic_real',data=kin_mo_blocked.real)
qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic_imag',data=kin_mo_blocked.imag)
qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap_real',data=ovlp_mo_blocked.real)
qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap_imag',data=ovlp_mo_blocked.imag)
qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e_real', data=ne_mo_blocked.real)
qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e_imag', data=ne_mo_blocked.imag)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic_real',data=kin_mo_blocked.real)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic_imag',data=kin_mo_blocked.imag)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap_real',data=ovlp_mo_blocked.real)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap_imag',data=ovlp_mo_blocked.imag)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e_real', data=ne_mo_blocked.real)
#qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e_imag', data=ne_mo_blocked.imag)
qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic',data=kin_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap',data=ovlp_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e', data=ne_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
#qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic',data=kin_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
#qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap',data=ovlp_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
#qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e', data=ne_mo_blocked_f.view(dtype=np.float64).reshape((Nk*nmo,Nk*nmo,2)))
qph5.create_dataset('mo_one_e_ints/mo_integrals_kinetic_kpts',data=kin_mo_f.view(dtype=np.float64).reshape((Nk,nmo,nmo,2)))
qph5.create_dataset('mo_one_e_ints/mo_integrals_overlap_kpts',data=ovlp_mo_f.view(dtype=np.float64).reshape((Nk,nmo,nmo,2)))
qph5.create_dataset('mo_one_e_ints/mo_integrals_n_e_kpts', data=ne_mo_f.view(dtype=np.float64).reshape((Nk,nmo,nmo,2)))
for fname,ints in zip(('S.mo.qp','V.mo.qp','T.mo.qp'),
(ovlp_mo, ne_mo, kin_mo)):
print_kpts_unblocked_upper(ints,fname,thresh_mono)
if print_debug:
for fname,ints in zip(('S.mo.qp','V.mo.qp','T.mo.qp'),
(ovlp_mo, ne_mo, kin_mo)):
print_kpts_unblocked_upper(ints,fname,thresh_mono)
##########################################
@ -784,8 +798,9 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
with h5py.File(qph5path,'a') as qph5:
kcon_f_phys = np.array(kconserv.transpose((1,2,0)),order='c')
qph5.create_dataset('nuclei/kconserv',data=kcon_f_phys+1)
print_kcon_chem_to_phys(kconserv,'K.qp')
if print_debug:
print_kcon_chem_to_phys(kconserv,'K.qp')
##########################################
# #
@ -805,7 +820,8 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
j3ao_new = get_j3ao_new(mf.with_df._cderi,nao,Nk)
if print_ao_ints_df:
print_df(j3arr,'D.qp',bielec_int_threshold)
if print_debug:
print_df(j3arr,'D.qp',bielec_int_threshold)
with h5py.File(qph5path,'a') as qph5:
#qph5.create_dataset('ao_two_e_ints/df_ao_integrals_real',data=j3arr.transpose((2,3,1,0)).real)
@ -817,7 +833,8 @@ def pyscf2QP2(cell,mf, kpts, kmesh=None, cas_idx=None, int_threshold = 1E-8,
j3mo = df_ao_to_mo(j3arr,mo_k)
j3mo_new = df_ao_to_mo_new(j3ao_new,mo_k)
print_df(j3mo,'D.mo.qp',bielec_int_threshold)
if print_debug:
print_df(j3mo,'D.mo.qp',bielec_int_threshold)
with h5py.File(qph5path,'a') as qph5:
#qph5.create_dataset('mo_two_e_ints/df_mo_integrals_real',data=j3mo.transpose((2,3,1,0)).real)

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@ -139,7 +139,7 @@ def convert_kpts(filename,qph5path):
with h5py.File(qph5path,'r') as qph5:
if 'mo_one_e_ints' in qph5.keys():
kin_mo_reim=qph5['mo_one_e_ints/mo_integrals_kinetic_kpts'][()].tolist()
ovlp_mo_reim=qph5['mo_one_e_ints/mo_integrals_overlap'][()].tolist()
ovlp_mo_reim=qph5['mo_one_e_ints/mo_integrals_overlap_kpts'][()].tolist()
ne_mo_reim=qph5['mo_one_e_ints/mo_integrals_n_e_kpts'][()].tolist()
ezfio.set_mo_one_e_ints_mo_integrals_kinetic_kpts(kin_mo_reim)