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ucisd.py
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ucisd.py
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#!/usr/bin/env python
# Copyright 2014-2019 The PySCF Developers. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#
# Author: Qiming Sun <osirpt.sun@gmail.com>
#
'''
Unrestricted CISD
'''
import time
from functools import reduce
import numpy
from pyscf import lib
from pyscf.lib import logger
from pyscf.cc import uccsd
from pyscf.cc import uccsd_rdm
from pyscf.ci import cisd
from pyscf.fci import cistring
from pyscf.cc.ccsd import _unpack_4fold
def make_diagonal(myci, eris):
nocca, noccb = eris.nocc
nmoa = eris.focka.shape[0]
nmob = eris.fockb.shape[1]
nvira = nmoa - nocca
nvirb = nmob - noccb
jdiag_aa = numpy.zeros((nmoa,nmoa))
jdiag_ab = numpy.zeros((nmoa,nmob))
jdiag_bb = numpy.zeros((nmob,nmob))
jdiag_aa[:nocca,:nocca] = numpy.einsum('iijj->ij', eris.oooo)
jdiag_aa[:nocca,nocca:] = numpy.einsum('iijj->ij', eris.oovv)
jdiag_aa[nocca:,:nocca] = jdiag_aa[:nocca,nocca:].T
jdiag_ab[:nocca,:noccb] = numpy.einsum('iijj->ij', eris.ooOO)
jdiag_ab[:nocca,noccb:] = numpy.einsum('iijj->ij', eris.ooVV)
jdiag_ab[nocca:,:noccb] = numpy.einsum('iijj->ji', eris.OOvv)
jdiag_bb[:noccb,:noccb] = numpy.einsum('iijj->ij', eris.OOOO)
jdiag_bb[:noccb,noccb:] = numpy.einsum('iijj->ij', eris.OOVV)
jdiag_bb[noccb:,:noccb] = jdiag_bb[:noccb,noccb:].T
kdiag_aa = numpy.zeros((nmoa,nmoa))
kdiag_bb = numpy.zeros((nmob,nmob))
kdiag_aa[:nocca,:nocca] = numpy.einsum('ijji->ij', eris.oooo)
kdiag_aa[:nocca,nocca:] = numpy.einsum('ijji->ij', eris.ovvo)
kdiag_aa[nocca:,:nocca] = kdiag_aa[:nocca,nocca:].T
kdiag_bb[:noccb,:noccb] = numpy.einsum('ijji->ij', eris.OOOO)
kdiag_bb[:noccb,noccb:] = numpy.einsum('ijji->ij', eris.OVVO)
kdiag_bb[noccb:,:noccb] = kdiag_bb[:noccb,noccb:].T
# if eris.vvvv is not None and eris.vvVV is not None and eris.VVVV is not None:
# def diag_idx(n):
# idx = numpy.arange(n)
# return idx * (idx + 1) // 2 + idx
# jdiag_aa[nocca:,nocca:] = eris.vvvv[diag_idx(nvira)[:,None],diag_idx(nvira)]
# jdiag_ab[nocca:,noccb:] = eris.vvVV[diag_idx(nvira)[:,None],diag_idx(nvirb)]
# jdiag_bb[noccb:,noccb:] = eris.VVVV[diag_idx(nvirb)[:,None],diag_idx(nvirb)]
# kdiag_aa[nocca:,nocca:] = lib.unpack_tril(eris.vvvv.diagonal())
# kdiag_bb[noccb:,noccb:] = lib.unpack_tril(eris.VVVV.diagonal())
jkdiag_aa = jdiag_aa - kdiag_aa
jkdiag_bb = jdiag_bb - kdiag_bb
mo_ea = eris.focka.diagonal()
mo_eb = eris.fockb.diagonal()
ehf = (mo_ea[:nocca].sum() + mo_eb[:noccb].sum()
- jkdiag_aa[:nocca,:nocca].sum() * .5
- jdiag_ab[:nocca,:noccb].sum()
- jkdiag_bb[:noccb,:noccb].sum() * .5)
dia_a = lib.direct_sum('a-i->ia', mo_ea[nocca:], mo_ea[:nocca])
dia_a -= jkdiag_aa[:nocca,nocca:]
dia_b = lib.direct_sum('a-i->ia', mo_eb[noccb:], mo_eb[:noccb])
dia_b -= jkdiag_bb[:noccb,noccb:]
e1diag_a = dia_a + ehf
e1diag_b = dia_b + ehf
e2diag_aa = lib.direct_sum('ia+jb->ijab', dia_a, dia_a)
e2diag_aa += ehf
e2diag_aa += jkdiag_aa[:nocca,:nocca].reshape(nocca,nocca,1,1)
e2diag_aa -= jkdiag_aa[:nocca,nocca:].reshape(nocca,1,1,nvira)
e2diag_aa -= jkdiag_aa[:nocca,nocca:].reshape(1,nocca,nvira,1)
e2diag_aa += jkdiag_aa[nocca:,nocca:].reshape(1,1,nvira,nvira)
e2diag_ab = lib.direct_sum('ia+jb->ijab', dia_a, dia_b)
e2diag_ab += ehf
e2diag_ab += jdiag_ab[:nocca,:noccb].reshape(nocca,noccb,1,1)
e2diag_ab += jdiag_ab[nocca:,noccb:].reshape(1,1,nvira,nvirb)
e2diag_ab -= jdiag_ab[:nocca,noccb:].reshape(nocca,1,1,nvirb)
e2diag_ab -= jdiag_ab[nocca:,:noccb].T.reshape(1,noccb,nvira,1)
e2diag_bb = lib.direct_sum('ia+jb->ijab', dia_b, dia_b)
e2diag_bb += ehf
e2diag_bb += jkdiag_bb[:noccb,:noccb].reshape(noccb,noccb,1,1)
e2diag_bb -= jkdiag_bb[:noccb,noccb:].reshape(noccb,1,1,nvirb)
e2diag_bb -= jkdiag_bb[:noccb,noccb:].reshape(1,noccb,nvirb,1)
e2diag_bb += jkdiag_bb[noccb:,noccb:].reshape(1,1,nvirb,nvirb)
return amplitudes_to_cisdvec(ehf, (e1diag_a, e1diag_b),
(e2diag_aa, e2diag_ab, e2diag_bb))
def contract(myci, civec, eris):
nocca, noccb = eris.nocc
nmoa = eris.focka.shape[0]
nmob = eris.fockb.shape[0]
nvira = nmoa - nocca
nvirb = nmob - noccb
c0, (c1a,c1b), (c2aa,c2ab,c2bb) = \
cisdvec_to_amplitudes(civec, (nmoa,nmob), (nocca,noccb))
#:t2 += 0.5*einsum('ijef,abef->ijab', c2, eris.vvvv)
#:eris_vvvv = ao2mo.restore(1, eris.vvvv, nvira)
#:eris_vvVV = ucisd_slow._restore(eris.vvVV, nvira, nvirb)
#:eris_VVVV = ao2mo.restore(1, eris.VVVV, nvirb)
#:t2aa += lib.einsum('ijef,aebf->ijab', c2aa, eris_vvvv)
#:t2bb += lib.einsum('ijef,aebf->ijab', c2bb, eris_VVVV)
#:t2ab += lib.einsum('iJeF,aeBF->iJaB', c2ab, eris_vvVV)
t2aa, t2ab, t2bb = myci._add_vvvv(None, (c2aa,c2ab,c2bb), eris)
t2aa *= .25
t2bb *= .25
fooa = eris.focka[:nocca,:nocca]
foob = eris.fockb[:noccb,:noccb]
fova = eris.focka[:nocca,nocca:]
fovb = eris.fockb[:noccb,noccb:]
fvoa = eris.focka[nocca:,:nocca]
fvob = eris.fockb[noccb:,:noccb]
fvva = eris.focka[nocca:,nocca:]
fvvb = eris.fockb[noccb:,noccb:]
t0 = 0
t1a = 0
t1b = 0
eris_oovv = _cp(eris.oovv)
eris_ooVV = _cp(eris.ooVV)
eris_OOvv = _cp(eris.OOvv)
eris_OOVV = _cp(eris.OOVV)
eris_ovov = _cp(eris.ovov)
eris_ovOV = _cp(eris.ovOV)
eris_OVOV = _cp(eris.OVOV)
#:t2 += eris.oovv * c0
t2aa += .25 * c0 * eris_ovov.conj().transpose(0,2,1,3)
t2aa -= .25 * c0 * eris_ovov.conj().transpose(0,2,3,1)
t2bb += .25 * c0 * eris_OVOV.conj().transpose(0,2,1,3)
t2bb -= .25 * c0 * eris_OVOV.conj().transpose(0,2,3,1)
t2ab += c0 * eris_ovOV.conj().transpose(0,2,1,3)
#:t0 += numpy.einsum('ijab,ijab', eris.oovv, c2) * .25
t0 += numpy.einsum('iajb,ijab', eris_ovov, c2aa) * .25
t0 -= numpy.einsum('jaib,ijab', eris_ovov, c2aa) * .25
t0 += numpy.einsum('iajb,ijab', eris_OVOV, c2bb) * .25
t0 -= numpy.einsum('jaib,ijab', eris_OVOV, c2bb) * .25
t0 += numpy.einsum('iajb,ijab', eris_ovOV, c2ab)
eris_ovov = eris_ovOV = eris_OVOV = None
#:tmp = einsum('imae,mbej->ijab', c2, eris.ovvo)
#:tmp = tmp - tmp.transpose(0,1,3,2)
#:t2 += tmp - tmp.transpose(1,0,2,3)
eris_ovvo = _cp(eris.ovvo)
eris_ovVO = _cp(eris.ovVO)
eris_OVVO = _cp(eris.OVVO)
ovvo = eris_ovvo - eris_oovv.transpose(0,3,2,1)
OVVO = eris_OVVO - eris_OOVV.transpose(0,3,2,1)
t2aa += lib.einsum('imae,jbem->ijab', c2aa, ovvo)
t2aa += lib.einsum('iMaE,jbEM->ijab', c2ab, eris_ovVO)
t2bb += lib.einsum('imae,jbem->ijab', c2bb, OVVO)
t2bb += lib.einsum('mIeA,meBJ->IJAB', c2ab, eris_ovVO)
t2ab += lib.einsum('imae,meBJ->iJaB', c2aa, eris_ovVO)
t2ab += lib.einsum('iMaE,MEBJ->iJaB', c2ab, OVVO)
t2ab += lib.einsum('IMAE,jbEM->jIbA', c2bb, eris_ovVO)
t2ab += lib.einsum('mIeA,jbem->jIbA', c2ab, ovvo)
t2ab -= lib.einsum('iMeA,JMeb->iJbA', c2ab, eris_OOvv)
t2ab -= lib.einsum('mIaE,jmEB->jIaB', c2ab, eris_ooVV)
#:t1 += einsum('nf,nafi->ia', c1, eris.ovvo)
t1a += numpy.einsum('nf,nfai->ia', c1a, eris_ovvo)
t1a -= numpy.einsum('nf,nifa->ia', c1a, eris_oovv)
t1b += numpy.einsum('nf,nfai->ia', c1b, eris_OVVO)
t1b -= numpy.einsum('nf,nifa->ia', c1b, eris_OOVV)
t1b += numpy.einsum('nf,nfai->ia', c1a, eris_ovVO)
t1a += numpy.einsum('nf,iafn->ia', c1b, eris_ovVO)
#:t1 -= 0.5*einsum('mnae,mnie->ia', c2, eris.ooov)
eris_ovoo = _cp(eris.ovoo)
eris_OVOO = _cp(eris.OVOO)
eris_OVoo = _cp(eris.OVoo)
eris_ovOO = _cp(eris.ovOO)
t1a += lib.einsum('mnae,meni->ia', c2aa, eris_ovoo)
t1b += lib.einsum('mnae,meni->ia', c2bb, eris_OVOO)
t1a -= lib.einsum('nMaE,MEni->ia', c2ab, eris_OVoo)
t1b -= lib.einsum('mNeA,meNI->IA', c2ab, eris_ovOO)
#:tmp = einsum('ma,mbij->ijab', c1, eris.ovoo)
#:t2 -= tmp - tmp.transpose(0,1,3,2)
t2aa -= lib.einsum('ma,jbmi->jiba', c1a, eris_ovoo)
t2bb -= lib.einsum('ma,jbmi->jiba', c1b, eris_OVOO)
t2ab -= lib.einsum('ma,JBmi->iJaB', c1a, eris_OVoo)
t2ab -= lib.einsum('MA,ibMJ->iJbA', c1b, eris_ovOO)
#:#:t1 -= 0.5*einsum('imef,maef->ia', c2, eris.ovvv)
#:eris_ovvv = _cp(eris.ovvv)
#:eris_OVVV = _cp(eris.OVVV)
#:eris_ovVV = _cp(eris.ovVV)
#:eris_OVvv = _cp(eris.OVvv)
#:t1a += lib.einsum('mief,mefa->ia', c2aa, eris_ovvv)
#:t1b += lib.einsum('MIEF,MEFA->IA', c2bb, eris_OVVV)
#:t1a += lib.einsum('iMfE,MEaf->ia', c2ab, eris_OVvv)
#:t1b += lib.einsum('mIeF,meAF->IA', c2ab, eris_ovVV)
#:#:tmp = einsum('ie,jeba->ijab', c1, numpy.asarray(eris.ovvv).conj())
#:#:t2 += tmp - tmp.transpose(1,0,2,3)
#:t2aa += lib.einsum('ie,mbae->imab', c1a, eris_ovvv)
#:t2bb += lib.einsum('ie,mbae->imab', c1b, eris_OVVV)
#:t2ab += lib.einsum('ie,MBae->iMaB', c1a, eris_OVvv)
#:t2ab += lib.einsum('IE,maBE->mIaB', c1b, eris_ovVV)
mem_now = lib.current_memory()[0]
max_memory = max(0, lib.param.MAX_MEMORY - mem_now)
if nvira > 0 and nocca > 0:
blksize = max(int(max_memory*1e6/8/(nvira**2*nocca*2)), 2)
for p0,p1 in lib.prange(0, nvira, blksize):
ovvv = eris.get_ovvv(slice(None), slice(p0,p1))
t1a += lib.einsum('mief,mefa->ia', c2aa[:,:,p0:p1], ovvv)
t2aa[:,:,p0:p1] += lib.einsum('mbae,ie->miba', ovvv, c1a)
ovvv = None
if nvirb > 0 and noccb > 0:
blksize = max(int(max_memory*1e6/8/(nvirb**2*noccb*2)), 2)
for p0,p1 in lib.prange(0, nvirb, blksize):
OVVV = eris.get_OVVV(slice(None), slice(p0,p1))
t1b += lib.einsum('MIEF,MEFA->IA', c2bb[:,:,p0:p1], OVVV)
t2bb[:,:,p0:p1] += lib.einsum('mbae,ie->miba', OVVV, c1b)
OVVV = None
if nvirb > 0 and nocca > 0:
blksize = max(int(max_memory*1e6/8/(nvirb**2*nocca*2)), 2)
for p0,p1 in lib.prange(0, nvira, blksize):
ovVV = eris.get_ovVV(slice(None), slice(p0,p1))
t1b += lib.einsum('mIeF,meAF->IA', c2ab[:,:,p0:p1], ovVV)
t2ab[:,:,p0:p1] += lib.einsum('maBE,IE->mIaB', ovVV, c1b)
ovVV = None
if nvira > 0 and noccb > 0:
blksize = max(int(max_memory*1e6/8/(nvira**2*noccb*2)), 2)
for p0,p1 in lib.prange(0, nvirb, blksize):
OVvv = eris.get_OVvv(slice(None), slice(p0,p1))
t1a += lib.einsum('iMfE,MEaf->ia', c2ab[:,:,:,p0:p1], OVvv)
t2ab[:,:,:,p0:p1] += lib.einsum('MBae,ie->iMaB', OVvv, c1a)
OVvv = None
#:t1 = einsum('ie,ae->ia', c1, fvv)
t1a += lib.einsum('ie,ae->ia', c1a, fvva)
t1b += lib.einsum('ie,ae->ia', c1b, fvvb)
#:t1 -= einsum('ma,mi->ia', c1, foo)
t1a -= lib.einsum('ma,mi->ia', c1a, fooa)
t1b -= lib.einsum('ma,mi->ia', c1b, foob)
#:t1 += einsum('imae,me->ia', c2, fov)
t1a += numpy.einsum('imae,me->ia', c2aa, fova)
t1a += numpy.einsum('imae,me->ia', c2ab, fovb)
t1b += numpy.einsum('imae,me->ia', c2bb, fovb)
t1b += numpy.einsum('miea,me->ia', c2ab, fova)
#:tmp = einsum('ijae,be->ijab', c2, fvv)
#:t2 = tmp - tmp.transpose(0,1,3,2)
t2aa += lib.einsum('ijae,be->ijab', c2aa, fvva*.5)
t2bb += lib.einsum('ijae,be->ijab', c2bb, fvvb*.5)
t2ab += lib.einsum('iJaE,BE->iJaB', c2ab, fvvb)
t2ab += lib.einsum('iJeA,be->iJbA', c2ab, fvva)
#:tmp = einsum('imab,mj->ijab', c2, foo)
#:t2 -= tmp - tmp.transpose(1,0,2,3)
t2aa -= lib.einsum('imab,mj->ijab', c2aa, fooa*.5)
t2bb -= lib.einsum('imab,mj->ijab', c2bb, foob*.5)
t2ab -= lib.einsum('iMaB,MJ->iJaB', c2ab, foob)
t2ab -= lib.einsum('mIaB,mj->jIaB', c2ab, fooa)
#:tmp = numpy.einsum('ia,bj->ijab', c1, fvo)
#:tmp = tmp - tmp.transpose(0,1,3,2)
#:t2 += tmp - tmp.transpose(1,0,2,3)
t2aa += numpy.einsum('ia,bj->ijab', c1a, fvoa)
t2bb += numpy.einsum('ia,bj->ijab', c1b, fvob)
t2ab += numpy.einsum('ia,bj->ijab', c1a, fvob)
t2ab += numpy.einsum('ia,bj->jiba', c1b, fvoa)
t2aa = t2aa - t2aa.transpose(0,1,3,2)
t2aa = t2aa - t2aa.transpose(1,0,2,3)
t2bb = t2bb - t2bb.transpose(0,1,3,2)
t2bb = t2bb - t2bb.transpose(1,0,2,3)
#:t2 += 0.5*einsum('mnab,mnij->ijab', c2, eris.oooo)
eris_oooo = _cp(eris.oooo)
eris_OOOO = _cp(eris.OOOO)
eris_ooOO = _cp(eris.ooOO)
t2aa += lib.einsum('mnab,minj->ijab', c2aa, eris_oooo)
t2bb += lib.einsum('mnab,minj->ijab', c2bb, eris_OOOO)
t2ab += lib.einsum('mNaB,miNJ->iJaB', c2ab, eris_ooOO)
#:t1 += fov.conj() * c0
t1a += fova.conj() * c0
t1b += fovb.conj() * c0
#:t0 = numpy.einsum('ia,ia', fov, c1)
t0 += numpy.einsum('ia,ia', fova, c1a)
t0 += numpy.einsum('ia,ia', fovb, c1b)
return amplitudes_to_cisdvec(t0, (t1a,t1b), (t2aa,t2ab,t2bb))
def amplitudes_to_cisdvec(c0, c1, c2):
c1a, c1b = c1
c2aa, c2ab, c2bb = c2
nocca, nvira = c1a.shape
noccb, nvirb = c1b.shape
def trilidx(n):
idx = numpy.tril_indices(n, -1)
return idx[0] * n + idx[1]
ooidxa = trilidx(nocca)
vvidxa = trilidx(nvira)
ooidxb = trilidx(noccb)
vvidxb = trilidx(nvirb)
size = (1, nocca*nvira, noccb*nvirb, nocca*noccb*nvira*nvirb,
len(ooidxa)*len(vvidxa), len(ooidxb)*len(vvidxb))
loc = numpy.cumsum(size)
civec = numpy.empty(loc[-1], dtype=c2ab.dtype)
civec[0] = c0
civec[loc[0]:loc[1]] = c1a.ravel()
civec[loc[1]:loc[2]] = c1b.ravel()
civec[loc[2]:loc[3]] = c2ab.ravel()
lib.take_2d(c2aa.reshape(nocca**2,nvira**2), ooidxa, vvidxa, out=civec[loc[3]:loc[4]])
lib.take_2d(c2bb.reshape(noccb**2,nvirb**2), ooidxb, vvidxb, out=civec[loc[4]:loc[5]])
return civec
def cisdvec_to_amplitudes(civec, nmo, nocc):
norba, norbb = nmo
nocca, noccb = nocc
nvira = norba - nocca
nvirb = norbb - noccb
nooa = nocca * (nocca-1) // 2
nvva = nvira * (nvira-1) // 2
noob = noccb * (noccb-1) // 2
nvvb = nvirb * (nvirb-1) // 2
size = (1, nocca*nvira, noccb*nvirb, nocca*noccb*nvira*nvirb,
nooa*nvva, noob*nvvb)
loc = numpy.cumsum(size)
c0 = civec[0]
c1a = civec[loc[0]:loc[1]].reshape(nocca,nvira)
c1b = civec[loc[1]:loc[2]].reshape(noccb,nvirb)
c2ab = civec[loc[2]:loc[3]].reshape(nocca,noccb,nvira,nvirb)
c2aa = _unpack_4fold(civec[loc[3]:loc[4]], nocca, nvira)
c2bb = _unpack_4fold(civec[loc[4]:loc[5]], noccb, nvirb)
return c0, (c1a,c1b), (c2aa,c2ab,c2bb)
def to_fcivec(cisdvec, norb, nelec, frozen=0):
'''Convert CISD coefficients to FCI coefficients'''
if isinstance(nelec, (int, numpy.number)):
nelecb = nelec//2
neleca = nelec - nelecb
else:
neleca, nelecb = nelec
frozena_mask = numpy.zeros(norb, dtype=bool)
frozenb_mask = numpy.zeros(norb, dtype=bool)
if isinstance(frozen, (int, numpy.integer)):
nfroza = nfrozb = frozen
frozena_mask[:frozen] = True
frozenb_mask[:frozen] = True
else:
nfroza = len(frozen[0])
nfrozb = len(frozen[1])
frozena_mask[frozen[0]] = True
frozenb_mask[frozen[1]] = True
# if nfroza != nfrozb:
# raise NotImplementedError
nocca = numpy.count_nonzero(~frozena_mask[:neleca])
noccb = numpy.count_nonzero(~frozenb_mask[:nelecb])
nmo = nmoa, nmob = norb - nfroza, norb - nfrozb
nocc = nocca, noccb
nvira, nvirb = nmoa - nocca, nmob - noccb
c0, c1, c2 = cisdvec_to_amplitudes(cisdvec, nmo, nocc)
c1a, c1b = c1
c2aa, c2ab, c2bb = c2
t1addra, t1signa = cisd.tn_addrs_signs(nmoa, nocca, 1)
t1addrb, t1signb = cisd.tn_addrs_signs(nmob, noccb, 1)
na = cistring.num_strings(nmoa, nocca)
nb = cistring.num_strings(nmob, noccb)
fcivec = numpy.zeros((na,nb))
fcivec[0,0] = c0
fcivec[t1addra,0] = c1a.ravel() * t1signa
fcivec[0,t1addrb] = c1b.ravel() * t1signb
c2ab = c2ab.transpose(0,2,1,3).reshape(nocca*nvira,-1)
c2ab = numpy.einsum('i,j,ij->ij', t1signa, t1signb, c2ab)
fcivec[t1addra[:,None],t1addrb] = c2ab
if nocca > 1 and nvira > 1:
ooidx = numpy.tril_indices(nocca, -1)
vvidx = numpy.tril_indices(nvira, -1)
c2aa = c2aa[ooidx][:,vvidx[0],vvidx[1]]
t2addra, t2signa = cisd.tn_addrs_signs(nmoa, nocca, 2)
fcivec[t2addra,0] = c2aa.ravel() * t2signa
if noccb > 1 and nvirb > 1:
ooidx = numpy.tril_indices(noccb, -1)
vvidx = numpy.tril_indices(nvirb, -1)
c2bb = c2bb[ooidx][:,vvidx[0],vvidx[1]]
t2addrb, t2signb = cisd.tn_addrs_signs(nmob, noccb, 2)
fcivec[0,t2addrb] = c2bb.ravel() * t2signb
if nfroza == nfrozb == 0:
return fcivec
assert(norb < 63)
strsa = cistring.gen_strings4orblist(range(norb), neleca)
strsb = cistring.gen_strings4orblist(range(norb), nelecb)
na = len(strsa)
nb = len(strsb)
count_a = numpy.zeros(na, dtype=int)
count_b = numpy.zeros(nb, dtype=int)
parity_a = numpy.zeros(na, dtype=bool)
parity_b = numpy.zeros(nb, dtype=bool)
core_a_mask = numpy.ones(na, dtype=bool)
core_b_mask = numpy.ones(nb, dtype=bool)
for i in range(norb):
if frozena_mask[i]:
if i < neleca:
core_a_mask &= (strsa & (1<<i)) != 0
parity_a ^= (count_a & 1) == 1
else:
core_a_mask &= (strsa & (1<<i)) == 0
else:
count_a += (strsa & (1<<i)) != 0
if frozenb_mask[i]:
if i < nelecb:
core_b_mask &= (strsb & (1<<i)) != 0
parity_b ^= (count_b & 1) == 1
else:
core_b_mask &= (strsb & (1<<i)) == 0
else:
count_b += (strsb & (1<<i)) != 0
sub_strsa = strsa[core_a_mask & (count_a == nocca)]
sub_strsb = strsb[core_b_mask & (count_b == noccb)]
addrsa = cistring.strs2addr(norb, neleca, sub_strsa)
addrsb = cistring.strs2addr(norb, nelecb, sub_strsb)
fcivec1 = numpy.zeros((na,nb))
fcivec1[addrsa[:,None],addrsb] = fcivec
fcivec1[parity_a,:] *= -1
fcivec1[:,parity_b] *= -1
return fcivec1
def from_fcivec(ci0, norb, nelec, frozen=0):
'''Extract CISD coefficients from FCI coefficients'''
if frozen is not 0:
raise NotImplementedError
if isinstance(nelec, (int, numpy.number)):
nelecb = nelec//2
neleca = nelec - nelecb
else:
neleca, nelecb = nelec
norba = norbb = norb
nocc = nocca, noccb = neleca, nelecb
nvira = norba - nocca
nvirb = norbb - noccb
t1addra, t1signa = cisd.tn_addrs_signs(norba, nocca, 1)
t1addrb, t1signb = cisd.tn_addrs_signs(norbb, noccb, 1)
na = cistring.num_strings(norba, nocca)
nb = cistring.num_strings(norbb, noccb)
ci0 = ci0.reshape(na,nb)
c0 = ci0[0,0]
c1a = (ci0[t1addra,0] * t1signa).reshape(nocca,nvira)
c1b = (ci0[0,t1addrb] * t1signb).reshape(noccb,nvirb)
c2ab = numpy.einsum('i,j,ij->ij', t1signa, t1signb, ci0[t1addra[:,None],t1addrb])
c2ab = c2ab.reshape(nocca,nvira,noccb,nvirb).transpose(0,2,1,3)
t2addra, t2signa = cisd.tn_addrs_signs(norba, nocca, 2)
t2addrb, t2signb = cisd.tn_addrs_signs(norbb, noccb, 2)
c2aa = (ci0[t2addra,0] * t2signa).reshape(nocca*(nocca-1)//2, nvira*(nvira-1)//2)
c2aa = _unpack_4fold(c2aa, nocca, nvira)
c2bb = (ci0[0,t2addrb] * t2signb).reshape(noccb*(noccb-1)//2, nvirb*(nvirb-1)//2)
c2bb = _unpack_4fold(c2bb, noccb, nvirb)
return amplitudes_to_cisdvec(c0, (c1a,c1b), (c2aa,c2ab,c2bb))
def overlap(cibra, ciket, nmo, nocc, s=None):
'''Overlap between two CISD wavefunctions.
Args:
s : a list of 2D arrays
The overlap matrix of non-orthogonal one-particle basis
'''
if s is None:
return dot(cibra, ciket, nmo, nocc)
if isinstance(nmo, (int, numpy.integer)):
nmoa = nmob = nmo
else:
nmoa, nmob = nmo
nocca, noccb = nocc
nvira, nvirb = nmoa - nocca, nmob - noccb
bra0, bra1, bra2 = cisdvec_to_amplitudes(cibra, (nmoa,nmob), nocc)
ket0, ket1, ket2 = cisdvec_to_amplitudes(ciket, (nmoa,nmob), nocc)
ooidx = numpy.tril_indices(nocca, -1)
vvidx = numpy.tril_indices(nvira, -1)
bra2aa = lib.take_2d(bra2[0].reshape(nocca**2,nvira**2),
ooidx[0]*nocca+ooidx[1], vvidx[0]*nvira+vvidx[1])
ket2aa = lib.take_2d(ket2[0].reshape(nocca**2,nvira**2),
ooidx[0]*nocca+ooidx[1], vvidx[0]*nvira+vvidx[1])
ooidx = numpy.tril_indices(noccb, -1)
vvidx = numpy.tril_indices(nvirb, -1)
bra2bb = lib.take_2d(bra2[2].reshape(noccb**2,nvirb**2),
ooidx[0]*noccb+ooidx[1], vvidx[0]*nvirb+vvidx[1])
ket2bb = lib.take_2d(ket2[2].reshape(noccb**2,nvirb**2),
ooidx[0]*noccb+ooidx[1], vvidx[0]*nvirb+vvidx[1])
nova = nocca * nvira
novb = noccb * nvirb
occlist0a = numpy.arange(nocca).reshape(1,nocca)
occlist0b = numpy.arange(noccb).reshape(1,noccb)
occlistsa = numpy.repeat(occlist0a, 1+nova+bra2aa.size, axis=0)
occlistsb = numpy.repeat(occlist0b, 1+novb+bra2bb.size, axis=0)
occlist0a = occlistsa[:1]
occlist1a = occlistsa[1:1+nova]
occlist2a = occlistsa[1+nova:]
occlist0b = occlistsb[:1]
occlist1b = occlistsb[1:1+novb]
occlist2b = occlistsb[1+novb:]
ia = 0
for i in range(nocca):
for a in range(nocca, nmoa):
occlist1a[ia,i] = a
ia += 1
ia = 0
for i in range(noccb):
for a in range(noccb, nmob):
occlist1b[ia,i] = a
ia += 1
ia = 0
for i in range(nocca):
for j in range(i):
for a in range(nocca, nmoa):
for b in range(nocca, a):
occlist2a[ia,i] = a
occlist2a[ia,j] = b
ia += 1
ia = 0
for i in range(noccb):
for j in range(i):
for a in range(noccb, nmob):
for b in range(noccb, a):
occlist2b[ia,i] = a
occlist2b[ia,j] = b
ia += 1
na = len(occlistsa)
trans_a = numpy.empty((na,na))
for i, idx in enumerate(occlistsa):
s_sub = s[0][idx].T.copy()
minors = s_sub[occlistsa]
trans_a[i,:] = numpy.linalg.det(minors)
nb = len(occlistsb)
trans_b = numpy.empty((nb,nb))
for i, idx in enumerate(occlistsb):
s_sub = s[1][idx].T.copy()
minors = s_sub[occlistsb]
trans_b[i,:] = numpy.linalg.det(minors)
# Mimic the transformation einsum('ab,ap->pb', FCI, trans).
# The wavefunction FCI has the [excitation_alpha,excitation_beta]
# representation. The zero blocks like FCI[S_alpha,D_beta],
# FCI[D_alpha,D_beta], are explicitly excluded.
bra_mat = numpy.zeros((na,nb))
bra_mat[0,0] = bra0
bra_mat[1:1+nova,0] = bra1[0].ravel()
bra_mat[0,1:1+novb] = bra1[1].ravel()
bra_mat[1+nova:,0] = bra2aa.ravel()
bra_mat[0,1+novb:] = bra2bb.ravel()
bra_mat[1:1+nova,1:1+novb] = bra2[1].transpose(0,2,1,3).reshape(nova,novb)
c_s = lib.einsum('ab,ap,bq->pq', bra_mat, trans_a, trans_b)
ovlp = c_s[0,0] * ket0
ovlp += numpy.dot(c_s[1:1+nova,0], ket1[0].ravel())
ovlp += numpy.dot(c_s[0,1:1+novb], ket1[1].ravel())
ovlp += numpy.dot(c_s[1+nova:,0] , ket2aa.ravel())
ovlp += numpy.dot(c_s[0,1+novb:] , ket2bb.ravel())
ovlp += numpy.einsum('ijab,iajb->', ket2[1],
c_s[1:1+nova,1:1+novb].reshape(nocca,nvira,noccb,nvirb))
return ovlp
def make_rdm1(myci, civec=None, nmo=None, nocc=None, ao_repr=False):
r'''
One-particle spin density matrices dm1a, dm1b in MO basis (the
occupied-virtual blocks due to the orbital response contribution are not
included).
dm1a[p,q] = <q_alpha^\dagger p_alpha>
dm1b[p,q] = <q_beta^\dagger p_beta>
The convention of 1-pdm is based on McWeeney's book, Eq (5.4.20).
'''
if civec is None: civec = myci.ci
if nmo is None: nmo = myci.nmo
if nocc is None: nocc = myci.nocc
d1 = _gamma1_intermediates(myci, civec, nmo, nocc)
return uccsd_rdm._make_rdm1(myci, d1, with_frozen=True, ao_repr=ao_repr)
def make_rdm2(myci, civec=None, nmo=None, nocc=None):
r'''
Two-particle spin density matrices dm2aa, dm2ab, dm2bb in MO basis
dm2aa[p,q,r,s] = <q_alpha^\dagger s_alpha^\dagger r_alpha p_alpha>
dm2ab[p,q,r,s] = <q_alpha^\dagger s_beta^\dagger r_beta p_alpha>
dm2bb[p,q,r,s] = <q_beta^\dagger s_beta^\dagger r_beta p_beta>
(p,q correspond to one particle and r,s correspond to another particle)
Two-particle density matrix should be contracted to integrals with the
pattern below to compute energy
E = numpy.einsum('pqrs,pqrs', eri_aa, dm2_aa)
E+= numpy.einsum('pqrs,pqrs', eri_ab, dm2_ab)
E+= numpy.einsum('pqrs,rspq', eri_ba, dm2_ab)
E+= numpy.einsum('pqrs,pqrs', eri_bb, dm2_bb)
where eri_aa[p,q,r,s] = (p_alpha q_alpha | r_alpha s_alpha )
eri_ab[p,q,r,s] = ( p_alpha q_alpha | r_beta s_beta )
eri_ba[p,q,r,s] = ( p_beta q_beta | r_alpha s_alpha )
eri_bb[p,q,r,s] = ( p_beta q_beta | r_beta s_beta )
'''
if civec is None: civec = myci.ci
if nmo is None: nmo = myci.nmo
if nocc is None: nocc = myci.nocc
d1 = _gamma1_intermediates(myci, civec, nmo, nocc)
d2 = _gamma2_intermediates(myci, civec, nmo, nocc)
return uccsd_rdm._make_rdm2(myci, d1, d2, with_dm1=True, with_frozen=True)
def _gamma1_intermediates(myci, civec, nmo, nocc):
nmoa, nmob = nmo
nocca, noccb = nocc
c0, c1, c2 = cisdvec_to_amplitudes(civec, nmo, nocc)
c1a, c1b = c1
c2aa, c2ab, c2bb = c2
dvoa = c0.conj() * c1a.T
dvob = c0.conj() * c1b.T
dvoa += numpy.einsum('jb,ijab->ai', c1a.conj(), c2aa)
dvoa += numpy.einsum('jb,ijab->ai', c1b.conj(), c2ab)
dvob += numpy.einsum('jb,ijab->ai', c1b.conj(), c2bb)
dvob += numpy.einsum('jb,jiba->ai', c1a.conj(), c2ab)
dova = dvoa.T.conj()
dovb = dvob.T.conj()
dooa =-numpy.einsum('ia,ka->ik', c1a.conj(), c1a)
doob =-numpy.einsum('ia,ka->ik', c1b.conj(), c1b)
dooa -= numpy.einsum('ijab,ikab->jk', c2aa.conj(), c2aa) * .5
dooa -= numpy.einsum('jiab,kiab->jk', c2ab.conj(), c2ab)
doob -= numpy.einsum('ijab,ikab->jk', c2bb.conj(), c2bb) * .5
doob -= numpy.einsum('ijab,ikab->jk', c2ab.conj(), c2ab)
dvva = numpy.einsum('ia,ic->ac', c1a, c1a.conj())
dvvb = numpy.einsum('ia,ic->ac', c1b, c1b.conj())
dvva += numpy.einsum('ijab,ijac->bc', c2aa, c2aa.conj()) * .5
dvva += numpy.einsum('ijba,ijca->bc', c2ab, c2ab.conj())
dvvb += numpy.einsum('ijba,ijca->bc', c2bb, c2bb.conj()) * .5
dvvb += numpy.einsum('ijab,ijac->bc', c2ab, c2ab.conj())
return (dooa, doob), (dova, dovb), (dvoa, dvob), (dvva, dvvb)
def _gamma2_intermediates(myci, civec, nmo, nocc):
nmoa, nmob = nmo
nocca, noccb = nocc
c0, c1, c2 = cisdvec_to_amplitudes(civec, nmo, nocc)
c1a, c1b = c1
c2aa, c2ab, c2bb = c2
goovv = c0 * c2aa.conj() * .5
goOvV = c0 * c2ab.conj()
gOOVV = c0 * c2bb.conj() * .5
govvv = numpy.einsum('ia,ikcd->kadc', c1a, c2aa.conj()) * .5
gOvVv = numpy.einsum('ia,ikcd->kadc', c1a, c2ab.conj())
goVvV = numpy.einsum('ia,kidc->kadc', c1b, c2ab.conj())
gOVVV = numpy.einsum('ia,ikcd->kadc', c1b, c2bb.conj()) * .5
gooov = numpy.einsum('ia,klac->klic', c1a, c2aa.conj()) *-.5
goOoV =-numpy.einsum('ia,klac->klic', c1a, c2ab.conj())
gOoOv =-numpy.einsum('ia,lkca->klic', c1b, c2ab.conj())
gOOOV = numpy.einsum('ia,klac->klic', c1b, c2bb.conj()) *-.5
goooo = numpy.einsum('ijab,klab->ijkl', c2aa.conj(), c2aa) * .25
goOoO = numpy.einsum('ijab,klab->ijkl', c2ab.conj(), c2ab)
gOOOO = numpy.einsum('ijab,klab->ijkl', c2bb.conj(), c2bb) * .25
gvvvv = numpy.einsum('ijab,ijcd->abcd', c2aa, c2aa.conj()) * .25
gvVvV = numpy.einsum('ijab,ijcd->abcd', c2ab, c2ab.conj())
gVVVV = numpy.einsum('ijab,ijcd->abcd', c2bb, c2bb.conj()) * .25
goVoV = numpy.einsum('jIaB,kIaC->jCkB', c2ab.conj(), c2ab)
gOvOv = numpy.einsum('iJbA,iKcA->JcKb', c2ab.conj(), c2ab)
govvo = numpy.einsum('ijab,ikac->jcbk', c2aa.conj(), c2aa)
govvo+= numpy.einsum('jIbA,kIcA->jcbk', c2ab.conj(), c2ab)
goVvO = numpy.einsum('jIbA,IKAC->jCbK', c2ab.conj(), c2bb)
goVvO+= numpy.einsum('ijab,iKaC->jCbK', c2aa.conj(), c2ab)
gOVVO = numpy.einsum('ijab,ikac->jcbk', c2bb.conj(), c2bb)
gOVVO+= numpy.einsum('iJaB,iKaC->JCBK', c2ab.conj(), c2ab)
govvo+= numpy.einsum('ia,jb->ibaj', c1a.conj(), c1a)
goVvO+= numpy.einsum('ia,jb->ibaj', c1a.conj(), c1b)
gOVVO+= numpy.einsum('ia,jb->ibaj', c1b.conj(), c1b)
dovov = goovv.transpose(0,2,1,3) - goovv.transpose(0,3,1,2)
doooo = goooo.transpose(0,2,1,3) - goooo.transpose(0,3,1,2)
dvvvv = gvvvv.transpose(0,2,1,3) - gvvvv.transpose(0,3,1,2)
dovvo = govvo.transpose(0,2,1,3)
dooov = gooov.transpose(0,2,1,3) - gooov.transpose(1,2,0,3)
dovvv = govvv.transpose(0,2,1,3) - govvv.transpose(0,3,1,2)
doovv =-dovvo.transpose(0,3,2,1)
dvvov = None
dOVOV = gOOVV.transpose(0,2,1,3) - gOOVV.transpose(0,3,1,2)
dOOOO = gOOOO.transpose(0,2,1,3) - gOOOO.transpose(0,3,1,2)
dVVVV = gVVVV.transpose(0,2,1,3) - gVVVV.transpose(0,3,1,2)
dOVVO = gOVVO.transpose(0,2,1,3)
dOOOV = gOOOV.transpose(0,2,1,3) - gOOOV.transpose(1,2,0,3)
dOVVV = gOVVV.transpose(0,2,1,3) - gOVVV.transpose(0,3,1,2)
dOOVV =-dOVVO.transpose(0,3,2,1)
dVVOV = None
dovOV = goOvV.transpose(0,2,1,3)
dooOO = goOoO.transpose(0,2,1,3)
dvvVV = gvVvV.transpose(0,2,1,3)
dovVO = goVvO.transpose(0,2,1,3)
dooOV = goOoV.transpose(0,2,1,3)
dovVV = goVvV.transpose(0,2,1,3)
dooVV = goVoV.transpose(0,2,1,3)
dooVV = -(dooVV + dooVV.transpose(1,0,3,2).conj()) * .5
dvvOV = None
dOVov = None
dOOoo = None
dVVvv = None
dOVvo = dovVO.transpose(3,2,1,0).conj()
dOOov = gOoOv.transpose(0,2,1,3)
dOVvv = gOvVv.transpose(0,2,1,3)
dOOvv = gOvOv.transpose(0,2,1,3)
dOOvv =-(dOOvv + dOOvv.transpose(1,0,3,2).conj()) * .5
dVVov = None
return ((dovov, dovOV, dOVov, dOVOV),
(dvvvv, dvvVV, dVVvv, dVVVV),
(doooo, dooOO, dOOoo, dOOOO),
(doovv, dooVV, dOOvv, dOOVV),
(dovvo, dovVO, dOVvo, dOVVO),
(dvvov, dvvOV, dVVov, dVVOV),
(dovvv, dovVV, dOVvv, dOVVV),
(dooov, dooOV, dOOov, dOOOV))
def trans_rdm1(myci, cibra, ciket, nmo=None, nocc=None):
r'''
One-particle spin density matrices dm1a, dm1b in MO basis (the
occupied-virtual blocks due to the orbital response contribution are not
included).
dm1a[p,q] = <q_alpha^\dagger p_alpha>
dm1b[p,q] = <q_beta^\dagger p_beta>
The convention of 1-pdm is based on McWeeney's book, Eq (5.4.20).
'''
if nmo is None: nmo = myci.nmo
if nocc is None: nocc = myci.nocc
c0bra, c1bra, c2bra = myci.cisdvec_to_amplitudes(cibra, nmo, nocc)
c0ket, c1ket, c2ket = myci.cisdvec_to_amplitudes(ciket, nmo, nocc)
nmoa, nmob = nmo
nocca, noccb = nocc
bra1a, bra1b = c1bra
bra2aa, bra2ab, bra2bb = c2bra
ket1a, ket1b = c1ket
ket2aa, ket2ab, ket2bb = c2ket
dvoa = c0bra.conj() * ket1a.T
dvob = c0bra.conj() * ket1b.T
dvoa += numpy.einsum('jb,ijab->ai', bra1a.conj(), ket2aa)
dvoa += numpy.einsum('jb,ijab->ai', bra1b.conj(), ket2ab)
dvob += numpy.einsum('jb,ijab->ai', bra1b.conj(), ket2bb)
dvob += numpy.einsum('jb,jiba->ai', bra1a.conj(), ket2ab)
dova = c0ket * bra1a.conj()
dovb = c0ket * bra1b.conj()
dova += numpy.einsum('jb,ijab->ia', ket1a.conj(), bra2aa)
dova += numpy.einsum('jb,ijab->ia', ket1b.conj(), bra2ab)
dovb += numpy.einsum('jb,ijab->ia', ket1b.conj(), bra2bb)
dovb += numpy.einsum('jb,jiba->ia', ket1a.conj(), bra2ab)
dooa =-numpy.einsum('ia,ka->ik', bra1a.conj(), ket1a)
doob =-numpy.einsum('ia,ka->ik', bra1b.conj(), ket1b)
dooa -= numpy.einsum('ijab,ikab->jk', bra2aa.conj(), ket2aa) * .5
dooa -= numpy.einsum('jiab,kiab->jk', bra2ab.conj(), ket2ab)
doob -= numpy.einsum('ijab,ikab->jk', bra2bb.conj(), ket2bb) * .5
doob -= numpy.einsum('ijab,ikab->jk', bra2ab.conj(), ket2ab)
dvva = numpy.einsum('ia,ic->ac', ket1a, bra1a.conj())
dvvb = numpy.einsum('ia,ic->ac', ket1b, bra1b.conj())
dvva += numpy.einsum('ijab,ijac->bc', ket2aa, bra2aa.conj()) * .5
dvva += numpy.einsum('ijba,ijca->bc', ket2ab, bra2ab.conj())
dvvb += numpy.einsum('ijba,ijca->bc', ket2bb, bra2bb.conj()) * .5
dvvb += numpy.einsum('ijab,ijac->bc', ket2ab, bra2ab.conj())
dm1a = numpy.empty((nmoa,nmoa), dtype=dooa.dtype)
dm1a[:nocca,:nocca] = dooa
dm1a[:nocca,nocca:] = dova
dm1a[nocca:,:nocca] = dvoa
dm1a[nocca:,nocca:] = dvva
norm = numpy.dot(cibra, ciket)
dm1a[numpy.diag_indices(nocca)] += norm
dm1b = numpy.empty((nmob,nmob), dtype=dooa.dtype)
dm1b[:noccb,:noccb] = doob
dm1b[:noccb,noccb:] = dovb
dm1b[noccb:,:noccb] = dvob
dm1b[noccb:,noccb:] = dvvb
dm1b[numpy.diag_indices(noccb)] += norm
if not (myci.frozen is 0 or myci.frozen is None):
nmoa = myci.mo_occ[0].size
nmob = myci.mo_occ[1].size
nocca = numpy.count_nonzero(myci.mo_occ[0] > 0)
noccb = numpy.count_nonzero(myci.mo_occ[1] > 0)
rdm1a = numpy.zeros((nmoa,nmoa), dtype=dm1a.dtype)
rdm1b = numpy.zeros((nmob,nmob), dtype=dm1b.dtype)
rdm1a[numpy.diag_indices(nocca)] = norm
rdm1b[numpy.diag_indices(noccb)] = norm
moidx = myci.get_frozen_mask()
moidxa = numpy.where(moidx[0])[0]
moidxb = numpy.where(moidx[1])[0]
rdm1a[moidxa[:,None],moidxa] = dm1a
rdm1b[moidxb[:,None],moidxb] = dm1b
dm1a = rdm1a
dm1b = rdm1b
return dm1a, dm1b
class UCISD(cisd.CISD):
def vector_size(self):
norba, norbb = self.nmo
nocca, noccb = self.nocc
nvira = norba - nocca
nvirb = norbb - noccb
nooa = nocca * (nocca-1) // 2
nvva = nvira * (nvira-1) // 2
noob = noccb * (noccb-1) // 2
nvvb = nvirb * (nvirb-1) // 2
size = (1 + nocca*nvira + noccb*nvirb +
nocca*noccb*nvira*nvirb + nooa*nvva + noob*nvvb)
return size
get_nocc = uccsd.get_nocc
get_nmo = uccsd.get_nmo
get_frozen_mask = uccsd.get_frozen_mask
def get_init_guess(self, eris=None, nroots=1, diag=None):
if eris is None: eris = self.ao2mo(self.mo_coeff)
nocca, noccb = self.nocc
mo_ea, mo_eb = eris.mo_energy
eia_a = mo_ea[:nocca,None] - mo_ea[None,nocca:]
eia_b = mo_eb[:noccb,None] - mo_eb[None,noccb:]
t1a = eris.focka[:nocca,nocca:].conj() / eia_a
t1b = eris.fockb[:noccb,noccb:].conj() / eia_b
eris_ovov = _cp(eris.ovov)
eris_ovOV = _cp(eris.ovOV)
eris_OVOV = _cp(eris.OVOV)
t2aa = eris_ovov.transpose(0,2,1,3) - eris_ovov.transpose(0,2,3,1)
t2bb = eris_OVOV.transpose(0,2,1,3) - eris_OVOV.transpose(0,2,3,1)
t2ab = eris_ovOV.transpose(0,2,1,3).copy()
t2aa = t2aa.conj()
t2ab = t2ab.conj()
t2bb = t2bb.conj()
t2aa /= lib.direct_sum('ia+jb->ijab', eia_a, eia_a)
t2ab /= lib.direct_sum('ia+jb->ijab', eia_a, eia_b)
t2bb /= lib.direct_sum('ia+jb->ijab', eia_b, eia_b)
emp2 = numpy.einsum('iajb,ijab', eris_ovov, t2aa) * .25
emp2 -= numpy.einsum('jaib,ijab', eris_ovov, t2aa) * .25
emp2 += numpy.einsum('iajb,ijab', eris_OVOV, t2bb) * .25
emp2 -= numpy.einsum('jaib,ijab', eris_OVOV, t2bb) * .25
emp2 += numpy.einsum('iajb,ijab', eris_ovOV, t2ab)
self.emp2 = emp2.real
logger.info(self, 'Init t2, MP2 energy = %.15g', self.emp2)
if abs(emp2) < 1e-3 and (abs(t1a).sum()+abs(t1b).sum()) < 1e-3:
t1a = 1e-1 / eia_a
t1b = 1e-1 / eia_b
ci_guess = amplitudes_to_cisdvec(1, (t1a,t1b), (t2aa,t2ab,t2bb))
if nroots > 1:
civec_size = ci_guess.size
ci1_size = t1a.size + t1b.size
dtype = ci_guess.dtype
nroots = min(ci1_size+1, nroots)
if diag is None:
idx = range(1, nroots)
else:
idx = diag[:ci1_size+1].argsort()[1:nroots] # exclude HF determinant
ci_guess = [ci_guess]
for i in idx:
g = numpy.zeros(civec_size, dtype)
g[i] = 1.0
ci_guess.append(g)
return self.emp2, ci_guess
contract = contract
make_diagonal = make_diagonal
_dot = None
_add_vvvv = uccsd._add_vvvv
def ao2mo(self, mo_coeff=None):
nmoa, nmob = self.get_nmo()
nao = self.mo_coeff[0].shape[0]
nmo_pair = nmoa * (nmoa+1) // 2
nao_pair = nao * (nao+1) // 2
mem_incore = (max(nao_pair**2, nmoa**4) + nmo_pair**2) * 8/1e6
mem_now = lib.current_memory()[0]
if (self._scf._eri is not None and
(mem_incore+mem_now < self.max_memory) or self.mol.incore_anyway):
return uccsd._make_eris_incore(self, mo_coeff)
elif getattr(self._scf, 'with_df', None):
raise NotImplementedError
else:
return uccsd._make_eris_outcore(self, mo_coeff)
def to_fcivec(self, cisdvec, nmo=None, nocc=None):
return to_fcivec(cisdvec, nmo, nocc)
def from_fcivec(self, fcivec, nmo=None, nocc=None):
return from_fcivec(fcivec, nmo, nocc)
def amplitudes_to_cisdvec(self, c0, c1, c2):
return amplitudes_to_cisdvec(c0, c1, c2)
def cisdvec_to_amplitudes(self, civec, nmo=None, nocc=None):
if nmo is None: nmo = self.nmo
if nocc is None: nocc = self.nocc
return cisdvec_to_amplitudes(civec, nmo, nocc)
make_rdm1 = make_rdm1
make_rdm2 = make_rdm2
trans_rdm1 = trans_rdm1
def nuc_grad_method(self):
from pyscf.grad import ucisd
return ucisd.Gradients(self)
CISD = UCISD
from pyscf import scf
scf.uhf.UHF.CISD = lib.class_as_method(CISD)
def _cp(a):
return numpy.array(a, copy=False, order='C')
if __name__ == '__main__':
from pyscf import gto
from pyscf import scf
from pyscf import ao2mo
mol = gto.Mole()
mol.verbose = 0
mol.atom = [
['O', ( 0., 0. , 0. )],
['H', ( 0., -0.757, 0.587)],
['H', ( 0., 0.757 , 0.587)],]
mol.basis = {'H': 'sto-3g',
'O': 'sto-3g',}
# mol.build()
# mf = scf.UHF(mol).run(conv_tol=1e-14)
# myci = CISD(mf)
# eris = myci.ao2mo()
# ecisd, civec = myci.kernel(eris=eris)
# print(ecisd - -0.048878084082066106)
#
# nmoa = mf.mo_energy[0].size