def test_update_lambda_real(self):
numpy.random.seed(21)
eris = mycc.ao2mo()
gcc1 = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
eri1 = gcc1.ao2mo()
orbspin = eri1.orbspin
nocc = mol.nelectron
nvir = mol.nao_nr() * 2 - nocc
t1r = numpy.random.random((nocc, nvir)) * .1
t2r = numpy.random.random((nocc, nocc, nvir, nvir)) * .1
t2r = t2r - t2r.transpose(1, 0, 2, 3)
t2r = t2r - t2r.transpose(0, 1, 3, 2)
l1r = numpy.random.random((nocc, nvir)) * .1
l2r = numpy.random.random((nocc, nocc, nvir, nvir)) * .1
l2r = l2r - l2r.transpose(1, 0, 2, 3)
l2r = l2r - l2r.transpose(0, 1, 3, 2)
t1r = addons.spin2spatial(t1r, orbspin)
t2r = addons.spin2spatial(t2r, orbspin)
t1r = addons.spatial2spin(t1r, orbspin)
t2r = addons.spatial2spin(t2r, orbspin)
l1r = addons.spin2spatial(l1r, orbspin)
l2r = addons.spin2spatial(l2r, orbspin)
l1r = addons.spatial2spin(l1r, orbspin)
l2r = addons.spatial2spin(l2r, orbspin)
imds = gccsd_lambda.make_intermediates(gcc1, t1r, t2r, eri1)
l1ref, l2ref = gccsd_lambda.update_lambda(gcc1, t1r, t2r, l1r, l2r,
eri1, imds)
t1 = addons.spin2spatial(t1r, orbspin)
t2 = addons.spin2spatial(t2r, orbspin)
l1 = addons.spin2spatial(l1r, orbspin)
l2 = addons.spin2spatial(l2r, orbspin)
imds = uccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1, l2 = uccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
self.assertAlmostEqual(
float(abs(addons.spatial2spin(l1, orbspin) - l1ref).max()), 0, 8)
self.assertAlmostEqual(
float(abs(addons.spatial2spin(l2, orbspin) - l2ref).max()), 0, 8)
l1ref = addons.spin2spatial(l1ref, orbspin)
l2ref = addons.spin2spatial(l2ref, orbspin)
self.assertAlmostEqual(abs(l1[0] - l1ref[0]).max(), 0, 8)
self.assertAlmostEqual(abs(l1[1] - l1ref[1]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[0] - l2ref[0]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[1] - l2ref[1]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[2] - l2ref[2]).max(), 0, 8)
def test_update_lambda_real(self):
numpy.random.seed(21)
eris = mycc.ao2mo()
gcc1 = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
eri1 = gcc1.ao2mo()
orbspin = eri1.orbspin
nocc = mol.nelectron
nvir = mol.nao_nr()*2 - nocc
t1r = numpy.random.random((nocc,nvir))*.1
t2r = numpy.random.random((nocc,nocc,nvir,nvir))*.1
t2r = t2r - t2r.transpose(1,0,2,3)
t2r = t2r - t2r.transpose(0,1,3,2)
l1r = numpy.random.random((nocc,nvir))*.1
l2r = numpy.random.random((nocc,nocc,nvir,nvir))*.1
l2r = l2r - l2r.transpose(1,0,2,3)
l2r = l2r - l2r.transpose(0,1,3,2)
t1r = addons.spin2spatial(t1r, orbspin)
t2r = addons.spin2spatial(t2r, orbspin)
t1r = addons.spatial2spin(t1r, orbspin)
t2r = addons.spatial2spin(t2r, orbspin)
l1r = addons.spin2spatial(l1r, orbspin)
l2r = addons.spin2spatial(l2r, orbspin)
l1r = addons.spatial2spin(l1r, orbspin)
l2r = addons.spatial2spin(l2r, orbspin)
imds = gccsd_lambda.make_intermediates(gcc1, t1r, t2r, eri1)
l1ref, l2ref = gccsd_lambda.update_lambda(gcc1, t1r, t2r, l1r, l2r, eri1, imds)
t1 = addons.spin2spatial(t1r, orbspin)
t2 = addons.spin2spatial(t2r, orbspin)
l1 = addons.spin2spatial(l1r, orbspin)
l2 = addons.spin2spatial(l2r, orbspin)
imds = uccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1, l2 = uccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
self.assertAlmostEqual(float(abs(addons.spatial2spin(l1, orbspin)-l1ref).max()), 0, 8)
self.assertAlmostEqual(float(abs(addons.spatial2spin(l2, orbspin)-l2ref).max()), 0, 8)
l1ref = addons.spin2spatial(l1ref, orbspin)
l2ref = addons.spin2spatial(l2ref, orbspin)
self.assertAlmostEqual(abs(l1[0]-l1ref[0]).max(), 0, 8)
self.assertAlmostEqual(abs(l1[1]-l1ref[1]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[0]-l2ref[0]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[1]-l2ref[1]).max(), 0, 8)
self.assertAlmostEqual(abs(l2[2]-l2ref[2]).max(), 0, 8)
def make_intermediates(mycc, t1, t2, eris):
imds = gccsd_lambda.make_intermediates(mycc, t1, t2, eris)
nocc, nvir = t1.shape
bcei = numpy.asarray(eris.ovvv).conj().transpose(3, 2, 1, 0)
majk = numpy.asarray(eris.ooov).conj().transpose(2, 3, 0, 1)
bcjk = numpy.asarray(eris.oovv).conj().transpose(2, 3, 0, 1)
mo_e = eris.mo_energy
eia = mo_e[:nocc, None] - mo_e[nocc:]
d3 = lib.direct_sum('ia+jb+kc->ijkabc', eia, eia, eia)
t3c = (numpy.einsum('jkae,bcei->ijkabc', t2, bcei) -
numpy.einsum('imbc,majk->ijkabc', t2, majk))
t3c = t3c - t3c.transpose(0, 1, 2, 4, 3, 5) - t3c.transpose(
0, 1, 2, 5, 4, 3)
t3c = t3c - t3c.transpose(1, 0, 2, 3, 4, 5) - t3c.transpose(
2, 1, 0, 3, 4, 5)
t3c /= d3
t3d = numpy.einsum('ia,bcjk->ijkabc', t1, bcjk)
t3d += numpy.einsum('ai,jkbc->ijkabc', eris.fock[nocc:, :nocc], t2)
t3d = t3d - t3d.transpose(0, 1, 2, 4, 3, 5) - t3d.transpose(
0, 1, 2, 5, 4, 3)
t3d = t3d - t3d.transpose(1, 0, 2, 3, 4, 5) - t3d.transpose(
2, 1, 0, 3, 4, 5)
t3d /= d3
l1_t = numpy.einsum('ijkabc,jkbc->ia', t3c.conj(), eris.oovv) / eia
imds.l1_t = l1_t * .25
m3 = t3c * 2 + t3d
tmp = numpy.einsum('ijkaef,kbfe->ijab', m3.conj(), eris.ovvv) * .5
l2_t = tmp - tmp.transpose(0, 1, 3, 2)
tmp = numpy.einsum('imnabc,mnjc->ijab', m3.conj(), eris.ooov) * .5
l2_t -= tmp - tmp.transpose(1, 0, 2, 3)
l2_t += numpy.einsum('kc,ijkabc->ijab', eris.fock[:nocc, nocc:],
t3c.conj())
imds.l2_t = l2_t / lib.direct_sum('ia+jb->ijab', eia, eia)
return imds
def make_intermediates(mycc, t1, t2, eris):
imds = gccsd_lambda.make_intermediates(mycc, t1, t2, eris)
nocc, nvir = t1.shape
bcei = numpy.asarray(eris.ovvv).conj().transpose(3,2,1,0)
majk = numpy.asarray(eris.ooov).conj().transpose(2,3,0,1)
bcjk = numpy.asarray(eris.oovv).conj().transpose(2,3,0,1)
mo_e = eris.mo_energy
eia = mo_e[:nocc,None] - mo_e[nocc:]
d3 = lib.direct_sum('ia+jb+kc->ijkabc', eia, eia, eia)
t3c =(numpy.einsum('jkae,bcei->ijkabc', t2, bcei)
- numpy.einsum('imbc,majk->ijkabc', t2, majk))
t3c = t3c - t3c.transpose(0,1,2,4,3,5) - t3c.transpose(0,1,2,5,4,3)
t3c = t3c - t3c.transpose(1,0,2,3,4,5) - t3c.transpose(2,1,0,3,4,5)
t3c /= d3
t3d = numpy.einsum('ia,bcjk->ijkabc', t1, bcjk)
t3d += numpy.einsum('ai,jkbc->ijkabc', eris.fock[nocc:,:nocc], t2)
t3d = t3d - t3d.transpose(0,1,2,4,3,5) - t3d.transpose(0,1,2,5,4,3)
t3d = t3d - t3d.transpose(1,0,2,3,4,5) - t3d.transpose(2,1,0,3,4,5)
t3d /= d3
l1_t = numpy.einsum('ijkabc,jkbc->ia', t3c.conj(), eris.oovv) / eia
imds.l1_t = l1_t * .25
m3 = t3c * 2 + t3d
tmp = numpy.einsum('ijkaef,kbfe->ijab', m3.conj(), eris.ovvv) * .5
l2_t = tmp - tmp.transpose(0,1,3,2)
tmp = numpy.einsum('imnabc,mnjc->ijab', m3.conj(), eris.ooov) * .5
l2_t -= tmp - tmp.transpose(1,0,2,3)
l2_t += numpy.einsum('kc,ijkabc->ijab', eris.fock[:nocc,nocc:], t3c.conj())
imds.l2_t = l2_t / lib.direct_sum('ia+jb->ijab', eia, eia)
return imds
def test_update_amps(self):
mf = scf.UHF(mol).run()
numpy.random.seed(21)
mycc = cc.GCCSD(mf)
eris = mycc.ao2mo()
orbspin = eris.orbspin
nocc = mol.nelectron
nvir = mol.nao_nr()*2 - nocc
t1 = numpy.random.random((nocc,nvir))*.1
t2 = numpy.random.random((nocc,nocc,nvir,nvir))*.1
t2 = t2 - t2.transpose(1,0,2,3)
t2 = t2 - t2.transpose(0,1,3,2)
l1 = numpy.random.random((nocc,nvir))*.1
l2 = numpy.random.random((nocc,nocc,nvir,nvir))*.1
l2 = l2 - l2.transpose(1,0,2,3)
l2 = l2 - l2.transpose(0,1,3,2)
l1ref, l2ref = update_l1l2(mf, t1, t2, l1, l2, orbspin)
imds = gccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1, l2 = gccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
self.assertAlmostEqual(abs(l1-l1ref).max(), 0, 8)
self.assertAlmostEqual(abs(l2-l2ref).max(), 0, 8)
def test_update_amps(self):
mf = scf.UHF(mol).run()
numpy.random.seed(21)
mycc = cc.GCCSD(mf)
eris = mycc.ao2mo()
orbspin = eris.orbspin
nocc = mol.nelectron
nvir = mol.nao_nr() * 2 - nocc
t1 = numpy.random.random((nocc, nvir)) * .1
t2 = numpy.random.random((nocc, nocc, nvir, nvir)) * .1
t2 = t2 - t2.transpose(1, 0, 2, 3)
t2 = t2 - t2.transpose(0, 1, 3, 2)
l1 = numpy.random.random((nocc, nvir)) * .1
l2 = numpy.random.random((nocc, nocc, nvir, nvir)) * .1
l2 = l2 - l2.transpose(1, 0, 2, 3)
l2 = l2 - l2.transpose(0, 1, 3, 2)
l1ref, l2ref = update_l1l2(mf, t1, t2, l1, l2, orbspin)
imds = gccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1, l2 = gccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
self.assertAlmostEqual(abs(l1 - l1ref).max(), 0, 8)
self.assertAlmostEqual(abs(l2 - l2ref).max(), 0, 8)
def test_update_lambda_complex(self):
mo_coeff = mf.mo_coeff + np.sin(mf.mo_coeff) * .01j
nao = mo_coeff.shape[0]
eri = ao2mo.restore(1, mf._eri, nao)
eri0 = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_coeff.conj(),
mo_coeff, mo_coeff.conj(), mo_coeff)
nocc, nvir = 5, nao - 5
eris = rccsd._ChemistsERIs(mol)
eris.oooo = eri0[:nocc, :nocc, :nocc, :nocc].copy()
eris.ovoo = eri0[:nocc, nocc:, :nocc, :nocc].copy()
eris.oovv = eri0[:nocc, :nocc, nocc:, nocc:].copy()
eris.ovvo = eri0[:nocc, nocc:, nocc:, :nocc].copy()
eris.ovov = eri0[:nocc, nocc:, :nocc, nocc:].copy()
eris.ovvv = eri0[:nocc, nocc:, nocc:, nocc:].copy()
eris.vvvv = eri0[nocc:, nocc:, nocc:, nocc:].copy()
eris.fock = np.diag(mf.mo_energy)
np.random.seed(1)
t1 = np.random.random((nocc, nvir)) + np.random.random(
(nocc, nvir)) * .1j - .5
t2 = np.random.random((nocc, nocc, nvir, nvir)) - .5
t2 = t2 + np.sin(t2) * .1j
t2 = t2 + t2.transpose(1, 0, 3, 2)
l1 = np.random.random((nocc, nvir)) + np.random.random(
(nocc, nvir)) * .1j - .5
l2 = np.random.random((nocc, nocc, nvir, nvir)) - .5
l2 = l2 + np.sin(l2) * .1j
l2 = l2 + l2.transpose(1, 0, 3, 2)
mycc = rccsd.RCCSD(mf)
imds = rccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1new_ref, l2new_ref = rccsd_lambda.update_lambda(
mycc, t1, t2, l1, l2, eris, imds)
orbspin = np.zeros(nao * 2, dtype=int)
orbspin[1::2] = 1
eri1 = np.zeros([nao * 2] * 4, dtype=np.complex128)
eri1[0::2,0::2,0::2,0::2] = \
eri1[0::2,0::2,1::2,1::2] = \
eri1[1::2,1::2,0::2,0::2] = \
eri1[1::2,1::2,1::2,1::2] = eri0
eri1 = eri1.transpose(0, 2, 1, 3) - eri1.transpose(0, 2, 3, 1)
erig = gccsd._PhysicistsERIs(mol)
nocc *= 2
nvir *= 2
erig.oooo = eri1[:nocc, :nocc, :nocc, :nocc].copy()
erig.ooov = eri1[:nocc, :nocc, :nocc, nocc:].copy()
erig.ovov = eri1[:nocc, nocc:, :nocc, nocc:].copy()
erig.ovvo = eri1[:nocc, nocc:, nocc:, :nocc].copy()
erig.oovv = eri1[:nocc, :nocc, nocc:, nocc:].copy()
erig.ovvv = eri1[:nocc, nocc:, nocc:, nocc:].copy()
erig.vvvv = eri1[nocc:, nocc:, nocc:, nocc:].copy()
mo_e = np.array([mf.mo_energy] * 2)
erig.fock = np.diag(mo_e.T.ravel())
erig.mo_energy = erig.fock.diagonal()
myccg = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
t1, t2 = myccg.amplitudes_from_ccsd(t1, t2)
l1, l2 = myccg.amplitudes_from_ccsd(l1, l2)
imds = gccsd_lambda.make_intermediates(myccg, t1, t2, erig)
l1new, l2new = gccsd_lambda.update_lambda(myccg, t1, t2, l1, l2, erig,
imds)
self.assertAlmostEqual(float(abs(l1new[0::2, 0::2] - l1new_ref).max()),
0, 9)
l2aa = l2new[0::2, 0::2, 0::2, 0::2]
l2ab = l2new[0::2, 1::2, 0::2, 1::2]
self.assertAlmostEqual(float(abs(l2ab - l2new_ref).max()), 0, 9)
self.assertAlmostEqual(
float(abs(l2ab - l2ab.transpose(1, 0, 2, 3) - l2aa).max()), 0, 9)
def test_update_lambda_complex(self):
nocca, noccb = mol.nelec
nmo = mol.nao_nr()
nvira,nvirb = nmo-nocca, nmo-noccb
numpy.random.seed(9)
t1 = [numpy.random.random((nocca,nvira))-.9,
numpy.random.random((noccb,nvirb))-.9]
l1 = [numpy.random.random((nocca,nvira))-.9,
numpy.random.random((noccb,nvirb))-.9]
t2 = [numpy.random.random((nocca,nocca,nvira,nvira))-.9,
numpy.random.random((nocca,noccb,nvira,nvirb))-.9,
numpy.random.random((noccb,noccb,nvirb,nvirb))-.9]
t2[0] = t2[0] - t2[0].transpose(1,0,2,3)
t2[0] = t2[0] - t2[0].transpose(0,1,3,2)
t2[2] = t2[2] - t2[2].transpose(1,0,2,3)
t2[2] = t2[2] - t2[2].transpose(0,1,3,2)
l2 = [numpy.random.random((nocca,nocca,nvira,nvira))-.9,
numpy.random.random((nocca,noccb,nvira,nvirb))-.9,
numpy.random.random((noccb,noccb,nvirb,nvirb))-.9]
l2[0] = l2[0] - l2[0].transpose(1,0,2,3)
l2[0] = l2[0] - l2[0].transpose(0,1,3,2)
l2[2] = l2[2] - l2[2].transpose(1,0,2,3)
l2[2] = l2[2] - l2[2].transpose(0,1,3,2)
# eris = mycc.ao2mo()
# imds = make_intermediates(mycc, t1, t2, eris)
# l1new, l2new = update_lambda(mycc, t1, t2, l1, l2, eris, imds)
# print(lib.finger(l1new[0]) --104.55975252585894)
# print(lib.finger(l1new[1]) --241.12677819375281)
# print(lib.finger(l2new[0]) --0.4957533529669417)
# print(lib.finger(l2new[1]) - 15.46423057451851 )
# print(lib.finger(l2new[2]) - 5.8430776663704407)
nocca, noccb = mol.nelec
mo_a = mf.mo_coeff[0] + numpy.sin(mf.mo_coeff[0]) * .01j
mo_b = mf.mo_coeff[1] + numpy.sin(mf.mo_coeff[1]) * .01j
nao = mo_a.shape[0]
eri = ao2mo.restore(1, mf._eri, nao)
eri0aa = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_a.conj(), mo_a, mo_a.conj(), mo_a)
eri0ab = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_a.conj(), mo_a, mo_b.conj(), mo_b)
eri0bb = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_b.conj(), mo_b, mo_b.conj(), mo_b)
eri0ba = eri0ab.transpose(2,3,0,1)
nvira = nao - nocca
nvirb = nao - noccb
eris = uccsd._ChemistsERIs(mol)
eris.oooo = eri0aa[:nocca,:nocca,:nocca,:nocca].copy()
eris.ovoo = eri0aa[:nocca,nocca:,:nocca,:nocca].copy()
eris.oovv = eri0aa[:nocca,:nocca,nocca:,nocca:].copy()
eris.ovvo = eri0aa[:nocca,nocca:,nocca:,:nocca].copy()
eris.ovov = eri0aa[:nocca,nocca:,:nocca,nocca:].copy()
eris.ovvv = eri0aa[:nocca,nocca:,nocca:,nocca:].copy()
eris.vvvv = eri0aa[nocca:,nocca:,nocca:,nocca:].copy()
eris.OOOO = eri0bb[:noccb,:noccb,:noccb,:noccb].copy()
eris.OVOO = eri0bb[:noccb,noccb:,:noccb,:noccb].copy()
eris.OOVV = eri0bb[:noccb,:noccb,noccb:,noccb:].copy()
eris.OVVO = eri0bb[:noccb,noccb:,noccb:,:noccb].copy()
eris.OVOV = eri0bb[:noccb,noccb:,:noccb,noccb:].copy()
eris.OVVV = eri0bb[:noccb,noccb:,noccb:,noccb:].copy()
eris.VVVV = eri0bb[noccb:,noccb:,noccb:,noccb:].copy()
eris.ooOO = eri0ab[:nocca,:nocca,:noccb,:noccb].copy()
eris.ovOO = eri0ab[:nocca,nocca:,:noccb,:noccb].copy()
eris.ooVV = eri0ab[:nocca,:nocca,noccb:,noccb:].copy()
eris.ovVO = eri0ab[:nocca,nocca:,noccb:,:noccb].copy()
eris.ovOV = eri0ab[:nocca,nocca:,:noccb,noccb:].copy()
eris.ovVV = eri0ab[:nocca,nocca:,noccb:,noccb:].copy()
eris.vvVV = eri0ab[nocca:,nocca:,noccb:,noccb:].copy()
eris.OOoo = eri0ba[:noccb,:noccb,:nocca,:nocca].copy()
eris.OVoo = eri0ba[:noccb,noccb:,:nocca,:nocca].copy()
eris.OOvv = eri0ba[:noccb,:noccb,nocca:,nocca:].copy()
eris.OVvo = eri0ba[:noccb,noccb:,nocca:,:nocca].copy()
eris.OVov = eri0ba[:noccb,noccb:,:nocca,nocca:].copy()
eris.OVvv = eri0ba[:noccb,noccb:,nocca:,nocca:].copy()
eris.VVvv = eri0ba[noccb:,noccb:,nocca:,nocca:].copy()
eris.focka = numpy.diag(mf.mo_energy[0])
eris.fockb = numpy.diag(mf.mo_energy[1])
eris.mo_energy = mf.mo_energy
t1[0] = t1[0] + numpy.sin(t1[0]) * .05j
t1[1] = t1[1] + numpy.sin(t1[1]) * .05j
t2[0] = t2[0] + numpy.sin(t2[0]) * .05j
t2[1] = t2[1] + numpy.sin(t2[1]) * .05j
t2[2] = t2[2] + numpy.sin(t2[2]) * .05j
l1[0] = l1[0] + numpy.sin(l1[0]) * .05j
l1[1] = l1[1] + numpy.sin(l1[1]) * .05j
l2[0] = l2[0] + numpy.sin(l2[0]) * .05j
l2[1] = l2[1] + numpy.sin(l2[1]) * .05j
l2[2] = l2[2] + numpy.sin(l2[2]) * .05j
imds = uccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1new_ref, l2new_ref = uccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
nocc = nocca + noccb
orbspin = numpy.zeros(nao*2, dtype=int)
orbspin[1::2] = 1
orbspin[nocc-1] = 0
orbspin[nocc ] = 1
eri1 = numpy.zeros([nao*2]*4, dtype=numpy.complex)
idxa = numpy.where(orbspin == 0)[0]
idxb = numpy.where(orbspin == 1)[0]
eri1[idxa[:,None,None,None],idxa[:,None,None],idxa[:,None],idxa] = eri0aa
eri1[idxa[:,None,None,None],idxa[:,None,None],idxb[:,None],idxb] = eri0ab
eri1[idxb[:,None,None,None],idxb[:,None,None],idxa[:,None],idxa] = eri0ba
eri1[idxb[:,None,None,None],idxb[:,None,None],idxb[:,None],idxb] = eri0bb
eri1 = eri1.transpose(0,2,1,3) - eri1.transpose(0,2,3,1)
erig = gccsd._PhysicistsERIs()
erig.oooo = eri1[:nocc,:nocc,:nocc,:nocc].copy()
erig.ooov = eri1[:nocc,:nocc,:nocc,nocc:].copy()
erig.ovov = eri1[:nocc,nocc:,:nocc,nocc:].copy()
erig.ovvo = eri1[:nocc,nocc:,nocc:,:nocc].copy()
erig.oovv = eri1[:nocc,:nocc,nocc:,nocc:].copy()
erig.ovvv = eri1[:nocc,nocc:,nocc:,nocc:].copy()
erig.vvvv = eri1[nocc:,nocc:,nocc:,nocc:].copy()
mo_e = numpy.empty(nao*2)
mo_e[orbspin==0] = mf.mo_energy[0]
mo_e[orbspin==1] = mf.mo_energy[1]
erig.fock = numpy.diag(mo_e)
erig.mo_energy = mo_e.real
myccg = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
t1 = myccg.spatial2spin(t1, orbspin)
t2 = myccg.spatial2spin(t2, orbspin)
l1 = myccg.spatial2spin(l1, orbspin)
l2 = myccg.spatial2spin(l2, orbspin)
imds = gccsd_lambda.make_intermediates(myccg, t1, t2, erig)
l1new, l2new = gccsd_lambda.update_lambda(myccg, t1, t2, l1, l2, erig, imds)
l1new = myccg.spin2spatial(l1new, orbspin)
l2new = myccg.spin2spatial(l2new, orbspin)
self.assertAlmostEqual(abs(l1new[0] - l1new_ref[0]).max(), 0, 11)
self.assertAlmostEqual(abs(l1new[1] - l1new_ref[1]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[0] - l2new_ref[0]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[1] - l2new_ref[1]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[2] - l2new_ref[2]).max(), 0, 11)
def test_update_lambda_complex(self):
nocca, noccb = mol.nelec
nmo = mol.nao_nr()
nvira, nvirb = nmo - nocca, nmo - noccb
numpy.random.seed(9)
t1 = [
numpy.random.random((nocca, nvira)) - .9,
numpy.random.random((noccb, nvirb)) - .9
]
l1 = [
numpy.random.random((nocca, nvira)) - .9,
numpy.random.random((noccb, nvirb)) - .9
]
t2 = [
numpy.random.random((nocca, nocca, nvira, nvira)) - .9,
numpy.random.random((nocca, noccb, nvira, nvirb)) - .9,
numpy.random.random((noccb, noccb, nvirb, nvirb)) - .9
]
t2[0] = t2[0] - t2[0].transpose(1, 0, 2, 3)
t2[0] = t2[0] - t2[0].transpose(0, 1, 3, 2)
t2[2] = t2[2] - t2[2].transpose(1, 0, 2, 3)
t2[2] = t2[2] - t2[2].transpose(0, 1, 3, 2)
l2 = [
numpy.random.random((nocca, nocca, nvira, nvira)) - .9,
numpy.random.random((nocca, noccb, nvira, nvirb)) - .9,
numpy.random.random((noccb, noccb, nvirb, nvirb)) - .9
]
l2[0] = l2[0] - l2[0].transpose(1, 0, 2, 3)
l2[0] = l2[0] - l2[0].transpose(0, 1, 3, 2)
l2[2] = l2[2] - l2[2].transpose(1, 0, 2, 3)
l2[2] = l2[2] - l2[2].transpose(0, 1, 3, 2)
# eris = mycc.ao2mo()
# imds = make_intermediates(mycc, t1, t2, eris)
# l1new, l2new = update_lambda(mycc, t1, t2, l1, l2, eris, imds)
# print(lib.finger(l1new[0]) --104.55975252585894)
# print(lib.finger(l1new[1]) --241.12677819375281)
# print(lib.finger(l2new[0]) --0.4957533529669417)
# print(lib.finger(l2new[1]) - 15.46423057451851 )
# print(lib.finger(l2new[2]) - 5.8430776663704407)
nocca, noccb = mol.nelec
mo_a = mf.mo_coeff[0] + numpy.sin(mf.mo_coeff[0]) * .01j
mo_b = mf.mo_coeff[1] + numpy.sin(mf.mo_coeff[1]) * .01j
nao = mo_a.shape[0]
eri = ao2mo.restore(1, mf._eri, nao)
eri0aa = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_a.conj(), mo_a,
mo_a.conj(), mo_a)
eri0ab = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_a.conj(), mo_a,
mo_b.conj(), mo_b)
eri0bb = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_b.conj(), mo_b,
mo_b.conj(), mo_b)
eri0ba = eri0ab.transpose(2, 3, 0, 1)
nvira = nao - nocca
nvirb = nao - noccb
eris = uccsd._ChemistsERIs(mol)
eris.oooo = eri0aa[:nocca, :nocca, :nocca, :nocca].copy()
eris.ovoo = eri0aa[:nocca, nocca:, :nocca, :nocca].copy()
eris.oovv = eri0aa[:nocca, :nocca, nocca:, nocca:].copy()
eris.ovvo = eri0aa[:nocca, nocca:, nocca:, :nocca].copy()
eris.ovov = eri0aa[:nocca, nocca:, :nocca, nocca:].copy()
eris.ovvv = eri0aa[:nocca, nocca:, nocca:, nocca:].copy()
eris.vvvv = eri0aa[nocca:, nocca:, nocca:, nocca:].copy()
eris.OOOO = eri0bb[:noccb, :noccb, :noccb, :noccb].copy()
eris.OVOO = eri0bb[:noccb, noccb:, :noccb, :noccb].copy()
eris.OOVV = eri0bb[:noccb, :noccb, noccb:, noccb:].copy()
eris.OVVO = eri0bb[:noccb, noccb:, noccb:, :noccb].copy()
eris.OVOV = eri0bb[:noccb, noccb:, :noccb, noccb:].copy()
eris.OVVV = eri0bb[:noccb, noccb:, noccb:, noccb:].copy()
eris.VVVV = eri0bb[noccb:, noccb:, noccb:, noccb:].copy()
eris.ooOO = eri0ab[:nocca, :nocca, :noccb, :noccb].copy()
eris.ovOO = eri0ab[:nocca, nocca:, :noccb, :noccb].copy()
eris.ooVV = eri0ab[:nocca, :nocca, noccb:, noccb:].copy()
eris.ovVO = eri0ab[:nocca, nocca:, noccb:, :noccb].copy()
eris.ovOV = eri0ab[:nocca, nocca:, :noccb, noccb:].copy()
eris.ovVV = eri0ab[:nocca, nocca:, noccb:, noccb:].copy()
eris.vvVV = eri0ab[nocca:, nocca:, noccb:, noccb:].copy()
eris.OOoo = eri0ba[:noccb, :noccb, :nocca, :nocca].copy()
eris.OVoo = eri0ba[:noccb, noccb:, :nocca, :nocca].copy()
eris.OOvv = eri0ba[:noccb, :noccb, nocca:, nocca:].copy()
eris.OVvo = eri0ba[:noccb, noccb:, nocca:, :nocca].copy()
eris.OVov = eri0ba[:noccb, noccb:, :nocca, nocca:].copy()
eris.OVvv = eri0ba[:noccb, noccb:, nocca:, nocca:].copy()
eris.VVvv = eri0ba[noccb:, noccb:, nocca:, nocca:].copy()
eris.focka = numpy.diag(mf.mo_energy[0])
eris.fockb = numpy.diag(mf.mo_energy[1])
t1[0] = t1[0] + numpy.sin(t1[0]) * .05j
t1[1] = t1[1] + numpy.sin(t1[1]) * .05j
t2[0] = t2[0] + numpy.sin(t2[0]) * .05j
t2[1] = t2[1] + numpy.sin(t2[1]) * .05j
t2[2] = t2[2] + numpy.sin(t2[2]) * .05j
l1[0] = l1[0] + numpy.sin(l1[0]) * .05j
l1[1] = l1[1] + numpy.sin(l1[1]) * .05j
l2[0] = l2[0] + numpy.sin(l2[0]) * .05j
l2[1] = l2[1] + numpy.sin(l2[1]) * .05j
l2[2] = l2[2] + numpy.sin(l2[2]) * .05j
imds = uccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1new_ref, l2new_ref = uccsd_lambda.update_lambda(
mycc, t1, t2, l1, l2, eris, imds)
nocc = nocca + noccb
orbspin = numpy.zeros(nao * 2, dtype=int)
orbspin[1::2] = 1
orbspin[nocc - 1] = 0
orbspin[nocc] = 1
eri1 = numpy.zeros([nao * 2] * 4, dtype=numpy.complex)
idxa = numpy.where(orbspin == 0)[0]
idxb = numpy.where(orbspin == 1)[0]
eri1[idxa[:, None, None, None], idxa[:, None, None], idxa[:, None],
idxa] = eri0aa
eri1[idxa[:, None, None, None], idxa[:, None, None], idxb[:, None],
idxb] = eri0ab
eri1[idxb[:, None, None, None], idxb[:, None, None], idxa[:, None],
idxa] = eri0ba
eri1[idxb[:, None, None, None], idxb[:, None, None], idxb[:, None],
idxb] = eri0bb
eri1 = eri1.transpose(0, 2, 1, 3) - eri1.transpose(0, 2, 3, 1)
erig = gccsd._PhysicistsERIs()
erig.oooo = eri1[:nocc, :nocc, :nocc, :nocc].copy()
erig.ooov = eri1[:nocc, :nocc, :nocc, nocc:].copy()
erig.ovov = eri1[:nocc, nocc:, :nocc, nocc:].copy()
erig.ovvo = eri1[:nocc, nocc:, nocc:, :nocc].copy()
erig.oovv = eri1[:nocc, :nocc, nocc:, nocc:].copy()
erig.ovvv = eri1[:nocc, nocc:, nocc:, nocc:].copy()
erig.vvvv = eri1[nocc:, nocc:, nocc:, nocc:].copy()
mo_e = numpy.empty(nao * 2)
mo_e[orbspin == 0] = mf.mo_energy[0]
mo_e[orbspin == 1] = mf.mo_energy[1]
erig.fock = numpy.diag(mo_e)
myccg = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
t1 = myccg.spatial2spin(t1, orbspin)
t2 = myccg.spatial2spin(t2, orbspin)
l1 = myccg.spatial2spin(l1, orbspin)
l2 = myccg.spatial2spin(l2, orbspin)
imds = gccsd_lambda.make_intermediates(myccg, t1, t2, erig)
l1new, l2new = gccsd_lambda.update_lambda(myccg, t1, t2, l1, l2, erig,
imds)
l1new = myccg.spin2spatial(l1new, orbspin)
l2new = myccg.spin2spatial(l2new, orbspin)
self.assertAlmostEqual(abs(l1new[0] - l1new_ref[0]).max(), 0, 11)
self.assertAlmostEqual(abs(l1new[1] - l1new_ref[1]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[0] - l2new_ref[0]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[1] - l2new_ref[1]).max(), 0, 11)
self.assertAlmostEqual(abs(l2new[2] - l2new_ref[2]).max(), 0, 11)
def test_update_lambda_complex(self):
mo_coeff = mf.mo_coeff + np.sin(mf.mo_coeff) * .01j
nao = mo_coeff.shape[0]
eri = ao2mo.restore(1, mf._eri, nao)
eri0 = lib.einsum('pqrs,pi,qj,rk,sl->ijkl', eri, mo_coeff.conj(), mo_coeff,
mo_coeff.conj(), mo_coeff)
nocc, nvir = 5, nao-5
eris = rccsd._ChemistsERIs(mol)
eris.oooo = eri0[:nocc,:nocc,:nocc,:nocc].copy()
eris.ovoo = eri0[:nocc,nocc:,:nocc,:nocc].copy()
eris.oovv = eri0[:nocc,:nocc,nocc:,nocc:].copy()
eris.ovvo = eri0[:nocc,nocc:,nocc:,:nocc].copy()
eris.ovov = eri0[:nocc,nocc:,:nocc,nocc:].copy()
eris.ovvv = eri0[:nocc,nocc:,nocc:,nocc:].copy()
eris.vvvv = eri0[nocc:,nocc:,nocc:,nocc:].copy()
eris.fock = np.diag(mf.mo_energy)
np.random.seed(1)
t1 = np.random.random((nocc,nvir)) + np.random.random((nocc,nvir))*.1j - .5
t2 = np.random.random((nocc,nocc,nvir,nvir)) - .5
t2 = t2 + np.sin(t2) * .1j
t2 = t2 + t2.transpose(1,0,3,2)
l1 = np.random.random((nocc,nvir)) + np.random.random((nocc,nvir))*.1j - .5
l2 = np.random.random((nocc,nocc,nvir,nvir)) - .5
l2 = l2 + np.sin(l2) * .1j
l2 = l2 + l2.transpose(1,0,3,2)
mycc = rccsd.RCCSD(mf)
imds = rccsd_lambda.make_intermediates(mycc, t1, t2, eris)
l1new_ref, l2new_ref = rccsd_lambda.update_lambda(mycc, t1, t2, l1, l2, eris, imds)
orbspin = np.zeros(nao*2, dtype=int)
orbspin[1::2] = 1
eri1 = np.zeros([nao*2]*4, dtype=np.complex)
eri1[0::2,0::2,0::2,0::2] = \
eri1[0::2,0::2,1::2,1::2] = \
eri1[1::2,1::2,0::2,0::2] = \
eri1[1::2,1::2,1::2,1::2] = eri0
eri1 = eri1.transpose(0,2,1,3) - eri1.transpose(0,2,3,1)
erig = gccsd._PhysicistsERIs(mol)
nocc *= 2
nvir *= 2
erig.oooo = eri1[:nocc,:nocc,:nocc,:nocc].copy()
erig.ooov = eri1[:nocc,:nocc,:nocc,nocc:].copy()
erig.ovov = eri1[:nocc,nocc:,:nocc,nocc:].copy()
erig.ovvo = eri1[:nocc,nocc:,nocc:,:nocc].copy()
erig.oovv = eri1[:nocc,:nocc,nocc:,nocc:].copy()
erig.ovvv = eri1[:nocc,nocc:,nocc:,nocc:].copy()
erig.vvvv = eri1[nocc:,nocc:,nocc:,nocc:].copy()
mo_e = np.array([mf.mo_energy]*2)
erig.fock = np.diag(mo_e.T.ravel())
erig.mo_energy = erig.fock.diagonal()
myccg = gccsd.GCCSD(scf.addons.convert_to_ghf(mf))
t1, t2 = myccg.amplitudes_from_ccsd(t1, t2)
l1, l2 = myccg.amplitudes_from_ccsd(l1, l2)
imds = gccsd_lambda.make_intermediates(myccg, t1, t2, erig)
l1new, l2new = gccsd_lambda.update_lambda(myccg, t1, t2, l1, l2, erig, imds)
self.assertAlmostEqual(float(abs(l1new[0::2,0::2]-l1new_ref).max()), 0, 9)
l2aa = l2new[0::2,0::2,0::2,0::2]
l2ab = l2new[0::2,1::2,0::2,1::2]
self.assertAlmostEqual(float(abs(l2ab-l2new_ref).max()), 0, 9)
self.assertAlmostEqual(float(abs(l2ab-l2ab.transpose(1,0,2,3) - l2aa).max()), 0, 9)
