def CTMRGEvenZFTN():
FTN = FiniteTensorNetwork(tensorNames=['alu', 'ald', 'aru', 'ard'])
FTN.addLink('alu', 'u', 'ald', 'u')
FTN.addLink('aru', 'u', 'ard', 'u')
FTN.addLink('alu', 'r', 'aru', 'r')
FTN.addLink('ald', 'r', 'ard', 'r')
return FTN
def CTMRGHEdgeBuildFTN():
FTN = FiniteTensorNetwork(tensorNames=['p', 'al', 'ar'])
# our a[l, r] is only for left part; for right part of a, we need to still point "r" to p
FTN.addLink('al', 'r', 'p', 'l')
FTN.addLink('ar', 'r', 'p', 'r')
FTN.addPostNameChange('ar', 'l', 'r')
return FTN
def CTMRGVEdgeBuildFTN():
FTN = FiniteTensorNetwork(tensorNames=['p', 'au', 'ad'])
# our a[u, d] is only for down part; for up part of a, we need to still point "u" to p
FTN.addLink('ad', 'u', 'p', 'd')
FTN.addLink('au', 'u', 'p', 'u')
FTN.addPostNameChange('au', 'd', 'u')
return FTN
def test_FreeBondFTN(self):
shapeA = (300, 4, 5)
shapeB = (300, 6)
shapeC = (4, 6, 5)
a = Tensor(shape=shapeA,
labels=['a300', 'b4', 'c5'],
data=np.ones(shapeA))
b = Tensor(shape=shapeB, labels=['a300', 'd6'], data=np.ones(shapeB))
c = Tensor(shape=shapeC,
labels=['e4', 'd6', 'c5'],
data=np.ones(shapeC))
tensorDict = TensorDict()
tensorDict.setTensor('a', a)
tensorDict.setTensor('b', b)
tensorDict.setTensor('c', c)
FTN = FiniteTensorNetwork(['a', 'b'], realCost=True)
FTN.addTensor('c')
FTN.addLink('a', 'a300', 'b', 'a300')
FTN.addLink('a', 'c5', 'c', 'c5')
FTN.addLink('b', 'd6', 'c', 'd6')
result = FTN.contract(tensorDict, removeTensorTag=False)
self.assertTrue(funcs.compareLists(result.labels, ['a-b4', 'c-e4']))
self.assertEqual(int(result.a[0][1]), 9000)
result = FTN.contract(tensorDict, removeTensorTag=True)
self.assertTrue(funcs.compareLists(result.labels, ['b4', 'e4']))
self.assertEqual(int(result.a[0][1]), 9000)
FTN.unlock()
FTN.addPostNameChange('c', 'e4', 'e4FromC')
FTN.addPreNameChange('a', 'b4', 'b4FromA')
FTN.addPreNameChange('a', 'a300', 'a3')
FTN.removePreNameChange('a', 'a300', 'a3')
FTN.addPostNameChange('a', 'd6', 'foo')
FTN.removePostNameChange('a', 'd6', 'foo')
result = FTN.contract(tensorDict, removeTensorTag=True)
# print(result.labels)
self.assertTrue(
funcs.compareLists(result.labels, ['b4FromA', 'e4FromC']))
self.assertEqual(int(result.a[0][1]), 9000)
FTN.unlock()
FTN.removePostNameChange('c', 'e4', 'e4FromC')
FTN.addPreNameChange('c', 'e4', 'e4FromC')
FTN.addPostOutProduct([('a', 'b4FromA'), ('c', 'e4FromC')], 'out')
result = FTN.contract(tensorDict, removeTensorTag=True)
self.assertListEqual(result.labels, ['out'])
self.assertEqual(result.shape[0], 16)
def CTMRGCornerExtendFTN():
FTN = FiniteTensorNetwork(tensorNames=['c', 'ph', 'pv', 'w'])
FTN.addLink('c', 'u', 'pv', 'd')
FTN.addLink('c', 'r', 'ph', 'l')
FTN.addLink('pv', 'r', 'w', 'l')
FTN.addLink('ph', 'u', 'w', 'd')
FTN.addPostOutProduct(['pv-u', 'w-u'], 'u')
FTN.addPostOutProduct(['ph-r', 'w-r'], 'r')
return FTN
def CTMRGVEdgeExtendFTN():
FTN = FiniteTensorNetwork(tensorNames=['p', 'w'])
FTN.addLink('p', 'r', 'w', 'l')
FTN.addPostOutProduct(['p-u', 'w-u'], 'u')
FTN.addPostOutProduct(['p-d', 'w-d'], 'd')
# FTN.addPostNameChange('p', 'u', 'ul')
# FTN.addPostNameChange('p', 'd', 'dl')
# FTN.addPostNameChange('w', 'u', 'ur')
# FTN.addPostNameChange('w', 'd', 'dr')
return FTN
def CTMRGHEdgeExtendFTN():
FTN = FiniteTensorNetwork(tensorNames=['p', 'w'])
FTN.addLink('p', 'u', 'w', 'd')
FTN.addPostOutProduct(['p-l', 'w-l'], 'l')
FTN.addPostOutProduct(['p-r', 'w-r'], 'r')
# FTN.addPostNameChange('p', 'l', 'ld')
# FTN.addPostNameChange('p', 'r', 'rd')
# FTN.addPostNameChange('w', 'l', 'lu')
# FTN.addPostNameChange('w', 'r', 'ru')
return FTN
def triangleContractFTN():
"""
Make a finite tensor network for triangle tensor contraction.
Returns
-------
FTN : FiniteTensorNetwork
A FiniteTensorNetwork that, takes three tensors(in form of makeTriangleTensorDict), legs of which are named as ["1", "2", "3"], contract them.
"""
FTN = FiniteTensorNetwork(tensorNames=['u', 'l', 'r'])
FTN.addLink('u', '2', 'l', '3')
FTN.addLink('u', '3', 'r', '2')
FTN.addLink('l', '2', 'r', '3')
FTN.addPostNameChange('u', '1', '1')
FTN.addPostNameChange('l', '1', '2')
FTN.addPostNameChange('r', '1', '3')
return FTN
def squareContractFTN():
"""
Make a finite tensor network for square tensor contraction.
Returns
-------
FTN : FiniteTensorNetwork
A FiniteTensorNetwork that, takes 4 tensors(in form of makeSquareTensorDict), legs of which are named as ['u', 'd', 'l', 'r'], contract them.
"""
FTN = FiniteTensorNetwork(tensorNames=['ul', 'ur', 'dr', 'dl'])
FTN.addLink('ul', 'd', 'dl', 'u')
FTN.addLink('ul', 'r', 'ur', 'l')
FTN.addLink('ur', 'd', 'dr', 'u')
FTN.addLink('dl', 'r', 'dr', 'l')
FTN.addPostOutProduct(['ul-u', 'ur-u'], 'u')
FTN.addPostOutProduct(['ul-l', 'dl-l'], 'l')
FTN.addPostOutProduct(['dl-d', 'dr-d'], 'd')
FTN.addPostOutProduct(['ur-r', 'dr-r'], 'r')
return FTN
def squareContractOutFTN():
"""
Make a finite tensor network for square tensor contraction, where tensors are having inner legs and outer legs named "o".
Returns
-------
FTN : FiniteTensorNetwork
A FiniteTensorNetwork that, takes 4 tensors(in form of makeSquareTensorDict), legs of which are named as ['u'/'d', 'l'/'r', 'o'], contract them.
"""
FTN = FiniteTensorNetwork(tensorNames=['ul', 'ur', 'dr', 'dl'])
FTN.addLink('ul', 'd', 'dl', 'u')
FTN.addLink('ul', 'r', 'ur', 'l')
FTN.addLink('ur', 'd', 'dr', 'u')
FTN.addLink('dl', 'r', 'dr', 'l')
FTN.addPostNameChange('ul', 'o', 'u')
FTN.addPostNameChange('ur', 'o', 'r')
FTN.addPostNameChange('dl', 'o', 'l')
FTN.addPostNameChange('dr', 'o', 'd')
return FTN
def HOTRGVerticalContractFTN():
FTN = FiniteTensorNetwork(tensorNames=['u', 'd', 'l', 'r'])
FTN.addLink('u', 'l', 'l', 'u')
FTN.addLink('u', 'r', 'r', 'u')
FTN.addLink('d', 'l', 'l', 'd')
FTN.addLink('d', 'r', 'r', 'd')
FTN.addLink('l', 'r', 'r', 'l')
FTN.addPostNameChange('u', 'o', 'u')
FTN.addPostNameChange('d', 'o', 'd')
return FTN
def test_FTN(self):
shapeA = (300, 4, 5)
shapeB = (300, 6)
shapeC = (4, 6, 5)
a = Tensor(shape=shapeA,
labels=['a300', 'b4', 'c5'],
data=np.ones(shapeA))
b = Tensor(shape=shapeB, labels=['a300', 'd6'], data=np.ones(shapeB))
c = Tensor(shape=shapeC,
labels=['b4', 'd6', 'c5'],
data=np.ones(shapeC))
tensorDict = TensorDict()
tensorDict.setTensor('a', a)
tensorDict.setTensor('b', b)
tensorDict.setTensor('c', c)
FTN = FiniteTensorNetwork(['a', 'b'], realCost=True)
FTN.addTensor('c')
FTN.addLink('a', 'a300', 'b', 'a300')
FTN.addLink('a', 'b4', 'c', 'b4')
FTN.addLink('a', 'c5', 'c', 'c5')
FTN.addLink('b', 'd6', 'c', 'd6')
result = FTN.contract(tensorDict)
self.assertEqual(int(result.a), 36000)
self.assertListEqual(FTN.optimalSeq, [(0, 1), (2, 0)])
result2 = FTN.contract(tensorDict)
self.assertEqual(int(result2.a), 36000)
self.assertListEqual(FTN.optimalSeq, [(0, 1), (2, 0)])
newShapeA = (3, 4, 5)
newShapeB = (3, 6)
newA = Tensor(shape=newShapeA,
labels=['a300', 'b4', 'c5'],
data=np.ones(newShapeA))
newB = Tensor(shape=newShapeB,
labels=['a300', 'd6'],
data=np.ones(newShapeB))
tensorDict.setTensor('a', newA)
tensorDict.setTensor('b', newB)
result3 = FTN.contract(tensorDict)
self.assertEqual(int(result3.a), 360)
self.assertListEqual(FTN.optimalSeq, [(0, 2), (1, 0)])
self.assertEqual(FTN.bondDims['a-a300'], 3)
self.assertEqual(FTN.tensorCount, 3)
def squareVerticalContractFTN(d):
funcs.assertInSet(d, ['u', 'd'], 'vertical direction')
opd = funcs.oppositeSingleDirection(d)
FTN = FiniteTensorNetwork(tensorNames=['ul', 'ur', 'dr', 'dl'])
FTN.addLink('ul', opd, 'dl', opd)
FTN.addLink('ul', 'r', 'ur', 'l')
FTN.addLink('ur', opd, 'dr', opd)
FTN.addLink('dl', 'r', 'dr', 'l')
FTN.addLink('ul', 'l', 'dl', 'l')
FTN.addLink('ur', 'r', 'dr', 'r')
FTN.addPostOutProduct([d + 'l-' + d, d + 'r-' + d], d)
FTN.addPostOutProduct([opd + 'l-' + d, opd + 'r-' + d], opd)
return FTN
def squareHorizontalContractFTN(d):
# TODO: add docstrings for following functions
funcs.assertInSet(d, ['l', 'r'], 'horizontal direction')
opd = funcs.oppositeSingleDirection(d)
FTN = FiniteTensorNetwork(tensorNames=['ul', 'ur', 'dr', 'dl'])
FTN.addLink('ul', 'd', 'dl', 'u')
FTN.addLink('ul', opd, 'ur', opd)
FTN.addLink('ur', 'd', 'dr', 'u')
FTN.addLink('dl', opd, 'dr', opd)
FTN.addLink('ul', 'u', 'ur', 'u')
FTN.addLink('dl', 'd', 'dr', 'd')
FTN.addPostOutProduct(['u' + d + '-' + d, 'd' + d + '-' + d], d)
FTN.addPostOutProduct(['u' + opd + '-' + d, 'd' + opd + '-' + d], opd)
return FTN
def EvenblyTNRQEnvFTN():
FTN = FiniteTensorNetwork(
tensorNames=['uul', 'uur', 'udl', 'udr', 'dul', 'dur', 'ddl', 'ddr'])
FTN.addLink('udl', 'r', 'dul', 'r')
FTN.addLink('udl', 'd', 'dul', 'd')
FTN.addLink('udr', 'r', 'dur', 'r')
FTN.addLink('udr', 'd', 'dur', 'd')
FTN.addLink('udl', 'l', 'udr', 'l')
FTN.addLink('dul', 'l', 'dur', 'l')
FTN.addLink('uur', 'l', 'ddr', 'l')
FTN.addLink('uur', 'u', 'ddr', 'u')
FTN.addLink('udr', 'u', 'uur', 'd')
FTN.addLink('dur', 'u', 'ddr', 'd')
FTN.addLink('uul', 'r', 'uur', 'r')
FTN.addLink('uul', 'd', 'udl', 'u')
FTN.addLink('ddl', 'r', 'ddr', 'r')
FTN.addLink('ddl', 'd', 'dul', 'u')
FTN.addPostOutProduct(['uul-l', 'uul-u'], '1')
FTN.addPostOutProduct(['ddl-l', 'ddl-u'], '2')
return FTN
def HOTRGGiltTN():
ATensorNames = ["aul", "aur", "adl", "adr"]
QTensorNames = [
'qbll', 'qbrl', 'qall', 'qarl', 'qblr', 'qbrr', 'qalr', 'qarr', 'qbu',
'qbd', 'qau', 'qad'
] # i(circle), o(line)
wTensorNames = ['wll', 'wlr', 'wrl', 'wrr'] # u, d, o
vTensorNames = ['vu', 'vd'] # l, r, o
tensorNames = ATensorNames + QTensorNames + wTensorNames + vTensorNames
FTN = FiniteTensorNetwork(tensorNames=tensorNames)
# FTN.addLink('aul', 'adl', 'd', 'u')
# FTN.addLink('aur', 'adr', 'd', 'u')
# up / down bonds
FTN.addLink('vu', 'l', 'qbu', 'o')
FTN.addLink('vu', 'r', 'qau', 'o')
FTN.addLink('vd', 'l', 'qbd', 'o')
FTN.addLink('vd', 'r', 'qad', 'o')
# left / right bonds
FTN.addLink('wll', 'u', 'qbll', 'o')
FTN.addLink('wll', 'd', 'qall', 'o')
FTN.addLink('wrr', 'u', 'qbrr', 'o')
FTN.addLink('wrr', 'd', 'qarr', 'o')
# A left bonds
FTN.addLink('aul', 'u', 'qbu', 'i')
FTN.addLink('adl', 'd', 'qbd', 'i')
FTN.addLink('aul', 'd', 'adl', 'u')
FTN.addLink('aul', 'l', 'qbll', 'i')
FTN.addLink('adl', 'l', 'qall', 'i')
FTN.addLink('aul', 'r', 'qbrl', 'i')
FTN.addLink('adl', 'r', 'qarl', 'i')
# A right bonds
FTN.addLink('aur', 'u', 'qau', 'i')
FTN.addLink('adr', 'd', 'qad', 'i')
FTN.addLink('aur', 'd', 'adr', 'u')
FTN.addLink('aur', 'l', 'qblr', 'i')
FTN.addLink('adr', 'l', 'qalr', 'i')
FTN.addLink('aur', 'r', 'qbrr', 'i')
FTN.addLink('adr', 'r', 'qarr', 'i')
# center w bonds
FTN.addLink('wlr', 'u', 'qbrl', 'o')
FTN.addLink('wlr', 'd', 'qarl', 'o')
FTN.addLink('wrl', 'u', 'qblr', 'o')
FTN.addLink('wrl', 'd', 'qalr', 'o')
FTN.addLink('wlr', 'o', 'wrl', 'o')
tensorDict = TensorDict()
chi = 10
for ATensorName in ATensorNames:
tensorDict.setTensor(
ATensorName,
Tensor(data=np.random.randn(chi, chi, chi, chi),
labels=['u', 'l', 'd', 'r']))
for QTensorName in QTensorNames:
tensorDict.setTensor(
QTensorName,
Tensor(data=np.random.randn(chi, chi), labels=['i', 'o']))
for wTensorName in wTensorNames:
tensorDict.setTensor(
wTensorName,
Tensor(data=np.random.randn(chi, chi, chi), labels=['u', 'd',
'o']))
for vTensorName in vTensorNames:
tensorDict.setTensor(
vTensorName,
Tensor(data=np.random.randn(chi, chi, chi), labels=['l', 'r',
'o']))
res = FTN.contract(tensorDict)
print(res)
def CTMRGOddFTN():
FTN = FiniteTensorNetwork(
tensorNames=['alu', 'ald', 'aru', 'ard', 'pu', 'pd', 'pl', 'pr', 'w'])
FTN.addLink('pu', 'l', 'alu', 'r')
FTN.addLink('pu', 'r', 'aru', 'r')
FTN.addLink('pd', 'l', 'ald', 'r')
FTN.addLink('pd', 'r', 'ard', 'r')
FTN.addLink('pl', 'u', 'alu', 'u')
FTN.addLink('pl', 'd', 'ald', 'u')
FTN.addLink('pr', 'u', 'aru', 'u')
FTN.addLink('pr', 'd', 'ard', 'u')
FTN.addLink('pl', 'r', 'w', 'l')
FTN.addLink('pr', 'r', 'w', 'r')
FTN.addLink('pd', 'u', 'w', 'd')
FTN.addLink('pu', 'u', 'w', 'u')
return FTN
