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mps_node_np.py
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mps_node_np.py
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import time
import numpy as np
import math
import sys
from npsvd import svd,rsvd
class MPSNode:
def __init__(self, tensor, index, neighbor,chi=32,cutoff=1.0e-15,norm_method=1,svdopt=True,swapopt=True,verbose=0):
self.tensor = tensor
self.svdopt=svdopt
self.swapopt = swapopt
self.dtype = tensor.dtype
self.norm_method=norm_method
self.index = index
self.chi=chi
self.cutoff=cutoff
self.neighbor = neighbor
self.type="mps"
self.mps = self.raw2mps(tensor)
self.cano=0 # position of canonicalization
def find_neighbor(self,j):
re=np.argwhere(self.neighbor==j)
if(len(re) == 0):
return -1
elif(len(re)>1):
print("Something wrong in find_neighbor: there are two positions storing the same neighbor")
sys.exit(3)
else:
return re[0][0]
def raw2mps(self,tensor):
if(len(tensor.shape)==0): # scalar, a isolated node
return []
shape = [1]+list(tensor.shape)+[1]
if(len(tensor.shape)==1): # degree 1, leaf
return [tensor.reshape(shape)]
order = len(tensor.shape)
tensor = tensor.reshape(1,-1)
mps=[]
for i in range(order-1):
dleft = tensor.shape[0]
tensor = tensor.reshape(dleft*shape[i+1],-1)
[U,s,V] = svd(tensor)
s_eff = s[s>self.cutoff]
myd = min(len(s_eff),self.chi)
s_eff=s_eff[:myd]
U=U[:,:myd]
V=V[:,:myd]
s=np.diag(s_eff)
mps.append(U.reshape(dleft,shape[i+1],myd))
tensor = [email protected]
mps.append(tensor.reshape(myd,shape[order],1))
self.cano = order-1 # left canonical
return mps
def mps2raw(self,mps):
if(len(mps)<2 and mps[0].numel()==1):
return mps[0]
shape = [mps[0].shape[1]]
tensor = mps[0].reshape(mps[0].shape[1],mps[0].shape[2])
for i in range(1,len(mps)):
shape = shape+[mps[i].shape[1]]
a = mps[i]
tensor = np.einsum("ij,jkl->ikl",tensor,a).reshape(tensor.shape[0]*a.shape[1],a.shape[2])
return tensor.reshape(shape)
def move2tail(self,idx):
"""
move idx to the end of mps
This must be careful that in this function, neighbors are not arranged.
"""
error = 0
if(idx<0):
print("move2tail(): idx should be larger than 0")
sys.exit(0)
if(idx == len(self.mps)-1):
self.cano_to(-1)
return error
for i in range(idx,len(self.mps)-1):
error = error + self.swap(i,i+1)
self.cano_to(-1)
return error
def move(self,a,b):
"""
move the tensor from index a to index b by swapping consecutive tensors
"""
error = 0
if(a==b):
return error
if(a<0 or b<0):
print("move2tail(): idx should be larger than 0")
sys.exit(0)
if(b>a):
b = b
for i in range(a,b):
error = error + self.swap(i,i+1)
else:
b = b
for i in range(a,b,-1):
error = error + self.swap(i,i-1)
return error
def cano_to(self,idx):
"""
move canonical position to i
"""
if(idx == -1):
idx = len(self.mps)-1
if(self.cano == idx): # there is nothing to do
return
if(self.cano < idx):
for i in range(self.cano,idx):
dl = self.mps[i].shape[0]
d = self.mps[i].shape[1]
#Q,R = torch.qr(self.mps[i].reshape(dl * d,-1))
#U,s,V = torch.svd(self.mps[i].reshape(dl * d,-1))
U,s,V = svd(self.mps[i].reshape(dl * d,-1))
#Q=U
#R=torch.diag(s)@V.t()
seff = s[s>self.cutoff]
myd = seff.shape[0]
if(myd==0):
myd = U.shape[1]
else:
s = seff
Q=U[:,:myd]
R=np.diag(s)@(V[:,:myd]).T
self.mps[i] = Q.reshape(dl,d,-1)
self.mps[i+1] = np.einsum("ij,jab->iab",R,self.mps[i+1])
self.cano = i+1
else:
for i in range(self.cano,idx,-1):
dr = self.mps[i].shape[2]
d = self.mps[i].shape[1]
#Q,R = torch.qr(self.mps[i].reshape(-1,d*dr).t())
#U,s,V = torch.svd(self.mps[i].reshape(-1,d*dr).t())
U,s,V = svd(self.mps[i].reshape(-1,d*dr).T)
#Q=U
#R=torch.diag(s)@V.t()
seff = s[s>self.cutoff]
myd = seff.shape[0]
if(myd==0):
myd = U.shape[1]
else:
s = seff
Q=U[:,:myd]
R=np.diag(s)@(V[:,:myd].T)
self.mps[i] = Q.T.reshape(-1,d,dr)
self.mps[i-1] = np.einsum("abc,ci->abi",self.mps[i-1],R.T)
self.cano = i-1
return 0
def left_canonical(self):
self.cano = 0
self.cano_to(-1)
def compress(self):
"""
Compress the whole mps.
First, do left canonicalization to move self.cano to -1.
Second, do two-site merging-splitting, for moving self.cano back to 0.
"""
error = 0
if len(self.mps) == 0:
return error
self.left_canonical() # now self.cano is at the bottom (right)
for j in range( len(self.mps)-1,0,-1):
i = j-1
tl = self.mps[i]
tr = self.mps[j]
d0 = tl.shape[0]
d1 = tl.shape[1]
d2 = tr.shape[1]
d3 = tr.shape[2] # notice the difference to self.swap()
mat = np.einsum("ijk,kab->ijab",tl,tr).reshape(d0*d1,d2*d3) # notice the difference to self. swap()
[U,s,V] = svd(mat)
s_eff = s[s>self.cutoff]
myd = min(len(s_eff),self.chi)
if(myd == 0):
print("Warning in swap(), probably a zero matrix is encountered !!! myd=",myd)
sys.exit(-8)
s_eff=s_eff[:myd]
error = error + s[myd:].sum()
U=U[:,:myd]
V=V[:,:myd]
s=np.diag(s_eff)
U = U@s
self.mps[i] = U.reshape(d0,d1,myd)
self.mps[j] = V.T.reshape(myd,d2,d3)
self.cano = 0
def compress_opt(self):
"""
Compress the whole mps.
First, do left canonicalization to move self.cano to -1.
Second, do two-site merging-splitting, for moving self.cano back to 0.
Do qr before SVD
"""
error = 0
if len(self.mps) == 0:
return error
self.left_canonical() # now self.cano is at the bottom (right)
for j in range( len(self.mps)-1,0,-1):
i = j-1
tl = self.mps[i]
tr = self.mps[j]
d0 = tl.shape[0]
d1 = tl.shape[1]
d2 = tr.shape[1]
d3 = tr.shape[2] # notice the difference to self.swap()
dd = tl.shape[2]
assert(dd == tr.shape[0])
# mat = torch.einsum("ijk,kab->ijab",tl,tr).reshape(d0*d1,d2*d3) # notice the difference to self. swap()
matl = tl.reshape(d0*d1,dd)
matr = tr.reshape(dd,d2*d3)
# flag=False
#if(matl.shape[0]*matr.shape[1] > dd*dd):
# if(1==1):
# flag=True
# Ql,Rl = np.linalg.qr(matl)
# Qr,Rr = np.linalg.qr(matr.T)
# mat = [email protected]
# else:
# mat = matl@matr
flag_left = False
flag_right = False
if(matl.shape[0] > matl.shape[1]):
flag_left = True
Ql,Rl = np.linalg.qr(matl)
else:
Rl = matl
if(matr.shape[0] < matr.shape[1]):
flag_right = True
Qr,Rr = np.linalg.qr(matr.T)
else:
Rr = matr.T
mat = [email protected]
[U,s,V] = svd(mat)
s_eff = s[s>self.cutoff]
if(len(s_eff) == 0):
s_eff = s[:1]
myd = min(len(s_eff),self.chi)
if(myd == 0):
print("Warning in swap(), probably a zero matrix is encountered !!! myd=",myd)
sys.exit(-8)
s_eff=s_eff[:myd]
error = error + s[myd:].sum()
U=U[:,:myd]
V=V[:,:myd]
s=np.diag(s_eff)
U = U@s
# if flag:
# U = Ql @ U
# V = Qr @ V
if flag_left:
U = Ql @ U
if flag_right:
V = Qr @ V
self.mps[i] = U.reshape(d0,d1,myd)
self.mps[j] = V.T.reshape(myd,d2,d3)
# print("correct after swap:, error=",self.check_mps())
self.cano = 0
def swap(self,i,j):
"""
swap index i and index j in mps, i and j must be consecutive indices
Assuming that canonical form is maintained.
Default direction is i \to j, that is the canonical position will be j after swap
The canonicalization is maintained.
"""
error = 0
# sys.stdout.write(" swap %d %d cano=%d "%(i,j,self.cano));sys.stdout.flush()
if(j<0 or j>len(self.mps)):
return
# print("in swap(), move cano")
if(self.cano != i and self.cano != j):
self.cano_to( i if abs(self.cano-i)<abs(self.cano-j) else j)
if(abs(i-j) != 1):
print("swap(): i and j must be consecutive indices, there must be something wrong")
sys.exit(3)
if(i<j):
tl = self.mps[i]
tr = self.mps[j]
else:
tl = self.mps[j]
tr = self.mps[i]
d0 = tl.shape[0]
d1 = tr.shape[1]
d2 = tl.shape[1]
d3 = tr.shape[2]
mat = np.einsum("ijk,kab->iajb",tl,tr).reshape(d0*d1,d2*d3) # swaped
if( self.swapopt and ((mat.shape[0] > 7000 and mat.shape[1] > 7000) or (mat.shape[0] > 20000 or mat.shape[1] > 20000)) ):
[U,s,V] = rsvd(mat,self.chi,10,10)
else:
[U,s,V] = svd(mat)
s_eff = s[s>self.cutoff]
if(len(s_eff) == 0):
s_eff = s[:1]
myd = min(len(s_eff),self.chi)
if(myd == 0):
print("Warning in swap(), probably a zero matrix is encountered !!! myd=",myd)
sys.exit(-7)
s_eff=s_eff[:myd]
error = error + s[myd:].sum()
U=U[:,:myd]
V=V[:,:myd]
s=np.diag(s_eff)
if(i<j):#going right
self.mps[i] = U.reshape(d0,d1,myd)
self.mps[j] = V.reshape(myd,d2,d3)
else:# going left
U = U@s
self.mps[j] = U.reshape(d0,d1,myd)
self.mps[i] = V.T.reshape(myd,d2,d3)
self.cano = j
return error
def shape(self,idx=math.inf):
if(idx == math.inf):
if(len(self.mps)==1):
return [1]
else:
return [i.shape[1] for i in self.mps]
else:
return self.mps[idx].shape[1]
def merge(self,j,cross=False):
"""
merge two identitical neighbors of i
"""
error = 0
idxj = np.argwhere(self.neighbor == j)
shape = self.shape()
if(idxj.size != 2):
print("there is nothing to do in self.merge() !")
sys.exit(4)
return
idx1 = idxj[0][0]
idx2 = idxj[1][0]
self.neighbor = np.delete(self.neighbor,idx2)
if(not cross):
error = self.move(idx2,idx1+1)
else:
error = self.move(idx2,idx1)
self.cano_to(idx1)
self.mps[idx1] = np.einsum("ijk,kab->ijab",self.mps[idx1],self.mps[idx1+1]).reshape(self.mps[idx1].shape[0],-1,self.mps[idx1+1].shape[2])
self.mps.pop(idx1+1)
self.cano_to(idx1)
return error
def logdim(self,idx=math.inf):
""" return log of number of elements of the raw tensor"""
try:
if(len(self.mps)==0):
return 0
except:
return 0
if(idx != math.inf):
return math.log2(self.mps[idx].shape[1])
else:
return np.log2(np.array([i.shape[1] for i in self.mps]).astype(np.float64)).sum().item() #**************************
def order(self):
""" return order of the tensor """
try:
if len(self.mps)==0:
return 0
except:
return 0
return len(self.mps)
def move2tail_neighbor(self,idx):
self.neighbor = list(self.neighbor[:idx]) + list(self.neighbor[idx+1:])+[self.neighbor[idx]]
def move2head(self,idx):
error = self.move(idx,0) # notice that j's neighbors are not modified !
self.cano_to(0)
return error
def eat(self,nodej,idx, idxi):
"""
Eat node j, that is contract idx of self to idxi of nodej, appending all neighbors of j to itself
TODO:
1. Moving to end and Moving to begin could be heavy if the position is not good enough. Considering reverse the whole chain before moving.
"""
error = 0
if( len(self.mps) == 1): # the node i is a leaf, according to the regulation introduced in contraction(), node j must be no larger than node i, so j must be a leaf as well
# print("two leaves")
assert self.mps[0].shape[0] == 1 and self.mps[0].shape[2] == 1 and len(nodej.mps) == 1 and nodej.mps[0].shape[0] == 1 and nodej.mps[0].shape[2] == 1
result = self.mps[0].reshape(1,self.mps[0].shape[1]) @ nodej.mps[0].reshape( nodej.mps[0].shape[1],1)
# if(norm<0):
# print("the result is smaller than 0",norm)
# return 0,norm.item()
# print("dot of two vectors:",result,np.linalg.norm(result),np.linalg.norm(result)**2)
# print("dot of two vectors:",result,np.abs(result),np.abs(result)**2)
lognorm = math.log(np.abs(result))
self.mps = []
return lognorm,0,result/np.abs(result)
# idx_i_in_j=np.argwhere(nodej.neighbor == self.index)[0][0]
# for l in range(len(nodej.neighbor)):
# if l != idx_i_in_j:
#
error = error + self.move2tail(idx)
mati = self.mps[-1].reshape(self.mps[-1].shape[:-1])
if( len(nodej.mps) == 1): # node i is not a leaf, j is a leaf
assert nodej.mps[0].shape[0] == 1 and nodej.mps[0].shape[2] == 1
assert(self.cano == len(self.mps)-1)
tensorj = nodej.mps[0]
matj = tensorj.reshape(tensorj.shape[1],1)
mat = mati @ matj
new_tensor = np.einsum("ijk,ka->ija",self.mps[-2],mat)
if(self.norm_method == 1):
norm = np.linalg.norm(new_tensor)
elif self.norm_method == 2:
norm = np.abs(new_tensor).max()
elif self.norm_method == 0:
norm = np.array(1)
else:
print("in eat(), norm_method not understood")
sys.exit(-8)
#norm = np.linalg.norm(new_tensor)
self.mps[-2] = new_tensor / norm
self.cano = self.cano - 1
self.mps.pop(-1)
return math.log(norm),error,1
error = error + nodej.move2head(idxi)
matj = nodej.mps[0].reshape(nodej.mps[0].shape[1:])
mat = mati @ matj
if(len(self.mps) > 1):
self.mps[-2] = np.einsum("ijk,ka->ija",self.mps[-2],mat)
self.mps.pop(-1)
self.cano = len(self.mps)-1
else:
print("Warning: this should never happen in eat()")
sys.exit(-6)
for a in range(1,len(nodej.mps)):
self.mps.append(nodej.mps[a])
self.cano_to(-1)
if(self.norm_method == 1):
norm = np.linalg.norm(self.mps[self.cano])
elif self.norm_method == 2:
norm = np.abs(self.mps[self.cano]).max()
elif self.norm_method == 0:
norm = np.array(1).astype(self.dtype)
else:
print("in eat(), norm_method not understood")
sys.exit(-8)
self.mps[self.cano] = self.mps[self.cano] / norm
if(norm <= self.cutoff):
return 0,error,1
return np.log(norm),error,1
def reverse(self):
if(len(self.mps) == 1):
return
# print("reversing")
# print([i.shape for i in self.mps])
self.neighbor = self.neighbor[::-1]
self.mps = [i.transpose([2,1,0]) for i in self.mps[::-1]]
self.cano = len(self.mps) - 1-self.cano
# print([i.shape for i in self.mps])
# print("done")
def add_neighbor(self, n, pos=-1):
if pos != -1:
self.neighbor = np.insert(self.neighbor, pos, n)
else:
self.neighbor = np.append(self.neighbor, n)
def delete_neighbor(self, n):
idx = np.argwhere(self.neighbor == n)
self.neighbor = np.delete(self.neighbor, idx)
return idx[0][0]
def lognorm(self):
if(len(self.mps)==0):
return 0,1
if(len(self.mps)==1 and self.mps[0].shape[1] == 1):
z=self.mps[0].squeeze()
# print("this should be the last tensor",z)
return np.log(np.abs(z)),np.sign(z)
print("mps.lognorm(): Computing norm of a MPS is not a good idea in contraction, check it!!!")
sys.exit(-9)
def clear(self):
self.mps = []
self.neighbor = []