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import math
import torch
import torch.nn.functional as F
"""
An implementation of the parallel scan operation in PyTorch (Blelloch version).
Please see docs/pscan.ipynb for a detailed explanation of what happens here.
"""
def npo2(len):
"""
Returns the next power of 2 above len
"""
return 2 ** math.ceil(math.log2(len))
def pad_npo2(X):
"""
Pads input length dim to the next power of 2
Args:
X : (B, L, D, N)
Returns:
Y : (B, npo2(L), D, N)
"""
len_npo2 = npo2(X.size(1))
pad_tuple = (0, 0, 0, 0, 0, len_npo2 - X.size(1))
return F.pad(X, pad_tuple, "constant", 0)
class PScan(torch.autograd.Function):
@staticmethod
def pscan(A, X):
# A : (B, D, L, N)
# X : (B, D, L, N)
# modifies X in place by doing a parallel scan.
# more formally, X will be populated by these values :
# H[t] = A[t] * H[t-1] + X[t] with H[0] = 0
# which are computed in parallel (2*log2(T) sequential steps (ideally), instead of T sequential steps)
# only supports L that is a power of two (mainly for a clearer code)
B, D, L, _ = A.size()
num_steps = int(math.log2(L))
# up sweep (last 2 steps unfolded)
Aa = A
Xa = X
for _ in range(num_steps-2):
T = Xa.size(2)
Aa = Aa.view(B, D, T//2, 2, -1)
Xa = Xa.view(B, D, T//2, 2, -1)
Xa[:, :, :, 1].add_(Aa[:, :, :, 1].mul(Xa[:, :, :, 0]))
Aa[:, :, :, 1].mul_(Aa[:, :, :, 0])
Aa = Aa[:, :, :, 1]
Xa = Xa[:, :, :, 1]
# we have only 4, 2 or 1 nodes left
if Xa.size(2) == 4:
Xa[:, :, 1].add_(Aa[:, :, 1].mul(Xa[:, :, 0]))
Aa[:, :, 1].mul_(Aa[:, :, 0])
Xa[:, :, 3].add_(Aa[:, :, 3].mul(Xa[:, :, 2] + Aa[:, :, 2].mul(Xa[:, :, 1])))
elif Xa.size(2) == 2:
Xa[:, :, 1].add_(Aa[:, :, 1].mul(Xa[:, :, 0]))
return
else:
return
# down sweep (first 2 steps unfolded)
Aa = A[:, :, 2**(num_steps-2)-1:L:2**(num_steps-2)]
Xa = X[:, :, 2**(num_steps-2)-1:L:2**(num_steps-2)]
Xa[:, :, 2].add_(Aa[:, :, 2].mul(Xa[:, :, 1]))
Aa[:, :, 2].mul_(Aa[:, :, 1])
for k in range(num_steps-3, -1, -1):
Aa = A[:, :, 2**k-1:L:2**k]
Xa = X[:, :, 2**k-1:L:2**k]
T = Xa.size(2)
Aa = Aa.view(B, D, T//2, 2, -1)
Xa = Xa.view(B, D, T//2, 2, -1)
Xa[:, :, 1:, 0].add_(Aa[:, :, 1:, 0].mul(Xa[:, :, :-1, 1]))
Aa[:, :, 1:, 0].mul_(Aa[:, :, :-1, 1])
@staticmethod
def pscan_rev(A, X):
# A : (B, D, L, N)
# X : (B, D, L, N)
# the same function as above, but in reverse
# (if you flip the input, call pscan, then flip the output, you get what this function outputs)
# it is used in the backward pass
# only supports L that is a power of two (mainly for a clearer code)
B, D, L, _ = A.size()
num_steps = int(math.log2(L))
# up sweep (last 2 steps unfolded)
Aa = A
Xa = X
for _ in range(num_steps-2):
T = Xa.size(2)
Aa = Aa.view(B, D, T//2, 2, -1)
Xa = Xa.view(B, D, T//2, 2, -1)
Xa[:, :, :, 0].add_(Aa[:, :, :, 0].mul(Xa[:, :, :, 1]))
Aa[:, :, :, 0].mul_(Aa[:, :, :, 1])
Aa = Aa[:, :, :, 0]
Xa = Xa[:, :, :, 0]
# we have only 4, 2 or 1 nodes left
if Xa.size(2) == 4:
Xa[:, :, 2].add_(Aa[:, :, 2].mul(Xa[:, :, 3]))
Aa[:, :, 2].mul_(Aa[:, :, 3])
Xa[:, :, 0].add_(Aa[:, :, 0].mul(Xa[:, :, 1].add(Aa[:, :, 1].mul(Xa[:, :, 2]))))
elif Xa.size(2) == 2:
Xa[:, :, 0].add_(Aa[:, :, 0].mul(Xa[:, :, 1]))
return
else:
return
# down sweep (first 2 steps unfolded)
Aa = A[:, :, 0:L:2**(num_steps-2)]
Xa = X[:, :, 0:L:2**(num_steps-2)]
Xa[:, :, 1].add_(Aa[:, :, 1].mul(Xa[:, :, 2]))
Aa[:, :, 1].mul_(Aa[:, :, 2])
for k in range(num_steps-3, -1, -1):
Aa = A[:, :, 0:L:2**k]
Xa = X[:, :, 0:L:2**k]
T = Xa.size(2)
Aa = Aa.view(B, D, T//2, 2, -1)
Xa = Xa.view(B, D, T//2, 2, -1)
Xa[:, :, :-1, 1].add_(Aa[:, :, :-1, 1].mul(Xa[:, :, 1:, 0]))
Aa[:, :, :-1, 1].mul_(Aa[:, :, 1:, 0])
@staticmethod
def forward(ctx, A_in, X_in):
"""
Applies the parallel scan operation, as defined above. Returns a new tensor.
If you can, privilege sequence lengths that are powers of two.
Args:
A_in : (B, L, D, N)
X_in : (B, L, D, N)
Returns:
H : (B, L, D, N)
"""
L = X_in.size(1)
# cloning is requiered because of the in-place ops
if L == npo2(L):
A = A_in.clone()
X = X_in.clone()
else:
# pad tensors (and clone btw)
A = pad_npo2(A_in) # (B, npo2(L), D, N)
X = pad_npo2(X_in) # (B, npo2(L), D, N)
# prepare tensors
A = A.transpose(2, 1) # (B, D, npo2(L), N)
X = X.transpose(2, 1) # (B, D, npo2(L), N)
# parallel scan (modifies X in-place)
PScan.pscan(A, X)
ctx.save_for_backward(A_in, X)
# slice [:, :L] (cut if there was padding)
return X.transpose(2, 1)[:, :L]
@staticmethod
def backward(ctx, grad_output_in):
"""
Flows the gradient from the output to the input. Returns two new tensors.
Args:
ctx : A_in : (B, L, D, N), X : (B, D, L, N)
grad_output_in : (B, L, D, N)
Returns:
gradA : (B, L, D, N), gradX : (B, L, D, N)
"""
A_in, X = ctx.saved_tensors
L = grad_output_in.size(1)
# cloning is requiered because of the in-place ops
if L == npo2(L):
grad_output = grad_output_in.clone()
# the next padding will clone A_in
else:
grad_output = pad_npo2(grad_output_in) # (B, npo2(L), D, N)
A_in = pad_npo2(A_in) # (B, npo2(L), D, N)
# prepare tensors
grad_output = grad_output.transpose(2, 1)
A_in = A_in.transpose(2, 1) # (B, D, npo2(L), N)
A = torch.nn.functional.pad(A_in[:, :, 1:], (0, 0, 0, 1)) # (B, D, npo2(L), N) shift 1 to the left (see hand derivation)
# reverse parallel scan (modifies grad_output in-place)
PScan.pscan_rev(A, grad_output)
Q = torch.zeros_like(X)
Q[:, :, 1:].add_(X[:, :, :-1] * grad_output[:, :, 1:])
return Q.transpose(2, 1)[:, :L], grad_output.transpose(2, 1)[:, :L]
pscan = PScan.apply