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soft_dtw_cuda.py
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soft_dtw_cuda.py
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# MIT License
#
# Copyright (c) 2020 Mehran Maghoumi
#
# Permission is hereby granted, free of charge, to any person obtaining a copy
# of this software and associated documentation files (the "Software"), to deal
# in the Software without restriction, including without limitation the rights
# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
# copies of the Software, and to permit persons to whom the Software is
# furnished to do so, subject to the following conditions:
#
# The above copyright notice and this permission notice shall be included in all
# copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
# SOFTWARE.
# ----------------------------------------------------------------------------------------------------------------------
import numpy as np
import torch
import torch.cuda
from numba import jit, prange
from torch.autograd import Function
from numba import cuda
import math
# ----------------------------------------------------------------------------------------------------------------------
@cuda.jit
def compute_softdtw_cuda(D, gamma, bandwidth, max_i, max_j, n_passes, R):
"""
:param seq_len: The length of the sequence (both inputs are assumed to be of the same size)
:param n_passes: 2 * seq_len - 1 (The number of anti-diagonals)
"""
# Each block processes one pair of examples
b = cuda.blockIdx.x
# We have as many threads as seq_len, because the most number of threads we need
# is equal to the number of elements on the largest anti-diagonal
tid = cuda.threadIdx.x
# Compute I, J, the indices from [0, seq_len)
# The row index is always the same as tid
I = tid
inv_gamma = 1.0 / gamma
# Go over each anti-diagonal. Only process threads that fall on the current on the anti-diagonal
for p in range(n_passes):
# The index is actually 'p - tid' but need to force it in-bounds
J = max(0, min(p - tid, max_j - 1))
# For simplicity, we define i, j which start from 1 (offset from I, J)
i = I + 1
j = J + 1
# Only compute if element[i, j] is on the current anti-diagonal, and also is within bounds
if I + J == p and (I < max_i and J < max_j):
# Don't compute if outside bandwidth
if not (abs(i - j) > bandwidth > 0):
r0 = -R[b, i - 1, j - 1] * inv_gamma
r1 = -R[b, i - 1, j] * inv_gamma
r2 = -R[b, i, j - 1] * inv_gamma
rmax = max(max(r0, r1), r2)
rsum = math.exp(r0 - rmax) + math.exp(r1 - rmax) + math.exp(r2 - rmax)
softmin = -gamma * (math.log(rsum) + rmax)
R[b, i, j] = D[b, i - 1, j - 1] + softmin
# Wait for other threads in this block
cuda.syncthreads()
# ----------------------------------------------------------------------------------------------------------------------
@cuda.jit
def compute_softdtw_backward_cuda(D, R, inv_gamma, bandwidth, max_i, max_j, n_passes, E):
k = cuda.blockIdx.x
tid = cuda.threadIdx.x
# Indexing logic is the same as above, however, the anti-diagonal needs to
# progress backwards
I = tid
for p in range(n_passes):
# Reverse the order to make the loop go backward
rev_p = n_passes - p - 1
# convert tid to I, J, then i, j
J = max(0, min(rev_p - tid, max_j - 1))
i = I + 1
j = J + 1
# Only compute if element[i, j] is on the current anti-diagonal, and also is within bounds
if I + J == rev_p and (I < max_i and J < max_j):
if math.isinf(R[k, i, j]):
R[k, i, j] = -math.inf
# Don't compute if outside bandwidth
if not (abs(i - j) > bandwidth > 0):
a = math.exp((R[k, i + 1, j] - R[k, i, j] - D[k, i + 1, j]) * inv_gamma)
b = math.exp((R[k, i, j + 1] - R[k, i, j] - D[k, i, j + 1]) * inv_gamma)
c = math.exp((R[k, i + 1, j + 1] - R[k, i, j] - D[k, i + 1, j + 1]) * inv_gamma)
E[k, i, j] = E[k, i + 1, j] * a + E[k, i, j + 1] * b + E[k, i + 1, j + 1] * c
# Wait for other threads in this block
cuda.syncthreads()
# ----------------------------------------------------------------------------------------------------------------------
class _SoftDTWCUDA(Function):
"""
CUDA implementation is inspired by the diagonal one proposed in https://ieeexplore.ieee.org/document/8400444:
"Developing a pattern discovery method in time series data and its GPU acceleration"
"""
@staticmethod
def forward(ctx, D, gamma, bandwidth):
dev = D.device
dtype = D.dtype
gamma = torch.cuda.FloatTensor([gamma])
bandwidth = torch.cuda.FloatTensor([bandwidth])
B = D.shape[0]
N = D.shape[1]
M = D.shape[2]
threads_per_block = max(N, M)
n_passes = 2 * threads_per_block - 1
# Prepare the output array
R = torch.ones((B, N + 2, M + 2), device=dev, dtype=dtype) * math.inf
R[:, 0, 0] = 0
# Run the CUDA kernel.
# Set CUDA's grid size to be equal to the batch size (every CUDA block processes one sample pair)
# Set the CUDA block size to be equal to the length of the longer sequence (equal to the size of the largest diagonal)
compute_softdtw_cuda[B, threads_per_block](cuda.as_cuda_array(D.detach()),
gamma.item(), bandwidth.item(), N, M, n_passes,
cuda.as_cuda_array(R))
ctx.save_for_backward(D, R.clone(), gamma, bandwidth)
return R[:, -2, -2]
@staticmethod
def backward(ctx, grad_output):
dev = grad_output.device
dtype = grad_output.dtype
D, R, gamma, bandwidth = ctx.saved_tensors
B = D.shape[0]
N = D.shape[1]
M = D.shape[2]
threads_per_block = max(N, M)
n_passes = 2 * threads_per_block - 1
D_ = torch.zeros((B, N + 2, M + 2), dtype=dtype, device=dev)
D_[:, 1:N + 1, 1:M + 1] = D
R[:, :, -1] = -math.inf
R[:, -1, :] = -math.inf
R[:, -1, -1] = R[:, -2, -2]
E = torch.zeros((B, N + 2, M + 2), dtype=dtype, device=dev)
E[:, -1, -1] = 1
# Grid and block sizes are set same as done above for the forward() call
compute_softdtw_backward_cuda[B, threads_per_block](cuda.as_cuda_array(D_),
cuda.as_cuda_array(R),
1.0 / gamma.item(), bandwidth.item(), N, M, n_passes,
cuda.as_cuda_array(E))
E = E[:, 1:N + 1, 1:M + 1]
return grad_output.view(-1, 1, 1).expand_as(E) * E, None, None
# ----------------------------------------------------------------------------------------------------------------------
#
# The following is the CPU implementation based on https://github.com/Sleepwalking/pytorch-softdtw
# Credit goes to Kanru Hua.
# I've added support for batching and pruning.
#
# ----------------------------------------------------------------------------------------------------------------------
@jit(nopython=True, parallel=True)
def compute_softdtw(D, gamma, bandwidth):
B = D.shape[0]
N = D.shape[1]
M = D.shape[2]
R = np.ones((B, N + 2, M + 2)) * np.inf
R[:, 0, 0] = 0
for b in prange(B):
for j in range(1, M + 1):
for i in range(1, N + 1):
# Check the pruning condition
if 0 < bandwidth < np.abs(i - j):
continue
r0 = -R[b, i - 1, j - 1] / gamma
r1 = -R[b, i - 1, j] / gamma
r2 = -R[b, i, j - 1] / gamma
rmax = max(max(r0, r1), r2)
rsum = np.exp(r0 - rmax) + np.exp(r1 - rmax) + np.exp(r2 - rmax)
softmin = - gamma * (np.log(rsum) + rmax)
R[b, i, j] = D[b, i - 1, j - 1] + softmin
return R
# ----------------------------------------------------------------------------------------------------------------------
@jit(nopython=True, parallel=True)
def compute_softdtw_backward(D_, R, gamma, bandwidth):
B = D_.shape[0]
N = D_.shape[1]
M = D_.shape[2]
D = np.zeros((B, N + 2, M + 2))
E = np.zeros((B, N + 2, M + 2))
D[:, 1:N + 1, 1:M + 1] = D_
E[:, -1, -1] = 1
R[:, :, -1] = -np.inf
R[:, -1, :] = -np.inf
R[:, -1, -1] = R[:, -2, -2]
for k in prange(B):
for j in range(M, 0, -1):
for i in range(N, 0, -1):
if np.isinf(R[k, i, j]):
R[k, i, j] = -np.inf
# Check the pruning condition
if 0 < bandwidth < np.abs(i - j):
continue
a0 = (R[k, i + 1, j] - R[k, i, j] - D[k, i + 1, j]) / gamma
b0 = (R[k, i, j + 1] - R[k, i, j] - D[k, i, j + 1]) / gamma
c0 = (R[k, i + 1, j + 1] - R[k, i, j] - D[k, i + 1, j + 1]) / gamma
a = np.exp(a0)
b = np.exp(b0)
c = np.exp(c0)
E[k, i, j] = E[k, i + 1, j] * a + E[k, i, j + 1] * b + E[k, i + 1, j + 1] * c
return E[:, 1:N + 1, 1:M + 1]
# ----------------------------------------------------------------------------------------------------------------------
class _SoftDTW(Function):
"""
CPU implementation based on https://github.com/Sleepwalking/pytorch-softdtw
"""
@staticmethod
def forward(ctx, D, gamma, bandwidth):
dev = D.device
dtype = D.dtype
gamma = torch.Tensor([gamma]).to(dev).type(dtype) # dtype fixed
bandwidth = torch.Tensor([bandwidth]).to(dev).type(dtype)
D_ = D.detach().cpu().numpy()
g_ = gamma.item()
b_ = bandwidth.item()
R = torch.Tensor(compute_softdtw(D_, g_, b_)).to(dev).type(dtype)
ctx.save_for_backward(D, R, gamma, bandwidth)
return R[:, -2, -2]
@staticmethod
def backward(ctx, grad_output):
dev = grad_output.device
dtype = grad_output.dtype
D, R, gamma, bandwidth = ctx.saved_tensors
D_ = D.detach().cpu().numpy()
R_ = R.detach().cpu().numpy()
g_ = gamma.item()
b_ = bandwidth.item()
E = torch.Tensor(compute_softdtw_backward(D_, R_, g_, b_)).to(dev).type(dtype)
return grad_output.view(-1, 1, 1).expand_as(E) * E, None, None
# ----------------------------------------------------------------------------------------------------------------------
class SoftDTW(torch.nn.Module):
"""
The soft DTW implementation that optionally supports CUDA
"""
def __init__(self, use_cuda, gamma=1.0, normalize=False, bandwidth=None, dist_func=None):
"""
Initializes a new instance using the supplied parameters
:param use_cuda: Flag indicating whether the CUDA implementation should be used
:param gamma: sDTW's gamma parameter
:param normalize: Flag indicating whether to perform normalization
(as discussed in https://github.com/mblondel/soft-dtw/issues/10#issuecomment-383564790)
:param bandwidth: Sakoe-Chiba bandwidth for pruning. Passing 'None' will disable pruning.
:param dist_func: Optional point-wise distance function to use. If 'None', then a default Euclidean distance function will be used.
"""
super(SoftDTW, self).__init__()
self.normalize = normalize
self.gamma = gamma
self.bandwidth = 0 if bandwidth is None else float(bandwidth)
self.use_cuda = use_cuda
# Set the distance function
if dist_func is not None:
self.dist_func = dist_func
else:
self.dist_func = SoftDTW._euclidean_dist_func
def _get_func_dtw(self, x, y):
"""
Checks the inputs and selects the proper implementation to use.
"""
bx, lx, dx = x.shape
by, ly, dy = y.shape
# Make sure the dimensions match
assert bx == by # Equal batch sizes
assert dx == dy # Equal feature dimensions
use_cuda = self.use_cuda
if use_cuda and (lx > 1024 or ly > 1024): # We should be able to spawn enough threads in CUDA
print("SoftDTW: Cannot use CUDA because the sequence length > 1024 (the maximum block size supported by CUDA)")
use_cuda = False
# Finally, return the correct function
return _SoftDTWCUDA.apply if use_cuda else _SoftDTW.apply
@staticmethod
def _euclidean_dist_func(x, y):
"""
Calculates the Euclidean distance between each element in x and y per timestep
"""
n = x.size(1)
m = y.size(1)
d = x.size(2)
x = x.unsqueeze(2).expand(-1, n, m, d)
y = y.unsqueeze(1).expand(-1, n, m, d)
return torch.pow(x - y, 2).sum(3)
def forward(self, X, Y):
"""
Compute the soft-DTW value between X and Y
:param X: One batch of examples, batch_size x seq_len x dims
:param Y: The other batch of examples, batch_size x seq_len x dims
:return: The computed results
"""
# Check the inputs and get the correct implementation
func_dtw = self._get_func_dtw(X, Y)
if self.normalize:
# Stack everything up and run
x = torch.cat([X, X, Y])
y = torch.cat([Y, X, Y])
D = self.dist_func(x, y)
out = func_dtw(D, self.gamma, self.bandwidth)
out_xy, out_xx, out_yy = torch.split(out, X.shape[0])
return out_xy - 1 / 2 * (out_xx + out_yy)
else:
D_xy = self.dist_func(X, Y)
return func_dtw(D_xy, self.gamma, self.bandwidth)
# ----------------------------------------------------------------------------------------------------------------------
def timed_run(a, b, sdtw):
"""
Runs a and b through sdtw, and times the forward and backward passes.
Assumes that a requires gradients.
:return: timing, forward result, backward result
"""
from timeit import default_timer as timer
# Forward pass
start = timer()
forward = sdtw(a, b)
end = timer()
t = end - start
grad_outputs = torch.ones_like(forward)
# Backward
start = timer()
grads = torch.autograd.grad(forward, a, grad_outputs=grad_outputs)[0]
end = timer()
# Total time
t += end - start
return t, forward, grads
# ----------------------------------------------------------------------------------------------------------------------
def profile(batch_size, seq_len_a, seq_len_b, dims, tol_backward):
sdtw = SoftDTW(False, gamma=1.0, normalize=False)
sdtw_cuda = SoftDTW(True, gamma=1.0, normalize=False)
n_iters = 6
print("Profiling forward() + backward() times for batch_size={}, seq_len_a={}, seq_len_b={}, dims={}...".format(batch_size, seq_len_a, seq_len_b, dims))
times_cpu = []
times_gpu = []
for i in range(n_iters):
a_cpu = torch.rand((batch_size, seq_len_a, dims), requires_grad=True)
b_cpu = torch.rand((batch_size, seq_len_b, dims))
a_gpu = a_cpu.cuda()
b_gpu = b_cpu.cuda()
# GPU
t_gpu, forward_gpu, backward_gpu = timed_run(a_gpu, b_gpu, sdtw_cuda)
# CPU
t_cpu, forward_cpu, backward_cpu = timed_run(a_cpu, b_cpu, sdtw)
# Verify the results
assert torch.allclose(forward_cpu, forward_gpu.cpu())
assert torch.allclose(backward_cpu, backward_gpu.cpu(), atol=tol_backward)
if i > 0: # Ignore the first time we run, in case this is a cold start (because timings are off at a cold start of the script)
times_cpu += [t_cpu]
times_gpu += [t_gpu]
# Average and log
avg_cpu = np.mean(times_cpu)
avg_gpu = np.mean(times_gpu)
print(" CPU: ", avg_cpu)
print(" GPU: ", avg_gpu)
print(" Speedup: ", avg_cpu / avg_gpu)
print()
# ----------------------------------------------------------------------------------------------------------------------
if __name__ == "__main__":
from timeit import default_timer as timer
torch.manual_seed(1234)
profile(128, 17, 15, 2, tol_backward=1e-6)
profile(512, 64, 64, 2, tol_backward=1e-4)
profile(512, 256, 256, 2, tol_backward=1e-3)