# How to get mini-batches in pytorch in a clean and efficient way?

I was trying to do a simple thing which was train a linear model with Stochastic Gradient Descent (SGD) using torch:

``````import numpy as np

import torch

import pdb

def get_batch2(X,Y,M,dtype):
X,Y = X.data.numpy(), Y.data.numpy()
N = len(Y)
valid_indices = np.array( range(N) )
batch_indices = np.random.choice(valid_indices,size=M,replace=False)
batch_xs = torch.FloatTensor(X[batch_indices,:]).type(dtype)
batch_ys = torch.FloatTensor(Y[batch_indices]).type(dtype)

def poly_kernel_matrix( x,D ):
N = len(x)
Kern = np.zeros( (N,D+1) )
for n in range(N):
for d in range(D+1):
Kern[n,d] = x[n]**d;
return Kern

## data params
N=5 # data set size
Degree=4 # number dimensions/features
D_sgd = Degree+1
##
x_true = np.linspace(0,1,N) # the real data points
y = np.sin(2*np.pi*x_true)
y.shape = (N,1)
## TORCH
dtype = torch.FloatTensor
# dtype = torch.cuda.FloatTensor # Uncomment this to run on GPU
X_mdl = poly_kernel_matrix( x_true,Degree )
## SGD mdl
w_init = torch.zeros(D_sgd,1).type(dtype)
M = 5 # mini-batch size
eta = 0.1 # step size
for i in range(500):
batch_xs, batch_ys = get_batch2(X_mdl,y,M,dtype)
# Forward pass: compute predicted y using operations on Variables
y_pred = batch_xs.mm(W)
# Compute and print loss using operations on Variables. Now loss is a Variable of shape (1,) and loss.data is a Tensor of shape (1,); loss.data[0] is a scalar value holding the loss.
loss = (1/N)*(y_pred - batch_ys).pow(2).sum()
# Use autograd to compute the backward pass. Now w will have gradients
loss.backward()
# Update weights using gradient descent; w1.data are Tensors,
# Manually zero the gradients after updating weights

#
c_sgd = W.data.numpy()
X_mdl = X_mdl.data.numpy()
y = y.data.numpy()
#
Xc_pinv = np.dot(X_mdl,c_sgd)
print('J(c_sgd) = ', (1/N)*(np.linalg.norm(y-Xc_pinv)**2) )
print('loss = ',loss.data[0])
``````

the code runs fine and all though my `get_batch2` method seems really dum/naive, its probably because I am new to pytorch but I have not found a good place where they discuss how to retrieve data batches. I went through their tutorials (http://pytorch.org/tutorials/beginner/pytorch_with_examples.html) and through the data set (http://pytorch.org/tutorials/beginner/data_loading_tutorial.html) with no luck. The tutorials all seem to assume that one already has the batch and batch-size at the beginning and then proceeds to train with that data without changing it (specifically look at http://pytorch.org/tutorials/beginner/pytorch_with_examples.html#pytorch-variables-and-autograd).

So my question is do I really need to turn my data back into numpy so that I can fetch some random sample of it and then turn it back to pytorch with Variable to be able to train in memory? Is there no way to get mini-batches with torch?

I looked at a few functions torch provides but with no luck:

``````#pdb.set_trace()
#valid_indices = torch.arange(0,N).numpy()
#valid_indices = np.array( range(N) )
#batch_indices = np.random.choice(valid_indices,size=M,replace=False)
#indices = torch.LongTensor(batch_indices)
#batch_xs, batch_ys = torch.index_select(X_mdl, 0, indices), torch.index_select(y, 0, indices)
#batch_xs,batch_ys = torch.index_select(X_mdl, 0, indices), torch.index_select(y, 0, indices)
``````

even though the code I provided works fine I am worried that its not an efficient implementation AND that if I were to use GPUs that there would be a considerable further slow down (because my guess it putting things in memory and then fetching them back to put them GPU like that is silly).

I implemented a new one based on the answer that suggested to use `torch.index_select()`:

``````def get_batch2(X,Y,M):
'''
get batch for pytorch model
'''
# TODO fix and make it nicer, there is pytorch forum question
#X,Y = X.data.numpy(), Y.data.numpy()
X,Y = X, Y
N = X.size()[0]
batch_indices = torch.LongTensor( np.random.randint(0,N+1,size=M) )
pdb.set_trace()
batch_xs = torch.index_select(X,0,batch_indices)
batch_ys = torch.index_select(Y,0,batch_indices)
``````

however, this seems to have issues because it does not work if `X,Y` are NOT variables...which is really odd. I added this to the pytorch forum: https://discuss.pytorch.org/t/how-to-get-mini-batches-in-pytorch-in-a-clean-and-efficient-way/10322

Right now what I am struggling with is making this work for gpu. My most current version:

``````def get_batch2(X,Y,M,dtype):
'''
get batch for pytorch model
'''
# TODO fix and make it nicer, there is pytorch forum question
#X,Y = X.data.numpy(), Y.data.numpy()
X,Y = X, Y
N = X.size()[0]
if dtype ==  torch.cuda.FloatTensor:
batch_indices = torch.cuda.LongTensor( np.random.randint(0,N,size=M) )# without replacement
else:
batch_indices = torch.LongTensor( np.random.randint(0,N,size=M) ).type(dtype)  # without replacement
pdb.set_trace()
batch_xs = torch.index_select(X,0,batch_indices)
batch_ys = torch.index_select(Y,0,batch_indices)
``````

the error:

``````RuntimeError: tried to construct a tensor from a int sequence, but found an item of type numpy.int64 at index (0)
``````

I don't get it, do I really have to do:

``````ints = [ random.randint(0,N) for i i range(M)]
``````

to get the integers?

It would also be ideal if the data could be a variable. It seems that it `torch.index_select` does not work for `Variable` type data.

this list of integers thing still doesn't work:

``````TypeError: torch.addmm received an invalid combination of arguments - got (int, torch.cuda.FloatTensor, int, torch.cuda.FloatTensor, torch.FloatTensor, out=torch.cuda.FloatTensor), but expected one of:
* (torch.cuda.FloatTensor source, torch.cuda.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (torch.cuda.FloatTensor source, torch.cuda.sparse.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (float beta, torch.cuda.FloatTensor source, torch.cuda.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (torch.cuda.FloatTensor source, float alpha, torch.cuda.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (float beta, torch.cuda.FloatTensor source, torch.cuda.sparse.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (torch.cuda.FloatTensor source, float alpha, torch.cuda.sparse.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
* (float beta, torch.cuda.FloatTensor source, float alpha, torch.cuda.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
didn't match because some of the arguments have invalid types: (int, torch.cuda.FloatTensor, int, torch.cuda.FloatTensor, torch.FloatTensor, out=torch.cuda.FloatTensor)
* (float beta, torch.cuda.FloatTensor source, float alpha, torch.cuda.sparse.FloatTensor mat1, torch.cuda.FloatTensor mat2, *, torch.cuda.FloatTensor out)
didn't match because some of the arguments have invalid types: (int, torch.cuda.FloatTensor, int, torch.cuda.FloatTensor, torch.FloatTensor, out=torch.cuda.FloatTensor)
``````
• on the pytorch forum: discuss.pytorch.org/t/… Commented Nov 23, 2017 at 22:40
• useful comment maybe: Make sure to call `index_select` with the same type of arguments, i.e. two tensors or two Variables. Wrap your `batch_indices` into a Variable or just use `X[batch_indices, :]`. Commented Nov 29, 2017 at 20:35
• also related: discuss.pytorch.org/t/… Commented Jan 23, 2018 at 1:51

If I'm understanding your code correctly, your `get_batch2` function appears to be taking random mini-batches from your dataset without tracking which indices you've used already in an epoch. The issue with this implementation is that it likely will not make use of all of your data.

The way I usually do batching is creating a random permutation of all the possible vertices using `torch.randperm(N)` and loop through them in batches. For example:

``````n_epochs = 100 # or whatever
batch_size = 128 # or whatever

for epoch in range(n_epochs):

# X is a torch Variable
permutation = torch.randperm(X.size()[0])

for i in range(0,X.size()[0], batch_size):

indices = permutation[i:i+batch_size]
batch_x, batch_y = X[indices], Y[indices]

# in case you wanted a semi-full example
outputs = model(batch_x)
loss = lossfunction(outputs,batch_y)

loss.backward()
optimizer.step()
``````

If you like to copy and paste, make sure you define your optimizer, model, and lossfunction somewhere before the start of the epoch loop.

With regards to your error, try using `torch.from_numpy(np.random.randint(0,N,size=M)).long()` instead of `torch.LongTensor(np.random.randint(0,N,size=M))`. I'm not sure if this will solve the error you are getting, but it will solve a future error.

• how does `torch.randperm(N)` help? Commented Nov 27, 2017 at 20:59
• It helps in two ways. The first is that it ensures each data point in X is sampled in a single epoch. It is usually good to use of all of your data to help your model generalize. The second way it helps is that it is relatively simple to implement. You don't have to make an entire function like `get_batch2()`. Commented Nov 28, 2017 at 21:44
• I wasn't aware people actually kept track of the indices they seen, is this standard practice? I thought it was just getting data without replacement what was the common practice, at least in neural nets, no? Commented Dec 1, 2017 at 17:41
• Yeah, the important parts are ensuring that data is not repeated in an epoch and all the data is used in each epoch. Otherwise the model might overfit to some particular data and could be worse at generalizing to unseen testing data. Tracking the indices is just a simple way to achieve this goal. Another approach would be to shuffle the data at the beginning of each epoch. Whatever works. It just looked like your example code was potentially reusing some data and neglecting other data within an epoch. Sorry if I misunderstood your code. Commented Dec 1, 2017 at 21:52
• nice answer, have not tested whether it works but `model.forward(inputs)`? I'm a noob but isn't Pytorch convention `model(inputs)`? stackoverflow.com/a/66594890/9481613 Commented May 13, 2023 at 1:29

# Data Set

First you define a dataset. You can use packages datasets in `torchvision.datasets` or use `ImageFolder` dataset class which follows the structure of Imagenet.

``````trainset=torchvision.datasets.ImageFolder(root='/path/to/your/data/trn', transform=generic_transform)
testset=torchvision.datasets.ImageFolder(root='/path/to/your/data/val', transform=generic_transform)
``````

# Transforms

Transforms are very useful for preprocessing loaded data on the fly. If you are using images, you have to use the `ToTensor()` transform to convert loaded images from `PIL` to `torch.tensor`. More transforms can be packed into a composit transform as follows.

``````generic_transform = transforms.Compose([
transforms.ToTensor(),
transforms.ToPILImage(),
#transforms.CenterCrop(size=128),
transforms.Lambda(lambda x: myimresize(x, (128, 128))),
transforms.ToTensor(),
transforms.Normalize((0., 0., 0.), (6, 6, 6))
])
``````

``````trainloader=torch.utils.data.DataLoader(trainset, batch_size=32, shuffle=True, num_workers=8)
``````

For training, you just enumerate on the data loader.

``````  for i, data in enumerate(trainloader, 0):
inputs, labels = data
inputs, labels = Variable(inputs.cuda()), Variable(labels.cuda())
# continue training...
``````

# NumPy Stuff

Yes. You have to convert `torch.tensor` to `numpy` using `.numpy()` method to work on it. If you are using CUDA you have to download the data from GPU to CPU first using the `.cpu()` method before calling `.numpy()`. Personally, coming from MATLAB background, I prefer to do most of the work with torch tensor, then convert data to numpy only for visualisation. Also bear in mind that torch stores data in a channel-first mode while numpy and PIL work with channel-last. This means you need to use `np.rollaxis` to move the channel axis to the last. A sample code is below.

``````np.rollaxis(make_grid(mynet.ftrextractor(inputs).data, nrow=8, padding=1).cpu().numpy(), 0, 3)
``````

# Logging

The best method I found to visualise the feature maps is using tensor board. A code is available at yunjey/pytorch-tutorial.

• The tensor board link is broken and also you can use `np.transpose()` to convert from channel first to channel last representation. Commented Oct 23, 2017 at 9:33
• if my data set is just a numpy array, how do I use your solution? I am confused sorry for the noob question. Commented Nov 23, 2017 at 23:54

You can use `torch.utils.data`

assuming you have loaded the data from the directory, in train and test numpy arrays, you can inherit from `torch.utils.data.Dataset` class to create your dataset object

``````class MyDataset(Dataset):
def __init__(self, x, y):
super(MyDataset, self).__init__()
assert x.shape[0] == y.shape[0] # assuming shape[0] = dataset size
self.x = x
self.y = y

def __len__(self):
return self.y.shape[0]

def __getitem__(self, index):
return self.x[index], self.y[index]
``````

``````traindata = MyDataset(train_x, train_y)
``````

Finally, use `DataLoader` to create your mini-batches

``````trainloader = torch.utils.data.DataLoader(traindata, batch_size=64, shuffle=True)
``````

Not sure what you were trying to do. W.r.t. batching you wouldn't have to convert to numpy. You could just use index_select() , e.g.:

``````for epoch in range(500):
k=0
loss = 0
while k < X_mdl.size(0):

random_batch = [0]*5
for i in range(k,k+M):
random_batch[i] = np.random.choice(N-1)
random_batch = torch.LongTensor(random_batch)
batch_xs = X_mdl.index_select(0, random_batch)
batch_ys = y.index_select(0, random_batch)

# Forward pass: compute predicted y using operations on Variables
y_pred = batch_xs.mul(W)
# etc..
``````

The rest of the code would have to be changed as well though.

My guess, you would like to create a get_batch function that concatenates your X tensors and Y tensors. Something like:

``````def make_batch(list_of_tensors):
X, y = list_of_tensors[0]
# may need to unsqueeze X and y to get right dimensions
for i, (sample, label) in enumerate(list_of_tensors[1:]):
X = torch.cat((X, sample), dim=0)
y = torch.cat((y, label), dim=0)
return X, y
``````

Then during training you select, e.g. max_batch_size = 32, examples through slicing.

``````for epoch:
X, y = make_batch(list_of_tensors)

k = 0
while k < X.size(0):
inputs = X[k:k+max_batch_size,:]
labels = y[k:k+max_batch_size,:]
# some computation
k+= max_batch_size
``````
• its really annoying, `index_select()` requires the data to not be a variable...why? Commented Nov 23, 2017 at 22:29
• Probably because changing only parts of the data inside a Variable doesn't enable gradient calculation. Commented Nov 27, 2017 at 11:21
• but the data always has its `requires_grad=False`...how does that matter? Commented Nov 27, 2017 at 20:58
• You're right, requires_grad is only a boolean that indicates whether the Variable has been created by a subgraph. The data Variable shouldn't require grad, because you will overwrite the original content anyway. Apparently, you can index_select a Variable with a Variable: discuss.pytorch.org/t/indexing-a-variable-with-a-variable/2111 Commented Nov 29, 2017 at 10:58
• Im confused about one thing whats the difference between `index_select()` vs just indexing directly `X[k1:k2,:]`? Like when would we use one vs the other? Commented Dec 1, 2017 at 17:40

Create a class that is a subclass of `torch.utils.data.Dataset` and pass it to a `torch.utils.data.Dataloader`. Below is an example for my project.

``````class CandidateDataset(Dataset):
def __init__(self, x, y):
self.len = x.shape[0]
if torch.cuda.is_available():
device = 'cuda'
else:
device = 'cpu'
self.x_data = torch.as_tensor(x, device=device, dtype=torch.float)
self.y_data = torch.as_tensor(y, device=device, dtype=torch.long)

def __getitem__(self, index):
return self.x_data[index], self.y_data[index]

def __len__(self):
return self.len

def fit(self, candidate_count):
feature_matrix = np.empty(shape=(candidate_count, 600))
target_matrix = np.empty(shape=(candidate_count, 1))
fill_matrices(feature_matrix, target_matrix)
candidate_ds = CandidateDataset(feature_matrix, target_matrix)
for epoch in range(self.N_EPOCHS):
print('starting epoch ' + str(epoch))
for batch_idx, (inputs, labels) in enumerate(train_loader):
print('starting batch ' + str(batch_idx) + ' epoch ' + str(epoch))
inputs, labels = Variable(inputs), Variable(labels)
inputs = inputs.view(1, inputs.size()[0], 600)
# init hidden with number of rows in input
y_pred = self.model(inputs, self.model.initHidden(inputs.size()[1]))
labels.squeeze_()
# labels should be tensor with batch_size rows. Column the index of the class (0 or 1)
loss = self.loss_f(y_pred, labels)
loss.backward()
self.optimizer.step()
print('done batch ' + str(batch_idx) + ' epoch ' + str(epoch))
``````

An alternative could be using `pd.DataFrame.sample`

``````train = pd.read_csv(TrainSetPath)

# use df.sample() to shuffle the data frame
train = train.sample(frac=1)
test = test.sample(frac=1)

for i in range(epochs):
for j in range(batch_per_epoch):
train_batch = train.sample(n=BatchSize, axis='index',replace=True)
y_train = train_batch['Target']
X_train = train_batch.drop(['Target'], axis=1)

# convert data frames to tensors and send them to GPU (if used)
X_train = torch.tensor(np.mat(X_train)).float().to(device)
y_train = torch.tensor(np.mat(y_train)).float().to(device)
``````