Working with deep learning models
Project description
QuNet
Easy working with deep learning models.
- Trainer class for training the model.
- Various tools for visualizing the training process and the state of the model.
- Training large models: float16, mini-batch splitting, etc.
- Large set of custom modules for neural networks (MLP, CNN, Transformer, etc.)
Install
pip install qunet
Usage
To work with the library, it is enough to add training_step(batch, batch_id)
to the model, in which to calculate the loss and, if necessary, some quality metrics.
For example, for 1D linear regression $y=f(x)$ with mse-loss and metric as |y_pred-y_true|, model looks like:
class Model(nn.Module):
def __init__(self):
super().__init__()
self.fc = nn.Linear( 1, 1 )
def forward(self, x): # (B,1)
return self.fc(x) # (B,1)
def training_step(self, batch, batch_id):
x, y_true = batch # the model knows the minbatch format
y_pred = self(x) # (B,1) forward function call
loss = (y_pred - y_true).pow(2).mean() # () loss for optimization (scalar)!
error = torch.abs(y_pred.detach()-y_true).mean() # (B,1) error for batch samples
return {'loss':loss, 'score': error} # if no score, you can return loss
model = Model()
Training and validation datasets can be standard DataLoader
.
For small datasets, you can also use the faster loader Data
from the library:
from qunet import Data, Trainer
num, val = 1000, 900
X = torch.rand(num)
Y = 2*X + torch.randn(X.shape)
data_trn = Data( (X[:val], Y[:val]) )
data_val = Data( (X[val:], Y[val:]) )
After that, we create an instance of the trainer, pass the model and data to it. Set the optimizer at the trainer and start training:
trainer = Trainer(model, data_trn, data_val)
trainer.set_optimizer( torch.optim.SGD(model.parameters(), lr=1e-2) )
trainer.fit(epochs=10, period_plot=5, monitor=['loss'])
This is all!
Let's make a small overview of the library. A more detailed introduction can be found in the document Quick start, documents describing the various modules of the library, and notebooks dedicated to various deep learning tasks.
Trainer
The trainer is a key object of the QuNet library. It solves the following tasks:
- Model training and validation.
- Visualization of the learning process, with ample opportunities for its customization.
- Calculation of optimal breakpoints based on the best local and smoothed metrics.
- Saving the best models by loss or score, as well as saving checkpoints.
- Combining different training schedulers
- For large models, switch to half precision and use the gradient accumulation buffer.
- Use of multiple callback objects that can be embedded in different parts of the pipeline.
Below is an example of visualization:
val_loss: best = 0.190465[293], smooth21 = 0.199713[296], last21 = 0.210965 В± 0.019436
trn_loss: best = 0.209042[234], smooth21 = 0.244457[299], last21 = 0.293281 В± 0.043728
val_score: best = 0.942300[291], smooth21 = 0.938188[295], last21 = 0.934581 В± 0.000000
trn_score: best = 0.929560[234], smooth21 = 0.916017[299], last21 = 0.898531 В± 0.005823
epochs=300, samples=15000000, steps=30000
times=(trn:214.34, val:11.69)m, 42.87 s/epoch, 428.68 s/10^3 steps, 857.35 s/10^6 samples
Example of learning curves of various schedulers:
ModelState
The standalone ModelState
class is a powerful replacement for libraries such as torchinfo.
It allows you to display information about submodules and their parameters.
Transformer params data
в”њв”Ђ ModuleList -> < blocks
в”‚ в””в”Ђ TransformerBlock (1, 10, 64) -> (1, 10, 64) < blocks[0]
в”‚ в””в”Ђ Residual (1, 10, 64) -> (1, 10, 64) < blocks[0].fft
в”‚ в””в”Ђ FFT (1, 10, 64) -> (1, 10, 64) < blocks[0].fft.module
в”‚ в””в”Ђ Dropout(0) (1, 10, 64) -> (1, 10, 64) < blocks[0].fft.module.drop
в”‚ в””в”Ђ LayerNorm 128 | (1, 10, 64) -> (1, 10, 64) < blocks[0].fft.norm
в”‚ в””в”Ђ Residual (1, 10, 64) -> (1, 10, 64) < blocks[0].att
в”‚ в””в”Ђ Attention (1, 10, 64) -> (1, 10, 64) < blocks[0].att.module
в”‚ в””в”Ђ Linear(64->192) 12,480 ~ 25% | (1, 10, 64) -> (1, 10, 192) < blocks[0].att.module.c_attn
в”‚ в””в”Ђ Linear(64->64) 4,160 ~ 8% | (1, 10, 64) -> (1, 10, 64) < blocks[0].att.module.c_proj
в”‚ в””в”Ђ Dropout(0) (1, 4, 10, 10) -> (1, 4, 10, 10) < blocks[0].att.module.att_dropout
в”‚ в””в”Ђ Dropout(0) (1, 10, 64) -> (1, 10, 64) < blocks[0].att.module.res_dropout
в”‚ в””в”Ђ LayerNorm 128 | (1, 10, 64) -> (1, 10, 64) < blocks[0].att.norm
в”‚ в””в”Ђ Residual (1, 10, 64) -> (1, 10, 64) < blocks[0].mlp
в”‚ в””в”Ђ MLP (1, 10, 64) -> (1, 10, 64) < blocks[0].mlp.module
в”‚ в””в”Ђ Sequential (1, 10, 64) -> (1, 10, 64) < blocks[0].mlp.module.layers
в”‚ в””в”Ђ Linear(64->256) 16,640 ~ 33% | (1, 10, 64) -> (1, 10, 256) < blocks[0].mlp.module.layers[0]
в”‚ в””в”Ђ GELU (1, 10, 256) -> (1, 10, 256) < blocks[0].mlp.module.layers[1]
в”‚ в””в”Ђ Dropout(0) (1, 10, 256) -> (1, 10, 256) < blocks[0].mlp.module.layers[2]
в”‚ в””в”Ђ Linear(256->64) 16,448 ~ 33% | (1, 10, 256) -> (1, 10, 64) < blocks[0].mlp.module.layers[3]
в”‚ в””в”Ђ LayerNorm 128 | (1, 10, 64) -> (1, 10, 64) < blocks[0].mlp.norm
=============================================
trainable: 50,115
During training, ModelState
keeps track of gradients and smoothes values:
# params |mean| [ min, max ] |grad| shape
-------------------------------------------------------------------------------------
0: blocks.0.fft.gamma 1 0.200 [ 0.200, 0.200] 1.3e+02 ()
1: blocks.0.fft.norm.weight 64 1.000 [ 1.000, 1.000] 4.7e-01 (64,)
2: blocks.0.fft.norm.bias 64 0.000 [ 0.000, 0.000] 2.2e-01 (64,)
...
Modules
The library has many ready-made modules for building various architectures of neural networks:
- MLP
- Transformer
- CNN
- ResCNN
- ProjViT
- ResCNN3D
- GNN
Most modules have debugging and visualization tools. For example, this is how the visualization of the learning process of a transformer, consisting of 10 blocks, looks like.
Such diagrams allow you to analyze the problem areas of the network and change them in the learning process.
Docs
Examples
- Interpolation_F(x) - interpolation of a function of one variable (example of setting up a training plot; working with the list of schedulers; adding a custom plot)
- MNIST - recognition of handwritten digits 0-9 (example using pytorch DataLoader, model predict, show errors, confusion matrix)
- CIFAR10 (truncated EfficientNet, pre-trained parameters, bone freezing, augmentation)
- Vanishing gradient
- Regression_1D - visualization of changes in model parameters
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