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A library to inspect and extract intermediate layers of PyTorch models.

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A library to inspect and extract intermediate layers of PyTorch models.

Why?

It's often the case that we want to inspect intermediate layers of PyTorch models without modifying the code. This can be useful to get attention matrices of language models, visualize layer embeddings, or apply a loss function to intermediate layers. Sometimes we want extract subparts of the model and run them independently, either to debug them or to train them separately. All of this can be done with Surgeon without changing one line of the original model.

Install

$ pip install surgeon-pytorch

PyPI - Python Version

Usage

Inspect

Given a PyTorch model we can display all layers using get_layers:

import torch
import torch.nn as nn

from surgeon_pytorch import Inspect, get_layers

class SomeModel(nn.Module):

    def __init__(self):
        super().__init__()
        self.layer1 = nn.Linear(5, 3)
        self.layer2 = nn.Linear(3, 2)
        self.layer3 = nn.Linear(2, 1)

    def forward(self, x):
        x1 = self.layer1(x)
        x2 = self.layer2(x1)
        y = self.layer3(x2)
        return y


model = SomeModel()
print(get_layers(model)) # ['layer1', 'layer2', 'layer3']

Then we can wrap our model to be inspected using Inspect and in every forward call the new model we will also output the provided layer outputs (in second return value):

model_wrapped = Inspect(model, layer='layer2')
x = torch.rand(1, 5)
y, x2 = model_wrapped(x)
print(x2) # tensor([[-0.2726,  0.0910]], grad_fn=<AddmmBackward0>)
Inspect Multiple Layers

We can provide a list of layers:

model_wrapped = Inspect(model, layer=['layer1', 'layer2'])
x = torch.rand(1, 5)
y, [x1, x2] = model_wrapped(x)
print(x1) # tensor([[ 0.1739,  0.3844, -0.4724]], grad_fn=<AddmmBackward0>)
print(x2) # tensor([[-0.2238,  0.0107]], grad_fn=<AddmmBackward0>)
Name Inspected Layer Outputs

We can provide a dictionary to get named outputs:

model_wrapped = Inspect(model, layer={'layer1': 'x1', 'layer2': 'x2'})
x = torch.rand(1, 5)
y, layers = model_wrapped(x)
print(layers)
"""
{
    'x1': tensor([[ 0.3707,  0.6584, -0.2970]], grad_fn=<AddmmBackward0>),
    'x2': tensor([[-0.1953, -0.3408]], grad_fn=<AddmmBackward0>)
}
"""
API
model = Inspect(
    model: nn.Module,
    layer: Union[str, Sequence[str], Dict[str, str]],
    keep_output: bool = True,
)

Extract

Given a PyTorch model we can display all intermediate nodes of the graph using get_nodes:

import torch
import torch.nn as nn
from surgeon_pytorch import Extract, get_nodes

class SomeModel(nn.Module):

    def __init__(self):
        super().__init__()
        self.layer1 = nn.Linear(5, 3)
        self.layer2 = nn.Linear(3, 2)
        self.layer3 = nn.Linear(1, 1)

    def forward(self, x):
        x1 = torch.relu(self.layer1(x))
        x2 = torch.sigmoid(self.layer2(x1))
        y = self.layer3(x2).tanh()
        return y

model = SomeModel()
print(get_nodes(model)) # ['x', 'layer1', 'relu', 'layer2', 'sigmoid', 'layer3', 'tanh']

Then we can extract outputs using Extract, which will create a new model that returns the requested output node:

model_ext = Extract(model, node_out='sigmoid')
x = torch.rand(1, 5)
sigmoid = model_ext(x)
print(sigmoid) # tensor([[0.5570, 0.3652]], grad_fn=<SigmoidBackward0>)

We can also extract a model with new input nodes:

model_ext = Extract(model, node_in='layer1', node_out='sigmoid')
layer1 = torch.rand(1, 3)
sigmoid = model_ext(layer1)
print(sigmoid) # tensor([[0.5444, 0.3965]], grad_fn=<SigmoidBackward0>)
Multiple Nodes

We can also provide multiple inputs and outputs and name them:

model_ext = Extract(model, node_in={ 'layer1': 'x' }, node_out={ 'sigmoid': 'y1', 'relu': 'y2'})
out = model_ext(x = torch.rand(1, 3))
print(out)
"""
{
    'y1': tensor([[0.4437, 0.7152]], grad_fn=<SigmoidBackward0>),
    'y2': tensor([[0.0555, 0.9014, 0.8297]]),
}
"""
Graph Input/Output Summary

Note that changing an input node might not be enough to cut the graph (there might be other dependencies connected to previous inputs). To view all inputs of the new graph we can call model_ext.summary which will give us an overview of all required inputs and returned outputs:

import torch
import torch.nn as nn
from surgeon_pytorch import Extract, get_nodes

class SomeModel(nn.Module):

    def __init__(self):
        super().__init__()
        self.layer1a = nn.Linear(2, 2)
        self.layer1b = nn.Linear(2, 2)
        self.layer2 = nn.Linear(2, 1)

    def forward(self, x):
        a = self.layer1a(x)
        b = self.layer1b(x)
        c = torch.add(a, b)
        y = self.layer2(c)
        return y

model = SomeModel()
print(get_nodes(model)) # ['x', 'layer1a', 'layer1b', 'add', 'layer2']

model_ext = Extract(model, node_in = {'layer1a': 'my_input'}, node_out = {'add': 'my_add'})
print(model_ext.summary) # {'input': ('x', 'my_input'), 'output': {'my_add': add}}

out = model_ext(x = torch.rand(1, 2), my_input = torch.rand(1,2))
print(out) # {'my_add': tensor([[ 0.3722, -0.6843]], grad_fn=<AddBackward0>)}
API

API

model = Extract(
    model: nn.Module,
    node_in: Optional[Union[str, Sequence[str], Dict[str, str]]] = None,
    node_out: Optional[Union[str, Sequence[str], Dict[str, str]]] = None,
    tracer: Optional[Type[Tracer]] = None,          # Tracer class used, default: torch.fx.Tracer
    concrete_args: Optional[Dict[str, Any]] = None, # Tracer concrete_args, default: None
    keep_output: bool = None,                       # Set to `True` to return original outputs as first argument, default: True except if node_out are provided
    share_modules: bool = False,                    # Set to true if you want to share module weights with original model
)

Inspect vs Extract

The Inspect class always executes the entire model provided as input, and it uses special hooks to record the tensor values as they flow through. This approach has the advantages that (1) we don't create a new module (2) it allows for a dynamic execution graph (i.e. for loops and if statements that depend on inputs). The downsides of Inspect are that (1) if we only need to execute part of the model some computation is wasted, and (2) we can only output values from nn.Module layers – no intermediate function values.

The Extract class builds an entirely new model using symbolic tracing. The advantages of this approach are (1) we can crop the graph anywhere and get a new model that computes only that part, (2) we can extract values from intermediate functions (not only layers), and (3) we can also change input tensors. The downside of Extract is that only static graphs are allowed (note that most models have static graphs).

TODO

  • add extract function to get intermediate block
  • add model inputs/outputs summary