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import numpy as np | |
import torch | |
import ttach as tta | |
from typing import Callable, List, Tuple | |
from pytorch_grad_cam.activations_and_gradients import ActivationsAndGradients | |
from pytorch_grad_cam.utils.svd_on_activations import get_2d_projection | |
from pytorch_grad_cam.utils.image import scale_cam_image | |
from pytorch_grad_cam.utils.model_targets import ClassifierOutputTarget | |
from pytorch_grad_cam.utils.svd_on_activations import get_2d_projection | |
# https://arxiv.org/abs/2008.00299 | |
class BaseCAM: | |
def __init__(self, | |
model: torch.nn.Module, | |
target_layers: List[torch.nn.Module], | |
use_cuda: bool = False, | |
reshape_transform: Callable = None, | |
compute_input_gradient: bool = False, | |
uses_gradients: bool = True) -> None: | |
self.model = model.eval() | |
self.target_layers = target_layers | |
self.cuda = use_cuda | |
if self.cuda: | |
self.model = model.cuda() | |
self.reshape_transform = reshape_transform | |
self.compute_input_gradient = compute_input_gradient | |
self.uses_gradients = uses_gradients | |
self.activations_and_grads = ActivationsAndGradients( | |
self.model, target_layers, reshape_transform) | |
""" Get a vector of weights for every channel in the target layer. | |
Methods that return weights channels, | |
will typically need to only implement this function. """ | |
def get_cam_weights(self, | |
input_tensor: torch.Tensor, | |
target_layers: List[torch.nn.Module], | |
targets: List[torch.nn.Module], | |
activations: torch.Tensor, | |
grads: torch.Tensor) -> np.ndarray: | |
raise Exception("Not Implemented") | |
def get_cam_image(self, | |
input_tensor: torch.Tensor, | |
target_layer: torch.nn.Module, | |
targets: List[torch.nn.Module], | |
activations: torch.Tensor, | |
grads: torch.Tensor, | |
eigen_smooth: bool = False) -> np.ndarray: | |
weights = self.get_cam_weights(input_tensor, | |
target_layer, | |
targets, | |
activations, | |
grads) | |
weighted_activations = weights[:, :, None, None] * activations | |
if eigen_smooth: | |
cam = get_2d_projection(weighted_activations) | |
else: | |
cam = weighted_activations.sum(axis=1) | |
return cam | |
def forward(self, | |
input_tensor: torch.Tensor, | |
targets: List[torch.nn.Module], | |
eigen_smooth: bool = False) -> np.ndarray: | |
if self.cuda: | |
input_tensor = input_tensor.cuda() | |
if self.compute_input_gradient: | |
input_tensor = torch.autograd.Variable(input_tensor, | |
requires_grad=True) | |
outputs = self.activations_and_grads(input_tensor) | |
if targets is None: | |
target_categories = np.argmax(outputs.cpu().data.numpy(), axis=-1) | |
targets = [ClassifierOutputTarget( | |
category) for category in target_categories] | |
if self.uses_gradients: | |
self.model.zero_grad() | |
loss = sum([target(output) | |
for target, output in zip(targets, outputs)]) | |
loss.backward(retain_graph=True) | |
# In most of the saliency attribution papers, the saliency is | |
# computed with a single target layer. | |
# Commonly it is the last convolutional layer. | |
# Here we support passing a list with multiple target layers. | |
# It will compute the saliency image for every image, | |
# and then aggregate them (with a default mean aggregation). | |
# This gives you more flexibility in case you just want to | |
# use all conv layers for example, all Batchnorm layers, | |
# or something else. | |
cam_per_layer = self.compute_cam_per_layer(input_tensor, | |
targets, | |
eigen_smooth) | |
return self.aggregate_multi_layers(cam_per_layer) | |
def get_target_width_height(self, | |
input_tensor: torch.Tensor) -> Tuple[int, int]: | |
width, height = input_tensor.size(-1), input_tensor.size(-2) | |
return width, height | |
def compute_cam_per_layer( | |
self, | |
input_tensor: torch.Tensor, | |
targets: List[torch.nn.Module], | |
eigen_smooth: bool) -> np.ndarray: | |
activations_list = [a.cpu().data.numpy() | |
for a in self.activations_and_grads.activations] | |
grads_list = [g.cpu().data.numpy() | |
for g in self.activations_and_grads.gradients] | |
target_size = self.get_target_width_height(input_tensor[0]["image"]) | |
cam_per_target_layer = [] | |
# Loop over the saliency image from every layer | |
for i in range(len(self.target_layers)): | |
target_layer = self.target_layers[i] | |
layer_activations = None | |
layer_grads = None | |
if i < len(activations_list): | |
layer_activations = activations_list[i] | |
if i < len(grads_list): | |
layer_grads = grads_list[i] | |
cam = self.get_cam_image(input_tensor, | |
target_layer, | |
targets, | |
layer_activations, | |
layer_grads, | |
eigen_smooth) | |
cam = np.maximum(cam, 0) | |
scaled = scale_cam_image(cam, target_size) | |
cam_per_target_layer.append(scaled[:, None, :]) | |
return cam_per_target_layer | |
def aggregate_multi_layers( | |
self, | |
cam_per_target_layer: np.ndarray) -> np.ndarray: | |
cam_per_target_layer = np.concatenate(cam_per_target_layer, axis=1) | |
cam_per_target_layer = np.maximum(cam_per_target_layer, 0) | |
result = np.mean(cam_per_target_layer, axis=1) | |
return scale_cam_image(result) | |
def forward_augmentation_smoothing(self, | |
input_tensor: torch.Tensor, | |
targets: List[torch.nn.Module], | |
eigen_smooth: bool = False) -> np.ndarray: | |
transforms = tta.Compose( | |
[ | |
tta.HorizontalFlip(), | |
tta.Multiply(factors=[0.9, 1, 1.1]), | |
] | |
) | |
cams = [] | |
for transform in transforms: | |
augmented_tensor = transform.augment_image(input_tensor) | |
cam = self.forward(augmented_tensor, | |
targets, | |
eigen_smooth) | |
# The ttach library expects a tensor of size BxCxHxW | |
cam = cam[:, None, :, :] | |
cam = torch.from_numpy(cam) | |
cam = transform.deaugment_mask(cam) | |
# Back to numpy float32, HxW | |
cam = cam.numpy() | |
cam = cam[:, 0, :, :] | |
cams.append(cam) | |
cam = np.mean(np.float32(cams), axis=0) | |
return cam | |
def __call__(self, | |
input_tensor: torch.Tensor, | |
targets: List[torch.nn.Module] = None, | |
aug_smooth: bool = False, | |
eigen_smooth: bool = False) -> np.ndarray: | |
# Smooth the CAM result with test time augmentation | |
if aug_smooth is True: | |
return self.forward_augmentation_smoothing( | |
input_tensor, targets, eigen_smooth) | |
return self.forward(input_tensor, | |
targets, eigen_smooth) | |
def __del__(self): | |
self.activations_and_grads.release() | |
def __enter__(self): | |
return self | |
def __exit__(self, exc_type, exc_value, exc_tb): | |
self.activations_and_grads.release() | |
if isinstance(exc_value, IndexError): | |
# Handle IndexError here... | |
print( | |
f"An exception occurred in CAM with block: {exc_type}. Message: {exc_value}") | |
return True | |
class EigenCAM(BaseCAM): | |
def __init__(self, model, target_layers, use_cuda=False, | |
reshape_transform=None): | |
super(EigenCAM, self).__init__(model, | |
target_layers, | |
use_cuda, | |
reshape_transform, | |
uses_gradients=False) | |
def get_cam_image(self, | |
input_tensor, | |
target_layer, | |
target_category, | |
activations, | |
grads, | |
eigen_smooth): | |
return get_2d_projection(activations) | |