Congratulations on being a very early adopter of our interpretability engine! Not sure what's going on? Check out the FAQ.

Use the package manager pip to install leap-ie.

pip install leap-ie

During installation leap-ie does not modify any dependencies related to PyTorch or Tensorflow in order to preserve your development environment. However, leap-ie requires that the following version requirements are met:

PyTorch

Tensorflow

If you do not have the required libraries installed, you can quickly install them by specifying them as extras:

PyTorch

pip install leap-ie[with-torch]

Tensorflow

pip install leap-ie[with-tensorflow]

Sign in and generate your API key in the leap app - you'll need this to get started.

from leap_ie.vision import engine
from leap_ie.vision.models import get_model

preprocessing_fn, model, class_list = get_model('resnet18', source='torchvision')

config = {"leap_api_key": "YOUR_API_KEY"}

results_df, results_dict = engine.generate(project_name="leap!", model=model, class_list=class_list, config = config, target_classes=[1], preprocessing=preprocessing_fn)

We provide easy access to all image classification torchvision models via leap_ie.models.get_model("model_name", source="torchvision"). We can also automatically pull image classification models from huggingface - just use the model id: get_model('nateraw/vit-age-classifier', source='huggingface').

Using the interpretability engine with your own models is really easy! All you need to do is import leap_ie, and wrap your model in our generate function:

from leap_ie.vision import engine

df_results, dict_results = engine.generate(
    project_name="interpretability",
    model=your_model,
    class_list=["hotdog", "not_hotdog"],
    config={"leap_api_key": "YOUR_LEAP_API_KEY"},
)

Currently we support image classification models only. We expect the model to take a batch of images as input, and return a batch of logits (NOT probabilities). For most models this will work out of the box, but if your model returns something else (e.g. a dictionary, or probabilities) you might have to edit it, or add a wrapper before passing it to engine.generate().

class ModelWrapper(nn.Module):
    def __init__(self, model):
        super().__init__()
        self.model = model

    def forward(self, x):
        x = self.model(x)
        return x["logits"]

model = ModelWrapper(your_model)

The generate function returns a pandas dataframe and a dictionary of numpy arrays. If you're in a jupyter notebook, you can view these dataframe inline using engine.display_df(df_results), but for the best experience we recommend you head to the leap app, or log directly to your weights and biases dashboard.

For more information about the data we return, see prototypes, entanglements, and feature isolations. If used with samples (see Sample Feature Isolation), the dataframe contains feature isolations for each sample, for the target classes (if provided), or for the top 3 predicted classes.

We support both pytorch and tensorflow! Specify your package with the mode parameter, using 'tf' for tensorflow and 'pt' for pytorch.

If using pytorch, we expect the model to take images to be in channels first format, e.g. of shape [1, channels, height, width]. If tensorflow, channels last, e.g.[1, height, width, channels].

We can also log results directly to your WandB projects. To do this, set project_name to the name of the WandB project where you'd like the results to be logged, and add your WandB API key and entity name to the config dictionary:

config = {
    "wandb_api_key": "YOUR_WANDB_API_KEY",
    "wandb_entity": "your_wandb_entity",
    "leap_api_key": "YOUR_LEAP_API_KEY",
}
df_results, dict_results = engine.generate(
    project_name="your_wandb_project_name",
    model=your_model,
    class_list=["hotdog", "not_hotdog"],
    config=config,
)

Given your model, we generate prototypes and entanglements We also isolate entangled features in your prototypes.

from leap_ie.vision import engine
from leap_ie.vision.models import get_model

config = {"leap_api_key": "YOUR_LEAP_API_KEY"}

# Replace this model with your own, or explore any imagenet classifier from torchvision (https://pytorch.org/vision/stable/models.html).
preprocessing_fn, model, class_list = get_model("resnet18", source="torchvision")

# indexes of classes to generate prototypes for. In this case, ['tench', 'goldfish', 'great white shark'].
target_classes = [0, 1, 2]

# generate prototypes
df_results, dict_results = engine.generate(
    project_name="resnet18",
    model=model,
    class_list=class_list,
    config=config,
    target_classes=target_classes,
    preprocessing=preprocessing_fn,
    samples=None,
    device=None,
    mode="pt",
)

# For the best experience, head to https://app.leap-labs.com/ to explore your prototypes and feature isolations in the browser!
# Or, if you're in a jupyter notebook, you can display your results inline:
engine.display_df(df_results)

Given some input image, we can show you which features your model thinks belong to each class. If you specify target classes, we'll isolate features for those, or if not, we'll isolate features for the three highest probability classes.

from torchvision import transforms
from leap_ie.vision import engine
from leap_ie.vision.models import get_model
from PIL import Image

config = {"leap_api_key": "YOUR_LEAP_API_KEY"}

# Replace this model with your own, or explore any imagenet classifier from torchvision (https://pytorch.org/vision/stable/models.html).
preprocessing_fn, model, class_list = get_model("resnet18", source="torchvision")

# load an image
image_path = "tools.jpeg"
tt = transforms.ToTensor()
image = preprocessing_fn[0](tt(Image.open(image_path)).unsqueeze(0))

# to isolate features:
df_results, dict_results = engine.generate(
    project_name="resnet18",
    model=model,
    class_list=class_list,
    config=config,
    target_classes=None,
    preprocessing=preprocessing_fn,
    samples=image,
    mode="pt",
)

# For the best experience, head to https://app.leap-labs.com/ to explore your prototypes and feature isolations in the browser!
# Or, if you're in a jupyter notebook, you can display your results inline:
engine.display_df(df_results)

The generate function is used for both prototype generation directly from the model, and for feature isolation on your input samples.

leap_ie.vision.engine.generate(
    project_name,
    model,
    class_list,
    config,
    target_classes=None,
    preprocessing=None,
    samples=None,
    device=None,
    mode="pt",
)

• project_name (str): Name of your project. Used for logging.

  • Required: Yes
  • Default: None

• model (object): Model for interpretation. Currently we support image classification models only. We expect the model to take a batch of images as input, and return a batch of logits (NOT probabilities). If using pytorch, we expect the model to take images to be in channels first format, e.g. of shape [1, channels, height, width]. If tensorflow, channels last, e.g.[1, height, width, channels].

  • Required: Yes
  • Default: None

• class_list (list): List of class names corresponding to your model's output classes, e.g. ['hotdog', 'not hotdog', ...].

  • Required: Yes
  • Default: None

• config (dict or str): Configuration dictionary, or path to a json file containing your configuration. At minimum, this must contain {"leap_api_key": "YOUR_LEAP_API_KEY"}.

  • Required: Yes
  • Default: None

• target_classes (list, optional): List of target class indices to generate prototypes or isolations for, e.g. [0,1]. If None, prototypes will be generated for the class at output index 0 only, e.g. 'hotdog', and feature isolations will be generated for the top 3 predicted classes.

  • Required: No
  • Default: None

• preprocessing (function, optional): Preprocessing function to be used for generation. This can be None, but for best results, use the preprocessing function used on inputs for inference.

  • Required: No
  • Default: None

• samples (array, optional): None, or a batch of images to perform feature isolation on. If provided, only feature isolation is performed (not prototype generation). We expect samples to be of shape [num_images, height, width, channels] if using tensorflow, or [1, channels, height, width] if using pytorch.

  • Required: No
  • Default: None

• device (str, optional): Device to be used for generation. If None, we will try to find a device.

  • Required: No
  • Default: None

• mode (str, optional): Framework to use, either 'pt' for pytorch or 'tf' for tensorflow. Default is 'pt'.

  • Required: No
  • Default: pt

Leap provides a number of configuration options to fine-tune the interpretability engine's performance with your models. You can provide it as a dictionary or a path to a .json file.

• hf_weight (int): How much to penalise high-frequency patterns in the input. If you are generating very blurry and indistinct prototypes, decrease this. If you are getting very noisy prototypes, increase it. This depends on your model architecture and is hard for us to predict, so you might want to experiment. It's a bit like focussing a microscope. Best practice is to start with zero, and gradually increase.

  • Default: 0

• input_dim (list): The dimensions of the input that your model expects.

  • Default: [224, 224, 3] if mode is "tf" else [3, 224, 224]

• isolation (bool): Whether to isolate features for entangled classes. Set to False if you want prototypes only.

  • Default: True

• find_lr_steps (int): How many steps to tune the learning rate over at the start of the generation process. We do this automatically for you, but if you want to tune the learning rate manually, set this to zero and provide a learning rate with lr.

  • Default: 500

• max_steps (int): How many steps to run the prototype generation/feature isolation process for. If you get indistinct prototypes or isolations, try increasing this number.

  • Default: 1500

Here are all of the config options currently available:

config = {
    alpha_mask: bool = False
    alpha_only: bool = False
    alpha_weight: int = 1
    baseline_init: int = 0
    diversity_weight: int = 0
    find_lr_steps: int = 500
    hf_weight: int = 0
    input_dim: tuple = [3, 224, 224]
    isolate_classes: list = None
    isolation: bool = True
    isolation_hf_weight: int = 1
    isolation_lr: float = 0.05
    log_freq: int = 100
    lr: float = 0.05
    max_isolate_classes: int = 3
    max_lr: float = 1.0
    max_steps: int = 1500
    min_lr: float = 0.0001
    mode: str = "pt"
    num_lr_windows: int = 50
    project_name: str
    samples: list = None
    seed: int = 0
    stop_lr_early: bool = True
    transform: str = "xl"
    use_alpha: bool = False
    use_baseline: bool = False
    use_hipe: bool = False
    }

• alpha_mask (bool): If True, applies a mask during prototype generation which encourages the resulting prototypes to be minimal, centered and concentrated. Experimental.

  • Default: False

• alpha_only (bool): If True, during the prototype generation process, only an alpha channel is optimised. This results in generation prototypical shapes and textures only, with no colour information.

  • Default: False

• baseline_init (int or str): How to initialise the input. A sensible option is the mean of your expected input data, if you know it. Use 'r' to initialise with random noise for more varied results with different random seeds.

  • Default: 0

• diversity_weight (int): When generating multiple prototypes for the same class, we can apply a diversity objective to push for more varied inputs. The higher this number, the harder the optimisation process will push for different inputs. Experimental.

  • Default: 0

• find_lr_steps (int): How many steps to tune the learning rate over at the start of the generation process. We do this automatically for you, but if you want to tune the learning rate manually, set this to zero and provide a learning rate with lr.

  • Default: 500

• hf_weight (int): How much to penalise high-frequency patterns in the input. If you are generating very blurry and indistinct prototypes, decrease this. If you are getting very noisy prototypes, increase it. This depends on your model architecture and is hard for us to predict, so you might want to experiment. It's a bit like focussing binoculars. Best practice is to start with zero, and gradually increase.

  • Default: 1

• input_dim (list): The dimensions of the input that your model expects.

  • Default: [224, 224, 3] if mode is "tf" else [3, 224, 224]

• isolate_classes (list): If you'd like to isolate features for specific classes, rather than the top n, specify their indices here for EACH target, e.g. [[2,7,8], [2,3]].

  • Default: None

• isolation (bool): Whether to isolate features for entangled classes. Set to False if you want prototypes only.

  • Default: True

• isolation_hf_weight (int): How much to penalise high-frequency patterns in the feature isolation mask. See hf_weight.

  • Default: 1

• isolation_lr (float): How much to update the isolation mask at each step during the feature isolation process.

  • Default: 0.05

• log_freq (int): Interval at which to log images.

  • Default: 100

• lr (float): How much to update the prototype at each step during the prototype generation process. We find this for you automatically between max_lr and min_lr, but if you would like to tune it manually, set find_lr_steps to zero and provide it here.

  • Default: 0.05

• max_isolate_classes (int): How many classes to isolate features for, if isolate_classes is not provided.

  • Default: min(3, len(class_list))

• max_lr (float): Maximum learning rate for learning rate finder.

• Default: 1.0

• max_steps (int): How many steps to run the prototype generation/feature isolation process for. If you get indistinct prototypes or isolations, try increasing this number.

  • Default: 1000

• min_lr (float): Minimum learning rate for learning rate finder.

• Default: 0.0001

• seed (int): Random seed for initialisation.

  • Default: 0

• transform (str): Random affine transformation to guard against adversarial noise. You can also experiment with the following options: ['s', 'm', 'l', 'xl']. You can also set this to None and provide your own transformation in `engine.generate(preprocessing=your transformation).

  • Default: xl

• use_alpha (bool): If True, adds an alpha channel to the prototype. This results in the prototype generation process returning semi-transparent prototypes, which allow it to express ambivalence about the values of pixels that don't change the model prediction.

  • Default: False

• use_baseline (bool): Whether to generate an equidistant baseline input prior to the prototype generation process. It takes a bit longer, but setting this to True will ensure that all prototypes generated for a model are not biased by input initialisation.

  • Default: False

• wandb_api_key (str): Provide your weights and biases API key here to enable logging results directly to your WandB dashboard.

  • Default: None

• wandb_entity (str): If logging to WandB, make sure to provide your WandB entity name here.

  • Default: None

Prototype generation is a global interpretability method. It provides insight into what a model has learned without looking at its performance on test data, by extracting learned features directly from the model itself. This is important, because there's no guarantee that your test data covers all potential failure modes. It's another way of understanding what your model has learned, and helping you to predict how it will behave in deployment, on unseen data.

So what is a prototype? For each class that your model has been trained to predict, we can generate an input that maximises the probability of that output – this is the model's prototype for that class. It's a representation of what the model 'thinks' that class is.

For example, if you have a model trained to diagnose cancer from biopsy slides, prototype generation can show you what the model has learned to look for - what it 'thinks' malignant cells look like. This means you can check to see if it's looking for the right stuff, and ensure that it hasn't learned any spurious correlations from its training data that would cause dangerous mistakes in deployment (e.g. looking for lab markings on the slides, rather than at cell morphology).

During the prototype generation process we extract a lot of information from the model, including which other classes share features with the class prototype that we're generating. Depending on your domain, some entanglement may be expected - for example, an animal classifier is likely to have significant entanglement between 'cat' and 'dog', because those classes share (at least) the 'fur' feature. However, entanglement - especially unexpected entanglement, that doesn't make sense in your domain - can also be a very good indicator of where your model is likely to make misclassifications in deployment.

Feature isolation does what it says on the tin - it isolates which features in the input the model is using to make its prediction.

We can apply feature isolation in two ways:

• 1. On a prototype that we've generated, to isolate which features are shared between entangled classes, and so help explain how those classes are entangled; and
• 2. On some input data, to explain individual predictions that your model makes, by isolating the features in the input that correspond to the predicted class (similar to saliency mapping).

So, you can use it to both understand properties of your model as a whole, and to better understand the individual predictions it makes.