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import gradio as gr
import numpy as np
import matplotlib.pyplot as plt
import warnings
from functools import partial
from sklearn.datasets import make_blobs, make_spd_matrix
from sklearn.svm import LinearSVC
from sklearn.inspection import DecisionBoundaryDisplay
from sklearn.exceptions import ConvergenceWarning
def train_model(n_samples, C, penalty, loss, max_iter):
if penalty == "l1" and loss == "hinge":
raise gr.Error("The combination of penalty='l1' and loss='hinge' is not supported")
default_base = {"n_samples": 20}
# Algorithms to compare
params = default_base.copy()
params.update({"n_samples":n_samples,
"C": C,
"penalty": penalty,
"loss": loss,
"max_iter": max_iter})
X, y = make_blobs(n_samples=params["n_samples"], centers=2, random_state=0)
fig, ax = plt.subplots()
# catch warnings related to convergence
with warnings.catch_warnings():
warnings.filterwarnings("ignore", category=ConvergenceWarning)
# add penalty, l1 and l2. Default is l2
# add loss, square_hinge is Default. the other loss is hinge
# multi_class{‘ovr’, ‘crammer_singer’}, default=’ovr’
clf = LinearSVC(penalty=penalty, C=params["C"],
loss=params["loss"],
max_iter=params["max_iter"],
random_state=42).fit(X, y)
# obtain the support vectors through the decision function
decision_function = clf.decision_function(X)
# we can also calculate the decision function manually
# decision_function = np.dot(X, clf.coef_[0]) + clf.intercept_[0]
# The support vectors are the samples that lie within the margin
# boundaries, whose size is conventionally constrained to 1
support_vector_indices = np.where(np.abs(decision_function) <= 1 + 1e-15)[0]
support_vectors = X[support_vector_indices]
ax.scatter(X[:, 0], X[:, 1], c=y, s=30, cmap=plt.cm.Paired)
DecisionBoundaryDisplay.from_estimator(
clf,
X,
ax=ax,
grid_resolution=50,
plot_method="contour",
colors="k",
levels=[-1, 0, 1],
alpha=0.5,
linestyles=["--", "-", "--"],
)
ax.scatter(
support_vectors[:, 0],
support_vectors[:, 1],
s=100,
linewidth=1,
facecolors="none",
edgecolors="k",
)
ax.set_title("C=" + str(C))
return fig
def iter_grid(n_rows, n_cols):
# create a grid using gradio Block
for _ in range(n_rows):
with gr.Row():
for _ in range(n_cols):
with gr.Column():
yield
title = "📈 Linear Support Vector Classification"
with gr.Blocks(title=title) as demo:
gr.Markdown(f"## {title}")
gr.Markdown("The LinearSVC is an implementation of a \
Support Vector Machine (SVM) for classification. \
It aims to find the optimal linear \
decision boundary that separates classes in the input data.")
gr.Markdown("The most important parameters of `LinearSVC` are:")
param_C = "\
1. `C`: The inverse of the regularization strength. \
A smaller `C` value increases the amount of regularization, \
promoting simpler models, while a larger `C` value reduces \
regularization, allowing more complex models. \
It controls the trade-off between fitting the \
training data and generalization to unseen data."
param_loss=" \
2. `loss`: The loss function used for training. \
The default is `squared_hinge`, which is a variant \
of hinge loss. The combination of penalty='l1' and \
loss='hinge' is not supported."
param_penalty="\
3. `penalty`: The type of regularization penalty \
applied to the model. The default is `l2`, which uses \
the L2 norm."
param_dual="\
4. `dual`: Determines whether the dual or primal optimization \
problem is solved. By default, `dual=True` when the number \
of samples is less than the number of features, and `dual=False` \
otherwise. For large-scale problems, setting `dual=False` \
can be more efficient."
param_tol="\
5. `tol`: The tolerance for stopping criteria. \
The solver stops when the optimization reaches \
a specified tolerance level."
param_max_iter="\
6. `max_iter`: The maximum number of iterations for solver \
convergence. If not specified, the default value is 1000."
gr.Markdown(param_C)
gr.Markdown(param_loss)
gr.Markdown(param_penalty)
gr.Markdown(param_dual)
gr.Markdown(param_tol)
gr.Markdown(param_max_iter)
gr.Markdown("Read more in the \
[original example](https://scikit-learn.org/stable/modules/generated/sklearn.svm.LinearSVC.html#sklearn.svm.LinearSVC).")
n_samples = gr.Slider(minimum=20, maximum=100, step=5,
label = "Number of Samples")
with gr.Row():
input_model = "LinearSVC"
fn = partial(train_model)
with gr.Row():
penalty = gr.Dropdown(["l1", "l2"], value="l2", interactive=True, label="Penalty to prevent overfitting")
loss = gr.Dropdown(["hinge", "squared hinge"], value="hinge", interactive=True, label="Loss function")
with gr.Row():
max_iter = gr.Slider(minimum=100, maximum=2000, step=100, value=1000,
label = "Max. number of iterations")
param_C = gr.Number(value=1,
label = "Regularization parameter C",
# info="When C is smal the regularization effect is stronger. "
# + "This can help to avoid overfitting but may lead to higher bias. "
# + "On the other hand, when C is large, the regularization effect "
# + "is weaker, and the model can have larger parameter values, "
# + "allowing for more complex decision boundaries that fit the "
# + "training data more closely. This may increase the risk of "
# + "overfitting and result in a higher variance model."
)
with gr.Row():
penalty2 = gr.Dropdown(["l1", "l2"], value="l2", interactive=True, label="Penalty to prevent overfitting")
loss2 = gr.Dropdown(["hinge", "squared hinge"], value="hinge", interactive=True, label="Loss function")
with gr.Row():
max_iter2 = gr.Slider(minimum=100, maximum=2000, step=100, value=1000,
label = "Max. number of iterations")
param_C2 = gr.Number(value=100,
label = "Regularization parameter C"
)
with gr.Row():
plot = gr.Plot(label=input_model)
n_samples.change(fn=fn, inputs=[n_samples, param_C, penalty, loss, max_iter], outputs=plot)
param_C.change(fn=fn, inputs=[n_samples, param_C, penalty, loss, max_iter], outputs=plot)
penalty.change(fn=fn, inputs=[n_samples, param_C, penalty, loss, max_iter], outputs=plot)
loss.change(fn=fn, inputs=[n_samples, param_C, penalty, loss, max_iter], outputs=plot)
max_iter.change(fn=fn, inputs=[n_samples, param_C, penalty, loss, max_iter], outputs=plot)
plot2 = gr.Plot(label=input_model)
n_samples.change(fn=fn, inputs=[n_samples, param_C2, penalty2, loss2, max_iter2], outputs=plot2)
param_C2.change(fn=fn, inputs=[n_samples, param_C2, penalty2, loss2, max_iter2], outputs=plot2)
penalty2.change(fn=fn, inputs=[n_samples, param_C2, penalty2, loss2, max_iter2], outputs=plot2)
loss2.change(fn=fn, inputs=[n_samples, param_C2, penalty2, loss2, max_iter2], outputs=plot2)
max_iter2.change(fn=fn, inputs=[n_samples, param_C2, penalty2, loss2, max_iter2], outputs=plot2)
demo.launch()