import numpy as np
from numpy import ndarray
from scipy.optimize import Bounds, LinearConstraint, minimize
def norm_squared(vector: ndarray) -> float:
"""
Return the squared second norm of vector
norm_squared(v) = sum(x * x for x in v)
Args:
vector (ndarray): input vector
Returns:
float: squared second norm of vector
>>> norm_squared([1, 2])
5
>>> norm_squared(np.asarray([1, 2]))
5
>>> norm_squared([0, 0])
0
"""
return np.dot(vector, vector)
class SVC:
"""
Support Vector Classifier
Args:
kernel (str): kernel to use. Default: linear
Possible choices:
- linear
regularization: constraint for soft margin (data not linearly separable)
Default: unbound
>>> SVC(kernel="asdf")
Traceback (most recent call last):
...
ValueError: Unknown kernel: asdf
>>> SVC(kernel="rbf")
Traceback (most recent call last):
...
ValueError: rbf kernel requires gamma
>>> SVC(kernel="rbf", gamma=-1)
Traceback (most recent call last):
...
ValueError: gamma must be > 0
"""
def __init__(
self,
*,
regularization: float = np.inf,
kernel: str = "linear",
gamma: float = 0,
) -> None:
self.regularization = regularization
self.gamma = gamma
if kernel == "linear":
self.kernel = self.__linear
elif kernel == "rbf":
if self.gamma == 0:
raise ValueError("rbf kernel requires gamma")
if not (isinstance(self.gamma, float) or isinstance(self.gamma, int)):
raise ValueError("gamma must be float or int")
if not self.gamma > 0:
raise ValueError("gamma must be > 0")
self.kernel = self.__rbf
else:
raise ValueError(f"Unknown kernel: {kernel}")
def __linear(self, vector1: ndarray, vector2: ndarray) -> float:
"""Linear kernel (as if no kernel used at all)"""
return np.dot(vector1, vector2)
def __rbf(self, vector1: ndarray, vector2: ndarray) -> float:
"""
RBF: Radial Basis Function Kernel
Note: for more information see:
https://en.wikipedia.org/wiki/Radial_basis_function_kernel
Args:
vector1 (ndarray): first vector
vector2 (ndarray): second vector)
Returns:
float: exp(-(gamma * norm_squared(vector1 - vector2)))
"""
return np.exp(-(self.gamma * norm_squared(vector1 - vector2)))
def fit(self, observations: list[ndarray], classes: ndarray) -> None:
"""
Fits the SVC with a set of observations.
Args:
observations (list[ndarray]): list of observations
classes (ndarray): classification of each observation (in {1, -1})
"""
self.observations = observations
self.classes = classes
(n,) = np.shape(classes)
def to_minimize(candidate: ndarray) -> float:
"""
Opposite of the function to maximize
Args:
candidate (ndarray): candidate array to test
Return:
float: Wolfe's Dual result to minimize
"""
s = 0
(n,) = np.shape(candidate)
for i in range(n):
for j in range(n):
s += (
candidate[i]
* candidate[j]
* classes[i]
* classes[j]
* self.kernel(observations[i], observations[j])
)
return 1 / 2 * s - sum(candidate)
ly_contraint = LinearConstraint(classes, 0, 0)
l_bounds = Bounds(0, self.regularization)
l_star = minimize(
to_minimize, np.ones(n), bounds=l_bounds, constraints=[ly_contraint]
).x
self.optimum = l_star
s = 0
for i in range(n):
for j in range(n):
s += classes[i] - classes[i] * self.optimum[i] * self.kernel(
observations[i], observations[j]
)
self.offset = s / n
def predict(self, observation: ndarray) -> int:
"""
Get the expected class of an observation
Args:
observation (Vector): observation
Returns:
int {1, -1}: expected class
>>> xs = [
... np.asarray([0, 1]), np.asarray([0, 2]),
... np.asarray([1, 1]), np.asarray([1, 2])
... ]
>>> y = np.asarray([1, 1, -1, -1])
>>> s = SVC()
>>> s.fit(xs, y)
>>> s.predict(np.asarray([0, 1]))
1
>>> s.predict(np.asarray([1, 1]))
-1
>>> s.predict(np.asarray([2, 2]))
-1
"""
s = sum(
self.optimum[n]
* self.classes[n]
* self.kernel(self.observations[n], observation)
for n in range(len(self.classes))
)
return 1 if s + self.offset >= 0 else -1
if __name__ == "__main__":
import doctest
doctest.testmod()