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evaluate.py
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331 lines (298 loc) · 9.36 KB
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from dataclasses import dataclass
from foolbox.models import pytorch
from foolbox.utils import accuracy
from foolbox.attacks import projected_gradient_descent
from foolbox.attacks import LinfPGD, carlini_wagner
from prototorch.core.distances import (
squared_euclidean_distance,
lpnorm_distance,
)
from distance import lpips_distance
import torch
@dataclass
class LowerBoundRTM:
LRTE: float
LRTA: float
CTE: float
CTA: float
@dataclass
class UpperBoundRTM:
URTE: float
URTA: float
def get_lowerbound_certification(
model,
data: torch.Tensor,
labels: torch.LongTensor,
epsilon: float,
p_norm: int | str,
q_norm: int | str,
device: str = "cpu",
) -> LowerBoundRTM:
# load model if any or live certification
match isinstance(model, str):
case True:
model = torch.load(model)
model.eval()
case _:
pass
condition1 = q_norm in ["lpips-linf", "lpips-l2", "lpips-l1"]
match condition1:
case True:
device ="cuda" if torch.cuda.is_available() else "cpu"
case False:
device = "cpu"
fmodel = pytorch.PyTorchModel(
model=model,
bounds=(0, 1),
device=device,
)
data = data.to(device)
labels = labels.to(device)
clean_acc = accuracy(fmodel, data, labels)
# setup attacks
match p_norm:
case "linf":
attack = LinfPGD()
raw_advs, clipped_advs, success = attack(
fmodel, data, labels, epsilons=epsilon
)
case "l2":
attack = carlini_wagner.L2CarliniWagnerAttack()
raw_advs, clipped_advs, success = attack(
fmodel, data, labels, epsilons=epsilon
)
case "l1":
attack = projected_gradient_descent.L1ProjectedGradientDescentAttack()
raw_advs, clipped_advs, success = attack(
fmodel, data, labels, epsilons=epsilon
)
case _:
raise NotImplementedError(
"evaluate with either l1, l2 or linf norm",
)
robust_test_error = success.float().mean(axis=-1).item()
robust_test_accuracy = 1 - robust_test_error
return LowerBoundRTM(
LRTE=round(robust_test_error, 4),
LRTA=round(robust_test_accuracy, 4),
CTA=round(clean_acc, 4),
CTE=round(1 - clean_acc, 4),
)
def get_upperbound_certification(
x_test: torch.Tensor,
prototypes: torch.Tensor,
labels: torch.LongTensor,
ppc: int,
epsilon: float,
p_norm: str | int | None = None,
q_norm: str | int | None = None,
device: str = "cpu",
) -> float:
condition1 = q_norm in ["lpips-linf", "lpips-l2", "lpips-l1"]
match condition1:
case True:
device ="cuda" if torch.cuda.is_available() else "cpu"
case False:
device = "cpu"
x_test = x_test.to(device)
prototypes = prototypes.to(device)
match (condition1, p_norm):
case (False, "l2"):
distance_space = lpnorm_distance(
x=x_test,
y=prototypes,
p=2,
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (False, "linf"):
distance_space = lpnorm_distance(
x=x_test,
y=prototypes,
p=float("inf"),
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (False, "l1"):
distance_space = lpnorm_distance(
x=x_test,
y=prototypes,
p=1,
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (False, None):
distance_space = squared_euclidean_distance(
x=x_test,
y=prototypes,
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm="l2",
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (True, "l2"): # use stable version only
distance_space = lpips_distance(
x=x_test,
y=prototypes,
p="l2",
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (True, "l1"): # only to investiage numerical stability
distance_space = lpips_distance(
x=x_test,
y=prototypes,
p="l1",
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case (True, "linf"): # only to investigate numerical stability
distance_space = lpips_distance(
x=x_test,
y=prototypes,
p="linf",
)
urte = get_urte(
distance_space=distance_space,
labels=labels,
ppc=ppc,
epsilon=epsilon,
p_norm=p_norm,
q_norm=q_norm,
x_test=x_test,
)
score = len(urte) / len(x_test)
return round(score, 4)
case _:
raise NotImplementedError(
"compute the closest distance: use l2, linf or l1 norm"
)
def get_urte(
distance_space: torch.Tensor,
labels: torch.LongTensor,
ppc: int,
epsilon: float,
p_norm: str,
q_norm: str,
x_test: torch.Tensor,
) -> list[float]:
margin = []
p = get_certification_norms(p_norm)
q = get_certification_norms(q_norm)
cond, epsilon = p <= q, 2 * epsilon
input_shape = torch.Tensor(list(x_test.shape[1:]))
n = int(torch.prod(input_shape).item())
for i, v in enumerate(distance_space):
dist = distance_space[i].reshape(len(torch.unique(labels)), ppc)
min_dist = torch.Tensor([torch.min(protos_dis) for protos_dis in dist])
wp_wm_indices = torch.argsort(min_dist)[:2]
if labels[i] == wp_wm_indices[0]:
wp = wp_wm_indices[0]
wm = wp_wm_indices[1]
else:
wp = wp_wm_indices[1]
wm = wp_wm_indices[0]
dp = min_dist[wp].item()
dm = min_dist[wm].item()
hypothesis_margin = dm - dp
hypothesis_margin = round(hypothesis_margin, 4)
match cond:
case True:
if hypothesis_margin <= epsilon:
margin.append(hypothesis_margin)
case False:
if (n ** (1 / p - 1 / q) * hypothesis_margin) <= epsilon:
margin.append(hypothesis_margin)
return margin
def get_certification_norms(input_norm: str):
match input_norm:
case "l1":
return 1
case "l2":
return 2
case "linf":
return float("inf")
case "lpips-l2":
return 2
case "lpips-l1":
return 1
case "lpips-linf":
return float("inf")
case _:
raise NotImplementedError(
"use either l1,l2 and linf for arbitrary semi-norms"
"or lpips-l2 and lpips-l1 for semi-metric"
)
@dataclass(slots=True)
class LPN:
lp_norm: str
def get_lpnorms(self, x, y):
match self.lp_norm:
case "l2":
return lpnorm_distance(x, y, 2)
case "linf":
return lpnorm_distance(x, y, float("inf"))
case "l1":
return lpnorm_distance(x, y, 1)
case "lpips-l2":
return lpips_distance(x, y, "l2") # semi_metric stable version
case "lpips-l1":
return lpips_distance(x, y, "l1") # semi-metric
case "lpips-linf":
return lpips_distance(x, y, "linf") # semi-metric
case _:
raise NotImplementedError(
"get_lpnorms:none of the cases did match",
)