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lasso_example_null_CV.py
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lasso_example_null_CV.py
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import functools
import numpy as np
from scipy.stats import norm as ndist
import regreg.api as rr
from selection.tests.instance import gaussian_instance
from knockoffs import lasso_glmnet
from core import (infer_full_target,
split_sampler, # split_sampler not working yet
normal_sampler,
logit_fit,
probit_fit)
def simulate(n=100, p=50, s=10, signal=(0, 0), sigma=2, alpha=0.1):
# description of statistical problem
X, y, truth = gaussian_instance(n=n,
p=p,
s=s,
equicorrelated=False,
rho=0.0,
sigma=sigma,
signal=signal,
random_signs=True,
scale=False)[:3]
XTX = X.T.dot(X)
XTXi = np.linalg.inv(XTX)
resid = y - X.dot(XTXi.dot(X.T.dot(y)))
dispersion = np.linalg.norm(resid)**2 / (n-p)
S = X.T.dot(y)
covS = dispersion * X.T.dot(X)
smooth_sampler = normal_sampler(S, covS)
splitting_sampler = split_sampler(X * y[:, None], covS)
def meta_algorithm(X, XTXi, resid, sampler):
S = sampler(scale=0.) # deterministic with scale=0
ynew = X.dot(XTXi).dot(S) + resid # will be ok for n>p and non-degen X
G = lasso_glmnet(X, ynew, *[None]*4)
select = G.select()
return set(list(select[0]))
selection_algorithm = functools.partial(meta_algorithm, X, XTXi, resid)
# run selection algorithm
observed_set = selection_algorithm(splitting_sampler)
# find the target, based on the observed outcome
# we just take the first target
pivots, covered, lengths = [], [], []
naive_pivots, naive_covered, naive_lengths = [], [], []
for idx in list(observed_set)[:1]:
print("variable: ", idx, "total selected: ", len(observed_set))
true_target = truth[idx]
(pivot,
interval) = infer_full_target(selection_algorithm,
observed_set,
idx,
splitting_sampler,
dispersion,
hypothesis=true_target,
fit_probability=probit_fit,
alpha=alpha,
B=500)
pivots.append(pivot)
covered.append((interval[0] < true_target) * (interval[1] > true_target))
lengths.append(interval[1] - interval[0])
target_sd = np.sqrt(dispersion * XTXi[idx, idx])
observed_target = np.squeeze(XTXi[idx].dot(X.T.dot(y)))
quantile = ndist.ppf(1 - 0.5 * alpha)
naive_interval = (observed_target-quantile * target_sd, observed_target+quantile * target_sd)
naive_pivots.append((1-ndist.cdf((observed_target-true_target)/target_sd))) # one-sided
naive_covered.append((naive_interval[0]<true_target)*(naive_interval[1]>true_target))
naive_lengths.append(naive_interval[1]-naive_interval[0])
return pivots, covered, lengths, naive_pivots, naive_covered, naive_lengths
if __name__ == "__main__":
import statsmodels.api as sm
import matplotlib.pyplot as plt
np.random.seed(1)
U = np.linspace(0, 1, 101)
P, L, coverage = [], [], []
naive_P, naive_L, naive_coverage = [], [], []
plt.clf()
for i in range(500):
p, cover, l, naive_p, naive_covered, naive_l = simulate()
coverage.extend(cover)
P.extend(p)
L.extend(l)
naive_P.extend(naive_p)
naive_coverage.extend(naive_covered)
naive_L.extend(naive_l)
print("selective:", np.mean(P), np.std(P), np.mean(L) , np.mean(coverage))
print("naive:", np.mean(naive_P), np.std(naive_P), np.mean(naive_L), np.mean(naive_coverage))
print("len ratio selective divided by naive:", np.mean(np.array(L) / np.array(naive_L)))
if i % 2 == 0 and i > 0:
plt.clf()
plt.plot(U, sm.distributions.ECDF(P)(U), 'r', label='Selective', linewidth=3)
plt.plot([0,1], [0,1], 'k--', linewidth=2)
plt.plot(U, sm.distributions.ECDF(naive_P)(U), 'b', label='Naive', linewidth=3)
plt.legend()
plt.savefig('lasso_example_null_CV.pdf')