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eugenium_mmd.py
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eugenium_mmd.py
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'''
Code taken from: https://github.com/eugenium/mmd
(modified slightly for efficiency/PEP by Stephanie Hyland)
Python implementation of MMD and Covariance estimates for Relative MMD
Some code is based on code from Vincent Van Asch
which is based on matlab code from Arthur Gretton
Eugene Belilovsky
'''
import numpy as np
import scipy as sp
from numpy import sqrt
from sklearn.metrics.pairwise import rbf_kernel
from functools import partial
import pdb
def my_kernel(X, Y, sigma):
gamma = 1 / (2 * sigma**2)
if len(X.shape) == 2:
X_sqnorms = np.einsum('...i,...i', X, X)
Y_sqnorms = np.einsum('...i,...i', Y, Y)
XY = np.einsum('ia,ja', X, Y)
elif len(X.shape) == 3:
X_sqnorms = np.einsum('...ij,...ij', X, X)
Y_sqnorms = np.einsum('...ij,...ij', Y, Y)
XY = np.einsum('iab,jab', X, Y)
else:
pdb.set_trace()
Kxy = np.exp(-gamma*(X_sqnorms.reshape(-1, 1) - 2*XY + Y_sqnorms.reshape(1, -1)))
return Kxy
def MMD_3_Sample_Test(X, Y, Z, sigma=-1, SelectSigma=True, computeMMDs=False):
'''Performs the relative MMD test which returns a test statistic for whether Y is closer to X or than Z.
See http://arxiv.org/pdf/1511.04581.pdf
The bandwith heuristic is based on the median heuristic (see Smola,Gretton).
'''
if(sigma<0):
#Similar heuristics
if SelectSigma:
siz=np.min((1000, X.shape[0]))
sigma1=kernelwidthPair(X[0:siz], Y[0:siz]);
sigma2=kernelwidthPair(X[0:siz], Z[0:siz]);
sigma=(sigma1+sigma2)/2.
else:
siz=np.min((1000, X.shape[0]*3))
Zem=np.r_[X[0:siz/3], Y[0:siz/3], Z[0:siz/3]]
sigma=kernelwidth(Zem);
#kernel = partial(rbf_kernel, gamma=1.0/(sigma**2))
kernel = partial(my_kernel, sigma=sigma)
#kernel = partial(grbf, sigma=sigma)
Kyy = kernel(Y, Y)
Kzz = kernel(Z, Z)
Kxy = kernel(X, Y)
Kxz = kernel(X, Z)
Kyynd = Kyy-np.diag(np.diagonal(Kyy))
Kzznd = Kzz-np.diag(np.diagonal(Kzz))
m = Kxy.shape[0];
n = Kyy.shape[0];
r = Kzz.shape[0];
u_yy=np.sum(Kyynd)*( 1./(n*(n-1)) )
u_zz=np.sum(Kzznd)*( 1./(r*(r-1)) )
u_xy=np.sum(Kxy)/(m*n)
u_xz=np.sum(Kxz)/(m*r)
#Compute the test statistic
t=u_yy - 2.*u_xy - (u_zz-2.*u_xz)
Diff_Var, Diff_Var_z2, data=MMD_Diff_Var(Kyy, Kzz, Kxy, Kxz)
pvalue=sp.stats.norm.cdf(-t/np.sqrt((Diff_Var)))
# pvalue_z2=sp.stats.norm.cdf(-t/np.sqrt((Diff_Var_z2)))
tstat=t/sqrt(Diff_Var)
if(computeMMDs):
Kxx = kernel(X, X)
Kxxnd = Kxx-np.diag(np.diagonal(Kxx))
u_xx=np.sum(Kxxnd)*( 1./(m*(m-1)) )
MMDXY=u_xx+u_yy-2.*u_xy
MMDXZ=u_xx+u_zz-2.*u_xz
else:
MMDXY=None
MMDXZ=None
return pvalue, tstat, sigma, MMDXY, MMDXZ
def MMD_Diff_Var(Kyy, Kzz, Kxy, Kxz):
'''
Compute the variance of the difference statistic MMDXY-MMDXZ
See http://arxiv.org/pdf/1511.04581.pdf Appendix for derivations
'''
m = Kxy.shape[0];
n = Kyy.shape[0];
r = Kzz.shape[0];
Kyynd = Kyy-np.diag(np.diagonal(Kyy));
Kzznd = Kzz-np.diag(np.diagonal(Kzz));
u_yy=np.sum(Kyynd)*( 1./(n*(n-1)) );
u_zz=np.sum(Kzznd)*( 1./(r*(r-1)) );
u_xy=np.sum(Kxy)/(m*n);
u_xz=np.sum(Kxz)/(m*r);
#compute zeta1
t1=(1./n**3)*np.sum(Kyynd.T.dot(Kyynd))-u_yy**2;
t2=(1./(n**2*m))*np.sum(Kxy.T.dot(Kxy))-u_xy**2;
t3=(1./(n*m**2))*np.sum(Kxy.dot(Kxy.T))-u_xy**2;
t4=(1./r**3)*np.sum(Kzznd.T.dot(Kzznd))-u_zz**2;
t5=(1./(r*m**2))*np.sum(Kxz.dot(Kxz.T))-u_xz**2;
t6=(1./(r**2*m))*np.sum(Kxz.T.dot(Kxz))-u_xz**2;
t7=(1./(n**2*m))*np.sum(Kyynd.dot(Kxy.T))-u_yy*u_xy;
t8=(1./(n*m*r))*np.sum(Kxy.T.dot(Kxz))-u_xz*u_xy;
t9=(1./(r**2*m))*np.sum(Kzznd.dot(Kxz.T))-u_zz*u_xz;
zeta1=(t1+t2+t3+t4+t5+t6-2.*(t7+t8+t9));
zeta2=(1/m/(m-1))*np.sum((Kyynd-Kzznd-Kxy.T-Kxy+Kxz+Kxz.T)**2)-(u_yy - 2.*u_xy - (u_zz-2.*u_xz))**2;
data=dict({'t1':t1,
't2':t2,
't3':t3,
't4':t4,
't5':t5,
't6':t6,
't7':t7,
't8':t8,
't9':t9,
'zeta1':zeta1,
'zeta2':zeta2,
})
#TODO more precise version for zeta2
# xx=(1/m^2)*sum(sum(Kxxnd.*Kxxnd))-u_xx^2;
# yy=(1/n^2)*sum(sum(Kyynd.*Kyynd))-u_yy^2;
#xy=(1/(n*m))*sum(sum(Kxy.*Kxy))-u_xy^2;
#xxy=(1/(n*m^2))*sum(sum(Kxxnd*Kxy))-u_xx*u_xy;
#yyx=(1/(n^2*m))*sum(sum(Kyynd*Kxy'))-u_yy*u_xy;
#zeta2=(xx+yy+xy+xy-2*(xxy+xxy +yyx+yyx))
Var=(4.*(m-2)/(m*(m-1)))*zeta1;
Var_z2=Var+(2./(m*(m-1)))*zeta2;
return Var, Var_z2, data
def grbf(x1, x2, sigma):
'''Calculates the Gaussian radial base function kernel'''
n, nfeatures = x1.shape
m, mfeatures = x2.shape
k1 = np.sum((x1*x1), 1)
q = np.tile(k1, (m, 1)).transpose()
del k1
k2 = np.sum((x2*x2), 1)
r = np.tile(k2.T, (n, 1))
del k2
h = q + r
del q, r
# The norm
h = h - 2*np.dot(x1, x2.transpose())
h = np.array(h, dtype=float)
return np.exp(-1.*h/(2.*pow(sigma, 2)))
def kernelwidthPair(x1, x2):
'''Implementation of the median heuristic. See Gretton 2012
Pick sigma such that the exponent of exp(- ||x-y|| / (2*sigma2)),
in other words ||x-y|| / (2*sigma2), equals 1 for the median distance x
and y of all distances between points from both data sets X and Y.
'''
n, nfeatures = x1.shape
m, mfeatures = x2.shape
k1 = np.sum((x1*x1), 1)
q = np.tile(k1, (m, 1)).transpose()
del k1
k2 = np.sum((x2*x2), 1)
r = np.tile(k2, (n, 1))
del k2
h= q + r
del q, r
# The norm
h = h - 2*np.dot(x1, x2.transpose())
h = np.array(h, dtype=float)
mdist = np.median([i for i in h.flat if i])
sigma = sqrt(mdist/2.0)
if not sigma: sigma = 1
return sigma
def kernelwidth(Zmed):
'''Alternative median heuristic when we cant partition the points
'''
m= Zmed.shape[0]
k1 = np.expand_dims(np.sum((Zmed*Zmed), axis=1), 1)
q = np.kron(np.ones((1, m)), k1)
r = np.kron(np.ones((m, 1)), k1.T)
del k1
h= q + r
del q, r
# The norm
h = h - 2.*Zmed.dot(Zmed.T)
h = np.array(h, dtype=float)
mdist = np.median([i for i in h.flat if i])
sigma = sqrt(mdist/2.0)
if not sigma: sigma = 1
return sigma
def MMD_unbiased(Kxx, Kyy, Kxy):
#The estimate when distribution of x is not equal to y
m = Kxx.shape[0]
n = Kyy.shape[0]
t1 = (1./(m*(m-1)))*np.sum(Kxx - np.diag(np.diagonal(Kxx)))
t2 = (2./(m*n)) * np.sum(Kxy)
t3 = (1./(n*(n-1)))* np.sum(Kyy - np.diag(np.diagonal(Kyy)))
MMDsquared = (t1-t2+t3)
return MMDsquared