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# -*- coding: utf-8 -*-
"""
Optimization algorithms for OT
"""
import numpy as np
import scipy as sp
from scipy.optimize.linesearch import scalar_search_armijo
from .lp import emd
# The corresponding scipy function does not work for matrices
def line_search_armijo(f,xk,pk,gfk,old_fval,args=(),c1=1e-4,alpha0=0.99):
"""
Armijo linesearch function that works with matrices
find an approximate minimum of f(xk+alpha*pk) that satifies the
armijo conditions.
Parameters
----------
f : function
loss function
xk : np.ndarray
initial position
pk : np.ndarray
descent direction
gfk : np.ndarray
gradient of f at xk
old_fval: float
loss value at xk
args : tuple, optional
arguments given to f
c1 : float, optional
c1 const in armijo rule (>0)
alpha0 : float, optional
initial step (>0)
Returns
-------
alpha : float
step that satisfy armijo conditions
fc : int
nb of function call
fa : float
loss value at step alpha
"""
xk = np.atleast_1d(xk)
fc = [0]
def phi(alpha1):
fc[0] += 1
return f(xk + alpha1*pk, *args)
if old_fval is None:
phi0 = phi(0.)
else:
phi0 = old_fval
derphi0 = np.sum(pk*gfk) # Quickfix for matrices
alpha,phi1 = scalar_search_armijo(phi,phi0,derphi0,c1=c1,alpha0=alpha0)
return alpha,fc[0],phi1
def cg(a,b,M,reg,f,df,G0=None,numItermax = 200,stopThr=1e-9,verbose=False,log=False):
"""
Solve the general regularized OT problem with conditional gradient
The function solves the following optimization problem:
.. math::
\gamma = arg\min_\gamma <\gamma,M>_F + reg*f(\gamma)
s.t. \gamma 1 = a
\gamma^T 1= b
\gamma\geq 0
where :
- M is the (ns,nt) metric cost matrix
- :math:`f` is the regularization term ( and df is its gradient)
- a and b are source and target weights (sum to 1)
The algorithm used for solving the problem is conditional gradient as discussed in [1]_
Parameters
----------
a : np.ndarray (ns,)
samples weights in the source domain
b : np.ndarray (nt,)
samples in the target domain
M : np.ndarray (ns,nt)
loss matrix
reg : float
Regularization term >0
G0 : np.ndarray (ns,nt), optional
initial guess (default is indep joint density)
numItermax : int, optional
Max number of iterations
stopThr : float, optional
Stop threshol on error (>0)
verbose : bool, optional
Print information along iterations
log : bool, optional
record log if True
Returns
-------
gamma: (ns x nt) ndarray
Optimal transportation matrix for the given parameters
log: dict
log dictionary return only if log==True in parameters
References
----------
.. [1] Ferradans, S., Papadakis, N., Peyré, G., & Aujol, J. F. (2014). Regularized discrete optimal transport. SIAM Journal on Imaging Sciences, 7(3), 1853-1882.
See Also
--------
ot.lp.emd : Unregularized optimal ransport
ot.bregman.sinkhorn : Entropic regularized optimal transport
"""
loop=1
if log:
log={'loss':[]}
if G0 is None:
G=np.outer(a,b)
else:
G=G0
def cost(G):
return np.sum(M*G)+reg*f(G)
f_val=cost(G)
if log:
log['loss'].append(f_val)
it=0
if verbose:
print('{:5s}|{:12s}|{:8s}'.format('It.','Loss','Delta loss')+'\n'+'-'*32)
print('{:5d}|{:8e}|{:8e}'.format(it,f_val,0))
while loop:
it+=1
old_fval=f_val
# problem linearization
Mi=M+reg*df(G)
# solve linear program
Gc=emd(a,b,Mi)
deltaG=Gc-G
# line search
alpha,fc,f_val = line_search_armijo(cost,G,deltaG,Mi,f_val)
G=G+alpha*deltaG
# test convergence
if it>=numItermax:
loop=0
delta_fval=(f_val-old_fval)/abs(f_val)
if abs(delta_fval)<stopThr:
loop=0
if log:
log['loss'].append(f_val)
if verbose:
if it%20 ==0:
print('{:5s}|{:12s}|{:8s}'.format('It.','Loss','Delta loss')+'\n'+'-'*32)
print('{:5d}|{:8e}|{:8e}'.format(it,f_val,delta_fval))
if log:
return G,log
else:
return G
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