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Merge remote-tracking branch 'gpy_real/devel' into merge_branch

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Alan Saul 2013-10-15 10:40:51 +01:00
commit a0aac76812
13 changed files with 700 additions and 132 deletions
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2
GPy/core/model.py
View file

@ -259,7 +259,7 @@ class Model(Parameterized):
these terms are present in the name the parameter is
constrained positive.
"""
positive_strings = ['variance', 'lengthscale', 'precision', 'kappa']
positive_strings = ['variance', 'lengthscale', 'precision', 'decay', 'kappa']
# param_names = self._get_param_names()
currently_constrained = self.all_constrained_indices()
to_make_positive = []

29
GPy/examples/dimensionality_reduction.py
View file

@ -331,27 +331,46 @@ def brendan_faces():
from GPy import kern
data = GPy.util.datasets.brendan_faces()
Q = 2
Y = data['Y'][0:-1:10, :]
# Y = data['Y']
Y = data['Y']
Yn = Y - Y.mean()
Yn /= Yn.std()
m = GPy.models.GPLVM(Yn, Q)
# m = GPy.models.BayesianGPLVM(Yn, Q, num_inducing=100)
# optimize
m.constrain('rbf|noise|white', GPy.core.transformations.logexp_clipped())
m.optimize('scg', messages=1, max_f_eval=10000)
m.optimize('scg', messages=1, max_iters=1000)
ax = m.plot_latent(which_indices=(0, 1))
y = m.likelihood.Y[0, :]
data_show = GPy.util.visualize.image_show(y[None, :], dimensions=(20, 28), transpose=True, invert=False, scale=False)
data_show = GPy.util.visualize.image_show(y[None, :], dimensions=(20, 28), transpose=True, order='F', invert=False, scale=False)
lvm_visualizer = GPy.util.visualize.lvm(m.X[0, :].copy(), m, data_show, ax)
raw_input('Press enter to finish')
return m
def olivetti_faces():
from GPy import kern
data = GPy.util.datasets.olivetti_faces()
Q = 2
Y = data['Y']
Yn = Y - Y.mean()
Yn /= Yn.std()
m = GPy.models.GPLVM(Yn, Q)
m.optimize('scg', messages=1, max_iters=1000)
ax = m.plot_latent(which_indices=(0, 1))
y = m.likelihood.Y[0, :]
data_show = GPy.util.visualize.image_show(y[None, :], dimensions=(112, 92), transpose=False, invert=False, scale=False)
lvm_visualizer = GPy.util.visualize.lvm(m.X[0, :].copy(), m, data_show, ax)
raw_input('Press enter to finish')
return m
def stick_play(range=None, frame_rate=15):
data = GPy.util.datasets.osu_run1()
# optimize
if range == None:

10
GPy/kern/constructors.py
View file

@ -322,17 +322,19 @@ if sympy_available:
real_input_dim -= 1
X = sp.symbols('x_:' + str(real_input_dim))
Z = sp.symbols('z_:' + str(real_input_dim))
variance = sp.var('variance',positive=True)
scale = sp.var('scale_i scale_j',positive=True)
if ARD:
lengthscales = [sp.var('lengthscale%i_i lengthscale%i_j' % i, positive=True) for i in range(real_input_dim)]
dist_string = ' + '.join(['(x_%i-z_%i)**2/(lengthscale%i_i*lengthscale%i_j)' % (i, i, i) for i in range(real_input_dim)])
shared_lengthscales = [sp.var('shared_lengthscale%i' % i, positive=True) for i in range(real_input_dim)]
dist_string = ' + '.join(['(x_%i-z_%i)**2/(shared_lengthscale%i**2 + lengthscale%i_i*lengthscale%i_j)' % (i, i, i) for i in range(real_input_dim)])
dist = parse_expr(dist_string)
f = variance*sp.exp(-dist/2.)
else:
lengthscale = sp.var('lengthscale_i lengthscale_j',positive=True)
lengthscales = sp.var('lengthscale_i lengthscale_j',positive=True)
shared_lengthscale = sp.var('shared_lengthscale',positive=True)
dist_string = ' + '.join(['(x_%i-z_%i)**2' % (i, i) for i in range(real_input_dim)])
dist = parse_expr(dist_string)
f = variance*sp.exp(-dist/(2*lengthscale_i*lengthscale_j))
f = scale_i*scale_j*sp.exp(-dist/(2*(lengthscale_i**2 + lengthscale_j**2 + shared_lengthscale**2)))
return kern(input_dim, [spkern(input_dim, f, output_dim=output_dim, name='eq_sympy')])
def sinc(input_dim, ARD=False, variance=1., lengthscale=1.):

53
GPy/kern/kern.py
View file

@ -79,15 +79,14 @@ class kern(Parameterized):
def plot_ARD(self, fignum=None, ax=None, title='', legend=False):
"""If an ARD kernel is present, it bar-plots the ARD parameters.
"""If an ARD kernel is present, plot a bar representation using matplotlib
:param fignum: figure number of the plot
:param ax: matplotlib axis to plot on
:param title:
title of the plot,
:param title:
title of the plot,
pass '' to not print a title
pass None for a generic title
"""
if ax is None:
fig = pb.figure(fignum)
@ -152,6 +151,13 @@ class kern(Parameterized):
return ax
def _transform_gradients(self, g):
"""
Apply the transformations of the kernel so that the returned vector
represents the gradient in the transformed space (i.e. that given by
get_params_transformed())
:param g: the gradient vector for the current model, usually created by dK_dtheta
"""
x = self._get_params()
[np.put(x, i, x * t.gradfactor(x[i])) for i, t in zip(self.constrained_indices, self.constraints)]
[np.put(g, i, v) for i, v in [(t[0], np.sum(g[t])) for t in self.tied_indices]]
@ -162,7 +168,9 @@ class kern(Parameterized):
return g
def compute_param_slices(self):
"""create a set of slices that can index the parameters of each part."""
"""
Create a set of slices that can index the parameters of each part.
"""
self.param_slices = []
count = 0
for p in self.parts:
@ -170,14 +178,19 @@ class kern(Parameterized):
count += p.num_params
def __add__(self, other):
"""
Shortcut for `add`.
"""
""" Overloading of the '+' operator. for more control, see self.add """
return self.add(other)
def add(self, other, tensor=False):
"""
Add another kernel to this one. Both kernels are defined on the same _space_
Add another kernel to this one.
If Tensor is False, both kernels are defined on the same _space_. then
the created kernel will have the same number of inputs as self and
other (which must be the same).
If Tensor is True, then the dimensions are stacked 'horizontally', so
that the resulting kernel has self.input_dim + other.input_dim
:param other: the other kernel to be added
:type other: GPy.kern
@ -210,9 +223,7 @@ class kern(Parameterized):
return newkern
def __mul__(self, other):
"""
Shortcut for `prod`.
"""
""" Here we overload the '*' operator. See self.prod for more information"""
return self.prod(other)
def __pow__(self, other, tensor=False):
@ -228,7 +239,7 @@ class kern(Parameterized):
:param other: the other kernel to be added
:type other: GPy.kern
:param tensor: whether or not to use the tensor space (default is false).
:type tensor: bool
:type tensor: bool
"""
K1 = self.copy()
@ -307,6 +318,17 @@ class kern(Parameterized):
return sum([[name + '_' + n for n in k._get_param_names()] for name, k in zip(names, self.parts)], [])
def K(self, X, X2=None, which_parts='all'):
"""
Compute the kernel function.
:param X: the first set of inputs to the kernel
:param X2: (optional) the second set of arguments to the kernel. If X2
is None, this is passed throgh to the 'part' object, which
handles this as X2 == X.
:param which_parts: a list of booleans detailing whether to include
each of the part functions. By default, 'all'
indicates [True]*self.num_parts
"""
if which_parts == 'all':
which_parts = [True] * self.num_parts
assert X.shape[1] == self.input_dim
@ -321,7 +343,7 @@ class kern(Parameterized):
def dK_dtheta(self, dL_dK, X, X2=None):
"""
Compute the gradient of the covariance function with respect to the parameters.
:param dL_dK: An array of gradients of the objective function with respect to the covariance function.
:type dL_dK: Np.ndarray (num_samples x num_inducing)
:param X: Observed data inputs
@ -329,6 +351,7 @@ class kern(Parameterized):
:param X2: Observed data inputs (optional, defaults to X)
:type X2: np.ndarray (num_inducing x input_dim)
returns: dL_dtheta
"""
assert X.shape[1] == self.input_dim
target = np.zeros(self.num_params)
@ -340,7 +363,7 @@ class kern(Parameterized):
return self._transform_gradients(target)
def dK_dX(self, dL_dK, X, X2=None):
"""Compute the gradient of the covariance function with respect to X.
"""Compute the gradient of the objective function with respect to X.
:param dL_dK: An array of gradients of the objective function with respect to the covariance function.
:type dL_dK: np.ndarray (num_samples x num_inducing)

2
GPy/kern/parts/hierarchical.py
View file

@ -7,7 +7,7 @@ from independent_outputs import index_to_slices
class Hierarchical(Kernpart):
"""
A kernel part which can reopresent a hierarchy of indepencnce: a gerenalisation of independent_outputs
A kernel part which can reopresent a hierarchy of indepencnce: a generalisation of independent_outputs
"""
def __init__(self,parts):

130
GPy/kern/parts/sympykern.py
View file

@ -43,9 +43,9 @@ class spkern(Kernpart):
assert all([z.name=='z_%i'%i for i,z in enumerate(self._sp_z)])
assert len(self._sp_x)==len(self._sp_z)
self.input_dim = len(self._sp_x)
self._real_input_dim = self.input_dim
if output_dim > 1:
self.input_dim += 1
assert self.input_dim == input_dim
self.output_dim = output_dim
# extract parameter names
@ -117,6 +117,9 @@ class spkern(Kernpart):
return spkern(self._sp_k+other._sp_k)
def _gen_code(self):
"""Generates the C functions necessary for computing the covariance function using the sympy objects as input."""
#TODO: maybe generate one C function only to save compile time? Also easier to take that as a basis and hand craft other covariances??
#generate c functions from sympy objects
argument_sequence = self._sp_x+self._sp_z+self._sp_theta
code_list = [('k',self._sp_k)]
@ -138,30 +141,50 @@ class spkern(Kernpart):
# Substitute any known derivatives which sympy doesn't compute
self._function_code = re.sub('DiracDelta\(.+?,.+?\)','0.0',self._function_code)
# This is the basic argument construction for the C code.
arg_list = (["X[i*input_dim+%s]"%x.name[2:] for x in self._sp_x]
+ ["Z[j*input_dim+%s]"%z.name[2:] for z in self._sp_z])
############################################################
# This is the basic argument construction for the C code. #
############################################################
arg_list = (["X2(i, %s)"%x.name[2:] for x in self._sp_x]
+ ["Z2(j, %s)"%z.name[2:] for z in self._sp_z])
# for multiple outputs need to also provide these arguments reversed.
if self.output_dim>1:
reverse_arg_list = list(arg_list)
reverse_arg_list.reverse()
# Add in any 'shared' parameters to the list.
param_arg_list = [shared_params.name for shared_params in self._sp_theta]
arg_list += param_arg_list
precompute_list=[]
if self.output_dim > 1:
reverse_arg_list+=list(param_arg_list)
split_param_arg_list = ["%s[%s]"%(theta.name[:-2],index) for index in ['ii', 'jj'] for theta in self._sp_theta_i]
split_param_reverse_arg_list = ["%s[%s]"%(theta.name[:-2],index) for index in ['jj', 'ii'] for theta in self._sp_theta_i]
split_param_arg_list = ["%s1(%s)"%(theta.name[:-2].upper(),index) for index in ['ii', 'jj'] for theta in self._sp_theta_i]
split_param_reverse_arg_list = ["%s1(%s)"%(theta.name[:-2].upper(),index) for index in ['jj', 'ii'] for theta in self._sp_theta_i]
arg_list += split_param_arg_list
reverse_arg_list += split_param_reverse_arg_list
precompute_list += [' '*16+"int %s=(int)%s[%s*input_dim+output_dim];"%(index, var, index2) for index, var, index2 in zip(['ii', 'jj'], ['X', 'Z'], ['i', 'j'])]
# Extract the right output indices from the inputs.
c_define_output_indices = [' '*16 + "int %s=(int)%s(%s, %i);"%(index, var, index2, self.input_dim-1) for index, var, index2 in zip(['ii', 'jj'], ['X2', 'Z2'], ['i', 'j'])]
precompute_list += c_define_output_indices
reverse_arg_string = ", ".join(reverse_arg_list)
arg_string = ", ".join(arg_list)
precompute_string = "\n".join(precompute_list)
# Code to compute argments string needed when only X is provided.
X_arg_string = re.sub('Z','X',arg_string)
# Code to compute argument string when only diagonal is required.
diag_arg_string = re.sub('int jj','//int jj',X_arg_string)
diag_arg_string = re.sub('j','i',diag_arg_string)
diag_precompute_string = precompute_list[0]
# Here's the code to do the looping for K
self._K_code =\
"""
// _K_code
// Code for computing the covariance function.
int i;
int j;
int N = target_array->dimensions[0];
@ -171,45 +194,65 @@ class spkern(Kernpart):
for (i=0;i<N;i++){
for (j=0;j<num_inducing;j++){
%s
target[i*num_inducing+j] = k(%s);
//target[i*num_inducing+j] =
TARGET2(i, j) += k(%s);
}
}
%s
"""%(precompute_string,arg_string,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
# Code to compute diagonal of covariance.
diag_arg_string = re.sub('Z','X',arg_string)
diag_arg_string = re.sub('int jj','//int jj',diag_arg_string)
diag_arg_string = re.sub('j','i',diag_arg_string)
diag_precompute_string = re.sub('int jj','//int jj',precompute_string)
diag_precompute_string = re.sub('Z','X',diag_precompute_string)
diag_precompute_string = re.sub('j','i',diag_precompute_string)
self._K_code_X = """
// _K_code_X
// Code for computing the covariance function.
int i;
int j;
int N = target_array->dimensions[0];
int num_inducing = target_array->dimensions[1];
int input_dim = X_array->dimensions[1];
//#pragma omp parallel for private(j)
for (i=0;i<N;i++){
%s // int ii=(int)X2(i, 1);
TARGET2(i, i) += k(%s);
for (j=0;j<i;j++){
%s //int jj=(int)X2(j, 1);
double kval = k(%s); //double kval = k(X2(i, 0), X2(j, 0), shared_lengthscale, LENGTHSCALE1(ii), SCALE1(ii), LENGTHSCALE1(jj), SCALE1(jj));
TARGET2(i, j) += kval;
TARGET2(j, i) += kval;
}
}
/*%s*/
"""%(diag_precompute_string, diag_arg_string, re.sub('Z2', 'X2', precompute_list[1]), X_arg_string,str(self._sp_k)) #adding a string representation forces recompile when needed
# Code to do the looping for Kdiag
self._Kdiag_code =\
"""
// _Kdiag_code
// Code for computing diagonal of covariance function.
int i;
int N = target_array->dimensions[0];
int input_dim = X_array->dimensions[1];
//#pragma omp parallel for
for (i=0;i<N;i++){
%s
target[i] = k(%s);
//target[i] =
TARGET1(i)=k(%s);
}
%s
"""%(diag_precompute_string,diag_arg_string,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
# Code to compute gradients
func_list = []
grad_func_list = []
if self.output_dim>1:
func_list += [' '*16 + "int %s=(int)%s[%s*input_dim+output_dim];"%(index, var, index2) for index, var, index2 in zip(['ii', 'jj'], ['X', 'Z'], ['i', 'j'])]
func_list += [' '*16 + 'target[%i+ii] += partial[i*num_inducing+j]*dk_d%s(%s);'%(self.num_shared_params+i*self.output_dim, theta.name, arg_string) for i, theta in enumerate(self._sp_theta_i)]
func_list += [' '*16 + 'target[%i+jj] += partial[i*num_inducing+j]*dk_d%s(%s);'%(self.num_shared_params+i*self.output_dim, theta.name, reverse_arg_string) for i, theta in enumerate(self._sp_theta_i)]
func_list += ([' '*16 + 'target[%i] += partial[i*num_inducing+j]*dk_d%s(%s);'%(i,theta.name,arg_string) for i,theta in enumerate(self._sp_theta)])
func_string = '\n'.join(func_list)
grad_func_list += c_define_output_indices
grad_func_list += [' '*16 + 'TARGET1(%i+ii) += PARTIAL2(i, j)*dk_d%s(%s);'%(self.num_shared_params+i*self.output_dim, theta.name, arg_string) for i, theta in enumerate(self._sp_theta_i)]
grad_func_list += [' '*16 + 'TARGET1(%i+jj) += PARTIAL2(i, j)*dk_d%s(%s);'%(self.num_shared_params+i*self.output_dim, theta.name, reverse_arg_string) for i, theta in enumerate(self._sp_theta_i)]
grad_func_list += ([' '*16 + 'TARGET1(%i) += PARTIAL2(i, j)*dk_d%s(%s);'%(i,theta.name,arg_string) for i,theta in enumerate(self._sp_theta)])
grad_func_string = '\n'.join(grad_func_list)
self._dK_dtheta_code =\
"""
// _dK_dtheta_code
// Code for computing gradient of covariance with respect to parameters.
int i;
int j;
int N = partial_array->dimensions[0];
@ -222,16 +265,18 @@ class spkern(Kernpart):
}
}
%s
"""%(func_string,"/*"+str(self._sp_k)+"*/") # adding a string representation forces recompile when needed
"""%(grad_func_string,"/*"+str(self._sp_k)+"*/") # adding a string representation forces recompile when needed
# Code to compute gradients for Kdiag TODO: needs clean up
diag_func_string = re.sub('Z','X',func_string,count=0)
diag_func_string = re.sub('int jj','//int jj',diag_func_string)
diag_func_string = re.sub('j','i',diag_func_string)
diag_func_string = re.sub('partial\[i\*num_inducing\+i\]','partial[i]',diag_func_string)
diag_grad_func_string = re.sub('Z','X',grad_func_string,count=0)
diag_grad_func_string = re.sub('int jj','//int jj',diag_grad_func_string)
diag_grad_func_string = re.sub('j','i',diag_grad_func_string)
diag_grad_func_string = re.sub('PARTIAL2\(i, i\)','PARTIAL1(i)',diag_grad_func_string)
self._dKdiag_dtheta_code =\
"""
// _dKdiag_dtheta_code
// Code for computing gradient of diagonal with respect to parameters.
int i;
int N = partial_array->dimensions[0];
int input_dim = X_array->dimensions[1];
@ -239,13 +284,19 @@ class spkern(Kernpart):
%s
}
%s
"""%(diag_func_string,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
"""%(diag_grad_func_string,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
# Code for gradients wrt X
gradient_funcs = "\n".join(["target[i*input_dim+%i] += partial[i*num_inducing+j]*dk_dx%i(%s);"%(q,q,arg_string) for q in range(self.input_dim)])
# Code for gradients wrt X, TODO: may need to deal with special case where one input is actually an output.
gradX_func_list = []
if self.output_dim>1:
gradX_func_list += c_define_output_indices
gradX_func_list += ["TARGET2(i, %i) += PARTIAL2(i, j)*dk_dx_%i(%s);"%(q,q,arg_string) for q in range(self._real_input_dim)]
gradX_func_string = "\n".join(gradX_func_list)
self._dK_dX_code = \
"""
// _dK_dX_code
// Code for computing gradient of covariance with respect to inputs.
int i;
int j;
int N = partial_array->dimensions[0];
@ -258,33 +309,36 @@ class spkern(Kernpart):
}
}
%s
"""%(gradient_funcs,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
"""%(gradX_func_string,"/*"+str(self._sp_k)+"*/") #adding a string representation forces recompile when needed
diag_gradient_funcs = re.sub('Z','X',gradient_funcs,count=0)
diag_gradient_funcs = re.sub('int jj','//int jj',diag_gradient_funcs)
diag_gradient_funcs = re.sub('j','i',diag_gradient_funcs)
diag_gradient_funcs = re.sub('partial\[i\*num_inducing\+i\]','2*partial[i]',diag_gradient_funcs)
diag_gradX_func_string = re.sub('Z','X',gradX_func_string,count=0)
diag_gradX_func_string = re.sub('int jj','//int jj',diag_gradX_func_string)
diag_gradX_func_string = re.sub('j','i',diag_gradX_func_string)
diag_gradX_func_string = re.sub('PARTIAL2\(i, i\)','2*PARTIAL1(i)',diag_gradX_func_string)
# Code for gradients of Kdiag wrt X
self._dKdiag_dX_code= \
"""
// _dKdiag_dX_code
// Code for computing gradient of diagonal with respect to inputs.
int N = partial_array->dimensions[0];
int input_dim = X_array->dimensions[1];
for (int i=0;i<N; i++){
%s
}
%s
"""%(diag_gradient_funcs,"/*"+str(self._sp_k)+"*/") #adding a
"""%(diag_gradX_func_string,"/*"+str(self._sp_k)+"*/") #adding a
# string representation forces recompile when needed Get rid
# of Zs in argument for diagonal. TODO: Why wasn't
# diag_func_string called here? Need to check that.
#self._dKdiag_dX_code = self._dKdiag_dX_code.replace('Z[j', 'X[i')
# Code to use when only X is provided.
self._K_code_X = self._K_code.replace('Z[', 'X[')
self._dK_dtheta_code_X = self._dK_dtheta_code.replace('Z[', 'X[')
self._dK_dX_code_X = self._dK_dX_code.replace('Z[', 'X[').replace('+= partial[', '+= 2*partial[')
self._dK_dtheta_code_X = self._dK_dtheta_code.replace('Z2(', 'X2(')
self._dK_dX_code_X = self._dK_dX_code.replace('Z2(', 'X2(')
#TODO: insert multiple functions here via string manipulation

2
GPy/util/__init__.py
View file

@ -14,3 +14,5 @@ import visualize
import decorators
import classification
import latent_space_visualizations
import netpbmfile

164
GPy/util/datasets.py
View file

@ -8,17 +8,12 @@ import zipfile
import tarfile
import datetime
ipython_notebook = False
if ipython_notebook:
import IPython.core.display
def ipynb_input(varname, prompt=''):
"""Prompt user for input and assign string val to given variable name."""
js_code = ("""
var value = prompt("{prompt}","");
var py_code = "{varname} = '" + value + "'";
IPython.notebook.kernel.execute(py_code);
""").format(prompt=prompt, varname=varname)
return IPython.core.display.Javascript(js_code)
ipython_available=True
try:
import IPython
except ImportError:
ipython_available=False
import sys, urllib
@ -34,8 +29,11 @@ data_path = os.path.join(os.path.dirname(__file__), 'datasets')
default_seed = 10000
overide_manual_authorize=False
neil_url = 'http://staffwww.dcs.shef.ac.uk/people/N.Lawrence/dataset_mirror/'
sam_url = 'http://www.cs.nyu.edu/~roweis/data/'
cmu_url = 'http://mocap.cs.cmu.edu/subjects/'
# Note: there may be a better way of storing data resources. One of the pythonistas will need to take a look.
# Note: there may be a better way of storing data resources, for the
# moment we are storing them in a dictionary.
data_resources = {'ankur_pose_data' : {'urls' : [neil_url + 'ankur_pose_data/'],
'files' : [['ankurDataPoseSilhouette.mat']],
'license' : None,
@ -49,7 +47,7 @@ data_resources = {'ankur_pose_data' : {'urls' : [neil_url + 'ankur_pose_data/'],
'license' : None,
'size' : 51276
},
'brendan_faces' : {'urls' : ['http://www.cs.nyu.edu/~roweis/data/'],
'brendan_faces' : {'urls' : [sam_url],
'files': [['frey_rawface.mat']],
'citation' : 'Frey, B. J., Colmenarez, A and Huang, T. S. Mixtures of Local Linear Subspaces for Face Recognition. Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition 1998, 32-37, June 1998. Computer Society Press, Los Alamitos, CA.',
'details' : """A video of Brendan Frey's face popularized as a benchmark for visualization by the Locally Linear Embedding.""",
@ -93,6 +91,12 @@ The database was created with funding from NSF EIA-0196217.""",
'details' : """Data from the textbook 'A First Course in Machine Learning'. Available from http://www.dcs.gla.ac.uk/~srogers/firstcourseml/.""",
'license' : None,
'size' : 21949154},
'olivetti_faces' : {'urls' : [neil_url + 'olivetti_faces/', sam_url],
'files' : [['att_faces.zip'], ['olivettifaces.mat']],
'citation' : 'Ferdinando Samaria and Andy Harter, Parameterisation of a Stochastic Model for Human Face Identification. Proceedings of 2nd IEEE Workshop on Applications of Computer Vision, Sarasota FL, December 1994',
'details' : """Olivetti Research Labs Face data base, acquired between December 1992 and December 1994 in the Olivetti Research Lab, Cambridge (which later became AT&T Laboratories, Cambridge). When using these images please give credit to AT&T Laboratories, Cambridge. """,
'license': None,
'size' : 8561331},
'olympic_marathon_men' : {'urls' : [neil_url + 'olympic_marathon_men/'],
'files' : [['olympicMarathonTimes.csv']],
'citation' : None,
@ -141,26 +145,41 @@ The database was created with funding from NSF EIA-0196217.""",
'citation' : 'A Global Geometric Framework for Nonlinear Dimensionality Reduction, J. B. Tenenbaum, V. de Silva and J. C. Langford, Science 290 (5500): 2319-2323, 22 December 2000',
'license' : None,
'size' : 24229368},
'xw_pen' : {'urls' : [neil_url + 'xw_pen/'],
'files' : [['xw_pen_15.csv']],
'details' : """Accelerometer pen data used for robust regression by Tipping and Lawrence.""",
'citation' : 'Michael E. Tipping and Neil D. Lawrence. Variational inference for Student-t models: Robust Bayesian interpolation and generalised component analysis. Neurocomputing, 69:123--141, 2005',
'license' : None,
'size' : 3410}
}
def prompt_user():
def prompt_user(prompt):
"""Ask user for agreeing to data set licenses."""
# raw_input returns the empty string for "enter"
yes = set(['yes', 'y'])
no = set(['no','n'])
choice = ''
if ipython_notebook:
ipynb_input(choice, prompt='provide your answer here')
else:
try:
print(prompt)
choice = raw_input().lower()
# would like to test for exception here, but not sure if we can do that without importing IPython
except:
print('Stdin is not implemented.')
print('You need to set')
print('overide_manual_authorize=True')
print('to proceed with the download. Please set that variable and continue.')
raise
if choice in yes:
return True
elif choice in no:
return False
else:
sys.stdout.write("Please respond with 'yes', 'y' or 'no', 'n'")
return prompt_user()
print("Your response was a " + choice)
print("Please respond with 'yes', 'y' or 'no', 'n'")
#return prompt_user()
def data_available(dataset_name=None):
@ -212,15 +231,14 @@ def authorize_download(dataset_name=None):
print('You must also agree to the following license:')
print(dr['license'])
print('')
print('Do you wish to proceed with the download? [yes/no]')
return prompt_user()
return prompt_user('Do you wish to proceed with the download? [yes/no]')
def download_data(dataset_name=None):
"""Check with the user that the are happy with terms and conditions for the data set, then download it."""
dr = data_resources[dataset_name]
if not authorize_download(dataset_name):
return False
raise Exception("Permission to download data set denied.")
if dr.has_key('suffices'):
for url, files, suffices in zip(dr['urls'], dr['files'], dr['suffices']):
@ -489,12 +507,12 @@ def ripley_synth(data_set='ripley_prnn_data'):
return data_details_return({'X': X, 'y': y, 'Xtest': Xtest, 'ytest': ytest, 'info': 'Synthetic data generated by Ripley for a two class classification problem.'}, data_set)
def osu_run1(data_set='osu_run1', sample_every=4):
path = os.path.join(data_path, data_set)
if not data_available(data_set):
download_data(data_set)
zip = zipfile.ZipFile(os.path.join(data_path, data_set, 'run1TXT.ZIP'), 'r')
path = os.path.join(data_path, data_set)
for name in zip.namelist():
zip.extract(name, path)
zip = zipfile.ZipFile(os.path.join(data_path, data_set, 'run1TXT.ZIP'), 'r')
for name in zip.namelist():
zip.extract(name, path)
Y, connect = GPy.util.mocap.load_text_data('Aug210106', path)
Y = Y[0:-1:sample_every, :]
return data_details_return({'Y': Y, 'connect' : connect}, data_set)
@ -579,8 +597,34 @@ def toy_linear_1d_classification(seed=default_seed):
X = (np.r_[x1, x2])[:, None]
return {'X': X, 'Y': sample_class(2.*X), 'F': 2.*X, 'seed' : seed}
def olympic_100m_men(data_set='rogers_girolami_data'):
def olivetti_faces(data_set='olivetti_faces'):
path = os.path.join(data_path, data_set)
if not data_available(data_set):
download_data(data_set)
zip = zipfile.ZipFile(os.path.join(path, 'att_faces.zip'), 'r')
for name in zip.namelist():
zip.extract(name, path)
Y = []
lbls = []
for subject in range(40):
for image in range(10):
image_path = os.path.join(path, 'orl_faces', 's'+str(subject+1), str(image+1) + '.pgm')
Y.append(GPy.util.netpbmfile.imread(image_path).flatten())
lbls.append(subject)
Y = np.asarray(Y)
lbls = np.asarray(lbls)[:, None]
return data_details_return({'Y': Y, 'lbls' : lbls, 'info': "ORL Faces processed to 64x64 images."}, data_set)
def xw_pen(data_set='xw_pen'):
if not data_available(data_set):
download_data(data_set)
Y = np.loadtxt(os.path.join(data_path, data_set, 'xw_pen_15.csv'), delimiter=',')
X = np.arange(485)[:, None]
return data_details_return({'Y': Y, 'X': X, 'info': "Tilt data from a personalized digital assistant pen. Plot in original paper showed regression between time steps 175 and 275."}, data_set)
def download_rogers_girolami_data():
if not data_available('rogers_girolami_data'):
download_data(data_set)
path = os.path.join(data_path, data_set)
tar_file = os.path.join(path, 'firstcoursemldata.tar.gz')
@ -588,6 +632,9 @@ def olympic_100m_men(data_set='rogers_girolami_data'):
print('Extracting file.')
tar.extractall(path=path)
tar.close()
def olympic_100m_men(data_set='rogers_girolami_data'):
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['male100']
X = olympic_data[:, 0][:, None]
@ -595,20 +642,45 @@ def olympic_100m_men(data_set='rogers_girolami_data'):
return data_details_return({'X': X, 'Y': Y, 'info': "Olympic sprint times for 100 m men from 1896 until 2008. Example is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_100m_women(data_set='rogers_girolami_data'):
if not data_available(data_set):
download_data(data_set)
path = os.path.join(data_path, data_set)
tar_file = os.path.join(path, 'firstcoursemldata.tar.gz')
tar = tarfile.open(tar_file)
print('Extracting file.')
tar.extractall(path=path)
tar.close()
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['female100']
X = olympic_data[:, 0][:, None]
Y = olympic_data[:, 1][:, None]
return data_details_return({'X': X, 'Y': Y, 'info': "Olympic sprint times for 100 m women from 1896 until 2008. Example is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_200m_women(data_set='rogers_girolami_data'):
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['female200']
X = olympic_data[:, 0][:, None]
Y = olympic_data[:, 1][:, None]
return data_details_return({'X': X, 'Y': Y, 'info': "Olympic 200 m winning times for women from 1896 until 2008. Data is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_200m_men(data_set='rogers_girolami_data'):
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['male200']
X = olympic_data[:, 0][:, None]
Y = olympic_data[:, 1][:, None]
return data_details_return({'X': X, 'Y': Y, 'info': "Male 200 m winning times for women from 1896 until 2008. Data is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_400m_women(data_set='rogers_girolami_data'):
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['female400']
X = olympic_data[:, 0][:, None]
Y = olympic_data[:, 1][:, None]
return data_details_return({'X': X, 'Y': Y, 'info': "Olympic 400 m winning times for women until 2008. Data is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_400m_men(data_set='rogers_girolami_data'):
download_rogers_girolami_data()
olympic_data = scipy.io.loadmat(os.path.join(data_path, data_set, 'data', 'olympics.mat'))['male400']
X = olympic_data[:, 0][:, None]
Y = olympic_data[:, 1][:, None]
return data_details_return({'X': X, 'Y': Y, 'info': "Male 400 m winning times for women until 2008. Data is from Rogers and Girolami's First Course in Machine Learning."}, data_set)
def olympic_marathon_men(data_set='olympic_marathon_men'):
if not data_available(data_set):
download_data(data_set)
@ -617,6 +689,26 @@ def olympic_marathon_men(data_set='olympic_marathon_men'):
Y = olympics[:, 1:2]
return data_details_return({'X': X, 'Y': Y}, data_set)
def olympics():
"""All olympics sprint winning times for multiple output prediction."""
X = np.zeros((0, 2))
Y = np.zeros((0, 1))
for i, dataset in enumerate([olympic_100m_men,
olympic_100m_women,
olympic_200m_men,
olympic_200m_women,
olympic_400m_men,
olympic_400m_women]):
data = dataset()
year = data['X']
time = data['Y']
X = np.vstack((X, np.hstack((year, np.ones_like(year)*i))))
Y = np.vstack((Y, time))
data['X'] = X
data['Y'] = Y
data['info'] = "Olympics sprint event winning for men and women to 2008. Data is from Rogers and Girolami's First Course in Machine Learning."
return data
# def movielens_small(partNo=1,seed=default_seed):
# np.random.seed(seed=seed)

4
GPy/util/linalg.py
View file

@ -333,6 +333,7 @@ def symmetrify(A, upper=False):
"""
N, M = A.shape
assert N == M
c_contig_code = """
int iN;
for (int i=1; i<N; i++){
@ -351,6 +352,8 @@ def symmetrify(A, upper=False):
}
}
"""
N = int(N) # for safe type casting
if A.flags['C_CONTIGUOUS'] and upper:
weave.inline(f_contig_code, ['A', 'N'], extra_compile_args=['-O3'])
elif A.flags['C_CONTIGUOUS'] and not upper:
@ -411,4 +414,3 @@ def backsub_both_sides(L, X, transpose='left'):
else:
tmp, _ = lapack.dtrtrs(L, np.asfortranarray(X), lower=1, trans=0)
return lapack.dtrtrs(L, np.asfortranarray(tmp.T), lower=1, trans=0)[0].T

20
GPy/util/misc.py
View file

@ -61,7 +61,7 @@ def fast_array_equal(A, B):
int i, j;
return_val = 1;
#pragma omp parallel for private(i, j)
// #pragma omp parallel for private(i, j)
for(i=0;i<N;i++){
for(j=0;j<D;j++){
if(A(i, j) != B(i, j)){
@ -76,7 +76,7 @@ def fast_array_equal(A, B):
int i, j, z;
return_val = 1;
#pragma omp parallel for private(i, j, z)
// #pragma omp parallel for private(i, j, z)
for(i=0;i<N;i++){
for(j=0;j<D;j++){
for(z=0;z<Q;z++){
@ -90,7 +90,7 @@ def fast_array_equal(A, B):
"""
support_code = """
#include <omp.h>
// #include <omp.h>
#include <math.h>
"""
@ -107,15 +107,17 @@ def fast_array_equal(A, B):
return False
elif A.shape == B.shape:
if A.ndim == 2:
N, D = A.shape
value = weave.inline(code2, support_code=support_code, libraries=['gomp'],
N, D = [int(i) for i in A.shape]
value = weave.inline(code2, support_code=support_code,
arg_names=['A', 'B', 'N', 'D'],
type_converters=weave.converters.blitz,**weave_options)
type_converters=weave.converters.blitz)
# libraries=['gomp'], **weave_options)
elif A.ndim == 3:
N, D, Q = A.shape
value = weave.inline(code3, support_code=support_code, libraries=['gomp'],
N, D, Q = [int(i) for i in A.shape]
value = weave.inline(code3, support_code=support_code,
arg_names=['A', 'B', 'N', 'D', 'Q'],
type_converters=weave.converters.blitz,**weave_options)
type_converters=weave.converters.blitz)
#libraries=['gomp'], **weave_options)
else:
value = np.array_equal(A,B)

331
GPy/util/netpbmfile.py Normal file
View file

@ -0,0 +1,331 @@
#!/usr/bin/env python
# -*- coding: utf-8 -*-
# netpbmfile.py
# Copyright (c) 2011-2013, Christoph Gohlke
# Copyright (c) 2011-2013, The Regents of the University of California
# Produced at the Laboratory for Fluorescence Dynamics.
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are met:
#
# * Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# * Redistributions in binary form must reproduce the above copyright
# notice, this list of conditions and the following disclaimer in the
# documentation and/or other materials provided with the distribution.
# * Neither the name of the copyright holders nor the names of any
# contributors may be used to endorse or promote products derived
# from this software without specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
# AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
# IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
# ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
# LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
# CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
# SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
# INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
# CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
# ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
# POSSIBILITY OF SUCH DAMAGE.
"""Read and write image data from respectively to Netpbm files.
This implementation follows the Netpbm format specifications at
http://netpbm.sourceforge.net/doc/. No gamma correction is performed.
The following image formats are supported: PBM (bi-level), PGM (grayscale),
PPM (color), PAM (arbitrary), XV thumbnail (RGB332, read-only).
:Author:
`Christoph Gohlke <http://www.lfd.uci.edu/~gohlke/>`_
:Organization:
Laboratory for Fluorescence Dynamics, University of California, Irvine
:Version: 2013.01.18
Requirements
------------
* `CPython 2.7, 3.2 or 3.3 <http://www.python.org>`_
* `Numpy 1.7 <http://www.numpy.org>`_
* `Matplotlib 1.2 <http://www.matplotlib.org>`_ (optional for plotting)
Examples
--------
>>> im1 = numpy.array([[0, 1],[65534, 65535]], dtype=numpy.uint16)
>>> imsave('_tmp.pgm', im1)
>>> im2 = imread('_tmp.pgm')
>>> assert numpy.all(im1 == im2)
"""
from __future__ import division, print_function
import sys
import re
import math
from copy import deepcopy
import numpy
__version__ = '2013.01.18'
__docformat__ = 'restructuredtext en'
__all__ = ['imread', 'imsave', 'NetpbmFile']
def imread(filename, *args, **kwargs):
"""Return image data from Netpbm file as numpy array.
`args` and `kwargs` are arguments to NetpbmFile.asarray().
Examples
--------
>>> image = imread('_tmp.pgm')
"""
try:
netpbm = NetpbmFile(filename)
image = netpbm.asarray()
finally:
netpbm.close()
return image
def imsave(filename, data, maxval=None, pam=False):
"""Write image data to Netpbm file.
Examples
--------
>>> image = numpy.array([[0, 1],[65534, 65535]], dtype=numpy.uint16)
>>> imsave('_tmp.pgm', image)
"""
try:
netpbm = NetpbmFile(data, maxval=maxval)
netpbm.write(filename, pam=pam)
finally:
netpbm.close()
class NetpbmFile(object):
"""Read and write Netpbm PAM, PBM, PGM, PPM, files."""
_types = {b'P1': b'BLACKANDWHITE', b'P2': b'GRAYSCALE', b'P3': b'RGB',
b'P4': b'BLACKANDWHITE', b'P5': b'GRAYSCALE', b'P6': b'RGB',
b'P7 332': b'RGB', b'P7': b'RGB_ALPHA'}
def __init__(self, arg=None, **kwargs):
"""Initialize instance from filename, open file, or numpy array."""
for attr in ('header', 'magicnum', 'width', 'height', 'maxval',
'depth', 'tupltypes', '_filename', '_fh', '_data'):
setattr(self, attr, None)
if arg is None:
self._fromdata([], **kwargs)
elif isinstance(arg, basestring):
self._fh = open(arg, 'rb')
self._filename = arg
self._fromfile(self._fh, **kwargs)
elif hasattr(arg, 'seek'):
self._fromfile(arg, **kwargs)
self._fh = arg
else:
self._fromdata(arg, **kwargs)
def asarray(self, copy=True, cache=False, **kwargs):
"""Return image data from file as numpy array."""
data = self._data
if data is None:
data = self._read_data(self._fh, **kwargs)
if cache:
self._data = data
else:
return data
return deepcopy(data) if copy else data
def write(self, arg, **kwargs):
"""Write instance to file."""
if hasattr(arg, 'seek'):
self._tofile(arg, **kwargs)
else:
with open(arg, 'wb') as fid:
self._tofile(fid, **kwargs)
def close(self):
"""Close open file. Future asarray calls might fail."""
if self._filename and self._fh:
self._fh.close()
self._fh = None
def __del__(self):
self.close()
def _fromfile(self, fh):
"""Initialize instance from open file."""
fh.seek(0)
data = fh.read(4096)
if (len(data) < 7) or not (b'0' < data[1:2] < b'8'):
raise ValueError("Not a Netpbm file:\n%s" % data[:32])
try:
self._read_pam_header(data)
except Exception:
try:
self._read_pnm_header(data)
except Exception:
raise ValueError("Not a Netpbm file:\n%s" % data[:32])
def _read_pam_header(self, data):
"""Read PAM header and initialize instance."""
regroups = re.search(
b"(^P7[\n\r]+(?:(?:[\n\r]+)|(?:#.*)|"
b"(HEIGHT\s+\d+)|(WIDTH\s+\d+)|(DEPTH\s+\d+)|(MAXVAL\s+\d+)|"
b"(?:TUPLTYPE\s+\w+))*ENDHDR\n)", data).groups()
self.header = regroups[0]
self.magicnum = b'P7'
for group in regroups[1:]:
key, value = group.split()
setattr(self, unicode(key).lower(), int(value))
matches = re.findall(b"(TUPLTYPE\s+\w+)", self.header)
self.tupltypes = [s.split(None, 1)[1] for s in matches]
def _read_pnm_header(self, data):
"""Read PNM header and initialize instance."""
bpm = data[1:2] in b"14"
regroups = re.search(b"".join((
b"(^(P[123456]|P7 332)\s+(?:#.*[\r\n])*",
b"\s*(\d+)\s+(?:#.*[\r\n])*",
b"\s*(\d+)\s+(?:#.*[\r\n])*" * (not bpm),
b"\s*(\d+)\s(?:\s*#.*[\r\n]\s)*)")), data).groups() + (1, ) * bpm
self.header = regroups[0]
self.magicnum = regroups[1]
self.width = int(regroups[2])
self.height = int(regroups[3])
self.maxval = int(regroups[4])
self.depth = 3 if self.magicnum in b"P3P6P7 332" else 1
self.tupltypes = [self._types[self.magicnum]]
def _read_data(self, fh, byteorder='>'):
"""Return image data from open file as numpy array."""
fh.seek(len(self.header))
data = fh.read()
dtype = 'u1' if self.maxval < 256 else byteorder + 'u2'
depth = 1 if self.magicnum == b"P7 332" else self.depth
shape = [-1, self.height, self.width, depth]
size = numpy.prod(shape[1:])
if self.magicnum in b"P1P2P3":
data = numpy.array(data.split(None, size)[:size], dtype)
data = data.reshape(shape)
elif self.maxval == 1:
shape[2] = int(math.ceil(self.width / 8))
data = numpy.frombuffer(data, dtype).reshape(shape)
data = numpy.unpackbits(data, axis=-2)[:, :, :self.width, :]
else:
data = numpy.frombuffer(data, dtype)
data = data[:size * (data.size // size)].reshape(shape)
if data.shape[0] < 2:
data = data.reshape(data.shape[1:])
if data.shape[-1] < 2:
data = data.reshape(data.shape[:-1])
if self.magicnum == b"P7 332":
rgb332 = numpy.array(list(numpy.ndindex(8, 8, 4)), numpy.uint8)
rgb332 *= [36, 36, 85]
data = numpy.take(rgb332, data, axis=0)
return data
def _fromdata(self, data, maxval=None):
"""Initialize instance from numpy array."""
data = numpy.array(data, ndmin=2, copy=True)
if data.dtype.kind not in "uib":
raise ValueError("not an integer type: %s" % data.dtype)
if data.dtype.kind == 'i' and numpy.min(data) < 0:
raise ValueError("data out of range: %i" % numpy.min(data))
if maxval is None:
maxval = numpy.max(data)
maxval = 255 if maxval < 256 else 65535
if maxval < 0 or maxval > 65535:
raise ValueError("data out of range: %i" % maxval)
data = data.astype('u1' if maxval < 256 else '>u2')
self._data = data
if data.ndim > 2 and data.shape[-1] in (3, 4):
self.depth = data.shape[-1]
self.width = data.shape[-2]
self.height = data.shape[-3]
self.magicnum = b'P7' if self.depth == 4 else b'P6'
else:
self.depth = 1
self.width = data.shape[-1]
self.height = data.shape[-2]
self.magicnum = b'P5' if maxval > 1 else b'P4'
self.maxval = maxval
self.tupltypes = [self._types[self.magicnum]]
self.header = self._header()
def _tofile(self, fh, pam=False):
"""Write Netbm file."""
fh.seek(0)
fh.write(self._header(pam))
data = self.asarray(copy=False)
if self.maxval == 1:
data = numpy.packbits(data, axis=-1)
data.tofile(fh)
def _header(self, pam=False):
"""Return file header as byte string."""
if pam or self.magicnum == b'P7':
header = "\n".join((
"P7",
"HEIGHT %i" % self.height,
"WIDTH %i" % self.width,
"DEPTH %i" % self.depth,
"MAXVAL %i" % self.maxval,
"\n".join("TUPLTYPE %s" % unicode(i) for i in self.tupltypes),
"ENDHDR\n"))
elif self.maxval == 1:
header = "P4 %i %i\n" % (self.width, self.height)
elif self.depth == 1:
header = "P5 %i %i %i\n" % (self.width, self.height, self.maxval)
else:
header = "P6 %i %i %i\n" % (self.width, self.height, self.maxval)
if sys.version_info[0] > 2:
header = bytes(header, 'ascii')
return header
def __str__(self):
"""Return information about instance."""
return unicode(self.header)
if sys.version_info[0] > 2:
basestring = str
unicode = lambda x: str(x, 'ascii')
if __name__ == "__main__":
# Show images specified on command line or all images in current directory
from glob import glob
from matplotlib import pyplot
files = sys.argv[1:] if len(sys.argv) > 1 else glob('*.p*m')
for fname in files:
try:
pam = NetpbmFile(fname)
img = pam.asarray(copy=False)
if False:
pam.write('_tmp.pgm.out', pam=True)
img2 = imread('_tmp.pgm.out')
assert numpy.all(img == img2)
imsave('_tmp.pgm.out', img)
img2 = imread('_tmp.pgm.out')
assert numpy.all(img == img2)
pam.close()
except ValueError as e:
print(fname, e)
continue
_shape = img.shape
if img.ndim > 3 or (img.ndim > 2 and img.shape[-1] not in (3, 4)):
img = img[0]
cmap = 'gray' if pam.maxval > 1 else 'binary'
pyplot.imshow(img, cmap, interpolation='nearest')
pyplot.title("%s %s %s %s" % (fname, unicode(pam.magicnum),
_shape, img.dtype))
pyplot.show()

24
GPy/util/symbolic.py
View file

@ -22,9 +22,31 @@ class ln_diff_erf(Function):
class sim_h(Function):
nargs = 5
def fdiff(self, argindex=1):
pass
@classmethod
def eval(cls, t, tprime, d_i, d_j, l):
return exp((d_j/2*l)**2)/(d_i+d_j)*(exp(-d_j*(tprime - t))*(erf((tprime-t)/l - d_j/2*l) + erf(t/l + d_j/2*l)) - exp(-(d_j*tprime + d_i))*(erf(tprime/l - d_j/2*l) + erf(d_j/2*l)))
# putting in the is_Number stuff forces it to look for a fdiff method for derivative.
if (t.is_Number
and tprime.is_Number
and d_i.is_Number
and d_j.is_Number
and l.is_Number):
if (t is S.NaN
or tprime is S.NaN
or d_i is S.NaN
or d_j is S.NaN
or l is S.NaN):
return S.NaN
else:
return (exp((d_j/2*l)**2)/(d_i+d_j)
*(exp(-d_j*(tprime - t))
*(erf((tprime-t)/l - d_j/2*l)
+ erf(t/l + d_j/2*l))
- exp(-(d_j*tprime + d_i))
*(erf(tprime/l - d_j/2*l)
+ erf(d_j/2*l))))
class erfc(Function):
nargs = 1

61
GPy/util/visualize.py
View file

@ -246,17 +246,36 @@ class lvm_dimselect(lvm):
class image_show(matplotlib_show):
"""Show a data vector as an image."""
def __init__(self, vals, axes=None, dimensions=(16,16), transpose=False, invert=False, scale=False, palette=[], presetMean = 0., presetSTD = -1., selectImage=0):
"""Show a data vector as an image. This visualizer rehapes the output vector and displays it as an image.
:param vals: the values of the output to display.
:type vals: ndarray
:param axes: the axes to show the output on.
:type vals: axes handle
:param dimensions: the dimensions that the image needs to be transposed to for display.
:type dimensions: tuple
:param transpose: whether to transpose the image before display.
:type bool: default is False.
:param order: whether array is in Fortan ordering ('F') or Python ordering ('C'). Default is python ('C').
:type order: string
:param invert: whether to invert the pixels or not (default False).
:type invert: bool
:param palette: a palette to use for the image.
:param preset_mean: the preset mean of a scaled image.
:type preset_mean: double
:param preset_std: the preset standard deviation of a scaled image.
:type preset_std: double"""
def __init__(self, vals, axes=None, dimensions=(16,16), transpose=False, order='C', invert=False, scale=False, palette=[], preset_mean = 0., preset_std = -1., select_image=0):
matplotlib_show.__init__(self, vals, axes)
self.dimensions = dimensions
self.transpose = transpose
self.order = order
self.invert = invert
self.scale = scale
self.palette = palette
self.presetMean = presetMean
self.presetSTD = presetSTD
self.selectImage = selectImage # This is used when the y vector contains multiple images concatenated.
self.preset_mean = preset_mean
self.preset_std = preset_std
self.select_image = select_image # This is used when the y vector contains multiple images concatenated.
self.set_image(self.vals)
if not self.palette == []: # Can just show the image (self.set_image() took care of setting the palette)
@ -272,22 +291,22 @@ class image_show(matplotlib_show):
def set_image(self, vals):
dim = self.dimensions[0] * self.dimensions[1]
nImg = np.sqrt(vals[0,].size/dim)
if nImg > 1 and nImg.is_integer(): # Show a mosaic of images
nImg = np.int(nImg)
self.vals = np.zeros((self.dimensions[0]*nImg, self.dimensions[1]*nImg))
for iR in range(nImg):
for iC in range(nImg):
currImgId = iR*nImg + iC
currImg = np.reshape(vals[0,dim*currImgId+np.array(range(dim))], self.dimensions, order='F')
firstRow = iR*self.dimensions[0]
lastRow = (iR+1)*self.dimensions[0]
firstCol = iC*self.dimensions[1]
lastCol = (iC+1)*self.dimensions[1]
self.vals[firstRow:lastRow, firstCol:lastCol] = currImg
num_images = np.sqrt(vals[0,].size/dim)
if num_images > 1 and num_images.is_integer(): # Show a mosaic of images
num_images = np.int(num_images)
self.vals = np.zeros((self.dimensions[0]*num_images, self.dimensions[1]*num_images))
for iR in range(num_images):
for iC in range(num_images):
cur_img_id = iR*num_images + iC
cur_img = np.reshape(vals[0,dim*cur_img_id+np.array(range(dim))], self.dimensions, order=self.order)
first_row = iR*self.dimensions[0]
last_row = (iR+1)*self.dimensions[0]
first_col = iC*self.dimensions[1]
last_col = (iC+1)*self.dimensions[1]
self.vals[first_row:last_row, first_col:last_col] = cur_img
else:
self.vals = np.reshape(vals[0,dim*self.selectImage+np.array(range(dim))], self.dimensions, order='F')
self.vals = np.reshape(vals[0,dim*self.select_image+np.array(range(dim))], self.dimensions, order=self.order)
if self.transpose:
self.vals = self.vals.T
# if not self.scale:
@ -296,8 +315,8 @@ class image_show(matplotlib_show):
self.vals = -self.vals
# un-normalizing, for visualisation purposes:
if self.presetSTD >= 0: # The Mean is assumed to be in the range (0,255)
self.vals = self.vals*self.presetSTD + self.presetMean
if self.preset_std >= 0: # The Mean is assumed to be in the range (0,255)
self.vals = self.vals*self.preset_std + self.preset_mean
# Clipping the values:
self.vals[self.vals < 0] = 0
self.vals[self.vals > 255] = 255