added domains to priors

GPy/core/priors.py

@@ -6,19 +6,20 @@ import numpy as np
 import pylab as pb
 from scipy.special import gammaln, digamma
 from ..util.linalg import pdinv
-from GPy.core.domains import UNDEFINED
+from GPy.core.domains import REAL, POSITIVE
+import warnings
 
 class prior:
-    domain = UNDEFINED
-    def pdf(self,x):
+    domain = None
+    def pdf(self, x):
         return np.exp(self.lnpdf(x))
 
     def plot(self):
         rvs = self.rvs(1000)
-        pb.hist(rvs,100,normed=True)
-        xmin,xmax = pb.xlim()
-        xx = np.linspace(xmin,xmax,1000)
-        pb.plot(xx,self.pdf(xx),'r',linewidth=2)
+        pb.hist(rvs, 100, normed=True)
+        xmin, xmax = pb.xlim()
+        xx = np.linspace(xmin, xmax, 1000)
+        pb.plot(xx, self.pdf(xx), 'r', linewidth=2)
 
 
 class Gaussian(prior):
@@ -31,24 +32,24 @@ class Gaussian(prior):
     .. Note:: Bishop 2006 notation is used throughout the code
 
     """
-
-    def __init__(self,mu,sigma):
+    domain = REAL
+    def __init__(self, mu, sigma):
         self.mu = float(mu)
         self.sigma = float(sigma)
         self.sigma2 = np.square(self.sigma)
-        self.constant = -0.5*np.log(2*np.pi*self.sigma2)
+        self.constant = -0.5 * np.log(2 * np.pi * self.sigma2)
 
     def __str__(self):
-        return "N("+str(np.round(self.mu))+', '+str(np.round(self.sigma2))+')'
+        return "N(" + str(np.round(self.mu)) + ', ' + str(np.round(self.sigma2)) + ')'
 
-    def lnpdf(self,x):
-        return self.constant - 0.5*np.square(x-self.mu)/self.sigma2
+    def lnpdf(self, x):
+        return self.constant - 0.5 * np.square(x - self.mu) / self.sigma2
 
-    def lnpdf_grad(self,x):
-        return -(x-self.mu)/self.sigma2
+    def lnpdf_grad(self, x):
+        return -(x - self.mu) / self.sigma2
 
-    def rvs(self,n):
-        return np.random.randn(n)*self.sigma + self.mu
+    def rvs(self, n):
+        return np.random.randn(n) * self.sigma + self.mu
 
 
 class log_Gaussian(prior):
@@ -61,24 +62,24 @@ class log_Gaussian(prior):
     .. Note:: Bishop 2006 notation is used throughout the code
 
     """
-
-    def __init__(self,mu,sigma):
+    domain = POSITIVE
+    def __init__(self, mu, sigma):
         self.mu = float(mu)
         self.sigma = float(sigma)
         self.sigma2 = np.square(self.sigma)
-        self.constant = -0.5*np.log(2*np.pi*self.sigma2)
+        self.constant = -0.5 * np.log(2 * np.pi * self.sigma2)
 
     def __str__(self):
-        return "lnN("+str(np.round(self.mu))+', '+str(np.round(self.sigma2))+')'
+        return "lnN(" + str(np.round(self.mu)) + ', ' + str(np.round(self.sigma2)) + ')'
 
-    def lnpdf(self,x):
-        return self.constant - 0.5*np.square(np.log(x)-self.mu)/self.sigma2 -np.log(x)
+    def lnpdf(self, x):
+        return self.constant - 0.5 * np.square(np.log(x) - self.mu) / self.sigma2 - np.log(x)
 
-    def lnpdf_grad(self,x):
-        return -((np.log(x)-self.mu)/self.sigma2+1.)/x
+    def lnpdf_grad(self, x):
+        return -((np.log(x) - self.mu) / self.sigma2 + 1.) / x
 
-    def rvs(self,n):
-        return np.exp(np.random.randn(n)*self.sigma + self.mu)
+    def rvs(self, n):
+        return np.exp(np.random.randn(n) * self.sigma + self.mu)
 
 
 class multivariate_Gaussian:
@@ -91,47 +92,47 @@ class multivariate_Gaussian:
     .. Note:: Bishop 2006 notation is used throughout the code
 
     """
-
-    def __init__(self,mu,var):
+    domain = REAL
+    def __init__(self, mu, var):
         self.mu = np.array(mu).flatten()
         self.var = np.array(var)
-        assert len(self.var.shape)==2
-        assert self.var.shape[0]==self.var.shape[1]
-        assert self.var.shape[0]==self.mu.size
+        assert len(self.var.shape) == 2
+        assert self.var.shape[0] == self.var.shape[1]
+        assert self.var.shape[0] == self.mu.size
         self.D = self.mu.size
         self.inv, self.hld = pdinv(self.var)
-        self.constant = -0.5*self.D*np.log(2*np.pi) - self.hld
+        self.constant = -0.5 * self.D * np.log(2 * np.pi) - self.hld
 
     def summary(self):
         raise NotImplementedError
 
-    def pdf(self,x):
+    def pdf(self, x):
         return np.exp(self.lnpdf(x))
 
-    def lnpdf(self,x):
-        d = x-self.mu
-        return self.constant - 0.5*np.sum(d*np.dot(d,self.inv),1)
+    def lnpdf(self, x):
+        d = x - self.mu
+        return self.constant - 0.5 * np.sum(d * np.dot(d, self.inv), 1)
 
-    def lnpdf_grad(self,x):
-        d = x-self.mu
-        return -np.dot(self.inv,d)
+    def lnpdf_grad(self, x):
+        d = x - self.mu
+        return -np.dot(self.inv, d)
 
-    def rvs(self,n):
-        return np.random.multivariate_normal(self.mu, self.var,n)
+    def rvs(self, n):
+        return np.random.multivariate_normal(self.mu, self.var, n)
 
     def plot(self):
-        if self.D==2:
+        if self.D == 2:
             rvs = self.rvs(200)
-            pb.plot(rvs[:,0],rvs[:,1], 'kx', mew=1.5)
-            xmin,xmax = pb.xlim()
-            ymin,ymax = pb.ylim()
+            pb.plot(rvs[:, 0], rvs[:, 1], 'kx', mew=1.5)
+            xmin, xmax = pb.xlim()
+            ymin, ymax = pb.ylim()
             xx, yy = np.mgrid[xmin:xmax:100j, ymin:ymax:100j]
-            xflat = np.vstack((xx.flatten(),yy.flatten())).T
-            zz = self.pdf(xflat).reshape(100,100)
-            pb.contour(xx,yy,zz,linewidths=2)
+            xflat = np.vstack((xx.flatten(), yy.flatten())).T
+            zz = self.pdf(xflat).reshape(100, 100)
+            pb.contour(xx, yy, zz, linewidths=2)
 
 
-def gamma_from_EV(E,V):
+def gamma_from_EV(E, V):
     """
     Creates an instance of a gamma prior  by specifying the Expected value(s)
     and Variance(s) of the distribution.
@@ -140,10 +141,10 @@ def gamma_from_EV(E,V):
     :param V: variance
 
     """
-
-    a = np.square(E)/V
-    b = E/V
-    return gamma(a,b)
+    warnings.warn("use Gamma.from_EV to create Gamma Prior", FutureWarning)
+    a = np.square(E) / V
+    b = E / V
+    return gamma(a, b)
 
 class gamma(prior):
     """
@@ -155,33 +156,34 @@ class gamma(prior):
     .. Note:: Bishop 2006 notation is used throughout the code
 
     """
-    def __init__(self,a,b):
+    domain = POSITIVE
+    def __init__(self, a, b):
         self.a = float(a)
         self.b = float(b)
-        self.constant = -gammaln(self.a) + a*np.log(b)
+        self.constant = -gammaln(self.a) + a * np.log(b)
 
     def __str__(self):
-        return "Ga("+str(np.round(self.a))+', '+str(np.round(self.b))+')'
+        return "Ga(" + str(np.round(self.a)) + ', ' + str(np.round(self.b)) + ')'
 
     def summary(self):
-        ret = {"E[x]": self.a/self.b,\
-            "E[ln x]": digamma(self.a) - np.log(self.b),\
-            "var[x]": self.a/self.b/self.b,\
-            "Entropy": gammaln(self.a) - (self.a-1.)*digamma(self.a) - np.log(self.b) + self.a}
-        if self.a >1:
-            ret['Mode'] = (self.a-1.)/self.b
+        ret = {"E[x]": self.a / self.b, \
+            "E[ln x]": digamma(self.a) - np.log(self.b), \
+            "var[x]": self.a / self.b / self.b, \
+            "Entropy": gammaln(self.a) - (self.a - 1.) * digamma(self.a) - np.log(self.b) + self.a}
+        if self.a > 1:
+            ret['Mode'] = (self.a - 1.) / self.b
         else:
             ret['mode'] = np.nan
         return ret
 
-    def lnpdf(self,x):
-        return self.constant + (self.a-1)*np.log(x) - self.b*x
+    def lnpdf(self, x):
+        return self.constant + (self.a - 1) * np.log(x) - self.b * x
 
-    def lnpdf_grad(self,x):
-        return (self.a-1.)/x - self.b
+    def lnpdf_grad(self, x):
+        return (self.a - 1.) / x - self.b
 
-    def rvs(self,n):
-        return np.random.gamma(scale=1./self.b,shape=self.a,size=n)
+    def rvs(self, n):
+        return np.random.gamma(scale=1. / self.b, shape=self.a, size=n)
 
 class inverse_gamma(prior):
     """
@@ -193,19 +195,20 @@ class inverse_gamma(prior):
     .. Note:: Bishop 2006 notation is used throughout the code
 
     """
-    def __init__(self,a,b):
+    domain = POSITIVE
+    def __init__(self, a, b):
         self.a = float(a)
         self.b = float(b)
-        self.constant = -gammaln(self.a) + a*np.log(b)
+        self.constant = -gammaln(self.a) + a * np.log(b)
 
     def __str__(self):
-        return "iGa("+str(np.round(self.a))+', '+str(np.round(self.b))+')'
+        return "iGa(" + str(np.round(self.a)) + ', ' + str(np.round(self.b)) + ')'
 
-    def lnpdf(self,x):
-        return self.constant - (self.a+1)*np.log(x) - self.b/x
+    def lnpdf(self, x):
+        return self.constant - (self.a + 1) * np.log(x) - self.b / x
 
-    def lnpdf_grad(self,x):
-        return -(self.a+1.)/x + self.b/x**2
+    def lnpdf_grad(self, x):
+        return -(self.a + 1.) / x + self.b / x ** 2
 
-    def rvs(self,n):
-        return 1./np.random.gamma(scale=1./self.b,shape=self.a,size=n)
+    def rvs(self, n):
+        return 1. / np.random.gamma(scale=1. / self.b, shape=self.a, size=n)

GPy/core/transformations.py

@@ -3,10 +3,10 @@
 
 
 import numpy as np
-from GPy.core.domains import UNDEFINED, POSITIVE, NEGATIVE, BOUNDED
+from GPy.core.domains import POSITIVE, NEGATIVE, BOUNDED
 
 class transformation(object):
-    domain = UNDEFINED
+    domain = None
     def f(self, x):
         raise NotImplementedError