Use more numexpr and pyfftw

python_sample/icgen/cosmogrowth.py

@@ -93,6 +93,9 @@ class LagrangianPerturbation(object):
         if supersample > 1:
           self.upgrade_sampling(supersample)
         self.ik = np.fft.fftfreq(self.N, d=L/self.N)*2*np.pi
+        self._kx = self.ik[:,None,None]
+        self._ky = self.ik[None,:,None]
+        self._kz = self.ik[None,None,:(self.N/2+1)]
         self.cache = {}#weakref.WeakValueDictionary()
 
     def upgrade_sampling(self, supersample):
@@ -111,14 +114,15 @@ class LagrangianPerturbation(object):
         self.cube = CubeFT(self.L, self.N, max_cpu=self.max_cpu)
         
     def _gradient(self, phi, direction):
-        self.cube.dhat = self._kdir(direction)*1j*phi 
+        ne.evaluate('phi_hat * i * kv / (kx**2 + ky**2 + kz**2)', out=self.cube.dhat,
+              local_dict={'i':-1j, 'phi_hat':phi, 'kv':self._kdir(direction),
+                          'kx':self._kx, 'ky':self._ky, 'kz':self._kz}
+#        self.cube.dhat = self._kdir(direction)*1j*phi 
+        self.cube.dhat[0,0,0] = 0
         return self.cube.irfft()
             
     def lpt1(self, direction=0):
-        k2 = self._get_k2()
-        k2[0,0,0] = 1
-    
-        return self._gradient(self.dhat/k2, direction)
+        return self._gradient(self.dhat, direction)
         
     def new_shape(self,direction, q=3, half=False):
         N0 = (self.N/2+1) if half else self.N
@@ -141,20 +145,22 @@ class LagrangianPerturbation(object):
         self.cache['k2'] = k2
         return k2
         
-    def _do_irfft(self, array):
+    def _do_irfft(self, array, copy=True):
+        if copy:
           self.cube.dhat = array
         return self.cube.irfft()
         
-    def _do_rfft(self, array):
+    def _do_rfft(self, array, copy=True):
+        if copy:
           self.cube.density = array
         return self.cube.rfft()
 
     def lpt2(self, direction=0):
-        k2 = self._get_k2()
-        k2[0,0,0] = 1
+#        k2 = self._get_k2()
+#        k2[0,0,0] = 1
 
-        potgen0 = lambda i: ne.evaluate('kdir**2*d/k2',local_dict={'kdir':self._kdir(i),'d':self.dhat,'k2':k2} )
-        potgen = lambda i,j: ne.evaluate('kdir0*kdir1*d/k2',local_dict={'kdir0':self._kdir(i),'kdir1':self._kdir(j),'d':self.dhat,'k2':k2} )
+        potgen0 = lambda i: ne.evaluate('kdir**2*d/k2',out=self.cube.dhat,local_dict={'kdir':self._kdir(i),'d':self.dhat,'k2':k2} )
+        potgen = lambda i,j: ne.evaluate('kdir0*kdir1*d/k2',out=self.cube.dhat,local_dict={'kdir0':self._kdir(i),'kdir1':self._kdir(j),'d':self.dhat,'k2':k2} )
 
         if 'lpt2_potential' not in self.cache:
             print("Rebuilding potential...")
@@ -162,10 +168,14 @@ class LagrangianPerturbation(object):
             for j in xrange(3):
                 q = self._do_irfft( potgen0(j) ).copy()
                 for i in xrange(j+1, 3):
-                    div_phi2 += q * self._do_irfft( potgen0(i) )
-                    div_phi2 -= self._do_irfft(potgen(i,j))**2
+                    ne.evaluate('div + q * pot', out=div_phi2, 
+                          local_dict={'q':q,'pot':self._do_irfft( potgen0(i), copy=False ) } 
+                          )
+                    ne.evaluate('div - pot**2',out=div_phi2,
+                          local_dict={'div':div_phi2,'pot':self._do_irfft(potgen(i,j), copy=False) }
+                          )
 
-            phi2_hat = -self._do_rfft(div_phi2) / k2
+            phi2_hat = self._do_rfft(div_phi2)
             #self.cache['lpt2_potential'] = phi2_hat
             del div_phi2
         else:

python_sample/ksz/gal_prof.py

@@ -6,7 +6,7 @@ from .constants import *
 # -----------------------------------------------------------------------------
 
 class KSZ_Profile(object):
-  R_star= 0.050 # 15 kpc/h 
+  R_star= 0.015 # 15 kpc/h 
   L_gal0 = 10**(0.4*(tmpp_cat['Msun']-tmpp_cat['Mstar']))
 
   def __init__(self):
@@ -17,23 +17,24 @@ class KSZ_Profile(object):
 
   def projected_profile(self, cos_theta,angularDistance):
 
-    idx = np.where(cos_theta > 0)[0]
+    idx_base = idx = np.where(cos_theta > 0)[0]
     tan_theta_2 = 1/(cos_theta[idx]**2) - 1
     tan_theta_2_max = (self.rGalaxy/angularDistance)**2
     tan_theta_2_min = (self.R_star/angularDistance)**2
 
     idx0 = np.where((tan_theta_2 < tan_theta_2_max))
-    idx = idx[idx0]
+    idx = idx_base[idx0]
     tan_theta_2 = tan_theta_2[idx0]
     tan_theta = np.sqrt(tan_theta_2)
 
     r = (tan_theta*angularDistance)
 
     m,idx_mask = self.evaluate_profile(r)
+    idx_mask = idx[idx_mask]
 
-    idx_mask = np.append(idx_mask,np.where(tan_theta_2<tan_theta_2_min)[0])
+    idx_mask = np.append(idx_mask,idx[np.where(tan_theta_2<tan_theta_2_min)[0]])
     if tan_theta_2.size > 0:
-      idx_mask = np.append(idx_mask,[tan_theta_2.argmin()])
+      idx_mask = np.append(idx_mask,idx[tan_theta_2.argmin()])
 
     return idx,idx_mask,m