Fixed integrator to stop at exactly the right distance

python/_project.pyx

@@ -600,14 +600,11 @@ def tophat_fourier(x not None):
 
 @cython.boundscheck(False)
 @cython.cdivision(True)
-cdef DTYPE_t cube_integral(DTYPE_t u[3], DTYPE_t u0[3], int r[1]) nogil:
+cdef DTYPE_t cube_integral(DTYPE_t u[3], DTYPE_t u0[3], int r[1], DTYPE_t alpha_max) nogil:
-    cdef DTYPE_t alpha_max
     cdef DTYPE_t tmp_a
     cdef DTYPE_t v[3]
     cdef int i, j
 
-    alpha_max = 10.0 # A big number
-
     for i in xrange(3):
         if u[i] == 0.:
             continue
@@ -630,14 +627,11 @@ cdef DTYPE_t cube_integral(DTYPE_t u[3], DTYPE_t u0[3], int r[1]) nogil:
 
 @cython.boundscheck(False)
 @cython.cdivision(True)
-cdef DTYPE_t cube_integral_trilin(DTYPE_t u[3], DTYPE_t u0[3], int r[1], DTYPE_t vertex_value[8]) nogil:
+cdef DTYPE_t cube_integral_trilin(DTYPE_t u[3], DTYPE_t u0[3], int r[1], DTYPE_t vertex_value[8], DTYPE_t alpha_max) nogil:
-    cdef DTYPE_t alpha_max
     cdef DTYPE_t I, tmp_a
     cdef DTYPE_t v[3], term[4]
     cdef int i, j, q
 
-    alpha_max = 10.0 # A big number
-
     j = 0
     for i in range(3):
         if u[i] == 0.:
@@ -665,16 +659,16 @@ cdef DTYPE_t cube_integral_trilin(DTYPE_t u[3], DTYPE_t u0[3], int r[1], DTYPE_t
 
 @cython.boundscheck(False)
 cdef DTYPE_t integrator0(DTYPE_t[:,:,:] density,
-                         DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1]) nogil:
+                         DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1], DTYPE_t alpha_max) nogil:
     cdef DTYPE_t d
     
     d = density[iu0[0], iu0[1], iu0[2]]
     
-    return cube_integral(u, u0, jumper)*d
+    return cube_integral(u, u0, jumper, alpha_max)*d
 
 @cython.boundscheck(False)
 cdef DTYPE_t integrator1(DTYPE_t[:,:,:] density,
-                         DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1]) nogil:
+                         DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1], DTYPE_t alpha_max) nogil:
     cdef DTYPE_t vertex_value[8]
     cdef DTYPE_t d
     cdef int a[3][2], i
@@ -693,7 +687,7 @@ cdef DTYPE_t integrator1(DTYPE_t[:,:,:] density,
     vertex_value[0 + 2*1 + 4*1] = density[a[0][0], a[1][1], a[2][1]]
     vertex_value[1 + 2*1 + 4*1] = density[a[0][1], a[1][1], a[2][1]]
 
-    return cube_integral_trilin(u, u0, jumper, vertex_value)
+    return cube_integral_trilin(u, u0, jumper, vertex_value, alpha_max)
 
 
     
@@ -714,7 +708,7 @@ cdef DTYPE_t C_line_of_sight_projection(DTYPE_t[:,:,:] density,
     cdef int jumper[1]
     
     cdef DTYPE_t (*integrator)(DTYPE_t[:,:,:],
-                               DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1]) nogil
+                               DTYPE_t u[3], DTYPE_t u0[3], int u_delta[3], int iu0[3], int jumper[1], DTYPE_t alpha_max) nogil
 
     if integrator_id == 0:
       integrator = integrator0
@@ -741,16 +735,17 @@ cdef DTYPE_t C_line_of_sight_projection(DTYPE_t[:,:,:] density,
             raise RuntimeError("u0[%d] = %g !" % (i,u0[i]))
 
     completed = 0
-    if ((iu0[0] >= N) or (iu0[0] <= 0) or
+    if ((iu0[0] >= N-1) or (iu0[0] <= 0) or
-        (iu0[1] >= N) or (iu0[1] <= 0) or
+        (iu0[1] >= N-1) or (iu0[1] <= 0) or
-        (iu0[2] >= N) or (iu0[2] <= 0)):
+        (iu0[2] >= N-1) or (iu0[2] <= 0)):
       completed = 1 
 
     I0 = 0
     jumper[0] = 0
+    dist2 = 0
     while completed == 0:
         
-        I0 += integrator(density, u, u0, u_delta, iu0, jumper)
+        I0 += integrator(density, u, u0, u_delta, iu0, jumper, max_distance-sqrt(dist2))
 
         if u[jumper[0]] < 0:
             iu0[jumper[0]] -= 1
@@ -760,9 +755,9 @@ cdef DTYPE_t C_line_of_sight_projection(DTYPE_t[:,:,:] density,
             u0[jumper[0]] = 0
 
             
-        if ((iu0[0] >= N) or (iu0[0] <= 0) or 
+        if ((iu0[0] >= N-1) or (iu0[0] <= 0) or 
-            (iu0[1] >= N) or (iu0[1] <= 0) or
+            (iu0[1] >= N-1) or (iu0[1] <= 0) or
-            (iu0[2] >= N) or (iu0[2] <= 0)):
+            (iu0[2] >= N-1) or (iu0[2] <= 0)):
             completed = 1
         else:
           dist2 = 0
@@ -788,7 +783,7 @@ def line_of_sight_projection(DTYPE_t[:,:,:] density not None,
   u[1] = a_u[1]
   u[2] = a_u[2]
   
-  C_line_of_sight_projection(density,
+  return C_line_of_sight_projection(density,
                              u,
                              min_distance,
                              max_distance, shifter, integrator_id)
@@ -846,10 +841,13 @@ def spherical_projection(int Nside,
         shifter = view.array(shape=(3,), format=FORMAT_DTYPE, itemsize=sizeof(DTYPE_t))
         shifter[:] = 0
         
+    print("allocating map")
     outm_array = np.empty(hp.nside2npix(Nside),dtype=DTYPE)
+    print("initializing views")
     outm = outm_array
     density_view = density
 
+    print("progress?")
     if progress != 0:
       p = pb.ProgressBar(maxval=outm.size,widgets=[pb.Bar(), pb.ETA()]).start()
 
@@ -864,7 +862,7 @@ def spherical_projection(int Nside,
     theta,phi = hp.pix2ang(Nside, np.arange(N0))
     with nogil, parallel():
       tid = smp_get_thread_id()
-      for i in prange(N0):
+      for i in prange(N0,schedule='dynamic',chunksize=256):
           if progress != 0 and (i%booster) == 0:
             with gil:
               p.update(_mysum(job_done))

src/mykdtree.tcc

@@ -280,7 +280,7 @@ namespace CosmoTool {
     coords tmpBound;
     NodeIntType nodeId;
 
-#pragma omp atomic
+#pragma omp atomic capture
     nodeId = (this->lastNode)++;
     
     node = &nodes[nodeId];