Pseudovectorisation of plane_pq_y

Former-commit-id: 4af74647f63a2aa4c669244245dfc4b2cf7a3efd
This commit is contained in:
Marek Nečada 2017-07-20 16:42:29 +03:00
parent 2451da7b3e
commit e0b1b3af55
1 changed files with 25 additions and 12 deletions

View File

@ -47,6 +47,7 @@ def ujit(f):
# Coordinate transforms for arrays of "arbitrary" shape # Coordinate transforms for arrays of "arbitrary" shape
#@ujit #@ujit
def cart2sph(cart,axis=-1, allow2d=False): def cart2sph(cart,axis=-1, allow2d=False):
cart = np.array(cart, copy=False)
if cart.shape[axis] == 3: if cart.shape[axis] == 3:
[x, y, z] = np.split(cart,3,axis=axis) [x, y, z] = np.split(cart,3,axis=axis)
r = np.linalg.norm(cart,axis=axis,keepdims=True) r = np.linalg.norm(cart,axis=axis,keepdims=True)
@ -67,6 +68,7 @@ def cart2sph(cart,axis=-1, allow2d=False):
#@ujit #@ujit
def sph2cart(sph, axis=-1): def sph2cart(sph, axis=-1):
sph = np.array(sph, copy=False)
if (sph.shape[axis] != 3): if (sph.shape[axis] != 3):
raise ValueError("The converted array has to have dimension 3" raise ValueError("The converted array has to have dimension 3"
" along the given axis") " along the given axis")
@ -99,6 +101,8 @@ def sph_loccart2cart(loccart, sph, axis=-1):
output: ... TODO output: ... TODO
The coordinates of the vector in global cartesian coordinates The coordinates of the vector in global cartesian coordinates
""" """
loccart = np.array(loccart, copy=False)
sph = np.array(sph, copy=False)
if (loccart.shape[axis] != 3): if (loccart.shape[axis] != 3):
raise ValueError("The converted array has to have dimension 3" raise ValueError("The converted array has to have dimension 3"
" along the given axis") " along the given axis")
@ -462,9 +466,9 @@ def plane_pq_y(nmax, kdir_cart, E_cart):
---------- ----------
nmax: int nmax: int
The order of the expansion. The order of the expansion.
kdir_cart: (3,)-shaped real array kdir_cart: (...,3)-shaped real array
The wave vector (its magnitude does not play a role). The wave vector (its magnitude does not play a role).
E_cart: (3,)-shaped complex array E_cart: (...,3)-shaped complex array
Amplitude of the plane wave Amplitude of the plane wave
Returns Returns
@ -477,21 +481,30 @@ def plane_pq_y(nmax, kdir_cart, E_cart):
warnings.warn("The direction vector for the plane wave coefficients should be real. I am discarding the imaginary part now.") warnings.warn("The direction vector for the plane wave coefficients should be real. I am discarding the imaginary part now.")
kdir_cart = kdir_cart.real kdir_cart = kdir_cart.real
E_cart = np.array(E_cart, copy=False)
k_sph = cart2sph(kdir_cart) k_sph = cart2sph(kdir_cart)
π̃_y, τ̃_y = get_π̃τ̃_y1(k_sph[1], nmax)
my, ny = get_mn_y(nmax) my, ny = get_mn_y(nmax)
nelem = len(my)
U_y = 4*π * 1j**ny / (ny * (ny+1)) U_y = 4*π * 1j**ny / (ny * (ny+1))
θ̂ = sph_loccart2cart(np.array([0,1,0]), k_sph, axis=-1) θ̂ = sph_loccart2cart(np.array([0,1,0]), k_sph, axis=-1)
φ̂ = sph_loccart2cart(np.array([0,0,1]), k_sph, axis=-1) φ̂ = sph_loccart2cart(np.array([0,0,1]), k_sph, axis=-1)
p_y = np.sum( U_y[:,ň]
* np.conj(np.exp(1j*my[:,ň]*k_sph[2]) * ( # not properly vectorised part:
θ̂[ň,:]*τ̃_y[:,ň] + 1j*φ̂[ň,:]*π̃_y[:,ň])) π̃_y = np.empty(k_sph.shape[:-1] + (nelem,), dtype=np.complex_)
* E_cart[ň,:], τ̃_y = np.empty(π̃_y.shape, dtype=np.complex_)
for i in np.ndindex(k_sph.shape[:-1]):
π̃_y[i], τ̃_y[i] = get_π̃τ̃_y1(k_sph[i][1], nmax) # this shit is not vectorised
# last indices of the summands: [...,y,local cartesian component index (of E)]
p_y = np.sum( U_y[...,:,ň]
* np.conj(np.exp(1j*my[...,:,ň]*k_sph[...,ň,ň,2]) * (
θ̂[...,ň,:]*τ̃_y[...,:,ň] + 1j*φ̂[...,ň,:]*π̃_y[...,:,ň]))
* E_cart[...,ň,:],
axis=-1) axis=-1)
q_y = np.sum( U_y[:,ň] q_y = np.sum( U_y[...,:,ň]
* np.conj(np.exp(1j*my[:,ň]*k_sph[2]) * ( * np.conj(np.exp(1j*my[...,:,ň]*k_sph[...,ň,ň,2]) * (
θ̂[ň,:]*π̃_y[:,ň] + 1j*φ̂[ň,:]*τ̃_y[:,ň])) θ̂[...,ň,:]*π̃_y[...,:,ň] + 1j*φ̂[...,ň,:]*τ̃_y[...,:,ň]))
* E_cart[ň,:], * E_cart[...,ň,:],
axis=-1) axis=-1)
return (p_y, q_y) return (p_y, q_y)