Refactored to reduce cyclomatic complexity

master
Per A Brodtkorb 8 years ago
parent 0b983f11e3
commit d8fc854e09

@ -15,11 +15,16 @@ __all__ = [
'StinemanInterp', 'CubicHermiteSpline']
def _check_window_and_order(window_size, order):
def _assert(cond, msg):
if not cond:
raise ValueError(msg)
def _check_window_size(window_size, min_size):
if window_size % 2 != 1 or window_size < 1:
raise TypeError("window_size size must be a positive odd number")
if window_size < order + 2:
raise TypeError("window_size is too small for the polynomials order")
raise TypeError("Window size must be a positive odd number")
if window_size < min_size:
raise TypeError("Window size is too small for the polynomials order")
def savitzky_golay(y, window_size, order, deriv=0):
@ -86,7 +91,7 @@ def savitzky_golay(y, window_size, order, deriv=0):
window_size = np.abs(np.int(window_size))
order = np.abs(np.int(order))
_check_window_and_order(window_size, order)
_check_window_size(window_size, min_size=order + 2)
order_range = range(order + 1)
half_window = (window_size - 1) // 2
# precompute coefficients
@ -213,84 +218,76 @@ def sgolay2d(z, window_size, order, derivative=None):
h=plt.matshow(Zn)
h=plt.matshow(Zf)
"""
def _pad_z(z, size):
# pad input array with appropriate values at the four borders
new_shape = z.shape[0] + 2 * size, z.shape[1] + 2 * size
zout = np.zeros((new_shape))
# top band
band = z[0, :]
zout[:size, size:-size] = band - np.abs(z[size:0:-1, :] - band)
# bottom band
band = z[-1, :]
zout[-size:, size:-size] = band + np.abs(z[-2:-size-2:-1, :] - band)
# left band
band = z[:, 0].reshape(-1, 1)
zout[size:-size, :size] = band - np.abs(z[:, size:0:-1] - band)
# right band
band = z[:, -1].reshape(-1, 1)
zout[size:-size, -size:] = band + np.abs(z[:, -2:-size - 2:-1] - band)
# central band
zout[size:-size, size:-size] = z
# top left corner
band = z[0, 0]
zout[:size, :size] = band - np.abs(z[size:0:-1, :][:, size:0:-1] - band)
# bottom right corner
band = z[-1, -1]
zout[-size:, -size:] = band + np.abs(z[-2:-size - 2:-1, :][:,-2:-size - 2:-1] - band)
# top right corner
band = zout[size, -size:]
zout[:size, -size:] = band - np.abs(zout[2 * size:size:-1, -size:] - band)
# bottom left corner
band = zout[-size:, size].reshape(-1, 1)
zout[-size:, :size] = band - np.abs(zout[-size:, 2 * size:size:-1] - band)
return zout
def _get_sign_and_dims(derivative):
sign = {None:1}.get(derivative, -1)
dims = {None:(0, ), 'col':(1, ), 'row':(2, ), 'both':(1, 2)}[derivative]
return sign, dims
def _build_matrix(order, window_size, size):
# exponents of the polynomial.
# p(x,y) = a0 + a1*x + a2*y + a3*x^2 + a4*y^2 + a5*x*y + ...
# this line gives a list of two item tuple. Each tuple contains
# the exponents of the k-th term. First element of tuple is for x
# second element for y.
# Ex. exps = [(0,0), (1,0), (0,1), (2,0), (1,1), (0,2), ...]
exps = [(k - n, n) for k in range(order + 1) for n in range(k + 1)]
# coordinates of points
ind = np.arange(-size, size + 1, dtype=np.float)
dx = np.repeat(ind, window_size)
dy = np.tile(ind, [window_size, 1]).reshape(window_size ** 2,)
# build matrix of system of equation
A = np.empty((window_size ** 2, len(exps)))
for i, exp in enumerate(exps):
A[:, i] = (dx ** exp[0]) * (dy ** exp[1])
return A
# number of terms in the polynomial expression
n_terms = (order + 1) * (order + 2) / 2.0
if window_size % 2 == 0:
raise ValueError('window_size must be odd')
if window_size ** 2 < n_terms:
raise ValueError('order is too high for the window size')
half_size = window_size // 2
# exponents of the polynomial.
# p(x,y) = a0 + a1*x + a2*y + a3*x^2 + a4*y^2 + a5*x*y + ...
# this line gives a list of two item tuple. Each tuple contains
# the exponents of the k-th term. First element of tuple is for x
# second element for y.
# Ex. exps = [(0,0), (1,0), (0,1), (2,0), (1,1), (0,2), ...]
exps = [(k - n, n) for k in range(order + 1) for n in range(k + 1)]
# coordinates of points
ind = np.arange(-half_size, half_size + 1, dtype=np.float)
dx = np.repeat(ind, window_size)
dy = np.tile(ind, [window_size, 1]).reshape(window_size ** 2,)
# build matrix of system of equation
A = np.empty((window_size ** 2, len(exps)))
for i, exp in enumerate(exps):
A[:, i] = (dx ** exp[0]) * (dy ** exp[1])
# pad input array with appropriate values at the four borders
new_shape = z.shape[0] + 2 * half_size, z.shape[1] + 2 * half_size
Z = np.zeros((new_shape))
# top band
band = z[0, :]
Z[:half_size, half_size:-half_size] = band - \
np.abs(np.flipud(z[1:half_size + 1, :]) - band)
# bottom band
band = z[-1, :]
Z[-half_size:, half_size:-half_size] = band + \
np.abs(np.flipud(z[-half_size - 1:-1, :]) - band)
# left band
band = np.tile(z[:, 0].reshape(-1, 1), [1, half_size])
Z[half_size:-half_size, :half_size] = band - \
np.abs(np.fliplr(z[:, 1:half_size + 1]) - band)
# right band
band = np.tile(z[:, -1].reshape(-1, 1), [1, half_size])
Z[half_size:-half_size, -half_size:] = band + \
np.abs(np.fliplr(z[:, -half_size - 1:-1]) - band)
# central band
Z[half_size:-half_size, half_size:-half_size] = z
# top left corner
band = z[0, 0]
Z[:half_size, :half_size] = band - \
np.abs(
np.flipud(np.fliplr(z[1:half_size + 1, 1:half_size + 1])) - band)
# bottom right corner
band = z[-1, -1]
Z[-half_size:, -half_size:] = band + \
np.abs(
np.flipud(np.fliplr(z[-half_size - 1:-1, -half_size - 1:-1])) - band)
# top right corner
band = Z[half_size, -half_size:]
Z[:half_size, -half_size:] = band - \
np.abs(
np.flipud(Z[half_size + 1:2 * half_size + 1, -half_size:]) - band)
# bottom left corner
band = Z[-half_size:, half_size].reshape(-1, 1)
Z[-half_size:, :half_size] = band - \
np.abs(
np.fliplr(Z[-half_size:, half_size + 1:2 * half_size + 1]) - band)
n_terms = (order + 1) * (order + 2) // 2
_check_window_size(window_size, min_size=np.sqrt(n_terms))
size = window_size // 2 # half_size
mat = _build_matrix(order, window_size, size)
padded_z = _pad_z(z, size)
# solve system and convolve
sgn = {None: 1}.get(derivative, -1)
dims = {None: (0,), 'col': (1,), 'row': (2,), 'both': (1, 2)}[derivative]
res = tuple(fftconvolve(Z, sgn * np.linalg.pinv(A)[i].reshape((window_size, -1)), mode='valid')
sign, dims = _get_sign_and_dims(derivative)
pinv = np.linalg.pinv
shape = window_size, -1
res = tuple(fftconvolve(padded_z, sign * np.reshape(pinv(mat)[i], shape),
mode='valid')
for i in dims)
if len(dims) > 1:
return res
@ -664,7 +661,7 @@ class SmoothSpline(PPform):
ddydx = diff(dydx, axis=0)
# sp.linalg.use_solver(useUmfpack=True)
u = 2 * sparse.linalg.spsolve((QQ + QQ.T), ddydx) # @UndefinedVariable
return u.reshape(n - 2, -1)
return np.reshape(u, (n - 2, -1))
def _edge_case(m0, d1):
@ -853,8 +850,7 @@ def stineman_interp(xi, x, y, yp=None):
# Cast key variables as float.
x = np.asarray(x, np.float_)
y = np.asarray(y, np.float_)
assert x.shape == y.shape
# N = len(y)
_assert(x.shape == y.shape, 'Shapes of x and y must be equal!')
if yp is None:
yp = slopes(x, y)
@ -1003,49 +999,7 @@ class StinemanInterp(object):
self.yp = np.asarray(yp, np.float_)
def __call__(self, xi):
xi = np.asarray(xi, np.float_)
x = self.x
y = self.y
yp = self.yp
# calculate linear slopes
dx = x[1:] - x[:-1]
dy = y[1:] - y[:-1]
s = dy / dx # note length of s is N-1 so last element is #N-2
# find the segment each xi is in
# this line actually is the key to the efficiency of this
# implementation
idx = np.searchsorted(x[1:-1], xi)
# now we have generally: x[idx[j]] <= xi[j] <= x[idx[j]+1]
# except at the boundaries, where it may be that xi[j] < x[0] or xi[j]
# > x[-1]
# the y-values that would come out from a linear interpolation:
sidx = s.take(idx)
xidx = x.take(idx)
yidx = y.take(idx)
xidxp1 = x.take(idx + 1)
yo = yidx + sidx * (xi - xidx)
# the difference that comes when using the slopes given in yp
# using the yp slope of the left point
dy1 = (yp.take(idx) - sidx) * (xi - xidx)
# using the yp slope of the right point
dy2 = (yp.take(idx + 1) - sidx) * (xi - xidxp1)
dy1dy2 = dy1 * dy2
# The following is optimized for Python. The solution actually
# does more calculations than necessary but exploiting the power
# of numpy, this is far more efficient than coding a loop by hand
# in Python
dy1mdy2 = np.where(dy1dy2, dy1 - dy2, np.inf)
dy1pdy2 = np.where(dy1dy2, dy1 + dy2, np.inf)
yi = yo + dy1dy2 * np.choose(
np.array(np.sign(dy1dy2), np.int32) + 1,
((2 * xi - xidx - xidxp1) / ((dy1mdy2) * (xidxp1 - xidx)), 0.0,
1 / (dy1pdy2)))
return yi
return stineman_interp(xi, self.x, self.y, self.yp)
class StinemanInterp2(BPoly):
@ -1335,7 +1289,7 @@ def test_func():
y = pp(x) # @UnusedVariable
x = linspace(0, 2 * pi + pi / 4, 20)
y = sin(x) + np.random.randn(x.size)
y = sin(x) + np.random.randn(np.size(x))
tck = interpolate.splrep(x, y, s=len(x)) # @UndefinedVariable
xnew = linspace(0, 2 * pi, 100)
ynew = interpolate.splev(xnew, tck, der=0) # @UndefinedVariable
@ -1358,7 +1312,6 @@ def test_func():
self = interpolate.ppform.fromspline(*tck2) # @UndefinedVariable
plt.plot(t, self(t))
plt.show('hold')
pass
def test_pp():

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