Changes in / [b093c1c:c6084f1] in sasmodels


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Location:
sasmodels
Files:
4 edited

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Removed

  • sasmodels/jitter.py

    r7d97437 r1198f90  
    1515    pass 
    1616 
    17 import matplotlib as mpl 
    1817import matplotlib.pyplot as plt 
    1918from matplotlib.widgets import Slider 
     
    747746        pass 
    748747 
    749     # CRUFT: use axisbg instead of facecolor for matplotlib<2 
    750     facecolor_prop = 'facecolor' if mpl.__version__ > '2' else 'axisbg' 
    751     props = {facecolor_prop: 'lightgoldenrodyellow'} 
     748    axcolor = 'lightgoldenrodyellow' 
    752749 
    753750    ## add control widgets to plot 
    754     axes_theta = plt.axes([0.1, 0.15, 0.45, 0.04], **props) 
    755     axes_phi = plt.axes([0.1, 0.1, 0.45, 0.04], **props) 
    756     axes_psi = plt.axes([0.1, 0.05, 0.45, 0.04], **props) 
     751    axes_theta = plt.axes([0.1, 0.15, 0.45, 0.04], axisbg=axcolor) 
     752    axes_phi = plt.axes([0.1, 0.1, 0.45, 0.04], axisbg=axcolor) 
     753    axes_psi = plt.axes([0.1, 0.05, 0.45, 0.04], axisbg=axcolor) 
    757754    stheta = Slider(axes_theta, 'Theta', -90, 90, valinit=theta) 
    758755    sphi = Slider(axes_phi, 'Phi', -180, 180, valinit=phi) 
    759756    spsi = Slider(axes_psi, 'Psi', -180, 180, valinit=psi) 
    760757 
    761     axes_dtheta = plt.axes([0.75, 0.15, 0.15, 0.04], **props) 
    762     axes_dphi = plt.axes([0.75, 0.1, 0.15, 0.04], **props) 
    763     axes_dpsi = plt.axes([0.75, 0.05, 0.15, 0.04], **props) 
     758    axes_dtheta = plt.axes([0.75, 0.15, 0.15, 0.04], axisbg=axcolor) 
     759    axes_dphi = plt.axes([0.75, 0.1, 0.15, 0.04], axisbg=axcolor) 
     760    axes_dpsi = plt.axes([0.75, 0.05, 0.15, 0.04], axisbg=axcolor) 
    764761    # Note: using ridiculous definition of rectangle distribution, whose width 
    765762    # in sasmodels is sqrt(3) times the given width.  Divide by sqrt(3) to keep 

  • sasmodels/kernelcl.py

    rf31815d rd86f0fc  
    5656import time 
    5757 
    58 try: 
    59     from time import perf_counter as clock 
    60 except ImportError: # CRUFT: python < 3.3 
    61     import sys 
    62     if sys.platform.count("darwin") > 0: 
    63         from time import time as clock 
    64     else: 
    65         from time import clock 
    66  
    6758import numpy as np  # type: ignore 
     59 
    6860 
    6961# Attempt to setup opencl. This may fail if the opencl package is not 
     
    583575        # Call kernel and retrieve results 
    584576        wait_for = None 
    585         last_nap = clock() 
     577        last_nap = time.clock() 
    586578        step = 1000000//self.q_input.nq + 1 
    587579        for start in range(0, call_details.num_eval, step): 
     
    594586                # Allow other processes to run 
    595587                wait_for[0].wait() 
    596                 current_time = clock() 
     588                current_time = time.clock() 
    597589                if current_time - last_nap > 0.5: 
    598590                    time.sleep(0.05) 

  • sasmodels/resolution.py

    re2592f0 r9e7837a  
    445445    q = np.sort(q) 
    446446    if q_min + 2*MINIMUM_RESOLUTION < q[0]: 
    447         n_low = int(np.ceil((q[0]-q_min) / (q[1]-q[0]))) if q[1] > q[0] else 15 
     447        n_low = np.ceil((q[0]-q_min) / (q[1]-q[0])) if q[1] > q[0] else 15 
    448448        q_low = np.linspace(q_min, q[0], n_low+1)[:-1] 
    449449    else: 
    450450        q_low = [] 
    451451    if q_max - 2*MINIMUM_RESOLUTION > q[-1]: 
    452         n_high = int(np.ceil((q_max-q[-1]) / (q[-1]-q[-2]))) if q[-1] > q[-2] else 15 
     452        n_high = np.ceil((q_max-q[-1]) / (q[-1]-q[-2])) if q[-1] > q[-2] else 15 
    453453        q_high = np.linspace(q[-1], q_max, n_high+1)[1:] 
    454454    else: 
     
    499499            q_min = q[0]*MINIMUM_ABSOLUTE_Q 
    500500        n_low = log_delta_q * (log(q[0])-log(q_min)) 
    501         q_low = np.logspace(log10(q_min), log10(q[0]), int(np.ceil(n_low))+1)[:-1] 
     501        q_low = np.logspace(log10(q_min), log10(q[0]), np.ceil(n_low)+1)[:-1] 
    502502    else: 
    503503        q_low = [] 
    504504    if q_max > q[-1]: 
    505505        n_high = log_delta_q * (log(q_max)-log(q[-1])) 
    506         q_high = np.logspace(log10(q[-1]), log10(q_max), int(np.ceil(n_high))+1)[1:] 
     506        q_high = np.logspace(log10(q[-1]), log10(q_max), np.ceil(n_high)+1)[1:] 
    507507    else: 
    508508        q_high = [] 

  • sasmodels/weights.py

    re2592f0 r3d58247  
    2323    default = dict(npts=35, width=0, nsigmas=3) 
    2424    def __init__(self, npts=None, width=None, nsigmas=None): 
    25         self.npts = self.default['npts'] if npts is None else int(npts) 
     25        self.npts = self.default['npts'] if npts is None else npts 
    2626        self.width = self.default['width'] if width is None else width 
    2727        self.nsigmas = self.default['nsigmas'] if nsigmas is None else nsigmas 
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