I have a program to do some operations with an array (wavelet transformations and various other complexities), then compare it to the previous array and its properties, output a graph comparing the two, and finally update the 'previous' array to contain this information. Basically my program is starting to get a little long and hard to read, but I can't really split it up into functions because all the functions are reading in and changing the same variables. Without defining all these variables as global everytime I want a function to alter them, it's quite hard.
Then I found this online:
You may have several functions that use the same state variables, either reading or writing them. You are passing a lot of parameters around. You have nested functions that have to forward their parameters to the functions they use. You are tempted to make some module variables to hold the state.
You could make a class instead! All methods of a class have access to all istance data of the class. By storing the shared state in the class, you avoid the need to pass it as parameters to the methods.
So I was wondering how can I adapt my program to be written using classes instead? I can attach my code if it helps, but it's quite long and I don't want to fill up the forum!
Here is the code:
import os, sys, string, math from optparse import OptionParser import numpy as np import pywt import matplotlib.pyplot as plt import matplotlib.mlab as mlab from matplotlib.ticker import MaxNLocator import glob dir = os.getcwd() profiles = glob.glob(dir+"/B0740-28/*_edit.FT.ascii") for x in range(0,len(profiles)): profiles[x] = profiles[x][28:] #produce list of profile file names mode = 'per' wavelets = ['db12'] levels = range(3,4) starts =  fig = 1 ix = 0 #profile index changes = np.zeros(len(profiles)) #array to record shape changes for num_levels in levels: for wavelet in wavelets: for profile in profiles: prof_name = profile.partition('.') #remove file extension pfile=open(dir+'/B0740-28/'+profile) data =  for line in pfile: data.append(float(line)) data = np.array(data) end = len(data) data = np.array(data)/max(data) #get pulse profile and normalise #ignore first 2 lines wav_name = wavelet.partition('.') w = pywt.Wavelet(wavelet) useful = pywt.dwt_max_level(end,w) #find max level of decomposition coeffs = pywt.wavedec(data,wavelet,mode,level=num_levels) #create wavelet coefficients: cAn, cDn, cD(n-1)... cD1 lowpass = pywt.upcoef('a',coeffs,wavelet,level=num_levels,take=end) highpass = np.zeros(end) for x in range(1,(num_levels+1)): highpass += pywt.upcoef('d',coeffs[len(coeffs)-x],wavelet,\ level=x,take=end) #reverse transform by upcoef #define highpass and lowpass components for n in range(0,len(data)): if float(data[n]) > 0.4: value = n starts.append(value) break if profile != profiles: offset = starts- value data = np.roll(data,offset) lowpass = np.roll(lowpass,offset) highpass = np.roll(highpass,offset) #adjust profiles so that they line up if profile == profiles: data_prev = 0 lowpass_prev = 0 highpass_prev = 0 mxm = data.argmax() diff_low = lowpass - lowpass_prev diff_high = highpass - highpass_prev if max(diff_low) >= 0.15 or min(diff_low) <= -0.15: changes[ix] = 1 else: changes[ix] = 0 #significant change? def doPlotting(name,yaxis): plt.plot(name) plt.xlim([mxm-80,mxm+100]) plt.ylabel(yaxis) plt.gca().yaxis.set_major_locator(MaxNLocator(nbins=4)) figure = plt.figure(fig) figure.subplots_adjust(hspace =.5) plt.suptitle('Comparison of Consecutive Profiles') plt.subplot(411); plt.plot(data_prev); \ doPlotting(data,'Data'); plt.ylim(ymax=1.1) plt.subplot(412); plt.plot(lowpass_prev); \ doPlotting(lowpass,'Lowpass'); plt.ylim(ymax=1.1) plt.subplot(413); plt.plot(highpass_prev); doPlotting(highpass,'Highpass') plt.subplot(414); doPlotting(diff_low,'Lowpass\nChange') plotname = 'differences_'+str(ix+1)+'_'+wav_name+'_'+str(num_levels) plt.savefig(dir+'/B0740-28/Plots/'+plotname) #creates plots of two most recent profiles + their decomposition fig += 1 ix += 1 #clears the figure content #increase array index data_prev = data lowpass_prev = lowpass highpass_prev = highpass #reassigns 'previous profile' values figure = plt.figure(fig) plt.plot(changes) plt.title('Lowpass Changes') plt.xlabel('Profile Number') plt.ylabel('Change > Threshold?') plt.ylim(-0.25,1.25) plt.xlim(0,48) plt.savefig(dir+'/B0740-28/Plots/changes') #Save lowpass changes plot