1 | import matplotlib.pyplot as plt |
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2 | from mpl_toolkits.mplot3d import axes3d |
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3 | import numpy as np |
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4 | import os |
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5 | import sys |
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6 | |
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7 | def wykres(threadsy,capacitiesy,wyniki,iteracje,atrybut): |
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8 | kolory=['red','green','blue'] |
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9 | alfy=[0.1,0.1,0.8] |
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10 | fig = plt.figure() |
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11 | ax = fig.add_subplot(111, projection='3d') |
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12 | ax.view_init(30,-150) |
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13 | for i,iteracja in enumerate(iteracje): |
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14 | X, Y = np.meshgrid(threadsy, capacitiesy) #X,Y are arrays of same size, 2D, with separated indexes |
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15 | Z=np.empty(X.shape) |
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16 | Z.fill(np.nan) #instead of nan, one could set -10 to clearly see on the plot which values are missing |
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17 | for wynik in wyniki: |
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18 | threads,capacity,slownik=wynik |
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19 | if slownik['iter']==iteracja: |
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20 | print threads,capacity,slownik[atrybut] if atrybut in slownik else np.nan |
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21 | threadsindex=threadsy.index(threads) |
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22 | capacitiesindex=capacitiesy.index(capacity) |
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23 | Z[capacitiesindex,threadsindex]=slownik[atrybut] if atrybut in slownik else np.nan |
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24 | print Z |
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25 | ktore=len(kolory)-len(iteracje)+i |
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26 | ax.plot_surface(X, Y, Z, rstride=1, cstride=1, color=kolory[ktore], linewidth=1, alpha=alfy[ktore],edgecolor=(0,0,0,alfy[ktore])) |
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27 | ax.set_xlabel('threads') |
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28 | ax.set_ylabel('capacity') |
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29 | ax.set_zlabel(atrybut) |
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30 | ax.set_xticks(threadsy) |
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31 | ax.set_yticks(capacitiesy) |
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32 | ax.set_zlim((0,ax.get_zlim()[1])) #scale from (forced) zero to auto |
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33 | plt.savefig("wykres_%d_%s.png" % (iteracja,atrybut)) |
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34 | #plt.show() #if you wanted to rotate the chart interactively |
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35 | plt.close() |
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36 | |
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37 | |
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38 | |
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39 | |
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40 | |
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41 | ####################################################### main ####################################################### |
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42 | |
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43 | threadsy=set() #used to store values of 'threads' that are in use. This is helpful because later a single multi-dimensional numpy array is used to keep all results |
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44 | capacitiesy=set() #used to store values of 'capacity' that are in use |
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45 | wyniki=[] #list of all results |
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46 | |
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47 | os.chdir(sys.argv[1]) #files with plots will also be created in that directory |
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48 | for plik in os.listdir('.'): |
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49 | if plik.endswith(".out") and plik.count('_')==2: |
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50 | podzielone=plik.replace('.','_').split('_') |
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51 | threads=int(podzielone[1]) |
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52 | capacity=int(podzielone[2]) |
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53 | threadsy.add(threads) |
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54 | capacitiesy.add(capacity) |
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55 | plik = open("test_%d_%d.out" % (threads,capacity), "r") #should be the same name as the original file |
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56 | slowniki = [] |
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57 | for linia in plik: |
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58 | linia=linia.strip() |
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59 | if linia.startswith("[INFO] Script::Message - iter="): |
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60 | slownik={} |
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61 | for pole in linia.split(' '): |
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62 | if '=' in pole: |
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63 | pole=pole.strip(',') |
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64 | pole=pole.split('=') |
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65 | slownik[pole[0]]=float(pole[1]) |
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66 | print slownik |
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67 | slowniki.append(slownik) |
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68 | wyniki.append((threads,capacity,slownik)) |
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69 | plik.close() |
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70 | |
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71 | threadsy=sorted(list(threadsy)) |
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72 | capacitiesy=sorted(list(capacitiesy)) |
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73 | print threadsy |
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74 | print capacitiesy |
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75 | |
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76 | wykres(threadsy,capacitiesy,wyniki,[3.0,6.0,9.0],'simsteps') |
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77 | wykres(threadsy,capacitiesy,wyniki,[3.0,6.0,9.0],'evals') |
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78 | wykres(threadsy,capacitiesy,wyniki,[3.0,6.0,9.0],'migrations') |
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79 | wykres(threadsy,capacitiesy,wyniki,[4.0,9.0],'fit_avg') |
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80 | wykres(threadsy,capacitiesy,wyniki,[4.0,9.0],'fit_max') |
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81 | |
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82 | #draws simple 2D plots of progress in consecutive iter's: |
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83 | #x=[] |
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84 | #y1=[] |
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85 | #y2=[] |
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86 | #for s in slowniki: |
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87 | # x.append(s['iter']) |
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88 | # y1.append(s['avg_fit']) |
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89 | # y2.append(s['max_fit']) |
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90 | #plt.plot(x,y1) |
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91 | #plt.plot(x,y2) |
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92 | #plt.savefig("avg_%d_%d.png" % (threads,capacity)) |
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93 | #plt.close() |
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94 | |
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