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Copy pathSimulateBarabasiLazy.py
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SimulateBarabasiLazy.py
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# -*- coding: utf-8 -*-
from __future__ import division #~ Domysle dzielenie int jako liczb float
import ipyparallel as ipp
import numpy as np
def BA_lazy_faz(p):
def simulation(x):
stg = {
'CONST_PRINT' : False, #~ Czy drukowac magnetyzacje co CONST_VERTICES krokow?
'CONST_OVERRIDEN' : False, #~ Czy ma nadpisywac pliki podczas zapisywania wynikow
'CONST_VERTICES' : 10000, #~ Ilosc wezlow
'CONST_SIM_COUNT' : 1, #~ Ilosc powtorzen symulacji
'CONST_SIM_LONG' : 10000, # ile wielkosci N ma liczyc
'CONST_PATH_BASIC_FOLDER' : 'now/complex_networks_sim/Wyniki_barabasi_lazy_fazowe',
'CONST_MODEL' : 'lazy',
'CONST_MODEL_BASIC_VAL' : 'CONST_START_MAGNETIZATION',
'CONST_NETWORK_MODEL' : 'barabasi',
'CONST_BARABASI_m' : 4,
'CONST_START_MAGNETIZATION' : x
}
k = 8
stg['CONST_EDGES'] = int(round(k * stg['CONST_VERTICES'] // 2, 0)) #~ Ilosc polaczen
stg['CONST_MEAN_k'] = round(stg['CONST_EDGES']/stg['CONST_VERTICES']*2, 1)
import sys
sys.path.append('/dmj/fizmed/pkowalczyk/now/complex_networks_sim')
import SimulateClique
result = SimulateClique.jedna_symulacja(stg)
print 'end', k
return simulation
def BA_clique_faz(p):
def simulation(x):
stg = {
'CONST_CLIQUE' : 3, #~ Wielkosc kliki
'CONST_PRINT' : False, #~ Czy drukowac magnetyzacje co CONST_VERTICES krokow?
'CONST_OVERRIDEN' : False, #~ Czy ma nadpisywac pliki podczas zapisywania wynikow
'CONST_VERTICES' : 10000, #~ Ilosc wezlow
'CONST_SIM_COUNT' : 1, #~ Ilosc powtorzen symulacji
'CONST_SIM_LONG' : 20, # ile wielkosci N ma liczyc
'CONST_PATH_BASIC_FOLDER' : 'now/complex_networks_sim/Wyniki_barabasi_clique_fazowe',
'CONST_MODEL' : 'clique',
'CONST_MODEL_BASIC_VAL' : 'CONST_START_MAGNETIZATION',
'CONST_NETWORK_MODEL' : 'barabasi',
'CONST_BARABASI_m' : 4,
'CONST_START_MAGNETIZATION' : x
}
k = 8
stg['CONST_EDGES'] = int(round(k * stg['CONST_VERTICES'] // 2, 0)) #~ Ilosc polaczen
stg['CONST_MEAN_k'] = round(stg['CONST_EDGES']/stg['CONST_VERTICES']*2, 1)
import sys
sys.path.append('/dmj/fizmed/pkowalczyk/now/complex_networks_sim')
import SimulateClique
result = SimulateClique.jedna_symulacja(stg)
print 'end', k
return simulation
def BA_clique_normal(p):
def simulation(x):
stg = {
'CONST_CLIQUE' : 3, #~ Wielkosc kliki
'CONST_PRINT' : False, #~ Czy drukowac magnetyzacje co CONST_VERTICES krokow?
'CONST_OVERRIDEN' : False, #~ Czy ma nadpisywac pliki podczas zapisywania wynikow
'CONST_VERTICES' : 100000, #~ Ilosc wezlow
'CONST_SIM_COUNT' : 1, #~ Ilosc powtorzen symulacji
'CONST_SIM_LONG' : 3, # ile wielkosci N ma liczyc
'CONST_PATH_BASIC_FOLDER' : 'now/complex_networks_sim/Wyniki_barabasi_clique_normal',
'CONST_MODEL' : 'clique',
'CONST_MODEL_BASIC_VAL' : 'CONST_BARABASI_m',
'CONST_NETWORK_MODEL' : 'barabasi',
'CONST_BARABASI_m' : x,
# 'CONST_START_MAGNETIZATION' : 0.5
}
k = x*2
stg['CONST_EDGES'] = int(round(k * stg['CONST_VERTICES'] // 2, 0)) #~ Ilosc polaczen
stg['CONST_MEAN_k'] = round(stg['CONST_EDGES']/stg['CONST_VERTICES']*2, 1)
import sys
sys.path.append('/dmj/fizmed/pkowalczyk/now/complex_networks_sim')
import SimulateClique
result = SimulateClique.jedna_symulacja(stg)
print 'end', k
return simulation
def main():
clients = ipp.Client()
dview = clients.load_balanced_view()
tasks = [0.5]*500
results = dview.map(BA_lazy_faz(None), tasks)
print list(results)
# results = dview.map(BA_lazy_faz(None), [0.05, 0.1, 0.15, 0.2, 0.25, 0.3, 0.35, 0.4, 0.45, 0.5]*8)
# print list(results)
# results = dview.map(BA_clique_faz(None), [0.05, 0.1, 0.15, 0.2, 0.25, 0.3, 0.35, 0.4, 0.45, 0.5]*8)
# print list(results)
print 'Koniec Programu'
if __name__ == '__main__':
main()