Soil Tutorial ============= Introduction ------------ This notebook is an introduction to the soil agent-based social network simulation framework. In particular, we will focus on a specific use case: studying the propagation of news in a social network. The steps we will follow are: - Modelling the behavior of agents - Running the simulation using different configurations - Analysing the results of each simulation But before that, let's import the soil module and networkx. .. code:: ipython3 import soil import networkx as nx %load_ext autoreload %autoreload 2 %pylab inline # To display plots in the notebooed_ .. parsed-literal:: Populating the interactive namespace from numpy and matplotlib Basic concepts -------------- There are three main elements in a soil simulation: - The network topology. A simulation may use an existing NetworkX topology, or generate one on the fly - Agents. There are two types: 1) network agents, which are linked to a node in the topology, and 2) environment agents, which are freely assigned to the environment. - The environment. It assigns agents to nodes in the network, and stores the environment parameters (shared state for all agents). Soil is based on ``simpy``, which is an event-based network simulation library. Soil provides several abstractions over events to make developing agents easier. This means you can use events (timeouts, delays) in soil, but for the most part we will assume your models will be step-based. Modeling behaviour ------------------ Our first step will be to model how every person in the social network reacts when it comes to news. We will follow a very simple model (a finite state machine). There are two types of people, those who have heard about a newsworthy event (infected) or those who have not (neutral). A neutral person may heard about the news either on the TV (with probability **prob\_tv\_spread**) or through their friends. Once a person has heard the news, they will spread it to their friends (with a probability **prob\_neighbor\_spread**). Some users do not have a TV, so they only rely on their friends. The spreading probabilities will change over time due to different factors. We will represent this variance using an environment agent. Network Agents ~~~~~~~~~~~~~~ A basic network agent in Soil should inherit from ``soil.agents.BaseAgent``, and define its behaviour in every step of the simulation by implementing a ``run(self)`` method. The most important attributes of the agent are: - ``agent.state``, a dictionary with the state of the agent. ``agent.state['id']`` reflects the state id of the agent. That state id can be used to look for other networks in that specific state. The state can be access via the agent as well. For instance: .. code:: py a = soil.agents.BaseAgent(env=env) a['hours_of_sleep'] = 10 print(a['hours_of_sleep']) The state of the agent is stored in every step of the simulation: ``py print(a['hours_of_sleep', 10]) # hours of sleep before step #10 print(a[None, 0]) # whole state of the agent before step #0`` - ``agent.env``, a reference to the environment. Most commonly used to get access to the environment parameters and the topology: .. code:: py a.env.G.nodes() # Get all nodes ids in the topology a.env['minimum_hours_of_sleep'] Since our model is a finite state machine, we will be basing it on ``soil.agents.FSM``. With ``soil.agents.FSM``, we do not need to specify a ``step`` method. Instead, we describe every step as a function. To change to another state, a function may return the new state. If no state is returned, the state remains unchanged.[ It will consist of two states, ``neutral`` (default) and ``infected``. Here's the code: .. code:: ipython3 import random class NewsSpread(soil.agents.FSM): @soil.agents.default_state @soil.agents.state def neutral(self): r = random.random() if self['has_tv'] and r < self.env['prob_tv_spread']: return self.infected return @soil.agents.state def infected(self): prob_infect = self.env['prob_neighbor_spread'] for neighbor in self.get_neighboring_agents(state_id=self.neutral.id): r = random.random() if r < prob_infect: neighbor.state['id'] = self.infected.id return Environment agents ~~~~~~~~~~~~~~~~~~ Environment agents allow us to control the state of the environment. In this case, we will use an environment agent to simulate a very viral event. When the event happens, the agent will modify the probability of spreading the rumor. .. code:: ipython3 NEIGHBOR_FACTOR = 0.9 TV_FACTOR = 0.5 class NewsEnvironmentAgent(soil.agents.BaseAgent): def step(self): if self.now == self['event_time']: self.env['prob_tv_spread'] = 1 self.env['prob_neighbor_spread'] = 1 elif self.now > self['event_time']: self.env['prob_tv_spread'] = self.env['prob_tv_spread'] * TV_FACTOR self.env['prob_neighbor_spread'] = self.env['prob_neighbor_spread'] * NEIGHBOR_FACTOR Testing the agents ~~~~~~~~~~~~~~~~~~ Feel free to skip this section if this is your first time with soil. Testing agents is not easy, and this is not a thorough testing process for agents. Rather, this section is aimed to show you how to access internal pats of soil so you can test your agents. First of all, let's check if our network agent has the states we would expect: .. code:: ipython3 NewsSpread.states .. parsed-literal:: {'infected': , 'neutral': } Now, let's run a simulation on a simple network. It is comprised of three nodes: .. code:: ipython3 G = nx.Graph() G.add_edge(0, 1) G.add_edge(0, 2) G.add_edge(2, 3) G.add_node(4) pos = nx.spring_layout(G) nx.draw_networkx(G, pos, node_color='red') nx.draw_networkx(G, pos, nodelist=[0], node_color='blue') .. image:: output_21_0.png Let's run a simple simulation that assigns a NewsSpread agent to all the nodes in that network. Notice how node 0 is the only one with a TV. .. code:: ipython3 env_params = {'prob_tv_spread': 0, 'prob_neighbor_spread': 0} MAX_TIME = 100 EVENT_TIME = 10 sim = soil.simulation.SoilSimulation(topology=G, num_trials=1, max_time=MAX_TIME, environment_agents=[{'agent_type': NewsEnvironmentAgent, 'state': { 'event_time': EVENT_TIME }}], network_agents=[{'agent_type': NewsSpread, 'weight': 1}], states={0: {'has_tv': True}}, default_state={'has_tv': False}, environment_params=env_params) env = sim.run_simulation()[0] .. parsed-literal:: INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.02695441246032715 seconds INFO:soil.utils:NOT dumping results INFO:soil.utils:Finished simulation in 0.03360605239868164 seconds Now we can access the results of the simulation and compare them to our expected results .. code:: ipython3 agents = list(env.network_agents) # Until the event, all agents are neutral for t in range(10): for a in agents: assert a['id', t] == a.neutral.id # After the event, the node with a TV is infected, the rest are not assert agents[0]['id', 11] == NewsSpread.infected.id for a in agents[1:4]: assert a['id', 11] == NewsSpread.neutral.id # At the end, the agents connected to the infected one will probably be infected, too. assert agents[1]['id', MAX_TIME] == NewsSpread.infected.id assert agents[2]['id', MAX_TIME] == NewsSpread.infected.id # But the node with no friends should not be affected assert agents[4]['id', MAX_TIME] == NewsSpread.neutral.id Lastly, let's see if the probabilities have decreased as expected: .. code:: ipython3 assert abs(env.environment_params['prob_neighbor_spread'] - (NEIGHBOR_FACTOR**(MAX_TIME-1-10))) < 10e-4 assert abs(env.environment_params['prob_tv_spread'] - (TV_FACTOR**(MAX_TIME-1-10))) < 10e-6 Running the simulation ---------------------- To run a simulation, we need a configuration. Soil can load configurations from python dictionaries as well as JSON and YAML files. For this demo, we will use a python dictionary: .. code:: ipython3 config = { 'name': 'ExampleSimulation', 'max_time': 20, 'interval': 1, 'num_trials': 1, 'network_params': { 'generator': 'complete_graph', 'n': 500, }, 'network_agents': [ { 'agent_type': NewsSpread, 'weight': 1, 'state': { 'has_tv': False } }, { 'agent_type': NewsSpread, 'weight': 2, 'state': { 'has_tv': True } } ], 'environment_agents':[ {'agent_type': NewsEnvironmentAgent, 'state': { 'event_time': 10 } } ], 'states': [ {'has_tv': True} ], 'environment_params':{ 'prob_tv_spread': 0.01, 'prob_neighbor_spread': 0.5 } } Let's run our simulation: .. code:: ipython3 soil.simulation.run_from_config(config, dump=False) .. parsed-literal:: INFO:soil.utils:Using config(s): ExampleSimulation INFO:soil.utils:Dumping results to soil_output/ExampleSimulation : False INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 5.869051456451416 seconds INFO:soil.utils:NOT dumping results INFO:soil.utils:Finished simulation in 6.9609293937683105 seconds In real life, you probably want to run several simulations, varying some of the parameters so that you can compare and answer your research questions. For instance: - Does the outcome depend on the structure of our network? We will use different generation algorithms to compare them (Barabasi-Albert and Erdos-Renyi) - How does neighbor spreading probability affect my simulation? We will try probability values in the range of [0, 0.4], in intervals of 0.1. .. code:: ipython3 network_1 = { 'generator': 'erdos_renyi_graph', 'n': 500, 'p': 0.1 } network_2 = { 'generator': 'barabasi_albert_graph', 'n': 500, 'm': 2 } for net in [network_1, network_2]: for i in range(5): prob = i / 10 config['environment_params']['prob_neighbor_spread'] = prob config['network_params'] = net config['name'] = 'Spread_{}_prob_{}'.format(net['generator'], prob) s = soil.simulation.run_from_config(config) .. parsed-literal:: INFO:soil.utils:Using config(s): Spread_erdos_renyi_graph_prob_0.0 INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.0 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 1.2258412837982178 seconds INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.0 INFO:soil.utils:Finished simulation in 5.597268104553223 seconds INFO:soil.utils:Using config(s): Spread_erdos_renyi_graph_prob_0.1 INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.1 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 1.3026399612426758 seconds INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.1 INFO:soil.utils:Finished simulation in 5.534018278121948 seconds INFO:soil.utils:Using config(s): Spread_erdos_renyi_graph_prob_0.2 INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.2 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 1.4764575958251953 seconds INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.2 INFO:soil.utils:Finished simulation in 6.170421123504639 seconds INFO:soil.utils:Using config(s): Spread_erdos_renyi_graph_prob_0.3 INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.3 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 1.5429913997650146 seconds INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.3 INFO:soil.utils:Finished simulation in 5.936013221740723 seconds INFO:soil.utils:Using config(s): Spread_erdos_renyi_graph_prob_0.4 INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.4 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 1.4097135066986084 seconds INFO:soil.utils:Dumping results to soil_output/Spread_erdos_renyi_graph_prob_0.4 INFO:soil.utils:Finished simulation in 5.732810974121094 seconds INFO:soil.utils:Using config(s): Spread_barabasi_albert_graph_prob_0.0 INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.0 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.751497745513916 seconds INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.0 INFO:soil.utils:Finished simulation in 2.3415369987487793 seconds INFO:soil.utils:Using config(s): Spread_barabasi_albert_graph_prob_0.1 INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.1 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.8503265380859375 seconds INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.1 INFO:soil.utils:Finished simulation in 2.5671920776367188 seconds INFO:soil.utils:Using config(s): Spread_barabasi_albert_graph_prob_0.2 INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.2 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.8511502742767334 seconds INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.2 INFO:soil.utils:Finished simulation in 2.55816912651062 seconds INFO:soil.utils:Using config(s): Spread_barabasi_albert_graph_prob_0.3 INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.3 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.8982968330383301 seconds INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.3 INFO:soil.utils:Finished simulation in 2.6871559619903564 seconds INFO:soil.utils:Using config(s): Spread_barabasi_albert_graph_prob_0.4 INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.4 : True INFO:soil.utils:Trial: 0 INFO:soil.utils: Running INFO:soil.utils:Finished trial in 0.9563727378845215 seconds INFO:soil.utils:Dumping results to soil_output/Spread_barabasi_albert_graph_prob_0.4 INFO:soil.utils:Finished simulation in 2.5253307819366455 seconds The results are conveniently stored in pickle (simulation), csv and sqlite (history of agent and environment state) and gexf (dynamic network) format. .. code:: ipython3 !tree soil_output !du -xh soil_output/* .. parsed-literal:: soil_output ├── Spread_barabasi_albert_graph_prob_0.0 │   ├── Spread_barabasi_albert_graph_prob_0.0.dumped.yml │   ├── Spread_barabasi_albert_graph_prob_0.0.simulation.pickle │   ├── Spread_barabasi_albert_graph_prob_0.0_trial_0.backup1508409808.7944386.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.0_trial_0.backup1508428617.9811945.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.0_trial_0.db.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.0_trial_0.environment.csv │   └── Spread_barabasi_albert_graph_prob_0.0_trial_0.gexf ├── Spread_barabasi_albert_graph_prob_0.1 │   ├── Spread_barabasi_albert_graph_prob_0.1.dumped.yml │   ├── Spread_barabasi_albert_graph_prob_0.1.simulation.pickle │   ├── Spread_barabasi_albert_graph_prob_0.1_trial_0.backup1508409810.9913027.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.1_trial_0.backup1508428620.3419535.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.1_trial_0.db.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.1_trial_0.environment.csv │   └── Spread_barabasi_albert_graph_prob_0.1_trial_0.gexf ├── Spread_barabasi_albert_graph_prob_0.2 │   ├── Spread_barabasi_albert_graph_prob_0.2.dumped.yml │   ├── Spread_barabasi_albert_graph_prob_0.2.simulation.pickle │   ├── Spread_barabasi_albert_graph_prob_0.2_trial_0.backup1508409813.2012305.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.2_trial_0.backup1508428622.91827.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.2_trial_0.db.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.2_trial_0.environment.csv │   └── Spread_barabasi_albert_graph_prob_0.2_trial_0.gexf ├── Spread_barabasi_albert_graph_prob_0.3 │   ├── Spread_barabasi_albert_graph_prob_0.3.dumped.yml │   ├── Spread_barabasi_albert_graph_prob_0.3.simulation.pickle │   ├── Spread_barabasi_albert_graph_prob_0.3_trial_0.backup1508409815.5177016.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.3_trial_0.backup1508428625.5117545.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.3_trial_0.db.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.3_trial_0.environment.csv │   └── Spread_barabasi_albert_graph_prob_0.3_trial_0.gexf ├── Spread_barabasi_albert_graph_prob_0.4 │   ├── Spread_barabasi_albert_graph_prob_0.4.dumped.yml │   ├── Spread_barabasi_albert_graph_prob_0.4.simulation.pickle │   ├── Spread_barabasi_albert_graph_prob_0.4_trial_0.backup1508409818.1516452.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.4_trial_0.backup1508428628.1986933.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.4_trial_0.db.sqlite │   ├── Spread_barabasi_albert_graph_prob_0.4_trial_0.environment.csv │   └── Spread_barabasi_albert_graph_prob_0.4_trial_0.gexf ├── Spread_erdos_renyi_graph_prob_0.0 │   ├── Spread_erdos_renyi_graph_prob_0.0.dumped.yml │   ├── Spread_erdos_renyi_graph_prob_0.0.simulation.pickle │   ├── Spread_erdos_renyi_graph_prob_0.0_trial_0.backup1508409781.0791047.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.0_trial_0.backup1508428588.625598.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.0_trial_0.db.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.0_trial_0.environment.csv │   └── Spread_erdos_renyi_graph_prob_0.0_trial_0.gexf ├── Spread_erdos_renyi_graph_prob_0.1 │   ├── Spread_erdos_renyi_graph_prob_0.1.dumped.yml │   ├── Spread_erdos_renyi_graph_prob_0.1.simulation.pickle │   ├── Spread_erdos_renyi_graph_prob_0.1_trial_0.backup1508409786.6177793.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.1_trial_0.backup1508428594.3783743.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.1_trial_0.db.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.1_trial_0.environment.csv │   └── Spread_erdos_renyi_graph_prob_0.1_trial_0.gexf ├── Spread_erdos_renyi_graph_prob_0.2 │   ├── Spread_erdos_renyi_graph_prob_0.2.dumped.yml │   ├── Spread_erdos_renyi_graph_prob_0.2.simulation.pickle │   ├── Spread_erdos_renyi_graph_prob_0.2_trial_0.backup1508409791.9751768.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.2_trial_0.backup1508428600.041021.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.2_trial_0.db.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.2_trial_0.environment.csv │   └── Spread_erdos_renyi_graph_prob_0.2_trial_0.gexf ├── Spread_erdos_renyi_graph_prob_0.3 │   ├── Spread_erdos_renyi_graph_prob_0.3.dumped.yml │   ├── Spread_erdos_renyi_graph_prob_0.3.simulation.pickle │   ├── Spread_erdos_renyi_graph_prob_0.3_trial_0.backup1508409797.606661.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.3_trial_0.backup1508428606.2884977.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.3_trial_0.db.sqlite │   ├── Spread_erdos_renyi_graph_prob_0.3_trial_0.environment.csv │   └── Spread_erdos_renyi_graph_prob_0.3_trial_0.gexf └── Spread_erdos_renyi_graph_prob_0.4 ├── Spread_erdos_renyi_graph_prob_0.4.dumped.yml ├── Spread_erdos_renyi_graph_prob_0.4.simulation.pickle ├── Spread_erdos_renyi_graph_prob_0.4_trial_0.backup1508409803.4306188.sqlite ├── Spread_erdos_renyi_graph_prob_0.4_trial_0.backup1508428612.3312593.sqlite ├── Spread_erdos_renyi_graph_prob_0.4_trial_0.db.sqlite ├── Spread_erdos_renyi_graph_prob_0.4_trial_0.environment.csv └── Spread_erdos_renyi_graph_prob_0.4_trial_0.gexf 10 directories, 70 files 2.5M soil_output/Spread_barabasi_albert_graph_prob_0.0 2.5M soil_output/Spread_barabasi_albert_graph_prob_0.1 2.5M soil_output/Spread_barabasi_albert_graph_prob_0.2 2.5M soil_output/Spread_barabasi_albert_graph_prob_0.3 2.5M soil_output/Spread_barabasi_albert_graph_prob_0.4 3.6M soil_output/Spread_erdos_renyi_graph_prob_0.0 3.7M soil_output/Spread_erdos_renyi_graph_prob_0.1 3.7M soil_output/Spread_erdos_renyi_graph_prob_0.2 3.7M soil_output/Spread_erdos_renyi_graph_prob_0.3 3.7M soil_output/Spread_erdos_renyi_graph_prob_0.4 Analysing the results --------------------- Loading data ~~~~~~~~~~~~ Once the simulations are over, we can use soil to analyse the results. Soil allows you to load results for specific trials, or for a set of trials if you specify a pattern. The specific methods are: - ``analysis.read_data()`` to load all the results from a directory. e.g. ``read_data('my_simulation/')``. For each trial it finds in each folder matching the pattern, it will return the dumped configuration for the simulation, the results of the trial, and the configuration itself. By default, it will try to load data from the sqlite database. - ``analysis.read_csv()`` to load all the results from a CSV file. e.g. ``read_csv('my_simulation/my_simulation_trial0.environment.csv')`` - ``analysis.read_sql()`` to load all the results from a sqlite database . e.g. ``read_sql('my_simulation/my_simulation_trial0.db.sqlite')`` Let's see it in action by loading the stored results into a pandas dataframe: .. code:: ipython3 from soil.analysis import * .. code:: ipython3 df = read_csv('soil_output/Spread_barabasi_albert_graph_prob_0.0/Spread_barabasi_albert_graph_prob_0.0_trial_0.environment.csv', keys=['id']) df .. raw:: html
agent_id t_step key value value_type
5 0 0 id neutral str
7 1 0 id neutral str
9 2 0 id neutral str
11 3 0 id neutral str
13 4 0 id neutral str
15 5 0 id neutral str
17 6 0 id neutral str
19 7 0 id neutral str
21 8 0 id neutral str
23 9 0 id neutral str
25 10 0 id neutral str
27 11 0 id neutral str
29 12 0 id neutral str
31 13 0 id neutral str
33 14 0 id neutral str
35 15 0 id neutral str
37 16 0 id neutral str
39 17 0 id neutral str
41 18 0 id neutral str
43 19 0 id neutral str
45 20 0 id neutral str
47 21 0 id neutral str
49 22 0 id neutral str
51 23 0 id neutral str
53 24 0 id neutral str
55 25 0 id neutral str
57 26 0 id neutral str
59 27 0 id neutral str
61 28 0 id neutral str
63 29 0 id neutral str
... ... ... ... ... ...
21025 470 20 id infected str
21027 471 20 id infected str
21029 472 20 id infected str
21031 473 20 id infected str
21033 474 20 id infected str
21035 475 20 id infected str
21037 476 20 id infected str
21039 477 20 id infected str
21041 478 20 id infected str
21043 479 20 id infected str
21045 480 20 id infected str
21047 481 20 id infected str
21049 482 20 id infected str
21051 483 20 id infected str
21053 484 20 id infected str
21055 485 20 id infected str
21057 486 20 id infected str
21059 487 20 id infected str
21061 488 20 id infected str
21063 489 20 id infected str
21065 490 20 id infected str
21067 491 20 id infected str
21069 492 20 id infected str
21071 493 20 id infected str
21073 494 20 id infected str
21075 495 20 id infected str
21077 496 20 id infected str
21079 497 20 id infected str
21081 498 20 id infected str
21083 499 20 id infected str

10500 rows × 5 columns

Soil can also process the data for us and return a dataframe with as many columns as there are attributes in the environment and the agent states: .. code:: ipython3 env, agents = process(df) agents .. raw:: html
id
t_step agent_id
0 0 neutral
1 neutral
10 neutral
100 neutral
101 neutral
102 neutral
103 neutral
104 neutral
105 neutral
106 neutral
107 neutral
108 neutral
109 neutral
11 neutral
110 neutral
111 neutral
112 neutral
113 neutral
114 neutral
115 neutral
116 neutral
117 neutral
118 neutral
119 neutral
12 neutral
120 neutral
121 neutral
122 neutral
123 neutral
124 neutral
... ... ...
20 72 infected
73 infected
74 infected
75 infected
76 infected
77 infected
78 infected
79 infected
8 infected
80 infected
81 infected
82 infected
83 infected
84 infected
85 infected
86 infected
87 infected
88 infected
89 infected
9 infected
90 infected
91 infected
92 infected
93 infected
94 infected
95 infected
96 infected
97 infected
98 infected
99 infected

10500 rows × 1 columns

The index of the results are the simulation step and the agent\_id. Hence, we can access the state of the simulation at a given step: .. code:: ipython3 agents.loc[0] .. raw:: html
id
agent_id
0 neutral
1 neutral
10 neutral
100 neutral
101 neutral
102 neutral
103 neutral
104 neutral
105 neutral
106 neutral
107 neutral
108 neutral
109 neutral
11 neutral
110 neutral
111 neutral
112 neutral
113 neutral
114 neutral
115 neutral
116 neutral
117 neutral
118 neutral
119 neutral
12 neutral
120 neutral
121 neutral
122 neutral
123 neutral
124 neutral
... ...
72 neutral
73 neutral
74 neutral
75 neutral
76 neutral
77 neutral
78 neutral
79 neutral
8 neutral
80 neutral
81 neutral
82 neutral
83 neutral
84 neutral
85 neutral
86 neutral
87 neutral
88 neutral
89 neutral
9 neutral
90 neutral
91 neutral
92 neutral
93 neutral
94 neutral
95 neutral
96 neutral
97 neutral
98 neutral
99 neutral

500 rows × 1 columns

Or, we can perform more complex tasks such as showing the agents that have changed their state between two simulation steps: .. code:: ipython3 changed = agents.loc[1]['id'] != agents.loc[0]['id'] agents.loc[0][changed] .. raw:: html
id
agent_id
140 neutral
164 neutral
170 neutral
310 neutral
455 neutral
To focus on specific agents, we can swap the levels of the index: .. code:: ipython3 agents1 = agents.swaplevel() .. code:: ipython3 agents1.loc['0'].dropna(axis=1) .. raw:: html
id
t_step
0 neutral
1 neutral
2 neutral
3 neutral
4 neutral
5 neutral
6 neutral
7 neutral
8 neutral
9 neutral
10 neutral
11 infected
12 infected
13 infected
14 infected
15 infected
16 infected
17 infected
18 infected
19 infected
20 infected
Plotting data ~~~~~~~~~~~~~ If you don't want to work with pandas, you can also use some pre-defined functions from soil to conveniently plot the results: .. code:: ipython3 plot_all('soil_output/Spread_barabasi_albert_graph_prob_0.0/', get_count, 'id'); .. image:: output_54_0.png .. image:: output_54_1.png .. code:: ipython3 plot_all('soil_output/Spread_barabasi*', get_count, 'id'); .. image:: output_55_0.png .. image:: output_55_1.png .. image:: output_55_2.png .. image:: output_55_3.png .. image:: output_55_4.png .. image:: output_55_5.png .. image:: output_55_6.png .. image:: output_55_7.png .. image:: output_55_8.png .. image:: output_55_9.png .. code:: ipython3 plot_all('soil_output/Spread_erdos*', get_value, 'prob_tv_spread'); .. image:: output_56_0.png .. image:: output_56_1.png .. image:: output_56_2.png .. image:: output_56_3.png .. image:: output_56_4.png .. image:: output_56_5.png .. image:: output_56_6.png .. image:: output_56_7.png .. image:: output_56_8.png .. image:: output_56_9.png Manually plotting with pandas ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Although the simplest way to visualize the results of a simulation is to use the built-in methods in the analysis module, sometimes the setup is more complicated and we need to explore the data a little further. For that, we can use native pandas over the results. Soil provides some convenience methods to simplify common operations: - ``analysis.split_df`` to separate a history dataframe into environment and agent parameters. - ``analysis.get_count`` to get a dataframe with the value counts for different attributes during the simulation. - ``analysis.get_value`` to get the evolution of the value of an attribute during the simulation. And, as we saw earlier, ``analysis.process`` can turn a dataframe in canonical form into a dataframe with a column per attribute. .. code:: ipython3 p = read_sql('soil_output/Spread_barabasi_albert_graph_prob_0.0/Spread_barabasi_albert_graph_prob_0.0_trial_0.db.sqlite') env, agents = split_df(p); Let's look at the evolution of agent parameters in the simulation .. code:: ipython3 res = agents.groupby(by=['t_step', 'key', 'value']).size().unstack(level=[1,2]).fillna(0) res.plot(); .. image:: output_61_0.png As we can see, ``event_time`` is cluttering our results, .. code:: ipython3 del res['event_time'] res.plot() .. parsed-literal:: .. image:: output_63_1.png .. code:: ipython3 processed = process_one(agents); processed .. raw:: html
event_time has_tv id
t_step agent_id
0 0 0 True neutral
1 0 False neutral
10 0 True neutral
100 0 True neutral
101 0 True neutral
102 0 False neutral
103 0 True neutral
104 0 True neutral
105 0 False neutral
106 0 False neutral
107 0 True neutral
108 0 True neutral
109 0 False neutral
11 0 True neutral
110 0 False neutral
111 0 False neutral
112 0 True neutral
113 0 True neutral
114 0 True neutral
115 0 True neutral
116 0 False neutral
117 0 True neutral
118 0 True neutral
119 0 False neutral
12 0 False neutral
120 0 False neutral
121 0 True neutral
122 0 True neutral
123 0 True neutral
124 0 False neutral
... ... ... ... ...
20 73 0 True infected
74 0 True infected
75 0 True infected
76 0 True infected
77 0 True infected
78 0 True infected
79 0 False infected
8 0 False infected
80 0 True infected
81 0 False infected
82 0 False infected
83 0 True infected
84 0 False infected
85 0 True infected
86 0 True infected
87 0 True infected
88 0 False infected
89 0 False infected
9 0 True infected
90 0 True infected
91 0 True infected
92 0 True infected
93 0 False infected
94 0 True infected
95 0 True infected
96 0 True infected
97 0 True infected
98 0 False infected
99 0 True infected
NewsEnvironmentAgent 10 False 0

10521 rows × 3 columns

Which is equivalent to: .. code:: ipython3 get_count(agents, 'id', 'has_tv').plot() .. parsed-literal:: .. image:: output_66_1.png .. code:: ipython3 get_value(agents, 'event_time').plot() .. parsed-literal:: .. image:: output_67_1.png Dealing with bigger data ------------------------ .. code:: ipython3 from soil import analysis .. code:: ipython3 !du -xsh ../rabbits/soil_output/rabbits_example/ .. parsed-literal:: 267M ../rabbits/soil_output/rabbits_example/ If we tried to load the entire history, we would probably run out of memory. Hence, it is recommended that you also specify the attributes you are interested in. .. code:: ipython3 p = analysis.plot_all('../rabbits/soil_output/rabbits_example/', analysis.get_count, 'id') .. image:: output_72_0.png .. image:: output_72_1.png .. code:: ipython3 df = analysis.read_sql('../rabbits/soil_output/rabbits_example/rabbits_example_trial_0.db.sqlite', keys=['id', 'rabbits_alive']) .. code:: ipython3 states = analysis.get_count(df, 'id') states.plot() .. parsed-literal:: .. image:: output_74_1.png .. code:: ipython3 alive = analysis.get_value(df, 'rabbits_alive', 'rabbits_alive', aggfunc='sum').apply(pd.to_numeric) alive.plot() .. parsed-literal:: .. image:: output_75_1.png .. code:: ipython3 h = alive.join(states); h.plot(); .. parsed-literal:: /home/jfernando/.local/lib/python3.6/site-packages/pandas/core/reshape/merge.py:551: UserWarning: merging between different levels can give an unintended result (1 levels on the left, 2 on the right) warnings.warn(msg, UserWarning) .. image:: output_76_1.png .. code:: ipython3 states[[('id','newborn'),('id','fertile'),('id', 'pregnant')]].sum(axis=1).sub(alive['rabbits_alive'], fill_value=0)