rename

2013-07-29 17:16:33 -04:00 · 2013-07-29 17:16:33 -04:00 · db2d5fc38c
commit db2d5fc38c
parent 2a533c1f73
3 changed files with 571 additions and 571 deletions
--- a/newtim.py
+++ b/newtim.py
@ -1,251 +0,0 @@
 import pymc as mc
 import functools
 import itertools
 from collections import defaultdict as dd
 import pprint
 import progressbar
 def ResistanceGame(n_players):
  full_set = [("G1", True), ("G2", True), ("G3", True), ("E1", False), ("E2", False),
              ("G4", True), ("E3", False), ("G5", True), ("G6", True), ("E4", False)]
  return full_set[:n_players]
 class DeceptionGame(object):
  def __init__(self, player_array):
    self.player_array = player_array
    self.all_permutations = list(itertools.permutations(player_array))
    self.n_players = len(player_array)
    self.trace = None
    self.observations = []
    self.tid = 0
    self.lady_will_duck = mc.Bernoulli("lady_will_duck", 0.5)
    self.mission_ducks_on_round = [None] * 5
    self.mission_ducks_on_round[0] = mc.Bernoulli("missionduck_on_0", 0.5)
    self.mission_ducks_on_round[1] = mc.Bernoulli("missionduck_on_1", 0.5)
    self.mission_ducks_on_round[2] = mc.Bernoulli("missionduck_on_2", 0.5)
    self.mission_ducks_on_round[3] = mc.Bernoulli("missionduck_on_3", 0.0)
    self.mission_ducks_on_round[4] = mc.Bernoulli("missionduck_on_4", 0.0)
    self.ignorance_on_round = [None] * 5
    self.ignorance_on_round[0] = mc.Bernoulli("ignorance_on_0", 0.9)
    self.ignorance_on_round[1] = mc.Bernoulli("ignorance_on_1", 0.7)
    self.ignorance_on_round[2] = mc.Bernoulli("ignorance_on_2", 0.5)
    self.ignorance_on_round[3] = mc.Bernoulli("ignorance_on_3", 0.3)
    self.ignorance_on_round[4] = mc.Bernoulli("ignorance_on_4", 0.3)
  def player_is_good(self, deal, player):
    return deal[player][1]
  def player_is_role(self, deal, player):
    return deal[player][0]
  def add_known_alliance(self, player_id, is_good):
    transaction = []
    def obs(deal):
      if self.player_is_good(deal, player_id) == is_good:
        return True
      else:
        return None
    transaction.append(obs)
    self.observations.append(transaction)
    self.tid += 1
  def add_known_role(self, player_id, role_str):
    transaction = []
    def obs(deal):
      if self.player_is_role(deal, player_id) == role_str:
        return True
      else:
        return None
    transaction.append(obs)
    self.observations.append(transaction)
    self.tid += 1
  def player_sees_player_and_claims(self, p1, p2, claim):
    transaction = []
    def obs(deal):
      if self.player_is_good(deal, p1):
        if self.player_is_good(deal, p2) == claim:
          return True
        else:
          return None
      else:
        if self.lady_will_duck.rand():
          if self.player_is_good(deal, p2) == claim:
            return True
          else:
            return False
        else:
          if self.player_is_good(deal, p2) == claim:
            return False
          else:
            return True
    transaction.append(obs)
    self.observations.append(transaction)
    self.tid += 1
  def do_mission(self, team, fails, must_fail, r):
    transaction = []
    rnd = r - 1
    def obs(deal):
      n_actually_good_people = sum([int(self.player_is_good(deal, x)) for x in team])
      n_spies = len(team) - n_actually_good_people
      if n_spies == 0:
        if fails != 0:
          return None
        else:
          return True
      else:
        if fails == 0:
          if must_fail:
            return None
          duck = False
          for i in range(n_spies - fails):
            duck = duck or self.mission_ducks_on_round[rnd].rand()
          return duck
        else:
          if fails > n_spies:
            return None
          return True
    transaction.append(obs)
    self.observations.append(transaction)
    self.tid += 1
  def do_vote(self, team, votes, r):
    transaction = []
    rnd = r - 1
    def obs(deal):
      n_actually_good_people = sum([int(self.player_is_good(deal, x)) for x in team])
      n_spies = len(team) - n_actually_good_people
      could_happen = True
      for player, vote in enumerate(votes):
        if self.player_is_good(deal, player):
          if player in team:
            continue
          elif n_spies > 0:
            if vote == 1:
              if self.ignorance_on_round[rnd].rand():
                continue
              else:
                return False
          else:
            if vote == 0:
              if self.ignorance_on_round[rnd].rand():
                continue
              else:
                return False
        else:
          if player in team:
            continue
          elif n_spies == 0:
            if vote == 1:
              if self.ignorance_on_round[rnd].rand():
                continue
              else:
                return False
          else:
            if vote == 0:
              if self.ignorance_on_round[rnd].rand():
                continue
              else:
                return False
      return could_happen
    transaction.append(obs)
    self.observations.append(transaction)
    self.tid += 1
  def eval(self, length=10):
    deck = self.all_permutations[:]
    new_deck = []
    trace = []
    progress = progressbar.ProgressBar(widgets=["Simulating games: ", progressbar.Bar(marker="*"), " ", progressbar.ETA()])
    for i in progress(range(length)):
      for deal in deck:
        f_list = []
        for obs in self.observations:
          for tid in obs:
            f_list.append(tid)
        is_bad = False
        dont_copy = False
        for f in f_list:
          out = f(deal)
          if out is None:
            is_bad = True
            dont_copy = True
            break
          if out is True:
            continue
          if out is False:
            is_bad = True
            continue
        if not is_bad:
          trace.append(deal)
        if not dont_copy:
          new_deck.append(deal)
      deck = new_deck
      new_deck = []
    self.trace = trace
  def report(self):
    if self.trace is None:
      self.eval()
    return self.get_player_data()
  def get_player_data(self):
    out = []
    for i in range(self.n_players):
      out.append({})
      out[i]["role"] = dd(float)
      out[i]["side"] = dd(float)
    progress = progressbar.ProgressBar(widgets=["Reticulating splines: ", progressbar.Bar(marker="*"), " ", progressbar.ETA()])
    size = len(self.trace) * 1.0
    for deal in progress(self.trace):
      for i, card in enumerate(deal):
        role, side = card
        out[i]["role"][role] += 1.0 / size
        out[i]["side"][side] += 1.0 / size
    for i in range(self.n_players):
      out[i]["role"] = dict(out[i]["role"])
      out[i]["side"] = dict(out[i]["side"])
    return out
  def _aggregate(self, l, i):
    out = dd(float)
    size = len(l) * 1.0
    for deal in l:
      out[deal[i]] += 1 / size
    return dict(out)
  def print_report(self):
    pp = pprint.PrettyPrinter(indent = 4)
    pp.pprint(self.report())
 base_game = DeceptionGame(ResistanceGame(5))
 #base_game.add_known_role(0, "G1")
 #base_game.add_known_alliance(1, False)
 #base_game.player_sees_player_and_claims(0, 1, True)
 #base_game.player_sees_player_and_claims(1, 2, False)
 #base_game.player_sees_player_and_claims(2, 3, False)
 base_game.do_vote([1,2], [0,1,1,0,1], 1)
 base_game.do_mission([1,2], 0, False, 1)
 base_game.do_vote([0, 1, 2], [1,1,1,0,1], 2)
 base_game.do_mission([0, 1, 2], 1, False, 2)
 base_game.do_vote([3, 4], [0,0,1,1,1], 3)
 base_game.do_mission([3, 4], 0, False, 3)
 base_game.do_vote([3, 4], [0,0,1,1,1], 4)
 base_game.do_mission([0, 3, 4], 1, False, 4)
 #base_game.do_vote([1, 3, 4], [0,1,1,0,1], 5)
 #base_game.do_mission([1, 3, 4], 1, True, 5)
 base_game.eval(100)
 base_game.print_report()
--- a/old-tim.py
+++ b/old-tim.py
@ -0,0 +1,356 @@
 import pymc as mc
 import functools
 import itertools
 from collections import defaultdict as dd
 import pprint
 import numpy
 def ResistanceGame(n_players):
    full_set = [("G1", True), ("G2", True), ("G3", True),
                ("E1", False), ("E2", False), ("G4", True),
                ("E3", False), ("G5", True), ("G6", True), ("E4", False)]
    return full_set[:n_players]
 def BuildNbyNBeliefMatrix(id, n_players):
    all_vars = []
    matrix = []
    for player_id in range(n_players):
        vec = mc.Uniform("%d_trust_%d" % (id, player_id),
                         0.0, 1.0,
                         trace=True,
                         size=n_players,
                         value=(numpy.ones(n_players) * (1.0 / n_players)))
        matrix.append(vec)
        all_vars.append(vec)
    # Enforce that there's only one role for each player.
    for i, player_vec in enumerate(matrix):
        @mc.potential
        def obs_one_role(player_vec=player_vec):
            return mc.distributions.normal_like(
                sum(player_vec),
                1.0,
                100)
        all_vars.append(obs_one_role)
    # Enforce that there's only one player per role.
    for i in range(n_players):
        @mc.potential
        def obs_one_per_role(matrix=matrix):
            return mc.distributions.normal_like(
                sum([vec[i] for vec in matrix]),
                1.0,
                100)
        all_vars.append(obs_one_per_role)
    return matrix, all_vars
 class Player(object):
    ''' Representing all that the player is and knows '''
    def __init__(self, id, game):
        self.id = id
        self.game = game
        self.all_vars = []
        self.build_belief_matrix()
    def side(self):
        return self.side_var
    def role(self):
        return self.role_var
    def build_belief_matrix(self):
        self.matrix, self.all_vars = \
            BuildNbyNBeliefMatrix(self.id, self.game.n_players)
        # Enforce that the player completely knows her own role.
        @mc.potential
        def knows(deck_var=self.game.deck_var, matrix=self.matrix):
            role_id = self.game.player_role_for_deck_var(deck_var, self.id)
            return mc.distributions.normal_like(
                matrix[self.id][role_id],
                1.0,
                100)
        self.all_vars.append(knows)
    def get_role_belief_for(self, player_id, role_id):
        return self.matrix[player_id][role_id]
 class DeceptionGame(object):
    def __init__(self, player_array):
        self.player_array = player_array
        self.all_permutations = list(itertools.permutations(player_array))
        self.deck_var = mc.DiscreteUniform("deal", 0,
                                           len(self.all_permutations) - 1)
        self.n_players = len(player_array)
        self.model = None
        self.player_side_vars = []
        self.player_role_vars = []
        self.role_ids = {}
        self.role_side = {}
        i = 0
        for card in player_array:
            role, good = card
            self.role_ids[role] = i
            self.role_side[i] = good
            i += 1
        def player_side(x, role):
            if self.role_side[role]:
                return True
            return False
        def player_role(x, deck_var=self.deck_var):
            role_str = self.all_permutations[deck_var][x][0]
            return int(self.role_ids[role_str])
        self.players = []
        for x in range(self.n_players):
            role = mc.Deterministic(eval=functools.partial(player_role, x),
                                    name="player_role_%d" % x,
                                    parents={"deck_var": self.deck_var},
                                    doc="Who is player %d?" % x,
                                    dtype=int,
                                    trace=True,
                                    plot=False)
            self.player_role_vars.append(role)
            side = mc.Deterministic(eval=functools.partial(
                                    player_side, x),
                                    name="player_side_%d" % x,
                                    parents={"role": role},
                                    doc="Is player %d good?" % x,
                                    dtype=bool,
                                    trace=True,
                                    plot=False)
            self.player_side_vars.append(side)
            #self.players.append(Player(x, self))
        self.lady_will_duck = mc.Bernoulli("lady_will_duck", 0.5)
        self.team_duck = [None] * 5
        self.team_duck[0] = mc.Bernoulli("team_duck_1", 0.8)
        self.team_duck[1] = mc.Bernoulli("team_duck_2", 0.6)
        self.team_duck[2] = mc.Bernoulli("team_duck_3", 0.4)
        self.team_duck[3] = mc.Bernoulli("team_duck_4", 0.2)
        self.team_duck[4] = mc.Bernoulli("team_duck_5", 0.0)
        self.observations = []
        self.tid = 0
    def get_role_id_for(self, name):
        return self.role_ids[name]
    def role_id_is_good(self, role_id):
        return self.role_side[role_id]
    def player_good_for_deck_var(self, index, player):
        return self.all_permutations[index][player][1]
    def player_role_for_deck_var(self, index, player):
        return self.get_role_id_for(self.all_permutations[index][player][0])
    def player_sees_player_and_claims(self, player_view, player_give, claim):
        transaction = []
        total_len = len(self.all_permutations)
        for i in range(len(self.all_permutations)):
            self.deck_var.value = (5119 * i) % total_len
            try:
                @mc.potential
                def claims(deck_var=self.deck_var, will_duck=self.lady_will_duck):
                    if self.player_good_for_deck_var(deck_var, player_view) or will_duck:
                        if self.player_good_for_deck_var(deck_var, player_give) == claim:
                            return 0.0
                        else:
                            return -numpy.inf
                    else:
                        if self.player_good_for_deck_var(deck_var, player_give) == claim:
                            return -numpy.inf
                        else:
                            return 0.0
                        return -numpy.inf
            except mc.ZeroProbability:
                continue
        transaction.append(claims)
        self.observations.append(transaction)
        self.tid += 1
    def add_known_side(self, player_id, is_good):
        transaction = []
        total_len = len(self.all_permutations)
        for i in range(len(self.all_permutations)):
            self.deck_var.value = (5119 * i) % total_len
            try:
                @mc.potential
                def obs(deck_var=self.deck_var):
                    x = float(self.player_good_for_deck_var(deck_var, player_id)) - \
                            float(is_good)
                    return mc.distributions.normal_like(x, 0.0, 10000)
            except mc.ZeroProbability:
                continue
            break
        transaction.append(obs)
        self.observations.append(transaction)
        self.tid += 1
    def add_known_role(self, player_id, role_str):
        transaction = []
        known_role_id = self.get_role_id_for(role_str)
        total_len = len(self.all_permutations)
        for i in range(len(self.all_permutations)):
            self.deck_var.value = (5119 * i) % total_len
            try:
                @mc.potential
                def role(deck_var=self.deck_var):
                    x = self.player_role_for_deck_var(deck_var, player_id) \
                            - known_role_id
                    return mc.distributions.normal_like(x, 0.0, 10000)
            except mc.ZeroProbability:
                continue
            break
        transaction.append(role)
        self.observations.append(transaction)
        self.tid += 1
    def build_team(self, team, votes, required_success):
        transaction = []
        for voter in range(self.n_players):
            total_len = len(self.all_permutations)
            for i in range(len(self.all_permutations)):
                self.deck_var.value = (5119 * i) % total_len
                try:
                    @mc.potential
                    def build_team(deck_var=self.deck_var):
                        voter_is_good = self.player_good_for_deck_var(deck_var, voter)
                        if voter_is_good:
                            return mc.distributions.normal_like(x - n_successes, 0.0, 1000)
                        else:
                            return mc.distributions.normal_like(x - required_success, len(team) -
                    team_votes.name = "voter_%d_tid%d" % (voter, self.tid)
                except mc.ZeroProbability:
                    continue
                break
            transaction.append(team_votes)
        self.observations.append(transaction)
        self.tid += 1
    def team_and_successes(self, team, n_successes, mandatory, r):
        transaction = []
        total_len = len(self.all_permutations)
        for i in range(len(self.all_permutations)):
            self.deck_var.value = (5119 * i) % total_len
            try:
                @mc.potential
                def team_votes(deck_var=self.deck_var, team_duck=self.team_duck[r - 1]):
                    team_allegience = [self.player_good_for_deck_var(deck_var, x)
                                             for x in team]
                    for i, al in enumerate(team_allegience):
                        if al is True:
                            continue
                        else:
                            if not mandatory and team_duck:
                                print "Ducking"
                                team_allegience[i] = True
                    x = sum([float(x) for x in team_allegience])
                    return mc.distributions.normal_like(x - n_successes, 0.0, 1000)
                team_votes.name = "team_votes_tid%d" % self.tid
            except mc.ZeroProbability:
                continue
            break
        transaction.append(team_votes)
        self.observations.append(transaction)
        self.tid += 1
    def eval(self, length=60000, burn=30):
        mcmc = mc.MCMC(self._build_model_list())
        mcmc.sample(length, burn)
        self.model = mcmc
    def eval_model_sans_players(self, length=40000, burn=0):
        mcmc = mc.MCMC(self._build_restricted_model_list())
        #mcmc.use_step_method(mc.DiscreteMetropolis, self.deck_var, proposal_distribution='Prior')
        mcmc.sample(length, burn, tune_throughout=False)
    def report(self):
        if self.model is None:
            self.eval()
        out = []
        for i in range(self.n_players):
            out.append(self.get_player_data(i))
        return out
    def get_player_data(self, i):
        out = {}
        role_key = "player_role_%d" % i
        side_key = "player_side_%d" % i
        temp_role = self._aggregate(list(self.model.trace(role_key)))
        out["role"] = {}
        for k, v in temp_role.iteritems():
            out["role"][self.player_array[int(k)][0]] = v
        out["side"] = self._aggregate(list(self.model.trace(side_key)))
        return out
    def _aggregate(self, l):
        out = dd(float)
        size = len(l) * 1.0
        for x in l:
            out[x] += 1 / size
        return dict(out)
    def print_report(self):
        pp = pprint.PrettyPrinter(indent=4)
        pp.pprint(self.report())
    def _build_restricted_model_list(self):
        out = []
        out.append(self.deck_var)
        out.extend(self.player_side_vars[:])
        out.extend(self.player_role_vars[:])
        return out
    def _build_model_list(self):
        out = []
        out.append(self.deck_var)
        out.append(self.lady_will_duck)
        out.extend(self.player_side_vars[:])
        out.extend(self.player_role_vars[:])
        for duck in self.team_duck:
            out.append(duck)
        for player in self.players:
            out.extend(player.all_vars[:])
        flattened = [item for transaction in self.observations
                     for item in transaction]
        out.extend(flattened[:])
        return list(set(out))
 base_game = DeceptionGame(ResistanceGame(5))
 #base_game.add_known_role(0, "G1")
 base_game.build_team([0, 1, 2], [1, 0, 1, 1, 0], 1)
 base_game.team_and_successes([0, 1, 2], 2, 1, False)
 #base_game.team_and_successes([0, 1, 2], 2, 2, False)
 #base_game.player_sees_player_and_claims(0, 1, False)
 #base_game.add_known_side(1, False)
 base_game.eval()
 base_game.print_report()
--- a/tim.py
+++ b/tim.py