2010-03-02 20:45:21 -07:00
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import math
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import random
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from sets import Set as set
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import GameMath as gm
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import Program
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2010-03-07 23:57:15 -07:00
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from cStringIO import StringIO
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2010-03-02 20:45:21 -07:00
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class Tank(object):
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# How often, in turns, that we can fire.
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FIRE_RATE = 20
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# How far the laser shoots from the center of the tank
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FIRE_RANGE = 45.0
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# The radius of the tank, from the center of the turret.
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# This is what is used for collision and hit detection.
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RADIUS = 7.5
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# Max speed, in pixels
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MAXSPEED = 7.0
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# Max acceleration, as a fraction of speed.
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MAXACCEL = 35
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# Sensor range, in pixels
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SENSOR_RANGE = 90.0
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# Max turret turn rate, in radians
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TURRET_TURN_RATE = math.pi/10
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# The max number of sensors/timers/toggles
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SENSOR_LIMIT = 10
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2010-03-07 23:57:15 -07:00
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def __init__(self, name, pos, color, boardSize, angle=None, tAngle=None):
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"""Create a new tank.
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@param name: The name name of the tank. Stored in self.name.
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@param pos: The starting position of the tank (x,y)
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@param color: The color of the tank.
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@param boardSize: The size of the board. (maxX, maxY)
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@param angle: The starting angle of the tank, defaults to random.
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@param tAngle: The starting turretAngle of the tank, defaults to random.
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"""
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self.name = name
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assert len(pos) == 2 and pos[0] > 0 and pos[1] > 0, \
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'Bad starting position: %s' % str(pos)
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self.pos = pos
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# The last speed of each tread (left, right)
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self._lastSpeed = 0.0, 0.0
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# The next speed that the tank should try to attain.
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self._nextMove = 0,0
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# When set, the led is drawn on the tank.
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self.led = False
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assert len(boardSize) == 2 and boardSize[0] > 0 and boardSize[1] > 0
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# The limits of the playfield (maxX, maxY)
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self._limits = boardSize
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# The current angle of the tank.
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if angle is None:
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self._angle = random.random()*2*math.pi
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else:
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self._angle = angle
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# The current angle of the turret
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if tAngle is None:
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self._tAngle = random.random()*2*math.pi
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else:
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self._tAngle = tAngle
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self.color = color
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# You can't fire until fireReady is 0.
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self._fireReady = self.FIRE_RATE
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# Means the tank will fire at it's next opportunity.
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self._fireNow = False
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# True when the tank has fired this turn (for drawing purposes)
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self._fired = False
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# What the desired turret angle should be (from the front of the tank).
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# None means the turret should stay stationary.
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self._tGoal = None
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# Holds the properties of each sensor
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self._sensors = []
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# Holds the state of each sensor
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self._sensorState = []
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# The tanks toggle memory
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self.toggles = []
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# The tanks timers
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self._timers = []
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# Is this tank dead?
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self.isDead = False
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# Death reason
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self.deathReason = 'survived'
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# Something to log to
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self.stdout = StringIO()
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def __repr__(self):
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return '<tank: %s, (%d, %d)>' % (self.name, self.pos[0], self.pos[1])
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def fire(self, near):
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"""Shoots, if ordered to and able. Returns the set of tanks
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destroyed."""
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killed = set()
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if self._fireReady > 0:
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# Ignore the shoot order
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self._fireNow = False
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if self._fireNow:
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self._fireNow = False
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self._fireReady = self.FIRE_RATE
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self._fired = True
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firePoint = gm.polar2cart(self.FIRE_RANGE,
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self._angle + self._tAngle)
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for tank in near:
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enemyPos = gm.minShift(self.pos, tank.pos, self._limits)
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if gm.segmentCircleCollision(((0,0), firePoint), enemyPos,
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self.RADIUS):
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killed.add(tank)
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else:
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self._fired = False
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return killed
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def addSensor(self, range, angle, width, attachedTurret=False):
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"""Add a sensor to this tank.
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@param angle: The angle, from the tanks front and going clockwise,
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of the center of the sensor. (radians)
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@param width: The width of the sensor (radians).
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@param range: The range of the sensor (percent)
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@param attachedTurret: If set, the sensor moves with the turret.
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"""
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assert range >=0 and range <= 1, "Invalid range value."
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if len(self._sensors) >= self.SENSOR_LIMIT:
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raise ValueError("You can only have 10 sensors.")
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range = range * self.SENSOR_RANGE
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if attachedTurret:
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attachedTurret = True
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else:
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attachedTurret = False
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self._sensors.append((range, angle, width, attachedTurret))
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self._sensorState.append(False)
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def getSensorState(self, key):
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return self._sensorState[key]
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def setMove(self, left, right):
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"""Parse the speed values given, and set them for the next move."""
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self._nextMove = left, right
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def getTurretAngle(self):
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return self._tAngle
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def setTurretAngle(self, angle=None):
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"""Set the desired angle of the turret. No angle means the turret
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should remain stationary."""
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if angle is None:
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self._tGoal = None
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else:
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self._tGoal = gm.reduceAngle(angle)
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def setFire(self):
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"""Set the tank to fire, next turn."""
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self._fireNow = True
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def fireReady(self):
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"""Returns True if the tank can fire now."""
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return self._fireReady == 0
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def setLED(self):
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self.led = True
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def set_program(self, text):
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"""Set the program for this tank."""
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self.program = Program.Program(self, text)
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def execute(self):
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"""Execute this tanks program."""
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self.led = False
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self.program.run()
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self._move(self._nextMove[0], self._nextMove[1])
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self._moveTurret()
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if self._fireReady > 0:
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self._fireReady = self._fireReady - 1
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def sense(self, near):
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"""Detect collisions and trigger sensors. Returns the set of
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tanks collided with, plus this one. We do both these steps at once
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mainly because all the data is available."""
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near = list(near)
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polar = []
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for tank in near:
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polar.append(gm.relativePolar(self.pos, tank.pos, self._limits))
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for sensorId in range(len(self._sensors)):
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# Reset the sensor
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self._sensorState[sensorId] = False
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dist, sensorAngle, width, tSens = self._sensors[sensorId]
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# Adjust the sensor angles according to the tanks angles.
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sensorAngle = sensorAngle + self._angle
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# If the angle is tied to the turret, add that too.
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if tSens:
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sensorAngle = sensorAngle + self._tAngle
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while sensorAngle >= 2*math.pi:
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sensorAngle = sensorAngle - 2*math.pi
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for i in range(len(near)):
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r, theta = polar[i]
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# Find the difference between the object angle and the sensor.
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# The max this can be is pi, so adjust for that.
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dAngle = gm.angleDiff(theta, sensorAngle)
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rCoord = gm.polar2cart(dist, sensorAngle - width/2)
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lCoord = gm.polar2cart(dist, sensorAngle + width/2)
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rightLine = ((0,0), rCoord)
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leftLine = ((0,0), lCoord)
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tankRelPos = gm.minShift(self.pos, near[i].pos, self._limits)
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if r < (dist + self.RADIUS):
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if abs(dAngle) <= (width/2) or \
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gm.segmentCircleCollision(rightLine, tankRelPos,
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self.RADIUS) or \
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gm.segmentCircleCollision(leftLine, tankRelPos,
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self.RADIUS):
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self._sensorState[sensorId] = True
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break
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# Check for collisions here, since we already have all the data.
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collided = set()
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for i in range(len(near)):
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r, theta = polar[i]
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if r < (self.RADIUS + near[i].RADIUS):
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collided.add(near[i])
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# Add this tank (a collision kills both, after all
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if collided:
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collided.add(self)
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return collided
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def die(self, reason):
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self.isDead = True
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self.deathReason = reason
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def _moveTurret(self):
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if self._tGoal is None or self._tAngle == self._tGoal:
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return
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diff = gm.angleDiff(self._tGoal, self._tAngle)
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if abs(diff) < self.TURRET_TURN_RATE:
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self._tAngle = self._tGoal
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elif diff > 0:
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self._tAngle = gm.reduceAngle(self._tAngle - self.TURRET_TURN_RATE)
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else:
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self._tAngle = gm.reduceAngle(self._tAngle + self.TURRET_TURN_RATE)
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def _move(self, lSpeed, rSpeed):
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assert abs(lSpeed) <= 100, "Bad speed value: %s" % lSpeed
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assert abs(rSpeed) <= 100, "Bad speed value: %s" % rSpeed
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# Handle acceleration
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if self._lastSpeed[0] < lSpeed and \
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self._lastSpeed[0] + self.MAXACCEL < lSpeed:
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lSpeed = self._lastSpeed[0] + self.MAXACCEL
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elif self._lastSpeed[0] > lSpeed and \
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self._lastSpeed[0] - self.MAXACCEL > lSpeed:
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lSpeed = self._lastSpeed[0] - self.MAXACCEL
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if self._lastSpeed[1] < rSpeed and \
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self._lastSpeed[1] + self.MAXACCEL < rSpeed:
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rSpeed = self._lastSpeed[1] + self.MAXACCEL
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elif self._lastSpeed[1] > rSpeed and \
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self._lastSpeed[1] - self.MAXACCEL > rSpeed:
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rSpeed = self._lastSpeed[1] - self.MAXACCEL
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self._lastSpeed = lSpeed, rSpeed
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# The simple case
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if lSpeed == rSpeed:
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fSpeed = self.MAXSPEED*lSpeed/100
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x = fSpeed*math.cos(self._angle)
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y = fSpeed*math.sin(self._angle)
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# Adjust our position
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self._reposition((x,y), 0)
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return
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# The works as follows:
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# The tank drives around in a circle of radius r, which is some
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# offset on a line perpendicular to the tank. The distance it travels
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# around the circle varies with the speed of each tread, and is
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# such that each side of the tank moves an equal angle around the
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# circle.
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L = self.MAXSPEED * lSpeed/100.0
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R = self.MAXSPEED * rSpeed/100.0
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friction = .75 * abs(L-R)/(2.0*self.MAXSPEED)
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L = L * (1 - friction)
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R = R * (1 - friction)
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# Si is the speed of the tread on the inside of the turn,
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# So is the speed on the outside of the turn.
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# dir is to note the direction of rotation.
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if abs(L) > abs(R):
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Si = R; So = L
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dir = 1
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else:
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Si = L; So = R
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dir = -1
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# The width of the tank...
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w = self.RADIUS * 2
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# This is the angle that will determine the circle the tank travels
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# around.
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# theta = math.atan((So - Sl)/w)
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# This is the distance from the outer tread to the center of the
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# circle formed by it's movement.
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r = w*So/(So - Si)
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# The fraction of the circle traveled is equal to the speed of
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# the outer tread over the circumference of the circle.
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# Ft = So/(2*pi*r)
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# The angle traveled is equal to the Fraction traveled * 2 * pi
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# This reduces to a simple: So/r
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# We multiply it by dir to adjust for the direction of rotation
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theta = So/r * dir
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# These are the offsets from the center of the circle, given that
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# the tank is turned in some direction. The tank is facing
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# perpendicular to the circle
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# So far everything has been relative to the outer tread. At this
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# point, however, we need to move relative to the center of the
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# tank. Hence the adjustment in r.
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x = -math.cos( self._angle + math.pi/2*dir ) * (r - w/2.0)
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y = -math.sin( self._angle + math.pi/2*dir ) * (r - w/2.0)
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# Now we just rotate the tank's position around the center of the
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# circle to get the change in coordinates.
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mx, my = gm.rotatePoint((x,y), theta)
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mx = mx - x
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my = my - y
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# Finally, we shift the tank relative to the playing field, and
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# rotate it by theta.
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self._reposition((mx, my), theta)
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def _reposition(self, move, angleChange):
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"""Move the tank by x,y = move, and change it's angle by angle.
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|
I assume the tanks move slower than the boardSize."""
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x = self.pos[0] + move[0]
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|
y = self.pos[1] + move[1]
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|
|
self._angle = self._angle + angleChange
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|
if x < 0:
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|
|
x = self._limits[0] + x
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|
elif x > self._limits[0]:
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|
x = x - self._limits[0]
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if y < 0:
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|
y = self._limits[1] + y
|
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|
|
elif y > self._limits[1]:
|
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|
y = y - self._limits[1]
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|
self.pos = round(x), round(y)
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|
|
while self._angle < 0:
|
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|
|
self._angle = self._angle + math.pi * 2
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|
|
while self._angle > math.pi * 2:
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|
|
self._angle = self._angle - math.pi * 2
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|
|
|
2010-03-03 12:23:09 -07:00
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|
def describe(self, f):
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|
|
"""Output a description of this tank"""
|
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|
|
f.write(' ["%s",[' % self.color)
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|
|
for i in range(len(self._sensors)):
|
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|
|
dist, sensorAngle, width, tSens = self._sensors[i]
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|
|
f.write('[%d,%.2f,%.2f,%d],' % (dist, sensorAngle, width, tSens))
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|
|
f.write(']],\n')
|
|
|
|
|
2010-03-02 20:45:21 -07:00
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|
|
def draw(self, f):
|
|
|
|
"""Output this tank's state as JSON.
|
|
|
|
|
|
|
|
[color, x, y, angle, turret_angle, led, fired]
|
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|
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|
|
"""
|
|
|
|
|
2010-03-03 12:23:09 -07:00
|
|
|
if self.isDead:
|
|
|
|
f.write(' 0,\n')
|
|
|
|
else:
|
|
|
|
flags = (self._fired << 0) | (self.led << 1)
|
|
|
|
sensors = 0
|
|
|
|
for i in range(len(self._sensorState)):
|
|
|
|
sensors |= self._sensorState[i] << i
|
|
|
|
f.write(' [%d,%d,%.2f,%.2f,%d,%d],\n' % (self.pos[0],
|
|
|
|
self.pos[1],
|
|
|
|
self._angle,
|
|
|
|
self._tAngle,
|
|
|
|
flags,
|
|
|
|
sensors))
|