Ejemplo n.º 1
0
def smallestAngleBetween():
    tester = Tester('smallestAngleBetween')
    twoPi = np.pi * 2

    def truncate(num):
        return '%.4f' % (num)

    tester.compare(
        truncate(-twoPi * 2 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 1 / 6,
                                                 twoPi * 5 / 6)))
    tester.compare(
        truncate(twoPi * 2 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 5 / 6,
                                                 twoPi * 1 / 6)))

    tester.compare(
        truncate(twoPi * 1 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 1 / 6,
                                                 twoPi * 2 / 6)))
    tester.compare(
        truncate(-twoPi * 1 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 2 / 6,
                                                 twoPi * 1 / 6)))

    tester.compare(
        truncate(-twoPi * 3 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 2 / 6,
                                                 twoPi * 5 / 6)))
    tester.compare(
        truncate(twoPi * 3 / 6),
        truncate(mathHelper.smallestAngleBetween(twoPi * 5 / 6,
                                                 twoPi * 2 / 6)))
Ejemplo n.º 2
0
def smallestAngleBetween():
    tester = Tester('smallestAngleBetween')
    twoPi = np.pi * 2
    def truncate(num):
        return '%.4f'%(num)
    tester.compare(truncate(-twoPi*2/6), truncate(mathHelper.smallestAngleBetween(twoPi*1/6, twoPi*5/6)))
    tester.compare(truncate(twoPi*2/6), truncate(mathHelper.smallestAngleBetween(twoPi*5/6, twoPi*1/6)))

    tester.compare(truncate(twoPi*1/6), truncate(mathHelper.smallestAngleBetween(twoPi*1/6, twoPi*2/6)))
    tester.compare(truncate(-twoPi*1/6), truncate(mathHelper.smallestAngleBetween(twoPi*2/6, twoPi*1/6)))

    tester.compare(truncate(-twoPi*3/6), truncate(mathHelper.smallestAngleBetween(twoPi*2/6, twoPi*5/6)))
    tester.compare(truncate(twoPi*3/6), truncate(mathHelper.smallestAngleBetween(twoPi*5/6, twoPi*2/6)))
Ejemplo n.º 3
0
    def offensivePositioning(self):
        correlationArr = []
        myPredictedTanks = copy.deepcopy(self.myTanks)
        for myTank in myPredictedTanks:
            # Account for the predicted position
            myTank['actualPosition'] = myTank['position']
            if 'predictedPosition' in myTank:
                myTank['position'] = myTank['predictedPosition']
            for enTank in self.enemyTanks:
                tempCor = self.intp.correlationAtoB(myTank, enTank)
                if tempCor['distance'] > PROJECTILE_RANGE + self.intp.avgPeriod * enTank['speed'] * 3:
                    tempCor['shootable'] = False
                else:
                    tempCor['shootable'] = self.intp.isShotClear(myTank['position'], enTank['position'])
                tempCor['turretChange'] = mathHelper.smallestAngleBetween(myTank['turret'], tempCor['angle'])
                correlationArr.append(tempCor)
        # Sort the array, smallest abs angle chang first
        correlationArr = sorted(correlationArr, key=lambda entry:np.absolute(entry['turretChange']))

        remainingAttackers = copy.deepcopy(self.myTankIds)
        usedAttackers = {}
        enemyAttacked = {}
        for entry in correlationArr:
            # Check that the enemy is shootable
            if entry['shootable']:
                # Check if attacking tank is available
                if entry['tankA']['id'] not in usedAttackers:
                    # Check that enemy doesn't have too many attackers (max attackers = roundUp(remainingHeath/ProjDmg) + 1)
                    if entry['tankB']['id'] not in enemyAttacked or enemyAttacked[entry['tankB']['id']] <= np.ceil(entry['tankB']['health'] / PROJECTILE_DAMAGE) + 1:
                        # Check that attacker is actually close enough
                        if entry['distance'] < PROJECTILE_RANGE + self.intp.avgPeriod * entry['tankB']['speed']:
                            # assign the attaker to the enemy tank
                            remainingAttackers.remove(entry['tankA']['id'])
                            entry['targetId'] = entry['tankB']['id']
                            usedAttackers[entry['tankA']['id']] = entry
                            if entry['tankB']['id'] in enemyAttacked:
                                enemyAttacked[entry['tankB']['id']] += 1
                            else:
                                enemyAttacked[entry['tankB']['id']] = 0

        # assign any remaining attackers to enemies
        for attacker in remainingAttackers:
            # nobody to fire at so stop firinging
            self.comm.stop(myTank['id'], 'FIRE')
            # Find closest enemy via path finding and assign that enemy
            myCorrelations = [cor for cor in correlationArr if cor['tankA']['id'] == attacker]
            myCorrelations = sorted(myCorrelations, key=lambda entry:entry['distance'])
            for cor in myCorrelations:
                if cor['distance'] < PROJECTILE_RANGE + self.intp.avgPeriod * cor['tankB']['speed'] * 2:
                    cor['targetId'] = cor['tankB']['id' ]
                    usedAttackers[attacker] = cor
                else:
                    break

            # find closest shootable friend and move somewhat close to them  (like 30 away?)

        # Rotate turret appropriately
        for attacker in usedAttackers:
            # add predicitve factor to rotation
            angleToRotate = usedAttackers[attacker]['turretChange'] * self.predictionFactor
            self.comm.rotateTurret(attacker, angleToRotate)


        return
Ejemplo n.º 4
0
    def offensivePositioning(self):
        correlationArr = []
        myPredictedTanks = copy.deepcopy(self.myTanks)
        for myTank in myPredictedTanks:
            # Account for the predicted position
            myTank["actualPosition"] = myTank["position"]
            if "predictedPosition" in myTank:
                myTank["position"] = myTank["predictedPosition"]
            for enTank in self.enemyTanks:
                tempCor = self.intp.correlationAtoB(myTank, enTank)
                if tempCor["distance"] > PROJECTILE_RANGE + self.intp.avgPeriod * enTank["speed"] * 3:
                    tempCor["shootable"] = False
                else:
                    tempCor["shootable"] = self.intp.isShotClear(myTank["position"], enTank["position"])
                tempCor["turretChange"] = mathHelper.smallestAngleBetween(myTank["turret"], tempCor["angle"])
                correlationArr.append(tempCor)
        # Sort the array, smallest abs angle chang first
        correlationArr = sorted(correlationArr, key=lambda entry: np.absolute(entry["turretChange"]))

        remainingAttackers = copy.deepcopy(self.myTankIds)
        usedAttackers = {}
        enemyAttacked = {}
        for entry in correlationArr:
            # Check that the enemy is shootable
            if entry["shootable"]:
                # Check if attacking tank is available
                if entry["tankA"]["id"] not in usedAttackers:
                    # Check that enemy doesn't have too many attackers (max attackers = roundUp(remainingHeath/ProjDmg) + 1)
                    if (
                        entry["tankB"]["id"] not in enemyAttacked
                        or enemyAttacked[entry["tankB"]["id"]]
                        <= np.ceil(entry["tankB"]["health"] / PROJECTILE_DAMAGE) + 1
                    ):
                        # Check that attacker is actually close enough
                        if entry["distance"] < PROJECTILE_RANGE + self.intp.avgPeriod * entry["tankB"]["speed"]:
                            # assign the attaker to the enemy tank
                            remainingAttackers.remove(entry["tankA"]["id"])
                            entry["targetId"] = entry["tankB"]["id"]
                            usedAttackers[entry["tankA"]["id"]] = entry
                            if entry["tankB"]["id"] in enemyAttacked:
                                enemyAttacked[entry["tankB"]["id"]] += 1
                            else:
                                enemyAttacked[entry["tankB"]["id"]] = 0

        # assign any remaining attackers to enemies
        for attacker in remainingAttackers:
            # nobody to fire at so stop firinging
            self.comm.stop(myTank["id"], "FIRE")
            # Find closest enemy via path finding and assign that enemy
            myCorrelations = [cor for cor in correlationArr if cor["tankA"]["id"] == attacker]
            myCorrelations = sorted(myCorrelations, key=lambda entry: entry["distance"])
            for cor in myCorrelations:
                if cor["distance"] < PROJECTILE_RANGE + self.intp.avgPeriod * cor["tankB"]["speed"] * 2:
                    cor["targetId"] = cor["tankB"]["id"]
                    usedAttackers[attacker] = cor
                else:
                    break

            # find closest shootable friend and move somewhat close to them  (like 30 away?)

        # Rotate turret appropriately
        for attacker in usedAttackers:
            # add predicitve factor to rotation
            angleToRotate = usedAttackers[attacker]["turretChange"] * self.predictionFactor
            self.comm.rotateTurret(attacker, angleToRotate)

        return