def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
ai.setTurnSpeed(45)
sendData = getSendData()
output = getOutput(sendData, 12, 5, 2, weight)
turn, thrust = "N", "N"
if output[0] >= .55:
ai.turnRight(1)
turn = "R"
elif output[0] < .45:
ai.turnLeft(1)
turn = "L"
ai.setTurnSpeed(abs(output[0]-.5)*100)
if output[1] > random():
ai.thrust(1)
thrust = "Y"
if ai.selfAlive():
print (turn +" "+ str(round(output[0],3)) +" | "+ thrust +" "+ str(round(output[1],3)))
def act(self):
if ai.selfAlive():
self.getInputs()
#self.printInputs()
steerOutput = self.steeringNet.activate(self.steerInputs)[0]
thrustOutput = self.thrustingNet.activate(self.thrustInputs)[0]
shootOutput = self.shootingNet.activate(self.shootInputs)[0]
print([steerOutput, thrustOutput, shootOutput])
if steerOutput > .5:
ai.turnLeft(1)
ai.turnRight(0)
else:
ai.turnRight(1)
ai.turnLeft(0)
if thrustOutput > .5:
ai.thrust(1)
else :
ai.thrust(0)
if shootOutput > .5:
ai.fireShot()
self.resetInputs()
else:
self.steeringNet.reset()
self.thrustingNet.reset()
self.shootingNet.reset()
def tthrust(self, num):
global thrusted
if num == 1:
ai.thrust(1)
self.thrusted = 1
else:
ai.thrust(0)
self.thrusted = 0
def AI_loop(self):
# Release keys
ai.thrust(0)
# Controller logic
if ai.selfSpeed() < self.speedLimit:
ai.thrust(1)
# Track updated information
self.frameCount += 1
def AI_loop(self):
# Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#-------------------- Set variables --------------------#
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + 45)
rightWall = ai.wallFeeler(500, heading - 45)
leftWallStraight = ai.wallFeeler(500, heading + 90)
rightWallStraight = ai.wallFeeler(500, heading - 90)
leftBack = ai.wallFeeler(500, heading + 135)
rightBack = ai.wallFeeler(500, heading - 135)
backWall = ai.wallFeeler(500, heading - 180)
trackWall = ai.wallFeeler(500, tracking)
R = (heading - 90) % 360
L = (heading + 90) % 360
aim = ai.aimdir(0)
bullet = ai.shotAlert(0)
speed = ai.selfSpeed()
message = ai.scanMsg(0)
x = ai.selfX()
y = ai.selfY()
if "***" in message:
coordMessage = message.split("***")[1]
coordinatesString = coordMessage.strip().split(" [")[0]
coordinates = eval(coordinatesString)
closestEnemyX = coordinates[0]
closestEnemyY = coordinates[1]
toTurn = self.angleToPoint(x, y, closestEnemyX, closestEnemyY,
heading)
distance = self.distance(x, closestEnemyX, y, closestEnemyY)
#-------------------- Move to target point --------------------#
if toTurn > 0 and toTurn < 20 and distance > 300:
ai.thrust(1)
ai.turnLeft(0)
ai.turnRight(0)
elif toTurn >= 20:
ai.turnRight(1)
elif toTurn <= 0:
ai.turnLeft(1)
if self.counter % 300 == 0:
self.foundPrey((900, 400))
self.counter = self.counter + 1
def moveToPos(selfX, selfY, targetPositionPixels, stoppingDistance):
deltaX = targetPositionPixels[0] - selfX
deltaY = selfY - targetPositionPixels[1]
targetDirection = (math.atan2(deltaY, deltaX))
distanceToTarget = math.sqrt((targetPositionPixels[0] - selfX)**2 + (targetPositionPixels[1] - selfY)**2)
isBraking = distanceToTarget < stoppingDistance
if not isBraking:
ai.turnToRad(targetDirection)
ai.setPower(40)
ai.thrust()
else:
brake(2)
def AI_loop(): #Release keys ai.thrust(0) ai.turnLeft(0) ai.turnRight(0) #Set variables heading = int(ai.selfHeadingDeg()) tracking = int(ai.selfTrackingDeg()) frontWall = ai.wallFeeler(500,heading) left45Wall = ai.wallFeeler(500,heading+45) right45Wall = ai.wallFeeler(500,heading-45) left90Wall = ai.wallFeeler(500,heading+90) right90Wall = ai.wallFeeler(500,heading-90) left135Wall = ai.wallFeeler(500,heading+135) right135Wall = ai.wallFeeler(500,heading-135) backWall = ai.wallFeeler(500,heading-180) trackWall = ai.wallFeeler(500,tracking)
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + 90)
rightWall = ai.wallFeeler(500, heading - 90)
trackWall = ai.wallFeeler(500, tracking)
#Thrust rules
if ai.selfSpeed() <= 1 and frontWall >= 20:
ai.thrust(1)
elif trackWall < 40:
ai.thrust(1)
#Turn rules
if leftWall < rightWall:
ai.turnRight(1)
else:
ai.turnLeft(1)
#Just keep shooting
ai.fireShot()
def control(self, target=None):
""" Control the ship position. """
try:
if target is None:
target = self.position
pos = np.array([ai.selfX(), ai.selfY()])
vel = np.array([ai.selfVelX(), ai.selfVelY()])
orientation = ai.selfHeadingDeg()
vel_des = (target - pos) * self.k_pos
acc_des = (vel_des - vel) * self.k_vel
acc_mod, acc_ang = cart2pol(acc_des)
#print("vel_des: %s, vel: %s. Acceleration: %s. Acc ang: %f" % (vel_des, vel, acc_des, acc_ang*180/3.1415))
# ang_vels = angle_diff(vel, vel_des)
# ai.turnToDeg(int(math.atan2(acc_des[1], acc_des[0])))
# print("")
# print("-"*80)
ang_des = int(acc_ang if acc_ang > 0 else acc_ang + 360)
# print("Turning to %u. Current: %u" % (ang_des, ai.selfHeadingDeg()))
ai.turnToDeg(ang_des)
thrust_level = np.cos(angle_diff(orientation, acc_ang)) * acc_mod
ai.thrust(thrust_level > self.t_th)
# print("Pos: %s. Target: %s" % (pos, self.position))
# print("Current angle: %f, ang_des: %f." % (orientation, ang_des))
#print("Cos: ", np.cos(angle_diff(orientation, acc_ang)))
#print("""Velocity: %s, vel_des: %s, acc_des = %s, (%f, %u), thrust_level = %f"""\
# % (vel, vel_des, acc_des, acc_mod, int(acc_ang* 180 / 3.1415), thrust_level))
except:
print("Unexpected error, %s: %s" % sys.exc_info()[:2])
print(traceback.print_tb(sys.exc_info()[-1]))
def control(self, target=None):
""" Control the ship position. """
try:
if target is None:
target = self.position
pos = np.array([ai.selfX(), ai.selfY()])
vel = np.array([ai.selfVelX(), ai.selfVelY()])
orientation = ai.selfHeadingDeg()
vel_des = (target - pos) * self.k_pos
acc_des = (vel_des - vel) * self.k_vel
acc_mod, acc_ang = cart2pol(acc_des)
#print("vel_des: %s, vel: %s. Acceleration: %s. Acc ang: %f" % (vel_des, vel, acc_des, acc_ang*180/3.1415))
# ang_vels = angle_diff(vel, vel_des)
# ai.turnToDeg(int(math.atan2(acc_des[1], acc_des[0])))
# print("")
# print("-"*80)
ang_des = int(acc_ang if acc_ang > 0 else acc_ang + 360)
# print("Turning to %u. Current: %u" % (ang_des, ai.selfHeadingDeg()))
ai.turnToDeg(ang_des)
thrust_level = np.cos(angle_diff(orientation, acc_ang)) * acc_mod
ai.thrust(thrust_level > self.t_th)
# print("Pos: %s. Target: %s" % (pos, self.position))
# print("Current angle: %f, ang_des: %f." % (orientation, ang_des))
#print("Cos: ", np.cos(angle_diff(orientation, acc_ang)))
#print("""Velocity: %s, vel_des: %s, acc_des = %s, (%f, %u), thrust_level = %f"""\
# % (vel, vel_des, acc_des, acc_mod, int(acc_ang* 180 / 3.1415), thrust_level))
except:
print("Unexpected error, %s: %s" % sys.exc_info()[:2])
print(traceback.print_tb(sys.exc_info()[-1]))
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + 90)
rightWall = ai.wallFeeler(500, heading - 90)
trackWall = ai.wallFeeler(500, tracking)
#Thrust rules
print("i am heading")
print(heading)
print(frontWall)
print(leftWall)
print(rightWall)
print("front left right")
if ai.selfSpeed() <= 5 and frontWall >= 20:
ai.thrust(1)
elif trackWall < 20:
ai.thrust(1)
#Turn rules
# if leftWall < rightWall:
# ai.turnRight(1)
# else:
# ai.turnLeft(1)
#------------------------
degList = []
deg = 0
for i in range(9):
degree = heading + deg
degList.append(ai.wallFeeler(500, degree))
deg = deg + 45
highestDist = 0
print(degList)
for element in degList:
if element >= highestDist:
highestDist = element
print("highestDist")
print(highestDist)
print("index of highestdist")
print(degList.index(highestDist))
ai.turn(heading + ((degList.index(highestDist)) * 45))
print("the way to turn")
print(heading + ((degList.index(highestDist)) * 45))
#-------------------------------
#Just keep shooting
ai.fireShot()
def preempt(self):
ai.thrust(0)
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500,heading)
left45Wall = ai.wallFeeler(500,heading+45)
right45Wall = ai.wallFeeler(500,heading-45)
left90Wall = ai.wallFeeler(500,heading+90)
right90Wall = ai.wallFeeler(500,heading-90)
left135Wall = ai.wallFeeler(500,heading+135)
right135Wall = ai.wallFeeler(500,heading-135)
backWall = ai.wallFeeler(500,heading-180)
trackWall = ai.wallFeeler(500,tracking)
result_list = []
risk_list = []
for i in range(8):
Degree = tracking+(45*i)
Speed = ai.selfSpeed()
Distance = ai.wallFeeler(10000,tracking+(45*i))
result = Closing_Rate(Degree, tracking, Speed, Distance)
result_list.append(result)
### Fuzzy membership ###
closing_rate, distance = Closing_Rate(Degree, tracking, Speed, Distance)
low, medium, fast = Fuzzy_Speed(closing_rate)
close, far = Fuzzy_Distance(distance)
risk = Fuzzy_Risk(low, medium, fast, close, far)
risk_list.append(risk)
## Get the direction in deg that is most risky for the robot ##
max_risk = max(risk_list)
track_risk = (tracking + (risk_list.index(max_risk)*45) % 360)
min_risk = min(risk_list)
####### Shooting Ennemies ########
##Find the closest ennemy##
ClosestID = ai.closestShipId()
#print(ClosestID)
##Get the closest ennemy direction and speed##
ClosestSpeed = ai.enemySpeedId(ClosestID)
ClosestDir = ai.enemyTrackingDegId(ClosestID)
## Get the lockheadingdeg ##
enemy = ai.lockClose()
#print(enemy)
head = ai.lockHeadingDeg()
#print(head)
enemyDist = ai.selfLockDist()
#print(enemyDist, ClosestSpeed, ClosestDir, head)
int1, int2, int3, int4, int5 = Data(enemyDist, ClosestSpeed, ClosestDir, head, heading, tracking)
output = Out(int1, int2, int3, int4, int5)
#print(output)
if(output > 0.5):
addDeg = output * 20
else:
addDeg = (output -0.5) * 20 * -1
## Get the angles on both side between tracking and heading ##
dist = (heading - track_risk) % 360
dist2 = (360 - dist) % 360
## Production system rules based off fuzzy output ##
if(dist <= 130 and dist >= 0 and ai.selfSpeed() > 0 and max_risk >= 75):
ai.turnLeft(1)
#print("turning left")
elif(dist2 <= 130 and dist2 >= 0 and ai.selfSpeed() > 0 and max_risk >= 75):
ai.turnRight(1)
#print("turning right")
elif(ai.selfSpeed() <= 10):
ai.thrust(1)
#print("thrust")
elif(trackWall <= 150):
ai.thrust(1)
#print("thrust")
elif(enemyDist <= 400 and heading > (head) and enemyDist != 0):
ai.turnRight(1)
ai.fireShot()
elif(enemyDist <= 400 and heading < (head) and enemyDist != 0):
ai.turnLeft(1)
ai.fireShot()
elif(enemyDist > 400 and heading > (head + addDeg) and enemyDist != 0):
ai.turnRight(1)
ai.fireShot()
elif(enemyDist > 400 and heading < (head + addDeg) and enemyDist != 0):
ai.turnLeft(1)
ai.fireShot()
else:
#print("chilling")
ai.thrust(0)
ai.fireShot()
def AI_loop():
turn, thrust = .5, 0
ai.turnLeft(0)
ai.turnRight(0)
ai.thrust(0)
ai.setTurnSpeed(64)
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
trackWall = ai.wallFeeler(500, tracking)
frontL = ai.wallFeeler(500, heading + 10)
frontR = ai.wallFeeler(500, heading - 10)
leftF = ai.wallFeeler(500, heading + 70)
leftB = ai.wallFeeler(500, heading + 110)
rightF = ai.wallFeeler(500, heading - 70)
rightB = ai.wallFeeler(500, heading - 110)
backL = ai.wallFeeler(500, heading - 190)
backR = ai.wallFeeler(500, heading - 170)
speed = ai.selfSpeed()
def findClosestArea(x):
return {
frontL: 1,
leftF: 2,
leftB: 3,
backL: 4,
backR: 5,
rightF: 6,
rightB: 7,
frontR: 8
}[x]
closestVal = min(frontL, leftF, leftB, backL, backR, rightF, rightB,
frontR)
#Find the closest Wall to our ship
closestWall = findClosestArea(closestVal)
#Rules for turning
#if we are heading for a wall, turn away from it
if trackWall < 100:
#round(abs(ai.angleDiff(heading, tracking))/3)
ai.setTurnSpeed(15 + round(abs(ai.angleDiff(heading, tracking)) / 4))
if ai.angleDiff(heading, tracking) > 0:
ai.turnRight(1)
turn = .9
else:
ai.turnLeft(1)
turn = .1
#otherwise turn away from the closest wall
elif closestWall == 1:
ai.setTurnSpeed(64)
ai.turnRight(1)
turn = 1
elif closestWall == 2:
ai.setTurnSpeed(46)
ai.turnRight(1)
turn = .9
elif closestWall == 3:
ai.setTurnSpeed(28)
ai.turnRight(1)
turn = .8
elif closestWall == 4:
ai.setTurnSpeed(10)
ai.turnRight(1)
turn = .6
elif closestWall == 5:
ai.setTurnSpeed(10)
ai.turnLeft(1)
turn = .4
elif closestWall == 6:
ai.setTurnSpeed(28)
ai.turnLeft(1)
turn = .2
elif closestWall == 7:
ai.setTurnSpeed(26)
ai.turnLeft(1)
turn = .1
elif closestWall == 8:
ai.setTurnSpeed(64)
ai.turnLeft(1)
turn = 0
#if we are going too fast and are not in danger turn around
# if speed > 2.5 and closestVal > 100:
# ai.setTurnSpeed(64)
# if ai.angleDiff(heading, tracking) > 0:
# ai.turnRight(1)
# turn = 1
# #print("R",random())
# else:
# ai.turnLeft(1)
# turn = 0
#print("L",random())
#Rules for thrusting
#if we are going slow and there isn't a wall in front of us
if min(frontL, frontR) > 100 and speed < 2.5:
ai.thrust(1)
thrust = 1
#if we are going too fast and are facing away from the direction we are heading
elif abs(ai.angleDiff(heading, tracking)) > 135 and speed > 2.5:
ai.thrust(1)
thrust = 1
#if we are heading toward a wall and we are not facing it
elif trackWall < 150 and (abs(ai.angleDiff(heading, tracking)) > 120):
ai.thrust(1)
thrust = 1
#If there is a wall very close behind us, get away from it
elif backL < 25 or backR < 25:
ai.thrust(1)
thrust = 1
doBackPropigation = False
if ai.selfAlive() and doBackPropigation:
#adjust the the learning NN
infile = open("Sem2W_1.txt", "r")
weight = eval(infile.read())
infile.close()
sendData = getSendData(turn, thrust)
weight = adjustNN(sendData, 12, 5, 2, weight)
outfile = open("Sem2W_1.txt", "w")
outfile.write(str(weight))
outfile.close()
def thrust(power):
ai.setPower(power)
ai.thrust()
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
ai.setTurnSpeed(45)
#noshoot simple2 v1 - possibly broken
#weight = [[0.7493857316521443, 0.13368056995306654, -0.47767010506248414, 0.36303490376111747, 0.3699402939846066, -0.24513421555956436, 0.6049213422682447, -1.002771350490762, 0.04035249957935825, -0.28434589370049973, 0.06045481719428707, -0.7059773487995405], [0.4597751718875, 0.48527265677711917, 1.1633270644302531, -0.2617787944640836, 0.43969814249154665, 0.39105202732983013, -0.4842763268769806, 0.0139642821717396, 0.6316767202549712, -0.7261062652316246, 0.21262210805420517, 0.5641099350636366], [-0.3874172140692371, 0.7651295146994167, 1.0395098788413182, 1.186226846675026, -0.025235379424306762, 0.2946735626872294, 0.8189904988668917, -0.3112836835374087, 0.4561011502092862, -1.117805735032487, -0.43961810490175446, -0.4119472393430895], [0.22275511634133816, -0.6648437205568158, -0.8414740640064268, 0.8056440111521608, 0.015267716015499746, 0.41334996924272127, 0.4081963555038903, -0.1419511839287509, 0.45361416054410414, -0.8794849582102071, -0.3468746833944422, 0.5401415708615188], [0.5074970117306209, 0.5819675141877677, 0.6517899284876814, 0.46691400605473293, 0.32604510520447944, 0.5968926122763236, 0.5310482664503053, -0.680392116654488, 0.8673231237747582, 0.33285892719317295, 0.8399077545012879, 0.6164215093257798], [-0.372562013299741, -0.19652620269354013, 0.1437357080878078, 0.4658598892474184, 0.2622911587442708, -0.0978653491300881], [-0.8758502232674676, -0.2171515591378693, -2.993752695121232, -0.35299785185297505, 0.23130479682141922, -0.3366867315248932]]
#same
#weight = [[-0.5615458044552419, 0.18357035281974562, 0.03349259503126993, 0.7384951638825633, -0.30798810007905386, 0.30573186272807085, 0.854959406907431, -0.7415861859492735, -0.7738387875893121, 0.02855354677310282, -0.851478966174285, -0.4098017778685181], [-0.207370684933253, -0.013364767376613134, -0.9163625758710611, 0.7147484720369136, 0.4332939609435104, 0.08179173241171495, -0.7872472562071717, -0.028481692524635203, 0.9018021433254303, 0.44174414866442663, -0.9254417448428363, -0.8782722048252558], [0.33830929947647237, 0.3662059060118147, 0.3811711776833437, 0.24042392561994674, 0.5277499126295441, -0.0004866655690337176, 0.25640579185352463, -0.7633986561071578, -0.612156341670209, 0.8230711072150679, 0.760953671186351, -0.2573796666700781], [-0.504034389497162, -0.5579761993837166, -0.5804468446739354, 0.20559197382639358, 0.2633102441141902, 0.6523171620389138, -0.024442707325193276, 0.20991650483980787, 0.8242995112997102, -0.310268650118638, 0.6134846337134139, -0.1333594123873779], [-0.1482061081648374, -0.8156028525698128, 0.5620698705963493, 0.3369535386843364, 0.4950101349517008, 0.632041030208815, 0.2282786987810209, 0.5886322102158713, 0.1479714498784525, -0.35843514023521145, 0.7822417167093876, -0.6863908492221918], [0.19475966937630487, 0.3329038845401951, -0.4194515125286082, -1.0059783572483236, 0.4401534681618835, -0.14131035905437314], [-0.1489506388852606, -0.7142411448348961, 0.19491176823686687, -0.7258125795197734, -0.5016315182547347, 1.187683861246764]]
#noshoot simple2 v1
#weight = [[4.023914862289385, -11.939688383204079, -15.825568188856662, -8.91142185823263, 2.641203914119205, -0.5129014819329881, 0.9220419943089314, 0.3895906088166904, -3.314207628630927, 1.467458787811278, 1.0256723985314264, 6.790853759075572], [0.46927642890835647, 0.4119664313516612, 1.0805195819839035, -22.587191583019706, -2.0569865767257087, 1.0122406403957074, 0.7655020473448081, 0.5363534804959299, -0.09153880599832058, 1.742638802899449, 0.604362216981221, -5.437549122082703], [-7.860553953097792, 8.381751807757572, 16.129268910929408, 0.8192147369369929, 12.621334155351937, 1.1871517887014937, 1.3270695309760896, 1.0735505581082165, -2.1305919492192547, 0.8033262515099523, 3.3317152348735313, -1.1046970930734303], [0.4398449547641411, 1.912802187200376, 1.5190820053279013, 0.05054235950852018, 20.89903152269866, -5.003395008994748, -2.6880139668653324, -7.882075146152547, 7.312459204984362, 0.7725581247271933, -3.2005214579831134, 8.556187322708842], [-1.293677418426306, 1.0762585514923537, 2.9472553959491394, -2.8811018920854745, 20.39410027291124, 3.5575387211971545, -4.928681592073799, 3.91012465174139, -0.6466184042394076, 8.419255646279453, -8.094268776239682, 19.5220882165644], [0.3806641134895386, -0.054247151061047154, 0.35553915476967757, -0.16909223457447353, 0.6749672736601655, -0.19785778477211138], [6.21846263437043, 13.27919055895352, 5.556186398879765, 1.9758063219353386, 3.685290720905768, 11.4029046390971]]
#weight = [[0.5903138120766798, 0.3877986755669686, -0.9141386987535192, -0.1976691845132495, 0.20203743452617146, -3.8075577538969068, 13.355367631879064, -4.451492883287705, -4.077459994350015, -2.8670604965816433, -4.7237141988262215, 4.196577955775335], [0.05788957126040142, 0.7553202993193877, -0.41293776536874083, 0.9699420358471046, -0.39940905986885467, -0.7501531314002139, -3.649664715012045, -4.480417131687637, 12.40189634710716, -3.5479446525980323, -5.617634895580113, 4.614443478920718], [-0.44964748196431087, -0.21623652235598786, 0.5866855307562749, 2.6966017037464547, -0.2198767358187771, -15.121568447637916, 5.394174355851121, 3.3357101263144284, 5.142941080162113, 4.396587735322672, 6.27965132359125, -1.7132992179558508], [-0.8420976477874832, 3.6695944609982, 3.985187073998181, 11.839206173737303, -5.338358329529615, 12.584411691032383, -3.6258238911963225, -9.100219517619708, 0.09757837890948427, 0.26347032883307564, -2.317810633312963, 3.488522703736898], [0.7765991306851521, 0.28898396896441564, 0.7418514532805458, 7.79799228304993, -0.19002509820555794, -0.4950254716867189, 1.674108868938578, -2.550479398095525, -0.4777881148214889, -17.68616848936312, 17.798127474785755, 3.564677234214063], [-7.8104601458246075, -2.0636289766378315, -8.171829518484577, -0.3002860633762538, -0.8003364861508999, -8.88545431866241], [-9.931271155016605, -8.304191180682096, -4.721651527085654, -11.413401995134363, -6.807105641677094, -4.2517323859898255]]
#take 3
#weight = [[3.2209677211590364, 3.197844521358916, 1.0178700774531555, 2.6850832852265705, -0.1142410857208976, -7.424760693950065, 2.4741068398654735, -2.2455337118424423, 0.7975567187947812, -7.14879174218826, 1.1236926484785208, 1.0893799362829708], [0.8039483127966134, 2.0360025213584287, 0.01727196345640146, 13.743242184336747, -3.1131725731697797, 3.551772323183245, -1.912134715951023, 6.3466547648380365, 2.7583972445682843, -8.543348277242536, 1.0695972197298327, 1.0968548560479523], [-1.9711628616688408, -2.915258703528061, -0.6856763056229077, 5.775022292258987, -0.9242292134264676, -5.2290301586614545, 1.554497111395412, -8.663422012897401, 3.434867742464676, -1.4626063376098368, 3.1916811250980226, -3.1266957996982083], [-2.963581011499582, -1.8333571215071727, 0.19431283257511642, 12.685505979633772, 5.629563357825744, 2.269402859201827, -0.5394798674782302, 0.5415330617135145, -1.3492223641876873, -2.3782036784139104, -1.6868806998589756, -2.566848157895665], [-2.1971772106385568, -3.046613937692231, -1.91992660803775, 6.63802500331367, -13.090973918413972, 2.0019783380453955, 1.5786044885623458, -1.1226639661286304, -0.8816140948702889, -0.6041236731069092, 0.4128577493527515, -9.236718652388456], [-0.37898780078879885, 0.02278416261917311, -0.7370299412447531, 0.4580826382451188, 0.024909816638153417, -0.2986982689652905], [-6.204456817434451, -7.054321617074455, -3.8731103597961956, -7.0447149929917146, -6.223052160580929, -15.546591666508577]]
#weight = [[1.1620356523045294, 1.2293119820243932, -1.0680281171990968, -5.292742962549776, 3.004567388617913, 0.1416865776270463, 3.291787739904783, 3.311779449153159, 0.14350525985680226, 1.864065320111765, 0.41531949262324336, -0.7533626568752921], [2.6058003821118527, 0.9844458916296726, -2.031523030007777, -3.4422006288675315, 4.5638626155289055, -2.7046080365173837, 1.5356155037759958, 2.143460607268979, 3.9199241782825687, 0.12721742246873802, -0.8673469875291382, -1.8507505784965346], [-0.6131784294183935, 0.4639547932071712, -0.2666315961058117, 7.5292821094228755, -1.087211170794136, -0.7293843967199962, 0.4755491742014118, 0.4206888297192853, -0.8152826105125003, 1.988359326013337, -5.637090150274117, 0.5993755933965147], [0.27691971567025647, 1.037850843325554, -0.8250576728298599, -2.000417570912899, -0.006391527390813737, 2.0837950209487466, -8.24238052083867, 2.073287983133908, 3.2529633929820907, 2.1453759622986524, 3.7417070714472893, -2.9435663281508724], [-0.5037569895779601, -0.09031006667126633, -0.5311072081881074, 0.9440264182616986, 0.783774066571815, 6.828375559954358, -2.841644500387658, 0.24901014690965492, -4.849174297326825, -1.5945524577293186, -4.823283932380879, 1.1962232130136108], [1.4042452333993327, -0.09263191061453735, 0.8155734671747938, 5.256825832477101, 3.7371321136701705, 6.574206973322576], [13.323880256265307, -2.429025764741311, -10.985707613602697, 5.331771733353978, -0.12615902379461702, 15.191420141027539]]
#take 4
#weight = [[0.1906964794417142, -1.3230251087714693, -1.8568527275491726, -10.570510924730712, 0.3754935945207968, -4.767279359714083, 0.11809759894653031, -6.033443845654109, -4.862563766686397, -1.5992520992754746, 7.726616433374799, -3.552685892017083], [0.3653010148791735, 1.6736547762277736, 0.4531478751025384, -16.54229219042565, -3.440356011229119, 1.0104044032989574, -1.5155008934004035, 0.10642496061430406, -0.31316504641192483, 3.6828030284027515, -0.7489883459127186, -1.5244542545724582], [3.764701498917189, 0.4439295275324288, -2.9864503359860985, -3.9316071635513206, 5.798674529890128, -5.74883908980071, 5.398546661400034, -2.51467872126794, 10.108154232633654, -2.18382803218839, 2.5521301844943816, 3.311614056240679], [3.540372052106104, 4.504838909273797, 0.9723232714577832, -8.437301256316747, 14.998025152577217, -0.31994218366769667, -2.907161494453055, 3.893824258473095, -0.7579119727276817, 5.473585535436292, -3.2397908440984766, 15.192742537984023], [-6.248680428157617, -6.451873887564568, 1.6916836827123973, -4.655942296742202, 16.84212812043791, 5.734711342713387, 0.2955864473988734, 1.791898461633518, -3.4668510416701595, -1.358433980522392, -1.1057313703313203, 0.6888252016526282], [-0.43458701659431115, -0.0012780178353029815, -0.3084730481531892, 0.45069433382083834, 0.11685910089310178, -0.38449878977835567], [3.853866205452628, 12.037185197898191, 1.8699413530857774, 5.001790072421261, 4.513316028443307, 9.851232302101327]]
#weight = [[1.2911306905979911, -0.24861004977707912, -0.3569265073483646, 6.428936726785303, -1.3066626434454807, 0.25686627368220305, 0.9109367109212936, 0.16801829318526124, -0.20947845384297986, 1.2064241958740287, 0.036856251428802896, -3.359023278463905], [0.8036278040339718, 0.08012145204557049, 0.6845458738830329, 5.665809973883479, -0.9210048722891027, 1.3932208121673026, 1.046083232807299, 0.7941648248360582, 0.9365855847155237, 1.459603497851585, -0.5332056328831426, -2.534773939928277], [0.13301078275476066, 0.3429847838792201, -1.0338159784473917, 4.850766016537791, 0.7802072613774678, 1.2836937010475253, -0.8584360890917163, 1.7672832265369043, 0.10738236989054603, 3.4517636983002387, 0.22658851691351473, -1.0683529525811006], [1.6450210175622832, -0.28557720210974497, -0.2443112896936013, 6.8747070212198045, -0.8271033896420884, 0.2800592224187591, 0.5652744631888489, 0.08792418368229415, 0.9155105124974535, 0.46138821886651926, -0.3837164120204661, -3.494842813175506], [-0.8165377903719206, 1.958062852731677, 2.000566970645578, 5.919031622286524, 0.5506236423988042, 0.5494849931384184, 1.7160531008225108, 0.5260681781001207, 2.06495028663279, -0.07306752095214097, -1.204154609328308, -4.01239045823013], [-0.6146224030404228, 0.3233086944120275, 5.3979041539672545, -4.401300546048576, -0.42678298976091805, 1.0758830778504247], [-5.977941738072086, 0.019369137899827416, -0.5522710341025945, -7.13480943116727, -4.873784872189164, -16.38430927507949]]
#over break training
weight = [[
0.3662869049519842, -0.8570465997089849, -1.0415622777532179,
0.4420706041485171, 0.009019607340448946, 10.71120549250932,
-12.382299178044326, 10.244684059761504, -4.7714116184482425,
10.703496354982395, -0.8400740885526794, 2.1209753284753745
],
[
2.5366260663128686, 1.068830514524183, -2.0352964619508715,
-0.4999108962144593, 20.533875500405504, -1.301731900907607,
0.3103574877473953, -0.6500134665269202, 0.5084981306498488,
-0.8059254394827501, 1.31308616755389, 15.873718577684429
],
[
0.08005904547677181, -0.007564753721625019,
-0.10037179685269433, -30.286524359136706,
1.0348747725041256, -0.9129196441653706, 0.3754957498625551,
-1.305163204786704, -0.30909410903499906, 1.3574890310465415,
-0.2886464224612783, -5.911566724871949
],
[
4.655481170315177, -1.2991521769114085, -4.454652256174474,
4.274677448402512, 16.502421922725226, 12.710289689086315,
-9.738471684679293, 9.865851212762863, -8.873570414630043,
-0.1285739247431209, -14.804016099227272, 10.638993200840254
],
[
-13.975667825847953, 13.618115550695093, 27.871087273931305,
1.7052627216183622, -16.717674225226972, 0.8131962686148689,
0.6430161349620291, -0.6832651795038519, 1.6123037795473343,
3.7701435389411695, -2.729257195826183, -2.0449519807080896
],
[
0.6784559764050078, -0.30818410563793897,
-0.12048266318505906, 0.7386778766766025,
0.18813592750492103, 0.9656707078851317
],
[
7.248480099597683, 9.862850677133501, 18.95475459828898,
1.981941403265762, 7.509742979506548, 19.364672423856124
]]
sendData = getSendData()
output = getOutput(sendData, 11, 5, 2, weight)
turn, thrust = "N", "N"
if output[0] >= .55:
ai.turnRight(1)
turn = "R"
elif output[0] < .45:
ai.turnLeft(1)
turn = "L"
ai.setTurnSpeed(abs(output[0] - .5) * 100)
if output[1] > random():
ai.thrust(1)
thrust = "Y"
if ai.selfAlive():
print(turn + " " + str(round(output[0], 3)) + " | " + thrust +
" " + str(round(output[1], 3)))
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
ai.setTurnSpeed(45)
turn, thrust = 0.5, 0
maxSpeed = 3
shotAngle = 9
wallClose = 12
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
trackWall = ai.wallFeeler(500, tracking)
trackLWall = ai.wallFeeler(500, tracking + 3)
trackRWall = ai.wallFeeler(500, tracking - 3)
frontWall = ai.wallFeeler(500, heading)
flWall = ai.wallFeeler(500, heading + 10)
frWall = ai.wallFeeler(500, heading - 10)
leftWall = ai.wallFeeler(500, heading + 90)
rightWall = ai.wallFeeler(500, heading - 90)
trackWall = ai.wallFeeler(500, tracking)
backWall = ai.wallFeeler(500, heading - 180)
backLeftWall = ai.wallFeeler(500, heading - 185)
backRightWall = ai.wallFeeler(500, heading - 175)
speed = ai.selfSpeed()
closest = min(frontWall, leftWall, rightWall, backWall, flWall, frWall)
def closestWall(x): #Find the closest Wall
return {
frontWall: 1,
leftWall: 2,
rightWall: 3,
backWall: 4,
flWall: 5,
frWall: 6,
}[x]
wallNum = closestWall(closest)
crashWall = min(
trackWall, trackLWall, trackRWall
) #The wall we are likely to crash into if we continue on our current course
#Rules for turning
if wallNum == 1 or wallNum == 5 or wallNum == 6: #Front Wall is Closest (Turn Away From It)
ai.turnLeft(1)
turn = 0
elif wallNum == 2: # Left Wall is Closest (Turn Away From It)
ai.turnRight(1)
turn = 1
elif wallNum == 3: #Right Wall is Closest (Turn Away From It)
ai.turnLeft(1)
turn = 0
else: #Back Wall is closest- turn so that we are facing directly away from it
if backLeftWall < backRightWall:
ai.turnRight(
1) #We need to turn right to face more directly away from it
turn = 1
if backLeftWall > backRightWall: # We need to turn left to face more directly away from it
ai.turnLeft(1)
turn = 0
#Rules for thrusting
if speed < maxSpeed and frontWall > 100: #If we are moving slowly and we won't ram into anything, accelerate
ai.thrust(1)
thrust = 1
elif trackWall < 250 and (
ai.angleDiff(heading, tracking) > 120
): #If we are getting close to a wall, and we can thrust away from it, do so
ai.thrust(1)
thrust = 1
elif backWall < 20: #If there is a wall very close behind us, get away from it
ai.thrust(1)
thrust = 1
def AI_loop(self):
if self.team == False:
ai.talk("/team 2")
self.team = True
# Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#-------------------- Set variables --------------------#
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + 45)
rightWall = ai.wallFeeler(500, heading - 45)
leftWallStraight = ai.wallFeeler(500, heading + 90)
rightWallStraight = ai.wallFeeler(500, heading - 90)
leftBack = ai.wallFeeler(500, heading + 135)
rightBack = ai.wallFeeler(500, heading - 135)
backWall = ai.wallFeeler(500, heading - 180)
trackWall = ai.wallFeeler(500, tracking)
R = (heading - 90) % 360
L = (heading + 90) % 360
aim = ai.aimdir(0)
bullet = ai.shotAlert(0)
speed = ai.selfSpeed()
x = ai.selfX()
y = ai.selfY()
enemyX1 = ai.screenEnemyXId(0)
enemyY1 = ai.screenEnemyYId(0)
enemyX2 = ai.screenEnemyXId(1)
enemyY2 = ai.screenEnemyYId(1)
enemyTeam1 = ai.enemyTeamId(0)
enemyTeam2 = ai.enemyTeamId(1)
myTeam = ai.selfTeam()
coordinate = self.grid[self.counter][1]
message = ai.scanMsg(0)
# print(enemyX1, enemyY1, enemyX2, enemyY2)
# print(myTeam, enemyTeam1, enemyTeam2)
# Continually check messages
if message != self.MessageBuffer[-1]:
self.checkMessage(message)
# Check if enemy is on screen
# If it is: broadcast location of enemy
# If it is not: send message that we lost enemy
if enemyX1 != -1 and enemyY1 != -1:
print("enemy 1")
enemyCoordinate = (enemyX1, enemyY1)
self.foundPrey(enemyCoordinate)
coordinate = enemyCoordinate
elif enemyX2 != -1 and enemyY2 != -1:
print("enemy 2")
enemyCoordinate = (enemyX2, enemyY2)
self.foundPrey(enemyCoordinate)
coordinate = enemyCoordinate
elif self.foundPreyFlag == True:
print("lost prey")
self.lostPrey()
targetX = coordinate[0]
targetY = coordinate[1]
toTurn = self.angleToPoint(x, y, targetX, targetY, heading)
distance = self.distance(x, targetX, y, targetY)
if self.foundPreyFlag == False and self.checking == False:
ai.talk("checking! " + str(coordinate))
self.checking = True
# If speed is too fast, turn around and thrust to negate velocity
if speed > 5:
turning = ai.angleDiff(heading, tracking)
if abs(turning) > 165 and abs(turning) <= 180:
ai.turnLeft(0)
ai.turnRight(0)
if self.frames % 10 == 0:
ai.thrust(1)
elif turning <= 165 and turning > 0:
ai.turnRight(1)
else:
ai.turnLeft(1)
else:
#-------------------- Go to coordinate / enemy --------------------#
if abs(toTurn) < 10 and distance > 100:
ai.turnLeft(0)
ai.turnRight(0)
if self.frames % 3 == 0:
ai.thrust(1)
elif toTurn >= 10:
ai.turnLeft(1)
elif toTurn <= -10:
ai.turnRight(1)
if self.foundPreyFlag == True and distance < 150:
print("Caught enemy!")
ai.quitAI()
elif distance < 150:
self.markSpotChecked(coordinate, "me")
#-------------------- Old turn and thrust rules --------------------#
if speed <= 3 and frontWall >= 200:
ai.thrust(1)
elif trackWall < 50:
ai.thrust(1)
elif backWall < 40:
ai.thrust(1)
# Figures out what corner we are in and turns the right directon
if (backWall < 30) and (rightWallStraight < 200):
ai.turnLeft(1)
elif backWall < 30 and (leftWallStraight < 200):
ai.turnRight(1)
# Walls along our periphery (90 degree feelers)
elif leftWallStraight < rightWallStraight and trackWall < 75:
ai.turnRight(1)
elif leftWallStraight > rightWallStraight and trackWall < 75:
ai.turnLeft(1)
self.frames = self.frames + 1
def AI_loop(self):
# Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
if self.quitFlag == True:
with open('fitness.txt', 'a') as inFile:
outString = str(self.fitness) + "\n"
inFile.write(outString)
ai.quitAI()
if ai.selfAlive() == 0 or self.frames > 3000:
self.foundPreyFlag = False
self.parterFoundPreyFlag = False
self.checking = False
if self.foundPreyFlag == True and self.parterFoundPreyFlag == True:
self.fitness = self.fitness + 2
#-------------------- Set variables --------------------#
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + 45)
rightWall = ai.wallFeeler(500, heading - 45)
leftWallStraight = ai.wallFeeler(500, heading + 90)
rightWallStraight = ai.wallFeeler(500, heading - 90)
leftBack = ai.wallFeeler(500, heading + 135)
rightBack = ai.wallFeeler(500, heading - 135)
backWall = ai.wallFeeler(500, heading - 180)
trackWall = ai.wallFeeler(500, tracking)
R = (heading - 90) % 360
L = (heading + 90) % 360
aim = ai.aimdir(0)
bullet = ai.shotAlert(0)
speed = ai.selfSpeed()
x = ai.selfX()
y = ai.selfY()
enemyX = -1
enemyY = -1
enemyTeam = -1
if self.preyID != -1:
enemyX = ai.screenEnemyXId(self.preyID)
enemyY = ai.screenEnemyYId(self.preyID)
enemyTeam = ai.enemyTeamId(self.preyID)
else:
enemyX = ai.screenEnemyXId(ai.closestShipId())
enemyY = ai.screenEnemyYId(ai.closestShipId())
enemyTeam = ai.enemyTeamId(ai.closestShipId())
myTeam = ai.selfTeam()
coordinate = self.grid[self.counter][1]
message = ai.scanMsg(0)
# Continually check messages
if message != self.MessageBuffer[-1]:
self.checkMessage(message)
# Check if enemy is on screen
# If it is: broadcast location of enemy
if enemyX != -1 and enemyY != -1 and enemyTeam != 2:
coordinate = (enemyX, enemyY)
self.foundPreyFlag = True
self.foundPrey(coordinate)
self.fitness += 1
elif self.foundPreyFlag == True:
self.foundPreyFlag = False
ai.talk("--- " + "Lost prey!")
if self.parterFoundPreyFlag == True:
coordinate = self.preyLocation
# Calculate most efficient way to turn to get where we want to
targetX = coordinate[0]
targetY = coordinate[1]
toTurn = self.angleToPoint(x, y, targetX, targetY, heading)
distance = self.distance(x, targetX, y, targetY)
if self.checking == False and self.foundPreyFlag == False:
ai.talk("checking! " + str(coordinate))
self.checking = True
# If speed is too fast, turn around and thrust to negate velocity
if speed > self.gene0:
turning = ai.angleDiff(heading, tracking)
if abs(turning) > self.gene1 and abs(turning) <= self.gene2:
ai.turnLeft(0)
ai.turnRight(0)
if self.frames % self.gene3 == 0:
ai.thrust(1)
elif turning <= self.gene4 and turning > self.gene5:
ai.turnRight(1)
else:
ai.turnLeft(1)
if self.foundPreyFlag == True and distance <= 150:
self.caughtPrey(coordinate, distance)
else:
#-------------------- Go to coordinate / enemy --------------------#
if abs(toTurn) < self.gene6 and distance > self.gene7:
ai.turnLeft(0)
ai.turnRight(0)
if self.frames % self.gene8 == 0:
ai.thrust(1)
elif toTurn >= self.gene9:
ai.turnLeft(1)
elif toTurn <= -self.gene10:
ai.turnRight(1)
if self.foundPreyFlag == True and distance <= 150:
self.caughtPrey(coordinate, distance)
elif self.foundPreyFlag == True and distance > 150:
self.foundPrey(coordinate)
elif distance < 150:
self.markSpotChecked(coordinate, "me")
#-------------------- Old turn and thrust rules --------------------#
if speed <= self.gene14 and frontWall >= self.gene15:
ai.thrust(1)
elif trackWall < self.gene16:
ai.thrust(1)
elif backWall < self.gene17:
ai.thrust(1)
if (backWall < self.gene18) and (rightWallStraight < self.gene19):
ai.turnLeft(1)
elif backWall < self.gene20 and (leftWallStraight < self.gene21):
ai.turnRight(1)
elif leftWallStraight < rightWallStraight and trackWall < self.gene22:
ai.turnRight(1)
elif leftWallStraight > rightWallStraight and trackWall < self.gene23:
ai.turnLeft(1)
self.frames = self.frames + 1
if self.caughtPreyFlag == True and self.quitFlag == False:
ai.talk("quit!")
self.quitFlag = True
if ai.selfAlive() == 0 or self.frames > 1800:
self.quitFlag = True
def AI_loop():
turn, thrust = .5, 0
ai.turnLeft(0)
ai.turnRight(0)
ai.thrust(0)
ai.setTurnSpeed(64)
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
trackWall = ai.wallFeeler(500, tracking)
frontL = ai.wallFeeler(500, heading + 10)
frontR = ai.wallFeeler(500, heading - 10)
leftF = ai.wallFeeler(500, heading + 70)
leftB = ai.wallFeeler(500, heading + 110)
rightF = ai.wallFeeler(500, heading - 70)
rightB = ai.wallFeeler(500, heading - 110)
backL = ai.wallFeeler(500, heading - 200)
backR = ai.wallFeeler(500, heading - 160)
trackHeadRelative = (tracking - heading)
speed = ai.selfSpeed()
def findClosestArea(x):
return {
frontL: 1,
leftF: 2,
leftB: 3,
backL: 4,
backR: 5,
rightF: 6,
rightB: 7,
frontR: 8
}[x]
closestVal = min(frontL, leftF, leftB, backL, backR, rightF, rightB,
frontR)
#Find the closest Wall to our ship
closestWall = findClosestArea(closestVal)
#Rules for turning
if closestWall == 1:
ai.setTurnSpeed(64)
ai.turnRight(1)
turn = 1
elif closestWall == 2:
ai.setTurnSpeed(46)
ai.turnRight(1)
turn = .9
elif closestWall == 3:
ai.setTurnSpeed(28)
ai.turnRight(1)
turn = .8
elif closestWall == 4:
ai.setTurnSpeed(10)
ai.turnRight(1)
turn = .6
elif closestWall == 5:
ai.setTurnSpeed(10)
ai.turnLeft(1)
turn = .4
elif closestWall == 6:
ai.setTurnSpeed(28)
ai.turnLeft(1)
turn = .2
elif closestWall == 7:
ai.setTurnSpeed(26)
ai.turnLeft(1)
turn = .1
elif closestWall == 8:
ai.setTurnSpeed(64)
ai.turnLeft(1)
turn = 0
#Rules for thrusting
#if we are going slow and there isn't a wall in front of us
if min(frontL, frontR) > 100 and speed < 3:
ai.thrust(1)
thrust = 1
#if we are heading toward a wall and we are not facing it
elif trackWall < 150 and (ai.angleDiff(heading, tracking) > 90):
ai.thrust(1)
thrust = 1
#If there is a wall very close behind us, get away from it
elif backL < 20 or backR < 20:
ai.thrust(1)
thrust = 1
doBackPropigation = True
if ai.selfAlive() and doBackPropigation:
#adjust the the learning NN
infile = open("Sem2W_1.txt", "r")
weight = eval(infile.read())
infile.close()
sendData = getSendData(turn, thrust)
weight = adjustNN(sendData, 12, 5, 2, weight)
outfile = open("Sem2W_1.txt", "w")
outfile.write(str(weight))
outfile.close()
def preempt(self):
ai.thrust(0)
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
## Get values of variables for Wall Feelers, Head & Tracking ##
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
left45Wall = ai.wallFeeler(500, heading + 45)
right45Wall = ai.wallFeeler(500, heading - 45)
left90Wall = ai.wallFeeler(500, heading + 90)
right90Wall = ai.wallFeeler(500, heading - 90)
left135Wall = ai.wallFeeler(500, heading + 135)
right135Wall = ai.wallFeeler(500, heading - 135)
backWall = ai.wallFeeler(500, heading - 180)
trackWall = ai.wallFeeler(500, tracking)
####### Getters Variable Regarding Important Information About Enemies ########
##Find the closest ennemy##
enemy = ai.lockClose()
## Get the lockheadingdeg of enemy ##
head = ai.lockHeadingDeg()
## Get the dstance from enemy ##
enemyDist = ai.selfLockDist()
##### Production System Rules ######
### Turning Rules ###
if frontWall <= frontAlertValue and (
left45Wall < right45Wall) and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
elif frontWall <= frontAlertValue and (
left45Wall > right45Wall) and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
elif left90Wall <= frontAlertValue and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
elif right90Wall <= frontAlertValue and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
### Thrust commands ####
elif ai.selfSpeed() <= speedAlertValue and (
frontWall >=
frontAlertValue) and (left45Wall >= frontAlertValue) and (
right45Wall >=
frontAlertValue) and (right90Wall >= frontAlertValue) and (
left90Wall >=
frontAlertValue) and (left135Wall >= backAlertValue) and (
right135Wall >= backAlertValue) and (backWall >=
backAlertValue):
ai.thrust(1)
elif trackWall <= TrackFastAlertValue and ai.selfSpeed(
) >= speedAlertValue:
ai.thrust(1)
elif trackWall <= TrackSlowAlertValue and ai.selfSpeed(
) <= speedAlertValue:
ai.thrust(1)
elif backWall <= TrackFastAlertValue and ai.selfSpeed() >= speedAlertValue:
ai.thrust(1)
elif backWall <= TrackSlowAlertValue and ai.selfSpeed() <= speedAlertValue:
ai.thrust(1)
elif left135Wall <= TrackFastAlertValue and ai.selfSpeed(
) >= speedAlertValue:
ai.thrust(1)
elif left135Wall <= TrackSlowAlertValue and ai.selfSpeed(
) <= speedAlertValue:
ai.thrust(1)
elif right135Wall <= TrackFastAlertValue and ai.selfSpeed(
) >= speedAlertValue:
ai.thrust(1)
elif right135Wall <= TrackSlowAlertValue and ai.selfSpeed(
) <= speedAlertValue:
ai.thrust(1)
##### Bullet Avoidance Commands #####
elif ai.shotAlert(0) >= 0 and ai.shotAlert(0) <= BulletAlertValue:
if ai.angleDiff(
heading,
ai.shotVelDir(0)) > 0 and ai.selfSpeed() <= speedAlertValue:
ai.turnLeft(1)
ai.thrust(1)
elif ai.angleDiff(
heading,
ai.shotVelDir(0)) < 0 and ai.selfSpeed() <= speedAlertValue:
ai.turnRight(1)
ai.thrust(1)
elif ai.angleDiff(
heading,
ai.shotVelDir(0)) > 0 and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
else:
ai.turnRight(1)
##### Shooting Ennemy Commands #####
elif enemyDist <= EnemyAlertValue and heading > (
head) and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
ai.fireShot()
elif enemyDist <= EnemyAlertValue and heading < (
head) and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
ai.fireShot()
elif ai.selfSpeed() < speedAlertValue:
ai.thrust(1)
else:
ai.thrust(0)
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500,heading)
left45Wall = ai.wallFeeler(500,heading+45)
right45Wall = ai.wallFeeler(500,heading-45)
left90Wall = ai.wallFeeler(500,heading+90)
right90Wall = ai.wallFeeler(500,heading-90)
left135Wall = ai.wallFeeler(500,heading+135)
right135Wall = ai.wallFeeler(500,heading-135)
backWall = ai.wallFeeler(500,heading-180)
trackWall = ai.wallFeeler(500,tracking)
You can run a server with the following command:
#Thrust rules
if ai.selfSpeed() <= 5 and (frontWall >= 200) and (left45Wall >= 200) and (right45Wall >= 200) and (right90Wall >= 200) and (left90Wall >= 200) and (left135Wall >= 50) and (right135Wall >= 50) and (backWall >= 50):
ai.thrust(1)
elif trackWall < 100:
ai.thrust(1)
elif frontWall <= 300 and (left45Wall < right45Wall):
ai.turnRight(1)
elif left90Wall <= 200:
ai.turnRight(1)
elif frontWall <= 300 and (left45Wall > right45Wall):
ai.turnLeft(1)
elif right90Wall <= 200:
ai.turnLeft(1)
elif backWall <= 30 or left135Wall <= 30 or right135Wall <= 30:
ai.thrust(1)
else:
ai.thrust(0)
def tick():
try:
global tickCount
global mode
if not ai.selfAlive():
tickCount = 0
mode = "ready"
return
tickCount += 1
selfX = ai.selfX()
selfY = ai.selfY()
selfVelX = ai.selfVelX()
selfVelY = ai.selfVelY()
selfSpeed = ai.selfSpeed()
tracking = ai.selfTrackingRad()
selfHeading = ai.selfHeadingRad()
message = ai.scanTalkMsg(0)
mass = ai.selfMass()
friction = ai.getOption("friction")
thrustPower = ai.getPower()
def scalar_product(lis, n):
return [x * n for x in lis]
def vector_sum(list1, list2):
return [sum(x) for x in zip(list1, list2)]
def time_of_impact(px, py, vx, vy, s):
a = s * s - (vx * vx + vy * vy)
b = px * vx + py * vy
c = px * px + py * py
d = b * b + a * c
t = 0 # Time
if d >= 0:
t = (b + math.sqrt(d)) / a
if (t < 0):
t = 0
return t
def stopping_distance(mass, friction, thrustPower, selfSpeed):
fForce = friction * mass
tForce = thrustPower
accTot = ((fForce / mass) + (tForce / (mass + 5)))
return ((selfSpeed * selfSpeed) / (2 * accTot))
stopping_distance = stopping_distance(mass, friction, thrustPower,
selfSpeed)
print("tick count:", tickCount, "mode", mode)
if mode == "ready":
print(friction, mass, selfSpeed, thrustPower)
print(selfX, selfY)
if "move-to" in message:
splitmessage = message.split()
action = splitmessage[0]
if "move-to-stop" in action:
mode = "move-to-stop"
if "move-to-pass" in action:
mode = "move-to-pass"
if mode == "move-to-pass":
splitmessage = message.split()
coordX = float(splitmessage[1])
coordY = float(splitmessage[2])
print(coordX, coordY)
distance = math.sqrt(
abs(coordX - selfX)**2 + abs(coordY - selfY)**2)
time = time_of_impact((coordX - selfX), (coordY - selfY), 0, 0, 10)
targetDirection = (math.atan2(coordY - selfY, coordX - selfX))
print(targetDirection)
if tracking == targetDirection:
ai.thrust()
else:
ai.turnToRad(targetDirection)
ai.thrust()
if distance < 10:
mode == "klar"
if mode == "move-to-stop":
splitmessage = message.split()
coordX = int(splitmessage[1])
coordY = int(splitmessage[2])
print(coordX, coordY)
distance = math.sqrt(
abs(coordX - selfX)**2 + abs(coordY - selfY)**2)
time = time_of_impact((coordX - selfX), (coordY - selfY), 0, 0,
selfSpeed + 0.000001)
target_position = vector_sum(
(coordX - selfX, coordY - selfY),
scalar_product((0 - selfVelX, 0 - selfVelY), time))
targetDirection = (math.atan2(target_position[1],
target_position[0]))
print(target_position)
print(targetDirection)
if tickCount % 2 == 0:
if abs(tracking - targetDirection) > 0.01:
ai.turnToRad(targetDirection)
print("vinkel", (tracking - targetDirection), "tid", time)
#if abs(targetDirection-tracking) > 0.03:
# ai.thrust()
#ai.thrust()
# if tickCount % 2 == 0:
#if selfSpeed < 30:
ai.thrust()
#if targetDirection-tracking < -0.1:
# ai.turnRad(-(tracking-targetDirection))
# ai.thrust()
#if targetDirection-tracking < 0.1:
# ai.turnRad(-(tracking-targetDirection))
# ai.thrust()
#if not tracking == targetDirection:
# ai.turnToRad(targetDirection)
# ai.thrust()
# if distance < 10:
# mode == "klar"
# print("V", selfSpeed, "tP", thrustPower, "fr", friction, "M", mass)
print(stopping_distance, distance)
if stopping_distance > distance:
mode = "brake"
if mode == "brake":
ai.turnToRad(tracking + math.pi)
ai.thrust()
print(selfX, selfY)
splitmessage = message.split()
coordX = int(splitmessage[1])
coordY = int(splitmessage[2])
distance = math.sqrt(
abs(coordX - selfX)**2 + abs(coordY - selfY)**2)
print(distance)
if selfSpeed < 2:
mode = "xD"
if mode == "xD":
print(selfX, selfY)
splitmessage = message.split()
coordX = int(splitmessage[1])
coordY = int(splitmessage[2])
distance = math.sqrt(
abs(coordX - selfX)**2 + abs(coordY - selfY)**2)
print(distance)
except:
print(traceback.print_exc())
def AI_loop():
turn, thrust = .5, 0
ai.turnLeft(0)
ai.turnRight(0)
ai.thrust(0)
ai.setTurnSpeed(64)
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
trackWall = ai.wallFeeler(500, tracking)
trackL3 = ai.wallFeeler(500, tracking + 3)
trackL10 = ai.wallFeeler(500, tracking + 10)
trackR3 = ai.wallFeeler(500, tracking - 3)
trackR10 = ai.wallFeeler(500, tracking - 10)
frontWall = ai.wallFeeler(500, heading)
frontL = ai.wallFeeler(500, heading + 15)
frontR = ai.wallFeeler(500, heading - 15)
leftWall = ai.wallFeeler(500, heading + 90)
leftF = ai.wallFeeler(500, heading + 65)
leftB = ai.wallFeeler(500, heading + 115)
rightWall = ai.wallFeeler(500, heading - 90)
rightF = ai.wallFeeler(500, heading - 65)
rightB = ai.wallFeeler(500, heading - 115)
backWall = ai.wallFeeler(500, heading - 180)
backL = ai.wallFeeler(500, heading - 195)
backR = ai.wallFeeler(500, heading - 165)
trackHeadRelative = (tracking - heading)
speed = ai.selfSpeed()
def findClosestArea(x):
return {
frontWall: 1,
frontL: 2,
leftF: 3,
leftWall: 4,
leftB: 5,
backL: 6,
backWall: 7,
backR: 8,
rightB: 9,
rightWall: 10,
rightF: 11,
frontR: 12
}[x]
closestVal = min(frontWall, frontL, leftF, leftWall, leftB, backL,
backWall, backR, rightB, rightWall, rightF, frontR)
#Find the closest Wall to our ship
closestWall = findClosestArea(closestVal)
#The wall we are likely to crash into if we continue on our current course
crashWall = min(trackWall, trackL3, trackL10, trackR3, trackR10)
#Rules for turning
if closestWall == 1:
ai.setTurnSpeed(64)
ai.turnLeft(1)
turn = 0
elif closestWall == 2:
ai.setTurnSpeed(64)
ai.turnRight(1)
turn = 1
elif closestWall == 3:
ai.setTurnSpeed(52)
ai.turnRight(1)
turn = .9
elif closestWall == 4:
ai.setTurnSpeed(40)
ai.turnRight(1)
turn = .8
elif closestWall == 5:
ai.setTurnSpeed(28)
ai.turnRight(1)
turn = .7
elif closestWall == 6:
ai.setTurnSpeed(16)
ai.turnRight(1)
turn = .6
elif closestWall == 7:
pass
elif closestWall == 8:
ai.setTurnSpeed(16)
ai.turnLeft(1)
turn = .4
elif closestWall == 9:
ai.setTurnSpeed(28)
ai.turnLeft(1)
turn = .3
elif closestWall == 10:
ai.setTurnSpeed(40)
ai.turnLeft(1)
turn = .2
elif closestWall == 11:
ai.setTurnSpeed(52)
ai.turnLeft(1)
turn = .1
elif closestWall == 12:
ai.setTurnSpeed(64)
ai.turnLeft(1)
turn = 0
#Rules for thrusting
#if we are going slow and there isn't a wall in front of us
if min(frontWall, frontL, frontR) > 100 and speed < 4:
ai.thrust(1)
thrust = 1
#if we are heading toward a wall and we are not facing it
elif crashWall < 150 and (ai.angleDiff(heading, tracking) > 90):
ai.thrust(1)
thrust = 1
#If there is a wall very close behind us, get away from it
elif backWall < 20 or backL < 20 or backR < 20:
ai.thrust(1)
thrust = 1
doBackPropigation = False
if ai.selfAlive() and doBackPropigation:
#adjust the the learning NN
infile = open("Sem2W_2.txt", "r")
weight = eval(infile.read())
infile.close()
sendData = getSendData(turn, thrust)
weight = adjustNN(sendData, 17, 7, 2, weight)
outfile = open("Sem2W_2.txt", "w")
outfile.write(str(weight))
outfile.close()
def AI_loop():
global frames, frameHistory, generation, current_chrom, population, scores, current_score
print("frame", frames)
#rules
chrom = population[current_chrom][0]
when_to_thrust_speed = convert(chrom[0:4])
front_wall_distance_thrust = convert(chrom[4:8]) * 4
back_wall_distance_thrust = convert(chrom[8:12]) * 2
track_wall_distance_thrust = convert(chrom[12:16]) * 4
left_wall_angle = convert(chrom[16:20]) * 3
right_wall_angle = convert(chrom[20:24]) * 3
back_wall_angle = convert(chrom[24:28]) * 10
left_90_wall_angle = convert(chrom[28:32]) * 6
right_90_wall_angle = convert(chrom[32:36]) * 6
left_back_wall_angle = convert(chrom[36:40]) * 9
right_back_wall_angle = convert(chrom[44:48]) * 9
fuzzy_rate = convert(chrom[48:52])
fuzzy_rate_1 = convert(chrom[52:56])
angle_diff_shoot = convert(chrom[56:60])
shot_alert_distance = convert(chrom[60:64]) * 6
rate = fuzzy_rate
rate1 = fuzzy_rate_1
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + left_wall_angle)
rightWall = ai.wallFeeler(500, heading - right_wall_angle)
left90Wall = ai.wallFeeler(500, heading + left_90_wall_angle)
right90Wall = ai.wallFeeler(500, heading - right_90_wall_angle)
leftbackWall = ai.wallFeeler(500, heading + left_back_wall_angle)
rightbackWall = ai.wallFeeler(500, heading - right_back_wall_angle)
trackWall = ai.wallFeeler(500, tracking)
backWall = ai.wallFeeler(500, heading - back_wall_angle)
#Shooting rules
if ai.aimdir(0) >= 0 and -angle_diff_shoot <= ai.angleDiff(
heading, ai.aimdir(0)) <= angle_diff_shoot and ai.screenEnemyX(
0) >= 0 and ai.screenEnemyY(0) >= 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.fireShot()
#Turn rules
if ai.aimdir(0) >= 0 and ai.angleDiff(
heading, ai.aimdir(0)) > 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.turnLeft(1)
#print("aim turn left")
elif ai.aimdir(0) >= 0 and ai.angleDiff(
heading, ai.aimdir(0)) < 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.turnRight(1)
#print("aim turn right")
elif left90Wall < right90Wall and minmax(10, (rate * ai.selfSpeed()), 100):
ai.turnRight(1)
#print("left90wall")
elif right90Wall < left90Wall and minmax(10, (rate * ai.selfSpeed()), 100):
ai.turnLeft(1)
#print("right90wall")
elif leftbackWall < minmax(5, (rate1 * ai.selfSpeed()), 50):
ai.turnRight(1)
#print("leftbackwall")
elif rightbackWall < minmax(5, (rate1 * ai.selfSpeed()), 50):
ai.turnLeft(1)
#print("rightbackwall")
#base case turn rules
elif leftWall < rightWall:
ai.turnRight(1)
else:
ai.turnLeft(1)
#Thrust rules
if ai.selfSpeed(
) <= when_to_thrust_speed and frontWall >= front_wall_distance_thrust:
ai.thrust(1)
#print("thrust 1")
#dynamic thrust away from walls
elif trackWall < track_wall_distance_thrust:
ai.thrust(1)
#print("thrust 2")
#thrust away from back wall
elif backWall < back_wall_distance_thrust:
ai.thrust(1)
#print("thrust 3")
#Shot avoidance
elif ai.shotAlert(0) >= 0 and ai.shotAlert(
0) <= shot_alert_distance and ai.shotVelDir(
0) != -1 and ai.angleDiff(heading, ai.shotVelDir(0)) > 0:
#print("shotveldir turn left")
ai.turnLeft(1)
ai.thrust(1)
elif ai.shotAlert(0) >= 0 and ai.shotAlert(
0) <= shot_alert_distance and ai.shotVelDir(
0) != -1 and ai.angleDiff(heading, ai.shotVelDir(0)) < 0:
#print("shotveldir turn right")
ai.turnRight(1)
ai.thrust(1)
#tracks frames alive
if ai.selfAlive() == 1:
frames += 1
elif ai.selfAlive() == 0 and frames == 0:
pass
else:
#adds every fitness to a list to avoid the issue of xpilot score never resetting
scores.append(ai.selfScore())
#base case
if len(scores) < 2:
current_score = scores[-1]
else:
current_score = scores[-1] - scores[-2]
if current_score <= 0:
current_score = 2
population[current_chrom][1] = (frames**2) * current_score
print("fitness: ", population[current_chrom][1])
current_chrom += 1
print("current_chrom is: ", current_chrom)
if current_chrom >= len(population):
current_chrom = 0
print("current_chrom is: ", current_chrom)
generation += 1
fitness_scores = fitness(population)
#writes highest fitness agent to file
if generation % 5 == 0:
print("first write")
current_fitness = max(fitness_scores)
best_individual_index = fitness_scores.index(current_fitness)
best_individual = population[best_individual_index][0]
newfile = open("GA_output.txt", "a+")
newfile.write("Generation: ")
newfile.write("\n")
newfile.write(str(generation))
newfile.write("\n")
newfile.write("Best individual: ")
newfile.write("\n")
newfile.write(str(best_individual))
newfile.write("\n")
newfile.write("Best fitness: ")
newfile.write("\n")
newfile.write(str(current_fitness))
newfile.write("\n")
newfile.close()
chrom_pair = top_individuals(population, fitness_scores)
new_pop = []
new_pop += crossover(chrom_pair)
while (len(new_pop) < population_size):
new_pop += crossover(chrom_pair)
population = []
population = new_pop
#writes population to file
if generation % 10 == 0:
print("second write")
popfile = open("GA_pop.txt", "a+")
popfile.write("Generation: ")
popfile.write("\n")
popfile.write(str(generation))
popfile.write("\n")
for i in population:
popfile.write(str(i))
popfile.write("\n")
popfile.write("\n")
popfile.close()
frames = 0
def tick():
#
# The API won't print out exceptions, so we have to catch and print them ourselves.
#
try:
#
# Declare global variables so we have access to them in the function
#
global tickCount
global mode
#
# Reset the state machine if we die.
#
if not ai.selfAlive():
tickCount = 0
mode = "ready"
return
tickCount += 1
#
# Read some "sensors" into local variables, to avoid excessive calls to the API
# and improve readability.
#
selfX = ai.selfX()
selfY = ai.selfY()
selfVelX = ai.selfVelX()
selfVelY = ai.selfVelY()
selfSpeed = ai.selfSpeed()
shotSpeed = ai.getOption("shotSpeed")
selfHeading = ai.selfHeadingRad()
# 0-2pi, 0 in x direction, positive toward y
# Add more sensors readings here
print ("tick count:", tickCount, "mode", mode)
def scalar_product(lis, n):
return [x * n for x in lis]
def vector_sum(list1, list2):
return [sum(x) for x in zip(list1, list2)]
# [a, b, c] [d, e, f]
# [a,d] [b, e] [c, f]
def time_of_impact(px, py, vx, vy, s):
a = s * s - (vx * vx + vy * vy)
b = px * vx + py * vy
c = px * px + py * py
d = b*b + a*c
t = 0 # Time
if d >= 0:
t = (b + math.sqrt(d)) / a
if (t < 0):
t = 0
return t
closest_asteroid_id = 0
if mode == "ready":
#print("self vel Y: ", selfVelY)
if ai.selfSpeed() > 7: # We're going too fast!!!
mode = "brake"
# Find closest asteroid
if tickCount % 1 == 0:
for i in range(ai.asteroidCountScreen()):
#if not 130 <= ai.radarType(i) <= 133: # We're only looking for asteroids.
# continue
radar_dist = ai.asteroidDist(i)
if radar_dist < ai.asteroidDist(closest_asteroid_id):
closest_asteroid_id = i
if ai.asteroidCountScreen() > 0:
mode = "aim"
if mode == "aim":
asteroidX = ai.asteroidX(closest_asteroid_id)
asteroidY = ai.asteroidY(closest_asteroid_id)
asteroidVelX = ai.asteroidVelX(closest_asteroid_id)
asteroidVelY = ai.asteroidVelY(closest_asteroid_id)
if asteroidX - selfX > ai.mapWidthPixels()/1.2:
print("Target is to the right. Seen to the left")
dx = ai.mapWidthPixels() - asteroidX
asteroidX = -dx
#targetPosition[0] -= ai.mapWidthPixels()
if selfX - asteroidX > ai.mapWidthPixels()/1.2:
print("Target is to the left. Seen to the right")
dx = asteroidX
asteroidX = ai.mapWidthPixels() + dx
#targetPosition[0] += ai.mapWidthPixels()
if asteroidY - selfY > ai.mapHeightPixels()/1.2:
print("Target is above. Seen below")
dx = ai.mapHeightPixels() - asteroidY
asteroidY = -dx
#targetPosition[1] -= ai.mapHeightPixels()
if selfY - asteroidY > ai.mapHeightPixels()/1.2:
print("Target is below. Seen above.")
dx = asteroidY
asteroidY = ai.mapHeightPixels() + dy
#targetPosition[1] += ai.mapHeightPixels()
time = time_of_impact(asteroidX - selfX, asteroidY - selfY,
asteroidVelX, asteroidVelY, shotSpeed)
targetPosition = vector_sum((asteroidX - selfX, asteroidY - selfY),
scalar_product((asteroidVelX, asteroidVelY), time*1.1))
print("Map size x: ", ai.mapWidthPixels())
targetAngle = math.atan2(targetPosition[1], targetPosition[0])
ai.turnToRad(targetAngle)
if abs(selfHeading - targetAngle) % 2*math.pi < 0.8:
print("Firing at", targetPosition[0], ",", targetPosition[1])
ai.fireShot()
mode = "ready"
if mode == "brake":
velocityVector = (selfVelX, selfVelY)
targetAngle = math.pi + (math.atan2(velocityVector[1], velocityVector[0])) # Negative velocity vector
ai.turnToRad(targetAngle)
ai.thrust()
selfVel = velocityVector[0] * velocityVector[0] + velocityVector[1] * velocityVector[1]
if selfVel < 3: # The bot has come to a stop.
mode = "ready"
except:
print(traceback.print_exc())
def AI_loop():
global maxSpeed, shotAngle, wallClose, dead, previousScore
global turnedLeft, turnedRight, thrusted, shot
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
ai.setTurnSpeed(45)
#Set variables"""
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
trackWall = ai.wallFeeler(500, tracking)
trackLWall = ai.wallFeeler(500, tracking+3)
trackRWall = ai.wallFeeler(500, tracking - 3)
frontWall = ai.wallFeeler(500,heading)
flWall = ai.wallFeeler(500, heading + 10)
frWall = ai.wallFeeler(500, heading - 10)
leftWall = ai.wallFeeler(500,heading+90)
llWall = ai.wallFeeler(500, heading + 100)
rlWall = ai.wallFeeler(500, heading + 80)
rightWall = ai.wallFeeler(500,heading-90)
lrWall = ai.wallFeeler(500, heading - 80)
rrWall = ai.wallFeeler(500, heading - 100)
trackWall = ai.wallFeeler(500,tracking)
backWall = ai.wallFeeler(500, heading - 180)
backLeftWall = ai.wallFeeler(500, heading - 190)
backRightWall = ai.wallFeeler(500, heading - 170)
speed = ai.selfSpeed()
closest = min(frontWall, leftWall, rightWall, backWall, flWall, frWall)
def closestWall(x): #Find the closest Wall
return {
frontWall : 1,
leftWall : 2,
rightWall : 3,
backWall : 4,
flWall : 5,
frWall : 6,
}[x]
wallNum = closestWall(closest)
#Code for finding the angle to the closest ship
targetX, targetY = ai.screenEnemyX(0), ai.screenEnemyY(0)
#baseString = "["+str(flWall/500)+","+str(frontWall/500)+","+str(frWall/500) + "," + str(backLeftWall/500) + "," + str(backWall/500) + "," + str(backRightWall/500) + ","+str(leftWall/500)+","+str(rightWall/500)+","+str(trackLWall/500) + "," + str(trackWall/500) + ","+str(trackRWall/500) + "," + str(speed/10)
calcDir = -1
if targetX- ai.selfX() != 0:
calcDir = (math.degrees(math.atan2((targetY - ai.selfY()), (targetX- ai.selfX()))) + 360)%360
crashWall = min(trackWall, trackLWall, trackRWall) #The wall we are likely to crash into if we continue on our current course
#Rules for turning
if crashWall > wallClose*speed and closest > 25 and targetX != -1: #If we are far enough away from a predicted crash and no closer than 25 pixels to a wall we can try and aim and kill them
diff = (calcDir - heading)
#if ai.shotAlert(0) > -1 and ai.shotAlert(0) < 35: #If we are about to get shot
# tturnRight(1) #Screw aiming and turn right and thrust
# tthrust(1) #This is arguably a horrible strategy because our sideways profile is much larger, but it's required for the grade
if diff >= 0:
if diff >= 180:
ai.turnRight(1) #If the target is to our right- turn right
else :
ai.turnLeft(1) #If the target is to our left - turn left
else :
if diff > -180:
ai.turnRight(1) #If the target is to our right - turn right
else :
ai.turnLeft(1) #If the target is to our left - turn left
else : #Rules for avoiding death
# if crashWall/ai.selfSpeed() > ai.closestShot() :
if wallNum == 1 or wallNum == 5 or wallNum == 6: #Front Wall is Closest (Turn Away From It)
ai.turnLeft(1)
elif wallNum == 2 : # Left Wall is Closest (Turn Away From It)
ai.turnRight(1)
elif wallNum == 3 : #Right Wall is Closest (Turn Away From It)
ai.turnLeft(1)
else : #Back Wall is closest- turn so that we are facing directly away from it
if backLeftWall < backRightWall:
ai.turnRight(1) #We need to turn right to face more directly away from it
if backLeftWall > backRightWall: # We need to turn left to face more directly away from it
ai.turnLeft(1)
#Rules for thrusting
if speed < maxSpeed and frontWall > 100: #If we are moving slowly and we won't ram into anything, accelerate
ai.thrust(1)
elif trackWall < 200 and (ai.angleDiff(heading, tracking) > 120): #If we are getting close to a wall, and we can thrust away from it, do so
ai.thrust(1)
elif backWall < 20: #If there is a wall very close behind us, get away from it
ai.thrust(1)
if abs(calcDir - heading) < shotAngle and calcDir != -1: #If we are close to the current proper trajectory for a shot then fire
ai.fireShot()
previousScore = ai.selfScore()
def brake(targetSpeed=2):
if selfSpeed > targetSpeed:
ai.turnToRad(selfTracking + math.pi)
ai.thrust()
def AI_loop():
chrom = [
0, 0, 0, 1, 0, 1, 0, 0, 0, 0, 1, 0, 1, 1, 0, 0, 0, 1, 1, 1, 0, 0, 1, 1,
1, 0, 1, 0, 0, 1, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 1, 1, 0, 0, 0, 1,
1, 1, 0, 0, 1, 1, 1, 0, 1, 0, 0, 1, 0, 1, 1, 0
]
when_to_thrust_speed = convert(chrom[0:4])
front_wall_distance_thrust = convert(chrom[4:8]) * 4
back_wall_distance_thrust = convert(chrom[8:12]) * 2
track_wall_distance_thrust = convert(chrom[12:16]) * 4
left_wall_angle = convert(chrom[16:20]) * 3
right_wall_angle = convert(chrom[20:24]) * 3
back_wall_angle = convert(chrom[24:28]) * 10
left_90_wall_angle = convert(chrom[28:32]) * 6
right_90_wall_angle = convert(chrom[32:36]) * 6
left_back_wall_angle = convert(chrom[36:40]) * 9
right_back_wall_angle = convert(chrom[44:48]) * 9
fuzzy_rate = convert(chrom[48:52])
fuzzy_rate_1 = convert(chrom[52:56])
angle_diff_shoot = convert(chrom[56:60])
shot_alert_distance = convert(chrom[60:64]) * 6
rate = fuzzy_rate
rate1 = fuzzy_rate_1
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
leftWall = ai.wallFeeler(500, heading + left_wall_angle)
rightWall = ai.wallFeeler(500, heading - right_wall_angle)
left90Wall = ai.wallFeeler(500, heading + left_90_wall_angle)
right90Wall = ai.wallFeeler(500, heading - right_90_wall_angle)
leftbackWall = ai.wallFeeler(500, heading + left_back_wall_angle)
rightbackWall = ai.wallFeeler(500, heading - right_back_wall_angle)
trackWall = ai.wallFeeler(500, tracking)
backWall = ai.wallFeeler(500, heading - back_wall_angle)
#Shooting rule - checks whether theres an enemy to aim at using aimdir,
#and then if we're pointing at them within 10 degrees
#check whether theres a wall between us and the enemy; if there is not then we shoot
if ai.aimdir(0) >= 0 and -angle_diff_shoot <= ai.angleDiff(
heading, ai.aimdir(0)) <= angle_diff_shoot and ai.screenEnemyX(
0) >= 0 and ai.screenEnemyY(0) >= 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.fireShot()
#Turn rules
#standard check for enemy proximity and wall between us,
#and if we're not aiming at them the angle is corrected
if ai.aimdir(0) >= 0 and ai.angleDiff(
heading, ai.aimdir(0)) > 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.turnLeft(1)
print("aim turn left")
elif ai.aimdir(0) >= 0 and ai.angleDiff(
heading, ai.aimdir(0)) < 0 and ai.wallBetween(
ai.selfX(), ai.selfY(), ai.screenEnemyX(0),
ai.screenEnemyY(0)) == -1:
ai.turnRight(1)
print("aim turn right")
#misc turn rules with fuzzy logic
elif left90Wall < right90Wall and minmax(10, (rate * ai.selfSpeed()), 100):
ai.turnRight(1)
print("left90wall")
elif right90Wall < left90Wall and minmax(10, (rate * ai.selfSpeed()), 100):
ai.turnLeft(1)
print("right90wall")
elif leftbackWall < minmax(5, (rate1 * ai.selfSpeed()), 50):
ai.turnRight(1)
print("leftbackwall")
elif rightbackWall < minmax(5, (rate1 * ai.selfSpeed()), 50):
ai.turnLeft(1)
print("rightbackwall")
#default/base case turn rules
elif leftWall < rightWall:
ai.turnRight(1)
else:
ai.turnLeft(1)
#Thrust rules
#rule for speeding up when no wall in front of us
if ai.selfSpeed(
) <= when_to_thrust_speed and frontWall >= front_wall_distance_thrust:
ai.thrust(1)
print("thrust 1")
#dynamic thrust away from walls
elif trackWall < track_wall_distance_thrust:
ai.thrust(1)
print("thrust 2")
#thrust away from back wall
elif backWall < back_wall_distance_thrust:
ai.thrust(1)
print("thrust 3")
#this block handles dodging enemy bullets
elif ai.shotAlert(0) >= 0 and ai.shotAlert(
0) <= shot_alert_distance and ai.shotVelDir(
0) != -1 and ai.angleDiff(heading, ai.shotVelDir(0)) > 0:
print("shotveldir turn left")
ai.turnLeft(1)
ai.thrust(1)
elif ai.shotAlert(0) >= 0 and ai.shotAlert(
0) <= shot_alert_distance and ai.shotVelDir(
0) != -1 and ai.angleDiff(heading, ai.shotVelDir(0)) < 0:
print("shotveldir turn right")
ai.turnRight(1)
ai.thrust(1)
def AI_loop():
global count_frame, loop, boolean, score, population_size, chromosome_size, population, mutation_prob, crossover_prob, fitness_list, generation, generation_size, first_time, done_learning
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
## Get A Chromosome in the Population -- Eventually Will go through each individual in the population ##
current_chromosome = population[loop]
## Transform Each Gene insisde A Single Selected Chromosome. 0s & 1s Are Turned Into Intergers For Fuzzy Sets to understand ##
## Each Value obtained is used to calculate the risk of each 45 degree around the agent ##
## Each value has its own "jump" variable which refers to the distance from each possible points/values ##
## The start and end represents the possible start point and end point for each variable and they depend on
## what the variiable is. It is to ensure a viable fuzzy set and fuzzy functions that these restrictions are applied. ##
frontAlert = current_chromosome[0:5]
frontAlertValue = transform(frontAlert, 25)
backAlert = current_chromosome[5:9]
backAlertValue = transform(backAlert, 25)
speedAlert = current_chromosome[9:13] #4 bits
speedAlertValue = transform(speedAlert, 1) #1 jumps per value
EnemyAlert = current_chromosome[13:18] #5 bits
EnemyAlertValue = transform(EnemyAlert, 50) #50 jumps per value
TrackSlowAlert = current_chromosome[18:22] #4 bits
TrackSlowAlertValue = transform(TrackSlowAlert, 25) #25 jumps per value
TrackFastAlert = current_chromosome[22:26] #4 bits
TrackFastAlertValue = transform(TrackFastAlert, 25) #25 jumps per value
BulletAlert = current_chromosome[26:32] #4 bits
BulletAlertValue = transform(BulletAlert, 15) #15 jumps per value
## Get values of variables for Wall Feelers, Head & Tracking ##
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500,heading)
left45Wall = ai.wallFeeler(500,heading+45)
right45Wall = ai.wallFeeler(500,heading-45)
left90Wall = ai.wallFeeler(500,heading+90)
right90Wall = ai.wallFeeler(500,heading-90)
left135Wall = ai.wallFeeler(500,heading+135)
right135Wall = ai.wallFeeler(500,heading-135)
backWall = ai.wallFeeler(500,heading-180)
trackWall = ai.wallFeeler(500,tracking)
####### Getters Variable Regarding Important Information About Enemies ########
##Find the closest ennemy##
enemy = ai.lockClose()
## Get the lockheadingdeg of enemy ##
head = ai.lockHeadingDeg()
## Get the dstance from enemy ##
enemyDist = ai.selfLockDist()
## If the Enemy is Dead ##
if(ai.selfAlive() == 0 and boolean == False):
## Calculate Fitness Current Population ##
score_previous = score
score_current = ai.selfScore()
fitness_value = fitness(population, count_frame, score_previous, score_current)
fitness_list.append(fitness_value)
## If it went through the whole population and ready to move to next generation ##
if((loop+1) == population_size):
## Output the fitness of population to allow user to see if learning is happening ##
print("Generation:", generation)
print("Agent Fitness:")
print(fitness_list)
print("Average Fitness:", statistics.mean(fitness_list))
print("Best Fitness:", max(fitness_list))
## Finding the optimal chromosome to output it in data file ##
string_maxChromosome = ""
for chrom_max in range(chromosome_size):
string_maxChromosome = string_maxChromosome + str(population[fitness_list.index(max(fitness_list))][chrom_max])
## Formatting entire population in a big string to register it in excel file##
string_population = ""
for pop in range(population_size):
for pop_chrom in range(chromosome_size):
string_population = string_population + str(population[pop][pop_chrom])
if(pop != (population_size-1)):
string_population = string_population + ","
## Formatting entire population's fitness in a big string to register it in excel file##
string_fitness = ""
for fit in range(len(fitness_list)):
string_fitness = string_fitness + str(fitness_list[fit])
if(fit != (len(fitness_list)-1)):
string_fitness = string_fitness + ","
## Output Data into Excel File ##
titles = ["Generation", "Average Fitness", "Best Fitness","Population Size", "Chromosome Size", "Crossover Probability", "Mutation Probability", "Best Chromosome", "Entire Population Chromosome", "Entire Population Fitness"]
data = [generation, statistics.mean(fitness_list), max(fitness_list), population_size, chromosome_size, crossover_prob, mutation_prob, string_maxChromosome, string_population, string_fitness]
first_time = Save_Data("Tiger_Training_Data.xls", 0, titles, data, first_time)
## Select Next Generation -- Apply Crossover & Mutation ##
new_population = select(population, fitness_list)
new_population = crossover(new_population, chromosome_size, population_size, crossover_prob)
new_population = mutate(new_population, chromosome_size, mutation_prob)
population = new_population
loop = 0
count_frame = 0
generation += 1
fitness_list.clear()
### DONE -- QUIT ###
if (generation == generation_size):
quitAI()
## Move to the next individual in population ##
else:
loop += 1
count_frame = 0
boolean = True
else:
## The agent is Alive ##
if(ai.selfAlive() == 1):
### Turning Rules ###
if frontWall <= frontAlertValue and (left45Wall < right45Wall) and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
elif frontWall <= frontAlertValue and (left45Wall > right45Wall) and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
elif left90Wall <= frontAlertValue and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
elif right90Wall <= frontAlertValue and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
### Thrust commands ####
elif ai.selfSpeed() <= speedAlertValue and (frontWall >= frontAlertValue) and (left45Wall >= frontAlertValue) and (right45Wall >= frontAlertValue) and (right90Wall >= frontAlertValue) and (left90Wall >= frontAlertValue) and (left135Wall >= backAlertValue) and (right135Wall >= backAlertValue) and (backWall >= backAlertValue):
ai.thrust(1)
elif trackWall <= TrackFastAlertValue and ai.selfSpeed() >= speedAlertValue:
ai.thrust(1)
elif trackWall <= TrackSlowAlertValue and ai.selfSpeed() <= speedAlertValue:
ai.thrust(1)
elif backWall <= TrackFastAlertValue and ai.selfSpeed() >= speedAlertValue:
ai.thrust(1)
elif backWall <= TrackSlowAlertValue and ai.selfSpeed() <= speedAlertValue:
ai.thrust(1)
elif left135Wall <= TrackFastAlertValue and ai.selfSpeed() >= speedAlertValue:
ai.thrust(1)
elif left135Wall <= TrackSlowAlertValue and ai.selfSpeed() <= speedAlertValue:
ai.thrust(1)
elif right135Wall <= TrackFastAlertValue and ai.selfSpeed() >= speedAlertValue:
ai.thrust(1)
elif right135Wall <= TrackSlowAlertValue and ai.selfSpeed() <= speedAlertValue:
ai.thrust(1)
##### Bullet Avoidance Commands #####
elif ai.shotAlert(0) >= 0 and ai.shotAlert(0) <= BulletAlertValue:
if ai.angleDiff(heading, ai.shotVelDir(0)) > 0 and ai.selfSpeed() <= speedAlertValue:
ai.turnLeft(1)
ai.thrust(1)
elif ai.angleDiff(heading, ai.shotVelDir(0)) < 0 and ai.selfSpeed() <= speedAlertValue:
ai.turnRight(1)
ai.thrust(1)
elif ai.angleDiff(heading, ai.shotVelDir(0)) > 0 and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
else:
ai.turnRight(1)
##### Shooting Ennemy Commands #####
elif enemyDist <= EnemyAlertValue and heading > (head) and ai.selfSpeed() > speedAlertValue:
ai.turnRight(1)
ai.fireShot()
elif enemyDist <= EnemyAlertValue and heading < (head) and ai.selfSpeed() > speedAlertValue:
ai.turnLeft(1)
ai.fireShot()
elif ai.selfSpeed() < speedAlertValue:
ai.thrust(1)
else:
ai.thrust(0)
count_frame += 3
boolean = False
def AI_loop():
#Release keys
ai.thrust(0)
ai.turnLeft(0)
ai.turnRight(0)
#Set variables
heading = int(ai.selfHeadingDeg())
tracking = int(ai.selfTrackingDeg())
frontWall = ai.wallFeeler(500, heading)
left45Wall = ai.wallFeeler(500, heading + 45)
right45Wall = ai.wallFeeler(500, heading - 45)
left90Wall = ai.wallFeeler(500, heading + 90)
right90Wall = ai.wallFeeler(500, heading - 90)
left135Wall = ai.wallFeeler(500, heading + 135)
right135Wall = ai.wallFeeler(500, heading - 135)
backWall = ai.wallFeeler(500, heading - 180)
trackWall = ai.wallFeeler(500, tracking)
####### Shooting Ennemies ########
##Find the closest ennemy##
ClosestID = ai.closestShipId()
#print(ClosestID)
##Get the closest ennemy direction and speed##
ClosestSpeed = ai.enemySpeedId(ClosestID)
#print(ClosestSpeed)
ClosestDir = ai.enemyTrackingDegId(ClosestID)
#print(ClosestDir)
## Get the lockheadingdeg ##
enemy = ai.lockNext()
print(enemy)
head = ai.lockHeadingDeg()
print(head)
enemyDist = ai.selfLockDist()
print(enemyDist)
### Turning Rules ###
if frontWall <= 200 and (left45Wall < right45Wall):
print("turning right")
ai.turnRight(1)
elif frontWall <= 200 and (left45Wall > right45Wall):
ai.turnLeft(1)
elif left90Wall <= 200:
print("turning right")
ai.turnRight(1)
elif right90Wall <= 200:
print("turning left")
ai.turnLeft(1)
### Thrust commands ####
elif ai.selfSpeed() <= 10 and (frontWall >= 200) and (
left45Wall >= 200) and (right45Wall >= 200) and (
right90Wall >= 200) and (left90Wall >= 200) and (
left135Wall >= 50) and (right135Wall >= 50) and (backWall
>= 50):
print("go forward")
ai.thrust(1)
elif trackWall < 75 and ai.selfSpeed() >= 10:
ai.thrust(1)
elif trackWall < 50 and ai.selfSpeed() <= 10:
ai.thrust(1)
elif backWall <= 75:
ai.thrust(1)
elif left135Wall <= 75:
ai.thrust(1)
elif right135Wall <= 75:
ai.thrust(1)
##### Shooting Ennemy Commands #####
elif enemyDist <= 500 and heading > (head):
ai.turnRight(1)
ai.fireShot()
elif enemyDist <= 500 and heading < (head):
ai.turnLeft(1)
ai.fireShot()
else:
print("chilling")
ai.thrust(0)