Created
May 21, 2012 04:42
-
-
Save scalatron/2760581 to your computer and use it in GitHub Desktop.
Brian McKenna's Bot from Scalatron hack night at ScalaSyd May 9, 2012
This file contains bidirectional Unicode text that may be interpreted or compiled differently than what appears below. To review, open the file in an editor that reveals hidden Unicode characters.
Learn more about bidirectional Unicode characters
// Brian McKenna's Bot - based on Scalatron Reference Bot - from Scalatron hack night at ScalaSyd May 9, 2012 | |
import util.Random | |
object ControlFunction | |
{ | |
def forMaster(bot: Bot) { | |
val (directionValue, nearestEnemyMaster, nearestEnemySlave, nearestGoodBeast, nearestGoodPlant) = analyzeViewAsMaster(bot.view) | |
val dontFireMissileUntil = bot.inputAsIntOrElse("dontFireMissileUntil", -1) | |
val lastDirection = bot.inputAsIntOrElse("lastDirection", 0) | |
val botCount = bot.inputAsIntOrElse("botCount", 0) | |
// determine movement direction | |
directionValue(lastDirection) += 10 // try to break ties by favoring the last direction | |
val bestDirection45 = directionValue.zipWithIndex.maxBy(_._1)._2 | |
val direction = XY.fromDirection45(bestDirection45) | |
bot.move(direction) | |
bot.set("lastDirection" -> bestDirection45) | |
bot.view.offsetToNearest('s').orElse(bot.view.offsetToNearest('P')).orElse(bot.view.offsetToNearest('B')) match { | |
case None => | |
case Some(relPos) => | |
val unitDelta = relPos.signum | |
val remainder = relPos - unitDelta // we place slave nearer target, so subtract that from overall delta | |
bot.spawn(unitDelta, "target" -> remainder) | |
} | |
} | |
def forSlave(bot: MiniBot) { | |
if(bot.time >= (5000 - bot.offsetToMaster.length) - 5) { | |
bot.move(bot.offsetToMaster) | |
return | |
} | |
bot.view.offsetToNearest('m') match { | |
case Some(delta: XY) => | |
if(delta.length <= 2) { | |
// yes -- blow it up! | |
bot.explode(4) | |
return | |
} | |
case None => | |
} | |
if(bot.energy > 1000) { | |
bot.move(bot.offsetToMaster) | |
return | |
} else if(bot.energy > 100) { | |
bot.view.offsetToNearest('M') match { | |
case Some(delta: XY) => | |
bot.move(delta.signum) | |
bot.set("rx" -> delta.x, "ry" -> delta.y) | |
return | |
case None => | |
} | |
} | |
bot.view.offsetToNearest('s').orElse(bot.view.offsetToNearest('P')).orElse(bot.view.offsetToNearest('B')) match { | |
case Some(delta: XY) => | |
// another slave is visible at the given relative position (i.e. position delta) | |
// move closer! | |
bot.move(delta.signum) | |
bot.set("rx" -> delta.x, "ry" -> delta.y) | |
case None => | |
bot.view.offsetToNearest('W') match { | |
case Some(delta: XY) => | |
bot.move(delta.negate) | |
case None => | |
// no target visible -- follow our targeting strategy | |
val target = bot.inputAsXYOrElse("target", XY.Zero) | |
// did we arrive at the target? | |
if(target.isNonZero) { | |
// no -- keep going | |
val unitDelta = target.signum // e.g. CellPos(-8,6) => CellPos(-1,1) | |
bot.move(unitDelta) | |
// compute the remaining delta and encode it into a new 'target' property | |
val remainder = target - unitDelta // e.g. = CellPos(-7,5) | |
bot.set("target" -> remainder) | |
} else { | |
bot.move(XY(Random.nextInt, Random.nextInt)) | |
} | |
} | |
} | |
} | |
/** Analyze the view, building a map of attractiveness for the 45-degree directions and | |
* recording other relevant data, such as the nearest elements of various kinds. | |
*/ | |
def analyzeViewAsMaster(view: View) = { | |
val directionValue = Array.ofDim[Double](8) | |
var nearestEnemyMaster: Option[XY] = None | |
var nearestEnemySlave: Option[XY] = None | |
var nearestGoodBeast: Option[XY] = None | |
var nearestGoodPlant: Option[XY] = None | |
val cells = view.cells | |
val cellCount = cells.length | |
for(i <- 0 until cellCount) { | |
val cellRelPos = view.relPosFromIndex(i) | |
if(cellRelPos.isNonZero) { | |
val stepDistance = cellRelPos.stepCount | |
val value: Double = cells(i) match { | |
case 'm' => // another master: not dangerous, but an obstacle | |
nearestEnemyMaster = Some(cellRelPos) | |
if(stepDistance < 2) -1000 else 0 | |
case 's' => // another slave: potentially dangerous? | |
nearestEnemySlave = Some(cellRelPos) | |
-100 / stepDistance | |
case 'S' => // out own slave | |
100 | |
case 'B' => // good beast: valuable, but runs away | |
nearestGoodBeast = Some(cellRelPos) | |
if(stepDistance == 1) 600 | |
else if(stepDistance == 2) 300 | |
else (150 - stepDistance * 15).max(10) | |
case 'P' => // good plant: less valuable, but does not run | |
nearestGoodPlant = Some(cellRelPos) | |
if(stepDistance == 1) 500 | |
else if(stepDistance == 2) 300 | |
else (150 - stepDistance * 10).max(10) | |
case 'b' => // bad beast: dangerous, but only if very close | |
if(stepDistance < 4) -400 / stepDistance else -50 / stepDistance | |
case 'p' => // bad plant: bad, but only if I step on it | |
if(stepDistance < 2) -1000 else 0 | |
case 'W' => // wall: harmless, just don't walk into it | |
if(stepDistance < 2) -1000 else 0 | |
case _ => 0.0 | |
} | |
val direction45 = cellRelPos.toDirection45 | |
directionValue(direction45) += value | |
} | |
} | |
(directionValue, nearestEnemyMaster, nearestEnemySlave, nearestGoodBeast, nearestGoodPlant) | |
} | |
} | |
// ------------------------------------------------------------------------------------------------- | |
// Framework | |
// ------------------------------------------------------------------------------------------------- | |
class ControlFunctionFactory { | |
def create = (input: String) => { | |
val (opcode, params) = CommandParser(input) | |
opcode match { | |
case "React" => | |
val bot = new BotImpl(params) | |
if( bot.generation == 0 ) { | |
ControlFunction.forMaster(bot) | |
} else { | |
ControlFunction.forSlave(bot) | |
} | |
bot.toString | |
case _ => "" // OK | |
} | |
} | |
} | |
// ------------------------------------------------------------------------------------------------- | |
trait Bot { | |
// inputs | |
def inputOrElse(key: String, fallback: String): String | |
def inputAsIntOrElse(key: String, fallback: Int): Int | |
def inputAsXYOrElse(keyPrefix: String, fallback: XY): XY | |
def view: View | |
def energy: Int | |
def time: Int | |
def generation: Int | |
// outputs | |
def move(delta: XY) : Bot | |
def say(text: String) : Bot | |
def status(text: String) : Bot | |
def spawn(offset: XY, params: (String,Any)*) : Bot | |
def set(params: (String,Any)*) : Bot | |
def log(text: String) : Bot | |
} | |
trait MiniBot extends Bot { | |
// inputs | |
def offsetToMaster: XY | |
// outputs | |
def explode(blastRadius: Int) : Bot | |
} | |
case class BotImpl(inputParams: Map[String, String]) extends MiniBot { | |
// input | |
def inputOrElse(key: String, fallback: String) = inputParams.getOrElse(key, fallback) | |
def inputAsIntOrElse(key: String, fallback: Int) = inputParams.get(key).map(_.toInt).getOrElse(fallback) | |
def inputAsXYOrElse(key: String, fallback: XY) = inputParams.get(key).map(s => XY(s)).getOrElse(fallback) | |
val view = View(inputParams("view")) | |
val energy = inputParams("energy").toInt | |
val time = inputParams("time").toInt | |
val generation = inputParams("generation").toInt | |
def offsetToMaster = inputAsXYOrElse("master", XY.Zero) | |
// output | |
private var stateParams = Map.empty[String,Any] // holds "Set()" commands | |
private var commands = "" // holds all other commands | |
private var debugOutput = "" // holds all "Log()" output | |
/** Appends a new command to the command string; returns 'this' for fluent API. */ | |
private def append(s: String) : Bot = { commands += (if(commands.isEmpty) s else "|" + s); this } | |
/** Renders commands and stateParams into a control function return string. */ | |
override def toString = { | |
var result = commands | |
if(!stateParams.isEmpty) { | |
if(!result.isEmpty) result += "|" | |
result += stateParams.map(e => e._1 + "=" + e._2).mkString("Set(",",",")") | |
} | |
if(!debugOutput.isEmpty) { | |
if(!result.isEmpty) result += "|" | |
result += "Log(text=" + debugOutput + ")" | |
} | |
result | |
} | |
def log(text: String) = { debugOutput += text + "\n"; this } | |
def move(direction: XY) = append("Move(direction=" + direction + ")") | |
def say(text: String) = append("Say(text=" + text + ")") | |
def status(text: String) = append("Status(text=" + text + ")") | |
def explode(blastRadius: Int) = append("Explode(size=" + blastRadius + ")") | |
def spawn(offset: XY, params: (String,Any)*) = | |
append("Spawn(direction=" + offset + | |
(if(params.isEmpty) "" else "," + params.map(e => e._1 + "=" + e._2).mkString(",")) + | |
")") | |
def set(params: (String,Any)*) = { stateParams ++= params; this } | |
def set(keyPrefix: String, xy: XY) = { stateParams ++= List(keyPrefix+"x" -> xy.x, keyPrefix+"y" -> xy.y); this } | |
} | |
// ------------------------------------------------------------------------------------------------- | |
/** Utility methods for parsing strings containing a single command of the format | |
* "Command(key=value,key=value,...)" | |
*/ | |
object CommandParser { | |
/** "Command(..)" => ("Command", Map( ("key" -> "value"), ("key" -> "value"), ..}) */ | |
def apply(command: String): (String, Map[String, String]) = { | |
/** "key=value" => ("key","value") */ | |
def splitParameterIntoKeyValue(param: String): (String, String) = { | |
val segments = param.split('=') | |
(segments(0), if(segments.length>=2) segments(1) else "") | |
} | |
val segments = command.split('(') | |
if( segments.length != 2 ) | |
throw new IllegalStateException("invalid command: " + command) | |
val opcode = segments(0) | |
val params = segments(1).dropRight(1).split(',') | |
val keyValuePairs = params.map(splitParameterIntoKeyValue).toMap | |
(opcode, keyValuePairs) | |
} | |
} | |
// ------------------------------------------------------------------------------------------------- | |
/** Utility class for managing 2D cell coordinates. | |
* The coordinate (0,0) corresponds to the top-left corner of the arena on screen. | |
* The direction (1,-1) points right and up. | |
*/ | |
case class XY(x: Int, y: Int) { | |
override def toString = x + ":" + y | |
def isNonZero = x != 0 || y != 0 | |
def isZero = x == 0 && y == 0 | |
def isNonNegative = x >= 0 && y >= 0 | |
def updateX(newX: Int) = XY(newX, y) | |
def updateY(newY: Int) = XY(x, newY) | |
def addToX(dx: Int) = XY(x + dx, y) | |
def addToY(dy: Int) = XY(x, y + dy) | |
def +(pos: XY) = XY(x + pos.x, y + pos.y) | |
def -(pos: XY) = XY(x - pos.x, y - pos.y) | |
def *(factor: Double) = XY((x * factor).intValue, (y * factor).intValue) | |
def distanceTo(pos: XY): Double = (this - pos).length // Phythagorean | |
def length: Double = math.sqrt(x * x + y * y) // Phythagorean | |
def stepsTo(pos: XY): Int = (this - pos).stepCount // steps to reach pos: max delta X or Y | |
def stepCount: Int = x.abs.max(y.abs) // steps from (0,0) to get here: max X or Y | |
def signum = XY(x.signum, y.signum) | |
def negate = XY(-x, -y) | |
def negateX = XY(-x, y) | |
def negateY = XY(x, -y) | |
/** Returns the direction index with 'Right' being index 0, then clockwise in 45 degree steps. */ | |
def toDirection45: Int = { | |
val unit = signum | |
unit.x match { | |
case -1 => | |
unit.y match { | |
case -1 => | |
if(x < y * 3) Direction45.Left | |
else if(y < x * 3) Direction45.Up | |
else Direction45.UpLeft | |
case 0 => | |
Direction45.Left | |
case 1 => | |
if(-x > y * 3) Direction45.Left | |
else if(y > -x * 3) Direction45.Down | |
else Direction45.LeftDown | |
} | |
case 0 => | |
unit.y match { | |
case 1 => Direction45.Down | |
case 0 => throw new IllegalArgumentException("cannot compute direction index for (0,0)") | |
case -1 => Direction45.Up | |
} | |
case 1 => | |
unit.y match { | |
case -1 => | |
if(x > -y * 3) Direction45.Right | |
else if(-y > x * 3) Direction45.Up | |
else Direction45.RightUp | |
case 0 => | |
Direction45.Right | |
case 1 => | |
if(x > y * 3) Direction45.Right | |
else if(y > x * 3) Direction45.Down | |
else Direction45.DownRight | |
} | |
} | |
} | |
def rotateCounterClockwise45 = XY.fromDirection45((signum.toDirection45 + 1) % 8) | |
def rotateCounterClockwise90 = XY.fromDirection45((signum.toDirection45 + 2) % 8) | |
def rotateClockwise45 = XY.fromDirection45((signum.toDirection45 + 7) % 8) | |
def rotateClockwise90 = XY.fromDirection45((signum.toDirection45 + 6) % 8) | |
def wrap(boardSize: XY) = { | |
val fixedX = if(x < 0) boardSize.x + x else if(x >= boardSize.x) x - boardSize.x else x | |
val fixedY = if(y < 0) boardSize.y + y else if(y >= boardSize.y) y - boardSize.y else y | |
if(fixedX != x || fixedY != y) XY(fixedX, fixedY) else this | |
} | |
} | |
object XY { | |
/** Parse an XY value from XY.toString format, e.g. "2:3". */ | |
def apply(s: String) : XY = { val a = s.split(':'); XY(a(0).toInt,a(1).toInt) } | |
val Zero = XY(0, 0) | |
val One = XY(1, 1) | |
val Right = XY( 1, 0) | |
val RightUp = XY( 1, -1) | |
val Up = XY( 0, -1) | |
val UpLeft = XY(-1, -1) | |
val Left = XY(-1, 0) | |
val LeftDown = XY(-1, 1) | |
val Down = XY( 0, 1) | |
val DownRight = XY( 1, 1) | |
def fromDirection45(index: Int): XY = index match { | |
case Direction45.Right => Right | |
case Direction45.RightUp => RightUp | |
case Direction45.Up => Up | |
case Direction45.UpLeft => UpLeft | |
case Direction45.Left => Left | |
case Direction45.LeftDown => LeftDown | |
case Direction45.Down => Down | |
case Direction45.DownRight => DownRight | |
} | |
def fromDirection90(index: Int): XY = index match { | |
case Direction90.Right => Right | |
case Direction90.Up => Up | |
case Direction90.Left => Left | |
case Direction90.Down => Down | |
} | |
def apply(array: Array[Int]): XY = XY(array(0), array(1)) | |
} | |
object Direction45 { | |
val Right = 0 | |
val RightUp = 1 | |
val Up = 2 | |
val UpLeft = 3 | |
val Left = 4 | |
val LeftDown = 5 | |
val Down = 6 | |
val DownRight = 7 | |
} | |
object Direction90 { | |
val Right = 0 | |
val Up = 1 | |
val Left = 2 | |
val Down = 3 | |
} | |
// ------------------------------------------------------------------------------------------------- | |
case class View(cells: String) { | |
val size = math.sqrt(cells.length).toInt | |
val center = XY(size / 2, size / 2) | |
def apply(relPos: XY) = cellAtRelPos(relPos) | |
def indexFromAbsPos(absPos: XY) = absPos.x + absPos.y * size | |
def absPosFromIndex(index: Int) = XY(index % size, index / size) | |
def absPosFromRelPos(relPos: XY) = relPos + center | |
def cellAtAbsPos(absPos: XY) = cells.charAt(indexFromAbsPos(absPos)) | |
def indexFromRelPos(relPos: XY) = indexFromAbsPos(absPosFromRelPos(relPos)) | |
def relPosFromAbsPos(absPos: XY) = absPos - center | |
def relPosFromIndex(index: Int) = relPosFromAbsPos(absPosFromIndex(index)) | |
def cellAtRelPos(relPos: XY) = cells.charAt(indexFromRelPos(relPos)) | |
def offsetToNearest(c: Char) = { | |
val matchingXY = cells.view.zipWithIndex.filter(_._1 == c) | |
if( matchingXY.isEmpty ) | |
None | |
else { | |
val nearest = matchingXY.map(p => relPosFromIndex(p._2)).minBy(_.length) | |
Some(nearest) | |
} | |
} | |
} |
Sign up for free
to join this conversation on GitHub.
Already have an account?
Sign in to comment