Refactor intcode machine so that it's actually usable

aoc/src/main/scala/aoc/y2019/Day02.scala

@@ -1,22 +1,20 @@
 package aoc.y2019
 
 import aoc.Day
+import cats._
+import cats.implicits._
 import cats.data.State
 
 object Day02 extends Day {
 
-  import Day05.Machine, Day05.MachineState, Day05.executeMachine
-
-  def initialReplacement(noun: Int, verb: Int): MachineState = State { m =>
-      (m.copy(m.memory.updated(1, noun).updated(2, verb)), false)
-  }
+  def initialReplacement(noun: Int, verb: Int): Intcode.Operation = Intcode.set(1, noun) *> Intcode.set(2, verb)
 
   def runMachine(memory: Vector[Int], noun: Int, verb: Int): Int = {
-    val initialState = Machine(memory)
+    val initialState = Intcode.Machine(memory)
     val runMachine = for {
       _ <- initialReplacement(noun, verb)
-      run <- executeMachine
-    } yield run
+      ran <- Intcode.run
+    } yield ran
     val endState = runMachine.runS(initialState).value
     endState.memory(0)
   }

aoc/src/main/scala/aoc/y2019/Day05.scala

@@ -7,134 +7,13 @@ import cats.data.State
 
 object Day05 extends Day {
 
-  case class Oresult(result: Option[Int], appendOutput: Vector[Int], newPointer: Option[Int])
-  object Oresult {
-    def apply(result: Int): Oresult = Oresult(result.some, Vector.empty, None)
-  }
-
-  sealed trait Operation {
-    val opcode: Int
-    val operandCount: Int
-    val inputCount: Int
-    def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult
-  }
-  case object Add extends Operation {
-    override val opcode: Int = 1
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(operands(0) + operands(1))
-  }
-  case object Multiply extends Operation {
-    override val opcode: Int = 2
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(operands(0) * operands(1))
-  }
-  case object Input extends Operation {
-    override val opcode: Int = 3
-    override val operandCount: Int = 0
-    override val inputCount: Int = 1
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(inputs.headOption, Vector.empty, None)
-  }
-  case object Output extends Operation {
-    override val opcode: Int = 4
-    override val operandCount: Int = 1
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(None, operands, None)
-  }
-  case object JumpIfTrue extends Operation {
-    override val opcode: Int = 5
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(None, Vector.empty, Option.when(operands(0) != 0)(operands(1)))
-  }
-  case object JumpIfFalse extends Operation {
-    override val opcode: Int = 6
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(None, Vector.empty, Option.when(operands(0) == 0)(operands(1)))
-  }
-  case object LessThan extends Operation {
-    override val opcode: Int = 7
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(if(operands(0) < operands(1)) 1 else 0)
-  }
-  case object Equal extends Operation {
-    override val opcode: Int = 8
-    override val operandCount: Int = 2
-    override val inputCount: Int = 0
-    override def apply(operands: Vector[Int], inputs: Vector[Int]): Oresult = Oresult(if(operands(0) == operands(1)) 1 else 0)
-  }
-
-  object Operation {
-    val all: Map[Int, Operation] = Seq(
-      Add,
-      Multiply,
-      Input,
-      Output,
-      JumpIfTrue,
-      JumpIfFalse,
-      LessThan,
-      Equal
-    ).map(op => (op.opcode, op)).toMap
-  }
-
-  case class Machine(memory: Vector[Int], pointer: Int = 0 , input: Vector[Int] = Vector.empty, output: Vector[Int] = Vector.empty)
-  type MachineState = State[Machine, Boolean]
-
-  def inputNumber(num: Int): MachineState = State { machine =>
-    (machine.copy(input = machine.input :+ num), false)
-  }
-
-  val executeMachine: MachineState = State { machine =>
-    lazy val states: LazyList[(Machine, Boolean)] =
-      (machine, false) #:: states.map {
-        case (state, true) => (state, true)
-        case (m @ Machine(memory, pointer, input, output), false) =>
-          memory(pointer) match {
-            case 99 => (m, true)
-            case opcode =>
-              val operation = Operation.all(opcode % 100)
-              val operandCount = operation.operandCount
-              val inputCount = operation.inputCount
-              val inputs = input.take(inputCount)
-              val immediateParameters = (1 to operandCount).toVector.map { operandNum =>
-                val divide = Math.pow(10, operandNum + 1).toInt
-                val modulo = Math.pow(10, operandNum + 2).toInt
-                ((opcode % modulo) / divide) == 1
-              }
-              val operands = (1 to operandCount).toVector.zip(immediateParameters).map {
-                case (operandNum, false) => memory(memory(pointer + operandNum))
-                case (operandNum, true) => memory(pointer + operandNum)
-              }
-              val Oresult(result, appendOutput, changePointer) = operation(operands, inputs)
-
-              val newMemory = result match  {
-                case Some(result) => memory.updated(memory(pointer + operandCount + 1), result)
-                case None => memory
-              }
-              val newPointer = (result, changePointer) match {
-                case (_, Some(newAddress)) => newAddress
-                case (Some(_), None) => pointer + operandCount + 2
-                case (None, None) => pointer + operandCount + 1
-              }
-              val newInput = input.drop(inputCount)
-              val newOutput = output ++ appendOutput
-
-              (Machine(newMemory, newPointer, newInput, newOutput), false)
-          }
-      }
-    states.takeWhile(!_._2).last
-  }
-
   def diagnostic(input: String, diagnosticNumber: Int): Int = {
     val memory = input.split(",").toVector.map(_.toInt)
-    val initialState = Machine(memory)
+    val initialState = Intcode.Machine(memory)
     val machineInput = diagnosticNumber
-    val runMachine: MachineState = for {
-      _ <- inputNumber(machineInput)
-      ran <- executeMachine
+    val runMachine: Intcode.Operation = for {
+      _ <- Intcode.input(machineInput)
+      ran <- Intcode.run
     } yield ran
     val endState = runMachine.runS(initialState).value
     endState.output.last

aoc/src/main/scala/aoc/y2019/Intcode.scala

@@ -0,0 +1,121 @@
+package aoc.y2019
+
+import cats._
+import cats.implicits._
+import cats.data.{Kleisli, State}
+
+object Intcode {
+
+  case class Machine(memory: Vector[Int], pc: Int = 0, input: Vector[Int] = Vector.empty, output: Vector[Int] = Vector.empty)
+  type Operation = State[Machine, Unit]
+
+  type Instruction = Kleisli[State[Machine, *], LazyList[Boolean], Unit]
+  val instructions: Map[Int, Instruction] = Map(
+    1 -> Instruction.add,
+    2 -> Instruction.multiply,
+    3 -> Instruction.input,
+    4 -> Instruction.output,
+    5 -> Instruction.jumpIfTrue,
+    6 -> Instruction.jumpIfFalse,
+    7 -> Instruction.lessThan,
+    8 -> Instruction.equals,
+  )
+
+  val parse: State[Machine, (Instruction, LazyList[Boolean])] = State.inspect {
+    machine: Machine =>
+      val instructionAndFlags = machine.memory(machine.pc)
+      val instruction: Instruction = instructions(instructionAndFlags % 100)
+      val flags: LazyList[Boolean] = {
+        val flagString = instructionAndFlags.toString.reverseIterator.drop(2)
+        val flagIterator = flagString.map(_ == '1')
+        LazyList.from(flagIterator) ++ LazyList.continually(false)
+      }
+      (instruction, flags)
+  }
+  val step: Operation = for {
+    (instruction, flags) <- parse
+    _ <- advance(1)
+    result <- instruction.run(flags)
+  } yield result
+  val run: Operation = step.untilM[Vector](State.inspect(machine => machine.memory(machine.pc) % 100 == 99)).map(_.last)
+
+  val noop: Operation = State.pure(())
+
+  def goto(address: Int): Operation = State.modify(_.copy(pc = address))
+  val location: State[Machine, Int] = State.inspect(_.pc)
+  def advance(by: Int): Operation = location.flatMap(c => goto(c + by))
+
+  def set(address: Int, value: Int): Operation = State.modify { machine =>
+    val newMemory = machine.memory.updated(address, value)
+    machine.copy(memory = newMemory)
+  }
+  def get(address: Int): State[Machine, Int] = State.inspect(_.memory(address))
+
+  def input(value: Int): Operation = State.modify { machine =>
+    machine.copy(input = machine.input :+ value)
+  }
+  val pullInput: State[Machine, Int] = State { machine =>
+    (machine.copy(input = machine.input.tail), machine.input.head)
+  }
+
+  def output(value: Int): Operation = State.modify { machine =>
+    machine.copy(output = machine.output :+ value)
+  }
+
+  object Instruction {
+
+    def trans(operandCount: Int, operation: Kleisli[State[Machine, *], Vector[Int], Unit]): Instruction = Kleisli {
+      flags: LazyList[Boolean] =>
+        State.inspect { machine: Machine =>
+          machine.memory.view
+            .slice(machine.pc, machine.pc + operandCount)
+            .zip(flags)
+            .map {
+              case (argument, true) => argument
+              case (argument, false) => machine.memory(argument)
+            }
+            .toVector
+        }.flatMap(operation.run)
+    }
+    def op(operandCount: Int, operation: Vector[Int] => Int): Instruction =
+      trans(operandCount, Kleisli(operation.map { result =>
+        for {
+          loc <- location
+          outputAddr <- get(loc + operandCount)
+          _ <- set(outputAddr, result)
+          advance <- advance(operandCount + 1)
+        } yield advance
+      }))
+
+    val add: Instruction = op(operandCount = 2, { case Vector(a, b) => a + b })
+    val multiply: Instruction = op(operandCount = 2, { case Vector(a, b) => a * b })
+    val input: Instruction = Kleisli { _ =>
+      for {
+        loc <- location
+        toAddr <- get(loc)
+        input <- pullInput
+        _ <- set(toAddr, input)
+        advance <- advance(1)
+      } yield advance
+    }
+    val output: Instruction = trans(1, Kleisli {
+      case Vector(value) => Intcode.output(value) *> advance(1)
+    })
+    val jumpIfTrue: Instruction = trans(2, Kleisli {
+      case Vector(condition, newAddr) => if(condition != 0) goto(newAddr) else advance(2)
+    })
+    val jumpIfFalse: Instruction = trans(2, Kleisli {
+      case Vector(condition, newAddr) => if(condition == 0) goto(newAddr) else advance(2)
+    })
+    val lessThan: Instruction = op(2, {
+      case Vector(a, b) if a < b => 1
+      case Vector(_, _) => 0
+    })
+    val equals: Instruction = op(2, {
+      case Vector(a, b) if a == b => 1
+      case Vector(_, _) => 0
+    })
+
+  }
+
+}

build.sbt

@@ -12,6 +12,8 @@ val sharedSettings = Seq(
     "org.typelevel" %%% "cats-free"    % "2.0.0",
   ),
   mainClass := Some("tf.bug.aoc.Main"),
+  addCompilerPlugin("org.typelevel" %% "kind-projector" % "0.11.0" cross CrossVersion.full),
+  addCompilerPlugin("com.olegpy" %% "better-monadic-for" % "0.3.1"),
 )
 
 // lazy val aoc = crossProject(/* JSPlatform, */ JVMPlatform /* , NativePlatform */ )