Local Mutable Chains

Merge request lab2425_spring/WACC_37!27 Co-authored-by: Jonny <j.sinteix@gmail.com>
2025-02-25 21:13:46 +00:00 · 2025-02-25 21:13:46 +00:00 · 70e023f27a
commit 70e023f27a
parent 7fd92b4212 11c483439c
1 changed files with 304 additions and 323 deletions
--- a/src/main/wacc/backend/asmGenerator.scala
+++ b/src/main/wacc/backend/asmGenerator.scala
@ -2,6 +2,9 @@ package wacc
 import scala.collection.mutable.LinkedHashMap
 import scala.collection.mutable.ListBuffer
 import cats.data.Chain
 import cats.syntax.foldable._
 // import parsley.token.errors.Label
 object asmGenerator {
  import microWacc._
@ -24,330 +27,11 @@ object asmGenerator {
  val _8_BIT_MASK = 0xff
-  def generateAsm(microProg: Program): List[AsmLine] = {
+  extension (chain: Chain[AsmLine])
-    given stack: Stack = Stack()
+    def +(line: AsmLine): Chain[AsmLine] = chain.append(line)
    given strings: ListBuffer[String] = ListBuffer[String]()
    given labelGenerator: LabelGenerator = LabelGenerator()
    val Program(funcs, main) = microProg
-    val progAsm =
+    def concatAll(chains: Chain[AsmLine]*): Chain[AsmLine] =
-      LabelDef("main") ::
+      chains.foldLeft(chain)(_ ++ _)
        funcPrologue() ++
        List(stack.align()) ++
        main.flatMap(generateStmt) ++
        List(Move(RAX, ImmediateVal(0))) ++
        funcEpilogue() ++
        generateBuiltInFuncs()
    val strDirs = strings.toList.zipWithIndex.flatMap { case (str, i) =>
      List(
        Directive.Int(str.size),
        LabelDef(s".L.str$i"),
        Directive.Asciz(str.escaped)
      )
    }
    List(Directive.IntelSyntax, Directive.Global("main"), Directive.RoData) ++
      strDirs ++
      List(Directive.Text) ++
      progAsm
  }
  def wrapFunc(labelName: String, funcBody: List[AsmLine])(using
      stack: Stack,
      strings: ListBuffer[String]
  ): List[AsmLine] = {
    LabelDef(labelName) ::
      funcPrologue() ++
      funcBody ++
      funcEpilogue()
  }
  def generateBuiltInFuncs()(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): List[AsmLine] = {
    wrapFunc(
      labelGenerator.getLabel(Builtin.Exit),
      List(stack.align(), assemblyIR.Call(CLibFunc.Exit))
    ) ++
      wrapFunc(
        labelGenerator.getLabel(Builtin.Printf),
        List(
          stack.align(),
          assemblyIR.Call(CLibFunc.PrintF),
          Move(RDI, ImmediateVal(0)),
          assemblyIR.Call(CLibFunc.Fflush)
        )
      ) ++
      wrapFunc(
        labelGenerator.getLabel(Builtin.Malloc),
        List(
          stack.align()
        )
      ) ++
      wrapFunc(labelGenerator.getLabel(Builtin.Free), List()) ++
      wrapFunc(
        labelGenerator.getLabel(Builtin.Read),
        List(
          stack.align(),
          stack.reserve(),
          stack.push(RSI),
          Load(RSI, stack.head),
          assemblyIR.Call(CLibFunc.Scanf),
          stack.pop(RAX),
          stack.drop()
        )
      )
  }
  def generateStmt(
      stmt: Stmt
  )(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): List[AsmLine] =
    stmt match {
      case Assign(lhs, rhs) =>
        var dest: () => IndexAddress =
          () => IndexAddress(RAX, 0) // gets overrwitten
        (lhs match {
          case ident: Ident =>
            dest = stack.accessVar(ident)
            if (!stack.contains(ident)) {
              List(stack.reserve(ident))
            } else Nil
          // TODO lhs = arrayElem
          case _ =>
            // dest = ???
            List()
        }) ++
          evalExprOntoStack(rhs) ++
          List(
            stack.pop(RAX),
            Move(dest(), RAX)
          )
      case If(cond, thenBranch, elseBranch) => {
        val elseLabel = labelGenerator.getLabel()
        val endLabel = labelGenerator.getLabel()
        evalExprOntoStack(cond) ++
          List(
            Compare(stack.head(SizeDir.Word), ImmediateVal(0)),
            stack.drop(),
            Jump(LabelArg(elseLabel), Cond.Equal)
          ) ++
          thenBranch.flatMap(generateStmt) ++
          List(Jump(LabelArg(endLabel)), LabelDef(elseLabel)) ++
          elseBranch.flatMap(generateStmt) ++
          List(LabelDef(endLabel))
      }
      case While(cond, body) => {
        val startLabel = labelGenerator.getLabel()
        val endLabel = labelGenerator.getLabel()
        List(LabelDef(startLabel)) ++
          evalExprOntoStack(cond) ++
          List(
            Compare(stack.head(SizeDir.Word), ImmediateVal(0)),
            stack.drop(),
            Jump(LabelArg(endLabel), Cond.Equal)
          ) ++
          body.flatMap(generateStmt) ++
          List(Jump(LabelArg(startLabel)), LabelDef(endLabel))
      }
      case microWacc.Return(expr) =>
        evalExprOntoStack(expr) ++
          List(stack.pop(RAX), assemblyIR.Return())
      case call: microWacc.Call => generateCall(call)
    }
  def evalExprOntoStack(expr: Expr)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): List[AsmLine] = {
    val out = expr match {
      case IntLiter(v) =>
        List(stack.push(ImmediateVal(v)))
      case CharLiter(v) =>
        List(stack.push(ImmediateVal(v.toInt)))
      case ident: Ident =>
        List(stack.push(stack.accessVar(ident)()))
      case ArrayLiter(elems) =>
        expr.ty match {
          case KnownType.String =>
            strings += elems.map {
              case CharLiter(v) => v
              case _            => ""
            }.mkString
            List(
              Load(
                RAX,
                IndexAddress(
                  RIP,
                  LabelArg(s".L.str${strings.size - 1}")
                )
              ),
              stack.push(RAX)
            )
          // TODO other array types
          case _ => List()
        }
      case BoolLiter(v)              => List(stack.push(ImmediateVal(if (v) 1 else 0)))
      case NullLiter()               => List(stack.push(ImmediateVal(0)))
      case ArrayElem(value, indices) => List()
      case UnaryOp(x, op) =>
        evalExprOntoStack(x) ++
          (op match {
            // TODO: chr and ord are TYPE CASTS. They do not change the internal value,
            //       but will need bound checking e.t.c.
            case UnaryOperator.Chr => List()
            case UnaryOperator.Ord => List()
            case UnaryOperator.Len => List()
            case UnaryOperator.Negate =>
              List(
                Negate(stack.head(SizeDir.Word))
              )
            case UnaryOperator.Not =>
              evalExprOntoStack(x) ++
                List(
                  Xor(stack.head(SizeDir.Word), ImmediateVal(1))
                )
          })
      case BinaryOp(x, y, op) =>
        op match {
          case BinaryOperator.Add =>
            evalExprOntoStack(x) ++
              evalExprOntoStack(y) ++
              List(
                stack.pop(RAX),
                Add(stack.head(SizeDir.Word), EAX)
                // TODO OVERFLOWING
              )
          case BinaryOperator.Sub =>
            evalExprOntoStack(x) ++
              evalExprOntoStack(y) ++
              List(
                stack.pop(RAX),
                Subtract(stack.head(SizeDir.Word), EAX)
                // TODO OVERFLOWING
              )
          case BinaryOperator.Mul =>
            evalExprOntoStack(x) ++
              evalExprOntoStack(y) ++
              List(
                stack.pop(RAX),
                Multiply(EAX, stack.head(SizeDir.Word)),
                stack.drop(),
                stack.push(RAX)
                // TODO OVERFLOWING
              )
          case BinaryOperator.Div =>
            evalExprOntoStack(y) ++
              evalExprOntoStack(x) ++
              List(
                stack.pop(RAX),
                Divide(stack.head(SizeDir.Word)),
                stack.drop(),
                stack.push(RAX)
                // TODO CHECK DIVISOR IS NOT 0
              )
          case BinaryOperator.Mod =>
            evalExprOntoStack(y) ++
              evalExprOntoStack(x) ++
              List(
                stack.pop(RAX),
                Divide(stack.head(SizeDir.Word)),
                stack.drop(),
                stack.push(RDX)
                // TODO CHECK DIVISOR IS NOT 0
              )
          case BinaryOperator.Eq =>
            generateComparison(x, y, Cond.Equal)
          case BinaryOperator.Neq =>
            generateComparison(x, y, Cond.NotEqual)
          case BinaryOperator.Greater =>
            generateComparison(x, y, Cond.Greater)
          case BinaryOperator.GreaterEq =>
            generateComparison(x, y, Cond.GreaterEqual)
          case BinaryOperator.Less =>
            generateComparison(x, y, Cond.Less)
          case BinaryOperator.LessEq =>
            generateComparison(x, y, Cond.LessEqual)
          case BinaryOperator.And =>
            evalExprOntoStack(x) ++
              evalExprOntoStack(y) ++
              List(
                stack.pop(RAX),
                And(stack.head(SizeDir.Word), EAX)
              )
          case BinaryOperator.Or =>
            evalExprOntoStack(x) ++
              evalExprOntoStack(y) ++
              List(
                stack.pop(RAX),
                Or(stack.head(SizeDir.Word), EAX)
              )
        }
      case call: microWacc.Call =>
        generateCall(call) ++
          List(stack.push(RAX))
    }
    if out.isEmpty then List(stack.push(ImmediateVal(0))) else out
  }
  def generateCall(call: microWacc.Call)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): List[AsmLine] = {
    val argRegs = List(RDI, RSI, RDX, RCX, R8, R9)
    val microWacc.Call(target, args) = call
    argRegs.zip(args).flatMap { (reg, expr) =>
      evalExprOntoStack(expr) ++
        List(stack.pop(reg))
    } ++
      args.drop(argRegs.size).flatMap(evalExprOntoStack) ++
      List(assemblyIR.Call(LabelArg(labelGenerator.getLabel(target)))) ++
      (if (args.size > argRegs.size) {
         List(stack.drop(args.size - argRegs.size))
       } else Nil)
  }
  def generateComparison(x: Expr, y: Expr, cond: Cond)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): List[AsmLine] = {
    evalExprOntoStack(x) ++
      evalExprOntoStack(y) ++
      List(
        stack.pop(RAX),
        Compare(stack.head(SizeDir.Word), EAX),
        Set(Register(RegSize.Byte, RegName.AL), cond),
        And(RAX, ImmediateVal(_8_BIT_MASK)),
        stack.drop(),
        stack.push(RAX)
      )
  }
  // Missing a sub instruction but dont think we need it
  def funcPrologue()(using stack: Stack): List[AsmLine] = {
    List(
      stack.push(RBP),
      Move(RBP, Register(RegSize.R64, RegName.SP))
    )
  }
  def funcEpilogue()(using stack: Stack): List[AsmLine] = {
    List(
      Move(Register(RegSize.R64, RegName.SP), RBP),
      stack.pop(RBP),
      assemblyIR.Return()
    )
  }
  class LabelGenerator {
    var labelVal = -1
@ -361,6 +45,303 @@ object asmGenerator {
    }
  }
  def generateAsm(microProg: Program): List[AsmLine] = {
    given stack: Stack = Stack()
    given strings: ListBuffer[String] = ListBuffer[String]()
    given labelGenerator: LabelGenerator = LabelGenerator()
    val Program(funcs, main) = microProg
    val progAsm = Chain(LabelDef("main")).concatAll(
      funcPrologue(),
      Chain.one(stack.align()),
      main.foldMap(generateStmt(_)),
      Chain.one(Move(RAX, ImmediateVal(0))),
      funcEpilogue(),
      generateBuiltInFuncs()
    )
    val strDirs = strings.toList.zipWithIndex.foldMap { case (str, i) =>
      Chain(
        Directive.Int(str.size),
        LabelDef(s".L.str$i"),
        Directive.Asciz(str.escaped)
      )
    }
    Chain(
      Directive.IntelSyntax,
      Directive.Global("main"),
      Directive.RoData
    ).concatAll(
      strDirs,
      Chain.one(Directive.Text),
      progAsm
    ).toList
  }
  def wrapFunc(labelName: String, funcBody: Chain[AsmLine])(using
      stack: Stack,
      strings: ListBuffer[String]
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    chain += LabelDef(labelName)
    chain ++= funcPrologue()
    chain ++= funcBody
    chain ++= funcEpilogue()
    chain
  }
  def generateBuiltInFuncs()(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    chain ++= wrapFunc(
      labelGenerator.getLabel(Builtin.Exit),
      Chain(stack.align(), assemblyIR.Call(CLibFunc.Exit))
    )
    chain ++= wrapFunc(
      labelGenerator.getLabel(Builtin.Printf),
      Chain(
        stack.align(),
        assemblyIR.Call(CLibFunc.PrintF),
        Move(RDI, ImmediateVal(0)),
        assemblyIR.Call(CLibFunc.Fflush)
      )
    )
    chain ++= wrapFunc(
      labelGenerator.getLabel(Builtin.Malloc),
      Chain.one(stack.align())
    )
    chain ++= wrapFunc(labelGenerator.getLabel(Builtin.Free), Chain.empty)
    chain ++= wrapFunc(
      labelGenerator.getLabel(Builtin.Read),
      Chain(
        stack.align(),
        stack.reserve(),
        stack.push(RSI),
        Load(RSI, stack.head),
        assemblyIR.Call(CLibFunc.Scanf),
        stack.pop(RAX),
        stack.drop()
      )
    )
    chain
  }
  def generateStmt(stmt: Stmt)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    stmt match {
      case Assign(lhs, rhs) =>
        var dest: () => IndexAddress = () => IndexAddress(RAX, 0) // overwritten below
        lhs match {
          case ident: Ident =>
            dest = stack.accessVar(ident)
            if (!stack.contains(ident)) chain += stack.reserve(ident)
          // TODO lhs = arrayElem
          case _ =>
        }
        chain ++= evalExprOntoStack(rhs)
        chain += stack.pop(RAX)
        chain += Move(dest(), RAX)
      case If(cond, thenBranch, elseBranch) =>
        val elseLabel = labelGenerator.getLabel()
        val endLabel = labelGenerator.getLabel()
        chain ++= evalExprOntoStack(cond)
        chain += Compare(stack.head(SizeDir.Word), ImmediateVal(0))
        chain += stack.drop()
        chain += Jump(LabelArg(elseLabel), Cond.Equal)
        chain ++= Chain.fromSeq(thenBranch).flatMap(generateStmt)
        chain += Jump(LabelArg(endLabel))
        chain += LabelDef(elseLabel)
        chain ++= Chain.fromSeq(elseBranch).flatMap(generateStmt)
        chain += LabelDef(endLabel)
      case While(cond, body) =>
        val startLabel = labelGenerator.getLabel()
        val endLabel = labelGenerator.getLabel()
        chain += LabelDef(startLabel)
        chain ++= evalExprOntoStack(cond)
        chain += Compare(stack.head(SizeDir.Word), ImmediateVal(0))
        chain += stack.drop()
        chain += Jump(LabelArg(endLabel), Cond.Equal)
        chain ++= Chain.fromSeq(body).flatMap(generateStmt)
        chain += Jump(LabelArg(startLabel))
        chain += LabelDef(endLabel)
      case microWacc.Return(expr) =>
        chain ++= evalExprOntoStack(expr)
        chain += stack.pop(RAX)
        chain += assemblyIR.Return()
      case call: microWacc.Call =>
        chain ++= generateCall(call)
    }
    chain
  }
  def evalExprOntoStack(expr: Expr)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    expr match {
      case IntLiter(v)  => chain += stack.push(ImmediateVal(v))
      case CharLiter(v) => chain += stack.push(ImmediateVal(v.toInt))
      case ident: Ident => chain += stack.push(stack.accessVar(ident)())
      case ArrayLiter(elems) =>
        expr.ty match {
          case KnownType.String =>
            strings += elems.collect { case CharLiter(v) => v }.mkString
            chain += Load(RAX, IndexAddress(RIP, LabelArg(s".L.str${strings.size - 1}")))
            chain += stack.push(RAX)
          case _ => // Other array types TODO
        }
      case BoolLiter(v)    => chain += stack.push(ImmediateVal(if (v) 1 else 0))
      case NullLiter()     => chain += stack.push(ImmediateVal(0))
      case ArrayElem(_, _) => // TODO: Implement handling
      case UnaryOp(x, op) =>
        chain ++= evalExprOntoStack(x)
        op match {
          case UnaryOperator.Chr | UnaryOperator.Ord | UnaryOperator.Len => // No op needed
          case UnaryOperator.Negate => chain += Negate(stack.head(SizeDir.Word))
          case UnaryOperator.Not =>
            chain += Xor(stack.head(SizeDir.Word), ImmediateVal(1))
        }
      case BinaryOp(x, y, op) =>
        chain ++= evalExprOntoStack(x)
        chain ++= evalExprOntoStack(y)
        chain += stack.pop(RAX)
        op match {
          case BinaryOperator.Add => chain += Add(stack.head(SizeDir.Word), EAX)
          case BinaryOperator.Sub => chain += Subtract(stack.head(SizeDir.Word), EAX)
          case BinaryOperator.Mul =>
            chain += Multiply(EAX, stack.head(SizeDir.Word))
            chain += stack.drop()
            chain += stack.push(RAX)
          case BinaryOperator.Div =>
            chain += Divide(stack.head(SizeDir.Word))
            chain += stack.drop()
            chain += stack.push(RAX)
          case BinaryOperator.Mod =>
            chain += Divide(stack.head(SizeDir.Word))
            chain += stack.drop()
            chain += stack.push(RDX)
          case BinaryOperator.Eq        => chain ++= generateComparison(x, y, Cond.Equal)
          case BinaryOperator.Neq       => chain ++= generateComparison(x, y, Cond.NotEqual)
          case BinaryOperator.Greater   => chain ++= generateComparison(x, y, Cond.Greater)
          case BinaryOperator.GreaterEq => chain ++= generateComparison(x, y, Cond.GreaterEqual)
          case BinaryOperator.Less      => chain ++= generateComparison(x, y, Cond.Less)
          case BinaryOperator.LessEq    => chain ++= generateComparison(x, y, Cond.LessEqual)
          case BinaryOperator.And       => chain += And(stack.head(SizeDir.Word), EAX)
          case BinaryOperator.Or        => chain += Or(stack.head(SizeDir.Word), EAX)
        }
      case call: microWacc.Call =>
        chain ++= generateCall(call)
        chain += stack.push(RAX)
    }
    if chain.isEmpty then chain += stack.push(ImmediateVal(0))
    chain
  }
  def generateCall(call: microWacc.Call)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    val argRegs = List(RDI, RSI, RDX, RCX, R8, R9)
    val microWacc.Call(target, args) = call
    argRegs.zip(args).foreach { (reg, expr) =>
      chain ++= evalExprOntoStack(expr)
      chain += stack.pop(reg)
    }
    args.drop(argRegs.size).foreach { expr =>
      chain ++= evalExprOntoStack(expr)
    }
    chain += assemblyIR.Call(LabelArg(labelGenerator.getLabel(target)))
    if (args.size > argRegs.size) {
      chain += stack.drop(args.size - argRegs.size)
    }
    chain
  }
  def generateComparison(x: Expr, y: Expr, cond: Cond)(using
      stack: Stack,
      strings: ListBuffer[String],
      labelGenerator: LabelGenerator
  ): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    chain ++= evalExprOntoStack(x)
    chain ++= evalExprOntoStack(y)
    chain += stack.pop(RAX)
    chain += Compare(stack.head(SizeDir.Word), EAX)
    chain += Set(Register(RegSize.Byte, RegName.AL), cond)
    chain += And(RAX, ImmediateVal(_8_BIT_MASK))
    chain += stack.drop()
    chain += stack.push(RAX)
    chain
  }
  // Missing a sub instruction but dont think we need it
  def funcPrologue()(using stack: Stack): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    chain += stack.push(RBP)
    chain += Move(RBP, Register(RegSize.R64, RegName.SP))
    chain
  }
  def funcEpilogue()(using stack: Stack): Chain[AsmLine] = {
    var chain = Chain.empty[AsmLine]
    chain += Move(Register(RegSize.R64, RegName.SP), RBP)
    chain += stack.pop(RBP)
    chain += assemblyIR.Return()
    chain
  }
  class Stack {
    private val stack = LinkedHashMap[Expr | Int, Int]()
    private val RSP = Register(RegSize.R64, RegName.SP)