/* NSC -- new Scala compiler * Copyright 2005-2010 LAMP/EPFL * @author Martin Odersky */ // $Id$ package scala.tools.nsc package ast import scala.collection.mutable.ListBuffer import symtab.Flags._ import symtab.SymbolTable /** XXX to resolve: TreeGen only assumes global is a SymbolTable, but * TreeDSL at the moment expects a Global. Can we get by with SymbolTable? */ abstract class TreeGen { val global: SymbolTable import global._ import definitions._ def rootId(name: Name) = Select(Ident(nme.ROOTPKG), name) def rootScalaDot(name: Name) = Select(rootId(nme.scala_) setSymbol ScalaPackage, name) def scalaDot(name: Name) = Select(Ident(nme.scala_) setSymbol ScalaPackage, name) def scalaAnyRefConstr = scalaDot(nme.AnyRef.toTypeName) def scalaUnitConstr = scalaDot(nme.Unit.toTypeName) def scalaScalaObjectConstr = scalaDot(nme.ScalaObject.toTypeName) def productConstr = scalaDot(nme.Product.toTypeName) private def isRootOrEmptyPackageClass(s: Symbol) = s.isRoot || s.isEmptyPackageClass def scalaFunctionConstr(argtpes: List[Tree], restpe: Tree): Tree = AppliedTypeTree( scalaDot(newTypeName("Function"+argtpes.length)), argtpes ::: List(restpe)) /** Builds a reference to value whose type is given stable prefix. * The type must be suitable for this. For example, it * must not be a TypeRef pointing to an abstract type variable. */ def mkAttributedQualifier(tpe: Type): Tree = mkAttributedQualifier(tpe, NoSymbol) /** Builds a reference to value whose type is given stable prefix. * If the type is unsuitable, e.g. it is a TypeRef for an * abstract type variable, then an Ident will be made using * termSym as the Ident's symbol. In that case, termSym must * not be NoSymbol. */ def mkAttributedQualifier(tpe: Type, termSym: Symbol): Tree = tpe match { case NoPrefix => EmptyTree case ThisType(clazz) => if (isRootOrEmptyPackageClass(clazz)) EmptyTree else mkAttributedThis(clazz) case SingleType(pre, sym) => val qual = mkAttributedStableRef(pre, sym) qual.tpe match { case MethodType(List(), restpe) => Apply(qual, List()) setType restpe case _ => qual } case TypeRef(pre, sym, args) => if (sym.isRoot) { mkAttributedThis(sym) } else if (sym.isModuleClass) { val qual = mkAttributedRef(pre, sym.sourceModule) qual.tpe match { case MethodType(List(), restpe) => Apply(qual, List()) setType restpe case _ => qual } } else if (sym.isModule || sym.isClass) { assert(phase.erasedTypes, tpe) mkAttributedThis(sym) } else if (sym.isType) { assert(termSym != NoSymbol) mkAttributedIdent(termSym) setType tpe } else { mkAttributedRef(pre, sym) } case ConstantType(value) => Literal(value) setType tpe case AnnotatedType(_, atp, _) => mkAttributedQualifier(atp) case RefinedType(parents, _) => // I am unclear whether this is reachable, but // the following implementation looks logical -Lex val firstStable = parents.find(_.isStable) assert(!firstStable.isEmpty) mkAttributedQualifier(firstStable.get) case _ => abort("bad qualifier: " + tpe) } /** Builds a reference to given symbol with given stable prefix. */ def mkAttributedRef(pre: Type, sym: Symbol): Tree = { val qual = mkAttributedQualifier(pre) qual match { case EmptyTree => mkAttributedIdent(sym) case This(clazz) if isRootOrEmptyPackageClass(qual.symbol) => mkAttributedIdent(sym) case _ => mkAttributedSelect(qual, sym) } } /** Builds a reference to given symbol. */ def mkAttributedRef(sym: Symbol): Tree = if (sym.owner.isClass) mkAttributedRef(sym.owner.thisType, sym) else mkAttributedIdent(sym) /** Replaces tree type with a stable type if possible */ def stabilize(tree: Tree): Tree = tree match { case Ident(_) => if (tree.symbol.isStable) tree.setType(singleType(tree.symbol.owner.thisType, tree.symbol)) else tree case Select(qual, _) => assert((tree.symbol ne null) && (qual.tpe ne null)) if (tree.symbol.isStable && qual.tpe.isStable) tree.setType(singleType(qual.tpe, tree.symbol)) else tree case _ => tree } /** Cast `tree' to type `pt' */ def mkCast(tree: Tree, pt: Type): Tree = { if (settings.debug.value) log("casting " + tree + ":" + tree.tpe + " to " + pt) assert(!tree.tpe.isInstanceOf[MethodType], tree) assert(!pt.typeSymbol.isPackageClass) assert(!pt.typeSymbol.isPackageObjectClass) assert(pt eq pt.normalize) //@MAT only called during erasure, which already takes care of that atPos(tree.pos)(mkAsInstanceOf(tree, pt, false)) } /** Builds a reference with stable type to given symbol */ def mkAttributedStableRef(pre: Type, sym: Symbol): Tree = stabilize(mkAttributedRef(pre, sym)) def mkAttributedStableRef(sym: Symbol): Tree = stabilize(mkAttributedRef(sym)) def mkAttributedThis(sym: Symbol): Tree = This(sym.name) setSymbol sym setType sym.thisType def mkAttributedIdent(sym: Symbol): Tree = Ident(sym.name) setSymbol sym setType sym.tpe def mkAttributedSelect(qual: Tree, sym: Symbol): Tree = { def tpe = qual.tpe def isUnqualified(n: Name) = n match { case nme.ROOT | nme.EMPTY_PACKAGE_NAME => true ; case _ => false } def hasUnqualifiedName(s: Symbol) = s != null && isUnqualified(s.name.toTermName) def isInPkgObject(s: Symbol) = s != null && s.owner.isPackageObjectClass && s.owner.owner == tpe.typeSymbol if (hasUnqualifiedName(qual.symbol)) mkAttributedIdent(sym) else { val pkgQualifier = if (!isInPkgObject(sym)) qual else { val obj = sym.owner.sourceModule Select(qual, nme.PACKAGEkw) setSymbol obj setType singleType(tpe, obj) } val tree = Select(pkgQualifier, sym) if (pkgQualifier.tpe == null) tree else tree setType (tpe memberType sym) } } private def mkTypeApply(value: Tree, tpe: Type, what: Symbol) = Apply( TypeApply( mkAttributedSelect(value, what), List(TypeTree(tpe.normalize)) ), Nil ) /** Builds an instance test with given value and type. */ def mkIsInstanceOf(value: Tree, tpe: Type, any: Boolean = true): Tree = mkTypeApply(value, tpe, (if (any) Any_isInstanceOf else Object_isInstanceOf)) /** Builds a cast with given value and type. */ def mkAsInstanceOf(value: Tree, tpe: Type, any: Boolean = true): Tree = mkTypeApply(value, tpe, (if (any) Any_asInstanceOf else Object_asInstanceOf)) def mkClassOf(tp: Type): Tree = Literal(Constant(tp)) setType ClassType(tp) def mkCheckInit(tree: Tree): Tree = { val tpe = if (tree.tpe != null || !tree.hasSymbol) tree.tpe else tree.symbol.tpe if (!global.phase.erasedTypes && settings.Xchecknull.value && tpe <:< NotNullClass.tpe && !tpe.isNotNull) mkRuntimeCall(nme.checkInitialized, List(tree)) else tree } /** Builds a list with given head and tail. */ def mkNewCons(head: Tree, tail: Tree): Tree = New(Apply(mkAttributedRef(ConsClass), List(head, tail))) /** Builds a list with given head and tail. */ def mkNil: Tree = mkAttributedRef(NilModule) /** Builds a tuple */ def mkTuple(elems: List[Tree]): Tree = if (elems.isEmpty) Literal(()) else Apply( Select(mkAttributedRef(TupleClass(elems.length).caseModule), nme.apply), elems) // tree1 AND tree2 def mkAnd(tree1: Tree, tree2: Tree): Tree = Apply(Select(tree1, Boolean_and), List(tree2)) // tree1 OR tree2 def mkOr(tree1: Tree, tree2: Tree): Tree = Apply(Select(tree1, Boolean_or), List(tree2)) // wrap the given expression in a SoftReference so it can be gc-ed def mkSoftRef(expr: Tree): Tree = New(TypeTree(SoftReferenceClass.tpe), List(List(expr))) def mkCached(cvar: Symbol, expr: Tree): Tree = { val cvarRef = if (cvar.owner.isClass) Select(This(cvar.owner), cvar) else Ident(cvar) Block( List( If(Apply(Select(cvarRef, nme.eq), List(Literal(Constant(null)))), Assign(cvarRef, expr), EmptyTree)), cvarRef ) } // var m$: T = null; or, if class member: local var m$: T = _; /*!!! def mkModuleValDef(accessor: Symbol) = { val mval = accessor.owner.newValue(accessor.pos.focus, nme.moduleVarName(accessor.name)) .setInfo(accessor.tpe.finalResultType) .setFlag(LAZY); if (mval.owner.isClass) { mval setFlag (PRIVATE | LOCAL | SYNTHETIC) mval.owner.info.decls.enter(mval) } ValDef(mval, New(TypeTree(mval.tpe), List(List()))) } */ // var m$: T = null; or, if class member: local var m$: T = _; def mkModuleVarDef(accessor: Symbol) = { val mvar = accessor.owner.newVariable(accessor.pos.focus, nme.moduleVarName(accessor.name)) .setInfo(accessor.tpe.finalResultType) .setFlag(MODULEVAR); if (mvar.owner.isClass) { mvar setFlag (PRIVATE | LOCAL | SYNTHETIC) mvar.owner.info.decls.enter(mvar) } ValDef(mvar, if (mvar.owner.isClass) EmptyTree else Literal(Constant(null))) } // def m: T = { if (m$ eq null) m$ = new m$class(...) m$ } // where (...) are eventual outer accessors def mkCachedModuleAccessDef(accessor: Symbol, mvar: Symbol) = DefDef(accessor, mkCached(mvar, newModule(accessor, mvar.tpe))) // def m: T = new tpe(...) // where (...) are eventual outer accessors def mkModuleAccessDef(accessor: Symbol, tpe: Type) = DefDef(accessor, newModule(accessor, tpe)) private def newModule(accessor: Symbol, tpe: Type) = New(TypeTree(tpe), List(for (pt <- tpe.typeSymbol.primaryConstructor.info.paramTypes) yield This(accessor.owner.enclClass))) // def m: T; def mkModuleAccessDcl(accessor: Symbol) = DefDef(accessor setFlag lateDEFERRED, EmptyTree) def mkRuntimeCall(meth: Name, args: List[Tree]): Tree = { Apply(Select(mkAttributedRef(ScalaRunTimeModule), meth), args) } def mkRuntimeCall(meth: Name, targs: List[Type], args: List[Tree]): Tree = { Apply(TypeApply(Select(mkAttributedRef(ScalaRunTimeModule), meth), targs map TypeTree), args) } /** Make a synchronized block on 'monitor'. */ def mkSynchronized(monitor: Tree, body: Tree): Tree = Apply(Select(monitor, Object_synchronized), List(body)) def wildcardStar(tree: Tree) = atPos(tree.pos) { Typed(tree, Ident(nme.WILDCARD_STAR.toTypeName)) } def paramToArg(vparam: Symbol) = { val arg = Ident(vparam) if (isRepeatedParamType(vparam.tpe)) wildcardStar(arg) else arg } def paramToArg(vparam: ValDef) = { val arg = Ident(vparam.name) if (treeInfo.isRepeatedParamType(vparam.tpt)) wildcardStar(arg) else arg } /** Make forwarder to method `target', passing all parameters in `params' */ def mkForwarder(target: Tree, vparamss: List[List[Symbol]]) = (target /: vparamss)((fn, vparams) => Apply(fn, vparams map paramToArg)) /** Applies a wrapArray call to an array, making it a WrappedArray */ def mkWrapArray(tree: Tree, elemtp: Type) = { val predef = mkAttributedRef(PredefModule) val meth = if ((elemtp <:< AnyRefClass.tpe) && !isPhantomClass(elemtp.typeSymbol) || isValueClass(elemtp.typeSymbol)) Select(predef, "wrapArray") else TypeApply(Select(predef, "genericWrapArray"), List(TypeTree(elemtp))) Apply(meth, List(tree)) } /** Used in situations where you need to access value of an expression several times */ def evalOnce(expr: Tree, owner: Symbol, unit: CompilationUnit)(within: (() => Tree) => Tree): Tree = { var used = false if (treeInfo.isPureExpr(expr)) { within(() => if (used) expr.duplicate else { used = true; expr }) } else { val temp = owner.newValue(expr.pos.makeTransparent, unit.fresh.newName(expr.pos, "ev$")) .setFlag(SYNTHETIC).setInfo(expr.tpe) val containing = within(() => Ident(temp) setPos temp.pos.focus setType expr.tpe) ensureNonOverlapping(containing, List(expr)) Block(List(ValDef(temp, expr)), containing) setPos (containing.pos union expr.pos) } } def evalOnceAll(exprs: List[Tree], owner: Symbol, unit: CompilationUnit)(within: (List[() => Tree]) => Tree): Tree = { val vdefs = new ListBuffer[ValDef] val exprs1 = new ListBuffer[() => Tree] val used = new Array[Boolean](exprs.length) var i = 0 for (expr <- exprs) { if (treeInfo.isPureExpr(expr)) { exprs1 += { val idx = i () => if (used(idx)) expr.duplicate else { used(idx) = true; expr } } } else { val temp = owner.newValue(expr.pos.makeTransparent, unit.fresh.newName(expr.pos, "ev$")) .setFlag(SYNTHETIC).setInfo(expr.tpe) vdefs += ValDef(temp, expr) exprs1 += (() => Ident(temp) setPos temp.pos.focus setType expr.tpe) } i += 1 } val prefix = vdefs.toList val containing = within(exprs1.toList) ensureNonOverlapping(containing, exprs) if (prefix.isEmpty) containing else Block(prefix, containing) setPos (prefix.head.pos union containing.pos) } }