package scala.tools.nsc package transform; import scala.tools.nsc._ import scala.collection.mutable.HashMap abstract class LazyVals extends Transform with ast.TreeDSL { // inherits abstract value `global' and class `Phase' from Transform import global._ // the global environment import definitions._ // standard classes and methods import typer.{typed, atOwner} // methods to type trees import CODE._ val phaseName: String = "lazyvals" def newTransformer(unit: CompilationUnit): Transformer = new LazyValues(unit) /** Create a new phase which applies transformer */ override def newPhase(prev: scala.tools.nsc.Phase): StdPhase = new Phase(prev) /** The phase defined by this transform */ class Phase(prev: scala.tools.nsc.Phase) extends StdPhase(prev) { def apply(unit: global.CompilationUnit): Unit = newTransformer(unit) transformUnit unit } /** * Transform local lazy accessors to check for the initialized bit. */ class LazyValues(unit: CompilationUnit) extends Transformer { /** map from method symbols to the number of lazy values it defines. */ private val lazyVals = new HashMap[Symbol, Int] { override def default(meth: Symbol) = 0 } import symtab.Flags._ import lazyVals._ /** Perform the following transformations: * - for a lazy accessor inside a method, make it check the initialization bitmap * - for all methods, add enough int vars to allow one flag per lazy local value * - blocks in template bodies behave almost like methods. A single bitmaps section is * added in the first block, for all lazy values defined in such blocks. * - remove ACCESSOR flags: accessors in traits are not statically implemented, * but moved to the host class. local lazy values should be statically implemented. */ override def transform(tree: Tree): Tree = { val sym = tree.symbol tree match { case DefDef(mods, name, tparams, vparams, tpt, rhs) => val res = if (!sym.owner.isClass && sym.hasFlag(LAZY)) { val enclosingDummyOrMethod = if (sym.enclMethod == NoSymbol) sym.owner else sym.enclMethod val idx = lazyVals(enclosingDummyOrMethod) val rhs1 = mkLazyDef(enclosingDummyOrMethod, super.transform(rhs), idx) lazyVals(sym.owner) = idx + 1 sym.resetFlag(LAZY | ACCESSOR) rhs1 } else super.transform(rhs) treeCopy.DefDef(tree, mods, name, tparams, vparams, tpt, typed(addBitmapDefs(sym, res))) case Template(parents, self, body) => val body1 = super.transformTrees(body) var added = false val stats = for (stat <- body1) yield stat match { case Block(_, _) if !added => added = true typed(addBitmapDefs(sym, stat)) case ValDef(mods, name, tpt, rhs) => typed(treeCopy.ValDef(stat, mods, name, tpt, addBitmapDefs(stat.symbol, rhs))) case _ => stat } treeCopy.Template(tree, parents, self, stats) case _ => super.transform(tree) } } /** Add the bitmap definitions to the rhs of a method definition. * If the rhs has been tail-call transformed, insert the bitmap * definitions inside the top-level label definition, so that each * iteration has the lazy values un-initialized. Otherwise add them * at the very beginning of the method. */ private def addBitmapDefs(methSym: Symbol, rhs: Tree): Tree = { def prependStats(stats: List[Tree], tree: Tree): Block = tree match { case Block(stats1, res) => Block(stats ::: stats1, res) case _ => Block(stats, tree) } val bmps = bitmaps(methSym) map (ValDef(_, ZERO)) if (bmps.isEmpty) rhs else rhs match { case Block(assign, l @ LabelDef(name, params, rhs1)) if (name.toString.equals("_" + methSym.name) && List.forall2(params.tail, methSym.tpe.paramTypes) { (ident, tpe) => ident.tpe == tpe }) => val sym = l.symbol Block(assign, treeCopy.LabelDef(l, name, params, typed(prependStats(bmps, rhs1)))) case _ => prependStats(bmps, rhs) } } /** return a 'lazified' version of rhs. Rhs should conform to the * following schema: * { * l$ = <rhs> * l$ * } or * <rhs> when the lazy value has type Unit (for which there is no field * to cache it's value. * * The result will be a tree of the form * { * if ((bitmap$n & MASK) == 0) { * l$ = <rhs> * bitmap$n = bimap$n | MASK * } * l$ * } * where bitmap$n is an int value acting as a bitmap of initialized values. It is * the 'n' is (offset / 32), the MASK is (1 << (offset % 32)). If the value has type * unit, no field is used to chache the value, so the resulting code is: * { * if ((bitmap$n & MASK) == 0) { * <rhs>; * bitmap$n = bimap$n | MASK * } * () * } */ private def mkLazyDef(meth: Symbol, tree: Tree, offset: Int): Tree = { val bitmapSym = getBitmapFor(meth, offset) val mask = LIT(1 << (offset % FLAGS_PER_WORD)) def mkBlock(stmt: Tree) = BLOCK(stmt, mkSetFlag(bitmapSym, mask), UNIT) val (block, res) = tree match { case Block(List(assignment), res) => (mkBlock(assignment), res) case rhs => (mkBlock(rhs), UNIT) } assert(res != UNIT || meth.tpe.finalResultType.typeSymbol == UnitClass) atPos(tree.pos)(typed { def body = { IF ((Ident(bitmapSym) INT_& mask) INT_== ZERO) THEN block ENDIF } BLOCK(body, res) }) } private def mkSetFlag(bmp: Symbol, mask: Tree): Tree = Ident(bmp) === (Ident(bmp) INT_| mask) final val FLAGS_PER_WORD = 32 val bitmaps = new HashMap[Symbol, List[Symbol]] { override def default(meth: Symbol) = Nil } /** Return the symbol corresponding of the right bitmap int inside meth, * given offset. */ private def getBitmapFor(meth: Symbol, offset: Int): Symbol = { val n = offset / FLAGS_PER_WORD val bmps = bitmaps(meth) if (bmps.length > n) bmps(n) else { val sym = meth.newVariable(meth.pos, nme.bitmapName(n)).setInfo(IntClass.tpe) bitmaps(meth) = (sym :: bmps).reverse sym } } } }