/* NSC -- new Scala compiler
* Copyright 2005-2006 LAMP/EPFL
* @author Martin Odersky
*/
// $Id$
package scala.tools.nsc.typechecker
import symtab.Flags._
import collection.mutable.HashMap
import transform.InfoTransform
import scala.tools.nsc.util.{Position, NoPosition}
/** <p>
* Post-attribution checking and transformation.
* </p>
* <p>
* This phase performs the following checks.
* </p>
* <ul>
* <li>All overrides conform to rules.</li>
* <li>All type arguments conform to bounds.</li>
* <li>All type variable uses conform to variance annotations.</li>
* <li>No forward reference to a term symbol extends beyond a value definition.</li>
* </ul>
* <p>
* It performs the following transformations.
* </p>
* <ul>
* <li>Local modules are replaced by variables and classes</li>
* <li>Calls to case factory methods are replaced by new's.</li>
* <li>Eliminate branches in a conditional if the condition is a constant</li>
* </ul>
*
* @author Martin Odersky
* @version 1.0
*
* @todo Check whether we always check type parameter bounds.
*/
abstract class RefChecks extends InfoTransform {
import global._
import definitions._
import typer.{typed, typedOperator, atOwner}
import posAssigner.atPos
/** the following two members override abstract members in Transform */
val phaseName: String = "refchecks"
override def phaseNewFlags: long = lateMETHOD
def newTransformer(unit: CompilationUnit): RefCheckTransformer =
new RefCheckTransformer(unit)
override def changesBaseClasses = false
def transformInfo(sym: Symbol, tp: Type): Type =
if (sym.isModule && !sym.isStatic) {
sym setFlag (lateMETHOD | STABLE)
PolyType(List(), tp)
} else tp
class RefCheckTransformer(unit: CompilationUnit) extends Transformer {
var localTyper: analyzer.Typer = typer;
// Override checking ------------------------------------------------------------
/** 1. Check all members of class `clazz' for overriding conditions.
* That is for overriding member M and overridden member O:
*
* 1.1. M must have the same or stronger access privileges as O.
* 1.2. O must not be final.
* 1.3. O is deferred, or M has `override' modifier.
* 1.4. If O is an immutable value, then so is M.
* // @M: LIFTED 1.5. Neither M nor O are a parameterized type alias
* 1.6. If O is a type alias, then M is an alias of O.
* 1.7. If O is an abstract type then
* 1.7.1 either M is an abstract type, and M's bounds are sharper than O's bounds.
* or M is a type alias or class which conforms to O's bounds.
* 1.7.2 higher-order type arguments must respect bounds on higher-order type parameters -- @M
* (explicit bounds and those implied by variance annotations) -- @see checkKindBounds
* 1.8. If O and M are values, then
* 1.8.1 M's type is a subtype of O's type, or
* 1.8.2 M is of type []S, O is of type ()T and S <: T, or
* 1.8.3 M is of type ()S, O is of type []T and S <: T, or
* 2. Check that only abstract classes have deferred members
* 3. Check that concrete classes do not have deferred definitions
* that are not implemented in a subclass.
* 4. Check that every member with an `override' modifier
* overrides some other member.
*/
private def checkAllOverrides(clazz: Symbol): unit = {
val self = clazz.thisType
def infoString(sym: Symbol) = {
val sym1 = analyzer.underlying(sym)
sym1.toString() +
(if (sym1.owner == clazz) ""
else (sym1.locationString +
(if (sym1.isAliasType) ", which equals "+self.memberInfo(sym1)
else if (sym1.isAbstractType) " with bounds "+self.memberInfo(sym1)
else if (sym1.isTerm) " of type "+self.memberInfo(sym1)
else "")))
}
def overridesType(tp1: Type, tp2: Type): boolean = (tp1.normalize, tp2.normalize) match {
case (MethodType(List(), rtp1), PolyType(List(), rtp2)) =>
rtp1 <:< rtp2
case (PolyType(List(), rtp1), MethodType(List(), rtp2)) =>
rtp1 <:< rtp2
case (TypeRef(_, sym, _), _) if (sym.isModuleClass) =>
overridesType(PolyType(List(), tp1), tp2)
case _ =>
tp1 <:< tp2
}
/** Check that all conditions for overriding <code>other</code> by
* <code>member</code> are met.
*/
def checkOverride(clazz: Symbol, member: Symbol, other: Symbol): unit = {
val pos = if (member.owner == clazz) member.pos else clazz.pos
def overrideError(msg: String): unit =
if (other.tpe != ErrorType && member.tpe != ErrorType)
unit.error(pos, "error overriding " + infoString(other) +
";\n " + infoString(member) + " " + msg);
def overrideTypeError(): unit = {
if (other.tpe != ErrorType && member.tpe != ErrorType) {
overrideError("has incompatible type "+analyzer.underlying(member).tpe.normalize);
explainTypes(member.tpe, other.tpe);
}
}
def overrideAccessError(): unit = {
val pwString = if (other.privateWithin == NoSymbol) ""
else other.privateWithin.name.toString
val otherAccess = flagsToString(other getFlag (PRIVATE | PROTECTED), pwString)
overrideError("has weaker access privileges; it should be "+
(if (otherAccess == "") "public" else "at least "+otherAccess))
}
//Console.println(infoString(member) + " overrides " + infoString(other) + " in " + clazz);//DEBUG
// return if we already checked this combination elsewhere
if (member.owner != clazz) {
if ((member.owner isSubClass other.owner) &&
((member hasFlag DEFERRED) || !(other hasFlag DEFERRED))) {
//Console.println(infoString(member) + " shadows1 " + infoString(other) " in " + clazz);//DEBUG
return;
}
if (clazz.info.parents exists (parent =>
(parent.symbol isSubClass other.owner) && (parent.symbol isSubClass member.owner) &&
((member hasFlag DEFERRED) || !(other hasFlag DEFERRED)))) {
//Console.println(infoString(member) + " shadows2 " + infoString(other) + " in " + clazz);//DEBUG
return;
}
if (clazz.info.parents forall (parent =>
(parent.symbol isSubClass other.owner) == (parent.symbol isSubClass member.owner))) {
//Console.println(infoString(member) + " shadows " + infoString(other) + " in " + clazz);//DEBUG
return;
}
}
if (member hasFlag PRIVATE) { // (1.1)
overrideError("has weaker access privileges; it should not be private")
}
val mb = member.accessBoundary(member.owner)
val ob = other.accessBoundary(member.owner)
if (mb != NoSymbol &&
(ob == NoSymbol ||
mb != ob && !(ob.ownerChain contains mb) ||
(other hasFlag PROTECTED) && !(member hasFlag PROTECTED))) {
overrideAccessError()
} else if (other hasFlag FINAL) { // (1.2)
overrideError("cannot override final member");
} else if (!(other hasFlag DEFERRED) && !(member hasFlag (OVERRIDE | ABSOVERRIDE))) { // (1.3)
overrideError("needs `override' modifier");
} else if ((other hasFlag ABSOVERRIDE) && other.isIncompleteIn(clazz) && !(member hasFlag ABSOVERRIDE)) {
overrideError("needs `abstract override' modifiers")
} else if ((member hasFlag (OVERRIDE | ABSOVERRIDE)) &&
(other hasFlag ACCESSOR) && other.accessed.isVariable) {
overrideError("cannot override a mutable variable")
} else if (other.isStable && !member.isStable) { // (1.4)
overrideError("needs to be an immutable value")
} else if (other.isStable && !(other hasFlag DEFERRED) && other.owner.isTrait && (member hasFlag OVERRIDE)) {
overrideError("cannot override a value or variable definition in a trait " +
"\n (this is an implementation restriction)")
} else {
if (other.isAliasType) {
//if (!member.typeParams.isEmpty) // (1.5) @MAT
// overrideError("may not be parameterized");
//if (!other.typeParams.isEmpty) // (1.5) @MAT
// overrideError("may not override parameterized type");
// @M: substSym
if (!(self.memberType(member).substSym(member.typeParams, other.typeParams) =:= self.memberType(other))) // (1.6)
overrideTypeError();
} else if (other.isAbstractType) {
//if (!member.typeParams.isEmpty) // (1.7) @MAT
// overrideError("may not be parameterized");
var memberTp = self.memberType(member)
if (!(self.memberInfo(other).bounds containsType memberTp)) { // (1.7.1) {
overrideTypeError(); // todo: do an explaintypes with bounds here
}
// check overriding (abstract type --> abstract type or abstract type --> concrete type member (a type alias))
// making an abstract type member concrete is like passing a type argument
val kindErrors = typer.infer.checkKindBounds(List(other), List(memberTp), self, member.owner) // (1.7.2)
if(!kindErrors.isEmpty)
unit.error(member.pos,
"The kind of "+member.keyString+" "+member.varianceString + member.nameString+
" does not conform to the expected kind of " + other.defString + other.locationString + "." +
kindErrors.toList.mkString("\n", ", ", ""))
// check a type alias's RHS corresponds to its declaration
// this overlaps somewhat with validateVariance
if(member.isAliasType) {
val kindErrors = typer.infer.checkKindBounds(List(member), List(memberTp.normalize), self, member.owner)
if(!kindErrors.isEmpty)
unit.error(member.pos,
"The kind of the right-hand side "+memberTp.normalize+" of "+member.keyString+" "+
member.varianceString + member.nameString+ " does not conform to its expected kind."+
kindErrors.toList.mkString("\n", ", ", ""))
}
} else if (other.isTerm) {
if (!overridesType(self.memberInfo(member), self.memberInfo(other))) { // 8
overrideTypeError();
}
}
}
}
val opc = new overridingPairs.Cursor(clazz)
while (opc.hasNext) {
//Console.println("overrides " + opc.overriding/* + ":" + opc.overriding.tpe*/ + opc.overriding.locationString + " " + opc.overridden/* + ":" + opc.overridden.tpe*/ + opc.overridden.locationString + opc.overridden.hasFlag(DEFERRED));//DEBUG
if (!opc.overridden.isClass) checkOverride(clazz, opc.overriding, opc.overridden);
opc.next
}
// 2. Check that only abstract classes have deferred members
if (clazz.isClass && !clazz.isTrait) {
def abstractClassError(mustBeMixin: boolean, msg: String): unit = {
unit.error(clazz.pos,
(if (clazz.isAnonymousClass || clazz.isModuleClass) "object creation impossible"
else if (mustBeMixin) clazz.toString() + " needs to be a mixin"
else clazz.toString() + " needs to be abstract") + ", since " + msg);
clazz.setFlag(ABSTRACT)
}
for (val member <- clazz.tpe.nonPrivateMembers)
if ((member hasFlag DEFERRED) && !(clazz hasFlag ABSTRACT)) {
abstractClassError(
false, infoString(member) + " is not defined" + analyzer.varNotice(member))
} else if ((member hasFlag ABSOVERRIDE) && member.isIncompleteIn(clazz)) {
val other = member.superSymbol(clazz);
abstractClassError(true,
infoString(member) + " is marked `abstract' and `override'" +
(if (other != NoSymbol)
" and overrides incomplete superclass member " + infoString(other)
else ""))
}
// 3. Check that concrete classes do not have deferred definitions
// that are not implemented in a subclass.
def checkNoAbstractDecls(bc: Symbol) {
for (val decl <- bc.info.decls.elements) {
if (decl hasFlag DEFERRED) {
val impl = decl.matchingSymbol(clazz.thisType)
if (impl == NoSymbol || (decl.owner isSubClass impl.owner)) {
abstractClassError(false, "there is a deferred declaration of "+infoString(decl)+
" which is not implemented in a subclass"+analyzer.varNotice(decl))
}
}
}
val parents = bc.info.parents
if (!parents.isEmpty && parents.head.symbol.hasFlag(ABSTRACT))
checkNoAbstractDecls(parents.head.symbol)
}
if (!(clazz hasFlag ABSTRACT)) checkNoAbstractDecls(clazz)
}
// 4. Check that every defined member with an `override' modifier overrides some other member.
for (val member <- clazz.info.decls.toList)
if ((member hasFlag (OVERRIDE | ABSOVERRIDE)) &&
(clazz.info.baseClasses.tail forall {
bc => member.matchingSymbol(bc, clazz.thisType) == NoSymbol
})) {
// for (val bc <- clazz.info.baseClasses.tail) Console.println("" + bc + " has " + bc.info.decl(member.name) + ":" + bc.info.decl(member.name).tpe);//DEBUG
unit.error(member.pos, member.toString() + " overrides nothing");
member resetFlag OVERRIDE
}
}
// Basetype Checking --------------------------------------------------------
/** <ol>
* <li> <!-- 1 -->
* Check that later type instances in the base-type sequence
* are subtypes of earlier type instances of the same mixin.
* </li>
* <li> <!-- 2 -->
* Check that case classes do not inherit from case classes.
* </li>
* <li> <!-- 3 -->
* Check that at most one base type is a case-class.
* </li>
* <li> <!-- 4 -->
* Check that inner classes do not inherit from Annotation
* </li>
* </ol>
*/
private def validateBaseTypes(clazz: Symbol): unit = {
val seenTypes = new Array[Type](clazz.info.closure.length)
var seenCaseClass = if (clazz hasFlag CASE) clazz else NoSymbol
def validateTypes(tps: List[Type], includeSuper: boolean): unit = {
if (!tps.isEmpty) {
for (val tp <- tps.tail.reverse) validateType(tp, false);
if (includeSuper) validateType(tps.head, true);
}
}
def validateType(tp: Type, includeSuper: boolean): unit = {
val baseClass = tp.symbol
if (baseClass.isClass) {
val index = clazz.info.closurePos(baseClass)
if (index >= 0) {
if ((seenTypes(index) ne null) && !(seenTypes(index) <:< tp))
unit.error(clazz.pos, "illegal inheritance;\n " + clazz +
" inherits different type instances of " + baseClass +
":\n" + tp + " and " + seenTypes(index));
seenTypes(index) = tp;
// check that case classes do not inherit from case classes
if (baseClass hasFlag CASE) {
if (seenCaseClass != NoSymbol && seenCaseClass != baseClass)
unit.error(clazz.pos, "implementation restriction: case " +
seenCaseClass + " and case " + baseClass +
" cannot be combined in one object");
seenCaseClass = baseClass
}
// check that inner classes do not inherit from Annotation
if (baseClass == ClassfileAnnotationClass)
if (!clazz.owner.isPackageClass)
unit.error(clazz.pos, "inner classes cannot be classfile annotations")
}
validateTypes(tp.parents, includeSuper)
}
}
validateTypes(clazz.info.parents, true)
}
// Variance Checking --------------------------------------------------------
private val ContraVariance = -1
private val NoVariance = 0
private val CoVariance = 1
private val AnyVariance = 2
/** Check variance of type variables in this type.
*
* @param base ...
* @param all ...
* @param variance ...
*/
private def validateVariance(base: Symbol, all: Type, variance: int): unit = {
def varianceString(variance: int): String =
if (variance == 1) "covariant"
else if (variance == -1) "contravariant"
else "invariant";
def relativeVariance(tvar: Symbol): int = {
val clazz = tvar.owner
var sym = base
var state = CoVariance
while (sym != clazz && state != AnyVariance) {
//Console.println("flip: " + sym + " " + sym.isParameter());//DEBUG
if ((sym hasFlag PARAM) && !sym.owner.isConstructor &&
!(tvar.isTypeParameterOrSkolem && sym.isTypeParameterOrSkolem &&
tvar.owner == sym.owner)) state = -state;
else if (!sym.owner.isClass || sym.isPrivateLocal || sym.isProtectedLocal)
state = AnyVariance
else if (sym.isAliasType)
state = NoVariance
sym = sym.owner
}
state
}
def validateVariance(tp: Type, variance: int): unit = tp match {
case ErrorType => ;
case WildcardType => ;
case NoType => ;
case NoPrefix => ;
case ThisType(_) => ;
case ConstantType(_) => ;
case DeBruijnIndex(_, _) => ;
case SingleType(pre, sym) =>
validateVariance(pre, variance)
case TypeRef(pre, sym, args) =>
if (sym.variance != NoVariance) {
val v = relativeVariance(sym);
if (v != AnyVariance && sym.variance != v * variance) {
//Console.println("relativeVariance(" + base + "," + sym + ") = " + v);//DEBUG
unit.error(base.pos,
varianceString(sym.variance) + " " + sym +
" occurs in " + varianceString(v * variance) +
" position in type " + all + " of " + base);
}
}
validateVariance(pre, variance)
validateVarianceArgs(args, variance, sym.typeParams) //@M for higher-kinded typeref, args.isEmpty
// However, these args respect variances by construction anyway
// -- the interesting case is in type application, see checkKindBounds in Infer
case ClassInfoType(parents, decls, symbol) =>
validateVariances(parents, variance)
case RefinedType(parents, decls) =>
validateVariances(parents, variance)
case TypeBounds(lo, hi) =>
validateVariance(lo, -variance)
validateVariance(hi, variance)
case MethodType(formals, result) =>
validateVariance(result, variance)
case PolyType(tparams, result) =>
validateVariance(result, variance)
case ExistentialType(tparams, result) =>
validateVariance(result, variance)
case AnnotatedType(attribs, tp) =>
validateVariance(tp, variance)
}
def validateVariances(tps: List[Type], variance: int): unit =
tps foreach (tp => validateVariance(tp, variance))
def validateVarianceArgs(tps: List[Type], variance: int, tparams: List[Symbol]): unit =
(tps zip tparams) foreach {
case (tp, tparam) => validateVariance(tp, variance * tparam.variance)
}
validateVariance(all, variance)
}
// Forward reference checking ---------------------------------------------------
class LevelInfo(val outer: LevelInfo) {
val scope: Scope = if (outer eq null) newScope else newScope(outer.scope)
var maxindex: int = Math.MIN_INT
var refpos: Position = _
var refsym: Symbol = _
}
private var currentLevel: LevelInfo = null
private val symIndex = new HashMap[Symbol, int]
private def pushLevel(): unit =
currentLevel = new LevelInfo(currentLevel)
private def popLevel(): unit =
currentLevel = currentLevel.outer
private def enterSyms(stats: List[Tree]): unit = {
var index = -1
for (val stat <- stats) {
index = index + 1;
stat match {
case ClassDef(_, _, _, _) | DefDef(_, _, _, _, _, _) | ModuleDef(_, _, _) | ValDef(_, _, _, _) =>
assert(stat.symbol != NoSymbol, stat);//debug
if (stat.symbol.isLocal) {
currentLevel.scope.enter(newScopeEntry(stat.symbol, currentLevel.scope));
symIndex(stat.symbol) = index;
}
case _ =>
}
}
}
private def enterReference(pos: Position, sym: Symbol): unit =
if (sym.isLocal) {
val e = currentLevel.scope.lookupEntry(sym.name)
if ((e ne null) && sym == e.sym) {
var l = currentLevel
while (l.scope != e.owner) l = l.outer;
val symindex = symIndex(sym)
if (l.maxindex < symindex) {
l.refpos = pos
l.refsym = sym
l.maxindex = symindex
}
}
}
// Comparison checking -------------------------------------------------------
object normalizeAll extends TypeMap {
def apply(tp: Type) = mapOver(tp).normalize
}
def checkSensible(pos: Position, fn: Tree, args: List[Tree]) = fn match {
case Select(qual, name) if (args.length == 1) =>
def isNew(tree: Tree) = tree match {
case Function(_, _)
| Apply(Select(New(_), nme.CONSTRUCTOR), _) => true
case _ => false
}
name match {
case nme.EQ | nme.NE | nme.LT | nme.GT | nme.LE | nme.GE =>
def underlyingClass(tp: Type): Symbol = {
var sym = tp.widen.symbol
while (sym.isAbstractType)
sym = sym.info.bounds.hi.widen.symbol
sym
}
val formal = underlyingClass(fn.tpe.paramTypes.head)
val actual = underlyingClass(args.head.tpe)
val receiver = underlyingClass(qual.tpe)
def nonSensibleWarning(what: String, alwaysEqual: boolean) =
unit.warning(pos, "comparing "+what+" using `"+name.decode+"' will always yield "+
(alwaysEqual == (name == nme.EQ || name == nme.LE || name == nme.GE)))
def nonSensible(pre: String, alwaysEqual: boolean) =
nonSensibleWarning(pre+"values of types "+normalizeAll(qual.tpe.widen)+" and "+normalizeAll(args.head.tpe.widen),
alwaysEqual) // @MAT normalize for consistency in error message, otherwise part is normalized due to use of `symbol', but the rest isn't
def hasObjectEquals = receiver.info.member(nme.equals_) == Object_equals
if (formal == UnitClass && actual == UnitClass)
nonSensible("", true)
else if ((receiver == BooleanClass || receiver == UnitClass) &&
!(receiver isSubClass actual))
nonSensible("", false)
else if (isNumericValueClass(receiver) &&
!isNumericValueClass(actual) &&
!(forMSIL || forCLDC|| (actual isSubClass BoxedNumberClass)) &&
!(receiver isSubClass actual))
nonSensible("", false)
else if ((receiver hasFlag FINAL) && hasObjectEquals && !isValueClass(receiver) &&
!(receiver isSubClass actual) && receiver != AllRefClass && actual != AllRefClass)
nonSensible("non-null ", false)
else if ((isNew(qual) || isNew(args.head)) && hasObjectEquals)
nonSensibleWarning("a fresh object", false)
case _ =>
}
case _ =>
}
// Transformation ------------------------------------------------------------
/* Convert a reference to a case factory of type `tpe' to a new of the class it produces. */
def toConstructor(pos: Position, tpe: Type): Tree = {
var rtpe = tpe.finalResultType
assert(rtpe.symbol hasFlag CASE, tpe);
localTyper.typedOperator {
atPos(pos) {
Select(New(TypeTree(rtpe)), rtpe.symbol.primaryConstructor)
}
}
}
def isConcreteLocalCaseFactory(clazz: Symbol) =
(clazz hasFlag CASE) && !(clazz hasFlag ABSTRACT) && !(clazz.owner hasFlag PACKAGE)
override def transformStats(stats: List[Tree], exprOwner: Symbol): List[Tree] = {
pushLevel()
enterSyms(stats)
var index = -1
val stats1 = stats flatMap { stat => index = index + 1; transformStat(stat, index) }
popLevel()
stats1
}
/** Implements lazy value accessors:
* - for lazy fields inside traits, the rhs is the initializer itself
* - for all other lazy values z the accessor is a block of this form:
* { z = <rhs>; z } where z can be an identifier or a field.
*/
def transformStat(tree: Tree, index: int): List[Tree] = tree match {
case ModuleDef(mods, name, impl) =>
val sym = tree.symbol
val cdef = ClassDef(mods | MODULE, name, List(), impl)
.setPos(tree.pos)
.setSymbol(sym.moduleClass)
.setType(NoType);
if (sym.isStatic) List(transform(cdef))
else {
val vdef =
localTyper.typed {
atPos(tree.pos) {
gen.mkModuleVarDef(sym)
}
}
val ddef =
atPhase(phase.next) {
localTyper.typed {
if (sym.owner.isTrait) gen.mkModuleAccessDcl(sym)
else gen.mkModuleAccessDef(sym, vdef.symbol)
}
}
if (sym.owner.isTrait) transformTrees(List(cdef, ddef))
else transformTrees(List(cdef, vdef, ddef))
}
case ClassDef(_, _, _, _) if isConcreteLocalCaseFactory(tree.symbol) =>
val clazz = tree.symbol
val factory = clazz.caseFactory
if (factory == NoSymbol) {
assert(clazz.owner.isTerm, clazz)
List(transform(tree))
} else {
def mkArgument(vparam: Symbol) = {
val id = Ident(vparam)
if (vparam.tpe.symbol == RepeatedParamClass) Typed(id, Ident(nme.WILDCARD_STAR.toTypeName))
else id
}
val caseFactoryDef =
localTyper.typed {
atPos(tree.pos) {
DefDef(
factory,
vparamss =>
(toConstructor(tree.pos, factory.tpe) /: vparamss) {
(fn, vparams) => Apply(fn, vparams map mkArgument)
})
}
}
List(transform(tree), caseFactoryDef)
}
case ValDef(_, _, _, _) =>
val tree1 = transform(tree); // important to do before forward reference check
val ValDef(_, _, _, rhs) = tree1
if (tree.symbol.hasFlag(LAZY)) {
assert(tree.symbol.isTerm, tree.symbol)
val vsym = tree.symbol
val lazyDefSym = vsym.lazyAccessor
assert(lazyDefSym != NoSymbol, vsym)
val lazyDef = atPos(tree.pos)(
DefDef(lazyDefSym, vparamss =>
if (tree.symbol.owner.isTrait) rhs // for traits, this is further tranformed in mixins
else Block(List(
Assign(gen.mkAttributedRef(vsym), rhs)),
gen.mkAttributedRef(vsym))))
log("Made lazy def: " + lazyDef)
typed(ValDef(vsym, EmptyTree)) :: typed(lazyDef) :: Nil
} else {
if (tree.symbol.isLocal && index <= currentLevel.maxindex && !tree.symbol.hasFlag(LAZY)) {
if (settings.debug.value) Console.println(currentLevel.refsym);
unit.error(currentLevel.refpos, "forward reference extends over definition of " + tree.symbol);
}
List(tree1)
}
case Import(_, _) =>
List()
case _ =>
List(transform(tree))
}
override def transform(tree: Tree): Tree = try {
/* Check whether argument types conform to bounds of type parameters */
def checkBounds(pre: Type, owner: Symbol, tparams: List[Symbol], argtps: List[Type]): unit = try {
typer.infer.checkBounds(tree.pos, pre, owner, tparams, argtps, "");
} catch {
case ex: TypeError => unit.error(tree.pos, ex.getMessage());
}
def isIrrefutable(pat: Tree, seltpe: Type): boolean = {
val result = pat match {
case Apply(_, args) =>
val clazz = pat.tpe.symbol;
clazz == seltpe.symbol &&
clazz.isClass && (clazz hasFlag CASE) &&
List.forall2(
args,
clazz.primaryConstructor.tpe.asSeenFrom(seltpe, clazz).paramTypes)(isIrrefutable)
case Typed(pat, tpt) =>
seltpe <:< tpt.tpe
case Ident(nme.WILDCARD) =>
true
case Bind(_, pat) =>
isIrrefutable(pat, seltpe)
case _ =>
false
}
//Console.println("is irefutable? " + pat + ":" + pat.tpe + " against " + seltpe + ": " + result);//DEBUG
result
}
/** Check that a deprecated val or def does not override a
* concrete, non-deprecated method. If it does, then
* deprecation is meaningless.
*/
def checkDeprecatedOvers() {
val symbol = tree.symbol
if (symbol.isDeprecated) {
val concrOvers =
symbol.allOverriddenSymbols.filter(sym =>
!sym.isDeprecated && !(sym hasFlag DEFERRED))
if(!concrOvers.isEmpty)
unit.deprecationWarning(
tree.pos,
symbol.toString + " overrides concrete, non-deprecated symbol(s):" +
concrOvers.map(_.fullNameString).mkString(" ", ", ", ""))
}
}
val savedLocalTyper = localTyper
val sym = tree.symbol
var result = tree
tree match {
case ClassDef(mods, name, tparams, impl) =>
validateVariance(sym, sym.info, CoVariance)
validateVariance(sym, sym.typeOfThis, CoVariance)
case DefDef(mods, name, tparams, vparams, tpt, EmptyTree) if tree.symbol.hasAttribute(definitions.NativeAttr.tpe) =>
tree.symbol.resetFlag(DEFERRED)
result = transform(copy.DefDef(tree, mods, name, tparams, vparams, tpt,
typed(Apply(gen.mkAttributedRef(definitions.Predef_error), List(Literal("native method stub"))))))
case DefDef(_, _, _, _, _, _) =>
validateVariance(sym, sym.tpe, CoVariance) //@M TODO: might be affected by change in tpe --> can't use tree.tpe though
checkDeprecatedOvers()
case ValDef(_, _, _, _) =>
validateVariance(sym, sym.tpe, if (sym.isVariable) NoVariance else CoVariance) //@M TODO: might be affected by change in tpe --> can't use tree.tpe though
checkDeprecatedOvers()
case TypeDef(_, _, _, _) =>
validateVariance(sym, sym.info, CoVariance)
case Template(_, _, _) =>
localTyper = localTyper.atOwner(tree, currentOwner)
validateBaseTypes(currentOwner)
checkAllOverrides(currentOwner)
case TypeTree() =>
new TypeTraverser {
def traverse(tp: Type): TypeTraverser = tp match {
case TypeRef(pre, sym, args) =>
if (!tp.isHigherKinded) checkBounds(pre, sym.owner, sym.typeParams, args)
this
case _ =>
this
}
} traverse tree.tpe
case TypeApply(fn, args) =>
checkBounds(NoPrefix, NoSymbol, fn.tpe.typeParams, args map (_.tpe))
if (sym.isSourceMethod && sym.hasFlag(CASE)) result = toConstructor(tree.pos, tree.tpe)
case Apply(
Select(qual, nme.filter),
List(Function(
List(ValDef(_, pname, tpt, _)),
Match(_, CaseDef(pat1, _, _) :: _))))
if ((pname startsWith nme.CHECK_IF_REFUTABLE_STRING) &&
isIrrefutable(pat1, tpt.tpe)) =>
result = qual
case Apply(fn, args) =>
checkSensible(tree.pos, fn, args)
case If(cond, thenpart, elsepart) =>
cond.tpe match {
case ConstantType(value) =>
result = if (value.booleanValue) thenpart else elsepart;
if (result == EmptyTree) result = Literal(()).setPos(tree.pos).setType(UnitClass.tpe)
case _ =>
}
case New(tpt) =>
enterReference(tree.pos, tpt.tpe.symbol)
case Ident(name) =>
if (sym.isSourceMethod && sym.hasFlag(CASE))
result = toConstructor(tree.pos, tree.tpe)
else if (name != nme.WILDCARD && name != nme.WILDCARD_STAR.toTypeName) {
assert(sym != NoSymbol, tree)//debug
enterReference(tree.pos, sym)
}
case Select(qual, name) =>
if (sym.isSourceMethod && sym.hasFlag(CASE))
result = toConstructor(tree.pos, tree.tpe)
else qual match {
case Super(qualifier, mix) =>
val base = qual.symbol;
//Console.println("super: " + tree + " in " + base);//DEBUG
assert(!(base.isTrait && sym.isTerm && mix == nme.EMPTY.toTypeName)) // term should have been eliminated by super accessors
case _ =>
}
case _ =>
}
result = super.transform(result)
localTyper = savedLocalTyper
result
} catch {
case ex: TypeError =>
if (settings.debug.value) ex.printStackTrace();
unit.error(tree.pos, ex.getMessage())
tree
}
}
}