package dotty.tools
package dotc
package typer
import core._
import ast._
import Contexts._, Types._, Flags._, Denotations._, Names._, StdNames._, NameOps._, Symbols._
import Trees._
import Constants._
import Scopes._
import annotation.unchecked
import util.Positions._
import util.{Stats, SimpleMap}
import util.common._
import Decorators._
import Uniques._
import ErrorReporting.errorType
import config.Printers._
import collection.mutable
object ProtoTypes {
import tpd._
/** A trait defining an `isCompatible` method. */
trait Compatibility {
/** Is there an implicit conversion from `tp` to `pt`? */
def viewExists(tp: Type, pt: Type)(implicit ctx: Context): Boolean
/** A type `tp` is compatible with a type `pt` if one of the following holds:
* 1. `tp` is a subtype of `pt`
* 2. `pt` is by name parameter type, and `tp` is compatible with its underlying type
* 3. there is an implicit conversion from `tp` to `pt`.
* 4. `tp` is a numeric subtype of `pt` (this case applies even if implicit conversions are disabled)
*/
def isCompatible(tp: Type, pt: Type)(implicit ctx: Context): Boolean =
(tp.widenExpr relaxed_<:< pt.widenExpr) || viewExists(tp, pt)
/** Test compatibility after normalization in a fresh typerstate. */
def normalizedCompatible(tp: Type, pt: Type)(implicit ctx: Context) = {
val nestedCtx = ctx.fresh.setExploreTyperState
isCompatible(normalize(tp, pt)(nestedCtx), pt)(nestedCtx)
}
/** Check that the result type of the current method
* fits the given expected result type.
*/
def constrainResult(mt: Type, pt: Type)(implicit ctx: Context): Boolean = pt match {
case pt: FunProto =>
mt match {
case mt: MethodType =>
mt.isDependent || constrainResult(mt.resultType, pt.resultType)
case _ =>
true
}
case _: ValueTypeOrProto if !(pt isRef defn.UnitClass) =>
mt match {
case mt: MethodType =>
mt.isDependent || isCompatible(normalize(mt, pt), pt)
case _ =>
isCompatible(mt, pt)
}
case _: WildcardType =>
isCompatible(mt, pt)
case _ =>
true
}
}
object NoViewsAllowed extends Compatibility {
override def viewExists(tp: Type, pt: Type)(implicit ctx: Context): Boolean = false
}
/** A trait for prototypes that match all types */
trait MatchAlways extends ProtoType {
def isMatchedBy(tp1: Type)(implicit ctx: Context) = true
def map(tm: TypeMap)(implicit ctx: Context): ProtoType = this
def fold[T](x: T, ta: TypeAccumulator[T])(implicit ctx: Context): T = x
}
/** A class marking ignored prototypes that can be revealed by `deepenProto` */
case class IgnoredProto(ignored: Type) extends UncachedGroundType with MatchAlways {
override def deepenProto(implicit ctx: Context): Type = ignored
}
/** A prototype for expressions [] that are part of a selection operation:
*
* [ ].name: proto
*/
abstract case class SelectionProto(val name: Name, val memberProto: Type, val compat: Compatibility)
extends CachedProxyType with ProtoType with ValueTypeOrProto {
override def isMatchedBy(tp1: Type)(implicit ctx: Context) = {
name == nme.WILDCARD || {
val mbr = tp1.member(name)
def qualifies(m: SingleDenotation) =
memberProto.isRef(defn.UnitClass) ||
compat.normalizedCompatible(m.info, memberProto)
mbr match { // hasAltWith inlined for performance
case mbr: SingleDenotation => mbr.exists && qualifies(mbr)
case _ => mbr hasAltWith qualifies
}
}
}
def underlying(implicit ctx: Context) = WildcardType
def derivedSelectionProto(name: Name, memberProto: Type, compat: Compatibility)(implicit ctx: Context) =
if ((name eq this.name) && (memberProto eq this.memberProto) && (compat eq this.compat)) this
else SelectionProto(name, memberProto, compat)
override def equals(that: Any): Boolean = that match {
case that: SelectionProto =>
(name eq that.name) && (memberProto == that.memberProto) && (compat eq that.compat)
case _ =>
false
}
def map(tm: TypeMap)(implicit ctx: Context) = derivedSelectionProto(name, tm(memberProto), compat)
def fold[T](x: T, ta: TypeAccumulator[T])(implicit ctx: Context) = ta(x, memberProto)
override def deepenProto(implicit ctx: Context) = derivedSelectionProto(name, memberProto.deepenProto, compat)
override def computeHash = addDelta(doHash(name, memberProto), if (compat eq NoViewsAllowed) 1 else 0)
}
class CachedSelectionProto(name: Name, memberProto: Type, compat: Compatibility) extends SelectionProto(name, memberProto, compat)
object SelectionProto {
def apply(name: Name, memberProto: Type, compat: Compatibility)(implicit ctx: Context): SelectionProto = {
val selproto = new CachedSelectionProto(name, memberProto, compat)
if (compat eq NoViewsAllowed) unique(selproto) else selproto
}
}
/** Create a selection proto-type, but only one level deep;
* treat constructors specially
*/
def selectionProto(name: Name, tp: Type, typer: Typer)(implicit ctx: Context) =
if (name.isConstructorName) WildcardType
else tp match {
case tp: UnapplyFunProto => new UnapplySelectionProto(name)
case tp => SelectionProto(name, IgnoredProto(tp), typer)
}
/** A prototype for expressions [] that are in some unspecified selection operation
*
* [].?: ?
*
* Used to indicate that expression is in a context where the only valid
* operation is further selection. In this case, the expression need not be a value.
* @see checkValue
*/
@sharable object AnySelectionProto extends SelectionProto(nme.WILDCARD, WildcardType, NoViewsAllowed)
/** A prototype for selections in pattern constructors */
class UnapplySelectionProto(name: Name) extends SelectionProto(name, WildcardType, NoViewsAllowed)
trait ApplyingProto extends ProtoType
/** A prototype for expressions that appear in function position
*
* [](args): resultType
*/
case class FunProto(args: List[untpd.Tree], resType: Type, typer: Typer)(implicit ctx: Context)
extends UncachedGroundType with ApplyingProto {
private var myTypedArgs: List[Tree] = Nil
override def resultType(implicit ctx: Context) = resType
/** A map in which typed arguments can be stored to be later integrated in `typedArgs`. */
private var myTypedArg: SimpleMap[untpd.Tree, Tree] = SimpleMap.Empty
/** A map recording the typer states in which arguments stored in myTypedArg were typed */
private var evalState: SimpleMap[untpd.Tree, TyperState] = SimpleMap.Empty
def isMatchedBy(tp: Type)(implicit ctx: Context) =
typer.isApplicable(tp, Nil, typedArgs, resultType)
def derivedFunProto(args: List[untpd.Tree] = this.args, resultType: Type, typer: Typer = this.typer) =
if ((args eq this.args) && (resultType eq this.resultType) && (typer eq this.typer)) this
else new FunProto(args, resultType, typer)
/** Forget the types of any arguments that have been typed producing a constraint in a
* typer state that is not yet committed into the one of the current context `ctx`.
* This is necessary to avoid "orphan" PolyParams that are referred to from
* type variables in the typed arguments, but that are not registered in the
* current constraint. A test case is pos/t1756.scala.
* @return True if all arguments have types (in particular, no types were forgotten).
*/
def allArgTypesAreCurrent()(implicit ctx: Context): Boolean = {
evalState foreachBinding { (arg, tstate) =>
if (tstate.uncommittedAncestor.constraint ne ctx.typerState.constraint) {
typr.println(i"need to invalidate $arg / ${myTypedArg(arg)}, ${tstate.constraint}, current = ${ctx.typerState.constraint}")
myTypedArg = myTypedArg.remove(arg)
evalState = evalState.remove(arg)
}
}
myTypedArg.size == args.length
}
private def cacheTypedArg(arg: untpd.Tree, typerFn: untpd.Tree => Tree)(implicit ctx: Context): Tree = {
var targ = myTypedArg(arg)
if (targ == null) {
targ = typerFn(arg)
if (!ctx.reporter.hasPending) {
myTypedArg = myTypedArg.updated(arg, targ)
evalState = evalState.updated(arg, ctx.typerState)
}
}
targ
}
/** The typed arguments. This takes any arguments already typed using
* `typedArg` into account.
*/
def typedArgs: List[Tree] = {
if (myTypedArgs.size != args.length)
myTypedArgs = args.mapconserve(cacheTypedArg(_, typer.typed(_)))
myTypedArgs
}
/** Type single argument and remember the unadapted result in `myTypedArg`.
* used to avoid repeated typings of trees when backtracking.
*/
def typedArg(arg: untpd.Tree, formal: Type)(implicit ctx: Context): Tree = {
val targ = cacheTypedArg(arg, typer.typedUnadapted(_, formal))
typer.adapt(targ, formal, arg)
}
private var myTupled: Type = NoType
/** The same proto-type but with all arguments combined in a single tuple */
def tupled: FunProto = myTupled match {
case pt: FunProto =>
pt
case _ =>
myTupled = new FunProto(untpd.Tuple(args) :: Nil, resultType, typer)
tupled
}
/** Somebody called the `tupled` method of this prototype */
def isTupled: Boolean = myTupled.isInstanceOf[FunProto]
override def toString = s"FunProto(${args mkString ","} => $resultType)"
def map(tm: TypeMap)(implicit ctx: Context): FunProto =
derivedFunProto(args, tm(resultType), typer)
def fold[T](x: T, ta: TypeAccumulator[T])(implicit ctx: Context): T =
ta(ta.foldOver(x, typedArgs.tpes), resultType)
override def deepenProto(implicit ctx: Context) = derivedFunProto(args, resultType.deepenProto, typer)
}
/** A prototype for expressions that appear in function position
*
* [](args): resultType, where args are known to be typed
*/
class FunProtoTyped(args: List[tpd.Tree], resultType: Type, typer: Typer)(implicit ctx: Context) extends FunProto(args, resultType, typer)(ctx) {
override def typedArgs = args
}
/** A prototype for implicitly inferred views:
*
* []: argType => resultType
*/
abstract case class ViewProto(argType: Type, resType: Type)
extends CachedGroundType with ApplyingProto {
override def resultType(implicit ctx: Context) = resType
def isMatchedBy(tp: Type)(implicit ctx: Context): Boolean =
ctx.typer.isApplicable(tp, argType :: Nil, resultType)
def derivedViewProto(argType: Type, resultType: Type)(implicit ctx: Context) =
if ((argType eq this.argType) && (resultType eq this.resultType)) this
else ViewProto(argType, resultType)
def map(tm: TypeMap)(implicit ctx: Context): ViewProto = derivedViewProto(tm(argType), tm(resultType))
def fold[T](x: T, ta: TypeAccumulator[T])(implicit ctx: Context): T =
ta(ta(x, argType), resultType)
override def deepenProto(implicit ctx: Context) = derivedViewProto(argType, resultType.deepenProto)
}
class CachedViewProto(argType: Type, resultType: Type) extends ViewProto(argType, resultType) {
override def computeHash = doHash(argType, resultType)
}
object ViewProto {
def apply(argType: Type, resultType: Type)(implicit ctx: Context) =
unique(new CachedViewProto(argType, resultType))
}
class UnapplyFunProto(argType: Type, typer: Typer)(implicit ctx: Context) extends FunProto(
untpd.TypedSplice(dummyTreeOfType(argType)) :: Nil, WildcardType, typer)
/** A prototype for expressions [] that are type-parameterized:
*
* [] [targs] resultType
*/
case class PolyProto(targs: List[Type], resType: Type) extends UncachedGroundType with ProtoType {
override def resultType(implicit ctx: Context) = resType
override def isMatchedBy(tp: Type)(implicit ctx: Context) = {
def isInstantiatable(tp: Type) = tp.widen match {
case tp: GenericType => tp.paramNames.length == targs.length
case _ => false
}
isInstantiatable(tp) || tp.member(nme.apply).hasAltWith(d => isInstantiatable(d.info))
}
def derivedPolyProto(targs: List[Type], resultType: Type) =
if ((targs eq this.targs) && (resType eq this.resType)) this
else PolyProto(targs, resType)
def map(tm: TypeMap)(implicit ctx: Context): PolyProto =
derivedPolyProto(targs mapConserve tm, tm(resultType))
def fold[T](x: T, ta: TypeAccumulator[T])(implicit ctx: Context): T =
ta(ta.foldOver(x, targs), resultType)
override def deepenProto(implicit ctx: Context) = derivedPolyProto(targs, resultType.deepenProto)
}
/** A prototype for expressions [] that are known to be functions:
*
* [] _
*/
@sharable object AnyFunctionProto extends UncachedGroundType with MatchAlways
/** A prototype for type constructors that are followed by a type application */
@sharable object AnyTypeConstructorProto extends UncachedGroundType with MatchAlways
/** Add all parameters in given polytype `pt` to the constraint's domain.
* If the constraint contains already some of these parameters in its domain,
* make a copy of the polytype and add the copy's type parameters instead.
* Return either the original polytype, or the copy, if one was made.
* Also, if `owningTree` is non-empty, add a type variable for each parameter.
* @return The added polytype, and the list of created type variables.
*/
def constrained(pt: PolyType, owningTree: untpd.Tree)(implicit ctx: Context): (PolyType, List[TypeVar]) = {
val state = ctx.typerState
assert(!(ctx.typerState.isCommittable && owningTree.isEmpty),
s"inconsistent: no typevars were added to committable constraint ${state.constraint}")
def newTypeVars(pt: PolyType): List[TypeVar] =
for (n <- (0 until pt.paramNames.length).toList)
yield new TypeVar(PolyParam(pt, n), state, owningTree, ctx.owner)
val added =
if (state.constraint contains pt) pt.duplicate(pt.paramNames, pt.paramBounds, pt.resultType)
else pt
val tvars = if (owningTree.isEmpty) Nil else newTypeVars(added)
ctx.typeComparer.addToConstraint(added, tvars)
(added, tvars)
}
/** Same as `constrained(pt, EmptyTree)`, but returns just the created polytype */
def constrained(pt: PolyType)(implicit ctx: Context): PolyType = constrained(pt, EmptyTree)._1
/** The normalized form of a type
* - unwraps polymorphic types, tracking their parameters in the current constraint
* - skips implicit parameters; if result type depends on implicit parameter,
* replace with Wildcard.
* - converts non-dependent method types to the corresponding function types
* - dereferences parameterless method types
* - dereferences nullary method types provided the corresponding function type
* is not a subtype of the expected type.
* Note: We need to take account of the possibility of inserting a () argument list in normalization. Otherwise, a type with a
* def toString(): String
* member would not count as a valid solution for ?{toString: String}. This would then lead to an implicit
* insertion, with a nice explosion of inference search because of course every implicit result has some sort
* of toString method. The problem is solved by dereferencing nullary method types if the corresponding
* function type is not compatible with the prototype.
*/
def normalize(tp: Type, pt: Type)(implicit ctx: Context): Type = Stats.track("normalize") {
tp.widenSingleton match {
case poly: PolyType => normalize(constrained(poly).resultType, pt)
case mt: MethodType =>
if (mt.isImplicit)
if (mt.isDependent)
mt.resultType.substParams(mt, mt.paramTypes.map(Function.const(WildcardType)))
else mt.resultType
else
if (mt.isDependent) tp
else {
val rt = normalize(mt.resultType, pt)
if (pt.isInstanceOf[ApplyingProto])
mt.derivedMethodType(mt.paramNames, mt.paramTypes, rt)
else {
val ft = defn.FunctionOf(mt.paramTypes, rt)
if (mt.paramTypes.nonEmpty || ft <:< pt) ft else rt
}
}
case et: ExprType => et.resultType
case _ => tp
}
}
/** Approximate occurrences of parameter types and uninstantiated typevars
* by wildcard types.
*/
final def wildApprox(tp: Type, theMap: WildApproxMap = null)(implicit ctx: Context): Type = tp match {
case tp: NamedType => // default case, inlined for speed
if (tp.symbol.isStatic) tp
else tp.derivedSelect(wildApprox(tp.prefix, theMap))
case tp: RefinedType => // default case, inlined for speed
tp.derivedRefinedType(wildApprox(tp.parent, theMap), tp.refinedName, wildApprox(tp.refinedInfo, theMap))
case tp: TypeAlias => // default case, inlined for speed
tp.derivedTypeAlias(wildApprox(tp.alias, theMap))
case tp @ PolyParam(poly, pnum) =>
def unconstrainedApprox = WildcardType(wildApprox(poly.paramBounds(pnum)).bounds)
if (ctx.mode.is(Mode.TypevarsMissContext))
unconstrainedApprox
else
ctx.typerState.constraint.entry(tp) match {
case bounds: TypeBounds => wildApprox(WildcardType(bounds))
case NoType => unconstrainedApprox
case inst => wildApprox(inst)
}
case MethodParam(mt, pnum) =>
WildcardType(TypeBounds.upper(wildApprox(mt.paramTypes(pnum))))
case tp: TypeVar =>
wildApprox(tp.underlying)
case tp @ HKApply(tycon, args) =>
wildApprox(tycon) match {
case _: WildcardType => WildcardType // this ensures we get a * type
case tycon1 => tp.derivedAppliedType(tycon1, args.mapConserve(wildApprox(_)))
}
case tp: AndType =>
val tp1a = wildApprox(tp.tp1)
val tp2a = wildApprox(tp.tp2)
def wildBounds(tp: Type) =
if (tp.isInstanceOf[WildcardType]) tp.bounds else TypeBounds.upper(tp)
if (tp1a.isInstanceOf[WildcardType] || tp2a.isInstanceOf[WildcardType])
WildcardType(wildBounds(tp1a) & wildBounds(tp2a))
else
tp.derivedAndType(tp1a, tp2a)
case tp: OrType =>
val tp1a = wildApprox(tp.tp1)
val tp2a = wildApprox(tp.tp2)
if (tp1a.isInstanceOf[WildcardType] || tp2a.isInstanceOf[WildcardType])
WildcardType(tp1a.bounds | tp2a.bounds)
else
tp.derivedOrType(tp1a, tp2a)
case tp: LazyRef =>
WildcardType
case tp: SelectionProto =>
tp.derivedSelectionProto(tp.name, wildApprox(tp.memberProto), NoViewsAllowed)
case tp: ViewProto =>
tp.derivedViewProto(wildApprox(tp.argType), wildApprox(tp.resultType))
case _: ThisType | _: BoundType | NoPrefix => // default case, inlined for speed
tp
case _ =>
(if (theMap != null) theMap else new WildApproxMap).mapOver(tp)
}
@sharable object AssignProto extends UncachedGroundType with MatchAlways
private[ProtoTypes] class WildApproxMap(implicit ctx: Context) extends TypeMap {
def apply(tp: Type) = wildApprox(tp, this)
}
@sharable private lazy val dummyTree = untpd.Literal(Constant(null))
/** Dummy tree to be used as an argument of a FunProto or ViewProto type */
object dummyTreeOfType {
def apply(tp: Type): Tree = dummyTree withTypeUnchecked tp
def unapply(tree: Tree): Option[Type] = tree match {
case Literal(Constant(null)) => Some(tree.typeOpt)
case _ => None
}
}
}
