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package scala.tools.nsc
package typechecker
trait Tags {
self: Analyzer =>
import global._
import definitions._
trait Tag {
self: Typer =>
private def resolveTag(pos: Position, taggedTp: Type, allowMaterialization: Boolean) = beforeTyper {
def wrapper (tree: => Tree): Tree = if (allowMaterialization) (context.withMacrosEnabled[Tree](tree)) else (context.withMacrosDisabled[Tree](tree))
wrapper(inferImplicit(
EmptyTree,
taggedTp,
/*reportAmbiguous =*/ true,
/*isView =*/ false,
/*context =*/ context,
/*saveAmbiguousDivergent =*/ true,
/*pos =*/ pos
).tree)
}
/** Finds in scope or materializes a ClassTag.
* Should be used instead of ClassManifest every time compiler needs to persist an erasure.
*
* Once upon a time, we had an `ErasureTag` which was to `ClassTag` the same that `AbsTypeTag` is for `TypeTag`.
* However we found out that we don't really need this concept, so it got removed.
*
* @param pos Position for error reporting. Please, provide meaningful value.
* @param tp Type we're looking a ClassTag for, e.g. resolveClassTag(pos, IntClass.tpe) will look for ClassTag[Int].
* @param allowMaterialization If true (default) then the resolver is allowed to launch materialization macros when there's no class tag in scope.
* If false then materialization macros are prohibited from running.
*
* @returns Tree that represents an `scala.reflect.ClassTag` for `tp` if everything is okay.
* EmptyTree if the result contains unresolved (i.e. not spliced) type parameters and abstract type members.
* EmptyTree if `allowMaterialization` is false, and there is no class tag in scope.
*/
def resolveClassTag(pos: Position, tp: Type, allowMaterialization: Boolean = true): Tree = {
val taggedTp = appliedType(ClassTagClass.typeConstructor, List(tp))
resolveTag(pos, taggedTp, allowMaterialization)
}
/** Finds in scope or materializes an AbsTypeTag (if `concrete` is false) or a TypeTag (if `concrete` is true).
*
* @param pos Position for error reporting. Please, provide meaningful value.
* @param pre Prefix that represents a universe this type tag will be bound to.
* If `pre` is set to `NoType`, then any type tag in scope will do, regardless of its affiliation.
* If `pre` is set to `NoType`, and tag resolution involves materialization, then `mkBasisPrefix` will be used.
* @param tp Type we're looking a TypeTag for, e.g. resolveTypeTag(pos, reflectBasisPrefix, IntClass.tpe, false) will look for scala.reflect.basis.TypeTag[Int].
* @param concrete If true then the result must not contain unresolved (i.e. not spliced) type parameters and abstract type members.
* If false then the function will always succeed (abstract types will be reified as free types).
* @param allowMaterialization If true (default) then the resolver is allowed to launch materialization macros when there's no type tag in scope.
* If false then materialization macros are prohibited from running.
*
* @returns Tree that represents a `scala.reflect.TypeTag` for `tp` if everything is okay.
* EmptyTree if `concrete` is true and the result contains unresolved (i.e. not spliced) type parameters and abstract type members.
* EmptyTree if `allowMaterialization` is false, and there is no array tag in scope.
*/
def resolveTypeTag(pos: Position, pre: Type, tp: Type, concrete: Boolean, allowMaterialization: Boolean = true): Tree = {
val tagSym = if (concrete) TypeTagClass else AbsTypeTagClass
val tagTp = if (pre == NoType) TypeRef(BaseUniverseClass.asTypeConstructor, tagSym, List(tp)) else singleType(pre, pre member tagSym.name)
val taggedTp = appliedType(tagTp, List(tp))
resolveTag(pos, taggedTp, allowMaterialization)
}
}
}
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