object specializeTypes extends SpecializeTypes
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Type Members
-
type
TypeEnv = Map[Global.Symbol, Global.Type]
- Definition Classes
- SpecializeTypes
-
abstract
class
StdPhase extends GlobalPhase
A standard phase template
A standard phase template
- Definition Classes
- SubComponent
-
class
Phase extends InfoTransform.Phase
- Definition Classes
- InfoTransform
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case class
Abstract(t: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a specialized abstract method, either specialized or original.
Symbol is a specialized abstract method, either specialized or original. The original
t
is abstract.- Definition Classes
- SpecializeTypes
-
class
Duplicator extends Duplicators
This duplicator additionally performs casts of expressions if that is allowed by the
casts
map.This duplicator additionally performs casts of expressions if that is allowed by the
casts
map.- Definition Classes
- SpecializeTypes
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case class
Forward(t: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a method that should be forwarded to 't'
Symbol is a method that should be forwarded to 't'
- Definition Classes
- SpecializeTypes
-
case class
Implementation(target: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a specialized method whose body should be the target's method body.
Symbol is a specialized method whose body should be the target's method body.
- Definition Classes
- SpecializeTypes
-
class
ImplementationAdapter extends Global.TreeSymSubstituter
A tree symbol substituter that substitutes on type skolems.
A tree symbol substituter that substitutes on type skolems. If a type parameter is a skolem, it looks for the original symbol in the 'from' and maps it to the corresponding new symbol. The new symbol should probably be a type skolem as well (not enforced).
All private members are made protected in order to be accessible from specialized classes.
- Definition Classes
- SpecializeTypes
-
case class
NormalizedMember(target: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a normalized member obtained by specializing 'target'.
Symbol is a normalized member obtained by specializing 'target'.
- Definition Classes
- SpecializeTypes
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case class
Overload(sym: Global.Symbol, env: TypeEnv) extends Product with Serializable
- Definition Classes
- SpecializeTypes
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case class
SpecialOverload(original: Global.Symbol, env: TypeEnv) extends SpecializedInfo with Product with Serializable
Symbol is a special overloaded method of 'original', in the environment env.
Symbol is a special overloaded method of 'original', in the environment env.
- Definition Classes
- SpecializeTypes
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case class
SpecialOverride(target: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a specialized override paired with
target
.Symbol is a specialized override paired with
target
.- Definition Classes
- SpecializeTypes
-
case class
SpecialSuperAccessor(t: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a special overload of the super accessor.
Symbol is a special overload of the super accessor.
- Definition Classes
- SpecializeTypes
-
class
SpecializationDuplicator extends Duplicator
Introduced to fix scala/bug#7343: Phase ordering problem between Duplicators and Specialization.
Introduced to fix scala/bug#7343: Phase ordering problem between Duplicators and Specialization. brief explanation: specialization rewires class parents during info transformation, and the new info then guides the tree changes. But if a symbol is created during duplication, which runs after specialization, its info is not visited and thus the corresponding tree is not specialized. One manifestation is the following:
object Test { class Parent[@specialized(Int) T]
def spec_method[@specialized(Int) T](t: T, expectedXSuper: String) = { class X extends Parent[T]() // even in the specialized variant, the local X class // doesn't extend Parent$mcI$sp, since its symbol has // been created after specialization and was not seen // by specialization's info transformer. ... } }
We fix this by forcing duplication to take place before specialization.
Note: The constructors phase (which also uses duplication) comes after erasure and uses the post-erasure typer => we must protect it from the beforeSpecialization phase shifting.
- Definition Classes
- SpecializeTypes
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class
SpecializationPhase extends Phase
- Definition Classes
- SpecializeTypes
-
class
SpecializationTransformer extends Global.Transformer
- Definition Classes
- SpecializeTypes
-
case class
SpecializedAccessor(target: Global.Symbol) extends SpecializedInfo with Product with Serializable
Symbol is a specialized accessor for the
target
field.Symbol is a specialized accessor for the
target
field.- Definition Classes
- SpecializeTypes
-
abstract
class
SpecializedInfo extends AnyRef
- Definition Classes
- SpecializeTypes
-
case class
SpecializedInnerClass(target: Global.Symbol, env: TypeEnv) extends SpecializedInfo with Product with Serializable
A specialized inner class that specializes original inner class
target
on a type parameter of the enclosing class, in the typeenvenv
.A specialized inner class that specializes original inner class
target
on a type parameter of the enclosing class, in the typeenvenv
.- Definition Classes
- SpecializeTypes
-
abstract
class
TypingTransformer extends Global.Transformer
- Definition Classes
- TypingTransformers
Value Members
-
final
def
!=(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
final
def
##(): Int
- Definition Classes
- AnyRef → Any
-
final
def
==(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
def
addConcreteSpecMethod(m: Global.Symbol): Unit
Add method m to the set of symbols for which we need an implementation tree in the tree transformer.
Add method m to the set of symbols for which we need an implementation tree in the tree transformer.
- Definition Classes
- SpecializeTypes
- Note
This field is part of the specializeTypes subcomponent, so any symbols that here are not garbage collected at the end of a compiler run!
-
final
def
afterOwnPhase[T](op: ⇒ T): T
- Definition Classes
- SubComponent
- Annotations
- @inline()
-
final
def
asInstanceOf[T0]: T0
- Definition Classes
- Any
-
final
def
beforeOwnPhase[T](op: ⇒ T): T
- Definition Classes
- SubComponent
- Annotations
- @inline()
-
def
changesBaseClasses: Boolean
This phase changes base classes.
This phase changes base classes.
- Definition Classes
- SpecializeTypes → InfoTransform
-
def
clone(): AnyRef
- Attributes
- protected[java.lang]
- Definition Classes
- AnyRef
- Annotations
- @native() @throws( ... )
-
def
concreteTypes(sym: Global.Symbol): List[Global.Type]
Return the types
sym
should be specialized at.Return the types
sym
should be specialized at. This may be some of the primitive types or AnyRef. AnyRef means that a new type parameter T will be generated later, known to be a subtype of AnyRef (T <: AnyRef). These are in a meaningful order for stability purposes.- Definition Classes
- SpecializeTypes
-
def
emptyEnv: TypeEnv
- Definition Classes
- SpecializeTypes
-
def
enabled: Boolean
Is this component enabled? Default is true.
Is this component enabled? Default is true.
- Definition Classes
- SubComponent
-
final
def
eq(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
-
def
equals(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
def
finalize(): Unit
- Attributes
- protected[java.lang]
- Definition Classes
- AnyRef
- Annotations
- @throws( classOf[java.lang.Throwable] )
-
final
def
getClass(): Class[_]
- Definition Classes
- AnyRef → Any
- Annotations
- @native()
-
val
global: Global.this.type
- Definition Classes
- specializeTypes → TypingTransformers → SubComponent
-
def
hasSpecializedParams(clazz: Global.Symbol): Boolean
Has
clazz
any type parameters that need be specialized?Has
clazz
any type parameters that need be specialized?- Definition Classes
- SpecializeTypes
-
def
hashCode(): Int
SubComponent are added to a HashSet and two phases are the same if they have the same name
SubComponent are added to a HashSet and two phases are the same if they have the same name
- Definition Classes
- SubComponent → AnyRef → Any
-
def
illegalSpecializedInheritance(clazz: Global.Symbol): Boolean
- Definition Classes
- SpecializeTypes
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val
initial: Boolean
True if this phase runs before all other phases.
True if this phase runs before all other phases. Usually,
parser
.- Definition Classes
- SubComponent
-
val
internal: Boolean
True if this phase is not provided by a plug-in.
True if this phase is not provided by a plug-in.
- Definition Classes
- SubComponent
-
final
def
isInstanceOf[T0]: Boolean
- Definition Classes
- Any
-
def
isNormalizedMember(m: Global.Symbol): Boolean
- Definition Classes
- SpecializeTypes
-
def
isSpecializedIn(sym: Global.Symbol, site: Global.Type): Boolean
Refines possiblySpecialized taking into account the instantiation of the specialized type variables at
site
Refines possiblySpecialized taking into account the instantiation of the specialized type variables at
site
- Definition Classes
- SpecializeTypes
-
def
keepsTypeParams: Boolean
- Definition Classes
- SpecializeTypes → InfoTransform
-
final
def
ne(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
-
def
newPhase(prev: nsc.Phase): StdPhase
Just to mark uncheckable
Just to mark uncheckable
- Definition Classes
- SpecializeTypes → InfoTransform → Transform → SubComponent
-
def
newTransformer(unit: Global.CompilationUnit): Global.Transformer
The transformer factory
The transformer factory
- Attributes
- protected
- Definition Classes
- SpecializeTypes → Transform
-
def
nonConflicting(env: TypeEnv): Boolean
Is any type variable in
env
conflicting with any if its type bounds, when type bindings inenv
are taken into account?Is any type variable in
env
conflicting with any if its type bounds, when type bindings inenv
are taken into account?A conflicting type environment could still be satisfiable.
- Definition Classes
- SpecializeTypes
-
final
def
notify(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
-
final
def
notifyAll(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
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def
originalClass(clazz: Global.Symbol): Global.Symbol
Return the generic class corresponding to this specialized class.
Return the generic class corresponding to this specialized class.
- Definition Classes
- SpecializeTypes
-
def
ownPhase: nsc.Phase
The phase corresponding to this subcomponent in the current compiler run
The phase corresponding to this subcomponent in the current compiler run
- Definition Classes
- SubComponent
-
val
phaseName: String
the name of the phase:
the name of the phase:
- Definition Classes
- SpecializeTypes → SubComponent
-
def
phaseNewFlags: Long
The following flags may be set by this phase:
The following flags may be set by this phase:
- Definition Classes
- SpecializeTypes → SubComponent
-
def
phaseNextFlags: Long
New flags defined by the phase which are not valid until immediately after it
New flags defined by the phase which are not valid until immediately after it
- Definition Classes
- SubComponent
-
def
possiblySpecialized(sym: Global.Symbol): Boolean
Is
member
potentially affected by specialization? This is a gross overapproximation, but it should be okay for use outside of specialization.Is
member
potentially affected by specialization? This is a gross overapproximation, but it should be okay for use outside of specialization.- Definition Classes
- SpecializeTypes
-
def
produceTypeParameters(syms: List[Global.Symbol], nowner: Global.Symbol, env: TypeEnv): collection.immutable.List[Global.Symbol]
Produces the symbols from type parameters
syms
of the original owner, in the given type environmentenv
.Produces the symbols from type parameters
syms
of the original owner, in the given type environmentenv
. The new owner isnowner
.Non-specialized type parameters are cloned into new ones. Type parameters specialized on AnyRef have preexisting symbols.
For instance, a @specialized(AnyRef) T, will become T$sp <: AnyRef.
- Definition Classes
- SpecializeTypes
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val
requires: List[String]
Names of phases required by this component.
Names of phases required by this component. Default is
Nil
.- Definition Classes
- SubComponent
-
val
runsAfter: collection.immutable.List[String]
- Definition Classes
- specializeTypes → SubComponent
-
val
runsBefore: List[String]
Names of phases that must run after this phase.
Names of phases that must run after this phase. Default is
Nil
.- Definition Classes
- SubComponent
-
val
runsRightAfter: Some[String]
- Definition Classes
- specializeTypes → SubComponent
-
def
satisfiabilityConstraints(env: TypeEnv): Option[TypeEnv]
- Definition Classes
- SpecializeTypes
-
def
satisfiable(env: TypeEnv, warnings: Boolean): Boolean
- Definition Classes
- SpecializeTypes
-
def
satisfiable(env: TypeEnv): Boolean
The type environment is sound w.r.t.
The type environment is sound w.r.t. to all type bounds or only soft conflicts appear. An environment is sound if all bindings are within the bounds of the given type variable. A soft conflict is a binding that does not fall within the bounds, but whose bounds contain type variables that are @specialized, (that could become satisfiable).
- Definition Classes
- SpecializeTypes
-
lazy val
specializableTypes: collection.immutable.List[Global.Type]
- Definition Classes
- SpecializeTypes
-
def
specializeCalls(unit: Global.CompilationUnit): TypingTransformer { ... /* 7 definitions in type refinement */ }
- Definition Classes
- SpecializeTypes
-
def
specializeClass(clazz: Global.Symbol, outerEnv: TypeEnv): List[Global.Symbol]
Specialize 'clazz', in the environment
outerEnv
.Specialize 'clazz', in the environment
outerEnv
. The outer environment contains bindings for specialized types of enclosing classes.A class C is specialized w.r.t to its own specialized type params
stps
, by specializing its members, and creating a new class for each combination ofstps
.- Definition Classes
- SpecializeTypes
-
val
specializedClass: HashMap[(Global.Symbol, TypeEnv), Global.Symbol]
For a given class and concrete type arguments, give its specialized class
For a given class and concrete type arguments, give its specialized class
- Definition Classes
- SpecializeTypes
-
def
specializedFunctionName(sym: Global.Symbol, args: List[Global.Type]): reflect.internal.Symbols.Symbol.NameType
- Definition Classes
- SpecializeTypes
-
def
specializedParams(sym: Global.Symbol): List[Global.Symbol]
Return specialized type parameters.
Return specialized type parameters.
- Definition Classes
- SpecializeTypes
-
val
specializedType: Global.TypeMap
- Definition Classes
- SpecializeTypes
-
def
specializedTypeVars(tpe: Global.Type): Set[Global.Symbol]
Return the set of @specialized type variables mentioned by the given type.
Return the set of @specialized type variables mentioned by the given type. It only counts type variables that appear:
- naked
- as arguments to type constructors in @specialized positions (arrays are considered as Array[@specialized T])
- Definition Classes
- SpecializeTypes
-
def
specializedTypeVars(sym: Global.Symbol): Set[Global.Symbol]
- Definition Classes
- SpecializeTypes
-
def
specializedTypeVars(tpes: List[Global.Type]): Set[Global.Symbol]
- Definition Classes
- SpecializeTypes
-
def
specializedTypeVarsBuffer(tpe: Global.Type, result: Buffer[Global.Symbol]): Unit
Return the set of @specialized type variables mentioned by the given type.
Return the set of @specialized type variables mentioned by the given type. It only counts type variables that appear:
- naked
- as arguments to type constructors in @specialized positions (arrays are considered as Array[@specialized T])
- Definition Classes
- SpecializeTypes
-
def
specializedTypeVarsBuffer(sym: Global.Symbol, result: Buffer[Global.Symbol]): Unit
- Definition Classes
- SpecializeTypes
-
def
specializesClass(sym: Global.Symbol): Global.Symbol
If the symbol is the companion of a value class, the value class.
If the symbol is the companion of a value class, the value class. Otherwise, AnyRef.
- Definition Classes
- SpecializeTypes
-
def
survivingArgs(sym: Global.Symbol, args: List[Global.Type]): List[Global.Type]
Given an original class symbol and a list of types its type parameters are instantiated at returns a list of type parameters that should remain in the TypeRef when instantiating a specialized type.
Given an original class symbol and a list of types its type parameters are instantiated at returns a list of type parameters that should remain in the TypeRef when instantiating a specialized type.
- Definition Classes
- SpecializeTypes
-
def
survivingParams(params: List[Global.Symbol], env: TypeEnv): collection.immutable.List[Global.Symbol]
Type parameters that survive when specializing in the specified environment.
Type parameters that survive when specializing in the specified environment.
- Definition Classes
- SpecializeTypes
-
final
def
synchronized[T0](arg0: ⇒ T0): T0
- Definition Classes
- AnyRef
-
val
terminal: Boolean
True if this phase runs after all other phases.
True if this phase runs after all other phases. Usually,
terminal
.- Definition Classes
- SubComponent
-
def
toString(): String
- Definition Classes
- AnyRef → Any
-
def
transformInfo(sym: Global.Symbol, tpe: Global.Type): Global.Type
Type transformation.
Type transformation. It is applied to all symbols, compiled or loaded. If it is a 'no-specialization' run, it is applied only to loaded symbols.
- Definition Classes
- SpecializeTypes → InfoTransform
-
final
def
wait(): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws( ... )
-
final
def
wait(arg0: Long, arg1: Int): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws( ... )
-
final
def
wait(arg0: Long): Unit
- Definition Classes
- AnyRef
- Annotations
- @native() @throws( ... )
-
object
SpecializedSuperConstructorCallArgument
- Definition Classes
- SpecializeTypes
-
object
TypeEnv
- Definition Classes
- SpecializeTypes
-
object
UnifyError extends Throwable with ControlThrowable with Product with Serializable
- Definition Classes
- SpecializeTypes
The Scala compiler and reflection APIs.