dotty.tools.dotc.transform
Members list
Type members
Classlikes
A utility class for generating access proxies. Currently used for inline accessors and protected accessors.
A utility class for generating access proxies. Currently used for inline accessors and protected accessors.
Attributes
- Companion
- object
- Supertypes
- Known subtypes
-
class InlineAccessors
Attributes
- Companion
- class
- Supertypes
- Self type
-
AccessProxies.type
This phase rewrites calls to Array.apply
to a direct instantiation of the array in the bytecode.
Attributes
- Companion
- class
- Supertypes
- Self type
-
ArrayApply.type
This phase rewrites calls to array constructors to newArray method in Dotty.runtime.Arrays module.
This phase rewrites calls to array constructors to newArray method in Dotty.runtime.Arrays module.
It assummes that generic arrays have already been handled by typer(see Applications.convertNewGenericArray). Additionally it optimizes calls to scala.Array.ofDim functions by replacing them with calls to newArray with specific dimensions
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
ArrayConstructors.type
Attributes
- Supertypes
Rewrite an application
Rewrite an application
(([X1, ..., Xm] => (x1, ..., xn) => b): T)[T1, ..., Tm](y1, ..., yn)
where
- all yi are pure references without a prefix
- the closure can also be contextual or erased, but cannot be a SAM type
- the type parameters Xi and type arguments Ti are optional
- the type ascription ...: T is optional
to
[xi := yi]b
This is more limited than beta reduction in inlining since it only works for simple variables yi
. It is more general since it also works for type-ascripted closures.
A typical use case is eliminating redundant closures for blackbox macros that return context functions. See i6375.scala.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
BetaReduce.type
A helper class for generating bridge methods in class root
.
A helper class for generating bridge methods in class root
.
Attributes
- Supertypes
This phase translates variables that are captured in closures to heap-allocated refs.
This phase translates variables that are captured in closures to heap-allocated refs.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
CapturedVars.type
Attributes
- Companion
- class
- Supertypes
- Self type
Checks that some definitions do not call themselves in an infinite loop This is an incomplete check, designed to catch some likely bugs instead of being exhaustive. The situations where infinite loops are diagnosed are
Checks that some definitions do not call themselves in an infinite loop This is an incomplete check, designed to catch some likely bugs instead of being exhaustive. The situations where infinite loops are diagnosed are
- A given method should not directly call itself
- An apply method in a given object should not directly call itself
- A lazy val should not directly force itself
- An extension method should not directly call itself
In all these cases, there are some situations which would not lead to an infinite loop at runtime. For instance, the call could go at runtime to an overriding version of the method or val which breaks the loop. That's why this phase only issues warnings, not errors, and also why we restrict checks to the 4 cases above, where a recursion is somewhat hidden. There are also other more complicated calling patterns that could also be diagnosed as loops with more effort. This could be improved in the future.
Attributes
- Companion
- object
- Supertypes
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
CheckNoSuperThis.type
Checks that super and this calls do not pass this
as (part of) an argument.
Checks that super and this calls do not pass this
as (part of) an argument.
Attributes
- Companion
- object
- Supertypes
- Self type
A no-op transform that checks whether the compiled sources are re-entrant. If -Ycheck:reentrant is set, the phase makes sure that there are no variables that are accessible from a global object. It excludes from checking paths that are labeled with one of the annotations
A no-op transform that checks whether the compiled sources are re-entrant. If -Ycheck:reentrant is set, the phase makes sure that there are no variables that are accessible from a global object. It excludes from checking paths that are labeled with one of the annotations
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
CheckReentrant.type
A transformer that check that requirements of Static fields\methods are implemented:
A transformer that check that requirements of Static fields\methods are implemented:
- Only objects can have members annotated with
@static
- The fields annotated with
@static
should precede any non-@static
fields. This ensures that we do not introduce surprises for users in initialization order. - If a member
foo
of anobject C
is annotated with@static
, the companion classC
is not allowed to define term members with namefoo
. - If a member
foo
of anobject C
is annotated with@static
, the companion classC
is not allowed to inherit classes that define a term member with namefoo
. - Only
@static
methods and vals are supported in companions of traits. Java8 supports those, but not vars, and JavaScript does not have interfaces at all. @static
Lazy vals are currently unsupported.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
CheckStatic.type
A compiler phase that checks for unused imports or definitions
Attributes
- Companion
- class
- Supertypes
- Self type
-
CheckUnused.type
Small phase to be run to collect main classes and store them in the context. The general rule to run this phase is:
Small phase to be run to collect main classes and store them in the context. The general rule to run this phase is:
- The output of compilation is JarArchive
- There is no
-Xmain-class
defined
The following flags affect this phase: -d path.jar -Xmain-class
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
CollectEntryPoints.type
Attributes
- Companion
- class
- Supertypes
- Self type
Collect fields that can be nulled out after use in lazy initialization.
Collect fields that can be nulled out after use in lazy initialization.
This information is used during lazy val transformation to assign null to private fields that are only used within a lazy val initializer. This is not just an optimization, but is needed for correctness to prevent memory leaks. E.g.
class TestByNameLazy(byNameMsg: => String) {
lazy val byLazyValMsg = byNameMsg
}
Here byNameMsg
should be null out once byLazyValMsg
is initialised.
A field is nullable if all the conditions below hold:
- belongs to a non trait-class
- is private[this]
- is not lazy
- its type is nullable after erasure
- is only used in a lazy val initializer
- defined in the same class as the lazy val
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
CompleteJavaEnums.type
For Scala enums that inherit from java.lang.Enum: Add constructor parameters for name
and ordinal
to pass from each case to the java.lang.Enum class.
For Scala enums that inherit from java.lang.Enum: Add constructor parameters for name
and ordinal
to pass from each case to the java.lang.Enum class.
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
Constructors.type
This transform
This transform
- moves initializers from body to constructor.
- makes all supercalls explicit
- also moves private fields that are accessed only from constructor into the constructor if possible.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Supertypes
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
CookComments.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
CountOuterAccesses.type
Counts number of accesses to outer accessors and outer fields of classes that are visible only within one source file. The info is collected in outerAccessCount
and used in the subsequent DropOuterAccessors phase
Counts number of accesses to outer accessors and outer fields of classes that are visible only within one source file. The info is collected in outerAccessCount
and used in the subsequent DropOuterAccessors phase
Attributes
- Companion
- object
- Supertypes
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
CrossVersionChecks.type
Utility class for lazy values whose evaluation depends on a context. This should be used whenever the evaluation of a lazy expression depends on some context, but the value can be re-used afterwards with a different context.
Utility class for lazy values whose evaluation depends on a context. This should be used whenever the evaluation of a lazy expression depends on some context, but the value can be re-used afterwards with a different context.
A typical use case is a lazy val in a phase object which exists once per root context where the expression intiializing the lazy val depends only on the root context, but not any changes afterwards.
Attributes
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
Dependencies.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
DropBreaks.type
Rewrites local Break throws to labeled returns. Drops try
statements on breaks if no other uses of its label remain. A Break throw with a Label
created by some enclosing boundary is replaced with a labeled return if
Rewrites local Break throws to labeled returns. Drops try
statements on breaks if no other uses of its label remain. A Break throw with a Label
created by some enclosing boundary is replaced with a labeled return if
- the throw and the boundary are in the same method, and
- there is no try expression inside the boundary that encloses the throw.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
DropOuterAccessors.type
Drops unused outer accessors of inner classes that are visible only in one toplevel class. For other classes, we can't tell whether an outer accessor is used or not. It could for instance be used in a type test in some other source.
Drops unused outer accessors of inner classes that are visible only in one toplevel class. For other classes, we can't tell whether an outer accessor is used or not. It could for instance be used in a type test in some other source.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
This phase implements the following transformations:
This phase implements the following transformations:
-
For types of method and class parameters:
=> T becomes () ?=> T
-
For references to cbn-parameters:
x becomes x.apply()
-
For arguments to cbn parameters
e becomes () ?=> e
An optimization is applied: If the argument e
to a cbn parameter is already of type () ?=> T
and is a pure expression, we avoid (2) and (3), i.e. we pass e
directly instead of () ?=> e.apply()
.
Note that () ?=> T
cannot be written in source since user-defined context functions must have at least one parameter. We use the type here as a convenient marker of something that will erase to Function0, and where we know that it came from a by-name parameter.
Note also that the transformation applies only to types of parameters, not to other occurrences of ExprTypes. In particular, embedded occurrences in function types such as (=> T) => U
are left as-is here (they are eliminated in erasure). Trying to convert these as well would mean traversing all the types, and that leads to cyclic reference errors in many cases. This can cause problems in that we might have sometimes a () ?=> T
where a => T
is expected. To compensate, there is a new clause in TypeComparer#subArg that declares () ?=> T
to be a subtype of => T
for arguments of type applications at any point after this phase and up to erasure.
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimByName.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimErasedValueType.type
This phase erases ErasedValueType to their underlying type. It also removes the synthetic cast methods u2evt$ and evt2u$ which are no longer needed afterwards. Finally, it checks that we don't introduce "double definitions" of pairs of methods that now have the same signature but were not considered matching before erasure.
This phase erases ErasedValueType to their underlying type. It also removes the synthetic cast methods u2evt$ and evt2u$ which are no longer needed afterwards. Finally, it checks that we don't introduce "double definitions" of pairs of methods that now have the same signature but were not considered matching before erasure.
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimOpaque.type
Rewrites opaque type aliases to normal alias types
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimOuterSelect.type
Eliminates syntactic references to package terms as prefixes of classes, so that there's no chance they accidentally end up in the backend.
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimPackagePrefixes.type
This phase rewrite PolyFunction subclasses to FunctionN subclasses
This phase rewrite PolyFunction subclasses to FunctionN subclasses
class Foo extends PolyFunction {
def apply(x_1: P_1, ..., x_N: P_N): R = rhs
}
becomes: class Foo extends FunctionN { def apply(x_1: P_1, ..., x_N: P_N): R = rhs }
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimPolyFunction.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimRepeated.type
A transformer that eliminates repeated parameters (T*) from all types, replacing them with Seq or Array types and adapting repeated arguments to conform to the transformed type if needed.
A transformer that eliminates repeated parameters (T*) from all types, replacing them with Seq or Array types and adapting repeated arguments to conform to the transformed type if needed.
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Replace This references to module classes in static methods by global identifiers to the corresponding modules.
Attributes
- Companion
- class
- Supertypes
- Self type
-
ElimStaticThis.type
A phase that can be inserted directly after a phase that cannot be checked, to enable a -Ycheck as soon as possible afterwards
Attributes
- Companion
- object
- Supertypes
Rewrite (x1, ... xN) => f(x1, ... xN)
for N >= 0 to f
, provided f
is a pure path of function type.
Rewrite (x1, ... xN) => f(x1, ... xN)
for N >= 0 to f
, provided f
is a pure path of function type.
This optimization is crucial for context functions. The compiler produces a contextual closure around values passed as arguments where a context function is expected, unless that value has the syntactic form of a context function literal.
Also handle variants of eta-expansions where
- result f.apply(X_1,...,X_n) is subject to a synthetic cast, or
- the application uses a specialized apply method, or
- the closure is adapted (see Erasure#adaptClosure)
Without this phase, when a contextual function is passed as an argument to a recursive function, that would have the unfortunate effect of a linear growth in transient thunks of identical type wrapped around each other, leading to performance degradation, and in some cases, stack overflows.
Attributes
- Companion
- object
- Supertypes
Make private term members that are accessed from another class non-private by resetting the Private flag and expanding their name.
Make private term members that are accessed from another class non-private by resetting the Private flag and expanding their name.
Make private accessor in value class not-private. This is necessary to unbox the value class when accessing it from separate compilation units
Also, make non-private any private parameter forwarders that forward to an inherited public or protected parameter accessor with the same name as the forwarder. This is necessary since private methods are not allowed to have the same name as inherited public ones.
See discussion in https://github.com/lampepfl/dotty/pull/784 and https://github.com/lampepfl/dotty/issues/783
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ExpandPrivate.type
Expand SAM closures that cannot be represented by the JVM as lambdas to anonymous classes. These fall into five categories
Expand SAM closures that cannot be represented by the JVM as lambdas to anonymous classes. These fall into five categories
- Partial function closures, we need to generate isDefinedAt and applyOrElse methods for these.
- Closures implementing non-trait classes
- Closures implementing classes that inherit from a class other than Object (a lambda cannot not be a run-time subtype of such a class)
- Closures that implement traits which run initialization code.
- Closures that get synthesized abstract methods in the transformation pipeline. These methods can be (1) superaccessors, (2) outer references, (3) accessors for fields.
However, implicit function types do not count as SAM types.
Attributes
- Companion
- class
- Supertypes
- Self type
-
ExpandSAMs.type
This phase adds outer accessors to classes and traits that need them. Compared to Scala 2.x, it tries to minimize the set of classes that take outer accessors by scanning class implementations for outer references.
This phase adds outer accessors to classes and traits that need them. Compared to Scala 2.x, it tries to minimize the set of classes that take outer accessors by scanning class implementations for outer references.
The following things are delayed until erasure and are performed by class OuterOps:
- add outer parameters to constructors
- pass outer arguments in constructor calls
replacement of outer this by outer paths is done in Erasure. needs to run after pattern matcher as it can add outer checks and force creation of $outer
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ExplicitOuter.type
Transform references of the form
Transform references of the form
C.this.m
where C
is a class with explicit self type and C
is not a subclass of the owner of m
to
C.this.asInstanceOf[S & C.this.type].m
where S
is the self type of C
. See run/i789.scala for a test case why this is needed.
Also replaces idents referring to the self type with ThisTypes.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
ExplicitSelf.type
Perform Step 1 in the inline classes SIP: Creates extension methods for all methods in a value class, except parameter or super accessors, or constructors.
Perform Step 1 in the inline classes SIP: Creates extension methods for all methods in a value class, except parameter or super accessors, or constructors.
Additionally, for a value class V, let U be the underlying type after erasure. We add to the companion module of V two cast methods: def u2evt$(x0: U): ErasedValueType(V, U) def evt2u$(x0: ErasedValueType(V, U)): U The casts are used in Erasure to make it typecheck, they are then removed in ElimErasedValueType. This is different from the implementation of value classes in Scala 2 (see SIP-15) which uses asInstanceOf
which does not typecheck.
Finally, if the constructor of a value class is private pr protected it is widened to public.
Also, drop the Local flag from all private[this] and protected[this] members that will be moved to the companion object.
Attributes
- Companion
- object
- Supertypes
-
trait FullParameterizationtrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ExtensionMethods.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
FirstTransform.type
The first tree transform
The first tree transform
- eliminates some kinds of trees: Imports other than language imports, Exports, NamedArgs, type trees other than TypeTree
- stubs out native methods
- eliminates self tree in Template and self symbol in ClassInfo
- collapses all type trees to trees of class TypeTree
- converts idempotent expressions with constant types
- drops branches of ifs using the rules if (true) A else B ==> A if (false) A else B ==> B
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Lift nested classes to toplevel
Lift nested classes to toplevel
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
ForwardDepChecks.type
Provides methods to produce fully parameterized versions of instance methods, where the this
of the enclosing class is abstracted out in an extra leading $this
parameter and type parameters of the class become additional type parameters of the fully parameterized method.
Provides methods to produce fully parameterized versions of instance methods, where the this
of the enclosing class is abstracted out in an extra leading $this
parameter and type parameters of the class become additional type parameters of the fully parameterized method.
Example usage scenarios are:
- extension methods of value classes
- implementations of trait methods
- static protected accessors
- local methods produced by tailrec transform
Note that the methods lift out type parameters of the class containing the instance method, but not type parameters of enclosing classes. The fully instantiated method therefore needs to be put in a scope "close" to the original method, i.e. they need to share the same outer pointer. Examples of legal positions are: in the companion object, or as a local method inside the original method.
Note: The scheme does not handle yet methods where type parameter bounds depend on value parameters of the enclosing class, as in:
class C(val a: String) extends AnyVal {
def foo[U <: a.type]: Unit = ...
}
The expansion of method foo
would lead to
def foo$extension[U <: $this.a.type]($this: C): Unit = ...
which is not typable. Not clear yet what to do. Maybe allow PolyTypes to follow method parameters and translate to the following:
def foo$extension($this: C)[U <: $this.a.type]: Unit = ...
Attributes
- See also
-
class-dependent-extension-method.scala in pending/pos.
- Companion
- object
- Supertypes
- Known subtypes
-
class ExtensionMethods
Attributes
- Companion
- trait
- Supertypes
- Self type
-
FullParameterization.type
This phase adds forwarder for XXL functions apply
methods that are implemented with a method with explicit parameters (not in Array[Object]).
This phase adds forwarder for XXL functions apply
methods that are implemented with a method with explicit parameters (not in Array[Object]).
In particular for every method def apply(x1: T1, ... xn: Tn): R
in class M
subtype of FunctionN[T1, ..., Tn, R]
with N
> 22 a forwarder def apply(xs: Array[Object]): R = this.apply(xs(0).asInstanceOf[T1], ..., xs(n-1).asInstanceOf[Tn]).asInstanceOf[R]
is generated.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
Helper object to generate generic java signatures, as defined in the Java Virtual Machine Specification, §4.3.4
Helper object to generate generic java signatures, as defined in the Java Virtual Machine Specification, §4.3.4
Attributes
- Supertypes
- Self type
-
GenericSignatures.type
Performs the following rewritings for fields of a class:
Performs the following rewritings for fields of a class:
Also, generate setters for fields that are private but not private[this] The form of a setter is
Omitted from the rewritings are
- private[this] fields in classes (excluding traits, value classes)
- fields generated for static modules (TODO: needed?)
- parameters, static fields, and fields coming from Java
The rhs is computed later, in phase Memoize.
Furthermore, assignments to mutable vars with setters are replaced by setter calls
p.x = e --> p.x_=(e)
No fields are generated yet. This is done later in phase Memoize.
Also, drop the Local flag from all private[this] and protected[this] members. This allows subsequent code motions in Flatten.
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
HoistSuperArgs.type
This phase hoists complex arguments of supercalls and this-calls out of the enclosing class. Example:
This phase hoists complex arguments of supercalls and this-calls out of the enclosing class. Example:
class B(y: Int) extends A({ def f(x: Int) = x * x; f(y)})
is translated to
class B(y: Int) extends A(B#B$superArg$1(this.y)) {
private <static> def B$superArg$1(y: Int): Int = {
def f(x: Int): Int = x.*(x); f(y)
}
}
An argument is complex if it contains a method or template definition, a this or a new, or it contains an identifier which needs a this
prefix to be accessed. This is the case if the identifier has neither a global reference nor a reference to a parameter of the enclosing class.
Attributes
- See also
-
needsHoist for an implementation. A hoisted argument definition gets the parameters of the class it is hoisted from as method parameters. The definition is installed in the scope enclosing the class, or, if that is a package, it is made a static method of the class itself.
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Rewrite an application
Rewrite an application
{new { def unapply(x0: X0)(x1: X1,..., xn: Xn) = b }}.unapply(y0)(y1, ..., yn)
where
- the method is
unapply
orunapplySeq
- the method does not have type parameters
to
[xi := yi]b
This removes placeholders added by inline unapply
/unapplySeq
patterns.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
InlinePatterns.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
InlineVals.type
Inlines all calls to inline methods that are not in an inline method or a quote
Inlines all calls to inline methods that are not in an inline method or a quote
Attributes
- Companion
- object
- Supertypes
Implements code coverage by inserting calls to scala.runtime.coverage.Invoker ("instruments" the source code). The result can then be consumed by the Scoverage tool.
Implements code coverage by inserting calls to scala.runtime.coverage.Invoker ("instruments" the source code). The result can then be consumed by the Scoverage tool.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MacroTransformclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
InstrumentCoverage.type
The phase is enabled if the -Yinstrument option is set. If enabled, it counts the number of closures or allocations for each source position. It does this by generating a call to dotty.tools.dotc.util.Stats.doRecord.
The phase is enabled if the -Yinstrument option is set. If enabled, it counts the number of closures or allocations for each source position. It does this by generating a call to dotty.tools.dotc.util.Stats.doRecord.
Attributes
- Companion
- object
- Supertypes
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
Instrumentation.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
InterceptedMethods.type
Replace member references as follows:
Replace member references as follows:
x != y
for != in class Any becomes!(x == y)
with == in class Any.x.##
for ## in NullClass becomes0
x.##
for ## in Any becomes calls to ScalaRunTime.hash, using the most precise overload available
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
LambdaLift.type
This phase performs the necessary rewritings to eliminate classes and methods nested in other methods. In detail:
This phase performs the necessary rewritings to eliminate classes and methods nested in other methods. In detail:
- It adds all free variables of local functions as additional parameters (proxies).
- It rebinds references to free variables to the corresponding proxies,
- It lifts all local functions and classes out as far as possible, but at least to the enclosing class.
- It stores free variables of non-trait classes as additional fields of the class. The fields serve as proxies for methods in the class, which avoids the need of passing additional parameters to these methods.
A particularly tricky case are local traits. These cannot store free variables as field proxies, because LambdaLift runs after Mixin, so the fields cannot be expanded anymore. Instead, methods of local traits get free variables of the trait as additional proxy parameters. The difference between local classes and local traits is illustrated by the two rewritings below.
def f(x: Int) = { def f(x: Int) = new C(x).f2 class C { ==> class C(x$1: Int) { def f2 = x def f2 = x$1 } } new C().f2 }
def f(x: Int) = { def f(x: Int) = new C().f2(x) trait T { ==> trait T def f2 = x def f2(x$1: Int) = x$1 } } class C extends T class C extends T new C().f2 }
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Rewrite { stats; expr}.f(args)
to { stats; expr.f(args) }
and { stats; expr }(args)
to { stats; expr(args) }
before proceeding, but leave closures alone. This is necessary to be able to collapse applies of IFTs (this is done in Erasure).
Rewrite { stats; expr}.f(args)
to { stats; expr.f(args) }
and { stats; expr }(args)
to { stats; expr(args) }
before proceeding, but leave closures alone. This is necessary to be able to collapse applies of IFTs (this is done in Erasure).
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
LetOverApply.type
Lifts try's that might be executed on non-empty expression stacks to their own methods. I.e.
Lifts try's that might be executed on non-empty expression stacks to their own methods. I.e.
try body catch handler
is lifted to
{ def liftedTree$n() = try body catch handler; liftedTree$n() }
However, don't lift try's without catch expressions (try-finally). Lifting is needed only for try-catch expressions that are evaluated in a context where the stack might not be empty. finally
does not attempt to continue evaluation after an exception, so the fact that values on the stack are 'lost' does not matter (copied from https://github.com/scala/scala/pull/922).
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
MacroAnnotations.type
A base class for transforms. A transform contains a compiler phase which applies a tree transformer.
A base class for transforms. A transform contains a compiler phase which applies a tree transformer.
Attributes
- Supertypes
- Known subtypes
-
class PrepJSInteropclass Inliningclass InstrumentCoverageclass PickleQuotesclass PostInliningclass PostTyperclass Splicingclass StagingShow all
A MegaPhase combines a number of mini-phases which are all executed in a single tree traversal.
A MegaPhase combines a number of mini-phases which are all executed in a single tree traversal.
This is an evolution of the previous "TreeTransformers.scala", which was written by @DarkDimius and is described in his thesis.
Attributes
Provides the implementations of all getters and setters, introducing fields to hold the value accessed by them. TODO: Make LazyVals a part of this phase?
Provides the implementations of all getters and setters, introducing fields to hold the value accessed by them. TODO: Make LazyVals a part of this phase?
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
This phase performs the following transformations:
This phase performs the following transformations:
-
(done in
traitDefs
andtransformSym
) For every concrete trait getterdef x(): T = expr
make it non-private, and add the definition of its trait setter:
<mods> def TraitName$_setter_$x(v: T): Unit
-
(done in
traitDefs
) Make every concrete trait setterdef x_=(y: T) = ()
deferred by mapping it to
<mods> def x_=(y: T)
-
(done in
transformSym
) For every module class constructor in traits, remove its Private flag (but do not expand its name), since it will have to be instantiated in the classes that mix in the trait. -
For a non-trait class C:
For every trait M directly implemented by the class (see SymUtils.mixin), in reverse linearization order, add the following definitions to C:
4.1 (done in `traitInits`) For every parameter accessor `<mods> def x(): T` in M, in order of textual occurrence, add <mods> def x() = e where `e` is the constructor argument in C that corresponds to `x`. Issue an error if no such argument exists. 4.2 (done in `traitInits`) For every concrete trait getter `<mods> def x(): T` in M which is not a parameter accessor, in order of textual occurrence, produce the following: 4.2.1 If `x` is also a member of `C`, and is a lazy val, <mods> lazy val x: T = super[M].x 4.2.2 If `x` is also a member of `C`, and is a module, <mods> lazy module val x: T = new T$(this) 4.2.3 If `x` is also a member of `C`, and is something else: <mods> def x(): T = _ 4.2.5 If `x` is not a member of `C`, nothing gets added. 4.3 (done in `superCallOpt`) The call: super[M].$init$() 4.4 (done in `setters`) For every concrete setter `<mods> def x_=(y: T)` in M: <mods> def x_=(y: T) = () 4.5 (done in `mixinForwarders`) For every method `<mods> def f[Ts](ps1)...(psN): U` imn M` that needs to be disambiguated: <mods> def f[Ts](ps1)...(psN): U = super[M].f[Ts](ps1)...(psN) A method in M needs to be disambiguated if it is concrete, not overridden in C, and if it overrides another concrete method.
-
(done in
transformTemplate
andtransformSym
) Drop all parameters from trait constructors, and rename them tonme.TRAIT_CONSTRUCTOR
. -
(done in
transformSym
) Drop ParamAccessor flag from all parameter accessors in traits.
Conceptually, this is the second half of the previous mixin phase. It needs to run after erasure because it copies references to possibly private inner classes and objects into enclosing classes where they are not visible. This can only be done if all references are symbolic.
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Supertypes
Move static methods from companion to the class itself
Move static methods from companion to the class itself
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
MoveStatics.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
NonLocalReturns.type
A module that can produce a kind of iterator (Cursor
), which yields all pairs of overriding/overridden symbols that are visible in some baseclass, unless there's a parent class that already contains the same pairs.
A module that can produce a kind of iterator (Cursor
), which yields all pairs of overriding/overridden symbols that are visible in some baseclass, unless there's a parent class that already contains the same pairs.
Adapted from the 2.9 version of OverridingPairs. The 2.10 version is IMO way too unwieldy to be maintained.
Attributes
- Supertypes
- Self type
-
OverridingPairs.type
Checks that the Phase Consistency Principle (PCP) holds and heals types.
Checks that the Phase Consistency Principle (PCP) holds and heals types.
Local term references are phase consistent if and only if they are used at the same level as their definition.
Local type references can be used at the level of their definition or lower. If used used at a higher level, it will be healed if possible, otherwise it is inconsistent.
Type healing consists in transforming a phase inconsistent type T
into summon[Type[T]].Underlying
.
As references to types do not necessarily have an associated tree it is not always possible to replace the types directly. Instead we always generate a type alias for it and place it at the start of the surrounding quote. This also avoids duplication. For example: '{ val x: List[T] = ListT () }
is transformed to
'{ type t$1 = summon[Type[T]].Underlying val x: List[t$1] = Listt$1; () }
Attributes
- Companion
- object
- Supertypes
-
trait Checkingclass TreeMapWithStagesclass TreeMapWithImplicitsclass TreeMapclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
PCPCheckAndHeal.type
For all private parameter accessors
For all private parameter accessors
private val x: T = ...
If there is a chain of parameter accessors starting with x
such that (1) The last parameter accessor in the chain is a field that's accessible from the current class, and (2) each preceding parameter is forwarded in the supercall of its class to a parameter that's also named x
then change the accessor to
private def x$accessor: T = super.x'.asInstanceOf[T]
where x' is a reference to the final parameter in the chain. Property (1) is established by the @see forwardParamAccessors method in PostTyper.
The reason for renaming x
to x$accessor
is that private methods in the JVM cannot override public ones.
The aim of this transformation is to avoid redundant parameter accessor fields.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
ParamForwarding.type
The pattern matching transform. After this phase, the only Match nodes remaining in the code are simple switches where every pattern is an integer or string constant
Attributes
- Companion
- class
- Supertypes
- Self type
-
PatternMatcher.type
Translates quoted terms and types to unpickleExprV2
or unpickleType
method calls.
Translates quoted terms and types to unpickleExprV2
or unpickleType
method calls.
Transforms top level quote
'{ ...
@TypeSplice type X0 = {{ 0 | .. | contentsTpe0 | .. }}
@TypeSplice type X2 = {{ 1 | .. | contentsTpe1 | .. }}
val x1: U1 = ???
val x2: U2 = ???
...
{{{ 3 | x1 | contents0 | T0
}}}
// hole
...
{{{
4 | x2 | contents1 | T1
}}}
// hole
...
{{{
5 | x1, x2 | contents2 | T2
}}}
// hole
...
}
to
unpickleExprV2(
pickled = [[ // PICKLED TASTY
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
PickleQuotes.type
A phase that adds mirror support for anonymous mirrors created at inlining.
A phase that adds mirror support for anonymous mirrors created at inlining.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MacroTransformclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
PostInlining.type
A macro transform that runs immediately after typer and that performs the following functions:
A macro transform that runs immediately after typer and that performs the following functions:
(1) Add super accessors (@see SuperAccessors)
(2) Convert parameter fields that have the same name as a corresponding public parameter field in a superclass to a forwarder to the superclass field (corresponding = super class field is initialized with subclass field)
Attributes
- See also
-
forwardParamAccessors. (3) Add synthetic members (@see SyntheticMembers) (4) Check that
New
nodes can be instantiated, and that annotations are valid (5) Convert all trees representing types to TypeTrees. (6) Check the bounds of AppliedTypeTrees (7) Insert.package
for selections of package object members (8) Replaces self references by name withthis
(9) Adds SourceFile annotations to all top-level classes and objects (10) Adds Child annotations to all sealed classes (11) Minimizescall
fields ofInlined
nodes to just point to the toplevel class from which code was inlined. The reason for making this a macro transform is that some functions (in particular super and protected accessors and instantiation checks) are naturally top-down and don't lend themselves to the bottom-up approach of a mini phase. The other two functions (forwarding param accessors and synthetic methods) only apply to templates and fit mini-phase or subfunction of a macro phase equally well. But taken by themselves they do not warrant their own group of miniphases before pickling. - Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MacroTransformclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
A base class for a phase that precedes a rechecker and that allows installing new types for local symbols.
A base class for a phase that precedes a rechecker and that allows installing new types for local symbols.
Attributes
- Supertypes
- Known subtypes
Add accessors for all protected accesses. An accessor is needed if according to the rules of the JVM a protected class member is not accessible from the point of access, but is accessible if the access is from an enclosing class. In this point a public access method is placed in that enclosing class.
Add accessors for all protected accesses. An accessor is needed if according to the rules of the JVM a protected class member is not accessible from the point of access, but is accessible if the access is from an enclosing class. In this point a public access method is placed in that enclosing class.
Attributes
- Companion
- class
- Supertypes
- Self type
-
ProtectedAccessors.type
This phase makes all erased term members of classes private so that they cannot conflict with non-erased members. This is needed so that subsequent phases like ResolveSuper that inspect class members work correctly. The phase also replaces all expressions that appear in an erased context by default values. This is necessary so that subsequent checking phases such as IsInstanceOfChecker don't give false negatives.
This phase makes all erased term members of classes private so that they cannot conflict with non-erased members. This is needed so that subsequent phases like ResolveSuper that inspect class members work correctly. The phase also replaces all expressions that appear in an erased context by default values. This is necessary so that subsequent checking phases such as IsInstanceOfChecker don't give false negatives.
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
PruneErasedDefs.type
A base class that runs a simplified typer pass over an already re-typed program. The pass does not transform trees but returns instead the re-typed type of each tree as it is traversed. The Recheck phase must be directly preceded by a phase of type PreRecheck.
A base class that runs a simplified typer pass over an already re-typed program. The pass does not transform trees but returns instead the re-typed type of each tree as it is traversed. The Recheck phase must be directly preceded by a phase of type PreRecheck.
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass Phaseclass Objecttrait Matchableclass AnyShow all
- Known subtypes
-
class CheckCapturesclass TestRecheck
- Self type
Helper methods to construct trees calling methods in Quotes.reflect
based on the current quotes
tree
Helper methods to construct trees calling methods in Quotes.reflect
based on the current quotes
tree
Attributes
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
This phase implements super accessors in classes that need them.
This phase implements super accessors in classes that need them.
For every trait M directly implemented by the class (see SymUtils.mixin), in reverse linearization order, add the following definitions to C:
For every superAccessor <mods> def super$f[Ts](ps1)...(psN): U
in M:
<mods> def super$f[Ts](ps1)...(psN): U = super[S].f[Ts](ps1)...(psN)
where S
is the superclass of M
in the linearization of C
.
This is the first part of what was the mixin phase. It is complemented by Mixin, which runs after erasure.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
ResolveSuper.type
The preceding lambda lift and flatten phases move symbols to different scopes and rename them. This miniphase cleans up afterwards and makes sure that all class scopes contain the symbols defined in them.
The preceding lambda lift and flatten phases move symbols to different scopes and rename them. This miniphase cleans up afterwards and makes sure that all class scopes contain the symbols defined in them.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
RestoreScopes.type
Removes Select
s that would be compiled into GetStatic
.
Removes Select
s that would be compiled into GetStatic
.
Otherwise, the backend needs to be aware that some qualifiers need to be dropped.
A tranformation similar to what this phase does seems to be performed by flatten in nsc.
The side effects of the qualifier of a dropped Select
is normally retained. As an exception, the qualifier is completely dropped if it is a reference to a static owner (see isStaticOwnerRef
). Concretely, this means that in
object Foo {
println("side effects")
object Bar
class Baz
}
Foo.Bar
new Foo.Baz()
the Foo
qualifiers will be dropped, since it is a static object. The println("side effects")
will therefore not be executed.
This intended behavior is equivalent to what scalac does.
Attributes
- Authors:
-
Dmytro Petrashko
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
SelectStatic.type
A transformer that eliminates SeqLiteral's, transforming SeqLiteral(elems)
to an operation equivalent to
A transformer that eliminates SeqLiteral's, transforming SeqLiteral(elems)
to an operation equivalent to
JavaSeqLiteral(elems).toSeq
Instead of toSeq
, which takes an implicit, the appropriate "wrapArray" method is called directly. The reason for this step is that JavaSeqLiterals, being arrays keep a precise type after erasure, whereas SeqLiterals only get the erased type Seq
,
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
SeqLiterals.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
SetRootTree.type
This phase synthesizes specialized methods for FunctionN, this is done since there are no scala signatures in the bytecode for the specialized methods.
This phase synthesizes specialized methods for FunctionN, this is done since there are no scala signatures in the bytecode for the specialized methods.
We know which specializations exist for the different arities, therefore we can hardcode them. This should, however be removed once we're using a different standard library.
Attributes
- Companion
- object
- Supertypes
-
trait InfoTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
Attributes
- Companion
- class
- Supertypes
- Self type
-
SpecializeFunctions.type
Specializes Tuples by replacing tuple construction and selection trees.
Specializes Tuples by replacing tuple construction and selection trees.
Specifically:
- Replaces
(1, 1)
(which isTuple2.apply[Int, Int](1, 1)
) andnew Tuple2[Int, Int](1, 1)
withnew Tuple2$mcII$sp(1, 1)
. - Replaces
(_: Tuple2[Int, Int])._1
with(_: Tuple2[Int, Int])._1$mcI$sp
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
SpecializeTuples.type
Transforms level 1 splices into holes. To do so it transforms the contents of the splice into a lambda that receives all cross-quote references.
Transforms level 1 splices into holes. To do so it transforms the contents of the splice into a lambda that receives all cross-quote references.
Cross-quote reference is a reference to a definition that is not defined in the current quote. Those references appear in quotes that are nested in a splice.
After this phase we have the invariant where all splices have the following shape
{{{ <holeIdx> | <holeType> | <captures>* | (<capturedTerms>*) => <spliceContent>
}}}
where <spliceContent>
does not contain any free references to quoted definitions and <captures>*
contains the quotes with references to all cross-quote references. There are some special rules for references in the LHS of assignments and cross-quote method references.
In the following code example x1
and x2
are cross-quote references.
'{ ...
val x1: T1 = ???
val x2: T2 = ???
${ (q: Quotes) ?=> f('{ g(x1, x2) }) }: T3
}
This phase identifies cross-quote references such as x1
and replaces it with an ${x1$}
. All cross-quote arguments are directly applied in the lambda.
'{ ...
val x1: T1 = ???
val x2: T2 = ???
{{{
0 | T3 | x1, x2 |
(x1$: Expr[T1], x2$: Expr[T2]) => // body of this lambda does not contain references to x1 or x2
(q: Quotes) ?=> f('{ g(${x1$}, ${x2$}) })
}}}
}
and then performs the same transformation on '{ g(${x1$}, ${x2$}) }
.
Attributes
- Companion
- object
- Supertypes
Checks that the Phase Consistency Principle (PCP) holds and heals types.
Checks that the Phase Consistency Principle (PCP) holds and heals types.
Type healing consists in transforming a phase inconsistent type T
into ${ implicitly[Type[T]] }
.
Attributes
- Companion
- object
- Supertypes
This class adds super accessors for all super calls that either appear in a trait or have as a target a member of some outer class.
This class adds super accessors for all super calls that either appear in a trait or have as a target a member of some outer class.
It also checks that:
(1) Symbols accessed from super are not abstract, or are overridden by an abstract override.
(2) If a symbol accessed from super is defined in a real class (not a trait), there are no abstract members which override this member in Java's rules (see SI-4989; such an access would lead to illegal bytecode)
(3) Super calls do not go to some synthetic members of Any (see isDisallowed)
(4) Super calls do not go to synthetic field accessors
Attributes
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
SyntheticMembers.type
Synthetic method implementations for case classes, case objects, and value classes.
Synthetic method implementations for case classes, case objects, and value classes.
Selectively added to case classes/objects, unless a non-default implementation already exists: def equals(other: Any): Boolean def hashCode(): Int def canEqual(other: Any): Boolean def toString(): String def productElement(i: Int): Any def productArity: Int def productPrefix: String
Add to serializable static objects, unless an implementation already exists: private def writeReplace(): AnyRef
Selectively added to value classes, unless a non-default implementation already exists: def equals(other: Any): Boolean def hashCode(): Int
Attributes
- Companion
- object
- Supertypes
A Tail Rec Transformer.
A Tail Rec Transformer.
What it does:
Finds method calls in tail-position and replaces them with jumps. A call is in a tail-position if it is the last instruction to be executed in the body of a method. This includes being in tail-position of a return
from a Labeled
block which is itself in tail-position (which is critical for tail-recursive calls in the cases of a match
). To identify tail positions, we recurse over the trees that may contain calls in tail-position (trees that can't contain such calls are not transformed).
When a method contains at least one tail-recursive call, its rhs is wrapped in the following structure:
var localForParam1: T1 = param1
...
while (<empty>) {
tailResult[ResultType]: {
return {
// original rhs with tail recursive calls transformed (see below)
}
}
}
Self-recursive calls in tail-position are then replaced by (a) reassigning the local var
s substituting formal parameters and (b) a return
from the tailResult
labeled block, which has the net effect of looping back to the beginning of the method. If the receiver is modifed in a recursive call, an additional var
is used to replace this
.
As a complete example of the transformation, the classical fact
function, defined as:
def fact(n: Int, acc: Int): Int =
if (n == 0) acc
else fact(n - 1, acc * n)
is rewritten as:
def fact(n: Int, acc: Int): Int = {
var acc$tailLocal1: Int = acc
var n$tailLocal1: Int = n
while (<empty>) {
tailLabel1[Unit]: {
return {
if (n$tailLocal1 == 0)
acc$tailLocal1
else {
val n$tailLocal1$tmp1: Int = n$tailLocal1 - 1
val acc$tailLocal1$tmp1: Int = acc$tailLocal1 * n$tailLocal1
n$tailLocal1 = n$tailLocal1$tmp1
acc$tailLocal1 = acc$tailLocal1$tmp1
(return[tailLabel1] ()): Int
}
}
}
}
}
As the JVM provides no way to jump from a method to another one, non-recursive calls in tail-position are not optimized.
A method call is self-recursive if it calls the current method and the method is final (otherwise, it could be a call to an overridden method in a subclass). Recursive calls on a different instance are optimized.
This phase has been moved after erasure to allow the use of vars for the parameters combined with a WhileDo
. This is also beneficial to support polymorphic tail-recursive calls.
In scalac, if the method had type parameters, the call must contain the same parameters as type arguments. This is no longer the case in dotc thanks to being located after erasure. In scalac, this is named tailCall but it does only provide optimization for self recursive functions, that's why it's renamed to tailrec
Attributes
- Authors:
-
Erik Stenman, Iulian Dragos, ported and heavily modified for dotty by Dmitry Petrashko moved after erasure and adapted to emit
Labeled
blocks by Sébastien Doeraene - Companion
- object
- Supertypes
A class that can be used to test basic rechecking without any customaization
A class that can be used to test basic rechecking without any customaization
Attributes
- Companion
- class
- Supertypes
- Self type
-
TestRecheck.type
Attributes
- Companion
- object
- Supertypes
-
class Rechecktrait SymTransformertrait DenotTransformerclass Phaseclass Objecttrait Matchableclass AnyShow all
This phase transforms wildcards in valdefs with their default value. In particular for every valdef that is declared: val x : T = _
to val x : T = <zero of T>
This phase transforms wildcards in valdefs with their default value. In particular for every valdef that is declared: val x : T = _
to val x : T = <zero of T>
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
TransformWildcards.type
Run by -Ycheck option after a given phase, this class retypes all syntax trees and verifies that the type of each tree node so obtained conforms to the type found in the tree node. It also performs the following checks:
Run by -Ycheck option after a given phase, this class retypes all syntax trees and verifies that the type of each tree node so obtained conforms to the type found in the tree node. It also performs the following checks:
- The owner of each definition is the same as the owner of the current typing context.
- Ident nodes do not refer to a denotation that would need a select to be accessible (see tpd.needsSelect).
- After typer, identifiers and select nodes refer to terms only (all types should be represented as TypeTrees then).
Attributes
- Companion
- object
- Supertypes
-
trait SymTransformertrait DenotTransformerclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
TreeChecker.type
Attributes
- Supertypes
- Self type
-
TreeExtractors.type
The main transformer class
The main transformer class
Value parameters
- level
-
the current level, where quotes add one and splices subtract one level. The initial level is 0, a level
l
wherel > 0
implies code has been quotedl
times andl == -1
is code inside a top level splice (in an inline method). - levels
-
a stacked map from symbols to the levels in which they were defined
Attributes
- Companion
- object
- Supertypes
- Known subtypes
-
class PCPCheckAndHeal
Attributes
- Companion
- class
- Supertypes
- Self type
-
TreeMapWithStages.type
Compiles the cases that can not be handled by primitive catch cases as a common pattern match.
Compiles the cases that can not be handled by primitive catch cases as a common pattern match.
The following code:
try { <code> }
catch {
<tryCases> // Cases that can be handled by catch
<patternMatchCases> // Cases starting with first one that can't be handled by catch
}
will become:
try { <code> }
catch {
<tryCases>
case e => e match {
<patternMatchCases>
}
}
Cases that are not supported include:
- Applies and unapplies
- Idents
- Alternatives
case _: T =>
whereT
is notThrowable
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
TryCatchPatterns.type
Optimize generic operations on tuples
Optimize generic operations on tuples
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
TupleOptimizations.type
This transform normalizes type tests and type casts, also replacing type tests with singleton argument type with reference equality check Any remaining type tests
This transform normalizes type tests and type casts, also replacing type tests with singleton argument type with reference equality check Any remaining type tests
- use the object methods $isInstanceOf and $asInstanceOf
- have a reference type as receiver
- can be translated directly to machine instructions
Unfortunately this phase ended up being not Y-checkable unless types are erased. A cast to an ConstantType(3) or x.type cannot be rewritten before erasure. That's why TypeTestsCasts is called from Erasure.
Attributes
- Supertypes
- Self type
-
TypeTestsCasts.type
Attributes
- Companion
- class
- Supertypes
- Self type
-
UncacheGivenAliases.type
This phase optimizes alias givens represented as lazy vals to be uncached if that does not change runtime behavior. A definition does not need to be cached if its right hand side has a stable type and is of one of them forms
This phase optimizes alias givens represented as lazy vals to be uncached if that does not change runtime behavior. A definition does not need to be cached if its right hand side has a stable type and is of one of them forms
this this.y y
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
- Self type
This phase replaces compiletime.uninitialized
on the right hand side of a mutable field definition by _
. This avoids a
This phase replaces compiletime.uninitialized
on the right hand side of a mutable field definition by _
. This avoids a
"@compileTimeOnly("`uninitialized` can only be used as the right hand side of a mutable field definition")`
error in Erasure and communicates to Constructors that the variable does not have an initializer.
Attributes
- Companion
- object
- Supertypes
Attributes
- Companion
- class
- Supertypes
- Self type
-
UninitializedDefs.type
This phase elides unnecessary value class allocations
This phase elides unnecessary value class allocations
For a value class V defined as: class V(val underlying: U) extends AnyVal we avoid unnecessary allocations: new V(u1) == new V(u2) => u1 == u2 provided V does not redefine equals
(new V(u)).underlying() => u
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
VCElideAllocations.type
This phase inlines calls to methods of value classes.
This phase inlines calls to methods of value classes.
A value class V after ExtensionMethods will look like: class V[A, B, ...](val underlying: U) extends AnyVal { def foo[T, S, ...](arg1: A1, arg2: A2, ...) = V.foo$extensionT, S, ..., A, B, ...(arg1, arg2, ...)
...
}
Let e have type V, if e is a stable prefix or if V does not have any class type parameter, then we can rewrite: e.fooX, Y, ... as: V.foo$extensionX, Y, ..., A', B', ...(args) where A', B', ... are the class type parameters A, B, ... as seen from e
. Otherwise, we need to evaluate e first: { val ev = e V.foo$extensionX, Y, ..., A', B', ...(args) }
This phase needs to be placed after phases which may introduce calls to value class methods (like PatternMatcher). This phase uses name mangling to find the correct extension method corresponding to a value class method (see ExtensionMethods.extensionMethod), therefore we choose to place it before phases which may perform their own name mangling on value class methods (like TypeSpecializer), this way VCInlineMethods does not need to have any knowledge of the name mangling done by other phases.
Attributes
- Companion
- object
- Supertypes
-
trait IdentityDenotTransformertrait DenotTransformerclass MiniPhaseclass Phaseclass Objecttrait Matchableclass AnyShow all
Attributes
- Companion
- class
- Supertypes
- Self type
-
VCInlineMethods.type
Methods that apply to user-defined value classes
Attributes
- Companion
- class
- Supertypes
- Self type
-
YCheckPositions.type