trait Context extends Aliases with Enclosures with Names with Reifiers with FrontEnds with Infrastructure with Typers with Parsers with Evals with ExprUtils with Internals
EXPERIMENTAL
The blackbox Scala macros context.
See the overview page for a description of how macros work. This documentation entry provides information on the API available to macro writers.
A macro context wraps a compiler universe exposed in universe
and having type scala.reflect.macros.Universe.
This type is a refinement over the generic reflection API provided in scala.reflect.api.Universe. The
extended Universe provides mutability for reflection artifacts (e.g. macros can change types of compiler trees,
add annotation to symbols representing definitions, etc) and exposes some internal compiler functionality
such as Symbol.deSkolemize
or Tree.attachments
.
Another fundamental part of a macro context is macroApplication
, which provides access to the tree undergoing
macro expansion. Parts of this tree can be found in arguments of the corresponding macro implementations and
in prefix
, but macroApplication
gives the full picture.
Other than that, macro contexts provide facilities for typechecking, exploring the compiler's symbol table and enclosing trees and compilation units, evaluating trees, logging warnings/errors and much more. Refer to the documentation of top-level traits in this package to learn the details.
If a macro def refers to a macro impl that uses blackbox.Context
, then this macro def becomes a blackbox macro,
which means that its expansion will be upcast to its return type, enforcing faithfullness of that macro to its
type signature. Whitebox macros, i.e. the ones defined with whitebox.Context
, aren't bound by this restriction,
which enables a number of important use cases, but they are also going to enjoy less support than blackbox macros,
so choose wisely. See the Macros Guide for more information.
- Source
- Context.scala
- See also
scala.reflect.macros.whitebox.Context
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Type Members
-
trait
ContextInternalApi
extends MacroInternalApi
- Definition Classes
- Internals
- See also
-
type
Expr[+T] = Universe.Expr[T]
Expr wraps an abstract syntax tree and tags it with its type.
Expr wraps an abstract syntax tree and tags it with its type.
- Definition Classes
- Aliases
-
type
Modifiers = Universe.Modifiers
The type of tree modifiers.
The type of tree modifiers.
- Definition Classes
- Aliases
-
type
Name = Universe.Name
The abstract type of names.
The abstract type of names.
- Definition Classes
- Aliases
-
type
Position = Universe.Position
Defines a universe-specific notion of positions.
Defines a universe-specific notion of positions.
- Definition Classes
- Aliases
-
abstract
type
PrefixType
The type of the prefix tree from which the macro is selected.
The type of the prefix tree from which the macro is selected. See the documentation entry for
prefix
for an example. -
type
Scope = Universe.Scope
The base type of all scopes.
The base type of all scopes.
- Definition Classes
- Aliases
-
type
Symbol = Universe.Symbol
The type of symbols representing declarations.
The type of symbols representing declarations.
- Definition Classes
- Aliases
-
type
TermName = Universe.TermName
The abstract type of names representing terms.
The abstract type of names representing terms.
- Definition Classes
- Aliases
-
type
Tree = Universe.Tree
The type of Scala abstract syntax trees.
The type of Scala abstract syntax trees.
- Definition Classes
- Aliases
-
type
Type = Universe.Type
The type of Scala types, and also Scala type signatures.
The type of Scala types, and also Scala type signatures. (No difference is internally made between the two).
- Definition Classes
- Aliases
-
type
TypeName = Universe.TypeName
The abstract type of names representing types.
The abstract type of names representing types.
- Definition Classes
- Aliases
-
type
TypeTag[T] = Universe.TypeTag[T]
The type of type tags.
The type of type tags.
- Definition Classes
- Aliases
-
type
TypecheckException = macros.TypecheckException
- Definition Classes
- Typers
- See also
scala.reflect.macros.TypecheckException
-
abstract
type
TypecheckMode
Represents mode of operations of the typechecker underlying
c.typecheck
calls.Represents mode of operations of the typechecker underlying
c.typecheck
calls. Is necessary since the shape of the typechecked tree alone is not enough to guess how it should be typechecked. Can be EXPRmode (typecheck as a term), TYPEmode (typecheck as a type) or PATTERNmode (typecheck as a pattern).- Definition Classes
- Typers
-
type
WeakTypeTag[T] = Universe.WeakTypeTag[T]
The type of weak type tags.
The type of weak type tags.
- Definition Classes
- Aliases
-
case class
EnclosureException
(expected: Class[_], enclosingTrees: List[blackbox.Context.Tree]) extends Exception with Product with Serializable
Indicates than one of the enclosure methods failed to find a tree of required type among enclosing trees.
Indicates than one of the enclosure methods failed to find a tree of required type among enclosing trees.
- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
type
CompilationUnit = Universe.CompilationUnit
The type of compilation units.
The type of compilation units.
- Definition Classes
- Aliases
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
type
Run = Universe.Run
The type of compilation runs.
The type of compilation runs.
- Definition Classes
- Aliases
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
Abstract Value Members
-
abstract
def
Expr[T](tree: Tree)(implicit arg0: WeakTypeTag[T]): Expr[T]
A shorthand to create an expr.
A shorthand to create an expr.
Unlike the conventional expr factory, which requires a scala.reflect.api.TreeCreator, this one accepts a regular tree, but the resulting exprs are unable of being migrated to other universes/mirrors (the functionality normally not needed for macros, since there is only one compile-time universe and only one compile-time mirror).
- Definition Classes
- Aliases
-
abstract
val
PATTERNmode: TypecheckMode
Indicates that an argument to
c.typecheck
should be typechecked as a pattern.Indicates that an argument to
c.typecheck
should be typechecked as a pattern.- Definition Classes
- Typers
-
abstract
val
TERMmode: TypecheckMode
Indicates that an argument to
c.typecheck
should be typechecked as a term.Indicates that an argument to
c.typecheck
should be typechecked as a term. This is the default typechecking mode in Scala 2.11 and the only one supported in Scala 2.10.- Definition Classes
- Typers
-
abstract
val
TYPEmode: TypecheckMode
Indicates that an argument to
c.typecheck
should be typechecked as a type.Indicates that an argument to
c.typecheck
should be typechecked as a type.- Definition Classes
- Typers
-
abstract
def
TypeTag[T](tpe: Type): TypeTag[T]
A shorthand to create a type tag.
A shorthand to create a type tag.
Unlike the conventional type tag factory, which requires a scala.reflect.api.TypeCreator, this one accepts a regular type, but the resulting type tags are unable of being migrated to other universes/mirrors (the functionality normally not needed for macros, since there is only one compile-time universe and only one compile-time mirror).
- Definition Classes
- Aliases
-
abstract
def
WeakTypeTag[T](tpe: Type): WeakTypeTag[T]
A shorthand to create a weak type tag.
A shorthand to create a weak type tag.
Unlike the conventional type tag factory, which requires a scala.reflect.api.TypeCreator, this one accepts a regular type, but the resulting type tags are unable of being migrated to other universes/mirrors (the functionality normally not needed for macros, since there is only one compile-time universe and only one compile-time mirror).
- Definition Classes
- Aliases
-
abstract
def
abort(pos: Position, msg: String): Nothing
Abruptly terminates current macro expansion leaving a note about what happened.
Abruptly terminates current macro expansion leaving a note about what happened. Use
enclosingPosition
if you're in doubt what position to pass topos
.- Definition Classes
- FrontEnds
-
abstract
def
classPath: List[URL]
Exposes current classpath.
Exposes current classpath.
- Definition Classes
- Infrastructure
-
abstract
def
compilerSettings: List[String]
Exposes current compiler settings as a list of options.
Exposes current compiler settings as a list of options. Use
scalac -help
,scalac -X
andscalac -Y
to learn about currently supported options.- Definition Classes
- Infrastructure
-
abstract
def
echo(pos: Position, msg: String): Unit
For sending a message which should not be labelled as a warning/error, but also shouldn't require -verbose to be visible.
For sending a message which should not be labelled as a warning/error, but also shouldn't require -verbose to be visible. Use
enclosingPosition
if you're in doubt what position to pass topos
.- Definition Classes
- FrontEnds
-
abstract
def
enclosingMacros: List[Context]
Contexts that represent macros in-flight, including the current one.
Contexts that represent macros in-flight, including the current one. Very much like a stack trace, but for macros only. Can be useful for interoperating with other macros and for imposing compiler-friendly limits on macro expansion.
Is also priceless for emitting sane error messages for macros that are called by other macros on synthetic (i.e. position-less) trees. In that dire case navigate the
enclosingMacros
stack, and it will most likely contain at least one macro with a position-ful macro application. SeeenclosingPosition
for a default implementation of this logic.Unlike
openMacros
, this is a val, which means that it gets initialized when the context is created and always stays the same regardless of whatever happens during macro expansion.- Definition Classes
- Enclosures
-
abstract
def
enclosingPosition: Position
Tries to guess a position for the enclosing application.
Tries to guess a position for the enclosing application. But that is simple, right? Just dereference
pos
ofmacroApplication
? Not really. If we're in a synthetic macro expansion (no positions), we must do our best to infer the position of something that triggered this expansion. Surprisingly, quite often we can do this by navigation theenclosingMacros
stack.- Definition Classes
- Enclosures
-
abstract
def
error(pos: Position, msg: String): Unit
Emits a compilation error.
Emits a compilation error. Use
enclosingPosition
if you're in doubt what position to pass topos
.- Definition Classes
- FrontEnds
-
abstract
def
eval[T](expr: Expr[T]): T
Takes a typed wrapper for a tree of type
T
and evaluates it to a value of typeT
.Takes a typed wrapper for a tree of type
T
and evaluates it to a value of typeT
.Can be used to perform compile-time computations on macro arguments to the extent permitted by the shape of the arguments.
Known issues: because of https://issues.scala-lang.org/browse/SI-5748 trees being evaluated first need to undergo
untypecheck
. Resetting symbols and types mutates the tree in place, therefore the conventional approach is toduplicate
the tree first.scala> def impl(c: Context)(x: c.Expr[String]) = { | val x1 = c.Expr[String](c.untypecheck(x.tree.duplicate)) | println(s"compile-time value is: ${c.eval(x1)}") | x | } impl: (c: Context)(x: c.Expr[String])c.Expr[String] scala> def test(x: String) = macro impl test: (x: String)String scala> test("x") compile-time value is: x res0: String = x scala> test("x" + "y") compile-time value is: xy res1: String = xy scala> val x = "x" x: String = x scala> test(x + "y") compile-time value is: xy res2: String = xy scala> { val x = "x"; test(x + "y") } error: exception during macro expansion: scala.tools.reflect.ToolBoxError: reflective compilation failed
Note that in the last case evaluation has failed, because the argument of a macro refers to a runtime value
x
, which is unknown at compile time.- Definition Classes
- Evals
-
abstract
def
freshName[NameType <: Name](name: NameType): NameType
Creates a more or less unique name having a given name as a prefix and having the same flavor (term name or type name) as the given name.
Creates a more or less unique name having a given name as a prefix and having the same flavor (term name or type name) as the given name. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
-
abstract
def
freshName(name: String): String
Creates a string that represents a more or less unique name having a given prefix.
Creates a string that represents a more or less unique name having a given prefix. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
-
abstract
def
freshName(): String
Creates a string that represents a more or less unique name.
Creates a string that represents a more or less unique name. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
-
abstract
def
hasErrors: Boolean
Does the compilation session have any errors?
Does the compilation session have any errors?
- Definition Classes
- FrontEnds
-
abstract
def
hasWarnings: Boolean
Does the compilation session have any warnings?
Does the compilation session have any warnings?
- Definition Classes
- FrontEnds
-
abstract
def
inferImplicitValue(pt: Type, silent: Boolean = true, withMacrosDisabled: Boolean = false, pos: Position = enclosingPosition): Tree
Infers an implicit value of the expected type
pt
in the macro callsite context.Infers an implicit value of the expected type
pt
in the macro callsite context. Optionalpos
parameter provides a position that will be associated with the implicit search.If
silent
is false,TypecheckException
will be thrown in case of an inference error. Ifsilent
is true, the typecheck is silent and will returnEmptyTree
if an error occurs. Such errors don't vanish and can be inspected by turning on -Xlog-implicits. Unlike intypecheck
,silent
is true by default.- Definition Classes
- Typers
- Exceptions thrown
-
abstract
def
inferImplicitView(tree: Tree, from: Type, to: Type, silent: Boolean = true, withMacrosDisabled: Boolean = false, pos: Position = enclosingPosition): Tree
Infers an implicit view from the provided tree
tree
of the typefrom
to the typeto
in the macro callsite context.Infers an implicit view from the provided tree
tree
of the typefrom
to the typeto
in the macro callsite context. Optionalpos
parameter provides a position that will be associated with the implicit search.If
silent
is false,TypecheckException
will be thrown in case of an inference error. Ifsilent
is true, the typecheck is silent and will returnEmptyTree
if an error occurs. Such errors don't vanish and can be inspected by turning on -Xlog-implicits. Unlike intypecheck
,silent
is true by default.- Definition Classes
- Typers
- Exceptions thrown
-
abstract
def
info(pos: Position, msg: String, force: Boolean): Unit
Emits an informational message, suppressed unless
-verbose
orforce=true
.Emits an informational message, suppressed unless
-verbose
orforce=true
. UseenclosingPosition
if you're in doubt what position to pass topos
.- Definition Classes
- FrontEnds
-
abstract
val
internal: ContextInternalApi
- Definition Classes
- Internals
- See also
-
abstract
def
macroApplication: Tree
The tree that undergoes macro expansion.
The tree that undergoes macro expansion. Can be useful to get an offset or a range position of the entire tree being processed.
- Definition Classes
- Enclosures
-
abstract
val
mirror: Universe.Mirror
The mirror of the compile-time universe.
-
abstract
def
openMacros: List[Context]
Contexts that represent macros in-flight, including the current one.
Contexts that represent macros in-flight, including the current one. Very much like a stack trace, but for macros only. Can be useful for interoperating with other macros and for imposing compiler-friendly limits on macro expansion.
Is also priceless for emitting sane error messages for macros that are called by other macros on synthetic (i.e. position-less) trees. In that dire case navigate the
openMacros
stack, and it will most likely contain at least one macro with a position-ful macro application. SeeenclosingPosition
for a default implementation of this logic.Unlike
enclosingMacros
, this is a def, which means that it gets recalculated on every invocation, so it might change depending on what is going on during macro expansion.- Definition Classes
- Typers
-
abstract
def
parse(code: String): Tree
Parses a string with a Scala expression into an abstract syntax tree.
Parses a string with a Scala expression into an abstract syntax tree. Only works for expressions, i.e. parsing a package declaration will fail.
- Definition Classes
- Parsers
- Exceptions thrown
-
abstract
val
prefix: Expr[PrefixType]
The prefix tree from which the macro is selected.
The prefix tree from which the macro is selected.
For example, for a macro
filter
defined as an instance method on a collectionColl
,prefix
represents an equivalent ofthis
for normal instance methods:scala> class Coll[T] { | def filter(p: T => Boolean): Coll[T] = macro M.filter[T] | }; object M { | def filter[T](c: Context { type PrefixType = Coll[T] }) | (p: c.Expr[T => Boolean]): c.Expr[Coll[T]] = | { | println(c.prefix.tree) | c.prefix | } | } defined class Coll defined module Macros scala> new Coll[Int]().filter(_ % 2 == 0) new Coll[Int]() res0: Coll[Int] = ... scala> val x = new Coll[String]() x: Coll[String] = ... scala> x.filter(_ != "") $line11.$read.$iw.$iw.$iw.$iw.$iw.$iw.$iw.$iw.$iw.$iw.$iw.$iw.x res1 @ 35563b4b: x.type = ...
Note how the value of
prefix
changes depending on the qualifier of the macro call (i.e. the expression that is at the left-hand side of the dot).Another noteworthy thing about the snippet above is the
Context { type PrefixType = Coll[T] }
type that is used to stress that the macro implementation works with prefixes of typeColl[T]
. -
abstract
def
reifyEnclosingRuntimeClass: Tree
Given a type, generate a tree that when compiled and executed produces the runtime class of the enclosing class or module.
Given a type, generate a tree that when compiled and executed produces the runtime class of the enclosing class or module. Returns
EmptyTree
if there does not exist an enclosing class or module.- Definition Classes
- Reifiers
-
abstract
def
reifyRuntimeClass(tpe: Type, concrete: Boolean = true): Tree
Given a type, generate a tree that when compiled and executed produces the runtime class of the original type.
Given a type, generate a tree that when compiled and executed produces the runtime class of the original type. If
concrete
is true, then this function will bail on types, who refer to abstract types (likeClassTag
does).- Definition Classes
- Reifiers
-
abstract
def
reifyTree(universe: Tree, mirror: Tree, tree: Tree): Tree
Given a tree, generate a tree that when compiled and executed produces the original tree.
Given a tree, generate a tree that when compiled and executed produces the original tree. For more information and examples see the documentation for
Universe.reify
.The produced tree will be bound to the specified
universe
andmirror
. Possible values foruniverse
includeuniverse.internal.gen.mkRuntimeUniverseRef
. Possible values formirror
includeEmptyTree
(in that case the reifier will automatically pick an appropriate mirror).This function is deeply connected to
Universe.reify
, a macro that reifies arbitrary expressions into runtime trees. They do very similar things (Universe.reify
callsContext.reifyTree
to implement itself), but they operate on different metalevels (see below).Let's study the differences between
Context.reifyTree
andUniverse.reify
on an example of using them inside afooMacro
macro:* Since reify itself is a macro, it will be executed when fooMacro is being compiled (metalevel -1) and will produce a tree that when evaluated during macro expansion of fooMacro (metalevel 0) will recreate the input tree.
This provides a facility analogous to quasi-quoting. Writing "reify{ expr }" will generate an AST that represents expr. Afterwards this AST (or its parts) can be used to construct the return value of fooMacro.
* reifyTree is evaluated during macro expansion (metalevel 0) and will produce a tree that when evaluated during the runtime of the program (metalevel 1) will recreate the input tree.
This provides a way to retain certain trees from macro expansion time to be inspected later, in the runtime. For example, DSL authors may find it useful to capture DSL snippets into ASTs that are then processed at runtime in a domain-specific way.
Also note the difference between universes of the runtime trees produced by two reifies:
* The result of compiling and running the result of reify will be bound to the Universe that called reify. This is possible because it's a macro, so it can generate whatever code it wishes.
* The result of compiling and running the result of reifyTree will be the
prefix
that needs to be passed explicitly. This happens because the Universe of the evaluated result is from a different metalevel than the Context the called reify.Typical usage of this function is to retain some of the trees received/created by a macro into the form that can be inspected (via pattern matching) or compiled/run (by a reflective ToolBox) during the runtime.
- Definition Classes
- Reifiers
-
abstract
def
reifyType(universe: Tree, mirror: Tree, tpe: Type, concrete: Boolean = false): Tree
Given a type, generate a tree that when compiled and executed produces the original type.
Given a type, generate a tree that when compiled and executed produces the original type. The produced tree will be bound to the specified
universe
andmirror
. For more information and examples see the documentation forContext.reifyTree
andUniverse.reify
.- Definition Classes
- Reifiers
-
abstract
def
settings: List[String]
Exposes macro-specific settings as a list of strings.
Exposes macro-specific settings as a list of strings. These settings are passed to the compiler via the "-Xmacro-settings:setting1,setting2...,settingN" command-line option.
- Definition Classes
- Infrastructure
-
abstract
def
typecheck(tree: Tree, mode: TypecheckMode = TERMmode, pt: Type = universe.WildcardType, silent: Boolean = false, withImplicitViewsDisabled: Boolean = false, withMacrosDisabled: Boolean = false): Tree
Typechecks the provided tree against the expected type
pt
in the macro callsite context under typechecking mode specified inmode
with EXPRmode being default.Typechecks the provided tree against the expected type
pt
in the macro callsite context under typechecking mode specified inmode
with EXPRmode being default. This populates symbols and types of the tree and possibly transforms it to reflect certain desugarings.If
silent
is false,TypecheckException
will be thrown in case of a typecheck error. Ifsilent
is true, the typecheck is silent and will returnEmptyTree
if an error occurs. Such errors don't vanish and can be inspected by turning on -Ymacro-debug-verbose. Unlike ininferImplicitValue
andinferImplicitView
,silent
is false by default.Typechecking can be steered with the following optional parameters:
withImplicitViewsDisabled
recursively prohibits implicit views (though, implicit vals will still be looked up and filled in), default value is falsewithMacrosDisabled
recursively prohibits macro expansions and macro-based implicits, default value is false- Definition Classes
- Typers
- Exceptions thrown
-
abstract
val
universe: Universe
The compile-time universe.
-
abstract
def
unreifyTree(tree: Tree): Tree
Undoes reification of a tree.
Undoes reification of a tree.
This reversion doesn't simply restore the original tree (that would lose the context of reification), but does something more involved that conforms to the following laws:
1) unreifyTree(reifyTree(tree)) != tree // unreified tree is tree + saved context // in current implementation, the result of unreify is opaque // i.e. there's no possibility to inspect underlying tree/context
2) reifyTree(unreifyTree(reifyTree(tree))) == reifyTree(tree) // the result of reifying a tree in its original context equals to // the result of reifying a tree along with its saved context
3) compileAndEval(unreifyTree(reifyTree(tree))) ~ compileAndEval(tree) // at runtime original and unreified trees are behaviorally equivalent
- Definition Classes
- Reifiers
-
abstract
def
untypecheck(tree: Tree): Tree
In the current implementation of Scala's reflection API, untyped trees (also known as parser trees or unattributed trees) are observationally different from typed trees (also known as typer trees, typechecked trees or attributed trees),
In the current implementation of Scala's reflection API, untyped trees (also known as parser trees or unattributed trees) are observationally different from typed trees (also known as typer trees, typechecked trees or attributed trees),
Usually, if some compiler API takes a tree, then both untyped and typed trees will do. However in some cases, only untyped or only typed trees are appropriate. For example, eval only accepts untyped trees and one can only splice typed trees inside typed trees. Therefore in the current reflection API, there is a need in functions that go back and forth between untyped and typed trees. For this we have typecheck and
untypecheck
.Note that
untypecheck
is currently afflicted by https://issues.scala-lang.org/browse/SI-5464, which makes it sometimes corrupt trees so that they don't make sense anymore. Unfortunately, there's no workaround for that. We plan to fix this issue soon, but for now please keep it in mind. -
abstract
def
warning(pos: Position, msg: String): Unit
Emits a warning.
Emits a warning. Use
enclosingPosition
if you're in doubt what position to pass topos
.- Definition Classes
- FrontEnds
-
abstract
def
enclosingClass: Tree
Tree that corresponds to the enclosing class, or EmptyTree if not applicable.
Tree that corresponds to the enclosing class, or EmptyTree if not applicable.
- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingDef: Universe.DefDef
Tree that corresponds to the enclosing DefDef tree.
Tree that corresponds to the enclosing DefDef tree. Throws
EnclosureException
if there's no such enclosing tree.- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingImpl: Universe.ImplDef
Tree that corresponds to the enclosing ImplDef tree (i.e.
Tree that corresponds to the enclosing ImplDef tree (i.e. either ClassDef or ModuleDef). Throws
EnclosureException
if there's no such enclosing tree.- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingMethod: Tree
Tree that corresponds to the enclosing method, or EmptyTree if not applicable.
Tree that corresponds to the enclosing method, or EmptyTree if not applicable.
- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingPackage: Universe.PackageDef
Tree that corresponds to the enclosing PackageDef tree.
Tree that corresponds to the enclosing PackageDef tree. Throws
EnclosureException
if there's no such enclosing tree.- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingRun: Run
Compilation run that contains this macro application.
Compilation run that contains this macro application.
- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingTemplate: Universe.Template
Tree that corresponds to the enclosing Template tree.
Tree that corresponds to the enclosing Template tree. Throws
EnclosureException
if there's no such enclosing tree.- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
enclosingUnit: CompilationUnit
Compilation unit that contains this macro application.
Compilation unit that contains this macro application.
- Definition Classes
- Enclosures
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) c.enclosingTree-style APIs are now deprecated; consult the scaladoc for more information
- See also
-
abstract
def
fresh[NameType <: Name](name: NameType): NameType
Creates a more or less unique name having a given name as a prefix and having the same flavor (term name or type name) as the given name.
Creates a more or less unique name having a given name as a prefix and having the same flavor (term name or type name) as the given name. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use freshName instead
-
abstract
def
fresh(name: String): String
Creates a string that represents a more or less unique name having a given prefix.
Creates a string that represents a more or less unique name having a given prefix. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use freshName instead
-
abstract
def
fresh(): String
Creates a string that represents a more or less unique name.
Creates a string that represents a more or less unique name. Consult scala.reflect.macros.Names for more information on uniqueness of such names.
- Definition Classes
- Names
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use freshName instead
-
abstract
def
literal(x: Char): Expr[Char]
Shorthand for
Literal(Constant(x: Char))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Char))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: String): Expr[String]
Shorthand for
Literal(Constant(x: String))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: String))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Double): Expr[Double]
Shorthand for
Literal(Constant(x: Double))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Double))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Float): Expr[Float]
Shorthand for
Literal(Constant(x: Float))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Float))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Long): Expr[Long]
Shorthand for
Literal(Constant(x: Long))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Long))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Int): Expr[Int]
Shorthand for
Literal(Constant(x: Int))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Int))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Short): Expr[Short]
Shorthand for
Literal(Constant(x: Short))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Short))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Byte): Expr[Byte]
Shorthand for
Literal(Constant(x: Byte))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Byte))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literal(x: Boolean): Expr[Boolean]
Shorthand for
Literal(Constant(x: Boolean))
in the underlyinguniverse
.Shorthand for
Literal(Constant(x: Boolean))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literalFalse: Expr[Boolean]
Shorthand for
Literal(Constant(false))
in the underlyinguniverse
.Shorthand for
Literal(Constant(false))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literalNull: Expr[Null]
Shorthand for
Literal(Constant(null))
in the underlyinguniverse
.Shorthand for
Literal(Constant(null))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literalTrue: Expr[Boolean]
Shorthand for
Literal(Constant(true))
in the underlyinguniverse
.Shorthand for
Literal(Constant(true))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
literalUnit: Expr[Unit]
Shorthand for
Literal(Constant(()))
in the underlyinguniverse
.Shorthand for
Literal(Constant(()))
in the underlyinguniverse
.- Definition Classes
- ExprUtils
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use quasiquotes instead
-
abstract
def
resetLocalAttrs(tree: Tree): Tree
Recursively resets locally defined symbols and types in a given tree.
Recursively resets locally defined symbols and types in a given tree. WARNING: Don't use this API, go for untypecheck instead.
- Definition Classes
- Typers
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
c.untypecheck
instead
Concrete Value Members
-
final
def
!=(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
final
def
##(): Int
- Definition Classes
- AnyRef → Any
- def +(other: String): String
- def ->[B](y: B): (Context, B)
-
final
def
==(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
val
Expr: Universe.Expr.type
Constructor/Extractor for
Expr
.Constructor/Extractor for
Expr
.- Definition Classes
- Aliases
-
val
TypeTag: Universe.TypeTag.type
Constructor/Extractor for
TypeTag
.Constructor/Extractor for
TypeTag
.- Definition Classes
- Aliases
-
val
TypecheckException: macros.TypecheckException.type
- Definition Classes
- Typers
- See also
scala.reflect.macros.TypecheckException
-
val
WeakTypeTag: Universe.WeakTypeTag.type
Constructor/Extractor for
WeakTypeTag
.Constructor/Extractor for
WeakTypeTag
.- Definition Classes
- Aliases
-
final
def
asInstanceOf[T0]: T0
- Definition Classes
- Any
-
def
clone(): AnyRef
- Attributes
- protected[java.lang]
- Definition Classes
- AnyRef
- Annotations
- @throws( ... )
- def ensuring(cond: (Context) ⇒ Boolean, msg: ⇒ Any): Context
- def ensuring(cond: (Context) ⇒ Boolean): Context
- def ensuring(cond: Boolean, msg: ⇒ Any): Context
- def ensuring(cond: Boolean): Context
-
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] )
- def formatted(fmtstr: String): String
-
final
def
getClass(): Class[_]
- Definition Classes
- AnyRef → Any
-
def
hashCode(): Int
- Definition Classes
- AnyRef → Any
-
final
def
isInstanceOf[T0]: Boolean
- Definition Classes
- Any
-
final
def
ne(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
-
final
def
notify(): Unit
- Definition Classes
- AnyRef
-
final
def
notifyAll(): Unit
- Definition Classes
- AnyRef
-
def
symbolOf[T](implicit arg0: WeakTypeTag[T]): Universe.TypeSymbol
Type symbol of
x
as derived from a type tag.Type symbol of
x
as derived from a type tag.- Definition Classes
- Aliases
-
final
def
synchronized[T0](arg0: ⇒ T0): T0
- Definition Classes
- AnyRef
-
def
toString(): String
- Definition Classes
- AnyRef → Any
-
def
typeOf[T](implicit ttag: TypeTag[T]): Type
Shortcut for
implicitly[TypeTag[T]].tpe
Shortcut for
implicitly[TypeTag[T]].tpe
- Definition Classes
- Aliases
-
def
typeTag[T](implicit ttag: TypeTag[T]): TypeTag[T]
Shortcut for
implicitly[TypeTag[T]]
Shortcut for
implicitly[TypeTag[T]]
- Definition Classes
- Aliases
-
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
- @throws( ... )
-
def
weakTypeOf[T](implicit attag: WeakTypeTag[T]): Type
Shortcut for
implicitly[WeakTypeTag[T]].tpe
Shortcut for
implicitly[WeakTypeTag[T]].tpe
- Definition Classes
- Aliases
-
def
weakTypeTag[T](implicit attag: WeakTypeTag[T]): WeakTypeTag[T]
Shortcut for
implicitly[WeakTypeTag[T]]
Shortcut for
implicitly[WeakTypeTag[T]]
- Definition Classes
- Aliases
- def →[B](y: B): (Context, B)
Deprecated Value Members
-
def
typeCheck(tree: Tree, pt: Type = universe.WildcardType, silent: Boolean = false, withImplicitViewsDisabled: Boolean = false, withMacrosDisabled: Boolean = false): Tree
- Definition Classes
- Typers
- Annotations
- @deprecated
- Deprecated
(Since version 2.11.0) use
c.typecheck
instead- See also
Typers.typecheck