Dotty Overall Structure
The compiler code is found in package dotty.tools. It spans the following three sub-packages:
backend Compiler backends (currently for JVM and JS)
dotc The main compiler
io Helper modules for file access and classpath handling.
The dotc package contains some main classes that can be run as separate
programs. The most important one is class Main. Main
inherits from
Driver which contains the highest level functions for starting a compiler
and processing some sources. Driver
in turn is based on two other high-level
classes, Compiler and Run.
Package Structure
Most functionality of dotc
is implemented in subpackages of dotc
. Here's a
list of sub-packages and their focus.
.
├── ast // Abstract syntax trees
├── config // Compiler configuration, settings, platform specific definitions.
├── core // Core data structures and operations, with specific subpackages for:
│ ├── classfile // Reading of Java classfiles into core data structures
│ ├── tasty // Reading and writing of TASTY files to/from core data structures
│ └── unpickleScala2 // Reading of Scala2 symbol information into core data structures
├── parsing // Scanner and parser
├── printing // Pretty-printing trees, types and other data
├── repl // The interactive REPL
├── reporting // Reporting of error messages, warnings and other info.
├── rewrite // Helpers for rewriting Scala 2's constructs into dotty's.
├── transform // Miniphases and helpers for tree transformations.
├── typer // Type-checking and other frontend phases
└── util // General purpose utility classes and modules.
Contexts
dotc
has almost no global state (the only significant bit of global state is
the name table, which is used to hash strings into unique names). Instead, all
essential bits of information that can vary over a compiler run are collected
in a Context. Most methods in dotc
take a Context
value as an implicit
parameter.
Contexts give a convenient way to customize values in some part of the
call-graph. To run, e.g. some compiler function f
at a given phase phase
,
we invoke f
with an explicit context parameter, like this
f(/*normal args*/)(ctx.withPhase(phase))
This assumes that f
is defined in the way most compiler functions are:
def f(/*normal parameters*/)(implicit ctx: Context) ...
Compiler code follows the convention that all implicit Context
parameters are
named ctx
. This is important to avoid implicit ambiguities in the case where
nested methods contain each a Context parameters. The common name ensures then
that the implicit parameters properly shadow each other.
Sometimes we want to make sure that implicit contexts are not captured in
closures or other long-lived objects, be it because we want to enforce that
nested methods each get their own implicit context, or because we want to avoid
a space leak in the case where a closure can survive several compiler runs. A
typical case is a completer for a symbol representing an external class, which
produces the attributes of the symbol on demand, and which might never be
invoked. In that case we follow the convention that any context parameter is
explicit, not implicit, so we can track where it is used, and that it has a
name different from ctx
. Commonly used is ictx
for "initialization
context".
With these two conventions in place, it has turned out that implicit contexts work amazingly well as a device for dependency injection and bulk parameterization. There is of course always the danger that an unexpected implicit will be passed, but in practice this has not turned out to be much of a problem.
Compiler Phases
Seen from a temporal perspective, the dotc
compiler consists of a list of
phases. The current list of phases is specified in class Compiler as follows:
def phases: List[List[Phase]] = List(
List(new FrontEnd), // Compiler frontend: scanner, parser, namer, typer
List(new sbt.ExtractDependencies), // Sends information on classes' dependencies to sbt via callbacks
List(new PostTyper), // Additional checks and cleanups after type checking
List(new sbt.ExtractAPI), // Sends a representation of the API of classes to sbt via callbacks
List(new Pickler), // Generate TASTY info
List(new FirstTransform, // Some transformations to put trees into a canonical form
new CheckReentrant), // Internal use only: Check that compiled program has no data races involving global vars
List(new RefChecks, // Various checks mostly related to abstract members and overriding
new CheckStatic, // Check restrictions that apply to @static members
new ElimRepeated, // Rewrite vararg parameters and arguments
new NormalizeFlags, // Rewrite some definition flags
new ExtensionMethods, // Expand methods of value classes with extension methods
new ExpandSAMs, // Expand single abstract method closures to anonymous classes
new TailRec, // Rewrite tail recursion to loops
new LiftTry, // Put try expressions that might execute on non-empty stacks into their own methods
new ClassOf), // Expand `Predef.classOf` calls.
List(new TryCatchPatterns, // Compile cases in try/catch
new PatternMatcher, // Compile pattern matches
new ExplicitOuter, // Add accessors to outer classes from nested ones.
new ExplicitSelf, // Make references to non-trivial self types explicit as casts
new ShortcutImplicits, // Allow implicit functions without creating closures
new CrossCastAnd, // Normalize selections involving intersection types.
new Splitter), // Expand selections involving union types into conditionals
List(new VCInlineMethods, // Inlines calls to value class methods
new IsInstanceOfEvaluator, // Issues warnings when unreachable statements are present in match/if expressions
new SeqLiterals, // Express vararg arguments as arrays
new InterceptedMethods, // Special handling of `==`, `|=`, `getClass` methods
new Getters, // Replace non-private vals and vars with getter defs (fields are added later)
new ElimByName, // Expand by-name parameters and arguments
new AugmentScala2Traits, // Expand traits defined in Scala 2.11 to simulate old-style rewritings
new ResolveSuper, // Implement super accessors and add forwarders to trait methods
new ArrayConstructors), // Intercept creation of (non-generic) arrays and intrinsify.
List(new Erasure), // Rewrite types to JVM model, erasing all type parameters, abstract types and refinements.
List(new ElimErasedValueType, // Expand erased value types to their underlying implementation types
new VCElideAllocations, // Peep-hole optimization to eliminate unnecessary value class allocations
new Mixin, // Expand trait fields and trait initializers
new LazyVals, // Expand lazy vals
new Memoize, // Add private fields to getters and setters
new LinkScala2ImplClasses, // Forward calls to the implementation classes of traits defined by Scala 2.11
new NonLocalReturns, // Expand non-local returns
new CapturedVars, // Represent vars captured by closures as heap objects
new Constructors, // Collect initialization code in primary constructors
// Note: constructors changes decls in transformTemplate, no InfoTransformers should be added after it
new FunctionalInterfaces,// Rewrites closures to implement @specialized types of Functions.
new GetClass), // Rewrites getClass calls on primitive types.
List(new LambdaLift, // Lifts out nested functions to class scope, storing free variables in environments
// Note: in this mini-phase block scopes are incorrect. No phases that rely on scopes should be here
new ElimStaticThis, // Replace `this` references to static objects by global identifiers
new Flatten, // Lift all inner classes to package scope
new RestoreScopes), // Repair scopes rendered invalid by moving definitions in prior phases of the group
List(new ExpandPrivate, // Widen private definitions accessed from nested classes
new SelectStatic, // get rid of selects that would be compiled into GetStatic
new CollectEntryPoints, // Find classes with main methods
new CollectSuperCalls, // Find classes that are called with super
new DropInlined, // Drop Inlined nodes, since backend has no use for them
new MoveStatics, // Move static methods to companion classes
new LabelDefs), // Converts calls to labels to jumps
List(new GenBCode) // Generate JVM bytecode
)
Note that phases are grouped, so the phases
method is of type
List[List[Phase]]
. The idea is that all phases in a group are fused into a
single tree traversal. That way, phases can be kept small (most phases perform
a single function) without requiring an excessive number of tree traversals
(which are costly, because they have generally bad cache locality).
Phases fall into four categories:
-
Frontend phases:
Frontend
,PostTyper
andPickler
.FrontEnd
parses the source programs and generates untyped abstract syntax trees, which are then typechecked and transformed into typed abstract syntax trees.PostTyper
performs checks and cleanups that require a fully typed program. In particular, it- creates super accessors representing
super
calls in traits - creates implementations of synthetic (compiler-implemented) methods
- avoids storing parameters passed unchanged from subclass to superclass in duplicate fields.
Finally
Pickler
serializes the typed syntax trees produced by the frontend as TASTY data structures. - creates super accessors representing
-
High-level transformations: All phases from
FirstTransform
toErasure
. Most of these phases transform syntax trees, expanding high-level constructs to more primitive ones. The last phase in the group,Erasure
translates all types into types supported directly by the JVM. To do this, it performs another type checking pass, but using the rules of the JVM's type system instead of Scala's. -
Low-level transformations: All phases from
ElimErasedValueType
toLabelDefs
. These further transform trees until they are essentially a structured version of Java bytecode. - Code generators: These map the transformed trees to Java classfiles or Javascript files.