/* NSC -- new Scala compiler
* Copyright 2005-2011 LAMP/EPFL
* @author Martin Odersky
*/
package scala.tools.nsc
package interpreter
import Predef.{ println => _, _ }
import java.io.{ PrintWriter }
import java.lang.reflect
import java.net.URL
import util.{ Set => _, _ }
import io.VirtualDirectory
import reporters.{ ConsoleReporter, Reporter }
import symtab.{ Flags, Names }
import scala.tools.nsc.interpreter.{ Results => IR }
import scala.tools.util.PathResolver
import scala.tools.nsc.util.{ ScalaClassLoader, Exceptional }
import ScalaClassLoader.URLClassLoader
import Exceptional.unwrap
import scala.collection.{ mutable, immutable }
import scala.PartialFunction.{ cond, condOpt }
import scala.util.control.Exception.{ ultimately }
import scala.reflect.NameTransformer
import IMain._
/** <p>
* An interpreter for Scala code.
* </p>
* <p>
* The main public entry points are <code>compile()</code>,
* <code>interpret()</code>, and <code>bind()</code>.
* The <code>compile()</code> method loads a
* complete Scala file. The <code>interpret()</code> method executes one
* line of Scala code at the request of the user. The <code>bind()</code>
* method binds an object to a variable that can then be used by later
* interpreted code.
* </p>
* <p>
* The overall approach is based on compiling the requested code and then
* using a Java classloader and Java reflection to run the code
* and access its results.
* </p>
* <p>
* In more detail, a single compiler instance is used
* to accumulate all successfully compiled or interpreted Scala code. To
* "interpret" a line of code, the compiler generates a fresh object that
* includes the line of code and which has public member(s) to export
* all variables defined by that code. To extract the result of an
* interpreted line to show the user, a second "result object" is created
* which imports the variables exported by the above object and then
* exports a single member named "scala_repl_result". To accomodate user expressions
* that read from variables or methods defined in previous statements, "import"
* statements are used.
* </p>
* <p>
* This interpreter shares the strengths and weaknesses of using the
* full compiler-to-Java. The main strength is that interpreted code
* behaves exactly as does compiled code, including running at full speed.
* The main weakness is that redefining classes and methods is not handled
* properly, because rebinding at the Java level is technically difficult.
* </p>
*
* @author Moez A. Abdel-Gawad
* @author Lex Spoon
*/
class IMain(val settings: Settings, protected val out: PrintWriter) {
intp =>
/** construct an interpreter that reports to Console */
def this(settings: Settings) = this(settings, new NewLinePrintWriter(new ConsoleWriter, true))
def this() = this(new Settings())
/** whether to print out result lines */
private[nsc] var printResults: Boolean = true
/** whether to print errors */
private[nsc] var totalSilence: Boolean = false
private val RESULT_OBJECT_PREFIX = "RequestResult$"
lazy val formatting: Formatting = new Formatting {
val prompt = Properties.shellPromptString
}
import formatting._
/** directory to save .class files to */
val virtualDirectory = new VirtualDirectory("(memory)", None)
/** reporter */
lazy val reporter: ConsoleReporter = new IMain.ReplReporter(this)
import reporter.{ printMessage, withoutTruncating }
// not sure if we have some motivation to print directly to console
private def echo(msg: String) { Console println msg }
/** We're going to go to some trouble to initialize the compiler asynchronously.
* It's critical that nothing call into it until it's been initialized or we will
* run into unrecoverable issues, but the perceived repl startup time goes
* through the roof if we wait for it. So we initialize it with a future and
* use a lazy val to ensure that any attempt to use the compiler object waits
* on the future.
*/
private val _compiler: Global = newCompiler(settings, reporter)
private def _initialize(): Boolean = {
val source = """
|// this is assembled to force the loading of approximately the
|// classes which will be loaded on the first expression anyway.
|class $repl_$init {
| val x = "abc".reverse.length + (5 max 5)
| scala.runtime.ScalaRunTime.stringOf(x)
|}
|""".stripMargin
try {
new _compiler.Run() compileSources List(new BatchSourceFile("<init>", source))
if (isReplDebug || settings.debug.value) {
// Can't use printMessage here, it deadlocks
Console.println("Repl compiler initialized.")
}
true
}
catch {
case x: AbstractMethodError =>
printMessage("""
|Failed to initialize compiler: abstract method error.
|This is most often remedied by a full clean and recompile.
|""".stripMargin
)
x.printStackTrace()
false
case x: MissingRequirementError => printMessage("""
|Failed to initialize compiler: %s not found.
|** Note that as of 2.8 scala does not assume use of the java classpath.
|** For the old behavior pass -usejavacp to scala, or if using a Settings
|** object programatically, settings.usejavacp.value = true.""".stripMargin.format(x.req)
)
false
}
}
// set up initialization future
private var _isInitialized: () => Boolean = null
def initialize() = synchronized {
if (_isInitialized == null)
_isInitialized = scala.concurrent.ops future _initialize()
}
/** the public, go through the future compiler */
lazy val global: Global = {
initialize()
// blocks until it is ; false means catastrophic failure
if (_isInitialized()) _compiler
else null
}
@deprecated("Use `global` for access to the compiler instance.")
lazy val compiler = global
import global._
import definitions.{ EmptyPackage, getMember }
import nme.{ INTERPRETER_IMPORT_WRAPPER, INTERPRETER_WRAPPER_SUFFIX }
object naming extends {
val global: intp.global.type = intp.global
} with Naming {
// make sure we don't overwrite their unwisely named res3 etc.
override def freshUserVarName(): String = {
val name = super.freshUserVarName()
if (definedNameMap contains name) freshUserVarName()
else name
}
}
import naming._
lazy val memberHandlers = new {
val intp: IMain.this.type = IMain.this
} with MemberHandlers
import memberHandlers._
/** Temporarily be quiet */
def beQuietDuring[T](operation: => T): T = {
val wasPrinting = printResults
ultimately(printResults = wasPrinting) {
printResults = false
operation
}
}
def beSilentDuring[T](operation: => T): T = {
val saved = totalSilence
totalSilence = true
try operation
finally totalSilence = saved
}
def quietRun[T](code: String) = beQuietDuring(interpret(code))
/** whether to bind the lastException variable */
private var bindLastException = true
/** A string representing code to be wrapped around all lines. */
private var _executionWrapper: String = ""
def executionWrapper = _executionWrapper
def setExecutionWrapper(code: String) = _executionWrapper = code
def clearExecutionWrapper() = _executionWrapper = ""
/** Temporarily stop binding lastException */
def withoutBindingLastException[T](operation: => T): T = {
val wasBinding = bindLastException
ultimately(bindLastException = wasBinding) {
bindLastException = false
operation
}
}
protected def createLineManager(): Line.Manager = new Line.Manager
lazy val lineManager = createLineManager()
/** interpreter settings */
lazy val isettings = new ISettings(this)
/** Instantiate a compiler. Subclasses can override this to
* change the compiler class used by this interpreter. */
protected def newCompiler(settings: Settings, reporter: Reporter) = {
settings.outputDirs setSingleOutput virtualDirectory
new Global(settings, reporter)
}
/** the compiler's classpath, as URL's */
lazy val compilerClasspath: List[URL] = new PathResolver(settings) asURLs
/* A single class loader is used for all commands interpreted by this Interpreter.
It would also be possible to create a new class loader for each command
to interpret. The advantages of the current approach are:
- Expressions are only evaluated one time. This is especially
significant for I/O, e.g. "val x = Console.readLine"
The main disadvantage is:
- Objects, classes, and methods cannot be rebound. Instead, definitions
shadow the old ones, and old code objects refer to the old
definitions.
*/
private var _classLoader: AbstractFileClassLoader = null
def resetClassLoader() = _classLoader = makeClassLoader()
def classLoader: AbstractFileClassLoader = {
if (_classLoader == null)
resetClassLoader()
_classLoader
}
private def makeClassLoader(): AbstractFileClassLoader = {
val parent =
if (parentClassLoader == null) ScalaClassLoader fromURLs compilerClasspath
else new URLClassLoader(compilerClasspath, parentClassLoader)
new AbstractFileClassLoader(virtualDirectory, parent)
}
private def loadByName(s: String): Class[_] = (classLoader tryToInitializeClass s).get
private def methodByName(c: Class[_], name: String): reflect.Method =
c.getMethod(name, classOf[Object])
protected def parentClassLoader: ClassLoader =
settings.explicitParentLoader.getOrElse( this.getClass.getClassLoader() )
def getInterpreterClassLoader() = classLoader
// Set the current Java "context" class loader to this interpreter's class loader
def setContextClassLoader() = classLoader.setAsContext()
/** the previous requests this interpreter has processed */
private lazy val prevRequests = mutable.ArrayBuffer[Request]()
private lazy val referencedNameMap = mutable.Map[Name, Request]()
private lazy val definedNameMap: mutable.Map[Name, Request] = mutable.Map[Name, Request]()
private def allHandlers = prevRequests.toList flatMap (_.handlers)
private def allReqAndHandlers = prevRequests.toList flatMap (req => req.handlers map (req -> _))
private def importHandlers = allHandlers collect { case x: ImportHandler => x }
def allDefinedNames = definedNameMap.keys.toList sortBy (_.toString)
def pathToType(id: String): String = pathToName(newTypeName(id))
def pathToTerm(id: String): String = pathToName(newTermName(id))
def pathToName(name: Name): String = {
if (definedNameMap contains name)
definedNameMap(name) fullPath name
else name.toString
}
/** Most recent tree handled which wasn't wholly synthetic. */
private def mostRecentlyHandledTree: Option[Tree] = {
prevRequests.reverse foreach { req =>
req.handlers.reverse foreach {
case x: MemberDefHandler if x.definesValue && !isInternalVarName(x.name) => return Some(x.member)
case _ => ()
}
}
None
}
/** Stubs for work in progress. */
def handleTypeRedefinition(name: TypeName, old: Request, req: Request) = {
for (t1 <- old.simpleNameOfType(name) ; t2 <- req.simpleNameOfType(name)) {
DBG("Redefining type '%s'\n %s -> %s".format(name, t1, t2))
}
}
def handleTermRedefinition(name: TermName, old: Request, req: Request) = {
for (t1 <- old.compilerTypeOf get name ; t2 <- req.compilerTypeOf get name) {
// Printing the types here has a tendency to cause assertion errors, like
// assertion failed: fatal: <refinement> has owner value x, but a class owner is required
// so DBG is by-name now to keep it in the family. (It also traps the assertion error,
// but we don't want to unnecessarily risk hosing the compiler's internal state.)
DBG("Redefining term '%s'\n %s -> %s".format(name, t1, t2))
}
}
def recordRequest(req: Request) {
if (req == null || referencedNameMap == null) {
DBG("Received null value at recordRequest.")
return
}
def tripart[T](set1: Set[T], set2: Set[T]) = {
val intersect = set1 intersect set2
List(set1 -- intersect, intersect, set2 -- intersect)
}
prevRequests += req
req.referencedNames foreach (x => referencedNameMap(x) = req)
req.definedNames foreach { name =>
if (definedNameMap contains name) {
if (name.isTypeName) handleTypeRedefinition(name.toTypeName, definedNameMap(name), req)
else handleTermRedefinition(name.toTermName, definedNameMap(name), req)
}
definedNameMap(name) = req
}
// XXX temporarily putting this here because of tricky initialization order issues
// so right now it's not bound until after you issue a command.
if (prevRequests.size == 1)
quietBind("settings", isettings)
}
def allSeenTypes = prevRequests.toList flatMap (_.typeOf.values.toList) distinct
def allDefinedTypes = prevRequests.toList flatMap (_.definedTypes.values.toList) distinct
def allImplicits = allHandlers filter (_.definesImplicit) flatMap (_.definedNames)
/** Compute imports that allow definitions from previous
* requests to be visible in a new request. Returns
* three pieces of related code:
*
* 1. An initial code fragment that should go before
* the code of the new request.
*
* 2. A code fragment that should go after the code
* of the new request.
*
* 3. An access path which can be traverested to access
* any bindings inside code wrapped by #1 and #2 .
*
* The argument is a set of Names that need to be imported.
*
* Limitations: This method is not as precise as it could be.
* (1) It does not process wildcard imports to see what exactly
* they import.
* (2) If it imports any names from a request, it imports all
* of them, which is not really necessary.
* (3) It imports multiple same-named implicits, but only the
* last one imported is actually usable.
*/
private case class ComputedImports(prepend: String, append: String, access: String)
private def importsCode(wanted: Set[Name]): ComputedImports = {
/** Narrow down the list of requests from which imports
* should be taken. Removes requests which cannot contribute
* useful imports for the specified set of wanted names.
*/
case class ReqAndHandler(req: Request, handler: MemberHandler) { }
def reqsToUse: List[ReqAndHandler] = {
/** Loop through a list of MemberHandlers and select which ones to keep.
* 'wanted' is the set of names that need to be imported.
*/
def select(reqs: List[ReqAndHandler], wanted: Set[Name]): List[ReqAndHandler] = {
val isWanted = wanted contains _
// Single symbol imports might be implicits! See bug #1752. Rather than
// try to finesse this, we will mimic all imports for now.
def keepHandler(handler: MemberHandler) = handler match {
case _: ImportHandler => true
case x => x.definesImplicit || (x.definedNames exists isWanted)
}
reqs match {
case Nil => Nil
case rh :: rest if !keepHandler(rh.handler) => select(rest, wanted)
case rh :: rest =>
import rh.handler._
val newWanted = wanted ++ referencedNames -- definedNames -- importedNames
rh :: select(rest, newWanted)
}
}
/** Flatten the handlers out and pair each with the original request */
select(allReqAndHandlers reverseMap { case (r, h) => ReqAndHandler(r, h) }, wanted).reverse
}
val code, trailingBraces, accessPath = new StringBuilder
val currentImps = mutable.HashSet[Name]()
// add code for a new object to hold some imports
def addWrapper() {
val impname = INTERPRETER_IMPORT_WRAPPER
code append "object %s {\n".format(impname)
trailingBraces append "}\n"
accessPath append ("." + impname)
currentImps.clear
}
addWrapper()
// loop through previous requests, adding imports for each one
for (ReqAndHandler(req, handler) <- reqsToUse) {
handler match {
// If the user entered an import, then just use it; add an import wrapping
// level if the import might conflict with some other import
case x: ImportHandler =>
if (x.importsWildcard || (currentImps exists (x.importedNames contains _)))
addWrapper()
code append (x.member + "\n")
// give wildcard imports a import wrapper all to their own
if (x.importsWildcard) addWrapper()
else currentImps ++= x.importedNames
// For other requests, import each defined name.
// import them explicitly instead of with _, so that
// ambiguity errors will not be generated. Also, quote
// the name of the variable, so that we don't need to
// handle quoting keywords separately.
case x =>
for (imv <- x.definedNames) {
if (currentImps contains imv) addWrapper()
code append ("import %s\n" format (req fullPath imv))
currentImps += imv
}
}
}
// add one extra wrapper, to prevent warnings in the common case of
// redefining the value bound in the last interpreter request.
addWrapper()
ComputedImports(code.toString, trailingBraces.toString, accessPath.toString)
}
/** Parse a line into a sequence of trees. Returns None if the input is incomplete. */
def parse(line: String): Option[List[Tree]] = {
var justNeedsMore = false
reporter.withIncompleteHandler((pos,msg) => {justNeedsMore = true}) {
// simple parse: just parse it, nothing else
def simpleParse(code: String): List[Tree] = {
reporter.reset
val unit = new CompilationUnit(new BatchSourceFile("<console>", code))
val scanner = new syntaxAnalyzer.UnitParser(unit)
scanner.templateStatSeq(false)._2
}
val trees = simpleParse(line)
if (reporter.hasErrors) Some(Nil) // the result did not parse, so stop
else if (justNeedsMore) None
else Some(trees)
}
}
def isParseable(line: String): Boolean = {
beSilentDuring {
parse(line) match {
case Some(xs) => xs.nonEmpty // parses as-is
case None => true // incomplete
}
}
}
/** Compile an nsc SourceFile. Returns true if there are
* no compilation errors, or false otherwise.
*/
def compileSources(sources: SourceFile*): Boolean = {
reporter.reset
new Run() compileSources sources.toList
!reporter.hasErrors
}
/** Compile a string. Returns true if there are no
* compilation errors, or false otherwise.
*/
def compileString(code: String): Boolean =
compileSources(new BatchSourceFile("<script>", code))
def compileAndSaveRun(label: String, code: String) = {
/** Secret bookcase entrance for repl debuggers: end the line
* with "// show" and see what's going on.
*/
if (code.lines exists (_.trim endsWith "// show")) {
echo(code)
parse(code) match {
case Some(trees) => trees foreach (t => DBG(asCompactString(t)))
case _ => DBG("Parse error:\n\n" + code)
}
}
val run = new Run()
run.compileSources(List(new BatchSourceFile(label, code)))
run
}
/** Build a request from the user. <code>trees</code> is <code>line</code>
* after being parsed.
*/
private def buildRequest(line: String, lineName: String, trees: List[Tree]): Request =
new Request(line, lineName, trees)
private def requestFromLine(line: String, synthetic: Boolean): Either[IR.Result, Request] = {
val trees = parse(indentCode(line)) match {
case None => return Left(IR.Incomplete)
case Some(Nil) => return Left(IR.Error) // parse error or empty input
case Some(trees) => trees
}
// use synthetic vars to avoid filling up the resXX slots
def varName = if (synthetic) freshInternalVarName() else freshUserVarName()
// Treat a single bare expression specially. This is necessary due to it being hard to
// modify code at a textual level, and it being hard to submit an AST to the compiler.
if (trees.size == 1) trees.head match {
case _:Assign => // we don't want to include assignments
case _:TermTree | _:Ident | _:Select => // ... but do want these as valdefs.
requestFromLine("val %s =\n%s".format(varName, line), synthetic) match {
case Right(req) => return Right(req withOriginalLine line)
case x => return x
}
case _ =>
}
// figure out what kind of request
Right(buildRequest(line, freshLineName(), trees))
}
/** <p>
* Interpret one line of input. All feedback, including parse errors
* and evaluation results, are printed via the supplied compiler's
* reporter. Values defined are available for future interpreted
* strings.
* </p>
* <p>
* The return value is whether the line was interpreter successfully,
* e.g. that there were no parse errors.
* </p>
*
* @param line ...
* @return ...
*/
def interpret(line: String): IR.Result = interpret(line, false)
def interpret(line: String, synthetic: Boolean): IR.Result = {
def loadAndRunReq(req: Request) = {
val (result, succeeded) = req.loadAndRun
/** To our displeasure, ConsoleReporter offers only printMessage,
* which tacks a newline on the end. Since that breaks all the
* output checking, we have to take one off to balance.
*/
def show() = {
if (result == "") ()
else printMessage(result stripSuffix "\n")
}
if (succeeded) {
if (printResults)
show()
if (!synthetic) // book-keeping
recordRequest(req)
IR.Success
}
else {
// don't truncate stack traces
withoutTruncating(show())
IR.Error
}
}
if (global == null) IR.Error
else requestFromLine(line, synthetic) match {
case Left(result) => result
case Right(req) =>
// null indicates a disallowed statement type; otherwise compile and
// fail if false (implying e.g. a type error)
if (req == null || !req.compile) IR.Error
else loadAndRunReq(req)
}
}
/** A name creator used for objects created by <code>bind()</code>. */
private lazy val newBinder = new naming.NameCreator("binder")
/** Bind a specified name to a specified value. The name may
* later be used by expressions passed to interpret.
*
* @param name the variable name to bind
* @param boundType the type of the variable, as a string
* @param value the object value to bind to it
* @return an indication of whether the binding succeeded
*/
def bind(name: String, boundType: String, value: Any): IR.Result = {
val binderName = newBinder()
compileString("""
|object %s {
| var value: %s = _
| def set(x: Any) = value = x.asInstanceOf[%s]
|}
""".stripMargin.format(binderName, boundType, boundType))
val binderObject = loadByName(binderName)
val setterMethod = methodByName(binderObject, "set")
setterMethod.invoke(null, value.asInstanceOf[AnyRef])
interpret("val %s = %s.value".format(name, binderName))
}
def quietBind(p: NamedParam): IR.Result = beQuietDuring(bind(p))
def bind(p: NamedParam): IR.Result = bind(p.name, p.tpe, p.value)
def bind[T: Manifest](name: String, value: T): IR.Result = bind((name, value))
def bindValue(x: Any): IR.Result = bind(freshUserVarName(), TypeStrings.fromValue(x), x)
/** Reset this interpreter, forgetting all user-specified requests. */
def reset() {
virtualDirectory.clear()
resetClassLoader()
resetAllCreators()
prevRequests.clear
}
/** This instance is no longer needed, so release any resources
* it is using. The reporter's output gets flushed.
*/
def close() {
reporter.flush
}
/** One line of code submitted by the user for interpretation */
// private
class Request(val line: String, val lineName: String, val trees: List[Tree]) {
private var _originalLine: String = null
def withOriginalLine(s: String): this.type = { _originalLine = s ; this }
def originalLine = if (_originalLine == null) line else _originalLine
/** name to use for the object that will compute "line" */
def objectName = lineName + INTERPRETER_WRAPPER_SUFFIX
/** name of the object that retrieves the result from the above object */
def resultObjectName = RESULT_OBJECT_PREFIX + objectName
/** handlers for each tree in this request */
val handlers: List[MemberHandler] = trees map (memberHandlers chooseHandler _)
/** all (public) names defined by these statements */
val definedNames = handlers flatMap (_.definedNames)
/** list of names used by this expression */
val referencedNames: List[Name] = handlers flatMap (_.referencedNames)
/** def and val names */
def termNames = handlers flatMap (_.definesTerm)
def typeNames = handlers flatMap (_.definesType)
/** Code to import bound names from previous lines - accessPath is code to
* append to objectName to access anything bound by request.
*/
val ComputedImports(importsPreamble, importsTrailer, accessPath) =
importsCode(Set.empty ++ referencedNames)
/** Code to access a variable with the specified name */
def fullPath(vname: String): String = "%s.`%s`".format(objectName + accessPath, vname)
/** Code to access a variable with the specified name */
def fullPath(vname: Name): String = fullPath(vname.toString)
/** the line of code to compute */
def toCompute = line
/** generate the source code for the object that computes this request */
private object ObjectSourceCode extends CodeAssembler[MemberHandler] {
val preamble = """
|object %s {
| %s%s
""".stripMargin.format(objectName, importsPreamble, indentCode(toCompute))
val postamble = importsTrailer + "\n}"
val generate = (m: MemberHandler) => m extraCodeToEvaluate Request.this
}
private object ResultObjectSourceCode extends CodeAssembler[MemberHandler] {
/** We only want to generate this code when the result
* is a value which can be referred to as-is.
*/
val valueExtractor =
if (!handlers.last.definesValue) ""
else handlers.last.definesTerm match {
case Some(vname) if typeOf contains vname =>
"""
|lazy val scala_repl_value = {
| scala_repl_result
| %s
|}""".stripMargin.format(fullPath(vname))
case _ => ""
}
// first line evaluates object to make sure constructor is run
// initial "" so later code can uniformly be: + etc
val preamble = """
|object %s {
| %s
| val scala_repl_result: String = %s {
| %s
| (""
""".stripMargin.format(resultObjectName, valueExtractor, executionWrapper, objectName + accessPath)
val postamble = """
| )
| }
|}
""".stripMargin
val generate = (m: MemberHandler) => m resultExtractionCode Request.this
}
// Generate the object which runs the line of code.
def objectSourceCode: String = ObjectSourceCode(handlers)
// Generate the object which retrieves the result from the objectSourceCode object.
def resultObjectSourceCode: String = ResultObjectSourceCode(handlers)
// compile the object containing the user's code
lazy val objRun = compileAndSaveRun("<console>", objectSourceCode)
// compile the result-extraction object
lazy val extractionObjectRun = compileAndSaveRun("<console>", resultObjectSourceCode)
lazy val loadedResultObject = loadByName(resultObjectName)
def extractionValue(): Option[AnyRef] = {
// ensure it has run
extractionObjectRun
// load it and retrieve the value
try Some(loadedResultObject getMethod "scala_repl_value" invoke loadedResultObject)
catch { case _: Exception => None }
}
/** Compile the object file. Returns whether the compilation succeeded.
* If all goes well, the "types" map is computed. */
def compile(): Boolean = {
// error counting is wrong, hence interpreter may overlook failure - so we reset
reporter.reset
// compile the main object
objRun
// bail on error
if (reporter.hasErrors)
return false
// extract and remember types
typeOf
definedTypes
// compile the result-extraction object
extractionObjectRun
// success
!reporter.hasErrors
}
def afterTyper[T](op: => T): T = atPhase(objRun.typerPhase.next)(op)
/** The outermost wrapper object */
lazy val outerResObjSym: Symbol = getMember(EmptyPackage, newTermName(objectName))
/** The innermost object inside the wrapper, found by
* following accessPath into the outer one. */
lazy val resObjSym =
accessPath.split("\\.").foldLeft(outerResObjSym) { (sym, name) =>
if (name == "") sym else
afterTyper(sym.info member newTermName(name))
}
/* typeOf lookup with encoding */
def lookupTypeOf(name: Name) = typeOf.getOrElse(name, typeOf(global.encode(name.toString)))
def simpleNameOfType(name: TypeName) = (compilerTypeOf get name) map (_.typeSymbol.simpleName)
private def typeMap[T](f: Type => T): Map[Name, T] = {
def toType(name: Name): T = {
// the types are all =>T; remove the =>
val tp1 = afterTyper(resObjSym.info.nonPrivateDecl(name).tpe match {
case NullaryMethodType(tp) => tp
case tp => tp
})
// normalize non-public types so we don't see protected aliases like Self
afterTyper(tp1 match {
case TypeRef(_, sym, _) if !sym.isPublic => f(tp1.normalize)
case tp => f(tp)
})
}
termNames ++ typeNames map (x => x -> toType(x)) toMap
}
/** Types of variables defined by this request. */
lazy val compilerTypeOf = typeMap[Type](x => x)
/** String representations of same. */
lazy val typeOf = typeMap[String](_.toString)
lazy val definedTypes: Map[Name, Type] = {
typeNames map (x => x -> afterTyper(resObjSym.info.nonPrivateDecl(x).tpe)) toMap
}
private def bindExceptionally(t: Throwable) = {
val ex: Exceptional =
if (isettings.showInternalStackTraces) Exceptional(t)
else new Exceptional(t) {
override def spanFn(frame: JavaStackFrame) = !(frame.className startsWith resultObjectName)
override def contextPrelude = super.contextPrelude + "/* The repl internal portion of the stack trace is elided. */\n"
}
quietBind("lastException", ex)
ex.contextHead + "\n(access lastException for the full trace)"
}
private def bindUnexceptionally(t: Throwable) = {
quietBind("lastException", t)
stackTraceString(t)
}
/** load and run the code using reflection */
def loadAndRun: (String, Boolean) = {
import interpreter.Line._
def handleException(t: Throwable) = {
/** We turn off the binding to accomodate ticket #2817 */
withoutBindingLastException {
val message =
if (opt.richExes) bindExceptionally(unwrap(t))
else bindUnexceptionally(unwrap(t))
(message, false)
}
}
try {
val resultValMethod = loadedResultObject getMethod "scala_repl_result"
val execution = lineManager.set(originalLine)(resultValMethod invoke loadedResultObject)
execution.await()
execution.state match {
case Done => ("" + execution.get(), true)
case Threw => if (bindLastException) handleException(execution.caught()) else throw execution.caught()
case Cancelled => ("Execution interrupted by signal.\n", false)
case Running => ("Execution still running! Seems impossible.", false)
}
}
finally lineManager.clear()
}
override def toString = "Request(line=%s, %s trees)".format(line, trees.size)
}
/** Returns the name of the most recent interpreter result.
* Mostly this exists so you can conveniently invoke methods on
* the previous result.
*/
def mostRecentVar: String =
if (mostRecentlyHandledTree.isEmpty) ""
else "" + (mostRecentlyHandledTree.get match {
case x: ValOrDefDef => x.name
case Assign(Ident(name), _) => name
case ModuleDef(_, name, _) => name
case _ => naming.mostRecentVar
})
private def requestForName(name: Name): Option[Request] =
prevRequests.reverse find (_.definedNames contains name)
private def requestForIdent(line: String): Option[Request] = requestForName(newTermName(line))
// XXX literals.
def stringToCompilerType(id: String): Type = {
// if it's a recognized identifier, the type of that; otherwise treat the
// String like a value (e.g. scala.collection.Map) .
def findType = typeForIdent(id) match {
case Some(x) => definitions.getClass(newTermName(x)).tpe
case _ => definitions.getModule(newTermName(id)).tpe
}
try findType catch { case _: MissingRequirementError => NoType }
}
def typeForIdent(id: String): Option[String] =
requestForIdent(id) flatMap (x => x.typeOf get newTermName(id))
def methodsOf(name: String) =
evalExpr[List[String]](methodsCode(name)) map (x => NameTransformer.decode(getOriginalName(x)))
def completionAware(name: String) = {
// XXX working around "object is not a value" crash, i.e.
// import java.util.ArrayList ; ArrayList.<tab>
clazzForIdent(name) flatMap (_ => evalExpr[Option[CompletionAware]](asCompletionAwareCode(name)))
}
def extractionValueForIdent(id: String): Option[AnyRef] =
requestForIdent(id) flatMap (_.extractionValue)
/** Executes code looking for a manifest of type T.
*/
def manifestFor[T: Manifest] =
evalExpr[Manifest[T]]("""manifest[%s]""".format(manifest[T]))
/** Executes code looking for an implicit value of type T.
*/
def implicitFor[T: Manifest] = {
val s = manifest[T].toString
evalExpr[Option[T]]("{ def f(implicit x: %s = null): %s = x ; Option(f) }".format(s, s))
// We don't use implicitly so as to fail without failing.
// evalExpr[T]("""implicitly[%s]""".format(manifest[T]))
}
def clazzForIdent(id: String): Option[Class[_]] =
extractionValueForIdent(id) flatMap (x => Option(x) map (_.getClass))
private def methodsCode(name: String) =
"%s.%s(%s)".format(classOf[ReflectionCompletion].getName, "methodsOf", name)
private def asCompletionAwareCode(name: String) =
"%s.%s(%s)".format(classOf[CompletionAware].getName, "unapply", name)
private def getOriginalName(name: String): String =
nme.originalName(newTermName(name)).toString
case class InterpreterEvalException(msg: String) extends Exception(msg)
def evalError(msg: String) = throw InterpreterEvalException(msg)
/** The user-facing eval in :power mode wraps an Option.
*/
def eval[T: Manifest](line: String): Option[T] =
try Some(evalExpr[T](line))
catch { case InterpreterEvalException(msg) => out println indentCode(msg) ; None }
def evalExpr[T: Manifest](line: String): T = {
// Nothing means the type could not be inferred.
if (manifest[T] eq Manifest.Nothing)
evalError("Could not infer type: try 'eval[SomeType](%s)' instead".format(line))
val lhs = freshInternalVarName()
beQuietDuring { interpret("val " + lhs + " = { " + line + " } ") }
// TODO - can we meaningfully compare the inferred type T with
// the internal compiler Type assigned to lhs?
// def assignedType = prevRequests.last.typeOf(newTermName(lhs))
val req = requestFromLine(lhs, true) match {
case Left(result) => evalError(result.toString)
case Right(req) => req
}
if (req == null || !req.compile || req.handlers.size != 1)
evalError("Eval error.")
try req.extractionValue.get.asInstanceOf[T] catch {
case e: Exception => evalError(e.getMessage)
}
}
def interpretExpr[T: Manifest](code: String): Option[T] = beQuietDuring {
interpret(code) match {
case IR.Success =>
try prevRequests.last.extractionValue map (_.asInstanceOf[T])
catch { case e: Exception => out println e ; None }
case _ => None
}
}
/** Another entry point for tab-completion, ids in scope */
private def simpleTermNames =
allHandlers flatMap (_.definedOrImported) filter (x => x.isTermName && !isInternalVarName(x))
/** Types which have been wildcard imported, such as:
* val x = "abc" ; import x._ // type java.lang.String
* import java.lang.String._ // object java.lang.String
*
* Used by tab completion.
*
* XXX right now this gets import x._ and import java.lang.String._,
* but doesn't figure out import String._. There's a lot of ad hoc
* scope twiddling which should be swept away in favor of digging
* into the compiler scopes.
*/
def wildcardImportedTypes(): List[Type] = {
importHandlers flatMap {
case x if x.importsWildcard => x.targetType
case _ => None
} distinct
}
/** Another entry point for tab-completion, ids in scope */
def unqualifiedIds() = (simpleTermNames map (_.toString)).distinct.sorted
/** For static/object method completion */
def getClassObject(path: String): Option[Class[_]] = classLoader tryToLoadClass path
/** Parse the ScalaSig to find type aliases */
def aliasForType(path: String) = ByteCode.aliasForType(path)
// debugging
def isCompletionDebug = settings.Ycompletion.value
def DBG(s: => String) =
try if (isReplDebug) repldbg(s)
catch { case x: AssertionError => repldbg("Assertion error printing debug string:\n " + x) }
}
/** Utility methods for the Interpreter. */
object IMain {
trait CodeAssembler[T] {
def preamble: String
def generate: T => String
def postamble: String
def apply(contributors: List[T]): String = stringFromWriter { code =>
code println preamble
contributors map generate foreach (code print _)
code println postamble
}
}
class ReplReporter(intp: IMain) extends ConsoleReporter(intp.settings, null, intp.out) {
import intp._
/** Truncate a string if it is longer than isettings.maxPrintString */
private def truncPrintString(str: String): String = {
val maxpr = isettings.maxPrintString
val trailer = "..."
if (!truncationOK || maxpr <= 0 || str.length <= maxpr) str
else (str take maxpr-3) + trailer
}
/** Clean up a string for output */
private def clean(str: String) = truncPrintString(
if (isettings.unwrapStrings) stripWrapperGunk(str)
else str
)
override def printMessage(msg: String) {
if (totalSilence)
return
out println clean(msg)
out.flush()
}
}
import scala.collection.generic.CanBuildFrom
def partialFlatMap[A, B, CC[X] <: Traversable[X]]
(coll: CC[A])
(pf: PartialFunction[A, CC[B]])
(implicit bf: CanBuildFrom[CC[A], B, CC[B]]) =
{
val b = bf(coll)
for (x <- coll collect pf)
b ++= x
b.result
}
}