/*
 * Copyright (c) 2014, 2016, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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package jdk.jshell;

import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.List;
import java.util.Locale;
import java.util.regex.Matcher;
import java.util.regex.Pattern;
import java.util.stream.Collectors;
import javax.lang.model.element.Modifier;
import com.sun.source.tree.ArrayTypeTree;
import com.sun.source.tree.AssignmentTree;
import com.sun.source.tree.ClassTree;
import com.sun.source.tree.ExpressionTree;
import com.sun.source.tree.IdentifierTree;
import com.sun.source.tree.MethodTree;
import com.sun.source.tree.ModifiersTree;
import com.sun.source.tree.Tree;
import com.sun.source.tree.VariableTree;
import com.sun.tools.javac.tree.JCTree;
import com.sun.tools.javac.tree.Pretty;
import java.io.IOException;
import java.io.StringWriter;
import java.io.Writer;
import java.util.LinkedHashSet;
import java.util.Set;
import jdk.jshell.ExpressionToTypeInfo.ExpressionInfo;
import jdk.jshell.Key.ErroneousKey;
import jdk.jshell.Key.MethodKey;
import jdk.jshell.Key.TypeDeclKey;
import jdk.jshell.Snippet.Kind;
import jdk.jshell.Snippet.SubKind;
import jdk.jshell.TaskFactory.AnalyzeTask;
import jdk.jshell.TaskFactory.BaseTask;
import jdk.jshell.TaskFactory.CompileTask;
import jdk.jshell.TaskFactory.ParseTask;
import jdk.jshell.Wrap.Range;
import jdk.jshell.Snippet.Status;
import jdk.jshell.spi.ExecutionControl.ClassBytecodes;
import jdk.jshell.spi.ExecutionControl.ClassInstallException;
import jdk.jshell.spi.ExecutionControl.EngineTerminationException;
import jdk.jshell.spi.ExecutionControl.InternalException;
import jdk.jshell.spi.ExecutionControl.NotImplementedException;
import jdk.jshell.spi.ExecutionControl.ResolutionException;
import jdk.jshell.spi.ExecutionControl.RunException;
import jdk.jshell.spi.ExecutionControl.UserException;
import static java.util.stream.Collectors.toList;
import static java.util.stream.Collectors.toSet;
import static java.util.Collections.singletonList;
import static jdk.internal.jshell.debug.InternalDebugControl.DBG_GEN;
import static jdk.jshell.Util.DOIT_METHOD_NAME;
import static jdk.jshell.Util.PREFIX_PATTERN;
import static jdk.jshell.Util.expunge;
import static jdk.jshell.Snippet.SubKind.SINGLE_TYPE_IMPORT_SUBKIND;
import static jdk.jshell.Snippet.SubKind.SINGLE_STATIC_IMPORT_SUBKIND;
import static jdk.jshell.Snippet.SubKind.TYPE_IMPORT_ON_DEMAND_SUBKIND;
import static jdk.jshell.Snippet.SubKind.STATIC_IMPORT_ON_DEMAND_SUBKIND;

The Evaluation Engine. Source internal analysis, wrapping control, compilation, declaration. redefinition, replacement, and execution.
Author:Robert Field
/** * The Evaluation Engine. Source internal analysis, wrapping control, * compilation, declaration. redefinition, replacement, and execution. * * @author Robert Field */
class Eval { private static final Pattern IMPORT_PATTERN = Pattern.compile("import\\p{javaWhitespace}+(?<static>static\\p{javaWhitespace}+)?(?<fullname>[\\p{L}\\p{N}_\\$\\.]+\\.(?<name>[\\p{L}\\p{N}_\\$]+|\\*))"); private int varNumber = 0; private final JShell state; Eval(JShell state) { this.state = state; }
Evaluates a snippet of source.
Params:
  • userSource – the source of the snippet
Throws:
Returns:the list of primary and update events
/** * Evaluates a snippet of source. * * @param userSource the source of the snippet * @return the list of primary and update events * @throws IllegalStateException */
List<SnippetEvent> eval(String userSource) throws IllegalStateException { List<SnippetEvent> allEvents = new ArrayList<>(); for (Snippet snip : sourceToSnippets(userSource)) { if (snip.kind() == Kind.ERRONEOUS) { state.maps.installSnippet(snip); allEvents.add(new SnippetEvent( snip, Status.NONEXISTENT, Status.REJECTED, false, null, null, null)); } else { allEvents.addAll(declare(snip, snip.syntheticDiags())); } } return allEvents; }
Converts the user source of a snippet into a Snippet list -- Snippet will have wrappers.
Params:
  • userSource – the source of the snippet
Returns:usually a singleton list of Snippet, but may be empty or multiple
/** * Converts the user source of a snippet into a Snippet list -- Snippet will * have wrappers. * * @param userSource the source of the snippet * @return usually a singleton list of Snippet, but may be empty or multiple */
List<Snippet> sourceToSnippetsWithWrappers(String userSource) { List<Snippet> snippets = sourceToSnippets(userSource); for (Snippet snip : snippets) { if (snip.outerWrap() == null) { snip.setOuterWrap( (snip.kind() == Kind.IMPORT) ? state.outerMap.wrapImport(snip.guts(), snip) : state.outerMap.wrapInTrialClass(snip.guts()) ); } } return snippets; }
Converts the user source of a snippet into a Snippet object (or list of objects in the case of: int x, y, z;). Does not install the Snippets or execute them.
Params:
  • userSource – the source of the snippet
Returns:usually a singleton list of Snippet, but may be empty or multiple
/** * Converts the user source of a snippet into a Snippet object (or list of * objects in the case of: int x, y, z;). Does not install the Snippets * or execute them. * * @param userSource the source of the snippet * @return usually a singleton list of Snippet, but may be empty or multiple */
private List<Snippet> sourceToSnippets(String userSource) { String compileSource = Util.trimEnd(new MaskCommentsAndModifiers(userSource, false).cleared()); if (compileSource.length() == 0) { return Collections.emptyList(); } ParseTask pt = state.taskFactory.parse(compileSource); List<? extends Tree> units = pt.units(); if (units.isEmpty()) { return compileFailResult(pt, userSource, Kind.ERRONEOUS); } Tree unitTree = units.get(0); if (pt.getDiagnostics().hasOtherThanNotStatementErrors()) { return compileFailResult(pt, userSource, kindOfTree(unitTree)); } // Erase illegal/ignored modifiers compileSource = new MaskCommentsAndModifiers(compileSource, true).cleared(); state.debug(DBG_GEN, "Kind: %s -- %s\n", unitTree.getKind(), unitTree); switch (unitTree.getKind()) { case IMPORT: return processImport(userSource, compileSource); case VARIABLE: return processVariables(userSource, units, compileSource, pt); case EXPRESSION_STATEMENT: return processExpression(userSource, compileSource); case CLASS: return processClass(userSource, unitTree, compileSource, SubKind.CLASS_SUBKIND, pt); case ENUM: return processClass(userSource, unitTree, compileSource, SubKind.ENUM_SUBKIND, pt); case ANNOTATION_TYPE: return processClass(userSource, unitTree, compileSource, SubKind.ANNOTATION_TYPE_SUBKIND, pt); case INTERFACE: return processClass(userSource, unitTree, compileSource, SubKind.INTERFACE_SUBKIND, pt); case METHOD: return processMethod(userSource, unitTree, compileSource, pt); default: return processStatement(userSource, compileSource); } } private List<Snippet> processImport(String userSource, String compileSource) { Wrap guts = Wrap.simpleWrap(compileSource); Matcher mat = IMPORT_PATTERN.matcher(compileSource); String fullname; String name; boolean isStatic; if (mat.find()) { isStatic = mat.group("static") != null; name = mat.group("name"); fullname = mat.group("fullname"); } else { // bad import -- fake it isStatic = compileSource.contains("static"); name = fullname = compileSource; } String fullkey = (isStatic ? "static-" : "") + fullname; boolean isStar = name.equals("*"); String keyName = isStar ? fullname : name; SubKind snippetKind = isStar ? (isStatic ? STATIC_IMPORT_ON_DEMAND_SUBKIND : TYPE_IMPORT_ON_DEMAND_SUBKIND) : (isStatic ? SINGLE_STATIC_IMPORT_SUBKIND : SINGLE_TYPE_IMPORT_SUBKIND); Snippet snip = new ImportSnippet(state.keyMap.keyForImport(keyName, snippetKind), userSource, guts, fullname, name, snippetKind, fullkey, isStatic, isStar); return singletonList(snip); } private static class EvalPretty extends Pretty { private final Writer out; public EvalPretty(Writer writer, boolean bln) { super(writer, bln); this.out = writer; }
Print string, DO NOT replacing all non-ascii character with unicode escapes.
/** * Print string, DO NOT replacing all non-ascii character with unicode * escapes. */
@Override public void print(Object o) throws IOException { out.write(o.toString()); } static String prettyExpr(JCTree tree, boolean bln) { StringWriter out = new StringWriter(); try { new EvalPretty(out, bln).printExpr(tree); } catch (IOException e) { throw new AssertionError(e); } return out.toString(); } } private List<Snippet> processVariables(String userSource, List<? extends Tree> units, String compileSource, ParseTask pt) { List<Snippet> snippets = new ArrayList<>(); TreeDissector dis = TreeDissector.createByFirstClass(pt); for (Tree unitTree : units) { VariableTree vt = (VariableTree) unitTree; String name = vt.getName().toString(); String typeName = EvalPretty.prettyExpr((JCTree) vt.getType(), false); Tree baseType = vt.getType(); TreeDependencyScanner tds = new TreeDependencyScanner(); tds.scan(baseType); // Not dependent on initializer StringBuilder sbBrackets = new StringBuilder(); while (baseType instanceof ArrayTypeTree) { //TODO handle annotations too baseType = ((ArrayTypeTree) baseType).getType(); sbBrackets.append("[]"); } Range rtype = dis.treeToRange(baseType); Range runit = dis.treeToRange(vt); runit = new Range(runit.begin, runit.end - 1); ExpressionTree it = vt.getInitializer(); Range rinit = null; int nameMax = runit.end - 1; SubKind subkind; if (it != null) { subkind = SubKind.VAR_DECLARATION_WITH_INITIALIZER_SUBKIND; rinit = dis.treeToRange(it); nameMax = rinit.begin - 1; } else { subkind = SubKind.VAR_DECLARATION_SUBKIND; } int nameStart = compileSource.lastIndexOf(name, nameMax); if (nameStart < 0) { throw new AssertionError("Name '" + name + "' not found"); } int nameEnd = nameStart + name.length(); Range rname = new Range(nameStart, nameEnd); Wrap guts = Wrap.varWrap(compileSource, rtype, sbBrackets.toString(), rname, rinit); DiagList modDiag = modifierDiagnostics(vt.getModifiers(), dis, true); Snippet snip = new VarSnippet(state.keyMap.keyForVariable(name), userSource, guts, name, subkind, typeName, tds.declareReferences(), modDiag); snippets.add(snip); } return snippets; } private List<Snippet> processExpression(String userSource, String compileSource) { String name = null; ExpressionInfo ei = ExpressionToTypeInfo.expressionInfo(compileSource, state); ExpressionTree assignVar; Wrap guts; Snippet snip; if (ei != null && ei.isNonVoid) { String typeName = ei.typeName; SubKind subkind; if (ei.tree instanceof IdentifierTree) { IdentifierTree id = (IdentifierTree) ei.tree; name = id.getName().toString(); subkind = SubKind.VAR_VALUE_SUBKIND; } else if (ei.tree instanceof AssignmentTree && (assignVar = ((AssignmentTree) ei.tree).getVariable()) instanceof IdentifierTree) { name = assignVar.toString(); subkind = SubKind.ASSIGNMENT_SUBKIND; } else { subkind = SubKind.OTHER_EXPRESSION_SUBKIND; } if (shouldGenTempVar(subkind)) { if (state.tempVariableNameGenerator != null) { name = state.tempVariableNameGenerator.get(); } while (name == null || state.keyMap.doesVariableNameExist(name)) { name = "$" + ++varNumber; } guts = Wrap.tempVarWrap(compileSource, typeName, name); Collection<String> declareReferences = null; //TODO snip = new VarSnippet(state.keyMap.keyForVariable(name), userSource, guts, name, SubKind.TEMP_VAR_EXPRESSION_SUBKIND, typeName, declareReferences, null); } else { guts = Wrap.methodReturnWrap(compileSource); snip = new ExpressionSnippet(state.keyMap.keyForExpression(name, typeName), userSource, guts, name, subkind); } } else { guts = Wrap.methodWrap(compileSource); if (ei == null) { // We got no type info, check for not a statement by trying AnalyzeTask at = trialCompile(guts); if (at.getDiagnostics().hasNotStatement()) { guts = Wrap.methodReturnWrap(compileSource); at = trialCompile(guts); } if (at.hasErrors()) { return compileFailResult(at, userSource, Kind.EXPRESSION); } } snip = new StatementSnippet(state.keyMap.keyForStatement(), userSource, guts); } return singletonList(snip); } private List<Snippet> processClass(String userSource, Tree unitTree, String compileSource, SubKind snippetKind, ParseTask pt) { TreeDependencyScanner tds = new TreeDependencyScanner(); tds.scan(unitTree); TreeDissector dis = TreeDissector.createByFirstClass(pt); ClassTree klassTree = (ClassTree) unitTree; String name = klassTree.getSimpleName().toString(); DiagList modDiag = modifierDiagnostics(klassTree.getModifiers(), dis, false); TypeDeclKey key = state.keyMap.keyForClass(name); // Corralling mutates. Must be last use of pt, unitTree, klassTree Wrap corralled = new Corraller(key.index(), pt.getContext()).corralType(klassTree); Wrap guts = Wrap.classMemberWrap(compileSource); Snippet snip = new TypeDeclSnippet(key, userSource, guts, name, snippetKind, corralled, tds.declareReferences(), tds.bodyReferences(), modDiag); return singletonList(snip); } private List<Snippet> processStatement(String userSource, String compileSource) { Wrap guts = Wrap.methodWrap(compileSource); // Check for unreachable by trying AnalyzeTask at = trialCompile(guts); if (at.hasErrors()) { if (at.getDiagnostics().hasUnreachableError()) { guts = Wrap.methodUnreachableSemiWrap(compileSource); at = trialCompile(guts); if (at.hasErrors()) { if (at.getDiagnostics().hasUnreachableError()) { // Without ending semicolon guts = Wrap.methodUnreachableWrap(compileSource); at = trialCompile(guts); } if (at.hasErrors()) { return compileFailResult(at, userSource, Kind.STATEMENT); } } } else { return compileFailResult(at, userSource, Kind.STATEMENT); } } Snippet snip = new StatementSnippet(state.keyMap.keyForStatement(), userSource, guts); return singletonList(snip); } private AnalyzeTask trialCompile(Wrap guts) { OuterWrap outer = state.outerMap.wrapInTrialClass(guts); return state.taskFactory.new AnalyzeTask(outer); } private List<Snippet> processMethod(String userSource, Tree unitTree, String compileSource, ParseTask pt) { TreeDependencyScanner tds = new TreeDependencyScanner(); tds.scan(unitTree); TreeDissector dis = TreeDissector.createByFirstClass(pt); MethodTree mt = (MethodTree) unitTree; String name = mt.getName().toString(); String parameterTypes = mt.getParameters() .stream() .map(param -> dis.treeToRange(param.getType()).part(compileSource)) .collect(Collectors.joining(",")); Tree returnType = mt.getReturnType(); DiagList modDiag = modifierDiagnostics(mt.getModifiers(), dis, true); MethodKey key = state.keyMap.keyForMethod(name, parameterTypes); // Corralling mutates. Must be last use of pt, unitTree, mt Wrap corralled = new Corraller(key.index(), pt.getContext()).corralMethod(mt); if (modDiag.hasErrors()) { return compileFailResult(modDiag, userSource, Kind.METHOD); } Wrap guts = Wrap.classMemberWrap(compileSource); Range typeRange = dis.treeToRange(returnType); String signature = "(" + parameterTypes + ")" + typeRange.part(compileSource); Snippet snip = new MethodSnippet(key, userSource, guts, name, signature, corralled, tds.declareReferences(), tds.bodyReferences(), modDiag); return singletonList(snip); } private Kind kindOfTree(Tree tree) { switch (tree.getKind()) { case IMPORT: return Kind.IMPORT; case VARIABLE: return Kind.VAR; case EXPRESSION_STATEMENT: return Kind.EXPRESSION; case CLASS: case ENUM: case ANNOTATION_TYPE: case INTERFACE: return Kind.TYPE_DECL; case METHOD: return Kind.METHOD; default: return Kind.STATEMENT; } }
The snippet has failed, return with the rejected snippet
Params:
  • xt – the task from which to extract the failure diagnostics
  • userSource – the incoming bad user source
Returns:a rejected snippet
/** * The snippet has failed, return with the rejected snippet * * @param xt the task from which to extract the failure diagnostics * @param userSource the incoming bad user source * @return a rejected snippet */
private List<Snippet> compileFailResult(BaseTask xt, String userSource, Kind probableKind) { return compileFailResult(xt.getDiagnostics(), userSource, probableKind); }
The snippet has failed, return with the rejected snippet
Params:
  • diags – the failure diagnostics
  • userSource – the incoming bad user source
Returns:a rejected snippet
/** * The snippet has failed, return with the rejected snippet * * @param diags the failure diagnostics * @param userSource the incoming bad user source * @return a rejected snippet */
private List<Snippet> compileFailResult(DiagList diags, String userSource, Kind probableKind) { ErroneousKey key = state.keyMap.keyForErroneous(); Snippet snip = new ErroneousSnippet(key, userSource, null, probableKind, SubKind.UNKNOWN_SUBKIND); snip.setFailed(diags); // Install wrapper for query by SourceCodeAnalysis.wrapper String compileSource = Util.trimEnd(new MaskCommentsAndModifiers(userSource, true).cleared()); OuterWrap outer; switch (probableKind) { case IMPORT: outer = state.outerMap.wrapImport(Wrap.simpleWrap(compileSource), snip); break; case EXPRESSION: outer = state.outerMap.wrapInTrialClass(Wrap.methodReturnWrap(compileSource)); break; case VAR: case TYPE_DECL: case METHOD: outer = state.outerMap.wrapInTrialClass(Wrap.classMemberWrap(compileSource)); break; default: outer = state.outerMap.wrapInTrialClass(Wrap.methodWrap(compileSource)); break; } snip.setOuterWrap(outer); return singletonList(snip); }
Should a temp var wrap the expression. TODO make this user configurable.
Params:
  • snippetKind –
Returns:
/** * Should a temp var wrap the expression. TODO make this user configurable. * * @param snippetKind * @return */
private boolean shouldGenTempVar(SubKind snippetKind) { return snippetKind == SubKind.OTHER_EXPRESSION_SUBKIND; } List<SnippetEvent> drop(Snippet si) { Unit c = new Unit(state, si); Set<Unit> outs; if (si instanceof PersistentSnippet) { Set<Unit> ins = c.dependents().collect(toSet()); outs = compileAndLoad(ins); } else { outs = Collections.emptySet(); } return events(c, outs, null, null); } private List<SnippetEvent> declare(Snippet si, DiagList generatedDiagnostics) { Unit c = new Unit(state, si, null, generatedDiagnostics); Set<Unit> ins = new LinkedHashSet<>(); ins.add(c); Set<Unit> outs = compileAndLoad(ins); if (!si.status().isDefined() && si.diagnostics().isEmpty() && si.unresolved().isEmpty()) { // did not succeed, but no record of it, extract from others si.setDiagnostics(outs.stream() .flatMap(u -> u.snippet().diagnostics().stream()) .collect(Collectors.toCollection(DiagList::new))); } // If appropriate, execute the snippet String value = null; JShellException exception = null; if (si.status().isDefined()) { if (si.isExecutable()) { try { value = state.executionControl().invoke(si.classFullName(), DOIT_METHOD_NAME); value = si.subKind().hasValue() ? expunge(value) : ""; } catch (ResolutionException ex) { DeclarationSnippet sn = (DeclarationSnippet) state.maps.getSnippetDeadOrAlive(ex.id()); exception = new UnresolvedReferenceException(sn, translateExceptionStack(ex)); } catch (UserException ex) { exception = new EvalException(translateExceptionMessage(ex), ex.causeExceptionClass(), translateExceptionStack(ex)); } catch (RunException ex) { // StopException - no-op } catch (InternalException ex) { state.debug(ex, "invoke"); } catch (EngineTerminationException ex) { state.closeDown(); } } else if (si.subKind() == SubKind.VAR_DECLARATION_SUBKIND) { switch (((VarSnippet) si).typeName()) { case "byte": case "short": case "int": case "long": value = "0"; break; case "float": case "double": value = "0.0"; break; case "boolean": value = "false"; break; case "char": value = "''"; break; default: value = "null"; break; } } } return events(c, outs, value, exception); } private boolean interestingEvent(SnippetEvent e) { return e.isSignatureChange() || e.causeSnippet() == null || e.status() != e.previousStatus() || e.exception() != null; } private List<SnippetEvent> events(Unit c, Collection<Unit> outs, String value, JShellException exception) { List<SnippetEvent> events = new ArrayList<>(); events.add(c.event(value, exception)); events.addAll(outs.stream() .filter(u -> u != c) .map(u -> u.event(null, null)) .filter(this::interestingEvent) .collect(Collectors.toList())); events.addAll(outs.stream() .flatMap(u -> u.secondaryEvents().stream()) .filter(this::interestingEvent) .collect(Collectors.toList())); //System.err.printf("Events: %s\n", events); return events; } private Set<OuterWrap> outerWrapSet(Collection<Unit> units) { return units.stream() .map(u -> u.snippet().outerWrap()) .collect(toSet()); } private Set<Unit> compileAndLoad(Set<Unit> ins) { if (ins.isEmpty()) { return ins; } Set<Unit> replaced = new LinkedHashSet<>(); // Loop until dependencies and errors are stable while (true) { state.debug(DBG_GEN, "compileAndLoad %s\n", ins); ins.stream().forEach(Unit::initialize); ins.stream().forEach(u -> u.setWrap(ins, ins)); AnalyzeTask at = state.taskFactory.new AnalyzeTask(outerWrapSet(ins)); ins.stream().forEach(u -> u.setDiagnostics(at)); // corral any Snippets that need it AnalyzeTask cat; if (ins.stream().anyMatch(u -> u.corralIfNeeded(ins))) { // if any were corralled, re-analyze everything cat = state.taskFactory.new AnalyzeTask(outerWrapSet(ins)); ins.stream().forEach(u -> u.setCorralledDiagnostics(cat)); } else { cat = at; } ins.stream().forEach(u -> u.setStatus(cat)); // compile and load the legit snippets boolean success; while (true) { List<Unit> legit = ins.stream() .filter(Unit::isDefined) .collect(toList()); state.debug(DBG_GEN, "compileAndLoad ins = %s -- legit = %s\n", ins, legit); if (legit.isEmpty()) { // no class files can be generated success = true; } else { // re-wrap with legit imports legit.stream().forEach(u -> u.setWrap(ins, legit)); // generate class files for those capable CompileTask ct = state.taskFactory.new CompileTask(outerWrapSet(legit)); if (!ct.compile()) { // oy! compile failed because of recursive new unresolved if (legit.stream() .filter(u -> u.smashingErrorDiagnostics(ct)) .count() > 0) { // try again, with the erroreous removed continue; } else { state.debug(DBG_GEN, "Should never happen error-less failure - %s\n", legit); } } // load all new classes load(legit.stream() .flatMap(u -> u.classesToLoad(ct.classList(u.snippet().outerWrap()))) .collect(toSet())); // attempt to redefine the remaining classes List<Unit> toReplace = legit.stream() .filter(u -> !u.doRedefines()) .collect(toList()); // prevent alternating redefine/replace cyclic dependency // loop by replacing all that have been replaced if (!toReplace.isEmpty()) { replaced.addAll(toReplace); replaced.stream().forEach(Unit::markForReplacement); } success = toReplace.isEmpty(); } break; } // add any new dependencies to the working set List<Unit> newDependencies = ins.stream() .flatMap(Unit::effectedDependents) .collect(toList()); state.debug(DBG_GEN, "compileAndLoad %s -- deps: %s success: %s\n", ins, newDependencies, success); if (!ins.addAll(newDependencies) && success) { // all classes that could not be directly loaded (because they // are new) have been redefined, and no new dependnencies were // identified ins.stream().forEach(Unit::finish); return ins; } } }
If there are classes to load, loads by calling the execution engine.
Params:
  • classbytecodes – names of the classes to load.
/** * If there are classes to load, loads by calling the execution engine. * @param classbytecodes names of the classes to load. */
private void load(Collection<ClassBytecodes> classbytecodes) { if (!classbytecodes.isEmpty()) { ClassBytecodes[] cbcs = classbytecodes.toArray(new ClassBytecodes[classbytecodes.size()]); try { state.executionControl().load(cbcs); state.classTracker.markLoaded(cbcs); } catch (ClassInstallException ex) { state.classTracker.markLoaded(cbcs, ex.installed()); } catch (NotImplementedException ex) { state.debug(ex, "Seriously?!? load not implemented"); state.closeDown(); } catch (EngineTerminationException ex) { state.closeDown(); } } } private StackTraceElement[] translateExceptionStack(Exception ex) { StackTraceElement[] raw = ex.getStackTrace(); int last = raw.length; do { if (last == 0) { last = raw.length - 1; break; } } while (!isWrap(raw[--last])); StackTraceElement[] elems = new StackTraceElement[last + 1]; for (int i = 0; i <= last; ++i) { StackTraceElement r = raw[i]; OuterSnippetsClassWrap outer = state.outerMap.getOuter(r.getClassName()); if (outer != null) { String klass = expunge(r.getClassName()); String method = r.getMethodName().equals(DOIT_METHOD_NAME) ? "" : r.getMethodName(); int wln = r.getLineNumber() - 1; int line = outer.wrapLineToSnippetLine(wln) + 1; Snippet sn = outer.wrapLineToSnippet(wln); String file = "#" + sn.id(); elems[i] = new StackTraceElement(klass, method, file, line); } else if (r.getFileName().equals("<none>")) { elems[i] = new StackTraceElement(r.getClassName(), r.getMethodName(), null, r.getLineNumber()); } else { elems[i] = r; } } return elems; } private String translateExceptionMessage(Exception ex) { String msg = ex.getMessage(); return msg.equals("<none>") ? null : msg; } private boolean isWrap(StackTraceElement ste) { return PREFIX_PATTERN.matcher(ste.getClassName()).find(); } private DiagList modifierDiagnostics(ModifiersTree modtree, final TreeDissector dis, boolean isAbstractProhibited) { class ModifierDiagnostic extends Diag { final boolean fatal; final String message; ModifierDiagnostic(List<Modifier> list, boolean fatal) { this.fatal = fatal; StringBuilder sb = new StringBuilder(); for (Modifier mod : list) { sb.append("'"); sb.append(mod.toString()); sb.append("' "); } String key = (list.size() > 1) ? fatal ? "jshell.diag.modifier.plural.fatal" : "jshell.diag.modifier.plural.ignore" : fatal ? "jshell.diag.modifier.single.fatal" : "jshell.diag.modifier.single.ignore"; this.message = state.messageFormat(key, sb.toString()); } @Override public boolean isError() { return fatal; } @Override public long getPosition() { return dis.getStartPosition(modtree); } @Override public long getStartPosition() { return dis.getStartPosition(modtree); } @Override public long getEndPosition() { return dis.getEndPosition(modtree); } @Override public String getCode() { return fatal ? "jdk.eval.error.illegal.modifiers" : "jdk.eval.warn.illegal.modifiers"; } @Override public String getMessage(Locale locale) { return message; } } List<Modifier> list = new ArrayList<>(); boolean fatal = false; for (Modifier mod : modtree.getFlags()) { switch (mod) { case SYNCHRONIZED: case NATIVE: list.add(mod); fatal = true; break; case ABSTRACT: if (isAbstractProhibited) { list.add(mod); fatal = true; } break; case PUBLIC: case PROTECTED: case PRIVATE: // quietly ignore, user cannot see effects one way or the other break; case STATIC: case FINAL: list.add(mod); break; } } return list.isEmpty() ? new DiagList() : new DiagList(new ModifierDiagnostic(list, fatal)); } }