Mercurial > hg > shenandoah-preopenjdk-archive > openjdk8 > nashorn
view src/jdk/nashorn/internal/codegen/Compiler.java @ 1079:e1e27c4262be
8060204: Fix warnings in Joni and tests
Reviewed-by: hannesw, sundar, attila
| author | lagergren |
|---|---|
| date | Mon, 03 Nov 2014 11:47:41 +0100 |
| parents | 03c06c337d9d |
| children |
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/* * Copyright (c) 2010, 2013, 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 * or visit www.oracle.com if you need additional information or have any * questions. */ package jdk.nashorn.internal.codegen; import static jdk.nashorn.internal.codegen.CompilerConstants.ARGUMENTS; import static jdk.nashorn.internal.codegen.CompilerConstants.CALLEE; import static jdk.nashorn.internal.codegen.CompilerConstants.RETURN; import static jdk.nashorn.internal.codegen.CompilerConstants.SCOPE; import static jdk.nashorn.internal.codegen.CompilerConstants.THIS; import static jdk.nashorn.internal.codegen.CompilerConstants.VARARGS; import static jdk.nashorn.internal.runtime.logging.DebugLogger.quote; import java.io.File; import java.lang.invoke.MethodType; import java.util.ArrayList; import java.util.Arrays; import java.util.Collections; import java.util.Comparator; import java.util.HashMap; import java.util.Iterator; import java.util.LinkedHashMap; import java.util.List; import java.util.Map; import java.util.Set; import java.util.TreeMap; import java.util.concurrent.atomic.AtomicInteger; import java.util.function.Consumer; import java.util.logging.Level; import jdk.internal.dynalink.support.NameCodec; import jdk.nashorn.internal.codegen.types.Type; import jdk.nashorn.internal.ir.Expression; import jdk.nashorn.internal.ir.FunctionNode; import jdk.nashorn.internal.ir.Optimistic; import jdk.nashorn.internal.ir.debug.ClassHistogramElement; import jdk.nashorn.internal.ir.debug.ObjectSizeCalculator; import jdk.nashorn.internal.runtime.CodeInstaller; import jdk.nashorn.internal.runtime.Context; import jdk.nashorn.internal.runtime.ErrorManager; import jdk.nashorn.internal.runtime.FunctionInitializer; import jdk.nashorn.internal.runtime.ParserException; import jdk.nashorn.internal.runtime.RecompilableScriptFunctionData; import jdk.nashorn.internal.runtime.ScriptEnvironment; import jdk.nashorn.internal.runtime.ScriptObject; import jdk.nashorn.internal.runtime.ScriptRuntime; import jdk.nashorn.internal.runtime.Source; import jdk.nashorn.internal.runtime.logging.DebugLogger; import jdk.nashorn.internal.runtime.logging.Loggable; import jdk.nashorn.internal.runtime.logging.Logger; /** * Responsible for converting JavaScripts to java byte code. Main entry * point for code generator. The compiler may also install classes given some * predefined Code installation policy, given to it at construction time. * @see CodeInstaller */ @Logger(name="compiler") public final class Compiler implements Loggable { /** Name of the scripts package */ public static final String SCRIPTS_PACKAGE = "jdk/nashorn/internal/scripts"; /** Name of the objects package */ public static final String OBJECTS_PACKAGE = "jdk/nashorn/internal/objects"; private final ScriptEnvironment env; private final Source source; private final String sourceName; private final ErrorManager errors; private final boolean optimistic; private final Map<String, byte[]> bytecode; private final Set<CompileUnit> compileUnits; private final ConstantData constantData; private final CodeInstaller<ScriptEnvironment> installer; /** logger for compiler, trampolines, splits and related code generation events * that affect classes */ private final DebugLogger log; private final Context context; private final TypeMap types; // Runtime scope in effect at the time of the compilation. Used to evaluate types of expressions and prevent overly // optimistic assumptions (which will lead to unnecessary deoptimizing recompilations). private final TypeEvaluator typeEvaluator; private final boolean strict; private final boolean onDemand; /** * If this is a recompilation, this is how we pass in the invalidations, e.g. programPoint=17, Type == int means * that using whatever was at program point 17 as an int failed. */ private final Map<Integer, Type> invalidatedProgramPoints; /** * Descriptor of the location where we write the type information after compilation. */ private final Object typeInformationFile; /** * Compile unit name of first compile unit - this prefix will be used for all * classes that a compilation generates. */ private final String firstCompileUnitName; /** * Contains the program point that should be used as the continuation entry point, as well as all previous * continuation entry points executed as part of a single logical invocation of the function. In practical terms, if * we execute a rest-of method from the program point 17, but then we hit deoptimization again during it at program * point 42, and execute a rest-of method from the program point 42, and then we hit deoptimization again at program * point 57 and are compiling a rest-of method for it, the values in the array will be [57, 42, 17]. This is only * set when compiling a rest-of method. If this method is a rest-of for a non-rest-of method, the array will have * one element. If it is a rest-of for a rest-of, the array will have two elements, and so on. */ private final int[] continuationEntryPoints; /** * ScriptFunction data for what is being compile, where applicable. * TODO: make this immutable, propagate it through the CompilationPhases */ private RecompilableScriptFunctionData compiledFunction; /** * Most compile unit names are longer than the default StringBuilder buffer, * worth startup performance when massive class generation is going on to increase * this */ private static final int COMPILE_UNIT_NAME_BUFFER_SIZE = 32; private final Map<Integer, byte[]> serializedAsts = new HashMap<>(); /** * Compilation phases that a compilation goes through */ public static class CompilationPhases implements Iterable<CompilationPhase> { /** * Singleton that describes compilation up to the phase where a function can be serialized. */ private final static CompilationPhases COMPILE_UPTO_SERIALIZABLE = new CompilationPhases( "Common initial phases", CompilationPhase.CONSTANT_FOLDING_PHASE, CompilationPhase.LOWERING_PHASE, CompilationPhase.TRANSFORM_BUILTINS_PHASE, CompilationPhase.SPLITTING_PHASE, CompilationPhase.PROGRAM_POINT_PHASE, CompilationPhase.SERIALIZE_SPLIT_PHASE ); private final static CompilationPhases COMPILE_SERIALIZABLE_UPTO_BYTECODE = new CompilationPhases( "After common phases, before bytecode generator", CompilationPhase.SYMBOL_ASSIGNMENT_PHASE, CompilationPhase.SCOPE_DEPTH_COMPUTATION_PHASE, CompilationPhase.OPTIMISTIC_TYPE_ASSIGNMENT_PHASE, CompilationPhase.LOCAL_VARIABLE_TYPE_CALCULATION_PHASE ); /** * Singleton that describes additional steps to be taken after deserializing, all the way up to (but not * including) generating and installing code. */ public final static CompilationPhases RECOMPILE_SERIALIZED_UPTO_BYTECODE = new CompilationPhases( "Recompile serialized function up to bytecode", CompilationPhase.REINITIALIZE_SERIALIZED, COMPILE_SERIALIZABLE_UPTO_BYTECODE ); /** * Singleton that describes back end of method generation, given that we have generated the normal * method up to CodeGenerator as in {@link CompilationPhases#COMPILE_UPTO_BYTECODE} */ public final static CompilationPhases GENERATE_BYTECODE_AND_INSTALL = new CompilationPhases( "Generate bytecode and install", CompilationPhase.BYTECODE_GENERATION_PHASE, CompilationPhase.INSTALL_PHASE ); /** Singleton that describes compilation up to the CodeGenerator, but not actually generating code */ public final static CompilationPhases COMPILE_UPTO_BYTECODE = new CompilationPhases( "Compile upto bytecode", COMPILE_UPTO_SERIALIZABLE, COMPILE_SERIALIZABLE_UPTO_BYTECODE); /** Singleton that describes a standard eager compilation, but no installation, for example used by --compile-only */ public final static CompilationPhases COMPILE_ALL_NO_INSTALL = new CompilationPhases( "Compile without install", COMPILE_UPTO_BYTECODE, CompilationPhase.BYTECODE_GENERATION_PHASE); /** Singleton that describes a standard eager compilation - this includes code installation */ public final static CompilationPhases COMPILE_ALL = new CompilationPhases( "Full eager compilation", COMPILE_UPTO_BYTECODE, GENERATE_BYTECODE_AND_INSTALL); /** Singleton that describes a full compilation - this includes code installation - from serialized state*/ public final static CompilationPhases COMPILE_ALL_SERIALIZED = new CompilationPhases( "Eager compilation from serializaed state", RECOMPILE_SERIALIZED_UPTO_BYTECODE, GENERATE_BYTECODE_AND_INSTALL); /** * Singleton that describes restOf method generation, given that we have generated the normal * method up to CodeGenerator as in {@link CompilationPhases#COMPILE_UPTO_BYTECODE} */ public final static CompilationPhases GENERATE_BYTECODE_AND_INSTALL_RESTOF = new CompilationPhases( "Generate bytecode and install - RestOf method", CompilationPhase.REUSE_COMPILE_UNITS_PHASE, GENERATE_BYTECODE_AND_INSTALL); /** Compile all for a rest of method */ public final static CompilationPhases COMPILE_ALL_RESTOF = new CompilationPhases( "Compile all, rest of", COMPILE_UPTO_BYTECODE, GENERATE_BYTECODE_AND_INSTALL_RESTOF); /** Compile from serialized for a rest of method */ public final static CompilationPhases COMPILE_SERIALIZED_RESTOF = new CompilationPhases( "Compile serialized, rest of", RECOMPILE_SERIALIZED_UPTO_BYTECODE, GENERATE_BYTECODE_AND_INSTALL_RESTOF); private final List<CompilationPhase> phases; private final String desc; private CompilationPhases(final String desc, final CompilationPhase... phases) { this(desc, Arrays.asList(phases)); } private CompilationPhases(final String desc, final CompilationPhases base, final CompilationPhase... phases) { this(desc, concat(base.phases, Arrays.asList(phases))); } private CompilationPhases(final String desc, final CompilationPhase first, final CompilationPhases rest) { this(desc, concat(Collections.singletonList(first), rest.phases)); } private CompilationPhases(final String desc, final CompilationPhases base) { this(desc, base.phases); } private CompilationPhases(final String desc, final CompilationPhases... bases) { this(desc, concatPhases(bases)); } private CompilationPhases(final String desc, final List<CompilationPhase> phases) { this.desc = desc; this.phases = phases; } private static List<CompilationPhase> concatPhases(final CompilationPhases[] bases) { final ArrayList<CompilationPhase> l = new ArrayList<>(); for(final CompilationPhases base: bases) { l.addAll(base.phases); } l.trimToSize(); return l; } private static <T> List<T> concat(final List<T> l1, final List<T> l2) { final ArrayList<T> l = new ArrayList<>(l1); l.addAll(l2); l.trimToSize(); return l; } @Override public String toString() { return "'" + desc + "' " + phases.toString(); } boolean contains(final CompilationPhase phase) { return phases.contains(phase); } @Override public Iterator<CompilationPhase> iterator() { return phases.iterator(); } boolean isRestOfCompilation() { return this == COMPILE_ALL_RESTOF || this == GENERATE_BYTECODE_AND_INSTALL_RESTOF || this == COMPILE_SERIALIZED_RESTOF; } String getDesc() { return desc; } String toString(final String prefix) { final StringBuilder sb = new StringBuilder(); for (final CompilationPhase phase : phases) { sb.append(prefix).append(phase).append('\n'); } return sb.toString(); } } /** * This array contains names that need to be reserved at the start * of a compile, to avoid conflict with variable names later introduced. * See {@link CompilerConstants} for special names used for structures * during a compile. */ private static String[] RESERVED_NAMES = { SCOPE.symbolName(), THIS.symbolName(), RETURN.symbolName(), CALLEE.symbolName(), VARARGS.symbolName(), ARGUMENTS.symbolName() }; // per instance private final int compilationId = COMPILATION_ID.getAndIncrement(); // per instance private final AtomicInteger nextCompileUnitId = new AtomicInteger(0); private static final AtomicInteger COMPILATION_ID = new AtomicInteger(0); /** * Constructor * * @param context context * @param env script environment * @param installer code installer * @param source source to compile * @param errors error manager * @param isStrict is this a strict compilation */ public Compiler( final Context context, final ScriptEnvironment env, final CodeInstaller<ScriptEnvironment> installer, final Source source, final ErrorManager errors, final boolean isStrict) { this(context, env, installer, source, errors, isStrict, false, null, null, null, null, null, null); } /** * Constructor * * @param context context * @param env script environment * @param installer code installer * @param source source to compile * @param errors error manager * @param isStrict is this a strict compilation * @param isOnDemand is this an on demand compilation * @param compiledFunction compiled function, if any * @param types parameter and return value type information, if any is known * @param invalidatedProgramPoints invalidated program points for recompilation * @param typeInformationFile descriptor of the location where type information is persisted * @param continuationEntryPoints continuation entry points for restof method * @param runtimeScope runtime scope for recompilation type lookup in {@code TypeEvaluator} */ @SuppressWarnings("unused") public Compiler( final Context context, final ScriptEnvironment env, final CodeInstaller<ScriptEnvironment> installer, final Source source, final ErrorManager errors, final boolean isStrict, final boolean isOnDemand, final RecompilableScriptFunctionData compiledFunction, final TypeMap types, final Map<Integer, Type> invalidatedProgramPoints, final Object typeInformationFile, final int[] continuationEntryPoints, final ScriptObject runtimeScope) { this.context = context; this.env = env; this.installer = installer; this.constantData = new ConstantData(); this.compileUnits = CompileUnit.createCompileUnitSet(); this.bytecode = new LinkedHashMap<>(); this.log = initLogger(context); this.source = source; this.errors = errors; this.sourceName = FunctionNode.getSourceName(source); this.onDemand = isOnDemand; this.compiledFunction = compiledFunction; this.types = types; this.invalidatedProgramPoints = invalidatedProgramPoints == null ? new HashMap<Integer, Type>() : invalidatedProgramPoints; this.typeInformationFile = typeInformationFile; this.continuationEntryPoints = continuationEntryPoints == null ? null: continuationEntryPoints.clone(); this.typeEvaluator = new TypeEvaluator(this, runtimeScope); this.firstCompileUnitName = firstCompileUnitName(); this.strict = isStrict; this.optimistic = env._optimistic_types; } private static String safeSourceName(final ScriptEnvironment env, final CodeInstaller<ScriptEnvironment> installer, final Source source) { String baseName = new File(source.getName()).getName(); final int index = baseName.lastIndexOf(".js"); if (index != -1) { baseName = baseName.substring(0, index); } baseName = baseName.replace('.', '_').replace('-', '_'); if (!env._loader_per_compile) { baseName = baseName + installer.getUniqueScriptId(); } // ASM's bytecode verifier does not allow JVM allowed safe escapes using '\' as escape char. // While ASM accepts such escapes for method names, field names, it enforces Java identifier // for class names. Workaround that ASM bug here by replacing JVM 'dangerous' chars with '_' // rather than safe encoding using '\'. final String mangled = env._verify_code? replaceDangerChars(baseName) : NameCodec.encode(baseName); return mangled != null ? mangled : baseName; } private static final String DANGEROUS_CHARS = "\\/.;:$[]<>"; private static String replaceDangerChars(final String name) { final int len = name.length(); final StringBuilder buf = new StringBuilder(); for (int i = 0; i < len; i++) { final char ch = name.charAt(i); if (DANGEROUS_CHARS.indexOf(ch) != -1) { buf.append('_'); } else { buf.append(ch); } } return buf.toString(); } private String firstCompileUnitName() { final StringBuilder sb = new StringBuilder(SCRIPTS_PACKAGE). append('/'). append(CompilerConstants.DEFAULT_SCRIPT_NAME.symbolName()). append('$'); if (isOnDemandCompilation()) { sb.append(RecompilableScriptFunctionData.RECOMPILATION_PREFIX); } if (compilationId > 0) { sb.append(compilationId).append('$'); } if (types != null && compiledFunction.getFunctionNodeId() > 0) { sb.append(compiledFunction.getFunctionNodeId()); final Type[] paramTypes = types.getParameterTypes(compiledFunction.getFunctionNodeId()); for (final Type t : paramTypes) { sb.append(Type.getShortSignatureDescriptor(t)); } sb.append('$'); } sb.append(Compiler.safeSourceName(env, installer, source)); return sb.toString(); } void declareLocalSymbol(final String symbolName) { typeEvaluator.declareLocalSymbol(symbolName); } void setData(final RecompilableScriptFunctionData data) { assert this.compiledFunction == null : data; this.compiledFunction = data; } @Override public DebugLogger getLogger() { return log; } @Override public DebugLogger initLogger(final Context ctxt) { final boolean optimisticTypes = env._optimistic_types; final boolean lazyCompilation = env._lazy_compilation; return ctxt.getLogger(this.getClass(), new Consumer<DebugLogger>() { @Override public void accept(final DebugLogger newLogger) { if (!lazyCompilation) { newLogger.warning("WARNING: Running with lazy compilation switched off. This is not a default setting."); } newLogger.warning("Optimistic types are ", optimisticTypes ? "ENABLED." : "DISABLED."); } }); } ScriptEnvironment getScriptEnvironment() { return env; } boolean isOnDemandCompilation() { return onDemand; } boolean useOptimisticTypes() { return optimistic; } Context getContext() { return context; } Type getOptimisticType(final Optimistic node) { return typeEvaluator.getOptimisticType(node); } /** * Returns true if the expression can be safely evaluated, and its value is an object known to always use * String as the type of its property names retrieved through * {@link ScriptRuntime#toPropertyIterator(Object)}. It is used to avoid optimistic assumptions about its * property name types. * @param expr the expression to test * @return true if the expression can be safely evaluated, and its value is an object known to always use * String as the type of its property iterators. */ boolean hasStringPropertyIterator(final Expression expr) { return typeEvaluator.hasStringPropertyIterator(expr); } void addInvalidatedProgramPoint(final int programPoint, final Type type) { invalidatedProgramPoints.put(programPoint, type); } /** * Returns a copy of this compiler's current mapping of invalidated optimistic program points to their types. The * copy is not live with regard to changes in state in this compiler instance, and is mutable. * @return a copy of this compiler's current mapping of invalidated optimistic program points to their types. */ public Map<Integer, Type> getInvalidatedProgramPoints() { return invalidatedProgramPoints == null ? null : new TreeMap<>(invalidatedProgramPoints); } TypeMap getTypeMap() { return types; } MethodType getCallSiteType(final FunctionNode fn) { if (types == null || !isOnDemandCompilation()) { return null; } return types.getCallSiteType(fn); } Type getParamType(final FunctionNode fn, final int pos) { return types == null ? null : types.get(fn, pos); } /** * Do a compilation job * * @param functionNode function node to compile * @param phases phases of compilation transforms to apply to function * @return transformed function * * @throws CompilationException if error occurs during compilation */ public FunctionNode compile(final FunctionNode functionNode, final CompilationPhases phases) throws CompilationException { if (log.isEnabled()) { log.info(">> Starting compile job for ", DebugLogger.quote(functionNode.getName()), " phases=", quote(phases.getDesc())); log.indent(); } final String name = DebugLogger.quote(functionNode.getName()); FunctionNode newFunctionNode = functionNode; for (final String reservedName : RESERVED_NAMES) { newFunctionNode.uniqueName(reservedName); } final boolean info = log.levelFinerThanOrEqual(Level.INFO); final DebugLogger timeLogger = env.isTimingEnabled() ? env._timing.getLogger() : null; long time = 0L; for (final CompilationPhase phase : phases) { log.fine(phase, " starting for ", name); try { newFunctionNode = phase.apply(this, phases, newFunctionNode); } catch (final ParserException error) { errors.error(error); if (env._dump_on_error) { error.printStackTrace(env.getErr()); } return null; } log.fine(phase, " done for function ", quote(name)); if (env._print_mem_usage) { printMemoryUsage(functionNode, phase.toString()); } time += (env.isTimingEnabled() ? phase.getEndTime() - phase.getStartTime() : 0L); } if (typeInformationFile != null && !phases.isRestOfCompilation()) { OptimisticTypesPersistence.store(typeInformationFile, invalidatedProgramPoints); } log.unindent(); if (info) { final StringBuilder sb = new StringBuilder("<< Finished compile job for "); sb.append(newFunctionNode.getSource()). append(':'). append(quote(newFunctionNode.getName())); if (time > 0L && timeLogger != null) { assert env.isTimingEnabled(); sb.append(" in ").append(time).append(" ms"); } log.info(sb); } return newFunctionNode; } Source getSource() { return source; } Map<String, byte[]> getBytecode() { return Collections.unmodifiableMap(bytecode); } /** * Reset bytecode cache for compiler reuse. */ void clearBytecode() { bytecode.clear(); } CompileUnit getFirstCompileUnit() { assert !compileUnits.isEmpty(); return compileUnits.iterator().next(); } Set<CompileUnit> getCompileUnits() { return compileUnits; } ConstantData getConstantData() { return constantData; } CodeInstaller<ScriptEnvironment> getCodeInstaller() { return installer; } void addClass(final String name, final byte[] code) { bytecode.put(name, code); } String nextCompileUnitName() { final StringBuilder sb = new StringBuilder(COMPILE_UNIT_NAME_BUFFER_SIZE); sb.append(firstCompileUnitName); final int cuid = nextCompileUnitId.getAndIncrement(); if (cuid > 0) { sb.append("$cu").append(cuid); } return sb.toString(); } Map<Integer, FunctionInitializer> functionInitializers; void addFunctionInitializer(final RecompilableScriptFunctionData functionData, final FunctionNode functionNode) { if (functionInitializers == null) { functionInitializers = new HashMap<>(); } if (!functionInitializers.containsKey(functionData)) { functionInitializers.put(functionData.getFunctionNodeId(), new FunctionInitializer(functionNode)); } } Map<Integer, FunctionInitializer> getFunctionInitializers() { return functionInitializers; } /** * Persist current compilation with the given {@code cacheKey}. * @param cacheKey cache key * @param functionNode function node */ public void persistClassInfo(final String cacheKey, final FunctionNode functionNode) { if (cacheKey != null && env._persistent_cache) { Map<Integer, FunctionInitializer> initializers; // If this is an on-demand compilation create a function initializer for the function being compiled. // Otherwise use function initializer map generated by codegen. if (functionInitializers == null) { initializers = new HashMap<>(); final FunctionInitializer initializer = new FunctionInitializer(functionNode, getInvalidatedProgramPoints()); initializers.put(functionNode.getId(), initializer); } else { initializers = functionInitializers; } final String mainClassName = getFirstCompileUnit().getUnitClassName(); installer.storeScript(cacheKey, source, mainClassName, bytecode, initializers, constantData.toArray(), compilationId); } } /** * Make sure the next compilation id is greater than {@code value}. * @param value compilation id value */ public static void updateCompilationId(final int value) { if (value >= COMPILATION_ID.get()) { COMPILATION_ID.set(value + 1); } } CompileUnit addCompileUnit(final long initialWeight) { final CompileUnit compileUnit = createCompileUnit(initialWeight); compileUnits.add(compileUnit); log.fine("Added compile unit ", compileUnit); return compileUnit; } CompileUnit createCompileUnit(final String unitClassName, final long initialWeight) { final ClassEmitter classEmitter = new ClassEmitter(context, sourceName, unitClassName, isStrict()); final CompileUnit compileUnit = new CompileUnit(unitClassName, classEmitter, initialWeight); classEmitter.begin(); return compileUnit; } private CompileUnit createCompileUnit(final long initialWeight) { return createCompileUnit(nextCompileUnitName(), initialWeight); } boolean isStrict() { return strict; } void replaceCompileUnits(final Set<CompileUnit> newUnits) { compileUnits.clear(); compileUnits.addAll(newUnits); } void serializeAst(final FunctionNode fn) { serializedAsts.put(fn.getId(), AstSerializer.serialize(fn)); } byte[] removeSerializedAst(final int fnId) { return serializedAsts.remove(fnId); } CompileUnit findUnit(final long weight) { for (final CompileUnit unit : compileUnits) { if (unit.canHold(weight)) { unit.addWeight(weight); return unit; } } return addCompileUnit(weight); } /** * Convert a package/class name to a binary name. * * @param name Package/class name. * @return Binary name. */ public static String binaryName(final String name) { return name.replace('/', '.'); } RecompilableScriptFunctionData getScriptFunctionData(final int functionId) { assert compiledFunction != null; final RecompilableScriptFunctionData fn = compiledFunction.getScriptFunctionData(functionId); assert fn != null : functionId; return fn; } boolean isGlobalSymbol(final FunctionNode fn, final String name) { return getScriptFunctionData(fn.getId()).isGlobalSymbol(fn, name); } int[] getContinuationEntryPoints() { return continuationEntryPoints; } Type getInvalidatedProgramPointType(final int programPoint) { return invalidatedProgramPoints.get(programPoint); } private void printMemoryUsage(final FunctionNode functionNode, final String phaseName) { if (!log.isEnabled()) { return; } log.info(phaseName, "finished. Doing IR size calculation..."); final ObjectSizeCalculator osc = new ObjectSizeCalculator(ObjectSizeCalculator.getEffectiveMemoryLayoutSpecification()); osc.calculateObjectSize(functionNode); final List<ClassHistogramElement> list = osc.getClassHistogram(); final StringBuilder sb = new StringBuilder(); final long totalSize = osc.calculateObjectSize(functionNode); sb.append(phaseName). append(" Total size = "). append(totalSize / 1024 / 1024). append("MB"); log.info(sb); Collections.sort(list, new Comparator<ClassHistogramElement>() { @Override public int compare(final ClassHistogramElement o1, final ClassHistogramElement o2) { final long diff = o1.getBytes() - o2.getBytes(); if (diff < 0) { return 1; } else if (diff > 0) { return -1; } else { return 0; } } }); for (final ClassHistogramElement e : list) { final String line = String.format(" %-48s %10d bytes (%8d instances)", e.getClazz(), e.getBytes(), e.getInstances()); log.info(line); if (e.getBytes() < totalSize / 200) { log.info(" ..."); break; // never mind, so little memory anyway } } } }