8211425: Allocation of old generation of java heap on alternate memory devices - G1 GC
8202286: Allocation of old generation of Java heap on alternate memory devices
Summary: Enable an experimental feature in HotSpot JVM to allocate old generation of G1 GC on an alternative memory device, such as NV-DIMMs.
Reviewed-by: sangheki, sjohanss
Contributed-by: kishor.kharbas@intel.com
/*
* Copyright (c) 2012, 2018, 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.
*
* 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 sun.hotspot;
import java.lang.management.MemoryUsage;
import java.lang.reflect.Executable;
import java.util.Arrays;
import java.util.List;
import java.util.function.BiFunction;
import java.util.function.Function;
import java.security.BasicPermission;
import java.util.Objects;
import sun.hotspot.parser.DiagnosticCommand;
public class WhiteBox {
@SuppressWarnings("serial")
public static class WhiteBoxPermission extends BasicPermission {
public WhiteBoxPermission(String s) {
super(s);
}
}
private WhiteBox() {}
private static final WhiteBox instance = new WhiteBox();
private static native void registerNatives();
/**
* Returns the singleton WhiteBox instance.
*
* The returned WhiteBox object should be carefully guarded
* by the caller, since it can be used to read and write data
* at arbitrary memory addresses. It must never be passed to
* untrusted code.
*/
public synchronized static WhiteBox getWhiteBox() {
SecurityManager sm = System.getSecurityManager();
if (sm != null) {
sm.checkPermission(new WhiteBoxPermission("getInstance"));
}
return instance;
}
static {
registerNatives();
}
// Get the maximum heap size supporting COOPs
public native long getCompressedOopsMaxHeapSize();
// Arguments
public native void printHeapSizes();
// Memory
private native long getObjectAddress0(Object o);
public long getObjectAddress(Object o) {
Objects.requireNonNull(o);
return getObjectAddress0(o);
}
public native int getHeapOopSize();
public native int getVMPageSize();
public native long getVMAllocationGranularity();
public native long getVMLargePageSize();
public native long getHeapSpaceAlignment();
public native long getHeapAlignment();
private native boolean isObjectInOldGen0(Object o);
public boolean isObjectInOldGen(Object o) {
Objects.requireNonNull(o);
return isObjectInOldGen0(o);
}
private native long getObjectSize0(Object o);
public long getObjectSize(Object o) {
Objects.requireNonNull(o);
return getObjectSize0(o);
}
// Runtime
// Make sure class name is in the correct format
public boolean isClassAlive(String name) {
return isClassAlive0(name.replace('.', '/'));
}
private native boolean isClassAlive0(String name);
public native int getSymbolRefcount(String name);
private native boolean isMonitorInflated0(Object obj);
public boolean isMonitorInflated(Object obj) {
Objects.requireNonNull(obj);
return isMonitorInflated0(obj);
}
public native void forceSafepoint();
private native long getConstantPool0(Class<?> aClass);
public long getConstantPool(Class<?> aClass) {
Objects.requireNonNull(aClass);
return getConstantPool0(aClass);
}
private native int getConstantPoolCacheIndexTag0();
public int getConstantPoolCacheIndexTag() {
return getConstantPoolCacheIndexTag0();
}
private native int getConstantPoolCacheLength0(Class<?> aClass);
public int getConstantPoolCacheLength(Class<?> aClass) {
Objects.requireNonNull(aClass);
return getConstantPoolCacheLength0(aClass);
}
private native int remapInstructionOperandFromCPCache0(Class<?> aClass, int index);
public int remapInstructionOperandFromCPCache(Class<?> aClass, int index) {
Objects.requireNonNull(aClass);
return remapInstructionOperandFromCPCache0(aClass, index);
}
private native int encodeConstantPoolIndyIndex0(int index);
public int encodeConstantPoolIndyIndex(int index) {
return encodeConstantPoolIndyIndex0(index);
}
// JVMTI
private native void addToBootstrapClassLoaderSearch0(String segment);
public void addToBootstrapClassLoaderSearch(String segment){
Objects.requireNonNull(segment);
addToBootstrapClassLoaderSearch0(segment);
}
private native void addToSystemClassLoaderSearch0(String segment);
public void addToSystemClassLoaderSearch(String segment) {
Objects.requireNonNull(segment);
addToSystemClassLoaderSearch0(segment);
}
// G1
public native boolean g1InConcurrentMark();
private native boolean g1IsHumongous0(Object o);
public boolean g1IsHumongous(Object o) {
Objects.requireNonNull(o);
return g1IsHumongous0(o);
}
private native boolean g1BelongsToHumongousRegion0(long adr);
public boolean g1BelongsToHumongousRegion(long adr) {
if (adr == 0) {
throw new IllegalArgumentException("adr argument should not be null");
}
return g1BelongsToHumongousRegion0(adr);
}
private native boolean g1BelongsToFreeRegion0(long adr);
public boolean g1BelongsToFreeRegion(long adr) {
if (adr == 0) {
throw new IllegalArgumentException("adr argument should not be null");
}
return g1BelongsToFreeRegion0(adr);
}
public native long g1NumMaxRegions();
public native long g1NumFreeRegions();
public native int g1RegionSize();
public native long dramReservedStart();
public native long dramReservedEnd();
public native long nvdimmReservedStart();
public native long nvdimmReservedEnd();
public native MemoryUsage g1AuxiliaryMemoryUsage();
private native Object[] parseCommandLine0(String commandline, char delim, DiagnosticCommand[] args);
public Object[] parseCommandLine(String commandline, char delim, DiagnosticCommand[] args) {
Objects.requireNonNull(args);
return parseCommandLine0(commandline, delim, args);
}
// Parallel GC
public native long psVirtualSpaceAlignment();
public native long psHeapGenerationAlignment();
/**
* Enumerates old regions with liveness less than specified and produces some statistics
* @param liveness percent of region's liveness (live_objects / total_region_size * 100).
* @return long[3] array where long[0] - total count of old regions
* long[1] - total memory of old regions
* long[2] - lowest estimation of total memory of old regions to be freed (non-full
* regions are not included)
*/
public native long[] g1GetMixedGCInfo(int liveness);
// NMT
public native long NMTMalloc(long size);
public native void NMTFree(long mem);
public native long NMTReserveMemory(long size);
public native long NMTAttemptReserveMemoryAt(long addr, long size);
public native void NMTCommitMemory(long addr, long size);
public native void NMTUncommitMemory(long addr, long size);
public native void NMTReleaseMemory(long addr, long size);
public native long NMTMallocWithPseudoStack(long size, int index);
public native boolean NMTChangeTrackingLevel();
public native int NMTGetHashSize();
// Compiler
public native int matchesMethod(Executable method, String pattern);
public native int matchesInline(Executable method, String pattern);
public native boolean shouldPrintAssembly(Executable method, int comp_level);
public native int deoptimizeFrames(boolean makeNotEntrant);
public native void deoptimizeAll();
public boolean isMethodCompiled(Executable method) {
return isMethodCompiled(method, false /*not osr*/);
}
private native boolean isMethodCompiled0(Executable method, boolean isOsr);
public boolean isMethodCompiled(Executable method, boolean isOsr){
Objects.requireNonNull(method);
return isMethodCompiled0(method, isOsr);
}
public boolean isMethodCompilable(Executable method) {
return isMethodCompilable(method, -2 /*any*/);
}
public boolean isMethodCompilable(Executable method, int compLevel) {
return isMethodCompilable(method, compLevel, false /*not osr*/);
}
private native boolean isMethodCompilable0(Executable method, int compLevel, boolean isOsr);
public boolean isMethodCompilable(Executable method, int compLevel, boolean isOsr) {
Objects.requireNonNull(method);
return isMethodCompilable0(method, compLevel, isOsr);
}
private native boolean isMethodQueuedForCompilation0(Executable method);
public boolean isMethodQueuedForCompilation(Executable method) {
Objects.requireNonNull(method);
return isMethodQueuedForCompilation0(method);
}
// Determine if the compiler corresponding to the compilation level 'compLevel'
// and to the compilation context 'compilation_context' provides an intrinsic
// for the method 'method'. An intrinsic is available for method 'method' if:
// - the intrinsic is enabled (by using the appropriate command-line flag) and
// - the platform on which the VM is running provides the instructions necessary
// for the compiler to generate the intrinsic code.
//
// The compilation context is related to using the DisableIntrinsic flag on a
// per-method level, see hotspot/src/share/vm/compiler/abstractCompiler.hpp
// for more details.
public boolean isIntrinsicAvailable(Executable method,
Executable compilationContext,
int compLevel) {
Objects.requireNonNull(method);
return isIntrinsicAvailable0(method, compilationContext, compLevel);
}
// If usage of the DisableIntrinsic flag is not expected (or the usage can be ignored),
// use the below method that does not require the compilation context as argument.
public boolean isIntrinsicAvailable(Executable method, int compLevel) {
return isIntrinsicAvailable(method, null, compLevel);
}
private native boolean isIntrinsicAvailable0(Executable method,
Executable compilationContext,
int compLevel);
public int deoptimizeMethod(Executable method) {
return deoptimizeMethod(method, false /*not osr*/);
}
private native int deoptimizeMethod0(Executable method, boolean isOsr);
public int deoptimizeMethod(Executable method, boolean isOsr) {
Objects.requireNonNull(method);
return deoptimizeMethod0(method, isOsr);
}
public void makeMethodNotCompilable(Executable method) {
makeMethodNotCompilable(method, -2 /*any*/);
}
public void makeMethodNotCompilable(Executable method, int compLevel) {
makeMethodNotCompilable(method, compLevel, false /*not osr*/);
}
private native void makeMethodNotCompilable0(Executable method, int compLevel, boolean isOsr);
public void makeMethodNotCompilable(Executable method, int compLevel, boolean isOsr) {
Objects.requireNonNull(method);
makeMethodNotCompilable0(method, compLevel, isOsr);
}
public int getMethodCompilationLevel(Executable method) {
return getMethodCompilationLevel(method, false /*not ost*/);
}
private native int getMethodCompilationLevel0(Executable method, boolean isOsr);
public int getMethodCompilationLevel(Executable method, boolean isOsr) {
Objects.requireNonNull(method);
return getMethodCompilationLevel0(method, isOsr);
}
private native boolean testSetDontInlineMethod0(Executable method, boolean value);
public boolean testSetDontInlineMethod(Executable method, boolean value) {
Objects.requireNonNull(method);
return testSetDontInlineMethod0(method, value);
}
public int getCompileQueuesSize() {
return getCompileQueueSize(-2 /*any*/);
}
public native int getCompileQueueSize(int compLevel);
private native boolean testSetForceInlineMethod0(Executable method, boolean value);
public boolean testSetForceInlineMethod(Executable method, boolean value) {
Objects.requireNonNull(method);
return testSetForceInlineMethod0(method, value);
}
public boolean enqueueMethodForCompilation(Executable method, int compLevel) {
return enqueueMethodForCompilation(method, compLevel, -1 /*InvocationEntryBci*/);
}
private native boolean enqueueMethodForCompilation0(Executable method, int compLevel, int entry_bci);
public boolean enqueueMethodForCompilation(Executable method, int compLevel, int entry_bci) {
Objects.requireNonNull(method);
return enqueueMethodForCompilation0(method, compLevel, entry_bci);
}
private native boolean enqueueInitializerForCompilation0(Class<?> aClass, int compLevel);
public boolean enqueueInitializerForCompilation(Class<?> aClass, int compLevel) {
Objects.requireNonNull(aClass);
return enqueueInitializerForCompilation0(aClass, compLevel);
}
private native void clearMethodState0(Executable method);
public void clearMethodState(Executable method) {
Objects.requireNonNull(method);
clearMethodState0(method);
}
public native void lockCompilation();
public native void unlockCompilation();
private native int getMethodEntryBci0(Executable method);
public int getMethodEntryBci(Executable method) {
Objects.requireNonNull(method);
return getMethodEntryBci0(method);
}
private native Object[] getNMethod0(Executable method, boolean isOsr);
public Object[] getNMethod(Executable method, boolean isOsr) {
Objects.requireNonNull(method);
return getNMethod0(method, isOsr);
}
public native long allocateCodeBlob(int size, int type);
public long allocateCodeBlob(long size, int type) {
int intSize = (int) size;
if ((long) intSize != size || size < 0) {
throw new IllegalArgumentException(
"size argument has illegal value " + size);
}
return allocateCodeBlob( intSize, type);
}
public native void freeCodeBlob(long addr);
public native void forceNMethodSweep();
public native Object[] getCodeHeapEntries(int type);
public native int getCompilationActivityMode();
private native long getMethodData0(Executable method);
public long getMethodData(Executable method) {
Objects.requireNonNull(method);
return getMethodData0(method);
}
public native Object[] getCodeBlob(long addr);
private native void clearInlineCaches0(boolean preserve_static_stubs);
public void clearInlineCaches() {
clearInlineCaches0(false);
}
public void clearInlineCaches(boolean preserve_static_stubs) {
clearInlineCaches0(preserve_static_stubs);
}
// Intered strings
public native boolean isInStringTable(String str);
// Memory
public native void readReservedMemory();
public native long allocateMetaspace(ClassLoader classLoader, long size);
public native void freeMetaspace(ClassLoader classLoader, long addr, long size);
public native long incMetaspaceCapacityUntilGC(long increment);
public native long metaspaceCapacityUntilGC();
public native boolean metaspaceShouldConcurrentCollect();
public native long metaspaceReserveAlignment();
// Don't use these methods directly
// Use sun.hotspot.gc.GC class instead.
public native boolean isGCSupported(int name);
public native boolean isGCSelected(int name);
public native boolean isGCSelectedErgonomically();
// Force Young GC
public native void youngGC();
// Force Full GC
public native void fullGC();
// Returns true if the current GC supports control of its concurrent
// phase via requestConcurrentGCPhase(). If false, a request will
// always fail.
public native boolean supportsConcurrentGCPhaseControl();
// Returns an array of concurrent phase names provided by this
// collector. These are the names recognized by
// requestConcurrentGCPhase().
public native String[] getConcurrentGCPhases();
// Attempt to put the collector into the indicated concurrent phase,
// and attempt to remain in that state until a new request is made.
//
// Returns immediately if already in the requested phase.
// Otherwise, waits until the phase is reached.
//
// Throws IllegalStateException if unsupported by the current collector.
// Throws NullPointerException if phase is null.
// Throws IllegalArgumentException if phase is not valid for the current collector.
public void requestConcurrentGCPhase(String phase) {
if (!supportsConcurrentGCPhaseControl()) {
throw new IllegalStateException("Concurrent GC phase control not supported");
} else if (phase == null) {
throw new NullPointerException("null phase");
} else if (!requestConcurrentGCPhase0(phase)) {
throw new IllegalArgumentException("Unknown concurrent GC phase: " + phase);
}
}
// Helper for requestConcurrentGCPhase(). Returns true if request
// succeeded, false if the phase is invalid.
private native boolean requestConcurrentGCPhase0(String phase);
// Method tries to start concurrent mark cycle.
// It returns false if CM Thread is always in concurrent cycle.
public native boolean g1StartConcMarkCycle();
// Tests on ReservedSpace/VirtualSpace classes
public native int stressVirtualSpaceResize(long reservedSpaceSize, long magnitude, long iterations);
public native void runMemoryUnitTests();
public native void readFromNoaccessArea();
public native long getThreadStackSize();
public native long getThreadRemainingStackSize();
// CPU features
public native String getCPUFeatures();
// VM flags
public native boolean isConstantVMFlag(String name);
public native boolean isLockedVMFlag(String name);
public native void setBooleanVMFlag(String name, boolean value);
public native void setIntVMFlag(String name, long value);
public native void setUintVMFlag(String name, long value);
public native void setIntxVMFlag(String name, long value);
public native void setUintxVMFlag(String name, long value);
public native void setUint64VMFlag(String name, long value);
public native void setSizeTVMFlag(String name, long value);
public native void setStringVMFlag(String name, String value);
public native void setDoubleVMFlag(String name, double value);
public native Boolean getBooleanVMFlag(String name);
public native Long getIntVMFlag(String name);
public native Long getUintVMFlag(String name);
public native Long getIntxVMFlag(String name);
public native Long getUintxVMFlag(String name);
public native Long getUint64VMFlag(String name);
public native Long getSizeTVMFlag(String name);
public native String getStringVMFlag(String name);
public native Double getDoubleVMFlag(String name);
private final List<Function<String,Object>> flagsGetters = Arrays.asList(
this::getBooleanVMFlag, this::getIntVMFlag, this::getUintVMFlag,
this::getIntxVMFlag, this::getUintxVMFlag, this::getUint64VMFlag,
this::getSizeTVMFlag, this::getStringVMFlag, this::getDoubleVMFlag);
public Object getVMFlag(String name) {
return flagsGetters.stream()
.map(f -> f.apply(name))
.filter(x -> x != null)
.findAny()
.orElse(null);
}
// Jigsaw
public native void DefineModule(Object module, boolean is_open, String version,
String location, Object[] packages);
public native void AddModuleExports(Object from_module, String pkg, Object to_module);
public native void AddReadsModule(Object from_module, Object source_module);
public native void AddModuleExportsToAllUnnamed(Object module, String pkg);
public native void AddModuleExportsToAll(Object module, String pkg);
public native int getOffsetForName0(String name);
public int getOffsetForName(String name) throws Exception {
int offset = getOffsetForName0(name);
if (offset == -1) {
throw new RuntimeException(name + " not found");
}
return offset;
}
public native Boolean getMethodBooleanOption(Executable method, String name);
public native Long getMethodIntxOption(Executable method, String name);
public native Long getMethodUintxOption(Executable method, String name);
public native Double getMethodDoubleOption(Executable method, String name);
public native String getMethodStringOption(Executable method, String name);
private final List<BiFunction<Executable,String,Object>> methodOptionGetters
= Arrays.asList(this::getMethodBooleanOption, this::getMethodIntxOption,
this::getMethodUintxOption, this::getMethodDoubleOption,
this::getMethodStringOption);
public Object getMethodOption(Executable method, String name) {
return methodOptionGetters.stream()
.map(f -> f.apply(method, name))
.filter(x -> x != null)
.findAny()
.orElse(null);
}
// Safepoint Checking
public native void assertMatchingSafepointCalls(boolean mutexSafepointValue, boolean attemptedNoSafepointValue);
// Sharing & archiving
public native String getDefaultArchivePath();
public native boolean isSharingEnabled();
public native boolean isShared(Object o);
public native boolean isSharedClass(Class<?> c);
public native boolean areSharedStringsIgnored();
public native boolean isCDSIncludedInVmBuild();
public native boolean isJFRIncludedInVmBuild();
public native boolean isJavaHeapArchiveSupported();
public native Object getResolvedReferences(Class<?> c);
public native boolean areOpenArchiveHeapObjectsMapped();
// Compiler Directive
public native int addCompilerDirective(String compDirect);
public native void removeCompilerDirective(int count);
// Handshakes
public native int handshakeWalkStack(Thread t, boolean all_threads);
// Returns true on linux if library has the noexecstack flag set.
public native boolean checkLibSpecifiesNoexecstack(String libfilename);
// Container testing
public native boolean isContainerized();
public native void printOsInfo();
// Decoder
public native void disableElfSectionCache();
// Resolved Method Table
public native int resolvedMethodRemovedCount();
// Protection Domain Table
public native int protectionDomainRemovedCount();
}