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UseDefInfo.cpp
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UseDefInfo.cpp
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/*******************************************************************************
* Copyright (c) 2000, 2021 IBM Corp. and others
*
* This program and the accompanying materials are made available under
* the terms of the Eclipse Public License 2.0 which accompanies this
* distribution and is available at http://eclipse.org/legal/epl-2.0
* or the Apache License, Version 2.0 which accompanies this distribution
* and is available at https://www.apache.org/licenses/LICENSE-2.0.
*
* This Source Code may also be made available under the following Secondary
* Licenses when the conditions for such availability set forth in the
* Eclipse Public License, v. 2.0 are satisfied: GNU General Public License,
* version 2 with the GNU Classpath Exception [1] and GNU General Public
* License, version 2 with the OpenJDK Assembly Exception [2].
*
* [1] https://www.gnu.org/software/classpath/license.html
* [2] http://openjdk.java.net/legal/assembly-exception.html
*
* SPDX-License-Identifier: EPL-2.0 OR Apache-2.0 OR GPL-2.0 WITH Classpath-exception-2.0 OR LicenseRef-GPL-2.0 WITH Assembly-exception
*******************************************************************************/
#include "optimizer/UseDefInfo.hpp"
#include <limits.h>
#include <stddef.h>
#include <stdint.h>
#include "codegen/CodeGenerator.hpp"
#include "env/FrontEnd.hpp"
#include "compile/Compilation.hpp"
#include "compile/Method.hpp"
#include "compile/SymbolReferenceTable.hpp"
#include "control/Options.hpp"
#include "control/Options_inlines.hpp"
#include "cs2/allocator.h"
#include "cs2/bitvectr.h"
#include "cs2/hashtab.h"
#include "cs2/sparsrbit.h"
#include "env/TRMemory.hpp"
#include "il/AliasSetInterface.hpp"
#include "il/Block.hpp"
#include "il/DataTypes.hpp"
#include "il/ILOpCodes.hpp"
#include "il/ILOps.hpp"
#include "il/MethodSymbol.hpp"
#include "il/Node.hpp"
#include "il/Node_inlines.hpp"
#include "il/ResolvedMethodSymbol.hpp"
#include "il/StaticSymbol.hpp"
#include "il/Symbol.hpp"
#include "il/SymbolReference.hpp"
#include "il/TreeTop.hpp"
#include "il/TreeTop_inlines.hpp"
#include "infra/Assert.hpp"
#include "infra/BitVector.hpp"
#include "infra/Cfg.hpp"
#include "infra/List.hpp"
#include "infra/CfgNode.hpp"
#include "optimizer/CallInfo.hpp"
#include "optimizer/Optimizer.hpp"
#include "optimizer/DataFlowAnalysis.hpp"
#include "optimizer/ValueNumberInfo.hpp"
#define MAX_EXPANDED_DEF_OR_USE_NODES (65000)
#define MAX_DEF_BY_USE_NODES_FOR_LOW_OPT (10000000)
#define MAX_DEF_BY_USE_NODES_FOR_HIGH_OPT (INT_MAX/100-1) // will be multiplied by 100 for big methods
#define MAX_SYMBOLS USHRT_MAX
#define MAX_EXPANDED_TOTAL_NODES USHRT_MAX
#define SIDE_TABLE_LIMIT (USHRT_MAX)
#define REACHING_DEFS_LIMIT (25000000) // 25 Million
/**
* Constructs TR_UseDefInfo instance. Note that this should not be called directly.
* Instead construction is handled by OMR::Optimizer::createUseDefInfo() method.
*
* @param cfg The compilation instance
* @param requiresGlobals
* @param prefersGlobals
* @param loadsShouldBeDefs
* @param cannotOmitTrivialDefs
* @param conversionRegsOnly
* @param doCompletion
* @param callsShouldBeUses Enables inclusion of calls as uses so that the alias analysis can detect
* when local (stack) variable has been aliased by a function call.
* A value of false is fine for Java like languages where
* local (stack) variables cannot be passed by reference to function calls
* and hence cannot be aliased. However for C like languages this flag should be
* set to true.
*/
TR_UseDefInfo::TR_UseDefInfo(TR::Compilation *comp, TR::CFG *cfg, TR::Optimizer *optimizer,
bool requiresGlobals, bool prefersGlobals, bool loadsShouldBeDefs, bool cannotOmitTrivialDefs, bool conversionRegsOnly,
bool doCompletion, bool callsShouldBeUses)
: _region(comp->trMemory()->heapMemoryRegion()),
_compilation(comp),
_optimizer(optimizer),
_atoms(0, std::make_pair<TR::Node *, TR::TreeTop *>(NULL, NULL), _region),
_useDefForMemorySymbols(false),
_useDefInfo(0, TR_UseDefInfo::BitVector(comp->allocator()), _region),
_isUseDefInfoValid(false),
_infoCache(_region),
_EMPTY(comp->allocator()),
_useDerefDefInfo(0, static_cast<const BitVector *>(NULL), _region),
_defUseInfo(0, TR_UseDefInfo::BitVector(comp->allocator()), _region),
_loadDefUseInfo(0, TR_UseDefInfo::BitVector(comp->allocator()), _region),
_tempsOnly(false),
_trace(comp->getOption(TR_TraceUseDefs)),
_hasLoadsAsDefs(loadsShouldBeDefs),
_hasCallsAsUses(callsShouldBeUses),
_useDefs(0, _region),
_numMemorySymbols(0),
_valueNumbersToMemorySymbolsMap(0, static_cast<MemorySymbolList *>(NULL), _region),
_sideTableToSymRefNumMap(comp->getSymRefCount(), _region),
_cfg(cfg),
_valueNumberInfo(NULL)
{
if (doCompletion)
prepareUseDefInfo(requiresGlobals, prefersGlobals, cannotOmitTrivialDefs, conversionRegsOnly);
}
void TR_UseDefInfo::prepareUseDefInfo(bool requiresGlobals, bool prefersGlobals, bool cannotOmitTrivialDefs, bool conversionRegsOnly)
{
LexicalTimer tlex("useDefInfo", comp()->phaseTimer());
TR_UseDefInfo::AuxiliaryData aux(
comp()->getSymRefCount(),
comp()->getNodeCount(),
comp()->trMemory()->heapMemoryRegion(),
comp()->allocator("UseDefAux")
);
int32_t i;
dumpOptDetails(comp(), " (Building use/def info)\n");
if (trace())
{
traceMsg(comp(), "started initialization of use/def info\n");
comp()->dumpMethodTrees("Pre Use Def Trees");
}
bool canBuild = false;
_hasCallsAsUses = false;
_uniqueIndexForDefsOnEntry = false;
if (comp()->cg()->getGRACompleted() && conversionRegsOnly)
_useDefForRegs = true;
else
_useDefForRegs = false;
TR::SymbolReferenceTable *symRefTab = comp()->getSymRefTab();
int32_t numSymRefs = comp()->getSymRefCount();
if (_hasLoadsAsDefs &&
!cannotOmitTrivialDefs &&
(comp()->getMethodHotness() < hot))
{
for (int32_t j = 0; j < numSymRefs; j++)
{
if (symRefTab->getSymRef(j) &&
symRefTab->getSymRef(j)->getSymbol()->isAutoOrParm())
{
aux._onceReadSymbolsIndices[j].GrowTo(comp()->getNodeCount()); /* no effect for sparse bit vectors, except to make non-null */
}
}
}
if (_hasLoadsAsDefs &&
!cannotOmitTrivialDefs)
{
for (int32_t j = 0; j < numSymRefs; j++)
{
if (symRefTab->getSymRef(j) &&
symRefTab->getSymRef(j)->getSymbol()->isAutoOrParm())
{
aux._onceWrittenSymbolsIndices[j].GrowTo(comp()->getNodeCount()); /* no effect for sparse bit vectors, except to make non-null */
}
}
}
aux._neverWrittenSymbols.setAll(numSymRefs);
aux._neverReadSymbols.setAll(numSymRefs);
aux._neverReferencedSymbols.setAll(numSymRefs);
comp()->incVisitCount();
TR::TreeTop *treeTop;
for (treeTop = comp()->getStartTree(); treeTop != NULL; treeTop = treeTop->getNextTreeTop())
findTrivialSymbolsToExclude(treeTop->getNode(), treeTop, aux);
if (trace())
{
//int32_t j;
//for (j=0;j<numSymRefs;j++)
// {
// if (_onceWrittenSymbols[j])
// dumpOptDetails(comp(), "Printing once written sym %d at node %p\n", j, _onceWrittenSymbols[j]->getNode());
// }
}
if (requiresGlobals || prefersGlobals)
{
if (!comp()->getOption(TR_DisableUseDefForShadows))
_useDefForMemorySymbols = true;
}
if (_useDefForMemorySymbols)
{
// TODO: This should be a member of TR_UseDefInfo::AuxiliaryData, and discarded when aux is discarded
// but to do this TR_ValueNumberInfo should be converted to not be dynamically allocated
// Also clean up deletes for dynamic allocation
_valueNumberInfo = optimizer()->createValueNumberInfo(false, false, true);
buildValueNumbersToMemorySymbolsMap();
}
if (requiresGlobals || prefersGlobals)
{
_indexFields = true;
_indexStatics = true;
canBuild = indexSymbolsAndNodes(aux);
// first try to exclude registers
if (!canBuild &&
_useDefForRegs)
{
_useDefForRegs = false;
canBuild = indexSymbolsAndNodes(aux);
}
if (requiresGlobals && !canBuild)
{
invalidateUseDefInfo();
optimizer()->setCantBuildGlobalsUseDefInfo(true);
if (trace())
traceMsg(comp(),"Use/Def info: cannot build global use/def info as it failed in indexSymbolsAndNodes\n");
return;
}
}
if (prefersGlobals && !canBuild)
{
_indexFields = false;
canBuild = indexSymbolsAndNodes(aux);
}
if (!canBuild)
{
_indexFields = false;
_indexStatics = false;
canBuild = indexSymbolsAndNodes(aux);
}
if (!canBuild)
{
invalidateUseDefInfo();
optimizer()->setCantBuildGlobalsUseDefInfo(true);
optimizer()->setCantBuildLocalsUseDefInfo(true);
if (trace())
traceMsg(comp(),"Use/Def info: cannot build global nor local use/def info as it failed in indexSymbolsAndNodes\n");
return;
}
// Adjust the use/def index for each node now that the sizes are known.
// There is still potential for index overflow when the adjustment is done.
//
comp()->incVisitCount();
TR::Block *block = NULL;
for (TR::TreeTop * treeTop = comp()->getStartTree(); treeTop != NULL; treeTop = treeTop->getNextTreeTop())
{
if (treeTop->getNode()->getOpCodeValue() == TR::BBStart)
{
block = treeTop->getNode()->getBlock();
}
if (!assignAdjustedNodeIndex(block, treeTop->getNode(), NULL, treeTop, aux))
{
invalidateUseDefInfo();
optimizer()->setCantBuildGlobalsUseDefInfo(true);
optimizer()->setCantBuildLocalsUseDefInfo(true);
return;
}
}
if (trace())
{
traceMsg(comp(), "Has loads as defs = %d\n", _hasLoadsAsDefs);
traceMsg(comp(), "Number of symbols = %d\n", _numSymbols);
traceMsg(comp(), "Number of memory symbols = %d\n", _numMemorySymbols);
traceMsg(comp(), "Number of statics and fields = %d\n", _numStaticsAndFields);
traceMsg(comp(), "Total nodes for use/def info = %d\n", getTotalNodes());
traceMsg(comp(), " Number of defOnly nodes = %d\n", _numDefOnlyNodes);
traceMsg(comp(), " Number of defUse nodes = %d\n", _numDefUseNodes);
traceMsg(comp(), " Number of useOnly nodes = %d\n", _numUseOnlyNodes);
traceMsg(comp(), "Total nodes for reaching defs = %d\n", getExpandedTotalNodes());
traceMsg(comp(), " Number of defOnly nodes = %d\n", _numExpandedDefOnlyNodes);
traceMsg(comp(), " Number of defUse nodes = %d\n", _numExpandedDefUseNodes);
traceMsg(comp(), " Number of useOnly nodes = %d\n", _numExpandedUseOnlyNodes);
traceMsg(comp(), " Number of defs on entry = %d\n", _numDefsOnEntry);
}
_atoms.resize(getTotalNodes());
_defsChecklist = new (_region) TR_BitVector(getTotalNodes(), _region);
// traceMsg(comp(), "Growing useDefInfo to %d\n",getNumUseNodes());
_useDefInfo.resize(getNumUseNodes(), TR_UseDefInfo::BitVector(comp()->allocator()));
// for (i = getNumUseNodes()-1; i >= 0; --i)
// _useDefInfo[i].GrowTo(getNumDefNodes());
_isUseDefInfoValid = true;
int numRegisters = _useDefForRegs ? comp()->cg()->getNumberOfGlobalRegisters() : 0;
aux._defsForSymbol.resize(_numSymbols + numRegisters, NULL);
for (i = 0; i < _numSymbols + numRegisters; ++i)
aux._defsForSymbol[i] = new (aux._region) TR_BitVector(aux._region);
// Initialize the array with definitions from method entry
//
for (i = 0; i < _numDefsOnEntry; ++i)
{
int32_t j;
if (i < (_numDefsOnEntry - numRegisters))
j = i;
else
j = _numSymbols + (i - (_numDefsOnEntry - numRegisters));
aux._defsForSymbol[j]->set(i);
}
aux._sideTableToUseDefMap.resize(getExpandedTotalNodes());
int32_t expandedNodeArraySize = getExpandedTotalNodes() * sizeof(TR::Node*);
aux._expandedAtoms.resize(expandedNodeArraySize, std::make_pair<TR::Node*, TR::TreeTop*>(NULL, NULL));
fillInDataStructures(aux);
// Flatten the info.. keep the node around for uses - and the treetop around for defs
//
_useDefs.resize(getTotalNodes());
for (int32_t k = 0; k < getTotalNodes(); ++k)
{
std::pair<TR::Node *, TR::TreeTop *> &atom = _atoms[k];
TR::Node *node = atom.first;
if (!node) continue;
int32_t index = node->getUseDefIndex();
if (isDefIndex(index) && !isUseIndex(index))
_useDefs[k] = TR_UseDef(atom.second);
else
_useDefs[k] = TR_UseDef(node);
}
if (trace())
traceMsg(comp(), "completed initialization of use/def info\n\n");
// virtually complete use/def info with reaching definitions analysis
performAnalysis(aux);
if (_valueNumberInfo)
{
delete _valueNumberInfo;
_valueNumberInfo = NULL;
}
}
void TR_UseDefInfo::invalidateUseDefInfo()
{
_isUseDefInfoValid = false;
_useDefInfo.clear();
_defUseInfo.clear();
_loadDefUseInfo.clear();
if (_valueNumberInfo)
{
delete _valueNumberInfo;
_valueNumberInfo = NULL;
}
return;
}
bool TR_UseDefInfo::performAnalysis(AuxiliaryData &aux)
{
if (!_isUseDefInfoValid)
//use-def info hasn't been successfully generated so performing reaching definition analysis is not possible
return false;
if (trace())
traceMsg(comp(), "started reaching definition analysis for use/def\n\n");
if (_numNonTrivialSymbols > 0)
{
bool succeeded = true;
{
TR_ReachingDefinitions rd(comp(), _cfg, optimizer(), this, aux, trace());
succeeded = _runReachingDefinitions(rd, aux);
}
if (!succeeded)
{
return false;
}
}
else
{
processReachingDefinition(NULL, aux);
}
if (trace())
traceMsg(comp(), "completed reaching definition analysis for use/def\n\n");
return true;
}
bool TR_UseDefInfo::_runReachingDefinitions(TR_ReachingDefinitions& reachingDefinitions,
AuxiliaryData &aux)
{
// stack memory is prohibited in UseDefInfo, but here we have to use it as reachingDefinitions use stack memory for _blockAnalysisInfo
TR::StackMemoryRegion stackMemoryRegion(*comp()->trMemory());
reachingDefinitions.perform();
bool succeeded = reachingDefinitions._blockAnalysisInfo != NULL;
if (!succeeded)
{
invalidateUseDefInfo();
if (trace())
traceMsg(comp(), "Method too complex to perform reaching defs, use/def info not built\n");
}
else
{
// Build use/def information from the bit vector information from reaching defs
//
LexicalTimer tlex2("useDefInfo_buildUseDefs", comp()->phaseTimer());
processReachingDefinition(reachingDefinitions._blockAnalysisInfo, aux);
}
return succeeded;
}
void TR_UseDefInfo::setVolatileSymbolsIndexAndRecurse(TR::BitVector &volatileSymbols, int32_t symRefNum)
{
TR::SymbolReference* symRef = comp()->getSymRefTab()->getSymRef(symRefNum);
if (!symRef || !symRef->getSymbol())
return;
if(volatileSymbols[symRef->getReferenceNumber()]) //already set, do not need to recurse.
return;
// traceMsg(comp(), "JIAG, setting volatile Symbols for symref %d.\n",symRefNum);
volatileSymbols[symRefNum] = true;
TR::SparseBitVector aliases(comp()->allocator());
symRef->getUseDefAliases().getAliases(aliases);
symRef->getUseonlyAliases().getAliasesAndUnionWith(aliases);
TR::SparseBitVector::Cursor aliasesCursor(aliases);
for (aliasesCursor.SetToFirstOne(); aliasesCursor.Valid(); aliasesCursor.SetToNextOne())
{
TR::SymbolReference *aliasedSymRef = comp()->getSymRefTab()->getSymRef(aliasesCursor);
if (!aliasedSymRef || !aliasedSymRef->getSymbol())
continue;
setVolatileSymbolsIndexAndRecurse(volatileSymbols,aliasedSymRef->getReferenceNumber());
}
}
void TR_UseDefInfo::findAndPopulateVolatileSymbolsIndex(TR::BitVector &volatileSymbols)
{
// traceMsg(comp(), "In findAndPopulateVolatileSymbolsIndex\n");
for (int32_t symRefNumber = comp()->getSymRefTab()->getIndexOfFirstSymRef(); unsigned(symRefNumber) < comp()->getSymRefCount(); symRefNumber++)
{
// traceMsg(comp(), "Considering symRef %d: ",symRefNumber);
TR::SymbolReference* symRef = comp()->getSymRefTab()->getSymRef(symRefNumber);
if (!symRef || !symRef->getSymbol())
continue;
if (symRef->getSymbol()->isVolatile())
{
// traceMsg(comp(), "it is volatile");
setVolatileSymbolsIndexAndRecurse(volatileSymbols, symRefNumber);
}
// traceMsg(comp(), "\n");
}
}
void TR_UseDefInfo::fillInDataStructures(AuxiliaryData &aux)
{
TR::SymbolReferenceTable *symRefTab = comp()->getSymRefTab();
// Fill in the data structures
//
comp()->incVisitCount();
TR::Block * block = NULL;
TR::SparseBitVector expandedLIndexes(comp()->allocator()); //expanded localIndex for variables defined by function
for (TR::TreeTop* treeTop = comp()->getStartTree(); treeTop != NULL; treeTop = treeTop->getNextTreeTop())
{
if (treeTop->getNode()->getOpCodeValue() == TR::BBStart)
{
block = treeTop->getNode()->getBlock();
}
insertData(block, treeTop->getNode(), NULL, treeTop, aux, expandedLIndexes);
}
//If function foo defined variable a, then the expanded localIndex of a related to foo
//must be in defsForSymbol of all functions aliased to a
// Set the bit if defs on entry kill anything
//
if (_uniqueIndexForDefsOnEntry)
{
for (int32_t i = getFirstDefIndex(); i < _numDefsOnEntry; i++)
{
TR::SymbolReference *symRef = symRefTab->getSymRef(_sideTableToSymRefNumMap[i]);
if (!symRef)
continue;
TR::SparseBitVector aliases(comp()->allocator());
symRef->getUseDefAliases().getAliases(aliases);
TR::SparseBitVector::Cursor aliasesCursor(aliases);
for (aliasesCursor.SetToFirstOne(); aliasesCursor.Valid(); aliasesCursor.SetToNextOne())
{
TR::SymbolReference *aliasedSymRef = comp()->getSymRefTab()->getSymRef(aliasesCursor);
if (!aliasedSymRef)
continue;
TR::Symbol *aliasedSym = aliasedSymRef->getSymbol();
if (!aliasedSym || !aliasedSym->isMethod())
continue;
if (aux._neverReferencedSymbols.get(aliasedSymRef->getReferenceNumber()))
continue;
if (excludedGlobals(aliasedSymRef->getSymbol()))
continue;
int32_t j = aliasedSymRef->getSymbol()->getLocalIndex();
if (j == NULL_USEDEF_SYMBOL_INDEX)
continue;
aux._defsForSymbol[j]->set(i);
//traceMsg(comp(),"\n _numDefsOnEntry=%d getNumExpandedDefNodes()=%d j=(u%d s#%d) i=(u%d s#%d)",_numDefsOnEntry, getNumExpandedDefNodes(), j, aliasedSymRef->getReferenceNumber(),i, symRef->getReferenceNumber());
}
}
}
}
bool TR_UseDefInfo::isLoadAddrUse(TR::Node * node)
{
return node->getOpCodeValue() == TR::loadaddr;
}
void TR_UseDefInfo::findTrivialSymbolsToExclude(TR::Node *node, TR::TreeTop *treeTop, AuxiliaryData &aux)
{
if (node->getVisitCount() == comp()->getVisitCount())
return;
node->setVisitCount(comp()->getVisitCount());
int32_t i;
for (i = 0; i < node->getNumChildren(); i++)
findTrivialSymbolsToExclude(node->getChild(i), treeTop, aux);
if (node->getOpCode().hasSymbolReference() &&
aux._neverReferencedSymbols.get(node->getSymbolReference()->getReferenceNumber()))
{
aux._neverReferencedSymbols.reset(node->getSymbolReference()->getReferenceNumber());
}
//if (!node->getOpCode().isStore() &&
// (node->getNumChildren() > 0))
// node = node->getFirstChild();
if (node->getOpCode().isStoreDirect())
{
TR::SymbolReference *symRef = node->getSymbolReference();
int32_t symRefNum = symRef->getReferenceNumber();
if (symRef->getSymbol()->isAutoOrParm())
{
if (!aux._onceReadSymbolsIndices[symRefNum].IsNull())
{
aux._onceReadSymbolsIndices[symRefNum][node->getGlobalIndex()] = true;
if (trace())
traceMsg(comp(), "SETTING node %p symRefNum %d\n", node, symRefNum);
}
if (aux._neverWrittenSymbols.get(symRefNum))
{
aux._neverWrittenSymbols.reset(symRefNum);
if (trace())
traceMsg(comp(), "Resetting write bit %d at node %p\n", symRefNum, node);
if (!aux._onceWrittenSymbolsIndices[symRefNum].IsNull())
{
if (symRef->getSymbol()->isParm())
aux._onceWrittenSymbolsIndices[symRefNum].ClearToNull();
else
aux._onceWrittenSymbolsIndices[symRefNum][node->getGlobalIndex()] = true;
if (trace())
traceMsg(comp(), "Sym ref %d written once at node %p\n", symRefNum, treeTop->getNode());
}
}
else if (!aux._onceWrittenSymbolsIndices[symRefNum].IsNull())
{
aux._onceWrittenSymbolsIndices[symRefNum].ClearToNull();
}
}
}
else if (node->getOpCode().isLoadVarDirect() ||
isLoadAddrUse(node))
{
TR::SymbolReference *symRef = node->getSymbolReference();
int32_t symRefNum = symRef->getReferenceNumber();
if (symRef->getSymbol()->isAutoOrParm())
{
if (aux._neverReadSymbols.get(symRefNum))
{
aux._neverReadSymbols.reset(symRefNum);
aux._loadsBySymRefNum[symRefNum] = node;
if (trace())
traceMsg(comp(), "Resetting read bit %d at node %p\n", symRefNum, node);
}
else if (!aux._onceReadSymbolsIndices[symRefNum].IsNull())
{
TR::Node *prevLoadNode = aux._loadsBySymRefNum[symRefNum];
if ((prevLoadNode->getByteCodeIndex() != node->getByteCodeIndex()) ||
(prevLoadNode->getInlinedSiteIndex() != node->getInlinedSiteIndex()))
{
aux._onceReadSymbolsIndices[symRefNum].ClearToNull();
if (trace())
traceMsg(comp(), "KILLING bit %d at node %p\n", symRefNum, node);
}
}
}
}
}
bool TR_UseDefInfo::isTrivialUseDefNode(TR::Node *node, AuxiliaryData &aux)
{
if (aux._doneTrivialNode.get(node->getGlobalIndex()))
return aux._isTrivialNode.get(node->getGlobalIndex()) != 0;
bool result = isTrivialUseDefNodeImpl(node, aux);
aux._doneTrivialNode.set(node->getGlobalIndex());
if (result)
aux._isTrivialNode.set(node->getGlobalIndex());
return result;
}
bool TR_UseDefInfo::isTrivialUseDefNodeImpl(TR::Node *node, AuxiliaryData &aux)
{
if (node->getOpCode().isStore() &&
node->getSymbol()->isAutoOrParm() &&
node->storedValueIsIrrelevant())
return true;
if (_useDefForRegs &&
(node->getOpCode().isLoadReg() ||
node->getOpCode().isStoreReg()))
return false;
TR::SymbolReference *symRef = node->getSymbolReference();
if (symRef->getSymbol()->isParm())
{
if (!aux._neverWrittenSymbols.get(symRef->getReferenceNumber()))
{
return false;
}
}
if (isTrivialUseDefSymRef(symRef, aux))
return true;
if (_hasLoadsAsDefs && symRef->getSymbol()->isAutoOrParm())
{
if (!aux._onceReadSymbolsIndices[symRef->getReferenceNumber()].IsNull() &&
((node->getOpCode().isLoadVarDirect() ||
isLoadAddrUse(node)) ||
(node->getOpCode().isStoreDirect() &&
aux._onceReadSymbolsIndices[symRef->getReferenceNumber()].ValueAt(node->getGlobalIndex()))))
return true;
}
else if (symRef->getSymbol()->isAutoOrParm() &&
(node->getOpCode().isLoadVarDirect() ||
(isLoadAddrUse(node))))
return true;
if (/* _hasLoadsAsDefs && */symRef->getSymbol()->isAutoOrParm())
{
if (!aux._onceWrittenSymbolsIndices[symRef->getReferenceNumber()].IsNull() &&
((node->getOpCode().isLoadVarDirect() ||
isLoadAddrUse(node)) ||
(node->getOpCode().isStoreDirect() &&
aux._onceWrittenSymbolsIndices[symRef->getReferenceNumber()].ValueAt(node->getGlobalIndex()))))
return true;
}
return false;
}
bool TR_UseDefInfo::isTrivialUseDefSymRef(TR::SymbolReference *symRef, AuxiliaryData &aux)
{
//if (!_hasLoadsAsDefs)
// return false;
int32_t symRefNum = symRef->getReferenceNumber();
if (symRef->getSymbol()->isAutoOrParm())
{
if (symRef->getSymbol()->isParm())
{
if (!aux._neverWrittenSymbols.get(symRefNum))
{
return false;
}
}
if (aux._neverWrittenSymbols.get(symRefNum))
return true;
else if (aux._neverReadSymbols.get(symRefNum))
return true;
}
return false;
}
bool TR_UseDefInfo::isValidAutoOrParm(TR::SymbolReference *symRef)
{
if (!symRef->getSymbol()->isAutoOrParm())
return false;
if (!_tempsOnly)
return true;
TR::BitVector useDefAliases(comp()->allocator());
symRef->getUseDefAliases().getAliases(useDefAliases);
TR::BitVector useOnlyAliases(comp()->allocator());
symRef->getUseonlyAliases().getAliases(useOnlyAliases);
return (useDefAliases.PopulationCount() == 1 &&
useOnlyAliases.PopulationCount() == 1);
}
bool TR_UseDefInfo::excludedGlobals(TR::Symbol *sym)
{
if (sym->isStatic() && (sym->isConst() || sym->castToStaticSymbol()->isConstObjectRef()))
return true;
if ((sym->isStatic() || sym->isMethodMetaData()) && !_indexStatics)
return true;
else if (sym->isShadow() && !_indexFields)
return true;
else
return false;
}
void TR_UseDefInfo::buildValueNumbersToMemorySymbolsMap()
{
LexicalTimer tlex("useDefInfo_buildValueNosToMSM", comp()->phaseTimer());
_valueNumbersToMemorySymbolsMap.resize(_valueNumberInfo->getNumberOfValues(), NULL);
for (size_t i = 0; i < _valueNumbersToMemorySymbolsMap.size(); ++i)
_valueNumbersToMemorySymbolsMap[i] = new (_region) MemorySymbolList(_region);
comp()->incVisitCount();
_numMemorySymbols = 0;
TR::TreeTop * treeTop;
for (treeTop = comp()->getStartTree(); treeTop; treeTop = treeTop->getNextTreeTop())
{
findMemorySymbols(treeTop->getNode());
}
}
void TR_UseDefInfo::findMemorySymbols(TR::Node *node)
{
vcount_t visitCount = comp()->getVisitCount();
if (visitCount == node->getVisitCount())
return;
node->setVisitCount(visitCount);
// Process children
//
for (int32_t i = 0; i < node->getNumChildren(); i++)
{
findMemorySymbols(node->getChild(i));
}
if ((node->getOpCode().isLoadIndirect() || node->getOpCode().isStoreIndirect()) &&
node->getSymbolReference()->getSymbol()->isShadow() &&
_valueNumberInfo &&
_valueNumberInfo->getNext(node->getFirstChild()) != node->getFirstChild()) // value number is shared with some other node
{
int32_t valueNumber = _valueNumberInfo->getValueNumber(node->getFirstChild());
uint32_t size = static_cast<uint32_t>(node->getSymbolReference()->getSymbol()->getSize());
uint32_t offset = static_cast<uint32_t>(node->getSymbolReference()->getOffset());
bool found = false;
for (auto itr = _valueNumbersToMemorySymbolsMap[valueNumber]->begin(), end = _valueNumbersToMemorySymbolsMap[valueNumber]->end();
itr != end; ++itr)
{
MemorySymbol &memorySymbol = *itr;
if ((memorySymbol._size == size) && (memorySymbol._offset == offset))
{
found = true;
break;
}
}
if (!found)
_valueNumbersToMemorySymbolsMap[valueNumber]->push_front(MemorySymbol(size, offset, _numMemorySymbols++));
if (trace())
traceMsg(comp(), "Node %p has memory symbol index %d (%d:%d:%d)\n", node, _valueNumbersToMemorySymbolsMap[valueNumber]->front()._localIndex, valueNumber, size, offset);
}
}
int32_t TR_UseDefInfo::getMemorySymbolIndex(TR::Node * node)
{
if (!_useDefForMemorySymbols) return -1;
if ((!node->getOpCode().isLoadIndirect() && !node->getOpCode().isStoreIndirect()) ||
!node->getSymbolReference()->getSymbol()->isShadow() ||
_valueNumberInfo->getNext(node->getFirstChild()) == node->getFirstChild())
return -1;
int32_t valueNumber = _valueNumberInfo->getValueNumber(node->getFirstChild());
uint32_t size = static_cast<uint32_t>(node->getSymbolReference()->getSymbol()->getSize());
uint32_t offset = static_cast<uint32_t>(node->getSymbolReference()->getOffset());
for (auto itr = _valueNumbersToMemorySymbolsMap[valueNumber]->begin(), end = _valueNumbersToMemorySymbolsMap[valueNumber]->end();
itr != end; ++itr)
{
MemorySymbol &memorySymbol = *itr;
if ((memorySymbol._size == size) && (memorySymbol._offset == offset))
return memorySymbol._localIndex;
}
TR_ASSERT(false, "Could not find memory symbol index for node %p (%d:%d:%d)", node, valueNumber, size, offset);
return -1;
}
bool TR_UseDefInfo::shouldIndexVolatileSym(TR::SymbolReference*ref, AuxiliaryData &aux)
{
if (! ref->getSymbol()->isVolatile()) //index non-volatiles
return true;
return false;
}
/**
* Find all symbols whose uses and defs are to be tracked and give them a
* local index. This index is used to index into the array of bit vectors
* that show which nodes define which symbols.
*
* At the same time count the number of defs on entry to the method.
*
* Symbol indices are assigned in a particular order as follows:
*
* 0 to (_numStaticsAndFields-1):
* Field, metadata and non-constant static symbols; these are the symbols
* that used to be killed by calls and by unresolved references.
* Currently _numStaticsAndFields is not used since kill sets are based
* on alias sets.
*
* _numStaticsAndFields to _numDefsOnEntry:
* Parameter, local, and constant static symbols; together with the
* previous group these are all the symbols that include the method entry
* as a definition point.
*/
bool TR_UseDefInfo::indexSymbolsAndNodes(AuxiliaryData &aux)
{
LexicalTimer tlex("indexSymbolsAndNodes", comp()->phaseTimer());
if (trace())
{
traceMsg(comp(), "Trying to index nodes with _indexFields = %d, _indexStatics = %d\n", _indexFields, _indexStatics);
}
_numSymbols = _numMemorySymbols;
_numNonTrivialSymbols = 0;
int32_t symRefCount = comp()->getSymRefCount();
TR::SymbolReferenceTable *symRefTab = comp()->getSymRefTab();
TR::SymbolReference *symRef;
TR::Symbol *sym;
int32_t symRefNumber;
if (trace())
{
traceMsg(comp(), "_neverReferencedSymbols[count = %d]: ", aux._neverReferencedSymbols.elementCount());
aux._neverReferencedSymbols.print(comp());
traceMsg(comp(), "\n");
}
TR_BitVector relevantAliases(aux._region);
TR_BitVector methodsAndShadows(aux._region);
TR_BitVector referencedSymRefs(aux._region);
TR_BitVector aliases(aux._region);
for (symRefNumber = symRefTab->getIndexOfFirstSymRef(); symRefNumber < symRefCount; symRefNumber++)
{
LexicalTimer tlex("indexSymbolsAndNodes_refs", comp()->phaseTimer());
symRef = symRefTab->getSymRef(symRefNumber);
if (!symRef || !symRef->getSymbol())
continue;
if (aux._neverReferencedSymbols.get(symRefNumber))
continue;
referencedSymRefs.set(symRefNumber);
if (excludedGlobals(symRef->getSymbol()))
continue;
if (symRef->getSymbol()->isMethod() || symRef->getSymbol()->isRegularShadow())
methodsAndShadows.set(symRefNumber);
else
relevantAliases.set(symRefNumber);
}
TR_BitVectorIterator refIter(referencedSymRefs);
while (refIter.hasMoreElements())
{
LexicalTimer tlex2("indexSymbolsAndNodes_refs", comp()->phaseTimer());
symRefNumber = refIter.getNextElement();
symRef = symRefTab->getSymRef(symRefNumber);
if (symRef)
{
sym = symRef->getSymbol();
// record number of relevant aliases
uint32_t num_aliases = 0;
uint32_t numMethodsAndShadows = 0;
if (symRef->sharesSymbol())
{
symRef->getUseDefAliases().getAliases(aliases);
num_aliases = aliases.commonElementCount(relevantAliases);
numMethodsAndShadows = aliases.commonElementCount(methodsAndShadows);
}
if (num_aliases == 0 && !sym->isMethod())
num_aliases = 1; // alias symbol with itself
if (numMethodsAndShadows != 0)
num_aliases++;
if (symRef->getSymbol()->isShadow())
num_aliases++;
aux._numAliases[symRefNumber] = num_aliases;
if (sym)
{
// Initialize all symbols with null usedef index
//
sym->setLocalIndex(NULL_USEDEF_SYMBOL_INDEX);
// Volatile symbols must not be considered since they don't have
// any specifiable def points.
//
if (!shouldIndexVolatileSym(symRef,aux))
{
if (trace())
traceMsg(comp(), "Ignoring Symbol [%p] because it is volatile %d or aliased to a volatile %d\n",sym,sym->isVolatile(),aux._volatileOrAliasedToVolatileSymbols.get(symRefNumber));
continue;
}
if (excludedGlobals(sym))
continue;
if (!sym->isStatic() &&
!sym->isMethodMetaData() &&
!sym->isShadow())
continue;
// Index this symbol
//
if (trace())
traceMsg(comp(), "Symbol [%p] has index %d\n", sym, _numSymbols);
_sideTableToSymRefNumMap[_numSymbols] = symRefNumber;
sym->setLocalIndex(_numSymbols++);
if (!isTrivialUseDefSymRef(symRef, aux) &&
((sym->isParm() && !aux._neverWrittenSymbols.get(symRef->getReferenceNumber())) ||
(aux._onceReadSymbolsIndices[symRef->getReferenceNumber()].IsNull() &&
aux._onceWrittenSymbolsIndices[symRef->getReferenceNumber()].IsNull())))
_numNonTrivialSymbols++;
}
}
}
_numStaticsAndFields = _numSymbols;
refIter.reset();
while (refIter.hasMoreElements())
{
symRefNumber = refIter.getNextElement();
symRef = symRefTab->getSymRef(symRefNumber);