shylie/llvm-project
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
llvm-project/llvm/lib/DebugInfo/LogicalView/Core/LVSymbol.cpp
Scott Linder 2e6bb8c9b8 [DebugInfo] Support more than 2 operands in DWARF operations 
Update DWARFExpression::Operation and LVOperation to support more than
2 operands.

Take the opportunity to use a SmallVector, which will handle at least 2
operands without allocation anyway, and removes the static limit
completely.

As there is no longer the concept of an "unused operand", remove
Operation::Encoding::SizeNA. Any use of it is now replaced with explicit
checks for how many operands an operation has.

There are still places where the limit remains 2, namely in the
DWARFLinker and in DIExpressions, but these can be updated in later
patches as-needed.

There are no explicit tests as this is nearly NFC: no new operation is
added which makes use of the additional operand capacity yet. A future
patch adding a new DWARF extension point will include operations which
require the support.

Reviewed By: Orlando, CarlosAlbertoEnciso

Differential Revision: https://reviews.llvm.org/D147270
2023-06-19 19:38:26 +00:00

448 lines
14 KiB
C++
Raw Blame History

//===-- LVSymbol.cpp ------------------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This implements the LVSymbol class.
//
//===----------------------------------------------------------------------===//
#include "llvm/DebugInfo/LogicalView/Core/LVSymbol.h"
#include "llvm/DebugInfo/LogicalView/Core/LVCompare.h"
#include "llvm/DebugInfo/LogicalView/Core/LVLocation.h"
#include "llvm/DebugInfo/LogicalView/Core/LVReader.h"
#include "llvm/DebugInfo/LogicalView/Core/LVScope.h"
using namespace llvm;
using namespace llvm::logicalview;
#define DEBUG_TYPE "Symbol"
namespace {
const char *const KindCallSiteParameter = "CallSiteParameter";
const char *const KindConstant = "Constant";
const char *const KindInherits = "Inherits";
const char *const KindMember = "Member";
const char *const KindParameter = "Parameter";
const char *const KindUndefined = "Undefined";
const char *const KindUnspecified = "Unspecified";
const char *const KindVariable = "Variable";
} // end anonymous namespace
// Return a string representation for the symbol kind.
const char *LVSymbol::kind() const {
const char *Kind = KindUndefined;
if (getIsCallSiteParameter())
Kind = KindCallSiteParameter;
else if (getIsConstant())
Kind = KindConstant;
else if (getIsInheritance())
Kind = KindInherits;
else if (getIsMember())
Kind = KindMember;
else if (getIsParameter())
Kind = KindParameter;
else if (getIsUnspecified())
Kind = KindUnspecified;
else if (getIsVariable())
Kind = KindVariable;
return Kind;
}
LVSymbolDispatch LVSymbol::Dispatch = {
{LVSymbolKind::IsCallSiteParameter, &LVSymbol::getIsCallSiteParameter},
{LVSymbolKind::IsConstant, &LVSymbol::getIsConstant},
{LVSymbolKind::IsInheritance, &LVSymbol::getIsInheritance},
{LVSymbolKind::IsMember, &LVSymbol::getIsMember},
{LVSymbolKind::IsParameter, &LVSymbol::getIsParameter},
{LVSymbolKind::IsUnspecified, &LVSymbol::getIsUnspecified},
{LVSymbolKind::IsVariable, &LVSymbol::getIsVariable}};
// Add a Location Entry.
void LVSymbol::addLocation(dwarf::Attribute Attr, LVAddress LowPC,
LVAddress HighPC, LVUnsigned SectionOffset,
uint64_t LocDescOffset, bool CallSiteLocation) {
if (!Locations)
Locations = std::make_unique<LVLocations>();
// Create the location entry.
CurrentLocation = getReader().createLocationSymbol();
CurrentLocation->setParent(this);
CurrentLocation->setAttr(Attr);
if (CallSiteLocation)
CurrentLocation->setIsCallSite();
CurrentLocation->addObject(LowPC, HighPC, SectionOffset, LocDescOffset);
Locations->push_back(CurrentLocation);
// Mark the symbol as having location information.
setHasLocation();
}
// Add a Location Record.
void LVSymbol::addLocationOperands(LVSmall Opcode,
ArrayRef<uint64_t> Operands) {
if (CurrentLocation)
CurrentLocation->addObject(Opcode, Operands);
}
// Add a Location Entry.
void LVSymbol::addLocationConstant(dwarf::Attribute Attr, LVUnsigned Constant,
uint64_t LocDescOffset) {
// Create a Location Entry, with the global information.
addLocation(Attr,
/*LowPC=*/0, /*HighPC=*/-1,
/*SectionOffset=*/0, LocDescOffset);
// Add records to Location Entry.
addLocationOperands(/*Opcode=*/LVLocationMemberOffset, {Constant});
}
LVLocations::iterator LVSymbol::addLocationGap(LVLocations::iterator Pos,
LVAddress LowPC,
LVAddress HighPC) {
// Create a location entry for the gap.
LVLocation *Gap = getReader().createLocationSymbol();
Gap->setParent(this);
Gap->setAttr(dwarf::DW_AT_location);
Gap->addObject(LowPC, HighPC,
/*section_offset=*/0,
/*locdesc_offset=*/0);
LVLocations::iterator Iter = Locations->insert(Pos, Gap);
// Add gap to Location Entry.
Gap->addObject(dwarf::DW_OP_hi_user, {});
// Mark the entry as a gap.
Gap->setIsGapEntry();
return Iter;
}
void LVSymbol::fillLocationGaps() {
// The symbol has locations records. Fill gaps in the location list.
if (!getHasLocation() || !getFillGaps())
return;
// Get the parent range information and add dummy location entries.
const LVLocations *Ranges = getParentScope()->getRanges();
if (!Ranges)
return;
for (const LVLocation *Entry : *Ranges) {
LVAddress ParentLowPC = Entry->getLowerAddress();
LVAddress ParentHighPC = Entry->getUpperAddress();
// Traverse the symbol locations and for each location contained in
// the current parent range, insert locations for any existing gap.
LVLocation *Location;
LVAddress LowPC = 0;
LVAddress Marker = ParentLowPC;
for (LVLocations::iterator Iter = Locations->begin();
Iter != Locations->end(); ++Iter) {
Location = *Iter;
LowPC = Location->getLowerAddress();
if (LowPC != Marker) {
// We have a gap at [Marker,LowPC - 1].
Iter = addLocationGap(Iter, Marker, LowPC - 1);
++Iter;
}
// Move to the next item in the location list.
Marker = Location->getUpperAddress() + 1;
}
// Check any gap at the end.
if (Marker < ParentHighPC)
// We have a gap at [Marker,ParentHighPC].
addLocationGap(Locations->end(), Marker, ParentHighPC);
}
}
// Get all the locations based on the valid function.
void LVSymbol::getLocations(LVLocations &LocationList,
LVValidLocation ValidLocation, bool RecordInvalid) {
if (!Locations)
return;
for (LVLocation *Location : *Locations) {
// Add the invalid location object.
if (!(Location->*ValidLocation)() && RecordInvalid)
LocationList.push_back(Location);
}
// Calculate coverage factor.
calculateCoverage();
}
void LVSymbol::getLocations(LVLocations &LocationList) const {
if (!Locations)
return;
for (LVLocation *Location : *Locations)
LocationList.push_back(Location);
}
// Calculate coverage factor.
void LVSymbol::calculateCoverage() {
if (!LVLocation::calculateCoverage(Locations.get(), CoverageFactor,
CoveragePercentage)) {
LVScope *Parent = getParentScope();
if (Parent->getIsInlinedFunction()) {
// For symbols representing the inlined function parameters and its
// variables, get the outer most parent that contains their location
// lower address.
// The symbol can have a set of non-contiguous locations. We are using
// only the first location entry to get the outermost parent.
// If no scope contains the location, assume its enclosing parent.
LVScope *Scope =
Parent->outermostParent(Locations->front()->getLowerAddress());
if (Scope)
Parent = Scope;
}
unsigned CoverageParent = Parent->getCoverageFactor();
// Get a percentage rounded to two decimal digits. This avoids
// implementation-defined rounding inside printing functions.
CoveragePercentage =
CoverageParent
? rint((double(CoverageFactor) / CoverageParent) * 100.0 * 100.0) /
100.0
: 0;
// Record invalid coverage entry.
if (options().getWarningCoverages() && CoveragePercentage > 100)
getReaderCompileUnit()->addInvalidCoverage(this);
}
}
void LVSymbol::resolveName() {
if (getIsResolvedName())
return;
setIsResolvedName();
LVElement::resolveName();
// Resolve any given pattern.
patterns().resolvePatternMatch(this);
}
void LVSymbol::resolveReferences() {
// The symbols can have the following references to other elements:
// A Type:
// DW_AT_type -> Type or Scope
// DW_AT_import -> Type
// A Reference:
// DW_AT_specification -> Symbol
// DW_AT_abstract_origin -> Symbol
// DW_AT_extension -> Symbol
// Resolve any referenced symbol.
LVSymbol *Reference = getReference();
if (Reference) {
Reference->resolve();
// Recursively resolve the symbol names.
resolveReferencesChain();
}
// Set the file/line information using the Debug Information entry.
setFile(Reference);
// Resolve symbol type.
if (LVElement *Element = getType()) {
Element->resolve();
// In the case of demoted typedefs, use the underlying type.
if (Element->getIsTypedefReduced()) {
Element = Element->getType();
Element->resolve();
}
// If the type is a template parameter, get its type, which can
// point to a type or scope, depending on the argument instance.
setGenericType(Element);
}
// Resolve the variable associated type.
if (!getType() && Reference)
setType(Reference->getType());
}
StringRef LVSymbol::resolveReferencesChain() {
// If the symbol have a DW_AT_specification or DW_AT_abstract_origin,
// follow the chain to resolve the name from those references.
if (getHasReference() && !isNamed())
setName(getReference()->resolveReferencesChain());
return getName();
}
void LVSymbol::markMissingParents(const LVSymbols *References,
const LVSymbols *Targets) {
if (!(References && Targets))
return;
LLVM_DEBUG({
dbgs() << "\n[LVSymbol::markMissingParents]\n";
for (const LVSymbol *Reference : *References)
dbgs() << "References: "
<< "Kind = " << formattedKind(Reference->kind()) << ", "
<< "Name = " << formattedName(Reference->getName()) << "\n";
for (const LVSymbol *Target : *Targets)
dbgs() << "Targets : "
<< "Kind = " << formattedKind(Target->kind()) << ", "
<< "Name = " << formattedName(Target->getName()) << "\n";
});
for (LVSymbol *Reference : *References) {
LLVM_DEBUG({
dbgs() << "Search Reference: Name = "
<< formattedName(Reference->getName()) << "\n";
});
if (!Reference->findIn(Targets))
Reference->markBranchAsMissing();
}
}
LVSymbol *LVSymbol::findIn(const LVSymbols *Targets) const {
if (!Targets)
return nullptr;
LLVM_DEBUG({
dbgs() << "\n[LVSymbol::findIn]\n"
<< "Reference: "
<< "Level = " << getLevel() << ", "
<< "Kind = " << formattedKind(kind()) << ", "
<< "Name = " << formattedName(getName()) << "\n";
for (const LVSymbol *Target : *Targets)
dbgs() << "Target : "
<< "Level = " << Target->getLevel() << ", "
<< "Kind = " << formattedKind(Target->kind()) << ", "
<< "Name = " << formattedName(Target->getName()) << "\n";
});
for (LVSymbol *Target : *Targets)
if (equals(Target))
return Target;
return nullptr;
}
// Check for a match on the arguments of a function.
bool LVSymbol::parametersMatch(const LVSymbols *References,
const LVSymbols *Targets) {
if (!References && !Targets)
return true;
if (References && Targets) {
LVSymbols ReferenceParams;
getParameters(References, &ReferenceParams);
LVSymbols TargetParams;
getParameters(Targets, &TargetParams);
return LVSymbol::equals(&ReferenceParams, &TargetParams);
}
return false;
}
// Return the symbols which are parameters.
void LVSymbol::getParameters(const LVSymbols *Symbols, LVSymbols *Parameters) {
if (Symbols)
for (LVSymbol *Symbol : *Symbols)
if (Symbol->getIsParameter())
Parameters->push_back(Symbol);
}
bool LVSymbol::equals(const LVSymbol *Symbol) const {
if (!LVElement::equals(Symbol))
return false;
// Check if any reference is the same.
if (!referenceMatch(Symbol))
return false;
if (getReference() && !getReference()->equals(Symbol->getReference()))
return false;
return true;
}
bool LVSymbol::equals(const LVSymbols *References, const LVSymbols *Targets) {
if (!References && !Targets)
return true;
if (References && Targets && References->size() == Targets->size()) {
for (const LVSymbol *Reference : *References)
if (!Reference->findIn(Targets))
return false;
return true;
}
return false;
}
void LVSymbol::report(LVComparePass Pass) {
getComparator().printItem(this, Pass);
}
void LVSymbol::printLocations(raw_ostream &OS, bool Full) const {
if (Locations)
for (const LVLocation *Location : *Locations)
Location->printRaw(OS, Full);
}
void LVSymbol::print(raw_ostream &OS, bool Full) const {
if (getIncludeInPrint() && getReader().doPrintSymbol(this)) {
getReaderCompileUnit()->incrementPrintedSymbols();
LVElement::print(OS, Full);
printExtra(OS, Full);
}
}
void LVSymbol::printExtra(raw_ostream &OS, bool Full) const {
// Accessibility depends on the parent (class, structure).
uint32_t AccessCode = 0;
if (getIsMember() || getIsInheritance())
AccessCode = getParentScope()->getIsClass() ? dwarf::DW_ACCESS_private
: dwarf::DW_ACCESS_public;
const LVSymbol *Symbol = getIsInlined() ? Reference : this;
std::string Attributes =
Symbol->getIsCallSiteParameter()
? ""
: formatAttributes(Symbol->externalString(),
Symbol->accessibilityString(AccessCode),
virtualityString());
OS << formattedKind(Symbol->kind()) << " " << Attributes;
if (Symbol->getIsUnspecified())
OS << formattedName(Symbol->getName());
else {
if (Symbol->getIsInheritance())
OS << Symbol->typeOffsetAsString()
<< formattedNames(Symbol->getTypeQualifiedName(),
Symbol->typeAsString());
else {
OS << formattedName(Symbol->getName());
// Print any bitfield information.
if (uint32_t Size = getBitSize())
OS << ":" << Size;
OS << " -> " << Symbol->typeOffsetAsString()
<< formattedNames(Symbol->getTypeQualifiedName(),
Symbol->typeAsString());
}
}
// Print any initial value if any.
if (ValueIndex)
OS << " = " << formattedName(getValue());
OS << "\n";
if (Full && options().getPrintFormatting()) {
if (getLinkageNameIndex())
printLinkageName(OS, Full, const_cast<LVSymbol *>(this));
if (LVSymbol *Reference = getReference())
Reference->printReference(OS, Full, const_cast<LVSymbol *>(this));
// Print location information.
LVLocation::print(Locations.get(), OS, Full);
}
}
Reference in New Issue View Git Blame Copy Permalink