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swiftshader / SwiftShader / 9c9608fa94a9209f2635c1d821c3652c3fd2a5e8 / . / third_party / llvm-16.0 / llvm / lib / DebugInfo / LogicalView / Core / LVScope.cpp
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//===-- LVScope.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 LVScope class.
//
//===----------------------------------------------------------------------===//
#include "llvm/DebugInfo/LogicalView/Core/LVScope.h"
#include "llvm/DebugInfo/LogicalView/Core/LVCompare.h"
#include "llvm/DebugInfo/LogicalView/Core/LVLine.h"
#include "llvm/DebugInfo/LogicalView/Core/LVLocation.h"
#include "llvm/DebugInfo/LogicalView/Core/LVRange.h"
#include "llvm/DebugInfo/LogicalView/Core/LVReader.h"
#include "llvm/DebugInfo/LogicalView/Core/LVSymbol.h"
#include "llvm/DebugInfo/LogicalView/Core/LVType.h"
using namespace llvm;
using namespace llvm::logicalview;
#define DEBUG_TYPE "Scope"
namespace {
const char *const KindArray = "Array";
const char *const KindBlock = "Block";
const char *const KindCallSite = "CallSite";
const char *const KindClass = "Class";
const char *const KindCompileUnit = "CompileUnit";
const char *const KindEnumeration = "Enumeration";
const char *const KindFile = "File";
const char *const KindFunction = "Function";
const char *const KindInlinedFunction = "InlinedFunction";
const char *const KindNamespace = "Namespace";
const char *const KindStruct = "Struct";
const char *const KindTemplateAlias = "TemplateAlias";
const char *const KindTemplatePack = "TemplatePack";
const char *const KindUndefined = "Undefined";
const char *const KindUnion = "Union";
} // end anonymous namespace
//===----------------------------------------------------------------------===//
// DWARF lexical block, such as: namespace, function, compile unit, module, etc.
//===----------------------------------------------------------------------===//
LVScope::~LVScope() {
delete Types;
delete Symbols;
delete Scopes;
delete Lines;
delete Ranges;
delete Children;
}
// Return a string representation for the scope kind.
const char *LVScope::kind() const {
const char *Kind = KindUndefined;
if (getIsArray())
Kind = KindArray;
else if (getIsBlock())
Kind = KindBlock;
else if (getIsCallSite())
Kind = KindCallSite;
else if (getIsCompileUnit())
Kind = KindCompileUnit;
else if (getIsEnumeration())
Kind = KindEnumeration;
else if (getIsInlinedFunction())
Kind = KindInlinedFunction;
else if (getIsNamespace())
Kind = KindNamespace;
else if (getIsTemplatePack())
Kind = KindTemplatePack;
else if (getIsRoot())
Kind = KindFile;
else if (getIsTemplateAlias())
Kind = KindTemplateAlias;
else if (getIsClass())
Kind = KindClass;
else if (getIsFunction())
Kind = KindFunction;
else if (getIsStructure())
Kind = KindStruct;
else if (getIsUnion())
Kind = KindUnion;
return Kind;
}
LVScopeDispatch LVScope::Dispatch = {
{LVScopeKind::IsAggregate, &LVScope::getIsAggregate},
{LVScopeKind::IsArray, &LVScope::getIsArray},
{LVScopeKind::IsBlock, &LVScope::getIsBlock},
{LVScopeKind::IsCallSite, &LVScope::getIsCallSite},
{LVScopeKind::IsCatchBlock, &LVScope::getIsCatchBlock},
{LVScopeKind::IsClass, &LVScope::getIsClass},
{LVScopeKind::IsCompileUnit, &LVScope::getIsCompileUnit},
{LVScopeKind::IsEntryPoint, &LVScope::getIsEntryPoint},
{LVScopeKind::IsEnumeration, &LVScope::getIsEnumeration},
{LVScopeKind::IsFunction, &LVScope::getIsFunction},
{LVScopeKind::IsFunctionType, &LVScope::getIsFunctionType},
{LVScopeKind::IsInlinedFunction, &LVScope::getIsInlinedFunction},
{LVScopeKind::IsLabel, &LVScope::getIsLabel},
{LVScopeKind::IsLexicalBlock, &LVScope::getIsLexicalBlock},
{LVScopeKind::IsNamespace, &LVScope::getIsNamespace},
{LVScopeKind::IsRoot, &LVScope::getIsRoot},
{LVScopeKind::IsStructure, &LVScope::getIsStructure},
{LVScopeKind::IsTemplate, &LVScope::getIsTemplate},
{LVScopeKind::IsTemplateAlias, &LVScope::getIsTemplateAlias},
{LVScopeKind::IsTemplatePack, &LVScope::getIsTemplatePack},
{LVScopeKind::IsTryBlock, &LVScope::getIsTryBlock},
{LVScopeKind::IsUnion, &LVScope::getIsUnion}};
void LVScope::addToChildren(LVElement *Element) {
if (!Children)
Children = new LVElements();
Children->push_back(Element);
}
void LVScope::addElement(LVElement *Element) {
assert(Element && "Invalid element.");
if (Element->getIsType())
addElement(static_cast<LVType *>(Element));
else if (Element->getIsScope())
addElement(static_cast<LVScope *>(Element));
else if (Element->getIsSymbol())
addElement(static_cast<LVSymbol *>(Element));
else if (Element->getIsLine())
addElement(static_cast<LVLine *>(Element));
else
llvm_unreachable("Invalid Element.");
}
// Adds the line info item to the ones stored in the scope.
void LVScope::addElement(LVLine *Line) {
assert(Line && "Invalid line.");
assert(!Line->getParent() && "Line already inserted");
if (!Lines)
Lines = new LVAutoLines();
// Add it to parent.
Lines->push_back(Line);
Line->setParent(this);
// Notify the reader about the new element being added.
getReaderCompileUnit()->addedElement(Line);
// All logical elements added to the children, are sorted by any of the
// following criterias: offset, name, line number, kind.
// Do not add the line records to the children, as they represent the
// logical view for the text section and any sorting will not preserve
// the original sequence.
// Indicate that this tree branch has lines.
traverseParents(&LVScope::getHasLines, &LVScope::setHasLines);
}
// Add a location.
void LVScope::addObject(LVLocation *Location) {
assert(Location && "Invalid location.");
assert(!Location->getParent() && "Location already inserted");
if (!Ranges)
Ranges = new LVAutoLocations();
// Add it to parent.
Location->setParent(this);
Location->setOffset(getOffset());
Ranges->push_back(Location);
setHasRanges();
}
// Adds the scope to the child scopes and sets the parent in the child.
void LVScope::addElement(LVScope *Scope) {
assert(Scope && "Invalid scope.");
assert(!Scope->getParent() && "Scope already inserted");
if (!Scopes)
Scopes = new LVAutoScopes();
// Add it to parent.
Scopes->push_back(Scope);
addToChildren(Scope);
Scope->setParent(this);
// Notify the reader about the new element being added.
getReaderCompileUnit()->addedElement(Scope);
// If the element is a global reference, mark its parent as having global
// references; that information is used, to print only those branches
// with global references.
if (Scope->getIsGlobalReference())
traverseParents(&LVScope::getHasGlobals, &LVScope::setHasGlobals);
else
traverseParents(&LVScope::getHasLocals, &LVScope::setHasLocals);
// Indicate that this tree branch has scopes.
traverseParents(&LVScope::getHasScopes, &LVScope::setHasScopes);
}
// Adds a symbol to the ones stored in the scope.
void LVScope::addElement(LVSymbol *Symbol) {
assert(Symbol && "Invalid symbol.");
assert(!Symbol->getParent() && "Symbol already inserted");
if (!Symbols)
Symbols = new LVAutoSymbols();
// Add it to parent.
Symbols->push_back(Symbol);
addToChildren(Symbol);
Symbol->setParent(this);
// Notify the reader about the new element being added.
getReaderCompileUnit()->addedElement(Symbol);
// If the element is a global reference, mark its parent as having global
// references; that information is used, to print only those branches
// with global references.
if (Symbol->getIsGlobalReference())
traverseParents(&LVScope::getHasGlobals, &LVScope::setHasGlobals);
else
traverseParents(&LVScope::getHasLocals, &LVScope::setHasLocals);
// Indicate that this tree branch has symbols.
traverseParents(&LVScope::getHasSymbols, &LVScope::setHasSymbols);
}
// Adds a type to the ones stored in the scope.
void LVScope::addElement(LVType *Type) {
assert(Type && "Invalid type.");
assert(!Type->getParent() && "Type already inserted");
if (!Types)
Types = new LVAutoTypes();
// Add it to parent.
Types->push_back(Type);
addToChildren(Type);
Type->setParent(this);
// Notify the reader about the new element being added.
getReaderCompileUnit()->addedElement(Type);
// If the element is a global reference, mark its parent as having global
// references; that information is used, to print only those branches
// with global references.
if (Type->getIsGlobalReference())
traverseParents(&LVScope::getHasGlobals, &LVScope::setHasGlobals);
else
traverseParents(&LVScope::getHasLocals, &LVScope::setHasLocals);
// Indicate that this tree branch has types.
traverseParents(&LVScope::getHasTypes, &LVScope::setHasTypes);
}
// Add a pair of ranges.
void LVScope::addObject(LVAddress LowerAddress, LVAddress UpperAddress) {
// Pack the ranges into a Location object.
LVLocation *Location = new LVLocation();
Location->setLowerAddress(LowerAddress);
Location->setUpperAddress(UpperAddress);
Location->setIsAddressRange();
addObject(Location);
}
bool LVScope::removeElement(LVElement *Element) {
auto Predicate = [Element](LVElement *Item) -> bool {
return Item == Element;
};
auto RemoveElement = [Element, Predicate](auto &Container) -> bool {
auto Iter = std::remove_if(Container->begin(), Container->end(), Predicate);
if (Iter != Container->end()) {
Container->erase(Iter, Container->end());
Element->resetParent();
return true;
}
return false;
};
// As 'children' contains only (scopes, symbols and types), check if the
// element we are deleting is a line.
if (Element->getIsLine())
return RemoveElement(Lines);
if (RemoveElement(Children)) {
if (Element->getIsSymbol())
return RemoveElement(Symbols);
if (Element->getIsType())
return RemoveElement(Types);
if (Element->getIsScope())
return RemoveElement(Scopes);
llvm_unreachable("Invalid element.");
}
return false;
}
void LVScope::addMissingElements(LVScope *Reference) {
setAddedMissing();
if (!Reference)
return;
// Get abstract symbols for the given scope reference.
const LVSymbols *ReferenceSymbols = Reference->getSymbols();
if (!ReferenceSymbols)
return;
LVSymbols References;
References.append(ReferenceSymbols->begin(), ReferenceSymbols->end());
auto RemoveSymbol = [&](LVSymbols &Symbols, LVSymbol *Symbol) {
LVSymbols::iterator Iter = std::remove_if(
Symbols.begin(), Symbols.end(),
[Symbol](LVSymbol *Item) -> bool { return Item == Symbol; });
if (Iter != Symbols.end())
Symbols.erase(Iter, Symbols.end());
};
// Erase abstract symbols already in this scope from the collection of
// symbols in the referenced scope.
if (getSymbols())
for (const LVSymbol *Symbol : *getSymbols())
if (Symbol->getHasReferenceAbstract())
RemoveSymbol(References, Symbol->getReference());
// If we have elements left in 'References', those are the elements that
// need to be inserted in the current scope.
if (References.size()) {
LLVM_DEBUG({
dbgs() << "Insert Missing Inlined Elements\n"
<< "Offset = " << hexSquareString(getOffset()) << " "
<< "Abstract = " << hexSquareString(Reference->getOffset())
<< "\n";
});
for (LVSymbol *Reference : References) {
LLVM_DEBUG({
dbgs() << "Missing Offset = " << hexSquareString(Reference->getOffset())
<< "\n";
});
// We can't clone the abstract origin reference, as it contain extra
// information that is incorrect for the element to be inserted.
// As the symbol being added does not exist in the debug section,
// use its parent scope offset, to indicate its DIE location.
LVSymbol *Symbol = new LVSymbol();
addElement(Symbol);
Symbol->setOffset(getOffset());
Symbol->setIsOptimized();
Symbol->setReference(Reference);
// The symbol can be a constant, parameter or variable.
if (Reference->getIsConstant())
Symbol->setIsConstant();
else if (Reference->getIsParameter())
Symbol->setIsParameter();
else if (Reference->getIsVariable())
Symbol->setIsVariable();
else
llvm_unreachable("Invalid symbol kind.");
}
}
}
void LVScope::updateLevel(LVScope *Parent, bool Moved) {
// Update the level for the element itself and all its children, using the
// given scope parent as reference.
setLevel(Parent->getLevel() + 1);
// Update the children.
if (Children)
for (LVElement *Element : *Children)
Element->updateLevel(this, Moved);
// Update any lines.
if (Lines)
for (LVLine *Line : *Lines)
Line->updateLevel(this, Moved);
}
void LVScope::resolve() {
if (getIsResolved())
return;
// Resolve the element itself.
LVElement::resolve();
// Resolve the children.
if (Children)
for (LVElement *Element : *Children) {
if (getIsGlobalReference())
// If the scope is a global reference, mark all its children as well.
Element->setIsGlobalReference();
Element->resolve();
}
}
void LVScope::resolveName() {
if (getIsResolvedName())
return;
setIsResolvedName();
// If the scope is a template, resolve the template parameters and get
// the name for the template with the encoded arguments.
if (getIsTemplate())
resolveTemplate();
else {
if (LVElement *BaseType = getType()) {
BaseType->resolveName();
resolveFullname(BaseType);
}
}
// In the case of unnamed scopes, try to generate a name for it, using
// the parents name and the line information. In the case of compiler
// generated functions, use its linkage name if is available.
if (!isNamed()) {
if (getIsArtificial())
setName(getLinkageName());
else
generateName();
}
LVElement::resolveName();
// Resolve any given pattern.
patterns().resolvePatternMatch(this);
}
void LVScope::resolveReferences() {
// The scopes 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 -> Scope
// DW_AT_abstract_origin -> Scope
// DW_AT_extension -> Scope
// Resolve any referenced scope.
LVScope *Reference = getReference();
if (Reference) {
Reference->resolve();
// Recursively resolve the scope names.
resolveReferencesChain();
}
// Set the file/line information using the Debug Information entry.
setFile(Reference);
// Resolve any referenced type or scope.
if (LVElement *Element = getType())
Element->resolve();
}
void LVScope::resolveElements() {
// The current element represents the Root. Traverse each Compile Unit.
if (!Scopes)
return;
for (LVScope *Scope : *Scopes) {
LVScopeCompileUnit *CompileUnit = static_cast<LVScopeCompileUnit *>(Scope);
getReader().setCompileUnit(CompileUnit);
CompileUnit->resolve();
// Propagate any matching information into the scopes tree.
CompileUnit->propagatePatternMatch();
}
}
StringRef LVScope::resolveReferencesChain() {
// If the scope has 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();
}
// Get template parameter types.
bool LVScope::getTemplateParameterTypes(LVTypes &Params) {
// Traverse the scope types and populate the given container with those
// types that are template parameters; that container will be used by
// 'encodeTemplateArguments' to resolve them.
if (const LVTypes *Types = getTypes())
for (LVType *Type : *Types)
if (Type->getIsTemplateParam()) {
Type->resolve();
Params.push_back(Type);
}
return !Params.empty();
}
// Resolve the template parameters/arguments relationship.
void LVScope::resolveTemplate() {
if (getIsTemplateResolved())
return;
setIsTemplateResolved();
// Check if we need to encode the template arguments.
if (options().getAttributeEncoded()) {
LVTypes Params;
if (getTemplateParameterTypes(Params)) {
std::string EncodedArgs;
// Encode the arguments as part of the template name and update the
// template name, to reflect the encoded parameters.
encodeTemplateArguments(EncodedArgs, &Params);
setEncodedArgs(EncodedArgs);
}
}
}
// Get the qualified name for the template.
void LVScope::getQualifiedName(std::string &QualifiedName) const {
if (getIsRoot() || getIsCompileUnit())
return;
if (LVScope *Parent = getParentScope())
Parent->getQualifiedName(QualifiedName);
if (!QualifiedName.empty())
QualifiedName.append("::");
QualifiedName.append(std::string(getName()));
}
// Encode the template arguments as part of the template name.
void LVScope::encodeTemplateArguments(std::string &Name) const {
// Qualify only when we are expanding parameters that are template
// instances; the debugger will assume the current scope symbol as
// the qualifying tag for the symbol being generated, which gives:
// namespace std {
// ...
// set<float,std::less<float>,std::allocator<float>>
// ...
// }
// The 'set' symbol is assumed to have the qualified tag 'std'.
// We are resolving a template parameter which is another template. If
// it is already resolved, just get the qualified name and return.
std::string BaseName;
getQualifiedName(BaseName);
if (getIsTemplateResolved())
Name.append(BaseName);
}
void LVScope::encodeTemplateArguments(std::string &Name,
const LVTypes *Types) const {
// The encoded string will start with the scope name.
Name.append("<");
// The list of types are the template parameters.
if (Types) {
bool AddComma = false;
for (const LVType *Type : *Types) {
if (AddComma)
Name.append(", ");
Type->encodeTemplateArgument(Name);
AddComma = true;
}
}
Name.append(">");
}
bool LVScope::resolvePrinting() const {
// The warnings collected during the scope creation as per compile unit.
// If there is a request for printing warnings, always print its associate
// Compile Unit.
if (options().getPrintWarnings() && (getIsRoot() || getIsCompileUnit()))
return true;
// In selection mode, always print the root scope regardless of the
// number of matched elements. If no matches, the root by itself will
// indicate no matches.
if (options().getSelectExecute()) {
return getIsRoot() || getIsCompileUnit() || getHasPattern();
}
bool Globals = options().getAttributeGlobal();
bool Locals = options().getAttributeLocal();
if ((Globals && Locals) || (!Globals && !Locals)) {
// Print both Global and Local.
} else {
// Check for Global or Local Objects.
if ((Globals && !(getHasGlobals() || getIsGlobalReference())) ||
(Locals && !(getHasLocals() || !getIsGlobalReference())))
return false;
}
// For the case of functions, skip it if is compiler generated.
if (getIsFunction() && getIsArtificial() &&
!options().getAttributeGenerated())
return false;
return true;
}
Error LVScope::doPrint(bool Split, bool Match, bool Print, raw_ostream &OS,
bool Full) const {
// During a view output splitting, use the output stream created by the
// split context, then switch to the reader output stream.
raw_ostream *StreamSplit = &OS;
// If 'Split', we use the scope name (CU name) as the ouput file; the
// delimiters in the pathname, must be replaced by a normal character.
if (getIsCompileUnit()) {
getReader().setCompileUnit(const_cast<LVScope *>(this));
if (Split) {
std::string ScopeName(getName());
if (std::error_code EC =
getReaderSplitContext().open(ScopeName, ".txt", OS))
return createStringError(EC, "Unable to create split output file %s",
ScopeName.c_str());
StreamSplit = static_cast<raw_ostream *>(&getReaderSplitContext().os());
}
}
// Ignore discarded or stripped scopes (functions).
bool DoPrint = (options().getAttributeDiscarded()) ? true : !getIsDiscarded();
// If we are in compare mode, the only conditions are related to the
// element being missing. In the case of elements comparison, we print the
// augmented view, that includes added elements.
// In print mode, we check other conditions, such as local, global, etc.
if (DoPrint) {
DoPrint =
getIsInCompare() ? options().getReportExecute() : resolvePrinting();
}
// At this point we have checked for very specific options, to decide if the
// element will be printed. Include the caller's test for element general
// print.
DoPrint = DoPrint && (Print || options().getOutputSplit());
if (DoPrint) {
// Print the element itself.
print(*StreamSplit, Full);
// Check if we have reached the requested lexical level specified in the
// command line options. Input file is level zero and the CU is level 1.
if ((getIsRoot() || options().getPrintAnyElement()) &&
options().getPrintFormatting() &&
getLevel() < options().getOutputLevel()) {
// Print the children.
if (Children)
for (const LVElement *Element : *Children) {
if (Match && !Element->getHasPattern())
continue;
if (Error Err =
Element->doPrint(Split, Match, Print, *StreamSplit, Full))
return Err;
}
// Print the line records.
if (Lines)
for (const LVLine *Line : *Lines) {
if (Match && !Line->getHasPattern())
continue;
if (Error Err =
Line->doPrint(Split, Match, Print, *StreamSplit, Full))
return Err;
}
// Print the warnings.
if (options().getPrintWarnings())
printWarnings(*StreamSplit, Full);
}
}
// Done printing the compile unit. Print any requested summary and
// restore the original output context.
if (getIsCompileUnit()) {
if (options().getPrintSummary())
printSummary(*StreamSplit);
if (options().getPrintSizes())
printSizes(*StreamSplit);
if (Split) {
getReaderSplitContext().close();
StreamSplit = &getReader().outputStream();
}
}
if (getIsRoot() && options().getPrintWarnings()) {
getReader().printRecords(*StreamSplit);
}
return Error::success();
}
void LVScope::sort() {
// Preserve the lines order as they are associated with user code.
LVSortFunction SortFunction = getSortFunction();
if (SortFunction) {
std::function<void(LVScope * Parent, LVSortFunction SortFunction)> Sort =
[&](LVScope *Parent, LVSortFunction SortFunction) {
auto Traverse = [&](auto *Set, LVSortFunction SortFunction) {
if (Set)
std::stable_sort(Set->begin(), Set->end(), SortFunction);
};
Traverse(Parent->Types, SortFunction);
Traverse(Parent->Symbols, SortFunction);
Traverse(Parent->Scopes, SortFunction);
Traverse(Parent->Ranges, compareRange);
Traverse(Parent->Children, SortFunction);
if (Parent->Scopes)
for (LVScope *Scope : *Parent->Scopes)
Sort(Scope, SortFunction);
};
// Start traversing the scopes root and transform the element name.
Sort(this, SortFunction);
}
}
void LVScope::traverseParents(LVScopeGetFunction GetFunction,
LVScopeSetFunction SetFunction) {
// Traverse the parent tree.
LVScope *Parent = this;
while (Parent) {
// Terminates if the 'SetFunction' has been already executed.
if ((Parent->*GetFunction)())
break;
(Parent->*SetFunction)();
Parent = Parent->getParentScope();
}
}
void LVScope::traverseParentsAndChildren(LVObjectGetFunction GetFunction,
LVObjectSetFunction SetFunction) {
if (options().getReportParents()) {
// First traverse the parent tree.
LVScope *Parent = this;
while (Parent) {
// Terminates if the 'SetFunction' has been already executed.
if ((Parent->*GetFunction)())
break;
(Parent->*SetFunction)();
Parent = Parent->getParentScope();
}
}
std::function<void(LVScope * Scope)> TraverseChildren = [&](LVScope *Scope) {
auto Traverse = [&](const auto *Set) {
if (Set)
for (const auto &Entry : *Set)
(Entry->*SetFunction)();
};
(Scope->*SetFunction)();
Traverse(Scope->getTypes());
Traverse(Scope->getSymbols());
Traverse(Scope->getLines());
if (const LVScopes *Scopes = Scope->getScopes())
for (LVScope *Scope : *Scopes)
TraverseChildren(Scope);
};
if (options().getReportChildren())
TraverseChildren(this);
}
// Traverse the symbol location ranges and for each range:
// - Apply the 'ValidLocation' validation criteria.
// - Add any failed range to the 'LocationList'.
// - Calculate location coverage.
void LVScope::getLocations(LVLocations &LocationList,
LVValidLocation ValidLocation, bool RecordInvalid) {
// Traverse scopes and symbols.
if (Symbols)
for (LVSymbol *Symbol : *Symbols)
Symbol->getLocations(LocationList, ValidLocation, RecordInvalid);
if (Scopes)
for (LVScope *Scope : *Scopes)
Scope->getLocations(LocationList, ValidLocation, RecordInvalid);
}
// Traverse the scope ranges and for each range:
// - Apply the 'ValidLocation' validation criteria.
// - Add any failed range to the 'LocationList'.
// - Calculate location coverage.
void LVScope::getRanges(LVLocations &LocationList,
LVValidLocation ValidLocation, bool RecordInvalid) {
// Ignore discarded or stripped scopes (functions).
if (getIsDiscarded())
return;
// Process the ranges for current scope.
if (Ranges) {
for (LVLocation *Location : *Ranges) {
// Add the invalid location object.
if (!(Location->*ValidLocation)() && RecordInvalid)
LocationList.push_back(Location);
}
// Calculate coverage factor.
calculateCoverage();
}
// Traverse the scopes.
if (Scopes)
for (LVScope *Scope : *Scopes)
Scope->getRanges(LocationList, ValidLocation, RecordInvalid);
}
// Get all the ranges associated with scopes.
void LVScope::getRanges(LVRange &RangeList) {
// Ignore discarded or stripped scopes (functions).
if (getIsDiscarded())
return;
if (Ranges)
RangeList.addEntry(this);
if (Scopes)
for (LVScope *Scope : *Scopes)
Scope->getRanges(RangeList);
}
LVScope *LVScope::outermostParent(LVAddress Address) {
LVScope *Parent = this;
while (Parent) {
const LVLocations *ParentRanges = Parent->getRanges();
if (ParentRanges)
for (const LVLocation *Location : *ParentRanges)
if (Location->getLowerAddress() <= Address)
return Parent;
Parent = Parent->getParentScope();
}
return Parent;
}
LVScope *LVScope::findIn(const LVScopes *Targets) const {
if (!Targets)
return nullptr;
// In the case of overloaded functions, sometimes the DWARF used to
// describe them, does not give suficient information. Try to find a
// perfect match or mark them as possible conflicts.
LVScopes Candidates;
for (LVScope *Target : *Targets)
if (LVScope::equals(Target))
Candidates.push_back(Target);
LLVM_DEBUG({
if (!Candidates.empty()) {
dbgs() << "\n[LVScope::findIn]\n"
<< "Reference: "
<< "Offset = " << hexSquareString(getOffset()) << ", "
<< "Level = " << getLevel() << ", "
<< "Kind = " << formattedKind(kind()) << ", "
<< "Name = " << formattedName(getName()) << "\n";
for (const LVScope *Candidate : Candidates)
dbgs() << "Candidate: "
<< "Offset = " << hexSquareString(Candidate->getOffset()) << ", "
<< "Level = " << Candidate->getLevel() << ", "
<< "Kind = " << formattedKind(Candidate->kind()) << ", "
<< "Name = " << formattedName(Candidate->getName()) << "\n";
}
});
if (!Candidates.empty())
return (Candidates.size() == 1)
? (equals(Candidates[0]) ? Candidates[0] : nullptr)
: findEqualScope(&Candidates);
return nullptr;
}
bool LVScope::equalNumberOfChildren(const LVScope *Scope) const {
// Same number of children. Take into account which elements are requested
// to be included in the comparison.
return !(
(options().getCompareScopes() && scopeCount() != Scope->scopeCount()) ||
(options().getCompareSymbols() &&
symbolCount() != Scope->symbolCount()) ||
(options().getCompareTypes() && typeCount() != Scope->typeCount()) ||
(options().getCompareLines() && lineCount() != Scope->lineCount()));
}
void LVScope::markMissingParents(const LVScope *Target, bool TraverseChildren) {
auto SetCompareState = [&](auto *Container) {
if (Container)
for (auto *Entry : *Container)
Entry->setIsInCompare();
};
SetCompareState(Types);
SetCompareState(Symbols);
SetCompareState(Lines);
SetCompareState(Scopes);
// At this point, we are ready to start comparing the current scope, once
// the compare bits have been set.
if (options().getCompareTypes() && getTypes() && Target->getTypes())
LVType::markMissingParents(getTypes(), Target->getTypes());
if (options().getCompareSymbols() && getSymbols() && Target->getSymbols())
LVSymbol::markMissingParents(getSymbols(), Target->getSymbols());
if (options().getCompareLines() && getLines() && Target->getLines())
LVLine::markMissingParents(getLines(), Target->getLines());
if (getScopes() && Target->getScopes())
LVScope::markMissingParents(getScopes(), Target->getScopes(),
TraverseChildren);
}
void LVScope::markMissingParents(const LVScopes *References,
const LVScopes *Targets,
bool TraverseChildren) {
if (!(References && Targets))
return;
LLVM_DEBUG({
dbgs() << "\n[LVScope::markMissingParents]\n";
for (const LVScope *Reference : *References)
dbgs() << "References: "
<< "Offset = " << hexSquareString(Reference->getOffset()) << ", "
<< "Level = " << Reference->getLevel() << ", "
<< "Kind = " << formattedKind(Reference->kind()) << ", "
<< "Name = " << formattedName(Reference->getName()) << "\n";
for (const LVScope *Target : *Targets)
dbgs() << "Targets : "
<< "Offset = " << hexSquareString(Target->getOffset()) << ", "
<< "Level = " << Target->getLevel() << ", "
<< "Kind = " << formattedKind(Target->kind()) << ", "
<< "Name = " << formattedName(Target->getName()) << "\n";
});
for (LVScope *Reference : *References) {
// Don't process 'Block' scopes, as we can't identify them.
if (Reference->getIsBlock() || Reference->getIsGeneratedName())
continue;
LLVM_DEBUG({
dbgs() << "\nSearch Reference: "
<< "Offset = " << hexSquareString(Reference->getOffset()) << " "
<< "Name = " << formattedName(Reference->getName()) << "\n";
});
LVScope *Target = Reference->findIn(Targets);
if (Target) {
LLVM_DEBUG({
dbgs() << "\nFound Target: "
<< "Offset = " << hexSquareString(Target->getOffset()) << " "
<< "Name = " << formattedName(Target->getName()) << "\n";
});
if (TraverseChildren)
Reference->markMissingParents(Target, TraverseChildren);
} else {
LLVM_DEBUG({
dbgs() << "Missing Reference: "
<< "Offset = " << hexSquareString(Reference->getOffset()) << " "
<< "Name = " << formattedName(Reference->getName()) << "\n";
});
Reference->markBranchAsMissing();
}
}
}
bool LVScope::equals(const LVScope *Scope) const {
if (!LVElement::equals(Scope))
return false;
// For lexical scopes, check if their parents are the same.
if (getIsLexicalBlock() && Scope->getIsLexicalBlock())
return getParentScope()->equals(Scope->getParentScope());
return true;
}
LVScope *LVScope::findEqualScope(const LVScopes *Scopes) const {
assert(Scopes && "Scopes must not be nullptr");
for (LVScope *Scope : *Scopes)
if (equals(Scope))
return Scope;
return nullptr;
}
bool LVScope::equals(const LVScopes *References, const LVScopes *Targets) {
if (!References && !Targets)
return true;
if (References && Targets && References->size() == Targets->size()) {
for (const LVScope *Reference : *References)
if (!Reference->findIn(Targets))
return false;
return true;
}
return false;
}
void LVScope::report(LVComparePass Pass) {
getComparator().printItem(this, Pass);
getComparator().push(this);
if (Children)
for (LVElement *Element : *Children)
Element->report(Pass);
if (Lines)
for (LVLine *Line : *Lines)
Line->report(Pass);
getComparator().pop();
}
void LVScope::printActiveRanges(raw_ostream &OS, bool Full) const {
if (options().getPrintFormatting() && options().getAttributeRange() &&
Ranges) {
for (const LVLocation *Location : *Ranges)
Location->print(OS, Full);
}
}
void LVScope::printEncodedArgs(raw_ostream &OS, bool Full) const {
if (options().getPrintFormatting() && options().getAttributeEncoded())
printAttributes(OS, Full, "{Encoded} ", const_cast<LVScope *>(this),
getEncodedArgs(), /*UseQuotes=*/false, /*PrintRef=*/false);
}
void LVScope::print(raw_ostream &OS, bool Full) const {
if (getIncludeInPrint() && getReader().doPrintScope(this)) {
// For a summary (printed elements), do not count the scope root.
// For a summary (selected elements) do not count a compile unit.
if (!(getIsRoot() || (getIsCompileUnit() && options().getSelectExecute())))
getReaderCompileUnit()->incrementPrintedScopes();
LVElement::print(OS, Full);
printExtra(OS, Full);
}
}
void LVScope::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind());
// Do not print any type or name for a lexical block.
if (!getIsBlock()) {
OS << " " << formattedName(getName());
if (!getIsAggregate())
OS << " -> " << typeOffsetAsString()
<< formattedNames(getTypeQualifiedName(), typeAsString());
}
OS << "\n";
// Print any active ranges.
if (Full && getIsBlock())
printActiveRanges(OS, Full);
}
//===----------------------------------------------------------------------===//
// DWARF Union/Structure/Class.
//===----------------------------------------------------------------------===//
bool LVScopeAggregate::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
if (!equalNumberOfChildren(Scope))
return false;
// Check if the parameters match in the case of templates.
if (!LVType::parametersMatch(getTypes(), Scope->getTypes()))
return false;
if (!isNamed() && !Scope->isNamed())
// In the case of unnamed union/structure/class compare the file name.
if (getFilenameIndex() != Scope->getFilenameIndex())
return false;
return true;
}
LVScope *LVScopeAggregate::findEqualScope(const LVScopes *Scopes) const {
assert(Scopes && "Scopes must not be nullptr");
for (LVScope *Scope : *Scopes)
if (equals(Scope))
return Scope;
return nullptr;
}
void LVScopeAggregate::printExtra(raw_ostream &OS, bool Full) const {
LVScope::printExtra(OS, Full);
if (Full) {
if (getIsTemplateResolved())
printEncodedArgs(OS, Full);
LVScope *Reference = getReference();
if (Reference)
Reference->printReference(OS, Full, const_cast<LVScopeAggregate *>(this));
}
}
//===----------------------------------------------------------------------===//
// DWARF Template alias.
//===----------------------------------------------------------------------===//
bool LVScopeAlias::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
return equalNumberOfChildren(Scope);
}
void LVScopeAlias::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << formattedName(getName()) << " -> "
<< typeOffsetAsString()
<< formattedNames(getTypeQualifiedName(), typeAsString()) << "\n";
}
//===----------------------------------------------------------------------===//
// DWARF array (DW_TAG_array_type).
//===----------------------------------------------------------------------===//
void LVScopeArray::resolveExtra() {
// If the scope is an array, resolve the subrange entries and get those
// values encoded and assigned to the scope type.
// Encode the array subrange entries as part of the name.
if (getIsArrayResolved())
return;
setIsArrayResolved();
// There are 2 cases to represent the bounds information for an array:
// 1) DW_TAG_array_type
// DW_AT_type --> ref_type
// DW_TAG_subrange_type
// DW_AT_type --> ref_type (type of object)
// DW_AT_count --> value (number of elements in subrange)
// 2) DW_TAG_array_type
// DW_AT_type --> ref_type
// DW_TAG_subrange_type
// DW_AT_lower_bound --> value
// DW_AT_upper_bound --> value
// The idea is to represent the bounds as a string, depending on the format:
// 1) [count]
// 2) [lower][upper]
// Traverse scope types, looking for those types that are subranges.
LVTypes Subranges;
if (const LVTypes *Types = getTypes())
for (LVType *Type : *Types)
if (Type->getIsSubrange()) {
Type->resolve();
Subranges.push_back(Type);
}
// Use the subrange types to generate the high level name for the array.
// Check the type has been fully resolved.
if (LVElement *BaseType = getType()) {
BaseType->resolveName();
resolveFullname(BaseType);
}
// In 'resolveFullname' a check is done for double spaces in the type name.
std::stringstream ArrayInfo;
if (ElementType)
ArrayInfo << getTypeName().str() << " ";
for (const LVType *Type : Subranges) {
if (Type->getIsSubrangeCount())
// Check if we have DW_AT_count subrange style.
ArrayInfo << "[" << Type->getCount() << "]";
else {
// Get lower and upper subrange values.
unsigned LowerBound;
unsigned UpperBound;
std::tie(LowerBound, UpperBound) = Type->getBounds();
// The representation depends on the bound values. If the lower value
// is zero, treat the pair as the elements count. Otherwise, just use
// the pair, as they are representing arrays in languages other than
// C/C++ and the lower limit is not zero.
if (LowerBound)
ArrayInfo << "[" << LowerBound << ".." << UpperBound << "]";
else
ArrayInfo << "[" << UpperBound + 1 << "]";
}
}
// Update the scope name, to reflect the encoded subranges.
setName(ArrayInfo.str());
}
bool LVScopeArray::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
if (!equalNumberOfChildren(Scope))
return false;
// Despite the arrays are encoded, to reflect the dimensions, we have to
// check the subranges, in order to determine if they are the same.
if (!LVType::equals(getTypes(), Scope->getTypes()))
return false;
return true;
}
void LVScopeArray::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << typeOffsetAsString()
<< formattedName(getName()) << "\n";
}
//===----------------------------------------------------------------------===//
// An object file (single or multiple CUs).
//===----------------------------------------------------------------------===//
void LVScopeCompileUnit::addSize(LVScope *Scope, LVOffset Lower,
LVOffset Upper) {
LLVM_DEBUG({
dbgs() << format(
"CU [0x%08" PRIx64 "], Scope [0x%08" PRIx64 "], Range [0x%08" PRIx64
":0x%08" PRIx64 "], Size = %" PRId64 "\n",
getOffset(), Scope->getOffset(), Lower, Upper, Upper - Lower);
});
// There is no need to check for a previous entry, as we are traversing the
// debug information in sequential order.
LVOffset Size = Upper - Lower;
Sizes[Scope] = Size;
if (this == Scope)
// Record contribution size for the compilation unit.
CUContributionSize = Size;
}
// Update parents and children with pattern information.
void LVScopeCompileUnit::propagatePatternMatch() {
// At this stage, we have finished creating the Scopes tree and we have
// a list of elements that match the pattern specified in the command line.
// The pattern corresponds to a scope or element; mark parents and/or
// children as having that pattern, before any printing is done.
if (!options().getSelectExecute())
return;
if (MatchedScopes.size()) {
for (LVScope *Scope : MatchedScopes)
Scope->traverseParentsAndChildren(&LVScope::getHasPattern,
&LVScope::setHasPattern);
} else {
// Mark the compile unit as having a pattern to enable any requests to
// print sizes and summary as that information is recorded at that level.
setHasPattern();
}
}
void LVScopeCompileUnit::processRangeLocationCoverage(
LVValidLocation ValidLocation) {
if (options().getAttributeRange()) {
// Traverse the scopes to get scopes that have invalid ranges.
LVLocations Locations;
bool RecordInvalid = options().getWarningRanges();
getRanges(Locations, ValidLocation, RecordInvalid);
// Validate ranges associated with scopes.
if (RecordInvalid)
for (LVLocation *Location : Locations)
addInvalidRange(Location);
}
if (options().getAttributeLocation()) {
// Traverse the scopes to get locations that have invalid ranges.
LVLocations Locations;
bool RecordInvalid = options().getWarningLocations();
getLocations(Locations, ValidLocation, RecordInvalid);
// Validate ranges associated with locations.
if (RecordInvalid)
for (LVLocation *Location : Locations)
addInvalidLocation(Location);
}
}
void LVScopeCompileUnit::addMapping(LVLine *Line, LVSectionIndex SectionIndex) {
LVAddress Address = Line->getOffset();
SectionMappings.add(SectionIndex, Address, Line);
}
LVLine *LVScopeCompileUnit::lineLowerBound(LVAddress Address,
LVScope *Scope) const {
LVSectionIndex SectionIndex = getReader().getSectionIndex(Scope);
LVAddressToLine *Map = SectionMappings.findMap(SectionIndex);
if (!Map || Map->empty())
return nullptr;
LVAddressToLine::const_iterator Iter = Map->lower_bound(Address);
return (Iter != Map->end()) ? Iter->second : nullptr;
}
LVLine *LVScopeCompileUnit::lineUpperBound(LVAddress Address,
LVScope *Scope) const {
LVSectionIndex SectionIndex = getReader().getSectionIndex(Scope);
LVAddressToLine *Map = SectionMappings.findMap(SectionIndex);
if (!Map || Map->empty())
return nullptr;
LVAddressToLine::const_iterator Iter = Map->upper_bound(Address);
if (Iter != Map->begin())
Iter = std::prev(Iter);
return Iter->second;
}
LVLineRange LVScopeCompileUnit::lineRange(LVLocation *Location) const {
// The parent of a location can be a symbol or a scope.
LVElement *Element = Location->getParent();
LVScope *Parent = Element->getIsScope() ? static_cast<LVScope *>(Element)
: Element->getParentScope();
LVLine *LowLine = lineLowerBound(Location->getLowerAddress(), Parent);
LVLine *HighLine = lineUpperBound(Location->getUpperAddress(), Parent);
return LVLineRange(LowLine, HighLine);
}
StringRef LVScopeCompileUnit::getFilename(size_t Index) const {
if (Index <= 0 || Index > Filenames.size())
return StringRef();
return getStringPool().getString(Filenames[Index - 1]);
}
bool LVScopeCompileUnit::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
return getNameIndex() == Scope->getNameIndex();
}
void LVScopeCompileUnit::incrementPrintedLines() {
options().getSelectExecute() ? ++Found.Lines : ++Printed.Lines;
}
void LVScopeCompileUnit::incrementPrintedScopes() {
options().getSelectExecute() ? ++Found.Scopes : ++Printed.Scopes;
}
void LVScopeCompileUnit::incrementPrintedSymbols() {
options().getSelectExecute() ? ++Found.Symbols : ++Printed.Symbols;
}
void LVScopeCompileUnit::incrementPrintedTypes() {
options().getSelectExecute() ? ++Found.Types : ++Printed.Types;
}
// Values are used by '--summary' option (allocated).
void LVScopeCompileUnit::increment(LVLine *Line) {
if (Line->getIncludeInPrint())
++Allocated.Lines;
}
void LVScopeCompileUnit::increment(LVScope *Scope) {
if (Scope->getIncludeInPrint())
++Allocated.Scopes;
}
void LVScopeCompileUnit::increment(LVSymbol *Symbol) {
if (Symbol->getIncludeInPrint())
++Allocated.Symbols;
}
void LVScopeCompileUnit::increment(LVType *Type) {
if (Type->getIncludeInPrint())
++Allocated.Types;
}
// A new element has been added to the scopes tree. Take the following steps:
// Increase the added element counters, for printing summary.
// During comparison notify the Reader of the new element.
void LVScopeCompileUnit::addedElement(LVLine *Line) {
increment(Line);
getReader().notifyAddedElement(Line);
}
void LVScopeCompileUnit::addedElement(LVScope *Scope) {
increment(Scope);
getReader().notifyAddedElement(Scope);
}
void LVScopeCompileUnit::addedElement(LVSymbol *Symbol) {
increment(Symbol);
getReader().notifyAddedElement(Symbol);
}
void LVScopeCompileUnit::addedElement(LVType *Type) {
increment(Type);
getReader().notifyAddedElement(Type);
}
// Record unsuported DWARF tags.
void LVScopeCompileUnit::addDebugTag(dwarf::Tag Target, LVOffset Offset) {
addItem<LVTagOffsetsMap, LVOffsetList, dwarf::Tag, LVOffset>(&DebugTags,
Target, Offset);
}
// Record elements with invalid offsets.
void LVScopeCompileUnit::addInvalidOffset(LVOffset Offset, LVElement *Element) {
if (WarningOffsets.find(Offset) == WarningOffsets.end())
WarningOffsets.emplace(Offset, Element);
}
// Record symbols with invalid coverage values.
void LVScopeCompileUnit::addInvalidCoverage(LVSymbol *Symbol) {
LVOffset Offset = Symbol->getOffset();
if (InvalidCoverages.find(Offset) == InvalidCoverages.end())
InvalidCoverages.emplace(Offset, Symbol);
}
// Record symbols with invalid locations.
void LVScopeCompileUnit::addInvalidLocation(LVLocation *Location) {
addInvalidLocationOrRange(Location, Location->getParentSymbol(),
&InvalidLocations);
}
// Record scopes with invalid ranges.
void LVScopeCompileUnit::addInvalidRange(LVLocation *Location) {
addInvalidLocationOrRange(Location, Location->getParentScope(),
&InvalidRanges);
}
// Record line zero.
void LVScopeCompileUnit::addLineZero(LVLine *Line) {
LVScope *Scope = Line->getParentScope();
LVOffset Offset = Scope->getOffset();
addInvalidOffset(Offset, Scope);
addItem<LVOffsetLinesMap, LVLines, LVOffset, LVLine *>(&LinesZero, Offset,
Line);
}
void LVScopeCompileUnit::printLocalNames(raw_ostream &OS, bool Full) const {
if (!options().getPrintFormatting())
return;
// Calculate an indentation value, to preserve a nice layout.
size_t Indentation = options().indentationSize() +
lineNumberAsString().length() +
indentAsString(getLevel() + 1).length() + 3;
enum class Option { Directory, File };
auto PrintNames = [&](Option Action) {
StringRef Kind = Action == Option::Directory ? "Directory" : "File";
std::set<std::string> UniqueNames;
for (size_t Index : Filenames) {
// In the case of missing directory name in the .debug_line table,
// the returned string has a leading '/'.
StringRef Name = getStringPool().getString(Index);
size_t Pos = Name.rfind('/');
if (Pos != std::string::npos)
Name = (Action == Option::File) ? Name.substr(Pos + 1)
: Name.substr(0, Pos);
// Collect only unique names.
UniqueNames.insert(std::string(Name));
}
for (const std::string &Name : UniqueNames)
OS << std::string(Indentation, ' ') << formattedKind(Kind) << " "
<< formattedName(Name) << "\n";
};
if (options().getAttributeDirectories())
PrintNames(Option::Directory);
if (options().getAttributeFiles())
PrintNames(Option::File);
if (options().getAttributePublics()) {
StringRef Kind = "Public";
// The public names are indexed by 'LVScope *'. We want to print
// them by logical element address, to show the scopes layout.
using OffsetSorted = std::map<LVAddress, LVPublicNames::const_iterator>;
OffsetSorted SortedNames;
for (LVPublicNames::const_iterator Iter = PublicNames.begin();
Iter != PublicNames.end(); ++Iter)
SortedNames.emplace(Iter->first->getOffset(), Iter);
LVPublicNames::const_iterator Iter;
for (OffsetSorted::reference Entry : SortedNames) {
Iter = Entry.second;
OS << std::string(Indentation, ' ') << formattedKind(Kind) << " "
<< formattedName((*Iter).first->getName());
if (options().getAttributeOffset()) {
LVAddress Address = (*Iter).second.first;
size_t Size = (*Iter).second.second;
OS << " [" << hexString(Address) << ":" << hexString(Address + Size)
<< "]";
}
OS << "\n";
}
}
}
void LVScopeCompileUnit::printWarnings(raw_ostream &OS, bool Full) const {
auto PrintHeader = [&](const char *Header) { OS << "\n" << Header << ":\n"; };
auto PrintFooter = [&](auto &Set) {
if (Set.empty())
OS << "None\n";
};
auto PrintOffset = [&](unsigned &Count, LVOffset Offset) {
if (Count == 5) {
Count = 0;
OS << "\n";
}
++Count;
OS << hexSquareString(Offset) << " ";
};
auto PrintElement = [&](const LVOffsetElementMap &Map, LVOffset Offset) {
LVOffsetElementMap::const_iterator Iter = Map.find(Offset);
LVElement *Element = Iter != Map.end() ? Iter->second : nullptr;
OS << "[" << hexString(Offset) << "]";
if (Element)
OS << " " << formattedKind(Element->kind()) << " "
<< formattedName(Element->getName());
OS << "\n";
};
auto PrintInvalidLocations = [&](const LVOffsetLocationsMap &Map,
const char *Header) {
PrintHeader(Header);
for (LVOffsetLocationsMap::const_reference Entry : Map) {
PrintElement(WarningOffsets, Entry.first);
for (const LVLocation *Location : *Entry.second)
OS << hexSquareString(Location->getOffset()) << " "
<< Location->getIntervalInfo() << "\n";
}
PrintFooter(Map);
};
if (options().getInternalTag() && getReader().isBinaryTypeELF()) {
PrintHeader("Unsupported DWARF Tags");
for (LVTagOffsetsMap::const_reference Entry : DebugTags) {
OS << format("\n0x%02x", (unsigned)Entry.first) << ", "
<< dwarf::TagString(Entry.first) << "\n";
unsigned Count = 0;
for (const LVOffset &Offset : *Entry.second)
PrintOffset(Count, Offset);
OS << "\n";
}
PrintFooter(DebugTags);
}
if (options().getWarningCoverages()) {
PrintHeader("Symbols Invalid Coverages");
for (LVOffsetSymbolMap::const_reference Entry : InvalidCoverages) {
// Symbol basic information.
LVSymbol *Symbol = Entry.second;
OS << hexSquareString(Entry.first) << " {Coverage} "
<< format("%.2f%%", Symbol->getCoveragePercentage()) << " "
<< formattedKind(Symbol->kind()) << " "
<< formattedName(Symbol->getName()) << "\n";
}
PrintFooter(InvalidCoverages);
}
if (options().getWarningLines()) {
PrintHeader("Lines Zero References");
for (LVOffsetLinesMap::const_reference Entry : LinesZero) {
PrintElement(WarningOffsets, Entry.first);
unsigned Count = 0;
for (const LVLine *Line : *Entry.second)
PrintOffset(Count, Line->getOffset());
OS << "\n";
}
PrintFooter(LinesZero);
}
if (options().getWarningLocations())
PrintInvalidLocations(InvalidLocations, "Invalid Location Ranges");
if (options().getWarningRanges())
PrintInvalidLocations(InvalidRanges, "Invalid Code Ranges");
}
void LVScopeCompileUnit::printTotals(raw_ostream &OS) const {
OS << "\nTotals by lexical level:\n";
for (size_t Index = 1; Index <= MaxSeenLevel; ++Index)
OS << format("[%03d]: %10d (%6.2f%%)\n", Index, Totals[Index].first,
Totals[Index].second);
}
void LVScopeCompileUnit::printScopeSize(const LVScope *Scope, raw_ostream &OS) {
LVSizesMap::const_iterator Iter = Sizes.find(Scope);
if (Iter != Sizes.end()) {
LVOffset Size = Iter->second;
assert(CUContributionSize && "Invalid CU contribution size.");
// Get a percentage rounded to two decimal digits. This avoids
// implementation-defined rounding inside printing functions.
float Percentage =
rint((float(Size) / CUContributionSize) * 100.0 * 100.0) / 100.0;
OS << format("%10" PRId64 " (%6.2f%%) : ", Size, Percentage);
Scope->print(OS);
// Keep record of the total sizes at each lexical level.
LVLevel Level = Scope->getLevel();
if (Level > MaxSeenLevel)
MaxSeenLevel = Level;
if (Level >= Totals.size())
Totals.resize(2 * Level);
Totals[Level].first += Size;
Totals[Level].second += Percentage;
}
}
void LVScopeCompileUnit::printSizes(raw_ostream &OS) const {
// Recursively print the contributions for each scope.
std::function<void(const LVScope *Scope)> PrintScope =
[&](const LVScope *Scope) {
// If we have selection criteria, then use only the selected scopes.
if (options().getSelectExecute() && options().getReportAnyView()) {
for (const LVScope *Scope : MatchedScopes)
if (Scope->getLevel() < options().getOutputLevel())
printScopeSize(Scope, OS);
return;
}
if (Scope->getLevel() < options().getOutputLevel()) {
if (const LVScopes *Scopes = Scope->getScopes())
for (const LVScope *Scope : *Scopes) {
printScopeSize(Scope, OS);
PrintScope(Scope);
}
}
};
bool PrintScopes = options().getPrintScopes();
if (!PrintScopes)
options().setPrintScopes();
getReader().setCompileUnit(const_cast<LVScopeCompileUnit *>(this));
OS << "\nScope Sizes:\n";
options().resetPrintFormatting();
options().setPrintOffset();
// Print the scopes regardless if the user has requested any scopes
// printing. Set the option just to allow printing the contributions.
printScopeSize(this, OS);
PrintScope(this);
// Print total scope sizes by level.
printTotals(OS);
options().resetPrintOffset();
options().setPrintFormatting();
if (!PrintScopes)
options().resetPrintScopes();
}
void LVScopeCompileUnit::printSummary(raw_ostream &OS) const {
printSummary(OS, options().getSelectExecute() ? Found : Printed, "Printed");
}
// Print summary details for the scopes tree.
void LVScopeCompileUnit::printSummary(raw_ostream &OS, const LVCounter &Counter,
const char *Header) const {
std::string Separator = std::string(29, '-');
auto PrintSeparator = [&]() { OS << Separator << "\n"; };
auto PrintHeadingRow = [&](const char *T, const char *U, const char *V) {
OS << format("%-9s%9s %9s\n", T, U, V);
};
auto PrintDataRow = [&](const char *T, unsigned U, unsigned V) {
OS << format("%-9s%9d %9d\n", T, U, V);
};
OS << "\n";
PrintSeparator();
PrintHeadingRow("Element", "Total", Header);
PrintSeparator();
PrintDataRow("Scopes", Allocated.Scopes, Counter.Scopes);
PrintDataRow("Symbols", Allocated.Symbols, Counter.Symbols);
PrintDataRow("Types", Allocated.Types, Counter.Types);
PrintDataRow("Lines", Allocated.Lines, Counter.Lines);
PrintSeparator();
PrintDataRow(
"Total",
Allocated.Scopes + Allocated.Symbols + Allocated.Lines + Allocated.Types,
Counter.Scopes + Counter.Symbols + Counter.Lines + Counter.Types);
}
void LVScopeCompileUnit::printMatchedElements(raw_ostream &OS,
bool UseMatchedElements) {
LVSortFunction SortFunction = getSortFunction();
if (SortFunction)
std::stable_sort(MatchedElements.begin(), MatchedElements.end(),
SortFunction);
// Check the type of elements required to be printed. 'MatchedElements'
// contains generic elements (lines, scopes, symbols, types). If we have a
// request to print any generic element, then allow the normal printing.
if (options().getPrintAnyElement()) {
if (UseMatchedElements)
OS << "\n";
print(OS);
if (UseMatchedElements) {
// Print the details for the matched elements.
for (const LVElement *Element : MatchedElements)
Element->print(OS);
} else {
// Print the view for the matched scopes.
for (const LVScope *Scope : MatchedScopes) {
Scope->print(OS);
if (const LVElements *Elements = Scope->getChildren())
for (LVElement *Element : *Elements)
Element->print(OS);
}
}
// Print any requested summary.
if (options().getPrintSummary()) {
// In the case of '--report=details' the matched elements are
// already counted; just proceed to print any requested summary.
// Otherwise, count them and print the summary.
if (!options().getReportList()) {
for (LVElement *Element : MatchedElements) {
if (!Element->getIncludeInPrint())
continue;
if (Element->getIsType())
++Found.Types;
else if (Element->getIsSymbol())
++Found.Symbols;
else if (Element->getIsScope())
++Found.Scopes;
else if (Element->getIsLine())
++Found.Lines;
else
assert(Element && "Invalid element.");
}
}
printSummary(OS, Found, "Printed");
}
}
// Check if we have a request to print sizes for the matched elements
// that are scopes.
if (options().getPrintSizes()) {
OS << "\n";
print(OS);
OS << "\nScope Sizes:\n";
printScopeSize(this, OS);
for (LVElement *Element : MatchedElements)
if (Element->getIsScope())
// Print sizes only for scopes.
printScopeSize(static_cast<LVScope *>(Element), OS);
printTotals(OS);
}
}
void LVScopeCompileUnit::print(raw_ostream &OS, bool Full) const {
// Reset counters for printed and found elements.
const_cast<LVScopeCompileUnit *>(this)->Found.reset();
const_cast<LVScopeCompileUnit *>(this)->Printed.reset();
if (getReader().doPrintScope(this) && options().getPrintFormatting())
OS << "\n";
LVScope::print(OS, Full);
}
void LVScopeCompileUnit::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " '" << getName() << "'\n";
if (options().getPrintFormatting() && options().getAttributeProducer())
printAttributes(OS, Full, "{Producer} ",
const_cast<LVScopeCompileUnit *>(this), getProducer(),
/*UseQuotes=*/true,
/*PrintRef=*/false);
// Reset file index, to allow its children to print the correct filename.
options().resetFilenameIndex();
// Print any files, directories, public names and active ranges.
if (Full) {
printLocalNames(OS, Full);
printActiveRanges(OS, Full);
}
}
//===----------------------------------------------------------------------===//
// DWARF enumeration (DW_TAG_enumeration_type).
//===----------------------------------------------------------------------===//
bool LVScopeEnumeration::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
return equalNumberOfChildren(Scope);
}
void LVScopeEnumeration::printExtra(raw_ostream &OS, bool Full) const {
// Print the full type name.
OS << formattedKind(kind()) << " " << (getIsEnumClass() ? "class " : "")
<< formattedName(getName());
if (getHasType())
OS << " -> " << typeOffsetAsString()
<< formattedNames(getTypeQualifiedName(), typeAsString());
OS << "\n";
}
//===----------------------------------------------------------------------===//
// DWARF formal parameter pack (DW_TAG_GNU_formal_parameter_pack).
//===----------------------------------------------------------------------===//
bool LVScopeFormalPack::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
return equalNumberOfChildren(Scope);
}
void LVScopeFormalPack::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << formattedName(getName()) << "\n";
}
//===----------------------------------------------------------------------===//
// DWARF function.
//===----------------------------------------------------------------------===//
void LVScopeFunction::resolveReferences() {
// Before we resolve any references to other elements, check if we have
// to insert missing elements, that have been stripped, which will help
// the logical view comparison.
if (options().getAttributeInserted() && getHasReferenceAbstract() &&
!getAddedMissing()) {
// Add missing elements at the function scope.
addMissingElements(getReference());
if (Scopes)
for (LVScope *Scope : *Scopes)
if (Scope->getHasReferenceAbstract() && !Scope->getAddedMissing())
Scope->addMissingElements(Scope->getReference());
}
LVScope::resolveReferences();
// The DWARF 'extern' attribute is generated at the class level.
// 0000003f DW_TAG_class_type "CLASS"
// 00000048 DW_TAG_subprogram "bar"
// DW_AT_external DW_FORM_flag_present
// 00000070 DW_TAG_subprogram "bar"
// DW_AT_specification DW_FORM_ref4 0x00000048
// If there is a reference linking the declaration and definition, mark
// the definition as extern, to facilitate the logical view comparison.
if (getHasReferenceSpecification()) {
LVScope *Reference = getReference();
if (Reference && Reference->getIsExternal()) {
Reference->resetIsExternal();
setIsExternal();
}
}
// Resolve the function associated type.
if (!getType())
if (LVScope *Reference = getReference())
setType(Reference->getType());
}
void LVScopeFunction::setName(StringRef ObjectName) {
LVScope::setName(ObjectName);
// Check for system generated functions.
getReader().isSystemEntry(this, ObjectName);
}
void LVScopeFunction::resolveExtra() {
// Check if we need to encode the template arguments.
if (getIsTemplate())
resolveTemplate();
}
bool LVScopeFunction::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
// When comparing logical elements, ignore any difference in the children.
if (options().getCompareContext() && !equalNumberOfChildren(Scope))
return false;
// Check if the linkage name matches.
if (getLinkageNameIndex() != Scope->getLinkageNameIndex())
return false;
// Check if the parameters match in the case of templates.
if (!LVType::parametersMatch(getTypes(), Scope->getTypes()))
return false;
// Check if the arguments match.
if (!LVSymbol::parametersMatch(getSymbols(), Scope->getSymbols()))
return false;
// Check if the lines match.
if (options().getCompareLines() &&
!LVLine::equals(getLines(), Scope->getLines()))
return false;
// Check if any reference is the same.
if (!referenceMatch(Scope))
return false;
if (getReference() && !getReference()->equals(Scope->getReference()))
return false;
return true;
}
LVScope *LVScopeFunction::findEqualScope(const LVScopes *Scopes) const {
assert(Scopes && "Scopes must not be nullptr");
// Go through candidates and try to find a best match.
for (LVScope *Scope : *Scopes)
// Match arguments, children, lines, references.
if (equals(Scope))
return Scope;
return nullptr;
}
void LVScopeFunction::printExtra(raw_ostream &OS, bool Full) const {
LVScope *Reference = getReference();
// Inline attributes based on the reference element.
uint32_t InlineCode =
Reference ? Reference->getInlineCode() : getInlineCode();
// Accessibility depends on the parent (class, structure).
uint32_t AccessCode = 0;
if (getIsMember())
AccessCode = getParentScope()->getIsClass() ? dwarf::DW_ACCESS_private
: dwarf::DW_ACCESS_public;
std::string Attributes =
getIsCallSite()
? ""
: formatAttributes(externalString(), accessibilityString(AccessCode),
inlineCodeString(InlineCode), virtualityString());
OS << formattedKind(kind()) << " " << Attributes << formattedName(getName())
<< discriminatorAsString() << " -> " << typeOffsetAsString()
<< formattedNames(getTypeQualifiedName(), typeAsString()) << "\n";
// Print any active ranges.
if (Full) {
if (getIsTemplateResolved())
printEncodedArgs(OS, Full);
printActiveRanges(OS, Full);
if (getLinkageNameIndex())
printLinkageName(OS, Full, const_cast<LVScopeFunction *>(this),
const_cast<LVScopeFunction *>(this));
if (Reference)
Reference->printReference(OS, Full, const_cast<LVScopeFunction *>(this));
}
}
//===----------------------------------------------------------------------===//
// DWARF inlined function (DW_TAG_inlined_function).
//===----------------------------------------------------------------------===//
void LVScopeFunctionInlined::resolveExtra() {
// Check if we need to encode the template arguments.
if (getIsTemplate())
resolveTemplate();
}
bool LVScopeFunctionInlined::equals(const LVScope *Scope) const {
if (!LVScopeFunction::equals(Scope))
return false;
// Check if any reference is the same.
if (getHasDiscriminator() && Scope->getHasDiscriminator())
if (getDiscriminator() != Scope->getDiscriminator())
return false;
// Check the call site information.
if (getCallFilenameIndex() != Scope->getCallFilenameIndex() ||
getCallLineNumber() != Scope->getCallLineNumber())
return false;
return true;
}
LVScope *LVScopeFunctionInlined::findEqualScope(const LVScopes *Scopes) const {
return LVScopeFunction::findEqualScope(Scopes);
}
void LVScopeFunctionInlined::printExtra(raw_ostream &OS, bool Full) const {
LVScopeFunction::printExtra(OS, Full);
}
//===----------------------------------------------------------------------===//
// DWARF subroutine type.
//===----------------------------------------------------------------------===//
// Resolve a Subroutine Type (Callback).
void LVScopeFunctionType::resolveExtra() {
if (getIsMemberPointerResolved())
return;
setIsMemberPointerResolved();
// The encoded string has the return type and the formal parameters type.
std::string Name(typeAsString());
Name.append(" (*)");
Name.append("(");
// Traverse the scope symbols, looking for those which are parameters.
if (const LVSymbols *Symbols = getSymbols()) {
bool AddComma = false;
for (LVSymbol *Symbol : *Symbols)
if (Symbol->getIsParameter()) {
Symbol->resolve();
if (LVElement *Type = Symbol->getType())
Type->resolveName();
if (AddComma)
Name.append(", ");
Name.append(std::string(Symbol->getTypeName()));
AddComma = true;
}
}
Name.append(")");
// Update the scope name, to reflect the encoded parameters.
setName(Name);
}
//===----------------------------------------------------------------------===//
// DWARF namespace (DW_TAG_namespace).
//===----------------------------------------------------------------------===//
bool LVScopeNamespace::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
if (!equalNumberOfChildren(Scope))
return false;
// Check if any reference is the same.
if (!referenceMatch(Scope))
return false;
if (getReference() && !getReference()->equals(Scope->getReference()))
return false;
return true;
}
LVScope *LVScopeNamespace::findEqualScope(const LVScopes *Scopes) const {
assert(Scopes && "Scopes must not be nullptr");
// Go through candidates and try to find a best match.
for (LVScope *Scope : *Scopes)
if (equals(Scope))
return Scope;
return nullptr;
}
void LVScopeNamespace::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << formattedName(getName()) << "\n";
// Print any active ranges.
if (Full) {
printActiveRanges(OS, Full);
if (LVScope *Reference = getReference())
Reference->printReference(OS, Full, const_cast<LVScopeNamespace *>(this));
}
}
//===----------------------------------------------------------------------===//
// An object file (single or multiple CUs).
//===----------------------------------------------------------------------===//
void LVScopeRoot::processRangeInformation() {
if (!options().getAttributeAnyLocation())
return;
if (Scopes)
for (LVScope *Scope : *Scopes) {
LVScopeCompileUnit *CompileUnit =
static_cast<LVScopeCompileUnit *>(Scope);
getReader().setCompileUnit(CompileUnit);
CompileUnit->processRangeLocationCoverage();
}
}
bool LVScopeRoot::equals(const LVScope *Scope) const {
return LVScope::equals(Scope);
}
void LVScopeRoot::print(raw_ostream &OS, bool Full) const {
OS << "\nLogical View:\n";
LVScope::print(OS, Full);
}
void LVScopeRoot::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << formattedName(getName()) << "";
if (options().getAttributeFormat())
OS << " -> " << getFileFormatName();
OS << "\n";
}
Error LVScopeRoot::doPrintMatches(bool Split, raw_ostream &OS,
bool UseMatchedElements) const {
// During a view output splitting, use the output stream created by the
// split context, then switch to the reader output stream.
static raw_ostream *StreamSplit = &OS;
if (Scopes) {
if (UseMatchedElements)
options().resetPrintFormatting();
print(OS);
for (LVScope *Scope : *Scopes) {
getReader().setCompileUnit(const_cast<LVScope *>(Scope));
// If 'Split', we use the scope name (CU name) as the ouput file; the
// delimiters in the pathname, must be replaced by a normal character.
if (Split) {
std::string ScopeName(Scope->getName());
if (std::error_code EC =
getReaderSplitContext().open(ScopeName, ".txt", OS))
return createStringError(EC, "Unable to create split output file %s",
ScopeName.c_str());
StreamSplit = static_cast<raw_ostream *>(&getReaderSplitContext().os());
}
Scope->printMatchedElements(*StreamSplit, UseMatchedElements);
// Done printing the compile unit. Restore the original output context.
if (Split) {
getReaderSplitContext().close();
StreamSplit = &getReader().outputStream();
}
}
if (UseMatchedElements)
options().setPrintFormatting();
}
return Error::success();
}
//===----------------------------------------------------------------------===//
// DWARF template parameter pack (DW_TAG_GNU_template_parameter_pack).
//===----------------------------------------------------------------------===//
bool LVScopeTemplatePack::equals(const LVScope *Scope) const {
if (!LVScope::equals(Scope))
return false;
return equalNumberOfChildren(Scope);
}
void LVScopeTemplatePack::printExtra(raw_ostream &OS, bool Full) const {
OS << formattedKind(kind()) << " " << formattedName(getName()) << "\n";
}