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//===--- ASTDiagnostic.cpp - Diagnostic Printing Hooks for AST Nodes ------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements a diagnostic formatting hook for AST elements.
//
//===----------------------------------------------------------------------===//
#include "clang/AST/ASTDiagnostic.h"
#include "clang/AST/ASTContext.h"
#include "clang/AST/DeclObjC.h"
#include "clang/AST/DeclTemplate.h"
#include "clang/AST/ExprCXX.h"
#include "clang/AST/TemplateBase.h"
#include "clang/AST/Type.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/Support/raw_ostream.h"
using namespace clang;
// Returns a desugared version of the QualType, and marks ShouldAKA as true
// whenever we remove significant sugar from the type.
static QualType Desugar(ASTContext &Context, QualType QT, bool &ShouldAKA) {
QualifierCollector QC;
while (true) {
const Type *Ty = QC.strip(QT);
// Don't aka just because we saw an elaborated type...
if (const ElaboratedType *ET = dyn_cast<ElaboratedType>(Ty)) {
QT = ET->desugar();
continue;
}
// ... or a paren type ...
if (const ParenType *PT = dyn_cast<ParenType>(Ty)) {
QT = PT->desugar();
continue;
}
// ...or a substituted template type parameter ...
if (const SubstTemplateTypeParmType *ST =
dyn_cast<SubstTemplateTypeParmType>(Ty)) {
QT = ST->desugar();
continue;
}
// ...or an attributed type...
if (const AttributedType *AT = dyn_cast<AttributedType>(Ty)) {
QT = AT->desugar();
continue;
}
// ... or an auto type.
if (const AutoType *AT = dyn_cast<AutoType>(Ty)) {
if (!AT->isSugared())
break;
QT = AT->desugar();
continue;
}
// Don't desugar template specializations, unless it's an alias template.
if (const TemplateSpecializationType *TST
= dyn_cast<TemplateSpecializationType>(Ty))
if (!TST->isTypeAlias())
break;
// Don't desugar magic Objective-C types.
if (QualType(Ty,0) == Context.getObjCIdType() ||
QualType(Ty,0) == Context.getObjCClassType() ||
QualType(Ty,0) == Context.getObjCSelType() ||
QualType(Ty,0) == Context.getObjCProtoType())
break;
// Don't desugar va_list.
if (QualType(Ty,0) == Context.getBuiltinVaListType())
break;
// Otherwise, do a single-step desugar.
QualType Underlying;
bool IsSugar = false;
switch (Ty->getTypeClass()) {
#define ABSTRACT_TYPE(Class, Base)
#define TYPE(Class, Base) \
case Type::Class: { \
const Class##Type *CTy = cast<Class##Type>(Ty); \
if (CTy->isSugared()) { \
IsSugar = true; \
Underlying = CTy->desugar(); \
} \
break; \
}
#include "clang/AST/TypeNodes.def"
}
// If it wasn't sugared, we're done.
if (!IsSugar)
break;
// If the desugared type is a vector type, we don't want to expand
// it, it will turn into an attribute mess. People want their "vec4".
if (isa<VectorType>(Underlying))
break;
// Don't desugar through the primary typedef of an anonymous type.
if (const TagType *UTT = Underlying->getAs<TagType>())
if (const TypedefType *QTT = dyn_cast<TypedefType>(QT))
if (UTT->getDecl()->getTypedefNameForAnonDecl() == QTT->getDecl())
break;
// Record that we actually looked through an opaque type here.
ShouldAKA = true;
QT = Underlying;
}
// If we have a pointer-like type, desugar the pointee as well.
// FIXME: Handle other pointer-like types.
if (const PointerType *Ty = QT->getAs<PointerType>()) {
QT = Context.getPointerType(Desugar(Context, Ty->getPointeeType(),
ShouldAKA));
} else if (const LValueReferenceType *Ty = QT->getAs<LValueReferenceType>()) {
QT = Context.getLValueReferenceType(Desugar(Context, Ty->getPointeeType(),
ShouldAKA));
} else if (const RValueReferenceType *Ty = QT->getAs<RValueReferenceType>()) {
QT = Context.getRValueReferenceType(Desugar(Context, Ty->getPointeeType(),
ShouldAKA));
}
return QC.apply(Context, QT);
}
/// \brief Convert the given type to a string suitable for printing as part of
/// a diagnostic.
///
/// There are four main criteria when determining whether we should have an
/// a.k.a. clause when pretty-printing a type:
///
/// 1) Some types provide very minimal sugar that doesn't impede the
/// user's understanding --- for example, elaborated type
/// specifiers. If this is all the sugar we see, we don't want an
/// a.k.a. clause.
/// 2) Some types are technically sugared but are much more familiar
/// when seen in their sugared form --- for example, va_list,
/// vector types, and the magic Objective C types. We don't
/// want to desugar these, even if we do produce an a.k.a. clause.
/// 3) Some types may have already been desugared previously in this diagnostic.
/// if this is the case, doing another "aka" would just be clutter.
/// 4) Two different types within the same diagnostic have the same output
/// string. In this case, force an a.k.a with the desugared type when
/// doing so will provide additional information.
///
/// \param Context the context in which the type was allocated
/// \param Ty the type to print
/// \param QualTypeVals pointer values to QualTypes which are used in the
/// diagnostic message
static std::string
ConvertTypeToDiagnosticString(ASTContext &Context, QualType Ty,
const DiagnosticsEngine::ArgumentValue *PrevArgs,
unsigned NumPrevArgs,
ArrayRef<intptr_t> QualTypeVals) {
// FIXME: Playing with std::string is really slow.
bool ForceAKA = false;
QualType CanTy = Ty.getCanonicalType();
std::string S = Ty.getAsString(Context.getPrintingPolicy());
std::string CanS = CanTy.getAsString(Context.getPrintingPolicy());
for (unsigned I = 0, E = QualTypeVals.size(); I != E; ++I) {
QualType CompareTy =
QualType::getFromOpaquePtr(reinterpret_cast<void*>(QualTypeVals[I]));
if (CompareTy.isNull())
continue;
if (CompareTy == Ty)
continue; // Same types
QualType CompareCanTy = CompareTy.getCanonicalType();
if (CompareCanTy == CanTy)
continue; // Same canonical types
std::string CompareS = CompareTy.getAsString(Context.getPrintingPolicy());
bool aka;
QualType CompareDesugar = Desugar(Context, CompareTy, aka);
std::string CompareDesugarStr =
CompareDesugar.getAsString(Context.getPrintingPolicy());
if (CompareS != S && CompareDesugarStr != S)
continue; // The type string is different than the comparison string
// and the desugared comparison string.
std::string CompareCanS =
CompareCanTy.getAsString(Context.getPrintingPolicy());
if (CompareCanS == CanS)
continue; // No new info from canonical type
ForceAKA = true;
break;
}
// Check to see if we already desugared this type in this
// diagnostic. If so, don't do it again.
bool Repeated = false;
for (unsigned i = 0; i != NumPrevArgs; ++i) {
// TODO: Handle ak_declcontext case.
if (PrevArgs[i].first == DiagnosticsEngine::ak_qualtype) {
void *Ptr = (void*)PrevArgs[i].second;
QualType PrevTy(QualType::getFromOpaquePtr(Ptr));
if (PrevTy == Ty) {
Repeated = true;
break;
}
}
}
// Consider producing an a.k.a. clause if removing all the direct
// sugar gives us something "significantly different".
if (!Repeated) {
bool ShouldAKA = false;
QualType DesugaredTy = Desugar(Context, Ty, ShouldAKA);
if (ShouldAKA || ForceAKA) {
if (DesugaredTy == Ty) {
DesugaredTy = Ty.getCanonicalType();
}
std::string akaStr = DesugaredTy.getAsString(Context.getPrintingPolicy());
if (akaStr != S) {
S = "'" + S + "' (aka '" + akaStr + "')";
return S;
}
}
}
S = "'" + S + "'";
return S;
}
static bool FormatTemplateTypeDiff(ASTContext &Context, QualType FromType,
QualType ToType, bool PrintTree,
bool PrintFromType, bool ElideType,
bool ShowColors, std::string &S);
void clang::FormatASTNodeDiagnosticArgument(
DiagnosticsEngine::ArgumentKind Kind,
intptr_t Val,
const char *Modifier,
unsigned ModLen,
const char *Argument,
unsigned ArgLen,
const DiagnosticsEngine::ArgumentValue *PrevArgs,
unsigned NumPrevArgs,
SmallVectorImpl<char> &Output,
void *Cookie,
ArrayRef<intptr_t> QualTypeVals) {
ASTContext &Context = *static_cast<ASTContext*>(Cookie);
std::string S;
bool NeedQuotes = true;
switch (Kind) {
default: llvm_unreachable("unknown ArgumentKind");
case DiagnosticsEngine::ak_qualtype_pair: {
TemplateDiffTypes &TDT = *reinterpret_cast<TemplateDiffTypes*>(Val);
QualType FromType =
QualType::getFromOpaquePtr(reinterpret_cast<void*>(TDT.FromType));
QualType ToType =
QualType::getFromOpaquePtr(reinterpret_cast<void*>(TDT.ToType));
if (FormatTemplateTypeDiff(Context, FromType, ToType, TDT.PrintTree,
TDT.PrintFromType, TDT.ElideType,
TDT.ShowColors, S)) {
NeedQuotes = !TDT.PrintTree;
TDT.TemplateDiffUsed = true;
break;
}
// Don't fall-back during tree printing. The caller will handle
// this case.
if (TDT.PrintTree)
return;
// Attempting to do a templete diff on non-templates. Set the variables
// and continue with regular type printing of the appropriate type.
Val = TDT.PrintFromType ? TDT.FromType : TDT.ToType;
ModLen = 0;
ArgLen = 0;
// Fall through
}
case DiagnosticsEngine::ak_qualtype: {
assert(ModLen == 0 && ArgLen == 0 &&
"Invalid modifier for QualType argument");
QualType Ty(QualType::getFromOpaquePtr(reinterpret_cast<void*>(Val)));
S = ConvertTypeToDiagnosticString(Context, Ty, PrevArgs, NumPrevArgs,
QualTypeVals);
NeedQuotes = false;
break;
}
case DiagnosticsEngine::ak_declarationname: {
DeclarationName N = DeclarationName::getFromOpaqueInteger(Val);
S = N.getAsString();
if (ModLen == 9 && !memcmp(Modifier, "objcclass", 9) && ArgLen == 0)
S = '+' + S;
else if (ModLen == 12 && !memcmp(Modifier, "objcinstance", 12)
&& ArgLen==0)
S = '-' + S;
else
assert(ModLen == 0 && ArgLen == 0 &&
"Invalid modifier for DeclarationName argument");
break;
}
case DiagnosticsEngine::ak_nameddecl: {
bool Qualified;
if (ModLen == 1 && Modifier[0] == 'q' && ArgLen == 0)
Qualified = true;
else {
assert(ModLen == 0 && ArgLen == 0 &&
"Invalid modifier for NamedDecl* argument");
Qualified = false;
}
const NamedDecl *ND = reinterpret_cast<const NamedDecl*>(Val);
ND->getNameForDiagnostic(S, Context.getPrintingPolicy(), Qualified);
break;
}
case DiagnosticsEngine::ak_nestednamespec: {
llvm::raw_string_ostream OS(S);
reinterpret_cast<NestedNameSpecifier*>(Val)->print(OS,
Context.getPrintingPolicy());
NeedQuotes = false;
break;
}
case DiagnosticsEngine::ak_declcontext: {
DeclContext *DC = reinterpret_cast<DeclContext *> (Val);
assert(DC && "Should never have a null declaration context");
if (DC->isTranslationUnit()) {
// FIXME: Get these strings from some localized place
if (Context.getLangOpts().CPlusPlus)
S = "the global namespace";
else
S = "the global scope";
} else if (TypeDecl *Type = dyn_cast<TypeDecl>(DC)) {
S = ConvertTypeToDiagnosticString(Context,
Context.getTypeDeclType(Type),
PrevArgs, NumPrevArgs, QualTypeVals);
} else {
// FIXME: Get these strings from some localized place
NamedDecl *ND = cast<NamedDecl>(DC);
if (isa<NamespaceDecl>(ND))
S += "namespace ";
else if (isa<ObjCMethodDecl>(ND))
S += "method ";
else if (isa<FunctionDecl>(ND))
S += "function ";
S += "'";
ND->getNameForDiagnostic(S, Context.getPrintingPolicy(), true);
S += "'";
}
NeedQuotes = false;
break;
}
}
if (NeedQuotes)
Output.push_back('\'');
Output.append(S.begin(), S.end());
if (NeedQuotes)
Output.push_back('\'');
}
/// TemplateDiff - A class that constructs a pretty string for a pair of
/// QualTypes. For the pair of types, a diff tree will be created containing
/// all the information about the templates and template arguments. Afterwards,
/// the tree is transformed to a string according to the options passed in.
namespace {
class TemplateDiff {
/// Context - The ASTContext which is used for comparing template arguments.
ASTContext &Context;
/// Policy - Used during expression printing.
PrintingPolicy Policy;
/// ElideType - Option to elide identical types.
bool ElideType;
/// PrintTree - Format output string as a tree.
bool PrintTree;
/// ShowColor - Diagnostics support color, so bolding will be used.
bool ShowColor;
/// FromType - When single type printing is selected, this is the type to be
/// be printed. When tree printing is selected, this type will show up first
/// in the tree.
QualType FromType;
/// ToType - The type that FromType is compared to. Only in tree printing
/// will this type be outputed.
QualType ToType;
/// Str - Storage for the output stream.
llvm::SmallString<128> Str;
/// OS - The stream used to construct the output strings.
llvm::raw_svector_ostream OS;
/// IsBold - Keeps track of the bold formatting for the output string.
bool IsBold;
/// DiffTree - A tree representation the differences between two types.
class DiffTree {
/// DiffNode - The root node stores the original type. Each child node
/// stores template arguments of their parents. For templated types, the
/// template decl is also stored.
struct DiffNode {
/// NextNode - The index of the next sibling node or 0.
unsigned NextNode;
/// ChildNode - The index of the first child node or 0.
unsigned ChildNode;
/// ParentNode - The index of the parent node.
unsigned ParentNode;
/// FromType, ToType - The type arguments.
QualType FromType, ToType;
/// FromExpr, ToExpr - The expression arguments.
Expr *FromExpr, *ToExpr;
/// FromTD, ToTD - The template decl for template template
/// arguments or the type arguments that are templates.
TemplateDecl *FromTD, *ToTD;
/// FromQual, ToQual - Qualifiers for template types.
Qualifiers FromQual, ToQual;
/// FromInt, ToInt - APSInt's for integral arguments.
llvm::APSInt FromInt, ToInt;
/// IsValidFromInt, IsValidToInt - Whether the APSInt's are valid.
bool IsValidFromInt, IsValidToInt;
/// FromDefault, ToDefault - Whether the argument is a default argument.
bool FromDefault, ToDefault;
/// Same - Whether the two arguments evaluate to the same value.
bool Same;
DiffNode(unsigned ParentNode = 0)
: NextNode(0), ChildNode(0), ParentNode(ParentNode),
FromType(), ToType(), FromExpr(0), ToExpr(0), FromTD(0), ToTD(0),
FromDefault(false), ToDefault(false), Same(false) { }
};
/// FlatTree - A flattened tree used to store the DiffNodes.
llvm::SmallVector<DiffNode, 16> FlatTree;
/// CurrentNode - The index of the current node being used.
unsigned CurrentNode;
/// NextFreeNode - The index of the next unused node. Used when creating
/// child nodes.
unsigned NextFreeNode;
/// ReadNode - The index of the current node being read.
unsigned ReadNode;
public:
DiffTree() :
CurrentNode(0), NextFreeNode(1) {
FlatTree.push_back(DiffNode());
}
// Node writing functions.
/// SetNode - Sets FromTD and ToTD of the current node.
void SetNode(TemplateDecl *FromTD, TemplateDecl *ToTD) {
FlatTree[CurrentNode].FromTD = FromTD;
FlatTree[CurrentNode].ToTD = ToTD;
}
/// SetNode - Sets FromType and ToType of the current node.
void SetNode(QualType FromType, QualType ToType) {
FlatTree[CurrentNode].FromType = FromType;
FlatTree[CurrentNode].ToType = ToType;
}
/// SetNode - Set FromExpr and ToExpr of the current node.
void SetNode(Expr *FromExpr, Expr *ToExpr) {
FlatTree[CurrentNode].FromExpr = FromExpr;
FlatTree[CurrentNode].ToExpr = ToExpr;
}
/// SetNode - Set FromInt and ToInt of the current node.
void SetNode(llvm::APSInt FromInt, llvm::APSInt ToInt,
bool IsValidFromInt, bool IsValidToInt) {
FlatTree[CurrentNode].FromInt = FromInt;
FlatTree[CurrentNode].ToInt = ToInt;
FlatTree[CurrentNode].IsValidFromInt = IsValidFromInt;
FlatTree[CurrentNode].IsValidToInt = IsValidToInt;
}
/// SetNode - Set FromQual and ToQual of the current node.
void SetNode(Qualifiers FromQual, Qualifiers ToQual) {
FlatTree[CurrentNode].FromQual = FromQual;
FlatTree[CurrentNode].ToQual = ToQual;
}
/// SetSame - Sets the same flag of the current node.
void SetSame(bool Same) {
FlatTree[CurrentNode].Same = Same;
}
/// SetDefault - Sets FromDefault and ToDefault flags of the current node.
void SetDefault(bool FromDefault, bool ToDefault) {
FlatTree[CurrentNode].FromDefault = FromDefault;
FlatTree[CurrentNode].ToDefault = ToDefault;
}
/// Up - Changes the node to the parent of the current node.
void Up() {
CurrentNode = FlatTree[CurrentNode].ParentNode;
}
/// AddNode - Adds a child node to the current node, then sets that node
/// node as the current node.
void AddNode() {
FlatTree.push_back(DiffNode(CurrentNode));
DiffNode &Node = FlatTree[CurrentNode];
if (Node.ChildNode == 0) {
// If a child node doesn't exist, add one.
Node.ChildNode = NextFreeNode;
} else {
// If a child node exists, find the last child node and add a
// next node to it.
unsigned i;
for (i = Node.ChildNode; FlatTree[i].NextNode != 0;
i = FlatTree[i].NextNode) {
}
FlatTree[i].NextNode = NextFreeNode;
}
CurrentNode = NextFreeNode;
++NextFreeNode;
}
// Node reading functions.
/// StartTraverse - Prepares the tree for recursive traversal.
void StartTraverse() {
ReadNode = 0;
CurrentNode = NextFreeNode;
NextFreeNode = 0;
}
/// Parent - Move the current read node to its parent.
void Parent() {
ReadNode = FlatTree[ReadNode].ParentNode;
}
/// NodeIsTemplate - Returns true if a template decl is set, and types are
/// set.
bool NodeIsTemplate() {
return (FlatTree[ReadNode].FromTD &&
!FlatTree[ReadNode].ToType.isNull()) ||
(FlatTree[ReadNode].ToTD && !FlatTree[ReadNode].ToType.isNull());
}
/// NodeIsQualType - Returns true if a Qualtype is set.
bool NodeIsQualType() {
return !FlatTree[ReadNode].FromType.isNull() ||
!FlatTree[ReadNode].ToType.isNull();
}
/// NodeIsExpr - Returns true if an expr is set.
bool NodeIsExpr() {
return FlatTree[ReadNode].FromExpr || FlatTree[ReadNode].ToExpr;
}
/// NodeIsTemplateTemplate - Returns true if the argument is a template
/// template type.
bool NodeIsTemplateTemplate() {
return FlatTree[ReadNode].FromType.isNull() &&
FlatTree[ReadNode].ToType.isNull() &&
(FlatTree[ReadNode].FromTD || FlatTree[ReadNode].ToTD);
}
/// NodeIsAPSInt - Returns true if the arugments are stored in APSInt's.
bool NodeIsAPSInt() {
return FlatTree[ReadNode].IsValidFromInt ||
FlatTree[ReadNode].IsValidToInt;
}
/// GetNode - Gets the FromType and ToType.
void GetNode(QualType &FromType, QualType &ToType) {
FromType = FlatTree[ReadNode].FromType;
ToType = FlatTree[ReadNode].ToType;
}
/// GetNode - Gets the FromExpr and ToExpr.
void GetNode(Expr *&FromExpr, Expr *&ToExpr) {
FromExpr = FlatTree[ReadNode].FromExpr;
ToExpr = FlatTree[ReadNode].ToExpr;
}
/// GetNode - Gets the FromTD and ToTD.
void GetNode(TemplateDecl *&FromTD, TemplateDecl *&ToTD) {
FromTD = FlatTree[ReadNode].FromTD;
ToTD = FlatTree[ReadNode].ToTD;
}
/// GetNode - Gets the FromInt and ToInt.
void GetNode(llvm::APSInt &FromInt, llvm::APSInt &ToInt,
bool &IsValidFromInt, bool &IsValidToInt) {
FromInt = FlatTree[ReadNode].FromInt;
ToInt = FlatTree[ReadNode].ToInt;
IsValidFromInt = FlatTree[ReadNode].IsValidFromInt;
IsValidToInt = FlatTree[ReadNode].IsValidToInt;
}
/// GetNode - Gets the FromQual and ToQual.
void GetNode(Qualifiers &FromQual, Qualifiers &ToQual) {
FromQual = FlatTree[ReadNode].FromQual;
ToQual = FlatTree[ReadNode].ToQual;
}
/// NodeIsSame - Returns true the arguments are the same.
bool NodeIsSame() {
return FlatTree[ReadNode].Same;
}
/// HasChildrend - Returns true if the node has children.
bool HasChildren() {
return FlatTree[ReadNode].ChildNode != 0;
}
/// MoveToChild - Moves from the current node to its child.
void MoveToChild() {
ReadNode = FlatTree[ReadNode].ChildNode;
}
/// AdvanceSibling - If there is a next sibling, advance to it and return
/// true. Otherwise, return false.
bool AdvanceSibling() {
if (FlatTree[ReadNode].NextNode == 0)
return false;
ReadNode = FlatTree[ReadNode].NextNode;
return true;
}
/// HasNextSibling - Return true if the node has a next sibling.
bool HasNextSibling() {
return FlatTree[ReadNode].NextNode != 0;
}
/// FromDefault - Return true if the from argument is the default.
bool FromDefault() {
return FlatTree[ReadNode].FromDefault;
}
/// ToDefault - Return true if the to argument is the default.
bool ToDefault() {
return FlatTree[ReadNode].ToDefault;
}
/// Empty - Returns true if the tree has no information.
bool Empty() {
return !FlatTree[0].FromTD && !FlatTree[0].ToTD &&
!FlatTree[0].FromExpr && !FlatTree[0].ToExpr &&
FlatTree[0].FromType.isNull() && FlatTree[0].ToType.isNull();
}
};
DiffTree Tree;
/// TSTiterator - an iterator that is used to enter a
/// TemplateSpecializationType and read TemplateArguments inside template
/// parameter packs in order with the rest of the TemplateArguments.
struct TSTiterator {
typedef const TemplateArgument& reference;
typedef const TemplateArgument* pointer;
/// TST - the template specialization whose arguments this iterator
/// traverse over.
const TemplateSpecializationType *TST;
/// Index - the index of the template argument in TST.
unsigned Index;
/// CurrentTA - if CurrentTA is not the same as EndTA, then CurrentTA
/// points to a TemplateArgument within a parameter pack.
TemplateArgument::pack_iterator CurrentTA;
/// EndTA - the end iterator of a parameter pack
TemplateArgument::pack_iterator EndTA;
/// TSTiterator - Constructs an iterator and sets it to the first template
/// argument.
TSTiterator(const TemplateSpecializationType *TST)
: TST(TST), Index(0), CurrentTA(0), EndTA(0) {
if (isEnd()) return;
// Set to first template argument. If not a parameter pack, done.
TemplateArgument TA = TST->getArg(0);
if (TA.getKind() != TemplateArgument::Pack) return;
// Start looking into the parameter pack.
CurrentTA = TA.pack_begin();
EndTA = TA.pack_end();
// Found a valid template argument.
if (CurrentTA != EndTA) return;
// Parameter pack is empty, use the increment to get to a valid
// template argument.
++(*this);
}
/// isEnd - Returns true if the iterator is one past the end.
bool isEnd() const {
return Index == TST->getNumArgs();
}
/// &operator++ - Increment the iterator to the next template argument.
TSTiterator &operator++() {
assert(!isEnd() && "Iterator incremented past end of arguments.");
// If in a parameter pack, advance in the parameter pack.
if (CurrentTA != EndTA) {
++CurrentTA;
if (CurrentTA != EndTA)
return *this;
}
// Loop until a template argument is found, or the end is reached.
while (true) {
// Advance to the next template argument. Break if reached the end.
if (++Index == TST->getNumArgs()) break;
// If the TemplateArgument is not a parameter pack, done.
TemplateArgument TA = TST->getArg(Index);
if (TA.getKind() != TemplateArgument::Pack) break;
// Handle parameter packs.
CurrentTA = TA.pack_begin();
EndTA = TA.pack_end();
// If the parameter pack is empty, try to advance again.
if (CurrentTA != EndTA) break;
}
return *this;
}
/// operator* - Returns the appropriate TemplateArgument.
reference operator*() const {
assert(!isEnd() && "Index exceeds number of arguments.");
if (CurrentTA == EndTA)
return TST->getArg(Index);
else
return *CurrentTA;
}
/// operator-> - Allow access to the underlying TemplateArgument.
pointer operator->() const {
return &operator*();
}
};
// These functions build up the template diff tree, including functions to
// retrieve and compare template arguments.
static const TemplateSpecializationType * GetTemplateSpecializationType(
ASTContext &Context, QualType Ty) {
if (const TemplateSpecializationType *TST =
Ty->getAs<TemplateSpecializationType>())
return TST;
const RecordType *RT = Ty->getAs<RecordType>();
if (!RT)
return 0;
const ClassTemplateSpecializationDecl *CTSD =
dyn_cast<ClassTemplateSpecializationDecl>(RT->getDecl());
if (!CTSD)
return 0;
Ty = Context.getTemplateSpecializationType(
TemplateName(CTSD->getSpecializedTemplate()),
CTSD->getTemplateArgs().data(),
CTSD->getTemplateArgs().size(),
Ty.getCanonicalType());
return Ty->getAs<TemplateSpecializationType>();
}
/// DiffTemplate - recursively visits template arguments and stores the
/// argument info into a tree.
void DiffTemplate(const TemplateSpecializationType *FromTST,
const TemplateSpecializationType *ToTST) {
// Begin descent into diffing template tree.
TemplateParameterList *Params =
FromTST->getTemplateName().getAsTemplateDecl()->getTemplateParameters();
unsigned TotalArgs = 0;
for (TSTiterator FromIter(FromTST), ToIter(ToTST);
!FromIter.isEnd() || !ToIter.isEnd(); ++TotalArgs) {
Tree.AddNode();
// Get the parameter at index TotalArgs. If index is larger
// than the total number of parameters, then there is an
// argument pack, so re-use the last parameter.
NamedDecl *ParamND = Params->getParam(
(TotalArgs < Params->size()) ? TotalArgs
: Params->size() - 1);
// Handle Types
if (TemplateTypeParmDecl *DefaultTTPD =
dyn_cast<TemplateTypeParmDecl>(ParamND)) {
QualType FromType, ToType;
GetType(FromIter, DefaultTTPD, FromType);
GetType(ToIter, DefaultTTPD, ToType);
Tree.SetNode(FromType, ToType);
Tree.SetDefault(FromIter.isEnd() && !FromType.isNull(),
ToIter.isEnd() && !ToType.isNull());
if (!FromType.isNull() && !ToType.isNull()) {
if (Context.hasSameType(FromType, ToType)) {
Tree.SetSame(true);
} else {
Qualifiers FromQual = FromType.getQualifiers(),
ToQual = ToType.getQualifiers();
const TemplateSpecializationType *FromArgTST =
GetTemplateSpecializationType(Context, FromType);
const TemplateSpecializationType *ToArgTST =
GetTemplateSpecializationType(Context, ToType);
if (FromArgTST && ToArgTST &&
hasSameTemplate(FromArgTST, ToArgTST)) {
FromQual -= QualType(FromArgTST, 0).getQualifiers();
ToQual -= QualType(ToArgTST, 0).getQualifiers();
Tree.SetNode(FromArgTST->getTemplateName().getAsTemplateDecl(),
ToArgTST->getTemplateName().getAsTemplateDecl());
Tree.SetNode(FromQual, ToQual);
DiffTemplate(FromArgTST, ToArgTST);
}
}
}
}
// Handle Expressions
if (NonTypeTemplateParmDecl *DefaultNTTPD =
dyn_cast<NonTypeTemplateParmDecl>(ParamND)) {
Expr *FromExpr, *ToExpr;
llvm::APSInt FromInt, ToInt;
unsigned ParamWidth = 0;
if (DefaultNTTPD->getType()->isIntegralOrEnumerationType())
ParamWidth = Context.getIntWidth(DefaultNTTPD->getType());
bool HasFromInt = !FromIter.isEnd() &&
FromIter->getKind() == TemplateArgument::Integral;
bool HasToInt = !ToIter.isEnd() &&
ToIter->getKind() == TemplateArgument::Integral;
//bool IsValidFromInt = false, IsValidToInt = false;
if (HasFromInt)
FromInt = FromIter->getAsIntegral();
else
GetExpr(FromIter, DefaultNTTPD, FromExpr);
if (HasToInt)
ToInt = ToIter->getAsIntegral();
else
GetExpr(ToIter, DefaultNTTPD, ToExpr);
if (!HasFromInt && !HasToInt) {
Tree.SetNode(FromExpr, ToExpr);
Tree.SetSame(IsEqualExpr(Context, ParamWidth, FromExpr, ToExpr));
Tree.SetDefault(FromIter.isEnd() && FromExpr,
ToIter.isEnd() && ToExpr);
} else {
if (!HasFromInt && FromExpr) {
FromInt = FromExpr->EvaluateKnownConstInt(Context);
HasFromInt = true;
}
if (!HasToInt && ToExpr) {
ToInt = ToExpr->EvaluateKnownConstInt(Context);
HasToInt = true;
}
Tree.SetNode(FromInt, ToInt, HasFromInt, HasToInt);
Tree.SetSame(IsSameConvertedInt(ParamWidth, FromInt, ToInt));
Tree.SetDefault(FromIter.isEnd() && HasFromInt,
ToIter.isEnd() && HasToInt);
}
}
// Handle Templates
if (TemplateTemplateParmDecl *DefaultTTPD =
dyn_cast<TemplateTemplateParmDecl>(ParamND)) {
TemplateDecl *FromDecl, *ToDecl;
GetTemplateDecl(FromIter, DefaultTTPD, FromDecl);
GetTemplateDecl(ToIter, DefaultTTPD, ToDecl);
Tree.SetNode(FromDecl, ToDecl);
Tree.SetSame(FromDecl && ToDecl &&
FromDecl->getIdentifier() == ToDecl->getIdentifier());
}
if (!FromIter.isEnd()) ++FromIter;
if (!ToIter.isEnd()) ++ToIter;
Tree.Up();
}
}
/// makeTemplateList - Dump every template alias into the vector.
static void makeTemplateList(
SmallVector<const TemplateSpecializationType*, 1> &TemplateList,
const TemplateSpecializationType *TST) {
while (TST) {
TemplateList.push_back(TST);
if (!TST->isTypeAlias())
return;
TST = TST->getAliasedType()->getAs<TemplateSpecializationType>();
}
}
/// hasSameBaseTemplate - Returns true when the base templates are the same,
/// even if the template arguments are not.
static bool hasSameBaseTemplate(const TemplateSpecializationType *FromTST,
const TemplateSpecializationType *ToTST) {
return FromTST->getTemplateName().getAsTemplateDecl()->getIdentifier() ==
ToTST->getTemplateName().getAsTemplateDecl()->getIdentifier();
}
/// hasSameTemplate - Returns true if both types are specialized from the
/// same template declaration. If they come from different template aliases,
/// do a parallel ascension search to determine the highest template alias in
/// common and set the arguments to them.
static bool hasSameTemplate(const TemplateSpecializationType *&FromTST,
const TemplateSpecializationType *&ToTST) {
// Check the top templates if they are the same.
if (hasSameBaseTemplate(FromTST, ToTST))
return true;
// Create vectors of template aliases.
SmallVector<const TemplateSpecializationType*, 1> FromTemplateList,
ToTemplateList;
makeTemplateList(FromTemplateList, FromTST);
makeTemplateList(ToTemplateList, ToTST);
SmallVector<const TemplateSpecializationType*, 1>::reverse_iterator
FromIter = FromTemplateList.rbegin(), FromEnd = FromTemplateList.rend(),
ToIter = ToTemplateList.rbegin(), ToEnd = ToTemplateList.rend();
// Check if the lowest template types are the same. If not, return.
if (!hasSameBaseTemplate(*FromIter, *ToIter))
return false;
// Begin searching up the template aliases. The bottom most template
// matches so move up until one pair does not match. Use the template
// right before that one.
for (; FromIter != FromEnd && ToIter != ToEnd; ++FromIter, ++ToIter) {
if (!hasSameBaseTemplate(*FromIter, *ToIter))
break;
}
FromTST = FromIter[-1];
ToTST = ToIter[-1];
return true;
}
/// GetType - Retrieves the template type arguments, including default
/// arguments.
void GetType(const TSTiterator &Iter, TemplateTypeParmDecl *DefaultTTPD,
QualType &ArgType) {
ArgType = QualType();
bool isVariadic = DefaultTTPD->isParameterPack();
if (!Iter.isEnd())
ArgType = Iter->getAsType();
else if (!isVariadic)
ArgType = DefaultTTPD->getDefaultArgument();
}
/// GetExpr - Retrieves the template expression argument, including default
/// arguments.
void GetExpr(const TSTiterator &Iter, NonTypeTemplateParmDecl *DefaultNTTPD,
Expr *&ArgExpr) {
ArgExpr = 0;
bool isVariadic = DefaultNTTPD->isParameterPack();
if (!Iter.isEnd())
ArgExpr = Iter->getAsExpr();
else if (!isVariadic)
ArgExpr = DefaultNTTPD->getDefaultArgument();
if (ArgExpr)
while (SubstNonTypeTemplateParmExpr *SNTTPE =
dyn_cast<SubstNonTypeTemplateParmExpr>(ArgExpr))
ArgExpr = SNTTPE->getReplacement();
}
/// GetTemplateDecl - Retrieves the template template arguments, including
/// default arguments.
void GetTemplateDecl(const TSTiterator &Iter,
TemplateTemplateParmDecl *DefaultTTPD,
TemplateDecl *&ArgDecl) {
ArgDecl = 0;
bool isVariadic = DefaultTTPD->isParameterPack();
TemplateArgument TA = DefaultTTPD->getDefaultArgument().getArgument();
TemplateDecl *DefaultTD = 0;
if (TA.getKind() != TemplateArgument::Null)
DefaultTD = TA.getAsTemplate().getAsTemplateDecl();
if (!Iter.isEnd())
ArgDecl = Iter->getAsTemplate().getAsTemplateDecl();
else if (!isVariadic)
ArgDecl = DefaultTD;
}
/// IsSameConvertedInt - Returns true if both integers are equal when
/// converted to an integer type with the given width.
static bool IsSameConvertedInt(unsigned Width, const llvm::APSInt &X,
const llvm::APSInt &Y) {
llvm::APInt ConvertedX = X.extOrTrunc(Width);
llvm::APInt ConvertedY = Y.extOrTrunc(Width);
return ConvertedX == ConvertedY;
}
/// IsEqualExpr - Returns true if the expressions evaluate to the same value.
static bool IsEqualExpr(ASTContext &Context, unsigned ParamWidth,
Expr *FromExpr, Expr *ToExpr) {
if (FromExpr == ToExpr)
return true;
if (!FromExpr || !ToExpr)
return false;
FromExpr = FromExpr->IgnoreParens();
ToExpr = ToExpr->IgnoreParens();
DeclRefExpr *FromDRE = dyn_cast<DeclRefExpr>(FromExpr),
*ToDRE = dyn_cast<DeclRefExpr>(ToExpr);
if (FromDRE || ToDRE) {
if (!FromDRE || !ToDRE)
return false;
return FromDRE->getDecl() == ToDRE->getDecl();
}
Expr::EvalResult FromResult, ToResult;
if (!FromExpr->EvaluateAsRValue(FromResult, Context) ||
!ToExpr->EvaluateAsRValue(ToResult, Context))
assert(0 && "Template arguments must be known at compile time.");
APValue &FromVal = FromResult.Val;
APValue &ToVal = ToResult.Val;
if (FromVal.getKind() != ToVal.getKind()) return false;
switch (FromVal.getKind()) {
case APValue::Int:
return IsSameConvertedInt(ParamWidth, FromVal.getInt(), ToVal.getInt());
case APValue::LValue: {
APValue::LValueBase FromBase = FromVal.getLValueBase();
APValue::LValueBase ToBase = ToVal.getLValueBase();
if (FromBase.isNull() && ToBase.isNull())
return true;
if (FromBase.isNull() || ToBase.isNull())
return false;
return FromBase.get<const ValueDecl*>() ==
ToBase.get<const ValueDecl*>();
}
case APValue::MemberPointer:
return FromVal.getMemberPointerDecl() == ToVal.getMemberPointerDecl();
default:
llvm_unreachable("Unknown template argument expression.");
}
}
// These functions converts the tree representation of the template
// differences into the internal character vector.
/// TreeToString - Converts the Tree object into a character stream which
/// will later be turned into the output string.
void TreeToString(int Indent = 1) {
if (PrintTree) {
OS << '\n';
for (int i = 0; i < Indent; ++i)
OS << " ";
++Indent;
}
// Handle cases where the difference is not templates with different
// arguments.
if (!Tree.NodeIsTemplate()) {
if (Tree.NodeIsQualType()) {
QualType FromType, ToType;
Tree.GetNode(FromType, ToType);
PrintTypeNames(FromType, ToType, Tree.FromDefault(), Tree.ToDefault(),
Tree.NodeIsSame());
return;
}
if (Tree.NodeIsExpr()) {
Expr *FromExpr, *ToExpr;
Tree.GetNode(FromExpr, ToExpr);
PrintExpr(FromExpr, ToExpr, Tree.FromDefault(), Tree.ToDefault(),
Tree.NodeIsSame());
return;
}
if (Tree.NodeIsTemplateTemplate()) {
TemplateDecl *FromTD, *ToTD;
Tree.GetNode(FromTD, ToTD);
PrintTemplateTemplate(FromTD, ToTD, Tree.FromDefault(),
Tree.ToDefault(), Tree.NodeIsSame());
return;
}
if (Tree.NodeIsAPSInt()) {
llvm::APSInt FromInt, ToInt;
bool IsValidFromInt, IsValidToInt;
Tree.GetNode(FromInt, ToInt, IsValidFromInt, IsValidToInt);
PrintAPSInt(FromInt, ToInt, IsValidFromInt, IsValidToInt,
Tree.FromDefault(), Tree.ToDefault(), Tree.NodeIsSame());
return;
}
llvm_unreachable("Unable to deduce template difference.");
}
// Node is root of template. Recurse on children.
TemplateDecl *FromTD, *ToTD;
Tree.GetNode(FromTD, ToTD);
assert(Tree.HasChildren() && "Template difference not found in diff tree.");
Qualifiers FromQual, ToQual;
Tree.GetNode(FromQual, ToQual);
PrintQualifiers(FromQual, ToQual);
OS << FromTD->getNameAsString() << '<';
Tree.MoveToChild();
unsigned NumElideArgs = 0;
do {
if (ElideType) {
if (Tree.NodeIsSame()) {
++NumElideArgs;
continue;
}
if (NumElideArgs > 0) {
PrintElideArgs(NumElideArgs, Indent);
NumElideArgs = 0;
OS << ", ";
}
}
TreeToString(Indent);
if (Tree.HasNextSibling())
OS << ", ";
} while (Tree.AdvanceSibling());
if (NumElideArgs > 0)
PrintElideArgs(NumElideArgs, Indent);
Tree.Parent();
OS << ">";
}
// To signal to the text printer that a certain text needs to be bolded,
// a special character is injected into the character stream which the
// text printer will later strip out.
/// Bold - Start bolding text.
void Bold() {
assert(!IsBold && "Attempting to bold text that is already bold.");
IsBold = true;
if (ShowColor)
OS << ToggleHighlight;
}
/// Unbold - Stop bolding text.
void Unbold() {
assert(IsBold && "Attempting to remove bold from unbold text.");
IsBold = false;
if (ShowColor)
OS << ToggleHighlight;
}
// Functions to print out the arguments and highlighting the difference.
/// PrintTypeNames - prints the typenames, bolding differences. Will detect
/// typenames that are the same and attempt to disambiguate them by using
/// canonical typenames.
void PrintTypeNames(QualType FromType, QualType ToType,
bool FromDefault, bool ToDefault, bool Same) {
assert((!FromType.isNull() || !ToType.isNull()) &&
"Only one template argument may be missing.");
if (Same) {
OS << FromType.getAsString();
return;
}
if (!FromType.isNull() && !ToType.isNull() &&
FromType.getLocalUnqualifiedType() ==
ToType.getLocalUnqualifiedType()) {
Qualifiers FromQual = FromType.getLocalQualifiers(),
ToQual = ToType.getLocalQualifiers(),
CommonQual;
PrintQualifiers(FromQual, ToQual);
FromType.getLocalUnqualifiedType().print(OS, Policy);
return;
}
std::string FromTypeStr = FromType.isNull() ? "(no argument)"
: FromType.getAsString();
std::string ToTypeStr = ToType.isNull() ? "(no argument)"
: ToType.getAsString();
// Switch to canonical typename if it is better.
// TODO: merge this with other aka printing above.
if (FromTypeStr == ToTypeStr) {
std::string FromCanTypeStr = FromType.getCanonicalType().getAsString();
std::string ToCanTypeStr = ToType.getCanonicalType().getAsString();
if (FromCanTypeStr != ToCanTypeStr) {
FromTypeStr = FromCanTypeStr;
ToTypeStr = ToCanTypeStr;
}
}
if (PrintTree) OS << '[';
OS << (FromDefault ? "(default) " : "");
Bold();
OS << FromTypeStr;
Unbold();
if (PrintTree) {
OS << " != " << (ToDefault ? "(default) " : "");
Bold();
OS << ToTypeStr;
Unbold();
OS << "]";
}
return;
}
/// PrintExpr - Prints out the expr template arguments, highlighting argument
/// differences.
void PrintExpr(const Expr *FromExpr, const Expr *ToExpr,
bool FromDefault, bool ToDefault, bool Same) {
assert((FromExpr || ToExpr) &&
"Only one template argument may be missing.");
if (Same) {
PrintExpr(FromExpr);
} else if (!PrintTree) {
OS << (FromDefault ? "(default) " : "");
Bold();
PrintExpr(FromExpr);
Unbold();
} else {
OS << (FromDefault ? "[(default) " : "[");
Bold();
PrintExpr(FromExpr);
Unbold();
OS << " != " << (ToDefault ? "(default) " : "");
Bold();
PrintExpr(ToExpr);
Unbold();
OS << ']';
}
}
/// PrintExpr - Actual formatting and printing of expressions.
void PrintExpr(const Expr *E) {
if (!E)
OS << "(no argument)";
else
E->printPretty(OS, 0, Policy); return;
}
/// PrintTemplateTemplate - Handles printing of template template arguments,
/// highlighting argument differences.
void PrintTemplateTemplate(TemplateDecl *FromTD, TemplateDecl *ToTD,
bool FromDefault, bool ToDefault, bool Same) {
assert((FromTD || ToTD) && "Only one template argument may be missing.");
if (Same) {
OS << "template " << FromTD->getNameAsString();
} else if (!PrintTree) {
OS << (FromDefault ? "(default) template " : "template ");
Bold();
OS << (FromTD ? FromTD->getNameAsString() : "(no argument)");
Unbold();
} else {
OS << (FromDefault ? "[(default) template " : "[template ");
Bold();
OS << (FromTD ? FromTD->getNameAsString() : "(no argument)");
Unbold();
OS << " != " << (ToDefault ? "(default) template " : "template ");
Bold();
OS << (ToTD ? ToTD->getNameAsString() : "(no argument)");
Unbold();
OS << ']';
}
}
/// PrintAPSInt - Handles printing of integral arguments, highlighting
/// argument differences.
void PrintAPSInt(llvm::APSInt FromInt, llvm::APSInt ToInt,
bool IsValidFromInt, bool IsValidToInt, bool FromDefault,
bool ToDefault, bool Same) {
assert((IsValidFromInt || IsValidToInt) &&
"Only one integral argument may be missing.");
if (Same) {
OS << FromInt.toString(10);
} else if (!PrintTree) {
OS << (FromDefault ? "(default) " : "");
Bold();
OS << (IsValidFromInt ? FromInt.toString(10) : "(no argument)");
Unbold();
} else {
OS << (FromDefault ? "[(default) " : "[");
Bold();
OS << (IsValidFromInt ? FromInt.toString(10) : "(no argument)");
Unbold();
OS << " != " << (ToDefault ? "(default) " : "");
Bold();
OS << (IsValidToInt ? ToInt.toString(10) : "(no argument)");
Unbold();
OS << ']';
}
}
// Prints the appropriate placeholder for elided template arguments.
void PrintElideArgs(unsigned NumElideArgs, unsigned Indent) {
if (PrintTree) {
OS << '\n';
for (unsigned i = 0; i < Indent; ++i)
OS << " ";
}
if (NumElideArgs == 0) return;
if (NumElideArgs == 1)
OS << "[...]";
else
OS << "[" << NumElideArgs << " * ...]";
}
// Prints and highlights differences in Qualifiers.
void PrintQualifiers(Qualifiers FromQual, Qualifiers ToQual) {
// Both types have no qualifiers
if (FromQual.empty() && ToQual.empty())
return;
// Both types have same qualifiers
if (FromQual == ToQual) {
PrintQualifier(FromQual, /*ApplyBold*/false);
return;
}
// Find common qualifiers and strip them from FromQual and ToQual.
Qualifiers CommonQual = Qualifiers::removeCommonQualifiers(FromQual,
ToQual);
// The qualifiers are printed before the template name.
// Inline printing:
// The common qualifiers are printed. Then, qualifiers only in this type
// are printed and highlighted. Finally, qualifiers only in the other
// type are printed and highlighted inside parentheses after "missing".
// Tree printing:
// Qualifiers are printed next to each other, inside brackets, and
// separated by "!=". The printing order is:
// common qualifiers, highlighted from qualifiers, "!=",
// common qualifiers, highlighted to qualifiers
if (PrintTree) {
OS << "[";
if (CommonQual.empty() && FromQual.empty()) {
Bold();
OS << "(no qualifiers) ";
Unbold();
} else {
PrintQualifier(CommonQual, /*ApplyBold*/false);
PrintQualifier(FromQual, /*ApplyBold*/true);
}
OS << "!= ";
if (CommonQual.empty() && ToQual.empty()) {
Bold();
OS << "(no qualifiers)";
Unbold();
} else {
PrintQualifier(CommonQual, /*ApplyBold*/false,
/*appendSpaceIfNonEmpty*/!ToQual.empty());
PrintQualifier(ToQual, /*ApplyBold*/true,
/*appendSpaceIfNonEmpty*/false);
}
OS << "] ";
} else {
PrintQualifier(CommonQual, /*ApplyBold*/false);
PrintQualifier(FromQual, /*ApplyBold*/true);
}
}
void PrintQualifier(Qualifiers Q, bool ApplyBold,
bool AppendSpaceIfNonEmpty = true) {
if (Q.empty()) return;
if (ApplyBold) Bold();
Q.print(OS, Policy, AppendSpaceIfNonEmpty);
if (ApplyBold) Unbold();
}
public:
TemplateDiff(ASTContext &Context, QualType FromType, QualType ToType,
bool PrintTree, bool PrintFromType, bool ElideType,
bool ShowColor)
: Context(Context),
Policy(Context.getLangOpts()),
ElideType(ElideType),
PrintTree(PrintTree),
ShowColor(ShowColor),
// When printing a single type, the FromType is the one printed.
FromType(PrintFromType ? FromType : ToType),
ToType(PrintFromType ? ToType : FromType),
OS(Str),
IsBold(false) {
}
/// DiffTemplate - Start the template type diffing.
void DiffTemplate() {
Qualifiers FromQual = FromType.getQualifiers(),
ToQual = ToType.getQualifiers();
const TemplateSpecializationType *FromOrigTST =
GetTemplateSpecializationType(Context, FromType);
const TemplateSpecializationType *ToOrigTST =
GetTemplateSpecializationType(Context, ToType);
// Only checking templates.
if (!FromOrigTST || !ToOrigTST)
return;
// Different base templates.
if (!hasSameTemplate(FromOrigTST, ToOrigTST)) {
return;
}
FromQual -= QualType(FromOrigTST, 0).getQualifiers();
ToQual -= QualType(ToOrigTST, 0).getQualifiers();
Tree.SetNode(FromType, ToType);
Tree.SetNode(FromQual, ToQual);
// Same base template, but different arguments.
Tree.SetNode(FromOrigTST->getTemplateName().getAsTemplateDecl(),
ToOrigTST->getTemplateName().getAsTemplateDecl());
DiffTemplate(FromOrigTST, ToOrigTST);
}
/// MakeString - When the two types given are templated types with the same
/// base template, a string representation of the type difference will be
/// loaded into S and return true. Otherwise, return false.
bool MakeString(std::string &S) {
Tree.StartTraverse();
if (Tree.Empty())
return false;
TreeToString();
assert(!IsBold && "Bold is applied to end of string.");
S = OS.str();
return true;
}
}; // end class TemplateDiff
} // end namespace
/// FormatTemplateTypeDiff - A helper static function to start the template
/// diff and return the properly formatted string. Returns true if the diff
/// is successful.
static bool FormatTemplateTypeDiff(ASTContext &Context, QualType FromType,
QualType ToType, bool PrintTree,
bool PrintFromType, bool ElideType,
bool ShowColors, std::string &S) {
if (PrintTree)
PrintFromType = true;
TemplateDiff TD(Context, FromType, ToType, PrintTree, PrintFromType,
ElideType, ShowColors);
TD.DiffTemplate();
return TD.MakeString(S);
}