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fuchsia / third_party / swift / f2cf0510d6e25911e9babada46e0025862bd00cd / . / include / swift / AST / DiagnosticEngine.h
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//===--- DiagnosticEngine.h - Diagnostic Display Engine ---------*- C++ -*-===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
//
// This file declares the DiagnosticEngine class, which manages any diagnostics
// emitted by Swift.
//
//===----------------------------------------------------------------------===//
#ifndef SWIFT_BASIC_DIAGNOSTICENGINE_H
#define SWIFT_BASIC_DIAGNOSTICENGINE_H
#include "swift/AST/ActorIsolation.h"
#include "swift/AST/DeclNameLoc.h"
#include "swift/AST/DiagnosticConsumer.h"
#include "swift/AST/TypeLoc.h"
#include "swift/Localization/LocalizationFormat.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/StringSet.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/FileSystem.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/VersionTuple.h"
namespace swift {
class Decl;
class DeclAttribute;
class DiagnosticEngine;
class SourceManager;
class ValueDecl;
class SourceFile;
enum class PatternKind : uint8_t;
enum class SelfAccessKind : uint8_t;
enum class ReferenceOwnership : uint8_t;
enum class StaticSpellingKind : uint8_t;
enum class DescriptiveDeclKind : uint8_t;
enum DeclAttrKind : unsigned;
/// Enumeration describing all of possible diagnostics.
///
/// Each of the diagnostics described in Diagnostics.def has an entry in
/// this enumeration type that uniquely identifies it.
enum class DiagID : uint32_t;
/// Describes a diagnostic along with its argument types.
///
/// The diagnostics header introduces instances of this type for each
/// diagnostic, which provide both the set of argument types (used to
/// check/convert the arguments at each call site) and the diagnostic ID
/// (for other information about the diagnostic).
template<typename ...ArgTypes>
struct Diag {
/// The diagnostic ID corresponding to this diagnostic.
DiagID ID;
};
namespace detail {
/// Describes how to pass a diagnostic argument of the given type.
///
/// By default, diagnostic arguments are passed by value, because they
/// tend to be small. Larger diagnostic arguments
/// need to specialize this class template to pass by reference.
template<typename T>
struct PassArgument {
typedef T type;
};
}
/// A family of wrapper types for compiler data types that forces its
/// underlying data to be formatted with full qualification.
///
/// So far, this is only useful for \c Type, hence the SFINAE'ing.
template <typename T, typename = void> struct FullyQualified {};
template <typename T>
struct FullyQualified<
T, typename std::enable_if<std::is_convertible<T, Type>::value>::type> {
Type t;
public:
FullyQualified(T t) : t(t){};
Type getType() const { return t; }
};
/// Describes the kind of diagnostic argument we're storing.
///
enum class DiagnosticArgumentKind {
String,
Integer,
Unsigned,
Identifier,
ObjCSelector,
ValueDecl,
Type,
TypeRepr,
FullyQualifiedType,
PatternKind,
SelfAccessKind,
ReferenceOwnership,
StaticSpellingKind,
DescriptiveDeclKind,
DeclAttribute,
VersionTuple,
LayoutConstraint,
ActorIsolation,
};
namespace diag {
enum class RequirementKind : uint8_t;
}
/// Variant type that holds a single diagnostic argument of a known
/// type.
///
/// All diagnostic arguments are converted to an instance of this class.
class DiagnosticArgument {
DiagnosticArgumentKind Kind;
union {
int IntegerVal;
unsigned UnsignedVal;
StringRef StringVal;
DeclNameRef IdentifierVal;
ObjCSelector ObjCSelectorVal;
ValueDecl *TheValueDecl;
Type TypeVal;
TypeRepr *TyR;
FullyQualified<Type> FullyQualifiedTypeVal;
PatternKind PatternKindVal;
SelfAccessKind SelfAccessKindVal;
ReferenceOwnership ReferenceOwnershipVal;
StaticSpellingKind StaticSpellingKindVal;
DescriptiveDeclKind DescriptiveDeclKindVal;
const DeclAttribute *DeclAttributeVal;
llvm::VersionTuple VersionVal;
LayoutConstraint LayoutConstraintVal;
ActorIsolation ActorIsolationVal;
};
public:
DiagnosticArgument(StringRef S)
: Kind(DiagnosticArgumentKind::String), StringVal(S) {
}
DiagnosticArgument(int I)
: Kind(DiagnosticArgumentKind::Integer), IntegerVal(I) {
}
DiagnosticArgument(unsigned I)
: Kind(DiagnosticArgumentKind::Unsigned), UnsignedVal(I) {
}
DiagnosticArgument(DeclNameRef R)
: Kind(DiagnosticArgumentKind::Identifier), IdentifierVal(R) {}
DiagnosticArgument(DeclName D)
: Kind(DiagnosticArgumentKind::Identifier),
IdentifierVal(DeclNameRef(D)) {}
DiagnosticArgument(DeclBaseName D)
: Kind(DiagnosticArgumentKind::Identifier),
IdentifierVal(DeclNameRef(D)) {}
DiagnosticArgument(Identifier I)
: Kind(DiagnosticArgumentKind::Identifier),
IdentifierVal(DeclNameRef(I)) {
}
DiagnosticArgument(ObjCSelector S)
: Kind(DiagnosticArgumentKind::ObjCSelector), ObjCSelectorVal(S) {
}
DiagnosticArgument(ValueDecl *VD)
: Kind(DiagnosticArgumentKind::ValueDecl), TheValueDecl(VD) {
}
DiagnosticArgument(Type T)
: Kind(DiagnosticArgumentKind::Type), TypeVal(T) {
}
DiagnosticArgument(TypeRepr *T)
: Kind(DiagnosticArgumentKind::TypeRepr), TyR(T) {
}
DiagnosticArgument(FullyQualified<Type> FQT)
: Kind(DiagnosticArgumentKind::FullyQualifiedType),
FullyQualifiedTypeVal(FQT) {}
DiagnosticArgument(const TypeLoc &TL) {
if (TypeRepr *tyR = TL.getTypeRepr()) {
Kind = DiagnosticArgumentKind::TypeRepr;
TyR = tyR;
} else {
Kind = DiagnosticArgumentKind::Type;
TypeVal = TL.getType();
}
}
DiagnosticArgument(PatternKind K)
: Kind(DiagnosticArgumentKind::PatternKind), PatternKindVal(K) {}
DiagnosticArgument(ReferenceOwnership RO)
: Kind(DiagnosticArgumentKind::ReferenceOwnership),
ReferenceOwnershipVal(RO) {}
DiagnosticArgument(SelfAccessKind SAK)
: Kind(DiagnosticArgumentKind::SelfAccessKind),
SelfAccessKindVal(SAK) {}
DiagnosticArgument(StaticSpellingKind SSK)
: Kind(DiagnosticArgumentKind::StaticSpellingKind),
StaticSpellingKindVal(SSK) {}
DiagnosticArgument(DescriptiveDeclKind DDK)
: Kind(DiagnosticArgumentKind::DescriptiveDeclKind),
DescriptiveDeclKindVal(DDK) {}
DiagnosticArgument(const DeclAttribute *attr)
: Kind(DiagnosticArgumentKind::DeclAttribute),
DeclAttributeVal(attr) {}
DiagnosticArgument(llvm::VersionTuple version)
: Kind(DiagnosticArgumentKind::VersionTuple),
VersionVal(version) { }
DiagnosticArgument(LayoutConstraint L)
: Kind(DiagnosticArgumentKind::LayoutConstraint), LayoutConstraintVal(L) {
}
DiagnosticArgument(ActorIsolation AI)
: Kind(DiagnosticArgumentKind::ActorIsolation),
ActorIsolationVal(AI) {
}
/// Initializes a diagnostic argument using the underlying type of the
/// given enum.
template<
typename EnumType,
typename std::enable_if<std::is_enum<EnumType>::value>::type* = nullptr>
DiagnosticArgument(EnumType value)
: DiagnosticArgument(
static_cast<typename std::underlying_type<EnumType>::type>(value)) {}
DiagnosticArgumentKind getKind() const { return Kind; }
StringRef getAsString() const {
assert(Kind == DiagnosticArgumentKind::String);
return StringVal;
}
int getAsInteger() const {
assert(Kind == DiagnosticArgumentKind::Integer);
return IntegerVal;
}
unsigned getAsUnsigned() const {
assert(Kind == DiagnosticArgumentKind::Unsigned);
return UnsignedVal;
}
DeclNameRef getAsIdentifier() const {
assert(Kind == DiagnosticArgumentKind::Identifier);
return IdentifierVal;
}
ObjCSelector getAsObjCSelector() const {
assert(Kind == DiagnosticArgumentKind::ObjCSelector);
return ObjCSelectorVal;
}
ValueDecl *getAsValueDecl() const {
assert(Kind == DiagnosticArgumentKind::ValueDecl);
return TheValueDecl;
}
Type getAsType() const {
assert(Kind == DiagnosticArgumentKind::Type);
return TypeVal;
}
TypeRepr *getAsTypeRepr() const {
assert(Kind == DiagnosticArgumentKind::TypeRepr);
return TyR;
}
FullyQualified<Type> getAsFullyQualifiedType() const {
assert(Kind == DiagnosticArgumentKind::FullyQualifiedType);
return FullyQualifiedTypeVal;
}
PatternKind getAsPatternKind() const {
assert(Kind == DiagnosticArgumentKind::PatternKind);
return PatternKindVal;
}
ReferenceOwnership getAsReferenceOwnership() const {
assert(Kind == DiagnosticArgumentKind::ReferenceOwnership);
return ReferenceOwnershipVal;
}
SelfAccessKind getAsSelfAccessKind() const {
assert(Kind == DiagnosticArgumentKind::SelfAccessKind);
return SelfAccessKindVal;
}
StaticSpellingKind getAsStaticSpellingKind() const {
assert(Kind == DiagnosticArgumentKind::StaticSpellingKind);
return StaticSpellingKindVal;
}
DescriptiveDeclKind getAsDescriptiveDeclKind() const {
assert(Kind == DiagnosticArgumentKind::DescriptiveDeclKind);
return DescriptiveDeclKindVal;
}
const DeclAttribute *getAsDeclAttribute() const {
assert(Kind == DiagnosticArgumentKind::DeclAttribute);
return DeclAttributeVal;
}
llvm::VersionTuple getAsVersionTuple() const {
assert(Kind == DiagnosticArgumentKind::VersionTuple);
return VersionVal;
}
LayoutConstraint getAsLayoutConstraint() const {
assert(Kind == DiagnosticArgumentKind::LayoutConstraint);
return LayoutConstraintVal;
}
ActorIsolation getAsActorIsolation() const {
assert(Kind == DiagnosticArgumentKind::ActorIsolation);
return ActorIsolationVal;
}
};
struct DiagnosticFormatOptions {
const std::string OpeningQuotationMark;
const std::string ClosingQuotationMark;
const std::string AKAFormatString;
const std::string OpaqueResultFormatString;
DiagnosticFormatOptions(std::string OpeningQuotationMark,
std::string ClosingQuotationMark,
std::string AKAFormatString,
std::string OpaqueResultFormatString)
: OpeningQuotationMark(OpeningQuotationMark),
ClosingQuotationMark(ClosingQuotationMark),
AKAFormatString(AKAFormatString),
OpaqueResultFormatString(OpaqueResultFormatString) {}
DiagnosticFormatOptions()
: OpeningQuotationMark("'"), ClosingQuotationMark("'"),
AKAFormatString("'%s' (aka '%s')"),
OpaqueResultFormatString("'%s' (%s of '%s')") {}
/// When formatting fix-it arguments, don't include quotes or other
/// additions which would result in invalid code.
static DiagnosticFormatOptions formatForFixIts() {
return DiagnosticFormatOptions("", "", "%s", "%s");
}
};
enum class FixItID : uint32_t;
/// Represents a fix-it defined with a format string and optional
/// DiagnosticArguments. The template parameters allow the
/// fixIt... methods on InFlightDiagnostic to infer their own
/// template params.
template <typename... ArgTypes> struct StructuredFixIt { FixItID ID; };
/// Diagnostic - This is a specific instance of a diagnostic along with all of
/// the DiagnosticArguments that it requires.
class Diagnostic {
public:
typedef DiagnosticInfo::FixIt FixIt;
private:
DiagID ID;
SmallVector<DiagnosticArgument, 3> Args;
SmallVector<CharSourceRange, 2> Ranges;
SmallVector<FixIt, 2> FixIts;
std::vector<Diagnostic> ChildNotes;
SourceLoc Loc;
bool IsChildNote = false;
const swift::Decl *Decl = nullptr;
friend DiagnosticEngine;
public:
// All constructors are intentionally implicit.
template<typename ...ArgTypes>
Diagnostic(Diag<ArgTypes...> ID,
typename detail::PassArgument<ArgTypes>::type... VArgs)
: ID(ID.ID) {
DiagnosticArgument DiagArgs[] = {
DiagnosticArgument(0), std::move(VArgs)...
};
Args.append(DiagArgs + 1, DiagArgs + 1 + sizeof...(VArgs));
}
/*implicit*/Diagnostic(DiagID ID, ArrayRef<DiagnosticArgument> Args)
: ID(ID), Args(Args.begin(), Args.end()) {}
// Accessors.
DiagID getID() const { return ID; }
ArrayRef<DiagnosticArgument> getArgs() const { return Args; }
ArrayRef<CharSourceRange> getRanges() const { return Ranges; }
ArrayRef<FixIt> getFixIts() const { return FixIts; }
ArrayRef<Diagnostic> getChildNotes() const { return ChildNotes; }
bool isChildNote() const { return IsChildNote; }
SourceLoc getLoc() const { return Loc; }
const class Decl *getDecl() const { return Decl; }
void setLoc(SourceLoc loc) { Loc = loc; }
void setIsChildNote(bool isChildNote) { IsChildNote = isChildNote; }
void setDecl(const class Decl *decl) { Decl = decl; }
/// Returns true if this object represents a particular diagnostic.
///
/// \code
/// someDiag.is(diag::invalid_diagnostic)
/// \endcode
template<typename ...OtherArgTypes>
bool is(Diag<OtherArgTypes...> Other) const {
return ID == Other.ID;
}
void addRange(CharSourceRange R) {
Ranges.push_back(R);
}
// Avoid copying the fix-it text more than necessary.
void addFixIt(FixIt &&F) {
FixIts.push_back(std::move(F));
}
void addChildNote(Diagnostic &&D);
};
/// Describes an in-flight diagnostic, which is currently active
/// within the diagnostic engine and can be augmented within additional
/// information (source ranges, Fix-Its, etc.).
///
/// Only a single in-flight diagnostic can be active at one time, and all
/// additional information must be emitted through the active in-flight
/// diagnostic.
class InFlightDiagnostic {
friend class DiagnosticEngine;
DiagnosticEngine *Engine;
bool IsActive;
/// Create a new in-flight diagnostic.
///
/// This constructor is only available to the DiagnosticEngine.
InFlightDiagnostic(DiagnosticEngine &Engine)
: Engine(&Engine), IsActive(true) { }
InFlightDiagnostic(const InFlightDiagnostic &) = delete;
InFlightDiagnostic &operator=(const InFlightDiagnostic &) = delete;
InFlightDiagnostic &operator=(InFlightDiagnostic &&) = delete;
public:
/// Create an active but unattached in-flight diagnostic.
///
/// The resulting diagnostic can be used as a dummy, accepting the
/// syntax to add additional information to a diagnostic without
/// actually emitting a diagnostic.
InFlightDiagnostic() : Engine(0), IsActive(true) { }
/// Transfer an in-flight diagnostic to a new object, which is
/// typically used when returning in-flight diagnostics.
InFlightDiagnostic(InFlightDiagnostic &&Other)
: Engine(Other.Engine), IsActive(Other.IsActive) {
Other.IsActive = false;
}
~InFlightDiagnostic() {
if (IsActive)
flush();
}
/// Flush the active diagnostic to the diagnostic output engine.
void flush();
/// Add a token-based range to the currently-active diagnostic.
InFlightDiagnostic &highlight(SourceRange R);
/// Add a character-based range to the currently-active diagnostic.
InFlightDiagnostic &highlightChars(SourceLoc Start, SourceLoc End);
static const char *fixItStringFor(const FixItID id);
/// Add a token-based replacement fix-it to the currently-active
/// diagnostic.
template <typename... ArgTypes>
InFlightDiagnostic &
fixItReplace(SourceRange R, StructuredFixIt<ArgTypes...> fixIt,
typename detail::PassArgument<ArgTypes>::type... VArgs) {
DiagnosticArgument DiagArgs[] = { std::move(VArgs)... };
return fixItReplace(R, fixItStringFor(fixIt.ID), DiagArgs);
}
/// Add a character-based replacement fix-it to the currently-active
/// diagnostic.
template <typename... ArgTypes>
InFlightDiagnostic &
fixItReplaceChars(SourceLoc Start, SourceLoc End,
StructuredFixIt<ArgTypes...> fixIt,
typename detail::PassArgument<ArgTypes>::type... VArgs) {
DiagnosticArgument DiagArgs[] = { std::move(VArgs)... };
return fixItReplaceChars(Start, End, fixItStringFor(fixIt.ID), DiagArgs);
}
/// Add an insertion fix-it to the currently-active diagnostic.
template <typename... ArgTypes>
InFlightDiagnostic &
fixItInsert(SourceLoc L, StructuredFixIt<ArgTypes...> fixIt,
typename detail::PassArgument<ArgTypes>::type... VArgs) {
DiagnosticArgument DiagArgs[] = { std::move(VArgs)... };
return fixItReplaceChars(L, L, fixItStringFor(fixIt.ID), DiagArgs);
}
/// Add an insertion fix-it to the currently-active diagnostic. The
/// text is inserted immediately *after* the token specified.
template <typename... ArgTypes>
InFlightDiagnostic &
fixItInsertAfter(SourceLoc L, StructuredFixIt<ArgTypes...> fixIt,
typename detail::PassArgument<ArgTypes>::type... VArgs) {
DiagnosticArgument DiagArgs[] = { std::move(VArgs)... };
return fixItInsertAfter(L, fixItStringFor(fixIt.ID), DiagArgs);
}
/// Add a token-based replacement fix-it to the currently-active
/// diagnostic.
InFlightDiagnostic &fixItReplace(SourceRange R, StringRef Str);
/// Add a character-based replacement fix-it to the currently-active
/// diagnostic.
InFlightDiagnostic &fixItReplaceChars(SourceLoc Start, SourceLoc End,
StringRef Str) {
return fixItReplaceChars(Start, End, "%0", {Str});
}
/// Add an insertion fix-it to the currently-active diagnostic.
InFlightDiagnostic &fixItInsert(SourceLoc L, StringRef Str) {
return fixItReplaceChars(L, L, "%0", {Str});
}
/// Add an insertion fix-it to the currently-active diagnostic. The
/// text is inserted immediately *after* the token specified.
InFlightDiagnostic &fixItInsertAfter(SourceLoc L, StringRef Str) {
return fixItInsertAfter(L, "%0", {Str});
}
/// Add a token-based removal fix-it to the currently-active
/// diagnostic.
InFlightDiagnostic &fixItRemove(SourceRange R);
/// Add a character-based removal fix-it to the currently-active
/// diagnostic.
InFlightDiagnostic &fixItRemoveChars(SourceLoc Start, SourceLoc End) {
return fixItReplaceChars(Start, End, {});
}
/// Add two replacement fix-it exchanging source ranges to the
/// currently-active diagnostic.
InFlightDiagnostic &fixItExchange(SourceRange R1, SourceRange R2);
private:
InFlightDiagnostic &fixItReplace(SourceRange R, StringRef FormatString,
ArrayRef<DiagnosticArgument> Args);
InFlightDiagnostic &fixItReplaceChars(SourceLoc Start, SourceLoc End,
StringRef FormatString,
ArrayRef<DiagnosticArgument> Args);
InFlightDiagnostic &fixItInsert(SourceLoc L, StringRef FormatString,
ArrayRef<DiagnosticArgument> Args) {
return fixItReplaceChars(L, L, FormatString, Args);
}
InFlightDiagnostic &fixItInsertAfter(SourceLoc L, StringRef FormatString,
ArrayRef<DiagnosticArgument> Args);
};
/// Class to track, map, and remap diagnostic severity and fatality
///
class DiagnosticState {
public:
/// Describes the current behavior to take with a diagnostic
enum class Behavior : uint8_t {
Unspecified,
Ignore,
Note,
Remark,
Warning,
Error,
Fatal,
};
private:
/// Whether we should continue to emit diagnostics, even after a
/// fatal error
bool showDiagnosticsAfterFatalError = false;
/// Don't emit any warnings
bool suppressWarnings = false;
/// Emit all warnings as errors
bool warningsAsErrors = false;
/// Whether a fatal error has occurred
bool fatalErrorOccurred = false;
/// Whether any error diagnostics have been emitted.
bool anyErrorOccurred = false;
/// Track the previous emitted Behavior, useful for notes
Behavior previousBehavior = Behavior::Unspecified;
/// Track settable, per-diagnostic state that we store
std::vector<Behavior> perDiagnosticBehavior;
public:
DiagnosticState();
/// Figure out the Behavior for the given diagnostic, taking current
/// state such as fatality into account.
Behavior determineBehavior(DiagID id);
bool hadAnyError() const { return anyErrorOccurred; }
bool hasFatalErrorOccurred() const { return fatalErrorOccurred; }
void setShowDiagnosticsAfterFatalError(bool val = true) {
showDiagnosticsAfterFatalError = val;
}
bool getShowDiagnosticsAfterFatalError() {
return showDiagnosticsAfterFatalError;
}
/// Whether to skip emitting warnings
void setSuppressWarnings(bool val) { suppressWarnings = val; }
bool getSuppressWarnings() const { return suppressWarnings; }
/// Whether to treat warnings as errors
void setWarningsAsErrors(bool val) { warningsAsErrors = val; }
bool getWarningsAsErrors() const { return warningsAsErrors; }
void resetHadAnyError() {
anyErrorOccurred = false;
fatalErrorOccurred = false;
}
/// Set per-diagnostic behavior
void setDiagnosticBehavior(DiagID id, Behavior behavior) {
perDiagnosticBehavior[(unsigned)id] = behavior;
}
private:
// Make the state movable only
DiagnosticState(const DiagnosticState &) = delete;
const DiagnosticState &operator=(const DiagnosticState &) = delete;
DiagnosticState(DiagnosticState &&) = default;
DiagnosticState &operator=(DiagnosticState &&) = default;
};
/// Class responsible for formatting diagnostics and presenting them
/// to the user.
class DiagnosticEngine {
public:
/// The source manager used to interpret source locations and
/// display diagnostics.
SourceManager &SourceMgr;
private:
/// The diagnostic consumer(s) that will be responsible for actually
/// emitting diagnostics.
SmallVector<DiagnosticConsumer *, 2> Consumers;
/// Tracks diagnostic behaviors and state
DiagnosticState state;
/// The currently active diagnostic, if there is one.
Optional<Diagnostic> ActiveDiagnostic;
/// All diagnostics that have are no longer active but have not yet
/// been emitted due to an open transaction.
SmallVector<Diagnostic, 4> TentativeDiagnostics;
/// The set of declarations for which we have pretty-printed
/// results that we can point to on the command line.
llvm::DenseMap<const Decl *, SourceLoc> PrettyPrintedDeclarations;
llvm::BumpPtrAllocator TransactionAllocator;
/// A set of all strings involved in current transactional chain.
/// This is required because diagnostics are not directly emitted
/// but rather stored until all transactions complete.
llvm::StringSet<llvm::BumpPtrAllocator &> TransactionStrings;
/// Diagnostic producer to handle the logic behind retrieving a localized
/// diagnostic message.
std::unique_ptr<diag::LocalizationProducer> localization;
/// The number of open diagnostic transactions. Diagnostics are only
/// emitted once all transactions have closed.
unsigned TransactionCount = 0;
/// For batch mode, use this to know where to output a diagnostic from a
/// non-primary file. It's any location in the buffer of the current primary
/// input being compiled.
/// May be invalid.
SourceLoc bufferIndirectlyCausingDiagnostic;
/// Print diagnostic names after their messages
bool printDiagnosticNames = false;
/// Path to diagnostic documentation directory.
std::string diagnosticDocumentationPath = "";
friend class InFlightDiagnostic;
friend class DiagnosticTransaction;
friend class CompoundDiagnosticTransaction;
public:
explicit DiagnosticEngine(SourceManager &SourceMgr)
: SourceMgr(SourceMgr), ActiveDiagnostic(),
TransactionStrings(TransactionAllocator) {}
/// hadAnyError - return true if any *error* diagnostics have been emitted.
bool hadAnyError() const { return state.hadAnyError(); }
bool hasFatalErrorOccurred() const {
return state.hasFatalErrorOccurred();
}
void setShowDiagnosticsAfterFatalError(bool val = true) {
state.setShowDiagnosticsAfterFatalError(val);
}
bool getShowDiagnosticsAfterFatalError() {
return state.getShowDiagnosticsAfterFatalError();
}
void flushConsumers() {
for (auto consumer : Consumers)
consumer->flush();
}
/// Whether to skip emitting warnings
void setSuppressWarnings(bool val) { state.setSuppressWarnings(val); }
bool getSuppressWarnings() const {
return state.getSuppressWarnings();
}
/// Whether to treat warnings as errors
void setWarningsAsErrors(bool val) { state.setWarningsAsErrors(val); }
bool getWarningsAsErrors() const {
return state.getWarningsAsErrors();
}
/// Whether to print diagnostic names after their messages
void setPrintDiagnosticNames(bool val) {
printDiagnosticNames = val;
}
bool getPrintDiagnosticNames() const {
return printDiagnosticNames;
}
void setDiagnosticDocumentationPath(std::string path) {
diagnosticDocumentationPath = path;
}
StringRef getDiagnosticDocumentationPath() {
return diagnosticDocumentationPath;
}
void setLocalization(std::string locale, std::string path) {
assert(!locale.empty());
assert(!path.empty());
llvm::SmallString<128> filePath(path);
llvm::sys::path::append(filePath, locale);
llvm::sys::path::replace_extension(filePath, ".db");
// If the serialized diagnostics file not available,
// fallback to the `YAML` file.
if (llvm::sys::fs::exists(filePath)) {
if (auto file = llvm::MemoryBuffer::getFile(filePath)) {
localization = std::make_unique<diag::SerializedLocalizationProducer>(
std::move(file.get()));
}
} else {
llvm::sys::path::replace_extension(filePath, ".yaml");
// In case of missing localization files, we should fallback to messages
// from `.def` files.
if (llvm::sys::fs::exists(filePath)) {
localization =
std::make_unique<diag::YAMLLocalizationProducer>(filePath.str());
}
}
}
void ignoreDiagnostic(DiagID id) {
state.setDiagnosticBehavior(id, DiagnosticState::Behavior::Ignore);
}
void resetHadAnyError() {
state.resetHadAnyError();
}
/// Add an additional DiagnosticConsumer to receive diagnostics.
void addConsumer(DiagnosticConsumer &Consumer) {
Consumers.push_back(&Consumer);
}
/// Remove a specific DiagnosticConsumer.
void removeConsumer(DiagnosticConsumer &Consumer) {
Consumers.erase(
std::remove(Consumers.begin(), Consumers.end(), &Consumer));
}
/// Remove and return all \c DiagnosticConsumers.
std::vector<DiagnosticConsumer *> takeConsumers() {
auto Result = std::vector<DiagnosticConsumer*>(Consumers.begin(),
Consumers.end());
Consumers.clear();
return Result;
}
/// Return all \c DiagnosticConsumers.
ArrayRef<DiagnosticConsumer *> getConsumers() const {
return Consumers;
}
/// Emit a diagnostic using a preformatted array of diagnostic
/// arguments.
///
/// \param Loc The location to which the diagnostic refers in the source
/// code.
///
/// \param ID The diagnostic ID.
///
/// \param Args The preformatted set of diagnostic arguments. The caller
/// must ensure that the diagnostic arguments have the appropriate type.
///
/// \returns An in-flight diagnostic, to which additional information can
/// be attached.
InFlightDiagnostic diagnose(SourceLoc Loc, DiagID ID,
ArrayRef<DiagnosticArgument> Args) {
return diagnose(Loc, Diagnostic(ID, Args));
}
/// Emit a diagnostic using a preformatted array of diagnostic
/// arguments.
///
/// \param Loc The declaration name location to which the
/// diagnostic refers in the source code.
///
/// \param ID The diagnostic ID.
///
/// \param Args The preformatted set of diagnostic arguments. The caller
/// must ensure that the diagnostic arguments have the appropriate type.
///
/// \returns An in-flight diagnostic, to which additional information can
/// be attached.
InFlightDiagnostic diagnose(DeclNameLoc Loc, DiagID ID,
ArrayRef<DiagnosticArgument> Args) {
return diagnose(Loc.getBaseNameLoc(), Diagnostic(ID, Args));
}
/// Emit an already-constructed diagnostic at the given location.
///
/// \param Loc The location to which the diagnostic refers in the source
/// code.
///
/// \param D The diagnostic.
///
/// \returns An in-flight diagnostic, to which additional information can
/// be attached.
InFlightDiagnostic diagnose(SourceLoc Loc, const Diagnostic &D) {
assert(!ActiveDiagnostic && "Already have an active diagnostic");
ActiveDiagnostic = D;
ActiveDiagnostic->setLoc(Loc);
return InFlightDiagnostic(*this);
}
/// Emit a diagnostic with the given set of diagnostic arguments.
///
/// \param Loc The location to which the diagnostic refers in the source
/// code.
///
/// \param ID The diagnostic to be emitted.
///
/// \param Args The diagnostic arguments, which will be converted to
/// the types expected by the diagnostic \p ID.
template<typename ...ArgTypes>
InFlightDiagnostic
diagnose(SourceLoc Loc, Diag<ArgTypes...> ID,
typename detail::PassArgument<ArgTypes>::type... Args) {
return diagnose(Loc, Diagnostic(ID, std::move(Args)...));
}
/// Delete an API that may lead clients to avoid specifying source location.
template<typename ...ArgTypes>
InFlightDiagnostic
diagnose(Diag<ArgTypes...> ID,
typename detail::PassArgument<ArgTypes>::type... Args) = delete;
/// Emit a diagnostic with the given set of diagnostic arguments.
///
/// \param Loc The declaration name location to which the
/// diagnostic refers in the source code.
///
/// \param ID The diagnostic to be emitted.
///
/// \param Args The diagnostic arguments, which will be converted to
/// the types expected by the diagnostic \p ID.
template<typename ...ArgTypes>
InFlightDiagnostic
diagnose(DeclNameLoc Loc, Diag<ArgTypes...> ID,
typename detail::PassArgument<ArgTypes>::type... Args) {
return diagnose(Loc.getBaseNameLoc(), Diagnostic(ID, std::move(Args)...));
}
/// Emit a diagnostic using a preformatted array of diagnostic
/// arguments.
///
/// \param decl The declaration to which this diagnostic refers, which
/// may or may not have associated source-location information.
///
/// \param id The diagnostic ID.
///
/// \param args The preformatted set of diagnostic arguments. The caller
/// must ensure that the diagnostic arguments have the appropriate type.
///
/// \returns An in-flight diagnostic, to which additional information can
/// be attached.
InFlightDiagnostic diagnose(const Decl *decl, DiagID id,
ArrayRef<DiagnosticArgument> args) {
return diagnose(decl, Diagnostic(id, args));
}
/// Emit an already-constructed diagnostic referencing the given
/// declaration.
///
/// \param decl The declaration to which this diagnostic refers, which
/// may or may not have associated source-location information.
///
/// \param diag The diagnostic.
///
/// \returns An in-flight diagnostic, to which additional information can
/// be attached.
InFlightDiagnostic diagnose(const Decl *decl, const Diagnostic &diag) {
assert(!ActiveDiagnostic && "Already have an active diagnostic");
ActiveDiagnostic = diag;
ActiveDiagnostic->setDecl(decl);
return InFlightDiagnostic(*this);
}
/// Emit a diagnostic with the given set of diagnostic arguments.
///
/// \param decl The declaration to which this diagnostic refers, which
/// may or may not have associated source-location information.
///
/// \param id The diagnostic to be emitted.
///
/// \param args The diagnostic arguments, which will be converted to
/// the types expected by the diagnostic \p ID.
template<typename ...ArgTypes>
InFlightDiagnostic
diagnose(const Decl *decl, Diag<ArgTypes...> id,
typename detail::PassArgument<ArgTypes>::type... args) {
return diagnose(decl, Diagnostic(id, std::move(args)...));
}
/// Emit a parent diagnostic and attached notes.
///
/// \param parentDiag An InFlightDiagnostic representing the parent diag.
///
/// \param builder A closure which builds and emits notes to be attached to
/// the parent diag.
void diagnoseWithNotes(InFlightDiagnostic parentDiag,
llvm::function_ref<void(void)> builder);
/// \returns true if diagnostic is marked with PointsToFirstBadToken
/// option.
bool isDiagnosticPointsToFirstBadToken(DiagID id) const;
/// \returns true if any diagnostic consumer gave an error while invoking
//// \c finishProcessing.
bool finishProcessing();
/// Format the given diagnostic text and place the result in the given
/// buffer.
static void formatDiagnosticText(
llvm::raw_ostream &Out, StringRef InText,
ArrayRef<DiagnosticArgument> FormatArgs,
DiagnosticFormatOptions FormatOpts = DiagnosticFormatOptions());
private:
/// Called when tentative diagnostic is about to be flushed,
/// to apply any required transformations e.g. copy string arguments
/// to extend their lifetime.
void onTentativeDiagnosticFlush(Diagnostic &diagnostic);
/// Flush the active diagnostic.
void flushActiveDiagnostic();
/// Retrieve the active diagnostic.
Diagnostic &getActiveDiagnostic() { return *ActiveDiagnostic; }
/// Generate DiagnosticInfo for a Diagnostic to be passed to consumers.
Optional<DiagnosticInfo>
diagnosticInfoForDiagnostic(const Diagnostic &diagnostic);
/// Send \c diag to all diagnostic consumers.
void emitDiagnostic(const Diagnostic &diag);
/// Send all tentative diagnostics to all diagnostic consumers and
/// delete them.
void emitTentativeDiagnostics();
public:
llvm::StringRef diagnosticStringFor(const DiagID id,
bool printDiagnosticName);
/// If there is no clear .dia file for a diagnostic, put it in the one
/// corresponding to the SourceLoc given here.
/// In particular, in batch mode when a diagnostic is located in
/// a non-primary file, use this affordance to place it in the .dia
/// file for the primary that is currently being worked on.
void setBufferIndirectlyCausingDiagnosticToInput(SourceLoc);
void resetBufferIndirectlyCausingDiagnostic();
SourceLoc getDefaultDiagnosticLoc() const {
return bufferIndirectlyCausingDiagnostic;
}
};
class BufferIndirectlyCausingDiagnosticRAII {
private:
DiagnosticEngine &Diags;
public:
BufferIndirectlyCausingDiagnosticRAII(const SourceFile &SF);
~BufferIndirectlyCausingDiagnosticRAII() {
Diags.resetBufferIndirectlyCausingDiagnostic();
}
};
/// Represents a diagnostic transaction. While a transaction is
/// open, all recorded diagnostics are saved until the transaction commits,
/// at which point they are emitted. If the transaction is instead aborted,
/// the diagnostics are erased. Transactions may be nested but must be closed
/// in LIFO order. An open transaction is implicitly committed upon
/// destruction.
class DiagnosticTransaction {
protected:
DiagnosticEngine &Engine;
/// How many tentative diagnostics there were when the transaction
/// was opened.
unsigned PrevDiagnostics;
/// How many other transactions were open when this transaction was
/// opened.
unsigned Depth;
/// Whether this transaction is currently open.
bool IsOpen = true;
public:
DiagnosticTransaction(const DiagnosticTransaction &) = delete;
DiagnosticTransaction &operator=(const DiagnosticTransaction &) = delete;
explicit DiagnosticTransaction(DiagnosticEngine &engine)
: Engine(engine),
PrevDiagnostics(Engine.TentativeDiagnostics.size()),
Depth(Engine.TransactionCount),
IsOpen(true)
{
Engine.TransactionCount++;
}
~DiagnosticTransaction() {
if (IsOpen) {
commit();
}
if (Depth == 0) {
Engine.TransactionStrings.clear();
Engine.TransactionAllocator.Reset();
}
}
bool hasErrors() const {
ArrayRef<Diagnostic> diagnostics(Engine.TentativeDiagnostics.begin() +
PrevDiagnostics,
Engine.TentativeDiagnostics.end());
for (auto &diagnostic : diagnostics) {
auto behavior = Engine.state.determineBehavior(diagnostic.getID());
if (behavior == DiagnosticState::Behavior::Fatal ||
behavior == DiagnosticState::Behavior::Error)
return true;
}
return false;
}
/// Abort and close this transaction and erase all diagnostics
/// record while it was open.
void abort() {
close();
Engine.TentativeDiagnostics.erase(
Engine.TentativeDiagnostics.begin() + PrevDiagnostics,
Engine.TentativeDiagnostics.end());
}
/// Commit and close this transaction. If this is the top-level
/// transaction, emit any diagnostics that were recorded while it was open.
void commit() {
close();
if (Depth == 0) {
assert(PrevDiagnostics == 0);
Engine.emitTentativeDiagnostics();
}
}
private:
void close() {
assert(IsOpen && "only open transactions may be closed");
IsOpen = false;
Engine.TransactionCount--;
assert(Depth == Engine.TransactionCount &&
"transactions must be closed LIFO");
}
};
/// Represents a diagnostic transaction which constructs a compound diagnostic
/// from any diagnostics emitted inside. A compound diagnostic consists of a
/// parent error, warning, or remark followed by a variable number of child
/// notes. The semantics are otherwise the same as a regular
/// DiagnosticTransaction.
class CompoundDiagnosticTransaction : public DiagnosticTransaction {
public:
explicit CompoundDiagnosticTransaction(DiagnosticEngine &engine)
: DiagnosticTransaction(engine) {}
~CompoundDiagnosticTransaction() {
if (IsOpen) {
commit();
}
if (Depth == 0) {
Engine.TransactionStrings.clear();
Engine.TransactionAllocator.Reset();
}
}
void commit() {
assert(PrevDiagnostics < Engine.TentativeDiagnostics.size() &&
"CompoundDiagnosticTransaction must contain at least one diag");
// The first diagnostic is assumed to be the parent. If this is not an
// error or warning, we'll assert later when trying to add children.
Diagnostic &parent = Engine.TentativeDiagnostics[PrevDiagnostics];
// Associate the children with the parent.
for (auto diag =
Engine.TentativeDiagnostics.begin() + PrevDiagnostics + 1;
diag != Engine.TentativeDiagnostics.end(); ++diag) {
diag->setIsChildNote(true);
parent.addChildNote(std::move(*diag));
}
// Erase the children, they'll be emitted alongside their parent.
Engine.TentativeDiagnostics.erase(Engine.TentativeDiagnostics.begin() +
PrevDiagnostics + 1,
Engine.TentativeDiagnostics.end());
DiagnosticTransaction::commit();
}
};
inline void
DiagnosticEngine::diagnoseWithNotes(InFlightDiagnostic parentDiag,
llvm::function_ref<void(void)> builder) {
CompoundDiagnosticTransaction transaction(*this);
parentDiag.flush();
builder();
}
} // end namespace swift
#endif