//===--- RAIIObjectsForParser.h - RAII helpers for the parser ---*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines and implements the some simple RAII objects that are used
// by the parser to manage bits in recursion.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_CLANG_LIB_PARSE_RAIIOBJECTSFORPARSER_H
#define LLVM_CLANG_LIB_PARSE_RAIIOBJECTSFORPARSER_H
#include "clang/Parse/ParseDiagnostic.h"
#include "clang/Parse/Parser.h"
#include "clang/Sema/DelayedDiagnostic.h"
#include "clang/Sema/Sema.h"
namespace clang {
// TODO: move ParsingClassDefinition here.
// TODO: move TentativeParsingAction here.
/// \brief A RAII object used to temporarily suppress access-like
/// checking. Access-like checks are those associated with
/// controlling the use of a declaration, like C++ access control
/// errors and deprecation warnings. They are contextually
/// dependent, in that they can only be resolved with full
/// information about what's being declared. They are also
/// suppressed in certain contexts, like the template arguments of
/// an explicit instantiation. However, those suppression contexts
/// cannot necessarily be fully determined in advance; for
/// example, something starting like this:
/// template <> class std::vector<A::PrivateType>
/// might be the entirety of an explicit instantiation:
/// template <> class std::vector<A::PrivateType>;
/// or just an elaborated type specifier:
/// template <> class std::vector<A::PrivateType> make_vector<>();
/// Therefore this class collects all the diagnostics and permits
/// them to be re-delayed in a new context.
class SuppressAccessChecks {
Sema &S;
sema::DelayedDiagnosticPool DiagnosticPool;
Sema::ParsingDeclState State;
bool Active;
public:
/// Begin suppressing access-like checks
SuppressAccessChecks(Parser &P, bool activate = true)
: S(P.getActions()), DiagnosticPool(nullptr) {
if (activate) {
State = S.PushParsingDeclaration(DiagnosticPool);
Active = true;
} else {
Active = false;
}
}
SuppressAccessChecks(SuppressAccessChecks &&Other)
: S(Other.S), DiagnosticPool(std::move(Other.DiagnosticPool)),
State(Other.State), Active(Other.Active) {
Other.Active = false;
}
void operator=(SuppressAccessChecks &&Other) = delete;
void done() {
assert(Active && "trying to end an inactive suppression");
S.PopParsingDeclaration(State, nullptr);
Active = false;
}
void redelay() {
assert(!Active && "redelaying without having ended first");
if (!DiagnosticPool.pool_empty())
S.redelayDiagnostics(DiagnosticPool);
assert(DiagnosticPool.pool_empty());
}
~SuppressAccessChecks() {
if (Active) done();
}
};
/// \brief RAII object used to inform the actions that we're
/// currently parsing a declaration. This is active when parsing a
/// variable's initializer, but not when parsing the body of a
/// class or function definition.
class ParsingDeclRAIIObject {
Sema &Actions;
sema::DelayedDiagnosticPool DiagnosticPool;
Sema::ParsingDeclState State;
bool Popped;
ParsingDeclRAIIObject(const ParsingDeclRAIIObject &) = delete;
void operator=(const ParsingDeclRAIIObject &) = delete;
public:
enum NoParent_t { NoParent };
ParsingDeclRAIIObject(Parser &P, NoParent_t _)
: Actions(P.getActions()), DiagnosticPool(nullptr) {
push();
}
/// Creates a RAII object whose pool is optionally parented by another.
ParsingDeclRAIIObject(Parser &P,
const sema::DelayedDiagnosticPool *parentPool)
: Actions(P.getActions()), DiagnosticPool(parentPool) {
push();
}
/// Creates a RAII object and, optionally, initialize its
/// diagnostics pool by stealing the diagnostics from another
/// RAII object (which is assumed to be the current top pool).
ParsingDeclRAIIObject(Parser &P, ParsingDeclRAIIObject *other)
: Actions(P.getActions()),
DiagnosticPool(other ? other->DiagnosticPool.getParent() : nullptr) {
if (other) {
DiagnosticPool.steal(other->DiagnosticPool);
other->abort();
}
push();
}
~ParsingDeclRAIIObject() {
abort();
}
sema::DelayedDiagnosticPool &getDelayedDiagnosticPool() {
return DiagnosticPool;
}
const sema::DelayedDiagnosticPool &getDelayedDiagnosticPool() const {
return DiagnosticPool;
}
/// Resets the RAII object for a new declaration.
void reset() {
abort();
push();
}
/// Signals that the context was completed without an appropriate
/// declaration being parsed.
void abort() {
pop(nullptr);
}
void complete(Decl *D) {
assert(!Popped && "ParsingDeclaration has already been popped!");
pop(D);
}
/// Unregister this object from Sema, but remember all the
/// diagnostics that were emitted into it.
void abortAndRemember() {
pop(nullptr);
}
private:
void push() {
State = Actions.PushParsingDeclaration(DiagnosticPool);
Popped = false;
}
void pop(Decl *D) {
if (!Popped) {
Actions.PopParsingDeclaration(State, D);
Popped = true;
}
}
};
/// A class for parsing a DeclSpec.
class ParsingDeclSpec : public DeclSpec {
ParsingDeclRAIIObject ParsingRAII;
public:
ParsingDeclSpec(Parser &P)
: DeclSpec(P.getAttrFactory()),
ParsingRAII(P, ParsingDeclRAIIObject::NoParent) {}
ParsingDeclSpec(Parser &P, ParsingDeclRAIIObject *RAII)
: DeclSpec(P.getAttrFactory()),
ParsingRAII(P, RAII) {}
const sema::DelayedDiagnosticPool &getDelayedDiagnosticPool() const {
return ParsingRAII.getDelayedDiagnosticPool();
}
void complete(Decl *D) {
ParsingRAII.complete(D);
}
void abort() {
ParsingRAII.abort();
}
};
/// A class for parsing a declarator.
class ParsingDeclarator : public Declarator {
ParsingDeclRAIIObject ParsingRAII;
public:
ParsingDeclarator(Parser &P, const ParsingDeclSpec &DS, TheContext C)
: Declarator(DS, C), ParsingRAII(P, &DS.getDelayedDiagnosticPool()) {
}
const ParsingDeclSpec &getDeclSpec() const {
return static_cast<const ParsingDeclSpec&>(Declarator::getDeclSpec());
}
ParsingDeclSpec &getMutableDeclSpec() const {
return const_cast<ParsingDeclSpec&>(getDeclSpec());
}
void clear() {
Declarator::clear();
ParsingRAII.reset();
}
void complete(Decl *D) {
ParsingRAII.complete(D);
}
};
/// A class for parsing a field declarator.
class ParsingFieldDeclarator : public FieldDeclarator {
ParsingDeclRAIIObject ParsingRAII;
public:
ParsingFieldDeclarator(Parser &P, const ParsingDeclSpec &DS)
: FieldDeclarator(DS), ParsingRAII(P, &DS.getDelayedDiagnosticPool()) {
}
const ParsingDeclSpec &getDeclSpec() const {
return static_cast<const ParsingDeclSpec&>(D.getDeclSpec());
}
ParsingDeclSpec &getMutableDeclSpec() const {
return const_cast<ParsingDeclSpec&>(getDeclSpec());
}
void complete(Decl *D) {
ParsingRAII.complete(D);
}
};
/// ExtensionRAIIObject - This saves the state of extension warnings when
/// constructed and disables them. When destructed, it restores them back to
/// the way they used to be. This is used to handle __extension__ in the
/// parser.
class ExtensionRAIIObject {
ExtensionRAIIObject(const ExtensionRAIIObject &) = delete;
void operator=(const ExtensionRAIIObject &) = delete;
DiagnosticsEngine &Diags;
public:
ExtensionRAIIObject(DiagnosticsEngine &diags) : Diags(diags) {
Diags.IncrementAllExtensionsSilenced();
}
~ExtensionRAIIObject() {
Diags.DecrementAllExtensionsSilenced();
}
};
/// ColonProtectionRAIIObject - This sets the Parser::ColonIsSacred bool and
/// restores it when destroyed. This says that "foo:" should not be
/// considered a possible typo for "foo::" for error recovery purposes.
class ColonProtectionRAIIObject {
Parser &P;
bool OldVal;
public:
ColonProtectionRAIIObject(Parser &p, bool Value = true)
: P(p), OldVal(P.ColonIsSacred) {
P.ColonIsSacred = Value;
}
/// restore - This can be used to restore the state early, before the dtor
/// is run.
void restore() {
P.ColonIsSacred = OldVal;
}
~ColonProtectionRAIIObject() {
restore();
}
};
/// \brief RAII object that makes '>' behave either as an operator
/// or as the closing angle bracket for a template argument list.
class GreaterThanIsOperatorScope {
bool &GreaterThanIsOperator;
bool OldGreaterThanIsOperator;
public:
GreaterThanIsOperatorScope(bool >IO, bool Val)
: GreaterThanIsOperator(GTIO), OldGreaterThanIsOperator(GTIO) {
GreaterThanIsOperator = Val;
}
~GreaterThanIsOperatorScope() {
GreaterThanIsOperator = OldGreaterThanIsOperator;
}
};
class InMessageExpressionRAIIObject {
bool &InMessageExpression;
bool OldValue;
public:
InMessageExpressionRAIIObject(Parser &P, bool Value)
: InMessageExpression(P.InMessageExpression),
OldValue(P.InMessageExpression) {
InMessageExpression = Value;
}
~InMessageExpressionRAIIObject() {
InMessageExpression = OldValue;
}
};
/// \brief RAII object that makes sure paren/bracket/brace count is correct
/// after declaration/statement parsing, even when there's a parsing error.
class ParenBraceBracketBalancer {
Parser &P;
unsigned short ParenCount, BracketCount, BraceCount;
public:
ParenBraceBracketBalancer(Parser &p)
: P(p), ParenCount(p.ParenCount), BracketCount(p.BracketCount),
BraceCount(p.BraceCount) { }
~ParenBraceBracketBalancer() {
P.ParenCount = ParenCount;
P.BracketCount = BracketCount;
P.BraceCount = BraceCount;
}
};
class PoisonSEHIdentifiersRAIIObject {
PoisonIdentifierRAIIObject Ident_AbnormalTermination;
PoisonIdentifierRAIIObject Ident_GetExceptionCode;
PoisonIdentifierRAIIObject Ident_GetExceptionInfo;
PoisonIdentifierRAIIObject Ident__abnormal_termination;
PoisonIdentifierRAIIObject Ident__exception_code;
PoisonIdentifierRAIIObject Ident__exception_info;
PoisonIdentifierRAIIObject Ident___abnormal_termination;
PoisonIdentifierRAIIObject Ident___exception_code;
PoisonIdentifierRAIIObject Ident___exception_info;
public:
PoisonSEHIdentifiersRAIIObject(Parser &Self, bool NewValue)
: Ident_AbnormalTermination(Self.Ident_AbnormalTermination, NewValue),
Ident_GetExceptionCode(Self.Ident_GetExceptionCode, NewValue),
Ident_GetExceptionInfo(Self.Ident_GetExceptionInfo, NewValue),
Ident__abnormal_termination(Self.Ident__abnormal_termination, NewValue),
Ident__exception_code(Self.Ident__exception_code, NewValue),
Ident__exception_info(Self.Ident__exception_info, NewValue),
Ident___abnormal_termination(Self.Ident___abnormal_termination, NewValue),
Ident___exception_code(Self.Ident___exception_code, NewValue),
Ident___exception_info(Self.Ident___exception_info, NewValue) {
}
};
/// \brief RAII class that helps handle the parsing of an open/close delimiter
/// pair, such as braces { ... } or parentheses ( ... ).
class BalancedDelimiterTracker : public GreaterThanIsOperatorScope {
Parser& P;
tok::TokenKind Kind, Close, FinalToken;
SourceLocation (Parser::*Consumer)();
SourceLocation LOpen, LClose;
unsigned short &getDepth() {
switch (Kind) {
case tok::l_brace: return P.BraceCount;
case tok::l_square: return P.BracketCount;
case tok::l_paren: return P.ParenCount;
default: llvm_unreachable("Wrong token kind");
}
}
enum { MaxDepth = 256 };
bool diagnoseOverflow();
bool diagnoseMissingClose();
public:
BalancedDelimiterTracker(Parser& p, tok::TokenKind k,
tok::TokenKind FinalToken = tok::semi)
: GreaterThanIsOperatorScope(p.GreaterThanIsOperator, true),
P(p), Kind(k), FinalToken(FinalToken)
{
switch (Kind) {
default: llvm_unreachable("Unexpected balanced token");
case tok::l_brace:
Close = tok::r_brace;
Consumer = &Parser::ConsumeBrace;
break;
case tok::l_paren:
Close = tok::r_paren;
Consumer = &Parser::ConsumeParen;
break;
case tok::l_square:
Close = tok::r_square;
Consumer = &Parser::ConsumeBracket;
break;
}
}
SourceLocation getOpenLocation() const { return LOpen; }
SourceLocation getCloseLocation() const { return LClose; }
SourceRange getRange() const { return SourceRange(LOpen, LClose); }
bool consumeOpen() {
if (!P.Tok.is(Kind))
return true;
if (getDepth() < P.getLangOpts().BracketDepth) {
LOpen = (P.*Consumer)();
return false;
}
return diagnoseOverflow();
}
bool expectAndConsume(unsigned DiagID = diag::err_expected,
const char *Msg = "",
tok::TokenKind SkipToTok = tok::unknown);
bool consumeClose() {
if (P.Tok.is(Close)) {
LClose = (P.*Consumer)();
return false;
} else if (P.Tok.is(tok::semi) && P.NextToken().is(Close)) {
SourceLocation SemiLoc = P.ConsumeToken();
P.Diag(SemiLoc, diag::err_unexpected_semi)
<< Close << FixItHint::CreateRemoval(SourceRange(SemiLoc, SemiLoc));
LClose = (P.*Consumer)();
return false;
}
return diagnoseMissingClose();
}
void skipToEnd();
};
} // end namespace clang
#endif