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llvm-project/clang/lib/Basic/IdentifierTable.cpp
Erich Keane c8554e13ee
Turn -Wdeprecated-literal-operator on by default (#111027) 
It would be nice to see what our users think about this change, as this
is something that WG21/EWG quite wants to fix a handful of questionable
issues with UB. Depending on the outcome of this after being committed,
we might instead suggest EWG undeprecate this, and require a bit of
'magic' from the lexer.

Additionally, this patch makes it so we emit this diagnostic ALSO in
cases where the literal name is reserved. It doesn't make sense to limit
that.

---------

Co-authored-by: Vlad Serebrennikov <serebrennikov.vladislav@gmail.com>
2024-10-11 06:10:03 -07:00

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//===- IdentifierTable.cpp - Hash table for identifier lookup -------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file implements the IdentifierInfo, IdentifierVisitor, and
// IdentifierTable interfaces.
//
//===----------------------------------------------------------------------===//
#include "clang/Basic/IdentifierTable.h"
#include "clang/Basic/CharInfo.h"
#include "clang/Basic/DiagnosticLex.h"
#include "clang/Basic/LangOptions.h"
#include "clang/Basic/OperatorKinds.h"
#include "clang/Basic/Specifiers.h"
#include "clang/Basic/TargetBuiltins.h"
#include "clang/Basic/TokenKinds.h"
#include "llvm/ADT/DenseMapInfo.h"
#include "llvm/ADT/FoldingSet.h"
#include "llvm/ADT/SmallString.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Support/Allocator.h"
#include "llvm/Support/raw_ostream.h"
#include <cassert>
#include <cstdio>
#include <cstring>
#include <string>
using namespace clang;
// A check to make sure the ObjCOrBuiltinID has sufficient room to store the
// largest possible target/aux-target combination. If we exceed this, we likely
// need to just change the ObjCOrBuiltinIDBits value in IdentifierTable.h.
static_assert(2 * LargestBuiltinID < (2 << (InterestingIdentifierBits - 1)),
"Insufficient ObjCOrBuiltinID Bits");
//===----------------------------------------------------------------------===//
// IdentifierTable Implementation
//===----------------------------------------------------------------------===//
IdentifierIterator::~IdentifierIterator() = default;
IdentifierInfoLookup::~IdentifierInfoLookup() = default;
namespace {
/// A simple identifier lookup iterator that represents an
/// empty sequence of identifiers.
class EmptyLookupIterator : public IdentifierIterator {
public:
StringRef Next() override { return StringRef(); }
};
} // namespace
IdentifierIterator *IdentifierInfoLookup::getIdentifiers() {
return new EmptyLookupIterator();
}
IdentifierTable::IdentifierTable(IdentifierInfoLookup *ExternalLookup)
: HashTable(8192), // Start with space for 8K identifiers.
ExternalLookup(ExternalLookup) {}
IdentifierTable::IdentifierTable(const LangOptions &LangOpts,
IdentifierInfoLookup *ExternalLookup)
: IdentifierTable(ExternalLookup) {
// Populate the identifier table with info about keywords for the current
// language.
AddKeywords(LangOpts);
}
//===----------------------------------------------------------------------===//
// Language Keyword Implementation
//===----------------------------------------------------------------------===//
// Constants for TokenKinds.def
namespace {
enum TokenKey : unsigned {
KEYC99 = 0x1,
KEYCXX = 0x2,
KEYCXX11 = 0x4,
KEYGNU = 0x8,
KEYMS = 0x10,
BOOLSUPPORT = 0x20,
KEYALTIVEC = 0x40,
KEYNOCXX = 0x80,
KEYBORLAND = 0x100,
KEYOPENCLC = 0x200,
KEYC23 = 0x400,
KEYNOMS18 = 0x800,
KEYNOOPENCL = 0x1000,
WCHARSUPPORT = 0x2000,
HALFSUPPORT = 0x4000,
CHAR8SUPPORT = 0x8000,
KEYOBJC = 0x10000,
KEYZVECTOR = 0x20000,
KEYCOROUTINES = 0x40000,
KEYMODULES = 0x80000,
KEYCXX20 = 0x100000,
KEYOPENCLCXX = 0x200000,
KEYMSCOMPAT = 0x400000,
KEYSYCL = 0x800000,
KEYCUDA = 0x1000000,
KEYZOS = 0x2000000,
KEYNOZOS = 0x4000000,
KEYHLSL = 0x8000000,
KEYFIXEDPOINT = 0x10000000,
KEYMAX = KEYFIXEDPOINT, // The maximum key
KEYALLCXX = KEYCXX | KEYCXX11 | KEYCXX20,
KEYALL = (KEYMAX | (KEYMAX - 1)) & ~KEYNOMS18 & ~KEYNOOPENCL &
~KEYNOZOS // KEYNOMS18, KEYNOOPENCL, KEYNOZOS are excluded.
};
/// How a keyword is treated in the selected standard. This enum is ordered
/// intentionally so that the value that 'wins' is the most 'permissive'.
enum KeywordStatus {
KS_Unknown, // Not yet calculated. Used when figuring out the status.
KS_Disabled, // Disabled
KS_Future, // Is a keyword in future standard
KS_Extension, // Is an extension
KS_Enabled, // Enabled
};
} // namespace
// This works on a single TokenKey flag and checks the LangOpts to get the
// KeywordStatus based exclusively on this flag, so that it can be merged in
// getKeywordStatus. Most should be enabled/disabled, but some might imply
// 'future' versions, or extensions. Returns 'unknown' unless this is KNOWN to
// be disabled, and the calling function makes it 'disabled' if no other flag
// changes it. This is necessary for the KEYNOCXX and KEYNOOPENCL flags.
static KeywordStatus getKeywordStatusHelper(const LangOptions &LangOpts,
TokenKey Flag) {
// Flag is a single bit version of TokenKey (that is, not
// KEYALL/KEYALLCXX/etc), so we can check with == throughout this function.
assert((Flag & ~(Flag - 1)) == Flag && "Multiple bits set?");
switch (Flag) {
case KEYC99:
if (LangOpts.C99)
return KS_Enabled;
return !LangOpts.CPlusPlus ? KS_Future : KS_Unknown;
case KEYC23:
if (LangOpts.C23)
return KS_Enabled;
return !LangOpts.CPlusPlus ? KS_Future : KS_Unknown;
case KEYCXX:
return LangOpts.CPlusPlus ? KS_Enabled : KS_Unknown;
case KEYCXX11:
if (LangOpts.CPlusPlus11)
return KS_Enabled;
return LangOpts.CPlusPlus ? KS_Future : KS_Unknown;
case KEYCXX20:
if (LangOpts.CPlusPlus20)
return KS_Enabled;
return LangOpts.CPlusPlus ? KS_Future : KS_Unknown;
case KEYGNU:
return LangOpts.GNUKeywords ? KS_Extension : KS_Unknown;
case KEYMS:
return LangOpts.MicrosoftExt ? KS_Extension : KS_Unknown;
case BOOLSUPPORT:
if (LangOpts.Bool) return KS_Enabled;
return !LangOpts.CPlusPlus ? KS_Future : KS_Unknown;
case KEYALTIVEC:
return LangOpts.AltiVec ? KS_Enabled : KS_Unknown;
case KEYBORLAND:
return LangOpts.Borland ? KS_Extension : KS_Unknown;
case KEYOPENCLC:
return LangOpts.OpenCL && !LangOpts.OpenCLCPlusPlus ? KS_Enabled
: KS_Unknown;
case WCHARSUPPORT:
return LangOpts.WChar ? KS_Enabled : KS_Unknown;
case HALFSUPPORT:
return LangOpts.Half ? KS_Enabled : KS_Unknown;
case CHAR8SUPPORT:
if (LangOpts.Char8) return KS_Enabled;
if (LangOpts.CPlusPlus20) return KS_Unknown;
if (LangOpts.CPlusPlus) return KS_Future;
return KS_Unknown;
case KEYOBJC:
// We treat bridge casts as objective-C keywords so we can warn on them
// in non-arc mode.
return LangOpts.ObjC ? KS_Enabled : KS_Unknown;
case KEYZVECTOR:
return LangOpts.ZVector ? KS_Enabled : KS_Unknown;
case KEYCOROUTINES:
return LangOpts.Coroutines ? KS_Enabled : KS_Unknown;
case KEYMODULES:
return KS_Unknown;
case KEYOPENCLCXX:
return LangOpts.OpenCLCPlusPlus ? KS_Enabled : KS_Unknown;
case KEYMSCOMPAT:
return LangOpts.MSVCCompat ? KS_Enabled : KS_Unknown;
case KEYSYCL:
return LangOpts.isSYCL() ? KS_Enabled : KS_Unknown;
case KEYCUDA:
return LangOpts.CUDA ? KS_Enabled : KS_Unknown;
case KEYZOS:
return LangOpts.ZOSExt ? KS_Enabled : KS_Unknown;
case KEYHLSL:
return LangOpts.HLSL ? KS_Enabled : KS_Unknown;
case KEYNOCXX:
// This is enabled in all non-C++ modes, but might be enabled for other
// reasons as well.
return LangOpts.CPlusPlus ? KS_Unknown : KS_Enabled;
case KEYNOOPENCL:
case KEYNOMS18:
case KEYNOZOS:
// The disable behavior for this is handled in getKeywordStatus.
return KS_Unknown;
case KEYFIXEDPOINT:
return LangOpts.FixedPoint ? KS_Enabled : KS_Disabled;
default:
llvm_unreachable("Unknown KeywordStatus flag");
}
}
/// Translates flags as specified in TokenKinds.def into keyword status
/// in the given language standard.
static KeywordStatus getKeywordStatus(const LangOptions &LangOpts,
unsigned Flags) {
// KEYALL means always enabled, so special case this one.
if (Flags == KEYALL) return KS_Enabled;
// These are tests that need to 'always win', as they are special in that they
// disable based on certain conditions.
if (LangOpts.OpenCL && (Flags & KEYNOOPENCL)) return KS_Disabled;
if (LangOpts.MSVCCompat && (Flags & KEYNOMS18) &&
!LangOpts.isCompatibleWithMSVC(LangOptions::MSVC2015))
return KS_Disabled;
if (LangOpts.ZOSExt && (Flags & KEYNOZOS))
return KS_Disabled;
KeywordStatus CurStatus = KS_Unknown;
while (Flags != 0) {
unsigned CurFlag = Flags & ~(Flags - 1);
Flags = Flags & ~CurFlag;
CurStatus = std::max(
CurStatus,
getKeywordStatusHelper(LangOpts, static_cast<TokenKey>(CurFlag)));
}
if (CurStatus == KS_Unknown)
return KS_Disabled;
return CurStatus;
}
/// AddKeyword - This method is used to associate a token ID with specific
/// identifiers because they are language keywords. This causes the lexer to
/// automatically map matching identifiers to specialized token codes.
static void AddKeyword(StringRef Keyword,
tok::TokenKind TokenCode, unsigned Flags,
const LangOptions &LangOpts, IdentifierTable &Table) {
KeywordStatus AddResult = getKeywordStatus(LangOpts, Flags);
// Don't add this keyword if disabled in this language.
if (AddResult == KS_Disabled) return;
IdentifierInfo &Info =
Table.get(Keyword, AddResult == KS_Future ? tok::identifier : TokenCode);
Info.setIsExtensionToken(AddResult == KS_Extension);
Info.setIsFutureCompatKeyword(AddResult == KS_Future);
}
/// AddCXXOperatorKeyword - Register a C++ operator keyword alternative
/// representations.
static void AddCXXOperatorKeyword(StringRef Keyword,
tok::TokenKind TokenCode,
IdentifierTable &Table) {
IdentifierInfo &Info = Table.get(Keyword, TokenCode);
Info.setIsCPlusPlusOperatorKeyword();
}
/// AddObjCKeyword - Register an Objective-C \@keyword like "class" "selector"
/// or "property".
static void AddObjCKeyword(StringRef Name,
tok::ObjCKeywordKind ObjCID,
IdentifierTable &Table) {
Table.get(Name).setObjCKeywordID(ObjCID);
}
static void AddNotableIdentifier(StringRef Name,
tok::NotableIdentifierKind BTID,
IdentifierTable &Table) {
// Don't add 'not_notable' identifier.
if (BTID != tok::not_notable) {
IdentifierInfo &Info = Table.get(Name, tok::identifier);
Info.setNotableIdentifierID(BTID);
}
}
/// AddKeywords - Add all keywords to the symbol table.
///
void IdentifierTable::AddKeywords(const LangOptions &LangOpts) {
// Add keywords and tokens for the current language.
#define KEYWORD(NAME, FLAGS) \
AddKeyword(StringRef(#NAME), tok::kw_ ## NAME, \
FLAGS, LangOpts, *this);
#define ALIAS(NAME, TOK, FLAGS) \
AddKeyword(StringRef(NAME), tok::kw_ ## TOK, \
FLAGS, LangOpts, *this);
#define CXX_KEYWORD_OPERATOR(NAME, ALIAS) \
if (LangOpts.CXXOperatorNames) \
AddCXXOperatorKeyword(StringRef(#NAME), tok::ALIAS, *this);
#define OBJC_AT_KEYWORD(NAME) \
if (LangOpts.ObjC) \
AddObjCKeyword(StringRef(#NAME), tok::objc_##NAME, *this);
#define NOTABLE_IDENTIFIER(NAME) \
AddNotableIdentifier(StringRef(#NAME), tok::NAME, *this);
#define TESTING_KEYWORD(NAME, FLAGS)
#include "clang/Basic/TokenKinds.def"
if (LangOpts.ParseUnknownAnytype)
AddKeyword("__unknown_anytype", tok::kw___unknown_anytype, KEYALL,
LangOpts, *this);
if (LangOpts.DeclSpecKeyword)
AddKeyword("__declspec", tok::kw___declspec, KEYALL, LangOpts, *this);
if (LangOpts.IEEE128)
AddKeyword("__ieee128", tok::kw___float128, KEYALL, LangOpts, *this);
// Add the 'import' contextual keyword.
get("import").setModulesImport(true);
}
/// Checks if the specified token kind represents a keyword in the
/// specified language.
/// \returns Status of the keyword in the language.
static KeywordStatus getTokenKwStatus(const LangOptions &LangOpts,
tok::TokenKind K) {
switch (K) {
#define KEYWORD(NAME, FLAGS) \
case tok::kw_##NAME: return getKeywordStatus(LangOpts, FLAGS);
#include "clang/Basic/TokenKinds.def"
default: return KS_Disabled;
}
}
/// Returns true if the identifier represents a keyword in the
/// specified language.
bool IdentifierInfo::isKeyword(const LangOptions &LangOpts) const {
switch (getTokenKwStatus(LangOpts, getTokenID())) {
case KS_Enabled:
case KS_Extension:
return true;
default:
return false;
}
}
/// Returns true if the identifier represents a C++ keyword in the
/// specified language.
bool IdentifierInfo::isCPlusPlusKeyword(const LangOptions &LangOpts) const {
if (!LangOpts.CPlusPlus || !isKeyword(LangOpts))
return false;
// This is a C++ keyword if this identifier is not a keyword when checked
// using LangOptions without C++ support.
LangOptions LangOptsNoCPP = LangOpts;
LangOptsNoCPP.CPlusPlus = false;
LangOptsNoCPP.CPlusPlus11 = false;
LangOptsNoCPP.CPlusPlus20 = false;
return !isKeyword(LangOptsNoCPP);
}
ReservedIdentifierStatus
IdentifierInfo::isReserved(const LangOptions &LangOpts) const {
StringRef Name = getName();
// '_' is a reserved identifier, but its use is so common (e.g. to store
// ignored values) that we don't warn on it.
if (Name.size() <= 1)
return ReservedIdentifierStatus::NotReserved;
// [lex.name] p3
if (Name[0] == '_') {
// Each name that begins with an underscore followed by an uppercase letter
// or another underscore is reserved.
if (Name[1] == '_')
return ReservedIdentifierStatus::StartsWithDoubleUnderscore;
if ('A' <= Name[1] && Name[1] <= 'Z')
return ReservedIdentifierStatus::
StartsWithUnderscoreFollowedByCapitalLetter;
// This is a bit misleading: it actually means it's only reserved if we're
// at global scope because it starts with an underscore.
return ReservedIdentifierStatus::StartsWithUnderscoreAtGlobalScope;
}
// Each name that contains a double underscore (__) is reserved.
if (LangOpts.CPlusPlus && Name.contains("__"))
return ReservedIdentifierStatus::ContainsDoubleUnderscore;
return ReservedIdentifierStatus::NotReserved;
}
ReservedLiteralSuffixIdStatus
IdentifierInfo::isReservedLiteralSuffixId() const {
StringRef Name = getName();
// Note: the diag::warn_deprecated_literal_operator_id diagnostic depends on
// this being the first check we do, so if this order changes, we have to fix
// that as well.
if (Name[0] != '_')
return ReservedLiteralSuffixIdStatus::NotStartsWithUnderscore;
if (Name.contains("__"))
return ReservedLiteralSuffixIdStatus::ContainsDoubleUnderscore;
return ReservedLiteralSuffixIdStatus::NotReserved;
}
StringRef IdentifierInfo::deuglifiedName() const {
StringRef Name = getName();
if (Name.size() >= 2 && Name.front() == '_' &&
(Name[1] == '_' || (Name[1] >= 'A' && Name[1] <= 'Z')))
return Name.ltrim('_');
return Name;
}
tok::PPKeywordKind IdentifierInfo::getPPKeywordID() const {
// We use a perfect hash function here involving the length of the keyword,
// the first and third character. For preprocessor ID's there are no
// collisions (if there were, the switch below would complain about duplicate
// case values). Note that this depends on 'if' being null terminated.
#define HASH(LEN, FIRST, THIRD) \
(LEN << 6) + (((FIRST - 'a') - (THIRD - 'a')) & 63)
#define CASE(LEN, FIRST, THIRD, NAME) \
case HASH(LEN, FIRST, THIRD): \
return memcmp(Name, #NAME, LEN) ? tok::pp_not_keyword : tok::pp_ ## NAME
unsigned Len = getLength();
if (Len < 2) return tok::pp_not_keyword;
const char *Name = getNameStart();
switch (HASH(Len, Name[0], Name[2])) {
default: return tok::pp_not_keyword;
CASE( 2, 'i', '\0', if);
CASE( 4, 'e', 'i', elif);
CASE( 4, 'e', 's', else);
CASE( 4, 'l', 'n', line);
CASE( 4, 's', 'c', sccs);
CASE( 5, 'e', 'b', embed);
CASE( 5, 'e', 'd', endif);
CASE( 5, 'e', 'r', error);
CASE( 5, 'i', 'e', ident);
CASE( 5, 'i', 'd', ifdef);
CASE( 5, 'u', 'd', undef);
CASE( 6, 'a', 's', assert);
CASE( 6, 'd', 'f', define);
CASE( 6, 'i', 'n', ifndef);
CASE( 6, 'i', 'p', import);
CASE( 6, 'p', 'a', pragma);
CASE( 7, 'd', 'f', defined);
CASE( 7, 'e', 'i', elifdef);
CASE( 7, 'i', 'c', include);
CASE( 7, 'w', 'r', warning);
CASE( 8, 'e', 'i', elifndef);
CASE( 8, 'u', 'a', unassert);
CASE(12, 'i', 'c', include_next);
CASE(14, '_', 'p', __public_macro);
CASE(15, '_', 'p', __private_macro);
CASE(16, '_', 'i', __include_macros);
#undef CASE
#undef HASH
}
}
//===----------------------------------------------------------------------===//
// Stats Implementation
//===----------------------------------------------------------------------===//
/// PrintStats - Print statistics about how well the identifier table is doing
/// at hashing identifiers.
void IdentifierTable::PrintStats() const {
unsigned NumBuckets = HashTable.getNumBuckets();
unsigned NumIdentifiers = HashTable.getNumItems();
unsigned NumEmptyBuckets = NumBuckets-NumIdentifiers;
unsigned AverageIdentifierSize = 0;
unsigned MaxIdentifierLength = 0;
// TODO: Figure out maximum times an identifier had to probe for -stats.
for (llvm::StringMap<IdentifierInfo*, llvm::BumpPtrAllocator>::const_iterator
I = HashTable.begin(), E = HashTable.end(); I != E; ++I) {
unsigned IdLen = I->getKeyLength();
AverageIdentifierSize += IdLen;
if (MaxIdentifierLength < IdLen)
MaxIdentifierLength = IdLen;
}
fprintf(stderr, "\n*** Identifier Table Stats:\n");
fprintf(stderr, "# Identifiers: %d\n", NumIdentifiers);
fprintf(stderr, "# Empty Buckets: %d\n", NumEmptyBuckets);
fprintf(stderr, "Hash density (#identifiers per bucket): %f\n",
NumIdentifiers/(double)NumBuckets);
fprintf(stderr, "Ave identifier length: %f\n",
(AverageIdentifierSize/(double)NumIdentifiers));
fprintf(stderr, "Max identifier length: %d\n", MaxIdentifierLength);
// Compute statistics about the memory allocated for identifiers.
HashTable.getAllocator().PrintStats();
}
//===----------------------------------------------------------------------===//
// SelectorTable Implementation
//===----------------------------------------------------------------------===//
unsigned llvm::DenseMapInfo<clang::Selector>::getHashValue(clang::Selector S) {
return DenseMapInfo<void*>::getHashValue(S.getAsOpaquePtr());
}
bool Selector::isKeywordSelector(ArrayRef<StringRef> Names) const {
assert(!Names.empty() && "must have >= 1 selector slots");
if (getNumArgs() != Names.size())
return false;
for (unsigned I = 0, E = Names.size(); I != E; ++I) {
if (getNameForSlot(I) != Names[I])
return false;
}
return true;
}
bool Selector::isUnarySelector(StringRef Name) const {
return isUnarySelector() && getNameForSlot(0) == Name;
}
unsigned Selector::getNumArgs() const {
unsigned IIF = getIdentifierInfoFlag();
if (IIF <= ZeroArg)
return 0;
if (IIF == OneArg)
return 1;
// We point to a MultiKeywordSelector.
MultiKeywordSelector *SI = getMultiKeywordSelector();
return SI->getNumArgs();
}
const IdentifierInfo *
Selector::getIdentifierInfoForSlot(unsigned argIndex) const {
if (getIdentifierInfoFlag() < MultiArg) {
assert(argIndex == 0 && "illegal keyword index");
return getAsIdentifierInfo();
}
// We point to a MultiKeywordSelector.
MultiKeywordSelector *SI = getMultiKeywordSelector();
return SI->getIdentifierInfoForSlot(argIndex);
}
StringRef Selector::getNameForSlot(unsigned int argIndex) const {
const IdentifierInfo *II = getIdentifierInfoForSlot(argIndex);
return II ? II->getName() : StringRef();
}
std::string MultiKeywordSelector::getName() const {
SmallString<256> Str;
llvm::raw_svector_ostream OS(Str);
for (keyword_iterator I = keyword_begin(), E = keyword_end(); I != E; ++I) {
if (*I)
OS << (*I)->getName();
OS << ':';
}
return std::string(OS.str());
}
std::string Selector::getAsString() const {
if (isNull())
return "<null selector>";
if (getIdentifierInfoFlag() < MultiArg) {
const IdentifierInfo *II = getAsIdentifierInfo();
if (getNumArgs() == 0) {
assert(II && "If the number of arguments is 0 then II is guaranteed to "
"not be null.");
return std::string(II->getName());
}
if (!II)
return ":";
return II->getName().str() + ":";
}
// We have a multiple keyword selector.
return getMultiKeywordSelector()->getName();
}
void Selector::print(llvm::raw_ostream &OS) const {
OS << getAsString();
}
LLVM_DUMP_METHOD void Selector::dump() const { print(llvm::errs()); }
/// Interpreting the given string using the normal CamelCase
/// conventions, determine whether the given string starts with the
/// given "word", which is assumed to end in a lowercase letter.
static bool startsWithWord(StringRef name, StringRef word) {
if (name.size() < word.size()) return false;
return ((name.size() == word.size() || !isLowercase(name[word.size()])) &&
name.starts_with(word));
}
ObjCMethodFamily Selector::getMethodFamilyImpl(Selector sel) {
const IdentifierInfo *first = sel.getIdentifierInfoForSlot(0);
if (!first) return OMF_None;
StringRef name = first->getName();
if (sel.isUnarySelector()) {
if (name == "autorelease") return OMF_autorelease;
if (name == "dealloc") return OMF_dealloc;
if (name == "finalize") return OMF_finalize;
if (name == "release") return OMF_release;
if (name == "retain") return OMF_retain;
if (name == "retainCount") return OMF_retainCount;
if (name == "self") return OMF_self;
if (name == "initialize") return OMF_initialize;
}
if (name == "performSelector" || name == "performSelectorInBackground" ||
name == "performSelectorOnMainThread")
return OMF_performSelector;
// The other method families may begin with a prefix of underscores.
name = name.ltrim('_');
if (name.empty()) return OMF_None;
switch (name.front()) {
case 'a':
if (startsWithWord(name, "alloc")) return OMF_alloc;
break;
case 'c':
if (startsWithWord(name, "copy")) return OMF_copy;
break;
case 'i':
if (startsWithWord(name, "init")) return OMF_init;
break;
case 'm':
if (startsWithWord(name, "mutableCopy")) return OMF_mutableCopy;
break;
case 'n':
if (startsWithWord(name, "new")) return OMF_new;
break;
default:
break;
}
return OMF_None;
}
ObjCInstanceTypeFamily Selector::getInstTypeMethodFamily(Selector sel) {
const IdentifierInfo *first = sel.getIdentifierInfoForSlot(0);
if (!first) return OIT_None;
StringRef name = first->getName();
if (name.empty()) return OIT_None;
switch (name.front()) {
case 'a':
if (startsWithWord(name, "array")) return OIT_Array;
break;
case 'd':
if (startsWithWord(name, "default")) return OIT_ReturnsSelf;
if (startsWithWord(name, "dictionary")) return OIT_Dictionary;
break;
case 's':
if (startsWithWord(name, "shared")) return OIT_ReturnsSelf;
if (startsWithWord(name, "standard")) return OIT_Singleton;
break;
case 'i':
if (startsWithWord(name, "init")) return OIT_Init;
break;
default:
break;
}
return OIT_None;
}
ObjCStringFormatFamily Selector::getStringFormatFamilyImpl(Selector sel) {
const IdentifierInfo *first = sel.getIdentifierInfoForSlot(0);
if (!first) return SFF_None;
StringRef name = first->getName();
switch (name.front()) {
case 'a':
if (name == "appendFormat") return SFF_NSString;
break;
case 'i':
if (name == "initWithFormat") return SFF_NSString;
break;
case 'l':
if (name == "localizedStringWithFormat") return SFF_NSString;
break;
case 's':
if (name == "stringByAppendingFormat" ||
name == "stringWithFormat") return SFF_NSString;
break;
}
return SFF_None;
}
namespace {
struct SelectorTableImpl {
llvm::FoldingSet<MultiKeywordSelector> Table;
llvm::BumpPtrAllocator Allocator;
};
} // namespace
static SelectorTableImpl &getSelectorTableImpl(void *P) {
return *static_cast<SelectorTableImpl*>(P);
}
SmallString<64>
SelectorTable::constructSetterName(StringRef Name) {
SmallString<64> SetterName("set");
SetterName += Name;
SetterName[3] = toUppercase(SetterName[3]);
return SetterName;
}
Selector
SelectorTable::constructSetterSelector(IdentifierTable &Idents,
SelectorTable &SelTable,
const IdentifierInfo *Name) {
IdentifierInfo *SetterName =
&Idents.get(constructSetterName(Name->getName()));
return SelTable.getUnarySelector(SetterName);
}
std::string SelectorTable::getPropertyNameFromSetterSelector(Selector Sel) {
StringRef Name = Sel.getNameForSlot(0);
assert(Name.starts_with("set") && "invalid setter name");
return (Twine(toLowercase(Name[3])) + Name.drop_front(4)).str();
}
size_t SelectorTable::getTotalMemory() const {
SelectorTableImpl &SelTabImpl = getSelectorTableImpl(Impl);
return SelTabImpl.Allocator.getTotalMemory();
}
Selector SelectorTable::getSelector(unsigned nKeys,
const IdentifierInfo **IIV) {
if (nKeys < 2)
return Selector(IIV[0], nKeys);
SelectorTableImpl &SelTabImpl = getSelectorTableImpl(Impl);
// Unique selector, to guarantee there is one per name.
llvm::FoldingSetNodeID ID;
MultiKeywordSelector::Profile(ID, IIV, nKeys);
void *InsertPos = nullptr;
if (MultiKeywordSelector *SI =
SelTabImpl.Table.FindNodeOrInsertPos(ID, InsertPos))
return Selector(SI);
// MultiKeywordSelector objects are not allocated with new because they have a
// variable size array (for parameter types) at the end of them.
unsigned Size = sizeof(MultiKeywordSelector) + nKeys*sizeof(IdentifierInfo *);
MultiKeywordSelector *SI =
(MultiKeywordSelector *)SelTabImpl.Allocator.Allocate(
Size, alignof(MultiKeywordSelector));
new (SI) MultiKeywordSelector(nKeys, IIV);
SelTabImpl.Table.InsertNode(SI, InsertPos);
return Selector(SI);
}
SelectorTable::SelectorTable() {
Impl = new SelectorTableImpl();
}
SelectorTable::~SelectorTable() {
delete &getSelectorTableImpl(Impl);
}
const char *clang::getOperatorSpelling(OverloadedOperatorKind Operator) {
switch (Operator) {
case OO_None:
case NUM_OVERLOADED_OPERATORS:
return nullptr;
#define OVERLOADED_OPERATOR(Name,Spelling,Token,Unary,Binary,MemberOnly) \
case OO_##Name: return Spelling;
#include "clang/Basic/OperatorKinds.def"
}
llvm_unreachable("Invalid OverloadedOperatorKind!");
}
StringRef clang::getNullabilitySpelling(NullabilityKind kind,
bool isContextSensitive) {
switch (kind) {
case NullabilityKind::NonNull:
return isContextSensitive ? "nonnull" : "_Nonnull";
case NullabilityKind::Nullable:
return isContextSensitive ? "nullable" : "_Nullable";
case NullabilityKind::NullableResult:
assert(!isContextSensitive &&
"_Nullable_result isn't supported as context-sensitive keyword");
return "_Nullable_result";
case NullabilityKind::Unspecified:
return isContextSensitive ? "null_unspecified" : "_Null_unspecified";
}
llvm_unreachable("Unknown nullability kind.");
}
llvm::raw_ostream &clang::operator<<(llvm::raw_ostream &OS,
NullabilityKind NK) {
switch (NK) {
case NullabilityKind::NonNull:
return OS << "NonNull";
case NullabilityKind::Nullable:
return OS << "Nullable";
case NullabilityKind::NullableResult:
return OS << "NullableResult";
case NullabilityKind::Unspecified:
return OS << "Unspecified";
}
llvm_unreachable("Unknown nullability kind.");
}
diag::kind
IdentifierTable::getFutureCompatDiagKind(const IdentifierInfo &II,
const LangOptions &LangOpts) {
assert(II.isFutureCompatKeyword() && "diagnostic should not be needed");
unsigned Flags = llvm::StringSwitch<unsigned>(II.getName())
#define KEYWORD(NAME, FLAGS) .Case(#NAME, FLAGS)
#include "clang/Basic/TokenKinds.def"
#undef KEYWORD
;
if (LangOpts.CPlusPlus) {
if ((Flags & KEYCXX11) == KEYCXX11)
return diag::warn_cxx11_keyword;
// char8_t is not modeled as a CXX20_KEYWORD because it's not
// unconditionally enabled in C++20 mode. (It can be disabled
// by -fno-char8_t.)
if (((Flags & KEYCXX20) == KEYCXX20) ||
((Flags & CHAR8SUPPORT) == CHAR8SUPPORT))
return diag::warn_cxx20_keyword;
} else {
if ((Flags & KEYC99) == KEYC99)
return diag::warn_c99_keyword;
if ((Flags & KEYC23) == KEYC23)
return diag::warn_c23_keyword;
}
llvm_unreachable(
"Keyword not known to come from a newer Standard or proposed Standard");
}
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