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llvm-project/llvm/lib/AsmParser/LLLexer.cpp
Matt Arsenault 2502e3b7ba
IR: Promote "denormal-fp-math" to a first class attribute (#174293) 
Convert "denormal-fp-math" and "denormal-fp-math-f32" into a first
class denormal_fpenv attribute. Previously the query for the effective
denormal mode involved two string attribute queries with parsing. I'm
introducing more uses of this, so it makes sense to convert this
to a more efficient encoding. The old representation was also awkward
since it was split across two separate attributes. The new encoding
just stores the default and float modes as bitfields, largely avoiding
the need to consider if the other mode is set.

The syntax in the common cases looks like this:
  `denormal_fpenv(preservesign,preservesign)`
  `denormal_fpenv(float: preservesign,preservesign)`
  `denormal_fpenv(dynamic,dynamic float: preservesign,preservesign)`

I wasn't sure about reusing the float type name instead of adding a
new keyword. It's parsed as a type but only accepts float. I'm also
debating switching the name to subnormal to match the current
preferred IEEE terminology (also used by nofpclass and other
contexts).

This has a behavior change when using the command flag debug
options to set the denormal mode. The behavior of the flag
ignored functions with an explicit attribute set, per
the default and f32 version. Now that these are one attribute,
the flag logic can't distinguish which of the two components
were explicitly set on the function. Only one test appeared to
rely on this behavior, so I just avoided using the flags in it.

This also does not perform all the code cleanups this enables.
In particular the attributor handling could be cleaned up.

I also guessed at how to support this in MLIR. I followed
MemoryEffects as a reference; it appears bitfields are expanded
into arguments to attributes, so the representation there is
a bit uglier with the 2 2-element fields flattened into 4 arguments.
2026-02-05 13:31:26 +00:00

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//===- LLLexer.cpp - Lexer for .ll Files ----------------------------------===//
//
// 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
//
//===----------------------------------------------------------------------===//
//
// Implement the Lexer for .ll files.
//
//===----------------------------------------------------------------------===//
#include "llvm/AsmParser/LLLexer.h"
#include "llvm/ADT/APInt.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/Twine.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/IR/Instruction.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/SourceMgr.h"
#include <cassert>
#include <cctype>
#include <cstdio>
using namespace llvm;
// Both the lexer and parser can issue error messages. If the lexer issues a
// lexer error, since we do not terminate execution immediately, usually that
// is followed by the parser issuing a parser error. However, the error issued
// by the lexer is more relevant in that case as opposed to potentially more
// generic parser error. So instead of always recording the last error message
// use the `Priority` to establish a priority, with Lexer > Parser > None. We
// record the issued message only if the message has same or higher priority
// than the existing one. This prevents lexer errors from being overwritten by
// parser errors.
void LLLexer::Error(LocTy ErrorLoc, const Twine &Msg,
LLLexer::ErrorPriority Priority) {
if (Priority < ErrorInfo.Priority)
return;
ErrorInfo.Error = SM.GetMessage(ErrorLoc, SourceMgr::DK_Error, Msg);
ErrorInfo.Priority = Priority;
}
void LLLexer::Warning(LocTy WarningLoc, const Twine &Msg) const {
SM.PrintMessage(WarningLoc, SourceMgr::DK_Warning, Msg);
}
//===----------------------------------------------------------------------===//
// Helper functions.
//===----------------------------------------------------------------------===//
// atoull - Convert an ascii string of decimal digits into the unsigned long
// long representation... this does not have to do input error checking,
// because we know that the input will be matched by a suitable regex...
//
uint64_t LLLexer::atoull(const char *Buffer, const char *End) {
uint64_t Result = 0;
for (; Buffer != End; Buffer++) {
uint64_t OldRes = Result;
Result *= 10;
Result += *Buffer-'0';
if (Result < OldRes) { // overflow detected.
LexError("constant bigger than 64 bits detected");
return 0;
}
}
return Result;
}
uint64_t LLLexer::HexIntToVal(const char *Buffer, const char *End) {
uint64_t Result = 0;
for (; Buffer != End; ++Buffer) {
uint64_t OldRes = Result;
Result *= 16;
Result += hexDigitValue(*Buffer);
if (Result < OldRes) { // overflow detected.
LexError("constant bigger than 64 bits detected");
return 0;
}
}
return Result;
}
void LLLexer::HexToIntPair(const char *Buffer, const char *End,
uint64_t Pair[2]) {
Pair[0] = 0;
if (End - Buffer >= 16) {
for (int i = 0; i < 16; i++, Buffer++) {
assert(Buffer != End);
Pair[0] *= 16;
Pair[0] += hexDigitValue(*Buffer);
}
}
Pair[1] = 0;
for (int i = 0; i < 16 && Buffer != End; i++, Buffer++) {
Pair[1] *= 16;
Pair[1] += hexDigitValue(*Buffer);
}
if (Buffer != End)
LexError("constant bigger than 128 bits detected");
}
/// FP80HexToIntPair - translate an 80 bit FP80 number (20 hexits) into
/// { low64, high16 } as usual for an APInt.
void LLLexer::FP80HexToIntPair(const char *Buffer, const char *End,
uint64_t Pair[2]) {
Pair[1] = 0;
for (int i=0; i<4 && Buffer != End; i++, Buffer++) {
assert(Buffer != End);
Pair[1] *= 16;
Pair[1] += hexDigitValue(*Buffer);
}
Pair[0] = 0;
for (int i = 0; i < 16 && Buffer != End; i++, Buffer++) {
Pair[0] *= 16;
Pair[0] += hexDigitValue(*Buffer);
}
if (Buffer != End)
LexError("constant bigger than 128 bits detected");
}
// UnEscapeLexed - Run through the specified buffer and change \xx codes to the
// appropriate character.
static void UnEscapeLexed(std::string &Str) {
if (Str.empty()) return;
char *Buffer = &Str[0], *EndBuffer = Buffer+Str.size();
char *BOut = Buffer;
for (char *BIn = Buffer; BIn != EndBuffer; ) {
if (BIn[0] == '\\') {
if (BIn < EndBuffer-1 && BIn[1] == '\\') {
*BOut++ = '\\'; // Two \ becomes one
BIn += 2;
} else if (BIn < EndBuffer-2 &&
isxdigit(static_cast<unsigned char>(BIn[1])) &&
isxdigit(static_cast<unsigned char>(BIn[2]))) {
*BOut = hexDigitValue(BIn[1]) * 16 + hexDigitValue(BIn[2]);
BIn += 3; // Skip over handled chars
++BOut;
} else {
*BOut++ = *BIn++;
}
} else {
*BOut++ = *BIn++;
}
}
Str.resize(BOut-Buffer);
}
/// isLabelChar - Return true for [-a-zA-Z$._0-9].
static bool isLabelChar(char C) {
return isalnum(static_cast<unsigned char>(C)) || C == '-' || C == '$' ||
C == '.' || C == '_';
}
/// isLabelTail - Return true if this pointer points to a valid end of a label.
static const char *isLabelTail(const char *CurPtr) {
while (true) {
if (CurPtr[0] == ':') return CurPtr+1;
if (!isLabelChar(CurPtr[0])) return nullptr;
++CurPtr;
}
}
//===----------------------------------------------------------------------===//
// Lexer definition.
//===----------------------------------------------------------------------===//
LLLexer::LLLexer(StringRef StartBuf, SourceMgr &SM, SMDiagnostic &Err,
LLVMContext &C)
: CurBuf(StartBuf), ErrorInfo(Err), SM(SM), Context(C) {
CurPtr = CurBuf.begin();
}
int LLLexer::getNextChar() {
char CurChar = *CurPtr++;
switch (CurChar) {
default: return (unsigned char)CurChar;
case 0:
// A nul character in the stream is either the end of the current buffer or
// a random nul in the file. Disambiguate that here.
if (CurPtr-1 != CurBuf.end())
return 0; // Just whitespace.
// Otherwise, return end of file.
--CurPtr; // Another call to lex will return EOF again.
return EOF;
}
}
lltok::Kind LLLexer::LexToken() {
// Set token end to next location, since the end is exclusive.
PrevTokEnd = CurPtr;
while (true) {
TokStart = CurPtr;
int CurChar = getNextChar();
switch (CurChar) {
default:
// Handle letters: [a-zA-Z_]
if (isalpha(static_cast<unsigned char>(CurChar)) || CurChar == '_')
return LexIdentifier();
return lltok::Error;
case EOF: return lltok::Eof;
case 0:
case ' ':
case '\t':
case '\n':
case '\r':
// Ignore whitespace.
continue;
case '+': return LexPositive();
case '@': return LexAt();
case '$': return LexDollar();
case '%': return LexPercent();
case '"': return LexQuote();
case '.':
if (const char *Ptr = isLabelTail(CurPtr)) {
CurPtr = Ptr;
StrVal.assign(TokStart, CurPtr-1);
return lltok::LabelStr;
}
if (CurPtr[0] == '.' && CurPtr[1] == '.') {
CurPtr += 2;
return lltok::dotdotdot;
}
return lltok::Error;
case ';':
SkipLineComment();
continue;
case '!': return LexExclaim();
case '^':
return LexCaret();
case ':':
return lltok::colon;
case '#': return LexHash();
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
case '-':
return LexDigitOrNegative();
case '=': return lltok::equal;
case '[': return lltok::lsquare;
case ']': return lltok::rsquare;
case '{': return lltok::lbrace;
case '}': return lltok::rbrace;
case '<': return lltok::less;
case '>': return lltok::greater;
case '(': return lltok::lparen;
case ')': return lltok::rparen;
case ',': return lltok::comma;
case '*': return lltok::star;
case '|': return lltok::bar;
case '/':
if (getNextChar() != '*')
return lltok::Error;
if (SkipCComment())
return lltok::Error;
continue;
}
}
}
void LLLexer::SkipLineComment() {
while (true) {
if (CurPtr[0] == '\n' || CurPtr[0] == '\r' || getNextChar() == EOF)
return;
}
}
/// This skips C-style /**/ comments. Returns true if there
/// was an error.
bool LLLexer::SkipCComment() {
while (true) {
int CurChar = getNextChar();
switch (CurChar) {
case EOF:
LexError("unterminated comment");
return true;
case '*':
// End of the comment?
CurChar = getNextChar();
if (CurChar == '/')
return false;
if (CurChar == EOF) {
LexError("unterminated comment");
return true;
}
}
}
}
/// Lex all tokens that start with an @ character.
/// GlobalVar @\"[^\"]*\"
/// GlobalVar @[-a-zA-Z$._][-a-zA-Z$._0-9]*
/// GlobalVarID @[0-9]+
lltok::Kind LLLexer::LexAt() {
return LexVar(lltok::GlobalVar, lltok::GlobalID);
}
lltok::Kind LLLexer::LexDollar() {
if (const char *Ptr = isLabelTail(TokStart)) {
CurPtr = Ptr;
StrVal.assign(TokStart, CurPtr - 1);
return lltok::LabelStr;
}
// Handle DollarStringConstant: $\"[^\"]*\"
if (CurPtr[0] == '"') {
++CurPtr;
while (true) {
int CurChar = getNextChar();
if (CurChar == EOF) {
LexError("end of file in COMDAT variable name");
return lltok::Error;
}
if (CurChar == '"') {
StrVal.assign(TokStart + 2, CurPtr - 1);
UnEscapeLexed(StrVal);
if (StringRef(StrVal).contains(0)) {
LexError("NUL character is not allowed in names");
return lltok::Error;
}
return lltok::ComdatVar;
}
}
}
// Handle ComdatVarName: $[-a-zA-Z$._][-a-zA-Z$._0-9]*
if (ReadVarName())
return lltok::ComdatVar;
return lltok::Error;
}
/// ReadString - Read a string until the closing quote.
lltok::Kind LLLexer::ReadString(lltok::Kind kind) {
const char *Start = CurPtr;
while (true) {
int CurChar = getNextChar();
if (CurChar == EOF) {
LexError("end of file in string constant");
return lltok::Error;
}
if (CurChar == '"') {
StrVal.assign(Start, CurPtr-1);
UnEscapeLexed(StrVal);
return kind;
}
}
}
/// ReadVarName - Read the rest of a token containing a variable name.
bool LLLexer::ReadVarName() {
const char *NameStart = CurPtr;
if (isalpha(static_cast<unsigned char>(CurPtr[0])) ||
CurPtr[0] == '-' || CurPtr[0] == '$' ||
CurPtr[0] == '.' || CurPtr[0] == '_') {
++CurPtr;
while (isalnum(static_cast<unsigned char>(CurPtr[0])) ||
CurPtr[0] == '-' || CurPtr[0] == '$' ||
CurPtr[0] == '.' || CurPtr[0] == '_')
++CurPtr;
StrVal.assign(NameStart, CurPtr);
return true;
}
return false;
}
// Lex an ID: [0-9]+. On success, the ID is stored in UIntVal and Token is
// returned, otherwise the Error token is returned.
lltok::Kind LLLexer::LexUIntID(lltok::Kind Token) {
if (!isdigit(static_cast<unsigned char>(CurPtr[0])))
return lltok::Error;
for (++CurPtr; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr)
/*empty*/;
uint64_t Val = atoull(TokStart + 1, CurPtr);
if ((unsigned)Val != Val)
LexError("invalid value number (too large)");
UIntVal = unsigned(Val);
return Token;
}
lltok::Kind LLLexer::LexVar(lltok::Kind Var, lltok::Kind VarID) {
// Handle StringConstant: \"[^\"]*\"
if (CurPtr[0] == '"') {
++CurPtr;
while (true) {
int CurChar = getNextChar();
if (CurChar == EOF) {
LexError("end of file in global variable name");
return lltok::Error;
}
if (CurChar == '"') {
StrVal.assign(TokStart+2, CurPtr-1);
UnEscapeLexed(StrVal);
if (StringRef(StrVal).contains(0)) {
LexError("NUL character is not allowed in names");
return lltok::Error;
}
return Var;
}
}
}
// Handle VarName: [-a-zA-Z$._][-a-zA-Z$._0-9]*
if (ReadVarName())
return Var;
// Handle VarID: [0-9]+
return LexUIntID(VarID);
}
/// Lex all tokens that start with a % character.
/// LocalVar ::= %\"[^\"]*\"
/// LocalVar ::= %[-a-zA-Z$._][-a-zA-Z$._0-9]*
/// LocalVarID ::= %[0-9]+
lltok::Kind LLLexer::LexPercent() {
return LexVar(lltok::LocalVar, lltok::LocalVarID);
}
/// Lex all tokens that start with a " character.
/// QuoteLabel "[^"]+":
/// StringConstant "[^"]*"
lltok::Kind LLLexer::LexQuote() {
lltok::Kind kind = ReadString(lltok::StringConstant);
if (kind == lltok::Error || kind == lltok::Eof)
return kind;
if (CurPtr[0] == ':') {
++CurPtr;
if (StringRef(StrVal).contains(0)) {
LexError("NUL character is not allowed in names");
kind = lltok::Error;
} else {
kind = lltok::LabelStr;
}
}
return kind;
}
/// Lex all tokens that start with a ! character.
/// !foo
/// !
lltok::Kind LLLexer::LexExclaim() {
// Lex a metadata name as a MetadataVar.
if (isalpha(static_cast<unsigned char>(CurPtr[0])) ||
CurPtr[0] == '-' || CurPtr[0] == '$' ||
CurPtr[0] == '.' || CurPtr[0] == '_' || CurPtr[0] == '\\') {
++CurPtr;
while (isalnum(static_cast<unsigned char>(CurPtr[0])) ||
CurPtr[0] == '-' || CurPtr[0] == '$' ||
CurPtr[0] == '.' || CurPtr[0] == '_' || CurPtr[0] == '\\')
++CurPtr;
StrVal.assign(TokStart+1, CurPtr); // Skip !
UnEscapeLexed(StrVal);
return lltok::MetadataVar;
}
return lltok::exclaim;
}
/// Lex all tokens that start with a ^ character.
/// SummaryID ::= ^[0-9]+
lltok::Kind LLLexer::LexCaret() {
// Handle SummaryID: ^[0-9]+
return LexUIntID(lltok::SummaryID);
}
/// Lex all tokens that start with a # character.
/// AttrGrpID ::= #[0-9]+
/// Hash ::= #
lltok::Kind LLLexer::LexHash() {
// Handle AttrGrpID: #[0-9]+
if (isdigit(static_cast<unsigned char>(CurPtr[0])))
return LexUIntID(lltok::AttrGrpID);
return lltok::hash;
}
/// Lex a label, integer type, keyword, or hexadecimal integer constant.
/// Label [-a-zA-Z$._0-9]+:
/// IntegerType i[0-9]+
/// Keyword sdiv, float, ...
/// HexIntConstant [us]0x[0-9A-Fa-f]+
lltok::Kind LLLexer::LexIdentifier() {
const char *StartChar = CurPtr;
const char *IntEnd = CurPtr[-1] == 'i' ? nullptr : StartChar;
const char *KeywordEnd = nullptr;
for (; isLabelChar(*CurPtr); ++CurPtr) {
// If we decide this is an integer, remember the end of the sequence.
if (!IntEnd && !isdigit(static_cast<unsigned char>(*CurPtr)))
IntEnd = CurPtr;
if (!KeywordEnd && !isalnum(static_cast<unsigned char>(*CurPtr)) &&
*CurPtr != '_')
KeywordEnd = CurPtr;
}
// If we stopped due to a colon, unless we were directed to ignore it,
// this really is a label.
if (!IgnoreColonInIdentifiers && *CurPtr == ':') {
StrVal.assign(StartChar-1, CurPtr++);
return lltok::LabelStr;
}
// Otherwise, this wasn't a label. If this was valid as an integer type,
// return it.
if (!IntEnd) IntEnd = CurPtr;
if (IntEnd != StartChar) {
CurPtr = IntEnd;
uint64_t NumBits = atoull(StartChar, CurPtr);
if (NumBits < IntegerType::MIN_INT_BITS ||
NumBits > IntegerType::MAX_INT_BITS) {
LexError("bitwidth for integer type out of range");
return lltok::Error;
}
TyVal = IntegerType::get(Context, NumBits);
return lltok::Type;
}
// Otherwise, this was a letter sequence. See which keyword this is.
if (!KeywordEnd) KeywordEnd = CurPtr;
CurPtr = KeywordEnd;
--StartChar;
StringRef Keyword(StartChar, CurPtr - StartChar);
#define KEYWORD(STR) \
do { \
if (Keyword == #STR) \
return lltok::kw_##STR; \
} while (false)
KEYWORD(true); KEYWORD(false);
KEYWORD(declare); KEYWORD(define);
KEYWORD(global); KEYWORD(constant);
KEYWORD(dso_local);
KEYWORD(dso_preemptable);
KEYWORD(private);
KEYWORD(internal);
KEYWORD(available_externally);
KEYWORD(linkonce);
KEYWORD(linkonce_odr);
KEYWORD(weak); // Use as a linkage, and a modifier for "cmpxchg".
KEYWORD(weak_odr);
KEYWORD(appending);
KEYWORD(dllimport);
KEYWORD(dllexport);
KEYWORD(common);
KEYWORD(default);
KEYWORD(hidden);
KEYWORD(protected);
KEYWORD(unnamed_addr);
KEYWORD(local_unnamed_addr);
KEYWORD(externally_initialized);
KEYWORD(extern_weak);
KEYWORD(external);
KEYWORD(thread_local);
KEYWORD(localdynamic);
KEYWORD(initialexec);
KEYWORD(localexec);
KEYWORD(zeroinitializer);
KEYWORD(undef);
KEYWORD(null);
KEYWORD(none);
KEYWORD(poison);
KEYWORD(to);
KEYWORD(caller);
KEYWORD(within);
KEYWORD(from);
KEYWORD(tail);
KEYWORD(musttail);
KEYWORD(notail);
KEYWORD(target);
KEYWORD(triple);
KEYWORD(source_filename);
KEYWORD(unwind);
KEYWORD(datalayout);
KEYWORD(volatile);
KEYWORD(atomic);
KEYWORD(unordered);
KEYWORD(monotonic);
KEYWORD(acquire);
KEYWORD(release);
KEYWORD(acq_rel);
KEYWORD(seq_cst);
KEYWORD(syncscope);
KEYWORD(nnan);
KEYWORD(ninf);
KEYWORD(nsz);
KEYWORD(arcp);
KEYWORD(contract);
KEYWORD(reassoc);
KEYWORD(afn);
KEYWORD(fast);
KEYWORD(nuw);
KEYWORD(nsw);
KEYWORD(nusw);
KEYWORD(exact);
KEYWORD(disjoint);
KEYWORD(inbounds);
KEYWORD(nneg);
KEYWORD(samesign);
KEYWORD(inrange);
KEYWORD(addrspace);
KEYWORD(section);
KEYWORD(partition);
KEYWORD(code_model);
KEYWORD(alias);
KEYWORD(ifunc);
KEYWORD(module);
KEYWORD(asm);
KEYWORD(sideeffect);
KEYWORD(inteldialect);
KEYWORD(gc);
KEYWORD(prefix);
KEYWORD(prologue);
KEYWORD(no_sanitize_address);
KEYWORD(no_sanitize_hwaddress);
KEYWORD(sanitize_address_dyninit);
KEYWORD(ccc);
KEYWORD(fastcc);
KEYWORD(coldcc);
KEYWORD(cfguard_checkcc);
KEYWORD(x86_stdcallcc);
KEYWORD(x86_fastcallcc);
KEYWORD(x86_thiscallcc);
KEYWORD(x86_vectorcallcc);
KEYWORD(arm_apcscc);
KEYWORD(arm_aapcscc);
KEYWORD(arm_aapcs_vfpcc);
KEYWORD(aarch64_vector_pcs);
KEYWORD(aarch64_sve_vector_pcs);
KEYWORD(aarch64_sme_preservemost_from_x0);
KEYWORD(aarch64_sme_preservemost_from_x1);
KEYWORD(aarch64_sme_preservemost_from_x2);
KEYWORD(msp430_intrcc);
KEYWORD(avr_intrcc);
KEYWORD(avr_signalcc);
KEYWORD(ptx_kernel);
KEYWORD(ptx_device);
KEYWORD(spir_kernel);
KEYWORD(spir_func);
KEYWORD(intel_ocl_bicc);
KEYWORD(x86_64_sysvcc);
KEYWORD(win64cc);
KEYWORD(x86_regcallcc);
KEYWORD(swiftcc);
KEYWORD(swifttailcc);
KEYWORD(anyregcc);
KEYWORD(preserve_mostcc);
KEYWORD(preserve_allcc);
KEYWORD(preserve_nonecc);
KEYWORD(ghccc);
KEYWORD(x86_intrcc);
KEYWORD(hhvmcc);
KEYWORD(hhvm_ccc);
KEYWORD(cxx_fast_tlscc);
KEYWORD(amdgpu_vs);
KEYWORD(amdgpu_ls);
KEYWORD(amdgpu_hs);
KEYWORD(amdgpu_es);
KEYWORD(amdgpu_gs);
KEYWORD(amdgpu_ps);
KEYWORD(amdgpu_cs);
KEYWORD(amdgpu_cs_chain);
KEYWORD(amdgpu_cs_chain_preserve);
KEYWORD(amdgpu_kernel);
KEYWORD(amdgpu_gfx);
KEYWORD(amdgpu_gfx_whole_wave);
KEYWORD(tailcc);
KEYWORD(m68k_rtdcc);
KEYWORD(graalcc);
KEYWORD(riscv_vector_cc);
KEYWORD(riscv_vls_cc);
KEYWORD(cheriot_compartmentcallcc);
KEYWORD(cheriot_compartmentcalleecc);
KEYWORD(cheriot_librarycallcc);
KEYWORD(cc);
KEYWORD(c);
KEYWORD(attributes);
KEYWORD(sync);
KEYWORD(async);
#define GET_ATTR_NAMES
#define ATTRIBUTE_ENUM(ENUM_NAME, DISPLAY_NAME) \
KEYWORD(DISPLAY_NAME);
#include "llvm/IR/Attributes.inc"
KEYWORD(read);
KEYWORD(write);
KEYWORD(readwrite);
KEYWORD(argmem);
KEYWORD(target_mem0);
KEYWORD(target_mem1);
KEYWORD(inaccessiblemem);
KEYWORD(errnomem);
KEYWORD(argmemonly);
KEYWORD(inaccessiblememonly);
KEYWORD(inaccessiblemem_or_argmemonly);
KEYWORD(nocapture);
KEYWORD(address_is_null);
KEYWORD(address);
KEYWORD(provenance);
KEYWORD(read_provenance);
// denormal_fpenv attribute
KEYWORD(ieee);
KEYWORD(preservesign);
KEYWORD(positivezero);
KEYWORD(dynamic);
// nofpclass attribute
KEYWORD(all);
KEYWORD(nan);
KEYWORD(snan);
KEYWORD(qnan);
KEYWORD(inf);
// ninf already a keyword
KEYWORD(pinf);
KEYWORD(norm);
KEYWORD(nnorm);
KEYWORD(pnorm);
// sub already a keyword
KEYWORD(nsub);
KEYWORD(psub);
KEYWORD(zero);
KEYWORD(nzero);
KEYWORD(pzero);
KEYWORD(type);
KEYWORD(opaque);
KEYWORD(comdat);
// Comdat types
KEYWORD(any);
KEYWORD(exactmatch);
KEYWORD(largest);
KEYWORD(nodeduplicate);
KEYWORD(samesize);
KEYWORD(eq); KEYWORD(ne); KEYWORD(slt); KEYWORD(sgt); KEYWORD(sle);
KEYWORD(sge); KEYWORD(ult); KEYWORD(ugt); KEYWORD(ule); KEYWORD(uge);
KEYWORD(oeq); KEYWORD(one); KEYWORD(olt); KEYWORD(ogt); KEYWORD(ole);
KEYWORD(oge); KEYWORD(ord); KEYWORD(uno); KEYWORD(ueq); KEYWORD(une);
KEYWORD(xchg); KEYWORD(nand); KEYWORD(max); KEYWORD(min); KEYWORD(umax);
KEYWORD(umin); KEYWORD(fmax); KEYWORD(fmin);
KEYWORD(fmaximum);
KEYWORD(fminimum);
KEYWORD(uinc_wrap);
KEYWORD(udec_wrap);
KEYWORD(usub_cond);
KEYWORD(usub_sat);
KEYWORD(splat);
KEYWORD(vscale);
KEYWORD(x);
KEYWORD(blockaddress);
KEYWORD(dso_local_equivalent);
KEYWORD(no_cfi);
KEYWORD(ptrauth);
// Metadata types.
KEYWORD(distinct);
// Use-list order directives.
KEYWORD(uselistorder);
KEYWORD(uselistorder_bb);
KEYWORD(personality);
KEYWORD(cleanup);
KEYWORD(catch);
KEYWORD(filter);
// Summary index keywords.
KEYWORD(path);
KEYWORD(hash);
KEYWORD(gv);
KEYWORD(guid);
KEYWORD(name);
KEYWORD(summaries);
KEYWORD(flags);
KEYWORD(blockcount);
KEYWORD(linkage);
KEYWORD(visibility);
KEYWORD(notEligibleToImport);
KEYWORD(live);
KEYWORD(dsoLocal);
KEYWORD(canAutoHide);
KEYWORD(importType);
KEYWORD(definition);
KEYWORD(declaration);
KEYWORD(function);
KEYWORD(insts);
KEYWORD(funcFlags);
KEYWORD(readNone);
KEYWORD(readOnly);
KEYWORD(noRecurse);
KEYWORD(returnDoesNotAlias);
KEYWORD(noInline);
KEYWORD(alwaysInline);
KEYWORD(noUnwind);
KEYWORD(mayThrow);
KEYWORD(hasUnknownCall);
KEYWORD(mustBeUnreachable);
KEYWORD(calls);
KEYWORD(callee);
KEYWORD(params);
KEYWORD(param);
KEYWORD(hotness);
KEYWORD(unknown);
KEYWORD(critical);
// Deprecated, keep in order to support old files.
KEYWORD(relbf);
KEYWORD(variable);
KEYWORD(vTableFuncs);
KEYWORD(virtFunc);
KEYWORD(aliasee);
KEYWORD(refs);
KEYWORD(typeIdInfo);
KEYWORD(typeTests);
KEYWORD(typeTestAssumeVCalls);
KEYWORD(typeCheckedLoadVCalls);
KEYWORD(typeTestAssumeConstVCalls);
KEYWORD(typeCheckedLoadConstVCalls);
KEYWORD(vFuncId);
KEYWORD(offset);
KEYWORD(args);
KEYWORD(typeid);
KEYWORD(typeidCompatibleVTable);
KEYWORD(summary);
KEYWORD(typeTestRes);
KEYWORD(kind);
KEYWORD(unsat);
KEYWORD(byteArray);
KEYWORD(inline);
KEYWORD(single);
KEYWORD(allOnes);
KEYWORD(sizeM1BitWidth);
KEYWORD(alignLog2);
KEYWORD(sizeM1);
KEYWORD(bitMask);
KEYWORD(inlineBits);
KEYWORD(vcall_visibility);
KEYWORD(wpdResolutions);
KEYWORD(wpdRes);
KEYWORD(indir);
KEYWORD(singleImpl);
KEYWORD(branchFunnel);
KEYWORD(singleImplName);
KEYWORD(resByArg);
KEYWORD(byArg);
KEYWORD(uniformRetVal);
KEYWORD(uniqueRetVal);
KEYWORD(virtualConstProp);
KEYWORD(info);
KEYWORD(byte);
KEYWORD(bit);
KEYWORD(varFlags);
KEYWORD(callsites);
KEYWORD(clones);
KEYWORD(stackIds);
KEYWORD(allocs);
KEYWORD(versions);
KEYWORD(memProf);
KEYWORD(notcold);
#undef KEYWORD
// Keywords for types.
#define TYPEKEYWORD(STR, LLVMTY) \
do { \
if (Keyword == STR) { \
TyVal = LLVMTY; \
return lltok::Type; \
} \
} while (false)
TYPEKEYWORD("void", Type::getVoidTy(Context));
TYPEKEYWORD("half", Type::getHalfTy(Context));
TYPEKEYWORD("bfloat", Type::getBFloatTy(Context));
TYPEKEYWORD("float", Type::getFloatTy(Context));
TYPEKEYWORD("double", Type::getDoubleTy(Context));
TYPEKEYWORD("x86_fp80", Type::getX86_FP80Ty(Context));
TYPEKEYWORD("fp128", Type::getFP128Ty(Context));
TYPEKEYWORD("ppc_fp128", Type::getPPC_FP128Ty(Context));
TYPEKEYWORD("label", Type::getLabelTy(Context));
TYPEKEYWORD("metadata", Type::getMetadataTy(Context));
TYPEKEYWORD("x86_amx", Type::getX86_AMXTy(Context));
TYPEKEYWORD("token", Type::getTokenTy(Context));
TYPEKEYWORD("ptr", PointerType::getUnqual(Context));
#undef TYPEKEYWORD
// Keywords for instructions.
#define INSTKEYWORD(STR, Enum) \
do { \
if (Keyword == #STR) { \
UIntVal = Instruction::Enum; \
return lltok::kw_##STR; \
} \
} while (false)
INSTKEYWORD(fneg, FNeg);
INSTKEYWORD(add, Add); INSTKEYWORD(fadd, FAdd);
INSTKEYWORD(sub, Sub); INSTKEYWORD(fsub, FSub);
INSTKEYWORD(mul, Mul); INSTKEYWORD(fmul, FMul);
INSTKEYWORD(udiv, UDiv); INSTKEYWORD(sdiv, SDiv); INSTKEYWORD(fdiv, FDiv);
INSTKEYWORD(urem, URem); INSTKEYWORD(srem, SRem); INSTKEYWORD(frem, FRem);
INSTKEYWORD(shl, Shl); INSTKEYWORD(lshr, LShr); INSTKEYWORD(ashr, AShr);
INSTKEYWORD(and, And); INSTKEYWORD(or, Or); INSTKEYWORD(xor, Xor);
INSTKEYWORD(icmp, ICmp); INSTKEYWORD(fcmp, FCmp);
INSTKEYWORD(phi, PHI);
INSTKEYWORD(call, Call);
INSTKEYWORD(trunc, Trunc);
INSTKEYWORD(zext, ZExt);
INSTKEYWORD(sext, SExt);
INSTKEYWORD(fptrunc, FPTrunc);
INSTKEYWORD(fpext, FPExt);
INSTKEYWORD(uitofp, UIToFP);
INSTKEYWORD(sitofp, SIToFP);
INSTKEYWORD(fptoui, FPToUI);
INSTKEYWORD(fptosi, FPToSI);
INSTKEYWORD(inttoptr, IntToPtr);
INSTKEYWORD(ptrtoaddr, PtrToAddr);
INSTKEYWORD(ptrtoint, PtrToInt);
INSTKEYWORD(bitcast, BitCast);
INSTKEYWORD(addrspacecast, AddrSpaceCast);
INSTKEYWORD(select, Select);
INSTKEYWORD(va_arg, VAArg);
INSTKEYWORD(ret, Ret);
INSTKEYWORD(br, Br);
INSTKEYWORD(switch, Switch);
INSTKEYWORD(indirectbr, IndirectBr);
INSTKEYWORD(invoke, Invoke);
INSTKEYWORD(resume, Resume);
INSTKEYWORD(unreachable, Unreachable);
INSTKEYWORD(callbr, CallBr);
INSTKEYWORD(alloca, Alloca);
INSTKEYWORD(load, Load);
INSTKEYWORD(store, Store);
INSTKEYWORD(cmpxchg, AtomicCmpXchg);
INSTKEYWORD(atomicrmw, AtomicRMW);
INSTKEYWORD(fence, Fence);
INSTKEYWORD(getelementptr, GetElementPtr);
INSTKEYWORD(extractelement, ExtractElement);
INSTKEYWORD(insertelement, InsertElement);
INSTKEYWORD(shufflevector, ShuffleVector);
INSTKEYWORD(extractvalue, ExtractValue);
INSTKEYWORD(insertvalue, InsertValue);
INSTKEYWORD(landingpad, LandingPad);
INSTKEYWORD(cleanupret, CleanupRet);
INSTKEYWORD(catchret, CatchRet);
INSTKEYWORD(catchswitch, CatchSwitch);
INSTKEYWORD(catchpad, CatchPad);
INSTKEYWORD(cleanuppad, CleanupPad);
INSTKEYWORD(freeze, Freeze);
#undef INSTKEYWORD
#define DWKEYWORD(TYPE, TOKEN) \
do { \
if (Keyword.starts_with("DW_" #TYPE "_")) { \
StrVal.assign(Keyword.begin(), Keyword.end()); \
return lltok::TOKEN; \
} \
} while (false)
DWKEYWORD(TAG, DwarfTag);
DWKEYWORD(ATE, DwarfAttEncoding);
DWKEYWORD(VIRTUALITY, DwarfVirtuality);
DWKEYWORD(LANG, DwarfLang);
DWKEYWORD(LNAME, DwarfSourceLangName);
DWKEYWORD(CC, DwarfCC);
DWKEYWORD(OP, DwarfOp);
DWKEYWORD(MACINFO, DwarfMacinfo);
DWKEYWORD(APPLE_ENUM_KIND, DwarfEnumKind);
#undef DWKEYWORD
// Keywords for debug record types.
#define DBGRECORDTYPEKEYWORD(STR) \
do { \
if (Keyword == "dbg_" #STR) { \
StrVal = #STR; \
return lltok::DbgRecordType; \
} \
} while (false)
DBGRECORDTYPEKEYWORD(value);
DBGRECORDTYPEKEYWORD(declare);
DBGRECORDTYPEKEYWORD(assign);
DBGRECORDTYPEKEYWORD(label);
DBGRECORDTYPEKEYWORD(declare_value);
#undef DBGRECORDTYPEKEYWORD
if (Keyword.starts_with("DIFlag")) {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::DIFlag;
}
if (Keyword.starts_with("DISPFlag")) {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::DISPFlag;
}
if (Keyword.starts_with("CSK_")) {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::ChecksumKind;
}
if (Keyword == "NoDebug" || Keyword == "FullDebug" ||
Keyword == "LineTablesOnly" || Keyword == "DebugDirectivesOnly") {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::EmissionKind;
}
if (Keyword == "GNU" || Keyword == "Apple" || Keyword == "None" ||
Keyword == "Default") {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::NameTableKind;
}
if (Keyword == "Binary" || Keyword == "Decimal" || Keyword == "Rational") {
StrVal.assign(Keyword.begin(), Keyword.end());
return lltok::FixedPointKind;
}
// Check for [us]0x[0-9A-Fa-f]+ which are Hexadecimal constant generated by
// the CFE to avoid forcing it to deal with 64-bit numbers.
if ((TokStart[0] == 'u' || TokStart[0] == 's') &&
TokStart[1] == '0' && TokStart[2] == 'x' &&
isxdigit(static_cast<unsigned char>(TokStart[3]))) {
int len = CurPtr-TokStart-3;
uint32_t bits = len * 4;
StringRef HexStr(TokStart + 3, len);
if (!all_of(HexStr, isxdigit)) {
// Bad token, return it as an error.
CurPtr = TokStart+3;
return lltok::Error;
}
APInt Tmp(bits, HexStr, 16);
uint32_t activeBits = Tmp.getActiveBits();
if (activeBits > 0 && activeBits < bits)
Tmp = Tmp.trunc(activeBits);
APSIntVal = APSInt(Tmp, TokStart[0] == 'u');
return lltok::APSInt;
}
// If this is "cc1234", return this as just "cc".
if (TokStart[0] == 'c' && TokStart[1] == 'c') {
CurPtr = TokStart+2;
return lltok::kw_cc;
}
// Finally, if this isn't known, return an error.
CurPtr = TokStart+1;
return lltok::Error;
}
/// Lex all tokens that start with a 0x prefix, knowing they match and are not
/// labels.
/// HexFPConstant 0x[0-9A-Fa-f]+
/// HexFP80Constant 0xK[0-9A-Fa-f]+
/// HexFP128Constant 0xL[0-9A-Fa-f]+
/// HexPPC128Constant 0xM[0-9A-Fa-f]+
/// HexHalfConstant 0xH[0-9A-Fa-f]+
/// HexBFloatConstant 0xR[0-9A-Fa-f]+
lltok::Kind LLLexer::Lex0x() {
CurPtr = TokStart + 2;
char Kind;
if ((CurPtr[0] >= 'K' && CurPtr[0] <= 'M') || CurPtr[0] == 'H' ||
CurPtr[0] == 'R') {
Kind = *CurPtr++;
} else {
Kind = 'J';
}
if (!isxdigit(static_cast<unsigned char>(CurPtr[0]))) {
// Bad token, return it as an error.
CurPtr = TokStart+1;
return lltok::Error;
}
while (isxdigit(static_cast<unsigned char>(CurPtr[0])))
++CurPtr;
if (Kind == 'J') {
// HexFPConstant - Floating point constant represented in IEEE format as a
// hexadecimal number for when exponential notation is not precise enough.
// Half, BFloat, Float, and double only.
APFloatVal = APFloat(APFloat::IEEEdouble(),
APInt(64, HexIntToVal(TokStart + 2, CurPtr)));
return lltok::APFloat;
}
uint64_t Pair[2];
switch (Kind) {
default: llvm_unreachable("Unknown kind!");
case 'K':
// F80HexFPConstant - x87 long double in hexadecimal format (10 bytes)
FP80HexToIntPair(TokStart+3, CurPtr, Pair);
APFloatVal = APFloat(APFloat::x87DoubleExtended(), APInt(80, Pair));
return lltok::APFloat;
case 'L':
// F128HexFPConstant - IEEE 128-bit in hexadecimal format (16 bytes)
HexToIntPair(TokStart+3, CurPtr, Pair);
APFloatVal = APFloat(APFloat::IEEEquad(), APInt(128, Pair));
return lltok::APFloat;
case 'M':
// PPC128HexFPConstant - PowerPC 128-bit in hexadecimal format (16 bytes)
HexToIntPair(TokStart+3, CurPtr, Pair);
APFloatVal = APFloat(APFloat::PPCDoubleDouble(), APInt(128, Pair));
return lltok::APFloat;
case 'H': {
uint64_t Val = HexIntToVal(TokStart + 3, CurPtr);
if (!llvm::isUInt<16>(Val)) {
LexError("hexadecimal constant too large for half (16-bit)");
return lltok::Error;
}
APFloatVal = APFloat(APFloat::IEEEhalf(), APInt(16, Val));
return lltok::APFloat;
}
case 'R': {
// Brain floating point
uint64_t Val = HexIntToVal(TokStart + 3, CurPtr);
if (!llvm::isUInt<16>(Val)) {
LexError("hexadecimal constant too large for bfloat (16-bit)");
return lltok::Error;
}
APFloatVal = APFloat(APFloat::BFloat(), APInt(16, Val));
return lltok::APFloat;
}
}
}
/// Lex tokens for a label or a numeric constant, possibly starting with -.
/// Label [-a-zA-Z$._0-9]+:
/// NInteger -[0-9]+
/// FPConstant [-+]?[0-9]+[.][0-9]*([eE][-+]?[0-9]+)?
/// PInteger [0-9]+
/// HexFPConstant 0x[0-9A-Fa-f]+
/// HexFP80Constant 0xK[0-9A-Fa-f]+
/// HexFP128Constant 0xL[0-9A-Fa-f]+
/// HexPPC128Constant 0xM[0-9A-Fa-f]+
lltok::Kind LLLexer::LexDigitOrNegative() {
// If the letter after the negative is not a number, this is probably a label.
if (!isdigit(static_cast<unsigned char>(TokStart[0])) &&
!isdigit(static_cast<unsigned char>(CurPtr[0]))) {
// Okay, this is not a number after the -, it's probably a label.
if (const char *End = isLabelTail(CurPtr)) {
StrVal.assign(TokStart, End-1);
CurPtr = End;
return lltok::LabelStr;
}
return lltok::Error;
}
// At this point, it is either a label, int or fp constant.
// Skip digits, we have at least one.
for (; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr)
/*empty*/;
// Check if this is a fully-numeric label:
if (isdigit(TokStart[0]) && CurPtr[0] == ':') {
uint64_t Val = atoull(TokStart, CurPtr);
++CurPtr; // Skip the colon.
if ((unsigned)Val != Val)
LexError("invalid value number (too large)");
UIntVal = unsigned(Val);
return lltok::LabelID;
}
// Check to see if this really is a string label, e.g. "-1:".
if (isLabelChar(CurPtr[0]) || CurPtr[0] == ':') {
if (const char *End = isLabelTail(CurPtr)) {
StrVal.assign(TokStart, End-1);
CurPtr = End;
return lltok::LabelStr;
}
}
// If the next character is a '.', then it is a fp value, otherwise its
// integer.
if (CurPtr[0] != '.') {
if (TokStart[0] == '0' && TokStart[1] == 'x')
return Lex0x();
APSIntVal = APSInt(StringRef(TokStart, CurPtr - TokStart));
return lltok::APSInt;
}
++CurPtr;
// Skip over [0-9]*([eE][-+]?[0-9]+)?
while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr;
if (CurPtr[0] == 'e' || CurPtr[0] == 'E') {
if (isdigit(static_cast<unsigned char>(CurPtr[1])) ||
((CurPtr[1] == '-' || CurPtr[1] == '+') &&
isdigit(static_cast<unsigned char>(CurPtr[2])))) {
CurPtr += 2;
while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr;
}
}
APFloatVal = APFloat(APFloat::IEEEdouble(),
StringRef(TokStart, CurPtr - TokStart));
return lltok::APFloat;
}
/// Lex a floating point constant starting with +.
/// FPConstant [-+]?[0-9]+[.][0-9]*([eE][-+]?[0-9]+)?
lltok::Kind LLLexer::LexPositive() {
// If the letter after the negative is a number, this is probably not a
// label.
if (!isdigit(static_cast<unsigned char>(CurPtr[0])))
return lltok::Error;
// Skip digits.
for (++CurPtr; isdigit(static_cast<unsigned char>(CurPtr[0])); ++CurPtr)
/*empty*/;
// At this point, we need a '.'.
if (CurPtr[0] != '.') {
CurPtr = TokStart+1;
return lltok::Error;
}
++CurPtr;
// Skip over [0-9]*([eE][-+]?[0-9]+)?
while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr;
if (CurPtr[0] == 'e' || CurPtr[0] == 'E') {
if (isdigit(static_cast<unsigned char>(CurPtr[1])) ||
((CurPtr[1] == '-' || CurPtr[1] == '+') &&
isdigit(static_cast<unsigned char>(CurPtr[2])))) {
CurPtr += 2;
while (isdigit(static_cast<unsigned char>(CurPtr[0]))) ++CurPtr;
}
}
APFloatVal = APFloat(APFloat::IEEEdouble(),
StringRef(TokStart, CurPtr - TokStart));
return lltok::APFloat;
}
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