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llvm-mirror/lib/MC/MCParser/AsmLexer.cpp
David Blaikie 9465551fc2 Fix uses of reserved identifiers starting with an underscore followed by an uppercase letter
This covers essentially all of llvm's headers and libs. One or two weird
cases I wasn't sure were worth/appropriate to fix.

llvm-svn: 232394
2015-03-16 18:06:57 +00:00

599 lines
19 KiB
C++

//===- AsmLexer.cpp - Lexer for Assembly Files ----------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This class implements the lexer for assembly files.
//
//===----------------------------------------------------------------------===//
#include "llvm/MC/MCParser/AsmLexer.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/SMLoc.h"
#include <cctype>
#include <cerrno>
#include <cstdio>
#include <cstdlib>
using namespace llvm;
AsmLexer::AsmLexer(const MCAsmInfo &MAI) : MAI(MAI) {
CurPtr = nullptr;
isAtStartOfLine = true;
AllowAtInIdentifier = !StringRef(MAI.getCommentString()).startswith("@");
}
AsmLexer::~AsmLexer() {
}
void AsmLexer::setBuffer(StringRef Buf, const char *ptr) {
CurBuf = Buf;
if (ptr)
CurPtr = ptr;
else
CurPtr = CurBuf.begin();
TokStart = nullptr;
}
/// ReturnError - Set the error to the specified string at the specified
/// location. This is defined to always return AsmToken::Error.
AsmToken AsmLexer::ReturnError(const char *Loc, const std::string &Msg) {
SetError(SMLoc::getFromPointer(Loc), Msg);
return AsmToken(AsmToken::Error, StringRef(Loc, 0));
}
int AsmLexer::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;
}
}
/// LexFloatLiteral: [0-9]*[.][0-9]*([eE][+-]?[0-9]*)?
///
/// The leading integral digit sequence and dot should have already been
/// consumed, some or all of the fractional digit sequence *can* have been
/// consumed.
AsmToken AsmLexer::LexFloatLiteral() {
// Skip the fractional digit sequence.
while (isdigit(*CurPtr))
++CurPtr;
// Check for exponent; we intentionally accept a slighlty wider set of
// literals here and rely on the upstream client to reject invalid ones (e.g.,
// "1e+").
if (*CurPtr == 'e' || *CurPtr == 'E') {
++CurPtr;
if (*CurPtr == '-' || *CurPtr == '+')
++CurPtr;
while (isdigit(*CurPtr))
++CurPtr;
}
return AsmToken(AsmToken::Real,
StringRef(TokStart, CurPtr - TokStart));
}
/// LexHexFloatLiteral matches essentially (.[0-9a-fA-F]*)?[pP][+-]?[0-9a-fA-F]+
/// while making sure there are enough actual digits around for the constant to
/// be valid.
///
/// The leading "0x[0-9a-fA-F]*" (i.e. integer part) has already been consumed
/// before we get here.
AsmToken AsmLexer::LexHexFloatLiteral(bool NoIntDigits) {
assert((*CurPtr == 'p' || *CurPtr == 'P' || *CurPtr == '.') &&
"unexpected parse state in floating hex");
bool NoFracDigits = true;
// Skip the fractional part if there is one
if (*CurPtr == '.') {
++CurPtr;
const char *FracStart = CurPtr;
while (isxdigit(*CurPtr))
++CurPtr;
NoFracDigits = CurPtr == FracStart;
}
if (NoIntDigits && NoFracDigits)
return ReturnError(TokStart, "invalid hexadecimal floating-point constant: "
"expected at least one significand digit");
// Make sure we do have some kind of proper exponent part
if (*CurPtr != 'p' && *CurPtr != 'P')
return ReturnError(TokStart, "invalid hexadecimal floating-point constant: "
"expected exponent part 'p'");
++CurPtr;
if (*CurPtr == '+' || *CurPtr == '-')
++CurPtr;
// N.b. exponent digits are *not* hex
const char *ExpStart = CurPtr;
while (isdigit(*CurPtr))
++CurPtr;
if (CurPtr == ExpStart)
return ReturnError(TokStart, "invalid hexadecimal floating-point constant: "
"expected at least one exponent digit");
return AsmToken(AsmToken::Real, StringRef(TokStart, CurPtr - TokStart));
}
/// LexIdentifier: [a-zA-Z_.][a-zA-Z0-9_$.@?]*
static bool IsIdentifierChar(char c, bool AllowAt) {
return isalnum(c) || c == '_' || c == '$' || c == '.' ||
(c == '@' && AllowAt) || c == '?';
}
AsmToken AsmLexer::LexIdentifier() {
// Check for floating point literals.
if (CurPtr[-1] == '.' && isdigit(*CurPtr)) {
// Disambiguate a .1243foo identifier from a floating literal.
while (isdigit(*CurPtr))
++CurPtr;
if (*CurPtr == 'e' || *CurPtr == 'E' ||
!IsIdentifierChar(*CurPtr, AllowAtInIdentifier))
return LexFloatLiteral();
}
while (IsIdentifierChar(*CurPtr, AllowAtInIdentifier))
++CurPtr;
// Handle . as a special case.
if (CurPtr == TokStart+1 && TokStart[0] == '.')
return AsmToken(AsmToken::Dot, StringRef(TokStart, 1));
return AsmToken(AsmToken::Identifier, StringRef(TokStart, CurPtr - TokStart));
}
/// LexSlash: Slash: /
/// C-Style Comment: /* ... */
AsmToken AsmLexer::LexSlash() {
switch (*CurPtr) {
case '*': break; // C style comment.
case '/': return ++CurPtr, LexLineComment();
default: return AsmToken(AsmToken::Slash, StringRef(CurPtr-1, 1));
}
// C Style comment.
++CurPtr; // skip the star.
while (1) {
int CurChar = getNextChar();
switch (CurChar) {
case EOF:
return ReturnError(TokStart, "unterminated comment");
case '*':
// End of the comment?
if (CurPtr[0] != '/') break;
++CurPtr; // End the */.
return LexToken();
}
}
}
/// LexLineComment: Comment: #[^\n]*
/// : //[^\n]*
AsmToken AsmLexer::LexLineComment() {
// FIXME: This is broken if we happen to a comment at the end of a file, which
// was .included, and which doesn't end with a newline.
int CurChar = getNextChar();
while (CurChar != '\n' && CurChar != '\r' && CurChar != EOF)
CurChar = getNextChar();
if (CurChar == EOF)
return AsmToken(AsmToken::Eof, StringRef(TokStart, 0));
return AsmToken(AsmToken::EndOfStatement, StringRef(TokStart, 0));
}
static void SkipIgnoredIntegerSuffix(const char *&CurPtr) {
// Skip ULL, UL, U, L and LL suffices.
if (CurPtr[0] == 'U')
++CurPtr;
if (CurPtr[0] == 'L')
++CurPtr;
if (CurPtr[0] == 'L')
++CurPtr;
}
// Look ahead to search for first non-hex digit, if it's [hH], then we treat the
// integer as a hexadecimal, possibly with leading zeroes.
static unsigned doLookAhead(const char *&CurPtr, unsigned DefaultRadix) {
const char *FirstHex = nullptr;
const char *LookAhead = CurPtr;
while (1) {
if (isdigit(*LookAhead)) {
++LookAhead;
} else if (isxdigit(*LookAhead)) {
if (!FirstHex)
FirstHex = LookAhead;
++LookAhead;
} else {
break;
}
}
bool isHex = *LookAhead == 'h' || *LookAhead == 'H';
CurPtr = isHex || !FirstHex ? LookAhead : FirstHex;
if (isHex)
return 16;
return DefaultRadix;
}
static AsmToken intToken(StringRef Ref, APInt &Value)
{
if (Value.isIntN(64))
return AsmToken(AsmToken::Integer, Ref, Value);
return AsmToken(AsmToken::BigNum, Ref, Value);
}
/// LexDigit: First character is [0-9].
/// Local Label: [0-9][:]
/// Forward/Backward Label: [0-9][fb]
/// Binary integer: 0b[01]+
/// Octal integer: 0[0-7]+
/// Hex integer: 0x[0-9a-fA-F]+ or [0x]?[0-9][0-9a-fA-F]*[hH]
/// Decimal integer: [1-9][0-9]*
AsmToken AsmLexer::LexDigit() {
// Decimal integer: [1-9][0-9]*
if (CurPtr[-1] != '0' || CurPtr[0] == '.') {
unsigned Radix = doLookAhead(CurPtr, 10);
bool isHex = Radix == 16;
// Check for floating point literals.
if (!isHex && (*CurPtr == '.' || *CurPtr == 'e')) {
++CurPtr;
return LexFloatLiteral();
}
StringRef Result(TokStart, CurPtr - TokStart);
APInt Value(128, 0, true);
if (Result.getAsInteger(Radix, Value))
return ReturnError(TokStart, !isHex ? "invalid decimal number" :
"invalid hexdecimal number");
// Consume the [bB][hH].
if (Radix == 2 || Radix == 16)
++CurPtr;
// The darwin/x86 (and x86-64) assembler accepts and ignores type
// suffices on integer literals.
SkipIgnoredIntegerSuffix(CurPtr);
return intToken(Result, Value);
}
if (*CurPtr == 'b') {
++CurPtr;
// See if we actually have "0b" as part of something like "jmp 0b\n"
if (!isdigit(CurPtr[0])) {
--CurPtr;
StringRef Result(TokStart, CurPtr - TokStart);
return AsmToken(AsmToken::Integer, Result, 0);
}
const char *NumStart = CurPtr;
while (CurPtr[0] == '0' || CurPtr[0] == '1')
++CurPtr;
// Requires at least one binary digit.
if (CurPtr == NumStart)
return ReturnError(TokStart, "invalid binary number");
StringRef Result(TokStart, CurPtr - TokStart);
APInt Value(128, 0, true);
if (Result.substr(2).getAsInteger(2, Value))
return ReturnError(TokStart, "invalid binary number");
// The darwin/x86 (and x86-64) assembler accepts and ignores ULL and LL
// suffixes on integer literals.
SkipIgnoredIntegerSuffix(CurPtr);
return intToken(Result, Value);
}
if (*CurPtr == 'x') {
++CurPtr;
const char *NumStart = CurPtr;
while (isxdigit(CurPtr[0]))
++CurPtr;
// "0x.0p0" is valid, and "0x0p0" (but not "0xp0" for example, which will be
// diagnosed by LexHexFloatLiteral).
if (CurPtr[0] == '.' || CurPtr[0] == 'p' || CurPtr[0] == 'P')
return LexHexFloatLiteral(NumStart == CurPtr);
// Otherwise requires at least one hex digit.
if (CurPtr == NumStart)
return ReturnError(CurPtr-2, "invalid hexadecimal number");
APInt Result(128, 0);
if (StringRef(TokStart, CurPtr - TokStart).getAsInteger(0, Result))
return ReturnError(TokStart, "invalid hexadecimal number");
// Consume the optional [hH].
if (*CurPtr == 'h' || *CurPtr == 'H')
++CurPtr;
// The darwin/x86 (and x86-64) assembler accepts and ignores ULL and LL
// suffixes on integer literals.
SkipIgnoredIntegerSuffix(CurPtr);
return intToken(StringRef(TokStart, CurPtr - TokStart), Result);
}
// Either octal or hexadecimal.
APInt Value(128, 0, true);
unsigned Radix = doLookAhead(CurPtr, 8);
bool isHex = Radix == 16;
StringRef Result(TokStart, CurPtr - TokStart);
if (Result.getAsInteger(Radix, Value))
return ReturnError(TokStart, !isHex ? "invalid octal number" :
"invalid hexdecimal number");
// Consume the [hH].
if (Radix == 16)
++CurPtr;
// The darwin/x86 (and x86-64) assembler accepts and ignores ULL and LL
// suffixes on integer literals.
SkipIgnoredIntegerSuffix(CurPtr);
return intToken(Result, Value);
}
/// LexSingleQuote: Integer: 'b'
AsmToken AsmLexer::LexSingleQuote() {
int CurChar = getNextChar();
if (CurChar == '\\')
CurChar = getNextChar();
if (CurChar == EOF)
return ReturnError(TokStart, "unterminated single quote");
CurChar = getNextChar();
if (CurChar != '\'')
return ReturnError(TokStart, "single quote way too long");
// The idea here being that 'c' is basically just an integral
// constant.
StringRef Res = StringRef(TokStart,CurPtr - TokStart);
long long Value;
if (Res.startswith("\'\\")) {
char theChar = Res[2];
switch (theChar) {
default: Value = theChar; break;
case '\'': Value = '\''; break;
case 't': Value = '\t'; break;
case 'n': Value = '\n'; break;
case 'b': Value = '\b'; break;
}
} else
Value = TokStart[1];
return AsmToken(AsmToken::Integer, Res, Value);
}
/// LexQuote: String: "..."
AsmToken AsmLexer::LexQuote() {
int CurChar = getNextChar();
// TODO: does gas allow multiline string constants?
while (CurChar != '"') {
if (CurChar == '\\') {
// Allow \", etc.
CurChar = getNextChar();
}
if (CurChar == EOF)
return ReturnError(TokStart, "unterminated string constant");
CurChar = getNextChar();
}
return AsmToken(AsmToken::String, StringRef(TokStart, CurPtr - TokStart));
}
StringRef AsmLexer::LexUntilEndOfStatement() {
TokStart = CurPtr;
while (!isAtStartOfComment(CurPtr) && // Start of line comment.
!isAtStatementSeparator(CurPtr) && // End of statement marker.
*CurPtr != '\n' && *CurPtr != '\r' &&
(*CurPtr != 0 || CurPtr != CurBuf.end())) {
++CurPtr;
}
return StringRef(TokStart, CurPtr-TokStart);
}
StringRef AsmLexer::LexUntilEndOfLine() {
TokStart = CurPtr;
while (*CurPtr != '\n' && *CurPtr != '\r' &&
(*CurPtr != 0 || CurPtr != CurBuf.end())) {
++CurPtr;
}
return StringRef(TokStart, CurPtr-TokStart);
}
const AsmToken AsmLexer::peekTok(bool ShouldSkipSpace) {
const char *SavedTokStart = TokStart;
const char *SavedCurPtr = CurPtr;
bool SavedAtStartOfLine = isAtStartOfLine;
bool SavedSkipSpace = SkipSpace;
std::string SavedErr = getErr();
SMLoc SavedErrLoc = getErrLoc();
SkipSpace = ShouldSkipSpace;
AsmToken Token = LexToken();
SetError(SavedErrLoc, SavedErr);
SkipSpace = SavedSkipSpace;
isAtStartOfLine = SavedAtStartOfLine;
CurPtr = SavedCurPtr;
TokStart = SavedTokStart;
return Token;
}
bool AsmLexer::isAtStartOfComment(const char *Ptr) {
const char *CommentString = MAI.getCommentString();
if (CommentString[1] == '\0')
return CommentString[0] == Ptr[0];
// FIXME: special case for the bogus "##" comment string in X86MCAsmInfoDarwin
if (CommentString[1] == '#')
return CommentString[0] == Ptr[0];
return strncmp(Ptr, CommentString, strlen(CommentString)) == 0;
}
bool AsmLexer::isAtStatementSeparator(const char *Ptr) {
return strncmp(Ptr, MAI.getSeparatorString(),
strlen(MAI.getSeparatorString())) == 0;
}
AsmToken AsmLexer::LexToken() {
TokStart = CurPtr;
// This always consumes at least one character.
int CurChar = getNextChar();
if (isAtStartOfComment(TokStart)) {
// If this comment starts with a '#', then return the Hash token and let
// the assembler parser see if it can be parsed as a cpp line filename
// comment. We do this only if we are at the start of a line.
if (CurChar == '#' && isAtStartOfLine)
return AsmToken(AsmToken::Hash, StringRef(TokStart, 1));
isAtStartOfLine = true;
return LexLineComment();
}
if (isAtStatementSeparator(TokStart)) {
CurPtr += strlen(MAI.getSeparatorString()) - 1;
return AsmToken(AsmToken::EndOfStatement,
StringRef(TokStart, strlen(MAI.getSeparatorString())));
}
// If we're missing a newline at EOF, make sure we still get an
// EndOfStatement token before the Eof token.
if (CurChar == EOF && !isAtStartOfLine) {
isAtStartOfLine = true;
return AsmToken(AsmToken::EndOfStatement, StringRef(TokStart, 1));
}
isAtStartOfLine = false;
switch (CurChar) {
default:
// Handle identifier: [a-zA-Z_.][a-zA-Z0-9_$.@]*
if (isalpha(CurChar) || CurChar == '_' || CurChar == '.')
return LexIdentifier();
// Unknown character, emit an error.
return ReturnError(TokStart, "invalid character in input");
case EOF: return AsmToken(AsmToken::Eof, StringRef(TokStart, 0));
case 0:
case ' ':
case '\t':
if (SkipSpace) {
// Ignore whitespace.
return LexToken();
} else {
int len = 1;
while (*CurPtr==' ' || *CurPtr=='\t') {
CurPtr++;
len++;
}
return AsmToken(AsmToken::Space, StringRef(TokStart, len));
}
case '\n': // FALL THROUGH.
case '\r':
isAtStartOfLine = true;
return AsmToken(AsmToken::EndOfStatement, StringRef(TokStart, 1));
case ':': return AsmToken(AsmToken::Colon, StringRef(TokStart, 1));
case '+': return AsmToken(AsmToken::Plus, StringRef(TokStart, 1));
case '-': return AsmToken(AsmToken::Minus, StringRef(TokStart, 1));
case '~': return AsmToken(AsmToken::Tilde, StringRef(TokStart, 1));
case '(': return AsmToken(AsmToken::LParen, StringRef(TokStart, 1));
case ')': return AsmToken(AsmToken::RParen, StringRef(TokStart, 1));
case '[': return AsmToken(AsmToken::LBrac, StringRef(TokStart, 1));
case ']': return AsmToken(AsmToken::RBrac, StringRef(TokStart, 1));
case '{': return AsmToken(AsmToken::LCurly, StringRef(TokStart, 1));
case '}': return AsmToken(AsmToken::RCurly, StringRef(TokStart, 1));
case '*': return AsmToken(AsmToken::Star, StringRef(TokStart, 1));
case ',': return AsmToken(AsmToken::Comma, StringRef(TokStart, 1));
case '$': return AsmToken(AsmToken::Dollar, StringRef(TokStart, 1));
case '@': return AsmToken(AsmToken::At, StringRef(TokStart, 1));
case '\\': return AsmToken(AsmToken::BackSlash, StringRef(TokStart, 1));
case '=':
if (*CurPtr == '=')
return ++CurPtr, AsmToken(AsmToken::EqualEqual, StringRef(TokStart, 2));
return AsmToken(AsmToken::Equal, StringRef(TokStart, 1));
case '|':
if (*CurPtr == '|')
return ++CurPtr, AsmToken(AsmToken::PipePipe, StringRef(TokStart, 2));
return AsmToken(AsmToken::Pipe, StringRef(TokStart, 1));
case '^': return AsmToken(AsmToken::Caret, StringRef(TokStart, 1));
case '&':
if (*CurPtr == '&')
return ++CurPtr, AsmToken(AsmToken::AmpAmp, StringRef(TokStart, 2));
return AsmToken(AsmToken::Amp, StringRef(TokStart, 1));
case '!':
if (*CurPtr == '=')
return ++CurPtr, AsmToken(AsmToken::ExclaimEqual, StringRef(TokStart, 2));
return AsmToken(AsmToken::Exclaim, StringRef(TokStart, 1));
case '%': return AsmToken(AsmToken::Percent, StringRef(TokStart, 1));
case '/': return LexSlash();
case '#': return AsmToken(AsmToken::Hash, StringRef(TokStart, 1));
case '\'': return LexSingleQuote();
case '"': return LexQuote();
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return LexDigit();
case '<':
switch (*CurPtr) {
case '<': return ++CurPtr, AsmToken(AsmToken::LessLess,
StringRef(TokStart, 2));
case '=': return ++CurPtr, AsmToken(AsmToken::LessEqual,
StringRef(TokStart, 2));
case '>': return ++CurPtr, AsmToken(AsmToken::LessGreater,
StringRef(TokStart, 2));
default: return AsmToken(AsmToken::Less, StringRef(TokStart, 1));
}
case '>':
switch (*CurPtr) {
case '>': return ++CurPtr, AsmToken(AsmToken::GreaterGreater,
StringRef(TokStart, 2));
case '=': return ++CurPtr, AsmToken(AsmToken::GreaterEqual,
StringRef(TokStart, 2));
default: return AsmToken(AsmToken::Greater, StringRef(TokStart, 1));
}
// TODO: Quoted identifiers (objc methods etc)
// local labels: [0-9][:]
// Forward/backward labels: [0-9][fb]
// Integers, fp constants, character constants.
}
}