lib/MC/MCParser/AsmLexer.cpp - llvm - Git at Google

 //===- 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.
   }
 }
	//===- 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.
	}
	}