lib/Analysis/ScanfFormatString.cpp - clang - Git at Google

 //= ScanfFormatString.cpp - Analysis of printf format strings --*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Handling of format string in scanf and friends.  The structure of format
 // strings for fscanf() are described in C99 7.19.6.2.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Analysis/Analyses/FormatString.h"
 #include "FormatStringParsing.h"

 using clang::analyze_format_string::ArgTypeResult;
 using clang::analyze_format_string::FormatStringHandler;
 using clang::analyze_format_string::LengthModifier;
 using clang::analyze_format_string::OptionalAmount;
 using clang::analyze_format_string::ConversionSpecifier;
 using clang::analyze_scanf::ScanfConversionSpecifier;
 using clang::analyze_scanf::ScanfSpecifier;
 using clang::UpdateOnReturn;

 typedef clang::analyze_format_string::SpecifierResult<ScanfSpecifier>
         ScanfSpecifierResult;

 static bool ParseScanList(FormatStringHandler &H,
                           ScanfConversionSpecifier &CS,
                           const char *&Beg, const char *E) {
   const char *I = Beg;
   const char *start = I - 1;
   UpdateOnReturn <const char*> UpdateBeg(Beg, I);

   // No more characters?
   if (I == E) {
     H.HandleIncompleteScanList(start, I);
     return true;
   }

   // Special case: ']' is the first character.
   if (*I == ']') {
     if (++I == E) {
       H.HandleIncompleteScanList(start, I - 1);
       return true;
     }
   }

   // Look for a ']' character which denotes the end of the scan list.
   while (*I != ']') {
     if (++I == E) {
       H.HandleIncompleteScanList(start, I - 1);
       return true;
     }
   }

   CS.setEndScanList(I);
   return false;
 }

 // FIXME: Much of this is copy-paste from ParsePrintfSpecifier.
 // We can possibly refactor.
 static ScanfSpecifierResult ParseScanfSpecifier(FormatStringHandler &H,
                                                 const char *&Beg,
                                                 const char *E,
                                                 unsigned &argIndex) {

   using namespace clang::analyze_scanf;
   const char *I = Beg;
   const char *Start = 0;
   UpdateOnReturn <const char*> UpdateBeg(Beg, I);

     // Look for a '%' character that indicates the start of a format specifier.
   for ( ; I != E ; ++I) {
     char c = *I;
     if (c == '\0') {
         // Detect spurious null characters, which are likely errors.
       H.HandleNullChar(I);
       return true;
     }
     if (c == '%') {
       Start = I++;  // Record the start of the format specifier.
       break;
     }
   }

     // No format specifier found?
   if (!Start)
     return false;

   if (I == E) {
       // No more characters left?
     H.HandleIncompleteSpecifier(Start, E - Start);
     return true;
   }

   ScanfSpecifier FS;
   if (ParseArgPosition(H, FS, Start, I, E))
     return true;

   if (I == E) {
       // No more characters left?
     H.HandleIncompleteSpecifier(Start, E - Start);
     return true;
   }

   // Look for '*' flag if it is present.
   if (*I == '*') {
     FS.setSuppressAssignment(I);
     if (++I == E) {
       H.HandleIncompleteSpecifier(Start, E - Start);
       return true;
     }
   }

   // Look for the field width (if any).  Unlike printf, this is either
   // a fixed integer or isn't present.
   const OptionalAmount &Amt = clang::analyze_format_string::ParseAmount(I, E);
   if (Amt.getHowSpecified() != OptionalAmount::NotSpecified) {
     assert(Amt.getHowSpecified() == OptionalAmount::Constant);
     FS.setFieldWidth(Amt);

     if (I == E) {
       // No more characters left?
       H.HandleIncompleteSpecifier(Start, E - Start);
       return true;
     }
   }

   // Look for the length modifier.
   if (ParseLengthModifier(FS, I, E) && I == E) {
       // No more characters left?
     H.HandleIncompleteSpecifier(Start, E - Start);
     return true;
   }

   // Detect spurious null characters, which are likely errors.
   if (*I == '\0') {
     H.HandleNullChar(I);
     return true;
   }

   // Finally, look for the conversion specifier.
   const char *conversionPosition = I++;
   ScanfConversionSpecifier::Kind k = ScanfConversionSpecifier::InvalidSpecifier;
   switch (*conversionPosition) {
     default:
       break;
     case '%': k = ConversionSpecifier::PercentArg;   break;
     case 'A': k = ConversionSpecifier::AArg; break;
     case 'E': k = ConversionSpecifier::EArg; break;
     case 'F': k = ConversionSpecifier::FArg; break;
     case 'G': k = ConversionSpecifier::GArg; break;
     case 'X': k = ConversionSpecifier::XArg; break;
     case 'a': k = ConversionSpecifier::aArg; break;
     case 'd': k = ConversionSpecifier::dArg; break;
     case 'e': k = ConversionSpecifier::eArg; break;
     case 'f': k = ConversionSpecifier::fArg; break;
     case 'g': k = ConversionSpecifier::gArg; break;
     case 'i': k = ConversionSpecifier::iArg; break;
     case 'n': k = ConversionSpecifier::nArg; break;
     case 'c': k = ConversionSpecifier::cArg; break;
     case 'C': k = ConversionSpecifier::CArg; break;
     case 'S': k = ConversionSpecifier::SArg; break;
     case '[': k = ConversionSpecifier::ScanListArg; break;
     case 'u': k = ConversionSpecifier::uArg; break;
     case 'x': k = ConversionSpecifier::xArg; break;
     case 'o': k = ConversionSpecifier::oArg; break;
     case 's': k = ConversionSpecifier::sArg; break;
     case 'p': k = ConversionSpecifier::pArg; break;
   }
   ScanfConversionSpecifier CS(conversionPosition, k);
   if (k == ScanfConversionSpecifier::ScanListArg) {
     if (!ParseScanList(H, CS, I, E))
       return true;
   }
   FS.setConversionSpecifier(CS);
   if (CS.consumesDataArgument() && !FS.getSuppressAssignment()
       && !FS.usesPositionalArg())
     FS.setArgIndex(argIndex++);

   // FIXME: '%' and '*' doesn't make sense.  Issue a warning.
   // FIXME: 'ConsumedSoFar' and '*' doesn't make sense.

   if (k == ScanfConversionSpecifier::InvalidSpecifier) {
     // Assume the conversion takes one argument.
     return !H.HandleInvalidScanfConversionSpecifier(FS, Beg, I - Beg);
   }
   return ScanfSpecifierResult(Start, FS);
 }

 bool clang::analyze_format_string::ParseScanfString(FormatStringHandler &H,
                                                     const char *I,
                                                     const char *E) {

   unsigned argIndex = 0;

   // Keep looking for a format specifier until we have exhausted the string.
   while (I != E) {
     const ScanfSpecifierResult &FSR = ParseScanfSpecifier(H, I, E, argIndex);
     // Did a fail-stop error of any kind occur when parsing the specifier?
     // If so, don't do any more processing.
     if (FSR.shouldStop())
       return true;;
       // Did we exhaust the string or encounter an error that
       // we can recover from?
     if (!FSR.hasValue())
       continue;
       // We have a format specifier.  Pass it to the callback.
     if (!H.HandleScanfSpecifier(FSR.getValue(), FSR.getStart(),
                                 I - FSR.getStart())) {
       return true;
     }
   }
   assert(I == E && "Format string not exhausted");
   return false;
 }
	//= ScanfFormatString.cpp - Analysis of printf format strings --- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Handling of format string in scanf and friends. The structure of format
	// strings for fscanf() are described in C99 7.19.6.2.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Analysis/Analyses/FormatString.h"
	#include "FormatStringParsing.h"

	using clang::analyze_format_string::ArgTypeResult;
	using clang::analyze_format_string::FormatStringHandler;
	using clang::analyze_format_string::LengthModifier;
	using clang::analyze_format_string::OptionalAmount;
	using clang::analyze_format_string::ConversionSpecifier;
	using clang::analyze_scanf::ScanfConversionSpecifier;
	using clang::analyze_scanf::ScanfSpecifier;
	using clang::UpdateOnReturn;

	typedef clang::analyze_format_string::SpecifierResult<ScanfSpecifier>
	ScanfSpecifierResult;

	static bool ParseScanList(FormatStringHandler &H,
	ScanfConversionSpecifier &CS,
	const char &Beg, const char E) {
	const char *I = Beg;
	const char *start = I - 1;
	UpdateOnReturn <const char*> UpdateBeg(Beg, I);

	// No more characters?
	if (I == E) {
	H.HandleIncompleteScanList(start, I);
	return true;
	}

	// Special case: ']' is the first character.
	if (*I == ']') {
	if (++I == E) {
	H.HandleIncompleteScanList(start, I - 1);
	return true;
	}
	}

	// Look for a ']' character which denotes the end of the scan list.
	while (*I != ']') {
	if (++I == E) {
	H.HandleIncompleteScanList(start, I - 1);
	return true;
	}
	}

	CS.setEndScanList(I);
	return false;
	}

	// FIXME: Much of this is copy-paste from ParsePrintfSpecifier.
	// We can possibly refactor.
	static ScanfSpecifierResult ParseScanfSpecifier(FormatStringHandler &H,
	const char *&Beg,
	const char *E,
	unsigned &argIndex) {

	using namespace clang::analyze_scanf;
	const char *I = Beg;
	const char *Start = 0;
	UpdateOnReturn <const char*> UpdateBeg(Beg, I);

	// Look for a '%' character that indicates the start of a format specifier.
	for ( ; I != E ; ++I) {
	char c = *I;
	if (c == '\0') {
	// Detect spurious null characters, which are likely errors.
	H.HandleNullChar(I);
	return true;
	}
	if (c == '%') {
	Start = I++; // Record the start of the format specifier.
	break;
	}
	}

	// No format specifier found?
	if (!Start)
	return false;

	if (I == E) {
	// No more characters left?
	H.HandleIncompleteSpecifier(Start, E - Start);
	return true;
	}

	ScanfSpecifier FS;
	if (ParseArgPosition(H, FS, Start, I, E))
	return true;

	if (I == E) {
	// No more characters left?
	H.HandleIncompleteSpecifier(Start, E - Start);
	return true;
	}

	// Look for '*' flag if it is present.
	if (I == '') {
	FS.setSuppressAssignment(I);
	if (++I == E) {
	H.HandleIncompleteSpecifier(Start, E - Start);
	return true;
	}
	}

	// Look for the field width (if any). Unlike printf, this is either
	// a fixed integer or isn't present.
	const OptionalAmount &Amt = clang::analyze_format_string::ParseAmount(I, E);
	if (Amt.getHowSpecified() != OptionalAmount::NotSpecified) {
	assert(Amt.getHowSpecified() == OptionalAmount::Constant);
	FS.setFieldWidth(Amt);

	if (I == E) {
	// No more characters left?
	H.HandleIncompleteSpecifier(Start, E - Start);
	return true;
	}
	}

	// Look for the length modifier.
	if (ParseLengthModifier(FS, I, E) && I == E) {
	// No more characters left?
	H.HandleIncompleteSpecifier(Start, E - Start);
	return true;
	}

	// Detect spurious null characters, which are likely errors.
	if (*I == '\0') {
	H.HandleNullChar(I);
	return true;
	}

	// Finally, look for the conversion specifier.
	const char *conversionPosition = I++;
	ScanfConversionSpecifier::Kind k = ScanfConversionSpecifier::InvalidSpecifier;
	switch (*conversionPosition) {
	default:
	break;
	case '%': k = ConversionSpecifier::PercentArg; break;
	case 'A': k = ConversionSpecifier::AArg; break;
	case 'E': k = ConversionSpecifier::EArg; break;
	case 'F': k = ConversionSpecifier::FArg; break;
	case 'G': k = ConversionSpecifier::GArg; break;
	case 'X': k = ConversionSpecifier::XArg; break;
	case 'a': k = ConversionSpecifier::aArg; break;
	case 'd': k = ConversionSpecifier::dArg; break;
	case 'e': k = ConversionSpecifier::eArg; break;
	case 'f': k = ConversionSpecifier::fArg; break;
	case 'g': k = ConversionSpecifier::gArg; break;
	case 'i': k = ConversionSpecifier::iArg; break;
	case 'n': k = ConversionSpecifier::nArg; break;
	case 'c': k = ConversionSpecifier::cArg; break;
	case 'C': k = ConversionSpecifier::CArg; break;
	case 'S': k = ConversionSpecifier::SArg; break;
	case '[': k = ConversionSpecifier::ScanListArg; break;
	case 'u': k = ConversionSpecifier::uArg; break;
	case 'x': k = ConversionSpecifier::xArg; break;
	case 'o': k = ConversionSpecifier::oArg; break;
	case 's': k = ConversionSpecifier::sArg; break;
	case 'p': k = ConversionSpecifier::pArg; break;
	}
	ScanfConversionSpecifier CS(conversionPosition, k);
	if (k == ScanfConversionSpecifier::ScanListArg) {
	if (!ParseScanList(H, CS, I, E))
	return true;
	}
	FS.setConversionSpecifier(CS);
	if (CS.consumesDataArgument() && !FS.getSuppressAssignment()
	&& !FS.usesPositionalArg())
	FS.setArgIndex(argIndex++);

	// FIXME: '%' and '*' doesn't make sense. Issue a warning.
	// FIXME: 'ConsumedSoFar' and '*' doesn't make sense.

	if (k == ScanfConversionSpecifier::InvalidSpecifier) {
	// Assume the conversion takes one argument.
	return !H.HandleInvalidScanfConversionSpecifier(FS, Beg, I - Beg);
	}
	return ScanfSpecifierResult(Start, FS);
	}

	bool clang::analyze_format_string::ParseScanfString(FormatStringHandler &H,
	const char *I,
	const char *E) {

	unsigned argIndex = 0;

	// Keep looking for a format specifier until we have exhausted the string.
	while (I != E) {
	const ScanfSpecifierResult &FSR = ParseScanfSpecifier(H, I, E, argIndex);
	// Did a fail-stop error of any kind occur when parsing the specifier?
	// If so, don't do any more processing.
	if (FSR.shouldStop())
	return true;;
	// Did we exhaust the string or encounter an error that
	// we can recover from?
	if (!FSR.hasValue())
	continue;
	// We have a format specifier. Pass it to the callback.
	if (!H.HandleScanfSpecifier(FSR.getValue(), FSR.getStart(),
	I - FSR.getStart())) {
	return true;
	}
	}
	assert(I == E && "Format string not exhausted");
	return false;
	}