//= 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::ScanfArgTypeResult;
using clang::analyze_scanf::ScanfConversionSpecifier;
using clang::analyze_scanf::ScanfSpecifier;
using clang::UpdateOnReturn;
using namespace clang;
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,
const LangOptions &LO) {
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, LO, /*scanf=*/true) && 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);
}
ScanfArgTypeResult ScanfSpecifier::getArgType(ASTContext &Ctx) const {
const ScanfConversionSpecifier &CS = getConversionSpecifier();
if (!CS.consumesDataArgument())
return ScanfArgTypeResult::Invalid();
switch(CS.getKind()) {
// Signed int.
case ConversionSpecifier::dArg:
case ConversionSpecifier::iArg:
switch (LM.getKind()) {
case LengthModifier::None: return ArgTypeResult(Ctx.IntTy);
case LengthModifier::AsChar:
return ArgTypeResult(ArgTypeResult::AnyCharTy);
case LengthModifier::AsShort: return ArgTypeResult(Ctx.ShortTy);
case LengthModifier::AsLong: return ArgTypeResult(Ctx.LongTy);
case LengthModifier::AsLongLong:
case LengthModifier::AsQuad:
return ArgTypeResult(Ctx.LongLongTy);
case LengthModifier::AsIntMax:
return ScanfArgTypeResult(Ctx.getIntMaxType(), "intmax_t *");
case LengthModifier::AsSizeT:
// FIXME: ssize_t.
return ScanfArgTypeResult();
case LengthModifier::AsPtrDiff:
return ScanfArgTypeResult(Ctx.getPointerDiffType(), "ptrdiff_t *");
case LengthModifier::AsLongDouble:
// GNU extension.
return ArgTypeResult(Ctx.LongLongTy);
case LengthModifier::AsAllocate: return ScanfArgTypeResult::Invalid();
case LengthModifier::AsMAllocate: return ScanfArgTypeResult::Invalid();
}
// Unsigned int.
case ConversionSpecifier::oArg:
case ConversionSpecifier::uArg:
case ConversionSpecifier::xArg:
case ConversionSpecifier::XArg:
switch (LM.getKind()) {
case LengthModifier::None: return ArgTypeResult(Ctx.UnsignedIntTy);
case LengthModifier::AsChar: return ArgTypeResult(Ctx.UnsignedCharTy);
case LengthModifier::AsShort: return ArgTypeResult(Ctx.UnsignedShortTy);
case LengthModifier::AsLong: return ArgTypeResult(Ctx.UnsignedLongTy);
case LengthModifier::AsLongLong:
case LengthModifier::AsQuad:
return ArgTypeResult(Ctx.UnsignedLongLongTy);
case LengthModifier::AsIntMax:
return ScanfArgTypeResult(Ctx.getUIntMaxType(), "uintmax_t *");
case LengthModifier::AsSizeT:
return ScanfArgTypeResult(Ctx.getSizeType(), "size_t *");
case LengthModifier::AsPtrDiff:
// FIXME: Unsigned version of ptrdiff_t?
return ScanfArgTypeResult();
case LengthModifier::AsLongDouble:
// GNU extension.
return ArgTypeResult(Ctx.UnsignedLongLongTy);
case LengthModifier::AsAllocate: return ScanfArgTypeResult::Invalid();
case LengthModifier::AsMAllocate: return ScanfArgTypeResult::Invalid();
}
// Float.
case ConversionSpecifier::aArg:
case ConversionSpecifier::AArg:
case ConversionSpecifier::eArg:
case ConversionSpecifier::EArg:
case ConversionSpecifier::fArg:
case ConversionSpecifier::FArg:
case ConversionSpecifier::gArg:
case ConversionSpecifier::GArg:
switch (LM.getKind()) {
case LengthModifier::None: return ArgTypeResult(Ctx.FloatTy);
case LengthModifier::AsLong: return ArgTypeResult(Ctx.DoubleTy);
case LengthModifier::AsLongDouble:
return ArgTypeResult(Ctx.LongDoubleTy);
default:
return ScanfArgTypeResult::Invalid();
}
// Char, string and scanlist.
case ConversionSpecifier::cArg:
case ConversionSpecifier::sArg:
case ConversionSpecifier::ScanListArg:
switch (LM.getKind()) {
case LengthModifier::None: return ScanfArgTypeResult::CStrTy;
case LengthModifier::AsLong:
return ScanfArgTypeResult(ScanfArgTypeResult::WCStrTy, "wchar_t *");
case LengthModifier::AsAllocate:
case LengthModifier::AsMAllocate:
return ScanfArgTypeResult(ArgTypeResult::CStrTy);
default:
return ScanfArgTypeResult::Invalid();
}
case ConversionSpecifier::CArg:
case ConversionSpecifier::SArg:
// FIXME: Mac OS X specific?
switch (LM.getKind()) {
case LengthModifier::None:
return ScanfArgTypeResult(ScanfArgTypeResult::WCStrTy, "wchar_t *");
case LengthModifier::AsAllocate:
case LengthModifier::AsMAllocate:
return ScanfArgTypeResult(ArgTypeResult::WCStrTy, "wchar_t **");
default:
return ScanfArgTypeResult::Invalid();
}
// Pointer.
case ConversionSpecifier::pArg:
return ScanfArgTypeResult(ArgTypeResult(ArgTypeResult::CPointerTy));
default:
break;
}
return ScanfArgTypeResult();
}
bool ScanfSpecifier::fixType(QualType QT, const LangOptions &LangOpt,
ASTContext &Ctx) {
if (!QT->isPointerType())
return false;
QualType PT = QT->getPointeeType();
const BuiltinType *BT = PT->getAs<BuiltinType>();
if (!BT)
return false;
// Pointer to a character.
if (PT->isAnyCharacterType()) {
CS.setKind(ConversionSpecifier::sArg);
if (PT->isWideCharType())
LM.setKind(LengthModifier::AsWideChar);
else
LM.setKind(LengthModifier::None);
return true;
}
// Figure out the length modifier.
switch (BT->getKind()) {
// no modifier
case BuiltinType::UInt:
case BuiltinType::Int:
case BuiltinType::Float:
LM.setKind(LengthModifier::None);
break;
// hh
case BuiltinType::Char_U:
case BuiltinType::UChar:
case BuiltinType::Char_S:
case BuiltinType::SChar:
LM.setKind(LengthModifier::AsChar);
break;
// h
case BuiltinType::Short:
case BuiltinType::UShort:
LM.setKind(LengthModifier::AsShort);
break;
// l
case BuiltinType::Long:
case BuiltinType::ULong:
case BuiltinType::Double:
LM.setKind(LengthModifier::AsLong);
break;
// ll
case BuiltinType::LongLong:
case BuiltinType::ULongLong:
LM.setKind(LengthModifier::AsLongLong);
break;
// L
case BuiltinType::LongDouble:
LM.setKind(LengthModifier::AsLongDouble);
break;
// Don't know.
default:
return false;
}
// Handle size_t, ptrdiff_t, etc. that have dedicated length modifiers in C99.
if (isa<TypedefType>(PT) && (LangOpt.C99 || LangOpt.CPlusPlus0x)) {
const IdentifierInfo *Identifier = QT.getBaseTypeIdentifier();
if (Identifier->getName() == "size_t") {
LM.setKind(LengthModifier::AsSizeT);
} else if (Identifier->getName() == "ssize_t") {
// Not C99, but common in Unix.
LM.setKind(LengthModifier::AsSizeT);
} else if (Identifier->getName() == "intmax_t") {
LM.setKind(LengthModifier::AsIntMax);
} else if (Identifier->getName() == "uintmax_t") {
LM.setKind(LengthModifier::AsIntMax);
} else if (Identifier->getName() == "ptrdiff_t") {
LM.setKind(LengthModifier::AsPtrDiff);
}
}
// If fixing the length modifier was enough, we are done.
const analyze_scanf::ScanfArgTypeResult &ATR = getArgType(Ctx);
if (hasValidLengthModifier() && ATR.isValid() && ATR.matchesType(Ctx, QT))
return true;
// Figure out the conversion specifier.
if (PT->isRealFloatingType())
CS.setKind(ConversionSpecifier::fArg);
else if (PT->isSignedIntegerType())
CS.setKind(ConversionSpecifier::dArg);
else if (PT->isUnsignedIntegerType())
CS.setKind(ConversionSpecifier::uArg);
else
llvm_unreachable("Unexpected type");
return true;
}
void ScanfSpecifier::toString(raw_ostream &os) const {
os << "%";
if (usesPositionalArg())
os << getPositionalArgIndex() << "$";
if (SuppressAssignment)
os << "*";
FieldWidth.toString(os);
os << LM.toString();
os << CS.toString();
}
bool clang::analyze_format_string::ParseScanfString(FormatStringHandler &H,
const char *I,
const char *E,
const LangOptions &LO) {
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,
LO);
// 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;
}
bool ScanfArgTypeResult::matchesType(ASTContext& C, QualType argTy) const {
switch (K) {
case InvalidTy:
llvm_unreachable("ArgTypeResult must be valid");
case UnknownTy:
return true;
case CStrTy:
return ArgTypeResult(ArgTypeResult::CStrTy).matchesType(C, argTy);
case WCStrTy:
return ArgTypeResult(ArgTypeResult::WCStrTy).matchesType(C, argTy);
case PtrToArgTypeResultTy: {
const PointerType *PT = argTy->getAs<PointerType>();
if (!PT)
return false;
return A.matchesType(C, PT->getPointeeType());
}
}
llvm_unreachable("Invalid ScanfArgTypeResult Kind!");
}
QualType ScanfArgTypeResult::getRepresentativeType(ASTContext &C) const {
switch (K) {
case InvalidTy:
llvm_unreachable("No representative type for Invalid ArgTypeResult");
case UnknownTy:
return QualType();
case CStrTy:
return C.getPointerType(C.CharTy);
case WCStrTy:
return C.getPointerType(C.getWCharType());
case PtrToArgTypeResultTy:
return C.getPointerType(A.getRepresentativeType(C));
}
llvm_unreachable("Invalid ScanfArgTypeResult Kind!");
}
std::string ScanfArgTypeResult::getRepresentativeTypeName(ASTContext& C) const {
std::string S = getRepresentativeType(C).getAsString();
if (!Name)
return std::string("'") + S + "'";
return std::string("'") + Name + "' (aka '" + S + "')";
}