void MCObjectDisassembler::buildSectionAtoms(MCModule *Module) {
  error_code ec;
  for (section_iterator SI = Obj.begin_sections(),
                        SE = Obj.end_sections();
                        SI != SE;
                        SI.increment(ec)) {
    if (ec) break;

    bool isText; SI->isText(isText);
    bool isData; SI->isData(isData);
    if (!isData && !isText)
      continue;

    uint64_t StartAddr; SI->getAddress(StartAddr);
    uint64_t SecSize; SI->getSize(SecSize);
    if (StartAddr == UnknownAddressOrSize || SecSize == UnknownAddressOrSize)
      continue;

    StringRef Contents; SI->getContents(Contents);
    StringRefMemoryObject memoryObject(Contents);

    // We don't care about things like non-file-backed sections yet.
    if (Contents.size() != SecSize || !SecSize)
      continue;
    uint64_t EndAddr = StartAddr + SecSize - 1;

    StringRef SecName; SI->getName(SecName);

    if (isText) {
      MCTextAtom *Text = Module->createTextAtom(StartAddr, EndAddr);
      Text->setName(SecName);
      uint64_t InstSize;
      for (uint64_t Index = 0; Index < SecSize; Index += InstSize) {
        MCInst Inst;
        if (Dis.getInstruction(Inst, InstSize, memoryObject, Index,
                               nulls(), nulls()))
          Text->addInst(Inst, InstSize);
        else
          // We don't care about splitting mixed atoms either.
          llvm_unreachable("Couldn't disassemble instruction in atom.");
      }

    } else {
      MCDataAtom *Data = Module->createDataAtom(StartAddr, EndAddr);
      Data->setName(SecName);
      for (uint64_t Index = 0; Index < SecSize; ++Index)
        Data->addData(Contents[Index]);
    }
  }
}
MCTextAtom *MCTextAtom::split(uint64_t SplitPt) {
  uint64_t LBegin, LEnd, RBegin, REnd;
  remapForSplit(SplitPt, LBegin, LEnd, RBegin, REnd);

  MCTextAtom *RightAtom = Parent->createTextAtom(RBegin, REnd);
  RightAtom->setName(getName());

  InstListTy::iterator I = Insts.begin();
  while (I != Insts.end() && I->Address < SplitPt) ++I;
  assert(I != Insts.end() && "Split point not found in disassembly!");
  assert(I->Address == SplitPt &&
         "Split point does not fall on instruction boundary!");

  std::copy(I, Insts.end(), std::back_inserter(RightAtom->Insts));
  Insts.erase(I, Insts.end());
  return RightAtom;
}
示例#3
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void MCObjectDisassembler::buildSectionAtoms(MCModule *Module) {
  error_code ec;
  for (section_iterator SI = Obj.begin_sections(),
                        SE = Obj.end_sections();
                        SI != SE;
                        SI.increment(ec)) {
    if (ec) break;

    bool isText; SI->isText(isText);
    bool isData; SI->isData(isData);
    if (!isData && !isText)
      continue;

    uint64_t StartAddr; SI->getAddress(StartAddr);
    uint64_t SecSize; SI->getSize(SecSize);
    if (StartAddr == UnknownAddressOrSize || SecSize == UnknownAddressOrSize)
      continue;
    StartAddr = getEffectiveLoadAddr(StartAddr);

    StringRef Contents; SI->getContents(Contents);
    StringRefMemoryObject memoryObject(Contents, StartAddr);

    // We don't care about things like non-file-backed sections yet.
    if (Contents.size() != SecSize || !SecSize)
      continue;
    uint64_t EndAddr = StartAddr + SecSize - 1;

    StringRef SecName; SI->getName(SecName);

    if (isText) {
      MCTextAtom *Text = 0;
      MCDataAtom *InvalidData = 0;

      uint64_t InstSize;
      for (uint64_t Index = 0; Index < SecSize; Index += InstSize) {
        const uint64_t CurAddr = StartAddr + Index;
        MCInst Inst;
        if (Dis.getInstruction(Inst, InstSize, memoryObject, CurAddr, nulls(),
                               nulls())) {
          if (!Text) {
            Text = Module->createTextAtom(CurAddr, CurAddr);
            Text->setName(SecName);
          }
          Text->addInst(Inst, InstSize);
          InvalidData = 0;
        } else {
          if (!InvalidData) {
            Text = 0;
            InvalidData = Module->createDataAtom(CurAddr, EndAddr);
          }
          InvalidData->addData(Contents[Index]);
        }
      }
    } else {
      MCDataAtom *Data = Module->createDataAtom(StartAddr, EndAddr);
      Data->setName(SecName);
      for (uint64_t Index = 0; Index < SecSize; ++Index)
        Data->addData(Contents[Index]);
    }
  }
}
示例#4
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void MCObjectDisassembler::buildCFG(MCModule *Module) {
  typedef std::map<uint64_t, BBInfo> BBInfoByAddrTy;
  BBInfoByAddrTy BBInfos;
  AddressSetTy Splits;
  AddressSetTy Calls;

  error_code ec;
  for (symbol_iterator SI = Obj.begin_symbols(), SE = Obj.end_symbols();
       SI != SE; SI.increment(ec)) {
    if (ec)
      break;
    SymbolRef::Type SymType;
    SI->getType(SymType);
    if (SymType == SymbolRef::ST_Function) {
      uint64_t SymAddr;
      SI->getAddress(SymAddr);
      SymAddr = getEffectiveLoadAddr(SymAddr);
      Calls.push_back(SymAddr);
      Splits.push_back(SymAddr);
    }
  }

  assert(Module->func_begin() == Module->func_end()
         && "Module already has a CFG!");

  // First, determine the basic block boundaries and call targets.
  for (MCModule::atom_iterator AI = Module->atom_begin(),
                               AE = Module->atom_end();
       AI != AE; ++AI) {
    MCTextAtom *TA = dyn_cast<MCTextAtom>(*AI);
    if (!TA) continue;
    Calls.push_back(TA->getBeginAddr());
    BBInfos[TA->getBeginAddr()].Atom = TA;
    for (MCTextAtom::const_iterator II = TA->begin(), IE = TA->end();
         II != IE; ++II) {
      if (MIA.isTerminator(II->Inst))
        Splits.push_back(II->Address + II->Size);
      uint64_t Target;
      if (MIA.evaluateBranch(II->Inst, II->Address, II->Size, Target)) {
        if (MIA.isCall(II->Inst))
          Calls.push_back(Target);
        Splits.push_back(Target);
      }
    }
  }

  RemoveDupsFromAddressVector(Splits);
  RemoveDupsFromAddressVector(Calls);

  // Split text atoms into basic block atoms.
  for (AddressSetTy::const_iterator SI = Splits.begin(), SE = Splits.end();
       SI != SE; ++SI) {
    MCAtom *A = Module->findAtomContaining(*SI);
    if (!A) continue;
    MCTextAtom *TA = cast<MCTextAtom>(A);
    if (TA->getBeginAddr() == *SI)
      continue;
    MCTextAtom *NewAtom = TA->split(*SI);
    BBInfos[NewAtom->getBeginAddr()].Atom = NewAtom;
    StringRef BBName = TA->getName();
    BBName = BBName.substr(0, BBName.find_last_of(':'));
    NewAtom->setName((BBName + ":" + utohexstr(*SI)).str());
  }

  // Compute succs/preds.
  for (MCModule::atom_iterator AI = Module->atom_begin(),
                               AE = Module->atom_end();
                               AI != AE; ++AI) {
    MCTextAtom *TA = dyn_cast<MCTextAtom>(*AI);
    if (!TA) continue;
    BBInfo &CurBB = BBInfos[TA->getBeginAddr()];
    const MCDecodedInst &LI = TA->back();
    if (MIA.isBranch(LI.Inst)) {
      uint64_t Target;
      if (MIA.evaluateBranch(LI.Inst, LI.Address, LI.Size, Target))
        CurBB.addSucc(BBInfos[Target]);
      if (MIA.isConditionalBranch(LI.Inst))
        CurBB.addSucc(BBInfos[LI.Address + LI.Size]);
    } else if (!MIA.isTerminator(LI.Inst))
      CurBB.addSucc(BBInfos[LI.Address + LI.Size]);
  }


  // Create functions and basic blocks.
  for (AddressSetTy::const_iterator CI = Calls.begin(), CE = Calls.end();
       CI != CE; ++CI) {
    BBInfo &BBI = BBInfos[*CI];
    if (!BBI.Atom) continue;

    MCFunction &MCFN = *Module->createFunction(BBI.Atom->getName());

    // Create MCBBs.
    SmallSetVector<BBInfo*, 16> Worklist;
    Worklist.insert(&BBI);
    for (size_t wi = 0; wi < Worklist.size(); ++wi) {
      BBInfo *BBI = Worklist[wi];
      if (!BBI->Atom)
        continue;
      BBI->BB = &MCFN.createBlock(*BBI->Atom);
      // Add all predecessors and successors to the worklist.
      for (BBInfoSetTy::iterator SI = BBI->Succs.begin(), SE = BBI->Succs.end();
                                 SI != SE; ++SI)
        Worklist.insert(*SI);
      for (BBInfoSetTy::iterator PI = BBI->Preds.begin(), PE = BBI->Preds.end();
                                 PI != PE; ++PI)
        Worklist.insert(*PI);
    }

    // Set preds/succs.
    for (size_t wi = 0; wi < Worklist.size(); ++wi) {
      BBInfo *BBI = Worklist[wi];
      MCBasicBlock *MCBB = BBI->BB;
      if (!MCBB)
        continue;
      for (BBInfoSetTy::iterator SI = BBI->Succs.begin(), SE = BBI->Succs.end();
           SI != SE; ++SI)
        if ((*SI)->BB)
          MCBB->addSuccessor((*SI)->BB);
      for (BBInfoSetTy::iterator PI = BBI->Preds.begin(), PE = BBI->Preds.end();
           PI != PE; ++PI)
        if ((*PI)->BB)
          MCBB->addPredecessor((*PI)->BB);
    }
  }
}
void MCObjectDisassembler::buildSectionAtoms(MCModule *Module) {
    for (const SectionRef &Section : Obj.sections()) {
        bool isText;
        Section.isText(isText);
        bool isData;
        Section.isData(isData);
        if (!isData && !isText)
            continue;

        uint64_t StartAddr;
        Section.getAddress(StartAddr);
        uint64_t SecSize;
        Section.getSize(SecSize);
        if (StartAddr == UnknownAddressOrSize || SecSize == UnknownAddressOrSize)
            continue;
        StartAddr = getEffectiveLoadAddr(StartAddr);

        StringRef Contents;
        Section.getContents(Contents);
        StringRefMemoryObject memoryObject(Contents, StartAddr);

        // We don't care about things like non-file-backed sections yet.
        if (Contents.size() != SecSize || !SecSize)
            continue;
        uint64_t EndAddr = StartAddr + SecSize - 1;

        StringRef SecName;
        Section.getName(SecName);

        if (isText) {
            MCTextAtom *Text = nullptr;
            MCDataAtom *InvalidData = nullptr;

            uint64_t InstSize;
            for (uint64_t Index = 0; Index < SecSize; Index += InstSize) {
                const uint64_t CurAddr = StartAddr + Index;
                MCInst Inst;
                if (Dis.getInstruction(Inst, InstSize, memoryObject, CurAddr, nulls(),
                                       nulls())) {
                    if (!Text) {
                        Text = Module->createTextAtom(CurAddr, CurAddr);
                        Text->setName(SecName);
                    }
                    Text->addInst(Inst, InstSize);
                    InvalidData = nullptr;
                } else {
                    assert(InstSize && "getInstruction() consumed no bytes");
                    if (!InvalidData) {
                        Text = nullptr;
                        InvalidData = Module->createDataAtom(CurAddr, CurAddr+InstSize - 1);
                    }
                    for (uint64_t I = 0; I < InstSize; ++I)
                        InvalidData->addData(Contents[Index+I]);
                }
            }
        } else {
            MCDataAtom *Data = Module->createDataAtom(StartAddr, EndAddr);
            Data->setName(SecName);
            for (uint64_t Index = 0; Index < SecSize; ++Index)
                Data->addData(Contents[Index]);
        }
    }
}