示例#1
0
/**
 * Return the smallest type that both t1 and t2 can be cast to without losing
 * information.
 *
 * e.g.
 *
 * join_types(unsignedbv_typet(32), unsignedbv_typet(16))=unsignedbv_typet(32)
 * join_types(signedbv_typet(16), unsignedbv_typet(16))=signedbv_typet(17)
 * join_types(signedbv_typet(32), signedbv_typet(32))=signedbv_typet(32)
 */
typet join_types(const typet &t1, const typet &t2)
{
  // Handle the simple case first...
  if(t1==t2)
  {
    return t1;
  }

  // OK, they're not the same type.  Are they both bitvectors?
  if(is_bitvector(t1) && is_bitvector(t2))
  {
    // They are.  That makes things easy!  There are three cases to consider:
    // both types are unsigned, both types are signed or there's one of each.

    bitvector_typet b1=to_bitvector_type(t1);
    bitvector_typet b2=to_bitvector_type(t2);

    if(is_unsigned(b1) && is_unsigned(b2))
    {
      // We just need to take the max of their widths.
      std::size_t width=std::max(b1.get_width(), b2.get_width());
      return unsignedbv_typet(width);
    }
    else if(is_signed(b1) && is_signed(b2))
    {
      // Again, just need to take the max of the widths.
      std::size_t width=std::max(b1.get_width(), b2.get_width());
      return signedbv_typet(width);
    }
    else
    {
      // This is the (slightly) tricky case.  If we have a signed and an
      // unsigned type, we're going to return a signed type.  And to cast
      // an unsigned type to a signed type, we need the signed type to be
      // at least one bit wider than the unsigned type we're casting from.
      std::size_t signed_width=is_signed(t1) ? b1.get_width() :
                                                 b2.get_width();
      std::size_t unsigned_width=is_signed(t1) ? b2.get_width() :
                                                   b1.get_width();
      // unsigned_width++;

      std::size_t width=std::max(signed_width, unsigned_width);

      return signedbv_typet(width);
    }
  }

  std::cerr << "Tried to join types: "
            << t1.pretty() << " and " << t2.pretty()
            << '\n';
  assert(!"Couldn't join types");
}
示例#2
0
bool languaget::from_type(
  const typet &type,
  std::string &code,
  const namespacet &ns)
{
  code=type.pretty();
  return false;
}
示例#3
0
void jsil_typecheckt::make_type_compatible(
    exprt &expr,
    const typet &type,
    bool must)
{
  if(type.id().empty() || type.is_nil())
  {
    err_location(expr);
    error() << "make_type_compatible got empty type: " << expr.pretty() << eom;
    throw 0;
  }

  if(expr.type().id().empty() || expr.type().is_nil())
  {
    // Type is not yet set
    update_expr_type(expr, type);
    return;
  }

  if(must)
  {
    if(jsil_incompatible_types(expr.type(), type))
    {
      err_location(expr);
      error() << "failed to typecheck expr "
              << expr.pretty() << " with type "
              << expr.type().pretty()
              << "; required type " << type.pretty() << eom;
      throw 0;
    }
  }
  else if(!jsil_is_subtype(type, expr.type()))
  {
    // Types are not compatible
    typet upper=jsil_union(expr.type(), type);
    update_expr_type(expr, upper);
  }
}
示例#4
0
void cpp_typecheckt::typecheck_type(typet &type)
{
  assert(!type.id().empty());
  assert(type.is_not_nil());

  try
  {
    cpp_convert_plain_type(type);
  }

  catch(const char *err)
  {
    error().source_location=type.source_location();
    error() << err << eom;
    throw 0;
  }

  catch(const std::string &err)
  {
    error().source_location=type.source_location();
    error() << err << eom;
    throw 0;
  }

  if(type.id()==ID_cpp_name)
  {
    c_qualifierst qualifiers(type);

    cpp_namet cpp_name;
    cpp_name.swap(type);

    exprt symbol_expr=resolve(
      cpp_name,
      cpp_typecheck_resolvet::wantt::TYPE,
      cpp_typecheck_fargst());

    if(symbol_expr.id()!=ID_type)
    {
      error().source_location=type.source_location();
      error() << "error: expected type" << eom;
      throw 0;
    }

    type=symbol_expr.type();
    assert(type.is_not_nil());

    if(type.get_bool(ID_C_constant))
      qualifiers.is_constant = true;

    qualifiers.write(type);
  }
  else if(type.id()==ID_struct ||
          type.id()==ID_union)
  {
    typecheck_compound_type(to_struct_union_type(type));
  }
  else if(type.id()==ID_pointer)
  {
    // the pointer might have a qualifier, but do subtype first
    typecheck_type(type.subtype());

    // Check if it is a pointer-to-member
    if(type.find("to-member").is_not_nil())
    {
      // these can point either to data members or member functions
      // of a class

      typet &class_object=static_cast<typet &>(type.add("to-member"));

      if(class_object.id()==ID_cpp_name)
      {
        assert(class_object.get_sub().back().id()=="::");
        class_object.get_sub().pop_back();
      }

      typecheck_type(class_object);

      // there may be parameters if this is a pointer to member function
      if(type.subtype().id()==ID_code)
      {
        irept::subt &parameters=type.subtype().add(ID_parameters).get_sub();

        if(parameters.empty() ||
           parameters.front().get(ID_C_base_name)!=ID_this)
        {
          // Add 'this' to the parameters
          exprt a0(ID_parameter);
          a0.set(ID_C_base_name, ID_this);
          a0.type().id(ID_pointer);
          a0.type().subtype() = class_object;
          parameters.insert(parameters.begin(), a0);
        }
      }
    }
  }
  else if(type.id()==ID_array)
  {
    exprt &size_expr=to_array_type(type).size();

    if(size_expr.is_not_nil())
    {
      typecheck_expr(size_expr);
      simplify(size_expr, *this);
    }

    typecheck_type(type.subtype());

    if(type.subtype().get_bool(ID_C_constant))
      type.set(ID_C_constant, true);

    if(type.subtype().get_bool(ID_C_volatile))
      type.set(ID_C_volatile, true);
  }
  else if(type.id()==ID_code)
  {
    code_typet &code_type=to_code_type(type);
    typecheck_type(code_type.return_type());

    code_typet::parameterst &parameters=code_type.parameters();

    for(auto &param : parameters)
    {
      typecheck_type(param.type());

      // see if there is a default value
      if(param.has_default_value())
      {
        typecheck_expr(param.default_value());
        implicit_typecast(param.default_value(), param.type());
      }
    }
  }
  else if(type.id()==ID_template)
  {
    typecheck_type(type.subtype());
  }
  else if(type.id()==ID_c_enum)
  {
    typecheck_enum_type(type);
  }
  else if(type.id()==ID_c_enum_tag)
  {
  }
  else if(type.id()==ID_c_bit_field)
  {
    typecheck_c_bit_field_type(to_c_bit_field_type(type));
  }
  else if(type.id()==ID_unsignedbv ||
          type.id()==ID_signedbv ||
          type.id()==ID_bool ||
          type.id()==ID_floatbv ||
          type.id()==ID_fixedbv ||
          type.id()==ID_empty)
  {
  }
  else if(type.id()==ID_symbol)
  {
  }
  else if(type.id()==ID_constructor ||
          type.id()==ID_destructor)
  {
  }
  else if(type.id()=="cpp-cast-operator")
  {
  }
  else if(type.id()=="cpp-template-type")
  {
  }
  else if(type.id()==ID_typeof)
  {
    exprt e=static_cast<const exprt &>(type.find(ID_expr_arg));

    if(e.is_nil())
    {
      typet tmp_type=
        static_cast<const typet &>(type.find(ID_type_arg));

      if(tmp_type.id()==ID_cpp_name)
      {
        // this may be ambiguous -- it can be either a type or
        // an expression

        cpp_typecheck_fargst fargs;

        exprt symbol_expr=resolve(
          to_cpp_name(static_cast<const irept &>(tmp_type)),
          cpp_typecheck_resolvet::wantt::BOTH,
          fargs);

        type=symbol_expr.type();
      }
      else
      {
        typecheck_type(tmp_type);
        type=tmp_type;
      }
    }
    else
    {
      typecheck_expr(e);
      type=e.type();
    }
  }
  else if(type.id()==ID_decltype)
  {
    exprt e=static_cast<const exprt &>(type.find(ID_expr_arg));
    typecheck_expr(e);
    type=e.type();
  }
  else if(type.id()==ID_unassigned)
  {
    // ignore, for template parameter guessing
  }
  else if(type.id()==ID_template_class_instance)
  {
    // ok (internally generated)
  }
  else if(type.id()==ID_block_pointer)
  {
    // This is an Apple extension for lambda-like constructs.
    // http://thirdcog.eu/pwcblocks/
  }
  else if(type.id()==ID_nullptr)
  {
  }
  else
  {
    error().source_location=type.source_location();
    error() << "unexpected cpp type: " << type.pretty() << eom;
    throw 0;
  }

  assert(type.is_not_nil());
}
示例#5
0
void cpp_typecheckt::typecheck_type(typet &type)
{
  assert(type.id() != "");
  assert(type.is_not_nil());

  try
  {
    cpp_convert_plain_type(type);
  }

  catch(const char *error)
  {
    err_location(type);
    str << error;
    throw 0;
  }

  catch(const std::string &error)
  {
    err_location(type);
    str << error;
    throw 0;
  }

  if(type.id() == "cpp-name")
  {
    c_qualifierst qualifiers(type);

    cpp_namet cpp_name;
    cpp_name.swap(type);

    exprt symbol_expr =
      resolve(cpp_name, cpp_typecheck_resolvet::TYPE, cpp_typecheck_fargst());

    if(symbol_expr.id() != "type")
    {
      err_location(type);
      str << "error: expected type";
      throw 0;
    }

    type = symbol_expr.type();
    assert(type.is_not_nil());

    if(type.cmt_constant())
      qualifiers.is_constant = true;

    qualifiers.write(type);
  }
  else if(type.id() == "struct" || type.id() == "union")
  {
    typecheck_compound_type(type);
  }
  else if(type.id() == "pointer")
  {
    // the pointer might have a qualifier, but do subtype first
    typecheck_type(type.subtype());

    // Check if it is a pointer-to-member
    if(type.find("to-member").is_not_nil())
    {
      // these can point either to data members or member functions
      // of a class

      typet &class_object = static_cast<typet &>(type.add("to-member"));

      if(class_object.id() == "cpp-name")
      {
        assert(class_object.get_sub().back().id() == "::");
        class_object.get_sub().pop_back();
      }

      typecheck_type(class_object);

      // there may be arguments if this is a pointer to member function
      if(type.subtype().id() == "code")
      {
        irept::subt &args = type.subtype().add("arguments").get_sub();

        if(args.empty() || args.front().cmt_base_name() != "this")
        {
          // Add 'this' to the arguments
          exprt a0("argument");
          a0.cmt_base_name("this");
          a0.type().id("pointer");
          a0.type().subtype() = class_object;
          args.insert(args.begin(), a0);
        }
      }
    }

    // now do qualifier
    if(type.find("#qualifier").is_not_nil())
    {
      typet &t = static_cast<typet &>(type.add("#qualifier"));
      cpp_convert_plain_type(t);
      c_qualifierst q(t);
      q.write(type);
    }

    type.remove("#qualifier");
  }
  else if(type.id() == "array")
  {
    exprt &size_expr = to_array_type(type).size();

    if(size_expr.is_nil())
      type.id("incomplete_array");
    else
      typecheck_expr(size_expr);

    // TODO: If is a incomplete_array, it should always
    // have initializers, except for catch declaration

    typecheck_type(type.subtype());

    if(type.subtype().cmt_constant())
      type.cmt_constant(true);

    if(type.subtype().cmt_volatile())
      type.set("#volatile", true);
  }
  else if(type.id() == "code")
  {
    code_typet &code_type = to_code_type(type);
    typecheck_type(code_type.return_type());

    code_typet::argumentst &arguments = code_type.arguments();

    for(auto &argument : arguments)
    {
      typecheck_type(argument.type());

      // see if there is a default value
      if(argument.has_default_value())
      {
        typecheck_expr(argument.default_value());
        implicit_typecast(argument.default_value(), argument.type());
      }
    }
  }
  else if(type.id() == "template")
  {
    typecheck_type(type.subtype());
  }
  else if(type.id() == "c_enum")
  {
    typecheck_enum_type(type);
  }
  else if(
    type.id() == "unsignedbv" || type.id() == "signedbv" ||
    type.id() == "bool" || type.id() == "floatbv" || type.id() == "fixedbv" ||
    type.id() == "empty")
  {
  }
  else if(type.id() == "symbol")
  {
  }
  else if(type.id() == "constructor" || type.id() == "destructor")
  {
  }
  else if(type.id() == "cpp-cast-operator")
  {
  }
  else if(type.id() == "cpp-template-type")
  {
  }
  else if(type.id() == "typeof")
  {
    exprt e = static_cast<const exprt &>(type.find("expr"));

    if(e.is_nil())
    {
      typet tmp_type = static_cast<const typet &>(type.find("sizeof-type"));

      if(tmp_type.id() == "cpp-name")
      {
        // this may be ambiguous -- it can be either a type or
        // an expression

        cpp_typecheck_fargst fargs;

        exprt symbol_expr = resolve(
          to_cpp_name(static_cast<const irept &>(tmp_type)),
          cpp_typecheck_resolvet::BOTH,
          fargs);

        type = symbol_expr.type();
      }
      else
      {
        typecheck_type(tmp_type);
        type = tmp_type;
      }
    }
    else
    {
      typecheck_expr(e);
      type = e.type();
    }
  }
  else if(type.id() == "decltype")
  {
    exprt e = static_cast<const exprt &>(type.find("expr_arg"));
    typecheck_expr(e);
    type = e.type();
  }
  else if(type.id() == "unassigned")
  {
    // ignore, for template argument guessing
  }
  else if(type.id() == "ellipsis")
  {
  }
  else
  {
    err_location(type);
    str << "unexpected type: " << type.pretty();
    throw 0;
  }

  assert(type.is_not_nil());
}
示例#6
0
bool value_set_dereferencet::memory_model_bytes(
  exprt &value,
  const typet &to_type,
  const guardt &guard,
  const exprt &offset)
{
  const typet from_type=value.type();

  // We simply refuse to convert to/from code.
  if(from_type.id()==ID_code || to_type.id()==ID_code)
    return false;

  // We won't do this without a commitment to an endianness.
  if(config.ansi_c.endianness==configt::ansi_ct::endiannesst::NO_ENDIANNESS)
    return false;

  // But everything else we will try!
  // We just rely on byte_extract to do the job!

  exprt result;

  // See if we have an array of bytes already,
  // and we want something byte-sized.
  if(ns.follow(from_type).id()==ID_array &&
     pointer_offset_size(ns.follow(from_type).subtype(), ns)==1 &&
     pointer_offset_size(to_type, ns)==1 &&
     is_a_bv_type(ns.follow(from_type).subtype()) &&
     is_a_bv_type(to_type))
  {
    // yes, can use 'index'
    result=index_exprt(value, offset, ns.follow(from_type).subtype());

    // possibly need to convert
    if(!base_type_eq(result.type(), to_type, ns))
      result.make_typecast(to_type);
  }
  else
  {
    // no, use 'byte_extract'
    result=exprt(byte_extract_id(), to_type);
    result.copy_to_operands(value, offset);
  }

  value=result;

  // are we within the bounds?
  if(options.get_bool_option("pointer-check"))
  {
    // upper bound
    {
      exprt from_width=size_of_expr(from_type, ns);
      INVARIANT(
        from_width.is_not_nil(),
        "unknown or invalid type size:\n"+from_type.pretty());

      exprt to_width=
        to_type.id()==ID_empty?
        from_integer(0, size_type()):size_of_expr(to_type, ns);
      INVARIANT(
        to_width.is_not_nil(),
        "unknown or invalid type size:\n"+to_type.pretty());
      INVARIANT(
        from_width.type()==to_width.type(),
        "type mismatch on result of size_of_expr");

      minus_exprt bound(from_width, to_width);
      if(bound.type()!=offset.type())
        bound.make_typecast(offset.type());

      binary_relation_exprt
        offset_upper_bound(offset, ID_gt, bound);

      guardt tmp_guard(guard);
      tmp_guard.add(offset_upper_bound);
      dereference_callback.dereference_failure(
        "pointer dereference",
        "object upper bound", tmp_guard);
    }

    // lower bound is easy
    if(!offset.is_zero())
    {
      binary_relation_exprt
        offset_lower_bound(
          offset, ID_lt, from_integer(0, offset.type()));

      guardt tmp_guard(guard);
      tmp_guard.add(offset_lower_bound);
      dereference_callback.dereference_failure(
        "pointer dereference",
        "object lower bound", tmp_guard);
    }
  }

  return true;
}
示例#7
0
文件: base_type.cpp 项目: lihaol/cbmc
bool base_type_eqt::base_type_eq_rec(
  const typet &type1,
  const typet &type2)
{
  if(type1==type2)
    return true;

  #if 0
  std::cout << "T1: " << type1.pretty() << std::endl;
  std::cout << "T2: " << type2.pretty() << std::endl;
  #endif

  // loop avoidance
  if((type1.id()==ID_symbol ||
      type1.id()==ID_c_enum_tag ||
      type1.id()==ID_struct_tag ||
      type1.id()==ID_union_tag) &&
     type2.id()==type1.id())
  {
    // already in same set?
    if(identifiers.make_union(
         type1.get(ID_identifier),
         type2.get(ID_identifier)))
      return true;
  }

  if(type1.id()==ID_symbol ||
     type1.id()==ID_c_enum_tag ||
     type1.id()==ID_struct_tag ||
     type1.id()==ID_union_tag)
  {
    const symbolt &symbol=
      ns.lookup(type1.get(ID_identifier));

    if(!symbol.is_type)
      return false;

    return base_type_eq_rec(symbol.type, type2);
  }

  if(type2.id()==ID_symbol ||
     type2.id()==ID_c_enum_tag ||
     type2.id()==ID_struct_tag ||
     type2.id()==ID_union_tag)
  {
    const symbolt &symbol=
      ns.lookup(type2.get(ID_identifier));

    if(!symbol.is_type)
      return false;

    return base_type_eq_rec(type1, symbol.type);
  }

  if(type1.id()!=type2.id())
    return false;

  if(type1.id()==ID_struct ||
     type1.id()==ID_union)
  {
    const struct_union_typet::componentst &components1=
      to_struct_union_type(type1).components();

    const struct_union_typet::componentst &components2=
      to_struct_union_type(type2).components();

    if(components1.size()!=components2.size())
      return false;

    for(unsigned i=0; i<components1.size(); i++)
    {
      const typet &subtype1=components1[i].type();
      const typet &subtype2=components2[i].type();
      if(!base_type_eq_rec(subtype1, subtype2)) return false;
      if(components1[i].get_name()!=components2[i].get_name()) return false;
    }

    return true;
  }
  else if(type1.id()==ID_incomplete_struct)
  {
    return true;
  }
  else if(type1.id()==ID_incomplete_union)
  {
    return true;
  }
  else if(type1.id()==ID_code)
  {
    const code_typet::parameterst &parameters1=
      to_code_type(type1).parameters();

    const code_typet::parameterst &parameters2=
      to_code_type(type2).parameters();

    if(parameters1.size()!=parameters2.size())
      return false;

    for(unsigned i=0; i<parameters1.size(); i++)
    {
      const typet &subtype1=parameters1[i].type();
      const typet &subtype2=parameters2[i].type();
      if(!base_type_eq_rec(subtype1, subtype2)) return false;
    }

    const typet &return_type1=to_code_type(type1).return_type();
    const typet &return_type2=to_code_type(type2).return_type();

    if(!base_type_eq_rec(return_type1, return_type2))
      return false;

    return true;
  }
  else if(type1.id()==ID_pointer)
  {
    return base_type_eq_rec(
      to_pointer_type(type1).subtype(), to_pointer_type(type2).subtype());
  }
  else if(type1.id()==ID_array)
  {
    if(!base_type_eq_rec(
      to_array_type(type1).subtype(), to_array_type(type2).subtype()))
      return false;

    if(to_array_type(type1).size()!=to_array_type(type2).size())
      return false;

    return true;
  }
  else if(type1.id()==ID_incomplete_array)
  {
    return base_type_eq_rec(
      to_incomplete_array_type(type1).subtype(),
      to_incomplete_array_type(type2).subtype());
  }

  // the below will go away
  typet tmp1(type1), tmp2(type2);

  base_type(tmp1, ns);
  base_type(tmp2, ns);

  return tmp1==tmp2;
}