void ansi_c_convert_typet::read(const typet &type)
{
clear();
source_location=type.source_location();
read_rec(type);
if(!aligned &&
type.find(ID_C_alignment).is_not_nil())
{
aligned=true;
alignment=static_cast<const exprt &>(type.find(ID_C_alignment));
}
}
void cpp_declarationt::name_anon_struct_union(typet &dest)
{
// We name any anon struct/unions according to the first
// declarator. No need to do anon enums, which get
// a name based on the enum elements.
if(dest.id()==ID_struct || dest.id()==ID_union)
{
if(dest.find(ID_tag).is_nil())
{
// it's anonymous
const declaratorst &d=declarators();
if(!d.empty() &&
d.front().name().is_simple_name())
{
// Anon struct/unions without declarator are pretty
// useless, but still possible.
irep_idt base_name="anon-"+id2string(d.front().name().get_base_name());
dest.set(ID_tag, cpp_namet(base_name));
dest.set(ID_C_is_anonymous, true);
}
}
}
else if(dest.id()==ID_merged_type)
{
Forall_subtypes(it, dest)
name_anon_struct_union(*it);
}
}
void c_typecheck_baset::typecheck_typeof_type(typet &type)
{
// retain the qualifiers as is
c_qualifierst c_qualifiers;
c_qualifiers.read(type);
if(!((const exprt &)type).has_operands())
{
typet t=static_cast<const typet &>(type.find(ID_type_arg));
typecheck_type(t);
type.swap(t);
}
else
{
exprt expr=((const exprt &)type).op0();
typecheck_expr(expr);
// undo an implicit address-of
if(expr.id()==ID_address_of &&
expr.get_bool(ID_C_implicit))
{
assert(expr.operands().size()==1);
exprt tmp;
tmp.swap(expr.op0());
expr.swap(tmp);
}
type.swap(expr.type());
}
c_qualifiers.write(type);
}
void java_bytecode_parsert::get_class_refs_rec(const typet &src)
{
if(src.id()==ID_code)
{
const code_typet &ct=to_code_type(src);
const typet &rt=ct.return_type();
get_class_refs_rec(rt);
for(const auto &p : ct.parameters())
get_class_refs_rec(p.type());
}
else if(src.id()==ID_symbol)
{
irep_idt name=src.get(ID_C_base_name);
if(has_prefix(id2string(name), "array["))
{
const typet &element_type=
static_cast<const typet &>(src.find(ID_C_element_type));
get_class_refs_rec(element_type);
}
else
parse_tree.class_refs.insert(name);
}
else if(src.id()==ID_struct)
{
const struct_typet &struct_type=to_struct_type(src);
for(const auto &c : struct_type.components())
get_class_refs_rec(c.type());
}
else if(src.id()==ID_pointer)
get_class_refs_rec(src.subtype());
}
void c_typecheck_baset::typecheck_symbol_type(typet &type)
{
{
// add prefix
symbol_typet &symbol_type=to_symbol_type(type);
symbol_type.set_identifier(add_language_prefix(symbol_type.get_identifier()));
}
// adjust identifier, if needed
replace_symbol(type);
const irep_idt &identifier=
to_symbol_type(type).get_identifier();
symbol_tablet::symbolst::const_iterator s_it=
symbol_table.symbols.find(identifier);
if(s_it==symbol_table.symbols.end())
{
err_location(type);
str << "type symbol `" << identifier << "' not found";
throw 0;
}
const symbolt &symbol=s_it->second;
if(!symbol.is_type)
{
err_location(type);
throw "expected type symbol";
}
if(symbol.is_macro)
{
// overwrite, but preserve (add) any qualifiers and other flags
c_qualifierst c_qualifiers(type);
bool is_packed=type.get_bool(ID_C_packed);
irept alignment=type.find(ID_C_alignment);
c_qualifiers+=c_qualifierst(symbol.type);
type=symbol.type;
c_qualifiers.write(type);
if(is_packed) type.set(ID_C_packed, true);
if(alignment.is_not_nil()) type.set(ID_C_alignment, alignment);
}
// CPROVER extensions
if(symbol.base_name=="__CPROVER_rational")
{
type=rational_typet();
}
else if(symbol.base_name=="__CPROVER_integer")
{
type=integer_typet();
}
}
void c_typecheck_baset::typecheck_type(typet &type)
{
// we first convert, and then check
// do we have alignment?
if(type.find(ID_C_alignment).is_not_nil())
{
exprt &alignment=static_cast<exprt &>(type.add(ID_C_alignment));
if(alignment.id()!=ID_default)
{
typecheck_expr(alignment);
make_constant(alignment);
}
}
if(type.id()==ID_code)
typecheck_code_type(to_code_type(type));
else if(type.id()==ID_array)
typecheck_array_type(to_array_type(type));
else if(type.id()==ID_pointer)
typecheck_type(type.subtype());
else if(type.id()==ID_struct ||
type.id()==ID_union)
typecheck_compound_type(to_struct_union_type(type));
else if(type.id()==ID_c_enum)
{
}
else if(type.id()==ID_c_bitfield)
typecheck_c_bit_field_type(type);
else if(type.id()==ID_typeof)
typecheck_typeof_type(type);
else if(type.id()==ID_symbol)
typecheck_symbol_type(type);
else if(type.id()==ID_vector)
typecheck_vector_type(to_vector_type(type));
else if(type.id()==ID_custom_unsignedbv ||
type.id()==ID_custom_signedbv ||
type.id()==ID_custom_floatbv ||
type.id()==ID_custom_fixedbv)
typecheck_custom_type(type);
// do a bit of rule checking
if(type.get_bool(ID_C_restricted) &&
type.id()!=ID_pointer &&
type.id()!=ID_array)
{
err_location(type);
error("only a pointer can be 'restrict'");
throw 0;
}
}
code_function_callt get_destructor(
const namespacet &ns,
const typet &type)
{
if(type.id()==ID_symbol)
{
return get_destructor(ns, ns.follow(type));
}
else if(type.id()==ID_struct)
{
const exprt &methods=static_cast<const exprt&>(type.find(ID_methods));
forall_operands(it, methods)
{
if(it->type().id()==ID_code)
{
const code_typet &code_type=to_code_type(it->type());
if(code_type.return_type().id()==ID_destructor &&
code_type.parameters().size()==1)
{
const typet &arg_type=code_type.parameters().front().type();
if(arg_type.id()==ID_pointer &&
ns.follow(arg_type.subtype())==type)
{
exprt symbol_expr(ID_symbol, it->type());
symbol_expr.set(ID_identifier, it->get(ID_name));
code_function_callt function_call;
function_call.function()=symbol_expr;
return function_call;
}
}
}
}
}
return static_cast<const code_function_callt &>(get_nil_irep());
}
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 ¶meters=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 ¶meters=code_type.parameters();
for(auto ¶m : 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());
}
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());
}
bool cpp_typecheckt::cpp_is_pod(const typet &type) const
{
if(type.id()==ID_struct)
{
// Not allowed in PODs:
// * Non-PODs
// * Constructors/Destructors
// * virtuals
// * private/protected, unless static
// * overloading assignment operator
// * Base classes
const struct_typet &struct_type=to_struct_type(type);
if(!type.find(ID_bases).get_sub().empty())
return false;
const struct_typet::componentst &components=
struct_type.components();
for(struct_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
{
if(it->get_bool(ID_is_type))
continue;
if(it->get_base_name()=="operator=")
return false;
if(it->get_bool(ID_is_virtual))
return false;
const typet &sub_type=it->type();
if(sub_type.id()==ID_code)
{
if(it->get_bool(ID_is_virtual))
return false;
const typet &return_type=to_code_type(sub_type).return_type();
if(return_type.id()==ID_constructor ||
return_type.id()==ID_destructor)
return false;
}
else if(it->get(ID_access)!=ID_public &&
!it->get_bool(ID_is_static))
return false;
if(!cpp_is_pod(sub_type))
return false;
}
return true;
}
else if(type.id()==ID_array)
{
return cpp_is_pod(type.subtype());
}
else if(type.id()==ID_pointer)
{
if(is_reference(type)) // references are not PODs
return false;
// but pointers are PODs!
return true;
}
else if(type.id()==ID_symbol)
{
const symbolt &symb=lookup(type.get(ID_identifier));
assert(symb.is_type);
return cpp_is_pod(symb.type);
}
// everything else is POD
return true;
}
exprt c_sizeoft::sizeof_rec(const typet &type)
{
exprt dest;
if(type.id()==ID_signedbv ||
type.id()==ID_unsignedbv ||
type.id()==ID_floatbv ||
type.id()==ID_fixedbv ||
type.id()==ID_c_enum ||
type.id()==ID_incomplete_c_enum)
{
// We round up to bytes.
// See special treatment for bit-fields below.
unsigned bits=type.get_int(ID_width);
unsigned bytes=bits/8;
if((bits%8)!=0) bytes++;
dest=from_integer(bytes, size_type());
}
else if(type.id()==ID_pointer)
{
// the following is an MS extension
if(type.get_bool(ID_C_ptr32))
return from_integer(4, size_type());
unsigned bits=config.ansi_c.pointer_width;
unsigned bytes=bits/8;
if((bits%8)!=0) bytes++;
dest=from_integer(bytes, size_type());
}
else if(type.id()==ID_bool)
{
// We fit booleans into a byte.
dest=from_integer(1, size_type());
}
else if(type.id()==ID_array)
{
const exprt &size_expr=
to_array_type(type).size();
if(size_expr.is_nil())
{
// treated like an empty array
dest=from_integer(0, size_type());
}
else
{
exprt tmp_dest=sizeof_rec(type.subtype());
if(tmp_dest.is_nil())
return tmp_dest;
mp_integer a, b;
if(!to_integer(tmp_dest, a) &&
!to_integer(size_expr, b))
{
dest=from_integer(a*b, size_type());
}
else
{
dest.id(ID_mult);
dest.type()=size_type();
dest.copy_to_operands(size_expr);
dest.move_to_operands(tmp_dest);
c_implicit_typecast(dest.op0(), dest.type(), ns);
c_implicit_typecast(dest.op1(), dest.type(), ns);
}
}
}
else if(type.id()==ID_struct)
{
const struct_typet::componentst &components=
to_struct_type(type).components();
dest=from_integer(0, size_type());
mp_integer bit_field_width=0;
for(struct_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
{
const typet &sub_type=ns.follow(it->type());
if(it->get_bool(ID_is_type))
{
}
else if(sub_type.id()==ID_code)
{
}
else if(it->get_is_bit_field())
{
// this needs to be a signedbv/unsignedbv/enum
if(sub_type.id()!=ID_signedbv &&
sub_type.id()!=ID_unsignedbv &&
sub_type.id()!=ID_c_enum)
return nil_exprt();
// We just sum them up.
// This assumes they are properly padded.
bit_field_width+=sub_type.get_int(ID_width);
}
else
{
exprt tmp=sizeof_rec(sub_type);
if(tmp.is_nil())
return tmp;
dest=plus_exprt(dest, tmp);
}
}
if(bit_field_width!=0)
dest=plus_exprt(dest, from_integer(bit_field_width/8, size_type()));
}
else if(type.id()==ID_union)
{
const irept::subt &components=
type.find(ID_components).get_sub();
mp_integer max_size=0;
forall_irep(it, components)
{
if(it->get_bool(ID_is_type))
continue;
const typet &sub_type=static_cast<const typet &>(it->find(ID_type));
if(sub_type.id()==ID_code)
{
}
else
{
exprt tmp=sizeof_rec(sub_type);
if(tmp.is_nil())
return tmp;
simplify(tmp, ns);
mp_integer tmp_int;
if(to_integer(tmp, tmp_int))
return static_cast<const exprt &>(get_nil_irep());
if(tmp_int>max_size) max_size=tmp_int;
}
}
dest=from_integer(max_size, size_type());
}
else if(type.id()==ID_symbol)
unsigned interpretert::get_size(const typet &type) const
{
if(type.id()==ID_struct)
{
const struct_typet::componentst &components=
to_struct_type(type).components();
unsigned sum=0;
for(struct_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
{
const typet &sub_type=it->type();
if(sub_type.id()!=ID_code)
sum+=get_size(sub_type);
}
return sum;
}
else if(type.id()==ID_union)
{
const union_typet::componentst &components=
to_union_type(type).components();
unsigned max_size=0;
for(union_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
{
const typet &sub_type=it->type();
if(sub_type.id()!=ID_code)
max_size=std::max(max_size, get_size(sub_type));
}
return max_size;
}
else if(type.id()==ID_array)
{
const exprt &size_expr=static_cast<const exprt &>(type.find(ID_size));
unsigned subtype_size=get_size(type.subtype());
mp_integer i;
if(!to_integer(size_expr, i))
return subtype_size*integer2unsigned(i);
else
return subtype_size;
}
else if(type.id()==ID_symbol)
{
return get_size(ns.follow(type));
}
else
return 1;
}
void c_typecheck_baset::typecheck_custom_type(typet &type)
{
// they all have a width
exprt size_expr=
static_cast<const exprt &>(type.find(ID_size));
typecheck_expr(size_expr);
source_locationt source_location=size_expr.source_location();
make_constant_index(size_expr);
mp_integer size_int;
if(to_integer(size_expr, size_int))
{
error().source_location=source_location;
error() << "failed to convert bit vector width to constant" << eom;
throw 0;
}
if(size_int<1)
{
error().source_location=source_location;
error() << "bit vector width invalid" << eom;
throw 0;
}
type.remove(ID_size);
type.set(ID_width, integer2string(size_int));
// depending on type, there may be a number of fractional bits
if(type.id()==ID_custom_unsignedbv)
type.id(ID_unsignedbv);
else if(type.id()==ID_custom_signedbv)
type.id(ID_signedbv);
else if(type.id()==ID_custom_fixedbv)
{
type.id(ID_fixedbv);
exprt f_expr=
static_cast<const exprt &>(type.find(ID_f));
source_locationt source_location=f_expr.find_source_location();
typecheck_expr(f_expr);
make_constant_index(f_expr);
mp_integer f_int;
if(to_integer(f_expr, f_int))
{
error().source_location=source_location;
error() << "failed to convert number of fraction bits to constant" << eom;
throw 0;
}
if(f_int<0 || f_int>size_int)
{
error().source_location=source_location;
error() << "fixedbv fraction width invalid" << eom;
throw 0;
}
type.remove(ID_f);
type.set(ID_integer_bits, integer2string(size_int-f_int));
}
else if(type.id()==ID_custom_floatbv)
{
type.id(ID_floatbv);
exprt f_expr=
static_cast<const exprt &>(type.find(ID_f));
source_locationt source_location=f_expr.find_source_location();
typecheck_expr(f_expr);
make_constant_index(f_expr);
mp_integer f_int;
if(to_integer(f_expr, f_int))
{
error().source_location=source_location;
error() << "failed to convert number of fraction bits to constant" << eom;
throw 0;
}
if(f_int<1 || f_int+1>=size_int)
{
error().source_location=source_location;
error() << "floatbv fraction width invalid" << eom;
throw 0;
}
type.remove(ID_f);
type.set(ID_f, integer2string(f_int));
}
else
assert(false);
}
void c_typecheck_baset::typecheck_c_enum_type(typet &type)
{
// These come with the declarations
// of the enum constants as operands.
exprt &as_expr=static_cast<exprt &>(static_cast<irept &>(type));
source_locationt source_location=type.source_location();
// We allow empty enums in the grammar to get better
// error messages.
if(as_expr.operands().empty())
{
error().source_location=source_location;
error() << "empty enum" << eom;
throw 0;
}
// enums start at zero;
// we also track min and max to find a nice base type
mp_integer value=0, min_value=0, max_value=0;
std::list<c_enum_typet::c_enum_membert> enum_members;
// We need to determine a width, and a signedness
// to obtain an 'underlying type'.
// We just do int, but gcc might pick smaller widths
// if the type is marked as 'packed'.
// gcc/clang may also pick a larger width. Visual Studio doesn't.
for(auto &op : as_expr.operands())
{
ansi_c_declarationt &declaration=to_ansi_c_declaration(op);
exprt &v=declaration.declarator().value();
if(v.is_not_nil()) // value given?
{
exprt tmp_v=v;
typecheck_expr(tmp_v);
add_rounding_mode(tmp_v);
simplify(tmp_v, *this);
if(tmp_v.is_true())
value=1;
else if(tmp_v.is_false())
value=0;
else if(!to_integer(tmp_v, value))
{
}
else
{
error().source_location=v.source_location();
error() << "enum is not a constant";
throw 0;
}
}
if(value<min_value)
min_value=value;
if(value>max_value)
max_value=value;
typet constant_type=
enum_constant_type(min_value, max_value);
v=from_integer(value, constant_type);
declaration.type()=constant_type;
typecheck_declaration(declaration);
irep_idt base_name=
declaration.declarator().get_base_name();
irep_idt identifier=
declaration.declarator().get_name();
// store
c_enum_typet::c_enum_membert member;
member.set_identifier(identifier);
member.set_base_name(base_name);
member.set_value(integer2string(value));
enum_members.push_back(member);
// produce value for next constant
++value;
}
// Remove these now; we add them to the
// c_enum symbol later.
as_expr.operands().clear();
bool is_packed=type.get_bool(ID_C_packed);
// tag?
if(type.find(ID_tag).is_nil())
{
// None, it's anonymous. We generate a tag.
std::string anon_identifier="#anon_enum";
for(const auto &member : enum_members)
{
anon_identifier+='$';
anon_identifier+=id2string(member.get_base_name());
anon_identifier+='=';
anon_identifier+=id2string(member.get_value());
}
if(is_packed)
anon_identifier+="#packed";
type.add(ID_tag).set(ID_identifier, anon_identifier);
}
irept &tag=type.add(ID_tag);
irep_idt base_name=tag.get(ID_C_base_name);
irep_idt identifier=tag.get(ID_identifier);
// Put into symbol table
symbolt enum_tag_symbol;
enum_tag_symbol.is_type=true;
enum_tag_symbol.type=type;
enum_tag_symbol.location=source_location;
enum_tag_symbol.is_file_local=true;
enum_tag_symbol.base_name=base_name;
enum_tag_symbol.name=identifier;
// throw in the enum members as 'body'
irept::subt &body=enum_tag_symbol.type.add(ID_body).get_sub();
for(const auto &member : enum_members)
body.push_back(member);
// We use a subtype to store the underlying type.
typet underlying_type=
enum_underlying_type(min_value, max_value, is_packed);
enum_tag_symbol.type.subtype()=underlying_type;
// is it in the symbol table already?
symbol_tablet::symbolst::iterator s_it=
symbol_table.symbols.find(identifier);
if(s_it!=symbol_table.symbols.end())
{
// Yes.
symbolt &symbol=s_it->second;
if(symbol.type.id()==ID_incomplete_c_enum)
{
// Ok, overwrite the type in the symbol table.
// This gives us the members and the subtype.
symbol.type=enum_tag_symbol.type;
}
else if(symbol.type.id()==ID_c_enum)
{
// We might already have the same anonymous enum, and this is
// simply ok. Note that the C standard treats these as
// different types.
if(!base_name.empty())
{
error().source_location=type.source_location();
error() << "redeclaration of enum tag" << eom;
throw 0;
}
}
else
{
error().source_location=source_location;
error() << "use of tag that does not match previous declaration" << eom;
throw 0;
}
}
else
{
symbolt *new_symbol;
move_symbol(enum_tag_symbol, new_symbol);
}
// We produce a c_enum_tag as the resulting type.
type.id(ID_c_enum_tag);
type.remove(ID_tag);
type.set(ID_identifier, identifier);
}
void ansi_c_convert_typet::read_rec(const typet &type)
{
if(type.id()==ID_merged_type)
{
forall_subtypes(it, type)
read_rec(*it);
}
else if(type.id()==ID_signed)
signed_cnt++;
else if(type.id()==ID_unsigned)
unsigned_cnt++;
else if(type.id()==ID_ptr32)
c_qualifiers.is_ptr32=true;
else if(type.id()==ID_ptr64)
c_qualifiers.is_ptr64=true;
else if(type.id()==ID_volatile)
c_qualifiers.is_volatile=true;
else if(type.id()==ID_asm)
{
// ignore for now
}
else if(type.id()==ID_const)
c_qualifiers.is_constant=true;
else if(type.id()==ID_restricted)
c_qualifiers.is_restricted=true;
else if(type.id()==ID_char)
char_cnt++;
else if(type.id()==ID_int)
int_cnt++;
else if(type.id()==ID_int8)
int8_cnt++;
else if(type.id()==ID_int16)
int16_cnt++;
else if(type.id()==ID_int32)
int32_cnt++;
else if(type.id()==ID_int64)
int64_cnt++;
else if(type.id()==ID_gcc_float128)
gcc_float128_cnt++;
else if(type.id()==ID_gcc_int128)
gcc_int128_cnt++;
else if(type.id()==ID_gcc_attribute_mode)
{
const exprt &size_expr=
static_cast<const exprt &>(type.find(ID_size));
if(size_expr.id()=="__QI__")
gcc_mode_QI=true;
else if(size_expr.id()=="__HI__")
gcc_mode_HI=true;
else if(size_expr.id()=="__SI__")
gcc_mode_SI=true;
else if(size_expr.id()=="__DI__")
gcc_mode_DI=true;
else
{
// we ignore without whining
}
}
else if(type.id()==ID_bv)
{
bv_cnt++;
const exprt &size_expr=
static_cast<const exprt &>(type.find(ID_size));
mp_integer size_int;
if(to_integer(size_expr, size_int))
{
err_location(location);
error("bit vector width has to be constant");
throw 0;
}
if(size_int<1 || size_int>1024)
{
err_location(location);
error("bit vector width invalid");
throw 0;
}
bv_width=integer2long(size_int);
}
else if(type.id()==ID_short)
short_cnt++;
else if(type.id()==ID_long)
long_cnt++;
else if(type.id()==ID_double)
double_cnt++;
else if(type.id()==ID_float)
float_cnt++;
else if(type.id()==ID_bool)
c_bool_cnt++;
else if(type.id()==ID_proper_bool)
proper_bool_cnt++;
else if(type.id()==ID_complex)
complex_cnt++;
else if(type.id()==ID_static)
c_storage_spec.is_static=true;
else if(type.id()==ID_thread_local)
c_storage_spec.is_thread_local=true;
else if(type.id()==ID_inline)
c_storage_spec.is_inline=true;
else if(type.id()==ID_extern)
c_storage_spec.is_extern=true;
else if(type.id()==ID_typedef)
c_storage_spec.is_typedef=true;
else if(type.id()==ID_register)
c_storage_spec.is_register=true;
else if(type.id()==ID_auto)
{
// ignore
}
else if(type.id()==ID_packed)
packed=true;
else if(type.id()==ID_aligned)
{
aligned=true;
// may come with size or not
if(type.find(ID_size).is_nil())
alignment=exprt(ID_default);
else
alignment=static_cast<const exprt &>(type.find(ID_size));
}
else if(type.id()==ID_transparent_union)
{
c_qualifiers.is_transparent_union=true;
}
else if(type.id()==ID_vector)
vector_size=to_vector_type(type).size();
else if(type.id()==ID_void)
{
// we store 'void' as 'empty'
typet tmp=type;
tmp.id(ID_empty);
other.push_back(tmp);
}
else
other.push_back(type);
}
mp_integer alignment(const typet &type, const namespacet &ns)
{
// is the alignment given?
const exprt &given_alignment=
static_cast<const exprt &>(type.find(ID_C_alignment));
if(given_alignment.is_not_nil())
{
mp_integer a_int;
if(!to_integer(given_alignment, a_int))
return a_int;
// we trust it blindly, no matter how nonsensical
}
// compute default
if(type.id()==ID_array)
{
return alignment(type.subtype(), ns);
}
else if(type.id()==ID_struct || type.id()==ID_union)
{
const struct_union_typet::componentst &components=
to_struct_union_type(type).components();
mp_integer result=1;
// get the max
// (should really be the smallest common denominator)
for(struct_union_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
result=std::max(result, alignment(it->type(), ns));
return result;
}
else if(type.id()==ID_unsignedbv ||
type.id()==ID_signedbv ||
type.id()==ID_fixedbv ||
type.id()==ID_floatbv ||
type.id()==ID_c_bool)
{
unsigned width=to_bitvector_type(type).get_width();
return width%8?width/8+1:width/8;
}
else if(type.id()==ID_c_enum)
{
return alignment(type.subtype(), ns);
}
else if(type.id()==ID_c_enum_tag)
{
return alignment(ns.follow_tag(to_c_enum_tag_type(type)), ns);
}
else if(type.id()==ID_pointer)
{
unsigned width=config.ansi_c.pointer_width;
return width%8?width/8+1:width/8;
}
else if(type.id()==ID_symbol)
return alignment(ns.follow(type), ns);
return 1;
}
void ansi_c_convert_typet::read_rec(const typet &type)
{
if(type.id()==ID_merged_type)
{
forall_subtypes(it, type)
read_rec(*it);
}
else if(type.id()==ID_signed)
signed_cnt++;
else if(type.id()==ID_unsigned)
unsigned_cnt++;
else if(type.id()==ID_ptr32)
c_qualifiers.is_ptr32=true;
else if(type.id()==ID_ptr64)
c_qualifiers.is_ptr64=true;
else if(type.id()==ID_volatile)
c_qualifiers.is_volatile=true;
else if(type.id()==ID_asm)
{
// These are called 'asm labels' by GCC.
// ignore for now
}
else if(type.id()==ID_const)
c_qualifiers.is_constant=true;
else if(type.id()==ID_restrict)
c_qualifiers.is_restricted=true;
else if(type.id()==ID_atomic)
c_qualifiers.is_atomic=true;
else if(type.id()==ID_atomic_type_specifier)
{
// this gets turned into the qualifier, uh
c_qualifiers.is_atomic=true;
read_rec(type.subtype());
}
else if(type.id()==ID_char)
char_cnt++;
else if(type.id()==ID_int)
int_cnt++;
else if(type.id()==ID_int8)
int8_cnt++;
else if(type.id()==ID_int16)
int16_cnt++;
else if(type.id()==ID_int32)
int32_cnt++;
else if(type.id()==ID_int64)
int64_cnt++;
else if(type.id()==ID_gcc_float128)
gcc_float128_cnt++;
else if(type.id()==ID_gcc_int128)
gcc_int128_cnt++;
else if(type.id()==ID_gcc_attribute_mode)
{
gcc_attribute_mode=type;
}
else if(type.id()==ID_gcc_attribute)
{
}
else if(type.id()==ID_msc_based)
{
const exprt &as_expr=static_cast<const exprt &>(static_cast<const irept &>(type));
assert(as_expr.operands().size()==1);
msc_based=as_expr.op0();
}
else if(type.id()==ID_custom_bv)
{
bv_cnt++;
const exprt &size_expr=
static_cast<const exprt &>(type.find(ID_size));
bv_width=size_expr;
}
else if(type.id()==ID_custom_floatbv)
{
floatbv_cnt++;
const exprt &size_expr=
static_cast<const exprt &>(type.find(ID_size));
const exprt &fsize_expr=
static_cast<const exprt &>(type.find(ID_f));
bv_width=size_expr;
fraction_width=fsize_expr;
}
else if(type.id()==ID_custom_fixedbv)
{
fixedbv_cnt++;
const exprt &size_expr=
static_cast<const exprt &>(type.find(ID_size));
const exprt &fsize_expr=
static_cast<const exprt &>(type.find(ID_f));
bv_width=size_expr;
fraction_width=fsize_expr;
}
else if(type.id()==ID_short)
short_cnt++;
else if(type.id()==ID_long)
long_cnt++;
else if(type.id()==ID_double)
double_cnt++;
else if(type.id()==ID_float)
float_cnt++;
else if(type.id()==ID_c_bool)
c_bool_cnt++;
else if(type.id()==ID_proper_bool)
proper_bool_cnt++;
else if(type.id()==ID_complex)
complex_cnt++;
else if(type.id()==ID_static)
c_storage_spec.is_static=true;
else if(type.id()==ID_thread_local)
c_storage_spec.is_thread_local=true;
else if(type.id()==ID_inline)
c_storage_spec.is_inline=true;
else if(type.id()==ID_extern)
c_storage_spec.is_extern=true;
else if(type.id()==ID_typedef)
c_storage_spec.is_typedef=true;
else if(type.id()==ID_register)
c_storage_spec.is_register=true;
else if(type.id()==ID_auto)
{
// ignore
}
else if(type.id()==ID_packed)
packed=true;
else if(type.id()==ID_aligned)
{
aligned=true;
// may come with size or not
if(type.find(ID_size).is_nil())
alignment=exprt(ID_default);
else
alignment=static_cast<const exprt &>(type.find(ID_size));
}
else if(type.id()==ID_transparent_union)
{
c_qualifiers.is_transparent_union=true;
}
else if(type.id()==ID_vector)
vector_size=to_vector_type(type).size();
else if(type.id()==ID_void)
{
// we store 'void' as 'empty'
typet tmp=type;
tmp.id(ID_empty);
other.push_back(tmp);
}
else if(type.id()==ID_msc_declspec)
{
const exprt &as_expr=
static_cast<const exprt &>(static_cast<const irept &>(type));
forall_operands(it, as_expr)
{
// these are symbols
const irep_idt &id=it->get(ID_identifier);
if(id=="thread")
c_storage_spec.is_thread_local=true;
else if(id=="align")
{
assert(it->operands().size()==1);
aligned=true;
alignment=it->op0();
}
}
}
else
void c_typecheck_baset::typecheck_type(typet &type)
{
// we first convert, and then check
{
ansi_c_convert_typet ansi_c_convert_type(get_message_handler());
ansi_c_convert_type.read(type);
ansi_c_convert_type.write(type);
}
if(type.id()==ID_already_typechecked)
{
// need to preserve any qualifiers
c_qualifierst c_qualifiers(type);
c_qualifiers+=c_qualifierst(type.subtype());
bool packed=type.get_bool(ID_C_packed);
exprt alignment=static_cast<const exprt &>(type.find(ID_C_alignment));
irept _typedef=type.find(ID_C_typedef);
type=type.subtype();
c_qualifiers.write(type);
if(packed)
type.set(ID_C_packed, true);
if(alignment.is_not_nil())
type.add(ID_C_alignment, alignment);
if(_typedef.is_not_nil())
type.add(ID_C_typedef, _typedef);
return; // done
}
// do we have alignment?
if(type.find(ID_C_alignment).is_not_nil())
{
exprt &alignment=static_cast<exprt &>(type.add(ID_C_alignment));
if(alignment.id()!=ID_default)
{
typecheck_expr(alignment);
make_constant(alignment);
}
}
if(type.id()==ID_code)
typecheck_code_type(to_code_type(type));
else if(type.id()==ID_array)
typecheck_array_type(to_array_type(type));
else if(type.id()==ID_pointer)
typecheck_type(type.subtype());
else if(type.id()==ID_struct ||
type.id()==ID_union)
typecheck_compound_type(to_struct_union_type(type));
else if(type.id()==ID_c_enum)
typecheck_c_enum_type(type);
else if(type.id()==ID_c_enum_tag)
typecheck_c_enum_tag_type(to_c_enum_tag_type(type));
else if(type.id()==ID_c_bit_field)
typecheck_c_bit_field_type(to_c_bit_field_type(type));
else if(type.id()==ID_typeof)
typecheck_typeof_type(type);
else if(type.id()==ID_symbol)
typecheck_symbol_type(type);
else if(type.id()==ID_vector)
typecheck_vector_type(to_vector_type(type));
else if(type.id()==ID_custom_unsignedbv ||
type.id()==ID_custom_signedbv ||
type.id()==ID_custom_floatbv ||
type.id()==ID_custom_fixedbv)
typecheck_custom_type(type);
else if(type.id()==ID_gcc_attribute_mode)
{
// get that mode
irep_idt mode=type.get(ID_size);
// A list of all modes ist at
// http://www.delorie.com/gnu/docs/gcc/gccint_53.html
typecheck_type(type.subtype());
typet underlying_type=type.subtype();
// gcc allows this, but clang doesn't; it's a compiler hint only,
// but we'll try to interpret it the GCC way
if(underlying_type.id()==ID_c_enum_tag)
{
underlying_type=
follow_tag(to_c_enum_tag_type(underlying_type)).subtype();
assert(underlying_type.id()==ID_signedbv ||
underlying_type.id()==ID_unsignedbv);
}
if(underlying_type.id()==ID_signedbv ||
underlying_type.id()==ID_unsignedbv)
{
bool is_signed=underlying_type.id()==ID_signedbv;
typet result;
if(mode=="__QI__") // 8 bits
result=is_signed?signed_char_type():unsigned_char_type();
else if(mode=="__byte__") // 8 bits
result=is_signed?signed_char_type():unsigned_char_type();
else if(mode=="__HI__") // 16 bits
result=is_signed?signed_short_int_type():unsigned_short_int_type();
else if(mode=="__SI__") // 32 bits
result=is_signed?signed_int_type():unsigned_int_type();
else if(mode=="__word__") // long int, we think
result=is_signed?signed_long_int_type():unsigned_long_int_type();
else if(mode=="__pointer__") // we think this is size_t/ssize_t
result=is_signed?signed_size_type():size_type();
else if(mode=="__DI__") // 64 bits
{
if(config.ansi_c.long_int_width==64)
result=is_signed?signed_long_int_type():unsigned_long_int_type();
else
{
assert(config.ansi_c.long_long_int_width==64);
result=
is_signed?signed_long_long_int_type():unsigned_long_long_int_type();
}
}
else if(mode=="__TI__") // 128 bits
result=is_signed?gcc_signed_int128_type():gcc_unsigned_int128_type();
else if(mode=="__V2SI__") // vector of 2 ints, deprecated by gcc
result=
vector_typet(
is_signed?signed_int_type():unsigned_int_type(),
from_integer(2, size_type()));
else if(mode=="__V4SI__") // vector of 4 ints, deprecated by gcc
result=
vector_typet(
is_signed?signed_int_type():unsigned_int_type(),
from_integer(4, size_type()));
else // give up, just use subtype
result=type.subtype();
// save the location
result.add_source_location()=type.source_location();
if(type.subtype().id()==ID_c_enum_tag)
{
const irep_idt &tag_name=
to_c_enum_tag_type(type.subtype()).get_identifier();
symbol_tablet::symbolst::iterator entry=
symbol_table.symbols.find(tag_name);
assert(entry!=symbol_table.symbols.end());
entry->second.type.subtype()=result;
}
type=result;
}
else if(underlying_type.id()==ID_floatbv)
{
typet result;
if(mode=="__SF__") // 32 bits
result=float_type();
else if(mode=="__DF__") // 64 bits
result=double_type();
else if(mode=="__TF__") // 128 bits
result=gcc_float128_type();
else if(mode=="__V2SF__") // vector of 2 floats, deprecated by gcc
result=vector_typet(float_type(), from_integer(2, size_type()));
else if(mode=="__V2DF__") // vector of 2 doubles, deprecated by gcc
result=vector_typet(double_type(), from_integer(2, size_type()));
else if(mode=="__V4SF__") // vector of 4 floats, deprecated by gcc
result=vector_typet(float_type(), from_integer(4, size_type()));
else if(mode=="__V4DF__") // vector of 4 doubles, deprecated by gcc
result=vector_typet(double_type(), from_integer(4, size_type()));
else // give up, just use subtype
result=type.subtype();
// save the location
result.add_source_location()=type.source_location();
type=result;
}
else if(underlying_type.id()==ID_complex)
{
// gcc allows this, but clang doesn't -- see enums above
typet result;
if(mode=="__SC__") // 32 bits
result=float_type();
else if(mode=="__DC__") // 64 bits
result=double_type();
else if(mode=="__TC__") // 128 bits
result=gcc_float128_type();
else // give up, just use subtype
result=type.subtype();
// save the location
result.add_source_location()=type.source_location();
type=complex_typet(result);
}
else
{
error().source_location=type.source_location();
error() << "attribute mode `" << mode
<< "' applied to inappropriate type `"
<< to_string(type) << "'" << eom;
throw 0;
}
}
// do a mild bit of rule checking
if(type.get_bool(ID_C_restricted) &&
type.id()!=ID_pointer &&
type.id()!=ID_array)
{
error().source_location=type.source_location();
error() << "only a pointer can be 'restrict'" << eom;
throw 0;
}
}