bool to_integer(const exprt &expr, mp_integer &int_value)
{
if(!expr.is_constant())
return true;
const std::string &value = expr.value().as_string();
const irep_idt &type_id = expr.type().id();
if(type_id == "pointer")
{
if(value == "NULL")
{
int_value = 0;
return false;
}
}
else if(type_id == "c_enum" || type_id == "symbol")
{
int_value = string2integer(value);
return false;
}
else if(type_id == "unsignedbv")
{
int_value = binary2integer(value, false);
return false;
}
else if(type_id == "signedbv")
{
int_value = binary2integer(value, true);
return false;
}
return true;
}
bool polynomial_acceleratort::fit_const(goto_programt::instructionst &body,
exprt &target,
polynomialt &poly) {
return false;
scratch_programt program(symbol_table);
program.append(body);
program.add_instruction(ASSERT)->guard = equal_exprt(target, not_exprt(target));
try {
if (program.check_sat(false)) {
#ifdef DEBUG
std::cout << "Fitting constant, eval'd to: " << expr2c(program.eval(target), ns) << std::endl;
#endif
constant_exprt val = to_constant_expr(program.eval(target));
mp_integer mp = binary2integer(val.get_value().c_str(), true);
monomialt mon;
monomialt::termt term;
term.var = from_integer(1, target.type());
term.exp = 1;
mon.terms.push_back(term);
mon.coeff = mp.to_long();
poly.monomials.push_back(mon);
return true;
}
} catch (std::string s) {
std::cout << "Error in fitting polynomial SAT check: " << s << std::endl;
} catch (const char *s) {
std::cout << "Error in fitting polynomial SAT check: " << s << std::endl;
}
return false;
}
exprt boolbvt::bv_get_rec(
const bvt &bv,
const std::vector<bool> &unknown,
std::size_t offset,
const typet &type) const
{
if(type.id()==ID_symbol)
return bv_get_rec(bv, unknown, offset, ns.follow(type));
std::size_t width=boolbv_width(type);
assert(bv.size()==unknown.size());
assert(bv.size()>=offset+width);
if(type.id()==ID_bool)
{
if(!unknown[offset])
{
switch(prop.l_get(bv[offset]).get_value())
{
case tvt::tv_enumt::TV_FALSE:
return false_exprt();
case tvt::tv_enumt::TV_TRUE:
return true_exprt();
default:
return false_exprt(); // default
}
}
return nil_exprt();
}
bvtypet bvtype=get_bvtype(type);
if(bvtype==IS_UNKNOWN)
{
if(type.id()==ID_array)
{
const typet &subtype=type.subtype();
std::size_t sub_width=boolbv_width(subtype);
if(sub_width!=0)
{
exprt::operandst op;
op.reserve(width/sub_width);
for(std::size_t new_offset=0;
new_offset<width;
new_offset+=sub_width)
{
op.push_back(
bv_get_rec(bv, unknown, offset+new_offset, subtype));
}
exprt dest=exprt(ID_array, type);
dest.operands().swap(op);
return dest;
}
}
else if(type.id()==ID_struct_tag)
{
return bv_get_rec(bv, unknown, offset, ns.follow_tag(to_struct_tag_type(type)));
}
else if(type.id()==ID_union_tag)
{
return bv_get_rec(bv, unknown, offset, ns.follow_tag(to_union_tag_type(type)));
}
else if(type.id()==ID_struct)
{
const struct_typet &struct_type=to_struct_type(type);
const struct_typet::componentst &components=struct_type.components();
std::size_t new_offset=0;
exprt::operandst op;
op.reserve(components.size());
for(struct_typet::componentst::const_iterator
it=components.begin();
it!=components.end();
it++)
{
const typet &subtype=ns.follow(it->type());
op.push_back(nil_exprt());
std::size_t sub_width=boolbv_width(subtype);
if(sub_width!=0)
{
op.back()=bv_get_rec(bv, unknown, offset+new_offset, subtype);
new_offset+=sub_width;
}
}
struct_exprt dest(type);
dest.operands().swap(op);
return dest;
}
else if(type.id()==ID_union)
{
const union_typet &union_type=to_union_type(type);
const union_typet::componentst &components=union_type.components();
assert(!components.empty());
// Any idea that's better than just returning the first component?
std::size_t component_nr=0;
union_exprt value(union_type);
value.set_component_name(
components[component_nr].get_name());
const typet &subtype=components[component_nr].type();
value.op()=bv_get_rec(bv, unknown, offset, subtype);
return value;
}
else if(type.id()==ID_vector)
{
const typet &subtype=ns.follow(type.subtype());
std::size_t sub_width=boolbv_width(subtype);
if(sub_width!=0 && width%sub_width==0)
{
std::size_t size=width/sub_width;
exprt value(ID_vector, type);
value.operands().resize(size);
for(std::size_t i=0; i<size; i++)
value.operands()[i]=
bv_get_rec(bv, unknown, i*sub_width, subtype);
return value;
}
}
else if(type.id()==ID_complex)
{
const typet &subtype=ns.follow(type.subtype());
std::size_t sub_width=boolbv_width(subtype);
if(sub_width!=0 && width==sub_width*2)
{
exprt value(ID_complex, type);
value.operands().resize(2);
value.op0()=bv_get_rec(bv, unknown, 0*sub_width, subtype);
value.op1()=bv_get_rec(bv, unknown, 1*sub_width, subtype);
return value;
}
}
}
std::string value;
for(std::size_t bit_nr=offset; bit_nr<offset+width; bit_nr++)
{
char ch;
if(unknown[bit_nr])
ch='0';
else
switch(prop.l_get(bv[bit_nr]).get_value())
{
case tvt::tv_enumt::TV_FALSE:
ch='0';
break;
case tvt::tv_enumt::TV_TRUE:
ch='1';
break;
case tvt::tv_enumt::TV_UNKNOWN:
ch='0';
break;
default:
assert(false);
}
value=ch+value;
}
switch(bvtype)
{
case IS_UNKNOWN:
if(type.id()==ID_string)
{
mp_integer int_value=binary2integer(value, false);
irep_idt s;
if(int_value>=string_numbering.size())
s=irep_idt();
else
s=string_numbering[int_value.to_long()];
return constant_exprt(s, type);
}
break;
case IS_RANGE:
{
mp_integer int_value=binary2integer(value, false);
mp_integer from=string2integer(type.get_string(ID_from));
constant_exprt value_expr(type);
value_expr.set_value(integer2string(int_value+from));
return value_expr;
}
break;
default:
case IS_C_ENUM:
constant_exprt value_expr(type);
value_expr.set_value(value);
return value_expr;
}
return nil_exprt();
}
void fixedbvt::from_expr(const constant_exprt &expr)
{
spec=to_fixedbv_type(expr.type());
v=binary2integer(id2string(expr.get_value()), true);
}
void bv_arithmetict::from_expr(const exprt &expr)
{
assert(expr.is_constant());
spec=expr.type();
value=binary2integer(expr.get_string(ID_value), spec.is_signed);
}
void ieee_floatt::from_expr(const constant_exprt &expr)
{
spec=ieee_float_spect(to_floatbv_type(expr.type()));
unpack(binary2integer(id2string(expr.get_value()), false));
}
void ieee_floatt::from_expr(const exprt &expr)
{
assert(expr.is_constant());
spec=to_floatbv_type(expr.type());
unpack(binary2integer(expr.get_string(ID_value), false));
}
void rw_sett::read_write_rec(
const exprt &expr,
bool r, bool w,
const std::string &suffix,
const guardt &guard)
{
if(expr.id()=="symbol" && !expr.has_operands())
{
const symbol_exprt &symbol_expr=to_symbol_expr(expr);
const symbolt *symbol;
if(!ns.lookup(symbol_expr.get_identifier(), symbol))
{
if(!symbol->static_lifetime /*&& expr.type().id()=="pointer"*/)
{
return; // ignore for now
}
if(symbol->name=="c::__ESBMC_alloc" ||
symbol->name=="c::__ESBMC_alloc_size" ||
symbol->name=="c::stdin" ||
symbol->name=="c::stdout" ||
symbol->name=="c::stderr" ||
symbol->name=="c::sys_nerr")
{
return; // ignore for now
}
}
irep_idt object=id2string(symbol_expr.get_identifier())+suffix;
entryt &entry=entries[object];
entry.object=object;
entry.r=entry.r || r;
entry.w=entry.w || w;
entry.guard = migrate_expr_back(guard.as_expr());
}
else if(expr.id()=="member")
{
assert(expr.operands().size()==1);
const std::string &component_name=expr.component_name().as_string();
read_write_rec(expr.op0(), r, w, "."+component_name+suffix, guard);
}
else if(expr.id()=="index")
{
// we don't distinguish the array elements for now
assert(expr.operands().size()==2);
std::string tmp;
tmp = integer2string(binary2integer(expr.op1().value().as_string(), true),10);
read_write_rec(expr.op0(), r, w, "["+suffix+tmp+"]", guard);
read(expr.op1(), guard);
}
else if(expr.id()=="dereference")
{
assert(expr.operands().size()==1);
read(expr.op0(), guard);
exprt tmp(expr.op0());
expr2tc tmp_expr;
migrate_expr(tmp, tmp_expr);
dereference(target, tmp_expr, ns, value_sets);
tmp = migrate_expr_back(tmp_expr);
read_write_rec(tmp, r, w, suffix, guard);
}
else if(expr.is_address_of() ||
expr.id()=="implicit_address_of")
{
assert(expr.operands().size()==1);
}
else if(expr.id()=="if")
{
assert(expr.operands().size()==3);
read(expr.op0(), guard);
guardt true_guard(guard);
expr2tc tmp_expr;
migrate_expr(expr.op0(), tmp_expr);
true_guard.add(tmp_expr);
read_write_rec(expr.op1(), r, w, suffix, true_guard);
guardt false_guard(guard);
migrate_expr(gen_not(expr.op0()), tmp_expr);
false_guard.add(tmp_expr);
read_write_rec(expr.op2(), r, w, suffix, false_guard);
}
else
{
forall_operands(it, expr)
read_write_rec(*it, r, w, suffix, guard);
}
}
