bool boolbvt::type_conversion(
  const typet &src_type, const bvt &src,
  const typet &dest_type, bvt &dest)
{
  bvtypet dest_bvtype=get_bvtype(dest_type);
  bvtypet src_bvtype=get_bvtype(src_type);
  
  if(src_bvtype==IS_C_BIT_FIELD)
    return type_conversion(
      c_bit_field_replacement_type(to_c_bit_field_type(src_type), ns), src, dest_type, dest);

  if(dest_bvtype==IS_C_BIT_FIELD)
    return type_conversion(
      src_type, src, c_bit_field_replacement_type(to_c_bit_field_type(dest_type), ns), dest);

  std::size_t src_width=src.size();
  std::size_t dest_width=boolbv_width(dest_type);
  
  if(dest_width==0 || src_width==0)
    return true;
  
  dest.clear();
  dest.reserve(dest_width);

  if(dest_type.id()==ID_complex)
  {
    if(src_type==dest_type.subtype())
    {
      forall_literals(it, src)
      dest.push_back(*it);

      // pad with zeros
      for(std::size_t i=src.size(); i<dest_width; i++)
        dest.push_back(const_literal(false));

      return false;
    }
    else if(src_type.id()==ID_complex)
    {
      // recursively do both halfs
      bvt lower, upper, lower_res, upper_res;
      lower.assign(src.begin(), src.begin()+src.size()/2);
      upper.assign(src.begin()+src.size()/2, src.end());
      type_conversion(ns.follow(src_type.subtype()), lower, ns.follow(dest_type.subtype()), lower_res);
      type_conversion(ns.follow(src_type.subtype()), upper, ns.follow(dest_type.subtype()), upper_res);
      assert(lower_res.size()+upper_res.size()==dest_width);
      dest=lower_res;
      dest.insert(dest.end(), upper_res.begin(), upper_res.end());
      return false;
    }
  }
  
  if(src_type.id()==ID_complex)
  {
    assert(dest_type.id()!=ID_complex);
    if(dest_type.id()==ID_signedbv ||
       dest_type.id()==ID_unsignedbv ||
       dest_type.id()==ID_floatbv ||
       dest_type.id()==ID_fixedbv ||
       dest_type.id()==ID_c_enum ||
       dest_type.id()==ID_c_enum_tag ||
       dest_type.id()==ID_bool)
    {
      // A cast from complex x to real T
      // is (T) __real__ x.
      bvt tmp_src(src);
      tmp_src.resize(src.size()/2); // cut off imag part
      return type_conversion(src_type.subtype(), tmp_src, dest_type, dest);
    }
  }
  
  switch(dest_bvtype)
  {
  case IS_RANGE:
    if(src_bvtype==IS_UNSIGNED ||
       src_bvtype==IS_SIGNED ||
       src_bvtype==IS_C_BOOL)
    {
      mp_integer dest_from=to_range_type(dest_type).get_from();

      if(dest_from==0)
      {
        // do zero extension
        dest.resize(dest_width);
        for(std::size_t i=0; i<dest.size(); i++)
          dest[i]=(i<src.size()?src[i]:const_literal(false));

        return false;
      }
    }
    else if(src_bvtype==IS_RANGE) // range to range
    {
      mp_integer src_from=to_range_type(src_type).get_from();
      mp_integer dest_from=to_range_type(dest_type).get_from();

      if(dest_from==src_from)
      {
        // do zero extension, if needed
        dest=bv_utils.zero_extension(src, dest_width);
        return false;
      }
      else
      {
        // need to do arithmetic: add src_from-dest_from
        mp_integer offset=src_from-dest_from;
        dest=
          bv_utils.add(
            bv_utils.zero_extension(src, dest_width),
            bv_utils.build_constant(offset, dest_width));
      }

      return false;
    }
    break;
    
  case IS_FLOAT: // to float
    {
      float_utilst float_utils(prop);
      
      switch(src_bvtype)
      {
      case IS_FLOAT: // float to float
        // we don't have a rounding mode here,
        // which is why we refuse.
        break;

      case IS_SIGNED: // signed to float
      case IS_C_ENUM:
        float_utils.spec=to_floatbv_type(dest_type);
        dest=float_utils.from_signed_integer(src);
        return false;

      case IS_UNSIGNED: // unsigned to float
      case IS_C_BOOL: // _Bool to float
        float_utils.spec=to_floatbv_type(dest_type);
        dest=float_utils.from_unsigned_integer(src);
        return false;

      case IS_BV:
        assert(src_width==dest_width);
        dest=src;
        return false;

      default:
        if(src_type.id()==ID_bool)
        {
          // bool to float
          
          // build a one
          ieee_floatt f;
          f.spec=to_floatbv_type(dest_type);
          f.from_integer(1);
          
          dest=convert_bv(f.to_expr());

          assert(src_width==1);
          
          Forall_literals(it, dest)
            *it=prop.land(*it, src[0]);
            
          return false;
        }
      }
    }
    break;

  case IS_FIXED:
    if(src_bvtype==IS_FIXED)
    {
      // fixed to fixed
      
      std::size_t dest_fraction_bits=to_fixedbv_type(dest_type).get_fraction_bits(),
                  dest_int_bits=dest_width-dest_fraction_bits;
      std::size_t op_fraction_bits=to_fixedbv_type(src_type).get_fraction_bits(),
                  op_int_bits=src_width-op_fraction_bits;
      
      dest.resize(dest_width);
      
      // i == position after dot
      // i == 0: first position after dot

      for(std::size_t i=0; i<dest_fraction_bits; i++)
      {
        // position in bv
        std::size_t p=dest_fraction_bits-i-1;
      
        if(i<op_fraction_bits)
          dest[p]=src[op_fraction_bits-i-1];
        else 
          dest[p]=const_literal(false); // zero padding
      }

      for(std::size_t i=0; i<dest_int_bits; i++)
      {
        // position in bv
        std::size_t p=dest_fraction_bits+i;
        assert(p<dest_width);
      
        if(i<op_int_bits)
          dest[p]=src[i+op_fraction_bits];
        else 
          dest[p]=src[src_width-1]; // sign extension
      }

      return false;
    }
    else if(src_bvtype==IS_BV)
    {
      assert(src_width==dest_width);
      dest=src;
      return false;
    }
    else if(src_bvtype==IS_UNSIGNED ||
            src_bvtype==IS_SIGNED ||
            src_bvtype==IS_C_BOOL ||
            src_bvtype==IS_C_ENUM)
    {
      // integer to fixed

      std::size_t dest_fraction_bits=
        to_fixedbv_type(dest_type).get_fraction_bits();

      for(std::size_t i=0; i<dest_fraction_bits; i++)
        dest.push_back(const_literal(false)); // zero padding

      for(std::size_t i=0; i<dest_width-dest_fraction_bits; i++)
      {
        literalt l;
      
        if(i<src_width)
          l=src[i];
        else
        {
          if(src_bvtype==IS_SIGNED || src_bvtype==IS_C_ENUM)
            l=src[src_width-1]; // sign extension
          else
            l=const_literal(false); // zero extension
        }
        
        dest.push_back(l);
      }

      return false;
    }
    else if(src_type.id()==ID_bool)
    {
      // bool to fixed
      std::size_t fraction_bits=
        to_fixedbv_type(dest_type).get_fraction_bits();

      assert(src_width==1);

      for(std::size_t i=0; i<dest_width; i++)
      {
        if(i==fraction_bits)
          dest.push_back(src[0]);
        else
          dest.push_back(const_literal(false));
      }

      return false;
    }
    break;
  
  case IS_UNSIGNED:
  case IS_SIGNED:
  case IS_C_ENUM:
    switch(src_bvtype)
    {
    case IS_FLOAT: // float to integer
      // we don't have a rounding mode here,
      // which is why we refuse.
      break;
     
    case IS_FIXED: // fixed to integer
      {
        std::size_t op_fraction_bits=
          to_fixedbv_type(src_type).get_fraction_bits();

        for(std::size_t i=0; i<dest_width; i++)
        {
          if(i<src_width-op_fraction_bits)
            dest.push_back(src[i+op_fraction_bits]);
          else
          {
            if(dest_bvtype==IS_SIGNED)
              dest.push_back(src[src_width-1]); // sign extension
            else
              dest.push_back(const_literal(false)); // zero extension
          }
        }
        
        // we might need to round up in case of negative numbers
        // e.g., (int)(-1.00001)==1
        
        bvt fraction_bits_bv=src;
        fraction_bits_bv.resize(op_fraction_bits);
        literalt round_up=
          prop.land(prop.lor(fraction_bits_bv), src.back());

        dest=bv_utils.incrementer(dest, round_up);

        return false;
      }

    case IS_UNSIGNED: // integer to integer
    case IS_SIGNED:
    case IS_C_ENUM:
    case IS_C_BOOL:
      {
        // We do sign extension for any source type
        // that is signed, independently of the
        // destination type.
        // E.g., ((short)(ulong)(short)-1)==-1
        bool sign_extension=
          src_bvtype==IS_SIGNED || src_bvtype==IS_C_ENUM;

        for(std::size_t i=0; i<dest_width; i++)
        {
          if(i<src_width)
            dest.push_back(src[i]);
          else if(sign_extension)
            dest.push_back(src[src_width-1]); // sign extension
          else
            dest.push_back(const_literal(false));
        }

        return false;
      }
      
    case IS_VERILOG_UNSIGNED: // verilog_unsignedbv to signed/unsigned/enum
      {
        for(std::size_t i=0; i<dest_width; i++)
        {
          std::size_t src_index=i*2; // we take every second bit

          if(src_index<src_width)
            dest.push_back(src[src_index]);
          else // always zero-extend
            dest.push_back(const_literal(false));
        }

        return false;
      }
      break;
      
    case IS_VERILOG_SIGNED: // verilog_signedbv to signed/unsigned/enum
      {
        for(std::size_t i=0; i<dest_width; i++)
        {
          std::size_t src_index=i*2; // we take every second bit

          if(src_index<src_width)
            dest.push_back(src[src_index]);
          else // always sign-extend
            dest.push_back(src.back());
        }

        return false;
      }
      break;
      
    default:
      if(src_type.id()==ID_bool)
      {
        // bool to integer

        assert(src_width==1);

        for(std::size_t i=0; i<dest_width; i++)
        {
          if(i==0)
            dest.push_back(src[0]);
          else
            dest.push_back(const_literal(false));
        }

        return false;
      }
    }
    break;
    
  case IS_VERILOG_UNSIGNED:
    if(src_bvtype==IS_UNSIGNED ||
       src_bvtype==IS_C_BOOL ||
       src_type.id()==ID_bool)
    {
      for(std::size_t i=0, j=0; i<dest_width; i+=2, j++)
      {
        if(j<src_width)
          dest.push_back(src[j]);
        else
          dest.push_back(const_literal(false));

        dest.push_back(const_literal(false));
      }

      return false;
    }
    else if(src_bvtype==IS_SIGNED)
    {
      for(std::size_t i=0, j=0; i<dest_width; i+=2, j++)
      {
        if(j<src_width)
          dest.push_back(src[j]);
        else
          dest.push_back(src.back());

        dest.push_back(const_literal(false));
      }

      return false;
    }
    else if(src_bvtype==IS_VERILOG_UNSIGNED)
    {
      // verilog_unsignedbv to verilog_unsignedbv
      dest=src;

      if(dest_width<src_width)
        dest.resize(dest_width);
      else
      {
        dest=src;
        while(dest.size()<dest_width)
        {
          dest.push_back(const_literal(false));
          dest.push_back(const_literal(false));
        }
      }
      return false;
    }
    break;

  case IS_BV:
    assert(src_width==dest_width);
    dest=src;
    return false;
    
  case IS_C_BOOL:
    dest.resize(dest_width, const_literal(false));

    if(src_bvtype==IS_FLOAT)
    {
      float_utilst float_utils(prop);
      float_utils.spec=to_floatbv_type(src_type);
      dest[0]=!float_utils.is_zero(src);
    }
    else if(src_bvtype==IS_C_BOOL)
      dest[0]=src[0];
    else
      dest[0]=!bv_utils.is_zero(src);

    return false;
    
  default:
    if(dest_type.id()==ID_array)
    {
      if(src_width==dest_width)
      {
        dest=src;
        return false;
      }
    }
    else if(dest_type.id()==ID_struct)
    {
      const struct_typet &dest_struct =
        to_struct_type(dest_type);

      if(src_type.id()==ID_struct)
      {
        // we do subsets

        dest.resize(dest_width, const_literal(false));

        const struct_typet &op_struct =
          to_struct_type(src_type);

        const struct_typet::componentst &dest_comp=
          dest_struct.components();

        const struct_typet::componentst &op_comp=
          op_struct.components();

        // build offset maps
        offset_mapt op_offsets, dest_offsets;

        build_offset_map(op_struct, op_offsets);
        build_offset_map(dest_struct, dest_offsets);

        // build name map
        typedef std::map<irep_idt, unsigned> op_mapt;
        op_mapt op_map;

        for(std::size_t i=0; i<op_comp.size(); i++)
          op_map[op_comp[i].get_name()]=i;

        // now gather required fields
        for(std::size_t i=0;
            i<dest_comp.size();
            i++)
        {
          std::size_t offset=dest_offsets[i];
          std::size_t comp_width=boolbv_width(dest_comp[i].type());
          if(comp_width==0) continue;

          op_mapt::const_iterator it=
            op_map.find(dest_comp[i].get_name());

          if(it==op_map.end())
          {
            // not found

            // filling with free variables
            for(std::size_t j=0; j<comp_width; j++)
              dest[offset+j]=prop.new_variable();
          }
          else
          {
            // found
            if(dest_comp[i].type()!=dest_comp[it->second].type())
            {
              // filling with free variables
              for(std::size_t j=0; j<comp_width; j++)
                dest[offset+j]=prop.new_variable();
            }
            else
            {
              std::size_t op_offset=op_offsets[it->second];
              for(std::size_t j=0; j<comp_width; j++)
                dest[offset+j]=src[op_offset+j];
            }
          }
        }

        return false;
      }
    }

  }

  return true;
}
Exemple #2
0
bvt float_utilst::add_sub(
  const bvt &src1,
  const bvt &src2,
  bool subtract)
{
  unbiased_floatt unpacked1=unpack(src1);
  unbiased_floatt unpacked2=unpack(src2);

  // subtract?
  if(subtract)
    unpacked2.sign=!unpacked2.sign;

  // figure out which operand has the bigger exponent
  const bvt exponent_difference=subtract_exponents(unpacked1, unpacked2);
  literalt src2_bigger=exponent_difference.back();

  const bvt bigger_exponent=
    bv_utils.select(src2_bigger, unpacked2.exponent, unpacked1.exponent);

  // swap fractions as needed
  const bvt new_fraction1=
    bv_utils.select(src2_bigger, unpacked2.fraction, unpacked1.fraction);

  const bvt new_fraction2=
    bv_utils.select(src2_bigger, unpacked1.fraction, unpacked2.fraction);

  // compute distance
  const bvt distance=bv_utils.absolute_value(exponent_difference);

  // limit the distance: shifting more than f+3 bits is unnecessary
  const bvt limited_dist=limit_distance(distance, spec.f+3);

  // pad fractions with 2 zeros from below
  const bvt fraction1_padded=bv_utils.concatenate(bv_utils.zeros(3), new_fraction1);
  const bvt fraction2_padded=bv_utils.concatenate(bv_utils.zeros(3), new_fraction2);

  // shift new_fraction2
  literalt sticky_bit;
  const bvt fraction1_shifted=fraction1_padded;
  const bvt fraction2_shifted=sticky_right_shift(
    fraction2_padded, limited_dist, sticky_bit);

  // sticky bit: or of the bits lost by the right-shift
  bvt fraction2_stickied=fraction2_shifted;
  fraction2_stickied[0]=prop.lor(fraction2_shifted[0], sticky_bit);

  // need to have two extra fraction bits for addition and rounding
  const bvt fraction1_ext=bv_utils.zero_extension(fraction1_shifted, fraction1_shifted.size()+2);
  const bvt fraction2_ext=bv_utils.zero_extension(fraction2_stickied, fraction2_stickied.size()+2);

  unbiased_floatt result;

  // now add/sub them
  literalt subtract_lit=prop.lxor(unpacked1.sign, unpacked2.sign);
  result.fraction=
    bv_utils.add_sub(fraction1_ext, fraction2_ext, subtract_lit);

  // sign of result
  literalt fraction_sign=result.fraction.back();
  result.fraction=bv_utils.absolute_value(result.fraction);

  result.exponent=bigger_exponent;

  // adjust the exponent for the fact that we added two bits to the fraction
  result.exponent=
    bv_utils.add(bv_utils.sign_extension(result.exponent, result.exponent.size()+1),
      bv_utils.build_constant(2, result.exponent.size()+1));

  // NaN?
  result.NaN=prop.lor(
      prop.land(prop.land(unpacked1.infinity, unpacked2.infinity),
                prop.lxor(unpacked1.sign, unpacked2.sign)),
      prop.lor(unpacked1.NaN, unpacked2.NaN));

  // infinity?
  result.infinity=prop.land(
      !result.NaN,
      prop.lor(unpacked1.infinity, unpacked2.infinity));

  // zero?
  // Note that:
  //  1. The zero flag isn't used apart from in divide and
  //     is only set on unpack
  //  2. Subnormals mean that addition or subtraction can't round to 0,
  //     thus we can perform this test now
  //  3. The rules for sign are different for zero
  result.zero = prop.land(
      !prop.lor(result.infinity, result.NaN),
      !prop.lor(result.fraction));


  // sign
  literalt add_sub_sign=
    prop.lxor(prop.lselect(src2_bigger, unpacked2.sign, unpacked1.sign),
              fraction_sign);

  literalt infinity_sign=
    prop.lselect(unpacked1.infinity, unpacked1.sign, unpacked2.sign);

  #if 1
  literalt zero_sign=
    prop.lselect(rounding_mode_bits.round_to_minus_inf,
                 prop.lor(unpacked1.sign, unpacked2.sign),
                 prop.land(unpacked1.sign, unpacked2.sign));

  result.sign=prop.lselect(
    result.infinity,
    infinity_sign,
    prop.lselect(result.zero,
                 zero_sign,
                 add_sub_sign));
  #else
  result.sign=prop.lselect(
    result.infinity,
    infinity_sign,
    add_sub_sign);
  #endif

  #if 0
  result.sign=const_literal(false);
  result.fraction.resize(spec.f+1, const_literal(true));
  result.exponent.resize(spec.e, const_literal(false));
  result.NaN=const_literal(false);
  result.infinity=const_literal(false);
  //for(std::size_t i=0; i<result.fraction.size(); i++)
  //  result.fraction[i]=const_literal(true);

  for(std::size_t i=0; i<result.fraction.size(); i++)
    result.fraction[i]=new_fraction2[i];

  return pack(bias(result));
  #endif

  return rounder(result);
}