예제 #1
0
bool
DWARFDebugPubnames::Extract(const DataExtractor& data)
{
    Timer scoped_timer (__PRETTY_FUNCTION__,
                        "DWARFDebugPubnames::Extract (byte_size = %zu)",
                        data.GetByteSize());
    LogSP log (LogChannelDWARF::GetLogIfAll(DWARF_LOG_DEBUG_PUBNAMES));
    if (log)
        log->Printf("DWARFDebugPubnames::Extract (byte_size = %zu)", data.GetByteSize());

    if (data.ValidOffset(0))
    {
        uint32_t offset = 0;

        DWARFDebugPubnamesSet set;
        while (data.ValidOffset(offset))
        {
            if (set.Extract(data, &offset))
            {
                m_sets.push_back(set);
                offset = set.GetOffsetOfNextEntry();
            }
            else
                break;
        }
        if (log)
            Dump (log.get());
        return true;
    }
    return false;
}
예제 #2
0
bool
DWARFCompileUnit::Extract(const DataExtractor &debug_info, uint32_t* offset_ptr)
{
    Clear();

    m_offset = *offset_ptr;

    if (debug_info.ValidOffset(*offset_ptr))
    {
        dw_offset_t abbr_offset;
        const DWARFDebugAbbrev *abbr = m_dwarf2Data->DebugAbbrev();
        m_length        = debug_info.GetU32(offset_ptr);
        m_version       = debug_info.GetU16(offset_ptr);
        abbr_offset     = debug_info.GetU32(offset_ptr);
        m_addr_size     = debug_info.GetU8 (offset_ptr);

        bool length_OK = debug_info.ValidOffset(GetNextCompileUnitOffset()-1);
        bool version_OK = SymbolFileDWARF::SupportedVersion(m_version);
        bool abbr_offset_OK = m_dwarf2Data->get_debug_abbrev_data().ValidOffset(abbr_offset);
        bool addr_size_OK = ((m_addr_size == 4) || (m_addr_size == 8));

        if (length_OK && version_OK && addr_size_OK && abbr_offset_OK && abbr != NULL)
        {
            m_abbrevs = abbr->GetAbbreviationDeclarationSet(abbr_offset);
            return true;
        }

        // reset the offset to where we tried to parse from if anything went wrong
        *offset_ptr = m_offset;
    }

    return false;
}
예제 #3
0
int
print_dwarf_expression (Stream &s,
                        const DataExtractor& data,
                        int address_size,
                        int dwarf_ref_size,
                        bool location_expression)
{
    int op_count = 0;
    uint32_t offset = 0;
    while (data.ValidOffset(offset))
    {
        if (location_expression && op_count > 0)
        {
            //  err (baton, "Dwarf location expressions may only have one operand!");
            return 1;
        }
        if (op_count > 0)
        {
            s.PutCString(", ");
        }
        if (print_dwarf_exp_op (s, data, &offset, address_size, dwarf_ref_size) == 1)
            return 1;
        op_count++;
    }

    return 0;
}
예제 #4
0
//----------------------------------------------------------------------
// Extract
//----------------------------------------------------------------------
bool
DWARFDebugAranges::Extract(const DataExtractor &debug_aranges_data)
{
    if (debug_aranges_data.ValidOffset(0))
    {
        uint32_t offset = 0;

        DWARFDebugArangeSet set;
        Range range;
        while (set.Extract(debug_aranges_data, &offset))
        {
            const uint32_t num_descriptors = set.NumDescriptors();
            if (num_descriptors > 0)
            {
                const dw_offset_t cu_offset = set.GetCompileUnitDIEOffset();
                
                for (uint32_t i=0; i<num_descriptors; ++i)
                {
                    const DWARFDebugArangeSet::Descriptor &descriptor = set.GetDescriptorRef(i);
                    m_aranges.Append(RangeToDIE::Entry (descriptor.address, descriptor.length, cu_offset));
                }
            }
            set.Clear();
        }
    }
    return false;
}
예제 #5
0
size_t
ObjectContainerBSDArchive::Archive::ParseObjects (DataExtractor &data)
{
    std::string str;
    uint32_t offset = 0;
    str.assign((const char *)data.GetData(&offset, SARMAG), SARMAG);
    if (str == ARMAG)
    {
        Object obj;
        do
        {
            offset = obj.Extract (data, offset);
            if (offset == LLDB_INVALID_INDEX32)
                break;
            uint32_t obj_idx = m_objects.size();
            m_objects.push_back(obj);
            // Insert all of the C strings out of order for now...
            m_object_name_to_index_map.Append (obj.ar_name.GetCString(), obj_idx);
            offset += obj.ar_file_size;
            obj.Clear();
        } while (data.ValidOffset(offset));

        // Now sort all of the object name pointers
        m_object_name_to_index_map.Sort ();
    }
    return m_objects.size();
}
예제 #6
0
//----------------------------------------------------------------------
// Extract
//----------------------------------------------------------------------
bool
DWARFDebugAranges::Extract(const DataExtractor &debug_aranges_data)
{
    if (debug_aranges_data.ValidOffset(0))
    {
        uint32_t offset = 0;

        typedef std::vector<DWARFDebugArangeSet>    SetCollection;
        typedef SetCollection::const_iterator       SetCollectionIter;
        SetCollection sets;

        DWARFDebugArangeSet set;
        Range range;
        while (set.Extract(debug_aranges_data, &offset))
            sets.push_back(set);

        uint32_t count = 0;

        for_each(sets.begin(), sets.end(), CountArangeDescriptors(count));

        if (count > 0)
        {
            m_aranges.reserve(count);
            AddArangeDescriptors range_adder(m_aranges);
            for_each(sets.begin(), sets.end(), range_adder);
        }

    //  puts("\n\nDWARFDebugAranges list is:\n");
    //  for_each(m_aranges.begin(), m_aranges.end(), PrintRange);
    }
    return false;
}
예제 #7
0
bool
DWARFDebugMacinfoEntry::Extract(const DataExtractor& mac_info_data, dw_offset_t* offset_ptr)
{
    if (mac_info_data.ValidOffset(*offset_ptr))
    {
        m_type_code = mac_info_data.GetU8(offset_ptr);

        switch (m_type_code)
        {

        case DW_MACINFO_define:
        case DW_MACINFO_undef:
            // 2 operands:
            // Arg 1: operand encodes the line number of the source line on which
            //      the relevant defining or undefining pre-processor directives
            //      appeared.
            m_line  = mac_info_data.GetULEB128(offset_ptr);
            // Arg 2: define string
            m_op2.cstr  = mac_info_data.GetCStr(offset_ptr);
            break;

        case DW_MACINFO_start_file:
            // 2 operands:
            // Op 1: line number of the source line on which the inclusion
            //      pre-processor directive occurred.
            m_line  = mac_info_data.GetULEB128(offset_ptr);
            // Op 2: a source file name index to a file number in the statement
            //      information table for the relevant compilation unit.
            m_op2.file_idx  = mac_info_data.GetULEB128(offset_ptr);
            break;

        case 0: // End of list
        case DW_MACINFO_end_file:
            // No operands
            m_line = DW_INVALID_OFFSET;
            m_op2.cstr = NULL;
            break;
        default:
            // Vendor specific entries always have a ULEB128 and a string
            m_line      = mac_info_data.GetULEB128(offset_ptr);
            m_op2.cstr  = mac_info_data.GetCStr(offset_ptr);
            break;
        }
        return true;
    }
    else
        m_type_code = 0;

    return false;
}
예제 #8
0
dw_offset_t
DWARFCompileUnit::Extract(dw_offset_t offset, const DataExtractor& debug_info_data, const DWARFAbbreviationDeclarationSet* abbrevs)
{
    Clear();

    m_offset = offset;

    if (debug_info_data.ValidOffset(offset))
    {
        m_length        = debug_info_data.GetU32(&offset);
        m_version       = debug_info_data.GetU16(&offset);
        bool abbrevs_OK = debug_info_data.GetU32(&offset) == abbrevs->GetOffset();
        m_abbrevs       = abbrevs;
        m_addr_size     = debug_info_data.GetU8 (&offset);

        bool version_OK = SymbolFileDWARF::SupportedVersion(m_version);
        bool addr_size_OK = ((m_addr_size == 4) || (m_addr_size == 8));

        if (version_OK && addr_size_OK && abbrevs_OK && debug_info_data.ValidOffset(offset))
            return offset;
    }
    return DW_INVALID_OFFSET;
}
예제 #9
0
//----------------------------------------------------------------------
// DWARFDebugAbbrev::Parse()
//----------------------------------------------------------------------
void
DWARFDebugAbbrev::Parse(const DataExtractor& data)
{
    lldb::offset_t offset = 0;

    while (data.ValidOffset(offset))
    {
        uint32_t initial_cu_offset = offset;
        DWARFAbbreviationDeclarationSet abbrevDeclSet;

        if (abbrevDeclSet.Extract(data, &offset))
            m_abbrevCollMap[initial_cu_offset] = abbrevDeclSet;
        else
            break;
    }
    m_prev_abbr_offset_pos = m_abbrevCollMap.end();
}
예제 #10
0
lldb::offset_t lldb_private::DumpDataExtractor(
    const DataExtractor &DE, Stream *s, offset_t start_offset,
    lldb::Format item_format, size_t item_byte_size, size_t item_count,
    size_t num_per_line, uint64_t base_addr,
    uint32_t item_bit_size,   // If zero, this is not a bitfield value, if
                              // non-zero, the value is a bitfield
    uint32_t item_bit_offset, // If "item_bit_size" is non-zero, this is the
                              // shift amount to apply to a bitfield
    ExecutionContextScope *exe_scope) {
  if (s == nullptr)
    return start_offset;

  if (item_format == eFormatPointer) {
    if (item_byte_size != 4 && item_byte_size != 8)
      item_byte_size = s->GetAddressByteSize();
  }

  offset_t offset = start_offset;

  if (item_format == eFormatInstruction) {
    TargetSP target_sp;
    if (exe_scope)
      target_sp = exe_scope->CalculateTarget();
    if (target_sp) {
      DisassemblerSP disassembler_sp(Disassembler::FindPlugin(
          target_sp->GetArchitecture(),
          target_sp->GetDisassemblyFlavor(), nullptr));
      if (disassembler_sp) {
        lldb::addr_t addr = base_addr + start_offset;
        lldb_private::Address so_addr;
        bool data_from_file = true;
        if (target_sp->GetSectionLoadList().ResolveLoadAddress(addr, so_addr)) {
          data_from_file = false;
        } else {
          if (target_sp->GetSectionLoadList().IsEmpty() ||
              !target_sp->GetImages().ResolveFileAddress(addr, so_addr))
            so_addr.SetRawAddress(addr);
        }

        size_t bytes_consumed = disassembler_sp->DecodeInstructions(
            so_addr, DE, start_offset, item_count, false, data_from_file);

        if (bytes_consumed) {
          offset += bytes_consumed;
          const bool show_address = base_addr != LLDB_INVALID_ADDRESS;
          const bool show_bytes = true;
          ExecutionContext exe_ctx;
          exe_scope->CalculateExecutionContext(exe_ctx);
          disassembler_sp->GetInstructionList().Dump(s, show_address,
                                                     show_bytes, &exe_ctx);
        }
      }
    } else
      s->Printf("invalid target");

    return offset;
  }

  if ((item_format == eFormatOSType || item_format == eFormatAddressInfo) &&
      item_byte_size > 8)
    item_format = eFormatHex;

  lldb::offset_t line_start_offset = start_offset;
  for (uint32_t count = 0; DE.ValidOffset(offset) && count < item_count;
       ++count) {
    if ((count % num_per_line) == 0) {
      if (count > 0) {
        if (item_format == eFormatBytesWithASCII &&
            offset > line_start_offset) {
          s->Printf("%*s",
                    static_cast<int>(
                        (num_per_line - (offset - line_start_offset)) * 3 + 2),
                    "");
          DumpDataExtractor(DE, s, line_start_offset, eFormatCharPrintable, 1,
                            offset - line_start_offset, SIZE_MAX,
                            LLDB_INVALID_ADDRESS, 0, 0);
        }
        s->EOL();
      }
      if (base_addr != LLDB_INVALID_ADDRESS)
        s->Printf("0x%8.8" PRIx64 ": ",
                  (uint64_t)(base_addr +
                             (offset - start_offset) / DE.getTargetByteSize()));

      line_start_offset = offset;
    } else if (item_format != eFormatChar &&
               item_format != eFormatCharPrintable &&
               item_format != eFormatCharArray && count > 0) {
      s->PutChar(' ');
    }

    switch (item_format) {
    case eFormatBoolean:
      if (item_byte_size <= 8)
        s->Printf("%s", DE.GetMaxU64Bitfield(&offset, item_byte_size,
                                             item_bit_size, item_bit_offset)
                            ? "true"
                            : "false");
      else {
        s->Printf("error: unsupported byte size (%" PRIu64
                  ") for boolean format",
                  (uint64_t)item_byte_size);
        return offset;
      }
      break;

    case eFormatBinary:
      if (item_byte_size <= 8) {
        uint64_t uval64 = DE.GetMaxU64Bitfield(&offset, item_byte_size,
                                               item_bit_size, item_bit_offset);
        // Avoid std::bitset<64>::to_string() since it is missing in
        // earlier C++ libraries
        std::string binary_value(64, '0');
        std::bitset<64> bits(uval64);
        for (uint32_t i = 0; i < 64; ++i)
          if (bits[i])
            binary_value[64 - 1 - i] = '1';
        if (item_bit_size > 0)
          s->Printf("0b%s", binary_value.c_str() + 64 - item_bit_size);
        else if (item_byte_size > 0 && item_byte_size <= 8)
          s->Printf("0b%s", binary_value.c_str() + 64 - item_byte_size * 8);
      } else {
        const bool is_signed = false;
        const unsigned radix = 2;
        offset = DumpAPInt(s, DE, offset, item_byte_size, is_signed, radix);
      }
      break;

    case eFormatBytes:
    case eFormatBytesWithASCII:
      for (uint32_t i = 0; i < item_byte_size; ++i) {
        s->Printf("%2.2x", DE.GetU8(&offset));
      }

      // Put an extra space between the groups of bytes if more than one
      // is being dumped in a group (item_byte_size is more than 1).
      if (item_byte_size > 1)
        s->PutChar(' ');
      break;

    case eFormatChar:
    case eFormatCharPrintable:
    case eFormatCharArray: {
      // If we are only printing one character surround it with single
      // quotes
      if (item_count == 1 && item_format == eFormatChar)
        s->PutChar('\'');

      const uint64_t ch = DE.GetMaxU64Bitfield(&offset, item_byte_size,
                                               item_bit_size, item_bit_offset);
      if (isprint(ch))
        s->Printf("%c", (char)ch);
      else if (item_format != eFormatCharPrintable) {
        switch (ch) {
        case '\033':
          s->Printf("\\e");
          break;
        case '\a':
          s->Printf("\\a");
          break;
        case '\b':
          s->Printf("\\b");
          break;
        case '\f':
          s->Printf("\\f");
          break;
        case '\n':
          s->Printf("\\n");
          break;
        case '\r':
          s->Printf("\\r");
          break;
        case '\t':
          s->Printf("\\t");
          break;
        case '\v':
          s->Printf("\\v");
          break;
        case '\0':
          s->Printf("\\0");
          break;
        default:
          if (item_byte_size == 1)
            s->Printf("\\x%2.2x", (uint8_t)ch);
          else
            s->Printf("%" PRIu64, ch);
          break;
        }
      } else {
        s->PutChar(NON_PRINTABLE_CHAR);
      }

      // If we are only printing one character surround it with single quotes
      if (item_count == 1 && item_format == eFormatChar)
        s->PutChar('\'');
    } break;

    case eFormatEnum: // Print enum value as a signed integer when we don't get
                      // the enum type
    case eFormatDecimal:
      if (item_byte_size <= 8)
        s->Printf("%" PRId64,
                  DE.GetMaxS64Bitfield(&offset, item_byte_size, item_bit_size,
                                       item_bit_offset));
      else {
        const bool is_signed = true;
        const unsigned radix = 10;
        offset = DumpAPInt(s, DE, offset, item_byte_size, is_signed, radix);
      }
      break;

    case eFormatUnsigned:
      if (item_byte_size <= 8)
        s->Printf("%" PRIu64,
                  DE.GetMaxU64Bitfield(&offset, item_byte_size, item_bit_size,
                                       item_bit_offset));
      else {
        const bool is_signed = false;
        const unsigned radix = 10;
        offset = DumpAPInt(s, DE, offset, item_byte_size, is_signed, radix);
      }
      break;

    case eFormatOctal:
      if (item_byte_size <= 8)
        s->Printf("0%" PRIo64,
                  DE.GetMaxS64Bitfield(&offset, item_byte_size, item_bit_size,
                                       item_bit_offset));
      else {
        const bool is_signed = false;
        const unsigned radix = 8;
        offset = DumpAPInt(s, DE, offset, item_byte_size, is_signed, radix);
      }
      break;

    case eFormatOSType: {
      uint64_t uval64 = DE.GetMaxU64Bitfield(&offset, item_byte_size,
                                             item_bit_size, item_bit_offset);
      s->PutChar('\'');
      for (uint32_t i = 0; i < item_byte_size; ++i) {
        uint8_t ch = (uint8_t)(uval64 >> ((item_byte_size - i - 1) * 8));
        if (isprint(ch))
          s->Printf("%c", ch);
        else {
          switch (ch) {
          case '\033':
            s->Printf("\\e");
            break;
          case '\a':
            s->Printf("\\a");
            break;
          case '\b':
            s->Printf("\\b");
            break;
          case '\f':
            s->Printf("\\f");
            break;
          case '\n':
            s->Printf("\\n");
            break;
          case '\r':
            s->Printf("\\r");
            break;
          case '\t':
            s->Printf("\\t");
            break;
          case '\v':
            s->Printf("\\v");
            break;
          case '\0':
            s->Printf("\\0");
            break;
          default:
            s->Printf("\\x%2.2x", ch);
            break;
          }
        }
      }
      s->PutChar('\'');
    } break;

    case eFormatCString: {
      const char *cstr = DE.GetCStr(&offset);

      if (!cstr) {
        s->Printf("NULL");
        offset = LLDB_INVALID_OFFSET;
      } else {
        s->PutChar('\"');

        while (const char c = *cstr) {
          if (isprint(c)) {
            s->PutChar(c);
          } else {
            switch (c) {
            case '\033':
              s->Printf("\\e");
              break;
            case '\a':
              s->Printf("\\a");
              break;
            case '\b':
              s->Printf("\\b");
              break;
            case '\f':
              s->Printf("\\f");
              break;
            case '\n':
              s->Printf("\\n");
              break;
            case '\r':
              s->Printf("\\r");
              break;
            case '\t':
              s->Printf("\\t");
              break;
            case '\v':
              s->Printf("\\v");
              break;
            default:
              s->Printf("\\x%2.2x", c);
              break;
            }
          }

          ++cstr;
        }

        s->PutChar('\"');
      }
    } break;

    case eFormatPointer:
      s->Address(DE.GetMaxU64Bitfield(&offset, item_byte_size, item_bit_size,
                                      item_bit_offset),
                 sizeof(addr_t));
      break;

    case eFormatComplexInteger: {
      size_t complex_int_byte_size = item_byte_size / 2;

      if (complex_int_byte_size > 0 && complex_int_byte_size <= 8) {
        s->Printf("%" PRIu64,
                  DE.GetMaxU64Bitfield(&offset, complex_int_byte_size, 0, 0));
        s->Printf(" + %" PRIu64 "i",
                  DE.GetMaxU64Bitfield(&offset, complex_int_byte_size, 0, 0));
      } else {
        s->Printf("error: unsupported byte size (%" PRIu64
                  ") for complex integer format",
                  (uint64_t)item_byte_size);
        return offset;
      }
    } break;

    case eFormatComplex:
      if (sizeof(float) * 2 == item_byte_size) {
        float f32_1 = DE.GetFloat(&offset);
        float f32_2 = DE.GetFloat(&offset);

        s->Printf("%g + %gi", f32_1, f32_2);
        break;
      } else if (sizeof(double) * 2 == item_byte_size) {
        double d64_1 = DE.GetDouble(&offset);
        double d64_2 = DE.GetDouble(&offset);

        s->Printf("%lg + %lgi", d64_1, d64_2);
        break;
      } else if (sizeof(long double) * 2 == item_byte_size) {
        long double ld64_1 = DE.GetLongDouble(&offset);
        long double ld64_2 = DE.GetLongDouble(&offset);
        s->Printf("%Lg + %Lgi", ld64_1, ld64_2);
        break;
      } else {
        s->Printf("error: unsupported byte size (%" PRIu64
                  ") for complex float format",
                  (uint64_t)item_byte_size);
        return offset;
      }
      break;

    default:
    case eFormatDefault:
    case eFormatHex:
    case eFormatHexUppercase: {
      bool wantsuppercase = (item_format == eFormatHexUppercase);
      switch (item_byte_size) {
      case 1:
      case 2:
      case 4:
      case 8:
        s->Printf(wantsuppercase ? "0x%*.*" PRIX64 : "0x%*.*" PRIx64,
                  (int)(2 * item_byte_size), (int)(2 * item_byte_size),
                  DE.GetMaxU64Bitfield(&offset, item_byte_size, item_bit_size,
                                       item_bit_offset));
        break;
      default: {
        assert(item_bit_size == 0 && item_bit_offset == 0);
        const uint8_t *bytes =
            (const uint8_t *)DE.GetData(&offset, item_byte_size);
        if (bytes) {
          s->PutCString("0x");
          uint32_t idx;
          if (DE.GetByteOrder() == eByteOrderBig) {
            for (idx = 0; idx < item_byte_size; ++idx)
              s->Printf(wantsuppercase ? "%2.2X" : "%2.2x", bytes[idx]);
          } else {
            for (idx = 0; idx < item_byte_size; ++idx)
              s->Printf(wantsuppercase ? "%2.2X" : "%2.2x",
                        bytes[item_byte_size - 1 - idx]);
          }
        }
      } break;
      }
    } break;

    case eFormatFloat: {
      TargetSP target_sp;
      bool used_apfloat = false;
      if (exe_scope)
        target_sp = exe_scope->CalculateTarget();
      if (target_sp) {
        ClangASTContext *clang_ast = target_sp->GetScratchClangASTContext();
        if (clang_ast) {
          clang::ASTContext *ast = clang_ast->getASTContext();
          if (ast) {
            llvm::SmallVector<char, 256> sv;
            // Show full precision when printing float values
            const unsigned format_precision = 0;
            const unsigned format_max_padding = 100;
            size_t item_bit_size = item_byte_size * 8;

            if (item_bit_size == ast->getTypeSize(ast->FloatTy)) {
              llvm::APInt apint(item_bit_size,
                                DE.GetMaxU64(&offset, item_byte_size));
              llvm::APFloat apfloat(ast->getFloatTypeSemantics(ast->FloatTy),
                                    apint);
              apfloat.toString(sv, format_precision, format_max_padding);
            } else if (item_bit_size == ast->getTypeSize(ast->DoubleTy)) {
              llvm::APInt apint;
              if (GetAPInt(DE, &offset, item_byte_size, apint)) {
                llvm::APFloat apfloat(ast->getFloatTypeSemantics(ast->DoubleTy),
                                      apint);
                apfloat.toString(sv, format_precision, format_max_padding);
              }
            } else if (item_bit_size == ast->getTypeSize(ast->LongDoubleTy)) {
              const auto &semantics =
                  ast->getFloatTypeSemantics(ast->LongDoubleTy);
              const auto byte_size =
                  (llvm::APFloat::getSizeInBits(semantics) + 7) / 8;

              llvm::APInt apint;
              if (GetAPInt(DE, &offset, byte_size, apint)) {
                llvm::APFloat apfloat(semantics, apint);
                apfloat.toString(sv, format_precision, format_max_padding);
              }
            } else if (item_bit_size == ast->getTypeSize(ast->HalfTy)) {
              llvm::APInt apint(item_bit_size, DE.GetU16(&offset));
              llvm::APFloat apfloat(ast->getFloatTypeSemantics(ast->HalfTy),
                                    apint);
              apfloat.toString(sv, format_precision, format_max_padding);
            }

            if (!sv.empty()) {
              s->Printf("%*.*s", (int)sv.size(), (int)sv.size(), sv.data());
              used_apfloat = true;
            }
          }
        }
      }

      if (!used_apfloat) {
        std::ostringstream ss;
        if (item_byte_size == sizeof(float) || item_byte_size == 2) {
          float f;
          if (item_byte_size == 2) {
            uint16_t half = DE.GetU16(&offset);
            f = half2float(half);
          } else {
            f = DE.GetFloat(&offset);
          }
          ss.precision(std::numeric_limits<float>::digits10);
          ss << f;
        } else if (item_byte_size == sizeof(double)) {
          ss.precision(std::numeric_limits<double>::digits10);
          ss << DE.GetDouble(&offset);
        } else if (item_byte_size == sizeof(long double) ||
                   item_byte_size == 10) {
          ss.precision(std::numeric_limits<long double>::digits10);
          ss << DE.GetLongDouble(&offset);
        } else {
          s->Printf("error: unsupported byte size (%" PRIu64
                    ") for float format",
                    (uint64_t)item_byte_size);
          return offset;
        }
        ss.flush();
        s->Printf("%s", ss.str().c_str());
      }
    } break;

    case eFormatUnicode16:
      s->Printf("U+%4.4x", DE.GetU16(&offset));
      break;

    case eFormatUnicode32:
      s->Printf("U+0x%8.8x", DE.GetU32(&offset));
      break;

    case eFormatAddressInfo: {
      addr_t addr = DE.GetMaxU64Bitfield(&offset, item_byte_size, item_bit_size,
                                         item_bit_offset);
      s->Printf("0x%*.*" PRIx64, (int)(2 * item_byte_size),
                (int)(2 * item_byte_size), addr);
      if (exe_scope) {
        TargetSP target_sp(exe_scope->CalculateTarget());
        lldb_private::Address so_addr;
        if (target_sp) {
          if (target_sp->GetSectionLoadList().ResolveLoadAddress(addr,
                                                                 so_addr)) {
            s->PutChar(' ');
            so_addr.Dump(s, exe_scope, Address::DumpStyleResolvedDescription,
                         Address::DumpStyleModuleWithFileAddress);
          } else {
            so_addr.SetOffset(addr);
            so_addr.Dump(s, exe_scope,
                         Address::DumpStyleResolvedPointerDescription);
          }
        }
      }
    } break;

    case eFormatHexFloat:
      if (sizeof(float) == item_byte_size) {
        char float_cstr[256];
        llvm::APFloat ap_float(DE.GetFloat(&offset));
        ap_float.convertToHexString(float_cstr, 0, false,
                                    llvm::APFloat::rmNearestTiesToEven);
        s->Printf("%s", float_cstr);
        break;
      } else if (sizeof(double) == item_byte_size) {
        char float_cstr[256];
        llvm::APFloat ap_float(DE.GetDouble(&offset));
        ap_float.convertToHexString(float_cstr, 0, false,
                                    llvm::APFloat::rmNearestTiesToEven);
        s->Printf("%s", float_cstr);
        break;
      } else {
        s->Printf("error: unsupported byte size (%" PRIu64
                  ") for hex float format",
                  (uint64_t)item_byte_size);
        return offset;
      }
      break;

    // please keep the single-item formats below in sync with
    // FormatManager::GetSingleItemFormat
    // if you fail to do so, users will start getting different outputs
    // depending on internal
    // implementation details they should not care about ||
    case eFormatVectorOfChar: //   ||
      s->PutChar('{');        //   \/
      offset =
          DumpDataExtractor(DE, s, offset, eFormatCharArray, 1, item_byte_size,
                            item_byte_size, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfSInt8:
      s->PutChar('{');
      offset =
          DumpDataExtractor(DE, s, offset, eFormatDecimal, 1, item_byte_size,
                            item_byte_size, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfUInt8:
      s->PutChar('{');
      offset = DumpDataExtractor(DE, s, offset, eFormatHex, 1, item_byte_size,
                                 item_byte_size, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfSInt16:
      s->PutChar('{');
      offset = DumpDataExtractor(
          DE, s, offset, eFormatDecimal, sizeof(uint16_t),
          item_byte_size / sizeof(uint16_t), item_byte_size / sizeof(uint16_t),
          LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfUInt16:
      s->PutChar('{');
      offset = DumpDataExtractor(DE, s, offset, eFormatHex, sizeof(uint16_t),
                                 item_byte_size / sizeof(uint16_t),
                                 item_byte_size / sizeof(uint16_t),
                                 LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfSInt32:
      s->PutChar('{');
      offset = DumpDataExtractor(
          DE, s, offset, eFormatDecimal, sizeof(uint32_t),
          item_byte_size / sizeof(uint32_t), item_byte_size / sizeof(uint32_t),
          LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfUInt32:
      s->PutChar('{');
      offset = DumpDataExtractor(DE, s, offset, eFormatHex, sizeof(uint32_t),
                                 item_byte_size / sizeof(uint32_t),
                                 item_byte_size / sizeof(uint32_t),
                                 LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfSInt64:
      s->PutChar('{');
      offset = DumpDataExtractor(
          DE, s, offset, eFormatDecimal, sizeof(uint64_t),
          item_byte_size / sizeof(uint64_t), item_byte_size / sizeof(uint64_t),
          LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfUInt64:
      s->PutChar('{');
      offset = DumpDataExtractor(DE, s, offset, eFormatHex, sizeof(uint64_t),
                                 item_byte_size / sizeof(uint64_t),
                                 item_byte_size / sizeof(uint64_t),
                                 LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfFloat16:
      s->PutChar('{');
      offset =
          DumpDataExtractor(DE, s, offset, eFormatFloat, 2, item_byte_size / 2,
                            item_byte_size / 2, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfFloat32:
      s->PutChar('{');
      offset =
          DumpDataExtractor(DE, s, offset, eFormatFloat, 4, item_byte_size / 4,
                            item_byte_size / 4, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfFloat64:
      s->PutChar('{');
      offset =
          DumpDataExtractor(DE, s, offset, eFormatFloat, 8, item_byte_size / 8,
                            item_byte_size / 8, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;

    case eFormatVectorOfUInt128:
      s->PutChar('{');
      offset =
          DumpDataExtractor(DE, s, offset, eFormatHex, 16, item_byte_size / 16,
                            item_byte_size / 16, LLDB_INVALID_ADDRESS, 0, 0);
      s->PutChar('}');
      break;
    }
  }

  if (item_format == eFormatBytesWithASCII && offset > line_start_offset) {
    s->Printf("%*s", static_cast<int>(
                         (num_per_line - (offset - line_start_offset)) * 3 + 2),
              "");
    DumpDataExtractor(DE, s, line_start_offset, eFormatCharPrintable, 1,
                      offset - line_start_offset, SIZE_MAX,
                      LLDB_INVALID_ADDRESS, 0, 0);
  }
  return offset; // Return the offset at which we ended up
}
예제 #11
0
bool
DWARFDebugArangeSet::Extract(const DataExtractor &data, lldb::offset_t *offset_ptr)
{
    if (data.ValidOffset(*offset_ptr))
    {
        m_arange_descriptors.clear();
        m_offset = *offset_ptr;

        // 7.20 Address Range Table
        //
        // Each set of entries in the table of address ranges contained in
        // the .debug_aranges section begins with a header consisting of: a
        // 4-byte length containing the length of the set of entries for this
        // compilation unit, not including the length field itself; a 2-byte
        // version identifier containing the value 2 for DWARF Version 2; a
        // 4-byte offset into the.debug_infosection; a 1-byte unsigned integer
        // containing the size in bytes of an address (or the offset portion of
        // an address for segmented addressing) on the target system; and a
        // 1-byte unsigned integer containing the size in bytes of a segment
        // descriptor on the target system. This header is followed by a series
        // of tuples. Each tuple consists of an address and a length, each in
        // the size appropriate for an address on the target architecture.
        m_header.length     = data.GetU32(offset_ptr);
        m_header.version    = data.GetU16(offset_ptr);
        m_header.cu_offset  = data.GetU32(offset_ptr);
        m_header.addr_size  = data.GetU8(offset_ptr);
        m_header.seg_size   = data.GetU8(offset_ptr);


        // The first tuple following the header in each set begins at an offset
        // that is a multiple of the size of a single tuple (that is, twice the
        // size of an address). The header is padded, if necessary, to the
        // appropriate boundary.
        const uint32_t header_size = *offset_ptr - m_offset;
        const uint32_t tuple_size = m_header.addr_size << 1;
        uint32_t first_tuple_offset = 0;
        while (first_tuple_offset < header_size)
            first_tuple_offset += tuple_size;

        *offset_ptr = m_offset + first_tuple_offset;

        Descriptor arangeDescriptor;

        assert(sizeof(arangeDescriptor.address) == sizeof(arangeDescriptor.length));
        assert(sizeof(arangeDescriptor.address) >= m_header.addr_size);

        while (data.ValidOffset(*offset_ptr))
        {
            arangeDescriptor.address    = data.GetMaxU64(offset_ptr, m_header.addr_size);
            arangeDescriptor.length     = data.GetMaxU64(offset_ptr, m_header.addr_size);

            // Each set of tuples is terminated by a 0 for the address and 0
            // for the length.
            if (arangeDescriptor.address || arangeDescriptor.length)
                m_arange_descriptors.push_back(arangeDescriptor);
            else
                break;  // We are done if we get a zero address and length
        }

        return !m_arange_descriptors.empty();
    }
    return false;
}