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|
// Copyright (C) 2012-2020 Internet Systems Consortium, Inc. ("ISC")
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this
// file, You can obtain one at http://mozilla.org/MPL/2.0/.
#include <config.h>
#include <dhcp/dhcp4.h>
#include <dhcp/dhcp6.h>
#include <dhcp/option4_addrlst.h>
#include <dhcp/option4_client_fqdn.h>
#include <dhcp/option6_addrlst.h>
#include <dhcp/option6_client_fqdn.h>
#include <dhcp/option6_ia.h>
#include <dhcp/option6_iaaddr.h>
#include <dhcp/option6_iaprefix.h>
#include <dhcp/option6_pdexclude.h>
#include <dhcp/option6_status_code.h>
#include <dhcp/option_custom.h>
#include <dhcp/option_definition.h>
#include <dhcp/option_int.h>
#include <dhcp/option_int_array.h>
#include <dhcp/option_opaque_data_tuples.h>
#include <dhcp/option_string.h>
#include <dhcp/option_vendor.h>
#include <dhcp/option_vendor_class.h>
#include <util/encode/hex.h>
#include <dns/labelsequence.h>
#include <dns/name.h>
#include <util/strutil.h>
#include <boost/algorithm/string/classification.hpp>
#include <boost/algorithm/string/predicate.hpp>
#include <boost/dynamic_bitset.hpp>
#include <boost/make_shared.hpp>
#include <sstream>
using namespace std;
using namespace isc::util;
namespace isc {
namespace dhcp {
OptionDefinition::OptionDefinition(const std::string& name,
const uint16_t code,
const std::string& space,
const std::string& type,
const bool array_type /* = false */)
: name_(name),
code_(code),
type_(OPT_UNKNOWN_TYPE),
array_type_(array_type),
encapsulated_space_(""),
record_fields_(),
user_context_(),
option_space_name_(space) {
// Data type is held as enum value by this class.
// Use the provided option type string to get the
// corresponding enum value.
type_ = OptionDataTypeUtil::getDataType(type);
}
OptionDefinition::OptionDefinition(const std::string& name,
const uint16_t code,
const std::string& space,
const OptionDataType type,
const bool array_type /* = false */)
: name_(name),
code_(code),
type_(type),
array_type_(array_type),
encapsulated_space_(""),
option_space_name_(space){
}
OptionDefinition::OptionDefinition(const std::string& name,
const uint16_t code,
const std::string& space,
const std::string& type,
const char* encapsulated_space)
: name_(name),
code_(code),
// Data type is held as enum value by this class.
// Use the provided option type string to get the
// corresponding enum value.
type_(OptionDataTypeUtil::getDataType(type)),
array_type_(false),
encapsulated_space_(encapsulated_space),
record_fields_(),
user_context_(),
option_space_name_(space) {
}
OptionDefinition::OptionDefinition(const std::string& name,
const uint16_t code,
const std::string& space,
const OptionDataType type,
const char* encapsulated_space)
: name_(name),
code_(code),
type_(type),
array_type_(false),
encapsulated_space_(encapsulated_space),
record_fields_(),
user_context_(),
option_space_name_(space) {
}
OptionDefinitionPtr
OptionDefinition::create(const std::string& name,
const uint16_t code,
const std::string& space,
const std::string& type,
const bool array_type) {
return (boost::make_shared<OptionDefinition>(name, code, space, type, array_type));
}
OptionDefinitionPtr
OptionDefinition::create(const std::string& name,
const uint16_t code,
const std::string& space,
const OptionDataType type,
const bool array_type) {
return (boost::make_shared<OptionDefinition>(name, code, space, type, array_type));
}
OptionDefinitionPtr
OptionDefinition::create(const std::string& name,
const uint16_t code,
const std::string& space,
const std::string& type,
const char* encapsulated_space) {
return (boost::make_shared<OptionDefinition>(name, code, space, type, encapsulated_space));
}
OptionDefinitionPtr
OptionDefinition::create(const std::string& name,
const uint16_t code,
const std::string& space,
const OptionDataType type,
const char* encapsulated_space) {
return (boost::make_shared<OptionDefinition>(name, code, space, type, encapsulated_space));
}
bool
OptionDefinition::equals(const OptionDefinition& other) const {
return (name_ == other.name_ &&
code_ == other.code_ &&
type_ == other.type_ &&
array_type_ == other.array_type_ &&
encapsulated_space_ == other.encapsulated_space_ &&
record_fields_ == other.record_fields_ &&
option_space_name_ == other.option_space_name_);
}
void
OptionDefinition::addRecordField(const std::string& data_type_name) {
OptionDataType data_type = OptionDataTypeUtil::getDataType(data_type_name);
addRecordField(data_type);
}
void
OptionDefinition::addRecordField(const OptionDataType data_type) {
if (type_ != OPT_RECORD_TYPE) {
isc_throw(isc::InvalidOperation,
"'record' option type must be used instead of '"
<< OptionDataTypeUtil::getDataTypeName(type_)
<< "' to add data fields to the record");
}
if (data_type >= OPT_RECORD_TYPE ||
data_type == OPT_ANY_ADDRESS_TYPE ||
data_type == OPT_EMPTY_TYPE) {
isc_throw(isc::BadValue,
"attempted to add invalid data type '"
<< OptionDataTypeUtil::getDataTypeName(data_type)
<< "' to the record.");
}
record_fields_.push_back(data_type);
}
OptionPtr
OptionDefinition::optionFactory(Option::Universe u, uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) const {
try {
// Some of the options are represented by the specialized classes derived
// from Option class (e.g. IA_NA, IAADDR). Although, they can be also
// represented by the generic classes, we want the object of the specialized
// type to be returned. Therefore, we first check that if we are dealing
// with such an option. If the instance is returned we just exit at this
// point. If not, we will search for a generic option type to return.
OptionPtr option = factorySpecialFormatOption(u, begin, end);
if (option) {
return (option);
}
switch(type_) {
case OPT_EMPTY_TYPE:
if (getEncapsulatedSpace().empty()) {
return (factoryEmpty(u, type));
} else {
return (OptionPtr(new OptionCustom(*this, u, begin, end)));
}
case OPT_BINARY_TYPE:
return (factoryGeneric(u, type, begin, end));
case OPT_UINT8_TYPE:
return (array_type_ ?
factoryIntegerArray<uint8_t>(u, type, begin, end) :
factoryInteger<uint8_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_INT8_TYPE:
return (array_type_ ?
factoryIntegerArray<int8_t>(u, type, begin, end) :
factoryInteger<int8_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_UINT16_TYPE:
return (array_type_ ?
factoryIntegerArray<uint16_t>(u, type, begin, end) :
factoryInteger<uint16_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_INT16_TYPE:
return (array_type_ ?
factoryIntegerArray<uint16_t>(u, type, begin, end) :
factoryInteger<int16_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_UINT32_TYPE:
return (array_type_ ?
factoryIntegerArray<uint32_t>(u, type, begin, end) :
factoryInteger<uint32_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_INT32_TYPE:
return (array_type_ ?
factoryIntegerArray<uint32_t>(u, type, begin, end) :
factoryInteger<int32_t>(u, type, getEncapsulatedSpace(),
begin, end));
case OPT_IPV4_ADDRESS_TYPE:
// If definition specifies that an option is an array
// of IPv4 addresses we return an instance of specialized
// class (OptionAddrLst4). For non-array types there is no
// specialized class yet implemented so we drop through
// to return an instance of OptionCustom.
if (array_type_) {
return (factoryAddrList4(type, begin, end));
}
break;
case OPT_IPV6_ADDRESS_TYPE:
// Handle array type only here (see comments for
// OPT_IPV4_ADDRESS_TYPE case).
if (array_type_) {
return (factoryAddrList6(type, begin, end));
}
break;
case OPT_STRING_TYPE:
return (OptionPtr(new OptionString(u, type, begin, end)));
case OPT_TUPLE_TYPE:
// Handle array type only here (see comments for
// OPT_IPV4_ADDRESS_TYPE case).
if (array_type_) {
return (factoryOpaqueDataTuples(u, type, begin, end));
}
break;
default:
// Do nothing. We will return generic option a few lines down.
;
}
return (OptionPtr(new OptionCustom(*this, u, begin, end)));
} catch (const SkipThisOptionError&) {
// We need to throw this one as is.
throw;
} catch (const SkipRemainingOptionsError&) {
// We need to throw this one as is.
throw;
} catch (const Exception& ex) {
isc_throw(InvalidOptionValue, ex.what());
}
}
OptionPtr
OptionDefinition::optionFactory(Option::Universe u, uint16_t type,
const OptionBuffer& buf) const {
return (optionFactory(u, type, buf.begin(), buf.end()));
}
OptionPtr
OptionDefinition::optionFactory(Option::Universe u, uint16_t type,
const std::vector<std::string>& values) const {
OptionBuffer buf;
if (!array_type_ && type_ != OPT_RECORD_TYPE) {
if (values.empty()) {
if (type_ != OPT_EMPTY_TYPE) {
isc_throw(InvalidOptionValue, "no option value specified");
}
} else {
writeToBuffer(u, util::str::trim(values[0]), type_, buf);
}
} else if (array_type_ && type_ != OPT_RECORD_TYPE) {
for (size_t i = 0; i < values.size(); ++i) {
writeToBuffer(u, util::str::trim(values[i]), type_, buf);
}
} else if (type_ == OPT_RECORD_TYPE) {
const RecordFieldsCollection& records = getRecordFields();
if (records.size() > values.size()) {
isc_throw(InvalidOptionValue, "number of data fields for the option"
<< " type '" << getCode() << "' is greater than number"
<< " of values provided.");
}
for (size_t i = 0; i < records.size(); ++i) {
writeToBuffer(u, util::str::trim(values[i]), records[i], buf);
}
if (array_type_ && (values.size() > records.size())) {
for (size_t i = records.size(); i < values.size(); ++i) {
writeToBuffer(u, util::str::trim(values[i]),
records.back(), buf);
}
}
}
return (optionFactory(u, type, buf.begin(), buf.end()));
}
void
OptionDefinition::validate() const {
using namespace boost::algorithm;
std::ostringstream err_str;
// Allowed characters in the option name are: lower or
// upper case letters, digits, underscores and hyphens.
// Empty option spaces are not allowed.
if (!all(name_, boost::is_from_range('a', 'z') ||
boost::is_from_range('A', 'Z') ||
boost::is_digit() ||
boost::is_any_of(std::string("-_"))) ||
name_.empty() ||
// Hyphens and underscores are not allowed at the beginning
// and at the end of the option name.
all(find_head(name_, 1), boost::is_any_of(std::string("-_"))) ||
all(find_tail(name_, 1), boost::is_any_of(std::string("-_")))) {
err_str << "invalid option name '" << name_ << "'";
} else if (!OptionSpace::validateName(option_space_name_)) {
err_str << "invalid option space name: '"
<< option_space_name_ << "'";
} else if (!encapsulated_space_.empty() &&
!OptionSpace::validateName(encapsulated_space_)) {
err_str << "invalid encapsulated option space name: '"
<< encapsulated_space_ << "'";
} else if (type_ >= OPT_UNKNOWN_TYPE) {
// Option definition must be of a known type.
err_str << "option type " << type_ << " not supported.";
} else if (type_ == OPT_RECORD_TYPE) {
// At least two data fields should be added to the record. Otherwise
// non-record option definition could be used.
if (getRecordFields().size() < 2) {
err_str << "invalid number of data fields: "
<< getRecordFields().size()
<< " specified for the option of type 'record'. Expected at"
<< " least 2 fields.";
} else {
// If the number of fields is valid we have to check if their order
// is valid too. We check that string or binary data fields are not
// laid before other fields. But we allow that they are laid at the
// end of an option.
const RecordFieldsCollection& fields = getRecordFields();
for (RecordFieldsConstIter it = fields.begin();
it != fields.end(); ++it) {
if (*it == OPT_STRING_TYPE &&
it < fields.end() - 1) {
err_str << "string data field can't be laid before data"
<< " fields of other types.";
break;
}
if (*it == OPT_BINARY_TYPE &&
it < fields.end() - 1) {
err_str << "binary data field can't be laid before data"
<< " fields of other types.";
break;
}
// Empty type is not allowed within a record.
if (*it == OPT_EMPTY_TYPE) {
err_str << "empty data type can't be stored as a field in"
<< " an option record.";
break;
}
}
// If the array flag is set the last field is an array.
if (err_str.str().empty() && array_type_) {
const OptionDataType& last_type = fields.back();
if (last_type == OPT_STRING_TYPE) {
err_str
<< "array of strings is not a valid option definition.";
} else if (last_type == OPT_BINARY_TYPE) {
err_str << "array of binary values is not a valid option "
"definition.";
}
// Empty type was already checked.
}
}
} else if (array_type_) {
if (type_ == OPT_STRING_TYPE) {
// Array of strings is not allowed because there is no way
// to determine the size of a particular string and thus there
// it no way to tell when other data fields begin.
err_str << "array of strings is not a valid option definition.";
} else if (type_ == OPT_BINARY_TYPE) {
err_str << "array of binary values is not"
<< " a valid option definition.";
} else if (type_ == OPT_EMPTY_TYPE) {
err_str << "array of empty value is not"
<< " a valid option definition.";
}
}
// Non-empty error string means that we have hit the error. We throw
// exception and include error string.
if (!err_str.str().empty()) {
isc_throw(MalformedOptionDefinition, err_str.str());
}
}
bool
OptionDefinition::haveCompressedFqdnListFormat() const {
return (haveType(OPT_FQDN_TYPE) && getArrayType());
}
bool
OptionDefinition::convertToBool(const std::string& value_str) const {
// Case-insensitive check that the input is one of: "true" or "false".
if (boost::iequals(value_str, "true")) {
return (true);
} else if (boost::iequals(value_str, "false")) {
return (false);
}
// The input string is neither "true" nor "false", so let's check
// if it is not an integer wrapped in a string.
int result;
try {
result = boost::lexical_cast<int>(value_str);
} catch (const boost::bad_lexical_cast&) {
isc_throw(BadDataTypeCast, "unable to covert the value '"
<< value_str << "' to boolean data type");
}
// The boolean value is encoded in DHCP option as 0 or 1. Therefore,
// we only allow a user to specify those values for options which
// have boolean fields.
if (result != 1 && result != 0) {
isc_throw(BadDataTypeCast, "unable to convert '" << value_str
<< "' to boolean data type");
}
return (static_cast<bool>(result));
}
template<typename T>
T
OptionDefinition::lexicalCastWithRangeCheck(const std::string& value_str)
const {
// The lexical cast should be attempted when converting to an integer
// value only.
if (!OptionDataTypeTraits<T>::integer_type) {
isc_throw(BadDataTypeCast,
"must not convert '" << value_str
<< "' to non-integer data type");
}
// We use the 64-bit value here because it has wider range than
// any other type we use here and it allows to detect out of
// bounds conditions e.g. negative value specified for uintX_t
// data type. Obviously if the value exceeds the limits of int64
// this function will not handle that properly.
int64_t result = 0;
try {
result = boost::lexical_cast<int64_t>(value_str);
} catch (const boost::bad_lexical_cast&) {
// boost::lexical_cast does not handle hexadecimal
// but stringstream does so do it the hard way.
std::stringstream ss;
ss << std::hex << value_str;
ss >> result;
if (ss.fail() || !ss.eof()) {
isc_throw(BadDataTypeCast, "unable to convert the value '"
<< value_str << "' to integer data type");
}
}
// Perform range checks.
if (OptionDataTypeTraits<T>::integer_type) {
if (result > numeric_limits<T>::max() ||
result < numeric_limits<T>::min()) {
isc_throw(BadDataTypeCast, "unable to convert '"
<< value_str << "' to numeric type. This value is "
"expected to be in the range of "
<< +numeric_limits<T>::min() << ".."
<< +numeric_limits<T>::max());
}
}
return (static_cast<T>(result));
}
void
OptionDefinition::writeToBuffer(Option::Universe u,
const std::string& value,
const OptionDataType type,
OptionBuffer& buf) const {
// We are going to write value given by value argument to the buffer.
// The actual type of the value is given by second argument. Check
// this argument to determine how to write this value to the buffer.
switch (type) {
case OPT_BINARY_TYPE:
OptionDataTypeUtil::writeBinary(value, buf);
return;
case OPT_BOOLEAN_TYPE:
// We encode the true value as 1 and false as 0 on 8 bits.
// That way we actually waste 7 bits but it seems to be the
// simpler way to encode boolean.
// @todo Consider if any other encode methods can be used.
OptionDataTypeUtil::writeBool(convertToBool(value), buf);
return;
case OPT_INT8_TYPE:
OptionDataTypeUtil::writeInt<uint8_t>
(lexicalCastWithRangeCheck<int8_t>(value),
buf);
return;
case OPT_INT16_TYPE:
OptionDataTypeUtil::writeInt<uint16_t>
(lexicalCastWithRangeCheck<int16_t>(value),
buf);
return;
case OPT_INT32_TYPE:
OptionDataTypeUtil::writeInt<uint32_t>
(lexicalCastWithRangeCheck<int32_t>(value),
buf);
return;
case OPT_UINT8_TYPE:
OptionDataTypeUtil::writeInt<uint8_t>
(lexicalCastWithRangeCheck<uint8_t>(value),
buf);
return;
case OPT_UINT16_TYPE:
OptionDataTypeUtil::writeInt<uint16_t>
(lexicalCastWithRangeCheck<uint16_t>(value),
buf);
return;
case OPT_UINT32_TYPE:
OptionDataTypeUtil::writeInt<uint32_t>
(lexicalCastWithRangeCheck<uint32_t>(value),
buf);
return;
case OPT_IPV4_ADDRESS_TYPE:
case OPT_IPV6_ADDRESS_TYPE:
{
asiolink::IOAddress address(value);
if (!address.isV4() && !address.isV6()) {
isc_throw(BadDataTypeCast, "provided address "
<< address
<< " is not a valid IPv4 or IPv6 address.");
}
OptionDataTypeUtil::writeAddress(address, buf);
return;
}
case OPT_IPV6_PREFIX_TYPE:
{
std::string txt = value;
// first let's remove any whitespaces
boost::erase_all(txt, " "); // space
boost::erase_all(txt, "\t"); // tabulation
// Is this prefix/len notation?
size_t pos = txt.find("/");
if (pos == string::npos) {
isc_throw(BadDataTypeCast, "provided address/prefix "
<< value
<< " is not valid.");
}
std::string txt_address = txt.substr(0, pos);
isc::asiolink::IOAddress address = isc::asiolink::IOAddress(txt_address);
if (!address.isV6()) {
isc_throw(BadDataTypeCast, "provided address "
<< txt_address
<< " is not a valid IPv4 or IPv6 address.");
}
std::string txt_prefix = txt.substr(pos + 1);
uint8_t len = 0;
try {
// start with the first character after /
len = lexicalCastWithRangeCheck<uint8_t>(txt_prefix);
} catch (...) {
isc_throw(BadDataTypeCast, "provided prefix "
<< txt_prefix
<< " is not valid.");
}
// Write a prefix.
OptionDataTypeUtil::writePrefix(PrefixLen(len), address, buf);
return;
}
case OPT_PSID_TYPE:
{
std::string txt = value;
// first let's remove any whitespaces
boost::erase_all(txt, " "); // space
boost::erase_all(txt, "\t"); // tabulation
// Is this prefix/len notation?
size_t pos = txt.find("/");
if (pos == string::npos) {
isc_throw(BadDataTypeCast, "provided PSID value "
<< value << " is not valid");
}
const std::string txt_psid = txt.substr(0, pos);
const std::string txt_psid_len = txt.substr(pos + 1);
uint16_t psid = 0;
uint8_t psid_len = 0;
try {
psid = lexicalCastWithRangeCheck<uint16_t>(txt_psid);
} catch (...) {
isc_throw(BadDataTypeCast, "provided PSID "
<< txt_psid << " is not valid");
}
try {
psid_len = lexicalCastWithRangeCheck<uint8_t>(txt_psid_len);
} catch (...) {
isc_throw(BadDataTypeCast, "provided PSID length "
<< txt_psid_len << " is not valid");
}
OptionDataTypeUtil::writePsid(PSIDLen(psid_len), PSID(psid), buf);
return;
}
case OPT_STRING_TYPE:
OptionDataTypeUtil::writeString(value, buf);
return;
case OPT_FQDN_TYPE:
OptionDataTypeUtil::writeFqdn(value, buf);
return;
case OPT_TUPLE_TYPE:
{
OpaqueDataTuple::LengthFieldType lft = u == Option::V4 ?
OpaqueDataTuple::LENGTH_1_BYTE : OpaqueDataTuple::LENGTH_2_BYTES;
OptionDataTypeUtil::writeTuple(value, lft, buf);
return;
}
default:
// We hit this point because invalid option data type has been specified
// This may be the case because 'empty' or 'record' data type has been
// specified. We don't throw exception here because it will be thrown
// at the exit point from this function.
;
}
isc_throw(isc::BadValue, "attempt to write invalid option data field type"
" into the option buffer: " << type);
}
OptionPtr
OptionDefinition::factoryAddrList4(uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
boost::shared_ptr<Option4AddrLst> option(new Option4AddrLst(type, begin,
end));
return (option);
}
OptionPtr
OptionDefinition::factoryAddrList6(uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
boost::shared_ptr<Option6AddrLst> option(new Option6AddrLst(type, begin,
end));
return (option);
}
OptionPtr
OptionDefinition::factoryEmpty(Option::Universe u, uint16_t type) {
OptionPtr option(new Option(u, type));
return (option);
}
OptionPtr
OptionDefinition::factoryGeneric(Option::Universe u, uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
OptionPtr option(new Option(u, type, begin, end));
return (option);
}
OptionPtr
OptionDefinition::factoryIA6(uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
if (std::distance(begin, end) < Option6IA::OPTION6_IA_LEN) {
isc_throw(isc::OutOfRange, "input option buffer has invalid size,"
<< " expected at least " << Option6IA::OPTION6_IA_LEN
<< " bytes");
}
boost::shared_ptr<Option6IA> option(new Option6IA(type, begin, end));
return (option);
}
OptionPtr
OptionDefinition::factoryIAAddr6(uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
if (std::distance(begin, end) < Option6IAAddr::OPTION6_IAADDR_LEN) {
isc_throw(isc::OutOfRange,
"input option buffer has invalid size, expected at least "
<< Option6IAAddr::OPTION6_IAADDR_LEN << " bytes");
}
boost::shared_ptr<Option6IAAddr> option(new Option6IAAddr(type, begin,
end));
return (option);
}
OptionPtr
OptionDefinition::factoryIAPrefix6(uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
if (std::distance(begin, end) < Option6IAPrefix::OPTION6_IAPREFIX_LEN) {
isc_throw(isc::OutOfRange,
"input option buffer has invalid size, expected at least "
<< Option6IAPrefix::OPTION6_IAPREFIX_LEN << " bytes");
}
boost::shared_ptr<Option6IAPrefix> option(new Option6IAPrefix(type, begin,
end));
return (option);
}
OptionPtr
OptionDefinition::factoryOpaqueDataTuples(Option::Universe u,
uint16_t type,
OptionBufferConstIter begin,
OptionBufferConstIter end) {
boost::shared_ptr<OptionOpaqueDataTuples>
option(new OptionOpaqueDataTuples(u, type, begin, end));
return (option);
}
OptionPtr
OptionDefinition::factoryFqdnList(Option::Universe u,
OptionBufferConstIter begin,
OptionBufferConstIter end) const {
const std::vector<uint8_t> data(begin, end);
if (data.empty()) {
isc_throw(InvalidOptionValue, "FQDN list option has invalid length of 0");
}
InputBuffer in_buf(static_cast<const void*>(&data[0]), data.size());
std::vector<uint8_t> out_buf;
out_buf.reserve(data.size());
while (in_buf.getPosition() < in_buf.getLength()) {
// Reuse readFqdn and writeFqdn code but on the whole buffer
// so the DNS name code handles compression for us.
try {
isc::dns::Name name(in_buf);
isc::dns::LabelSequence labels(name);
if (labels.getDataLength() > 0) {
size_t read_len = 0;
const uint8_t* label = labels.getData(&read_len);
out_buf.insert(out_buf.end(), label, label + read_len);
}
} catch (const isc::Exception& ex) {
isc_throw(InvalidOptionValue, ex.what());
}
}
return OptionPtr(new OptionCustom(*this, u,
out_buf.begin(), out_buf.end()));
}
OptionPtr
OptionDefinition::factorySpecialFormatOption(Option::Universe u,
OptionBufferConstIter begin,
OptionBufferConstIter end) const {
if ((u == Option::V6) && haveSpace(DHCP6_OPTION_SPACE)) {
switch (getCode()) {
case D6O_IA_NA:
case D6O_IA_PD:
// Record of 3 uint32, no array.
return (factoryIA6(getCode(), begin, end));
case D6O_IAADDR:
// Record of an IPv6 address followed by 2 uint32, no array.
return (factoryIAAddr6(getCode(), begin, end));
case D6O_IAPREFIX:
// Record of 2 uint32, one uint8 and an IPv6 address, no array.
return (factoryIAPrefix6(getCode(), begin, end));
case D6O_CLIENT_FQDN:
// Record of one uint8 and one FQDN, no array.
return (OptionPtr(new Option6ClientFqdn(begin, end)));
case D6O_VENDOR_OPTS:
// Type uint32.
// Vendor-Specific Information (option code 17).
return (OptionPtr(new OptionVendor(Option::V6, begin, end)));
case D6O_VENDOR_CLASS:
// Record of one uint32 and one string.
// Vendor Class (option code 16).
return (OptionPtr(new OptionVendorClass(Option::V6, begin, end)));
case D6O_STATUS_CODE:
// Record of one uint16 and one string.
// Status Code (option code 13).
return (OptionPtr(new Option6StatusCode(begin, end)));
case D6O_BOOTFILE_PARAM:
// Array of tuples.
// Bootfile params (option code 60).
return (factoryOpaqueDataTuples(Option::V6, getCode(), begin, end));
case D6O_PD_EXCLUDE:
// Type IPv6 prefix.
// Prefix Exclude (option code 67),
return (OptionPtr(new Option6PDExclude(begin, end)));
default:
break;
}
} else if ((u == Option::V4) && haveSpace(DHCP4_OPTION_SPACE)) {
switch (getCode()) {
case DHO_SERVICE_SCOPE:
// Record of a boolean and a string.
return (OptionPtr(new Option4SlpServiceScope(begin, end)));
case DHO_FQDN:
// Record of 3 uint8 and a FQDN, no array.
return (OptionPtr(new Option4ClientFqdn(begin, end)));
case DHO_VIVCO_SUBOPTIONS:
// Record of uint32 followed by binary.
// V-I Vendor Class (option code 124).
return (OptionPtr(new OptionVendorClass(Option::V4, begin, end)));
case DHO_VIVSO_SUBOPTIONS:
// Type uint32.
// Vendor-Specific Information (option code 125).
return (OptionPtr(new OptionVendor(Option::V4, begin, end)));
default:
break;
}
}
if ((u == Option::V4) && haveCompressedFqdnListFormat()) {
return (factoryFqdnList(Option::V4, begin, end));
}
return (OptionPtr());
}
} // end of isc::dhcp namespace
} // end of isc namespace
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