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|
// Copyright (C) 2012-2023 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/libdhcp++.h>
#include <dhcp/option_data_types.h>
#include <dhcp/option_custom.h>
#include <exceptions/isc_assert.h>
#include <util/encode/hex.h>
using namespace isc::asiolink;
namespace isc {
namespace dhcp {
OptionCustom::OptionCustom(const OptionDefinition& def,
Universe u)
: Option(u, def.getCode(), OptionBuffer()),
definition_(def) {
setEncapsulatedSpace(def.getEncapsulatedSpace());
createBuffers();
}
OptionCustom::OptionCustom(const OptionDefinition& def,
Universe u,
const OptionBuffer& data)
: Option(u, def.getCode(), data.begin(), data.end()),
definition_(def) {
setEncapsulatedSpace(def.getEncapsulatedSpace());
createBuffers(getData());
}
OptionCustom::OptionCustom(const OptionDefinition& def,
Universe u,
OptionBufferConstIter first,
OptionBufferConstIter last)
: Option(u, def.getCode(), first, last),
definition_(def) {
setEncapsulatedSpace(def.getEncapsulatedSpace());
createBuffers(getData());
}
OptionPtr
OptionCustom::clone() const {
return (cloneInternal<OptionCustom>());
}
void
OptionCustom::addArrayDataField(const IOAddress& address) {
checkArrayType();
if ((address.isV4() && definition_.getType() != OPT_IPV4_ADDRESS_TYPE) ||
(address.isV6() && definition_.getType() != OPT_IPV6_ADDRESS_TYPE)) {
isc_throw(BadDataTypeCast, "invalid address specified "
<< address << ". Expected a valid IPv"
<< (definition_.getType() == OPT_IPV4_ADDRESS_TYPE ?
"4" : "6") << " address.");
}
OptionBuffer buf;
OptionDataTypeUtil::writeAddress(address, buf);
buffers_.push_back(buf);
}
void
OptionCustom::addArrayDataField(const std::string& value) {
checkArrayType();
OpaqueDataTuple::LengthFieldType lft = OptionDataTypeUtil::getTupleLenFieldType(getUniverse());
OptionBuffer buf;
OptionDataTypeUtil::writeTuple(value, lft, buf);
buffers_.push_back(buf);
}
void
OptionCustom::addArrayDataField(const OpaqueDataTuple& value) {
checkArrayType();
OptionBuffer buf;
OptionDataTypeUtil::writeTuple(value, buf);
buffers_.push_back(buf);
}
void
OptionCustom::addArrayDataField(const bool value) {
checkArrayType();
OptionBuffer buf;
OptionDataTypeUtil::writeBool(value, buf);
buffers_.push_back(buf);
}
void
OptionCustom::addArrayDataField(const PrefixLen& prefix_len,
const asiolink::IOAddress& prefix) {
checkArrayType();
if (definition_.getType() != OPT_IPV6_PREFIX_TYPE) {
isc_throw(BadDataTypeCast, "IPv6 prefix can be specified only for"
" an option comprising an array of IPv6 prefix values");
}
OptionBuffer buf;
OptionDataTypeUtil::writePrefix(prefix_len, prefix, buf);
buffers_.push_back(buf);
}
void
OptionCustom::addArrayDataField(const PSIDLen& psid_len, const PSID& psid) {
checkArrayType();
if (definition_.getType() != OPT_PSID_TYPE) {
isc_throw(BadDataTypeCast, "PSID value can be specified onlu for"
" an option comprising an array of PSID length / value"
" tuples");
}
OptionBuffer buf;
OptionDataTypeUtil::writePsid(psid_len, psid, buf);
buffers_.push_back(buf);
}
void
OptionCustom::checkIndex(const uint32_t index) const {
if (index >= buffers_.size()) {
isc_throw(isc::OutOfRange, "specified data field index " << index
<< " is out of range.");
}
}
void
OptionCustom::createBuffer(OptionBuffer& buffer,
const OptionDataType data_type) const {
// For data types that have a fixed size we can use the
// utility function to get the buffer's size.
size_t data_size = OptionDataTypeUtil::getDataTypeLen(data_type);
// For variable data sizes the utility function returns zero.
// It is ok for string values because the default string
// is 'empty'. However for FQDN the empty value is not valid
// so we initialize it to '.'. For prefix there is a prefix
// length fixed field.
if (data_size == 0) {
if (data_type == OPT_FQDN_TYPE) {
OptionDataTypeUtil::writeFqdn(".", buffer);
} else if (data_type == OPT_IPV6_PREFIX_TYPE) {
OptionDataTypeUtil::writePrefix(PrefixLen(0),
IOAddress::IPV6_ZERO_ADDRESS(),
buffer);
}
} else {
// At this point we can resize the buffer. Note that
// for string values we are setting the empty buffer
// here.
buffer.resize(data_size);
}
}
void
OptionCustom::createBuffers() {
definition_.validate();
std::vector<OptionBuffer> buffers;
OptionDataType data_type = definition_.getType();
// This function is called when an empty data buffer has been
// passed to the constructor. In such cases values for particular
// data fields will be set using modifier functions but for now
// we need to initialize a set of buffers that are specified
// for an option by its definition. Since there is no data yet,
// we are going to fill these buffers with default values.
if (data_type == OPT_RECORD_TYPE) {
// For record types we need to iterate over all data fields
// specified in option definition and create corresponding
// buffers for each of them.
const OptionDefinition::RecordFieldsCollection fields =
definition_.getRecordFields();
for (OptionDefinition::RecordFieldsConstIter field = fields.begin();
field != fields.end(); ++field) {
OptionBuffer buf;
createBuffer(buf, *field);
// We have the buffer with default value prepared so we
// add it to the set of buffers.
buffers.push_back(buf);
}
} else if (!definition_.getArrayType() &&
data_type != OPT_EMPTY_TYPE) {
// For either 'empty' options we don't have to create any buffers
// for obvious reason. For arrays we also don't create any buffers
// yet because the set of fields that belong to the array is open
// ended so we can't allocate required buffers until we know how
// many of them are needed.
// For non-arrays we have a single value being held by the option
// so we have to allocate exactly one buffer.
OptionBuffer buf;
createBuffer(buf, data_type);
// Add a buffer that we have created and leave.
buffers.push_back(buf);
}
// The 'swap' is used here because we want to make sure that we
// don't touch buffers_ until we successfully allocate all
// buffers to be stored there.
std::swap(buffers, buffers_);
}
size_t
OptionCustom::bufferLength(const OptionDataType data_type, bool in_array,
OptionBuffer::const_iterator begin,
OptionBuffer::const_iterator end) const {
// For fixed-size data type such as boolean, integer, even
// IP address we can use the utility function to get the required
// buffer size.
size_t data_size = OptionDataTypeUtil::getDataTypeLen(data_type);
// For variable size types (e.g. string) the function above will
// return 0 so we need to do a runtime check of the length.
if (data_size == 0) {
// FQDN is a special data type as it stores variable length data
// but the data length is encoded in the buffer. The easiest way
// to obtain the length of the data is to read the FQDN. The
// utility function will return the size of the buffer on success.
if (data_type == OPT_FQDN_TYPE) {
std::string fqdn =
OptionDataTypeUtil::readFqdn(OptionBuffer(begin, end));
// The size of the buffer holding an FQDN is always
// 1 byte larger than the size of the string
// representation of this FQDN.
data_size = fqdn.size() + 1;
} else if (!definition_.getArrayType() &&
((data_type == OPT_BINARY_TYPE) ||
(data_type == OPT_STRING_TYPE))) {
// In other case we are dealing with string or binary value
// which size can't be determined. Thus we consume the
// remaining part of the buffer for it. Note that variable
// size data can be laid at the end of the option only and
// that the validate() function in OptionDefinition object
// should have checked wheter it is a case for this option.
data_size = std::distance(begin, end);
} else if (data_type == OPT_IPV6_PREFIX_TYPE) {
// The size of the IPV6 prefix type is determined as
// one byte (which is the size of the prefix in bits)
// followed by the prefix bits (right-padded with
// zeros to the nearest octet boundary)
if ((begin == end) && !in_array)
return 0;
PrefixTuple prefix =
OptionDataTypeUtil::readPrefix(OptionBuffer(begin, end));
// Data size comprises 1 byte holding a prefix length and the
// prefix length (in bytes) rounded to the nearest byte boundary.
data_size = sizeof(uint8_t) + (prefix.first.asUint8() + 7) / 8;
} else if (data_type == OPT_TUPLE_TYPE) {
OpaqueDataTuple::LengthFieldType lft =
OptionDataTypeUtil::getTupleLenFieldType(getUniverse());
std::string value =
OptionDataTypeUtil::readTuple(OptionBuffer(begin, end), lft);
data_size = value.size();
// The size of the buffer holding a tuple is always
// 1 or 2 byte larger than the size of the string
data_size += getUniverse() == Option::V4 ? 1 : 2;
} else {
// If we reached the end of buffer we assume that this option is
// truncated because there is no remaining data to initialize
// an option field.
isc_throw(OutOfRange, "option buffer truncated");
}
}
return data_size;
}
void
OptionCustom::createBuffers(const OptionBuffer& data_buf) {
// Check that the option definition is correct as we are going
// to use it to split the data_ buffer into set of sub buffers.
definition_.validate();
std::vector<OptionBuffer> buffers;
OptionBuffer::const_iterator data = data_buf.begin();
OptionDataType data_type = definition_.getType();
if (data_type == OPT_RECORD_TYPE) {
// An option comprises a record of data fields. We need to
// get types of these data fields to allocate enough space
// for each buffer.
const OptionDefinition::RecordFieldsCollection& fields =
definition_.getRecordFields();
// Go over all data fields within a record.
for (OptionDefinition::RecordFieldsConstIter field = fields.begin();
field != fields.end(); ++field) {
size_t data_size = bufferLength(*field, false,
data, data_buf.end());
// Our data field requires that there is a certain chunk of
// data left in the buffer. If not, option is truncated.
if (std::distance(data, data_buf.end()) < data_size) {
isc_throw(OutOfRange, "option buffer truncated");
}
// Store the created buffer.
buffers.push_back(OptionBuffer(data, data + data_size));
// Proceed to the next data field.
data += data_size;
}
// Get extra buffers when the last field is an array.
if (definition_.getArrayType()) {
while (data != data_buf.end()) {
// Code copied from the standard array case
size_t data_size = bufferLength(fields.back(), true,
data, data_buf.end());
isc_throw_assert(data_size > 0);
if (std::distance(data, data_buf.end()) < data_size) {
break;
}
buffers.push_back(OptionBuffer(data, data + data_size));
data += data_size;
}
}
// Unpack suboptions if any.
else if (data != data_buf.end() && !getEncapsulatedSpace().empty()) {
unpackOptions(OptionBuffer(data, data_buf.end()));
}
} else if (data_type != OPT_EMPTY_TYPE) {
// If data_type value is other than OPT_RECORD_TYPE, our option is
// empty (have no data at all) or it comprises one or more
// data fields of the same type. The type of those fields
// is held in the data_type variable so let's use it to determine
// a size of buffers.
size_t data_size = OptionDataTypeUtil::getDataTypeLen(data_type);
// The check below will fail if the input buffer is too short
// for the data size being held by this option.
// Note that data_size returned by getDataTypeLen may be zero
// if variable length data is being held by the option but
// this will not cause this check to throw exception.
if (std::distance(data, data_buf.end()) < data_size) {
isc_throw(OutOfRange, "option buffer truncated");
}
// For an array of values we are taking different path because
// we have to handle multiple buffers.
if (definition_.getArrayType()) {
while (data != data_buf.end()) {
data_size = bufferLength(data_type, true, data, data_buf.end());
// We don't perform other checks for data types that can't be
// used together with array indicator such as strings, empty field
// etc. This is because OptionDefinition::validate function should
// have checked this already. Thus data_size must be greater than
// zero.
isc_throw_assert(data_size > 0);
// Get chunks of data and store as a collection of buffers.
// Truncate any remaining part which length is not divisible by
// data_size. Note that it is ok to truncate the data if and only
// if the data buffer is long enough to keep at least one value.
// This has been checked above already.
if (std::distance(data, data_buf.end()) < data_size) {
break;
}
buffers.push_back(OptionBuffer(data, data + data_size));
data += data_size;
}
} else {
// For non-arrays the data_size can be zero because
// getDataTypeLen returns zero for variable size data types
// such as strings. Simply take whole buffer.
data_size = bufferLength(data_type, false, data, data_buf.end());
if ((data_size > 0) && (std::distance(data, data_buf.end()) >= data_size)) {
buffers.push_back(OptionBuffer(data, data + data_size));
data += data_size;
} else {
isc_throw(OutOfRange, "option buffer truncated");
}
// Unpack suboptions if any.
if (data != data_buf.end() && !getEncapsulatedSpace().empty()) {
unpackOptions(OptionBuffer(data, data_buf.end()));
}
}
} else {
// Unpack suboptions if any.
if (data != data_buf.end() && !getEncapsulatedSpace().empty()) {
unpackOptions(OptionBuffer(data, data_buf.end()));
}
}
// If everything went ok we can replace old buffer set with new ones.
std::swap(buffers_, buffers);
}
std::string
OptionCustom::dataFieldToText(const OptionDataType data_type,
const uint32_t index) const {
std::ostringstream text;
// Get the value of the data field.
switch (data_type) {
case OPT_BINARY_TYPE:
text << util::encode::encodeHex(readBinary(index));
break;
case OPT_BOOLEAN_TYPE:
text << (readBoolean(index) ? "true" : "false");
break;
case OPT_INT8_TYPE:
text << static_cast<int>(readInteger<int8_t>(index));
break;
case OPT_INT16_TYPE:
text << readInteger<int16_t>(index);
break;
case OPT_INT32_TYPE:
text << readInteger<int32_t>(index);
break;
case OPT_UINT8_TYPE:
text << static_cast<unsigned>(readInteger<uint8_t>(index));
break;
case OPT_UINT16_TYPE:
text << readInteger<uint16_t>(index);
break;
case OPT_UINT32_TYPE:
text << readInteger<uint32_t>(index);
break;
case OPT_IPV4_ADDRESS_TYPE:
case OPT_IPV6_ADDRESS_TYPE:
text << readAddress(index);
break;
case OPT_FQDN_TYPE:
text << "\"" << readFqdn(index) << "\"";
break;
case OPT_TUPLE_TYPE:
text << "\"" << readTuple(index) << "\"";
break;
case OPT_STRING_TYPE:
text << "\"" << readString(index) << "\"";
break;
case OPT_PSID_TYPE:
{
PSIDTuple t = readPsid(index);
text << "len=" << t.first.asUnsigned() << ",psid=" << t.second.asUint16();
}
default:
;
}
// Append data field type in brackets.
text << " (" << OptionDataTypeUtil::getDataTypeName(data_type) << ")";
return (text.str());
}
void
OptionCustom::pack(isc::util::OutputBuffer& buf, bool check) const {
// Pack DHCP header (V4 or V6).
packHeader(buf, check);
// Write data from buffers.
for (std::vector<OptionBuffer>::const_iterator it = buffers_.begin();
it != buffers_.end(); ++it) {
// In theory the createBuffers function should have taken
// care that there are no empty buffers added to the
// collection but it is almost always good to make sure.
if (!it->empty()) {
buf.writeData(&(*it)[0], it->size());
}
}
// Write suboptions.
packOptions(buf, check);
}
IOAddress
OptionCustom::readAddress(const uint32_t index) const {
checkIndex(index);
// The address being read can be either IPv4 or IPv6. The decision
// is made based on the buffer length. If it holds 4 bytes it is IPv4
// address, if it holds 16 bytes it is IPv6.
if (buffers_[index].size() == asiolink::V4ADDRESS_LEN) {
return (OptionDataTypeUtil::readAddress(buffers_[index], AF_INET));
} else if (buffers_[index].size() == asiolink::V6ADDRESS_LEN) {
return (OptionDataTypeUtil::readAddress(buffers_[index], AF_INET6));
} else {
isc_throw(BadDataTypeCast, "unable to read data from the buffer as"
<< " IP address. Invalid buffer length "
<< buffers_[index].size() << ".");
}
}
void
OptionCustom::writeAddress(const IOAddress& address,
const uint32_t index) {
checkIndex(index);
if ((address.isV4() && buffers_[index].size() != V4ADDRESS_LEN) ||
(address.isV6() && buffers_[index].size() != V6ADDRESS_LEN)) {
isc_throw(BadDataTypeCast, "invalid address specified "
<< address << ". Expected a valid IPv"
<< (buffers_[index].size() == V4ADDRESS_LEN ? "4" : "6")
<< " address.");
}
OptionBuffer buf;
OptionDataTypeUtil::writeAddress(address, buf);
std::swap(buf, buffers_[index]);
}
const OptionBuffer&
OptionCustom::readBinary(const uint32_t index) const {
checkIndex(index);
return (buffers_[index]);
}
void
OptionCustom::writeBinary(const OptionBuffer& buf,
const uint32_t index) {
checkIndex(index);
buffers_[index] = buf;
}
std::string
OptionCustom::readTuple(const uint32_t index) const {
checkIndex(index);
OpaqueDataTuple::LengthFieldType lft = OptionDataTypeUtil::getTupleLenFieldType(getUniverse());
return (OptionDataTypeUtil::readTuple(buffers_[index], lft));
}
void
OptionCustom::readTuple(OpaqueDataTuple& tuple,
const uint32_t index) const {
checkIndex(index);
OptionDataTypeUtil::readTuple(buffers_[index], tuple);
}
void
OptionCustom::writeTuple(const std::string& value, const uint32_t index) {
checkIndex(index);
buffers_[index].clear();
OpaqueDataTuple::LengthFieldType lft = OptionDataTypeUtil::getTupleLenFieldType(getUniverse());
OptionDataTypeUtil::writeTuple(value, lft, buffers_[index]);
}
void
OptionCustom::writeTuple(const OpaqueDataTuple& value, const uint32_t index) {
checkIndex(index);
buffers_[index].clear();
OptionDataTypeUtil::writeTuple(value, buffers_[index]);
}
bool
OptionCustom::readBoolean(const uint32_t index) const {
checkIndex(index);
return (OptionDataTypeUtil::readBool(buffers_[index]));
}
void
OptionCustom::writeBoolean(const bool value, const uint32_t index) {
checkIndex(index);
buffers_[index].clear();
OptionDataTypeUtil::writeBool(value, buffers_[index]);
}
std::string
OptionCustom::readFqdn(const uint32_t index) const {
checkIndex(index);
return (OptionDataTypeUtil::readFqdn(buffers_[index]));
}
void
OptionCustom::writeFqdn(const std::string& fqdn, const uint32_t index) {
checkIndex(index);
// Create a temporary buffer where the FQDN will be written.
OptionBuffer buf;
// Try to write to the temporary buffer rather than to the
// buffers_ member directly guarantees that we don't modify
// (clear) buffers_ until we are sure that the provided FQDN
// is valid.
OptionDataTypeUtil::writeFqdn(fqdn, buf);
// If we got to this point it means that the FQDN is valid.
// We can move the contents of the temporary buffer to the
// target buffer.
std::swap(buffers_[index], buf);
}
PrefixTuple
OptionCustom::readPrefix(const uint32_t index) const {
checkIndex(index);
return (OptionDataTypeUtil::readPrefix(buffers_[index]));
}
void
OptionCustom::writePrefix(const PrefixLen& prefix_len,
const IOAddress& prefix,
const uint32_t index) {
checkIndex(index);
OptionBuffer buf;
OptionDataTypeUtil::writePrefix(prefix_len, prefix, buf);
// If there are no errors while writing PSID to a buffer, we can
// replace the current buffer with a new buffer.
std::swap(buffers_[index], buf);
}
PSIDTuple
OptionCustom::readPsid(const uint32_t index) const {
checkIndex(index);
return (OptionDataTypeUtil::readPsid(buffers_[index]));
}
void
OptionCustom::writePsid(const PSIDLen& psid_len, const PSID& psid,
const uint32_t index) {
checkIndex(index);
OptionBuffer buf;
OptionDataTypeUtil::writePsid(psid_len, psid, buf);
// If there are no errors while writing PSID to a buffer, we can
// replace the current buffer with a new buffer.
std::swap(buffers_[index], buf);
}
std::string
OptionCustom::readString(const uint32_t index) const {
checkIndex(index);
return (OptionDataTypeUtil::readString(buffers_[index]));
}
void
OptionCustom::writeString(const std::string& text, const uint32_t index) {
checkIndex(index);
// Let's clear a buffer as we want to replace the value of the
// whole buffer. If we fail to clear the buffer the data will
// be appended.
buffers_[index].clear();
// If the text value is empty we can leave because the buffer
// is already empty.
if (!text.empty()) {
OptionDataTypeUtil::writeString(text, buffers_[index]);
}
}
void
OptionCustom::unpack(OptionBufferConstIter begin,
OptionBufferConstIter end) {
initialize(begin, end);
}
uint16_t
OptionCustom::len() const {
// The length of the option is a sum of option header ...
size_t length = getHeaderLen();
// ... lengths of all buffers that hold option data ...
for (std::vector<OptionBuffer>::const_iterator buf = buffers_.begin();
buf != buffers_.end(); ++buf) {
length += buf->size();
}
// ... and lengths of all suboptions
for (OptionCollection::const_iterator it = options_.begin();
it != options_.end();
++it) {
length += (*it).second->len();
}
return (static_cast<uint16_t>(length));
}
void OptionCustom::initialize(const OptionBufferConstIter first,
const OptionBufferConstIter last) {
setData(first, last);
// Chop the data_ buffer into set of buffers that represent
// option fields data.
createBuffers(getData());
}
std::string OptionCustom::toText(int indent) const {
std::stringstream output;
output << headerToText(indent) << ":";
OptionDataType data_type = definition_.getType();
if (data_type == OPT_RECORD_TYPE) {
const OptionDefinition::RecordFieldsCollection& fields =
definition_.getRecordFields();
// For record types we iterate over fields defined in
// option definition and match the appropriate buffer
// with them.
for (OptionDefinition::RecordFieldsConstIter field = fields.begin();
field != fields.end(); ++field) {
output << " " << dataFieldToText(*field, std::distance(fields.begin(),
field));
}
// If the last record field is an array iterate on extra buffers
if (definition_.getArrayType()) {
for (unsigned int i = fields.size(); i < getDataFieldsNum(); ++i) {
output << " " << dataFieldToText(fields.back(), i);
}
}
} else {
// For non-record types we iterate over all buffers
// and print the data type set globally for an option
// definition. We take the same code path for arrays
// and non-arrays as they only differ in such a way that
// non-arrays have just single data field.
for (unsigned int i = 0; i < getDataFieldsNum(); ++i) {
output << " " << dataFieldToText(definition_.getType(), i);
}
}
// Append suboptions.
output << suboptionsToText(indent + 2);
return (output.str());
}
} // end of isc::dhcp namespace
} // end of isc namespace
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