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2450 | // Copyright (C) 2011-2024 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 <asiolink/io_address.h>
#include <dhcp/testutils/pkt_captures.h>
#include <dhcp/dhcp6.h>
#include <dhcp/option.h>
#include <dhcp/option_custom.h>
#include <dhcp/option6_ia.h>
#include <dhcp/option6_iaaddr.h>
#include <dhcp/option6_iaprefix.h>
#include <dhcp/option_int.h>
#include <dhcp/option_int_array.h>
#include <dhcp/option_string.h>
#include <dhcp/option_vendor.h>
#include <dhcp/iface_mgr.h>
#include <dhcp/pkt6.h>
#include <dhcp/hwaddr.h>
#include <dhcp/docsis3_option_defs.h>
#include <testutils/gtest_utils.h>
#include <util/range_utilities.h>
#include <boost/date_time/posix_time/posix_time.hpp><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <boost/range/adaptor/reversed.hpp><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <boost/scoped_ptr.hpp><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <boost/pointer_cast.hpp><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <util/encode/encode.h>
#include <gtest/gtest.h><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <algorithm><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <iostream><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <sstream><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <utility><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
#include <arpa/inet.h><--- Include file: not found. Please note: Cppcheck does not need standard library headers to get proper results.
using namespace std;
using namespace isc;
using namespace isc::asiolink;
using namespace isc::dhcp;
using namespace isc::dhcp::test;
using boost::scoped_ptr;
namespace {
class NakedPkt6 : public Pkt6 {
public:
/// @brief Constructor, used in replying to a message
///
/// @param msg_type type of message (SOLICIT=1, ADVERTISE=2, ...)
/// @param transid transaction-id
/// @param proto protocol (TCP or UDP)
NakedPkt6(const uint8_t msg_type, const uint32_t transid,
const DHCPv6Proto& proto = UDP)
: Pkt6(msg_type, transid, proto) {
}
/// @brief Constructor, used in message transmission
///
/// Creates new message. Transaction-id will randomized.
///
/// @param buf pointer to a buffer of received packet content
/// @param len size of buffer of received packet content
/// @param proto protocol (usually UDP, but TCP will be supported eventually)
NakedPkt6(const uint8_t* buf, const uint32_t len,
const DHCPv6Proto& proto = UDP)
: Pkt6(buf, len, proto) {
}
using Pkt::getNonCopiedOptions;
using Pkt6::getNonCopiedRelayOption;
using Pkt6::getNonCopiedRelayOptions;
using Pkt6::getNonCopiedAnyRelayOption;
using Pkt6::getNonCopiedAllRelayOptions;
};
typedef boost::shared_ptr<NakedPkt6> NakedPkt6Ptr;
class Pkt6Test : public ::testing::Test {
public:
Pkt6Test() {
}
/// @brief generates an option with given code (and length) and
/// random content
///
/// @param code option code
/// @param len data length (data will be randomized)
///
/// @return pointer to the new option
OptionPtr generateRandomOption(uint16_t code, size_t len = 10) {
OptionBuffer data(len);
util::fillRandom(data.begin(), data.end());
return OptionPtr(new Option(Option::V6, code, data));
}
/// @brief Create a wire representation of the test packet and clone it.
///
/// The purpose of this function is to create a packet to be used to
/// check that packet parsing works correctly. The unpack() function
/// requires that the data_ field of the object holds the data to be
/// parsed. This function creates an on-wire representation of the
/// packet by calling pack(). But, the pack() function stores the
/// on-wire representation into the output buffer (not the data_ field).
/// For this reason, it is not enough to return the packet on which
/// pack() is called. This function returns a clone of this packet
/// which is created using a constructor taking a buffer and buffer
/// length as an input. This constructor is normally used to parse
/// received packets. It stores the packet in a data_ field and
/// therefore unpack() can be called to parse it.
///
/// @param parent Packet from which the new packet should be created.
Pkt6Ptr packAndClone(Pkt6Ptr& parent) {
OptionPtr opt1(new Option(Option::V6, 1));
OptionPtr opt2(new Option(Option::V6, 2));
OptionPtr opt3(new Option(Option::V6, 100));
// Let's not use zero-length option type 3 as it is IA_NA
parent->addOption(opt1);
parent->addOption(opt2);
parent->addOption(opt3);
EXPECT_NO_THROW(parent->pack());
// Create second packet,based on assembled data from the first one
Pkt6Ptr clone(new Pkt6(static_cast<const uint8_t*>
(parent->getBuffer().getData()),
parent->getBuffer().getLength()));
return (clone);
}
};
TEST_F(Pkt6Test, constructor) {<--- syntax error
uint8_t data[] = { 0, 1, 2, 3, 4, 5 };
scoped_ptr<Pkt6> pkt1(new Pkt6(data, sizeof(data)));
EXPECT_EQ(6, pkt1->data_.size());
EXPECT_EQ(0, memcmp( &pkt1->data_[0], data, sizeof(data)));
}
/// @brief returns captured actual SOLICIT packet
///
/// Captured SOLICIT packet with transid=0x3d79fb and options: client-id,
/// in_na, dns-server, elapsed-time, option-request
/// This code was autogenerated (see src/bin/dhcp6/tests/iface_mgr_unittest.c),
/// but we spent some time to make is less ugly than it used to be.
///
/// @return pointer to Pkt6 that represents received SOLICIT
Pkt6Ptr capture1() {
uint8_t data[98];
data[0] = 1;
data[1] = 1; data[2] = 2; data[3] = 3; data[4] = 0;
data[5] = 1; data[6] = 0; data[7] = 14; data[8] = 0;
data[9] = 1; data[10] = 0; data[11] = 1; data[12] = 21;
data[13] = 158; data[14] = 60; data[15] = 22; data[16] = 0;
data[17] = 30; data[18] = 140; data[19] = 155; data[20] = 115;
data[21] = 73; data[22] = 0; data[23] = 3; data[24] = 0;
data[25] = 40; data[26] = 0; data[27] = 0; data[28] = 0;
data[29] = 1; data[30] = 255; data[31] = 255; data[32] = 255;
data[33] = 255; data[34] = 255; data[35] = 255; data[36] = 255;
data[37] = 255; data[38] = 0; data[39] = 5; data[40] = 0;
data[41] = 24; data[42] = 32; data[43] = 1; data[44] = 13;
data[45] = 184; data[46] = 0; data[47] = 1; data[48] = 0;
data[49] = 0; data[50] = 0; data[51] = 0; data[52] = 0;
data[53] = 0; data[54] = 0; data[55] = 0; data[56] = 18;
data[57] = 52; data[58] = 255; data[59] = 255; data[60] = 255;
data[61] = 255; data[62] = 255; data[63] = 255; data[64] = 255;
data[65] = 255; data[66] = 0; data[67] = 23; data[68] = 0;
data[69] = 16; data[70] = 32; data[71] = 1; data[72] = 13;
data[73] = 184; data[74] = 0; data[75] = 1; data[76] = 0;
data[77] = 0; data[78] = 0; data[79] = 0; data[80] = 0;
data[81] = 0; data[82] = 0; data[83] = 0; data[84] = 221;
data[85] = 221; data[86] = 0; data[87] = 8; data[88] = 0;
data[89] = 2; data[90] = 0; data[91] = 100; data[92] = 0;
data[93] = 6; data[94] = 0; data[95] = 2; data[96] = 0;
data[97] = 23;
Pkt6Ptr pkt(new Pkt6(data, sizeof(data)));
pkt->setRemotePort(546);
pkt->setRemoteAddr(IOAddress("fe80::21e:8cff:fe9b:7349"));
pkt->setLocalPort(0);
pkt->setLocalAddr(IOAddress("ff02::1:2"));
pkt->setIndex(2);
pkt->setIface("eth0");
return (pkt);
}
/// @brief creates doubly relayed solicit message
///
/// This is a traffic capture exported from wireshark. It includes a SOLICIT
/// message that passed through two relays. Each relay include interface-id,
/// remote-id and relay-forw encapsulation. It is especially interesting,
/// because of the following properties:
/// - double encapsulation
/// - first relay inserts relay-msg before extra options
/// - second relay inserts relay-msg after extra options
/// - both relays are from different vendors
/// - interface-id are different for each relay
/// - first relay inserts valid remote-id
/// - second relay inserts remote-id with empty vendor data
/// - the solicit message requests for custom options in ORO
/// - there are option types in RELAY-FORW that do not appear in SOLICIT
/// - there are option types in SOLICT that do not appear in RELAY-FORW
///
/// RELAY-FORW
/// - relay message option
/// - RELAY-FORW
/// - interface-id option
/// - remote-id option
/// - RELAY-FORW
/// SOLICIT
/// - client-id option
/// - ia_na option
/// - elapsed time
/// - ORO
/// - interface-id option
/// - remote-id option
///
/// The original capture was posted to dibbler users mailing list.
///
/// @return created double relayed SOLICIT message
Pkt6Ptr capture2() {
// string exported from Wireshark
string hex_string =
"0c01200108880db800010000000000000000fe80000000000000020021fffe5c"
"18a90009007d0c0000000000000000000000000000000000fe80000000000000"
"020021fffe5c18a9001200154953414d3134342065746820312f312f30352f30"
"310025000400000de900090036016b4fe20001000e0001000118b03341000021"
"5c18a90003000c00000001ffffffffffffffff00080002000000060006001700"
"f200f30012001c4953414d3134347c3239397c697076367c6e743a76703a313a"
"313130002500120000197f0001000118b033410000215c18a9";
std::vector<uint8_t> bin;
// Decode the hex string and store it in bin (which happens
// to be OptionBuffer format)
isc::util::encode::decodeHex(hex_string, bin);
NakedPkt6Ptr pkt(new NakedPkt6(&bin[0], bin.size()));
pkt->setRemotePort(547);
pkt->setRemoteAddr(IOAddress("fe80::1234"));
pkt->setLocalPort(547);
pkt->setLocalAddr(IOAddress("ff05::1:3"));
pkt->setIndex(2);
pkt->setIface("eth0");
return (boost::dynamic_pointer_cast<Pkt6>(pkt));
}
TEST_F(Pkt6Test, unpack_solicit1) {
Pkt6Ptr sol(capture1());
ASSERT_NO_THROW(sol->unpack());
// Check for length
EXPECT_EQ(98, sol->len() );
// Check for type
EXPECT_EQ(DHCPV6_SOLICIT, sol->getType() );
// Check that all present options are returned
EXPECT_TRUE(sol->getOption(D6O_CLIENTID)); // client-id is present
EXPECT_TRUE(sol->getOption(D6O_IA_NA)); // IA_NA is present
EXPECT_TRUE(sol->getOption(D6O_ELAPSED_TIME)); // elapsed is present
EXPECT_TRUE(sol->getOption(D6O_NAME_SERVERS));
EXPECT_TRUE(sol->getOption(D6O_ORO));
// Let's check that non-present options are not returned
EXPECT_FALSE(sol->getOption(D6O_SERVERID)); // server-id is missing
EXPECT_FALSE(sol->getOption(D6O_IA_TA));
EXPECT_FALSE(sol->getOption(D6O_IAADDR));
}
TEST_F(Pkt6Test, packUnpack) {
// Create an on-wire representation of the test packet and clone it.
Pkt6Ptr pkt(new Pkt6(DHCPV6_SOLICIT, 0x020304));
Pkt6Ptr clone = packAndClone(pkt);
// Now recreate options list
ASSERT_NO_THROW(clone->unpack());
// transid, message-type should be the same as before
EXPECT_EQ(0x020304, clone->getTransid());
EXPECT_EQ(DHCPV6_SOLICIT, clone->getType());
EXPECT_TRUE(clone->getOption(1));
EXPECT_TRUE(clone->getOption(2));
EXPECT_TRUE(clone->getOption(100));
EXPECT_FALSE(clone->getOption(4));
}
// Checks if the code is able to handle malformed packet
TEST_F(Pkt6Test, unpackMalformed) {
// Get a packet. We're really interested in its on-wire
// representation only.
Pkt6Ptr donor(capture1());
// That's our original content. It should be sane.
OptionBuffer orig = donor->data_;
Pkt6Ptr success(new Pkt6(&orig[0], orig.size()));
EXPECT_NO_THROW(success->unpack());
// Insert trailing garbage.
OptionBuffer malform1 = orig;
malform1.push_back(123);
// Let's check a truncated packet. Moderately sane DHCPv6 packet should at
// least have four bytes header. Zero bytes is definitely not a valid one.
OptionBuffer empty(1); // Let's allocate one byte, so we won't be
// dereferencing an empty buffer.
Pkt6Ptr empty_pkt(new Pkt6(&empty[0], 0));
EXPECT_THROW(empty_pkt->unpack(), isc::BadValue);
// Neither is 3 bytes long.
OptionBuffer shorty;
shorty.push_back(DHCPV6_SOLICIT);
shorty.push_back(1);
shorty.push_back(2);
Pkt6Ptr too_short_pkt(new Pkt6(&shorty[0], shorty.size()));
EXPECT_THROW(too_short_pkt->unpack(), isc::BadValue);
// The code should complain about remaining bytes that can't be parsed
// but doesn't do so yet.
Pkt6Ptr trailing_garbage(new Pkt6(&malform1[0], malform1.size()));
EXPECT_NO_THROW(trailing_garbage->unpack());
// A strict approach would assume the code will reject the whole packet,
// but we decided to follow Jon Postel's law and be silent about
// received malformed or truncated options.
// Add an option that is truncated
OptionBuffer malform2 = orig;
malform2.push_back(0);
malform2.push_back(123); // 0, 123 - option code = 123
malform2.push_back(0);
malform2.push_back(1); // 0, 1 - option length = 1
// Option content would go here, but it's missing
Pkt6Ptr trunc_option(new Pkt6(&malform2[0], malform2.size()));
// The unpack() operation should succeed...
EXPECT_NO_THROW(trunc_option->unpack());
// ... but there should be no option 123 as it was malformed.
EXPECT_FALSE(trunc_option->getOption(123));
// Check with truncated length field
Pkt6Ptr trunc_length(new Pkt6(&malform2[0], malform2.size() - 1));
EXPECT_NO_THROW(trunc_length->unpack());
EXPECT_FALSE(trunc_length->getOption(123));
// Check with missing length field
Pkt6Ptr no_length(new Pkt6(&malform2[0], malform2.size() - 2));
EXPECT_NO_THROW(no_length->unpack());
EXPECT_FALSE(no_length->getOption(123));
// Check with truncated type field
Pkt6Ptr trunc_type(new Pkt6(&malform2[0], malform2.size() - 3));
EXPECT_NO_THROW(trunc_type->unpack());
EXPECT_FALSE(trunc_type->getOption(123));
}
// Checks if the code is able to handle a malformed vendor option
TEST_F(Pkt6Test, unpackVendorMalformed) {
// Get a packet. We're really interested in its on-wire
// representation only.
Pkt6Ptr donor(capture1());
// Add a vendor option
OptionBuffer orig = donor->data_;
orig.push_back(0); // vendor options
orig.push_back(17);
orig.push_back(0);
size_t len_index = orig.size();
orig.push_back(18); // length=18
orig.push_back(1); // vendor_id=0x1020304
orig.push_back(2);
orig.push_back(3);
orig.push_back(4);
orig.push_back(1); // suboption type=0x101
orig.push_back(1);
orig.push_back(0); // suboption length=3
orig.push_back(3);
orig.push_back(102); // data="foo"
orig.push_back(111);
orig.push_back(111);
orig.push_back(1); // suboption type=0x102
orig.push_back(2);
orig.push_back(0); // suboption length=3
orig.push_back(3);
orig.push_back(99); // data="bar'
orig.push_back(98);
orig.push_back(114);
Pkt6Ptr success(new Pkt6(&orig[0], orig.size()));
EXPECT_NO_THROW(success->unpack());
// Truncated vendor option is not accepted but doesn't throw
vector<uint8_t> shortv = orig;
shortv[len_index] = 20;
Pkt6Ptr too_short_vendor_pkt(new Pkt6(&shortv[0], shortv.size()));
EXPECT_NO_THROW(too_short_vendor_pkt->unpack());
// Truncated option header is not accepted
vector<uint8_t> shorth = orig;
shorth.resize(orig.size() - 4);
shorth[len_index] = 12;
Pkt6Ptr too_short_header_pkt(new Pkt6(&shorth[0], shorth.size()));
EXPECT_THROW(too_short_header_pkt->unpack(), SkipRemainingOptionsError);
// Truncated option data is not accepted
vector<uint8_t> shorto = orig;
shorto.resize(orig.size() - 2);
shorto[len_index] = 16;
Pkt6Ptr too_short_option_pkt(new Pkt6(&shorto[0], shorto.size()));
EXPECT_THROW(too_short_option_pkt->unpack(), SkipRemainingOptionsError);
}
// This test verifies that options can be added (addOption()), retrieved
// (getOption(), getOptions()) and deleted (delOption()).
TEST_F(Pkt6Test, addGetDelOptions) {
scoped_ptr<Pkt6> parent(new Pkt6(DHCPV6_SOLICIT, random()));
OptionPtr opt1(new Option(Option::V6, 1));
OptionPtr opt2(new Option(Option::V6, 2));
OptionPtr opt3(new Option(Option::V6, 2));
parent->addOption(opt1);
parent->addOption(opt2);
// getOption() test
EXPECT_EQ(opt1, parent->getOption(1));
EXPECT_EQ(opt2, parent->getOption(2));
// Expect NULL
EXPECT_EQ(OptionPtr(), parent->getOption(4));
// Now there are 2 options of type 2
parent->addOption(opt3);
OptionCollection options = parent->getOptions(2);
EXPECT_EQ(2, options.size()); // there should be 2 instances
// Both options must be of type 2 and there must not be
// any other type returned
for (auto const& x : options) {
EXPECT_EQ(2, x.second->getType());
}
// Try to get a single option. Normally for singular options
// it is better to use getOption(), but getOptions() must work
// as well
options = parent->getOptions(1);
ASSERT_EQ(1, options.size());
EXPECT_EQ(1, (*options.begin()).second->getType());
EXPECT_EQ(opt1, options.begin()->second);
// Let's delete one of them
EXPECT_EQ(true, parent->delOption(2));
// There still should be the other option 2
EXPECT_NE(OptionPtr(), parent->getOption(2));
// Let's delete the other option 2
EXPECT_EQ(true, parent->delOption(2));
// No more options with type=2
EXPECT_EQ(OptionPtr(), parent->getOption(2));
// Let's try to delete - should fail
EXPECT_TRUE(false == parent->delOption(2));
// Finally try to get a non-existent option
options = parent->getOptions(1234);
EXPECT_EQ(0, options.size());
}
// Check that multiple options of the same type may be retrieved by using
// getOptions or getNonCopiedOptions. In the former case, also check
// that retrieved options are copied when setCopyRetrievedOptions is
// enabled.
TEST_F(Pkt6Test, getOptions) {
NakedPkt6 pkt(DHCPV6_SOLICIT, 1234);
OptionPtr opt1(new Option(Option::V6, 1));
OptionPtr opt2(new Option(Option::V6, 1));
OptionPtr opt3(new Option(Option::V6, 2));
OptionPtr opt4(new Option(Option::V6, 2));
pkt.addOption(opt1);
pkt.addOption(opt2);
pkt.addOption(opt3);
pkt.addOption(opt4);
// Retrieve options with option code 1.
OptionCollection options = pkt.getOptions(1);
ASSERT_EQ(2, options.size());
OptionCollection::const_iterator opt_it;
// Make sure that the first option is returned. We're using the pointer
// to opt1 to find the option.
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(1, opt1));
EXPECT_TRUE(opt_it != options.end());
// Make sure that the second option is returned.
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(1, opt2));
EXPECT_TRUE(opt_it != options.end());
// Retrieve options with option code 2.
options = pkt.getOptions(2);
// opt3 and opt4 should exist.
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(2, opt3));
EXPECT_TRUE(opt_it != options.end());
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(2, opt4));
EXPECT_TRUE(opt_it != options.end());
// Enable copying options when they are retrieved.
pkt.setCopyRetrievedOptions(true);
options = pkt.getOptions(1);
ASSERT_EQ(2, options.size());
// Both retrieved options should be copied so an attempt to find them
// using option pointer should fail. Original pointers should have
// been replaced with new instances.
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(1, opt1));
EXPECT_TRUE(opt_it == options.end());
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(1, opt2));
EXPECT_TRUE(opt_it == options.end());
// Return instances of options with the option code 1 and make sure
// that copies of the options were used to replace original options
// in the packet.
OptionCollection options_modified = pkt.getNonCopiedOptions(1);
for (auto const& opt_it_modified : options_modified) {
opt_it = std::find(options.begin(), options.end(), opt_it_modified);
ASSERT_TRUE(opt_it != options.end());
}
// Let's check that remaining two options haven't been affected by
// retrieving the options with option code 1.
options = pkt.getNonCopiedOptions(2);
ASSERT_EQ(2, options.size());
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(2, opt3));
EXPECT_TRUE(opt_it != options.end());
opt_it = std::find(options.begin(), options.end(),
std::pair<const unsigned int, OptionPtr>(2, opt4));
EXPECT_TRUE(opt_it != options.end());
}
TEST_F(Pkt6Test, Timestamp) {
boost::scoped_ptr<Pkt6> pkt(new Pkt6(DHCPV6_SOLICIT, 0x020304));
// Just after construction timestamp is invalid
ASSERT_TRUE(pkt->getTimestamp().is_not_a_date_time());
// Update packet time.
pkt->updateTimestamp();
// Get updated packet time.
boost::posix_time::ptime ts_packet = pkt->getTimestamp();
// After timestamp is updated it should be date-time.
ASSERT_FALSE(ts_packet.is_not_a_date_time());
// Check current time.
boost::posix_time::ptime ts_now =
boost::posix_time::microsec_clock::universal_time();
// Calculate period between packet time and now.
boost::posix_time::time_period ts_period(ts_packet, ts_now);
// Duration should be positive or zero.
EXPECT_TRUE(ts_period.length().total_microseconds() >= 0);
}
// This test verifies that getName() method returns proper
// packet type names.
TEST_F(Pkt6Test, getName) {
// Check all possible packet types
for (unsigned itype = 0; itype < 256; ++itype) {
uint8_t type = itype;
switch (type) {
case DHCPV6_ADVERTISE:
EXPECT_STREQ("ADVERTISE", Pkt6::getName(type));
break;
case DHCPV6_CONFIRM:
EXPECT_STREQ("CONFIRM", Pkt6::getName(type));
break;
case DHCPV6_DECLINE:
EXPECT_STREQ("DECLINE", Pkt6::getName(type));
break;
case DHCPV6_DHCPV4_QUERY:
EXPECT_STREQ("DHCPV4_QUERY", Pkt6::getName(type));
break;
case DHCPV6_DHCPV4_RESPONSE:
EXPECT_STREQ("DHCPV4_RESPONSE", Pkt6::getName(type));
break;
case DHCPV6_INFORMATION_REQUEST:
EXPECT_STREQ("INFORMATION_REQUEST",
Pkt6::getName(type));
break;
case DHCPV6_LEASEQUERY:
EXPECT_STREQ("LEASEQUERY", Pkt6::getName(type));
break;
case DHCPV6_LEASEQUERY_DATA:
EXPECT_STREQ("LEASEQUERY_DATA", Pkt6::getName(type));
break;
case DHCPV6_LEASEQUERY_DONE:
EXPECT_STREQ("LEASEQUERY_DONE", Pkt6::getName(type));
break;
case DHCPV6_LEASEQUERY_REPLY:
EXPECT_STREQ("LEASEQUERY_REPLY", Pkt6::getName(type));
break;
case DHCPV6_REBIND:
EXPECT_STREQ("REBIND", Pkt6::getName(type));
break;
case DHCPV6_RECONFIGURE:
EXPECT_STREQ("RECONFIGURE", Pkt6::getName(type));
break;
case DHCPV6_RELAY_FORW:
EXPECT_STREQ("RELAY_FORWARD", Pkt6::getName(type));
break;
case DHCPV6_RELAY_REPL:
EXPECT_STREQ("RELAY_REPLY", Pkt6::getName(type));
break;
case DHCPV6_RELEASE:
EXPECT_STREQ("RELEASE", Pkt6::getName(type));
break;
case DHCPV6_RENEW:
EXPECT_STREQ("RENEW", Pkt6::getName(type));
break;
case DHCPV6_REPLY:
EXPECT_STREQ("REPLY", Pkt6::getName(type));
break;
case DHCPV6_REQUEST:
EXPECT_STREQ("REQUEST", Pkt6::getName(type));
break;
case DHCPV6_SOLICIT:
EXPECT_STREQ("SOLICIT", Pkt6::getName(type));
break;
default:
EXPECT_STREQ("UNKNOWN", Pkt6::getName(type));
}
}
}
// This test verifies that a fancy solicit that passed through two
// relays can be parsed properly. See capture2() method description
// for details regarding the packet.
TEST_F(Pkt6Test, relayUnpack) {
Pkt6Ptr msg(capture2());
EXPECT_NO_THROW(msg->unpack());
EXPECT_EQ(DHCPV6_SOLICIT, msg->getType());
EXPECT_EQ(217, msg->len());
ASSERT_EQ(2, msg->relay_info_.size());
OptionPtr opt;
// Part 1: Check options inserted by the first relay
// There should be 2 options in first relay
EXPECT_EQ(2, msg->relay_info_[0].options_.size());
// There should be interface-id option
EXPECT_EQ(1, msg->getRelayOptions(D6O_INTERFACE_ID, 0).size());
ASSERT_TRUE(opt = msg->getRelayOption(D6O_INTERFACE_ID, 0));
OptionBuffer data = opt->getData();
EXPECT_EQ(32, opt->len()); // 28 bytes of data + 4 bytes header
EXPECT_EQ(data.size(), 28);
// That's a strange interface-id, but this is a real life example
EXPECT_TRUE(0 == memcmp("ISAM144|299|ipv6|nt:vp:1:110", &data[0], 28));
// Get the remote-id option
EXPECT_EQ(1, msg->getRelayOptions(D6O_REMOTE_ID, 0).size());
ASSERT_TRUE(opt = msg->getRelayOption(D6O_REMOTE_ID, 0));
EXPECT_EQ(22, opt->len()); // 18 bytes of data + 4 bytes header
boost::shared_ptr<OptionCustom> custom = boost::dynamic_pointer_cast<OptionCustom>(opt);
uint32_t vendor_id = custom->readInteger<uint32_t>(0);
EXPECT_EQ(6527, vendor_id); // 6527 = Panthera Networks
uint8_t expected_remote_id[] = { 0x00, 0x01, 0x00, 0x01, 0x18, 0xb0,
0x33, 0x41, 0x00, 0x00, 0x21, 0x5c,
0x18, 0xa9 };
OptionBuffer remote_id = custom->readBinary(1);
ASSERT_EQ(sizeof(expected_remote_id), remote_id.size());
ASSERT_EQ(0, memcmp(expected_remote_id, &remote_id[0], remote_id.size()));
// Part 2: Check options inserted by the second relay
// Get the interface-id from the second relay
EXPECT_EQ(1, msg->getRelayOptions(D6O_INTERFACE_ID, 1).size());
ASSERT_TRUE(opt = msg->getRelayOption(D6O_INTERFACE_ID, 1));
data = opt->getData();
EXPECT_EQ(25, opt->len()); // 21 bytes + 4 bytes header
EXPECT_EQ(data.size(), 21);
EXPECT_TRUE(0 == memcmp("ISAM144 eth 1/1/05/01", &data[0], 21));
// Get the remote-id option
EXPECT_EQ(1, msg->getRelayOptions(D6O_REMOTE_ID, 1).size());
ASSERT_TRUE(opt = msg->getRelayOption(D6O_REMOTE_ID, 1));
EXPECT_EQ(8, opt->len());
custom = boost::dynamic_pointer_cast<OptionCustom>(opt);
vendor_id = custom->readInteger<uint32_t>(0);
EXPECT_EQ(3561, vendor_id); // 3561 = Broadband Forum
// @todo: See if we can validate empty remote-id field
// Let's check if there is no leak between options stored in
// the SOLICIT message and the relay.
EXPECT_TRUE(msg->getRelayOptions(D6O_IA_NA, 1).empty());
EXPECT_FALSE(opt = msg->getRelayOption(D6O_IA_NA, 1));
// Part 3: Let's check options in the message itself
// This is not redundant compared to other direct messages tests,
// as we parsed it differently
EXPECT_EQ(DHCPV6_SOLICIT, msg->getType());
EXPECT_EQ(0x6b4fe2, msg->getTransid());
ASSERT_TRUE(opt = msg->getOption(D6O_CLIENTID));
EXPECT_EQ(18, opt->len()); // 14 bytes of data + 4 bytes of header
uint8_t expected_client_id[] = { 0x00, 0x01, 0x00, 0x01, 0x18, 0xb0,
0x33, 0x41, 0x00, 0x00, 0x21, 0x5c,
0x18, 0xa9 };
data = opt->getData();
ASSERT_EQ(data.size(), sizeof(expected_client_id));
ASSERT_EQ(0, memcmp(&data[0], expected_client_id, data.size()));
ASSERT_TRUE(opt = msg->getOption(D6O_IA_NA));
boost::shared_ptr<Option6IA> ia =
boost::dynamic_pointer_cast<Option6IA>(opt);
ASSERT_TRUE(ia);
EXPECT_EQ(1, ia->getIAID());
EXPECT_EQ(0xffffffff, ia->getT1());
EXPECT_EQ(0xffffffff, ia->getT2());
ASSERT_TRUE(opt = msg->getOption(D6O_ELAPSED_TIME));
EXPECT_EQ(6, opt->len()); // 2 bytes of data + 4 bytes of header
boost::shared_ptr<OptionInt<uint16_t> > elapsed =
boost::dynamic_pointer_cast<OptionInt<uint16_t> > (opt);
ASSERT_TRUE(elapsed);
EXPECT_EQ(0, elapsed->getValue());
ASSERT_TRUE(opt = msg->getOption(D6O_ORO));
boost::shared_ptr<OptionIntArray<uint16_t> > oro =
boost::dynamic_pointer_cast<OptionIntArray<uint16_t> > (opt);
const std::vector<uint16_t> oro_list = oro->getValues();
EXPECT_EQ(3, oro_list.size());
EXPECT_EQ(23, oro_list[0]);
EXPECT_EQ(242, oro_list[1]);
EXPECT_EQ(243, oro_list[2]);
}
// This test verified that message with relay information can be
// packed and then unpacked.
TEST_F(Pkt6Test, relayPack) {
scoped_ptr<Pkt6> parent(new Pkt6(DHCPV6_ADVERTISE, 0x020304));
Pkt6::RelayInfo relay1;
relay1.msg_type_ = DHCPV6_RELAY_REPL;
relay1.hop_count_ = 17; // not very meaningful, but useful for testing
relay1.linkaddr_ = IOAddress("2001:db8::1");
relay1.peeraddr_ = IOAddress("fe80::abcd");
uint8_t relay_opt_data[] = { 1, 2, 3, 4, 5, 6, 7, 8};
vector<uint8_t> relay_data(relay_opt_data,
relay_opt_data + sizeof(relay_opt_data));
OptionPtr optRelay1(new Option(Option::V6, 200, relay_data));
relay1.options_.insert(make_pair(optRelay1->getType(), optRelay1));
OptionPtr opt1(new Option(Option::V6, 100));
OptionPtr opt2(new Option(Option::V6, 101));
OptionPtr opt3(new Option(Option::V6, 102));
// Let's not use zero-length option type 3 as it is IA_NA
parent->addRelayInfo(relay1);
parent->addOption(opt1);
parent->addOption(opt2);
parent->addOption(opt3);
EXPECT_EQ(DHCPV6_ADVERTISE, parent->getType());
EXPECT_NO_THROW(parent->pack());
EXPECT_EQ(Pkt6::DHCPV6_PKT_HDR_LEN
+ 3 * Option::OPTION6_HDR_LEN // ADVERTISE
+ Pkt6::DHCPV6_RELAY_HDR_LEN // Relay header
+ Option::OPTION6_HDR_LEN // Relay-msg
+ optRelay1->len(),
parent->len());
// Create second packet,based on assembled data from the first one
scoped_ptr<Pkt6> clone(new Pkt6(static_cast<const uint8_t*>(
parent->getBuffer().getData()),
parent->getBuffer().getLength()));
// Now recreate options list
EXPECT_NO_THROW( clone->unpack() );
// transid, message-type should be the same as before
EXPECT_EQ(parent->getTransid(), parent->getTransid());
EXPECT_EQ(DHCPV6_ADVERTISE, clone->getType());
EXPECT_TRUE( clone->getOption(100));
EXPECT_TRUE( clone->getOption(101));
EXPECT_TRUE( clone->getOption(102));
EXPECT_FALSE(clone->getOption(103));
// Now check relay info
ASSERT_EQ(1, clone->relay_info_.size());
EXPECT_EQ(DHCPV6_RELAY_REPL, clone->relay_info_[0].msg_type_);
EXPECT_EQ(17, clone->relay_info_[0].hop_count_);
EXPECT_EQ("2001:db8::1", clone->relay_info_[0].linkaddr_.toText());
EXPECT_EQ("fe80::abcd", clone->relay_info_[0].peeraddr_.toText());
// There should be exactly one option
EXPECT_EQ(1, clone->relay_info_[0].options_.size());
EXPECT_EQ(1, clone->getRelayOptions(200, 0).size());
OptionPtr opt = clone->getRelayOption(200, 0);
EXPECT_TRUE(opt);
EXPECT_EQ(opt->getType() , optRelay1->getType());
EXPECT_EQ(opt->len(), optRelay1->len());
OptionBuffer data = opt->getData();
ASSERT_EQ(data.size(), sizeof(relay_opt_data));
EXPECT_EQ(0, memcmp(&data[0], relay_opt_data, sizeof(relay_opt_data)));
// As we have a nicely built relay packet we can check
// that the functions to get the peer and link addresses work
EXPECT_EQ("2001:db8::1", clone->getRelay6LinkAddress(0).toText());
EXPECT_EQ("fe80::abcd", clone->getRelay6PeerAddress(0).toText());
vector<uint8_t>binary = clone->getRelay6LinkAddress(0).toBytes();
uint8_t expected0[] = {0x20, 1, 0x0d, 0xb8, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 1};
EXPECT_EQ(0, memcmp(expected0, &binary[0], 16));
}
TEST_F(Pkt6Test, getRelayOption) {
NakedPkt6Ptr msg(boost::dynamic_pointer_cast<NakedPkt6>(capture2()));
ASSERT_TRUE(msg);
ASSERT_NO_THROW(msg->unpack());
ASSERT_EQ(2, msg->relay_info_.size());
OptionPtr opt_iface_id = msg->getNonCopiedRelayOption(D6O_INTERFACE_ID, 0);
ASSERT_TRUE(opt_iface_id);
OptionPtr opt_iface_id_returned = msg->getRelayOption(D6O_INTERFACE_ID, 0);
ASSERT_TRUE(opt_iface_id_returned);
EXPECT_TRUE(opt_iface_id == opt_iface_id_returned);
msg->setCopyRetrievedOptions(true);
opt_iface_id_returned = msg->getRelayOption(D6O_INTERFACE_ID, 0);
EXPECT_FALSE(opt_iface_id == opt_iface_id_returned);
opt_iface_id = msg->getNonCopiedRelayOption(D6O_INTERFACE_ID, 0);
EXPECT_TRUE(opt_iface_id == opt_iface_id_returned);
}
TEST_F(Pkt6Test, getRelayOptions) {
NakedPkt6Ptr msg(boost::dynamic_pointer_cast<NakedPkt6>(capture2()));
ASSERT_TRUE(msg);
ASSERT_NO_THROW(msg->unpack());
ASSERT_EQ(2, msg->relay_info_.size());
OptionCollection opts_iface_id =
msg->getNonCopiedRelayOptions(D6O_INTERFACE_ID, 0);
ASSERT_EQ(1, opts_iface_id.size());
OptionPtr opt_iface_id = msg->getNonCopiedRelayOption(D6O_INTERFACE_ID, 0);
ASSERT_TRUE(opt_iface_id);
OptionCollection opts_iface_id_returned =
msg->getRelayOptions(D6O_INTERFACE_ID, 0);
ASSERT_EQ(1, opts_iface_id_returned.size());
OptionPtr opt_iface_id_returned = msg->getRelayOption(D6O_INTERFACE_ID, 0);
ASSERT_TRUE(opt_iface_id_returned);
EXPECT_TRUE(opt_iface_id == opt_iface_id_returned);
EXPECT_TRUE(opts_iface_id == opts_iface_id_returned);
EXPECT_TRUE(opts_iface_id.begin()->second == opt_iface_id);
EXPECT_TRUE(opts_iface_id_returned.begin()->second == opt_iface_id_returned);
msg->setCopyRetrievedOptions(true);
opts_iface_id_returned = msg->getRelayOptions(D6O_INTERFACE_ID, 0);
ASSERT_EQ(1, opts_iface_id_returned.size());
opt_iface_id_returned = msg->getRelayOption(D6O_INTERFACE_ID, 0);
EXPECT_FALSE(opt_iface_id == opt_iface_id_returned);
EXPECT_FALSE(opts_iface_id.begin()->second == opt_iface_id_returned);
EXPECT_FALSE(opts_iface_id_returned.begin()->second == opt_iface_id);
EXPECT_FALSE(opts_iface_id_returned.begin()->second == opt_iface_id_returned);
opt_iface_id = msg->getNonCopiedRelayOption(D6O_INTERFACE_ID, 0);
EXPECT_TRUE(opt_iface_id == opt_iface_id_returned);
opts_iface_id_returned = msg->getNonCopiedRelayOptions(D6O_INTERFACE_ID, 0);
opts_iface_id = msg->getNonCopiedRelayOptions(D6O_INTERFACE_ID, 0);
EXPECT_TRUE(opts_iface_id == opts_iface_id_returned);
}
// This test verifies that options added by relays to the message can be
// accessed and retrieved properly
TEST_F(Pkt6Test, getAnyRelayOption) {
boost::scoped_ptr<NakedPkt6> msg(new NakedPkt6(DHCPV6_ADVERTISE, 0x020304));
msg->addOption(generateRandomOption(300));
// generate options for relay1
Pkt6::RelayInfo relay1;
// generate 3 options with code 200,201,202 and random content
OptionPtr relay1_opt1(generateRandomOption(200));
OptionPtr relay1_opt2(generateRandomOption(201));
OptionPtr relay1_opt3(generateRandomOption(202));
relay1.options_.insert(make_pair(200, relay1_opt1));
relay1.options_.insert(make_pair(201, relay1_opt2));
relay1.options_.insert(make_pair(202, relay1_opt3));
msg->addRelayInfo(relay1);
// generate options for relay2
Pkt6::RelayInfo relay2;
OptionPtr relay2_opt1(new Option(Option::V6, 100));
OptionPtr relay2_opt2(new Option(Option::V6, 101));
OptionPtr relay2_opt3(new Option(Option::V6, 102));
OptionPtr relay2_opt4(new Option(Option::V6, 200));
// the same code as relay1_opt3
relay2.options_.insert(make_pair(100, relay2_opt1));
relay2.options_.insert(make_pair(101, relay2_opt2));
relay2.options_.insert(make_pair(102, relay2_opt3));
relay2.options_.insert(make_pair(200, relay2_opt4));
msg->addRelayInfo(relay2);
// generate options for relay3
Pkt6::RelayInfo relay3;
OptionPtr relay3_opt1(generateRandomOption(200, 7));
relay3.options_.insert(make_pair(200, relay3_opt1));
msg->addRelayInfo(relay3);
// Ok, so we now have a packet that traversed the following network:
// client---relay3---relay2---relay1---server
// First check that the getAnyRelayOption does not confuse client options
// and relay options
// 300 is a client option, present in the message itself.
OptionPtr opt =
msg->getAnyRelayOption(300, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_FALSE(opt);
opt = msg->getAnyRelayOption(300, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_FALSE(opt);
opt = msg->getAnyRelayOption(300, Pkt6::RELAY_GET_FIRST);
EXPECT_FALSE(opt);
opt = msg->getAnyRelayOption(300, Pkt6::RELAY_GET_LAST);
EXPECT_FALSE(opt);
EXPECT_TRUE(msg->getAllRelayOptions(300, Pkt6::RELAY_SEARCH_FROM_CLIENT).empty());
EXPECT_TRUE(msg->getAllRelayOptions(300, Pkt6::RELAY_SEARCH_FROM_SERVER).empty());
EXPECT_TRUE(msg->getAllRelayOptions(300, Pkt6::RELAY_GET_FIRST).empty());
EXPECT_TRUE(msg->getAllRelayOptions(300, Pkt6::RELAY_GET_LAST).empty());
// Option 200 is added in every relay.
// We want to get that one inserted by relay3 (first match, starting from
// closest to the client.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay3_opt1));
EXPECT_TRUE(opt == relay3_opt1);
// Check collections.
OptionCollection opts0 =
msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_EQ(3, opts0.size());
vector<OptionPtr> lopts0;
for (auto const& it : opts0) {
lopts0.push_back(it.second);
}
ASSERT_EQ(3, lopts0.size());
EXPECT_TRUE(lopts0[0] == opt);
EXPECT_TRUE(lopts0[0] == relay3_opt1);
EXPECT_TRUE(lopts0[1] == relay2_opt4);
EXPECT_TRUE(lopts0[2] == relay1_opt1);
OptionCollection opts =
msg->getAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_TRUE(opts == opts0);
// We want to get that one inserted by relay1 (first match, starting from
// closest to the server.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay1_opt1));
EXPECT_TRUE(opt == relay1_opt1);
// Check collections.
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_EQ(3, opts.size());
vector<OptionPtr> lopts;
for (auto const& it : opts) {
lopts.push_back(it.second);
}
ASSERT_EQ(3, lopts.size());
EXPECT_TRUE(lopts[0] == opt);
EXPECT_TRUE(lopts[0] == relay1_opt1);
EXPECT_TRUE(lopts[1] == relay2_opt4);
EXPECT_TRUE(lopts[2] == relay3_opt1);
EXPECT_TRUE(opts == msg->getAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_SERVER));
// Check reverse order.
vector<OptionPtr> ropts;
for (auto const& it : boost::adaptors::reverse(opts)) {
ropts.push_back(it.second);
}
EXPECT_TRUE(lopts0 == ropts);
// We just want option from the first relay (closest to the client)
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_GET_FIRST);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay3_opt1));
EXPECT_TRUE(opt == relay3_opt1);
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_GET_FIRST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opt == opts.begin()->second);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_GET_FIRST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opts.begin()->second == relay3_opt1);
// We just want option from the last relay (closest to the server)
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_GET_LAST);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay1_opt1));
EXPECT_TRUE(opt == relay1_opt1);
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_GET_LAST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opt == opts.begin()->second);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_GET_LAST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opts.begin()->second == relay1_opt1);
// Enable copying options when they are retrieved and redo the tests
// but expect that options are still equal but different pointers
// are returned.
msg->setCopyRetrievedOptions(true);
// From client.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay3_opt1));
EXPECT_FALSE(opt == relay3_opt1);
// Test that option copy has replaced the original option within the
// packet. We achieve that by calling a variant of the method which
// retrieved non-copied option.
relay3_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
ASSERT_TRUE(relay3_opt1);
EXPECT_TRUE(opt == relay3_opt1);
// Check collections.
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
lopts0.clear();
for (auto const& it : opts) {
lopts0.push_back(it.second);
}
ASSERT_EQ(3, lopts0.size());
EXPECT_TRUE(lopts0[0] == opt);
EXPECT_TRUE(lopts0[0] == relay3_opt1);
EXPECT_TRUE(lopts0[1] == relay2_opt4);
EXPECT_TRUE(lopts0[2] == relay1_opt1);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_CLIENT);
lopts.clear();
for (auto const& it : opts) {
lopts.push_back(it.second);
}
ASSERT_EQ(3, lopts.size());
EXPECT_TRUE(relay3_opt1->equals(lopts[0]));
EXPECT_FALSE(lopts[0] == lopts0[0]);
EXPECT_TRUE(relay2_opt4->equals(lopts[1]));
EXPECT_FALSE(lopts[1] == lopts0[1]);
EXPECT_TRUE(relay1_opt1->equals(lopts[2]));
EXPECT_FALSE(lopts[2] == lopts0[2]);
// Get current values for next tests.
relay3_opt1 = lopts[0];
relay2_opt4 = lopts[1];
relay1_opt1 = lopts[2];
// From server.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay1_opt1));
EXPECT_FALSE(opt == relay1_opt1);
relay1_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
ASSERT_TRUE(relay1_opt1);
EXPECT_TRUE(opt == relay1_opt1);
// Check collections.
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
lopts0.clear();
for (auto const& it : opts) {
lopts0.push_back(it.second);
}
ASSERT_EQ(3, lopts0.size());
EXPECT_TRUE(lopts0[0] == opt);
EXPECT_TRUE(lopts0[0] == relay1_opt1);
EXPECT_TRUE(lopts0[1] == relay2_opt4);
EXPECT_TRUE(lopts0[2] == relay3_opt1);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_SEARCH_FROM_SERVER);
lopts.clear();
for (auto const& it : opts) {
lopts.push_back(it.second);
}
ASSERT_EQ(3, lopts.size());
EXPECT_TRUE(relay1_opt1->equals(lopts[0]));
EXPECT_FALSE(lopts[0] == lopts0[0]);
EXPECT_TRUE(relay2_opt4->equals(lopts[1]));
EXPECT_FALSE(lopts[1] == lopts0[1]);
EXPECT_TRUE(relay3_opt1->equals(lopts[2]));
EXPECT_FALSE(lopts[2] == lopts0[2]);
// First.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_GET_FIRST);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay3_opt1));
EXPECT_FALSE(opt == relay3_opt1);
relay3_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_GET_FIRST);
ASSERT_TRUE(relay3_opt1);
EXPECT_TRUE(opt == relay3_opt1);
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_GET_FIRST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opt == opts.begin()->second);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_GET_FIRST);
EXPECT_EQ(1, opts.size());
EXPECT_FALSE(opts.begin()->second == relay3_opt1);
relay3_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_GET_FIRST);
EXPECT_TRUE(opts.begin()->second == relay3_opt1);
// Last.
opt = msg->getAnyRelayOption(200, Pkt6::RELAY_GET_LAST);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay1_opt1));
EXPECT_FALSE(opt == relay1_opt1);
relay1_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_GET_LAST);
ASSERT_TRUE(relay1_opt1);
EXPECT_TRUE(opt == relay1_opt1);
opts = msg->getNonCopiedAllRelayOptions(200, Pkt6::RELAY_GET_LAST);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opt == opts.begin()->second);
opts = msg->getAllRelayOptions(200, Pkt6::RELAY_GET_LAST);
EXPECT_EQ(1, opts.size());
EXPECT_FALSE(opts.begin()->second == relay1_opt1);
relay1_opt1 = msg->getNonCopiedAnyRelayOption(200, Pkt6::RELAY_GET_LAST);
EXPECT_TRUE(opts.begin()->second == relay1_opt1);
// Disable copying options and continue with other tests.
msg->setCopyRetrievedOptions(false);
// Let's try to ask for something that is inserted by the middle relay
// only.
opt = msg->getAnyRelayOption(100, Pkt6::RELAY_SEARCH_FROM_SERVER);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay2_opt1));
opts = msg->getNonCopiedAllRelayOptions(100, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opts.begin()->second == relay2_opt1);
opts = msg->getAllRelayOptions(100, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(relay2_opt1->equals(opts.begin()->second));
opt = msg->getAnyRelayOption(100, Pkt6::RELAY_SEARCH_FROM_CLIENT);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(relay2_opt1));
opts = msg->getNonCopiedAllRelayOptions(100, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(opts.begin()->second == relay2_opt1);
opts = msg->getAllRelayOptions(100, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_EQ(1, opts.size());
EXPECT_TRUE(relay2_opt1->equals(opts.begin()->second));
opt = msg->getAnyRelayOption(100, Pkt6::RELAY_GET_FIRST);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(100, Pkt6::RELAY_GET_FIRST);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(100, Pkt6::RELAY_GET_FIRST);
EXPECT_TRUE(opts.empty());
opt = msg->getAnyRelayOption(100, Pkt6::RELAY_GET_LAST);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(100, Pkt6::RELAY_GET_LAST);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(100, Pkt6::RELAY_GET_LAST);
EXPECT_TRUE(opts.empty());
// Finally, try to get an option that does not exist
opt = msg->getAnyRelayOption(500, Pkt6::RELAY_GET_FIRST);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(500, Pkt6::RELAY_GET_FIRST);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(500, Pkt6::RELAY_GET_FIRST);
EXPECT_TRUE(opts.empty());
opt = msg->getAnyRelayOption(500, Pkt6::RELAY_GET_LAST);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(500, Pkt6::RELAY_GET_LAST);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(500, Pkt6::RELAY_GET_LAST);
EXPECT_TRUE(opts.empty());
opt = msg->getAnyRelayOption(500, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(500, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(500, Pkt6::RELAY_SEARCH_FROM_SERVER);
EXPECT_TRUE(opts.empty());
opt = msg->getAnyRelayOption(500, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_FALSE(opt);
opts = msg->getNonCopiedAllRelayOptions(500, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_TRUE(opts.empty());
opts = msg->getAllRelayOptions(500, Pkt6::RELAY_SEARCH_FROM_CLIENT);
EXPECT_TRUE(opts.empty());
}
// Tests whether Pkt6::toText() properly prints out all parameters, including
// relay options: remote-id, interface-id.
TEST_F(Pkt6Test, toText) {
// This packet contains doubly relayed solicit. The inner-most
// relay-forward contains interface-id and remote-id. We will
// check that these are printed correctly.
Pkt6Ptr msg(capture2());
EXPECT_NO_THROW(msg->unpack());
ASSERT_EQ(2, msg->relay_info_.size());
string expected =
"local_address=[ff05::1:3]:547, remote_address=[fe80::1234]:547,\n"
"msg_type=SOLICIT (1), trans_id=0x6b4fe2,\n"
"options:\n"
" type=00001, len=00014: 00:01:00:01:18:b0:33:41:00:00:21:5c:18:a9\n"
" type=00003(IA_NA), len=00012: iaid=1, t1=4294967295, t2=4294967295\n"
" type=00006, len=00006: 23(uint16) 242(uint16) 243(uint16)\n"
" type=00008, len=00002: 0 (uint16)\n"
"2 relay(s):\n"
"relay[0]: msg-type=12(RELAY_FORWARD), hop-count=1,\n"
"link-address=2001:888:db8:1::, peer-address=fe80::200:21ff:fe5c:18a9, 2 option(s)\n"
"type=00018, len=00028: 49:53:41:4d:31:34:34:7c:32:39:39:7c:69:70:76:36:7c:6e:74:3a:76:70:3a:31:3a:31:31:30 'ISAM144|299|ipv6|nt:vp:1:110'\n"
"type=00037, len=00018: 6527 (uint32) 0001000118B033410000215C18A9 (binary)\n"
"relay[1]: msg-type=12(RELAY_FORWARD), hop-count=0,\n"
"link-address=::, peer-address=fe80::200:21ff:fe5c:18a9, 2 option(s)\n"
"type=00018, len=00021: 49:53:41:4d:31:34:34:20:65:74:68:20:31:2f:31:2f:30:35:2f:30:31 'ISAM144 eth 1/1/05/01'\n"
"type=00037, len=00004: 3561 (uint32) '' (binary)\n";
EXPECT_EQ(expected, msg->toText());
}
// Tests whether a packet can be assigned to a class and later
// checked if it belongs to a given class
TEST_F(Pkt6Test, clientClasses) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// Default values (do not belong to any class)
EXPECT_FALSE(pkt.inClass(DOCSIS3_CLASS_EROUTER));
EXPECT_FALSE(pkt.inClass(DOCSIS3_CLASS_MODEM));
EXPECT_TRUE(pkt.getClasses().empty());
// Add to the first class
pkt.addClass(DOCSIS3_CLASS_EROUTER);
EXPECT_TRUE(pkt.inClass(DOCSIS3_CLASS_EROUTER));
EXPECT_FALSE(pkt.inClass(DOCSIS3_CLASS_MODEM));
ASSERT_FALSE(pkt.getClasses().empty());
// Add to a second class
pkt.addClass(DOCSIS3_CLASS_MODEM);
EXPECT_TRUE(pkt.inClass(DOCSIS3_CLASS_EROUTER));
EXPECT_TRUE(pkt.inClass(DOCSIS3_CLASS_MODEM));
// Check that it's ok to add to the same class repeatedly
EXPECT_NO_THROW(pkt.addClass("foo"));
EXPECT_NO_THROW(pkt.addClass("foo"));
EXPECT_NO_THROW(pkt.addClass("foo"));
// Check that the packet belongs to 'foo'
EXPECT_TRUE(pkt.inClass("foo"));
}
// Tests operations on additional classes list.
TEST_F(Pkt6Test, additionalClientClasses) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// Default values (do not belong to any class)
EXPECT_TRUE(pkt.getAdditionalClasses().empty());
// Add to the first class
pkt.addAdditionalClass(DOCSIS3_CLASS_EROUTER);
EXPECT_EQ(1, pkt.getAdditionalClasses().size());
// Add to a second class
pkt.addAdditionalClass(DOCSIS3_CLASS_MODEM);
EXPECT_EQ(2, pkt.getAdditionalClasses().size());
EXPECT_TRUE(pkt.getAdditionalClasses().contains(DOCSIS3_CLASS_EROUTER));
EXPECT_TRUE(pkt.getAdditionalClasses().contains(DOCSIS3_CLASS_MODEM));
EXPECT_FALSE(pkt.getAdditionalClasses().contains("foo"));
// Check that it's ok to add to the same class repeatedly
EXPECT_NO_THROW(pkt.addAdditionalClass("foo"));
EXPECT_NO_THROW(pkt.addAdditionalClass("foo"));
EXPECT_NO_THROW(pkt.addAdditionalClass("foo"));
// Check that the packet belongs to 'foo'
EXPECT_TRUE(pkt.getAdditionalClasses().contains("foo"));
}
// Tests whether a packet can be assigned to a subclass and later
// checked if it belongs to a given subclass
TEST_F(Pkt6Test, templateClasses) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// Default values (do not belong to any subclass)
EXPECT_FALSE(pkt.inClass("SPAWN_template-interface-name_eth0"));
EXPECT_FALSE(pkt.inClass("SPAWN_template-interface-id_interface-id0"));
EXPECT_TRUE(pkt.getClasses().empty());
// Add to the first subclass
pkt.addSubClass("template-interface-name", "SPAWN_template-interface-name_eth0");
EXPECT_TRUE(pkt.inClass("SPAWN_template-interface-name_eth0"));
EXPECT_FALSE(pkt.inClass("SPAWN_template-interface-id_interface-id0"));
ASSERT_FALSE(pkt.getClasses().empty());
// Add to a second subclass
pkt.addSubClass("template-interface-id", "SPAWN_template-interface-id_interface-id0");
EXPECT_TRUE(pkt.inClass("SPAWN_template-interface-name_eth0"));
EXPECT_TRUE(pkt.inClass("SPAWN_template-interface-id_interface-id0"));
// Verify the order is as expected.
const ClientClasses& classes = pkt.getClasses();
auto cclass = classes.cbegin();
ASSERT_NE(cclass, classes.cend());
EXPECT_EQ("SPAWN_template-interface-name_eth0", (*cclass));
++cclass;
ASSERT_NE(cclass, classes.cend());
EXPECT_EQ("template-interface-name", (*cclass));
++cclass;
ASSERT_NE(cclass, classes.cend());
EXPECT_EQ("SPAWN_template-interface-id_interface-id0", (*cclass));
++cclass;
ASSERT_NE(cclass, classes.cend());
EXPECT_EQ("template-interface-id", (*cclass));
// Check that it's ok to add to the same subclass repeatedly
EXPECT_NO_THROW(pkt.addSubClass("template-foo", "SPAWN_template-foo_bar"));
EXPECT_NO_THROW(pkt.addSubClass("template-foo", "SPAWN_template-foo_bar"));
EXPECT_NO_THROW(pkt.addSubClass("template-bar", "SPAWN_template-bar_bar"));
// Check that the packet belongs to 'SPAWN_template-foo_bar'
EXPECT_TRUE(pkt.inClass("SPAWN_template-foo_bar"));
// Check that the packet belongs to 'SPAWN_template-bar_bar'
EXPECT_TRUE(pkt.inClass("SPAWN_template-bar_bar"));
}
// Tests whether MAC can be obtained and that MAC sources are not
// confused.
TEST_F(Pkt6Test, getMAC) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// DHCPv6 packet by default doesn't have MAC address specified.
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_ANY));
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_RAW));
// We haven't specified source IPv6 address, so this method should
// fail, too
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL));
// Let's check if setting IPv6 address improves the situation.
IOAddress linklocal_eui64("fe80::204:06ff:fe08:0a0c");
pkt.setRemoteAddr(linklocal_eui64);
HWAddrPtr mac;
ASSERT_TRUE(mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_ANY));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, mac->source_);
ASSERT_TRUE(mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, mac->source_);
ASSERT_TRUE(mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL |
HWAddr::HWADDR_SOURCE_RAW));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, mac->source_);
pkt.setRemoteAddr(IOAddress("::"));
// Let's invent a MAC
const uint8_t hw[] = { 2, 4, 6, 8, 10, 12 }; // MAC
const uint8_t hw_type = 123; // hardware type
HWAddrPtr dummy_hwaddr(new HWAddr(hw, sizeof(hw), hw_type));
// Now let's pretend that we obtained it from raw sockets
pkt.setRemoteHWAddr(dummy_hwaddr);
// Now we should be able to get something
ASSERT_TRUE(mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_ANY));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_RAW, mac->source_);
ASSERT_TRUE(pkt.getMAC(HWAddr::HWADDR_SOURCE_RAW));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_RAW, mac->source_);
EXPECT_TRUE(pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL |
HWAddr::HWADDR_SOURCE_RAW));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_RAW, mac->source_);
// Check that the returned MAC is indeed the expected one
ASSERT_TRUE(*dummy_hwaddr == *pkt.getMAC(HWAddr::HWADDR_SOURCE_ANY));
ASSERT_TRUE(*dummy_hwaddr == *pkt.getMAC(HWAddr::HWADDR_SOURCE_RAW));
}
// Test checks whether getMACFromIPv6LinkLocal() returns the hardware (MAC)
// address properly (for direct message).
TEST_F(Pkt6Test, getMACFromIPv6LinkLocal_direct) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// Let's get the first interface
IfacePtr iface = IfaceMgr::instance().getIface(1);
ASSERT_TRUE(iface);
// and set source interface data properly. getMACFromIPv6LinkLocal attempts
// to use source interface to obtain hardware type
pkt.setIface(iface->getName());
pkt.setIndex(iface->getIndex());
// Note that u and g bits (the least significant ones of the most
// significant byte) have special meaning and must not be set in MAC.
// u bit is always set in EUI-64. g is always cleared.
IOAddress global("2001:db8::204:06ff:fe08:0a:0c");
IOAddress linklocal_eui64("fe80::f204:06ff:fe08:0a0c");
IOAddress linklocal_noneui64("fe80::f204:0608:0a0c:0e10");
// If received from a global address, this method should fail
pkt.setRemoteAddr(global);
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL));
// If received from link-local that is EUI-64 based, it should succeed
pkt.setRemoteAddr(linklocal_eui64);
HWAddrPtr found = pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL);
ASSERT_TRUE(found);
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, found->source_);
stringstream tmp;
tmp << "hwtype=" << (int)iface->getHWType() << " f0:04:06:08:0a:0c";
EXPECT_EQ(tmp.str(), found->toText(true));
}
// Test checks whether getMACFromIPv6LinkLocal() returns the hardware (MAC)
// address properly (for relayed message).
TEST_F(Pkt6Test, getMACFromIPv6LinkLocal_singleRelay) {
// Let's create a Solicit first...
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// ... and pretend it was relayed by a single relay.
Pkt6::RelayInfo info;
pkt.addRelayInfo(info);
ASSERT_EQ(1, pkt.relay_info_.size());
// Let's get the first interface
IfacePtr iface = IfaceMgr::instance().getIface(1);
ASSERT_TRUE(iface);
// and set source interface data properly. getMACFromIPv6LinkLocal attempts
// to use source interface to obtain hardware type
pkt.setIface(iface->getName());
pkt.setIndex(iface->getIndex());
IOAddress global("2001:db8::204:06ff:fe08:0a:0c"); // global address
IOAddress linklocal_noneui64("fe80::f204:0608:0a0c:0e10"); // no fffe
IOAddress linklocal_eui64("fe80::f204:06ff:fe08:0a0c"); // valid EUI-64
// If received from a global address, this method should fail
pkt.relay_info_[0].peeraddr_ = global;
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL));
// If received from a link-local that does not use EUI-64, it should fail
pkt.relay_info_[0].peeraddr_ = linklocal_noneui64;
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL));
// If received from link-local that is EUI-64 based, it should succeed
pkt.relay_info_[0].peeraddr_ = linklocal_eui64;
HWAddrPtr found = pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL);
ASSERT_TRUE(found);
stringstream tmp;
tmp << "hwtype=" << (int)iface->getHWType() << " f0:04:06:08:0a:0c";
EXPECT_EQ(tmp.str(), found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, found->source_);
}
// Test checks whether getMACFromIPv6LinkLocal() returns the hardware (MAC)
// address properly (for a message relayed multiple times).
TEST_F(Pkt6Test, getMACFromIPv6LinkLocal_multiRelay) {
// Let's create a Solicit first...
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// ... and pretend it was relayed via 3 relays. Keep in mind that
// the relays are stored in relay_info_ in the encapsulation order
// rather than in traverse order. The following simulates:
// client --- relay1 --- relay2 --- relay3 --- server
IOAddress linklocal1("fe80::200:ff:fe00:1"); // valid EUI-64
IOAddress linklocal2("fe80::200:ff:fe00:2"); // valid EUI-64
IOAddress linklocal3("fe80::200:ff:fe00:3"); // valid EUI-64
// Let's add info about relay3. This was the last relay, so it added the
// outermost encapsulation layer, so it was parsed first during reception.
// Its peer-addr field contains an address of relay2, so it's useless for
// this method.
Pkt6::RelayInfo info;
info.peeraddr_ = linklocal3;
pkt.addRelayInfo(info);
// Now add info about relay2. Its peer-addr contains an address of the
// previous relay (relay1). Still useless for us.
info.peeraddr_ = linklocal2;
pkt.addRelayInfo(info);
// Finally add the first relay. This is the relay that received the packet
// from the client directly, so its peer-addr field contains an address of
// the client. The method should get that address and build MAC from it.
info.peeraddr_ = linklocal1;
pkt.addRelayInfo(info);
ASSERT_EQ(3, pkt.relay_info_.size());
// Let's get the first interface
IfacePtr iface = IfaceMgr::instance().getIface(1);
ASSERT_TRUE(iface);
// and set source interface data properly. getMACFromIPv6LinkLocal attempts
// to use source interface to obtain hardware type
pkt.setIface(iface->getName());
pkt.setIndex(iface->getIndex());
// The method should return MAC based on the first relay that was closest
HWAddrPtr found = pkt.getMAC(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL);
ASSERT_TRUE(found);
// Let's check the info now.
stringstream tmp;
tmp << "hwtype=" << iface->getHWType() << " 00:00:00:00:00:01";
EXPECT_EQ(tmp.str(), found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_IPV6_LINK_LOCAL, found->source_);
}
// Test checks whether getMACFromIPv6RelayOpt() returns the hardware (MAC)
// address properly from a single relayed message.
TEST_F(Pkt6Test, getMACFromIPv6RelayOpt_singleRelay) {
// Let's create a Solicit first...
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// Packets that are not relayed should fail
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION));
// Now pretend it was relayed by a single relay.
Pkt6::RelayInfo info;
// generate options with code 79 and client link layer address
const uint8_t opt_data[] = {
0x00, 0x01, // Ethertype
0x0a, 0x1b, 0x0b, 0x01, 0xca, 0xfe // MAC
};
OptionPtr relay_opt(new Option(Option::V6, 79,
OptionBuffer(opt_data, opt_data + sizeof(opt_data))));
info.options_.insert(make_pair(relay_opt->getType(), relay_opt));
pkt.addRelayInfo(info);
ASSERT_EQ(1, pkt.relay_info_.size());
HWAddrPtr found = pkt.getMAC(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION);
ASSERT_TRUE(found);
stringstream tmp;
tmp << "hwtype=1 0a:1b:0b:01:ca:fe";
EXPECT_EQ(tmp.str(), found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION, found->source_);
}
// Test checks whether getMACFromIPv6RelayOpt() returns the hardware (MAC)
// address properly from a message relayed by multiple servers.
TEST_F(Pkt6Test, getMACFromIPv6RelayOpt_multipleRelay) {
// Let's create a Solicit first...
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// Now pretend it was relayed two times. The relay closest to the server
// adds link-layer-address information against the RFC, the process fails.
Pkt6::RelayInfo info1;
uint8_t opt_data[] = {
0x00, 0x01, // Ethertype
0x1a, 0x30, 0x0b, 0xfa, 0xc0, 0xfe // MAC
};
OptionPtr relay_opt1(new Option(Option::V6, D6O_CLIENT_LINKLAYER_ADDR,
OptionBuffer(opt_data, opt_data + sizeof(opt_data))));
info1.options_.insert(make_pair(relay_opt1->getType(), relay_opt1));
pkt.addRelayInfo(info1);
// Second relay, closest to the client has not implemented RFC6939
Pkt6::RelayInfo info2;
pkt.addRelayInfo(info2);
ASSERT_EQ(2, pkt.relay_info_.size());
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION));
// Let's envolve the packet with a third relay (now the closest to the client)
// that inserts the correct client_linklayer_addr option.
Pkt6::RelayInfo info3;
// We reuse the option and modify the MAC to be sure we get the right address
opt_data[2] = 0xfa;
OptionPtr relay_opt3(new Option(Option::V6, D6O_CLIENT_LINKLAYER_ADDR,
OptionBuffer(opt_data, opt_data + sizeof(opt_data))));
info3.options_.insert(make_pair(relay_opt3->getType(), relay_opt3));
pkt.addRelayInfo(info3);
ASSERT_EQ(3, pkt.relay_info_.size());
// Now extract the MAC address from the relayed option
HWAddrPtr found = pkt.getMAC(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION);
ASSERT_TRUE(found);
stringstream tmp;
tmp << "hwtype=1 fa:30:0b:fa:c0:fe";
EXPECT_EQ(tmp.str(), found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_CLIENT_ADDR_RELAY_OPTION,found->source_);
}
TEST_F(Pkt6Test, getMACFromDUID) {
Pkt6 pkt(DHCPV6_ADVERTISE, 1234);
// Although MACs are typically 6 bytes long, let's make this test a bit
// more challenging and use odd MAC lengths.
uint8_t duid_llt[] = { 0, 1, // type (DUID-LLT)
0, 7, // hwtype (7 - just a randomly picked value)
1, 2, 3, 4, // timestamp
0xa, 0xb, 0xc, 0xd, 0xe, 0xf, 0x10 // MAC address (7 bytes)
};
uint8_t duid_ll[] = { 0, 3, // type (DUID-LL)
0, 11, // hwtype (11 - just a randomly picked value)
0xa, 0xb, 0xc, 0xd, 0xe // MAC address (5 bytes)
};
uint8_t duid_en[] = { 0, 2, // type (DUID-EN)
1, 2, 3, 4, // enterprise-id
0xa, 0xb, 0xc // opaque data
};
OptionPtr clientid1(new Option(Option::V6, D6O_CLIENTID, OptionBuffer(
duid_llt, duid_llt + sizeof(duid_llt))));
OptionPtr clientid2(new Option(Option::V6, D6O_CLIENTID, OptionBuffer(
duid_ll, duid_ll + sizeof(duid_ll))));
OptionPtr clientid3(new Option(Option::V6, D6O_CLIENTID, OptionBuffer(
duid_en, duid_en + sizeof(duid_en))));
// Packet does not have any client-id, this call should fail
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_DUID));
// Let's test DUID-LLT. This should work.
pkt.addOption(clientid1);
HWAddrPtr mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_DUID);
ASSERT_TRUE(mac);
EXPECT_EQ("hwtype=7 0a:0b:0c:0d:0e:0f:10", mac->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_DUID, mac->source_);
// Let's test DUID-LL. This should work.
ASSERT_TRUE(pkt.delOption(D6O_CLIENTID));
pkt.addOption(clientid2);
mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_DUID);
ASSERT_TRUE(mac);
EXPECT_EQ("hwtype=11 0a:0b:0c:0d:0e", mac->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_DUID, mac->source_);
// Finally, let's try DUID-EN. This should fail, as EN type does not
// contain any MAC address information.
ASSERT_TRUE(pkt.delOption(D6O_CLIENTID));
pkt.addOption(clientid3);
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_DUID));
}
// Test checks whether getMAC(DOCSIS_MODEM) is working properly.
// We only have a small number of actual traffic captures from
// cable networks, so the scope of unit-tests is somewhat limited.
TEST_F(Pkt6Test, getMAC_DOCSIS_Modem) {
// Let's use a captured traffic. The one we have comes from a
// modem with MAC address 10:0d:7f:00:07:88.
Pkt6Ptr pkt = PktCaptures::captureDocsisRelayedSolicit();
ASSERT_NO_THROW(pkt->unpack());
// The method should return MAC based on the vendor-specific info,
// suboption 36, which is inserted by the modem itself.
HWAddrPtr found = pkt->getMAC(HWAddr::HWADDR_SOURCE_DOCSIS_MODEM);
ASSERT_TRUE(found);
// Let's check the info.
EXPECT_EQ("hwtype=1 10:0d:7f:00:07:88", found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_DOCSIS_MODEM, found->source_);
// Now let's remove the option
OptionVendorPtr vendor = boost::dynamic_pointer_cast<
OptionVendor>(pkt->getOption(D6O_VENDOR_OPTS));
ASSERT_TRUE(vendor);
ASSERT_TRUE(vendor->delOption(DOCSIS3_V6_DEVICE_ID));
// Ok, there's no more suboption 36. Now getMAC() should fail.
EXPECT_FALSE(pkt->getMAC(HWAddr::HWADDR_SOURCE_DOCSIS_MODEM));
}
// Test checks whether getMAC(DOCSIS_CMTS) is working properly.
// We only have a small number of actual traffic captures from
// cable networks, so the scope of unit-tests is somewhat limited.
TEST_F(Pkt6Test, getMAC_DOCSIS_CMTS) {
// Let's use a captured traffic. The one we have comes from a
// modem with MAC address 20:e5:2a:b8:15:14.
Pkt6Ptr pkt = PktCaptures::captureeRouterRelayedSolicit();
ASSERT_NO_THROW(pkt->unpack());
// The method should return MAC based on the vendor-specific info,
// suboption 36, which is inserted by the modem itself.
HWAddrPtr found = pkt->getMAC(HWAddr::HWADDR_SOURCE_DOCSIS_CMTS);
ASSERT_TRUE(found);
// Let's check the info.
EXPECT_EQ("hwtype=1 20:e5:2a:b8:15:14", found->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_DOCSIS_CMTS, found->source_);
// Now let's remove the suboption 1026 that is inserted by the
// relay.
OptionVendorPtr vendor = boost::dynamic_pointer_cast<
OptionVendor>(pkt->getAnyRelayOption(D6O_VENDOR_OPTS,
isc::dhcp::Pkt6::RELAY_SEARCH_FROM_CLIENT));
ASSERT_TRUE(vendor);
EXPECT_TRUE(vendor->delOption(DOCSIS3_V6_CMTS_CM_MAC));
EXPECT_FALSE(pkt->getMAC(HWAddr::HWADDR_SOURCE_DOCSIS_CMTS));
}
// Test checks whether getMACFromRemoteIdRelayOption() returns the hardware (MAC)
// address properly from a relayed message.
TEST_F(Pkt6Test, getMACFromRemoteIdRelayOption) {
// Create a solicit message.
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// This should fail as the message is't relayed yet.
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID));
// Let's get the first interface
IfacePtr iface = IfaceMgr::instance().getIface(1);
ASSERT_TRUE(iface);
// and set source interface data properly. getMACFromIPv6LinkLocal attempts
// to use source interface to obtain hardware type
pkt.setIface(iface->getName());
pkt.setIndex(iface->getIndex());
// Generate option data with randomly picked enterprise number and remote-id
const uint8_t opt_data[] = {
1, 2, 3, 4, // enterprise-number
0xa, 0xb, 0xc, 0xd, 0xe, 0xf // remote-id can be used as a standard MAC
};
// Create option with number 37 (remote-id relay agent option)
OptionPtr relay_opt(new Option(Option::V6, D6O_REMOTE_ID,
OptionBuffer(opt_data, opt_data + sizeof(opt_data))));
// First simulate relaying message without adding remote-id option
Pkt6::RelayInfo info;
pkt.addRelayInfo(info);
ASSERT_EQ(1, pkt.relay_info_.size());
// This should fail as the remote-id option isn't there
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID));
// Now add this option to the relayed message
info.options_.insert(make_pair(relay_opt->getType(), relay_opt));
pkt.addRelayInfo(info);
ASSERT_EQ(2, pkt.relay_info_.size());
// This should work now
HWAddrPtr mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID);
ASSERT_TRUE(mac);
stringstream tmp;
tmp << "hwtype=" << (int)iface->getHWType() << " 0a:0b:0c:0d:0e:0f";
EXPECT_EQ(tmp.str(), mac->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_REMOTE_ID, mac->source_);
}
// Test checks whether getMACFromRemoteIdRelayOption() returns the hardware (MAC)
// address properly from a relayed message (even if the remote-id is longer than
// 20 bytes).
TEST_F(Pkt6Test, getMACFromRemoteIdRelayOptionExtendedValue) {
// Create a solicit message.
Pkt6 pkt(DHCPV6_SOLICIT, 1234);
// This should fail as the message is't relayed yet.
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID));
// Let's get the first interface
IfacePtr iface = IfaceMgr::instance().getIface(1);
ASSERT_TRUE(iface);
// and set source interface data properly. getMACFromIPv6LinkLocal attempts
// to use source interface to obtain hardware type
pkt.setIface(iface->getName());
pkt.setIndex(iface->getIndex());
// Generate option data with randomly picked enterprise number and remote-id
const uint8_t opt_data[] = {
1, 2, 3, 4, // enterprise-number
0xa, 0xb, 0xc, 0xd, 0xe, 0xf, // remote-id can be longer than 20 bytes,
0xa, 0xb, 0xc, 0xd, 0xe, 0xf, // truncate it so that is can be used as
0xa, 0xb, 0xc, 0xd, 0xe, 0xf, // a standard MAC
0xa, 0xb, 0xc, 0xd, 0xe, 0xf
};
// Create option with number 37 (remote-id relay agent option)
OptionPtr relay_opt(new Option(Option::V6, D6O_REMOTE_ID,
OptionBuffer(opt_data, opt_data + sizeof(opt_data))));
// First simulate relaying message without adding remote-id option
Pkt6::RelayInfo info;
pkt.addRelayInfo(info);
ASSERT_EQ(1, pkt.relay_info_.size());
// This should fail as the remote-id option isn't there
EXPECT_FALSE(pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID));
// Now add this option to the relayed message
info.options_.insert(make_pair(relay_opt->getType(), relay_opt));
pkt.addRelayInfo(info);
ASSERT_EQ(2, pkt.relay_info_.size());
// This should work now
HWAddrPtr mac = pkt.getMAC(HWAddr::HWADDR_SOURCE_REMOTE_ID);
ASSERT_TRUE(mac);
stringstream tmp;
tmp << "hwtype=" << (int)iface->getHWType()
<< " 0a:0b:0c:0d:0e:0f:0a:0b:0c:0d:0e:0f:0a:0b:0c:0d:0e:0f:0a:0b";
EXPECT_EQ(tmp.str(), mac->toText(true));
EXPECT_EQ(HWAddr::HWADDR_SOURCE_REMOTE_ID, mac->source_);
}
// This test verifies that a solicit that passed through two relays is parsed
// properly. In particular the second relay (outer encapsulation) included RSOO
// (Relay Supplied Options option). This test checks whether it was parsed
// properly. See captureRelayed2xRSOO() description for details.
TEST_F(Pkt6Test, rsoo) {
Pkt6Ptr msg = dhcp::test::PktCaptures::captureRelayed2xRSOO();
EXPECT_NO_THROW(msg->unpack());
EXPECT_EQ(DHCPV6_SOLICIT, msg->getType());
EXPECT_EQ(217, msg->len());
ASSERT_EQ(2, msg->relay_info_.size());
// There should be an RSOO option in the outermost relay
OptionPtr opt = msg->getRelayOption(D6O_RSOO, 1);
ASSERT_TRUE(opt);
EXPECT_EQ(D6O_RSOO, opt->getType());
const OptionCollection& rsoo = opt->getOptions();
ASSERT_EQ(2, rsoo.size());
OptionPtr rsoo1 = opt->getOption(255);
OptionPtr rsoo2 = opt->getOption(256);
ASSERT_TRUE(rsoo1);
ASSERT_TRUE(rsoo2);
EXPECT_EQ(8, rsoo1->len()); // 4 bytes of data + header
EXPECT_EQ(13, rsoo2->len()); // 9 bytes of data + header
}
// Verify that the DUID can be extracted from the DHCPv6 packet
// holding Client Identifier option.
TEST_F(Pkt6Test, getClientId) {
// Create a packet.
Pkt6Ptr pkt(new Pkt6(DHCPV6_SOLICIT, 0x2312));
// Initially, the packet should hold no DUID.
EXPECT_FALSE(pkt->getClientId());
// Create DUID and add it to the packet.
const uint8_t duid_data[] = { 1, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 0 };
OptionBuffer duid_vec(duid_data, duid_data + sizeof(duid_data) - 1);
pkt->addOption(OptionPtr(new Option(Option::V6, D6O_CLIENTID,
duid_vec.begin(),
duid_vec.end())));
// Simulate the packet transmission over the wire, i.e. create on
// wire representation of the packet, and then parse it.
Pkt6Ptr pkt_clone = packAndClone(pkt);
ASSERT_NO_THROW(pkt_clone->unpack());
// This time the DUID should be returned.
DuidPtr duid = pkt_clone->getClientId();
ASSERT_TRUE(duid);
// And it should be equal to the one that we used to create
// the packet.
EXPECT_TRUE(duid->getDuid() == duid_vec);
}
// This test verifies that it is possible to obtain the packet
// identifiers (DUID, HW Address, transaction id) in the textual
// format.
TEST_F(Pkt6Test, makeLabel) {
DuidPtr duid(new DUID(DUID::fromText("0102020202030303030303")));
HWAddrPtr hwaddr(new HWAddr(HWAddr::fromText("01:02:03:04:05:06",
HTYPE_ETHER)));
// Specify DUID and no HW Address.
EXPECT_EQ("duid=[01:02:02:02:02:03:03:03:03:03:03], [no hwaddr info], tid=0x123",
Pkt6::makeLabel(duid, 0x123, HWAddrPtr()));
// Specify HW Address and no DUID.
EXPECT_EQ("duid=[no info], [hwtype=1 01:02:03:04:05:06], tid=0x123",
Pkt6::makeLabel(DuidPtr(), 0x123, hwaddr));
// Specify both DUID and HW Address.
EXPECT_EQ("duid=[01:02:02:02:02:03:03:03:03:03:03], "
"[hwtype=1 01:02:03:04:05:06], tid=0x123",
Pkt6::makeLabel(duid, 0x123, hwaddr));
// Specify neither DUID nor HW Address.
EXPECT_EQ("duid=[no info], [no hwaddr info], tid=0x0",
Pkt6::makeLabel(DuidPtr(), 0x0, HWAddrPtr()));
}
// Tests that the variant of makeLabel which doesn't include transaction
// id produces expected output.
TEST_F(Pkt6Test, makeLabelWithoutTransactionId) {
DuidPtr duid(new DUID(DUID::fromText("0102020202030303030303")));
HWAddrPtr hwaddr(new HWAddr(HWAddr::fromText("01:02:03:04:05:06",
HTYPE_ETHER)));
// Specify DUID and no HW Address.
EXPECT_EQ("duid=[01:02:02:02:02:03:03:03:03:03:03], [no hwaddr info]",
Pkt6::makeLabel(duid, HWAddrPtr()));
// Specify HW Address and no DUID.
EXPECT_EQ("duid=[no info], [hwtype=1 01:02:03:04:05:06]",
Pkt6::makeLabel(DuidPtr(), hwaddr));
// Specify both DUID and HW Address.
EXPECT_EQ("duid=[01:02:02:02:02:03:03:03:03:03:03], "
"[hwtype=1 01:02:03:04:05:06]",
Pkt6::makeLabel(duid, hwaddr));
// Specify neither DUID nor HW Address.
EXPECT_EQ("duid=[no info], [no hwaddr info]", Pkt6::makeLabel(DuidPtr(), HWAddrPtr()));
}
// This test verifies that it is possible to obtain the packet
// identifiers in the textual format from the packet instance.
TEST_F(Pkt6Test, getLabel) {
// Create a packet.
Pkt6Ptr pkt(new Pkt6(DHCPV6_SOLICIT, 0x2312));
EXPECT_EQ("duid=[no info], [no hwaddr info], tid=0x2312",
pkt->getLabel());
DuidPtr duid(new DUID(DUID::fromText("0102020202030303030303")));
pkt->addOption(OptionPtr(new Option(Option::V6, D6O_CLIENTID,
duid->getDuid().begin(),
duid->getDuid().end())));
// Simulate the packet transmission over the wire, i.e. create on
// wire representation of the packet, and then parse it.
Pkt6Ptr pkt_clone = packAndClone(pkt);
ASSERT_NO_THROW(pkt_clone->unpack());
EXPECT_EQ("duid=[01:02:02:02:02:03:03:03:03:03:03], [no hwaddr info], tid=0x2312",
pkt_clone->getLabel());
}
// Test that empty client identifier option doesn't cause an exception from
// Pkt6::getLabel.
TEST_F(Pkt6Test, getLabelEmptyClientId) {
// Create a packet.
Pkt6 pkt(DHCPV6_SOLICIT, 0x2312);
// Add empty client identifier option.
pkt.addOption(OptionPtr(new Option(Option::V6, D6O_CLIENTID)));
EXPECT_EQ("duid=[no info], [no hwaddr info], tid=0x2312", pkt.getLabel());
}
// Verifies that when the VIVSO, 17, has length that is too
// short (i.e. less than sizeof(uint8_t), unpack throws a
// SkipRemainingOptionsError exception
TEST_F(Pkt6Test, truncatedVendorLength) {
// Build a good Solicit packet
Pkt6Ptr pkt = dhcp::test::PktCaptures::captureSolicitWithVIVSO();
// Unpacking should not throw
ASSERT_NO_THROW(pkt->unpack());
ASSERT_EQ(DHCPV6_SOLICIT, pkt->getType());
// VIVSO option should be there
OptionPtr x = pkt->getOption(D6O_VENDOR_OPTS);
ASSERT_TRUE(x);
ASSERT_EQ(D6O_VENDOR_OPTS, x->getType());
OptionVendorPtr vivso = boost::dynamic_pointer_cast<OptionVendor>(x);
ASSERT_TRUE(vivso);
EXPECT_EQ(8, vivso->len()); // data + opt code + len
// Build a bad Solicit packet
pkt = dhcp::test::PktCaptures::captureSolicitWithTruncatedVIVSO();
// Unpack should throw Skip exception
ASSERT_THROW(pkt->unpack(), SkipRemainingOptionsError);
ASSERT_EQ(DHCPV6_SOLICIT, pkt->getType());
// VIVSO option should not be there
x = pkt->getOption(D6O_VENDOR_OPTS);
ASSERT_FALSE(x);
}
// Checks that unpacking correctly handles SkipThisOptionError by
// omitting the offending option from the unpacked options.
TEST_F(Pkt6Test, testSkipThisOptionError) {
// Get a packet. We're really interested in its on-wire
// representation only.
Pkt6Ptr donor(capture1());
// That's our original content. It should be sane.
OptionBuffer orig = donor->data_;
orig.push_back(0);
orig.push_back(41); // new-posix-timezone
orig.push_back(0);
orig.push_back(3); // length=3
orig.push_back(0x61); // data="abc"
orig.push_back(0x62);
orig.push_back(0x63);
orig.push_back(0);
orig.push_back(59); // bootfile-url
orig.push_back(0);
orig.push_back(3); // length=3
orig.push_back(0); // data= all nulls
orig.push_back(0);
orig.push_back(0);
orig.push_back(0);
orig.push_back(42); // new-tzdb-timezone
orig.push_back(0);
orig.push_back(3); // length=3
orig.push_back(0x64); // data="def"
orig.push_back(0x65);
orig.push_back(0x66);
// Unpacking should not throw.
Pkt6Ptr pkt(new Pkt6(&orig[0], orig.size()));
ASSERT_NO_THROW_LOG(pkt->unpack());
// We should have option 41 = "abc".
OptionPtr opt;
OptionStringPtr opstr;
ASSERT_TRUE(opt = pkt->getOption(41));
ASSERT_TRUE(opstr = boost::dynamic_pointer_cast<OptionString>(opt));
EXPECT_EQ(3, opstr->getValue().length());
EXPECT_EQ("abc", opstr->getValue());
// We should not have option 59.
EXPECT_FALSE(opt = pkt->getOption(59));
// We should have option 42 = "def".
ASSERT_TRUE(opt = pkt->getOption(42));
ASSERT_TRUE(opstr = boost::dynamic_pointer_cast<OptionString>(opt));
EXPECT_EQ(3, opstr->getValue().length());
EXPECT_EQ("def", opstr->getValue());
}
// This test verifies that LQ_QUERY_OPTIONs can be created, packed,
// and unpacked correctly.
TEST_F(Pkt6Test, lqQueryOption) {
const OptionDefinition& def = LibDHCP::D6O_LQ_QUERY_DEF();
OptionCustomPtr lq_option(new OptionCustom(def, Option::V6));
ASSERT_TRUE(lq_option);
// Add query type (77 is technically not valid but better visually).
uint8_t orig_type = 77;
ASSERT_NO_THROW_LOG(lq_option->writeInteger<uint8_t>(77,0));
// Add query link address
IOAddress orig_link("2001:db8::1");
ASSERT_NO_THROW_LOG(lq_option->writeAddress(orig_link, 1));
// Now add supported sub-options: D6O_IAADR, D6O_CLIENTID, and D6O_ORO
// We are ingoring the fact that a query containing both a D6O_IAADDR
// and a D6O_CLIENTID is not technically valid. We only care that the
// sub options will pack and unpack.
// Add a D6O_IAADDR option
Option6IAAddrPtr orig_iaaddr(new Option6IAAddr(D6O_IAADDR, IOAddress("2001:db8::2"), 0, 0));
ASSERT_TRUE(orig_iaaddr);
ASSERT_NO_THROW_LOG(lq_option->addOption(orig_iaaddr));
// Add a D6O_CLIENTID option
DuidPtr duid(new DUID(DUID::fromText("0102020202030303030303")));
OptionPtr orig_clientid(new Option(Option::V6, D6O_CLIENTID, OptionBuffer(
duid->getDuid().begin(), duid->getDuid().end())));
ASSERT_NO_THROW_LOG(lq_option->addOption(orig_clientid));
// Add a D6O_ORO option
OptionUint16ArrayPtr orig_oro(new OptionUint16Array(Option::V6, D6O_ORO));
ASSERT_TRUE(orig_oro);
orig_oro->addValue(1234);
ASSERT_NO_THROW_LOG(lq_option->addOption(orig_oro));
// Now let's create a packet to which to add our new lq_option.
Pkt6Ptr orig(new Pkt6(DHCPV6_LEASEQUERY, 0x2312));
orig->addOption(lq_option);
ASSERT_NO_THROW_LOG(orig->pack());
// Now create second packet,based on assembled data from the first one
Pkt6Ptr clone(new Pkt6(static_cast<const uint8_t*>
(orig->getBuffer().getData()),
orig->getBuffer().getLength()));
// Unpack it.
ASSERT_NO_THROW_LOG(clone->unpack());
// We should be able to find our query option.
OptionPtr opt;
opt = clone->getOption(D6O_LQ_QUERY);
ASSERT_TRUE(opt);
OptionCustomPtr clone_query = boost::dynamic_pointer_cast<OptionCustom>(opt);
ASSERT_TRUE(clone_query);
// Verify the query type is right.
uint8_t clone_type;
ASSERT_NO_THROW_LOG(clone_type = clone_query->readInteger<uint8_t>(0));
EXPECT_EQ(orig_type, clone_type);
// Verify the query link address is right.
IOAddress clone_link("::");
ASSERT_NO_THROW_LOG(clone_link = clone_query->readAddress(1));
EXPECT_EQ(orig_link, clone_link);
// Verify the suboptions.
// Verify the D6O_IAADDR option
opt = clone_query->getOption(D6O_IAADDR);
ASSERT_TRUE(opt);
Option6IAAddrPtr clone_iaaddr = boost::dynamic_pointer_cast<Option6IAAddr>(opt);
ASSERT_TRUE(clone_iaaddr);
EXPECT_TRUE(clone_iaaddr->equals(*orig_iaaddr));
// Verify the D6O_CLIENTID option
opt = clone_query->getOption(D6O_CLIENTID);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(*orig_clientid));
// Verify the D6O_ORO option
opt = clone_query->getOption(D6O_ORO);
ASSERT_TRUE(opt);
OptionUint16ArrayPtr clone_oro = boost::dynamic_pointer_cast<OptionUint16Array>(opt);
ASSERT_TRUE(clone_oro);
EXPECT_TRUE(clone_oro->equals(*orig_oro));
}
// This test verifies that D6O_CLIENT_DATA options can be created, packed,
// and unpacked correctly.
TEST_F(Pkt6Test, clientDataOption) {
const OptionDefinition& def = LibDHCP::D6O_CLIENT_DATA_DEF();
OptionCustomPtr cd_option(new OptionCustom(def, Option::V6));
ASSERT_TRUE(cd_option);
// Now add supported sub-options: D6O_CLIENTID, D6O_IAADR, D6O_IAAPREFIX,
// and D6O_CLTT
// Add a D6O_CLIENTID option
DuidPtr duid(new DUID(DUID::fromText("0102020202030303030303")));
OptionPtr orig_clientid(new Option(Option::V6, D6O_CLIENTID, OptionBuffer(
duid->getDuid().begin(), duid->getDuid().end())));
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_clientid));
// Add a D6O_IAADDR option
Option6IAAddrPtr orig_iaaddr1(new Option6IAAddr(D6O_IAADDR, IOAddress("2001:db8::1"), 0, 0));
ASSERT_TRUE(orig_iaaddr1);
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_iaaddr1));
// Add another D6O_IAADDR option
Option6IAAddrPtr orig_iaaddr2(new Option6IAAddr(D6O_IAADDR, IOAddress("2001:db8::2"), 0, 0));
ASSERT_TRUE(orig_iaaddr2);
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_iaaddr2));
// Add a D6O_IAPREFIX option
Option6IAAddrPtr orig_iaprefix1(new Option6IAPrefix(D6O_IAPREFIX, IOAddress("2001:db8:1::"), 64, 0, 0));
ASSERT_TRUE(orig_iaprefix1);
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_iaprefix1));
// Add another D6O_IAPREFIX option
Option6IAAddrPtr orig_iaprefix2(new Option6IAPrefix(D6O_IAPREFIX, IOAddress("2001:db8:2::"), 64, 0, 0));
ASSERT_TRUE(orig_iaprefix2);
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_iaprefix2));
// Add a D6O_CLT_TIME option
OptionUint32Ptr orig_cltt(new OptionInt<uint32_t>(Option::V6, D6O_CLT_TIME, 4000));
ASSERT_TRUE(orig_cltt);
ASSERT_NO_THROW_LOG(cd_option->addOption(orig_cltt));
// Now let's create a packet to which to add our new client data option.
Pkt6Ptr orig(new Pkt6(DHCPV6_LEASEQUERY_REPLY, 0x2312));
orig->addOption(cd_option);
ASSERT_NO_THROW_LOG(orig->pack());
// Now create second packet,based on assembled data from the first one
Pkt6Ptr clone(new Pkt6(static_cast<const uint8_t*>
(orig->getBuffer().getData()),
orig->getBuffer().getLength()));
// Unpack it.
ASSERT_NO_THROW_LOG(clone->unpack());
// We should be able to find our client data option.
OptionPtr opt;
opt = clone->getOption(D6O_CLIENT_DATA);
ASSERT_TRUE(opt);
OptionCustomPtr clone_cd_option = boost::dynamic_pointer_cast<OptionCustom>(opt);
ASSERT_TRUE(clone_cd_option);
// Verify the suboptions.
opt = clone_cd_option->getOption(D6O_CLIENTID);
ASSERT_TRUE(opt);
EXPECT_TRUE(opt->equals(*orig_clientid));
// Verify the first address option
opt = clone_cd_option->getOption(D6O_IAADDR);
ASSERT_TRUE(opt);
Option6IAAddrPtr clone_iaaddr = boost::dynamic_pointer_cast<Option6IAAddr>(opt);
ASSERT_TRUE(clone_iaaddr);
EXPECT_TRUE(clone_iaaddr->equals(*orig_iaaddr1));
// Verify the second address option.
opt = clone_cd_option->getOption(D6O_IAADDR);
ASSERT_TRUE(opt);
clone_iaaddr = boost::dynamic_pointer_cast<Option6IAAddr>(opt);
ASSERT_TRUE(clone_iaaddr);
EXPECT_TRUE(clone_iaaddr->equals(*orig_iaaddr2));
// Verify the first prefix option.
opt = clone_cd_option->getOption(D6O_IAPREFIX);
ASSERT_TRUE(opt);
Option6IAPrefixPtr clone_iaprefix = boost::dynamic_pointer_cast<Option6IAPrefix>(opt);
ASSERT_TRUE(clone_iaprefix);
EXPECT_TRUE(clone_iaprefix->equals(*orig_iaprefix1));
// Verify the second prefix option.
opt = clone_cd_option->getOption(D6O_IAPREFIX);
ASSERT_TRUE(opt);
clone_iaprefix = boost::dynamic_pointer_cast<Option6IAPrefix>(opt);
ASSERT_TRUE(clone_iaprefix);
EXPECT_TRUE(clone_iaprefix->equals(*orig_iaprefix2));
// Verify the CLT option.
opt = clone_cd_option->getOption(D6O_CLT_TIME);
ASSERT_TRUE(opt);
OptionUint32Ptr clone_cltt = boost::dynamic_pointer_cast<OptionUint32>(opt);
ASSERT_TRUE(clone_cltt);
EXPECT_TRUE(clone_cltt->equals(*orig_cltt));
}
// This test verifies that D6O_LQ_RELAY_DATA options can be created, packed,
// and unpacked correctly.
TEST_F(Pkt6Test, relayDataOption) {
const OptionDefinition& def = LibDHCP::D6O_LQ_RELAY_DATA_DEF();
OptionCustomPtr rd_option(new OptionCustom(def, Option::V6));
ASSERT_TRUE(rd_option);
// Write out the peer address.
IOAddress orig_address("2001:db8::1");
rd_option->writeAddress(orig_address, 0);
// Write out the binary data (in real life this is a RELAY_FORW message)
std::vector<uint8_t>orig_data({ 01,02,03,04,05,06 });
rd_option->writeBinary(orig_data, 1);
// Now let's create a packet to which to add our new relay data option.
Pkt6Ptr orig(new Pkt6(DHCPV6_LEASEQUERY_REPLY, 0x2312));
orig->addOption(rd_option);
ASSERT_NO_THROW_LOG(orig->pack());
// Now create second packet,based on assembled data from the first one
Pkt6Ptr clone(new Pkt6(static_cast<const uint8_t*>
(orig->getBuffer().getData()),
orig->getBuffer().getLength()));
// Unpack it.
ASSERT_NO_THROW_LOG(clone->unpack());
// We should be able to find our client data option.
OptionPtr opt;
opt = clone->getOption(D6O_LQ_RELAY_DATA);
ASSERT_TRUE(opt);
OptionCustomPtr clone_rd_option = boost::dynamic_pointer_cast<OptionCustom>(opt);
ASSERT_TRUE(clone_rd_option);
// Verify the address field.
IOAddress clone_addr("::");
ASSERT_NO_THROW_LOG(clone_addr = clone_rd_option->readAddress(0));
EXPECT_EQ(orig_address, clone_addr);
// Verify the binary field
OptionBuffer clone_data;
ASSERT_NO_THROW_LOG(clone_data = clone_rd_option->readBinary(1));
EXPECT_EQ(orig_data, clone_data);
}
// Exercises packet event stack and helper functions.
TEST_F(Pkt6Test, PktEvents) {
// Get current time.
auto start_time = PktEvent::now();
// Verify that a set time is not equal to an EMPTY_TIME.
ASSERT_NE(start_time, PktEvent::EMPTY_TIME());
// Create a test packet.
scoped_ptr<Pkt6> pkt(new Pkt6(DHCPV6_SOLICIT, 0x020304));
// Upon creation, the events table should be empty.
ASSERT_TRUE(pkt->getPktEvents().empty());
// An non-existent event should return an empty time.
auto event_time = pkt->getPktEventTime(PktEvent::BUFFER_READ);
ASSERT_EQ(event_time, PktEvent::EMPTY_TIME());
// Sleep for 200 microseconds to put some distance between now and start_time.
usleep(200);
// Should be able to add an event, defaulting the event time to current time.
pkt->addPktEvent(PktEvent::BUFFER_READ);
event_time = pkt->getPktEventTime(PktEvent::BUFFER_READ);
ASSERT_GT(event_time, start_time);
// Should be able to overwrite an existing event's time.
pkt->setPktEvent(PktEvent::BUFFER_READ, start_time);
event_time = pkt->getPktEventTime(PktEvent::BUFFER_READ);
ASSERT_EQ(event_time, start_time);
// Should be able to add an event with an explicit time.
pkt->addPktEvent(PktEvent::RESPONSE_SENT, start_time);
event_time = pkt->getPktEventTime(PktEvent::RESPONSE_SENT);
ASSERT_EQ(event_time, start_time);
// Should be able to fetch the list of events.
auto const& events = pkt->getPktEvents();
ASSERT_FALSE(events.empty());
auto event = events.begin();
ASSERT_EQ((*event).label_, PktEvent::BUFFER_READ);
++event;
ASSERT_EQ((*event).label_, PktEvent::RESPONSE_SENT);
// Discard the event stack contents.
pkt->clearPktEvents();
ASSERT_TRUE(pkt->getPktEvents().empty());
// Verify dumpPktEvent terse output. Also serves to
// verify adding events using struct timeval.
struct timeval log_time = {1706802676, 100};
struct timeval log_time_plus = {1706802676, 250};
pkt->addPktEvent("first-event", log_time);
pkt->addPktEvent("second-event", log_time_plus);
std::string log = pkt->dumpPktEvents();
EXPECT_EQ(log, "2024-Feb-01 15:51:16.000100 : first-event, 2024-Feb-01 15:51:16.000250 : second-event");
// Verify dumpPktEvent verbose output.
log = pkt->dumpPktEvents(true);
EXPECT_EQ(log,
"Event log: \n"
"2024-Feb-01 15:51:16.000100 : first-event\n"
"2024-Feb-01 15:51:16.000250 : second-event elapsed: 00:00:00.000150\n"
"total elapsed: 00:00:00.000150");
}
} // namespace
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