// Copyright (C) 2013-2022 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 #include #include #include #include // in_systm.h is required on some some BSD systems // complaining that n_time is undefined but used // in ip.h. #include #include using namespace isc::asiolink; using namespace isc::util; namespace isc { namespace dhcp { void decodeEthernetHeader(InputBuffer& buf, Pkt4Ptr& pkt) { // The size of the buffer to be parsed must not be lower // then the size of the Ethernet frame header. if (buf.getLength() - buf.getPosition() < ETHERNET_HEADER_LEN) { isc_throw(InvalidPacketHeader, "size of ethernet header in received " << "packet is invalid, expected at least " << ETHERNET_HEADER_LEN << " bytes, received " << buf.getLength() - buf.getPosition() << " bytes"); } // Packet object must not be NULL. We want to output some values // to this object. if (!pkt) { isc_throw(BadValue, "NULL packet object provided when parsing ethernet" " frame header"); } // The size of the single address is always lower then the size of // the header that holds this address. Otherwise, it is a programming // error that we want to detect in the compilation time. BOOST_STATIC_ASSERT(ETHERNET_HEADER_LEN > HWAddr::ETHERNET_HWADDR_LEN); // Remember initial position. size_t start_pos = buf.getPosition(); // Read the destination HW address. std::vector dest_addr; buf.readVector(dest_addr, HWAddr::ETHERNET_HWADDR_LEN); pkt->setLocalHWAddr(HWTYPE_ETHERNET, HWAddr::ETHERNET_HWADDR_LEN, dest_addr); // Read the source HW address. std::vector src_addr; buf.readVector(src_addr, HWAddr::ETHERNET_HWADDR_LEN); pkt->setRemoteHWAddr(HWTYPE_ETHERNET, HWAddr::ETHERNET_HWADDR_LEN, src_addr); // Move the buffer read pointer to the end of the Ethernet frame header. buf.setPosition(start_pos + ETHERNET_HEADER_LEN); } void decodeIpUdpHeader(InputBuffer& buf, Pkt4Ptr& pkt) { // The size of the buffer must be at least equal to the minimal size of // the IPv4 packet header plus UDP header length. if (buf.getLength() - buf.getPosition() < MIN_IP_HEADER_LEN + UDP_HEADER_LEN) { isc_throw(InvalidPacketHeader, "the total size of the IP and UDP headers in " << "received packet is invalid, expected at least " << MIN_IP_HEADER_LEN + UDP_HEADER_LEN << " bytes, received " << buf.getLength() - buf.getPosition() << " bytes"); } // Packet object must not be NULL. if (!pkt) { isc_throw(BadValue, "NULL packet object provided when parsing IP and UDP" " packet headers"); } BOOST_STATIC_ASSERT(IP_SRC_ADDR_OFFSET < MIN_IP_HEADER_LEN); // Remember initial position of the read pointer. size_t start_pos = buf.getPosition(); // Read IP header length (mask most significant bits as they indicate IP version). uint8_t ip_len = buf.readUint8() & 0xF; // IP length is the number of 4 byte chunks that construct IPv4 header. // It must not be lower than 5 because first 20 bytes are fixed. if (ip_len < 5) { isc_throw(InvalidPacketHeader, "Value of the length of the IP header must not be" << " lower than 5 words. The length of the received header is " << static_cast(ip_len) << "."); } // Seek to the position of source IP address. buf.setPosition(start_pos + IP_SRC_ADDR_OFFSET); // Read source address. pkt->setRemoteAddr(IOAddress(buf.readUint32())); // Read destination address. pkt->setLocalAddr(IOAddress(buf.readUint32())); // Skip IP header options (if any) to start of the // UDP header. buf.setPosition(start_pos + ip_len * 4); // Read source port from UDP header. pkt->setRemotePort(buf.readUint16()); // Read destination port from UDP header. pkt->setLocalPort(buf.readUint16()); // Set the pointer position to the first byte o the // UDP payload (DHCP packet). buf.setPosition(start_pos + ip_len * 4 + UDP_HEADER_LEN); } void writeEthernetHeader(const Pkt4Ptr& pkt, OutputBuffer& out_buf) { // Set destination HW address. HWAddrPtr remote_addr = pkt->getRemoteHWAddr(); if (remote_addr) { if (remote_addr->hwaddr_.size() != HWAddr::ETHERNET_HWADDR_LEN) { isc_throw(BadValue, "invalid size of the remote HW address " << remote_addr->hwaddr_.size() << " when constructing" << " an ethernet frame header; expected size is" << " " << HWAddr::ETHERNET_HWADDR_LEN); } else if (!pkt->isRelayed() && (pkt->getFlags() & Pkt4::FLAG_BROADCAST_MASK)) { out_buf.writeData(&std::vector(HWAddr::ETHERNET_HWADDR_LEN,255)[0], HWAddr::ETHERNET_HWADDR_LEN); } else { out_buf.writeData(&remote_addr->hwaddr_[0], HWAddr::ETHERNET_HWADDR_LEN); } } else { // HW address has not been specified. This is possible when receiving // packet through a logical interface (e.g. lo). In such cases, we // don't want to fail but rather provide a default HW address, which // consists of zeros. out_buf.writeData(&std::vector(HWAddr::ETHERNET_HWADDR_LEN)[0], HWAddr::ETHERNET_HWADDR_LEN); } // Set source HW address. HWAddrPtr local_addr = pkt->getLocalHWAddr(); if (local_addr) { if (local_addr->hwaddr_.size() == HWAddr::ETHERNET_HWADDR_LEN) { out_buf.writeData(&local_addr->hwaddr_[0], HWAddr::ETHERNET_HWADDR_LEN); } else { isc_throw(BadValue, "invalid size of the local HW address " << local_addr->hwaddr_.size() << " when constructing" << " an ethernet frame header; expected size is" << " " << HWAddr::ETHERNET_HWADDR_LEN); } } else { // Provide default HW address. out_buf.writeData(&std::vector(HWAddr::ETHERNET_HWADDR_LEN)[0], HWAddr::ETHERNET_HWADDR_LEN); } // Type IP. out_buf.writeUint16(ETHERNET_TYPE_IP); } void writeIpUdpHeader(const Pkt4Ptr& pkt, util::OutputBuffer& out_buf) { out_buf.writeUint8(0x45); // IP version 4, IP header length 5 out_buf.writeUint8(IPTOS_LOWDELAY); // DSCP and ECN out_buf.writeUint16(28 + pkt->getBuffer().getLength()); // Total length. out_buf.writeUint16(0); // Identification out_buf.writeUint16(0x4000); // Disable fragmentation. out_buf.writeUint8(128); // TTL out_buf.writeUint8(IPPROTO_UDP); // Protocol UDP. out_buf.writeUint16(0); // Temporarily set checksum to 0. out_buf.writeUint32(pkt->getLocalAddr().toUint32()); // Source address. out_buf.writeUint32(pkt->getRemoteAddr().toUint32()); // Destination address. // Calculate pseudo header checksum. It will be necessary to compute // UDP checksum. // Get the UDP length. This includes udp header's and data length. uint32_t udp_len = 8 + pkt->getBuffer().getLength(); // The magic number "8" indicates the offset where the source address // is stored in the buffer. This offset is counted here from the // current tail of the buffer. Starting from this offset we calculate // the checksum using 8 following bytes of data. This will include // 4 bytes of source address and 4 bytes of destination address. // The IPPROTO_UDP and udp_len are also added up to the checksum. uint16_t pseudo_hdr_checksum = calcChecksum(static_cast(out_buf.getData()) + out_buf.getLength() - 8, 8, IPPROTO_UDP + udp_len); // Calculate IP header checksum. uint16_t ip_checksum = ~calcChecksum(static_cast(out_buf.getData()) + out_buf.getLength() - 20, 20); // Write checksum in the IP header. The offset of the checksum is 10 bytes // back from the tail of the current buffer. out_buf.writeUint16At(ip_checksum, out_buf.getLength() - 10); // Start UDP header. out_buf.writeUint16(pkt->getLocalPort()); // Source port. out_buf.writeUint16(pkt->getRemotePort()); // Destination port. out_buf.writeUint16(udp_len); // Length of the header and data. // Checksum is calculated from the contents of UDP header, data and pseudo ip header. // The magic number "6" indicates that the UDP header starts at offset 6 from the // tail of the current buffer. These 6 bytes contain source and destination port // as well as the length of the header. uint16_t udp_checksum = ~calcChecksum(static_cast(out_buf.getData()) + out_buf.getLength() - 6, 6, calcChecksum(static_cast(pkt->getBuffer().getData()), pkt->getBuffer().getLength(), pseudo_hdr_checksum)); // Write UDP checksum. out_buf.writeUint16(udp_checksum); } uint16_t calcChecksum(const uint8_t* buf, const uint32_t buf_size, uint32_t sum) { uint32_t i; for (i = 0; i < (buf_size & ~1U); i += 2) { uint16_t chunk = buf[i] << 8 | buf[i + 1]; sum += chunk; if (sum > 0xFFFF) { sum -= 0xFFFF; } } // If one byte has left, we also need to add it to the checksum. if (i < buf_size) { sum += buf[i] << 8; if (sum > 0xFFFF) { sum -= 0xFFFF; } } return (sum); } } }