341 lines
14 KiB
Plaintext
341 lines
14 KiB
Plaintext
ndhc, Copyright (C) 2004-2015 Nicholas J. Kain.
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See LICENSE for licensing information. In short: Two-clause / New BSD.
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Requirements:
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Linux kernel
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GNU Make (tested: 3.82) or CMake (tested: 2.8)
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Ragel (tested: 6.7)
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INTRODUCTION
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------------
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ndhc is a multi-process, privilege-separated dhcp client. Each subprocess runs
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with the minimal necessary privileges in order to perform its task. Currently,
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ndhc consists of three subprocesses: the ndhc-master, ndhc-ifch, and
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ndhc-sockd.
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ndhc-master communicates with dhcp servers and handles the vagaries of the dhcp
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client protocol. It runs as a non-root user inside a chroot. ndhc runs as a
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normal user with no special privileges and is restricted to a chroot that
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contains nothing more than a domain socket filesystem object (if using syslog),
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a urandom device node, and a null device node.
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ndhc-ifch handles interface change requests. It listens on a unix socket for
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such requests. ndhc-ifch runs as a non-root user inside a chroot, and retains
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only the power to configure network interfaces. ndhc-ifch automatically forks
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from ndhc-master to perform its job.
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ndhc-sockd plays a similar role to ndhc-ifch, but it instead has the ability to
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bind to a low port, the ability to open a raw socket, and the ability to
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communicate on broadcast channels. ndhc communicates with ndhc-sockd
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over a unix socket, and the file descriptors that ndhc-sockd creates are
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passed back to ndhc over the unix socket.
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ndhc fully implements RFC5227's address conflict detection and defense. Great
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care is taken to ensure that address conflicts will be detected, and ndhc also
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has extensive support for address defense. Care is taken to prevent
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unintentional ARP flooding under any circumstance.
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ndhc also monitors hardware link status via netlink events and reacts
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appropriately when interface carrier status changes or an interface is
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explicitly deconfigured. This functionality can be useful on wired networks
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when transient carrier downtimes occur (or cables are changed), but it is
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particularly useful on wireless networks.
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RFC3927's IPv4 Link Local Addressing is not supported. I have found v4 LLAs
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to be more of an annoyance than a help. v6 LLAs work much better in practice.
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FEATURES
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--------
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Privilege-separated. ndhc does not run as root after initial startup, and
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capabilities are divided between the subprocesses. All processes run in a
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chroot.
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Robust. ndhc performs no runtime heap allocations -- malloc() (more
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specifically, brk(), mmap(), etc) is never called after initialization (libc
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behavior during initialization time will vary), and ndhc never performs
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recursive calls and only stack-allocates fixed-length types, so stack depth is
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bounded, too.
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Active defense of IP address and IP collision avoidance. ndhc fully implements
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RFC5227. It is capable of both a normal level of tenacity in defense, where
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it will eventually back off and request a new lease if a peer won't relent
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in the case of a conflict, and of relentlessly defending a lease forever. In
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either mode, it rate-limits defense messages, so it can't be tricked into
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flooding by a hostile peer or DHCP server, either.
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Small. Both ndhc avoids unnecessary outside dependencies and is written in
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plain C.
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Fast. ndhc filters input using the BPF/LPF mechanism so that uninteresting
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packets are dropped by the operating system before ndhc even sees the data.
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ndhc also only listens to DHCP traffic when it's necessary.
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Flexible. ndhc can request particular IPs, send user-specified client IDs,
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write a file that contains the current lease IP, write PID files, etc.
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Self-contained. ndhc does not exec other processes, or rely on the shell.
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Further, ndhc relies on no external libraries aside from the system libc.
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Aware of the hardware link status. If you disconnect an interface on which
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ndhc is providing dhcp service, it will be aware. When the link status
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returns, ndhc will fingerprint the reconnected network and make sure that it
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corresponds to the one on which it has a lease. If the new network is
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different, it will forget about the old lease and request a new one.
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USAGE
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-----
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1) Compile and install ndhc.
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a) make
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b) Install the build/ndhc executable in a normal place. I would suggest
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/usr/sbin or /usr/local/sbin.
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1alt) Compile and install ndhc.
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a) Create a build directory:
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mkdir build && cd build
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b) Create the makefiles:
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cmake ..
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c) Build ndhc:
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make
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d) Install the ndhc/ndhc executable in a normal place. I would suggest
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/usr/sbin or /usr/local/sbin.
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2) Time to create the jail in which ndhc will run.
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a) Become root and create new group "ndhc".
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$ su -
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# umask 077
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# groupadd ndhc
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b) Create new users "dhcpifch" and "dhcp". The primary group of these
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users should be "ndhc".
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# useradd -d /var/lib/ndhc -s /sbin/nologin -g ndhc dhcpsockd
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# useradd -d /var/lib/ndhc -s /sbin/nologin -g ndhc dhcpifch
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# useradd -d /var/lib/ndhc -s /sbin/nologin -g ndhc dhcp
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c) Create the state directory where DUIDs and IAIDs will be stored.
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# mkdir /etc/ndhc
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# chown root.root /etc/ndhc
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# chmod 0755 /etc/ndhc
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d) Create the jail directory and set its ownership properly.
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# mkdir /var/lib/ndhc
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# chown root.root /var/lib/ndhc
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# chmod a+rx /var/lib/ndhc
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# cd /var/lib/ndhc
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# mkdir var
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# mkdir var/state
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# mkdir var/run
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# chown -R dhcp.ndhc var
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# chmod -R a+rx var
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# chmod g+w var/run
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e) Create a urandom device for ndhc to use within the jail.
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# mkdir dev
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# mknod dev/urandom c 1 9
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# mknod dev/null c 1 3
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# chown -R root.root dev
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# chmod a+rx dev
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# chmod a+r dev/urandom
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# chmod a+rw dev/null
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f) (optional) If you wish for logging to properly work, you
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will need to properly configure your logging daemon so that it
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opens a domain socket in the proper location within the jail.
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Since this varies per-daemon, I cannot provide a general
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configuration.
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3) At this point the jail is usable; ndhc is ready to be used. An example
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of invoking ndhc:
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# ndhc -i wan0 -u dhcp -U dhcpifch -D dhcpsockd -C /var/lib/ndhc
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4o) If you encounter problems, I suggest running ndhc in the foreground and
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examining the printed output.
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BEHAVIOR NOTES
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--------------
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ndhc does not enable updates of the local hostname and resolv.conf by default.
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If you wish to enable these functions, use the --resolve (-R) and --hostname
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(-H) flags. See ndhc --help.
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STATE STORAGE NOTES
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-------------------
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ndhc requires a read/writable directory to store the DUID/IAID states. By
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default this directory is /etc/ndhc. It exists outside the chroot. The DUID
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will be stored in a single file, DUID. The IAIDs exist per-interface and are
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stored in files with names similar to IAID-xx:xx:xx:xx:xx:xx, where the xx
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values are replaced by the Ethernet hardware address of the interface.
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If it is impossible to read or store the DUIDs or IAIDs, ndhc will
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fail at start time before it performs any network activity or forks any
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subprocesses.
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If the host system lacks volatile storage, then a clientid should manually
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be specified using the -I or --clientid command arguments.
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RANDOMNESS NOTES
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----------------
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Each ndhc subprocess maintains a PCG PRNG that is uniquely seeded from the
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kernel random device at startup. Each PRNG consumes 128 bits of entropy for
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its initial state.
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DHCP does not require cryptographic randomness, so this arrangement should
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be more than sufficient to ensure proper UUIDs, assuming only that the
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kernel random device is even minimally seeded with real entropy.
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PORTING NOTES
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-------------
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DHCP clients aren't naturally very portable. It's necessary to perform a lot
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of tasks that are platform-specific. ndhc is rather platform-dependent, and it
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extensively uses Linux-specific features. Some of these features are also
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available on the BSDs.
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1) ndhc takes advantage of Linux capabilities so that it does not need full
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root privileges. Capabilities were a proposed POSIX feature that was not made
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part of the official standard, so any implemention that may exist will be
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system-dependent.
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2) ndhc configures network interfaces and routes. Interface and route
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configuration is entirely non-portable.
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3) ndhc uses netlink sockets extensively for fetching data, setting data,
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and hardware link state change notification events.
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4) ndhc uses the Berkeley Packet Filter / Linux Packet Filter interfaces to
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drop unwanted packets in kernelspace. This functionality is available on
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most modern unix systems, but it is not standard.
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5) ndhc uses epoll() and signalfd(). These are Linux-specific.
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6) Numerous socket options are used, and the AF_PACKET socket family is used
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for raw sockets and ARP. These are largely Linux-specific, too.
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7) ndhc can optionally use seccomp-filter to allow only a set of whitelisted
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syscalls. This functionality is Linux-specific.
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HISTORY
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-------
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I started writing ndhc back in 2004. My ISP at the time required a dhcp
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client for connection authentication, and I was not comfortable with any
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of the existing clients, which all ran as root and had colorful security
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histories. DHCP is generally not a routed protocol, and lacks real
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authentication mechanisms in real world deployments (some largely
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abandoned RFCs for such behavior do exist), so no program existed to
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fill the niche of a truly secure DHCP client.
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My router/server at the time ran a custom Linux distro that was designed
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for extreme security. A root privileged DHCP client would be nearly the
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only root-owned process running on the machine, so I was highly motivated
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to develop an alternative.
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A separate ifchd was first written entirely from scratch. It did not take long
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to write, since it was by design rather simple, and I was already familiar with
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the quirks of Linux capabilities. That left me with the choice of adapting an
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existing DHCP client or writing my own from scratch.
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At the time, I just wanted something that would work, so my choice was to
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adapt udhcpc to work with ifchd. udhcpc was chosen since it was intended to
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be used with resource-constrained or embedded systems, and was thus very
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small. ISC dhclient was another alternative, but it is an extremely large
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program, and it would have been very hard to audit it for correctness.
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udhcpc was not did not really fit my requirements well, since it was designed
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to be small at all costs, sacrificing correctness when necessary. The code was
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hard to follow, and had many quirks. Bounds-checking was rare, type aliasing
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common, and state transitions were convoluted. Not all of the client was
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asynchronous, and no precautions were taken against conflicting peers. ARP was
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not used at all.
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However, it was small. With a lot of work, I ripped out the script-calling
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mechanisms and replaced them with ifchd requests. Bounds-checking was
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aggressively (and somewhat hamfistedly) retrofitted into the code. It was
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cleaned to a degree, and importantly it worked for connecting to my ISP.
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Then I changed ISPs. My new ISP used PPPoE, not dhcp. Around the same time, I
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also switched to using Gentoo rather than a hand-built distribution. I didn't
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have time to maintain the old custom setup, and it was very hard keeping up
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with library vulnerabilties in eg, zlib or openssl, and ensuring that all
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installed binaries, dynamic and static, were updated. ndhc was abandoned for
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many years. It wasn't needed on my server, and it was "too much effort" to
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deviate from the stock distro dhcp clients on other machines.
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Then, around 2008, I changed ISPs again. This time my new ISP used dhcp and
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not PPPoE. So, after a few months, I decided to dust off the old ndhc/ifchd
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project and adapt it to my modern standards and machines.
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ifchd was in good shape and required little work. I ended up rewriting
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ndhc. The only parts that remained from the original were the parts that
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I had already rewritten before, and some of those were rewritten, too.
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Eventually ifchd was rewritten to extensively use a Ragel-generated DFA-based
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parser to make it easier to verify correct behavior for all possible inputs.
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Quite a while later, I eventually merged ifchd into the same binary as ndhc
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and instead rely on forking subprocesses and using socketpairs for IPC. This
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brought a lot of simplifications, particularly for user configuration.
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Afterwards, privilege seperation was applied to the remaining capabilities,
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creating the ndhc-sockd subprocess. After this change, the main ndhc
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process runs completely unprivileged.
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The end result is a modern DHCP client is largely RFC-compliant, except where
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the RFCs dictate behavior that would be problematic, overly complex, useless,
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or exploitable. DHCP is poorly specified, and real-world servers and clients
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vary a lot from the RFCs, so these conditions are necessary for a useful
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program.
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Although ndhc's implementation and behavior are different, I have to credit
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the idea of using netlink events to discover hardware link status transitions
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to Stefan Rompf and his 'dhcpclient' program. The Linux netlink events that
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are used are otherwise rather obscure and poorly documented, and I wouldn't
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have known about them otherwise.
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GRSECURITY NOTES
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----------------
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Make sure that CONFIG_GRKERNSEC_CHROOT_CAPS is disabled. Otherwise, ndhc will
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lose its capabilities (in particular, the ability to reconfigure interfaces)
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when it chroots.
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DHCP PROTOCOL QUIRKS
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--------------------
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Send a packet that has an options field set to:
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'DHCP-OPTION-OVERLOAD:3'
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Then in the file and sname fields:
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'DHCP-OPTION-OVERLOAD:3'
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I suspect some bad dhcp programs will hang given this input.
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DHCP explicitly specifies that there is no minimum lease time and also
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specifies that the minimum default rebinding time is leasetime*0.875 and
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the minimum default renewing time is leasetime*0.500. All times are relative
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to the instant when the lease is bound and are specified in seconds. Taken
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together, this means that a client strictly implementing the RFC should
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accept a lease that either is perpetually rebinding (lease == 1s) or instantly
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expires (lease == 0s). ndhc ignores the RFC and specifies a minimum lease
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time of one minute.
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Renew and rebind times are optionally specified and may take on any value.
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This means that a malicious server could demand a rebind time before a renew
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time, or make these times ridiculously short, or specify both times past
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that of the lease duration. ndhc avoids all of this nonsense by simply
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ignoring these options and using the default values specified by the RFC.
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There are other quirks, but these are just several interesting ones that
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immediately occur to me while I'm writing this document.
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