From 00f3bcea0531f50be49793f9c51bf370756aa55b Mon Sep 17 00:00:00 2001
From: Stefano Brivio <sbrivio@redhat.com>
Date: Thu, 18 Mar 2021 12:56:03 +0100
Subject: passt: Add the README

Signed-off-by: Stefano Brivio <sbrivio@redhat.com>
---
 README.md | 177 ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
 1 file changed, 177 insertions(+)
 create mode 100644 README.md

(limited to 'README.md')

diff --git a/README.md b/README.md
new file mode 100644
index 0000000..48f4f6d
--- /dev/null
+++ b/README.md
@@ -0,0 +1,177 @@
+# passt: Plug A Simple Socket Transport
+
+_passt_ implements a translation layer between a Layer-2 network interface (tap)
+and native Layer-4 sockets (TCP, UDP, ICMP/ICMPv6 echo) on a host. It doesn't
+require any capabilities or privileges, and it can be used as a simple
+replacement for Slirp.
+
+- [General idea](#general-idea)
+- [Non-functional Targets](#non-functional-targets)
+- [Interfaces and Environment](#interfaces-and-environment)
+- [Services](#services)
+- [Addresses](#addresses)
+- [Protocols](#protocols)
+- [Ports](#ports)
+- [Try it](#try-it)
+- [Contribute](#contribute)
+
+## General idea
+
+When container workloads are moved to virtual machines, the network traffic is
+typically forwarded by interfaces operating at data link level. Some components
+in the containers ecosystem (such as _service meshes_), however, expect
+applications to run locally, with visible sockets and processes, for the
+purposes of socket redirection, monitoring, port mapping.
+
+To solve this issue, user mode networking as provided e.g. by _Slirp_,
+_libslirp_, _slirp4netns_ can be used. However, these existing solutions
+implement a full TCP/IP stack, replaying traffic on sockets that are local to
+the pod of the service mesh. This creates the illusion of application processes
+running on the same host, eventually separated by user namespaces.
+
+While being almost transparent to the service mesh infrastructure, that kind of
+solution comes with a number of downsides:
+
+* three different TCP/IP stacks (guest, adaptation and host) need to be
+  traversed for every service request. There are no chances to implement
+  zero-copy mechanisms, and the amount of context switches increases
+  dramatically
+* addressing needs to be coordinated to create the pretense of consistent
+  addresses and routes between guest and host environments. This typically needs
+  a NAT with masquerading, or some form of packet bridging
+* the traffic seen by the service mesh and observable externally is a distant
+  replica of the packets forwarded to and from the guest environment:
+  * TCP congestion windows and network buffering mechanisms in general operate
+    differently from what would be naturally expected by the application
+  * protocols carrying addressing information might pose additional challenges,
+    as the applications don't see the same set of addresses and routes as they
+    would if deployed with regular containers
+
+_passt_ implements a thinner layer between guest and host, that only implements
+what's strictly needed to pretend processes are running locally. A further, full
+TCP/IP stack is not necessarily needed. Some sort of TCP adaptation is needed,
+however, as this layer runs without the `CAP\_NET\_RAW` capability: we can't
+create raw IP sockets on the pod, and therefore need to map packets at Layer-2
+to Layer-4 sockets offered by the host kernel.
+
+The problem and this approach are illustrated in more detail, with diagrams,
+[here](https://gitlab.com/abologna/kubevirt-and-kvm/-/blob/master/Networking.md).
+
+## Non-functional Targets
+
+Security and maintainability goals:
+
+* no dynamic memory allocation
+* ~2 000 LoC target
+* no external dependencies
+
+## Interfaces and Environment
+
+_passt_ exchanges packets with _qemu_ via UNIX domain socket, using the `socket`
+back-end in qemu. Currently, qemu can only connect to a listening process via
+TCP. Two temporary solutions are available:
+
+* a [patch](https://passt.top/passt/tree/qemu) for qemu
+* a wrapper, [qrap](https://passt.top/passt/tree/qrap.c), that connects to a
+  UNIX domain socket and starts qemu, which can now use the file descriptor
+  that's already opened
+
+This approach, compared to using a _tap_ device, doesn't require any security
+capabilities, as we don't need to create any interface.
+
+## Services
+
+_passt_ provides some minimalistic implementations of networking services that
+can't practically run on the host:
+
+* [ARP proxy](https://passt.top/passt/tree/arp.c), that resolve the address of
+  the host (which is used as gateway) to the original MAC address of the host
+* [DHCP server](https://passt.top/passt/tree/dhcp.c), a simple implementation
+  handing out one single IPv4 address to the guest, namely, the same address as
+  the first one configured for the upstream host interface, and passing the
+  nameservers configured on the host
+* [NDP proxy](https://passt.top/passt/tree/ndp.c), which can also assign prefix
+  and nameserver using SLAAC
+* _to be done_: DHCPv6 server: right now, the guest gets the same _prefix_ as
+  the host, but not the same address, because the suffix is generated from the
+  MAC address of the virtual machine, so we currently have to translate packet
+  addresses back and forth. With a DHCPv6 server, we could simply assign the
+  host address to the guest
+
+## Addresses
+
+For IPv4, the guest is assigned, via DHCP, the same address as the upstream
+interface of the host, and the same default gateway as the default gateway of
+the host. Addresses are never translated.
+
+For IPv6, the guest is assigned, via SLAAC, the same prefix as the upstream
+interface of the host, and the same default route as the default route of the
+host. This means that the guest will typically have a different address, and
+the destination address is translated for packets going to the guest. This will
+be avoided in the future once a minimalistic DHCPv6 server is implemented in
+_passt_.
+
+## Protocols
+
+_passt_ supports TCP, UDP and ICMP/ICMPv6 echo (requests and replies). More
+details about the TCP implementation are available
+[here](https://passt.top/passt/tree/tcp.c), and for the UDP
+implementation [here](https://passt.top/passt/tree/udp.c).
+
+An IGMP proxy is currently work in progress.
+
+## Ports
+
+To avoid the need for explicit port mapping configuration, _passt_ binds to all
+unbound non-ephemeral (0-49152) TCP ports and all unbound (0-65536) UDP ports.
+Binding to low ports (0-1023) will fail without additional capabilities, and
+ports already bound (service proxies, etc.) will also not be used.
+
+Service proxies and other services running in the container need to be started
+before _passt_ starts.
+
+## Try it
+
+* build from source:
+
+        git clone https://passt.top/passt
+        cd passt
+        make
+
+* a static build for x86_64 as of the latest commit is also available for
+  convenience [here](https://passt.top/builds/static/). These binaries are
+  simply built with:
+
+        CFLAGS="-static" make
+
+* run the demo script, that creates a network namespace called `passt`, sets up
+  sets up a _veth_ pair and and addresses, together with NAT for IPv4 and NDP
+  proxying for IPv6, then starts _passt_ in the network namespace:
+
+        doc/demo.sh
+
+* from the same network namespace, start qemu. At the moment, qemu doesn't
+  support UNIX domain sockets for the `socket` back-end. Two alternatives:
+
+  * use the _qrap_ wrapper, which maps a tap socket descriptor to _passt_'s
+    UNIX domain socket, for example:
+
+            ip netns exec passt ./qrap 5 qemu-system-x86_64 ... -net socket,fd=5 -net nic,model=virtio ...
+
+  * or patch qemu with [this patch](https://passt.top/passt/tree/qemu/0001-net-Allow-also-UNIX-domain-sockets-to-be-used-as-net.patch)
+    and start it like this:
+
+            qemu-system-x86_64 ... -net socket,connect=/tmp/passt.socket -net nic,model=virtio
+
+* and that's it, you should now have TCP connections, UDP, and ICMP/ICMPv6
+  echo working from/to the guest for IPv4 and IPv6
+
+* to connect to a service on the VM, just connect to the same port directly
+  with the address of the network namespace. For example, to ssh to the guest,
+  from the main namespace on the host:
+
+        ssh 192.0.2.2
+
+## Contribute
+
+Send patches and issue reports to [sbrivio@redhat.com](mailto:sbrivio@redhat.com).
-- 
cgit v1.2.3