docs: Logging Packets (#47)

Signed-off-by: Dave Tucker <dave@dtucker.co.uk>
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Dave Tucker 3 years ago committed by GitHub
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docs/.gitignore vendored

@ -1 +1,3 @@
book book
# example application
myapp-*

@ -4,3 +4,6 @@ language = "en"
multilingual = false multilingual = false
src = "src" src = "src"
title = "Building eBPF Programs With Aya" title = "Building eBPF Programs With Aya"
[rust]
edition = "2018"

@ -4,4 +4,5 @@
- [eBPF Program Limitiations](./ebpf/index.md) - [eBPF Program Limitiations](./ebpf/index.md)
- [Getting Started](./start/index.md) - [Getting Started](./start/index.md)
- [Development Environment](./start/development.md) - [Development Environment](./start/development.md)
- [Hello XDP!](./start/hello-xdp.md) - [Hello XDP!](./start/hello-xdp.md)
- [Logging Packets](./start/logging-packets.md)

@ -14,7 +14,7 @@ Once you have the Rust tool-chains installed, you must also install the `bpf-lin
```console ```console
cargo +nightly install bpf-linker cargo +nightly install bpf-linker
cargo install cargo-generate cargo install --git https://github.com/cargo-generate/cargo-generate
``` ```
## Starting A New Project ## Starting A New Project

@ -135,7 +135,7 @@ fn try_main() -> Result<(), anyhow::Error> {
Let's adapt it to load our program. Let's adapt it to load our program.
We'll need the following imports at the top of the file: We will add a dependency on `ctrlc = "3.2"` to `myapp/Cargo.toml`, then add the following imports at the top of the `myapp/src/main.rs`:
```rust,ignore ```rust,ignore
use aya::Bpf; use aya::Bpf;
@ -145,6 +145,8 @@ use std::{
env, env,
thread, thread,
time::Duration, time::Duration,
sync::Arc,
sync::atomic::{AtomicBool, Ordering},
}; };
``` ```
@ -164,13 +166,22 @@ fn try_main() -> Result<(), anyhow::Error> {
let probe: &mut Xdp = bpf.program_mut("xdp")?.try_into()?; let probe: &mut Xdp = bpf.program_mut("xdp")?.try_into()?;
probe.load()?; probe.load()?;
probe.attach(&iface, XdpFlags::default())?; probe.attach(&iface, XdpFlags::default())?;
for _i in 1..10 {
thread::sleep(Duration::from_secs(1)); let running = Arc::new(AtomicBool::new(true));
}; let r = running.clone();
ctrlc::set_handler(move || {
r.store(false, Ordering::SeqCst);
}).expect("Error setting Ctrl-C handler");
println!("Waiting for Ctrl-C...");
while running.load(Ordering::SeqCst) {}
println!("Exiting...");
Ok(()) Ok(())
} }
``` ```
The program takes two positional arguments The program takes two positional arguments
- The path to our eBPF application - The path to our eBPF application
- The interface we wish to attach it to (defaults to `eth0`) - The interface we wish to attach it to (defaults to `eth0`)
@ -188,22 +199,24 @@ Finally, we can attach it to an interface with `probe.attach(&iface, XdpFlags::d
Let's try it out! Let's try it out!
```console ```console
cargo build $ cargo build
sudo ./target/debug/myapp ./target/bpfel-unknown-none/debug/myapp wlp2s0 $ sudo ./target/debug/myapp ./target/bpfel-unknown-none/debug/myapp wlp2s0
Waiting for Ctrl-C...
Exiting...
``` ```
That was uneventful. Did it work? That was uneventful. Did it work?
### The Lifecycle of an eBPF Program > 💡 **HINT: Error Loading Program?**
>
> If you get an error loading the program, try changing `XdpFlags::default()` to `XdpFlags::SKB_MODE`
You'll notice that our program ends by sleeping for 10 seconds and you may even have wondered what this is for... ### The Lifecycle of an eBPF Program
When you load an eBPF program or map in to the kernel, the kernel maintains a reference count. The program runs until CTRL+C is pressed and then exits.
So, when our eBPF application is loaded, the kernel returns a file descriptor and the reference count is incremented. On exit, Aya takes care of detaching the program for us.
When our program terminates, the file descriptor is closed, the reference count is decremented and the memory (eventually) freed.
You can see this when by issuing the `sudo bpftool prog list` command when `myapp` is running: If you issue the `sudo bpftool prog list` command when `myapp` is running you can verify that it is loaded:
```console ```console
84: xdp tag 3b185187f1855c4c gpl 84: xdp tag 3b185187f1855c4c gpl
@ -212,4 +225,4 @@ You can see this when by issuing the `sudo bpftool prog list` command when `myap
pids myapp(69184) pids myapp(69184)
``` ```
For our firewall to work once the user-space program has exited, we'll need to pin it to the BPF FS. Running the command again once `myapp` has exited will show that the program is no longer running.

@ -0,0 +1,315 @@
# Logging Packets
In the previous chapter, our XDP application ran for 10 seconds and permitted some traffic.
There was however no output on the console, so you just have to trust that it was working correctly. Let's expand this program to log the traffic that is being permitted
## Getting Data to User-Space
### Sharing Data
To get data from kernel-space to user-space we use an eBPF map. There are numerous types of maps to chose from, but in this example we'll be using a PerfEventArray.
While we could go all out and extract data all the way up to L7, we'll constrain our firewall to L3, and to make things easier, IPv4 only.
The data structure that we'll need to send information to user-space will need to hold an IPv4 address and an action for Permit/Deny, we'll encode both as a `u32`.
Let's go ahead and add that to `myapp-common/src/lib.rs`
```rust,ignore
#[repr(C)]
pub struct PacketLog {
pub ipv4_address: u32,
pub action: u32,
}
#[cfg(feature = "user")]
unsafe impl aya::Pod for PacketLog {}
```
> 💡 **HINT: Struct Alignment**
>
> Structs must be aligned to 8 byte boundaries. You can do this manually, or alternatively you may use `#[repr(packed)]`. If you do not do this, the eBPF verifier will get upset and emit an `invalid indirect read from stack` error.
We implement the `aya::Pod` trait for our struct since it is Plain Old Data as can be safely converted to a byte-slice and back.
### eBPF: Map Creation
Let's create a map called `EVENTS` in `myapp-ebpf/src/main.rs`
```rust,ignore
use aya_bpf::macros::map;
use aya_bpf::maps::PerfMap;
use myapp_common::PacketLog;
#[map(name = "EVENTS")]
static mut EVENTS: PerfMap<PacketLog> = PerfMap::<PacketLog>::with_max_entries(1024, 0);
```
When the eBPF program is loaded by Aya, the map will be created for us.
### Userspace: Map Creation
After our call to `probe.attach()` we'll add the following code.
```rust,ignore
use aya::maps::AsyncPerfEventArray;
let mut perf_array = AsyncPerfEventArray::try_from(bpf.map_mut("EVENTS")?)?;
```
Our `perf_array` is a mutable reference to the map that was created after the XDP program was loaded by Aya.
## Writing Data
Now we've got our maps set up, let's add some data!
### Generating Bindings To vmlinux.h
To get useful data to add to our maps, we first need some useful data structures to populate with data from the `XdpContext`.
We want to log the Source IP Address of incoming traffic, so we'll need to:
1. Read the Ethernet Header to determine if this is an IPv4 Packet
1. Read the Source IP Address from the IPv4 Header
The two structs in the kernel for this are `ethhdr` from `uapi/linux/if_ether.h` and `iphdr` from `uapi/linux/ip.h`.
If I were to use bindgen to generate Rust bindings for those headers, I'd be tied to the kernel version of the system that I'm developing on.
This is where `aya-gen` comes in to play. It can easily generate bindings for using the BTF information in `/sys/kernel/btf/vmlinux`.
Once the bindings are generated and checked in to our repository they shouldn't need to be regenerated again unless we need to add a new struct.
Lets use `xtask` to automate this so we can easily reproduce this file in future.
We'll add the following content to `xtask/src/codegen.rs`
```rust,ignore
use aya_gen::btf_types;
use std::{
fs::File,
io::Write,
path::{Path, PathBuf},
};
pub fn generate() -> Result<(), anyhow::Error> {
let dir = PathBuf::from("myapp-ebpf/src");
let names: Vec<&str> = vec!["ethhdr", "iphdr"];
let bindings = btf_types::generate(Path::new("/sys/kernel/btf/vmlinux"), &names, false)?;
// Write the bindings to the $OUT_DIR/bindings.rs file.
let mut out = File::create(dir.join("bindings.rs"))?;
write!(out, "{}", bindings).expect("unable to write bindings to file");
Ok(())
}
```
This will generate a file called `myapp-ebpf/src/bindings.rs`. If you've chosen an application name other than `myapp` you'll need to adjust the path appropriately.
Add a new dependencies to `xtask/Cargo.toml`:
```toml
[dependencies]
aya-gen = { git = "http://github.com/alessandrod/aya", branch = "main" }
```
And finally, we must register the command in `xtask/src/main.rs`:
```rust,ignore
mod build_ebpf;
mod codegen;
use std::process::exit;
use structopt::StructOpt;
#[derive(StructOpt)]
pub struct Options {
#[structopt(subcommand)]
command: Command,
}
#[derive(StructOpt)]
enum Command {
BuildEbpf(build_ebpf::Options),
Codegen,
}
fn main() {
let opts = Options::from_args();
use Command::*;
let ret = match opts.command {
BuildEbpf(opts) => build_ebpf::build(opts),
Codegen => codegen::generate(),
};
if let Err(e) = ret {
eprintln!("{:#}", e);
exit(1);
}
}
```
Once we've generated our file using `cargo xtask codegen` from the root of the project.
These can then be accessed from within `myapp-ebpf/src/main.rs`:
```rust,ignore
mod bindings;
use bindings::{ethhdr, iphdr};
```
### Getting Packet Data From The Context
The `XdpContext` contains two fields, `data` and `data_end`.
`data` is a pointer to the start of the data in kernel memory and `data_end`, a pointer to the end of the data in kernel memory. In order to access this data and ensure that the eBPF verifier is happy, we'll introduce a helper function:
```rust,ignore
#[inline(always)]
unsafe fn ptr_at<T>(ctx: &XdpContext, offset: usize) -> Result<*const T, ()> {
let start = ctx.data();
let end = ctx.data_end();
let len = mem::size_of::<T>();
if start + offset + len > end {
return Err(());
}
Ok((start + offset) as *const T)
}
```
This function will ensure that before we access any data, we check that it's contained between `data` and `data_end`.
It is marked as `unsafe` because when calling the function, you must ensure that there is a valid `T` at that location or there will be undefined behaviour.
### Writing Data To The Map
With our helper function in place, we can:
1. Read the Ethertype field to check if we have an IPv4 packet.
1. Read the IPv4 Source Address from the IP header
First let's add another dependency on `memoffset = "0.6"` to `myapp-ebpf/Cargo.toml`, and then we'll change our `try_xdp_firewall` function to look like this:
```rust,ignore
use memoffset::offset_of;
fn try_xdp_firewall(ctx: XdpContext) -> Result<u32, ()> {
let h_proto = u16::from_be(unsafe { *ptr_at(&ctx, offset_of!(ethhdr, h_proto))? });
if h_proto != ETH_P_IP {
return Ok(xdp_action::XDP_PASS)
}
let source = u32::from_be(unsafe { *ptr_at(&ctx, ETH_HDR_LEN + offset_of!(iphdr, saddr))? });
let log_entry = PacketLog{
ipv4_address: source,
action: xdp_action::XDP_PASS,
};
unsafe { EVENTS.output(&ctx, &log_entry, 0); }
Ok(xdp_action::XDP_PASS)
}
```
> 💡 **HINT: Reading Fields Using `offset_of!`**
>
> As there is limited stack space, it's more memory efficient to use the `offset_of!` macro to read
> a single field from a struct, rather than reading the whole struct and accessing the field by name.
Once we have our IPv4 source address, we can create a `PacketLog` struct and output this to our PerfEventArray
## Reading Data
### Going Async
In order to read from the `AsyncPerfEventArray`, we have to call `AsyncPerfEventArray::open()` for each online CPU, then we have to poll the file descriptor for events.
While this is do-able using `PerfEventArray` and `mio` or `epoll`, the code is much less easy to follow. Instead, we'll use `tokio` to make our user-space application async.
Let's add some dependencies to `myapp/src/Cargo.toml`:
```toml
[dependencies]
aya = { git = "https://github.com/alessandrod/aya", branch="main", features=["async_tokio"] }
myapp-common = { path = "../myapp-common", features=["userspace"] }
anyhow = "1.0.42"
bytes = "1"
tokio = { version = "1.9.0", features = ["full"] }
```
And adjust our `myapp/src/main.rs` to look like this:
```rust,ignore
use aya::{
maps::perf::AsyncPerfEventArray,
programs::{Xdp, XdpFlags},
util::online_cpus,
Bpf,
};
use bytes::BytesMut;
use std::{
convert::{TryFrom, TryInto},
env, fs, net,
};
use tokio::{signal, task};
use myapp_common::PacketLog;
#[tokio::main]
async fn main() -> Result<(), anyhow::Error> {
let path = match env::args().nth(1) {
Some(iface) => iface,
None => panic!("not path provided"),
};
let iface = match env::args().nth(2) {
Some(iface) => iface,
None => "eth0".to_string(),
};
let data = fs::read(path)?;
let mut bpf = Bpf::load(&data, None)?;
let probe: &mut Xdp = bpf.program_mut("xdp")?.try_into()?;
probe.load()?;
probe.attach(&iface, XdpFlags::default())?;
let mut perf_array = AsyncPerfEventArray::try_from(bpf.map_mut("EVENTS")?)?;
for cpu_id in online_cpus()? {
let mut buf = perf_array.open(cpu_id, None)?;
task::spawn(async move {
let mut buffers = (0..10)
.map(|_| BytesMut::with_capacity(1024))
.collect::<Vec<_>>();
loop {
let events = buf.read_events(&mut buffers).await.unwrap();
for i in 0..events.read {
let buf = &mut buffers[i];
let ptr = buf.as_ptr() as *const PacketLog;
let data = unsafe { ptr.read_unaligned() };
let src_addr = net::Ipv4Addr::from(data.ipv4_address);
println!("LOG: SRC {}, ACTION {}", src_addr, data.action);
}
}
});
}
signal::ctrl_c().await.expect("failed to listen for event");
Ok::<_, anyhow::Error>(())
}
```
This will now spawn a `tokio::task` to read each of the `AsyncPerfEventArrayBuffers` contained in out `AsyncPerfEventArray`.
When we receive an event, we use `read_unaligned` to read our data into a `PacketLog`.
We then use `println!` to log the event to the console.
We no longer need to sleep, as we run until we receive the `CTRL+C` signal.
## Running the program
```console
$ cargo build
$ cargo xtask build-ebpf
$ sudo ./target/debug/myapp ./target/bpfel-unknown-none/debug/myapp wlp2s0
LOG: SRC 192.168.1.205, ACTION 2
LOG: SRC 192.168.1.21, ACTION 2
LOG: SRC 192.168.1.21, ACTION 2
LOG: SRC 18.168.253.132, ACTION 2
LOG: SRC 18.168.253.132, ACTION 2
LOG: SRC 18.168.253.132, ACTION 2
LOG: SRC 140.82.121.6, ACTION 2
```
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