From d013e222611495d0c6601173757894641ea4311f Mon Sep 17 00:00:00 2001
From: Jan-Erik Rediger <janerik@fnordig.de>
Date: Sat, 4 Mar 2017 17:25:31 +0100
Subject: [PATCH] New post: Send ICMP Echo Replies using eBPF

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+---
+layout: post
+title: "Send ICMP Echo Replies using eBPF"
+date: 04.03.2017 17:25
+---
+
+For my master thesis I am working with eBPF, the [Extended Berkeley Packet Filter](https://www.kernel.org/doc/Documentation/networking/filter.txt).
+By now it is used by several subsystems in the Linux kernel,
+ranging from tracing and seccomp rules to network filtering.
+
+As I am using it for network filtering I wanted a small useful and working example on how to parse
+and resend packets with it.
+Luckily, the hard part of attaching it early in the packet processing pipeline is already handled by `tc`,
+Linux' traffic control utility from the iproute2 project.
+
+However, it took me a while to get a reliably working ICMP ping-pong example to work.
+Now that I have I published it to save others the trouble.  
+The result is online in the [ebpf-icmp-ping][git] repository.
+The rest of the blog post will explain some of the steps in [`bpf.c`](https://github.com/badboy/ebpf-icmp-ping/blob/cf2c1ff5bc16049e64bf8424984d226ecaa468ea/bpf.c) and how it is used.
+
+A subset of C can be compiled to the eBPF bytecode
+and luckily the Clang compiler has a eBPF backend to make it all work.
+
+The usable subset is a lot more restricted than plain C and requires a bit more boilerplate
+to assist the compiler (and Kernel verifier) to produce safe programs.
+All memory access needs to be checked up front.
+Assigning from one part in the passed buffer to another might fail
+(I'm not 100% sure yet whether that's due to restrictions of eBPF or the code generation).
+And you can't have loops, but luckily Clang/LLVM is quite good at unrolling loops with a fixed iteration count.
+
+Let's dive in.
+
+First we define our function and put it in a specific section of the generated ELF file.
+`tc` will know how to pull it out.
+Our function gets a single pointer to a kernel-allocated buffer of the network packet.
+
+~~~c
+SEC("action")
+int pingpong(struct __sk_buff *skb)
+~~~
+
+Accessing data in this buffer can be done using different methods.
+Either read out bytes at specified offsets or rely on the struct definitions of the Kernel.
+We do the latter, but first we need to check that there is enough data.
+If not, we don't do anything.
+
+~~~c
+void *data = (void *)(long)skb->data;
+void *data_end = (void *)(long)skb->data_end;
+
+if (data + sizeof(struct ethhdr) + sizeof(struct iphdr) + sizeof(struct icmphdr) > data_end)
+    return TC_ACT_UNSPEC;
+~~~
+
+Once that is done, the verifier let's us use pointers to the right parts of the buffer
+
+~~~c
+struct ethhdr  *eth  = data;
+struct iphdr   *ip   = (data + sizeof(struct ethhdr));
+struct icmphdr *icmp = (data + sizeof(struct ethhdr) + sizeof(struct iphdr));
+~~~
+
+We do some checks to ensure we have a packet we can handle and then parse out the addresses.
+MAC addresses are 48 bits, so the best is to copy them out.
+
+~~~c
+__u8 src_mac[ETH_ALEN];
+__u8 dst_mac[ETH_ALEN];
+bpf_memcpy(src_mac, eth->h_source, ETH_ALEN);
+bpf_memcpy(dst_mac, eth->h_dest, ETH_ALEN);
+~~~
+
+The IP addresses can be accessed more directly.
+
+~~~c
+__u32 src_ip = ip->saddr;
+__u32 dst_ip = ip->daddr;
+~~~
+
+We can then swap the MAC addresses by storing the other address at the right place.
+
+~~~c
+bpf_skb_store_bytes(skb, offsetof(struct ethhdr, h_source), dst_mac, ETH_ALEN, 0);
+bpf_skb_store_bytes(skb, offsetof(struct ethhdr, h_dest), src_mac, ETH_ALEN, 0);
+~~~
+
+Same goes for the IPs:
+
+~~~c
+bpf_skb_store_bytes(skb, IP_SRC_OFF, &dst_ip, sizeof(dst_ip), 0);
+bpf_skb_store_bytes(skb, IP_DST_OFF, &src_ip, sizeof(src_ip), 0);
+~~~
+
+The IP header is checksummed, but simply swapping a few bytes does not affect the checksum,
+so no need to recalculate it.
+We can then modify the ICMP type, but here we need to calculate the new checksum.
+The Linux kernel provides helper methods for eBPF to do this.
+
+First recalculate the checksum:
+
+~~~c
+__u8 new_type = 0;
+bpf_l4_csum_replace(skb, ICMP_CSUM_OFF, ICMP_PING, new_type, ICMP_CSUM_SIZE);
+~~~
+
+Then insert the actual data (the order is not relevant here).
+
+~~~c
+bpf_skb_store_bytes(skb, ICMP_TYPE_OFF, &new_type, sizeof(new_type), 0);
+~~~
+
+Last but not least we need to redirect the packet back out the same network interface it came in.
+This is done using another helper function:
+
+~~~c
+bpf_clone_redirect(skb, skb->ifindex, 0);
+~~~
+
+The last argument specifies the direction, where `0` is `tx`, and thus outgoing and `1` is `rx`, thus incoming.
+Finally we set a return code to inform the kernel that the packet should not be processed any further.
+
+The full code is in [`bpf.c`](https://github.com/badboy/ebpf-icmp-ping/blob/cf2c1ff5bc16049e64bf8424984d226ecaa468ea/bpf.c).
+
+To use this code we first need a `qdisc` to attach this program to as an action.
+
+~~~bash
+tc qdisc add dev eth0 ingress handle ffff:
+~~~
+
+Then we can attach the classifier (which does nothing) and our action (the ICMP pong) to the create ingress queue:
+
+~~~bash
+tc filter add dev eth0 parent ffff: bpf obj bpf.o sec classifier flowid ffff:1 \
+  action bpf obj bpf.o sec action ok
+~~~
+
+If all worked correctly, `tc` can show some info:
+
+~~~bash
+$ tc filter show dev eth0 ingress
+filter parent ffff: protocol all pref 49152 bpf
+filter parent ffff: protocol all pref 49152 bpf handle 0x1 flowid ffff:1 bpf.o:[classifier]
+        action order 1: bpf bpf.o:[action] default-action pass
+        index 30 ref 1 bind 1
+~~~
+
+If you enabled the debug print, the output can be viewed as well:
+
+~~~bash
+$ tc exec bpf dbg
+Running! Hang up with ^C!
+
+  <idle>-0  [000] ..s. 81710.218035: : [action] IP Packet, proto= 1, src= 20490432, dst= 1714989248
+~~~
+
+And that's it.
+`ICMP Echo Requests` are now handled inside the kernel using eBPF and never travel through the rest of the network stack.
+
+[git]: https://github.com/badboy/ebpf-icmp-ping