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tailscale/derp/xdp/xdp.c

596 lines
16 KiB
C

//go:build ignore
#include <linux/bpf.h>
#include <linux/if_ether.h>
#include <linux/in.h>
#include <linux/ip.h>
#include <linux/ipv6.h>
#include <linux/udp.h>
#include <bpf_endian.h>
#include <bpf_helpers.h>
struct config {
// TODO(jwhited): if we add more fields consider endianness consistency in
// the context of the data. cilium/ebpf uses native endian encoding for map
// encoding even if we use big endian types here, e.g. __be16.
__u16 dst_port;
// If drop_stun is set to a nonzero value all UDP packets destined to
// dst_port will be dropped. This is useful for shedding home client load
// during maintenance.
__u16 drop_stun;
};
struct config *unused_config __attribute__((unused)); // required by bpf2go -type
struct {
__uint(type, BPF_MAP_TYPE_ARRAY);
__uint(key_size, sizeof(__u32));
__uint(value_size, sizeof(struct config));
__uint(max_entries, 1);
} config_map SEC(".maps");
struct counters_key {
__u8 unused;
__u8 af;
__u8 pba;
__u8 prog_end;
};
struct counters_key *unused_counters_key __attribute__((unused)); // required by bpf2go -type
enum counter_key_af {
COUNTER_KEY_AF_UNKNOWN,
COUNTER_KEY_AF_IPV4,
COUNTER_KEY_AF_IPV6,
COUNTER_KEY_AF_LEN
};
enum counter_key_af *unused_counter_key_af __attribute__((unused)); // required by bpf2go -type
enum counter_key_packets_bytes_action {
COUNTER_KEY_PACKETS_PASS_TOTAL,
COUNTER_KEY_BYTES_PASS_TOTAL,
COUNTER_KEY_PACKETS_ABORTED_TOTAL,
COUNTER_KEY_BYTES_ABORTED_TOTAL,
COUNTER_KEY_PACKETS_TX_TOTAL,
COUNTER_KEY_BYTES_TX_TOTAL,
COUNTER_KEY_PACKETS_DROP_TOTAL,
COUNTER_KEY_BYTES_DROP_TOTAL,
COUNTER_KEY_PACKETS_BYTES_ACTION_LEN
};
enum counter_key_packets_bytes_action *unused_counter_key_packets_bytes_action __attribute__((unused)); // required by bpf2go -type
enum counter_key_prog_end {
COUNTER_KEY_END_UNSPECIFIED,
COUNTER_KEY_END_UNEXPECTED_FIRST_STUN_ATTR,
COUNTER_KEY_END_INVALID_UDP_CSUM,
COUNTER_KEY_END_INVALID_IP_CSUM,
COUNTER_KEY_END_NOT_STUN_PORT,
COUNTER_KEY_END_INVALID_SW_ATTR_VAL,
COUNTER_KEY_END_DROP_STUN,
COUNTER_KEY_END_LEN
};
enum counter_key_prog_end *unused_counter_key_prog_end __attribute__((unused)); // required by bpf2go -type
#define COUNTERS_MAP_MAX_ENTRIES ((COUNTER_KEY_AF_LEN - 1) << 16) | \
((COUNTER_KEY_PACKETS_BYTES_ACTION_LEN - 1) << 8) | \
(COUNTER_KEY_END_LEN - 1)
struct {
__uint(type, BPF_MAP_TYPE_PERCPU_HASH);
__uint(key_size, sizeof(struct counters_key));
__uint(value_size, sizeof(__u64));
__uint(max_entries, COUNTERS_MAP_MAX_ENTRIES);
} counters_map SEC(".maps");
struct stunreq {
__be16 type;
__be16 length;
__be32 magic;
__be32 txid[3];
// attributes follow
};
struct stunattr {
__be16 num;
__be16 length;
};
struct stunxor {
__u8 unused;
__u8 family;
__be16 port;
__be32 addr;
};
struct stunxor6 {
__u8 unused;
__u8 family;
__be16 port;
__be32 addr[4];
};
#define STUN_BINDING_REQUEST 1
#define STUN_MAGIC 0x2112a442
#define STUN_ATTR_SW 0x8022
#define STUN_ATTR_XOR_MAPPED_ADDR 0x0020
#define STUN_BINDING_RESPONSE 0x0101
#define STUN_MAGIC_FOR_PORT_XOR 0x2112
#define MAX_UDP_LEN_IPV4 1480
#define MAX_UDP_LEN_IPV6 1460
#define IP_MF 0x2000
#define IP_OFFSET 0x1fff
static __always_inline __u16 csum_fold_flip(__u32 csum) {
__u32 sum;
sum = (csum >> 16) + (csum & 0xffff); // maximum value 0x1fffe
sum += (sum >> 16); // maximum value 0xffff
return ~sum;
}
// csum_const_size is an alternative to bpf_csum_diff. It's a verifier
// workaround for when we are forced to use a constant max_size + bounds
// checking. The alternative being passing a dynamic length to bpf_csum_diff
// {from,to}_size arguments, which the verifier can't follow. For further info
// see: https://github.com/iovisor/bcc/issues/2463#issuecomment-512503958
static __always_inline __u16 csum_const_size(__u32 seed, void* from, void* data_end, int max_size) {
__u16 *buf = from;
for (int i = 0; i < max_size; i += 2) {
if ((void *)(buf + 1) > data_end) {
break;
}
seed += *buf;
buf++;
}
if ((void *)buf + 1 <= data_end) {
seed += *(__u8 *)buf;
}
return csum_fold_flip(seed);
}
static __always_inline __u32 pseudo_sum_ipv6(struct ipv6hdr* ip6, __u16 udp_len) {
__u32 pseudo = 0; // TODO(jwhited): __u64 for intermediate checksum values to reduce number of ops
for (int i = 0; i < 8; i ++) {
pseudo += ip6->saddr.in6_u.u6_addr16[i];
pseudo += ip6->daddr.in6_u.u6_addr16[i];
}
pseudo += bpf_htons(ip6->nexthdr);
pseudo += udp_len;
return pseudo;
}
static __always_inline __u32 pseudo_sum_ipv4(struct iphdr* ip, __u16 udp_len) {
__u32 pseudo = (__u16)ip->saddr;
pseudo += (__u16)(ip->saddr >> 16);
pseudo += (__u16)ip->daddr;
pseudo += (__u16)(ip->daddr >> 16);
pseudo += bpf_htons(ip->protocol);
pseudo += udp_len;
return pseudo;
}
struct packet_context {
enum counter_key_af af;
enum counter_key_prog_end prog_end;
};
static __always_inline int inc_counter(struct counters_key key, __u64 val) {
__u64 *counter = bpf_map_lookup_elem(&counters_map, &key);
if (!counter) {
return bpf_map_update_elem(&counters_map, &key, &val, BPF_ANY);
}
*counter += val;
return bpf_map_update_elem(&counters_map, &key, counter, BPF_ANY);
}
static __always_inline int handle_counters(struct xdp_md *ctx, int action, struct packet_context *pctx) {
void *data_end = (void *)(long)ctx->data_end;
void *data = (void *)(long)ctx->data;
__u64 bytes = data_end - data;
enum counter_key_packets_bytes_action packets_pba = COUNTER_KEY_PACKETS_PASS_TOTAL;
enum counter_key_packets_bytes_action bytes_pba = COUNTER_KEY_BYTES_PASS_TOTAL;
switch (action) {
case XDP_ABORTED:
packets_pba = COUNTER_KEY_PACKETS_ABORTED_TOTAL;
bytes_pba = COUNTER_KEY_BYTES_ABORTED_TOTAL;
break;
case XDP_PASS:
packets_pba = COUNTER_KEY_PACKETS_PASS_TOTAL;
bytes_pba = COUNTER_KEY_BYTES_PASS_TOTAL;
break;
case XDP_TX:
packets_pba = COUNTER_KEY_PACKETS_TX_TOTAL;
bytes_pba = COUNTER_KEY_BYTES_TX_TOTAL;
break;
case XDP_DROP:
packets_pba = COUNTER_KEY_PACKETS_DROP_TOTAL;
bytes_pba = COUNTER_KEY_BYTES_DROP_TOTAL;
break;
}
struct counters_key packets_key = {
.af = pctx->af,
.pba = packets_pba,
.prog_end = pctx->prog_end,
};
struct counters_key bytes_key = {
.af = pctx->af,
.pba = bytes_pba,
.prog_end = pctx->prog_end,
};
inc_counter(packets_key, 1);
inc_counter(bytes_key, bytes);
return 0;
}
#define is_ipv6 (pctx->af == COUNTER_KEY_AF_IPV6)
static __always_inline int handle_packet(struct xdp_md *ctx, struct packet_context *pctx) {
void *data_end = (void *)(long)ctx->data_end;
void *data = (void *)(long)ctx->data;
pctx->af = COUNTER_KEY_AF_UNKNOWN;
pctx->prog_end = COUNTER_KEY_END_UNSPECIFIED;
struct ethhdr *eth = data;
if ((void *)(eth + 1) > data_end) {
return XDP_PASS;
}
struct iphdr *ip;
struct ipv6hdr *ip6;
struct udphdr *udp;
int validate_udp_csum = 0;
if (eth->h_proto == bpf_htons(ETH_P_IP)) {
pctx->af = COUNTER_KEY_AF_IPV4;
ip = (void *)(eth + 1);
if ((void *)(ip + 1) > data_end) {
return XDP_PASS;
}
if (ip->ihl != 5 ||
ip->version != 4 ||
ip->protocol != IPPROTO_UDP ||
(ip->frag_off & bpf_htons(IP_MF | IP_OFFSET)) != 0) {
return XDP_PASS;
}
// validate ipv4 header checksum
__u32 cs_unfolded = bpf_csum_diff(0, 0, (void *)ip, sizeof(*ip), 0);
__u16 cs = csum_fold_flip(cs_unfolded);
if (cs != 0) {
pctx->prog_end = COUNTER_KEY_END_INVALID_IP_CSUM;
return XDP_PASS;
}
if (bpf_ntohs(ip->tot_len) != data_end - (void *)ip) {
return XDP_PASS;
}
udp = (void *)(ip + 1);
if ((void *)(udp + 1) > data_end) {
return XDP_PASS;
}
if (udp->check != 0) {
// https://datatracker.ietf.org/doc/html/rfc768#page-3
// If the computed checksum is zero, it is transmitted as all
// ones (the equivalent in one's complement arithmetic). An all
// zero transmitted checksum value means that the transmitter
// generated no checksum (for debugging or for higher level
// protocols that don't care).
validate_udp_csum = 1;
}
} else if (eth->h_proto == bpf_htons(ETH_P_IPV6)) {
pctx->af = COUNTER_KEY_AF_IPV6;
ip6 = (void *)(eth + 1);
if ((void *)(ip6 + 1) > data_end) {
return XDP_PASS;
}
if (ip6->version != 6 || ip6->nexthdr != IPPROTO_UDP) {
return XDP_PASS;
}
udp = (void *)(ip6 + 1);
if ((void *)(udp + 1) > data_end) {
return XDP_PASS;
}
if (bpf_ntohs(ip6->payload_len) != data_end - (void *)udp) {
return XDP_PASS;
}
// https://datatracker.ietf.org/doc/html/rfc8200#page-28
// Unlike IPv4, the default behavior when UDP packets are
// originated by an IPv6 node is that the UDP checksum is not
// optional. That is, whenever originating a UDP packet, an IPv6
// node must compute a UDP checksum over the packet and the
// pseudo-header, and, if that computation yields a result of
// zero, it must be changed to hex FFFF for placement in the UDP
// header. IPv6 receivers must discard UDP packets containing a
// zero checksum and should log the error.
validate_udp_csum = 1;
} else {
return XDP_PASS;
}
__u32 config_key = 0;
struct config *c = bpf_map_lookup_elem(&config_map, &config_key);
if (!c) {
return XDP_PASS;
}
if (bpf_ntohs(udp->len) != data_end - (void *)udp) {
return XDP_PASS;
}
if (bpf_ntohs(udp->dest) != c->dst_port) {
pctx->prog_end = COUNTER_KEY_END_NOT_STUN_PORT;
return XDP_PASS;
}
if (c->drop_stun) {
pctx->prog_end = COUNTER_KEY_END_DROP_STUN;
return XDP_DROP;
}
if (validate_udp_csum) {
__u16 cs;
__u32 pseudo_sum;
if (is_ipv6) {
pseudo_sum = pseudo_sum_ipv6(ip6, udp->len);
cs = csum_const_size(pseudo_sum, udp, data_end, MAX_UDP_LEN_IPV6);
} else {
pseudo_sum = pseudo_sum_ipv4(ip, udp->len);
cs = csum_const_size(pseudo_sum, udp, data_end, MAX_UDP_LEN_IPV4);
}
if (cs != 0) {
pctx->prog_end = COUNTER_KEY_END_INVALID_UDP_CSUM;
return XDP_PASS;
}
}
struct stunreq *req = (void *)(udp + 1);
if ((void *)(req + 1) > data_end) {
return XDP_PASS;
}
if (req->type != bpf_htons(STUN_BINDING_REQUEST)) {
return XDP_PASS;
}
if (bpf_ntohl(req->magic) != STUN_MAGIC) {
return XDP_PASS;
}
void *attrs = (void *)(req + 1);
__u16 attrs_len = ((char *)data_end) - ((char *)attrs);
if (bpf_ntohs(req->length) != attrs_len) {
return XDP_PASS;
}
struct stunattr *sa = attrs;
if ((void *)(sa + 1) > data_end) {
return XDP_PASS;
}
// Assume the order and contents of attributes. We *could* loop through
// them, but parsing their lengths and performing arithmetic against the
// packet pointer is more pain than it's worth. Bounds checks are invisible
// to the verifier in certain circumstances where things move from registers
// to the stack and/or compilation optimizations remove them entirely. There
// have only ever been two attributes included by the client, and we are
// only interested in one of them, anyway. Verify the software attribute,
// but ignore the fingerprint attribute as it's only useful where STUN is
// multiplexed with other traffic on the same port/socket, which is not the
// case here.
void *attr_data = (void *)(sa + 1);
if (bpf_ntohs(sa->length) != 8 || bpf_ntohs(sa->num) != STUN_ATTR_SW) {
pctx->prog_end = COUNTER_KEY_END_UNEXPECTED_FIRST_STUN_ATTR;
return XDP_PASS;
}
if (attr_data + 8 > data_end) {
return XDP_PASS;
}
char want_sw[] = {0x74, 0x61, 0x69, 0x6c, 0x6e, 0x6f, 0x64, 0x65}; // tailnode
char *got_sw = attr_data;
for (int j = 0; j < 8; j++) {
if (got_sw[j] != want_sw[j]) {
pctx->prog_end = COUNTER_KEY_END_INVALID_SW_ATTR_VAL;
return XDP_PASS;
}
}
// Begin transforming packet into a STUN_BINDING_RESPONSE. From here
// onwards we return XDP_ABORTED instead of XDP_PASS when transformations or
// bounds checks fail as it would be nonsensical to pass a mangled packet
// through to the kernel, and we may be interested in debugging via
// tracepoint.
// Set success response and new length. Magic cookie and txid remain the
// same.
req->type = bpf_htons(STUN_BINDING_RESPONSE);
if (is_ipv6) {
req->length = bpf_htons(sizeof(struct stunattr) + sizeof(struct stunxor6));
} else {
req->length = bpf_htons(sizeof(struct stunattr) + sizeof(struct stunxor));
}
// Set attr type. Length remains unchanged, but set it again for future
// safety reasons.
sa->num = bpf_htons(STUN_ATTR_XOR_MAPPED_ADDR);
if (is_ipv6) {
sa->length = bpf_htons(sizeof(struct stunxor6));
} else {
sa->length = bpf_htons(sizeof(struct stunxor));
}
struct stunxor *xor;
struct stunxor6 *xor6;
// Adjust tail and reset header pointers.
int adjust_tail_by;
if (is_ipv6) {
xor6 = attr_data;
adjust_tail_by = (void *)(xor6 + 1) - data_end;
} else {
xor = attr_data;
adjust_tail_by = (void *)(xor + 1) - data_end;
}
if (bpf_xdp_adjust_tail(ctx, adjust_tail_by)) {
return XDP_ABORTED;
}
data_end = (void *)(long)ctx->data_end;
data = (void *)(long)ctx->data;
eth = data;
if ((void *)(eth + 1) > data_end) {
return XDP_ABORTED;
}
if (is_ipv6) {
ip6 = (void *)(eth + 1);
if ((void *)(ip6 + 1) > data_end) {
return XDP_ABORTED;
}
udp = (void *)(ip6 + 1);
if ((void *)(udp + 1) > data_end) {
return XDP_ABORTED;
}
} else {
ip = (void *)(eth + 1);
if ((void *)(ip + 1) > data_end) {
return XDP_ABORTED;
}
udp = (void *)(ip + 1);
if ((void *)(udp + 1) > data_end) {
return XDP_ABORTED;
}
}
req = (void *)(udp + 1);
if ((void *)(req + 1) > data_end) {
return XDP_ABORTED;
}
sa = (void *)(req + 1);
if ((void *)(sa + 1) > data_end) {
return XDP_ABORTED;
}
// Set attr data.
if (is_ipv6) {
xor6 = (void *)(sa + 1);
if ((void *)(xor6 + 1) > data_end) {
return XDP_ABORTED;
}
xor6->unused = 0x00; // unused byte
xor6->family = 0x02;
xor6->port = udp->source ^ bpf_htons(STUN_MAGIC_FOR_PORT_XOR);
xor6->addr[0] = ip6->saddr.in6_u.u6_addr32[0] ^ bpf_htonl(STUN_MAGIC);
for (int i = 1; i < 4; i++) {
// All three are __be32, no endianness flips.
xor6->addr[i] = ip6->saddr.in6_u.u6_addr32[i] ^ req->txid[i-1];
}
} else {
xor = (void *)(sa + 1);
if ((void *)(xor + 1) > data_end) {
return XDP_ABORTED;
}
xor->unused = 0x00; // unused byte
xor->family = 0x01;
xor->port = udp->source ^ bpf_htons(STUN_MAGIC_FOR_PORT_XOR);
xor->addr = ip->saddr ^ bpf_htonl(STUN_MAGIC);
}
// Flip ethernet header source and destination address.
__u8 eth_tmp[ETH_ALEN];
__builtin_memcpy(eth_tmp, eth->h_source, ETH_ALEN);
__builtin_memcpy(eth->h_source, eth->h_dest, ETH_ALEN);
__builtin_memcpy(eth->h_dest, eth_tmp, ETH_ALEN);
// Flip ip header source and destination address.
if (is_ipv6) {
struct in6_addr ip_tmp = ip6->saddr;
ip6->saddr = ip6->daddr;
ip6->daddr = ip_tmp;
} else {
__be32 ip_tmp = ip->saddr;
ip->saddr = ip->daddr;
ip->daddr = ip_tmp;
}
// Flip udp header source and destination ports;
__be16 port_tmp = udp->source;
udp->source = udp->dest;
udp->dest = port_tmp;
// Update total length, TTL, and checksum.
__u32 cs = 0;
if (is_ipv6) {
if ((void *)(ip6 +1) > data_end) {
return XDP_ABORTED;
}
__u16 payload_len = data_end - (void *)(ip6 + 1);
ip6->payload_len = bpf_htons(payload_len);
ip6->hop_limit = IPDEFTTL;
} else {
__u16 tot_len = data_end - (void *)ip;
ip->tot_len = bpf_htons(tot_len);
ip->ttl = IPDEFTTL;
ip->check = 0;
cs = bpf_csum_diff(0, 0, (void *)ip, sizeof(*ip), cs);
ip->check = csum_fold_flip(cs);
}
// Avoid dynamic length math against the packet pointer, which is just a big
// verifier headache. Instead sizeof() all the things.
int to_csum_len = sizeof(*udp) + sizeof(*req) + sizeof(*sa);
// Update udp header length and checksum.
if (is_ipv6) {
to_csum_len += sizeof(*xor6);
udp = (void *)(ip6 + 1);
if ((void *)(udp +1) > data_end) {
return XDP_ABORTED;
}
__u16 udp_len = data_end - (void *)udp;
udp->len = bpf_htons(udp_len);
udp->check = 0;
cs = pseudo_sum_ipv6(ip6, udp->len);
} else {
to_csum_len += sizeof(*xor);
udp = (void *)(ip + 1);
if ((void *)(udp +1) > data_end) {
return XDP_ABORTED;
}
__u16 udp_len = data_end - (void *)udp;
udp->len = bpf_htons(udp_len);
udp->check = 0;
cs = pseudo_sum_ipv4(ip, udp->len);
}
if ((void *)udp + to_csum_len > data_end) {
return XDP_ABORTED;
}
cs = bpf_csum_diff(0, 0, (void*)udp, to_csum_len, cs);
udp->check = csum_fold_flip(cs);
return XDP_TX;
}
#undef is_ipv6
SEC("xdp")
int xdp_prog_func(struct xdp_md *ctx) {
struct packet_context pctx = {
.af = COUNTER_KEY_AF_UNKNOWN,
.prog_end = COUNTER_KEY_END_UNSPECIFIED,
};
int action = XDP_PASS;
action = handle_packet(ctx, &pctx);
handle_counters(ctx, action, &pctx);
return action;
}