bitcoin/contrib/tracing/log_raw_p2p_msgs.py
Hennadii Stepanov 1362d6173f
scripted-diff: Insert missed copyright headers
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./contrib/devtools/copyright_header.py insert contrib/guix/libexec/build.sh
./contrib/devtools/copyright_header.py insert contrib/guix/libexec/codesign.sh
./contrib/devtools/copyright_header.py insert contrib/tracing/log_raw_p2p_msgs.py
./contrib/devtools/copyright_header.py insert contrib/tracing/log_utxocache_flush.py
./contrib/devtools/copyright_header.py insert contrib/tracing/p2p_monitor.py
./contrib/devtools/copyright_header.py insert test/lint/lint-files.sh
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2021-12-30 19:46:41 +02:00

184 lines
7.1 KiB
Python
Executable File

#!/usr/bin/env python3
# Copyright (c) 2021 The Bitcoin Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
""" Demonstration of eBPF limitations and the effect on USDT with the
net:inbound_message and net:outbound_message tracepoints. """
# This script shows a limitation of eBPF when data larger than 32kb is passed to
# user-space. It uses BCC (https://github.com/iovisor/bcc) to load a sandboxed
# eBPF program into the Linux kernel (root privileges are required). The eBPF
# program attaches to two statically defined tracepoints. The tracepoint
# 'net:inbound_message' is called when a new P2P message is received, and
# 'net:outbound_message' is called on outbound P2P messages. The eBPF program
# submits the P2P messages to this script via a BPF ring buffer. The submitted
# messages are printed.
# eBPF Limitations:
#
# Bitcoin P2P messages can be larger than 32kb (e.g. tx, block, ...). The eBPF
# VM's stack is limited to 512 bytes, and we can't allocate more than about 32kb
# for a P2P message in the eBPF VM. The message data is cut off when the message
# is larger than MAX_MSG_DATA_LENGTH (see definition below). This can be detected
# in user-space by comparing the data length to the message length variable. The
# message is cut off when the data length is smaller than the message length.
# A warning is included with the printed message data.
#
# Data is submitted to user-space (i.e. to this script) via a ring buffer. The
# throughput of the ring buffer is limited. Each p2p_message is about 32kb in
# size. In- or outbound messages submitted to the ring buffer in rapid
# succession fill the ring buffer faster than it can be read. Some messages are
# lost.
#
# BCC prints: "Possibly lost 2 samples" on lost messages.
import sys
from bcc import BPF, USDT
# BCC: The C program to be compiled to an eBPF program (by BCC) and loaded into
# a sandboxed Linux kernel VM.
program = """
#include <uapi/linux/ptrace.h>
#define MIN(a,b) ({ __typeof__ (a) _a = (a); __typeof__ (b) _b = (b); _a < _b ? _a : _b; })
// Maximum possible allocation size
// from include/linux/percpu.h in the Linux kernel
#define PCPU_MIN_UNIT_SIZE (32 << 10)
// Tor v3 addresses are 62 chars + 6 chars for the port (':12345').
#define MAX_PEER_ADDR_LENGTH 62 + 6
#define MAX_PEER_CONN_TYPE_LENGTH 20
#define MAX_MSG_TYPE_LENGTH 20
#define MAX_MSG_DATA_LENGTH PCPU_MIN_UNIT_SIZE - 200
struct p2p_message
{
u64 peer_id;
char peer_addr[MAX_PEER_ADDR_LENGTH];
char peer_conn_type[MAX_PEER_CONN_TYPE_LENGTH];
char msg_type[MAX_MSG_TYPE_LENGTH];
u64 msg_size;
u8 msg[MAX_MSG_DATA_LENGTH];
};
// We can't store the p2p_message struct on the eBPF stack as it is limited to
// 512 bytes and P2P message can be bigger than 512 bytes. However, we can use
// an BPF-array with a length of 1 to allocate up to 32768 bytes (this is
// defined by PCPU_MIN_UNIT_SIZE in include/linux/percpu.h in the Linux kernel).
// Also see https://github.com/iovisor/bcc/issues/2306
BPF_ARRAY(msg_arr, struct p2p_message, 1);
// Two BPF perf buffers for pushing data (here P2P messages) to user-space.
BPF_PERF_OUTPUT(inbound_messages);
BPF_PERF_OUTPUT(outbound_messages);
int trace_inbound_message(struct pt_regs *ctx) {
int idx = 0;
struct p2p_message *msg = msg_arr.lookup(&idx);
// lookup() does not return a NULL pointer. However, the BPF verifier
// requires an explicit check that that the `msg` pointer isn't a NULL
// pointer. See https://github.com/iovisor/bcc/issues/2595
if (msg == NULL) return 1;
bpf_usdt_readarg(1, ctx, &msg->peer_id);
bpf_usdt_readarg_p(2, ctx, &msg->peer_addr, MAX_PEER_ADDR_LENGTH);
bpf_usdt_readarg_p(3, ctx, &msg->peer_conn_type, MAX_PEER_CONN_TYPE_LENGTH);
bpf_usdt_readarg_p(4, ctx, &msg->msg_type, MAX_MSG_TYPE_LENGTH);
bpf_usdt_readarg(5, ctx, &msg->msg_size);
bpf_usdt_readarg_p(6, ctx, &msg->msg, MIN(msg->msg_size, MAX_MSG_DATA_LENGTH));
inbound_messages.perf_submit(ctx, msg, sizeof(*msg));
return 0;
};
int trace_outbound_message(struct pt_regs *ctx) {
int idx = 0;
struct p2p_message *msg = msg_arr.lookup(&idx);
// lookup() does not return a NULL pointer. However, the BPF verifier
// requires an explicit check that that the `msg` pointer isn't a NULL
// pointer. See https://github.com/iovisor/bcc/issues/2595
if (msg == NULL) return 1;
bpf_usdt_readarg(1, ctx, &msg->peer_id);
bpf_usdt_readarg_p(2, ctx, &msg->peer_addr, MAX_PEER_ADDR_LENGTH);
bpf_usdt_readarg_p(3, ctx, &msg->peer_conn_type, MAX_PEER_CONN_TYPE_LENGTH);
bpf_usdt_readarg_p(4, ctx, &msg->msg_type, MAX_MSG_TYPE_LENGTH);
bpf_usdt_readarg(5, ctx, &msg->msg_size);
bpf_usdt_readarg_p(6, ctx, &msg->msg, MIN(msg->msg_size, MAX_MSG_DATA_LENGTH));
outbound_messages.perf_submit(ctx, msg, sizeof(*msg));
return 0;
};
"""
def print_message(event, inbound):
print(f"%s %s msg '%s' from peer %d (%s, %s) with %d bytes: %s" %
(
f"Warning: incomplete message (only %d out of %d bytes)!" % (
len(event.msg), event.msg_size) if len(event.msg) < event.msg_size else "",
"inbound" if inbound else "outbound",
event.msg_type.decode("utf-8"),
event.peer_id,
event.peer_conn_type.decode("utf-8"),
event.peer_addr.decode("utf-8"),
event.msg_size,
bytes(event.msg[:event.msg_size]).hex(),
)
)
def main(bitcoind_path):
bitcoind_with_usdts = USDT(path=str(bitcoind_path))
# attaching the trace functions defined in the BPF program to the tracepoints
bitcoind_with_usdts.enable_probe(
probe="inbound_message", fn_name="trace_inbound_message")
bitcoind_with_usdts.enable_probe(
probe="outbound_message", fn_name="trace_outbound_message")
bpf = BPF(text=program, usdt_contexts=[bitcoind_with_usdts])
# BCC: perf buffer handle function for inbound_messages
def handle_inbound(_, data, size):
""" Inbound message handler.
Called each time a message is submitted to the inbound_messages BPF table."""
event = bpf["inbound_messages"].event(data)
print_message(event, True)
# BCC: perf buffer handle function for outbound_messages
def handle_outbound(_, data, size):
""" Outbound message handler.
Called each time a message is submitted to the outbound_messages BPF table."""
event = bpf["outbound_messages"].event(data)
print_message(event, False)
# BCC: add handlers to the inbound and outbound perf buffers
bpf["inbound_messages"].open_perf_buffer(handle_inbound)
bpf["outbound_messages"].open_perf_buffer(handle_outbound)
print("Logging raw P2P messages.")
print("Messages larger that about 32kb will be cut off!")
print("Some messages might be lost!")
while True:
try:
bpf.perf_buffer_poll()
except KeyboardInterrupt:
exit()
if __name__ == "__main__":
if len(sys.argv) < 2:
print("USAGE:", sys.argv[0], "path/to/bitcoind")
exit()
path = sys.argv[1]
main(path)