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#! /usr/bin/python3 # @lint-avoid-python-3-compatibility-imports # # tcpcong Measure tcp congestion control status duration. # For Linux, uses BCC, eBPF. # # USAGE: tcpcong [-h] [-T] [-L] [-R] [-m] [-d] [interval] [outputs] # # Copyright (c) Ping Gan. # # 27-Jan-2022 Ping Gan Created this. from __future__ import print_function from bcc import BPF from time import sleep, strftime from struct import pack from socket import inet_ntop, AF_INET, AF_INET6 from struct import pack import argparse examples = """examples: ./tcpcong # show tcp congestion status duration ./tcpcong 1 10 # show 1 second summaries, 10 times ./tcpcong -L 3000-3006 1 # 1s summaries, local port 3000-3006 ./tcpcong -R 5000-5005 1 # 1s summaries, remote port 5000-5005 ./tcpcong -uT 1 # 1s summaries, microseconds, and timestamps ./tcpcong -d # show the duration as histograms """ parser = argparse.ArgumentParser( description="Summarize tcp socket congestion control status duration", formatter_class=argparse.RawDescriptionHelpFormatter, epilog=examples) parser.add_argument("-L", "--localport", help="trace local ports only") parser.add_argument("-R", "--remoteport", help="trace the dest ports only") parser.add_argument("-T", "--timestamp", action="store_true", help="include timestamp on output") parser.add_argument("-d", "--dist", action="store_true", help="show distributions as histograms") parser.add_argument("-u", "--microseconds", action="store_true", help="output in microseconds") parser.add_argument("interval", nargs="?", default=99999999, help="output interval, in seconds") parser.add_argument("outputs", nargs="?", default=99999999, help="number of outputs") parser.add_argument("--ebpf", action="store_true", help=argparse.SUPPRESS) args = parser.parse_args() countdown = int(args.outputs) debug = 0 start_rport = end_rport = -1 if args.remoteport: rports = args.remoteport.split("-") if (len(rports) != 2) and (len(rports) != 1): print("unrecognized remote port range") exit(1) if len(rports) == 2: start_rport = int(rports[0]) end_rport = int(rports[1]) else: start_rport = int(rports[0]) end_rport = int(rports[0]) if start_rport > end_rport: tmp = start_rport start_rport = end_rport end_rport = tmp start_lport = end_lport = -1 if args.localport: lports = args.localport.split("-") if (len(lports) != 2) and (len(lports) != 1): print("unrecognized local port range") exit(1) if len(lports) == 2: start_lport = int(lports[0]) end_lport = int(lports[1]) else: start_lport = int(lports[0]) end_lport = int(lports[0]) if start_lport > end_lport: tmp = start_lport start_lport = end_lport end_lport = tmp # define BPF program bpf_head_text = """ #include <uapi/linux/ptrace.h> #include <net/sock.h> #include <bcc/proto.h> #include <net/tcp.h> #include <net/inet_connection_sock.h> typedef struct ipv4_flow_key { u32 saddr; u32 daddr; u16 lport; u16 dport; } ipv4_flow_key_t; typedef struct ipv6_flow_key { unsigned __int128 saddr; unsigned __int128 daddr; u16 lport; u16 dport; } ipv6_flow_key_t; typedef struct data_val { DEF_TEXT u64 last_ts; u16 last_cong_stat; } data_val_t; BPF_HASH(ipv4_stat, ipv4_flow_key_t, data_val_t); BPF_HASH(ipv6_stat, ipv6_flow_key_t, data_val_t); HIST_TABLE """ bpf_extra_head = """ typedef struct process_key { char comm[TASK_COMM_LEN]; u32 tid; } process_key_t; typedef struct ipv4_flow_val { ipv4_flow_key_t ipv4_key; u16 cong_state; } ipv4_flow_val_t; typedef struct ipv6_flow_val { ipv6_flow_key_t ipv6_key; u16 cong_state; } ipv6_flow_val_t; BPF_HASH(start_ipv4, process_key_t, ipv4_flow_val_t); BPF_HASH(start_ipv6, process_key_t, ipv6_flow_val_t); SOCK_STORE_DEF typedef struct cong { u8 cong_stat:5, ca_inited:1, ca_setsockopt:1, ca_dstlocked:1; } cong_status_t; """ bpf_no_ca_tp_body_text = """ static int entry_state_update_func(struct sock *sk) { u16 dport = 0, lport = 0; u32 tid = bpf_get_current_pid_tgid(); process_key_t key = {0}; bpf_get_current_comm(&key.comm, sizeof(key.comm)); key.tid = tid; u64 family = sk->__sk_common.skc_family; struct inet_connection_sock *icsk = inet_csk(sk); cong_status_t cong_status; bpf_probe_read_kernel(&cong_status, sizeof(cong_status), (void *)((long)&icsk->icsk_retransmits) - 1); if (family == AF_INET) { ipv4_flow_val_t ipv4_val = {0}; ipv4_val.ipv4_key.saddr = sk->__sk_common.skc_rcv_saddr; ipv4_val.ipv4_key.daddr = sk->__sk_common.skc_daddr; ipv4_val.ipv4_key.lport = sk->__sk_common.skc_num; dport = sk->__sk_common.skc_dport; dport = ntohs(dport); lport = ipv4_val.ipv4_key.lport; FILTER_LPORT FILTER_DPORT ipv4_val.ipv4_key.dport = dport; ipv4_val.cong_state = cong_status.cong_stat + 1; start_ipv4.update(&key, &ipv4_val); } else if (family == AF_INET6) { ipv6_flow_val_t ipv6_val = {0}; bpf_probe_read_kernel(&ipv6_val.ipv6_key.saddr, sizeof(ipv6_val.ipv6_key.saddr), &sk->__sk_common.skc_v6_rcv_saddr.in6_u.u6_addr32); bpf_probe_read_kernel(&ipv6_val.ipv6_key.daddr, sizeof(ipv6_val.ipv6_key.daddr), &sk->__sk_common.skc_v6_daddr.in6_u.u6_addr32); ipv6_val.ipv6_key.lport = sk->__sk_common.skc_num; dport = sk->__sk_common.skc_dport; dport = ntohs(dport); lport = ipv6_val.ipv6_key.lport; FILTER_LPORT FILTER_DPORT ipv6_val.ipv6_key.dport = dport; ipv6_val.cong_state = cong_status.cong_stat + 1; start_ipv6.update(&key, &ipv6_val); } SOCK_STORE_ADD return 0; } static int ret_state_update_func(struct sock *sk) { u64 ts, ts1; u16 family, last_cong_state; u16 dport = 0, lport = 0; u32 tid = bpf_get_current_pid_tgid(); process_key_t key = {0}; bpf_get_current_comm(&key.comm, sizeof(key.comm)); key.tid = tid; struct inet_connection_sock *icsk = inet_csk(sk); cong_status_t cong_status; bpf_probe_read_kernel(&cong_status, sizeof(cong_status), (void *)((long)&icsk->icsk_retransmits) - 1); data_val_t *datap, data = {0}; STATE_KEY bpf_probe_read_kernel(&family, sizeof(family), &sk->__sk_common.skc_family); if (family == AF_INET) { ipv4_flow_val_t *val4 = start_ipv4.lookup(&key); if (val4 == 0) { SOCK_STORE_DEL return 0; //missed } ipv4_flow_key_t keyv4 = {0}; bpf_probe_read_kernel(&keyv4, sizeof(ipv4_flow_key_t), &(val4->ipv4_key)); dport = keyv4.dport; lport = keyv4.lport; FILTER_LPORT FILTER_DPORT datap = ipv4_stat.lookup(&keyv4); if (datap == 0) { data.last_ts = bpf_ktime_get_ns(); data.last_cong_stat = val4->cong_state; ipv4_stat.update(&keyv4, &data); } else { last_cong_state = val4->cong_state; if ((cong_status.cong_stat + 1) != last_cong_state) { ts1 = bpf_ktime_get_ns(); ts = ts1 - datap->last_ts; datap->last_ts = ts1; datap->last_cong_stat = cong_status.cong_stat + 1; ts /= 1000; STORE } } start_ipv4.delete(&key); } else if (family == AF_INET6) { ipv6_flow_val_t *val6 = start_ipv6.lookup(&key); if (val6 == 0) { SOCK_STORE_DEL return 0; //missed } ipv6_flow_key_t keyv6 = {0}; bpf_probe_read_kernel(&keyv6, sizeof(ipv6_flow_key_t), &(val6->ipv6_key)); dport = keyv6.dport; lport = keyv6.lport; FILTER_LPORT FILTER_DPORT datap = ipv6_stat.lookup(&keyv6); if (datap == 0) { data.last_ts = bpf_ktime_get_ns(); data.last_cong_stat = val6->cong_state; ipv6_stat.update(&keyv6, &data); } else { last_cong_state = val6->cong_state; if ((cong_status.cong_stat + 1) != last_cong_state) { ts1 = bpf_ktime_get_ns(); ts = ts1 - datap->last_ts; datap->last_ts = ts1; datap->last_cong_stat = (cong_status.cong_stat + 1); ts /= 1000; STORE } } start_ipv6.delete(&key); } SOCK_STORE_DEL return 0; } """ bpf_ca_tp_body_text = """ TRACEPOINT_PROBE(tcp, tcp_cong_state_set) { u64 ts, ts1; u16 family, last_cong_state, dport = 0, lport = 0; u8 cong_state; const struct sock *sk = (const struct sock *)args->skaddr; data_val_t *datap, data = {0}; family = sk->__sk_common.skc_family; dport = args->dport; lport = args->sport; cong_state = args->cong_state; STATE_KEY if (family == AF_INET) { ipv4_flow_key_t key4 = {0}; key4.saddr = sk->__sk_common.skc_rcv_saddr; key4.daddr = sk->__sk_common.skc_daddr; FILTER_LPORT FILTER_DPORT key4.lport = lport; key4.dport = dport; datap = ipv4_stat.lookup(&key4); if (datap == 0) { data.last_ts = bpf_ktime_get_ns(); data.last_cong_stat = cong_state + 1; ipv4_stat.update(&key4, &data); } else { last_cong_state = datap->last_cong_stat; if ((cong_state + 1) != last_cong_state) { ts1 = bpf_ktime_get_ns(); ts = ts1 - datap->last_ts; datap->last_ts = ts1; datap->last_cong_stat = cong_state + 1; ts /= 1000; STORE } } } else if (family == AF_INET6) { ipv6_flow_key_t key6 = {0}; bpf_probe_read_kernel(&key6.saddr, sizeof(key6.saddr), &sk->__sk_common.skc_v6_rcv_saddr.in6_u.u6_addr32); bpf_probe_read_kernel(&key6.daddr, sizeof(key6.daddr), &sk->__sk_common.skc_v6_daddr.in6_u.u6_addr32); FILTER_LPORT FILTER_DPORT key6.lport = lport; key6.dport = dport; datap = ipv6_stat.lookup(&key6); if (datap == 0) { data.last_ts = bpf_ktime_get_ns(); data.last_cong_stat = cong_state + 1; ipv6_stat.update(&key6, &data); } else { last_cong_state = datap->last_cong_stat; if ((cong_state + 1) != last_cong_state) { ts1 = bpf_ktime_get_ns(); ts = ts1 - datap->last_ts; datap->last_ts = ts1; datap->last_cong_stat = cong_state + 1; ts /= 1000; STORE } } } return 0; } """ kprobe_program = """ int entry_func(struct pt_regs *ctx, struct sock *sk) { return entry_state_update_func(sk); } int ret_func(struct pt_regs *ctx) { u32 tid = bpf_get_current_pid_tgid(); process_key_t key = {0}; bpf_get_current_comm(&key.comm, sizeof(key.comm)); key.tid = tid; struct sock **sockpp; sockpp = sock_store.lookup(&key); if (sockpp == 0) { return 0; //miss the entry } struct sock *sk = *sockpp; return ret_state_update_func(sk); } """ kfunc_program = """ KFUNC_PROBE(tcp_fastretrans_alert, struct sock *sk) { return entry_state_update_func(sk); } KRETFUNC_PROBE(tcp_fastretrans_alert, struct sock *sk) { return ret_state_update_func(sk); } KFUNC_PROBE(tcp_enter_cwr, struct sock *sk) { return entry_state_update_func(sk); } KRETFUNC_PROBE(tcp_enter_cwr, struct sock *sk) { return ret_state_update_func(sk); } KFUNC_PROBE(tcp_enter_loss, struct sock *sk) { return entry_state_update_func(sk); } KRETFUNC_PROBE(tcp_enter_loss, struct sock *sk) { return ret_state_update_func(sk); } KFUNC_PROBE(tcp_enter_recovery, struct sock *sk) { return entry_state_update_func(sk); } KRETFUNC_PROBE(tcp_enter_recovery, struct sock *sk) { return ret_state_update_func(sk); } KFUNC_PROBE(tcp_process_tlp_ack, struct sock *sk) { return entry_state_update_func(sk); } KRETFUNC_PROBE(tcp_process_tlp_ack, struct sock *sk) { return ret_state_update_func(sk); } """ # code replace is_support_tp_ca = BPF.tracepoint_exists("tcp", "tcp_cong_state_set") if is_support_tp_ca: bpf_text = bpf_head_text + bpf_ca_tp_body_text else: bpf_text = bpf_head_text + bpf_extra_head bpf_text += bpf_no_ca_tp_body_text is_support_kfunc = BPF.support_kfunc() if is_support_kfunc: bpf_text += kfunc_program bpf_text = bpf_text.replace('SOCK_STORE_DEF', '') bpf_text = bpf_text.replace('SOCK_STORE_ADD', '') bpf_text = bpf_text.replace('SOCK_STORE_DEL', '') else: bpf_text += kprobe_program bpf_text = bpf_text.replace('SOCK_STORE_DEF', 'BPF_HASH(sock_store, process_key_t, struct sock *);') bpf_text = bpf_text.replace('SOCK_STORE_ADD', 'sock_store.update(&key, &sk);') bpf_text = bpf_text.replace('SOCK_STORE_DEL', 'sock_store.delete(&key);') if args.localport: bpf_text = bpf_text.replace('FILTER_LPORT', 'if (lport < %d || lport > %d) { return 0; }' % (start_lport, end_lport)) else: bpf_text = bpf_text.replace('FILTER_LPORT', '') if args.remoteport: bpf_text = bpf_text.replace('FILTER_DPORT', 'if (dport < %d || dport > %d) { return 0; }' % (start_rport, end_rport)) else: bpf_text = bpf_text.replace('FILTER_DPORT', '') table_def_text = """ u64 open_dura; u64 loss_dura; u64 disorder_dura; u64 recover_dura; u64 cwr_dura; u64 total_changes; """ store_text = """ datap->total_changes += 1; if (last_cong_state == (TCP_CA_Open + 1)) { datap->open_dura += ts; } else if (last_cong_state == (TCP_CA_Disorder + 1)) { datap->disorder_dura += ts; } else if (last_cong_state == (TCP_CA_CWR + 1)) { datap->cwr_dura += ts; } else if (last_cong_state == (TCP_CA_Recovery + 1)) { datap->recover_dura += ts; } else if (last_cong_state == (TCP_CA_Loss + 1)) { datap->loss_dura += ts; } """ store_dist_text = """ if (last_cong_state == (TCP_CA_Open + 1)) { key_s.state = TCP_CA_Open; } else if (last_cong_state == (TCP_CA_Disorder + 1)) { key_s.state = TCP_CA_Disorder; } else if (last_cong_state == (TCP_CA_CWR + 1)) { key_s.state = TCP_CA_CWR; } else if (last_cong_state == (TCP_CA_Recovery + 1)) { key_s.state = TCP_CA_Recovery; } else if (last_cong_state == (TCP_CA_Loss + 1)) { key_s.state = TCP_CA_Loss; } TIME_UNIT key_s.slot = bpf_log2l(ts); dist.atomic_increment(key_s); """ hist_table_text = """ typedef struct congest_state_key { u32 state; u64 slot; }congest_state_key_t; BPF_HISTOGRAM(dist, congest_state_key_t); """ if args.dist: bpf_text = bpf_text.replace('DEF_TEXT', '') bpf_text = bpf_text.replace('STORE', store_dist_text) bpf_text = bpf_text.replace('STATE_KEY', 'congest_state_key_t key_s = {0};') bpf_text = bpf_text.replace('HIST_TABLE', hist_table_text) if args.microseconds: bpf_text = bpf_text.replace('TIME_UNIT', '') else: bpf_text = bpf_text.replace('TIME_UNIT', 'ts /= 1000;') else: bpf_text = bpf_text.replace('DEF_TEXT', table_def_text) bpf_text = bpf_text.replace('STORE', store_text) bpf_text = bpf_text.replace('STATE_KEY', '') bpf_text = bpf_text.replace('HIST_TABLE', '') if debug or args.ebpf: print(bpf_text) if args.ebpf: exit() # load BPF program b = BPF(text=bpf_text) if not is_support_tp_ca and not is_support_kfunc: # all the tcp congestion control status update functions # are called by below 5 functions. b.attach_kprobe(event="tcp_fastretrans_alert", fn_name="entry_func") b.attach_kretprobe(event="tcp_fastretrans_alert", fn_name="ret_func") b.attach_kprobe(event="tcp_enter_cwr", fn_name="entry_func") b.attach_kretprobe(event="tcp_enter_cwr", fn_name="ret_func") b.attach_kprobe(event="tcp_process_tlp_ack", fn_name="entry_func") b.attach_kretprobe(event="tcp_process_tlp_ack", fn_name="ret_func") b.attach_kprobe(event="tcp_enter_loss", fn_name="entry_func") b.attach_kretprobe(event="tcp_enter_loss", fn_name="ret_func") b.attach_kprobe(event="tcp_enter_recovery", fn_name="entry_func") b.attach_kretprobe(event="tcp_enter_recovery", fn_name="ret_func") print("Tracing tcp congestion control status duration... Hit Ctrl-C to end.") def cong_state_to_name(state): # this need to match with kernel state state_name = ["open", "disorder", "cwr", "recovery", "loss"] return state_name[state] # output exiting = 0 if args.interval else 1 ipv6_stat = b.get_table("ipv6_stat") ipv4_stat = b.get_table("ipv4_stat") if args.dist: dist = b.get_table("dist") label = "ms" if args.microseconds: label = "us" while (1): try: sleep(int(args.interval)) except KeyboardInterrupt: exiting = 1 print() if args.timestamp: print("%-8s\n" % strftime("%H:%M:%S"), end="") if args.dist: if args.microseconds: dist.print_log2_hist("usecs", "tcp_congest_state", section_print_fn=cong_state_to_name) else: dist.print_log2_hist("msecs", "tcp_congest_state", section_print_fn=cong_state_to_name) dist.clear() else: if ipv4_stat: print("%-21s% -21s %-7s %-6s %-7s %-7s %-6s %-5s" % ("LAddrPort", "RAddrPort", "Open_" + label, "Dod_" + label, "Rcov_" + label, "Cwr_" + label, "Los_" + label, "Chgs")) laddr = "" raddr = "" for k, v in sorted(ipv4_stat.items(), key=lambda ipv4_stat: ipv4_stat[0].lport): laddr = inet_ntop(AF_INET, pack("I", k.saddr)) raddr = inet_ntop(AF_INET, pack("I", k.daddr)) open_dura = v.open_dura disorder_dura = v.disorder_dura recover_dura = v.recover_dura cwr_dura = v.cwr_dura loss_dura = v.loss_dura if not args.microseconds: open_dura /= 1000 disorder_dura /= 1000 recover_dura /= 1000 cwr_dura /= 1000 loss_dura /= 1000 if v.total_changes != 0: print("%-21s %-21s %-7d %-6d %-7d %-7d %-6d %-5d" % (laddr + "/" + str(k.lport), raddr + "/" + str(k.dport), open_dura, disorder_dura, recover_dura, cwr_dura, loss_dura, v.total_changes)) if ipv6_stat: print("%-32s %-32s %-7s %-6s %-7s %-7s %-6s %-5s" % ("LAddrPort6", "RAddrPort6", "Open_" + label, "Dod_" + label, "Rcov_" + label, "Cwr_" + label, "Los_" + label, "Chgs")) for k, v in sorted(ipv6_stat.items(), key=lambda ipv6_stat: ipv6_stat[0].lport): laddr = inet_ntop(AF_INET6, bytes(k.saddr)) raddr = inet_ntop(AF_INET6, bytes(k.daddr)) open_dura = v.open_dura disorder_dura = v.disorder_dura recover_dura = v.recover_dura cwr_dura = v.cwr_dura loss_dura = v.loss_dura if not args.microseconds: open_dura /= 1000 disorder_dura /= 1000 recover_dura /= 1000 cwr_dura /= 1000 loss_dura /= 1000 if v.total_changes != 0: print("%-32s %-32s %-7d %-7d %-7d %-6d %-6d %-5d" % (laddr + "/" + str(k.lport), raddr + "/" + str(k.dport), open_dura, disorder_dura, recover_dura, cwr_dura, loss_dura, v.total_changes)) ipv4_stat.clear() ipv6_stat.clear() countdown -= 1 if exiting or countdown == 0: exit()