import argparse from time import sleep, strftime from sys import argv import ctypes as ct from bcc import BPF, USDT import inspect import os # Parse command line arguments parser = argparse.ArgumentParser(description="Trace the moving average of the latency of an operation using usdt probes.", formatter_class=argparse.RawDescriptionHelpFormatter) parser.add_argument("-p", "--pid", type=int, help="The id of the process to trace.") parser.add_argument("-i", "--interval", type=int, help="The interval in seconds on which to report the latency distribution.") parser.add_argument("-c", "--count", type=int, default=16, help="The count of samples over which to calculate the moving average.") parser.add_argument("-f", "--filterstr", type=str, default="", help="The prefix filter for the operation input. If specified, only operations for which the input string starts with the filterstr are traced.") parser.add_argument("-v", "--verbose", dest="verbose", action="store_true", help="If true, will output verbose logging information.") parser.set_defaults(verbose=False) args = parser.parse_args() this_pid = int(args.pid) this_interval = int(args.interval) this_count = int(args.count) this_filter = str(args.filterstr) if this_interval < 1: print("Invalid value for interval, using 1.") this_interval = 1 if this_count < 1: print("Invalid value for count, using 1.") this_count = 1 debugLevel=0 if args.verbose: debugLevel=4 # BPF program bpf_text_shared = "%s/bpf_text_shared.c" % os.path.dirname(os.path.abspath(inspect.getfile(inspect.currentframe()))) bpf_text = open(bpf_text_shared, 'r').read() bpf_text += """ const u32 MAX_SAMPLES = SAMPLE_COUNT; struct hash_key_t { char input[64]; }; struct hash_leaf_t { u32 count; u64 total; u64 average; }; /** * @brief Contains the averages for the operation latencies by operation input. */ BPF_HASH(lat_hash, struct hash_key_t, struct hash_leaf_t, 512); /** * @brief Reads the operation response arguments, calculates the latency, and stores it in the histogram. * @param ctx The BPF context. */ int trace_operation_end(struct pt_regs* ctx) { u64 operation_id; bpf_usdt_readarg(1, ctx, &operation_id); struct start_data_t* start_data = start_hash.lookup(&operation_id); if (0 == start_data) { return 0; } u64 duration = bpf_ktime_get_ns() - start_data->start; struct hash_key_t hash_key = {}; __builtin_memcpy(&hash_key.input, start_data->input, sizeof(hash_key.input)); start_hash.delete(&operation_id); struct hash_leaf_t zero = {}; struct hash_leaf_t* hash_leaf = lat_hash.lookup_or_init(&hash_key, &zero); if (0 == hash_leaf) { return 0; } if (hash_leaf->count < MAX_SAMPLES) { hash_leaf->count++; } else { hash_leaf->total -= hash_leaf->average; } hash_leaf->total += duration; hash_leaf->average = hash_leaf->total / hash_leaf->count; return 0; } """ bpf_text = bpf_text.replace("SAMPLE_COUNT", str(this_count)) bpf_text = bpf_text.replace("FILTER_STRING", this_filter) if this_filter: bpf_text = bpf_text.replace("FILTER", "if (!filter(start_data.input)) { return 0; }") else: bpf_text = bpf_text.replace("FILTER", "") # Create USDT context print("Attaching probes to pid %d" % this_pid) usdt_ctx = USDT(pid=this_pid) usdt_ctx.enable_probe(probe="operation_start", fn_name="trace_operation_start") usdt_ctx.enable_probe(probe="operation_end", fn_name="trace_operation_end") # Create BPF context, load BPF program bpf_ctx = BPF(text=bpf_text, usdt_contexts=[usdt_ctx], debug=debugLevel) print("Tracing... Hit Ctrl-C to end.") lat_hash = bpf_ctx.get_table("lat_hash") while (1): try: sleep(this_interval) except KeyboardInterrupt: exit() print("[%s]" % strftime("%H:%M:%S")) print("%-64s %8s %16s" % ("input", "count", "latency (us)")) for k, v in lat_hash.items(): print("%-64s %8d %16d" % (k.input, v.count, v.average / 1000))