commit | 4f88a9401357d7b75e917abd994aa6ea97dda4d3 | [log] [tgz] |
---|---|---|
author | Brendan Gregg <brendan.d.gregg@gmail.com> | Fri Jul 22 17:11:51 2016 -0700 |
committer | 4ast <alexei.starovoitov@gmail.com> | Fri Jul 22 17:11:51 2016 -0700 |
tree | d3ee4936e6460d0e22f5f4175459ead5f31548c2 | |
parent | f4bf27517d1fe59ed915d7f8cb3610d4a58583ae [diff] |
USDT Python API and example (#624) * Python USDT API Code from @vmg * Basic USDT example * retire procstat.py * improve/fix USDT exceptions
BCC is a toolkit for creating efficient kernel tracing and manipulation programs, and includes several useful tools and examples. It makes use of eBPF (Extended Berkeley Packet Filters), a new feature that was first added to Linux 3.15. Much of what BCC uses requires Linux 4.1 and above.
eBPF was described by Ingo Molnár as:
One of the more interesting features in this cycle is the ability to attach eBPF programs (user-defined, sandboxed bytecode executed by the kernel) to kprobes. This allows user-defined instrumentation on a live kernel image that can never crash, hang or interfere with the kernel negatively.
BCC makes eBPF programs easier to write, with kernel instrumentation in C and a front-end in Python. It is suited for many tasks, including performance analysis and network traffic control.
This example traces a disk I/O kernel function, and populates an in-kernel power-of-2 histogram of the I/O size. For efficiency, only the histogram summary is returned to user-level.
# ./bitehist.py Tracing... Hit Ctrl-C to end. ^C kbytes : count distribution 0 -> 1 : 3 | | 2 -> 3 : 0 | | 4 -> 7 : 211 |********** | 8 -> 15 : 0 | | 16 -> 31 : 0 | | 32 -> 63 : 0 | | 64 -> 127 : 1 | | 128 -> 255 : 800 |**************************************|
The above output shows a bimodal distribution, where the largest mode of 800 I/O was between 128 and 255 Kbytes in size.
See the source: bitehist.c and bitehist.py. What this traces, what this stores, and how the data is presented, can be entirely customized. This shows only some of many possible capabilities.
See INSTALL.md for installation steps on your platform.
See FAQ.txt for the most common troubleshoot questions.
Some of these are single files that contain both C and Python, others have a pair of .c and .py files, and some are directories of files.
Examples:
Examples:
BPF guarantees that the programs loaded into the kernel cannot crash, and cannot run forever, but yet BPF is general purpose enough to perform many arbitrary types of computation. Currently, it is possible to write a program in C that will compile into a valid BPF program, yet it is vastly easier to write a C program that will compile into invalid BPF (C is like that). The user won't know until trying to run the program whether it was valid or not.
With a BPF-specific frontend, one should be able to write in a language and receive feedback from the compiler on the validity as it pertains to a BPF backend. This toolkit aims to provide a frontend that can only create valid BPF programs while still harnessing its full flexibility.
Furthermore, current integrations with BPF have a kludgy workflow, sometimes involving compiling directly in a linux kernel source tree. This toolchain aims to minimize the time that a developer spends getting BPF compiled, and instead focus on the applications that can be written and the problems that can be solved with BPF.
The features of this toolkit include:
In the future, more bindings besides python will likely be supported. Feel free to add support for the language of your choice and send a pull request!
The BCC toolchain is currently composed of two parts: a C wrapper around LLVM, and a Python API to interact with the running program. Later, we will go into more detail of how this all works.
First, we should include the BPF class from the bpf module:
from bcc import BPF
Since the C code is so short, we will embed it inside the python script.
The BPF program always takes at least one argument, which is a pointer to the context for this type of program. Different program types have different calling conventions, but for this one we don't care so void *
is fine.
BPF(text='void kprobe__sys_clone(void *ctx) { bpf_trace_printk("Hello, World!\\n"); }').trace_print()
For this example, we will call the program every time fork()
is called by a userspace process. Underneath the hood, fork translates to the clone
syscall. BCC recognizes prefix kprobe__
, and will auto attach our program to the kernel symbol sys_clone
.
The python process will then print the trace printk circular buffer until ctrl-c is pressed. The BPF program is removed from the kernel when the userspace process that loaded it closes the fd (or exits).
Output:
bcc/examples$ sudo python hello_world.py python-7282 [002] d... 3757.488508: : Hello, World!
For an explanation of the meaning of the printed fields, see the trace_pipe section of the kernel ftrace doc.
At Red Hat Summit 2015, BCC was presented as part of a session on BPF. A multi-host vxlan environment is simulated and a BPF program used to monitor one of the physical interfaces. The BPF program keeps statistics on the inner and outer IP addresses traversing the interface, and the userspace component turns those statistics into a graph showing the traffic distribution at multiple granularities. See the code here.
Here is a slightly more complex tracing example than Hello World. This program will be invoked for every task change in the kernel, and record in a BPF map the new and old pids.
The C program below introduces two new concepts. The first is the macro BPF_TABLE
. This defines a table (type="hash"), with key type key_t
and leaf type u64
(a single counter). The table name is stats
, containing 1024 entries maximum. One can lookup
, lookup_or_init
, update
, and delete
entries from the table. The second concept is the prev argument. This argument is treated specially by the BCC frontend, such that accesses to this variable are read from the saved context that is passed by the kprobe infrastructure. The prototype of the args starting from position 1 should match the prototype of the kernel function being kprobed. If done so, the program will have seamless access to the function parameters.
#include <uapi/linux/ptrace.h> #include <linux/sched.h> struct key_t { u32 prev_pid; u32 curr_pid; }; // map_type, key_type, leaf_type, table_name, num_entry BPF_TABLE("hash", struct key_t, u64, stats, 1024); // attach to finish_task_switch in kernel/sched/core.c, which has the following // prototype: // struct rq *finish_task_switch(struct task_struct *prev) int count_sched(struct pt_regs *ctx, struct task_struct *prev) { struct key_t key = {}; u64 zero = 0, *val; key.curr_pid = bpf_get_current_pid_tgid(); key.prev_pid = prev->pid; val = stats.lookup_or_init(&key, &zero); (*val)++; return 0; }
The userspace component loads the file shown above, and attaches it to the finish_task_switch
kernel function. The [] operator of the BPF object gives access to each BPF_TABLE in the program, allowing pass-through access to the values residing in the kernel. Use the object as you would any other python dict object: read, update, and deletes are all allowed.
from bcc import BPF from time import sleep b = BPF(src_file="task_switch.c") b.attach_kprobe(event="finish_task_switch", fn_name="count_sched") # generate many schedule events for i in range(0, 100): sleep(0.01) for k, v in b["stats"].items(): print("task_switch[%5d->%5d]=%u" % (k.prev_pid, k.curr_pid, v.value))
See INSTALL.md for installation steps on your platform.
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