[PATCH tip 0/9] tracing: attach eBPF programs to tracepoints/syscalls/kprobe
From: Alexei Starovoitov
Date: Thu Jan 15 2015 - 23:18:47 EST
Hi Ingo, Steven,
This patch set is based on tip/master.
It adds ability to attach eBPF programs to tracepoints, syscalls and kprobes.
Mechanism of attaching:
- load program via bpf() syscall and receive program_fd
- event_fd = open("/sys/kernel/debug/tracing/events/.../filter")
- write 'bpf-123' to event_fd where 123 is program_fd
- program will be attached to particular event and event automatically enabled
- close(event_fd) will detach bpf program from event and event disabled
Program attach point and input arguments:
- programs attached to kprobes receive 'struct pt_regs *' as an input.
See tracex4_kern.c that demonstrates how users can write a C program like:
SEC("events/kprobes/sys_write")
int bpf_prog4(struct pt_regs *regs)
{
long write_size = regs->dx;
// here user need to know the proto of sys_write() from kernel
// sources and x64 calling convention to know that register $rdx
// contains 3rd argument to sys_write() which is 'size_t count'
it's obviously architecture dependent, but allows building sophisticated
user tools on top, that can see from debug info of vmlinux which variables
are in which registers or stack locations and fetch it from there.
'perf probe' can potentialy use this hook to generate programs in user space
and insert them instead of letting kernel parse string during kprobe creation.
- programs attached to tracepoints and syscalls receive 'struct bpf_context *':
u64 arg1, arg2, ..., arg6;
for syscalls they match syscall arguments.
for tracepoints these args match arguments passed to tracepoint.
For example:
trace_sched_migrate_task(p, new_cpu); from sched/core.c
arg1 <- p which is 'struct task_struct *'
arg2 <- new_cpu which is 'unsigned int'
arg3..arg6 = 0
the program can use bpf_fetch_u8/16/32/64/ptr() helpers to walk 'task_struct'
or any other kernel data structures.
These helpers are using probe_kernel_read() similar to 'perf probe' which is
not 100% safe in both cases, but good enough.
To access task_struct's pid inside 'sched_migrate_task' tracepoint
the program can do:
struct task_struct *task = (struct task_struct *)ctx->arg1;
u32 pid = bpf_fetch_u32(&task->pid);
Since struct layout is kernel configuration specific such programs are not
portable and require access to kernel headers to be compiled,
but in this case we don't need debug info.
llvm with bpf backend will statically compute task->pid offset as a constant
based on kernel headers only.
The example of this arbitrary pointer walking is tracex1_kern.c
which does skb->dev->name == "lo" filtering.
In all cases the programs are called before trace buffer is allocated to
minimize the overhead, since we want to filter huge number of events, but
buffer alloc/free and argument copy for every event is too costly.
Theoretically we can invoke programs after buffer is allocated, but it
doesn't seem needed, since above approach is faster and achieves the same.
Note, tracepoint/syscall and kprobe programs are two different types:
BPF_PROG_TYPE_TRACING_FILTER and BPF_PROG_TYPE_KPROBE_FILTER,
since they expect different input.
Both use the same set of helper functions:
- map access (lookup/update/delete)
- fetch (probe_kernel_read wrappers)
- memcmp (probe_kernel_read + memcmp)
- dump_stack
- trace_printk
The last two are mainly to debug the programs and to print data for user
space consumptions.
Portability:
- kprobe programs are architecture dependent and need user scripting
language like ktap/stap/dtrace/perf that will dynamically generate
them based on debug info in vmlinux
- tracepoint programs are architecture independent, but if arbitrary pointer
walking (with fetch() helpers) is used, they need data struct layout to match.
Debug info is not necessary
- for networking use case we need to access 'struct sk_buff' fields in portable
way (user space needs to fetch packet length without knowing skb->len offset),
so for some frequently used data structures we will add helper functions
or pseudo instructions to access them. I've hacked few ways specifically
for skb, but abandoned them in favor of more generic type/field infra.
That work is still wip. Not part of this set.
Once it's ready tracepoint programs that access common data structs
will be kernel independent.
Program return value:
- programs return 0 to discard an event
- and return non-zero to proceed with event (allocate trace buffer, copy
arguments there and print it eventually in trace_pipe in traditional way)
Examples:
- dropmon.c - simple kfree_skb() accounting in eBPF assembler, similar
to dropmon tool
- tracex1_kern.c - does net/netif_receive_skb event filtering
for dev->skb->name == "lo" condition
- tracex2_kern.c - same kfree_skb() accounting like dropmon, but now in C
plus computes histogram of all write sizes from sys_write syscall
and prints the histogram in userspace
- tracex3_kern.c - most sophisticated example that computes IO latency
between block/block_rq_issue and block/block_rq_complete events
and prints 'heatmap' using gray shades of text terminal.
Useful to analyze disk performance.
- tracex4_kern.c - computes histogram of write sizes from sys_write syscall
using kprobe mechanism instead of syscall. Since kprobe is optimized into
ftrace the overhead of instrumentation is smaller than in example 2.
The user space tools like ktap/dtrace/systemptap/perf that has access
to debug info would probably want to use kprobe attachment point, since kprobe
can be inserted anywhere and all registers are avaiable in the program.
tracepoint attachments are useful without debug info, so standalone tools
like iosnoop will use them.
The main difference vs existing perf_probe/ftrace infra is in kernel aggregation
and conditional walking of arbitrary data structures.
Thanks!
Alexei Starovoitov (9):
tracing: attach eBPF programs to tracepoints and syscalls
tracing: allow eBPF programs to call bpf_printk()
tracing: allow eBPF programs to call ktime_get_ns()
samples: bpf: simple tracing example in eBPF assembler
samples: bpf: simple tracing example in C
samples: bpf: counting example for kfree_skb tracepoint and write
syscall
samples: bpf: IO latency analysis (iosnoop/heatmap)
tracing: attach eBPF programs to kprobe/kretprobe
samples: bpf: simple kprobe example
include/linux/ftrace_event.h | 6 +
include/trace/bpf_trace.h | 25 ++++
include/trace/ftrace.h | 30 +++++
include/uapi/linux/bpf.h | 11 ++
kernel/trace/Kconfig | 1 +
kernel/trace/Makefile | 1 +
kernel/trace/bpf_trace.c | 250 ++++++++++++++++++++++++++++++++++++
kernel/trace/trace.h | 3 +
kernel/trace/trace_events.c | 41 +++++-
kernel/trace/trace_events_filter.c | 80 +++++++++++-
kernel/trace/trace_kprobe.c | 11 +-
kernel/trace/trace_syscalls.c | 31 +++++
samples/bpf/Makefile | 18 +++
samples/bpf/bpf_helpers.h | 18 +++
samples/bpf/bpf_load.c | 62 ++++++++-
samples/bpf/bpf_load.h | 3 +
samples/bpf/dropmon.c | 129 +++++++++++++++++++
samples/bpf/tracex1_kern.c | 28 ++++
samples/bpf/tracex1_user.c | 24 ++++
samples/bpf/tracex2_kern.c | 71 ++++++++++
samples/bpf/tracex2_user.c | 95 ++++++++++++++
samples/bpf/tracex3_kern.c | 96 ++++++++++++++
samples/bpf/tracex3_user.c | 146 +++++++++++++++++++++
samples/bpf/tracex4_kern.c | 36 ++++++
samples/bpf/tracex4_user.c | 83 ++++++++++++
25 files changed, 1290 insertions(+), 9 deletions(-)
create mode 100644 include/trace/bpf_trace.h
create mode 100644 kernel/trace/bpf_trace.c
create mode 100644 samples/bpf/dropmon.c
create mode 100644 samples/bpf/tracex1_kern.c
create mode 100644 samples/bpf/tracex1_user.c
create mode 100644 samples/bpf/tracex2_kern.c
create mode 100644 samples/bpf/tracex2_user.c
create mode 100644 samples/bpf/tracex3_kern.c
create mode 100644 samples/bpf/tracex3_user.c
create mode 100644 samples/bpf/tracex4_kern.c
create mode 100644 samples/bpf/tracex4_user.c
--
1.7.9.5
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