[RFC PATCH -next v2 3/4] arm64/ftrace: support dynamically allocated trampolines
Wangshaobo (bobo)
bobo.shaobowang at huawei.com
Wed May 4 19:57:35 PDT 2022
在 2022/4/22 0:27, Mark Rutland 写道:
> On Thu, Apr 21, 2022 at 11:42:01AM -0400, Steven Rostedt wrote:
>> On Thu, 21 Apr 2022 16:14:13 +0100
>> Mark Rutland <mark.rutland at arm.com> wrote:
>>
>>>> Let's say you have 10 ftrace_ops registered (with bpf and kprobes this can
>>>> be quite common). But each of these ftrace_ops traces a function (or
>>>> functions) that are not being traced by the other ftrace_ops. That is, each
>>>> ftrace_ops has its own unique function(s) that they are tracing. One could
>>>> be tracing schedule, the other could be tracing ksoftirqd_should_run
>>>> (whatever).
>>> Ok, so that's when messing around with bpf or kprobes, and not generally
>>> when using plain old ftrace functionality under /sys/kernel/tracing/
>>> (unless that's concurrent with one of the former, as per your other
>>> reply) ?
>> It's any user of the ftrace infrastructure, which includes kprobes, bpf,
>> perf, function tracing, function graph tracing, and also affects instances.
>>
>>>> Without this change, because the arch does not support dynamically
>>>> allocated trampolines, it means that all these ftrace_ops will be
>>>> registered to the same trampoline. That means, for every function that is
>>>> traced, it will loop through all 10 of theses ftrace_ops and check their
>>>> hashes to see if their callback should be called or not.
>>> Sure; I can see how that can be quite expensive.
>>>
>>> What I'm trying to figure out is who this matters to and when, since the
>>> implementation is going to come with a bunch of subtle/fractal
>>> complexities, and likely a substantial overhead too when enabling or
>>> disabling tracing of a patch-site. I'd like to understand the trade-offs
>>> better.
>>>
>>>> With dynamically allocated trampolines, each ftrace_ops will have their own
>>>> trampoline, and that trampoline will be called directly if the function
>>>> is only being traced by the one ftrace_ops. This is much more efficient.
>>>>
>>>> If a function is traced by more than one ftrace_ops, then it falls back to
>>>> the loop.
>>> I see -- so the dynamic trampoline is just to get the ops? Or is that
>>> doing additional things?
>> It's to get both the ftrace_ops (as that's one of the parameters) as well
>> as to call the callback directly. Not sure if arm is affected by spectre,
>> but the "loop" function is filled with indirect function calls, where as
>> the dynamic trampolines call the callback directly.
>>
>> Instead of:
>>
>> bl ftrace_caller
>>
>> ftrace_caller:
>> [..]
>> bl ftrace_ops_list_func
>> [..]
>>
>>
>> void ftrace_ops_list_func(...)
>> {
>> __do_for_each_ftrace_ops(op, ftrace_ops_list) {
>> if (ftrace_ops_test(op, ip)) // test the hash to see if it
>> // should trace this
>> // function.
>> op->func(...);
>> }
>> }
>>
>> It does:
>>
>> bl dyanmic_tramp
>>
>> dynamic_tramp:
>> [..]
>> bl func // call the op->func directly!
>>
>>
>> Much more efficient!
>>
>>
>>> There might be a middle-ground here where we patch the ftrace_ops
>>> pointer into a literal pool at the patch-site, which would allow us to
>>> handle this atomically, and would avoid the issues with out-of-range
>>> trampolines.
>> Have an example of what you are suggesting?
> We can make the compiler to place 2 NOPs before the function entry point, and 2
> NOPs after it using `-fpatchable-function-entry=4,2` (the arguments are
> <total>,<before>). On arm64 all instructions are 4 bytes, and we'll use the
> first two NOPs as an 8-byte literal pool.
>
> Ignoring BTI for now, the compiler generates (with some magic labels added here
> for demonstration):
>
> __before_func:
> NOP
> NOP
> func:
> NOP
> NOP
> __remainder_of_func:
> ...
>
> At ftrace_init_nop() time we patch that to:
>
> __before_func:
> // treat the 2 NOPs as an 8-byte literal-pool
> .quad <default ops pointer> // see below
> func:
> MOV X9, X30
> NOP
> __remainder_of_func:
> ...
>
> When enabling tracing we do
>
> __before_func:
> // patch this with the relevant ops pointer
> .quad <ops pointer>
> func:
> MOV X9, X30
> BL <trampoline> // common trampoline
I have a question that does this common trampoline allocated by
module_alloc()? if yes,
how to handle the long jump from traced func to common trampoline if
only adding
two NOPs in front of func.
-- Wang ShaoBo
> __remainder_of_func:
> ..
>
> The `BL <trampoline>` clobbers X30 with __remainder_of_func, so within
> the trampoline we can find the ops pointer at an offset from X30. On
> arm64 we can load that directly with something like:
>
> LDR <tmp>, [X30, # -(__remainder_of_func - __before_func)]
>
> ... then load the ops->func from that and invoke it (or pass it to a
> helper which does):
>
> // Ignoring the function arguments for this demonstration
> LDR <tmp2>, [<tmp>, #OPS_FUNC_OFFSET]
> BLR <tmp2>
>
> That avoids iterating over the list *without* requiring separate
> trampolines, and allows us to patch the sequence without requiring
> stop-the-world logic (since arm64 has strong requirements for patching
> most instructions other than branches and nops).
>
> We can initialize the ops pointer to a default ops that does the whole
> __do_for_each_ftrace_ops() dance.
>
> To handle BTI we can have two trampolines, or we can always reserve 3 NOPs
> before the function so that we can have a consistent offset regardless.
>
> Thanks,
> Mark.
> .
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