arm64: documentation: document tagged pointer stack constraints

Some kernel features don't currently work if a task puts a non-zero
address tag in its stack pointer, frame pointer, or frame record entries
(FP, LR).

For example, with a tagged stack pointer, the kernel can't deliver
signals to the process, and the task is killed instead. As another
example, with a tagged frame pointer or frame records, perf fails to
generate call graphs or resolve symbols.

For now, just document these limitations, instead of finding and fixing
everything that doesn't work, as it's not known if anyone needs to use
tags in these places anyway.

In addition, as requested by Dave Martin, generalize the limitations
into a general kernel address tag policy, and refactor
tagged-pointers.txt to include it.

Fixes: d50240a5f6 ("arm64: mm: permit use of tagged pointers at EL0")
Cc: <stable@vger.kernel.org> # 3.12.x-
Reviewed-by: Dave Martin <Dave.Martin@arm.com>
Acked-by: Will Deacon <will.deacon@arm.com>
Signed-off-by: Kristina Martsenko <kristina.martsenko@arm.com>
Signed-off-by: Catalin Marinas <catalin.marinas@arm.com>
This commit is contained in:
Kristina Martsenko 2017-05-03 16:37:48 +01:00 коммит произвёл Catalin Marinas
Родитель 276e93279a
Коммит f0e421b1bf
1 изменённых файлов: 47 добавлений и 15 удалений

Просмотреть файл

@ -11,24 +11,56 @@ in AArch64 Linux.
The kernel configures the translation tables so that translations made
via TTBR0 (i.e. userspace mappings) have the top byte (bits 63:56) of
the virtual address ignored by the translation hardware. This frees up
this byte for application use, with the following caveats:
this byte for application use.
(1) The kernel requires that all user addresses passed to EL1
are tagged with tag 0x00. This means that any syscall
parameters containing user virtual addresses *must* have
their top byte cleared before trapping to the kernel.
(2) Non-zero tags are not preserved when delivering signals.
This means that signal handlers in applications making use
of tags cannot rely on the tag information for user virtual
addresses being maintained for fields inside siginfo_t.
One exception to this rule is for signals raised in response
to watchpoint debug exceptions, where the tag information
will be preserved.
Passing tagged addresses to the kernel
--------------------------------------
(3) Special care should be taken when using tagged pointers,
since it is likely that C compilers will not hazard two
virtual addresses differing only in the upper byte.
All interpretation of userspace memory addresses by the kernel assumes
an address tag of 0x00.
This includes, but is not limited to, addresses found in:
- pointer arguments to system calls, including pointers in structures
passed to system calls,
- the stack pointer (sp), e.g. when interpreting it to deliver a
signal,
- the frame pointer (x29) and frame records, e.g. when interpreting
them to generate a backtrace or call graph.
Using non-zero address tags in any of these locations may result in an
error code being returned, a (fatal) signal being raised, or other modes
of failure.
For these reasons, passing non-zero address tags to the kernel via
system calls is forbidden, and using a non-zero address tag for sp is
strongly discouraged.
Programs maintaining a frame pointer and frame records that use non-zero
address tags may suffer impaired or inaccurate debug and profiling
visibility.
Preserving tags
---------------
Non-zero tags are not preserved when delivering signals. This means that
signal handlers in applications making use of tags cannot rely on the
tag information for user virtual addresses being maintained for fields
inside siginfo_t. One exception to this rule is for signals raised in
response to watchpoint debug exceptions, where the tag information will
be preserved.
The architecture prevents the use of a tagged PC, so the upper byte will
be set to a sign-extension of bit 55 on exception return.
Other considerations
--------------------
Special care should be taken when using tagged pointers, since it is
likely that C compilers will not hazard two virtual addresses differing
only in the upper byte.