tmp_suning_uos_patched/Documentation/asm-annotations.rst
Nick Desaulniers 4c973f7507 x86/entry: Emit a symbol for register restoring thunk
commit 5e6dca82bcaa49348f9e5fcb48df4881f6d6c4ae upstream.

Arnd found a randconfig that produces the warning:

  arch/x86/entry/thunk_64.o: warning: objtool: missing symbol for insn at
  offset 0x3e

when building with LLVM_IAS=1 (Clang's integrated assembler). Josh
notes:

  With the LLVM assembler not generating section symbols, objtool has no
  way to reference this code when it generates ORC unwinder entries,
  because this code is outside of any ELF function.

  The limitation now being imposed by objtool is that all code must be
  contained in an ELF symbol.  And .L symbols don't create such symbols.

  So basically, you can use an .L symbol *inside* a function or a code
  segment, you just can't use the .L symbol to contain the code using a
  SYM_*_START/END annotation pair.

Fangrui notes that this optimization is helpful for reducing image size
when compiling with -ffunction-sections and -fdata-sections. I have
observed on the order of tens of thousands of symbols for the kernel
images built with those flags.

A patch has been authored against GNU binutils to match this behavior
of not generating unused section symbols ([1]), so this will
also become a problem for users of GNU binutils once they upgrade to 2.36.

Omit the .L prefix on a label so that the assembler will emit an entry
into the symbol table for the label, with STB_LOCAL binding. This
enables objtool to generate proper unwind info here with LLVM_IAS=1 or
GNU binutils 2.36+.

 [ bp: Massage commit message. ]

Reported-by: Arnd Bergmann <arnd@arndb.de>
Suggested-by: Josh Poimboeuf <jpoimboe@redhat.com>
Suggested-by: Borislav Petkov <bp@alien8.de>
Suggested-by: Mark Brown <broonie@kernel.org>
Signed-off-by: Nick Desaulniers <ndesaulniers@google.com>
Signed-off-by: Borislav Petkov <bp@suse.de>
Acked-by: Peter Zijlstra (Intel) <peterz@infradead.org>
Acked-by: Josh Poimboeuf <jpoimboe@redhat.com>
Link: https://lkml.kernel.org/r/20210112194625.4181814-1-ndesaulniers@google.com
Link: https://github.com/ClangBuiltLinux/linux/issues/1209
Link: https://reviews.llvm.org/D93783
Link: https://sourceware.org/binutils/docs/as/Symbol-Names.html
Link: https://sourceware.org/git/?p=binutils-gdb.git;a=commit;h=d1bcae833b32f1408485ce69f844dcd7ded093a8 [1]
Cc: Chris Clayton <chris2553@googlemail.com>
Signed-off-by: Greg Kroah-Hartman <gregkh@linuxfoundation.org>
2021-02-03 23:28:40 +01:00

223 lines
9.4 KiB
ReStructuredText

Assembler Annotations
=====================
Copyright (c) 2017-2019 Jiri Slaby
This document describes the new macros for annotation of data and code in
assembly. In particular, it contains information about ``SYM_FUNC_START``,
``SYM_FUNC_END``, ``SYM_CODE_START``, and similar.
Rationale
---------
Some code like entries, trampolines, or boot code needs to be written in
assembly. The same as in C, such code is grouped into functions and
accompanied with data. Standard assemblers do not force users into precisely
marking these pieces as code, data, or even specifying their length.
Nevertheless, assemblers provide developers with such annotations to aid
debuggers throughout assembly. On top of that, developers also want to mark
some functions as *global* in order to be visible outside of their translation
units.
Over time, the Linux kernel has adopted macros from various projects (like
``binutils``) to facilitate such annotations. So for historic reasons,
developers have been using ``ENTRY``, ``END``, ``ENDPROC``, and other
annotations in assembly. Due to the lack of their documentation, the macros
are used in rather wrong contexts at some locations. Clearly, ``ENTRY`` was
intended to denote the beginning of global symbols (be it data or code).
``END`` used to mark the end of data or end of special functions with
*non-standard* calling convention. In contrast, ``ENDPROC`` should annotate
only ends of *standard* functions.
When these macros are used correctly, they help assemblers generate a nice
object with both sizes and types set correctly. For example, the result of
``arch/x86/lib/putuser.S``::
Num: Value Size Type Bind Vis Ndx Name
25: 0000000000000000 33 FUNC GLOBAL DEFAULT 1 __put_user_1
29: 0000000000000030 37 FUNC GLOBAL DEFAULT 1 __put_user_2
32: 0000000000000060 36 FUNC GLOBAL DEFAULT 1 __put_user_4
35: 0000000000000090 37 FUNC GLOBAL DEFAULT 1 __put_user_8
This is not only important for debugging purposes. When there are properly
annotated objects like this, tools can be run on them to generate more useful
information. In particular, on properly annotated objects, ``objtool`` can be
run to check and fix the object if needed. Currently, ``objtool`` can report
missing frame pointer setup/destruction in functions. It can also
automatically generate annotations for :doc:`ORC unwinder <x86/orc-unwinder>`
for most code. Both of these are especially important to support reliable
stack traces which are in turn necessary for :doc:`Kernel live patching
<livepatch/livepatch>`.
Caveat and Discussion
---------------------
As one might realize, there were only three macros previously. That is indeed
insufficient to cover all the combinations of cases:
* standard/non-standard function
* code/data
* global/local symbol
There was a discussion_ and instead of extending the current ``ENTRY/END*``
macros, it was decided that brand new macros should be introduced instead::
So how about using macro names that actually show the purpose, instead
of importing all the crappy, historic, essentially randomly chosen
debug symbol macro names from the binutils and older kernels?
.. _discussion: https://lkml.kernel.org/r/20170217104757.28588-1-jslaby@suse.cz
Macros Description
------------------
The new macros are prefixed with the ``SYM_`` prefix and can be divided into
three main groups:
1. ``SYM_FUNC_*`` -- to annotate C-like functions. This means functions with
standard C calling conventions. For example, on x86, this means that the
stack contains a return address at the predefined place and a return from
the function can happen in a standard way. When frame pointers are enabled,
save/restore of frame pointer shall happen at the start/end of a function,
respectively, too.
Checking tools like ``objtool`` should ensure such marked functions conform
to these rules. The tools can also easily annotate these functions with
debugging information (like *ORC data*) automatically.
2. ``SYM_CODE_*`` -- special functions called with special stack. Be it
interrupt handlers with special stack content, trampolines, or startup
functions.
Checking tools mostly ignore checking of these functions. But some debug
information still can be generated automatically. For correct debug data,
this code needs hints like ``UNWIND_HINT_REGS`` provided by developers.
3. ``SYM_DATA*`` -- obviously data belonging to ``.data`` sections and not to
``.text``. Data do not contain instructions, so they have to be treated
specially by the tools: they should not treat the bytes as instructions,
nor assign any debug information to them.
Instruction Macros
~~~~~~~~~~~~~~~~~~
This section covers ``SYM_FUNC_*`` and ``SYM_CODE_*`` enumerated above.
``objtool`` requires that all code must be contained in an ELF symbol. Symbol
names that have a ``.L`` prefix do not emit symbol table entries. ``.L``
prefixed symbols can be used within a code region, but should be avoided for
denoting a range of code via ``SYM_*_START/END`` annotations.
* ``SYM_FUNC_START`` and ``SYM_FUNC_START_LOCAL`` are supposed to be **the
most frequent markings**. They are used for functions with standard calling
conventions -- global and local. Like in C, they both align the functions to
architecture specific ``__ALIGN`` bytes. There are also ``_NOALIGN`` variants
for special cases where developers do not want this implicit alignment.
``SYM_FUNC_START_WEAK`` and ``SYM_FUNC_START_WEAK_NOALIGN`` markings are
also offered as an assembler counterpart to the *weak* attribute known from
C.
All of these **shall** be coupled with ``SYM_FUNC_END``. First, it marks
the sequence of instructions as a function and computes its size to the
generated object file. Second, it also eases checking and processing such
object files as the tools can trivially find exact function boundaries.
So in most cases, developers should write something like in the following
example, having some asm instructions in between the macros, of course::
SYM_FUNC_START(memset)
... asm insns ...
SYM_FUNC_END(memset)
In fact, this kind of annotation corresponds to the now deprecated ``ENTRY``
and ``ENDPROC`` macros.
* ``SYM_FUNC_START_ALIAS`` and ``SYM_FUNC_START_LOCAL_ALIAS`` serve for those
who decided to have two or more names for one function. The typical use is::
SYM_FUNC_START_ALIAS(__memset)
SYM_FUNC_START(memset)
... asm insns ...
SYM_FUNC_END(memset)
SYM_FUNC_END_ALIAS(__memset)
In this example, one can call ``__memset`` or ``memset`` with the same
result, except the debug information for the instructions is generated to
the object file only once -- for the non-``ALIAS`` case.
* ``SYM_CODE_START`` and ``SYM_CODE_START_LOCAL`` should be used only in
special cases -- if you know what you are doing. This is used exclusively
for interrupt handlers and similar where the calling convention is not the C
one. ``_NOALIGN`` variants exist too. The use is the same as for the ``FUNC``
category above::
SYM_CODE_START_LOCAL(bad_put_user)
... asm insns ...
SYM_CODE_END(bad_put_user)
Again, every ``SYM_CODE_START*`` **shall** be coupled by ``SYM_CODE_END``.
To some extent, this category corresponds to deprecated ``ENTRY`` and
``END``. Except ``END`` had several other meanings too.
* ``SYM_INNER_LABEL*`` is used to denote a label inside some
``SYM_{CODE,FUNC}_START`` and ``SYM_{CODE,FUNC}_END``. They are very similar
to C labels, except they can be made global. An example of use::
SYM_CODE_START(ftrace_caller)
/* save_mcount_regs fills in first two parameters */
...
SYM_INNER_LABEL(ftrace_caller_op_ptr, SYM_L_GLOBAL)
/* Load the ftrace_ops into the 3rd parameter */
...
SYM_INNER_LABEL(ftrace_call, SYM_L_GLOBAL)
call ftrace_stub
...
retq
SYM_CODE_END(ftrace_caller)
Data Macros
~~~~~~~~~~~
Similar to instructions, there is a couple of macros to describe data in the
assembly.
* ``SYM_DATA_START`` and ``SYM_DATA_START_LOCAL`` mark the start of some data
and shall be used in conjunction with either ``SYM_DATA_END``, or
``SYM_DATA_END_LABEL``. The latter adds also a label to the end, so that
people can use ``lstack`` and (local) ``lstack_end`` in the following
example::
SYM_DATA_START_LOCAL(lstack)
.skip 4096
SYM_DATA_END_LABEL(lstack, SYM_L_LOCAL, lstack_end)
* ``SYM_DATA`` and ``SYM_DATA_LOCAL`` are variants for simple, mostly one-line
data::
SYM_DATA(HEAP, .long rm_heap)
SYM_DATA(heap_end, .long rm_stack)
In the end, they expand to ``SYM_DATA_START`` with ``SYM_DATA_END``
internally.
Support Macros
~~~~~~~~~~~~~~
All the above reduce themselves to some invocation of ``SYM_START``,
``SYM_END``, or ``SYM_ENTRY`` at last. Normally, developers should avoid using
these.
Further, in the above examples, one could see ``SYM_L_LOCAL``. There are also
``SYM_L_GLOBAL`` and ``SYM_L_WEAK``. All are intended to denote linkage of a
symbol marked by them. They are used either in ``_LABEL`` variants of the
earlier macros, or in ``SYM_START``.
Overriding Macros
~~~~~~~~~~~~~~~~~
Architecture can also override any of the macros in their own
``asm/linkage.h``, including macros specifying the type of a symbol
(``SYM_T_FUNC``, ``SYM_T_OBJECT``, and ``SYM_T_NONE``). As every macro
described in this file is surrounded by ``#ifdef`` + ``#endif``, it is enough
to define the macros differently in the aforementioned architecture-dependent
header.