tools/objtool/Documentation/stack-validation.txt - linux - Git at Google

 Compile-time stack metadata validation
 ======================================


 Overview
 --------

 The kernel CONFIG_STACK_VALIDATION option enables a host tool named
 objtool which runs at compile time.  It has a "check" subcommand which
 analyzes every .o file and ensures the validity of its stack metadata.
 It enforces a set of rules on asm code and C inline assembly code so
 that stack traces can be reliable.

 For each function, it recursively follows all possible code paths and
 validates the correct frame pointer state at each instruction.

 It also follows code paths involving special sections, like
 .altinstructions, __jump_table, and __ex_table, which can add
 alternative execution paths to a given instruction (or set of
 instructions).  Similarly, it knows how to follow switch statements, for
 which gcc sometimes uses jump tables.

 (Objtool also has an 'orc generate' subcommand which generates debuginfo
 for the ORC unwinder.  See Documentation/x86/orc-unwinder.txt in the
 kernel tree for more details.)


 Why do we need stack metadata validation?
 -----------------------------------------

 Here are some of the benefits of validating stack metadata:

 a) More reliable stack traces for frame pointer enabled kernels

    Frame pointers are used for debugging purposes.  They allow runtime
    code and debug tools to be able to walk the stack to determine the
    chain of function call sites that led to the currently executing
    code.

    For some architectures, frame pointers are enabled by
    CONFIG_FRAME_POINTER.  For some other architectures they may be
    required by the ABI (sometimes referred to as "backchain pointers").

    For C code, gcc automatically generates instructions for setting up
    frame pointers when the -fno-omit-frame-pointer option is used.

    But for asm code, the frame setup instructions have to be written by
    hand, which most people don't do.  So the end result is that
    CONFIG_FRAME_POINTER is honored for C code but not for most asm code.

    For stack traces based on frame pointers to be reliable, all
    functions which call other functions must first create a stack frame
    and update the frame pointer.  If a first function doesn't properly
    create a stack frame before calling a second function, the *caller*
    of the first function will be skipped on the stack trace.

    For example, consider the following example backtrace with frame
    pointers enabled:

      [<ffffffff81812584>] dump_stack+0x4b/0x63
      [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
      [<ffffffff8127f568>] seq_read+0x108/0x3e0
      [<ffffffff812cce62>] proc_reg_read+0x42/0x70
      [<ffffffff81256197>] __vfs_read+0x37/0x100
      [<ffffffff81256b16>] vfs_read+0x86/0x130
      [<ffffffff81257898>] SyS_read+0x58/0xd0
      [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76

    It correctly shows that the caller of cmdline_proc_show() is
    seq_read().

    If we remove the frame pointer logic from cmdline_proc_show() by
    replacing the frame pointer related instructions with nops, here's
    what it looks like instead:

      [<ffffffff81812584>] dump_stack+0x4b/0x63
      [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
      [<ffffffff812cce62>] proc_reg_read+0x42/0x70
      [<ffffffff81256197>] __vfs_read+0x37/0x100
      [<ffffffff81256b16>] vfs_read+0x86/0x130
      [<ffffffff81257898>] SyS_read+0x58/0xd0
      [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76

    Notice that cmdline_proc_show()'s caller, seq_read(), has been
    skipped.  Instead the stack trace seems to show that
    cmdline_proc_show() was called by proc_reg_read().

    The benefit of objtool here is that because it ensures that *all*
    functions honor CONFIG_FRAME_POINTER, no functions will ever[*] be
    skipped on a stack trace.

    [*] unless an interrupt or exception has occurred at the very
        beginning of a function before the stack frame has been created,
        or at the very end of the function after the stack frame has been
        destroyed.  This is an inherent limitation of frame pointers.

 b) ORC (Oops Rewind Capability) unwind table generation

    An alternative to frame pointers and DWARF, ORC unwind data can be
    used to walk the stack.  Unlike frame pointers, ORC data is out of
    band.  So it doesn't affect runtime performance and it can be
    reliable even when interrupts or exceptions are involved.

    For more details, see Documentation/x86/orc-unwinder.txt.

 c) Higher live patching compatibility rate

    Livepatch has an optional "consistency model", which is needed for
    more complex patches.  In order for the consistency model to work,
    stack traces need to be reliable (or an unreliable condition needs to
    be detectable).  Objtool makes that possible.

    For more details, see the livepatch documentation in the Linux kernel
    source tree at Documentation/livepatch/livepatch.txt.

 Rules
 -----

 To achieve the validation, objtool enforces the following rules:

 1. Each callable function must be annotated as such with the ELF
    function type.  In asm code, this is typically done using the
    ENTRY/ENDPROC macros.  If objtool finds a return instruction
    outside of a function, it flags an error since that usually indicates
    callable code which should be annotated accordingly.

    This rule is needed so that objtool can properly identify each
    callable function in order to analyze its stack metadata.

 2. Conversely, each section of code which is *not* callable should *not*
    be annotated as an ELF function.  The ENDPROC macro shouldn't be used
    in this case.

    This rule is needed so that objtool can ignore non-callable code.
    Such code doesn't have to follow any of the other rules.

 3. Each callable function which calls another function must have the
    correct frame pointer logic, if required by CONFIG_FRAME_POINTER or
    the architecture's back chain rules.  This can by done in asm code
    with the FRAME_BEGIN/FRAME_END macros.

    This rule ensures that frame pointer based stack traces will work as
    designed.  If function A doesn't create a stack frame before calling
    function B, the _caller_ of function A will be skipped on the stack
    trace.

 4. Dynamic jumps and jumps to undefined symbols are only allowed if:

    a) the jump is part of a switch statement; or

    b) the jump matches sibling call semantics and the frame pointer has
       the same value it had on function entry.

    This rule is needed so that objtool can reliably analyze all of a
    function's code paths.  If a function jumps to code in another file,
    and it's not a sibling call, objtool has no way to follow the jump
    because it only analyzes a single file at a time.

 5. A callable function may not execute kernel entry/exit instructions.
    The only code which needs such instructions is kernel entry code,
    which shouldn't be be in callable functions anyway.

    This rule is just a sanity check to ensure that callable functions
    return normally.


 Objtool warnings
 ----------------

 For asm files, if you're getting an error which doesn't make sense,
 first make sure that the affected code follows the above rules.

 For C files, the common culprits are inline asm statements and calls to
 "noreturn" functions.  See below for more details.

 Another possible cause for errors in C code is if the Makefile removes
 -fno-omit-frame-pointer or adds -fomit-frame-pointer to the gcc options.

 Here are some examples of common warnings reported by objtool, what
 they mean, and suggestions for how to fix them.


 1. file.o: warning: objtool: func()+0x128: call without frame pointer save/setup

    The func() function made a function call without first saving and/or
    updating the frame pointer, and CONFIG_FRAME_POINTER is enabled.

    If the error is for an asm file, and func() is indeed a callable
    function, add proper frame pointer logic using the FRAME_BEGIN and
    FRAME_END macros.  Otherwise, if it's not a callable function, remove
    its ELF function annotation by changing ENDPROC to END, and instead
    use the manual unwind hint macros in asm/unwind_hints.h.

    If it's a GCC-compiled .c file, the error may be because the function
    uses an inline asm() statement which has a "call" instruction.  An
    asm() statement with a call instruction must declare the use of the
    stack pointer in its output operand.  On x86_64, this means adding
    the ASM_CALL_CONSTRAINT as an output constraint:

      asm volatile("call func" : ASM_CALL_CONSTRAINT);

    Otherwise the stack frame may not get created before the call.


 2. file.o: warning: objtool: .text+0x53: unreachable instruction

    Objtool couldn't find a code path to reach the instruction.

    If the error is for an asm file, and the instruction is inside (or
    reachable from) a callable function, the function should be annotated
    with the ENTRY/ENDPROC macros (ENDPROC is the important one).
    Otherwise, the code should probably be annotated with the unwind hint
    macros in asm/unwind_hints.h so objtool and the unwinder can know the
    stack state associated with the code.

    If you're 100% sure the code won't affect stack traces, or if you're
    a just a bad person, you can tell objtool to ignore it.  See the
    "Adding exceptions" section below.

    If it's not actually in a callable function (e.g. kernel entry code),
    change ENDPROC to END.


 4. file.o: warning: objtool: func(): can't find starting instruction
    or
    file.o: warning: objtool: func()+0x11dd: can't decode instruction

    Does the file have data in a text section?  If so, that can confuse
    objtool's instruction decoder.  Move the data to a more appropriate
    section like .data or .rodata.


 5. file.o: warning: objtool: func()+0x6: unsupported instruction in callable function

    This is a kernel entry/exit instruction like sysenter or iret.  Such
    instructions aren't allowed in a callable function, and are most
    likely part of the kernel entry code.  They should usually not have
    the callable function annotation (ENDPROC) and should always be
    annotated with the unwind hint macros in asm/unwind_hints.h.


 6. file.o: warning: objtool: func()+0x26: sibling call from callable instruction with modified stack frame

    This is a dynamic jump or a jump to an undefined symbol.  Objtool
    assumed it's a sibling call and detected that the frame pointer
    wasn't first restored to its original state.

    If it's not really a sibling call, you may need to move the
    destination code to the local file.

    If the instruction is not actually in a callable function (e.g.
    kernel entry code), change ENDPROC to END and annotate manually with
    the unwind hint macros in asm/unwind_hints.h.


 7. file: warning: objtool: func()+0x5c: stack state mismatch

    The instruction's frame pointer state is inconsistent, depending on
    which execution path was taken to reach the instruction.

    Make sure that, when CONFIG_FRAME_POINTER is enabled, the function
    pushes and sets up the frame pointer (for x86_64, this means rbp) at
    the beginning of the function and pops it at the end of the function.
    Also make sure that no other code in the function touches the frame
    pointer.

    Another possibility is that the code has some asm or inline asm which
    does some unusual things to the stack or the frame pointer.  In such
    cases it's probably appropriate to use the unwind hint macros in
    asm/unwind_hints.h.


 8. file.o: warning: objtool: funcA() falls through to next function funcB()

    This means that funcA() doesn't end with a return instruction or an
    unconditional jump, and that objtool has determined that the function
    can fall through into the next function.  There could be different
    reasons for this:

    1) funcA()'s last instruction is a call to a "noreturn" function like
       panic().  In this case the noreturn function needs to be added to
       objtool's hard-coded global_noreturns array.  Feel free to bug the
       objtool maintainer, or you can submit a patch.

    2) funcA() uses the unreachable() annotation in a section of code
       that is actually reachable.

    3) If funcA() calls an inline function, the object code for funcA()
       might be corrupt due to a gcc bug.  For more details, see:
       https://gcc.gnu.org/bugzilla/show_bug.cgi?id=70646


 If the error doesn't seem to make sense, it could be a bug in objtool.
 Feel free to ask the objtool maintainer for help.


 Adding exceptions
 -----------------

 If you _really_ need objtool to ignore something, and are 100% sure
 that it won't affect kernel stack traces, you can tell objtool to
 ignore it:

 - To skip validation of a function, use the STACK_FRAME_NON_STANDARD
   macro.

 - To skip validation of a file, add

     OBJECT_FILES_NON_STANDARD_filename.o := n

   to the Makefile.

 - To skip validation of a directory, add

     OBJECT_FILES_NON_STANDARD := y

   to the Makefile.
	Compile-time stack metadata validation
	======================================


	Overview
	--------

	The kernel CONFIG_STACK_VALIDATION option enables a host tool named
	objtool which runs at compile time. It has a "check" subcommand which
	analyzes every .o file and ensures the validity of its stack metadata.
	It enforces a set of rules on asm code and C inline assembly code so
	that stack traces can be reliable.

	For each function, it recursively follows all possible code paths and
	validates the correct frame pointer state at each instruction.

	It also follows code paths involving special sections, like
	.altinstructions, __jump_table, and __ex_table, which can add
	alternative execution paths to a given instruction (or set of
	instructions). Similarly, it knows how to follow switch statements, for
	which gcc sometimes uses jump tables.

	(Objtool also has an 'orc generate' subcommand which generates debuginfo
	for the ORC unwinder. See Documentation/x86/orc-unwinder.txt in the
	kernel tree for more details.)


	Why do we need stack metadata validation?
	-----------------------------------------

	Here are some of the benefits of validating stack metadata:

	a) More reliable stack traces for frame pointer enabled kernels

	Frame pointers are used for debugging purposes. They allow runtime
	code and debug tools to be able to walk the stack to determine the
	chain of function call sites that led to the currently executing
	code.

	For some architectures, frame pointers are enabled by
	CONFIG_FRAME_POINTER. For some other architectures they may be
	required by the ABI (sometimes referred to as "backchain pointers").

	For C code, gcc automatically generates instructions for setting up
	frame pointers when the -fno-omit-frame-pointer option is used.

	But for asm code, the frame setup instructions have to be written by
	hand, which most people don't do. So the end result is that
	CONFIG_FRAME_POINTER is honored for C code but not for most asm code.

	For stack traces based on frame pointers to be reliable, all
	functions which call other functions must first create a stack frame
	and update the frame pointer. If a first function doesn't properly
	create a stack frame before calling a second function, the caller
	of the first function will be skipped on the stack trace.

	For example, consider the following example backtrace with frame
	pointers enabled:

	[<ffffffff81812584>] dump_stack+0x4b/0x63
	[<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
	[<ffffffff8127f568>] seq_read+0x108/0x3e0
	[<ffffffff812cce62>] proc_reg_read+0x42/0x70
	[<ffffffff81256197>] __vfs_read+0x37/0x100
	[<ffffffff81256b16>] vfs_read+0x86/0x130
	[<ffffffff81257898>] SyS_read+0x58/0xd0
	[<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76

	It correctly shows that the caller of cmdline_proc_show() is
	seq_read().

	If we remove the frame pointer logic from cmdline_proc_show() by
	replacing the frame pointer related instructions with nops, here's
	what it looks like instead:

	[<ffffffff81812584>] dump_stack+0x4b/0x63
	[<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
	[<ffffffff812cce62>] proc_reg_read+0x42/0x70
	[<ffffffff81256197>] __vfs_read+0x37/0x100
	[<ffffffff81256b16>] vfs_read+0x86/0x130
	[<ffffffff81257898>] SyS_read+0x58/0xd0
	[<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76

	Notice that cmdline_proc_show()'s caller, seq_read(), has been
	skipped. Instead the stack trace seems to show that
	cmdline_proc_show() was called by proc_reg_read().

	The benefit of objtool here is that because it ensures that all
	functions honor CONFIG_FRAME_POINTER, no functions will ever[*] be
	skipped on a stack trace.

	[*] unless an interrupt or exception has occurred at the very
	beginning of a function before the stack frame has been created,
	or at the very end of the function after the stack frame has been
	destroyed. This is an inherent limitation of frame pointers.

	b) ORC (Oops Rewind Capability) unwind table generation

	An alternative to frame pointers and DWARF, ORC unwind data can be
	used to walk the stack. Unlike frame pointers, ORC data is out of
	band. So it doesn't affect runtime performance and it can be
	reliable even when interrupts or exceptions are involved.

	For more details, see Documentation/x86/orc-unwinder.txt.

	c) Higher live patching compatibility rate

	Livepatch has an optional "consistency model", which is needed for
	more complex patches. In order for the consistency model to work,
	stack traces need to be reliable (or an unreliable condition needs to
	be detectable). Objtool makes that possible.

	For more details, see the livepatch documentation in the Linux kernel
	source tree at Documentation/livepatch/livepatch.txt.

	Rules
	-----

	To achieve the validation, objtool enforces the following rules:

	1. Each callable function must be annotated as such with the ELF
	function type. In asm code, this is typically done using the
	ENTRY/ENDPROC macros. If objtool finds a return instruction
	outside of a function, it flags an error since that usually indicates
	callable code which should be annotated accordingly.

	This rule is needed so that objtool can properly identify each
	callable function in order to analyze its stack metadata.

	2. Conversely, each section of code which is not callable should not
	be annotated as an ELF function. The ENDPROC macro shouldn't be used
	in this case.

	This rule is needed so that objtool can ignore non-callable code.
	Such code doesn't have to follow any of the other rules.

	3. Each callable function which calls another function must have the
	correct frame pointer logic, if required by CONFIG_FRAME_POINTER or
	the architecture's back chain rules. This can by done in asm code
	with the FRAME_BEGIN/FRAME_END macros.

	This rule ensures that frame pointer based stack traces will work as
	designed. If function A doesn't create a stack frame before calling
	function B, the _caller_ of function A will be skipped on the stack
	trace.

	4. Dynamic jumps and jumps to undefined symbols are only allowed if:

	a) the jump is part of a switch statement; or

	b) the jump matches sibling call semantics and the frame pointer has
	the same value it had on function entry.

	This rule is needed so that objtool can reliably analyze all of a
	function's code paths. If a function jumps to code in another file,
	and it's not a sibling call, objtool has no way to follow the jump
	because it only analyzes a single file at a time.

	5. A callable function may not execute kernel entry/exit instructions.
	The only code which needs such instructions is kernel entry code,
	which shouldn't be be in callable functions anyway.

	This rule is just a sanity check to ensure that callable functions
	return normally.


	Objtool warnings
	----------------

	For asm files, if you're getting an error which doesn't make sense,
	first make sure that the affected code follows the above rules.

	For C files, the common culprits are inline asm statements and calls to
	"noreturn" functions. See below for more details.

	Another possible cause for errors in C code is if the Makefile removes
	-fno-omit-frame-pointer or adds -fomit-frame-pointer to the gcc options.

	Here are some examples of common warnings reported by objtool, what
	they mean, and suggestions for how to fix them.


	1. file.o: warning: objtool: func()+0x128: call without frame pointer save/setup

	The func() function made a function call without first saving and/or
	updating the frame pointer, and CONFIG_FRAME_POINTER is enabled.

	If the error is for an asm file, and func() is indeed a callable
	function, add proper frame pointer logic using the FRAME_BEGIN and
	FRAME_END macros. Otherwise, if it's not a callable function, remove
	its ELF function annotation by changing ENDPROC to END, and instead
	use the manual unwind hint macros in asm/unwind_hints.h.

	If it's a GCC-compiled .c file, the error may be because the function
	uses an inline asm() statement which has a "call" instruction. An
	asm() statement with a call instruction must declare the use of the
	stack pointer in its output operand. On x86_64, this means adding
	the ASM_CALL_CONSTRAINT as an output constraint:

	asm volatile("call func" : ASM_CALL_CONSTRAINT);

	Otherwise the stack frame may not get created before the call.


	2. file.o: warning: objtool: .text+0x53: unreachable instruction

	Objtool couldn't find a code path to reach the instruction.

	If the error is for an asm file, and the instruction is inside (or
	reachable from) a callable function, the function should be annotated
	with the ENTRY/ENDPROC macros (ENDPROC is the important one).
	Otherwise, the code should probably be annotated with the unwind hint
	macros in asm/unwind_hints.h so objtool and the unwinder can know the
	stack state associated with the code.

	If you're 100% sure the code won't affect stack traces, or if you're
	a just a bad person, you can tell objtool to ignore it. See the
	"Adding exceptions" section below.

	If it's not actually in a callable function (e.g. kernel entry code),
	change ENDPROC to END.


	4. file.o: warning: objtool: func(): can't find starting instruction
	or
	file.o: warning: objtool: func()+0x11dd: can't decode instruction

	Does the file have data in a text section? If so, that can confuse
	objtool's instruction decoder. Move the data to a more appropriate
	section like .data or .rodata.


	5. file.o: warning: objtool: func()+0x6: unsupported instruction in callable function

	This is a kernel entry/exit instruction like sysenter or iret. Such
	instructions aren't allowed in a callable function, and are most
	likely part of the kernel entry code. They should usually not have
	the callable function annotation (ENDPROC) and should always be
	annotated with the unwind hint macros in asm/unwind_hints.h.


	6. file.o: warning: objtool: func()+0x26: sibling call from callable instruction with modified stack frame

	This is a dynamic jump or a jump to an undefined symbol. Objtool
	assumed it's a sibling call and detected that the frame pointer
	wasn't first restored to its original state.

	If it's not really a sibling call, you may need to move the
	destination code to the local file.

	If the instruction is not actually in a callable function (e.g.
	kernel entry code), change ENDPROC to END and annotate manually with
	the unwind hint macros in asm/unwind_hints.h.


	7. file: warning: objtool: func()+0x5c: stack state mismatch

	The instruction's frame pointer state is inconsistent, depending on
	which execution path was taken to reach the instruction.

	Make sure that, when CONFIG_FRAME_POINTER is enabled, the function
	pushes and sets up the frame pointer (for x86_64, this means rbp) at
	the beginning of the function and pops it at the end of the function.
	Also make sure that no other code in the function touches the frame
	pointer.

	Another possibility is that the code has some asm or inline asm which
	does some unusual things to the stack or the frame pointer. In such
	cases it's probably appropriate to use the unwind hint macros in
	asm/unwind_hints.h.


	8. file.o: warning: objtool: funcA() falls through to next function funcB()

	This means that funcA() doesn't end with a return instruction or an
	unconditional jump, and that objtool has determined that the function
	can fall through into the next function. There could be different
	reasons for this:

	1) funcA()'s last instruction is a call to a "noreturn" function like
	panic(). In this case the noreturn function needs to be added to
	objtool's hard-coded global_noreturns array. Feel free to bug the
	objtool maintainer, or you can submit a patch.

	2) funcA() uses the unreachable() annotation in a section of code
	that is actually reachable.

	3) If funcA() calls an inline function, the object code for funcA()
	might be corrupt due to a gcc bug. For more details, see:
	https://gcc.gnu.org/bugzilla/show_bug.cgi?id=70646


	If the error doesn't seem to make sense, it could be a bug in objtool.
	Feel free to ask the objtool maintainer for help.


	Adding exceptions
	-----------------

	If you _really_ need objtool to ignore something, and are 100% sure
	that it won't affect kernel stack traces, you can tell objtool to
	ignore it:

	- To skip validation of a function, use the STACK_FRAME_NON_STANDARD
	macro.

	- To skip validation of a file, add

	OBJECT_FILES_NON_STANDARD_filename.o := n

	to the Makefile.

	- To skip validation of a directory, add

	OBJECT_FILES_NON_STANDARD := y

	to the Makefile.