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1Compile-time stack metadata validation
2======================================
3
4
5Overview
6--------
7
8The kernel CONFIG_STACK_VALIDATION option enables a host tool named
9objtool which runs at compile time. It has a "check" subcommand which
10analyzes every .o file and ensures the validity of its stack metadata.
11It enforces a set of rules on asm code and C inline assembly code so
12that stack traces can be reliable.
13
14For each function, it recursively follows all possible code paths and
15validates the correct frame pointer state at each instruction.
16
17It also follows code paths involving special sections, like
18.altinstructions, __jump_table, and __ex_table, which can add
19alternative execution paths to a given instruction (or set of
20instructions). Similarly, it knows how to follow switch statements, for
21which gcc sometimes uses jump tables.
22
23(Objtool also has an 'orc generate' subcommand which generates debuginfo
24for the ORC unwinder. See Documentation/x86/orc-unwinder.rst in the
25kernel tree for more details.)
26
27
28Why do we need stack metadata validation?
29-----------------------------------------
30
31Here are some of the benefits of validating stack metadata:
32
33a) More reliable stack traces for frame pointer enabled kernels
34
35 Frame pointers are used for debugging purposes. They allow runtime
36 code and debug tools to be able to walk the stack to determine the
37 chain of function call sites that led to the currently executing
38 code.
39
40 For some architectures, frame pointers are enabled by
41 CONFIG_FRAME_POINTER. For some other architectures they may be
42 required by the ABI (sometimes referred to as "backchain pointers").
43
44 For C code, gcc automatically generates instructions for setting up
45 frame pointers when the -fno-omit-frame-pointer option is used.
46
47 But for asm code, the frame setup instructions have to be written by
48 hand, which most people don't do. So the end result is that
49 CONFIG_FRAME_POINTER is honored for C code but not for most asm code.
50
51 For stack traces based on frame pointers to be reliable, all
52 functions which call other functions must first create a stack frame
53 and update the frame pointer. If a first function doesn't properly
54 create a stack frame before calling a second function, the *caller*
55 of the first function will be skipped on the stack trace.
56
57 For example, consider the following example backtrace with frame
58 pointers enabled:
59
60 [<ffffffff81812584>] dump_stack+0x4b/0x63
61 [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
62 [<ffffffff8127f568>] seq_read+0x108/0x3e0
63 [<ffffffff812cce62>] proc_reg_read+0x42/0x70
64 [<ffffffff81256197>] __vfs_read+0x37/0x100
65 [<ffffffff81256b16>] vfs_read+0x86/0x130
66 [<ffffffff81257898>] SyS_read+0x58/0xd0
67 [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76
68
69 It correctly shows that the caller of cmdline_proc_show() is
70 seq_read().
71
72 If we remove the frame pointer logic from cmdline_proc_show() by
73 replacing the frame pointer related instructions with nops, here's
74 what it looks like instead:
75
76 [<ffffffff81812584>] dump_stack+0x4b/0x63
77 [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
78 [<ffffffff812cce62>] proc_reg_read+0x42/0x70
79 [<ffffffff81256197>] __vfs_read+0x37/0x100
80 [<ffffffff81256b16>] vfs_read+0x86/0x130
81 [<ffffffff81257898>] SyS_read+0x58/0xd0
82 [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76
83
84 Notice that cmdline_proc_show()'s caller, seq_read(), has been
85 skipped. Instead the stack trace seems to show that
86 cmdline_proc_show() was called by proc_reg_read().
87
88 The benefit of objtool here is that because it ensures that *all*
89 functions honor CONFIG_FRAME_POINTER, no functions will ever[*] be
90 skipped on a stack trace.
91
92 [*] unless an interrupt or exception has occurred at the very
93 beginning of a function before the stack frame has been created,
94 or at the very end of the function after the stack frame has been
95 destroyed. This is an inherent limitation of frame pointers.
96
97b) ORC (Oops Rewind Capability) unwind table generation
98
99 An alternative to frame pointers and DWARF, ORC unwind data can be
100 used to walk the stack. Unlike frame pointers, ORC data is out of
101 band. So it doesn't affect runtime performance and it can be
102 reliable even when interrupts or exceptions are involved.
103
104 For more details, see Documentation/x86/orc-unwinder.rst.
105
106c) Higher live patching compatibility rate
107
108 Livepatch has an optional "consistency model", which is needed for
109 more complex patches. In order for the consistency model to work,
110 stack traces need to be reliable (or an unreliable condition needs to
111 be detectable). Objtool makes that possible.
112
113 For more details, see the livepatch documentation in the Linux kernel
114 source tree at Documentation/livepatch/livepatch.rst.
115
116Rules
117-----
118
119To achieve the validation, objtool enforces the following rules:
120
1211. Each callable function must be annotated as such with the ELF
122 function type. In asm code, this is typically done using the
123 ENTRY/ENDPROC macros. If objtool finds a return instruction
124 outside of a function, it flags an error since that usually indicates
125 callable code which should be annotated accordingly.
126
127 This rule is needed so that objtool can properly identify each
128 callable function in order to analyze its stack metadata.
129
1302. Conversely, each section of code which is *not* callable should *not*
131 be annotated as an ELF function. The ENDPROC macro shouldn't be used
132 in this case.
133
134 This rule is needed so that objtool can ignore non-callable code.
135 Such code doesn't have to follow any of the other rules.
136
1373. Each callable function which calls another function must have the
138 correct frame pointer logic, if required by CONFIG_FRAME_POINTER or
139 the architecture's back chain rules. This can by done in asm code
140 with the FRAME_BEGIN/FRAME_END macros.
141
142 This rule ensures that frame pointer based stack traces will work as
143 designed. If function A doesn't create a stack frame before calling
144 function B, the _caller_ of function A will be skipped on the stack
145 trace.
146
1474. Dynamic jumps and jumps to undefined symbols are only allowed if:
148
149 a) the jump is part of a switch statement; or
150
151 b) the jump matches sibling call semantics and the frame pointer has
152 the same value it had on function entry.
153
154 This rule is needed so that objtool can reliably analyze all of a
155 function's code paths. If a function jumps to code in another file,
156 and it's not a sibling call, objtool has no way to follow the jump
157 because it only analyzes a single file at a time.
158
1595. A callable function may not execute kernel entry/exit instructions.
160 The only code which needs such instructions is kernel entry code,
161 which shouldn't be be in callable functions anyway.
162
163 This rule is just a sanity check to ensure that callable functions
164 return normally.
165
166
167Objtool warnings
168----------------
169
170For asm files, if you're getting an error which doesn't make sense,
171first make sure that the affected code follows the above rules.
172
173For C files, the common culprits are inline asm statements and calls to
174"noreturn" functions. See below for more details.
175
176Another possible cause for errors in C code is if the Makefile removes
177-fno-omit-frame-pointer or adds -fomit-frame-pointer to the gcc options.
178
179Here are some examples of common warnings reported by objtool, what
180they mean, and suggestions for how to fix them.
181
182
1831. file.o: warning: objtool: func()+0x128: call without frame pointer save/setup
184
185 The func() function made a function call without first saving and/or
186 updating the frame pointer, and CONFIG_FRAME_POINTER is enabled.
187
188 If the error is for an asm file, and func() is indeed a callable
189 function, add proper frame pointer logic using the FRAME_BEGIN and
190 FRAME_END macros. Otherwise, if it's not a callable function, remove
191 its ELF function annotation by changing ENDPROC to END, and instead
192 use the manual unwind hint macros in asm/unwind_hints.h.
193
194 If it's a GCC-compiled .c file, the error may be because the function
195 uses an inline asm() statement which has a "call" instruction. An
196 asm() statement with a call instruction must declare the use of the
197 stack pointer in its output operand. On x86_64, this means adding
198 the ASM_CALL_CONSTRAINT as an output constraint:
199
200 asm volatile("call func" : ASM_CALL_CONSTRAINT);
201
202 Otherwise the stack frame may not get created before the call.
203
204
2052. file.o: warning: objtool: .text+0x53: unreachable instruction
206
207 Objtool couldn't find a code path to reach the instruction.
208
209 If the error is for an asm file, and the instruction is inside (or
210 reachable from) a callable function, the function should be annotated
211 with the ENTRY/ENDPROC macros (ENDPROC is the important one).
212 Otherwise, the code should probably be annotated with the unwind hint
213 macros in asm/unwind_hints.h so objtool and the unwinder can know the
214 stack state associated with the code.
215
216 If you're 100% sure the code won't affect stack traces, or if you're
217 a just a bad person, you can tell objtool to ignore it. See the
218 "Adding exceptions" section below.
219
220 If it's not actually in a callable function (e.g. kernel entry code),
221 change ENDPROC to END.
222
223
2244. file.o: warning: objtool: func(): can't find starting instruction
225 or
226 file.o: warning: objtool: func()+0x11dd: can't decode instruction
227
228 Does the file have data in a text section? If so, that can confuse
229 objtool's instruction decoder. Move the data to a more appropriate
230 section like .data or .rodata.
231
232
2335. file.o: warning: objtool: func()+0x6: unsupported instruction in callable function
234
235 This is a kernel entry/exit instruction like sysenter or iret. Such
236 instructions aren't allowed in a callable function, and are most
237 likely part of the kernel entry code. They should usually not have
238 the callable function annotation (ENDPROC) and should always be
239 annotated with the unwind hint macros in asm/unwind_hints.h.
240
241
2426. file.o: warning: objtool: func()+0x26: sibling call from callable instruction with modified stack frame
243
244 This is a dynamic jump or a jump to an undefined symbol. Objtool
245 assumed it's a sibling call and detected that the frame pointer
246 wasn't first restored to its original state.
247
248 If it's not really a sibling call, you may need to move the
249 destination code to the local file.
250
251 If the instruction is not actually in a callable function (e.g.
252 kernel entry code), change ENDPROC to END and annotate manually with
253 the unwind hint macros in asm/unwind_hints.h.
254
255
2567. file: warning: objtool: func()+0x5c: stack state mismatch
257
258 The instruction's frame pointer state is inconsistent, depending on
259 which execution path was taken to reach the instruction.
260
261 Make sure that, when CONFIG_FRAME_POINTER is enabled, the function
262 pushes and sets up the frame pointer (for x86_64, this means rbp) at
263 the beginning of the function and pops it at the end of the function.
264 Also make sure that no other code in the function touches the frame
265 pointer.
266
267 Another possibility is that the code has some asm or inline asm which
268 does some unusual things to the stack or the frame pointer. In such
269 cases it's probably appropriate to use the unwind hint macros in
270 asm/unwind_hints.h.
271
272
2738. file.o: warning: objtool: funcA() falls through to next function funcB()
274
275 This means that funcA() doesn't end with a return instruction or an
276 unconditional jump, and that objtool has determined that the function
277 can fall through into the next function. There could be different
278 reasons for this:
279
280 1) funcA()'s last instruction is a call to a "noreturn" function like
281 panic(). In this case the noreturn function needs to be added to
282 objtool's hard-coded global_noreturns array. Feel free to bug the
283 objtool maintainer, or you can submit a patch.
284
285 2) funcA() uses the unreachable() annotation in a section of code
286 that is actually reachable.
287
288 3) If funcA() calls an inline function, the object code for funcA()
289 might be corrupt due to a gcc bug. For more details, see:
290 https://gcc.gnu.org/bugzilla/show_bug.cgi?id=70646
291
292
293If the error doesn't seem to make sense, it could be a bug in objtool.
294Feel free to ask the objtool maintainer for help.
295
296
297Adding exceptions
298-----------------
299
300If you _really_ need objtool to ignore something, and are 100% sure
301that it won't affect kernel stack traces, you can tell objtool to
302ignore it:
303
304- To skip validation of a function, use the STACK_FRAME_NON_STANDARD
305 macro.
306
307- To skip validation of a file, add
308
309 OBJECT_FILES_NON_STANDARD_filename.o := y
310
311 to the Makefile.
312
313- To skip validation of a directory, add
314
315 OBJECT_FILES_NON_STANDARD := y
316
317 to the Makefile.
1Compile-time stack metadata validation
2======================================
3
4
5Overview
6--------
7
8The kernel CONFIG_STACK_VALIDATION option enables a host tool named
9objtool which runs at compile time. It has a "check" subcommand which
10analyzes every .o file and ensures the validity of its stack metadata.
11It enforces a set of rules on asm code and C inline assembly code so
12that stack traces can be reliable.
13
14Currently it only checks frame pointer usage, but there are plans to add
15CFI validation for C files and CFI generation for asm files.
16
17For each function, it recursively follows all possible code paths and
18validates the correct frame pointer state at each instruction.
19
20It also follows code paths involving special sections, like
21.altinstructions, __jump_table, and __ex_table, which can add
22alternative execution paths to a given instruction (or set of
23instructions). Similarly, it knows how to follow switch statements, for
24which gcc sometimes uses jump tables.
25
26
27Why do we need stack metadata validation?
28-----------------------------------------
29
30Here are some of the benefits of validating stack metadata:
31
32a) More reliable stack traces for frame pointer enabled kernels
33
34 Frame pointers are used for debugging purposes. They allow runtime
35 code and debug tools to be able to walk the stack to determine the
36 chain of function call sites that led to the currently executing
37 code.
38
39 For some architectures, frame pointers are enabled by
40 CONFIG_FRAME_POINTER. For some other architectures they may be
41 required by the ABI (sometimes referred to as "backchain pointers").
42
43 For C code, gcc automatically generates instructions for setting up
44 frame pointers when the -fno-omit-frame-pointer option is used.
45
46 But for asm code, the frame setup instructions have to be written by
47 hand, which most people don't do. So the end result is that
48 CONFIG_FRAME_POINTER is honored for C code but not for most asm code.
49
50 For stack traces based on frame pointers to be reliable, all
51 functions which call other functions must first create a stack frame
52 and update the frame pointer. If a first function doesn't properly
53 create a stack frame before calling a second function, the *caller*
54 of the first function will be skipped on the stack trace.
55
56 For example, consider the following example backtrace with frame
57 pointers enabled:
58
59 [<ffffffff81812584>] dump_stack+0x4b/0x63
60 [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
61 [<ffffffff8127f568>] seq_read+0x108/0x3e0
62 [<ffffffff812cce62>] proc_reg_read+0x42/0x70
63 [<ffffffff81256197>] __vfs_read+0x37/0x100
64 [<ffffffff81256b16>] vfs_read+0x86/0x130
65 [<ffffffff81257898>] SyS_read+0x58/0xd0
66 [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76
67
68 It correctly shows that the caller of cmdline_proc_show() is
69 seq_read().
70
71 If we remove the frame pointer logic from cmdline_proc_show() by
72 replacing the frame pointer related instructions with nops, here's
73 what it looks like instead:
74
75 [<ffffffff81812584>] dump_stack+0x4b/0x63
76 [<ffffffff812d6dc2>] cmdline_proc_show+0x12/0x30
77 [<ffffffff812cce62>] proc_reg_read+0x42/0x70
78 [<ffffffff81256197>] __vfs_read+0x37/0x100
79 [<ffffffff81256b16>] vfs_read+0x86/0x130
80 [<ffffffff81257898>] SyS_read+0x58/0xd0
81 [<ffffffff8181c1f2>] entry_SYSCALL_64_fastpath+0x12/0x76
82
83 Notice that cmdline_proc_show()'s caller, seq_read(), has been
84 skipped. Instead the stack trace seems to show that
85 cmdline_proc_show() was called by proc_reg_read().
86
87 The benefit of objtool here is that because it ensures that *all*
88 functions honor CONFIG_FRAME_POINTER, no functions will ever[*] be
89 skipped on a stack trace.
90
91 [*] unless an interrupt or exception has occurred at the very
92 beginning of a function before the stack frame has been created,
93 or at the very end of the function after the stack frame has been
94 destroyed. This is an inherent limitation of frame pointers.
95
96b) 100% reliable stack traces for DWARF enabled kernels
97
98 (NOTE: This is not yet implemented)
99
100 As an alternative to frame pointers, DWARF Call Frame Information
101 (CFI) metadata can be used to walk the stack. Unlike frame pointers,
102 CFI metadata is out of band. So it doesn't affect runtime
103 performance and it can be reliable even when interrupts or exceptions
104 are involved.
105
106 For C code, gcc automatically generates DWARF CFI metadata. But for
107 asm code, generating CFI is a tedious manual approach which requires
108 manually placed .cfi assembler macros to be scattered throughout the
109 code. It's clumsy and very easy to get wrong, and it makes the real
110 code harder to read.
111
112 Stacktool will improve this situation in several ways. For code
113 which already has CFI annotations, it will validate them. For code
114 which doesn't have CFI annotations, it will generate them. So an
115 architecture can opt to strip out all the manual .cfi annotations
116 from their asm code and have objtool generate them instead.
117
118 We might also add a runtime stack validation debug option where we
119 periodically walk the stack from schedule() and/or an NMI to ensure
120 that the stack metadata is sane and that we reach the bottom of the
121 stack.
122
123 So the benefit of objtool here will be that external tooling should
124 always show perfect stack traces. And the same will be true for
125 kernel warning/oops traces if the architecture has a runtime DWARF
126 unwinder.
127
128c) Higher live patching compatibility rate
129
130 (NOTE: This is not yet implemented)
131
132 Currently with CONFIG_LIVEPATCH there's a basic live patching
133 framework which is safe for roughly 85-90% of "security" fixes. But
134 patches can't have complex features like function dependency or
135 prototype changes, or data structure changes.
136
137 There's a strong need to support patches which have the more complex
138 features so that the patch compatibility rate for security fixes can
139 eventually approach something resembling 100%. To achieve that, a
140 "consistency model" is needed, which allows tasks to be safely
141 transitioned from an unpatched state to a patched state.
142
143 One of the key requirements of the currently proposed livepatch
144 consistency model [*] is that it needs to walk the stack of each
145 sleeping task to determine if it can be transitioned to the patched
146 state. If objtool can ensure that stack traces are reliable, this
147 consistency model can be used and the live patching compatibility
148 rate can be improved significantly.
149
150 [*] https://lkml.kernel.org/r/cover.1423499826.git.jpoimboe@redhat.com
151
152
153Rules
154-----
155
156To achieve the validation, objtool enforces the following rules:
157
1581. Each callable function must be annotated as such with the ELF
159 function type. In asm code, this is typically done using the
160 ENTRY/ENDPROC macros. If objtool finds a return instruction
161 outside of a function, it flags an error since that usually indicates
162 callable code which should be annotated accordingly.
163
164 This rule is needed so that objtool can properly identify each
165 callable function in order to analyze its stack metadata.
166
1672. Conversely, each section of code which is *not* callable should *not*
168 be annotated as an ELF function. The ENDPROC macro shouldn't be used
169 in this case.
170
171 This rule is needed so that objtool can ignore non-callable code.
172 Such code doesn't have to follow any of the other rules.
173
1743. Each callable function which calls another function must have the
175 correct frame pointer logic, if required by CONFIG_FRAME_POINTER or
176 the architecture's back chain rules. This can by done in asm code
177 with the FRAME_BEGIN/FRAME_END macros.
178
179 This rule ensures that frame pointer based stack traces will work as
180 designed. If function A doesn't create a stack frame before calling
181 function B, the _caller_ of function A will be skipped on the stack
182 trace.
183
1844. Dynamic jumps and jumps to undefined symbols are only allowed if:
185
186 a) the jump is part of a switch statement; or
187
188 b) the jump matches sibling call semantics and the frame pointer has
189 the same value it had on function entry.
190
191 This rule is needed so that objtool can reliably analyze all of a
192 function's code paths. If a function jumps to code in another file,
193 and it's not a sibling call, objtool has no way to follow the jump
194 because it only analyzes a single file at a time.
195
1965. A callable function may not execute kernel entry/exit instructions.
197 The only code which needs such instructions is kernel entry code,
198 which shouldn't be be in callable functions anyway.
199
200 This rule is just a sanity check to ensure that callable functions
201 return normally.
202
203
204Errors in .S files
205------------------
206
207If you're getting an error in a compiled .S file which you don't
208understand, first make sure that the affected code follows the above
209rules.
210
211Here are some examples of common warnings reported by objtool, what
212they mean, and suggestions for how to fix them.
213
214
2151. asm_file.o: warning: objtool: func()+0x128: call without frame pointer save/setup
216
217 The func() function made a function call without first saving and/or
218 updating the frame pointer.
219
220 If func() is indeed a callable function, add proper frame pointer
221 logic using the FRAME_BEGIN and FRAME_END macros. Otherwise, remove
222 its ELF function annotation by changing ENDPROC to END.
223
224 If you're getting this error in a .c file, see the "Errors in .c
225 files" section.
226
227
2282. asm_file.o: warning: objtool: .text+0x53: return instruction outside of a callable function
229
230 A return instruction was detected, but objtool couldn't find a way
231 for a callable function to reach the instruction.
232
233 If the return instruction is inside (or reachable from) a callable
234 function, the function needs to be annotated with the ENTRY/ENDPROC
235 macros.
236
237 If you _really_ need a return instruction outside of a function, and
238 are 100% sure that it won't affect stack traces, you can tell
239 objtool to ignore it. See the "Adding exceptions" section below.
240
241
2423. asm_file.o: warning: objtool: func()+0x9: function has unreachable instruction
243
244 The instruction lives inside of a callable function, but there's no
245 possible control flow path from the beginning of the function to the
246 instruction.
247
248 If the instruction is actually needed, and it's actually in a
249 callable function, ensure that its function is properly annotated
250 with ENTRY/ENDPROC.
251
252 If it's not actually in a callable function (e.g. kernel entry code),
253 change ENDPROC to END.
254
255
2564. asm_file.o: warning: objtool: func(): can't find starting instruction
257 or
258 asm_file.o: warning: objtool: func()+0x11dd: can't decode instruction
259
260 Did you put data in a text section? If so, that can confuse
261 objtool's instruction decoder. Move the data to a more appropriate
262 section like .data or .rodata.
263
264
2655. asm_file.o: warning: objtool: func()+0x6: kernel entry/exit from callable instruction
266
267 This is a kernel entry/exit instruction like sysenter or sysret.
268 Such instructions aren't allowed in a callable function, and are most
269 likely part of the kernel entry code.
270
271 If the instruction isn't actually in a callable function, change
272 ENDPROC to END.
273
274
2756. asm_file.o: warning: objtool: func()+0x26: sibling call from callable instruction with changed frame pointer
276
277 This is a dynamic jump or a jump to an undefined symbol. Stacktool
278 assumed it's a sibling call and detected that the frame pointer
279 wasn't first restored to its original state.
280
281 If it's not really a sibling call, you may need to move the
282 destination code to the local file.
283
284 If the instruction is not actually in a callable function (e.g.
285 kernel entry code), change ENDPROC to END.
286
287
2887. asm_file: warning: objtool: func()+0x5c: frame pointer state mismatch
289
290 The instruction's frame pointer state is inconsistent, depending on
291 which execution path was taken to reach the instruction.
292
293 Make sure the function pushes and sets up the frame pointer (for
294 x86_64, this means rbp) at the beginning of the function and pops it
295 at the end of the function. Also make sure that no other code in the
296 function touches the frame pointer.
297
298
299Errors in .c files
300------------------
301
3021. c_file.o: warning: objtool: funcA() falls through to next function funcB()
303
304 This means that funcA() doesn't end with a return instruction or an
305 unconditional jump, and that objtool has determined that the function
306 can fall through into the next function. There could be different
307 reasons for this:
308
309 1) funcA()'s last instruction is a call to a "noreturn" function like
310 panic(). In this case the noreturn function needs to be added to
311 objtool's hard-coded global_noreturns array. Feel free to bug the
312 objtool maintainer, or you can submit a patch.
313
314 2) funcA() uses the unreachable() annotation in a section of code
315 that is actually reachable.
316
317 3) If funcA() calls an inline function, the object code for funcA()
318 might be corrupt due to a gcc bug. For more details, see:
319 https://gcc.gnu.org/bugzilla/show_bug.cgi?id=70646
320
3212. If you're getting any other objtool error in a compiled .c file, it
322 may be because the file uses an asm() statement which has a "call"
323 instruction. An asm() statement with a call instruction must declare
324 the use of the stack pointer in its output operand. For example, on
325 x86_64:
326
327 register void *__sp asm("rsp");
328 asm volatile("call func" : "+r" (__sp));
329
330 Otherwise the stack frame may not get created before the call.
331
3323. Another possible cause for errors in C code is if the Makefile removes
333 -fno-omit-frame-pointer or adds -fomit-frame-pointer to the gcc options.
334
335Also see the above section for .S file errors for more information what
336the individual error messages mean.
337
338If the error doesn't seem to make sense, it could be a bug in objtool.
339Feel free to ask the objtool maintainer for help.
340
341
342Adding exceptions
343-----------------
344
345If you _really_ need objtool to ignore something, and are 100% sure
346that it won't affect kernel stack traces, you can tell objtool to
347ignore it:
348
349- To skip validation of a function, use the STACK_FRAME_NON_STANDARD
350 macro.
351
352- To skip validation of a file, add
353
354 OBJECT_FILES_NON_STANDARD_filename.o := n
355
356 to the Makefile.
357
358- To skip validation of a directory, add
359
360 OBJECT_FILES_NON_STANDARD := y
361
362 to the Makefile.