Message ID | 20240625-arm64-gcs-v9-5-0f634469b8f0@kernel.org (mailing list archive) |
---|---|
State | New, archived |
Headers | show |
Series | arm64/gcs: Provide support for GCS in userspace | expand |
On 6/25/24 7:57 AM, Mark Brown wrote: > Add some documentation of the userspace ABI for Guarded Control Stacks. > > Reviewed-by: Thiago Jung Bauermann <thiago.bauermann@linaro.org> > Signed-off-by: Mark Brown <broonie@kernel.org> > --- > Documentation/arch/arm64/gcs.rst | 233 +++++++++++++++++++++++++++++++++++++ > Documentation/arch/arm64/index.rst | 1 + > 2 files changed, 234 insertions(+) > > diff --git a/Documentation/arch/arm64/gcs.rst b/Documentation/arch/arm64/gcs.rst > new file mode 100644 > index 000000000000..c45c0326836a > --- /dev/null > +++ b/Documentation/arch/arm64/gcs.rst > @@ -0,0 +1,233 @@ > +=============================================== > +Guarded Control Stack support for AArch64 Linux > +=============================================== > + > +This document outlines briefly the interface provided to userspace by Linux in > +order to support use of the ARM Guarded Control Stack (GCS) feature. > + > +This is an outline of the most important features and issues only and not > +intended to be exhaustive. > + > + > + > +1. General > +----------- > + > +* GCS is an architecture feature intended to provide greater protection > + against return oriented programming (ROP) attacks and to simplify the > + implementation of features that need to collect stack traces such as > + profiling. > + > +* When GCS is enabled a separate guarded control stack is maintained by the > + PE which is writeable only through specific GCS operations. This > + stores the call stack only, when a procedure call instruction is only. When > + performed the current PC is pushed onto the GCS and on RET the > + address in the LR is verified against that on the top of the GCS. > + > +* When active current GCS pointer is stored in the system register Cannot parse this incomplete sentence... > + GCSPR_EL0. This is readable by userspace but can only be updated > + via specific GCS instructions. > + > +* The architecture provides instructions for switching between guarded > + control stacks with checks to ensure that the new stack is a valid > + target for switching. > + > +* The functionality of GCS is similar to that provided by the x86 Shadow > + Stack feature, due to sharing of userspace interfaces the ABI refers to feature. Due to > + shadow stacks rather than GCS. > + > +* Support for GCS is reported to userspace via HWCAP2_GCS in the aux vector > + AT_HWCAP2 entry. > + > +* GCS is enabled per thread. While there is support for disabling GCS > + at runtime this should be done with great care. > + > +* GCS memory access faults are reported as normal memory access faults. > + > +* GCS specific errors (those reported with EC 0x2d) will be reported as > + SIGSEGV with a si_code of SEGV_CPERR (control protection error). > + > +* GCS is supported only for AArch64. > + > +* On systems where GCS is supported GCSPR_EL0 is always readable by EL0 > + regardless of the GCS configuration for the thread. > + > +* The architecture supports enabling GCS without verifying that return values > + in LR match those in the GCS, the LR will be ignored. This is not supported GCS; the LR > + by Linux. > + > +* EL0 GCS entries with bit 63 set are reserved for use, one such use is defined for use. One such > + below for signals and should be ignored when parsing the stack if not > + understood. > + > + > +2. Enabling and disabling Guarded Control Stacks > +------------------------------------------------- > + > +* GCS is enabled and disabled for a thread via the PR_SET_SHADOW_STACK_STATUS > + prctl(), this takes a single flags argument specifying which GCS features prctl(). This takes > + should be used. > + > +* When set PR_SHADOW_STACK_ENABLE flag allocates a Guarded Control Stack > + and enables GCS for the thread, enabling the functionality controlled by > + GCSCRE0_EL1.{nTR, RVCHKEN, PCRSEL}. > + > +* When set the PR_SHADOW_STACK_PUSH flag enables the functionality controlled > + by GCSCRE0_EL1.PUSHMEn, allowing explicit GCS pushes. > + > +* When set the PR_SHADOW_STACK_WRITE flag enables the functionality controlled > + by GCSCRE0_EL1.STREn, allowing explicit stores to the Guarded Control Stack. > + > +* Any unknown flags will cause PR_SET_SHADOW_STACK_STATUS to return -EINVAL. > + > +* PR_LOCK_SHADOW_STACK_STATUS is passed a bitmask of features with the same > + values as used for PR_SET_SHADOW_STACK_STATUS. Any future changes to the > + status of the specified GCS mode bits will be rejected. > + > +* PR_LOCK_SHADOW_STACK_STATUS allows any bit to be locked, this allows locked; this allows > + userspace to prevent changes to any future features. > + > +* There is no support for a process to remove a lock that has been set for > + it. > + > +* PR_SET_SHADOW_STACK_STATUS and PR_LOCK_SHADOW_STACK_STATUS affect only the > + thread that called them, any other running threads will be unaffected. them; any other > + > +* New threads inherit the GCS configuration of the thread that created them. > + > +* GCS is disabled on exec(). > + > +* The current GCS configuration for a thread may be read with the > + PR_GET_SHADOW_STACK_STATUS prctl(), this returns the same flags that prctl(). This > + are passed to PR_SET_SHADOW_STACK_STATUS. > + > +* If GCS is disabled for a thread after having previously been enabled then > + the stack will remain allocated for the lifetime of the thread. At present > + any attempt to reenable GCS for the thread will be rejected, this may be rejected; this > + revisited in future. > + > +* It should be noted that since enabling GCS will result in GCS becoming > + active immediately it is not normally possible to return from the function > + that invoked the prctl() that enabled GCS. It is expected that the normal > + usage will be that GCS is enabled very early in execution of a program. > + > + > + > +3. Allocation of Guarded Control Stacks > +---------------------------------------- > + > +* When GCS is enabled for a thread a new Guarded Control Stack will be > + allocated for it of size RLIMIT_STACK or 4 gigabytes, whichever is > + smaller. > + > +* When a new thread is created by a thread which has GCS enabled then a > + new Guarded Control Stack will be allocated for the new thread with > + half the size of the standard stack. > + > +* When a stack is allocated by enabling GCS or during thread creation then > + the top 8 bytes of the stack will be initialised to 0 and GCSPR_EL0 will > + be set to point to the address of this 0 value, this can be used to value. This can be > + detect the top of the stack. > + > +* Additional Guarded Control Stacks can be allocated using the > + map_shadow_stack() system call. > + > +* Stacks allocated using map_shadow_stack() can optionally have an end of > + stack marker and cap placed at the top of the stack. If the flag > + SHADOW_STACK_SET_TOKEN is specified a cap will be placed on the stack, stack; > + if SHADOW_STACK_SET_MARKER is not specified the cap will be the top 8 > + bytes of the stack and if it is specified then the cap will be the next > + 8 bytes. While specifying just SHADOW_STACK_SET_MARKER by itself is > + valid since the marker is all bits 0 it has no observable effect. > + > +* Stacks allocated using map_shadow_stack() must have a size which is a > + multiple of 8 bytes larger than 8 bytes and must be 8 bytes aligned. > + > +* An address can be specified to map_shadow_stack(), if one is provided then map_shadow_stack(). If one > + it must be aligned to a page boundary. > + > +* When a thread is freed the Guarded Control Stack initially allocated for > + that thread will be freed. Note carefully that if the stack has been > + switched this may not be the stack currently in use by the thread. > + > + > +4. Signal handling > +-------------------- > + > +* A new signal frame record gcs_context encodes the current GCS mode and > + pointer for the interrupted context on signal delivery. This will always > + be present on systems that support GCS. > + > +* The record contains a flag field which reports the current GCS configuration > + for the interrupted context as PR_GET_SHADOW_STACK_STATUS would. > + > +* The signal handler is run with the same GCS configuration as the interrupted > + context. > + > +* When GCS is enabled for the interrupted thread a signal handling specific > + GCS cap token will be written to the GCS, this is an architectural GCS cap GCS. This is > + token with bit 63 set and the token type (bits 0..11) all clear. The > + GCSPR_EL0 reported in the signal frame will point to this cap token. > + > +* The signal handler will use the same GCS as the interrupted context. > + > +* When GCS is enabled on signal entry a frame with the address of the signal > + return handler will be pushed onto the GCS, allowing return from the signal > + handler via RET as normal. This will not be reported in the gcs_context in > + the signal frame. > + > + > +5. Signal return > +----------------- > + > +When returning from a signal handler: > + > +* If there is a gcs_context record in the signal frame then the GCS flags > + and GCSPR_EL0 will be restored from that context prior to further > + validation. > + > +* If there is no gcs_context record in the signal frame then the GCS > + configuration will be unchanged. > + > +* If GCS is enabled on return from a signal handler then GCSPR_EL0 must > + point to a valid GCS signal cap record, this will be popped from the record; this will be > + GCS prior to signal return. > + > +* If the GCS configuration is locked when returning from a signal then any > + attempt to change the GCS configuration will be treated as an error. This > + is true even if GCS was not enabled prior to signal entry. > + > +* GCS may be disabled via signal return but any attempt to enable GCS via > + signal return will be rejected. > + > + > +6. ptrace extensions > +--------------------- > + > +* A new regset NT_ARM_GCS is defined for use with PTRACE_GETREGSET and > + PTRACE_SETREGSET. > + > +* Due to the complexity surrounding allocation and deallocation of stacks and > + lack of practical application it is not possible to enable GCS via ptrace. > + GCS may be disabled via the ptrace interface. > + > +* Other GCS modes may be configured via ptrace. > + > +* Configuration via ptrace ignores locking of GCS mode bits. > + > + > +7. ELF coredump extensions > +--------------------------- > + > +* NT_ARM_GCS notes will be added to each coredump for each thread of the > + dumped process. The contents will be equivalent to the data that would > + have been read if a PTRACE_GETREGSET of the corresponding type were > + executed for each thread when the coredump was generated. > + > + > + > +8. /proc extensions > +-------------------- > + > +* Guarded Control Stack pages will include "ss" in their VmFlags in > + /proc/<pid>/smaps.
* Mark Brown: > +4. Signal handling > +-------------------- > + > +* A new signal frame record gcs_context encodes the current GCS mode and > + pointer for the interrupted context on signal delivery. This will always > + be present on systems that support GCS. > + > +* The record contains a flag field which reports the current GCS configuration > + for the interrupted context as PR_GET_SHADOW_STACK_STATUS would. > + > +* The signal handler is run with the same GCS configuration as the interrupted > + context. > + > +* When GCS is enabled for the interrupted thread a signal handling specific > + GCS cap token will be written to the GCS, this is an architectural GCS cap > + token with bit 63 set and the token type (bits 0..11) all clear. The > + GCSPR_EL0 reported in the signal frame will point to this cap token. How does this marker interfere with Top Byte Ignore (TBI; I hope I got the name right)? The specification currently does not say that only addresses pushed to the shadow stack with the top byte cleared, which potentially makes the markup ambiguous. On x86-64, the same issue may exist with LAM. I have not tested yet what happens there. On AArch64 and RISC-V, it may be more natural to use the LSB instead of the LSB for the mark bit because of its instruction alignment. We also have a gap on x86-64 for backtrace generation because the interrupted instruction address does not end up on the shadow stack. This address is potentially quite interesting for backtrace generation. I assume it's currently missing because the kernel does not resume execution using a regular return instruction. It would be really useful if it could be pushed to the shadow stack, or recoverable from the shadow stack in some other way (e.g., the address of the signal context could be pushed instead). That would need some form of marker as well. Thanks, Florian
On Wed, Jul 10, 2024 at 12:36:21PM +0200, Florian Weimer wrote: > * Mark Brown: > > +* When GCS is enabled for the interrupted thread a signal handling specific > > + GCS cap token will be written to the GCS, this is an architectural GCS cap > > + token with bit 63 set and the token type (bits 0..11) all clear. The > > + GCSPR_EL0 reported in the signal frame will point to this cap token. > How does this marker interfere with Top Byte Ignore (TBI; I hope I got > the name right)? The specification currently does not say that only > addresses pushed to the shadow stack with the top byte cleared, which > potentially makes the markup ambiguous. On x86-64, the same issue may Indeed... Given that we use the address on the GCS as part of the token on first pass I think we could get away with just using the address and not setting the top bit, we'd have an invalid cap pointing into a GCS page which shouldn't otherwise be on the GCS. I'll give that some more thought. > exist with LAM. I have not tested yet what happens there. On AArch64 > and RISC-V, it may be more natural to use the LSB instead of the LSB for > the mark bit because of its instruction alignment. The LSB is already taken by the architecture on aarch64, the bottom bits of the value are used for the token type field with no values/bits reserved for software use. > We also have a gap on x86-64 for backtrace generation because the > interrupted instruction address does not end up on the shadow stack. > This address is potentially quite interesting for backtrace generation. > I assume it's currently missing because the kernel does not resume > execution using a regular return instruction. It would be really useful > if it could be pushed to the shadow stack, or recoverable from the > shadow stack in some other way (e.g., the address of the signal context > could be pushed instead). That would need some form of marker as well. Right, we'd have to manually consume any extra address we put on the GCS. I'm not seeing any gagetisation issues with writing an extra value there that isn't a valid stack cap at the minute but I'll need to think it through properly - don't know if anyone else has thoughts here?
+Stephen, who had been asking about RIP integrity awhile back. Thread context for Stephen: https://lore.kernel.org/lkml/Zo7SdDT_cBp6uXgT@finisterre.sirena.org.uk/#t On Wed, 2024-07-10 at 19:27 +0100, Mark Brown wrote: > On Wed, Jul 10, 2024 at 12:36:21PM +0200, Florian Weimer wrote: > > * Mark Brown: > > > > +* When GCS is enabled for the interrupted thread a signal handling > > > specific > > > + GCS cap token will be written to the GCS, this is an architectural GCS > > > cap > > > + token with bit 63 set and the token type (bits 0..11) all clear. The > > > + GCSPR_EL0 reported in the signal frame will point to this cap token. > > > How does this marker interfere with Top Byte Ignore (TBI; I hope I got > > the name right)? The specification currently does not say that only > > addresses pushed to the shadow stack with the top byte cleared, which > > potentially makes the markup ambiguous. On x86-64, the same issue may > > Indeed... Given that we use the address on the GCS as part of the token > on first pass I think we could get away with just using the address and > not setting the top bit, we'd have an invalid cap pointing into a GCS > page which shouldn't otherwise be on the GCS. I'll give that some more > thought. > > > exist with LAM. I have not tested yet what happens there. On AArch64 > > and RISC-V, it may be more natural to use the LSB instead of the LSB for > > the mark bit because of its instruction alignment. > > The LSB is already taken by the architecture on aarch64, the bottom bits > of the value are used for the token type field with no values/bits > reserved for software use. > > > We also have a gap on x86-64 for backtrace generation because the > > interrupted instruction address does not end up on the shadow stack. > > This address is potentially quite interesting for backtrace generation. > > I assume it's currently missing because the kernel does not resume > > execution using a regular return instruction. It would be really useful > > if it could be pushed to the shadow stack, or recoverable from the > > shadow stack in some other way (e.g., the address of the signal context > > could be pushed instead). That would need some form of marker as well. > > Right, we'd have to manually consume any extra address we put on the > GCS. I'm not seeing any gagetisation issues with writing an extra value > there that isn't a valid stack cap at the minute but I'll need to think > it through properly - don't know if anyone else has thoughts here? Shadow stack has one main usage (security) and another less proven, but interesting usage for backtracing. I'm wary of adding things to the shadow stack as they come up in an ad-hoc fashion, especially for the fuzzier usage. Do you have a handle on everything the tracing usage would need? But besides that I've wondered if there could be a security benefit to adding some fields of the sigframe (RIP being the prime one) to the shadow stack, or a cryptographic hash of the sigframe.
Mark Brown <broonie@kernel.org> writes: > +3. Allocation of Guarded Control Stacks > +---------------------------------------- > + > +* When GCS is enabled for a thread a new Guarded Control Stack will be > + allocated for it of size RLIMIT_STACK or 4 gigabytes, whichever is s/4 gigabytes/2 gigabytes/ > + smaller.
On Tue, Jul 16, 2024 at 06:50:12PM +0000, Edgecombe, Rick P wrote: > On Wed, 2024-07-10 at 19:27 +0100, Mark Brown wrote: > > On Wed, Jul 10, 2024 at 12:36:21PM +0200, Florian Weimer wrote: > > > We also have a gap on x86-64 for backtrace generation because the > > > interrupted instruction address does not end up on the shadow stack. > > > This address is potentially quite interesting for backtrace generation. > > > I assume it's currently missing because the kernel does not resume > > > execution using a regular return instruction. It would be really useful > > > if it could be pushed to the shadow stack, or recoverable from the > > > shadow stack in some other way (e.g., the address of the signal context > > > could be pushed instead). That would need some form of marker as well. > > Right, we'd have to manually consume any extra address we put on the > > GCS. I'm not seeing any gagetisation issues with writing an extra value > > there that isn't a valid stack cap at the minute but I'll need to think > > it through properly - don't know if anyone else has thoughts here? > Shadow stack has one main usage (security) and another less proven, but > interesting usage for backtracing. I'm wary of adding things to the shadow stack > as they come up in an ad-hoc fashion, especially for the fuzzier usage. Do you > have a handle on everything the tracing usage would need? Yeah, the current instruction pointer seems fairly straightforward to idiomatically fit in there but going beyond that gets tricker. > But besides that I've wondered if there could be a security benefit to adding > some fields of the sigframe (RIP being the prime one) to the shadow stack, or a > cryptographic hash of the sigframe. One trick with trying to actually validate anything extra we put in there from the sigframe would be that one of the things a signal handler can do is modify the signal context - for the specific case of RIP that'd be an issue for rseq for example.
diff --git a/Documentation/arch/arm64/gcs.rst b/Documentation/arch/arm64/gcs.rst new file mode 100644 index 000000000000..c45c0326836a --- /dev/null +++ b/Documentation/arch/arm64/gcs.rst @@ -0,0 +1,233 @@ +=============================================== +Guarded Control Stack support for AArch64 Linux +=============================================== + +This document outlines briefly the interface provided to userspace by Linux in +order to support use of the ARM Guarded Control Stack (GCS) feature. + +This is an outline of the most important features and issues only and not +intended to be exhaustive. + + + +1. General +----------- + +* GCS is an architecture feature intended to provide greater protection + against return oriented programming (ROP) attacks and to simplify the + implementation of features that need to collect stack traces such as + profiling. + +* When GCS is enabled a separate guarded control stack is maintained by the + PE which is writeable only through specific GCS operations. This + stores the call stack only, when a procedure call instruction is + performed the current PC is pushed onto the GCS and on RET the + address in the LR is verified against that on the top of the GCS. + +* When active current GCS pointer is stored in the system register + GCSPR_EL0. This is readable by userspace but can only be updated + via specific GCS instructions. + +* The architecture provides instructions for switching between guarded + control stacks with checks to ensure that the new stack is a valid + target for switching. + +* The functionality of GCS is similar to that provided by the x86 Shadow + Stack feature, due to sharing of userspace interfaces the ABI refers to + shadow stacks rather than GCS. + +* Support for GCS is reported to userspace via HWCAP2_GCS in the aux vector + AT_HWCAP2 entry. + +* GCS is enabled per thread. While there is support for disabling GCS + at runtime this should be done with great care. + +* GCS memory access faults are reported as normal memory access faults. + +* GCS specific errors (those reported with EC 0x2d) will be reported as + SIGSEGV with a si_code of SEGV_CPERR (control protection error). + +* GCS is supported only for AArch64. + +* On systems where GCS is supported GCSPR_EL0 is always readable by EL0 + regardless of the GCS configuration for the thread. + +* The architecture supports enabling GCS without verifying that return values + in LR match those in the GCS, the LR will be ignored. This is not supported + by Linux. + +* EL0 GCS entries with bit 63 set are reserved for use, one such use is defined + below for signals and should be ignored when parsing the stack if not + understood. + + +2. Enabling and disabling Guarded Control Stacks +------------------------------------------------- + +* GCS is enabled and disabled for a thread via the PR_SET_SHADOW_STACK_STATUS + prctl(), this takes a single flags argument specifying which GCS features + should be used. + +* When set PR_SHADOW_STACK_ENABLE flag allocates a Guarded Control Stack + and enables GCS for the thread, enabling the functionality controlled by + GCSCRE0_EL1.{nTR, RVCHKEN, PCRSEL}. + +* When set the PR_SHADOW_STACK_PUSH flag enables the functionality controlled + by GCSCRE0_EL1.PUSHMEn, allowing explicit GCS pushes. + +* When set the PR_SHADOW_STACK_WRITE flag enables the functionality controlled + by GCSCRE0_EL1.STREn, allowing explicit stores to the Guarded Control Stack. + +* Any unknown flags will cause PR_SET_SHADOW_STACK_STATUS to return -EINVAL. + +* PR_LOCK_SHADOW_STACK_STATUS is passed a bitmask of features with the same + values as used for PR_SET_SHADOW_STACK_STATUS. Any future changes to the + status of the specified GCS mode bits will be rejected. + +* PR_LOCK_SHADOW_STACK_STATUS allows any bit to be locked, this allows + userspace to prevent changes to any future features. + +* There is no support for a process to remove a lock that has been set for + it. + +* PR_SET_SHADOW_STACK_STATUS and PR_LOCK_SHADOW_STACK_STATUS affect only the + thread that called them, any other running threads will be unaffected. + +* New threads inherit the GCS configuration of the thread that created them. + +* GCS is disabled on exec(). + +* The current GCS configuration for a thread may be read with the + PR_GET_SHADOW_STACK_STATUS prctl(), this returns the same flags that + are passed to PR_SET_SHADOW_STACK_STATUS. + +* If GCS is disabled for a thread after having previously been enabled then + the stack will remain allocated for the lifetime of the thread. At present + any attempt to reenable GCS for the thread will be rejected, this may be + revisited in future. + +* It should be noted that since enabling GCS will result in GCS becoming + active immediately it is not normally possible to return from the function + that invoked the prctl() that enabled GCS. It is expected that the normal + usage will be that GCS is enabled very early in execution of a program. + + + +3. Allocation of Guarded Control Stacks +---------------------------------------- + +* When GCS is enabled for a thread a new Guarded Control Stack will be + allocated for it of size RLIMIT_STACK or 4 gigabytes, whichever is + smaller. + +* When a new thread is created by a thread which has GCS enabled then a + new Guarded Control Stack will be allocated for the new thread with + half the size of the standard stack. + +* When a stack is allocated by enabling GCS or during thread creation then + the top 8 bytes of the stack will be initialised to 0 and GCSPR_EL0 will + be set to point to the address of this 0 value, this can be used to + detect the top of the stack. + +* Additional Guarded Control Stacks can be allocated using the + map_shadow_stack() system call. + +* Stacks allocated using map_shadow_stack() can optionally have an end of + stack marker and cap placed at the top of the stack. If the flag + SHADOW_STACK_SET_TOKEN is specified a cap will be placed on the stack, + if SHADOW_STACK_SET_MARKER is not specified the cap will be the top 8 + bytes of the stack and if it is specified then the cap will be the next + 8 bytes. While specifying just SHADOW_STACK_SET_MARKER by itself is + valid since the marker is all bits 0 it has no observable effect. + +* Stacks allocated using map_shadow_stack() must have a size which is a + multiple of 8 bytes larger than 8 bytes and must be 8 bytes aligned. + +* An address can be specified to map_shadow_stack(), if one is provided then + it must be aligned to a page boundary. + +* When a thread is freed the Guarded Control Stack initially allocated for + that thread will be freed. Note carefully that if the stack has been + switched this may not be the stack currently in use by the thread. + + +4. Signal handling +-------------------- + +* A new signal frame record gcs_context encodes the current GCS mode and + pointer for the interrupted context on signal delivery. This will always + be present on systems that support GCS. + +* The record contains a flag field which reports the current GCS configuration + for the interrupted context as PR_GET_SHADOW_STACK_STATUS would. + +* The signal handler is run with the same GCS configuration as the interrupted + context. + +* When GCS is enabled for the interrupted thread a signal handling specific + GCS cap token will be written to the GCS, this is an architectural GCS cap + token with bit 63 set and the token type (bits 0..11) all clear. The + GCSPR_EL0 reported in the signal frame will point to this cap token. + +* The signal handler will use the same GCS as the interrupted context. + +* When GCS is enabled on signal entry a frame with the address of the signal + return handler will be pushed onto the GCS, allowing return from the signal + handler via RET as normal. This will not be reported in the gcs_context in + the signal frame. + + +5. Signal return +----------------- + +When returning from a signal handler: + +* If there is a gcs_context record in the signal frame then the GCS flags + and GCSPR_EL0 will be restored from that context prior to further + validation. + +* If there is no gcs_context record in the signal frame then the GCS + configuration will be unchanged. + +* If GCS is enabled on return from a signal handler then GCSPR_EL0 must + point to a valid GCS signal cap record, this will be popped from the + GCS prior to signal return. + +* If the GCS configuration is locked when returning from a signal then any + attempt to change the GCS configuration will be treated as an error. This + is true even if GCS was not enabled prior to signal entry. + +* GCS may be disabled via signal return but any attempt to enable GCS via + signal return will be rejected. + + +6. ptrace extensions +--------------------- + +* A new regset NT_ARM_GCS is defined for use with PTRACE_GETREGSET and + PTRACE_SETREGSET. + +* Due to the complexity surrounding allocation and deallocation of stacks and + lack of practical application it is not possible to enable GCS via ptrace. + GCS may be disabled via the ptrace interface. + +* Other GCS modes may be configured via ptrace. + +* Configuration via ptrace ignores locking of GCS mode bits. + + +7. ELF coredump extensions +--------------------------- + +* NT_ARM_GCS notes will be added to each coredump for each thread of the + dumped process. The contents will be equivalent to the data that would + have been read if a PTRACE_GETREGSET of the corresponding type were + executed for each thread when the coredump was generated. + + + +8. /proc extensions +-------------------- + +* Guarded Control Stack pages will include "ss" in their VmFlags in + /proc/<pid>/smaps. diff --git a/Documentation/arch/arm64/index.rst b/Documentation/arch/arm64/index.rst index d08e924204bf..dcf3ee3eb8c0 100644 --- a/Documentation/arch/arm64/index.rst +++ b/Documentation/arch/arm64/index.rst @@ -14,6 +14,7 @@ ARM64 Architecture booting cpu-feature-registers elf_hwcaps + gcs hugetlbpage kdump legacy_instructions