<feed xmlns='http://www.w3.org/2005/Atom'>
<title>linux.git/arch/arm/kernel/entry-armv.S, branch v5.16</title>
<subtitle>Linux kernel source tree</subtitle>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/'/>
<entry>
<title>ARM: 9169/1: entry: fix Thumb2 bug in iWMMXt exception handling</title>
<updated>2021-12-17T12:02:17+00:00</updated>
<author>
<name>Ard Biesheuvel</name>
<email>ardb@kernel.org</email>
</author>
<published>2021-12-15T08:31:36+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=8536a5ef886005bc443c2da9b842d69fd3d7647f'/>
<id>8536a5ef886005bc443c2da9b842d69fd3d7647f</id>
<content type='text'>
The Thumb2 version of the FP exception handling entry code treats the
register holding the CP number (R8) differently, resulting in the iWMMXT
CP number check to be incorrect.

Fix this by unifying the ARM and Thumb2 code paths, and switch the
order of the additions of the TI_USED_CP offset and the shifted CP
index.

Cc: &lt;stable@vger.kernel.org&gt;
Fixes: b86040a59feb ("Thumb-2: Implementation of the unified start-up and exceptions code")
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Signed-off-by: Russell King (Oracle) &lt;rmk+kernel@armlinux.org.uk&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
The Thumb2 version of the FP exception handling entry code treats the
register holding the CP number (R8) differently, resulting in the iWMMXT
CP number check to be incorrect.

Fix this by unifying the ARM and Thumb2 code paths, and switch the
order of the additions of the TI_USED_CP offset and the shifted CP
index.

Cc: &lt;stable@vger.kernel.org&gt;
Fixes: b86040a59feb ("Thumb-2: Implementation of the unified start-up and exceptions code")
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Signed-off-by: Russell King (Oracle) &lt;rmk+kernel@armlinux.org.uk&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>Merge tag 'for-linus' of git://git.armlinux.org.uk/~rmk/linux-arm</title>
<updated>2021-11-02T18:33:15+00:00</updated>
<author>
<name>Linus Torvalds</name>
<email>torvalds@linux-foundation.org</email>
</author>
<published>2021-11-02T18:33:15+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=ab2e7f4b46bf8fccf088ec496b3bb26b43e91340'/>
<id>ab2e7f4b46bf8fccf088ec496b3bb26b43e91340</id>
<content type='text'>
Pull ARM updates from Russell King:

 - Rejig task/thread info to place thread info in task struct

 - Amba bus cleanups (removing unused functions)

 - Handle Amba device probe without IRQ domains

 - Parse linux,usable-memory-range in decompressor

 - Mark OCRAM as read-only after initialisation

 - Refactor page fault handling

 - Fix PXN handling with LPAE kernels

 - Warning and build fixes from Arnd

* tag 'for-linus' of git://git.armlinux.org.uk/~rmk/linux-arm: (32 commits)
  ARM: 9151/1: Thumb2: avoid __builtin_thread_pointer() on Clang
  ARM: 9150/1: Fix PID_IN_CONTEXTIDR regression when THREAD_INFO_IN_TASK=y
  ARM: 9147/1: add printf format attribute to early_print()
  ARM: 9146/1: RiscPC needs older gcc version
  ARM: 9145/1: patch: fix BE32 compilation
  ARM: 9144/1: forbid ftrace with clang and thumb2_kernel
  ARM: 9143/1: add CONFIG_PHYS_OFFSET default values
  ARM: 9142/1: kasan: work around LPAE build warning
  ARM: 9140/1: allow compile-testing without machine record
  ARM: 9137/1: disallow CONFIG_THUMB with ARMv4
  ARM: 9136/1: ARMv7-M uses BE-8, not BE-32
  ARM: 9135/1: kprobes: address gcc -Wempty-body warning
  ARM: 9101/1: sa1100/assabet: convert LEDs to gpiod APIs
  ARM: 9131/1: mm: Fix PXN process with LPAE feature
  ARM: 9130/1: mm: Provide die_kernel_fault() helper
  ARM: 9126/1: mm: Kill page table base print in show_pte()
  ARM: 9127/1: mm: Cleanup access_error()
  ARM: 9129/1: mm: Kill task_struct argument for __do_page_fault()
  ARM: 9128/1: mm: Refactor the __do_page_fault()
  ARM: imx6: mark OCRAM mapping read-only
  ...
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
Pull ARM updates from Russell King:

 - Rejig task/thread info to place thread info in task struct

 - Amba bus cleanups (removing unused functions)

 - Handle Amba device probe without IRQ domains

 - Parse linux,usable-memory-range in decompressor

 - Mark OCRAM as read-only after initialisation

 - Refactor page fault handling

 - Fix PXN handling with LPAE kernels

 - Warning and build fixes from Arnd

* tag 'for-linus' of git://git.armlinux.org.uk/~rmk/linux-arm: (32 commits)
  ARM: 9151/1: Thumb2: avoid __builtin_thread_pointer() on Clang
  ARM: 9150/1: Fix PID_IN_CONTEXTIDR regression when THREAD_INFO_IN_TASK=y
  ARM: 9147/1: add printf format attribute to early_print()
  ARM: 9146/1: RiscPC needs older gcc version
  ARM: 9145/1: patch: fix BE32 compilation
  ARM: 9144/1: forbid ftrace with clang and thumb2_kernel
  ARM: 9143/1: add CONFIG_PHYS_OFFSET default values
  ARM: 9142/1: kasan: work around LPAE build warning
  ARM: 9140/1: allow compile-testing without machine record
  ARM: 9137/1: disallow CONFIG_THUMB with ARMv4
  ARM: 9136/1: ARMv7-M uses BE-8, not BE-32
  ARM: 9135/1: kprobes: address gcc -Wempty-body warning
  ARM: 9101/1: sa1100/assabet: convert LEDs to gpiod APIs
  ARM: 9131/1: mm: Fix PXN process with LPAE feature
  ARM: 9130/1: mm: Provide die_kernel_fault() helper
  ARM: 9126/1: mm: Kill page table base print in show_pte()
  ARM: 9127/1: mm: Cleanup access_error()
  ARM: 9129/1: mm: Kill task_struct argument for __do_page_fault()
  ARM: 9128/1: mm: Refactor the __do_page_fault()
  ARM: imx6: mark OCRAM mapping read-only
  ...
</pre>
</div>
</content>
</entry>
<entry>
<title>irq: arm: perform irqentry in entry code</title>
<updated>2021-10-25T09:05:31+00:00</updated>
<author>
<name>Mark Rutland</name>
<email>mark.rutland@arm.com</email>
</author>
<published>2021-10-19T17:17:17+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=a7b0872e964cf306fe26d9d49585a90486e32fdf'/>
<id>a7b0872e964cf306fe26d9d49585a90486e32fdf</id>
<content type='text'>
In preparation for removing HANDLE_DOMAIN_IRQ_IRQENTRY, have arch/arm
perform all the irqentry accounting in its entry code.

For configurations with CONFIG_GENERIC_IRQ_MULTI_HANDLER, we can use
generic_handle_arch_irq(). Other than asm_do_IRQ(), all C calls to
handle_IRQ() are from irqchip handlers which will be called from
generic_handle_arch_irq(), so to avoid double accounting IRQ entry, the
entry logic is moved from handle_IRQ() into asm_do_IRQ().

For ARMv7M the entry assembly is tightly coupled with the NVIC irqchip, and
while the entry code should logically live under arch/arm/, moving the
entry logic there makes things more convoluted. So for now, place the
entry logic in the NVIC irqchip, but separated into a separate
function to make the split of responsibility clear.

For all other configurations without CONFIG_GENERIC_IRQ_MULTI_HANDLER,
IRQ entry is already handled in arch code, and requires no changes.

There should be no functional change as a result of this patch.

Signed-off-by: Mark Rutland &lt;mark.rutland@arm.com&gt;
Reviewed-by: Marc Zyngier &lt;maz@kernel.org&gt;
Tested-by: Vladimir Murzin &lt;vladimir.murzin@arm.com&gt; # ARMv7M
Cc: Russell King &lt;linux@armlinux.org.uk&gt;
Cc: Thomas Gleixner &lt;tglx@linutronix.de&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
In preparation for removing HANDLE_DOMAIN_IRQ_IRQENTRY, have arch/arm
perform all the irqentry accounting in its entry code.

For configurations with CONFIG_GENERIC_IRQ_MULTI_HANDLER, we can use
generic_handle_arch_irq(). Other than asm_do_IRQ(), all C calls to
handle_IRQ() are from irqchip handlers which will be called from
generic_handle_arch_irq(), so to avoid double accounting IRQ entry, the
entry logic is moved from handle_IRQ() into asm_do_IRQ().

For ARMv7M the entry assembly is tightly coupled with the NVIC irqchip, and
while the entry code should logically live under arch/arm/, moving the
entry logic there makes things more convoluted. So for now, place the
entry logic in the NVIC irqchip, but separated into a separate
function to make the split of responsibility clear.

For all other configurations without CONFIG_GENERIC_IRQ_MULTI_HANDLER,
IRQ entry is already handled in arch code, and requires no changes.

There should be no functional change as a result of this patch.

Signed-off-by: Mark Rutland &lt;mark.rutland@arm.com&gt;
Reviewed-by: Marc Zyngier &lt;maz@kernel.org&gt;
Tested-by: Vladimir Murzin &lt;vladimir.murzin@arm.com&gt; # ARMv7M
Cc: Russell King &lt;linux@armlinux.org.uk&gt;
Cc: Thomas Gleixner &lt;tglx@linutronix.de&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: smp: Enable THREAD_INFO_IN_TASK</title>
<updated>2021-09-27T14:54:02+00:00</updated>
<author>
<name>Ard Biesheuvel</name>
<email>ardb@kernel.org</email>
</author>
<published>2021-09-18T08:44:38+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=18ed1c01a7dd3d7c780b06a49124da237a4c1790'/>
<id>18ed1c01a7dd3d7c780b06a49124da237a4c1790</id>
<content type='text'>
Now that we no longer rely on thread_info living at the base of the task
stack to be able to access the 'current' pointer, we can wire up the
generic support for moving thread_info into the task struct itself.

Note that this requires us to update the cpu field in thread_info
explicitly, now that the core code no longer does so. Ideally, we would
switch the percpu code to access the cpu field in task_struct instead,
but this unleashes #include circular dependency hell.

Co-developed-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Tested-by: Amit Daniel Kachhap &lt;amit.kachhap@arm.com&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
Now that we no longer rely on thread_info living at the base of the task
stack to be able to access the 'current' pointer, we can wire up the
generic support for moving thread_info into the task struct itself.

Note that this requires us to update the cpu field in thread_info
explicitly, now that the core code no longer does so. Ideally, we would
switch the percpu code to access the cpu field in task_struct instead,
but this unleashes #include circular dependency hell.

Co-developed-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Tested-by: Amit Daniel Kachhap &lt;amit.kachhap@arm.com&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: smp: Store current pointer in TPIDRURO register if available</title>
<updated>2021-09-27T14:54:02+00:00</updated>
<author>
<name>Ard Biesheuvel</name>
<email>ardb@kernel.org</email>
</author>
<published>2021-09-18T08:44:37+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=50596b7559bf226bb35ad55855ee979453ec06a1'/>
<id>50596b7559bf226bb35ad55855ee979453ec06a1</id>
<content type='text'>
Now that the user space TLS register is assigned on every return to user
space, we can use it to keep the 'current' pointer while running in the
kernel. This removes the need to access it via thread_info, which is
located at the base of the stack, but will be moved out of there in a
subsequent patch.

Use the __builtin_thread_pointer() helper when available - this will
help GCC understand that reloading the value within the same function is
not necessary, even when using the per-task stack protector (which also
generates accesses via the TLS register). For example, the generated
code below loads TPIDRURO only once, and uses it to access both the
stack canary and the preempt_count fields.

&lt;do_one_initcall&gt;:
       e92d 41f0       stmdb   sp!, {r4, r5, r6, r7, r8, lr}
       ee1d 4f70       mrc     15, 0, r4, cr13, cr0, {3}
       4606            mov     r6, r0
       b094            sub     sp, #80 ; 0x50
       f8d4 34e8       ldr.w   r3, [r4, #1256] ; 0x4e8  &lt;- stack canary
       9313            str     r3, [sp, #76]   ; 0x4c
       f8d4 8004       ldr.w   r8, [r4, #4]             &lt;- preempt count

Co-developed-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Tested-by: Amit Daniel Kachhap &lt;amit.kachhap@arm.com&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
Now that the user space TLS register is assigned on every return to user
space, we can use it to keep the 'current' pointer while running in the
kernel. This removes the need to access it via thread_info, which is
located at the base of the stack, but will be moved out of there in a
subsequent patch.

Use the __builtin_thread_pointer() helper when available - this will
help GCC understand that reloading the value within the same function is
not necessary, even when using the per-task stack protector (which also
generates accesses via the TLS register). For example, the generated
code below loads TPIDRURO only once, and uses it to access both the
stack canary and the preempt_count fields.

&lt;do_one_initcall&gt;:
       e92d 41f0       stmdb   sp!, {r4, r5, r6, r7, r8, lr}
       ee1d 4f70       mrc     15, 0, r4, cr13, cr0, {3}
       4606            mov     r6, r0
       b094            sub     sp, #80 ; 0x50
       f8d4 34e8       ldr.w   r3, [r4, #1256] ; 0x4e8  &lt;- stack canary
       9313            str     r3, [sp, #76]   ; 0x4c
       f8d4 8004       ldr.w   r8, [r4, #4]             &lt;- preempt count

Co-developed-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Keith Packard &lt;keithpac@amazon.com&gt;
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Tested-by: Amit Daniel Kachhap &lt;amit.kachhap@arm.com&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: ep93xx: remove MaverickCrunch support</title>
<updated>2021-08-04T11:30:04+00:00</updated>
<author>
<name>Arnd Bergmann</name>
<email>arnd@arndb.de</email>
</author>
<published>2021-02-27T12:40:09+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=12c3dca25d2fa17a101de0d80bf3f238b1cecbae'/>
<id>12c3dca25d2fa17a101de0d80bf3f238b1cecbae</id>
<content type='text'>
The MaverickCrunch support for ep93xx never made it into glibc and
was removed from gcc in its 4.8 release in 2012. It is now one of
the last parts of arch/arm/ that fails to build with the clang
integrated assembler, which is unlikely to ever want to support it.

The two alternatives are to force the use of binutils/gas when
building the crunch support, or to remove it entirely.

According to Hartley Sweeten:

 "Martin Guy did a lot of work trying to get the maverick crunch working
  but I was never able to successfully use it for anything. It "kind"
  of works but depending on the EP93xx silicon revision there are still
  a number of hardware bugs that either give imprecise or garbage results.

  I have no problem with removing the kernel support for the maverick
  crunch."

Unless someone else comes up with a good reason to keep it around,
remove it now. This touches mostly the ep93xx platform, but removes
a bit of code from ARM common ptrace and signal frame handling as well.

If there are remaining users of MaverickCrunch, they can use LTS
kernels for at least another five years before kernel support ends.

Link: https://lore.kernel.org/linux-arm-kernel/20210802141245.1146772-1-arnd@kernel.org/
Link: https://lore.kernel.org/linux-arm-kernel/20210226164345.3889993-1-arnd@kernel.org/
Link: https://github.com/ClangBuiltLinux/linux/issues/1272
Link: https://gcc.gnu.org/legacy-ml/gcc/2008-03/msg01063.html
Cc: "Martin Guy" &lt;martinwguy@martinwguy@gmail.com&gt;
Signed-off-by: Arnd Bergmann &lt;arnd@arndb.de&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
The MaverickCrunch support for ep93xx never made it into glibc and
was removed from gcc in its 4.8 release in 2012. It is now one of
the last parts of arch/arm/ that fails to build with the clang
integrated assembler, which is unlikely to ever want to support it.

The two alternatives are to force the use of binutils/gas when
building the crunch support, or to remove it entirely.

According to Hartley Sweeten:

 "Martin Guy did a lot of work trying to get the maverick crunch working
  but I was never able to successfully use it for anything. It "kind"
  of works but depending on the EP93xx silicon revision there are still
  a number of hardware bugs that either give imprecise or garbage results.

  I have no problem with removing the kernel support for the maverick
  crunch."

Unless someone else comes up with a good reason to keep it around,
remove it now. This touches mostly the ep93xx platform, but removes
a bit of code from ARM common ptrace and signal frame handling as well.

If there are remaining users of MaverickCrunch, they can use LTS
kernels for at least another five years before kernel support ends.

Link: https://lore.kernel.org/linux-arm-kernel/20210802141245.1146772-1-arnd@kernel.org/
Link: https://lore.kernel.org/linux-arm-kernel/20210226164345.3889993-1-arnd@kernel.org/
Link: https://github.com/ClangBuiltLinux/linux/issues/1272
Link: https://gcc.gnu.org/legacy-ml/gcc/2008-03/msg01063.html
Cc: "Martin Guy" &lt;martinwguy@martinwguy@gmail.com&gt;
Signed-off-by: Arnd Bergmann &lt;arnd@arndb.de&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: 9030/1: entry: omit FP emulation for UND exceptions taken in kernel mode</title>
<updated>2020-12-08T10:15:00+00:00</updated>
<author>
<name>Ard Biesheuvel</name>
<email>ardb@kernel.org</email>
</author>
<published>2020-11-19T17:09:16+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=f77ac2e378be9dd61eb88728f0840642f045d9d1'/>
<id>f77ac2e378be9dd61eb88728f0840642f045d9d1</id>
<content type='text'>
There are a couple of problems with the exception entry code that deals
with FP exceptions (which are reported as UND exceptions) when building
the kernel in Thumb2 mode:
- the conditional branch to vfp_kmode_exception in vfp_support_entry()
  may be out of range for its target, depending on how the linker decides
  to arrange the sections;
- when the UND exception is taken in kernel mode, the emulation handling
  logic is entered via the 'call_fpe' label, which means we end up using
  the wrong value/mask pairs to match and detect the NEON opcodes.

Since UND exceptions in kernel mode are unlikely to occur on a hot path
(as opposed to the user mode version which is invoked for VFP support
code and lazy restore), we can use the existing undef hook machinery for
any kernel mode instruction emulation that is needed, including calling
the existing vfp_kmode_exception() routine for unexpected cases. So drop
the call to call_fpe, and instead, install an undef hook that will get
called for NEON and VFP instructions that trigger an UND exception in
kernel mode.

While at it, make sure that the PC correction is accurate for the
execution mode where the exception was taken, by checking the PSR
Thumb bit.

Cc: Dmitry Osipenko &lt;digetx@gmail.com&gt;
Cc: Kees Cook &lt;keescook@chromium.org&gt;
Fixes: eff8728fe698 ("vmlinux.lds.h: Add PGO and AutoFDO input sections")
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Reviewed-by: Nick Desaulniers &lt;ndesaulniers@google.com&gt;
Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
There are a couple of problems with the exception entry code that deals
with FP exceptions (which are reported as UND exceptions) when building
the kernel in Thumb2 mode:
- the conditional branch to vfp_kmode_exception in vfp_support_entry()
  may be out of range for its target, depending on how the linker decides
  to arrange the sections;
- when the UND exception is taken in kernel mode, the emulation handling
  logic is entered via the 'call_fpe' label, which means we end up using
  the wrong value/mask pairs to match and detect the NEON opcodes.

Since UND exceptions in kernel mode are unlikely to occur on a hot path
(as opposed to the user mode version which is invoked for VFP support
code and lazy restore), we can use the existing undef hook machinery for
any kernel mode instruction emulation that is needed, including calling
the existing vfp_kmode_exception() routine for unexpected cases. So drop
the call to call_fpe, and instead, install an undef hook that will get
called for NEON and VFP instructions that trigger an UND exception in
kernel mode.

While at it, make sure that the PC correction is accurate for the
execution mode where the exception was taken, by checking the PSR
Thumb bit.

Cc: Dmitry Osipenko &lt;digetx@gmail.com&gt;
Cc: Kees Cook &lt;keescook@chromium.org&gt;
Fixes: eff8728fe698 ("vmlinux.lds.h: Add PGO and AutoFDO input sections")
Signed-off-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Reviewed-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Reviewed-by: Nick Desaulniers &lt;ndesaulniers@google.com&gt;
Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: 9015/2: Define the virtual space of KASan's shadow region</title>
<updated>2020-10-27T12:11:08+00:00</updated>
<author>
<name>Linus Walleij</name>
<email>linus.walleij@linaro.org</email>
</author>
<published>2020-10-25T22:53:46+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=c12366ba441da2f6f2b915410aca2b5b39c16514'/>
<id>c12366ba441da2f6f2b915410aca2b5b39c16514</id>
<content type='text'>
Define KASAN_SHADOW_OFFSET,KASAN_SHADOW_START and KASAN_SHADOW_END for
the Arm kernel address sanitizer. We are "stealing" lowmem (the 4GB
addressable by a 32bit architecture) out of the virtual address
space to use as shadow memory for KASan as follows:

 +----+ 0xffffffff
 |    |
 |    | |-&gt; Static kernel image (vmlinux) BSS and page table
 |    |/
 +----+ PAGE_OFFSET
 |    |
 |    | |-&gt;  Loadable kernel modules virtual address space area
 |    |/
 +----+ MODULES_VADDR = KASAN_SHADOW_END
 |    |
 |    | |-&gt; The shadow area of kernel virtual address.
 |    |/
 +----+-&gt;  TASK_SIZE (start of kernel space) = KASAN_SHADOW_START the
 |    |   shadow address of MODULES_VADDR
 |    | |
 |    | |
 |    | |-&gt; The user space area in lowmem. The kernel address
 |    | |   sanitizer do not use this space, nor does it map it.
 |    | |
 |    | |
 |    | |
 |    | |
 |    |/
 ------ 0

0 .. TASK_SIZE is the memory that can be used by shared
userspace/kernelspace. It us used for userspace processes and for
passing parameters and memory buffers in system calls etc. We do not
need to shadow this area.

KASAN_SHADOW_START:
 This value begins with the MODULE_VADDR's shadow address. It is the
 start of kernel virtual space. Since we have modules to load, we need
 to cover also that area with shadow memory so we can find memory
 bugs in modules.

KASAN_SHADOW_END
 This value is the 0x100000000's shadow address: the mapping that would
 be after the end of the kernel memory at 0xffffffff. It is the end of
 kernel address sanitizer shadow area. It is also the start of the
 module area.

KASAN_SHADOW_OFFSET:
 This value is used to map an address to the corresponding shadow
 address by the following formula:

   shadow_addr = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET;

 As you would expect, &gt;&gt; 3 is equal to dividing by 8, meaning each
 byte in the shadow memory covers 8 bytes of kernel memory, so one
 bit shadow memory per byte of kernel memory is used.

 The KASAN_SHADOW_OFFSET is provided in a Kconfig option depending
 on the VMSPLIT layout of the system: the kernel and userspace can
 split up lowmem in different ways according to needs, so we calculate
 the shadow offset depending on this.

When kasan is enabled, the definition of TASK_SIZE is not an 8-bit
rotated constant, so we need to modify the TASK_SIZE access code in the
*.s file.

The kernel and modules may use different amounts of memory,
according to the VMSPLIT configuration, which in turn
determines the PAGE_OFFSET.

We use the following KASAN_SHADOW_OFFSETs depending on how the
virtual memory is split up:

- 0x1f000000 if we have 1G userspace / 3G kernelspace split:
  - The kernel address space is 3G (0xc0000000)
  - PAGE_OFFSET is then set to 0x40000000 so the kernel static
    image (vmlinux) uses addresses 0x40000000 .. 0xffffffff
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0x3f000000
    so the modules use addresses 0x3f000000 .. 0x3fffffff
  - So the addresses 0x3f000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0xc1000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x18200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0x26e00000, to
    KASAN_SHADOW_END at 0x3effffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0x3f000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0x26e00000 = (0x3f000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0x26e00000 - (0x3f000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0x26e00000 - 0x07e00000
    KASAN_SHADOW_OFFSET = 0x1f000000

- 0x5f000000 if we have 2G userspace / 2G kernelspace split:
  - The kernel space is 2G (0x80000000)
  - PAGE_OFFSET is set to 0x80000000 so the kernel static
    image uses 0x80000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0x7f000000
    so the modules use addresses 0x7f000000 .. 0x7fffffff
  - So the addresses 0x7f000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x81000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x10200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0x6ee00000, to
    KASAN_SHADOW_END at 0x7effffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0x7f000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0x6ee00000 = (0x7f000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0x6ee00000 - (0x7f000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0x6ee00000 - 0x0fe00000
    KASAN_SHADOW_OFFSET = 0x5f000000

- 0x9f000000 if we have 3G userspace / 1G kernelspace split,
  and this is the default split for ARM:
  - The kernel address space is 1GB (0x40000000)
  - PAGE_OFFSET is set to 0xc0000000 so the kernel static
    image uses 0xc0000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0xbf000000
    so the modules use addresses 0xbf000000 .. 0xbfffffff
  - So the addresses 0xbf000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x41000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x08200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0xb6e00000, to
    KASAN_SHADOW_END at 0xbfffffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0xbf000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0xb6e00000 = (0xbf000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0xb6e00000 - (0xbf000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0xb6e00000 - 0x17e00000
    KASAN_SHADOW_OFFSET = 0x9f000000

- 0x8f000000 if we have 3G userspace / 1G kernelspace with
  full 1 GB low memory (VMSPLIT_3G_OPT):
  - The kernel address space is 1GB (0x40000000)
  - PAGE_OFFSET is set to 0xb0000000 so the kernel static
    image uses 0xb0000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0xaf000000
    so the modules use addresses 0xaf000000 .. 0xaffffff
  - So the addresses 0xaf000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x51000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x0a200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0xa4e00000, to
    KASAN_SHADOW_END at 0xaeffffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0xaf000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0xa4e00000 = (0xaf000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0xa4e00000 - (0xaf000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0xa4e00000 - 0x15e00000
    KASAN_SHADOW_OFFSET = 0x8f000000

- The default value of 0xffffffff for KASAN_SHADOW_OFFSET
  is an error value. We should always match one of the
  above shadow offsets.

When we do this, TASK_SIZE will sometimes get a bit odd values
that will not fit into immediate mov assembly instructions.
To account for this, we need to rewrite some assembly using
TASK_SIZE like this:

-       mov     r1, #TASK_SIZE
+       ldr     r1, =TASK_SIZE

or

-       cmp     r4, #TASK_SIZE
+       ldr     r0, =TASK_SIZE
+       cmp     r4, r0

this is done to avoid the immediate #TASK_SIZE that need to
fit into a limited number of bits.

Cc: Andrey Ryabinin &lt;aryabinin@virtuozzo.com&gt;
Cc: Alexander Potapenko &lt;glider@google.com&gt;
Cc: Dmitry Vyukov &lt;dvyukov@google.com&gt;
Cc: kasan-dev@googlegroups.com
Cc: Mike Rapoport &lt;rppt@linux.ibm.com&gt;
Reviewed-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Tested-by: Ard Biesheuvel &lt;ardb@kernel.org&gt; # QEMU/KVM/mach-virt/LPAE/8G
Tested-by: Florian Fainelli &lt;f.fainelli@gmail.com&gt; # Brahma SoCs
Tested-by: Ahmad Fatoum &lt;a.fatoum@pengutronix.de&gt; # i.MX6Q
Reported-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Signed-off-by: Abbott Liu &lt;liuwenliang@huawei.com&gt;
Signed-off-by: Florian Fainelli &lt;f.fainelli@gmail.com&gt;
Signed-off-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
Define KASAN_SHADOW_OFFSET,KASAN_SHADOW_START and KASAN_SHADOW_END for
the Arm kernel address sanitizer. We are "stealing" lowmem (the 4GB
addressable by a 32bit architecture) out of the virtual address
space to use as shadow memory for KASan as follows:

 +----+ 0xffffffff
 |    |
 |    | |-&gt; Static kernel image (vmlinux) BSS and page table
 |    |/
 +----+ PAGE_OFFSET
 |    |
 |    | |-&gt;  Loadable kernel modules virtual address space area
 |    |/
 +----+ MODULES_VADDR = KASAN_SHADOW_END
 |    |
 |    | |-&gt; The shadow area of kernel virtual address.
 |    |/
 +----+-&gt;  TASK_SIZE (start of kernel space) = KASAN_SHADOW_START the
 |    |   shadow address of MODULES_VADDR
 |    | |
 |    | |
 |    | |-&gt; The user space area in lowmem. The kernel address
 |    | |   sanitizer do not use this space, nor does it map it.
 |    | |
 |    | |
 |    | |
 |    | |
 |    |/
 ------ 0

0 .. TASK_SIZE is the memory that can be used by shared
userspace/kernelspace. It us used for userspace processes and for
passing parameters and memory buffers in system calls etc. We do not
need to shadow this area.

KASAN_SHADOW_START:
 This value begins with the MODULE_VADDR's shadow address. It is the
 start of kernel virtual space. Since we have modules to load, we need
 to cover also that area with shadow memory so we can find memory
 bugs in modules.

KASAN_SHADOW_END
 This value is the 0x100000000's shadow address: the mapping that would
 be after the end of the kernel memory at 0xffffffff. It is the end of
 kernel address sanitizer shadow area. It is also the start of the
 module area.

KASAN_SHADOW_OFFSET:
 This value is used to map an address to the corresponding shadow
 address by the following formula:

   shadow_addr = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET;

 As you would expect, &gt;&gt; 3 is equal to dividing by 8, meaning each
 byte in the shadow memory covers 8 bytes of kernel memory, so one
 bit shadow memory per byte of kernel memory is used.

 The KASAN_SHADOW_OFFSET is provided in a Kconfig option depending
 on the VMSPLIT layout of the system: the kernel and userspace can
 split up lowmem in different ways according to needs, so we calculate
 the shadow offset depending on this.

When kasan is enabled, the definition of TASK_SIZE is not an 8-bit
rotated constant, so we need to modify the TASK_SIZE access code in the
*.s file.

The kernel and modules may use different amounts of memory,
according to the VMSPLIT configuration, which in turn
determines the PAGE_OFFSET.

We use the following KASAN_SHADOW_OFFSETs depending on how the
virtual memory is split up:

- 0x1f000000 if we have 1G userspace / 3G kernelspace split:
  - The kernel address space is 3G (0xc0000000)
  - PAGE_OFFSET is then set to 0x40000000 so the kernel static
    image (vmlinux) uses addresses 0x40000000 .. 0xffffffff
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0x3f000000
    so the modules use addresses 0x3f000000 .. 0x3fffffff
  - So the addresses 0x3f000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0xc1000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x18200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0x26e00000, to
    KASAN_SHADOW_END at 0x3effffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0x3f000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0x26e00000 = (0x3f000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0x26e00000 - (0x3f000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0x26e00000 - 0x07e00000
    KASAN_SHADOW_OFFSET = 0x1f000000

- 0x5f000000 if we have 2G userspace / 2G kernelspace split:
  - The kernel space is 2G (0x80000000)
  - PAGE_OFFSET is set to 0x80000000 so the kernel static
    image uses 0x80000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0x7f000000
    so the modules use addresses 0x7f000000 .. 0x7fffffff
  - So the addresses 0x7f000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x81000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x10200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0x6ee00000, to
    KASAN_SHADOW_END at 0x7effffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0x7f000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0x6ee00000 = (0x7f000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0x6ee00000 - (0x7f000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0x6ee00000 - 0x0fe00000
    KASAN_SHADOW_OFFSET = 0x5f000000

- 0x9f000000 if we have 3G userspace / 1G kernelspace split,
  and this is the default split for ARM:
  - The kernel address space is 1GB (0x40000000)
  - PAGE_OFFSET is set to 0xc0000000 so the kernel static
    image uses 0xc0000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0xbf000000
    so the modules use addresses 0xbf000000 .. 0xbfffffff
  - So the addresses 0xbf000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x41000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x08200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0xb6e00000, to
    KASAN_SHADOW_END at 0xbfffffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0xbf000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0xb6e00000 = (0xbf000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0xb6e00000 - (0xbf000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0xb6e00000 - 0x17e00000
    KASAN_SHADOW_OFFSET = 0x9f000000

- 0x8f000000 if we have 3G userspace / 1G kernelspace with
  full 1 GB low memory (VMSPLIT_3G_OPT):
  - The kernel address space is 1GB (0x40000000)
  - PAGE_OFFSET is set to 0xb0000000 so the kernel static
    image uses 0xb0000000 .. 0xffffffff.
  - On top of that we have the MODULES_VADDR which under
    the worst case (using ARM instructions) is
    PAGE_OFFSET - 16M (0x01000000) = 0xaf000000
    so the modules use addresses 0xaf000000 .. 0xaffffff
  - So the addresses 0xaf000000 .. 0xffffffff need to be
    covered with shadow memory. That is 0x51000000 bytes
    of memory.
  - 1/8 of that is needed for its shadow memory, so
    0x0a200000 bytes of shadow memory is needed. We
    "steal" that from the remaining lowmem.
  - The KASAN_SHADOW_START becomes 0xa4e00000, to
    KASAN_SHADOW_END at 0xaeffffff.
  - Now we can calculate the KASAN_SHADOW_OFFSET for any
    kernel address as 0xaf000000 needs to map to the first
    byte of shadow memory and 0xffffffff needs to map to
    the last byte of shadow memory. Since:
    SHADOW_ADDR = (address &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    0xa4e00000 = (0xaf000000 &gt;&gt; 3) + KASAN_SHADOW_OFFSET
    KASAN_SHADOW_OFFSET = 0xa4e00000 - (0xaf000000 &gt;&gt; 3)
    KASAN_SHADOW_OFFSET = 0xa4e00000 - 0x15e00000
    KASAN_SHADOW_OFFSET = 0x8f000000

- The default value of 0xffffffff for KASAN_SHADOW_OFFSET
  is an error value. We should always match one of the
  above shadow offsets.

When we do this, TASK_SIZE will sometimes get a bit odd values
that will not fit into immediate mov assembly instructions.
To account for this, we need to rewrite some assembly using
TASK_SIZE like this:

-       mov     r1, #TASK_SIZE
+       ldr     r1, =TASK_SIZE

or

-       cmp     r4, #TASK_SIZE
+       ldr     r0, =TASK_SIZE
+       cmp     r4, r0

this is done to avoid the immediate #TASK_SIZE that need to
fit into a limited number of bits.

Cc: Andrey Ryabinin &lt;aryabinin@virtuozzo.com&gt;
Cc: Alexander Potapenko &lt;glider@google.com&gt;
Cc: Dmitry Vyukov &lt;dvyukov@google.com&gt;
Cc: kasan-dev@googlegroups.com
Cc: Mike Rapoport &lt;rppt@linux.ibm.com&gt;
Reviewed-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Tested-by: Ard Biesheuvel &lt;ardb@kernel.org&gt; # QEMU/KVM/mach-virt/LPAE/8G
Tested-by: Florian Fainelli &lt;f.fainelli@gmail.com&gt; # Brahma SoCs
Tested-by: Ahmad Fatoum &lt;a.fatoum@pengutronix.de&gt; # i.MX6Q
Reported-by: Ard Biesheuvel &lt;ardb@kernel.org&gt;
Signed-off-by: Abbott Liu &lt;liuwenliang@huawei.com&gt;
Signed-off-by: Florian Fainelli &lt;f.fainelli@gmail.com&gt;
Signed-off-by: Linus Walleij &lt;linus.walleij@linaro.org&gt;
Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>ARM: uaccess: consolidate uaccess asm to asm/uaccess-asm.h</title>
<updated>2020-05-03T16:30:24+00:00</updated>
<author>
<name>Russell King</name>
<email>rmk+kernel@armlinux.org.uk</email>
</author>
<published>2020-05-03T12:03:54+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=747ffc2fcf969eff9309d7f2d1d61cb8b9e1bb40'/>
<id>747ffc2fcf969eff9309d7f2d1d61cb8b9e1bb40</id>
<content type='text'>
Consolidate the user access assembly code to asm/uaccess-asm.h.  This
moves the csdb, check_uaccess, uaccess_mask_range_ptr, uaccess_enable,
uaccess_disable, uaccess_save, uaccess_restore macros, and creates two
new ones for exception entry and exit - uaccess_entry and uaccess_exit.

This makes the uaccess_save and uaccess_restore macros private to
asm/uaccess-asm.h.

Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
Consolidate the user access assembly code to asm/uaccess-asm.h.  This
moves the csdb, check_uaccess, uaccess_mask_range_ptr, uaccess_enable,
uaccess_disable, uaccess_save, uaccess_restore macros, and creates two
new ones for exception entry and exit - uaccess_entry and uaccess_exit.

This makes the uaccess_save and uaccess_restore macros private to
asm/uaccess-asm.h.

Signed-off-by: Russell King &lt;rmk+kernel@armlinux.org.uk&gt;
</pre>
</div>
</content>
</entry>
<entry>
<title>sched/rt, ARM: Use CONFIG_PREEMPTION</title>
<updated>2019-12-08T13:37:32+00:00</updated>
<author>
<name>Thomas Gleixner</name>
<email>tglx@linutronix.de</email>
</author>
<published>2019-10-15T19:17:48+00:00</published>
<link rel='alternate' type='text/html' href='https://git.tavy.me/linux.git/commit/?id=e7289c6de81c8e8991148e46c9ab43e2d23940f3'/>
<id>e7289c6de81c8e8991148e46c9ab43e2d23940f3</id>
<content type='text'>
CONFIG_PREEMPTION is selected by CONFIG_PREEMPT and by CONFIG_PREEMPT_RT.
Both PREEMPT and PREEMPT_RT require the same functionality which today
depends on CONFIG_PREEMPT.

Switch the entry code, cache over to use CONFIG_PREEMPTION and add output
in show_stack() for PREEMPT_RT.

[bigeasy: +traps.c]

Signed-off-by: Thomas Gleixner &lt;tglx@linutronix.de&gt;
Signed-off-by: Sebastian Andrzej Siewior &lt;bigeasy@linutronix.de&gt;
Signed-off-by: Thomas Gleixner &lt;tglx@linutronix.de&gt;
Cc: Linus Torvalds &lt;torvalds@linux-foundation.org&gt;
Cc: Peter Zijlstra &lt;peterz@infradead.org&gt;
Cc: Russell King &lt;linux@armlinux.org.uk&gt;
Cc: linux-arm-kernel@lists.infradead.org
Link: https://lore.kernel.org/r/20191015191821.11479-2-bigeasy@linutronix.de
Signed-off-by: Ingo Molnar &lt;mingo@kernel.org&gt;
</content>
<content type='xhtml'>
<div xmlns='http://www.w3.org/1999/xhtml'>
<pre>
CONFIG_PREEMPTION is selected by CONFIG_PREEMPT and by CONFIG_PREEMPT_RT.
Both PREEMPT and PREEMPT_RT require the same functionality which today
depends on CONFIG_PREEMPT.

Switch the entry code, cache over to use CONFIG_PREEMPTION and add output
in show_stack() for PREEMPT_RT.

[bigeasy: +traps.c]

Signed-off-by: Thomas Gleixner &lt;tglx@linutronix.de&gt;
Signed-off-by: Sebastian Andrzej Siewior &lt;bigeasy@linutronix.de&gt;
Signed-off-by: Thomas Gleixner &lt;tglx@linutronix.de&gt;
Cc: Linus Torvalds &lt;torvalds@linux-foundation.org&gt;
Cc: Peter Zijlstra &lt;peterz@infradead.org&gt;
Cc: Russell King &lt;linux@armlinux.org.uk&gt;
Cc: linux-arm-kernel@lists.infradead.org
Link: https://lore.kernel.org/r/20191015191821.11479-2-bigeasy@linutronix.de
Signed-off-by: Ingo Molnar &lt;mingo@kernel.org&gt;
</pre>
</div>
</content>
</entry>
</feed>
