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The topic of nesting and reentrancy in the context of early entry code hasn't been addressed so far. So do it. Signed-off-by: Nicolas Saenz Julienne <nsaenzju@redhat.com> Reviewed-by: Frederic Weisbecker <frederic@kernel.org> Reviewed-by: Paul E. McKenney <paulmck@kernel.org> Link: https://lore.kernel.org/r/20220110105044.94423-2-nsaenzju@redhat.com Signed-off-by: Jonathan Corbet <corbet@lwn.net>
280 lines
9.5 KiB
ReStructuredText
280 lines
9.5 KiB
ReStructuredText
Entry/exit handling for exceptions, interrupts, syscalls and KVM
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================================================================
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All transitions between execution domains require state updates which are
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subject to strict ordering constraints. State updates are required for the
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following:
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* Lockdep
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* RCU / Context tracking
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* Preemption counter
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* Tracing
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* Time accounting
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The update order depends on the transition type and is explained below in
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the transition type sections: `Syscalls`_, `KVM`_, `Interrupts and regular
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exceptions`_, `NMI and NMI-like exceptions`_.
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Non-instrumentable code - noinstr
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---------------------------------
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Most instrumentation facilities depend on RCU, so intrumentation is prohibited
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for entry code before RCU starts watching and exit code after RCU stops
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watching. In addition, many architectures must save and restore register state,
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which means that (for example) a breakpoint in the breakpoint entry code would
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overwrite the debug registers of the initial breakpoint.
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Such code must be marked with the 'noinstr' attribute, placing that code into a
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special section inaccessible to instrumentation and debug facilities. Some
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functions are partially instrumentable, which is handled by marking them
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noinstr and using instrumentation_begin() and instrumentation_end() to flag the
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instrumentable ranges of code:
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.. code-block:: c
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noinstr void entry(void)
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{
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handle_entry(); // <-- must be 'noinstr' or '__always_inline'
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...
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instrumentation_begin();
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handle_context(); // <-- instrumentable code
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instrumentation_end();
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...
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handle_exit(); // <-- must be 'noinstr' or '__always_inline'
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}
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This allows verification of the 'noinstr' restrictions via objtool on
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supported architectures.
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Invoking non-instrumentable functions from instrumentable context has no
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restrictions and is useful to protect e.g. state switching which would
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cause malfunction if instrumented.
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All non-instrumentable entry/exit code sections before and after the RCU
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state transitions must run with interrupts disabled.
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Syscalls
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--------
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Syscall-entry code starts in assembly code and calls out into low-level C code
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after establishing low-level architecture-specific state and stack frames. This
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low-level C code must not be instrumented. A typical syscall handling function
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invoked from low-level assembly code looks like this:
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.. code-block:: c
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noinstr void syscall(struct pt_regs *regs, int nr)
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{
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arch_syscall_enter(regs);
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nr = syscall_enter_from_user_mode(regs, nr);
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instrumentation_begin();
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if (!invoke_syscall(regs, nr) && nr != -1)
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result_reg(regs) = __sys_ni_syscall(regs);
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instrumentation_end();
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syscall_exit_to_user_mode(regs);
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}
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syscall_enter_from_user_mode() first invokes enter_from_user_mode() which
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establishes state in the following order:
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* Lockdep
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* RCU / Context tracking
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* Tracing
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and then invokes the various entry work functions like ptrace, seccomp, audit,
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syscall tracing, etc. After all that is done, the instrumentable invoke_syscall
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function can be invoked. The instrumentable code section then ends, after which
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syscall_exit_to_user_mode() is invoked.
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syscall_exit_to_user_mode() handles all work which needs to be done before
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returning to user space like tracing, audit, signals, task work etc. After
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that it invokes exit_to_user_mode() which again handles the state
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transition in the reverse order:
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* Tracing
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* RCU / Context tracking
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* Lockdep
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syscall_enter_from_user_mode() and syscall_exit_to_user_mode() are also
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available as fine grained subfunctions in cases where the architecture code
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has to do extra work between the various steps. In such cases it has to
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ensure that enter_from_user_mode() is called first on entry and
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exit_to_user_mode() is called last on exit.
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Do not nest syscalls. Nested systcalls will cause RCU and/or context tracking
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to print a warning.
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KVM
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---
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Entering or exiting guest mode is very similar to syscalls. From the host
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kernel point of view the CPU goes off into user space when entering the
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guest and returns to the kernel on exit.
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kvm_guest_enter_irqoff() is a KVM-specific variant of exit_to_user_mode()
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and kvm_guest_exit_irqoff() is the KVM variant of enter_from_user_mode().
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The state operations have the same ordering.
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Task work handling is done separately for guest at the boundary of the
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vcpu_run() loop via xfer_to_guest_mode_handle_work() which is a subset of
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the work handled on return to user space.
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Do not nest KVM entry/exit transitions because doing so is nonsensical.
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Interrupts and regular exceptions
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---------------------------------
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Interrupts entry and exit handling is slightly more complex than syscalls
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and KVM transitions.
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If an interrupt is raised while the CPU executes in user space, the entry
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and exit handling is exactly the same as for syscalls.
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If the interrupt is raised while the CPU executes in kernel space the entry and
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exit handling is slightly different. RCU state is only updated when the
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interrupt is raised in the context of the CPU's idle task. Otherwise, RCU will
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already be watching. Lockdep and tracing have to be updated unconditionally.
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irqentry_enter() and irqentry_exit() provide the implementation for this.
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The architecture-specific part looks similar to syscall handling:
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.. code-block:: c
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noinstr void interrupt(struct pt_regs *regs, int nr)
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{
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arch_interrupt_enter(regs);
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state = irqentry_enter(regs);
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instrumentation_begin();
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irq_enter_rcu();
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invoke_irq_handler(regs, nr);
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irq_exit_rcu();
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instrumentation_end();
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irqentry_exit(regs, state);
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}
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Note that the invocation of the actual interrupt handler is within a
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irq_enter_rcu() and irq_exit_rcu() pair.
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irq_enter_rcu() updates the preemption count which makes in_hardirq()
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return true, handles NOHZ tick state and interrupt time accounting. This
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means that up to the point where irq_enter_rcu() is invoked in_hardirq()
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returns false.
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irq_exit_rcu() handles interrupt time accounting, undoes the preemption
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count update and eventually handles soft interrupts and NOHZ tick state.
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In theory, the preemption count could be updated in irqentry_enter(). In
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practice, deferring this update to irq_enter_rcu() allows the preemption-count
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code to be traced, while also maintaining symmetry with irq_exit_rcu() and
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irqentry_exit(), which are described in the next paragraph. The only downside
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is that the early entry code up to irq_enter_rcu() must be aware that the
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preemption count has not yet been updated with the HARDIRQ_OFFSET state.
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Note that irq_exit_rcu() must remove HARDIRQ_OFFSET from the preemption count
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before it handles soft interrupts, whose handlers must run in BH context rather
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than irq-disabled context. In addition, irqentry_exit() might schedule, which
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also requires that HARDIRQ_OFFSET has been removed from the preemption count.
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Even though interrupt handlers are expected to run with local interrupts
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disabled, interrupt nesting is common from an entry/exit perspective. For
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example, softirq handling happens within an irqentry_{enter,exit}() block with
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local interrupts enabled. Also, although uncommon, nothing prevents an
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interrupt handler from re-enabling interrupts.
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Interrupt entry/exit code doesn't strictly need to handle reentrancy, since it
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runs with local interrupts disabled. But NMIs can happen anytime, and a lot of
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the entry code is shared between the two.
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NMI and NMI-like exceptions
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---------------------------
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NMIs and NMI-like exceptions (machine checks, double faults, debug
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interrupts, etc.) can hit any context and must be extra careful with
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the state.
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State changes for debug exceptions and machine-check exceptions depend on
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whether these exceptions happened in user-space (breakpoints or watchpoints) or
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in kernel mode (code patching). From user-space, they are treated like
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interrupts, while from kernel mode they are treated like NMIs.
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NMIs and other NMI-like exceptions handle state transitions without
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distinguishing between user-mode and kernel-mode origin.
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The state update on entry is handled in irqentry_nmi_enter() which updates
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state in the following order:
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* Preemption counter
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* Lockdep
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* RCU / Context tracking
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* Tracing
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The exit counterpart irqentry_nmi_exit() does the reverse operation in the
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reverse order.
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Note that the update of the preemption counter has to be the first
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operation on enter and the last operation on exit. The reason is that both
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lockdep and RCU rely on in_nmi() returning true in this case. The
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preemption count modification in the NMI entry/exit case must not be
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traced.
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Architecture-specific code looks like this:
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.. code-block:: c
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noinstr void nmi(struct pt_regs *regs)
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{
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arch_nmi_enter(regs);
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state = irqentry_nmi_enter(regs);
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instrumentation_begin();
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nmi_handler(regs);
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instrumentation_end();
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irqentry_nmi_exit(regs);
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}
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and for e.g. a debug exception it can look like this:
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.. code-block:: c
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noinstr void debug(struct pt_regs *regs)
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{
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arch_nmi_enter(regs);
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debug_regs = save_debug_regs();
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if (user_mode(regs)) {
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state = irqentry_enter(regs);
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instrumentation_begin();
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user_mode_debug_handler(regs, debug_regs);
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instrumentation_end();
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irqentry_exit(regs, state);
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} else {
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state = irqentry_nmi_enter(regs);
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instrumentation_begin();
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kernel_mode_debug_handler(regs, debug_regs);
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instrumentation_end();
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irqentry_nmi_exit(regs, state);
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}
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}
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There is no combined irqentry_nmi_if_kernel() function available as the
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above cannot be handled in an exception-agnostic way.
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NMIs can happen in any context. For example, an NMI-like exception triggered
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while handling an NMI. So NMI entry code has to be reentrant and state updates
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need to handle nesting.
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