Documentation/core-api/entry.rst - linux/kernel/git/gregkh/usb - Git at Google

 Entry/exit handling for exceptions, interrupts, syscalls and KVM
 ================================================================

 All transitions between execution domains require state updates which are
 subject to strict ordering constraints. State updates are required for the
 following:

   * Lockdep
   * RCU / Context tracking
   * Preemption counter
   * Tracing
   * Time accounting

 The update order depends on the transition type and is explained below in
 the transition type sections: `Syscalls`_, `KVM`_, `Interrupts and regular
 exceptions`_, `NMI and NMI-like exceptions`_.

 Non-instrumentable code - noinstr
 ---------------------------------

 Most instrumentation facilities depend on RCU, so intrumentation is prohibited
 for entry code before RCU starts watching and exit code after RCU stops
 watching. In addition, many architectures must save and restore register state,
 which means that (for example) a breakpoint in the breakpoint entry code would
 overwrite the debug registers of the initial breakpoint.

 Such code must be marked with the 'noinstr' attribute, placing that code into a
 special section inaccessible to instrumentation and debug facilities. Some
 functions are partially instrumentable, which is handled by marking them
 noinstr and using instrumentation_begin() and instrumentation_end() to flag the
 instrumentable ranges of code:

 .. code-block:: c

   noinstr void entry(void)
   {
   	handle_entry();     // <-- must be 'noinstr' or '__always_inline'
 	...

 	instrumentation_begin();
 	handle_context();   // <-- instrumentable code
 	instrumentation_end();

 	...
 	handle_exit();      // <-- must be 'noinstr' or '__always_inline'
   }

 This allows verification of the 'noinstr' restrictions via objtool on
 supported architectures.

 Invoking non-instrumentable functions from instrumentable context has no
 restrictions and is useful to protect e.g. state switching which would
 cause malfunction if instrumented.

 All non-instrumentable entry/exit code sections before and after the RCU
 state transitions must run with interrupts disabled.

 Syscalls
 --------

 Syscall-entry code starts in assembly code and calls out into low-level C code
 after establishing low-level architecture-specific state and stack frames. This
 low-level C code must not be instrumented. A typical syscall handling function
 invoked from low-level assembly code looks like this:

 .. code-block:: c

   noinstr void syscall(struct pt_regs *regs, int nr)
   {
 	arch_syscall_enter(regs);
 	nr = syscall_enter_from_user_mode(regs, nr);

 	instrumentation_begin();
 	if (!invoke_syscall(regs, nr) && nr != -1)
 	 	result_reg(regs) = __sys_ni_syscall(regs);
 	instrumentation_end();

 	syscall_exit_to_user_mode(regs);
   }

 syscall_enter_from_user_mode() first invokes enter_from_user_mode() which
 establishes state in the following order:

   * Lockdep
   * RCU / Context tracking
   * Tracing

 and then invokes the various entry work functions like ptrace, seccomp, audit,
 syscall tracing, etc. After all that is done, the instrumentable invoke_syscall
 function can be invoked. The instrumentable code section then ends, after which
 syscall_exit_to_user_mode() is invoked.

 syscall_exit_to_user_mode() handles all work which needs to be done before
 returning to user space like tracing, audit, signals, task work etc. After
 that it invokes exit_to_user_mode() which again handles the state
 transition in the reverse order:

   * Tracing
   * RCU / Context tracking
   * Lockdep

 syscall_enter_from_user_mode() and syscall_exit_to_user_mode() are also
 available as fine grained subfunctions in cases where the architecture code
 has to do extra work between the various steps. In such cases it has to
 ensure that enter_from_user_mode() is called first on entry and
 exit_to_user_mode() is called last on exit.

 Do not nest syscalls. Nested systcalls will cause RCU and/or context tracking
 to print a warning.

 KVM
 ---

 Entering or exiting guest mode is very similar to syscalls. From the host
 kernel point of view the CPU goes off into user space when entering the
 guest and returns to the kernel on exit.

 kvm_guest_enter_irqoff() is a KVM-specific variant of exit_to_user_mode()
 and kvm_guest_exit_irqoff() is the KVM variant of enter_from_user_mode().
 The state operations have the same ordering.

 Task work handling is done separately for guest at the boundary of the
 vcpu_run() loop via xfer_to_guest_mode_handle_work() which is a subset of
 the work handled on return to user space.

 Do not nest KVM entry/exit transitions because doing so is nonsensical.

 Interrupts and regular exceptions
 ---------------------------------

 Interrupts entry and exit handling is slightly more complex than syscalls
 and KVM transitions.

 If an interrupt is raised while the CPU executes in user space, the entry
 and exit handling is exactly the same as for syscalls.

 If the interrupt is raised while the CPU executes in kernel space the entry and
 exit handling is slightly different. RCU state is only updated when the
 interrupt is raised in the context of the CPU's idle task. Otherwise, RCU will
 already be watching. Lockdep and tracing have to be updated unconditionally.

 irqentry_enter() and irqentry_exit() provide the implementation for this.

 The architecture-specific part looks similar to syscall handling:

 .. code-block:: c

   noinstr void interrupt(struct pt_regs *regs, int nr)
   {
 	arch_interrupt_enter(regs);
 	state = irqentry_enter(regs);

 	instrumentation_begin();

 	irq_enter_rcu();
 	invoke_irq_handler(regs, nr);
 	irq_exit_rcu();

 	instrumentation_end();

 	irqentry_exit(regs, state);
   }

 Note that the invocation of the actual interrupt handler is within a
 irq_enter_rcu() and irq_exit_rcu() pair.

 irq_enter_rcu() updates the preemption count which makes in_hardirq()
 return true, handles NOHZ tick state and interrupt time accounting. This
 means that up to the point where irq_enter_rcu() is invoked in_hardirq()
 returns false.

 irq_exit_rcu() handles interrupt time accounting, undoes the preemption
 count update and eventually handles soft interrupts and NOHZ tick state.

 In theory, the preemption count could be updated in irqentry_enter(). In
 practice, deferring this update to irq_enter_rcu() allows the preemption-count
 code to be traced, while also maintaining symmetry with irq_exit_rcu() and
 irqentry_exit(), which are described in the next paragraph. The only downside
 is that the early entry code up to irq_enter_rcu() must be aware that the
 preemption count has not yet been updated with the HARDIRQ_OFFSET state.

 Note that irq_exit_rcu() must remove HARDIRQ_OFFSET from the preemption count
 before it handles soft interrupts, whose handlers must run in BH context rather
 than irq-disabled context. In addition, irqentry_exit() might schedule, which
 also requires that HARDIRQ_OFFSET has been removed from the preemption count.

 Even though interrupt handlers are expected to run with local interrupts
 disabled, interrupt nesting is common from an entry/exit perspective. For
 example, softirq handling happens within an irqentry_{enter,exit}() block with
 local interrupts enabled. Also, although uncommon, nothing prevents an
 interrupt handler from re-enabling interrupts.

 Interrupt entry/exit code doesn't strictly need to handle reentrancy, since it
 runs with local interrupts disabled. But NMIs can happen anytime, and a lot of
 the entry code is shared between the two.

 NMI and NMI-like exceptions
 ---------------------------

 NMIs and NMI-like exceptions (machine checks, double faults, debug
 interrupts, etc.) can hit any context and must be extra careful with
 the state.

 State changes for debug exceptions and machine-check exceptions depend on
 whether these exceptions happened in user-space (breakpoints or watchpoints) or
 in kernel mode (code patching). From user-space, they are treated like
 interrupts, while from kernel mode they are treated like NMIs.

 NMIs and other NMI-like exceptions handle state transitions without
 distinguishing between user-mode and kernel-mode origin.

 The state update on entry is handled in irqentry_nmi_enter() which updates
 state in the following order:

   * Preemption counter
   * Lockdep
   * RCU / Context tracking
   * Tracing

 The exit counterpart irqentry_nmi_exit() does the reverse operation in the
 reverse order.

 Note that the update of the preemption counter has to be the first
 operation on enter and the last operation on exit. The reason is that both
 lockdep and RCU rely on in_nmi() returning true in this case. The
 preemption count modification in the NMI entry/exit case must not be
 traced.

 Architecture-specific code looks like this:

 .. code-block:: c

   noinstr void nmi(struct pt_regs *regs)
   {
 	arch_nmi_enter(regs);
 	state = irqentry_nmi_enter(regs);

 	instrumentation_begin();
 	nmi_handler(regs);
 	instrumentation_end();

 	irqentry_nmi_exit(regs);
   }

 and for e.g. a debug exception it can look like this:

 .. code-block:: c

   noinstr void debug(struct pt_regs *regs)
   {
 	arch_nmi_enter(regs);

 	debug_regs = save_debug_regs();

 	if (user_mode(regs)) {
 		state = irqentry_enter(regs);

 		instrumentation_begin();
 		user_mode_debug_handler(regs, debug_regs);
 		instrumentation_end();

 		irqentry_exit(regs, state);
   	} else {
   		state = irqentry_nmi_enter(regs);

 		instrumentation_begin();
 		kernel_mode_debug_handler(regs, debug_regs);
 		instrumentation_end();

 		irqentry_nmi_exit(regs, state);
 	}
   }

 There is no combined irqentry_nmi_if_kernel() function available as the
 above cannot be handled in an exception-agnostic way.

 NMIs can happen in any context. For example, an NMI-like exception triggered
 while handling an NMI. So NMI entry code has to be reentrant and state updates
 need to handle nesting.
	Entry/exit handling for exceptions, interrupts, syscalls and KVM
	================================================================

	All transitions between execution domains require state updates which are
	subject to strict ordering constraints. State updates are required for the
	following:

	* Lockdep
	* RCU / Context tracking
	* Preemption counter
	* Tracing
	* Time accounting

	The update order depends on the transition type and is explained below in
	the transition type sections: `Syscalls`_, `KVM`_, `Interrupts and regular
	exceptions`_, `NMI and NMI-like exceptions`_.

	Non-instrumentable code - noinstr
	---------------------------------

	Most instrumentation facilities depend on RCU, so intrumentation is prohibited
	for entry code before RCU starts watching and exit code after RCU stops
	watching. In addition, many architectures must save and restore register state,
	which means that (for example) a breakpoint in the breakpoint entry code would
	overwrite the debug registers of the initial breakpoint.

	Such code must be marked with the 'noinstr' attribute, placing that code into a
	special section inaccessible to instrumentation and debug facilities. Some
	functions are partially instrumentable, which is handled by marking them
	noinstr and using instrumentation_begin() and instrumentation_end() to flag the
	instrumentable ranges of code:

	.. code-block:: c

	noinstr void entry(void)
	{
	handle_entry(); // <-- must be 'noinstr' or '__always_inline'
	...

	instrumentation_begin();
	handle_context(); // <-- instrumentable code
	instrumentation_end();

	...
	handle_exit(); // <-- must be 'noinstr' or '__always_inline'
	}

	This allows verification of the 'noinstr' restrictions via objtool on
	supported architectures.

	Invoking non-instrumentable functions from instrumentable context has no
	restrictions and is useful to protect e.g. state switching which would
	cause malfunction if instrumented.

	All non-instrumentable entry/exit code sections before and after the RCU
	state transitions must run with interrupts disabled.

	Syscalls
	--------

	Syscall-entry code starts in assembly code and calls out into low-level C code
	after establishing low-level architecture-specific state and stack frames. This
	low-level C code must not be instrumented. A typical syscall handling function
	invoked from low-level assembly code looks like this:

	.. code-block:: c

	noinstr void syscall(struct pt_regs *regs, int nr)
	{
	arch_syscall_enter(regs);
	nr = syscall_enter_from_user_mode(regs, nr);

	instrumentation_begin();
	if (!invoke_syscall(regs, nr) && nr != -1)
	result_reg(regs) = __sys_ni_syscall(regs);
	instrumentation_end();

	syscall_exit_to_user_mode(regs);
	}

	syscall_enter_from_user_mode() first invokes enter_from_user_mode() which
	establishes state in the following order:

	* Lockdep
	* RCU / Context tracking
	* Tracing

	and then invokes the various entry work functions like ptrace, seccomp, audit,
	syscall tracing, etc. After all that is done, the instrumentable invoke_syscall
	function can be invoked. The instrumentable code section then ends, after which
	syscall_exit_to_user_mode() is invoked.

	syscall_exit_to_user_mode() handles all work which needs to be done before
	returning to user space like tracing, audit, signals, task work etc. After
	that it invokes exit_to_user_mode() which again handles the state
	transition in the reverse order:

	* Tracing
	* RCU / Context tracking
	* Lockdep

	syscall_enter_from_user_mode() and syscall_exit_to_user_mode() are also
	available as fine grained subfunctions in cases where the architecture code
	has to do extra work between the various steps. In such cases it has to
	ensure that enter_from_user_mode() is called first on entry and
	exit_to_user_mode() is called last on exit.

	Do not nest syscalls. Nested systcalls will cause RCU and/or context tracking
	to print a warning.

	KVM
	---

	Entering or exiting guest mode is very similar to syscalls. From the host
	kernel point of view the CPU goes off into user space when entering the
	guest and returns to the kernel on exit.

	kvm_guest_enter_irqoff() is a KVM-specific variant of exit_to_user_mode()
	and kvm_guest_exit_irqoff() is the KVM variant of enter_from_user_mode().
	The state operations have the same ordering.

	Task work handling is done separately for guest at the boundary of the
	vcpu_run() loop via xfer_to_guest_mode_handle_work() which is a subset of
	the work handled on return to user space.

	Do not nest KVM entry/exit transitions because doing so is nonsensical.

	Interrupts and regular exceptions
	---------------------------------

	Interrupts entry and exit handling is slightly more complex than syscalls
	and KVM transitions.

	If an interrupt is raised while the CPU executes in user space, the entry
	and exit handling is exactly the same as for syscalls.

	If the interrupt is raised while the CPU executes in kernel space the entry and
	exit handling is slightly different. RCU state is only updated when the
	interrupt is raised in the context of the CPU's idle task. Otherwise, RCU will
	already be watching. Lockdep and tracing have to be updated unconditionally.

	irqentry_enter() and irqentry_exit() provide the implementation for this.

	The architecture-specific part looks similar to syscall handling:

	.. code-block:: c

	noinstr void interrupt(struct pt_regs *regs, int nr)
	{
	arch_interrupt_enter(regs);
	state = irqentry_enter(regs);

	instrumentation_begin();

	irq_enter_rcu();
	invoke_irq_handler(regs, nr);
	irq_exit_rcu();

	instrumentation_end();

	irqentry_exit(regs, state);
	}

	Note that the invocation of the actual interrupt handler is within a
	irq_enter_rcu() and irq_exit_rcu() pair.

	irq_enter_rcu() updates the preemption count which makes in_hardirq()
	return true, handles NOHZ tick state and interrupt time accounting. This
	means that up to the point where irq_enter_rcu() is invoked in_hardirq()
	returns false.

	irq_exit_rcu() handles interrupt time accounting, undoes the preemption
	count update and eventually handles soft interrupts and NOHZ tick state.

	In theory, the preemption count could be updated in irqentry_enter(). In
	practice, deferring this update to irq_enter_rcu() allows the preemption-count
	code to be traced, while also maintaining symmetry with irq_exit_rcu() and
	irqentry_exit(), which are described in the next paragraph. The only downside
	is that the early entry code up to irq_enter_rcu() must be aware that the
	preemption count has not yet been updated with the HARDIRQ_OFFSET state.

	Note that irq_exit_rcu() must remove HARDIRQ_OFFSET from the preemption count
	before it handles soft interrupts, whose handlers must run in BH context rather
	than irq-disabled context. In addition, irqentry_exit() might schedule, which
	also requires that HARDIRQ_OFFSET has been removed from the preemption count.

	Even though interrupt handlers are expected to run with local interrupts
	disabled, interrupt nesting is common from an entry/exit perspective. For
	example, softirq handling happens within an irqentry_{enter,exit}() block with
	local interrupts enabled. Also, although uncommon, nothing prevents an
	interrupt handler from re-enabling interrupts.

	Interrupt entry/exit code doesn't strictly need to handle reentrancy, since it
	runs with local interrupts disabled. But NMIs can happen anytime, and a lot of
	the entry code is shared between the two.

	NMI and NMI-like exceptions
	---------------------------

	NMIs and NMI-like exceptions (machine checks, double faults, debug
	interrupts, etc.) can hit any context and must be extra careful with
	the state.

	State changes for debug exceptions and machine-check exceptions depend on
	whether these exceptions happened in user-space (breakpoints or watchpoints) or
	in kernel mode (code patching). From user-space, they are treated like
	interrupts, while from kernel mode they are treated like NMIs.

	NMIs and other NMI-like exceptions handle state transitions without
	distinguishing between user-mode and kernel-mode origin.

	The state update on entry is handled in irqentry_nmi_enter() which updates
	state in the following order:

	* Preemption counter
	* Lockdep
	* RCU / Context tracking
	* Tracing

	The exit counterpart irqentry_nmi_exit() does the reverse operation in the
	reverse order.

	Note that the update of the preemption counter has to be the first
	operation on enter and the last operation on exit. The reason is that both
	lockdep and RCU rely on in_nmi() returning true in this case. The
	preemption count modification in the NMI entry/exit case must not be
	traced.

	Architecture-specific code looks like this:

	.. code-block:: c

	noinstr void nmi(struct pt_regs *regs)
	{
	arch_nmi_enter(regs);
	state = irqentry_nmi_enter(regs);

	instrumentation_begin();
	nmi_handler(regs);
	instrumentation_end();

	irqentry_nmi_exit(regs);
	}

	and for e.g. a debug exception it can look like this:

	.. code-block:: c

	noinstr void debug(struct pt_regs *regs)
	{
	arch_nmi_enter(regs);

	debug_regs = save_debug_regs();

	if (user_mode(regs)) {
	state = irqentry_enter(regs);

	instrumentation_begin();
	user_mode_debug_handler(regs, debug_regs);
	instrumentation_end();

	irqentry_exit(regs, state);
	} else {
	state = irqentry_nmi_enter(regs);

	instrumentation_begin();
	kernel_mode_debug_handler(regs, debug_regs);
	instrumentation_end();

	irqentry_nmi_exit(regs, state);
	}
	}

	There is no combined irqentry_nmi_if_kernel() function available as the
	above cannot be handled in an exception-agnostic way.

	NMIs can happen in any context. For example, an NMI-like exception triggered
	while handling an NMI. So NMI entry code has to be reentrant and state updates
	need to handle nesting.