Documentation/arch/x86/xstate.rst - kernel/common - Git at Google

 Using XSTATE features in user space applications
 ================================================

 The x86 architecture supports floating-point extensions which are
 enumerated via CPUID. Applications consult CPUID and use XGETBV to
 evaluate which features have been enabled by the kernel XCR0.

 Up to AVX-512 and PKRU states, these features are automatically enabled by
 the kernel if available. Features like AMX TILE_DATA (XSTATE component 18)
 are enabled by XCR0 as well, but the first use of related instruction is
 trapped by the kernel because by default the required large XSTATE buffers
 are not allocated automatically.

 The purpose for dynamic features
 --------------------------------

 Legacy userspace libraries often have hard-coded, static sizes for
 alternate signal stacks, often using MINSIGSTKSZ which is typically 2KB.
 That stack must be able to store at *least* the signal frame that the
 kernel sets up before jumping into the signal handler. That signal frame
 must include an XSAVE buffer defined by the CPU.

 However, that means that the size of signal stacks is dynamic, not static,
 because different CPUs have differently-sized XSAVE buffers. A compiled-in
 size of 2KB with existing applications is too small for new CPU features
 like AMX. Instead of universally requiring larger stack, with the dynamic
 enabling, the kernel can enforce userspace applications to have
 properly-sized altstacks.

 Using dynamically enabled XSTATE features in user space applications
 --------------------------------------------------------------------

 The kernel provides an arch_prctl(2) based mechanism for applications to
 request the usage of such features. The arch_prctl(2) options related to
 this are:

 -ARCH_GET_XCOMP_SUPP

  arch_prctl(ARCH_GET_XCOMP_SUPP, &features);

  ARCH_GET_XCOMP_SUPP stores the supported features in userspace storage of
  type uint64_t. The second argument is a pointer to that storage.

 -ARCH_GET_XCOMP_PERM

  arch_prctl(ARCH_GET_XCOMP_PERM, &features);

  ARCH_GET_XCOMP_PERM stores the features for which the userspace process
  has permission in userspace storage of type uint64_t. The second argument
  is a pointer to that storage.

 -ARCH_REQ_XCOMP_PERM

  arch_prctl(ARCH_REQ_XCOMP_PERM, feature_nr);

  ARCH_REQ_XCOMP_PERM allows to request permission for a dynamically enabled
  feature or a feature set. A feature set can be mapped to a facility, e.g.
  AMX, and can require one or more XSTATE components to be enabled.

  The feature argument is the number of the highest XSTATE component which
  is required for a facility to work.

 When requesting permission for a feature, the kernel checks the
 availability. The kernel ensures that sigaltstacks in the process's tasks
 are large enough to accommodate the resulting large signal frame. It
 enforces this both during ARCH_REQ_XCOMP_SUPP and during any subsequent
 sigaltstack(2) calls. If an installed sigaltstack is smaller than the
 resulting sigframe size, ARCH_REQ_XCOMP_SUPP results in -ENOSUPP. Also,
 sigaltstack(2) results in -ENOMEM if the requested altstack is too small
 for the permitted features.

 Permission, when granted, is valid per process. Permissions are inherited
 on fork(2) and cleared on exec(3).

 The first use of an instruction related to a dynamically enabled feature is
 trapped by the kernel. The trap handler checks whether the process has
 permission to use the feature. If the process has no permission then the
 kernel sends SIGILL to the application. If the process has permission then
 the handler allocates a larger xstate buffer for the task so the large
 state can be context switched. In the unlikely cases that the allocation
 fails, the kernel sends SIGSEGV.

 AMX TILE_DATA enabling example
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 Below is the example of how userspace applications enable
 TILE_DATA dynamically:

   1. The application first needs to query the kernel for AMX
      support::

         #include <asm/prctl.h>
         #include <sys/syscall.h>
         #include <stdio.h>
         #include <unistd.h>

         #ifndef ARCH_GET_XCOMP_SUPP
         #define ARCH_GET_XCOMP_SUPP  0x1021
         #endif

         #ifndef ARCH_XCOMP_TILECFG
         #define ARCH_XCOMP_TILECFG   17
         #endif

         #ifndef ARCH_XCOMP_TILEDATA
         #define ARCH_XCOMP_TILEDATA  18
         #endif

         #define MASK_XCOMP_TILE      ((1 << ARCH_XCOMP_TILECFG) | \
                                       (1 << ARCH_XCOMP_TILEDATA))

         unsigned long features;
         long rc;

         ...

         rc = syscall(SYS_arch_prctl, ARCH_GET_XCOMP_SUPP, &features);

         if (!rc && (features & MASK_XCOMP_TILE) == MASK_XCOMP_TILE)
             printf("AMX is available.\n");

   2. After that, determining support for AMX, an application must
      explicitly ask permission to use it::

         #ifndef ARCH_REQ_XCOMP_PERM
         #define ARCH_REQ_XCOMP_PERM  0x1023
         #endif

         ...

         rc = syscall(SYS_arch_prctl, ARCH_REQ_XCOMP_PERM, ARCH_XCOMP_TILEDATA);

         if (!rc)
             printf("AMX is ready for use.\n");

 Note this example does not include the sigaltstack preparation.

 Dynamic features in signal frames
 ---------------------------------

 Dynamcally enabled features are not written to the signal frame upon signal
 entry if the feature is in its initial configuration.  This differs from
 non-dynamic features which are always written regardless of their
 configuration.  Signal handlers can examine the XSAVE buffer's XSTATE_BV
 field to determine if a features was written.

 Dynamic features for virtual machines
 -------------------------------------

 The permission for the guest state component needs to be managed separately
 from the host, as they are exclusive to each other. A coupled of options
 are extended to control the guest permission:

 -ARCH_GET_XCOMP_GUEST_PERM

  arch_prctl(ARCH_GET_XCOMP_GUEST_PERM, &features);

  ARCH_GET_XCOMP_GUEST_PERM is a variant of ARCH_GET_XCOMP_PERM. So it
  provides the same semantics and functionality but for the guest
  components.

 -ARCH_REQ_XCOMP_GUEST_PERM

  arch_prctl(ARCH_REQ_XCOMP_GUEST_PERM, feature_nr);

  ARCH_REQ_XCOMP_GUEST_PERM is a variant of ARCH_REQ_XCOMP_PERM. It has the
  same semantics for the guest permission. While providing a similar
  functionality, this comes with a constraint. Permission is frozen when the
  first VCPU is created. Any attempt to change permission after that point
  is going to be rejected. So, the permission has to be requested before the
  first VCPU creation.

 Note that some VMMs may have already established a set of supported state
 components. These options are not presumed to support any particular VMM.
	Using XSTATE features in user space applications
	================================================

	The x86 architecture supports floating-point extensions which are
	enumerated via CPUID. Applications consult CPUID and use XGETBV to
	evaluate which features have been enabled by the kernel XCR0.

	Up to AVX-512 and PKRU states, these features are automatically enabled by
	the kernel if available. Features like AMX TILE_DATA (XSTATE component 18)
	are enabled by XCR0 as well, but the first use of related instruction is
	trapped by the kernel because by default the required large XSTATE buffers
	are not allocated automatically.

	The purpose for dynamic features
	--------------------------------

	Legacy userspace libraries often have hard-coded, static sizes for
	alternate signal stacks, often using MINSIGSTKSZ which is typically 2KB.
	That stack must be able to store at least the signal frame that the
	kernel sets up before jumping into the signal handler. That signal frame
	must include an XSAVE buffer defined by the CPU.

	However, that means that the size of signal stacks is dynamic, not static,
	because different CPUs have differently-sized XSAVE buffers. A compiled-in
	size of 2KB with existing applications is too small for new CPU features
	like AMX. Instead of universally requiring larger stack, with the dynamic
	enabling, the kernel can enforce userspace applications to have
	properly-sized altstacks.

	Using dynamically enabled XSTATE features in user space applications
	--------------------------------------------------------------------

	The kernel provides an arch_prctl(2) based mechanism for applications to
	request the usage of such features. The arch_prctl(2) options related to
	this are:

	-ARCH_GET_XCOMP_SUPP

	arch_prctl(ARCH_GET_XCOMP_SUPP, &features);

	ARCH_GET_XCOMP_SUPP stores the supported features in userspace storage of
	type uint64_t. The second argument is a pointer to that storage.

	-ARCH_GET_XCOMP_PERM

	arch_prctl(ARCH_GET_XCOMP_PERM, &features);

	ARCH_GET_XCOMP_PERM stores the features for which the userspace process
	has permission in userspace storage of type uint64_t. The second argument
	is a pointer to that storage.

	-ARCH_REQ_XCOMP_PERM

	arch_prctl(ARCH_REQ_XCOMP_PERM, feature_nr);

	ARCH_REQ_XCOMP_PERM allows to request permission for a dynamically enabled
	feature or a feature set. A feature set can be mapped to a facility, e.g.
	AMX, and can require one or more XSTATE components to be enabled.

	The feature argument is the number of the highest XSTATE component which
	is required for a facility to work.

	When requesting permission for a feature, the kernel checks the
	availability. The kernel ensures that sigaltstacks in the process's tasks
	are large enough to accommodate the resulting large signal frame. It
	enforces this both during ARCH_REQ_XCOMP_SUPP and during any subsequent
	sigaltstack(2) calls. If an installed sigaltstack is smaller than the
	resulting sigframe size, ARCH_REQ_XCOMP_SUPP results in -ENOSUPP. Also,
	sigaltstack(2) results in -ENOMEM if the requested altstack is too small
	for the permitted features.

	Permission, when granted, is valid per process. Permissions are inherited
	on fork(2) and cleared on exec(3).

	The first use of an instruction related to a dynamically enabled feature is
	trapped by the kernel. The trap handler checks whether the process has
	permission to use the feature. If the process has no permission then the
	kernel sends SIGILL to the application. If the process has permission then
	the handler allocates a larger xstate buffer for the task so the large
	state can be context switched. In the unlikely cases that the allocation
	fails, the kernel sends SIGSEGV.

	AMX TILE_DATA enabling example
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	Below is the example of how userspace applications enable
	TILE_DATA dynamically:

	1. The application first needs to query the kernel for AMX
	support::

	#include <asm/prctl.h>
	#include <sys/syscall.h>
	#include <stdio.h>
	#include <unistd.h>

	#ifndef ARCH_GET_XCOMP_SUPP
	#define ARCH_GET_XCOMP_SUPP 0x1021
	#endif

	#ifndef ARCH_XCOMP_TILECFG
	#define ARCH_XCOMP_TILECFG 17
	#endif

	#ifndef ARCH_XCOMP_TILEDATA
	#define ARCH_XCOMP_TILEDATA 18
	#endif

	#define MASK_XCOMP_TILE ((1 << ARCH_XCOMP_TILECFG) \| \
	(1 << ARCH_XCOMP_TILEDATA))

	unsigned long features;
	long rc;

	...

	rc = syscall(SYS_arch_prctl, ARCH_GET_XCOMP_SUPP, &features);

	if (!rc && (features & MASK_XCOMP_TILE) == MASK_XCOMP_TILE)
	printf("AMX is available.\n");

	2. After that, determining support for AMX, an application must
	explicitly ask permission to use it::

	#ifndef ARCH_REQ_XCOMP_PERM
	#define ARCH_REQ_XCOMP_PERM 0x1023
	#endif

	...

	rc = syscall(SYS_arch_prctl, ARCH_REQ_XCOMP_PERM, ARCH_XCOMP_TILEDATA);

	if (!rc)
	printf("AMX is ready for use.\n");

	Note this example does not include the sigaltstack preparation.

	Dynamic features in signal frames
	---------------------------------

	Dynamcally enabled features are not written to the signal frame upon signal
	entry if the feature is in its initial configuration. This differs from
	non-dynamic features which are always written regardless of their
	configuration. Signal handlers can examine the XSAVE buffer's XSTATE_BV
	field to determine if a features was written.

	Dynamic features for virtual machines
	-------------------------------------

	The permission for the guest state component needs to be managed separately
	from the host, as they are exclusive to each other. A coupled of options
	are extended to control the guest permission:

	-ARCH_GET_XCOMP_GUEST_PERM

	arch_prctl(ARCH_GET_XCOMP_GUEST_PERM, &features);

	ARCH_GET_XCOMP_GUEST_PERM is a variant of ARCH_GET_XCOMP_PERM. So it
	provides the same semantics and functionality but for the guest
	components.

	-ARCH_REQ_XCOMP_GUEST_PERM

	arch_prctl(ARCH_REQ_XCOMP_GUEST_PERM, feature_nr);

	ARCH_REQ_XCOMP_GUEST_PERM is a variant of ARCH_REQ_XCOMP_PERM. It has the
	same semantics for the guest permission. While providing a similar
	functionality, this comes with a constraint. Permission is frozen when the
	first VCPU is created. Any attempt to change permission after that point
	is going to be rejected. So, the permission has to be requested before the
	first VCPU creation.

	Note that some VMMs may have already established a set of supported state
	components. These options are not presumed to support any particular VMM.