Commit c9b012e5 authored by Linus Torvalds's avatar Linus Torvalds
Browse files

Merge tag 'arm64-upstream' of git://

Pull arm64 updates from Will Deacon:
 "The big highlight is support for the Scalable Vector Extension (SVE)
  which required extensive ABI work to ensure we don't break existing
  applications by blowing away their signal stack with the rather large
  new vector context (<= 2 kbit per vector register). There's further
  work to be done optimising things like exception return, but the ABI
  is solid now.

  Much of the line count comes from some new PMU drivers we have, but
  they're pretty self-contained and I suspect we'll have more of them in

  Plenty of acronym soup here:

   - initial support for the Scalable Vector Extension (SVE)

   - improved handling for SError interrupts (required to handle RAS

   - enable GCC support for 128-bit integer types

   - remove kernel text addresses from backtraces and register dumps

   - use of WFE to implement long delay()s

   - ACPI IORT updates from Lorenzo Pieralisi

   - perf PMU driver for the Statistical Profiling Extension (SPE)

   - perf PMU driver for Hisilicon's system PMUs

   - misc cleanups and non-critical fixes"

* tag 'arm64-upstream' of git:// (97 commits)
  arm64: Make ARMV8_DEPRECATED depend on SYSCTL
  arm64: Implement __lshrti3 library function
  arm64: support __int128 on gcc 5+
  arm64/sve: Add documentation
  arm64/sve: Detect SVE and activate runtime support
  arm64/sve: KVM: Hide SVE from CPU features exposed to guests
  arm64/sve: KVM: Treat guest SVE use as undefined instruction execution
  arm64/sve: KVM: Prevent guests from using SVE
  arm64/sve: Add sysctl to set the default vector length for new processes
  arm64/sve: Add prctl controls for userspace vector length management
  arm64/sve: ptrace and ELF coredump support
  arm64/sve: Preserve SVE registers around EFI runtime service calls
  arm64/sve: Preserve SVE registers around kernel-mode NEON use
  arm64/sve: Probe SVE capabilities and usable vector lengths
  arm64: cpufeature: Move sys_caps_initialised declarations
  arm64/sve: Backend logic for setting the vector length
  arm64/sve: Signal handling support
  arm64/sve: Support vector length resetting for new processes
  arm64/sve: Core task context handling
  arm64/sve: Low-level CPU setup
parents b293fca4 6cfa7cc4
......@@ -110,10 +110,20 @@ infrastructure:
| Name | bits | visible |
| RES0 | [63-32] | n |
| RES0 | [63-48] | n |
| DP | [47-44] | y |
| SM4 | [43-40] | y |
| SM3 | [39-36] | y |
| SHA3 | [35-32] | y |
| RDM | [31-28] | y |
| RES0 | [27-24] | n |
| ATOMICS | [23-20] | y |
| CRC32 | [19-16] | y |
......@@ -132,7 +142,11 @@ infrastructure:
| Name | bits | visible |
| RES0 | [63-28] | n |
| RES0 | [63-36] | n |
| SVE | [35-32] | y |
| RES0 | [31-28] | n |
| GIC | [27-24] | n |
ARM64 ELF hwcaps
This document describes the usage and semantics of the arm64 ELF hwcaps.
1. Introduction
Some hardware or software features are only available on some CPU
implementations, and/or with certain kernel configurations, but have no
architected discovery mechanism available to userspace code at EL0. The
kernel exposes the presence of these features to userspace through a set
of flags called hwcaps, exposed in the auxilliary vector.
Userspace software can test for features by acquiring the AT_HWCAP entry
of the auxilliary vector, and testing whether the relevant flags are
set, e.g.
bool floating_point_is_present(void)
unsigned long hwcaps = getauxval(AT_HWCAP);
if (hwcaps & HWCAP_FP)
return true;
return false;
Where software relies on a feature described by a hwcap, it should check
the relevant hwcap flag to verify that the feature is present before
attempting to make use of the feature.
Features cannot be probed reliably through other means. When a feature
is not available, attempting to use it may result in unpredictable
behaviour, and is not guaranteed to result in any reliable indication
that the feature is unavailable, such as a SIGILL.
2. Interpretation of hwcaps
The majority of hwcaps are intended to indicate the presence of features
which are described by architected ID registers inaccessible to
userspace code at EL0. These hwcaps are defined in terms of ID register
fields, and should be interpreted with reference to the definition of
these fields in the ARM Architecture Reference Manual (ARM ARM).
Such hwcaps are described below in the form:
Functionality implied by idreg.field == val.
Such hwcaps indicate the availability of functionality that the ARM ARM
defines as being present when idreg.field has value val, but do not
indicate that idreg.field is precisely equal to val, nor do they
indicate the absence of functionality implied by other values of
Other hwcaps may indicate the presence of features which cannot be
described by ID registers alone. These may be described without
reference to ID registers, and may refer to other documentation.
3. The hwcaps exposed in AT_HWCAP
Functionality implied by ID_AA64PFR0_EL1.FP == 0b0000.
Functionality implied by ID_AA64PFR0_EL1.AdvSIMD == 0b0000.
The generic timer is configured to generate events at a frequency of
approximately 100KHz.
Functionality implied by ID_AA64ISAR1_EL1.AES == 0b0001.
Functionality implied by ID_AA64ISAR1_EL1.AES == 0b0010.
Functionality implied by ID_AA64ISAR0_EL1.SHA1 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.SHA2 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.CRC32 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.Atomic == 0b0010.
Functionality implied by ID_AA64PFR0_EL1.FP == 0b0001.
Functionality implied by ID_AA64PFR0_EL1.AdvSIMD == 0b0001.
EL0 access to certain ID registers is available, to the extent
described by Documentation/arm64/cpu-feature-registers.txt.
These ID registers may imply the availability of features.
Functionality implied by ID_AA64ISAR0_EL1.RDM == 0b0001.
Functionality implied by ID_AA64ISAR1_EL1.JSCVT == 0b0001.
Functionality implied by ID_AA64ISAR1_EL1.FCMA == 0b0001.
Functionality implied by ID_AA64ISAR1_EL1.LRCPC == 0b0001.
Functionality implied by ID_AA64ISAR1_EL1.DPB == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.SHA3 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.SM3 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.SM4 == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.DP == 0b0001.
Functionality implied by ID_AA64ISAR0_EL1.SHA2 == 0b0002.
Functionality implied by ID_AA64PFR0_EL1.SVE == 0b0001.
......@@ -86,9 +86,9 @@ Translation table lookup with 64KB pages:
+-------------------------------------------------> [63] TTBR0/1
When using KVM, the hypervisor maps kernel pages in EL2, at a fixed
offset from the kernel VA (top 24bits of the kernel VA set to zero):
When using KVM without the Virtualization Host Extensions, the hypervisor
maps kernel pages in EL2 at a fixed offset from the kernel VA. See the
kern_hyp_va macro for more details.
Start End Size Use
0000004000000000 0000007fffffffff 256GB kernel objects mapped in HYP
When using KVM with the Virtualization Host Extensions, no additional
mappings are created, since the host kernel runs directly in EL2.
Scalable Vector Extension support for AArch64 Linux
Author: Dave Martin <>
Date: 4 August 2017
This document outlines briefly the interface provided to userspace by Linux in
order to support use of the ARM Scalable Vector Extension (SVE).
This is an outline of the most important features and issues only and not
intended to be exhaustive.
This document does not aim to describe the SVE architecture or programmer's
model. To aid understanding, a minimal description of relevant programmer's
model features for SVE is included in Appendix A.
1. General
* SVE registers Z0..Z31, P0..P15 and FFR and the current vector length VL, are
tracked per-thread.
* The presence of SVE is reported to userspace via HWCAP_SVE in the aux vector
AT_HWCAP entry. Presence of this flag implies the presence of the SVE
instructions and registers, and the Linux-specific system interfaces
described in this document. SVE is reported in /proc/cpuinfo as "sve".
* Support for the execution of SVE instructions in userspace can also be
detected by reading the CPU ID register ID_AA64PFR0_EL1 using an MRS
instruction, and checking that the value of the SVE field is nonzero. [3]
It does not guarantee the presence of the system interfaces described in the
following sections: software that needs to verify that those interfaces are
present must check for HWCAP_SVE instead.
* Debuggers should restrict themselves to interacting with the target via the
NT_ARM_SVE regset. The recommended way of detecting support for this regset
is to connect to a target process first and then attempt a
ptrace(PTRACE_GETREGSET, pid, NT_ARM_SVE, &iov).
2. Vector length terminology
The size of an SVE vector (Z) register is referred to as the "vector length".
To avoid confusion about the units used to express vector length, the kernel
adopts the following conventions:
* Vector length (VL) = size of a Z-register in bytes
* Vector quadwords (VQ) = size of a Z-register in units of 128 bits
(So, VL = 16 * VQ.)
The VQ convention is used where the underlying granularity is important, such
as in data structure definitions. In most other situations, the VL convention
is used. This is consistent with the meaning of the "VL" pseudo-register in
the SVE instruction set architecture.
3. System call behaviour
* On syscall, V0..V31 are preserved (as without SVE). Thus, bits [127:0] of
Z0..Z31 are preserved. All other bits of Z0..Z31, and all of P0..P15 and FFR
become unspecified on return from a syscall.
* The SVE registers are not used to pass arguments to or receive results from
any syscall.
* In practice the affected registers/bits will be preserved or will be replaced
with zeros on return from a syscall, but userspace should not make
assumptions about this. The kernel behaviour may vary on a case-by-case
* All other SVE state of a thread, including the currently configured vector
length, the state of the PR_SVE_VL_INHERIT flag, and the deferred vector
length (if any), is preserved across all syscalls, subject to the specific
exceptions for execve() described in section 6.
In particular, on return from a fork() or clone(), the parent and new child
process or thread share identical SVE configuration, matching that of the
parent before the call.
4. Signal handling
* A new signal frame record sve_context encodes the SVE registers on signal
delivery. [1]
* This record is supplementary to fpsimd_context. The FPSR and FPCR registers
are only present in fpsimd_context. For convenience, the content of V0..V31
is duplicated between sve_context and fpsimd_context.
* The signal frame record for SVE always contains basic metadata, in particular
the thread's vector length (in sve_context.vl).
* The SVE registers may or may not be included in the record, depending on
whether the registers are live for the thread. The registers are present if
and only if:
sve_context.head.size >= SVE_SIG_CONTEXT_SIZE(sve_vq_from_vl(sve_context.vl)).
* If the registers are present, the remainder of the record has a vl-dependent
size and layout. Macros SVE_SIG_* are defined [1] to facilitate access to
the members.
* If the SVE context is too big to fit in sigcontext.__reserved[], then extra
space is allocated on the stack, an extra_context record is written in
__reserved[] referencing this space. sve_context is then written in the
extra space. Refer to [1] for further details about this mechanism.
5. Signal return
When returning from a signal handler:
* If there is no sve_context record in the signal frame, or if the record is
present but contains no register data as desribed in the previous section,
then the SVE registers/bits become non-live and take unspecified values.
* If sve_context is present in the signal frame and contains full register
data, the SVE registers become live and are populated with the specified
data. However, for backward compatibility reasons, bits [127:0] of Z0..Z31
are always restored from the corresponding members of fpsimd_context.vregs[]
and not from sve_context. The remaining bits are restored from sve_context.
* Inclusion of fpsimd_context in the signal frame remains mandatory,
irrespective of whether sve_context is present or not.
* The vector length cannot be changed via signal return. If sve_context.vl in
the signal frame does not match the current vector length, the signal return
attempt is treated as illegal, resulting in a forced SIGSEGV.
6. prctl extensions
Some new prctl() calls are added to allow programs to manage the SVE vector
prctl(PR_SVE_SET_VL, unsigned long arg)
Sets the vector length of the calling thread and related flags, where
arg == vl | flags. Other threads of the calling process are unaffected.
vl is the desired vector length, where sve_vl_valid(vl) must be true.
Inherit the current vector length across execve(). Otherwise, the
vector length is reset to the system default at execve(). (See
Section 9.)
Defer the requested vector length change until the next execve()
performed by this thread.
The effect is equivalent to implicit exceution of the following
call immediately after the next execve() (if any) by the thread:
This allows launching of a new program with a different vector
length, while avoiding runtime side effects in the caller.
Without PR_SVE_SET_VL_ONEXEC, the requested change takes effect
Return value: a nonnegative on success, or a negative value on error:
EINVAL: SVE not supported, invalid vector length requested, or
invalid flags.
On success:
* Either the calling thread's vector length or the deferred vector length
to be applied at the next execve() by the thread (dependent on whether
PR_SVE_SET_VL_ONEXEC is present in arg), is set to the largest value
supported by the system that is less than or equal to vl. If vl ==
SVE_VL_MAX, the value set will be the largest value supported by the
* Any previously outstanding deferred vector length change in the calling
thread is cancelled.
* The returned value describes the resulting configuration, encoded as for
PR_SVE_GET_VL. The vector length reported in this value is the new
current vector length for this thread if PR_SVE_SET_VL_ONEXEC was not
present in arg; otherwise, the reported vector length is the deferred
vector length that will be applied at the next execve() by the calling
* Changing the vector length causes all of P0..P15, FFR and all bits of
Z0..V31 except for Z0 bits [127:0] .. Z31 bits [127:0] to become
unspecified. Calling PR_SVE_SET_VL with vl equal to the thread's current
vector length, or calling PR_SVE_SET_VL with the PR_SVE_SET_VL_ONEXEC
flag, does not constitute a change to the vector length for this purpose.
Gets the vector length of the calling thread.
The following flag may be OR-ed into the result:
Vector length will be inherited across execve().
There is no way to determine whether there is an outstanding deferred
vector length change (which would only normally be the case between a
fork() or vfork() and the corresponding execve() in typical use).
To extract the vector length from the result, and it with
Return value: a nonnegative value on success, or a negative value on error:
EINVAL: SVE not supported.
7. ptrace extensions
* A new regset NT_ARM_SVE is defined for use with PTRACE_GETREGSET and
Refer to [2] for definitions.
The regset data starts with struct user_sve_header, containing:
Size of the complete regset, in bytes.
This depends on vl and possibly on other things in the future.
If a call to PTRACE_GETREGSET requests less data than the value of
size, the caller can allocate a larger buffer and retry in order to
read the complete regset.
Maximum size in bytes that the regset can grow to for the target
thread. The regset won't grow bigger than this even if the target
thread changes its vector length etc.
Target thread's current vector length, in bytes.
Maximum possible vector length for the target thread.
SVE registers are not live (GETREGSET) or are to be made
non-live (SETREGSET).
The payload is of type struct user_fpsimd_state, with the same
meaning as for NT_PRFPREG, starting at offset
SVE_PT_FPSIMD_OFFSET from the start of user_sve_header.
Extra data might be appended in the future: the size of the
payload should be obtained using SVE_PT_FPSIMD_SIZE(vq, flags).
vq should be obtained using sve_vq_from_vl(vl).
SVE registers are live (GETREGSET) or are to be made live
The payload contains the SVE register data, starting at offset
SVE_PT_SVE_OFFSET from the start of user_sve_header, and with
size SVE_PT_SVE_SIZE(vq, flags);
... OR-ed with zero or more of the following flags, which have the same
meaning and behaviour as the corresponding PR_SET_VL_* flags:
* The effects of changing the vector length and/or flags are equivalent to
those documented for PR_SVE_SET_VL.
The caller must make a further GETREGSET call if it needs to know what VL is
actually set by SETREGSET, unless is it known in advance that the requested
VL is supported.
* In the SVE_PT_REGS_SVE case, the size and layout of the payload depends on
the header fields. The SVE_PT_SVE_*() macros are provided to facilitate
access to the members.
* In either case, for SETREGSET it is permissible to omit the payload, in which
case only the vector length and flags are changed (along with any
consequences of those changes).
* For SETREGSET, if an SVE_PT_REGS_SVE payload is present and the
requested VL is not supported, the effect will be the same as if the
payload were omitted, except that an EIO error is reported. No
attempt is made to translate the payload data to the correct layout
for the vector length actually set. The thread's FPSIMD state is
preserved, but the remaining bits of the SVE registers become
unspecified. It is up to the caller to translate the payload layout
for the actual VL and retry.
* The effect of writing a partial, incomplete payload is unspecified.
8. ELF coredump extensions
* A NT_ARM_SVE note will be added to each coredump for each thread of the
dumped process. The contents will be equivalent to the data that would have
been read if a PTRACE_GETREGSET of NT_ARM_SVE were executed for each thread
when the coredump was generated.
9. System runtime configuration
* To mitigate the ABI impact of expansion of the signal frame, a policy
mechanism is provided for administrators, distro maintainers and developers
to set the default vector length for userspace processes:
Writing the text representation of an integer to this file sets the system
default vector length to the specified value, unless the value is greater
than the maximum vector length supported by the system in which case the
default vector length is set to that maximum.
The result can be determined by reopening the file and reading its
At boot, the default vector length is initially set to 64 or the maximum
supported vector length, whichever is smaller. This determines the initial
vector length of the init process (PID 1).
Reading this file returns the current system default vector length.
* At every execve() call, the new vector length of the new process is set to
the system default vector length, unless
* PR_SVE_SET_VL_INHERIT (or equivalently SVE_PT_VL_INHERIT) is set for the
calling thread, or
* a deferred vector length change is pending, established via the
* Modifying the system default vector length does not affect the vector length
of any existing process or thread that does not make an execve() call.
Appendix A. SVE programmer's model (informative)
This section provides a minimal description of the additions made by SVE to the
ARMv8-A programmer's model that are relevant to this document.
Note: This section is for information only and not intended to be complete or
to replace any architectural specification.
A.1. Registers
In A64 state, SVE adds the following:
* 32 8VL-bit vector registers Z0..Z31
For each Zn, Zn bits [127:0] alias the ARMv8-A vector register Vn.
A register write using a Vn register name zeros all bits of the corresponding
Zn except for bits [127:0].
* 16 VL-bit predicate registers P0..P15
* 1 VL-bit special-purpose predicate register FFR (the "first-fault register")
* a VL "pseudo-register" that determines the size of each vector register
The SVE instruction set architecture provides no way to write VL directly.
Instead, it can be modified only by EL1 and above, by writing appropriate
system registers.
* The value of VL can be configured at runtime by EL1 and above:
16 <= VL <= VLmax, where VL must be a multiple of 16.
* The maximum vector length is determined by the hardware:
16 <= VLmax <= 256.
(The SVE architecture specifies 256, but permits future architecture
revisions to raise this limit.)
* FPSR and FPCR are retained from ARMv8-A, and interact with SVE floating-point
operations in a similar way to the way in which they interact with ARMv8
floating-point operations.
8VL-1 128 0 bit index
+---- //// -----------------+
Z0 | : V0 |
: :
Z7 | : V7 |
Z8 | : * V8 |
: : :
Z15 | : *V15 |
Z16 | : V16 |
: :
Z31 | : V31 |
+---- //// -----------------+
31 0
VL-1 0 +-------+
+---- //// --+ FPSR | |
P0 | | +-------+