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linux/arch/arm/vfp/vfpmodule.c
Ard Biesheuvel 293bb04938 ARM: 9446/1: Disallow kernel mode NEON when IRQs are disabled 
Commit

  c79f816311 ("ARM: 9283/1: permit non-nested kernel mode NEON in softirq context")

relaxed the rules around the use of SIMD instructions in kernel mode on
ARM, to allow such use when serving a softirq. To avoid having to
preserve/restore kernel mode NEON state when such a softirq is taken,
softirqs are now disabled when using the NEON from task context.

However, the fact that the softirq API does not allow unmasking of
softirqs with interrupts disabled was overlooked, resulting in a WARN()
in some cases, as reported by Guenter:

  WARNING: CPU: 0 PID: 1145 at kernel/softirq.c:369 __local_bh_enable_ip+0x118/0x194
  Call trace:
   unwind_backtrace from show_stack+0x10/0x14
   show_stack from dump_stack_lvl+0x7c/0xac
   dump_stack_lvl from __warn+0x7c/0x1b8
   __warn from warn_slowpath_fmt+0x19c/0x1a4
   warn_slowpath_fmt from __local_bh_enable_ip+0x118/0x194
   __local_bh_enable_ip from crc_t10dif_arch+0xd4/0xe8
   crc_t10dif_arch from crc_t10dif_wrapper+0x14/0x1c
   crc_t10dif_wrapper from crc_main_test+0x178/0x360
   crc_main_test from kunit_try_run_case+0x78/0x1e0
   kunit_try_run_case from kunit_generic_run_threadfn_adapter+0x1c/0x34
   kunit_generic_run_threadfn_adapter from kthread+0x118/0x254
   kthread from ret_from_fork+0x14/0x28

While disabling softirqs is not really needed when running with IRQs
disabled (given that the only way a softirq can be delivered
asynchrously is over the back of an IRQ), let's not complicate this
logic more than needed, and simply disallow use of the NEON in kernel
mode when IRQs are disabled.

Another approach might be to only disable and re-enable softirqs if IRQs
are enabled, but other than the test case above, there are no clear use
cases for doing non-trivial arithmetic processing (hence using an
accelerated SIMD implementation) with IRQs disabled.

Reported-by: Guenter Roeck <linux@roeck-us.net>
Tested-by: Guenter Roeck <linux@roeck-us.net>
Link: https://lore.kernel.org/all/389b899f-893c-4855-9e30-d8920a5d6f91@roeck-us.net
Reviewed-by: Eric Biggers <ebiggers@kernel.org>
Signed-off-by: Ard Biesheuvel <ardb@kernel.org>
Signed-off-by: Russell King (Oracle) <rmk+kernel@armlinux.org.uk>
2025-05-29 11:22:25 +01:00

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// SPDX-License-Identifier: GPL-2.0-only
/*
* linux/arch/arm/vfp/vfpmodule.c
*
* Copyright (C) 2004 ARM Limited.
* Written by Deep Blue Solutions Limited.
*/
#include <linux/types.h>
#include <linux/cpu.h>
#include <linux/cpu_pm.h>
#include <linux/hardirq.h>
#include <linux/kernel.h>
#include <linux/notifier.h>
#include <linux/signal.h>
#include <linux/sched/signal.h>
#include <linux/smp.h>
#include <linux/init.h>
#include <linux/uaccess.h>
#include <linux/user.h>
#include <linux/export.h>
#include <linux/perf_event.h>
#include <asm/cp15.h>
#include <asm/cputype.h>
#include <asm/system_info.h>
#include <asm/thread_notify.h>
#include <asm/traps.h>
#include <asm/vfp.h>
#include <asm/neon.h>
#include "vfpinstr.h"
#include "vfp.h"
static bool have_vfp __ro_after_init;
/*
* Dual-use variable.
* Used in startup: set to non-zero if VFP checks fail
* After startup, holds VFP architecture
*/
static unsigned int VFP_arch;
#ifdef CONFIG_CPU_FEROCEON
extern unsigned int VFP_arch_feroceon __alias(VFP_arch);
#endif
/*
* The pointer to the vfpstate structure of the thread which currently
* owns the context held in the VFP hardware, or NULL if the hardware
* context is invalid.
*
* For UP, this is sufficient to tell which thread owns the VFP context.
* However, for SMP, we also need to check the CPU number stored in the
* saved state too to catch migrations.
*/
union vfp_state *vfp_current_hw_state[NR_CPUS];
/*
* Claim ownership of the VFP unit.
*
* The caller may change VFP registers until vfp_state_release() is called.
*
* local_bh_disable() is used to disable preemption and to disable VFP
* processing in softirq context. On PREEMPT_RT kernels local_bh_disable() is
* not sufficient because it only serializes soft interrupt related sections
* via a local lock, but stays preemptible. Disabling preemption is the right
* choice here as bottom half processing is always in thread context on RT
* kernels so it implicitly prevents bottom half processing as well.
*/
static void vfp_state_hold(void)
{
if (!IS_ENABLED(CONFIG_PREEMPT_RT))
local_bh_disable();
else
preempt_disable();
}
static void vfp_state_release(void)
{
if (!IS_ENABLED(CONFIG_PREEMPT_RT))
local_bh_enable();
else
preempt_enable();
}
/*
* Is 'thread's most up to date state stored in this CPUs hardware?
* Must be called from non-preemptible context.
*/
static bool vfp_state_in_hw(unsigned int cpu, struct thread_info *thread)
{
#ifdef CONFIG_SMP
if (thread->vfpstate.hard.cpu != cpu)
return false;
#endif
return vfp_current_hw_state[cpu] == &thread->vfpstate;
}
/*
* Force a reload of the VFP context from the thread structure. We do
* this by ensuring that access to the VFP hardware is disabled, and
* clear vfp_current_hw_state. Must be called from non-preemptible context.
*/
static void vfp_force_reload(unsigned int cpu, struct thread_info *thread)
{
if (vfp_state_in_hw(cpu, thread)) {
fmxr(FPEXC, fmrx(FPEXC) & ~FPEXC_EN);
vfp_current_hw_state[cpu] = NULL;
}
#ifdef CONFIG_SMP
thread->vfpstate.hard.cpu = NR_CPUS;
#endif
}
/*
* Per-thread VFP initialization.
*/
static void vfp_thread_flush(struct thread_info *thread)
{
union vfp_state *vfp = &thread->vfpstate;
unsigned int cpu;
/*
* Disable VFP to ensure we initialize it first. We must ensure
* that the modification of vfp_current_hw_state[] and hardware
* disable are done for the same CPU and without preemption.
*
* Do this first to ensure that preemption won't overwrite our
* state saving should access to the VFP be enabled at this point.
*/
cpu = get_cpu();
if (vfp_current_hw_state[cpu] == vfp)
vfp_current_hw_state[cpu] = NULL;
fmxr(FPEXC, fmrx(FPEXC) & ~FPEXC_EN);
put_cpu();
memset(vfp, 0, sizeof(union vfp_state));
vfp->hard.fpexc = FPEXC_EN;
vfp->hard.fpscr = FPSCR_ROUND_NEAREST;
#ifdef CONFIG_SMP
vfp->hard.cpu = NR_CPUS;
#endif
}
static void vfp_thread_exit(struct thread_info *thread)
{
/* release case: Per-thread VFP cleanup. */
union vfp_state *vfp = &thread->vfpstate;
unsigned int cpu = get_cpu();
if (vfp_current_hw_state[cpu] == vfp)
vfp_current_hw_state[cpu] = NULL;
put_cpu();
}
static void vfp_thread_copy(struct thread_info *thread)
{
struct thread_info *parent = current_thread_info();
vfp_sync_hwstate(parent);
thread->vfpstate = parent->vfpstate;
#ifdef CONFIG_SMP
thread->vfpstate.hard.cpu = NR_CPUS;
#endif
}
/*
* When this function is called with the following 'cmd's, the following
* is true while this function is being run:
* THREAD_NOTIFY_SWITCH:
* - the previously running thread will not be scheduled onto another CPU.
* - the next thread to be run (v) will not be running on another CPU.
* - thread->cpu is the local CPU number
* - not preemptible as we're called in the middle of a thread switch
* THREAD_NOTIFY_FLUSH:
* - the thread (v) will be running on the local CPU, so
* v === current_thread_info()
* - thread->cpu is the local CPU number at the time it is accessed,
* but may change at any time.
* - we could be preempted if tree preempt rcu is enabled, so
* it is unsafe to use thread->cpu.
* THREAD_NOTIFY_EXIT
* - we could be preempted if tree preempt rcu is enabled, so
* it is unsafe to use thread->cpu.
*/
static int vfp_notifier(struct notifier_block *self, unsigned long cmd, void *v)
{
struct thread_info *thread = v;
u32 fpexc;
#ifdef CONFIG_SMP
unsigned int cpu;
#endif
switch (cmd) {
case THREAD_NOTIFY_SWITCH:
fpexc = fmrx(FPEXC);
#ifdef CONFIG_SMP
cpu = thread->cpu;
/*
* On SMP, if VFP is enabled, save the old state in
* case the thread migrates to a different CPU. The
* restoring is done lazily.
*/
if ((fpexc & FPEXC_EN) && vfp_current_hw_state[cpu])
vfp_save_state(vfp_current_hw_state[cpu], fpexc);
#endif
/*
* Always disable VFP so we can lazily save/restore the
* old state.
*/
fmxr(FPEXC, fpexc & ~FPEXC_EN);
break;
case THREAD_NOTIFY_FLUSH:
vfp_thread_flush(thread);
break;
case THREAD_NOTIFY_EXIT:
vfp_thread_exit(thread);
break;
case THREAD_NOTIFY_COPY:
vfp_thread_copy(thread);
break;
}
return NOTIFY_DONE;
}
static struct notifier_block vfp_notifier_block = {
.notifier_call = vfp_notifier,
};
/*
* Raise a SIGFPE for the current process.
* sicode describes the signal being raised.
*/
static void vfp_raise_sigfpe(unsigned int sicode, struct pt_regs *regs)
{
/*
* This is the same as NWFPE, because it's not clear what
* this is used for
*/
current->thread.error_code = 0;
current->thread.trap_no = 6;
send_sig_fault(SIGFPE, sicode,
(void __user *)(instruction_pointer(regs) - 4),
current);
}
static void vfp_panic(char *reason, u32 inst)
{
int i;
pr_err("VFP: Error: %s\n", reason);
pr_err("VFP: EXC 0x%08x SCR 0x%08x INST 0x%08x\n",
fmrx(FPEXC), fmrx(FPSCR), inst);
for (i = 0; i < 32; i += 2)
pr_err("VFP: s%2u: 0x%08x s%2u: 0x%08x\n",
i, vfp_get_float(i), i+1, vfp_get_float(i+1));
}
/*
* Process bitmask of exception conditions.
*/
static int vfp_raise_exceptions(u32 exceptions, u32 inst, u32 fpscr)
{
int si_code = 0;
pr_debug("VFP: raising exceptions %08x\n", exceptions);
if (exceptions == VFP_EXCEPTION_ERROR) {
vfp_panic("unhandled bounce", inst);
return FPE_FLTINV;
}
/*
* If any of the status flags are set, update the FPSCR.
* Comparison instructions always return at least one of
* these flags set.
*/
if (exceptions & (FPSCR_N|FPSCR_Z|FPSCR_C|FPSCR_V))
fpscr &= ~(FPSCR_N|FPSCR_Z|FPSCR_C|FPSCR_V);
fpscr |= exceptions;
fmxr(FPSCR, fpscr);
#define RAISE(stat,en,sig) \
if (exceptions & stat && fpscr & en) \
si_code = sig;
/*
* These are arranged in priority order, least to highest.
*/
RAISE(FPSCR_DZC, FPSCR_DZE, FPE_FLTDIV);
RAISE(FPSCR_IXC, FPSCR_IXE, FPE_FLTRES);
RAISE(FPSCR_UFC, FPSCR_UFE, FPE_FLTUND);
RAISE(FPSCR_OFC, FPSCR_OFE, FPE_FLTOVF);
RAISE(FPSCR_IOC, FPSCR_IOE, FPE_FLTINV);
return si_code;
}
/*
* Emulate a VFP instruction.
*/
static u32 vfp_emulate_instruction(u32 inst, u32 fpscr, struct pt_regs *regs)
{
u32 exceptions = VFP_EXCEPTION_ERROR;
pr_debug("VFP: emulate: INST=0x%08x SCR=0x%08x\n", inst, fpscr);
if (INST_CPRTDO(inst)) {
if (!INST_CPRT(inst)) {
/*
* CPDO
*/
if (vfp_single(inst)) {
exceptions = vfp_single_cpdo(inst, fpscr);
} else {
exceptions = vfp_double_cpdo(inst, fpscr);
}
} else {
/*
* A CPRT instruction can not appear in FPINST2, nor
* can it cause an exception. Therefore, we do not
* have to emulate it.
*/
}
} else {
/*
* A CPDT instruction can not appear in FPINST2, nor can
* it cause an exception. Therefore, we do not have to
* emulate it.
*/
}
perf_sw_event(PERF_COUNT_SW_EMULATION_FAULTS, 1, regs, regs->ARM_pc);
return exceptions & ~VFP_NAN_FLAG;
}
/*
* Package up a bounce condition.
*/
static void VFP_bounce(u32 trigger, u32 fpexc, struct pt_regs *regs)
{
u32 fpscr, orig_fpscr, fpsid, exceptions;
int si_code2 = 0;
int si_code = 0;
pr_debug("VFP: bounce: trigger %08x fpexc %08x\n", trigger, fpexc);
/*
* At this point, FPEXC can have the following configuration:
*
* EX DEX IXE
* 0 1 x - synchronous exception
* 1 x 0 - asynchronous exception
* 1 x 1 - sychronous on VFP subarch 1 and asynchronous on later
* 0 0 1 - synchronous on VFP9 (non-standard subarch 1
* implementation), undefined otherwise
*
* Clear various bits and enable access to the VFP so we can
* handle the bounce.
*/
fmxr(FPEXC, fpexc & ~(FPEXC_EX|FPEXC_DEX|FPEXC_FP2V|FPEXC_VV|FPEXC_TRAP_MASK));
fpsid = fmrx(FPSID);
orig_fpscr = fpscr = fmrx(FPSCR);
/*
* Check for the special VFP subarch 1 and FPSCR.IXE bit case
*/
if ((fpsid & FPSID_ARCH_MASK) == (1 << FPSID_ARCH_BIT)
&& (fpscr & FPSCR_IXE)) {
/*
* Synchronous exception, emulate the trigger instruction
*/
goto emulate;
}
if (fpexc & FPEXC_EX) {
/*
* Asynchronous exception. The instruction is read from FPINST
* and the interrupted instruction has to be restarted.
*/
trigger = fmrx(FPINST);
regs->ARM_pc -= 4;
} else if (!(fpexc & FPEXC_DEX)) {
/*
* Illegal combination of bits. It can be caused by an
* unallocated VFP instruction but with FPSCR.IXE set and not
* on VFP subarch 1.
*/
si_code = vfp_raise_exceptions(VFP_EXCEPTION_ERROR, trigger, fpscr);
goto exit;
}
/*
* Modify fpscr to indicate the number of iterations remaining.
* If FPEXC.EX is 0, FPEXC.DEX is 1 and the FPEXC.VV bit indicates
* whether FPEXC.VECITR or FPSCR.LEN is used.
*/
if (fpexc & (FPEXC_EX | FPEXC_VV)) {
u32 len;
len = fpexc + (1 << FPEXC_LENGTH_BIT);
fpscr &= ~FPSCR_LENGTH_MASK;
fpscr |= (len & FPEXC_LENGTH_MASK) << (FPSCR_LENGTH_BIT - FPEXC_LENGTH_BIT);
}
/*
* Handle the first FP instruction. We used to take note of the
* FPEXC bounce reason, but this appears to be unreliable.
* Emulate the bounced instruction instead.
*/
exceptions = vfp_emulate_instruction(trigger, fpscr, regs);
if (exceptions)
si_code2 = vfp_raise_exceptions(exceptions, trigger, orig_fpscr);
/*
* If there isn't a second FP instruction, exit now. Note that
* the FPEXC.FP2V bit is valid only if FPEXC.EX is 1.
*/
if ((fpexc & (FPEXC_EX | FPEXC_FP2V)) != (FPEXC_EX | FPEXC_FP2V))
goto exit;
/*
* The barrier() here prevents fpinst2 being read
* before the condition above.
*/
barrier();
trigger = fmrx(FPINST2);
emulate:
exceptions = vfp_emulate_instruction(trigger, orig_fpscr, regs);
if (exceptions)
si_code = vfp_raise_exceptions(exceptions, trigger, orig_fpscr);
exit:
vfp_state_release();
if (si_code2)
vfp_raise_sigfpe(si_code2, regs);
if (si_code)
vfp_raise_sigfpe(si_code, regs);
}
static void vfp_enable(void *unused)
{
u32 access;
BUG_ON(preemptible());
access = get_copro_access();
/*
* Enable full access to VFP (cp10 and cp11)
*/
set_copro_access(access | CPACC_FULL(10) | CPACC_FULL(11));
}
/* Called by platforms on which we want to disable VFP because it may not be
* present on all CPUs within a SMP complex. Needs to be called prior to
* vfp_init().
*/
void __init vfp_disable(void)
{
if (VFP_arch) {
pr_debug("%s: should be called prior to vfp_init\n", __func__);
return;
}
VFP_arch = 1;
}
#ifdef CONFIG_CPU_PM
static int vfp_pm_suspend(void)
{
struct thread_info *ti = current_thread_info();
u32 fpexc = fmrx(FPEXC);
/* if vfp is on, then save state for resumption */
if (fpexc & FPEXC_EN) {
pr_debug("%s: saving vfp state\n", __func__);
vfp_save_state(&ti->vfpstate, fpexc);
/* disable, just in case */
fmxr(FPEXC, fmrx(FPEXC) & ~FPEXC_EN);
} else if (vfp_current_hw_state[ti->cpu]) {
#ifndef CONFIG_SMP
fmxr(FPEXC, fpexc | FPEXC_EN);
vfp_save_state(vfp_current_hw_state[ti->cpu], fpexc);
fmxr(FPEXC, fpexc);
#endif
}
/* clear any information we had about last context state */
vfp_current_hw_state[ti->cpu] = NULL;
return 0;
}
static void vfp_pm_resume(void)
{
/* ensure we have access to the vfp */
vfp_enable(NULL);
/* and disable it to ensure the next usage restores the state */
fmxr(FPEXC, fmrx(FPEXC) & ~FPEXC_EN);
}
static int vfp_cpu_pm_notifier(struct notifier_block *self, unsigned long cmd,
void *v)
{
switch (cmd) {
case CPU_PM_ENTER:
vfp_pm_suspend();
break;
case CPU_PM_ENTER_FAILED:
case CPU_PM_EXIT:
vfp_pm_resume();
break;
}
return NOTIFY_OK;
}
static struct notifier_block vfp_cpu_pm_notifier_block = {
.notifier_call = vfp_cpu_pm_notifier,
};
static void vfp_pm_init(void)
{
cpu_pm_register_notifier(&vfp_cpu_pm_notifier_block);
}
#else
static inline void vfp_pm_init(void) { }
#endif /* CONFIG_CPU_PM */
/*
* Ensure that the VFP state stored in 'thread->vfpstate' is up to date
* with the hardware state.
*/
void vfp_sync_hwstate(struct thread_info *thread)
{
vfp_state_hold();
if (vfp_state_in_hw(raw_smp_processor_id(), thread)) {
u32 fpexc = fmrx(FPEXC);
/*
* Save the last VFP state on this CPU.
*/
fmxr(FPEXC, fpexc | FPEXC_EN);
vfp_save_state(&thread->vfpstate, fpexc | FPEXC_EN);
fmxr(FPEXC, fpexc);
}
vfp_state_release();
}
/* Ensure that the thread reloads the hardware VFP state on the next use. */
void vfp_flush_hwstate(struct thread_info *thread)
{
unsigned int cpu = get_cpu();
vfp_force_reload(cpu, thread);
put_cpu();
}
/*
* Save the current VFP state into the provided structures and prepare
* for entry into a new function (signal handler).
*/
int vfp_preserve_user_clear_hwstate(struct user_vfp *ufp,
struct user_vfp_exc *ufp_exc)
{
struct thread_info *thread = current_thread_info();
struct vfp_hard_struct *hwstate = &thread->vfpstate.hard;
/* Ensure that the saved hwstate is up-to-date. */
vfp_sync_hwstate(thread);
/*
* Copy the floating point registers. There can be unused
* registers see asm/hwcap.h for details.
*/
memcpy(&ufp->fpregs, &hwstate->fpregs, sizeof(hwstate->fpregs));
/*
* Copy the status and control register.
*/
ufp->fpscr = hwstate->fpscr;
/*
* Copy the exception registers.
*/
ufp_exc->fpexc = hwstate->fpexc;
ufp_exc->fpinst = hwstate->fpinst;
ufp_exc->fpinst2 = hwstate->fpinst2;
/* Ensure that VFP is disabled. */
vfp_flush_hwstate(thread);
/*
* As per the PCS, clear the length and stride bits for function
* entry.
*/
hwstate->fpscr &= ~(FPSCR_LENGTH_MASK | FPSCR_STRIDE_MASK);
return 0;
}
/* Sanitise and restore the current VFP state from the provided structures. */
int vfp_restore_user_hwstate(struct user_vfp *ufp, struct user_vfp_exc *ufp_exc)
{
struct thread_info *thread = current_thread_info();
struct vfp_hard_struct *hwstate = &thread->vfpstate.hard;
unsigned long fpexc;
/* Disable VFP to avoid corrupting the new thread state. */
vfp_flush_hwstate(thread);
/*
* Copy the floating point registers. There can be unused
* registers see asm/hwcap.h for details.
*/
memcpy(&hwstate->fpregs, &ufp->fpregs, sizeof(hwstate->fpregs));
/*
* Copy the status and control register.
*/
hwstate->fpscr = ufp->fpscr;
/*
* Sanitise and restore the exception registers.
*/
fpexc = ufp_exc->fpexc;
/* Ensure the VFP is enabled. */
fpexc |= FPEXC_EN;
/* Ensure FPINST2 is invalid and the exception flag is cleared. */
fpexc &= ~(FPEXC_EX | FPEXC_FP2V);
hwstate->fpexc = fpexc;
hwstate->fpinst = ufp_exc->fpinst;
hwstate->fpinst2 = ufp_exc->fpinst2;
return 0;
}
/*
* VFP hardware can lose all context when a CPU goes offline.
* As we will be running in SMP mode with CPU hotplug, we will save the
* hardware state at every thread switch. We clear our held state when
* a CPU has been killed, indicating that the VFP hardware doesn't contain
* a threads VFP state. When a CPU starts up, we re-enable access to the
* VFP hardware. The callbacks below are called on the CPU which
* is being offlined/onlined.
*/
static int vfp_dying_cpu(unsigned int cpu)
{
vfp_current_hw_state[cpu] = NULL;
return 0;
}
static int vfp_starting_cpu(unsigned int unused)
{
vfp_enable(NULL);
return 0;
}
static int vfp_kmode_exception(struct pt_regs *regs, unsigned int instr)
{
/*
* If we reach this point, a floating point exception has been raised
* while running in kernel mode. If the NEON/VFP unit was enabled at the
* time, it means a VFP instruction has been issued that requires
* software assistance to complete, something which is not currently
* supported in kernel mode.
* If the NEON/VFP unit was disabled, and the location pointed to below
* is properly preceded by a call to kernel_neon_begin(), something has
* caused the task to be scheduled out and back in again. In this case,
* rebuilding and running with CONFIG_DEBUG_ATOMIC_SLEEP enabled should
* be helpful in localizing the problem.
*/
if (fmrx(FPEXC) & FPEXC_EN)
pr_crit("BUG: unsupported FP instruction in kernel mode\n");
else
pr_crit("BUG: FP instruction issued in kernel mode with FP unit disabled\n");
pr_crit("FPEXC == 0x%08x\n", fmrx(FPEXC));
return 1;
}
/*
* vfp_support_entry - Handle VFP exception
*
* @regs: pt_regs structure holding the register state at exception entry
* @trigger: The opcode of the instruction that triggered the exception
*
* Returns 0 if the exception was handled, or an error code otherwise.
*/
static int vfp_support_entry(struct pt_regs *regs, u32 trigger)
{
struct thread_info *ti = current_thread_info();
u32 fpexc;
if (unlikely(!have_vfp))
return -ENODEV;
if (!user_mode(regs))
return vfp_kmode_exception(regs, trigger);
vfp_state_hold();
fpexc = fmrx(FPEXC);
/*
* If the VFP unit was not enabled yet, we have to check whether the
* VFP state in the CPU's registers is the most recent VFP state
* associated with the process. On UP systems, we don't save the VFP
* state eagerly on a context switch, so we may need to save the
* VFP state to memory first, as it may belong to another process.
*/
if (!(fpexc & FPEXC_EN)) {
/*
* Enable the VFP unit but mask the FP exception flag for the
* time being, so we can access all the registers.
*/
fpexc |= FPEXC_EN;
fmxr(FPEXC, fpexc & ~FPEXC_EX);
/*
* Check whether or not the VFP state in the CPU's registers is
* the most recent VFP state associated with this task. On SMP,
* migration may result in multiple CPUs holding VFP states
* that belong to the same task, but only the most recent one
* is valid.
*/
if (!vfp_state_in_hw(ti->cpu, ti)) {
if (!IS_ENABLED(CONFIG_SMP) &&
vfp_current_hw_state[ti->cpu] != NULL) {
/*
* This CPU is currently holding the most
* recent VFP state associated with another
* task, and we must save that to memory first.
*/
vfp_save_state(vfp_current_hw_state[ti->cpu],
fpexc);
}
/*
* We can now proceed with loading the task's VFP state
* from memory into the CPU registers.
*/
fpexc = vfp_load_state(&ti->vfpstate);
vfp_current_hw_state[ti->cpu] = &ti->vfpstate;
#ifdef CONFIG_SMP
/*
* Record that this CPU is now the one holding the most
* recent VFP state of the task.
*/
ti->vfpstate.hard.cpu = ti->cpu;
#endif
}
if (fpexc & FPEXC_EX)
/*
* Might as well handle the pending exception before
* retrying branch out before setting an FPEXC that
* stops us reading stuff.
*/
goto bounce;
/*
* No FP exception is pending: just enable the VFP and
* replay the instruction that trapped.
*/
fmxr(FPEXC, fpexc);
vfp_state_release();
} else {
/* Check for synchronous or asynchronous exceptions */
if (!(fpexc & (FPEXC_EX | FPEXC_DEX))) {
u32 fpscr = fmrx(FPSCR);
/*
* On some implementations of the VFP subarch 1,
* setting FPSCR.IXE causes all the CDP instructions to
* be bounced synchronously without setting the
* FPEXC.EX bit
*/
if (!(fpscr & FPSCR_IXE)) {
if (!(fpscr & FPSCR_LENGTH_MASK)) {
pr_debug("not VFP\n");
vfp_state_release();
return -ENOEXEC;
}
fpexc |= FPEXC_DEX;
}
}
bounce: regs->ARM_pc += 4;
/* VFP_bounce() will invoke vfp_state_release() */
VFP_bounce(trigger, fpexc, regs);
}
return 0;
}
static struct undef_hook neon_support_hook[] = {{
.instr_mask = 0xfe000000,
.instr_val = 0xf2000000,
.cpsr_mask = PSR_T_BIT,
.cpsr_val = 0,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xff100000,
.instr_val = 0xf4000000,
.cpsr_mask = PSR_T_BIT,
.cpsr_val = 0,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xef000000,
.instr_val = 0xef000000,
.cpsr_mask = PSR_T_BIT,
.cpsr_val = PSR_T_BIT,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xff100000,
.instr_val = 0xf9000000,
.cpsr_mask = PSR_T_BIT,
.cpsr_val = PSR_T_BIT,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xff000800,
.instr_val = 0xfc000800,
.cpsr_mask = 0,
.cpsr_val = 0,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xff000800,
.instr_val = 0xfd000800,
.cpsr_mask = 0,
.cpsr_val = 0,
.fn = vfp_support_entry,
}, {
.instr_mask = 0xff000800,
.instr_val = 0xfe000800,
.cpsr_mask = 0,
.cpsr_val = 0,
.fn = vfp_support_entry,
}};
static struct undef_hook vfp_support_hook = {
.instr_mask = 0x0c000e00,
.instr_val = 0x0c000a00,
.fn = vfp_support_entry,
};
#ifdef CONFIG_KERNEL_MODE_NEON
/*
* Kernel-side NEON support functions
*/
void kernel_neon_begin(void)
{
struct thread_info *thread = current_thread_info();
unsigned int cpu;
u32 fpexc;
vfp_state_hold();
/*
* Kernel mode NEON is only allowed outside of hardirq context with
* preemption and softirq processing disabled. This will make sure that
* the kernel mode NEON register contents never need to be preserved.
*/
BUG_ON(in_hardirq());
BUG_ON(irqs_disabled());
cpu = __smp_processor_id();
fpexc = fmrx(FPEXC) | FPEXC_EN;
fmxr(FPEXC, fpexc);
/*
* Save the userland NEON/VFP state. Under UP,
* the owner could be a task other than 'current'
*/
if (vfp_state_in_hw(cpu, thread))
vfp_save_state(&thread->vfpstate, fpexc);
#ifndef CONFIG_SMP
else if (vfp_current_hw_state[cpu] != NULL)
vfp_save_state(vfp_current_hw_state[cpu], fpexc);
#endif
vfp_current_hw_state[cpu] = NULL;
}
EXPORT_SYMBOL(kernel_neon_begin);
void kernel_neon_end(void)
{
/* Disable the NEON/VFP unit. */
fmxr(FPEXC, fmrx(FPEXC) & ~FPEXC_EN);
vfp_state_release();
}
EXPORT_SYMBOL(kernel_neon_end);
#endif /* CONFIG_KERNEL_MODE_NEON */
static int __init vfp_detect(struct pt_regs *regs, unsigned int instr)
{
VFP_arch = UINT_MAX; /* mark as not present */
regs->ARM_pc += 4;
return 0;
}
static struct undef_hook vfp_detect_hook __initdata = {
.instr_mask = 0x0c000e00,
.instr_val = 0x0c000a00,
.cpsr_mask = MODE_MASK,
.cpsr_val = SVC_MODE,
.fn = vfp_detect,
};
/*
* VFP support code initialisation.
*/
static int __init vfp_init(void)
{
unsigned int vfpsid;
unsigned int cpu_arch = cpu_architecture();
unsigned int isar6;
/*
* Enable the access to the VFP on all online CPUs so the
* following test on FPSID will succeed.
*/
if (cpu_arch >= CPU_ARCH_ARMv6)
on_each_cpu(vfp_enable, NULL, 1);
/*
* First check that there is a VFP that we can use.
* The handler is already setup to just log calls, so
* we just need to read the VFPSID register.
*/
register_undef_hook(&vfp_detect_hook);
barrier();
vfpsid = fmrx(FPSID);
barrier();
unregister_undef_hook(&vfp_detect_hook);
pr_info("VFP support v0.3: ");
if (VFP_arch) {
pr_cont("not present\n");
return 0;
/* Extract the architecture on CPUID scheme */
} else if ((read_cpuid_id() & 0x000f0000) == 0x000f0000) {
VFP_arch = vfpsid & FPSID_CPUID_ARCH_MASK;
VFP_arch >>= FPSID_ARCH_BIT;
/*
* Check for the presence of the Advanced SIMD
* load/store instructions, integer and single
* precision floating point operations. Only check
* for NEON if the hardware has the MVFR registers.
*/
if (IS_ENABLED(CONFIG_NEON) &&
(fmrx(MVFR1) & 0x000fff00) == 0x00011100) {
elf_hwcap |= HWCAP_NEON;
for (int i = 0; i < ARRAY_SIZE(neon_support_hook); i++)
register_undef_hook(&neon_support_hook[i]);
}
if (IS_ENABLED(CONFIG_VFPv3)) {
u32 mvfr0 = fmrx(MVFR0);
if (((mvfr0 & MVFR0_DP_MASK) >> MVFR0_DP_BIT) == 0x2 ||
((mvfr0 & MVFR0_SP_MASK) >> MVFR0_SP_BIT) == 0x2) {
elf_hwcap |= HWCAP_VFPv3;
/*
* Check for VFPv3 D16 and VFPv4 D16. CPUs in
* this configuration only have 16 x 64bit
* registers.
*/
if ((mvfr0 & MVFR0_A_SIMD_MASK) == 1)
/* also v4-D16 */
elf_hwcap |= HWCAP_VFPv3D16;
else
elf_hwcap |= HWCAP_VFPD32;
}
if ((fmrx(MVFR1) & 0xf0000000) == 0x10000000)
elf_hwcap |= HWCAP_VFPv4;
if (((fmrx(MVFR1) & MVFR1_ASIMDHP_MASK) >> MVFR1_ASIMDHP_BIT) == 0x2)
elf_hwcap |= HWCAP_ASIMDHP;
if (((fmrx(MVFR1) & MVFR1_FPHP_MASK) >> MVFR1_FPHP_BIT) == 0x3)
elf_hwcap |= HWCAP_FPHP;
}
/*
* Check for the presence of Advanced SIMD Dot Product
* instructions.
*/
isar6 = read_cpuid_ext(CPUID_EXT_ISAR6);
if (cpuid_feature_extract_field(isar6, 4) == 0x1)
elf_hwcap |= HWCAP_ASIMDDP;
/*
* Check for the presence of Advanced SIMD Floating point
* half-precision multiplication instructions.
*/
if (cpuid_feature_extract_field(isar6, 8) == 0x1)
elf_hwcap |= HWCAP_ASIMDFHM;
/*
* Check for the presence of Advanced SIMD Bfloat16
* floating point instructions.
*/
if (cpuid_feature_extract_field(isar6, 20) == 0x1)
elf_hwcap |= HWCAP_ASIMDBF16;
/*
* Check for the presence of Advanced SIMD and floating point
* Int8 matrix multiplication instructions instructions.
*/
if (cpuid_feature_extract_field(isar6, 24) == 0x1)
elf_hwcap |= HWCAP_I8MM;
/* Extract the architecture version on pre-cpuid scheme */
} else {
if (vfpsid & FPSID_NODOUBLE) {
pr_cont("no double precision support\n");
return 0;
}
VFP_arch = (vfpsid & FPSID_ARCH_MASK) >> FPSID_ARCH_BIT;
}
cpuhp_setup_state_nocalls(CPUHP_AP_ARM_VFP_STARTING,
"arm/vfp:starting", vfp_starting_cpu,
vfp_dying_cpu);
have_vfp = true;
register_undef_hook(&vfp_support_hook);
thread_register_notifier(&vfp_notifier_block);
vfp_pm_init();
/*
* We detected VFP, and the support code is
* in place; report VFP support to userspace.
*/
elf_hwcap |= HWCAP_VFP;
pr_cont("implementor %02x architecture %d part %02x variant %x rev %x\n",
(vfpsid & FPSID_IMPLEMENTER_MASK) >> FPSID_IMPLEMENTER_BIT,
VFP_arch,
(vfpsid & FPSID_PART_MASK) >> FPSID_PART_BIT,
(vfpsid & FPSID_VARIANT_MASK) >> FPSID_VARIANT_BIT,
(vfpsid & FPSID_REV_MASK) >> FPSID_REV_BIT);
return 0;
}
core_initcall(vfp_init);
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