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// SPDX-License-Identifier: GPL-2.0-only
// Copyright (C) 2015-2019 ARM Limited.
// Original author: Dave Martin <Dave.Martin@arm.com>
//
// Simple Scalable Vector Extension context switch test
// Repeatedly writes unique test patterns into each SVE register
// and reads them back to verify integrity.
//
// for x in `seq 1 NR_CPUS`; do sve-test & pids=$pids\ $! ; done
// (leave it running for as long as you want...)
// kill $pids
#include <asm/unistd.h>
#include "assembler.h"
#include "asm-offsets.h"
#include "sme-inst.h"
#define NZR 32
#define NPR 16
#define MAXVL_B (2048 / 8)
.arch_extension sve
.macro _sve_ldr_v zt, xn
ldr z\zt, [x\xn]
.endm
.macro _sve_str_v zt, xn
str z\zt, [x\xn]
.endm
.macro _sve_ldr_p pt, xn
ldr p\pt, [x\xn]
.endm
.macro _sve_str_p pt, xn
str p\pt, [x\xn]
.endm
// Generate accessor functions to read/write programmatically selected
// SVE registers.
// x0 is the register index to access
// x1 is the memory address to read from (getz,setp) or store to (setz,setp)
// All clobber x0-x2
define_accessor setz, NZR, _sve_ldr_v
define_accessor getz, NZR, _sve_str_v
define_accessor setp, NPR, _sve_ldr_p
define_accessor getp, NPR, _sve_str_p
// Declare some storate space to shadow the SVE register contents:
.pushsection .text
.data
.align 4
zref:
.space MAXVL_B * NZR
pref:
.space MAXVL_B / 8 * NPR
ffrref:
.space MAXVL_B / 8
scratch:
.space MAXVL_B
.popsection
// Generate a test pattern for storage in SVE registers
// x0: pid (16 bits)
// x1: register number (6 bits)
// x2: generation (4 bits)
// These values are used to constuct a 32-bit pattern that is repeated in the
// scratch buffer as many times as will fit:
// bits 31:28 generation number (increments once per test_loop)
// bits 27:22 32-bit lane index
// bits 21:16 register number
// bits 15: 0 pid
function pattern
orr w1, w0, w1, lsl #16
orr w2, w1, w2, lsl #28
ldr x0, =scratch
mov w1, #MAXVL_B / 4
0: str w2, [x0], #4
add w2, w2, #(1 << 22)
subs w1, w1, #1
bne 0b
ret
endfunction
// Get the address of shadow data for SVE Z-register Z<xn>
.macro _adrz xd, xn, nrtmp
ldr \xd, =zref
rdvl x\nrtmp, #1
madd \xd, x\nrtmp, \xn, \xd
.endm
// Get the address of shadow data for SVE P-register P<xn - NZR>
.macro _adrp xd, xn, nrtmp
ldr \xd, =pref
rdvl x\nrtmp, #1
lsr x\nrtmp, x\nrtmp, #3
sub \xn, \xn, #NZR
madd \xd, x\nrtmp, \xn, \xd
.endm
// Set up test pattern in a SVE Z-register
// x0: pid
// x1: register number
// x2: generation
function setup_zreg
mov x4, x30
mov x6, x1
bl pattern
_adrz x0, x6, 2
mov x5, x0
ldr x1, =scratch
bl memcpy
mov x0, x6
mov x1, x5
bl setz
ret x4
endfunction
// Set up test pattern in a SVE P-register
// x0: pid
// x1: register number
// x2: generation
function setup_preg
mov x4, x30
mov x6, x1
bl pattern
_adrp x0, x6, 2
mov x5, x0
ldr x1, =scratch
bl memcpy
mov x0, x6
mov x1, x5
bl setp
ret x4
endfunction
// Set up test pattern in the FFR
// x0: pid
// x2: generation
//
// We need to generate a canonical FFR value, which consists of a number of
// low "1" bits, followed by a number of zeros. This gives us 17 unique values
// per 16 bits of FFR, so we create a 4 bit signature out of the PID and
// generation, and use that as the initial number of ones in the pattern.
// We fill the upper lanes of FFR with zeros.
// Beware: corrupts P0.
function setup_ffr
#ifndef SSVE
mov x4, x30
and w0, w0, #0x3
bfi w0, w2, #2, #2
mov w1, #1
lsl w1, w1, w0
sub w1, w1, #1
ldr x0, =ffrref
strh w1, [x0], 2
rdvl x1, #1
lsr x1, x1, #3
sub x1, x1, #2
bl memclr
mov x0, #0
ldr x1, =ffrref
bl setp
wrffr p0.b
ret x4
#else
ret
#endif
endfunction
// Trivial memory compare: compare x2 bytes starting at address x0 with
// bytes starting at address x1.
// Returns only if all bytes match; otherwise, the program is aborted.
// Clobbers x0-x5.
function memcmp
cbz x2, 2f
stp x0, x1, [sp, #-0x20]!
str x2, [sp, #0x10]
mov x5, #0
0: ldrb w3, [x0, x5]
ldrb w4, [x1, x5]
add x5, x5, #1
cmp w3, w4
b.ne 1f
subs x2, x2, #1
b.ne 0b
1: ldr x2, [sp, #0x10]
ldp x0, x1, [sp], #0x20
b.ne barf
2: ret
endfunction
// Verify that a SVE Z-register matches its shadow in memory, else abort
// x0: reg number
// Clobbers x0-x7.
function check_zreg
mov x3, x30
_adrz x5, x0, 6
mov x4, x0
ldr x7, =scratch
mov x0, x7
mov x1, x6
bl memfill_ae
mov x0, x4
mov x1, x7
bl getz
mov x0, x5
mov x1, x7
mov x2, x6
mov x30, x3
b memcmp
endfunction
// Verify that a SVE P-register matches its shadow in memory, else abort
// x0: reg number
// Clobbers x0-x7.
function check_preg
mov x3, x30
_adrp x5, x0, 6
mov x4, x0
ldr x7, =scratch
mov x0, x7
mov x1, x6
bl memfill_ae
mov x0, x4
mov x1, x7
bl getp
mov x0, x5
mov x1, x7
mov x2, x6
mov x30, x3
b memcmp
endfunction
// Verify that the FFR matches its shadow in memory, else abort
// Beware -- corrupts P0.
// Clobbers x0-x5.
function check_ffr
#ifndef SSVE
mov x3, x30
ldr x4, =scratch
rdvl x5, #1
lsr x5, x5, #3
mov x0, x4
mov x1, x5
bl memfill_ae
rdffr p0.b
mov x0, #0
mov x1, x4
bl getp
ldr x0, =ffrref
mov x1, x4
mov x2, x5
mov x30, x3
b memcmp
#else
ret
#endif
endfunction
// Any SVE register modified here can cause corruption in the main
// thread -- but *only* the registers modified here.
function irritator_handler
// Increment the irritation signal count (x23):
ldr x0, [x2, #ucontext_regs + 8 * 23]
add x0, x0, #1
str x0, [x2, #ucontext_regs + 8 * 23]
// Corrupt some random Z-regs
adr x0, .text + (irritator_handler - .text) / 16 * 16
movi v0.8b, #1
movi v9.16b, #2
movi v31.8b, #3
#ifndef SSVE
// And P0
rdffr p0.b
// And FFR
wrffr p15.b
#endif
ret
endfunction
function tickle_handler
// Increment the signal count (x23):
ldr x0, [x2, #ucontext_regs + 8 * 23]
add x0, x0, #1
str x0, [x2, #ucontext_regs + 8 * 23]
ret
endfunction
function terminate_handler
mov w21, w0
mov x20, x2
puts "Terminated by signal "
mov w0, w21
bl putdec
puts ", no error, iterations="
ldr x0, [x20, #ucontext_regs + 8 * 22]
bl putdec
puts ", signals="
ldr x0, [x20, #ucontext_regs + 8 * 23]
bl putdecn
mov x0, #0
mov x8, #__NR_exit
svc #0
endfunction
// w0: signal number
// x1: sa_action
// w2: sa_flags
// Clobbers x0-x6,x8
function setsignal
str x30, [sp, #-((sa_sz + 15) / 16 * 16 + 16)]!
mov w4, w0
mov x5, x1
mov w6, w2
add x0, sp, #16
mov x1, #sa_sz
bl memclr
mov w0, w4
add x1, sp, #16
str w6, [x1, #sa_flags]
str x5, [x1, #sa_handler]
mov x2, #0
mov x3, #sa_mask_sz
mov x8, #__NR_rt_sigaction
svc #0
cbz w0, 1f
puts "sigaction failure\n"
b .Labort
1: ldr x30, [sp], #((sa_sz + 15) / 16 * 16 + 16)
ret
endfunction
// Main program entry point
.globl _start
function _start
mov x23, #0 // Irritation signal count
mov w0, #SIGINT
adr x1, terminate_handler
mov w2, #SA_SIGINFO
bl setsignal
mov w0, #SIGTERM
adr x1, terminate_handler
mov w2, #SA_SIGINFO
bl setsignal
mov w0, #SIGUSR1
adr x1, irritator_handler
mov w2, #SA_SIGINFO
orr w2, w2, #SA_NODEFER
bl setsignal
mov w0, #SIGUSR2
adr x1, tickle_handler
mov w2, #SA_SIGINFO
orr w2, w2, #SA_NODEFER
bl setsignal
#ifdef SSVE
puts "Streaming mode "
smstart_sm
#endif
// Sanity-check and report the vector length
rdvl x19, #8
cmp x19, #128
b.lo 1f
cmp x19, #2048
b.hi 1f
tst x19, #(8 - 1)
b.eq 2f
1: puts "Bad vector length: "
mov x0, x19
bl putdecn
b .Labort
2: puts "Vector length:\t"
mov x0, x19
bl putdec
puts " bits\n"
// Obtain our PID, to ensure test pattern uniqueness between processes
mov x8, #__NR_getpid
svc #0
mov x20, x0
puts "PID:\t"
mov x0, x20
bl putdecn
#ifdef SSVE
smstart_sm // syscalls will have exited streaming mode
#endif
mov x22, #0 // generation number, increments per iteration
.Ltest_loop:
rdvl x0, #8
cmp x0, x19
b.ne vl_barf
mov x21, #0 // Set up Z-regs & shadow with test pattern
0: mov x0, x20
mov x1, x21
and x2, x22, #0xf
bl setup_zreg
add x21, x21, #1
cmp x21, #NZR
b.lo 0b
mov x0, x20 // Set up FFR & shadow with test pattern
mov x1, #NZR + NPR
and x2, x22, #0xf
bl setup_ffr
0: mov x0, x20 // Set up P-regs & shadow with test pattern
mov x1, x21
and x2, x22, #0xf
bl setup_preg
add x21, x21, #1
cmp x21, #NZR + NPR
b.lo 0b
// Can't do this when SVE state is volatile across SVC:
// mov x8, #__NR_sched_yield // Encourage preemption
// svc #0
#ifdef SSVE
mrs x0, S3_3_C4_C2_2 // SVCR should have ZA=0,SM=1
and x1, x0, #3
cmp x1, #1
b.ne svcr_barf
#endif
mov x21, #0
0: mov x0, x21
bl check_zreg
add x21, x21, #1
cmp x21, #NZR
b.lo 0b
0: mov x0, x21
bl check_preg
add x21, x21, #1
cmp x21, #NZR + NPR
b.lo 0b
bl check_ffr
add x22, x22, #1
b .Ltest_loop
.Labort:
mov x0, #0
mov x1, #SIGABRT
mov x8, #__NR_kill
svc #0
endfunction
function barf
// fpsimd.c acitivty log dump hack
// ldr w0, =0xdeadc0de
// mov w8, #__NR_exit
// svc #0
// end hack
mov x10, x0 // expected data
mov x11, x1 // actual data
mov x12, x2 // data size
#ifdef SSVE
mrs x13, S3_3_C4_C2_2
#endif
puts "Mismatch: PID="
mov x0, x20
bl putdec
puts ", iteration="
mov x0, x22
bl putdec
puts ", reg="
mov x0, x21
bl putdecn
puts "\tExpected ["
mov x0, x10
mov x1, x12
bl dumphex
puts "]\n\tGot ["
mov x0, x11
mov x1, x12
bl dumphex
puts "]\n"
#ifdef SSVE
puts "\tSVCR: "
mov x0, x13
bl putdecn
#endif
mov x8, #__NR_getpid
svc #0
// fpsimd.c acitivty log dump hack
// ldr w0, =0xdeadc0de
// mov w8, #__NR_exit
// svc #0
// ^ end of hack
mov x1, #SIGABRT
mov x8, #__NR_kill
svc #0
// mov x8, #__NR_exit
// mov x1, #1
// svc #0
endfunction
function vl_barf
mov x10, x0
puts "Bad active VL: "
mov x0, x10
bl putdecn
mov x8, #__NR_exit
mov x1, #1
svc #0
endfunction
function svcr_barf
mov x10, x0
puts "Bad SVCR: "
mov x0, x10
bl putdecn
mov x8, #__NR_exit
mov x1, #1
svc #0
endfunction