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qemu / qemu / f1912e48244816d071b2836052c54845ba57343c / . / target / arm / tcg / helper-a64.c
blob: 21a9abd90a6214e1f7a59f665cbef87318327122 [file] [log] [blame]
/*
* AArch64 specific helpers
*
* Copyright (c) 2013 Alexander Graf <agraf@suse.de>
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "qemu/units.h"
#include "cpu.h"
#include "gdbstub/helpers.h"
#include "exec/helper-proto.h"
#include "qemu/host-utils.h"
#include "qemu/log.h"
#include "qemu/main-loop.h"
#include "qemu/bitops.h"
#include "internals.h"
#include "qemu/crc32c.h"
#include "exec/exec-all.h"
#include "exec/cpu_ldst.h"
#include "qemu/int128.h"
#include "qemu/atomic128.h"
#include "fpu/softfloat.h"
#include <zlib.h> /* For crc32 */
/* C2.4.7 Multiply and divide */
/* special cases for 0 and LLONG_MIN are mandated by the standard */
uint64_t HELPER(udiv64)(uint64_t num, uint64_t den)
{
if (den == 0) {
return 0;
}
return num / den;
}
int64_t HELPER(sdiv64)(int64_t num, int64_t den)
{
if (den == 0) {
return 0;
}
if (num == LLONG_MIN && den == -1) {
return LLONG_MIN;
}
return num / den;
}
uint64_t HELPER(rbit64)(uint64_t x)
{
return revbit64(x);
}
void HELPER(msr_i_spsel)(CPUARMState *env, uint32_t imm)
{
update_spsel(env, imm);
}
void HELPER(msr_set_allint_el1)(CPUARMState *env)
{
/* ALLINT update to PSTATE. */
if (arm_hcrx_el2_eff(env) & HCRX_TALLINT) {
raise_exception_ra(env, EXCP_UDEF,
syn_aa64_sysregtrap(0, 1, 0, 4, 1, 0x1f, 0), 2,
GETPC());
}
env->pstate |= PSTATE_ALLINT;
}
static void daif_check(CPUARMState *env, uint32_t op,
uint32_t imm, uintptr_t ra)
{
/* DAIF update to PSTATE. This is OK from EL0 only if UMA is set. */
if (arm_current_el(env) == 0 && !(arm_sctlr(env, 0) & SCTLR_UMA)) {
raise_exception_ra(env, EXCP_UDEF,
syn_aa64_sysregtrap(0, extract32(op, 0, 3),
extract32(op, 3, 3), 4,
imm, 0x1f, 0),
exception_target_el(env), ra);
}
}
void HELPER(msr_i_daifset)(CPUARMState *env, uint32_t imm)
{
daif_check(env, 0x1e, imm, GETPC());
env->daif |= (imm << 6) & PSTATE_DAIF;
arm_rebuild_hflags(env);
}
void HELPER(msr_i_daifclear)(CPUARMState *env, uint32_t imm)
{
daif_check(env, 0x1f, imm, GETPC());
env->daif &= ~((imm << 6) & PSTATE_DAIF);
arm_rebuild_hflags(env);
}
/* Convert a softfloat float_relation_ (as returned by
* the float*_compare functions) to the correct ARM
* NZCV flag state.
*/
static inline uint32_t float_rel_to_flags(int res)
{
uint64_t flags;
switch (res) {
case float_relation_equal:
flags = PSTATE_Z | PSTATE_C;
break;
case float_relation_less:
flags = PSTATE_N;
break;
case float_relation_greater:
flags = PSTATE_C;
break;
case float_relation_unordered:
default:
flags = PSTATE_C | PSTATE_V;
break;
}
return flags;
}
uint64_t HELPER(vfp_cmph_a64)(uint32_t x, uint32_t y, void *fp_status)
{
return float_rel_to_flags(float16_compare_quiet(x, y, fp_status));
}
uint64_t HELPER(vfp_cmpeh_a64)(uint32_t x, uint32_t y, void *fp_status)
{
return float_rel_to_flags(float16_compare(x, y, fp_status));
}
uint64_t HELPER(vfp_cmps_a64)(float32 x, float32 y, void *fp_status)
{
return float_rel_to_flags(float32_compare_quiet(x, y, fp_status));
}
uint64_t HELPER(vfp_cmpes_a64)(float32 x, float32 y, void *fp_status)
{
return float_rel_to_flags(float32_compare(x, y, fp_status));
}
uint64_t HELPER(vfp_cmpd_a64)(float64 x, float64 y, void *fp_status)
{
return float_rel_to_flags(float64_compare_quiet(x, y, fp_status));
}
uint64_t HELPER(vfp_cmped_a64)(float64 x, float64 y, void *fp_status)
{
return float_rel_to_flags(float64_compare(x, y, fp_status));
}
float32 HELPER(vfp_mulxs)(float32 a, float32 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float32_squash_input_denormal(a, fpst);
b = float32_squash_input_denormal(b, fpst);
if ((float32_is_zero(a) && float32_is_infinity(b)) ||
(float32_is_infinity(a) && float32_is_zero(b))) {
/* 2.0 with the sign bit set to sign(A) XOR sign(B) */
return make_float32((1U << 30) |
((float32_val(a) ^ float32_val(b)) & (1U << 31)));
}
return float32_mul(a, b, fpst);
}
float64 HELPER(vfp_mulxd)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float64_squash_input_denormal(a, fpst);
b = float64_squash_input_denormal(b, fpst);
if ((float64_is_zero(a) && float64_is_infinity(b)) ||
(float64_is_infinity(a) && float64_is_zero(b))) {
/* 2.0 with the sign bit set to sign(A) XOR sign(B) */
return make_float64((1ULL << 62) |
((float64_val(a) ^ float64_val(b)) & (1ULL << 63)));
}
return float64_mul(a, b, fpst);
}
/* 64bit/double versions of the neon float compare functions */
uint64_t HELPER(neon_ceq_f64)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
return -float64_eq_quiet(a, b, fpst);
}
uint64_t HELPER(neon_cge_f64)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
return -float64_le(b, a, fpst);
}
uint64_t HELPER(neon_cgt_f64)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
return -float64_lt(b, a, fpst);
}
/* Reciprocal step and sqrt step. Note that unlike the A32/T32
* versions, these do a fully fused multiply-add or
* multiply-add-and-halve.
*/
uint32_t HELPER(recpsf_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
a = float16_squash_input_denormal(a, fpst);
b = float16_squash_input_denormal(b, fpst);
a = float16_chs(a);
if ((float16_is_infinity(a) && float16_is_zero(b)) ||
(float16_is_infinity(b) && float16_is_zero(a))) {
return float16_two;
}
return float16_muladd(a, b, float16_two, 0, fpst);
}
float32 HELPER(recpsf_f32)(float32 a, float32 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float32_squash_input_denormal(a, fpst);
b = float32_squash_input_denormal(b, fpst);
a = float32_chs(a);
if ((float32_is_infinity(a) && float32_is_zero(b)) ||
(float32_is_infinity(b) && float32_is_zero(a))) {
return float32_two;
}
return float32_muladd(a, b, float32_two, 0, fpst);
}
float64 HELPER(recpsf_f64)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float64_squash_input_denormal(a, fpst);
b = float64_squash_input_denormal(b, fpst);
a = float64_chs(a);
if ((float64_is_infinity(a) && float64_is_zero(b)) ||
(float64_is_infinity(b) && float64_is_zero(a))) {
return float64_two;
}
return float64_muladd(a, b, float64_two, 0, fpst);
}
uint32_t HELPER(rsqrtsf_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
a = float16_squash_input_denormal(a, fpst);
b = float16_squash_input_denormal(b, fpst);
a = float16_chs(a);
if ((float16_is_infinity(a) && float16_is_zero(b)) ||
(float16_is_infinity(b) && float16_is_zero(a))) {
return float16_one_point_five;
}
return float16_muladd(a, b, float16_three, float_muladd_halve_result, fpst);
}
float32 HELPER(rsqrtsf_f32)(float32 a, float32 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float32_squash_input_denormal(a, fpst);
b = float32_squash_input_denormal(b, fpst);
a = float32_chs(a);
if ((float32_is_infinity(a) && float32_is_zero(b)) ||
(float32_is_infinity(b) && float32_is_zero(a))) {
return float32_one_point_five;
}
return float32_muladd(a, b, float32_three, float_muladd_halve_result, fpst);
}
float64 HELPER(rsqrtsf_f64)(float64 a, float64 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float64_squash_input_denormal(a, fpst);
b = float64_squash_input_denormal(b, fpst);
a = float64_chs(a);
if ((float64_is_infinity(a) && float64_is_zero(b)) ||
(float64_is_infinity(b) && float64_is_zero(a))) {
return float64_one_point_five;
}
return float64_muladd(a, b, float64_three, float_muladd_halve_result, fpst);
}
/* Pairwise long add: add pairs of adjacent elements into
* double-width elements in the result (eg _s8 is an 8x8->16 op)
*/
uint64_t HELPER(neon_addlp_s8)(uint64_t a)
{
uint64_t nsignmask = 0x0080008000800080ULL;
uint64_t wsignmask = 0x8000800080008000ULL;
uint64_t elementmask = 0x00ff00ff00ff00ffULL;
uint64_t tmp1, tmp2;
uint64_t res, signres;
/* Extract odd elements, sign extend each to a 16 bit field */
tmp1 = a & elementmask;
tmp1 ^= nsignmask;
tmp1 |= wsignmask;
tmp1 = (tmp1 - nsignmask) ^ wsignmask;
/* Ditto for the even elements */
tmp2 = (a >> 8) & elementmask;
tmp2 ^= nsignmask;
tmp2 |= wsignmask;
tmp2 = (tmp2 - nsignmask) ^ wsignmask;
/* calculate the result by summing bits 0..14, 16..22, etc,
* and then adjusting the sign bits 15, 23, etc manually.
* This ensures the addition can't overflow the 16 bit field.
*/
signres = (tmp1 ^ tmp2) & wsignmask;
res = (tmp1 & ~wsignmask) + (tmp2 & ~wsignmask);
res ^= signres;
return res;
}
uint64_t HELPER(neon_addlp_u8)(uint64_t a)
{
uint64_t tmp;
tmp = a & 0x00ff00ff00ff00ffULL;
tmp += (a >> 8) & 0x00ff00ff00ff00ffULL;
return tmp;
}
uint64_t HELPER(neon_addlp_s16)(uint64_t a)
{
int32_t reslo, reshi;
reslo = (int32_t)(int16_t)a + (int32_t)(int16_t)(a >> 16);
reshi = (int32_t)(int16_t)(a >> 32) + (int32_t)(int16_t)(a >> 48);
return (uint32_t)reslo | (((uint64_t)reshi) << 32);
}
uint64_t HELPER(neon_addlp_u16)(uint64_t a)
{
uint64_t tmp;
tmp = a & 0x0000ffff0000ffffULL;
tmp += (a >> 16) & 0x0000ffff0000ffffULL;
return tmp;
}
/* Floating-point reciprocal exponent - see FPRecpX in ARM ARM */
uint32_t HELPER(frecpx_f16)(uint32_t a, void *fpstp)
{
float_status *fpst = fpstp;
uint16_t val16, sbit;
int16_t exp;
if (float16_is_any_nan(a)) {
float16 nan = a;
if (float16_is_signaling_nan(a, fpst)) {
float_raise(float_flag_invalid, fpst);
if (!fpst->default_nan_mode) {
nan = float16_silence_nan(a, fpst);
}
}
if (fpst->default_nan_mode) {
nan = float16_default_nan(fpst);
}
return nan;
}
a = float16_squash_input_denormal(a, fpst);
val16 = float16_val(a);
sbit = 0x8000 & val16;
exp = extract32(val16, 10, 5);
if (exp == 0) {
return make_float16(deposit32(sbit, 10, 5, 0x1e));
} else {
return make_float16(deposit32(sbit, 10, 5, ~exp));
}
}
float32 HELPER(frecpx_f32)(float32 a, void *fpstp)
{
float_status *fpst = fpstp;
uint32_t val32, sbit;
int32_t exp;
if (float32_is_any_nan(a)) {
float32 nan = a;
if (float32_is_signaling_nan(a, fpst)) {
float_raise(float_flag_invalid, fpst);
if (!fpst->default_nan_mode) {
nan = float32_silence_nan(a, fpst);
}
}
if (fpst->default_nan_mode) {
nan = float32_default_nan(fpst);
}
return nan;
}
a = float32_squash_input_denormal(a, fpst);
val32 = float32_val(a);
sbit = 0x80000000ULL & val32;
exp = extract32(val32, 23, 8);
if (exp == 0) {
return make_float32(sbit | (0xfe << 23));
} else {
return make_float32(sbit | (~exp & 0xff) << 23);
}
}
float64 HELPER(frecpx_f64)(float64 a, void *fpstp)
{
float_status *fpst = fpstp;
uint64_t val64, sbit;
int64_t exp;
if (float64_is_any_nan(a)) {
float64 nan = a;
if (float64_is_signaling_nan(a, fpst)) {
float_raise(float_flag_invalid, fpst);
if (!fpst->default_nan_mode) {
nan = float64_silence_nan(a, fpst);
}
}
if (fpst->default_nan_mode) {
nan = float64_default_nan(fpst);
}
return nan;
}
a = float64_squash_input_denormal(a, fpst);
val64 = float64_val(a);
sbit = 0x8000000000000000ULL & val64;
exp = extract64(float64_val(a), 52, 11);
if (exp == 0) {
return make_float64(sbit | (0x7feULL << 52));
} else {
return make_float64(sbit | (~exp & 0x7ffULL) << 52);
}
}
float32 HELPER(fcvtx_f64_to_f32)(float64 a, CPUARMState *env)
{
/* Von Neumann rounding is implemented by using round-to-zero
* and then setting the LSB of the result if Inexact was raised.
*/
float32 r;
float_status *fpst = &env->vfp.fp_status;
float_status tstat = *fpst;
int exflags;
set_float_rounding_mode(float_round_to_zero, &tstat);
set_float_exception_flags(0, &tstat);
r = float64_to_float32(a, &tstat);
exflags = get_float_exception_flags(&tstat);
if (exflags & float_flag_inexact) {
r = make_float32(float32_val(r) | 1);
}
exflags |= get_float_exception_flags(fpst);
set_float_exception_flags(exflags, fpst);
return r;
}
/* 64-bit versions of the CRC helpers. Note that although the operation
* (and the prototypes of crc32c() and crc32() mean that only the bottom
* 32 bits of the accumulator and result are used, we pass and return
* uint64_t for convenience of the generated code. Unlike the 32-bit
* instruction set versions, val may genuinely have 64 bits of data in it.
* The upper bytes of val (above the number specified by 'bytes') must have
* been zeroed out by the caller.
*/
uint64_t HELPER(crc32_64)(uint64_t acc, uint64_t val, uint32_t bytes)
{
uint8_t buf[8];
stq_le_p(buf, val);
/* zlib crc32 converts the accumulator and output to one's complement. */
return crc32(acc ^ 0xffffffff, buf, bytes) ^ 0xffffffff;
}
uint64_t HELPER(crc32c_64)(uint64_t acc, uint64_t val, uint32_t bytes)
{
uint8_t buf[8];
stq_le_p(buf, val);
/* Linux crc32c converts the output to one's complement. */
return crc32c(acc, buf, bytes) ^ 0xffffffff;
}
/*
* AdvSIMD half-precision
*/
#define ADVSIMD_HELPER(name, suffix) HELPER(glue(glue(advsimd_, name), suffix))
#define ADVSIMD_HALFOP(name) \
uint32_t ADVSIMD_HELPER(name, h)(uint32_t a, uint32_t b, void *fpstp) \
{ \
float_status *fpst = fpstp; \
return float16_ ## name(a, b, fpst); \
}
ADVSIMD_HALFOP(add)
ADVSIMD_HALFOP(sub)
ADVSIMD_HALFOP(mul)
ADVSIMD_HALFOP(div)
ADVSIMD_HALFOP(min)
ADVSIMD_HALFOP(max)
ADVSIMD_HALFOP(minnum)
ADVSIMD_HALFOP(maxnum)
#define ADVSIMD_TWOHALFOP(name) \
uint32_t ADVSIMD_HELPER(name, 2h)(uint32_t two_a, uint32_t two_b, void *fpstp) \
{ \
float16 a1, a2, b1, b2; \
uint32_t r1, r2; \
float_status *fpst = fpstp; \
a1 = extract32(two_a, 0, 16); \
a2 = extract32(two_a, 16, 16); \
b1 = extract32(two_b, 0, 16); \
b2 = extract32(two_b, 16, 16); \
r1 = float16_ ## name(a1, b1, fpst); \
r2 = float16_ ## name(a2, b2, fpst); \
return deposit32(r1, 16, 16, r2); \
}
ADVSIMD_TWOHALFOP(add)
ADVSIMD_TWOHALFOP(sub)
ADVSIMD_TWOHALFOP(mul)
ADVSIMD_TWOHALFOP(div)
ADVSIMD_TWOHALFOP(min)
ADVSIMD_TWOHALFOP(max)
ADVSIMD_TWOHALFOP(minnum)
ADVSIMD_TWOHALFOP(maxnum)
/* Data processing - scalar floating-point and advanced SIMD */
static float16 float16_mulx(float16 a, float16 b, void *fpstp)
{
float_status *fpst = fpstp;
a = float16_squash_input_denormal(a, fpst);
b = float16_squash_input_denormal(b, fpst);
if ((float16_is_zero(a) && float16_is_infinity(b)) ||
(float16_is_infinity(a) && float16_is_zero(b))) {
/* 2.0 with the sign bit set to sign(A) XOR sign(B) */
return make_float16((1U << 14) |
((float16_val(a) ^ float16_val(b)) & (1U << 15)));
}
return float16_mul(a, b, fpst);
}
ADVSIMD_HALFOP(mulx)
ADVSIMD_TWOHALFOP(mulx)
/* fused multiply-accumulate */
uint32_t HELPER(advsimd_muladdh)(uint32_t a, uint32_t b, uint32_t c,
void *fpstp)
{
float_status *fpst = fpstp;
return float16_muladd(a, b, c, 0, fpst);
}
uint32_t HELPER(advsimd_muladd2h)(uint32_t two_a, uint32_t two_b,
uint32_t two_c, void *fpstp)
{
float_status *fpst = fpstp;
float16 a1, a2, b1, b2, c1, c2;
uint32_t r1, r2;
a1 = extract32(two_a, 0, 16);
a2 = extract32(two_a, 16, 16);
b1 = extract32(two_b, 0, 16);
b2 = extract32(two_b, 16, 16);
c1 = extract32(two_c, 0, 16);
c2 = extract32(two_c, 16, 16);
r1 = float16_muladd(a1, b1, c1, 0, fpst);
r2 = float16_muladd(a2, b2, c2, 0, fpst);
return deposit32(r1, 16, 16, r2);
}
/*
* Floating point comparisons produce an integer result. Softfloat
* routines return float_relation types which we convert to the 0/-1
* Neon requires.
*/
#define ADVSIMD_CMPRES(test) (test) ? 0xffff : 0
uint32_t HELPER(advsimd_ceq_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
int compare = float16_compare_quiet(a, b, fpst);
return ADVSIMD_CMPRES(compare == float_relation_equal);
}
uint32_t HELPER(advsimd_cge_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
int compare = float16_compare(a, b, fpst);
return ADVSIMD_CMPRES(compare == float_relation_greater ||
compare == float_relation_equal);
}
uint32_t HELPER(advsimd_cgt_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
int compare = float16_compare(a, b, fpst);
return ADVSIMD_CMPRES(compare == float_relation_greater);
}
uint32_t HELPER(advsimd_acge_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
float16 f0 = float16_abs(a);
float16 f1 = float16_abs(b);
int compare = float16_compare(f0, f1, fpst);
return ADVSIMD_CMPRES(compare == float_relation_greater ||
compare == float_relation_equal);
}
uint32_t HELPER(advsimd_acgt_f16)(uint32_t a, uint32_t b, void *fpstp)
{
float_status *fpst = fpstp;
float16 f0 = float16_abs(a);
float16 f1 = float16_abs(b);
int compare = float16_compare(f0, f1, fpst);
return ADVSIMD_CMPRES(compare == float_relation_greater);
}
/* round to integral */
uint32_t HELPER(advsimd_rinth_exact)(uint32_t x, void *fp_status)
{
return float16_round_to_int(x, fp_status);
}
uint32_t HELPER(advsimd_rinth)(uint32_t x, void *fp_status)
{
int old_flags = get_float_exception_flags(fp_status), new_flags;
float16 ret;
ret = float16_round_to_int(x, fp_status);
/* Suppress any inexact exceptions the conversion produced */
if (!(old_flags & float_flag_inexact)) {
new_flags = get_float_exception_flags(fp_status);
set_float_exception_flags(new_flags & ~float_flag_inexact, fp_status);
}
return ret;
}
/*
* Half-precision floating point conversion functions
*
* There are a multitude of conversion functions with various
* different rounding modes. This is dealt with by the calling code
* setting the mode appropriately before calling the helper.
*/
uint32_t HELPER(advsimd_f16tosinth)(uint32_t a, void *fpstp)
{
float_status *fpst = fpstp;
/* Invalid if we are passed a NaN */
if (float16_is_any_nan(a)) {
float_raise(float_flag_invalid, fpst);
return 0;
}
return float16_to_int16(a, fpst);
}
uint32_t HELPER(advsimd_f16touinth)(uint32_t a, void *fpstp)
{
float_status *fpst = fpstp;
/* Invalid if we are passed a NaN */
if (float16_is_any_nan(a)) {
float_raise(float_flag_invalid, fpst);
return 0;
}
return float16_to_uint16(a, fpst);
}
static int el_from_spsr(uint32_t spsr)
{
/* Return the exception level that this SPSR is requesting a return to,
* or -1 if it is invalid (an illegal return)
*/
if (spsr & PSTATE_nRW) {
switch (spsr & CPSR_M) {
case ARM_CPU_MODE_USR:
return 0;
case ARM_CPU_MODE_HYP:
return 2;
case ARM_CPU_MODE_FIQ:
case ARM_CPU_MODE_IRQ:
case ARM_CPU_MODE_SVC:
case ARM_CPU_MODE_ABT:
case ARM_CPU_MODE_UND:
case ARM_CPU_MODE_SYS:
return 1;
case ARM_CPU_MODE_MON:
/* Returning to Mon from AArch64 is never possible,
* so this is an illegal return.
*/
default:
return -1;
}
} else {
if (extract32(spsr, 1, 1)) {
/* Return with reserved M[1] bit set */
return -1;
}
if (extract32(spsr, 0, 4) == 1) {
/* return to EL0 with M[0] bit set */
return -1;
}
return extract32(spsr, 2, 2);
}
}
static void cpsr_write_from_spsr_elx(CPUARMState *env,
uint32_t val)
{
uint32_t mask;
/* Save SPSR_ELx.SS into PSTATE. */
env->pstate = (env->pstate & ~PSTATE_SS) | (val & PSTATE_SS);
val &= ~PSTATE_SS;
/* Move DIT to the correct location for CPSR */
if (val & PSTATE_DIT) {
val &= ~PSTATE_DIT;
val |= CPSR_DIT;
}
mask = aarch32_cpsr_valid_mask(env->features, \
&env_archcpu(env)->isar);
cpsr_write(env, val, mask, CPSRWriteRaw);
}
void HELPER(exception_return)(CPUARMState *env, uint64_t new_pc)
{
int cur_el = arm_current_el(env);
unsigned int spsr_idx = aarch64_banked_spsr_index(cur_el);
uint32_t spsr = env->banked_spsr[spsr_idx];
int new_el;
bool return_to_aa64 = (spsr & PSTATE_nRW) == 0;
aarch64_save_sp(env, cur_el);
arm_clear_exclusive(env);
/* We must squash the PSTATE.SS bit to zero unless both of the
* following hold:
* 1. debug exceptions are currently disabled
* 2. singlestep will be active in the EL we return to
* We check 1 here and 2 after we've done the pstate/cpsr write() to
* transition to the EL we're going to.
*/
if (arm_generate_debug_exceptions(env)) {
spsr &= ~PSTATE_SS;
}
/*
* FEAT_RME forbids return from EL3 with an invalid security state.
* We don't need an explicit check for FEAT_RME here because we enforce
* in scr_write() that you can't set the NSE bit without it.
*/
if (cur_el == 3 && (env->cp15.scr_el3 & (SCR_NS | SCR_NSE)) == SCR_NSE) {
goto illegal_return;
}
new_el = el_from_spsr(spsr);
if (new_el == -1) {
goto illegal_return;
}
if (new_el > cur_el || (new_el == 2 && !arm_is_el2_enabled(env))) {
/* Disallow return to an EL which is unimplemented or higher
* than the current one.
*/
goto illegal_return;
}
if (new_el != 0 && arm_el_is_aa64(env, new_el) != return_to_aa64) {
/* Return to an EL which is configured for a different register width */
goto illegal_return;
}
if (new_el == 1 && (arm_hcr_el2_eff(env) & HCR_TGE)) {
goto illegal_return;
}
bql_lock();
arm_call_pre_el_change_hook(env_archcpu(env));
bql_unlock();
if (!return_to_aa64) {
env->aarch64 = false;
/* We do a raw CPSR write because aarch64_sync_64_to_32()
* will sort the register banks out for us, and we've already
* caught all the bad-mode cases in el_from_spsr().
*/
cpsr_write_from_spsr_elx(env, spsr);
if (!arm_singlestep_active(env)) {
env->pstate &= ~PSTATE_SS;
}
aarch64_sync_64_to_32(env);
if (spsr & CPSR_T) {
env->regs[15] = new_pc & ~0x1;
} else {
env->regs[15] = new_pc & ~0x3;
}
helper_rebuild_hflags_a32(env, new_el);
qemu_log_mask(CPU_LOG_INT, "Exception return from AArch64 EL%d to "
"AArch32 EL%d PC 0x%" PRIx32 "\n",
cur_el, new_el, env->regs[15]);
} else {
int tbii;
env->aarch64 = true;
spsr &= aarch64_pstate_valid_mask(&env_archcpu(env)->isar);
pstate_write(env, spsr);
if (!arm_singlestep_active(env)) {
env->pstate &= ~PSTATE_SS;
}
aarch64_restore_sp(env, new_el);
helper_rebuild_hflags_a64(env, new_el);
/*
* Apply TBI to the exception return address. We had to delay this
* until after we selected the new EL, so that we could select the
* correct TBI+TBID bits. This is made easier by waiting until after
* the hflags rebuild, since we can pull the composite TBII field
* from there.
*/
tbii = EX_TBFLAG_A64(env->hflags, TBII);
if ((tbii >> extract64(new_pc, 55, 1)) & 1) {
/* TBI is enabled. */
int core_mmu_idx = arm_env_mmu_index(env);
if (regime_has_2_ranges(core_to_aa64_mmu_idx(core_mmu_idx))) {
new_pc = sextract64(new_pc, 0, 56);
} else {
new_pc = extract64(new_pc, 0, 56);
}
}
env->pc = new_pc;
qemu_log_mask(CPU_LOG_INT, "Exception return from AArch64 EL%d to "
"AArch64 EL%d PC 0x%" PRIx64 "\n",
cur_el, new_el, env->pc);
}
/*
* Note that cur_el can never be 0. If new_el is 0, then
* el0_a64 is return_to_aa64, else el0_a64 is ignored.
*/
aarch64_sve_change_el(env, cur_el, new_el, return_to_aa64);
bql_lock();
arm_call_el_change_hook(env_archcpu(env));
bql_unlock();
return;
illegal_return:
/* Illegal return events of various kinds have architecturally
* mandated behaviour:
* restore NZCV and DAIF from SPSR_ELx
* set PSTATE.IL
* restore PC from ELR_ELx
* no change to exception level, execution state or stack pointer
*/
env->pstate |= PSTATE_IL;
env->pc = new_pc;
spsr &= PSTATE_NZCV | PSTATE_DAIF | PSTATE_ALLINT;
spsr |= pstate_read(env) & ~(PSTATE_NZCV | PSTATE_DAIF | PSTATE_ALLINT);
pstate_write(env, spsr);
if (!arm_singlestep_active(env)) {
env->pstate &= ~PSTATE_SS;
}
helper_rebuild_hflags_a64(env, cur_el);
qemu_log_mask(LOG_GUEST_ERROR, "Illegal exception return at EL%d: "
"resuming execution at 0x%" PRIx64 "\n", cur_el, env->pc);
}
/*
* Square Root and Reciprocal square root
*/
uint32_t HELPER(sqrt_f16)(uint32_t a, void *fpstp)
{
float_status *s = fpstp;
return float16_sqrt(a, s);
}
void HELPER(dc_zva)(CPUARMState *env, uint64_t vaddr_in)
{
uintptr_t ra = GETPC();
/*
* Implement DC ZVA, which zeroes a fixed-length block of memory.
* Note that we do not implement the (architecturally mandated)
* alignment fault for attempts to use this on Device memory
* (which matches the usual QEMU behaviour of not implementing either
* alignment faults or any memory attribute handling).
*/
int blocklen = 4 << env_archcpu(env)->dcz_blocksize;
uint64_t vaddr = vaddr_in & ~(blocklen - 1);
int mmu_idx = arm_env_mmu_index(env);
void *mem;
/*
* Trapless lookup. In addition to actual invalid page, may
* return NULL for I/O, watchpoints, clean pages, etc.
*/
mem = tlb_vaddr_to_host(env, vaddr, MMU_DATA_STORE, mmu_idx);
#ifndef CONFIG_USER_ONLY
if (unlikely(!mem)) {
/*
* Trap if accessing an invalid page. DC_ZVA requires that we supply
* the original pointer for an invalid page. But watchpoints require
* that we probe the actual space. So do both.
*/
(void) probe_write(env, vaddr_in, 1, mmu_idx, ra);
mem = probe_write(env, vaddr, blocklen, mmu_idx, ra);
if (unlikely(!mem)) {
/*
* The only remaining reason for mem == NULL is I/O.
* Just do a series of byte writes as the architecture demands.
*/
for (int i = 0; i < blocklen; i++) {
cpu_stb_mmuidx_ra(env, vaddr + i, 0, mmu_idx, ra);
}
return;
}
}
#endif
set_helper_retaddr(ra);
memset(mem, 0, blocklen);
clear_helper_retaddr();
}
void HELPER(unaligned_access)(CPUARMState *env, uint64_t addr,
uint32_t access_type, uint32_t mmu_idx)
{
arm_cpu_do_unaligned_access(env_cpu(env), addr, access_type,
mmu_idx, GETPC());
}
/* Memory operations (memset, memmove, memcpy) */
/*
* Return true if the CPY* and SET* insns can execute; compare
* pseudocode CheckMOPSEnabled(), though we refactor it a little.
*/
static bool mops_enabled(CPUARMState *env)
{
int el = arm_current_el(env);
if (el < 2 &&
(arm_hcr_el2_eff(env) & (HCR_E2H | HCR_TGE)) != (HCR_E2H | HCR_TGE) &&
!(arm_hcrx_el2_eff(env) & HCRX_MSCEN)) {
return false;
}
if (el == 0) {
if (!el_is_in_host(env, 0)) {
return env->cp15.sctlr_el[1] & SCTLR_MSCEN;
} else {
return env->cp15.sctlr_el[2] & SCTLR_MSCEN;
}
}
return true;
}
static void check_mops_enabled(CPUARMState *env, uintptr_t ra)
{
if (!mops_enabled(env)) {
raise_exception_ra(env, EXCP_UDEF, syn_uncategorized(),
exception_target_el(env), ra);
}
}
/*
* Return the target exception level for an exception due
* to mismatched arguments in a FEAT_MOPS copy or set.
* Compare pseudocode MismatchedCpySetTargetEL()
*/
static int mops_mismatch_exception_target_el(CPUARMState *env)
{
int el = arm_current_el(env);
if (el > 1) {
return el;
}
if (el == 0 && (arm_hcr_el2_eff(env) & HCR_TGE)) {
return 2;
}
if (el == 1 && (arm_hcrx_el2_eff(env) & HCRX_MCE2)) {
return 2;
}
return 1;
}
/*
* Check whether an M or E instruction was executed with a CF value
* indicating the wrong option for this implementation.
* Assumes we are always Option A.
*/
static void check_mops_wrong_option(CPUARMState *env, uint32_t syndrome,
uintptr_t ra)
{
if (env->CF != 0) {
syndrome |= 1 << 17; /* Set the wrong-option bit */
raise_exception_ra(env, EXCP_UDEF, syndrome,
mops_mismatch_exception_target_el(env), ra);
}
}
/*
* Return the maximum number of bytes we can transfer starting at addr
* without crossing a page boundary.
*/
static uint64_t page_limit(uint64_t addr)
{
return TARGET_PAGE_ALIGN(addr + 1) - addr;
}
/*
* Return the number of bytes we can copy starting from addr and working
* backwards without crossing a page boundary.
*/
static uint64_t page_limit_rev(uint64_t addr)
{
return (addr & ~TARGET_PAGE_MASK) + 1;
}
/*
* Perform part of a memory set on an area of guest memory starting at
* toaddr (a dirty address) and extending for setsize bytes.
*
* Returns the number of bytes actually set, which might be less than
* setsize; the caller should loop until the whole set has been done.
* The caller should ensure that the guest registers are correct
* for the possibility that the first byte of the set encounters
* an exception or watchpoint. We guarantee not to take any faults
* for bytes other than the first.
*/
static uint64_t set_step(CPUARMState *env, uint64_t toaddr,
uint64_t setsize, uint32_t data, int memidx,
uint32_t *mtedesc, uintptr_t ra)
{
void *mem;
setsize = MIN(setsize, page_limit(toaddr));
if (*mtedesc) {
uint64_t mtesize = mte_mops_probe(env, toaddr, setsize, *mtedesc);
if (mtesize == 0) {
/* Trap, or not. All CPU state is up to date */
mte_check_fail(env, *mtedesc, toaddr, ra);
/* Continue, with no further MTE checks required */
*mtedesc = 0;
} else {
/* Advance to the end, or to the tag mismatch */
setsize = MIN(setsize, mtesize);
}
}
toaddr = useronly_clean_ptr(toaddr);
/*
* Trapless lookup: returns NULL for invalid page, I/O,
* watchpoints, clean pages, etc.
*/
mem = tlb_vaddr_to_host(env, toaddr, MMU_DATA_STORE, memidx);
#ifndef CONFIG_USER_ONLY
if (unlikely(!mem)) {
/*
* Slow-path: just do one byte write. This will handle the
* watchpoint, invalid page, etc handling correctly.
* For clean code pages, the next iteration will see
* the page dirty and will use the fast path.
*/
cpu_stb_mmuidx_ra(env, toaddr, data, memidx, ra);
return 1;
}
#endif
/* Easy case: just memset the host memory */
set_helper_retaddr(ra);
memset(mem, data, setsize);
clear_helper_retaddr();
return setsize;
}
/*
* Similar, but setting tags. The architecture requires us to do this
* in 16-byte chunks. SETP accesses are not tag checked; they set
* the tags.
*/
static uint64_t set_step_tags(CPUARMState *env, uint64_t toaddr,
uint64_t setsize, uint32_t data, int memidx,
uint32_t *mtedesc, uintptr_t ra)
{
void *mem;
uint64_t cleanaddr;
setsize = MIN(setsize, page_limit(toaddr));
cleanaddr = useronly_clean_ptr(toaddr);
/*
* Trapless lookup: returns NULL for invalid page, I/O,
* watchpoints, clean pages, etc.
*/
mem = tlb_vaddr_to_host(env, cleanaddr, MMU_DATA_STORE, memidx);
#ifndef CONFIG_USER_ONLY
if (unlikely(!mem)) {
/*
* Slow-path: just do one write. This will handle the
* watchpoint, invalid page, etc handling correctly.
* The architecture requires that we do 16 bytes at a time,
* and we know both ptr and size are 16 byte aligned.
* For clean code pages, the next iteration will see
* the page dirty and will use the fast path.
*/
uint64_t repldata = data * 0x0101010101010101ULL;
MemOpIdx oi16 = make_memop_idx(MO_TE | MO_128, memidx);
cpu_st16_mmu(env, toaddr, int128_make128(repldata, repldata), oi16, ra);
mte_mops_set_tags(env, toaddr, 16, *mtedesc);
return 16;
}
#endif
/* Easy case: just memset the host memory */
set_helper_retaddr(ra);
memset(mem, data, setsize);
clear_helper_retaddr();
mte_mops_set_tags(env, toaddr, setsize, *mtedesc);
return setsize;
}
typedef uint64_t StepFn(CPUARMState *env, uint64_t toaddr,
uint64_t setsize, uint32_t data,
int memidx, uint32_t *mtedesc, uintptr_t ra);
/* Extract register numbers from a MOPS exception syndrome value */
static int mops_destreg(uint32_t syndrome)
{
return extract32(syndrome, 10, 5);
}
static int mops_srcreg(uint32_t syndrome)
{
return extract32(syndrome, 5, 5);
}
static int mops_sizereg(uint32_t syndrome)
{
return extract32(syndrome, 0, 5);
}
/*
* Return true if TCMA and TBI bits mean we need to do MTE checks.
* We only need to do this once per MOPS insn, not for every page.
*/
static bool mte_checks_needed(uint64_t ptr, uint32_t desc)
{
int bit55 = extract64(ptr, 55, 1);
/*
* Note that tbi_check() returns true for "access checked" but
* tcma_check() returns true for "access unchecked".
*/
if (!tbi_check(desc, bit55)) {
return false;
}
return !tcma_check(desc, bit55, allocation_tag_from_addr(ptr));
}
/* Take an exception if the SETG addr/size are not granule aligned */
static void check_setg_alignment(CPUARMState *env, uint64_t ptr, uint64_t size,
uint32_t memidx, uintptr_t ra)
{
if ((size != 0 && !QEMU_IS_ALIGNED(ptr, TAG_GRANULE)) ||
!QEMU_IS_ALIGNED(size, TAG_GRANULE)) {
arm_cpu_do_unaligned_access(env_cpu(env), ptr, MMU_DATA_STORE,
memidx, ra);
}
}
static uint64_t arm_reg_or_xzr(CPUARMState *env, int reg)
{
/*
* Runtime equivalent of cpu_reg() -- return the CPU register value,
* for contexts when index 31 means XZR (not SP).
*/
return reg == 31 ? 0 : env->xregs[reg];
}
/*
* For the Memory Set operation, our implementation chooses
* always to use "option A", where we update Xd to the final
* address in the SETP insn, and set Xn to be -(bytes remaining).
* On SETM and SETE insns we only need update Xn.
*
* @env: CPU
* @syndrome: syndrome value for mismatch exceptions
* (also contains the register numbers we need to use)
* @mtedesc: MTE descriptor word
* @stepfn: function which does a single part of the set operation
* @is_setg: true if this is the tag-setting SETG variant
*/
static void do_setp(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc,
StepFn *stepfn, bool is_setg, uintptr_t ra)
{
/* Prologue: we choose to do up to the next page boundary */
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint8_t data = arm_reg_or_xzr(env, rs);
uint32_t memidx = FIELD_EX32(mtedesc, MTEDESC, MIDX);
uint64_t toaddr = env->xregs[rd];
uint64_t setsize = env->xregs[rn];
uint64_t stagesetsize, step;
check_mops_enabled(env, ra);
if (setsize > INT64_MAX) {
setsize = INT64_MAX;
if (is_setg) {
setsize &= ~0xf;
}
}
if (unlikely(is_setg)) {
check_setg_alignment(env, toaddr, setsize, memidx, ra);
} else if (!mte_checks_needed(toaddr, mtedesc)) {
mtedesc = 0;
}
stagesetsize = MIN(setsize, page_limit(toaddr));
while (stagesetsize) {
env->xregs[rd] = toaddr;
env->xregs[rn] = setsize;
step = stepfn(env, toaddr, stagesetsize, data, memidx, &mtedesc, ra);
toaddr += step;
setsize -= step;
stagesetsize -= step;
}
/* Insn completed, so update registers to the Option A format */
env->xregs[rd] = toaddr + setsize;
env->xregs[rn] = -setsize;
/* Set NZCV = 0000 to indicate we are an Option A implementation */
env->NF = 0;
env->ZF = 1; /* our env->ZF encoding is inverted */
env->CF = 0;
env->VF = 0;
return;
}
void HELPER(setp)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_setp(env, syndrome, mtedesc, set_step, false, GETPC());
}
void HELPER(setgp)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_setp(env, syndrome, mtedesc, set_step_tags, true, GETPC());
}
static void do_setm(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc,
StepFn *stepfn, bool is_setg, uintptr_t ra)
{
/* Main: we choose to do all the full-page chunks */
CPUState *cs = env_cpu(env);
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint8_t data = arm_reg_or_xzr(env, rs);
uint64_t toaddr = env->xregs[rd] + env->xregs[rn];
uint64_t setsize = -env->xregs[rn];
uint32_t memidx = FIELD_EX32(mtedesc, MTEDESC, MIDX);
uint64_t step, stagesetsize;
check_mops_enabled(env, ra);
/*
* We're allowed to NOP out "no data to copy" before the consistency
* checks; we choose to do so.
*/
if (env->xregs[rn] == 0) {
return;
}
check_mops_wrong_option(env, syndrome, ra);
/*
* Our implementation will work fine even if we have an unaligned
* destination address, and because we update Xn every time around
* the loop below and the return value from stepfn() may be less
* than requested, we might find toaddr is unaligned. So we don't
* have an IMPDEF check for alignment here.
*/
if (unlikely(is_setg)) {
check_setg_alignment(env, toaddr, setsize, memidx, ra);
} else if (!mte_checks_needed(toaddr, mtedesc)) {
mtedesc = 0;
}
/* Do the actual memset: we leave the last partial page to SETE */
stagesetsize = setsize & TARGET_PAGE_MASK;
while (stagesetsize > 0) {
step = stepfn(env, toaddr, setsize, data, memidx, &mtedesc, ra);
toaddr += step;
setsize -= step;
stagesetsize -= step;
env->xregs[rn] = -setsize;
if (stagesetsize > 0 && unlikely(cpu_loop_exit_requested(cs))) {
cpu_loop_exit_restore(cs, ra);
}
}
}
void HELPER(setm)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_setm(env, syndrome, mtedesc, set_step, false, GETPC());
}
void HELPER(setgm)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_setm(env, syndrome, mtedesc, set_step_tags, true, GETPC());
}
static void do_sete(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc,
StepFn *stepfn, bool is_setg, uintptr_t ra)
{
/* Epilogue: do the last partial page */
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint8_t data = arm_reg_or_xzr(env, rs);
uint64_t toaddr = env->xregs[rd] + env->xregs[rn];
uint64_t setsize = -env->xregs[rn];
uint32_t memidx = FIELD_EX32(mtedesc, MTEDESC, MIDX);
uint64_t step;
check_mops_enabled(env, ra);
/*
* We're allowed to NOP out "no data to copy" before the consistency
* checks; we choose to do so.
*/
if (setsize == 0) {
return;
}
check_mops_wrong_option(env, syndrome, ra);
/*
* Our implementation has no address alignment requirements, but
* we do want to enforce the "less than a page" size requirement,
* so we don't need to have the "check for interrupts" here.
*/
if (setsize >= TARGET_PAGE_SIZE) {
raise_exception_ra(env, EXCP_UDEF, syndrome,
mops_mismatch_exception_target_el(env), ra);
}
if (unlikely(is_setg)) {
check_setg_alignment(env, toaddr, setsize, memidx, ra);
} else if (!mte_checks_needed(toaddr, mtedesc)) {
mtedesc = 0;
}
/* Do the actual memset */
while (setsize > 0) {
step = stepfn(env, toaddr, setsize, data, memidx, &mtedesc, ra);
toaddr += step;
setsize -= step;
env->xregs[rn] = -setsize;
}
}
void HELPER(sete)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_sete(env, syndrome, mtedesc, set_step, false, GETPC());
}
void HELPER(setge)(CPUARMState *env, uint32_t syndrome, uint32_t mtedesc)
{
do_sete(env, syndrome, mtedesc, set_step_tags, true, GETPC());
}
/*
* Perform part of a memory copy from the guest memory at fromaddr
* and extending for copysize bytes, to the guest memory at
* toaddr. Both addresses are dirty.
*
* Returns the number of bytes actually set, which might be less than
* copysize; the caller should loop until the whole copy has been done.
* The caller should ensure that the guest registers are correct
* for the possibility that the first byte of the copy encounters
* an exception or watchpoint. We guarantee not to take any faults
* for bytes other than the first.
*/
static uint64_t copy_step(CPUARMState *env, uint64_t toaddr, uint64_t fromaddr,
uint64_t copysize, int wmemidx, int rmemidx,
uint32_t *wdesc, uint32_t *rdesc, uintptr_t ra)
{
void *rmem;
void *wmem;
/* Don't cross a page boundary on either source or destination */
copysize = MIN(copysize, page_limit(toaddr));
copysize = MIN(copysize, page_limit(fromaddr));
/*
* Handle MTE tag checks: either handle the tag mismatch for byte 0,
* or else copy up to but not including the byte with the mismatch.
*/
if (*rdesc) {
uint64_t mtesize = mte_mops_probe(env, fromaddr, copysize, *rdesc);
if (mtesize == 0) {
mte_check_fail(env, *rdesc, fromaddr, ra);
*rdesc = 0;
} else {
copysize = MIN(copysize, mtesize);
}
}
if (*wdesc) {
uint64_t mtesize = mte_mops_probe(env, toaddr, copysize, *wdesc);
if (mtesize == 0) {
mte_check_fail(env, *wdesc, toaddr, ra);
*wdesc = 0;
} else {
copysize = MIN(copysize, mtesize);
}
}
toaddr = useronly_clean_ptr(toaddr);
fromaddr = useronly_clean_ptr(fromaddr);
/* Trapless lookup of whether we can get a host memory pointer */
wmem = tlb_vaddr_to_host(env, toaddr, MMU_DATA_STORE, wmemidx);
rmem = tlb_vaddr_to_host(env, fromaddr, MMU_DATA_LOAD, rmemidx);
#ifndef CONFIG_USER_ONLY
/*
* If we don't have host memory for both source and dest then just
* do a single byte copy. This will handle watchpoints, invalid pages,
* etc correctly. For clean code pages, the next iteration will see
* the page dirty and will use the fast path.
*/
if (unlikely(!rmem || !wmem)) {
uint8_t byte;
if (rmem) {
byte = *(uint8_t *)rmem;
} else {
byte = cpu_ldub_mmuidx_ra(env, fromaddr, rmemidx, ra);
}
if (wmem) {
*(uint8_t *)wmem = byte;
} else {
cpu_stb_mmuidx_ra(env, toaddr, byte, wmemidx, ra);
}
return 1;
}
#endif
/* Easy case: just memmove the host memory */
set_helper_retaddr(ra);
memmove(wmem, rmem, copysize);
clear_helper_retaddr();
return copysize;
}
/*
* Do part of a backwards memory copy. Here toaddr and fromaddr point
* to the *last* byte to be copied.
*/
static uint64_t copy_step_rev(CPUARMState *env, uint64_t toaddr,
uint64_t fromaddr,
uint64_t copysize, int wmemidx, int rmemidx,
uint32_t *wdesc, uint32_t *rdesc, uintptr_t ra)
{
void *rmem;
void *wmem;
/* Don't cross a page boundary on either source or destination */
copysize = MIN(copysize, page_limit_rev(toaddr));
copysize = MIN(copysize, page_limit_rev(fromaddr));
/*
* Handle MTE tag checks: either handle the tag mismatch for byte 0,
* or else copy up to but not including the byte with the mismatch.
*/
if (*rdesc) {
uint64_t mtesize = mte_mops_probe_rev(env, fromaddr, copysize, *rdesc);
if (mtesize == 0) {
mte_check_fail(env, *rdesc, fromaddr, ra);
*rdesc = 0;
} else {
copysize = MIN(copysize, mtesize);
}
}
if (*wdesc) {
uint64_t mtesize = mte_mops_probe_rev(env, toaddr, copysize, *wdesc);
if (mtesize == 0) {
mte_check_fail(env, *wdesc, toaddr, ra);
*wdesc = 0;
} else {
copysize = MIN(copysize, mtesize);
}
}
toaddr = useronly_clean_ptr(toaddr);
fromaddr = useronly_clean_ptr(fromaddr);
/* Trapless lookup of whether we can get a host memory pointer */
wmem = tlb_vaddr_to_host(env, toaddr, MMU_DATA_STORE, wmemidx);
rmem = tlb_vaddr_to_host(env, fromaddr, MMU_DATA_LOAD, rmemidx);
#ifndef CONFIG_USER_ONLY
/*
* If we don't have host memory for both source and dest then just
* do a single byte copy. This will handle watchpoints, invalid pages,
* etc correctly. For clean code pages, the next iteration will see
* the page dirty and will use the fast path.
*/
if (unlikely(!rmem || !wmem)) {
uint8_t byte;
if (rmem) {
byte = *(uint8_t *)rmem;
} else {
byte = cpu_ldub_mmuidx_ra(env, fromaddr, rmemidx, ra);
}
if (wmem) {
*(uint8_t *)wmem = byte;
} else {
cpu_stb_mmuidx_ra(env, toaddr, byte, wmemidx, ra);
}
return 1;
}
#endif
/*
* Easy case: just memmove the host memory. Note that wmem and
* rmem here point to the *last* byte to copy.
*/
set_helper_retaddr(ra);
memmove(wmem - (copysize - 1), rmem - (copysize - 1), copysize);
clear_helper_retaddr();
return copysize;
}
/*
* for the Memory Copy operation, our implementation chooses always
* to use "option A", where we update Xd and Xs to the final addresses
* in the CPYP insn, and then in CPYM and CPYE only need to update Xn.
*
* @env: CPU
* @syndrome: syndrome value for mismatch exceptions
* (also contains the register numbers we need to use)
* @wdesc: MTE descriptor for the writes (destination)
* @rdesc: MTE descriptor for the reads (source)
* @move: true if this is CPY (memmove), false for CPYF (memcpy forwards)
*/
static void do_cpyp(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc, uint32_t move, uintptr_t ra)
{
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint32_t rmemidx = FIELD_EX32(rdesc, MTEDESC, MIDX);
uint32_t wmemidx = FIELD_EX32(wdesc, MTEDESC, MIDX);
bool forwards = true;
uint64_t toaddr = env->xregs[rd];
uint64_t fromaddr = env->xregs[rs];
uint64_t copysize = env->xregs[rn];
uint64_t stagecopysize, step;
check_mops_enabled(env, ra);
if (move) {
/*
* Copy backwards if necessary. The direction for a non-overlapping
* copy is IMPDEF; we choose forwards.
*/
if (copysize > 0x007FFFFFFFFFFFFFULL) {
copysize = 0x007FFFFFFFFFFFFFULL;
}
uint64_t fs = extract64(fromaddr, 0, 56);
uint64_t ts = extract64(toaddr, 0, 56);
uint64_t fe = extract64(fromaddr + copysize, 0, 56);
if (fs < ts && fe > ts) {
forwards = false;
}
} else {
if (copysize > INT64_MAX) {
copysize = INT64_MAX;
}
}
if (!mte_checks_needed(fromaddr, rdesc)) {
rdesc = 0;
}
if (!mte_checks_needed(toaddr, wdesc)) {
wdesc = 0;
}
if (forwards) {
stagecopysize = MIN(copysize, page_limit(toaddr));
stagecopysize = MIN(stagecopysize, page_limit(fromaddr));
while (stagecopysize) {
env->xregs[rd] = toaddr;
env->xregs[rs] = fromaddr;
env->xregs[rn] = copysize;
step = copy_step(env, toaddr, fromaddr, stagecopysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
toaddr += step;
fromaddr += step;
copysize -= step;
stagecopysize -= step;
}
/* Insn completed, so update registers to the Option A format */
env->xregs[rd] = toaddr + copysize;
env->xregs[rs] = fromaddr + copysize;
env->xregs[rn] = -copysize;
} else {
/*
* In a reverse copy the to and from addrs in Xs and Xd are the start
* of the range, but it's more convenient for us to work with pointers
* to the last byte being copied.
*/
toaddr += copysize - 1;
fromaddr += copysize - 1;
stagecopysize = MIN(copysize, page_limit_rev(toaddr));
stagecopysize = MIN(stagecopysize, page_limit_rev(fromaddr));
while (stagecopysize) {
env->xregs[rn] = copysize;
step = copy_step_rev(env, toaddr, fromaddr, stagecopysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
copysize -= step;
stagecopysize -= step;
toaddr -= step;
fromaddr -= step;
}
/*
* Insn completed, so update registers to the Option A format.
* For a reverse copy this is no different to the CPYP input format.
*/
env->xregs[rn] = copysize;
}
/* Set NZCV = 0000 to indicate we are an Option A implementation */
env->NF = 0;
env->ZF = 1; /* our env->ZF encoding is inverted */
env->CF = 0;
env->VF = 0;
return;
}
void HELPER(cpyp)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpyp(env, syndrome, wdesc, rdesc, true, GETPC());
}
void HELPER(cpyfp)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpyp(env, syndrome, wdesc, rdesc, false, GETPC());
}
static void do_cpym(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc, uint32_t move, uintptr_t ra)
{
/* Main: we choose to copy until less than a page remaining */
CPUState *cs = env_cpu(env);
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint32_t rmemidx = FIELD_EX32(rdesc, MTEDESC, MIDX);
uint32_t wmemidx = FIELD_EX32(wdesc, MTEDESC, MIDX);
bool forwards = true;
uint64_t toaddr, fromaddr, copysize, step;
check_mops_enabled(env, ra);
/* We choose to NOP out "no data to copy" before consistency checks */
if (env->xregs[rn] == 0) {
return;
}
check_mops_wrong_option(env, syndrome, ra);
if (move) {
forwards = (int64_t)env->xregs[rn] < 0;
}
if (forwards) {
toaddr = env->xregs[rd] + env->xregs[rn];
fromaddr = env->xregs[rs] + env->xregs[rn];
copysize = -env->xregs[rn];
} else {
copysize = env->xregs[rn];
/* This toaddr and fromaddr point to the *last* byte to copy */
toaddr = env->xregs[rd] + copysize - 1;
fromaddr = env->xregs[rs] + copysize - 1;
}
if (!mte_checks_needed(fromaddr, rdesc)) {
rdesc = 0;
}
if (!mte_checks_needed(toaddr, wdesc)) {
wdesc = 0;
}
/* Our implementation has no particular parameter requirements for CPYM */
/* Do the actual memmove */
if (forwards) {
while (copysize >= TARGET_PAGE_SIZE) {
step = copy_step(env, toaddr, fromaddr, copysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
toaddr += step;
fromaddr += step;
copysize -= step;
env->xregs[rn] = -copysize;
if (copysize >= TARGET_PAGE_SIZE &&
unlikely(cpu_loop_exit_requested(cs))) {
cpu_loop_exit_restore(cs, ra);
}
}
} else {
while (copysize >= TARGET_PAGE_SIZE) {
step = copy_step_rev(env, toaddr, fromaddr, copysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
toaddr -= step;
fromaddr -= step;
copysize -= step;
env->xregs[rn] = copysize;
if (copysize >= TARGET_PAGE_SIZE &&
unlikely(cpu_loop_exit_requested(cs))) {
cpu_loop_exit_restore(cs, ra);
}
}
}
}
void HELPER(cpym)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpym(env, syndrome, wdesc, rdesc, true, GETPC());
}
void HELPER(cpyfm)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpym(env, syndrome, wdesc, rdesc, false, GETPC());
}
static void do_cpye(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc, uint32_t move, uintptr_t ra)
{
/* Epilogue: do the last partial page */
int rd = mops_destreg(syndrome);
int rs = mops_srcreg(syndrome);
int rn = mops_sizereg(syndrome);
uint32_t rmemidx = FIELD_EX32(rdesc, MTEDESC, MIDX);
uint32_t wmemidx = FIELD_EX32(wdesc, MTEDESC, MIDX);
bool forwards = true;
uint64_t toaddr, fromaddr, copysize, step;
check_mops_enabled(env, ra);
/* We choose to NOP out "no data to copy" before consistency checks */
if (env->xregs[rn] == 0) {
return;
}
check_mops_wrong_option(env, syndrome, ra);
if (move) {
forwards = (int64_t)env->xregs[rn] < 0;
}
if (forwards) {
toaddr = env->xregs[rd] + env->xregs[rn];
fromaddr = env->xregs[rs] + env->xregs[rn];
copysize = -env->xregs[rn];
} else {
copysize = env->xregs[rn];
/* This toaddr and fromaddr point to the *last* byte to copy */
toaddr = env->xregs[rd] + copysize - 1;
fromaddr = env->xregs[rs] + copysize - 1;
}
if (!mte_checks_needed(fromaddr, rdesc)) {
rdesc = 0;
}
if (!mte_checks_needed(toaddr, wdesc)) {
wdesc = 0;
}
/* Check the size; we don't want to have do a check-for-interrupts */
if (copysize >= TARGET_PAGE_SIZE) {
raise_exception_ra(env, EXCP_UDEF, syndrome,
mops_mismatch_exception_target_el(env), ra);
}
/* Do the actual memmove */
if (forwards) {
while (copysize > 0) {
step = copy_step(env, toaddr, fromaddr, copysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
toaddr += step;
fromaddr += step;
copysize -= step;
env->xregs[rn] = -copysize;
}
} else {
while (copysize > 0) {
step = copy_step_rev(env, toaddr, fromaddr, copysize,
wmemidx, rmemidx, &wdesc, &rdesc, ra);
toaddr -= step;
fromaddr -= step;
copysize -= step;
env->xregs[rn] = copysize;
}
}
}
void HELPER(cpye)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpye(env, syndrome, wdesc, rdesc, true, GETPC());
}
void HELPER(cpyfe)(CPUARMState *env, uint32_t syndrome, uint32_t wdesc,
uint32_t rdesc)
{
do_cpye(env, syndrome, wdesc, rdesc, false, GETPC());
}
static bool is_guarded_page(CPUARMState *env, target_ulong addr, uintptr_t ra)
{
#ifdef CONFIG_USER_ONLY
return page_get_flags(addr) & PAGE_BTI;
#else
CPUTLBEntryFull *full;
void *host;
int mmu_idx = cpu_mmu_index(env_cpu(env), true);
int flags = probe_access_full(env, addr, 0, MMU_INST_FETCH, mmu_idx,
false, &host, &full, ra);
assert(!(flags & TLB_INVALID_MASK));
return full->extra.arm.guarded;
#endif
}
void HELPER(guarded_page_check)(CPUARMState *env)
{
/*
* We have already verified that bti is enabled, and that the
* instruction at PC is not ok for BTYPE. This is always at
* the beginning of a block, so PC is always up-to-date and
* no unwind is required.
*/
if (is_guarded_page(env, env->pc, 0)) {
raise_exception(env, EXCP_UDEF, syn_btitrap(env->btype),
exception_target_el(env));
}
}
void HELPER(guarded_page_br)(CPUARMState *env, target_ulong pc)
{
/*
* We have already checked for branch via x16 and x17.
* What remains for choosing BTYPE is checking for a guarded page.
*/
env->btype = is_guarded_page(env, pc, GETPC()) ? 3 : 1;
}