qemu-e2k/target/arm/tcg/mte_helper.c
Anton Johansson a81fef4b64 target/arm: Replace TARGET_PAGE_ENTRY_EXTRA
TARGET_PAGE_ENTRY_EXTRA is a macro that allows guests to specify additional
fields for caching with the full TLB entry.  This macro is replaced with
a union in CPUTLBEntryFull, thus making CPUTLB target-agnostic at the
cost of slightly inflated CPUTLBEntryFull for non-arm guests.

Note, this is needed to ensure that fields in CPUTLB don't vary in
offset between various targets.

(arm is the only guest actually making use of this feature.)

Signed-off-by: Anton Johansson <anjo@rev.ng>
Message-Id: <20230912153428.17816-2-anjo@rev.ng>
Signed-off-by: Richard Henderson <richard.henderson@linaro.org>
2023-10-03 08:01:02 -07:00

1183 lines
37 KiB
C

/*
* ARM v8.5-MemTag Operations
*
* Copyright (c) 2020 Linaro, Ltd.
*
* 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/log.h"
#include "cpu.h"
#include "internals.h"
#include "exec/exec-all.h"
#include "exec/ram_addr.h"
#include "exec/cpu_ldst.h"
#include "exec/helper-proto.h"
#include "hw/core/tcg-cpu-ops.h"
#include "qapi/error.h"
#include "qemu/guest-random.h"
static int choose_nonexcluded_tag(int tag, int offset, uint16_t exclude)
{
if (exclude == 0xffff) {
return 0;
}
if (offset == 0) {
while (exclude & (1 << tag)) {
tag = (tag + 1) & 15;
}
} else {
do {
do {
tag = (tag + 1) & 15;
} while (exclude & (1 << tag));
} while (--offset > 0);
}
return tag;
}
/**
* allocation_tag_mem_probe:
* @env: the cpu environment
* @ptr_mmu_idx: the addressing regime to use for the virtual address
* @ptr: the virtual address for which to look up tag memory
* @ptr_access: the access to use for the virtual address
* @ptr_size: the number of bytes in the normal memory access
* @tag_access: the access to use for the tag memory
* @probe: true to merely probe, never taking an exception
* @ra: the return address for exception handling
*
* Our tag memory is formatted as a sequence of little-endian nibbles.
* That is, the byte at (addr >> (LOG2_TAG_GRANULE + 1)) contains two
* tags, with the tag at [3:0] for the lower addr and the tag at [7:4]
* for the higher addr.
*
* Here, resolve the physical address from the virtual address, and return
* a pointer to the corresponding tag byte.
*
* If there is no tag storage corresponding to @ptr, return NULL.
*
* If the page is inaccessible for @ptr_access, or has a watchpoint, there are
* three options:
* (1) probe = true, ra = 0 : pure probe -- we return NULL if the page is not
* accessible, and do not take watchpoint traps. The calling code must
* handle those cases in the right priority compared to MTE traps.
* (2) probe = false, ra = 0 : probe, no fault expected -- the caller guarantees
* that the page is going to be accessible. We will take watchpoint traps.
* (3) probe = false, ra != 0 : non-probe -- we will take both memory access
* traps and watchpoint traps.
* (probe = true, ra != 0 is invalid and will assert.)
*/
static uint8_t *allocation_tag_mem_probe(CPUARMState *env, int ptr_mmu_idx,
uint64_t ptr, MMUAccessType ptr_access,
int ptr_size, MMUAccessType tag_access,
bool probe, uintptr_t ra)
{
#ifdef CONFIG_USER_ONLY
uint64_t clean_ptr = useronly_clean_ptr(ptr);
int flags = page_get_flags(clean_ptr);
uint8_t *tags;
uintptr_t index;
assert(!(probe && ra));
if (!(flags & (ptr_access == MMU_DATA_STORE ? PAGE_WRITE_ORG : PAGE_READ))) {
cpu_loop_exit_sigsegv(env_cpu(env), ptr, ptr_access,
!(flags & PAGE_VALID), ra);
}
/* Require both MAP_ANON and PROT_MTE for the page. */
if (!(flags & PAGE_ANON) || !(flags & PAGE_MTE)) {
return NULL;
}
tags = page_get_target_data(clean_ptr);
index = extract32(ptr, LOG2_TAG_GRANULE + 1,
TARGET_PAGE_BITS - LOG2_TAG_GRANULE - 1);
return tags + index;
#else
CPUTLBEntryFull *full;
MemTxAttrs attrs;
int in_page, flags;
hwaddr ptr_paddr, tag_paddr, xlat;
MemoryRegion *mr;
ARMASIdx tag_asi;
AddressSpace *tag_as;
void *host;
/*
* Probe the first byte of the virtual address. This raises an
* exception for inaccessible pages, and resolves the virtual address
* into the softmmu tlb.
*
* When RA == 0, this is either a pure probe or a no-fault-expected probe.
* Indicate to probe_access_flags no-fault, then either return NULL
* for the pure probe, or assert that we received a valid page for the
* no-fault-expected probe.
*/
flags = probe_access_full(env, ptr, 0, ptr_access, ptr_mmu_idx,
ra == 0, &host, &full, ra);
if (probe && (flags & TLB_INVALID_MASK)) {
return NULL;
}
assert(!(flags & TLB_INVALID_MASK));
/* If the virtual page MemAttr != Tagged, access unchecked. */
if (full->extra.arm.pte_attrs != 0xf0) {
return NULL;
}
/*
* If not backed by host ram, there is no tag storage: access unchecked.
* This is probably a guest os bug though, so log it.
*/
if (unlikely(flags & TLB_MMIO)) {
qemu_log_mask(LOG_GUEST_ERROR,
"Page @ 0x%" PRIx64 " indicates Tagged Normal memory "
"but is not backed by host ram\n", ptr);
return NULL;
}
/*
* Remember these values across the second lookup below,
* which may invalidate this pointer via tlb resize.
*/
ptr_paddr = full->phys_addr | (ptr & ~TARGET_PAGE_MASK);
attrs = full->attrs;
full = NULL;
/*
* The Normal memory access can extend to the next page. E.g. a single
* 8-byte access to the last byte of a page will check only the last
* tag on the first page.
* Any page access exception has priority over tag check exception.
*/
in_page = -(ptr | TARGET_PAGE_MASK);
if (unlikely(ptr_size > in_page)) {
flags |= probe_access_full(env, ptr + in_page, 0, ptr_access,
ptr_mmu_idx, ra == 0, &host, &full, ra);
assert(!(flags & TLB_INVALID_MASK));
}
/* Any debug exception has priority over a tag check exception. */
if (!probe && unlikely(flags & TLB_WATCHPOINT)) {
int wp = ptr_access == MMU_DATA_LOAD ? BP_MEM_READ : BP_MEM_WRITE;
assert(ra != 0);
cpu_check_watchpoint(env_cpu(env), ptr, ptr_size, attrs, wp, ra);
}
/* Convert to the physical address in tag space. */
tag_paddr = ptr_paddr >> (LOG2_TAG_GRANULE + 1);
/* Look up the address in tag space. */
tag_asi = attrs.secure ? ARMASIdx_TagS : ARMASIdx_TagNS;
tag_as = cpu_get_address_space(env_cpu(env), tag_asi);
mr = address_space_translate(tag_as, tag_paddr, &xlat, NULL,
tag_access == MMU_DATA_STORE, attrs);
/*
* Note that @mr will never be NULL. If there is nothing in the address
* space at @tag_paddr, the translation will return the unallocated memory
* region. For our purposes, the result must be ram.
*/
if (unlikely(!memory_region_is_ram(mr))) {
/* ??? Failure is a board configuration error. */
qemu_log_mask(LOG_UNIMP,
"Tag Memory @ 0x%" HWADDR_PRIx " not found for "
"Normal Memory @ 0x%" HWADDR_PRIx "\n",
tag_paddr, ptr_paddr);
return NULL;
}
/*
* Ensure the tag memory is dirty on write, for migration.
* Tag memory can never contain code or display memory (vga).
*/
if (tag_access == MMU_DATA_STORE) {
ram_addr_t tag_ra = memory_region_get_ram_addr(mr) + xlat;
cpu_physical_memory_set_dirty_flag(tag_ra, DIRTY_MEMORY_MIGRATION);
}
return memory_region_get_ram_ptr(mr) + xlat;
#endif
}
static uint8_t *allocation_tag_mem(CPUARMState *env, int ptr_mmu_idx,
uint64_t ptr, MMUAccessType ptr_access,
int ptr_size, MMUAccessType tag_access,
uintptr_t ra)
{
return allocation_tag_mem_probe(env, ptr_mmu_idx, ptr, ptr_access,
ptr_size, tag_access, false, ra);
}
uint64_t HELPER(irg)(CPUARMState *env, uint64_t rn, uint64_t rm)
{
uint16_t exclude = extract32(rm | env->cp15.gcr_el1, 0, 16);
int rrnd = extract32(env->cp15.gcr_el1, 16, 1);
int start = extract32(env->cp15.rgsr_el1, 0, 4);
int seed = extract32(env->cp15.rgsr_el1, 8, 16);
int offset, i, rtag;
/*
* Our IMPDEF choice for GCR_EL1.RRND==1 is to continue to use the
* deterministic algorithm. Except that with RRND==1 the kernel is
* not required to have set RGSR_EL1.SEED != 0, which is required for
* the deterministic algorithm to function. So we force a non-zero
* SEED for that case.
*/
if (unlikely(seed == 0) && rrnd) {
do {
Error *err = NULL;
uint16_t two;
if (qemu_guest_getrandom(&two, sizeof(two), &err) < 0) {
/*
* Failed, for unknown reasons in the crypto subsystem.
* Best we can do is log the reason and use a constant seed.
*/
qemu_log_mask(LOG_UNIMP, "IRG: Crypto failure: %s\n",
error_get_pretty(err));
error_free(err);
two = 1;
}
seed = two;
} while (seed == 0);
}
/* RandomTag */
for (i = offset = 0; i < 4; ++i) {
/* NextRandomTagBit */
int top = (extract32(seed, 5, 1) ^ extract32(seed, 3, 1) ^
extract32(seed, 2, 1) ^ extract32(seed, 0, 1));
seed = (top << 15) | (seed >> 1);
offset |= top << i;
}
rtag = choose_nonexcluded_tag(start, offset, exclude);
env->cp15.rgsr_el1 = rtag | (seed << 8);
return address_with_allocation_tag(rn, rtag);
}
uint64_t HELPER(addsubg)(CPUARMState *env, uint64_t ptr,
int32_t offset, uint32_t tag_offset)
{
int start_tag = allocation_tag_from_addr(ptr);
uint16_t exclude = extract32(env->cp15.gcr_el1, 0, 16);
int rtag = choose_nonexcluded_tag(start_tag, tag_offset, exclude);
return address_with_allocation_tag(ptr + offset, rtag);
}
static int load_tag1(uint64_t ptr, uint8_t *mem)
{
int ofs = extract32(ptr, LOG2_TAG_GRANULE, 1) * 4;
return extract32(*mem, ofs, 4);
}
uint64_t HELPER(ldg)(CPUARMState *env, uint64_t ptr, uint64_t xt)
{
int mmu_idx = cpu_mmu_index(env, false);
uint8_t *mem;
int rtag = 0;
/* Trap if accessing an invalid page. */
mem = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_LOAD, 1,
MMU_DATA_LOAD, GETPC());
/* Load if page supports tags. */
if (mem) {
rtag = load_tag1(ptr, mem);
}
return address_with_allocation_tag(xt, rtag);
}
static void check_tag_aligned(CPUARMState *env, uint64_t ptr, uintptr_t ra)
{
if (unlikely(!QEMU_IS_ALIGNED(ptr, TAG_GRANULE))) {
arm_cpu_do_unaligned_access(env_cpu(env), ptr, MMU_DATA_STORE,
cpu_mmu_index(env, false), ra);
g_assert_not_reached();
}
}
/* For use in a non-parallel context, store to the given nibble. */
static void store_tag1(uint64_t ptr, uint8_t *mem, int tag)
{
int ofs = extract32(ptr, LOG2_TAG_GRANULE, 1) * 4;
*mem = deposit32(*mem, ofs, 4, tag);
}
/* For use in a parallel context, atomically store to the given nibble. */
static void store_tag1_parallel(uint64_t ptr, uint8_t *mem, int tag)
{
int ofs = extract32(ptr, LOG2_TAG_GRANULE, 1) * 4;
uint8_t old = qatomic_read(mem);
while (1) {
uint8_t new = deposit32(old, ofs, 4, tag);
uint8_t cmp = qatomic_cmpxchg(mem, old, new);
if (likely(cmp == old)) {
return;
}
old = cmp;
}
}
typedef void stg_store1(uint64_t, uint8_t *, int);
static inline void do_stg(CPUARMState *env, uint64_t ptr, uint64_t xt,
uintptr_t ra, stg_store1 store1)
{
int mmu_idx = cpu_mmu_index(env, false);
uint8_t *mem;
check_tag_aligned(env, ptr, ra);
/* Trap if accessing an invalid page. */
mem = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_STORE, TAG_GRANULE,
MMU_DATA_STORE, ra);
/* Store if page supports tags. */
if (mem) {
store1(ptr, mem, allocation_tag_from_addr(xt));
}
}
void HELPER(stg)(CPUARMState *env, uint64_t ptr, uint64_t xt)
{
do_stg(env, ptr, xt, GETPC(), store_tag1);
}
void HELPER(stg_parallel)(CPUARMState *env, uint64_t ptr, uint64_t xt)
{
do_stg(env, ptr, xt, GETPC(), store_tag1_parallel);
}
void HELPER(stg_stub)(CPUARMState *env, uint64_t ptr)
{
int mmu_idx = cpu_mmu_index(env, false);
uintptr_t ra = GETPC();
check_tag_aligned(env, ptr, ra);
probe_write(env, ptr, TAG_GRANULE, mmu_idx, ra);
}
static inline void do_st2g(CPUARMState *env, uint64_t ptr, uint64_t xt,
uintptr_t ra, stg_store1 store1)
{
int mmu_idx = cpu_mmu_index(env, false);
int tag = allocation_tag_from_addr(xt);
uint8_t *mem1, *mem2;
check_tag_aligned(env, ptr, ra);
/*
* Trap if accessing an invalid page(s).
* This takes priority over !allocation_tag_access_enabled.
*/
if (ptr & TAG_GRANULE) {
/* Two stores unaligned mod TAG_GRANULE*2 -- modify two bytes. */
mem1 = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_STORE,
TAG_GRANULE, MMU_DATA_STORE, ra);
mem2 = allocation_tag_mem(env, mmu_idx, ptr + TAG_GRANULE,
MMU_DATA_STORE, TAG_GRANULE,
MMU_DATA_STORE, ra);
/* Store if page(s) support tags. */
if (mem1) {
store1(TAG_GRANULE, mem1, tag);
}
if (mem2) {
store1(0, mem2, tag);
}
} else {
/* Two stores aligned mod TAG_GRANULE*2 -- modify one byte. */
mem1 = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_STORE,
2 * TAG_GRANULE, MMU_DATA_STORE, ra);
if (mem1) {
tag |= tag << 4;
qatomic_set(mem1, tag);
}
}
}
void HELPER(st2g)(CPUARMState *env, uint64_t ptr, uint64_t xt)
{
do_st2g(env, ptr, xt, GETPC(), store_tag1);
}
void HELPER(st2g_parallel)(CPUARMState *env, uint64_t ptr, uint64_t xt)
{
do_st2g(env, ptr, xt, GETPC(), store_tag1_parallel);
}
void HELPER(st2g_stub)(CPUARMState *env, uint64_t ptr)
{
int mmu_idx = cpu_mmu_index(env, false);
uintptr_t ra = GETPC();
int in_page = -(ptr | TARGET_PAGE_MASK);
check_tag_aligned(env, ptr, ra);
if (likely(in_page >= 2 * TAG_GRANULE)) {
probe_write(env, ptr, 2 * TAG_GRANULE, mmu_idx, ra);
} else {
probe_write(env, ptr, TAG_GRANULE, mmu_idx, ra);
probe_write(env, ptr + TAG_GRANULE, TAG_GRANULE, mmu_idx, ra);
}
}
uint64_t HELPER(ldgm)(CPUARMState *env, uint64_t ptr)
{
int mmu_idx = cpu_mmu_index(env, false);
uintptr_t ra = GETPC();
int gm_bs = env_archcpu(env)->gm_blocksize;
int gm_bs_bytes = 4 << gm_bs;
void *tag_mem;
uint64_t ret;
int shift;
ptr = QEMU_ALIGN_DOWN(ptr, gm_bs_bytes);
/* Trap if accessing an invalid page. */
tag_mem = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_LOAD,
gm_bs_bytes, MMU_DATA_LOAD, ra);
/* The tag is squashed to zero if the page does not support tags. */
if (!tag_mem) {
return 0;
}
/*
* The ordering of elements within the word corresponds to
* a little-endian operation. Computation of shift comes from
*
* index = address<LOG2_TAG_GRANULE+3:LOG2_TAG_GRANULE>
* data<index*4+3:index*4> = tag
*
* Because of the alignment of ptr above, BS=6 has shift=0.
* All memory operations are aligned. Defer support for BS=2,
* requiring insertion or extraction of a nibble, until we
* support a cpu that requires it.
*/
switch (gm_bs) {
case 3:
/* 32 bytes -> 2 tags -> 8 result bits */
ret = *(uint8_t *)tag_mem;
break;
case 4:
/* 64 bytes -> 4 tags -> 16 result bits */
ret = cpu_to_le16(*(uint16_t *)tag_mem);
break;
case 5:
/* 128 bytes -> 8 tags -> 32 result bits */
ret = cpu_to_le32(*(uint32_t *)tag_mem);
break;
case 6:
/* 256 bytes -> 16 tags -> 64 result bits */
return cpu_to_le64(*(uint64_t *)tag_mem);
default:
/*
* CPU configured with unsupported/invalid gm blocksize.
* This is detected early in arm_cpu_realizefn.
*/
g_assert_not_reached();
}
shift = extract64(ptr, LOG2_TAG_GRANULE, 4) * 4;
return ret << shift;
}
void HELPER(stgm)(CPUARMState *env, uint64_t ptr, uint64_t val)
{
int mmu_idx = cpu_mmu_index(env, false);
uintptr_t ra = GETPC();
int gm_bs = env_archcpu(env)->gm_blocksize;
int gm_bs_bytes = 4 << gm_bs;
void *tag_mem;
int shift;
ptr = QEMU_ALIGN_DOWN(ptr, gm_bs_bytes);
/* Trap if accessing an invalid page. */
tag_mem = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_STORE,
gm_bs_bytes, MMU_DATA_LOAD, ra);
/*
* Tag store only happens if the page support tags,
* and if the OS has enabled access to the tags.
*/
if (!tag_mem) {
return;
}
/* See LDGM for comments on BS and on shift. */
shift = extract64(ptr, LOG2_TAG_GRANULE, 4) * 4;
val >>= shift;
switch (gm_bs) {
case 3:
/* 32 bytes -> 2 tags -> 8 result bits */
*(uint8_t *)tag_mem = val;
break;
case 4:
/* 64 bytes -> 4 tags -> 16 result bits */
*(uint16_t *)tag_mem = cpu_to_le16(val);
break;
case 5:
/* 128 bytes -> 8 tags -> 32 result bits */
*(uint32_t *)tag_mem = cpu_to_le32(val);
break;
case 6:
/* 256 bytes -> 16 tags -> 64 result bits */
*(uint64_t *)tag_mem = cpu_to_le64(val);
break;
default:
/* cpu configured with unsupported gm blocksize. */
g_assert_not_reached();
}
}
void HELPER(stzgm_tags)(CPUARMState *env, uint64_t ptr, uint64_t val)
{
uintptr_t ra = GETPC();
int mmu_idx = cpu_mmu_index(env, false);
int log2_dcz_bytes, log2_tag_bytes;
intptr_t dcz_bytes, tag_bytes;
uint8_t *mem;
/*
* In arm_cpu_realizefn, we assert that dcz > LOG2_TAG_GRANULE+1,
* i.e. 32 bytes, which is an unreasonably small dcz anyway,
* to make sure that we can access one complete tag byte here.
*/
log2_dcz_bytes = env_archcpu(env)->dcz_blocksize + 2;
log2_tag_bytes = log2_dcz_bytes - (LOG2_TAG_GRANULE + 1);
dcz_bytes = (intptr_t)1 << log2_dcz_bytes;
tag_bytes = (intptr_t)1 << log2_tag_bytes;
ptr &= -dcz_bytes;
mem = allocation_tag_mem(env, mmu_idx, ptr, MMU_DATA_STORE, dcz_bytes,
MMU_DATA_STORE, ra);
if (mem) {
int tag_pair = (val & 0xf) * 0x11;
memset(mem, tag_pair, tag_bytes);
}
}
static void mte_sync_check_fail(CPUARMState *env, uint32_t desc,
uint64_t dirty_ptr, uintptr_t ra)
{
int is_write, syn;
env->exception.vaddress = dirty_ptr;
is_write = FIELD_EX32(desc, MTEDESC, WRITE);
syn = syn_data_abort_no_iss(arm_current_el(env) != 0, 0, 0, 0, 0, is_write,
0x11);
raise_exception_ra(env, EXCP_DATA_ABORT, syn, exception_target_el(env), ra);
g_assert_not_reached();
}
static void mte_async_check_fail(CPUARMState *env, uint64_t dirty_ptr,
uintptr_t ra, ARMMMUIdx arm_mmu_idx, int el)
{
int select;
if (regime_has_2_ranges(arm_mmu_idx)) {
select = extract64(dirty_ptr, 55, 1);
} else {
select = 0;
}
env->cp15.tfsr_el[el] |= 1 << select;
#ifdef CONFIG_USER_ONLY
/*
* Stand in for a timer irq, setting _TIF_MTE_ASYNC_FAULT,
* which then sends a SIGSEGV when the thread is next scheduled.
* This cpu will return to the main loop at the end of the TB,
* which is rather sooner than "normal". But the alternative
* is waiting until the next syscall.
*/
qemu_cpu_kick(env_cpu(env));
#endif
}
/* Record a tag check failure. */
void mte_check_fail(CPUARMState *env, uint32_t desc,
uint64_t dirty_ptr, uintptr_t ra)
{
int mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
ARMMMUIdx arm_mmu_idx = core_to_aa64_mmu_idx(mmu_idx);
int el, reg_el, tcf;
uint64_t sctlr;
reg_el = regime_el(env, arm_mmu_idx);
sctlr = env->cp15.sctlr_el[reg_el];
switch (arm_mmu_idx) {
case ARMMMUIdx_E10_0:
case ARMMMUIdx_E20_0:
el = 0;
tcf = extract64(sctlr, 38, 2);
break;
default:
el = reg_el;
tcf = extract64(sctlr, 40, 2);
}
switch (tcf) {
case 1:
/* Tag check fail causes a synchronous exception. */
mte_sync_check_fail(env, desc, dirty_ptr, ra);
break;
case 0:
/*
* Tag check fail does not affect the PE.
* We eliminate this case by not setting MTE_ACTIVE
* in tb_flags, so that we never make this runtime call.
*/
g_assert_not_reached();
case 2:
/* Tag check fail causes asynchronous flag set. */
mte_async_check_fail(env, dirty_ptr, ra, arm_mmu_idx, el);
break;
case 3:
/*
* Tag check fail causes asynchronous flag set for stores, or
* a synchronous exception for loads.
*/
if (FIELD_EX32(desc, MTEDESC, WRITE)) {
mte_async_check_fail(env, dirty_ptr, ra, arm_mmu_idx, el);
} else {
mte_sync_check_fail(env, desc, dirty_ptr, ra);
}
break;
}
}
/**
* checkN:
* @tag: tag memory to test
* @odd: true to begin testing at tags at odd nibble
* @cmp: the tag to compare against
* @count: number of tags to test
*
* Return the number of successful tests.
* Thus a return value < @count indicates a failure.
*
* A note about sizes: count is expected to be small.
*
* The most common use will be LDP/STP of two integer registers,
* which means 16 bytes of memory touching at most 2 tags, but
* often the access is aligned and thus just 1 tag.
*
* Using AdvSIMD LD/ST (multiple), one can access 64 bytes of memory,
* touching at most 5 tags. SVE LDR/STR (vector) with the default
* vector length is also 64 bytes; the maximum architectural length
* is 256 bytes touching at most 9 tags.
*
* The loop below uses 7 logical operations and 1 memory operation
* per tag pair. An implementation that loads an aligned word and
* uses masking to ignore adjacent tags requires 18 logical operations
* and thus does not begin to pay off until 6 tags.
* Which, according to the survey above, is unlikely to be common.
*/
static int checkN(uint8_t *mem, int odd, int cmp, int count)
{
int n = 0, diff;
/* Replicate the test tag and compare. */
cmp *= 0x11;
diff = *mem++ ^ cmp;
if (odd) {
goto start_odd;
}
while (1) {
/* Test even tag. */
if (unlikely((diff) & 0x0f)) {
break;
}
if (++n == count) {
break;
}
start_odd:
/* Test odd tag. */
if (unlikely((diff) & 0xf0)) {
break;
}
if (++n == count) {
break;
}
diff = *mem++ ^ cmp;
}
return n;
}
/**
* checkNrev:
* @tag: tag memory to test
* @odd: true to begin testing at tags at odd nibble
* @cmp: the tag to compare against
* @count: number of tags to test
*
* Return the number of successful tests.
* Thus a return value < @count indicates a failure.
*
* This is like checkN, but it runs backwards, checking the
* tags starting with @tag and then the tags preceding it.
* This is needed by the backwards-memory-copying operations.
*/
static int checkNrev(uint8_t *mem, int odd, int cmp, int count)
{
int n = 0, diff;
/* Replicate the test tag and compare. */
cmp *= 0x11;
diff = *mem-- ^ cmp;
if (!odd) {
goto start_even;
}
while (1) {
/* Test odd tag. */
if (unlikely((diff) & 0xf0)) {
break;
}
if (++n == count) {
break;
}
start_even:
/* Test even tag. */
if (unlikely((diff) & 0x0f)) {
break;
}
if (++n == count) {
break;
}
diff = *mem-- ^ cmp;
}
return n;
}
/**
* mte_probe_int() - helper for mte_probe and mte_check
* @env: CPU environment
* @desc: MTEDESC descriptor
* @ptr: virtual address of the base of the access
* @fault: return virtual address of the first check failure
*
* Internal routine for both mte_probe and mte_check.
* Return zero on failure, filling in *fault.
* Return negative on trivial success for tbi disabled.
* Return positive on success with tbi enabled.
*/
static int mte_probe_int(CPUARMState *env, uint32_t desc, uint64_t ptr,
uintptr_t ra, uint64_t *fault)
{
int mmu_idx, ptr_tag, bit55;
uint64_t ptr_last, prev_page, next_page;
uint64_t tag_first, tag_last;
uint32_t sizem1, tag_count, n, c;
uint8_t *mem1, *mem2;
MMUAccessType type;
bit55 = extract64(ptr, 55, 1);
*fault = ptr;
/* If TBI is disabled, the access is unchecked, and ptr is not dirty. */
if (unlikely(!tbi_check(desc, bit55))) {
return -1;
}
ptr_tag = allocation_tag_from_addr(ptr);
if (tcma_check(desc, bit55, ptr_tag)) {
return 1;
}
mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
type = FIELD_EX32(desc, MTEDESC, WRITE) ? MMU_DATA_STORE : MMU_DATA_LOAD;
sizem1 = FIELD_EX32(desc, MTEDESC, SIZEM1);
/* Find the addr of the end of the access */
ptr_last = ptr + sizem1;
/* Round the bounds to the tag granule, and compute the number of tags. */
tag_first = QEMU_ALIGN_DOWN(ptr, TAG_GRANULE);
tag_last = QEMU_ALIGN_DOWN(ptr_last, TAG_GRANULE);
tag_count = ((tag_last - tag_first) / TAG_GRANULE) + 1;
/* Locate the page boundaries. */
prev_page = ptr & TARGET_PAGE_MASK;
next_page = prev_page + TARGET_PAGE_SIZE;
if (likely(tag_last - prev_page < TARGET_PAGE_SIZE)) {
/* Memory access stays on one page. */
mem1 = allocation_tag_mem(env, mmu_idx, ptr, type, sizem1 + 1,
MMU_DATA_LOAD, ra);
if (!mem1) {
return 1;
}
/* Perform all of the comparisons. */
n = checkN(mem1, ptr & TAG_GRANULE, ptr_tag, tag_count);
} else {
/* Memory access crosses to next page. */
mem1 = allocation_tag_mem(env, mmu_idx, ptr, type, next_page - ptr,
MMU_DATA_LOAD, ra);
mem2 = allocation_tag_mem(env, mmu_idx, next_page, type,
ptr_last - next_page + 1,
MMU_DATA_LOAD, ra);
/*
* Perform all of the comparisons.
* Note the possible but unlikely case of the operation spanning
* two pages that do not both have tagging enabled.
*/
n = c = (next_page - tag_first) / TAG_GRANULE;
if (mem1) {
n = checkN(mem1, ptr & TAG_GRANULE, ptr_tag, c);
}
if (n == c) {
if (!mem2) {
return 1;
}
n += checkN(mem2, 0, ptr_tag, tag_count - c);
}
}
if (likely(n == tag_count)) {
return 1;
}
/*
* If we failed, we know which granule. For the first granule, the
* failure address is @ptr, the first byte accessed. Otherwise the
* failure address is the first byte of the nth granule.
*/
if (n > 0) {
*fault = tag_first + n * TAG_GRANULE;
}
return 0;
}
uint64_t mte_check(CPUARMState *env, uint32_t desc, uint64_t ptr, uintptr_t ra)
{
uint64_t fault;
int ret = mte_probe_int(env, desc, ptr, ra, &fault);
if (unlikely(ret == 0)) {
mte_check_fail(env, desc, fault, ra);
} else if (ret < 0) {
return ptr;
}
return useronly_clean_ptr(ptr);
}
uint64_t HELPER(mte_check)(CPUARMState *env, uint32_t desc, uint64_t ptr)
{
/*
* R_XCHFJ: Alignment check not caused by memory type is priority 1,
* higher than any translation fault. When MTE is disabled, tcg
* performs the alignment check during the code generated for the
* memory access. With MTE enabled, we must check this here before
* raising any translation fault in allocation_tag_mem.
*/
unsigned align = FIELD_EX32(desc, MTEDESC, ALIGN);
if (unlikely(align)) {
align = (1u << align) - 1;
if (unlikely(ptr & align)) {
int idx = FIELD_EX32(desc, MTEDESC, MIDX);
bool w = FIELD_EX32(desc, MTEDESC, WRITE);
MMUAccessType type = w ? MMU_DATA_STORE : MMU_DATA_LOAD;
arm_cpu_do_unaligned_access(env_cpu(env), ptr, type, idx, GETPC());
}
}
return mte_check(env, desc, ptr, GETPC());
}
/*
* No-fault version of mte_check, to be used by SVE for MemSingleNF.
* Returns false if the access is Checked and the check failed. This
* is only intended to probe the tag -- the validity of the page must
* be checked beforehand.
*/
bool mte_probe(CPUARMState *env, uint32_t desc, uint64_t ptr)
{
uint64_t fault;
int ret = mte_probe_int(env, desc, ptr, 0, &fault);
return ret != 0;
}
/*
* Perform an MTE checked access for DC_ZVA.
*/
uint64_t HELPER(mte_check_zva)(CPUARMState *env, uint32_t desc, uint64_t ptr)
{
uintptr_t ra = GETPC();
int log2_dcz_bytes, log2_tag_bytes;
int mmu_idx, bit55;
intptr_t dcz_bytes, tag_bytes, i;
void *mem;
uint64_t ptr_tag, mem_tag, align_ptr;
bit55 = extract64(ptr, 55, 1);
/* If TBI is disabled, the access is unchecked, and ptr is not dirty. */
if (unlikely(!tbi_check(desc, bit55))) {
return ptr;
}
ptr_tag = allocation_tag_from_addr(ptr);
if (tcma_check(desc, bit55, ptr_tag)) {
goto done;
}
/*
* In arm_cpu_realizefn, we asserted that dcz > LOG2_TAG_GRANULE+1,
* i.e. 32 bytes, which is an unreasonably small dcz anyway, to make
* sure that we can access one complete tag byte here.
*/
log2_dcz_bytes = env_archcpu(env)->dcz_blocksize + 2;
log2_tag_bytes = log2_dcz_bytes - (LOG2_TAG_GRANULE + 1);
dcz_bytes = (intptr_t)1 << log2_dcz_bytes;
tag_bytes = (intptr_t)1 << log2_tag_bytes;
align_ptr = ptr & -dcz_bytes;
/*
* 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.
*/
mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
(void) probe_write(env, ptr, 1, mmu_idx, ra);
mem = allocation_tag_mem(env, mmu_idx, align_ptr, MMU_DATA_STORE,
dcz_bytes, MMU_DATA_LOAD, ra);
if (!mem) {
goto done;
}
/*
* Unlike the reasoning for checkN, DC_ZVA is always aligned, and thus
* it is quite easy to perform all of the comparisons at once without
* any extra masking.
*
* The most common zva block size is 64; some of the thunderx cpus use
* a block size of 128. For user-only, aarch64_max_initfn will set the
* block size to 512. Fill out the other cases for future-proofing.
*
* In order to be able to find the first miscompare later, we want the
* tag bytes to be in little-endian order.
*/
switch (log2_tag_bytes) {
case 0: /* zva_blocksize 32 */
mem_tag = *(uint8_t *)mem;
ptr_tag *= 0x11u;
break;
case 1: /* zva_blocksize 64 */
mem_tag = cpu_to_le16(*(uint16_t *)mem);
ptr_tag *= 0x1111u;
break;
case 2: /* zva_blocksize 128 */
mem_tag = cpu_to_le32(*(uint32_t *)mem);
ptr_tag *= 0x11111111u;
break;
case 3: /* zva_blocksize 256 */
mem_tag = cpu_to_le64(*(uint64_t *)mem);
ptr_tag *= 0x1111111111111111ull;
break;
default: /* zva_blocksize 512, 1024, 2048 */
ptr_tag *= 0x1111111111111111ull;
i = 0;
do {
mem_tag = cpu_to_le64(*(uint64_t *)(mem + i));
if (unlikely(mem_tag != ptr_tag)) {
goto fail;
}
i += 8;
align_ptr += 16 * TAG_GRANULE;
} while (i < tag_bytes);
goto done;
}
if (likely(mem_tag == ptr_tag)) {
goto done;
}
fail:
/* Locate the first nibble that differs. */
i = ctz64(mem_tag ^ ptr_tag) >> 4;
mte_check_fail(env, desc, align_ptr + i * TAG_GRANULE, ra);
done:
return useronly_clean_ptr(ptr);
}
uint64_t mte_mops_probe(CPUARMState *env, uint64_t ptr, uint64_t size,
uint32_t desc)
{
int mmu_idx, tag_count;
uint64_t ptr_tag, tag_first, tag_last;
void *mem;
bool w = FIELD_EX32(desc, MTEDESC, WRITE);
uint32_t n;
mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
/* True probe; this will never fault */
mem = allocation_tag_mem_probe(env, mmu_idx, ptr,
w ? MMU_DATA_STORE : MMU_DATA_LOAD,
size, MMU_DATA_LOAD, true, 0);
if (!mem) {
return size;
}
/*
* TODO: checkN() is not designed for checks of the size we expect
* for FEAT_MOPS operations, so we should implement this differently.
* Maybe we should do something like
* if (region start and size are aligned nicely) {
* do direct loads of 64 tag bits at a time;
* } else {
* call checkN()
* }
*/
/* Round the bounds to the tag granule, and compute the number of tags. */
ptr_tag = allocation_tag_from_addr(ptr);
tag_first = QEMU_ALIGN_DOWN(ptr, TAG_GRANULE);
tag_last = QEMU_ALIGN_DOWN(ptr + size - 1, TAG_GRANULE);
tag_count = ((tag_last - tag_first) / TAG_GRANULE) + 1;
n = checkN(mem, ptr & TAG_GRANULE, ptr_tag, tag_count);
if (likely(n == tag_count)) {
return size;
}
/*
* Failure; for the first granule, it's at @ptr. Otherwise
* it's at the first byte of the nth granule. Calculate how
* many bytes we can access without hitting that failure.
*/
if (n == 0) {
return 0;
} else {
return n * TAG_GRANULE - (ptr - tag_first);
}
}
uint64_t mte_mops_probe_rev(CPUARMState *env, uint64_t ptr, uint64_t size,
uint32_t desc)
{
int mmu_idx, tag_count;
uint64_t ptr_tag, tag_first, tag_last;
void *mem;
bool w = FIELD_EX32(desc, MTEDESC, WRITE);
uint32_t n;
mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
/* True probe; this will never fault */
mem = allocation_tag_mem_probe(env, mmu_idx, ptr,
w ? MMU_DATA_STORE : MMU_DATA_LOAD,
size, MMU_DATA_LOAD, true, 0);
if (!mem) {
return size;
}
/*
* TODO: checkNrev() is not designed for checks of the size we expect
* for FEAT_MOPS operations, so we should implement this differently.
* Maybe we should do something like
* if (region start and size are aligned nicely) {
* do direct loads of 64 tag bits at a time;
* } else {
* call checkN()
* }
*/
/* Round the bounds to the tag granule, and compute the number of tags. */
ptr_tag = allocation_tag_from_addr(ptr);
tag_first = QEMU_ALIGN_DOWN(ptr - (size - 1), TAG_GRANULE);
tag_last = QEMU_ALIGN_DOWN(ptr, TAG_GRANULE);
tag_count = ((tag_last - tag_first) / TAG_GRANULE) + 1;
n = checkNrev(mem, ptr & TAG_GRANULE, ptr_tag, tag_count);
if (likely(n == tag_count)) {
return size;
}
/*
* Failure; for the first granule, it's at @ptr. Otherwise
* it's at the last byte of the nth granule. Calculate how
* many bytes we can access without hitting that failure.
*/
if (n == 0) {
return 0;
} else {
return (n - 1) * TAG_GRANULE + ((ptr + 1) - tag_last);
}
}
void mte_mops_set_tags(CPUARMState *env, uint64_t ptr, uint64_t size,
uint32_t desc)
{
int mmu_idx, tag_count;
uint64_t ptr_tag;
void *mem;
if (!desc) {
/* Tags not actually enabled */
return;
}
mmu_idx = FIELD_EX32(desc, MTEDESC, MIDX);
/* True probe: this will never fault */
mem = allocation_tag_mem_probe(env, mmu_idx, ptr, MMU_DATA_STORE, size,
MMU_DATA_STORE, true, 0);
if (!mem) {
return;
}
/*
* We know that ptr and size are both TAG_GRANULE aligned; store
* the tag from the pointer value into the tag memory.
*/
ptr_tag = allocation_tag_from_addr(ptr);
tag_count = size / TAG_GRANULE;
if (ptr & TAG_GRANULE) {
/* Not 2*TAG_GRANULE-aligned: store tag to first nibble */
store_tag1_parallel(TAG_GRANULE, mem, ptr_tag);
mem++;
tag_count--;
}
memset(mem, ptr_tag | (ptr_tag << 4), tag_count / 2);
if (tag_count & 1) {
/* Final trailing unaligned nibble */
mem += tag_count / 2;
store_tag1_parallel(0, mem, ptr_tag);
}
}