It is no longer used, so tidy up everything reached by it.
This includes the gen_opc_* arrays, the search_pc parameter
and the inline gen_intermediate_code_internal functions.
Backports commit 4e5e1215156662b2b153255c49d4640d82c5568b from qemu
The gen_opc_* arrays are already redundant with the data stored in
the insn_start arguments. Transition restore_state_to_opc to use
data from the latter.
Backports commit bad729e272387de7dbfa3ec4319036552fc6c107 from qemu
The only generic code relying on this is linux-user. Linux user
already has a lot of #ifdef TARGET_ customisation so instead, define
ELF_ARCH as either EM_ARM or EM_AARCH64 appropriately.
The armv7m bootloader can just pass EM_ARM directly, as that
is architecture specific code. Note that arm_boot already has its own
logic selecting an arm specific elf machine so this makes V7M more
consistent with arm_boot.
This removes another architecture specific definition from the global
namespace.
Backports commit b597c3f7da17fcb37d394a16a6c0ef0a02846177 from qemu
Break out mpidr_read_val() to allow future sharing of the
code that conditionally sets the M and U bits of MPIDR.
No functional changes.
Backports commit 06a7e6477c129ceaa72bd400cf281d44c456be43 from qemu
Stage-2 MMU translations do not have configurable TBI as
the top byte is always 0 (48-bit IPAs).
Backports commit 1edee4708a0e3163cbf20fac325be456abd960bb from qemu
This is set to true when the index is for an instruction fetch
translation.
The core get_page_addr_code() sets it, as do the SOFTMMU_CODE_ACCESS
acessors.
All targets ignore it for now, and all other callers pass "false".
This will allow targets who wish to split the mmu index between
instruction and data accesses to do so. A subsequent patch will
do just that for PowerPC.
Backports commit 97ed5ccdee95f0b98bedc601ff979e368583472c from qemu
Log the target EL when taking exceptions. This is useful when
debugging guest SW or QEMU itself while transitioning through
the various ELs.
Backports commit dbc29a868cf5b7e6fa7bb2e6c4f188b9470779c5 from qemu
If EL3 is not supported in current configuration,
we should not try to get EL3 bitness.
Backports commit cef9ee706792b1e205fe472b67053a0e82cd058e from qemu
Introduces reusable definitions for CPU affinity masks/shifts and gets rid
of hardcoded magic numbers.
Backports commit 0f4a9e45ec35811ee250ac232d84d3c6d4fcd7fc from qemu
There is an error in arm_excp_unmasked() function:
bitwise operator & is used with integer and bool operands
causing an incorrect zeroed result.
The patch fixes it.
Backports commit 771842585f3119f69641ed90a97d56eb9ed6f5ae from qemu
There is an error in functions aarch64_sync_32_to_64() and
aarch64_sync_64_to_32() with mapping of registers between AArch32 and
AArch64. This commit fixes the mapping to match the v8 ARM ARM
section D1.20.1 (table D1-77).
Backports commit 3a9148d0bdcee990fbe86759b9b1f5723c1d7fbc from qemu
All of these hw_errors are fatal and indicate something wrong with
QEMU implementation.
Convert to g_assert_not_reached.
Backports commit 8f6fd322f6e25995629a1a07b56bc5b91fb947ca from qemu
For the A64 instruction set, the semihosting call instruction
is 'HLT 0xf000'. Wire this up to call do_arm_semihosting()
if semihosting is enabled.
Backports commit 8012c84ff92a36d05dfe61af9b24dd01a7ea25e4 from qemu
The 64-bit A64 semihosting API has some pervasive changes from
the 32-bit version:
* all parameter blocks are arrays of 64-bit values, not 32-bit
* the semihosting call number is passed in W0
* the return value is a 64-bit value in X0
Implement the necessary handling for this widening.
Backports relevant parts of commit faacc041619581c566c21ed87aa1933420731282 from qemu
Print semihosting debugging information before the
do_arm_semihosting() call so that angel_SWIreason_ReportException,
which causes the function to not return, gets the same debug prints as
other semihosting calls. Also print out the semihosting call number.
Backports commit 205ace55ffff77964e50af08c99639ec47db53f6 from qemu
Implement the AArch64 TLBI operations which take an intermediate
physical address and invalidate stage 2 translations.
Backports commit cea66e91212164e02ad1d245c2371f7e8eb59e7f from qemu
Now we have the ability to flush the TLB only for specific MMU indexes,
update the AArch64 TLB maintenance instruction implementations to only
flush the parts of the TLB they need to, rather than doing full flushes.
We take the opportunity to remove some duplicate functions (the per-asid
tlb ops work like the non-per-asid ones because we don't support
flushing a TLB only by ASID) and to bring the function names in line
with the architectural TLBI operation names.
Backports commit fd3ed969227f54f08f87d9eb6de2d4e48e99279b from qemu
Move the two regdefs for TLBI ALLE1 and TLBI ALLE1IS down so that the
whole set of AArch64 TLBI regdefs is arranged in numeric order.
Backports commit 83ddf975777cc23337b7ef92e83b1b9c949396f3 from qemu
Apply the correct conditions in the ats_access() function for
the ATS12NSO* address translation operations:
* succeed at EL2 or EL3
* normal UNDEF trap from NS EL1
* trap to EL3 from S EL1 (only possible if EL3 is AArch64)
(This change means they're now available in our EL3-supporting
CPUs when they would previously always UNDEF.)
Backports commit 87562e4f4a2bdd028eef3549ce9cb4e7c83cb0bf from qemu
Some coprocessor register access functions need to be able
to report "trap to EL3 with an 'uncategorized' syndrome";
add the necessary CPAccessResult enum and handling for it.
I don't currently know of any registers that need to trap
to EL2 with the 'uncategorized' syndrome, but adding the
_EL2 enum as well is trivial and fills in what would
otherwise be an odd gap in the handling.
Backports commit e76157264da20b85698b09fa5eb8e02e515e232c from qemu
Wire up the AArch64 EL2 and EL3 address translation operations
(AT S12E1*, AT S12E0*, AT S1E2*, AT S1E3*), and correct some
errors in the ats_write64() function in previously unused code
that would have done the wrong kind of lookup for accesses from
EL3 when SCR.NS==0.
Backports commit 2a47df953202e1f226aa045ea974427c4540a167 from qemu
For EL2 stage 1 translations, there is no TTBR1. We were already
handling this for 64-bit EL2; add the code to take the 'no TTBR1'
code path for 64-bit EL2 as well.
Backports commit d0a2cbceb2aa20d64d53e1c20c7d26a78ade8382 from qemu
We already implemented ACTLR_EL1; add the missing ACTLR_EL2 and
ACTLR_EL3, for consistency.
Since we don't currently have any CPUs that need the EL2/EL3
versions to reset to non-zero values, implement as RAZ/WI.
Backports commit 834a6c6920316d39aaf0e68ac936c0a3ad164815 from qemu
The AFSR registers are implementation dependent auxiliary fault
status registers. We already implemented a RAZ/WI AFSR0_EL1 and
AFSR_EL1; add the missing AFSR{0,1}_EL{2,3} for consistency.
Backports commit 37cd6c2478196623ca28526627ca8c69afe0d654 from qemu
The AMAIR registers are for providing auxiliary implementation
defined memory attributes. We already implemented a RAZ/WI
AMAIR_EL1; add the EL2 and EL3 versions for consistency.
Backports commit 2179ef958c81480b841ffa0aab5e265688ffd2b0 from qemu
Add the AArch64 registers MAIR_EL3 and TPIDR_EL3, which are the only
two which we had implemented the 32-bit Secure equivalents of but
not the 64-bit Secure versions.
Backports commit 4cfb8ad896a6f85953038bd913ce3d82d347013d from qemu
If EL3 is AArch32, then the secure physical timer is accessed via
banking of the registers used for the non-secure physical timer.
Implement this banking.
Note that the access controls for the AArch32 banked registers
remain the same as the physical-timer checks; they are not the
same as the controls on the AArch64 secure timer registers.
Backports commit 9ff9dd3c875956523bb4c19ca712e5d05aab3c65 from qemu
On CPUs with EL3, there are two physical timers, one for Secure and one
for Non-secure. Implement this extra timer and the AArch64 registers
which access it.
Backports commit b4d3978c2fdf944e428a46d2850dbd950b6fbe78 from qemu
It's easy to accidentally define two cpregs which both try
to reset the same underlying state field (for instance a
clash between an AArch64 EL3 definition and an AArch32
banked register definition). if the two definitions disagree
about the reset value then the result is dependent on which
one happened to be reached last in the hashtable enumeration.
Add a consistency check to detect and assert in these cases:
after reset, we run a second pass where we check that the
reset operation doesn't change the value of the register.
Backports commit 49a661910c1374858602a3002b67115893673c25 from qemu
Rename gt_cnt_reset to gt_timer_reset as the function really
resets the timers and not the counters. Move the registration
from counter regs to timer regs.
Backports commit d57b9ee84f6b2786f025712609edb259d0de086d from qemu
The SCTLR_EL3 cpreg definition was implicitly resetting the
register state to 0, which is both wrong and clashes with
the reset done via the SCTLR definition (since sctlr[3]
is unioned with sctlr_s). This went unnoticed until recently,
when an unrelated change (commit a903c449b41f105aa) happened to
perturb the order of enumeration through the cpregs hashtable for
reset such that the erroneous reset happened after the correct one
rather than before it. Fix this by marking SCTLR_EL3 as an alias,
so its reset is left up to the AArch32 view.
Backports commit e46e1a74ef482f1ef773e750df9654ef4442ca29 from qemu
Remove un-needed usages of ENV_GET_CPU() by converting the APIs to use
CPUState pointers and retrieving the env_ptr as minimally needed.
Scripted conversion for target-* change:
for I in target-*/cpu.h; do
sed -i \
's/\(^int cpu_[^_]*_exec(\)[^ ][^ ]* \*s);$/\1CPUState *cpu);/' \
$I;
done
Backports commit ea3e9847408131abc840240bd61e892d28459452 from qemu
The callers (most of them in target-foo/cpu.c) to this function all
have the cpu pointer handy. Just pass it to avoid an ENV_GET_CPU() from
core code (in exec.c).
Backports commit 4bad9e392e788a218967167a38ce2ae7a32a6231 from qemu