Whenever we notice that a counter overflow has occurred, send an
interrupt. This is made more reliable with the addition of a timer in a
follow-on commit.
Backports commit f4efb4b2a17528837cb445f9bdfaef8df4a5acf7 from qemu
In disas_simd_indexed(), for the case of "complex fp", each indexable
element is a complex pair, so the total size is twice that indicated
in the 'size' field in the encoding. We were trying to do this
"double the size" operation with a left shift by 1, but this is
incorrect because the 'size' field is a MO_8/MO_16/MO_32/MO_64
value, and doubling the size should be done by a simple increment.
This meant we were mishandling FCMLA (by element) of values where
the real and imaginary parts are 32-bit floats, and would incorrectly
UNDEF this encoding. (No other insns take this code path, and for
16-bit floats it happens that 1 << 1 and 1 + 1 are both the same).
Backports commit eaefb97a8b97dbf42c016fe65b68b92f99a346f6 from qemu
The FCMLA (by element) instruction exists in the
"vector x indexed element" encoding group, but not in
the "scalar x indexed element" group. Correctly UNDEF
the unallocated encodings.
Backports commit 4dfabb6d568e6b315594d7d464dacaf3368aff60 from qemu
In the AdvSIMD scalar x indexed element and vector x indexed element
encoding group, the SDOT and UDOT instructions are vector only,
and their opcode is unallocated in the scalar group. Correctly
UNDEF this unallocated encoding.
Backports commit 4977986ca38fb1d5357532e1a8032b984047a369 from qemu
In the encoding groups
* floating-point data-processing (1 source)
* floating-point data-processing (2 source)
* floating-point data-processing (3 source)
* floating-point immediate
* floating-point compare
* floating-ponit conditional compare
* floating-point conditional select
bit 31 is M and bit 29 is S (and bit 30 is 0, already checked at
this point in the decode). None of these groups allocate any
encoding for M=1 or S=1. We checked this in disas_fp_compare(),
disas_fp_ccomp() and disas_fp_csel(), but missed it in disas_fp_1src(),
disas_fp_2src(), disas_fp_3src() and disas_fp_imm().
We also missed that in the fp immediate encoding the imm5 field
must be all zeroes.
Correctly UNDEF the unallocated encodings here.
Backports commit c1e20801f5ee53472dbf2757df605543f3f4ce0b from qemu
In the "add/subtract (extended register)" encoding group, the "opt"
field in bits [23:22] must be zero. Correctly UNDEF the unallocated
encodings where this field is not zero.
Backports commit 4f61106614410945b1d1c93081544ad5b13044fc from qemu
In the AdvSIMD load/store single structure encodings, the
non-post-indexed case should have zeroes in [20:16] (which is the
Rm field for the post-indexed case). Bit 31 must also be zero
(a check we got right in ldst_multiple but not here). Correctly
UNDEF these unallocated encodings.
Backports commit 9c72b68ad746a51f63822cffab4d144b5957823a from qemu
In the AdvSIMD load/store multiple structures encodings,
the non-post-indexed case should have zeroes in [20:16]
(which is the Rm field for the post-indexed case).
Correctly UNDEF the currently unallocated encodings which
have non-zeroes in those bits.
Backports commit e1f220811dbd5d85fb02ff286358f9ee6188938f from qemu
The PRFM prefetch insn in the load/store with imm9 encodings
requires idx field 0b00; we were underdecoding this by
only checking !is_unpriv (which is equivalent to idx != 2).
Correctly UNDEF the unallocated encodings where idx == 0b01
and 0b11 as well as 0b10.
Backports commit a80c4256543987ca88407349ee012a673a10a2ae from qemu
The "system instructions" and "system register move" subcategories
of "branches, exception generating and system instructions" for A64
only apply if bits [23:22] are zero; other values are currently
unallocated. Correctly UNDEF these unallocated encodings.
Backports commit 08d5e3bde6b4ad32996bf69d93aa66ae43d3f3ff from qemu
It's either "GNU *Library* General Public License version 2" or
"GNU Lesser General Public License version *2.1*", but there was
no "version 2.0" of the "Lesser" license. So assume that version
2.1 is meant here.
Also some files mention the GPL instead of the LGPL after declaring
that the files are licensed under the LGPL, so change these spots to
use LGPL, too.
Backports commit d749fb85bd35f2f175a4ed3d170561e4f54f7297 from qemu
It's either "GNU *Library* General Public version 2" or "GNU Lesser
General Public version *2.1*", but there was no "version 2.0" of the
"Lesser" library. So assume that version 2.1 is meant here.
Backports commit fb0343d5b4dd4b9b9e96e563d913a3e0c709fe4e from qemu
Some files claim that the code is licensed under the GPL, but then
suddenly suggest that the user should have a look at the LGPL.
That's of course non-sense, replace it with the correct GPL wording
instead.
Backports commit e361a772ffcd33675ffdd4637eea98a460dfed1b from qemu
Modern AMD CPUs support NPT and NRIPSAVE features and KVM exposes these
when present. NRIPSAVE apeared somewhere in Opteron_G3 lifetime (e.g.
QuadCore AMD Opteron 2378 has is but QuadCore AMD Opteron HE 2344 doesn't),
NPT was introduced a bit earlier.
Add the FEAT_SVM leaf to Opteron_G4/G5 and EPYC/EPYC-IBPB cpu models.
Backports commit 9fe8b7be17eaac4cfde4083000cc96747d7cf4f8 from qemu
Update the stepping from 5 to 6, in order that
the Cascadelake-Server CPU model can support AVX512VNNI
and MSR based features exposed by ARCH_CAPABILITIES.
Backports commit b0a1980384fc265d91de7e09aa5fe531a69e6288 from qemu
For TCG we want to distinguish which cluster a CPU is in, and
we need to do it quickly. Cache the cluster index in the CPUState
struct, by having the cluster object set cpu->cluster_index for
each CPU child when it is realized.
This means that board/SoC code must add all CPUs to the cluster
before realizing the cluster object. Regrettably QOM provides no
way to prevent adding children to a realized object and no way for
the parent to be notified when a new child is added to it, so
we don't have any way to enforce/assert this constraint; all
we can do is document it in a comment. We can at least put in a
check that the cluster contains at least one CPU, which should
catch the typical cases of "realized cluster too early" or
"forgot to parent the CPUs into it".
The restriction on how many clusters can exist in the system
is imposed by TCG code which will be added in a subsequent commit,
but the check to enforce it in cluster.c fits better in this one.
Backports relevant parts of commit 7ea7b9ad532e59c3efbcabff0e3484f4df06104c from qemu
A bug was introduced during a respin of:
commit 57a4a11b2b281bb548b419ca81bfafb214e4c77a
target/arm: Add array for supported PMU events, generate PMCEID[01]_EL0
This patch introduced two calls to get_pmceid() during CPU
initialization - one each for PMCEID0 and PMCEID1. In addition to
building the register values, get_pmceid() clears an internal array
mapping event numbers to their implementations (supported_event_map)
before rebuilding it. This is an optimization since much of the logic is
shared. However, since it was called twice, the contents of
supported_event_map reflect only the events in PMCEID1 (the second call
to get_pmceid()).
Fix this bug by moving the initialization of PMCEID0 and PMCEID1 back
into a single function call, and name it more appropriately since it is
doing more than simply generating the contents of the PMCEID[01]
registers.
Backports commit bf8d09694ccc07487cd73d7562081fdaec3370c8 from qemu
In the softmmu version of cpu_memory_rw_debug(), we ask the
CPU for the attributes to use for the virtual memory access,
and we correctly use those to identify the address space
index. However, we were not passing them in to the
address_space_write_rom() and address_space_rw() functions.
The effect of this was that a memory access from the gdbstub
to a device which had behaviour that was sensitive to the
memory attributes (such as some ARMv8M NVIC registers) was
incorrectly always performed as if non-secure, rather than
using the right security state for the CPU's current state.
Fixes: https://bugs.launchpad.net/qemu/+bug/1812091
Backports commit ea7a5330b79523540ba776c529b09dc8cf3fa0c5 from qemu
When tsz == 0, aarch32 selects the address space via exclusion,
and there are no "top_bits" remaining that require validation.
Fixes: ba97be9f4a4
Backports commit 36d820af0eddf4fc6a533579b052d8f0085a9fb8 from qemu
The avx instruction set does not directly provide MO_64.
We can still implement 64-bit with comparison and vpblendvb.
Backports commit bc37faf4cb2baa77c44298c01558970b88d32808 from qemu
Only MO_8 and MO_16 are implemented, since that's all the
instruction set provides.
Backports commit 8ffafbcec275e61f6a1a17ac1d0bd918d5b23db3 from qemu
We handle many of these during integer expansion, and the
rest of them during integer optimization.
Backports commit 9a9eda78e4e56051485efb65e01748084f99ac3c from qemu
Strictly speaking, as far as the standard care, performing pointer
arithmetic on a void* type is ill formed. This is a GNU extension that
allows this. Instead, just use unsigned char* which preserves the same
behavior.
Python 3 versions earlier than 3.4 do not have it, use the
same workaround that is in place for 3.0.
Backports commit 651514df88fd53d537b3b78a7548663cc0816b1b from qemu
Add I6500 core configuration. Note that this configuration is
supported only on best-effort basis due to the lack of certain
features in QEMU.
Backports commit ca1ffd14ed8a11ad88619c0478e5ea58f0af5137 from qemu