* Make cranelift_codegen::isa::unwind::input public
* Move UnwindCode's common offset field out of the structure
* Make MachCompileResult::unwind_info more generic
* Record initial stack pointer offset
This patch implements, for aarch64, the following wasm SIMD extensions.
v128.load32_zero and v128.load64_zero instructions
https://github.com/WebAssembly/simd/pull/237
The changes are straightforward:
* no new CLIF instructions. They are translated into an existing CLIF scalar
load followed by a CLIF `scalar_to_vector`.
* the comment/specification for CLIF `scalar_to_vector` has been changed to
match the actual intended semantics, per consulation with Andrew Brown.
* translation from `scalar_to_vector` to aarch64 `fmov` instruction. This
has been generalised slightly so as to allow both 32- and 64-bit transfers.
* special-case zero in `lower_constant_f128` in order to avoid a
potentially slow call to `Inst::load_fp_constant128`.
* Once "Allow loads to merge into other operations during instruction
selection in MachInst backends"
(https://github.com/bytecodealliance/wasmtime/issues/2340) lands,
we can use that functionality to pattern match the two-CLIF pair and
emit a single AArch64 instruction.
* A simple filetest has been added.
There is no comprehensive testcase in this commit, because that is a separate
repo. The implementation has been tested, nevertheless.
This patch implements, for aarch64, the following wasm SIMD extensions
i32x4.dot_i16x8_s instruction
https://github.com/WebAssembly/simd/pull/127
It also updates dependencies as follows, in order that the new instruction can
be parsed, decoded, etc:
wat to 1.0.27
wast to 26.0.1
wasmparser to 0.65.0
wasmprinter to 0.2.12
The changes are straightforward:
* new CLIF instruction `widening_pairwise_dot_product_s`
* translation from wasm into `widening_pairwise_dot_product_s`
* new AArch64 instructions `smull`, `smull2` (part of the `VecRRR` group)
* translation from `widening_pairwise_dot_product_s` to `smull ; smull2 ; addv`
There is no testcase in this commit, because that is a separate repo. The
implementation has been tested, nevertheless.
In particular, introduce initial support for the MOVI and MVNI
instructions, with 8-bit elements. Also, treat vector constants
as 32- or 64-bit floating-point numbers, if their value allows
it, by relying on the architectural zero extension. Finally,
stop generating literal loads for 32-bit constants.
Copyright (c) 2020, Arm Limited.
This patch implements, for aarch64, the following wasm SIMD extensions
Floating-point rounding instructions
https://github.com/WebAssembly/simd/pull/232
Pseudo-Minimum and Pseudo-Maximum instructions
https://github.com/WebAssembly/simd/pull/122
The changes are straightforward:
* `build.rs`: the relevant tests have been enabled
* `cranelift/codegen/meta/src/shared/instructions.rs`: new CLIF instructions
`fmin_pseudo` and `fmax_pseudo`. The wasm rounding instructions do not need
any new CLIF instructions.
* `cranelift/wasm/src/code_translator.rs`: translation into CLIF; this is
pretty much the same as any other unary or binary vector instruction (for
the rounding and the pmin/max respectively)
* `cranelift/codegen/src/isa/aarch64/lower_inst.rs`:
- `fmin_pseudo` and `fmax_pseudo` are converted into a two instruction
sequence, `fcmpgt` followed by `bsl`
- the CLIF rounding instructions are converted to a suitable vector
`frint{n,z,p,m}` instruction.
* `cranelift/codegen/src/isa/aarch64/inst/mod.rs`: minor extension of `pub
enum VecMisc2` to handle the rounding operations. And corresponding `emit`
cases.
The `bitmask.{8x16,16x8,32x4}` instructions do not map neatly to any single
AArch64 SIMD instruction, and instead need a sequence of around ten
instructions. Because of this, this patch is somewhat longer and more complex
than it would be for (eg) x64.
Main changes are:
* the relevant testsuite test (`simd_boolean.wast`) has been enabled on aarch64.
* at the CLIF level, add a new instruction `vhigh_bits`, into which these wasm
instructions are to be translated.
* in the wasm->CLIF translation (code_translator.rs), translate into
`vhigh_bits`. This is straightforward.
* in the CLIF->AArch64 translation (lower_inst.rs), translate `vhigh_bits`
into equivalent sequences of AArch64 instructions. There is a different
sequence for each of the `{8x16, 16x8, 32x4}` variants.
All other changes are AArch64-specific, and add instruction definitions needed
by the previous step:
* Add two new families of AArch64 instructions: `VecShiftImm` (vector shift by
immediate) and `VecExtract` (effectively a double-length vector shift)
* To the existing AArch64 family `VecRRR`, add a `zip1` variant. To the
`VecLanesOp` family add an `addv` variant.
* Add supporting code for the above changes to AArch64 instructions:
- getting the register uses (`aarch64_get_regs`)
- mapping the registers (`aarch64_map_regs`)
- printing instructions
- emitting instructions (`impl MachInstEmit for Inst`). The handling of
`VecShiftImm` is a bit complex.
- emission tests for new instructions and variants.
It corresponds to WebAssembly's `load*_splat` operations, which
were previously represented as a combination of `Load` and `Splat`
instructions. However, there are architectures such as Armv8-A
that have a single machine instruction equivalent to the Wasm
operations. In order to generate it, it is necessary to merge the
`Load` and the `Splat` in the backend, which is not possible
because the load may have side effects. The new IR instruction
works around this limitation.
The AArch64 backend leverages the new instruction to improve code
generation.
Copyright (c) 2020, Arm Limited.
A new associated type Info is added to MachInstEmit, which is the
immutable counterpart to State. It can't easily be constructed from an
ABICallee, since it would require adding an associated type to the
latter, and making so leaks the associated type in a lot of places in
the code base and makes the code harder to read. Instead, the EmitInfo
state can simply be passed to the `Vcode::emit` function directly.
This PR updates the AArch64 ABI implementation so that it (i) properly
respects that v8-v15 inclusive have callee-save lower halves, and
caller-save upper halves, by conservatively approximating (to full
registers) in the appropriate directions when generating prologue
caller-saves and when informing the regalloc of clobbered regs across
callsites.
In order to prevent saving all of these vector registers in the prologue
of every non-leaf function due to the above approximation, this also
makes use of a new regalloc.rs feature to exclude call instructions'
writes from the clobber set returned by register allocation. This is
safe whenever the caller and callee have the same ABI (because anything
the callee could clobber, the caller is allowed to clobber as well
without saving it in the prologue).
Fixes#2254.
Previously, in #2128, we factored out a common "vanilla 64-bit ABI"
implementation from the AArch64 ABI code, with the idea that this should
be largely compatible with x64. This PR alters the new x64 backend to
make use of the shared infrastructure, removing the duplication that
existed previously. The generated code is nearly (not exactly) the same;
the only difference relates to how the clobber-save region is padded in
the prologue.
This also changes some register allocations in the aarch64 code because
call support in the shared ABI infra now passes a temp vreg in, rather
than requiring use of a fixed, non-allocable temp; tests have been
updated, and the runtime behavior is unchanged.
This commit performs a small cleanup in the AArch64 backend - after
the MAdd and MSub variants have been extracted, the ALUOp enum is
used purely for binary integer operations.
Also, Inst::Mov has been renamed to Inst::Mov64 for consistency.
Copyright (c) 2020, Arm Limited.
It does this by providing an implementation of the CLIF instructions `AtomicRmw`, `AtomicCas`,
`AtomicLoad`, `AtomicStore` and `Fence`.
The translation is straightforward. `AtomicCas` is translated into x64 `cmpxchg`, `AtomicLoad`
becomes a normal load because x64-TSO provides adequate sequencing, `AtomicStore` becomes a
normal store followed by `mfence`, and `Fence` becomes `mfence`. `AtomicRmw` is the only
complex case: it becomes a normal load, followed by a loop which computes an updated value,
tries to `cmpxchg` it back to memory, and repeats if necessary.
This is a minimum-effort initial implementation. `AtomicRmw` could be implemented more
efficiently using LOCK-prefixed integer read-modify-write instructions in the case where the old
value in memory is not required. Subsequent work could add that, if required.
The x64 emitter has been updated to emit the new instructions, obviously. The `LegacyPrefix`
mechanism has been revised to handle multiple prefix bytes, not just one, since it is now
sometimes necessary to emit both 0x66 (Operand Size Override) and F0 (Lock).
In the aarch64 implementation of atomics, there has been some minor renaming for the sake of
clarity, and for consistency with this x64 implementation.
We have observed that the ABI implementations for AArch64 and x64 are
very similar; in fact, x64's implementation started as a modified copy
of AArch64's implementation. This is an artifact of both a similar ABI
(both machines pass args and return values in registers first, then the
stack, and both machines give considerable freedom with stack-frame
layout) and a too-low-level ABI abstraction in the existing design. For
machines that fit the mainstream or most common ABI-design idioms, we
should be able to do much better.
This commit factors AArch64 into machine-specific and
machine-independent parts, but does not yet modify x64; that will come
next.
This should be completely neutral with respect to compile time and
generated code performance.
The implementation is pretty straightforward. Wasm atomic instructions fall
into 5 groups
* atomic read-modify-write
* atomic compare-and-swap
* atomic loads
* atomic stores
* fences
and the implementation mirrors that structure, at both the CLIF and AArch64
levels.
At the CLIF level, there are five new instructions, one for each group. Some
comments about these:
* for those that take addresses (all except fences), the address is contained
entirely in a single `Value`; there is no offset field as there is with
normal loads and stores. Wasm atomics require alignment checks, and
removing the offset makes implementation of those checks a bit simpler.
* atomic loads and stores get their own instructions, rather than reusing the
existing load and store instructions, for two reasons:
- per above comment, makes alignment checking simpler
- reuse of existing loads and stores would require extension of `MemFlags`
to indicate atomicity, which sounds semantically unclean. For example,
then *any* instruction carrying `MemFlags` could be marked as atomic, even
in cases where it is meaningless or ambiguous.
* I tried to specify, in comments, the behaviour of these instructions as
tightly as I could. Unfortunately there is no way (per my limited CLIF
knowledge) to enforce the constraint that they may only be used on I8, I16,
I32 and I64 types, and in particular not on floating point or vector types.
The translation from Wasm to CLIF, in `code_translator.rs` is unremarkable.
At the AArch64 level, there are also five new instructions, one for each
group. All of them except `::Fence` contain multiple real machine
instructions. Atomic r-m-w and atomic c-a-s are emitted as the usual
load-linked store-conditional loops, guarded at both ends by memory fences.
Atomic loads and stores are emitted as a load preceded by a fence, and a store
followed by a fence, respectively. The amount of fencing may be overkill, but
it reflects exactly what the SM Wasm baseline compiler for AArch64 does.
One reason to implement r-m-w and c-a-s as a single insn which is expanded
only at emission time is that we must be very careful what instructions we
allow in between the load-linked and store-conditional. In particular, we
cannot allow *any* extra memory transactions in there, since -- particularly
on low-end hardware -- that might cause the transaction to fail, hence
deadlocking the generated code. That implies that we can't present the LL/SC
loop to the register allocator as its constituent instructions, since it might
insert spills anywhere. Hence we must present it as a single indivisible
unit, as we do here. It also has the benefit of reducing the total amount of
work the RA has to do.
The only other notable feature of the r-m-w and c-a-s translations into
AArch64 code, is that they both need a scratch register internally. Rather
than faking one up by claiming, in `get_regs` that it modifies an extra
scratch register, and having to have a dummy initialisation of it, these new
instructions (`::LLSC` and `::CAS`) simply use fixed registers in the range
x24-x28. We rely on the RA's ability to coalesce V<-->R copies to make the
cost of the resulting extra copies zero or almost zero. x24-x28 are chosen so
as to be call-clobbered, hence their use is less likely to interfere with long
live ranges that span calls.
One subtlety regarding the use of completely fixed input and output registers
is that we must be careful how the surrounding copy from/to of the arg/result
registers is done. In particular, it is not safe to simply emit copies in
some arbitrary order if one of the arg registers is a real reg. For that
reason, the arguments are first moved into virtual regs if they are not
already there, using a new method `<LowerCtx for Lower>::ensure_in_vreg`.
Again, we rely on coalescing to turn them into no-ops in the common case.
There is also a ridealong fix for the AArch64 lowering case for
`Opcode::Trapif | Opcode::Trapff`, which removes a bug in which two trap insns
in a row were generated.
In the patch as submitted there are 6 "FIXME JRS" comments, which mark things
which I believe to be correct, but for which I would appreciate a second
opinion. Unless otherwise directed, I will remove them for the final commit
but leave the associated code/comments unchanged.
It seems that this is actually the correct behavior for bool types wider
than `b1`; some of the vector instruction optimizations depend on bool
lanes representing false and true as all-zeroes and all-ones
respectively. For `b8`..`b64`, this results in an extra negation after a
`cset` when a bool is produced by an `icmp`/`fcmp`, but the most common
case (`b1`) is unaffected, because an all-ones one-bit value is just
`1`.
An example of this assumption can be seen here:
399ee0a54c/cranelift/codegen/src/simple_preopt.rs (L956)
Thanks to Joey Gouly of ARM for noting this issue while implementing
SIMD support, and digging into the source (finding the above example) to
determine the correct behavior.
We had previously fixed a bug in which constant shift amounts should be
masked to modulo the number of bits in the operand; however, we did not
fix the analogous case for shifts incorporated into the second register
argument of ALU instructions that support integrated shifts. This
failure to mask resulted in illegal instructions being generated, e.g.
in https://bugzilla.mozilla.org/show_bug.cgi?id=1653502. This PR fixes
the issue by masking the amount, as the shift semantics require.
This commit adds support for generating stackmaps at safepoints to the
new backend framework and to the AArch64 backend in particular. It has
been tested to work with SpiderMonkey.
This commit adds the inital support to allow reftypes to flow through
the program when targetting aarch64. It also adds a fix to the
`ModuleTranslationState` needed to send R32/R64 types over from the
SpiderMonkey embedding.
This commit does not include any support for safepoints in aarch64
or the `MachInst` infrastructure; that is in the next commit.
This commit also makes a drive-by improvement to `Bint`, avoiding an
unneeded zero-extension op when the extended value comes directly from a
conditional-set (which produces a full-width 0 or 1).
The main issue with the InstSize enum was that it was used both for
GPR and SIMD & FP operands, even though machine instructions do not
mix them in general (as in a destination register is either a GPR
or not). As a result it had methods such as sf_bit() that made
sense only for one type of operand.
Another issue was that the enum name was not reflecting its purpose
accurately - it was meant to represent an instruction operand size,
not an instruction size, which is fixed in A64 (always 4 bytes).
Now the enum is split into one for GPR operands and another for
scalar SIMD & FP operands.
Copyright (c) 2020, Arm Limited.
The ARM book says that the immr field should contain (-count % 64); the
existing code was approximating this with (64 - count), which is not
correct for a zero count.
- put the division in the synthetic instruction as well,
- put the branch table check in the inst's emission code,
- replace OneWayCondJmp by TrapIf vcode instruction,
- add comments describing code generated by the synthetic instructions
