* 2499: First pass on TableOps fuzzer generator wasm_encoder migration
- wasm binary generated via sections and smushed together into a module
- test: compare generated wat against expected wat
- note: doesn't work
- Grouped instructions not implemented
- Vec<u8> to wat String not implemented
* 2499: Add typesection, abstract instruction puts, and update test
- TableOp.insert now will interact with a function object directly
- add types for generated function
- expected test string now reflects expected generated code
* 2499: Mark unused index as _i
* 2499: Function insertion is in proper stack order, and fix off by 1
index
- imported functions must be typed
- instructions operate on a stack ie. define values as instructions
before using
* 2499: Apply suggestions from code review
- typo fixing
- oracle ingests binary bytes itself
Co-authored-by: Nick Fitzgerald <fitzgen@gmail.com>
* 2499: Code cleanup + renaming vars
- busywork, nothing to see here
Co-authored-by: Nick Fitzgerald <fitzgen@gmail.com>
This commit updates all the wasm-tools crates that we use and enables
fuzzing of the module linking proposal in our various fuzz targets. This
also refactors some of the dummy value generation logic to not be
fallible and to always succeed, the thinking being that we don't want to
accidentally hide errors while fuzzing. Additionally instantiation is
only allowed to fail with a `Trap`, other failure reasons are unwrapped.
The new crate introduced here, `wasmtime-bench-api`, creates a shared library, e.g. `wasmtime_bench_api.so`, for executing Wasm benchmarks using Wasmtime. It allows us to measure several phases separately by exposing `engine_compile_module`, `engine_instantiate_module`, and `engine_execute_module`, which pass around an opaque pointer to the internally initialized state. This state is initialized and freed by `engine_create` and `engine_free`, respectively. The API also introduces a way of passing in functions to satisfy the `"bench" "start"` and `"bench" "end"` symbols that we expect Wasm benchmarks to import. The API is exposed in a C-compatible way so that we can dynamically load it (carefully) in our benchmark runner.
It turns out that Souper does not allow a constant to be assigned to a variable,
they may only be used as operands. The 2.0.0 version of the `souper-ir` crate
correctly reflects this. In the `cranelift_codegen::souper_harvest` module, we
need to modify our Souper IR harvester so that it delays converting `iconst` and
`bconst` into Souper IR until their values are used as operands. Finally, some
unit tests in the `peepmatic-souper` crate need some small updates as well.
* Implement imported/exported modules/instances
This commit implements the final piece of the module linking proposal
which is to flesh out the support for importing/exporting instances and
modules. This ended up having a few changes:
* Two more `PrimaryMap` instances are now stored in an `Instance`. The value
for instances is `InstanceHandle` (pretty easy) and for modules it's
`Box<dyn Any>` (less easy).
* The custom host state for `InstanceHandle` for `wasmtime` is now
`Arc<TypeTables` to be able to fully reconstruct an instance's types
just from its instance.
* Type matching for imports now has been updated to take
instances/modules into account.
One of the main downsides of this implementation is that type matching
of imports is duplicated between wasmparser and wasmtime, leading to
posssible bugs especially in the subtelties of module linking. I'm not
sure how best to unify these two pieces of validation, however, and it
may be more trouble than it's worth.
cc #2094
* Update wat/wast/wasmparser
* Review comments
* Fix a bug in publish script to vendor the right witx
Currently there's two witx binaries in our repository given the two wasi
spec submodules, so this updates the publication script to vendor the
right one.
This PR adds a new fuzz target, `differential_wasmi`, that runs a
Cranelift-based Wasm backend alongside a simple third-party Wasm
interpeter crate (`wasmi`). The fuzzing runs the first function in a
given module to completion on each side, and then diffs the return value
and linear memory contents.
This strategy should provide end-to-end coverage including both the Wasm
translation to CLIF (which has seen some subtle and scary bugs at
times), the lowering from CLIF to VCode, the register allocation, and
the final code emission.
This PR also adds a feature `experimental_x64` to the fuzzing crate (and
the chain of dependencies down to `cranelift-codegen`) so that we can
fuzz the new x86-64 backend as well as the current one.
* Provide filename/line number information in `Trap`
This commit extends the `Trap` type and `Store` to retain DWARF debug
information found in a wasm file unconditionally, if it's present. This
then enables us to print filenames and line numbers which point back to
actual source code when a trap backtrace is printed. Additionally the
`FrameInfo` type has been souped up to return filename/line number
information as well.
The implementation here is pretty simplistic currently. The meat of all
the work happens in `gimli` and `addr2line`, and otherwise wasmtime is
just schlepping around bytes of dwarf debuginfo here and there!
The general goal here is to assist with debugging when using wasmtime
because filenames and line numbers are generally orders of magnitude
better even when you already have a stack trace. Another nicety here is
that backtraces will display inlined frames (learned through debug
information), improving the experience in release mode as well.
An example of this is that with this file:
```rust
fn main() {
panic!("hello");
}
```
we get this stack trace:
```
$ rustc foo.rs --target wasm32-wasi -g
$ cargo run foo.wasm
Finished dev [unoptimized + debuginfo] target(s) in 0.16s
Running `target/debug/wasmtime foo.wasm`
thread 'main' panicked at 'hello', foo.rs:2:5
note: run with `RUST_BACKTRACE=1` environment variable to display a backtrace
Error: failed to run main module `foo.wasm`
Caused by:
0: failed to invoke command default
1: wasm trap: unreachable
wasm backtrace:
0: 0x6c1c - panic_abort::__rust_start_panic::abort::h2d60298621b1ccbf
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/panic_abort/src/lib.rs:77:17
- __rust_start_panic
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/panic_abort/src/lib.rs:32:5
1: 0x68c7 - rust_panic
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:626:9
2: 0x65a1 - std::panicking::rust_panic_with_hook::h2345fb0909b53e12
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:596:5
3: 0x1436 - std::panicking::begin_panic::{{closure}}::h106f151a6db8c8fb
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:506:9
4: 0xda8 - std::sys_common::backtrace::__rust_end_short_backtrace::he55aa13f22782798
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/sys_common/backtrace.rs:153:18
5: 0x1324 - std::panicking::begin_panic::h1727e7d1d719c76f
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:505:12
6: 0xfde - foo::main::h2db1313a64510850
at /Users/acrichton/code/wasmtime/foo.rs:2:5
7: 0x11d5 - core::ops::function::FnOnce::call_once::h20ee1cc04aeff1fc
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/core/src/ops/function.rs:227:5
8: 0xddf - std::sys_common::backtrace::__rust_begin_short_backtrace::h054493e41e27e69c
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/sys_common/backtrace.rs:137:18
9: 0x1d5a - std::rt::lang_start::{{closure}}::hd83784448d3fcb42
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/rt.rs:66:18
10: 0x69d8 - core::ops::function::impls::<impl core::ops::function::FnOnce<A> for &F>::call_once::h564d3dad35014917
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/core/src/ops/function.rs:259:13
- std::panicking::try::do_call::hdca4832ace5a8603
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:381:40
- std::panicking::try::ha8624a1a6854b456
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panicking.rs:345:19
- std::panic::catch_unwind::h71421f57cf2bc688
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/panic.rs:382:14
- std::rt::lang_start_internal::h260050c92cd470af
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/rt.rs:51:25
11: 0x1d0c - std::rt::lang_start::h0b4bcf3c5e498224
at /rustc/7eac88abb2e57e752f3302f02be5f3ce3d7adfb4/library/std/src/rt.rs:65:5
12: 0xffc - <unknown>!__original_main
13: 0x393 - __muloti4
at /cargo/registry/src/github.com-1ecc6299db9ec823/compiler_builtins-0.1.35/src/macros.rs:269
```
This is relatively noisy by default but there's filenames and line
numbers! Additionally frame 10 can be seen to have lots of frames
inlined into it. All information is always available to the embedder but
we could try to handle the `__rust_begin_short_backtrace` and
`__rust_end_short_backtrace` markers to trim the backtrace by default as
well.
The only gotcha here is that it looks like `__muloti4` is out of place.
That's because the libc that Rust ships with doesn't have dwarf
information, although I'm not sure why we land in that function for
symbolizing it...
* Add a configuration switch for debuginfo
* Control debuginfo by default with `WASM_BACKTRACE_DETAILS`
* Try cpp_demangle on demangling as well
* Rename to WASMTIME_BACKTRACE_DETAILS
This commit deletes the old `snapshot_0` implementation of wasi-common,
along with the `wig` crate that was used to generate bindings for it.
This then reimplements `snapshot_0` in terms of
`wasi_snapshot_preview1`. There were very few changes between the two
snapshots:
* The `nlink` field of `FileStat` was increased from 32 to 64 bits.
* The `set` field of `whence` was reordered.
* Clock subscriptions in polling dropped their redundant userdata field.
This makes all of the syscalls relatively straightforward to simply
delegate to the next snapshot's implementation. Some trickery happens to
avoid extra cost when dealing with iovecs, but since the memory layout
of iovecs remained the same this should still work.
Now that `snapshot_0` is using wiggle we simply have a trait to
implement, and that's implemented for the same `WasiCtx` that has the
`wasi_snapshot_preview1` trait implemented for it as well. While this
theoretically means that you could share the file descriptor table
between the two snapshots that's not supported in the generated bindings
just yet. A separate `WasiCtx` will be created for each WASI module.
* Add an initial wasi-nn implementation for Wasmtime
This change adds a crate, `wasmtime-wasi-nn`, that uses `wiggle` to expose the current state of the wasi-nn API and `openvino` to implement the exposed functions. It includes an end-to-end test demonstrating how to do classification using wasi-nn:
- `crates/wasi-nn/tests/classification-example` contains Rust code that is compiled to the `wasm32-wasi` target and run with a Wasmtime embedding that exposes the wasi-nn calls
- the example uses Rust bindings for wasi-nn contained in `crates/wasi-nn/tests/wasi-nn-rust-bindings`; this crate contains code generated by `witx-bindgen` and eventually should be its own standalone crate
* Test wasi-nn as a CI step
This change adds:
- a GitHub action for installing OpenVINO
- a script, `ci/run-wasi-nn-example.sh`, to run the classification example
This commit removes the global variable associated with wasm traps which
stores frame information. The only purpose of this global is to help
symbolicate `Trap`s created since we support creating a `Trap` without a
`Store`. The global, however, is only used for wasm frames on the stack,
and when wasm frames are on the stack we know that our thread local for
"what was the last context" is set and configured.
The change here is to hijack this thread-local some more to effectively
store the `Store` inside of it. All frame information is then moved
directly into `Store` and no longer lives off on the side in a global.
Additionally support for registering/unregistering modules is now
simplified because once a module is registered with a store it can never
be unregistered.
This has one slight functional change where if there are two instances
of `Store` interleaving calls to wasm code on the stack we'll only be
able to symbolicate one of them instead of both. That's arguably also a
feature however because this is sort of a way to leak information across
stores right now.
Otherwise, though, this isn't intended to change any existing logic, but
instead keep everything working as-is.
* this requires upgrading to wasmparser 0.67.0.
* There are no CLIF side changes because the CLIF `select` instruction is
polymorphic enough.
* on aarch64, there is unfortunately no conditional-move (csel) instruction on
vectors. This patch adds a synthetic instruction `VecCSel` which *does*
behave like that. At emit time, this is emitted as an if-then-else diamond
(4 insns).
* aarch64 implementation is otherwise straightforwards.
This will hopefully remove a small thorn in our side with periodic
nightly breakage due to nightly features changing. This commit moves
lightbeam to stable Rust, swapping out `staticvec` for `arrayvec` and
otherwise updating some dependencies (namely `dynasm`) to compile with
stable.
This then also updates CI appropriately to not use a pinned nightly and
instead us a floating `nightly` channel so we can head off any breakage
coming up ASAP.
I don't think this has happened in awhile but I've run a `cargo update`
as well as trimming some of the duplicate/older dependencies in
`Cargo.lock` by updating some of our immediate dependencies as well.
Currently the runtime needs to acquire the current stack pointer so it
can set a limit for where if the wasm stack goes below that point it
will abort the wasm code. Acquiring the stack pointer is done in a
brittle way right now which involves looking at the address of what we
hope is an on-stack structure. This turns out to not work at all with
ASan as well.
Instead this commit switches to the `psm` crate which is used by the
Rust compiler team for stack manipulation, namely a coarse version of
segmented stacks to avoid stack overflow in the compiler. We don't need
most of the implementation of `psm`, just the `stack_pointer` function,
but it shouldn't be a burden to bring in!
Closes#2344
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.
* Rewrite interpreter generically
This change re-implements the Cranelift interpreter to use generic values; this makes it possible to do abstract interpretation of Cranelift instructions. In doing so, the interpretation state is extracted from the `Interpreter` structure and is accessed via a `State` trait; this makes it possible to not only more clearly observe the interpreter's state but also to interpret using a dummy state (e.g. `ImmutableRegisterState`). This addition made it possible to implement more of the Cranelift instructions (~70%, ignoring the x86-specific instructions).
* Replace macros with closures
This commit removes the binaryen support for fuzzing from wasmtime,
instead switching over to `wasm-smith`. In general it's great to have
what fuzzing we can, but our binaryen support suffers from a few issues:
* The Rust crate, binaryen-sys, seems largely unmaintained at this
point. While we could likely take ownership and/or send PRs to update
the crate it seems like the maintenance is largely on us at this point.
* Currently the binaryen-sys crate doesn't support fuzzing anything
beyond MVP wasm, but we're interested at least in features like bulk
memory and reference types. Additionally we'll also be interested in
features like module-linking. New features would require either
implementation work in binaryen or the binaryen-sys crate to support.
* We have 4-5 fuzz-bugs right now related to timeouts simply in
generating a module for wasmtime to fuzz. One investigation along
these lines in the past revealed a bug in binaryen itself, and in any
case these bugs would otherwise need to get investigated, reported,
and possibly fixed ourselves in upstream binaryen.
Overall I'm not sure at this point if maintaining binaryen fuzzing is
worth it with the advent of `wasm-smith` which has similar goals for
wasm module generation, but is much more readily maintainable on our
end.
Additonally in this commit I've added a fuzzer for wasm-smith's
`SwarmConfig`-based fuzzer which should expand the coverage of tested
modules.
Closes#2163
