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.
* Fix module-linking handling of instance subtypes
When we alias the nth export of an instance, due to subtyping the nth
export may not actually be what we want. Instead we need to look at our
local type definition's nth export's name, and lookup that name off the
export.
* Update crates/wasmtime/src/instance.rs
Co-authored-by: Peter Huene <peter@huene.dev>
Co-authored-by: Peter Huene <peter@huene.dev>
* 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 commit is intended to do almost everything necessary for processing
the alias section of module linking. Most of this is internal
refactoring, the highlights being:
* Type contents are now stored separately from a `wasmtime_env::Module`.
Given that modules can freely alias types and have them used all over
the place, it seemed best to have one canonical location to type
storage which everywhere else points to (with indices). A new
`TypeTables` structure is produced during compilation which is shared
amongst all member modules in a wasm blob.
* Instantiation is heavily refactored to account for module linking. The
main gotcha here is that imports are now listed as "initializers". We
have a sort of pseudo-bytecode-interpreter which interprets the
initialization of a module. This is more complicated than just
matching imports at this point because in the module linking proposal
the module, alias, import, and instance sections may all be
interleaved. This means that imports aren't guaranteed to show up at
the beginning of the address space for modules/instances.
Otherwise most of the changes here largely fell out from these two
design points. Aliases are recorded as initializers in this scheme.
Copying around type information and/or just knowing type information
during compilation is also pretty easy since everything is just a
pointer into a `TypeTables` and we don't have to actually copy any types
themselves. Lots of various refactorings were necessary to accomodate
these changes.
Tests are hoped to cover a breadth of functionality here, but not
necessarily a depth. There's still one more piece of the module linking
proposal missing which is exporting instances/modules, which will come
in a future PR.
It's also worth nothing that there's one large TODO which isn't
implemented in this change that I plan on opening an issue for.
With module linking when a set of modules comes back from compilation
each modules has all the trampolines for the entire set of modules. This
is quite a lot of duplicate trampolines across module-linking modules.
We'll want to refactor this at some point to instead have only one set
of trampolines per set of module linking modules and have them shared
from there. I figured it was best to separate out this change, however,
since it's purely related to resource usage, and doesn't impact
non-module-linking modules at all.
cc #2094
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 implements the interpretation necessary of the instance
section of the module linking proposal. Instantiating a module which
itself has nested instantiated instances will now instantiate the nested
instances properly. This isn't all that useful without the ability to
alias exports off the result, but we can at least observe the side
effects of instantiation through the `start` function.
cc #2094
With the module linking proposal the field name on imports is now
optional, and only the module is required to be specified. This commit
propagates this API change to the boundary of wasmtime's API, ensuring
consumers are aware of what's optional with module linking and what
isn't. Note that it's expected that all existing users will either
update accordingly or unwrap the result since module linking is
presumably disabled.
If a host-defined `Func::new` closure returns values from the wrong
store, this currently trips a debug assertion and causes other issues
elsewhere in release mode. This commit adds the same dynamic checks
found in `Func::wrap` in the `Func::new` case today.
This fixes an issue where if a store-incompatible value is returned from
a host-defined function then that value is leaked. Practically this
means that it's possible to accidentally leak `Func` values, but a
simple insertion of a `drop` does the trick!
This commit fixes an issue with wasmtime where it was possible for a
trampoline from one module to get used for another module after it was
freed. This issue arises because we register a module's native
trampolines *before* it's fully instantiated, which is a fallible
process. Some fallibility is predictable, such as import type
mismatches, but other fallibility is less predictable, such as failure
to allocate a linear memory.
The problem happened when a module was registered with a `Store`,
retaining information about its trampolines, but then instantiation
failed and the module's code was never persisted within the `Store`.
Unlike as documented in #2374 the `Module` inside an `Instance` is not
the primary way to hold on to a module's code, but rather the
`Arc<ModuleCode>` is persisted within the global frame information off
on the side. This persistence only made its way into the store through
the `Box<Any>` field of `InstanceHandle`, but that's never made if
instantiation fails during import matching.
The fix here is to build on the refactoring of #2407 to not store module
code in frame information but rather explicitly in the `Store`.
Registration is now deferred until just-before an instance handle is
created, and during module registration we insert the `Arc<ModuleCode>`
into a set stored within the `Store`.
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 file has grown quite a lot with `Store` over time so this splits it
up into three separate files, one for each of the main types defined in
it: `Config`, `Engine`, and `Store`.
* 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.
When invoking a WebAssembly routine from Rust code, arguments
are stored into an array of u128, and read from a piece of
generated trampoline code before calling the compiled target
function using the platform ABI calling convention.
The WasmTy/WasmRet routines handle the conversion between Rust
data types and those u128 buffers. This currently works by
in effect converting the Rust object to a u128 and then storing
this u128 into the buffer. The generated trampoline code will
then read an object of appropriate type from the beginning of
that buffer.
This does not work on big-endian platforms, since the above
approach causes the value to be stored into the rightmost
bytes of the u128 buffer, while the trampoline code reads
the leftmost bytes.
This patch fixes the problem by changing WasmTy/WasmRet to
use the leftmost bytes as well, by casting the u128 pointer
to a pointer of the correct type before storing to it (or
reading from it).
(Note that it is not necessary to actually byte-swap the
values since the trampoline code will not treat them like
WebAssembly little-endian memory, but simply access them
in native byte order.)
We've generally moved to a model where `InstanceHandle` doesn't hold
ownership of its internals, instead relying on the caller to manage
that. This removes an allocation on the `Func::wrap` path but otherwise
shouldn't have much impact.
This commit adds lots of plumbing to get the type section from the
module linking proposal plumbed all the way through to the `wasmtime`
crate and the `wasmtime-c-api` crate. This isn't all that useful right
now because Wasmtime doesn't support imported/exported
modules/instances, but this is all necessary groundwork to getting that
exported at some point. I've added some light tests but I suspect the
bulk of the testing will come in a future commit.
One major change in this commit is that `SignatureIndex` no longer
follows type type index space in a wasm module. Instead a new
`TypeIndex` type is used to track that. Function signatures, still
indexed by `SignatureIndex`, are then packed together tightly.
This commit is intended to be the first of many in implementing the
module linking proposal. At this time this builds on #2059 so it
shouldn't land yet. The goal of this commit is to compile bare-bones
modules which use module linking, e.g. those with nested modules.
My hope with module linking is that almost everything in wasmtime only
needs mild refactorings to handle it. The goal is that all per-module
structures are still per-module and at the top level there's just a
`Vec` containing a bunch of modules. That's implemented currently where
`wasmtime::Module` contains `Arc<[CompiledModule]>` and an index of
which one it's pointing to. This should enable
serialization/deserialization of any module in a nested modules
scenario, no matter how you got it.
Tons of features of the module linking proposal are missing from this
commit. For example instantiation flat out doesn't work, nor does
import/export of modules or instances. That'll be coming as future
commits, but the purpose here is to start laying groundwork in Wasmtime
for handling lots of modules in lots of places.
This commit updates `wasmtime::FuncType` to exactly store an internal
`WasmFuncType` from the cranelift crates. This allows us to remove a
translation layer when we are given a `FuncType` and want to get an
internal cranelift type out as a result.
The other major change from this commit was changing the constructor and
accessors of `FuncType` to be iterator-based instead of exposing
implementation details.
After compilation there's actually no need to hold onto the native
signature for a wasm function type, so this commit moves out the
`ir::Signature` value from a `Module` into a separate field that's
deallocated when compilation is finished. This simplifies the
`SignatureRegistry` because it only needs to track wasm functino types
and it also means less work is done for `Func::wrap`.
The ModuleFrameInfo and FunctionInfo data structures maintain
a list of ranges via a BTreeMap. The key to that map is one
past the end of the module/function in question. This causes
a problem in the case of immediately adjacent ranges. For
example, if we have two functions occupying adjacent ranges:
A: 0-100
B: 100-200
function A is stored with a key of 100 and B with a key of 200.
Now, when looking up the function associated with address 100,
we'd expect to find B. However the current code:
let (end, func) = info.functions.range(pc..).next()?;
if pc < func.start || *end < pc {
will look up the value 100 in the map and return function A,
which will then fail the pc < func.start check in the next
line, so the result will be failure.
To fix this problem, make sure that the key used when
registering functions or modules is the address of the
last byte, not one past the end.
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.
This commit reduces the size of `InstructionAddressMap` from 24 bytes to
8 bytes by dropping the `code_len` field and reducing `code_offset` to
`u32` instead of `usize`. The intention is to primarily make the
in-memory version take up less space, and the hunch is that the
`code_len` is largely not necessary since most entries in this map are
always adjacent to one another. The `code_len` field is now implied by
the `code_offset` field of the next entry in the map.
This isn't as big of an improvement to serialized module size as #2321
or #2322, primarily because of the switch to variable-length encoding.
Despite this though it shaves about 10MB off the encoded size of the
module from #2318
This commit refactors where trampolines and signature information is
stored within a `Store`, namely moving them from
`wasmtime_runtime::Instance` instead to `Store` itself. The goal here is
to remove an allocation inside of an `Instance` and make them a bit
cheaper to create. Additionally this should open up future possibilities
like not creating duplicate trampolines for signatures already in the
`Store` when using `Func::new`.
Added in c4e10227de I think the original
reason (which I'm not entirely knowledgeable of) may no longer be
applicable? In any case this is a significant difference on Windows from
other platforms because it makes loads/stores of wasm code have manual
checks instead of relying on the guard page, causing runtime and
compile-time slowdowns on Windows-only.
I originally rediscovered this when investigating #2318 and saw that
both the compile time of the module in question and trap information
tables were much larger than they were on Linux. Removing this
Windows-specific configuration fixed the discrepancies and afterwards
Linux and Windows were basically the same.
Update `Module::{serialize,deserialize}` to use variable-length integers
with `bincode` to make the output artifacts smaller. Locally this
reduces the size of #2318 from 160 to 110 MB, a 30% decrease in size!
Deserialization performance is slightly slower, but seemingly within the
range of noise locally for me.
Similar to other data structures owned by the `Store` there's no need
for `Instance` to have a strong `Arc` reference, instead it's sufficient
for `Store` to have the owning reference.
There's no need to name each export since each synthetic instance we're
creating only has one export, so let's use the empty string which
doesn't require any allocations.
This commit adds initial (gated) support for the multi-memory wasm
proposal. This was actually quite easy since almost all of wasmtime
already expected multi-memory to be implemented one day. The only real
substantive change is the `memory.copy` intrinsic changes, which now
accounts for the source/destination memories possibly being different.
