2afaac5181f4b73e86fac39d095c84a9b8e59129
17 Commits
| Author | SHA1 | Message | Date | |
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Alex Crichton
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2afaac5181 |
Return anyhow::Error from host functions instead of Trap, redesign Trap (#5149)
* Return `anyhow::Error` from host functions instead of `Trap` This commit refactors how errors are modeled when returned from host functions and additionally refactors how custom errors work with `Trap`. At a high level functions in Wasmtime that previously worked with `Result<T, Trap>` now work with `Result<T>` instead where the error is `anyhow::Error`. This includes functions such as: * Host-defined functions in a `Linker<T>` * `TypedFunc::call` * Host-related callbacks like call hooks Errors are now modeled primarily as `anyhow::Error` throughout Wasmtime. This subsequently removes the need for `Trap` to have the ability to represent all host-defined errors as it previously did. Consequently the `From` implementations for any error into a `Trap` have been removed here and the only embedder-defined way to create a `Trap` is to use `Trap::new` with a custom string. After this commit the distinction between a `Trap` and a host error is the wasm backtrace that it contains. Previously all errors in host functions would flow through a `Trap` and get a wasm backtrace attached to them, but now this only happens if a `Trap` itself is created meaning that arbitrary host-defined errors flowing from a host import to the other side won't get backtraces attached. Some internals of Wasmtime itself were updated or preserved to use `Trap::new` to capture a backtrace where it seemed useful, such as when fuel runs out. The main motivation for this commit is that it now enables hosts to thread a concrete error type from a host function all the way through to where a wasm function was invoked. Previously this could not be done since the host error was wrapped in a `Trap` that didn't provide the ability to get at the internals. A consequence of this commit is that when a host error is returned that isn't a `Trap` we'll capture a backtrace and then won't have a `Trap` to attach it to. To avoid losing the contextual information this commit uses the `Error::context` method to attach the backtrace as contextual information to ensure that the backtrace is itself not lost. This is a breaking change for likely all users of Wasmtime, but it's hoped to be a relatively minor change to workaround. Most use cases can likely change `-> Result<T, Trap>` to `-> Result<T>` and otherwise explicit creation of a `Trap` is largely no longer necessary. * Fix some doc links * add some tests and make a backtrace type public (#55) * Trap: avoid a trailing newline in the Display impl which in turn ends up with three newlines between the end of the backtrace and the `Caused by` in the anyhow Debug impl * make BacktraceContext pub, and add tests showing downcasting behavior of anyhow::Error to traps or backtraces * Remove now-unnecesary `Trap` downcasts in `Linker::module` * Fix test output expectations * Remove `Trap::i32_exit` This commit removes special-handling in the `wasmtime::Trap` type for the i32 exit code required by WASI. This is now instead modeled as a specific `I32Exit` error type in the `wasmtime-wasi` crate which is returned by the `proc_exit` hostcall. Embedders which previously tested for i32 exits now downcast to the `I32Exit` value. * Remove the `Trap::new` constructor This commit removes the ability to create a trap with an arbitrary error message. The purpose of this commit is to continue the prior trend of leaning into the `anyhow::Error` type instead of trying to recreate it with `Trap`. A subsequent simplification to `Trap` after this commit is that `Trap` will simply be an `enum` of trap codes with no extra information. This commit is doubly-motivated by the desire to always use the new `BacktraceContext` type instead of sometimes using that and sometimes using `Trap`. Most of the changes here were around updating `Trap::new` calls to `bail!` calls instead. Tests which assert particular error messages additionally often needed to use the `:?` formatter instead of the `{}` formatter because the prior formats the whole `anyhow::Error` and the latter only formats the top-most error, which now contains the backtrace. * Merge `Trap` and `TrapCode` With prior refactorings there's no more need for `Trap` to be opaque or otherwise contain a backtrace. This commit parse down `Trap` to simply an `enum` which was the old `TrapCode`. All various tests and such were updated to handle this. The main consequence of this commit is that all errors have a `BacktraceContext` context attached to them. This unfortunately means that the backtrace is printed first before the error message or trap code, but given all the prior simplifications that seems worth it at this time. * Rename `BacktraceContext` to `WasmBacktrace` This feels like a better name given how this has turned out, and additionally this commit removes having both `WasmBacktrace` and `BacktraceContext`. * Soup up documentation for errors and traps * Fix build of the C API Co-authored-by: Pat Hickey <pat@moreproductive.org> |
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Nick Fitzgerald
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ff0e84ecf4 |
Wasmtime: fix stack walking across frames from different stores (#4779)
We were previously implicitly assuming that all Wasm frames in a stack used the
same `VMRuntimeLimits` as the previous frame we walked, but this is not true
when Wasm in store A calls into the host which then calls into Wasm in store B:
| ... |
| Host | |
+-----------------+ | stack
| Wasm in store A | | grows
+-----------------+ | down
| Host | |
+-----------------+ |
| Wasm in store B | V
+-----------------+
Trying to walk this stack would previously result in a runtime panic.
The solution is to push the maintenance of our list of saved Wasm FP/SP/PC
registers that allow us to identify contiguous regions of Wasm frames on the
stack deeper into `CallThreadState`. The saved registers list is now maintained
whenever updating the `CallThreadState` linked list by making the
`CallThreadState::prev` field private and only accessible via a getter and
setter, where the setter always maintains our invariants.
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Alex Crichton
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534e4263ce |
Use tokio::test instead of dummy_waker in tests (#3975)
Currently wasmtime's async tests use a mixture of `#[tokio::test]` and `dummy_waker`. To be consistent this tries to move all tests possible to `#[tokio::test]` and just a two need to keep using `dummy_waker` (no renamed to `noop_waker`) due to what they're testing. |
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Alex Crichton
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76b82910c9 |
Remove the module linking implementation in Wasmtime (#3958)
* Remove the module linking implementation in Wasmtime This commit removes the experimental implementation of the module linking WebAssembly proposal from Wasmtime. The module linking is no longer intended for core WebAssembly but is instead incorporated into the component model now at this point. This means that very large parts of Wasmtime's implementation of module linking are no longer applicable and would change greatly with an implementation of the component model. The main purpose of this is to remove Wasmtime's reliance on the support for module-linking in `wasmparser` and tooling crates. With this reliance removed we can move over to the `component-model` branch of `wasmparser` and use the updated support for the component model. Additionally given the trajectory of the component model proposal the embedding API of Wasmtime will not look like what it looks like today for WebAssembly. For example the core wasm `Instance` will not change and instead a `Component` is likely to be added instead. Some more rationale for this is in #3941, but the basic idea is that I feel that it's not going to be viable to develop support for the component model on a non-`main` branch of Wasmtime. Additionaly I don't think it's viable, for the same reasons as `wasm-tools`, to support the old module linking proposal and the new component model at the same time. This commit takes a moment to not only delete the existing module linking implementation but some abstractions are also simplified. For example module serialization is a bit simpler that there's only one module. Additionally instantiation is much simpler since the only initializer we have to deal with are imports and nothing else. Closes #3941 * Fix doc link * Update comments |
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Alex Crichton
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15bb0c6903 |
Remove the ModuleLimits pooling configuration structure (#3837)
* Remove the `ModuleLimits` pooling configuration structure
This commit is an attempt to improve the usability of the pooling
allocator by removing the need to configure a `ModuleLimits` structure.
Internally this structure has limits on all forms of wasm constructs but
this largely bottoms out in the size of an allocation for an instance in
the instance pooling allocator. Maintaining this list of limits can be
cumbersome as modules may get tweaked over time and there's otherwise no
real reason to limit the number of globals in a module since the main
goal is to limit the memory consumption of a `VMContext` which can be
done with a memory allocation limit rather than fine-tuned control over
each maximum and minimum.
The new approach taken in this commit is to remove `ModuleLimits`. Some
fields, such as `tables`, `table_elements` , `memories`, and
`memory_pages` are moved to `InstanceLimits` since they're still
enforced at runtime. A new field `size` is added to `InstanceLimits`
which indicates, in bytes, the maximum size of the `VMContext`
allocation. If the size of a `VMContext` for a module exceeds this value
then instantiation will fail.
This involved adding a few more checks to `{Table, Memory}::new_static`
to ensure that the minimum size is able to fit in the allocation, since
previously modules were validated at compile time of the module that
everything fit and that validation no longer happens (it happens at
runtime).
A consequence of this commit is that Wasmtime will have no built-in way
to reject modules at compile time if they'll fail to be instantiated
within a particular pooling allocator configuration. Instead a module
must attempt instantiation see if a failure happens.
* Fix benchmark compiles
* Fix some doc links
* Fix a panic by ensuring modules have limited tables/memories
* Review comments
* Add back validation at `Module` time instantiation is possible
This allows for getting an early signal at compile time that a module
will never be instantiable in an engine with matching settings.
* Provide a better error message when sizes are exceeded
Improve the error message when an instance size exceeds the maximum by
providing a breakdown of where the bytes are all going and why the large
size is being requested.
* Try to fix test in qemu
* Flag new test as 64-bit only
Sizes are all specific to 64-bit right now
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Alex Crichton
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bcf3544924 |
Optimize Func::call and its C API (#3319)
* Optimize `Func::call` and its C API This commit is an alternative to #3298 which achieves effectively the same goal of optimizing the `Func::call` API as well as its C API sibling of `wasmtime_func_call`. The strategy taken here is different than #3298 though where a new API isn't created, rather a small tweak to an existing API is done. Specifically this commit handles the major sources of slowness with `Func::call` with: * Looking up the type of a function, to typecheck the arguments with and use to guide how the results should be loaded, no longer hits the rwlock in the `Engine` but instead each `Func` contains its own `FuncType`. This can be an unnecessary allocation for funcs not used with `Func::call`, so this is a downside of this implementation relative to #3298. A mitigating factor, though, is that instance exports are loaded lazily into the `Store` and in theory not too many funcs are active in the store as `Func` objects. * Temporary storage is amortized with a long-lived `Vec` in the `Store` rather than allocating a new vector on each call. This is basically the same strategy as #3294 only applied to different types in different places. Specifically `wasmtime::Store` now retains a `Vec<u128>` for `Func::call`, and the C API retains a `Vec<Val>` for calling `Func::call`. * Finally, an API breaking change is made to `Func::call` and its type signature (as well as `Func::call_async`). Instead of returning `Box<[Val]>` as it did before this function now takes a `results: &mut [Val]` parameter. This allows the caller to manage the allocation and we can amortize-remove it in `wasmtime_func_call` by using space after the parameters in the `Vec<Val>` we're passing in. This change is naturally a breaking change and we'll want to consider it carefully, but mitigating factors are that most embeddings are likely using `TypedFunc::call` instead and this signature taking a mutable slice better aligns with `Func::new` which receives a mutable slice for the results. Overall this change, in the benchmark of "call a nop function from the C API" is not quite as good as #3298. It's still a bit slower, on the order of 15ns, because there's lots of capacity checks around vectors and the type checks are slightly less optimized than before. Overall though this is still significantly better than today because allocations and the rwlock to acquire the type information are both avoided. I personally feel that this change is the best to do because it has less of an API impact than #3298. * Rebase issues |
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Alex Crichton
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9b088756b3 |
Implement Linker::module_async (#3121)
This implements and adds the async counterpart of the `Linker::module` method. Closes #3077 |
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Alex Crichton
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13d317a0a8 |
Fix stack checks of recursive async function calls (#3088)
* Fix stack checks of recursive async function calls Previously the stack pointer limit wasn't adjusted, even in the face of stack switching. This commit updates the logic around the stack limit calculation to configure it on all async function calls, even if they're recursive. Synchronous function calls, however, continue to only configure the stack limit at the start, not for recursive calls. * Update crates/wasmtime/src/func.rs Co-authored-by: Peter Huene <peter@huene.dev> Co-authored-by: Peter Huene <peter@huene.dev> |
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Alex Crichton
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b9985fe2e5 |
Change the injection count of fuel in a store from u32 to u64 (#3048)
* Change the injection count of fuel in a store from u32 to u64 This commit updates the type of the amount of times to inject fuel in the `out_of_fuel_async_yield` to `u64` instead of `u32`. This should allow effectively infinite fuel to get injected, even if a small amount of fuel is injected per iteration. Closes #2927 Closes #3046 * Fix tokio example |
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Alex Crichton
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7ce46043dc |
Add guard pages to the front of linear memories (#2977)
* Add guard pages to the front of linear memories
This commit implements a safety feature for Wasmtime to place guard
pages before the allocation of all linear memories. Guard pages placed
after linear memories are typically present for performance (at least)
because it can help elide bounds checks. Guard pages before a linear
memory, however, are never strictly needed for performance or features.
The intention of a preceding guard page is to help insulate against bugs
in Cranelift or other code generators, such as CVE-2021-32629.
This commit adds a `Config::guard_before_linear_memory` configuration
option, defaulting to `true`, which indicates whether guard pages should
be present both before linear memories as well as afterwards. Guard
regions continue to be controlled by
`{static,dynamic}_memory_guard_size` methods.
The implementation here affects both on-demand allocated memories as
well as the pooling allocator for memories. For on-demand memories this
adjusts the size of the allocation as well as adjusts the calculations
for the base pointer of the wasm memory. For the pooling allocator this
will place a singular extra guard region at the very start of the
allocation for memories. Since linear memories in the pooling allocator
are contiguous every memory already had a preceding guard region in
memory, it was just the previous memory's guard region afterwards. Only
the first memory needed this extra guard.
I've attempted to write some tests to help test all this, but this is
all somewhat tricky to test because the settings are pretty far away
from the actual behavior. I think, though, that the tests added here
should help cover various use cases and help us have confidence in
tweaking the various `Config` settings beyond their defaults.
Note that this also contains a semantic change where
`InstanceLimits::memory_reservation_size` has been removed. Instead this
field is now inferred from the `static_memory_maximum_size` and guard
size settings. This should hopefully remove some duplication in these
settings, canonicalizing on the guard-size/static-size settings as the
way to control memory sizes and virtual reservations.
* Update config docs
* Fix a typo
* Fix benchmark
* Fix wasmtime-runtime tests
* Fix some more tests
* Try to fix uffd failing test
* Review items
* Tweak 32-bit defaults
Makes the pooling allocator a bit more reasonable by default on 32-bit
with these settings.
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Alex Crichton
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7a1b7cdf92 |
Implement RFC 11: Redesigning Wasmtime's APIs (#2897)
Implement Wasmtime's new API as designed by RFC 11. This is quite a large commit which has had lots of discussion externally, so for more information it's best to read the RFC thread and the PR thread. |
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Alex Crichton
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2697a18d2f |
Redo the statically typed Func API (#2719)
* Redo the statically typed `Func` API
This commit reimplements the `Func` API with respect to statically typed
dispatch. Previously `Func` had a `getN` and `getN_async` family of
methods which were implemented for 0 to 16 parameters. The return value
of these functions was an `impl Fn(..)` closure with the appropriate
parameters and return values.
There are a number of downsides with this approach that have become
apparent over time:
* The addition of `*_async` doubled the API surface area (which is quite
large here due to one-method-per-number-of-parameters).
* The [documentation of `Func`][old-docs] are quite verbose and feel
"polluted" with all these getters, making it harder to understand the
other methods that can be used to interact with a `Func`.
* These methods unconditionally pay the cost of returning an owned `impl
Fn` with a `'static` lifetime. While cheap, this is still paying the
cost for cloning the `Store` effectively and moving data into the
closed-over environment.
* Storage of the return value into a struct, for example, always
requires `Box`-ing the returned closure since it otherwise cannot be
named.
* Recently I had the desire to implement an "unchecked" path for
invoking wasm where you unsafely assert the type signature of a wasm
function. Doing this with today's scheme would require doubling
(again) the API surface area for both async and synchronous calls,
further polluting the documentation.
The main benefit of the previous scheme is that by returning a `impl Fn`
it was quite easy and ergonomic to actually invoke the function. In
practice, though, examples would often have something akin to
`.get0::<()>()?()?` which is a lot of things to interpret all at once.
Note that `get0` means "0 parameters" yet a type parameter is passed.
There's also a double function invocation which looks like a lot of
characters all lined up in a row.
Overall, I think that the previous design is starting to show too many
cracks and deserves a rewrite. This commit is that rewrite.
The new design in this commit is to delete the `getN{,_async}` family of
functions and instead have a new API:
impl Func {
fn typed<P, R>(&self) -> Result<&Typed<P, R>>;
}
impl Typed<P, R> {
fn call(&self, params: P) -> Result<R, Trap>;
async fn call_async(&self, params: P) -> Result<R, Trap>;
}
This should entirely replace the current scheme, albeit by slightly
losing ergonomics use cases. The idea behind the API is that the
existence of `Typed<P, R>` is a "proof" that the underlying function
takes `P` and returns `R`. The `Func::typed` method peforms a runtime
type-check to ensure that types all match up, and if successful you get
a `Typed` value. Otherwise an error is returned.
Once you have a `Typed` then, like `Func`, you can either `call` or
`call_async`. The difference with a `Typed`, however, is that the
params/results are statically known and hence these calls can be much
more efficient.
This is a much smaller API surface area from before and should greatly
simplify the `Func` documentation. There's still a problem where
`Func::wrapN_async` produces a lot of functions to document, but that's
now the sole offender. It's a nice benefit that the
statically-typed-async verisons are now expressed with an `async`
function rather than a function-returning-a-future which makes it both
more efficient and easier to understand.
The type `P` and `R` are intended to either be bare types (e.g. `i32`)
or tuples of any length (including 0). At this time `R` is only allowed
to be `()` or a bare `i32`-style type because multi-value is not
supported with a native ABI (yet). The `P`, however, can be any size of
tuples of parameters. This is also where some ergonomics are lost
because instead of `f(1, 2)` you now have to write `f.call((1, 2))`
(note the double-parens). Similarly `f()` becomes `f.call(())`.
Overall I feel that this is a better tradeoff than before. While not
universally better due to the loss in ergonomics I feel that this design
is much more flexible in terms of what you can do with the return value
and also understanding the API surface area (just less to take in).
[old-docs]: https://docs.rs/wasmtime/0.24.0/wasmtime/struct.Func.html#method.get0
* Rename Typed to TypedFunc
* Implement multi-value returns through `Func::typed`
* Fix examples in docs
* Fix some more errors
* More test fixes
* Rebasing and adding `get_typed_func`
* Updating tests
* Fix typo
* More doc tweaks
* Tweak visibility on `Func::invoke`
* Fix tests again
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Alex Crichton
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918c012d00 |
Fix some issues around TLS management with async (#2709)
This commit fixes a few issues around managing the thread-local state of a wasmtime thread. We intentionally only have a singular TLS variable in the whole world, and the problem is that when stack-switching off an async thread we were not restoring the previous TLS state. This is necessary in two cases: * Futures aren't guaranteed to be polled/completed in a stack-like fashion. If a poll sees that a future isn't ready then we may resume execution in a previous wasm context that ends up needing the TLS information. * Futures can also cross threads (when the whole store crosses threads) and we need to save/restore TLS state from the thread we're coming from and the thread that we're going to. The stack switching issue necessitates some more glue around suspension and resumption of a stack to ensure we save/restore the TLS state on both sides. The thread issue, however, also necessitates that we use `#[inline(never)]` on TLS access functions and never have TLS borrows live across a function which could result in running arbitrary code (as was the case for the `tls::set` function. |
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Peter Huene
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54c07d8f16 |
Implement shared host functions. (#2625)
* Implement defining host functions at the Config level. This commit introduces defining host functions at the `Config` rather than with `Func` tied to a `Store`. The intention here is to enable a host to define all of the functions once with a `Config` and then use a `Linker` (or directly with `Store::get_host_func`) to use the functions when instantiating a module. This should help improve the performance of use cases where a `Store` is short-lived and redefining the functions at every module instantiation is a noticeable performance hit. This commit adds `add_to_config` to the code generation for Wasmtime's `Wasi` type. The new method adds the WASI functions to the given config as host functions. This commit adds context functions to `Store`: `get` to get a context of a particular type and `set` to set the context on the store. For safety, `set` cannot replace an existing context value of the same type. `Wasi::set_context` was added to set the WASI context for a `Store` when using `Wasi::add_to_config`. * Add `Config::define_host_func_async`. * Make config "async" rather than store. This commit moves the concept of "async-ness" to `Config` rather than `Store`. Note: this is a breaking API change for anyone that's already adopted the new async support in Wasmtime. Now `Config::new_async` is used to create an "async" config and any `Store` associated with that config is inherently "async". This is needed for async shared host functions to have some sanity check during their execution (async host functions, like "async" `Func`, need to be called with the "async" variants). * Update async function tests to smoke async shared host functions. This commit updates the async function tests to also smoke the shared host functions, plus `Func::wrap0_async`. This also changes the "wrap async" method names on `Config` to `wrap$N_host_func_async` to slightly better match what is on `Func`. * Move the instance allocator into `Engine`. This commit moves the instantiated instance allocator from `Config` into `Engine`. This makes certain settings in `Config` no longer order-dependent, which is how `Config` should ideally be. This also removes the confusing concept of the "default" instance allocator, instead opting to construct the on-demand instance allocator when needed. This does alter the semantics of the instance allocator as now each `Engine` gets its own instance allocator rather than sharing a single one between all engines created from a configuration. * Make `Engine::new` return `Result`. This is a breaking API change for anyone using `Engine::new`. As creating the pooling instance allocator may fail (likely cause is not enough memory for the provided limits), instead of panicking when creating an `Engine`, `Engine::new` now returns a `Result`. * Remove `Config::new_async`. This commit removes `Config::new_async` in favor of treating "async support" as any other setting on `Config`. The setting is `Config::async_support`. * Remove order dependency when defining async host functions in `Config`. This commit removes the order dependency where async support must be enabled on the `Config` prior to defining async host functions. The check is now delayed to when an `Engine` is created from the config. * Update WASI example to use shared `Wasi::add_to_config`. This commit updates the WASI example to use `Wasi::add_to_config`. As only a single store and instance are used in the example, it has no semantic difference from the previous example, but the intention is to steer users towards defining WASI on the config and only using `Wasi::add_to_linker` when more explicit scoping of the WASI context is required. |
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Peter Huene
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505437e353 |
Code cleanup.
Last minute code clean up to fix some comments and rename `address_space_size` to `memory_reservation_size` to better describe what the option is doing. |
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Peter Huene
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e71ccbf9bc |
Implement the pooling instance allocator.
This commit implements the pooling instance allocator. The allocation strategy can be set with `Config::with_allocation_strategy`. The pooling strategy uses the pooling instance allocator to preallocate a contiguous region of memory for instantiating modules that adhere to various limits. The intention of the pooling instance allocator is to reserve as much of the host address space needed for instantiating modules ahead of time and to reuse committed memory pages wherever possible. |
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Alex Crichton
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7795a230f2 |
Implement support for async functions in Wasmtime (#2434)
* Implement support for `async` functions in Wasmtime This is an implementation of [RFC 2] in Wasmtime which is to support `async`-defined host functions. At a high level support is added by executing WebAssembly code that might invoke an asynchronous host function on a separate native stack. When the host function's future is not ready we switch back to the main native stack to continue execution. There's a whole bunch of details in this commit, and it's a bit much to go over them all here in this commit message. The most important changes here are: * A new `wasmtime-fiber` crate has been written to manage the low-level details of stack-switching. Unixes use `mmap` to allocate a stack and Windows uses the native fibers implementation. We'll surely want to refactor this to move stack allocation elsewhere in the future. Fibers are intended to be relatively general with a lot of type paremters to fling values back and forth across suspension points. The whole crate is a giant wad of `unsafe` unfortunately and involves handwritten assembly with custom dwarf CFI directives to boot. Definitely deserves a close eye in review! * The `Store` type has two new methods -- `block_on` and `on_fiber` which bridge between the async and non-async worlds. Lots of unsafe fiddly bits here as we're trying to communicate context pointers between disparate portions of the code. Extra eyes and care in review is greatly appreciated. * The APIs for binding `async` functions are unfortunately pretty ugly in `Func`. This is mostly due to language limitations and compiler bugs (I believe) in Rust. Instead of `Func::wrap` we have a `Func::wrapN_async` family of methods, and we've also got a whole bunch of `Func::getN_async` methods now too. It may be worth rethinking the API of `Func` to try to make the documentation page actually grok'able. This isn't super heavily tested but the various test should suffice for engaging hopefully nearly all the infrastructure in one form or another. This is just the start though! [RFC 2]: https://github.com/bytecodealliance/rfcs/pull/2 * Add wasmtime-fiber to publish script * Save vector/float registers on ARM too. * Fix a typo * Update lock file * Implement periodically yielding with fuel consumption This commit implements APIs on `Store` to periodically yield execution of futures through the consumption of fuel. When fuel runs out a future's execution is yielded back to the caller, and then upon resumption fuel is re-injected. The goal of this is to allow cooperative multi-tasking with futures. * Fix compile without async * Save/restore the frame pointer in fiber switching Turns out this is another caller-saved register! * Simplify x86_64 fiber asm Take a leaf out of aarch64's playbook and don't have extra memory to load/store these arguments, instead leverage how `wasmtime_fiber_switch` already loads a bunch of data into registers which we can then immediately start using on a fiber's start without any extra memory accesses. * Add x86 support to wasmtime-fiber * Add ARM32 support to fiber crate * Make fiber build file probing more flexible * Use CreateFiberEx on Windows * Remove a stray no-longer-used trait declaration * Don't reach into `Caller` internals * Tweak async fuel to eventually run out. With fuel it's probably best to not provide any way to inject infinite fuel. * Fix some typos * Cleanup asm a bit * Use a shared header file to deduplicate some directives * Guarantee hidden visibility for functions * Enable gc-sections on macOS x86_64 * Add `.type` annotations for ARM * Update lock file * Fix compile error * Review comments |