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cranelift/tests/all/call_hook.rs

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#![cfg(not(miri))]
use anyhow::bail;
use std::future::Future;
use std::pin::Pin;
use std::task::{self, Poll};
use wasmtime::*;
// Crate a synchronous Func, call it directly:
#[test]
fn call_wrapped_func() -> Result<(), Error> {
let mut store = Store::<State>::default();
store.call_hook(sync_call_hook);
fn verify(state: &State) {
// Calling this func will switch context into wasm, then back to host:
assert_eq!(state.context, vec![Context::Wasm, Context::Host]);
assert_eq!(state.calls_into_host, state.returns_from_host + 1);
assert_eq!(state.calls_into_wasm, state.returns_from_wasm + 1);
}
let mut funcs = Vec::new();
funcs.push(Func::wrap(
&mut store,
|caller: Caller<State>, a: i32, b: i64, c: f32, d: f64| {
verify(caller.data());
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
},
));
let func_ty = FuncType::new(
store.engine(),
[ValType::I32, ValType::I64, ValType::F32, ValType::F64],
[],
);
funcs.push(Func::new(
&mut store,
func_ty,
|caller: Caller<State>, params, results| {
verify(caller.data());
assert_eq!(params.len(), 4);
assert_eq!(params[0].i32().unwrap(), 1);
assert_eq!(params[1].i64().unwrap(), 2);
assert_eq!(params[2].f32().unwrap(), 3.0);
assert_eq!(params[3].f64().unwrap(), 4.0);
assert_eq!(results.len(), 0);
Ok(())
},
));
let func_ty = FuncType::new(
store.engine(),
[ValType::I32, ValType::I64, ValType::F32, ValType::F64],
[],
);
funcs.push(unsafe {
Func::new_unchecked(&mut store, func_ty, |caller: Caller<State>, space| {
verify(caller.data());
assert_eq!(space[0].get_i32(), 1i32);
assert_eq!(space[1].get_i64(), 2i64);
assert_eq!(space[2].get_f32(), 3.0f32.to_bits());
assert_eq!(space[3].get_f64(), 4.0f64.to_bits());
Ok(())
})
});
let mut n = 0;
for f in funcs.iter() {
f.call(
&mut store,
&[Val::I32(1), Val::I64(2), 3.0f32.into(), 4.0f64.into()],
&mut [],
)?;
n += 1;
// One switch from vm to host to call f, another in return from f.
assert_eq!(store.data().calls_into_host, n);
assert_eq!(store.data().returns_from_host, n);
assert_eq!(store.data().calls_into_wasm, n);
assert_eq!(store.data().returns_from_wasm, n);
f.typed::<(i32, i64, f32, f64), ()>(&store)?
.call(&mut store, (1, 2, 3.0, 4.0))?;
n += 1;
assert_eq!(store.data().calls_into_host, n);
assert_eq!(store.data().returns_from_host, n);
assert_eq!(store.data().calls_into_wasm, n);
assert_eq!(store.data().returns_from_wasm, n);
unsafe {
let mut args = [
Val::I32(1).to_raw(&mut store)?,
Val::I64(2).to_raw(&mut store)?,
Val::F32(3.0f32.to_bits()).to_raw(&mut store)?,
Val::F64(4.0f64.to_bits()).to_raw(&mut store)?,
];
f.call_unchecked(&mut store, args.as_mut_ptr(), args.len())?;
}
n += 1;
assert_eq!(store.data().calls_into_host, n);
assert_eq!(store.data().returns_from_host, n);
assert_eq!(store.data().calls_into_wasm, n);
assert_eq!(store.data().returns_from_wasm, n);
}
Ok(())
}
// Create an async Func, call it directly:
#[tokio::test]
async fn call_wrapped_async_func() -> Result<(), Error> {
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let f = Func::wrap_async(
&mut store,
|caller: Caller<State>, (a, b, c, d): (i32, i64, f32, f64)| {
Box::new(async move {
// Calling this func will switch context into wasm, then back to host:
assert_eq!(caller.data().context, vec![Context::Wasm, Context::Host]);
assert_eq!(
caller.data().calls_into_host,
caller.data().returns_from_host + 1
);
assert_eq!(
caller.data().calls_into_wasm,
caller.data().returns_from_wasm + 1
);
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
})
},
);
f.call_async(
&mut store,
&[Val::I32(1), Val::I64(2), 3.0f32.into(), 4.0f64.into()],
&mut [],
)
.await?;
// One switch from vm to host to call f, another in return from f.
assert_eq!(store.data().calls_into_host, 1);
assert_eq!(store.data().returns_from_host, 1);
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().returns_from_wasm, 1);
f.typed::<(i32, i64, f32, f64), ()>(&store)?
.call_async(&mut store, (1, 2, 3.0, 4.0))
.await?;
assert_eq!(store.data().calls_into_host, 2);
assert_eq!(store.data().returns_from_host, 2);
assert_eq!(store.data().calls_into_wasm, 2);
assert_eq!(store.data().returns_from_wasm, 2);
Ok(())
}
// Use the Linker to define a sync func, call it through WebAssembly:
#[test]
fn call_linked_func() -> Result<(), Error> {
let engine = Engine::default();
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let mut linker = Linker::new(&engine);
linker.func_wrap(
"host",
"f",
|caller: Caller<State>, a: i32, b: i64, c: f32, d: f64| {
// Calling this func will switch context into wasm, then back to host:
assert_eq!(caller.data().context, vec![Context::Wasm, Context::Host]);
assert_eq!(
caller.data().calls_into_host,
caller.data().returns_from_host + 1
);
assert_eq!(
caller.data().calls_into_wasm,
caller.data().returns_from_wasm + 1
);
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
},
)?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32) (param i64) (param f32) (param f64)))
(func (export "export")
(call $f (i32.const 1) (i64.const 2) (f32.const 3.0) (f64.const 4.0)))
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate(&mut store, &module)?;
let export = inst
.get_export(&mut store, "export")
.expect("get export")
.into_func()
.expect("export is func");
export.call(&mut store, &[], &mut [])?;
// One switch from vm to host to call f, another in return from f.
assert_eq!(store.data().calls_into_host, 1);
assert_eq!(store.data().returns_from_host, 1);
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().returns_from_wasm, 1);
export.typed::<(), ()>(&store)?.call(&mut store, ())?;
assert_eq!(store.data().calls_into_host, 2);
assert_eq!(store.data().returns_from_host, 2);
assert_eq!(store.data().calls_into_wasm, 2);
assert_eq!(store.data().returns_from_wasm, 2);
Ok(())
}
// Use the Linker to define an async func, call it through WebAssembly:
#[tokio::test]
async fn call_linked_func_async() -> Result<(), Error> {
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let f = Func::wrap_async(
&mut store,
|caller: Caller<State>, (a, b, c, d): (i32, i64, f32, f64)| {
Box::new(async move {
// Calling this func will switch context into wasm, then back to host:
assert_eq!(caller.data().context, vec![Context::Wasm, Context::Host]);
assert_eq!(
caller.data().calls_into_host,
caller.data().returns_from_host + 1
);
assert_eq!(
caller.data().calls_into_wasm,
caller.data().returns_from_wasm + 1
);
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
})
},
);
let mut linker = Linker::new(&engine);
linker.define(&mut store, "host", "f", f)?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32) (param i64) (param f32) (param f64)))
(func (export "export")
(call $f (i32.const 1) (i64.const 2) (f32.const 3.0) (f64.const 4.0)))
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate_async(&mut store, &module).await?;
let export = inst
.get_export(&mut store, "export")
.expect("get export")
.into_func()
.expect("export is func");
export.call_async(&mut store, &[], &mut []).await?;
// One switch from vm to host to call f, another in return from f.
assert_eq!(store.data().calls_into_host, 1);
assert_eq!(store.data().returns_from_host, 1);
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().returns_from_wasm, 1);
export
.typed::<(), ()>(&store)?
.call_async(&mut store, ())
.await?;
assert_eq!(store.data().calls_into_host, 2);
assert_eq!(store.data().returns_from_host, 2);
assert_eq!(store.data().calls_into_wasm, 2);
assert_eq!(store.data().returns_from_wasm, 2);
Ok(())
}
#[test]
fn instantiate() -> Result<(), Error> {
let mut store = Store::<State>::default();
store.call_hook(sync_call_hook);
let m = Module::new(store.engine(), "(module)")?;
Instance::new(&mut store, &m, &[])?;
assert_eq!(store.data().calls_into_wasm, 0);
assert_eq!(store.data().calls_into_host, 0);
let m = Module::new(store.engine(), "(module (func) (start 0))")?;
Instance::new(&mut store, &m, &[])?;
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().calls_into_host, 0);
Ok(())
}
#[tokio::test]
async fn instantiate_async() -> Result<(), Error> {
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let m = Module::new(store.engine(), "(module)")?;
Instance::new_async(&mut store, &m, &[]).await?;
assert_eq!(store.data().calls_into_wasm, 0);
assert_eq!(store.data().calls_into_host, 0);
let m = Module::new(store.engine(), "(module (func) (start 0))")?;
Instance::new_async(&mut store, &m, &[]).await?;
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().calls_into_host, 0);
Ok(())
}
#[test]
fn recursion() -> Result<(), Error> {
// Make sure call hook behaves reasonably when called recursively
let engine = Engine::default();
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let mut linker = Linker::new(&engine);
linker.func_wrap("host", "f", |mut caller: Caller<State>, n: i32| {
assert_eq!(caller.data().context.last(), Some(&Context::Host));
assert_eq!(caller.data().calls_into_host, caller.data().calls_into_wasm);
// Recurse
if n > 0 {
caller
.get_export("export")
.expect("caller exports \"export\"")
.into_func()
.expect("export is a func")
.typed::<i32, ()>(&caller)
.expect("export typing")
.call(&mut caller, n - 1)
.unwrap()
}
})?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32)))
(func (export "export") (param i32)
(call $f (local.get 0)))
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate(&mut store, &module)?;
let export = inst
.get_export(&mut store, "export")
.expect("get export")
.into_func()
.expect("export is func");
// Recursion depth:
let n: usize = 10;
export.call(&mut store, &[Val::I32(n as i32)], &mut [])?;
// Recurse down to 0: n+1 calls
assert_eq!(store.data().calls_into_host, n + 1);
assert_eq!(store.data().returns_from_host, n + 1);
assert_eq!(store.data().calls_into_wasm, n + 1);
assert_eq!(store.data().returns_from_wasm, n + 1);
export
.typed::<i32, ()>(&store)?
.call(&mut store, n as i32)?;
assert_eq!(store.data().calls_into_host, 2 * (n + 1));
assert_eq!(store.data().returns_from_host, 2 * (n + 1));
assert_eq!(store.data().calls_into_wasm, 2 * (n + 1));
assert_eq!(store.data().returns_from_wasm, 2 * (n + 1));
Ok(())
}
#[test]
fn trapping() -> Result<(), Error> {
const TRAP_IN_F: i32 = 0;
const TRAP_NEXT_CALL_HOST: i32 = 1;
const TRAP_NEXT_RETURN_HOST: i32 = 2;
const TRAP_NEXT_CALL_WASM: i32 = 3;
const TRAP_NEXT_RETURN_WASM: i32 = 4;
let engine = Engine::default();
let mut linker = Linker::new(&engine);
linker.func_wrap(
"host",
"f",
|mut caller: Caller<State>, action: i32, recur: i32| -> Result<()> {
assert_eq!(caller.data().context.last(), Some(&Context::Host));
assert_eq!(caller.data().calls_into_host, caller.data().calls_into_wasm);
match action {
TRAP_IN_F => bail!("trapping in f"),
TRAP_NEXT_CALL_HOST => caller.data_mut().trap_next_call_host = true,
TRAP_NEXT_RETURN_HOST => caller.data_mut().trap_next_return_host = true,
TRAP_NEXT_CALL_WASM => caller.data_mut().trap_next_call_wasm = true,
TRAP_NEXT_RETURN_WASM => caller.data_mut().trap_next_return_wasm = true,
_ => {} // Do nothing
}
// recur so that we can trigger a next call.
// propagate its trap, if it traps!
if recur > 0 {
let _ = caller
.get_export("export")
.expect("caller exports \"export\"")
.into_func()
.expect("export is a func")
.typed::<(i32, i32), ()>(&caller)
.expect("export typing")
.call(&mut caller, (action, 0))?;
}
Ok(())
},
)?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32) (param i32)))
(func (export "export") (param i32) (param i32)
(call $f (local.get 0) (local.get 1)))
)
"#;
let module = Module::new(&engine, wat)?;
let run = |action: i32, recur: bool| -> (State, Option<Error>) {
let mut store = Store::new(&engine, State::default());
store.call_hook(sync_call_hook);
let inst = linker
.instantiate(&mut store, &module)
.expect("instantiate");
let export = inst
.get_export(&mut store, "export")
.expect("get export")
.into_func()
.expect("export is func");
let r = export.call(
&mut store,
&[Val::I32(action), Val::I32(if recur { 1 } else { 0 })],
&mut [],
);
(store.into_data(), r.err())
};
let (s, e) = run(TRAP_IN_F, false);
assert!(format!("{:?}", e.unwrap()).contains("trapping in f"));
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 1);
assert_eq!(s.returns_from_wasm, 1);
// trap in next call to host. No calls after the bit is set, so this trap shouldn't happen
let (s, e) = run(TRAP_NEXT_CALL_HOST, false);
assert!(e.is_none());
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 1);
assert_eq!(s.returns_from_wasm, 1);
// trap in next call to host. recur, so the second call into host traps:
let (s, e) = run(TRAP_NEXT_CALL_HOST, true);
assert!(format!("{:?}", e.unwrap()).contains("call_hook: trapping on CallingHost"));
assert_eq!(s.calls_into_host, 2);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 2);
assert_eq!(s.returns_from_wasm, 2);
// trap in the return from host. should trap right away, without recursion
let (s, e) = run(TRAP_NEXT_RETURN_HOST, false);
assert!(format!("{:?}", e.unwrap()).contains("call_hook: trapping on ReturningFromHost"));
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 1);
assert_eq!(s.returns_from_wasm, 1);
// trap in next call to wasm. No calls after the bit is set, so this trap shouldn't happen:
let (s, e) = run(TRAP_NEXT_CALL_WASM, false);
assert!(e.is_none());
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 1);
assert_eq!(s.returns_from_wasm, 1);
// trap in next call to wasm. recur, so the second call into wasm traps:
let (s, e) = run(TRAP_NEXT_CALL_WASM, true);
assert!(format!("{:?}", e.unwrap()).contains("call_hook: trapping on CallingWasm"));
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 2);
assert_eq!(s.returns_from_wasm, 1);
// trap in the return from wasm. should trap right away, without recursion
let (s, e) = run(TRAP_NEXT_RETURN_WASM, false);
assert!(format!("{:?}", e.unwrap()).contains("call_hook: trapping on ReturningFromWasm"));
assert_eq!(s.calls_into_host, 1);
assert_eq!(s.returns_from_host, 1);
assert_eq!(s.calls_into_wasm, 1);
assert_eq!(s.returns_from_wasm, 1);
Ok(())
}
#[tokio::test]
async fn basic_async_hook() -> Result<(), Error> {
struct HandlerR;
#[async_trait::async_trait]
impl CallHookHandler<State> for HandlerR {
async fn handle_call_event(
&self,
ctx: StoreContextMut<'_, State>,
ch: CallHook,
) -> Result<()> {
sync_call_hook(ctx, ch)
}
}
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, State::default());
store.call_hook_async(HandlerR {});
assert_eq!(store.data().calls_into_host, 0);
assert_eq!(store.data().returns_from_host, 0);
assert_eq!(store.data().calls_into_wasm, 0);
assert_eq!(store.data().returns_from_wasm, 0);
let mut linker = Linker::new(&engine);
linker.func_wrap(
"host",
"f",
|caller: Caller<State>, a: i32, b: i64, c: f32, d: f64| {
// Calling this func will switch context into wasm, then back to host:
assert_eq!(caller.data().context, vec![Context::Wasm, Context::Host]);
assert_eq!(
caller.data().calls_into_host,
caller.data().returns_from_host + 1
);
assert_eq!(
caller.data().calls_into_wasm,
caller.data().returns_from_wasm + 1
);
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
},
)?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32) (param i64) (param f32) (param f64)))
(func (export "export")
(call $f (i32.const 1) (i64.const 2) (f32.const 3.0) (f64.const 4.0)))
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate_async(&mut store, &module).await?;
let export = inst
.get_export(&mut store, "export")
.expect("get export")
.into_func()
.expect("export is func");
export.call_async(&mut store, &[], &mut []).await?;
// One switch from vm to host to call f, another in return from f.
assert_eq!(store.data().calls_into_host, 1);
assert_eq!(store.data().returns_from_host, 1);
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().returns_from_wasm, 1);
Ok(())
}
#[tokio::test]
async fn timeout_async_hook() -> Result<(), Error> {
struct HandlerR;
#[async_trait::async_trait]
impl CallHookHandler<State> for HandlerR {
async fn handle_call_event(
&self,
mut ctx: StoreContextMut<'_, State>,
ch: CallHook,
) -> Result<()> {
let obj = ctx.data_mut();
if obj.calls_into_host > 200 {
bail!("timeout");
}
match ch {
CallHook::CallingHost => obj.calls_into_host += 1,
CallHook::CallingWasm => obj.calls_into_wasm += 1,
CallHook::ReturningFromHost => obj.returns_from_host += 1,
CallHook::ReturningFromWasm => obj.returns_from_wasm += 1,
}
Ok(())
}
}
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, State::default());
store.call_hook_async(HandlerR {});
assert_eq!(store.data().calls_into_host, 0);
assert_eq!(store.data().returns_from_host, 0);
assert_eq!(store.data().calls_into_wasm, 0);
assert_eq!(store.data().returns_from_wasm, 0);
let mut linker = Linker::new(&engine);
linker.func_wrap(
"host",
"f",
|_caller: Caller<State>, a: i32, b: i64, c: f32, d: f64| {
assert_eq!(a, 1);
assert_eq!(b, 2);
assert_eq!(c, 3.0);
assert_eq!(d, 4.0);
},
)?;
let wat = r#"
(module
(import "host" "f"
(func $f (param i32) (param i64) (param f32) (param f64)))
(func (export "export")
(loop $start
(call $f (i32.const 1) (i64.const 2) (f32.const 3.0) (f64.const 4.0))
(br $start)))
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate_async(&mut store, &module).await?;
let export = inst
.get_typed_func::<(), ()>(&mut store, "export")
.expect("export is func");
store.set_epoch_deadline(1);
store.epoch_deadline_async_yield_and_update(1);
assert!(export.call_async(&mut store, ()).await.is_err());
// One switch from vm to host to call f, another in return from f.
assert!(store.data().calls_into_host > 1);
assert!(store.data().returns_from_host > 1);
assert_eq!(store.data().calls_into_wasm, 1);
assert_eq!(store.data().returns_from_wasm, 0);
Ok(())
}
#[tokio::test]
async fn drop_suspended_async_hook() -> Result<(), Error> {
struct Handler;
#[async_trait::async_trait]
impl CallHookHandler<u32> for Handler {
async fn handle_call_event(
&self,
mut ctx: StoreContextMut<'_, u32>,
_ch: CallHook,
) -> Result<()> {
let state = ctx.data_mut();
assert_eq!(*state, 0);
*state += 1;
let _dec = Decrement(state);
// Simulate some sort of event which takes a number of yields
for _ in 0..500 {
tokio::task::yield_now().await;
}
Ok(())
}
}
let mut config = Config::new();
config.async_support(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, 0);
store.call_hook_async(Handler);
let mut linker = Linker::new(&engine);
// Simulate a host function that has lots of yields with an infinite loop.
linker.func_wrap_async("host", "f", |mut cx, _: ()| {
Box::new(async move {
let state = cx.data_mut();
assert_eq!(*state, 0);
*state += 1;
let _dec = Decrement(state);
for _ in 0.. {
tokio::task::yield_now().await;
}
})
})?;
let wat = r#"
(module
(import "host" "f" (func $f))
(func (export "") call $f)
)
"#;
let module = Module::new(&engine, wat)?;
let inst = linker.instantiate_async(&mut store, &module).await?;
assert_eq!(*store.data(), 0);
let export = inst
.get_typed_func::<(), ()>(&mut store, "")
.expect("export is func");
// First test that if we drop in the middle of an async hook that everything
// is alright.
PollNTimes {
future: Box::pin(export.call_async(&mut store, ())),
times: 200,
}
.await;
assert_eq!(*store.data(), 0); // double-check user dtors ran
// Next test that if we drop while in a host async function that everything
// is also alright.
PollNTimes {
future: Box::pin(export.call_async(&mut store, ())),
times: 1_000,
}
.await;
assert_eq!(*store.data(), 0); // double-check user dtors ran
return Ok(());
// A helper struct to poll an inner `future` N `times` and then resolve.
// This is used above to test that when futures are dropped while they're
// pending everything works and is cleaned up on the Wasmtime side of
// things.
struct PollNTimes<F> {
future: F,
times: u32,
}
impl<F: Future + Unpin> Future for PollNTimes<F> {
type Output = ();
fn poll(mut self: Pin<&mut Self>, task: &mut task::Context<'_>) -> Poll<()> {
for _ in 0..self.times {
match Pin::new(&mut self.future).poll(task) {
Poll::Ready(_) => panic!("future should not be ready"),
Poll::Pending => {}
}
}
Poll::Ready(())
}
}
// helper struct to decrement a counter on drop
struct Decrement<'a>(&'a mut u32);
impl Drop for Decrement<'_> {
fn drop(&mut self) {
*self.0 -= 1;
}
}
}
#[derive(Debug, PartialEq, Eq)]
enum Context {
Host,
Wasm,
}
struct State {
context: Vec<Context>,
calls_into_host: usize,
returns_from_host: usize,
calls_into_wasm: usize,
returns_from_wasm: usize,
trap_next_call_host: bool,
trap_next_return_host: bool,
trap_next_call_wasm: bool,
trap_next_return_wasm: bool,
}
impl Default for State {
fn default() -> Self {
State {
context: Vec::new(),
calls_into_host: 0,
returns_from_host: 0,
calls_into_wasm: 0,
returns_from_wasm: 0,
trap_next_call_host: false,
trap_next_return_host: false,
trap_next_call_wasm: false,
trap_next_return_wasm: false,
}
}
}
impl State {
// This implementation asserts that hooks are always called in a stack-like manner.
fn call_hook(&mut self, s: CallHook) -> Result<()> {
match s {
CallHook::CallingHost => {
self.calls_into_host += 1;
if self.trap_next_call_host {
bail!("call_hook: trapping on CallingHost");
} else {
self.context.push(Context::Host);
}
}
CallHook::ReturningFromHost => match self.context.pop() {
Some(Context::Host) => {
self.returns_from_host += 1;
if self.trap_next_return_host {
bail!("call_hook: trapping on ReturningFromHost");
}
}
c => panic!(
"illegal context: expected Some(Host), got {:?}. remaining: {:?}",
c, self.context
),
},
CallHook::CallingWasm => {
self.calls_into_wasm += 1;
if self.trap_next_call_wasm {
bail!("call_hook: trapping on CallingWasm");
} else {
self.context.push(Context::Wasm);
}
}
CallHook::ReturningFromWasm => match self.context.pop() {
Some(Context::Wasm) => {
self.returns_from_wasm += 1;
if self.trap_next_return_wasm {
bail!("call_hook: trapping on ReturningFromWasm");
}
}
c => panic!(
"illegal context: expected Some(Wasm), got {:?}. remaining: {:?}",
c, self.context
),
},
}
Ok(())
}
}
fn sync_call_hook(mut ctx: StoreContextMut<'_, State>, transition: CallHook) -> Result<()> {
ctx.data_mut().call_hook(transition)
}