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c6b01935ecbffe0d61888b913b69708e91a5ffff
wasmtime/crates/wast/src/wast.rs
Nick Fitzgerald e40c039e65 wasmtime: Rip out incomplete/incorrect externref "host info" support 
Better to be loud that we don't support attaching arbitrary host info to
`externref`s than to limp along and pretend we do support it. Supporting it
properly won't reuse any of this code anyways.
2020-06-25 14:00:40 -07:00

477 lines
16 KiB
Rust
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use crate::spectest::link_spectest;
use anyhow::{anyhow, bail, Context as _, Result};
use std::path::Path;
use std::str;
use wasmtime::*;
use wast::Wat;
use wast::{
parser::{self, ParseBuffer},
RefType,
};
/// Translate from a `script::Value` to a `RuntimeValue`.
fn runtime_value(v: &wast::Expression<'_>) -> Result<Val> {
use wast::Instruction::*;
if v.instrs.len() != 1 {
bail!("too many instructions in {:?}", v);
}
Ok(match &v.instrs[0] {
I32Const(x) => Val::I32(*x),
I64Const(x) => Val::I64(*x),
F32Const(x) => Val::F32(x.bits),
F64Const(x) => Val::F64(x.bits),
V128Const(x) => Val::V128(u128::from_le_bytes(x.to_le_bytes())),
RefNull(RefType::Extern) => Val::ExternRef(None),
RefNull(RefType::Func) => Val::FuncRef(None),
RefExtern(x) => Val::ExternRef(Some(ExternRef::new(*x))),
other => bail!("couldn't convert {:?} to a runtime value", other),
})
}
/// The wast test script language allows modules to be defined and actions
/// to be performed on them.
pub struct WastContext {
/// Wast files have a concept of a "current" module, which is the most
/// recently defined.
current: Option<Instance>,
// FIXME(#1479) this is only needed to retain correct trap information after
// we've dropped previous `Instance` values.
modules: Vec<Module>,
linker: Linker,
store: Store,
}
enum Outcome<T = Vec<Val>> {
Ok(T),
Trap(Trap),
}
impl<T> Outcome<T> {
fn into_result(self) -> Result<T, Trap> {
match self {
Outcome::Ok(t) => Ok(t),
Outcome::Trap(t) => Err(t),
}
}
}
impl WastContext {
/// Construct a new instance of `WastContext`.
pub fn new(store: Store) -> Self {
// Spec tests will redefine the same module/name sometimes, so we need
// to allow shadowing in the linker which picks the most recent
// definition as what to link when linking.
let mut linker = Linker::new(&store);
linker.allow_shadowing(true);
Self {
current: None,
linker,
store,
modules: Vec::new(),
}
}
fn get_export(&self, module: Option<&str>, name: &str) -> Result<Extern> {
match module {
Some(module) => self.linker.get_one_by_name(module, name),
None => self
.current
.as_ref()
.ok_or_else(|| anyhow!("no previous instance found"))?
.get_export(name)
.ok_or_else(|| anyhow!("no item named `{}` found", name)),
}
}
fn instantiate(&mut self, module: &[u8]) -> Result<Outcome<Instance>> {
let module = Module::new(self.store.engine(), module)?;
self.modules.push(module.clone());
let instance = match self.linker.instantiate(&module) {
Ok(i) => i,
Err(e) => return e.downcast::<Trap>().map(Outcome::Trap),
};
Ok(Outcome::Ok(instance))
}
/// Register "spectest" which is used by the spec testsuite.
pub fn register_spectest(&mut self) -> Result<()> {
link_spectest(&mut self.linker)?;
Ok(())
}
/// Perform the action portion of a command.
fn perform_execute(&mut self, exec: wast::WastExecute<'_>) -> Result<Outcome> {
match exec {
wast::WastExecute::Invoke(invoke) => self.perform_invoke(invoke),
wast::WastExecute::Module(mut module) => {
let binary = module.encode()?;
let result = self.instantiate(&binary)?;
Ok(match result {
Outcome::Ok(_) => Outcome::Ok(Vec::new()),
Outcome::Trap(e) => Outcome::Trap(e),
})
}
wast::WastExecute::Get { module, global } => self.get(module.map(|s| s.name()), global),
}
}
fn perform_invoke(&mut self, exec: wast::WastInvoke<'_>) -> Result<Outcome> {
let values = exec
.args
.iter()
.map(|v| runtime_value(v))
.collect::<Result<Vec<_>>>()?;
self.invoke(exec.module.map(|i| i.name()), exec.name, &values)
}
/// Define a module and register it.
fn module(&mut self, instance_name: Option<&str>, module: &[u8]) -> Result<()> {
let instance = match self.instantiate(module)? {
Outcome::Ok(i) => i,
Outcome::Trap(e) => return Err(e).context("instantiation failed"),
};
if let Some(name) = instance_name {
self.linker.instance(name, &instance)?;
}
self.current = Some(instance);
Ok(())
}
/// Register an instance to make it available for performing actions.
fn register(&mut self, name: Option<&str>, as_name: &str) -> Result<()> {
match name {
Some(name) => self.linker.alias(name, as_name),
None => {
let current = self
.current
.as_ref()
.ok_or(anyhow!("no previous instance"))?;
self.linker.instance(as_name, current)?;
Ok(())
}
}
}
/// Invoke an exported function from an instance.
fn invoke(
&mut self,
instance_name: Option<&str>,
field: &str,
args: &[Val],
) -> Result<Outcome> {
let func = self
.get_export(instance_name, field)?
.into_func()
.ok_or_else(|| anyhow!("no function named `{}`", field))?;
Ok(match func.call(args) {
Ok(result) => Outcome::Ok(result.into()),
Err(e) => Outcome::Trap(e.downcast()?),
})
}
/// Get the value of an exported global from an instance.
fn get(&mut self, instance_name: Option<&str>, field: &str) -> Result<Outcome> {
let global = self
.get_export(instance_name, field)?
.into_global()
.ok_or_else(|| anyhow!("no global named `{}`", field))?;
Ok(Outcome::Ok(vec![global.get()]))
}
fn assert_return(&self, result: Outcome, results: &[wast::AssertExpression]) -> Result<()> {
let values = result.into_result()?;
for (v, e) in values.iter().zip(results) {
if val_matches(v, e)? {
continue;
}
bail!("expected {:?}, got {:?}", e, v)
}
Ok(())
}
fn assert_trap(&self, result: Outcome, expected: &str) -> Result<()> {
let trap = match result {
Outcome::Ok(values) => bail!("expected trap, got {:?}", values),
Outcome::Trap(t) => t,
};
let actual = trap.to_string();
if actual.contains(expected)
// `bulk-memory-operations/bulk.wast` checks for a message that
// specifies which element is uninitialized, but our traps don't
// shepherd that information out.
|| (expected.contains("uninitialized element 2") && actual.contains("uninitialized element"))
{
return Ok(());
}
if cfg!(feature = "lightbeam") {
println!("TODO: Check the assert_trap message: {}", expected);
return Ok(());
}
bail!("expected '{}', got '{}'", expected, actual)
}
/// Run a wast script from a byte buffer.
pub fn run_buffer(&mut self, filename: &str, wast: &[u8]) -> Result<()> {
let wast = str::from_utf8(wast)?;
let adjust_wast = |mut err: wast::Error| {
err.set_path(filename.as_ref());
err.set_text(wast);
err
};
let buf = wast::parser::ParseBuffer::new(wast).map_err(adjust_wast)?;
let ast = wast::parser::parse::<wast::Wast>(&buf).map_err(adjust_wast)?;
for directive in ast.directives {
let sp = directive.span();
self.run_directive(directive).with_context(|| {
let (line, col) = sp.linecol_in(wast);
format!("failed directive on {}:{}:{}", filename, line + 1, col)
})?;
}
Ok(())
}
fn run_directive(&mut self, directive: wast::WastDirective) -> Result<()> {
use wast::WastDirective::*;
match directive {
Module(mut module) => {
let binary = module.encode()?;
self.module(module.id.map(|s| s.name()), &binary)?;
}
QuoteModule { span: _, source } => {
let mut module = String::new();
for src in source {
module.push_str(str::from_utf8(src)?);
module.push_str(" ");
}
let buf = ParseBuffer::new(&module)?;
let mut wat = parser::parse::<Wat>(&buf)?;
let binary = wat.module.encode()?;
self.module(wat.module.id.map(|s| s.name()), &binary)?;
}
Register {
span: _,
name,
module,
} => {
self.register(module.map(|s| s.name()), name)?;
}
Invoke(i) => {
self.perform_invoke(i)?;
}
AssertReturn {
span: _,
exec,
results,
} => {
let result = self.perform_execute(exec)?;
self.assert_return(result, &results)?;
}
AssertTrap {
span: _,
exec,
message,
} => {
let result = self.perform_execute(exec)?;
self.assert_trap(result, message)?;
}
AssertExhaustion {
span: _,
call,
message,
} => {
let result = self.perform_invoke(call)?;
self.assert_trap(result, message)?;
}
AssertInvalid {
span: _,
mut module,
message,
} => {
let bytes = module.encode()?;
let err = match self.module(None, &bytes) {
Ok(()) => bail!("expected module to fail to build"),
Err(e) => e,
};
let error_message = format!("{:?}", err);
if !is_matching_assert_invalid_error_message(&message, &error_message) {
bail!(
"assert_invalid: expected \"{}\", got \"{}\"",
message,
error_message
)
}
}
AssertMalformed {
module,
span: _,
message: _,
} => {
let mut module = match module {
wast::QuoteModule::Module(m) => m,
// This is a `*.wat` parser test which we're not
// interested in.
wast::QuoteModule::Quote(_) => return Ok(()),
};
let bytes = module.encode()?;
if let Ok(_) = self.module(None, &bytes) {
bail!("expected malformed module to fail to instantiate");
}
}
AssertUnlinkable {
span: _,
mut module,
message,
} => {
let bytes = module.encode()?;
let err = match self.module(None, &bytes) {
Ok(()) => bail!("expected module to fail to link"),
Err(e) => e,
};
let error_message = format!("{:?}", err);
if !error_message.contains(&message) {
bail!(
"assert_unlinkable: expected {}, got {}",
message,
error_message
)
}
}
}
Ok(())
}
/// Run a wast script from a file.
pub fn run_file(&mut self, path: &Path) -> Result<()> {
let bytes =
std::fs::read(path).with_context(|| format!("failed to read `{}`", path.display()))?;
self.run_buffer(path.to_str().unwrap(), &bytes)
}
}
fn is_matching_assert_invalid_error_message(expected: &str, actual: &str) -> bool {
actual.contains(expected)
// Waiting on https://github.com/WebAssembly/bulk-memory-operations/pull/137
// to propagate to WebAssembly/testsuite.
|| (expected.contains("unknown table") && actual.contains("unknown elem"))
// `elem.wast` and `proposals/bulk-memory-operations/elem.wast` disagree
// on the expected error message for the same error.
|| (expected.contains("out of bounds") && actual.contains("does not fit"))
// slight difference in error messages
|| (expected.contains("unknown elem segment") && actual.contains("unknown element segment"))
}
fn extract_lane_as_i8(bytes: u128, lane: usize) -> i8 {
(bytes >> (lane * 8)) as i8
}
fn extract_lane_as_i16(bytes: u128, lane: usize) -> i16 {
(bytes >> (lane * 16)) as i16
}
fn extract_lane_as_i32(bytes: u128, lane: usize) -> i32 {
(bytes >> (lane * 32)) as i32
}
fn extract_lane_as_i64(bytes: u128, lane: usize) -> i64 {
(bytes >> (lane * 64)) as i64
}
fn is_canonical_f32_nan(bits: u32) -> bool {
(bits & 0x7fff_ffff) == 0x7fc0_0000
}
fn is_canonical_f64_nan(bits: u64) -> bool {
(bits & 0x7fff_ffff_ffff_ffff) == 0x7ff8_0000_0000_0000
}
fn is_arithmetic_f32_nan(bits: u32) -> bool {
const AF32_NAN: u32 = 0x0040_0000;
(bits & AF32_NAN) == AF32_NAN
}
fn is_arithmetic_f64_nan(bits: u64) -> bool {
const AF64_NAN: u64 = 0x0008_0000_0000_0000;
(bits & AF64_NAN) == AF64_NAN
}
fn val_matches(actual: &Val, expected: &wast::AssertExpression) -> Result<bool> {
Ok(match (actual, expected) {
(Val::I32(a), wast::AssertExpression::I32(b)) => a == b,
(Val::I64(a), wast::AssertExpression::I64(b)) => a == b,
// Note that these float comparisons are comparing bits, not float
// values, so we're testing for bit-for-bit equivalence
(Val::F32(a), wast::AssertExpression::F32(b)) => f32_matches(*a, b),
(Val::F64(a), wast::AssertExpression::F64(b)) => f64_matches(*a, b),
(Val::V128(a), wast::AssertExpression::V128(b)) => v128_matches(*a, b),
(Val::ExternRef(x), wast::AssertExpression::RefNull(wast::RefType::Extern)) => x.is_none(),
(Val::ExternRef(x), wast::AssertExpression::RefExtern(y)) => {
if let Some(x) = x {
let x = x
.data()
.downcast_ref::<u32>()
.expect("only u32 externrefs created in wast test suites");
x == y
} else {
false
}
}
(Val::FuncRef(x), wast::AssertExpression::RefNull(wast::RefType::Func)) => x.is_none(),
_ => bail!(
"don't know how to compare {:?} and {:?} yet",
actual,
expected
),
})
}
fn f32_matches(actual: u32, expected: &wast::NanPattern<wast::Float32>) -> bool {
match expected {
wast::NanPattern::CanonicalNan => is_canonical_f32_nan(actual),
wast::NanPattern::ArithmeticNan => is_arithmetic_f32_nan(actual),
wast::NanPattern::Value(expected_value) => actual == expected_value.bits,
}
}
fn f64_matches(actual: u64, expected: &wast::NanPattern<wast::Float64>) -> bool {
match expected {
wast::NanPattern::CanonicalNan => is_canonical_f64_nan(actual),
wast::NanPattern::ArithmeticNan => is_arithmetic_f64_nan(actual),
wast::NanPattern::Value(expected_value) => actual == expected_value.bits,
}
}
fn v128_matches(actual: u128, expected: &wast::V128Pattern) -> bool {
match expected {
wast::V128Pattern::I8x16(b) => b
.iter()
.enumerate()
.all(|(i, b)| *b == extract_lane_as_i8(actual, i)),
wast::V128Pattern::I16x8(b) => b
.iter()
.enumerate()
.all(|(i, b)| *b == extract_lane_as_i16(actual, i)),
wast::V128Pattern::I32x4(b) => b
.iter()
.enumerate()
.all(|(i, b)| *b == extract_lane_as_i32(actual, i)),
wast::V128Pattern::I64x2(b) => b
.iter()
.enumerate()
.all(|(i, b)| *b == extract_lane_as_i64(actual, i)),
wast::V128Pattern::F32x4(b) => b.iter().enumerate().all(|(i, b)| {
let a = extract_lane_as_i32(actual, i) as u32;
f32_matches(a, b)
}),
wast::V128Pattern::F64x2(b) => b.iter().enumerate().all(|(i, b)| {
let a = extract_lane_as_i64(actual, i) as u64;
f64_matches(a, b)
}),
}
}
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