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denoland-rusty-v8/tests/test_api.rs

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// Copyright 2019-2021 the Deno authors. All rights reserved. MIT license.
use once_cell::sync::Lazy;
use std::any::type_name;
use std::borrow::Cow;
use std::cell::RefCell;
use std::collections::hash_map::DefaultHasher;
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use std::collections::{HashMap, HashSet};
use std::convert::{Into, TryFrom, TryInto};
use std::ffi::c_void;
use std::ffi::CStr;
use std::hash::Hash;
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use std::mem::MaybeUninit;
use std::os::raw::c_char;
use std::ptr::{addr_of, NonNull};
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use std::sync::atomic::{AtomicUsize, Ordering};
use std::sync::Arc;
use std::sync::Mutex;
use v8::fast_api::Type::*;
use v8::fast_api::{CType, FastApiTypedArray};
use v8::inspector::ChannelBase;
use v8::{fast_api, AccessorConfiguration};
// TODO(piscisaureus): Ideally there would be no need to import this trait.
use v8::MapFnTo;
mod setup {
use std::sync::Once;
use std::sync::RwLock;
use std::sync::RwLockReadGuard;
use std::sync::RwLockWriteGuard;
static PROCESS_LOCK: RwLock<()> = RwLock::new(());
/// Set up global state for a test that can run in parallel with other tests.
pub(super) fn parallel_test() -> SetupGuard<RwLockReadGuard<'static, ()>> {
initialize_once();
SetupGuard::new(PROCESS_LOCK.read().unwrap())
}
/// Set up global state for a test that must be the only test running.
pub(super) fn sequential_test() -> SetupGuard<RwLockWriteGuard<'static, ()>> {
initialize_once();
SetupGuard::new(PROCESS_LOCK.write().unwrap())
}
fn initialize_once() {
static START: Once = Once::new();
START.call_once(|| {
assert!(v8::icu::set_common_data_73(align_data::include_aligned!(
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align_data::Align16,
"../third_party/icu/common/icudtl.dat"
))
.is_ok());
v8::V8::set_flags_from_string(
"--no_freeze_flags_after_init --expose_gc --harmony-import-assertions --harmony-shadow-realm --allow_natives_syntax --turbo_fast_api_calls",
);
v8::V8::initialize_platform(
v8::new_unprotected_default_platform(0, false).make_shared(),
);
v8::V8::initialize();
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});
}
#[must_use]
pub(super) struct SetupGuard<G> {
_inner: G,
}
impl<G> SetupGuard<G> {
fn new(inner: G) -> Self {
Self { _inner: inner }
}
}
}
#[test]
fn handle_scope_nested() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope1 = &mut v8::HandleScope::new(isolate);
{
let _scope2 = &mut v8::HandleScope::new(scope1);
}
}
}
#[test]
#[allow(clippy::float_cmp)]
fn handle_scope_numbers() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope1 = &mut v8::HandleScope::new(isolate);
let l1 = v8::Integer::new(scope1, -123);
let l2 = v8::Integer::new_from_unsigned(scope1, 456);
{
let scope2 = &mut v8::HandleScope::new(scope1);
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let l3 = v8::Number::new(scope2, 78.9);
let l4 = v8::Local::<v8::Int32>::try_from(l1).unwrap();
let l5 = v8::Local::<v8::Uint32>::try_from(l2).unwrap();
assert_eq!(l1.value(), -123);
assert_eq!(l2.value(), 456);
assert_eq!(l3.value(), 78.9);
assert_eq!(l4.value(), -123);
assert_eq!(l5.value(), 456);
assert_eq!(v8::Number::value(&l1), -123f64);
assert_eq!(v8::Number::value(&l2), 456f64);
}
}
}
#[test]
fn handle_scope_non_lexical_lifetime() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope1 = &mut v8::HandleScope::new(isolate);
// Despite `local` living slightly longer than `scope2`, this test should
// not crash.
let local = {
let scope2 = &mut v8::HandleScope::new(scope1);
v8::Integer::new(scope2, 123)
};
assert_eq!(local.value(), 123);
}
#[test]
fn global_handles() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let g1: v8::Global<v8::String>;
let mut g2: Option<v8::Global<v8::Integer>> = None;
let g3: v8::Global<v8::Integer>;
let g4: v8::Global<v8::Integer>;
let mut g5: Option<v8::Global<v8::Integer>> = None;
let g6;
{
let scope = &mut v8::HandleScope::new(isolate);
let l1 = v8::String::new(scope, "bla").unwrap();
let l2 = v8::Integer::new(scope, 123);
g1 = v8::Global::new(scope, l1);
g2.replace(v8::Global::new(scope, l2));
g3 = v8::Global::new(scope, g2.as_ref().unwrap());
g4 = v8::Global::new(scope, l2);
let l5 = v8::Integer::new(scope, 100);
g5.replace(v8::Global::new(scope, l5));
g6 = g1.clone();
}
{
let scope = &mut v8::HandleScope::new(isolate);
assert_eq!(g1.open(scope).to_rust_string_lossy(scope), "bla");
assert_eq!(g2.as_ref().unwrap().open(scope).value(), 123);
assert_eq!(g3.open(scope).value(), 123);
assert_eq!(g4.open(scope).value(), 123);
{
let num = g5.as_ref().unwrap().open(scope);
assert_eq!(num.value(), 100);
}
g5.take();
assert!(g6 == g1);
assert_eq!(g6.open(scope).to_rust_string_lossy(scope), "bla");
}
{
let g1_ptr = g1.clone().into_raw();
let g1_reconstructed = unsafe { v8::Global::from_raw(isolate, g1_ptr) };
assert_eq!(g1, g1_reconstructed);
}
}
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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#[test]
fn global_from_into_raw() {
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let (raw, weak) = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
let global = v8::Global::new(scope, local);
let weak = v8::Weak::new(scope, &global);
let raw = global.into_raw();
(raw, weak)
};
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(!weak.is_empty());
{
let reconstructed = unsafe { v8::Global::from_raw(scope, raw) };
let global_from_weak = weak.to_global(scope).unwrap();
assert_eq!(global_from_weak, reconstructed);
}
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak.is_empty());
}
#[test]
fn local_handle_deref() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let key = v8::String::new(scope, "key").unwrap();
let obj: v8::Local<v8::Object> = v8::Object::new(scope);
obj.get(scope, key.into());
{
use v8::Handle;
obj.get(scope, key.into());
obj.open(scope).get(scope, key.into());
}
}
#[test]
fn global_handle_drop() {
let _setup_guard = setup::parallel_test();
// Global 'g1' will be dropped _after_ the Isolate has been disposed.
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#[allow(clippy::needless_late_init)]
let _g1: v8::Global<v8::String>;
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let l1 = v8::String::new(scope, "foo").unwrap();
_g1 = v8::Global::new(scope, l1);
// Global 'g2' will be dropped _before_ the Isolate has been disposed.
let l2 = v8::String::new(scope, "bar").unwrap();
let _g2 = v8::Global::new(scope, l2);
}
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#[test]
fn test_string() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
// Ensure that a Latin-1 string correctly round-trips
let scope = &mut v8::HandleScope::new(isolate);
let reference = "\u{00a0}";
assert_eq!(2, reference.len());
let local = v8::String::new(scope, reference).unwrap();
assert_eq!(1, local.length());
assert_eq!(2, local.utf8_length(scope));
// Should round-trip to UTF-8
assert_eq!(2, local.to_rust_string_lossy(scope).len());
let mut buf = [MaybeUninit::uninit(); 0];
assert_eq!(2, local.to_rust_cow_lossy(scope, &mut buf).len());
let mut buf = [MaybeUninit::uninit(); 10];
assert_eq!(2, local.to_rust_cow_lossy(scope, &mut buf).len());
}
{
let scope = &mut v8::HandleScope::new(isolate);
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let reference = "Hello 🦕 world!";
let local = v8::String::new(scope, reference).unwrap();
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assert_eq!(15, local.length());
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assert_eq!(17, local.utf8_length(scope));
assert_eq!(reference, local.to_rust_string_lossy(scope));
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let mut vec = vec![0; 17];
let options = v8::WriteOptions::NO_NULL_TERMINATION;
let mut nchars = 0;
assert_eq!(
17,
local.write_utf8(scope, &mut vec, Some(&mut nchars), options)
);
assert_eq!(15, nchars);
let mut u16_buffer = [0u16; 16];
assert_eq!(15, local.write(scope, &mut u16_buffer, 0, options));
assert_eq!(
String::from(reference),
String::from_utf16(&u16_buffer[..15]).unwrap()
);
}
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{
let scope = &mut v8::HandleScope::new(isolate);
let local = v8::String::empty(scope);
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assert_eq!(0, local.length());
assert_eq!(0, local.utf8_length(scope));
assert_eq!("", local.to_rust_string_lossy(scope));
}
{
let scope = &mut v8::HandleScope::new(isolate);
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let local =
v8::String::new_from_utf8(scope, b"", v8::NewStringType::Normal).unwrap();
assert_eq!(0, local.length());
assert_eq!(0, local.utf8_length(scope));
assert_eq!("", local.to_rust_string_lossy(scope));
}
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{
let scope = &mut v8::HandleScope::new(isolate);
let local =
v8::String::new_from_one_byte(scope, b"foo", v8::NewStringType::Normal)
.unwrap();
assert_eq!(3, local.length());
assert_eq!(3, local.utf8_length(scope));
let options = v8::WriteOptions::NO_NULL_TERMINATION;
let mut buffer = [0u8; 3];
assert_eq!(3, local.write_one_byte(scope, &mut buffer, 0, options));
assert_eq!(b"foo", &buffer);
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assert_eq!("foo", local.to_rust_string_lossy(scope));
}
{
let scope = &mut v8::HandleScope::new(isolate);
let local = v8::String::new_from_two_byte(
scope,
&[0xD83E, 0xDD95],
v8::NewStringType::Normal,
)
.unwrap();
assert_eq!(2, local.length());
assert_eq!(4, local.utf8_length(scope));
assert_eq!("🦕", local.to_rust_string_lossy(scope));
}
{
let scope = &mut v8::HandleScope::new(isolate);
let mut buffer = Vec::with_capacity(v8::String::max_length());
for _ in 0..buffer.capacity() / 4 {
// U+10348 in UTF-8
buffer.push(0xF0_u8);
buffer.push(0x90_u8);
buffer.push(0x8D_u8);
buffer.push(0x88_u8);
}
let local =
v8::String::new_from_utf8(scope, &buffer, v8::NewStringType::Normal)
.unwrap();
// U+10348 is 2 UTF-16 code units, which is the unit of v8::String.length().
assert_eq!(v8::String::max_length() / 2, local.length());
assert_eq!(
buffer.as_slice(),
local.to_rust_string_lossy(scope).as_bytes()
);
let mut too_long = Vec::with_capacity(v8::String::max_length() + 4);
for _ in 0..too_long.capacity() / 4 {
// U+10348 in UTF-8
too_long.push(0xF0_u8);
too_long.push(0x90_u8);
too_long.push(0x8D_u8);
too_long.push(0x88_u8);
}
let none =
v8::String::new_from_utf8(scope, &too_long, v8::NewStringType::Normal);
assert!(none.is_none());
}
{
let scope = &mut v8::HandleScope::new(isolate);
let invalid_sequence_identifier = v8::String::new_from_utf8(
scope,
&[0xa0, 0xa1],
v8::NewStringType::Normal,
);
assert!(invalid_sequence_identifier.is_some());
let invalid_sequence_identifier = invalid_sequence_identifier.unwrap();
assert_eq!(invalid_sequence_identifier.length(), 2);
let invalid_3_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xe2, 0x28, 0xa1],
v8::NewStringType::Normal,
);
assert!(invalid_3_octet_sequence.is_some());
let invalid_3_octet_sequence = invalid_3_octet_sequence.unwrap();
assert_eq!(invalid_3_octet_sequence.length(), 3);
let invalid_3_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xe2, 0x82, 0x28],
v8::NewStringType::Normal,
);
assert!(invalid_3_octet_sequence.is_some());
let invalid_3_octet_sequence = invalid_3_octet_sequence.unwrap();
assert_eq!(invalid_3_octet_sequence.length(), 2);
let invalid_4_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xf0, 0x28, 0x8c, 0xbc],
v8::NewStringType::Normal,
);
assert!(invalid_4_octet_sequence.is_some());
let invalid_4_octet_sequence = invalid_4_octet_sequence.unwrap();
assert_eq!(invalid_4_octet_sequence.length(), 4);
let invalid_4_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xf0, 0x90, 0x28, 0xbc],
v8::NewStringType::Normal,
);
assert!(invalid_4_octet_sequence.is_some());
let invalid_4_octet_sequence = invalid_4_octet_sequence.unwrap();
assert_eq!(invalid_4_octet_sequence.length(), 3);
let invalid_4_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xf0, 0x28, 0x8c, 0x28],
v8::NewStringType::Normal,
);
assert!(invalid_4_octet_sequence.is_some());
let invalid_4_octet_sequence = invalid_4_octet_sequence.unwrap();
assert_eq!(invalid_4_octet_sequence.length(), 4);
let valid_5_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xf8, 0xa1, 0xa1, 0xa1, 0xa1],
v8::NewStringType::Normal,
);
assert!(valid_5_octet_sequence.is_some());
let invalid_4_octet_sequence = valid_5_octet_sequence.unwrap();
assert_eq!(invalid_4_octet_sequence.length(), 5);
let valid_6_octet_sequence = v8::String::new_from_utf8(
scope,
&[0xfc, 0xa1, 0xa1, 0xa1, 0xa1, 0xa1],
v8::NewStringType::Normal,
);
assert!(valid_6_octet_sequence.is_some());
let invalid_4_octet_sequence = valid_6_octet_sequence.unwrap();
assert_eq!(invalid_4_octet_sequence.length(), 6);
}
{
let scope = &mut v8::HandleScope::new(isolate);
let s = "Lorem ipsum dolor sit amet. Qui inventore debitis et voluptas cupiditate qui recusandae molestias et ullam possimus";
let one_byte = v8::String::new_from_one_byte(
scope,
s.as_bytes(),
v8::NewStringType::Normal,
)
.unwrap();
// Does not fit
let mut buffer = [MaybeUninit::uninit(); 10];
let cow = one_byte.to_rust_cow_lossy(scope, &mut buffer);
assert!(matches!(cow, Cow::Owned(_)));
assert_eq!(s, cow);
// Fits
let mut buffer = [MaybeUninit::uninit(); 1000];
let cow = one_byte.to_rust_cow_lossy(scope, &mut buffer);
assert!(matches!(cow, Cow::Borrowed(_)));
assert_eq!(s, cow);
let s = "🦕 Lorem ipsum dolor sit amet. Qui inventore debitis et voluptas cupiditate qui recusandae molestias et ullam possimus";
let two_bytes =
v8::String::new_from_utf8(scope, s.as_bytes(), v8::NewStringType::Normal)
.unwrap();
// Does not fit
let mut buffer = [MaybeUninit::uninit(); 10];
let cow = two_bytes.to_rust_cow_lossy(scope, &mut buffer);
assert!(matches!(cow, Cow::Owned(_)));
assert_eq!(s, cow);
// Fits
let mut buffer = [MaybeUninit::uninit(); 1000];
let cow = two_bytes.to_rust_cow_lossy(scope, &mut buffer);
assert!(matches!(cow, Cow::Borrowed(_)));
assert_eq!(s, cow);
}
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}
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#[test]
#[allow(clippy::float_cmp)]
fn escapable_handle_scope() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let handle_scope = &mut v8::HandleScope::new(isolate);
// After dropping EscapableHandleScope, we should be able to
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// read escaped values.
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let number = {
let escapable_scope = &mut v8::EscapableHandleScope::new(handle_scope);
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let number = v8::Number::new(escapable_scope, 78.9);
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escapable_scope.escape(number)
};
assert_eq!(number.value(), 78.9);
let string = {
let escapable_scope = &mut v8::EscapableHandleScope::new(handle_scope);
let string = v8::String::new(escapable_scope, "Hello 🦕 world!").unwrap();
escapable_scope.escape(string)
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};
assert_eq!("Hello 🦕 world!", string.to_rust_string_lossy(handle_scope));
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let string = {
let escapable_scope = &mut v8::EscapableHandleScope::new(handle_scope);
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let nested_str_val = {
let nested_escapable_scope =
&mut v8::EscapableHandleScope::new(escapable_scope);
let string =
v8::String::new(nested_escapable_scope, "Hello 🦕 world!").unwrap();
nested_escapable_scope.escape(string)
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};
escapable_scope.escape(nested_str_val)
};
assert_eq!("Hello 🦕 world!", string.to_rust_string_lossy(handle_scope));
}
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}
#[test]
#[should_panic(expected = "EscapableHandleScope::escape() called twice")]
fn escapable_handle_scope_can_escape_only_once() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope1 = &mut v8::HandleScope::new(isolate);
let scope2 = &mut v8::EscapableHandleScope::new(scope1);
let local1 = v8::Integer::new(scope2, -123);
let escaped1 = scope2.escape(local1);
assert!(escaped1 == local1);
let local2 = v8::Integer::new(scope2, 456);
let escaped2 = scope2.escape(local2);
assert!(escaped2 == local2);
}
#[test]
fn context_scope() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context1 = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context1);
assert!(scope.get_current_context() == context1);
assert!(scope.get_entered_or_microtask_context() == context1);
{
let context2 = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context2);
assert!(scope.get_current_context() == context2);
assert!(scope.get_entered_or_microtask_context() == context2);
}
assert!(scope.get_current_context() == context1);
assert!(scope.get_entered_or_microtask_context() == context1);
}
#[test]
#[should_panic(
expected = "HandleScope<()> and Context do not belong to the same Isolate"
)]
fn context_scope_param_and_context_must_share_isolate() {
let _setup_guard = setup::parallel_test();
let isolate1 = &mut v8::Isolate::new(Default::default());
let isolate2 = &mut v8::Isolate::new(Default::default());
let scope1 = &mut v8::HandleScope::new(isolate1);
let scope2 = &mut v8::HandleScope::new(isolate2);
let context1 = v8::Context::new(scope1);
let context2 = v8::Context::new(scope2);
let _context_scope_12 = &mut v8::ContextScope::new(scope1, context2);
let _context_scope_21 = &mut v8::ContextScope::new(scope2, context1);
}
#[test]
#[should_panic(
expected = "attempt to use Handle in an Isolate that is not its host"
)]
fn handle_scope_param_and_context_must_share_isolate() {
let _setup_guard = setup::parallel_test();
let isolate1 = &mut v8::Isolate::new(Default::default());
let isolate2 = &mut v8::Isolate::new(Default::default());
let global_context1;
let global_context2;
{
let scope1 = &mut v8::HandleScope::new(isolate1);
let scope2 = &mut v8::HandleScope::new(isolate2);
let local_context_1 = v8::Context::new(scope1);
let local_context_2 = v8::Context::new(scope2);
global_context1 = v8::Global::new(scope1, local_context_1);
global_context2 = v8::Global::new(scope2, local_context_2);
}
let _handle_scope_12 =
&mut v8::HandleScope::with_context(isolate1, global_context2);
let _handle_scope_21 =
&mut v8::HandleScope::with_context(isolate2, global_context1);
}
#[test]
fn microtasks() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
assert_eq!(isolate.get_microtasks_policy(), v8::MicrotasksPolicy::Auto);
isolate.set_microtasks_policy(v8::MicrotasksPolicy::Explicit);
assert_eq!(
isolate.get_microtasks_policy(),
v8::MicrotasksPolicy::Explicit
);
isolate.perform_microtask_checkpoint();
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
let function = v8::Function::new(
scope,
|_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
_: v8::ReturnValue| {
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
},
)
.unwrap();
scope.enqueue_microtask(function);
// Flushes the microtasks queue unless the policy is set to explicit.
let _ = eval(scope, "").unwrap();
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 0);
scope.perform_microtask_checkpoint();
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
scope.set_microtasks_policy(v8::MicrotasksPolicy::Auto);
assert_eq!(scope.get_microtasks_policy(), v8::MicrotasksPolicy::Auto);
scope.enqueue_microtask(function);
let _ = eval(scope, "").unwrap();
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 2);
}
}
#[test]
#[should_panic(
expected = "v8::OwnedIsolate instances must be dropped in the reverse order of creation. They are entered upon creation and exited upon being dropped."
)]
fn isolate_drop_order() {
let isolate1 = v8::Isolate::new(Default::default());
let isolate2 = v8::Isolate::new(Default::default());
drop(isolate1);
drop(isolate2);
}
#[test]
fn get_isolate_from_handle() {
extern "C" {
fn v8__internal__GetIsolateFromHeapObject(
location: *const v8::Data,
) -> *mut v8::Isolate;
}
fn check_handle_helper(
isolate: &mut v8::Isolate,
expect_some: Option<bool>,
local: v8::Local<v8::Data>,
) {
let isolate_ptr = NonNull::from(isolate);
let maybe_ptr = unsafe { v8__internal__GetIsolateFromHeapObject(&*local) };
let maybe_ptr = NonNull::new(maybe_ptr);
if let Some(ptr) = maybe_ptr {
assert_eq!(ptr, isolate_ptr);
}
if let Some(expected_some) = expect_some {
assert_eq!(maybe_ptr.is_some(), expected_some);
}
}
fn check_handle<'s, F, D>(
scope: &mut v8::HandleScope<'s>,
expect_some: Option<bool>,
f: F,
) where
F: Fn(&mut v8::HandleScope<'s>) -> D,
D: Into<v8::Local<'s, v8::Data>>,
{
let local = f(scope).into();
// Check that we can get the isolate from a Local.
check_handle_helper(scope, expect_some, local);
// Check that we can still get it after converting it to a Global.
let global = v8::Global::new(scope, local);
let local2 = v8::Local::new(scope, &global);
check_handle_helper(scope, expect_some, local2);
}
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fn check_eval(
scope: &mut v8::HandleScope,
expect_some: Option<bool>,
code: &str,
) {
check_handle(scope, expect_some, |scope| eval(scope, code).unwrap());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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check_handle(scope, None, v8::null);
check_handle(scope, None, v8::undefined);
check_handle(scope, None, |s| v8::Boolean::new(s, true));
check_handle(scope, None, |s| v8::Boolean::new(s, false));
check_handle(scope, None, |s| v8::String::new(s, "").unwrap());
check_eval(scope, None, "''");
check_handle(scope, Some(true), |s| v8::String::new(s, "Words").unwrap());
check_eval(scope, Some(true), "'Hello'");
check_eval(scope, Some(true), "Symbol()");
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check_handle(scope, Some(true), v8::Object::new);
check_eval(scope, Some(true), "this");
check_handle(scope, Some(true), |s| s.get_current_context());
check_eval(scope, Some(true), "({ foo: 'bar' })");
check_eval(scope, Some(true), "() => {}");
check_handle(scope, Some(true), |s| v8::Number::new(s, 4.2f64));
check_handle(scope, Some(true), |s| v8::Number::new(s, -0f64));
check_handle(scope, Some(false), |s| v8::Integer::new(s, 0));
check_eval(scope, Some(true), "3.3");
check_eval(scope, Some(false), "3.3 / 3.3");
}
#[test]
fn handles_from_isolate() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let _ = v8::null(isolate);
let _ = v8::undefined(isolate);
let _ = v8::Boolean::new(isolate, true);
}
#[test]
fn array_buffer() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let ab = v8::ArrayBuffer::new(scope, 42);
assert_eq!(42, ab.byte_length());
assert!(!ab.was_detached());
assert!(ab.is_detachable());
assert!(ab.detach(None).unwrap());
assert_eq!(0, ab.byte_length());
assert!(ab.was_detached());
assert!(ab.detach(None).unwrap()); // Calling it twice should be a no-op.
// detecting if it was detached on a zero-length ArrayBuffer should work
let empty_ab = v8::ArrayBuffer::new(scope, 0);
assert!(!empty_ab.was_detached());
assert!(empty_ab.detach(None).unwrap());
assert!(empty_ab.was_detached());
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let bs = v8::ArrayBuffer::new_backing_store(scope, 84);
assert_eq!(84, bs.byte_length());
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assert!(!bs.is_shared());
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// SAFETY: Manually deallocating memory once V8 calls the
// deleter callback.
unsafe extern "C" fn backing_store_deleter_callback(
data: *mut c_void,
byte_length: usize,
deleter_data: *mut c_void,
) {
let slice = std::slice::from_raw_parts(data as *const u8, byte_length);
assert_eq!(slice, &[0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);
assert_eq!(byte_length, 10);
assert_eq!(deleter_data, std::ptr::null_mut());
let layout = std::alloc::Layout::new::<[u8; 10]>();
std::alloc::dealloc(data as *mut u8, layout);
}
// SAFETY: Manually allocating memory so that it will be only
// deleted when V8 calls deleter callback.
let data = unsafe {
let layout = std::alloc::Layout::new::<[u8; 10]>();
let ptr = std::alloc::alloc(layout);
(ptr as *mut [u8; 10]).write([0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);
ptr as *mut c_void
};
let unique_bs = unsafe {
v8::ArrayBuffer::new_backing_store_from_ptr(
data,
10,
backing_store_deleter_callback,
std::ptr::null_mut(),
)
};
assert_eq!(10, unique_bs.byte_length());
assert!(!unique_bs.is_shared());
assert_eq!(unique_bs[0].get(), 0);
assert_eq!(unique_bs[9].get(), 9);
// From Box<[u8]>
let data: Box<[u8]> = vec![0, 1, 2, 3, 4, 5, 6, 7, 8, 9].into_boxed_slice();
let unique_bs = v8::ArrayBuffer::new_backing_store_from_boxed_slice(data);
assert_eq!(10, unique_bs.byte_length());
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assert!(!unique_bs.is_shared());
assert_eq!(unique_bs[0].get(), 0);
assert_eq!(unique_bs[9].get(), 9);
let shared_bs_1 = unique_bs.make_shared();
assert_eq!(10, shared_bs_1.byte_length());
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assert!(!shared_bs_1.is_shared());
assert_eq!(shared_bs_1[0].get(), 0);
assert_eq!(shared_bs_1[9].get(), 9);
let ab = v8::ArrayBuffer::with_backing_store(scope, &shared_bs_1);
let shared_bs_2 = ab.get_backing_store();
assert_eq!(10, shared_bs_2.byte_length());
assert_eq!(shared_bs_2[0].get(), 0);
assert_eq!(shared_bs_2[9].get(), 9);
// From Vec<u8>
let data = vec![0, 1, 2, 3, 4, 5, 6, 7, 8, 9];
let unique_bs = v8::ArrayBuffer::new_backing_store_from_vec(data);
assert_eq!(10, unique_bs.byte_length());
assert!(!unique_bs.is_shared());
assert_eq!(unique_bs[0].get(), 0);
assert_eq!(unique_bs[9].get(), 9);
let shared_bs_1 = unique_bs.make_shared();
assert_eq!(10, shared_bs_1.byte_length());
assert!(!shared_bs_1.is_shared());
assert_eq!(shared_bs_1[0].get(), 0);
assert_eq!(shared_bs_1[9].get(), 9);
let ab = v8::ArrayBuffer::with_backing_store(scope, &shared_bs_1);
let shared_bs_2 = ab.get_backing_store();
assert_eq!(10, shared_bs_2.byte_length());
assert_eq!(shared_bs_2[0].get(), 0);
assert_eq!(shared_bs_2[9].get(), 9);
// Empty
let ab = v8::ArrayBuffer::empty(scope);
assert_eq!(0, ab.byte_length());
assert!(!ab.get_backing_store().is_shared());
// Empty but from vec
let ab = v8::ArrayBuffer::with_backing_store(
scope,
&v8::ArrayBuffer::new_backing_store_from_bytes(vec![]).make_shared(),
);
assert_eq!(0, ab.byte_length());
assert!(!ab.get_backing_store().is_shared());
// Empty but from vec with a huge capacity
let mut v = Vec::with_capacity(10_000_000);
v.extend_from_slice(&[1, 2, 3, 4]);
let ab = v8::ArrayBuffer::with_backing_store(
scope,
&v8::ArrayBuffer::new_backing_store_from_bytes(v).make_shared(),
);
// Allocate a completely unused buffer overtop of the old allocation
let mut v2: Vec<u8> = Vec::with_capacity(10_000_000);
v2.extend_from_slice(&[10, 20, 30, 40]);
// Make sure the the arraybuffer didn't get stomped
assert_eq!(4, ab.byte_length());
assert_eq!(1, ab.get_backing_store()[0].get());
assert_eq!(2, ab.get_backing_store()[1].get());
assert_eq!(3, ab.get_backing_store()[2].get());
assert_eq!(4, ab.get_backing_store()[3].get());
assert!(!ab.get_backing_store().is_shared());
drop(v2);
// From a bytes::BytesMut
let mut data = bytes::BytesMut::new();
data.extend_from_slice(&[100; 16]);
data[0] = 1;
let unique_bs =
v8::ArrayBuffer::new_backing_store_from_bytes(Box::new(data));
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assert_eq!(unique_bs.first().unwrap().get(), 1);
assert_eq!(unique_bs.get(15).unwrap().get(), 100);
let ab =
v8::ArrayBuffer::with_backing_store(scope, &unique_bs.make_shared());
assert_eq!(ab.byte_length(), 16);
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assert_eq!(ab.get_backing_store().first().unwrap().get(), 1);
}
}
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#[test]
fn backing_store_segfault() {
let _setup_guard = setup::parallel_test();
let array_buffer_allocator = v8::new_default_allocator().make_shared();
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let shared_bs = {
array_buffer_allocator.assert_use_count_eq(1);
let params = v8::Isolate::create_params()
.array_buffer_allocator(array_buffer_allocator.clone());
array_buffer_allocator.assert_use_count_eq(2);
let isolate = &mut v8::Isolate::new(params);
array_buffer_allocator.assert_use_count_eq(2);
let scope = &mut v8::HandleScope::new(isolate);
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let ab = v8::ArrayBuffer::new(scope, 10);
let shared_bs = ab.get_backing_store();
array_buffer_allocator.assert_use_count_eq(3);
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shared_bs
};
shared_bs.assert_use_count_eq(1);
array_buffer_allocator.assert_use_count_eq(2);
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drop(array_buffer_allocator);
drop(shared_bs); // Error occurred here.
}
#[test]
fn shared_array_buffer_allocator() {
let alloc1 = v8::new_default_allocator().make_shared();
alloc1.assert_use_count_eq(1);
let alloc2 = alloc1.clone();
alloc1.assert_use_count_eq(2);
alloc2.assert_use_count_eq(2);
let mut alloc2 = v8::SharedPtr::from(alloc2);
alloc1.assert_use_count_eq(2);
alloc2.assert_use_count_eq(2);
drop(alloc1);
alloc2.assert_use_count_eq(1);
alloc2.take();
alloc2.assert_use_count_eq(0);
}
#[test]
fn array_buffer_with_shared_backing_store() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let ab1 = v8::ArrayBuffer::new(scope, 42);
assert_eq!(42, ab1.byte_length());
let bs1 = ab1.get_backing_store();
assert_eq!(ab1.byte_length(), bs1.byte_length());
bs1.assert_use_count_eq(2);
let bs2 = ab1.get_backing_store();
assert_eq!(ab1.byte_length(), bs2.byte_length());
bs1.assert_use_count_eq(3);
bs2.assert_use_count_eq(3);
let bs3 = ab1.get_backing_store();
assert_eq!(ab1.byte_length(), bs3.byte_length());
bs1.assert_use_count_eq(4);
bs2.assert_use_count_eq(4);
bs3.assert_use_count_eq(4);
drop(bs2);
bs1.assert_use_count_eq(3);
bs3.assert_use_count_eq(3);
drop(bs1);
bs3.assert_use_count_eq(2);
let ab2 = v8::ArrayBuffer::with_backing_store(scope, &bs3);
assert_eq!(ab1.byte_length(), ab2.byte_length());
bs3.assert_use_count_eq(3);
let bs4 = ab2.get_backing_store();
assert_eq!(ab1.byte_length(), bs4.byte_length());
bs3.assert_use_count_eq(4);
bs4.assert_use_count_eq(4);
let bs5 = bs4.clone();
bs3.assert_use_count_eq(5);
bs4.assert_use_count_eq(5);
bs5.assert_use_count_eq(5);
drop(bs3);
bs4.assert_use_count_eq(4);
bs5.assert_use_count_eq(4);
drop(bs4);
bs5.assert_use_count_eq(3);
}
}
#[test]
fn deref_empty_backing_store() {
// Test that the slice that results from derefing a backing store is not
// backed by a null pointer, since that would be UB.
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let backing_store = v8::ArrayBuffer::new_backing_store(isolate, 0);
let slice: &[std::cell::Cell<u8>] = &backing_store;
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assert!(!std::hint::black_box(slice.as_ptr()).is_null());
}
fn eval<'s>(
scope: &mut v8::HandleScope<'s>,
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code: &str,
) -> Option<v8::Local<'s, v8::Value>> {
let scope = &mut v8::EscapableHandleScope::new(scope);
let source = v8::String::new(scope, code).unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let r = script.run(scope);
r.map(|v| scope.escape(v))
}
#[test]
fn external() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let ex1_value = 1usize as *mut std::ffi::c_void;
let ex1_handle_a = v8::External::new(scope, ex1_value);
assert_eq!(ex1_handle_a.value(), ex1_value);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let ex2_value = 2334567usize as *mut std::ffi::c_void;
let ex3_value = -2isize as *mut std::ffi::c_void;
let ex2_handle_a = v8::External::new(scope, ex2_value);
let ex3_handle_a = v8::External::new(scope, ex3_value);
assert!(ex1_handle_a != ex2_handle_a);
assert!(ex2_handle_a != ex3_handle_a);
assert!(ex3_handle_a != ex1_handle_a);
assert_ne!(ex2_value, ex3_value);
assert_eq!(ex2_handle_a.value(), ex2_value);
assert_eq!(ex3_handle_a.value(), ex3_value);
let ex1_key = v8::String::new(scope, "ex1").unwrap().into();
let ex2_key = v8::String::new(scope, "ex2").unwrap().into();
let ex3_key = v8::String::new(scope, "ex3").unwrap().into();
global.set(scope, ex1_key, ex1_handle_a.into());
global.set(scope, ex2_key, ex2_handle_a.into());
global.set(scope, ex3_key, ex3_handle_a.into());
let ex1_handle_b: v8::Local<v8::External> =
eval(scope, "ex1").unwrap().try_into().unwrap();
let ex2_handle_b: v8::Local<v8::External> =
eval(scope, "ex2").unwrap().try_into().unwrap();
let ex3_handle_b: v8::Local<v8::External> =
eval(scope, "ex3").unwrap().try_into().unwrap();
assert!(ex1_handle_b != ex2_handle_b);
assert!(ex2_handle_b != ex3_handle_b);
assert!(ex3_handle_b != ex1_handle_b);
assert!(ex1_handle_a == ex1_handle_b);
assert!(ex2_handle_a == ex2_handle_b);
assert!(ex3_handle_a == ex3_handle_b);
assert_ne!(ex1_handle_a.value(), ex2_value);
assert_ne!(ex2_handle_a.value(), ex3_value);
assert_ne!(ex3_handle_a.value(), ex1_value);
assert_eq!(ex1_handle_a.value(), ex1_value);
assert_eq!(ex2_handle_a.value(), ex2_value);
assert_eq!(ex3_handle_a.value(), ex3_value);
}
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#[test]
fn try_catch() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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{
// Error thrown - should be caught.
let tc = &mut v8::TryCatch::new(scope);
let result = eval(tc, "throw new Error('foo')");
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assert!(result.is_none());
assert!(tc.has_caught());
assert!(tc.exception().is_some());
assert!(tc.stack_trace().is_some());
assert!(tc.message().is_some());
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assert_eq!(
tc.message().unwrap().get(tc).to_rust_string_lossy(tc),
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"Uncaught Error: foo"
);
};
{
// No error thrown.
let tc = &mut v8::TryCatch::new(scope);
let result = eval(tc, "1 + 1");
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assert!(result.is_some());
assert!(!tc.has_caught());
assert!(tc.exception().is_none());
assert!(tc.stack_trace().is_none());
assert!(tc.message().is_none());
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assert!(tc.rethrow().is_none());
};
{
// Rethrow and reset.
let tc1 = &mut v8::TryCatch::new(scope);
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{
let tc2 = &mut v8::TryCatch::new(tc1);
eval(tc2, "throw 'bar'");
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assert!(tc2.has_caught());
assert!(tc2.rethrow().is_some());
tc2.reset();
Upgrade to V8 12.1.285.6 (#1374) 1. [[exceptions] Unify pending and scheduled exceptions](https://chromium-review.googlesource.com/c/v8/v8/+/5050065) Reset no longer clears exception if it was rethrown. The test had to be adjusted for the same. 2. [[api] Allow passing CppHeap on Isolate creation](https://chromium-review.googlesource.com/c/v8/v8/+/4989254) `AttachCppHeap` was deprecated but the alternative of passing `CppHeap` via Isolate CreateParams hard crashes (SIGSEGV). There are no tests for this in V8 and it seems the [Chromium CL](https://chromium-review.googlesource.com/c/chromium/src/+/4992764) is also crashing. For now I've just suppressed the deprecation warning until the crash is fixed in V8. 3. v8::Serializer impl must not throw more than one exception. I changed `get_shared_buffer_id()` to not throw and return `None`. V8 internally calls data clone error when it's the SAB is not clonable. Other changes: - `v8::ScriptCompiler` size increased by 3 words with `v8::ScriptCompiler::CompilationDetails`. - `v8::ObjectTemplate::SetAccessor` & `v8::ObjectTemplate::SetAccessorProperty` signature changed and also deprecated. - `v8::Context::SetContinuationPreservedEmbedderData` deprecated. Use `v8::Isolate::GetContinuationPreservedEmbedderData` instead. - `GetStalledTopLevelAwaitMessage` deprecated. Use `GetStalledTopLevelAwaitMessages` instead. - `v8::Isolate::AttachCppHeap` deprecated. Set the heap on Isolate creation using CreateParams instead. - `v8::ScriptOrigin` deprecated. Use constructor without the isolate. - `v8::SnapshotCreator` is deprecated. Use the version that passes CreateParams instead. - `v8::Isolate` assertion failures. Co-authored-by: Bartek Iwańczuk <biwanczuk@gmail.com>
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// Reset does not clear exception on rethrow.
// https://chromium-review.googlesource.com/c/v8/v8/+/5050065
assert!(tc2.has_caught());
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}
assert!(tc1.has_caught());
};
}
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}
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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#[test]
fn try_catch_caught_lifetime() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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let (caught_exc, caught_msg) = {
let tc = &mut v8::TryCatch::new(scope);
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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// Throw exception.
let msg = v8::String::new(tc, "DANG!").unwrap();
let exc = v8::Exception::type_error(tc, msg);
tc.throw_exception(exc);
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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// Catch exception.
let caught_exc = tc.exception().unwrap();
let caught_msg = tc.message().unwrap();
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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// Move `caught_exc` and `caught_msg` out of the extent of the TryCatch,
// but still within the extent of the enclosing HandleScope.
(caught_exc, caught_msg)
};
// This should not crash.
assert!(caught_exc.to_rust_string_lossy(scope).contains("DANG"));
Use correct lifetime for TryCatch::exception()/message() return value (#380) According to v8.h, "the returned handle is valid until this TryCatch block has been destroyed". This is incorrect, as can be demonstrated with the test below. In practice the return value lives no longer and no shorter than the active HandleScope at the time these methods are called. An issue has been opened about this in the V8 bug tracker: https://bugs.chromium.org/p/v8/issues/detail?id=10537. ```rust fn try_catch_bad_lifetimes() { let _setup_guard = setup(); let mut isolate = v8::Isolate::new(Default::default()); let mut hs = v8::HandleScope::new(&mut isolate); let scope = hs.enter(); let context = v8::Context::new(scope); let mut cs = v8::ContextScope::new(scope, context); let scope = cs.enter(); let caught_msg_2 = { let mut try_catch = v8::TryCatch::new(scope); let try_catch = try_catch.enter(); let caught_msg_1 = { let mut hs = v8::HandleScope::new(scope); let scope = hs.enter(); // Throw exception #1. let msg_1 = v8::String::new(scope, "BOOM!").unwrap(); let exc_1 = v8::Exception::type_error(scope, msg_1); scope.isolate().throw_exception(exc_1); // Catch exception #1. let caught_msg_1 = try_catch.message().unwrap(); let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Move `caught_msg_1` out of the HandleScope it was created in. // The borrow checker allows this because `caught_msg_1`'s // lifetime is contrained to not outlive the TryCatch, but it is // allowed to outlive the HandleScope that was active when the // exception was caught. caught_msg_1 }; // Next line crashes. let caught_str_1 = caught_msg_1.get(scope).to_rust_string_lossy(scope); assert!(caught_str_1.contains("BOOM")); // Throws exception #2. let msg_2 = v8::String::new(scope, "DANG!").unwrap(); let exc_2 = v8::Exception::type_error(scope, msg_2); scope.isolate().throw_exception(exc_2); // Catch exception #2. let caught_msg_2 = try_catch.message().unwrap(); let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); // Move `caught_msg_2` out of the extent of the TryCatch, but still // within the extent of its HandleScope. This is unnecessarily // rejected at compile time. caught_msg_2 }; let caught_str_2 = caught_msg_2.get(scope).to_rust_string_lossy(scope); assert!(caught_str_2.contains("DANG")); } ```
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assert!(caught_msg
.get(scope)
.to_rust_string_lossy(scope)
.contains("DANG"));
}
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#[test]
fn throw_exception() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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{
let tc = &mut v8::TryCatch::new(scope);
let exception = v8::String::new(tc, "boom").unwrap();
tc.throw_exception(exception.into());
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assert!(tc.has_caught());
assert!(tc
.exception()
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.unwrap()
.strict_equals(v8::String::new(tc, "boom").unwrap().into()));
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};
}
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}
#[test]
fn isolate_termination_methods() {
let _setup_guard = setup::parallel_test();
let isolate = v8::Isolate::new(Default::default());
let handle = isolate.thread_safe_handle();
drop(isolate);
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assert!(!handle.terminate_execution());
assert!(!handle.cancel_terminate_execution());
assert!(!handle.is_execution_terminating());
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
extern "C" fn callback(
_isolate: &mut v8::Isolate,
data: *mut std::ffi::c_void,
) {
assert_eq!(data, std::ptr::null_mut());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
}
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assert!(!handle.request_interrupt(callback, std::ptr::null_mut()));
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 0);
}
#[test]
fn thread_safe_handle_drop_after_isolate() {
let _setup_guard = setup::parallel_test();
let isolate = v8::Isolate::new(Default::default());
let handle = isolate.thread_safe_handle();
// We can call it twice.
let handle_ = isolate.thread_safe_handle();
// Check that handle is Send and Sync.
fn f<S: Send + Sync>(_: S) {}
f(handle_);
// All methods on IsolateHandle should return false after the isolate is
// dropped.
drop(isolate);
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assert!(!handle.terminate_execution());
assert!(!handle.cancel_terminate_execution());
assert!(!handle.is_execution_terminating());
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
extern "C" fn callback(
_isolate: &mut v8::Isolate,
data: *mut std::ffi::c_void,
) {
assert_eq!(data, std::ptr::null_mut());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
}
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assert!(!handle.request_interrupt(callback, std::ptr::null_mut()));
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 0);
}
// QEMU doesn't like when we spawn threads
// This works just fine on real hardware
#[cfg(not(target_os = "android"))]
#[test]
fn terminate_execution() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let (tx, rx) = std::sync::mpsc::channel::<bool>();
let handle = isolate.thread_safe_handle();
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let t = std::thread::spawn(move || {
// allow deno to boot and run
std::thread::sleep(std::time::Duration::from_millis(300));
handle.terminate_execution();
// allow shutdown
std::thread::sleep(std::time::Duration::from_millis(200));
// unless reported otherwise the test should fail after this point
tx.send(false).ok();
});
// Run an infinite loop, which should be terminated.
let source = v8::String::new(scope, "for(;;) {}").unwrap();
let r = v8::Script::compile(scope, source, None);
let script = r.unwrap();
let result = script.run(scope);
assert!(result.is_none());
// TODO assert_eq!(e.to_string(), "Uncaught Error: execution terminated")
let msg = rx.recv().expect("execution should be terminated");
assert!(!msg);
// Make sure the isolate unusable again.
eval(scope, "1+1").expect("execution should be possible again");
t.join().expect("join t");
}
// TODO(ry) This test should use threads
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#[test]
fn request_interrupt_small_scripts() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let handle = isolate.thread_safe_handle();
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
extern "C" fn callback(
_isolate: &mut v8::Isolate,
data: *mut std::ffi::c_void,
) {
assert_eq!(data, std::ptr::null_mut());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
}
handle.request_interrupt(callback, std::ptr::null_mut());
eval(scope, "(function(x){return x;})(1);");
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assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
}
#[test]
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fn add_message_listener() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_capture_stack_trace_for_uncaught_exceptions(true, 32);
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
extern "C" fn check_message_0(
message: v8::Local<v8::Message>,
_exception: v8::Local<v8::Value>,
) {
let scope = &mut unsafe { v8::CallbackScope::new(message) };
let scope = &mut v8::HandleScope::new(scope);
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let message_str = message.get(scope);
assert_eq!(message_str.to_rust_string_lossy(scope), "Uncaught foo");
assert_eq!(Some(1), message.get_line_number(scope));
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assert!(message.get_script_resource_name(scope).is_some());
assert!(message.get_source_line(scope).is_some());
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assert_eq!(message.get_start_position(), 0);
assert_eq!(message.get_end_position(), 1);
assert_eq!(message.get_wasm_function_index(), -1);
assert!(message.error_level() >= 0);
assert_eq!(message.get_start_column(), 0);
assert_eq!(message.get_end_column(), 1);
assert!(!message.is_shared_cross_origin());
assert!(!message.is_opaque());
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let stack_trace = message.get_stack_trace(scope).unwrap();
assert_eq!(1, stack_trace.get_frame_count());
let frame = stack_trace.get_frame(scope, 0).unwrap();
assert_eq!(1, frame.get_line_number());
assert_eq!(1, frame.get_column());
// Note: V8 flags like --expose_externalize_string and --expose_gc install
// scripts of their own and therefore affect the script id that we get.
assert_eq!(4, frame.get_script_id());
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assert!(frame.get_script_name(scope).is_none());
assert!(frame.get_script_name_or_source_url(scope).is_none());
assert!(frame.get_function_name(scope).is_none());
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assert!(!frame.is_eval());
assert!(!frame.is_constructor());
assert!(!frame.is_wasm());
assert!(frame.is_user_javascript());
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CALL_COUNT.fetch_add(1, Ordering::SeqCst);
}
isolate.add_message_listener(check_message_0);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(scope, "throw 'foo'").unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
assert!(script.run(scope).is_none());
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
}
fn unexpected_module_resolve_callback<'a>(
_context: v8::Local<'a, v8::Context>,
_specifier: v8::Local<'a, v8::String>,
_import_assertions: v8::Local<'a, v8::FixedArray>,
_referrer: v8::Local<'a, v8::Module>,
) -> Option<v8::Local<'a, v8::Module>> {
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unreachable!()
}
#[test]
fn set_host_initialize_import_meta_object_callback() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
extern "C" fn callback(
context: v8::Local<v8::Context>,
_module: v8::Local<v8::Module>,
meta: v8::Local<v8::Object>,
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) {
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
let scope = &mut unsafe { v8::CallbackScope::new(context) };
let scope = &mut v8::HandleScope::new(scope);
let key = v8::String::new(scope, "foo").unwrap();
let value = v8::String::new(scope, "bar").unwrap();
meta.create_data_property(scope, key.into(), value.into());
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}
isolate.set_host_initialize_import_meta_object_callback(callback);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let source = mock_source(
scope,
"google.com",
"if (import.meta.foo != 'bar') throw 'bad'",
);
let module = v8::script_compiler::compile_module(scope, source).unwrap();
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let result =
module.instantiate_module(scope, unexpected_module_resolve_callback);
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assert!(result.is_some());
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module.evaluate(scope).unwrap();
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
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assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
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}
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#[test]
fn script_compile_and_run() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(scope, "'Hello ' + 13 + 'th planet'").unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
source.to_rust_string_lossy(scope);
let result = script.run(scope).unwrap();
assert_eq!(result.to_rust_string_lossy(scope), "Hello 13th planet");
}
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}
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#[test]
fn script_origin() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let resource_name = v8::String::new(scope, "foo.js").unwrap();
let resource_line_offset = 4;
let resource_column_offset = 5;
let resource_is_shared_cross_origin = true;
let script_id = 123;
let source_map_url = v8::String::new(scope, "source_map_url").unwrap();
let resource_is_opaque = true;
let is_wasm = false;
let is_module = false;
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let script_origin = v8::ScriptOrigin::new(
scope,
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resource_name.into(),
resource_line_offset,
resource_column_offset,
resource_is_shared_cross_origin,
script_id,
source_map_url.into(),
resource_is_opaque,
is_wasm,
is_module,
);
let source = v8::String::new(scope, "1+2").unwrap();
let script =
v8::Script::compile(scope, source, Some(&script_origin)).unwrap();
source.to_rust_string_lossy(scope);
let _result = script.run(scope).unwrap();
}
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}
#[test]
fn get_version() {
assert!(v8::V8::get_version().len() > 3);
}
#[test]
fn set_flags_from_command_line() {
let r = v8::V8::set_flags_from_command_line(vec![
"binaryname".to_string(),
"--log-colour".to_string(),
"--should-be-ignored".to_string(),
]);
assert_eq!(
r,
vec!["binaryname".to_string(), "--should-be-ignored".to_string()]
);
}
#[test]
fn inspector_string_view() {
let chars = b"Hello world!";
let view = v8::inspector::StringView::from(&chars[..]);
assert_eq!(chars.len(), view.into_iter().len());
assert_eq!(chars.len(), view.len());
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for (c1, c2) in chars.iter().copied().map(u16::from).zip(view) {
assert_eq!(c1, c2);
}
}
#[test]
fn inspector_string_buffer() {
let chars = b"Hello Venus!";
let mut buf = {
let src_view = v8::inspector::StringView::from(&chars[..]);
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v8::inspector::StringBuffer::create(src_view)
};
let view = buf.as_mut().unwrap().string();
assert_eq!(chars.len(), view.into_iter().len());
assert_eq!(chars.len(), view.len());
for (c1, c2) in chars.iter().copied().map(u16::from).zip(view) {
assert_eq!(c1, c2);
}
}
#[test]
fn test_primitives() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let null = v8::null(scope);
assert!(!null.is_undefined());
assert!(null.is_null());
assert!(null.is_null_or_undefined());
let undefined = v8::undefined(scope);
assert!(undefined.is_undefined());
assert!(!undefined.is_null());
assert!(undefined.is_null_or_undefined());
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let true_ = v8::Boolean::new(scope, true);
assert!(true_.is_true());
assert!(!true_.is_undefined());
assert!(!true_.is_null());
assert!(!true_.is_null_or_undefined());
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let false_ = v8::Boolean::new(scope, false);
assert!(false_.is_false());
assert!(!false_.is_undefined());
assert!(!false_.is_null());
assert!(!false_.is_null_or_undefined());
}
}
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#[test]
fn exception() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let msg_in = v8::String::new(scope, "This is a test error").unwrap();
let _exception = v8::Exception::error(scope, msg_in);
let _exception = v8::Exception::range_error(scope, msg_in);
let _exception = v8::Exception::reference_error(scope, msg_in);
let _exception = v8::Exception::syntax_error(scope, msg_in);
let exception = v8::Exception::type_error(scope, msg_in);
let actual_msg_out =
v8::Exception::create_message(scope, exception).get(scope);
let expected_msg_out =
v8::String::new(scope, "Uncaught TypeError: This is a test error").unwrap();
assert!(actual_msg_out.strict_equals(expected_msg_out.into()));
assert!(v8::Exception::get_stack_trace(scope, exception).is_none());
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}
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#[test]
fn create_message_argument_lifetimes() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let create_message = v8::Function::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
let message = v8::Exception::create_message(scope, args.get(0));
let message_str = message.get(scope);
rv.set(message_str.into())
},
)
.unwrap();
let receiver = context.global(scope);
let message_str = v8::String::new(scope, "mishap").unwrap();
let exception = v8::Exception::type_error(scope, message_str);
let actual = create_message
.call(scope, receiver.into(), &[exception])
.unwrap();
let expected =
v8::String::new(scope, "Uncaught TypeError: mishap").unwrap();
assert!(actual.strict_equals(expected.into()));
}
}
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#[test]
fn json() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let json_string = v8::String::new(scope, "{\"a\": 1, \"b\": 2}").unwrap();
let maybe_value = v8::json::parse(scope, json_string);
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assert!(maybe_value.is_some());
let value = maybe_value.unwrap();
let maybe_stringified = v8::json::stringify(scope, value);
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assert!(maybe_stringified.is_some());
let stringified = maybe_stringified.unwrap();
let rust_str = stringified.to_rust_string_lossy(scope);
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assert_eq!("{\"a\":1,\"b\":2}".to_string(), rust_str);
}
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}
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#[test]
fn no_internal_field() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object = v8::Object::new(scope);
let value = v8::Integer::new(scope, 42).into();
assert_eq!(0, object.internal_field_count());
for index in &[0, 1, 1337] {
assert!(object.get_internal_field(scope, *index).is_none());
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assert!(!object.set_internal_field(*index, value));
assert!(object.get_internal_field(scope, *index).is_none());
}
}
}
#[test]
fn object_template() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let object_templ = v8::ObjectTemplate::new(scope);
let function_templ = v8::FunctionTemplate::new(scope, fortytwo_callback);
let name = v8::String::new(scope, "f").unwrap();
let attr = v8::PropertyAttribute::READ_ONLY
| v8::PropertyAttribute::DONT_ENUM
| v8::PropertyAttribute::DONT_DELETE;
object_templ.set_internal_field_count(1);
object_templ.set_with_attr(name.into(), function_templ.into(), attr);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object = object_templ.new_instance(scope).unwrap();
assert!(!object.is_null_or_undefined());
assert_eq!(1, object.internal_field_count());
let data = object.get_internal_field(scope, 0).unwrap();
assert!(data.is_value());
let value: v8::Local<v8::Value> = data.try_into().unwrap();
assert!(value.is_undefined());
let fortytwo: v8::Local<'_, v8::Value> = v8::Integer::new(scope, 42).into();
assert!(object.set_internal_field(0, fortytwo.into()));
let data = object.get_internal_field(scope, 0).unwrap();
assert!(data.is_value());
let value: v8::Local<v8::Value> = data.try_into().unwrap();
assert!(value.same_value(fortytwo));
let name = v8::String::new(scope, "g").unwrap();
context.global(scope).define_own_property(
scope,
name.into(),
object.into(),
v8::PropertyAttribute::DONT_ENUM,
);
let source = r#"
{
const d = Object.getOwnPropertyDescriptor(globalThis, "g");
[d.configurable, d.enumerable, d.writable].toString()
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "true,false,true").unwrap();
assert!(expected.strict_equals(actual));
let actual = eval(scope, "g.f()").unwrap();
let expected = v8::Integer::new(scope, 42);
assert!(expected.strict_equals(actual));
let source = r#"
{
const d = Object.getOwnPropertyDescriptor(g, "f");
[d.configurable, d.enumerable, d.writable].toString()
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "false,false,false").unwrap();
assert!(expected.strict_equals(actual));
}
}
#[test]
fn object_template_from_function_template() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let function_templ = v8::FunctionTemplate::new(scope, fortytwo_callback);
let expected_class_name = v8::String::new(scope, "fortytwo").unwrap();
function_templ.set_class_name(expected_class_name);
let object_templ =
v8::ObjectTemplate::new_from_template(scope, function_templ);
assert_eq!(0, object_templ.internal_field_count());
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object = object_templ.new_instance(scope).unwrap();
assert!(!object.is_null_or_undefined());
let name = v8::String::new(scope, "g").unwrap();
context.global(scope).set(scope, name.into(), object.into());
let actual_class_name = eval(scope, "g.constructor.name").unwrap();
assert!(expected_class_name.strict_equals(actual_class_name));
}
}
#[test]
fn object_template_immutable_proto() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let object_templ = v8::ObjectTemplate::new(scope);
object_templ.set_immutable_proto();
let context = v8::Context::new_from_template(scope, object_templ);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
{
let r = 0;
try {
Object.setPrototypeOf(globalThis, {});
} catch {
r = 42;
}
String(r);
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "42").unwrap();
assert!(actual == expected);
}
}
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#[test]
fn function_template_signature() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let templ0 = v8::FunctionTemplate::new(scope, fortytwo_callback);
let signature = v8::Signature::new(scope, templ0);
let templ1 = v8::FunctionTemplate::builder(fortytwo_callback)
.signature(signature)
.build(scope);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let scope = &mut v8::TryCatch::new(scope);
let global = context.global(scope);
let name = v8::String::new(scope, "C").unwrap();
let value = templ0.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let name = v8::String::new(scope, "f").unwrap();
let value = templ1.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
assert!(eval(scope, "f.call(new C)").is_some());
assert!(eval(scope, "f.call(new Object)").is_none());
assert!(scope.has_caught());
assert!(scope
.exception()
.unwrap()
.to_rust_string_lossy(scope)
.contains("Illegal invocation"));
}
}
#[test]
fn function_template_prototype() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let scope = &mut v8::TryCatch::new(scope);
let function_templ = v8::FunctionTemplate::new(scope, fortytwo_callback);
let prototype_templ = function_templ.prototype_template(scope);
let amount_name = v8::String::new(scope, "amount").unwrap();
let value = v8::Number::new(scope, 1.0);
let second_value = v8::Number::new(scope, 2.0);
let third_value = v8::Number::new(scope, 3.0);
prototype_templ.set(amount_name.into(), value.into());
let function = function_templ.get_function(scope).unwrap();
function.new_instance(scope, &[]);
let object1 = function.new_instance(scope, &[]).unwrap();
assert!(!object1.is_null_or_undefined());
let name = v8::String::new(scope, "ob1").unwrap();
context
.global(scope)
.set(scope, name.into(), object1.into());
let actual_amount =
eval(scope, "ob1.amount").unwrap().to_number(scope).unwrap();
dbg!("{}", actual_amount.number_value(scope).unwrap());
assert!(value.eq(&actual_amount));
let object2 = function.new_instance(scope, &[]).unwrap();
assert!(!object2.is_null_or_undefined());
let name = v8::String::new(scope, "ob2").unwrap();
context
.global(scope)
.set(scope, name.into(), object2.into());
let actual_amount =
eval(scope, "ob2.amount").unwrap().to_number(scope).unwrap();
dbg!("{}", actual_amount.number_value(scope).unwrap());
assert!(value.eq(&actual_amount));
eval(scope, "ob1.amount = 2").unwrap();
let actual_amount =
eval(scope, "ob1.amount").unwrap().to_number(scope).unwrap();
dbg!("{}", actual_amount.number_value(scope).unwrap());
assert!(second_value.eq(&actual_amount));
// We need to get the prototype of the object to change it, it is not the same object as the prototype template!
object2
.get_prototype(scope)
.unwrap()
.to_object(scope)
.unwrap()
.set(scope, amount_name.into(), third_value.into());
let actual_amount =
eval(scope, "ob1.amount").unwrap().to_number(scope).unwrap();
dbg!("{}", actual_amount.number_value(scope).unwrap());
assert!(second_value.eq(&actual_amount));
let actual_amount =
eval(scope, "ob2.amount").unwrap().to_number(scope).unwrap();
dbg!("{}", actual_amount.number_value(scope).unwrap());
assert!(third_value.eq(&actual_amount));
}
}
#[test]
fn instance_template_with_internal_field() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
pub fn constructor_callback(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut retval: v8::ReturnValue,
) {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(this.set_internal_field(0, v8::Integer::new(scope, 42).into()));
retval.set(this.into())
}
let function_templ = v8::FunctionTemplate::new(scope, constructor_callback);
let instance_templ = function_templ.instance_template(scope);
instance_templ.set_internal_field_count(1);
let name = v8::String::new(scope, "WithInternalField").unwrap();
let val = function_templ.get_function(scope).unwrap();
context.global(scope).set(scope, name.into(), val.into());
let new_instance = eval(scope, "new WithInternalField()").unwrap();
let internal_field_data = new_instance
.to_object(scope)
.unwrap()
.get_internal_field(scope, 0)
.unwrap();
let internal_field: v8::Local<v8::Value> =
internal_field_data.try_into().unwrap();
assert_eq!(internal_field.integer_value(scope).unwrap(), 42);
}
#[test]
fn object_template_set_accessor() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let internal_field = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
rv.set(internal_field);
};
let setter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
_rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
assert!(value.is_int32());
assert!(this.set_internal_field(0, value.into()));
};
let getter_with_data =
|scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_string());
assert!(!args.should_throw_on_error());
assert_eq!(args.data().to_rust_string_lossy(scope), "data");
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let internal_field = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
rv.set(internal_field);
};
let setter_with_data = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
_rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_string());
assert!(!args.should_throw_on_error());
assert_eq!(args.data().to_rust_string_lossy(scope), "data");
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
assert!(value.is_int32());
assert!(this.set_internal_field(0, value.into()));
};
let key = v8::String::new(scope, "key").unwrap();
let name = v8::String::new(scope, "obj").unwrap();
// Lone getter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_accessor(key.into(), getter);
let obj = templ.new_instance(scope).unwrap();
let int = v8::Integer::new(scope, 42);
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(eval(scope, "obj.key").unwrap().strict_equals(int.into()));
// Getter + setter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_accessor_with_setter(key.into(), getter, setter);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
let new_int = v8::Integer::new(scope, 9);
eval(scope, "obj.key = 9");
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
// Falls back on standard setter
assert!(eval(scope, "obj.key2 = null; obj.key2").unwrap().is_null());
// Getter + setter + data
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
let data = v8::String::new(scope, "data").unwrap();
templ.set_accessor_with_configuration(
key.into(),
AccessorConfiguration::new(getter_with_data)
.setter(setter_with_data)
.data(data.into()),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
let new_int = v8::Integer::new(scope, 9);
eval(scope, "obj.key = 9");
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
// Falls back on standard setter
assert!(eval(scope, "obj.key2 = null; obj.key2").unwrap().is_null());
// Accessor property
let getter = v8::FunctionTemplate::new(scope, fortytwo_callback);
fn property_setter(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
_: v8::ReturnValue,
) {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
let ret = v8::Integer::new(scope, 69);
assert!(this.set_internal_field(0, ret.into()));
}
let setter = v8::FunctionTemplate::new(scope, property_setter);
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
// Getter
let key = v8::String::new(scope, "key1").unwrap();
templ.set_accessor_property(
key.into(),
Some(getter),
None,
v8::PropertyAttribute::default(),
);
// Setter
let key = v8::String::new(scope, "key2").unwrap();
templ.set_accessor_property(
key.into(),
None,
Some(setter),
v8::PropertyAttribute::default(),
);
let obj = templ.new_instance(scope).unwrap();
let int = v8::Integer::new(scope, 42);
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(eval(scope, "obj.key1").unwrap().strict_equals(int.into()));
assert!(eval(scope, "obj.key2 = 123; obj.key2")
.unwrap()
.is_undefined());
}
}
#[test]
fn object_template_set_named_property_handler() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let internal_field = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
rv.set(internal_field);
};
let setter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let panic_on_get = v8::String::new(scope, "panicOnGet").unwrap();
if key.strict_equals(panic_on_get.into()) {
return;
}
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
assert!(value.is_int32());
assert!(this.set_internal_field(0, value.into()));
rv.set_undefined();
};
let query = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let panic_on_get = v8::String::new(scope, "panicOnGet").unwrap();
if key.strict_equals(panic_on_get.into()) {
return;
}
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
// PropertyAttribute::READ_ONLY
rv.set_int32(1);
let expected_value = v8::Integer::new(scope, 42);
let internal_field: v8::Local<v8::Value> = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(expected_value.into()));
};
let deleter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let this = args.this();
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
assert!(this.set_internal_field(0, v8::undefined(scope).into()));
rv.set_bool(true);
};
let enumerator = |scope: &mut v8::HandleScope,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
// Validate is the current object.
let expected_value = v8::Integer::new(scope, 42);
let internal_field: v8::Local<v8::Value> = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(expected_value.into()));
let key: v8::Local<v8::Name> =
v8::String::new(scope, "key").unwrap().into();
let result = v8::Array::new_with_elements(scope, &[key.into()]);
rv.set(result.into());
};
let definer = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
desc: &v8::PropertyDescriptor,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let this = args.this();
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
assert!(desc.has_enumerable());
assert!(desc.has_configurable());
assert!(desc.has_writable());
assert!(desc.has_value());
assert!(!desc.has_get());
assert!(!desc.has_set());
assert!(desc.enumerable());
assert!(desc.configurable());
assert!(desc.writable());
let value = desc.value();
assert!(value.is_int32());
assert!(this.set_internal_field(0, value.into()));
rv.set_undefined();
};
let descriptor = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let fallthrough_key = v8::String::new(scope, "fallthrough").unwrap();
if key.strict_equals(fallthrough_key.into()) {
return;
}
let this = args.this();
let expected_key = v8::String::new(scope, "key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let descriptor = v8::Object::new(scope);
let value_key = v8::String::new(scope, "value").unwrap();
let data = this.get_internal_field(scope, 0).unwrap();
let value = data.try_into().unwrap();
descriptor.set(scope, value_key.into(), value);
let enumerable_key = v8::String::new(scope, "enumerable").unwrap();
let enumerable = v8::Boolean::new(scope, true);
descriptor.set(scope, enumerable_key.into(), enumerable.into());
let configurable_key = v8::String::new(scope, "configurable").unwrap();
let configurable = v8::Boolean::new(scope, true);
descriptor.set(scope, configurable_key.into(), configurable.into());
let writable_key = v8::String::new(scope, "writable").unwrap();
let writable = v8::Boolean::new(scope, true);
descriptor.set(scope, writable_key.into(), writable.into());
rv.set(descriptor.into());
};
let name = v8::String::new(scope, "obj").unwrap();
// Lone getter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new().getter(getter),
);
let obj = templ.new_instance(scope).unwrap();
let int = v8::Integer::new(scope, 42);
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(eval(scope, "obj.key").unwrap().strict_equals(int.into()));
assert!(eval(scope, "obj.fallthrough").unwrap().is_undefined());
assert!(eval(scope, "obj.fallthrough = 'a'; obj.fallthrough")
.unwrap()
.is_string());
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(int.into()));
// Getter + setter + deleter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new()
.getter(getter)
.setter(setter)
.deleter(deleter),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
let new_int = v8::Integer::new(scope, 9);
eval(scope, "obj.key = 9");
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
assert!(eval(scope, "delete obj.key").unwrap().boolean_value(scope));
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.is_undefined());
assert!(eval(scope, "delete obj.key").unwrap().boolean_value(scope));
assert!(eval(scope, "obj.fallthrough = 'a'; obj.fallthrough")
.unwrap()
.is_string());
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.is_undefined());
assert!(eval(scope, "delete obj.fallthrough")
.unwrap()
.boolean_value(scope));
assert!(eval(scope, "obj.fallthrough").unwrap().is_undefined());
// query descriptor
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new().query(query),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(eval(scope, "'key' in obj").unwrap().boolean_value(scope));
assert!(!eval(scope, "'fallthrough' in obj")
.unwrap()
.boolean_value(scope));
eval(scope, "obj.fallthrough = 'a'").unwrap();
assert!(eval(scope, "'fallthrough' in obj")
.unwrap()
.boolean_value(scope));
// enumerator
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new().enumerator(enumerator),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
let arr = v8::Local::<v8::Array>::try_from(
eval(scope, "Object.keys(obj)").unwrap(),
)
.unwrap();
assert_eq!(arr.length(), 1);
let index = v8::Integer::new(scope, 0);
let result = arr.get(scope, index.into()).unwrap();
let expected = v8::String::new(scope, "key").unwrap();
assert!(expected.strict_equals(result));
eval(scope, "obj.fallthrough = 'a'").unwrap();
let arr = v8::Local::<v8::Array>::try_from(
eval(scope, "Object.keys(obj)").unwrap(),
)
.unwrap();
assert_eq!(arr.length(), 2);
// definer
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new().definer(definer),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
eval(
scope,
"Object.defineProperty(obj, 'key', { value: 9, enumerable: true, configurable: true, writable: true })",
)
.unwrap();
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
assert!(eval(
scope,
"Object.defineProperty(obj, 'fallthrough', { value: 'a' }); obj.fallthrough"
)
.unwrap()
.is_string());
// descriptor
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new().descriptor(descriptor),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
let desc = eval(scope, "Object.getOwnPropertyDescriptor(obj, 'key')")
.unwrap()
.to_object(scope)
.unwrap();
let expected_value = v8::Integer::new(scope, 42);
let value_key = v8::String::new(scope, "value").unwrap().into();
assert!(desc
.get(scope, value_key)
.unwrap()
.strict_equals(expected_value.into()));
let enumerable_key = v8::String::new(scope, "enumerable").unwrap().into();
assert!(desc
.get(scope, enumerable_key)
.unwrap()
.boolean_value(scope));
let configurable_key =
v8::String::new(scope, "configurable").unwrap().into();
assert!(desc
.get(scope, configurable_key)
.unwrap()
.boolean_value(scope));
let writable_key = v8::String::new(scope, "writable").unwrap().into();
assert!(desc.get(scope, writable_key).unwrap().boolean_value(scope));
assert!(
eval(scope, "Object.getOwnPropertyDescriptor(obj, 'fallthrough')")
.unwrap()
.is_undefined()
);
// Getter + Setter + Query + NON_MASKING
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new()
.getter(getter)
.setter(setter)
.query(query)
.flags(v8::PropertyHandlerFlags::NON_MASKING),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(!eval(scope, "'panicOnGet' in obj")
.unwrap()
.boolean_value(scope));
eval(scope, "obj.panicOnGet = 'x'").unwrap();
assert!(eval(scope, "'panicOnGet' in obj")
.unwrap()
.boolean_value(scope));
assert!(eval(scope, "obj.panicOnGet").unwrap().is_string());
// Test `v8::NamedPropertyHandlerConfiguration::*_raw()` methods
{
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new()
.getter_raw(getter.map_fn_to())
.setter_raw(setter.map_fn_to())
.query_raw(query.map_fn_to())
.flags(v8::PropertyHandlerFlags::NON_MASKING),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope.get_current_context().global(scope).set(
scope,
name.into(),
obj.into(),
);
assert!(!eval(scope, "'panicOnGet' in obj")
.unwrap()
.boolean_value(scope));
eval(scope, "obj.panicOnGet = 'x'").unwrap();
assert!(eval(scope, "'panicOnGet' in obj")
.unwrap()
.boolean_value(scope));
assert!(eval(scope, "obj.panicOnGet").unwrap().is_string());
}
}
}
#[test]
fn object_template_set_indexed_property_handler() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let getter = |scope: &mut v8::HandleScope,
index: u32,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_index = 37;
assert!(index.eq(&expected_index));
let internal_field = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
rv.set(internal_field);
};
let setter = |_scope: &mut v8::HandleScope,
index: u32,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
assert_eq!(index, 37);
assert!(value.is_int32());
assert!(this.set_internal_field(0, value.into()));
rv.set_undefined();
};
let query = |_scope: &mut v8::HandleScope,
index: u32,
_args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
if index == 12 {
return;
}
assert_eq!(index, 37);
// PropertyAttribute::READ_ONLY
rv.set_int32(1);
};
let deleter = |_scope: &mut v8::HandleScope,
index: u32,
_args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(index, 37);
rv.set_bool(false);
};
let enumerator = |scope: &mut v8::HandleScope,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
// Validate is the current object.
let expected_value = v8::Integer::new(scope, 42);
let internal_field: v8::Local<v8::Value> = this
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(expected_value.into()));
let key = v8::Integer::new(scope, 37);
let result = v8::Array::new_with_elements(scope, &[key.into()]);
rv.set(result.into());
};
let definer = |_scope: &mut v8::HandleScope,
index: u32,
desc: &v8::PropertyDescriptor,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(index, 37);
assert!(!desc.has_enumerable());
assert!(!desc.has_configurable());
assert!(!desc.has_writable());
assert!(desc.has_value());
assert!(!desc.has_get());
assert!(!desc.has_set());
let value = desc.value();
this.set_internal_field(0, value.into());
rv.set_undefined();
};
let descriptor = |scope: &mut v8::HandleScope,
index: u32,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(index, 37);
let descriptor = v8::Object::new(scope);
let value_key = v8::String::new(scope, "value").unwrap();
let data = this.get_internal_field(scope, 0).unwrap();
let value = data.try_into().unwrap();
descriptor.set(scope, value_key.into(), value);
let enumerable_key = v8::String::new(scope, "enumerable").unwrap();
let enumerable = v8::Boolean::new(scope, true);
descriptor.set(scope, enumerable_key.into(), enumerable.into());
let configurable_key = v8::String::new(scope, "configurable").unwrap();
let configurable = v8::Boolean::new(scope, true);
descriptor.set(scope, configurable_key.into(), configurable.into());
let writable_key = v8::String::new(scope, "writable").unwrap();
let writable = v8::Boolean::new(scope, true);
descriptor.set(scope, writable_key.into(), writable.into());
rv.set(descriptor.into());
};
let name = v8::String::new(scope, "obj").unwrap();
// Lone getter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new().getter(getter),
);
let obj = templ.new_instance(scope).unwrap();
let int = v8::Integer::new(scope, 42);
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
assert!(eval(scope, "obj[37]").unwrap().strict_equals(int.into()));
// Getter + setter + deleter
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new()
.getter(getter)
.setter(setter)
.deleter(deleter),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
let new_int = v8::Integer::new(scope, 9);
eval(scope, "obj[37] = 9");
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
assert!(!eval(scope, "delete obj[37]").unwrap().boolean_value(scope));
// Query
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new().query(query),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
assert!(eval(scope, "'37' in obj").unwrap().boolean_value(scope));
// Enumerator
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new()
.getter(getter)
.enumerator(enumerator),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
let value = eval(
scope,
"
let value = -1;
for (const i in obj) {
value = obj[i];
}
value
",
)
.unwrap();
assert!(value.strict_equals(int.into()));
// Definer
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new().definer(definer),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
eval(scope, "Object.defineProperty(obj, 37, { value: 9 })").unwrap();
let internal_field: v8::Local<v8::Value> = obj
.get_internal_field(scope, 0)
.unwrap()
.try_into()
.unwrap();
assert!(internal_field.strict_equals(new_int.into()));
// Descriptor
let templ = v8::ObjectTemplate::new(scope);
templ.set_internal_field_count(1);
templ.set_indexed_property_handler(
v8::IndexedPropertyHandlerConfiguration::new().descriptor(descriptor),
);
let obj = templ.new_instance(scope).unwrap();
obj.set_internal_field(0, int.into());
scope
.get_current_context()
.global(scope)
.set(scope, name.into(), obj.into());
let desc = eval(scope, "Object.getOwnPropertyDescriptor(obj, 37)")
.unwrap()
.to_object(scope)
.unwrap();
let value_key = v8::String::new(scope, "value").unwrap().into();
assert!(desc
.get(scope, value_key)
.unwrap()
.strict_equals(int.into()));
let enumerable_key = v8::String::new(scope, "enumerable").unwrap().into();
assert!(desc
.get(scope, enumerable_key)
.unwrap()
.boolean_value(scope));
let configurable_key = v8::String::new(scope, "configurable").unwrap().into();
assert!(desc
.get(scope, configurable_key)
.unwrap()
.boolean_value(scope));
let writable_key = v8::String::new(scope, "writable").unwrap().into();
assert!(desc.get(scope, writable_key).unwrap().boolean_value(scope));
}
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#[test]
fn object() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let null: v8::Local<v8::Value> = v8::null(scope).into();
let n1: v8::Local<v8::Name> = v8::String::new(scope, "a").unwrap().into();
let n2: v8::Local<v8::Name> = v8::String::new(scope, "b").unwrap().into();
let p = v8::String::new(scope, "p").unwrap().into();
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let v1: v8::Local<v8::Value> = v8::Number::new(scope, 1.0).into();
let v2: v8::Local<v8::Value> = v8::Number::new(scope, 2.0).into();
let object = v8::Object::with_prototype_and_properties(
scope,
null,
&[n1, n2],
&[v1, v2],
);
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assert!(!object.is_null_or_undefined());
let lhs = object.get_creation_context(scope).unwrap().global(scope);
let rhs = context.global(scope);
assert!(lhs.strict_equals(rhs.into()));
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let object_ = v8::Object::new(scope);
assert!(!object_.is_null_or_undefined());
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let id = object_.get_identity_hash();
assert_eq!(id, object_.get_hash());
assert_ne!(id, v8::Object::new(scope).get_hash());
assert!(object.has(scope, n1.into()).unwrap());
assert!(object.has_own_property(scope, n1).unwrap());
let n_unused = v8::String::new(scope, "unused").unwrap();
assert!(!object.has(scope, n_unused.into()).unwrap());
assert!(!object.has_own_property(scope, n_unused.into()).unwrap());
assert!(object.delete(scope, n1.into()).unwrap());
assert!(!object.has(scope, n1.into()).unwrap());
assert!(!object.has_own_property(scope, n1).unwrap());
let global = context.global(scope);
let object_string = v8::String::new(scope, "o").unwrap().into();
global.set(scope, object_string, object.into());
assert!(eval(scope, "Object.isExtensible(o)").unwrap().is_true());
assert!(eval(scope, "Object.isSealed(o)").unwrap().is_false());
assert!(eval(scope, "Object.isFrozen(o)").unwrap().is_false());
assert!(object
.set_integrity_level(scope, v8::IntegrityLevel::Sealed)
.unwrap());
assert!(eval(scope, "Object.isExtensible(o)").unwrap().is_false());
assert!(eval(scope, "Object.isSealed(o)").unwrap().is_true());
assert!(eval(scope, "Object.isFrozen(o)").unwrap().is_false());
// Creating new properties is not allowed anymore
eval(scope, "o.p = true").unwrap();
assert!(!object.has(scope, p).unwrap());
// Deleting properties is not allowed anymore
eval(scope, "delete o.b").unwrap();
assert!(object.has(scope, n2.into()).unwrap());
// But we can still write new values.
assert!(eval(scope, "o.b = true; o.b").unwrap().is_true());
assert!(object
.set_integrity_level(scope, v8::IntegrityLevel::Frozen)
.unwrap());
assert!(eval(scope, "Object.isExtensible(o)").unwrap().is_false());
assert!(eval(scope, "Object.isSealed(o)").unwrap().is_true());
assert!(eval(scope, "Object.isFrozen(o)").unwrap().is_true());
// Creating new properties is not allowed anymore
eval(scope, "o.p = true").unwrap();
assert!(!object.has(scope, p).unwrap());
// Deleting properties is not allowed anymore
eval(scope, "delete o.b").unwrap();
assert!(object.has(scope, n2.into()).unwrap());
// And we can also not write new values
assert!(eval(scope, "o.b = false; o.b").unwrap().is_true());
}
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}
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#[test]
fn map() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let map = v8::Map::new(scope);
assert_eq!(map.size(), 0);
let undefined = v8::undefined(scope).into();
{
let key = v8::Object::new(scope).into();
let value = v8::Integer::new(scope, 1337).into();
assert_eq!(map.has(scope, key), Some(false));
assert_eq!(map.get(scope, key), Some(undefined));
assert_eq!(map.set(scope, key, value), Some(map));
assert_eq!(map.has(scope, key), Some(true));
assert_eq!(map.size(), 1);
assert_eq!(map.get(scope, key), Some(value));
}
map.clear();
assert_eq!(map.size(), 0);
{
let key = v8::String::new(scope, "key").unwrap().into();
let value = v8::Integer::new(scope, 42).into();
assert_eq!(map.delete(scope, key), Some(false));
map.set(scope, key, value);
assert_eq!(map.size(), 1);
assert_eq!(map.delete(scope, key), Some(true));
assert_eq!(map.size(), 0);
}
}
}
#[test]
fn set() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let set = v8::Set::new(scope);
assert_eq!(set.size(), 0);
{
let key = v8::Object::new(scope).into();
assert_eq!(set.has(scope, key), Some(false));
assert_eq!(set.add(scope, key), Some(set));
assert_eq!(set.has(scope, key), Some(true));
assert_eq!(set.size(), 1);
}
set.clear();
assert_eq!(set.size(), 0);
{
let key = v8::String::new(scope, "key").unwrap().into();
assert_eq!(set.delete(scope, key), Some(false));
set.add(scope, key);
assert_eq!(set.size(), 1);
assert_eq!(set.delete(scope, key), Some(true));
assert_eq!(set.size(), 0);
}
}
}
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#[test]
fn array() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let s1 = v8::String::new(scope, "a").unwrap();
let s2 = v8::String::new(scope, "b").unwrap();
let array = v8::Array::new(scope, 2);
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assert_eq!(array.length(), 2);
let lhs = array.get_creation_context(scope).unwrap().global(scope);
let rhs = context.global(scope);
assert!(lhs.strict_equals(rhs.into()));
array.set_index(scope, 0, s1.into());
array.set_index(scope, 1, s2.into());
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let maybe_v1 = array.get_index(scope, 0);
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assert!(maybe_v1.is_some());
assert!(maybe_v1.unwrap().same_value(s1.into()));
let maybe_v2 = array.get_index(scope, 1);
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assert!(maybe_v2.is_some());
assert!(maybe_v2.unwrap().same_value(s2.into()));
let array = v8::Array::new_with_elements(scope, &[]);
assert_eq!(array.length(), 0);
let array = v8::Array::new_with_elements(scope, &[s1.into(), s2.into()]);
assert_eq!(array.length(), 2);
let maybe_v1 = array.get_index(scope, 0);
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assert!(maybe_v1.is_some());
assert!(maybe_v1.unwrap().same_value(s1.into()));
let maybe_v2 = array.get_index(scope, 1);
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assert!(maybe_v2.is_some());
assert!(maybe_v2.unwrap().same_value(s2.into()));
assert!(array.has_index(scope, 1).unwrap());
assert!(array.delete_index(scope, 1).unwrap());
assert!(!array.has_index(scope, 1).unwrap());
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}
}
#[test]
fn create_data_property() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
eval(scope, "var a = {};");
let key = v8::String::new(scope, "a").unwrap();
let obj = context.global(scope).get(scope, key.into()).unwrap();
assert!(obj.is_object());
let obj = obj.to_object(scope).unwrap();
let key = v8::String::new(scope, "foo").unwrap();
let value = v8::String::new(scope, "bar").unwrap();
assert!(obj
.create_data_property(scope, key.into(), value.into())
.unwrap());
let actual = obj.get(scope, key.into()).unwrap();
assert!(value.strict_equals(actual));
let key2 = v8::String::new(scope, "foo2").unwrap();
assert!(obj.set(scope, key2.into(), value.into()).unwrap());
let actual = obj.get(scope, key2.into()).unwrap();
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assert!(value.strict_equals(actual));
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}
}
#[test]
fn object_set_accessor() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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{
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "getter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let s = v8::String::new(scope, "hello").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
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CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let obj = v8::Object::new(scope);
let getter_key = v8::String::new(scope, "getter_key").unwrap();
obj.set_accessor(scope, getter_key.into(), getter);
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = v8::Integer::new(scope, 42);
obj.set(scope, int_key.into(), int_value.into());
let obj_name = v8::String::new(scope, "obj").unwrap();
context
.global(scope)
.set(scope, obj_name.into(), obj.into());
let actual = eval(scope, "obj.getter_key").unwrap();
let expected = v8::String::new(scope, "hello").unwrap();
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assert!(actual.strict_equals(expected.into()));
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assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
}
#[test]
fn object_set_accessor_with_setter() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let s = v8::String::new(scope, "hello").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let setter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
_rv: v8::ReturnValue| {
println!("setter called");
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let new_value = v8::Local::<v8::Integer>::try_from(value).unwrap();
this.set(scope, int_key.into(), new_value.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let obj = v8::Object::new(scope);
let getter_setter_key =
v8::String::new(scope, "getter_setter_key").unwrap();
obj.set_accessor_with_setter(
scope,
getter_setter_key.into(),
getter,
setter,
);
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = v8::Integer::new(scope, 42);
obj.set(scope, int_key.into(), int_value.into());
let obj_name = v8::String::new(scope, "obj").unwrap();
context
.global(scope)
.set(scope, obj_name.into(), obj.into());
let actual = eval(scope, "obj.getter_setter_key").unwrap();
let expected = v8::String::new(scope, "hello").unwrap();
assert!(actual.strict_equals(expected.into()));
eval(scope, "obj.getter_setter_key = 123").unwrap();
assert_eq!(
obj
.get(scope, int_key.into())
.unwrap()
.to_integer(scope)
.unwrap()
.value(),
123
);
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 2);
}
}
#[test]
fn object_set_accessor_with_setter_with_property() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let s = v8::String::new(scope, "hello").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let setter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
_rv: v8::ReturnValue| {
println!("setter called");
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_undefined());
assert!(!args.should_throw_on_error());
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let new_value = v8::Local::<v8::Integer>::try_from(value).unwrap();
this.set(scope, int_key.into(), new_value.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let obj = v8::Object::new(scope);
let getter_setter_key =
v8::String::new(scope, "getter_setter_key").unwrap();
obj.set_accessor_with_configuration(
scope,
getter_setter_key.into(),
AccessorConfiguration::new(getter)
.setter(setter)
.property_attribute(v8::PropertyAttribute::READ_ONLY),
);
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = v8::Integer::new(scope, 42);
obj.set(scope, int_key.into(), int_value.into());
let obj_name = v8::String::new(scope, "obj").unwrap();
context
.global(scope)
.set(scope, obj_name.into(), obj.into());
let actual = eval(scope, "obj.getter_setter_key").unwrap();
let expected = v8::String::new(scope, "hello").unwrap();
assert!(actual.strict_equals(expected.into()));
eval(scope, "obj.getter_setter_key = 123").unwrap();
assert_eq!(
obj
.get(scope, int_key.into())
.unwrap()
.to_integer(scope)
.unwrap()
.value(),
42 //Since it is read only
);
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
}
#[test]
fn object_set_accessor_with_data() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
let getter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_string());
assert!(!args.should_throw_on_error());
let data = v8::String::new(scope, "data").unwrap();
assert!(data.strict_equals(args.data()));
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let s = v8::String::new(scope, "hello").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let setter = |scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
value: v8::Local<v8::Value>,
args: v8::PropertyCallbackArguments,
_rv: v8::ReturnValue| {
println!("setter called");
let this = args.this();
assert_eq!(args.holder(), this);
assert!(args.data().is_string());
assert!(!args.should_throw_on_error());
let data = v8::String::new(scope, "data").unwrap();
assert!(data.strict_equals(args.data()));
let expected_key = v8::String::new(scope, "getter_setter_key").unwrap();
assert!(key.strict_equals(expected_key.into()));
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = this.get(scope, int_key.into()).unwrap();
let int_value = v8::Local::<v8::Integer>::try_from(int_value).unwrap();
assert_eq!(int_value.value(), 42);
let new_value = v8::Local::<v8::Integer>::try_from(value).unwrap();
this.set(scope, int_key.into(), new_value.into());
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
};
let obj = v8::Object::new(scope);
let getter_setter_key =
v8::String::new(scope, "getter_setter_key").unwrap();
let data = v8::String::new(scope, "data").unwrap();
obj.set_accessor_with_configuration(
scope,
getter_setter_key.into(),
AccessorConfiguration::new(getter)
.setter(setter)
.data(data.into()),
);
let int_key = v8::String::new(scope, "int_key").unwrap();
let int_value = v8::Integer::new(scope, 42);
obj.set(scope, int_key.into(), int_value.into());
let obj_name = v8::String::new(scope, "obj").unwrap();
context
.global(scope)
.set(scope, obj_name.into(), obj.into());
let actual = eval(scope, "obj.getter_setter_key").unwrap();
let expected = v8::String::new(scope, "hello").unwrap();
assert!(actual.strict_equals(expected.into()));
eval(scope, "obj.getter_setter_key = 123").unwrap();
assert_eq!(
obj
.get(scope, int_key.into())
.unwrap()
.to_integer(scope)
.unwrap()
.value(),
123
);
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 2);
}
}
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#[test]
fn promise_resolved() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let maybe_resolver = v8::PromiseResolver::new(scope);
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assert!(maybe_resolver.is_some());
let resolver = maybe_resolver.unwrap();
let promise = resolver.get_promise(scope);
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assert!(!promise.has_handler());
assert_eq!(promise.state(), v8::PromiseState::Pending);
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let value = v8::String::new(scope, "test").unwrap();
resolver.resolve(scope, value.into());
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assert_eq!(promise.state(), v8::PromiseState::Fulfilled);
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let result = promise.result(scope);
assert_eq!(result.to_rust_string_lossy(scope), "test".to_string());
// Resolve again with different value, since promise is already in
// `Fulfilled` state it should be ignored.
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let value = v8::String::new(scope, "test2").unwrap();
resolver.resolve(scope, value.into());
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let result = promise.result(scope);
assert_eq!(result.to_rust_string_lossy(scope), "test".to_string());
}
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}
#[test]
fn promise_rejected() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let maybe_resolver = v8::PromiseResolver::new(scope);
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assert!(maybe_resolver.is_some());
let resolver = maybe_resolver.unwrap();
let promise = resolver.get_promise(scope);
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assert!(!promise.has_handler());
assert_eq!(promise.state(), v8::PromiseState::Pending);
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let value = v8::String::new(scope, "test").unwrap();
let rejected = resolver.reject(scope, value.into());
assert!(rejected.unwrap());
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assert_eq!(promise.state(), v8::PromiseState::Rejected);
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let result = promise.result(scope);
assert_eq!(result.to_rust_string_lossy(scope), "test".to_string());
// Reject again with different value, since promise is already in `Rejected`
// state it should be ignored.
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let value = v8::String::new(scope, "test2").unwrap();
resolver.reject(scope, value.into());
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let result = promise.result(scope);
assert_eq!(result.to_rust_string_lossy(scope), "test".to_string());
}
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}
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#[test]
fn proxy() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let target = v8::Object::new(scope);
let handler = v8::Object::new(scope);
let maybe_proxy = v8::Proxy::new(scope, target, handler);
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assert!(maybe_proxy.is_some());
let proxy = maybe_proxy.unwrap();
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assert!(target == proxy.get_target(scope));
assert!(handler == proxy.get_handler(scope));
assert!(!proxy.is_revoked());
proxy.revoke();
assert!(proxy.is_revoked());
}
}
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fn fn_callback_external(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
assert_eq!(args.length(), 0);
let data = args.data();
let external = v8::Local::<v8::External>::try_from(data).unwrap();
let data =
unsafe { std::slice::from_raw_parts(external.value() as *mut u8, 5) };
assert_eq!(&[0, 1, 2, 3, 4], data);
let s = v8::String::new(scope, "Hello callback!").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
}
fn fn_callback(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
assert_eq!(args.length(), 0);
let s = v8::String::new(scope, "Hello callback!").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
}
fn fn_callback_new(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
assert_eq!(args.length(), 0);
assert!(args.new_target().is_object());
let recv = args.this();
let key = v8::String::new(scope, "works").unwrap();
let value = v8::Boolean::new(scope, true);
assert!(recv.set(scope, key.into(), value.into()).unwrap());
assert!(rv.get(scope).is_undefined());
rv.set(recv.into());
}
fn fn_callback2(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
assert_eq!(args.length(), 2);
let arg1_val = v8::String::new(scope, "arg1").unwrap();
let arg1 = args.get(0);
assert!(arg1.is_string());
assert!(arg1.strict_equals(arg1_val.into()));
let arg2_val = v8::Integer::new(scope, 2);
let arg2 = args.get(1);
assert!(arg2.is_number());
assert!(arg2.strict_equals(arg2_val.into()));
let s = v8::String::new(scope, "Hello callback!").unwrap();
assert!(rv.get(scope).is_undefined());
rv.set(s.into());
}
fn fortytwo_callback(
_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
rv.set_int32(42);
}
fn data_is_true_callback(
_scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
_rv: v8::ReturnValue,
) {
let data = args.data();
assert!(data.is_true());
}
fn nested_builder<'a>(
scope: &mut v8::HandleScope<'a>,
args: v8::FunctionCallbackArguments<'a>,
_: v8::ReturnValue,
) {
let arg0 = args.get(0);
v8::Function::builder(
|_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
_: v8::ReturnValue| {},
)
.data(arg0)
.build(scope);
}
#[test]
fn function_builder_raw() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let recv: v8::Local<v8::Value> = global.into();
extern "C" fn callback(info: *const v8::FunctionCallbackInfo) {
let info = unsafe { &*info };
let scope = unsafe { &mut v8::CallbackScope::new(info) };
let args =
v8::FunctionCallbackArguments::from_function_callback_info(info);
assert!(args.length() == 1);
assert!(args.get(0).is_string());
let mut rv = v8::ReturnValue::from_function_callback_info(info);
rv.set(
v8::String::new(scope, "Hello from function!")
.unwrap()
.into(),
);
}
let func = v8::Function::new_raw(scope, callback).unwrap();
let arg0 = v8::String::new(scope, "Hello").unwrap();
let value = func.call(scope, recv, &[arg0.into()]).unwrap();
assert!(value.is_string());
assert_eq!(value.to_rust_string_lossy(scope), "Hello from function!");
}
}
#[test]
fn return_value() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let recv: v8::Local<v8::Value> = global.into();
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// set_bool
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_bool(false);
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_boolean());
assert!(!value.is_true());
}
// set_int32
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_int32(69);
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_int32());
assert_eq!(value.int32_value(scope).unwrap(), 69);
}
// set_uint32
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_uint32(69);
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_uint32());
assert_eq!(value.uint32_value(scope).unwrap(), 69);
}
// set_null
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_null();
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_null());
}
// set_undefined
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_undefined();
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_undefined());
}
// set_double
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_double(69.420);
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_number());
assert_eq!(value.number_value(scope).unwrap(), 69.420);
}
// set_empty_string
{
let template = v8::FunctionTemplate::new(
scope,
|scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue| {
assert_eq!(args.length(), 0);
assert!(rv.get(scope).is_undefined());
rv.set_empty_string();
},
);
let function = template
.get_function(scope)
.expect("Unable to create function");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_string());
assert_eq!(value.to_rust_string_lossy(scope), "");
}
}
}
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#[test]
fn function() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let recv: v8::Local<v8::Value> = global.into();
// Just check that this compiles.
v8::Function::builder(nested_builder);
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// create function using template
let fn_template = v8::FunctionTemplate::new(scope, fn_callback);
let function = fn_template
.get_function(scope)
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.expect("Unable to create function");
let lhs = function.get_creation_context(scope).unwrap().global(scope);
let rhs = context.global(scope);
assert!(lhs.strict_equals(rhs.into()));
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
let value_str = value.to_string(scope).unwrap();
let rust_str = value_str.to_rust_string_lossy(scope);
assert_eq!(rust_str, "Hello callback!".to_string());
// create function using template from a raw ptr
let fn_template =
v8::FunctionTemplate::new_raw(scope, fn_callback.map_fn_to());
let function = fn_template
.get_function(scope)
.expect("Unable to create function");
let lhs = function.get_creation_context(scope).unwrap().global(scope);
let rhs = context.global(scope);
assert!(lhs.strict_equals(rhs.into()));
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
let value_str = value.to_string(scope).unwrap();
let rust_str = value_str.to_rust_string_lossy(scope);
assert_eq!(rust_str, "Hello callback!".to_string());
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// create function without a template
let function = v8::Function::new(scope, fn_callback2)
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.expect("Unable to create function");
let arg1 = v8::String::new(scope, "arg1").unwrap();
let arg2 = v8::Integer::new(scope, 2);
let value = function
.call(scope, recv, &[arg1.into(), arg2.into()])
.unwrap();
let value_str = value.to_string(scope).unwrap();
let rust_str = value_str.to_rust_string_lossy(scope);
assert_eq!(rust_str, "Hello callback!".to_string());
// create function without a template from a raw ptr
let function = v8::Function::new_raw(scope, fn_callback2.map_fn_to())
.expect("Unable to create function");
let arg1 = v8::String::new(scope, "arg1").unwrap();
let arg2 = v8::Integer::new(scope, 2);
let value = function
.call(scope, recv, &[arg1.into(), arg2.into()])
.unwrap();
let value_str = value.to_string(scope).unwrap();
let rust_str = value_str.to_rust_string_lossy(scope);
assert_eq!(rust_str, "Hello callback!".to_string());
// create a function with associated data
let true_data = v8::Boolean::new(scope, true);
let function = v8::Function::builder(data_is_true_callback)
.data(true_data.into())
.build(scope)
.expect("Unable to create function with data");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_undefined());
// create a function with associated data from a raw ptr
let true_data = v8::Boolean::new(scope, true);
let function = v8::Function::builder_raw(data_is_true_callback.map_fn_to())
.data(true_data.into())
.build(scope)
.expect("Unable to create function with data");
let value = function
.call(scope, recv, &[])
.expect("Function call failed");
assert!(value.is_undefined());
// create a prototype-less function that throws on new
let function = v8::Function::builder(fn_callback)
.length(42)
.constructor_behavior(v8::ConstructorBehavior::Throw)
.build(scope)
.unwrap();
let name = v8::String::new(scope, "f").unwrap();
global.set(scope, name.into(), function.into()).unwrap();
let result = eval(scope, "f.length").unwrap();
assert_eq!(42, result.integer_value(scope).unwrap());
let result = eval(scope, "f.prototype").unwrap();
assert!(result.is_undefined());
assert!(eval(scope, "new f()").is_none()); // throws
let function = v8::Function::builder(fn_callback_new).build(scope).unwrap();
let name = v8::String::new(scope, "f2").unwrap();
global.set(scope, name.into(), function.into()).unwrap();
let f2: v8::Local<v8::Object> =
eval(scope, "new f2()").unwrap().try_into().unwrap();
let key = v8::String::new(scope, "works").unwrap();
let value = f2.get(scope, key.into()).unwrap();
assert!(value.is_boolean());
assert!(value.boolean_value(scope));
}
{
let mut root_scope = v8::HandleScope::new(isolate);
let context = v8::Context::new(&mut root_scope);
let mut scope = v8::ContextScope::new(&mut root_scope, context);
let function: v8::Local<v8::Function> =
eval(&mut scope, "function a() { return 1; }; a")
.unwrap()
.try_into()
.unwrap();
drop(scope);
let recv = v8::undefined(&mut root_scope).into();
let ret = function
.call_with_context(&mut root_scope, context, recv, &[])
.unwrap();
let integer: v8::Local<v8::Integer> = ret.try_into().unwrap();
let mut scope = v8::ContextScope::new(&mut root_scope, context);
assert_eq!(integer.int32_value(&mut scope).unwrap(), 1);
}
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}
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#[test]
fn function_column_and_line_numbers() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = mock_source(
scope,
"google.com",
r#"export function f(a, b) {
return a;
}
export function anotherFunctionG(a, b) {
return b;
}"#,
);
let module = v8::script_compiler::compile_module(scope, source).unwrap();
let result =
module.instantiate_module(scope, unexpected_module_resolve_callback);
assert!(result.is_some());
module.evaluate(scope).unwrap();
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
let namespace = module.get_module_namespace();
assert!(namespace.is_module_namespace_object());
let namespace_obj = namespace.to_object(scope).unwrap();
let f_str = v8::String::new(scope, "f").unwrap();
let f_function_obj: v8::Local<v8::Function> = namespace_obj
.get(scope, f_str.into())
.unwrap()
.try_into()
.unwrap();
// The column number is zero-indexed and indicates the position of the end of the name.
assert_eq!(f_function_obj.get_script_column_number(), Some(17));
// The line number is zero-indexed as well.
assert_eq!(f_function_obj.get_script_line_number(), Some(0));
let g_str = v8::String::new(scope, "anotherFunctionG").unwrap();
let g_function_obj: v8::Local<v8::Function> = namespace_obj
.get(scope, g_str.into())
.unwrap()
.try_into()
.unwrap();
assert_eq!(g_function_obj.get_script_column_number(), Some(32));
assert_eq!(g_function_obj.get_script_line_number(), Some(4));
let fn_template = v8::FunctionTemplate::new(scope, fn_callback);
let function = fn_template
.get_function(scope)
.expect("Unable to create function");
assert_eq!(function.get_script_column_number(), None);
assert_eq!(function.get_script_line_number(), None);
}
}
#[test]
fn function_script_origin_and_id() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut num_cases = 10;
let mut prev_id = None;
while num_cases > 0 {
let resource_name = format!("google.com/{}", num_cases);
let source = mock_source(
scope,
resource_name.as_str(), // make sure each source has a different resource name
r#"export function f(a, b) {
return a;
}
export function anotherFunctionG(a, b) {
return b;
}"#,
);
let module = v8::script_compiler::compile_module(scope, source).unwrap();
let result =
module.instantiate_module(scope, unexpected_module_resolve_callback);
assert!(result.is_some());
module.evaluate(scope).unwrap();
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
let namespace = module.get_module_namespace();
assert!(namespace.is_module_namespace_object());
let namespace_obj = namespace.to_object(scope).unwrap();
let f_str = v8::String::new(scope, "f").unwrap();
let f_function_obj: v8::Local<v8::Function> = namespace_obj
.get(scope, f_str.into())
.unwrap()
.try_into()
.unwrap();
// Modules with different resource names will have incrementing script IDs
// but the script ID of the first module is a V8 internal, so should not
// be depended on.
// See https://groups.google.com/g/v8-users/c/iEfceRohiy8 for more discussion.
let script_id = f_function_obj.script_id();
assert!(f_function_obj.script_id() > 0);
if let Some(id) = prev_id {
assert_eq!(script_id, id + 1);
assert_eq!(script_id, f_function_obj.get_script_origin().script_id(),);
}
prev_id = Some(script_id);
// Verify source map URL matches
assert_eq!(
"source_map_url",
f_function_obj
.get_script_origin()
.source_map_url()
.unwrap()
.to_rust_string_lossy(scope)
);
// Verify resource name matches in script origin
let resource_name_val = f_function_obj.get_script_origin().resource_name();
assert!(resource_name_val.is_some());
assert_eq!(
resource_name_val.unwrap().to_rust_string_lossy(scope),
resource_name
);
num_cases -= 1;
}
}
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#[test]
fn constructor() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let array_name = v8::String::new(scope, "Array").unwrap();
let array_constructor = global.get(scope, array_name.into()).unwrap();
let array_constructor =
v8::Local::<v8::Function>::try_from(array_constructor).unwrap();
let array = array_constructor.new_instance(scope, &[]).unwrap();
v8::Local::<v8::Array>::try_from(array).unwrap();
}
}
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extern "C" fn promise_reject_callback(msg: v8::PromiseRejectMessage) {
let scope = &mut unsafe { v8::CallbackScope::new(&msg) };
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let event = msg.get_event();
assert_eq!(event, v8::PromiseRejectEvent::PromiseRejectWithNoHandler);
let promise = msg.get_promise();
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assert_eq!(promise.state(), v8::PromiseState::Rejected);
let value = msg.get_value().unwrap();
{
let scope = &mut v8::HandleScope::new(scope);
let value_str = value.to_rust_string_lossy(scope);
assert_eq!(value_str, "promise rejected".to_string());
}
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}
#[test]
fn set_promise_reject_callback() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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isolate.set_promise_reject_callback(promise_reject_callback);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let resolver = v8::PromiseResolver::new(scope).unwrap();
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let value = v8::String::new(scope, "promise rejected").unwrap();
resolver.reject(scope, value.into());
}
}
#[test]
fn promise_reject_callback_no_value() {
extern "C" fn promise_reject_callback(m: v8::PromiseRejectMessage) {
use v8::PromiseRejectEvent::*;
let value = m.get_value();
match m.get_event() {
PromiseHandlerAddedAfterReject => assert!(value.is_none()),
PromiseRejectWithNoHandler => assert!(value.is_some()),
_ => unreachable!(),
};
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_promise_reject_callback(promise_reject_callback);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
function kaboom(resolve, reject) {
throw new Error("kaboom");
}
new Promise(kaboom).then(_ => {});
"#;
eval(scope, source).unwrap();
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}
}
#[test]
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#[allow(clippy::clone_on_copy)]
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fn promise_hook() {
extern "C" fn hook(
type_: v8::PromiseHookType,
promise: v8::Local<v8::Promise>,
_parent: v8::Local<v8::Value>,
) {
// Check that PromiseHookType implements Clone and PartialEq.
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_ = type_.clone() == v8::PromiseHookType::Init;
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let scope = &mut unsafe { v8::CallbackScope::new(promise) };
let context = promise.get_creation_context(scope).unwrap();
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let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let name = v8::String::new(scope, "hook").unwrap();
let func = global.get(scope, name.into()).unwrap();
let func = v8::Local::<v8::Function>::try_from(func).unwrap();
let args = &[v8::Integer::new(scope, type_ as i32).into(), promise.into()];
func.call(scope, global.into(), args).unwrap();
}
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_promise_hook(hook);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
var promises = new Set();
function hook(type, promise) {
if (type === /* Init */ 0) promises.add(promise);
if (type === /* Resolve */ 1) promises.delete(promise);
}
function expect(expected, actual = promises.size) {
if (actual !== expected) throw `expected ${expected}, actual ${actual}`;
}
expect(0);
new Promise(resolve => {
expect(1);
resolve();
expect(0);
});
expect(0);
new Promise(() => {});
expect(1);
promises.values().next().value
"#;
let promise = eval(scope, source).unwrap();
let promise = v8::Local::<v8::Promise>::try_from(promise).unwrap();
assert!(!promise.has_handler());
assert_eq!(promise.state(), v8::PromiseState::Pending);
}
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}
#[test]
fn context_get_extras_binding_object() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let extras_binding = context.get_extras_binding_object(scope);
assert!(extras_binding.is_object());
// Disabled for now because patch doesn't apply cleanly on v8 12.0
// // Verify that Deno specific APIs are available on the extras object.
// for builtin_name in &["fromUtf8", "toUtf8", "isOneByte"] {
// let name = v8::String::new(scope, builtin_name).unwrap();
// let value = extras_binding.get(scope, name.into()).unwrap();
// assert!(value.is_function());
// }
}
}
#[test]
fn context_promise_hooks() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let init_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
globalThis.promises = new Set();
function initHook(promise) {
promises.add(promise);
}
initHook;
"#,
)
.unwrap(),
)
.unwrap();
let before_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
globalThis.promiseStack = [];
function beforeHook(promise) {
promiseStack.push(promise);
}
beforeHook;
"#,
)
.unwrap(),
)
.unwrap();
let after_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
function afterHook(promise) {
const it = promiseStack.pop();
if (it !== promise) throw new Error("unexpected promise");
}
afterHook;
"#,
)
.unwrap(),
)
.unwrap();
let resolve_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
function resolveHook(promise) {
promises.delete(promise);
}
resolveHook;
"#,
)
.unwrap(),
)
.unwrap();
scope.set_promise_hooks(
Some(init_hook),
Some(before_hook),
Some(after_hook),
Some(resolve_hook),
);
let source = r#"
function expect(expected, actual = promises.size) {
if (actual !== expected) throw `expected ${expected}, actual ${actual}`;
}
expect(0);
var p = new Promise(resolve => {
expect(1);
resolve();
expect(0);
});
expect(0);
new Promise(() => {});
expect(1);
expect(0, promiseStack.length);
p.then(() => {
expect(1, promiseStack.length);
});
promises.values().next().value
"#;
let promise = eval(scope, source).unwrap();
let promise = v8::Local::<v8::Promise>::try_from(promise).unwrap();
assert!(!promise.has_handler());
assert_eq!(promise.state(), v8::PromiseState::Pending);
scope.perform_microtask_checkpoint();
let _ = eval(
scope,
r#"
expect(0, promiseStack.length);
"#,
)
.unwrap();
}
}
#[test]
fn context_promise_hooks_partial() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let init_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
globalThis.promises = new Set();
function initHook(promise) {
promises.add(promise);
}
initHook;
"#,
)
.unwrap(),
)
.unwrap();
let before_hook = v8::Local::<v8::Function>::try_from(
eval(
scope,
r#"
globalThis.promiseStack = [];
function beforeHook(promise) {
promiseStack.push(promise);
}
beforeHook;
"#,
)
.unwrap(),
)
.unwrap();
scope.set_promise_hooks(Some(init_hook), Some(before_hook), None, None);
let source = r#"
function expect(expected, actual = promises.size) {
if (actual !== expected) throw `expected ${expected}, actual ${actual}`;
}
expect(0);
var p = new Promise(resolve => {
expect(1);
resolve();
expect(1);
});
expect(1);
new Promise(() => {});
expect(2);
expect(0, promiseStack.length);
p.then(() => {
expect(1, promiseStack.length);
});
promises.values().next().value
"#;
let promise = eval(scope, source).unwrap();
let promise = v8::Local::<v8::Promise>::try_from(promise).unwrap();
assert!(promise.has_handler());
assert_eq!(promise.state(), v8::PromiseState::Fulfilled);
scope.perform_microtask_checkpoint();
let _ = eval(
scope,
r#"
expect(1, promiseStack.length);
"#,
)
.unwrap();
}
}
#[test]
fn security_token() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Define a variable in the parent context
let global = {
let global = context.global(scope);
let variable_key = v8::String::new(scope, "variable").unwrap();
let variable_value = v8::String::new(scope, "value").unwrap();
global.set(scope, variable_key.into(), variable_value.into());
v8::Global::new(scope, global)
};
// This code will try to access the variable defined in the parent context
let source = r#"
if (variable !== 'value') {
throw new Error('Expected variable to be value');
}
"#;
let templ = v8::ObjectTemplate::new(scope);
let global = v8::Local::new(scope, global);
templ.set_named_property_handler(
v8::NamedPropertyHandlerConfiguration::new()
.getter(
|scope: &mut v8::HandleScope,
key: v8::Local<v8::Name>,
args: v8::PropertyCallbackArguments,
mut rv: v8::ReturnValue| {
let obj = v8::Local::<v8::Object>::try_from(args.data()).unwrap();
if let Some(val) = obj.get(scope, key.into()) {
rv.set(val);
}
},
)
.data(global.into()),
);
// Creates a child context
{
let security_token = context.get_security_token(scope);
let child_context = v8::Context::new_from_template(scope, templ);
// Without the security context, the variable can not be shared
child_context.set_security_token(security_token);
let child_scope = &mut v8::ContextScope::new(scope, child_context);
let try_catch = &mut v8::TryCatch::new(child_scope);
let result = eval(try_catch, source);
assert!(!try_catch.has_caught());
assert!(result.unwrap().is_undefined());
}
// Runs the same code but without the security token, it should fail
{
let child_context = v8::Context::new_from_template(scope, templ);
let child_scope = &mut v8::ContextScope::new(scope, child_context);
let try_catch = &mut v8::TryCatch::new(child_scope);
let result = eval(try_catch, source);
assert!(try_catch.has_caught());
let exc = try_catch.exception().unwrap();
let exc = exc.to_string(try_catch).unwrap();
let exc = exc.to_rust_string_lossy(try_catch);
assert!(exc.contains("no access"));
assert!(result.is_none());
}
}
}
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#[test]
fn context_with_object_template() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
static mut CALLS: Vec<String> = Vec::new();
fn definer<'s>(
_scope: &mut v8::HandleScope<'s>,
_key: v8::Local<'s, v8::Name>,
_descriptor: &v8::PropertyDescriptor,
_args: v8::PropertyCallbackArguments<'s>,
_rv: v8::ReturnValue,
) {
unsafe {
CALLS.push("definer".to_string());
}
}
pub fn setter<'s>(
_scope: &mut v8::HandleScope<'s>,
_key: v8::Local<'s, v8::Name>,
_value: v8::Local<'s, v8::Value>,
_args: v8::PropertyCallbackArguments<'s>,
_rv: v8::ReturnValue,
) {
unsafe {
CALLS.push("setter".to_string());
}
}
{
let scope = &mut v8::HandleScope::new(isolate);
let object_template = v8::ObjectTemplate::new(scope);
let mut config = v8::NamedPropertyHandlerConfiguration::new().flags(
v8::PropertyHandlerFlags::NON_MASKING
| v8::PropertyHandlerFlags::HAS_NO_SIDE_EFFECT,
);
config = config.definer_raw(definer.map_fn_to());
config = config.setter_raw(setter.map_fn_to());
object_template.set_named_property_handler(config);
let context = v8::Context::new_from_template(scope, object_template);
let scope = &mut v8::ContextScope::new(scope, context);
eval(scope, r#"Object.defineProperty(globalThis, 'key', { value: 9, enumerable: true, configurable: true, writable: true })"#).unwrap();
let calls_set =
unsafe { CALLS.clone().into_iter().collect::<HashSet<String>>() };
assert!(calls_set.contains("setter"));
assert!(calls_set.contains("definer"));
}
}
#[test]
fn allow_code_generation_from_strings() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
// The code generation is allowed by default
assert!(context.is_code_generation_from_strings_allowed());
// This code will try to use generation from strings
let source = r#"
eval("const i = 1; i")
"#;
{
let scope = &mut v8::ContextScope::new(scope, context);
let try_catch = &mut v8::TryCatch::new(scope);
let result = eval(try_catch, source).unwrap();
let expected = v8::Integer::new(try_catch, 1);
assert!(expected.strict_equals(result));
assert!(!try_catch.has_caught());
}
context.set_allow_generation_from_strings(false);
assert!(!context.is_code_generation_from_strings_allowed());
{
let scope = &mut v8::ContextScope::new(scope, context);
let try_catch = &mut v8::TryCatch::new(scope);
let result = eval(try_catch, source);
assert!(try_catch.has_caught());
let exc = try_catch.exception().unwrap();
let exc = exc.to_string(try_catch).unwrap();
let exc = exc.to_rust_string_lossy(try_catch);
assert!(exc
.contains("Code generation from strings disallowed for this context"));
assert!(result.is_none());
}
}
}
#[test]
fn allow_atomics_wait() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
for allow in &[false, true, false] {
let allow = *allow;
isolate.set_allow_atomics_wait(allow);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
const b = new SharedArrayBuffer(4);
const a = new Int32Array(b);
"timed-out" === Atomics.wait(a, 0, 0, 1);
"#;
let try_catch = &mut v8::TryCatch::new(scope);
let result = eval(try_catch, source);
if allow {
assert!(!try_catch.has_caught());
assert!(result.unwrap().is_true());
} else {
assert!(try_catch.has_caught());
let exc = try_catch.exception().unwrap();
let exc = exc.to_string(try_catch).unwrap();
let exc = exc.to_rust_string_lossy(try_catch);
assert!(exc.contains("Atomics.wait cannot be called in this context"));
}
}
}
}
fn mock_script_origin<'s>(
scope: &mut v8::HandleScope<'s>,
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resource_name_: &str,
) -> v8::ScriptOrigin<'s> {
let resource_name = v8::String::new(scope, resource_name_).unwrap();
let resource_line_offset = 0;
let resource_column_offset = 0;
let resource_is_shared_cross_origin = true;
let script_id = 123;
let source_map_url = v8::String::new(scope, "source_map_url").unwrap();
let resource_is_opaque = true;
let is_wasm = false;
let is_module = true;
v8::ScriptOrigin::new(
scope,
resource_name.into(),
resource_line_offset,
resource_column_offset,
resource_is_shared_cross_origin,
script_id,
source_map_url.into(),
resource_is_opaque,
is_wasm,
is_module,
)
}
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fn mock_source(
scope: &mut v8::HandleScope,
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resource_name: &str,
source: &str,
) -> v8::script_compiler::Source {
let source_str = v8::String::new(scope, source).unwrap();
let script_origin = mock_script_origin(scope, resource_name);
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v8::script_compiler::Source::new(source_str, Some(&script_origin))
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}
#[test]
fn script_compiler_source() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_promise_reject_callback(promise_reject_callback);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = "1+2";
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let script_origin = mock_script_origin(scope, "foo.js");
let source = v8::script_compiler::Source::new(
v8::String::new(scope, source).unwrap(),
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Some(&script_origin),
);
assert!(source.get_cached_data().is_none());
let result = v8::script_compiler::compile_module(scope, source);
assert!(result.is_some());
}
}
#[test]
fn module_instantiation_failures1() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source_text = v8::String::new(
scope,
"import './foo.js';\n\
export {} from './bar.js';",
)
.unwrap();
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let origin = mock_script_origin(scope, "foo.js");
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let source = v8::script_compiler::Source::new(source_text, Some(&origin));
let module = v8::script_compiler::compile_module(scope, source).unwrap();
assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
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let module_requests = module.get_module_requests();
assert_eq!(2, module_requests.length());
assert!(module.script_id().is_some());
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let mr1 = v8::Local::<v8::ModuleRequest>::try_from(
module_requests.get(scope, 0).unwrap(),
)
.unwrap();
assert_eq!("./foo.js", mr1.get_specifier().to_rust_string_lossy(scope));
let loc = module.source_offset_to_location(mr1.get_source_offset());
assert_eq!(0, loc.get_line_number());
assert_eq!(7, loc.get_column_number());
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assert_eq!(0, mr1.get_import_attributes().length());
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let mr2 = v8::Local::<v8::ModuleRequest>::try_from(
module_requests.get(scope, 1).unwrap(),
)
.unwrap();
assert_eq!("./bar.js", mr2.get_specifier().to_rust_string_lossy(scope));
let loc = module.source_offset_to_location(mr2.get_source_offset());
assert_eq!(1, loc.get_line_number());
assert_eq!(15, loc.get_column_number());
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assert_eq!(0, mr2.get_import_attributes().length());
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// Instantiation should fail.
{
let tc = &mut v8::TryCatch::new(scope);
fn resolve_callback<'a>(
context: v8::Local<'a, v8::Context>,
_specifier: v8::Local<'a, v8::String>,
_import_assertions: v8::Local<'a, v8::FixedArray>,
_referrer: v8::Local<'a, v8::Module>,
) -> Option<v8::Local<'a, v8::Module>> {
let scope = &mut unsafe { v8::CallbackScope::new(context) };
let scope = &mut v8::HandleScope::new(scope);
let e = v8::String::new(scope, "boom").unwrap();
scope.throw_exception(e.into());
None
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}
let result = module.instantiate_module(tc, resolve_callback);
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assert!(result.is_none());
assert!(tc.has_caught());
assert!(tc
.exception()
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.unwrap()
.strict_equals(v8::String::new(tc, "boom").unwrap().into()));
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assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
}
}
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}
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// Clippy thinks the return value doesn't need to be an Option, it's unaware
// of the mapping that MapFnFrom<F> does for ResolveModuleCallback.
#[allow(clippy::unnecessary_wraps)]
fn compile_specifier_as_module_resolve_callback<'a>(
context: v8::Local<'a, v8::Context>,
specifier: v8::Local<'a, v8::String>,
_import_assertions: v8::Local<'a, v8::FixedArray>,
_referrer: v8::Local<'a, v8::Module>,
) -> Option<v8::Local<'a, v8::Module>> {
let scope = &mut unsafe { v8::CallbackScope::new(context) };
let origin = mock_script_origin(scope, "module.js");
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let source = v8::script_compiler::Source::new(specifier, Some(&origin));
let module = v8::script_compiler::compile_module(scope, source).unwrap();
Some(module)
}
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#[test]
fn module_evaluation() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let source_text = v8::String::new(
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scope,
"import 'Object.expando = 5';\n\
import 'Object.expando *= 2';",
)
.unwrap();
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let origin = mock_script_origin(scope, "foo.js");
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let source = v8::script_compiler::Source::new(source_text, Some(&origin));
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let module = v8::script_compiler::compile_module(scope, source).unwrap();
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assert!(module.script_id().is_some());
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assert!(module.is_source_text_module());
assert!(!module.is_synthetic_module());
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assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
module.hash(&mut DefaultHasher::new()); // Should not crash.
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let result = module
.instantiate_module(scope, compile_specifier_as_module_resolve_callback);
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assert!(result.unwrap());
assert_eq!(v8::ModuleStatus::Instantiated, module.get_status());
let result = module.evaluate(scope);
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assert!(result.is_some());
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
let result = eval(scope, "Object.expando").unwrap();
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assert!(result.is_number());
let expected = v8::Number::new(scope, 10.);
assert!(result.strict_equals(expected.into()));
}
}
#[test]
fn module_stalled_top_level_await() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source_text =
v8::String::new(scope, "await new Promise((_resolve, _reject) => {});")
.unwrap();
let origin = mock_script_origin(scope, "foo.js");
let source = v8::script_compiler::Source::new(source_text, Some(&origin));
let module = v8::script_compiler::compile_module(scope, source).unwrap();
assert!(module.script_id().is_some());
assert!(module.is_source_text_module());
assert!(!module.is_synthetic_module());
assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
module.hash(&mut DefaultHasher::new()); // Should not crash.
let result = module
.instantiate_module(scope, compile_specifier_as_module_resolve_callback);
assert!(result.unwrap());
assert_eq!(v8::ModuleStatus::Instantiated, module.get_status());
let result = module.evaluate(scope);
assert!(result.is_some());
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
let promise: v8::Local<v8::Promise> = result.unwrap().try_into().unwrap();
scope.perform_microtask_checkpoint();
assert_eq!(promise.state(), v8::PromiseState::Pending);
let stalled = module.get_stalled_top_level_await_message(scope);
assert_eq!(stalled.len(), 1);
let (_module, message) = stalled[0];
let message_str = message.get(scope);
assert_eq!(
message_str.to_rust_string_lossy(scope),
"Top-level await promise never resolved"
);
assert_eq!(Some(1), message.get_line_number(scope));
assert_eq!(
message
.get_script_resource_name(scope)
.unwrap()
.to_rust_string_lossy(scope),
"foo.js"
);
assert_eq!(
message
.get_source_line(scope)
.unwrap()
.to_rust_string_lossy(scope),
"await new Promise((_resolve, _reject) => {});"
);
}
}
#[test]
fn import_assertions() {
use std::sync::atomic::AtomicUsize;
use std::sync::atomic::Ordering;
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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// Clippy thinks the return value doesn't need to be an Option, it's unaware
// of the mapping that MapFnFrom<F> does for ResolveModuleCallback.
#[allow(clippy::unnecessary_wraps)]
fn module_resolve_callback<'a>(
context: v8::Local<'a, v8::Context>,
_specifier: v8::Local<'a, v8::String>,
import_assertions: v8::Local<'a, v8::FixedArray>,
_referrer: v8::Local<'a, v8::Module>,
) -> Option<v8::Local<'a, v8::Module>> {
let scope = &mut unsafe { v8::CallbackScope::new(context) };
// "type" keyword, value and source offset of assertion
assert_eq!(import_assertions.length(), 3);
let assert1 = import_assertions.get(scope, 0).unwrap();
let assert1_val = v8::Local::<v8::Value>::try_from(assert1).unwrap();
assert_eq!(assert1_val.to_rust_string_lossy(scope), "type");
let assert2 = import_assertions.get(scope, 1).unwrap();
let assert2_val = v8::Local::<v8::Value>::try_from(assert2).unwrap();
assert_eq!(assert2_val.to_rust_string_lossy(scope), "json");
let assert3 = import_assertions.get(scope, 2).unwrap();
let assert3_val = v8::Local::<v8::Value>::try_from(assert3).unwrap();
assert_eq!(assert3_val.to_rust_string_lossy(scope), "27");
let origin = mock_script_origin(scope, "module.js");
let src = v8::String::new(scope, "export const a = 'a';").unwrap();
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let source = v8::script_compiler::Source::new(src, Some(&origin));
let module = v8::script_compiler::compile_module(scope, source).unwrap();
Some(module)
}
fn dynamic_import_cb<'s>(
scope: &mut v8::HandleScope<'s>,
_host_defined_options: v8::Local<'s, v8::Data>,
_resource_name: v8::Local<'s, v8::Value>,
_specifier: v8::Local<'s, v8::String>,
import_assertions: v8::Local<'s, v8::FixedArray>,
) -> Option<v8::Local<'s, v8::Promise>> {
// "type" keyword, value
assert_eq!(import_assertions.length(), 2);
let assert1 = import_assertions.get(scope, 0).unwrap();
let assert1_val = v8::Local::<v8::Value>::try_from(assert1).unwrap();
assert_eq!(assert1_val.to_rust_string_lossy(scope), "type");
let assert2 = import_assertions.get(scope, 1).unwrap();
let assert2_val = v8::Local::<v8::Value>::try_from(assert2).unwrap();
assert_eq!(assert2_val.to_rust_string_lossy(scope), "json");
None
}
isolate.set_host_import_module_dynamically_callback(dynamic_import_cb);
// TODO(@littledivy): this won't work when V8 removes `assert`.
static COUNTER: AtomicUsize = AtomicUsize::new(0);
extern "C" fn callback(
_msg: v8::Local<v8::Message>,
_: v8::Local<v8::Value>,
) {
COUNTER.fetch_add(1, Ordering::SeqCst);
}
isolate.add_message_listener_with_error_level(
callback,
v8::MessageErrorLevel::ALL,
);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source_text = v8::String::new(
scope,
"import 'foo.json' assert { type: \"json\" };\n\
import('foo.json', { assert: { type: 'json' } });",
)
.unwrap();
let origin = mock_script_origin(scope, "foo.js");
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let source = v8::script_compiler::Source::new(source_text, Some(&origin));
let module = v8::script_compiler::compile_module(scope, source).unwrap();
assert!(module.script_id().is_some());
assert!(module.is_source_text_module());
assert!(!module.is_synthetic_module());
assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
module.hash(&mut DefaultHasher::new()); // Should not crash.
let result = module.instantiate_module(scope, module_resolve_callback);
assert!(result.unwrap());
assert_eq!(v8::ModuleStatus::Instantiated, module.get_status());
}
assert_eq!(COUNTER.load(Ordering::SeqCst), 1);
}
#[test]
fn primitive_array() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let length = 3;
let array = v8::PrimitiveArray::new(scope, length);
assert_eq!(length, array.length());
for i in 0..length {
let item = array.get(scope, i);
assert!(item.is_undefined());
}
let string = v8::String::new(scope, "test").unwrap();
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array.set(scope, 1, string.into());
assert!(array.get(scope, 0).is_undefined());
assert!(array.get(scope, 1).is_string());
let num = v8::Number::new(scope, 0.42);
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array.set(scope, 2, num.into());
assert!(array.get(scope, 0).is_undefined());
assert!(array.get(scope, 1).is_string());
assert!(array.get(scope, 2).is_number());
}
}
#[test]
fn equality() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
assert!(v8::String::new(scope, "a")
.unwrap()
.strict_equals(v8::String::new(scope, "a").unwrap().into()));
assert!(!v8::String::new(scope, "a")
.unwrap()
.strict_equals(v8::String::new(scope, "b").unwrap().into()));
assert!(v8::String::new(scope, "a")
.unwrap()
.same_value(v8::String::new(scope, "a").unwrap().into()));
assert!(!v8::String::new(scope, "a")
.unwrap()
.same_value(v8::String::new(scope, "b").unwrap().into()));
}
}
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#[test]
#[allow(clippy::eq_op)]
fn equality_edge_cases() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let pos_zero = eval(scope, "0").unwrap();
let neg_zero = eval(scope, "-0").unwrap();
let nan = eval(scope, "NaN").unwrap();
assert!(pos_zero == pos_zero);
assert!(pos_zero.same_value(pos_zero));
assert!(pos_zero.same_value_zero(pos_zero));
assert!(pos_zero.strict_equals(pos_zero));
assert_eq!(pos_zero.get_hash(), pos_zero.get_hash());
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assert!(neg_zero == neg_zero);
assert!(neg_zero.same_value(neg_zero));
assert!(neg_zero.same_value_zero(neg_zero));
assert!(neg_zero.strict_equals(neg_zero));
assert_eq!(neg_zero.get_hash(), neg_zero.get_hash());
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assert!(pos_zero == neg_zero);
assert!(!pos_zero.same_value(neg_zero));
assert!(pos_zero.same_value_zero(neg_zero));
assert!(pos_zero.strict_equals(neg_zero));
assert_eq!(pos_zero.get_hash(), neg_zero.get_hash());
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assert!(neg_zero == pos_zero);
assert!(!neg_zero.same_value(pos_zero));
assert!(neg_zero.same_value_zero(pos_zero));
assert!(neg_zero.strict_equals(pos_zero));
assert_eq!(neg_zero.get_hash(), pos_zero.get_hash());
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assert!(nan == nan);
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assert!(nan.same_value(nan));
assert!(nan.same_value_zero(nan));
assert!(!nan.strict_equals(nan));
assert_eq!(nan.get_hash(), nan.get_hash());
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assert!(nan != pos_zero);
assert!(!nan.same_value(pos_zero));
assert!(!nan.same_value_zero(pos_zero));
assert!(!nan.strict_equals(pos_zero));
assert!(neg_zero != nan);
assert!(!neg_zero.same_value(nan));
assert!(!neg_zero.same_value_zero(nan));
assert!(!neg_zero.strict_equals(nan));
}
#[test]
fn get_hash() {
use std::collections::HashMap;
use std::collections::HashSet;
use std::iter::once;
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Note: the set with hashes and the collition counter is used below in both
// the 'primitives' and the 'objects' section.
let mut hashes = HashSet::new();
let mut collision_count = 0;
let mut get_primitives = || -> v8::Local<v8::Array> {
eval(
scope,
r#"[
undefined,
null,
false,
true,
0,
123,
12345e67,
123456789012345678901234567890123456789012345678901234567890n,
NaN,
-Infinity,
"",
"hello metaverse!",
Symbol.isConcatSpreadable
]"#,
)
.unwrap()
.try_into()
.unwrap()
};
let primitives1 = get_primitives();
let primitives2 = get_primitives();
let len = primitives1.length();
assert!(len > 10);
assert_eq!(len, primitives2.length());
let mut name_count = 0;
for i in 0..len {
let pri1 = primitives1.get_index(scope, i).unwrap();
let pri2 = primitives2.get_index(scope, i).unwrap();
let hash = pri1.get_hash();
assert_eq!(hash, pri2.get_hash());
if let Ok(name) = v8::Local::<v8::Name>::try_from(pri1) {
assert_eq!(hash, name.get_identity_hash());
name_count += 1;
}
if !hashes.insert(hash) {
collision_count += 1;
}
let map =
once((v8::Global::new(scope, pri1), i)).collect::<HashMap<_, _>>();
assert_eq!(map[&*pri2], i);
}
assert_eq!(name_count, 3);
assert!(collision_count <= 2);
for _ in 0..1 {
let objects: v8::Local::<v8::Array> = eval(
scope,
r#"[
[1, 2, 3],
(function() { return arguments; })(1, 2, 3),
{ a: 1, b: 2, c: 3 },
Object.create(null),
new Map([[null, 1], ["2", 3n]]),
new Set(),
function f() {},
function* f() {},
async function f() {},
async function* f() {},
foo => foo,
async bar => bar,
class Custom extends Object { method(p) { return -p; } },
new class MyString extends String { constructor() { super("yeaeaeah"); } },
(() => { try { not_defined } catch(e) { return e; } })()
]"#)
.unwrap()
.try_into()
.unwrap();
let len = objects.length();
assert!(len > 10);
for i in 0..len {
let val = objects.get_index(scope, i).unwrap();
let hash = val.get_hash();
let obj = v8::Local::<v8::Object>::try_from(val).unwrap();
assert_eq!(hash, obj.get_identity_hash());
if !hashes.insert(hash) {
collision_count += 1;
}
let map =
once((v8::Global::new(scope, obj), i)).collect::<HashMap<_, _>>();
assert_eq!(map[&*obj], i);
}
assert!(collision_count <= 2);
}
// TODO: add tests for `External` and for types that are not derived from
// `v8::Value`, like `Module`, `Function/ObjectTemplate` etc.
}
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#[test]
fn array_buffer_view() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(
scope,
"new Uint8Array(new Uint8Array([22,22,23,23,23,23]).buffer, 2, 4)",
)
.unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
source.to_rust_string_lossy(scope);
let result: v8::Local<v8::ArrayBufferView> =
script.run(scope).unwrap().try_into().unwrap();
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assert_eq!(result.byte_length(), 4);
assert_eq!(result.byte_offset(), 2);
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let mut dest = [0; 4];
let copy_bytes = result.copy_contents(&mut dest);
assert_eq!(copy_bytes, 4);
assert_eq!(dest, [23, 23, 23, 23]);
let slice = unsafe {
std::slice::from_raw_parts(
result.data() as *const u8,
result.byte_length(),
)
};
assert_eq!(dest, slice);
let maybe_ab = result.buffer(scope);
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assert!(maybe_ab.is_some());
let ab = maybe_ab.unwrap();
assert_eq!(ab.byte_length(), 6);
assert_eq!(
result.get_backing_store().unwrap().data(),
ab.get_backing_store().data()
);
}
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}
#[test]
fn continuation_preserved_embedder_data() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let data = scope.get_continuation_preserved_embedder_data();
assert!(data.is_undefined());
let value = v8::String::new(scope, "hello").unwrap();
scope.set_continuation_preserved_embedder_data(value.into());
let data = scope.get_continuation_preserved_embedder_data();
assert!(data.is_string());
assert_eq!(data.to_rust_string_lossy(scope), "hello");
eval(scope, "b = 2 + 3").unwrap();
let data = scope.get_continuation_preserved_embedder_data();
assert!(data.is_string());
assert_eq!(data.to_rust_string_lossy(scope), "hello");
}
}
#[test]
fn snapshot_creator() {
let _setup_guard = setup::sequential_test();
// First we create the snapshot, there is a single global variable 'a' set to
// the value 3.
let isolate_data_index;
let context_data_index;
let context_data_index_2;
let startup_data = {
let mut snapshot_creator = v8::Isolate::snapshot_creator(None);
{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
eval(scope, "b = 2 + 3").unwrap();
scope.set_default_context(context);
}
snapshot_creator
.create_blob(v8::FunctionCodeHandling::Clear)
.unwrap()
};
let startup_data = {
let mut snapshot_creator =
v8::Isolate::snapshot_creator_from_existing_snapshot(startup_data, None);
{
// Check that the SnapshotCreator isolate has been set up correctly.
let _ = snapshot_creator.thread_safe_handle();
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
eval(scope, "a = 1 + 2").unwrap();
scope.set_default_context(context);
let n1 = v8::Number::new(scope, 1.0);
let n2 = v8::Number::new(scope, 2.0);
let n3 = v8::Number::new(scope, 3.0);
isolate_data_index = scope.add_isolate_data(n1);
context_data_index = scope.add_context_data(context, n2);
context_data_index_2 = scope.add_context_data(context, n3);
}
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snapshot_creator
.create_blob(v8::FunctionCodeHandling::Clear)
.unwrap()
};
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assert!(startup_data.len() > 0);
// Now we try to load up the snapshot and check that 'a' has the correct
// value.
{
let params = v8::Isolate::create_params().snapshot_blob(startup_data);
let isolate = &mut v8::Isolate::new(params);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let result = eval(scope, "a === 3").unwrap();
let true_val = v8::Boolean::new(scope, true).into();
assert!(result.same_value(true_val));
let result = eval(scope, "b === 5").unwrap();
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let true_val = v8::Boolean::new(scope, true).into();
assert!(result.same_value(true_val));
let isolate_data = scope
.get_isolate_data_from_snapshot_once::<v8::Value>(isolate_data_index);
assert!(isolate_data.unwrap() == v8::Number::new(scope, 1.0));
let no_data_err = scope
.get_isolate_data_from_snapshot_once::<v8::Value>(isolate_data_index);
assert!(matches!(no_data_err, Err(v8::DataError::NoData { .. })));
let context_data = scope
.get_context_data_from_snapshot_once::<v8::Value>(context_data_index);
assert!(context_data.unwrap() == v8::Number::new(scope, 2.0));
let no_data_err = scope
.get_context_data_from_snapshot_once::<v8::Value>(context_data_index);
assert!(matches!(no_data_err, Err(v8::DataError::NoData { .. })));
let bad_type_err = scope
.get_context_data_from_snapshot_once::<v8::Private>(
context_data_index_2,
);
assert!(matches!(bad_type_err, Err(v8::DataError::BadType { .. })));
// Ensure we can compile a request for v8::Data
_ = scope
.get_context_data_from_snapshot_once::<v8::Data>(context_data_index_2);
}
}
}
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#[test]
fn snapshot_creator_multiple_contexts() {
let _setup_guard = setup::sequential_test();
let startup_data = {
let mut snapshot_creator = v8::Isolate::snapshot_creator(None);
{
let mut scope = v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(&mut scope);
let scope = &mut v8::ContextScope::new(&mut scope, context);
eval(scope, "globalThis.__bootstrap = { defaultContextProp: 1};")
.unwrap();
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp").unwrap();
let one_val = v8::Number::new(scope, 1.0).into();
assert!(value.same_value(one_val));
}
scope.set_default_context(context);
}
{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
eval(scope, "globalThis.__bootstrap = { context0Prop: 2 };").unwrap();
{
let value = eval(scope, "globalThis.__bootstrap.context0Prop").unwrap();
let two_val = v8::Number::new(scope, 2.0).into();
assert!(value.same_value(two_val));
}
assert_eq!(0, scope.add_context(context));
}
snapshot_creator
.create_blob(v8::FunctionCodeHandling::Clear)
.unwrap()
};
let startup_data = {
let mut snapshot_creator =
v8::Isolate::snapshot_creator_from_existing_snapshot(startup_data, None);
{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp").unwrap();
let one_val = v8::Number::new(scope, 1.0).into();
assert!(value.same_value(one_val));
}
{
let value = eval(scope, "globalThis.__bootstrap.context0Prop").unwrap();
assert!(value.is_undefined());
}
{
eval(scope, "globalThis.__bootstrap.defaultContextProp2 = 3;").unwrap();
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp2").unwrap();
let three_val = v8::Number::new(scope, 3.0).into();
assert!(value.same_value(three_val));
}
scope.set_default_context(context);
}
{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::from_snapshot(scope, 0).unwrap();
let scope = &mut v8::ContextScope::new(scope, context);
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp").unwrap();
assert!(value.is_undefined());
}
{
let value = eval(scope, "globalThis.__bootstrap.context0Prop").unwrap();
let two_val = v8::Number::new(scope, 2.0).into();
assert!(value.same_value(two_val));
}
{
eval(scope, "globalThis.__bootstrap.context0Prop2 = 4;").unwrap();
let value =
eval(scope, "globalThis.__bootstrap.context0Prop2").unwrap();
let four_val = v8::Number::new(scope, 4.0).into();
assert!(value.same_value(four_val));
}
assert_eq!(scope.add_context(context), 0);
}
snapshot_creator
.create_blob(v8::FunctionCodeHandling::Clear)
.unwrap()
};
{
let params = v8::Isolate::create_params().snapshot_blob(startup_data);
let isolate = &mut v8::Isolate::new(params);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let value = eval(scope, "globalThis.__bootstrap.context0Prop").unwrap();
assert!(value.is_undefined());
}
{
let value =
eval(scope, "globalThis.__bootstrap.context0Prop2").unwrap();
assert!(value.is_undefined());
}
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp").unwrap();
let one_val = v8::Number::new(scope, 1.0).into();
assert!(value.same_value(one_val));
}
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp2").unwrap();
let three_val = v8::Number::new(scope, 3.0).into();
assert!(value.same_value(three_val));
}
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::from_snapshot(scope, 0).unwrap();
let scope = &mut v8::ContextScope::new(scope, context);
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp").unwrap();
assert!(value.is_undefined());
}
{
let value =
eval(scope, "globalThis.__bootstrap.defaultContextProp2").unwrap();
assert!(value.is_undefined());
}
{
let value = eval(scope, "globalThis.__bootstrap.context0Prop").unwrap();
let two_val = v8::Number::new(scope, 2.0).into();
assert!(value.same_value(two_val));
}
{
let value =
eval(scope, "globalThis.__bootstrap.context0Prop2").unwrap();
let four_val = v8::Number::new(scope, 4.0).into();
assert!(value.same_value(four_val));
}
}
}
}
#[test]
fn external_references() {
let _setup_guard = setup::sequential_test();
// Allocate externals for the test.
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let external_ptr =
Box::into_raw(vec![0_u8, 1, 2, 3, 4].into_boxed_slice()) as *mut c_void;
// Push them to the external reference table.
let refs = [
v8::ExternalReference {
function: fn_callback.map_fn_to(),
},
v8::ExternalReference {
function: fn_callback_external.map_fn_to(),
},
v8::ExternalReference {
pointer: external_ptr,
},
];
// Exercise the Debug impl
println!("{refs:?}");
let refs = v8::ExternalReferences::new(&refs);
// TODO(piscisaureus): leaking the `ExternalReferences` collection shouldn't
// be necessary. The reference needs to remain valid for the lifetime of the
// `SnapshotCreator` or `Isolate` that uses it, which would be the case here
// even without leaking.
let refs: &'static v8::ExternalReferences = Box::leak(Box::new(refs));
// First we create the snapshot, there is a single global variable 'a' set to
// the value 3.
let startup_data = {
let mut snapshot_creator = v8::Isolate::snapshot_creator(Some(refs));
{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// create function using template
let external = v8::External::new(scope, external_ptr);
let fn_template = v8::FunctionTemplate::builder(fn_callback_external)
.data(external.into())
.build(scope);
let function = fn_template
.get_function(scope)
.expect("Unable to create function");
let global = context.global(scope);
let key = v8::String::new(scope, "F").unwrap();
global.set(scope, key.into(), function.into());
scope.set_default_context(context);
}
snapshot_creator
.create_blob(v8::FunctionCodeHandling::Clear)
.unwrap()
};
assert!(startup_data.len() > 0);
// Now we try to load up the snapshot and check that 'a' has the correct
// value.
{
let params = v8::Isolate::create_params()
.snapshot_blob(startup_data)
.external_references(&**refs);
let isolate = &mut v8::Isolate::new(params);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let result = eval(scope, "if(F() != 'wrong answer') throw 'boom1'");
assert!(result.is_none());
let result = eval(scope, "if(F() != 'Hello callback!') throw 'boom2'");
assert!(result.is_some());
}
}
}
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#[test]
fn create_params_snapshot_blob() {
let static_data = b"abcd";
let _ = v8::CreateParams::default().snapshot_blob(&static_data[..]);
let vec_1 = Vec::from(&b"defg"[..]);
let _ = v8::CreateParams::default().snapshot_blob(vec_1);
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let vec_2 = std::fs::read(file!()).unwrap();
let _ = v8::CreateParams::default().snapshot_blob(vec_2);
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let arc_slice: std::sync::Arc<[u8]> = std::fs::read(file!()).unwrap().into();
let _ = v8::CreateParams::default().snapshot_blob(arc_slice.clone());
let _ = v8::CreateParams::default().snapshot_blob(arc_slice);
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}
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#[test]
fn uint8_array() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source =
v8::String::new(scope, "new Uint8Array([23,23,23,23])").unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
source.to_rust_string_lossy(scope);
let result: v8::Local<v8::ArrayBufferView> =
script.run(scope).unwrap().try_into().unwrap();
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assert_eq!(result.byte_length(), 4);
assert_eq!(result.byte_offset(), 0);
let mut dest = [0; 4];
let copy_bytes = result.copy_contents(&mut dest);
assert_eq!(copy_bytes, 4);
assert_eq!(dest, [23, 23, 23, 23]);
let maybe_ab = result.buffer(scope);
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assert!(maybe_ab.is_some());
let ab = maybe_ab.unwrap();
let uint8_array = v8::Uint8Array::new(scope, ab, 0, 0);
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assert!(uint8_array.is_some());
}
}
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#[test]
fn typed_array_constructors() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let ab = v8::ArrayBuffer::new(scope, 8);
let t = v8::Uint8Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_uint8_array());
assert_eq!(t.length(), 0);
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// Uint8Array::max_length() ought to be 1 << 53 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 53) - 1, v8::Uint8Array::max_length());
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let t = v8::Uint8ClampedArray::new(scope, ab, 0, 0).unwrap();
assert!(t.is_uint8_clamped_array());
assert_eq!(t.length(), 0);
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// Uint8ClampedArray::max_length() ought to be 1 << 53 - 1 on 64 bits when
// heap sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 53) - 1, v8::Uint8ClampedArray::max_length());
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let t = v8::Int8Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_int8_array());
assert_eq!(t.length(), 0);
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// Int8Array::max_length() ought to be 1 << 53 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 53) - 1, v8::Int8Array::max_length());
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let t = v8::Uint16Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_uint16_array());
assert_eq!(t.length(), 0);
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// Uint16Array::max_length() ought to be 1 << 52 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 52) - 1, v8::Uint16Array::max_length());
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let t = v8::Int16Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_int16_array());
assert_eq!(t.length(), 0);
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// Int16Array::max_length() ought to be 1 << 52 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 52) - 1, v8::Int16Array::max_length());
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let t = v8::Uint32Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_uint32_array());
assert_eq!(t.length(), 0);
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// Uint32Array::max_length() ought to be 1 << 51 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 51) - 1, v8::Uint32Array::max_length());
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let t = v8::Int32Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_int32_array());
assert_eq!(t.length(), 0);
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// Int32Array::max_length() ought to be 1 << 51 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 51) - 1, v8::Int32Array::max_length());
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let t = v8::Float32Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_float32_array());
assert_eq!(t.length(), 0);
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// Float32Array::max_length() ought to be 1 << 51 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 51) - 1, v8::Float32Array::max_length());
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let t = v8::Float64Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_float64_array());
assert_eq!(t.length(), 0);
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// Float64Array::max_length() ought to be 1 << 50 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 50) - 1, v8::Float64Array::max_length());
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let t = v8::BigUint64Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_big_uint64_array());
assert_eq!(t.length(), 0);
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// BigUint64Array::max_length() ought to be 1 << 50 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 50) - 1, v8::BigUint64Array::max_length());
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let t = v8::BigInt64Array::new(scope, ab, 0, 0).unwrap();
assert!(t.is_big_int64_array());
assert_eq!(t.length(), 0);
// BigInt64Array::max_length() ought to be 1 << 50 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 50) - 1, v8::BigInt64Array::max_length());
// TypedArray::max_byte_length() ought to be 1 << 53 - 1 on 64 bits when heap
// sandbox is disabled.
#[cfg(target_pointer_width = "64")]
assert_eq!((1 << 53) - 1, v8::TypedArray::max_byte_length());
// TypedArray::max_byte_length() ought to be >= 2^28 < 2^30 in 32 bits
#[cfg(target_pointer_width = "32")]
assert!(((2 << 28)..(2 << 30)).contains(&v8::TypedArray::max_byte_length()));
// v8::ArrayBuffer::new raises a fatal if the length is > kMaxLength, so we test this behavior
// through the JS side of things, where a non-fatal RangeError is thrown in such cases.
{
let scope = &mut v8::TryCatch::new(scope);
eval(
scope,
&format!("new Uint8Array({})", v8::Uint8Array::max_length() + 1),
);
// Array is too big (> max_length) - expecting this threw a RangeError
assert!(scope.has_caught());
}
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}
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#[test]
fn dynamic_import() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
fn dynamic_import_cb<'s>(
scope: &mut v8::HandleScope<'s>,
_host_defined_options: v8::Local<'s, v8::Data>,
_resource_name: v8::Local<'s, v8::Value>,
specifier: v8::Local<'s, v8::String>,
_import_assertions: v8::Local<'s, v8::FixedArray>,
) -> Option<v8::Local<'s, v8::Promise>> {
assert!(
specifier.strict_equals(v8::String::new(scope, "bar.js").unwrap().into())
);
let e = v8::String::new(scope, "boom").unwrap();
scope.throw_exception(e.into());
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CALL_COUNT.fetch_add(1, Ordering::SeqCst);
None
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}
isolate.set_host_import_module_dynamically_callback(dynamic_import_cb);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let result = eval(
scope,
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"(async function () {\n\
let x = await import('bar.js');\n\
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})();",
);
assert!(result.is_some());
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 1);
}
}
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#[test]
fn shared_array_buffer() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let sab = v8::SharedArrayBuffer::new(scope, 16).unwrap();
let shared_bs_1 = sab.get_backing_store();
shared_bs_1[5].set(12);
shared_bs_1[12].set(52);
let global = context.global(scope);
let key = v8::String::new(scope, "shared").unwrap();
let r = global
.create_data_property(scope, key.into(), sab.into())
.unwrap();
assert!(r);
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let source = v8::String::new(
scope,
r"sharedBytes = new Uint8Array(shared);
sharedBytes[2] = 16;
sharedBytes[14] = 62;
sharedBytes[5] + sharedBytes[12]",
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)
.unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let result: v8::Local<v8::Integer> =
script.run(scope).unwrap().try_into().unwrap();
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assert_eq!(result.value(), 64);
assert_eq!(shared_bs_1[2].get(), 16);
assert_eq!(shared_bs_1[14].get(), 62);
let data: Box<[u8]> = vec![0, 1, 2, 3, 4, 5, 6, 7, 8, 9].into_boxed_slice();
let bs = v8::SharedArrayBuffer::new_backing_store_from_boxed_slice(data);
assert_eq!(bs.byte_length(), 10);
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assert!(bs.is_shared());
let shared_bs_2 = bs.make_shared();
assert_eq!(shared_bs_2.byte_length(), 10);
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assert!(shared_bs_2.is_shared());
let ab = v8::SharedArrayBuffer::with_backing_store(scope, &shared_bs_2);
let shared_bs_3 = ab.get_backing_store();
assert_eq!(shared_bs_3.byte_length(), 10);
assert_eq!(shared_bs_3[0].get(), 0);
assert_eq!(shared_bs_3[9].get(), 9);
// Empty
let ab = v8::SharedArrayBuffer::empty(scope);
assert_eq!(ab.byte_length(), 0);
assert!(ab.get_backing_store().is_shared());
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}
}
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#[test]
fn typeof_checker() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let value_1 = eval(scope, "").unwrap();
let type_of = value_1.type_of(scope);
let value_2 = eval(scope, "").unwrap();
let type_of_2 = value_2.type_of(scope);
assert_eq!(type_of, type_of_2);
let value_3 = eval(scope, "1").unwrap();
let type_of_3 = value_3.type_of(scope);
assert_ne!(type_of_2, type_of_3);
}
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#[test]
#[allow(clippy::cognitive_complexity)]
#[allow(clippy::eq_op)]
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fn value_checker() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let value = eval(scope, "undefined").unwrap();
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assert!(value.is_undefined());
assert!(value.is_null_or_undefined());
assert!(value == value);
assert!(value == v8::Local::<v8::Primitive>::try_from(value).unwrap());
assert!(value == v8::undefined(scope));
assert!(value != v8::null(scope));
assert!(value != v8::Boolean::new(scope, false));
assert!(value != v8::Integer::new(scope, 0));
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let value = eval(scope, "null").unwrap();
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assert!(value.is_null());
assert!(value.is_null_or_undefined());
assert!(value == value);
assert!(value == v8::Local::<v8::Primitive>::try_from(value).unwrap());
assert!(value == v8::null(scope));
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::null(scope));
assert!(value != v8::undefined(scope));
assert!(value != v8::Boolean::new(scope, false));
assert!(value != v8::Integer::new(scope, 0));
assert!(value.to_boolean(scope) == v8::Boolean::new(scope, false));
assert!(!value.boolean_value(scope));
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let value = eval(scope, "true").unwrap();
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assert!(value.is_boolean());
assert!(value.is_true());
assert!(!value.is_false());
assert!(value == value);
assert!(value == v8::Local::<v8::Boolean>::try_from(value).unwrap());
assert!(value == v8::Boolean::new(scope, true));
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == eval(scope, "!false").unwrap());
assert!(v8::Global::new(scope, value) != eval(scope, "1").unwrap());
assert!(value != v8::Boolean::new(scope, false));
assert!(value.boolean_value(scope));
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let value = eval(scope, "false").unwrap();
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assert!(value.is_boolean());
assert!(!value.is_true());
assert!(value.is_false());
assert!(value == value);
assert!(value == v8::Local::<v8::Boolean>::try_from(value).unwrap());
assert!(value == v8::Boolean::new(scope, false));
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == eval(scope, "!true").unwrap());
assert!(v8::Global::new(scope, value) != eval(scope, "0").unwrap());
assert!(value != v8::Boolean::new(scope, true));
assert!(value != v8::null(scope));
assert!(value != v8::undefined(scope));
assert!(value != v8::Integer::new(scope, 0));
assert!(!value.boolean_value(scope));
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let value = eval(scope, "'name'").unwrap();
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assert!(value.is_name());
assert!(value.is_string());
assert!(value == value);
assert!(value == v8::Local::<v8::String>::try_from(value).unwrap());
assert!(value == v8::String::new(scope, "name").unwrap());
assert!(value != v8::String::new(scope, "name\0").unwrap());
assert!(value != v8::Object::new(scope));
assert!(value.to_boolean(scope) == v8::Boolean::new(scope, true));
assert!(value.boolean_value(scope));
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let value = eval(scope, "Symbol()").unwrap();
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assert!(value.is_name());
assert!(value.is_symbol());
assert!(value == value);
assert!(value == v8::Local::<v8::Symbol>::try_from(value).unwrap());
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(value != eval(scope, "Symbol()").unwrap());
assert!(v8::Global::new(scope, value) != eval(scope, "Symbol()").unwrap());
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let value = eval(scope, "() => 0").unwrap();
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assert!(value.is_function());
assert!(value == value);
assert!(value == v8::Local::<v8::Function>::try_from(value).unwrap());
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(value != eval(scope, "() => 0").unwrap());
assert!(v8::Global::new(scope, value) != eval(scope, "() => 0").unwrap());
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let value = eval(scope, "async () => 0").unwrap();
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assert!(value.is_async_function());
assert!(value == value);
assert!(value == v8::Local::<v8::Function>::try_from(value).unwrap());
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(value != v8::Object::new(scope));
assert!(v8::Global::new(scope, value) != v8::Object::new(scope));
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let value = eval(scope, "[]").unwrap();
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assert!(value.is_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Array>::try_from(value).unwrap());
assert!(value != v8::Array::new(scope, 0));
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let value = eval(scope, "9007199254740995n").unwrap();
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assert!(value.is_big_int());
assert!(value.to_big_int(scope).is_some());
assert!(value == value);
assert!(value == v8::Local::<v8::BigInt>::try_from(value).unwrap());
assert!(value == eval(scope, "1801439850948199n * 5n").unwrap());
assert!(value != eval(scope, "1801439850948199 * 5").unwrap());
let detail_string = value.to_detail_string(scope).unwrap();
let detail_string = detail_string.to_rust_string_lossy(scope);
assert_eq!("9007199254740995", detail_string);
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let value = eval(scope, "123").unwrap();
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assert!(value.is_number());
assert!(value.is_int32());
assert!(value.is_uint32());
assert!(value == value);
assert!(value == v8::Local::<v8::Number>::try_from(value).unwrap());
assert!(value == v8::Integer::new(scope, 123));
assert!(value == v8::Number::new(scope, 123f64));
assert!(value == value.to_int32(scope).unwrap());
assert!(value != value.to_string(scope).unwrap());
assert_eq!(123, value.to_uint32(scope).unwrap().value());
assert_eq!(123, value.to_int32(scope).unwrap().value());
assert_eq!(123, value.to_integer(scope).unwrap().value());
assert_eq!(123, value.integer_value(scope).unwrap());
assert_eq!(123, value.uint32_value(scope).unwrap());
assert_eq!(123, value.int32_value(scope).unwrap());
let value = eval(scope, "12.3").unwrap();
assert!(value.is_number());
assert!(!value.is_int32());
assert!(!value.is_uint32());
assert!(value == value);
assert!(value == v8::Local::<v8::Number>::try_from(value).unwrap());
assert!(value == v8::Number::new(scope, 12.3f64));
assert!(value != value.to_integer(scope).unwrap());
assert!(12.3 - value.number_value(scope).unwrap() < 0.00001);
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let value = eval(scope, "-123").unwrap();
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assert!(value.is_number());
assert!(value.is_int32());
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assert!(!value.is_uint32());
assert!(value == value);
assert!(value == v8::Local::<v8::Int32>::try_from(value).unwrap());
assert!(value == v8::Integer::new(scope, -123));
assert!(value == v8::Number::new(scope, -123f64));
assert!(value != v8::String::new(scope, "-123").unwrap());
assert!(
value
== v8::Integer::new_from_unsigned(scope, -123i32 as u32)
.to_int32(scope)
.unwrap()
);
// The following test does not pass. This appears to be a V8 bug.
// assert!(value != value.to_uint32(scope).unwrap());
let value = eval(scope, "NaN").unwrap();
assert!(value.is_number());
assert!(!value.is_int32());
assert!(!value.is_uint32());
assert!(!value.strict_equals(value));
assert!(
value.to_string(scope).unwrap() == v8::String::new(scope, "NaN").unwrap()
);
let value = eval(scope, "({})").unwrap();
assert!(value.is_object());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value == v8::Global::new(scope, value));
assert!(v8::Global::new(scope, value) == v8::Global::new(scope, value));
assert!(value != v8::Object::new(scope));
assert!(v8::Global::new(scope, value) != v8::Object::new(scope));
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let value = eval(scope, "new Date()").unwrap();
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assert!(value.is_date());
assert!(value == value);
assert!(value == v8::Local::<v8::Date>::try_from(value).unwrap());
assert!(value != eval(scope, "new Date()").unwrap());
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let value = eval(scope, "(function(){return arguments})()").unwrap();
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assert!(value.is_arguments_object());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Promise(function(){})").unwrap();
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assert!(value.is_promise());
assert!(value == value);
assert!(value == v8::Local::<v8::Promise>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Map()").unwrap();
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assert!(value.is_map());
assert!(value == value);
assert!(value == v8::Local::<v8::Map>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Set").unwrap();
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assert!(value.is_set());
assert!(value == value);
assert!(value == v8::Local::<v8::Set>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Map().entries()").unwrap();
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assert!(value.is_map_iterator());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Set().entries()").unwrap();
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assert!(value.is_set_iterator());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(
scope,
r#"
function* values() {
for (var i = 0; i < arguments.length; i++) {
yield arguments[i];
}
}
values(1, 2, 3)"#,
)
.unwrap();
assert!(value.is_generator_object());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
let value = eval(scope, "new WeakMap()").unwrap();
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assert!(value.is_weak_map());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new WeakSet()").unwrap();
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assert!(value.is_weak_set());
assert!(value == value);
assert!(value == v8::Local::<v8::Object>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new ArrayBuffer(8)").unwrap();
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assert!(value.is_array_buffer());
assert!(value == value);
assert!(value == v8::Local::<v8::ArrayBuffer>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Uint8Array([])").unwrap();
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assert!(value.is_uint8_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Uint8Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Uint8ClampedArray([])").unwrap();
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assert!(value.is_uint8_clamped_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(
value == v8::Local::<v8::Uint8ClampedArray>::try_from(value).unwrap()
);
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Int8Array([])").unwrap();
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assert!(value.is_int8_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Int8Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Uint16Array([])").unwrap();
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assert!(value.is_uint16_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Uint16Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Int16Array([])").unwrap();
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assert!(value.is_int16_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Int16Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Uint32Array([])").unwrap();
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assert!(value.is_uint32_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Uint32Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Int32Array([])").unwrap();
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assert!(value.is_int32_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Int32Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Float32Array([])").unwrap();
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assert!(value.is_float32_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Float32Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Float64Array([])").unwrap();
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assert!(value.is_float64_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::Float64Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new BigInt64Array([])").unwrap();
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assert!(value.is_big_int64_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::BigInt64Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new BigUint64Array([])").unwrap();
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assert!(value.is_big_uint64_array());
assert!(value.is_array_buffer_view());
assert!(value.is_typed_array());
assert!(value == value);
assert!(value == v8::Local::<v8::BigUint64Array>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new SharedArrayBuffer(64)").unwrap();
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assert!(value.is_shared_array_buffer());
assert!(value == value);
assert!(
value == v8::Local::<v8::SharedArrayBuffer>::try_from(value).unwrap()
);
assert!(value != v8::Object::new(scope));
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let value = eval(scope, "new Proxy({},{})").unwrap();
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assert!(value.is_proxy());
assert!(value == value);
assert!(value == v8::Local::<v8::Proxy>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
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// Other checker, Just check if it can be called
value.is_external();
value.is_module_namespace_object();
value.is_wasm_module_object();
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}
}
#[test]
fn try_from_data() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let module_source = mock_source(scope, "answer.js", "fail()");
let function_callback =
|_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
_: v8::ReturnValue| { unreachable!() };
let function_template = v8::FunctionTemplate::new(scope, function_callback);
let d: v8::Local<v8::Data> = function_template.into();
assert!(d.is_function_template());
assert!(!d.is_module());
assert!(!d.is_object_template());
assert!(!d.is_private());
assert!(!d.is_value());
assert!(
v8::Local::<v8::FunctionTemplate>::try_from(d).unwrap()
== function_template
);
let module =
v8::script_compiler::compile_module(scope, module_source).unwrap();
let d: v8::Local<v8::Data> = module.into();
assert!(!d.is_function_template());
assert!(d.is_module());
assert!(!d.is_object_template());
assert!(!d.is_private());
assert!(!d.is_value());
assert!(v8::Local::<v8::Module>::try_from(d).unwrap() == module);
let object_template = v8::ObjectTemplate::new(scope);
let d: v8::Local<v8::Data> = object_template.into();
assert!(!d.is_function_template());
assert!(!d.is_module());
assert!(d.is_object_template());
assert!(!d.is_private());
assert!(!d.is_value());
assert!(
v8::Local::<v8::ObjectTemplate>::try_from(d).unwrap() == object_template
);
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let p: v8::Local<v8::Data> = v8::Private::new(scope, None).into();
assert!(!p.is_function_template());
assert!(!p.is_module());
assert!(!p.is_object_template());
assert!(p.is_private());
assert!(!p.is_value());
let values: &[v8::Local<v8::Value>] = &[
v8::null(scope).into(),
v8::undefined(scope).into(),
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v8::BigInt::new_from_u64(scope, 1337).into(),
v8::Boolean::new(scope, true).into(),
v8::Function::new(scope, function_callback).unwrap().into(),
v8::Number::new(scope, 42.0).into(),
v8::Object::new(scope).into(),
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v8::Symbol::new(scope, None).into(),
v8::String::new(scope, "hello").unwrap().into(),
];
for &v in values {
let d: v8::Local<v8::Data> = v.into();
assert!(!d.is_function_template());
assert!(!d.is_module());
assert!(!d.is_object_template());
assert!(!d.is_private());
assert!(d.is_value());
assert!(v8::Local::<v8::Value>::try_from(d).unwrap() == v);
}
}
#[test]
fn try_from_value() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let value: v8::Local<v8::Value> = v8::undefined(scope).into();
let _primitive = v8::Local::<v8::Primitive>::try_from(value).unwrap();
assert!(matches!(
v8::Local::<v8::Object>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Object>()
));
assert!(matches!(
v8::Local::<v8::Int32>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Int32>()
));
}
{
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let value: v8::Local<v8::Value> = v8::Boolean::new(scope, true).into();
let primitive = v8::Local::<v8::Primitive>::try_from(value).unwrap();
let _boolean = v8::Local::<v8::Boolean>::try_from(value).unwrap();
let _boolean = v8::Local::<v8::Boolean>::try_from(primitive).unwrap();
assert!(matches!(
v8::Local::<v8::String>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::String>()
));
assert!(matches!(
v8::Local::<v8::Number>::try_from(primitive),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Number>()
));
}
{
let value: v8::Local<v8::Value> = v8::Number::new(scope, -1234f64).into();
let primitive = v8::Local::<v8::Primitive>::try_from(value).unwrap();
let _number = v8::Local::<v8::Number>::try_from(value).unwrap();
let number = v8::Local::<v8::Number>::try_from(primitive).unwrap();
let _integer = v8::Local::<v8::Integer>::try_from(value).unwrap();
let _integer = v8::Local::<v8::Integer>::try_from(primitive).unwrap();
let integer = v8::Local::<v8::Integer>::try_from(number).unwrap();
let _int32 = v8::Local::<v8::Int32>::try_from(value).unwrap();
let _int32 = v8::Local::<v8::Int32>::try_from(primitive).unwrap();
let _int32 = v8::Local::<v8::Int32>::try_from(integer).unwrap();
let _int32 = v8::Local::<v8::Int32>::try_from(number).unwrap();
assert!(matches!(
v8::Local::<v8::String>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::String>()
));
assert!(matches!(
v8::Local::<v8::Boolean>::try_from(primitive),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Boolean>()
));
assert!(matches!(
v8::Local::<v8::Uint32>::try_from(integer),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Uint32>()
));
}
{
let value: v8::Local<v8::Value> = eval(scope, "(() => {})").unwrap();
let object = v8::Local::<v8::Object>::try_from(value).unwrap();
let _function = v8::Local::<v8::Function>::try_from(value).unwrap();
let _function = v8::Local::<v8::Function>::try_from(object).unwrap();
assert!(matches!(
v8::Local::<v8::Primitive>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Primitive>()
));
assert!(matches!(
v8::Local::<v8::BigInt>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::BigInt>()
));
assert!(matches!(
v8::Local::<v8::NumberObject>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::NumberObject>()
));
assert!(matches!(
v8::Local::<v8::NumberObject>::try_from(object),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::NumberObject>()
));
assert!(matches!(
v8::Local::<v8::Set>::try_from(value),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Set>()
));
assert!(matches!(
v8::Local::<v8::Set>::try_from(object),
Err(v8::DataError::BadType { expected, .. })
if expected == type_name::<v8::Set>()
));
}
}
}
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struct ClientCounter {
base: v8::inspector::V8InspectorClientBase,
count_run_message_loop_on_pause: usize,
count_quit_message_loop_on_pause: usize,
count_run_if_waiting_for_debugger: usize,
count_generate_unique_id: i64,
}
impl ClientCounter {
fn new() -> Self {
Self {
base: v8::inspector::V8InspectorClientBase::new::<Self>(),
count_run_message_loop_on_pause: 0,
count_quit_message_loop_on_pause: 0,
count_run_if_waiting_for_debugger: 0,
count_generate_unique_id: 0,
}
}
}
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impl v8::inspector::V8InspectorClientImpl for ClientCounter {
fn base(&self) -> &v8::inspector::V8InspectorClientBase {
&self.base
}
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fn base_mut(&mut self) -> &mut v8::inspector::V8InspectorClientBase {
&mut self.base
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}
unsafe fn base_ptr(
this: *const Self,
) -> *const v8::inspector::V8InspectorClientBase
where
Self: Sized,
{
unsafe { addr_of!((*this).base) }
}
fn run_message_loop_on_pause(&mut self, context_group_id: i32) {
assert_eq!(context_group_id, 1);
self.count_run_message_loop_on_pause += 1;
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}
fn quit_message_loop_on_pause(&mut self) {
self.count_quit_message_loop_on_pause += 1;
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}
fn run_if_waiting_for_debugger(&mut self, context_group_id: i32) {
assert_eq!(context_group_id, 1);
self.count_run_message_loop_on_pause += 1;
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}
fn generate_unique_id(&mut self) -> i64 {
self.count_generate_unique_id += 1;
self.count_generate_unique_id
}
}
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struct ChannelCounter {
base: v8::inspector::ChannelBase,
count_send_response: usize,
count_send_notification: usize,
notifications: Vec<String>,
count_flush_protocol_notifications: usize,
}
impl ChannelCounter {
pub fn new() -> Self {
Self {
base: v8::inspector::ChannelBase::new::<Self>(),
count_send_response: 0,
count_send_notification: 0,
notifications: vec![],
count_flush_protocol_notifications: 0,
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}
}
}
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impl v8::inspector::ChannelImpl for ChannelCounter {
fn base(&self) -> &v8::inspector::ChannelBase {
&self.base
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}
fn base_mut(&mut self) -> &mut v8::inspector::ChannelBase {
&mut self.base
}
unsafe fn base_ptr(_this: *const Self) -> *const ChannelBase
where
Self: Sized,
{
unsafe { addr_of!((*_this).base) }
}
fn send_response(
&mut self,
call_id: i32,
message: v8::UniquePtr<v8::inspector::StringBuffer>,
) {
println!(
"send_response call_id {} message {}",
call_id,
message.unwrap().string()
);
self.count_send_response += 1;
}
fn send_notification(
&mut self,
message: v8::UniquePtr<v8::inspector::StringBuffer>,
) {
let msg = message.unwrap().string().to_string();
println!("send_notification message {}", msg);
self.count_send_notification += 1;
self.notifications.push(msg);
}
fn flush_protocol_notifications(&mut self) {
self.count_flush_protocol_notifications += 1;
}
}
#[test]
fn inspector_can_dispatch_method() {
use v8::inspector::*;
let message = String::from("Runtime.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Debugger.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Profiler.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("HeapProfiler.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Console.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Schema.getDomains");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Foo.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(!V8InspectorSession::can_dispatch_method(string_view));
let message = String::from("Bar.enable");
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
assert!(!V8InspectorSession::can_dispatch_method(string_view));
}
#[test]
fn inspector_dispatch_protocol_message() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
use v8::inspector::*;
let mut default_client = ClientCounter::new();
let mut inspector = V8Inspector::create(isolate, &mut default_client);
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let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let mut _scope = v8::ContextScope::new(scope, context);
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let name = b"";
let name_view = StringView::from(&name[..]);
let aux_data = StringView::from(&name[..]);
inspector.context_created(context, 1, name_view, aux_data);
let mut channel = ChannelCounter::new();
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let state = b"{}";
let state_view = StringView::from(&state[..]);
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let mut session = inspector.connect(
1,
&mut channel,
state_view,
V8InspectorClientTrustLevel::Untrusted,
);
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let message = String::from(
r#"{"id":1,"method":"Network.enable","params":{"maxPostDataSize":65536}}"#,
);
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
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session.dispatch_protocol_message(string_view);
assert_eq!(channel.count_send_response, 1);
assert_eq!(channel.count_send_notification, 0);
assert_eq!(channel.count_flush_protocol_notifications, 0);
inspector.context_destroyed(context);
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}
#[test]
fn inspector_exception_thrown() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
use v8::inspector::*;
let mut default_client = ClientCounter::new();
let mut inspector = V8Inspector::create(isolate, &mut default_client);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let mut context_scope = v8::ContextScope::new(scope, context);
let name = b"";
let name_view = StringView::from(&name[..]);
let aux_data = b"";
let aux_data_view = StringView::from(&aux_data[..]);
inspector.context_created(context, 1, name_view, aux_data_view);
let mut channel = ChannelCounter::new();
let state = b"{}";
let state_view = StringView::from(&state[..]);
let mut session = inspector.connect(
1,
&mut channel,
state_view,
V8InspectorClientTrustLevel::Untrusted,
);
let message = String::from(r#"{"id":1,"method":"Runtime.enable"}"#);
let message = &message.into_bytes()[..];
let string_view = StringView::from(message);
session.dispatch_protocol_message(string_view);
assert_eq!(channel.count_send_response, 1);
assert_eq!(channel.count_send_notification, 1);
assert_eq!(channel.count_flush_protocol_notifications, 0);
let message = "test exception".to_string();
let message = &message.into_bytes()[..];
let message_string_view = StringView::from(message);
let detailed_message = "detailed message".to_string();
let detailed_message = &detailed_message.into_bytes()[..];
let detailed_message_string_view = StringView::from(detailed_message);
let url = "file://exception.js".to_string();
let url = &url.into_bytes()[..];
let url_string_view = StringView::from(url);
let exception_msg =
v8::String::new(&mut context_scope, "This is a test error").unwrap();
let exception = v8::Exception::error(&mut context_scope, exception_msg);
let stack_trace =
v8::Exception::get_stack_trace(&mut context_scope, exception).unwrap();
let stack_trace_ptr = inspector.create_stack_trace(stack_trace);
let _id = inspector.exception_thrown(
context,
message_string_view,
exception,
detailed_message_string_view,
url_string_view,
1,
1,
stack_trace_ptr,
1,
);
assert_eq!(channel.count_send_notification, 2);
let notification = channel.notifications.get(1).unwrap().clone();
let expected_notification = "{\"method\":\"Runtime.exceptionThrown\",\"params\":{\"timestamp\":0,\"exceptionDetails\":{\"exceptionId\":1,\"text\":\"test exception\",\"lineNumber\":0,\"columnNumber\":0,\"scriptId\":\"1\",\"url\":\"file://exception.js\",\"exception\":{\"type\":\"object\",\"subtype\":\"error\",\"className\":\"Error\",\"description\":\"Error: This is a test error\",\"objectId\":\"1.1.1\",\"preview\":{\"type\":\"object\",\"subtype\":\"error\",\"description\":\"Error: This is a test error\",\"overflow\":false,\"properties\":[{\"name\":\"stack\",\"type\":\"string\",\"value\":\"Error: This is a test error\"},{\"name\":\"message\",\"type\":\"string\",\"value\":\"This is a test error\"}]}},\"executionContextId\":1}}}";
assert_eq!(notification, expected_notification);
}
#[test]
fn inspector_schedule_pause_on_next_statement() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
use v8::inspector::*;
let mut client = ClientCounter::new();
let mut inspector = V8Inspector::create(isolate, &mut client);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut channel = ChannelCounter::new();
let state = b"{}";
let state_view = StringView::from(&state[..]);
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let mut session = inspector.connect(
1,
&mut channel,
state_view,
V8InspectorClientTrustLevel::FullyTrusted,
);
let name = b"";
let name_view = StringView::from(&name[..]);
let aux_data = StringView::from(&name[..]);
inspector.context_created(context, 1, name_view, aux_data);
// In order for schedule_pause_on_next_statement to work, it seems you need
// to first enable the debugger.
let message = String::from(r#"{"id":1,"method":"Debugger.enable"}"#);
let message = &message.into_bytes()[..];
let message = StringView::from(message);
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session.dispatch_protocol_message(message);
// The following commented out block seems to act similarly to
// schedule_pause_on_next_statement. I'm not sure if they have the exact same
// effect tho.
// let message = String::from(r#"{"id":2,"method":"Debugger.pause"}"#);
// let message = &message.into_bytes()[..];
// let message = StringView::from(message);
// session.dispatch_protocol_message(&message);
let reason = b"";
let reason = StringView::from(&reason[..]);
let detail = b"";
let detail = StringView::from(&detail[..]);
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session.schedule_pause_on_next_statement(reason, detail);
assert_eq!(channel.count_send_response, 1);
assert_eq!(channel.count_send_notification, 0);
assert_eq!(channel.count_flush_protocol_notifications, 0);
assert_eq!(client.count_run_message_loop_on_pause, 0);
assert_eq!(client.count_quit_message_loop_on_pause, 0);
assert_eq!(client.count_run_if_waiting_for_debugger, 0);
let r = eval(scope, "1+2").unwrap();
assert!(r.is_number());
assert_eq!(channel.count_send_response, 1);
assert_eq!(channel.count_send_notification, 3);
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assert_eq!(channel.count_flush_protocol_notifications, 1);
assert_eq!(client.count_run_message_loop_on_pause, 1);
assert_eq!(client.count_quit_message_loop_on_pause, 0);
assert_eq!(client.count_run_if_waiting_for_debugger, 0);
assert_ne!(client.count_generate_unique_id, 0);
}
#[test]
fn inspector_console_api_message() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
use v8::inspector::*;
struct Client {
base: V8InspectorClientBase,
messages: Vec<String>,
}
impl Client {
fn new() -> Self {
Self {
base: V8InspectorClientBase::new::<Self>(),
messages: Vec::new(),
}
}
}
impl V8InspectorClientImpl for Client {
fn base(&self) -> &V8InspectorClientBase {
&self.base
}
fn base_mut(&mut self) -> &mut V8InspectorClientBase {
&mut self.base
}
unsafe fn base_ptr(
_this: *const Self,
) -> *const v8::inspector::V8InspectorClientBase {
unsafe { addr_of!((*_this).base) }
}
fn console_api_message(
&mut self,
_context_group_id: i32,
_level: i32,
message: &StringView,
_url: &StringView,
_line_number: u32,
_column_number: u32,
_stack_trace: &mut V8StackTrace,
) {
self.messages.push(message.to_string());
}
}
let mut client = Client::new();
let mut inspector = V8Inspector::create(isolate, &mut client);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let name = b"";
let name_view = StringView::from(&name[..]);
let aux_data = b"{\"isDefault\": true}";
let aux_data_view = StringView::from(&aux_data[..]);
inspector.context_created(context, 1, name_view, aux_data_view);
let source = r#"
console.log("one");
console.error("two");
console.trace("three");
"#;
let _ = eval(scope, source).unwrap();
assert_eq!(client.messages, vec!["one", "two", "three"]);
}
#[test]
fn context_from_object_template() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let object_templ = v8::ObjectTemplate::new(scope);
let function_templ = v8::FunctionTemplate::new(scope, fortytwo_callback);
let name = v8::String::new(scope, "f").unwrap();
object_templ.set(name.into(), function_templ.into());
let context = v8::Context::new_from_template(scope, object_templ);
let scope = &mut v8::ContextScope::new(scope, context);
let actual = eval(scope, "f()").unwrap();
let expected = v8::Integer::new(scope, 42);
assert!(expected.strict_equals(actual));
}
}
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#[test]
fn take_heap_snapshot() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
{
class Eyecatcher {}
const eyecatchers = globalThis.eyecatchers = [];
for (let i = 0; i < 1e4; i++) eyecatchers.push(new Eyecatcher);
}
"#;
let _ = eval(scope, source).unwrap();
let mut vec = Vec::<u8>::new();
scope.take_heap_snapshot(|chunk| {
vec.extend_from_slice(chunk);
true
});
let s = std::str::from_utf8(&vec).unwrap();
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assert!(s.contains("Eyecatcher"));
}
}
#[test]
fn get_constructor_name() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
fn check_ctor_name(
scope: &mut v8::HandleScope,
script: &str,
expected_name: &str,
) {
let val = eval(scope, script).unwrap();
let obj: v8::Local<v8::Object> = val.try_into().unwrap();
assert_eq!(
obj.get_constructor_name().to_rust_string_lossy(scope),
expected_name
);
}
let code = r#"
function Parent() {};
function Child() {};
Child.prototype = new Parent();
Child.prototype.constructor = Child;
var outer = { inner: (0, function() { }) };
var p = new Parent();
var c = new Child();
var x = new outer.inner();
var proto = Child.prototype;
"#;
eval(scope, code).unwrap();
check_ctor_name(scope, "p", "Parent");
check_ctor_name(scope, "c", "Child");
check_ctor_name(scope, "x", "outer.inner");
check_ctor_name(scope, "proto", "Parent");
}
#[test]
fn get_property_attributes() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let obj = eval(scope, "({ a: 1 })").unwrap();
let obj = obj.to_object(scope).unwrap();
let key = v8::String::new(scope, "a").unwrap();
let attrs = obj.get_property_attributes(scope, key.into()).unwrap();
assert!(!attrs.is_read_only());
assert!(!attrs.is_dont_enum());
assert!(!attrs.is_dont_delete());
assert!(attrs.is_none());
// doesn't exist
let key = v8::String::new(scope, "b").unwrap();
let attrs = obj.get_property_attributes(scope, key.into()).unwrap();
assert!(attrs.is_none());
// exception
let key = eval(scope, "({ toString() { throw 'foo' } })").unwrap();
let tc = &mut v8::TryCatch::new(scope);
assert!(obj.get_property_attributes(tc, key).is_none());
assert!(tc.has_caught());
}
#[test]
fn get_own_property_descriptor() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let obj = eval(scope, "({ a: 1 })").unwrap();
let obj = obj.to_object(scope).unwrap();
let key = v8::String::new(scope, "a").unwrap();
let desc = obj.get_own_property_descriptor(scope, key.into()).unwrap();
let desc = desc.to_object(scope).unwrap();
let value_key = v8::String::new(scope, "value").unwrap();
let value = desc.get(scope, value_key.into()).unwrap();
assert!(value.is_number());
let writable_key = v8::String::new(scope, "writable").unwrap();
let writable = desc.get(scope, writable_key.into()).unwrap();
assert!(writable.is_boolean());
assert!(writable.boolean_value(scope));
let enumerable_key = v8::String::new(scope, "enumerable").unwrap();
let enumerable = desc.get(scope, enumerable_key.into()).unwrap();
assert!(enumerable.is_boolean());
assert!(enumerable.boolean_value(scope));
let configurable_key = v8::String::new(scope, "configurable").unwrap();
let configurable = desc.get(scope, configurable_key.into()).unwrap();
assert!(configurable.is_boolean());
let get_key = v8::String::new(scope, "get").unwrap();
let get = desc.get(scope, get_key.into()).unwrap();
assert!(get.is_undefined());
let set_key = v8::String::new(scope, "set").unwrap();
let set = desc.get(scope, set_key.into()).unwrap();
assert!(set.is_undefined());
// doesn't exist
let b_key = v8::String::new(scope, "b").unwrap();
let desc = obj
.get_own_property_descriptor(scope, b_key.into())
.unwrap();
assert!(desc.is_undefined());
}
#[test]
fn preview_entries() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let obj = eval(
scope,
"var set = new Set([1,2,3]); set.delete(1); set.keys()",
)
.unwrap();
let obj = obj.to_object(scope).unwrap();
let (preview, is_key_value) = obj.preview_entries(scope);
let preview = preview.unwrap();
assert!(!is_key_value);
assert_eq!(preview.length(), 2);
assert_eq!(
preview
.get_index(scope, 0)
.unwrap()
.number_value(scope)
.unwrap(),
2.0
);
assert_eq!(
preview
.get_index(scope, 1)
.unwrap()
.number_value(scope)
.unwrap(),
3.0
);
}
{
let obj = eval(
scope,
"var set = new Set([1,2,3]); set.delete(2); set.entries()",
)
.unwrap();
let obj = obj.to_object(scope).unwrap();
let (preview, is_key_value) = obj.preview_entries(scope);
let preview = preview.unwrap();
assert!(is_key_value);
assert_eq!(preview.length(), 4);
let first = preview
.get_index(scope, 0)
.unwrap()
.number_value(scope)
.unwrap();
let second = preview
.get_index(scope, 2)
.unwrap()
.number_value(scope)
.unwrap();
assert_eq!(first, 1.0);
assert_eq!(second, 3.0);
assert_eq!(
first,
preview
.get_index(scope, 1)
.unwrap()
.number_value(scope)
.unwrap(),
);
assert_eq!(
second,
preview
.get_index(scope, 3)
.unwrap()
.number_value(scope)
.unwrap(),
);
}
}
#[test]
fn test_prototype_api() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let obj = v8::Object::new(scope);
let proto_obj = v8::Object::new(scope);
let key_local: v8::Local<v8::Value> =
v8::String::new(scope, "test_proto_key").unwrap().into();
let value_local: v8::Local<v8::Value> =
v8::String::new(scope, "test_proto_value").unwrap().into();
proto_obj.set(scope, key_local, value_local);
obj.set_prototype(scope, proto_obj.into());
assert!(obj
.get_prototype(scope)
.unwrap()
.same_value(proto_obj.into()));
let sub_gotten = obj.get(scope, key_local).unwrap();
assert!(sub_gotten.is_string());
assert_eq!(sub_gotten.to_rust_string_lossy(scope), "test_proto_value");
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let obj = v8::Object::new(scope);
let null = v8::null(scope);
obj.set_prototype(scope, null.into());
assert!(obj.get_prototype(scope).unwrap().is_null());
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let val = eval(scope, "({ __proto__: null })").unwrap();
let obj = val.to_object(scope).unwrap();
assert!(obj.get_prototype(scope).unwrap().is_null());
}
}
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#[test]
fn test_map_api() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
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{
let scope = &mut v8::HandleScope::new(isolate);
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let value = eval(scope, "new Map([['r','s'],['v',8]])").unwrap();
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assert!(value.is_map());
assert!(value == v8::Local::<v8::Map>::try_from(value).unwrap());
assert!(value != v8::Object::new(scope));
assert_eq!(v8::Local::<v8::Map>::try_from(value).unwrap().size(), 2);
let map = v8::Local::<v8::Map>::try_from(value).unwrap();
assert_eq!(map.size(), 2);
let map_array = map.as_array(scope);
assert_eq!(map_array.length(), 4);
assert!(
map_array.get_index(scope, 0).unwrap()
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== v8::String::new(scope, "r").unwrap()
);
assert!(
map_array.get_index(scope, 1).unwrap()
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== v8::String::new(scope, "s").unwrap()
);
assert!(
map_array.get_index(scope, 2).unwrap()
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== v8::String::new(scope, "v").unwrap()
);
assert!(
map_array.get_index(scope, 3).unwrap() == v8::Number::new(scope, 8f64)
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);
}
}
#[test]
fn test_object_get_property_names() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let js_test_str: v8::Local<v8::Value> =
v8::String::new(scope, "test").unwrap().into();
let js_proto_test_str: v8::Local<v8::Value> =
v8::String::new(scope, "proto_test").unwrap().into();
let js_test_symbol: v8::Local<v8::Value> =
eval(scope, "Symbol('test_symbol')").unwrap();
let js_null: v8::Local<v8::Value> = v8::null(scope).into();
let js_sort_fn: v8::Local<v8::Function> = eval(scope, "Array.prototype.sort")
.unwrap()
.try_into()
.unwrap();
{
let obj = v8::Object::new(scope);
obj.set(scope, js_test_str, js_null);
let proto_obj = v8::Object::new(scope);
proto_obj.set(scope, js_proto_test_str, js_null);
obj.set_prototype(scope, proto_obj.into());
let own_props = obj
.get_own_property_names(scope, Default::default())
.unwrap();
assert_eq!(own_props.length(), 1);
assert!(own_props.get_index(scope, 0).unwrap() == js_test_str);
let proto_props = proto_obj
.get_own_property_names(scope, Default::default())
.unwrap();
assert_eq!(proto_props.length(), 1);
assert!(proto_props.get_index(scope, 0).unwrap() == js_proto_test_str);
let all_props = obj.get_property_names(scope, Default::default()).unwrap();
js_sort_fn.call(scope, all_props.into(), &[]).unwrap();
assert_eq!(all_props.length(), 2);
assert!(all_props.get_index(scope, 0).unwrap() == js_proto_test_str);
assert!(all_props.get_index(scope, 1).unwrap() == js_test_str);
}
{
let obj = v8::Object::new(scope);
obj.set(scope, js_test_str, js_null);
obj.set(scope, js_test_symbol, js_null);
let own_props = obj
.get_own_property_names(scope, Default::default())
.unwrap();
assert_eq!(own_props.length(), 1);
assert!(own_props.get_index(scope, 0).unwrap() == js_test_str);
}
{
let obj = v8::Object::new(scope);
obj.set(scope, js_test_str, js_null);
obj.set(scope, js_test_symbol, js_null);
let own_props = obj
.get_property_names(
scope,
v8::GetPropertyNamesArgs {
mode: v8::KeyCollectionMode::IncludePrototypes,
property_filter: v8::PropertyFilter::ONLY_ENUMERABLE
| v8::PropertyFilter::SKIP_SYMBOLS,
index_filter: v8::IndexFilter::IncludeIndices,
key_conversion: v8::KeyConversionMode::KeepNumbers,
},
)
.unwrap();
assert_eq!(own_props.length(), 1);
assert!(own_props.get_index(scope, 0).unwrap() == js_test_str);
}
{
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let val = eval(scope, "({ 'a': 3, 2: 'b', '7': 'c' })").unwrap();
let obj = val.to_object(scope).unwrap();
{
let own_props = obj
.get_own_property_names(scope, Default::default())
.unwrap();
assert_eq!(own_props.length(), 3);
assert!(own_props.get_index(scope, 0).unwrap().is_number());
assert_eq!(
own_props.get_index(scope, 0).unwrap(),
v8::Integer::new(scope, 2)
);
assert!(own_props.get_index(scope, 1).unwrap().is_number());
assert_eq!(
own_props.get_index(scope, 1).unwrap(),
v8::Integer::new(scope, 7)
);
assert!(own_props.get_index(scope, 2).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 2).unwrap(),
v8::String::new(scope, "a").unwrap()
);
}
{
let own_props = obj
.get_own_property_names(
scope,
v8::GetPropertyNamesArgsBuilder::new()
.key_conversion(v8::KeyConversionMode::ConvertToString)
.build(),
)
.unwrap();
assert_eq!(own_props.length(), 3);
assert!(own_props.get_index(scope, 0).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 0).unwrap(),
v8::String::new(scope, "2").unwrap()
);
assert!(own_props.get_index(scope, 1).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 1).unwrap(),
v8::String::new(scope, "7").unwrap()
);
assert!(own_props.get_index(scope, 2).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 2).unwrap(),
v8::String::new(scope, "a").unwrap()
);
}
{
let own_props = obj
.get_property_names(
scope,
v8::GetPropertyNamesArgsBuilder::new()
.key_conversion(v8::KeyConversionMode::ConvertToString)
.build(),
)
.unwrap();
assert_eq!(own_props.length(), 3);
assert!(own_props.get_index(scope, 0).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 0).unwrap(),
v8::String::new(scope, "2").unwrap()
);
assert!(own_props.get_index(scope, 1).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 1).unwrap(),
v8::String::new(scope, "7").unwrap()
);
assert!(own_props.get_index(scope, 2).unwrap().is_string());
assert_eq!(
own_props.get_index(scope, 2).unwrap(),
v8::String::new(scope, "a").unwrap()
);
}
}
}
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#[test]
fn module_snapshot() {
let _setup_guard = setup::sequential_test();
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let startup_data = {
let mut snapshot_creator = v8::Isolate::snapshot_creator(None);
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{
let scope = &mut v8::HandleScope::new(&mut snapshot_creator);
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let source_text = v8::String::new(
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scope,
"import 'globalThis.b = 42';\n\
globalThis.a = 3",
)
.unwrap();
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let origin = mock_script_origin(scope, "foo.js");
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let source = v8::script_compiler::Source::new(source_text, Some(&origin));
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let module = v8::script_compiler::compile_module(scope, source).unwrap();
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assert_eq!(v8::ModuleStatus::Uninstantiated, module.get_status());
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let script_id = module.script_id();
assert!(script_id.is_some());
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let result = module.instantiate_module(
scope,
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compile_specifier_as_module_resolve_callback,
);
assert!(result.unwrap());
assert_eq!(v8::ModuleStatus::Instantiated, module.get_status());
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assert_eq!(script_id, module.script_id());
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let result = module.evaluate(scope);
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assert!(result.is_some());
assert_eq!(v8::ModuleStatus::Evaluated, module.get_status());
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assert_eq!(script_id, module.script_id());
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scope.set_default_context(context);
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}
snapshot_creator
.create_blob(v8::FunctionCodeHandling::Keep)
.unwrap()
};
assert!(startup_data.len() > 0);
{
let params = v8::Isolate::create_params().snapshot_blob(startup_data);
let isolate = &mut v8::Isolate::new(params);
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{
let scope = &mut v8::HandleScope::new(isolate);
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let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let true_val = v8::Boolean::new(scope, true).into();
let result = eval(scope, "a === 3").unwrap();
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assert!(result.same_value(true_val));
let result = eval(scope, "b === 42").unwrap();
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assert!(result.same_value(true_val));
}
}
}
#[derive(Default)]
struct TestHeapLimitState {
near_heap_limit_callback_calls: u64,
}
extern "C" fn heap_limit_callback(
data: *mut c_void,
current_heap_limit: usize,
_initial_heap_limit: usize,
) -> usize {
let state = unsafe { &mut *(data as *mut TestHeapLimitState) };
state.near_heap_limit_callback_calls += 1;
current_heap_limit * 2 // Avoid V8 OOM.
}
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// This test might fail due to a bug in V8. The upstream bug report is at
// https://bugs.chromium.org/p/v8/issues/detail?id=10843.
#[test]
fn heap_limits() {
let _setup_guard = setup::parallel_test();
let params = v8::CreateParams::default().heap_limits(0, 10 << 20); // 10 MB.
let isolate = &mut v8::Isolate::new(params);
let mut test_state = TestHeapLimitState::default();
let state_ptr = &mut test_state as *mut _ as *mut c_void;
isolate.add_near_heap_limit_callback(heap_limit_callback, state_ptr);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Allocate JavaScript arrays until V8 calls the near-heap-limit callback.
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// It takes about 50-200k iterations of this loop to get to that point.
for _ in 0..1_000_000 {
eval(
scope,
r#"
"hello 🦕 world"
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.repeat(10)
.split("🦕")
.map((s) => s.repeat(100).split("o"))
"#,
)
.unwrap();
if test_state.near_heap_limit_callback_calls > 0 {
break;
}
}
assert_eq!(1, test_state.near_heap_limit_callback_calls);
}
#[test]
fn heap_statistics() {
let _setup_guard = setup::parallel_test();
let params = v8::CreateParams::default().heap_limits(0, 10 << 20); // 10 MB.
let isolate = &mut v8::Isolate::new(params);
let mut s = v8::HeapStatistics::default();
isolate.get_heap_statistics(&mut s);
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assert!(s.used_heap_size() > 0);
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assert!(s.total_heap_size() > 0);
assert!(s.total_heap_size() >= s.used_heap_size());
assert!(s.heap_size_limit() > 0);
assert!(s.heap_size_limit() >= s.total_heap_size());
assert!(s.malloced_memory() > 0);
assert!(s.peak_malloced_memory() > 0);
// This invariant broke somewhere between V8 versions 8.6.337 and 8.7.25.
// TODO(piscisaureus): re-enable this assertion when the underlying V8 bug is
// fixed.
// assert!(s.peak_malloced_memory() >= s.malloced_memory());
assert_eq!(s.used_global_handles_size(), 0);
assert_eq!(s.total_global_handles_size(), 0);
assert_eq!(s.number_of_native_contexts(), 0);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let local = eval(scope, "").unwrap();
let _global = v8::Global::new(scope, local);
scope.get_heap_statistics(&mut s);
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assert_ne!(s.used_global_handles_size(), 0);
assert_ne!(s.total_global_handles_size(), 0);
assert_ne!(s.number_of_native_contexts(), 0);
}
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#[test]
fn low_memory_notification() {
let mut isolate = v8::Isolate::new(Default::default());
isolate.low_memory_notification();
}
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// Clippy thinks the return value doesn't need to be an Option, it's unaware
// of the mapping that MapFnFrom<F> does for ResolveModuleCallback.
#[allow(clippy::unnecessary_wraps)]
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fn synthetic_evaluation_steps<'a>(
context: v8::Local<'a, v8::Context>,
module: v8::Local<v8::Module>,
) -> Option<v8::Local<'a, v8::Value>> {
let scope = &mut unsafe { v8::CallbackScope::new(context) };
let mut set = |name, value| {
let name = v8::String::new(scope, name).unwrap();
let value = v8::Number::new(scope, value).into();
module
.set_synthetic_module_export(scope, name, value)
.unwrap();
};
set("a", 1.0);
set("b", 2.0);
{
let scope = &mut v8::TryCatch::new(scope);
let name = v8::String::new(scope, "does not exist").unwrap();
let value = v8::undefined(scope).into();
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assert!(module
.set_synthetic_module_export(scope, name, value)
.is_none());
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assert!(scope.has_caught());
scope.reset();
}
Some(v8::undefined(scope).into())
}
#[test]
fn synthetic_module() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let export_names = [
v8::String::new(scope, "a").unwrap(),
v8::String::new(scope, "b").unwrap(),
];
let module_name = v8::String::new(scope, "synthetic module").unwrap();
let module = v8::Module::create_synthetic_module(
scope,
module_name,
&export_names,
synthetic_evaluation_steps,
);
assert!(!module.is_source_text_module());
assert!(module.is_synthetic_module());
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assert!(module.script_id().is_none());
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assert_eq!(module.get_status(), v8::ModuleStatus::Uninstantiated);
module
.instantiate_module(scope, unexpected_module_resolve_callback)
.unwrap();
assert_eq!(module.get_status(), v8::ModuleStatus::Instantiated);
module.evaluate(scope).unwrap();
assert_eq!(module.get_status(), v8::ModuleStatus::Evaluated);
let ns =
v8::Local::<v8::Object>::try_from(module.get_module_namespace()).unwrap();
let mut check = |name, value| {
let name = v8::String::new(scope, name).unwrap().into();
let value = v8::Number::new(scope, value).into();
assert!(ns.get(scope, name).unwrap().strict_equals(value));
};
check("a", 1.0);
check("b", 2.0);
}
#[allow(clippy::float_cmp)]
#[test]
fn date() {
let time = 1_291_404_900_000.; // 2010-12-03 20:35:00 - Mees <3
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let date = v8::Date::new(scope, time).unwrap();
assert_eq!(date.value_of(), time);
let key = v8::String::new(scope, "d").unwrap();
context.global(scope).set(scope, key.into(), date.into());
let result = eval(scope, "d.toISOString()").unwrap();
let result = result.to_string(scope).unwrap();
let result = result.to_rust_string_lossy(scope);
assert_eq!(result, "2010-12-03T19:35:00.000Z");
// V8 chops off fractions.
let date = v8::Date::new(scope, std::f64::consts::PI).unwrap();
assert_eq!(date.value_of(), 3.0);
assert_eq!(date.number_value(scope).unwrap(), 3.0);
}
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#[test]
fn symbol() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let desc = v8::String::new(scope, "a description").unwrap();
let s = v8::Symbol::new(scope, None);
assert!(s.description(scope) == v8::undefined(scope));
let s = v8::Symbol::new(scope, Some(desc));
assert!(s.description(scope) == desc);
let s_pub = v8::Symbol::for_key(scope, desc);
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assert!(s_pub.description(scope) == desc);
assert!(s_pub != s);
let s_pub2 = v8::Symbol::for_key(scope, desc);
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assert!(s_pub2 != s);
assert!(s_pub == s_pub2);
let s_api = v8::Symbol::for_api(scope, desc);
assert!(s_api.description(scope) == desc);
assert!(s_api != s);
assert!(s_api != s_pub);
let s_api2 = v8::Symbol::for_api(scope, desc);
assert!(s_api2 != s);
assert!(s_api2 != s_pub);
assert!(s_api == s_api2);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
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let s = eval(scope, "Symbol.asyncIterator").unwrap();
assert!(s == v8::Symbol::get_async_iterator(scope));
}
#[test]
fn private() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let p = v8::Private::new(scope, None);
assert!(p.name(scope) == v8::undefined(scope));
let name = v8::String::new(scope, "a name").unwrap();
let p = v8::Private::new(scope, Some(name));
assert!(p.name(scope) == name);
let p_api = v8::Private::for_api(scope, Some(name));
assert!(p_api.name(scope) == name);
assert!(p_api != p);
let p_api2 = v8::Private::for_api(scope, Some(name));
assert!(p_api2 != p);
assert!(p_api == p_api2);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object = v8::Object::new(scope);
let sentinel = v8::Object::new(scope).into();
assert!(!object.has_private(scope, p).unwrap());
assert!(object.get_private(scope, p).unwrap().is_undefined());
// True indicates that the operation didn't throw an
// exception, not that it found and deleted a key.
assert!(object.delete_private(scope, p).unwrap());
assert!(object.set_private(scope, p, sentinel).unwrap());
assert!(object.has_private(scope, p).unwrap());
assert!(object
.get_private(scope, p)
.unwrap()
.strict_equals(sentinel));
assert!(object.delete_private(scope, p).unwrap());
assert!(!object.has_private(scope, p).unwrap());
assert!(object.get_private(scope, p).unwrap().is_undefined());
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}
#[test]
fn bigint() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let b = v8::BigInt::new_from_u64(scope, 1337);
assert_eq!(b.u64_value(), (1337, true));
let b = v8::BigInt::new_from_i64(scope, -1337);
assert_eq!(b.i64_value(), (-1337, true));
let words = vec![10, 10];
let b = v8::BigInt::new_from_words(scope, false, &words).unwrap();
assert_eq!(b.i64_value(), (10, false));
let raw_b = eval(scope, "184467440737095516170n").unwrap();
assert!(b == raw_b);
let b = v8::BigInt::new_from_words(scope, true, &words).unwrap();
assert_eq!(b.i64_value(), (-10, false));
let raw_b = eval(scope, "-184467440737095516170n").unwrap();
assert!(b == raw_b);
let raw_b = v8::Local::<v8::BigInt>::try_from(raw_b).unwrap();
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let mut vec = vec![0; raw_b.word_count()];
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assert_eq!(raw_b.to_words_array(&mut vec), (true, &mut [10, 10][..]));
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let mut vec = vec![0; 1];
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assert_eq!(raw_b.to_words_array(&mut vec), (true, &mut [10][..]));
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let mut vec = vec![1337, 20];
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assert_eq!(raw_b.to_words_array(&mut vec), (true, &mut [10, 10][..]));
}
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// SerDes testing
type ArrayBuffers = Vec<v8::SharedRef<v8::BackingStore>>;
struct Custom1Value<'a> {
array_buffers: &'a mut ArrayBuffers,
}
impl<'a> Custom1Value<'a> {
fn serializer<'s>(
scope: &mut v8::HandleScope<'s>,
array_buffers: &'a mut ArrayBuffers,
) -> v8::ValueSerializer<'a, 's> {
v8::ValueSerializer::new(scope, Box::new(Self { array_buffers }))
}
fn deserializer<'s>(
scope: &mut v8::HandleScope<'s>,
data: &[u8],
array_buffers: &'a mut ArrayBuffers,
) -> v8::ValueDeserializer<'a, 's> {
v8::ValueDeserializer::new(scope, Box::new(Self { array_buffers }), data)
}
}
impl<'a> v8::ValueSerializerImpl for Custom1Value<'a> {
#[allow(unused_variables)]
fn throw_data_clone_error<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
message: v8::Local<'s, v8::String>,
) {
let error = v8::Exception::error(scope, message);
scope.throw_exception(error);
}
#[allow(unused_variables)]
fn get_shared_array_buffer_id<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
shared_array_buffer: v8::Local<'s, v8::SharedArrayBuffer>,
) -> Option<u32> {
self
.array_buffers
.push(v8::SharedArrayBuffer::get_backing_store(
&shared_array_buffer,
));
Some((self.array_buffers.len() as u32) - 1)
}
fn write_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
object: v8::Local<'s, v8::Object>,
value_serializer: &mut dyn v8::ValueSerializerHelper,
) -> Option<bool> {
let key = v8::String::new(scope, "hostObject").unwrap();
let value = object
.get(scope, key.into())
.unwrap()
.uint32_value(scope)
.unwrap();
value_serializer.write_uint32(value);
Some(true)
}
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}
impl<'a> v8::ValueDeserializerImpl for Custom1Value<'a> {
#[allow(unused_variables)]
fn get_shared_array_buffer_from_id<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
transfer_id: u32,
) -> Option<v8::Local<'s, v8::SharedArrayBuffer>> {
let backing_store = self.array_buffers.get(transfer_id as usize).unwrap();
Some(v8::SharedArrayBuffer::with_backing_store(
scope,
backing_store,
))
}
fn read_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
value_deserializer: &mut dyn v8::ValueDeserializerHelper,
) -> Option<v8::Local<'s, v8::Object>> {
let mut value = 0;
value_deserializer.read_uint32(&mut value);
let template = v8::ObjectTemplate::new(scope);
template.set_internal_field_count(1);
let host_object = template.new_instance(scope).unwrap();
let key = v8::String::new(scope, "readHostObject").unwrap();
let value = v8::Integer::new_from_unsigned(scope, value);
host_object.set(scope, key.into(), value.into());
Some(host_object)
}
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}
#[test]
fn value_serializer_and_deserializer() {
use v8::ValueDeserializerHelper;
use v8::ValueSerializerHelper;
let _setup_guard = setup::parallel_test();
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let mut array_buffers = ArrayBuffers::new();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let buffer;
{
let mut value_serializer =
Custom1Value::serializer(scope, &mut array_buffers);
value_serializer.write_header();
value_serializer.write_double(55.44);
value_serializer.write_uint32(22);
buffer = value_serializer.release();
}
let mut double: f64 = 0.0;
let mut int32: u32 = 0;
{
let mut value_deserializer =
Custom1Value::deserializer(scope, &buffer, &mut array_buffers);
assert_eq!(value_deserializer.read_header(context), Some(true));
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assert!(value_deserializer.read_double(&mut double));
assert!(value_deserializer.read_uint32(&mut int32));
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assert!(!value_deserializer.read_uint32(&mut int32));
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}
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assert!((double - 55.44).abs() < f64::EPSILON);
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assert_eq!(int32, 22);
}
#[test]
fn value_serializer_and_deserializer_js_objects() {
use v8::ValueDeserializerHelper;
use v8::ValueSerializerHelper;
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let buffer;
let mut array_buffers = ArrayBuffers::new();
{
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let objects: v8::Local<v8::Value> = eval(
scope,
r#"[
undefined,
true,
false,
null,
33,
44.444,
99999.55434344,
"test",
new String("test"),
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[1, 2, 3],
{a: "tt", add: "tsqqqss"}
]"#,
)
.unwrap();
let mut value_serializer =
Custom1Value::serializer(scope, &mut array_buffers);
value_serializer.write_header();
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assert_eq!(value_serializer.write_value(context, objects), Some(true));
buffer = value_serializer.release();
}
{
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut value_deserializer =
Custom1Value::deserializer(scope, &buffer, &mut array_buffers);
assert_eq!(value_deserializer.read_header(context), Some(true));
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let name = v8::String::new(scope, "objects").unwrap();
let objects: v8::Local<v8::Value> =
value_deserializer.read_value(context).unwrap();
drop(value_deserializer);
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context.global(scope).set(scope, name.into(), objects);
let result: v8::Local<v8::Value> = eval(
scope,
r#"
{
const compare = [
undefined,
true,
false,
null,
33,
44.444,
99999.55434344,
"test",
new String("test"),
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[1, 2, 3],
{a: "tt", add: "tsqqqss"}
];
let equal = true;
function obj_isEquivalent(a, b) {
if (a == null) return b == null;
let aProps = Object.getOwnPropertyNames(a);
let bProps = Object.getOwnPropertyNames(b);
if (aProps.length != bProps.length) return false;
for (let i = 0; i < aProps.length; i++) {
let propName = aProps[i];
if (a[propName] !== b[propName]) return false;
}
return true;
}
function arr_isEquivalent(a, b) {
if (a.length != b.length) return false;
for (let i = 0; i < Math.max(a.length, b.length); i++) {
if (a[i] !== b[i]) return false;
}
return true;
}
objects.forEach(function (item, index) {
let other = compare[index];
if (Array.isArray(item)) {
equal = equal && arr_isEquivalent(item, other);
} else if (typeof item == 'object') {
equal = equal && obj_isEquivalent(item, other);
} else {
equal = equal && (item == objects[index]);
}
});
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equal.toString()
}
"#,
)
.unwrap();
let expected = v8::String::new(scope, "true").unwrap();
assert!(expected.strict_equals(result));
}
}
#[test]
fn value_serializer_and_deserializer_array_buffers() {
let buffer;
let mut array_buffers = ArrayBuffers::new();
{
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let objects: v8::Local<v8::Value> = eval(
scope,
r#"{
var sab = new SharedArrayBuffer(10);
var arr = new Int8Array(sab);
arr[3] = 4;
sab
}"#,
)
.unwrap();
let mut value_serializer =
Custom1Value::serializer(scope, &mut array_buffers);
assert_eq!(value_serializer.write_value(context, objects), Some(true));
buffer = value_serializer.release();
}
{
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut value_deserializer =
Custom1Value::deserializer(scope, &buffer, &mut array_buffers);
let name = v8::String::new(scope, "objects").unwrap();
let objects: v8::Local<v8::Value> =
value_deserializer.read_value(context).unwrap();
drop(value_deserializer);
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context.global(scope).set(scope, name.into(), objects);
let result: v8::Local<v8::Value> = eval(
scope,
r#"
{
var arr = new Int8Array(objects);
arr.toString()
}
"#,
)
.unwrap();
let expected = v8::String::new(scope, "0,0,0,4,0,0,0,0,0,0").unwrap();
assert!(expected.strict_equals(result));
}
}
#[test]
fn value_serializer_and_deserializer_embedder_host_object() {
let buffer;
let expected: u32 = 123;
let mut array_buffers = ArrayBuffers::new();
{
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let template = v8::ObjectTemplate::new(scope);
template.set_internal_field_count(1);
let host_object = template.new_instance(scope).unwrap();
let key = v8::String::new(scope, "hostObject").unwrap();
let value = v8::Integer::new_from_unsigned(scope, expected);
host_object.set(scope, key.into(), value.into());
let mut value_serializer =
Custom1Value::serializer(scope, &mut array_buffers);
assert_eq!(
value_serializer.write_value(context, host_object.into()),
Some(true)
);
buffer = value_serializer.release();
}
{
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut value_deserializer =
Custom1Value::deserializer(scope, &buffer, &mut array_buffers);
let host_object_out = value_deserializer
.read_value(context)
.unwrap()
.to_object(scope)
.unwrap();
drop(value_deserializer);
let key = v8::String::new(scope, "readHostObject").unwrap();
let value = host_object_out
.get(scope, key.into())
.unwrap()
.uint32_value(scope)
.unwrap();
assert_eq!(value, expected);
}
}
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struct Custom2Value {}
impl<'a> Custom2Value {
fn serializer<'s>(
scope: &mut v8::HandleScope<'s>,
) -> v8::ValueSerializer<'a, 's> {
v8::ValueSerializer::new(scope, Box::new(Self {}))
}
}
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impl v8::ValueSerializerImpl for Custom2Value {
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#[allow(unused_variables)]
fn throw_data_clone_error<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
message: v8::Local<'s, v8::String>,
) {
Upgrade to V8 12.1.285.6 (#1374) 1. [[exceptions] Unify pending and scheduled exceptions](https://chromium-review.googlesource.com/c/v8/v8/+/5050065) Reset no longer clears exception if it was rethrown. The test had to be adjusted for the same. 2. [[api] Allow passing CppHeap on Isolate creation](https://chromium-review.googlesource.com/c/v8/v8/+/4989254) `AttachCppHeap` was deprecated but the alternative of passing `CppHeap` via Isolate CreateParams hard crashes (SIGSEGV). There are no tests for this in V8 and it seems the [Chromium CL](https://chromium-review.googlesource.com/c/chromium/src/+/4992764) is also crashing. For now I've just suppressed the deprecation warning until the crash is fixed in V8. 3. v8::Serializer impl must not throw more than one exception. I changed `get_shared_buffer_id()` to not throw and return `None`. V8 internally calls data clone error when it's the SAB is not clonable. Other changes: - `v8::ScriptCompiler` size increased by 3 words with `v8::ScriptCompiler::CompilationDetails`. - `v8::ObjectTemplate::SetAccessor` & `v8::ObjectTemplate::SetAccessorProperty` signature changed and also deprecated. - `v8::Context::SetContinuationPreservedEmbedderData` deprecated. Use `v8::Isolate::GetContinuationPreservedEmbedderData` instead. - `GetStalledTopLevelAwaitMessage` deprecated. Use `GetStalledTopLevelAwaitMessages` instead. - `v8::Isolate::AttachCppHeap` deprecated. Set the heap on Isolate creation using CreateParams instead. - `v8::ScriptOrigin` deprecated. Use constructor without the isolate. - `v8::SnapshotCreator` is deprecated. Use the version that passes CreateParams instead. - `v8::Isolate` assertion failures. Co-authored-by: Bartek Iwańczuk <biwanczuk@gmail.com>
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let scope = &mut v8::TryCatch::new(scope);
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let error = v8::Exception::error(scope, message);
scope.throw_exception(error);
}
}
#[test]
fn value_serializer_not_implemented() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let scope = &mut v8::TryCatch::new(scope);
let objects: v8::Local<v8::Value> = eval(
scope,
r#"{
var sab = new SharedArrayBuffer(10);
var arr = new Int8Array(sab);
arr[3] = 4;
sab
}"#,
)
.unwrap();
let mut value_serializer = Custom2Value::serializer(scope);
assert_eq!(value_serializer.write_value(context, objects), None);
assert!(scope.exception().is_some());
assert!(scope.stack_trace().is_some());
assert!(scope.message().is_some());
assert_eq!(
scope
.message()
.unwrap()
.get(scope)
.to_rust_string_lossy(scope),
"Uncaught Error: #<SharedArrayBuffer> could not be cloned."
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);
}
struct Custom3Value {}
impl<'a> Custom3Value {
fn serializer<'s>(
scope: &mut v8::HandleScope<'s>,
) -> v8::ValueSerializer<'a, 's> {
v8::ValueSerializer::new(scope, Box::new(Self {}))
}
fn deserializer<'s>(
scope: &mut v8::HandleScope<'s>,
data: &[u8],
) -> v8::ValueDeserializer<'a, 's> {
v8::ValueDeserializer::new(scope, Box::new(Self {}), data)
}
}
impl v8::ValueSerializerImpl for Custom3Value {
#[allow(unused_variables)]
fn throw_data_clone_error<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
message: v8::Local<'s, v8::String>,
) {
let error = v8::Exception::error(scope, message);
scope.throw_exception(error);
}
fn has_custom_host_object(&mut self, _isolate: &mut v8::Isolate) -> bool {
true
}
fn is_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
object: v8::Local<'s, v8::Object>,
) -> Option<bool> {
let key = v8::String::new(scope, "hostObject").unwrap();
object.has_own_property(scope, key.into())
}
fn write_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
object: v8::Local<'s, v8::Object>,
value_serializer: &mut dyn v8::ValueSerializerHelper,
) -> Option<bool> {
let key = v8::String::new(scope, "hostObject").unwrap();
let value = object
.get(scope, key.into())
.unwrap()
.uint32_value(scope)
.unwrap();
value_serializer.write_uint32(value);
Some(true)
}
}
impl v8::ValueDeserializerImpl for Custom3Value {
fn read_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
value_deserializer: &mut dyn v8::ValueDeserializerHelper,
) -> Option<v8::Local<'s, v8::Object>> {
let mut value = 0;
value_deserializer.read_uint32(&mut value);
let host_object = v8::Object::new(scope);
let key = v8::String::new(scope, "readHostObject").unwrap();
let value = v8::Integer::new_from_unsigned(scope, value);
host_object.set(scope, key.into(), value.into());
Some(host_object)
}
}
#[test]
fn value_serializer_and_deserializer_custom_host_object() {
let buffer;
let expected: u32 = 123;
{
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let host_object = v8::Object::new(scope);
let key = v8::String::new(scope, "hostObject").unwrap();
let value = v8::Integer::new_from_unsigned(scope, expected);
host_object.set(scope, key.into(), value.into());
let mut value_serializer = Custom3Value::serializer(scope);
assert_eq!(
value_serializer.write_value(context, host_object.into()),
Some(true)
);
buffer = value_serializer.release();
}
{
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut value_deserializer = Custom3Value::deserializer(scope, &buffer);
let host_object_out = value_deserializer
.read_value(context)
.unwrap()
.to_object(scope)
.unwrap();
drop(value_deserializer);
let key = v8::String::new(scope, "readHostObject").unwrap();
let has_prop = host_object_out.has_own_property(scope, key.into()).unwrap();
assert!(has_prop);
let value = host_object_out
.get(scope, key.into())
.unwrap()
.uint32_value(scope)
.unwrap();
assert_eq!(value, expected);
}
}
#[test]
fn memory_pressure_notification() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.memory_pressure_notification(v8::MemoryPressureLevel::Moderate);
isolate.memory_pressure_notification(v8::MemoryPressureLevel::Critical);
isolate.memory_pressure_notification(v8::MemoryPressureLevel::None);
}
// Flaky on aarch64-qemu (Stack corruption).
#[cfg(not(target_os = "android"))]
#[test]
fn clear_kept_objects() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_microtasks_policy(v8::MicrotasksPolicy::Explicit);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let step1 = r#"
var weakrefs = [];
for (let i = 0; i < 424242; i++) weakrefs.push(new WeakRef({ i }));
"#;
let step2 = r#"
if (weakrefs.some(w => !w.deref())) throw "fail";
"#;
let step3 = r#"
if (weakrefs.every(w => w.deref())) throw "fail";
"#;
eval(scope, step1).unwrap();
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
eval(scope, step2).unwrap();
scope.clear_kept_objects();
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
eval(scope, step3).unwrap();
}
#[test]
fn wasm_streaming_callback() {
thread_local! {
static WS: RefCell<Option<v8::WasmStreaming>> = RefCell::new(None);
}
let callback = |scope: &mut v8::HandleScope,
url: v8::Local<v8::Value>,
ws: v8::WasmStreaming| {
assert_eq!("https://example.com", url.to_rust_string_lossy(scope));
WS.with(|slot| assert!(slot.borrow_mut().replace(ws).is_none()));
};
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(v8::CreateParams::default());
isolate.set_wasm_streaming_callback(callback);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let script = r#"
globalThis.result = null;
WebAssembly
.compileStreaming("https://example.com")
.then(result => globalThis.result = result);
"#;
eval(scope, script).unwrap();
assert!(scope.has_pending_background_tasks());
let global = context.global(scope);
let name = v8::String::new(scope, "result").unwrap().into();
assert!(global.get(scope, name).unwrap().is_null());
let mut ws = WS.with(|slot| slot.borrow_mut().take().unwrap());
assert!(global.get(scope, name).unwrap().is_null());
// MVP of WASM modules: contains only the magic marker and the version (1).
ws.on_bytes_received(&[0x00, 0x61, 0x73, 0x6d, 0x01, 0x00, 0x00, 0x00]);
assert!(global.get(scope, name).unwrap().is_null());
ws.set_url("https://example2.com");
assert!(global.get(scope, name).unwrap().is_null());
ws.finish();
assert!(!scope.has_pending_background_tasks());
let result = global.get(scope, name).unwrap();
assert!(result.is_wasm_module_object());
let wasm_module_object: v8::Local<v8::WasmModuleObject> =
result.try_into().unwrap();
let compiled_wasm_module = wasm_module_object.get_compiled_module();
assert_eq!(compiled_wasm_module.source_url(), "https://example2.com");
let script = r#"
globalThis.result = null;
WebAssembly
.compileStreaming("https://example.com")
.catch(result => globalThis.result = result);
"#;
eval(scope, script).unwrap();
let ws = WS.with(|slot| slot.borrow_mut().take().unwrap());
assert!(global.get(scope, name).unwrap().is_null());
let exception = v8::Object::new(scope).into(); // Can be anything.
ws.abort(Some(exception));
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// We did not set wasm resolve callback so V8 uses the default one that
// runs microtasks automatically.
while v8::Platform::pump_message_loop(
&v8::V8::get_current_platform(),
scope,
false, // don't block if there are no tasks
) {}
assert!(global.get(scope, name).unwrap().strict_equals(exception));
}
#[test]
fn unbound_script_conversion() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let unbound_script = {
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(scope, "'Hello ' + value").unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
script.get_unbound_script(scope)
};
{
// Execute the script in another context.
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global_object = scope.get_current_context().global(scope);
let key = v8::String::new(scope, "value").unwrap();
let value = v8::String::new(scope, "world").unwrap();
global_object.set(scope, key.into(), value.into());
let script = unbound_script.bind_to_current_context(scope);
let result = script.run(scope).unwrap();
assert_eq!(result.to_rust_string_lossy(scope), "Hello world");
}
}
#[test]
fn run_with_rust_allocator() {
use std::sync::Arc;
unsafe extern "C" fn allocate(count: &AtomicUsize, n: usize) -> *mut c_void {
count.fetch_add(n, Ordering::SeqCst);
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Box::into_raw(vec![0u8; n].into_boxed_slice()) as *mut c_void
}
unsafe extern "C" fn allocate_uninitialized(
count: &AtomicUsize,
n: usize,
) -> *mut c_void {
count.fetch_add(n, Ordering::SeqCst);
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let mut store: Vec<MaybeUninit<u8>> = Vec::with_capacity(n);
store.set_len(n);
Box::into_raw(store.into_boxed_slice()) as *mut [u8] as *mut c_void
}
unsafe extern "C" fn free(count: &AtomicUsize, data: *mut c_void, n: usize) {
count.fetch_sub(n, Ordering::SeqCst);
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let _ = Box::from_raw(std::slice::from_raw_parts_mut(data as *mut u8, n));
}
unsafe extern "C" fn reallocate(
count: &AtomicUsize,
prev: *mut c_void,
oldlen: usize,
newlen: usize,
) -> *mut c_void {
count.fetch_add(newlen.wrapping_sub(oldlen), Ordering::SeqCst);
let old_store =
Box::from_raw(std::slice::from_raw_parts_mut(prev as *mut u8, oldlen));
let mut new_store = Vec::with_capacity(newlen);
let copy_len = oldlen.min(newlen);
new_store.extend_from_slice(&old_store[..copy_len]);
new_store.resize(newlen, 0u8);
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Box::into_raw(new_store.into_boxed_slice()) as *mut c_void
}
unsafe extern "C" fn drop(count: *const AtomicUsize) {
Arc::from_raw(count);
}
let vtable: &'static v8::RustAllocatorVtable<AtomicUsize> =
&v8::RustAllocatorVtable {
allocate,
allocate_uninitialized,
free,
reallocate,
drop,
};
let count = Arc::new(AtomicUsize::new(0));
let _setup_guard = setup::parallel_test();
let create_params = v8::CreateParams::default();
assert!(!create_params.has_set_array_buffer_allocator());
let create_params = create_params.array_buffer_allocator(unsafe {
v8::new_rust_allocator(Arc::into_raw(count.clone()), vtable)
});
assert!(create_params.has_set_array_buffer_allocator());
let isolate = &mut v8::Isolate::new(create_params);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(
scope,
r#"
for(let i = 0; i < 10; i++) new ArrayBuffer(1024 * i);
"OK";
"#,
)
.unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let result = script.run(scope).unwrap();
assert_eq!(result.to_rust_string_lossy(scope), "OK");
}
let mut stats = v8::HeapStatistics::default();
isolate.get_heap_statistics(&mut stats);
let count_loaded = count.load(Ordering::SeqCst);
assert!(count_loaded > 0);
assert!(count_loaded <= stats.external_memory());
// Force a GC.
isolate.low_memory_notification();
let count_loaded = count.load(Ordering::SeqCst);
assert_eq!(count_loaded, 0);
}
#[test]
fn oom_callback() {
extern "C" fn oom_handler(
_: *const std::os::raw::c_char,
_: &v8::OomDetails,
) {
unreachable!()
}
let _setup_guard = setup::parallel_test();
let params = v8::CreateParams::default().heap_limits(0, 1048576 * 8);
let isolate = &mut v8::Isolate::new(params);
isolate.set_oom_error_handler(oom_handler);
// Don't attempt to trigger the OOM callback since we don't have a safe way to
// recover from it.
}
#[test]
fn prepare_stack_trace_callback() {
thread_local! {
static SITES: RefCell<Option<v8::Global<v8::Array>>> = RefCell::new(None);
}
let script = r#"
function g() { throw new Error("boom") }
function f() { g() }
try {
f()
} catch (e) {
e.stack
}
"#;
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
isolate.set_prepare_stack_trace_callback(callback);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let scope = &mut v8::TryCatch::new(scope);
let result = eval(scope, script).unwrap();
assert_eq!(Some(42), result.uint32_value(scope));
let sites = SITES.with(|slot| slot.borrow_mut().take()).unwrap();
let sites = v8::Local::new(scope, sites);
assert_eq!(3, sites.length());
let scripts = [
r#"
if ("g" !== site.getFunctionName()) throw "fail";
if (2 !== site.getLineNumber()) throw "fail";
"#,
r#"
if ("f" !== site.getFunctionName()) throw "fail";
if (3 !== site.getLineNumber()) throw "fail";
"#,
r#"
if (null !== site.getFunctionName()) throw "fail";
if (5 !== site.getLineNumber()) throw "fail";
"#,
];
let global = context.global(scope);
let name = v8::String::new(scope, "site").unwrap().into();
for i in 0..3 {
let site = sites.get_index(scope, i).unwrap();
global.set(scope, name, site).unwrap();
let script = scripts[i as usize];
let result = eval(scope, script);
assert!(result.is_some());
}
fn callback<'s>(
scope: &mut v8::HandleScope<'s>,
error: v8::Local<v8::Value>,
sites: v8::Local<v8::Array>,
) -> v8::Local<'s, v8::Value> {
let message = v8::Exception::create_message(scope, error);
let actual = message.get(scope).to_rust_string_lossy(scope);
assert_eq!(actual, "Uncaught Error: boom");
SITES.with(|slot| {
let mut slot = slot.borrow_mut();
assert!(slot.is_none());
*slot = Some(v8::Global::new(scope, sites));
});
v8::Integer::new(scope, 42).into()
}
}
#[test]
fn icu_date() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
(new Date(Date.UTC(2020, 5, 26, 7, 0, 0))).toLocaleString("de-DE", {
weekday: "long",
year: "numeric",
month: "long",
day: "numeric",
});
"#;
let value = eval(scope, source).unwrap();
let date_de_val = v8::String::new(scope, "Freitag, 26. Juni 2020").unwrap();
assert!(value.is_string());
assert!(value.strict_equals(date_de_val.into()));
}
}
#[test]
fn icu_set_common_data_fail() {
assert!(v8::icu::set_common_data_73(&[1, 2, 3]).is_err());
}
#[test]
fn icu_format() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = r#"
new Intl.NumberFormat("ja-JP", { style: "currency", currency: "JPY" }).format(
1230000,
);
"#;
let value = eval(scope, source).unwrap();
let currency_jpy_val = v8::String::new(scope, "¥1,230,000").unwrap();
assert!(value.is_string());
assert!(value.strict_equals(currency_jpy_val.into()));
}
}
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#[test]
fn icu_collator() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::String::new(scope, "new Intl.Collator('en-US')").unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
assert!(script.run(scope).is_some());
}
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fn create_module<'s>(
scope: &mut v8::HandleScope<'s, v8::Context>,
source: &str,
code_cache: Option<v8::UniqueRef<v8::CachedData>>,
options: v8::script_compiler::CompileOptions,
) -> v8::Local<'s, v8::Module> {
let source = v8::String::new(scope, source).unwrap();
let resource_name = v8::String::new(scope, "<resource>").unwrap();
let source_map_url = v8::undefined(scope);
let script_origin = v8::ScriptOrigin::new(
scope,
resource_name.into(),
0,
0,
false,
0,
source_map_url.into(),
false,
false,
true,
);
let has_cache = code_cache.is_some();
let mut source = match code_cache {
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Some(x) => v8::script_compiler::Source::new_with_cached_data(
source,
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Some(&script_origin),
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x,
),
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None => v8::script_compiler::Source::new(source, Some(&script_origin)),
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};
let module = v8::script_compiler::compile_module2(
scope,
&mut source,
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options,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
let code_cache = source.get_cached_data();
assert_eq!(code_cache.is_some(), has_cache);
if let Some(code_cache) = code_cache {
assert!(!code_cache.rejected());
}
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module
}
fn create_unbound_module_script<'s>(
scope: &mut v8::HandleScope<'s, v8::Context>,
source: &str,
code_cache: Option<v8::UniqueRef<v8::CachedData>>,
) -> v8::Local<'s, v8::UnboundModuleScript> {
let module = create_module(
scope,
source,
code_cache,
v8::script_compiler::CompileOptions::NoCompileOptions,
);
module.get_unbound_module_script(scope)
}
#[test]
fn unbound_module_script_conversion() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let mut scope = v8::ContextScope::new(scope, context);
create_unbound_module_script(&mut scope, "'Hello ' + value", None);
}
#[test]
fn cached_data_version_tag() {
let _setup_guard = setup::sequential_test();
// The value is unpredictable/unstable, as it is generated from a combined
// hash of the V8 version number and select configuration flags. This test
// asserts that it returns the same value twice in a row (the value ought to
// be stable for a given v8 build), which also verifies the binding does not
// result in a crash.
assert_eq!(
v8::script_compiler::cached_data_version_tag(),
v8::script_compiler::cached_data_version_tag()
);
}
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#[test]
fn code_cache() {
fn resolve_callback<'a>(
_context: v8::Local<'a, v8::Context>,
_specifier: v8::Local<'a, v8::String>,
_import_assertions: v8::Local<'a, v8::FixedArray>,
_referrer: v8::Local<'a, v8::Module>,
) -> Option<v8::Local<'a, v8::Module>> {
None
}
const CODE: &str = "export const hello = 'world';";
let _setup_guard = setup::parallel_test();
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let code_cache = {
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let mut scope = v8::ContextScope::new(scope, context);
let unbound_module_script =
create_unbound_module_script(&mut scope, CODE, None);
unbound_module_script.create_code_cache().unwrap().to_vec()
};
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let mut scope = v8::ContextScope::new(scope, context);
let module = create_module(
&mut scope,
CODE,
Some(v8::CachedData::new(&code_cache)),
v8::script_compiler::CompileOptions::ConsumeCodeCache,
);
let mut scope = v8::HandleScope::new(&mut scope);
module
.instantiate_module(&mut scope, resolve_callback)
.unwrap();
module.evaluate(&mut scope).unwrap();
let top =
v8::Local::<v8::Object>::try_from(module.get_module_namespace()).unwrap();
let key = v8::String::new(&mut scope, "hello").unwrap();
let value =
v8::Local::<v8::String>::try_from(top.get(&mut scope, key.into()).unwrap())
.unwrap();
assert_eq!(&value.to_rust_string_lossy(&mut scope), "world");
}
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#[test]
fn function_code_cache() {
const CODE: &str = "return word.split('').reverse().join('');";
let _setup_guard = setup::parallel_test();
let code_cache = {
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::script_compiler::Source::new(
v8::String::new(scope, CODE).unwrap(),
None,
);
let word = v8::String::new(scope, "word").unwrap();
let function = v8::script_compiler::compile_function(
scope,
source,
&[word],
&[],
v8::script_compiler::CompileOptions::EagerCompile,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
function.create_code_cache().unwrap()
};
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let source = v8::script_compiler::Source::new_with_cached_data(
v8::String::new(scope, CODE).unwrap(),
None,
code_cache,
);
let word = v8::String::new(scope, "word").unwrap();
let function = v8::script_compiler::compile_function(
scope,
source,
&[word],
&[],
v8::script_compiler::CompileOptions::EagerCompile,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
let input = v8::String::new(scope, "input").unwrap().into();
let expected = v8::String::new(scope, "tupni").unwrap();
let undefined = v8::undefined(scope).into();
assert_eq!(expected, function.call(scope, undefined, &[input]).unwrap());
}
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#[test]
fn eager_compile_script() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let code = v8::String::new(scope, "1 + 1").unwrap();
let source = v8::script_compiler::Source::new(code, None);
let script = v8::script_compiler::compile(
scope,
source,
v8::script_compiler::CompileOptions::EagerCompile,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
let ret = script.run(scope).unwrap();
assert_eq!(ret.uint32_value(scope).unwrap(), 2);
}
#[test]
fn code_cache_script() {
const CODE: &str = "1 + 1";
let _setup_guard = setup::parallel_test();
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let code_cache = {
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let code = v8::String::new(scope, CODE).unwrap();
let source = v8::script_compiler::Source::new(code, None);
let script = v8::script_compiler::compile_unbound_script(
scope,
source,
v8::script_compiler::CompileOptions::EagerCompile,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
script.create_code_cache().unwrap().to_vec()
};
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let code = v8::String::new(scope, CODE).unwrap();
let source = v8::script_compiler::Source::new_with_cached_data(
code,
None,
v8::CachedData::new(&code_cache),
);
let script = v8::script_compiler::compile(
scope,
source,
v8::script_compiler::CompileOptions::ConsumeCodeCache,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
let ret = script.run(scope).unwrap();
assert_eq!(ret.uint32_value(scope).unwrap(), 2);
}
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#[test]
fn compile_function() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let x = v8::Integer::new(scope, 42);
let y = v8::Integer::new(scope, 1337);
let argument = v8::String::new(scope, "x").unwrap();
let extension = v8::Object::new(scope);
let name = v8::String::new(scope, "y").unwrap();
extension.set(scope, name.into(), y.into()).unwrap();
let source = v8::String::new(scope, "return x * y").unwrap();
let source = v8::script_compiler::Source::new(source, None);
let function = v8::script_compiler::compile_function(
scope,
source,
&[argument],
&[extension],
v8::script_compiler::CompileOptions::NoCompileOptions,
v8::script_compiler::NoCacheReason::NoReason,
)
.unwrap();
let undefined = v8::undefined(scope).into();
let result = function.call(scope, undefined, &[x.into()]).unwrap();
assert!(result.is_int32());
assert_eq!(42 * 1337, result.int32_value(scope).unwrap());
}
static EXAMPLE_STRING: v8::OneByteConst =
v8::String::create_external_onebyte_const(b"const static");
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#[test]
fn external_strings() {
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Parse JSON from an external string
let json_static = b"{\"a\": 1, \"b\": 2}";
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let json_external =
v8::String::new_external_onebyte_static(scope, json_static).unwrap();
let maybe_value = v8::json::parse(scope, json_external);
assert!(maybe_value.is_some());
// Check length
assert!(json_external.length() == 16);
// Externality checks
assert!(json_external.is_external());
assert!(json_external.is_external_onebyte());
assert!(!json_external.is_external_twobyte());
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assert!(json_external.is_onebyte());
assert!(json_external.contains_only_onebyte());
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// In & out
let hello =
v8::String::new_external_onebyte_static(scope, b"hello world").unwrap();
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let rust_str = hello.to_rust_string_lossy(scope);
assert_eq!(rust_str, "hello world");
// Externality checks
assert!(hello.is_external());
assert!(hello.is_external_onebyte());
assert!(!hello.is_external_twobyte());
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assert!(hello.is_onebyte());
assert!(hello.contains_only_onebyte());
// Two-byte static
let two_byte = v8::String::new_external_twobyte_static(
scope,
&[0xDD95, 0x0020, 0xD83E, 0xDD95],
)
.unwrap();
let rust_str = two_byte.to_rust_string_lossy(scope);
assert_eq!(rust_str, "\u{FFFD} 🦕");
assert!(two_byte.length() == 4);
// Externality checks
assert!(two_byte.is_external());
assert!(!two_byte.is_external_onebyte());
assert!(two_byte.is_external_twobyte());
assert!(!two_byte.is_onebyte());
assert!(!two_byte.contains_only_onebyte());
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// two-byte "internal" test
let gradients = v8::String::new(scope, "∇gradients").unwrap();
assert!(!gradients.is_external());
assert!(!gradients.is_external_onebyte());
assert!(!gradients.is_external_twobyte());
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assert!(!gradients.is_onebyte());
assert!(!gradients.contains_only_onebyte());
// one-byte "internal" test
let latin1 = v8::String::new(scope, "latin-1").unwrap();
assert!(!latin1.is_external());
assert!(!latin1.is_external_onebyte());
assert!(!latin1.is_external_twobyte());
assert!(latin1.is_onebyte());
assert!(latin1.contains_only_onebyte());
// one-byte "const" test
assert_eq!(EXAMPLE_STRING.as_bytes(), b"const static");
let const_ref_string =
v8::String::new_from_onebyte_const(scope, &EXAMPLE_STRING).unwrap();
assert!(const_ref_string.is_external());
assert!(const_ref_string.is_external_onebyte());
assert!(!const_ref_string.is_external_twobyte());
assert!(const_ref_string.is_onebyte());
assert!(const_ref_string.contains_only_onebyte());
assert!(const_ref_string
.strict_equals(v8::String::new(scope, "const static").unwrap().into()));
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}
#[test]
fn counter_lookup_callback() {
#[derive(Eq, PartialEq, Hash)]
struct Name(*const c_char);
struct Count(*mut i32);
unsafe impl Send for Name {}
unsafe impl Send for Count {}
static MAP: Lazy<Arc<Mutex<HashMap<Name, Count>>>> = Lazy::new(Arc::default);
// |name| points to a static zero-terminated C string.
extern "C" fn callback(name: *const c_char) -> *mut i32 {
MAP
.lock()
.unwrap()
.entry(Name(name))
.or_insert_with(|| Count(Box::leak(Box::new(0))))
.0
}
let _setup_guard = setup::parallel_test();
let params = v8::CreateParams::default().counter_lookup_callback(callback);
let isolate = &mut v8::Isolate::new(params);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let _ = eval(scope, "console.log(42);").unwrap();
let count = MAP
.lock()
.unwrap()
.iter()
.find_map(|(name, count)| {
let name = unsafe { CStr::from_ptr(name.0) };
// Note: counter names start with a "c:" prefix.
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if "c:V8.CompilationCacheMisses" == name.to_string_lossy() {
Some(unsafe { *count.0 })
} else {
None
}
})
.unwrap();
assert_ne!(count, 0);
}
#[cfg(not(target_os = "android"))]
#[test]
fn compiled_wasm_module() {
let _setup_guard = setup::parallel_test();
let compiled_module = {
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let wire_bytes = &[
0x00, 0x61, 0x73, 0x6d, 0x01, 0x00, 0x00, 0x00, 0x00, 0x07, 0x03, 0x66,
0x6F, 0x6F, 0x62, 0x61, 0x72,
];
let module = v8::WasmModuleObject::compile(scope, wire_bytes).unwrap();
module.get_compiled_module()
};
assert_eq!(
compiled_module.get_wire_bytes_ref(),
&[
0x00, 0x61, 0x73, 0x6d, 0x01, 0x00, 0x00, 0x00, 0x00, 0x07, 0x03, 0x66,
0x6F, 0x6F, 0x62, 0x61, 0x72
]
);
assert_eq!(compiled_module.source_url(), "wasm://wasm/3e495052");
{
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let module =
v8::WasmModuleObject::from_compiled_module(scope, &compiled_module)
.unwrap();
let key = v8::String::new(scope, "module").unwrap().into();
global.set(scope, key, module.into());
let foo_ab: v8::Local<v8::ArrayBuffer> =
eval(scope, "WebAssembly.Module.customSections(module, 'foo')[0]")
.unwrap()
.try_into()
.unwrap();
let foo_bs = foo_ab.get_backing_store();
let foo_section = unsafe {
std::slice::from_raw_parts(
foo_bs.data().unwrap().as_ptr() as *mut u8,
foo_bs.byte_length(),
)
};
assert_eq!(foo_section, b"bar");
}
}
#[test]
fn function_names() {
// Setup isolate
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Rust function
fn callback(
scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
rv.set(v8::Integer::new(scope, 42).into())
}
// named v8 function
{
let key = v8::String::new(scope, "magicFn").unwrap();
let name = v8::String::new(scope, "fooBar").unwrap();
let tmpl = v8::FunctionTemplate::new(scope, callback);
let func = tmpl.get_function(scope).unwrap();
func.set_name(name);
let global = context.global(scope);
global.set(scope, key.into(), func.into());
let is_42: v8::Local<v8::Boolean> =
eval(scope, "magicFn() === 42").unwrap().try_into().unwrap();
assert!(is_42.is_true());
let js_str: v8::Local<v8::String> = eval(scope, "magicFn.toString()")
.unwrap()
.try_into()
.unwrap();
assert_eq!(
js_str.to_rust_string_lossy(scope),
"function fooBar() { [native code] }"
);
let v8_name = func.get_name(scope);
assert_eq!(v8_name.to_rust_string_lossy(scope), "fooBar");
}
// anon v8 function
{
let key = v8::String::new(scope, "anonFn").unwrap();
let tmpl = v8::FunctionTemplate::new(scope, callback);
let func = tmpl.get_function(scope).unwrap();
let global = context.global(scope);
global.set(scope, key.into(), func.into());
let is_42: v8::Local<v8::Boolean> =
eval(scope, "anonFn() === 42").unwrap().try_into().unwrap();
assert!(is_42.is_true());
let js_str: v8::Local<v8::String> = eval(scope, "anonFn.toString()")
.unwrap()
.try_into()
.unwrap();
assert_eq!(
js_str.to_rust_string_lossy(scope),
"function () { [native code] }"
);
let v8_name = func.get_name(scope);
assert_eq!(v8_name.to_rust_string_lossy(scope), "");
}
}
// https://github.com/denoland/rusty_v8/issues/849
#[test]
fn backing_store_from_empty_boxed_slice() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let store = v8::ArrayBuffer::new_backing_store_from_boxed_slice(Box::new([]))
.make_shared();
let _ = v8::ArrayBuffer::with_backing_store(&mut scope, &store);
}
#[test]
fn backing_store_from_empty_vec() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let store =
v8::ArrayBuffer::new_backing_store_from_vec(Vec::new()).make_shared();
let _ = v8::ArrayBuffer::with_backing_store(&mut scope, &store);
}
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#[test]
fn backing_store_data() {
let _setup_guard = setup::parallel_test();
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let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let v = vec![1, 2, 3, 4, 5];
let len = v.len();
let store = v8::ArrayBuffer::new_backing_store_from_vec(v).make_shared();
let buf = v8::ArrayBuffer::with_backing_store(&mut scope, &store);
assert_eq!(buf.byte_length(), len);
assert!(buf.data().is_some());
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assert_eq!(
unsafe {
std::slice::from_raw_parts_mut(
buf.data().unwrap().cast::<u8>().as_ptr(),
len,
)
},
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&[1, 2, 3, 4, 5]
);
}
#[test]
fn backing_store_resizable() {
let _setup_guard = setup::parallel_test();
let v = vec![1, 2, 3, 4, 5];
let store_fixed =
v8::ArrayBuffer::new_backing_store_from_vec(v).make_shared();
assert!(!store_fixed.is_resizable_by_user_javascript());
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let ab_val =
eval(&mut scope, "new ArrayBuffer(100, {maxByteLength: 200})").unwrap();
assert!(ab_val.is_array_buffer());
let ab = v8::Local::<v8::ArrayBuffer>::try_from(ab_val).unwrap();
let store_resizable = ab.get_backing_store();
assert!(store_resizable.is_resizable_by_user_javascript());
}
#[test]
fn current_stack_trace() {
// Setup isolate
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// A simple JS-facing function that returns its call depth, max of 5
fn call_depth(
scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
let stack = v8::StackTrace::current_stack_trace(scope, 5).unwrap();
let count = stack.get_frame_count();
rv.set(v8::Integer::new(scope, count as i32).into())
}
let key = v8::String::new(scope, "callDepth").unwrap();
let tmpl = v8::FunctionTemplate::new(scope, call_depth);
let func = tmpl.get_function(scope).unwrap();
let global = context.global(scope);
global.set(scope, key.into(), func.into());
let top_level = eval(scope, "callDepth()")
.unwrap()
.uint32_value(scope)
.unwrap();
assert_eq!(top_level, 1);
let nested = eval(scope, "(_ => (_ => callDepth())())()")
.unwrap()
.uint32_value(scope)
.unwrap();
assert_eq!(nested, 3);
let too_deep = eval(
scope,
"(_ => (_ => (_ => (_ => (_ => (_ => (_ => callDepth())())())())())())())()",
)
.unwrap()
.uint32_value(scope)
.unwrap();
assert_eq!(too_deep, 5);
}
#[test]
fn current_script_name_or_source_url() {
let _setup_guard = setup::parallel_test();
static mut USED: u32 = 0;
fn analyze_script_url_in_stack(
scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
_rv: v8::ReturnValue,
) {
let maybe_name = v8::StackTrace::current_script_name_or_source_url(scope);
assert!(maybe_name.is_some());
unsafe { USED = 1 };
assert_eq!(maybe_name.unwrap().to_rust_string_lossy(scope), "foo.js")
}
// Setup isolate
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let key = v8::String::new(scope, "analyzeScriptURLInStack").unwrap();
let tmpl = v8::FunctionTemplate::new(scope, analyze_script_url_in_stack);
let obj_template = v8::ObjectTemplate::new(scope);
obj_template.set(key.into(), tmpl.into());
let context = v8::Context::new_from_template(scope, obj_template);
let scope = &mut v8::ContextScope::new(scope, context);
let src = r#"function foo() {
analyzeScriptURLInStack();
}
foo();"#;
let resource_name = v8::String::new(scope, "foo.js").unwrap();
let resource_line_offset = 4;
let resource_column_offset = 5;
let resource_is_shared_cross_origin = true;
let script_id = 123;
let source_map_url = v8::String::new(scope, "source_map_url").unwrap();
let resource_is_opaque = true;
let is_wasm = false;
let is_module = false;
let script_origin = v8::ScriptOrigin::new(
scope,
resource_name.into(),
resource_line_offset,
resource_column_offset,
resource_is_shared_cross_origin,
script_id,
source_map_url.into(),
resource_is_opaque,
is_wasm,
is_module,
);
let source = v8::String::new(scope, src).unwrap();
let script =
v8::Script::compile(scope, source, Some(&script_origin)).unwrap();
script.run(scope).unwrap();
unsafe { assert_eq!(USED, 1) };
}
#[test]
fn instance_of() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let global = context.global(&mut scope);
let array_name = v8::String::new(&mut scope, "Array").unwrap();
let array_constructor = global.get(&mut scope, array_name.into()).unwrap();
let array_constructor =
v8::Local::<v8::Object>::try_from(array_constructor).unwrap();
let array: v8::Local<v8::Value> =
v8::Array::new_with_elements(&mut scope, &[]).into();
assert!(array.instance_of(&mut scope, array_constructor).unwrap());
}
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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#[test]
fn get_default_locale() {
v8::icu::set_default_locale("nb_NO");
let default_locale = v8::icu::get_language_tag();
assert_eq!(default_locale, "nb-NO");
}
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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#[test]
fn weak_handle() {
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let weak = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
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let weak = v8::Weak::new(scope, local);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(!weak.is_empty());
assert_eq!(weak, local);
assert_eq!(weak.to_local(scope), Some(local));
weak
};
let scope = &mut v8::HandleScope::new(scope);
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak.is_empty());
assert_eq!(weak.to_local(scope), None);
}
#[test]
fn finalizers() {
use std::cell::Cell;
use std::ops::Deref;
use std::rc::Rc;
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// The finalizer for a dropped Weak is never called.
{
{
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
let _ =
2022-11-25 08:32:52 -05:00
v8::Weak::with_finalizer(scope, local, Box::new(|_| unreachable!()));
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
}
let scope = &mut v8::HandleScope::new(scope);
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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}
let finalizer_called = Rc::new(Cell::new(false));
let weak = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
// We use a channel to send data into the finalizer without having to worry
// about lifetimes.
let (tx, rx) = std::sync::mpsc::sync_channel::<(
Rc<v8::Weak<v8::Object>>,
Rc<Cell<bool>>,
)>(1);
let weak = Rc::new(v8::Weak::with_finalizer(
scope,
2022-11-25 08:32:52 -05:00
local,
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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Box::new(move |_| {
let (weak, finalizer_called) = rx.try_recv().unwrap();
finalizer_called.set(true);
assert!(weak.is_empty());
}),
));
tx.send((weak.clone(), finalizer_called.clone())).unwrap();
assert!(!weak.is_empty());
assert_eq!(weak.deref(), &local);
assert_eq!(weak.to_local(scope), Some(local));
weak
};
let scope = &mut v8::HandleScope::new(scope);
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak.is_empty());
assert!(finalizer_called.get());
}
#[test]
fn guaranteed_finalizers() {
// Test that guaranteed finalizers behave the same as regular finalizers for
// everything except being guaranteed.
use std::cell::Cell;
use std::ops::Deref;
use std::rc::Rc;
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// The finalizer for a dropped Weak is never called.
{
{
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
let _ = v8::Weak::with_guaranteed_finalizer(
scope,
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local,
Box::new(|| unreachable!()),
);
}
let scope = &mut v8::HandleScope::new(scope);
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
}
let finalizer_called = Rc::new(Cell::new(false));
let weak = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
// We use a channel to send data into the finalizer without having to worry
// about lifetimes.
let (tx, rx) = std::sync::mpsc::sync_channel::<(
Rc<v8::Weak<v8::Object>>,
Rc<Cell<bool>>,
)>(1);
let weak = Rc::new(v8::Weak::with_guaranteed_finalizer(
scope,
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local,
Box::new(move || {
let (weak, finalizer_called) = rx.try_recv().unwrap();
finalizer_called.set(true);
assert!(weak.is_empty());
}),
));
tx.send((weak.clone(), finalizer_called.clone())).unwrap();
assert!(!weak.is_empty());
assert_eq!(weak.deref(), &local);
assert_eq!(weak.to_local(scope), Some(local));
weak
};
let scope = &mut v8::HandleScope::new(scope);
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
assert!(weak.is_empty());
assert!(finalizer_called.get());
}
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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#[test]
fn weak_from_global() {
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = {
let scope = &mut v8::HandleScope::new(scope);
let object = v8::Object::new(scope);
v8::Global::new(scope, object)
};
let weak = v8::Weak::new(scope, &global);
assert!(!weak.is_empty());
assert_eq!(weak.to_global(scope).unwrap(), global);
drop(global);
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak.is_empty());
}
#[test]
fn weak_from_into_raw() {
use std::cell::Cell;
use std::rc::Rc;
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let finalizer_called = Rc::new(Cell::new(false));
assert_eq!(v8::Weak::<v8::Object>::empty(scope).into_raw(), None);
assert!(unsafe { v8::Weak::<v8::Object>::from_raw(scope, None) }.is_empty());
// regular back and forth
{
finalizer_called.take();
let (weak1, weak2) = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
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let weak = v8::Weak::new(scope, local);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let weak_with_finalizer = v8::Weak::with_finalizer(
scope,
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local,
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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Box::new({
let finalizer_called = finalizer_called.clone();
move |_| {
finalizer_called.set(true);
}
}),
);
let raw1 = weak.into_raw();
let raw2 = weak_with_finalizer.into_raw();
assert!(raw1.is_some());
assert!(raw2.is_some());
let weak1 = unsafe { v8::Weak::from_raw(scope, raw1) };
let weak2 = unsafe { v8::Weak::from_raw(scope, raw2) };
assert_eq!(weak1.to_local(scope), Some(local));
assert_eq!(weak2.to_local(scope), Some(local));
assert!(!finalizer_called.get());
(weak1, weak2)
};
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak1.is_empty());
assert!(weak2.is_empty());
assert!(finalizer_called.get());
}
// into_raw from a GC'd pointer
{
let weak = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
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v8::Weak::new(scope, local)
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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};
assert!(!weak.is_empty());
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(weak.is_empty());
assert_eq!(weak.into_raw(), None);
}
// It's fine if there's a GC while the Weak is leaked.
{
finalizer_called.take();
let (weak, weak_with_finalizer) = {
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
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let weak = v8::Weak::new(scope, local);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
let weak_with_finalizer = v8::Weak::with_finalizer(
scope,
2022-11-25 08:32:52 -05:00
local,
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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Box::new({
let finalizer_called = finalizer_called.clone();
move |_| {
finalizer_called.set(true);
}
}),
);
(weak, weak_with_finalizer)
};
assert!(!weak.is_empty());
assert!(!weak_with_finalizer.is_empty());
assert!(!finalizer_called.get());
let raw1 = weak.into_raw();
let raw2 = weak_with_finalizer.into_raw();
assert!(raw1.is_some());
assert!(raw2.is_some());
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
assert!(finalizer_called.get());
let weak1 = unsafe { v8::Weak::from_raw(scope, raw1) };
let weak2 = unsafe { v8::Weak::from_raw(scope, raw2) };
assert!(weak1.is_empty());
assert!(weak2.is_empty());
}
// Leaking a Weak will not crash the isolate.
{
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
v8::Weak::new(scope, local).into_raw();
v8::Weak::with_finalizer(scope, local, Box::new(|_| {})).into_raw();
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
}
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
2022-05-09 06:20:55 -04:00
}
#[test]
fn drop_weak_from_raw_in_finalizer() {
use std::cell::Cell;
use std::rc::Rc;
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let weak_ptr = Rc::new(Cell::new(None));
let finalized = Rc::new(Cell::new(false));
{
let scope = &mut v8::HandleScope::new(scope);
let local = v8::Object::new(scope);
let weak = v8::Weak::with_finalizer(
scope,
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local,
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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Box::new({
let weak_ptr = weak_ptr.clone();
let finalized = finalized.clone();
move |isolate| {
let weak_ptr = weak_ptr.get().unwrap();
let weak: v8::Weak<v8::Object> =
unsafe { v8::Weak::from_raw(isolate, Some(weak_ptr)) };
drop(weak);
finalized.set(true);
}
}),
);
weak_ptr.set(weak.into_raw());
}
assert!(!finalized.get());
scope.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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assert!(finalized.get());
}
#[test]
fn finalizer_on_kept_global() {
// If a global is kept alive after an isolate is dropped, regular finalizers
// won't be called, but guaranteed ones will.
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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use std::cell::Cell;
use std::rc::Rc;
let _setup_guard = setup::parallel_test();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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let global;
let weak1;
let weak2;
let regular_finalized = Rc::new(Cell::new(false));
let guaranteed_finalized = Rc::new(Cell::new(false));
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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{
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object = v8::Object::new(scope);
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global = v8::Global::new(scope, object);
weak1 = v8::Weak::with_finalizer(
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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scope,
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object,
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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Box::new({
let finalized = regular_finalized.clone();
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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move |_| finalized.set(true)
}),
);
weak2 = v8::Weak::with_guaranteed_finalizer(
scope,
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object,
Box::new({
let guaranteed_finalized = guaranteed_finalized.clone();
move || guaranteed_finalized.set(true)
}),
);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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}
assert!(weak1.is_empty());
assert!(weak2.is_empty());
assert!(!regular_finalized.get());
assert!(guaranteed_finalized.get());
drop(weak1);
drop(weak2);
feat: Weak handles and finalizers (#895) This change adds support for weak handles that don't prevent GC of the referenced objects, through the `v8::Weak<T>` API. A weak handle can be empty (if it was created empty or its object was GC'd) or non-empty, and if non-empty it allows getting its object as a global or local. When creating a `v8::Weak` you can also set a finalizer that will be called at some point after the object is GC'd, as long as the weak handle is still alive at that point. This finalization corresponds to the second-pass callback in `kParameter` mode in the C++ API, so it will only be called after the object is GC'd. The finalizer function is a `FnOnce` that may close over data, and which takes a `&mut Isolate` as an argument. The C++ finalization API doesn't guarantee _when_ or even _if_ the finalizer will ever be called, but in order to prevent memory leaks, the rusty_v8 wrapper ensures that it will be called at some point, even if it's just before the isolate gets dropped. `v8::Weak<T>` implements `Clone`, but a finalizer is tied to a single weak handle, so its clones won't be able to keep the finalizer alive. And in fact, cloning will create a new weak handle that isn't tied to a finalizer at all. `v8::Weak::clone_with_finalizer` can be used to make a clone of a weak handle which has a finalizer tied to it. Note that `v8::Weak<T>` doesn't implement `Hash`, because the hash would have to change once the handle's object is GC'd, which is a big gotcha and would break some of the algorithms that rely on hashes, such as the Rust std's `HashMap`.
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drop(global);
}
#[test]
fn isolate_data_slots() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
assert_eq!(isolate.get_number_of_data_slots(), 2);
let expected0 = "Bla";
isolate.set_data(0, &expected0 as *const _ as *mut &str as *mut c_void);
let expected1 = 123.456f64;
isolate.set_data(1, &expected1 as *const _ as *mut f64 as *mut c_void);
let actual0 = isolate.get_data(0) as *mut &str;
let actual0 = unsafe { *actual0 };
assert_eq!(actual0, expected0);
let actual1 = isolate.get_data(1) as *mut f64;
let actual1 = unsafe { *actual1 };
assert_eq!(actual1, expected1);
}
#[test]
fn context_embedder_data() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let global_context;
let expected0 = "Bla";
let expected1 = 123.456f64;
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
unsafe {
context.set_aligned_pointer_in_embedder_data(
0,
&expected0 as *const _ as *mut &str as *mut c_void,
);
context.set_aligned_pointer_in_embedder_data(
1,
&expected1 as *const _ as *mut f64 as *mut c_void,
);
}
global_context = v8::Global::new(scope, context);
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = global_context.open(scope);
let actual0 =
context.get_aligned_pointer_from_embedder_data(0) as *mut &str;
let actual0 = unsafe { *actual0 };
assert_eq!(actual0, expected0);
let actual1 = context.get_aligned_pointer_from_embedder_data(1) as *mut f64;
let actual1 = unsafe { *actual1 };
assert_eq!(actual1, expected1);
}
}
#[test]
fn host_create_shadow_realm_context_callback() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
{
let tc_scope = &mut v8::TryCatch::new(scope);
assert!(eval(tc_scope, "new ShadowRealm()").is_none());
assert!(tc_scope.has_caught());
}
struct CheckData {
callback_called: bool,
main_context: v8::Global<v8::Context>,
}
let main_context = v8::Global::new(scope, context);
scope.set_slot(CheckData {
callback_called: false,
main_context,
});
scope.set_host_create_shadow_realm_context_callback(|scope| {
let main_context = {
let data = scope.get_slot_mut::<CheckData>().unwrap();
data.callback_called = true;
data.main_context.clone()
};
assert_eq!(scope.get_current_context(), main_context);
// Can't return None without throwing.
let message = v8::String::new(scope, "Unsupported").unwrap();
let exception = v8::Exception::type_error(scope, message);
scope.throw_exception(exception);
None
});
{
let tc_scope = &mut v8::TryCatch::new(scope);
assert!(eval(tc_scope, "new ShadowRealm()").is_none());
assert!(tc_scope.has_caught());
assert!(tc_scope.get_slot::<CheckData>().unwrap().callback_called);
}
scope.set_host_create_shadow_realm_context_callback(|scope| {
let main_context = {
let data = scope.get_slot_mut::<CheckData>().unwrap();
data.callback_called = true;
data.main_context.clone()
};
assert_eq!(scope.get_current_context(), main_context);
let new_context = v8::Context::new(scope);
{
let scope = &mut v8::ContextScope::new(scope, new_context);
let global = new_context.global(scope);
let key = v8::String::new(scope, "test").unwrap();
let value = v8::Integer::new(scope, 42);
global.set(scope, key.into(), value.into()).unwrap();
}
Some(new_context)
});
let value =
eval(scope, "new ShadowRealm().evaluate(`globalThis.test`)").unwrap();
assert_eq!(value.uint32_value(scope), Some(42));
assert!(scope.get_slot::<CheckData>().unwrap().callback_called);
}
#[test]
fn test_fast_calls() {
static mut WHO: &str = "none";
fn fast_fn(_recv: v8::Local<v8::Object>, a: u32, b: u32) -> u32 {
unsafe { WHO = "fast" };
a + b
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Uint32, Uint32],
fast_api::CType::Uint32,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
let a = args.get(0).uint32_value(scope).unwrap();
let b = args.get(1).uint32_value(scope).unwrap();
rv.set_uint32(a + b);
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(x, y) { return func(x, y); }
%PrepareFunctionForOptimization(f);
if (42 !== f(19, 23)) throw "unexpected";
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
if (42 !== f(19, 23)) throw "unexpected";
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn test_fast_calls_empty_buffer() {
static mut WHO: &str = "none";
unsafe fn fast_fn(
_recv: v8::Local<v8::Object>,
buffer: *mut FastApiTypedArray<u8>,
) {
assert_eq!(WHO, "slow");
WHO = "fast";
assert_eq!(
0,
FastApiTypedArray::get_storage_from_pointer_if_aligned(buffer)
.unwrap()
.len()
);
}
fn slow_fn(
_scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
_rv: v8::ReturnValue,
) {
unsafe {
WHO = "slow";
}
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, TypedArray(CType::Uint8)],
fast_api::CType::Void,
fast_fn as _,
);
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(arr) { func(arr); }
%PrepareFunctionForOptimization(f);
f(new Uint8Array(0));
%OptimizeFunctionOnNextCall(f);
f(new Uint8Array(0));
"#;
eval(scope, source).unwrap();
assert_eq!(unsafe { WHO }, "fast");
}
#[test]
fn test_fast_calls_sequence() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
a: u32,
b: u32,
array: v8::Local<v8::Array>,
) -> u32 {
unsafe { WHO = "fast" };
assert_eq!(array.length(), 2);
a + b + array.length()
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Uint32, Uint32, Sequence(fast_api::CType::Void)],
fast_api::CType::Uint32,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(x, y, data) { return func(x, y, data); }
%PrepareFunctionForOptimization(f);
const arr = [3, 4];
f(1, 2, arr);
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f(1, 2, arr);
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn test_fast_calls_arraybuffer() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
a: u32,
b: u32,
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data: *const fast_api::FastApiTypedArray<u32>,
) -> u32 {
unsafe { WHO = "fast" };
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a + b + unsafe { &*data }.get(0)
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Uint32, Uint32, TypedArray(fast_api::CType::Uint32)],
fast_api::CType::Uint32,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(x, y, data) { return func(x, y, data); }
%PrepareFunctionForOptimization(f);
const arr = new Uint32Array([3, 4]);
f(1, 2, arr);
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f(1, 2, arr);
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn test_fast_calls_typedarray() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
data: *const fast_api::FastApiTypedArray<u8>,
) -> u32 {
unsafe { WHO = "fast" };
let first = unsafe { &*data }.get(0);
let second = unsafe { &*data }.get(1);
let third = unsafe { &*data }.get(2);
assert_eq!(first, 4);
assert_eq!(second, 5);
assert_eq!(third, 6);
let sum = first + second + third;
sum.into()
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, TypedArray(fast_api::CType::Uint8)],
fast_api::CType::Uint32,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(data) { return func(data); }
%PrepareFunctionForOptimization(f);
const arr = new Uint8Array([4, 5, 6]);
f(arr);
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
const result = f(arr);
if (result != 15) {
throw new Error("wrong result");
}
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn test_fast_calls_reciever() {
const V8_WRAPPER_TYPE_INDEX: i32 = 0;
const V8_WRAPPER_OBJECT_INDEX: i32 = 1;
static mut WHO: &str = "none";
fn fast_fn(recv: v8::Local<v8::Object>) -> u32 {
unsafe {
WHO = "fast";
let embedder_obj =
recv.get_aligned_pointer_from_internal_field(V8_WRAPPER_OBJECT_INDEX);
let i = *(embedder_obj as *const u32);
assert_eq!(i, 69);
i
}
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value],
fast_api::CType::Uint32,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(
v8::CreateParams::default().embedder_wrapper_type_info_offsets(
V8_WRAPPER_TYPE_INDEX,
V8_WRAPPER_OBJECT_INDEX,
),
);
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let object_template = v8::ObjectTemplate::new(scope);
assert!(object_template
.set_internal_field_count((V8_WRAPPER_OBJECT_INDEX + 1) as usize));
let obj = object_template.new_instance(scope).unwrap();
let embedder_obj = Box::into_raw(Box::new(69u32));
obj.set_aligned_pointer_in_internal_field(
V8_WRAPPER_OBJECT_INDEX,
embedder_obj as _,
);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "method").unwrap();
let value = template.get_function(scope).unwrap();
obj.set(scope, name.into(), value.into()).unwrap();
let obj_str = v8::String::new(scope, "obj").unwrap();
let global = context.global(scope);
global.set(scope, obj_str.into(), obj.into()).unwrap();
let source = r#"
function f() { return obj.method(); }
%PrepareFunctionForOptimization(f);
f();
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f();
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
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#[test]
fn test_fast_calls_overload() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
data: *const fast_api::FastApiTypedArray<u32>,
) {
unsafe { WHO = "fast_buf" };
let buf = unsafe { &*data };
assert_eq!(buf.length, 2);
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assert_eq!(buf.get(0), 6);
assert_eq!(buf.get(1), 9);
}
fn fast_fn2(_recv: v8::Local<v8::Object>, data: v8::Local<v8::Array>) {
unsafe { WHO = "fast_array" };
assert_eq!(data.length(), 2);
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, TypedArray(CType::Uint32)],
CType::Void,
fast_fn as _,
);
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const FAST_TEST2: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Sequence(CType::Void)],
CType::Void,
fast_fn2 as _,
);
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fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
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let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn).build_fast(
scope,
&FAST_TEST,
None,
Some(&FAST_TEST2),
None,
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);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(data) { return func(data); }
%PrepareFunctionForOptimization(f);
const arr = [6, 9];
const buf = new Uint32Array(arr);
f(buf);
f(arr);
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f(buf);
"#;
eval(scope, source).unwrap();
assert_eq!("fast_buf", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f(arr);
"#;
eval(scope, source).unwrap();
assert_eq!("fast_array", unsafe { WHO });
}
#[test]
fn test_fast_calls_callback_options_fallback() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
options: *mut fast_api::FastApiCallbackOptions,
) {
if unsafe { WHO == "fast" } {
let options = unsafe { &mut *options };
options.fallback = true; // Go back to slow path.
} else {
unsafe { WHO = "fast" };
}
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, CallbackOptions],
CType::Void,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f() { return func(); }
%PrepareFunctionForOptimization(f);
f();
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f();
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
let source = r#"
f(); // Second call fallbacks back to slow path.
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
}
#[test]
fn test_fast_calls_callback_options_data() {
static mut DATA: bool = false;
unsafe fn fast_fn(
_recv: v8::Local<v8::Object>,
options: *mut fast_api::FastApiCallbackOptions,
) {
let options = &mut *options;
if !options.data.data.is_external() {
options.fallback = true;
return;
}
let data = v8::Local::<v8::External>::cast(options.data.data);
let data = &mut *(data.value() as *mut bool);
*data = true;
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, CallbackOptions],
CType::Void,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
rv.set(v8::Boolean::new(scope, false).into());
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let external =
v8::External::new(scope, unsafe { &mut DATA as *mut bool as *mut c_void });
let template = v8::FunctionTemplate::builder(slow_fn)
.data(external.into())
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f() { return func(); }
%PrepareFunctionForOptimization(f);
f();
"#;
eval(scope, source).unwrap();
assert!(unsafe { !DATA });
let source = r#"
%OptimizeFunctionOnNextCall(f);
f();
"#;
eval(scope, source).unwrap();
assert!(unsafe { DATA });
}
#[test]
fn test_detach_key() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
// Object detach key
{
let detach_key = eval(scope, "({})").unwrap();
assert!(detach_key.is_object());
let buffer = v8::ArrayBuffer::new(scope, 1024);
buffer.set_detach_key(detach_key);
assert!(buffer.is_detachable());
assert_eq!(buffer.detach(None), None);
assert!(!buffer.was_detached());
assert_eq!(buffer.detach(Some(detach_key)), Some(true));
assert!(buffer.was_detached());
}
// External detach key
{
let mut rust_detach_key = Box::new(42usize);
let v8_detach_key = v8::External::new(
scope,
&mut *rust_detach_key as *mut usize as *mut c_void,
);
let buffer = v8::ArrayBuffer::new(scope, 1024);
buffer.set_detach_key(v8_detach_key.into());
assert!(buffer.is_detachable());
assert_eq!(buffer.detach(None), None);
assert!(!buffer.was_detached());
assert_eq!(buffer.detach(Some(v8_detach_key.into())), Some(true));
assert!(buffer.was_detached());
}
// Undefined detach key
{
let buffer = v8::ArrayBuffer::new(scope, 1024);
buffer.set_detach_key(v8::undefined(scope).into());
assert!(buffer.is_detachable());
assert_eq!(buffer.detach(Some(v8::undefined(scope).into())), Some(true));
assert!(buffer.was_detached());
}
}
#[test]
fn test_fast_calls_onebytestring() {
static mut WHO: &str = "none";
fn fast_fn(
_recv: v8::Local<v8::Object>,
data: *const fast_api::FastApiOneByteString,
) -> u32 {
unsafe { WHO = "fast" };
let data = unsafe { &*data }.as_bytes();
assert_eq!(b"hello", data);
data.len() as u32
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, SeqOneByteString],
CType::Uint32,
fast_fn as _,
);
fn slow_fn(
_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
_: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(data) { return func(data); }
%PrepareFunctionForOptimization(f);
const str = "hello";
f(str);
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
const result = f(str);
if (result != 5) {
throw new Error("wrong result");
}
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn test_fast_calls_i64representation() {
static mut FAST_CALL_COUNT: u32 = 0;
static mut SLOW_CALL_COUNT: u32 = 0;
fn fast_fn(_recv: v8::Local<v8::Object>, a: u64, b: u64) -> u64 {
unsafe { FAST_CALL_COUNT += 1 };
assert_eq!(9007199254740991, a);
assert_eq!(646, b);
a * b
}
const FAST_TEST_NUMBER: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Uint64, Uint64],
CType::Uint64,
fast_fn as _,
);
const FAST_TEST_BIGINT: fast_api::FastFunction =
fast_api::FastFunction::new_with_bigint(
&[V8Value, Uint64, Uint64],
CType::Uint64,
fast_fn as _,
);
fn slow_fn(
_: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
_: v8::ReturnValue,
) {
unsafe { SLOW_CALL_COUNT += 1 };
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template_number = v8::FunctionTemplate::builder(slow_fn).build_fast(
scope,
&FAST_TEST_NUMBER,
None,
None,
None,
);
let template_bigint = v8::FunctionTemplate::builder(slow_fn).build_fast(
scope,
&FAST_TEST_BIGINT,
None,
None,
None,
);
let name_number = v8::String::new(scope, "func_number").unwrap();
let name_bigint = v8::String::new(scope, "func_bigint").unwrap();
let value_number = template_number.get_function(scope).unwrap();
let value_bigint = template_bigint.get_function(scope).unwrap();
global
.set(scope, name_number.into(), value_number.into())
.unwrap();
global
.set(scope, name_bigint.into(), value_bigint.into())
.unwrap();
let source = r#"
function f(a, b) { return func_number(a, b); }
%PrepareFunctionForOptimization(f);
f(1, 2);
"#;
eval(scope, source).unwrap();
assert_eq!(1, unsafe { SLOW_CALL_COUNT });
let source = r#"
%OptimizeFunctionOnNextCall(f);
{
const result = f(Number.MAX_SAFE_INTEGER, 646);
// Correct answer is 5818650718562680186: data is lost.
if (result != 5818650718562680000) {
throw new Error(`wrong number result: ${result}`);
}
}
"#;
eval(scope, source).unwrap();
assert_eq!(1, unsafe { FAST_CALL_COUNT });
let source = r#"
function g(a, b) { return func_bigint(a, b); }
%PrepareFunctionForOptimization(g);
g(1n, 2n);
"#;
eval(scope, source).unwrap();
assert_eq!(2, unsafe { SLOW_CALL_COUNT });
let source = r#"
%OptimizeFunctionOnNextCall(g);
{
const result = g(BigInt(Number.MAX_SAFE_INTEGER), 646n);
if (result != 5818650718562680186n) {
throw new Error(`wrong bigint result: ${result}`);
}
}
"#;
eval(scope, source).unwrap();
assert_eq!(2, unsafe { FAST_CALL_COUNT });
}
#[test]
fn gc_callbacks() {
let _setup_guard = setup::parallel_test();
#[derive(Default)]
struct GCCallbackState {
mark_sweep_calls: u64,
incremental_marking_calls: u64,
}
extern "C" fn callback(
_isolate: *mut v8::Isolate,
r#type: v8::GCType,
_flags: v8::GCCallbackFlags,
data: *mut c_void,
) {
// We should get a mark-sweep GC here.
assert_eq!(r#type, v8::GCType::MARK_SWEEP_COMPACT);
let state = unsafe { &mut *(data as *mut GCCallbackState) };
state.mark_sweep_calls += 1;
}
extern "C" fn callback2(
_isolate: *mut v8::Isolate,
r#type: v8::GCType,
_flags: v8::GCCallbackFlags,
data: *mut c_void,
) {
// We should get a mark-sweep GC here.
assert_eq!(r#type, v8::GCType::INCREMENTAL_MARKING);
let state = unsafe { &mut *(data as *mut GCCallbackState) };
state.incremental_marking_calls += 1;
}
let mut state = GCCallbackState::default();
let state_ptr = &mut state as *mut _ as *mut c_void;
let isolate = &mut v8::Isolate::new(Default::default());
isolate.add_gc_prologue_callback(callback, state_ptr, v8::GCType::ALL);
isolate.add_gc_prologue_callback(
callback2,
state_ptr,
v8::GCType::INCREMENTAL_MARKING | v8::GCType::PROCESS_WEAK_CALLBACKS,
);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
assert_eq!(state.mark_sweep_calls, 1);
assert_eq!(state.incremental_marking_calls, 0);
}
isolate.remove_gc_prologue_callback(callback, state_ptr);
isolate.remove_gc_prologue_callback(callback2, state_ptr);
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
scope
.request_garbage_collection_for_testing(v8::GarbageCollectionType::Full);
// Assert callback was removed and not called again.
assert_eq!(state.mark_sweep_calls, 1);
assert_eq!(state.incremental_marking_calls, 0);
}
}
#[test]
fn test_fast_calls_pointer() {
static mut WHO: &str = "none";
fn fast_fn(_recv: v8::Local<v8::Object>, data: *mut c_void) -> *mut c_void {
// Assert before re-assigning WHO, as the reassignment will change the reference.
assert!(std::ptr::eq(data, unsafe { WHO.as_ptr() as *mut c_void }));
unsafe { WHO = "fast" };
std::ptr::null_mut()
}
const FAST_TEST: fast_api::FastFunction = fast_api::FastFunction::new(
&[V8Value, Pointer],
fast_api::CType::Pointer,
fast_fn as _,
);
fn slow_fn(
scope: &mut v8::HandleScope,
_: v8::FunctionCallbackArguments,
mut rv: v8::ReturnValue,
) {
unsafe { WHO = "slow" };
rv.set(
v8::External::new(scope, unsafe { WHO.as_ptr() as *mut c_void }).into(),
);
}
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let global = context.global(scope);
let template = v8::FunctionTemplate::builder(slow_fn)
.build_fast(scope, &FAST_TEST, None, None, None);
let name = v8::String::new(scope, "func").unwrap();
let value = template.get_function(scope).unwrap();
global.set(scope, name.into(), value.into()).unwrap();
let source = r#"
function f(data) {
return func(data);
}
%PrepareFunctionForOptimization(f);
const external = f(null);
if (
typeof external !== "object" || external === null ||
Object.keys(external).length > 0 || Object.getPrototypeOf(external) !== null
) {
throw new Error(
"External pointer object should be an empty object with no properties and no prototype",
);
}
"#;
eval(scope, source).unwrap();
assert_eq!("slow", unsafe { WHO });
let source = r#"
%OptimizeFunctionOnNextCall(f);
const external_fast = f(external);
if (external_fast !== null) {
throw new Error("Null pointer external should be JS null");
}
"#;
eval(scope, source).unwrap();
assert_eq!("fast", unsafe { WHO });
}
#[test]
fn object_define_property() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut desc = v8::PropertyDescriptor::new();
desc.set_configurable(true);
desc.set_enumerable(false);
let name = v8::String::new(scope, "g").unwrap();
context
.global(scope)
.define_property(scope, name.into(), &desc);
let source = r#"
{
const d = Object.getOwnPropertyDescriptor(globalThis, "g");
[d.configurable, d.enumerable, d.writable].toString()
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "true,false,false").unwrap();
assert!(expected.strict_equals(actual));
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut desc = v8::PropertyDescriptor::new_from_value_writable(
v8::Integer::new(scope, 42).into(),
true,
);
desc.set_configurable(true);
desc.set_enumerable(false);
let name = v8::String::new(scope, "g").unwrap();
context
.global(scope)
.define_property(scope, name.into(), &desc);
let source = r#"
{
const d = Object.getOwnPropertyDescriptor(globalThis, "g");
[d.configurable, d.enumerable, d.writable].toString()
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "true,false,true").unwrap();
assert!(expected.strict_equals(actual));
}
{
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
let mut desc = v8::PropertyDescriptor::new_from_value(
v8::Integer::new(scope, 42).into(),
);
desc.set_configurable(true);
desc.set_enumerable(false);
let name = v8::String::new(scope, "g").unwrap();
context
.global(scope)
.define_property(scope, name.into(), &desc);
let source = r#"
{
const d = Object.getOwnPropertyDescriptor(globalThis, "g");
[d.configurable, d.enumerable, d.writable].toString()
}
"#;
let actual = eval(scope, source).unwrap();
let expected = v8::String::new(scope, "true,false,false").unwrap();
assert!(expected.strict_equals(actual));
}
}
// Regression test for https://github.com/denoland/deno/issues/19021
#[test]
fn bubbling_up_exception() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
fn boom_fn(
scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
_retval: v8::ReturnValue,
) {
let msg = v8::String::new(scope, "boom").unwrap();
let exception = v8::Exception::type_error(scope, msg);
scope.throw_exception(exception);
}
let global_proxy = scope.get_current_context().global(scope);
let identifier = v8::String::new(scope, "boom").unwrap();
let value = v8::FunctionTemplate::new(scope, boom_fn)
.get_function(scope)
.unwrap();
global_proxy.set(scope, identifier.into(), value.into());
let code = r#"
try {
boom()
} catch (e) {
//
}
"#;
let source = v8::String::new(scope, code).unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let scope = &mut v8::TryCatch::new(scope);
let _result = script.run(scope);
// This fails in debug build, but passes in release build.
assert!(!scope.has_caught());
assert!(scope.exception().is_none());
}
// Regression test for https://github.com/denoland/deno/issues/19021
#[test]
fn bubbling_up_exception_in_function_call() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
fn boom_fn(
scope: &mut v8::HandleScope,
_args: v8::FunctionCallbackArguments,
_retval: v8::ReturnValue,
) {
let msg = v8::String::new(scope, "boom").unwrap();
let exception = v8::Exception::type_error(scope, msg);
scope.throw_exception(exception);
}
let global_proxy = scope.get_current_context().global(scope);
let identifier = v8::String::new(scope, "boom").unwrap();
let value = v8::FunctionTemplate::new(scope, boom_fn)
.get_function(scope)
.unwrap();
global_proxy.set(scope, identifier.into(), value.into());
let code = r#"
(function () {
return function callBoom() {
try {
boom()
} catch (e) {
//
}
}
})();
"#;
let source = v8::String::new(scope, code).unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let scope = &mut v8::TryCatch::new(scope);
let call_boom_fn_val = script.run(scope).unwrap();
let call_boom_fn =
v8::Local::<v8::Function>::try_from(call_boom_fn_val).unwrap();
let scope = &mut v8::TryCatch::new(scope);
let this = v8::undefined(scope);
let result = call_boom_fn.call(scope, this.into(), &[]).unwrap();
assert!(result.is_undefined());
// This fails in debug build, but passes in release build.
assert!(!scope.has_caught());
assert!(scope.exception().is_none());
}
// Regression test for https://github.com/denoland/rusty_v8/issues/1226
#[test]
fn exception_thrown_but_continues_execution() {
let _setup_guard = setup::parallel_test();
let isolate = &mut v8::Isolate::new(Default::default());
let scope = &mut v8::HandleScope::new(isolate);
let context = v8::Context::new(scope);
let scope = &mut v8::ContextScope::new(scope, context);
static CALL_COUNT: AtomicUsize = AtomicUsize::new(0);
fn call_object_property<'s>(
scope: &mut v8::HandleScope<'s>,
value: v8::Local<v8::Value>,
property: &str,
) -> Option<v8::Local<'s, v8::Value>> {
let object: v8::Local<v8::Object> = value.try_into().unwrap();
let ident = v8::String::new(scope, property).unwrap().into();
let prop = object.get(scope, ident).unwrap();
let func: v8::Local<v8::Function> = prop.try_into().unwrap();
let recv = scope.get_current_context().global(scope).into();
let retval = func.call(scope, recv, &[]);
retval
}
fn print_fn(
scope: &mut v8::HandleScope,
args: v8::FunctionCallbackArguments,
_retval: v8::ReturnValue,
) {
let local_arg = args.get(0);
CALL_COUNT.fetch_add(1, Ordering::SeqCst);
let print_str = if local_arg.is_string() {
local_arg.to_rust_string_lossy(scope)
} else if local_arg.is_object() {
let obj_repr = call_object_property(scope, local_arg, "repr");
if obj_repr.is_none() {
return;
}
"[".to_owned() + &obj_repr.unwrap().to_rust_string_lossy(scope) + "]"
} else {
"Unknown type".to_owned()
};
println!("{print_str}");
}
let global_proxy = scope.get_current_context().global(scope);
let identifier = v8::String::new(scope, "print").unwrap();
let value = v8::FunctionTemplate::new(scope, print_fn)
.get_function(scope)
.unwrap();
global_proxy.set(scope, identifier.into(), value.into());
let code = r#"
let object_with_ok_repr = {
repr: function() { return "object_with_ok_repr"; }
};
print(object_with_ok_repr);
let object_with_broken_repr = {
repr: function() { boom }
};
print(object_with_broken_repr);
print("this should not be reachable");
"#;
let source = v8::String::new(scope, code).unwrap();
let script = v8::Script::compile(scope, source, None).unwrap();
let scope = &mut v8::TryCatch::new(scope);
let _result = script.run(scope);
assert_eq!(CALL_COUNT.load(Ordering::SeqCst), 2);
}
#[test]
fn disallow_javascript_execution_scope() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
// We can run JS before the scope begins.
assert_eq!(
eval(&mut scope, "42").unwrap().uint32_value(&mut scope),
Some(42)
);
{
let try_catch = &mut v8::TryCatch::new(&mut scope);
{
let scope = &mut v8::DisallowJavascriptExecutionScope::new(
try_catch,
v8::OnFailure::ThrowOnFailure,
);
assert!(eval(scope, "42").is_none());
}
assert!(try_catch.has_caught());
try_catch.reset();
}
// And we can run JS after the scope ends.
assert_eq!(
eval(&mut scope, "42").unwrap().uint32_value(&mut scope),
Some(42)
);
}
// TODO: Test DisallowJavascriptExecutionScope with OnFailure::CrashOnFailure
// and OnFailure::DumpOnFailure. #[should_panic] obviously doesn't work on
// those.
#[test]
fn allow_javascript_execution_scope() {
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let disallow_scope = &mut v8::DisallowJavascriptExecutionScope::new(
&mut scope,
v8::OnFailure::CrashOnFailure,
);
let allow_scope = &mut v8::AllowJavascriptExecutionScope::new(disallow_scope);
assert_eq!(
eval(allow_scope, "42").unwrap().uint32_value(allow_scope),
Some(42)
);
}
#[test]
fn allow_scope_in_read_host_object() {
// The scope that is passed to ValueDeserializerImpl::read_host_object is
// internally a DisallowJavascriptExecutionScope, so an allow scope must be
// created in order to run JS code in that callback.
struct Serializer;
impl v8::ValueSerializerImpl for Serializer {
fn write_host_object<'s>(
&mut self,
_scope: &mut v8::HandleScope<'s>,
_object: v8::Local<'s, v8::Object>,
_value_serializer: &mut dyn v8::ValueSerializerHelper,
) -> Option<bool> {
// Doesn't look at the object or writes anything.
Some(true)
}
fn throw_data_clone_error<'s>(
&mut self,
_scope: &mut v8::HandleScope<'s>,
_message: v8::Local<'s, v8::String>,
) {
todo!()
}
}
struct Deserializer;
impl v8::ValueDeserializerImpl for Deserializer {
fn read_host_object<'s>(
&mut self,
scope: &mut v8::HandleScope<'s>,
_value_deserializer: &mut dyn v8::ValueDeserializerHelper,
) -> Option<v8::Local<'s, v8::Object>> {
let scope2 = &mut v8::AllowJavascriptExecutionScope::new(scope);
let value = eval(scope2, "{}").unwrap();
let object = v8::Local::<v8::Object>::try_from(value).unwrap();
Some(object)
}
}
let _setup_guard = setup::parallel_test();
let mut isolate = v8::Isolate::new(Default::default());
let mut scope = v8::HandleScope::new(&mut isolate);
let context = v8::Context::new(&mut scope);
let mut scope = v8::ContextScope::new(&mut scope, context);
let serialized = {
let mut serializer =
v8::ValueSerializer::new(&mut scope, Box::new(Serializer));
serializer
.write_value(context, v8::Object::new(&mut scope).into())
.unwrap();
serializer.release()
};
let mut deserializer =
v8::ValueDeserializer::new(&mut scope, Box::new(Deserializer), &serialized);
let value = deserializer.read_value(context).unwrap();
assert!(value.is_object());
}