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000bd98ae57c9adb387810570341c36e79f62d4b
wasmtime/tests/all/memory.rs
Alex Crichton b14551d7ca Refactor configuration for the pooling allocator (#5205) 
This commit changes the APIs in the `wasmtime` crate for configuring the
pooling allocator. I plan on adding a few more configuration options in
the near future and the current structure was feeling unwieldy for
adding these new abstractions.

The previous `struct`-based API has been replaced with a builder-style
API in a similar shape as to `Config`. This is done to help make it
easier to add more configuration options in the future through adding
more methods as opposed to adding more field which could break prior
initializations.
2022-11-04 20:06:45 +00:00

465 lines
14 KiB
Rust
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use anyhow::Result;
use rayon::prelude::*;
use wasmtime::*;
fn module(engine: &Engine) -> Result<Module> {
let mut wat = format!("(module\n");
wat.push_str("(import \"\" \"\" (memory 0))\n");
for i in 0..=33 {
let offset = if i == 0 {
0
} else if i == 33 {
!0
} else {
1u32 << (i - 1)
};
for (width, instr) in [
(1, &["i32.load8_s"][..]),
(2, &["i32.load16_s"]),
(4, &["i32.load" /*, "f32.load"*/]),
(8, &["i64.load" /*, "f64.load"*/]),
#[cfg(not(any(target_arch = "s390x", target_arch = "riscv64")))]
(16, &["v128.load"]),
]
.iter()
{
for (j, instr) in instr.iter().enumerate() {
wat.push_str(&format!(
"(func (export \"{} {} v{}\") (param i32)\n",
width, offset, j
));
wat.push_str("local.get 0\n");
wat.push_str(instr);
wat.push_str(&format!(" offset={}\n", offset));
wat.push_str("drop\n)");
}
}
}
wat.push_str(")");
Module::new(engine, &wat)
}
struct TestFunc {
width: u32,
offset: u32,
func: TypedFunc<u32, ()>,
}
fn find_funcs(store: &mut Store<()>, instance: &Instance) -> Vec<TestFunc> {
let list = instance
.exports(&mut *store)
.map(|export| {
let name = export.name();
let mut parts = name.split_whitespace();
(
parts.next().unwrap().parse().unwrap(),
parts.next().unwrap().parse().unwrap(),
export.into_func().unwrap(),
)
})
.collect::<Vec<_>>();
list.into_iter()
.map(|(width, offset, func)| TestFunc {
width,
offset,
func: func.typed(&store).unwrap(),
})
.collect()
}
fn test_traps(store: &mut Store<()>, funcs: &[TestFunc], addr: u32, mem: &Memory) {
let mem_size = mem.data_size(&store) as u64;
for func in funcs {
let result = func.func.call(&mut *store, addr);
let base = u64::from(func.offset) + u64::from(addr);
let range = base..base + u64::from(func.width);
if range.start >= mem_size || range.end >= mem_size {
assert!(
result.is_err(),
"access at {}+{}+{} succeeded but should have failed when memory has {} bytes",
addr,
func.offset,
func.width,
mem_size
);
} else {
assert!(result.is_ok());
}
}
}
#[test]
fn offsets_static_dynamic_oh_my() -> Result<()> {
const GB: u64 = 1 << 30;
let mut engines = Vec::new();
let sizes = [0, 1 * GB, 4 * GB];
for &static_memory_maximum_size in sizes.iter() {
for &guard_size in sizes.iter() {
for &guard_before_linear_memory in [true, false].iter() {
let mut config = Config::new();
config.wasm_simd(true);
config.static_memory_maximum_size(static_memory_maximum_size);
config.dynamic_memory_guard_size(guard_size);
config.static_memory_guard_size(guard_size);
config.guard_before_linear_memory(guard_before_linear_memory);
config.cranelift_debug_verifier(true);
engines.push(Engine::new(&config)?);
}
}
}
engines.par_iter().for_each(|engine| {
let module = module(&engine).unwrap();
for (min, max) in [(1, Some(2)), (1, None)].iter() {
let mut store = Store::new(&engine, ());
let mem = Memory::new(&mut store, MemoryType::new(*min, *max)).unwrap();
let instance = Instance::new(&mut store, &module, &[mem.into()]).unwrap();
let funcs = find_funcs(&mut store, &instance);
test_traps(&mut store, &funcs, 0, &mem);
test_traps(&mut store, &funcs, 65536, &mem);
test_traps(&mut store, &funcs, u32::MAX, &mem);
mem.grow(&mut store, 1).unwrap();
test_traps(&mut store, &funcs, 0, &mem);
test_traps(&mut store, &funcs, 65536, &mem);
test_traps(&mut store, &funcs, u32::MAX, &mem);
}
});
Ok(())
}
#[test]
fn guards_present() -> Result<()> {
const GUARD_SIZE: u64 = 65536;
let mut config = Config::new();
config.static_memory_maximum_size(1 << 20);
config.dynamic_memory_guard_size(GUARD_SIZE);
config.static_memory_guard_size(GUARD_SIZE);
config.guard_before_linear_memory(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
let static_mem = Memory::new(&mut store, MemoryType::new(1, Some(2)))?;
let dynamic_mem = Memory::new(&mut store, MemoryType::new(1, None))?;
let assert_guards = |store: &Store<()>| unsafe {
// guards before
println!("check pre-static-mem");
assert_faults(static_mem.data_ptr(&store).offset(-(GUARD_SIZE as isize)));
println!("check pre-dynamic-mem");
assert_faults(dynamic_mem.data_ptr(&store).offset(-(GUARD_SIZE as isize)));
// guards after
println!("check post-static-mem");
assert_faults(
static_mem
.data_ptr(&store)
.add(static_mem.data_size(&store)),
);
println!("check post-dynamic-mem");
assert_faults(
dynamic_mem
.data_ptr(&store)
.add(dynamic_mem.data_size(&store)),
);
};
assert_guards(&store);
// static memory should start with the second page unmapped
unsafe {
assert_faults(static_mem.data_ptr(&store).add(65536));
}
println!("growing");
static_mem.grow(&mut store, 1).unwrap();
dynamic_mem.grow(&mut store, 1).unwrap();
assert_guards(&store);
Ok(())
}
#[test]
fn guards_present_pooling() -> Result<()> {
const GUARD_SIZE: u64 = 65536;
let mut pool = PoolingAllocationConfig::default();
pool.instance_count(2).instance_memory_pages(10);
let mut config = Config::new();
config.static_memory_maximum_size(1 << 20);
config.dynamic_memory_guard_size(GUARD_SIZE);
config.static_memory_guard_size(GUARD_SIZE);
config.guard_before_linear_memory(true);
config.allocation_strategy(InstanceAllocationStrategy::Pooling(pool));
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
let mem1 = {
let m = Module::new(&engine, "(module (memory (export \"\") 1 2))")?;
Instance::new(&mut store, &m, &[])?
.get_memory(&mut store, "")
.unwrap()
};
let mem2 = {
let m = Module::new(&engine, "(module (memory (export \"\") 1))")?;
Instance::new(&mut store, &m, &[])?
.get_memory(&mut store, "")
.unwrap()
};
unsafe fn assert_guards(store: &Store<()>, mem: &Memory) {
// guards before
println!("check pre-mem");
assert_faults(mem.data_ptr(&store).offset(-(GUARD_SIZE as isize)));
// unmapped just after memory
println!("check mem");
assert_faults(mem.data_ptr(&store).add(mem.data_size(&store)));
// guards after memory
println!("check post-mem");
assert_faults(mem.data_ptr(&store).add(1 << 20));
}
unsafe {
assert_guards(&store, &mem1);
assert_guards(&store, &mem2);
println!("growing");
mem1.grow(&mut store, 1).unwrap();
mem2.grow(&mut store, 1).unwrap();
assert_guards(&store, &mem1);
assert_guards(&store, &mem2);
}
Ok(())
}
unsafe fn assert_faults(ptr: *mut u8) {
use std::io::Error;
#[cfg(unix)]
{
// There's probably a faster way to do this here, but, uh, when in rome?
match libc::fork() {
0 => {
*ptr = 4;
std::process::exit(0);
}
-1 => panic!("failed to fork: {}", Error::last_os_error()),
n => {
let mut status = 0;
assert!(
libc::waitpid(n, &mut status, 0) == n,
"failed to wait: {}",
Error::last_os_error()
);
assert!(libc::WIFSIGNALED(status));
}
}
}
#[cfg(windows)]
{
use windows_sys::Win32::System::Memory::*;
let mut info = std::mem::MaybeUninit::uninit();
let r = VirtualQuery(
ptr as *const _,
info.as_mut_ptr(),
std::mem::size_of_val(&info),
);
if r == 0 {
panic!("failed to VirtualAlloc: {}", Error::last_os_error());
}
let info = info.assume_init();
assert_eq!(info.AllocationProtect, PAGE_NOACCESS);
}
}
#[test]
fn massive_64_bit_still_limited() -> Result<()> {
// Creating a 64-bit memory which exceeds the limits of the address space
// should still send a request to the `ResourceLimiter` to ensure that it
// gets at least some chance to see that oom was requested.
let mut config = Config::new();
config.wasm_memory64(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, MyLimiter { hit: false });
store.limiter(|x| x);
let ty = MemoryType::new64(1 << 48, None);
assert!(Memory::new(&mut store, ty).is_err());
assert!(store.data().hit);
return Ok(());
struct MyLimiter {
hit: bool,
}
impl ResourceLimiter for MyLimiter {
fn memory_growing(
&mut self,
_current: usize,
_request: usize,
_max: Option<usize>,
) -> bool {
self.hit = true;
true
}
fn table_growing(&mut self, _current: u32, _request: u32, _max: Option<u32>) -> bool {
unreachable!()
}
}
}
#[test]
fn tiny_static_heap() -> Result<()> {
// The size of the memory in the module below is the exact same size as
// the static memory size limit in the configuration. This is intended to
// specifically test that a load of all the valid addresses of the memory
// all pass bounds-checks in cranelift to help weed out any off-by-one bugs.
let mut config = Config::new();
config.static_memory_maximum_size(65536);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
let module = Module::new(
&engine,
r#"
(module
(memory 1 1)
(func (export "run")
(local $i i32)
(loop
(if (i32.eq (local.get $i) (i32.const 65536))
(return))
(drop (i32.load8_u (local.get $i)))
(local.set $i (i32.add (local.get $i) (i32.const 1)))
br 0
)
)
)
"#,
)?;
let i = Instance::new(&mut store, &module, &[])?;
let f = i.get_typed_func::<(), (), _>(&mut store, "run")?;
f.call(&mut store, ())?;
Ok(())
}
#[test]
fn static_forced_max() -> Result<()> {
let mut config = Config::new();
config.static_memory_maximum_size(5 * 65536);
config.static_memory_forced(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
let mem = Memory::new(&mut store, MemoryType::new(0, None))?;
mem.grow(&mut store, 5).unwrap();
assert!(mem.grow(&mut store, 1).is_err());
Ok(())
}
#[test]
fn dynamic_extra_growth_unchanged_pointer() -> Result<()> {
const EXTRA_PAGES: u64 = 5;
let mut config = Config::new();
config.static_memory_maximum_size(0);
// 5 wasm pages extra
config.dynamic_memory_reserved_for_growth(EXTRA_PAGES * (1 << 16));
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
fn assert_behaves_well(store: &mut Store<()>, mem: &Memory) -> Result<()> {
let ptr = mem.data_ptr(&store);
// Each growth here should retain the same linear pointer in memory and the
// memory shouldn't get moved.
for _ in 0..EXTRA_PAGES {
mem.grow(&mut *store, 1)?;
assert_eq!(ptr, mem.data_ptr(&store));
}
// Growth afterwards though will be forced to move the pointer
mem.grow(&mut *store, 1)?;
let new_ptr = mem.data_ptr(&store);
assert_ne!(ptr, new_ptr);
for _ in 0..EXTRA_PAGES - 1 {
mem.grow(&mut *store, 1)?;
assert_eq!(new_ptr, mem.data_ptr(&store));
}
Ok(())
}
let mem = Memory::new(&mut store, MemoryType::new(10, None))?;
assert_behaves_well(&mut store, &mem)?;
let module = Module::new(&engine, r#"(module (memory (export "mem") 10))"#)?;
let instance = Instance::new(&mut store, &module, &[])?;
let mem = instance.get_memory(&mut store, "mem").unwrap();
assert_behaves_well(&mut store, &mem)?;
let module = Module::new(
&engine,
r#"
(module
(memory (export "mem") 10)
(data (i32.const 0) ""))
"#,
)?;
let instance = Instance::new(&mut store, &module, &[])?;
let mem = instance.get_memory(&mut store, "mem").unwrap();
assert_behaves_well(&mut store, &mem)?;
Ok(())
}
// This test exercises trying to create memories of the maximum 64-bit memory
// size of `1 << 48` pages. This should always fail but in the process of
// determining this failure we shouldn't hit any overflows or anything like that
// (checked via debug-mode tests).
#[test]
fn memory64_maximum_minimum() -> Result<()> {
let mut config = Config::new();
config.wasm_memory64(true);
let engine = Engine::new(&config)?;
let mut store = Store::new(&engine, ());
assert!(Memory::new(&mut store, MemoryType::new64(1 << 48, None)).is_err());
let module = Module::new(
&engine,
&format!(
r#"
(module
(memory i64 {})
)
"#,
1u64 << 48,
),
)?;
assert!(Instance::new(&mut store, &module, &[]).is_err());
let module = Module::new(
&engine,
&format!(
r#"
(module
(memory i64 {})
(data (i64.const 0) "")
)
"#,
1u64 << 48,
),
)?;
assert!(Instance::new(&mut store, &module, &[]).is_err());
Ok(())
}
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