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//! Memory management for executable code.
use crate::subslice_range;
use crate::unwind::UnwindRegistration;
use anyhow::{anyhow, bail, Context, Result};
use object::read::{File, Object, ObjectSection};
use object::ObjectSymbol;
use std::mem;
use std::mem::ManuallyDrop;
use std::ops::Range;
use wasmtime_environ::obj;
use wasmtime_environ::FunctionLoc;
use wasmtime_jit_icache_coherence as icache_coherence;
use wasmtime_runtime::libcalls;
use wasmtime_runtime::{MmapVec, VMTrampoline};
/// Management of executable memory within a `MmapVec`
///
/// This type consumes ownership of a region of memory and will manage the
/// executable permissions of the contained JIT code as necessary.
pub struct CodeMemory {
// NB: these are `ManuallyDrop` because `unwind_registration` must be
// dropped first since it refers to memory owned by `mmap`.
mmap: ManuallyDrop<MmapVec>,
unwind_registration: ManuallyDrop<Option<UnwindRegistration>>,
published: bool,
enable_branch_protection: bool,
relocations: Vec<(usize, obj::LibCall)>,
// Ranges within `self.mmap` of where the particular sections lie.
text: Range<usize>,
unwind: Range<usize>,
trap_data: Range<usize>,
wasm_data: Range<usize>,
address_map_data: Range<usize>,
func_name_data: Range<usize>,
info_data: Range<usize>,
dwarf: Range<usize>,
}
impl Drop for CodeMemory {
fn drop(&mut self) {
// Drop `unwind_registration` before `self.mmap`
unsafe {
ManuallyDrop::drop(&mut self.unwind_registration);
ManuallyDrop::drop(&mut self.mmap);
}
}
}
fn _assert() {
fn _assert_send_sync<T: Send + Sync>() {}
_assert_send_sync::<CodeMemory>();
}
impl CodeMemory {
/// Creates a new `CodeMemory` by taking ownership of the provided
/// `MmapVec`.
///
/// The returned `CodeMemory` manages the internal `MmapVec` and the
/// `publish` method is used to actually make the memory executable.
pub fn new(mmap: MmapVec) -> Result<Self> {
let obj = File::parse(&mmap[..])
.with_context(|| "failed to parse internal compilation artifact")?;
let mut relocations = Vec::new();
let mut text = 0..0;
let mut unwind = 0..0;
let mut enable_branch_protection = None;
let mut trap_data = 0..0;
let mut wasm_data = 0..0;
let mut address_map_data = 0..0;
let mut func_name_data = 0..0;
let mut info_data = 0..0;
let mut dwarf = 0..0;
for section in obj.sections() {
let data = section.data()?;
let name = section.name()?;
let range = subslice_range(data, &mmap);
// Double-check that sections are all aligned properly.
if section.align() != 0 && data.len() != 0 {
if (data.as_ptr() as u64 - mmap.as_ptr() as u64) % section.align() != 0 {
bail!(
"section `{}` isn't aligned to {:#x}",
section.name().unwrap_or("ERROR"),
section.align()
);
}
}
match name {
obj::ELF_WASM_BTI => match data.len() {
1 => enable_branch_protection = Some(data[0] != 0),
_ => bail!("invalid `{name}` section"),
},
".text" => {
text = range;
// The text section might have relocations for things like
// libcalls which need to be applied, so handle those here.
//
// Note that only a small subset of possible relocations are
// handled. Only those required by the compiler side of
// things are processed.
for (offset, reloc) in section.relocations() {
assert_eq!(reloc.kind(), object::RelocationKind::Absolute);
assert_eq!(reloc.encoding(), object::RelocationEncoding::Generic);
assert_eq!(usize::from(reloc.size()), std::mem::size_of::<usize>());
assert_eq!(reloc.addend(), 0);
let sym = match reloc.target() {
object::RelocationTarget::Symbol(id) => id,
other => panic!("unknown relocation target {other:?}"),
};
let sym = obj.symbol_by_index(sym).unwrap().name().unwrap();
let libcall = obj::LibCall::from_str(sym)
.unwrap_or_else(|| panic!("unknown symbol relocation: {sym}"));
let offset = usize::try_from(offset).unwrap();
relocations.push((offset, libcall));
}
}
UnwindRegistration::SECTION_NAME => unwind = range,
obj::ELF_WASM_DATA => wasm_data = range,
obj::ELF_WASMTIME_ADDRMAP => address_map_data = range,
obj::ELF_WASMTIME_TRAPS => trap_data = range,
obj::ELF_NAME_DATA => func_name_data = range,
obj::ELF_WASMTIME_INFO => info_data = range,
obj::ELF_WASMTIME_DWARF => dwarf = range,
_ => log::debug!("ignoring section {name}"),
}
}
Ok(Self {
mmap: ManuallyDrop::new(mmap),
unwind_registration: ManuallyDrop::new(None),
published: false,
enable_branch_protection: enable_branch_protection
.ok_or_else(|| anyhow!("missing `{}` section", obj::ELF_WASM_BTI))?,
text,
unwind,
trap_data,
address_map_data,
func_name_data,
dwarf,
info_data,
wasm_data,
relocations,
})
}
/// Returns a reference to the underlying `MmapVec` this memory owns.
pub fn mmap(&self) -> &MmapVec {
&self.mmap
}
/// Returns the contents of the text section of the ELF executable this
/// represents.
pub fn text(&self) -> &[u8] {
&self.mmap[self.text.clone()]
}
/// Returns the contents of the `ELF_WASMTIME_DWARF` section.
pub fn dwarf(&self) -> &[u8] {
&self.mmap[self.dwarf.clone()]
}
/// Returns the data in the `ELF_NAME_DATA` section.
pub fn func_name_data(&self) -> &[u8] {
&self.mmap[self.func_name_data.clone()]
}
/// Returns the concatenated list of all data associated with this wasm
/// module.
///
/// This is used for initialization of memories and all data ranges stored
/// in a `Module` are relative to the slice returned here.
pub fn wasm_data(&self) -> &[u8] {
&self.mmap[self.wasm_data.clone()]
}
/// Returns the encoded address map section used to pass to
/// `wasmtime_environ::lookup_file_pos`.
pub fn address_map_data(&self) -> &[u8] {
&self.mmap[self.address_map_data.clone()]
}
/// Returns the contents of the `ELF_WASMTIME_INFO` section, or an empty
/// slice if it wasn't found.
pub fn wasmtime_info(&self) -> &[u8] {
&self.mmap[self.info_data.clone()]
}
/// Returns the contents of the `ELF_WASMTIME_TRAPS` section, or an empty
/// slice if it wasn't found.
pub fn trap_data(&self) -> &[u8] {
&self.mmap[self.trap_data.clone()]
}
/// Returns a `VMTrampoline` function pointer for the given function in the
/// text section.
///
/// # Unsafety
///
/// This function is unsafe as there's no guarantee that the returned
/// function pointer is valid.
pub unsafe fn vmtrampoline(&self, loc: FunctionLoc) -> VMTrampoline {
let ptr = self.text()[loc.start as usize..][..loc.length as usize].as_ptr();
mem::transmute::<*const u8, VMTrampoline>(ptr)
}
/// Publishes the internal ELF image to be ready for execution.
///
/// This method can only be called once and will panic if called twice. This
/// will parse the ELF image from the original `MmapVec` and do everything
/// necessary to get it ready for execution, including:
///
/// * Change page protections from read/write to read/execute.
/// * Register unwinding information with the OS
///
/// After this function executes all JIT code should be ready to execute.
pub fn publish(&mut self) -> Result<()> {
assert!(!self.published);
self.published = true;
if self.text().is_empty() {
return Ok(());
}
// The unsafety here comes from a few things:
//
// * We're actually updating some page protections to executable memory.
//
// * We're registering unwinding information which relies on the
// correctness of the information in the first place. This applies to
// both the actual unwinding tables as well as the validity of the
// pointers we pass in itself.
unsafe {
// First, if necessary, apply relocations. This can happen for
// things like libcalls which happen late in the lowering process
// that don't go through the Wasm-based libcalls layer that's
// indirected through the `VMContext`. Note that most modules won't
// have relocations, so this typically doesn't do anything.
self.apply_relocations()?;
// Next freeze the contents of this image by making all of the
// memory readonly. Nothing after this point should ever be modified
// so commit everything. For a compiled-in-memory image this will
// mean IPIs to evict writable mappings from other cores. For
// loaded-from-disk images this shouldn't result in IPIs so long as
// there weren't any relocations because nothing should have
// otherwise written to the image at any point either.
self.mmap.make_readonly(0..self.mmap.len())?;
let text = self.text();
// Clear the newly allocated code from cache if the processor requires it
//
// Do this before marking the memory as R+X, technically we should be able to do it after
// but there are some CPU's that have had errata about doing this with read only memory.
icache_coherence::clear_cache(text.as_ptr().cast(), text.len())
.expect("Failed cache clear");
// Switch the executable portion from readonly to read/execute.
self.mmap
.make_executable(self.text.clone(), self.enable_branch_protection)
.expect("unable to make memory executable");
// Flush any in-flight instructions from the pipeline
icache_coherence::pipeline_flush_mt().expect("Failed pipeline flush");
// With all our memory set up use the platform-specific
// `UnwindRegistration` implementation to inform the general
// runtime that there's unwinding information available for all
// our just-published JIT functions.
self.register_unwind_info()?;
}
Ok(())
}
unsafe fn apply_relocations(&mut self) -> Result<()> {
if self.relocations.is_empty() {
return Ok(());
}
for (offset, libcall) in self.relocations.iter() {
let offset = self.text.start + offset;
let libcall = match libcall {
obj::LibCall::FloorF32 => libcalls::relocs::floorf32 as usize,
obj::LibCall::FloorF64 => libcalls::relocs::floorf64 as usize,
obj::LibCall::NearestF32 => libcalls::relocs::nearestf32 as usize,
obj::LibCall::NearestF64 => libcalls::relocs::nearestf64 as usize,
obj::LibCall::CeilF32 => libcalls::relocs::ceilf32 as usize,
obj::LibCall::CeilF64 => libcalls::relocs::ceilf64 as usize,
obj::LibCall::TruncF32 => libcalls::relocs::truncf32 as usize,
obj::LibCall::TruncF64 => libcalls::relocs::truncf64 as usize,
};
*self.mmap.as_mut_ptr().add(offset).cast::<usize>() = libcall;
}
Ok(())
}
unsafe fn register_unwind_info(&mut self) -> Result<()> {
if self.unwind.len() == 0 {
return Ok(());
}
let text = self.text();
let unwind_info = &self.mmap[self.unwind.clone()];
let registration =
UnwindRegistration::new(text.as_ptr(), unwind_info.as_ptr(), unwind_info.len())
.context("failed to create unwind info registration")?;
*self.unwind_registration = Some(registration);
Ok(())
}
}