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wasmtime/cranelift/wasm/src/environ/dummy.rs
Chris Fallin 43f1765272 Cranellift: remove Baldrdash support and related features. (#4571) 
* Cranellift: remove Baldrdash support and related features.

As noted in Mozilla's bugzilla bug 1781425 [1], the SpiderMonkey team
has recently determined that their current form of integration with
Cranelift is too hard to maintain, and they have chosen to remove it
from their codebase. If and when they decide to build updated support
for Cranelift, they will adopt different approaches to several details
of the integration.

In the meantime, after discussion with the SpiderMonkey folks, they
agree that it makes sense to remove the bits of Cranelift that exist
to support the integration ("Baldrdash"), as they will not need
them. Many of these bits are difficult-to-maintain special cases that
are not actually tested in Cranelift proper: for example, the
Baldrdash integration required Cranelift to emit function bodies
without prologues/epilogues, and instead communicate very precise
information about the expected frame size and layout, then stitched
together something post-facto. This was brittle and caused a lot of
incidental complexity ("fallthrough returns", the resulting special
logic in block-ordering); this is just one example. As another
example, one particular Baldrdash ABI variant processed stack args in
reverse order, so our ABI code had to support both traversal
orders. We had a number of other Baldrdash-specific settings as well
that did various special things.

This PR removes Baldrdash ABI support, the `fallthrough_return`
instruction, and pulls some threads to remove now-unused bits as a
result of those two, with the  understanding that the SpiderMonkey folks
will build new functionality as needed in the future and we can perhaps
find cleaner abstractions to make it all work.

[1] https://bugzilla.mozilla.org/show_bug.cgi?id=1781425

* Review feedback.

* Fix (?) DWARF debug tests: add `--disable-cache` to wasmtime invocations.

The debugger tests invoke `wasmtime` from within each test case under
the control of a debugger (gdb or lldb). Some of these tests started to
inexplicably fail in CI with unrelated changes, and the failures were
only inconsistently reproducible locally. It seems to be cache related:
if we disable cached compilation on the nested `wasmtime` invocations,
the tests consistently pass.

* Review feedback.
2022-08-02 19:37:56 +00:00

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//! "Dummy" implementations of `ModuleEnvironment` and `FuncEnvironment` for testing
//! wasm translation. For complete implementations of `ModuleEnvironment` and
//! `FuncEnvironment`, see [wasmtime-environ] in [Wasmtime].
//!
//! [wasmtime-environ]: https://crates.io/crates/wasmtime-environ
//! [Wasmtime]: https://github.com/bytecodealliance/wasmtime
use crate::environ::{FuncEnvironment, GlobalVariable, ModuleEnvironment, TargetEnvironment};
use crate::func_translator::FuncTranslator;
use crate::state::FuncTranslationState;
use crate::WasmType;
use crate::{
DataIndex, DefinedFuncIndex, ElemIndex, FuncIndex, Global, GlobalIndex, Memory, MemoryIndex,
Table, TableIndex, TypeIndex, WasmFuncType, WasmResult,
};
use core::convert::TryFrom;
use cranelift_codegen::cursor::FuncCursor;
use cranelift_codegen::ir::immediates::{Offset32, Uimm64};
use cranelift_codegen::ir::types::*;
use cranelift_codegen::ir::{self, InstBuilder};
use cranelift_codegen::isa::{CallConv, TargetFrontendConfig};
use cranelift_entity::{EntityRef, PrimaryMap, SecondaryMap};
use cranelift_frontend::FunctionBuilder;
use std::boxed::Box;
use std::string::String;
use std::vec::Vec;
use wasmparser::{FuncValidator, FunctionBody, Operator, ValidatorResources, WasmFeatures};
/// Compute a `ir::ExternalName` for a given wasm function index.
fn get_func_name(func_index: FuncIndex) -> ir::ExternalName {
ir::ExternalName::user(0, func_index.as_u32())
}
/// A collection of names under which a given entity is exported.
pub struct Exportable<T> {
/// A wasm entity.
pub entity: T,
/// Names under which the entity is exported.
pub export_names: Vec<String>,
}
impl<T> Exportable<T> {
pub fn new(entity: T) -> Self {
Self {
entity,
export_names: Vec::new(),
}
}
}
/// The main state belonging to a `DummyEnvironment`. This is split out from
/// `DummyEnvironment` to allow it to be borrowed separately from the
/// `FuncTranslator` field.
pub struct DummyModuleInfo {
/// Target description relevant to frontends producing Cranelift IR.
config: TargetFrontendConfig,
/// Signatures as provided by `declare_signature`.
pub signatures: PrimaryMap<TypeIndex, ir::Signature>,
/// Module and field names of imported functions as provided by `declare_func_import`.
pub imported_funcs: Vec<(String, String)>,
/// Module and field names of imported globals as provided by `declare_global_import`.
pub imported_globals: Vec<(String, String)>,
/// Module and field names of imported tables as provided by `declare_table_import`.
pub imported_tables: Vec<(String, String)>,
/// Module and field names of imported memories as provided by `declare_memory_import`.
pub imported_memories: Vec<(String, String)>,
/// Functions, imported and local.
pub functions: PrimaryMap<FuncIndex, Exportable<TypeIndex>>,
/// Function bodies.
pub function_bodies: PrimaryMap<DefinedFuncIndex, ir::Function>,
/// Tables as provided by `declare_table`.
pub tables: PrimaryMap<TableIndex, Exportable<Table>>,
/// Memories as provided by `declare_memory`.
pub memories: PrimaryMap<MemoryIndex, Exportable<Memory>>,
/// Globals as provided by `declare_global`.
pub globals: PrimaryMap<GlobalIndex, Exportable<Global>>,
/// The start function.
pub start_func: Option<FuncIndex>,
}
impl DummyModuleInfo {
/// Creates a new `DummyModuleInfo` instance.
pub fn new(config: TargetFrontendConfig) -> Self {
Self {
config,
signatures: PrimaryMap::new(),
imported_funcs: Vec::new(),
imported_globals: Vec::new(),
imported_tables: Vec::new(),
imported_memories: Vec::new(),
functions: PrimaryMap::new(),
function_bodies: PrimaryMap::new(),
tables: PrimaryMap::new(),
memories: PrimaryMap::new(),
globals: PrimaryMap::new(),
start_func: None,
}
}
}
/// State for tracking and checking reachability at each operator. Used for unit testing with the
/// `DummyEnvironment`.
#[derive(Clone)]
pub struct ExpectedReachability {
/// Before- and after-reachability
reachability: Vec<(bool, bool)>,
before_idx: usize,
after_idx: usize,
}
impl ExpectedReachability {
fn check_before(&mut self, reachable: bool) {
assert_eq!(reachable, self.reachability[self.before_idx].0);
self.before_idx += 1;
}
fn check_after(&mut self, reachable: bool) {
assert_eq!(reachable, self.reachability[self.after_idx].1);
self.after_idx += 1;
}
fn check_end(&self) {
assert_eq!(self.before_idx, self.reachability.len());
assert_eq!(self.after_idx, self.reachability.len());
}
}
/// This `ModuleEnvironment` implementation is a "naïve" one, doing essentially nothing and
/// emitting placeholders when forced to. Don't try to execute code translated for this
/// environment, essentially here for translation debug purposes.
pub struct DummyEnvironment {
/// Module information.
pub info: DummyModuleInfo,
/// Function translation.
trans: FuncTranslator,
/// Vector of wasm bytecode size for each function.
pub func_bytecode_sizes: Vec<usize>,
/// Instructs to collect debug data during translation.
debug_info: bool,
/// Name of the module from the wasm file.
pub module_name: Option<String>,
/// Function names.
function_names: SecondaryMap<FuncIndex, String>,
/// Expected reachability data (before/after for each op) to assert. This is used for testing.
expected_reachability: Option<ExpectedReachability>,
}
impl DummyEnvironment {
/// Creates a new `DummyEnvironment` instance.
pub fn new(config: TargetFrontendConfig, debug_info: bool) -> Self {
Self {
info: DummyModuleInfo::new(config),
trans: FuncTranslator::new(),
func_bytecode_sizes: Vec::new(),
debug_info,
module_name: None,
function_names: SecondaryMap::new(),
expected_reachability: None,
}
}
/// Return a `DummyFuncEnvironment` for translating functions within this
/// `DummyEnvironment`.
pub fn func_env(&self) -> DummyFuncEnvironment {
DummyFuncEnvironment::new(&self.info, self.expected_reachability.clone())
}
fn get_func_type(&self, func_index: FuncIndex) -> TypeIndex {
self.info.functions[func_index].entity
}
/// Return the number of imported functions within this `DummyEnvironment`.
pub fn get_num_func_imports(&self) -> usize {
self.info.imported_funcs.len()
}
/// Return the name of the function, if a name for the function with
/// the corresponding index exists.
pub fn get_func_name(&self, func_index: FuncIndex) -> Option<&str> {
self.function_names.get(func_index).map(String::as_ref)
}
/// Test reachability bits before and after every opcode during translation, as provided by the
/// `FuncTranslationState`. This is generally used only for unit tests. This is applied to
/// every function in the module (so is likely only useful for test modules with one function).
pub fn test_expected_reachability(&mut self, reachability: Vec<(bool, bool)>) {
self.expected_reachability = Some(ExpectedReachability {
reachability,
before_idx: 0,
after_idx: 0,
});
}
}
/// The `FuncEnvironment` implementation for use by the `DummyEnvironment`.
pub struct DummyFuncEnvironment<'dummy_environment> {
pub mod_info: &'dummy_environment DummyModuleInfo,
/// Expected reachability data (before/after for each op) to assert. This is used for testing.
expected_reachability: Option<ExpectedReachability>,
}
impl<'dummy_environment> DummyFuncEnvironment<'dummy_environment> {
pub fn new(
mod_info: &'dummy_environment DummyModuleInfo,
expected_reachability: Option<ExpectedReachability>,
) -> Self {
Self {
mod_info,
expected_reachability,
}
}
// Create a signature for `sigidx` amended with a `vmctx` argument after the standard wasm
// arguments.
fn vmctx_sig(&self, sigidx: TypeIndex) -> ir::Signature {
let mut sig = self.mod_info.signatures[sigidx].clone();
sig.params.push(ir::AbiParam::special(
self.pointer_type(),
ir::ArgumentPurpose::VMContext,
));
sig
}
fn reference_type(&self) -> ir::Type {
match self.pointer_type() {
ir::types::I32 => ir::types::R32,
ir::types::I64 => ir::types::R64,
_ => panic!("unsupported pointer type"),
}
}
}
impl<'dummy_environment> TargetEnvironment for DummyFuncEnvironment<'dummy_environment> {
fn target_config(&self) -> TargetFrontendConfig {
self.mod_info.config
}
}
impl<'dummy_environment> FuncEnvironment for DummyFuncEnvironment<'dummy_environment> {
fn make_global(
&mut self,
func: &mut ir::Function,
index: GlobalIndex,
) -> WasmResult<GlobalVariable> {
// Just create a dummy `vmctx` global.
let offset = i32::try_from((index.index() * 8) + 8).unwrap().into();
let vmctx = func.create_global_value(ir::GlobalValueData::VMContext {});
Ok(GlobalVariable::Memory {
gv: vmctx,
offset,
ty: match self.mod_info.globals[index].entity.wasm_ty {
WasmType::I32 => ir::types::I32,
WasmType::I64 => ir::types::I64,
WasmType::F32 => ir::types::F32,
WasmType::F64 => ir::types::F64,
WasmType::V128 => ir::types::I8X16,
WasmType::FuncRef | WasmType::ExternRef => ir::types::R64,
},
})
}
fn make_heap(&mut self, func: &mut ir::Function, _index: MemoryIndex) -> WasmResult<ir::Heap> {
// Create a static heap whose base address is stored at `vmctx+0`.
let addr = func.create_global_value(ir::GlobalValueData::VMContext);
let gv = func.create_global_value(ir::GlobalValueData::Load {
base: addr,
offset: Offset32::new(0),
global_type: self.pointer_type(),
readonly: true,
});
Ok(func.create_heap(ir::HeapData {
base: gv,
min_size: 0.into(),
offset_guard_size: 0x8000_0000.into(),
style: ir::HeapStyle::Static {
bound: 0x1_0000_0000.into(),
},
index_type: I32,
}))
}
fn make_table(&mut self, func: &mut ir::Function, _index: TableIndex) -> WasmResult<ir::Table> {
// Create a table whose base address is stored at `vmctx+0`.
let vmctx = func.create_global_value(ir::GlobalValueData::VMContext);
let base_gv = func.create_global_value(ir::GlobalValueData::Load {
base: vmctx,
offset: Offset32::new(0),
global_type: self.pointer_type(),
readonly: true, // when tables in wasm become "growable", revisit whether this can be readonly or not.
});
let bound_gv = func.create_global_value(ir::GlobalValueData::Load {
base: vmctx,
offset: Offset32::new(0),
global_type: I32,
readonly: true,
});
Ok(func.create_table(ir::TableData {
base_gv,
min_size: Uimm64::new(0),
bound_gv,
element_size: Uimm64::from(u64::from(self.pointer_bytes()) * 2),
index_type: I32,
}))
}
fn make_indirect_sig(
&mut self,
func: &mut ir::Function,
index: TypeIndex,
) -> WasmResult<ir::SigRef> {
// A real implementation would probably change the calling convention and add `vmctx` and
// signature index arguments.
Ok(func.import_signature(self.vmctx_sig(index)))
}
fn make_direct_func(
&mut self,
func: &mut ir::Function,
index: FuncIndex,
) -> WasmResult<ir::FuncRef> {
let sigidx = self.mod_info.functions[index].entity;
// A real implementation would probably add a `vmctx` argument.
// And maybe attempt some signature de-duplication.
let signature = func.import_signature(self.vmctx_sig(sigidx));
let name = get_func_name(index);
Ok(func.import_function(ir::ExtFuncData {
name,
signature,
colocated: false,
}))
}
fn before_translate_operator(
&mut self,
_op: &Operator,
_builder: &mut FunctionBuilder,
state: &FuncTranslationState,
) -> WasmResult<()> {
if let Some(ref mut r) = &mut self.expected_reachability {
r.check_before(state.reachable());
}
Ok(())
}
fn after_translate_operator(
&mut self,
_op: &Operator,
_builder: &mut FunctionBuilder,
state: &FuncTranslationState,
) -> WasmResult<()> {
if let Some(ref mut r) = &mut self.expected_reachability {
r.check_after(state.reachable());
}
Ok(())
}
fn after_translate_function(
&mut self,
_builder: &mut FunctionBuilder,
_state: &FuncTranslationState,
) -> WasmResult<()> {
if let Some(ref mut r) = &mut self.expected_reachability {
r.check_end();
}
Ok(())
}
fn translate_call_indirect(
&mut self,
builder: &mut FunctionBuilder,
_table_index: TableIndex,
_table: ir::Table,
_sig_index: TypeIndex,
sig_ref: ir::SigRef,
callee: ir::Value,
call_args: &[ir::Value],
) -> WasmResult<ir::Inst> {
// Pass the current function's vmctx parameter on to the callee.
let vmctx = builder
.func
.special_param(ir::ArgumentPurpose::VMContext)
.expect("Missing vmctx parameter");
// The `callee` value is an index into a table of function pointers.
// Apparently, that table is stored at absolute address 0 in this dummy environment.
// TODO: Generate bounds checking code.
let ptr = self.pointer_type();
let callee_offset = if ptr == I32 {
builder.ins().imul_imm(callee, 4)
} else {
let ext = builder.ins().uextend(I64, callee);
builder.ins().imul_imm(ext, 4)
};
let mflags = ir::MemFlags::trusted();
let func_ptr = builder.ins().load(ptr, mflags, callee_offset, 0);
// Build a value list for the indirect call instruction containing the callee, call_args,
// and the vmctx parameter.
let mut args = ir::ValueList::default();
args.push(func_ptr, &mut builder.func.dfg.value_lists);
args.extend(call_args.iter().cloned(), &mut builder.func.dfg.value_lists);
args.push(vmctx, &mut builder.func.dfg.value_lists);
Ok(builder
.ins()
.CallIndirect(ir::Opcode::CallIndirect, INVALID, sig_ref, args)
.0)
}
fn translate_call(
&mut self,
mut pos: FuncCursor,
_callee_index: FuncIndex,
callee: ir::FuncRef,
call_args: &[ir::Value],
) -> WasmResult<ir::Inst> {
// Pass the current function's vmctx parameter on to the callee.
let vmctx = pos
.func
.special_param(ir::ArgumentPurpose::VMContext)
.expect("Missing vmctx parameter");
// Build a value list for the call instruction containing the call_args and the vmctx
// parameter.
let mut args = ir::ValueList::default();
args.extend(call_args.iter().cloned(), &mut pos.func.dfg.value_lists);
args.push(vmctx, &mut pos.func.dfg.value_lists);
Ok(pos.ins().Call(ir::Opcode::Call, INVALID, callee, args).0)
}
fn translate_memory_grow(
&mut self,
mut pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
_val: ir::Value,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_memory_size(
&mut self,
mut pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_memory_copy(
&mut self,
_pos: FuncCursor,
_src_index: MemoryIndex,
_src_heap: ir::Heap,
_dst_index: MemoryIndex,
_dst_heap: ir::Heap,
_dst: ir::Value,
_src: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_memory_fill(
&mut self,
_pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
_dst: ir::Value,
_val: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_memory_init(
&mut self,
_pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
_seg_index: u32,
_dst: ir::Value,
_src: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_data_drop(&mut self, _pos: FuncCursor, _seg_index: u32) -> WasmResult<()> {
Ok(())
}
fn translate_table_size(
&mut self,
mut pos: FuncCursor,
_index: TableIndex,
_table: ir::Table,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_table_grow(
&mut self,
mut pos: FuncCursor,
_table_index: TableIndex,
_table: ir::Table,
_delta: ir::Value,
_init_value: ir::Value,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_table_get(
&mut self,
builder: &mut FunctionBuilder,
_table_index: TableIndex,
_table: ir::Table,
_index: ir::Value,
) -> WasmResult<ir::Value> {
Ok(builder.ins().null(self.reference_type()))
}
fn translate_table_set(
&mut self,
_builder: &mut FunctionBuilder,
_table_index: TableIndex,
_table: ir::Table,
_value: ir::Value,
_index: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_table_copy(
&mut self,
_pos: FuncCursor,
_dst_index: TableIndex,
_dst_table: ir::Table,
_src_index: TableIndex,
_src_table: ir::Table,
_dst: ir::Value,
_src: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_table_fill(
&mut self,
_pos: FuncCursor,
_table_index: TableIndex,
_dst: ir::Value,
_val: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_table_init(
&mut self,
_pos: FuncCursor,
_seg_index: u32,
_table_index: TableIndex,
_table: ir::Table,
_dst: ir::Value,
_src: ir::Value,
_len: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_elem_drop(&mut self, _pos: FuncCursor, _seg_index: u32) -> WasmResult<()> {
Ok(())
}
fn translate_ref_func(
&mut self,
mut pos: FuncCursor,
_func_index: FuncIndex,
) -> WasmResult<ir::Value> {
Ok(pos.ins().null(self.reference_type()))
}
fn translate_custom_global_get(
&mut self,
mut pos: FuncCursor,
_global_index: GlobalIndex,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_custom_global_set(
&mut self,
_pos: FuncCursor,
_global_index: GlobalIndex,
_val: ir::Value,
) -> WasmResult<()> {
Ok(())
}
fn translate_atomic_wait(
&mut self,
mut pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
_addr: ir::Value,
_expected: ir::Value,
_timeout: ir::Value,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, -1))
}
fn translate_atomic_notify(
&mut self,
mut pos: FuncCursor,
_index: MemoryIndex,
_heap: ir::Heap,
_addr: ir::Value,
_count: ir::Value,
) -> WasmResult<ir::Value> {
Ok(pos.ins().iconst(I32, 0))
}
fn unsigned_add_overflow_condition(&self) -> ir::condcodes::IntCC {
unimplemented!()
}
}
impl TargetEnvironment for DummyEnvironment {
fn target_config(&self) -> TargetFrontendConfig {
self.info.config
}
}
impl<'data> ModuleEnvironment<'data> for DummyEnvironment {
fn declare_type_func(&mut self, wasm: WasmFuncType) -> WasmResult<()> {
let mut sig = ir::Signature::new(CallConv::Fast);
let mut cvt = |ty: &WasmType| {
let reference_type = match self.pointer_type() {
ir::types::I32 => ir::types::R32,
ir::types::I64 => ir::types::R64,
_ => panic!("unsupported pointer type"),
};
ir::AbiParam::new(match ty {
WasmType::I32 => ir::types::I32,
WasmType::I64 => ir::types::I64,
WasmType::F32 => ir::types::F32,
WasmType::F64 => ir::types::F64,
WasmType::V128 => ir::types::I8X16,
WasmType::FuncRef | WasmType::ExternRef => reference_type,
})
};
sig.params.extend(wasm.params().iter().map(&mut cvt));
sig.returns.extend(wasm.returns().iter().map(&mut cvt));
self.info.signatures.push(sig);
Ok(())
}
fn declare_func_import(
&mut self,
index: TypeIndex,
module: &'data str,
field: &'data str,
) -> WasmResult<()> {
assert_eq!(
self.info.functions.len(),
self.info.imported_funcs.len(),
"Imported functions must be declared first"
);
self.info.functions.push(Exportable::new(index));
self.info
.imported_funcs
.push((String::from(module), String::from(field)));
Ok(())
}
fn declare_func_type(&mut self, index: TypeIndex) -> WasmResult<()> {
self.info.functions.push(Exportable::new(index));
Ok(())
}
fn declare_global(&mut self, global: Global) -> WasmResult<()> {
self.info.globals.push(Exportable::new(global));
Ok(())
}
fn declare_global_import(
&mut self,
global: Global,
module: &'data str,
field: &'data str,
) -> WasmResult<()> {
self.info.globals.push(Exportable::new(global));
self.info
.imported_globals
.push((String::from(module), String::from(field)));
Ok(())
}
fn declare_table(&mut self, table: Table) -> WasmResult<()> {
self.info.tables.push(Exportable::new(table));
Ok(())
}
fn declare_table_import(
&mut self,
table: Table,
module: &'data str,
field: &'data str,
) -> WasmResult<()> {
self.info.tables.push(Exportable::new(table));
self.info
.imported_tables
.push((String::from(module), String::from(field)));
Ok(())
}
fn declare_table_elements(
&mut self,
_table_index: TableIndex,
_base: Option<GlobalIndex>,
_offset: u32,
_elements: Box<[FuncIndex]>,
) -> WasmResult<()> {
// We do nothing
Ok(())
}
fn declare_passive_element(
&mut self,
_elem_index: ElemIndex,
_segments: Box<[FuncIndex]>,
) -> WasmResult<()> {
Ok(())
}
fn declare_passive_data(
&mut self,
_elem_index: DataIndex,
_segments: &'data [u8],
) -> WasmResult<()> {
Ok(())
}
fn declare_memory(&mut self, memory: Memory) -> WasmResult<()> {
self.info.memories.push(Exportable::new(memory));
Ok(())
}
fn declare_memory_import(
&mut self,
memory: Memory,
module: &'data str,
field: &'data str,
) -> WasmResult<()> {
self.info.memories.push(Exportable::new(memory));
self.info
.imported_memories
.push((String::from(module), String::from(field)));
Ok(())
}
fn declare_data_initialization(
&mut self,
_memory_index: MemoryIndex,
_base: Option<GlobalIndex>,
_offset: u64,
_data: &'data [u8],
) -> WasmResult<()> {
// We do nothing
Ok(())
}
fn declare_func_export(&mut self, func_index: FuncIndex, name: &'data str) -> WasmResult<()> {
self.info.functions[func_index]
.export_names
.push(String::from(name));
Ok(())
}
fn declare_table_export(
&mut self,
table_index: TableIndex,
name: &'data str,
) -> WasmResult<()> {
self.info.tables[table_index]
.export_names
.push(String::from(name));
Ok(())
}
fn declare_memory_export(
&mut self,
memory_index: MemoryIndex,
name: &'data str,
) -> WasmResult<()> {
self.info.memories[memory_index]
.export_names
.push(String::from(name));
Ok(())
}
fn declare_global_export(
&mut self,
global_index: GlobalIndex,
name: &'data str,
) -> WasmResult<()> {
self.info.globals[global_index]
.export_names
.push(String::from(name));
Ok(())
}
fn declare_start_func(&mut self, func_index: FuncIndex) -> WasmResult<()> {
debug_assert!(self.info.start_func.is_none());
self.info.start_func = Some(func_index);
Ok(())
}
fn define_function_body(
&mut self,
mut validator: FuncValidator<ValidatorResources>,
body: FunctionBody<'data>,
) -> WasmResult<()> {
self.func_bytecode_sizes
.push(body.get_binary_reader().bytes_remaining());
let func = {
let mut func_environ =
DummyFuncEnvironment::new(&self.info, self.expected_reachability.clone());
let func_index =
FuncIndex::new(self.get_num_func_imports() + self.info.function_bodies.len());
let name = get_func_name(func_index);
let sig = func_environ.vmctx_sig(self.get_func_type(func_index));
let mut func = ir::Function::with_name_signature(name, sig);
if self.debug_info {
func.collect_debug_info();
}
self.trans
.translate_body(&mut validator, body, &mut func, &mut func_environ)?;
func
};
self.info.function_bodies.push(func);
Ok(())
}
fn declare_module_name(&mut self, name: &'data str) {
self.module_name = Some(String::from(name));
}
fn declare_func_name(&mut self, func_index: FuncIndex, name: &'data str) {
self.function_names[func_index] = String::from(name);
}
fn wasm_features(&self) -> WasmFeatures {
WasmFeatures {
multi_value: true,
simd: true,
reference_types: true,
bulk_memory: true,
..WasmFeatures::default()
}
}
}
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