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#![cfg_attr(not(feature = "std"), no_std)]
#[cfg(not(feature = "std"))]
#[macro_use]
extern crate alloc;
#[cfg(feature = "std")]
extern crate std as alloc;
pub mod stack;
pub const DEFAULT_MEMORY_INDEX: u32 = 0;
pub const DEFAULT_TABLE_INDEX: u32 = 0;
pub const LINEAR_MEMORY_MAX_PAGES: u32 = 65536;
use alloc::{string::String, vec::Vec};
use core::fmt;
#[cfg(feature = "std")]
use std::error;
use self::context::ModuleContextBuilder;
use parity_wasm::elements::{
BlockType,
ExportEntry,
External,
FuncBody,
GlobalEntry,
GlobalType,
InitExpr,
Instruction,
Internal,
MemoryType,
Module,
ResizableLimits,
TableType,
Type,
ValueType,
};
pub mod context;
pub mod func;
pub mod util;
#[cfg(test)]
mod tests;
#[derive(Debug)]
pub struct Error(pub String);
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "{}", self.0)
}
}
#[cfg(feature = "std")]
impl error::Error for Error {
fn description(&self) -> &str {
&self.0
}
}
impl From<stack::Error> for Error {
fn from(e: stack::Error) -> Error {
Error(format!("Stack: {}", e))
}
}
pub trait Validator {
type Input;
type Output;
type FuncValidator: FuncValidator;
fn new(module: &Module, input: Self::Input) -> Self;
fn func_validator_input(&mut self) -> <Self::FuncValidator as FuncValidator>::Input;
fn on_function_validated(
&mut self,
index: u32,
output: <<Self as Validator>::FuncValidator as FuncValidator>::Output,
);
fn finish(self) -> Self::Output;
}
pub trait FuncValidator {
type Input;
type Output;
fn new(ctx: &func::FunctionValidationContext, body: &FuncBody, input: Self::Input) -> Self;
fn next_instruction(
&mut self,
ctx: &mut func::FunctionValidationContext,
instruction: &Instruction,
) -> Result<(), Error>;
fn finish(self, ctx: &func::FunctionValidationContext) -> Self::Output;
}
pub struct PlainValidator;
impl Validator for PlainValidator {
type Input = ();
type Output = ();
type FuncValidator = PlainFuncValidator;
fn new(_module: &Module, _args: Self::Input) -> PlainValidator {
PlainValidator
}
fn func_validator_input(&mut self) -> <Self::FuncValidator as FuncValidator>::Input {}
fn on_function_validated(
&mut self,
_index: u32,
_output: <<Self as Validator>::FuncValidator as FuncValidator>::Output,
) {
}
fn finish(self) {}
}
pub struct PlainFuncValidator;
impl FuncValidator for PlainFuncValidator {
type Input = ();
type Output = ();
fn new(
_ctx: &func::FunctionValidationContext,
_body: &FuncBody,
_input: Self::Input,
) -> PlainFuncValidator {
PlainFuncValidator
}
fn next_instruction(
&mut self,
ctx: &mut func::FunctionValidationContext,
instruction: &Instruction,
) -> Result<(), Error> {
ctx.step(instruction)
}
fn finish(self, _ctx: &func::FunctionValidationContext) {}
}
pub fn validate_module<V: Validator>(
module: &Module,
input: <V as Validator>::Input,
) -> Result<V::Output, Error> {
let mut context_builder = ModuleContextBuilder::new();
let mut imported_globals = Vec::new();
let mut validation = V::new(module, input);
context_builder.set_types(
module
.type_section()
.map(|ts| {
ts.types()
.iter()
.map(|&Type::Function(ref ty)| ty)
.cloned()
.collect()
})
.unwrap_or_default(),
);
for import_entry in module
.import_section()
.map(|i| i.entries())
.unwrap_or_default()
{
match *import_entry.external() {
External::Function(idx) => context_builder.push_func_type_index(idx),
External::Table(ref table) => context_builder.push_table(*table),
External::Memory(ref memory) => context_builder.push_memory(*memory),
External::Global(ref global) => {
context_builder.push_global(*global);
imported_globals.push(*global);
}
}
}
if let Some(function_section) = module.function_section() {
for func_entry in function_section.entries() {
context_builder.push_func_type_index(func_entry.type_ref())
}
}
if let Some(table_section) = module.table_section() {
for table_entry in table_section.entries() {
validate_table_type(table_entry)?;
context_builder.push_table(*table_entry);
}
}
if let Some(mem_section) = module.memory_section() {
for mem_entry in mem_section.entries() {
validate_memory_type(mem_entry)?;
context_builder.push_memory(*mem_entry);
}
}
if let Some(global_section) = module.global_section() {
for global_entry in global_section.entries() {
validate_global_entry(global_entry, &imported_globals)?;
context_builder.push_global(*global_entry.global_type());
}
}
let context = context_builder.build();
let function_section_len = module
.function_section()
.map(|s| s.entries().len())
.unwrap_or(0);
let code_section_len = module.code_section().map(|s| s.bodies().len()).unwrap_or(0);
if function_section_len != code_section_len {
return Err(Error(format!(
"length of function section is {}, while len of code section is {}",
function_section_len, code_section_len
)));
}
if function_section_len != 0 {
let function_section = module
.function_section()
.expect("function_section_len != 0; qed");
let code_section = module
.code_section()
.expect("function_section_len != 0; function_section_len == code_section_len; qed");
for (index, function) in function_section.entries().iter().enumerate() {
let function_body = code_section
.bodies()
.get(index as usize)
.ok_or_else(|| Error(format!("Missing body for function {}", index)))?;
let func_validator_input = validation.func_validator_input();
let output = func::drive::<V::FuncValidator>(
&context,
function,
function_body,
func_validator_input,
)
.map_err(|Error(ref msg)| {
Error(format!(
"Function #{} reading/validation error: {}",
index, msg
))
})?;
validation.on_function_validated(index as u32, output);
}
}
if let Some(start_fn_idx) = module.start_section() {
let (params, return_ty) = context.require_function(start_fn_idx)?;
if return_ty != BlockType::NoResult || !params.is_empty() {
return Err(Error(
"start function expected to have type [] -> []".into(),
));
}
}
if let Some(export_section) = module.export_section() {
let mut export_names = export_section
.entries()
.iter()
.map(ExportEntry::field)
.collect::<Vec<_>>();
export_names.sort_unstable();
for (fst, snd) in export_names.iter().zip(export_names.iter().skip(1)) {
if fst == snd {
return Err(Error(format!("duplicate export {}", fst)));
}
}
for export in export_section.entries() {
match *export.internal() {
Internal::Function(function_index) => {
context.require_function(function_index)?;
}
Internal::Global(global_index) => {
context.require_global(global_index, None)?;
}
Internal::Memory(memory_index) => {
context.require_memory(memory_index)?;
}
Internal::Table(table_index) => {
context.require_table(table_index)?;
}
}
}
}
if let Some(import_section) = module.import_section() {
for import in import_section.entries() {
match *import.external() {
External::Function(function_type_index) => {
context.require_function_type(function_type_index)?;
}
External::Global(_) => {}
External::Memory(ref memory_type) => {
validate_memory_type(memory_type)?;
}
External::Table(ref table_type) => {
validate_table_type(table_type)?;
}
}
}
}
if context.tables().len() > 1 {
return Err(Error(format!(
"too many tables in index space: {}",
context.tables().len()
)));
}
if context.memories().len() > 1 {
return Err(Error(format!(
"too many memory regions in index space: {}",
context.memories().len()
)));
}
if let Some(data_section) = module.data_section() {
for data_segment in data_section.entries() {
context.require_memory(data_segment.index())?;
let offset = data_segment
.offset()
.as_ref()
.ok_or_else(|| Error("passive memory segments are not supported".into()))?;
let init_ty = expr_const_type(offset, context.globals())?;
if init_ty != ValueType::I32 {
return Err(Error("segment offset should return I32".into()));
}
}
}
if let Some(element_section) = module.elements_section() {
for element_segment in element_section.entries() {
context.require_table(element_segment.index())?;
let offset = element_segment
.offset()
.as_ref()
.ok_or_else(|| Error("passive element segments are not supported".into()))?;
let init_ty = expr_const_type(offset, context.globals())?;
if init_ty != ValueType::I32 {
return Err(Error("segment offset should return I32".into()));
}
for function_index in element_segment.members() {
context.require_function(*function_index)?;
}
}
}
Ok(validation.finish())
}
fn validate_limits(limits: &ResizableLimits) -> Result<(), Error> {
if let Some(maximum) = limits.maximum() {
if limits.initial() > maximum {
return Err(Error(format!(
"maximum limit {} is less than minimum {}",
maximum,
limits.initial()
)));
}
}
Ok(())
}
fn validate_memory_type(memory_type: &MemoryType) -> Result<(), Error> {
let initial = memory_type.limits().initial();
let maximum: Option<u32> = memory_type.limits().maximum();
validate_memory(initial, maximum).map_err(Error)
}
pub fn validate_memory(initial: u32, maximum: Option<u32>) -> Result<(), String> {
if initial > LINEAR_MEMORY_MAX_PAGES {
return Err(format!(
"initial memory size must be at most {} pages",
LINEAR_MEMORY_MAX_PAGES
));
}
if let Some(maximum) = maximum {
if initial > maximum {
return Err(format!(
"maximum limit {} is less than minimum {}",
maximum, initial,
));
}
if maximum > LINEAR_MEMORY_MAX_PAGES {
return Err(format!(
"maximum memory size must be at most {} pages",
LINEAR_MEMORY_MAX_PAGES
));
}
}
Ok(())
}
fn validate_table_type(table_type: &TableType) -> Result<(), Error> {
validate_limits(table_type.limits())
}
fn validate_global_entry(global_entry: &GlobalEntry, globals: &[GlobalType]) -> Result<(), Error> {
let init = global_entry.init_expr();
let init_expr_ty = expr_const_type(init, globals)?;
if init_expr_ty != global_entry.global_type().content_type() {
return Err(Error(format!(
"Trying to initialize variable of type {:?} with value of type {:?}",
global_entry.global_type().content_type(),
init_expr_ty
)));
}
Ok(())
}
fn expr_const_type(init_expr: &InitExpr, globals: &[GlobalType]) -> Result<ValueType, Error> {
let code = init_expr.code();
if code.len() != 2 {
return Err(Error(
"Init expression should always be with length 2".into(),
));
}
let expr_ty: ValueType = match code[0] {
Instruction::I32Const(_) => ValueType::I32,
Instruction::I64Const(_) => ValueType::I64,
Instruction::F32Const(_) => ValueType::F32,
Instruction::F64Const(_) => ValueType::F64,
Instruction::GetGlobal(idx) => match globals.get(idx as usize) {
Some(target_global) => {
if target_global.is_mutable() {
return Err(Error(format!("Global {} is mutable", idx)));
}
target_global.content_type()
}
None => {
return Err(Error(format!(
"Global {} doesn't exists or not yet defined",
idx
)));
}
},
_ => return Err(Error("Non constant opcode in init expr".into())),
};
if code[1] != Instruction::End {
return Err(Error("Expression doesn't ends with `end` opcode".into()));
}
Ok(expr_ty)
}