//! # wasmi //! //! This library allows to load WebAssembly modules in binary format and invoke functions on them. //! //! # Introduction //! //! WebAssembly (wasm) is a safe, portable, compact format that designed for efficient execution. //! //! Wasm code is distributed in a form of modules, that contains definitions of: //! //! - functions, //! - global variables, //! - linear memories, //! - tables. //! //! and this definitions can be imported. Also, each definition can be exported. //! //! In addition to definitions, modules can define initialization data for their memories or tables that takes the //! form of segments copied to given offsets. They can also define a `start` function that is automatically executed. //! //! ## Loading and Validation //! //! Before execution a module should be validated. This process checks that module is well-formed //! and makes only allowed operations. //! //! Valid modules can't access memory out of it's sandbox, can't cause stack underflow //! and can call functions only with correct signatures. //! //! ## Instantiatiation //! //! In order to execute code in wasm module it should be instatiated. //! Instantiation includes the following steps: //! //! 1. Create an empty module instance, //! 2. Resolve definition instances for each declared import in the module, //! 3. Instantiate definitions declared in the module (e.g. allocate global variables, allocate linear memory, etc), //! 4. Initialize memory and table contents by copiying segments into them, //! 5. Execute `start` function, if any. //! //! After these steps, module instance are ready to execute functions. //! //! ## Execution //! //! It is allowed to only execute functions which are exported by a module. //! Functions can either return a result or trap (e.g. there can't be linking-error at the middle of execution). //! This property is ensured by the validation process. //! //! # Examples //! //! ```rust //! extern crate wasmi; //! extern crate wabt; //! //! use wasmi::{ModuleInstance, ImportsBuilder, NopExternals, RuntimeValue}; //! //! fn main() { //! // Parse WAT (WebAssembly Text format) into wasm bytecode. //! let wasm_binary: Vec = //! wabt::wat2wasm( //! r#" //! (module //! (func (export "test") (result i32) //! i32.const 1337 //! ) //! ) //! "#, //! ) //! .expect("failed to parse wat"); //! //! // Load wasm binary and prepare it for instantiation. //! let module = wasmi::Module::from_buffer(&wasm_binary) //! .expect("failed to load wasm"); //! //! // Instantiate a module with empty imports and //! // asserting that there is no `start` function. //! let instance = //! ModuleInstance::new( //! &module, //! &ImportsBuilder::default() //! ) //! .expect("failed to instantiate wasm module") //! .assert_no_start(); //! //! // Finally, invoke exported function "test" with no parameters //! // and empty external function executor. //! assert_eq!( //! instance.invoke_export( //! "test", //! &[], //! &mut NopExternals, //! ).expect("failed to execute export"), //! Some(RuntimeValue::I32(1337)), //! ); //! } //! ``` #![warn(missing_docs)] #[cfg(test)] extern crate wabt; extern crate parity_wasm; extern crate byteorder; extern crate memory_units as memory_units_crate; #[cfg(all(not(feature = "32bit_opt_in"), target_pointer_width = "32"))] compile_error! { "32-bit targets are not supported at the moment. You can use '32bit_opt_in' feature. See https://github.com/pepyakin/wasmi/issues/43" } use std::fmt; use std::error; use std::collections::HashMap; /// Error type which can thrown by wasm code or by host environment. /// /// Under some conditions, wasm execution may produce a `Trap`, which immediately aborts execution. /// Traps can't be handled by WebAssembly code, but are reported to the embedder. #[derive(Debug)] pub struct Trap { kind: TrapKind, } impl Trap { /// Create new trap. pub fn new(kind: TrapKind) -> Trap { Trap { kind } } /// Returns kind of this trap. pub fn kind(&self) -> &TrapKind { &self.kind } } impl fmt::Display for Trap { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "Trap: {:?}", self.kind) } } impl error::Error for Trap { fn description(&self) -> &str { "runtime trap" } } /// Error type which can thrown by wasm code or by host environment. /// /// See [`Trap`] for details. /// /// [`Trap`]: struct.Trap.html #[derive(Debug)] pub enum TrapKind { /// Wasm code executed `unreachable` opcode. /// /// `unreachable` is a special opcode which always traps upon execution. /// This opcode have a similar purpose as `ud2` in x86. Unreachable, /// Attempt to load or store at the address which /// lies outside of bounds of the memory. /// /// Since addresses are interpreted as unsigned integers, out of bounds access /// can't happen with negative addresses (i.e. they will always wrap). MemoryAccessOutOfBounds, /// Attempt to access table element at index which /// lies outside of bounds. /// /// This typically can happen when `call_indirect` is executed /// with index that lies out of bounds. /// /// Since indexes are interpreted as unsinged integers, out of bounds access /// can't happen with negative indexes (i.e. they will always wrap). TableAccessOutOfBounds, /// Attempt to access table element which is uninitialized (i.e. `None`). /// /// This typically can happen when `call_indirect` is executed. ElemUninitialized, /// Attempt to divide by zero. /// /// This trap typically can happen if `div` or `rem` is executed with /// zero as divider. DivisionByZero, /// Attempt to make a conversion to an int failed. /// /// This can happen when: /// /// - trying to do signed division (or get the remainder) -2N-1 over -1. This is /// because the result +2N-1 isn't representable as a N-bit signed integer. /// - trying to truncate NaNs, infinity, or value for which the result is out of range into an integer. InvalidConversionToInt, /// Stack overflow. /// /// This is likely caused by some infinite or very deep recursion. /// Extensive inlining might also be the cause of stack overflow. StackOverflow, /// Attempt to invoke a function with mismatching signature. /// /// This can happen if [`FuncInstance`] was invoked /// with mismatching [signature][`Signature`]. /// /// This can always happen with indirect calls. `call_indirect` instruction always /// specifies the expected signature of function. If `call_indirect` is executed /// with index that points on function with signature different that is /// expected by this `call_indirect`, this trap is raised. /// /// [`Signature`]: struct.Signature.html UnexpectedSignature, /// Error specified by the host. /// /// Typically returned from an implementation of [`Externals`]. /// /// [`Externals`]: trait.Externals.html Host(Box), } /// Internal interpreter error. #[derive(Debug)] pub enum Error { /// Module validation error. Might occur only at load time. Validation(String), /// Error while instantiating a module. Might occur when provided /// with incorrect exports (i.e. linkage failure). Instantiation(String), /// Function-level error. Function(String), /// Table-level error. Table(String), /// Memory-level error. Memory(String), /// Global-level error. Global(String), /// Value-level error. Value(String), /// Trap. Trap(Trap), /// Custom embedder error. Host(Box), } impl Error { /// Returns [`HostError`] if this `Error` represents some host error. /// /// I.e. if this error have variant [`Host`] or [`Trap`][`Trap`] with [host][`TrapKind::Host`] error. /// /// [`HostError`]: trait.HostError.html /// [`Host`]: enum.Error.html#variant.Host /// [`Trap`]: enum.Error.html#variant.Trap /// [`TrapKind::Host`]: enum.TrapKind.html#variant.Host pub fn as_host_error(&self) -> Option<&host::HostError> { match *self { Error::Host(ref host_err) => Some(&**host_err), Error::Trap(ref trap) => match *trap.kind() { TrapKind::Host(ref host_err) => Some(&**host_err), _ => None, } _ => None, } } } impl Into for Error { fn into(self) -> String { match self { Error::Validation(s) => s, Error::Instantiation(s) => s, Error::Function(s) => s, Error::Table(s) => s, Error::Memory(s) => s, Error::Global(s) => s, Error::Value(s) => s, Error::Trap(s) => format!("trap: {:?}", s), Error::Host(e) => format!("user: {}", e), } } } impl fmt::Display for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { Error::Validation(ref s) => write!(f, "Validation: {}", s), Error::Instantiation(ref s) => write!(f, "Instantiation: {}", s), Error::Function(ref s) => write!(f, "Function: {}", s), Error::Table(ref s) => write!(f, "Table: {}", s), Error::Memory(ref s) => write!(f, "Memory: {}", s), Error::Global(ref s) => write!(f, "Global: {}", s), Error::Value(ref s) => write!(f, "Value: {}", s), Error::Trap(ref s) => write!(f, "Trap: {:?}", s), Error::Host(ref e) => write!(f, "User: {}", e), } } } impl error::Error for Error { fn description(&self) -> &str { match *self { Error::Validation(ref s) => s, Error::Instantiation(ref s) => s, Error::Function(ref s) => s, Error::Table(ref s) => s, Error::Memory(ref s) => s, Error::Global(ref s) => s, Error::Value(ref s) => s, Error::Trap(_) => "Trap", Error::Host(_) => "Host error", } } } impl From for Error where U: host::HostError + Sized { fn from(e: U) -> Self { Error::Host(Box::new(e)) } } impl From for Trap where U: host::HostError + Sized { fn from(e: U) -> Self { Trap::new(TrapKind::Host(Box::new(e))) } } impl From for Error { fn from(e: Trap) -> Error { Error::Trap(e) } } impl From for Trap { fn from(e: TrapKind) -> Trap { Trap::new(e) } } impl From for Error { fn from(e: validation::Error) -> Error { Error::Validation(e.to_string()) } } mod validation; mod common; mod memory; mod module; mod runner; mod table; mod value; mod host; mod imports; mod global; mod func; mod types; #[cfg(test)] mod tests; pub use self::memory::{MemoryInstance, MemoryRef, LINEAR_MEMORY_PAGE_SIZE}; pub use self::table::{TableInstance, TableRef}; pub use self::value::RuntimeValue; pub use self::host::{Externals, NopExternals, HostError, RuntimeArgs}; pub use self::imports::{ModuleImportResolver, ImportResolver, ImportsBuilder}; pub use self::module::{ModuleInstance, ModuleRef, ExternVal, NotStartedModuleRef}; pub use self::global::{GlobalInstance, GlobalRef}; pub use self::func::{FuncInstance, FuncRef}; pub use self::types::{Signature, ValueType, GlobalDescriptor, TableDescriptor, MemoryDescriptor}; /// WebAssembly-specific sizes and units. pub mod memory_units { pub use memory_units_crate::wasm32::*; pub use memory_units_crate::{Bytes, ByteSize, RoundUpTo, size_of}; } /// Deserialized module prepared for instantiation. pub struct Module { labels: HashMap>, module: parity_wasm::elements::Module, } impl Module { /// Create `Module` from `parity_wasm::elements::Module`. /// /// This function will load, validate and prepare a `parity_wasm`'s `Module`. /// /// # Errors /// /// Returns `Err` if provided `Module` is not valid. /// /// # Examples /// /// ```rust /// extern crate parity_wasm; /// extern crate wasmi; /// /// use parity_wasm::builder; /// use parity_wasm::elements; /// /// fn main() { /// let parity_module = /// builder::module() /// .function() /// .signature().with_param(elements::ValueType::I32).build() /// .body().build() /// .build() /// .build(); /// /// let module = wasmi::Module::from_parity_wasm_module(parity_module) /// .expect("parity-wasm builder generated invalid module!"); /// /// // Instantiate `module`, etc... /// } /// ``` pub fn from_parity_wasm_module(module: parity_wasm::elements::Module) -> Result { use validation::{validate_module, ValidatedModule}; let ValidatedModule { labels, module, } = validate_module(module)?; Ok(Module { labels, module, }) } /// Create `Module` from a given buffer. /// /// This function will deserialize wasm module from a given module, /// validate and prepare it for instantiation. /// /// # Errors /// /// Returns `Err` if wasm binary in provided `buffer` is not valid wasm binary. /// /// # Examples /// /// ```rust /// extern crate wasmi; /// /// fn main() { /// let module = /// wasmi::Module::from_buffer( /// // Minimal module: /// // \0asm - magic /// // 0x01 - version (in little-endian) /// &[0x00, 0x61, 0x73, 0x6d, 0x01, 0x00, 0x00, 0x00] /// ).expect("Failed to load minimal module"); /// /// // Instantiate `module`, etc... /// } /// ``` pub fn from_buffer>(buffer: B) -> Result { let module = parity_wasm::elements::deserialize_buffer(buffer.as_ref()) .map_err(|e: parity_wasm::elements::Error| Error::Validation(e.to_string()))?; Module::from_parity_wasm_module(module) } pub(crate) fn module(&self) -> &parity_wasm::elements::Module { &self.module } pub(crate) fn labels(&self) -> &HashMap> { &self.labels } }