//! All the runtime support necessary for the wasm to cranelift translation is formalized by the //! traits `FunctionEnvironment` and `ModuleEnvironment`. //! //! There are skeleton implementations of these traits in the `dummy` module, and complete //! implementations in [Wasmtime]. //! //! [Wasmtime]: https://github.com/CraneStation/wasmtime use crate::state::TranslationState; use crate::translation_utils::{ FuncIndex, Global, GlobalIndex, Memory, MemoryIndex, SignatureIndex, Table, TableIndex, }; use core::convert::From; use cranelift_codegen::cursor::FuncCursor; use cranelift_codegen::ir::immediates::Offset32; use cranelift_codegen::ir::{self, InstBuilder}; use cranelift_codegen::isa::TargetFrontendConfig; use cranelift_frontend::FunctionBuilder; use failure_derive::Fail; use std::boxed::Box; use wasmparser::BinaryReaderError; use wasmparser::Operator; /// The value of a WebAssembly global variable. #[derive(Clone, Copy)] pub enum GlobalVariable { /// This is a constant global with a value known at compile time. Const(ir::Value), /// This is a variable in memory that should be referenced through a `GlobalValue`. Memory { /// The address of the global variable storage. gv: ir::GlobalValue, /// An offset to add to the address. offset: Offset32, /// The global variable's type. ty: ir::Type, }, } /// A WebAssembly translation error. /// /// When a WebAssembly function can't be translated, one of these error codes will be returned /// to describe the failure. #[derive(Fail, Debug)] pub enum WasmError { /// The input WebAssembly code is invalid. /// /// This error code is used by a WebAssembly translator when it encounters invalid WebAssembly /// code. This should never happen for validated WebAssembly code. #[fail(display = "Invalid input WebAssembly code at offset {}: {}", _1, _0)] InvalidWebAssembly { /// A string describing the validation error. message: &'static str, /// The bytecode offset where the error occurred. offset: usize, }, /// A feature used by the WebAssembly code is not supported by the embedding environment. /// /// Embedding environments may have their own limitations and feature restrictions. #[fail(display = "Unsupported feature: {}", _0)] Unsupported(&'static str), /// An implementation limit was exceeded. /// /// Cranelift can compile very large and complicated functions, but the [implementation has /// limits][limits] that cause compilation to fail when they are exceeded. /// /// [limits]: https://cranelift.readthedocs.io/en/latest/ir.html#implementation-limits #[fail(display = "Implementation limit exceeded")] ImplLimitExceeded, /// Any user-defined error. #[fail(display = "User error: {}", _0)] User(std::string::String), } impl From for WasmError { /// Convert from a `BinaryReaderError` to a `WasmError`. fn from(e: BinaryReaderError) -> Self { let BinaryReaderError { message, offset } = e; WasmError::InvalidWebAssembly { message, offset } } } /// A convenient alias for a `Result` that uses `WasmError` as the error type. pub type WasmResult = Result; /// How to return from functions. #[derive(Copy, Clone, PartialEq, Eq, Debug)] pub enum ReturnMode { /// Use normal return instructions as needed. NormalReturns, /// Use a single fallthrough return at the end of the function. FallthroughReturn, } /// Environment affecting the translation of a single WebAssembly function. /// /// A `FuncEnvironment` trait object is required to translate a WebAssembly function to Cranelift /// IR. The function environment provides information about the WebAssembly module as well as the /// runtime environment. pub trait FuncEnvironment { /// Get the information needed to produce Cranelift IR for the given target. fn target_config(&self) -> TargetFrontendConfig; /// Get the Cranelift integer type to use for native pointers. /// /// This returns `I64` for 64-bit architectures and `I32` for 32-bit architectures. fn pointer_type(&self) -> ir::Type { ir::Type::int(u16::from(self.target_config().pointer_bits())).unwrap() } /// Get the size of a native pointer, in bytes. fn pointer_bytes(&self) -> u8 { self.target_config().pointer_bytes() } /// Should the code be structured to use a single `fallthrough_return` instruction at the end /// of the function body, rather than `return` instructions as needed? This is used by VMs /// to append custom epilogues. fn return_mode(&self) -> ReturnMode { ReturnMode::NormalReturns } /// Set up the necessary preamble definitions in `func` to access the global variable /// identified by `index`. /// /// The index space covers both imported globals and globals defined by the module. /// /// Return the global variable reference that should be used to access the global and the /// WebAssembly type of the global. fn make_global( &mut self, func: &mut ir::Function, index: GlobalIndex, ) -> WasmResult; /// Set up the necessary preamble definitions in `func` to access the linear memory identified /// by `index`. /// /// The index space covers both imported and locally declared memories. fn make_heap(&mut self, func: &mut ir::Function, index: MemoryIndex) -> WasmResult; /// Set up the necessary preamble definitions in `func` to access the table identified /// by `index`. /// /// The index space covers both imported and locally declared tables. fn make_table(&mut self, func: &mut ir::Function, index: TableIndex) -> WasmResult; /// Set up a signature definition in the preamble of `func` that can be used for an indirect /// call with signature `index`. /// /// The signature may contain additional arguments needed for an indirect call, but the /// arguments marked as `ArgumentPurpose::Normal` must correspond to the WebAssembly signature /// arguments. /// /// The signature will only be used for indirect calls, even if the module has direct function /// calls with the same WebAssembly type. fn make_indirect_sig( &mut self, func: &mut ir::Function, index: SignatureIndex, ) -> WasmResult; /// Set up an external function definition in the preamble of `func` that can be used to /// directly call the function `index`. /// /// The index space covers both imported functions and functions defined in the current module. /// /// The function's signature may contain additional arguments needed for a direct call, but the /// arguments marked as `ArgumentPurpose::Normal` must correspond to the WebAssembly signature /// arguments. /// /// The function's signature will only be used for direct calls, even if the module has /// indirect calls with the same WebAssembly type. fn make_direct_func( &mut self, func: &mut ir::Function, index: FuncIndex, ) -> WasmResult; /// Translate a `call_indirect` WebAssembly instruction at `pos`. /// /// Insert instructions at `pos` for an indirect call to the function `callee` in the table /// `table_index` with WebAssembly signature `sig_index`. The `callee` value will have type /// `i32`. /// /// The signature `sig_ref` was previously created by `make_indirect_sig()`. /// /// Return the call instruction whose results are the WebAssembly return values. #[cfg_attr(feature = "cargo-clippy", allow(clippy::too_many_arguments))] fn translate_call_indirect( &mut self, pos: FuncCursor, table_index: TableIndex, table: ir::Table, sig_index: SignatureIndex, sig_ref: ir::SigRef, callee: ir::Value, call_args: &[ir::Value], ) -> WasmResult; /// Translate a `call` WebAssembly instruction at `pos`. /// /// Insert instructions at `pos` for a direct call to the function `callee_index`. /// /// The function reference `callee` was previously created by `make_direct_func()`. /// /// Return the call instruction whose results are the WebAssembly return values. fn translate_call( &mut self, mut pos: FuncCursor, _callee_index: FuncIndex, callee: ir::FuncRef, call_args: &[ir::Value], ) -> WasmResult { Ok(pos.ins().call(callee, call_args)) } /// Translate a `memory.grow` WebAssembly instruction. /// /// The `index` provided identifies the linear memory to grow, and `heap` is the heap reference /// returned by `make_heap` for the same index. /// /// The `val` value is the requested memory size in pages. /// /// Returns the old size (in pages) of the memory. fn translate_memory_grow( &mut self, pos: FuncCursor, index: MemoryIndex, heap: ir::Heap, val: ir::Value, ) -> WasmResult; /// Translates a `memory.size` WebAssembly instruction. /// /// The `index` provided identifies the linear memory to query, and `heap` is the heap reference /// returned by `make_heap` for the same index. /// /// Returns the size in pages of the memory. fn translate_memory_size( &mut self, pos: FuncCursor, index: MemoryIndex, heap: ir::Heap, ) -> WasmResult; /// Emit code at the beginning of every wasm loop. /// /// This can be used to insert explicit interrupt or safepoint checking at /// the beginnings of loops. fn translate_loop_header(&mut self, _pos: FuncCursor) -> WasmResult<()> { // By default, don't emit anything. Ok(()) } /// Optional callback for the `FunctionEnvironment` performing this translation to maintain /// internal state or prepare custom state for the operator to translate fn before_translate_operator( &mut self, _op: &Operator, _builder: &mut FunctionBuilder, _state: &mut TranslationState, ) -> WasmResult<()> { Ok(()) } /// Optional callback for the `FunctionEnvironment` performing this translation to maintain /// internal state or finalize custom state for the operator that was translated fn after_translate_operator( &mut self, _op: &Operator, _builder: &mut FunctionBuilder, _state: &mut TranslationState, ) -> WasmResult<()> { Ok(()) } } /// An object satisfying the `ModuleEnvironment` trait can be passed as argument to the /// [`translate_module`](fn.translate_module.html) function. These methods should not be called /// by the user, they are only for `cranelift-wasm` internal use. pub trait ModuleEnvironment<'data> { /// Get the information needed to produce Cranelift IR for the current target. fn target_config(&self) -> TargetFrontendConfig; /// Provides the number of signatures up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_signatures(&mut self, _num: u32) {} /// Declares a function signature to the environment. fn declare_signature(&mut self, sig: ir::Signature); /// Provides the number of imports up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_imports(&mut self, _num: u32) {} /// Declares a function import to the environment. fn declare_func_import( &mut self, sig_index: SignatureIndex, module: &'data str, field: &'data str, ); /// Declares a table import to the environment. fn declare_table_import(&mut self, table: Table, module: &'data str, field: &'data str); /// Declares a memory import to the environment. fn declare_memory_import(&mut self, memory: Memory, module: &'data str, field: &'data str); /// Declares a global import to the environment. fn declare_global_import(&mut self, global: Global, module: &'data str, field: &'data str); /// Notifies the implementation that all imports have been declared. fn finish_imports(&mut self) {} /// Provides the number of defined functions up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_func_types(&mut self, _num: u32) {} /// Declares the type (signature) of a local function in the module. fn declare_func_type(&mut self, sig_index: SignatureIndex); /// Provides the number of defined tables up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_tables(&mut self, _num: u32) {} /// Declares a table to the environment. fn declare_table(&mut self, table: Table); /// Provides the number of defined memories up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_memories(&mut self, _num: u32) {} /// Declares a memory to the environment fn declare_memory(&mut self, memory: Memory); /// Provides the number of defined globals up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_globals(&mut self, _num: u32) {} /// Declares a global to the environment. fn declare_global(&mut self, global: Global); /// Provides the number of exports up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_exports(&mut self, _num: u32) {} /// Declares a function export to the environment. fn declare_func_export(&mut self, func_index: FuncIndex, name: &'data str); /// Declares a table export to the environment. fn declare_table_export(&mut self, table_index: TableIndex, name: &'data str); /// Declares a memory export to the environment. fn declare_memory_export(&mut self, memory_index: MemoryIndex, name: &'data str); /// Declares a global export to the environment. fn declare_global_export(&mut self, global_index: GlobalIndex, name: &'data str); /// Notifies the implementation that all exports have been declared. fn finish_exports(&mut self) {} /// Declares the optional start function. fn declare_start_func(&mut self, index: FuncIndex); /// Provides the number of element initializers up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_table_elements(&mut self, _num: u32) {} /// Fills a declared table with references to functions in the module. fn declare_table_elements( &mut self, table_index: TableIndex, base: Option, offset: usize, elements: Box<[FuncIndex]>, ); /// Provides the contents of a function body. /// /// Note there's no `reserve_function_bodies` function because the number of /// functions is already provided by `reserve_func_types`. fn define_function_body( &mut self, body_bytes: &'data [u8], body_offset: usize, ) -> WasmResult<()>; /// Provides the number of data initializers up front. By default this does nothing, but /// implementations can use this to preallocate memory if desired. fn reserve_data_initializers(&mut self, _num: u32) {} /// Fills a declared memory with bytes at module instantiation. fn declare_data_initialization( &mut self, memory_index: MemoryIndex, base: Option, offset: usize, data: &'data [u8], ); }