//! Instruction Set Architectures. //! //! The `isa` module provides a `TargetIsa` trait which provides the behavior specialization needed //! by the ISA-independent code generator. The sub-modules of this module provide definitions for //! the instruction sets that Cranelift can target. Each sub-module has it's own implementation of //! `TargetIsa`. //! //! # Constructing a `TargetIsa` instance //! //! The target ISA is built from the following information: //! //! - The name of the target ISA as a string. Cranelift is a cross-compiler, so the ISA to target //! can be selected dynamically. Individual ISAs can be left out when Cranelift is compiled, so a //! string is used to identify the proper sub-module. //! - Values for settings that apply to all ISAs. This is represented by a `settings::Flags` //! instance. //! - Values for ISA-specific settings. //! //! The `isa::lookup()` function is the main entry point which returns an `isa::Builder` //! appropriate for the requested ISA: //! //! ``` //! # #[macro_use] extern crate target_lexicon; //! use cranelift_codegen::isa; //! use cranelift_codegen::settings::{self, Configurable}; //! use std::str::FromStr; //! use target_lexicon::Triple; //! //! let shared_builder = settings::builder(); //! let shared_flags = settings::Flags::new(shared_builder); //! //! match isa::lookup(triple!("x86_64")) { //! Err(_) => { //! // The x86_64 target ISA is not available. //! } //! Ok(mut isa_builder) => { //! isa_builder.set("use_popcnt", "on"); //! let isa = isa_builder.finish(shared_flags); //! } //! } //! ``` //! //! The configured target ISA trait object is a `Box` which can be used for multiple //! concurrent function compilations. use crate::dominator_tree::DominatorTree; pub use crate::isa::call_conv::CallConv; use crate::flowgraph; use crate::ir::{self, Function, Type}; #[cfg(feature = "unwind")] use crate::isa::unwind::{systemv::RegisterMappingError, UnwindInfoKind}; use crate::machinst::{CompiledCode, CompiledCodeStencil, TextSectionBuilder}; use crate::settings; use crate::settings::SetResult; use crate::CodegenResult; use alloc::{boxed::Box, sync::Arc, vec::Vec}; use core::fmt; use core::fmt::{Debug, Formatter}; use cranelift_control::ControlPlane; use target_lexicon::{triple, Architecture, PointerWidth, Triple}; // This module is made public here for benchmarking purposes. No guarantees are // made regarding API stability. #[cfg(feature = "x86")] pub mod x64; #[cfg(feature = "arm64")] pub mod aarch64; #[cfg(feature = "riscv64")] pub mod riscv64; #[cfg(feature = "s390x")] mod s390x; pub mod unwind; mod call_conv; /// Returns a builder that can create a corresponding `TargetIsa` /// or `Err(LookupError::SupportDisabled)` if not enabled. macro_rules! isa_builder { ($name: ident, $cfg_terms: tt, $triple: ident) => {{ #[cfg $cfg_terms] { Ok($name::isa_builder($triple)) } #[cfg(not $cfg_terms)] { Err(LookupError::SupportDisabled) } }}; } /// Look for an ISA for the given `triple`. /// Return a builder that can create a corresponding `TargetIsa`. pub fn lookup(triple: Triple) -> Result { match triple.architecture { Architecture::X86_64 => { isa_builder!(x64, (feature = "x86"), triple) } Architecture::Aarch64 { .. } => isa_builder!(aarch64, (feature = "arm64"), triple), Architecture::S390x { .. } => isa_builder!(s390x, (feature = "s390x"), triple), Architecture::Riscv64 { .. } => isa_builder!(riscv64, (feature = "riscv64"), triple), _ => Err(LookupError::Unsupported), } } /// The string names of all the supported, but possibly not enabled, architectures. The elements of /// this slice are suitable to be passed to the [lookup_by_name] function to obtain the default /// configuration for that architecture. pub const ALL_ARCHITECTURES: &[&str] = &["x86_64", "aarch64", "s390x", "riscv64"]; /// Look for a supported ISA with the given `name`. /// Return a builder that can create a corresponding `TargetIsa`. pub fn lookup_by_name(name: &str) -> Result { lookup(triple!(name)) } /// Describes reason for target lookup failure #[derive(PartialEq, Eq, Copy, Clone, Debug)] pub enum LookupError { /// Support for this target was disabled in the current build. SupportDisabled, /// Support for this target has not yet been implemented. Unsupported, } // This is manually implementing Error and Display instead of using thiserror to reduce the amount // of dependencies used by Cranelift. impl std::error::Error for LookupError {} impl fmt::Display for LookupError { fn fmt(&self, f: &mut Formatter) -> fmt::Result { match self { LookupError::SupportDisabled => write!(f, "Support for this target is disabled"), LookupError::Unsupported => { write!(f, "Support for this target has not been implemented yet") } } } } /// The type of a polymorphic TargetISA object which is 'static. pub type OwnedTargetIsa = Arc; /// Type alias of `IsaBuilder` used for building Cranelift's ISAs. pub type Builder = IsaBuilder>; /// Builder for a `TargetIsa`. /// Modify the ISA-specific settings before creating the `TargetIsa` trait object with `finish`. #[derive(Clone)] pub struct IsaBuilder { triple: Triple, setup: settings::Builder, constructor: fn(Triple, settings::Flags, &settings::Builder) -> T, } impl IsaBuilder { /// Creates a new ISA-builder from its components, namely the `triple` for /// the ISA, the ISA-specific settings builder, and a final constructor /// function to generate the ISA from its components. pub fn new( triple: Triple, setup: settings::Builder, constructor: fn(Triple, settings::Flags, &settings::Builder) -> T, ) -> Self { IsaBuilder { triple, setup, constructor, } } /// Gets the triple for the builder. pub fn triple(&self) -> &Triple { &self.triple } /// Iterates the available settings in the builder. pub fn iter(&self) -> impl Iterator { self.setup.iter() } /// Combine the ISA-specific settings with the provided /// ISA-independent settings and allocate a fully configured /// `TargetIsa` trait object. May return an error if some of the /// flags are inconsistent or incompatible: for example, some /// platform-independent features, like general SIMD support, may /// need certain ISA extensions to be enabled. pub fn finish(&self, shared_flags: settings::Flags) -> T { (self.constructor)(self.triple.clone(), shared_flags, &self.setup) } } impl settings::Configurable for IsaBuilder { fn set(&mut self, name: &str, value: &str) -> SetResult<()> { self.setup.set(name, value) } fn enable(&mut self, name: &str) -> SetResult<()> { self.setup.enable(name) } } /// After determining that an instruction doesn't have an encoding, how should we proceed to /// legalize it? /// /// The `Encodings` iterator returns a legalization function to call. pub type Legalize = fn(ir::Inst, &mut ir::Function, &mut flowgraph::ControlFlowGraph, &dyn TargetIsa) -> bool; /// This struct provides information that a frontend may need to know about a target to /// produce Cranelift IR for the target. #[derive(Clone, Copy, Hash)] pub struct TargetFrontendConfig { /// The default calling convention of the target. pub default_call_conv: CallConv, /// The pointer width of the target. pub pointer_width: PointerWidth, } impl TargetFrontendConfig { /// Get the pointer type of this target. pub fn pointer_type(self) -> ir::Type { ir::Type::int(self.pointer_bits() as u16).unwrap() } /// Get the width of pointers on this target, in units of bits. pub fn pointer_bits(self) -> u8 { self.pointer_width.bits() } /// Get the width of pointers on this target, in units of bytes. pub fn pointer_bytes(self) -> u8 { self.pointer_width.bytes() } } /// Methods that are specialized to a target ISA. /// /// Implies a Display trait that shows the shared flags, as well as any ISA-specific flags. pub trait TargetIsa: fmt::Display + Send + Sync { /// Get the name of this ISA. fn name(&self) -> &'static str; /// Get the target triple that was used to make this trait object. fn triple(&self) -> &Triple; /// Get the ISA-independent flags that were used to make this trait object. fn flags(&self) -> &settings::Flags; /// Get the ISA-dependent flag values that were used to make this trait object. fn isa_flags(&self) -> Vec; /// Get a flag indicating whether branch protection is enabled. fn is_branch_protection_enabled(&self) -> bool { false } /// Get the ISA-dependent maximum vector register size, in bytes. fn dynamic_vector_bytes(&self, dynamic_ty: ir::Type) -> u32; /// Compile the given function. fn compile_function( &self, func: &Function, domtree: &DominatorTree, want_disasm: bool, ctrl_plane: &mut ControlPlane, ) -> CodegenResult; #[cfg(feature = "unwind")] /// Map a regalloc::Reg to its corresponding DWARF register. fn map_regalloc_reg_to_dwarf( &self, _: crate::machinst::Reg, ) -> Result { Err(RegisterMappingError::UnsupportedArchitecture) } /// Creates unwind information for the function. /// /// Returns `None` if there is no unwind information for the function. #[cfg(feature = "unwind")] fn emit_unwind_info( &self, result: &CompiledCode, kind: UnwindInfoKind, ) -> CodegenResult>; /// Creates a new System V Common Information Entry for the ISA. /// /// Returns `None` if the ISA does not support System V unwind information. #[cfg(feature = "unwind")] fn create_systemv_cie(&self) -> Option { // By default, an ISA cannot create a System V CIE None } /// Returns an object that can be used to build the text section of an /// executable. /// /// This object will internally attempt to handle as many relocations as /// possible using relative calls/jumps/etc between functions. /// /// The `num_labeled_funcs` argument here is the number of functions which /// will be "labeled" or might have calls between them, typically the number /// of defined functions in the object file. fn text_section_builder(&self, num_labeled_funcs: usize) -> Box; /// Returns the minimum function alignment and the preferred function /// alignment, for performance, required by this ISA. fn function_alignment(&self) -> FunctionAlignment; /// Create a polymorphic TargetIsa from this specific implementation. fn wrapped(self) -> OwnedTargetIsa where Self: Sized + 'static, { Arc::new(self) } /// Generate a `Capstone` context for disassembling bytecode for this architecture. #[cfg(feature = "disas")] fn to_capstone(&self) -> Result { Err(capstone::Error::UnsupportedArch) } /// Returns whether this ISA has a native fused-multiply-and-add instruction /// for floats. /// /// Currently this only returns false on x86 when some native features are /// not detected. fn has_native_fma(&self) -> bool; /// Returns whether the CLIF `x86_blendv` instruction is implemented for /// this ISA for the specified type. fn has_x86_blendv_lowering(&self, ty: Type) -> bool; /// Returns whether the CLIF `x86_pshufb` instruction is implemented for /// this ISA. fn has_x86_pshufb_lowering(&self) -> bool; /// Returns whether the CLIF `x86_pmulhrsw` instruction is implemented for /// this ISA. fn has_x86_pmulhrsw_lowering(&self) -> bool; /// Returns whether the CLIF `x86_pmaddubsw` instruction is implemented for /// this ISA. fn has_x86_pmaddubsw_lowering(&self) -> bool; } /// Function alignment specifications as required by an ISA, returned by /// [`TargetIsa::function_alignment`]. #[derive(Copy, Clone)] pub struct FunctionAlignment { /// The minimum alignment required by an ISA, where all functions must be /// aligned to at least this amount. pub minimum: u32, /// A "preferred" alignment which should be used for more /// performance-sensitive situations. This can involve cache-line-aligning /// for example to get more of a small function into fewer cache lines. pub preferred: u32, } /// Methods implemented for free for target ISA! impl<'a> dyn TargetIsa + 'a { /// Get the default calling convention of this target. pub fn default_call_conv(&self) -> CallConv { CallConv::triple_default(self.triple()) } /// Get the endianness of this ISA. pub fn endianness(&self) -> ir::Endianness { match self.triple().endianness().unwrap() { target_lexicon::Endianness::Little => ir::Endianness::Little, target_lexicon::Endianness::Big => ir::Endianness::Big, } } /// Returns the minimum symbol alignment for this ISA. pub fn symbol_alignment(&self) -> u64 { match self.triple().architecture { // All symbols need to be aligned to at least 2 on s390x. Architecture::S390x => 2, _ => 1, } } /// Get the pointer type of this ISA. pub fn pointer_type(&self) -> ir::Type { ir::Type::int(self.pointer_bits() as u16).unwrap() } /// Get the width of pointers on this ISA. pub(crate) fn pointer_width(&self) -> PointerWidth { self.triple().pointer_width().unwrap() } /// Get the width of pointers on this ISA, in units of bits. pub fn pointer_bits(&self) -> u8 { self.pointer_width().bits() } /// Get the width of pointers on this ISA, in units of bytes. pub fn pointer_bytes(&self) -> u8 { self.pointer_width().bytes() } /// Get the information needed by frontends producing Cranelift IR. pub fn frontend_config(&self) -> TargetFrontendConfig { TargetFrontendConfig { default_call_conv: self.default_call_conv(), pointer_width: self.pointer_width(), } } } impl Debug for &dyn TargetIsa { fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result { write!( f, "TargetIsa {{ triple: {:?}, pointer_width: {:?}}}", self.triple(), self.pointer_width() ) } }