//! ARM ABI implementation. use super::registers::{D, GPR, Q, S}; use crate::abi::{legalize_args, ArgAction, ArgAssigner, ValueConversion}; use crate::ir::{self, AbiParam, ArgumentExtension, ArgumentLoc, ArgumentPurpose, Type}; use crate::isa::RegClass; use crate::regalloc::RegisterSet; use core::i32; use target_lexicon::Triple; struct Args { pointer_bits: u8, pointer_bytes: u8, pointer_type: Type, regs: u32, reg_limit: u32, offset: u32, } impl Args { fn new(bits: u8) -> Self { Self { pointer_bits: bits, pointer_bytes: bits / 8, pointer_type: Type::int(u16::from(bits)).unwrap(), regs: 0, reg_limit: 8, offset: 0, } } } impl ArgAssigner for Args { fn assign(&mut self, arg: &AbiParam) -> ArgAction { fn align(value: u32, to: u32) -> u32 { (value + to - 1) & !(to - 1) } let ty = arg.value_type; // Check for a legal type. // RISC-V doesn't have SIMD at all, so break all vectors down. if ty.is_vector() { return ValueConversion::VectorSplit.into(); } // Large integers and booleans are broken down to fit in a register. if !ty.is_float() && ty.bits() > u16::from(self.pointer_bits) { // Align registers and stack to a multiple of two pointers. self.regs = align(self.regs, 2); self.offset = align(self.offset, 2 * u32::from(self.pointer_bytes)); return ValueConversion::IntSplit.into(); } // Small integers are extended to the size of a pointer register. if ty.is_int() && ty.bits() < u16::from(self.pointer_bits) { match arg.extension { ArgumentExtension::None => {} ArgumentExtension::Uext => return ValueConversion::Uext(self.pointer_type).into(), ArgumentExtension::Sext => return ValueConversion::Sext(self.pointer_type).into(), } } if self.regs < self.reg_limit { // Assign to a register. let reg = GPR.unit(10 + self.regs as usize); self.regs += 1; ArgumentLoc::Reg(reg).into() } else { // Assign a stack location. let loc = ArgumentLoc::Stack(self.offset as i32); self.offset += u32::from(self.pointer_bytes); debug_assert!(self.offset <= i32::MAX as u32); loc.into() } } } /// Legalize `sig`. pub fn legalize_signature(sig: &mut ir::Signature, triple: &Triple, current: bool) { let bits = triple.pointer_width().unwrap().bits(); let mut args = Args::new(bits); legalize_args(&mut sig.params, &mut args); let mut rets = Args::new(bits); legalize_args(&mut sig.returns, &mut rets); if current { let ptr = Type::int(u16::from(bits)).unwrap(); // Add the link register as an argument and return value. // // The `jalr` instruction implementing a return can technically accept the return address // in any register, but a micro-architecture with a return address predictor will only // recognize it as a return if the address is in `x1`. let link = AbiParam::special_reg(ptr, ArgumentPurpose::Link, GPR.unit(1)); sig.params.push(link); sig.returns.push(link); } } /// Get register class for a type appearing in a legalized signature. pub fn regclass_for_abi_type(ty: ir::Type) -> RegClass { if ty.is_int() { GPR } else { match ty.bits() { 32 => S, 64 => D, 128 => Q, _ => panic!("Unexpected {} ABI type for arm32", ty), } } } /// Get the set of allocatable registers for `func`. pub fn allocatable_registers(_func: &ir::Function) -> RegisterSet { let mut regs = RegisterSet::new(); regs.take(GPR, GPR.unit(0)); // Hard-wired 0. // %x1 is the link register which is available for allocation. regs.take(GPR, GPR.unit(2)); // Stack pointer. regs.take(GPR, GPR.unit(3)); // Global pointer. regs.take(GPR, GPR.unit(4)); // Thread pointer. // TODO: %x8 is the frame pointer. Reserve it? regs }