#![no_std] #![feature(error_in_core)] // use std::collections::HashMap; extern crate alloc; use alloc::vec::Vec; use { core::fmt::{Display, Formatter}, hashbrown::HashMap, lasso::{Rodeo, Spur}, logos::{Lexer, Logos, Span}, }; macro_rules! tokendef { ($($opcode:literal),* $(,)?) => { paste::paste! { #[derive(Clone, Copy, Debug, PartialEq, Eq, Logos)] #[logos(extras = Rodeo)] #[logos(skip r"[ \t\f]+")] #[logos(skip r"-- .*")] pub enum Token { $(#[token($opcode, |_| hbbytecode::opcode::[<$opcode:upper>])])* OpCode(u8), #[regex("[0-9]+", |l| l.slice().parse().ok())] #[regex( "-[0-9]+", |lexer| { Some(u64::from_ne_bytes(lexer.slice().parse::().ok()?.to_ne_bytes())) }, )] Integer(u64), #[regex( "r[0-9]+", |lexer| match lexer.slice()[1..].parse() { Ok(n) => Some(n), _ => None }, )] Register(u8), #[regex( r"\p{XID_Start}\p{XID_Continue}*:", |lexer| lexer.extras.get_or_intern(&lexer.slice()[..lexer.slice().len() - 1]), )] Label(Spur), #[regex( r"\p{XID_Start}\p{XID_Continue}*", |lexer| lexer.extras.get_or_intern(lexer.slice()), )] Symbol(Spur), #[token("\n")] #[token(";")] ISep, #[token(",")] PSep, } } }; } #[rustfmt::skip] tokendef![ "nop", "add", "sub", "mul", "and", "or", "xor", "sl", "sr", "srs", "cmp", "cmpu", "dir", "neg", "not", "addi", "muli", "andi", "ori", "xori", "sli", "sri", "srsi", "cmpi", "cmpui", "cp", "swa", "li", "ld", "st", "bmc", "brc", "jmp", "jeq", "jne", "jlt", "jgt", "jltu", "jgtu", "ecall", "addf", "subf", "mulf", "dirf", "fmaf", "negf", "itf", "fti", "addfi", "mulfi", ]; #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum ErrorKind { UnexpectedToken, InvalidToken, UnexpectedEnd, InvalidSymbol, } #[derive(Clone, Debug, PartialEq, Eq)] pub struct Error { pub kind: ErrorKind, pub span: Span, } impl Display for Error { fn fmt(&self, f: &mut Formatter<'_>) -> core::fmt::Result { write!(f, "Error {:?} at {:?}", self.kind, self.span) } } impl core::error::Error for Error {} macro_rules! expect_matches { ($self:expr, $($pat:pat),* $(,)?) => {$( let $pat = $self.next()? else { return Err(ErrorKind::UnexpectedToken) }; )*} } pub fn assembly(code: &str, buf: &mut Vec) -> Result<(), Error> { struct Assembler<'a> { lexer: Lexer<'a, Token>, buf: &'a mut Vec, label_map: HashMap, to_sub_label: HashMap, } impl<'a> Assembler<'a> { fn next(&mut self) -> Result { match self.lexer.next() { Some(Ok(t)) => Ok(t), Some(Err(())) => Err(ErrorKind::InvalidToken), None => Err(ErrorKind::UnexpectedEnd), } } fn assemble(&mut self) -> Result<(), ErrorKind> { use hbbytecode::opcode::*; loop { match self.lexer.next() { Some(Ok(Token::OpCode(op))) => { self.buf.push(op); match op { NOP | ECALL => Ok(()), DIR | DIRF => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), Token::PSep, Token::Register(r2), Token::PSep, Token::Register(r3), ); self.buf.extend([r0, r1, r2, r3]); Ok(()) } ADD..=CMPU | ADDF..=MULF => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), Token::PSep, Token::Register(r2), ); self.buf.extend([r0, r1, r2]); Ok(()) } BRC => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), Token::PSep, Token::Integer(count), ); self.buf.extend([ r0, r1, u8::try_from(count).map_err(|_| ErrorKind::UnexpectedToken)?, ]); Ok(()) } NEG..=NOT | CP..=SWA | NEGF..=FTI => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), ); self.buf.extend([r0, r1]); Ok(()) } LI | JMP => { expect_matches!(self, Token::Register(r0), Token::PSep); self.buf.push(r0); self.insert_imm()?; Ok(()) } ADDI..=CMPUI | BMC | JEQ..=JGTU | ADDFI..=MULFI => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), Token::PSep, ); self.buf.extend([r0, r1]); self.insert_imm()?; Ok(()) } LD..=ST => { expect_matches!( self, Token::Register(r0), Token::PSep, Token::Register(r1), Token::PSep, Token::Integer(offset), Token::PSep, Token::Integer(len), ); self.buf.extend([r0, r1]); self.buf.extend(offset.to_le_bytes()); self.buf.extend( u16::try_from(len) .map_err(|_| ErrorKind::InvalidToken)? .to_le_bytes(), ); Ok(()) } _ => unreachable!(), }?; match self.next() { Ok(Token::ISep) => (), Ok(_) => return Err(ErrorKind::UnexpectedToken), Err(ErrorKind::UnexpectedEnd) => return Ok(()), Err(e) => return Err(e), } } Some(Ok(Token::Label(lbl))) => { self.label_map.insert(lbl, self.buf.len() as u64); } Some(Ok(Token::ISep)) => (), Some(Ok(_)) => return Err(ErrorKind::UnexpectedToken), Some(Err(())) => return Err(ErrorKind::InvalidToken), None => return Ok(()), } } } fn link_local_syms(&mut self) -> Result<(), ErrorKind> { for (ix, sym) in &self.to_sub_label { self.label_map .get(sym) .ok_or(ErrorKind::InvalidSymbol)? .to_le_bytes() .iter() .enumerate() .for_each(|(i, b)| { self.buf[ix + i] = *b; }); } Ok(()) } fn insert_imm(&mut self) -> Result<(), ErrorKind> { let imm = match self.next()? { Token::Integer(i) => i.to_le_bytes(), Token::Symbol(s) => { self.to_sub_label.insert(self.buf.len(), s); [0; 8] } _ => return Err(ErrorKind::UnexpectedToken), }; self.buf.extend(imm); Ok(()) } } let mut asm = Assembler { lexer: Token::lexer(code), label_map: Default::default(), to_sub_label: Default::default(), buf, }; asm.assemble().map_err(|kind| Error { kind, span: asm.lexer.span(), })?; asm.link_local_syms() .map_err(|kind| Error { kind, span: 0..0 }) }