#![feature( assert_matches, let_chains, if_let_guard, macro_metavar_expr, anonymous_lifetime_in_impl_trait, core_intrinsics, never_type, unwrap_infallible, slice_partition_dedup, hash_raw_entry, portable_simd, iter_collect_into, new_uninit, ptr_metadata, slice_ptr_get, slice_take, map_try_insert, extract_if, ptr_internals, iter_intersperse, slice_from_ptr_range )] #![warn(clippy::dbg_macro)] #![allow(stable_features, internal_features)] #![no_std] #[cfg(feature = "std")] pub use fs::*; use { self::{ ident::Ident, lexer::TokenKind, parser::{CommentOr, Expr, ExprRef, FileId, Pos}, son::reg, ty::ArrayLen, }, alloc::{collections::BTreeMap, string::String, vec::Vec}, core::{cell::Cell, fmt::Display, ops::Range}, hashbrown::hash_map, hbbytecode as instrs, }; #[macro_use] extern crate alloc; #[cfg(any(feature = "std", test))] extern crate std; #[cfg(test)] const README: &str = include_str!("../README.md"); #[macro_export] macro_rules! run_tests { ($runner:path: $($name:ident;)*) => {$( #[test] fn $name() { $crate::run_test(core::any::type_name_of_val(&$name), stringify!($name), $crate::README, $runner); } )*}; } pub mod codegen; #[cfg(any(feature = "std", test))] pub mod fs; pub mod parser; pub mod son; mod lexer; mod vc; mod ctx_map { use core::hash::BuildHasher; pub type Hash = u64; pub type HashBuilder = core::hash::BuildHasherDefault; #[derive(Default)] pub struct IdentityHasher(u64); impl core::hash::Hasher for IdentityHasher { fn finish(&self) -> u64 { self.0 } fn write(&mut self, _: &[u8]) { unimplemented!() } fn write_u64(&mut self, i: u64) { self.0 = i; } } pub struct Key { pub value: T, pub hash: Hash, } impl core::hash::Hash for Key { fn hash(&self, state: &mut H) { state.write_u64(self.hash); } } pub trait CtxEntry { type Ctx: ?Sized; type Key<'a>: Eq + core::hash::Hash; fn key<'a>(&self, ctx: &'a Self::Ctx) -> Self::Key<'a>; } pub struct CtxMap { inner: hashbrown::HashMap, (), HashBuilder>, } impl Default for CtxMap { fn default() -> Self { Self { inner: Default::default() } } } impl CtxMap { pub fn entry<'a, 'b>( &'a mut self, key: T::Key<'b>, ctx: &'b T::Ctx, ) -> (hashbrown::hash_map::RawEntryMut<'a, Key, (), HashBuilder>, Hash) { let hash = crate::FnvBuildHasher::default().hash_one(&key); (self.inner.raw_entry_mut().from_hash(hash, |k| k.value.key(ctx) == key), hash) } pub fn get<'a>(&self, key: T::Key<'a>, ctx: &'a T::Ctx) -> Option<&T> { let hash = crate::FnvBuildHasher::default().hash_one(&key); self.inner .raw_entry() .from_hash(hash, |k| k.value.key(ctx) == key) .map(|(k, _)| &k.value) } pub fn clear(&mut self) { self.inner.clear(); } pub fn remove(&mut self, value: &T, ctx: &T::Ctx) -> Option { let (entry, _) = self.entry(value.key(ctx), ctx); match entry { hashbrown::hash_map::RawEntryMut::Occupied(o) => Some(o.remove_entry().0.value), hashbrown::hash_map::RawEntryMut::Vacant(_) => None, } } pub fn insert<'a>(&mut self, key: T::Key<'a>, value: T, ctx: &'a T::Ctx) { let (entry, hash) = self.entry(key, ctx); match entry { hashbrown::hash_map::RawEntryMut::Occupied(_) => unreachable!(), hashbrown::hash_map::RawEntryMut::Vacant(v) => { _ = v.insert(Key { hash, value }, ()) } } } pub fn get_or_insert<'a>( &mut self, key: T::Key<'a>, ctx: &'a mut T::Ctx, with: impl FnOnce(&'a mut T::Ctx) -> T, ) -> &mut T { let (entry, hash) = self.entry(key, unsafe { &mut *(&mut *ctx as *mut _) }); match entry { hashbrown::hash_map::RawEntryMut::Occupied(o) => &mut o.into_key_value().0.value, hashbrown::hash_map::RawEntryMut::Vacant(v) => { &mut v.insert(Key { hash, value: with(ctx) }, ()).0.value } } } } } mod task { use super::Offset; pub fn unpack(offset: Offset) -> Result { if offset >> 31 != 0 { Err((offset & !(1 << 31)) as usize) } else { Ok(offset) } } pub fn is_done(offset: Offset) -> bool { unpack(offset).is_ok() } pub fn id(index: usize) -> Offset { 1 << 31 | index as u32 } } mod ident { pub type Ident = u32; const LEN_BITS: u32 = 6; pub fn len(ident: u32) -> u32 { ident & ((1 << LEN_BITS) - 1) } pub fn is_null(ident: u32) -> bool { (ident >> LEN_BITS) == 0 } pub fn pos(ident: u32) -> u32 { (ident >> LEN_BITS).saturating_sub(1) } pub fn new(pos: u32, len: u32) -> u32 { debug_assert!(len < (1 << LEN_BITS)); ((pos + 1) << LEN_BITS) | len } pub fn range(ident: u32) -> core::ops::Range { let (len, pos) = (len(ident) as usize, pos(ident) as usize); pos..pos + len } } mod ty { use { crate::{ ident, lexer::TokenKind, parser::{self, Pos}, }, core::{num::NonZeroU32, ops::Range}, }; pub type ArrayLen = u32; pub type Builtin = u32; pub type Struct = u32; pub type Ptr = u32; pub type Func = u32; pub type Global = u32; pub type Module = u32; pub type Slice = u32; #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug)] pub struct Tuple(pub u32); impl Tuple { const LEN_BITS: u32 = 5; const LEN_MASK: usize = Self::MAX_LEN - 1; const MAX_LEN: usize = 1 << Self::LEN_BITS; pub fn new(pos: usize, len: usize) -> Option { if len >= Self::MAX_LEN { return None; } Some(Self((pos << Self::LEN_BITS | len) as u32)) } pub fn range(self) -> Range { let start = self.0 as usize >> Self::LEN_BITS; start..start + self.len() } pub fn len(self) -> usize { self.0 as usize & Self::LEN_MASK } pub fn empty() -> Self { Self(0) } } #[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug, Hash)] pub struct Id(NonZeroU32); impl crate::ctx_map::CtxEntry for Id { type Ctx = crate::TypeIns; type Key<'a> = crate::SymKey<'a>; fn key<'a>(&self, ctx: &'a Self::Ctx) -> Self::Key<'a> { match self.expand() { Kind::Struct(s) => { let st = &ctx.structs[s as usize]; debug_assert_ne!(st.pos, Pos::MAX); crate::SymKey::Struct(st.file, st.pos) } Kind::Ptr(p) => crate::SymKey::Pointer(&ctx.ptrs[p as usize]), Kind::Func(f) => { let fc = &ctx.funcs[f as usize]; if let Some(base) = fc.base { crate::SymKey::FuncInst(base, fc.sig.unwrap().args) } else { crate::SymKey::Decl(fc.file, fc.name) } } Kind::Global(g) => { let gb = &ctx.globals[g as usize]; crate::SymKey::Decl(gb.file, gb.name) } Kind::Slice(s) => crate::SymKey::Array(&ctx.arrays[s as usize]), Kind::Module(_) | Kind::Builtin(_) => crate::SymKey::Decl(u32::MAX, u32::MAX), } } } impl Default for Id { fn default() -> Self { Self(unsafe { NonZeroU32::new_unchecked(UNDECLARED) }) } } impl Id { pub fn is_signed(self) -> bool { (I8..=INT).contains(&self.repr()) } pub fn is_unsigned(self) -> bool { (U8..=UINT).contains(&self.repr()) } pub fn is_integer(self) -> bool { (U8..=INT).contains(&self.repr()) } pub fn strip_pointer(self) -> Self { match self.expand() { Kind::Ptr(_) => Kind::Builtin(UINT).compress(), _ => self, } } pub fn is_pointer(self) -> bool { matches!(Kind::from_ty(self), Kind::Ptr(_)) } pub fn try_upcast(self, ob: Self) -> Option { let (oa, ob) = (Self(self.0.min(ob.0)), Self(self.0.max(ob.0))); let (a, b) = (oa.strip_pointer(), ob.strip_pointer()); Some(match () { _ if oa == Self::from(NEVER) => ob, _ if ob == Self::from(NEVER) => oa, _ if oa == ob => oa, _ if oa.is_pointer() && ob.is_pointer() => return None, _ if a.is_signed() && b.is_signed() || a.is_unsigned() && b.is_unsigned() => ob, _ if a.is_unsigned() && b.is_signed() && a.repr() - U8 < b.repr() - I8 => ob, _ if oa.is_integer() && ob.is_pointer() => ob, _ => return None, }) } pub fn expand(self) -> Kind { Kind::from_ty(self) } pub const fn repr(self) -> u32 { self.0.get() } #[allow(unused)] pub fn is_struct(&self) -> bool { matches!(self.expand(), Kind::Struct(_)) } } impl From for Id { fn from(id: u64) -> Self { Self(unsafe { NonZeroU32::new_unchecked(id as _) }) } } impl From for Id { fn from(id: u32) -> Self { Kind::Builtin(id).compress() } } const fn array_to_lower_case(array: [u8; N]) -> [u8; N] { let mut result = [0; N]; let mut i = 0; while i < N { result[i] = array[i].to_ascii_lowercase(); i += 1; } result } // const string to lower case macro_rules! builtin_type { ($($name:ident;)*) => { $(pub const $name: Builtin = ${index(0)} + 1;)* mod __lc_names { use super::*; $(pub const $name: &[u8] = &array_to_lower_case(unsafe { *(stringify!($name).as_ptr() as *const [u8; stringify!($name).len()]) });)* } #[allow(dead_code)] impl Id { $(pub const $name: Self = Kind::Builtin($name).compress();)* } pub fn from_str(name: &str) -> Option { match name.as_bytes() { $(__lc_names::$name => Some($name),)* _ => None, } } pub fn to_str(ty: Builtin) -> &'static str { match ty { $($name => unsafe { core::str::from_utf8_unchecked(__lc_names::$name) },)* v => unreachable!("invalid type: {}", v), } } }; } builtin_type! { UNDECLARED; NEVER; VOID; TYPE; BOOL; U8; U16; U32; UINT; I8; I16; I32; INT; LEFT_UNREACHABLE; RIGHT_UNREACHABLE; } macro_rules! type_kind { ($(#[$meta:meta])* $vis:vis enum $name:ident {$( $variant:ident, )*}) => { $(#[$meta])* $vis enum $name { $($variant($variant),)* } impl $name { const FLAG_BITS: u32 = (${count($variant)} as u32).next_power_of_two().ilog2(); const FLAG_OFFSET: u32 = core::mem::size_of::() as u32 * 8 - Self::FLAG_BITS; const INDEX_MASK: u32 = (1 << (32 - Self::FLAG_BITS)) - 1; $vis fn from_ty(ty: Id) -> Self { let (flag, index) = (ty.repr() >> Self::FLAG_OFFSET, ty.repr() & Self::INDEX_MASK); match flag { $(${index(0)} => Self::$variant(index),)* i => unreachable!("{i}"), } } $vis const fn compress(self) -> Id { let (index, flag) = match self { $(Self::$variant(index) => (index, ${index(0)}),)* }; Id(unsafe { NonZeroU32::new_unchecked((flag << Self::FLAG_OFFSET) | index) }) } $vis const fn inner(self) -> u32 { match self { $(Self::$variant(index) => index,)* } } } }; } type_kind! { #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum Kind { Builtin, Struct, Ptr, Func, Global, Module, Slice, } } impl Default for Kind { fn default() -> Self { Self::Builtin(UNDECLARED) } } pub struct Display<'a> { tys: &'a super::Types, files: &'a [parser::Ast], ty: Id, } impl<'a> Display<'a> { pub(super) fn new(tys: &'a super::Types, files: &'a [parser::Ast], ty: Id) -> Self { Self { tys, files, ty } } fn rety(&self, ty: Id) -> Self { Self::new(self.tys, self.files, ty) } } impl<'a> core::fmt::Display for Display<'a> { fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { use Kind as TK; match TK::from_ty(self.ty) { TK::Module(idx) => write!(f, "@use({:?})[{}]", self.files[idx as usize].path, idx), TK::Builtin(ty) => write!(f, "{}", to_str(ty)), TK::Ptr(ty) => { write!(f, "^{}", self.rety(self.tys.ins.ptrs[ty as usize].base)) } TK::Struct(idx) => { let record = &self.tys.ins.structs[idx as usize]; if ident::is_null(record.name) { write!(f, "[{idx}]{{")?; for (i, &super::Field { name, ty }) in self.tys.struct_fields(idx).iter().enumerate() { if i != 0 { write!(f, ", ")?; } write!(f, "{}: {}", self.tys.names.ident_str(name), self.rety(ty))?; } write!(f, "}}") } else { let file = &self.files[record.file as usize]; write!(f, "{}", file.ident_str(record.name)) } } TK::Func(idx) => write!(f, "fn{idx}"), TK::Global(idx) => write!(f, "global{idx}"), TK::Slice(idx) => { let array = self.tys.ins.arrays[idx as usize]; match array.len { ArrayLen::MAX => write!(f, "[{}]", self.rety(array.ty)), len => write!(f, "[{}; {len}]", self.rety(array.ty)), } } } } } pub fn bin_ret(ty: Id, op: TokenKind) -> Id { use TokenKind as T; match op { T::Lt | T::Gt | T::Le | T::Ge | T::Ne | T::Eq => BOOL.into(), _ => ty, } } } type EncodedInstr = (usize, [u8; instrs::MAX_SIZE]); type Offset = u32; type Size = u32; fn emit(out: &mut Vec, (len, instr): EncodedInstr) { out.extend_from_slice(&instr[..len]); } #[derive(PartialEq, Eq, Hash, Clone, Copy)] pub enum SymKey<'a> { Pointer(&'a Ptr), Struct(FileId, Pos), FuncInst(ty::Func, ty::Tuple), Decl(FileId, Ident), Array(&'a Array), } #[derive(Clone, Copy)] struct Sig { args: ty::Tuple, ret: ty::Id, } struct Func { file: FileId, name: Ident, base: Option, computed: Option, expr: ExprRef, sig: Option, offset: Offset, // TODO: change to indices into common vec relocs: Vec, code: Vec, } impl Default for Func { fn default() -> Self { Self { file: u32::MAX, name: 0, base: None, computed: None, expr: Default::default(), sig: None, offset: u32::MAX, relocs: Default::default(), code: Default::default(), } } } struct TypedReloc { target: ty::Id, reloc: Reloc, } struct Global { file: FileId, name: Ident, ty: ty::Id, offset: Offset, data: Vec, } impl Default for Global { fn default() -> Self { Self { ty: Default::default(), offset: u32::MAX, data: Default::default(), file: u32::MAX, name: u32::MAX, } } } // TODO: make into bit struct (width: u2, sub_offset: u3, offset: u27) #[derive(Clone, Copy, Debug)] struct Reloc { offset: Offset, sub_offset: u8, width: u8, } impl Reloc { fn new(offset: usize, sub_offset: u8, width: u8) -> Self { Self { offset: offset as u32, sub_offset, width } } fn apply_jump(mut self, code: &mut [u8], to: u32, from: u32) -> i64 { self.offset += from; let offset = to as i64 - self.offset as i64; self.write_offset(code, offset); offset } fn write_offset(&self, code: &mut [u8], offset: i64) { let bytes = offset.to_ne_bytes(); let slice = &mut code[self.offset as usize + self.sub_offset as usize..]; slice[..self.width as usize].copy_from_slice(&bytes[..self.width as usize]); } } struct Field { name: Ident, ty: ty::Id, } #[derive(Default)] struct Struct { name: Ident, pos: Pos, file: FileId, size: Cell, align: Cell, explicit_alignment: Option, field_start: u32, } #[derive(PartialEq, Eq, Hash)] pub struct Ptr { base: ty::Id, } #[derive(Clone, Copy, PartialEq, Eq, Hash)] pub struct Array { ty: ty::Id, len: ArrayLen, } struct ParamAlloc(Range); impl ParamAlloc { pub fn next(&mut self) -> u8 { self.0.next().expect("too many paramteters") } fn next_wide(&mut self) -> u8 { (self.next(), self.next()).0 } } #[repr(packed)] #[allow(dead_code)] struct AbleOsExecutableHeader { magic_number: [u8; 3], executable_version: u32, code_length: u64, data_length: u64, debug_length: u64, config_length: u64, metadata_length: u64, } impl ctx_map::CtxEntry for Ident { type Ctx = str; type Key<'a> = &'a str; fn key<'a>(&self, ctx: &'a Self::Ctx) -> Self::Key<'a> { unsafe { ctx.get_unchecked(ident::range(*self)) } } } #[derive(Default)] struct IdentInterner { lookup: ctx_map::CtxMap, strings: String, } impl IdentInterner { fn intern(&mut self, ident: &str) -> Ident { let (entry, hash) = self.lookup.entry(ident, &self.strings); match entry { hash_map::RawEntryMut::Occupied(o) => o.get_key_value().0.value, hash_map::RawEntryMut::Vacant(v) => { let id = ident::new(self.strings.len() as _, ident.len() as _); self.strings.push_str(ident); v.insert(ctx_map::Key { hash, value: id }, ()); id } } } fn ident_str(&self, ident: Ident) -> &str { &self.strings[ident::range(ident)] } fn project(&self, ident: &str) -> Option { self.lookup.get(ident, &self.strings).copied() } } #[derive(Default)] struct TypesTmp { fields: Vec, frontier: Vec, globals: Vec, funcs: Vec, } #[derive(Default)] pub struct TypeIns { funcs: Vec, args: Vec, globals: Vec, structs: Vec, fields: Vec, ptrs: Vec, arrays: Vec, } #[derive(Default)] struct Types { syms: ctx_map::CtxMap, names: IdentInterner, ins: TypeIns, tmp: TypesTmp, } const HEADER_SIZE: usize = core::mem::size_of::(); impl Types { fn struct_field_range(&self, strct: ty::Struct) -> Range { let start = self.ins.structs[strct as usize].field_start as usize; let end = self .ins .structs .get(strct as usize + 1) .map_or(self.ins.fields.len(), |s| s.field_start as usize); start..end } fn struct_fields(&self, strct: ty::Struct) -> &[Field] { &self.ins.fields[self.struct_field_range(strct)] } fn find_type( &mut self, file: FileId, id: Result, files: &[parser::Ast], ) -> Option { if let Ok(id) = id && let Some(&ty) = self.syms.get(SymKey::Decl(file, id), &self.ins) { if let ty::Kind::Global(g) = ty.expand() { let g = &self.ins.globals[g as usize]; if g.ty == ty::Id::TYPE { return Some(ty::Id::from( u32::from_ne_bytes(*g.data.first_chunk().unwrap()) as u64 )); } } return Some(ty); } let f = &files[file as usize]; let (Expr::BinOp { left, right, .. }, name) = f.find_decl(id)? else { unreachable!() }; let ty = left .find_pattern_path(name, right, |right| self.ty(file, right, files)) .unwrap_or_else(|_| unreachable!())?; if let ty::Kind::Struct(s) = ty.expand() { self.ins.structs[s as usize].name = name; } self.syms.insert(SymKey::Decl(file, name), ty, &self.ins); Some(ty) } /// returns none if comptime eval is required fn ty(&mut self, file: FileId, expr: &Expr, files: &[parser::Ast]) -> Option { Some(match *expr { Expr::Mod { id, .. } => ty::Kind::Module(id).compress(), Expr::UnOp { op: TokenKind::Xor, val, .. } => { let base = self.ty(file, val, files)?; self.make_ptr(base) } Expr::Ident { id, .. } if ident::is_null(id) => id.into(), Expr::Ident { id, .. } => self.find_type(file, Ok(id), files)?, Expr::Field { target, name, .. } => { let ty::Kind::Module(file) = self.ty(file, target, files)?.expand() else { return None; }; self.find_type(file, Err(name), files)? } Expr::Slice { size: None, item, .. } => { let ty = self.ty(file, item, files)?; self.make_array(ty, ArrayLen::MAX) } Expr::Slice { size: Some(&Expr::Number { value, .. }), item, .. } => { let ty = self.ty(file, item, files)?; self.make_array(ty, value as _) } Expr::Struct { pos, fields, packed, .. } => { let sym = SymKey::Struct(file, pos); if let Some(&ty) = self.syms.get(sym, &self.ins) { return Some(ty); } let prev_tmp = self.tmp.fields.len(); for field in fields.iter().filter_map(CommentOr::or) { let Some(ty) = self.ty(file, &field.ty, files) else { self.tmp.fields.truncate(prev_tmp); return None; }; self.tmp.fields.push(Field { name: self.names.intern(field.name), ty }); } self.ins.structs.push(Struct { file, pos, field_start: self.ins.fields.len() as _, explicit_alignment: packed.then_some(1), ..Default::default() }); self.ins.fields.extend(self.tmp.fields.drain(prev_tmp..)); let ty = ty::Kind::Struct(self.ins.structs.len() as u32 - 1).compress(); self.syms.insert(sym, ty, &self.ins); ty } _ => return None, }) } fn assemble(&mut self, to: &mut Vec) { to.extend([0u8; HEADER_SIZE]); emit(to, instrs::jal(reg::RET_ADDR, reg::ZERO, 0)); emit(to, instrs::tx()); let exe = self.dump_reachable(0, to); Reloc::new(HEADER_SIZE, 3, 4).apply_jump(to, self.ins.funcs[0].offset, 0); unsafe { *to.as_mut_ptr().cast::() = exe } } fn dump_reachable(&mut self, from: ty::Func, to: &mut Vec) -> AbleOsExecutableHeader { debug_assert!(self.tmp.frontier.is_empty()); debug_assert!(self.tmp.funcs.is_empty()); debug_assert!(self.tmp.globals.is_empty()); self.tmp.frontier.push(ty::Kind::Func(from).compress()); while let Some(itm) = self.tmp.frontier.pop() { match itm.expand() { ty::Kind::Func(func) => { let fuc = &mut self.ins.funcs[func as usize]; if task::is_done(fuc.offset) { continue; } fuc.offset = 0; self.tmp.funcs.push(func); self.tmp.frontier.extend(fuc.relocs.iter().map(|r| r.target)); } ty::Kind::Global(glob) => { let glb = &mut self.ins.globals[glob as usize]; if task::is_done(glb.offset) { continue; } glb.offset = 0; self.tmp.globals.push(glob); } _ => unreachable!(), } } for &func in &self.tmp.funcs { let fuc = &mut self.ins.funcs[func as usize]; fuc.offset = to.len() as _; to.extend(&fuc.code); } let code_length = to.len(); for global in self.tmp.globals.drain(..) { let global = &mut self.ins.globals[global as usize]; global.offset = to.len() as _; to.extend(&global.data); } let data_length = to.len() - code_length; for func in self.tmp.funcs.drain(..) { let fuc = &self.ins.funcs[func as usize]; for rel in &fuc.relocs { let offset = match rel.target.expand() { ty::Kind::Func(fun) => self.ins.funcs[fun as usize].offset, ty::Kind::Global(glo) => self.ins.globals[glo as usize].offset, _ => unreachable!(), }; rel.reloc.apply_jump(to, offset, fuc.offset); } } AbleOsExecutableHeader { magic_number: [0x15, 0x91, 0xD2], executable_version: 0, code_length: (code_length - HEADER_SIZE) as _, data_length: data_length as _, debug_length: 0, config_length: 0, metadata_length: 0, } } pub fn disasm<'a>( &'a self, mut sluce: &[u8], files: &'a [parser::Ast], output: &mut String, eca_handler: impl FnMut(&mut &[u8]), ) -> Result<(), hbbytecode::DisasmError<'a>> { use instrs::DisasmItem; let functions = self .ins .funcs .iter() .filter(|f| task::is_done(f.offset)) .map(|f| { let name = if f.file != u32::MAX { let file = &files[f.file as usize]; let Expr::BinOp { left: &Expr::Ident { name, .. }, .. } = f.expr.get(file).unwrap() else { unreachable!() }; name } else { "target_fn" }; (f.offset, (name, f.code.len() as u32, DisasmItem::Func)) }) .chain(self.ins.globals.iter().filter(|g| task::is_done(g.offset)).map(|g| { let name = if g.file == u32::MAX { core::str::from_utf8(&g.data).unwrap() } else { let file = &files[g.file as usize]; file.ident_str(g.name) }; (g.offset, (name, g.data.len() as Size, DisasmItem::Global)) })) .collect::>(); instrs::disasm(&mut sluce, &functions, output, eca_handler) } fn parama(&self, ret: impl Into) -> ParamAlloc { ParamAlloc(2 + (9..=16).contains(&self.size_of(ret.into())) as u8..12) } fn make_ptr(&mut self, base: ty::Id) -> ty::Id { ty::Kind::Ptr(self.make_ptr_low(base)).compress() } fn make_ptr_low(&mut self, base: ty::Id) -> ty::Ptr { let ptr = Ptr { base }; let (entry, hash) = self.syms.entry(SymKey::Pointer(&ptr), &self.ins); match entry { hash_map::RawEntryMut::Occupied(o) => o.get_key_value().0.value, hash_map::RawEntryMut::Vacant(v) => { self.ins.ptrs.push(ptr); v.insert( ctx_map::Key { value: ty::Kind::Ptr(self.ins.ptrs.len() as u32 - 1).compress(), hash, }, (), ) .0 .value } } .expand() .inner() } fn make_array(&mut self, ty: ty::Id, len: ArrayLen) -> ty::Id { ty::Kind::Slice(self.make_array_low(ty, len)).compress() } fn make_array_low(&mut self, ty: ty::Id, len: ArrayLen) -> ty::Slice { self.syms .get_or_insert(SymKey::Array(&Array { ty, len }), &mut self.ins, |ins| { ins.arrays.push(Array { ty, len }); ty::Kind::Slice(ins.arrays.len() as u32 - 1).compress() }) .expand() .inner() //let array = Array { ty, len }; //let (entry, hash) = self.syms.entry(SymKey::Array(&array), &self.ins); //match entry { // hash_map::RawEntryMut::Occupied(o) => o.get_key_value().0.value, // hash_map::RawEntryMut::Vacant(v) => { // self.ins.arrays.push(array); // v.insert( // ctx_map::Key { // value: ty::Kind::Slice(self.ins.ptrs.len() as u32 - 1).compress(), // hash, // }, // (), // ) // .0 // .value // } //} //.expand() //.inner() } fn size_of(&self, ty: ty::Id) -> Size { match ty.expand() { ty::Kind::Ptr(_) => 8, ty::Kind::Builtin(ty::VOID) => 0, ty::Kind::Builtin(ty::NEVER) => 0, ty::Kind::Builtin(ty::INT | ty::UINT) => 8, ty::Kind::Builtin(ty::I32 | ty::U32 | ty::TYPE) => 4, ty::Kind::Builtin(ty::I16 | ty::U16) => 2, ty::Kind::Builtin(ty::I8 | ty::U8 | ty::BOOL) => 1, ty::Kind::Slice(arr) => { let arr = &self.ins.arrays[arr as usize]; match arr.len { 0 => 0, ArrayLen::MAX => 16, len => self.size_of(arr.ty) * len, } } ty::Kind::Struct(stru) => { if self.ins.structs[stru as usize].size.get() != 0 { return self.ins.structs[stru as usize].size.get(); } let mut oiter = OffsetIter::new(stru, self); while oiter.next(self).is_some() {} self.ins.structs[stru as usize].size.set(oiter.offset); oiter.offset } ty => unimplemented!("size_of: {:?}", ty), } } fn align_of(&self, ty: ty::Id) -> Size { match ty.expand() { ty::Kind::Struct(stru) => { if self.ins.structs[stru as usize].align.get() != 0 { return self.ins.structs[stru as usize].align.get() as _; } let align = self.ins.structs[stru as usize].explicit_alignment.map_or_else( || { self.struct_fields(stru) .iter() .map(|&Field { ty, .. }| self.align_of(ty)) .max() .unwrap_or(1) }, |a| a as _, ); self.ins.structs[stru as usize].align.set(align.try_into().unwrap()); align } ty::Kind::Slice(arr) => { let arr = &self.ins.arrays[arr as usize]; match arr.len { ArrayLen::MAX => 8, _ => self.align_of(arr.ty), } } _ => self.size_of(ty).max(1), } } fn base_of(&self, ty: ty::Id) -> Option { match ty.expand() { ty::Kind::Ptr(p) => Some(self.ins.ptrs[p as usize].base), _ => None, } } fn find_struct_field(&self, s: ty::Struct, name: &str) -> Option { let name = self.names.project(name)?; self.struct_fields(s).iter().position(|f| f.name == name) } } struct OffsetIter { strct: ty::Struct, offset: Offset, fields: Range, } impl OffsetIter { fn new(strct: ty::Struct, tys: &Types) -> Self { Self { strct, offset: 0, fields: tys.struct_field_range(strct) } } fn offset_of(tys: &Types, idx: ty::Struct, field: &str) -> Option<(Offset, ty::Id)> { let field_id = tys.names.project(field)?; OffsetIter::new(idx, tys) .into_iter(tys) .find(|(f, _)| f.name == field_id) .map(|(f, off)| (off, f.ty)) } fn next<'a>(&mut self, tys: &'a Types) -> Option<(&'a Field, Offset)> { let stru = &tys.ins.structs[self.strct as usize]; let field = &tys.ins.fields[self.fields.next()?]; let align = stru.explicit_alignment.map_or_else(|| tys.align_of(field.ty), |a| a as u32); self.offset = (self.offset + align - 1) & !(align - 1); let off = self.offset; self.offset += tys.size_of(field.ty); Some((field, off)) } fn next_ty(&mut self, tys: &Types) -> Option<(ty::Id, Offset)> { let (field, off) = self.next(tys)?; Some((field.ty, off)) } fn into_iter(mut self, tys: &Types) -> impl Iterator { core::iter::from_fn(move || self.next(tys)) } } type HashMap = hashbrown::HashMap; type _HashSet = hashbrown::HashSet; type FnvBuildHasher = core::hash::BuildHasherDefault; struct FnvHasher(u64); impl core::hash::Hasher for FnvHasher { fn finish(&self) -> u64 { self.0 } fn write(&mut self, bytes: &[u8]) { self.0 = bytes.iter().fold(self.0, |hash, &byte| { let mut hash = hash; hash ^= byte as u64; hash = hash.wrapping_mul(0x100000001B3); hash }); } } impl Default for FnvHasher { fn default() -> Self { Self(0xCBF29CE484222325) } } #[cfg(test)] pub fn run_test( name: &'static str, ident: &'static str, input: &'static str, test: fn(&'static str, &'static str, &mut String), ) { use std::{io::Write, path::PathBuf, string::ToString}; let filter = std::env::var("PT_FILTER").unwrap_or_default(); if !filter.is_empty() && !name.contains(&filter) { return; } let mut output = String::new(); { struct DumpOut<'a>(&'a mut String); impl Drop for DumpOut<'_> { fn drop(&mut self) { if std::thread::panicking() { std::println!("{}", self.0); } } } let dump = DumpOut(&mut output); test(ident, input, dump.0); } let mut root = PathBuf::from( std::env::var("PT_TEST_ROOT") .unwrap_or(concat!(env!("CARGO_MANIFEST_DIR"), "/tests").to_string()), ); root.push(name.replace("::", "_").replace(concat!(env!("CARGO_PKG_NAME"), "_"), "")); root.set_extension("txt"); let expected = std::fs::read_to_string(&root).unwrap_or_default(); if output == expected { return; } if std::env::var("PT_UPDATE").is_ok() { std::fs::write(&root, output).unwrap(); return; } if !root.exists() { std::fs::create_dir_all(root.parent().unwrap()).unwrap(); std::fs::write(&root, vec![]).unwrap(); } let mut proc = std::process::Command::new("diff") .arg("-u") .arg("--color") .arg(&root) .arg("-") .stdin(std::process::Stdio::piped()) .stdout(std::process::Stdio::inherit()) .spawn() .unwrap(); proc.stdin.as_mut().unwrap().write_all(output.as_bytes()).unwrap(); proc.wait().unwrap(); panic!("test failed"); } #[cfg(test)] fn test_parse_files(ident: &'static str, input: &'static str) -> Vec { use std::{borrow::ToOwned, string::ToString}; fn find_block(mut input: &'static str, test_name: &'static str) -> &'static str { const CASE_PREFIX: &str = "#### "; const CASE_SUFFIX: &str = "\n```hb"; loop { let Some(pos) = input.find(CASE_PREFIX) else { unreachable!("test {test_name} not found"); }; input = unsafe { input.get_unchecked(pos + CASE_PREFIX.len()..) }; if !input.starts_with(test_name) { continue; } input = unsafe { input.get_unchecked(test_name.len()..) }; if !input.starts_with(CASE_SUFFIX) { continue; } input = unsafe { input.get_unchecked(CASE_SUFFIX.len()..) }; let end = input.find("```").unwrap_or(input.len()); break unsafe { input.get_unchecked(..end) }; } } let input = find_block(input, ident); let mut module_map = Vec::new(); let mut last_start = 0; let mut last_module_name = "test"; for (i, m) in input.match_indices("// in module: ") { parser::test::format(ident, input[last_start..i].trim()); module_map.push((last_module_name, &input[last_start..i])); let (module_name, _) = input[i + m.len()..].split_once('\n').unwrap(); last_module_name = module_name; last_start = i + m.len() + module_name.len() + 1; } parser::test::format(ident, input[last_start..].trim()); module_map.push((last_module_name, input[last_start..].trim())); let loader = |path: &str, _: &str| { module_map .iter() .position(|&(name, _)| name == path) .map(|i| i as parser::FileId) .ok_or("Not Found".to_string()) }; let mut stack = parser::StackAlloc::default(); module_map .iter() .map(|&(path, content)| parser::Ast::new(path, content.to_owned(), &mut stack, &loader)) .collect() } #[cfg(test)] fn test_run_vm(out: &[u8], output: &mut String) { use core::fmt::Write; let mut stack = [0_u64; 1024 * 20]; let mut vm = unsafe { hbvm::Vm::<_, { 1024 * 100 }>::new( LoggedMem::default(), hbvm::mem::Address::new(out.as_ptr() as u64).wrapping_add(HEADER_SIZE), ) }; vm.write_reg(codegen::STACK_PTR, unsafe { stack.as_mut_ptr().add(stack.len()) } as u64); let stat = loop { match vm.run() { Ok(hbvm::VmRunOk::End) => break Ok(()), Ok(hbvm::VmRunOk::Ecall) => match vm.read_reg(2).0 { 1 => writeln!(output, "ev: Ecall").unwrap(), // compatibility with a test 69 => { let [size, align] = [vm.read_reg(3).0 as usize, vm.read_reg(4).0 as usize]; let layout = core::alloc::Layout::from_size_align(size, align).unwrap(); let ptr = unsafe { alloc::alloc::alloc(layout) }; vm.write_reg(1, ptr as u64); } 96 => { let [ptr, size, align] = [ vm.read_reg(3).0 as usize, vm.read_reg(4).0 as usize, vm.read_reg(5).0 as usize, ]; let layout = core::alloc::Layout::from_size_align(size, align).unwrap(); unsafe { alloc::alloc::dealloc(ptr as *mut u8, layout) }; } 3 => vm.write_reg(1, 42), unknown => unreachable!("unknown ecall: {unknown:?}"), }, Ok(hbvm::VmRunOk::Timer) => { writeln!(output, "timed out").unwrap(); break Ok(()); } Ok(ev) => writeln!(output, "ev: {:?}", ev).unwrap(), Err(e) => break Err(e), } }; writeln!(output, "code size: {}", out.len() - HEADER_SIZE).unwrap(); writeln!(output, "ret: {:?}", vm.read_reg(1).0).unwrap(); writeln!(output, "status: {:?}", stat).unwrap(); } #[derive(Default)] pub struct LoggedMem { pub mem: hbvm::mem::HostMemory, op_buf: Vec, disp_buf: String, prev_instr: Option, } impl LoggedMem { unsafe fn display_instr(&mut self, instr: hbbytecode::Instr, addr: hbvm::mem::Address) { let novm: *const hbvm::Vm = core::ptr::null(); let offset = core::ptr::addr_of!((*novm).memory) as usize; let regs = unsafe { &*core::ptr::addr_of!( (*(((self as *mut _ as *mut u8).sub(offset)) as *const hbvm::Vm)) .registers ) }; let mut bytes = core::slice::from_raw_parts( (addr.get() - 1) as *const u8, core::mem::size_of::() + 1, ); use core::fmt::Write; hbbytecode::parse_args(&mut bytes, instr, &mut self.op_buf).unwrap(); debug_assert!(bytes.is_empty()); self.disp_buf.clear(); write!(self.disp_buf, "{:<10}", format!("{instr:?}")).unwrap(); for (i, op) in self.op_buf.drain(..).enumerate() { if i != 0 { write!(self.disp_buf, ", ").unwrap(); } write!(self.disp_buf, "{op:?}").unwrap(); if let hbbytecode::Oper::R(r) = op { write!(self.disp_buf, "({})", regs[r as usize].0).unwrap() } } log::trace!("read-typed: {:x}: {}", addr.get(), self.disp_buf); } } impl hbvm::mem::Memory for LoggedMem { unsafe fn load( &mut self, addr: hbvm::mem::Address, target: *mut u8, count: usize, ) -> Result<(), hbvm::mem::LoadError> { log::trace!( "load: {:x} {}", addr.get(), AsHex(core::slice::from_raw_parts(addr.get() as *const u8, count)) ); self.mem.load(addr, target, count) } unsafe fn store( &mut self, addr: hbvm::mem::Address, source: *const u8, count: usize, ) -> Result<(), hbvm::mem::StoreError> { log::trace!( "store: {:x} {}", addr.get(), AsHex(core::slice::from_raw_parts(source, count)) ); self.mem.store(addr, source, count) } unsafe fn prog_read(&mut self, addr: hbvm::mem::Address) -> T { if log::log_enabled!(log::Level::Trace) { if core::any::TypeId::of::() == core::any::TypeId::of::() { if let Some(instr) = self.prev_instr { self.display_instr::<()>(instr, addr); } self.prev_instr = hbbytecode::Instr::try_from(*(addr.get() as *const u8)).ok(); } else { let instr = self.prev_instr.take().unwrap(); self.display_instr::(instr, addr); } } self.mem.prog_read(addr) } } struct AsHex<'a>(&'a [u8]); impl Display for AsHex<'_> { fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { for &b in self.0 { write!(f, "{b:02x}")?; } Ok(()) } }