use crate::ident::Ident; use { crate::{ instrs, lexer, log, parser::{self}, }, std::rc::Rc, }; use {lexer::TokenKind as T, parser::Expr as E}; type LabelId = u32; type Reg = u8; type MaskElem = u64; type Type = u32; #[derive(Debug)] struct LinReg(Reg); #[cfg(debug_assertions)] impl Drop for LinReg { fn drop(&mut self) { if !std::thread::panicking() { panic!("reg leaked"); } } } pub mod bt { use super::*; const fn builtin_type(id: u32) -> Type { Type::MAX - id } macro_rules! builtin_type { ($($name:ident;)*) => {$( pub const $name: Type = TypeKind::Builtin(${index(0)}).encode(); )*}; } builtin_type! { VOID; NEVER; INT; BOOL; } } #[derive(Debug)] enum TypeKind { Builtin(Type), Struct(Type), Pointer(Type), } impl TypeKind { const fn from_ty(ty: Type) -> Self { let (flag, index) = (ty & 0b11, ty >> 2); match flag { 0 => Self::Builtin(index), 1 => Self::Pointer(index), 2 => Self::Struct(index), _ => unreachable!(), } } const fn encode(self) -> Type { let (index, flag) = match self { Self::Builtin(index) => (index, 0), Self::Pointer(index) => (index, 1), Self::Struct(index) => (index, 2), }; index << 2 | flag } } const STACK_PTR: Reg = 254; const ZERO: Reg = 0; const RET_ADDR: Reg = 31; const ELEM_WIDTH: usize = std::mem::size_of::() * 8; struct Frame { label: LabelId, prev_relocs: usize, offset: u32, } struct Reloc { id: LabelId, offset: u32, instr_offset: u16, size: u16, } struct StackReloc { offset: u32, size: u16, } #[derive(Default)] pub struct Func { code: Vec, relocs: Vec, } impl Func { pub fn extend(&mut self, bytes: &[u8]) { self.code.extend_from_slice(bytes); } pub fn offset(&mut self, id: LabelId, instr_offset: u16, size: u16) { self.relocs.push(Reloc { id, offset: self.code.len() as u32, instr_offset, size, }); } fn encode(&mut self, (len, instr): (usize, [u8; instrs::MAX_SIZE])) { let name = instrs::NAMES[instr[0] as usize]; log::dbg!( "{:08x}: {}: {}", self.code.len(), name, instr .iter() .take(len) .skip(1) .map(|b| format!("{:02x}", b)) .collect::() ); self.code.extend_from_slice(&instr[..len]); } fn push(&mut self, value: Reg, size: usize) { self.subi64(STACK_PTR, STACK_PTR, size as _); self.encode(instrs::st(value, STACK_PTR, 0, size as _)); } fn pop(&mut self, value: Reg, size: usize) { self.encode(instrs::ld(value, STACK_PTR, 0, size as _)); self.encode(instrs::addi64(STACK_PTR, STACK_PTR, size as _)); } fn subi64(&mut self, dest: Reg, src: Reg, imm: u64) { self.encode(instrs::addi64(dest, src, imm.wrapping_neg())); } fn call(&mut self, func: LabelId) { self.offset(func, 3, 4); self.encode(instrs::jal(RET_ADDR, ZERO, 0)); } fn ret(&mut self) { self.pop(RET_ADDR, 8); self.encode(instrs::jala(ZERO, RET_ADDR, 0)); } fn prelude(&mut self, entry: LabelId) { self.call(entry); self.encode(instrs::tx()); } fn relocate(&mut self, labels: &[FnLabel], shift: i64) { for reloc in self.relocs.drain(..) { let label = &labels[reloc.id as usize]; let offset = if reloc.size == 8 { reloc.offset as i64 } else { label.offset as i64 - reloc.offset as i64 } + shift; log::dbg!( label.name, offset, reloc.size, reloc.instr_offset, reloc.offset, shift, label.offset ); let dest = &mut self.code[reloc.offset as usize + reloc.instr_offset as usize..] [..reloc.size as usize]; match reloc.size { 2 => dest.copy_from_slice(&(offset as i16).to_le_bytes()), 4 => dest.copy_from_slice(&(offset as i32).to_le_bytes()), 8 => dest.copy_from_slice(&(offset as i64).to_le_bytes()), _ => unreachable!(), }; } } } #[derive(Default)] pub struct RegAlloc { free: Vec, // TODO:use 256 bit mask instead used: Vec, } impl RegAlloc { fn init_callee(&mut self) { self.clear(); self.free.extend(32..=253); } fn clear(&mut self) { self.free.clear(); self.used.clear(); } fn allocate(&mut self) -> LinReg { let reg = self.free.pop().expect("TODO: we need to spill"); if self.used.binary_search_by_key(&!reg, |&r| !r).is_err() { self.used.push(reg); } LinReg(reg) } fn free(&mut self, reg: LinReg) { self.free.push(reg.0); std::mem::forget(reg); } } struct FnLabel { offset: u32, // TODO: use different stile of identifier that does not allocate, eg. index + length into a // file name: Ident, } struct Variable { id: Ident, value: Value, } struct RetReloc { offset: u32, instr_offset: u16, size: u16, } struct Loop { offset: u32, relocs: Vec, } struct Struct { id: Ident, fields: Rc<[(Rc, Type)]>, } pub struct Codegen<'a> { path: &'a std::path::Path, ret: Type, gpa: RegAlloc, code: Func, temp: Func, labels: Vec, stack_size: u64, vars: Vec, stack_relocs: Vec, ret_relocs: Vec, loops: Vec, records: Vec, pointers: Vec, main: Option, } impl<'a> Codegen<'a> { pub fn new() -> Self { Self { path: std::path::Path::new(""), ret: bt::VOID, gpa: Default::default(), code: Default::default(), temp: Default::default(), labels: Default::default(), stack_size: 0, vars: Default::default(), stack_relocs: Default::default(), ret_relocs: Default::default(), loops: Default::default(), records: Default::default(), pointers: Default::default(), main: None, } } pub fn file( &mut self, path: &'a std::path::Path, exprs: &'a [parser::Expr<'a>], ) -> std::fmt::Result { self.path = path; for expr in exprs { self.expr(expr, None); } Ok(()) } fn size_of(&self, ty: Type) -> u64 { match ty { bt::INT => 8, bt::BOOL => 1, _ => match TypeKind::from_ty(ty) { TypeKind::Pointer(_) => 8, TypeKind::Builtin(e) => unreachable!("{:?}", e), TypeKind::Struct(ty) => self.records[ty as usize] .fields .iter() .map(|(_, ty)| self.size_of(*ty)) .sum(), }, } } fn loc_to_reg(&mut self, loc: Loc) -> LinReg { match loc { Loc::RegRef(rr) => { let reg = self.gpa.allocate(); self.code.encode(instrs::cp(reg.0, rr)); reg } Loc::Reg(reg) => reg, Loc::Deref(dreg) => { let reg = self.gpa.allocate(); self.code.encode(instrs::ld(reg.0, dreg.0, 0, 8)); self.gpa.free(dreg); reg } Loc::Imm(imm) => { let reg = self.gpa.allocate(); self.code.encode(instrs::li64(reg.0, imm)); reg } Loc::Stack(offset) | Loc::StackRef(offset) => { let reg = self.gpa.allocate(); self.load_stack(reg.0, offset, 8); reg } } } fn alloc_stack(&mut self, size: u32) -> u64 { let offset = self.stack_size; self.stack_size += size as u64; offset } fn store_stack(&mut self, reg: Reg, offset: u64, size: u16) { self.stack_relocs.push(StackReloc { offset: self.code.code.len() as u32 + 3, size, }); self.code.encode(instrs::st(reg, STACK_PTR, offset, size)); } fn load_stack(&mut self, reg: Reg, offset: u64, size: u16) { self.stack_relocs.push(StackReloc { offset: self.code.code.len() as u32 + 3, size, }); self.code.encode(instrs::ld(reg, STACK_PTR, offset, size)); } fn reloc_stack(&mut self) { for reloc in self.stack_relocs.drain(..) { let dest = &mut self.code.code[reloc.offset as usize..][..reloc.size as usize]; let value = u64::from_ne_bytes(dest.try_into().unwrap()); let offset = self.stack_size - value; dest.copy_from_slice(&offset.to_ne_bytes()); } } fn reloc_rets(&mut self) { let len = self.code.code.len() as i32; for reloc in self.ret_relocs.drain(..) { let dest = &mut self.code.code[reloc.offset as usize + reloc.instr_offset as usize..] [..reloc.size as usize]; debug_assert!(dest.iter().all(|&b| b == 0)); let offset = len - reloc.offset as i32; dest.copy_from_slice(&offset.to_ne_bytes()); } } fn ty(&mut self, expr: &parser::Expr<'a>) -> Type { match *expr { E::Ident { name: "int", .. } => bt::INT, E::Ident { name: "bool", .. } => bt::BOOL, E::Ident { name: "void", .. } => bt::VOID, E::Ident { name: "never", .. } => bt::NEVER, E::Ident { id, .. } => { let index = self .records .iter() .position(|r| r.id == id) .unwrap_or_else(|| { panic!("type not found: {:?}", id); }); TypeKind::Struct(index as Type).encode() } expr => unimplemented!("type: {:#?}", expr), } } fn expr(&mut self, expr: &'a parser::Expr<'a>, expeted: Option) -> Option { match *expr { E::Ctor { ty, fields } => { let ty = self.ty(&ty); let TypeKind::Struct(idx) = TypeKind::from_ty(ty) else { panic!("expected struct, got {:?}", ty); }; let size = self.size_of(ty); let stack = self.alloc_stack(size as u32); let mut field_values = fields .iter() .map(|(name, field)| self.expr(field, None).map(|v| (*name, v))) .collect::>>()?; let decl_fields = self.records[idx as usize].fields.clone(); let mut offset = 0; for (name, ty) in decl_fields.as_ref() { let index = field_values .iter() .position(|(n, _)| *n == name.as_ref()) .unwrap(); let (_, value) = field_values.remove(index); if value.ty != *ty { panic!("expected {:?}, got {:?}", ty, value.ty); } let reg = self.loc_to_reg(value.loc); self.store_stack(reg.0, stack + offset, 8); self.gpa.free(reg); offset += 8; } Some(Value { ty, loc: Loc::Stack(stack), }) } E::Field { target, field } => { let target = self.expr(target, None)?; let TypeKind::Struct(idx) = TypeKind::from_ty(target.ty) else { panic!("expected struct, got {:?}", target.ty); }; let decl_fields = self.records[idx as usize].fields.clone(); let index = decl_fields .iter() .position(|(name, _)| name.as_ref() == field) .unwrap(); let size = self.size_of(decl_fields[index].1); assert_eq!(size, 8, "TODO: implement other sizes"); let value = match target.loc { Loc::Reg(_) => todo!(), Loc::RegRef(_) => todo!(), Loc::Deref(r) => { self.code.encode(instrs::addi64(r.0, r.0, index as u64 * 8)); Loc::Deref(r) } Loc::Imm(_) => todo!(), Loc::Stack(stack) => Loc::Stack(stack + index as u64 * 8), Loc::StackRef(stack) => Loc::StackRef(stack + index as u64 * 8), }; Some(Value { ty: decl_fields[index].1, loc: value, }) } E::BinOp { left: E::Ident { id, .. }, op: T::Decl, right: E::Struct { fields, .. }, } => { let fields = fields .iter() .map(|&(name, ty)| (name.into(), self.ty(&ty))) .collect(); self.records.push(Struct { id: *id, fields }); Some(Value::VOID) } E::UnOp { op: T::Amp, val, .. } => { let val = self.expr(val, None)?; match val.loc { Loc::StackRef(off) => { let reg = self.gpa.allocate(); self.stack_relocs.push(StackReloc { offset: self.code.code.len() as u32 + 3, size: 8, }); self.code.encode(instrs::addi64(reg.0, STACK_PTR, off)); Some(Value { ty: self.alloc_pointer(val.ty), loc: Loc::Reg(reg), }) } l => panic!("cant take pointer of {:?}", l), } } E::UnOp { op: T::Star, val, .. } => { let val = self.expr(val, None)?; let reg = self.loc_to_reg(val.loc); match TypeKind::from_ty(val.ty) { TypeKind::Pointer(ty) => Some(Value { ty: self.pointers[ty as usize], loc: Loc::Deref(reg), }), _ => panic!("cant deref {:?}", val.ty), } } E::BinOp { left: E::Ident { name, id, .. }, op: T::Decl, right: E::Closure { ret, body, args, .. }, } => { log::dbg!("fn: {}", name); let frame = self.add_label(*id); if *name == "main" { self.main = Some(frame.label); } log::dbg!("fn-args"); for (i, arg) in args.iter().enumerate() { let offset = self.alloc_stack(8); let ty = self.ty(&arg.ty); self.vars.push(Variable { id: arg.id, value: Value { ty, loc: Loc::Stack(offset), }, }); self.store_stack(i as Reg + 2, offset, 8); } self.gpa.init_callee(); self.ret = self.ty(ret); log::dbg!("fn-body"); if self.expr(body, None).is_some() { panic!("expected all paths in the fucntion {name} to return"); } self.vars.clear(); log::dbg!("fn-relocs"); self.reloc_stack(); log::dbg!("fn-prelude"); self.write_fn_prelude(frame); log::dbg!("fn-ret"); self.reloc_rets(); self.ret(); self.stack_size = 0; self.vars.clear(); Some(Value::VOID) } E::BinOp { left: E::Ident { id, .. }, op: T::Decl, right, } => { let val = self.expr(right, None)?; let loc = self.make_loc_owned(val.loc, val.ty); let loc = self.ensure_spilled(loc); self.vars.push(Variable { id: *id, value: Value { ty: val.ty, loc }, }); Some(Value::VOID) } E::Call { func: E::Ident { id, .. }, args, } => { for (i, arg) in args.iter().enumerate() { let arg = self.expr(arg, None)?; let reg = self.loc_to_reg(arg.loc); self.code.encode(instrs::cp(i as Reg + 2, reg.0)); self.gpa.free(reg); } let func = self.get_or_reserve_label(*id); self.code.call(func); let reg = self.gpa.allocate(); self.code.encode(instrs::cp(reg.0, 1)); Some(Value { ty: self.ret, loc: Loc::Reg(reg), }) } E::Ident { name, id, .. } => { let var = self .vars .iter() .find(|v| v.id == id) .unwrap_or_else(|| panic!("variable not found: {:?}", name)); Some(Value { ty: var.value.ty, loc: var.value.loc.take_ref(), }) } E::Return { val, .. } => { if let Some(val) = val { let val = self.expr(val, Some(self.ret))?; if val.ty != self.ret { panic!("expected {:?}, got {:?}", self.ret, val.ty); } self.assign( Value { ty: self.ret, loc: Loc::RegRef(1), }, val, ); } self.ret_relocs.push(RetReloc { offset: self.code.code.len() as u32, instr_offset: 1, size: 4, }); self.code.encode(instrs::jmp(0)); None } E::Block { stmts, .. } => { for stmt in stmts { if let Loc::Reg(reg) = self.expr(stmt, None)?.loc { self.gpa.free(reg); } } Some(Value::VOID) } E::Number { value, .. } => Some(Value { ty: expeted.unwrap_or(bt::INT), loc: Loc::Imm(value), }), E::If { cond, then, else_, .. } => 'b: { log::dbg!("if-cond"); let cond = self.expr(cond, Some(bt::BOOL))?; let reg = self.loc_to_reg(cond.loc); let jump_offset = self.code.code.len() as u32; self.code.encode(instrs::jeq(reg.0, 0, 0)); self.gpa.free(reg); log::dbg!("if-then"); let then_unreachable = self.expr(then, None).is_none(); let mut else_unreachable = false; let mut jump = self.code.code.len() as i16 - jump_offset as i16; if let Some(else_) = else_ { log::dbg!("if-else"); let else_jump_offset = self.code.code.len() as u32; if !then_unreachable { self.code.encode(instrs::jmp(0)); jump = self.code.code.len() as i16 - jump_offset as i16; } else_unreachable = self.expr(else_, None).is_none(); if !then_unreachable { let jump = self.code.code.len() as i32 - else_jump_offset as i32; log::dbg!("if-else-jump: {}", jump); self.code.code[else_jump_offset as usize + 1..][..4] .copy_from_slice(&jump.to_ne_bytes()); } } log::dbg!("if-then-jump: {}", jump); self.code.code[jump_offset as usize + 3..][..2] .copy_from_slice(&jump.to_ne_bytes()); if then_unreachable && else_unreachable { break 'b None; } Some(Value::VOID) } E::Loop { body, .. } => 'a: { log::dbg!("loop"); let loop_start = self.code.code.len() as u32; self.loops.push(Loop { offset: loop_start, relocs: Default::default(), }); let body_unreachable = self.expr(body, None).is_none(); log::dbg!("loop-end"); if !body_unreachable { let loop_end = self.code.code.len(); self.code .encode(instrs::jmp(loop_start as i32 - loop_end as i32)); } let loop_end = self.code.code.len() as u32; let loop_ = self.loops.pop().unwrap(); let is_unreachable = loop_.relocs.is_empty(); for reloc in loop_.relocs { let dest = &mut self.code.code [reloc.offset as usize + reloc.instr_offset as usize..] [..reloc.size as usize]; let offset = loop_end as i32 - reloc.offset as i32; dest.copy_from_slice(&offset.to_ne_bytes()); } if is_unreachable { log::dbg!("infinite loop"); break 'a None; } Some(Value::VOID) } E::Break { .. } => { let loop_ = self.loops.last_mut().unwrap(); let offset = self.code.code.len() as u32; self.code.encode(instrs::jmp(0)); loop_.relocs.push(RetReloc { offset, instr_offset: 1, size: 4, }); None } E::Continue { .. } => { let loop_ = self.loops.last().unwrap(); let offset = self.code.code.len() as u32; self.code .encode(instrs::jmp(loop_.offset as i32 - offset as i32)); None } E::BinOp { left, op, right } => { let left = self.expr(left, expeted)?; let right = self.expr(right, Some(left.ty))?; if op == T::Assign { return self.assign(left, right); } let lhs = self.loc_to_reg(left.loc); let rhs = self.loc_to_reg(right.loc); let op = match op { T::Plus => instrs::add64, T::Minus => instrs::sub64, T::Star => instrs::mul64, T::Le => { self.code.encode(instrs::cmpu(lhs.0, lhs.0, rhs.0)); self.gpa.free(rhs); self.code.encode(instrs::cmpui(lhs.0, lhs.0, 1)); return Some(Value { ty: bt::BOOL, loc: Loc::Reg(lhs), }); } T::Eq => { self.code.encode(instrs::cmpu(lhs.0, lhs.0, rhs.0)); self.gpa.free(rhs); self.code.encode(instrs::cmpui(lhs.0, lhs.0, 0)); self.code.encode(instrs::not(lhs.0, lhs.0)); return Some(Value { ty: bt::BOOL, loc: Loc::Reg(lhs), }); } T::FSlash => |reg0, reg1, reg2| instrs::diru64(reg0, ZERO, reg1, reg2), _ => unimplemented!("{:#?}", op), }; self.code.encode(op(lhs.0, lhs.0, rhs.0)); self.gpa.free(rhs); Some(Value { ty: left.ty, loc: Loc::Reg(lhs), }) } ast => unimplemented!("{:#?}", ast), } } fn assign(&mut self, left: Value, right: Value) -> Option { let rhs = self.loc_to_reg(right.loc); match left.loc { Loc::Deref(reg) => { self.code.encode(instrs::st(rhs.0, reg.0, 0, 8)); self.gpa.free(reg); } Loc::RegRef(reg) => self.code.encode(instrs::cp(reg, rhs.0)), Loc::StackRef(offset) => self.store_stack(rhs.0, offset, 8), _ => unimplemented!(), } self.gpa.free(rhs); Some(Value::VOID) } fn get_or_reserve_label(&mut self, name: Ident) -> LabelId { if let Some(label) = self.labels.iter().position(|l| l.name == name) { label as u32 } else { self.labels.push(FnLabel { offset: 0, name }); self.labels.len() as u32 - 1 } } fn add_label(&mut self, name: Ident) -> Frame { let offset = self.code.code.len() as u32; let label = if let Some(label) = self.labels.iter().position(|l| l.name == name) { self.labels[label].offset = offset; label as u32 } else { self.labels.push(FnLabel { offset, name: name.into(), }); self.labels.len() as u32 - 1 }; Frame { label, prev_relocs: self.code.relocs.len(), offset, } } fn get_label(&self, name: Ident) -> LabelId { self.labels.iter().position(|l| l.name == name).unwrap() as _ } fn write_fn_prelude(&mut self, frame: Frame) { self.temp.push(RET_ADDR, 8); for ® in self.gpa.used.clone().iter() { self.temp.push(reg, 8); } self.temp.subi64(STACK_PTR, STACK_PTR, self.stack_size); for reloc in &mut self.code.relocs[frame.prev_relocs..] { reloc.offset += self.temp.code.len() as u32; } for reloc in &mut self.ret_relocs { reloc.offset += self.temp.code.len() as u32; } self.code.code.splice( frame.offset as usize..frame.offset as usize, self.temp.code.drain(..), ); } fn ret(&mut self) { self.code .encode(instrs::addi64(STACK_PTR, STACK_PTR, self.stack_size)); for reg in self.gpa.used.clone().iter().rev() { self.code.pop(*reg, 8); } self.code.ret(); } pub fn dump(mut self, out: &mut impl std::io::Write) -> std::io::Result<()> { self.temp.prelude(self.main.unwrap()); self.temp .relocate(&self.labels, self.temp.code.len() as i64); self.code.relocate(&self.labels, 0); out.write_all(&self.temp.code)?; out.write_all(&self.code.code) } fn alloc_pointer(&mut self, ty: Type) -> Type { let ty = self .pointers .iter() .position(|&p| p == ty) .unwrap_or_else(|| { self.pointers.push(ty); self.pointers.len() - 1 }); TypeKind::Pointer(ty as Type).encode() } fn make_loc_owned(&mut self, loc: Loc, ty: Type) -> Loc { match loc { Loc::RegRef(rreg) => { let reg = self.gpa.allocate(); self.code.encode(instrs::cp(reg.0, rreg)); Loc::Reg(reg) } Loc::Imm(imm) => { let reg = self.gpa.allocate(); self.code.encode(instrs::li64(reg.0, imm)); Loc::Reg(reg) } Loc::StackRef(mut off) => { let size = self.size_of(ty); assert!(size % 8 == 0, "TODO: implement other sizes"); let stack = self.alloc_stack(size as u32); let reg = self.gpa.allocate(); while size > 0 { self.load_stack(reg.0, off, 8); self.store_stack(reg.0, stack, 8); off += 8; } self.gpa.free(reg); Loc::Stack(stack) } l => l, } } fn ensure_spilled(&mut self, loc: Loc) -> Loc { match loc { Loc::Reg(reg) => { let stack = self.alloc_stack(8); self.store_stack(reg.0, stack, 8); self.gpa.free(reg); Loc::Stack(stack) } l => l, } } } pub struct Value { ty: Type, loc: Loc, } impl Value { const VOID: Self = Self { ty: bt::VOID, loc: Loc::Imm(0), }; } #[derive(Debug)] enum Loc { Reg(LinReg), RegRef(Reg), Deref(LinReg), Imm(u64), Stack(u64), StackRef(u64), } impl Loc { fn take_ref(&self) -> Loc { match self { Self::Reg(reg) => Self::RegRef(reg.0), Self::Stack(off) => Self::StackRef(*off), un => unreachable!("{:?}", un), } } } #[cfg(test)] mod tests { use crate::{instrs, log}; struct TestMem; impl hbvm::mem::Memory for TestMem { #[inline] unsafe fn load( &mut self, addr: hbvm::mem::Address, target: *mut u8, count: usize, ) -> Result<(), hbvm::mem::LoadError> { log::dbg!( "read: {:x} {} {:?}", addr.get(), count, core::slice::from_raw_parts(target, count) .iter() .rev() .skip_while(|&&b| b == 0) .map(|&b| format!("{:02x}", b)) .collect::() ); unsafe { core::ptr::copy(addr.get() as *const u8, target, count) } Ok(()) } #[inline] unsafe fn store( &mut self, addr: hbvm::mem::Address, source: *const u8, count: usize, ) -> Result<(), hbvm::mem::StoreError> { log::dbg!("write: {:x} {}", addr.get(), count); unsafe { core::ptr::copy(source, addr.get() as *mut u8, count) } Ok(()) } #[inline] unsafe fn prog_read(&mut self, addr: hbvm::mem::Address) -> T { log::dbg!( "read-typed: {:x} {} {:?}", addr.get(), std::any::type_name::(), if core::mem::size_of::() == 1 { instrs::NAMES[std::ptr::read(addr.get() as *const u8) as usize].to_string() } else { core::slice::from_raw_parts(addr.get() as *const u8, core::mem::size_of::()) .iter() .map(|&b| format!("{:02x}", b)) .collect::() } ); unsafe { core::ptr::read(addr.get() as *const T) } } } fn generate(input: &'static str, output: &mut String) { let path = std::path::Path::new("test"); let arena = crate::parser::Arena::default(); let mut parser = super::parser::Parser::new(input, path, &arena); let exprs = parser.file(); let mut codegen = super::Codegen::new(); codegen.file(path, &exprs).unwrap(); let mut out = Vec::new(); codegen.dump(&mut out).unwrap(); use std::fmt::Write; let mut stack = [0_u64; 128]; let mut vm = unsafe { hbvm::Vm::::new(TestMem, hbvm::mem::Address::new(out.as_ptr() as u64)) }; vm.write_reg( super::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(ev) => writeln!(output, "ev: {:?}", ev).unwrap(), Err(e) => break Err(e), } }; writeln!(output, "ret: {:?}", vm.read_reg(1).0).unwrap(); writeln!(output, "status: {:?}", stat).unwrap(); } crate::run_tests! { generate: example => include_str!("../examples/main_fn.hb"); arithmetic => include_str!("../examples/arithmetic.hb"); variables => include_str!("../examples/variables.hb"); functions => include_str!("../examples/functions.hb"); if_statements => include_str!("../examples/if_statement.hb"); loops => include_str!("../examples/loops.hb"); fb_driver => include_str!("../examples/fb_driver.hb"); pointers => include_str!("../examples/pointers.hb"); structs => include_str!("../examples/structs.hb"); } }