holey-bytes/hblang/src/codegen.rs

2729 lines
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pub use self::reg::{RET_ADDR, STACK_PTR, ZERO};
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use {
crate::{
ident::{self, Ident},
instrs::{self, *},
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lexer::TokenKind,
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log,
parser::{
self, find_symbol, idfl, CommentOr, CtorField, Expr, ExprRef, FileId, Pos, StructField,
},
ty, Field, Func, Global, LoggedMem, OffsetIter, ParamAlloc, Reloc, Sig, Struct, SymKey,
TypedReloc, Types,
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},
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core::panic,
std::fmt::Display,
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};
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type Offset = u32;
type Size = u32;
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type ArrayLen = u32;
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fn load_value(ptr: *const u8, size: u32) -> u64 {
let mut dst = [0u8; 8];
dst[..size as usize].copy_from_slice(unsafe { std::slice::from_raw_parts(ptr, size as usize) });
u64::from_ne_bytes(dst)
}
fn ensure_loaded(value: CtValue, derefed: bool, size: u32) -> u64 {
if derefed {
load_value(value.0 as *const u8, size)
} else {
value.0
}
}
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mod stack {
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use {
super::{Offset, Size},
std::num::NonZeroU32,
};
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impl crate::Reloc {
pub fn pack_srel(id: &Id, off: u32) -> u64 {
((id.repr() as u64) << 32) | (off as u64)
}
pub fn apply_stack_offset(&self, code: &mut [u8], stack: &Alloc) {
let bytes =
&code[self.offset as usize + self.sub_offset as usize..][..self.width as usize];
let (id, off) = Self::unpack_srel(u64::from_ne_bytes(bytes.try_into().unwrap()));
self.write_offset(code, stack.final_offset(id, off) as i64);
}
pub fn unpack_srel(id: u64) -> (u32, u32) {
((id >> 32) as u32, id as u32)
}
}
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#[derive(Debug, PartialEq, Eq)]
pub struct Id(NonZeroU32);
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impl Id {
fn index(&self) -> usize {
(self.0.get() as usize - 1) & !(1 << 31)
}
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pub fn repr(&self) -> u32 {
self.0.get()
}
pub fn as_ref(&self) -> Self {
Self(unsafe { NonZeroU32::new_unchecked(self.0.get() | 1 << 31) })
}
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pub fn is_ref(&self) -> bool {
self.0.get() & (1 << 31) != 0
}
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}
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impl Drop for Id {
fn drop(&mut self) {
if !std::thread::panicking() && !self.is_ref() {
unreachable!("stack id leaked: {:?}", self.0);
}
}
}
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#[derive(PartialEq)]
struct Meta {
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size: Size,
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offset: Offset,
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rc: u32,
}
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#[derive(Default)]
pub struct Alloc {
height: Size,
pub max_height: Size,
meta: Vec<Meta>,
}
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impl Alloc {
pub fn allocate(&mut self, size: Size) -> Id {
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self.meta.push(Meta { size, offset: 0, rc: 1 });
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self.height += size;
self.max_height = self.max_height.max(self.height);
Id(unsafe { NonZeroU32::new_unchecked(self.meta.len() as u32) })
}
pub fn free(&mut self, id: Id) {
std::mem::forget(id);
//if id.is_ref() {}
//let meta = &mut self.meta[id.index()];
//meta.rc -= 1;
//if meta.rc != 0 {
// return;
//}
//meta.offset = self.height;
//self.height -= meta.size;
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}
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pub fn dup_id(&mut self, id: &Id) -> Id {
if id.is_ref() {
return id.as_ref();
}
self.meta[id.index()].rc += 1;
Id(id.0)
}
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pub fn finalize_leaked(&mut self) {
for meta in self.meta.iter_mut().filter(|m| m.rc > 0) {
meta.offset = self.height;
self.height -= meta.size;
}
}
pub fn clear(&mut self) {
self.height = 0;
self.max_height = 0;
self.meta.clear();
}
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pub fn final_offset(&self, id: u32, extra_offset: Offset) -> Offset {
debug_assert_ne!(id, 0);
(self.max_height - self.meta[(id as usize - 1) & !(1 << 31)].offset) + extra_offset
}
}
}
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mod reg {
pub const STACK_PTR: Reg = 254;
pub const ZERO: Reg = 0;
pub const RET: Reg = 1;
pub const RET_ADDR: Reg = 31;
type Reg = u8;
#[cfg(debug_assertions)]
type Bt = std::backtrace::Backtrace;
#[cfg(not(debug_assertions))]
type Bt = ();
#[derive(Default, Debug)]
pub struct Id(Reg, Option<Bt>);
impl PartialEq for Id {
fn eq(&self, other: &Self) -> bool {
self.0 == other.0
}
}
impl Eq for Id {}
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impl Id {
pub const RET: Self = Id(RET, None);
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pub fn get(&self) -> Reg {
self.0
}
pub fn as_ref(&self) -> Self {
Self(self.0, None)
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}
pub fn is_ref(&self) -> bool {
self.1.is_none()
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}
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}
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impl From<u8> for Id {
fn from(value: u8) -> Self {
Self(value, None)
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}
}
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#[cfg(debug_assertions)]
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impl Drop for Id {
fn drop(&mut self) {
if !std::thread::panicking()
&& let Some(bt) = self.1.take()
{
unreachable!("reg id leaked: {:?} {bt}", self.0);
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}
}
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}
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#[derive(Default, PartialEq, Eq)]
pub struct Alloc {
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free: Vec<Reg>,
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max_used: Reg,
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}
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impl Alloc {
pub fn init(&mut self) {
self.free.clear();
self.free.extend((32..=253).rev());
self.max_used = RET_ADDR;
}
pub fn allocate(&mut self) -> Id {
let reg = self.free.pop().expect("TODO: we need to spill");
self.max_used = self.max_used.max(reg);
Id(
reg,
#[cfg(debug_assertions)]
Some(std::backtrace::Backtrace::capture()),
#[cfg(not(debug_assertions))]
Some(()),
)
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}
pub fn free(&mut self, reg: Id) {
if reg.1.is_some() {
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self.free.push(reg.0);
std::mem::forget(reg);
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}
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}
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pub fn pushed_size(&self) -> usize {
((self.max_used as usize).saturating_sub(RET_ADDR as usize) + 1) * 8
}
}
}
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struct Value {
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ty: ty::Id,
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loc: Loc,
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}
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impl Value {
fn new(ty: impl Into<ty::Id>, loc: impl Into<Loc>) -> Self {
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Self { ty: ty.into(), loc: loc.into() }
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}
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fn void() -> Self {
Self { ty: ty::VOID.into(), loc: Loc::ct(0) }
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}
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fn imm(value: u64) -> Self {
Self { ty: ty::UINT.into(), loc: Loc::ct(value) }
}
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fn ty(ty: ty::Id) -> Self {
Self { ty: ty::TYPE.into(), loc: Loc::ct(ty.repr() as u64) }
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}
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}
enum LocCow<'a> {
Ref(&'a Loc),
Owned(Loc),
}
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impl<'a> LocCow<'a> {
fn as_ref(&self) -> &Loc {
match self {
Self::Ref(value) => value,
Self::Owned(value) => value,
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}
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}
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}
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impl<'a> From<&'a Loc> for LocCow<'a> {
fn from(value: &'a Loc) -> Self {
Self::Ref(value)
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}
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}
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impl<'a> From<Loc> for LocCow<'a> {
fn from(value: Loc) -> Self {
Self::Owned(value)
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}
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}
#[repr(packed)]
#[derive(Debug, PartialEq, Eq, Clone, Copy)]
struct CtValue(u64);
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#[derive(Debug, PartialEq, Eq)]
enum Loc {
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Rt { derefed: bool, reg: reg::Id, stack: Option<stack::Id>, offset: Offset },
Ct { derefed: bool, value: CtValue },
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}
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impl Loc {
fn stack(stack: stack::Id) -> Self {
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Self::Rt { stack: Some(stack), reg: reg::STACK_PTR.into(), derefed: true, offset: 0 }
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}
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fn reg(reg: impl Into<reg::Id>) -> Self {
let reg = reg.into();
assert!(reg.get() != 0);
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Self::Rt { derefed: false, reg, stack: None, offset: 0 }
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}
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fn ct(value: u64) -> Self {
Self::Ct { value: CtValue(value), derefed: false }
}
fn ct_ptr(value: u64) -> Self {
Self::Ct { value: CtValue(value), derefed: true }
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}
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fn ty(ty: ty::Id) -> Self {
Self::ct(ty.repr() as _)
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}
fn offset(mut self, offset: u32) -> Self {
match &mut self {
Self::Rt { offset: off, .. } => *off += offset,
Self::Ct { derefed: false, value } => value.0 += offset as u64,
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_ => unreachable!("offseting constant"),
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}
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self
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}
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fn as_ref(&self) -> Self {
match *self {
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Loc::Rt { derefed, ref reg, ref stack, offset } => Loc::Rt {
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derefed,
reg: reg.as_ref(),
stack: stack.as_ref().map(stack::Id::as_ref),
offset,
},
Loc::Ct { value, derefed } => Self::Ct { derefed, value },
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}
}
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fn into_derefed(mut self) -> Self {
match &mut self {
Self::Rt { derefed, .. } => *derefed = true,
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val => unreachable!("{val:?}"),
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}
self
}
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fn assert_valid(&self) {
assert!(!matches!(self, Self::Rt { reg, .. } if reg.get() == 0));
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}
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fn take_owned(&mut self) -> Option<Self> {
if self.is_ref() {
return None;
}
Some(std::mem::replace(self, self.as_ref()))
}
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fn is_ref(&self) -> bool {
matches!(self, Self::Rt { reg, stack, .. } if reg.is_ref() && stack.as_ref().map_or(true, stack::Id::is_ref))
}
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fn to_ty(&self) -> Option<ty::Id> {
match *self {
Self::Ct { derefed: false, value } => Some(ty::Id::from(value.0)),
Self::Ct { derefed: true, value } => {
Some(unsafe { std::ptr::read(value.0 as *const u8 as _) })
}
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Self::Rt { .. } => None,
}
}
fn is_stack(&self) -> bool {
matches!(self, Self::Rt { derefed: true, reg, stack: Some(_), offset: 0 } if reg.get() == STACK_PTR)
}
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fn is_reg(&self) -> bool {
matches!(self, Self::Rt { derefed: false, reg: _, stack: None, offset: 0 })
}
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}
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impl From<reg::Id> for Loc {
fn from(reg: reg::Id) -> Self {
Loc::reg(reg)
}
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}
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impl Default for Loc {
fn default() -> Self {
Self::ct(0)
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}
}
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#[derive(Clone, Copy)]
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struct Loop {
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var_count: u32,
offset: u32,
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reloc_base: u32,
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}
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struct Variable {
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id: Ident,
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value: Value,
}
struct ItemCtxSnap {
stack_relocs: usize,
ret_relocs: usize,
loop_relocs: usize,
code: usize,
relocs: usize,
}
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#[derive(Default)]
struct ItemCtx {
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file: FileId,
id: ty::Kind,
ret: Option<ty::Id>,
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ret_reg: reg::Id,
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inline_ret_loc: Loc,
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task_base: usize,
stack: stack::Alloc,
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regs: reg::Alloc,
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loops: Vec<Loop>,
vars: Vec<Variable>,
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stack_relocs: Vec<Reloc>,
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ret_relocs: Vec<Reloc>,
loop_relocs: Vec<Reloc>,
code: Vec<u8>,
relocs: Vec<TypedReloc>,
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}
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impl ItemCtx {
fn write_trap(&mut self, kind: trap::Trap) {
self.emit(eca());
self.code.push(255);
self.code.extend(kind.as_slice());
}
fn snap(&self) -> ItemCtxSnap {
ItemCtxSnap {
stack_relocs: self.stack_relocs.len(),
ret_relocs: self.ret_relocs.len(),
loop_relocs: self.loop_relocs.len(),
code: self.code.len(),
relocs: self.relocs.len(),
}
}
fn revert(&mut self, snap: ItemCtxSnap) {
self.stack_relocs.truncate(snap.stack_relocs);
self.ret_relocs.truncate(snap.ret_relocs);
self.loop_relocs.truncate(snap.loop_relocs);
self.code.truncate(snap.code);
self.relocs.truncate(snap.relocs);
}
fn emit_addi(&mut self, dest: u8, op: u8, delta: u64) {
if delta == 0 {
if dest != op {
self.emit(cp(dest, op));
}
return;
}
self.emit(addi64(dest, op, delta));
}
fn emit(&mut self, (len, instr): (usize, [u8; instrs::MAX_SIZE])) {
self.code.extend_from_slice(&instr[..len]);
}
fn emit_prelude(&mut self) {
self.emit(instrs::addi64(STACK_PTR, STACK_PTR, 0));
self.emit(instrs::st(RET_ADDR, STACK_PTR, 0, 0));
}
fn emit_entry_prelude(&mut self) {
self.emit(jal(RET_ADDR, reg::ZERO, 0));
self.emit(tx());
}
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pub fn dup_loc(&mut self, loc: &Loc) -> Loc {
match *loc {
Loc::Rt { derefed, ref reg, ref stack, offset } => Loc::Rt {
reg: reg.as_ref(),
derefed,
stack: stack.as_ref().map(|s| self.stack.dup_id(s)),
offset,
},
ref loc => loc.as_ref(),
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}
}
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fn finalize(&mut self) {
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if let Some(last_ret) = self.ret_relocs.last()
&& last_ret.offset as usize == self.code.len() - 5
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{
self.code.truncate(self.code.len() - 5);
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self.ret_relocs.pop();
}
let len = self.code.len() as Offset;
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self.stack.finalize_leaked();
for rel in self.stack_relocs.drain(..) {
rel.apply_stack_offset(&mut self.code, &self.stack)
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}
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for rel in self.ret_relocs.drain(..) {
let off = rel.apply_jump(&mut self.code, len, 0);
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debug_assert!(off > 0);
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}
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let pushed = self.regs.pushed_size() as i64;
let stack = self.stack.max_height as i64;
write_reloc(&mut self.code, 3, -(pushed + stack), 8);
write_reloc(&mut self.code, 3 + 8 + 3, stack, 8);
write_reloc(&mut self.code, 3 + 8 + 3 + 8, pushed, 2);
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self.emit(instrs::ld(reg::RET_ADDR, reg::STACK_PTR, stack as _, pushed as _));
self.emit(instrs::addi64(reg::STACK_PTR, reg::STACK_PTR, (pushed + stack) as _));
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self.stack.clear();
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debug_assert!(self.loops.is_empty());
debug_assert!(self.loop_relocs.is_empty());
debug_assert!(self.vars.is_empty());
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}
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fn free_loc(&mut self, src: impl Into<LocCow>) {
if let LocCow::Owned(Loc::Rt { reg, stack, .. }) = src.into() {
self.regs.free(reg);
if let Some(stack) = stack {
self.stack.free(stack);
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}
}
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}
}
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fn write_reloc(doce: &mut [u8], offset: usize, value: i64, size: u16) {
let value = value.to_ne_bytes();
doce[offset..offset + size as usize].copy_from_slice(&value[..size as usize]);
}
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mod task {
use super::Offset;
pub fn unpack(offset: Offset) -> Result<Offset, usize> {
if offset >> 31 != 0 {
Err((offset & !(1 << 31)) as usize)
} else {
Ok(offset)
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}
}
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pub fn id(index: usize) -> Offset {
1 << 31 | index as u32
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}
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}
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#[derive(Debug)]
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struct FTask {
file: FileId,
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id: ty::Func,
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}
#[derive(Default, Debug)]
struct Ctx {
loc: Option<Loc>,
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ty: Option<ty::Id>,
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}
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impl Ctx {
pub fn with_loc(self, loc: Loc) -> Self {
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Self { loc: Some(loc), ..self }
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}
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pub fn with_ty(self, ty: impl Into<ty::Id>) -> Self {
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Self { ty: Some(ty.into()), ..self }
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}
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fn into_value(self) -> Option<Value> {
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Some(Value { ty: self.ty.unwrap(), loc: self.loc? })
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}
}
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impl From<Value> for Ctx {
fn from(value: Value) -> Self {
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Self { loc: Some(value.loc), ty: Some(value.ty) }
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}
}
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#[derive(Default)]
struct Pool {
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cis: Vec<ItemCtx>,
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arg_locs: Vec<Loc>,
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}
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const VM_STACK_SIZE: usize = 1024 * 1024 * 2;
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struct Comptime {
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vm: hbvm::Vm<LoggedMem, { 1024 * 10 }>,
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_stack: Box<[u8; VM_STACK_SIZE]>,
code: Vec<u8>,
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}
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impl Default for Comptime {
fn default() -> Self {
let mut stack = Box::<[u8; VM_STACK_SIZE]>::new_uninit();
let mut vm = hbvm::Vm::default();
let ptr = unsafe { stack.as_mut_ptr().cast::<u8>().add(VM_STACK_SIZE) as u64 };
vm.write_reg(STACK_PTR, ptr);
Self { vm, _stack: unsafe { stack.assume_init() }, code: Default::default() }
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}
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}
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mod trap {
use {
super::ty,
crate::parser::{ExprRef, FileId},
};
macro_rules! gen_trap {
(
#[derive(Trap)]
$vis:vis enum $name:ident {
$($variant:ident {
$($fname:ident: $fty:ty,)*
},)*
}
) => {
#[repr(u8)]
$vis enum $name {
$($variant($variant),)*
}
impl $name {
$vis fn size(&self) -> usize {
1 + match self {
$(Self::$variant(_) => std::mem::size_of::<$variant>(),)*
}
}
}
$(
#[repr(packed)]
$vis struct $variant {
$($vis $fname: $fty,)*
}
)*
};
}
gen_trap! {
#[derive(Trap)]
pub enum Trap {
MakeStruct {
file: FileId,
struct_expr: ExprRef,
},
MomizedCall {
func: ty::Func,
},
}
}
impl Trap {
pub fn as_slice(&self) -> &[u8] {
unsafe { std::slice::from_raw_parts(self as *const _ as _, self.size()) }
}
}
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}
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#[derive(Default)]
pub struct Codegen {
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pub files: Vec<parser::Ast>,
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tasks: Vec<Option<FTask>>,
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tys: Types,
ci: ItemCtx,
pool: Pool,
ct: Comptime,
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}
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impl Codegen {
pub fn generate(&mut self) {
self.ci.emit_entry_prelude();
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self.find_or_declare(0, 0, Err("main"), "");
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self.make_func_reachable(0);
self.complete_call_graph();
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}
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fn expr(&mut self, expr: &Expr) -> Option<Value> {
self.expr_ctx(expr, Ctx::default())
}
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fn build_struct(
&mut self,
explicit_alignment: Option<u32>,
fields: &[CommentOr<StructField>],
) -> ty::Struct {
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let fields = fields
.iter()
.filter_map(CommentOr::or)
.map(|sf| Field { name: sf.name.into(), ty: self.ty(&sf.ty) })
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.collect();
self.tys.structs.push(Struct { name: 0, file: 0, fields, explicit_alignment });
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self.tys.structs.len() as u32 - 1
}
fn expr_ctx(&mut self, expr: &Expr, mut ctx: Ctx) -> Option<Value> {
use {Expr as E, TokenKind as T};
let value = match *expr {
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E::Mod { id, .. } => Some(Value::ty(ty::Kind::Module(id).compress())),
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E::Struct { fields, captured, packed, .. } => {
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if captured.is_empty() {
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Some(Value::ty(
ty::Kind::Struct(self.build_struct(packed.then_some(1), fields)).compress(),
))
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} else {
let values = captured
.iter()
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.map(|&id| E::Ident {
pos: 0,
is_ct: false,
id,
name: "booodab",
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is_first: false,
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})
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.map(|expr| self.expr(&expr))
.collect::<Option<Vec<_>>>()?;
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let values_size =
values.iter().map(|value| 4 + self.tys.size_of(value.ty)).sum::<Size>();
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let stack = self.ci.stack.allocate(values_size);
let mut ptr = Loc::stack(stack.as_ref());
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for value in values {
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self.store_sized(Loc::ty(value.ty), &ptr, 4);
ptr = ptr.offset(4);
let size = self.tys.size_of(value.ty);
self.store_sized(value.loc, &ptr, size);
ptr = ptr.offset(size);
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}
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self.stack_offset(2, STACK_PTR, Some(&stack), 0);
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let val = self.eca(
trap::Trap::MakeStruct(trap::MakeStruct {
file: self.ci.file,
struct_expr: ExprRef::new(expr),
}),
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ty::TYPE,
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);
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self.ci.free_loc(Loc::stack(stack));
Some(val)
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}
}
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E::Slice { size, item, .. } => {
let ty = self.ty(item);
let len = size.map_or(ArrayLen::MAX, |expr| self.eval_const(expr, ty::U32) as _);
Some(Value::ty(self.tys.make_array(ty, len)))
}
E::Index { base, index } => {
// TODO: we need to check if index is in bounds on debug builds
let mut base_val = self.expr(base)?;
if base_val.ty.is_pointer() {
base_val.loc = self.make_loc_owned(base_val.loc, base_val.ty);
}
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let index_val = self.expr(index)?;
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_ = self.assert_ty(index.pos(), index_val.ty, ty::INT.into(), "subsctipt");
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if let ty::Kind::Ptr(ty) = base_val.ty.expand() {
base_val.ty = self.tys.ptrs[ty as usize].base;
base_val.loc = base_val.loc.into_derefed();
}
match base_val.ty.expand() {
ty::Kind::Slice(arr) => {
let ty = self.tys.arrays[arr as usize].ty;
let item_size = self.tys.size_of(ty);
let Loc::Rt { derefed: true, ref mut reg, ref stack, offset } =
base_val.loc
else {
unreachable!()
};
if reg.is_ref() {
let new_reg = self.ci.regs.allocate();
self.stack_offset(new_reg.get(), reg.get(), stack.as_ref(), offset);
*reg = new_reg;
} else {
self.stack_offset(reg.get(), reg.get(), stack.as_ref(), offset);
}
let idx = self.loc_to_reg(index_val.loc, 8);
if item_size != 1 {
self.ci.emit(muli64(idx.get(), idx.get(), item_size as _));
}
self.ci.emit(add64(reg.get(), reg.get(), idx.get()));
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self.ci.regs.free(idx);
Some(Value::new(ty, base_val.loc))
}
_ => self.report(
base.pos(),
format_args!(
"compiler did not (yet) learn how to index into '{}'",
self.ty_display(base_val.ty)
),
),
}
}
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E::Directive { name: "inline", args: [func_ast, args @ ..], .. } => {
let ty::Kind::Func(mut func) = self.ty(func_ast).expand() else {
self.report(func_ast.pos(), "first argument of inline needs to be a function");
};
let fuc = &self.tys.funcs[func as usize];
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let fast = self.files[fuc.file as usize].clone();
let E::BinOp { right: &E::Closure { args: cargs, body, .. }, .. } =
fuc.expr.get(&fast).unwrap()
else {
unreachable!();
};
let scope = self.ci.vars.len();
let sig = self.compute_signature(&mut func, func_ast.pos(), args)?;
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self.assert_arg_count(expr.pos(), args.len(), cargs.len(), "inline function call");
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if scope == self.ci.vars.len() {
for ((arg, ty), carg) in
args.iter().zip(sig.args.view(&self.tys.args).to_owned()).zip(cargs)
{
let loc = self.expr_ctx(arg, Ctx::default().with_ty(ty))?.loc;
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self.ci.vars.push(Variable { id: carg.id, value: Value { ty, loc } });
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}
}
let ret_reloc_base = self.ci.ret_relocs.len();
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let loc = self.alloc_ret(sig.ret, ctx, true);
let prev_ret_reg = std::mem::replace(&mut self.ci.inline_ret_loc, loc);
let fuc = &self.tys.funcs[func as usize];
let prev_file = std::mem::replace(&mut self.ci.file, fuc.file);
let prev_ret = std::mem::replace(&mut self.ci.ret, Some(sig.ret));
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self.expr(body);
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let loc = std::mem::replace(&mut self.ci.inline_ret_loc, prev_ret_reg);
self.ci.file = prev_file;
self.ci.ret = prev_ret;
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for var in self.ci.vars.drain(scope..).collect::<Vec<_>>() {
self.ci.free_loc(var.value.loc);
}
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if let Some(last_ret) = self.ci.ret_relocs.last()
&& last_ret.offset as usize == self.ci.code.len() - 5
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{
self.ci.code.truncate(self.ci.code.len() - 5);
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self.ci.ret_relocs.pop();
}
let len = self.ci.code.len() as u32;
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for rel in self.ci.ret_relocs.drain(ret_reloc_base..) {
rel.apply_jump(&mut self.ci.code, len, 0);
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}
return Some(Value { ty: sig.ret, loc });
}
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E::Directive { name: "TypeOf", args: [expr], .. } => {
Some(Value::ty(self.infer_type(expr)))
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}
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E::Directive { name: "eca", args, pos } => {
let Some(ty) = ctx.ty else {
self.report(
pos,
"type to return form eca is unknown, use `@as(<type>, @eca(...<expr>))`",
);
};
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let mut parama = self.tys.parama(ty);
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let base = self.pool.arg_locs.len();
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for arg in args {
let arg = self.expr(arg)?;
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if arg.ty == ty::Id::from(ty::TYPE) {
self.report(pos, "na na na nana, no passing types to ecas");
}
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self.pass_arg(&arg, &mut parama);
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self.pool.arg_locs.push(arg.loc);
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}
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for value in self.pool.arg_locs.drain(base..) {
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self.ci.free_loc(value);
}
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let loc = self.alloc_ret(ty, ctx, false);
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self.ci.emit(eca());
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self.load_ret(ty, &loc);
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return Some(Value { ty, loc });
}
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E::Directive { name: "sizeof", args: [ty], .. } => {
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let ty = self.ty(ty);
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return Some(Value::imm(self.tys.size_of(ty) as _));
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}
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E::Directive { name: "alignof", args: [ty], .. } => {
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let ty = self.ty(ty);
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return Some(Value::imm(self.tys.align_of(ty) as _));
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}
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E::Directive { name: "intcast", args: [val], .. } => {
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let Some(ty) = ctx.ty else {
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self.report(
expr.pos(),
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"type to cast to is unknown, use `@as(<type>, @intcast(<expr>))`",
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);
};
let mut val = self.expr(val)?;
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let from_size = self.tys.size_of(val.ty);
let to_size = self.tys.size_of(ty);
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if from_size < to_size && val.ty.is_signed() {
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let reg = self.loc_to_reg(val.loc, from_size);
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let op = [sxt8, sxt16, sxt32][from_size.ilog2() as usize];
self.ci.emit(op(reg.get(), reg.get()));
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val.loc = Loc::reg(reg);
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}
Some(Value { ty, loc: val.loc })
}
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E::Directive { name: "bitcast", args: [val], .. } => {
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let Some(ty) = ctx.ty else {
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self.report(
expr.pos(),
"type to cast to is unknown, use `@as(<type>, @bitcast(<expr>))`",
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);
};
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let size = self.tys.size_of(ty);
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ctx.ty = None;
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let val = self.expr_ctx(val, ctx)?;
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if self.tys.size_of(val.ty) != size {
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self.report(
expr.pos(),
format_args!(
"cannot bitcast {} to {} (different sizes: {} != {size})",
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self.ty_display(val.ty),
self.ty_display(ty),
self.tys.size_of(val.ty),
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),
);
}
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debug_assert_eq!(
self.tys.align_of(val.ty),
self.tys.align_of(ty),
"TODO: might need stack relocation"
);
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return Some(Value { ty, loc: val.loc });
}
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E::Directive { name: "as", args: [ty, val], .. } => {
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let ty = self.ty(ty);
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ctx.ty = Some(ty);
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return self.expr_ctx(val, ctx);
}
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E::Bool { value, .. } => {
Some(Value { ty: ty::BOOL.into(), loc: Loc::ct(value as u64) })
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}
E::Idk { pos } => {
let Some(ty) = ctx.ty else {
self.report(
pos,
"`idk` can be used only when type can be inferred, use @as(<type>, idk)",
);
};
if ctx.loc.is_some() {
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// self.report(
// pos,
// format_args!(
// "`idk` would be written to an existing memory location \
// which at ths point does notthing so its prohibited. TODO: make debug \
// builds write 0xAA instead. Info for weak people: {:?}",
// ctx.loc
// ),
// );
}
let loc = match self.tys.size_of(ty) {
0 => Loc::default(),
1..=8 => Loc::reg(self.ci.regs.allocate()),
size => Loc::stack(self.ci.stack.allocate(size)),
};
Some(Value { ty, loc })
}
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E::String { pos, mut literal } => {
literal = literal.trim_matches('"');
if !literal.ends_with("\\0") {
self.report(pos, "string literal must end with null byte (for now)");
}
let report = |bytes: &std::str::Bytes, message| {
self.report(pos + (literal.len() - bytes.len()) as u32 - 1, message)
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};
let mut str = Vec::<u8>::with_capacity(literal.len());
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let decode_braces = |str: &mut Vec<u8>, bytes: &mut std::str::Bytes| {
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while let Some(b) = bytes.next()
&& b != b'}'
{
let c = bytes
.next()
.unwrap_or_else(|| report(bytes, "incomplete escape sequence"));
let decode = |b: u8| match b {
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b'0'..=b'9' => b - b'0',
b'a'..=b'f' => b - b'a' + 10,
b'A'..=b'F' => b - b'A' + 10,
_ => report(bytes, "expected hex digit or '}'"),
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};
str.push(decode(b) << 4 | decode(c));
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}
};
let mut bytes = literal.bytes();
while let Some(b) = bytes.next() {
if b != b'\\' {
str.push(b);
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continue;
}
let b = match bytes
.next()
.unwrap_or_else(|| report(&bytes, "incomplete escape sequence"))
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{
b'n' => b'\n',
b'r' => b'\r',
b't' => b'\t',
b'\\' => b'\\',
b'\'' => b'\'',
b'"' => b'"',
b'0' => b'\0',
b'{' => {
decode_braces(&mut str, &mut bytes);
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continue;
}
_ => report(&bytes, "unknown escape sequence, expected [nrt\\\"'{0]"),
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};
str.push(b);
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}
let reloc = Reloc::new(self.ci.code.len() as _, 3, 4);
let glob = self.tys.globals.len() as ty::Global;
self.tys.globals.push(Global { data: str, ..Default::default() });
self.ci
.relocs
.push(TypedReloc { target: ty::Kind::Global(glob).compress(), reloc });
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let reg = self.ci.regs.allocate();
self.ci.emit(instrs::lra(reg.get(), 0, 0));
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Some(Value::new(self.tys.make_ptr(ty::U8.into()), reg))
}
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E::Ctor { pos, ty, fields, .. } => {
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let (ty, loc) = self.prepare_struct_ctor(pos, &mut ctx, ty, fields.len());
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let ty::Kind::Struct(stru) = ty.expand() else {
self.report(
pos,
"our current technology does not (yet) allow\
us to construct '{}' with struct constructor",
);
};
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for &CtorField { pos, name, ref value, .. } in fields {
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let Some((offset, ty)) = self.tys.offset_of(stru, name) else {
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self.report(pos, format_args!("field not found: {name:?}"));
};
let loc = loc.as_ref().offset(offset);
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let value = self.expr_ctx(value, Ctx::default().with_loc(loc).with_ty(ty))?;
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self.ci.free_loc(value.loc);
}
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if let Some(dst_loc) = ctx.loc {
self.store_typed(loc, &dst_loc, ty);
return Some(Value { ty, loc: dst_loc });
} else {
return Some(Value { ty, loc });
}
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}
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E::Tupl { pos, ty, fields, .. } => {
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let (ty, loc) = self.prepare_struct_ctor(pos, &mut ctx, ty, fields.len());
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match ty.expand() {
ty::Kind::Struct(stru) => {
let mut oiter = OffsetIter::new(stru);
for field in fields {
let (ty, offset) = oiter.next_ty(&self.tys).unwrap();
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let loc = loc.as_ref().offset(offset);
let ctx = Ctx::default().with_loc(loc).with_ty(ty);
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let value = self.expr_ctx(field, ctx)?;
self.ci.free_loc(value.loc);
}
}
ty::Kind::Slice(arr) => {
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let arr = self.tys.arrays[arr as usize];
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let item_size = self.tys.size_of(arr.ty);
for (i, value) in fields.iter().enumerate() {
let loc = loc.as_ref().offset(i as u32 * item_size);
let value =
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self.expr_ctx(value, Ctx::default().with_loc(loc).with_ty(arr.ty))?;
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self.ci.free_loc(value.loc);
}
}
_ => self.report(
pos,
format_args!(
"compiler does not (yet) know how to initialize\
'{}' with tuple constructor",
self.ty_display(ty)
),
),
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}
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if let Some(dst_loc) = ctx.loc {
self.store_typed(loc, &dst_loc, ty);
return Some(Value { ty, loc: dst_loc });
} else {
return Some(Value { ty, loc });
}
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}
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E::Field { target, name: field } => {
let checkpoint = self.ci.snap();
let mut tal = self.expr(target)?;
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if let ty::Kind::Ptr(ty) = tal.ty.expand() {
tal.ty = self.tys.ptrs[ty as usize].base;
tal.loc = tal.loc.into_derefed();
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}
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match tal.ty.expand() {
ty::Kind::Struct(idx) => {
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let Some((offset, ty)) = self.tys.offset_of(idx, field) else {
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self.report(target.pos(), format_args!("field not found: {field:?}"));
};
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Some(Value { ty, loc: tal.loc.offset(offset) })
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}
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ty::Kind::Builtin(ty::TYPE) => {
self.ci.free_loc(tal.loc);
self.ci.revert(checkpoint);
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match ty::Kind::from_ty(self.ty(target)) {
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ty::Kind::Module(idx) => {
match self.find_or_declare(target.pos(), idx, Err(field), "") {
ty::Kind::Global(idx) => self.handle_global(idx),
e => Some(Value::ty(e.compress())),
}
}
ty::Kind::Global(idx) => self.handle_global(idx),
e => unimplemented!("{e:?}"),
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}
}
smh => self.report(
target.pos(),
format_args!("the field operation is not supported: {smh:?}"),
),
}
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}
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E::UnOp { op: T::Sub, val, pos } => {
let value = self.expr(val)?;
if !value.ty.is_integer() {
self.report(pos, format_args!("cant negate '{}'", self.ty_display(value.ty)));
}
let size = self.tys.size_of(value.ty);
let (oper, dst, drop_loc) = if let Some(dst) = &ctx.loc
&& dst.is_reg()
&& let Some(dst) = ctx.loc.take()
{
(
self.loc_to_reg(&value.loc, size),
if dst.is_ref() {
self.loc_to_reg(&dst, size)
} else {
self.loc_to_reg(dst, size)
},
value.loc,
)
} else {
let oper = self.loc_to_reg(value.loc, size);
(oper.as_ref(), oper, Loc::default())
};
self.ci.emit(neg(dst.get(), oper.get()));
self.ci.free_loc(drop_loc);
Some(Value::new(value.ty, dst))
}
E::UnOp { op: T::Xor, val, .. } => {
let val = self.ty(val);
Some(Value::ty(self.tys.make_ptr(val)))
}
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E::UnOp { op: T::Band, val, pos } => {
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let mut val = self.expr(val)?;
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let Loc::Rt { derefed: drfd @ true, reg, stack, offset } = &mut val.loc else {
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self.report(
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pos,
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format_args!(
"cant take pointer of {} ({:?})",
self.ty_display(val.ty),
val.loc
),
);
};
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*drfd = false;
let offset = std::mem::take(offset) as _;
if reg.is_ref() {
let new_reg = self.ci.regs.allocate();
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self.stack_offset(new_reg.get(), reg.get(), stack.as_ref(), offset);
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*reg = new_reg;
} else {
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self.stack_offset(reg.get(), reg.get(), stack.as_ref(), offset);
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}
// FIXME: we might be able to track this but it will be pain
std::mem::forget(stack.take());
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Some(Value { ty: self.tys.make_ptr(val.ty), loc: val.loc })
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}
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E::UnOp { op: T::Mul, val, pos } => {
let val = self.expr(val)?;
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match val.ty.expand() {
ty::Kind::Ptr(ty) => Some(Value {
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ty: self.tys.ptrs[ty as usize].base,
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loc: Loc::reg(self.loc_to_reg(val.loc, self.tys.size_of(val.ty)))
.into_derefed(),
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}),
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_ => self.report(
pos,
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format_args!("expected pointer, got {}", self.ty_display(val.ty)),
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),
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}
}
E::BinOp { left, op: T::Decl, right } if self.has_ct(left) => {
let slot_base = self.ct.vm.read_reg(reg::STACK_PTR).0;
let (cnt, ty) = self.eval_const_low(right, None);
if self.assign_ct_pattern(left, ty, cnt as _) {
self.ct.vm.write_reg(reg::STACK_PTR, slot_base);
}
Some(Value::void())
}
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E::BinOp { left, op: T::Decl, right } => {
let value = self.expr(right)?;
self.assign_pattern(left, value)
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}
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E::Call { func: fast, args, .. } => {
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log::trc!("call {fast}");
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let func_ty = self.ty(fast);
let ty::Kind::Func(mut func) = func_ty.expand() else {
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self.report(fast.pos(), "can't call this, maybe in the future");
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};
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// TODO: this will be usefull but not now
let scope = self.ci.vars.len();
//let mut snap = self.output.snap();
//snap.sub(&self.ci.snap);
//let prev_stack_rel = self.ci.stack_relocs.len();
//let prev_ret_rel = self.ci.ret_relocs.len();
let sig = self.compute_signature(&mut func, expr.pos(), args)?;
//self.ci.ret_relocs.truncate(prev_ret_rel);
//self.ci.stack_relocs.truncate(prev_stack_rel);
//snap.add(&self.ci.snap);
//self.output.trunc(&snap);
self.ci.vars.truncate(scope);
let fuc = &self.tys.funcs[func as usize];
let ast = self.files[fuc.file as usize].clone();
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let E::BinOp { right: &E::Closure { args: cargs, .. }, .. } =
fuc.expr.get(&ast).unwrap()
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else {
unreachable!();
};
let mut parama = self.tys.parama(sig.ret);
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let mut values = Vec::with_capacity(args.len());
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let mut sig_args = sig.args.range();
let mut should_momize = !args.is_empty() && sig.ret == ty::Id::from(ty::TYPE);
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self.assert_arg_count(expr.pos(), args.len(), cargs.len(), "function call");
for (i, (arg, carg)) in args.iter().zip(cargs).enumerate() {
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let ty = self.tys.args[sig_args.next().unwrap()];
let sym = parser::find_symbol(&ast.symbols, carg.id);
if sym.flags & idfl::COMPTIME != 0 {
sig_args.next().unwrap();
continue;
}
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// TODO: pass the arg as dest
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let varg = self.expr_ctx(arg, Ctx::default().with_ty(ty))?;
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_ = self.assert_ty(arg.pos(), varg.ty, ty, format_args!("argument({i})"));
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self.pass_arg(&varg, &mut parama);
values.push(varg.loc);
should_momize = false;
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}
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for value in values {
self.ci.free_loc(value);
}
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let loc = self.alloc_ret(sig.ret, ctx, true);
if should_momize {
self.ci.write_trap(trap::Trap::MomizedCall(trap::MomizedCall { func }));
}
let reloc = Reloc::new(self.ci.code.len(), 3, 4);
self.ci.relocs.push(TypedReloc { target: ty::Kind::Func(func).compress(), reloc });
self.ci.emit(jal(RET_ADDR, ZERO, 0));
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self.make_func_reachable(func);
if should_momize {
self.ci.emit(tx());
}
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self.load_ret(sig.ret, &loc);
return Some(Value { ty: sig.ret, loc });
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}
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E::Ident { id, .. } if ident::is_null(id) => Some(Value::ty(id.into())),
E::Ident { id, .. }
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if let Some((var_index, var)) =
self.ci.vars.iter_mut().enumerate().find(|(_, v)| v.id == id) =>
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{
let loc = var.value.loc.as_ref();
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Some(Value { ty: self.ci.vars[var_index].value.ty, loc })
}
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E::Ident { id, name, .. } => match self
.tys
.syms
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.get(&SymKey { ident: id, file: self.ci.file })
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.copied()
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.map(ty::Kind::from_ty)
.unwrap_or_else(|| self.find_or_declare(ident::pos(id), self.ci.file, Ok(id), name))
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{
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ty::Kind::Global(id) => self.handle_global(id),
tk => Some(Value::ty(tk.compress())),
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},
E::Return { pos, val, .. } => {
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let size = self.ci.ret.map_or(17, |ty| self.tys.size_of(ty));
let loc = match size {
_ if self.ci.inline_ret_loc != Loc::default() => {
Some(self.ci.inline_ret_loc.as_ref())
}
0 => None,
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1..=16 => Some(Loc::reg(1)),
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_ => Some(Loc::reg(self.ci.ret_reg.as_ref()).into_derefed()),
};
let value = if let Some(val) = val {
self.expr_ctx(val, Ctx { ty: self.ci.ret, loc })?
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} else {
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Value::void()
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};
match self.ci.ret {
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None => self.ci.ret = Some(value.ty),
Some(ret) => _ = self.assert_ty(pos, value.ty, ret, "return type"),
}
self.ci.ret_relocs.push(Reloc::new(self.ci.code.len(), 1, 4));
self.ci.emit(jmp(0));
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None
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}
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E::Block { stmts, .. } => {
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for stmt in stmts {
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let val = self.expr(stmt)?;
self.ci.free_loc(val.loc);
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}
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Some(Value::void())
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}
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E::Number { value, pos, .. } => Some(Value {
ty: {
let ty = ctx.ty.map(ty::Id::strip_pointer).unwrap_or(ty::INT.into());
if !ty.is_integer() && !ty.is_pointer() {
self.report(
pos,
format_args!(
"this integer was inferred to be '{}' \
which does not make sense",
self.ty_display(ty)
),
);
}
ty
},
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loc: Loc::ct(value as u64),
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}),
E::If { cond, then, mut else_, .. } => {
let mut then = Some(then);
let jump_offset;
if let &E::BinOp { left, op, right } = cond
&& let ty = self.infer_type(left)
&& let Some((op, swapped)) = op.cond_op(ty.is_signed())
{
let left = self.expr_ctx(left, Ctx::default())?;
let right = self.expr_ctx(right, Ctx::default())?;
let lsize = self.tys.size_of(left.ty);
let rsize = self.tys.size_of(right.ty);
let left_reg = self.loc_to_reg(&left.loc, lsize);
let right_reg = self.loc_to_reg(&right.loc, rsize);
jump_offset = self.ci.code.len();
self.ci.emit(op(left_reg.get(), right_reg.get(), 0));
self.ci.free_loc(left.loc);
self.ci.free_loc(right.loc);
self.ci.regs.free(left_reg);
self.ci.regs.free(right_reg);
if swapped {
std::mem::swap(&mut then, &mut else_);
}
} else {
let cond = self.expr_ctx(cond, Ctx::default().with_ty(ty::BOOL))?;
let reg = self.loc_to_reg(&cond.loc, 1);
jump_offset = self.ci.code.len();
self.ci.emit(jeq(reg.get(), 0, 0));
self.ci.free_loc(cond.loc);
self.ci.regs.free(reg);
}
let then_unreachable =
if let Some(then) = then { self.expr(then).is_none() } else { false };
let mut else_unreachable = false;
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let mut jump = self.ci.code.len() as i64 - jump_offset as i64;
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if let Some(else_) = else_ {
let else_jump_offset = self.ci.code.len();
if !then_unreachable {
self.ci.emit(jmp(0));
jump = self.ci.code.len() as i64 - jump_offset as i64;
}
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else_unreachable = self.expr(else_).is_none();
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if !then_unreachable {
let jump = self.ci.code.len() as i64 - else_jump_offset as i64;
write_reloc(&mut self.ci.code, else_jump_offset + 1, jump, 4);
}
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}
write_reloc(&mut self.ci.code, jump_offset + 3, jump, 2);
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(!then_unreachable || !else_unreachable).then_some(Value::void())
}
E::Loop { body, .. } => 'a: {
let loop_start = self.ci.code.len();
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self.ci.loops.push(Loop {
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var_count: self.ci.vars.len() as _,
offset: loop_start as _,
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reloc_base: self.ci.loop_relocs.len() as u32,
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});
let body_unreachable = self.expr(body).is_none();
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if !body_unreachable {
let loop_end = self.ci.code.len();
self.ci.emit(jmp(loop_start as i32 - loop_end as i32));
}
let loop_end = self.ci.code.len() as u32;
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let loopa = self.ci.loops.pop().unwrap();
let is_unreachable = loopa.reloc_base == self.ci.loop_relocs.len() as u32;
for reloc in self.ci.loop_relocs.drain(loopa.reloc_base as usize..) {
let off = reloc.apply_jump(&mut self.ci.code, loop_end, 0);
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debug_assert!(off > 0);
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}
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let mut vars = std::mem::take(&mut self.ci.vars);
for var in vars.drain(loopa.var_count as usize..) {
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self.ci.free_loc(var.value.loc);
}
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self.ci.vars = vars;
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if is_unreachable {
break 'a None;
}
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Some(Value::void())
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}
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E::Break { .. } => {
self.ci.loop_relocs.push(Reloc::new(self.ci.code.len(), 1, 4));
self.ci.emit(jmp(0));
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None
}
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E::Continue { .. } => {
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let loop_ = self.ci.loops.last().unwrap();
let offset = self.ci.code.len();
self.ci.emit(jmp(loop_.offset as i32 - offset as i32));
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None
}
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E::BinOp { left, op: op @ (T::And | T::Or), right } => {
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let lhs = self.expr_ctx(left, Ctx::default().with_ty(ty::BOOL))?;
let lhs = self.loc_to_reg(lhs.loc, 1);
let jump_offset = self.ci.code.len() + 3;
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let op = if op == T::And { jeq } else { jne };
self.ci.emit(op(lhs.get(), 0, 0));
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if let Some(rhs) = self.expr_ctx(right, Ctx::default().with_ty(ty::BOOL)) {
let rhs = self.loc_to_reg(rhs.loc, 1);
self.ci.emit(cp(lhs.get(), rhs.get()));
}
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let jump = self.ci.code.len() as i64 - jump_offset as i64;
write_reloc(&mut self.ci.code, jump_offset, jump, 2);
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Some(Value { ty: ty::BOOL.into(), loc: Loc::reg(lhs) })
}
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E::BinOp { left, op, right } if op != T::Decl => 'ops: {
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let left = self.expr_ctx(left, Ctx {
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ty: ctx.ty.filter(|_| op.is_homogenous()),
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..Default::default()
})?;
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if op == T::Assign {
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let value = self.expr_ctx(right, Ctx::from(left)).unwrap();
self.ci.free_loc(value.loc);
return Some(Value::void());
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}
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if let ty::Kind::Struct(_) = left.ty.expand() {
let right = self.expr_ctx(right, Ctx::default().with_ty(left.ty))?;
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_ = self.assert_ty(expr.pos(), right.ty, left.ty, "right struct operand");
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return self.struct_op(op, left.ty, ctx, left.loc, right.loc);
}
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let lsize = self.tys.size_of(left.ty);
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let (mut lhs, dst, drop_loc) = if let Some(dst) = &ctx.loc
&& dst.is_reg()
&& let Some(dst) = ctx.loc.take()
{
(
self.loc_to_reg(&left.loc, lsize),
if dst.is_ref() {
self.loc_to_reg(&dst, lsize)
} else {
self.loc_to_reg(dst, lsize)
},
left.loc,
)
} else {
let lhs = self.loc_to_reg(left.loc, lsize);
(lhs.as_ref(), lhs, Loc::default())
};
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let right = self.expr_ctx(right, Ctx::default().with_ty(left.ty))?;
let rsize = self.tys.size_of(right.ty);
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let ty = self.assert_ty(expr.pos(), right.ty, left.ty, "right sclalar operand");
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let size = self.tys.size_of(ty);
let signed = ty.is_signed();
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if let Loc::Ct { value: CtValue(mut imm), derefed } = right.loc
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&& let Some(oper) = op.imm_binop(signed, size)
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{
if derefed {
let mut dst = [0u8; 8];
dst[..size as usize].copy_from_slice(unsafe {
std::slice::from_raw_parts(imm as _, rsize as usize)
});
imm = u64::from_ne_bytes(dst);
}
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if matches!(op, T::Add | T::Sub)
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&& let ty::Kind::Ptr(ty) = ty::Kind::from_ty(ty)
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{
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let size = self.tys.size_of(self.tys.ptrs[ty as usize].base);
imm *= size as u64;
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}
self.ci.emit(oper(dst.get(), lhs.get(), imm));
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self.ci.regs.free(lhs);
self.ci.free_loc(drop_loc);
break 'ops Some(Value::new(ty, dst));
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}
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let mut rhs = self.loc_to_reg(&right.loc, rsize);
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if matches!(op, T::Add | T::Sub) {
let min_size = lsize.min(rsize);
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if ty.is_signed() && min_size < size {
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let operand = if lsize < rsize {
lhs = self.cow_reg(lhs);
lhs.get()
} else {
rhs = self.cow_reg(rhs);
rhs.get()
};
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let op = [sxt8, sxt16, sxt32][min_size.ilog2() as usize];
self.ci.emit(op(operand, operand));
}
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if left.ty.is_pointer() ^ right.ty.is_pointer() {
let (offset, ty) = if left.ty.is_pointer() {
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rhs = self.cow_reg(rhs);
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(rhs.get(), left.ty)
} else {
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lhs = self.cow_reg(lhs);
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(lhs.get(), right.ty)
};
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let ty::Kind::Ptr(ty) = ty.expand() else { unreachable!() };
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let size = self.tys.size_of(self.tys.ptrs[ty as usize].base);
self.ci.emit(muli64(offset, offset, size as _));
}
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}
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if let Some(op) = op.binop(signed, size) {
self.ci.emit(op(dst.get(), lhs.get(), rhs.get()));
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self.ci.regs.free(lhs);
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self.ci.regs.free(rhs);
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self.ci.free_loc(right.loc);
self.ci.free_loc(drop_loc);
break 'ops Some(Value::new(ty, dst));
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}
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'cmp: {
let against = match op {
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T::Le | T::Gt => 1,
T::Ne | T::Eq => 0,
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T::Ge | T::Lt => (-1i64) as _,
_ => break 'cmp,
};
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let op_fn = if signed { cmps } else { cmpu };
self.ci.emit(op_fn(dst.get(), lhs.get(), rhs.get()));
self.ci.emit(cmpui(dst.get(), dst.get(), against));
if matches!(op, T::Eq | T::Lt | T::Gt) {
self.ci.emit(not(dst.get(), dst.get()));
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}
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self.ci.regs.free(lhs);
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self.ci.regs.free(rhs);
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self.ci.free_loc(right.loc);
self.ci.free_loc(drop_loc);
break 'ops Some(Value::new(ty::BOOL, dst));
}
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unimplemented!("{:#?}", op)
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}
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E::Comment { .. } => Some(Value::void()),
ref ast => self.report_unhandled_ast(ast, "expression"),
}?;
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if let Some(ty) = ctx.ty {
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_ = self.assert_ty(expr.pos(), value.ty, ty, format_args!("'{expr}'"));
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}
Some(match ctx.loc {
Some(dest) => {
self.store_sized(
value.loc,
dest,
self.tys.size_of(ctx.ty.unwrap_or(value.ty)).min(self.tys.size_of(value.ty)),
);
Value { ty: value.ty, loc: Loc::ct(0) }
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}
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None => value,
})
}
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fn compute_signature(&mut self, func: &mut ty::Func, pos: Pos, args: &[Expr]) -> Option<Sig> {
let fuc = &self.tys.funcs[*func as usize];
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let fast = self.files[fuc.file as usize].clone();
let Expr::BinOp { right: &Expr::Closure { args: cargs, ret, .. }, .. } =
fuc.expr.get(&fast).unwrap()
else {
unreachable!();
};
Some(if let Some(sig) = fuc.sig {
sig
} else {
let arg_base = self.tys.args.len();
for (arg, carg) in args.iter().zip(cargs) {
let ty = self.ty(&carg.ty);
self.tys.args.push(ty);
let sym = parser::find_symbol(&fast.symbols, carg.id);
let loc = if sym.flags & idfl::COMPTIME == 0 {
// FIXME: could fuck us
Loc::default()
} else {
debug_assert_eq!(
ty,
ty::TYPE.into(),
"TODO: we dont support anything except type generics"
);
let arg = self.expr_ctx(arg, Ctx::default().with_ty(ty))?;
self.tys.args.push(arg.loc.to_ty().unwrap());
arg.loc
};
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self.ci.vars.push(Variable { id: carg.id, value: Value { ty, loc } });
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}
let args = self.pack_args(pos, arg_base);
let ret = self.ty(ret);
let sym = SymKey { file: !args.repr(), ident: ty::Kind::Func(*func).compress().repr() };
let ct = || {
let func_id = self.tys.funcs.len();
let fuc = &self.tys.funcs[*func as usize];
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self.tys.funcs.push(Func {
file: fuc.file,
sig: Some(Sig { args, ret }),
expr: fuc.expr,
..Default::default()
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});
ty::Kind::Func(func_id as _).compress()
};
*func = self.tys.syms.entry(sym).or_insert_with(ct).expand().inner();
Sig { args, ret }
})
}
fn has_ct(&self, expr: &Expr) -> bool {
expr.has_ct(&self.cfile().symbols)
}
fn infer_type(&mut self, expr: &Expr) -> ty::Id {
// FIXME: very inneficient
let mut ci = ItemCtx {
file: self.ci.file,
id: self.ci.id,
ret: self.ci.ret,
task_base: self.ci.task_base,
loops: self.ci.loops.clone(),
vars: self
.ci
.vars
.iter()
.map(|v| Variable {
id: v.id,
value: Value { ty: v.value.ty, loc: v.value.loc.as_ref() },
})
.collect(),
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stack_relocs: self.ci.stack_relocs.clone(),
ret_relocs: self.ci.ret_relocs.clone(),
loop_relocs: self.ci.loop_relocs.clone(),
..Default::default()
};
ci.regs.init();
std::mem::swap(&mut self.ci, &mut ci);
let value = self.expr(expr).unwrap();
self.ci.free_loc(value.loc);
std::mem::swap(&mut self.ci, &mut ci);
value.ty
}
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fn eval_const(&mut self, expr: &Expr, ty: impl Into<ty::Id>) -> u64 {
self.eval_const_low(expr, Some(ty.into())).0
}
fn eval_const_low(&mut self, expr: &Expr, mut ty: Option<ty::Id>) -> (u64, ty::Id) {
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let mut ci = ItemCtx {
file: self.ci.file,
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id: ty::Kind::Builtin(u32::MAX),
ret: ty,
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..self.pool.cis.pop().unwrap_or_default()
};
ci.vars.append(&mut self.ci.vars);
let loc = self.ct_eval(ci, |s, prev| {
s.ci.emit_prelude();
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if s.ci.ret.map_or(true, |r| s.tys.size_of(r) > 16) {
let reg = s.ci.regs.allocate();
s.ci.emit(instrs::cp(reg.get(), 1));
s.ci.ret_reg = reg;
};
let ctx = Ctx { loc: None, ty: s.ci.ret };
if s.expr_ctx(&Expr::Return { pos: 0, val: Some(expr) }, ctx).is_some() {
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s.report(expr.pos(), "we fucked up");
};
ty = s.ci.ret;
s.complete_call_graph();
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prev.vars.append(&mut s.ci.vars);
s.ci.finalize();
s.ci.emit(tx());
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Ok(1)
});
match loc {
Ok(i) | Err(i) => {
(self.ct.vm.read_reg(i).cast::<u64>(), ty.expect("you have died (in brahmaputra)"))
}
}
}
fn assign_ct_pattern(&mut self, pat: &Expr, ty: ty::Id, offset: *mut u8) -> bool {
let size = self.tys.size_of(ty);
match *pat {
Expr::Ident { id, .. }
if find_symbol(&self.cfile().symbols, id).flags & idfl::REFERENCED == 0
&& size <= 8 =>
{
let loc = Loc::ct(load_value(offset, size));
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self.ci.vars.push(Variable { id, value: Value { ty, loc } });
true
}
Expr::Ident { id, .. } => {
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let var = Variable { id, value: Value { ty, loc: Loc::ct_ptr(offset as _) } };
self.ci.vars.push(var);
false
}
ref pat => self.report_unhandled_ast(pat, "comptime pattern"),
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}
}
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fn assign_pattern(&mut self, pat: &Expr, right: Value) -> Option<Value> {
match *pat {
Expr::Ident { id, .. } => {
let mut loc = self.make_loc_owned(right.loc, right.ty);
let sym = parser::find_symbol(&self.cfile().symbols, id).flags;
if sym & idfl::REFERENCED != 0 {
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loc = self.spill(loc, self.tys.size_of(right.ty));
}
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self.ci.vars.push(Variable { id, value: Value { ty: right.ty, loc } });
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}
Expr::Ctor { pos, fields, .. } => {
let ty::Kind::Struct(idx) = right.ty.expand() else {
self.report(pos, "can't use struct destruct on non struct value (TODO: shold work with modules)");
};
for &CtorField { pos, name, ref value } in fields {
let Some((offset, ty)) = self.tys.offset_of(idx, name) else {
self.report(pos, format_args!("field not found: {name:?}"));
};
let loc = self.ci.dup_loc(&right.loc).offset(offset);
self.assign_pattern(value, Value::new(ty, loc));
}
self.ci.free_loc(right.loc);
}
ref pat => self.report_unhandled_ast(pat, "pattern"),
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};
Some(Value::void())
}
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fn prepare_struct_ctor(
&mut self,
pos: Pos,
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ctx: &mut Ctx,
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ty: Option<&Expr>,
field_len: usize,
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) -> (ty::Id, Loc) {
let Some(mut ty) = ty.map(|ty| self.ty(ty)).or(ctx.ty) else {
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self.report(pos, "expected type, (it cannot be inferred)");
};
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match ty.expand() {
ty::Kind::Struct(stru) => {
let field_count = self.tys.structs[stru as usize].fields.len();
if field_count != field_len {
self.report(
pos,
format_args!("expected {field_count} fields, got {field_len}"),
);
}
}
ty::Kind::Slice(arr) => {
let arr = &self.tys.arrays[arr as usize];
if arr.len == ArrayLen::MAX {
ty = self.tys.make_array(arr.ty, field_len as _);
} else if arr.len != field_len as u32 {
self.report(
pos,
format_args!(
"literal has {} elements, but explicit array type has {} elements",
arr.len, field_len
),
);
}
}
_ => self.report(pos, "expected expression to evaluate to struct (or array maybe)"),
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}
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let size = self.tys.size_of(ty);
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if ctx.loc.as_ref().map_or(true, |l| l.is_reg()) {
(ty, Loc::stack(self.ci.stack.allocate(size)))
} else {
(ty, ctx.loc.take().unwrap_or_else(|| Loc::stack(self.ci.stack.allocate(size))))
}
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}
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fn struct_op(
&mut self,
op: TokenKind,
ty: ty::Id,
ctx: Ctx,
left: Loc,
mut right: Loc,
) -> Option<Value> {
if let ty::Kind::Struct(stuct) = ty.expand() {
let loc = ctx
.loc
.or_else(|| right.take_owned())
.unwrap_or_else(|| Loc::stack(self.ci.stack.allocate(self.tys.size_of(ty))));
let mut oiter = OffsetIter::new(stuct);
while let Some((ty, offset)) = oiter.next_ty(&self.tys) {
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let ctx = Ctx::from(Value { ty, loc: loc.as_ref().offset(offset) });
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let left = left.as_ref().offset(offset);
let right = right.as_ref().offset(offset);
let value = self.struct_op(op, ty, ctx, left, right)?;
self.ci.free_loc(value.loc);
}
self.ci.free_loc(left);
self.ci.free_loc(right);
return Some(Value { ty, loc });
}
let size = self.tys.size_of(ty);
let signed = ty.is_signed();
let lhs = self.loc_to_reg(left, size);
if let Loc::Ct { value, derefed: false } = right
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&& let Some(op) = op.imm_binop(signed, size)
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{
self.ci.emit(op(lhs.get(), lhs.get(), value.0));
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return Some(if let Some(value) = ctx.into_value() {
self.store_typed(Loc::reg(lhs.as_ref()), value.loc, value.ty);
Value::void()
} else {
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Value { ty, loc: Loc::reg(lhs) }
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});
}
let rhs = self.loc_to_reg(right, size);
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if let Some(op) = op.binop(signed, size) {
self.ci.emit(op(lhs.get(), lhs.get(), rhs.get()));
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self.ci.regs.free(rhs);
return if let Some(value) = ctx.into_value() {
self.store_typed(Loc::reg(lhs), value.loc, value.ty);
Some(Value::void())
} else {
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Some(Value { ty, loc: Loc::reg(lhs) })
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};
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}
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unimplemented!("{:#?}", op)
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}
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fn handle_global(&mut self, id: ty::Global) -> Option<Value> {
let ptr = self.ci.regs.allocate();
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let reloc = Reloc::new(self.ci.code.len(), 3, 4);
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let global = &mut self.tys.globals[id as usize];
self.ci.relocs.push(TypedReloc { target: ty::Kind::Global(id).compress(), reloc });
self.ci.emit(instrs::lra(ptr.get(), 0, 0));
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Some(Value { ty: global.ty, loc: Loc::reg(ptr).into_derefed() })
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}
fn spill(&mut self, loc: Loc, size: Size) -> Loc {
if loc.is_ref() || !loc.is_stack() {
let stack = Loc::stack(self.ci.stack.allocate(size));
self.store_sized(loc, &stack, size);
stack
} else {
loc
}
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}
fn make_loc_owned(&mut self, loc: Loc, ty: ty::Id) -> Loc {
let size = self.tys.size_of(ty);
match size {
0 => Loc::default(),
1..=8 => Loc::reg(self.loc_to_reg(loc, size)),
_ if loc.is_ref() => {
let new_loc = Loc::stack(self.ci.stack.allocate(size));
self.store_sized(loc, &new_loc, size);
new_loc
}
_ => loc,
}
}
fn complete_call_graph(&mut self) {
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while self.ci.task_base < self.tasks.len()
&& let Some(task_slot) = self.tasks.pop()
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{
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let Some(task) = task_slot else { continue };
self.handle_task(task);
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}
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}
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fn handle_task(&mut self, FTask { file, id }: FTask) {
let func = &self.tys.funcs[id as usize];
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debug_assert!(func.file == file);
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let sig = func.sig.unwrap();
let ast = self.files[file as usize].clone();
let expr = func.expr.get(&ast).unwrap();
let ct_stack_base = self.ct.vm.read_reg(reg::STACK_PTR).0;
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let repl = ItemCtx {
file,
id: ty::Kind::Func(id),
ret: Some(sig.ret),
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..self.pool.cis.pop().unwrap_or_default()
};
let prev_ci = std::mem::replace(&mut self.ci, repl);
self.ci.regs.init();
let Expr::BinOp {
left: Expr::Ident { .. },
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op: TokenKind::Decl,
right: &Expr::Closure { body, args, .. },
} = expr
else {
unreachable!("{expr}")
};
self.ci.emit_prelude();
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let mut parama = self.tys.parama(sig.ret);
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let mut sig_args = sig.args.range();
for arg in args.iter() {
let ty = self.tys.args[sig_args.next().unwrap()];
let sym = parser::find_symbol(&ast.symbols, arg.id).flags;
let loc = match sym & idfl::COMPTIME != 0 {
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true => Loc::ty(self.tys.args[sig_args.next().unwrap()]),
false => self.load_arg(sym, ty, &mut parama),
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};
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self.ci.vars.push(Variable { id: arg.id, value: Value { ty, loc } });
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}
if self.tys.size_of(sig.ret) > 16 {
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let reg = self.ci.regs.allocate();
self.ci.emit(instrs::cp(reg.get(), 1));
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self.ci.ret_reg = reg;
} else {
self.ci.ret_reg = reg::Id::RET;
}
if self.expr(body).is_some() {
self.report(body.pos(), "expected all paths in the fucntion to return");
}
for vars in self.ci.vars.drain(..).collect::<Vec<_>>() {
self.ci.free_loc(vars.value.loc);
}
self.ci.finalize();
self.ci.emit(jala(ZERO, RET_ADDR, 0));
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self.ci.regs.free(std::mem::take(&mut self.ci.ret_reg));
self.tys.funcs[id as usize].code.append(&mut self.ci.code);
self.tys.funcs[id as usize].relocs.append(&mut self.ci.relocs);
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self.pool.cis.push(std::mem::replace(&mut self.ci, prev_ci));
self.ct.vm.write_reg(reg::STACK_PTR, ct_stack_base);
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}
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fn load_arg(&mut self, flags: parser::IdentFlags, ty: ty::Id, parama: &mut ParamAlloc) -> Loc {
let size = self.tys.size_of(ty) as Size;
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if size == 0 {
return Loc::default();
}
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let (src, dst) = match size {
0 => (Loc::default(), Loc::default()),
..=8 if flags & idfl::REFERENCED == 0 => {
(Loc::reg(parama.next()), Loc::reg(self.ci.regs.allocate()))
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}
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1..=8 => (Loc::reg(parama.next()), Loc::stack(self.ci.stack.allocate(size))),
9..=16 => (Loc::reg(parama.next_wide()), Loc::stack(self.ci.stack.allocate(size))),
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_ if flags & (idfl::MUTABLE | idfl::REFERENCED) == 0 => {
let ptr = parama.next();
let reg = self.ci.regs.allocate();
self.ci.emit(instrs::cp(reg.get(), ptr));
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return Loc::reg(reg).into_derefed();
}
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_ => (Loc::reg(parama.next()).into_derefed(), Loc::stack(self.ci.stack.allocate(size))),
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};
self.store_sized(src, &dst, size);
dst
}
fn eca(&mut self, trap: trap::Trap, ret: impl Into<ty::Id>) -> Value {
self.ci.write_trap(trap);
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Value { ty: ret.into(), loc: Loc::reg(1) }
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}
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fn alloc_ret(&mut self, ret: ty::Id, ctx: Ctx, custom_ret_reg: bool) -> Loc {
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let size = self.tys.size_of(ret);
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if size == 0 {
debug_assert!(ctx.loc.is_none(), "{}", self.ty_display(ret));
return Loc::default();
}
if ctx.loc.is_some() && size < 16 {
return ctx.loc.unwrap();
}
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match size {
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0 => Loc::default(),
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1..=8 if custom_ret_reg => Loc::reg(self.ci.regs.allocate()),
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1..=8 => Loc::reg(1),
9..=16 => Loc::stack(self.ci.stack.allocate(size)),
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17.. => {
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let loc = ctx.loc.unwrap_or_else(|| Loc::stack(self.ci.stack.allocate(size)));
let Loc::Rt { reg, stack, offset, .. } = &loc else {
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todo!("old man with the beard looks at the sky scared");
};
self.stack_offset(1, reg.get(), stack.as_ref(), *offset);
loc
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}
}
}
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fn loc_to_reg(&mut self, loc: impl Into<LocCow>, size: Size) -> reg::Id {
match loc.into() {
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LocCow::Owned(Loc::Rt { derefed: false, mut reg, offset, stack }) => {
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debug_assert!(stack.is_none(), "TODO");
assert_eq!(offset, 0, "TODO");
if reg.is_ref() {
let new_reg = self.ci.regs.allocate();
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debug_assert_ne!(reg.get(), 0);
self.ci.emit(cp(new_reg.get(), reg.get()));
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reg = new_reg;
}
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reg
}
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LocCow::Ref(&Loc::Rt { derefed: false, ref reg, offset, ref stack }) => {
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debug_assert!(stack.is_none(), "TODO");
assert_eq!(offset, 0, "TODO");
reg.as_ref()
}
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loc => {
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let reg = self.ci.regs.allocate();
self.store_sized(loc, Loc::reg(reg.as_ref()), size);
reg
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}
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}
}
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fn load_ret(&mut self, ty: ty::Id, loc: &Loc) {
let size = self.tys.size_of(ty);
if let 1..=16 = size {
self.store_sized(Loc::reg(1), loc, size);
}
}
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fn pass_arg(&mut self, value: &Value, parama: &mut ParamAlloc) {
self.pass_arg_low(&value.loc, self.tys.size_of(value.ty), parama)
}
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fn pass_arg_low(&mut self, loc: &Loc, size: Size, parama: &mut ParamAlloc) {
if size > 16 {
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let Loc::Rt { reg, stack, offset, .. } = loc else { unreachable!() };
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self.stack_offset(parama.next(), reg.get(), stack.as_ref(), *offset as _);
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return;
}
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let dst = match size {
0 => return,
9..=16 => Loc::reg(parama.next_wide()),
_ => Loc::reg(parama.next()),
};
self.store_sized(loc, dst, size);
}
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fn store_typed(&mut self, src: impl Into<LocCow>, dst: impl Into<LocCow>, ty: ty::Id) {
self.store_sized(src, dst, self.tys.size_of(ty) as _)
}
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fn store_sized(&mut self, src: impl Into<LocCow>, dst: impl Into<LocCow>, size: Size) {
self.store_sized_low(src.into(), dst.into(), size);
}
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fn store_sized_low(&mut self, src: LocCow, dst: LocCow, size: Size) {
macro_rules! lpat {
($der:literal, $reg:ident, $off:pat, $sta:pat) => {
&Loc::Rt { derefed: $der, reg: ref $reg, offset: $off, stack: $sta }
};
}
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if size == 0 {
return;
}
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src.as_ref().assert_valid();
dst.as_ref().assert_valid();
match (src.as_ref(), dst.as_ref()) {
(&Loc::Ct { value, derefed }, lpat!(true, reg, off, ref sta)) => {
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let ct = self.ci.regs.allocate();
self.ci.emit(li64(ct.get(), ensure_loaded(value, derefed, size)));
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let off = self.opt_stack_reloc(sta.as_ref(), off, 3);
self.ci.emit(st(ct.get(), reg.get(), off, size as _));
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self.ci.regs.free(ct);
}
(&Loc::Ct { value, derefed }, lpat!(false, reg, 0, None)) => {
self.ci.emit(li64(reg.get(), ensure_loaded(value, derefed, size)))
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}
(&Loc::Ct { value, derefed }, lpat!(false, reg, 8, None))
if reg.get() == 1 && size == 8 =>
{
self.ci.emit(li64(reg.get() + 1, ensure_loaded(value, derefed, size)));
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}
(&Loc::Ct { value, derefed }, lpat!(false, reg, off, None)) if reg.get() == 1 => {
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let freg = reg.get() + (off / 8) as u8;
let mask = !(((1u64 << (8 * size)) - 1) << (8 * (off % 8)));
self.ci.emit(andi(freg, freg, mask));
let value = ensure_loaded(value, derefed, size) << (8 * (off % 8));
self.ci.emit(ori(freg, freg, value));
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}
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(lpat!(true, src, soff, ref ssta), lpat!(true, dst, doff, ref dsta)) => {
// TODO: some oportuinies to ellit more optimal code
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let src_off = if src.is_ref() { self.ci.regs.allocate() } else { src.as_ref() };
let dst_off = if dst.is_ref() { self.ci.regs.allocate() } else { dst.as_ref() };
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self.stack_offset(src_off.get(), src.get(), ssta.as_ref(), soff);
self.stack_offset(dst_off.get(), dst.get(), dsta.as_ref(), doff);
self.ci.emit(bmc(src_off.get(), dst_off.get(), size as _));
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self.ci.regs.free(src_off);
self.ci.regs.free(dst_off);
}
(lpat!(false, src, 0, None), lpat!(false, dst, 0, None)) => {
if src != dst {
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debug_assert_ne!(src.get(), 0);
self.ci.emit(cp(dst.get(), src.get()));
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}
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}
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(lpat!(true, src, soff, ref ssta), lpat!(false, dst, 0, None)) => {
if size < 8 {
self.ci.emit(cp(dst.get(), 0));
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}
let off = self.opt_stack_reloc(ssta.as_ref(), soff, 3);
self.ci.emit(ld(dst.get(), src.get(), off, size as _));
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}
(lpat!(false, src, 0, None), lpat!(true, dst, doff, ref dsta)) => {
let off = self.opt_stack_reloc(dsta.as_ref(), doff, 3);
self.ci.emit(st(src.get(), dst.get(), off, size as _))
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}
(a, b) => unreachable!("{a:?} {b:?}"),
}
self.ci.free_loc(src);
self.ci.free_loc(dst);
}
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fn stack_offset(&mut self, dst: u8, op: u8, stack: Option<&stack::Id>, off: Offset) {
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let Some(stack) = stack else {
self.ci.emit_addi(dst, op, off as _);
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return;
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};
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let off = self.stack_reloc(stack, off, 3);
self.ci.emit(addi64(dst, op, off));
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}
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fn opt_stack_reloc(&mut self, stack: Option<&stack::Id>, off: Offset, sub_offset: u8) -> u64 {
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stack.map(|s| self.stack_reloc(s, off, sub_offset)).unwrap_or(off as _)
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}
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fn stack_reloc(&mut self, stack: &stack::Id, off: Offset, sub_offset: u8) -> u64 {
let offset = self.ci.code.len();
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self.ci.stack_relocs.push(Reloc::new(offset, sub_offset, 8));
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Reloc::pack_srel(stack, off)
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}
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fn ty(&mut self, expr: &Expr) -> ty::Id {
self.tys
.ty(self.ci.file, expr, &self.files)
.unwrap_or_else(|| ty::Id::from(self.eval_const(expr, ty::TYPE)))
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}
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fn read_trap(addr: u64) -> Option<&'static trap::Trap> {
// TODO: make this debug only
if unsafe { *(addr as *const u8) } != 255 {
return None;
}
Some(unsafe { &*((addr + 1) as *const trap::Trap) })
}
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fn handle_ecall(&mut self) {
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let trap = Self::read_trap(self.ct.vm.pc.get()).unwrap();
self.ct.vm.pc = self.ct.vm.pc.wrapping_add(trap.size() + 1);
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let mut code_index = self.ct.vm.pc.get() as usize - self.ct.code.as_ptr() as usize;
debug_assert!(code_index < self.ct.code.len());
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match *trap {
trap::Trap::MakeStruct(trap::MakeStruct { file, struct_expr }) => {
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let cfile = self.files[file as usize].clone();
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let &Expr::Struct { fields, captured, packed, .. } =
struct_expr.get(&cfile).unwrap()
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else {
unreachable!()
};
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let prev_len = self.ci.vars.len();
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let mut values = self.ct.vm.read_reg(2).0 as *const u8;
for &id in captured {
let ty: ty::Id = unsafe { std::ptr::read_unaligned(values.cast()) };
unsafe { values = values.add(4) };
let size = self.tys.size_of(ty) as usize;
let mut imm = [0u8; 8];
assert!(size <= imm.len(), "TODO");
unsafe { std::ptr::copy_nonoverlapping(values, imm.as_mut_ptr(), size) };
self.ci.vars.push(Variable {
id,
value: Value::new(ty, Loc::ct(u64::from_ne_bytes(imm))),
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});
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}
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let stru =
ty::Kind::Struct(self.build_struct(packed.then_some(1), fields)).compress();
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self.ci.vars.truncate(prev_len);
self.ct.vm.write_reg(1, stru.repr() as u64);
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debug_assert_ne!(stru.expand().inner(), 1);
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}
trap::Trap::MomizedCall(trap::MomizedCall { func }) => {
let sym = SymKey { file: u32::MAX, ident: ty::Kind::Func(func).compress().repr() };
if let Some(&ty) = self.tys.syms.get(&sym) {
self.ct.vm.write_reg(1, ty.repr());
} else {
self.run_vm();
self.tys.syms.insert(sym, self.ct.vm.read_reg(1).0.into());
}
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code_index += jal(0, 0, 0).0 + tx().0;
}
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}
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let offset = code_index + self.ct.code.as_ptr() as usize;
self.ct.vm.pc = hbvm::mem::Address::new(offset as _);
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}
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fn find_or_declare(
&mut self,
pos: Pos,
file: FileId,
name: Result<Ident, &str>,
lit_name: &str,
) -> ty::Kind {
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log::trc!("find_or_declare: {lit_name} {file}");
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let f = self.files[file as usize].clone();
let Some((expr, ident)) = f.find_decl(name) else {
match name {
Ok(_) => self.report(pos, format_args!("undefined indentifier: {lit_name}")),
Err("main") => self.report(pos, format_args!("missing main function: {f}")),
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Err(name) => self.report(pos, format_args!("undefined indentifier: {name}")),
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}
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};
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if let Some(existing) = self.tys.syms.get(&SymKey { file, ident }) {
if let ty::Kind::Func(id) = existing.expand()
&& let func = &mut self.tys.funcs[id as usize]
&& let Err(idx) = task::unpack(func.offset)
&& idx < self.tasks.len()
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{
func.offset = task::id(self.tasks.len());
let task = self.tasks[idx].take();
self.tasks.push(task);
}
return existing.expand();
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}
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let prev_file = std::mem::replace(&mut self.ci.file, file);
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let sym = match expr {
Expr::BinOp {
left: &Expr::Ident { .. },
op: TokenKind::Decl,
right: &Expr::Closure { pos, args, ret, .. },
} => {
let func = Func {
file,
sig: 'b: {
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let arg_base = self.tys.args.len();
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for arg in args {
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let sym = find_symbol(&self.files[file as usize].symbols, arg.id);
if sym.flags & idfl::COMPTIME != 0 {
self.tys.args.truncate(arg_base);
break 'b None;
}
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let ty = self.ty(&arg.ty);
self.tys.args.push(ty);
}
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let args = self.pack_args(pos, arg_base);
let ret = self.ty(ret);
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Some(Sig { args, ret })
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},
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expr: {
let refr = ExprRef::new(expr);
debug_assert!(refr.get(&f).is_some());
refr
},
..Default::default()
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};
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let id = self.tys.funcs.len() as _;
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self.tys.funcs.push(func);
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ty::Kind::Func(id)
}
Expr::BinOp {
left: &Expr::Ident { .. },
op: TokenKind::Decl,
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right: Expr::Struct { fields, packed, .. },
} => ty::Kind::Struct(self.build_struct(packed.then_some(1), fields)),
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Expr::BinOp { left, op: TokenKind::Decl, right } => {
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let gid = self.tys.globals.len() as ty::Global;
self.tys.globals.push(Global { file, name: ident, ..Default::default() });
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let ci = ItemCtx {
file,
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id: ty::Kind::Builtin(u32::MAX),
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..self.pool.cis.pop().unwrap_or_default()
};
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_ = left.find_pattern_path(ident, right, |expr| {
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self.tys.globals[gid as usize] = self
.ct_eval(ci, |s, _| Ok::<_, !>(s.generate_global(expr, file, ident)))
.into_ok();
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});
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ty::Kind::Global(gid)
}
e => unimplemented!("{e:#?}"),
};
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self.ci.file = prev_file;
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self.tys.syms.insert(SymKey { ident, file }, sym.compress());
sym
}
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fn make_func_reachable(&mut self, func: ty::Func) {
let fuc = &mut self.tys.funcs[func as usize];
if fuc.offset == u32::MAX {
fuc.offset = task::id(self.tasks.len() as _);
self.tasks.push(Some(FTask { file: fuc.file, id: func }));
}
}
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fn generate_global(&mut self, expr: &Expr, file: FileId, name: Ident) -> Global {
self.ci.emit_prelude();
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let ret = self.ci.regs.allocate();
self.ci.emit(instrs::cp(ret.get(), 1));
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self.ci.task_base = self.tasks.len();
let ctx = Ctx::default().with_loc(Loc::reg(ret).into_derefed());
let Some(ret) = self.expr_ctx(expr, ctx) else {
self.report(expr.pos(), "expression is not reachable");
};
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self.complete_call_graph();
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let mut data = vec![0; self.tys.size_of(ret.ty) as usize];
self.ci.finalize();
self.ci.emit(tx());
self.ct.vm.write_reg(1, data.as_mut_ptr() as u64);
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self.ci.free_loc(ret.loc);
Global { ty: ret.ty, file, name, data, ..Default::default() }
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}
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fn ct_eval<T, E>(
&mut self,
ci: ItemCtx,
compile: impl FnOnce(&mut Self, &mut ItemCtx) -> Result<T, E>,
) -> Result<T, E> {
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log::trc!("eval");
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let mut prev_ci = std::mem::replace(&mut self.ci, ci);
self.ci.task_base = self.tasks.len();
self.ci.regs.init();
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let ret = compile(self, &mut prev_ci);
let mut rr = std::mem::take(&mut self.ci.ret_reg);
let is_on_stack = !rr.is_ref();
if !rr.is_ref() {
self.ci.emit(instrs::cp(1, rr.get()));
let rref = rr.as_ref();
self.ci.regs.free(std::mem::replace(&mut rr, rref));
}
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if ret.is_ok() {
let last_fn = self.tys.funcs.len();
self.tys.funcs.push(Default::default());
self.tys.funcs[last_fn].code.append(&mut self.ci.code);
self.tys.funcs[last_fn].relocs.append(&mut self.ci.relocs);
if is_on_stack {
let size =
self.tys.size_of(self.ci.ret.expect("you have died (colaterall fuck up)"));
let slot = self.ct.vm.read_reg(reg::STACK_PTR).0;
self.ct.vm.write_reg(reg::STACK_PTR, slot.wrapping_add(size as _));
self.ct.vm.write_reg(1, slot);
}
self.tys.dump_reachable(last_fn as _, &mut self.ct.code);
let entry = &mut self.ct.code[self.tys.funcs[last_fn].offset as usize] as *mut _ as _;
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let prev_pc = std::mem::replace(&mut self.ct.vm.pc, hbvm::mem::Address::new(entry))
- self.ct.code.as_ptr() as usize;
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#[cfg(debug_assertions)]
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{
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let mut vc = Vec::<u8>::new();
if let Err(e) = self.tys.disasm(&self.ct.code, &self.files, &mut vc, |bts| {
if let Some(trap) = Self::read_trap(bts.as_ptr() as _) {
bts.take(..trap.size() + 1).unwrap();
}
}) {
panic!("{e} {}", String::from_utf8(vc).unwrap());
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} else {
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log::trc!("{}", String::from_utf8(vc).unwrap());
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}
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}
self.run_vm();
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self.ct.vm.pc = prev_pc + self.ct.code.as_ptr() as usize;
self.tys.funcs.pop().unwrap();
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}
self.pool.cis.push(std::mem::replace(&mut self.ci, prev_ci));
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log::trc!("eval-end");
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ret
}
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pub fn disasm(&mut self, output: &mut impl std::io::Write) -> std::io::Result<()> {
let mut bin = Vec::new();
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self.assemble(&mut bin);
self.tys.disasm(&bin, &self.files, output, |_| {})
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}
fn run_vm(&mut self) {
loop {
match self.ct.vm.run().unwrap() {
hbvm::VmRunOk::End => break,
hbvm::VmRunOk::Timer => unreachable!(),
hbvm::VmRunOk::Ecall => self.handle_ecall(),
hbvm::VmRunOk::Breakpoint => unreachable!(),
}
}
}
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fn ty_display(&self, ty: ty::Id) -> ty::Display {
ty::Display::new(&self.tys, &self.files, ty)
}
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#[must_use]
#[track_caller]
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fn assert_ty(&self, pos: Pos, ty: ty::Id, expected: ty::Id, hint: impl Display) -> ty::Id {
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if let Some(res) = ty.try_upcast(expected) {
res
} else {
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let dty = self.ty_display(ty);
let dexpected = self.ty_display(expected);
self.report(pos, format_args!("expected {hint} of type {dexpected}, got {dty}",));
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}
}
fn assert_arg_count(&self, pos: Pos, got: usize, expected: usize, hint: impl Display) {
if got != expected {
let s = if expected != 1 { "s" } else { "" };
self.report(pos, format_args!("{hint} expected {expected} argument{s}, got {got}"))
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}
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}
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fn report_log(&self, pos: Pos, msg: impl std::fmt::Display) {
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let mut out = String::new();
self.cfile().report_to(pos, msg, &mut out);
eprintln!("{out}");
}
#[track_caller]
fn report(&self, pos: Pos, msg: impl std::fmt::Display) -> ! {
self.report_log(pos, msg);
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unreachable!();
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}
#[track_caller]
fn report_unhandled_ast(&self, ast: &Expr, hint: &str) -> ! {
self.report(
ast.pos(),
format_args!(
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"compiler does not (yet) know how to handle ({hint}):\n\
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{ast:}\n\
info for weak people:\n\
{ast:#?}"
),
)
}
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fn cfile(&self) -> &parser::Ast {
&self.files[self.ci.file as usize]
}
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fn pack_args(&mut self, pos: Pos, arg_base: usize) -> ty::Tuple {
let needle = &self.tys.args[arg_base..];
if needle.is_empty() {
return ty::Tuple::empty();
}
let len = needle.len();
// FIXME: maybe later when this becomes a bottleneck we use more
// efficient search (SIMD?, indexing?)
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let sp = self.tys.args.windows(needle.len()).position(|val| val == needle).unwrap();
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self.tys.args.truncate((sp + needle.len()).max(arg_base));
ty::Tuple::new(sp, len)
.unwrap_or_else(|| self.report(pos, "amount of arguments not supported"))
}
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fn cow_reg(&mut self, rhs: reg::Id) -> reg::Id {
if rhs.is_ref() {
let reg = self.ci.regs.allocate();
self.ci.emit(cp(reg.get(), rhs.get()));
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reg
} else {
rhs
}
}
pub fn assemble(&mut self, buf: &mut Vec<u8>) {
self.tys.funcs.iter_mut().for_each(|f| f.offset = u32::MAX);
self.tys.globals.iter_mut().for_each(|g| g.offset = u32::MAX);
self.tys.assemble(buf)
}
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}
#[cfg(test)]
mod tests {
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fn generate(ident: &'static str, input: &'static str, output: &mut String) {
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let mut codegen =
super::Codegen { files: crate::test_parse_files(ident, input), ..Default::default() };
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codegen.generate();
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let mut out = Vec::new();
codegen.assemble(&mut out);
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let mut buf = Vec::<u8>::new();
let err = codegen.tys.disasm(&out, &codegen.files, &mut buf, |_| {});
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output.push_str(String::from_utf8(buf).unwrap().as_str());
if err.is_err() {
return;
}
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crate::test_run_vm(&out, output);
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}
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crate::run_tests! { generate:
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arithmetic;
variables;
functions;
comments;
if_statements;
loops;
//fb_driver;
pointers;
structs;
different_types;
struct_operators;
directives;
global_variables;
generic_types;
generic_functions;
c_strings;
idk;
struct_patterns;
arrays;
struct_return_from_module_function;
//comptime_pointers;
sort_something_viredly;
hex_octal_binary_literals;
//comptime_min_reg_leak;
// structs_in_registers;
comptime_function_from_another_file;
inline;
inline_test;
some_generic_code;
integer_inference_issues;
writing_into_string;
request_page;
tests_ptr_to_ptr_copy;
wide_ret;
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}
}