holey-bytes/lang/src/son.rs

4445 lines
163 KiB
Rust
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use {
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self::var::{Scope, Variable},
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crate::{
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ctx_map::CtxEntry,
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debug,
ident::Ident,
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instrs,
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lexer::{self, TokenKind},
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parser::{
self,
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idfl::{self},
CtorField, Expr, ExprRef, FileId, Pos,
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},
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reg, task,
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ty::{self, Arg, ArrayLen, Loc, Tuple},
vc::{BitSet, Vc},
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Comptime, Func, Global, HashMap, Offset, OffsetIter, PLoc, Reloc, Sig, SymKey, TypeParser,
TypedReloc, Types,
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},
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alloc::{borrow::ToOwned, string::String, vec::Vec},
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core::{
assert_matches::debug_assert_matches,
borrow::Borrow,
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cell::RefCell,
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fmt::{self, Debug, Display, Write},
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format_args as fa, mem,
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ops::{self},
usize,
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},
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hashbrown::hash_map,
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hbbytecode::DisasmError,
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regalloc2::VReg,
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};
const VOID: Nid = 0;
const NEVER: Nid = 1;
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const ENTRY: Nid = 2;
const MEM: Nid = 3;
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type Nid = u16;
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type Lookup = crate::ctx_map::CtxMap<Nid>;
impl crate::ctx_map::CtxEntry for Nid {
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type Ctx = [Result<Node, (Nid, debug::Trace)>];
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type Key<'a> = (Kind, &'a [Nid], ty::Id);
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fn key<'a>(&self, ctx: &'a Self::Ctx) -> Self::Key<'a> {
ctx[*self as usize].as_ref().unwrap().key()
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}
}
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#[derive(Clone)]
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struct Nodes {
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values: Vec<Result<Node, (Nid, debug::Trace)>>,
visited: BitSet,
free: Nid,
lookup: Lookup,
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}
impl Default for Nodes {
fn default() -> Self {
Self {
values: Default::default(),
free: Nid::MAX,
lookup: Default::default(),
visited: Default::default(),
}
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}
}
impl Nodes {
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fn graphviz_low(
&self,
tys: &Types,
files: &[parser::Ast],
out: &mut String,
) -> core::fmt::Result {
use core::fmt::Write;
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writeln!(out)?;
writeln!(out, "digraph G {{")?;
writeln!(out, "rankdir=BT;")?;
writeln!(out, "concentrate=true;")?;
writeln!(out, "compound=true;")?;
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for (i, node) in self.iter() {
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let color = match () {
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_ if node.lock_rc == Nid::MAX => "orange",
_ if node.lock_rc == Nid::MAX - 1 => "blue",
_ if node.lock_rc != 0 => "red",
_ if node.outputs.is_empty() => "purple",
_ if node.is_mem() => "green",
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_ if self.is_cfg(i) => "yellow",
_ => "white",
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};
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let dest = i;
//let mut index_override = None;
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//if !matches!(node.kind, Kind::Then | Kind::Else) {
if node.ty != ty::Id::VOID {
writeln!(
out,
" node{i}[label=\"{i} {} {}\" color={color}]",
node.kind,
ty::Display::new(tys, files, node.ty)
)?;
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} else {
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writeln!(out, " node{i}[label=\"{i} {}\" color={color}]", node.kind,)?;
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}
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//} else {
// dest = node.inputs[0];
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// index_override = if node.kind == Kind::Then { Some(0) } else { Some(1) };
//}
//if node.kind == Kind::If {
// continue;
//}
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for (j, &o) in node.outputs.iter().enumerate() {
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//let j = index_override.unwrap_or(j);
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let color = if self.is_cfg(i) && self.is_cfg(o) { "red" } else { "lightgray" };
let index = self[o].inputs.iter().position(|&inp| i == inp).unwrap();
let style = if index == 0 && !self.is_cfg(o) { "style=dotted" } else { "" };
writeln!(
out,
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" node{o} -> node{dest}[color={color} taillabel={index} headlabel={j} {style}]",
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)?;
}
}
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writeln!(out, "}}")?;
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Ok(())
}
#[allow(dead_code)]
fn graphviz(&self, tys: &Types, files: &[parser::Ast]) {
let out = &mut String::new();
_ = self.graphviz_low(tys, files, out);
log::info!("{out}");
}
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fn graphviz_in_browser(&self, tys: &Types, files: &[parser::Ast]) {
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#[cfg(all(debug_assertions, feature = "std"))]
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{
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let out = &mut String::new();
_ = self.graphviz_low(tys, files, out);
if !std::process::Command::new("brave")
.arg(format!("https://dreampuf.github.io/GraphvizOnline/#{out}"))
.status()
.unwrap()
.success()
{
log::error!("{out}");
}
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}
}
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fn gcm(&mut self) {
self.visited.clear(self.values.len());
push_up(self);
// TODO: handle infinte loops
self.visited.clear(self.values.len());
push_down(self, VOID);
}
fn remove_low(&mut self, id: Nid) -> Node {
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if cfg!(debug_assertions) {
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let value =
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mem::replace(&mut self.values[id as usize], Err((self.free, debug::trace())))
.unwrap();
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self.free = id;
value
} else {
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mem::replace(&mut self.values[id as usize], Err((Nid::MAX, debug::trace()))).unwrap()
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}
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}
fn clear(&mut self) {
self.values.clear();
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self.lookup.clear();
self.free = Nid::MAX;
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}
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fn new_node_nop(&mut self, ty: ty::Id, kind: Kind, inps: impl Into<Vc>) -> Nid {
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let node =
Node { ralloc_backref: u16::MAX, inputs: inps.into(), kind, ty, ..Default::default() };
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if node.kind == Kind::Phi && node.ty != ty::Id::VOID {
debug_assert_ne!(
self[node.inputs[1]].ty,
ty::Id::VOID,
"{:?} {:?}",
self[node.inputs[1]],
node.ty.expand(),
);
if self[node.inputs[0]].kind != Kind::Loop {
debug_assert_ne!(
self[node.inputs[2]].ty,
ty::Id::VOID,
"{:?} {:?}",
self[node.inputs[2]],
node.ty.expand(),
);
}
}
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let mut lookup_meta = None;
if !node.is_not_gvnd() {
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let (raw_entry, hash) = self.lookup.entry(node.key(), &self.values);
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let entry = match raw_entry {
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hash_map::RawEntryMut::Occupied(o) => return o.get_key_value().0.value,
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hash_map::RawEntryMut::Vacant(v) => v,
};
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lookup_meta = Some((entry, hash));
}
if self.free == Nid::MAX {
self.free = self.values.len() as _;
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self.values.push(Err((Nid::MAX, debug::trace())));
}
let free = self.free;
for &d in node.inputs.as_slice() {
debug_assert_ne!(d, free);
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self.values[d as usize].as_mut().unwrap_or_else(|_| panic!("{d}")).outputs.push(free);
}
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self.free = mem::replace(&mut self.values[free as usize], Ok(node)).unwrap_err().0;
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if let Some((entry, hash)) = lookup_meta {
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entry.insert(crate::ctx_map::Key { value: free, hash }, ());
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}
free
}
fn remove_node_lookup(&mut self, target: Nid) {
if !self[target].is_not_gvnd() {
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self.lookup.remove(&target, &self.values).unwrap();
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}
}
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fn new_node_low(&mut self, ty: ty::Id, kind: Kind, inps: impl Into<Vc>) -> (Nid, bool) {
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let id = self.new_node_nop(ty, kind, inps);
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if let Some(opt) = self.peephole(id) {
debug_assert_ne!(opt, id);
self.lock(opt);
self.remove(id);
self.unlock(opt);
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(opt, true)
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} else {
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(id, false)
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}
}
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fn new_node(&mut self, ty: ty::Id, kind: Kind, inps: impl Into<Vc>) -> Nid {
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self.new_node_low(ty, kind, inps).0
}
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fn new_node_lit(&mut self, ty: ty::Id, kind: Kind, inps: impl Into<Vc>) -> Value {
Value::new(self.new_node_low(ty, kind, inps).0).ty(ty)
}
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fn lock(&mut self, target: Nid) {
self[target].lock_rc += 1;
}
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#[track_caller]
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fn unlock(&mut self, target: Nid) {
self[target].lock_rc -= 1;
}
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fn remove(&mut self, target: Nid) -> bool {
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if !self[target].is_dangling() {
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return false;
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}
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debug_assert!(!matches!(self[target].kind, Kind::Call { .. }), "{:?}", self[target]);
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for i in 0..self[target].inputs.len() {
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let inp = self[target].inputs[i];
let index = self[inp].outputs.iter().position(|&p| p == target).unwrap();
self[inp].outputs.swap_remove(index);
self.remove(inp);
}
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self.remove_node_lookup(target);
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self.remove_low(target);
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//std::println!("{target} {}", trace());
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true
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}
fn peephole(&mut self, target: Nid) -> Option<Nid> {
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use {Kind as K, TokenKind as T};
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match self[target].kind {
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K::BinOp { op } => {
let &[ctrl, mut lhs, mut rhs] = self[target].inputs.as_slice() else {
unreachable!()
};
let ty = self[target].ty;
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if let (&K::CInt { value: a }, &K::CInt { value: b }) =
(&self[lhs].kind, &self[rhs].kind)
{
return Some(
self.new_node(ty, K::CInt { value: op.apply_binop(a, b) }, [ctrl]),
);
}
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if lhs == rhs {
match op {
T::Sub => return Some(self.new_node(ty, K::CInt { value: 0 }, [ctrl])),
T::Add => {
let rhs = self.new_node_nop(ty, K::CInt { value: 2 }, [ctrl]);
return Some(
self.new_node(ty, K::BinOp { op: T::Mul }, [ctrl, lhs, rhs]),
);
}
_ => {}
}
}
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// this is more general the pushing constants to left to help deduplicate expressions more
let mut changed = false;
if op.is_comutative() && self[lhs].key() < self[rhs].key() {
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core::mem::swap(&mut lhs, &mut rhs);
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changed = true;
}
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if let K::CInt { value } = self[rhs].kind {
match (op, value) {
(T::Add | T::Sub | T::Shl, 0) | (T::Mul | T::Div, 1) => return Some(lhs),
(T::Mul, 0) => return Some(rhs),
_ => {}
}
}
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if op.is_comutative() && self[lhs].kind == (K::BinOp { op }) {
let &[_, a, b] = self[lhs].inputs.as_slice() else { unreachable!() };
if let K::CInt { value: av } = self[b].kind
&& let K::CInt { value: bv } = self[rhs].kind
{
// (a op #b) op #c => a op (#b op #c)
let new_rhs =
self.new_node_nop(ty, K::CInt { value: op.apply_binop(av, bv) }, [
ctrl,
]);
return Some(self.new_node(ty, K::BinOp { op }, [ctrl, a, new_rhs]));
}
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if self.is_const(b) {
// (a op #b) op c => (a op c) op #b
let new_lhs = self.new_node(ty, K::BinOp { op }, [ctrl, a, rhs]);
return Some(self.new_node(ty, K::BinOp { op }, [ctrl, new_lhs, b]));
}
}
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if op == T::Add
&& self[lhs].kind == (K::BinOp { op: T::Mul })
&& self[lhs].inputs[1] == rhs
&& let K::CInt { value } = self[self[lhs].inputs[2]].kind
{
// a * #n + a => a * (#n + 1)
let new_rhs = self.new_node_nop(ty, K::CInt { value: value + 1 }, [ctrl]);
return Some(self.new_node(ty, K::BinOp { op: T::Mul }, [ctrl, rhs, new_rhs]));
}
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if op == T::Sub
&& self[lhs].kind == (K::BinOp { op: T::Add })
&& let K::CInt { value: a } = self[rhs].kind
&& let K::CInt { value: b } = self[self[lhs].inputs[2]].kind
{
let new_rhs = self.new_node_nop(ty, K::CInt { value: b - a }, [ctrl]);
return Some(self.new_node(ty, K::BinOp { op: T::Add }, [
ctrl,
self[lhs].inputs[1],
new_rhs,
]));
}
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if op == T::Sub && self[lhs].kind == (K::BinOp { op }) {
// (a - b) - c => a - (b + c)
let &[_, a, b] = self[lhs].inputs.as_slice() else { unreachable!() };
let c = rhs;
let new_rhs = self.new_node(ty, K::BinOp { op: T::Add }, [ctrl, b, c]);
return Some(self.new_node(ty, K::BinOp { op }, [ctrl, a, new_rhs]));
}
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if changed {
return Some(self.new_node(ty, self[target].kind, [ctrl, lhs, rhs]));
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}
}
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K::UnOp { op } => {
let &[ctrl, oper] = self[target].inputs.as_slice() else { unreachable!() };
let ty = self[target].ty;
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if let K::CInt { value } = self[oper].kind {
return Some(
self.new_node(ty, K::CInt { value: op.apply_unop(value) }, [ctrl]),
);
}
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}
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K::If => {
let cond = self[target].inputs[1];
if let K::CInt { value } = self[cond].kind {
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let ty = if value == 0 {
ty::Id::LEFT_UNREACHABLE
} else {
ty::Id::RIGHT_UNREACHABLE
};
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return Some(self.new_node_nop(ty, K::If, [self[target].inputs[0], cond]));
}
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}
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K::Phi => {
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let &[ctrl, lhs, rhs] = self[target].inputs.as_slice() else { unreachable!() };
if lhs == rhs {
return Some(lhs);
}
if self[lhs].kind == Kind::Stre
&& self[rhs].kind == Kind::Stre
&& self[lhs].ty == self[rhs].ty
&& self[lhs].inputs[2] == self[rhs].inputs[2]
&& self[lhs].inputs.get(3) == self[rhs].inputs.get(3)
{
let pick_value = self.new_node(self[lhs].ty, Kind::Phi, [
ctrl,
self[lhs].inputs[1],
self[rhs].inputs[1],
]);
let mut vc = Vc::from([VOID, pick_value, self[lhs].inputs[2]]);
for &rest in &self[lhs].inputs[3..] {
vc.push(rest);
}
for &rest in &self[rhs].inputs[4..] {
vc.push(rest);
}
return Some(self.new_node(self[lhs].ty, Kind::Stre, vc));
}
}
K::Stre => {
if self[target].inputs[2] != VOID
&& self[target].inputs.len() == 4
&& self[self[target].inputs[1]].kind != Kind::Load
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&& self[self[target].inputs[3]].kind == Kind::Stre
&& self[self[target].inputs[3]].lock_rc == 0
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&& self[self[target].inputs[3]].inputs[2] == self[target].inputs[2]
{
return Some(self.modify_input(
self[target].inputs[3],
1,
self[target].inputs[1],
));
}
}
K::Load => {
if self[target].inputs.len() == 3
&& self[self[target].inputs[2]].kind == Kind::Stre
&& self[self[target].inputs[2]].inputs[2] == self[target].inputs[1]
&& self[self[target].inputs[2]].ty == self[target].ty
{
return Some(self[self[target].inputs[2]].inputs[1]);
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}
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}
K::Extend => {
if self[target].ty.simple_size() == self[self[target].inputs[1]].ty.simple_size() {
return Some(self[target].inputs[1]);
}
}
K::Loop => {
if self[target].inputs[1] == NEVER {
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self.lock(target);
for o in self[target].outputs.clone() {
if self[o].kind == Kind::Phi {
self.replace(o, self[o].inputs[1]);
}
}
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self.unlock(target);
return Some(self[target].inputs[0]);
}
}
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_ => {}
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}
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None
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}
fn is_const(&self, id: Nid) -> bool {
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matches!(self[id].kind, Kind::CInt { .. })
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}
fn replace(&mut self, target: Nid, with: Nid) {
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let mut back_press = 0;
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for i in 0..self[target].outputs.len() {
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let out = self[target].outputs[i - back_press];
let index = self[out].inputs.iter().position(|&p| p == target).unwrap();
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self.lock(target);
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let prev_len = self[target].outputs.len();
self.modify_input(out, index, with);
back_press += (self[target].outputs.len() != prev_len) as usize;
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self.unlock(target);
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}
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self.remove(target);
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}
fn modify_input(&mut self, target: Nid, inp_index: usize, with: Nid) -> Nid {
self.remove_node_lookup(target);
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debug_assert_ne!(self[target].inputs[inp_index], with);
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let prev = self[target].inputs[inp_index];
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self[target].inputs[inp_index] = with;
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let (entry, hash) = self.lookup.entry(target.key(&self.values), &self.values);
match entry {
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hash_map::RawEntryMut::Occupied(other) => {
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let rpl = other.get_key_value().0.value;
self[target].inputs[inp_index] = prev;
self.lookup.insert(target.key(&self.values), target, &self.values);
self.replace(target, rpl);
rpl
}
hash_map::RawEntryMut::Vacant(slot) => {
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slot.insert(crate::ctx_map::Key { value: target, hash }, ());
let index = self[prev].outputs.iter().position(|&o| o == target).unwrap();
self[prev].outputs.swap_remove(index);
self[with].outputs.push(target);
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self.remove(prev);
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target
}
}
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}
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#[track_caller]
fn unlock_remove(&mut self, id: Nid) -> bool {
self[id].lock_rc -= 1;
self.remove(id)
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}
fn iter(&self) -> impl DoubleEndedIterator<Item = (Nid, &Node)> {
self.values.iter().enumerate().filter_map(|(i, s)| Some((i as _, s.as_ref().ok()?)))
}
#[allow(clippy::format_in_format_args)]
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fn basic_blocks_instr(&mut self, out: &mut String, node: Nid) -> core::fmt::Result {
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if self[node].kind != Kind::Loop && self[node].kind != Kind::Region {
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write!(out, " {node:>2}-c{:>2}: ", self[node].ralloc_backref)?;
}
match self[node].kind {
Kind::Start => unreachable!(),
Kind::End => unreachable!(),
Kind::If => write!(out, " if: "),
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Kind::Region | Kind::Loop => writeln!(out, " goto: {node}"),
Kind::Return => write!(out, " ret: "),
Kind::CInt { value } => write!(out, "cint: #{value:<4}"),
Kind::Phi => write!(out, " phi: "),
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Kind::Arg => write!(
out,
" arg: {:<5}",
self[VOID].outputs.iter().position(|&n| n == node).unwrap() - 2
),
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Kind::BinOp { op } | Kind::UnOp { op } => {
write!(out, "{:>4}: ", op.name())
}
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Kind::Call { func, args: _ } => {
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write!(out, "call: {func} {} ", self[node].depth)
}
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Kind::Global { global } => write!(out, "glob: {global:<5}"),
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Kind::Entry => write!(out, "ctrl: {:<5}", "entry"),
Kind::Then => write!(out, "ctrl: {:<5}", "then"),
Kind::Else => write!(out, "ctrl: {:<5}", "else"),
Kind::Stck => write!(out, "stck: "),
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Kind::Load => write!(out, "load: "),
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Kind::Stre => write!(out, "stre: "),
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Kind::Mem => write!(out, " mem: "),
Kind::Idk => write!(out, " idk: "),
Kind::Extend => write!(out, " ext: "),
}?;
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if self[node].kind != Kind::Loop && self[node].kind != Kind::Region {
writeln!(
out,
" {:<14} {}",
format!("{:?}", self[node].inputs),
format!("{:?}", self[node].outputs)
)?;
}
Ok(())
}
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fn basic_blocks_low(&mut self, out: &mut String, mut node: Nid) -> core::fmt::Result {
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let iter = |nodes: &Nodes, node| nodes[node].outputs.clone().into_iter().rev();
while self.visited.set(node) {
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match self[node].kind {
Kind::Start => {
writeln!(out, "start: {}", self[node].depth)?;
let mut cfg_index = Nid::MAX;
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for o in iter(self, node) {
self.basic_blocks_instr(out, o)?;
if self[o].kind.is_cfg() {
cfg_index = o;
}
}
node = cfg_index;
}
Kind::End => break,
Kind::If => {
self.basic_blocks_low(out, self[node].outputs[0])?;
node = self[node].outputs[1];
}
Kind::Region => {
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writeln!(
out,
"region{node}: {} {} {:?}",
self[node].depth, self[node].loop_depth, self[node].inputs
)?;
let mut cfg_index = Nid::MAX;
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for o in iter(self, node) {
self.basic_blocks_instr(out, o)?;
if self.is_cfg(o) {
cfg_index = o;
}
}
node = cfg_index;
}
Kind::Loop => {
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writeln!(
out,
"loop{node}: {} {} {:?}",
self[node].depth, self[node].loop_depth, self[node].outputs
)?;
let mut cfg_index = Nid::MAX;
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for o in iter(self, node) {
self.basic_blocks_instr(out, o)?;
if self.is_cfg(o) {
cfg_index = o;
}
}
node = cfg_index;
}
Kind::Return => {
node = self[node].outputs[0];
}
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Kind::Then | Kind::Else | Kind::Entry => {
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writeln!(
out,
"b{node}: {} {} {:?}",
self[node].depth, self[node].loop_depth, self[node].outputs
)?;
let mut cfg_index = Nid::MAX;
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for o in iter(self, node) {
self.basic_blocks_instr(out, o)?;
if self.is_cfg(o) {
cfg_index = o;
}
}
node = cfg_index;
}
Kind::Call { .. } => {
let mut cfg_index = Nid::MAX;
let mut print_ret = true;
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for o in iter(self, node) {
if self[o].inputs[0] == node
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&& (self[node].outputs[0] != o || core::mem::take(&mut print_ret))
{
self.basic_blocks_instr(out, o)?;
}
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if self.is_cfg(o) {
cfg_index = o;
}
}
node = cfg_index;
}
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_ => unreachable!(),
}
}
Ok(())
}
fn basic_blocks(&mut self) {
let mut out = String::new();
self.visited.clear(self.values.len());
self.basic_blocks_low(&mut out, VOID).unwrap();
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log::info!("{out}");
}
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fn is_cfg(&self, o: Nid) -> bool {
self[o].kind.is_cfg()
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}
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fn check_final_integrity(&self, tys: &Types, files: &[parser::Ast]) {
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if !cfg!(debug_assertions) {
return;
}
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let mut failed = false;
for (id, node) in self.iter() {
if node.lock_rc != 0 {
log::error!("{} {} {:?}", node.lock_rc, 0, node.kind);
failed = true;
}
if !matches!(node.kind, Kind::End | Kind::Mem | Kind::Arg) && node.outputs.is_empty() {
log::error!("outputs are empry {id} {:?}", node.kind);
failed = true;
}
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// let mut allowed_cfgs = 1 + (node.kind == Kind::If) as usize;
// for &o in node.outputs.iter() {
// if self.is_cfg(i) {
// if allowed_cfgs == 0 && self.is_cfg(o) {
// log::err!(
// "multiple cfg outputs detected: {:?} -> {:?}",
// node.kind,
// self[o].kind
// );
// failed = true;
// } else {
// allowed_cfgs += self.is_cfg(o) as usize;
// }
// }
// let other = match &self.values[o as usize] {
// Ok(other) => other,
// Err(_) => {
// log::err!("the edge points to dropped node: {i} {:?} {o}", node.kind,);
// failed = true;
// continue;
// }
// };
// let occurs = self[o].inputs.iter().filter(|&&el| el == i).count();
// let self_occurs = self[i].outputs.iter().filter(|&&el| el == o).count();
// if occurs != self_occurs {
// log::err!(
// "the edge is not bidirectional: {i} {:?} {self_occurs} {o} {:?} {occurs}",
// node.kind,
// other.kind
// );
// failed = true;
// }
// }
}
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if failed {
self.graphviz_in_browser(tys, files);
panic!()
}
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}
#[expect(dead_code)]
fn climb_expr(&mut self, from: Nid, mut for_each: impl FnMut(Nid, &Node) -> bool) -> bool {
fn climb_impl(
nodes: &mut Nodes,
from: Nid,
for_each: &mut impl FnMut(Nid, &Node) -> bool,
) -> bool {
for i in 0..nodes[from].inputs.len() {
let n = nodes[from].inputs[i];
if n != Nid::MAX
&& nodes.visited.set(n)
&& !nodes.is_cfg(n)
&& (for_each(n, &nodes[n]) || climb_impl(nodes, n, for_each))
{
return true;
}
}
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false
}
self.visited.clear(self.values.len());
climb_impl(self, from, &mut for_each)
}
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fn late_peephole(&mut self, target: Nid) -> Nid {
if let Some(id) = self.peephole(target) {
self.replace(target, id);
return id;
}
target
}
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fn load_loop_var(&mut self, index: usize, value: &mut Variable, loops: &mut [Loop]) {
self.load_loop_value(&mut |l| l.scope.iter_mut().nth(index).unwrap(), value, loops);
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}
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fn load_loop_store(&mut self, value: &mut Variable, loops: &mut [Loop]) {
self.load_loop_value(&mut |l| &mut l.scope.store, value, loops);
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}
fn load_loop_value(
&mut self,
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get_lvalue: &mut impl FnMut(&mut Loop) -> &mut Variable,
var: &mut Variable,
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loops: &mut [Loop],
) {
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if var.value() != VOID {
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return;
}
let [loops @ .., loob] = loops else { unreachable!() };
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let node = loob.node;
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let lvar = get_lvalue(loob);
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self.load_loop_value(get_lvalue, lvar, loops);
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if !self[lvar.value()].is_lazy_phi(node) {
let inps = [node, lvar.value(), VOID];
lvar.set_value(self.new_node_nop(lvar.ty, Kind::Phi, inps), self);
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}
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var.set_value(lvar.value(), self);
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}
fn check_dominance(&mut self, nd: Nid, min: Nid, check_outputs: bool) {
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if !cfg!(debug_assertions) {
return;
}
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let node = self[nd].clone();
for &i in node.inputs.iter() {
let dom = idom(self, i);
debug_assert!(
self.dominates(dom, min),
"{dom} {min} {node:?} {:?}",
self.basic_blocks()
);
}
if check_outputs {
for &o in node.outputs.iter() {
let dom = use_block(nd, o, self);
debug_assert!(
self.dominates(min, dom),
"{min} {dom} {node:?} {:?}",
self.basic_blocks()
);
}
}
}
fn dominates(&mut self, dominator: Nid, mut dominated: Nid) -> bool {
loop {
if dominator == dominated {
break true;
}
if idepth(self, dominator) > idepth(self, dominated) {
break false;
}
dominated = idom(self, dominated);
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}
}
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#[expect(dead_code)]
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fn iter_mut(&mut self) -> impl Iterator<Item = &mut Node> {
self.values.iter_mut().flat_map(Result::as_mut)
}
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#[allow(dead_code)]
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fn eliminate_stack_temporaries(&mut self) {
'o: for stack in self[MEM].outputs.clone() {
if self.values[stack as usize].is_err() || self[stack].kind != Kind::Stck {
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continue;
}
let mut full_read_into = None;
let mut unidentifed = Vc::default();
for &o in self[stack].outputs.iter() {
match self[o].kind {
Kind::Load
if self[o].ty == self[stack].ty
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&& self[o].outputs.iter().all(|&n| self[n].kind == Kind::Stre)
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&& let mut full_stores = self[o].outputs.iter().filter(|&&n| {
self[n].kind == Kind::Stre && self[n].inputs[1] == o
})
&& let Some(&n) = full_stores.next()
&& full_stores.next().is_none() =>
{
if full_read_into.replace(n).is_some() {
continue 'o;
}
}
_ => unidentifed.push(o),
}
}
let Some(dst) = full_read_into else { continue };
let mut saved = Vc::default();
let mut cursor = dst;
cursor = *self[cursor].inputs.get(3).unwrap_or(&MEM);
while cursor != MEM && self[cursor].kind == Kind::Stre {
let mut contact_point = cursor;
let mut region = self[cursor].inputs[2];
if let Kind::BinOp { op } = self[region].kind {
debug_assert_matches!(op, TokenKind::Add | TokenKind::Sub);
contact_point = region;
region = self[region].inputs[1]
}
if region != stack {
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break;
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}
let Some(index) = unidentifed.iter().position(|&n| n == contact_point) else {
continue 'o;
};
unidentifed.remove(index);
saved.push(contact_point);
cursor = *self[cursor].inputs.get(3).unwrap_or(&MEM);
if unidentifed.is_empty() {
break;
}
}
if !unidentifed.is_empty() {
continue;
}
// FIXME: when the loads and stores become parallel we will need to get saved
// differently
let region = self[dst].inputs[2];
for mut oper in saved.into_iter().rev() {
let mut region = region;
if let Kind::BinOp { op } = self[oper].kind {
debug_assert_eq!(self[oper].outputs.len(), 1);
debug_assert_eq!(self[self[oper].outputs[0]].kind, Kind::Stre);
region = self.new_node(self[oper].ty, Kind::BinOp { op }, [
VOID,
region,
self[oper].inputs[2],
]);
oper = self[oper].outputs[0];
}
self.modify_input(oper, 2, region);
}
self.replace(dst, *self[dst].inputs.get(3).unwrap_or(&MEM));
if self.values[stack as usize].is_ok() {
self.lock(stack);
}
if self.values[dst as usize].is_ok() {
self.lock(dst);
}
}
}
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}
impl ops::Index<Nid> for Nodes {
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type Output = Node;
fn index(&self, index: Nid) -> &Self::Output {
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self.values[index as usize].as_ref().unwrap_or_else(|(_, bt)| panic!("{index} {bt:#?}"))
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}
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}
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impl ops::IndexMut<Nid> for Nodes {
fn index_mut(&mut self, index: Nid) -> &mut Self::Output {
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self.values[index as usize].as_mut().unwrap_or_else(|(_, bt)| panic!("{index} {bt:#?}"))
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}
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}
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#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash, PartialOrd, Ord, Default)]
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#[repr(u8)]
pub enum Kind {
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#[default]
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Start,
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// [ctrl]
Entry,
Mem,
// [terms...]
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End,
// [ctrl, cond]
If,
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Then,
Else,
// [lhs, rhs]
Region,
// [entry, back]
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Loop,
// [ctrl, ?value]
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Return,
// [ctrl]
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CInt {
value: i64,
},
// [ctrl, lhs, rhs]
Phi,
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Arg,
// [ctrl, oper]
Extend,
// [ctrl, oper]
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UnOp {
op: lexer::TokenKind,
},
// [ctrl, lhs, rhs]
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BinOp {
op: lexer::TokenKind,
},
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// [ctrl]
Global {
global: ty::Global,
},
// [ctrl, ...args]
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Call {
func: ty::Func,
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args: ty::Tuple,
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},
// [ctrl]
Idk,
// [ctrl]
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Stck,
// [ctrl, memory]
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Load,
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// [ctrl, value, memory]
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Stre,
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}
impl Kind {
fn is_pinned(&self) -> bool {
self.is_cfg() || matches!(self, Self::Phi | Self::Arg | Self::Mem)
}
fn is_cfg(&self) -> bool {
matches!(
self,
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Self::Start
| Self::End
| Self::Return
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| Self::Entry
| Self::Then
| Self::Else
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| Self::Call { .. }
| Self::If
| Self::Region
| Self::Loop
)
}
fn ends_basic_block(&self) -> bool {
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matches!(self, Self::Return | Self::If | Self::End)
}
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}
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impl fmt::Display for Kind {
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fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
match self {
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Kind::CInt { value } => write!(f, "#{value}"),
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Kind::Entry => write!(f, "ctrl[entry]"),
Kind::Then => write!(f, "ctrl[then]"),
Kind::Else => write!(f, "ctrl[else]"),
Kind::BinOp { op } => write!(f, "{op}"),
Kind::Call { func, .. } => write!(f, "call {func}"),
slf => write!(f, "{slf:?}"),
}
}
}
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#[derive(Debug, Default, Clone)]
//#[repr(align(64))]
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pub struct Node {
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kind: Kind,
inputs: Vc,
outputs: Vc,
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ty: ty::Id,
offset: Offset,
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ralloc_backref: RallocBRef,
depth: IDomDepth,
lock_rc: LockRc,
loop_depth: LoopDepth,
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}
impl Node {
fn is_dangling(&self) -> bool {
self.outputs.len() + self.lock_rc as usize == 0
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}
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fn key(&self) -> (Kind, &[Nid], ty::Id) {
(self.kind, &self.inputs, self.ty)
}
fn is_lazy_phi(&self, loob: Nid) -> bool {
self.kind == Kind::Phi && self.inputs[2] == 0 && self.inputs[0] == loob
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}
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fn is_not_gvnd(&self) -> bool {
(self.kind == Kind::Phi && self.inputs[2] == 0)
|| matches!(self.kind, Kind::Arg | Kind::Stck)
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}
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fn is_mem(&self) -> bool {
matches!(self.kind, Kind::Stre | Kind::Load | Kind::Stck)
}
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}
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type RallocBRef = u16;
type LoopDepth = u16;
type LockRc = u16;
type IDomDepth = u16;
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#[derive(Clone)]
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struct Loop {
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node: Nid,
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ctrl: [Nid; 2],
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ctrl_scope: [Scope; 2],
scope: Scope,
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}
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mod var {
use {
super::{Kind, Nid, Nodes},
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crate::{debug, ident::Ident, ty},
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alloc::vec::Vec,
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};
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// makes sure value inside is laways locked for this instance of variable
#[derive(Default, Clone)]
pub struct Variable {
pub id: Ident,
pub ty: ty::Id,
pub ptr: bool,
value: Nid,
}
impl Variable {
pub fn new(id: Ident, ty: ty::Id, ptr: bool, value: Nid, nodes: &mut Nodes) -> Self {
nodes.lock(value);
Self { id, ty, ptr, value }
}
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pub fn value(&self) -> Nid {
self.value
}
pub fn set_value(&mut self, mut new_value: Nid, nodes: &mut Nodes) -> Nid {
nodes.unlock(self.value);
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core::mem::swap(&mut self.value, &mut new_value);
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nodes.lock(self.value);
new_value
}
pub fn dup(&self, nodes: &mut Nodes) -> Self {
nodes.lock(self.value);
Self { id: self.id, ty: self.ty, ptr: self.ptr, value: self.value }
}
pub fn remove(self, nodes: &mut Nodes) {
nodes.unlock_remove(self.value);
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core::mem::forget(self);
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}
pub fn set_value_remove(&mut self, new_value: Nid, nodes: &mut Nodes) {
let old = self.set_value(new_value, nodes);
nodes.remove(old);
}
pub fn remove_ignore_arg(self, nodes: &mut Nodes) {
if nodes[self.value].kind == Kind::Arg {
nodes.unlock(self.value);
} else {
nodes.unlock_remove(self.value);
}
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core::mem::forget(self);
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}
}
impl Drop for Variable {
fn drop(&mut self) {
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if self.ty != ty::Id::UNDECLARED && !debug::panicking() {
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panic!("variable unproperly deinitialized")
}
}
}
#[derive(Default, Clone)]
pub struct Scope {
pub vars: Vec<Variable>,
pub loads: Vec<Nid>,
pub store: Variable,
}
impl Scope {
pub fn iter_mut(&mut self) -> impl Iterator<Item = &mut Variable> {
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core::iter::once(&mut self.store).chain(self.vars.iter_mut())
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}
pub fn dup(&self, nodes: &mut Nodes) -> Self {
Self {
vars: self.vars.iter().map(|v| v.dup(nodes)).collect(),
loads: self.loads.iter().copied().inspect(|&l| nodes.lock(l)).collect(),
store: self.store.dup(nodes),
}
}
pub fn clear(&mut self, nodes: &mut Nodes) {
self.vars.drain(..).for_each(|n| n.remove(nodes));
self.loads.drain(..).for_each(|l| _ = nodes.unlock_remove(l));
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core::mem::take(&mut self.store).remove(nodes);
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}
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}
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}
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#[derive(Default, Clone)]
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struct ItemCtx {
file: FileId,
ret: Option<ty::Id>,
task_base: usize,
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inline_var_base: usize,
inline_depth: u16,
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inline_ret: Option<(Value, Nid, Scope)>,
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nodes: Nodes,
ctrl: Nid,
call_count: u16,
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loops: Vec<Loop>,
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scope: Scope,
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ret_relocs: Vec<Reloc>,
relocs: Vec<TypedReloc>,
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jump_relocs: Vec<(Nid, Reloc)>,
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code: Vec<u8>,
}
impl ItemCtx {
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fn init(&mut self, file: FileId, ret: Option<ty::Id>, task_base: usize) {
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debug_assert_eq!(self.loops.len(), 0);
debug_assert_eq!(self.scope.vars.len(), 0);
debug_assert_eq!(self.ret_relocs.len(), 0);
debug_assert_eq!(self.relocs.len(), 0);
debug_assert_eq!(self.jump_relocs.len(), 0);
debug_assert_eq!(self.code.len(), 0);
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self.call_count = 0;
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self.file = file;
self.ret = ret;
self.task_base = task_base;
self.nodes.clear();
self.scope.vars.clear();
let start = self.nodes.new_node(ty::Id::VOID, Kind::Start, []);
debug_assert_eq!(start, VOID);
let end = self.nodes.new_node(ty::Id::NEVER, Kind::End, []);
debug_assert_eq!(end, NEVER);
self.nodes.lock(end);
self.ctrl = self.nodes.new_node(ty::Id::VOID, Kind::Entry, [VOID]);
debug_assert_eq!(self.ctrl, ENTRY);
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self.nodes.lock(self.ctrl);
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let mem = self.nodes.new_node(ty::Id::VOID, Kind::Mem, [VOID]);
debug_assert_eq!(mem, MEM);
self.nodes.lock(mem);
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self.scope.store = Variable::new(0, ty::Id::VOID, false, MEM, &mut self.nodes);
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}
fn finalize(&mut self) {
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self.scope.clear(&mut self.nodes);
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self.nodes.unlock(NEVER);
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self.nodes.unlock(ENTRY);
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self.nodes.unlock(MEM);
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self.nodes.eliminate_stack_temporaries();
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}
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fn emit(&mut self, instr: (usize, [u8; instrs::MAX_SIZE])) {
crate::emit(&mut self.code, instr);
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}
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fn emit_body_code(&mut self, sig: Sig, tys: &Types, files: &[parser::Ast]) -> usize {
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let mut nodes = core::mem::take(&mut self.nodes);
let fuc = Function::new(&mut nodes, tys, sig);
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let mut ralloc = Regalloc::default(); // TODO: reuse
log::info!("{:?}", fuc);
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if self.call_count != 0 {
core::mem::swap(
&mut ralloc.env.preferred_regs_by_class,
&mut ralloc.env.non_preferred_regs_by_class,
);
};
let options = regalloc2::RegallocOptions {
verbose_log: false,
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validate_ssa: cfg!(debug_assertions),
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algorithm: regalloc2::Algorithm::Ion,
};
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regalloc2::run_with_ctx(&fuc, &ralloc.env, &options, &mut ralloc.ctx).unwrap_or_else(
|err| {
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if let regalloc2::RegAllocError::SSA(vreg, inst) = err {
fuc.nodes[vreg.vreg() as Nid].lock_rc = Nid::MAX;
fuc.nodes[fuc.instrs[inst.index()].nid].lock_rc = Nid::MAX - 1;
}
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fuc.nodes.graphviz_in_browser(tys, files);
panic!("{err}")
},
);
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if self.call_count != 0 {
core::mem::swap(
&mut ralloc.env.preferred_regs_by_class,
&mut ralloc.env.non_preferred_regs_by_class,
);
};
let mut saved_regs = HashMap::<u8, u8>::default();
let mut atr = |allc: regalloc2::Allocation| {
debug_assert!(allc.is_reg());
let hvenc = regalloc2::PReg::from_index(allc.index()).hw_enc() as u8;
if hvenc <= 12 {
return hvenc;
}
let would_insert = saved_regs.len() as u8 + reg::RET_ADDR + 1;
*saved_regs.entry(hvenc).or_insert(would_insert)
};
let (retl, mut parama) = tys.parama(sig.ret);
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let mut typs = sig.args.args();
let mut args = fuc.nodes[VOID].outputs[2..].iter();
while let Some(aty) = typs.next(tys) {
let Arg::Value(ty) = aty else { continue };
let Some(loc) = parama.next(ty, tys) else { continue };
let &arg = args.next().unwrap();
let (rg, size) = match loc {
PLoc::WideReg(rg, size) => (rg, size),
PLoc::Reg(rg, size) if ty.loc(tys) == Loc::Stack => (rg, size),
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PLoc::Reg(..) | PLoc::Ref(..) => continue,
};
self.emit(instrs::st(rg, reg::STACK_PTR, fuc.nodes[arg].offset as _, size));
self.emit(instrs::addi64(rg, reg::STACK_PTR, fuc.nodes[arg].offset as _));
}
for (i, block) in fuc.blocks.iter().enumerate() {
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let blk = regalloc2::Block(i as _);
fuc.nodes[block.nid].offset = self.code.len() as _;
for instr_or_edit in ralloc.ctx.output.block_insts_and_edits(&fuc, blk) {
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let inst = match instr_or_edit {
regalloc2::InstOrEdit::Inst(inst) => inst,
regalloc2::InstOrEdit::Edit(&regalloc2::Edit::Move { from, to }) => {
self.emit(instrs::cp(atr(to), atr(from)));
continue;
}
};
let nid = fuc.instrs[inst.index()].nid;
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if nid == NEVER {
continue;
};
let allocs = ralloc.ctx.output.inst_allocs(inst);
let node = &fuc.nodes[nid];
let mut extend = |base: ty::Id, dest: ty::Id, from: usize, to: usize| {
if base.simple_size() == dest.simple_size() {
return Default::default();
}
match (base.is_signed(), dest.is_signed()) {
(true, true) => {
let op = [instrs::sxt8, instrs::sxt16, instrs::sxt32]
[base.simple_size().unwrap().ilog2() as usize];
op(atr(allocs[to]), atr(allocs[from]))
}
_ => {
let mask = (1u64 << (base.simple_size().unwrap() * 8)) - 1;
instrs::andi(atr(allocs[to]), atr(allocs[from]), mask)
}
}
};
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match node.kind {
Kind::If => {
let &[_, cnd] = node.inputs.as_slice() else { unreachable!() };
if let Kind::BinOp { op } = fuc.nodes[cnd].kind
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&& let Some((op, swapped)) =
op.cond_op(fuc.nodes[fuc.nodes[cnd].inputs[1]].ty.is_signed())
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{
let &[lhs, rhs] = allocs else { unreachable!() };
let &[_, lh, rh] = fuc.nodes[cnd].inputs.as_slice() else {
unreachable!()
};
self.emit(extend(fuc.nodes[lh].ty, fuc.nodes[lh].ty.extend(), 0, 0));
self.emit(extend(fuc.nodes[rh].ty, fuc.nodes[rh].ty.extend(), 1, 1));
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let rel = Reloc::new(self.code.len(), 3, 2);
self.jump_relocs.push((node.outputs[!swapped as usize], rel));
self.emit(op(atr(lhs), atr(rhs), 0));
} else {
self.emit(extend(fuc.nodes[cnd].ty, fuc.nodes[cnd].ty.extend(), 0, 0));
let rel = Reloc::new(self.code.len(), 3, 2);
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self.jump_relocs.push((node.outputs[0], rel));
self.emit(instrs::jne(atr(allocs[0]), reg::ZERO, 0));
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}
}
Kind::Loop | Kind::Region => {
if node.ralloc_backref as usize != i + 1 {
let rel = Reloc::new(self.code.len(), 1, 4);
self.jump_relocs.push((nid, rel));
self.emit(instrs::jmp(0));
}
}
Kind::Return => {
match retl {
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Some(PLoc::Reg(r, size)) if sig.ret.loc(tys) == Loc::Stack => {
self.emit(instrs::ld(r, atr(allocs[0]), 0, size))
}
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None | Some(PLoc::Reg(..)) => {}
Some(PLoc::WideReg(r, size)) => {
self.emit(instrs::ld(r, atr(allocs[0]), 0, size))
}
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Some(PLoc::Ref(_, size)) => {
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let [src, dst] = [atr(allocs[0]), atr(allocs[1])];
if let Ok(size) = u16::try_from(size) {
self.emit(instrs::bmc(src, dst, size));
} else {
for _ in 0..size / u16::MAX as u32 {
self.emit(instrs::bmc(src, dst, u16::MAX));
self.emit(instrs::addi64(src, src, u16::MAX as _));
self.emit(instrs::addi64(dst, dst, u16::MAX as _));
}
self.emit(instrs::bmc(src, dst, size as u16));
self.emit(instrs::addi64(src, src, size.wrapping_neg() as _));
self.emit(instrs::addi64(dst, dst, size.wrapping_neg() as _));
}
}
}
if i != fuc.blocks.len() - 1 {
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let rel = Reloc::new(self.code.len(), 1, 4);
self.ret_relocs.push(rel);
self.emit(instrs::jmp(0));
}
}
Kind::CInt { value } => {
self.emit(instrs::li64(atr(allocs[0]), value as _));
}
Kind::Extend => {
let base = fuc.nodes[node.inputs[1]].ty;
let dest = node.ty;
self.emit(extend(base, dest, 1, 0))
}
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Kind::UnOp { op } => {
let op = op.unop().expect("TODO: unary operator not supported");
let &[dst, oper] = allocs else { unreachable!() };
self.emit(op(atr(dst), atr(oper)));
}
Kind::BinOp { .. } if node.lock_rc != 0 => {}
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Kind::BinOp { op } => {
let &[.., rhs] = node.inputs.as_slice() else { unreachable!() };
if let Kind::CInt { value } = fuc.nodes[rhs].kind
&& fuc.nodes[rhs].lock_rc != 0
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&& let Some(op) =
op.imm_binop(node.ty.is_signed(), fuc.tys.size_of(node.ty))
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{
let &[dst, lhs] = allocs else { unreachable!() };
self.emit(op(atr(dst), atr(lhs), value as _));
} else if let Some(op) =
op.binop(node.ty.is_signed(), fuc.tys.size_of(node.ty))
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{
let &[dst, lhs, rhs] = allocs else { unreachable!() };
self.emit(op(atr(dst), atr(lhs), atr(rhs)));
} else if let Some(against) = op.cmp_against() {
let &[_, lh, rh] = node.inputs.as_slice() else { unreachable!() };
self.emit(extend(fuc.nodes[lh].ty, fuc.nodes[lh].ty.extend(), 0, 0));
self.emit(extend(fuc.nodes[rh].ty, fuc.nodes[rh].ty.extend(), 1, 1));
let signed = fuc.nodes[lh].ty.is_signed();
let op_fn = if signed { instrs::cmps } else { instrs::cmpu };
let &[dst, lhs, rhs] = allocs else { unreachable!() };
self.emit(op_fn(atr(dst), atr(lhs), atr(rhs)));
self.emit(instrs::cmpui(atr(dst), atr(dst), against));
if matches!(op, TokenKind::Eq | TokenKind::Lt | TokenKind::Gt) {
self.emit(instrs::not(atr(dst), atr(dst)));
}
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}
}
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Kind::Call { args, func } => {
let (ret, mut parama) = tys.parama(node.ty);
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let has_ret = ret.is_some() as usize;
let mut args = args.args();
let mut allocs = allocs[has_ret..].iter();
while let Some(arg) = args.next(tys) {
let Arg::Value(ty) = arg else { continue };
let Some(loc) = parama.next(ty, tys) else { continue };
let &arg = allocs.next().unwrap();
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let (rg, size) = match loc {
PLoc::Reg(rg, size) if ty.loc(tys) == Loc::Stack => (rg, size),
PLoc::WideReg(rg, size) => (rg, size),
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PLoc::Ref(..) | PLoc::Reg(..) => continue,
};
self.emit(instrs::ld(rg, atr(arg), 0, size));
}
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debug_assert!(
!matches!(ret, Some(PLoc::Ref(..))) || allocs.next().is_some()
);
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if func == ty::ECA {
self.emit(instrs::eca());
} else {
self.relocs.push(TypedReloc {
target: ty::Kind::Func(func).compress(),
reloc: Reloc::new(self.code.len(), 3, 4),
});
self.emit(instrs::jal(reg::RET_ADDR, reg::ZERO, 0));
}
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if let Some(PLoc::WideReg(r, size)) = ret {
let stck = fuc.nodes[*node.inputs.last().unwrap()].offset;
self.emit(instrs::st(r, reg::STACK_PTR, stck as _, size));
}
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if let Some(PLoc::Reg(r, size)) = ret
&& node.ty.loc(tys) == Loc::Stack
{
let stck = fuc.nodes[*node.inputs.last().unwrap()].offset;
self.emit(instrs::st(r, reg::STACK_PTR, stck as _, size));
}
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}
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Kind::Global { global } => {
let reloc = Reloc::new(self.code.len(), 3, 4);
self.relocs.push(TypedReloc {
target: ty::Kind::Global(global).compress(),
reloc,
});
self.emit(instrs::lra(atr(allocs[0]), 0, 0));
}
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Kind::Stck => {
let base = reg::STACK_PTR;
let offset = fuc.nodes[nid].offset;
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self.emit(instrs::addi64(atr(allocs[0]), base, offset as _));
}
Kind::Idk => {}
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Kind::Load => {
let mut region = node.inputs[1];
let mut offset = 0;
if fuc.nodes[region].kind == (Kind::BinOp { op: TokenKind::Add })
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&& let Kind::CInt { value } =
fuc.nodes[fuc.nodes[region].inputs[2]].kind
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{
region = fuc.nodes[region].inputs[1];
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offset = value as Offset;
}
let size = tys.size_of(node.ty);
if node.ty.loc(tys) != Loc::Stack {
let (base, offset) = match fuc.nodes[region].kind {
Kind::Stck => (reg::STACK_PTR, fuc.nodes[region].offset + offset),
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_ => (atr(allocs[1]), offset),
};
self.emit(instrs::ld(atr(allocs[0]), base, offset as _, size as _));
}
}
Kind::Stre if node.inputs[2] == VOID => {}
Kind::Stre => {
let mut region = node.inputs[2];
let mut offset = 0;
let size = u16::try_from(tys.size_of(node.ty)).expect("TODO");
if fuc.nodes[region].kind == (Kind::BinOp { op: TokenKind::Add })
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&& let Kind::CInt { value } =
fuc.nodes[fuc.nodes[region].inputs[2]].kind
&& node.ty.loc(tys) == Loc::Reg
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{
region = fuc.nodes[region].inputs[1];
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offset = value as Offset;
}
let nd = &fuc.nodes[region];
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let (base, offset, src) = match nd.kind {
Kind::Stck if node.ty.loc(tys) == Loc::Reg => {
(reg::STACK_PTR, nd.offset + offset, allocs[0])
}
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_ => (atr(allocs[0]), offset, allocs[1]),
};
match node.ty.loc(tys) {
Loc::Reg => self.emit(instrs::st(atr(src), base, offset as _, size)),
Loc::Stack => {
debug_assert_eq!(offset, 0);
self.emit(instrs::bmc(atr(src), base, size))
}
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}
}
Kind::Start
| Kind::Entry
| Kind::Mem
| Kind::End
| Kind::Then
| Kind::Else
| Kind::Phi
| Kind::Arg => unreachable!(),
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}
}
}
self.nodes = nodes;
saved_regs.len()
}
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fn emit_body(&mut self, tys: &mut Types, files: &[parser::Ast], sig: Sig) {
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self.nodes.check_final_integrity(tys, files);
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self.nodes.graphviz(tys, files);
self.nodes.gcm();
self.nodes.basic_blocks();
self.nodes.graphviz(tys, files);
debug_assert!(self.code.is_empty());
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let tail = core::mem::take(&mut self.call_count) == 0;
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'_open_function: {
self.emit(instrs::addi64(reg::STACK_PTR, reg::STACK_PTR, 0));
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self.emit(instrs::st(reg::RET_ADDR + tail as u8, reg::STACK_PTR, 0, 0));
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}
let mut stack_size = 0;
'_compute_stack: {
let mems = core::mem::take(&mut self.nodes[MEM].outputs);
for &stck in mems.iter() {
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if !matches!(self.nodes[stck].kind, Kind::Stck | Kind::Arg) {
debug_assert_matches!(
self.nodes[stck].kind,
Kind::Phi | Kind::Return | Kind::Load | Kind::Call { .. } | Kind::Stre
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);
continue;
}
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stack_size += tys.size_of(self.nodes[stck].ty);
self.nodes[stck].offset = stack_size;
}
for &stck in mems.iter() {
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if !matches!(self.nodes[stck].kind, Kind::Stck | Kind::Arg) {
continue;
}
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self.nodes[stck].offset = stack_size - self.nodes[stck].offset;
}
self.nodes[MEM].outputs = mems;
}
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let saved = self.emit_body_code(sig, tys, files);
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if let Some(last_ret) = self.ret_relocs.last()
&& last_ret.offset as usize == self.code.len() - 5
&& self
.jump_relocs
.last()
.map_or(true, |&(r, _)| self.nodes[r].offset as usize != self.code.len())
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{
self.code.truncate(self.code.len() - 5);
self.ret_relocs.pop();
}
// FIXME: maybe do this incrementally
for (nd, rel) in self.jump_relocs.drain(..) {
let offset = self.nodes[nd].offset;
//debug_assert!(offset < self.code.len() as u32 - 1);
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rel.apply_jump(&mut self.code, offset, 0);
}
let end = self.code.len();
for ret_rel in self.ret_relocs.drain(..) {
ret_rel.apply_jump(&mut self.code, end as _, 0);
}
let mut stripped_prelude_size = 0;
'_close_function: {
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let pushed = (saved as i64 + !tail as i64) * 8;
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let stack = stack_size as i64;
match (pushed, stack) {
(0, 0) => {
stripped_prelude_size = instrs::addi64(0, 0, 0).0 + instrs::st(0, 0, 0, 0).0;
self.code.drain(0..stripped_prelude_size);
break '_close_function;
}
(0, stack) => {
write_reloc(&mut self.code, 3, -stack, 8);
stripped_prelude_size = instrs::st(0, 0, 0, 0).0;
let end = instrs::addi64(0, 0, 0).0 + instrs::st(0, 0, 0, 0).0;
self.code.drain(instrs::addi64(0, 0, 0).0..end);
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self.emit(instrs::addi64(reg::STACK_PTR, reg::STACK_PTR, stack as _));
break '_close_function;
}
_ => {}
}
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 + tail as u8,
reg::STACK_PTR,
stack as _,
pushed as _,
));
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self.emit(instrs::addi64(reg::STACK_PTR, reg::STACK_PTR, (pushed + stack) as _));
}
self.relocs.iter_mut().for_each(|r| r.reloc.offset -= stripped_prelude_size as u32);
self.emit(instrs::jala(reg::ZERO, reg::RET_ADDR, 0));
}
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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]);
}
struct FTask {
file: FileId,
id: ty::Func,
}
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#[derive(Default, Debug)]
struct Ctx {
ty: Option<ty::Id>,
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}
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impl Ctx {
pub fn with_ty(self, ty: impl Into<ty::Id>) -> Self {
Self { ty: Some(ty.into()) }
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}
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}
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#[derive(Default)]
struct Pool {
cis: Vec<ItemCtx>,
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used_cis: usize,
}
impl Pool {
pub fn push_ci(
&mut self,
file: FileId,
ret: Option<ty::Id>,
task_base: usize,
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target: &mut ItemCtx,
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) {
if let Some(slot) = self.cis.get_mut(self.used_cis) {
core::mem::swap(slot, target);
} else {
self.cis.push(ItemCtx::default());
core::mem::swap(self.cis.last_mut().unwrap(), target);
}
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target.init(file, ret, task_base);
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self.used_cis += 1;
}
pub fn pop_ci(&mut self, target: &mut ItemCtx) {
self.used_cis -= 1;
core::mem::swap(&mut self.cis[self.used_cis], target);
}
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fn save_ci(&mut self, ci: &ItemCtx) {
if let Some(slot) = self.cis.get_mut(self.used_cis) {
slot.clone_from(ci);
} else {
self.cis.push(ci.clone());
}
self.used_cis += 1;
}
fn restore_ci(&mut self, dst: &mut ItemCtx) {
self.used_cis -= 1;
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dst.scope.clear(&mut dst.nodes);
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*dst = core::mem::take(&mut self.cis[self.used_cis]);
}
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}
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struct Regalloc {
env: regalloc2::MachineEnv,
ctx: regalloc2::Ctx,
}
impl Default for Regalloc {
fn default() -> Self {
Self {
env: regalloc2::MachineEnv {
preferred_regs_by_class: [
(1..13).map(|i| regalloc2::PReg::new(i, regalloc2::RegClass::Int)).collect(),
vec![],
vec![],
],
non_preferred_regs_by_class: [
(13..64).map(|i| regalloc2::PReg::new(i, regalloc2::RegClass::Int)).collect(),
vec![],
vec![],
],
scratch_by_class: Default::default(),
fixed_stack_slots: Default::default(),
},
ctx: Default::default(),
}
}
}
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#[derive(Default, Clone, Copy, PartialEq, Eq, Debug)]
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struct Value {
ty: ty::Id,
var: bool,
ptr: bool,
id: Nid,
}
impl Value {
const NEVER: Option<Value> =
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Some(Self { ty: ty::Id::NEVER, var: false, ptr: false, id: NEVER });
const VOID: Value = Self { ty: ty::Id::VOID, var: false, ptr: false, id: VOID };
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pub fn new(id: Nid) -> Self {
Self { id, ..Default::default() }
}
pub fn var(id: usize) -> Self {
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Self { id: u16::MAX - (id as Nid), var: true, ..Default::default() }
}
pub fn ptr(id: Nid) -> Self {
Self { id, ptr: true, ..Default::default() }
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}
#[inline(always)]
pub fn ty(self, ty: impl Into<ty::Id>) -> Self {
Self { ty: ty.into(), ..self }
}
}
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#[derive(Default)]
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pub struct Codegen<'a> {
pub files: &'a [parser::Ast],
pub errors: RefCell<String>,
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tasks: Vec<Option<FTask>>,
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tys: Types,
ci: ItemCtx,
pool: Pool,
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#[expect(dead_code)]
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ralloc: Regalloc,
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ct: Comptime,
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}
impl TypeParser for Codegen<'_> {
fn tys(&mut self) -> &mut Types {
&mut self.tys
}
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fn eval_const(&mut self, file: FileId, expr: &Expr, ret: ty::Id) -> u64 {
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let mut scope = core::mem::take(&mut self.ci.scope.vars);
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self.pool.push_ci(file, Some(ret), self.tasks.len(), &mut self.ci);
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self.ci.scope.vars = scope;
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let prev_err_len = self.errors.borrow().len();
self.expr(&Expr::Return { pos: expr.pos(), val: Some(expr) });
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scope = core::mem::take(&mut self.ci.scope.vars);
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self.ci.finalize();
let res = if self.errors.borrow().len() == prev_err_len {
self.emit_and_eval(file, ret, &mut [])
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} else {
1
};
self.pool.pop_ci(&mut self.ci);
self.ci.scope.vars = scope;
res
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}
fn infer_type(&mut self, expr: &Expr) -> ty::Id {
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self.pool.save_ci(&self.ci);
let ty = self.expr(expr).map_or(ty::Id::NEVER, |v| v.ty);
self.pool.restore_ci(&mut self.ci);
ty
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}
fn on_reuse(&mut self, existing: ty::Id) {
if let ty::Kind::Func(id) = existing.expand()
&& let func = &mut self.tys.ins.funcs[id as usize]
&& let Err(idx) = task::unpack(func.offset)
&& idx < self.tasks.len()
{
func.offset = task::id(self.tasks.len());
let task = self.tasks[idx].take();
self.tasks.push(task);
}
}
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fn eval_global(&mut self, file: FileId, name: Ident, expr: &Expr) -> ty::Id {
let gid = self.tys.ins.globals.len() as ty::Global;
self.tys.ins.globals.push(Global { file, name, ..Default::default() });
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let ty = ty::Kind::Global(gid);
self.pool.push_ci(file, None, self.tasks.len(), &mut self.ci);
let prev_err_len = self.errors.borrow().len();
self.expr(&(Expr::Return { pos: expr.pos(), val: Some(expr) }));
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self.ci.finalize();
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let ret = self.ci.ret.expect("for return type to be infered");
if self.errors.borrow().len() == prev_err_len {
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let mut mem = vec![0u8; self.tys.size_of(ret) as usize];
self.emit_and_eval(file, ret, &mut mem);
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self.tys.ins.globals[gid as usize].data = mem;
}
self.pool.pop_ci(&mut self.ci);
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self.tys.ins.globals[gid as usize].ty = ret;
ty.compress()
}
fn report(&self, pos: Pos, msg: impl Display) -> ty::Id {
self.report(pos, msg);
ty::Id::NEVER
}
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fn find_local_ty(&mut self, ident: Ident) -> Option<ty::Id> {
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self.ci.scope.vars.iter().rfind(|v| (v.id == ident && v.value() == NEVER)).map(|v| v.ty)
}
}
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impl<'a> Codegen<'a> {
fn emit_and_eval(&mut self, file: FileId, ret: ty::Id, ret_loc: &mut [u8]) -> u64 {
if !self.complete_call_graph() {
return 1;
}
self.ci.emit_body(&mut self.tys, self.files, Sig { args: Tuple::empty(), ret });
self.ci.code.truncate(self.ci.code.len() - instrs::jala(0, 0, 0).0);
self.ci.emit(instrs::tx());
let func = Func {
file,
name: 0,
relocs: core::mem::take(&mut self.ci.relocs),
code: core::mem::take(&mut self.ci.code),
..Default::default()
};
// TODO: return them back
let fuc = self.tys.ins.funcs.len() as ty::Func;
self.tys.ins.funcs.push(func);
self.tys.dump_reachable(fuc, &mut self.ct.code);
self.dump_ct_asm();
self.ct.run(ret_loc, self.tys.ins.funcs[fuc as usize].offset)
}
fn dump_ct_asm(&self) {
#[cfg(debug_assertions)]
{
let mut vc = String::new();
if let Err(e) = self.tys.disasm(&self.ct.code, self.files, &mut vc, |_| {}) {
panic!("{e} {}", vc);
} else {
log::trace!("{}", vc);
}
}
}
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pub fn push_embeds(&mut self, embeds: Vec<Vec<u8>>) {
self.tys.ins.globals = embeds
.into_iter()
.map(|data| Global {
ty: self.tys.make_array(ty::Id::U8, data.len() as _),
data,
..Default::default()
})
.collect();
}
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fn store_mem(&mut self, region: Nid, ty: ty::Id, value: Nid) -> Nid {
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if value == NEVER {
return NEVER;
}
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debug_assert!(
self.ci.nodes[region].kind != Kind::Load || self.ci.nodes[region].ty.is_pointer()
);
debug_assert!(self.ci.nodes[region].kind != Kind::Stre);
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self.ci.nodes.load_loop_store(&mut self.ci.scope.store, &mut self.ci.loops);
let mut vc = Vc::from([VOID, value, region, self.ci.scope.store.value()]);
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for load in self.ci.scope.loads.drain(..) {
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if load == value {
self.ci.nodes.unlock(load);
continue;
}
if !self.ci.nodes.unlock_remove(load) {
vc.push(load);
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}
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}
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let store = self.ci.nodes.new_node_nop(ty, Kind::Stre, vc);
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self.ci.scope.store.set_value(store, &mut self.ci.nodes);
let opted = self.ci.nodes.late_peephole(store);
self.ci.scope.store.set_value_remove(opted, &mut self.ci.nodes);
opted
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}
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fn load_mem(&mut self, region: Nid, ty: ty::Id) -> Nid {
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debug_assert_ne!(region, VOID);
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debug_assert_ne!({ self.ci.nodes[region].ty }, ty::Id::VOID, "{:?}", {
self.ci.nodes[region].lock_rc = Nid::MAX;
self.ci.nodes.graphviz_in_browser(&self.tys, self.files);
});
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debug_assert!(
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self.ci.nodes[region].kind != Kind::Load || self.ci.nodes[region].ty.is_pointer(),
"{:?} {} {}",
self.ci.nodes.graphviz_in_browser(&self.tys, self.files),
self.cfile().path,
self.ty_display(self.ci.nodes[region].ty)
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);
debug_assert!(self.ci.nodes[region].kind != Kind::Stre);
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self.ci.nodes.load_loop_store(&mut self.ci.scope.store, &mut self.ci.loops);
let vc = [VOID, region, self.ci.scope.store.value()];
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let load = self.ci.nodes.new_node(ty, Kind::Load, vc);
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self.ci.nodes.lock(load);
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self.ci.scope.loads.push(load);
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load
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}
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pub fn generate(&mut self, entry: FileId) {
self.find_type(0, entry, Err("main"), self.files);
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self.make_func_reachable(0);
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self.complete_call_graph();
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}
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pub fn assemble(&mut self, buf: &mut Vec<u8>) {
self.tys.reassemble(buf);
}
pub fn disasm(&mut self, output: &mut String) -> Result<(), DisasmError> {
let mut bin = Vec::new();
self.assemble(&mut bin);
self.tys.disasm(&bin, self.files, output, |_| {})
}
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fn make_func_reachable(&mut self, func: ty::Func) {
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let fuc = &mut self.tys.ins.funcs[func as usize];
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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 raw_expr(&mut self, expr: &Expr) -> Option<Value> {
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self.raw_expr_ctx(expr, Ctx::default())
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}
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fn raw_expr_ctx(&mut self, expr: &Expr, ctx: Ctx) -> Option<Value> {
// ordered by complexity of the expression
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match *expr {
Expr::Idk { pos } => {
let Some(ty) = ctx.ty else {
self.report(
pos,
"resulting value cannot be inferred from context, \
consider using `@as(<ty>, idk)` to hint the type",
);
return Value::NEVER;
};
if matches!(ty.expand(), ty::Kind::Struct(_) | ty::Kind::Slice(_)) {
let stck = self.ci.nodes.new_node(ty, Kind::Stck, [VOID, MEM]);
Some(Value::ptr(stck).ty(ty))
} else {
Some(self.ci.nodes.new_node_lit(ty, Kind::Idk, [VOID]))
}
}
Expr::Bool { value, .. } => Some(self.ci.nodes.new_node_lit(
ty::Id::BOOL,
Kind::CInt { value: value as i64 },
[VOID],
)),
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Expr::Number { value, .. } => Some(self.ci.nodes.new_node_lit(
ctx.ty.filter(|ty| ty.is_integer()).unwrap_or(ty::Id::INT),
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Kind::CInt { value },
[VOID],
)),
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Expr::Ident { id, .. }
if let Some(index) = self.ci.scope.vars.iter().rposition(|v| v.id == id) =>
{
let var = &mut self.ci.scope.vars[index];
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self.ci.nodes.load_loop_var(index + 1, var, &mut self.ci.loops);
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Some(Value::var(index).ty(var.ty))
}
Expr::Ident { id, pos, .. } => {
let decl = self.find_type(pos, self.ci.file, Ok(id), self.files);
match decl.expand() {
ty::Kind::Builtin(ty::NEVER) => Value::NEVER,
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ty::Kind::Global(global) => {
let gl = &self.tys.ins.globals[global as usize];
let value = self.ci.nodes.new_node(gl.ty, Kind::Global { global }, [VOID]);
Some(Value::ptr(value).ty(gl.ty))
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}
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_ => Some(Value::new(Nid::MAX).ty(decl)),
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}
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}
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Expr::Comment { .. } => Some(Value::VOID),
Expr::String { pos, literal } => {
let literal = &literal[1..literal.len() - 1];
let report = |bytes: &core::str::Bytes, message: &str| {
self.report(pos + (literal.len() - bytes.len()) as u32 - 1, message)
};
let mut data = Vec::<u8>::with_capacity(literal.len());
crate::endoce_string(literal, &mut data, report).unwrap();
let ty = self.tys.make_ptr(ty::Id::U8);
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let global = match self.tys.ins.strings.entry(data.clone()) {
hash_map::Entry::Occupied(occupied_entry) => *occupied_entry.get(),
hash_map::Entry::Vacant(vacant_entry) => {
let global = self.tys.ins.globals.len() as ty::Global;
self.tys.ins.globals.push(Global { data, ty, ..Default::default() });
*vacant_entry.insert(global)
}
};
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let global = self.ci.nodes.new_node(ty, Kind::Global { global }, [VOID]);
Some(Value::new(global).ty(ty))
}
Expr::Return { pos, val } => {
let mut value = if let Some(val) = val {
self.expr_ctx(val, Ctx { ty: self.ci.ret })?
} else {
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Value { ty: ty::Id::VOID, ..Default::default() }
};
let expected = *self.ci.ret.get_or_insert(value.ty);
self.assert_ty(pos, &mut value, expected, "return value");
if self.ci.inline_depth == 0 {
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debug_assert_ne!(self.ci.ctrl, VOID);
let mut inps = Vc::from([self.ci.ctrl, value.id]);
self.ci.nodes.load_loop_store(&mut self.ci.scope.store, &mut self.ci.loops);
inps.push(self.ci.scope.store.value());
self.ci.ctrl = self.ci.nodes.new_node(ty::Id::VOID, Kind::Return, inps);
self.ci.nodes[NEVER].inputs.push(self.ci.ctrl);
self.ci.nodes[self.ci.ctrl].outputs.push(NEVER);
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} else if let Some((pv, ctrl, scope)) = &mut self.ci.inline_ret {
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self.ci.nodes.unlock(*ctrl);
*ctrl =
self.ci.nodes.new_node(ty::Id::VOID, Kind::Region, [self.ci.ctrl, *ctrl]);
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self.ci.nodes.lock(*ctrl);
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Self::merge_scopes(
&mut self.ci.nodes,
&mut self.ci.loops,
*ctrl,
scope,
&mut self.ci.scope,
);
self.ci.nodes.unlock(pv.id);
pv.id = self.ci.nodes.new_node(value.ty, Kind::Phi, [*ctrl, value.id, pv.id]);
self.ci.nodes.lock(pv.id);
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self.ci.ctrl = *ctrl;
} else {
self.ci.nodes.lock(value.id);
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self.ci.nodes.lock(self.ci.ctrl);
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let mut scope = self.ci.scope.dup(&mut self.ci.nodes);
scope
.vars
.drain(self.ci.inline_var_base..)
.for_each(|v| v.remove(&mut self.ci.nodes));
self.ci.inline_ret = Some((value, self.ci.ctrl, scope));
}
None
}
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Expr::Field { target, name, pos } => {
let mut vtarget = self.raw_expr(target)?;
self.strip_var(&mut vtarget);
let tty = vtarget.ty;
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if let ty::Kind::Module(m) = tty.expand() {
return match self.find_type(pos, m, Err(name), self.files).expand() {
ty::Kind::Builtin(ty::NEVER) => Value::NEVER,
ty::Kind::Global(global) => {
let gl = &self.tys.ins.globals[global as usize];
let value =
self.ci.nodes.new_node(gl.ty, Kind::Global { global }, [VOID]);
Some(Value::ptr(value).ty(gl.ty))
}
v => Some(Value::new(Nid::MAX).ty(v.compress())),
};
}
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let ty::Kind::Struct(s) = self.tys.base_of(tty).unwrap_or(tty).expand() else {
self.report(
pos,
fa!(
"the '{}' is not a struct, or pointer to one, \
but accessing fields is only possible on structs",
self.ty_display(tty)
),
);
return Value::NEVER;
};
let Some((offset, ty)) = OffsetIter::offset_of(&self.tys, s, name) else {
let field_list = self
.tys
.struct_fields(s)
.iter()
.map(|f| self.tys.names.ident_str(f.name))
.intersperse("', '")
.collect::<String>();
self.report(
pos,
fa!(
"the '{}' does not have this field, \
but it does have '{field_list}'",
self.ty_display(tty)
),
);
return Value::NEVER;
};
Some(Value::ptr(self.offset(vtarget.id, offset)).ty(ty))
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}
Expr::UnOp { op: TokenKind::Band, val, .. } => {
let ctx = Ctx { ty: ctx.ty.and_then(|ty| self.tys.base_of(ty)) };
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let mut val = self.raw_expr_ctx(val, ctx)?;
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self.strip_var(&mut val);
if val.ptr {
val.ptr = false;
val.ty = self.tys.make_ptr(val.ty);
return Some(val);
}
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let stack = self.ci.nodes.new_node_nop(val.ty, Kind::Stck, [VOID, MEM]);
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self.store_mem(stack, val.ty, val.id);
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Some(Value::new(stack).ty(self.tys.make_ptr(val.ty)))
}
Expr::UnOp { op: TokenKind::Mul, val, pos } => {
let ctx = Ctx { ty: ctx.ty.map(|ty| self.tys.make_ptr(ty)) };
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let mut val = self.expr_ctx(val, ctx)?;
let Some(base) = self.tys.base_of(val.ty) else {
self.report(
pos,
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fa!("the '{}' can not be dereferneced", self.ty_display(val.ty)),
);
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return Value::NEVER;
};
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val.ptr = true;
val.ty = base;
Some(val)
}
Expr::UnOp { pos, op: op @ TokenKind::Sub, val } => {
let val = self.expr_ctx(val, ctx)?;
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if !val.ty.is_integer() {
self.report(pos, fa!("cant negate '{}'", self.ty_display(val.ty)));
}
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Some(self.ci.nodes.new_node_lit(val.ty, Kind::UnOp { op }, [VOID, val.id]))
}
Expr::BinOp { left, op: TokenKind::Decl, right } => {
let mut right = self.expr(right)?;
if right.ty.loc(&self.tys) == Loc::Stack {
let stck = self.ci.nodes.new_node_nop(right.ty, Kind::Stck, [VOID, MEM]);
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self.store_mem(stck, right.ty, right.id);
right.id = stck;
right.ptr = true;
}
self.assign_pattern(left, right);
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Some(Value::VOID)
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}
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Expr::BinOp { left, op: TokenKind::Assign, right } => {
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let dest = self.raw_expr(left)?;
let mut value = self.expr_ctx(right, Ctx::default().with_ty(dest.ty))?;
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self.assert_ty(left.pos(), &mut value, dest.ty, "assignment source");
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if dest.var {
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let var = &mut self.ci.scope.vars[(u16::MAX - dest.id) as usize];
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if var.ptr {
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let val = var.value();
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let ty = var.ty;
self.store_mem(val, ty, value.id);
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} else {
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var.set_value_remove(value.id, &mut self.ci.nodes);
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}
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} else if dest.ptr {
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self.store_mem(dest.id, dest.ty, value.id);
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} else {
self.report(left.pos(), "cannot assign to this expression");
}
Some(Value::VOID)
}
Expr::BinOp { left, op, right }
if !matches!(op, TokenKind::Assign | TokenKind::Decl) =>
{
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let mut lhs = self.raw_expr_ctx(left, ctx)?;
self.strip_var(&mut lhs);
match lhs.ty.expand() {
_ if lhs.ty.is_pointer() || lhs.ty.is_integer() || lhs.ty == ty::Id::BOOL => {
if core::mem::take(&mut lhs.ptr) {
lhs.id = self.load_mem(lhs.id, lhs.ty);
}
self.ci.nodes.lock(lhs.id);
let rhs = self.expr_ctx(right, Ctx::default().with_ty(lhs.ty));
self.ci.nodes.unlock(lhs.id);
let mut rhs = rhs?;
self.strip_var(&mut rhs);
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let ty = self.binop_ty(left.pos(), &mut lhs, &mut rhs, op);
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let inps = [VOID, lhs.id, rhs.id];
Some(self.ci.nodes.new_node_lit(
ty::bin_ret(ty, op),
Kind::BinOp { op },
inps,
))
}
ty::Kind::Struct(s) if op.is_homogenous() => {
self.ci.nodes.lock(lhs.id);
let rhs = self.raw_expr_ctx(right, Ctx::default().with_ty(lhs.ty));
self.ci.nodes.unlock(lhs.id);
let mut rhs = rhs?;
self.strip_var(&mut rhs);
let dst = self.ci.nodes.new_node(lhs.ty, Kind::Stck, [VOID, MEM]);
self.struct_op(left.pos(), op, s, dst, lhs.id, rhs.id);
Some(Value::ptr(dst).ty(lhs.ty))
}
_ => {
self.report(
left.pos(),
fa!("'{0} {op} {0}' is not supported", self.ty_display(lhs.ty),),
);
Value::NEVER
}
}
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}
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Expr::Index { base, index } => {
let mut bs = self.raw_expr(base)?;
self.strip_var(&mut bs);
if let Some(base) = self.tys.base_of(bs.ty) {
bs.ptr = true;
bs.ty = base;
}
let ty::Kind::Slice(s) = bs.ty.expand() else {
self.report(
base.pos(),
fa!(
"cant index into '{}' which is not array nor slice",
self.ty_display(bs.ty)
),
);
return Value::NEVER;
};
let elem = self.tys.ins.slices[s as usize].elem;
let idx = self.expr_ctx(index, Ctx::default().with_ty(ty::Id::INT))?;
let value = self.tys.size_of(elem) as i64;
let size = self.ci.nodes.new_node_nop(ty::Id::INT, Kind::CInt { value }, [VOID]);
let inps = [VOID, idx.id, size];
let offset =
self.ci.nodes.new_node(ty::Id::INT, Kind::BinOp { op: TokenKind::Mul }, inps);
let inps = [VOID, bs.id, offset];
let ptr =
self.ci.nodes.new_node(ty::Id::INT, Kind::BinOp { op: TokenKind::Add }, inps);
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Some(Value::ptr(ptr).ty(elem))
}
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Expr::Embed { id, .. } => {
let glob = &self.tys.ins.globals[id as usize];
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let g = self.ci.nodes.new_node(glob.ty, Kind::Global { global: id }, [VOID]);
Some(Value::ptr(g).ty(glob.ty))
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}
Expr::Directive { name: "sizeof", args: [ty], .. } => {
let ty = self.ty(ty);
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Some(self.ci.nodes.new_node_lit(
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ty::Id::UINT,
Kind::CInt { value: self.tys.size_of(ty) as _ },
[VOID],
))
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}
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Expr::Directive { name: "alignof", args: [ty], .. } => {
let ty = self.ty(ty);
Some(self.ci.nodes.new_node_lit(
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ty::Id::UINT,
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Kind::CInt { value: self.tys.align_of(ty) as _ },
[VOID],
))
}
Expr::Directive { name: "bitcast", args: [val], pos } => {
let mut val = self.raw_expr(val)?;
self.strip_var(&mut val);
let Some(ty) = ctx.ty else {
self.report(
pos,
"resulting type cannot be inferred from context, \
consider using `@as(<ty>, @bitcast(<expr>))` to hint the type",
);
return Value::NEVER;
};
let (got, expected) = (self.tys.size_of(val.ty), self.tys.size_of(ty));
if got != expected {
self.report(
pos,
fa!(
"cast from '{}' to '{}' is not supported, \
sizes dont match ({got} != {expected})",
self.ty_display(val.ty),
self.ty_display(ty)
),
);
}
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match ty.loc(&self.tys) {
Loc::Reg if core::mem::take(&mut val.ptr) => val.id = self.load_mem(val.id, ty),
Loc::Stack if !val.ptr => {
let stack = self.ci.nodes.new_node_nop(ty, Kind::Stck, [VOID, MEM]);
self.store_mem(stack, val.ty, val.id);
val.id = stack;
val.ptr = true;
}
_ => {}
}
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val.ty = ty;
Some(val)
}
Expr::Directive { name: "intcast", args: [expr], pos } => {
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let val = self.expr(expr)?;
if !val.ty.is_integer() {
self.report(
expr.pos(),
fa!(
"only integers can be truncated ('{}' is not an integer)",
self.ty_display(val.ty)
),
);
return Value::NEVER;
}
let Some(ty) = ctx.ty else {
self.report(
pos,
"resulting integer cannot be inferred from context, \
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consider using `@as(<int_ty>, @intcast(<expr>))` to hint the type",
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);
return Value::NEVER;
};
if self.tys.size_of(val.ty) <= self.tys.size_of(ty) {
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return Some(val);
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}
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let value = (1i64 << (self.tys.size_of(ty) * 8)) - 1;
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let mask = self.ci.nodes.new_node_nop(val.ty, Kind::CInt { value }, [VOID]);
let inps = [VOID, val.id, mask];
Some(self.ci.nodes.new_node_lit(ty, Kind::BinOp { op: TokenKind::Band }, inps))
}
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Expr::Directive { name: "as", args: [ty, expr], .. } => {
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let ty = self.ty(ty);
let ctx = Ctx::default().with_ty(ty);
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let mut val = self.raw_expr_ctx(expr, ctx)?;
self.strip_var(&mut val);
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self.assert_ty(expr.pos(), &mut val, ty, "hinted expr");
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Some(val)
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}
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Expr::Directive { pos, name: "eca", args } => {
let Some(ty) = ctx.ty else {
self.report(
pos,
"return type cannot be inferred from context, \
consider using `@as(<return_ty>, @eca(<expr>...))` to hint the type",
);
return Value::NEVER;
};
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let mut inps = Vc::from([NEVER]);
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let arg_base = self.tys.tmp.args.len();
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for arg in args {
let value = self.expr(arg)?;
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self.tys.tmp.args.push(value.ty);
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debug_assert_ne!(self.ci.nodes[value.id].kind, Kind::Stre);
self.ci.nodes.lock(value.id);
inps.push(value.id);
}
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let args = self.tys.pack_args(arg_base).expect("TODO");
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for &n in inps.iter().skip(1) {
self.ci.nodes.unlock(n);
}
inps.push(self.ci.scope.store.value());
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self.ci.scope.loads.retain(|&load| {
if inps.contains(&load) {
return true;
}
if !self.ci.nodes.unlock_remove(load) {
inps.push(load);
}
false
});
let alt_value = match ty.loc(&self.tys) {
Loc::Reg => None,
Loc::Stack => {
let stck = self.ci.nodes.new_node_nop(ty, Kind::Stck, [VOID, MEM]);
inps.push(stck);
Some(Value::ptr(stck).ty(ty))
}
};
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inps[0] = self.ci.ctrl;
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self.ci.ctrl = self.ci.nodes.new_node(ty, Kind::Call { func: ty::ECA, args }, inps);
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self.store_mem(VOID, ty::Id::VOID, VOID);
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alt_value.or(Some(Value::new(self.ci.ctrl).ty(ty)))
}
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//Expr::Directive { name: "inline", args: [func, args @ ..], .. }
Expr::Call { func, args, .. } => {
self.ci.call_count += 1;
let ty = self.ty(func);
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let ty::Kind::Func(mut fu) = ty.expand() else {
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self.report(
func.pos(),
fa!("compiler cant (yet) call '{}'", self.ty_display(ty)),
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);
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return Value::NEVER;
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};
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let Some(sig) = self.compute_signature(&mut fu, func.pos(), args) else {
return Value::NEVER;
};
self.make_func_reachable(fu);
let fuc = &self.tys.ins.funcs[fu as usize];
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let ast = &self.files[fuc.file as usize];
let &Expr::Closure { args: cargs, .. } = fuc.expr.get(ast) else { unreachable!() };
if args.len() != cargs.len() {
self.report(
func.pos(),
fa!(
"expected {} function argumenr{}, got {}",
cargs.len(),
if cargs.len() == 1 { "" } else { "s" },
args.len()
),
);
}
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let mut inps = Vc::from([NEVER]);
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let mut tys = sig.args.args();
let mut cargs = cargs.iter();
let mut args = args.iter();
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let mut has_ptr_arg = false;
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while let Some(ty) = tys.next(&self.tys) {
let carg = cargs.next().unwrap();
let arg = args.next().unwrap();
let Arg::Value(ty) = ty else { continue };
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has_ptr_arg |= ty.has_pointers(&self.tys);
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let mut value = self.expr_ctx(arg, Ctx::default().with_ty(ty))?;
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debug_assert_ne!(self.ci.nodes[value.id].kind, Kind::Stre);
self.assert_ty(arg.pos(), &mut value, ty, fa!("argument {}", carg.name));
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self.ci.nodes.lock(value.id);
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inps.push(value.id);
}
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for &n in inps.iter().skip(1) {
self.ci.nodes.unlock(n);
}
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if has_ptr_arg {
inps.push(self.ci.scope.store.value());
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self.ci.scope.loads.retain(|&load| {
if inps.contains(&load) {
return true;
}
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if !self.ci.nodes.unlock_remove(load) {
inps.push(load);
}
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false
});
}
let alt_value = match sig.ret.loc(&self.tys) {
Loc::Reg => None,
Loc::Stack => {
let stck = self.ci.nodes.new_node_nop(sig.ret, Kind::Stck, [VOID, MEM]);
inps.push(stck);
Some(Value::ptr(stck).ty(sig.ret))
}
};
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inps[0] = self.ci.ctrl;
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self.ci.ctrl =
self.ci.nodes.new_node(sig.ret, Kind::Call { func: fu, args: sig.args }, inps);
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if has_ptr_arg {
self.store_mem(VOID, ty::Id::VOID, VOID);
}
alt_value.or(Some(Value::new(self.ci.ctrl).ty(sig.ret)))
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}
Expr::Directive { name: "inline", args: [func, args @ ..], .. } => {
let ty = self.ty(func);
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let ty::Kind::Func(mut fu) = ty.expand() else {
self.report(
func.pos(),
fa!(
"first argument to @inline should be a function,
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but here its '{}'",
self.ty_display(ty)
),
);
return Value::NEVER;
};
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let Some(sig) = self.compute_signature(&mut fu, func.pos(), args) else {
return Value::NEVER;
};
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let Func { expr, file, .. } = self.tys.ins.funcs[fu as usize];
let ast = &self.files[file as usize];
let &Expr::Closure { args: cargs, body, .. } = expr.get(ast) else {
unreachable!()
};
if args.len() != cargs.len() {
self.report(
func.pos(),
fa!(
"expected {} inline function argumenr{}, got {}",
cargs.len(),
if cargs.len() == 1 { "" } else { "s" },
args.len()
),
);
}
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let mut tys = sig.args.args();
let mut args = args.iter();
let mut cargs = cargs.iter();
let var_base = self.ci.scope.vars.len();
while let Some(aty) = tys.next(&self.tys) {
let arg = args.next().unwrap();
let carg = cargs.next().unwrap();
match aty {
Arg::Type(id) => {
self.ci.scope.vars.push(Variable::new(
carg.id,
id,
false,
NEVER,
&mut self.ci.nodes,
));
}
Arg::Value(ty) => {
let mut value = self.raw_expr_ctx(arg, Ctx::default().with_ty(ty))?;
self.strip_var(&mut value);
debug_assert_ne!(self.ci.nodes[value.id].kind, Kind::Stre);
debug_assert_ne!(value.id, 0);
self.assert_ty(
arg.pos(),
&mut value,
ty,
fa!("argument {}", carg.name),
);
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self.ci.scope.vars.push(Variable::new(
carg.id,
ty,
value.ptr,
value.id,
&mut self.ci.nodes,
));
}
}
}
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let prev_var_base =
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core::mem::replace(&mut self.ci.inline_var_base, self.ci.scope.vars.len());
let prev_ret = self.ci.ret.replace(sig.ret);
let prev_inline_ret = self.ci.inline_ret.take();
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let prev_file = core::mem::replace(&mut self.ci.file, file);
self.ci.inline_depth += 1;
if self.expr(body).is_some() && sig.ret == ty::Id::VOID {
self.report(
body.pos(),
"expected all paths in the fucntion to return \
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or the return type to be 'void'",
);
}
self.ci.ret = prev_ret;
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self.ci.file = prev_file;
self.ci.inline_depth -= 1;
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self.ci.inline_var_base = prev_var_base;
for var in self.ci.scope.vars.drain(var_base..) {
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var.remove(&mut self.ci.nodes);
}
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core::mem::replace(&mut self.ci.inline_ret, prev_inline_ret).map(
|(v, ctrl, scope)| {
self.ci.nodes.unlock(ctrl);
self.ci.nodes.unlock(v.id);
self.ci.scope.clear(&mut self.ci.nodes);
self.ci.scope = scope;
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self.ci
.scope
.vars
.drain(var_base..)
.for_each(|v| v.remove(&mut self.ci.nodes));
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self.ci.ctrl = ctrl;
v
},
)
}
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Expr::Tupl { pos, ty, fields, .. } => {
let Some(sty) = ty.map(|ty| self.ty(ty)).or(ctx.ty) else {
self.report(
pos,
"the type of struct cannot be inferred from context, \
use an explicit type instead: <type>.{ ... }",
);
return Value::NEVER;
};
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match sty.expand() {
ty::Kind::Struct(s) => {
let mem = self.ci.nodes.new_node(sty, Kind::Stck, [VOID, MEM]);
let mut offs = OffsetIter::new(s, &self.tys);
for field in fields {
let Some((ty, offset)) = offs.next_ty(&self.tys) else {
self.report(
field.pos(),
"this init argumen overflows the field count",
);
break;
};
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let mut value = self.expr_ctx(field, Ctx::default().with_ty(ty))?;
_ = self.assert_ty(field.pos(), &mut value, ty, "tuple field");
let mem = self.offset(mem, offset);
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self.store_mem(mem, ty, value.id);
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}
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let field_list = offs
.into_iter(&self.tys)
.map(|(f, ..)| self.tys.names.ident_str(f.name))
.intersperse(", ")
.collect::<String>();
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if !field_list.is_empty() {
self.report(
pos,
fa!("the struct initializer is missing {field_list} \
(append them to the end of the constructor)"),
);
}
Some(Value::ptr(mem).ty(sty))
}
ty::Kind::Slice(s) => {
let slice = &self.tys.ins.slices[s as usize];
let len = slice.len().unwrap_or(fields.len());
let elem = slice.elem;
let elem_size = self.tys.size_of(elem);
let aty = slice
.len()
.map_or_else(|| self.tys.make_array(elem, len as ArrayLen), |_| sty);
if len != fields.len() {
self.report(
pos,
fa!(
"expected '{}' but constructor has {} elements",
self.ty_display(aty),
fields.len()
),
);
return Value::NEVER;
}
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let mem = self.ci.nodes.new_node(aty, Kind::Stck, [VOID, MEM]);
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for (field, offset) in
fields.iter().zip((0u32..).step_by(elem_size as usize))
{
let mut value = self.expr_ctx(field, Ctx::default().with_ty(elem))?;
_ = self.assert_ty(field.pos(), &mut value, elem, "array value");
let mem = self.offset(mem, offset);
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self.store_mem(mem, elem, value.id);
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}
Some(Value::ptr(mem).ty(aty))
}
_ => {
let inferred = if ty.is_some() { "" } else { "inferred " };
self.report(
pos,
fa!(
"the {inferred}type of the constructor is `{}`, \
but thats not a struct nor slice or array",
self.ty_display(sty)
),
);
Value::NEVER
}
}
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}
Expr::Struct { .. } => {
let value = self.ty(expr).repr() as i64;
Some(self.ci.nodes.new_node_lit(ty::Id::TYPE, Kind::CInt { value }, [VOID]))
}
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Expr::Ctor { pos, ty, fields, .. } => {
let Some(sty) = ty.map(|ty| self.ty(ty)).or(ctx.ty) else {
self.report(
pos,
"the type of struct cannot be inferred from context, \
use an explicit type instead: <type>.{ ... }",
);
return Value::NEVER;
};
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let ty::Kind::Struct(s) = sty.expand() else {
let inferred = if ty.is_some() { "" } else { "inferred " };
self.report(
pos,
fa!(
"the {inferred}type of the constructor is `{}`, \
but thats not a struct",
self.ty_display(sty)
),
);
return Value::NEVER;
};
// TODO: dont allocate
let mut offs = OffsetIter::new(s, &self.tys)
.into_iter(&self.tys)
.map(|(f, o)| (f.ty, o))
.collect::<Vec<_>>();
let mem = self.ci.nodes.new_node(sty, Kind::Stck, [VOID, MEM]);
for field in fields {
let Some(index) = self.tys.find_struct_field(s, field.name) else {
self.report(
field.pos,
fa!("struct '{}' does not have this field", self.ty_display(sty)),
);
continue;
};
let (ty, offset) =
core::mem::replace(&mut offs[index], (ty::Id::UNDECLARED, field.pos));
if ty == ty::Id::UNDECLARED {
self.report(field.pos, "the struct field is already initialized");
self.report(offset, "previous initialization is here");
continue;
}
let value = self.expr_ctx(&field.value, Ctx::default().with_ty(ty))?;
let mem = self.offset(mem, offset);
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self.store_mem(mem, ty, value.id);
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}
let field_list = self
.tys
.struct_fields(s)
.iter()
.zip(offs)
.filter(|&(_, (ty, _))| ty != ty::Id::UNDECLARED)
.map(|(f, _)| self.tys.names.ident_str(f.name))
.intersperse(", ")
.collect::<String>();
if !field_list.is_empty() {
self.report(pos, fa!("the struct initializer is missing {field_list}"));
}
Some(Value::ptr(mem).ty(sty))
}
Expr::Block { stmts, .. } => {
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let base = self.ci.scope.vars.len();
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let mut ret = Some(Value::VOID);
for stmt in stmts {
ret = ret.and(self.expr(stmt));
if let Some(mut id) = ret {
self.assert_ty(stmt.pos(), &mut id, ty::Id::VOID, "statement");
} else {
break;
}
}
self.ci.nodes.lock(self.ci.ctrl);
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for var in self.ci.scope.vars.drain(base..) {
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var.remove(&mut self.ci.nodes);
}
self.ci.nodes.unlock(self.ci.ctrl);
ret
}
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Expr::Loop { body, .. } => {
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self.ci.ctrl = self.ci.nodes.new_node(ty::Id::VOID, Kind::Loop, [self.ci.ctrl; 2]);
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self.ci.loops.push(Loop {
node: self.ci.ctrl,
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ctrl: [Nid::MAX; 2],
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ctrl_scope: core::array::from_fn(|_| Default::default()),
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scope: self.ci.scope.dup(&mut self.ci.nodes),
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});
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for var in &mut self.ci.scope.iter_mut() {
var.set_value(VOID, &mut self.ci.nodes);
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}
self.expr(body);
let Loop { ctrl: [con, ..], ctrl_scope: [cons, ..], .. } =
self.ci.loops.last_mut().unwrap();
let mut cons = core::mem::take(cons);
let mut con = *con;
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if con != Nid::MAX {
self.ci.nodes.unlock(con);
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con = self.ci.nodes.new_node(ty::Id::VOID, Kind::Region, [con, self.ci.ctrl]);
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Self::merge_scopes(
&mut self.ci.nodes,
&mut self.ci.loops,
con,
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&mut self.ci.scope,
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&mut cons,
);
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cons.clear(&mut self.ci.nodes);
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self.ci.ctrl = con;
}
let Loop { node, ctrl: [.., bre], ctrl_scope: [.., mut bres], mut scope } =
self.ci.loops.pop().unwrap();
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self.ci.nodes.modify_input(node, 1, self.ci.ctrl);
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if let Some(idx) =
self.ci.nodes[node].outputs.iter().position(|&n| self.ci.nodes.is_cfg(n))
{
self.ci.nodes[node].outputs.swap(idx, 0);
}
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if bre == Nid::MAX {
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for (loop_var, scope_var) in self.ci.scope.iter_mut().zip(scope.iter_mut()) {
if self.ci.nodes[scope_var.value()].is_lazy_phi(node) {
if loop_var.value() != scope_var.value() {
scope_var.set_value(
self.ci.nodes.modify_input(
scope_var.value(),
2,
loop_var.value(),
),
&mut self.ci.nodes,
);
} else {
let phi = &self.ci.nodes[scope_var.value()];
let prev = phi.inputs[1];
self.ci.nodes.replace(scope_var.value(), prev);
scope_var.set_value(prev, &mut self.ci.nodes);
}
}
}
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scope.clear(&mut self.ci.nodes);
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self.ci.ctrl = NEVER;
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return None;
}
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self.ci.ctrl = bre;
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core::mem::swap(&mut self.ci.scope, &mut bres);
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debug_assert_eq!(self.ci.scope.vars.len(), scope.vars.len());
debug_assert_eq!(self.ci.scope.vars.len(), bres.vars.len());
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self.ci.nodes.lock(node);
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for ((dest_var, scope_var), loop_var) in
self.ci.scope.iter_mut().zip(scope.iter_mut()).zip(bres.iter_mut())
{
if self.ci.nodes[scope_var.value()].is_lazy_phi(node) {
if loop_var.value() != scope_var.value() {
scope_var.set_value(
self.ci.nodes.modify_input(scope_var.value(), 2, loop_var.value()),
&mut self.ci.nodes,
);
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} else {
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if dest_var.value() == scope_var.value() {
dest_var.set_value(VOID, &mut self.ci.nodes);
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}
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let phi = &self.ci.nodes[scope_var.value()];
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let prev = phi.inputs[1];
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self.ci.nodes.replace(scope_var.value(), prev);
scope_var.set_value(prev, &mut self.ci.nodes);
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}
}
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if dest_var.value() == VOID {
dest_var.set_value(scope_var.value(), &mut self.ci.nodes);
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}
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debug_assert!(!self.ci.nodes[dest_var.value()].is_lazy_phi(node));
}
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scope.clear(&mut self.ci.nodes);
bres.clear(&mut self.ci.nodes);
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self.ci.scope.loads.drain(..).for_each(|l| _ = self.ci.nodes.unlock_remove(l));
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self.ci.nodes.unlock(self.ci.ctrl);
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self.ci.nodes.unlock(node);
let rpl = self.ci.nodes.late_peephole(node);
if self.ci.ctrl == node {
self.ci.ctrl = rpl;
}
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Some(Value::VOID)
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}
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Expr::Break { pos } => self.jump_to(pos, 1),
Expr::Continue { pos } => self.jump_to(pos, 0),
Expr::If { cond, then, else_, .. } => {
let cond = self.expr_ctx(cond, Ctx::default().with_ty(ty::BOOL))?;
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let if_node =
self.ci.nodes.new_node(ty::Id::VOID, Kind::If, [self.ci.ctrl, cond.id]);
'b: {
let branch = match self.tof(if_node).expand().inner() {
ty::LEFT_UNREACHABLE => else_,
ty::RIGHT_UNREACHABLE => Some(then),
_ => break 'b,
};
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self.ci.nodes.lock(self.ci.ctrl);
self.ci.nodes.remove(if_node);
self.ci.nodes.unlock(self.ci.ctrl);
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if let Some(branch) = branch {
return self.expr(branch);
} else {
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return Some(Value::VOID);
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}
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}
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self.ci.nodes.load_loop_store(&mut self.ci.scope.store, &mut self.ci.loops);
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let orig_store = self.ci.scope.store.dup(&mut self.ci.nodes);
let else_scope = self.ci.scope.dup(&mut self.ci.nodes);
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self.ci.ctrl = self.ci.nodes.new_node(ty::Id::VOID, Kind::Then, [if_node]);
let lcntrl = self.expr(then).map_or(Nid::MAX, |_| self.ci.ctrl);
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let mut then_scope = core::mem::replace(&mut self.ci.scope, else_scope);
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self.ci.ctrl = self.ci.nodes.new_node(ty::Id::VOID, Kind::Else, [if_node]);
let rcntrl = if let Some(else_) = else_ {
self.expr(else_).map_or(Nid::MAX, |_| self.ci.ctrl)
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} else {
self.ci.ctrl
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};
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orig_store.remove(&mut self.ci.nodes);
if lcntrl == Nid::MAX && rcntrl == Nid::MAX {
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then_scope.clear(&mut self.ci.nodes);
return None;
} else if lcntrl == Nid::MAX {
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then_scope.clear(&mut self.ci.nodes);
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return Some(Value::VOID);
} else if rcntrl == Nid::MAX {
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self.ci.scope.clear(&mut self.ci.nodes);
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self.ci.scope = then_scope;
self.ci.ctrl = lcntrl;
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return Some(Value::VOID);
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}
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self.ci.ctrl = self.ci.nodes.new_node(ty::Id::VOID, Kind::Region, [lcntrl, rcntrl]);
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Self::merge_scopes(
&mut self.ci.nodes,
&mut self.ci.loops,
self.ci.ctrl,
&mut self.ci.scope,
&mut then_scope,
);
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then_scope.clear(&mut self.ci.nodes);
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Some(Value::VOID)
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}
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ref e => self.report_unhandled_ast(e, "bruh"),
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}
}
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fn struct_op(
&mut self,
pos: Pos,
op: TokenKind,
s: ty::Struct,
dst: Nid,
lhs: Nid,
rhs: Nid,
) -> bool {
let mut offs = OffsetIter::new(s, &self.tys);
while let Some((ty, off)) = offs.next_ty(&self.tys) {
let lhs = self.offset(lhs, off);
let rhs = self.offset(rhs, off);
let dst = self.offset(dst, off);
match ty.expand() {
_ if ty.is_pointer() || ty.is_integer() || ty == ty::Id::BOOL => {
let lhs = self.load_mem(lhs, ty);
let rhs = self.load_mem(rhs, ty);
let res = self.ci.nodes.new_node(ty, Kind::BinOp { op }, [VOID, lhs, rhs]);
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self.store_mem(dst, ty, res);
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}
ty::Kind::Struct(is) => {
if !self.struct_op(pos, op, is, dst, lhs, rhs) {
self.report(
pos,
fa!(
"... when appliing '{0} {op} {0}'",
self.ty_display(ty::Kind::Struct(s).compress())
),
);
}
}
_ => self.report(pos, fa!("'{0} {op} {0}' is not supported", self.ty_display(ty))),
}
}
true
}
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fn compute_signature(&mut self, func: &mut ty::Func, pos: Pos, args: &[Expr]) -> Option<Sig> {
let fuc = &self.tys.ins.funcs[*func as usize];
let fast = self.files[fuc.file as usize].clone();
let &Expr::Closure { args: cargs, ret, .. } = fuc.expr.get(&fast) else {
unreachable!();
};
Some(if let Some(sig) = fuc.sig {
sig
} else {
let arg_base = self.tys.tmp.args.len();
let base = self.ci.scope.vars.len();
for (arg, carg) in args.iter().zip(cargs) {
let ty = self.ty(&carg.ty);
self.tys.tmp.args.push(ty);
let sym = parser::find_symbol(&fast.symbols, carg.id);
let ty = if sym.flags & idfl::COMPTIME == 0 {
// FIXME: could fuck us
ty::Id::UNDECLARED
} else {
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if ty != ty::Id::TYPE {
self.report(
arg.pos(),
fa!(
"arbitrary comptime types are not supported yet \
(expected '{}' got '{}')",
self.ty_display(ty::Id::TYPE),
self.ty_display(ty)
),
);
return None;
}
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let ty = self.ty(arg);
self.tys.tmp.args.push(ty);
ty
};
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self.ci.scope.vars.push(Variable::new(
carg.id,
ty,
false,
NEVER,
&mut self.ci.nodes,
));
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}
let Some(args) = self.tys.pack_args(arg_base) else {
self.report(pos, "function instance has too many arguments");
return None;
};
let ret = self.ty(ret);
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self.ci.scope.vars.drain(base..).for_each(|v| v.remove(&mut self.ci.nodes));
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let sym = SymKey::FuncInst(*func, args);
let ct = |ins: &mut crate::TypeIns| {
let func_id = ins.funcs.len();
let fuc = &ins.funcs[*func as usize];
ins.funcs.push(Func {
file: fuc.file,
name: fuc.name,
base: Some(*func),
sig: Some(Sig { args, ret }),
expr: fuc.expr,
..Default::default()
});
ty::Kind::Func(func_id as _).compress()
};
*func = self.tys.syms.get_or_insert(sym, &mut self.tys.ins, ct).expand().inner();
Sig { args, ret }
})
}
fn assign_pattern(&mut self, pat: &Expr, right: Value) {
match *pat {
Expr::Ident { id, .. } => {
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self.ci.scope.vars.push(Variable::new(
id,
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right.ty,
right.ptr,
right.id,
&mut self.ci.nodes,
));
}
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)");
return;
};
for &CtorField { pos, name, ref value } in fields {
let Some((offset, ty)) = OffsetIter::offset_of(&self.tys, idx, name) else {
self.report(pos, format_args!("field not found: {name:?}"));
continue;
};
let off = self.offset(right.id, offset);
self.assign_pattern(value, Value::ptr(off).ty(ty));
}
}
ref pat => self.report_unhandled_ast(pat, "pattern"),
}
}
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fn expr_ctx(&mut self, expr: &Expr, ctx: Ctx) -> Option<Value> {
let mut n = self.raw_expr_ctx(expr, ctx)?;
self.strip_var(&mut n);
if core::mem::take(&mut n.ptr) {
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n.id = self.load_mem(n.id, n.ty);
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}
Some(n)
}
fn offset(&mut self, val: Nid, off: Offset) -> Nid {
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if off == 0 {
return val;
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}
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let off = self.ci.nodes.new_node_nop(ty::Id::INT, Kind::CInt { value: off as i64 }, [VOID]);
let inps = [VOID, val, off];
self.ci.nodes.new_node(ty::Id::INT, Kind::BinOp { op: TokenKind::Add }, inps)
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}
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fn strip_var(&mut self, n: &mut Value) {
if core::mem::take(&mut n.var) {
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let id = (u16::MAX - n.id) as usize;
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n.ptr = self.ci.scope.vars[id].ptr;
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n.id = self.ci.scope.vars[id].value();
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}
}
fn expr(&mut self, expr: &Expr) -> Option<Value> {
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self.expr_ctx(expr, Default::default())
}
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fn jump_to(&mut self, pos: Pos, id: usize) -> Option<Value> {
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let Some(mut loob) = self.ci.loops.last_mut() else {
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self.report(pos, "break outside a loop");
return None;
};
if loob.ctrl[id] == Nid::MAX {
self.ci.nodes.lock(self.ci.ctrl);
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loob.ctrl[id] = self.ci.ctrl;
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loob.ctrl_scope[id] = self.ci.scope.dup(&mut self.ci.nodes);
loob.ctrl_scope[id]
.vars
.drain(loob.scope.vars.len()..)
.for_each(|v| v.remove(&mut self.ci.nodes));
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} else {
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let reg =
self.ci.nodes.new_node(ty::Id::VOID, Kind::Region, [self.ci.ctrl, loob.ctrl[id]]);
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let mut scope = core::mem::take(&mut loob.ctrl_scope[id]);
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Self::merge_scopes(
&mut self.ci.nodes,
&mut self.ci.loops,
reg,
&mut scope,
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&mut self.ci.scope,
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);
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loob = self.ci.loops.last_mut().unwrap();
loob.ctrl_scope[id] = scope;
self.ci.nodes.unlock(loob.ctrl[id]);
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loob.ctrl[id] = reg;
self.ci.nodes.lock(loob.ctrl[id]);
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}
self.ci.ctrl = NEVER;
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None
}
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fn merge_scopes(
nodes: &mut Nodes,
loops: &mut [Loop],
ctrl: Nid,
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to: &mut Scope,
from: &mut Scope,
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) {
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nodes.lock(ctrl);
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for (i, (to_value, from_value)) in to.iter_mut().zip(from.iter_mut()).enumerate() {
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debug_assert_eq!(to_value.ty, from_value.ty);
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if to_value.value() != from_value.value() {
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nodes.load_loop_var(i, from_value, loops);
nodes.load_loop_var(i, to_value, loops);
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if to_value.value() != from_value.value() {
let inps = [ctrl, from_value.value(), to_value.value()];
to_value
.set_value_remove(nodes.new_node(from_value.ty, Kind::Phi, inps), nodes);
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}
}
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}
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for load in to.loads.drain(..) {
nodes.unlock_remove(load);
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}
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for load in from.loads.drain(..) {
nodes.unlock_remove(load);
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}
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nodes.unlock(ctrl);
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}
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#[inline(always)]
fn tof(&self, id: Nid) -> ty::Id {
self.ci.nodes[id].ty
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}
fn complete_call_graph(&mut self) -> bool {
let prev_err_len = self.errors.borrow().len();
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while self.ci.task_base < self.tasks.len()
&& let Some(task_slot) = self.tasks.pop()
{
let Some(task) = task_slot else { continue };
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self.emit_func(task);
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}
self.errors.borrow().len() == prev_err_len
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}
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fn emit_func(&mut self, FTask { file, id }: FTask) {
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let func = &mut self.tys.ins.funcs[id as usize];
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debug_assert_eq!(func.file, file);
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func.offset = u32::MAX - 1;
let sig = func.sig.expect("to emmit only concrete functions");
let ast = &self.files[file as usize];
let expr = func.expr.get(ast);
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self.pool.push_ci(file, Some(sig.ret), 0, &mut self.ci);
let prev_err_len = self.errors.borrow().len();
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let &Expr::Closure { body, args, .. } = expr else {
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unreachable!("{}", self.ast_display(expr))
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};
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let mut tys = sig.args.args();
let mut args = args.iter();
while let Some(aty) = tys.next(&self.tys) {
let arg = args.next().unwrap();
match aty {
Arg::Type(ty) => {
self.ci.scope.vars.push(Variable::new(
arg.id,
ty,
false,
NEVER,
&mut self.ci.nodes,
));
}
Arg::Value(ty) => {
let mut deps = Vc::from([VOID]);
if ty.loc(&self.tys) == Loc::Stack && self.tys.size_of(ty) <= 16 {
deps.push(MEM);
}
// TODO: whe we not using the deps?
let value = self.ci.nodes.new_node_nop(ty, Kind::Arg, deps);
let ptr = ty.loc(&self.tys) == Loc::Stack;
self.ci.scope.vars.push(Variable::new(
arg.id,
ty,
ptr,
value,
&mut self.ci.nodes,
));
}
}
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}
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if self.expr(body).is_some() && sig.ret == ty::Id::VOID {
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self.report(
body.pos(),
"expected all paths in the fucntion to return \
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or the return type to be 'void'",
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);
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}
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self.ci.scope.vars.drain(..).for_each(|v| v.remove_ignore_arg(&mut self.ci.nodes));
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self.ci.finalize();
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if self.errors.borrow().len() == prev_err_len {
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self.ci.emit_body(&mut self.tys, self.files, sig);
self.tys.ins.funcs[id as usize].code.append(&mut self.ci.code);
self.tys.ins.funcs[id as usize].relocs.append(&mut self.ci.relocs);
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}
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self.pool.pop_ci(&mut self.ci);
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}
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fn ty(&mut self, expr: &Expr) -> ty::Id {
self.parse_ty(self.ci.file, expr, None, self.files)
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}
fn ty_display(&self, ty: ty::Id) -> ty::Display {
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ty::Display::new(&self.tys, self.files, ty)
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}
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fn ast_display(&self, ast: &'a Expr<'a>) -> parser::Display<'a> {
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parser::Display::new(&self.cfile().file, ast)
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}
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#[must_use]
#[track_caller]
fn binop_ty(&mut self, pos: Pos, lhs: &mut Value, rhs: &mut Value, op: TokenKind) -> ty::Id {
if let Some(upcasted) = lhs.ty.try_upcast(rhs.ty, ty::TyCheck::BinOp) {
let to_correct = if lhs.ty != upcasted {
Some(lhs)
} else if rhs.ty != upcasted {
Some(rhs)
} else {
None
};
if let Some(oper) = to_correct {
oper.ty = upcasted;
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if core::mem::take(&mut oper.ptr) {
oper.id = self.load_mem(oper.id, oper.ty);
}
oper.id = self.ci.nodes.new_node(upcasted, Kind::Extend, [VOID, oper.id]);
if matches!(op, TokenKind::Add | TokenKind::Sub)
&& let Some(elem) = self.tys.base_of(upcasted)
{
let value = self.tys.size_of(elem) as i64;
let cnst =
self.ci.nodes.new_node_nop(ty::Id::INT, Kind::CInt { value }, [VOID]);
oper.id =
self.ci.nodes.new_node(upcasted, Kind::BinOp { op: TokenKind::Mul }, [
VOID, oper.id, cnst,
]);
}
}
upcasted
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} else {
let ty = self.ty_display(lhs.ty);
let expected = self.ty_display(rhs.ty);
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self.report(pos, fa!("'{ty} {op} {expected}' is not supported"));
ty::Id::NEVER
}
}
#[track_caller]
fn assert_ty(
&mut self,
pos: Pos,
src: &mut Value,
expected: ty::Id,
hint: impl fmt::Display,
) -> bool {
if let Some(upcasted) = src.ty.try_upcast(expected, ty::TyCheck::Assign)
&& upcasted == expected
{
if src.ty != upcasted {
debug_assert!(
src.ty.is_integer() || src.ty == ty::Id::NEVER,
"{} {}",
self.ty_display(src.ty),
self.ty_display(upcasted)
);
debug_assert!(
upcasted.is_integer() || src.ty == ty::Id::NEVER,
"{} {}",
self.ty_display(src.ty),
self.ty_display(upcasted)
);
src.ty = upcasted;
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if core::mem::take(&mut src.ptr) {
src.id = self.load_mem(src.id, src.ty);
}
src.id = self.ci.nodes.new_node(upcasted, Kind::Extend, [VOID, src.id]);
}
true
} else {
let ty = self.ty_display(src.ty);
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let expected = self.ty_display(expected);
self.report(pos, fa!("expected {hint} to be of type {expected}, got {ty}"));
false
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}
}
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#[track_caller]
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fn report(&self, pos: Pos, msg: impl core::fmt::Display) {
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let mut buf = self.errors.borrow_mut();
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write!(buf, "{}", self.cfile().report(pos, msg)).unwrap();
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}
#[track_caller]
fn report_unhandled_ast(&self, ast: &Expr, hint: impl Display) -> ! {
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log::info!("{ast:#?}");
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self.fatal_report(ast.pos(), fa!("compiler does not (yet) know how to handle ({hint})"));
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}
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fn cfile(&self) -> &'a parser::Ast {
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&self.files[self.ci.file as usize]
}
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fn fatal_report(&self, pos: Pos, msg: impl Display) -> ! {
self.report(pos, msg);
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panic!("{}", self.errors.borrow());
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}
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}
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// FIXME: make this more efficient (allocated with arena)
#[derive(Debug)]
struct Block {
nid: Nid,
preds: Vec<regalloc2::Block>,
succs: Vec<regalloc2::Block>,
instrs: regalloc2::InstRange,
params: Vec<regalloc2::VReg>,
branch_blockparams: Vec<regalloc2::VReg>,
}
#[derive(Debug)]
struct Instr {
nid: Nid,
ops: Vec<regalloc2::Operand>,
}
struct Function<'a> {
sig: Sig,
nodes: &'a mut Nodes,
tys: &'a Types,
blocks: Vec<Block>,
instrs: Vec<Instr>,
}
impl Debug for Function<'_> {
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fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
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for (i, block) in self.blocks.iter().enumerate() {
writeln!(f, "sb{i}{:?}-{:?}:", block.params, block.preds)?;
for inst in block.instrs.iter() {
let instr = &self.instrs[inst.index()];
writeln!(f, "{}: i{:?}:{:?}", inst.index(), self.nodes[instr.nid].kind, instr.ops)?;
}
writeln!(f, "eb{i}{:?}-{:?}:", block.branch_blockparams, block.succs)?;
}
Ok(())
}
}
impl<'a> Function<'a> {
fn new(nodes: &'a mut Nodes, tys: &'a Types, sig: Sig) -> Self {
let mut s =
Self { nodes, tys, sig, blocks: Default::default(), instrs: Default::default() };
s.nodes.visited.clear(s.nodes.values.len());
s.emit_node(VOID, VOID);
s.add_block(0);
s.blocks.pop();
s
}
fn add_block(&mut self, nid: Nid) -> RallocBRef {
if let Some(prev) = self.blocks.last_mut() {
prev.instrs = regalloc2::InstRange::new(
prev.instrs.first(),
regalloc2::Inst::new(self.instrs.len()),
);
}
self.blocks.push(Block {
nid,
preds: Default::default(),
succs: Default::default(),
instrs: regalloc2::InstRange::new(
regalloc2::Inst::new(self.instrs.len()),
regalloc2::Inst::new(self.instrs.len() + 1),
),
params: Default::default(),
branch_blockparams: Default::default(),
});
self.blocks.len() as RallocBRef - 1
}
fn add_instr(&mut self, nid: Nid, ops: Vec<regalloc2::Operand>) {
self.instrs.push(Instr { nid, ops });
}
fn urg(&mut self, nid: Nid) -> regalloc2::Operand {
regalloc2::Operand::reg_use(self.rg(nid))
}
fn drg(&mut self, nid: Nid) -> regalloc2::Operand {
regalloc2::Operand::reg_def(self.rg(nid))
}
fn rg(&self, nid: Nid) -> VReg {
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debug_assert!(
!self.nodes.is_cfg(nid) || matches!(self.nodes[nid].kind, Kind::Call { .. }),
"{:?}",
self.nodes[nid]
);
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debug_assert_eq!(self.nodes[nid].lock_rc, 0, "{:?}", self.nodes[nid]);
debug_assert!(self.nodes[nid].kind != Kind::Phi || self.nodes[nid].ty != ty::Id::VOID);
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regalloc2::VReg::new(nid as _, regalloc2::RegClass::Int)
}
fn emit_node(&mut self, nid: Nid, prev: Nid) {
if matches!(self.nodes[nid].kind, Kind::Region | Kind::Loop) {
let prev_bref = self.nodes[prev].ralloc_backref;
let node = self.nodes[nid].clone();
let idx = 1 + node.inputs.iter().position(|&i| i == prev).unwrap();
for ph in node.outputs {
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if self.nodes[ph].kind != Kind::Phi || self.nodes[ph].ty == ty::Id::VOID {
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continue;
}
let rg = self.rg(self.nodes[ph].inputs[idx]);
self.blocks[prev_bref as usize].branch_blockparams.push(rg);
}
self.add_instr(nid, vec![]);
match (self.nodes[nid].kind, self.nodes.visited.set(nid)) {
(Kind::Loop, false) => {
for i in node.inputs {
self.bridge(i, nid);
}
return;
}
(Kind::Region, true) => return,
_ => {}
}
} else if !self.nodes.visited.set(nid) {
return;
}
let node = self.nodes[nid].clone();
match node.kind {
Kind::Start => {
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debug_assert_matches!(self.nodes[node.outputs[0]].kind, Kind::Entry);
self.emit_node(node.outputs[0], VOID)
}
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Kind::End => {}
Kind::If => {
self.nodes[nid].ralloc_backref = self.nodes[prev].ralloc_backref;
let &[_, cond] = node.inputs.as_slice() else { unreachable!() };
let &[mut then, mut else_] = node.outputs.as_slice() else { unreachable!() };
if let Kind::BinOp { op } = self.nodes[cond].kind
&& let Some((_, swapped)) = op.cond_op(node.ty.is_signed())
{
if swapped {
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core::mem::swap(&mut then, &mut else_);
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}
let &[_, lhs, rhs] = self.nodes[cond].inputs.as_slice() else { unreachable!() };
let ops = vec![self.urg(lhs), self.urg(rhs)];
self.add_instr(nid, ops);
} else {
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core::mem::swap(&mut then, &mut else_);
let ops = vec![self.urg(cond)];
self.add_instr(nid, ops);
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}
self.emit_node(then, nid);
self.emit_node(else_, nid);
}
Kind::Region | Kind::Loop => {
self.nodes[nid].ralloc_backref = self.add_block(nid);
if node.kind == Kind::Region {
for i in node.inputs {
self.bridge(i, nid);
}
}
let mut block = vec![];
for ph in node.outputs.clone() {
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if self.nodes[ph].kind != Kind::Phi || self.nodes[ph].ty == ty::Id::VOID {
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continue;
}
block.push(self.rg(ph));
}
self.blocks[self.nodes[nid].ralloc_backref as usize].params = block;
for o in node.outputs.into_iter().rev() {
self.emit_node(o, nid);
}
}
Kind::Return => {
let ops = match self.tys.parama(self.sig.ret).0 {
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None => vec![],
Some(PLoc::Reg(..)) if self.sig.ret.loc(self.tys) == Loc::Stack => {
vec![self.urg(self.nodes[node.inputs[1]].inputs[1])]
}
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Some(PLoc::Reg(r, ..)) => {
vec![regalloc2::Operand::reg_fixed_use(
self.rg(node.inputs[1]),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
)]
}
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Some(PLoc::WideReg(..)) => {
vec![self.urg(self.nodes[node.inputs[1]].inputs[1])]
}
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Some(PLoc::Ref(..)) => {
vec![self.urg(self.nodes[node.inputs[1]].inputs[1]), self.urg(MEM)]
}
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};
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self.add_instr(nid, ops);
self.emit_node(node.outputs[0], nid);
}
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Kind::CInt { .. }
if node.outputs.iter().all(|&o| {
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let ond = &self.nodes[o];
matches!(ond.kind, Kind::BinOp { op }
if op.imm_binop(ond.ty.is_signed(), 8).is_some()
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&& self.nodes.is_const(ond.inputs[2])
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&& op.cond_op(ond.ty.is_signed()).is_none())
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}) =>
{
self.nodes.lock(nid)
}
Kind::CInt { .. } => {
let ops = vec![self.drg(nid)];
self.add_instr(nid, ops);
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}
Kind::Extend => {
let ops = vec![self.drg(nid), self.urg(node.inputs[1])];
self.add_instr(nid, ops);
}
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Kind::Entry => {
self.nodes[nid].ralloc_backref = self.add_block(nid);
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let (ret, mut parama) = self.tys.parama(self.sig.ret);
let mut typs = self.sig.args.args();
#[allow(clippy::unnecessary_to_owned)]
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let mut args = self.nodes[VOID].outputs[2..].to_owned().into_iter();
while let Some(ty) = typs.next_value(self.tys) {
let arg = args.next().unwrap();
match parama.next(ty, self.tys) {
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None => {}
Some(PLoc::Reg(r, _) | PLoc::WideReg(r, _) | PLoc::Ref(r, _)) => {
self.add_instr(NEVER, vec![regalloc2::Operand::reg_fixed_def(
self.rg(arg),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
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)]);
}
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}
}
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if let Some(PLoc::Ref(r, ..)) = ret {
self.add_instr(NEVER, vec![regalloc2::Operand::reg_fixed_def(
self.rg(MEM),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
)]);
}
for o in node.outputs.into_iter().rev() {
self.emit_node(o, nid);
}
}
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Kind::Then | Kind::Else => {
self.nodes[nid].ralloc_backref = self.add_block(nid);
self.bridge(prev, nid);
for o in node.outputs.into_iter().rev() {
self.emit_node(o, nid);
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}
}
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Kind::BinOp { op: TokenKind::Add }
if self.nodes.is_const(node.inputs[2])
&& node.outputs.iter().all(|&n| {
(matches!(self.nodes[n].kind, Kind::Stre if self.nodes[n].inputs[2] == nid)
|| matches!(self.nodes[n].kind, Kind::Load if self.nodes[n].inputs[1] == nid))
&& self.nodes[n].ty.loc(self.tys) == Loc::Reg
}) =>
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{
self.nodes.lock(nid)
}
Kind::BinOp { op }
if op.cond_op(node.ty.is_signed()).is_some()
&& node.outputs.iter().all(|&n| self.nodes[n].kind == Kind::If) =>
{
self.nodes.lock(nid)
}
Kind::BinOp { .. } => {
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let &[_, lhs, rhs] = node.inputs.as_slice() else { unreachable!() };
let ops = if let Kind::CInt { .. } = self.nodes[rhs].kind
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&& self.nodes[rhs].lock_rc != 0
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{
vec![self.drg(nid), self.urg(lhs)]
} else {
vec![self.drg(nid), self.urg(lhs), self.urg(rhs)]
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};
self.add_instr(nid, ops);
}
Kind::UnOp { .. } => {
let ops = vec![self.drg(nid), self.urg(node.inputs[1])];
self.add_instr(nid, ops);
}
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Kind::Call { args, .. } => {
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self.nodes[nid].ralloc_backref = self.nodes[prev].ralloc_backref;
let mut ops = vec![];
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let (ret, mut parama) = self.tys.parama(node.ty);
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if ret.is_some() {
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ops.push(regalloc2::Operand::reg_fixed_def(
self.rg(nid),
regalloc2::PReg::new(1, regalloc2::RegClass::Int),
));
}
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let mut tys = args.args();
let mut args = node.inputs[1..].iter();
while let Some(ty) = tys.next_value(self.tys) {
let mut i = *args.next().unwrap();
let Some(loc) = parama.next(ty, self.tys) else { continue };
match loc {
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PLoc::Reg(r, _) if ty.loc(self.tys) == Loc::Reg => {
ops.push(regalloc2::Operand::reg_fixed_use(
self.rg(i),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
));
}
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PLoc::WideReg(..) | PLoc::Reg(..) => {
loop {
match self.nodes[i].kind {
Kind::Stre { .. } => i = self.nodes[i].inputs[2],
Kind::Load { .. } => i = self.nodes[i].inputs[1],
_ => break,
}
debug_assert_ne!(i, 0);
}
debug_assert!(i != 0);
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ops.push(self.urg(i));
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}
PLoc::Ref(r, _) => {
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loop {
match self.nodes[i].kind {
Kind::Stre { .. } => i = self.nodes[i].inputs[2],
Kind::Load { .. } => i = self.nodes[i].inputs[1],
_ => break,
}
debug_assert_ne!(i, 0);
}
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debug_assert!(i != 0);
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ops.push(regalloc2::Operand::reg_fixed_use(
self.rg(i),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
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));
}
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}
}
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if let Some(PLoc::Ref(r, _)) = ret {
ops.push(regalloc2::Operand::reg_fixed_use(
self.rg(*node.inputs.last().unwrap()),
regalloc2::PReg::new(r as _, regalloc2::RegClass::Int),
));
}
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self.add_instr(nid, ops);
for o in node.outputs.into_iter().rev() {
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if self.nodes[o].inputs[0] == nid
|| (matches!(self.nodes[o].kind, Kind::Loop | Kind::Region)
&& self.nodes[o].inputs[1] == nid)
{
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self.emit_node(o, nid);
}
}
}
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Kind::Global { .. } => {
let ops = vec![self.drg(nid)];
self.add_instr(nid, ops);
}
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Kind::Stck
if node.ty.loc(self.tys) == Loc::Reg && node.outputs.iter().all(|&n| {
matches!(self.nodes[n].kind, Kind::Stre | Kind::Load)
|| matches!(self.nodes[n].kind, Kind::BinOp { op: TokenKind::Add }
if self.nodes.is_const(self.nodes[n].inputs[2])
&& self.nodes[n]
.outputs
.iter()
.all(|&n| matches!(self.nodes[n].kind, Kind::Stre | Kind::Load)))
}) => {}
Kind::Stck if self.tys.size_of(node.ty) == 0 => self.nodes.lock(nid),
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Kind::Stck => {
let ops = vec![self.drg(nid)];
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self.add_instr(nid, ops);
}
Kind::Idk => {
let ops = vec![self.drg(nid)];
self.add_instr(nid, ops);
}
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Kind::Phi | Kind::Arg | Kind::Mem => {}
Kind::Load { .. } if node.ty.loc(self.tys) == Loc::Stack => {
self.nodes.lock(nid)
}
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Kind::Load { .. } => {
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let mut region = node.inputs[1];
if self.nodes[region].kind == (Kind::BinOp { op: TokenKind::Add })
&& self.nodes.is_const(self.nodes[region].inputs[2])
&& node.ty.loc(self.tys) == Loc::Reg
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{
region = self.nodes[region].inputs[1]
}
let ops = match self.nodes[region].kind {
Kind::Stck => vec![self.drg(nid)],
_ => vec![self.drg(nid), self.urg(region)],
};
self.add_instr(nid, ops);
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}
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Kind::Stre if node.inputs[2] == VOID => self.nodes.lock(nid),
Kind::Stre => {
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let mut region = node.inputs[2];
if self.nodes[region].kind == (Kind::BinOp { op: TokenKind::Add })
&& self.nodes.is_const(self.nodes[region].inputs[2])
&& node.ty.loc(self.tys) == Loc::Reg
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{
region = self.nodes[region].inputs[1]
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}
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let ops = match self.nodes[region].kind {
_ if node.ty.loc(self.tys) == Loc::Stack => {
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if self.nodes[node.inputs[1]].kind == Kind::Arg {
vec![self.urg(region), self.urg(node.inputs[1])]
} else {
vec![self.urg(region), self.urg(self.nodes[node.inputs[1]].inputs[1])]
}
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}
Kind::Stck => vec![self.urg(node.inputs[1])],
_ => vec![self.urg(region), self.urg(node.inputs[1])],
};
self.add_instr(nid, ops);
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}
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}
}
fn bridge(&mut self, pred: u16, succ: u16) {
if self.nodes[pred].ralloc_backref == u16::MAX
|| self.nodes[succ].ralloc_backref == u16::MAX
{
return;
}
self.blocks[self.nodes[pred].ralloc_backref as usize]
.succs
.push(regalloc2::Block::new(self.nodes[succ].ralloc_backref as usize));
self.blocks[self.nodes[succ].ralloc_backref as usize]
.preds
.push(regalloc2::Block::new(self.nodes[pred].ralloc_backref as usize));
}
}
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impl regalloc2::Function for Function<'_> {
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fn num_insts(&self) -> usize {
self.instrs.len()
}
fn num_blocks(&self) -> usize {
self.blocks.len()
}
fn entry_block(&self) -> regalloc2::Block {
regalloc2::Block(0)
}
fn block_insns(&self, block: regalloc2::Block) -> regalloc2::InstRange {
self.blocks[block.index()].instrs
}
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fn block_succs(&self, block: regalloc2::Block) -> &[regalloc2::Block] {
&self.blocks[block.index()].succs
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}
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fn block_preds(&self, block: regalloc2::Block) -> &[regalloc2::Block] {
&self.blocks[block.index()].preds
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}
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fn block_params(&self, block: regalloc2::Block) -> &[regalloc2::VReg] {
&self.blocks[block.index()].params
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}
fn is_ret(&self, insn: regalloc2::Inst) -> bool {
self.nodes[self.instrs[insn.index()].nid].kind == Kind::Return
}
fn is_branch(&self, insn: regalloc2::Inst) -> bool {
matches!(
self.nodes[self.instrs[insn.index()].nid].kind,
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Kind::If | Kind::Then | Kind::Else | Kind::Entry | Kind::Loop | Kind::Region
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)
}
fn branch_blockparams(
&self,
block: regalloc2::Block,
_insn: regalloc2::Inst,
_succ_idx: usize,
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) -> &[regalloc2::VReg] {
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debug_assert!(
self.blocks[block.index()].succs.len() == 1
|| self.blocks[block.index()].branch_blockparams.is_empty()
);
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&self.blocks[block.index()].branch_blockparams
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}
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fn inst_operands(&self, insn: regalloc2::Inst) -> &[regalloc2::Operand] {
&self.instrs[insn.index()].ops
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}
fn inst_clobbers(&self, insn: regalloc2::Inst) -> regalloc2::PRegSet {
let node = &self.nodes[self.instrs[insn.index()].nid];
if matches!(node.kind, Kind::Call { .. }) {
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let mut set = regalloc2::PRegSet::default();
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let returns = self.tys.parama(node.ty).0.is_some();
for i in 1 + returns as usize..13 {
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set.add(regalloc2::PReg::new(i, regalloc2::RegClass::Int));
}
set
} else {
regalloc2::PRegSet::default()
}
}
fn num_vregs(&self) -> usize {
self.nodes.values.len()
}
fn spillslot_size(&self, regclass: regalloc2::RegClass) -> usize {
match regclass {
regalloc2::RegClass::Int => 1,
regalloc2::RegClass::Float => unreachable!(),
regalloc2::RegClass::Vector => unreachable!(),
}
}
}
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fn loop_depth(target: Nid, nodes: &mut Nodes) -> LoopDepth {
if nodes[target].loop_depth != 0 {
return nodes[target].loop_depth;
}
nodes[target].loop_depth = match nodes[target].kind {
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Kind::Entry | Kind::Then | Kind::Else | Kind::Call { .. } | Kind::Return | Kind::If => {
let dpth = loop_depth(nodes[target].inputs[0], nodes);
if nodes[target].loop_depth != 0 {
return nodes[target].loop_depth;
}
dpth
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}
Kind::Region => {
let l = loop_depth(nodes[target].inputs[0], nodes);
let r = loop_depth(nodes[target].inputs[1], nodes);
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debug_assert_eq!(l, r);
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l
}
Kind::Loop => {
let depth = loop_depth(nodes[target].inputs[0], nodes) + 1;
nodes[target].loop_depth = depth;
let mut cursor = nodes[target].inputs[1];
while cursor != target {
nodes[cursor].loop_depth = depth;
let next = if nodes[cursor].kind == Kind::Region {
loop_depth(nodes[cursor].inputs[0], nodes);
nodes[cursor].inputs[1]
} else {
idom(nodes, cursor)
};
debug_assert_ne!(next, VOID);
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if matches!(nodes[cursor].kind, Kind::Then | Kind::Else) {
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let other = *nodes[next]
.outputs
.iter()
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.find(|&&n| nodes[n].kind != nodes[cursor].kind)
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.unwrap();
if nodes[other].loop_depth == 0 {
nodes[other].loop_depth = depth - 1;
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}
}
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cursor = next;
}
depth
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}
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Kind::Start | Kind::End => 1,
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u => unreachable!("{u:?}"),
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};
nodes[target].loop_depth
}
fn idepth(nodes: &mut Nodes, target: Nid) -> IDomDepth {
if target == VOID {
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return 0;
}
if nodes[target].depth == 0 {
nodes[target].depth = match nodes[target].kind {
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Kind::End | Kind::Start => unreachable!("{:?}", nodes[target].kind),
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Kind::Region => {
idepth(nodes, nodes[target].inputs[0]).max(idepth(nodes, nodes[target].inputs[1]))
}
_ => idepth(nodes, nodes[target].inputs[0]),
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} + 1;
}
nodes[target].depth
}
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fn push_up(nodes: &mut Nodes) {
fn collect_rpo(node: Nid, nodes: &mut Nodes, rpo: &mut Vec<Nid>) {
if !nodes.is_cfg(node) || !nodes.visited.set(node) {
return;
}
for i in 0..nodes[node].outputs.len() {
collect_rpo(nodes[node].outputs[i], nodes, rpo);
}
rpo.push(node);
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}
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fn push_up_impl(node: Nid, nodes: &mut Nodes) {
if !nodes.visited.set(node) {
return;
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}
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for i in 1..nodes[node].inputs.len() {
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let inp = nodes[node].inputs[i];
if !nodes[inp].kind.is_pinned() {
push_up_impl(inp, nodes);
}
}
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if nodes[node].kind.is_pinned() {
return;
}
let mut deepest = VOID;
for i in 1..nodes[node].inputs.len() {
let inp = nodes[node].inputs[i];
if idepth(nodes, inp) > idepth(nodes, deepest) {
deepest = idom(nodes, inp);
}
}
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if deepest == VOID {
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return;
}
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let index = nodes[0].outputs.iter().position(|&p| p == node).unwrap();
nodes[0].outputs.remove(index);
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nodes[node].inputs[0] = deepest;
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debug_assert!(
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!nodes[deepest].outputs.contains(&node)
|| matches!(nodes[deepest].kind, Kind::Call { .. }),
"{node} {:?} {deepest} {:?}",
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nodes[node],
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nodes[deepest]
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);
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nodes[deepest].outputs.push(node);
}
let mut rpo = vec![];
collect_rpo(VOID, nodes, &mut rpo);
for node in rpo.into_iter().rev() {
loop_depth(node, nodes);
for i in 0..nodes[node].inputs.len() {
push_up_impl(nodes[node].inputs[i], nodes);
}
if matches!(nodes[node].kind, Kind::Loop | Kind::Region) {
for i in 0..nodes[node].outputs.len() {
let usage = nodes[node].outputs[i];
if nodes[usage].kind == Kind::Phi {
push_up_impl(usage, nodes);
}
}
}
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}
debug_assert_eq!(
nodes
.iter()
.map(|(n, _)| n)
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.filter(|&n| !nodes.visited.get(n) && !matches!(nodes[n].kind, Kind::Arg | Kind::Mem))
.collect::<Vec<_>>(),
vec![],
"{:?}",
nodes
.iter()
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.filter(|&(n, nod)| !nodes.visited.get(n) && !matches!(nod.kind, Kind::Arg | Kind::Mem))
.collect::<Vec<_>>()
);
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}
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fn push_down(nodes: &mut Nodes, node: Nid) {
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fn is_forward_edge(usage: Nid, def: Nid, nodes: &mut Nodes) -> bool {
match nodes[usage].kind {
Kind::Phi => {
nodes[usage].inputs[2] != def || nodes[nodes[usage].inputs[0]].kind != Kind::Loop
}
Kind::Loop => nodes[usage].inputs[1] != def,
_ => true,
}
}
fn better(nodes: &mut Nodes, is: Nid, then: Nid) -> bool {
debug_assert_ne!(idepth(nodes, is), idepth(nodes, then), "{is} {then}");
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loop_depth(is, nodes) < loop_depth(then, nodes)
|| idepth(nodes, is) > idepth(nodes, then)
|| nodes[then].kind == Kind::If
}
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if !nodes.visited.set(node) {
return;
}
for usage in nodes[node].outputs.clone() {
if is_forward_edge(usage, node, nodes) && nodes[node].kind == Kind::Stre {
push_down(nodes, usage);
}
}
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for usage in nodes[node].outputs.clone() {
if is_forward_edge(usage, node, nodes) {
push_down(nodes, usage);
}
}
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if nodes[node].kind.is_pinned() {
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return;
}
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let mut min = None::<Nid>;
for i in 0..nodes[node].outputs.len() {
let usage = nodes[node].outputs[i];
let ub = use_block(node, usage, nodes);
min = min.map(|m| common_dom(ub, m, nodes)).or(Some(ub));
}
let mut min = min.unwrap();
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debug_assert!(nodes.dominates(nodes[node].inputs[0], min));
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let mut cursor = min;
while cursor != nodes[node].inputs[0] {
cursor = idom(nodes, cursor);
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if better(nodes, cursor, min) {
min = cursor;
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}
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}
if nodes[min].kind.ends_basic_block() {
min = idom(nodes, min);
}
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nodes.check_dominance(node, min, true);
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let prev = nodes[node].inputs[0];
debug_assert!(idepth(nodes, min) >= idepth(nodes, prev));
let index = nodes[prev].outputs.iter().position(|&p| p == node).unwrap();
nodes[prev].outputs.remove(index);
nodes[node].inputs[0] = min;
nodes[min].outputs.push(node);
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}
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fn use_block(target: Nid, from: Nid, nodes: &mut Nodes) -> Nid {
if nodes[from].kind != Kind::Phi {
return idom(nodes, from);
}
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let index = nodes[from].inputs.iter().position(|&n| n == target).unwrap();
nodes[nodes[from].inputs[0]].inputs[index - 1]
}
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fn idom(nodes: &mut Nodes, target: Nid) -> Nid {
match nodes[target].kind {
Kind::Start => VOID,
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Kind::End => unreachable!(),
Kind::Region => {
let &[lcfg, rcfg] = nodes[target].inputs.as_slice() else { unreachable!() };
common_dom(lcfg, rcfg, nodes)
}
_ => nodes[target].inputs[0],
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}
}
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fn common_dom(mut a: Nid, mut b: Nid, nodes: &mut Nodes) -> Nid {
while a != b {
let [ldepth, rdepth] = [idepth(nodes, a), idepth(nodes, b)];
if ldepth >= rdepth {
a = idom(nodes, a);
}
if ldepth <= rdepth {
b = idom(nodes, b);
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}
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}
a
}
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#[cfg(test)]
mod tests {
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use {
alloc::{string::String, vec::Vec},
core::fmt::Write,
};
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fn generate(ident: &'static str, input: &'static str, output: &mut String) {
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_ = log::set_logger(&crate::fs::Logger);
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log::set_max_level(log::LevelFilter::Info);
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// log::set_max_level(log::LevelFilter::Trace);
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let (ref files, embeds) = crate::test_parse_files(ident, input);
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let mut codegen = super::Codegen { files, ..Default::default() };
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codegen.push_embeds(embeds);
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codegen.generate(0);
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{
let errors = codegen.errors.borrow();
if !errors.is_empty() {
output.push_str(&errors);
return;
}
}
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let mut out = Vec::new();
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codegen.tys.reassemble(&mut out);
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let err = codegen.tys.disasm(&out, codegen.files, output, |_| {});
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if let Err(e) = err {
writeln!(output, "!!! asm is invalid: {e}").unwrap();
return;
}
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crate::test_run_vm(&out, output);
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}
crate::run_tests! { generate:
// Tour Examples
main_fn;
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arithmetic;
functions;
comments;
if_statements;
variables;
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loops;
pointers;
structs;
hex_octal_binary_literals;
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struct_operators;
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global_variables;
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directives;
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c_strings;
struct_patterns;
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arrays;
inline;
idk;
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generic_functions;
// Incomplete Examples;
//comptime_pointers;
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generic_types;
fb_driver;
// Purely Testing Examples;
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returning_global_struct;
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small_struct_bitcast;
small_struct_assignment;
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intcast_store;
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string_flip;
wide_ret;
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comptime_min_reg_leak;
different_types;
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struct_return_from_module_function;
sort_something_viredly;
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structs_in_registers;
comptime_function_from_another_file;
inline_test;
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inlined_generic_functions;
some_generic_code;
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integer_inference_issues;
writing_into_string;
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request_page;
tests_ptr_to_ptr_copy;
// Just Testing Optimizations;
const_folding_with_arg;
branch_assignments;
exhaustive_loop_testing;
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pointer_opts;
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conditional_stores;
loop_stores;
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}
}