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nac3_sca/nac3core/src/typecheck/typedef.rs

627 lines
21 KiB
Rust
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use ena::unify::{InPlaceUnificationTable, NoError, UnifyKey, UnifyValue};
use generational_arena::{Arena, Index};
use std::cell::RefCell;
use std::collections::HashMap;
use std::iter::once;
use std::mem::swap;
use std::rc::Rc;
// Order:
// TVar
// |--> TSeq
// | |--> TTuple
// | `--> TList
// |--> TRecord
// | |--> TObj
// | `--> TVirtual
// `--> TCall
// `--> TFunc
#[derive(Copy, Clone, PartialEq, Eq, Debug)]
pub struct Type(u32);
#[derive(Copy, Clone, Debug, PartialEq, Eq)]
pub struct TypeIndex(Index);
impl UnifyValue for TypeIndex {
type Error = NoError;
fn unify_values(_: &Self, value2: &Self) -> Result<Self, Self::Error> {
// WARN: depends on the implementation details of ena.
// We do not use this to do unification, instead we perform unification
// and assign the type by `union_value(key, new_value)`, which set the
// value as `unify_values(key.value, new_value)`. So, we need to return
// the right one.
Ok(*value2)
}
}
impl UnifyKey for Type {
type Value = TypeIndex;
fn index(&self) -> u32 {
self.0
}
fn from_index(u: u32) -> Self {
Type(u)
}
fn tag() -> &'static str {
"TypeID"
}
}
pub type Mapping<K, V = Type> = HashMap<K, V>;
pub type VarMap = Mapping<u32>;
#[derive(Clone)]
pub struct Call {
posargs: Vec<Type>,
kwargs: HashMap<String, Type>,
ret: Type,
fun: RefCell<Option<Type>>,
}
#[derive(Clone)]
pub struct FuncArg {
name: String,
ty: Type,
is_optional: bool,
}
// We use a lot of `Rc`/`RefCell`s here as we want to simplify our code.
// We may not really need so much `Rc`s, but we would have to do complicated
// stuffs otherwise.
pub enum TypeEnum {
TVar {
// TODO: upper/lower bound
id: u32,
},
TSeq {
map: VarMap,
},
TTuple {
ty: Vec<Type>,
},
TList {
ty: Type,
},
TRecord {
fields: Mapping<String>,
},
TObj {
obj_id: usize,
fields: Mapping<String>,
params: VarMap,
},
TVirtual {
ty: Type,
},
TCall {
calls: Vec<Rc<Call>>,
},
TFunc {
args: Vec<FuncArg>,
ret: Type,
params: VarMap,
},
}
impl TypeEnum {
fn get_int(&self) -> i32 {
match self {
TypeEnum::TVar { .. } => 1,
TypeEnum::TSeq { .. } => 5,
TypeEnum::TTuple { .. } => 10,
TypeEnum::TList { .. } => 15,
TypeEnum::TRecord { .. } => 7,
TypeEnum::TObj { .. } => 14,
TypeEnum::TVirtual { .. } => 21,
TypeEnum::TCall { .. } => 11,
TypeEnum::TFunc { .. } => 22,
}
}
// e.g. List <: Var
pub fn kind_le(&self, other: &TypeEnum) -> bool {
let a = self.get_int();
let b = other.get_int();
(a % b) == 0
}
pub fn get_kind_name(&self) -> &'static str {
// this function is for debugging only...
// a proper to_str implementation requires the context
match self {
TypeEnum::TVar { .. } => "TVar",
TypeEnum::TSeq { .. } => "TSeq",
TypeEnum::TTuple { .. } => "TTuple",
TypeEnum::TList { .. } => "TList",
TypeEnum::TRecord { .. } => "TRecord",
TypeEnum::TObj { .. } => "TObj",
TypeEnum::TVirtual { .. } => "TVirtual",
TypeEnum::TCall { .. } => "TCall",
TypeEnum::TFunc { .. } => "TFunc",
}
}
}
pub struct ObjDef {
name: String,
fields: Mapping<String>,
}
pub struct Unifier {
unification_table: RefCell<InPlaceUnificationTable<Type>>,
type_arena: RefCell<Arena<Rc<RefCell<TypeEnum>>>>,
obj_def_table: Vec<ObjDef>,
}
impl Unifier {
pub fn new() -> Unifier {
Unifier {
unification_table: RefCell::new(InPlaceUnificationTable::new()),
type_arena: RefCell::new(Arena::new()),
obj_def_table: Vec::new(),
}
}
pub fn add_ty(&self, a: TypeEnum) -> Type {
let index = self.type_arena.borrow_mut().insert(Rc::new(a.into()));
self.unification_table
.borrow_mut()
.new_key(TypeIndex(index))
}
pub fn get_ty(&self, a: Type) -> Rc<RefCell<TypeEnum>> {
let mut table = self.unification_table.borrow_mut();
let arena = self.type_arena.borrow();
arena.get(table.probe_value(a).0).unwrap().clone()
}
pub fn unify(&self, mut a: Type, mut b: Type) -> Result<(), String> {
let (mut i_a, mut i_b) = {
let mut table = self.unification_table.borrow_mut();
(table.probe_value(a), table.probe_value(b))
};
if i_a == i_b {
return Ok(());
}
let (mut ty_a_cell, mut ty_b_cell) = {
let arena = self.type_arena.borrow();
(
arena.get(i_a.0).unwrap().clone(),
arena.get(i_b.0).unwrap().clone(),
)
};
let (ty_a, ty_b) = {
// simplify our pattern matching...
if ty_a_cell.borrow().kind_le(&ty_b_cell.borrow()) {
swap(&mut a, &mut b);
swap(&mut i_a, &mut i_b);
swap(&mut ty_a_cell, &mut ty_b_cell);
}
(ty_a_cell.borrow(), ty_b_cell.borrow())
};
self.occur_check(i_a, b)?;
match &*ty_a {
TypeEnum::TVar { .. } => {
// TODO: type variables bound check...
self.set_a_to_b(a, b);
}
TypeEnum::TSeq { map: map1 } => {
match &*ty_b {
TypeEnum::TSeq { .. } => {
drop(ty_b);
if let TypeEnum::TSeq { map: map2 } = &mut *ty_b_cell.as_ref().borrow_mut()
{
// unify them to map2
for (key, value) in map1.iter() {
if let Some(ty) = map2.get(key) {
self.unify(*ty, *value)?;
} else {
map2.insert(*key, *value);
}
}
} else {
unreachable!()
}
self.set_a_to_b(a, b);
}
TypeEnum::TTuple { ty: types } => {
let len = types.len() as u32;
for (k, v) in map1.iter() {
if *k >= len {
return Err(format!(
"Tuple index out of range. (Length: {}, Index: {})",
types.len(),
k
));
}
self.unify(*v, types[*k as usize])?;
}
self.set_a_to_b(a, b);
}
TypeEnum::TList { ty } => {
for v in map1.values() {
self.unify(*v, *ty)?;
}
self.set_a_to_b(a, b);
}
_ => {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
}
TypeEnum::TTuple { ty: ty1 } => {
if let TypeEnum::TTuple { ty: ty2 } = &*ty_b {
if ty1.len() != ty2.len() {
return Err(format!(
"Cannot unify tuples with length {} and {}",
ty1.len(),
ty2.len()
));
}
for (x, y) in ty1.iter().zip(ty2.iter()) {
self.unify(*x, *y)?;
}
self.set_a_to_b(a, b);
} else {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
TypeEnum::TList { ty: ty1 } => {
if let TypeEnum::TList { ty: ty2 } = *ty_b {
self.unify(*ty1, ty2)?;
self.set_a_to_b(a, b);
} else {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
TypeEnum::TRecord { fields: fields1 } => {
match &*ty_b {
TypeEnum::TRecord { .. } => {
drop(ty_b);
if let TypeEnum::TRecord { fields: fields2 } =
&mut *ty_b_cell.as_ref().borrow_mut()
{
for (key, value) in fields1.iter() {
if let Some(ty) = fields2.get(key) {
self.unify(*ty, *value)?;
} else {
fields2.insert(key.clone(), *value);
}
}
} else {
unreachable!()
}
self.set_a_to_b(a, b);
}
TypeEnum::TObj {
fields: fields2, ..
} => {
for (key, value) in fields1.iter() {
if let Some(ty) = fields2.get(key) {
self.unify(*ty, *value)?;
} else {
return Err(format!("No such attribute {}", key));
}
}
self.set_a_to_b(a, b);
}
TypeEnum::TVirtual { ty } => {
// not sure if this is correct...
self.unify(a, *ty)?;
self.set_a_to_b(a, b);
}
_ => {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
}
TypeEnum::TObj {
obj_id: id1,
params: params1,
..
} => {
if let TypeEnum::TObj {
obj_id: id2,
params: params2,
..
} = &*ty_b
{
if id1 != id2 {
return Err(format!("Cannot unify objects with ID {} and {}", id1, id2));
}
for (x, y) in params1.values().zip(params2.values()) {
self.unify(*x, *y)?;
}
self.set_a_to_b(a, b);
} else {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
TypeEnum::TVirtual { ty: ty1 } => {
if let TypeEnum::TVirtual { ty: ty2 } = &*ty_b {
self.unify(*ty1, *ty2)?;
self.set_a_to_b(a, b);
} else {
return self.report_kind_error(&*ty_a, &*ty_b);
}
}
_ => unimplemented!(),
}
Ok(())
}
fn set_a_to_b(&self, a: Type, b: Type) {
// unify a and b together, and set the value to b's value this would
// also deallocate a's previous value in the arena to save space...
let mut table = self.unification_table.borrow_mut();
let i_a = table.probe_value(a);
let i_b = table.probe_value(b);
table.union(a, b);
table.union_value(a, i_b);
self.type_arena.borrow_mut().remove(i_a.0);
}
fn report_kind_error(&self, a: &TypeEnum, b: &TypeEnum) -> Result<(), String> {
Err(format!(
"Cannot unify {} with {}",
a.get_kind_name(),
b.get_kind_name()
))
}
fn occur_check(&self, a: TypeIndex, b: Type) -> Result<(), String> {
let i_b = self.unification_table.borrow_mut().probe_value(b);
if a == i_b {
return Err("Recursive type is prohibited.".to_owned());
}
let ty = self.type_arena.borrow().get(i_b.0).unwrap().clone();
let ty = ty.borrow();
match &*ty {
TypeEnum::TVar { .. } => {
// TODO: occur check for bounds...
}
TypeEnum::TSeq { map } | TypeEnum::TObj { params: map, .. } => {
for t in map.values() {
self.occur_check(a, *t)?;
}
}
TypeEnum::TTuple { ty } => {
for t in ty.iter() {
self.occur_check(a, *t)?;
}
}
TypeEnum::TList { ty } | TypeEnum::TVirtual { ty } => {
self.occur_check(a, *ty)?;
}
TypeEnum::TRecord { fields } => {
for t in fields.values() {
self.occur_check(a, *t)?;
}
}
TypeEnum::TCall { calls } => {
for t in calls
.iter()
.map(|call| {
call.posargs
.iter()
.chain(call.kwargs.values())
.chain(once(&call.ret))
})
.flatten()
{
self.occur_check(a, *t)?;
}
}
TypeEnum::TFunc { args, ret, params } => {
for t in args
.iter()
.map(|v| &v.ty)
.chain(params.values())
.chain(once(ret))
{
self.occur_check(a, *t)?;
}
}
};
Ok(())
}
pub fn subst(&self, a: Type, mapping: &VarMap) -> Option<Type> {
let index = self.unification_table.borrow_mut().probe_value(a);
let ty_cell = {
let arena = self.type_arena.borrow();
arena.get(index.0).unwrap().clone()
};
let ty = ty_cell.borrow();
// this function would only be called when we instantiate functions.
// function type signature should ONLY contain concrete types and type
// variables, i.e. things like TRecord, TCall should not occur, and we
// should be safe to not implement the substitution for those variants.
match &*ty {
TypeEnum::TVar { id } => mapping.get(&id).cloned(),
TypeEnum::TSeq { map } => self.subst_map(map, mapping).map(|m| {
let index = self
.type_arena
.borrow_mut()
.insert(Rc::new(TypeEnum::TSeq { map: m }.into()));
self.unification_table
.borrow_mut()
.new_key(TypeIndex(index))
}),
TypeEnum::TTuple { ty } => {
let mut new_ty = None;
for (i, t) in ty.iter().enumerate() {
if let Some(t1) = self.subst(*t, mapping) {
if new_ty.is_none() {
new_ty = Some(ty.clone());
}
new_ty.as_mut().unwrap()[i] = t1;
}
}
new_ty.map(|t| self.add_ty(TypeEnum::TTuple { ty: t }))
}
TypeEnum::TList { ty } => self
.subst(*ty, mapping)
.map(|t| self.add_ty(TypeEnum::TList { ty: t })),
TypeEnum::TVirtual { ty } => self
.subst(*ty, mapping)
.map(|t| self.add_ty(TypeEnum::TVirtual { ty: t })),
TypeEnum::TObj {
obj_id,
fields,
params,
} => {
// Type variables in field types must be present in the type parameter.
// If the mapping does not contain any type variables in the
// parameter list, we don't need to substitute the fields.
// This is also used to prevent infinite substitution...
let need_subst = params.values().any(|v| {
let index = self.unification_table.borrow_mut().probe_value(*v);
let arena = self.type_arena.borrow();
let ty_cell = arena.get(index.0).unwrap();
let ty = ty_cell.borrow();
if let TypeEnum::TVar { id } = &*ty {
mapping.contains_key(id)
} else {
false
}
});
if need_subst {
let obj_id = *obj_id;
let params = self
.subst_map(&params, mapping)
.unwrap_or_else(|| params.clone());
let fields = self
.subst_map(&fields, mapping)
.unwrap_or_else(|| fields.clone());
Some(self.add_ty(TypeEnum::TObj {
obj_id,
params,
fields,
}))
} else {
None
}
}
TypeEnum::TFunc { args, ret, params } => {
let new_params = self.subst_map(params, mapping);
let new_ret = self.subst(*ret, mapping);
let mut new_args = None;
for (i, t) in args.iter().enumerate() {
if let Some(t1) = self.subst(t.ty, mapping) {
if new_args.is_none() {
new_args = Some(args.clone());
}
new_args.as_mut().unwrap()[i] = FuncArg {
name: t.name.clone(),
ty: t1,
is_optional: t.is_optional,
};
}
}
if new_params.is_some() || new_ret.is_some() || new_args.is_some() {
let params = new_params.unwrap_or_else(|| params.clone());
let ret = new_ret.unwrap_or_else(|| *ret);
let args = new_args.unwrap_or_else(|| args.clone());
Some(self.add_ty(TypeEnum::TFunc { params, ret, args }))
} else {
None
}
}
_ => unimplemented!(),
}
}
fn subst_map<K>(&self, map: &Mapping<K>, mapping: &VarMap) -> Option<Mapping<K>>
where
K: std::hash::Hash + std::cmp::Eq + std::clone::Clone,
{
let mut map2 = None;
for (k, v) in map.iter() {
if let Some(v1) = self.subst(*v, mapping) {
if map2.is_none() {
map2 = Some(map.clone());
}
*map2.as_mut().unwrap().get_mut(k).unwrap() = v1;
}
}
map2
}
pub fn eq(&self, a: Type, b: Type) -> bool {
if a == b {
return true;
}
let (i_a, i_b) = {
let mut table = self.unification_table.borrow_mut();
(table.probe_value(a), table.probe_value(b))
};
if i_a == i_b {
return true;
}
let (ty_a, ty_b) = {
let arena = self.type_arena.borrow();
(
arena.get(i_a.0).unwrap().clone(),
arena.get(i_b.0).unwrap().clone(),
)
};
let ty_a = ty_a.borrow();
let ty_b = ty_b.borrow();
match (&*ty_a, &*ty_b) {
(TypeEnum::TVar { id: id1 }, TypeEnum::TVar { id: id2 }) => id1 == id2,
(TypeEnum::TSeq { map: map1 }, TypeEnum::TSeq { map: map2 }) => self.map_eq(map1, map2),
(TypeEnum::TTuple { ty: ty1 }, TypeEnum::TTuple { ty: ty2 }) => {
ty1.len() == ty2.len()
&& ty1.iter().zip(ty2.iter()).all(|(t1, t2)| self.eq(*t1, *t2))
}
(TypeEnum::TList { ty: ty1 }, TypeEnum::TList { ty: ty2 })
| (TypeEnum::TVirtual { ty: ty1 }, TypeEnum::TVirtual { ty: ty2 }) => {
self.eq(*ty1, *ty2)
}
(TypeEnum::TRecord { fields: fields1 }, TypeEnum::TRecord { fields: fields2 }) => {
self.map_eq(fields1, fields2)
}
(
TypeEnum::TObj {
obj_id: id1,
params: params1,
..
},
TypeEnum::TObj {
obj_id: id2,
params: params2,
..
},
) => id1 == id2 && self.map_eq(params1, params2),
// TCall and TFunc are not yet implemented
_ => false,
}
}
fn map_eq<K>(&self, map1: &Mapping<K>, map2: &Mapping<K>) -> bool
where
K: std::hash::Hash + std::cmp::Eq + std::clone::Clone,
{
if map1.len() != map2.len() {
return false;
}
for (k, v) in map1.iter() {
if !map2.get(k).map(|v1| self.eq(*v, *v1)).unwrap_or(false) {
return false;
}
}
true
}
}
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