nac3/nac3core/src/toplevel/composer.rs

1093 lines
49 KiB
Rust

use super::*;
pub struct TopLevelComposer {
// list of top level definitions, same as top level context
pub definition_ast_list: Vec<(Arc<RwLock<TopLevelDef>>, Option<ast::Stmt<()>>)>,
// start as a primitive unifier, will add more top_level defs inside
pub unifier: Unifier,
// primitive store
pub primitives_ty: PrimitiveStore,
// keyword list to prevent same user-defined name
pub keyword_list: HashSet<String>,
// to prevent duplicate definition
pub defined_class_name: HashSet<String>,
pub defined_class_method_name: HashSet<String>,
pub defined_function_name: HashSet<String>,
}
impl Default for TopLevelComposer {
fn default() -> Self {
Self::new()
}
}
impl TopLevelComposer {
/// return a composer and things to make a "primitive" symbol resolver, so that the symbol
/// resolver can later figure out primitive type definitions when passed a primitive type name
pub fn new() -> Self {
let primitives = Self::make_primitives();
TopLevelComposer {
definition_ast_list: {
let top_level_def_list = vec![
Arc::new(RwLock::new(Self::make_top_level_class_def(0, None, "int32"))),
Arc::new(RwLock::new(Self::make_top_level_class_def(1, None, "int64"))),
Arc::new(RwLock::new(Self::make_top_level_class_def(2, None, "float"))),
Arc::new(RwLock::new(Self::make_top_level_class_def(3, None, "bool"))),
Arc::new(RwLock::new(Self::make_top_level_class_def(4, None, "none"))),
];
let ast_list: Vec<Option<ast::Stmt<()>>> = vec![None, None, None, None, None];
izip!(top_level_def_list, ast_list).collect_vec()
},
primitives_ty: primitives.0,
unifier: primitives.1,
keyword_list: HashSet::from_iter(vec![
"Generic".into(),
"virtual".into(),
"list".into(),
"tuple".into(),
"int32".into(),
"int64".into(),
"float".into(),
"bool".into(),
"none".into(),
"None".into(),
"self".into(),
"Kernel".into(),
"KernelImmutable".into(),
]),
defined_class_method_name: Default::default(),
defined_class_name: Default::default(),
defined_function_name: Default::default(),
}
}
pub fn make_top_level_context(self) -> TopLevelContext {
TopLevelContext {
definitions: RwLock::new(
self.definition_ast_list.into_iter().map(|(x, ..)| x).collect_vec(),
)
.into(),
// FIXME: all the big unifier or?
unifiers: Default::default(),
}
}
fn extract_def_list(&self) -> Vec<Arc<RwLock<TopLevelDef>>> {
self.definition_ast_list.iter().map(|(def, ..)| def.clone()).collect_vec()
}
/// register, just remeber the names of top level classes/function
/// and check duplicate class/method/function definition
pub fn register_top_level(
&mut self,
ast: ast::Stmt<()>,
resolver: Option<Arc<Box<dyn SymbolResolver + Send + Sync>>>,
mod_path: String,
) -> Result<(String, DefinitionId), String> {
let defined_class_name = &mut self.defined_class_name;
let defined_class_method_name = &mut self.defined_class_method_name;
let defined_function_name = &mut self.defined_function_name;
match &ast.node {
ast::StmtKind::ClassDef { name, body, .. } => {
if self.keyword_list.contains(name) {
return Err("cannot use keyword as a class name".into());
}
if !defined_class_name.insert({
let mut n = mod_path.clone();
n.push_str(name.as_str());
n
}) {
return Err("duplicate definition of class".into());
}
let class_name = name.to_string();
let class_def_id = self.definition_ast_list.len();
// since later when registering class method, ast will still be used,
// here push None temporarly, later will move the ast inside
let mut class_def_ast = (
Arc::new(RwLock::new(Self::make_top_level_class_def(
class_def_id,
resolver.clone(),
name,
))),
None,
);
// parse class def body and register class methods into the def list.
// module's symbol resolver would not know the name of the class methods,
// thus cannot return their definition_id
let mut class_method_name_def_ids: Vec<(
// the simple method name without class name
String,
// in this top level def, method name is prefixed with the class name
Arc<RwLock<TopLevelDef>>,
DefinitionId,
Type,
)> = Vec::new();
// we do not push anything to the def list, so we keep track of the index
// and then push in the correct order after the for loop
let mut class_method_index_offset = 0;
let mut has_init = false;
for b in body {
if let ast::StmtKind::FunctionDef { name: method_name, .. } = &b.node {
if self.keyword_list.contains(name) {
return Err("cannot use keyword as a method name".into());
}
let global_class_method_name =
Self::make_class_method_name(class_name.clone(), method_name);
if !defined_class_method_name.insert({
let mut n = mod_path.clone();
n.push_str(global_class_method_name.as_str());
n
}) {
return Err("duplicate class method definition".into());
}
if method_name == "__init__" {
has_init = true;
}
let method_def_id = self.definition_ast_list.len() + {
// plus 1 here since we already have the class def
class_method_index_offset += 1;
class_method_index_offset
};
// dummy method define here
let dummy_method_type = self.unifier.get_fresh_var();
class_method_name_def_ids.push((
method_name.clone(),
RwLock::new(Self::make_top_level_function_def(
global_class_method_name,
// later unify with parsed type
dummy_method_type.0,
resolver.clone(),
))
.into(),
DefinitionId(method_def_id),
dummy_method_type.0,
));
} else {
// do nothing
continue;
}
}
if !has_init {
return Err("class def must have __init__ method defined".into());
}
// move the ast to the entry of the class in the ast_list
class_def_ast.1 = Some(ast);
// get the methods into the top level class_def
for (name, _, id, ty) in &class_method_name_def_ids {
let mut class_def = class_def_ast.0.write();
if let TopLevelDef::Class { methods, .. } = class_def.deref_mut() {
methods.push((name.clone(), *ty, *id))
} else {
unreachable!()
}
}
// now class_def_ast and class_method_def_ast_ids are ok, put them into actual def list in correct order
self.definition_ast_list.push(class_def_ast);
for (_, def, ..) in class_method_name_def_ids {
self.definition_ast_list.push((def, None));
}
// put the constructor into the def_list
self.definition_ast_list.push((
RwLock::new(TopLevelDef::Initializer { class_id: DefinitionId(class_def_id) })
.into(),
None,
));
Ok((class_name, DefinitionId(class_def_id)))
}
ast::StmtKind::FunctionDef { name, .. } => {
if self.keyword_list.contains(name) {
return Err("cannot use keyword as a top level function name".into());
}
let fun_name = name.to_string();
if !defined_function_name.insert({
let mut n = mod_path.clone();
n.push_str(name.as_str());
n
}) {
return Err("duplicate top level function define".into());
}
// add to the definition list
self.definition_ast_list.push((
RwLock::new(Self::make_top_level_function_def(
name.into(),
// dummy here, unify with correct type later
self.unifier.get_fresh_var().0,
resolver,
))
.into(),
Some(ast),
));
// return
Ok((fun_name, DefinitionId(self.definition_ast_list.len() - 1)))
}
_ => Err("only registrations of top level classes/functions are supprted".into()),
}
}
pub fn start_analysis(&mut self) -> Result<(), String> {
self.analyze_top_level_class_type_var()?;
self.analyze_top_level_class_bases()?;
self.analyze_top_level_class_fields_methods()?;
self.analyze_top_level_function()?;
Ok(())
}
/// step 1, analyze the type vars associated with top level class
fn analyze_top_level_class_type_var(&mut self) -> Result<(), String> {
let def_list = &self.definition_ast_list;
let temp_def_list = self.extract_def_list();
let unifier = self.unifier.borrow_mut();
let primitives_store = &self.primitives_ty;
// skip 5 to skip analyzing the primitives
for (class_def, class_ast) in def_list.iter().skip(5) {
// only deal with class def here
let mut class_def = class_def.write();
let (class_bases_ast, class_def_type_vars, class_resolver) = {
if let TopLevelDef::Class { type_vars, resolver, .. } = class_def.deref_mut() {
if let Some(ast::Located {
node: ast::StmtKind::ClassDef { bases, .. }, ..
}) = class_ast
{
(bases, type_vars, resolver)
} else {
unreachable!("must be both class")
}
} else {
continue;
}
};
let class_resolver = class_resolver.as_ref().unwrap();
let class_resolver = class_resolver.deref();
let mut is_generic = false;
for b in class_bases_ast {
match &b.node {
// analyze typevars bounded to the class,
// only support things like `class A(Generic[T, V])`,
// things like `class A(Generic[T, V, ImportedModule.T])` is not supported
// i.e. only simple names are allowed in the subscript
// should update the TopLevelDef::Class.typevars and the TypeEnum::TObj.params
ast::ExprKind::Subscript { value, slice, .. }
if {
matches!(
&value.node,
ast::ExprKind::Name { id, .. } if id == "Generic"
)
} =>
{
if !is_generic {
is_generic = true;
} else {
return Err("Only single Generic[...] can be in bases".into());
}
let type_var_list: Vec<&ast::Expr<()>>;
// if `class A(Generic[T, V, G])`
if let ast::ExprKind::Tuple { elts, .. } = &slice.node {
type_var_list = elts.iter().collect_vec();
// `class A(Generic[T])`
} else {
type_var_list = vec![slice.deref()];
}
// parse the type vars
let type_vars = type_var_list
.into_iter()
.map(|e| {
class_resolver.parse_type_annotation(
&temp_def_list,
unifier,
primitives_store,
e,
)
})
.collect::<Result<Vec<_>, _>>()?;
// check if all are unique type vars
let all_unique_type_var = {
let mut occured_type_var_id: HashSet<u32> = HashSet::new();
type_vars.iter().all(|x| {
let ty = unifier.get_ty(*x);
if let TypeEnum::TVar { id, .. } = ty.as_ref() {
occured_type_var_id.insert(*id)
} else {
false
}
})
};
if !all_unique_type_var {
return Err("expect unique type variables".into());
}
// add to TopLevelDef
class_def_type_vars.extend(type_vars);
}
// if others, do nothing in this function
_ => continue,
}
}
}
Ok(())
}
/// step 2, base classes.
/// now that the type vars of all classes are done, handle base classes and
/// put Self class into the ancestors list. We only allow single inheritance
fn analyze_top_level_class_bases(&mut self) -> Result<(), String> {
let temp_def_list = self.extract_def_list();
let unifier = self.unifier.borrow_mut();
// first, only push direct parent into the list
// skip 5 to skip analyzing the primitives
for (class_def, class_ast) in self.definition_ast_list.iter_mut().skip(5) {
let mut class_def = class_def.write();
let (class_def_id, class_bases, class_ancestors, class_resolver, class_type_vars) = {
if let TopLevelDef::Class { ancestors, resolver, object_id, type_vars, .. } =
class_def.deref_mut()
{
if let Some(ast::Located {
node: ast::StmtKind::ClassDef { bases, .. }, ..
}) = class_ast
{
(object_id, bases, ancestors, resolver, type_vars)
} else {
unreachable!("must be both class")
}
} else {
continue;
}
};
let class_resolver = class_resolver.as_ref().unwrap();
let class_resolver = class_resolver.deref();
let mut has_base = false;
for b in class_bases {
// type vars have already been handled, so skip on `Generic[...]`
if matches!(
&b.node,
ast::ExprKind::Subscript { value, .. }
if matches!(
&value.node,
ast::ExprKind::Name { id, .. } if id == "Generic"
)
) {
continue;
}
if has_base {
return Err("a class def can only have at most one base class \
declaration and one generic declaration"
.into());
}
has_base = true;
// the function parse_ast_to make sure that no type var occured in
// bast_ty if it is a CustomClassKind
let base_ty = parse_ast_to_type_annotation_kinds(
class_resolver.as_ref(),
&temp_def_list,
unifier,
&self.primitives_ty,
b,
vec![(*class_def_id, class_type_vars.clone())].into_iter().collect(),
)?;
if let TypeAnnotation::CustomClassKind { .. } = &base_ty {
class_ancestors.push(base_ty);
} else {
return Err("class base declaration can only be custom class".into());
}
}
}
// second, get all ancestors
let mut ancestors_store: HashMap<DefinitionId, Vec<TypeAnnotation>> = Default::default();
// skip 5 to skip analyzing the primitives
for (class_def, _) in self.definition_ast_list.iter().skip(5) {
let class_def = class_def.read();
let (class_ancestors, class_id) = {
if let TopLevelDef::Class { ancestors, object_id, .. } = class_def.deref() {
(ancestors, *object_id)
} else {
continue;
}
};
ancestors_store.insert(
class_id,
// if class has direct parents, get all ancestors of its parents. Else just empty
if class_ancestors.is_empty() {
vec![]
} else {
Self::get_all_ancestors_helper(&class_ancestors[0], temp_def_list.as_slice())?
},
);
}
// insert the ancestors to the def list
// skip 5 to skip analyzing the primitives
for (class_def, _) in self.definition_ast_list.iter_mut().skip(5) {
let mut class_def = class_def.write();
let (class_ancestors, class_id, class_type_vars) = {
if let TopLevelDef::Class { ancestors, object_id, type_vars, .. } =
class_def.deref_mut()
{
(ancestors, *object_id, type_vars)
} else {
continue;
}
};
let ans = ancestors_store.get_mut(&class_id).unwrap();
class_ancestors.append(ans);
// insert self type annotation to the front of the vector to maintain the order
class_ancestors
.insert(0, make_self_type_annotation(class_type_vars.as_slice(), class_id));
}
Ok(())
}
/// step 3, class fields and methods
fn analyze_top_level_class_fields_methods(&mut self) -> Result<(), String> {
let temp_def_list = self.extract_def_list();
let primitives = &self.primitives_ty;
let def_ast_list = &self.definition_ast_list;
let unifier = self.unifier.borrow_mut();
let mut type_var_to_concrete_def: HashMap<Type, TypeAnnotation> = HashMap::new();
// skip 5 to skip analyzing the primitives
for (class_def, class_ast) in def_ast_list.iter().skip(5) {
if matches!(&*class_def.read(), TopLevelDef::Class { .. }) {
Self::analyze_single_class_methods_fields(
class_def.clone(),
&class_ast.as_ref().unwrap().node,
&temp_def_list,
unifier,
primitives,
&mut type_var_to_concrete_def,
&self.keyword_list,
)?
}
}
// println!("type_var_to_concrete_def1: {:?}", type_var_to_concrete_def);
// handle the inheritanced methods and fields
let mut current_ancestor_depth: usize = 2;
loop {
let mut finished = true;
for (class_def, _) in def_ast_list.iter().skip(5) {
let mut class_def = class_def.write();
if let TopLevelDef::Class { ancestors, .. } = class_def.deref() {
// if the length of the ancestor is equal to the current depth
// it means that all the ancestors of the class is handled
if ancestors.len() == current_ancestor_depth {
finished = false;
Self::analyze_single_class_ancestors(
class_def.deref_mut(),
&temp_def_list,
unifier,
primitives,
&mut type_var_to_concrete_def,
)?;
}
}
}
if finished {
break;
} else {
current_ancestor_depth += 1;
}
if current_ancestor_depth > def_ast_list.len() + 1 {
unreachable!("cannot be longer than the whole top level def list")
}
}
// println!("type_var_to_concrete_def3: {:?}\n", type_var_to_concrete_def);
// unification of previously assigned typevar
for (ty, def) in type_var_to_concrete_def {
// println!(
// "{:?}_{} -> {:?}\n",
// ty,
// unifier.stringify(ty,
// &mut |id| format!("class{}", id),
// &mut |id| format!("tvar{}", id)
// ),
// def
// );
let target_ty =
get_type_from_type_annotation_kinds(&temp_def_list, unifier, primitives, &def)?;
unifier.unify(ty, target_ty)?;
}
Ok(())
}
/// step 4, after class methods are done, top level functions have nothing unknown
fn analyze_top_level_function(&mut self) -> Result<(), String> {
let def_list = &self.definition_ast_list;
let keyword_list = &self.keyword_list;
let temp_def_list = self.extract_def_list();
let unifier = self.unifier.borrow_mut();
let primitives_store = &self.primitives_ty;
// skip 5 to skip analyzing the primitives
for (function_def, function_ast) in def_list.iter().skip(5) {
let mut function_def = function_def.write();
let function_def = function_def.deref_mut();
let function_ast = if let Some(function_ast) = function_ast {
function_ast
} else {
// no ast, class method, continue
continue;
};
if let TopLevelDef::Function { signature: dummy_ty, resolver, var_id, .. } =
function_def
{
if let ast::StmtKind::FunctionDef { args, returns, .. } = &function_ast.node {
let resolver = resolver.as_ref();
let resolver = resolver.unwrap();
let resolver = resolver.deref();
let mut function_var_map: HashMap<u32, Type> = HashMap::new();
let arg_types = {
// make sure no duplicate parameter
let mut defined_paramter_name: HashSet<String> = HashSet::new();
let have_unique_fuction_parameter_name = args.args.iter().all(|x| {
defined_paramter_name.insert(x.node.arg.clone())
&& !keyword_list.contains(&x.node.arg)
});
if !have_unique_fuction_parameter_name {
return Err("top level function must have unique parameter names \
and names thould not be the same as the keywords"
.into());
}
args.args
.iter()
.map(|x| -> Result<FuncArg, String> {
let annotation = x
.node
.annotation
.as_ref()
.ok_or_else(|| {
"function parameter type annotation needed".to_string()
})?
.as_ref();
let type_annotation = parse_ast_to_type_annotation_kinds(
resolver.as_ref(),
temp_def_list.as_slice(),
unifier,
primitives_store,
annotation,
// NOTE: since only class need this, for function
// it should be fine to be empty map
HashMap::new(),
)?;
let type_vars_within =
get_type_var_contained_in_type_annotation(&type_annotation)
.into_iter()
.map(|x| -> Result<(u32, Type), String> {
if let TypeAnnotation::TypeVarKind(ty) = x {
Ok((Self::get_var_id(ty, unifier)?, ty))
} else {
unreachable!("must be type var annotation kind")
}
})
.collect::<Result<Vec<_>, _>>()?;
for (id, ty) in type_vars_within {
if let Some(prev_ty) = function_var_map.insert(id, ty) {
// if already have the type inserted, make sure they are the same thing
assert_eq!(prev_ty, ty);
}
}
let ty = get_type_from_type_annotation_kinds(
temp_def_list.as_ref(),
unifier,
primitives_store,
&type_annotation,
)?;
Ok(FuncArg {
name: x.node.arg.clone(),
ty,
default_value: Default::default(),
})
})
.collect::<Result<Vec<_>, _>>()?
};
let return_ty = {
if let Some(returns) = returns {
let return_ty_annotation = {
let return_annotation = returns.as_ref();
parse_ast_to_type_annotation_kinds(
resolver.as_ref(),
&temp_def_list,
unifier,
primitives_store,
return_annotation,
// NOTE: since only class need this, for function
// it should be fine to be empty map
HashMap::new(),
)?
};
let type_vars_within =
get_type_var_contained_in_type_annotation(&return_ty_annotation)
.into_iter()
.map(|x| -> Result<(u32, Type), String> {
if let TypeAnnotation::TypeVarKind(ty) = x {
Ok((Self::get_var_id(ty, unifier)?, ty))
} else {
unreachable!("must be type var here")
}
})
.collect::<Result<Vec<_>, _>>()?;
for (id, ty) in type_vars_within {
if let Some(prev_ty) = function_var_map.insert(id, ty) {
// if already have the type inserted, make sure they are the same thing
assert_eq!(prev_ty, ty);
}
}
get_type_from_type_annotation_kinds(
&temp_def_list,
unifier,
primitives_store,
&return_ty_annotation,
)?
} else {
primitives_store.none
}
};
var_id.extend_from_slice(
function_var_map.keys().into_iter().copied().collect_vec().as_slice(),
);
let function_ty = unifier.add_ty(TypeEnum::TFunc(
FunSignature { args: arg_types, ret: return_ty, vars: function_var_map }
.into(),
));
unifier.unify(*dummy_ty, function_ty)?;
} else {
unreachable!("must be both function");
}
} else {
// not top level function def, skip
continue;
}
}
Ok(())
}
fn analyze_single_class_methods_fields(
class_def: Arc<RwLock<TopLevelDef>>,
class_ast: &ast::StmtKind<()>,
temp_def_list: &[Arc<RwLock<TopLevelDef>>],
unifier: &mut Unifier,
primitives: &PrimitiveStore,
type_var_to_concrete_def: &mut HashMap<Type, TypeAnnotation>,
keyword_list: &HashSet<String>,
) -> Result<(), String> {
let mut class_def = class_def.write();
let (
class_id,
_class_name,
_class_bases_ast,
class_body_ast,
_class_ancestor_def,
class_fields_def,
class_methods_def,
class_type_vars_def,
class_resolver,
) = if let TopLevelDef::Class {
object_id,
ancestors,
fields,
methods,
resolver,
type_vars,
..
} = class_def.deref_mut()
{
if let ast::StmtKind::ClassDef { name, bases, body, .. } = &class_ast {
(
*object_id,
name.clone(),
bases,
body,
ancestors,
fields,
methods,
type_vars,
resolver,
)
} else {
unreachable!("here must be class def ast");
}
} else {
unreachable!("here must be toplevel class def");
};
let class_resolver = class_resolver.as_ref().unwrap();
let class_resolver = class_resolver.as_ref();
let mut defined_fields: HashSet<String> = HashSet::new();
for b in class_body_ast {
if let ast::StmtKind::FunctionDef { args, returns, name, .. } = &b.node {
let (method_dummy_ty, method_id) =
Self::get_class_method_def_info(class_methods_def, name)?;
// the method var map can surely include the class's generic parameters
let mut method_var_map: HashMap<u32, Type> = class_type_vars_def
.iter()
.map(|ty| {
if let TypeEnum::TVar { id, .. } = unifier.get_ty(*ty).as_ref() {
(*id, *ty)
} else {
unreachable!("must be type var here")
}
})
.collect();
let arg_types: Vec<FuncArg> = {
// check method parameters cannot have same name
let mut defined_paramter_name: HashSet<String> = HashSet::new();
let have_unique_fuction_parameter_name = args.args.iter().all(|x| {
defined_paramter_name.insert(x.node.arg.clone())
&& (!keyword_list.contains(&x.node.arg) || x.node.arg == "self")
});
if !have_unique_fuction_parameter_name {
return Err("class method must have unique parameter names \
and names thould not be the same as the keywords"
.into());
}
if name == "__init__" && !defined_paramter_name.contains("self") {
return Err("__init__ function must have a `self` parameter".into());
}
if !defined_paramter_name.contains("self") {
return Err("currently does not support static method".into());
}
let mut result = Vec::new();
for x in &args.args {
let name = x.node.arg.clone();
if name != "self" {
let type_ann = {
let annotation_expr = x
.node
.annotation
.as_ref()
.ok_or_else(|| "type annotation needed".to_string())?
.as_ref();
parse_ast_to_type_annotation_kinds(
class_resolver.as_ref(),
temp_def_list,
unifier,
primitives,
annotation_expr,
vec![(class_id, class_type_vars_def.clone())]
.into_iter()
.collect(),
)?
};
// find type vars within this method parameter type annotation
let type_vars_within =
get_type_var_contained_in_type_annotation(&type_ann);
// handle the class type var and the method type var
for type_var_within in type_vars_within {
if let TypeAnnotation::TypeVarKind(ty) = type_var_within {
let id = Self::get_var_id(ty, unifier)?;
if let Some(prev_ty) = method_var_map.insert(id, ty) {
// if already in the list, make sure they are the same?
assert_eq!(prev_ty, ty);
}
} else {
unreachable!("must be type var annotation");
}
}
// finish handling type vars
let dummy_func_arg = FuncArg {
name,
ty: unifier.get_fresh_var().0,
// TODO: default value?
default_value: None,
};
// push the dummy type and the type annotation
// into the list for later unification
type_var_to_concrete_def.insert(dummy_func_arg.ty, type_ann.clone());
result.push(dummy_func_arg)
}
}
result
};
let ret_type = {
if let Some(result) = returns {
let result = result.as_ref();
let annotation = parse_ast_to_type_annotation_kinds(
class_resolver.as_ref(),
temp_def_list,
unifier,
primitives,
result,
vec![(class_id, class_type_vars_def.clone())].into_iter().collect(),
)?;
// find type vars within this return type annotation
let type_vars_within =
get_type_var_contained_in_type_annotation(&annotation);
// handle the class type var and the method type var
for type_var_within in type_vars_within {
if let TypeAnnotation::TypeVarKind(ty) = type_var_within {
let id = Self::get_var_id(ty, unifier)?;
if let Some(prev_ty) = method_var_map.insert(id, ty) {
// if already in the list, make sure they are the same?
assert_eq!(prev_ty, ty);
}
} else {
unreachable!("must be type var annotation");
}
}
let dummy_return_type = unifier.get_fresh_var().0;
type_var_to_concrete_def.insert(dummy_return_type, annotation.clone());
dummy_return_type
} else {
// if do not have return annotation, return none
// for uniform handling, still use type annoatation
let dummy_return_type = unifier.get_fresh_var().0;
type_var_to_concrete_def.insert(
dummy_return_type,
TypeAnnotation::PrimitiveKind(primitives.none),
);
dummy_return_type
}
};
if let TopLevelDef::Function { var_id, .. } =
temp_def_list.get(method_id.0).unwrap().write().deref_mut()
{
var_id.extend_from_slice(
method_var_map.keys().into_iter().copied().collect_vec().as_slice(),
);
}
let method_type = unifier.add_ty(TypeEnum::TFunc(
FunSignature { args: arg_types, ret: ret_type, vars: method_var_map }.into(),
));
// unify now since function type is not in type annotation define
// which should be fine since type within method_type will be subst later
unifier.unify(method_dummy_ty, method_type)?;
} else if let ast::StmtKind::AnnAssign { target, annotation, value: None, .. } = &b.node
{
if let ast::ExprKind::Name { id: attr, .. } = &target.node {
if defined_fields.insert(attr.to_string()) {
let dummy_field_type = unifier.get_fresh_var().0;
class_fields_def.push((attr.to_string(), dummy_field_type));
// handle Kernel[T], KernelImmutable[T]
let annotation = {
match &annotation.as_ref().node {
ast::ExprKind::Subscript { value, slice, .. }
if {
matches!(&value.node, ast::ExprKind::Name { id, .. } if id == "Kernel" || id == "KernelImmutable")
} =>
{
slice
}
_ => annotation,
}
};
let annotation = parse_ast_to_type_annotation_kinds(
class_resolver.as_ref(),
&temp_def_list,
unifier,
primitives,
annotation.as_ref(),
vec![(class_id, class_type_vars_def.clone())].into_iter().collect(),
)?;
// find type vars within this return type annotation
let type_vars_within =
get_type_var_contained_in_type_annotation(&annotation);
// handle the class type var and the method type var
for type_var_within in type_vars_within {
if let TypeAnnotation::TypeVarKind(t) = type_var_within {
if !class_type_vars_def.contains(&t) {
return Err("class fields can only use type \
vars declared as class generic type vars"
.into());
}
} else {
unreachable!("must be type var annotation");
}
}
type_var_to_concrete_def.insert(dummy_field_type, annotation);
} else {
return Err("same class fields defined twice".into());
}
}
} else {
return Err("unsupported statement type in class definition body".into());
}
}
Ok(())
}
fn analyze_single_class_ancestors(
class_def: &mut TopLevelDef,
temp_def_list: &[Arc<RwLock<TopLevelDef>>],
unifier: &mut Unifier,
_primitives: &PrimitiveStore,
type_var_to_concrete_def: &mut HashMap<Type, TypeAnnotation>,
) -> Result<(), String> {
let (
_class_id,
class_ancestor_def,
class_fields_def,
class_methods_def,
_class_type_vars_def,
_class_resolver,
) = if let TopLevelDef::Class {
object_id,
ancestors,
fields,
methods,
resolver,
type_vars,
..
} = class_def
{
(*object_id, ancestors, fields, methods, type_vars, resolver)
} else {
unreachable!("here must be class def ast");
};
// since when this function is called, the ancestors of the direct parent
// are supposed to be already handled, so we only need to deal with the direct parent
let base = class_ancestor_def.get(1).unwrap();
if let TypeAnnotation::CustomClassKind { id, params: _ } = base {
let base = temp_def_list.get(id.0).unwrap();
let base = base.read();
if let TopLevelDef::Class { methods, fields, .. } = &*base {
// handle methods override
// since we need to maintain the order, create a new list
let mut new_child_methods: Vec<(String, Type, DefinitionId)> = Vec::new();
let mut is_override: HashSet<String> = HashSet::new();
for (anc_method_name, anc_method_ty, anc_method_def_id) in methods {
// find if there is a method with same name in the child class
let mut to_be_added =
(anc_method_name.to_string(), *anc_method_ty, *anc_method_def_id);
for (class_method_name, class_method_ty, class_method_defid) in
class_methods_def.iter()
{
if class_method_name == anc_method_name {
// ignore and handle self
// if is __init__ method, no need to check return type
let ok = class_method_name == "__init__"
|| Self::check_overload_function_type(
*class_method_ty,
*anc_method_ty,
unifier,
type_var_to_concrete_def,
);
if !ok {
return Err("method has same name as ancestors' method, but incompatible type".into());
}
// mark it as added
is_override.insert(class_method_name.to_string());
to_be_added = (
class_method_name.to_string(),
*class_method_ty,
*class_method_defid,
);
break;
}
}
new_child_methods.push(to_be_added);
}
// add those that are not overriding method to the new_child_methods
for (class_method_name, class_method_ty, class_method_defid) in
class_methods_def.iter()
{
if !is_override.contains(class_method_name) {
new_child_methods.push((
class_method_name.to_string(),
*class_method_ty,
*class_method_defid,
));
}
}
// use the new_child_methods to replace all the elements in `class_methods_def`
class_methods_def.drain(..);
class_methods_def.extend(new_child_methods);
// handle class fields
let mut new_child_fields: Vec<(String, Type)> = Vec::new();
// let mut is_override: HashSet<String> = HashSet::new();
for (anc_field_name, anc_field_ty) in fields {
let to_be_added = (anc_field_name.to_string(), *anc_field_ty);
// find if there is a fields with the same name in the child class
for (class_field_name, ..) in class_fields_def.iter() {
if class_field_name == anc_field_name {
// let ok = Self::check_overload_field_type(
// *class_field_ty,
// *anc_field_ty,
// unifier,
// type_var_to_concrete_def,
// );
// if !ok {
// return Err("fields has same name as ancestors' field, but incompatible type".into());
// }
// // mark it as added
// is_override.insert(class_field_name.to_string());
// to_be_added = (class_field_name.to_string(), *class_field_ty);
// break;
return Err(format!(
"field `{}` has already declared in the ancestor classes",
class_field_name
));
}
}
new_child_fields.push(to_be_added);
}
for (class_field_name, class_field_ty) in class_fields_def.iter() {
if !is_override.contains(class_field_name) {
new_child_fields.push((class_field_name.to_string(), *class_field_ty));
}
}
class_fields_def.drain(..);
class_fields_def.extend(new_child_fields);
} else {
unreachable!("must be top level class def")
}
} else {
unreachable!("must be class type annotation")
}
Ok(())
}
}