//! implements `ASTLowerer`. //! //! ASTLowerer(ASTからHIRへの変換器)を実装 use erg_common::astr::AtomicStr; use erg_common::config::ErgConfig; use erg_common::dict; use erg_common::error::{Location, MultiErrorDisplay}; use erg_common::set; use erg_common::set::Set; use erg_common::traits::{Locational, Runnable, Stream}; use erg_common::vis::Visibility; use erg_common::{enum_unwrap, fmt_option, fn_name, get_hash, log, switch_lang, Str}; use erg_parser::ast; use erg_parser::ast::{OperationKind, AST}; use erg_parser::build_ast::ASTBuilder; use erg_parser::token::{Token, TokenKind}; use erg_parser::Parser; use crate::artifact::{CompleteArtifact, IncompleteArtifact}; use crate::context::instantiate::TyVarCache; use crate::ty::constructors::{ array_mut, array_t, free_var, func, mono, poly, proc, set_mut, set_t, ty_tp, }; use crate::ty::free::{Constraint, HasLevel}; use crate::ty::typaram::TyParam; use crate::ty::value::{GenTypeObj, TypeObj, ValueObj}; use crate::ty::{HasType, ParamTy, Type}; use crate::context::{ClassDefType, Context, ContextKind, RegistrationMode, TypeRelationInstance}; use crate::error::{ CompileError, CompileErrors, LowerError, LowerErrors, LowerResult, LowerWarnings, SingleLowerResult, }; use crate::hir; use crate::hir::HIR; use crate::mod_cache::SharedModuleCache; use crate::reorder::Reorderer; use crate::varinfo::{Mutability, VarInfo, VarKind}; use crate::AccessKind; use Visibility::*; /// Singleton that checks types of an AST, and convert (lower) it into a HIR #[derive(Debug)] pub struct ASTLowerer { cfg: ErgConfig, pub(crate) ctx: Context, errs: LowerErrors, warns: LowerWarnings, } impl Default for ASTLowerer { fn default() -> Self { Self::new_with_cache( ErgConfig::default(), Str::ever(""), SharedModuleCache::new(), SharedModuleCache::new(), ) } } impl Runnable for ASTLowerer { type Err = CompileError; type Errs = CompileErrors; const NAME: &'static str = "Erg lowerer"; #[inline] fn cfg(&self) -> &ErgConfig { &self.cfg } fn new(cfg: ErgConfig) -> Self { Self::new_with_cache( cfg, Str::ever(""), SharedModuleCache::new(), SharedModuleCache::new(), ) } #[inline] fn finish(&mut self) {} fn clear(&mut self) { self.errs.clear(); self.warns.clear(); } fn exec(&mut self) -> Result { let mut ast_builder = ASTBuilder::new(self.cfg.copy()); let ast = ast_builder.build(self.input().read())?; let artifact = self .lower(ast, "exec") .map_err(|artifact| artifact.errors)?; if self.cfg.verbose >= 2 { artifact.warns.fmt_all_stderr(); } println!("{}", artifact.hir); Ok(0) } fn eval(&mut self, src: String) -> Result { let mut ast_builder = ASTBuilder::new(self.cfg.copy()); let ast = ast_builder.build(src)?; let artifact = self .lower(ast, "eval") .map_err(|artifact| artifact.errors)?; Ok(format!("{}", artifact.hir)) } } impl ASTLowerer { pub fn new_with_cache>( cfg: ErgConfig, mod_name: S, mod_cache: SharedModuleCache, py_mod_cache: SharedModuleCache, ) -> Self { Self { ctx: Context::new_module(mod_name, cfg.clone(), mod_cache, py_mod_cache), cfg, errs: LowerErrors::empty(), warns: LowerWarnings::empty(), } } fn return_t_check( &self, loc: Location, name: &Str, expect: &Type, found: &Type, ) -> SingleLowerResult<()> { self.ctx .sub_unify(found, expect, loc, Some(name)) .map_err(|_| { LowerError::type_mismatch_error( self.cfg.input.clone(), line!() as usize, loc, self.ctx.caused_by(), name, None, expect, found, self.ctx.get_candidates(found), self.ctx.get_type_mismatch_hint(expect, found), ) }) } /// OK: exec `i: Int` /// OK: exec `i: Int = 1` /// NG: exec `1 + 2` /// OK: exec `None` fn use_check(&self, expr: &hir::Expr, mode: &str) -> SingleLowerResult<()> { if mode != "eval" && !expr.ref_t().is_nonelike() && !expr.is_type_asc() { Err(LowerError::syntax_error( self.cfg.input.clone(), line!() as usize, expr.loc(), AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => format!("式の評価結果(: {})が使われていません", expr.ref_t()), "simplified_chinese" => format!("表达式评估结果(: {})未使用", expr.ref_t()), "traditional_chinese" => format!("表達式評估結果(: {})未使用", expr.ref_t()), "english" => format!("the evaluation result of the expression (: {}) is not used", expr.ref_t()), ), Some( switch_lang!( "japanese" => "値を使わない場合は、discard関数を使用してください", "simplified_chinese" => "如果您不想使用该值,请使用discard函数", "traditional_chinese" => "如果您不想使用該值,請使用discard函數", "english" => "if you don't use the value, use discard function", ) .into(), ), )) } else { Ok(()) } } fn pop_append_errs(&mut self) { if let Err(mut errs) = self.ctx.check_decls_and_pop() { self.errs.append(&mut errs); } } fn lower_literal(&self, lit: ast::Literal) -> LowerResult { let loc = lit.loc(); let lit = hir::Literal::try_from(lit.token).map_err(|_| { LowerError::invalid_literal( self.cfg.input.clone(), line!() as usize, loc, self.ctx.caused_by(), ) })?; Ok(lit) } fn lower_array(&mut self, array: ast::Array) -> LowerResult { log!(info "entered {}({array})", fn_name!()); match array { ast::Array::Normal(arr) => Ok(hir::Array::Normal(self.lower_normal_array(arr)?)), ast::Array::WithLength(arr) => { Ok(hir::Array::WithLength(self.lower_array_with_length(arr)?)) } other => todo!("{other}"), } } fn lower_normal_array(&mut self, array: ast::NormalArray) -> LowerResult { log!(info "entered {}({array})", fn_name!()); let mut new_array = vec![]; let (elems, _) = array.elems.into_iters(); let mut union = Type::Never; for elem in elems { let elem = self.lower_expr(elem.expr)?; union = self.ctx.union(&union, elem.ref_t()); if matches!(union, Type::Or(_, _)) { return Err(LowerErrors::from(LowerError::syntax_error( self.cfg.input.clone(), line!() as usize, elem.loc(), AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => "配列の要素は全て同じ型である必要があります", "simplified_chinese" => "数组元素必须全部是相同类型", "traditional_chinese" => "數組元素必須全部是相同類型", "english" => "all elements of an array must be of the same type", ), Some( switch_lang!( "japanese" => "Int or Strなど明示的に型を指定してください", "simplified_chinese" => "请明确指定类型,例如: Int or Str", "traditional_chinese" => "請明確指定類型,例如: Int or Str", "english" => "please specify the type explicitly, e.g. Int or Str", ) .into(), ), ))); } new_array.push(elem); } let elem_t = if union == Type::Never { free_var(self.ctx.level, Constraint::new_type_of(Type::Type)) } else { union }; Ok(hir::NormalArray::new( array.l_sqbr, array.r_sqbr, elem_t, hir::Args::from(new_array), )) } fn lower_array_with_length( &mut self, array: ast::ArrayWithLength, ) -> LowerResult { log!(info "entered {}({array})", fn_name!()); let elem = self.lower_expr(array.elem.expr)?; let array_t = self.gen_array_with_length_type(&elem, &array.len); let len = self.lower_expr(*array.len)?; let hir_array = hir::ArrayWithLength::new(array.l_sqbr, array.r_sqbr, array_t, elem, len); Ok(hir_array) } fn gen_array_with_length_type(&self, elem: &hir::Expr, len: &ast::Expr) -> Type { let maybe_len = self.ctx.eval_const_expr(len); match maybe_len { Ok(v @ ValueObj::Nat(_)) => { if elem.ref_t().is_mut_type() { poly( "ArrayWithMutType!", vec![TyParam::t(elem.t()), TyParam::Value(v)], ) } else { array_t(elem.t(), TyParam::Value(v)) } } Ok(v @ ValueObj::Mut(_)) if v.class() == mono("Nat!") => { if elem.ref_t().is_mut_type() { poly( "ArrayWithMutTypeAndLength!", vec![TyParam::t(elem.t()), TyParam::Value(v)], ) } else { array_mut(elem.t(), TyParam::Value(v)) } } Ok(other) => todo!("{other} is not a Nat object"), // REVIEW: is it ok to ignore the error? Err(_e) => { if elem.ref_t().is_mut_type() { poly( "ArrayWithMutType!", vec![TyParam::t(elem.t()), TyParam::erased(Type::Nat)], ) } else { array_t(elem.t(), TyParam::erased(Type::Nat)) } } } } fn lower_tuple(&mut self, tuple: ast::Tuple) -> LowerResult { log!(info "entered {}({tuple})", fn_name!()); match tuple { ast::Tuple::Normal(tup) => Ok(hir::Tuple::Normal(self.lower_normal_tuple(tup)?)), } } fn lower_normal_tuple(&mut self, tuple: ast::NormalTuple) -> LowerResult { log!(info "entered {}({tuple})", fn_name!()); let mut new_tuple = vec![]; let (elems, _) = tuple.elems.into_iters(); for elem in elems { let elem = self.lower_expr(elem.expr)?; new_tuple.push(elem); } Ok(hir::NormalTuple::new(hir::Args::from(new_tuple))) } fn lower_record(&mut self, record: ast::Record) -> LowerResult { log!(info "entered {}({record})", fn_name!()); match record { ast::Record::Normal(rec) => self.lower_normal_record(rec), ast::Record::Shortened(_rec) => unreachable!(), // should be desugared } } fn lower_normal_record(&mut self, record: ast::NormalRecord) -> LowerResult { log!(info "entered {}({record})", fn_name!()); let mut hir_record = hir::Record::new(record.l_brace, record.r_brace, hir::RecordAttrs::empty()); self.ctx.grow("", ContextKind::Dummy, Private, None); for attr in record.attrs.into_iter() { let attr = self.lower_def(attr).map_err(|e| { self.pop_append_errs(); e })?; hir_record.push(attr); } self.pop_append_errs(); Ok(hir_record) } fn lower_set(&mut self, set: ast::Set) -> LowerResult { log!(info "enter {}({set})", fn_name!()); match set { ast::Set::Normal(set) => Ok(hir::Set::Normal(self.lower_normal_set(set)?)), ast::Set::WithLength(set) => Ok(hir::Set::WithLength(self.lower_set_with_length(set)?)), } } fn lower_normal_set(&mut self, set: ast::NormalSet) -> LowerResult { log!(info "entered {}({set})", fn_name!()); let (elems, _) = set.elems.into_iters(); let mut union = Type::Never; let mut new_set = vec![]; for elem in elems { let elem = self.lower_expr(elem.expr)?; union = self.ctx.union(&union, elem.ref_t()); if union.is_intersection_type() { return Err(LowerErrors::from(LowerError::syntax_error( self.cfg.input.clone(), line!() as usize, elem.loc(), AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => "集合の要素は全て同じ型である必要があります", "simplified_chinese" => "集合元素必须全部是相同类型", "traditional_chinese" => "集合元素必須全部是相同類型", "english" => "all elements of a set must be of the same type", ), Some( switch_lang!( "japanese" => "Int or Strなど明示的に型を指定してください", "simplified_chinese" => "明确指定类型,例如: Int or Str", "traditional_chinese" => "明確指定類型,例如: Int or Str", "english" => "please specify the type explicitly, e.g. Int or Str", ) .into(), ), ))); } new_set.push(elem); } let elem_t = if union == Type::Never { free_var(self.ctx.level, Constraint::new_type_of(Type::Type)) } else { union }; // TODO: lint /* if is_duplicated { self.warns.push(LowerWarning::syntax_error( self.cfg.input.clone(), line!() as usize, normal_set.loc(), AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => "要素が重複しています", "simplified_chinese" => "元素重复", "traditional_chinese" => "元素重複", "english" => "Elements are duplicated", ), None, )); } Ok(normal_set) */ let elems = hir::Args::from(new_set); // check if elem_t is Eq if let Err(errs) = self.ctx.sub_unify(&elem_t, &mono("Eq"), elems.loc(), None) { self.errs.extend(errs.into_iter()); } Ok(hir::NormalSet::new(set.l_brace, set.r_brace, elem_t, elems)) } /// This (e.g. {"a"; 3}) is meaningless as an object, but makes sense as a type (e.g. {Int; 3}). fn lower_set_with_length( &mut self, set: ast::SetWithLength, ) -> LowerResult { log!("entered {}({set})", fn_name!()); let elem = self.lower_expr(set.elem.expr)?; let set_t = self.gen_set_with_length_type(&elem, &set.len); let len = self.lower_expr(*set.len)?; let hir_set = hir::SetWithLength::new(set.l_brace, set.r_brace, set_t, elem, len); Ok(hir_set) } fn gen_set_with_length_type(&mut self, elem: &hir::Expr, len: &ast::Expr) -> Type { let maybe_len = self.ctx.eval_const_expr(len); match maybe_len { Ok(v @ ValueObj::Nat(_)) => { if elem.ref_t().is_mut_type() { poly( "SetWithMutType!", vec![TyParam::t(elem.t()), TyParam::Value(v)], ) } else if self.ctx.subtype_of(&elem.t(), &Type::Type) { poly("SetType", vec![TyParam::t(elem.t()), TyParam::Value(v)]) } else { set_t(elem.t(), TyParam::Value(v)) } } Ok(v @ ValueObj::Mut(_)) if v.class() == mono("Nat!") => { if elem.ref_t().is_mut_type() { poly( "SetWithMutTypeAndLength!", vec![TyParam::t(elem.t()), TyParam::Value(v)], ) } else { set_mut(elem.t(), TyParam::Value(v)) } } Ok(other) => todo!("{other} is not a Nat object"), Err(_e) => { if elem.ref_t().is_mut_type() { poly( "SetWithMutType!", vec![TyParam::t(elem.t()), TyParam::erased(Type::Nat)], ) } else { set_t(elem.t(), TyParam::erased(Type::Nat)) } } } } fn lower_dict(&mut self, dict: ast::Dict) -> LowerResult { log!(info "enter {}({dict})", fn_name!()); match dict { ast::Dict::Normal(set) => Ok(hir::Dict::Normal(self.lower_normal_dict(set)?)), other => todo!("{other}"), // ast::Dict::WithLength(set) => Ok(hir::Dict::WithLength(self.lower_dict_with_length(set)?)), } } fn lower_normal_dict(&mut self, dict: ast::NormalDict) -> LowerResult { log!(info "enter {}({dict})", fn_name!()); let mut union = dict! {}; let mut new_kvs = vec![]; for kv in dict.kvs { let loc = kv.loc(); let key = self.lower_expr(kv.key)?; let value = self.lower_expr(kv.value)?; if union.insert(key.t(), value.t()).is_some() { return Err(LowerErrors::from(LowerError::syntax_error( self.cfg.input.clone(), line!() as usize, loc, AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => "Dictの値は全て同じ型である必要があります", "simplified_chinese" => "Dict的值必须是同一类型", "traditional_chinese" => "Dict的值必須是同一類型", "english" => "Values of Dict must be the same type", ), Some( switch_lang!( "japanese" => "Int or Strなど明示的に型を指定してください", "simplified_chinese" => "明确指定类型,例如: Int or Str", "traditional_chinese" => "明確指定類型,例如: Int or Str", "english" => "please specify the type explicitly, e.g. Int or Str", ) .into(), ), ))); } new_kvs.push(hir::KeyValue::new(key, value)); } for key_t in union.keys() { let loc = Location::concat(&dict.l_brace, &dict.r_brace); // check if key_t is Eq if let Err(errs) = self.ctx.sub_unify(key_t, &mono("Eq"), loc, None) { self.errs.extend(errs.into_iter()); } } let kv_ts = if union.is_empty() { dict! { ty_tp(free_var(self.ctx.level, Constraint::new_type_of(Type::Type))) => ty_tp(free_var(self.ctx.level, Constraint::new_type_of(Type::Type))) } } else { union .into_iter() .map(|(k, v)| (TyParam::t(k), TyParam::t(v))) .collect() }; // TODO: lint /* if is_duplicated { self.warns.push(LowerWarning::syntax_error( self.cfg.input.clone(), line!() as usize, normal_set.loc(), AtomicStr::arc(&self.ctx.name[..]), switch_lang!( "japanese" => "要素が重複しています", "simplified_chinese" => "元素重复", "traditional_chinese" => "元素重複", "english" => "Elements are duplicated", ), None, )); } Ok(normal_set) */ Ok(hir::NormalDict::new( dict.l_brace, dict.r_brace, kv_ts, new_kvs, )) } fn lower_acc(&mut self, acc: ast::Accessor) -> LowerResult { log!(info "entered {}({acc})", fn_name!()); match acc { ast::Accessor::Ident(ident) => { let ident = self.lower_ident(ident)?; let acc = hir::Accessor::Ident(ident); Ok(acc) } ast::Accessor::Attr(attr) => { let obj = self.lower_expr(*attr.obj)?; let vi = self.ctx.rec_get_attr_info( &obj, &attr.ident, &self.cfg.input, &self.ctx.name, )?; let ident = hir::Identifier::new(attr.ident.dot, attr.ident.name, None, vi); let acc = hir::Accessor::Attr(hir::Attribute::new(obj, ident)); Ok(acc) } ast::Accessor::TypeApp(_t_app) => { todo!() } // TupleAttr, Subscr are desugared _ => unreachable!(), } } fn lower_ident(&self, ident: ast::Identifier) -> LowerResult { // `match` is an untypable special form // `match`は型付け不可能な特殊形式 let (vi, __name__) = if ident.vis().is_private() && (&ident.inspect()[..] == "match" || &ident.inspect()[..] == "match!") { (VarInfo::default(), None) } else { ( self.ctx.rec_get_var_info( &ident, AccessKind::Name, &self.cfg.input, &self.ctx.name, )?, self.ctx .get_singular_ctx_by_ident(&ident, &self.ctx.name) .ok() .map(|ctx| ctx.name.clone()), ) }; let ident = hir::Identifier::new(ident.dot, ident.name, __name__, vi); Ok(ident) } fn lower_bin(&mut self, bin: ast::BinOp) -> LowerResult { log!(info "entered {}({bin})", fn_name!()); let mut args = bin.args.into_iter(); let lhs = hir::PosArg::new(self.lower_expr(*args.next().unwrap())?); let rhs = hir::PosArg::new(self.lower_expr(*args.next().unwrap())?); let args = [lhs, rhs]; let t = self .ctx .get_binop_t(&bin.op, &args, &self.cfg.input, &self.ctx.name)?; let mut args = args.into_iter(); let lhs = args.next().unwrap().expr; let rhs = args.next().unwrap().expr; Ok(hir::BinOp::new(bin.op, lhs, rhs, t)) } fn lower_unary(&mut self, unary: ast::UnaryOp) -> LowerResult { log!(info "entered {}({unary})", fn_name!()); let mut args = unary.args.into_iter(); let arg = hir::PosArg::new(self.lower_expr(*args.next().unwrap())?); let args = [arg]; let t = self .ctx .get_unaryop_t(&unary.op, &args, &self.cfg.input, &self.ctx.name)?; let mut args = args.into_iter(); let expr = args.next().unwrap().expr; Ok(hir::UnaryOp::new(unary.op, expr, t)) } fn lower_call(&mut self, call: ast::Call) -> LowerResult { log!(info "entered {}({}{}(...))", fn_name!(), call.obj, fmt_option!(call.attr_name)); let opt_cast_to = if call.is_assert_cast() { if let Some(typ) = call.assert_cast_target_type() { Some(Parser::expr_to_type_spec(typ.clone()).map_err(|e| { let e = LowerError::new(e.into(), self.input().clone(), self.ctx.caused_by()); LowerErrors::from(e) })?) } else { return Err(LowerErrors::from(LowerError::syntax_error( self.input().clone(), line!() as usize, call.args.loc(), self.ctx.caused_by(), "invalid assert casting type", None, ))); } } else { None }; let (pos_args, kw_args, paren) = call.args.deconstruct(); let mut hir_args = hir::Args::new( Vec::with_capacity(pos_args.len()), None, Vec::with_capacity(kw_args.len()), paren, ); for arg in pos_args.into_iter() { hir_args.push_pos(hir::PosArg::new(self.lower_expr(arg.expr)?)); } for arg in kw_args.into_iter() { hir_args.push_kw(hir::KwArg::new(arg.keyword, self.lower_expr(arg.expr)?)); } let mut obj = self.lower_expr(*call.obj)?; let vi = self.ctx.get_call_t( &obj, &call.attr_name, &hir_args.pos_args, &hir_args.kw_args, &self.cfg.input, &self.ctx.name, )?; let attr_name = if let Some(attr_name) = call.attr_name { Some(hir::Identifier::new( attr_name.dot, attr_name.name, None, vi, )) } else { *obj.ref_mut_t() = vi.t; None }; let mut call = hir::Call::new(obj, attr_name, hir_args); match call.additional_operation() { Some(kind @ (OperationKind::Import | OperationKind::PyImport)) => { let mod_name = enum_unwrap!(call.args.get_left_or_key("Path").unwrap(), hir::Expr::Lit); if let Err(errs) = self.ctx.import_mod(kind, mod_name) { self.errs.extend(errs.into_iter()); }; } Some(OperationKind::Del) => match call.args.get_left_or_key("obj").unwrap() { hir::Expr::Accessor(hir::Accessor::Ident(ident)) => { self.ctx.del(ident)?; } other => { return Err(LowerErrors::from(LowerError::syntax_error( self.input().clone(), line!() as usize, other.loc(), self.ctx.caused_by(), "", None, ))) } }, _ => { if let Some(type_spec) = opt_cast_to { self.ctx.cast(type_spec, &mut call)?; } } } Ok(call) } fn lower_pack(&mut self, pack: ast::DataPack) -> LowerResult { log!(info "entered {}({pack})", fn_name!()); let class = self.lower_expr(*pack.class)?; let args = self.lower_record(pack.args)?; let args = vec![hir::PosArg::new(hir::Expr::Record(args))]; let attr_name = ast::Identifier::new( Some(Token::new( TokenKind::Dot, Str::ever("."), pack.connector.lineno, pack.connector.col_begin, )), ast::VarName::new(Token::new( TokenKind::Symbol, Str::ever("new"), pack.connector.lineno, pack.connector.col_begin, )), ); let vi = self.ctx.get_call_t( &class, &Some(attr_name.clone()), &args, &[], &self.cfg.input, &self.ctx.name, )?; let args = hir::Args::new(args, None, vec![], None); let attr_name = hir::Identifier::new(attr_name.dot, attr_name.name, None, vi); Ok(hir::Call::new(class, Some(attr_name), args)) } fn lower_params(&mut self, params: ast::Params) -> LowerResult { log!(info "entered {}({})", fn_name!(), params); let mut hir_defaults = vec![]; for default in params.defaults.into_iter() { let default_val = self.lower_expr(default.default_val)?; hir_defaults.push(hir::DefaultParamSignature::new(default.sig, default_val)); } let hir_params = hir::Params::new( params.non_defaults, params.var_args, hir_defaults, params.parens, ); Ok(hir_params) } /// TODO: varargs fn lower_lambda(&mut self, lambda: ast::Lambda) -> LowerResult { log!(info "entered {}({lambda})", fn_name!()); let is_procedural = lambda.is_procedural(); let id = get_hash(&lambda.sig); let name = format!(""); let kind = if is_procedural { ContextKind::Proc } else { ContextKind::Func }; let tv_cache = self .ctx .instantiate_ty_bounds(&lambda.sig.bounds, RegistrationMode::Normal)?; self.ctx.grow(&name, kind, Private, Some(tv_cache)); let params = self.lower_params(lambda.sig.params)?; if let Err(errs) = self.ctx.assign_params(¶ms, None) { self.errs.extend(errs.into_iter()); } if let Err(errs) = self.ctx.preregister(&lambda.body) { self.errs.extend(errs.into_iter()); } let body = self.lower_block(lambda.body).map_err(|e| { self.pop_append_errs(); e })?; let (non_default_params, default_params): (Vec<_>, Vec<_>) = self .ctx .params .iter() .partition(|(_, v)| !v.kind.has_default()); let non_default_params = non_default_params .into_iter() .map(|(name, vi)| { ParamTy::pos(name.as_ref().map(|n| n.inspect().clone()), vi.t.clone()) }) .collect(); let default_params = default_params .into_iter() .map(|(name, vi)| ParamTy::kw(name.as_ref().unwrap().inspect().clone(), vi.t.clone())) .collect(); self.pop_append_errs(); let t = if is_procedural { proc(non_default_params, None, default_params, body.t()) } else { func(non_default_params, None, default_params, body.t()) }; let t = if t.has_qvar() { t.quantify() } else { t }; Ok(hir::Lambda::new(id, params, lambda.op, body, t)) } fn lower_def(&mut self, def: ast::Def) -> LowerResult { log!(info "entered {}({})", fn_name!(), def.sig); if def.def_kind().is_class_or_trait() && self.ctx.kind != ContextKind::Module { self.ctx.decls.remove(def.sig.ident().unwrap().inspect()); return Err(LowerErrors::from(LowerError::inner_typedef_error( self.cfg.input.clone(), line!() as usize, def.loc(), self.ctx.caused_by(), ))); } let name = if let Some(name) = def.sig.name_as_str() { name.clone() } else { Str::ever("") }; if self .ctx .registered_info(&name, def.sig.is_const()) .is_some() && def.sig.vis().is_private() { return Err(LowerErrors::from(LowerError::reassign_error( self.cfg.input.clone(), line!() as usize, def.sig.loc(), self.ctx.caused_by(), &name, ))); } let kind = ContextKind::from(def.def_kind()); let vis = def.sig.vis(); let res = match def.sig { ast::Signature::Subr(sig) => { let tv_cache = self .ctx .instantiate_ty_bounds(&sig.bounds, RegistrationMode::Normal)?; self.ctx.grow(&name, kind, vis, Some(tv_cache)); self.lower_subr_def(sig, def.body) } ast::Signature::Var(sig) => { self.ctx.grow(&name, kind, vis, None); self.lower_var_def(sig, def.body) } }; // TODO: Context上の関数に型境界情報を追加 self.pop_append_errs(); // remove from decls regardless of success or failure to lower self.ctx.decls.remove(&name); res } fn lower_var_def( &mut self, sig: ast::VarSignature, body: ast::DefBody, ) -> LowerResult { log!(info "entered {}({sig})", fn_name!()); if let Err(errs) = self.ctx.preregister(&body.block) { self.errs.extend(errs.into_iter()); } match self.lower_block(body.block) { Ok(block) => { let found_body_t = block.ref_t(); let opt_expect_body_t = self .ctx .outer .as_ref() .unwrap() .get_current_scope_var(sig.inspect().unwrap()) .map(|vi| vi.t.clone()); let ident = match &sig.pat { ast::VarPattern::Ident(ident) => ident, _ => unreachable!(), }; if let Some(expect_body_t) = opt_expect_body_t { // TODO: expect_body_t is smaller for constants // TODO: 定数の場合、expect_body_tのほうが小さくなってしまう if !sig.is_const() { if let Err(e) = self.return_t_check( sig.loc(), ident.inspect(), &expect_body_t, found_body_t, ) { self.errs.push(e); } } } self.ctx.outer.as_mut().unwrap().assign_var_sig( &sig, found_body_t, body.id, None, )?; let mut ident = hir::Identifier::bare(ident.dot.clone(), ident.name.clone()); ident.vi.t = found_body_t.clone(); let sig = hir::VarSignature::new(ident); let body = hir::DefBody::new(body.op, block, body.id); Ok(hir::Def::new(hir::Signature::Var(sig), body)) } Err(errs) => { self.ctx.outer.as_mut().unwrap().assign_var_sig( &sig, &Type::Failure, ast::DefId(0), None, )?; Err(errs) } } } // NOTE: 呼ばれている間はinner scopeなので注意 fn lower_subr_def( &mut self, sig: ast::SubrSignature, body: ast::DefBody, ) -> LowerResult { log!(info "entered {}({sig})", fn_name!()); let t = self .ctx .outer .as_ref() .unwrap() .get_current_scope_var(sig.ident.inspect()) .map(|vi| vi.t.clone()) .unwrap_or(Type::Failure); match t { Type::Subr(t) => { let params = self.lower_params(sig.params)?; if let Err(errs) = self.ctx.assign_params(¶ms, Some(t.clone())) { self.errs.extend(errs.into_iter()); } if let Err(errs) = self.ctx.preregister(&body.block) { self.errs.extend(errs.into_iter()); } match self.lower_block(body.block) { Ok(block) => { let found_body_t = block.ref_t(); let expect_body_t = t.return_t.as_ref(); if !sig.ident.is_const() { if let Err(e) = self.return_t_check( sig.ident.loc(), sig.ident.inspect(), expect_body_t, found_body_t, ) { self.errs.push(e); } } let id = body.id; let t = self.ctx.outer.as_mut().unwrap().assign_subr( &sig.ident, &sig.decorators, id, found_body_t, )?; let ident = hir::Identifier::bare(sig.ident.dot, sig.ident.name); let sig = hir::SubrSignature::new(ident, params, t); let body = hir::DefBody::new(body.op, block, body.id); Ok(hir::Def::new(hir::Signature::Subr(sig), body)) } Err(errs) => { self.ctx.outer.as_mut().unwrap().assign_subr( &sig.ident, &sig.decorators, ast::DefId(0), &Type::Failure, )?; Err(errs) } } } Type::Failure => { let params = self.lower_params(sig.params)?; if let Err(errs) = self.ctx.assign_params(¶ms, None) { self.errs.extend(errs.into_iter()); } if let Err(errs) = self.ctx.preregister(&body.block) { self.errs.extend(errs.into_iter()); } self.ctx.outer.as_mut().unwrap().fake_subr_assign( &sig.ident, &sig.decorators, Type::Failure, ); let block = self.lower_block(body.block)?; let ident = hir::Identifier::bare(sig.ident.dot, sig.ident.name); let sig = hir::SubrSignature::new(ident, params, Type::Failure); let body = hir::DefBody::new(body.op, block, body.id); Ok(hir::Def::new(hir::Signature::Subr(sig), body)) } _ => unreachable!(), } } fn lower_class_def(&mut self, class_def: ast::ClassDef) -> LowerResult { log!(info "entered {}({class_def})", fn_name!()); let mut hir_def = self.lower_def(class_def.def)?; let mut hir_methods = hir::Block::empty(); let mut dummy_tv_cache = TyVarCache::new(self.ctx.level, &self.ctx); for mut methods in class_def.methods_list.into_iter() { let (class, impl_trait) = match &methods.class { ast::TypeSpec::TypeApp { spec, args } => { let (impl_trait, loc) = match &args.args.pos_args().first().unwrap().expr { // TODO: check `tasc.op` ast::Expr::TypeAsc(tasc) => ( self.ctx.instantiate_typespec( &tasc.t_spec, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?, tasc.t_spec.loc(), ), _ => unreachable!(), }; ( self.ctx.instantiate_typespec( spec, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?, Some((impl_trait, loc)), ) } other => ( self.ctx.instantiate_typespec( other, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?, None, ), }; // assume the class has implemented the trait, regardless of whether the implementation is correct if let Some((trait_, trait_loc)) = &impl_trait { self.register_trait_impl(&class, trait_, *trait_loc)?; } if let Some(class_root) = self.ctx.get_nominal_type_ctx(&class) { if !class_root.kind.is_class() { return Err(LowerErrors::from(LowerError::method_definition_error( self.cfg.input.clone(), line!() as usize, methods.loc(), self.ctx.caused_by(), &class.qual_name(), None, ))); } } else { return Err(LowerErrors::from(LowerError::no_var_error( self.cfg.input.clone(), line!() as usize, methods.class.loc(), self.ctx.caused_by(), &class.qual_name(), self.ctx.get_similar_name(&class.local_name()), ))); } let kind = ContextKind::MethodDefs(impl_trait.as_ref().map(|(t, _)| t.clone())); self.ctx.grow(&class.local_name(), kind, Private, None); for def in methods.defs.iter_mut() { if methods.vis.is(TokenKind::Dot) { def.sig.ident_mut().unwrap().dot = Some(Token::new( TokenKind::Dot, ".", def.sig.ln_begin().unwrap(), def.sig.col_begin().unwrap(), )); } self.ctx.preregister_def(def)?; } for def in methods.defs.into_iter() { match self.lower_def(def) { Ok(def) => { hir_methods.push(hir::Expr::Def(def)); } Err(errs) => { self.errs.extend(errs.into_iter()); } } } if let Err(mut errs) = self.ctx.check_decls() { self.errs.append(&mut errs); } if let Some((trait_, _)) = &impl_trait { self.check_override(&class, Some(trait_)); } else { self.check_override(&class, None); } if let Err(err) = self.check_trait_impl(impl_trait, &class) { self.errs.push(err); } self.check_collision_and_push(class); } let class = mono(hir_def.sig.ident().inspect()); let class_ctx = self.ctx.get_nominal_type_ctx(&class).unwrap(); let type_obj = enum_unwrap!(self.ctx.rec_get_const_obj(hir_def.sig.ident().inspect()).unwrap(), ValueObj::Type:(TypeObj::Generated:(_))); let sup_type = enum_unwrap!(&hir_def.body.block.first().unwrap(), hir::Expr::Call) .args .get_left_or_key("Super") .unwrap(); Self::check_inheritable(&self.cfg, &mut self.errs, type_obj, sup_type, &hir_def.sig); // vi.t.non_default_params().unwrap()[0].typ().clone() let (__new__, need_to_gen_new) = if let (Some(dunder_new_vi), Some(new_vi)) = ( class_ctx.get_current_scope_var("__new__"), class_ctx.get_current_scope_var("new"), ) { (dunder_new_vi.t.clone(), new_vi.kind == VarKind::Auto) } else { todo!() }; let require_or_sup = self.get_require_or_sup(hir_def.body.block.remove(0)); Ok(hir::ClassDef::new( type_obj.clone(), hir_def.sig, require_or_sup, need_to_gen_new, __new__, hir_methods, )) } fn register_trait_impl( &mut self, class: &Type, trait_: &Type, trait_loc: Location, ) -> LowerResult<()> { // TODO: polymorphic trait if let Some(impls) = self.ctx.trait_impls.get_mut(&trait_.qual_name()) { impls.insert(TypeRelationInstance::new(class.clone(), trait_.clone())); } else { self.ctx.trait_impls.insert( trait_.qual_name(), set! {TypeRelationInstance::new(class.clone(), trait_.clone())}, ); } let trait_ctx = if let Some(trait_ctx) = self.ctx.get_nominal_type_ctx(trait_) { trait_ctx.clone() } else { // TODO: maybe parameters are wrong return Err(LowerErrors::from(LowerError::no_var_error( self.cfg.input.clone(), line!() as usize, trait_loc, self.ctx.caused_by(), &trait_.local_name(), None, ))); }; let (_, class_ctx) = self .ctx .get_mut_nominal_type_ctx(class) .unwrap_or_else(|| todo!("{class} not found")); class_ctx.register_supertrait(trait_.clone(), &trait_ctx); Ok(()) } /// HACK: Cannot be methodized this because `&self` has been taken immediately before. fn check_inheritable( cfg: &ErgConfig, errs: &mut LowerErrors, type_obj: &GenTypeObj, sup_class: &hir::Expr, sub_sig: &hir::Signature, ) { if let TypeObj::Generated(gen) = type_obj.require_or_sup().unwrap() { if let Some(impls) = gen.impls() { if !impls.contains_intersec(&mono("InheritableType")) { errs.push(LowerError::inheritance_error( cfg.input.clone(), line!() as usize, sup_class.to_string(), sup_class.loc(), sub_sig.ident().inspect().into(), )); } } else { errs.push(LowerError::inheritance_error( cfg.input.clone(), line!() as usize, sup_class.to_string(), sup_class.loc(), sub_sig.ident().inspect().into(), )); } } } fn check_override(&mut self, class: &Type, impl_trait: Option<&Type>) { if let Some(sups) = self.ctx.get_nominal_super_type_ctxs(class) { // exclude the first one because it is the class itself for sup in sups.into_iter().skip(1) { for (method_name, vi) in self.ctx.locals.iter().chain( self.ctx .methods_list .iter() .flat_map(|(_, c)| c.locals.iter()), ) { if let Some(sup_vi) = sup.get_current_scope_var(method_name.inspect()) { // must `@Override` if let Some(decos) = &vi.comptime_decos { if decos.contains("Override") { continue; } } if sup_vi.impl_of.as_ref() != impl_trait { continue; } self.errs.push(LowerError::override_error( self.cfg.input.clone(), line!() as usize, method_name.inspect(), method_name.loc(), &mono(&sup.name), // TODO: get super type self.ctx.caused_by(), )); } } } } } /// Inspect the Trait implementation for correctness, /// i.e., check that all required attributes are defined and that no extra attributes are defined fn check_trait_impl( &mut self, impl_trait: Option<(Type, Location)>, class: &Type, ) -> SingleLowerResult<()> { if let Some((impl_trait, loc)) = impl_trait { let mut unverified_names = self.ctx.locals.keys().collect::>(); if let Some(trait_obj) = self.ctx.rec_get_const_obj(&impl_trait.local_name()) { if let ValueObj::Type(typ) = trait_obj { match typ { TypeObj::Generated(gen) => match gen.require_or_sup().unwrap().typ() { Type::Record(attrs) => { for (field, decl_t) in attrs.iter() { if let Some((name, vi)) = self.ctx.get_local_kv(&field.symbol) { let def_t = &vi.t; // A(<: Add(R)), R -> A.Output // => A(<: Int), R -> A.Output let replaced_decl_t = decl_t.clone().replace(&impl_trait, class); unverified_names.remove(name); // def_t must be subtype of decl_t if !self.ctx.supertype_of(&replaced_decl_t, def_t) { self.errs.push(LowerError::trait_member_type_error( self.cfg.input.clone(), line!() as usize, name.loc(), self.ctx.caused_by(), name.inspect(), &impl_trait, decl_t, &vi.t, None, )); } } else { self.errs.push(LowerError::trait_member_not_defined_error( self.cfg.input.clone(), line!() as usize, self.ctx.caused_by(), &field.symbol, &impl_trait, class, None, )); } } } other => todo!("{other}"), }, TypeObj::Builtin(_typ) => { let ctx = self.ctx.get_nominal_type_ctx(_typ).unwrap(); for (decl_name, decl_vi) in ctx.decls.iter() { if let Some((name, vi)) = self.ctx.get_local_kv(decl_name.inspect()) { let def_t = &vi.t; let replaced_decl_t = decl_vi.t.clone().replace(&impl_trait, class); unverified_names.remove(name); if !self.ctx.supertype_of(&replaced_decl_t, def_t) { self.errs.push(LowerError::trait_member_type_error( self.cfg.input.clone(), line!() as usize, name.loc(), self.ctx.caused_by(), name.inspect(), &impl_trait, &decl_vi.t, &vi.t, None, )); } } else { self.errs.push(LowerError::trait_member_not_defined_error( self.cfg.input.clone(), line!() as usize, self.ctx.caused_by(), decl_name.inspect(), &impl_trait, class, None, )); } } } } } else { return Err(LowerError::type_mismatch_error( self.cfg.input.clone(), line!() as usize, loc, self.ctx.caused_by(), &impl_trait.qual_name(), None, &Type::TraitType, &trait_obj.t(), None, None, )); } } else { return Err(LowerError::no_var_error( self.cfg.input.clone(), line!() as usize, loc, self.ctx.caused_by(), &impl_trait.qual_name(), self.ctx.get_similar_name(&impl_trait.local_name()), )); } for unverified in unverified_names { self.errs.push(LowerError::trait_member_not_defined_error( self.cfg.input.clone(), line!() as usize, self.ctx.caused_by(), unverified.inspect(), &impl_trait, class, None, )); } } Ok(()) } fn check_collision_and_push(&mut self, class: Type) { let methods = self.ctx.pop(); let (_, class_root) = self .ctx .get_mut_nominal_type_ctx(&class) .unwrap_or_else(|| todo!("{class} not found")); for (newly_defined_name, vi) in methods.locals.clone().into_iter() { for (_, already_defined_methods) in class_root.methods_list.iter_mut() { // TODO: 特殊化なら同じ名前でもOK // TODO: 定義のメソッドもエラー表示 if let Some((_already_defined_name, already_defined_vi)) = already_defined_methods.get_local_kv(newly_defined_name.inspect()) { if already_defined_vi.kind != VarKind::Auto && already_defined_vi.impl_of == vi.impl_of { self.errs.push(LowerError::duplicate_definition_error( self.cfg.input.clone(), line!() as usize, newly_defined_name.loc(), methods.caused_by(), newly_defined_name.inspect(), )); } else { already_defined_methods .locals .remove(&newly_defined_name.inspect()[..]); } } } } class_root .methods_list .push((ClassDefType::Simple(class), methods)); } fn get_require_or_sup(&self, expr: hir::Expr) -> hir::Expr { match expr { acc @ hir::Expr::Accessor(_) => acc, hir::Expr::Call(mut call) => match call.obj.show_acc().as_ref().map(|s| &s[..]) { Some("Class") => call.args.remove_left_or_key("Requirement").unwrap(), Some("Inherit") => call.args.remove_left_or_key("Super").unwrap(), Some("Inheritable") => { self.get_require_or_sup(call.args.remove_left_or_key("Class").unwrap()) } _ => todo!(), }, other => todo!("{other}"), } } fn lower_type_asc(&mut self, tasc: ast::TypeAscription) -> LowerResult { log!(info "entered {}({tasc})", fn_name!()); let is_instance_ascription = tasc.is_instance_ascription(); let mut dummy_tv_cache = TyVarCache::new(self.ctx.level, &self.ctx); let t = self.ctx.instantiate_typespec( &tasc.t_spec, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?; let loc = tasc.loc(); let expr = self.lower_expr(*tasc.expr)?; if is_instance_ascription { self.ctx.sub_unify( expr.ref_t(), &t, expr.loc(), Some(&Str::from(expr.to_string())), )?; } else { let ctx = self .ctx .get_singular_ctx_by_hir_expr(&expr, &self.ctx.name)?; // REVIEW: need to use subtype_of? if ctx.super_traits.iter().all(|trait_| trait_ != &t) && ctx.super_classes.iter().all(|class| class != &t) { return Err(LowerErrors::from(LowerError::subtyping_error( self.cfg.input.clone(), line!() as usize, expr.ref_t(), // FIXME: &t, loc, self.ctx.caused_by(), ))); } } Ok(expr.type_asc(tasc.t_spec)) } // Call.obj == Accessor cannot be type inferred by itself (it can only be inferred with arguments) // so turn off type checking (check=false) fn lower_expr(&mut self, expr: ast::Expr) -> LowerResult { log!(info "entered {}", fn_name!()); match expr { ast::Expr::Lit(lit) => Ok(hir::Expr::Lit(self.lower_literal(lit)?)), ast::Expr::Array(arr) => Ok(hir::Expr::Array(self.lower_array(arr)?)), ast::Expr::Tuple(tup) => Ok(hir::Expr::Tuple(self.lower_tuple(tup)?)), ast::Expr::Record(rec) => Ok(hir::Expr::Record(self.lower_record(rec)?)), ast::Expr::Set(set) => Ok(hir::Expr::Set(self.lower_set(set)?)), ast::Expr::Dict(dict) => Ok(hir::Expr::Dict(self.lower_dict(dict)?)), ast::Expr::Accessor(acc) => Ok(hir::Expr::Accessor(self.lower_acc(acc)?)), ast::Expr::BinOp(bin) => Ok(hir::Expr::BinOp(self.lower_bin(bin)?)), ast::Expr::UnaryOp(unary) => Ok(hir::Expr::UnaryOp(self.lower_unary(unary)?)), ast::Expr::Call(call) => Ok(hir::Expr::Call(self.lower_call(call)?)), ast::Expr::DataPack(pack) => Ok(hir::Expr::Call(self.lower_pack(pack)?)), ast::Expr::Lambda(lambda) => Ok(hir::Expr::Lambda(self.lower_lambda(lambda)?)), ast::Expr::Def(def) => Ok(hir::Expr::Def(self.lower_def(def)?)), ast::Expr::ClassDef(defs) => Ok(hir::Expr::ClassDef(self.lower_class_def(defs)?)), ast::Expr::TypeAsc(tasc) => Ok(hir::Expr::TypeAsc(self.lower_type_asc(tasc)?)), other => todo!("{other}"), } } fn lower_block(&mut self, ast_block: ast::Block) -> LowerResult { log!(info "entered {}", fn_name!()); let mut hir_block = Vec::with_capacity(ast_block.len()); for chunk in ast_block.into_iter() { let chunk = self.lower_expr(chunk)?; hir_block.push(chunk); } Ok(hir::Block::new(hir_block)) } fn declare_or_import_var( &mut self, sig: ast::VarSignature, mut body: ast::DefBody, ) -> LowerResult { log!(info "entered {}({sig})", fn_name!()); if body.block.len() > 1 { return Err(LowerErrors::from(LowerError::declare_error( self.cfg.input.clone(), line!() as usize, body.block.loc(), self.ctx.caused_by(), ))); } let chunk = self.declare_chunk(body.block.remove(0))?; let py_name = if let hir::Expr::TypeAsc(tasc) = &chunk { enum_unwrap!(tasc.expr.as_ref(), hir::Expr::Accessor) .local_name() .map(Str::rc) } else { sig.inspect().cloned() }; let block = hir::Block::new(vec![chunk]); let found_body_t = block.ref_t(); let ident = match &sig.pat { ast::VarPattern::Ident(ident) => ident, _ => unreachable!(), }; let id = body.id; self.ctx .assign_var_sig(&sig, found_body_t, id, py_name.clone())?; let mut ident = hir::Identifier::bare(ident.dot.clone(), ident.name.clone()); ident.vi.t = found_body_t.clone(); ident.vi.py_name = py_name; let sig = hir::VarSignature::new(ident); let body = hir::DefBody::new(body.op, block, body.id); Ok(hir::Def::new(hir::Signature::Var(sig), body)) } fn declare_alias_or_import(&mut self, def: ast::Def) -> LowerResult { log!(info "entered {}({})", fn_name!(), def.sig); let name = if let Some(name) = def.sig.name_as_str() { name.clone() } else { Str::ever("") }; if self .ctx .registered_info(&name, def.sig.is_const()) .is_some() && def.sig.vis().is_private() { return Err(LowerErrors::from(LowerError::reassign_error( self.cfg.input.clone(), line!() as usize, def.sig.loc(), self.ctx.caused_by(), &name, ))); } #[allow(clippy::let_and_return)] let res = match def.sig { ast::Signature::Subr(sig) => { return Err(LowerErrors::from(LowerError::declare_error( self.cfg.input.clone(), line!() as usize, sig.loc(), self.ctx.caused_by(), ))); } ast::Signature::Var(sig) => self.declare_or_import_var(sig, def.body), }; // self.pop_append_errs(); res } fn fake_lower_obj(&self, obj: ast::Expr) -> LowerResult { match obj { ast::Expr::Accessor(ast::Accessor::Ident(ident)) => { let acc = hir::Accessor::Ident(hir::Identifier::bare(ident.dot, ident.name)); Ok(hir::Expr::Accessor(acc)) } ast::Expr::Accessor(ast::Accessor::Attr(attr)) => { let obj = self.fake_lower_obj(*attr.obj)?; let ident = hir::Identifier::bare(attr.ident.dot, attr.ident.name); Ok(obj.attr_expr(ident)) } other => Err(LowerErrors::from(LowerError::declare_error( self.cfg.input.clone(), line!() as usize, other.loc(), self.ctx.caused_by(), ))), } } fn declare_ident(&mut self, tasc: ast::TypeAscription) -> LowerResult { log!(info "entered {}({})", fn_name!(), tasc); let is_instance_ascription = tasc.is_instance_ascription(); let mut dummy_tv_cache = TyVarCache::new(self.ctx.level, &self.ctx); match *tasc.expr { ast::Expr::Accessor(ast::Accessor::Ident(ident)) => { let py_name = Str::rc(ident.inspect().trim_end_matches('!')); let t = self.ctx.instantiate_typespec( &tasc.t_spec, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?; t.lift(); let t = self.ctx.generalize_t(t); if is_instance_ascription { self.declare_instance(&ident, &t, py_name)?; } else { self.declare_subtype(&ident, &t)?; } let muty = Mutability::from(&ident.inspect()[..]); let vis = ident.vis(); let py_name = Str::rc(ident.inspect().trim_end_matches('!')); let vi = VarInfo::new(t, muty, vis, VarKind::Declared, None, None, Some(py_name)); let ident = hir::Identifier::new(ident.dot, ident.name, None, vi); Ok(hir::Expr::Accessor(hir::Accessor::Ident(ident)).type_asc(tasc.t_spec)) } ast::Expr::Accessor(ast::Accessor::Attr(attr)) => { let py_name = Str::rc(attr.ident.inspect().trim_end_matches('!')); let t = self.ctx.instantiate_typespec( &tasc.t_spec, None, &mut dummy_tv_cache, RegistrationMode::Normal, false, )?; let namespace = self.ctx.name.clone(); let ctx = self .ctx .get_mut_singular_ctx(attr.obj.as_ref(), &namespace)?; ctx.assign_var_sig( &ast::VarSignature::new(ast::VarPattern::Ident(attr.ident.clone()), None), &t, ast::DefId(0), Some(py_name), )?; let obj = self.fake_lower_obj(*attr.obj)?; let muty = Mutability::from(&attr.ident.inspect()[..]); let vis = attr.ident.vis(); let py_name = Str::rc(attr.ident.inspect().trim_end_matches('!')); let vi = VarInfo::new(t, muty, vis, VarKind::Declared, None, None, Some(py_name)); let ident = hir::Identifier::new(attr.ident.dot, attr.ident.name, None, vi); let attr = obj.attr_expr(ident); Ok(attr.type_asc(tasc.t_spec)) } other => Err(LowerErrors::from(LowerError::declare_error( self.cfg.input.clone(), line!() as usize, other.loc(), self.ctx.caused_by(), ))), } } fn declare_instance( &mut self, ident: &ast::Identifier, t: &Type, py_name: Str, ) -> LowerResult<()> { // .X = 'x': Type if ident.is_raw() { return Ok(()); } if ident.is_const() { let vi = VarInfo::new( t.clone(), Mutability::Const, ident.vis(), VarKind::Declared, None, None, Some(py_name.clone()), ); self.ctx.decls.insert(ident.name.clone(), vi); } self.ctx.assign_var_sig( &ast::VarSignature::new(ast::VarPattern::Ident(ident.clone()), None), t, ast::DefId(0), Some(py_name), )?; match t { Type::ClassType => { let ty_obj = GenTypeObj::class( mono(format!("{}{ident}", self.ctx.path())), TypeObj::Builtin(Type::Uninited), None, ); self.ctx.register_gen_type(ident, ty_obj); } Type::TraitType => { let ty_obj = GenTypeObj::trait_( mono(format!("{}{ident}", self.ctx.path())), TypeObj::Builtin(Type::Uninited), None, ); self.ctx.register_gen_type(ident, ty_obj); } _ => {} } Ok(()) } fn declare_subtype(&mut self, ident: &ast::Identifier, trait_: &Type) -> LowerResult<()> { if ident.is_raw() { return Ok(()); } if let Some((_, ctx)) = self.ctx.get_mut_type(ident.inspect()) { ctx.register_marker_trait(trait_.clone()); Ok(()) } else { Err(LowerErrors::from(LowerError::no_var_error( self.cfg.input.clone(), line!() as usize, ident.loc(), self.ctx.caused_by(), ident.inspect(), self.ctx.get_similar_name(ident.inspect()), ))) } } fn declare_chunk(&mut self, expr: ast::Expr) -> LowerResult { log!(info "entered {}", fn_name!()); match expr { ast::Expr::Def(def) => Ok(hir::Expr::Def(self.declare_alias_or_import(def)?)), ast::Expr::ClassDef(defs) => Err(LowerErrors::from(LowerError::feature_error( self.cfg.input.clone(), defs.loc(), "class declaration", self.ctx.caused_by(), ))), ast::Expr::TypeAsc(tasc) => Ok(hir::Expr::TypeAsc(self.declare_ident(tasc)?)), ast::Expr::Call(call) if call .additional_operation() .map(|op| op.is_import()) .unwrap_or(false) => { Ok(hir::Expr::Call(self.lower_call(call)?)) } other => Err(LowerErrors::from(LowerError::declare_error( self.cfg.input.clone(), line!() as usize, other.loc(), self.ctx.caused_by(), ))), } } fn declare_module(&mut self, ast: AST) -> HIR { let mut module = hir::Module::with_capacity(ast.module.len()); for chunk in ast.module.into_iter() { match self.declare_chunk(chunk) { Ok(chunk) => { module.push(chunk); } Err(errs) => { self.errs.extend(errs.into_iter()); } } } HIR::new(ast.name, module) } pub fn lower(&mut self, ast: AST, mode: &str) -> Result { log!(info "the AST lowering process has started."); log!(info "the type-checking process has started."); let ast = Reorderer::new(self.cfg.clone()) .reorder(ast) .map_err(|errs| { IncompleteArtifact::new(None, errs, LowerWarnings::from(self.warns.take_all())) })?; if mode == "declare" { let hir = self.declare_module(ast); if self.errs.is_empty() { log!(info "HIR:\n{hir}"); log!(info "the declaring process has completed."); return Ok(CompleteArtifact::new( hir, LowerWarnings::from(self.warns.take_all()), )); } else { log!(err "the declaring process has failed."); return Err(IncompleteArtifact::new( Some(hir), LowerErrors::from(self.errs.take_all()), LowerWarnings::from(self.warns.take_all()), )); } } let mut module = hir::Module::with_capacity(ast.module.len()); if let Err(errs) = self.ctx.preregister(ast.module.block()) { self.errs.extend(errs.into_iter()); } for chunk in ast.module.into_iter() { match self.lower_expr(chunk) { Ok(chunk) => { module.push(chunk); } Err(errs) => { self.errs.extend(errs.into_iter()); } } } self.ctx.check_decls().unwrap_or_else(|mut errs| { self.errs.append(&mut errs); }); let hir = HIR::new(ast.name, module); log!(info "HIR (not resolved, current errs: {}):\n{hir}", self.errs.len()); let hir = match self.ctx.resolve(hir) { Ok(hir) => { log!(info "HIR (resolved):\n{hir}"); hir } Err((hir, errs)) => { self.errs.extend(errs.into_iter()); log!(err "the resolving process has failed. errs: {}", self.errs.len()); return Err(IncompleteArtifact::new( Some(hir), LowerErrors::from(self.errs.take_all()), LowerWarnings::from(self.warns.take_all()), )); } }; // TODO: recursive check for chunk in hir.module.iter() { if let Err(err) = self.use_check(chunk, mode) { self.errs.push(err); } } if self.errs.is_empty() { log!(info "the AST lowering process has completed."); Ok(CompleteArtifact::new( hir, LowerWarnings::from(self.warns.take_all()), )) } else { log!(err "the AST lowering process has failed. errs: {}", self.errs.len()); Err(IncompleteArtifact::new( Some(hir), LowerErrors::from(self.errs.take_all()), LowerWarnings::from(self.warns.take_all()), )) } } }