use crate::{ codegen::CodeGenContext, symbol_resolver::{SymbolResolver, ValueEnum}, toplevel::DefinitionId, typecheck::{ type_inferencer::PrimitiveStore, typedef::{Type, Unifier}, }, }; use indoc::indoc; use nac3parser::{ast::fold::Fold, parser::parse_program}; use parking_lot::Mutex; use std::{collections::HashMap, sync::Arc}; use test_case::test_case; use super::*; struct ResolverInternal { id_to_type: Mutex>, id_to_def: Mutex>, class_names: Mutex>, } impl ResolverInternal { fn add_id_def(&self, id: StrRef, def: DefinitionId) { self.id_to_def.lock().insert(id, def); } fn add_id_type(&self, id: StrRef, ty: Type) { self.id_to_type.lock().insert(id, ty); } } struct Resolver(Arc); impl SymbolResolver for Resolver { fn get_default_param_value( &self, _: &nac3parser::ast::Expr, ) -> Option { unimplemented!() } fn get_symbol_type( &self, _: &mut Unifier, _: &[Arc>], _: &PrimitiveStore, str: StrRef, ) -> Result { self.0 .id_to_type .lock() .get(&str) .cloned() .ok_or_else(|| format!("cannot find symbol `{}`", str)) } fn get_symbol_value<'ctx, 'a>( &self, _: StrRef, _: &mut CodeGenContext<'ctx, 'a>, ) -> Option> { unimplemented!() } fn get_identifier_def(&self, id: StrRef) -> Result { self.0.id_to_def.lock().get(&id).cloned().ok_or_else(|| "Unknown identifier".to_string()) } fn get_string_id(&self, _: &str) -> i32 { unimplemented!() } fn get_exception_id(&self, _tyid: usize) -> usize { unimplemented!() } } #[test_case( vec![ indoc! {" def fun(a: int32) -> int32: return a "}, indoc! {" class A: def __init__(self): self.a: int32 = 3 "}, indoc! {" class B: def __init__(self): self.b: float = 4.3 def fun(self): self.b = self.b + 3.0 "}, indoc! {" def foo(a: float): a + 1.0 "}, indoc! {" class C(B): def __init__(self): self.c: int32 = 4 self.a: bool = True "}, ]; "register" )] fn test_simple_register(source: Vec<&str>) { let mut composer: TopLevelComposer = Default::default(); for s in source { let ast = parse_program(s, Default::default()).unwrap(); let ast = ast[0].clone(); composer.register_top_level(ast, None, "".into(), false).unwrap(); } } #[test_case( indoc! {" class A: def foo(self): pass a = A() "}; "register" )] fn test_simple_register_without_constructor(source: &str) { let mut composer: TopLevelComposer = Default::default(); let ast = parse_program(source, Default::default()).unwrap(); let ast = ast[0].clone(); composer.register_top_level(ast, None, "".into(), true).unwrap(); } #[test_case( vec![ indoc! {" def fun(a: int32) -> int32: return a "}, indoc! {" def foo(a: float): a + 1.0 "}, indoc! {" def f(b: int64) -> int32: return 3 "}, ], vec![ "fn[[a:0], 0]", "fn[[a:2], 4]", "fn[[b:1], 0]", ], vec![ "fun", "foo", "f" ]; "function compose" )] fn test_simple_function_analyze(source: Vec<&str>, tys: Vec<&str>, names: Vec<&str>) { let mut composer: TopLevelComposer = Default::default(); let internal_resolver = Arc::new(ResolverInternal { id_to_def: Default::default(), id_to_type: Default::default(), class_names: Default::default(), }); let resolver = Arc::new(Resolver(internal_resolver.clone())) as Arc; for s in source { let ast = parse_program(s, Default::default()).unwrap(); let ast = ast[0].clone(); let (id, def_id, ty) = composer.register_top_level(ast, Some(resolver.clone()), "".into(), false).unwrap(); internal_resolver.add_id_def(id, def_id); if let Some(ty) = ty { internal_resolver.add_id_type(id, ty); } } composer.start_analysis(true).unwrap(); for (i, (def, _)) in composer.definition_ast_list.iter().skip(composer.builtin_num).enumerate() { let def = &*def.read(); if let TopLevelDef::Function { signature, name, .. } = def { let ty_str = composer.unifier.internal_stringify( *signature, &mut |id| id.to_string(), &mut |id| id.to_string(), &mut None, ); assert_eq!(ty_str, tys[i]); assert_eq!(name, names[i]); } } } #[test_case( vec![ indoc! {" class A(): a: int32 def __init__(self): self.a = 3 def fun(self, b: B): pass def foo(self, a: T, b: V): pass "}, indoc! {" class B(C): def __init__(self): pass "}, indoc! {" class C(A): def __init__(self): pass def fun(self, b: B): a = 1 pass "}, indoc! {" def foo(a: A): pass "}, indoc! {" def ff(a: T) -> V: pass "} ], vec![]; "simple class compose" )] #[test_case( vec![ indoc! {" class Generic_A(Generic[V], B): a: int64 def __init__(self): self.a = 123123123123 def fun(self, a: int32) -> V: pass "}, indoc! {" class B: aa: bool def __init__(self): self.aa = False def foo(self, b: T): pass "} ], vec![]; "generic class" )] #[test_case( vec![ indoc! {" def foo(a: list[int32], b: tuple[T, float]) -> A[B, bool]: pass "}, indoc! {" class A(Generic[T, V]): a: T b: V def __init__(self, v: V): self.a = 1 self.b = v def fun(self, a: T) -> V: pass "}, indoc! {" def gfun(a: A[list[float], int32]): pass "}, indoc! {" class B: def __init__(self): pass "} ], vec![]; "list tuple generic" )] #[test_case( vec![ indoc! {" class A(Generic[T, V]): a: A[float, bool] b: B def __init__(self, a: A[float, bool], b: B): self.a = a self.b = b def fun(self, a: A[float, bool]) -> A[bool, int32]: pass "}, indoc! {" class B(A[int64, bool]): def __init__(self): pass def foo(self, b: B) -> B: pass def bar(self, a: A[list[B], int32]) -> tuple[A[virtual[A[B, int32]], bool], B]: pass "} ], vec![]; "self1" )] #[test_case( vec![ indoc! {" class A(Generic[T]): a: int32 b: T c: A[int64] def __init__(self, t: T): self.a = 3 self.b = T def fun(self, a: int32, b: T) -> list[virtual[B[bool]]]: pass def foo(self, c: C): pass "}, indoc! {" class B(Generic[V], A[float]): d: C def __init__(self): pass def fun(self, a: int32, b: T) -> list[virtual[B[bool]]]: # override pass "}, indoc! {" class C(B[bool]): e: int64 def __init__(self): pass "} ], vec![]; "inheritance_override" )] #[test_case( vec![ indoc! {" class A(Generic[T]): def __init__(self): pass def fun(self, a: A[T]) -> A[T]: pass "} ], vec!["application of type vars to generic class is not currently supported (at unknown:4:24)"]; "err no type var in generic app" )] #[test_case( vec![ indoc! {" class A(B): def __init__(self): pass "}, indoc! {" class B(A): def __init__(self): pass "} ], vec!["cyclic inheritance detected"]; "cyclic1" )] #[test_case( vec![ indoc! {" class A(B[bool, int64]): def __init__(self): pass "}, indoc! {" class B(Generic[V, T], C[int32]): def __init__(self): pass "}, indoc! {" class C(Generic[T], A): def __init__(self): pass "}, ], vec!["cyclic inheritance detected"]; "cyclic2" )] #[test_case( vec![ indoc! {" class A: pass "} ], vec!["5: Class {\nname: \"A\",\ndef_id: DefinitionId(5),\nancestors: [CustomClassKind { id: DefinitionId(5), params: [] }],\nfields: [],\nmethods: [],\ntype_vars: []\n}"]; "simple pass in class" )] #[test_case( vec![indoc! {" class A: def __init__(): pass "}], vec!["__init__ method must have a `self` parameter (at unknown:2:5)"]; "err no self_1" )] #[test_case( vec![ indoc! {" class A(B, Generic[T], C): def __init__(self): pass "}, indoc! {" class B: def __init__(self): pass "}, indoc! {" class C: def __init__(self): pass "} ], vec!["a class definition can only have at most one base class declaration and one generic declaration (at unknown:1:24)"]; "err multiple inheritance" )] #[test_case( vec![ indoc! {" class A(Generic[T]): a: int32 b: T c: A[int64] def __init__(self, t: T): self.a = 3 self.b = T def fun(self, a: int32, b: T) -> list[virtual[B[bool]]]: pass "}, indoc! {" class B(Generic[V], A[float]): def __init__(self): pass def fun(self, a: int32, b: T) -> list[virtual[B[int32]]]: # override pass "} ], vec!["method fun has same name as ancestors' method, but incompatible type"]; "err_incompatible_inheritance_method" )] #[test_case( vec![ indoc! {" class A(Generic[T]): a: int32 b: T c: A[int64] def __init__(self, t: T): self.a = 3 self.b = T def fun(self, a: int32, b: T) -> list[virtual[B[bool]]]: pass "}, indoc! {" class B(Generic[V], A[float]): a: int32 def __init__(self): pass def fun(self, a: int32, b: T) -> list[virtual[B[bool]]]: # override pass "} ], vec!["field `a` has already declared in the ancestor classes"]; "err_incompatible_inheritance_field" )] #[test_case( vec![ indoc! {" class A: def __init__(self): pass "}, indoc! {" class A: a: int32 def __init__(self): pass "} ], vec!["duplicate definition of class `A` (at unknown:1:1)"]; "class same name" )] fn test_analyze(source: Vec<&str>, res: Vec<&str>) { let print = false; let mut composer: TopLevelComposer = Default::default(); let internal_resolver = make_internal_resolver_with_tvar( vec![ ("T".into(), vec![]), ("V".into(), vec![composer.primitives_ty.bool, composer.primitives_ty.int32]), ("G".into(), vec![composer.primitives_ty.bool, composer.primitives_ty.int64]), ], &mut composer.unifier, print, ); let resolver = Arc::new(Resolver(internal_resolver.clone())) as Arc; for s in source { let ast = parse_program(s, Default::default()).unwrap(); let ast = ast[0].clone(); let (id, def_id, ty) = { match composer.register_top_level(ast, Some(resolver.clone()), "".into(), false) { Ok(x) => x, Err(msg) => { if print { println!("{}", msg); } else { assert_eq!(res[0], msg); } return; } } }; internal_resolver.add_id_def(id, def_id); if let Some(ty) = ty { internal_resolver.add_id_type(id, ty); } } if let Err(msg) = composer.start_analysis(false) { if print { println!("{}", msg); } else { assert_eq!(res[0], msg); } } else { // skip 5 to skip primitives let mut res_vec: Vec = Vec::new(); for (def, _) in composer.definition_ast_list.iter().skip(composer.builtin_num) { let def = &*def.read(); res_vec.push(format!("{}\n", def.to_string(composer.unifier.borrow_mut()))); } insta::assert_debug_snapshot!(res_vec); } } #[test_case( vec![ indoc! {" def fun(a: int32, b: int32) -> int32: return a + b "}, indoc! {" def fib(n: int32) -> int32: if n <= 2: return 1 a = fib(n - 1) b = fib(n - 2) return fib(n - 1) "} ], vec![]; "simple function" )] #[test_case( vec![ indoc! {" class A: a: int32 def __init__(self): self.a = 3 def fun(self) -> int32: b = self.a + 3 return b * self.a def clone(self) -> A: SELF = self return SELF def sum(self) -> int32: if self.a == 0: return self.a else: a = self.a self.a = self.a - 1 return a + self.sum() def fib(self, a: int32) -> int32: if a <= 2: return 1 return self.fib(a - 1) + self.fib(a - 2) "}, indoc! {" def fun(a: A) -> int32: return a.fun() + 2 "} ], vec![]; "simple class body" )] #[test_case( vec![ indoc! {" def fun(a: V, c: G, t: T) -> V: b = a cc = c ret = fun(b, cc, t) return ret * ret "}, indoc! {" def sum_three(l: list[V]) -> V: return l[0] + l[1] + l[2] "}, indoc! {" def sum_sq_pair(p: tuple[V, V]) -> list[V]: a = p[0] b = p[1] a = a**a b = b**b return [a, b] "} ], vec![]; "type var fun" )] #[test_case( vec![ indoc! {" class A(Generic[G]): a: G b: bool def __init__(self, aa: G): self.a = aa if 2 > 1: self.b = True else: # self.b = False pass def fun(self, a: G) -> list[G]: ret = [a, self.a] return ret if self.b else self.fun(self.a) "} ], vec![]; "type var class" )] #[test_case( vec![ indoc! {" class A: def fun(self): pass "}, indoc!{" class B: a: int32 b: bool def __init__(self): # self.b = False if 3 > 2: self.a = 3 self.b = False else: self.a = 4 self.b = True "} ], vec![]; "no_init_inst_check" )] fn test_inference(source: Vec<&str>, res: Vec<&str>) { let print = true; let mut composer: TopLevelComposer = Default::default(); let internal_resolver = make_internal_resolver_with_tvar( vec![ ("T".into(), vec![]), ( "V".into(), vec![ composer.primitives_ty.float, composer.primitives_ty.int32, composer.primitives_ty.int64, ], ), ("G".into(), vec![composer.primitives_ty.bool, composer.primitives_ty.int64]), ], &mut composer.unifier, print, ); let resolver = Arc::new(Resolver(internal_resolver.clone())) as Arc; for s in source { let ast = parse_program(s, Default::default()).unwrap(); let ast = ast[0].clone(); let (id, def_id, ty) = { match composer.register_top_level(ast, Some(resolver.clone()), "".into(), false) { Ok(x) => x, Err(msg) => { if print { println!("{}", msg); } else { assert_eq!(res[0], msg); } return; } } }; internal_resolver.add_id_def(id, def_id); if let Some(ty) = ty { internal_resolver.add_id_type(id, ty); } } if let Err(msg) = composer.start_analysis(true) { if print { println!("{}", msg); } else { assert_eq!(res[0], msg); } } else { // skip 5 to skip primitives let mut stringify_folder = TypeToStringFolder { unifier: &mut composer.unifier }; for (_i, (def, _)) in composer.definition_ast_list.iter().skip(composer.builtin_num).enumerate() { let def = &*def.read(); if let TopLevelDef::Function { instance_to_stmt, name, .. } = def { println!( "=========`{}`: number of instances: {}===========", name, instance_to_stmt.len() ); for inst in instance_to_stmt.iter() { let ast = &inst.1.body; for b in ast.iter() { println!("{:?}", stringify_folder.fold_stmt(b.clone()).unwrap()); println!("--------------------"); } println!("\n"); } } } } } fn make_internal_resolver_with_tvar( tvars: Vec<(StrRef, Vec)>, unifier: &mut Unifier, print: bool, ) -> Arc { let res: Arc = ResolverInternal { id_to_def: Default::default(), id_to_type: tvars .into_iter() .map(|(name, range)| { (name, { let (ty, id) = unifier.get_fresh_var_with_range(range.as_slice(), None, None); if print { println!("{}: {:?}, typevar{}", name, ty, id); } ty }) }) .collect::>() .into(), class_names: Default::default(), } .into(); if print { println!(); } res } struct TypeToStringFolder<'a> { unifier: &'a mut Unifier, } impl<'a> Fold> for TypeToStringFolder<'a> { type TargetU = String; type Error = String; fn map_user(&mut self, user: Option) -> Result { Ok(if let Some(ty) = user { self.unifier.internal_stringify( ty, &mut |id| format!("class{}", id.to_string()), &mut |id| format!("typevar{}", id.to_string()), &mut None, ) } else { "None".into() }) } }