Okay I am figuring things out about hindley-milner again
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greg
parent
617a30b967
commit
c530715671
@ -115,7 +115,7 @@ impl TypeContext {
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let spec = PathSpecifier(name.clone());
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let spec = PathSpecifier(name.clone());
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let ty = expr.1.as_ref()
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let ty = expr.1.as_ref()
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.map(|ty| self.from_anno(ty))
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.map(|ty| self.from_anno(ty))
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.unwrap_or_else(|| { self.get_existential_type() });
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.unwrap_or_else(|| { self.alloc_existential_type() }); // this call to alloc_existential is OK b/c a binding only ever has one type, so if the annotation is absent, it's fine to just make one de novo
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let entry = TypeContextEntry { ty, constant: *constant };
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let entry = TypeContextEntry { ty, constant: *constant };
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self.symbol_table.insert(spec, entry);
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self.symbol_table.insert(spec, entry);
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},
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},
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@ -137,7 +137,7 @@ impl TypeContext {
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pub fn debug_symbol_table(&self) -> String {
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pub fn debug_symbol_table(&self) -> String {
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format!("Symbol table:\n {:?}", self.symbol_table)
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format!("Symbol table:\n {:?}", self.symbol_table)
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}
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}
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fn get_existential_type(&mut self) -> Type {
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fn alloc_existential_type(&mut self) -> Type {
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let ret = Type::TVar(TypeVar::Exist(self.existential_type_label_count));
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let ret = Type::TVar(TypeVar::Exist(self.existential_type_label_count));
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self.existential_type_label_count += 1;
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self.existential_type_label_count += 1;
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ret
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ret
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@ -153,7 +153,7 @@ impl TypeContext {
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"Int" => TConst(Integer),
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"Int" => TConst(Integer),
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"Bool" => TConst(Boolean),
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"Bool" => TConst(Boolean),
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"String" => TConst(StringT),
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"String" => TConst(StringT),
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_ => self.get_existential_type()
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s => TVar(TypeVar::Univ(Rc::new(format!("{}",s)))),
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}
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}
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},
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},
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&TypeName::Tuple(ref items) => {
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&TypeName::Tuple(ref items) => {
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@ -170,13 +170,22 @@ impl TypeContext {
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use self::Type::*;
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use self::Type::*;
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use self::TypeConst::*;
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use self::TypeConst::*;
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let return_type = sig.type_anno.as_ref().map(|anno| self.from_anno(&anno)).unwrap_or_else(|| { self.get_existential_type() });
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//TODO this won't work properly until you make sure that all (universal) type vars in the function have the same existential type var
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// actually this should never even put existential types into the symbol table at all
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//this will crash if more than 5 arg function is used
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let names = vec!["a", "b", "c", "d", "e", "f"];
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let mut idx = 0;
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let mut get_type = || { let q = TVar(TypeVar::Univ(Rc::new(format!("{}", names.get(idx).unwrap())))); idx += 1; q };
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let return_type = sig.type_anno.as_ref().map(|anno| self.from_anno(&anno)).unwrap_or_else(|| { get_type() });
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if sig.params.len() == 0 {
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if sig.params.len() == 0 {
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TConst(FunctionT(Box::new(TConst(Unit)), Box::new(return_type)))
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TConst(FunctionT(Box::new(TConst(Unit)), Box::new(return_type)))
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} else {
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} else {
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let mut output_type = return_type;
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let mut output_type = return_type;
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for p in sig.params.iter() {
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for p in sig.params.iter() {
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let p_type = p.1.as_ref().map(|anno| self.from_anno(anno)).unwrap_or_else(|| { self.get_existential_type() });
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let p_type = p.1.as_ref().map(|anno| self.from_anno(anno)).unwrap_or_else(|| { get_type() });
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output_type = TConst(FunctionT(Box::new(p_type), Box::new(output_type)));
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output_type = TConst(FunctionT(Box::new(p_type), Box::new(output_type)));
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}
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}
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output_type
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output_type
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@ -202,6 +211,7 @@ impl TypeContext {
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Ok(last)
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Ok(last)
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}
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}
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/*
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fn infer(&mut self, expr: &Expression) -> TypeCheckResult {
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fn infer(&mut self, expr: &Expression) -> TypeCheckResult {
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use self::ExpressionType::*;
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use self::ExpressionType::*;
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use self::Type::*;
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use self::Type::*;
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@ -298,6 +308,39 @@ impl TypeContext {
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))
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))
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)
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)
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}
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}
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*/
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fn infer(&mut self, expr: &Expression) -> TypeCheckResult {
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use self::ExpressionType::*;
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use self::Type::*;
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use self::TypeConst::*;
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Ok(match (&expr.0, &expr.1) {
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(ex, &Some(ref anno)) => {
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let tx = self.infer(&Expression(ex.clone(), None))?; //TODO rewrite this to call into a function that takes just an ExprType, to avoid this cloning
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let ty = self.from_anno(anno);
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self.unify(tx, ty)?
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},
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(&IntLiteral(_), _) => TConst(Integer),
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(&BoolLiteral(_), _) => TConst(Boolean),
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(&Value(ref name), _) => {
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self.lookup(name)
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.map(|entry| entry.ty)
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.ok_or(format!("Couldn't find {}", name))?
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},
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(&Call { ref f, ref arguments }, _) => {
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let tf = self.infer(f)?;
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let targ = self.infer(arguments.get(0).unwrap())?;
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match tf {
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TConst(FunctionT(box t1, box t2)) => {
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let _ = self.unify(t1, targ);
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t2
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},
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_ => return Err(format!("Not a function!")),
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}
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},
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_ => TConst(Bottom),
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})
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}
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fn unify(&mut self, t1: Type, t2: Type) -> TypeCheckResult {
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fn unify(&mut self, t1: Type, t2: Type) -> TypeCheckResult {
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use self::Type::*;
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use self::Type::*;
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