Parameterize Type type over existential/universal
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@ -6,7 +6,7 @@ use util::ScopeStack;
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pub type TypeName = Rc<String>;
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pub type TypeName = Rc<String>;
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pub struct TypeContext<'a> {
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pub struct TypeContext<'a> {
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variable_map: ScopeStack<'a, Rc<String>, Type<()>>,
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variable_map: ScopeStack<'a, Rc<String>, Type<TVar>>,
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evar_count: u32
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evar_count: u32
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}
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}
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@ -28,16 +28,47 @@ enum Type<A> {
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Arrow(Box<Type<A>>, Box<Type<A>>),
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Arrow(Box<Type<A>>, Box<Type<A>>),
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}
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}
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#[derive(Debug, Clone)]
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enum TVar {
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enum TVar {
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Univ(UniversalVar),
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Univ(UVar),
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Exist(ExistentialVar)
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Exist(ExistentialVar)
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}
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}
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struct UniversalVar(Rc<String>);
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#[derive(Debug, Clone)]
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struct UVar(Rc<String>);
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#[derive(Debug, Clone)]
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struct ExistentialVar(u32);
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struct ExistentialVar(u32);
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impl Type<UVar> {
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fn to_tvar(&self) -> Type<TVar> {
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match self {
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Type::Var(UVar(name)) => Type::Var(TVar::Univ(UVar(name.clone()))),
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Type::Const(ref c) => Type::Const(c.clone()),
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Type::Arrow(a, b) => Type::Arrow(
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Box::new(a.to_tvar()),
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Box::new(b.to_tvar())
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)
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}
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}
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}
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impl Type<TVar> {
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fn skolemize(&self) -> Type<UVar> {
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match self {
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Type::Var(TVar::Univ(uvar)) => Type::Var(uvar.clone()),
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Type::Var(TVar::Exist(evar)) => unimplemented!(),
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Type::Const(ref c) => Type::Const(c.clone()),
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Type::Arrow(a, b) => Type::Arrow(
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Box::new(a.skolemize()),
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Box::new(b.skolemize())
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)
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}
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}
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}
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impl TypeIdentifier {
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impl TypeIdentifier {
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fn to_monotype(&self) -> Type<()> {
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fn to_monotype(&self) -> Type<UVar> {
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match self {
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match self {
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TypeIdentifier::Tuple(items) => unimplemented!(),
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TypeIdentifier::Tuple(items) => unimplemented!(),
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TypeIdentifier::Singleton(TypeSingletonName { name, .. }) => {
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TypeIdentifier::Singleton(TypeSingletonName { name, .. }) => {
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@ -94,7 +125,7 @@ impl<'a> TypeContext<'a> {
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}
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}
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impl<'a> TypeContext<'a> {
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impl<'a> TypeContext<'a> {
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fn infer_ast(&mut self, ast: &AST) -> InferResult<Type<()>> {
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fn infer_ast(&mut self, ast: &AST) -> InferResult<Type<UVar>> {
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let mut output = Type::Const(TConst::Unit);
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let mut output = Type::Const(TConst::Unit);
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for statement in ast.0.iter() {
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for statement in ast.0.iter() {
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output = self.infer_statement(statement)?;
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output = self.infer_statement(statement)?;
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@ -102,29 +133,29 @@ impl<'a> TypeContext<'a> {
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Ok(output)
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Ok(output)
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}
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}
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fn infer_statement(&mut self, stmt: &Statement) -> InferResult<Type<()>> {
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fn infer_statement(&mut self, stmt: &Statement) -> InferResult<Type<UVar>> {
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match stmt {
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match stmt {
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Statement::ExpressionStatement(ref expr) => self.infer_expr(expr),
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Statement::ExpressionStatement(ref expr) => self.infer_expr(expr),
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Statement::Declaration(ref decl) => self.infer_decl(decl),
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Statement::Declaration(ref decl) => self.infer_decl(decl),
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}
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}
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}
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}
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fn infer_expr(&mut self, expr: &Expression) -> InferResult<Type<()>> {
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fn infer_expr(&mut self, expr: &Expression) -> InferResult<Type<UVar>> {
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match expr {
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match expr {
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Expression(expr_type, Some(type_anno)) => {
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Expression(expr_type, Some(type_anno)) => {
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let tx = self.infer_expr_type(expr_type)?;
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let tx = self.infer_expr_type(expr_type)?;
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let ty = type_anno.to_monotype();
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let ty = type_anno.to_monotype();
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self.unify(&ty, &tx)
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self.unify(&ty.to_tvar(), &tx.to_tvar()).map(|x| x.skolemize())
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},
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},
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Expression(expr_type, None) => self.infer_expr_type(expr_type)
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Expression(expr_type, None) => self.infer_expr_type(expr_type)
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}
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}
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}
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}
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fn infer_decl(&mut self, expr: &Declaration) -> InferResult<Type<()>> {
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fn infer_decl(&mut self, expr: &Declaration) -> InferResult<Type<UVar>> {
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Ok(Type::Const(TConst::user("unimplemented")))
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Ok(Type::Const(TConst::user("unimplemented")))
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}
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}
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fn infer_expr_type(&mut self, expr_type: &ExpressionType) -> InferResult<Type<()>> {
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fn infer_expr_type(&mut self, expr_type: &ExpressionType) -> InferResult<Type<UVar>> {
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use self::ExpressionType::*;
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use self::ExpressionType::*;
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Ok(match expr_type {
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Ok(match expr_type {
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NatLiteral(_) => Type::Const(TConst::Nat),
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NatLiteral(_) => Type::Const(TConst::Nat),
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@ -135,17 +166,17 @@ impl<'a> TypeContext<'a> {
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//TODO handle the distinction between 0-arg constructors and variables at some point
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//TODO handle the distinction between 0-arg constructors and variables at some point
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// need symbol table for that
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// need symbol table for that
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match self.variable_map.lookup(name) {
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match self.variable_map.lookup(name) {
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Some(ty) => ty.clone(),
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Some(ty) => ty.clone().skolemize(),
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None => return TypeError::new(&format!("Variable {} not found", name))
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None => return TypeError::new(&format!("Variable {} not found", name))
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}
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}
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},
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},
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IfExpression { discriminator, body } => self.infer_if_expr(discriminator, body)?,
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IfExpression { discriminator, body } => self.infer_if_expr(discriminator, body)?,
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Call { f, arguments } => {
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Call { f, arguments } => {
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let tf: Type<()> = self.infer_expr(f)?; //has to be an Arrow Type
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let tf = self.infer_expr(f)?; //has to be an Arrow Type
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let targ = self.infer_expr(&arguments[0])?; // TODO make this work with functions with more than one arg
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let targ = self.infer_expr(&arguments[0])?; // TODO make this work with functions with more than one arg
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match tf {
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match tf {
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Type::Arrow(t1, t2) => {
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Type::Arrow(t1, t2) => {
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self.unify(&t1, &targ)?;
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self.unify(&t1.to_tvar(), &targ.to_tvar())?;
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*t2.clone()
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*t2.clone()
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},
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},
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_ => return TypeError::new("not a function")
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_ => return TypeError::new("not a function")
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@ -163,7 +194,7 @@ impl<'a> TypeContext<'a> {
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})
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})
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}
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}
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fn infer_if_expr(&mut self, discriminator: &Discriminator, body: &IfExpressionBody) -> InferResult<Type<()>> {
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fn infer_if_expr(&mut self, discriminator: &Discriminator, body: &IfExpressionBody) -> InferResult<Type<UVar>> {
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let test = match discriminator {
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let test = match discriminator {
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Discriminator::Simple(expr) => expr,
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Discriminator::Simple(expr) => expr,
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_ => return TypeError::new("Dame desu")
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_ => return TypeError::new("Dame desu")
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@ -177,7 +208,7 @@ impl<'a> TypeContext<'a> {
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unimplemented!()
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unimplemented!()
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}
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}
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fn infer_block(&mut self, block: &Block) -> InferResult<Type<()>> {
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fn infer_block(&mut self, block: &Block) -> InferResult<Type<UVar>> {
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let mut output = Type::Const(TConst::Unit);
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let mut output = Type::Const(TConst::Unit);
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for statement in block.iter() {
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for statement in block.iter() {
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output = self.infer_statement(statement)?;
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output = self.infer_statement(statement)?;
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@ -185,7 +216,7 @@ impl<'a> TypeContext<'a> {
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Ok(output)
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Ok(output)
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}
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}
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fn unify(&mut self, t1: &Type<()>, t2: &Type<()>) -> InferResult<Type<()>> {
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fn unify(&mut self, t1: &Type<TVar>, t2: &Type<TVar>) -> InferResult<Type<TVar>> {
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unimplemented!()
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unimplemented!()
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}
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}
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