schala/schala-lang/src/typechecking.rs

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use std::cell::RefCell;
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use std::rc::Rc;
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use std::collections::HashMap;
use std::fmt;
use std::fmt::Write;
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/*
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use std::collections::hash_set::Union;
use std::iter::Iterator;
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use itertools::Itertools;
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*/
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use parsing;
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use util::StateStack;
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use symbol_table::{SymbolSpec, Symbol, SymbolTable};
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pub type TypeName = Rc<String>;
type TypeResult<T> = Result<T, String>;
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#[derive(Debug, PartialEq, Clone)]
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enum Type {
Const(TConst),
Var(TypeName),
Func(Vec<Type>),
}
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#[derive(Debug, PartialEq, Clone)]
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enum TConst {
Unit,
Nat,
StringT,
Custom(String)
}
#[derive(Debug, PartialEq, Clone)]
struct Scheme {
names: Vec<TypeName>,
ty: Type,
}
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impl fmt::Display for Scheme {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "∀{:?} . {:?}", self.names, self.ty)
}
}
#[derive(Debug, PartialEq, Clone)]
struct Substitution(HashMap<TypeName, Type>);
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impl Substitution {
fn empty() -> Substitution {
Substitution(HashMap::new())
}
}
#[derive(Debug, PartialEq, Clone)]
struct TypeEnv(HashMap<TypeName, Scheme>);
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impl TypeEnv {
fn default() -> TypeEnv {
TypeEnv(HashMap::new())
}
fn populate_from_symbols(&mut self, symbol_table: &SymbolTable) {
for (name, symbol) in symbol_table.values.iter() {
if let SymbolSpec::Func(ref type_names) = symbol.spec {
let mut ch: char = 'a';
let mut names = vec![];
for _ in type_names.iter() {
names.push(Rc::new(format!("{}", ch)));
ch = ((ch as u8) + 1) as char;
}
let sigma = Scheme {
names: names.clone(),
ty: Type::Func(names.into_iter().map(|n| Type::Var(n)).collect())
};
self.0.insert(name.clone(), sigma);
}
}
}
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}
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pub struct TypeContext<'a> {
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values: StateStack<'a, TypeName, Type>,
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symbol_table_handle: Rc<RefCell<SymbolTable>>,
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global_env: TypeEnv
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}
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impl<'a> TypeContext<'a> {
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pub fn new(symbol_table_handle: Rc<RefCell<SymbolTable>>) -> TypeContext<'static> {
TypeContext { values: StateStack::new(None), global_env: TypeEnv::default(), symbol_table_handle }
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}
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pub fn debug_types(&self) -> String {
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let mut output = format!("Type environment\n");
for (name, scheme) in &self.global_env.0 {
write!(output, "{} -> {}\n", name, scheme).unwrap();
}
output
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}
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pub fn type_check_ast(&mut self, input: &parsing::AST) -> Result<String, String> {
let ref symbol_table = self.symbol_table_handle.borrow();
self.global_env.populate_from_symbols(symbol_table);
let output = self.global_env.infer_block(&input.0)?;
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Ok(format!("{:?}", output))
}
}
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impl TypeEnv {
fn instantiate(&mut self, sigma: Scheme) -> Type {
match sigma {
Scheme { ty, .. } => ty,
}
}
fn generate(&mut self, ty: Type) -> Scheme {
Scheme {
names: vec![], //TODO incomplete
ty
}
}
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fn infer_block(&mut self, block: &Vec<parsing::Statement>) -> TypeResult<Type> {
let mut output = Type::Const(TConst::Unit);
for statement in block {
output = self.infer_statement(statement)?;
}
Ok(output)
}
fn infer_statement(&mut self, statement: &parsing::Statement) -> TypeResult<Type> {
match statement {
parsing::Statement::ExpressionStatement(expr) => self.infer_expr(expr),
parsing::Statement::Declaration(decl) => self.infer_decl(decl)
}
}
fn infer_decl(&mut self, decl: &parsing::Declaration) -> TypeResult<Type> {
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use parsing::Declaration::*;
match decl {
Binding { name, expr, .. } => {
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let ty = self.infer_expr(expr)?;
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let sigma = self.generate(ty);
self.0.insert(name.clone(), sigma);
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},
_ => (),
}
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Ok(Type::Const(TConst::Unit))
}
fn infer_expr(&mut self, expr: &parsing::Expression) -> TypeResult<Type> {
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match expr {
parsing::Expression(expr, Some(anno)) => {
self.infer_exprtype(expr)
},
parsing::Expression(expr, None) => {
self.infer_exprtype(expr)
}
}
}
fn infer_exprtype(&mut self, expr: &parsing::ExpressionType) -> TypeResult<Type> {
use self::TConst::*;
use parsing::ExpressionType::*;
Ok(match expr {
NatLiteral(_) => Type::Const(Nat),
StringLiteral(_) => Type::Const(StringT),
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BinExp(op, lhs, rhs) => {
return Err(format!("NOTDONE"))
},
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Call { f, arguments } => {
return Err(format!("NOTDONE"))
},
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Value(name) => {
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let s = match self.0.get(name) {
Some(sigma) => sigma.clone(),
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None => return Err(format!("Unknown variable: {}", name))
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};
self.instantiate(s)
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},
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_ => Type::Const(Unit)
})
}
}
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/* GIANT TODO - use the rust im crate, unless I make this code way less haskell-ish after it's done
*/
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/*
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pub type TypeResult<T> = Result<T, String>;
*/
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/* TODO this should just check the name against a map, and that map should be pre-populated with
* types */
/*
impl parsing::TypeName {
fn to_type(&self) -> TypeResult<Type> {
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use self::parsing::TypeSingletonName;
use self::parsing::TypeName::*;
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use self::Type::*; use self::TConstOld::*;
Ok(match self {
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Tuple(_) => return Err(format!("Tuples not yet implemented")),
Singleton(name) => match name {
TypeSingletonName { name, .. } => match &name[..] {
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/*
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"Nat" => Const(Nat),
"Int" => Const(Int),
"Float" => Const(Float),
"Bool" => Const(Bool),
"String" => Const(StringT),
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*/
n => Const(Custom(n.to_string()))
}
}
})
}
}
*/
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/*
impl TypeContext {
pub fn type_check_ast(&mut self, ast: &parsing::AST) -> TypeResult<String> {
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let ref block = ast.0;
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let mut infer = Infer::default();
let env = TypeEnvironment::default();
let output = infer.infer_block(block, &env);
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match output {
Ok(s) => Ok(format!("{:?}", s)),
Err(s) => Err(format!("Error: {:?}", s))
}
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}
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}
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// this is the equivalent of the Haskell Infer monad
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#[derive(Debug, Default)]
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struct Infer {
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_idents: u32,
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}
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#[derive(Debug)]
enum InferError {
CannotUnify(MonoType, MonoType),
OccursCheckFailed(Rc<String>, MonoType),
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UnknownIdentifier(Rc<String>),
Custom(String),
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}
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type InferResult<T> = Result<T, InferError>;
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impl Infer {
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fn fresh(&mut self) -> MonoType {
let i = self._idents;
self._idents += 1;
let name = Rc::new(format!("{}", ('a' as u8 + 1) as char));
MonoType::Var(name)
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}
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fn unify(&mut self, a: MonoType, b: MonoType) -> InferResult<Substitution> {
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use self::InferError::*; use self::MonoType::*;
Ok(match (a, b) {
(Const(ref a), Const(ref b)) if a == b => Substitution::new(),
(Var(ref name), ref var) => Substitution::bind_variable(name, var),
(ref var, Var(ref name)) => Substitution::bind_variable(name, var),
(Function(box a1, box b1), Function(box a2, box b2)) => {
let s1 = self.unify(a1, a2)?;
let s2 = self.unify(b1.apply_substitution(&s1), b2.apply_substitution(&s1))?;
s1.merge(s2)
},
(a, b) => return Err(CannotUnify(a, b))
})
}
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fn infer_block(&mut self, block: &Vec<parsing::Statement>, env: &TypeEnvironment) -> InferResult<MonoType> {
use self::parsing::Statement;
let mut ret = MonoType::Const(TypeConst::Unit);
for statement in block.iter() {
ret = match statement {
Statement::ExpressionStatement(expr) => {
let (sub, ty) = self.infer_expr(expr, env)?;
//TODO handle substitution monadically
ty
}
Statement::Declaration(decl) => MonoType::Const(TypeConst::Unit),
}
}
Ok(ret)
}
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fn infer_expr(&mut self, expr: &parsing::Expression, env: &TypeEnvironment) -> InferResult<(Substitution, MonoType)> {
use self::parsing::Expression;
match expr {
Expression(e, Some(anno)) => self.infer_annotated_expr(e, anno, env),
/*
let anno_ty = anno.to_type()?;
let ty = self.infer_exprtype(&e)?;
self.unify(ty, anno_ty)
},
*/
Expression(e, None) => self.infer_exprtype(e, env)
}
}
fn infer_annotated_expr(&mut self, expr: &parsing::ExpressionType, anno: &parsing::TypeName, env: &TypeEnvironment) -> InferResult<(Substitution, MonoType)> {
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Err(InferError::Custom(format!("exprtype not done: {:?}", expr)))
}
fn infer_exprtype(&mut self, expr: &parsing::ExpressionType, env: &TypeEnvironment) -> InferResult<(Substitution, MonoType)> {
use self::parsing::ExpressionType::*;
use self::TypeConst::*;
Ok(match expr {
NatLiteral(_) => (Substitution::new(), MonoType::Const(Nat)),
FloatLiteral(_) => (Substitution::new(), MonoType::Const(Float)),
StringLiteral(_) => (Substitution::new(), MonoType::Const(StringT)),
BoolLiteral(_) => (Substitution::new(), MonoType::Const(Bool)),
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Value(name) => match env.lookup(name) {
Some(sigma) => {
let tau = self.instantiate(&sigma);
(Substitution::new(), tau)
},
None => return Err(InferError::UnknownIdentifier(name.clone())),
},
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e => return Err(InferError::Custom(format!("Type inference for {:?} not done", e)))
})
}
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fn instantiate(&mut self, sigma: &PolyType) -> MonoType {
let ref ty: MonoType = sigma.1;
let mut subst = Substitution::new();
for name in sigma.0.iter() {
let fresh_mvar = self.fresh();
let new = Substitution::bind_variable(name, &fresh_mvar);
subst = subst.merge(new);
}
ty.apply_substitution(&subst)
}
}
*/
/* OLD STUFF DOWN HERE */
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/*
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impl TypeContext {
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fn infer_block(&mut self, statements: &Vec<parsing::Statement>) -> TypeResult<Type> {
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let mut ret_type = Type::Const(TConst::Unit);
for statement in statements {
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ret_type = self.infer_statement(statement)?;
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}
Ok(ret_type)
}
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fn infer_statement(&mut self, statement: &parsing::Statement) -> TypeResult<Type> {
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use self::parsing::Statement::*;
match statement {
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ExpressionStatement(expr) => self.infer(expr),
Declaration(decl) => self.add_declaration(decl),
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}
}
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fn add_declaration(&mut self, decl: &parsing::Declaration) -> TypeResult<Type> {
use self::parsing::Declaration::*;
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use self::Type::*;
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match decl {
Binding { name, expr, .. } => {
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let ty = self.infer(expr)?;
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self.bindings.insert(name.clone(), ty);
},
_ => return Err(format!("other formats not done"))
}
Ok(Void)
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}
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fn infer(&mut self, expr: &parsing::Expression) -> TypeResult<Type> {
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use self::parsing::Expression;
match expr {
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Expression(e, Some(anno)) => {
let anno_ty = anno.to_type()?;
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let ty = self.infer_exprtype(&e)?;
self.unify(ty, anno_ty)
},
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Expression(e, None) => self.infer_exprtype(e)
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}
}
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fn infer_exprtype(&mut self, expr: &parsing::ExpressionType) -> TypeResult<Type> {
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use self::parsing::ExpressionType::*;
use self::Type::*; use self::TConst::*;
match expr {
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NatLiteral(_) => Ok(Const(Nat)),
FloatLiteral(_) => Ok(Const(Float)),
StringLiteral(_) => Ok(Const(StringT)),
BoolLiteral(_) => Ok(Const(Bool)),
BinExp(op, lhs, rhs) => { /* remember there are both the haskell convention talk and the write you a haskell ways to do this! */
match op.get_type()? {
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Func(box t1, box Func(box t2, box t3)) => {
let lhs_ty = self.infer(lhs)?;
let rhs_ty = self.infer(rhs)?;
self.unify(t1, lhs_ty)?;
self.unify(t2, rhs_ty)?;
Ok(t3)
},
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other => Err(format!("{:?} is not a binary function type", other))
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}
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},
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PrefixExp(op, expr) => match op.get_type()? {
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Func(box t1, box t2) => {
let expr_ty = self.infer(expr)?;
self.unify(t1, expr_ty)?;
Ok(t2)
},
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other => Err(format!("{:?} is not a prefix op function type", other))
},
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Value(name) => {
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match self.bindings.get(name) {
Some(ty) => Ok(ty.clone()),
None => Err(format!("No binding found for variable: {}", name)),
}
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},
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Call { f, arguments } => {
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let mut tf = self.infer(f)?;
for arg in arguments.iter() {
match tf {
Func(box t, box rest) => {
let t_arg = self.infer(arg)?;
self.unify(t, t_arg)?;
tf = rest;
},
other => return Err(format!("Function call failed to unify; last type: {:?}", other)),
}
}
Ok(tf)
},
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TupleLiteral(expressions) => {
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let mut types = vec![];
for expr in expressions {
types.push(self.infer(expr)?);
}
Ok(Sum(types))
},
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_ => Err(format!("Type not yet implemented"))
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}
}
fn unify(&mut self, t1: Type, t2: Type) -> TypeResult<Type> {
use self::Type::*;// use self::TConst::*;
match (t1, t2) {
(Const(ref a), Const(ref b)) if a == b => Ok(Const(a.clone())),
(a, b) => Err(format!("Types {:?} and {:?} don't unify", a, b))
}
}
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}
*/
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#[cfg(test)]
mod tests {
use super::{Type, TConst, TypeContext};
use super::Type::*;
use super::TConst::*;
macro_rules! type_test {
($input:expr, $correct:expr) => {
{
let mut tc = TypeContext::new();
let ast = ::parsing::parse(::tokenizing::tokenize($input)).0.unwrap() ;
//tc.add_symbols(&ast);
assert_eq!($correct, tc.infer_block(&ast.0).unwrap())
}
}
}
#[test]
fn basic_inference() {
type_test!("30", Const(Nat));
//type_test!("fn x(a: Int): Bool {}; x(1)", TConst(Boolean));
}
}