#[macro_use] extern crate lalrpop_util; lalrpop_mod!(pub grammar); use std::rc::Rc; mod ast; use crate::ast::{Form,PossibleTailCall}; fn eval(e: Rc
, f: Rc) -> Rc { let mut e = e; let mut x = Option::Some(f); loop { let cur = x.take().unwrap(); //println!("Evaluating {:?} in {:?}", cur, e); match *cur { Form::Symbol(ref s) => { let mut t = e; //println!("Looking up {} in {:?}", s, t); //println!("Looking up {}", s); while s != t.car().unwrap().car().unwrap().sym().unwrap() { t = t.cdr().unwrap(); } return t.car().unwrap().cdr().unwrap(); }, Form::Pair(ref c, ref p) => { let comb = eval(Rc::clone(&e), Rc::clone(c)); match *comb { Form::PrimComb(ref _n, ref f) => match f(e, Rc::clone(p)) { PossibleTailCall::Result(r) => return r, PossibleTailCall::TailCall(ne, nx) => { e = ne; x = Some(nx); }, }, Form::DeriComb{ref se, ref de, ref params, ref body } => { let mut new_e = Rc::clone(se); if let Some(de) = de { new_e = assoc(de, Rc::clone(&e), new_e); } if let Some(params) = params.sym() { new_e = assoc(params, Rc::clone(p), new_e); } // always a tail call e = new_e; x = Some(Rc::clone(body)); }, _ => panic!("Tried to call not a Prim/DeriComb {:?}", comb), } }, _ => return cur, } } } fn assoc(k: &str, v: Rc, l: Rc) -> Rc { Rc::new(Form::Pair( Rc::new(Form::Pair( Rc::new(Form::Symbol(k.to_owned())), v)), l)) } fn assoc_vec(kvs: Vec<(&str, Rc)>) -> Rc { let mut to_ret = Rc::new(Form::Nil); for (k, v) in kvs { to_ret = assoc(k, v, to_ret); } to_ret } fn root_env() -> Rc { assoc_vec(vec![ // TODO: Should be properly tail recursive ("eval", Rc::new(Form::PrimComb("eval".to_owned(), |e, p| { //println!("To get eval body, evaluating {:?} in {:?}", p.car(), e); let b = eval(Rc::clone(&e), p.car().unwrap()); let e = if let Some(ne) = p.cdr().unwrap().car() { //println!("To get eval env, evaluating {:?} in {:?}", ne, e); eval(e, ne) } else { e }; //println!("Evaling {:?} in {:?}", b, e); PossibleTailCall::TailCall(e, b) }))), // (vau de params body) ("vau", Rc::new(Form::PrimComb("vau".to_owned(), |e, p| { let de = p.car().unwrap().sym().map(|s| s.to_owned()); let params = p.cdr().unwrap().car().unwrap(); let body = p.cdr().unwrap().cdr().unwrap().car().unwrap(); PossibleTailCall::Result(Rc::new(Form::DeriComb { se: e, de, params, body })) }))), ("=", Rc::new(Form::PrimComb("=".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()); let b = eval(e, p.cdr().unwrap().car().unwrap()); PossibleTailCall::Result(Rc::new(Form::Bool(a == b))) }))), ("if", Rc::new(Form::PrimComb("if".to_owned(), |e, p| { if eval(Rc::clone(&e), p.car().unwrap()).truthy() { PossibleTailCall::TailCall(e, p.cdr().unwrap().car().unwrap()) } else if let Some(els) = p.cdr().unwrap().cdr().and_then(|x| x.car()) { PossibleTailCall::TailCall(e, els) } else { // should we really allow this? (2 arg if with no else) PossibleTailCall::Result(Rc::new(Form::Nil)) } }))), ("cons", Rc::new(Form::PrimComb("cons".to_owned(), |e, p| { let h = eval(Rc::clone(&e), p.car().unwrap()); let t = eval(e, p.cdr().unwrap().car().unwrap()); PossibleTailCall::Result(Rc::new(Form::Pair(h, t))) }))), ("car", Rc::new(Form::PrimComb("car".to_owned(), |e, p| { PossibleTailCall::Result(eval(Rc::clone(&e), p.car().unwrap()).car().unwrap()) }))), ("cdr", Rc::new(Form::PrimComb("cdr".to_owned(), |e, p| { PossibleTailCall::Result(eval(Rc::clone(&e), p.car().unwrap()).cdr().unwrap()) }))), ("quote", Rc::new(Form::PrimComb("quote".to_owned(), |_e, p| { PossibleTailCall::Result(p.car().unwrap()) }))), ("debug", Rc::new(Form::PrimComb("debug".to_owned(), |e, p| { println!("Debug: {:?}", eval(Rc::clone(&e), p.car().unwrap())); PossibleTailCall::TailCall(e, p.cdr().unwrap().car().unwrap()) }))), ("assert", Rc::new(Form::PrimComb("assert".to_owned(), |e, p| { let thing = eval(Rc::clone(&e), p.car().unwrap()); if !thing.truthy() { println!("Assert failed: {:?}", thing); } assert!(thing.truthy()); PossibleTailCall::TailCall(e, p.cdr().unwrap().car().unwrap()) }))), ("+", Rc::new(Form::PrimComb("+".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a + b))) }))), ("-", Rc::new(Form::PrimComb("-".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a - b))) }))), ("*", Rc::new(Form::PrimComb("*".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a * b))) }))), ("/", Rc::new(Form::PrimComb("/".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a / b))) }))), ("%", Rc::new(Form::PrimComb("%".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a % b))) }))), ("&", Rc::new(Form::PrimComb("&".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a & b))) }))), ("|", Rc::new(Form::PrimComb("|".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a | b))) }))), ("^", Rc::new(Form::PrimComb("^".to_owned(), |e, p| { let a = eval(Rc::clone(&e), p.car().unwrap()).int().unwrap(); let b = eval(e, p.cdr().unwrap().car().unwrap()).int().unwrap(); PossibleTailCall::Result(Rc::new(Form::Int(a ^ b))) }))), ("comb?", Rc::new(Form::PrimComb("comb?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::PrimComb(_n, _f) => true, Form::DeriComb { .. } => true, _ => false, }))) }))), ("pair?", Rc::new(Form::PrimComb("pair?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::Pair(_a,_b) => true, _ => false, }))) }))), ("symbol?", Rc::new(Form::PrimComb("symbol?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::Symbol(_) => true, _ => false, }))) }))), ("int?", Rc::new(Form::PrimComb("int?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::Int(_) => true, _ => false, }))) }))), // maybe bool? but also could be derived. Nil def ("bool?", Rc::new(Form::PrimComb("bool?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::Bool(_) => true, _ => false, }))) }))), ("nil?", Rc::new(Form::PrimComb("nil?".to_owned(), |e, p| { PossibleTailCall::Result(Rc::new(Form::Bool(match &*eval(e, p.car().unwrap()) { Form::Nil => true, _ => false, }))) }))), // consts ("true", Rc::new(Form::Bool(true))), ("false", Rc::new(Form::Bool(false))), ("nil", Rc::new(Form::Nil)), ]) } fn main() { let input = "(= 17 ((vau d p (+ (eval (car p) d) 13)) (+ 1 3)))"; let parsed_input = grammar::TermParser::new().parse(input).unwrap(); println!("Parsed input is {:?}", parsed_input); let result = eval(root_env(), Rc::new(parsed_input)); println!("Result is {:?}", result); } #[test] fn parse_test() { let g = grammar::TermParser::new(); for test in [ "22", "(22)", "(((22)))", "(22 )", "()", "( )", "( 44)", "(44 )", "(22 44 (1) 33 (4 5 (6) 6))", "hello", "-", "+", "(+ 1 ;hi 3)", "'13", "hello-world", "_", ] { assert!(g.parse(test).is_ok()); } assert!(g.parse("((22)").is_err()); } fn eval_test>(gram: &grammar::TermParser, e: &Rc, code: &str, expected: T) { assert_eq!(*eval(Rc::clone(e), Rc::new(gram.parse(code).unwrap())), expected.into()); } #[test] fn basic_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, "(+ 2 (car (cons 4 '(1 2))))", 6); eval_test(&g, &e, "(= 17 ((vau d p (+ (eval (car p) d) 13)) (+ 1 3)))", true); eval_test(&g, &e, "(if (= 2 2) (+ 1 2) (+ 3 4))", 3); eval_test(&g, &e, "(quote a)", "a"); eval_test(&g, &e, "'a", "a"); eval_test(&g, &e, "'(1 . a)", (1, "a")); eval_test(&g, &e, "'(1 a)", (1, ("a", Form::Nil))); eval_test(&g, &e, "true", true); eval_test(&g, &e, "false", false); eval_test(&g, &e, "nil", Form::Nil); eval_test(&g, &e, "(+ 1 2)", 3); eval_test(&g, &e, "(- 1 2)", -1); eval_test(&g, &e, "(* 1 2)", 2); eval_test(&g, &e, "(/ 4 2)", 2); eval_test(&g, &e, "(% 3 2)", 1); eval_test(&g, &e, "(& 3 2)", 2); eval_test(&g, &e, "(| 2 1)", 3); eval_test(&g, &e, "(^ 2 1)", 3); eval_test(&g, &e, "(^ 3 1)", 2); eval_test(&g, &e, "(comb? +)", true); eval_test(&g, &e, "(comb? (vau d p 1))", true); eval_test(&g, &e, "(comb? 1)", false); eval_test(&g, &e, "(pair? '(a))", true); //eval_test(&g, &e, "(pair? '())", true); eval_test(&g, &e, "(nil? nil)", true); eval_test(&g, &e, "(nil? 1)", false); eval_test(&g, &e, "(pair? 1)", false); eval_test(&g, &e, "(symbol? 'a)", true); eval_test(&g, &e, "(symbol? 1)", false); eval_test(&g, &e, "(int? 1)", true); eval_test(&g, &e, "(int? true)", false); eval_test(&g, &e, "(bool? true)", true); eval_test(&g, &e, "(bool? 1)", false); eval_test(&g, &e, "!(bool?) 1", false); eval_test(&g, &e, "!(bool?) true", true); eval_test(&g, &e, "((vau root_env _ (eval 'a (cons (cons 'a 2) root_env))))", 2); } use once_cell::sync::Lazy; static LET: Lazy = Lazy::new(|| { "!((vau root_env p (eval (car p) (cons (cons 'let1 (vau de p (eval (car (cdr (cdr p))) (cons (cons (car p) (eval (car (cdr p)) de)) de))) ) root_env))))".to_owned() }); #[test] fn fib_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (let1 x 10 (+ x 7))", *LET), 17); let def_fib = " !(let1 fib (vau de p !(let1 self (eval (car p) de)) !(let1 n (eval (car (cdr p)) de)) !(if (= 0 n) 0) !(if (= 1 n) 1) (+ (self self (- n 1)) (self self (- n 2))) ))"; eval_test(&g, &e, &format!("{} {} (fib fib 6)", *LET, def_fib), 8); } #[test] fn fact_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); let def_fact = " !(let1 fact (vau de p !(let1 self (eval (car p) de)) !(let1 n (eval (car (cdr p)) de)) !(if (= 0 n) 1) (* n (self self (- n 1))) ))"; eval_test(&g, &e, &format!("{} {} (fact fact 6)", *LET, def_fact), 720); } static VAPPLY: Lazy = Lazy::new(|| { format!(" {} !(let1 vapply (vau de p !(let1 f (eval (car p) de)) !(let1 ip (eval (car (cdr p)) de)) !(let1 nde (eval (car (cdr (cdr p))) de)) (eval (cons f ip) nde) ))", *LET) }); #[test] fn vapply_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // need the vapply to keep env in check because otherwise the env keeps growing // and the Rc::drop will overflow the stack lol let def_badid = format!(" {} !(let1 badid (vau de p !(let1 inner (vau ide ip !(let1 self (car ip)) !(let1 n (car (cdr ip))) !(let1 acc (car (cdr (cdr ip)))) !(if (= 0 n) acc) (vapply self (cons self (cons (- n 1) (cons (+ acc 1) nil))) de) )) (vapply inner (cons inner (cons (eval (car p) de) (cons 0 nil))) de) ))", *VAPPLY); // Won't work unless tail calls work eval_test(&g, &e, &format!("{} (badid 1000)", def_badid), 1000); } static VMAP: Lazy = Lazy::new(|| { format!(" {} !(let1 vmap (vau de p !(let1 vmap_inner (vau ide ip !(let1 self (car ip)) !(let1 f (car (cdr ip))) !(let1 l (car (cdr (cdr ip)))) !(if (= nil l) l) (cons (vapply f (cons (car l) nil) de) (vapply self (cons self (cons f (cons (cdr l) nil))) de)) )) (vapply vmap_inner (cons vmap_inner (cons (eval (car p) de) (cons (eval (car (cdr p)) de) nil))) de) ))", *VAPPLY) }); #[test] fn vmap_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // Maybe define in terms of a right fold? eval_test(&g, &e, &format!("{} (vmap (vau de p (+ 1 (car p))) '(1 2 3))", *VMAP), (2, (3, (4, Form::Nil)))); } static WRAP: Lazy = Lazy::new(|| { format!(" {} !(let1 wrap (vau de p !(let1 f (eval (car p) de)) (vau ide p (vapply f (vmap (vau _ xp (eval (car xp) ide)) p) ide)) ))", *VMAP) }); #[test] fn wrap_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // Make sure (wrap (vau ...)) and internal style are optimized the same eval_test(&g, &e, &format!("{} ((wrap (vau _ p (+ (car p) 1))) (+ 1 2))", *WRAP), 4); } static UNWRAP: Lazy = Lazy::new(|| { format!(" {} !(let1 unwrap (vau de p !(let1 f (eval (car p) de)) (vau ide p (vapply f (vmap (vau _ xp (cons quote (cons (car xp) nil))) p) ide)) ))", *WRAP) }); #[test] fn unwrap_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // Can't represent prims in tests :( - they do work though, uncommenting and checking the // failed assert verifies //eval_test(&g, &e, &format!("{} ((unwrap (vau de p (car p))) (+ 1 2))", def_unwrap), ("quote", (("+", (1, (2, Form::Nil))), Form::Nil))); //eval_test(&g, &e, &format!("{} ((unwrap (vau de p (eval (car p) de))) (+ 1 2))", def_unwrap), (("+", (1, (2, Form::Nil))), Form::Nil)); eval_test(&g, &e, &format!("{} ((unwrap (vau de p (eval (eval (car p) de) de))) (+ 1 2))", *UNWRAP), 3); eval_test(&g, &e, &format!("{} ((unwrap (vau de p (+ (eval (eval (car p) de) de) 1))) (+ 1 2))", *UNWRAP), 4); } static LAPPLY: Lazy = Lazy::new(|| { format!(" {} !(let1 lapply (vau de p !(let1 f (eval (car p) de)) !(let1 ip (eval (car (cdr p)) de)) !(let1 nde (eval (car (cdr (cdr p))) de)) (eval (cons (unwrap f) ip) nde) ))", *UNWRAP) }); #[test] fn lapply_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // Should this allow envs at all? It technically can, but I feel like it kinda goes against the // sensible deriviation let def_lbadid = format!(" {} !(let1 lbadid (vau de p !(let1 inner (wrap (vau ide ip !(let1 self (car ip)) !(let1 n (car (cdr ip))) !(let1 acc (car (cdr (cdr ip)))) !(if (= 0 n) acc) (lapply self (cons self (cons (- n 1) (cons (+ acc 1) nil))) de) ))) (lapply inner (cons inner (cons (eval (car p) de) (cons 0 nil))) de) ))", *LAPPLY); // Won't work unless tail calls work // takes a while though eval_test(&g, &e, &format!("{} (lbadid 1000)", def_lbadid), 1000); } static VFOLDL: Lazy = Lazy::new(|| { format!(" {} !(let1 vfoldl (vau de p !(let1 vfoldl_inner (vau ide ip !(let1 self (car ip)) !(let1 f (car (cdr ip))) !(let1 a (car (cdr (cdr ip)))) !(let1 l (car (cdr (cdr (cdr ip))))) !(if (= nil l) a) (vapply self (cons self (cons f (cons (vapply f (cons a (cons (car l) nil)) de) (cons (cdr l) nil)))) de) )) (vapply vfoldl_inner (cons vfoldl_inner (cons (eval (car p) de) (cons (eval (car (cdr p)) de) (cons (eval (car (cdr (cdr p))) de) nil)))) de) ))", *LAPPLY) }); #[test] fn vfoldl_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (vfoldl (vau de p (+ (car p) (car (cdr p)))) 0 '(1 2 3))", *VFOLDL), 6); } static ZIPD: Lazy = Lazy::new(|| { format!(" {} !(let1 zipd (vau de p !(let1 zipd_inner (vau ide ip !(let1 self (car ip)) !(let1 a (car (cdr ip))) !(let1 b (car (cdr (cdr ip)))) !(if (= nil a) a) !(if (= nil b) b) (cons (cons (car a) (car b)) (vapply self (cons self (cons (cdr a) (cons (cdr b) nil))) de)) )) (vapply zipd_inner (cons zipd_inner (cons (eval (car p) de) (cons (eval (car (cdr p)) de) nil))) de) ))", *VFOLDL) }); #[test] fn zipd_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (zipd '(1 2 3) '(4 5 6))", *ZIPD), ((1,4), ((2,5), ((3,6), Form::Nil)))); } static CONCAT: Lazy = Lazy::new(|| { format!(" {} !(let1 concat (vau de p !(let1 concat_inner (vau ide ip !(let1 self (car ip)) !(let1 a (car (cdr ip))) !(let1 b (car (cdr (cdr ip)))) !(if (= nil a) b) (cons (car a) (vapply self (cons self (cons (cdr a) (cons b nil))) de)) )) (vapply concat_inner (cons concat_inner (cons (eval (car p) de) (cons (eval (car (cdr p)) de) nil))) de) ))", *ZIPD) }); #[test] fn concat_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (concat '(1 2 3) '(4 5 6))", *CONCAT), (1, (2, (3, (4, (5, (6, Form::Nil))))))); } static BVAU: Lazy = Lazy::new(|| { format!(" {} !(let1 match_params (wrap (vau 0 p !(let1 self (car p)) !(let1 p_ls (car (cdr p))) !(let1 dp (car (cdr (cdr p)))) !(let1 e (car (cdr (cdr (cdr p))))) !(if (= nil p_ls) (assert (= nil dp) e)) !(if (symbol? p_ls) (cons (cons p_ls dp) e)) (self self (cdr p_ls) (cdr dp) (self self (car p_ls) (car dp) e)) ))) !(let1 bvau (vau se p (if (= nil (cdr (cdr p))) ; No de case !(let1 p_ls (car p)) !(let1 b_v (car (cdr p))) (vau 0 dp (eval b_v (match_params match_params p_ls dp se)) ) ; de case !(let1 de_s (car p)) !(let1 p_ls (car (cdr p))) !(let1 b_v (car (cdr (cdr p)))) (vau dde dp (eval b_v (match_params match_params p_ls dp (cons (cons de_s dde) se))) ) ) ))", *CONCAT) }); #[test] fn bvau_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} ((bvau _ (a b c) (+ a (- b c))) 10 2 3)", *BVAU), 9); eval_test(&g, &e, &format!("{} ((bvau (a b c) (+ a (- b c))) 10 2 3)", *BVAU), 9); eval_test(&g, &e, &format!("{} ((bvau (a b . c) c) 10 2 3)", *BVAU), (3, Form::Nil)); eval_test(&g, &e, &format!("{} ((bvau (a b . c) c) 10 2)", *BVAU), Form::Nil); eval_test(&g, &e, &format!("{} ((bvau (a b . c) c) 10 2 3 4 5)", *BVAU), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((bvau c c) 3 4 5)", *BVAU), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((bvau c c))", *BVAU), Form::Nil); eval_test(&g, &e, &format!("{} ((bvau ((a b) . c) c) (10 2) 3 4 5)", *BVAU), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((bvau ((a b) . c) a) (10 2) 3 4 5)", *BVAU), 10); eval_test(&g, &e, &format!("{} ((bvau ((a b) . c) b) (10 2) 3 4 5)", *BVAU), 2); eval_test(&g, &e, &format!("{} ((wrap (bvau _ (a b c) (+ a (- b c)))) (+ 10 1) (+ 2 2) (+ 5 3))", *BVAU), 7); eval_test(&g, &e, &format!("{} ((wrap (bvau (a b c) (+ a (- b c)))) (+ 10 1) (+ 2 2) (+ 5 3))", *BVAU), 7); } static LAMBDA: Lazy = Lazy::new(|| { format!(" {} !(let1 lambda (vau de p (wrap (vapply bvau p de)) ))", *BVAU) }); #[test] fn lambda_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} ((lambda (a b c) (+ a (- b c))) (+ 10 1) (+ 2 2) (+ 5 3))", *LAMBDA), 7); eval_test(&g, &e, &format!("{} ((lambda (a b . c) c) 10 2 3)", *LAMBDA), (3, Form::Nil)); eval_test(&g, &e, &format!("{} ((lambda (a b . c) c) 10 2)", *LAMBDA), Form::Nil); eval_test(&g, &e, &format!("{} ((lambda (a b . c) c) 10 2 3 4 5)", *LAMBDA), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((lambda c c) 3 4 5)", *LAMBDA), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((lambda c c))", *LAMBDA), Form::Nil); eval_test(&g, &e, &format!("{} ((lambda ((a b) . c) c) '(10 2) 3 4 5)", *LAMBDA), (3, (4, (5, Form::Nil)))); eval_test(&g, &e, &format!("{} ((lambda ((a b) . c) a) '(10 2) 3 4 5)", *LAMBDA), 10); eval_test(&g, &e, &format!("{} ((lambda ((a b) . c) b) '(10 2) 3 4 5)", *LAMBDA), 2); eval_test(&g, &e, &format!("{} ((lambda ((a b . c) d) b) '(10 2 3 4) 3)", *LAMBDA), 2); eval_test(&g, &e, &format!("{} ((lambda ((a b . c) d) c) '(10 2 3 4) 3)", *LAMBDA), (3, (4, Form::Nil))); // should fail //eval_test(&g, &e, &format!("{} ((lambda (a b c) c) 10 2 3 4)", *LAMBDA), 3); } static LET2: Lazy = Lazy::new(|| { format!(" {} !(let1 let1 (bvau dp (s v b) (eval b (match_params match_params s (eval v dp) dp)) )) ", *LAMBDA) }); #[test] fn let2_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (let1 x (+ 10 1) (+ x 1))", *LET2), 12); eval_test(&g, &e, &format!("{} (let1 x '(10 1) x)", *LET2), (10, (1, Form::Nil))); eval_test(&g, &e, &format!("{} (let1 (a b) '(10 1) a)", *LET2), 10); eval_test(&g, &e, &format!("{} (let1 (a b) '(10 1) b)", *LET2), 1); eval_test(&g, &e, &format!("{} (let1 (a b . c) '(10 1) c)", *LET2), Form::Nil); eval_test(&g, &e, &format!("{} (let1 (a b . c) '(10 1 2 3) c)", *LET2), (2, (3, Form::Nil))); eval_test(&g, &e, &format!("{} (let1 ((a . b) . c) '((10 1) 2 3) a)", *LET2), 10); eval_test(&g, &e, &format!("{} (let1 ((a . b) . c) '((10 1) 2 3) b)", *LET2), (1, Form::Nil)); // should fail //eval_test(&g, &e, &format!("{} (let1 (a b c) '(10 2 3 4) a)", *LET2), 10); } static LIST: Lazy = Lazy::new(|| { format!(" {} !(let1 list (lambda args args)) ", *LET2) }); #[test] fn list_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (list 1 2 (+ 3 4))", *LIST), (1, (2, (7, Form::Nil)))); } static Y: Lazy = Lazy::new(|| { format!(" {} !(let1 Y (lambda (f3) ((lambda (x1) (x1 x1)) (lambda (x2) (f3 (wrap (vau app_env y (lapply (x2 x2) y app_env))))))) ) ", *LIST) }); #[test] fn y_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} ((Y (lambda (recurse) (lambda (n) (if (= 0 n) 1 (* n (recurse (- n 1))))))) 5)", *Y), 120); } static RLAMBDA: Lazy = Lazy::new(|| { format!(" {} !(let1 rlambda (bvau se (n p b) (eval (list Y (list lambda (list n) (list lambda p b))) se) )) ", *Y) }); #[test] fn rlambda_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} ((rlambda recurse (n) (if (= 0 n) 1 (* n (recurse (- n 1))))) 5)", *RLAMBDA), 120); } static AND_OR: Lazy = Lazy::new(|| { // need to extend for varidac format!(" {} !(let1 and (bvau se (a b) !(let1 ae (eval a se)) (if ae (eval b se) ae) )) !(let1 or (bvau se (a b) !(let1 ae (eval a se)) (if ae ae (eval b se)) )) ", *RLAMBDA) }); #[test] fn and_or_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); eval_test(&g, &e, &format!("{} (and true true)", *AND_OR), true); eval_test(&g, &e, &format!("{} (and false true)", *AND_OR), false); eval_test(&g, &e, &format!("{} (and true false)", *AND_OR), false); eval_test(&g, &e, &format!("{} (and false false)", *AND_OR), false); eval_test(&g, &e, &format!("{} (or true true)", *AND_OR), true); eval_test(&g, &e, &format!("{} (or false true)", *AND_OR), true); eval_test(&g, &e, &format!("{} (or true false)", *AND_OR), true); eval_test(&g, &e, &format!("{} (or false false)", *AND_OR), false); } static MATCH: Lazy = Lazy::new(|| { format!(" {} !(let1 match (vau de (x . cases) !(let1 evaluate_case (rlambda evaluate_case (access c) !(if (symbol? c) (array true (lambda (b) (array let (array c access) b)))) !(if (and (array? c) (= 2 (len c)) (= 'unquote (idx c 0))) (array (array = access (idx c 1)) (lambda (b) b))) !(if (and (array? c) (= 2 (len c)) (= 'quote (idx c 0))) (array (array = access c) (lambda (b) b))) !(if (array? c) !(let1 tests (array and (array array? access) (array = (len c) (array len access)))) !(let1 (tests body_func) ((lambda recurse (tests body_func i) (if (= i (len c)) (array tests body_func) ; else !(let1 (inner_test inner_body_func) (evaluate_case (array idx access i) (idx c i)) ) (recurse (concat tests (array inner_test)) (lambda (b) (body_func (inner_body_func b))) (+ i 1)))) tests (lambda (b) b) 0)) (array tests body_func)) (array (array = access c) (lambda (b) b)) )) !(let1 helper (rlambda helper (x_sym cases i) (if (< i (- (len cases) 1)) (let1 (test body_func) (evaluate_case x_sym (idx cases i)) (concat (array test (body_func (idx cases (+ i 1)))) (helper x_sym cases (+ i 2)))) (array true (array assert false))))) (eval (array let (array '___MATCH_SYM x) (concat (array cond) (helper '___MATCH_SYM cases 0))) de) )) ", *AND_OR) }); //#[test] //fn match_eval_test() { let g = grammar::TermParser::new(); let e = root_env(); // eval_test(&g, &e, &format!("{} (match (+ 1 2) 1 2 2 3 3 4 true 0)", *MATCH), 120); //}