#[macro_use] extern crate pretty_assertions; // #[macro_use] // extern crate indoc; extern crate bumpalo; extern crate roc_mono; mod helpers; // Test monomorphization #[cfg(test)] mod test_mono { use crate::helpers::{can_expr, infer_expr, test_home, CanExprOut}; use bumpalo::Bump; use roc_collections::all::MutMap; use roc_module::ident::TagName::*; use roc_module::symbol::{Interns, Symbol}; use roc_mono::expr::Expr::{self, *}; use roc_mono::expr::Procs; use roc_mono::layout::{Builtin, Layout}; use roc_types::subs::Subs; // HELPERS fn compiles_to(src: &str, expected: Expr<'_>) { compiles_to_with_interns(src, |_| expected) } fn compiles_to_with_interns<'a, F>(src: &str, get_expected: F) where F: FnOnce(Interns) -> Expr<'a>, { let arena = Bump::new(); let CanExprOut { loc_expr, var_store, var, constraint, home, mut interns, .. } = can_expr(src); let subs = Subs::new(var_store.into()); let mut unify_problems = Vec::new(); let (_content, mut subs) = infer_expr(subs, &mut unify_problems, &constraint, var); // Compile and add all the Procs before adding main let mut procs = Procs::default(); let mut ident_ids = interns.all_ident_ids.remove(&home).unwrap(); // assume 64-bit pointers let pointer_size = std::mem::size_of::() as u32; // Populate Procs and Subs, and get the low-level Expr from the canonical Expr let mono_expr = Expr::new( &arena, &mut subs, loc_expr.value, &mut procs, home, &mut ident_ids, pointer_size, ); dbg!(&procs); // Put this module's ident_ids back in the interns interns.all_ident_ids.insert(home, ident_ids); assert_eq!(mono_expr, get_expected(interns)); } #[test] fn int_literal() { compiles_to("5", Int(5)); } #[test] fn float_literal() { compiles_to("0.5", Float(0.5)); } #[test] fn float_addition() { compiles_to( "3.0 + 4", CallByName( Symbol::FLOAT_ADD, &[ (Float(3.0), Layout::Builtin(Builtin::Float64)), (Float(4.0), Layout::Builtin(Builtin::Float64)), ], ), ); } #[test] fn int_addition() { compiles_to( "0xDEADBEEF + 4", CallByName( Symbol::INT_ADD, &[ (Int(3735928559), Layout::Builtin(Builtin::Int64)), (Int(4), Layout::Builtin(Builtin::Int64)), ], ), ); } #[test] fn num_addition() { // Default to Int for `Num *` compiles_to( "3 + 5", CallByName( Symbol::INT_ADD, &[ (Int(3), Layout::Builtin(Builtin::Int64)), (Int(5), Layout::Builtin(Builtin::Int64)), ], ), ); } #[test] fn specialize_closure() { compiles_to( r#" f = \x -> x + 5 { x: f 0x4, y: f 3.14 } "#, { use self::Builtin::*; use Layout::Builtin; let home = test_home(); let gen_symbol_3 = Interns::from_index(home, 3); let gen_symbol_4 = Interns::from_index(home, 4); Struct { fields: &[ ( "x".into(), CallByName(gen_symbol_3, &[(Int(4), Builtin(Int64))]), ), ( "y".into(), CallByName(gen_symbol_4, &[(Float(3.14), Builtin(Float64))]), ), ], layout: Layout::Struct(&[ ("x".into(), Builtin(Int64)), ("y".into(), Builtin(Float64)), ]), } }, ) } #[test] fn bool_literal() { let arena = Bump::new(); compiles_to_with_interns( r#" x : Bool x = True x "#, |interns| { let home = test_home(); let var_x = interns.symbol(home, "x".into()); let stores = [( var_x, Layout::Builtin(Builtin::Bool(Global("False".into()), Global("True".into()))), Bool(true), )]; let load = Load(var_x); Store(arena.alloc(stores), arena.alloc(load)) }, ); } #[test] fn two_element_enum() { let arena = Bump::new(); compiles_to_with_interns( r#" x : [ Yes, No ] x = No x "#, |interns| { let home = test_home(); let var_x = interns.symbol(home, "x".into()); let stores = [( var_x, Layout::Builtin(Builtin::Bool(Global("No".into()), Global("Yes".into()))), Bool(false), )]; let load = Load(var_x); Store(arena.alloc(stores), arena.alloc(load)) }, ); } #[test] fn three_element_enum() { let arena = Bump::new(); compiles_to_with_interns( r#" # this test is brought to you by fruits.com! x : [ Apple, Orange, Banana ] x = Orange x "#, |interns| { let home = test_home(); let var_x = interns.symbol(home, "x".into()); let mut fruits = MutMap::default(); fruits.insert(Global("Banana".into()), 0); fruits.insert(Global("Orange".into()), 1); fruits.insert(Global("Apple".into()), 2); let stores = [(var_x, Layout::Builtin(Builtin::Byte(fruits)), Byte(1))]; let load = Load(var_x); Store(arena.alloc(stores), arena.alloc(load)) }, ); } #[test] fn set_unique_int_list() { compiles_to("List.getUnsafe (List.set [ 12, 9, 7, 3 ] 1 42) 1", { CallByName( Symbol::LIST_GET_UNSAFE, &vec![ ( CallByName( Symbol::LIST_SET, &vec![ ( Array { elem_layout: Layout::Builtin(Builtin::Int64), elems: &vec![Int(12), Int(9), Int(7), Int(3)], }, Layout::Builtin(Builtin::List(&Layout::Builtin( Builtin::Int64, ))), ), (Int(1), Layout::Builtin(Builtin::Int64)), (Int(42), Layout::Builtin(Builtin::Int64)), ], ), Layout::Builtin(Builtin::List(&Layout::Builtin(Builtin::Int64))), ), (Int(1), Layout::Builtin(Builtin::Int64)), ], ) }); } }