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@ -5,6 +5,8 @@ Rust Implementation of Ladder-Types (parsing, unification, rewriting, etc)
## Ladder Types
### Motivation
In order to implement complex datastructures and algorithms, usually
many layers of abstraction are built ontop of each other.
Consequently higher-level data types are encoded into lower-level data
@ -57,6 +59,48 @@ this:
1696093021:1696093039:1528324679:1539892301:1638141920:1688010253
```
### Syntax
In their core form, type-terms can be one of the following:
- (**Atomic Type**) | `SomeTypeName`
- (**Literal Integer**) | `0` | `1` | `2` | ...
- (**Literal Character**) | `'a'` | `'b'` | `'c'` | ...
- (**Literal String**) | `"abc"`
- (**Parameter Application**) | `<T1 T2>` given `T1` and `T2` are type-terms
- (**Ladder**) | `T1 ~ T2` given `T1` and `T2` are type-terms
Ontop of that, the following syntax-sugar is defined:
#### Complex Types
- `[ T ]` <===> `<Seq T>`
- `{ a:A b:B }` <===> `<Struct <"a" A> <"b" B>>`
- `a:A | b:B` <===> `<Enum <"a" A> <"b" B>>`
#### Function Types
- `A -> B` <===> `<Fn A B>`
#### Reference Types
- `*A` <===> `<Ptr A>`
- `&A` <===> `<ConstRef A>`
- `&!A` <===> `<MutRef A>`
### Equivalences
#### Currying
`<<A B> C>` <===> `<A B C>`
#### Ladder-Normal-Form
exhaustively apply `<A B~C>` ===> `<A B>~<A C>`
e.g. `[<Digit 10>]~[Char]~[Ascii]` is in **LNF**
#### Parameter-Normal-Form
exhaustively apply `<A B>~<A C>` ===> `<A B~C>`
e.g. `[<Digit 10>~Char~Ascii]` is in **PNF**
## How to use this crate
```rust
@ -73,6 +117,19 @@ fn main() {
}
```
## Roadmap
- [x] (Un-)Parsing
- [x] (De-)Currying
- [x] Unification
- [x] Ladder-Normal-Form
- [x] Parameter-Normal-Form
- [ ] (De)-Sugaring
- [ ] Seq
- [ ] Enum
- [ ] Struct
- [ ] References
- [ ] Function
## License
[GPLv3](COPYING)

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@ -7,6 +7,7 @@ pub mod parser;
pub mod unparser;
pub mod curry;
pub mod lnf;
pub mod pnf;
pub mod subtype;
pub mod unification;

113
src/pnf.rs Normal file
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@ -0,0 +1,113 @@
use crate::term::TypeTerm;
//<<<<>>>><<>><><<>><<<*>>><<>><><<>><<<<>>>>\\
impl TypeTerm {
/// transmute type into Parameter-Normal-Form (PNF)
///
/// Example:
/// ```ignore
/// <Seq <Digit 10>>~<Seq Char>
/// ⇒ <Seq <Digit 10>~Char>
/// ```
pub fn param_normalize(self) -> Self {
match self {
TypeTerm::Ladder(mut rungs) => {
if rungs.len() > 0 {
// normalize all rungs separately
for r in rungs.iter_mut() {
*r = r.clone().param_normalize();
}
// take top-rung
match rungs.remove(0) {
TypeTerm::App(params_top) => {
let mut params_ladders = Vec::new();
let mut tail : Vec<TypeTerm> = Vec::new();
// append all other rungs to ladders inside
// the application
for p in params_top {
params_ladders.push(vec![ p ]);
}
for r in rungs {
match r {
TypeTerm::App(mut params_rung) => {
if params_rung.len() > 0 {
let mut first_param = params_rung.remove(0);
if first_param == params_ladders[0][0] {
for (l, p) in params_ladders.iter_mut().skip(1).zip(params_rung) {
l.push(p.param_normalize());
}
} else {
params_rung.insert(0, first_param);
tail.push(TypeTerm::App(params_rung));
}
}
}
TypeTerm::Ladder(mut rs) => {
for r in rs {
tail.push(r.param_normalize());
}
}
atomic => {
tail.push(atomic);
}
}
}
let head = TypeTerm::App(
params_ladders.into_iter()
.map(
|mut l| {
l.dedup();
match l.len() {
0 => TypeTerm::unit(),
1 => l.remove(0),
_ => TypeTerm::Ladder(l).param_normalize()
}
}
)
.collect()
);
if tail.len() > 0 {
tail.insert(0, head);
TypeTerm::Ladder(tail)
} else {
head
}
}
TypeTerm::Ladder(mut r) => {
r.append(&mut rungs);
TypeTerm::Ladder(r)
}
atomic => {
rungs.insert(0, atomic);
TypeTerm::Ladder(rungs)
}
}
} else {
TypeTerm::unit()
}
}
TypeTerm::App(params) => {
TypeTerm::App(
params.into_iter()
.map(|p| p.param_normalize())
.collect())
}
atomic => atomic
}
}
}
//<<<<>>>><<>><><<>><<<*>>><<>><><<>><<<<>>>>\\

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@ -3,6 +3,7 @@ pub mod lexer;
pub mod parser;
pub mod curry;
pub mod lnf;
pub mod pnf;
pub mod subtype;
pub mod substitution;
pub mod unification;

41
src/test/pnf.rs Normal file
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@ -0,0 +1,41 @@
use crate::dict::TypeDict;
#[test]
fn test_param_normalize() {
let mut dict = TypeDict::new();
assert_eq!(
dict.parse("A~B~C").expect("parse error"),
dict.parse("A~B~C").expect("parse error").param_normalize(),
);
assert_eq!(
dict.parse("<A B>~C").expect("parse error"),
dict.parse("<A B>~C").expect("parse error").param_normalize(),
);
assert_eq!(
dict.parse("<A B~C>").expect("parse error"),
dict.parse("<A B>~<A C>").expect("parse error").param_normalize(),
);
assert_eq!(
dict.parse("<A B~C D~E>").expect("parse error"),
dict.parse("<A B D>~<A C D>~<A C E>").expect("parse errror").param_normalize(),
);
assert_eq!(
dict.parse("<Seq <Digit 10>~Char>").expect("parse error"),
dict.parse("<Seq <Digit 10>>~<Seq Char>").expect("parse errror").param_normalize(),
);
assert_eq!(
dict.parse("<A <B C~D~E> F~G H H>").expect("parse error"),
dict.parse("<A <B C> F H H>
~<A <B D> F H H>
~<A <B E> F H H>
~<A <B E> G H H>").expect("parse errror")
.param_normalize(),
);
}