/Noq

Simple expression transformer that is not Coq.

Primary LanguageRustMIT LicenseMIT

Noq

EXTREMELY IMPORTANT! THIS LANGUAGE IS A WORK IN PROGRESS! ANYTHING CAN CHANGE AT ANY MOMENT WITHOUT ANY NOTICE! USE THIS LANGUAGE AT YOUR OWN RISK!

Not Coq. Simple expression transformer that is NOT Coq.

Quick Start

$ cargo run ./examples/peano.noq

Main Idea

The Main Idea is being able to define transformation rules of symbolic algebraic expressions and sequentially applying them.

Expression

Current expression syntax can be defined roughly like this:

<expression> ::= <operator-0>
<operator-0> ::= <operator-1> ((`+` | `-`) <operator-0>)*
<operator-1> ::= <operator-2> ((`*` | `/`) <operator-1>)*
<operator-2> ::= <primary> (`^` <operator-2>)*
<primary> ::= (`(` <expression> `)`) | <application-chain> | <symbol> | <variable>
<application-chain> ::= (<symbol> | <variable>) (<fun-args>)+
<symbol> ::= [a-z0-9][_a-zA-Z0-9]*
<variable> ::= [_A-Z][_a-zA-Z0-9]*
<fun-args> ::= `(` (<expression>),* `)`

Rules and Shapes

The two main entities of the language are Rules and Shapes. A rule defines pattern (head) and it's corresponding substitution (body). The rule definition has the following syntax:

<name:symbol> :: <head:expression> = <body:expression>

Here is an example of a rule that swaps elements of a pair:

swap :: swap(pair(A, B)) = pair(B, A)

Shaping is a process of sequential applying of rules to an expression transforming it into a different expression. Shaping has the following syntax:

<expression> {
  ... sequence of rule applications ...
}

For example here is how you shape expression swap(pair(f(a), g(b))) with the swap rule defined above:

swap(pair(f(a), g(b))) {
  swap | all
}

The result of this shaping is pair(g(b), f(a)).

Anonymous rules

You don't have to define a rule to use it in shaping:

swap(pair(f(a), g(b))) {
  swap(pair(A, B)) = pair(B, A) | all
}