1
1
mirror of https://github.com/github/semantic.git synced 2024-12-19 21:01:35 +03:00
semantic/prototype/Doubt/Syntax.swift
2015-11-03 11:28:52 -05:00

129 lines
4.6 KiB
Swift
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/// A node in a syntax tree. Expressed algebraically to enable representation of both normal syntax trees and their diffs.
public enum Syntax<Recur, A>: CustomDebugStringConvertible {
case Leaf(A)
case Indexed([Recur])
case Fixed([Recur])
case Keyed([String:Recur])
// MARK: Functor
public func map<T>(@noescape transform: Recur throws -> T) rethrows -> Syntax<T, A> {
switch self {
case let .Leaf(n):
return .Leaf(n)
case let .Indexed(x):
return try .Indexed(x.map(transform))
case let .Fixed(x):
return try .Fixed(x.map(transform))
case let .Keyed(d):
return try .Keyed(Dictionary(elements: d.map { try ($0, transform($1)) }))
}
}
// MARK: CustomDebugStringConvertible
public var debugDescription: String {
switch self {
case let .Leaf(n):
return ".Leaf(\(n))"
case let .Indexed(x):
return ".Indexed(\(String(reflecting: x)))"
case let .Fixed(x):
return ".Fixed(\(String(reflecting: x)))"
case let .Keyed(d):
return ".Keyed(\(String(reflecting: d)))"
}
}
}
// MARK: - Hylomorphism
/// Hylomorphism through `Syntax`.
///
/// A hylomorphism (from the Aristotelian philosophy that form and matter are one) is a function of type `A B` whose call-tree is linear in the size of the nodes produced by `up`. Conceptually, its the composition of a catamorphism (see also `cata`) and an anamorphism (see also `ana`), but is implemented by [Stream fusion](http://lambda-the-ultimate.org/node/2192) and as such enjoys O(n) time complexity, O(1) size complexity, and small constant factors for both (modulo inadvisable implementations of `up` and `down`).
///
/// Hylomorphisms are used to construct diffs corresponding to equal terms; see also `CofreeType.zip`.
///
/// `hylo` can be used with arbitrary functors which can eliminate to and introduce with `Syntax` values.
public func hylo<A, B, Leaf>(down: Syntax<B, Leaf> -> B, _ up: A -> Syntax<A, Leaf>)(_ a: A) -> B {
return down(up(a).map(hylo(down, up)))
}
/// Reiteration through `Syntax`.
///
/// This is a form of hylomorphism (from the Aristotelian philosophy that form and matter are one). As such, it returns a function of type `A B` whose call-tree is linear in the size of the nodes produced by `up`. Conceptually, its the composition of a catamorphism (see also `cata`) and an anamorphism (see also `ana`), but is implemented by [Stream fusion](http://lambda-the-ultimate.org/node/2192) and as such enjoys O(n) time complexity, O(1) size complexity, and small constant factors for both (modulo inadvisable implementations of `up` and `down`).
///
/// Hylomorphisms are used to construct diffs corresponding to equal terms; see also `CofreeType.zip`.
///
/// `hylo` can be used with arbitrary functors which can eliminate to and introduce with `Annotation` & `Syntax` pairs.
public func hylo<A, B, Leaf, Annotation>(down: (Annotation, Syntax<B, Leaf>) -> B, _ up: A -> (Annotation, Syntax<A, Leaf>))(_ a: A) -> B {
let (annotation, syntax) = up(a)
return down(annotation, syntax.map(hylo(down, up)))
}
// MARK: - ArrayLiteralConvertible
extension Syntax: ArrayLiteralConvertible {
public init(arrayLiteral: Recur...) {
self = .Indexed(arrayLiteral)
}
}
// MARK: - DictionaryLiteralConvertible
extension Syntax: DictionaryLiteralConvertible {
public init(dictionaryLiteral elements: (String, Recur)...) {
self = .Keyed(Dictionary(elements: elements))
}
}
// MARK: - Equality
extension Syntax {
public static func equals(leaf leaf: (A, A) -> Bool, recur: (Recur, Recur) -> Bool)(_ left: Syntax<Recur, A>, _ right: Syntax<Recur, A>) -> Bool {
switch (left, right) {
case let (.Leaf(l1), .Leaf(l2)):
return leaf(l1, l2)
case let (.Indexed(v1), .Indexed(v2)) where v1.count == v2.count:
return zip(v1, v2).reduce(true) { $0 && recur($1) }
case let (.Fixed(v1), .Fixed(v2)) where v1.count == v2.count:
return zip(v1, v2).reduce(true) { $0 && recur($1) }
case let (.Keyed(d1), .Keyed(d2)) where Set(d1.keys) == Set(d2.keys):
return d1.keys.reduce(true) { $0 && recur(d1[$1]!, d2[$1]!) }
default:
return false
}
}
}
public func == <F: Equatable, A: Equatable> (left: Syntax<F, A>, right: Syntax<F, A>) -> Bool {
return Syntax.equals(leaf: ==, recur: ==)(left, right)
}
// MARK: - JSON
extension Syntax {
public func JSON(@noescape leaf leaf: A -> Doubt.JSON, @noescape recur: Recur -> Doubt.JSON) -> Doubt.JSON {
switch self {
case let .Leaf(a):
return [ "leaf": leaf(a) ]
case let .Indexed(a):
return [ "indexed": .Array(a.map(recur)) ]
case let .Fixed(a):
return [ "fixed": .Array(a.map(recur)) ]
case let .Keyed(d):
return [ "keyed": .Dictionary(Dictionary(elements: d.map { ($0, recur($1)) })) ]
}
}
}
import Prelude