Get this thing compiling again after the arrowectomy
author |
Steve Losh <steve@stevelosh.com> |
date |
Sat, 21 Jan 2017 12:30:37 +0000 |
parents |
cc9330259660 |
children |
e36b35a1857f |
(in-package :scully.terms)
(in-readtable :fare-quasiquote)
;;;; Overview -----------------------------------------------------------------
;;; We start with a set of grounded rules like: ((next bar) x y (true foo)).
;;;
;;; We need to turn map each term to a unique integer, making sure that they end
;;; up ordered how we want them.
;;;
;;; Our desired ordering has a few "layers":
;;;
;;; Base: (true ...)
;;; Does: (does ...)
;;; Possible: (legal ...)
;;; terminal
;;; (goal ...)
;;; anything that depends on only these or lower
;;; Happens: (next ...)
;;; (sees ...)
;;; anything that depends on only these or lower
;;;
;;; Within each layer the ordering is arbitrary, EXCEPT that if a rule X that
;;; relies on the negation of a rule Y, then Y must come before X.
;;;; Dependency Graph ---------------------------------------------------------
(defun build-dependency-graph (rules &key includep)
"Build a dependency graph of the given `rules`.
All rule heads will be included as vertices.
A head will have a dependency on each of its body terms for which
`(funcall includep term)` returns `t`. If `includep` is `nil` all
dependencies will be included.
Only body terms upon which there is a dependency will be included in the graph
-- if a body term is discarded by `includep` there will be no vertex for it.
"
(let ((graph (digraph:make-digraph :test #'equal)))
(labels
((mark-dependency (head dep)
(digraph:insert-vertex graph dep)
(digraph:insert-edge graph head dep))
(mark-dependencies (head body)
(digraph:insert-vertex graph head)
(iterate (for b :in body)
(when (or (null includep)
(funcall includep b))
(mark-dependency head (bare-term b))))))
(iterate (for (head . body) :in rules)
(mark-dependencies head body)))
graph))
;;;; Layer Partitioning -------------------------------------------------------
;;; We want to partition the terms of the rules into layers. The result will be
;;; a hash table containing two types of entries, for convenience:
;;;
;;; term -> layer keyword
;;; layer keyword -> list of terms in the layer
(defun mark (layers layer term)
(setf (gethash term layers) layer)
(pushnew term (gethash layer layers) :test #'equal)
(values))
(defun extract-simple (predicates layer layers terms)
"Extract simple terms for a given `layer` from `terms`.
Extract the terms with predicates in `predicates` and mark them appropriately
in the `layers` hash table.
Returns a list of remaining terms.
"
(iterate (for term :in terms)
(if (member (term-predicate term) predicates)
(mark layers layer term)
(collect term))))
(defun extract-base (layers terms)
(let ((terms (extract-simple '(ggp-rules::true
ggp-rules::role)
:base layers terms)))
;; In addition to the simple things, we need to make sure we've got
;; a corresponding `(true *)` term for any `(init *)` term.
(iterate (for term :in terms)
(match term
(`(ggp-rules::init ,contents)
(mark layers :base `(ggp-rules::true ,contents))
(mark layers :base term))
(_ (collect term))))))
(defun extract-does (layers terms)
(prog1
(extract-simple '(ggp-rules::does) :does layers terms)
;; In addition to the simple things, we need to make sure we've got
;; a corresponding `(does *)` term for any `(legal *)` term.
(iterate (for term :in terms)
(match term
(`(ggp-rules::legal ,@contents)
(mark layers :does `(ggp-rules::does ,@contents)))
(_ (collect term))))))
(defun extract-possible% (layers dependencies terms)
(labels ((find-dependencies (term)
"Return the layers of each of `term`s dependencies."
(mapcar (rcurry #'gethash layers)
(digraph:successors dependencies term)))
(find-eligible (terms)
"Find terms that depend only on things in `:base`/`:possible`."
(iterate (for term :in terms)
(for unmet = (set-difference (find-dependencies term)
'(:base :possible)))
(when (null unmet)
(collect term)))))
(iterate
(with remaining = terms)
(for next = (find-eligible remaining))
(while next)
(mapcar (curry #'mark layers :possible) next)
(zapf remaining (set-difference % next :test #'equal))
(finally (return remaining)))))
(defun extract-possible (layers dependencies terms)
;; At this point we've got the :base and :does layers finished. We then
;; extract the simple things for the :possible layer.
;;
;; Once we've done this, rules that depend on ONLY things in the
;; :base/:possible layers can also be extracted.
(-<> terms
(extract-simple '(ggp-rules::legal
ggp-rules::goal
ggp-rules::terminal)
:possible layers <>)
(extract-possible% layers dependencies <>)))
(defun extract-early-happens (layers terms)
;; We need to extract these early because we don't want them to get included
;; in the `:possible` layer if they don't depend on anything.
(extract-simple '(ggp-rules::sees
ggp-rules::next)
:happens layers terms))
(defun extract-final-happens (layers terms)
;; Everything left at the end must be in the `:happens` layer.
(mapcar (curry #'mark layers :happens) terms)
nil)
(defun partition-rules (dependencies rules)
(let* ((terms (-<> rules
flatten-once
(mapcar #'bare-term <>)
(remove-duplicates <> :test #'equal)))
(layers (make-hash-table :test #'equal)))
(-<> terms
(extract-base layers <>)
(extract-does layers <>)
(extract-early-happens layers <>) ; ugh
(extract-possible layers dependencies <>)
(extract-final-happens layers <>))
layers))
;;;; Stratification -----------------------------------------------------------
(defun build-single-layer-dependency-graph (rules)
(let* ((layer-heads (remove-duplicates (mapcar #'rule-head rules)
:test #'equal)))
(build-dependency-graph
rules
:includep (lambda (body-term)
(and (negationp body-term)
(member (bare-term body-term) layer-heads
:test #'equal))))))
(defun stratify-layer (rules)
"Stratify a single layer of rules into a list of strata."
(iterate
(with dependencies = (build-single-layer-dependency-graph rules))
(with remaining = rules)
(until (null remaining))
(for next-heads = (digraph:leafs dependencies))
(when (null next-heads)
(error "Cycle in negations detected!"))
(for stratum = (remove-if-not (lambda (head)
(member head next-heads :test #'equal))
remaining
:key #'rule-head))
(collect stratum)
(setf remaining (set-difference remaining stratum :test #'equal))
(dolist (head next-heads)
(digraph:remove-vertex dependencies head))))
;;;; Intra-Layer Ordering -----------------------------------------------------
(defun sort-and-flatten-strata (strata)
"Take `strata` and turn it into a sorted list of rule heads."
(flet ((heads-in-stratum (stratum)
(-<> stratum
(mapcar #'rule-head <>)
(remove-duplicates <> :test #'equal))))
(-<> strata
(mapcar #'heads-in-stratum <>)
(flatten-once <>))))
(defun extract-rules-for-layer (layers rules layer-key)
"Return all rules for the given layer.
`layers` should be a table of terms to layer keys.
`rules` should be the list of all rules.
"
(iterate (for head :in (gethash layer-key layers))
(for matching-rules = (remove-if-not (curry #'equal head) rules
:key #'rule-head))
(appending matching-rules)))
(defun order-layer (layer-terms layer-strata)
"Return a list of all terms in the layer in the proper order."
(let* ((strata-terms (sort-and-flatten-strata layer-strata))
(leftovers (set-difference layer-terms strata-terms :test #'equal)))
(append leftovers strata-terms)))
(defun order-terms (rules)
"Find a linear ordering of all terms in `rules`.
Returns three values:
* A list of all terms, in order
* A list of the `:possible` strata
* A list of the `:happens` strata
"
;; Start by partitioning the terms into the layers.
(let* ((dependencies (build-dependency-graph rules))
(layers (partition-rules dependencies rules)))
;; Then we need to stratify the possible & happens layers.
(let* ((possible-rules (extract-rules-for-layer layers rules :possible))
(happens-rules (extract-rules-for-layer layers rules :happens))
(possible-strata (stratify-layer possible-rules))
(happens-strata (stratify-layer happens-rules)))
;; We order the individual layers.
(let ((base-terms (gethash :base layers))
(does-terms (gethash :does layers))
(possible-terms (order-layer (gethash :possible layers) possible-strata))
(happens-terms (order-layer (gethash :happens layers) happens-strata)))
;; And finally we concatenate the layer orderings into one bigass order:
;; base < possible < does < happens
(values (append base-terms possible-terms does-terms happens-terms)
possible-strata
happens-strata)))))
;;;; Integerization -----------------------------------------------------------
(defun integerize-term (term->number term)
(match term
(`(ggp-rules::not ,body)
`(ggp-rules::not ,(gethash body term->number)))
(_ (gethash term term->number))))
(defun integerize-rule (term->number rule)
(mapcar (curry #'integerize-term term->number) rule))
(defun integerize-stratum (term->number stratum)
(mapcar (curry #'integerize-rule term->number) stratum))
(defun integerize-rules (rules)
"Integerize `rules`.
`rules` should be a (normalized) list of rules.
A list of 4 values will be returned:
* The term->number hash table
* The number->term hash table
* A list of the `:possible` strata
* A list of the `:happens` strata
"
(let ((term->number (make-hash-table :test #'equal))
(number->term (make-hash-table)))
(multiple-value-bind (terms possible happens)
(order-terms rules)
;; Generate the mapping tables
(iterate (for i :from 0)
(for term :in terms)
(setf (gethash i number->term) term
(gethash term term->number) i))
;; Return the tables and the integerized rules
(list term->number
number->term
(mapcar (curry #'integerize-stratum term->number) possible)
(mapcar (curry #'integerize-stratum term->number) happens)))))
;;;; Scratch ------------------------------------------------------------------
(defparameter *rules*
'(
(ggp-rules::<= x (ggp-rules::true a))
(ggp-rules::<= x (ggp-rules::true b))
(ggp-rules::<= y (ggp-rules::true b) (ggp-rules::not z))
(ggp-rules::<= z (ggp-rules::not x) foo)
(ggp-rules::<= dogs (ggp-rules::not y))
(ggp-rules::<= dogs (ggp-rules::true cats))
(ggp-rules::<= mice (ggp-rules::does player something))
; (ggp-rules::<= cats (ggp-rules::does player something) x)
))
(defun print-strata (strata)
(iterate (for i :from 0)
(for stratum :in strata)
(format t "STRATUM ~D:~%~{ ~S~%~}~2%"
i stratum)))
; (-<> *rules*
; (normalize-rules <>)
; (integerize-rules <>)
; ; (nth 2 <>)
; ; (print-strata <>)
; (no <>)
; ; (rest <>)
; ; (map nil #'print-hash-table <>)
; )