Implement anonymous variables and the `*_void` opcodes
That was more difficult than I expected. The shitty part was that we have to
thread the anonymous variables way the hell down into the register allocation
phase. I took the opportunity to refactor a bit so further things like this
shouldn't be quite so bad.
author |
Steve Losh <steve@stevelosh.com> |
date |
Mon, 04 Jul 2016 23:35:08 +0000 |
parents |
27f037427ad3 |
children |
07e1d5f315f5 |
(in-package #:bones.circle)
;;;; Circular, Doubly-Linked Lists
;;; If you found this through a Google search or a link or something, turn back
;;; now. You probably don't want this.
;;;
;;; When we're creating and optimizing the WAM instructions (before rendering
;;; into bytecode) it would be really nice to have a data structure that
;;; supports a few things:
;;;
;;; * O(1) appending (when building the initial list of instructions)
;;; * O(n) forward traversal (when rendering and optimizing for `set_constant`)
;;; * O(n) backward traversal (when optimizing for `unify_constant`)
;;; * In-place removal/replacement, with the ability to choose "which side we
;;; move to" after.
;;;
;;; That last one is tricky. We want to be able to remove/replace/splice
;;; elements during a single traversal. For example, we want to perform the
;;; following optimization for constants (taken from the WAM book erratum):
;;;
;;; unify_variable Xi -> unify_constant c
;;; ...
;;; get_structure c/0, Xi
;;;
;;; The nicest way to do this would be something like:
;;;
;;; 1. Iterate backward from end to start.
;;; 2. When we see a `:get-structure-* CONSTANT LOCALREG` instruction:
;;; A. Remove it in-place, so the next node will be processed on the next
;;; iteration (remember, we're iterating backwards).
;;; B. Search forward for the corresponding `:unify-variable` instruction and
;;; replace it in-place with the `:unify-constant` instruction.
;;;
;;; Of course you could do all this with immutable data structures, but it'll be
;;; pretty slow. And since one of the primary goals of this project is to be
;;; fast, we don't want to do slow things.
;;;
;;; So instead we make our own data structure for the list of WAM instructions.
;;; A "circle" is a circular, doubly-linked list, with a sentinel node to denote
;;; the start/end of the list.
;;;
;;; TODO: explain further
;;; TODO: docstrings below
(defparameter *circle-sentinel* 'circle-sentinel)
(declaim (inline circle-prev circle-value circle-next))
(defstruct circle prev value next)
(declaim (inline circle-tie))
(defun* circle-tie ((c1 circle) (c2 circle))
(:returns :void)
(setf (circle-next c1) c2
(circle-prev c2) c1)
(values))
(defun* make-empty-circle ()
(:returns circle)
"Create an empty circle.
It will still contain a sentinel.
"
(let ((circle (make-circle :value *circle-sentinel*)))
(setf (slot-value circle 'prev) circle
(slot-value circle 'next) circle)
circle))
(defun* make-circle-with ((list list))
"Create a circle whose nodes contain the values in `list`."
(:returns circle)
(let ((sentinel (make-empty-circle)))
(loop :with prev = sentinel
:for value :in list
:for current = (make-circle :prev prev
:value value)
:do (setf (circle-next prev) current
prev current)
:finally (unless (null list)
(circle-tie current sentinel)))
sentinel))
(defun* circle-sentinel-p ((circle circle))
(:returns boolean)
"Return whether this circle node is the sentinel."
(eql (circle-value circle) *circle-sentinel*))
(defun* circle-empty-p ((circle circle))
(:returns boolean)
"Return whether this circle is empty."
(and (circle-sentinel-p circle)
(eql circle (circle-next circle))))
(defun* circle-rotate ((circle circle) (n integer))
(:returns circle)
(cond
((> n 0) (circle-rotate (circle-next circle) (1- n)))
((< n 0) (circle-rotate (circle-prev circle) (1+ n)))
(t circle)))
(defun* circle-nth ((circle circle) (n integer))
(:returns circle)
(assert (circle-sentinel-p circle) ()
"Can only call circle-nth on the sentinel.")
(circle-rotate circle
(if (< n 0)
n
(1+ n))))
(defun* circle-insert-before ((circle circle) value)
(:returns :void)
;; L new old R
(let ((old circle)
(l (circle-prev circle))
; (r (circle-next circle))
(new (make-circle :value value)))
(circle-tie l new)
(circle-tie new old))
(values))
(defun* circle-insert-after ((circle circle) value)
(:returns :void)
;; L old new R
(let ((old circle)
; (l (circle-prev circle))
(r (circle-next circle))
(new (make-circle :value value)))
(circle-tie old new)
(circle-tie new r))
(values)
)
(defun* circle-insert-beginning ((circle circle) value)
(:returns :void)
(assert (circle-sentinel-p circle) ()
"Can only insert-beginning at the sentinel.")
(circle-insert-after circle value))
(defun* circle-insert-end ((circle circle) value)
(:returns :void)
(assert (circle-sentinel-p circle) ()
"Can only insert-end at the sentinel.")
(circle-insert-before circle value))
(defun* circle-prepend-circle ((circle circle) (other circle))
(:returns :void)
(assert (circle-sentinel-p circle) ()
"Can only prepend to the sentinel.")
(assert (circle-sentinel-p other) ()
"Can only prepend from the sentinel.")
;; S new-first ... new-last R
(let ((s circle)
(r (circle-next circle)))
(circle-tie s (circle-next other))
(circle-tie (circle-prev other) r))
(values))
(defun* circle-prepend ((circle circle) values)
(:returns :void)
(unless (null values)
(circle-prepend-circle circle (make-circle-with values)))
(values))
(defun* circle-append-circle ((circle circle) (other circle))
(:returns :void)
(assert (circle-sentinel-p circle) ()
"Can only append to the sentinel.")
(assert (circle-sentinel-p other) ()
"Can only append from the sentinel.")
;; L new-first ... new-last S
(let ((s circle)
(l (circle-prev circle)))
(circle-tie l (circle-next other))
(circle-tie (circle-prev other) s))
(values))
(defun* circle-append ((circle circle) values)
(:returns :void)
(unless (null values)
(circle-append-circle circle (make-circle-with values)))
(values))
(defun* circle-forward ((circle circle))
(:returns (or circle null))
(let ((next (circle-next circle)))
(when (not (circle-sentinel-p next))
next)))
(defun* circle-backward ((circle circle))
(:returns (or circle null))
(let ((prev (circle-prev circle)))
(when (not (circle-sentinel-p prev))
prev)))
(defun* circle-remove ((circle circle))
(:returns :void)
;; L rem R
(assert (not (circle-sentinel-p circle)) () "Cannot remove sentinel.")
(let ((l (circle-prev circle))
(r (circle-next circle)))
(circle-tie l r))
(values))
(defun* circle-backward-remove ((circle circle))
(:returns (or circle null))
(prog1
(circle-backward circle)
(circle-remove circle)))
(defun* circle-forward-remove ((circle circle))
(:returns (or circle null))
(prog1
(circle-forward circle)
(circle-remove circle)))
(defun* circle-replace ((circle circle) value)
(:returns circle)
(assert (not (circle-sentinel-p circle)) ()
"Cannot replace sentinel.")
;; L new R
(let ((l (circle-prev circle))
(r (circle-next circle))
(new (make-circle :value value)))
(circle-tie l new)
(circle-tie new r)
new))
(defun* circle-backward-replace ((circle circle) value)
(:returns (or circle null))
(prog1
(circle-backward circle)
(circle-replace circle value)))
(defun* circle-forward-replace ((circle circle) value)
(:returns (or circle null))
(prog1
(circle-forward circle)
(circle-replace circle value)))
(defun* circle-splice ((circle circle) values)
(:returns :void)
(if (null values)
(circle-remove circle)
(progn
(assert (not (circle-sentinel-p circle)) ()
"Cannot splice sentinel.")
;; L new-first ... new-last R
(let ((l (circle-prev circle))
(r (circle-next circle))
(new (make-circle-with values)))
(circle-tie l (circle-next new))
(circle-tie (circle-prev new) r))))
(values))
(defun* circle-backward-splice ((circle circle) values)
(:returns (or circle null))
(prog1
(circle-backward circle)
(circle-splice circle values)))
(defun* circle-forward-splice ((circle circle) values)
(:returns (or circle null))
(prog1
(circle-forward circle)
(circle-splice circle values)))
(defun* circle-to-list ((circle circle) &optional include-sentinel-p)
(:returns list)
(loop
:with node = circle
:when (or include-sentinel-p
(not (circle-sentinel-p node)))
:collect (circle-value node) :into results
:do (setf node (circle-next node))
:when (eql node circle) :do (return results)))
(defmethod print-object ((object circle) stream)
(print-unreadable-object (object stream :type t :identity nil)
(format stream "~S" (subst '%%% *circle-sentinel* (circle-to-list object t)))))