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regions.lisp
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regions.lisp
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;;; -*- Mode: Lisp; Syntax: Common-Lisp; Package: CLIM-INTERNALS; -*-
;;; --------------------------------------------------------------------------------------
;;; Title: The CLIM Region Datatype
;;; Created: 1998-12-02 19:26
;;; Author: Gilbert Baumann <[email protected]>
;;; License: LGPL (See file COPYING for details).
;;; $Id: regions.lisp,v 1.39 2009-06-03 20:33:16 ahefner Exp $
;;; --------------------------------------------------------------------------------------
;;; (c) copyright 1998,1999,2001 by Gilbert Baumann
;;; (c) copyright 2001 by Arnaud Rouanet ([email protected])
;;; This library is free software; you can redistribute it and/or
;;; modify it under the terms of the GNU Library General Public
;;; License as published by the Free Software Foundation; either
;;; version 2 of the License, or (at your option) any later version.
;;;
;;; This library is distributed in the hope that it will be useful,
;;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
;;; Library General Public License for more details.
;;;
;;; You should have received a copy of the GNU Library General Public
;;; License along with this library; if not, write to the
;;; Free Software Foundation, Inc., 59 Temple Place - Suite 330,
;;; Boston, MA 02111-1307 USA.
;;;; Changes
;;; When Who What
;;; --------------------------------------------------------------------------------------
;;; 2002-06-27 GB REGION-INTERSECTS-REGION-P has an :around method on bounding
;;; rectangles.
;;; 2002-06-04 APD partially fixed (BOUNDING-RECTANGLE* STANDARD-ELLIPSE)
;;; 2001-07-16 GB added (REGION-CONTAINS-POSITION-P STANDARD-ELLIPSE ..)
;;; added (BOUNDING-RECTANGLE* STANDARD-ELLIPSE)
;;; added (REGION-INTERSECTION LINE STANDARD-ELLIPSE) and vice versa
;;; 2001-07-12 GB fixed bugs in
;;; (BOUNDING-RECTANGLE* STANDARD-REGION-UNION)
;;; (BOUNDING-RECTANGLE* STANDARD-REGION-INTERSECTION)
;;; 2001-07-09 GB maybe fixed a bug in MAP-OVER-SCHNITT-GERADE/POLYGON.
;;; 2001-03-09 AR fixed a bug in MAKE-ELLIPICAL-THING
;;; fixed STANDARD-ELLIPTICAL-ARC defclass
;;; 2001-03-06 AR fixed bug in (REGION-EQUAL STANDARD-RECTANGLE STANDARD-RECTANGLE)
;;; REGION is now a subclass of DESIGN.
;;; 2001-01-21 GB fixed bug in (TRANSFORM-REGION T RECTANGLE-SET)
;;; added some documentation
;;; GB = Gilbert Baumann <[email protected]>
;;; AR = Arnaud Rouanet <[email protected]>
;;; ---- TODO ----------------------------------------------------------------------------
;; - ellipses: The intersection of two ellipses is there, but
;; handling the start/end angle is not implemented.
;; - This code is anything else than well organized.
;; - provide better (faster) implementations for REGION-EQUAL,
;; REGION-CONTAINS-REGION-P, and REGION-INTERSECTS-REGION-P.
;; - Compute a union/intersection/difference of an union of polygon vs another
;; polygon or union of polygons directly via POLYGON-OP.
;; - STANDARD-REGION-UNION should either become a subclass
;; 'STANDARD-DISJUNCT-REGION-UNION' or a flag. Some set operations could take
;; advantage out the information, if the subregions of an union are disjunct.
;; - provide sensible PRINT-OBJECT methods.
;; - while you are are at it; provide a reasonable fast vertical scan routine.
;; polygons should make use of the sweep line algorithm.
;; - implement bounding rectangle cache for polygons and polylines
;; - make REGION-CONTAINS-POSITION-P for polygons faster by handling the special
;; case of the intersection of a horizontal line and the polygons
;; - MAKE-POLY{LINE,GON} should canonise its arguments; no edges of length 0 and
;; no co-linear vertexes. Maybe: canonise rectangles? Also a polygon of less
;; than three vertexes is to be considered empty aka +nowhere+.
(in-package :clim-internals)
(defclass nowhere-region (region nowhere-mixin) ())
(defclass everywhere-region (region everywhere-mixin) ())
;; coordinate is defined in coordinates.lisp
(defvar +everywhere+ (make-instance 'everywhere-region))
(defvar +nowhere+ (make-instance 'nowhere-region))
(defmethod bounding-rectangle* ((x nowhere-region))
(values 0 0 0 0))
;; 2.5.1.1 Region Predicates in CLIM
(defgeneric region-equal (region1 region2))
(defgeneric region-contains-region-p (region1 region2))
(defgeneric region-contains-position-p (region x y))
(defgeneric region-intersects-region-p (region1 region2))
;; 2.5.1.2 Composition of CLIM Regions
(defclass standard-region-union (region-set)
((regions :initarg :regions :reader standard-region-set-regions)))
(defclass standard-region-intersection (region-set)
((regions :initarg :regions :reader standard-region-set-regions)))
(defclass standard-region-difference (region-set)
((a :initarg :a :reader standard-region-difference-a)
(b :initarg :b :reader standard-region-difference-b)))
;; Protocol:
(defgeneric region-set-regions (region &key normalize))
(defgeneric map-over-region-set-regions (function region &key normalize))
(defgeneric region-union (region1 region2))
(defgeneric region-intersection (region1 region2))
(defgeneric region-difference (region1 region2))
;;; ---- 2.5.2 CLIM Point Objects --------------------------------------------------------
(defclass standard-point (point)
((x :type coordinate :initarg :x)
(y :type coordinate :initarg :y)))
(defun make-point (x y)
(make-instance 'standard-point :x (coerce x 'coordinate) :y (coerce y 'coordinate)))
(defmethod print-object ((self standard-point) sink)
(with-slots (x y) self
(format sink "#<~S ~S ~S>" 'standard-point x y)))
;; Point protocol: point-position
(defgeneric point-position (point))
(defmethod point-position ((self standard-point))
(with-slots (x y) self
(values x y)))
(defmethod point-x ((self point))
(nth-value 0 (point-position self)))
(defmethod point-y ((self point))
(nth-value 1 (point-position self)))
(defmethod transform-region (transformation (self standard-point))
(with-slots (x y) self
(multiple-value-bind (x* y*) (transform-position transformation x y)
(make-point x* y*))))
(defmethod region-contains-position-p ((self standard-point) px py)
(with-slots (x y) self
(and (coordinate= x px) (coordinate= y py))))
;;; ---- 2.5.3 Polygons and Polylines in CLIM --------------------------------------------
;; Protocol:
(defclass standard-polyline (polyline)
((points :initarg :points)
(closed :initarg :closed)))
(defclass standard-polygon (polygon)
((points :initarg :points)) )
;;; ---- 2.5.3.1 Constructors for CLIM Polygons and Polylines ---------------------------
(defun coord-seq->point-seq (sequence)
(let ((res nil))
(do-sequence ((x y) sequence)
(push (make-point x y) res))
(nreverse res)))
(defun make-polyline (point-seq &key closed)
(assert (every #'pointp point-seq))
(setq point-seq (coerce point-seq 'list))
(cond ((every (lambda (x) (region-equal x (car point-seq)))
(cdr point-seq))
+nowhere+)
(t
(make-instance 'standard-polyline :points point-seq :closed closed))))
(defun make-polyline* (coord-seq &key closed)
(make-polyline (coord-seq->point-seq coord-seq) :closed closed))
(defun make-polygon (point-seq)
(assert (every #'pointp point-seq))
(setq point-seq (coerce point-seq 'list))
(cond ((every (lambda (x) (region-equal x (car point-seq)))
(cdr point-seq))
+nowhere+)
(t
(make-instance 'standard-polygon :points point-seq))))
(defun make-polygon* (coord-seq)
(make-polygon (coord-seq->point-seq coord-seq)))
(defmethod polygon-points ((self standard-polygon))
(with-slots (points) self
points))
(defmethod map-over-polygon-coordinates (fun (self standard-polygon))
(with-slots (points) self
(mapc (lambda (p) (funcall fun (point-x p) (point-y p))) points)))
(defmethod map-over-polygon-segments (fun (self standard-polygon))
(with-slots (points) self
(do ((q points (cdr q)))
((null (cdr q))
(funcall fun (point-x (car q)) (point-y (car q)) (point-x (car points)) (point-y (car points))))
(funcall fun (point-x (car q)) (point-y (car q)) (point-x (cadr q)) (point-y (cadr q))))))
(defmethod polygon-points ((self standard-polyline))
(with-slots (points) self
points))
(defmethod map-over-polygon-coordinates (fun (self standard-polyline))
(with-slots (points) self
(mapc (lambda (p) (funcall fun (point-x p) (point-y p))) points)))
(defmethod map-over-polygon-segments (fun (self standard-polyline))
(with-slots (points closed) self
(do ((q points (cdr q)))
((null (cdr q))
(when closed
(funcall fun (point-x (car q)) (point-y (car q)) (point-x (car points)) (point-y (car points)))))
(funcall fun (point-x (car q)) (point-y (car q)) (point-x (cadr q)) (point-y (cadr q))))))
(defmethod polyline-closed ((self standard-polyline))
(with-slots (closed) self
closed))
(defmethod transform-region (transformation (self standard-polyline))
(with-slots (points closed) self
(make-polyline (mapcar (lambda (p)
(multiple-value-bind (x* y*) (transform-position transformation (point-x p) (point-y p))
(make-point x* y*)))
points)
:closed closed)))
(defmethod transform-region (transformation (self standard-polygon))
(with-slots (points) self
(make-polygon (mapcar (lambda (p)
(multiple-value-bind (x* y*) (transform-position transformation (point-x p) (point-y p))
(make-point x* y*)))
points))))
(defmethod region-contains-position-p ((self standard-polyline) x y)
(setf x (coerce x 'coordinate)
y (coerce y 'coordinate))
(block nil
(map-over-polygon-segments (lambda (x1 y1 x2 y2)
(when (line-contains-point-p* x1 y1 x2 y2 x y)
(return t)))
self)
nil))
(defun line-contains-point-p* (x1 y1 x2 y2 px py)
(and (or (<= x1 px x2) (>= x1 px x2))
(or (<= y1 py y2) (>= y1 py y2))
(coordinate= (* (- py y1) (- x2 x1))
(* (- px x1) (- y2 y1)))))
(defun line-contains-point-p** (x1 y1 x2 y2 px py)
(coordinate= (* (- py y1) (- x2 x1))
(* (- px x1) (- y2 y1))))
;;; ---- 2.5.4 Lines in CLIM -------------------------------------------------------------
;; Line protocol: line-start-point* line-end-point*
(defclass standard-line (line)
((x1 :type coordinate :initarg :x1)
(y1 :type coordinate :initarg :y1)
(x2 :type coordinate :initarg :x2)
(y2 :type coordinate :initarg :y2)))
(defun make-line (start-point end-point)
(make-line* (point-x start-point) (point-y start-point) (point-x end-point) (point-y end-point)))
(defun make-line* (start-x start-y end-x end-y)
(setf start-x (coerce start-x 'coordinate)
start-y (coerce start-y 'coordinate)
end-x (coerce end-x 'coordinate)
end-y (coerce end-y 'coordinate))
(if (and (coordinate= start-x end-x)
(coordinate= start-y end-y))
+nowhere+
(make-instance 'standard-line :x1 start-x :y1 start-y :x2 end-x :y2 end-y)))
(defmethod line-start-point* ((line standard-line))
(with-slots (x1 y1 x2 y2) line
(values x1 y1)))
(defmethod line-end-point* ((line standard-line))
(with-slots (x1 y1 x2 y2) line
(values x2 y2)))
(defmethod line-start-point ((line line))
(multiple-value-bind (x y) (line-start-point* line)
(make-point x y)))
(defmethod line-end-point ((line line))
(multiple-value-bind (x y) (line-end-point* line)
(make-point x y)))
;; polyline protocol for standard-line's:
(defmethod polygon-points ((line standard-line))
(with-slots (x1 y1 x2 y2) line
(list (make-point x1 y1) (make-point x2 y2))))
(defmethod map-over-polygon-coordinates (fun (line standard-line))
(with-slots (x1 y1 x2 y2) line
(funcall fun x1 y1)
(funcall fun x2 y2)))
(defmethod map-over-polygon-segments (fun (line standard-line))
(with-slots (x1 y1 x2 y2) line
(funcall fun x1 y1 x2 y2)))
(defmethod polyline-closed ((line standard-line))
nil)
(defmethod transform-region (transformation (line standard-line))
(with-slots (x1 y1 x2 y2) line
(multiple-value-bind (x1* y1*) (transform-position transformation x1 y1)
(multiple-value-bind (x2* y2*) (transform-position transformation x2 y2)
(make-line* x1* y1* x2* y2*)))))
(defmethod region-contains-position-p ((self standard-line) x y)
(multiple-value-bind (x1 y1) (line-start-point* self)
(multiple-value-bind (x2 y2) (line-end-point* self)
(line-contains-point-p* x1 y1 x2 y2 x y))))
(defmethod print-object ((self standard-line) sink)
(with-slots (x1 y1 x2 y2) self
(format sink "#<~S ~D ~D ~D ~D>" (type-of self) x1 y1 x2 y2)))
;;; ---- 2.5.5 Rectangles in CLIM --------------------------------------------------------
;; protocol:
;; rectangle-edges*
(defclass standard-rectangle (rectangle)
((coordinates :initform (make-array 4 :element-type 'coordinate))))
(defmethod initialize-instance :after ((obj standard-rectangle)
&key (x1 0.0d0) (y1 0.0d0)
(x2 0.0d0) (y2 0.0d0))
(let ((coords (slot-value obj 'coordinates)))
(setf (aref coords 0) x1)
(setf (aref coords 1) y1)
(setf (aref coords 2) x2)
(setf (aref coords 3) y2)))
(defmacro with-standard-rectangle ((x1 y1 x2 y2) rectangle &body body)
(with-gensyms (coords)
`(let ((,coords (slot-value ,rectangle 'coordinates)))
(declare (type (simple-array coordinate (4)) ,coords))
(let ((,x1 (aref ,coords 0))
(,y1 (aref ,coords 1))
(,x2 (aref ,coords 2))
(,y2 (aref ,coords 3)))
(declare (type coordinate ,x1 ,y1 ,x2 ,y2))
,@body))))
(defmacro with-standard-rectangle* ((&key x1 y1 x2 y2) rectangle &body body)
(with-gensyms (coords)
`(let ((,coords (slot-value ,rectangle 'coordinates)))
(declare (type (simple-array coordinate (4)) ,coords))
(let (,@(and x1 `((,x1 (aref ,coords 0))))
,@(and y1 `((,y1 (aref ,coords 1))))
,@(and x2 `((,x2 (aref ,coords 2))))
,@(and y2 `((,y2 (aref ,coords 3)))))
(declare (type coordinate
,@(and x1 `(,x1))
,@(and y1 `(,y1))
,@(and x2 `(,x2))
,@(and y2 `(,y2))))
,@body))))
(defun make-rectangle (point1 point2)
(make-rectangle* (point-x point1) (point-y point1) (point-x point2) (point-y point2)))
(defun make-rectangle* (x1 y1 x2 y2)
(psetq x1 (coerce (min x1 x2) 'coordinate)
x2 (coerce (max x1 x2) 'coordinate)
y1 (coerce (min y1 y2) 'coordinate)
y2 (coerce (max y1 y2) 'coordinate))
(if (or (coordinate= x1 x2)
(coordinate= y1 y2))
+nowhere+
(make-instance 'standard-rectangle :x1 x1 :x2 x2 :y1 y1 :y2 y2)))
(defmethod rectangle-edges* ((rect standard-rectangle))
(with-standard-rectangle (x1 y1 x2 y2)
rect
(values x1 y1 x2 y2)))
;;; standard-rectangles are immutable and all that, but we still need to set
;;; their positions and dimensions (in output recording)
(defgeneric* (setf rectangle-edges*) (x1 y1 x2 y2 rectangle))
(defmethod* (setf rectangle-edges*)
(x1 y1 x2 y2 (rectangle standard-rectangle))
(let ((coords (slot-value rectangle 'coordinates)))
(declare (type (simple-array coordinate (4)) coords))
(setf (aref coords 0) x1)
(setf (aref coords 1) y1)
(setf (aref coords 2) x2)
(setf (aref coords 3) y2))
(values x1 y1 x2 y2))
(defmethod rectangle-min-point ((rect rectangle))
(multiple-value-bind (x1 y1 x2 y2) (rectangle-edges* rect)
(declare (ignore x2 y2))
(make-point x1 y1)))
(defmethod rectangle-min-point ((rect standard-rectangle))
(with-standard-rectangle* (:x1 x1 :y1 y1)
rect
(make-point x1 y1)))
(defmethod rectangle-max-point ((rect rectangle))
(multiple-value-bind (x1 y1 x2 y2) (rectangle-edges* rect)
(declare (ignore x1 y1))
(make-point x2 y2)))
(defmethod rectangle-max-point ((rect standard-rectangle))
(with-standard-rectangle* (:x2 x2 :y2 y2)
rect
(make-point x2 y2)))
(defmethod rectangle-min-x ((rect rectangle))
(nth-value 0 (rectangle-edges* rect)))
(defmethod rectangle-min-x ((rect standard-rectangle))
(with-standard-rectangle* (:x1 x1)
rect
x1))
(defmethod rectangle-min-y ((rect rectangle))
(nth-value 1 (rectangle-edges* rect)))
(defmethod rectangle-min-y ((rect standard-rectangle))
(with-standard-rectangle* (:y1 y1)
rect
y1))
(defmethod rectangle-max-x ((rect rectangle))
(nth-value 2 (rectangle-edges* rect)))
(defmethod rectangle-max-x ((rect standard-rectangle))
(with-standard-rectangle* (:x2 x2)
rect
x2))
(defmethod rectangle-max-y ((rect rectangle))
(nth-value 3 (rectangle-edges* rect)))
(defmethod rectangle-max-y ((rect standard-rectangle))
(with-standard-rectangle* (:y2 y2)
rect
y2))
(defmethod rectangle-width ((rect rectangle))
(multiple-value-bind (x1 y1 x2 y2) (rectangle-edges* rect)
(declare (ignore y1 y2))
(- x2 x1)))
(defmethod rectangle-width ((rect standard-rectangle))
(with-standard-rectangle* (:x1 x1 :x2 x2)
rect
(- x2 x1)))
(defmethod rectangle-height ((rect rectangle))
(multiple-value-bind (x1 y1 x2 y2) (rectangle-edges* rect)
(declare (ignore x1 x2))
(- y2 y1)))
(defmethod rectangle-height ((rect standard-rectangle))
(with-standard-rectangle* (:y1 y1 :y2 y2)
rect
(- y2 y1)))
(defmethod rectangle-size ((rect rectangle))
(multiple-value-bind (x1 y1 x2 y2) (rectangle-edges* rect)
(values (- x2 x1) (- y2 y1))))
(defmethod rectangle-size ((rect standard-rectangle))
(with-standard-rectangle (x1 y1 x2 y2)
rect
(values (- x2 x1) (- y2 y1))))
;; polyline/polygon protocol for standard-rectangle's
(defmethod polygon-points ((rect standard-rectangle))
(with-standard-rectangle (x1 y1 x2 y2)
rect
(list (make-point x1 y1)
(make-point x1 y2)
(make-point x2 y2)
(make-point x2 y1))))
(defmethod map-over-polygon-coordinates (fun (rect standard-rectangle))
(with-standard-rectangle (x1 y1 x2 y2)
rect
(funcall fun x1 y1)
(funcall fun x1 y2)
(funcall fun x2 y2)
(funcall fun x2 y1)))
(defmethod map-over-polygon-segments (fun (rect standard-rectangle))
(with-standard-rectangle (x1 y1 x2 y2)
rect
(funcall fun x1 y1 x1 y2)
(funcall fun x1 y2 x2 y2)
(funcall fun x2 y2 x2 y1)
(funcall fun x2 y1 x1 y1)))
(defmethod transform-region (transformation (rect standard-rectangle))
(cond ((rectilinear-transformation-p transformation)
(with-standard-rectangle (x1 y1 x2 y2)
rect
(multiple-value-bind (x1* y1*) (transform-position transformation x1 y1)
(multiple-value-bind (x2* y2*) (transform-position transformation x2 y2)
(make-rectangle* x1* y1* x2* y2*)))))
(t
(make-polygon (mapcar (lambda (p) (transform-region transformation p))
(polygon-points rect)))) ))
(defmethod region-contains-position-p ((self standard-rectangle) x y)
(with-standard-rectangle (x1 y1 x2 y2)
self
(and (<= x1 (coerce x 'coordinate) x2)
(<= y1 (coerce y 'coordinate) y2))))
;;; ---- 2.5.6 Ellipses and Elliptical Arcs in CLIM --------------------------------------
(defclass elliptical-thing ()
((start-angle :initarg :start-angle)
(end-angle :initarg :end-angle)
(tr :initarg :tr))) ;a transformation from the unit circle to get the elliptical object
(defmethod print-object ((ell elliptical-thing) stream)
(with-slots (start-angle end-angle tr) ell
(format stream "#<~A [~A ~A] ~A>"
(type-of ell)
(and start-angle (* (/ 180 pi) start-angle))
(and end-angle (* (/ 180 pi) end-angle))
tr)))
(defclass standard-ellipse (elliptical-thing ellipse) ())
(defclass standard-elliptical-arc (elliptical-thing elliptical-arc) ())
;;; ---- 2.5.6.1 Constructor Functions for Ellipses and Elliptical Arcs in CLIM ---------
(defun make-ellipse (center-point radius-1-dx radius-1-dy radius-2-dx radius-2-dy &key start-angle end-angle)
(make-ellipse* (point-x center-point) (point-y center-point)
radius-1-dx radius-1-dy radius-2-dx radius-2-dy
:start-angle start-angle
:end-angle end-angle))
(defun make-ellipse* (center-x center-y radius-1-dx radius-1-dy radius-2-dx radius-2-dy
&key start-angle end-angle)
(make-ellipical-thing 'standard-ellipse
center-x center-y radius-1-dx radius-1-dy radius-2-dx radius-2-dy
start-angle end-angle))
(defun make-elliptical-arc (center-point radius-1-dx radius-1-dy radius-2-dx radius-2-dy &key start-angle end-angle)
(make-elliptical-arc* (point-x center-point) (point-y center-point)
radius-1-dx radius-1-dy radius-2-dx radius-2-dy
:start-angle start-angle
:end-angle end-angle))
(defun make-elliptical-arc* (center-x center-y radius-1-dx radius-1-dy radius-2-dx radius-2-dy
&key start-angle end-angle)
(make-ellipical-thing 'standard-elliptical-arc
center-x center-y radius-1-dx radius-1-dy radius-2-dx radius-2-dy
start-angle end-angle))
(defun make-ellipical-thing (class
center-x center-y radius-1-dx radius-1-dy radius-2-dx radius-2-dy
start-angle end-angle)
(setf center-x (coerce center-x 'coordinate)
center-y (coerce center-y 'coordinate)
radius-1-dx (coerce radius-1-dx 'coordinate)
radius-1-dy (coerce radius-1-dy 'coordinate)
radius-2-dx (coerce radius-2-dx 'coordinate)
radius-2-dy (coerce radius-2-dy 'coordinate)
start-angle (and start-angle (coerce start-angle 'coordinate))
end-angle (and end-angle (coerce end-angle 'coordinate)) )
(let ((tr (make-3-point-transformation* 0 0 1 0 0 1
center-x center-y
(+ center-x radius-1-dx) (+ center-y radius-1-dy)
(+ center-x radius-2-dx) (+ center-y radius-2-dy))))
(cond ((and (null start-angle) (null end-angle)))
((null start-angle) (setf start-angle 0))
((null end-angle) (setf end-angle (* 2 pi))))
(make-instance class :tr tr :start-angle start-angle :end-angle end-angle) ))
(defmethod transform-region (transformation (self elliptical-thing))
(with-slots (start-angle end-angle tr) self
;; I think this should be untransform-angle below, as the ellipse angles
;; go counter-clockwise in screen coordinates, whereas our transformations
;; rotate clockwise.. -Hefner
(let ((start-angle* (and start-angle (untransform-angle transformation start-angle)))
(end-angle* (and end-angle (untransform-angle transformation end-angle))))
(when (reflection-transformation-p transformation)
(rotatef start-angle* end-angle*))
(make-instance (type-of self)
:tr (compose-transformations transformation tr)
:start-angle start-angle*
:end-angle end-angle*))))
(defmethod region-contains-position-p ((self standard-ellipse) x y)
;; XXX start/end angle still missing
(with-slots (tr) self
(multiple-value-bind (x y) (untransform-position tr x y)
(<= (+ (* x x) (* y y)) 1))))
(defmethod bounding-rectangle* ((region standard-ellipse))
;; XXX start/end angle still missing
(with-slots (tr) region
(flet ((contact-radius* (x y)
"Returns coordinates of the radius of the point, in
which the vector field (x y) touches the ellipse."
(multiple-value-bind (xc yc) (untransform-distance tr x y)
(let* ((d (sqrt (+ (* xc xc) (* yc yc))))
(xn (- (/ yc d)))
(yn (/ xc d)))
(transform-distance tr xn yn)))))
(multiple-value-bind (cx cy) (ellipse-center-point* region)
(if (zerop (ellipse-radii region))
(values cx cy cx cy)
(multiple-value-bind (vdx vdy) (contact-radius* 1 0)
(declare (ignore vdx))
(multiple-value-bind (hdx hdy) (contact-radius* 0 1)
(declare (ignore hdy))
(let ((rx (abs hdx))
(ry (abs vdy)))
(values (- cx rx) (- cy ry)
(+ cx rx) (+ cy ry))))))))))
(defun intersection-line/unit-circle (x1 y1 x2 y2)
"Computes the intersection of the line from (x1,y1) to (x2,y2) and the unit circle.
If the intersection is empty, NIL is returned.
Otherwise four values are returned: x1, y1, x2, y2; the start and end point of the
resulting line."
(let* ((dx (- x2 x1))
(dy (- y2 y1))
(a (+ (expt dx 2) (expt dy 2)))
(b (+ (* 2 x1 dx) (* 2 y1 dy)))
(c (+ (expt x1 2) (expt y1 2) -1)))
(let ((s1 (- (/ (+ (sqrt (- (expt b 2) (* 4 a c))) b) (* 2 a))))
(s2 (- (/ (- b (sqrt (- (expt b 2) (* 4 a c)))) (* 2 a)))))
(cond ((and (realp s1) (realp s2)
(not (and (< s1 0) (< s2 0)))
(not (and (> s1 1) (> s2 1))))
(let ((s1 (max 0 (min 1 s1)))
(s2 (max 0 (min 1 s2))))
(values (+ x1 (* s1 dx))
(+ y1 (* s1 dy))
(+ x1 (* s2 dx))
(+ y1 (* s2 dy)))))
(t
nil)))))
(defmethod region-intersection ((line line) (ellipse standard-ellipse))
(with-slots (tr) ellipse
(multiple-value-bind (x1 y1 x2 y2)
(multiple-value-call #'intersection-line/unit-circle
(multiple-value-call #'untransform-position tr (line-start-point* line))
(multiple-value-call #'untransform-position tr (line-end-point* line)))
(if x1
(multiple-value-call #'make-line*
(transform-position tr x1 y1)
(transform-position tr x2 y2))
+nowhere+))))
(defmethod region-intersection ((ellipse standard-ellipse) (line standard-line))
(region-intersection ellipse line))
;;; ---- 2.5.6.2 Accessors for CLIM Elliptical Objects -----------------------------------
(defmethod ellipse-center-point* ((self elliptical-thing))
(with-slots (tr) self
(transform-position tr 0 0)))
(defmethod ellipse-center-point ((self elliptical-thing))
(with-slots (tr) self
(transform-region tr (make-point 0 0))))
(defmethod ellipse-radii ((self elliptical-thing))
(with-slots (tr) self
(multiple-value-bind (dx1 dy1) (transform-distance tr 1 0)
(multiple-value-bind (dx2 dy2) (transform-distance tr 0 1)
(values dx1 dy1 dx2 dy2)))))
(defmethod ellipse-start-angle ((self elliptical-thing))
(with-slots (start-angle) self
start-angle))
(defmethod ellipse-end-angle ((self elliptical-thing))
(with-slots (end-angle) self
end-angle))
(defun ellipse-coefficients (ell)
;; Returns the coefficients of the equation specifing the ellipse as in
;; ax^2 + by^2 + cxy + dx + dy - f = 0
;; Note 1:
;; The `f' here may seem to be superfluous, since you
;; could simply multiply the whole equation by 1/f. But this is
;; not the case, since `f' may as well be 0.
;; Note 2:
;; In the literature you often find something like
;; (x^2)/a + (y^2)/b - 1 = 0 for an axis aligned ellipse, but
;; I rather choose to treat all coefficients as simple factors instead
;; of denominators.
(with-slots (tr) ell
;;warum die inverse hier?
(multiple-value-bind (a b d e c f) (get-transformation (invert-transformation tr))
(values
(+ (* a a) (* d d)) ; x**2
(+ (* b b) (* e e)) ; y**2
(+ (* 2 a b) (* 2 d e)) ; xy
(+ (* 2 a c) (* 2 d f)) ; x
(+ (* 2 b c) (* 2 e f)) ; y
(+ (* c c) (* f f) -1)))) )
;;; Straight from the horse's mouth -- moore
;;;
;;; Axis of an ellipse
;;; -------------------------
;; Given an ellipse with its center at the origin, as
;; ax^2 + by^2 + cxy - 1 = 0
;; The two axis of an ellipse are characterized by minimizing and
;; maximizing the radius. Let (x,y) be a point on the delimiter of the
;; ellipse. It's radius (distance from the origin) then is:
;; r^2 = x^2 + y^2
;; To find the axis can now be stated as an minimization problem with
;; constraints. So mechanically construct the auxiliarry function H:
;; H = x^2 + y^2 - k(ax^2 + by^2 + cxy - 1)
;; So the following set of equations remain to be solved
;; (I) dH/dx = 0 = 2x + 2kax + kcy
;; (II) dH/dy = 0 = 2y + 2kby + kcx
;; (III) dH/dk = 0 = ax^2 + by^2 + cxy - 1
;; Unfortunately, as I always do the math work - hopelessly, even -
;; Maxima is the tool of my choice:
;; g1: 2*x + 2*k*a*x + k*c*y$
;; g2: 2*y + 2*k*b*y + k*c*x$
;; g3: a*x*x + b*y*y + c*x*y -1$
;; sol1: solve ([g1,g2],[k,y])$
;; /* This yields two solutions because of the squares with occur. The
;; * last equation (G3) must therefore be handled for both solutions for
;; * y.
;; */
;; y1: rhs(first(rest(first(sol1))))$
;; y2: rhs(first(rest(first(rest(sol1)))))$
;; /* Substitute the 'y' found. */
;; sol2: solve(subst(y1,y,g3),x);
;; x11: rhs(first(sol2));
;; x12: rhs(first(rest(sol2)));
;; sol3: solve(subst(y2,y,g3),x);
;; x21: rhs(first(sol3));
;; x22: rhs(first(rest(sol3)));
;; /* dump everything */
;; dumpsol([[x=x11,y=y1], [x=x12,y=y1], [x=x21,y=y2], [x=x22,y=y2]]);
(defun ellipse-normal-radii* (ell)
(multiple-value-bind (a b c) (ellipse-coefficients ell)
(cond ((coordinate= 0 c)
;; this is the unit circle
(values 0 (sqrt (/ 1 b))
(sqrt (/ 1 a)) 0))
(t
(let* ((x1 (- (/ c
(sqrt (+ (- (* (* c c)
(sqrt (+ (* c c)
(* b b)
(- (* 2 a b)) (* a a)))))
(- (* 2 (* b b)
(sqrt (+ (* c c) (* b b)
(- (* 2 a b)) (* a a)))))
(* 2 a b (sqrt (+ (* c c) (* b b)
(- (* 2 a b))
(* a a))))
(* 2 b (* c c))
(* 2 (expt b 3))
(- (* 4 a (* b b))) (* 2 (* a a) b))))))
(y1 (- (/ (+ (* (sqrt (+ (* c c)
(* b b)
(- (* 2 a b))
(* a a)))
x1)
(- (* b x1)) (* a x1))
c)))
(x2 (- (/ c
(sqrt (+ (* (* c c)
(sqrt (+ (* c c)
(* b b)
(- (* 2 a b))
(* a a))))
(* 2 (* b b) (sqrt (+ (* c c)
(* b b)
(- (* 2 a b))
(* a a))))
(- (* 2 a b (sqrt (+ (* c c)
(* b b)
(- (* 2 a b))
(* a a)))))
(* 2 b (* c c))
(* 2 (expt b 3))
(- (* 4 a (* b b))) (* 2 (* a a) b))))))
(y2 (- (/ (+ (- (* (sqrt (+ (* c c)
(* b b)
(- (* 2 a b))
(* a a)))
x2))
(- (* b x2)) (* a x2))
c))))
(values x1 y1 x2 y2))))))
;;; ---- Intersection of Ellipse vs. Ellipse ---------------------------------------------
;; Das ganze ist so unverstaendlich, ich muss noch mal nach meinen Notizen
;; fanden, um die Herleitung der Loesung fuer das Schnittproblem praesentieren
;; zu koennen.
(defun intersection-ellipse/ellipse (e1 e2)
;; Eine der beiden Ellipsen fuehren wir zuerst auf den Einheitskreis zurueck.
(let ((a (invert-transformation (slot-value e1 'tr))))
(let ((r (intersection-ellipse/unit-circle (transform-region a e2))))
(if (atom r)
r
(mapcar (lambda (p)
(multiple-value-bind (x y) (transform-position (slot-value e1 'tr) (car p) (cdr p))
(make-point x y)))
r)))))
(defun intersection-ellipse/unit-circle (ell)
(multiple-value-bind (a b c d e f) (ellipse-coefficients ell)
(let ((pn (elli-polynom ell)))
(cond ((= (length pn) 0)
:coincident)
(t
(let ((ys (newton-iteration pn 0d0))
(res nil))
(dolist (y ys)
(let ((x (sqrt (- 1 (* y y)))))
(when (realp x)
(when (coordinate= 0 (ellipse-equation a b c d e f x y))
(pushnew (cons x y) res :test #'equal))
(when (coordinate= 0 (ellipse-equation a b c d e f (- x) y))
(pushnew (cons (- x) y) res :test #'equal)) )))
res)) ))))
(defun ellipse-equation (a b c d e f x y)
(+ (* a x x) (* b y y) (* c x y) (* d x) (* e y) f))
(defun elli-polynom (ell)
;; Was ganz lustig ist, ist dass wir bei Kreisen immer ein Polynom
;; vom Grade zwei bekommen.
(multiple-value-bind (a b c d e f) (ellipse-coefficients ell)
(canonize-polynom
(vector (+ (* (- b a) (- b a)) (* c c))
(+ (* 2 b e) (* -2 a e) (* 2 c d))
(+ (* e e) (* 2 (- b a) (+ a f)) (* -1 c c) (* d d))
(+ (* 2 e a) (* 2 e f) (* -2 c d))
(+ (* (+ a f) (+ a f)) (* -1 d d)) ))) )
;; Wir basteln uns mal eine einfache Newtoniteration. Manchmal
;; scheitern wir noch hoffungslos an lokalen Minima. Ansonsten ist das
;; Konvergenzverhalten fuer unsere Aufgabe schon ganz gut. Aber wir
;; handeln uns durch das Abdividieren der Nullstellen z.T. noch
;; beachtliche Fehler ein; ich versuche das zu mildern in dem ich nach
;; Finden einer Nullstell noch eine paar Newtonschritte mit dem
;; Original-Polynom mache (newton-ziel-gerade).
;; Ich sollte man nicht so faul sein und die reichhaltige Literatur zu
;; Rate ziehen tun; es muss auch etwas bessers als Newtoniteration
;; geben. Ich habe da noch so vage Erinnerungen an die
;; Numerik-Vorlesung ...
(defun newton-ziel-gerade (pn x &optional (n 4))
(cond ((= n 0) x)
((multiple-value-bind (f p2) (horner-schema pn x)
(multiple-value-bind (f*) (horner-schema p2 x)
(newton-ziel-gerade pn (- x (/ f f*)) (- n 1)))))))
(defun solve-p1 (b c)
(if (= b 0)
nil
(list (- (/ c b)))))
(defun solve-p2 (a b c)
(cond ((= a 0)
(solve-p1 b c))
(t
(let* ((p (/ b a))
(q (/ c a))
(d (- (/ (* p p) 4) q)))
(cond ((< d 0)
nil)
((= d 0)
(list (/ p 2)))
(t
(list (+ (/ p 2) (sqrt d))
(- (/ p 2) (sqrt d))))))) ))
(defun maybe-solve-polynom-trivially (pn)
(case (length pn)
(0 (values nil t))
(1 (values nil t))
(2 (values (solve-p1 (aref pn 0) (aref pn 1)) t))
(3 (values (solve-p2 (aref pn 0) (aref pn 1) (aref pn 2)) t))
(t (values nil nil))))
(defun canonize-polynom (pn)
(cond ((= (length pn) 0) pn)
((coordinate= (aref pn 0) 0)
(canonize-polynom (subseq pn 1)))
(t pn)))
(defun newton-iteration (polynom x-start)
;; ACHTUNG: Speziell auf unser problem angepasst, nicht ohne lesen uebernehmen!
(multiple-value-bind (sol done?) (maybe-solve-polynom-trivially polynom)
(cond (done?
sol)
(t
(let ((x x-start)
x1
(n 0)
(pn polynom)
(eps-f 0d0)
(eps-f* 0d-16)
(eps-x 1d-20)
(m 20) ;maximal zahl schritte
(res nil) )
(loop
(cond ((> n m)
(return)))
(multiple-value-bind (f p2) (horner-schema pn x)
(multiple-value-bind (f*) (horner-schema p2 x)
(cond ((<= (abs f*) eps-f*)
;; Wir haengen an einer Extremstelle fest -- mit zufaelligem Startwert weiter.
(setf x1 (+ 1d0 (random 2d0))))
(t
(setf x1 (- x (/ f f*)))
(cond ((or (<= (abs f) eps-f)
(<= (abs (- x1 x)) eps-x))
;; noch ein paar newton schritte, um das ergebnis zu verbessern
(setf x1 (newton-ziel-gerade polynom x1))
(push x1 res)
;; abdividieren
(multiple-value-bind (f p2) (horner-schema pn x1)
f
(setq pn (canonize-polynom p2))
(multiple-value-bind (sol done?) (maybe-solve-polynom-trivially pn)
(when done?
;; Hier trotzdem noch nachiterieren -- ist das eine gute Idee?
(setf sol (mapcar (lambda (x) (newton-ziel-gerade polynom x)) sol))
(setf res (nconc sol res))
(return))))
(setf x1 x-start)
(setq n 0)) ))))
(setf x (min 1d0 (max -1d0 x1))) ;Darf man das machen?
(incf n)))
res)) )))
(defun horner-schema (polynom x)
;; Wertet das polynom `polynom' mit Hilfe des Hornerschemas an der
;; Stelle `x' aus; Gibt zwei Werte zurueck: