/* $Xorg: do_tris.c,v 1.3 2000/08/17 19:54:10 cpqbld Exp $ */ /***************************************************************************** Copyright 1988, 1989 by Digital Equipment Corporation, Maynard, Massachusetts. All Rights Reserved Permission to use, copy, modify, and distribute this software and its documentation for any purpose and without fee is hereby granted, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation, and that the name of Digital not be used in advertising or publicity pertaining to distribution of the software without specific, written prior permission. DIGITAL DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL DIGITAL BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. ******************************************************************************/ /* $XFree86$ */ #undef POLYTRIANGLE_HACK /* don't use this code */ #ifdef POLYTRIANGLE_HACK #include #endif #include "x11perf.h" #include "bitmaps.h" #include #include #define NUM_POINTS 3 /* 3 points to a triangle */ static XPoint *points; static GC pgc; #ifndef PI #define PI 3.14159265357989 #endif static double Area(XPoint p1, XPoint p2, XPoint p3) { return (p1.x*p2.y - p1.x*p3.y + p2.x*p3.y - p2.x*p1.y + p3.x*p1.y - p3.x*p2.y)/2; } /* static double Distance(XPoint p1, XPoint p2) { return sqrt((float) ((p1.x-p2.x)*(p1.x-p2.x) + (p1.y-p2.y)*(p1.y-p2.y))); } */ int InitTriangles(XParms xp, Parms p, int reps) { int i, j, numPoints; int rows; int x, y; int size, iradius; double phi, phiinc, radius, delta, phi2, area, aarea; XPoint *curPoint; pgc = xp->fggc; size = p->special; phi = 0.0; delta = 2.0 * PI / ((double) NUM_POINTS); if (xp->version == VERSION1_2) { radius = ((double) size) * sqrt(3.0)/2.0; phiinc = delta/10.0; } else { /* Version 1.2's radius computation was completely bogus, and resulted in triangles with sides about 50% longer than advertised. However, this inadvertently resulted in triangles with areas just a little bit smaller than the triangle that covers size^2 pixels, which would make the area directly comparable to 10x10 rectangles and 10x10 trapezoids. So here's the new computation so -triangleN has the same area as -rectN. */ radius = ((double) size) * sqrt(sqrt(16.0/27.0)); phiinc = 1.75*PI / ((double) p->objects); } iradius = (int) (radius + 0.5); numPoints = (p->objects) * NUM_POINTS; points = (XPoint *)malloc(numPoints * sizeof(XPoint)); curPoint = points; x = iradius; y = iradius; rows = 0; aarea = 0.0; for (i = 0; i != p->objects; i++) { for (j = 0; j != NUM_POINTS; j++) { phi2 = phi + ((double) j) * delta; curPoint->x = (int) ((double)x + (radius * cos(phi2)) + 0.5); curPoint->y = (int) ((double)y + (radius * sin(phi2)) + 0.5); curPoint++; } area = Area(curPoint[-1], curPoint[-2], curPoint[-3]); aarea += area; /* printf("%6.1lf %6.1lf %6.1lf %6.1lf\n", Distance(curPoint[-1], curPoint[-2]), Distance(curPoint[-1], curPoint[-3]), Distance(curPoint[-2], curPoint[-3]), area); */ phi += phiinc; y += 2 * iradius; rows++; if (y + iradius > HEIGHT || rows == MAXROWS) { rows = 0; y = iradius; x += 2 * iradius; if (x + iradius > WIDTH) { x = iradius; } } } /* printf("Average area = %6.2lf\n", aarea/p->objects); */ SetFillStyle(xp, p); return reps; } #ifndef POLYTRIANGLE_HACK void DoTriangles(XParms xp, Parms p, int reps) { int i, j; XPoint *curPoint; for (i = 0; i != reps; i++) { curPoint = points; for (j = 0; j != p->objects; j++) { XFillPolygon(xp->d, xp->w, pgc, curPoint, NUM_POINTS, Convex, CoordModeOrigin); curPoint += NUM_POINTS; } if (pgc == xp->bggc) pgc = xp->fggc; else pgc = xp->bggc; CheckAbort (); } } #else static xReq _dummy_request = { 0, 0, 0 }; static void XPolyTriangle(register Display *dpy, Drawable d, GC gc, XPoint *points, int n_triangles, int shape, int mode) { register xFillPolyReq *req; register long nbytes; int max_triangles; int n_this_time; int *buf, *pts; int gcid; int last; max_triangles = (dpy->bufmax - dpy->buffer) / 28; LockDisplay(dpy); FlushGC(dpy, gc); dpy->request += n_triangles; pts = (int *) points; gcid = gc->gid; last = shape | (mode << 8); while (n_triangles) { if ((n_this_time = max_triangles) > n_triangles) n_this_time = n_triangles; n_triangles -= n_this_time; GetReqExtra(FillPoly, (SIZEOF(xFillPolyReq) + 12) * n_this_time - SIZEOF(xFillPolyReq), req); --dpy->request; buf = req; while (n_this_time--) { buf[0] = X_FillPoly | (7 << 16); buf[1] = d; buf[2] = gcid; buf[3] = last; buf[4] = pts[0]; buf[5] = pts[1]; buf[6] = pts[2]; buf += 7; pts += 3; } } dpy->last_req = &_dummy_request; UnlockDisplay(dpy); SyncHandle(); } void DoTriangles(XParms xp, Parms p, int reps) { int i, j; XPoint *curPoint; for (i = 0; i != reps; i++) { XPolyTriangle (xp->d, xp->w, pgc, points, p->objects, Convex, CoordModeOrigin); if (pgc == xp->bggc) pgc = xp->fggc; else pgc = xp->bggc; CheckAbort (); } } #endif void EndTriangles(XParms xp, Parms p) { free(points); }