xenocara/xserver/mi/mifillarc.c

816 lines
17 KiB
C
Raw Normal View History

2006-11-26 11:13:41 -07:00
/************************************************************
Copyright 1989, 1998 The Open Group
Permission to use, copy, modify, distribute, and sell this software and its
documentation for any purpose is hereby granted without fee, provided that
the above copyright notice appear in all copies and that both that
copyright notice and this permission notice appear in supporting
documentation.
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
OPEN GROUP BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN
AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
Except as contained in this notice, the name of The Open Group shall not be
used in advertising or otherwise to promote the sale, use or other dealings
in this Software without prior written authorization from The Open Group.
Author: Bob Scheifler, MIT X Consortium
********************************************************/
#ifdef HAVE_DIX_CONFIG_H
#include <dix-config.h>
#endif
#include <math.h>
#include <X11/X.h>
#include <X11/Xprotostr.h>
#include "regionstr.h"
#include "gcstruct.h"
#include "pixmapstr.h"
#include "mifpoly.h"
#include "mi.h"
#include "mifillarc.h"
#define QUADRANT (90 * 64)
#define HALFCIRCLE (180 * 64)
#define QUADRANT3 (270 * 64)
#ifndef M_PI
#define M_PI 3.14159265358979323846
#endif
#define Dsin(d) sin((double)d*(M_PI/11520.0))
#define Dcos(d) cos((double)d*(M_PI/11520.0))
_X_EXPORT void
miFillArcSetup(arc, info)
register xArc *arc;
register miFillArcRec *info;
{
info->y = arc->height >> 1;
info->dy = arc->height & 1;
info->yorg = arc->y + info->y;
info->dx = arc->width & 1;
info->xorg = arc->x + (arc->width >> 1) + info->dx;
info->dx = 1 - info->dx;
if (arc->width == arc->height)
{
/* (2x - 2xorg)^2 = d^2 - (2y - 2yorg)^2 */
/* even: xorg = yorg = 0 odd: xorg = .5, yorg = -.5 */
info->ym = 8;
info->xm = 8;
info->yk = info->y << 3;
if (!info->dx)
{
info->xk = 0;
info->e = -1;
}
else
{
info->y++;
info->yk += 4;
info->xk = -4;
info->e = - (info->y << 3);
}
}
else
{
/* h^2 * (2x - 2xorg)^2 = w^2 * h^2 - w^2 * (2y - 2yorg)^2 */
/* even: xorg = yorg = 0 odd: xorg = .5, yorg = -.5 */
info->ym = (arc->width * arc->width) << 3;
info->xm = (arc->height * arc->height) << 3;
info->yk = info->y * info->ym;
if (!info->dy)
info->yk -= info->ym >> 1;
if (!info->dx)
{
info->xk = 0;
info->e = - (info->xm >> 3);
}
else
{
info->y++;
info->yk += info->ym;
info->xk = -(info->xm >> 1);
info->e = info->xk - info->yk;
}
}
}
void
miFillArcDSetup(arc, info)
register xArc *arc;
register miFillArcDRec *info;
{
/* h^2 * (2x - 2xorg)^2 = w^2 * h^2 - w^2 * (2y - 2yorg)^2 */
/* even: xorg = yorg = 0 odd: xorg = .5, yorg = -.5 */
info->y = arc->height >> 1;
info->dy = arc->height & 1;
info->yorg = arc->y + info->y;
info->dx = arc->width & 1;
info->xorg = arc->x + (arc->width >> 1) + info->dx;
info->dx = 1 - info->dx;
info->ym = ((double)arc->width) * (arc->width * 8);
info->xm = ((double)arc->height) * (arc->height * 8);
info->yk = info->y * info->ym;
if (!info->dy)
info->yk -= info->ym / 2.0;
if (!info->dx)
{
info->xk = 0;
info->e = - (info->xm / 8.0);
}
else
{
info->y++;
info->yk += info->ym;
info->xk = -info->xm / 2.0;
info->e = info->xk - info->yk;
}
}
static void
miGetArcEdge(
register xArc *arc,
register miSliceEdgePtr edge,
int k,
Bool top,
Bool left )
{
register int xady, y;
y = arc->height >> 1;
if (!(arc->width & 1))
y++;
if (!top)
{
y = -y;
if (arc->height & 1)
y--;
}
xady = k + y * edge->dx;
if (xady <= 0)
edge->x = - ((-xady) / edge->dy + 1);
else
edge->x = (xady - 1) / edge->dy;
edge->e = xady - edge->x * edge->dy;
if ((top && (edge->dx < 0)) || (!top && (edge->dx > 0)))
edge->e = edge->dy - edge->e + 1;
if (left)
edge->x++;
edge->x += arc->x + (arc->width >> 1);
if (edge->dx > 0)
{
edge->deltax = 1;
edge->stepx = edge->dx / edge->dy;
edge->dx = edge->dx % edge->dy;
}
else
{
edge->deltax = -1;
edge->stepx = - ((-edge->dx) / edge->dy);
edge->dx = (-edge->dx) % edge->dy;
}
if (!top)
{
edge->deltax = -edge->deltax;
edge->stepx = -edge->stepx;
}
}
void
miEllipseAngleToSlope (angle, width, height, dxp, dyp, d_dxp, d_dyp)
int angle;
int width;
int height;
int *dxp;
int *dyp;
double *d_dxp;
double *d_dyp;
{
int dx, dy;
double d_dx, d_dy, scale;
Bool negative_dx, negative_dy;
switch (angle) {
case 0:
*dxp = -1;
*dyp = 0;
if (d_dxp) {
*d_dxp = width / 2.0;
*d_dyp = 0;
}
break;
case QUADRANT:
*dxp = 0;
*dyp = 1;
if (d_dxp) {
*d_dxp = 0;
*d_dyp = - height / 2.0;
}
break;
case HALFCIRCLE:
*dxp = 1;
*dyp = 0;
if (d_dxp) {
*d_dxp = - width / 2.0;
*d_dyp = 0;
}
break;
case QUADRANT3:
*dxp = 0;
*dyp = -1;
if (d_dxp) {
*d_dxp = 0;
*d_dyp = height / 2.0;
}
break;
default:
d_dx = Dcos(angle) * width;
d_dy = Dsin(angle) * height;
if (d_dxp) {
*d_dxp = d_dx / 2.0;
*d_dyp = - d_dy / 2.0;
}
negative_dx = FALSE;
if (d_dx < 0.0)
{
d_dx = -d_dx;
negative_dx = TRUE;
}
negative_dy = FALSE;
if (d_dy < 0.0)
{
d_dy = -d_dy;
negative_dy = TRUE;
}
scale = d_dx;
if (d_dy > d_dx)
scale = d_dy;
dx = floor ((d_dx * 32768) / scale + 0.5);
if (negative_dx)
dx = -dx;
*dxp = dx;
dy = floor ((d_dy * 32768) / scale + 0.5);
if (negative_dy)
dy = -dy;
*dyp = dy;
break;
}
}
static void
miGetPieEdge(
register xArc *arc,
register int angle,
register miSliceEdgePtr edge,
Bool top,
Bool left )
{
register int k;
int dx, dy;
miEllipseAngleToSlope (angle, arc->width, arc->height, &dx, &dy, 0, 0);
if (dy == 0)
{
edge->x = left ? -65536 : 65536;
edge->stepx = 0;
edge->e = 0;
edge->dx = -1;
return;
}
if (dx == 0)
{
edge->x = arc->x + (arc->width >> 1);
if (left && (arc->width & 1))
edge->x++;
else if (!left && !(arc->width & 1))
edge->x--;
edge->stepx = 0;
edge->e = 0;
edge->dx = -1;
return;
}
if (dy < 0) {
dx = -dx;
dy = -dy;
}
k = (arc->height & 1) ? dx : 0;
if (arc->width & 1)
k += dy;
edge->dx = dx << 1;
edge->dy = dy << 1;
miGetArcEdge(arc, edge, k, top, left);
}
_X_EXPORT void
miFillArcSliceSetup(arc, slice, pGC)
register xArc *arc;
register miArcSliceRec *slice;
GCPtr pGC;
{
register int angle1, angle2;
angle1 = arc->angle1;
if (arc->angle2 < 0)
{
angle2 = angle1;
angle1 += arc->angle2;
}
else
angle2 = angle1 + arc->angle2;
while (angle1 < 0)
angle1 += FULLCIRCLE;
while (angle1 >= FULLCIRCLE)
angle1 -= FULLCIRCLE;
while (angle2 < 0)
angle2 += FULLCIRCLE;
while (angle2 >= FULLCIRCLE)
angle2 -= FULLCIRCLE;
slice->min_top_y = 0;
slice->max_top_y = arc->height >> 1;
slice->min_bot_y = 1 - (arc->height & 1);
slice->max_bot_y = slice->max_top_y - 1;
slice->flip_top = FALSE;
slice->flip_bot = FALSE;
if (pGC->arcMode == ArcPieSlice)
{
slice->edge1_top = (angle1 < HALFCIRCLE);
slice->edge2_top = (angle2 <= HALFCIRCLE);
if ((angle2 == 0) || (angle1 == HALFCIRCLE))
{
if (angle2 ? slice->edge2_top : slice->edge1_top)
slice->min_top_y = slice->min_bot_y;
else
slice->min_top_y = arc->height;
slice->min_bot_y = 0;
}
else if ((angle1 == 0) || (angle2 == HALFCIRCLE))
{
slice->min_top_y = slice->min_bot_y;
if (angle1 ? slice->edge1_top : slice->edge2_top)
slice->min_bot_y = arc->height;
else
slice->min_bot_y = 0;
}
else if (slice->edge1_top == slice->edge2_top)
{
if (angle2 < angle1)
{
slice->flip_top = slice->edge1_top;
slice->flip_bot = !slice->edge1_top;
}
else if (slice->edge1_top)
{
slice->min_top_y = 1;
slice->min_bot_y = arc->height;
}
else
{
slice->min_bot_y = 0;
slice->min_top_y = arc->height;
}
}
miGetPieEdge(arc, angle1, &slice->edge1,
slice->edge1_top, !slice->edge1_top);
miGetPieEdge(arc, angle2, &slice->edge2,
slice->edge2_top, slice->edge2_top);
}
else
{
double w2, h2, x1, y1, x2, y2, dx, dy, scale;
int signdx, signdy, y, k;
Bool isInt1 = TRUE, isInt2 = TRUE;
w2 = (double)arc->width / 2.0;
h2 = (double)arc->height / 2.0;
if ((angle1 == 0) || (angle1 == HALFCIRCLE))
{
x1 = angle1 ? -w2 : w2;
y1 = 0.0;
}
else if ((angle1 == QUADRANT) || (angle1 == QUADRANT3))
{
x1 = 0.0;
y1 = (angle1 == QUADRANT) ? h2 : -h2;
}
else
{
isInt1 = FALSE;
x1 = Dcos(angle1) * w2;
y1 = Dsin(angle1) * h2;
}
if ((angle2 == 0) || (angle2 == HALFCIRCLE))
{
x2 = angle2 ? -w2 : w2;
y2 = 0.0;
}
else if ((angle2 == QUADRANT) || (angle2 == QUADRANT3))
{
x2 = 0.0;
y2 = (angle2 == QUADRANT) ? h2 : -h2;
}
else
{
isInt2 = FALSE;
x2 = Dcos(angle2) * w2;
y2 = Dsin(angle2) * h2;
}
dx = x2 - x1;
dy = y2 - y1;
if (arc->height & 1)
{
y1 -= 0.5;
y2 -= 0.5;
}
if (arc->width & 1)
{
x1 += 0.5;
x2 += 0.5;
}
if (dy < 0.0)
{
dy = -dy;
signdy = -1;
}
else
signdy = 1;
if (dx < 0.0)
{
dx = -dx;
signdx = -1;
}
else
signdx = 1;
if (isInt1 && isInt2)
{
slice->edge1.dx = dx * 2;
slice->edge1.dy = dy * 2;
}
else
{
scale = (dx > dy) ? dx : dy;
slice->edge1.dx = floor((dx * 32768) / scale + .5);
slice->edge1.dy = floor((dy * 32768) / scale + .5);
}
if (!slice->edge1.dy)
{
if (signdx < 0)
{
y = floor(y1 + 1.0);
if (y >= 0)
{
slice->min_top_y = y;
slice->min_bot_y = arc->height;
}
else
{
slice->max_bot_y = -y - (arc->height & 1);
}
}
else
{
y = floor(y1);
if (y >= 0)
slice->max_top_y = y;
else
{
slice->min_top_y = arc->height;
slice->min_bot_y = -y - (arc->height & 1);
}
}
slice->edge1_top = TRUE;
slice->edge1.x = 65536;
slice->edge1.stepx = 0;
slice->edge1.e = 0;
slice->edge1.dx = -1;
slice->edge2 = slice->edge1;
slice->edge2_top = FALSE;
}
else if (!slice->edge1.dx)
{
if (signdy < 0)
x1 -= 1.0;
slice->edge1.x = ceil(x1);
slice->edge1_top = signdy < 0;
slice->edge1.x += arc->x + (arc->width >> 1);
slice->edge1.stepx = 0;
slice->edge1.e = 0;
slice->edge1.dx = -1;
slice->edge2_top = !slice->edge1_top;
slice->edge2 = slice->edge1;
}
else
{
if (signdx < 0)
slice->edge1.dx = -slice->edge1.dx;
if (signdy < 0)
slice->edge1.dx = -slice->edge1.dx;
k = ceil(((x1 + x2) * slice->edge1.dy - (y1 + y2) * slice->edge1.dx) / 2.0);
slice->edge2.dx = slice->edge1.dx;
slice->edge2.dy = slice->edge1.dy;
slice->edge1_top = signdy < 0;
slice->edge2_top = !slice->edge1_top;
miGetArcEdge(arc, &slice->edge1, k,
slice->edge1_top, !slice->edge1_top);
miGetArcEdge(arc, &slice->edge2, k,
slice->edge2_top, slice->edge2_top);
}
}
}
#define ADDSPANS() \
pts->x = xorg - x; \
pts->y = yorg - y; \
*wids = slw; \
pts++; \
wids++; \
if (miFillArcLower(slw)) \
{ \
pts->x = xorg - x; \
pts->y = yorg + y + dy; \
pts++; \
*wids++ = slw; \
}
static void
miFillEllipseI(
DrawablePtr pDraw,
GCPtr pGC,
xArc *arc )
{
register int x, y, e;
int yk, xk, ym, xm, dx, dy, xorg, yorg;
int slw;
miFillArcRec info;
DDXPointPtr points;
register DDXPointPtr pts;
int *widths;
register int *wids;
points = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec) * arc->height);
if (!points)
return;
widths = (int *)ALLOCATE_LOCAL(sizeof(int) * arc->height);
if (!widths)
{
DEALLOCATE_LOCAL(points);
return;
}
miFillArcSetup(arc, &info);
MIFILLARCSETUP();
if (pGC->miTranslate)
{
xorg += pDraw->x;
yorg += pDraw->y;
}
pts = points;
wids = widths;
while (y > 0)
{
MIFILLARCSTEP(slw);
ADDSPANS();
}
(*pGC->ops->FillSpans)(pDraw, pGC, pts - points, points, widths, FALSE);
DEALLOCATE_LOCAL(widths);
DEALLOCATE_LOCAL(points);
}
static void
miFillEllipseD(
DrawablePtr pDraw,
GCPtr pGC,
xArc *arc )
{
register int x, y;
int xorg, yorg, dx, dy, slw;
double e, yk, xk, ym, xm;
miFillArcDRec info;
DDXPointPtr points;
register DDXPointPtr pts;
int *widths;
register int *wids;
points = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec) * arc->height);
if (!points)
return;
widths = (int *)ALLOCATE_LOCAL(sizeof(int) * arc->height);
if (!widths)
{
DEALLOCATE_LOCAL(points);
return;
}
miFillArcDSetup(arc, &info);
MIFILLARCSETUP();
if (pGC->miTranslate)
{
xorg += pDraw->x;
yorg += pDraw->y;
}
pts = points;
wids = widths;
while (y > 0)
{
MIFILLARCSTEP(slw);
ADDSPANS();
}
(*pGC->ops->FillSpans)(pDraw, pGC, pts - points, points, widths, FALSE);
DEALLOCATE_LOCAL(widths);
DEALLOCATE_LOCAL(points);
}
#define ADDSPAN(l,r) \
if (r >= l) \
{ \
pts->x = l; \
pts->y = ya; \
pts++; \
*wids++ = r - l + 1; \
}
#define ADDSLICESPANS(flip) \
if (!flip) \
{ \
ADDSPAN(xl, xr); \
} \
else \
{ \
xc = xorg - x; \
ADDSPAN(xc, xr); \
xc += slw - 1; \
ADDSPAN(xl, xc); \
}
static void
miFillArcSliceI(
DrawablePtr pDraw,
GCPtr pGC,
xArc *arc )
{
int yk, xk, ym, xm, dx, dy, xorg, yorg, slw;
register int x, y, e;
miFillArcRec info;
miArcSliceRec slice;
int ya, xl, xr, xc;
DDXPointPtr points;
register DDXPointPtr pts;
int *widths;
register int *wids;
miFillArcSetup(arc, &info);
miFillArcSliceSetup(arc, &slice, pGC);
MIFILLARCSETUP();
slw = arc->height;
if (slice.flip_top || slice.flip_bot)
slw += (arc->height >> 1) + 1;
points = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec) * slw);
if (!points)
return;
widths = (int *)ALLOCATE_LOCAL(sizeof(int) * slw);
if (!widths)
{
DEALLOCATE_LOCAL(points);
return;
}
if (pGC->miTranslate)
{
xorg += pDraw->x;
yorg += pDraw->y;
slice.edge1.x += pDraw->x;
slice.edge2.x += pDraw->x;
}
pts = points;
wids = widths;
while (y > 0)
{
MIFILLARCSTEP(slw);
MIARCSLICESTEP(slice.edge1);
MIARCSLICESTEP(slice.edge2);
if (miFillSliceUpper(slice))
{
ya = yorg - y;
MIARCSLICEUPPER(xl, xr, slice, slw);
ADDSLICESPANS(slice.flip_top);
}
if (miFillSliceLower(slice))
{
ya = yorg + y + dy;
MIARCSLICELOWER(xl, xr, slice, slw);
ADDSLICESPANS(slice.flip_bot);
}
}
(*pGC->ops->FillSpans)(pDraw, pGC, pts - points, points, widths, FALSE);
DEALLOCATE_LOCAL(widths);
DEALLOCATE_LOCAL(points);
}
static void
miFillArcSliceD(
DrawablePtr pDraw,
GCPtr pGC,
xArc *arc )
{
register int x, y;
int dx, dy, xorg, yorg, slw;
double e, yk, xk, ym, xm;
miFillArcDRec info;
miArcSliceRec slice;
int ya, xl, xr, xc;
DDXPointPtr points;
register DDXPointPtr pts;
int *widths;
register int *wids;
miFillArcDSetup(arc, &info);
miFillArcSliceSetup(arc, &slice, pGC);
MIFILLARCSETUP();
slw = arc->height;
if (slice.flip_top || slice.flip_bot)
slw += (arc->height >> 1) + 1;
points = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec) * slw);
if (!points)
return;
widths = (int *)ALLOCATE_LOCAL(sizeof(int) * slw);
if (!widths)
{
DEALLOCATE_LOCAL(points);
return;
}
if (pGC->miTranslate)
{
xorg += pDraw->x;
yorg += pDraw->y;
slice.edge1.x += pDraw->x;
slice.edge2.x += pDraw->x;
}
pts = points;
wids = widths;
while (y > 0)
{
MIFILLARCSTEP(slw);
MIARCSLICESTEP(slice.edge1);
MIARCSLICESTEP(slice.edge2);
if (miFillSliceUpper(slice))
{
ya = yorg - y;
MIARCSLICEUPPER(xl, xr, slice, slw);
ADDSLICESPANS(slice.flip_top);
}
if (miFillSliceLower(slice))
{
ya = yorg + y + dy;
MIARCSLICELOWER(xl, xr, slice, slw);
ADDSLICESPANS(slice.flip_bot);
}
}
(*pGC->ops->FillSpans)(pDraw, pGC, pts - points, points, widths, FALSE);
DEALLOCATE_LOCAL(widths);
DEALLOCATE_LOCAL(points);
}
/* MIPOLYFILLARC -- The public entry for the PolyFillArc request.
* Since we don't have to worry about overlapping segments, we can just
* fill each arc as it comes.
*/
_X_EXPORT void
miPolyFillArc(pDraw, pGC, narcs, parcs)
DrawablePtr pDraw;
GCPtr pGC;
int narcs;
xArc *parcs;
{
register int i;
register xArc *arc;
for(i = narcs, arc = parcs; --i >= 0; arc++)
{
if (miFillArcEmpty(arc))
continue;;
if ((arc->angle2 >= FULLCIRCLE) || (arc->angle2 <= -FULLCIRCLE))
{
if (miCanFillArc(arc))
miFillEllipseI(pDraw, pGC, arc);
else
miFillEllipseD(pDraw, pGC, arc);
}
else
{
if (miCanFillArc(arc))
miFillArcSliceI(pDraw, pGC, arc);
else
miFillArcSliceD(pDraw, pGC, arc);
}
}
}