reactos/win32ss/gdi/ntgdi/bezier.c

215 lines
6.9 KiB
C

/*
* COPYRIGHT: GNU LGPL
* PURPOSE: Bezier functions
*/
#include <win32k.h>
#define NDEBUG
#include <debug.h>
/* Based on Wine Staging 1.7.37 - dlls/gdi32/painting.c */
/******************************************************************
*
* *Very* simple bezier drawing code,
*
* It uses a recursive algorithm to divide the curve in a series
* of straight line segments. Not ideal but sufficient for me.
* If you are in need for something better look for some incremental
* algorithm.
*
* 7 July 1998 Rein Klazes
*/
/*
* some macro definitions for bezier drawing
*
* to avoid truncation errors the coordinates are
* shifted upwards. When used in drawing they are
* shifted down again, including correct rounding
* and avoiding floating point arithmetic
* 4 bits should allow 27 bits coordinates which I saw
* somewhere in the win32 doc's
*
*/
#define BEZIERSHIFTBITS 4
#define BEZIERSHIFTUP(x) ((x)<<BEZIERSHIFTBITS)
#define BEZIERPIXEL BEZIERSHIFTUP(1)
#define BEZIERSHIFTDOWN(x) (((x)+(1<<(BEZIERSHIFTBITS-1)))>>BEZIERSHIFTBITS)
/* maximum depth of recursion */
#define BEZIERMAXDEPTH 8
/* size of array to store points on */
/* enough for one curve */
#define BEZIER_INITBUFSIZE (150)
/* calculate Bezier average, in this case the middle
* correctly rounded...
* */
#define BEZIERMIDDLE(Mid, P1, P2) \
(Mid).x=((P1).x+(P2).x + 1)/2;\
(Mid).y=((P1).y+(P2).y + 1)/2;
/**********************************************************
* BezierCheck helper function to check
* that recursion can be terminated
* Points[0] and Points[3] are begin and endpoint
* Points[1] and Points[2] are control points
* level is the recursion depth
* returns true if the recursion can be terminated
*/
static BOOL BezierCheck( int level, POINT *Points)
{
INT dx, dy;
dx=Points[3].x-Points[0].x;
dy=Points[3].y-Points[0].y;
if(abs(dy)<=abs(dx)){/* shallow line */
/* check that control points are between begin and end */
if(Points[1].x < Points[0].x){
if(Points[1].x < Points[3].x)
return FALSE;
}else
if(Points[1].x > Points[3].x)
return FALSE;
if(Points[2].x < Points[0].x){
if(Points[2].x < Points[3].x)
return FALSE;
}else
if(Points[2].x > Points[3].x)
return FALSE;
dx=BEZIERSHIFTDOWN(dx);
if(!dx) return TRUE;
if(abs(Points[1].y-Points[0].y-(dy/dx)*
BEZIERSHIFTDOWN(Points[1].x-Points[0].x)) > BEZIERPIXEL ||
abs(Points[2].y-Points[0].y-(dy/dx)*
BEZIERSHIFTDOWN(Points[2].x-Points[0].x)) > BEZIERPIXEL )
return FALSE;
else
return TRUE;
}else{ /* steep line */
/* check that control points are between begin and end */
if(Points[1].y < Points[0].y){
if(Points[1].y < Points[3].y)
return FALSE;
}else
if(Points[1].y > Points[3].y)
return FALSE;
if(Points[2].y < Points[0].y){
if(Points[2].y < Points[3].y)
return FALSE;
}else
if(Points[2].y > Points[3].y)
return FALSE;
dy=BEZIERSHIFTDOWN(dy);
if(!dy) return TRUE;
if(abs(Points[1].x-Points[0].x-(dx/dy)*
BEZIERSHIFTDOWN(Points[1].y-Points[0].y)) > BEZIERPIXEL ||
abs(Points[2].x-Points[0].x-(dx/dy)*
BEZIERSHIFTDOWN(Points[2].y-Points[0].y)) > BEZIERPIXEL )
return FALSE;
else
return TRUE;
}
}
/* Helper for GDI_Bezier.
* Just handles one Bezier, so Points should point to four POINTs
*/
static void GDI_InternalBezier( POINT *Points, POINT **PtsOut, INT *dwOut,
INT *nPtsOut, INT level )
{
if(*nPtsOut == *dwOut) {
*dwOut *= 2;
*PtsOut = ExAllocatePoolWithTag(PagedPool, *dwOut * sizeof(POINT), TAG_BEZIER);
if (*PtsOut == NULL)
{
/// \todo FIXME!
NT_ASSERT(FALSE);
return;
}
}
if(!level || BezierCheck(level, Points)) {
if(*nPtsOut == 0) {
(*PtsOut)[0].x = BEZIERSHIFTDOWN(Points[0].x);
(*PtsOut)[0].y = BEZIERSHIFTDOWN(Points[0].y);
*nPtsOut = 1;
}
(*PtsOut)[*nPtsOut].x = BEZIERSHIFTDOWN(Points[3].x);
(*PtsOut)[*nPtsOut].y = BEZIERSHIFTDOWN(Points[3].y);
(*nPtsOut) ++;
} else {
POINT Points2[4]; /* for the second recursive call */
Points2[3]=Points[3];
BEZIERMIDDLE(Points2[2], Points[2], Points[3]);
BEZIERMIDDLE(Points2[0], Points[1], Points[2]);
BEZIERMIDDLE(Points2[1],Points2[0],Points2[2]);
BEZIERMIDDLE(Points[1], Points[0], Points[1]);
BEZIERMIDDLE(Points[2], Points[1], Points2[0]);
BEZIERMIDDLE(Points[3], Points[2], Points2[1]);
Points2[0]=Points[3];
/* do the two halves */
GDI_InternalBezier(Points, PtsOut, dwOut, nPtsOut, level-1);
GDI_InternalBezier(Points2, PtsOut, dwOut, nPtsOut, level-1);
}
}
/***********************************************************************
* GDI_Bezier [INTERNAL]
* Calculate line segments that approximate -what microsoft calls- a bezier
* curve.
* The routine recursively divides the curve in two parts until a straight
* line can be drawn
*
* PARAMS
*
* Points [I] Ptr to count POINTs which are the end and control points
* of the set of Bezier curves to flatten.
* count [I] Number of Points. Must be 3n+1.
* nPtsOut [O] Will contain no of points that have been produced (i.e. no. of
* lines+1).
*
* RETURNS
*
* Ptr to an array of POINTs that contain the lines that approximate the
* Beziers. The array is allocated on the process heap and it is the caller's
* responsibility to HeapFree it. [this is not a particularly nice interface
* but since we can't know in advance how many points we will generate, the
* alternative would be to call the function twice, once to determine the size
* and a second time to do the work - I decided this was too much of a pain].
*/
POINT *GDI_Bezier( const POINT *Points, INT count, INT *nPtsOut )
{
POINT *out;
INT Bezier, dwOut = BEZIER_INITBUFSIZE, i;
if (count == 1 || (count - 1) % 3 != 0) {
DPRINT1("Invalid no. of points %d\n", count);
return NULL;
}
*nPtsOut = 0;
out = ExAllocatePoolWithTag(PagedPool, dwOut * sizeof(POINT), TAG_BEZIER);
if (!out) return NULL;
for(Bezier = 0; Bezier < (count-1)/3; Bezier++) {
POINT ptBuf[4];
memcpy(ptBuf, Points + Bezier * 3, sizeof(POINT) * 4);
for(i = 0; i < 4; i++) {
ptBuf[i].x = BEZIERSHIFTUP(ptBuf[i].x);
ptBuf[i].y = BEZIERSHIFTUP(ptBuf[i].y);
}
GDI_InternalBezier( ptBuf, &out, &dwOut, nPtsOut, BEZIERMAXDEPTH );
}
DPRINT("Produced %d points\n", *nPtsOut);
return out;
}
/* EOF */