/* * GDI drawing functions. * * Copyright 1993, 1994 Alexandre Julliard * Copyright 1997 Bertho A. Stultiens * 1999 Huw D M Davies * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include #include #include #include "windef.h" #include "winbase.h" #include "wingdi.h" #include "winerror.h" #include "ntgdi_private.h" #include "wine/debug.h" WINE_DEFAULT_DEBUG_CHANNEL(gdi); /*********************************************************************** * null driver fallback implementations */ BOOL CDECL nulldrv_AngleArc( PHYSDEV dev, INT x, INT y, DWORD radius, FLOAT start, FLOAT sweep ) { DC *dc = get_physdev_dc( dev ); INT x1 = GDI_ROUND( x + cos( start * M_PI / 180 ) * radius ); INT y1 = GDI_ROUND( y - sin( start * M_PI / 180 ) * radius ); INT x2 = GDI_ROUND( x + cos( (start + sweep) * M_PI / 180) * radius ); INT y2 = GDI_ROUND( y - sin( (start + sweep) * M_PI / 180) * radius ); INT arcdir = dc->attr->arc_direction; BOOL ret; dc->attr->arc_direction = sweep >= 0 ? AD_COUNTERCLOCKWISE : AD_CLOCKWISE; ret = NtGdiArcInternal( NtGdiArcTo, dev->hdc, x - radius, y - radius, x + radius, y + radius, x1, y1, x2, y2 ); dc->attr->arc_direction = arcdir; return ret; } BOOL CDECL nulldrv_ArcTo( PHYSDEV dev, INT left, INT top, INT right, INT bottom, INT xstart, INT ystart, INT xend, INT yend ) { INT width = abs( right - left ); INT height = abs( bottom - top ); double xradius = width / 2.0; double yradius = height / 2.0; double xcenter = right > left ? left + xradius : right + xradius; double ycenter = bottom > top ? top + yradius : bottom + yradius; double angle; if (!height || !width) return FALSE; /* draw a line from the current position to the starting point of the arc, then draw the arc */ angle = atan2( (ystart - ycenter) / height, (xstart - xcenter) / width ); NtGdiLineTo( dev->hdc, GDI_ROUND( xcenter + cos(angle) * xradius ), GDI_ROUND( ycenter + sin(angle) * yradius )); return NtGdiArcInternal( NtGdiArc, dev->hdc, left, top, right, bottom, xstart, ystart, xend, yend ); } BOOL CDECL nulldrv_FillRgn( PHYSDEV dev, HRGN rgn, HBRUSH brush ) { BOOL ret = FALSE; HBRUSH prev; if ((prev = NtGdiSelectBrush( dev->hdc, brush ))) { PHYSDEV physdev = GET_DC_PHYSDEV( get_physdev_dc( dev ), pPaintRgn ); ret = physdev->funcs->pPaintRgn( physdev, rgn ); NtGdiSelectBrush( dev->hdc, prev ); } return ret; } BOOL CDECL nulldrv_FrameRgn( PHYSDEV dev, HRGN rgn, HBRUSH brush, INT width, INT height ) { BOOL ret = FALSE; HRGN tmp = NtGdiCreateRectRgn( 0, 0, 0, 0 ); if (tmp) { if (REGION_FrameRgn( tmp, rgn, width, height )) ret = NtGdiFillRgn( dev->hdc, tmp, brush ); NtGdiDeleteObjectApp( tmp ); } return ret; } BOOL CDECL nulldrv_InvertRgn( PHYSDEV dev, HRGN rgn ) { DC *dc = get_physdev_dc( dev ); INT prev_rop = dc->attr->rop_mode; BOOL ret; dc->attr->rop_mode = R2_NOT; ret = NtGdiFillRgn( dev->hdc, rgn, get_stock_object(BLACK_BRUSH) ); dc->attr->rop_mode = prev_rop; return ret; } static BOOL polyline( HDC hdc, const POINT *points, UINT count ) { return NtGdiPolyPolyDraw( hdc, points, &count, 1, NtGdiPolyPolyline ); } BOOL CDECL nulldrv_PolyBezier( PHYSDEV dev, const POINT *points, DWORD count ) { BOOL ret = FALSE; POINT *pts; INT n; if ((pts = GDI_Bezier( points, count, &n ))) { ret = polyline( dev->hdc, pts, n ); HeapFree( GetProcessHeap(), 0, pts ); } return ret; } BOOL CDECL nulldrv_PolyBezierTo( PHYSDEV dev, const POINT *points, DWORD count ) { DC *dc = get_nulldrv_dc( dev ); BOOL ret = FALSE; POINT *pts = HeapAlloc( GetProcessHeap(), 0, sizeof(POINT) * (count + 1) ); if (pts) { pts[0] = dc->attr->cur_pos; memcpy( pts + 1, points, sizeof(POINT) * count ); count++; ret = NtGdiPolyPolyDraw( dev->hdc, pts, &count, 1, NtGdiPolyBezier ); HeapFree( GetProcessHeap(), 0, pts ); } return ret; } BOOL CDECL nulldrv_PolyDraw( PHYSDEV dev, const POINT *points, const BYTE *types, DWORD count ) { DC *dc = get_nulldrv_dc( dev ); POINT *line_pts = NULL, *bzr_pts = NULL, bzr[4]; DWORD i; INT num_pts, num_bzr_pts, space, size; /* check for valid point types */ for (i = 0; i < count; i++) { switch (types[i]) { case PT_MOVETO: case PT_LINETO | PT_CLOSEFIGURE: case PT_LINETO: break; case PT_BEZIERTO: if (i + 2 >= count) return FALSE; if (types[i + 1] != PT_BEZIERTO) return FALSE; if ((types[i + 2] & ~PT_CLOSEFIGURE) != PT_BEZIERTO) return FALSE; i += 2; break; default: return FALSE; } } space = count + 300; line_pts = HeapAlloc( GetProcessHeap(), 0, space * sizeof(POINT) ); num_pts = 1; line_pts[0] = dc->attr->cur_pos; for (i = 0; i < count; i++) { switch (types[i]) { case PT_MOVETO: if (num_pts >= 2) polyline( dev->hdc, line_pts, num_pts ); num_pts = 0; line_pts[num_pts++] = points[i]; break; case PT_LINETO: case (PT_LINETO | PT_CLOSEFIGURE): line_pts[num_pts++] = points[i]; break; case PT_BEZIERTO: bzr[0].x = line_pts[num_pts - 1].x; bzr[0].y = line_pts[num_pts - 1].y; memcpy( &bzr[1], &points[i], 3 * sizeof(POINT) ); if ((bzr_pts = GDI_Bezier( bzr, 4, &num_bzr_pts ))) { size = num_pts + (count - i) + num_bzr_pts; if (space < size) { space = size * 2; line_pts = HeapReAlloc( GetProcessHeap(), 0, line_pts, space * sizeof(POINT) ); } memcpy( &line_pts[num_pts], &bzr_pts[1], (num_bzr_pts - 1) * sizeof(POINT) ); num_pts += num_bzr_pts - 1; HeapFree( GetProcessHeap(), 0, bzr_pts ); } i += 2; break; } if (types[i] & PT_CLOSEFIGURE) line_pts[num_pts++] = line_pts[0]; } if (num_pts >= 2) polyline( dev->hdc, line_pts, num_pts ); HeapFree( GetProcessHeap(), 0, line_pts ); return TRUE; } BOOL CDECL nulldrv_PolylineTo( PHYSDEV dev, const POINT *points, INT count ) { DC *dc = get_nulldrv_dc( dev ); BOOL ret = FALSE; POINT *pts; if (!count) return FALSE; if ((pts = HeapAlloc( GetProcessHeap(), 0, sizeof(POINT) * (count + 1) ))) { pts[0] = dc->attr->cur_pos; memcpy( pts + 1, points, sizeof(POINT) * count ); ret = polyline( dev->hdc, pts, count + 1 ); HeapFree( GetProcessHeap(), 0, pts ); } return ret; } /*********************************************************************** * NtGdiLineTo (win32u.@) */ BOOL WINAPI NtGdiLineTo( HDC hdc, INT x, INT y ) { DC * dc = get_dc_ptr( hdc ); PHYSDEV physdev; BOOL ret; if(!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pLineTo ); ret = physdev->funcs->pLineTo( physdev, x, y ); if(ret) { dc->attr->cur_pos.x = x; dc->attr->cur_pos.y = y; } release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiMoveTo (win32u.@) */ BOOL WINAPI NtGdiMoveTo( HDC hdc, INT x, INT y, POINT *pt ) { BOOL ret; PHYSDEV physdev; DC * dc = get_dc_ptr( hdc ); if(!dc) return FALSE; if(pt) *pt = dc->attr->cur_pos; dc->attr->cur_pos.x = x; dc->attr->cur_pos.y = y; physdev = GET_DC_PHYSDEV( dc, pMoveTo ); ret = physdev->funcs->pMoveTo( physdev, x, y ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiArcInternal (win32u.@) */ BOOL WINAPI NtGdiArcInternal( UINT type, HDC hdc, INT left, INT top, INT right, INT bottom, INT xstart, INT ystart, INT xend, INT yend ) { PHYSDEV physdev; BOOL ret; DC *dc; if (!(dc = get_dc_ptr( hdc ))) return FALSE; update_dc( dc ); switch (type) { case NtGdiArc: physdev = GET_DC_PHYSDEV( dc, pArc ); ret = physdev->funcs->pArc( physdev, left, top, right, bottom, xstart, ystart, xend, yend ); break; case NtGdiArcTo: { double width = abs( right - left ); double height = abs( bottom - top ); double xradius = width / 2; double yradius = height / 2; double xcenter = right > left ? left + xradius : right + xradius; double ycenter = bottom > top ? top + yradius : bottom + yradius; physdev = GET_DC_PHYSDEV( dc, pArcTo ); ret = physdev->funcs->pArcTo( physdev, left, top, right, bottom, xstart, ystart, xend, yend ); if (ret) { double angle = atan2(((yend - ycenter) / height), ((xend - xcenter) / width)); dc->attr->cur_pos.x = GDI_ROUND( xcenter + (cos( angle ) * xradius) ); dc->attr->cur_pos.y = GDI_ROUND( ycenter + (sin( angle ) * yradius) ); } break; } case NtGdiChord: physdev = GET_DC_PHYSDEV( dc, pChord ); ret = physdev->funcs->pChord( physdev, left, top, right, bottom, xstart, ystart, xend, yend ); break; case NtGdiPie: physdev = GET_DC_PHYSDEV( dc, pPie ); ret = physdev->funcs->pPie( physdev, left, top, right, bottom, xstart, ystart, xend, yend ); break; default: WARN( "invalid arc type %u\n", type ); ret = FALSE; } release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiEllipse (win32u.@) */ BOOL WINAPI NtGdiEllipse( HDC hdc, INT left, INT top, INT right, INT bottom ) { BOOL ret; PHYSDEV physdev; DC * dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pEllipse ); ret = physdev->funcs->pEllipse( physdev, left, top, right, bottom ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiRectangle (win32u.@) */ BOOL WINAPI NtGdiRectangle( HDC hdc, INT left, INT top, INT right, INT bottom ) { PHYSDEV physdev; BOOL ret; DC * dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pRectangle ); ret = physdev->funcs->pRectangle( physdev, left, top, right, bottom ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiRoundRect (win32u.@) */ BOOL WINAPI NtGdiRoundRect( HDC hdc, INT left, INT top, INT right, INT bottom, INT ell_width, INT ell_height ) { PHYSDEV physdev; BOOL ret; DC *dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pRoundRect ); ret = physdev->funcs->pRoundRect( physdev, left, top, right, bottom, ell_width, ell_height ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiSetPixel (win32u.@) */ COLORREF WINAPI NtGdiSetPixel( HDC hdc, INT x, INT y, COLORREF color ) { PHYSDEV physdev; COLORREF ret; DC * dc = get_dc_ptr( hdc ); if (!dc) return CLR_INVALID; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pSetPixel ); ret = physdev->funcs->pSetPixel( physdev, x, y, color ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiGetPixel (win32u.@) */ COLORREF WINAPI NtGdiGetPixel( HDC hdc, INT x, INT y ) { PHYSDEV physdev; COLORREF ret; DC * dc = get_dc_ptr( hdc ); if (!dc) return CLR_INVALID; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pGetPixel ); ret = physdev->funcs->pGetPixel( physdev, x, y ); release_dc_ptr( dc ); return ret; } /****************************************************************************** * NtGdiSetPixelFormat (win32u.@) * * Probably not the correct semantics, it's supposed to be an internal backend for SetPixelFormat. */ BOOL WINAPI NtGdiSetPixelFormat( HDC hdc, INT format ) { DC *dc; BOOL ret = TRUE; if (!(dc = get_dc_ptr( hdc ))) return FALSE; if (!dc->pixel_format) dc->pixel_format = format; else ret = (dc->pixel_format == format); release_dc_ptr( dc ); return ret; } /****************************************************************************** * NtGdiDescribePixelFormat (win32u.@) */ INT WINAPI NtGdiDescribePixelFormat( HDC hdc, INT format, UINT size, PIXELFORMATDESCRIPTOR *descr ) { FIXME( "(%p,%d,%d,%p): stub\n", hdc, format, size, descr ); return 0; } /****************************************************************************** * NtGdiSwapBuffers (win32u.@) */ BOOL WINAPI NtGdiSwapBuffers( HDC hdc ) { FIXME( "(%p): stub\n", hdc ); return FALSE; } /*********************************************************************** * NtGdiFillRgn (win32u.@) */ BOOL WINAPI NtGdiFillRgn( HDC hdc, HRGN hrgn, HBRUSH hbrush ) { PHYSDEV physdev; BOOL retval; DC * dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pFillRgn ); retval = physdev->funcs->pFillRgn( physdev, hrgn, hbrush ); release_dc_ptr( dc ); return retval; } /*********************************************************************** * NtGdiFrameRgn (win32u.@) */ BOOL WINAPI NtGdiFrameRgn( HDC hdc, HRGN hrgn, HBRUSH hbrush, INT width, INT height ) { PHYSDEV physdev; BOOL ret; DC *dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pFrameRgn ); ret = physdev->funcs->pFrameRgn( physdev, hrgn, hbrush, width, height ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiInvertRgn (win32u.@) */ BOOL WINAPI NtGdiInvertRgn( HDC hdc, HRGN hrgn ) { PHYSDEV physdev; BOOL ret; DC *dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pInvertRgn ); ret = physdev->funcs->pInvertRgn( physdev, hrgn ); release_dc_ptr( dc ); return ret; } /********************************************************************** * NtGdiPolyPolyDraw (win32u.@) */ ULONG WINAPI NtGdiPolyPolyDraw( HDC hdc, const POINT *points, const UINT *counts, UINT count, UINT function ) { PHYSDEV physdev; ULONG ret; DC *dc; if (function == NtGdiPolyPolygonRgn) return HandleToULong( create_polypolygon_region( points, (const INT *)counts, count, HandleToULong(hdc), NULL )); if (!(dc = get_dc_ptr( hdc ))) return FALSE; update_dc( dc ); switch (function) { case NtGdiPolyPolygon: physdev = GET_DC_PHYSDEV( dc, pPolyPolygon ); ret = physdev->funcs->pPolyPolygon( physdev, points, (const INT *)counts, count ); break; case NtGdiPolyPolyline: physdev = GET_DC_PHYSDEV( dc, pPolyPolyline ); ret = physdev->funcs->pPolyPolyline( physdev, points, counts, count ); break; case NtGdiPolyBezier: /* *counts must be 3 * n + 1 (where n >= 1) */ if (count == 1 && *counts != 1 && *counts % 3 == 1) { physdev = GET_DC_PHYSDEV( dc, pPolyBezier ); ret = physdev->funcs->pPolyBezier( physdev, points, *counts ); if (ret) dc->attr->cur_pos = points[*counts - 1]; } else ret = FALSE; break; case NtGdiPolyBezierTo: if (count == 1 && *counts && *counts % 3 == 0) { physdev = GET_DC_PHYSDEV( dc, pPolyBezierTo ); ret = physdev->funcs->pPolyBezierTo( physdev, points, *counts ); if (ret) dc->attr->cur_pos = points[*counts - 1]; } else ret = FALSE; break; case NtGdiPolylineTo: if (count == 1) { physdev = GET_DC_PHYSDEV( dc, pPolylineTo ); ret = physdev->funcs->pPolylineTo( physdev, points, *counts ); if (ret && *counts) dc->attr->cur_pos = points[*counts - 1]; } else ret = FALSE; break; default: WARN( "invalid function %u\n", function ); ret = FALSE; break; } release_dc_ptr( dc ); return ret; } /********************************************************************** * NtGdiExtFloodFill (win32u.@) */ BOOL WINAPI NtGdiExtFloodFill( HDC hdc, INT x, INT y, COLORREF color, UINT fill_type ) { PHYSDEV physdev; BOOL ret; DC * dc = get_dc_ptr( hdc ); if (!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pExtFloodFill ); ret = physdev->funcs->pExtFloodFill( physdev, x, y, color, fill_type ); release_dc_ptr( dc ); return ret; } /*********************************************************************** * NtGdiAngleArc (win32u.@) */ BOOL WINAPI NtGdiAngleArc( HDC hdc, INT x, INT y, DWORD dwRadius, FLOAT eStartAngle, FLOAT eSweepAngle ) { PHYSDEV physdev; BOOL result; DC *dc; if( (signed int)dwRadius < 0 ) return FALSE; dc = get_dc_ptr( hdc ); if(!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pAngleArc ); result = physdev->funcs->pAngleArc( physdev, x, y, dwRadius, eStartAngle, eSweepAngle ); if (result) { dc->attr->cur_pos.x = GDI_ROUND( x + cos( (eStartAngle + eSweepAngle) * M_PI / 180 ) * dwRadius ); dc->attr->cur_pos.y = GDI_ROUND( y - sin( (eStartAngle + eSweepAngle) * M_PI / 180 ) * dwRadius ); } release_dc_ptr( dc ); return result; } /*********************************************************************** * NtGdiPolyDraw (win32u.@) */ BOOL WINAPI NtGdiPolyDraw( HDC hdc, const POINT *points, const BYTE *types, DWORD count ) { DC *dc = get_dc_ptr( hdc ); PHYSDEV physdev; BOOL result; if(!dc) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pPolyDraw ); result = physdev->funcs->pPolyDraw( physdev, points, types, count ); if (result && count) dc->attr->cur_pos = points[count - 1]; release_dc_ptr( dc ); return result; } /****************************************************************** * * *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) /* 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 = HeapReAlloc( GetProcessHeap(), 0, *PtsOut, *dwOut * sizeof(POINT) ); } 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) { ERR("Invalid no. of points %d\n", count); return NULL; } *nPtsOut = 0; out = HeapAlloc( GetProcessHeap(), 0, dwOut * sizeof(POINT)); 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 ); } TRACE("Produced %d points\n", *nPtsOut); return out; } /****************************************************************************** * NtGdiGdiGradientFill (win32u.@) */ BOOL WINAPI NtGdiGradientFill( HDC hdc, TRIVERTEX *vert_array, ULONG nvert, void *grad_array, ULONG ngrad, ULONG mode ) { DC *dc; PHYSDEV physdev; BOOL ret; ULONG i; if (!vert_array || !nvert || !grad_array || !ngrad || mode > GRADIENT_FILL_TRIANGLE) { SetLastError( ERROR_INVALID_PARAMETER ); return FALSE; } for (i = 0; i < ngrad * (mode == GRADIENT_FILL_TRIANGLE ? 3 : 2); i++) if (((ULONG *)grad_array)[i] >= nvert) return FALSE; if (!(dc = get_dc_ptr( hdc ))) return FALSE; update_dc( dc ); physdev = GET_DC_PHYSDEV( dc, pGradientFill ); ret = physdev->funcs->pGradientFill( physdev, vert_array, nvert, grad_array, ngrad, mode ); release_dc_ptr( dc ); return ret; } /****************************************************************************** * NtGdiDrawStream (win32u.@) */ BOOL WINAPI NtGdiDrawStream( HDC hdc, ULONG in, void *pvin ) { FIXME("stub: %p, %d, %p\n", hdc, in, pvin); return FALSE; }