- Sync gdiplus with wine head

[reactos.git] / reactos / dll / win32 / gdiplus / gdiplus.c

/*
 * Copyright (C) 2007 Google (Evan Stade)
 *
 * 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 <stdarg.h>
#include <math.h>

#include "windef.h"
#include "winbase.h"
#include "winerror.h"
#include "wine/debug.h"
#include "wingdi.h"

#include "objbase.h"

#include "winreg.h"
#include "shlwapi.h"

#include "gdiplus.h"
#include "gdiplus_private.h"

WINE_DEFAULT_DEBUG_CHANNEL(gdiplus);

static Status WINAPI NotificationHook(ULONG_PTR *token)
{
    TRACE("%p\n", token);
    if(!token)
        return InvalidParameter;

    return Ok;
}

static void WINAPI NotificationUnhook(ULONG_PTR token)
{
    TRACE("%ld\n", token);
}

/*****************************************************
 *      DllMain
 */
BOOL WINAPI DllMain(HINSTANCE hinst, DWORD reason, LPVOID reserved)
{
    TRACE("(%p, %d, %p)\n", hinst, reason, reserved);

    switch(reason)
    {
    case DLL_WINE_PREATTACH:
        return FALSE;  /* prefer native version */

    case DLL_PROCESS_ATTACH:
        DisableThreadLibraryCalls( hinst );
        break;
    }
    return TRUE;
}

/*****************************************************
 *      GdiplusStartup [GDIPLUS.@]
 */
Status WINAPI GdiplusStartup(ULONG_PTR *token, const struct GdiplusStartupInput *input,
                             struct GdiplusStartupOutput *output)
{
    if(!token || !input)
        return InvalidParameter;

    TRACE("%p %p %p\n", token, input, output);
    TRACE("GdiplusStartupInput %d %p %d %d\n", input->GdiplusVersion,
          input->DebugEventCallback, input->SuppressBackgroundThread,
          input->SuppressExternalCodecs);

    if(input->GdiplusVersion != 1)
        return UnsupportedGdiplusVersion;

    if(input->SuppressBackgroundThread){
        if(!output)
            return InvalidParameter;

        output->NotificationHook = NotificationHook;
        output->NotificationUnhook = NotificationUnhook;
    }

    /* FIXME: DebugEventCallback ignored */

    return Ok;
}

/*****************************************************
 *      GdiplusShutdown [GDIPLUS.@]
 */
void WINAPI GdiplusShutdown(ULONG_PTR token)
{
    /* FIXME: no object tracking */
}

/*****************************************************
 *      GdipAlloc [GDIPLUS.@]
 */
void* WINGDIPAPI GdipAlloc(SIZE_T size)
{
    return HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, size);
}

/*****************************************************
 *      GdipFree [GDIPLUS.@]
 */
void WINGDIPAPI GdipFree(void* ptr)
{
    HeapFree(GetProcessHeap(), 0, ptr);
}

/* Calculates the bezier points needed to fill in the arc portion starting at
 * angle start and ending at end.  These two angles should be no more than 90
 * degrees from each other.  x1, y1, x2, y2 describes the bounding box (upper
 * left and width and height).  Angles must be in radians. write_first indicates
 * that the first bezier point should be written out (usually this is false).
 * pt is the array of GpPointFs that gets written to.
 **/
static void add_arc_part(GpPointF * pt, REAL x1, REAL y1, REAL x2, REAL y2,
    REAL start, REAL end, BOOL write_first)
{
    REAL center_x, center_y, rad_x, rad_y, cos_start, cos_end,
        sin_start, sin_end, a, half;
    INT i;

    rad_x = x2 / 2.0;
    rad_y = y2 / 2.0;
    center_x = x1 + rad_x;
    center_y = y1 + rad_y;

    cos_start = cos(start);
    cos_end = cos(end);
    sin_start = sin(start);
    sin_end = sin(end);

    half = (end - start) / 2.0;
    a = 4.0 / 3.0 * (1 - cos(half)) / sin(half);

    if(write_first){
        pt[0].X = cos_start;
        pt[0].Y = sin_start;
    }
    pt[1].X = cos_start - a * sin_start;
    pt[1].Y = sin_start + a * cos_start;

    pt[3].X = cos_end;
    pt[3].Y = sin_end;
    pt[2].X = cos_end + a * sin_end;
    pt[2].Y = sin_end - a * cos_end;

    /* expand the points back from the unit circle to the ellipse */
    for(i = (write_first ? 0 : 1); i < 4; i ++){
        pt[i].X = pt[i].X * rad_x + center_x;
        pt[i].Y = pt[i].Y * rad_y + center_y;
    }
}

/* We plot the curve as if it is on a circle then stretch the points.  This
 * adjusts the angles so that when we stretch the points they will end in the
 * right place. This is only complicated because atan and atan2 do not behave
 * conveniently. */
static void unstretch_angle(REAL * angle, REAL rad_x, REAL rad_y)
{
    REAL stretched;
    INT revs_off;

    *angle = deg2rad(*angle);

    if(fabs(cos(*angle)) < 0.00001 || fabs(sin(*angle)) < 0.00001)
        return;

    stretched = gdiplus_atan2(sin(*angle) / fabs(rad_y), cos(*angle) / fabs(rad_x));
    revs_off = roundr(*angle / (2.0 * M_PI)) - roundr(stretched / (2.0 * M_PI));
    stretched += ((REAL)revs_off) * M_PI * 2.0;
    *angle = stretched;
}

/* Stores the bezier points that correspond to the arc in points.  If points is
 * null, just return the number of points needed to represent the arc. */
INT arc2polybezier(GpPointF * points, REAL x1, REAL y1, REAL x2, REAL y2,
    REAL startAngle, REAL sweepAngle)
{
    INT i, count;
    REAL end_angle, start_angle, endAngle;

    endAngle = startAngle + sweepAngle;
    unstretch_angle(&startAngle, x2 / 2.0, y2 / 2.0);
    unstretch_angle(&endAngle, x2 / 2.0, y2 / 2.0);

    count = ceil(fabs(endAngle - startAngle) / M_PI_2) * 3 + 1;
    /* don't make more than a full circle */
    count = min(MAX_ARC_PTS, count);

    if(count == 1)
        return 0;
    if(!points)
        return count;

    /* start_angle and end_angle are the iterative variables */
    start_angle = startAngle;

    for(i = 0; i < count - 1; i += 3){
        /* check if we've overshot the end angle */
        if( sweepAngle > 0.0 )
            end_angle = min(start_angle + M_PI_2, endAngle);
        else
            end_angle = max(start_angle - M_PI_2, endAngle);

        add_arc_part(&points[i], x1, y1, x2, y2, start_angle, end_angle, i == 0);

        start_angle += M_PI_2 * (sweepAngle < 0.0 ? -1.0 : 1.0);
    }

    return count;
}

COLORREF ARGB2COLORREF(ARGB color)
{
    /*
    Packing of these color structures:
    COLORREF:   00bbggrr
    ARGB:       aarrggbb
    FIXME:doesn't handle alpha channel
    */
    return ((color & 0x0000ff) << 16) +
           (color & 0x00ff00) +
           ((color & 0xff0000) >> 16);
}

/* Like atan2, but puts angle in correct quadrant if dx is 0. */
REAL gdiplus_atan2(REAL dy, REAL dx)
{
    if((dx == 0.0) && (dy != 0.0))
        return dy > 0.0 ? M_PI_2 : -M_PI_2;

    return atan2(dy, dx);
}

GpStatus hresult_to_status(HRESULT res)
{
    switch(res){
        case S_OK:
            return Ok;
        case E_OUTOFMEMORY:
            return OutOfMemory;
        case E_INVALIDARG:
            return InvalidParameter;
        default:
            return GenericError;
    }
}

/* converts a given unit to its value in pixels */
REAL convert_unit(HDC hdc, GpUnit unit)
{
    switch(unit)
    {
        case UnitInch:
            return (REAL) GetDeviceCaps(hdc, LOGPIXELSX);
        case UnitPoint:
            return ((REAL)GetDeviceCaps(hdc, LOGPIXELSX)) / 72.0;
        case UnitDocument:
            return ((REAL)GetDeviceCaps(hdc, LOGPIXELSX)) / 300.0;
        case UnitMillimeter:
            return ((REAL)GetDeviceCaps(hdc, LOGPIXELSX)) / 25.4;
        case UnitWorld:
            ERR("cannot convert UnitWorld\n");
            return 0.0;
        case UnitPixel:
        case UnitDisplay:
        default:
            return 1.0;
    }
}

/* Calculates Bezier points from cardinal spline points. */
void calc_curve_bezier(CONST GpPointF *pts, REAL tension, REAL *x1,
    REAL *y1, REAL *x2, REAL *y2)
{
    REAL xdiff, ydiff;

    /* calculate tangent */
    xdiff = pts[2].X - pts[0].X;
    ydiff = pts[2].Y - pts[0].Y;

    /* apply tangent to get control points */
    *x1 = pts[1].X - tension * xdiff;
    *y1 = pts[1].Y - tension * ydiff;
    *x2 = pts[1].X + tension * xdiff;
    *y2 = pts[1].Y + tension * ydiff;
}

/* Calculates Bezier points from cardinal spline endpoints. */
void calc_curve_bezier_endp(REAL xend, REAL yend, REAL xadj, REAL yadj,
    REAL tension, REAL *x, REAL *y)
{
    /* tangent at endpoints is the line from the endpoint to the adjacent point */
    *x = roundr(tension * (xadj - xend) + xend);
    *y = roundr(tension * (yadj - yend) + yend);
}

/* make sure path has enough space for len more points */
BOOL lengthen_path(GpPath *path, INT len)
{
    /* initial allocation */
    if(path->datalen == 0){
        path->datalen = len * 2;

        path->pathdata.Points = GdipAlloc(path->datalen * sizeof(PointF));
        if(!path->pathdata.Points)   return FALSE;

        path->pathdata.Types = GdipAlloc(path->datalen);
        if(!path->pathdata.Types){
            GdipFree(path->pathdata.Points);
            return FALSE;
        }
    }
    /* reallocation, double size of arrays */
    else if(path->datalen - path->pathdata.Count < len){
        while(path->datalen - path->pathdata.Count < len)
            path->datalen *= 2;

        path->pathdata.Points = HeapReAlloc(GetProcessHeap(), 0,
            path->pathdata.Points, path->datalen * sizeof(PointF));
        if(!path->pathdata.Points)  return FALSE;

        path->pathdata.Types = HeapReAlloc(GetProcessHeap(), 0,
            path->pathdata.Types, path->datalen);
        if(!path->pathdata.Types)   return FALSE;
    }

    return TRUE;
}

/* recursive deletion of GpRegion nodes */
inline void delete_element(region_element* element)
{
    switch(element->type)
    {
        case RegionDataRect:
            break;
        case RegionDataPath:
            GdipDeletePath(element->elementdata.pathdata.path);
            break;
        case RegionDataEmptyRect:
        case RegionDataInfiniteRect:
            break;
        default:
            delete_element(element->elementdata.combine.left);
            delete_element(element->elementdata.combine.right);
            GdipFree(element->elementdata.combine.left);
            GdipFree(element->elementdata.combine.right);
            break;
    }
}