void wxImage::Create( int width, int height )
{
+ UnRef();
+
m_refData = new wxImageRefData();
M_IMGDATA->m_data = (unsigned char *) malloc( width*height*3 );
bitmap.Create( width, height, bpp );
- /*
// Create mask
- GdkImage *mask_image = (GdkImage*) NULL;
-
- if (HasMask())
- {
- unsigned char *mask_data = (unsigned char*)malloc( ((width >> 3)+8) * height );
-
- mask_image = gdk_image_new_bitmap( gdk_visual_get_system(), mask_data, width, height );
-
- wxMask *mask = new wxMask();
- mask->m_bitmap = gdk_pixmap_new( (GdkWindow*)&gdk_root_parent, width, height, 1 );
-
- bitmap.SetMask( mask );
- }
- */
+ XImage *mask_image = (XImage*) NULL;
+ if (HasMask())
+ {
+ mask_image = XCreateImage( dpy, vis, 1, ZPixmap, 0, 0, width, height, 32, 0 );
+ mask_image->data = (char*) malloc( mask_image->bytes_per_line * mask_image->height );
+ }
// Retrieve depth info
else if ((vi->green_mask > vi->blue_mask) && (vi->blue_mask > vi->red_mask)) b_o = GBR;
}
- /*
int r_mask = GetMaskRed();
int g_mask = GetMaskGreen();
int b_mask = GetMaskBlue();
- */
XColor colors[256];
if (bpp == 8)
wxSearchColor scolor( 256, colors );
unsigned char* data = GetData();
+ bool hasMask = HasMask();
+
int index = 0;
for (int y = 0; y < height; y++)
{
int b = data[index];
index++;
- /*
- if (HasMask())
+ if (hasMask)
{
- if ((r == r_mask) && (b == b_mask) && (g == g_mask))
- gdk_image_put_pixel( mask_image, x, y, 1 );
- else
- gdk_image_put_pixel( mask_image, x, y, 0 );
+ if ((r == r_mask) && (b == b_mask) && (g == g_mask))
+ XPutPixel( mask_image, x, y, 0 );
+ else
+ XPutPixel( mask_image, x, y, 1 );
}
- */
switch (bpp)
{
XDestroyImage( data_image );
XFreeGC( dpy, gc );
- /*
// Blit mask
+ if (HasMask())
+ {
+ wxBitmap maskBitmap(width, height, 1);
- if (HasMask())
- {
- GdkGC *mask_gc = gdk_gc_new( bitmap.GetMask()->GetBitmap() );
+ GC gcMask = XCreateGC( dpy, (Pixmap) maskBitmap.GetPixmap(), (XtGCMask) 0, (XGCValues*)NULL );
+ XPutImage( dpy, (Drawable)maskBitmap.GetPixmap(), gcMask, mask_image, 0, 0, 0, 0, width, height );
- gdk_draw_image( bitmap.GetMask()->GetBitmap(), mask_gc, mask_image, 0, 0, 0, 0, width, height );
+ XDestroyImage( mask_image );
+ XFreeGC( dpy, gcMask );
- gdk_image_destroy( mask_image );
- gdk_gc_unref( mask_gc );
- }
- */
+ wxMask* mask = new wxMask;
+ mask->SetPixmap(maskBitmap.GetPixmap());
+
+ bitmap.SetMask(mask);
+
+ maskBitmap.SetPixmapNull();
+ }
return bitmap;
}
* Rotation code by Carlos Moreno
*/
-struct wxRotationPixel
-{
- unsigned char rgb[3];
-};
-
-struct wxRotationPoint
-{
- wxRotationPoint (double _x, double _y) : x(_x), y(_y) {}
- wxRotationPoint (const wxPoint & p) : x(p.x), y(p.y) {}
- double x, y;
-};
+// GRG: I've removed wxRotationPoint - we already have wxRealPoint which
+// does exactly the same thing. And I also got rid of wxRotationPixel
+// bacause of potential problems in architectures where alignment
+// is an issue, so I had to rewrite parts of the code.
static const double gs_Epsilon = 1e-10;
// repeating the time-consuming calls to these functions -- sin/cos can
// be computed and stored in the calling function.
-inline wxRotationPoint rotated_point (const wxRotationPoint & p, double cos_angle, double sin_angle, const wxRotationPoint & p0)
+inline wxRealPoint rotated_point (const wxRealPoint & p, double cos_angle, double sin_angle, const wxRealPoint & p0)
{
- return wxRotationPoint (p0.x + (p.x - p0.x) * cos_angle - (p.y - p0.y) * sin_angle,
- p0.y + (p.y - p0.y) * cos_angle + (p.x - p0.x) * sin_angle);
+ return wxRealPoint (p0.x + (p.x - p0.x) * cos_angle - (p.y - p0.y) * sin_angle,
+ p0.y + (p.y - p0.y) * cos_angle + (p.x - p0.x) * sin_angle);
}
-inline wxRotationPoint rotated_point (double x, double y, double cos_angle, double sin_angle, const wxRotationPoint & p0)
+inline wxRealPoint rotated_point (double x, double y, double cos_angle, double sin_angle, const wxRealPoint & p0)
{
- return rotated_point (wxRotationPoint(x,y), cos_angle, sin_angle, p0);
+ return rotated_point (wxRealPoint(x,y), cos_angle, sin_angle, p0);
}
wxImage wxImage::Rotate(double angle, const wxPoint & centre_of_rotation, bool interpolating, wxPoint * offset_after_rotation) const
{
- const wxImage& img = * this;
int i;
angle = -angle; // screen coordinates are a mirror image of "real" coordinates
// Create pointer-based array to accelerate access to wxImage's data
- wxRotationPixel ** data = new wxRotationPixel * [img.GetHeight()];
+ unsigned char ** data = new unsigned char * [GetHeight()];
- data[0] = (wxRotationPixel *) img.GetData();
+ data[0] = GetData();
- for (i = 1; i < img.GetHeight(); i++)
- {
- data[i] = data[i - 1] + img.GetWidth();
- }
+ for (i = 1; i < GetHeight(); i++)
+ data[i] = data[i - 1] + (3 * GetWidth());
- // pre-compute coefficients for rotation formula
+ // precompute coefficients for rotation formula
// (sine and cosine of the angle)
const double cos_angle = cos(angle);
const double sin_angle = sin(angle);
// First, find rectangle that covers the rotated image; to do that,
// rotate the four corners
- const wxRotationPoint p0 = centre_of_rotation;
+ const wxRealPoint p0(centre_of_rotation.x, centre_of_rotation.y);
- wxRotationPoint p1 = rotated_point (0, 0, cos_angle, sin_angle, p0);
- wxRotationPoint p2 = rotated_point (0, img.GetHeight(), cos_angle, sin_angle, p0);
- wxRotationPoint p3 = rotated_point (img.GetWidth(), 0, cos_angle, sin_angle, p0);
- wxRotationPoint p4 = rotated_point (img.GetWidth(), img.GetHeight(), cos_angle, sin_angle, p0);
+ wxRealPoint p1 = rotated_point (0, 0, cos_angle, sin_angle, p0);
+ wxRealPoint p2 = rotated_point (0, GetHeight(), cos_angle, sin_angle, p0);
+ wxRealPoint p3 = rotated_point (GetWidth(), 0, cos_angle, sin_angle, p0);
+ wxRealPoint p4 = rotated_point (GetWidth(), GetHeight(), cos_angle, sin_angle, p0);
int x1 = (int) floor (wxMin (wxMin(p1.x, p2.x), wxMin(p3.x, p4.x)));
int y1 = (int) floor (wxMin (wxMin(p1.y, p2.y), wxMin(p3.y, p4.y)));
-
int x2 = (int) ceil (wxMax (wxMax(p1.x, p2.x), wxMax(p3.x, p4.x)));
int y2 = (int) ceil (wxMax (wxMax(p1.y, p2.y), wxMax(p3.y, p4.y)));
*offset_after_rotation = wxPoint (x1, y1);
}
- wxRotationPixel ** result_data = new wxRotationPixel * [rotated.GetHeight()];
-
- result_data[0] = (wxRotationPixel *) rotated.GetData();
-
- for (i = 1; i < rotated.GetHeight(); i++)
- {
- result_data[i] = result_data[i - 1] + rotated.GetWidth();
- }
+ // GRG: The rotated (destination) image is always accessed
+ // sequentially, so there is no need for a pointer-based
+ // array here (and in fact it would be slower).
+ //
+ unsigned char * dst = rotated.GetData();
// GRG: if the original image has a mask, use its RGB values
// as the blank pixel, else, fall back to default (black).
//
- wxRotationPixel blankPixel = {{ 0, 0, 0 }};
+ unsigned char blank_r = 0;
+ unsigned char blank_g = 0;
+ unsigned char blank_b = 0;
if (HasMask())
{
- unsigned char r = GetMaskRed();
- unsigned char g = GetMaskGreen();
- unsigned char b = GetMaskBlue();
- rotated.SetMaskColour( r, g, b );
- blankPixel.rgb[0] = r;
- blankPixel.rgb[1] = g;
- blankPixel.rgb[2] = b;
+ blank_r = GetMaskRed();
+ blank_g = GetMaskGreen();
+ blank_b = GetMaskBlue();
+ rotated.SetMaskColour( blank_r, blank_g, blank_b );
}
// Now, for each point of the rotated image, find where it came from, by
// performing an inverse rotation (a rotation of -angle) and getting the
// pixel at those coordinates
- // GRG: I'd suggest to take the (interpolating) test out of the loops
+ // GRG: I've taken the (interpolating) test out of the loops, so that
+ // it is done only once, instead of repeating it for each pixel.
int x;
- for (x = 0; x < rotated.GetWidth(); x++)
+ if (interpolating)
{
for (int y = 0; y < rotated.GetHeight(); y++)
{
- wxRotationPoint src = rotated_point (x + x1, y + y1, cos_angle, -sin_angle, p0);
-
- if (interpolating)
+ for (x = 0; x < rotated.GetWidth(); x++)
{
- if (0 < src.x && src.x < img.GetWidth() - 1 &&
- 0 < src.y && src.y < img.GetHeight() - 1)
+ wxRealPoint src = rotated_point (x + x1, y + y1, cos_angle, -sin_angle, p0);
+
+ if (-0.25 < src.x && src.x < GetWidth() - 0.75 &&
+ -0.25 < src.y && src.y < GetHeight() - 0.75)
{
// interpolate using the 4 enclosing grid-points. Those
// points can be obtained using floor and ceiling of the
// exact coordinates of the point
+ // C.M. 2000-02-17: when the point is near the border, special care is required.
+
+ int x1, y1, x2, y2;
+
+ if (0 < src.x && src.x < GetWidth() - 1)
+ {
+ x1 = wxCint(floor(src.x));
+ x2 = wxCint(ceil(src.x));
+ }
+ else // else means that x is near one of the borders (0 or width-1)
+ {
+ x1 = x2 = wxCint (src.x);
+ }
- const int x1 = wxCint(floor(src.x));
- const int y1 = wxCint(floor(src.y));
- const int x2 = wxCint(ceil(src.x));
- const int y2 = wxCint(ceil(src.y));
+ if (0 < src.y && src.y < GetHeight() - 1)
+ {
+ y1 = wxCint(floor(src.y));
+ y2 = wxCint(ceil(src.y));
+ }
+ else
+ {
+ y1 = y2 = wxCint (src.y);
+ }
// get four points and the distances (square of the distance,
// for efficiency reasons) for the interpolation formula
- const wxRotationPixel & v1 = data[y1][x1];
- const wxRotationPixel & v2 = data[y1][x2];
- const wxRotationPixel & v3 = data[y2][x2];
- const wxRotationPixel & v4 = data[y2][x1];
+
+ // GRG: Do not calculate the points until they are
+ // really needed -- this way we can calculate
+ // just one, instead of four, if d1, d2, d3
+ // or d4 are < gs_Epsilon
const double d1 = (src.x - x1) * (src.x - x1) + (src.y - y1) * (src.y - y1);
const double d2 = (src.x - x2) * (src.x - x2) + (src.y - y1) * (src.y - y1);
if (d1 < gs_Epsilon) // d1,d2,d3,d4 are positive -- no need for abs()
{
- result_data[y][x] = v1;
+ unsigned char *p = data[y1] + (3 * x1);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
}
else if (d2 < gs_Epsilon)
{
- result_data[y][x] = v2;
+ unsigned char *p = data[y1] + (3 * x2);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
}
else if (d3 < gs_Epsilon)
{
- result_data[y][x] = v3;
+ unsigned char *p = data[y2] + (3 * x2);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
}
else if (d4 < gs_Epsilon)
{
- result_data[y][x] = v4;
+ unsigned char *p = data[y2] + (3 * x1);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
}
else
{
// weights for the weighted average are proportional to the inverse of the distance
+ unsigned char *v1 = data[y1] + (3 * x1);
+ unsigned char *v2 = data[y1] + (3 * x2);
+ unsigned char *v3 = data[y2] + (3 * x2);
+ unsigned char *v4 = data[y2] + (3 * x1);
+
const double w1 = 1/d1, w2 = 1/d2, w3 = 1/d3, w4 = 1/d4;
- for (int i = 0; i < 3; i++) // repeat calculation for R, G, and B
- {
- result_data[y][x].rgb[i] =
- (unsigned char) ( (w1 * v1.rgb[i] + w2 * v2.rgb[i] +
- w3 * v3.rgb[i] + w4 * v4.rgb[i]) /
- (w1 + w2 + w3 + w4) );
- }
+ // GRG: Unrolled.
+
+ *(dst++) = (unsigned char)
+ ( (w1 * *(v1++) + w2 * *(v2++) +
+ w3 * *(v3++) + w4 * *(v4++)) /
+ (w1 + w2 + w3 + w4) );
+ *(dst++) = (unsigned char)
+ ( (w1 * *(v1++) + w2 * *(v2++) +
+ w3 * *(v3++) + w4 * *(v4++)) /
+ (w1 + w2 + w3 + w4) );
+ *(dst++) = (unsigned char)
+ ( (w1 * *(v1++) + w2 * *(v2++) +
+ w3 * *(v3++) + w4 * *(v4++)) /
+ (w1 + w2 + w3 + w4) );
}
}
else
{
- result_data[y][x] = blankPixel;
+ *(dst++) = blank_r;
+ *(dst++) = blank_g;
+ *(dst++) = blank_b;
}
}
- else
+ }
+ }
+ else // not interpolating
+ {
+ for (int y = 0; y < rotated.GetHeight(); y++)
+ {
+ for (x = 0; x < rotated.GetWidth(); x++)
{
- const int xs = wxCint (src.x); // wxCint performs rounding to the
+ wxRealPoint src = rotated_point (x + x1, y + y1, cos_angle, -sin_angle, p0);
+
+ const int xs = wxCint (src.x); // wxCint rounds to the
const int ys = wxCint (src.y); // closest integer
- if (0 <= xs && xs < img.GetWidth() &&
- 0 <= ys && ys < img.GetHeight())
+ if (0 <= xs && xs < GetWidth() &&
+ 0 <= ys && ys < GetHeight())
{
- result_data[y][x] = data[ys][xs];
+ unsigned char *p = data[ys] + (3 * xs);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
+ *(dst++) = *(p++);
}
else
{
- result_data[y][x] = blankPixel;
+ *(dst++) = blank_r;
+ *(dst++) = blank_g;
+ *(dst++) = blank_b;
}
}
}
}
delete [] data;
- delete [] result_data;
return rotated;
}