/**
* _cairo_traps_extract_region:
* @traps: a #cairo_traps_t
* @region: a #cairo_region_t
*
* Determines if a set of trapezoids are exactly representable as a
* cairo region. If so, the passed-in region is initialized to
* the area representing the given traps. It should be finalized
* with cairo_region_fini(). If not, %CAIRO_INT_STATUS_UNSUPPORTED
* is returned.
*
* Return value: %CAIRO_STATUS_SUCCESS, %CAIRO_INT_STATUS_UNSUPPORTED
* or %CAIRO_STATUS_NO_MEMORY
**/
cairo_int_status_t
_cairo_traps_extract_region (cairo_traps_t *traps,
cairo_antialias_t antialias,
cairo_region_t **region)
{
cairo_rectangle_int_t stack_rects[CAIRO_STACK_ARRAY_LENGTH (cairo_rectangle_int_t)];
cairo_rectangle_int_t *rects = stack_rects;
cairo_int_status_t status;
int i, rect_count;
/* we only treat this a hint... */
if (antialias != CAIRO_ANTIALIAS_NONE && ! traps->maybe_region)
return CAIRO_INT_STATUS_UNSUPPORTED;
if (! _traps_are_pixel_aligned (traps, antialias)) {
traps->maybe_region = FALSE;
return CAIRO_INT_STATUS_UNSUPPORTED;
}
if (traps->num_traps > ARRAY_LENGTH (stack_rects)) {
rects = _cairo_malloc_ab (traps->num_traps, sizeof (cairo_rectangle_int_t));
if (unlikely (rects == NULL))
return _cairo_error (CAIRO_STATUS_NO_MEMORY);
}
rect_count = 0;
for (i = 0; i < traps->num_traps; i++) {
int x1, y1, x2, y2;
if (antialias == CAIRO_ANTIALIAS_NONE) {
x1 = _cairo_fixed_integer_round_down (traps->traps[i].left.p1.x);
y1 = _cairo_fixed_integer_round_down (traps->traps[i].top);
x2 = _cairo_fixed_integer_round_down (traps->traps[i].right.p1.x);
y2 = _cairo_fixed_integer_round_down (traps->traps[i].bottom);
} else {
x1 = _cairo_fixed_integer_part (traps->traps[i].left.p1.x);
y1 = _cairo_fixed_integer_part (traps->traps[i].top);
x2 = _cairo_fixed_integer_part (traps->traps[i].right.p1.x);
y2 = _cairo_fixed_integer_part (traps->traps[i].bottom);
}
if (x2 > x1 && y2 > y1) {
rects[rect_count].x = x1;
rects[rect_count].y = y1;
rects[rect_count].width = x2 - x1;
rects[rect_count].height = y2 - y1;
rect_count++;
}
}
*region = cairo_region_create_rectangles (rects, rect_count);
status = (*region)->status;
if (rects != stack_rects)
free (rects);
return status;
}
static void
update_shape (GtkWidget* window,
gint radius,
gint shadow_size)
{
if (g_composited)
{
/* remove any current shape-mask */
gtk_widget_input_shape_combine_region (window, NULL);
return;
}
int width;
int height;
gtk_widget_get_size_request (window, &width, &height);
const cairo_rectangle_int_t rects[] = {{2, 0, width - 4, height},
{1, 1, width - 2, height - 2},
{0, 2, width, height - 4}};
cairo_region_t* region = NULL;
region = cairo_region_create_rectangles (rects, 3);
if (cairo_region_status (region) == CAIRO_STATUS_SUCCESS)
{
gtk_widget_shape_combine_region (window, NULL);
gtk_widget_shape_combine_region (window, region);
}
}
cairo_region_t *
meta_region_transform (cairo_region_t *region,
MetaMonitorTransform transform,
int width,
int height)
{
int n_rects, i;
cairo_rectangle_int_t *rects;
cairo_region_t *transformed_region;
if (transform == META_MONITOR_TRANSFORM_NORMAL)
return cairo_region_copy (region);
n_rects = cairo_region_num_rectangles (region);
rects = g_new0 (cairo_rectangle_int_t, n_rects);
for (i = 0; i < n_rects; i++)
{
cairo_region_get_rectangle (region, i, &rects[i]);
meta_rectangle_transform (&rects[i],
transform,
width,
height,
&rects[i]);
}
transformed_region = cairo_region_create_rectangles (rects, n_rects);
g_free (rects);
return transformed_region;
}
cairo_region_t *
meta_region_scale (cairo_region_t *region, int scale)
{
int n_rects, i;
cairo_rectangle_int_t *rects;
cairo_region_t *scaled_region;
if (scale == 1)
return cairo_region_copy (region);
n_rects = cairo_region_num_rectangles (region);
rects = g_malloc (sizeof(cairo_rectangle_int_t) * n_rects);
for (i = 0; i < n_rects; i++)
{
cairo_region_get_rectangle (region, i, &rects[i]);
rects[i].x *= scale;
rects[i].y *= scale;
rects[i].width *= scale;
rects[i].height *= scale;
}
scaled_region = cairo_region_create_rectangles (rects, n_rects);
g_free (rects);
return scaled_region;
}
cairo_region_t *
meta_region_scale_double (cairo_region_t *region,
double scale,
MetaRoundingStrategy rounding_strategy)
{
int n_rects, i;
cairo_rectangle_int_t *rects;
cairo_region_t *scaled_region;
g_return_val_if_fail (scale > 0.0, NULL);
if (scale == 1.0)
return cairo_region_copy (region);
n_rects = cairo_region_num_rectangles (region);
rects = g_malloc (sizeof(cairo_rectangle_int_t) * n_rects);
for (i = 0; i < n_rects; i++)
{
cairo_region_get_rectangle (region, i, &rects[i]);
meta_rectangle_scale_double (&rects[i], scale, rounding_strategy,
&rects[i]);
}
scaled_region = cairo_region_create_rectangles (rects, n_rects);
g_free (rects);
return scaled_region;
}
cairo_region_t *
meta_region_crop_and_scale (cairo_region_t *region,
ClutterRect *src_rect,
int dst_width,
int dst_height)
{
int n_rects, i;
cairo_rectangle_int_t *rects;
cairo_region_t *viewport_region;
if (src_rect->size.width == dst_width &&
src_rect->size.height == dst_height &&
roundf (src_rect->origin.x) == src_rect->origin.x &&
roundf (src_rect->origin.y) == src_rect->origin.y)
{
viewport_region = cairo_region_copy (region);
if (src_rect->origin.x != 0 || src_rect->origin.y != 0)
{
cairo_region_translate (viewport_region,
(int) src_rect->origin.x,
(int) src_rect->origin.y);
}
return viewport_region;
}
n_rects = cairo_region_num_rectangles (region);
rects = g_new0 (cairo_rectangle_int_t, n_rects);
for (i = 0; i < n_rects; i++)
{
cairo_region_get_rectangle (region, i, &rects[i]);
meta_rectangle_crop_and_scale (&rects[i],
src_rect,
dst_width,
dst_height,
&rects[i]);
}
viewport_region = cairo_region_create_rectangles (rects, n_rects);
g_free (rects);
return viewport_region;
}
static cairo_region_t *
region_from_rects (BroadwayRect *rects, int n_rects)
{
cairo_region_t *region;
cairo_rectangle_int_t *cairo_rects;
int i;
cairo_rects = g_new (cairo_rectangle_int_t, n_rects);
for (i = 0; i < n_rects; i++)
{
cairo_rects[i].x = rects[i].x;
cairo_rects[i].y = rects[i].y;
cairo_rects[i].width = rects[i].width;
cairo_rects[i].height = rects[i].height;
}
region = cairo_region_create_rectangles (cairo_rects, n_rects);
g_free (cairo_rects);
return region;
}
/* This special-case filler supports only a path that describes a
* device-axis aligned rectangle. It exists to avoid the overhead of
* the general tessellator when drawing very common rectangles.
*
* If the path described anything but a device-axis aligned rectangle,
* this function will abort.
*/
cairo_region_t *
_cairo_path_fixed_fill_rectilinear_to_region (const cairo_path_fixed_t *path,
cairo_fill_rule_t fill_rule,
const cairo_rectangle_int_t *extents)
{
cairo_rectangle_int_t rectangle_stack[CAIRO_STACK_ARRAY_LENGTH (cairo_rectangle_int_t)];
cairo_box_t box;
cairo_region_t *region = NULL;
assert (path->maybe_fill_region);
assert (! path->is_empty_fill);
if (_cairo_path_fixed_is_box (path, &box)) {
rectangle_stack[0].x = _cairo_fixed_integer_part (box.p1.x);
rectangle_stack[0].y = _cairo_fixed_integer_part (box.p1.y);
rectangle_stack[0].width = _cairo_fixed_integer_part (box.p2.x) -
rectangle_stack[0].x;
rectangle_stack[0].height = _cairo_fixed_integer_part (box.p2.y) -
rectangle_stack[0].y;
if (! _cairo_rectangle_intersect (&rectangle_stack[0], extents))
region = cairo_region_create ();
else
region = cairo_region_create_rectangle (&rectangle_stack[0]);
} else if (fill_rule == CAIRO_FILL_RULE_WINDING) {
cairo_rectangle_int_t *rects = rectangle_stack;
cairo_path_fixed_iter_t iter;
int last_cw = -1;
int size = ARRAY_LENGTH (rectangle_stack);
int count = 0;
/* Support a series of rectangles as can be expected to describe a
* GdkRegion clip region during exposes.
*/
_cairo_path_fixed_iter_init (&iter, path);
while (_cairo_path_fixed_iter_is_fill_box (&iter, &box)) {
int cw = 0;
if (box.p1.x > box.p2.x) {
cairo_fixed_t t;
t = box.p1.x;
box.p1.x = box.p2.x;
box.p2.x = t;
cw = ! cw;
}
if (box.p1.y > box.p2.y) {
cairo_fixed_t t;
t = box.p1.y;
box.p1.y = box.p2.y;
box.p2.y = t;
cw = ! cw;
}
if (last_cw < 0)
last_cw = cw;
else if (last_cw != cw)
goto TESSELLATE;
if (count == size) {
cairo_rectangle_int_t *new_rects;
size *= 4;
if (rects == rectangle_stack) {
new_rects = _cairo_malloc_ab (size,
sizeof (cairo_rectangle_int_t));
if (unlikely (new_rects == NULL)) {
/* XXX _cairo_region_nil */
break;
}
memcpy (new_rects, rects, sizeof (rectangle_stack));
} else {
new_rects = _cairo_realloc_ab (rects, size,
sizeof (cairo_rectangle_int_t));
if (unlikely (new_rects == NULL)) {
/* XXX _cairo_region_nil */
break;
}
}
rects = new_rects;
}
rects[count].x = _cairo_fixed_integer_part (box.p1.x);
rects[count].y = _cairo_fixed_integer_part (box.p1.y);
rects[count].width = _cairo_fixed_integer_part (box.p2.x) - rects[count].x;
rects[count].height = _cairo_fixed_integer_part (box.p2.y) - rects[count].y;
if (_cairo_rectangle_intersect (&rects[count], extents))
count++;
}
if (_cairo_path_fixed_iter_at_end (&iter))
region = cairo_region_create_rectangles (rects, count);
TESSELLATE:
if (rects != rectangle_stack)
free (rects);
}
if (region == NULL) {
/* Hmm, complex polygon */
region = _cairo_path_fixed_fill_rectilinear_tessellate_to_region (path,
fill_rule,
extents);
}
return region;
}
static gboolean
goc_canvas_draw (GtkWidget *widget, cairo_t *cr)
{
double x0, y0, x1, y1;
double ax0, ay0, ax1, ay1;
double clip_x1, clip_y1, clip_x2, clip_y2;
GocCanvas *canvas = GOC_CANVAS (widget);
GdkEventExpose *event = (GdkEventExpose *) gtk_get_current_event ();
GocCanvasPrivate *priv = (GocCanvasPrivate *) canvas->priv;
cairo_rectangle_list_t *l = cairo_copy_clip_rectangle_list (cr);
int i, x, y;
if (GOC_IS_ITEM (priv->invalidated_item) && priv->invalid_region) {
/* evaluate the cairo clipped region and compare with the saved one */
cairo_region_t *region;
cairo_rectangle_int_t rect[l->num_rectangles];
for (i= 0; i < l->num_rectangles; i++) {
rect[i].x = l->rectangles[i].x;
rect[i].y = l->rectangles[i].y;
rect[i].width = l->rectangles[i].width;
rect[i].height = l->rectangles[i].height;
}
region = cairo_region_create_rectangles (rect, l->num_rectangles);
if (cairo_region_equal (priv->invalid_region, region)) {
cairo_rectangle_list_destroy (l);
cairo_region_destroy (region);
/* looks like each time we call gtk_widget_queue_draw*,
the draw event is fired twice */
if (priv->done) {
priv->invalidated_item = NULL;
cairo_region_destroy (priv->invalid_region);
priv->invalid_region = NULL;
} else {
goc_item_draw (priv->invalidated_item, cr);
priv->done = TRUE;
}
return TRUE;
}
cairo_region_destroy (region);
}
x = gtk_adjustment_get_value (gtk_scrollable_get_hadjustment (GTK_SCROLLABLE (canvas)));
y = gtk_adjustment_get_value (gtk_scrollable_get_vadjustment (GTK_SCROLLABLE (canvas)));
cairo_translate (cr, -x, -y);
goc_item_get_bounds (GOC_ITEM (canvas->root),&x0, &y0, &x1, &y1);
for (i= 0; i < l->num_rectangles; i++) {
cairo_save (cr);
cairo_rectangle (cr, l->rectangles[i].x, l->rectangles[i].y,
l->rectangles[i].width, l->rectangles[i].height);
cairo_clip (cr);
clip_x1 = l->rectangles[i].x;
clip_y1 = l->rectangles[i].y;
clip_x2 = clip_x1 + l->rectangles[i].width;
clip_y2 = clip_y1 + l->rectangles[i].height;
if (canvas->direction == GOC_DIRECTION_RTL) {
ax1 = (double) (canvas->width - clip_x1) / canvas->pixels_per_unit + canvas->scroll_x1;
ax0 = (double) (canvas->width - clip_x2) / canvas->pixels_per_unit + canvas->scroll_x1;
} else {
ax0 = (double) clip_x1 / canvas->pixels_per_unit + canvas->scroll_x1;
ax1 = ((double) clip_x1 + event->area.width) / canvas->pixels_per_unit + canvas->scroll_x1;
}
ay0 = (double) clip_y1 / canvas->pixels_per_unit + canvas->scroll_y1;
ay1 = (double) clip_y2 / canvas->pixels_per_unit + canvas->scroll_y1;
if (x0 <= ax1 && x1 >= ax0 && y0 <= ay1 && y1 >= ay0) {
canvas->cur_event = (GdkEvent *) event;
goc_item_draw_region (GOC_ITEM (canvas->root), cr, ax0, ay0, ax1, ay1);
}
cairo_restore (cr);
}
cairo_rectangle_list_destroy (l);
return TRUE;
}
