bsnes/hiro/gtk/widget/canvas.cpp

197 lines
5.8 KiB
C++

#if defined(Hiro_Canvas)
namespace hiro {
static auto Canvas_drop(GtkWidget* widget, GdkDragContext* context, signed x, signed y,
GtkSelectionData* data, unsigned type, unsigned timestamp, pCanvas* p) -> void {
if(!p->state().droppable) return;
auto paths = DropPaths(data);
if(!paths) return;
p->self().doDrop(paths);
}
static auto Canvas_expose(GtkWidget* widget, GdkEventExpose* event, pCanvas* p) -> signed {
p->_onExpose(event);
return true;
}
static auto Canvas_mouseLeave(GtkWidget* widget, GdkEventButton* event, pCanvas* p) -> signed {
p->self().doMouseLeave();
return true;
}
static auto Canvas_mouseMove(GtkWidget* widget, GdkEventButton* event, pCanvas* p) -> signed {
p->self().doMouseMove({(signed)event->x, (signed)event->y});
return true;
}
static auto Canvas_mousePress(GtkWidget* widget, GdkEventButton* event, pCanvas* p) -> signed {
switch(event->button) {
case 1: p->self().doMousePress(Mouse::Button::Left); break;
case 2: p->self().doMousePress(Mouse::Button::Middle); break;
case 3: p->self().doMousePress(Mouse::Button::Right); break;
}
return true;
}
static auto Canvas_mouseRelease(GtkWidget* widget, GdkEventButton* event, pCanvas* p) -> signed {
switch(event->button) {
case 1: p->self().doMouseRelease(Mouse::Button::Left); break;
case 2: p->self().doMouseRelease(Mouse::Button::Middle); break;
case 3: p->self().doMouseRelease(Mouse::Button::Right); break;
}
return true;
}
auto pCanvas::construct() -> void {
gtkWidget = gtk_drawing_area_new();
gtk_widget_add_events(gtkWidget,
GDK_BUTTON_PRESS_MASK | GDK_BUTTON_RELEASE_MASK | GDK_EXPOSURE_MASK | GDK_LEAVE_NOTIFY_MASK | GDK_POINTER_MOTION_MASK);
setDroppable(state().droppable);
_rasterize();
_redraw();
//todo: need to work around GTK+ library bug:
//after calling destruct(), construct() with state.droppable == true;
//GTK+ will throw SIGBUS inside g_signal_connect_data() on one of the below connections
g_signal_connect(G_OBJECT(gtkWidget), "button-press-event", G_CALLBACK(Canvas_mousePress), (gpointer)this);
g_signal_connect(G_OBJECT(gtkWidget), "button-release-event", G_CALLBACK(Canvas_mouseRelease), (gpointer)this);
g_signal_connect(G_OBJECT(gtkWidget), "drag-data-received", G_CALLBACK(Canvas_drop), (gpointer)this);
g_signal_connect(G_OBJECT(gtkWidget), "expose-event", G_CALLBACK(Canvas_expose), (gpointer)this);
g_signal_connect(G_OBJECT(gtkWidget), "leave-notify-event", G_CALLBACK(Canvas_mouseLeave), (gpointer)this);
g_signal_connect(G_OBJECT(gtkWidget), "motion-notify-event", G_CALLBACK(Canvas_mouseMove), (gpointer)this);
pWidget::construct();
}
auto pCanvas::destruct() -> void {
_release();
if(gtkWidget) gtk_widget_destroy(gtkWidget), gtkWidget = nullptr;
gtkParent = nullptr;
}
auto pCanvas::minimumSize() const -> Size {
if(auto& icon = state().icon) return {(int)icon.width(), (int)icon.height()};
return {0, 0};
}
auto pCanvas::setColor(Color color) -> void {
update();
}
auto pCanvas::setDroppable(bool droppable) -> void {
if(droppable) {
gtk_drag_dest_set(gtkWidget, GTK_DEST_DEFAULT_ALL, nullptr, 0, GDK_ACTION_COPY);
gtk_drag_dest_add_uri_targets(gtkWidget);
}
}
auto pCanvas::setGeometry(Geometry geometry) -> void {
update();
pWidget::setGeometry(geometry);
}
auto pCanvas::setGradient(Gradient gradient) -> void {
update();
}
auto pCanvas::setIcon(const image& icon) -> void {
update();
}
auto pCanvas::update() -> void {
_rasterize();
_redraw();
}
auto pCanvas::_onExpose(GdkEventExpose* expose) -> void {
if(surface == nullptr) return;
int sx = 0, sy = 0, dx = 0, dy = 0;
int width = surfaceWidth;
int height = surfaceHeight;
auto geometry = pSizable::state().geometry;
if(width <= geometry.width()) {
sx = 0;
dx = (geometry.width() - width) / 2;
} else {
sx = (width - geometry.width()) / 2;
dx = 0;
width = geometry.width();
}
if(height <= geometry.height()) {
sy = 0;
dy = (geometry.height() - height) / 2;
} else {
sy = (height - geometry.height()) / 2;
dy = 0;
height = geometry.height();
}
gdk_draw_pixbuf(gtk_widget_get_window(gtkWidget), nullptr, surface, sx, sy, dx, dy, width, height, GDK_RGB_DITHER_NONE, 0, 0);
}
auto pCanvas::_rasterize() -> void {
int width = 0;
int height = 0;
if(auto& icon = state().icon) {
width = icon.width();
height = icon.height();
} else {
width = pSizable::state().geometry.width();
height = pSizable::state().geometry.height();
}
if(width <= 0 || height <= 0) return;
if(width != surfaceWidth || height != surfaceHeight) _release();
surfaceWidth = width;
surfaceHeight = height;
if(!surface) surface = gdk_pixbuf_new(GDK_COLORSPACE_RGB, true, 8, width, height);
auto buffer = (uint32_t*)gdk_pixbuf_get_pixels(surface);
if(auto& icon = state().icon) {
memory::copy<uint32_t>(buffer, state().icon.data(), width * height);
} else if(auto& gradient = state().gradient) {
auto& colors = gradient.state.colors;
image fill;
fill.allocate(width, height);
fill.gradient(colors[0].value(), colors[1].value(), colors[2].value(), colors[3].value());
memory::copy(buffer, fill.data(), fill.size());
} else {
uint32_t color = state().color.value();
for(auto n : range(width * height)) buffer[n] = color;
}
//ARGB -> ABGR conversion
for(auto n : range(width * height)) {
uint32_t color = *buffer;
color = (color & 0xff00ff00) | ((color & 0xff0000) >> 16) | ((color & 0x0000ff) << 16);
*buffer++ = color;
}
}
auto pCanvas::_redraw() -> void {
if(gtk_widget_get_realized(gtkWidget)) {
gdk_window_invalidate_rect(gtk_widget_get_window(gtkWidget), nullptr, true);
}
}
auto pCanvas::_release() -> void {
if(surface) {
g_object_unref(surface);
surface = nullptr;
}
surfaceWidth = 0;
surfaceHeight = 0;
}
}
#endif