// Copyright (c) 2012 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // This file defines utility functions for X11 (Linux only). This code has been // ported from XCB since we can't use XCB on Ubuntu while its 32-bit support // remains woefully incomplete. #include "ui/base/x/x11_util.h" #include #include #include #include #include #include #include #include #include #include #include "base/bind.h" #include "base/debug/trace_event.h" #include "base/logging.h" #include "base/memory/scoped_ptr.h" #include "base/memory/singleton.h" #include "base/message_loop/message_loop.h" #include "base/metrics/histogram.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/sys_byteorder.h" #include "base/threading/thread.h" #include "skia/ext/image_operations.h" #include "third_party/skia/include/core/SkBitmap.h" #include "third_party/skia/include/core/SkPostConfig.h" #include "ui/base/x/x11_menu_list.h" #include "ui/base/x/x11_util_internal.h" #include "ui/events/event_utils.h" #include "ui/events/keycodes/keyboard_code_conversion_x.h" #include "ui/events/x/device_data_manager_x11.h" #include "ui/events/x/touch_factory_x11.h" #include "ui/gfx/canvas.h" #include "ui/gfx/image/image_skia.h" #include "ui/gfx/image/image_skia_rep.h" #include "ui/gfx/point.h" #include "ui/gfx/point_conversions.h" #include "ui/gfx/rect.h" #include "ui/gfx/size.h" #include "ui/gfx/skia_util.h" #include "ui/gfx/x/x11_error_tracker.h" #if defined(OS_FREEBSD) #include #include #endif namespace ui { namespace { int DefaultX11ErrorHandler(XDisplay* d, XErrorEvent* e) { if (base::MessageLoop::current()) { base::MessageLoop::current()->PostTask( FROM_HERE, base::Bind(&LogErrorEventDescription, d, *e)); } else { LOG(ERROR) << "X error received: " << "serial " << e->serial << ", " << "error_code " << static_cast(e->error_code) << ", " << "request_code " << static_cast(e->request_code) << ", " << "minor_code " << static_cast(e->minor_code); } return 0; } int DefaultX11IOErrorHandler(XDisplay* d) { // If there's an IO error it likely means the X server has gone away LOG(ERROR) << "X IO error received (X server probably went away)"; _exit(1); } // Note: The caller should free the resulting value data. bool GetProperty(XID window, const std::string& property_name, long max_length, XAtom* type, int* format, unsigned long* num_items, unsigned char** property) { XAtom property_atom = GetAtom(property_name.c_str()); unsigned long remaining_bytes = 0; return XGetWindowProperty(gfx::GetXDisplay(), window, property_atom, 0, // offset into property data to read max_length, // max length to get False, // deleted AnyPropertyType, type, format, num_items, &remaining_bytes, property); } // A process wide singleton that manages the usage of X cursors. class XCursorCache { public: XCursorCache() {} ~XCursorCache() { Clear(); } ::Cursor GetCursor(int cursor_shape) { // Lookup cursor by attempting to insert a null value, which avoids // a second pass through the map after a cache miss. std::pair::iterator, bool> it = cache_.insert( std::make_pair(cursor_shape, 0)); if (it.second) { XDisplay* display = gfx::GetXDisplay(); it.first->second = XCreateFontCursor(display, cursor_shape); } return it.first->second; } void Clear() { XDisplay* display = gfx::GetXDisplay(); for (std::map::iterator it = cache_.begin(); it != cache_.end(); ++it) { XFreeCursor(display, it->second); } cache_.clear(); } private: // Maps X11 font cursor shapes to Cursor IDs. std::map cache_; DISALLOW_COPY_AND_ASSIGN(XCursorCache); }; XCursorCache* cursor_cache = NULL; // A process wide singleton cache for custom X cursors. class XCustomCursorCache { public: static XCustomCursorCache* GetInstance() { return Singleton::get(); } ::Cursor InstallCustomCursor(XcursorImage* image) { XCustomCursor* custom_cursor = new XCustomCursor(image); ::Cursor xcursor = custom_cursor->cursor(); cache_[xcursor] = custom_cursor; return xcursor; } void Ref(::Cursor cursor) { cache_[cursor]->Ref(); } void Unref(::Cursor cursor) { if (cache_[cursor]->Unref()) cache_.erase(cursor); } void Clear() { cache_.clear(); } const XcursorImage* GetXcursorImage(::Cursor cursor) const { return cache_.find(cursor)->second->image(); } private: friend struct DefaultSingletonTraits; class XCustomCursor { public: // This takes ownership of the image. XCustomCursor(XcursorImage* image) : image_(image), ref_(1) { cursor_ = XcursorImageLoadCursor(gfx::GetXDisplay(), image); } ~XCustomCursor() { XcursorImageDestroy(image_); XFreeCursor(gfx::GetXDisplay(), cursor_); } ::Cursor cursor() const { return cursor_; } void Ref() { ++ref_; } // Returns true if the cursor was destroyed because of the unref. bool Unref() { if (--ref_ == 0) { delete this; return true; } return false; } const XcursorImage* image() const { return image_; }; private: XcursorImage* image_; int ref_; ::Cursor cursor_; DISALLOW_COPY_AND_ASSIGN(XCustomCursor); }; XCustomCursorCache() {} ~XCustomCursorCache() { Clear(); } std::map< ::Cursor, XCustomCursor*> cache_; DISALLOW_COPY_AND_ASSIGN(XCustomCursorCache); }; } // namespace bool IsXInput2Available() { return DeviceDataManagerX11::GetInstance()->IsXInput2Available(); } static SharedMemorySupport DoQuerySharedMemorySupport(XDisplay* dpy) { int dummy; Bool pixmaps_supported; // Query the server's support for XSHM. if (!XShmQueryVersion(dpy, &dummy, &dummy, &pixmaps_supported)) return SHARED_MEMORY_NONE; #if defined(OS_FREEBSD) // On FreeBSD we can't access the shared memory after it was marked for // deletion, unless this behaviour is explicitly enabled by the user. // In case it's not enabled disable shared memory support. int allow_removed; size_t length = sizeof(allow_removed); if ((sysctlbyname("kern.ipc.shm_allow_removed", &allow_removed, &length, NULL, 0) < 0) || allow_removed < 1) { return SHARED_MEMORY_NONE; } #endif // Next we probe to see if shared memory will really work int shmkey = shmget(IPC_PRIVATE, 1, 0600); if (shmkey == -1) { LOG(WARNING) << "Failed to get shared memory segment."; return SHARED_MEMORY_NONE; } else { VLOG(1) << "Got shared memory segment " << shmkey; } void* address = shmat(shmkey, NULL, 0); // Mark the shared memory region for deletion shmctl(shmkey, IPC_RMID, NULL); XShmSegmentInfo shminfo; memset(&shminfo, 0, sizeof(shminfo)); shminfo.shmid = shmkey; gfx::X11ErrorTracker err_tracker; bool result = XShmAttach(dpy, &shminfo); if (result) VLOG(1) << "X got shared memory segment " << shmkey; else LOG(WARNING) << "X failed to attach to shared memory segment " << shmkey; if (err_tracker.FoundNewError()) result = false; shmdt(address); if (!result) { LOG(WARNING) << "X failed to attach to shared memory segment " << shmkey; return SHARED_MEMORY_NONE; } VLOG(1) << "X attached to shared memory segment " << shmkey; XShmDetach(dpy, &shminfo); return pixmaps_supported ? SHARED_MEMORY_PIXMAP : SHARED_MEMORY_PUTIMAGE; } SharedMemorySupport QuerySharedMemorySupport(XDisplay* dpy) { static SharedMemorySupport shared_memory_support = SHARED_MEMORY_NONE; static bool shared_memory_support_cached = false; if (shared_memory_support_cached) return shared_memory_support; shared_memory_support = DoQuerySharedMemorySupport(dpy); shared_memory_support_cached = true; return shared_memory_support; } bool QueryRenderSupport(Display* dpy) { int dummy; // We don't care about the version of Xrender since all the features which // we use are included in every version. static bool render_supported = XRenderQueryExtension(dpy, &dummy, &dummy); return render_supported; } ::Cursor GetXCursor(int cursor_shape) { if (!cursor_cache) cursor_cache = new XCursorCache; return cursor_cache->GetCursor(cursor_shape); } ::Cursor CreateReffedCustomXCursor(XcursorImage* image) { return XCustomCursorCache::GetInstance()->InstallCustomCursor(image); } void RefCustomXCursor(::Cursor cursor) { XCustomCursorCache::GetInstance()->Ref(cursor); } void UnrefCustomXCursor(::Cursor cursor) { XCustomCursorCache::GetInstance()->Unref(cursor); } XcursorImage* SkBitmapToXcursorImage(const SkBitmap* cursor_image, const gfx::Point& hotspot) { DCHECK(cursor_image->colorType() == kN32_SkColorType); gfx::Point hotspot_point = hotspot; SkBitmap scaled; // X11 seems to have issues with cursors when images get larger than 64 // pixels. So rescale the image if necessary. const float kMaxPixel = 64.f; bool needs_scale = false; if (cursor_image->width() > kMaxPixel || cursor_image->height() > kMaxPixel) { float scale = 1.f; if (cursor_image->width() > cursor_image->height()) scale = kMaxPixel / cursor_image->width(); else scale = kMaxPixel / cursor_image->height(); scaled = skia::ImageOperations::Resize(*cursor_image, skia::ImageOperations::RESIZE_BETTER, static_cast(cursor_image->width() * scale), static_cast(cursor_image->height() * scale)); hotspot_point = gfx::ToFlooredPoint(gfx::ScalePoint(hotspot, scale)); needs_scale = true; } const SkBitmap* bitmap = needs_scale ? &scaled : cursor_image; XcursorImage* image = XcursorImageCreate(bitmap->width(), bitmap->height()); image->xhot = std::min(bitmap->width() - 1, hotspot_point.x()); image->yhot = std::min(bitmap->height() - 1, hotspot_point.y()); if (bitmap->width() && bitmap->height()) { bitmap->lockPixels(); // The |bitmap| contains ARGB image, so just copy it. memcpy(image->pixels, bitmap->getPixels(), bitmap->width() * bitmap->height() * 4); bitmap->unlockPixels(); } return image; } int CoalescePendingMotionEvents(const XEvent* xev, XEvent* last_event) { XIDeviceEvent* xievent = static_cast(xev->xcookie.data); int num_coalesced = 0; XDisplay* display = xev->xany.display; int event_type = xev->xgeneric.evtype; DCHECK(event_type == XI_Motion || event_type == XI_TouchUpdate); while (XPending(display)) { XEvent next_event; XPeekEvent(display, &next_event); // If we can't get the cookie, abort the check. if (!XGetEventData(next_event.xgeneric.display, &next_event.xcookie)) return num_coalesced; // If this isn't from a valid device, throw the event away, as // that's what the message pump would do. Device events come in pairs // with one from the master and one from the slave so there will // always be at least one pending. if (!ui::TouchFactory::GetInstance()->ShouldProcessXI2Event(&next_event)) { XFreeEventData(display, &next_event.xcookie); XNextEvent(display, &next_event); continue; } if (next_event.type == GenericEvent && next_event.xgeneric.evtype == event_type && !ui::DeviceDataManagerX11::GetInstance()->IsCMTGestureEvent( &next_event)) { XIDeviceEvent* next_xievent = static_cast(next_event.xcookie.data); // Confirm that the motion event is targeted at the same window // and that no buttons or modifiers have changed. if (xievent->event == next_xievent->event && xievent->child == next_xievent->child && xievent->detail == next_xievent->detail && xievent->buttons.mask_len == next_xievent->buttons.mask_len && (memcmp(xievent->buttons.mask, next_xievent->buttons.mask, xievent->buttons.mask_len) == 0) && xievent->mods.base == next_xievent->mods.base && xievent->mods.latched == next_xievent->mods.latched && xievent->mods.locked == next_xievent->mods.locked && xievent->mods.effective == next_xievent->mods.effective) { XFreeEventData(display, &next_event.xcookie); // Free the previous cookie. if (num_coalesced > 0) XFreeEventData(display, &last_event->xcookie); // Get the event and its cookie data. XNextEvent(display, last_event); XGetEventData(display, &last_event->xcookie); ++num_coalesced; continue; } } // This isn't an event we want so free its cookie data. XFreeEventData(display, &next_event.xcookie); break; } if (event_type == XI_Motion && num_coalesced > 0) { base::TimeDelta delta = ui::EventTimeFromNative(last_event) - ui::EventTimeFromNative(const_cast(xev)); UMA_HISTOGRAM_COUNTS_10000("Event.CoalescedCount.Mouse", num_coalesced); UMA_HISTOGRAM_TIMES("Event.CoalescedLatency.Mouse", delta); } return num_coalesced; } void HideHostCursor() { CR_DEFINE_STATIC_LOCAL(XScopedCursor, invisible_cursor, (CreateInvisibleCursor(), gfx::GetXDisplay())); XDefineCursor(gfx::GetXDisplay(), DefaultRootWindow(gfx::GetXDisplay()), invisible_cursor.get()); } ::Cursor CreateInvisibleCursor() { XDisplay* xdisplay = gfx::GetXDisplay(); ::Cursor invisible_cursor; char nodata[] = { 0, 0, 0, 0, 0, 0, 0, 0 }; XColor black; black.red = black.green = black.blue = 0; Pixmap blank = XCreateBitmapFromData(xdisplay, DefaultRootWindow(xdisplay), nodata, 8, 8); invisible_cursor = XCreatePixmapCursor(xdisplay, blank, blank, &black, &black, 0, 0); XFreePixmap(xdisplay, blank); return invisible_cursor; } void SetUseOSWindowFrame(XID window, bool use_os_window_frame) { // This data structure represents additional hints that we send to the window // manager and has a direct lineage back to Motif, which defined this de facto // standard. This struct doesn't seem 64-bit safe though, but it's what GDK // does. typedef struct { unsigned long flags; unsigned long functions; unsigned long decorations; long input_mode; unsigned long status; } MotifWmHints; MotifWmHints motif_hints; memset(&motif_hints, 0, sizeof(motif_hints)); // Signals that the reader of the _MOTIF_WM_HINTS property should pay // attention to the value of |decorations|. motif_hints.flags = (1L << 1); motif_hints.decorations = use_os_window_frame ? 1 : 0; XAtom hint_atom = GetAtom("_MOTIF_WM_HINTS"); XChangeProperty(gfx::GetXDisplay(), window, hint_atom, hint_atom, 32, PropModeReplace, reinterpret_cast(&motif_hints), sizeof(MotifWmHints)/sizeof(long)); } bool IsShapeExtensionAvailable() { int dummy; static bool is_shape_available = XShapeQueryExtension(gfx::GetXDisplay(), &dummy, &dummy); return is_shape_available; } XID GetX11RootWindow() { return DefaultRootWindow(gfx::GetXDisplay()); } bool GetCurrentDesktop(int* desktop) { return GetIntProperty(GetX11RootWindow(), "_NET_CURRENT_DESKTOP", desktop); } void SetHideTitlebarWhenMaximizedProperty(XID window, HideTitlebarWhenMaximized property) { // XChangeProperty() expects "hide" to be long. unsigned long hide = property; XChangeProperty(gfx::GetXDisplay(), window, GetAtom("_GTK_HIDE_TITLEBAR_WHEN_MAXIMIZED"), XA_CARDINAL, 32, // size in bits PropModeReplace, reinterpret_cast(&hide), 1); } void ClearX11DefaultRootWindow() { XDisplay* display = gfx::GetXDisplay(); XID root_window = GetX11RootWindow(); gfx::Rect root_bounds; if (!GetWindowRect(root_window, &root_bounds)) { LOG(ERROR) << "Failed to get the bounds of the X11 root window"; return; } XGCValues gc_values = {0}; gc_values.foreground = BlackPixel(display, DefaultScreen(display)); GC gc = XCreateGC(display, root_window, GCForeground, &gc_values); XFillRectangle(display, root_window, gc, root_bounds.x(), root_bounds.y(), root_bounds.width(), root_bounds.height()); XFreeGC(display, gc); } bool IsWindowVisible(XID window) { TRACE_EVENT0("ui", "IsWindowVisible"); XWindowAttributes win_attributes; if (!XGetWindowAttributes(gfx::GetXDisplay(), window, &win_attributes)) return false; if (win_attributes.map_state != IsViewable) return false; // Minimized windows are not visible. std::vector wm_states; if (GetAtomArrayProperty(window, "_NET_WM_STATE", &wm_states)) { XAtom hidden_atom = GetAtom("_NET_WM_STATE_HIDDEN"); if (std::find(wm_states.begin(), wm_states.end(), hidden_atom) != wm_states.end()) { return false; } } // Some compositing window managers (notably kwin) do not actually unmap // windows on desktop switch, so we also must check the current desktop. int window_desktop, current_desktop; return (!GetWindowDesktop(window, &window_desktop) || !GetCurrentDesktop(¤t_desktop) || window_desktop == kAllDesktops || window_desktop == current_desktop); } bool GetWindowRect(XID window, gfx::Rect* rect) { Window root, child; int x, y; unsigned int width, height; unsigned int border_width, depth; if (!XGetGeometry(gfx::GetXDisplay(), window, &root, &x, &y, &width, &height, &border_width, &depth)) return false; if (!XTranslateCoordinates(gfx::GetXDisplay(), window, root, 0, 0, &x, &y, &child)) return false; *rect = gfx::Rect(x, y, width, height); std::vector insets; if (GetIntArrayProperty(window, "_NET_FRAME_EXTENTS", &insets) && insets.size() == 4) { rect->Inset(-insets[0], -insets[2], -insets[1], -insets[3]); } // Not all window managers support _NET_FRAME_EXTENTS so return true even if // requesting the property fails. return true; } bool WindowContainsPoint(XID window, gfx::Point screen_loc) { TRACE_EVENT0("ui", "WindowContainsPoint"); gfx::Rect window_rect; if (!GetWindowRect(window, &window_rect)) return false; if (!window_rect.Contains(screen_loc)) return false; if (!IsShapeExtensionAvailable()) return true; // According to http://www.x.org/releases/X11R7.6/doc/libXext/shapelib.html, // if an X display supports the shape extension the bounds of a window are // defined as the intersection of the window bounds and the interior // rectangles. This means to determine if a point is inside a window for the // purpose of input handling we have to check the rectangles in the ShapeInput // list. // According to http://www.x.org/releases/current/doc/xextproto/shape.html, // we need to also respect the ShapeBounding rectangles. // The effective input region of a window is defined to be the intersection // of the client input region with both the default input region and the // client bounding region. Any portion of the client input region that is not // included in both the default input region and the client bounding region // will not be included in the effective input region on the screen. int rectangle_kind[] = {ShapeInput, ShapeBounding}; for (size_t kind_index = 0; kind_index < arraysize(rectangle_kind); kind_index++) { int dummy; int shape_rects_size = 0; XRectangle* shape_rects = XShapeGetRectangles(gfx::GetXDisplay(), window, rectangle_kind[kind_index], &shape_rects_size, &dummy); if (!shape_rects) { // The shape is empty. This can occur when |window| is minimized. DCHECK_EQ(0, shape_rects_size); return false; } bool is_in_shape_rects = false; for (int i = 0; i < shape_rects_size; ++i) { // The ShapeInput and ShapeBounding rects are to be in window space, so we // have to translate by the window_rect's offset to map to screen space. gfx::Rect shape_rect = gfx::Rect(shape_rects[i].x + window_rect.x(), shape_rects[i].y + window_rect.y(), shape_rects[i].width, shape_rects[i].height); if (shape_rect.Contains(screen_loc)) { is_in_shape_rects = true; break; } } XFree(shape_rects); if (!is_in_shape_rects) return false; } return true; } bool PropertyExists(XID window, const std::string& property_name) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* property = NULL; int result = GetProperty(window, property_name, 1, &type, &format, &num_items, &property); if (result != Success) return false; XFree(property); return num_items > 0; } bool GetRawBytesOfProperty(XID window, XAtom property, scoped_refptr* out_data, size_t* out_data_items, XAtom* out_type) { // Retrieve the data from our window. unsigned long nitems = 0; unsigned long nbytes = 0; XAtom prop_type = None; int prop_format = 0; unsigned char* property_data = NULL; if (XGetWindowProperty(gfx::GetXDisplay(), window, property, 0, 0x1FFFFFFF /* MAXINT32 / 4 */, False, AnyPropertyType, &prop_type, &prop_format, &nitems, &nbytes, &property_data) != Success) { return false; } if (prop_type == None) return false; size_t bytes = 0; // So even though we should theoretically have nbytes (and we can't // pass NULL there), we need to manually calculate the byte length here // because nbytes always returns zero. switch (prop_format) { case 8: bytes = nitems; break; case 16: bytes = sizeof(short) * nitems; break; case 32: bytes = sizeof(long) * nitems; break; default: NOTREACHED(); break; } if (out_data) *out_data = new XRefcountedMemory(property_data, bytes); else XFree(property_data); if (out_data_items) *out_data_items = nitems; if (out_type) *out_type = prop_type; return true; } bool GetIntProperty(XID window, const std::string& property_name, int* value) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* property = NULL; int result = GetProperty(window, property_name, 1, &type, &format, &num_items, &property); if (result != Success) return false; if (format != 32 || num_items != 1) { XFree(property); return false; } *value = static_cast(*(reinterpret_cast(property))); XFree(property); return true; } bool GetXIDProperty(XID window, const std::string& property_name, XID* value) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* property = NULL; int result = GetProperty(window, property_name, 1, &type, &format, &num_items, &property); if (result != Success) return false; if (format != 32 || num_items != 1) { XFree(property); return false; } *value = *(reinterpret_cast(property)); XFree(property); return true; } bool GetIntArrayProperty(XID window, const std::string& property_name, std::vector* value) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* properties = NULL; int result = GetProperty(window, property_name, (~0L), // (all of them) &type, &format, &num_items, &properties); if (result != Success) return false; if (format != 32) { XFree(properties); return false; } long* int_properties = reinterpret_cast(properties); value->clear(); for (unsigned long i = 0; i < num_items; ++i) { value->push_back(static_cast(int_properties[i])); } XFree(properties); return true; } bool GetAtomArrayProperty(XID window, const std::string& property_name, std::vector* value) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* properties = NULL; int result = GetProperty(window, property_name, (~0L), // (all of them) &type, &format, &num_items, &properties); if (result != Success) return false; if (type != XA_ATOM) { XFree(properties); return false; } XAtom* atom_properties = reinterpret_cast(properties); value->clear(); value->insert(value->begin(), atom_properties, atom_properties + num_items); XFree(properties); return true; } bool GetStringProperty( XID window, const std::string& property_name, std::string* value) { XAtom type = None; int format = 0; // size in bits of each item in 'property' unsigned long num_items = 0; unsigned char* property = NULL; int result = GetProperty(window, property_name, 1024, &type, &format, &num_items, &property); if (result != Success) return false; if (format != 8) { XFree(property); return false; } value->assign(reinterpret_cast(property), num_items); XFree(property); return true; } bool SetIntProperty(XID window, const std::string& name, const std::string& type, int value) { std::vector values(1, value); return SetIntArrayProperty(window, name, type, values); } bool SetIntArrayProperty(XID window, const std::string& name, const std::string& type, const std::vector& value) { DCHECK(!value.empty()); XAtom name_atom = GetAtom(name.c_str()); XAtom type_atom = GetAtom(type.c_str()); // XChangeProperty() expects values of type 32 to be longs. scoped_ptr data(new long[value.size()]); for (size_t i = 0; i < value.size(); ++i) data[i] = value[i]; gfx::X11ErrorTracker err_tracker; XChangeProperty(gfx::GetXDisplay(), window, name_atom, type_atom, 32, // size in bits of items in 'value' PropModeReplace, reinterpret_cast(data.get()), value.size()); // num items return !err_tracker.FoundNewError(); } bool SetAtomProperty(XID window, const std::string& name, const std::string& type, XAtom value) { std::vector values(1, value); return SetAtomArrayProperty(window, name, type, values); } bool SetAtomArrayProperty(XID window, const std::string& name, const std::string& type, const std::vector& value) { DCHECK(!value.empty()); XAtom name_atom = GetAtom(name.c_str()); XAtom type_atom = GetAtom(type.c_str()); // XChangeProperty() expects values of type 32 to be longs. scoped_ptr data(new XAtom[value.size()]); for (size_t i = 0; i < value.size(); ++i) data[i] = value[i]; gfx::X11ErrorTracker err_tracker; XChangeProperty(gfx::GetXDisplay(), window, name_atom, type_atom, 32, // size in bits of items in 'value' PropModeReplace, reinterpret_cast(data.get()), value.size()); // num items return !err_tracker.FoundNewError(); } bool SetStringProperty(XID window, XAtom property, XAtom type, const std::string& value) { gfx::X11ErrorTracker err_tracker; XChangeProperty(gfx::GetXDisplay(), window, property, type, 8, PropModeReplace, reinterpret_cast(value.c_str()), value.size()); return !err_tracker.FoundNewError(); } XAtom GetAtom(const char* name) { // TODO(derat): Cache atoms to avoid round-trips to the server. return XInternAtom(gfx::GetXDisplay(), name, false); } void SetWindowClassHint(XDisplay* display, XID window, const std::string& res_name, const std::string& res_class) { XClassHint class_hints; // const_cast is safe because XSetClassHint does not modify the strings. // Just to be safe, the res_name and res_class parameters are local copies, // not const references. class_hints.res_name = const_cast(res_name.c_str()); class_hints.res_class = const_cast(res_class.c_str()); XSetClassHint(display, window, &class_hints); } void SetWindowRole(XDisplay* display, XID window, const std::string& role) { if (role.empty()) { XDeleteProperty(display, window, GetAtom("WM_WINDOW_ROLE")); } else { char* role_c = const_cast(role.c_str()); XChangeProperty(display, window, GetAtom("WM_WINDOW_ROLE"), XA_STRING, 8, PropModeReplace, reinterpret_cast(role_c), role.size()); } } bool GetCustomFramePrefDefault() { // Ideally, we'd use the custom frame by default and just fall back on using // system decorations for the few (?) tiling window managers where the custom // frame doesn't make sense (e.g. awesome, ion3, ratpoison, xmonad, etc.) or // other WMs where it has issues (e.g. Fluxbox -- see issue 19130). The EWMH // _NET_SUPPORTING_WM property makes it easy to look up a name for the current // WM, but at least some of the WMs in the latter group don't set it. // Instead, we default to using system decorations for all WMs and // special-case the ones where the custom frame should be used. ui::WindowManagerName wm_type = GuessWindowManager(); return (wm_type == WM_BLACKBOX || wm_type == WM_COMPIZ || wm_type == WM_ENLIGHTENMENT || wm_type == WM_METACITY || wm_type == WM_MUFFIN || wm_type == WM_MUTTER || wm_type == WM_OPENBOX || wm_type == WM_XFWM4); } bool GetWindowDesktop(XID window, int* desktop) { return GetIntProperty(window, "_NET_WM_DESKTOP", desktop); } std::string GetX11ErrorString(XDisplay* display, int err) { char buffer[256]; XGetErrorText(display, err, buffer, arraysize(buffer)); return buffer; } // Returns true if |window| is a named window. bool IsWindowNamed(XID window) { XTextProperty prop; if (!XGetWMName(gfx::GetXDisplay(), window, &prop) || !prop.value) return false; XFree(prop.value); return true; } bool EnumerateChildren(EnumerateWindowsDelegate* delegate, XID window, const int max_depth, int depth) { if (depth > max_depth) return false; std::vector windows; std::vector::iterator iter; if (depth == 0) { XMenuList::GetInstance()->InsertMenuWindowXIDs(&windows); // Enumerate the menus first. for (iter = windows.begin(); iter != windows.end(); iter++) { if (delegate->ShouldStopIterating(*iter)) return true; } windows.clear(); } XID root, parent, *children; unsigned int num_children; int status = XQueryTree(gfx::GetXDisplay(), window, &root, &parent, &children, &num_children); if (status == 0) return false; for (int i = static_cast(num_children) - 1; i >= 0; i--) windows.push_back(children[i]); XFree(children); // XQueryTree returns the children of |window| in bottom-to-top order, so // reverse-iterate the list to check the windows from top-to-bottom. for (iter = windows.begin(); iter != windows.end(); iter++) { if (IsWindowNamed(*iter) && delegate->ShouldStopIterating(*iter)) return true; } // If we're at this point, we didn't find the window we're looking for at the // current level, so we need to recurse to the next level. We use a second // loop because the recursion and call to XQueryTree are expensive and is only // needed for a small number of cases. if (++depth <= max_depth) { for (iter = windows.begin(); iter != windows.end(); iter++) { if (EnumerateChildren(delegate, *iter, max_depth, depth)) return true; } } return false; } bool EnumerateAllWindows(EnumerateWindowsDelegate* delegate, int max_depth) { XID root = GetX11RootWindow(); return EnumerateChildren(delegate, root, max_depth, 0); } void EnumerateTopLevelWindows(ui::EnumerateWindowsDelegate* delegate) { std::vector stack; if (!ui::GetXWindowStack(ui::GetX11RootWindow(), &stack)) { // Window Manager doesn't support _NET_CLIENT_LIST_STACKING, so fall back // to old school enumeration of all X windows. Some WMs parent 'top-level' // windows in unnamed actual top-level windows (ion WM), so extend the // search depth to all children of top-level windows. const int kMaxSearchDepth = 1; ui::EnumerateAllWindows(delegate, kMaxSearchDepth); return; } XMenuList::GetInstance()->InsertMenuWindowXIDs(&stack); std::vector::iterator iter; for (iter = stack.begin(); iter != stack.end(); iter++) { if (delegate->ShouldStopIterating(*iter)) return; } } bool GetXWindowStack(Window window, std::vector* windows) { windows->clear(); Atom type; int format; unsigned long count; unsigned char *data = NULL; if (GetProperty(window, "_NET_CLIENT_LIST_STACKING", ~0L, &type, &format, &count, &data) != Success) { return false; } bool result = false; if (type == XA_WINDOW && format == 32 && data && count > 0) { result = true; XID* stack = reinterpret_cast(data); for (long i = static_cast(count) - 1; i >= 0; i--) windows->push_back(stack[i]); } if (data) XFree(data); return result; } bool CopyAreaToCanvas(XID drawable, gfx::Rect source_bounds, gfx::Point dest_offset, gfx::Canvas* canvas) { ui::XScopedImage scoped_image( XGetImage(gfx::GetXDisplay(), drawable, source_bounds.x(), source_bounds.y(), source_bounds.width(), source_bounds.height(), AllPlanes, ZPixmap)); XImage* image = scoped_image.get(); if (!image) { LOG(ERROR) << "XGetImage failed"; return false; } if (image->bits_per_pixel == 32) { if ((0xff << SK_R32_SHIFT) != image->red_mask || (0xff << SK_G32_SHIFT) != image->green_mask || (0xff << SK_B32_SHIFT) != image->blue_mask) { LOG(WARNING) << "XImage and Skia byte orders differ"; return false; } // Set the alpha channel before copying to the canvas. Otherwise, areas of // the framebuffer that were cleared by ply-image rather than being obscured // by an image during boot may end up transparent. // TODO(derat|marcheu): Remove this if/when ply-image has been updated to // set the framebuffer's alpha channel regardless of whether the device // claims to support alpha or not. for (int i = 0; i < image->width * image->height * 4; i += 4) image->data[i + 3] = 0xff; SkBitmap bitmap; bitmap.installPixels(SkImageInfo::MakeN32Premul(image->width, image->height), image->data, image->bytes_per_line); gfx::ImageSkia image_skia; gfx::ImageSkiaRep image_rep(bitmap, canvas->image_scale()); image_skia.AddRepresentation(image_rep); canvas->DrawImageInt(image_skia, dest_offset.x(), dest_offset.y()); } else { NOTIMPLEMENTED() << "Unsupported bits-per-pixel " << image->bits_per_pixel; return false; } return true; } bool GetWindowManagerName(std::string* wm_name) { DCHECK(wm_name); int wm_window = 0; if (!GetIntProperty(GetX11RootWindow(), "_NET_SUPPORTING_WM_CHECK", &wm_window)) { return false; } // It's possible that a window manager started earlier in this X session left // a stale _NET_SUPPORTING_WM_CHECK property when it was replaced by a // non-EWMH window manager, so we trap errors in the following requests to // avoid crashes (issue 23860). // EWMH requires the supporting-WM window to also have a // _NET_SUPPORTING_WM_CHECK property pointing to itself (to avoid a stale // property referencing an ID that's been recycled for another window), so we // check that too. gfx::X11ErrorTracker err_tracker; int wm_window_property = 0; bool result = GetIntProperty( wm_window, "_NET_SUPPORTING_WM_CHECK", &wm_window_property); if (err_tracker.FoundNewError() || !result || wm_window_property != wm_window) { return false; } result = GetStringProperty( static_cast(wm_window), "_NET_WM_NAME", wm_name); return !err_tracker.FoundNewError() && result; } WindowManagerName GuessWindowManager() { std::string name; if (GetWindowManagerName(&name)) { // These names are taken from the WMs' source code. if (name == "Blackbox") return WM_BLACKBOX; if (name == "chromeos-wm") return WM_CHROME_OS; if (name == "Compiz" || name == "compiz") return WM_COMPIZ; if (name == "e16") return WM_ENLIGHTENMENT; if (StartsWithASCII(name, "IceWM", true)) return WM_ICE_WM; if (name == "KWin") return WM_KWIN; if (name == "Metacity") return WM_METACITY; if (name == "Mutter (Muffin)") return WM_MUFFIN; if (name == "GNOME Shell") return WM_MUTTER; // GNOME Shell uses Mutter if (name == "Mutter") return WM_MUTTER; if (name == "Openbox") return WM_OPENBOX; if (name == "Xfwm4") return WM_XFWM4; } return WM_UNKNOWN; } void SetDefaultX11ErrorHandlers() { SetX11ErrorHandlers(NULL, NULL); } bool IsX11WindowFullScreen(XID window) { // If _NET_WM_STATE_FULLSCREEN is in _NET_SUPPORTED, use the presence or // absence of _NET_WM_STATE_FULLSCREEN in _NET_WM_STATE to determine // whether we're fullscreen. XAtom fullscreen_atom = GetAtom("_NET_WM_STATE_FULLSCREEN"); if (WmSupportsHint(fullscreen_atom)) { std::vector atom_properties; if (GetAtomArrayProperty(window, "_NET_WM_STATE", &atom_properties)) { return std::find(atom_properties.begin(), atom_properties.end(), fullscreen_atom) != atom_properties.end(); } } gfx::Rect window_rect; if (!ui::GetWindowRect(window, &window_rect)) return false; // We can't use gfx::Screen here because we don't have an aura::Window. So // instead just look at the size of the default display. // // TODO(erg): Actually doing this correctly would require pulling out xrandr, // which we don't even do in the desktop screen yet. ::XDisplay* display = gfx::GetXDisplay(); ::Screen* screen = DefaultScreenOfDisplay(display); int width = WidthOfScreen(screen); int height = HeightOfScreen(screen); return window_rect.size() == gfx::Size(width, height); } bool WmSupportsHint(XAtom atom) { std::vector supported_atoms; if (!GetAtomArrayProperty(GetX11RootWindow(), "_NET_SUPPORTED", &supported_atoms)) { return false; } return std::find(supported_atoms.begin(), supported_atoms.end(), atom) != supported_atoms.end(); } const unsigned char* XRefcountedMemory::front() const { return x11_data_; } size_t XRefcountedMemory::size() const { return length_; } XRefcountedMemory::~XRefcountedMemory() { XFree(x11_data_); } XScopedString::~XScopedString() { XFree(string_); } XScopedImage::~XScopedImage() { reset(NULL); } void XScopedImage::reset(XImage* image) { if (image_ == image) return; if (image_) XDestroyImage(image_); image_ = image; } XScopedCursor::XScopedCursor(::Cursor cursor, XDisplay* display) : cursor_(cursor), display_(display) { } XScopedCursor::~XScopedCursor() { reset(0U); } ::Cursor XScopedCursor::get() const { return cursor_; } void XScopedCursor::reset(::Cursor cursor) { if (cursor_) XFreeCursor(display_, cursor_); cursor_ = cursor; } namespace test { void ResetXCursorCache() { delete cursor_cache; cursor_cache = NULL; } const XcursorImage* GetCachedXcursorImage(::Cursor cursor) { return XCustomCursorCache::GetInstance()->GetXcursorImage(cursor); } } // ---------------------------------------------------------------------------- // These functions are declared in x11_util_internal.h because they require // XLib.h to be included, and it conflicts with many other headers. XRenderPictFormat* GetRenderARGB32Format(XDisplay* dpy) { static XRenderPictFormat* pictformat = NULL; if (pictformat) return pictformat; // First look for a 32-bit format which ignores the alpha value XRenderPictFormat templ; templ.depth = 32; templ.type = PictTypeDirect; templ.direct.red = 16; templ.direct.green = 8; templ.direct.blue = 0; templ.direct.redMask = 0xff; templ.direct.greenMask = 0xff; templ.direct.blueMask = 0xff; templ.direct.alphaMask = 0; static const unsigned long kMask = PictFormatType | PictFormatDepth | PictFormatRed | PictFormatRedMask | PictFormatGreen | PictFormatGreenMask | PictFormatBlue | PictFormatBlueMask | PictFormatAlphaMask; pictformat = XRenderFindFormat(dpy, kMask, &templ, 0 /* first result */); if (!pictformat) { // Not all X servers support xRGB32 formats. However, the XRENDER spec says // that they must support an ARGB32 format, so we can always return that. pictformat = XRenderFindStandardFormat(dpy, PictStandardARGB32); CHECK(pictformat) << "XRENDER ARGB32 not supported."; } return pictformat; } void SetX11ErrorHandlers(XErrorHandler error_handler, XIOErrorHandler io_error_handler) { XSetErrorHandler(error_handler ? error_handler : DefaultX11ErrorHandler); XSetIOErrorHandler( io_error_handler ? io_error_handler : DefaultX11IOErrorHandler); } void LogErrorEventDescription(XDisplay* dpy, const XErrorEvent& error_event) { char error_str[256]; char request_str[256]; XGetErrorText(dpy, error_event.error_code, error_str, sizeof(error_str)); strncpy(request_str, "Unknown", sizeof(request_str)); if (error_event.request_code < 128) { std::string num = base::UintToString(error_event.request_code); XGetErrorDatabaseText( dpy, "XRequest", num.c_str(), "Unknown", request_str, sizeof(request_str)); } else { int num_ext; char** ext_list = XListExtensions(dpy, &num_ext); for (int i = 0; i < num_ext; i++) { int ext_code, first_event, first_error; XQueryExtension(dpy, ext_list[i], &ext_code, &first_event, &first_error); if (error_event.request_code == ext_code) { std::string msg = base::StringPrintf( "%s.%d", ext_list[i], error_event.minor_code); XGetErrorDatabaseText( dpy, "XRequest", msg.c_str(), "Unknown", request_str, sizeof(request_str)); break; } } XFreeExtensionList(ext_list); } LOG(WARNING) << "X error received: " << "serial " << error_event.serial << ", " << "error_code " << static_cast(error_event.error_code) << " (" << error_str << "), " << "request_code " << static_cast(error_event.request_code) << ", " << "minor_code " << static_cast(error_event.minor_code) << " (" << request_str << ")"; } // ---------------------------------------------------------------------------- // End of x11_util_internal.h } // namespace ui