qubes-doc/developer/system/gui.md
2024-04-26 08:00:00 +00:00

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61 GUI virtualization

qubes-gui and qubes-guid processes

All AppVM X applications connect to local (running in AppVM) Xorg servers that use the following "hardware" drivers:

  • dummyqsb_drv - video driver, that paints onto a framebuffer located in RAM, not connected to real hardware
  • qubes_drv - it provides a virtual keyboard and mouse (in fact, more, see below)

For each AppVM, there is a pair of qubes-gui (running in AppVM) and qubes-guid (running in the AppVMs GuiVM, dom0 by default) processes connected over vchan. The main responsibilities of qubes-gui are:

  • call XCompositeRedirectSubwindows on the root window, so that each window has its own composition buffer
  • instruct the local Xorg server to notify it about window creation, configuration and damage events; pass information on these events to dom0
  • receive information about keyboard and mouse events from dom0, tell qubes-drv to fake appropriate events
  • receive information about window size/position change, apply them to the local window

The main responsibilities of qubes-guid are:

  • create a window in dom0 whenever an information on window creation in AppVM is received from qubes-gui
  • whenever the local window receives XEvent, pass information on it to AppVM (particularly, mouse and keyboard data)
  • whenever AppVM signals damage event, tell local Xorg server to repaint a given window fragment
  • receive information about window size/position change, apply them to the local window

Note that keyboard and mouse events are passed to AppVM only if a window belonging to this AppVM has focus. AppVM has no way to get information on keystrokes fed to other AppVMs (e.g. XTEST extension will report the status of local AppVM keyboard only) or synthesize and pass events to other AppVMs.

Window content updates implementation

Typical remote desktop applications, like VNC, pass information on all changed window content in-band (say, over tcp). As that channel has limited throughput, this impacts video performance. In the case of Qubes, qubes-gui does not transfer all changed pixels via vchan. Instead, for each window, upon its creation or size change:

  • Old qubes-gui versions will ask qubes-drv driver for the list of physical memory frames that hold the composition buffer of a window, and pass this to dom0 via the deprecated MFNDUMP message.
  • New qubes-gui versions will rely on qubes-drv having allocated memory using gntalloc, and then pass the grant table indexes gntalloc has chosen to the GUI daemon using the WINDOW_DUMP message.

Now, qubes-guid has to tell the dom0 Xorg server about the location of the buffer. There is no supported way (e.g. Xorg extension) to do this zero-copy style. The following method is used in Qubes:

  • in dom0, the Xorg server is started with LD_PRELOAD-ed library named shmoverride.so. This library hooks all function calls related to shared memory.
  • qubes-guid creates a shared memory segment, and then tells Xorg to attach it via MIT-SHM extension
  • when Xorg tries to attach the segment (via glibc shmat) shmoverride.so intercepts this call and instead maps AppVM memory via xc_map_foreign_pages for the deprecated MFNDUMP message, or xengnttab_map_domain_grant_refs for the WINDOW_DUMP message.
  • afterwards, we can use MIT-SHM functions, such as XShmPutImage, to draw onto a dom0 window. XShmPutImage will paint with DRAM speed, and many drivers use DMA to make this even faster.

The important detail is that xc_map_foreign_pages verifies that a given mfn range actually belongs to a given domain id (and the latter is provided by trusted qubes-guid). Therefore, rogue AppVM cannot gain anything by passing crafted mnfs in the MFNDUMP message. Similarly, xengnttab_map_domain_grant_refs will only map grants from the specific domain ID specified by qubes-guid, so crafted WINDOW_DUMP messages are not helpful to an attacker.

To sum up, this solution has the following benefits:

  • window updates at DRAM speed
  • no changes to Xorg code
  • minimal size of the supporting code

There are two reasons that WINDOW_DUMP is preferred over MFNDUMP:

  1. xc_map_foreign_pages can only be used by dom0, as it allows accessing all memory of any VM. Allowing any VM other than dom0 to do this would be a security vulnerability.
  2. xc_map_foreign_pages requires the guest physical address of the pages to map, but normal userspace processes (such as qubes-gui or Xorg) do not have access to that information. Therefore, the translation is done via the u2mfn out-of-tree kernel module.

Currently, using WINDOW_DUMP does come at a performance cost, because the AppVMs X server must copy the pages from the application to the gntalloc-allocated memory. This will be solved by future improvements to gntalloc, which will allow exporting any page via gntalloc, including memory shared by another process.

gui.png

Security markers on dom0 windows

It is important that the user knows which AppVM a given window belongs to. This prevents a rogue AppVM from painting a window pretending to belong to other AppVM or dom0 and trying to steal, for example, passwords.

In Qubes, a custom window decorator is used that paints a colourful frame (the colour is determined during AppVM creation) around decorated windows. Additionally, the window title always starts with [name of the AppVM]. If a window has an override_redirect attribute, meaning that it should not be treated by a window manager (typical case is menu windows), qubes-guid draws a two-pixel colourful frame inside it manually.

Clipboard sharing implementation

Certainly, it would be insecure to allow AppVM to read/write the clipboards of other AppVMs unconditionally. Therefore, the following mechanism is used:

  • there is a "qubes clipboard" in dom0 - its contents are stored in a regular file in dom0.
  • if the user wants to copy local AppVM clipboard to qubes clipboard, she must focus on any window belonging to this AppVM, and press Ctrl-Shift-C. This combination is trapped by qubes-guid, and CLIPBOARD_REQ message is sent to AppVM. qubes-gui responds with CLIPBOARD_DATA message followed by clipboard contents.
  • the user focuses on other AppVM window, presses Ctrl-Shift-V. This combination is trapped by qubes-guid, and CLIPBOARD_DATA message followed by qubes clipboard contents is sent to AppVM; qubes-gui copies data to the local clipboard, and then user can paste its contents to local applications normally.

This way, the user can quickly copy clipboards between AppVMs. This action is fully controlled by the user, it cannot be triggered/forced by any AppVM.

qubes-gui and qubes-guid code notes

Both applications are structured similarly. They use select function to wait for any of these two event sources:

  • messages from the local X server
  • messages from the vchan connecting to the remote party

The XEvents are handled by the handle_xevent_eventname function, and messages are handled by handle_messagename function. One should be very careful when altering the actual select loop, because both XEvents and vchan messages are buffered, and select will not wake for each message.

If one changes the number/order/signature of messages, one should increase the QUBES_GUID_PROTOCOL_VERSION constant in messages.h include file.

qubes-guid writes debugging information to /var/log/qubes/qubes.domain_id.log file; qubes-gui writes debugging information to /var/log/qubes/gui_agent.log. Include these files when reporting a bug.

AppVM -> GuiVM messages

Proper handling of the below messages is security-critical. Note that all messages except for CLIPBOARD, MFNDUMP, and WINDOW_DUMP have fixed size, so the parsing code can be small.

The override_redirect window attribute is explained at Override Redirect Flag. The transient_for attribute is explained at transient_for attribute.

Window manager hints and flags are described in the Extended Window Manager Hints (EWMH) spec, especially under the _NET_WM_STATE section.

Each message starts with the following header:

struct msghdr {
    uint32_t type;
    uint32_t window;
    /* This field is intended for use by GUI agents to skip unknown
     * messages from the (trusted) GUI daemon. GUI daemon, on the other
     * hand, should never rely on this field to calculate the actual len
     * of message to be read, as the (untrusted) agent can put whatever
     * it wants here! */
    uint32_t untrusted_len;
};

This header is followed by message-specific data:

Message name Structure after header Action
MSG_CLIPBOARD_DATA amorphic blob (in protocol before 1.2, length determined by the "window" field, in 1.2 and later - by untrusted_len in the header) Store the received clipboard content (not parsed in any way)
MSG_CREATE
struct msg_create {
  uint32_t x;
  uint32_t y;
  uint32_t width;
  uint32_t height;
  uint32_t parent;
  uint32_t override_redirect;
};
Create a window with given parameters
MSG_DESTROY None Destroy a window
MSG_MAP
struct msg_map_info {
  uint32_t transient_for;
  uint32_t override_redirect;
};
Map a window with given parameters
MSG_UNMAP None Unmap a window
MSG_CONFIGURE
struct msg_configure {
  uint32_t x;
  uint32_t y;
  uint32_t width;
  uint32_t height;
  uint32_t override_redirect;
};
Change window position/size/type
MSG_MFNDUMP
struct shm_cmd {
  uint32_t shmid;
  uint32_t width;
  uint32_t height;
  uint32_t bpp;
  uint32_t off;
  uint32_t num_mfn;
  uint32_t domid;
  uint32_t mfns[0];
};
Retrieve the array of mfns that constitute the composition buffer of a remote window.

The "num_mfn" 32bit integers follow the shm_cmd structure; "off" is the offset of the composite buffer start in the first frame; "shmid" and "domid" parameters are just placeholders (to be filled by qubes-guid), so that we can use the same structure when talking to shmoverride.so.

MSG_SHMIMAGE
struct msg_shmimage {
     uint32_t x;
     uint32_t y;
     uint32_t width;
     uint32_t height;
};
Repaint the given window fragment
MSG_WMNAME
struct msg_wmname {
  char data[128];
};
Set the window name. Only printable characters are allowed, and by default non-ASCII characters are not allowed.
MSG_DOCK None Dock the window in the tray
MSG_WINDOW_HINTS
struct msg_window_hints {
     uint32_t flags;
     uint32_t min_width;
     uint32_t min_height;
     uint32_t max_width;
     uint32_t max_height;
     uint32_t width_inc;
     uint32_t height_inc;
     uint32_t base_width;
     uint32_t base_height;
};
Size hints for window manager
MSG_WINDOW_FLAGS
struct msg_window_flags {
     uint32_t flags_set;
     uint32_t flags_unset;
};
Change window state request; fields contains bitmask which flags request to be set and which unset
MSG_CURSOR
struct msg_cursor {
     uint32_t cursor;
};
Update cursor pointer for a window. Supported cursor IDs are default cursor (0) and X Font cursors (with 0x100 bit set).
MSG_WMCLASS
struct msg_wmclass {
    char res_class[64];
    char res_name[64];
};
Set the WM_CLASS property of a window.
MSG_WINDOW_DUMP
struct msg_window_dump_hdr {
    uint32_t type;
    uint32_t width;
    uint32_t height;
    uint32_t bpp;
};
Header for shared memory dump command of type hdr.type. Currently only
WINDOW_DUMP_TYPE_GRANT_REFS
(0) is supported.
WINDOW_DUMP_TYPE_GRANT_REFS
struct msg_window_dump_grant_refs {
    uint32_t refs[0];
};
Grant references that should be mapped into the compositing buffer.

GuiVM -> AppVM messages

Proper handling of the below messages is NOT security-critical.

Each message starts with the following header

struct msghdr {
        uint32_t type;
        uint32_t window;
};

The header is followed by message-specific data:

Message name Structure after header Action
MSG_KEYPRESS
struct msg_keypress {
  uint32_t type;
  uint32_t x;
  uint32_t y;
  uint32_t state;
  uint32_t keycode;
};
Tell
qubes_drv
driver to generate a keypress
MSG_BUTTON
struct msg_button {
  uint32_t type;
  uint32_t x;
  uint32_t y;
  uint32_t state;
  uint32_t button;
};
Tell
qubes_drv
driver to generate mouseclick
MSG_MOTION
struct msg_motion {
  uint32_t x;
  uint32_t y;
  uint32_t state;
  uint32_t is_hint;
};
Tell
qubes_drv
driver to generate motion event
MSG_CONFIGURE
struct msg_configure {
  uint32_t x;
  uint32_t y;
  uint32_t width;
  uint32_t height;
  uint32_t override_redirect;
};
Change window position/size/type
MSG_MAP
struct msg_map_info {
  uint32_t transient_for;
  uint32_t override_redirect;
};
Map a window with given parameters
MSG_CLOSE None send wmDeleteMessage to the window
MSG_CROSSING
struct msg_crossing {
  uint32_t type;
  uint32_t x;
  uint32_t y;
  uint32_t state;
  uint32_t mode;
  uint32_t detail;
  uint32_t focus;
};
Notify window about enter/leave event
MSG_FOCUS
struct msg_focus {
  uint32_t type;
  uint32_t mode;
  uint32_t detail;
};
Raise a window, XSetInputFocus
MSG_CLIPBOARD_REQ None Retrieve the local clipboard, pass contents to gui-daemon
MSG_CLIPBOARD_DATA amorphic blob Insert the received data into local clipboard
MSG_EXECUTE Obsolete Obsolete, unused
MSG_KEYMAP_NOTIFY unsigned char remote_keys[32]; Synchronize the keyboard state (key pressed/released) with dom0
MSG_WINDOW_FLAGS
struct msg_window_flags {
  uint32_t flags_set;
  uint32_t flags_unset;
};
Window state change confirmation

KEYPRESS, BUTTON, MOTION, FOCUS messages pass information extracted from dom0 XEvent; see appropriate event documentation.