OpenGL without X.org in linux

Question

I'd like to open an OpenGL context without X in Linux. Is there any way at all to do it?

I know it's possible for integrated Intel graphics card hardware, though most people have Nvidia cards in their system. I'd like to get a solution that works with Nvidia cards.

If there's no other way than through integrated Intel hardware, I guess it'd be okay to know how it's done with those.

X11 protocol itself is too large and complex. Mouse/Keyboard/Tablet input multiplexing it provides is too watered-down for modern programs. I think it's the worst roadblock that prevents Linux desktop from improving, which is why I look for alternatives.

Answer 1

Update (Sep. 17, 2017):

NVIDIA recently published an article detailing how to use OpenGL on headless systems, which is a very similar use case as the question describes.

In summary:

• Link to libOpenGL.so and libEGL.so instead of libGL.so. (Your linker options should therefore be -lOpenGL -lEGL
• Call eglGetDisplay, then eglInitialize to initialize EGL.
• Call eglChooseConfig with the config attribute EGL_SURFACE_TYPE followed with EGL_PBUFFER_BIT.
• Call eglCreatePbufferSurface, then eglBindApi(EGL_OPENGL_API);, then eglCreateContext and eglMakeCurrent.

From that point on, do your OpenGL rendering as usual, and you can blit your pixel buffer surface wherever you like. This supplementary article from NVIDIA includes a basic example and an example for multiple GPUs. The PBuffer surface can also be replaced with a window surface or pixmap surface, according to the application needs.

I regret not doing more research on this on my previous edit, but oh well. Better answers are better answers.

---

Since my answer in 2010, there have been a number of major shakeups in the Linux graphics space. So, an updated answer:

Today, nouveau and the other DRI drivers have matured to the point where OpenGL software is stable and performs reasonably well in general. With the introduction of the EGL API in Mesa, it's now possible to write OpenGL and OpenGL ES applications on even Linux desktops.

You can write your application to target EGL, and it can be run without the presence of a window manager or even a compositor. To do so, you would call eglGetDisplay, eglInitialize, and ultimately eglCreateContext and eglMakeCurrent, instead of the usual glx calls to do the same.

I do not know the specific code path for working without a display server, but EGL accepts both X11 displays and Wayland displays, and I do know it is possible for EGL to operate without one. You can create GL ES 1.1, ES 2.0, ES 3.0 (if you have Mesa 9.1 or later), and OpenGL 3.1 (Mesa 9.0 or later) contexts. Mesa has not (as of Sep. 2013) yet implemented OpenGL 3.2 Core.

Notably, on the Raspberry Pi and on Android, EGL and GL ES 2.0 (1.1 on Android < 3.0) are supported by default. On the Raspberry Pi, I don't think Wayland yet works (as of Sep. 2013), but you do get EGL without a display server using the included binary drivers. Your EGL code should also be portable (with minimal modification) to iOS, if that interests you.

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Below is the outdated, previously accepted post:

I'd like to open an OpenGL context without X in linux. Is there any way at all to do it?

I believe Mesa provides a framebuffer target. If it provides any hardware acceleration at all, it will only be with hardware for which there are open source drivers that have been adapted to support such a use.

Gallium3D is also immature, and support for this isn't even on the roadmap, as far as I know.

I'd like to get a solution that works with nvidia cards.

There isn't one. Period.

NVIDIA only provides an X driver, and the Nouveau project is still immature, and doesn't support the kind of use that you're looking for, as they are currently focused only on the X11 driver.

Answer 2

You might be interested in a project called Wayland

http://en.wikipedia.org/wiki/Wayland_%28display_server%29

Answer 3

Have you looked at this page? http://virtuousgeek.org/blog/index.php/jbarnes/2011/10/31/writing_stanalone_programs_with_egl_and_

It is likely a bit outdated. I haven't tried yet, but I would appreciate more documentation of this type.

Probably a good idea, as of today, is to follow Wayland compositor-drm.c implementation: http://cgit.freedesktop.org/wayland/weston/tree/src/compositor-drm.c

Answer 4

https://gitlab.freedesktop.org/mesa/kmscube/ is a good a reference implementation of OGL (or OGLES) hardware-accelerated rendering without an X11 or wayland dependency.

Answer 5

You can look at how Android has solved this issues. See Android-x86 project.

Android uses mesa with egl and opengles. Android has its own simple Gralloc component for mode setting and graphic allocations. On top of that they have SurfaceFlinger component which is a composition engine, which uses OpenGLES for acceleration.

Cannot see why couldn't you use these components in similar way and even reuse the Android glue code.

Answer 6

You could use the SRM library (Simple Rendering Manager), which is a C library designed for rendering using OpenGL ES 2.0 within a KMS/DRM context (no Xorg or Wayland needed). One of its significant advantages is that it streamlines all DRM/KMS configurations for you. Additionally, it facilitates the sharing of OpenGL textures between GPUs in a multi-GPU setup from a single allocation.

It has been tested on Intel GPUs (i915 driver), Nvidia GPUs (nouveau and nvidia-drm drivers) and in Mali GPUs (Lima driver)

Here's a basic example which simply changes the screen color of all connected screens using glClear():

#include <SRMCore.h>
#include <SRMDevice.h>
#include <SRMConnector.h>
#include <SRMConnectorMode.h>
#include <SRMListener.h>

#include <SRMList.h>
#include <SRMLog.h>

#include <GLES2/gl2.h>

#include <math.h>
#include <fcntl.h>
#include <unistd.h>

float color = 0.f;

/* Opens a DRM device */
static int openRestricted(const char *path, int flags, void *userData)
{
    SRM_UNUSED(userData);

    // Here something like libseat could be used instead
    return open(path, flags);
}

/* Closes a DRM device */
static void closeRestricted(int fd, void *userData)
{
    SRM_UNUSED(userData);
    close(fd);
}

static SRMInterface srmInterface =
{
    .openRestricted = &openRestricted,
    .closeRestricted = &closeRestricted
};

static void initializeGL(SRMConnector *connector, void *userData)
{
    SRM_UNUSED(userData);

    /* You must not do any drawing here as it won't make it to
     * the screen. */

    SRMConnectorMode *mode = srmConnectorGetCurrentMode(connector);

    glViewport(0, 
               0, 
               srmConnectorModeGetWidth(mode), 
               srmConnectorModeGetHeight(mode));

    // Schedule a repaint (this eventually calls paintGL() later, not directly)
    srmConnectorRepaint(connector);
}

static void paintGL(SRMConnector *connector, void *userData)
{
    SRM_UNUSED(userData);

    glClearColor((sinf(color) + 1.f) / 2.f,
                 (sinf(color * 0.5f) + 1.f) / 2.f,
                 (sinf(color * 0.25f) + 1.f) / 2.f,
                 1.f);

    color += 0.01f;

    if (color > M_PI*4.f)
        color = 0.f;

    glClear(GL_COLOR_BUFFER_BIT);
    srmConnectorRepaint(connector);
}

static void resizeGL(SRMConnector *connector, void *userData)
{
    /* You must not do any drawing here as it won't make it to
     * the screen.
     * This is called when the connector changes its current mode,
     * set with srmConnectorSetMode() */

    // Reuse initializeGL() as it only sets the viewport
    initializeGL(connector, userData);
}

static void pageFlipped(SRMConnector *connector, void *userData)
{
    SRM_UNUSED(connector);
    SRM_UNUSED(userData);

    /* You must not do any drawing here as it won't make it to
     * the screen.
     * This is called when the last rendered frame is now being
     * displayed on screen.
     * Google v-sync for more info. */
}

static void uninitializeGL(SRMConnector *connector, void *userData)
{
    SRM_UNUSED(connector);
    SRM_UNUSED(userData);

    /* You must not do any drawing here as it won't make it to
     * the screen.
     * Here you should free any resource created on initializeGL()
     * like shaders, programs, textures, etc. */
}

static SRMConnectorInterface connectorInterface =
{
    .initializeGL = &initializeGL,
    .paintGL = &paintGL,
    .resizeGL = &resizeGL,
    .pageFlipped = &pageFlipped,
    .uninitializeGL = &uninitializeGL
};

static void connectorPluggedEventHandler(SRMListener *listener, SRMConnector *connector)
{
    SRM_UNUSED(listener);

    /* This is called when a new connector is avaliable (E.g. Plugging an HDMI display). */

    /* Got a new connector, let's render on it */
    if (!srmConnectorInitialize(connector, &connectorInterface, NULL))
        SRMError("[srm-basic] Failed to initialize connector %s.",
                 srmConnectorGetModel(connector));
}

static void connectorUnpluggedEventHandler(SRMListener *listener, SRMConnector *connector)
{
    SRM_UNUSED(listener);
    SRM_UNUSED(connector);

    /* This is called when a connector is no longer avaliable (E.g. Unplugging an HDMI display). */

    /* The connnector is automatically uninitialized after this event (if initialized)
     * so calling srmConnectorUninitialize() is a no-op. */
}

int main(void)
{
    SRMCore *core = srmCoreCreate(&srmInterface, NULL);

    if (!core)
    {
        SRMFatal("[srm-basic] Failed to initialize SRM core.");
        return 1;
    }

    // Subscribe to Udev events
    SRMListener *connectorPluggedEventListener = srmCoreAddConnectorPluggedEventListener(core, &connectorPluggedEventHandler, NULL);
    SRMListener *connectorUnpluggedEventListener = srmCoreAddConnectorUnpluggedEventListener(core, &connectorUnpluggedEventHandler, NULL);

    // Find and initialize avaliable connectors

    // Loop each GPU (device)
    SRMListForeach (deviceIt, srmCoreGetDevices(core))
    {
        SRMDevice *device = srmListItemGetData(deviceIt);

        // Loop each GPU connector (screen)
        SRMListForeach (connectorIt, srmDeviceGetConnectors(device))
        {
            SRMConnector *connector = srmListItemGetData(connectorIt);

            if (srmConnectorIsConnected(connector))
            {
                if (!srmConnectorInitialize(connector, &connectorInterface, NULL))
                    SRMError("[srm-basic] Failed to initialize connector %s.",
                             srmConnectorGetModel(connector));
            }
        }
    }

    while (1)
    {
        /* Udev monitor poll DRM devices/connectors hotplugging events (-1 disables timeout).
         * To get a pollable FD use srmCoreGetMonitorFD() */

        if (srmCoreProccessMonitor(core, -1) < 0)
            break;
    }

    /* Unsubscribe to DRM events
     *
     * These listeners are automatically destroyed when calling srmCoreDestroy()
     * so there is no need to free them manually.
     * This is here just to show how to unsubscribe to events on the fly. */

    srmListenerDestroy(connectorPluggedEventListener);
    srmListenerDestroy(connectorUnpluggedEventListener);

    // Finish SRM
    srmCoreDestroy(core);

    return 0;
}

1. Start by creating an SRMCore instance.
2. Then, iterate through each SRMDevice (GPU). Each GPU has a list of SRMConnectors (displays).
3. Initialize the connectors you want using srmConnectorInitialize().
4. The library creates a rendering thread for each connector, and it invokes typical OpenGL events like initializeGL(), paintGL(), resizeGL(), etc.
5. To schedule a new repaint in a connector, use srmConnectorRepaint().
6. If you need to create OpenGL textures, refer to the SRMBuffer documentation.

I hope you find this library useful for your specific use case.