forked from Minki/linux
5d070be683
Accidentally the wrong file. Oops. Reviewed-by: Sean Paul <seanpaul@chromium.org> Signed-off-by: Daniel Vetter <daniel.vetter@ffwll.ch> Link: http://patchwork.freedesktop.org/patch/msgid/1471034937-651-10-git-send-email-daniel.vetter@ffwll.ch
642 lines
25 KiB
ReStructuredText
642 lines
25 KiB
ReStructuredText
=========================
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Kernel Mode Setting (KMS)
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=========================
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Drivers must initialize the mode setting core by calling
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:c:func:`drm_mode_config_init()` on the DRM device. The function
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initializes the :c:type:`struct drm_device <drm_device>`
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mode_config field and never fails. Once done, mode configuration must
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be setup by initializing the following fields.
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- int min_width, min_height; int max_width, max_height;
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Minimum and maximum width and height of the frame buffers in pixel
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units.
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- struct drm_mode_config_funcs \*funcs;
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Mode setting functions.
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KMS Data Structures
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===================
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.. kernel-doc:: include/drm/drm_crtc.h
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:internal:
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KMS API Functions
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=================
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.. kernel-doc:: drivers/gpu/drm/drm_crtc.c
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:export:
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Atomic Mode Setting Function Reference
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======================================
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.. kernel-doc:: drivers/gpu/drm/drm_atomic.c
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:export:
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.. kernel-doc:: include/drm/drm_atomic.h
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:internal:
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Frame Buffer Abstraction
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========================
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Frame buffers are abstract memory objects that provide a source of
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pixels to scanout to a CRTC. Applications explicitly request the
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creation of frame buffers through the DRM_IOCTL_MODE_ADDFB(2) ioctls
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and receive an opaque handle that can be passed to the KMS CRTC control,
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plane configuration and page flip functions.
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Frame buffers rely on the underneath memory manager for low-level memory
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operations. When creating a frame buffer applications pass a memory
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handle (or a list of memory handles for multi-planar formats) through
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the ``drm_mode_fb_cmd2`` argument. For drivers using GEM as their
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userspace buffer management interface this would be a GEM handle.
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Drivers are however free to use their own backing storage object
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handles, e.g. vmwgfx directly exposes special TTM handles to userspace
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and so expects TTM handles in the create ioctl and not GEM handles.
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The lifetime of a drm framebuffer is controlled with a reference count,
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drivers can grab additional references with
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:c:func:`drm_framebuffer_reference()`and drop them again with
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:c:func:`drm_framebuffer_unreference()`. For driver-private
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framebuffers for which the last reference is never dropped (e.g. for the
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fbdev framebuffer when the struct :c:type:`struct drm_framebuffer
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<drm_framebuffer>` is embedded into the fbdev helper struct)
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drivers can manually clean up a framebuffer at module unload time with
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:c:func:`drm_framebuffer_unregister_private()`.
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DRM Format Handling
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===================
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.. kernel-doc:: drivers/gpu/drm/drm_fourcc.c
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:export:
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Dumb Buffer Objects
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===================
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The KMS API doesn't standardize backing storage object creation and
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leaves it to driver-specific ioctls. Furthermore actually creating a
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buffer object even for GEM-based drivers is done through a
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driver-specific ioctl - GEM only has a common userspace interface for
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sharing and destroying objects. While not an issue for full-fledged
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graphics stacks that include device-specific userspace components (in
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libdrm for instance), this limit makes DRM-based early boot graphics
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unnecessarily complex.
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Dumb objects partly alleviate the problem by providing a standard API to
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create dumb buffers suitable for scanout, which can then be used to
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create KMS frame buffers.
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To support dumb objects drivers must implement the dumb_create,
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dumb_destroy and dumb_map_offset operations.
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- int (\*dumb_create)(struct drm_file \*file_priv, struct
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drm_device \*dev, struct drm_mode_create_dumb \*args);
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The dumb_create operation creates a driver object (GEM or TTM
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handle) suitable for scanout based on the width, height and depth
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from the struct :c:type:`struct drm_mode_create_dumb
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<drm_mode_create_dumb>` argument. It fills the argument's
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handle, pitch and size fields with a handle for the newly created
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object and its line pitch and size in bytes.
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- int (\*dumb_destroy)(struct drm_file \*file_priv, struct
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drm_device \*dev, uint32_t handle);
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The dumb_destroy operation destroys a dumb object created by
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dumb_create.
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- int (\*dumb_map_offset)(struct drm_file \*file_priv, struct
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drm_device \*dev, uint32_t handle, uint64_t \*offset);
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The dumb_map_offset operation associates an mmap fake offset with
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the object given by the handle and returns it. Drivers must use the
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:c:func:`drm_gem_create_mmap_offset()` function to associate
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the fake offset as described in ?.
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Note that dumb objects may not be used for gpu acceleration, as has been
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attempted on some ARM embedded platforms. Such drivers really must have
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a hardware-specific ioctl to allocate suitable buffer objects.
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Display Modes Function Reference
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================================
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.. kernel-doc:: include/drm/drm_modes.h
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:internal:
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.. kernel-doc:: drivers/gpu/drm/drm_modes.c
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:export:
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KMS Initialization and Cleanup
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==============================
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A KMS device is abstracted and exposed as a set of planes, CRTCs,
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encoders and connectors. KMS drivers must thus create and initialize all
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those objects at load time after initializing mode setting.
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CRTCs (:c:type:`struct drm_crtc <drm_crtc>`)
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--------------------------------------------
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A CRTC is an abstraction representing a part of the chip that contains a
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pointer to a scanout buffer. Therefore, the number of CRTCs available
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determines how many independent scanout buffers can be active at any
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given time. The CRTC structure contains several fields to support this:
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a pointer to some video memory (abstracted as a frame buffer object), a
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display mode, and an (x, y) offset into the video memory to support
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panning or configurations where one piece of video memory spans multiple
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CRTCs.
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CRTC Initialization
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~~~~~~~~~~~~~~~~~~~
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A KMS device must create and register at least one struct
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:c:type:`struct drm_crtc <drm_crtc>` instance. The instance is
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allocated and zeroed by the driver, possibly as part of a larger
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structure, and registered with a call to :c:func:`drm_crtc_init()`
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with a pointer to CRTC functions.
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Planes (:c:type:`struct drm_plane <drm_plane>`)
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-----------------------------------------------
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A plane represents an image source that can be blended with or overlayed
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on top of a CRTC during the scanout process. Planes are associated with
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a frame buffer to crop a portion of the image memory (source) and
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optionally scale it to a destination size. The result is then blended
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with or overlayed on top of a CRTC.
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The DRM core recognizes three types of planes:
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- DRM_PLANE_TYPE_PRIMARY represents a "main" plane for a CRTC.
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Primary planes are the planes operated upon by CRTC modesetting and
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flipping operations described in the page_flip hook in
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:c:type:`struct drm_crtc_funcs <drm_crtc_funcs>`.
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- DRM_PLANE_TYPE_CURSOR represents a "cursor" plane for a CRTC.
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Cursor planes are the planes operated upon by the
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DRM_IOCTL_MODE_CURSOR and DRM_IOCTL_MODE_CURSOR2 ioctls.
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- DRM_PLANE_TYPE_OVERLAY represents all non-primary, non-cursor
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planes. Some drivers refer to these types of planes as "sprites"
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internally.
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For compatibility with legacy userspace, only overlay planes are made
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available to userspace by default. Userspace clients may set the
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DRM_CLIENT_CAP_UNIVERSAL_PLANES client capability bit to indicate
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that they wish to receive a universal plane list containing all plane
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types.
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Plane Initialization
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~~~~~~~~~~~~~~~~~~~~
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To create a plane, a KMS drivers allocates and zeroes an instances of
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:c:type:`struct drm_plane <drm_plane>` (possibly as part of a
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larger structure) and registers it with a call to
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:c:func:`drm_universal_plane_init()`. The function takes a
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bitmask of the CRTCs that can be associated with the plane, a pointer to
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the plane functions, a list of format supported formats, and the type of
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plane (primary, cursor, or overlay) being initialized.
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Cursor and overlay planes are optional. All drivers should provide one
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primary plane per CRTC (although this requirement may change in the
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future); drivers that do not wish to provide special handling for
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primary planes may make use of the helper functions described in ? to
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create and register a primary plane with standard capabilities.
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Encoders (:c:type:`struct drm_encoder <drm_encoder>`)
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-----------------------------------------------------
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An encoder takes pixel data from a CRTC and converts it to a format
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suitable for any attached connectors. On some devices, it may be
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possible to have a CRTC send data to more than one encoder. In that
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case, both encoders would receive data from the same scanout buffer,
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resulting in a "cloned" display configuration across the connectors
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attached to each encoder.
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Encoder Initialization
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~~~~~~~~~~~~~~~~~~~~~~
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As for CRTCs, a KMS driver must create, initialize and register at least
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one :c:type:`struct drm_encoder <drm_encoder>` instance. The
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instance is allocated and zeroed by the driver, possibly as part of a
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larger structure.
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Drivers must initialize the :c:type:`struct drm_encoder
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<drm_encoder>` possible_crtcs and possible_clones fields before
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registering the encoder. Both fields are bitmasks of respectively the
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CRTCs that the encoder can be connected to, and sibling encoders
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candidate for cloning.
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After being initialized, the encoder must be registered with a call to
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:c:func:`drm_encoder_init()`. The function takes a pointer to the
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encoder functions and an encoder type. Supported types are
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- DRM_MODE_ENCODER_DAC for VGA and analog on DVI-I/DVI-A
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- DRM_MODE_ENCODER_TMDS for DVI, HDMI and (embedded) DisplayPort
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- DRM_MODE_ENCODER_LVDS for display panels
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- DRM_MODE_ENCODER_TVDAC for TV output (Composite, S-Video,
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Component, SCART)
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- DRM_MODE_ENCODER_VIRTUAL for virtual machine displays
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Encoders must be attached to a CRTC to be used. DRM drivers leave
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encoders unattached at initialization time. Applications (or the fbdev
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compatibility layer when implemented) are responsible for attaching the
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encoders they want to use to a CRTC.
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Connectors (:c:type:`struct drm_connector <drm_connector>`)
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-----------------------------------------------------------
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A connector is the final destination for pixel data on a device, and
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usually connects directly to an external display device like a monitor
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or laptop panel. A connector can only be attached to one encoder at a
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time. The connector is also the structure where information about the
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attached display is kept, so it contains fields for display data, EDID
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data, DPMS & connection status, and information about modes supported on
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the attached displays.
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Connector Initialization
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~~~~~~~~~~~~~~~~~~~~~~~~
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Finally a KMS driver must create, initialize, register and attach at
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least one :c:type:`struct drm_connector <drm_connector>`
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instance. The instance is created as other KMS objects and initialized
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by setting the following fields.
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interlace_allowed
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Whether the connector can handle interlaced modes.
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doublescan_allowed
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Whether the connector can handle doublescan.
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display_info
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Display information is filled from EDID information when a display
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is detected. For non hot-pluggable displays such as flat panels in
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embedded systems, the driver should initialize the
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display_info.width_mm and display_info.height_mm fields with the
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physical size of the display.
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polled
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Connector polling mode, a combination of
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DRM_CONNECTOR_POLL_HPD
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The connector generates hotplug events and doesn't need to be
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periodically polled. The CONNECT and DISCONNECT flags must not
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be set together with the HPD flag.
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DRM_CONNECTOR_POLL_CONNECT
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Periodically poll the connector for connection.
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DRM_CONNECTOR_POLL_DISCONNECT
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Periodically poll the connector for disconnection.
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Set to 0 for connectors that don't support connection status
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discovery.
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The connector is then registered with a call to
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:c:func:`drm_connector_init()` with a pointer to the connector
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functions and a connector type, and exposed through sysfs with a call to
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:c:func:`drm_connector_register()`.
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Supported connector types are
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- DRM_MODE_CONNECTOR_VGA
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- DRM_MODE_CONNECTOR_DVII
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- DRM_MODE_CONNECTOR_DVID
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- DRM_MODE_CONNECTOR_DVIA
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- DRM_MODE_CONNECTOR_Composite
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- DRM_MODE_CONNECTOR_SVIDEO
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- DRM_MODE_CONNECTOR_LVDS
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- DRM_MODE_CONNECTOR_Component
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- DRM_MODE_CONNECTOR_9PinDIN
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- DRM_MODE_CONNECTOR_DisplayPort
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- DRM_MODE_CONNECTOR_HDMIA
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- DRM_MODE_CONNECTOR_HDMIB
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- DRM_MODE_CONNECTOR_TV
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- DRM_MODE_CONNECTOR_eDP
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- DRM_MODE_CONNECTOR_VIRTUAL
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Connectors must be attached to an encoder to be used. For devices that
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map connectors to encoders 1:1, the connector should be attached at
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initialization time with a call to
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:c:func:`drm_mode_connector_attach_encoder()`. The driver must
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also set the :c:type:`struct drm_connector <drm_connector>`
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encoder field to point to the attached encoder.
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Finally, drivers must initialize the connectors state change detection
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with a call to :c:func:`drm_kms_helper_poll_init()`. If at least
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one connector is pollable but can't generate hotplug interrupts
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(indicated by the DRM_CONNECTOR_POLL_CONNECT and
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DRM_CONNECTOR_POLL_DISCONNECT connector flags), a delayed work will
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automatically be queued to periodically poll for changes. Connectors
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that can generate hotplug interrupts must be marked with the
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DRM_CONNECTOR_POLL_HPD flag instead, and their interrupt handler must
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call :c:func:`drm_helper_hpd_irq_event()`. The function will
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queue a delayed work to check the state of all connectors, but no
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periodic polling will be done.
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Connector Operations
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~~~~~~~~~~~~~~~~~~~~
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**Note**
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Unless otherwise state, all operations are mandatory.
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DPMS
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''''
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void (\*dpms)(struct drm_connector \*connector, int mode);
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The DPMS operation sets the power state of a connector. The mode
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argument is one of
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- DRM_MODE_DPMS_ON
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- DRM_MODE_DPMS_STANDBY
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- DRM_MODE_DPMS_SUSPEND
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- DRM_MODE_DPMS_OFF
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In all but DPMS_ON mode the encoder to which the connector is attached
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should put the display in low-power mode by driving its signals
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appropriately. If more than one connector is attached to the encoder
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care should be taken not to change the power state of other displays as
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a side effect. Low-power mode should be propagated to the encoders and
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CRTCs when all related connectors are put in low-power mode.
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Modes
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'''''
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int (\*fill_modes)(struct drm_connector \*connector, uint32_t
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max_width, uint32_t max_height);
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Fill the mode list with all supported modes for the connector. If the
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``max_width`` and ``max_height`` arguments are non-zero, the
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implementation must ignore all modes wider than ``max_width`` or higher
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than ``max_height``.
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The connector must also fill in this operation its display_info
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width_mm and height_mm fields with the connected display physical size
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in millimeters. The fields should be set to 0 if the value isn't known
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or is not applicable (for instance for projector devices).
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Connection Status
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'''''''''''''''''
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The connection status is updated through polling or hotplug events when
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supported (see ?). The status value is reported to userspace through
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ioctls and must not be used inside the driver, as it only gets
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initialized by a call to :c:func:`drm_mode_getconnector()` from
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userspace.
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enum drm_connector_status (\*detect)(struct drm_connector
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\*connector, bool force);
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Check to see if anything is attached to the connector. The ``force``
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parameter is set to false whilst polling or to true when checking the
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connector due to user request. ``force`` can be used by the driver to
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avoid expensive, destructive operations during automated probing.
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Return connector_status_connected if something is connected to the
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connector, connector_status_disconnected if nothing is connected and
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connector_status_unknown if the connection state isn't known.
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Drivers should only return connector_status_connected if the
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connection status has really been probed as connected. Connectors that
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can't detect the connection status, or failed connection status probes,
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should return connector_status_unknown.
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Cleanup
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-------
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The DRM core manages its objects' lifetime. When an object is not needed
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anymore the core calls its destroy function, which must clean up and
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free every resource allocated for the object. Every
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:c:func:`drm_\*_init()` call must be matched with a corresponding
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:c:func:`drm_\*_cleanup()` call to cleanup CRTCs
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(:c:func:`drm_crtc_cleanup()`), planes
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(:c:func:`drm_plane_cleanup()`), encoders
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(:c:func:`drm_encoder_cleanup()`) and connectors
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(:c:func:`drm_connector_cleanup()`). Furthermore, connectors that
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have been added to sysfs must be removed by a call to
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:c:func:`drm_connector_unregister()` before calling
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:c:func:`drm_connector_cleanup()`.
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Connectors state change detection must be cleanup up with a call to
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:c:func:`drm_kms_helper_poll_fini()`.
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Output discovery and initialization example
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-------------------------------------------
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::
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void intel_crt_init(struct drm_device *dev)
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{
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struct drm_connector *connector;
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struct intel_output *intel_output;
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intel_output = kzalloc(sizeof(struct intel_output), GFP_KERNEL);
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if (!intel_output)
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return;
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connector = &intel_output->base;
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drm_connector_init(dev, &intel_output->base,
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&intel_crt_connector_funcs, DRM_MODE_CONNECTOR_VGA);
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drm_encoder_init(dev, &intel_output->enc, &intel_crt_enc_funcs,
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DRM_MODE_ENCODER_DAC);
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drm_mode_connector_attach_encoder(&intel_output->base,
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&intel_output->enc);
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/* Set up the DDC bus. */
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intel_output->ddc_bus = intel_i2c_create(dev, GPIOA, "CRTDDC_A");
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if (!intel_output->ddc_bus) {
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dev_printk(KERN_ERR, &dev->pdev->dev, "DDC bus registration "
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"failed.\n");
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return;
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}
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intel_output->type = INTEL_OUTPUT_ANALOG;
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connector->interlace_allowed = 0;
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connector->doublescan_allowed = 0;
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drm_encoder_helper_add(&intel_output->enc, &intel_crt_helper_funcs);
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drm_connector_helper_add(connector, &intel_crt_connector_helper_funcs);
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drm_connector_register(connector);
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}
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In the example above (taken from the i915 driver), a CRTC, connector and
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encoder combination is created. A device-specific i2c bus is also
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created for fetching EDID data and performing monitor detection. Once
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the process is complete, the new connector is registered with sysfs to
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make its properties available to applications.
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KMS Locking
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===========
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.. kernel-doc:: drivers/gpu/drm/drm_modeset_lock.c
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:doc: kms locking
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.. kernel-doc:: include/drm/drm_modeset_lock.h
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:internal:
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.. kernel-doc:: drivers/gpu/drm/drm_modeset_lock.c
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:export:
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KMS Properties
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==============
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Drivers may need to expose additional parameters to applications than
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those described in the previous sections. KMS supports attaching
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properties to CRTCs, connectors and planes and offers a userspace API to
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list, get and set the property values.
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Properties are identified by a name that uniquely defines the property
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purpose, and store an associated value. For all property types except
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blob properties the value is a 64-bit unsigned integer.
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KMS differentiates between properties and property instances. Drivers
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first create properties and then create and associate individual
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instances of those properties to objects. A property can be instantiated
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multiple times and associated with different objects. Values are stored
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in property instances, and all other property information are stored in
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the property and shared between all instances of the property.
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Every property is created with a type that influences how the KMS core
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handles the property. Supported property types are
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DRM_MODE_PROP_RANGE
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Range properties report their minimum and maximum admissible values.
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The KMS core verifies that values set by application fit in that
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range.
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DRM_MODE_PROP_ENUM
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Enumerated properties take a numerical value that ranges from 0 to
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the number of enumerated values defined by the property minus one,
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and associate a free-formed string name to each value. Applications
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can retrieve the list of defined value-name pairs and use the
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numerical value to get and set property instance values.
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DRM_MODE_PROP_BITMASK
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Bitmask properties are enumeration properties that additionally
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restrict all enumerated values to the 0..63 range. Bitmask property
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instance values combine one or more of the enumerated bits defined
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by the property.
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DRM_MODE_PROP_BLOB
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Blob properties store a binary blob without any format restriction.
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The binary blobs are created as KMS standalone objects, and blob
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property instance values store the ID of their associated blob
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object.
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Blob properties are only used for the connector EDID property and
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cannot be created by drivers.
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To create a property drivers call one of the following functions
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depending on the property type. All property creation functions take
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property flags and name, as well as type-specific arguments.
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- struct drm_property \*drm_property_create_range(struct
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drm_device \*dev, int flags, const char \*name, uint64_t min,
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uint64_t max);
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Create a range property with the given minimum and maximum values.
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- struct drm_property \*drm_property_create_enum(struct drm_device
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\*dev, int flags, const char \*name, const struct
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drm_prop_enum_list \*props, int num_values);
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Create an enumerated property. The ``props`` argument points to an
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array of ``num_values`` value-name pairs.
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- struct drm_property \*drm_property_create_bitmask(struct
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drm_device \*dev, int flags, const char \*name, const struct
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drm_prop_enum_list \*props, int num_values);
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Create a bitmask property. The ``props`` argument points to an array
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of ``num_values`` value-name pairs.
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Properties can additionally be created as immutable, in which case they
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will be read-only for applications but can be modified by the driver. To
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create an immutable property drivers must set the
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DRM_MODE_PROP_IMMUTABLE flag at property creation time.
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When no array of value-name pairs is readily available at property
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creation time for enumerated or range properties, drivers can create the
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property using the :c:func:`drm_property_create()` function and
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manually add enumeration value-name pairs by calling the
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:c:func:`drm_property_add_enum()` function. Care must be taken to
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properly specify the property type through the ``flags`` argument.
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After creating properties drivers can attach property instances to CRTC,
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connector and plane objects by calling the
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:c:func:`drm_object_attach_property()`. The function takes a
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pointer to the target object, a pointer to the previously created
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property and an initial instance value.
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Existing KMS Properties
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-----------------------
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The following table gives description of drm properties exposed by
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various modules/drivers.
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.. csv-table::
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:header-rows: 1
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:file: kms-properties.csv
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Vertical Blanking
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=================
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Vertical blanking plays a major role in graphics rendering. To achieve
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tear-free display, users must synchronize page flips and/or rendering to
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vertical blanking. The DRM API offers ioctls to perform page flips
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synchronized to vertical blanking and wait for vertical blanking.
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The DRM core handles most of the vertical blanking management logic,
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which involves filtering out spurious interrupts, keeping race-free
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blanking counters, coping with counter wrap-around and resets and
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keeping use counts. It relies on the driver to generate vertical
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blanking interrupts and optionally provide a hardware vertical blanking
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counter. Drivers must implement the following operations.
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- int (\*enable_vblank) (struct drm_device \*dev, int crtc); void
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(\*disable_vblank) (struct drm_device \*dev, int crtc);
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Enable or disable vertical blanking interrupts for the given CRTC.
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- u32 (\*get_vblank_counter) (struct drm_device \*dev, int crtc);
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Retrieve the value of the vertical blanking counter for the given
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CRTC. If the hardware maintains a vertical blanking counter its value
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should be returned. Otherwise drivers can use the
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:c:func:`drm_vblank_count()` helper function to handle this
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operation.
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Drivers must initialize the vertical blanking handling core with a call
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to :c:func:`drm_vblank_init()` in their load operation.
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Vertical blanking interrupts can be enabled by the DRM core or by
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drivers themselves (for instance to handle page flipping operations).
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The DRM core maintains a vertical blanking use count to ensure that the
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interrupts are not disabled while a user still needs them. To increment
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the use count, drivers call :c:func:`drm_vblank_get()`. Upon
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return vertical blanking interrupts are guaranteed to be enabled.
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To decrement the use count drivers call
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:c:func:`drm_vblank_put()`. Only when the use count drops to zero
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will the DRM core disable the vertical blanking interrupts after a delay
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by scheduling a timer. The delay is accessible through the
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vblankoffdelay module parameter or the ``drm_vblank_offdelay`` global
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variable and expressed in milliseconds. Its default value is 5000 ms.
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Zero means never disable, and a negative value means disable
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immediately. Drivers may override the behaviour by setting the
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:c:type:`struct drm_device <drm_device>`
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vblank_disable_immediate flag, which when set causes vblank interrupts
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to be disabled immediately regardless of the drm_vblank_offdelay
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value. The flag should only be set if there's a properly working
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hardware vblank counter present.
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When a vertical blanking interrupt occurs drivers only need to call the
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:c:func:`drm_handle_vblank()` function to account for the
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interrupt.
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Resources allocated by :c:func:`drm_vblank_init()` must be freed
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with a call to :c:func:`drm_vblank_cleanup()` in the driver unload
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operation handler.
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Vertical Blanking and Interrupt Handling Functions Reference
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------------------------------------------------------------
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.. kernel-doc:: drivers/gpu/drm/drm_irq.c
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:export:
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.. kernel-doc:: include/drm/drm_irq.h
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:internal:
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