drivers/gpu/drm/xen/xen_drm_front.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 OR MIT */

 /*
  *  Xen para-virtual DRM device
  *
  * Copyright (C) 2016-2018 EPAM Systems Inc.
  *
  * Author: Oleksandr Andrushchenko <oleksandr_andrushchenko@epam.com>
  */

 #ifndef __XEN_DRM_FRONT_H_
 #define __XEN_DRM_FRONT_H_

 #include <drm/drmP.h>
 #include <drm/drm_simple_kms_helper.h>

 #include <linux/scatterlist.h>

 #include "xen_drm_front_cfg.h"

 /**
  * DOC: Driver modes of operation in terms of display buffers used
  *
  * Depending on the requirements for the para-virtualized environment, namely
  * requirements dictated by the accompanying DRM/(v)GPU drivers running in both
  * host and guest environments, display buffers can be allocated by either
  * frontend driver or backend.
  */

 /**
  * DOC: Buffers allocated by the frontend driver
  *
  * In this mode of operation driver allocates buffers from system memory.
  *
  * Note! If used with accompanying DRM/(v)GPU drivers this mode of operation
  * may require IOMMU support on the platform, so accompanying DRM/vGPU
  * hardware can still reach display buffer memory while importing PRIME
  * buffers from the frontend driver.
  */

 /**
  * DOC: Buffers allocated by the backend
  *
  * This mode of operation is run-time configured via guest domain configuration
  * through XenStore entries.
  *
  * For systems which do not provide IOMMU support, but having specific
  * requirements for display buffers it is possible to allocate such buffers
  * at backend side and share those with the frontend.
  * For example, if host domain is 1:1 mapped and has DRM/GPU hardware expecting
  * physically contiguous memory, this allows implementing zero-copying
  * use-cases.
  *
  * Note, while using this scenario the following should be considered:
  *
  * #. If guest domain dies then pages/grants received from the backend
  *    cannot be claimed back
  *
  * #. Misbehaving guest may send too many requests to the
  *    backend exhausting its grant references and memory
  *    (consider this from security POV)
  */

 /**
  * DOC: Driver limitations
  *
  * #. Only primary plane without additional properties is supported.
  *
  * #. Only one video mode per connector supported which is configured
  *    via XenStore.
  *
  * #. All CRTCs operate at fixed frequency of 60Hz.
  */

 /* timeout in ms to wait for backend to respond */
 #define XEN_DRM_FRONT_WAIT_BACK_MS	3000

 #ifndef GRANT_INVALID_REF
 /*
  * Note on usage of grant reference 0 as invalid grant reference:
  * grant reference 0 is valid, but never exposed to a PV driver,
  * because of the fact it is already in use/reserved by the PV console.
  */
 #define GRANT_INVALID_REF	0
 #endif

 struct xen_drm_front_info {
 	struct xenbus_device *xb_dev;
 	struct xen_drm_front_drm_info *drm_info;

 	/* to protect data between backend IO code and interrupt handler */
 	spinlock_t io_lock;

 	int num_evt_pairs;
 	struct xen_drm_front_evtchnl_pair *evt_pairs;
 	struct xen_drm_front_cfg cfg;

 	/* display buffers */
 	struct list_head dbuf_list;
 };

 struct xen_drm_front_drm_pipeline {
 	struct xen_drm_front_drm_info *drm_info;

 	int index;

 	struct drm_simple_display_pipe pipe;

 	struct drm_connector conn;
 	/* These are only for connector mode checking */
 	int width, height;

 	struct drm_pending_vblank_event *pending_event;

 	struct delayed_work pflip_to_worker;

 	bool conn_connected;
 };

 struct xen_drm_front_drm_info {
 	struct xen_drm_front_info *front_info;
 	struct drm_device *drm_dev;

 	struct xen_drm_front_drm_pipeline pipeline[XEN_DRM_FRONT_MAX_CRTCS];
 };

 static inline u64 xen_drm_front_fb_to_cookie(struct drm_framebuffer *fb)
 {
 	return (uintptr_t)fb;
 }

 static inline u64 xen_drm_front_dbuf_to_cookie(struct drm_gem_object *gem_obj)
 {
 	return (uintptr_t)gem_obj;
 }

 int xen_drm_front_mode_set(struct xen_drm_front_drm_pipeline *pipeline,
 			   u32 x, u32 y, u32 width, u32 height,
 			   u32 bpp, u64 fb_cookie);

 int xen_drm_front_dbuf_create(struct xen_drm_front_info *front_info,
 			      u64 dbuf_cookie, u32 width, u32 height,
 			      u32 bpp, u64 size, struct page **pages);

 int xen_drm_front_fb_attach(struct xen_drm_front_info *front_info,
 			    u64 dbuf_cookie, u64 fb_cookie, u32 width,
 			    u32 height, u32 pixel_format);

 int xen_drm_front_fb_detach(struct xen_drm_front_info *front_info,
 			    u64 fb_cookie);

 int xen_drm_front_page_flip(struct xen_drm_front_info *front_info,
 			    int conn_idx, u64 fb_cookie);

 void xen_drm_front_on_frame_done(struct xen_drm_front_info *front_info,
 				 int conn_idx, u64 fb_cookie);

 #endif /* __XEN_DRM_FRONT_H_ */
	/* SPDX-License-Identifier: GPL-2.0 OR MIT */

	/*
	* Xen para-virtual DRM device
	*
	* Copyright (C) 2016-2018 EPAM Systems Inc.
	*
	* Author: Oleksandr Andrushchenko <oleksandr_andrushchenko@epam.com>
	*/

	#ifndef __XEN_DRM_FRONT_H_
	#define __XEN_DRM_FRONT_H_

	#include <drm/drmP.h>
	#include <drm/drm_simple_kms_helper.h>

	#include <linux/scatterlist.h>

	#include "xen_drm_front_cfg.h"

	/**
	* DOC: Driver modes of operation in terms of display buffers used
	*
	* Depending on the requirements for the para-virtualized environment, namely
	* requirements dictated by the accompanying DRM/(v)GPU drivers running in both
	* host and guest environments, display buffers can be allocated by either
	* frontend driver or backend.
	*/

	/**
	* DOC: Buffers allocated by the frontend driver
	*
	* In this mode of operation driver allocates buffers from system memory.
	*
	* Note! If used with accompanying DRM/(v)GPU drivers this mode of operation
	* may require IOMMU support on the platform, so accompanying DRM/vGPU
	* hardware can still reach display buffer memory while importing PRIME
	* buffers from the frontend driver.
	*/

	/**
	* DOC: Buffers allocated by the backend
	*
	* This mode of operation is run-time configured via guest domain configuration
	* through XenStore entries.
	*
	* For systems which do not provide IOMMU support, but having specific
	* requirements for display buffers it is possible to allocate such buffers
	* at backend side and share those with the frontend.
	* For example, if host domain is 1:1 mapped and has DRM/GPU hardware expecting
	* physically contiguous memory, this allows implementing zero-copying
	* use-cases.
	*
	* Note, while using this scenario the following should be considered:
	*
	* #. If guest domain dies then pages/grants received from the backend
	* cannot be claimed back
	*
	* #. Misbehaving guest may send too many requests to the
	* backend exhausting its grant references and memory
	* (consider this from security POV)
	*/

	/**
	* DOC: Driver limitations
	*
	* #. Only primary plane without additional properties is supported.
	*
	* #. Only one video mode per connector supported which is configured
	* via XenStore.
	*
	* #. All CRTCs operate at fixed frequency of 60Hz.
	*/

	/* timeout in ms to wait for backend to respond */
	#define XEN_DRM_FRONT_WAIT_BACK_MS 3000

	#ifndef GRANT_INVALID_REF
	/*
	* Note on usage of grant reference 0 as invalid grant reference:
	* grant reference 0 is valid, but never exposed to a PV driver,
	* because of the fact it is already in use/reserved by the PV console.
	*/
	#define GRANT_INVALID_REF 0
	#endif

	struct xen_drm_front_info {
	struct xenbus_device *xb_dev;
	struct xen_drm_front_drm_info *drm_info;

	/* to protect data between backend IO code and interrupt handler */
	spinlock_t io_lock;

	int num_evt_pairs;
	struct xen_drm_front_evtchnl_pair *evt_pairs;
	struct xen_drm_front_cfg cfg;

	/* display buffers */
	struct list_head dbuf_list;
	};

	struct xen_drm_front_drm_pipeline {
	struct xen_drm_front_drm_info *drm_info;

	int index;

	struct drm_simple_display_pipe pipe;

	struct drm_connector conn;
	/* These are only for connector mode checking */
	int width, height;

	struct drm_pending_vblank_event *pending_event;

	struct delayed_work pflip_to_worker;

	bool conn_connected;
	};

	struct xen_drm_front_drm_info {
	struct xen_drm_front_info *front_info;
	struct drm_device *drm_dev;

	struct xen_drm_front_drm_pipeline pipeline[XEN_DRM_FRONT_MAX_CRTCS];
	};

	static inline u64 xen_drm_front_fb_to_cookie(struct drm_framebuffer *fb)
	{
	return (uintptr_t)fb;
	}

	static inline u64 xen_drm_front_dbuf_to_cookie(struct drm_gem_object *gem_obj)
	{
	return (uintptr_t)gem_obj;
	}

	int xen_drm_front_mode_set(struct xen_drm_front_drm_pipeline *pipeline,
	u32 x, u32 y, u32 width, u32 height,
	u32 bpp, u64 fb_cookie);

	int xen_drm_front_dbuf_create(struct xen_drm_front_info *front_info,
	u64 dbuf_cookie, u32 width, u32 height,
	u32 bpp, u64 size, struct page **pages);

	int xen_drm_front_fb_attach(struct xen_drm_front_info *front_info,
	u64 dbuf_cookie, u64 fb_cookie, u32 width,
	u32 height, u32 pixel_format);

	int xen_drm_front_fb_detach(struct xen_drm_front_info *front_info,
	u64 fb_cookie);

	int xen_drm_front_page_flip(struct xen_drm_front_info *front_info,
	int conn_idx, u64 fb_cookie);

	void xen_drm_front_on_frame_done(struct xen_drm_front_info *front_info,
	int conn_idx, u64 fb_cookie);

	#endif /* __XEN_DRM_FRONT_H_ */