drivers/staging/vboxvideo/vboxvideo.h - pub/scm/linux/kernel/git/arnd/asm-generic - Git at Google

 /* SPDX-License-Identifier: MIT */
 /* Copyright (C) 2006-2016 Oracle Corporation */

 #ifndef __VBOXVIDEO_H__
 #define __VBOXVIDEO_H__

 #define VBOX_VIDEO_MAX_SCREENS 64

 /*
  * The last 4096 bytes of the guest VRAM contains the generic info for all
  * DualView chunks: sizes and offsets of chunks. This is filled by miniport.
  *
  * Last 4096 bytes of each chunk contain chunk specific data: framebuffer info,
  * etc. This is used exclusively by the corresponding instance of a display
  * driver.
  *
  * The VRAM layout:
  *   Last 4096 bytes - Adapter information area.
  *   4096 bytes aligned miniport heap (value specified in the config rouded up).
  *   Slack - what left after dividing the VRAM.
  *   4096 bytes aligned framebuffers:
  *     last 4096 bytes of each framebuffer is the display information area.
  *
  * The Virtual Graphics Adapter information in the guest VRAM is stored by the
  * guest video driver using structures prepended by VBOXVIDEOINFOHDR.
  *
  * When the guest driver writes dword 0 to the VBE_DISPI_INDEX_VBOX_VIDEO
  * the host starts to process the info. The first element at the start of
  * the 4096 bytes region should be normally be a LINK that points to
  * actual information chain. That way the guest driver can have some
  * fixed layout of the information memory block and just rewrite
  * the link to point to relevant memory chain.
  *
  * The processing stops at the END element.
  *
  * The host can access the memory only when the port IO is processed.
  * All data that will be needed later must be copied from these 4096 bytes.
  * But other VRAM can be used by host until the mode is disabled.
  *
  * The guest driver writes dword 0xffffffff to the VBE_DISPI_INDEX_VBOX_VIDEO
  * to disable the mode.
  *
  * VBE_DISPI_INDEX_VBOX_VIDEO is used to read the configuration information
  * from the host and issue commands to the host.
  *
  * The guest writes the VBE_DISPI_INDEX_VBOX_VIDEO index register, the the
  * following operations with the VBE data register can be performed:
  *
  * Operation            Result
  * write 16 bit value   NOP
  * read 16 bit value    count of monitors
  * write 32 bit value   set the vbox cmd value and the cmd processed by the host
  * read 32 bit value    result of the last vbox command is returned
  */

 struct vbva_cmd_hdr {
 	s16 x;
 	s16 y;
 	u16 w;
 	u16 h;
 } __packed;

 /*
  * The VBVA ring buffer is suitable for transferring large (< 2GB) amount of
  * data. For example big bitmaps which do not fit to the buffer.
  *
  * Guest starts writing to the buffer by initializing a record entry in the
  * records queue. VBVA_F_RECORD_PARTIAL indicates that the record is being
  * written. As data is written to the ring buffer, the guest increases
  * free_offset.
  *
  * The host reads the records on flushes and processes all completed records.
  * When host encounters situation when only a partial record presents and
  * len_and_flags & ~VBVA_F_RECORD_PARTIAL >= VBVA_RING_BUFFER_SIZE -
  * VBVA_RING_BUFFER_THRESHOLD, the host fetched all record data and updates
  * data_offset. After that on each flush the host continues fetching the data
  * until the record is completed.
  */

 #define VBVA_RING_BUFFER_SIZE        (4194304 - 1024)
 #define VBVA_RING_BUFFER_THRESHOLD   (4096)

 #define VBVA_MAX_RECORDS (64)

 #define VBVA_F_MODE_ENABLED         0x00000001u
 #define VBVA_F_MODE_VRDP            0x00000002u
 #define VBVA_F_MODE_VRDP_RESET      0x00000004u
 #define VBVA_F_MODE_VRDP_ORDER_MASK 0x00000008u

 #define VBVA_F_STATE_PROCESSING     0x00010000u

 #define VBVA_F_RECORD_PARTIAL       0x80000000u

 struct vbva_record {
 	u32 len_and_flags;
 } __packed;

 /*
  * The minimum HGSMI heap size is PAGE_SIZE (4096 bytes) and is a restriction of
  * the runtime heapsimple API. Use minimum 2 pages here, because the info area
  * also may contain other data (for example hgsmi_host_flags structure).
  */
 #define VBVA_ADAPTER_INFORMATION_SIZE 65536
 #define VBVA_MIN_BUFFER_SIZE          65536

 /* The value for port IO to let the adapter to interpret the adapter memory. */
 #define VBOX_VIDEO_DISABLE_ADAPTER_MEMORY        0xFFFFFFFF

 /* The value for port IO to let the adapter to interpret the adapter memory. */
 #define VBOX_VIDEO_INTERPRET_ADAPTER_MEMORY      0x00000000

 /*
  * The value for port IO to let the adapter to interpret the display memory.
  * The display number is encoded in low 16 bits.
  */
 #define VBOX_VIDEO_INTERPRET_DISPLAY_MEMORY_BASE 0x00010000

 struct vbva_host_flags {
 	u32 host_events;
 	u32 supported_orders;
 } __packed;

 struct vbva_buffer {
 	struct vbva_host_flags host_flags;

 	/* The offset where the data start in the buffer. */
 	u32 data_offset;
 	/* The offset where next data must be placed in the buffer. */
 	u32 free_offset;

 	/* The queue of record descriptions. */
 	struct vbva_record records[VBVA_MAX_RECORDS];
 	u32 record_first_index;
 	u32 record_free_index;

 	/* Space to leave free when large partial records are transferred. */
 	u32 partial_write_tresh;

 	u32 data_len;
 	/* variable size for the rest of the vbva_buffer area in VRAM. */
 	u8 data[0];
 } __packed;

 #define VBVA_MAX_RECORD_SIZE (128 * 1024 * 1024)

 /* guest->host commands */
 #define VBVA_QUERY_CONF32			 1
 #define VBVA_SET_CONF32				 2
 #define VBVA_INFO_VIEW				 3
 #define VBVA_INFO_HEAP				 4
 #define VBVA_FLUSH				 5
 #define VBVA_INFO_SCREEN			 6
 #define VBVA_ENABLE				 7
 #define VBVA_MOUSE_POINTER_SHAPE		 8
 /* informs host about HGSMI caps. see vbva_caps below */
 #define VBVA_INFO_CAPS				12
 /* configures scanline, see VBVASCANLINECFG below */
 #define VBVA_SCANLINE_CFG			13
 /* requests scanline info, see VBVASCANLINEINFO below */
 #define VBVA_SCANLINE_INFO			14
 /* inform host about VBVA Command submission */
 #define VBVA_CMDVBVA_SUBMIT			16
 /* inform host about VBVA Command submission */
 #define VBVA_CMDVBVA_FLUSH			17
 /* G->H DMA command */
 #define VBVA_CMDVBVA_CTL			18
 /* Query most recent mode hints sent */
 #define VBVA_QUERY_MODE_HINTS			19
 /*
  * Report the guest virtual desktop position and size for mapping host and
  * guest pointer positions.
  */
 #define VBVA_REPORT_INPUT_MAPPING		20
 /* Report the guest cursor position and query the host position. */
 #define VBVA_CURSOR_POSITION			21

 /* host->guest commands */
 #define VBVAHG_EVENT				1
 #define VBVAHG_DISPLAY_CUSTOM			2

 /* vbva_conf32::index */
 #define VBOX_VBVA_CONF32_MONITOR_COUNT		0
 #define VBOX_VBVA_CONF32_HOST_HEAP_SIZE		1
 /*
  * Returns VINF_SUCCESS if the host can report mode hints via VBVA.
  * Set value to VERR_NOT_SUPPORTED before calling.
  */
 #define VBOX_VBVA_CONF32_MODE_HINT_REPORTING	2
 /*
  * Returns VINF_SUCCESS if the host can report guest cursor enabled status via
  * VBVA.  Set value to VERR_NOT_SUPPORTED before calling.
  */
 #define VBOX_VBVA_CONF32_GUEST_CURSOR_REPORTING	3
 /*
  * Returns the currently available host cursor capabilities.  Available if
  * VBOX_VBVA_CONF32_GUEST_CURSOR_REPORTING returns success.
  */
 #define VBOX_VBVA_CONF32_CURSOR_CAPABILITIES	4
 /* Returns the supported flags in vbva_infoscreen.flags. */
 #define VBOX_VBVA_CONF32_SCREEN_FLAGS		5
 /* Returns the max size of VBVA record. */
 #define VBOX_VBVA_CONF32_MAX_RECORD_SIZE	6

 struct vbva_conf32 {
 	u32 index;
 	u32 value;
 } __packed;

 /* Reserved for historical reasons. */
 #define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED0   BIT(0)
 /*
  * Guest cursor capability: can the host show a hardware cursor at the host
  * pointer location?
  */
 #define VBOX_VBVA_CURSOR_CAPABILITY_HARDWARE    BIT(1)
 /* Reserved for historical reasons. */
 #define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED2   BIT(2)
 /* Reserved for historical reasons.  Must always be unset. */
 #define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED3   BIT(3)
 /* Reserved for historical reasons. */
 #define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED4   BIT(4)
 /* Reserved for historical reasons. */
 #define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED5   BIT(5)

 struct vbva_infoview {
 	/* Index of the screen, assigned by the guest. */
 	u32 view_index;

 	/* The screen offset in VRAM, the framebuffer starts here. */
 	u32 view_offset;

 	/* The size of the VRAM memory that can be used for the view. */
 	u32 view_size;

 	/* The recommended maximum size of the VRAM memory for the screen. */
 	u32 max_screen_size;
 } __packed;

 struct vbva_flush {
 	u32 reserved;
 } __packed;

 /* vbva_infoscreen.flags */
 #define VBVA_SCREEN_F_NONE			0x0000
 #define VBVA_SCREEN_F_ACTIVE			0x0001
 /*
  * The virtual monitor has been disabled by the guest and should be removed
  * by the host and ignored for purposes of pointer position calculation.
  */
 #define VBVA_SCREEN_F_DISABLED			0x0002
 /*
  * The virtual monitor has been blanked by the guest and should be blacked
  * out by the host using width, height, etc values from the vbva_infoscreen
  * request.
  */
 #define VBVA_SCREEN_F_BLANK			0x0004
 /*
  * The virtual monitor has been blanked by the guest and should be blacked
  * out by the host using the previous mode values for width. height, etc.
  */
 #define VBVA_SCREEN_F_BLANK2			0x0008

 struct vbva_infoscreen {
 	/* Which view contains the screen. */
 	u32 view_index;

 	/* Physical X origin relative to the primary screen. */
 	s32 origin_x;

 	/* Physical Y origin relative to the primary screen. */
 	s32 origin_y;

 	/* Offset of visible framebuffer relative to the framebuffer start. */
 	u32 start_offset;

 	/* The scan line size in bytes. */
 	u32 line_size;

 	/* Width of the screen. */
 	u32 width;

 	/* Height of the screen. */
 	u32 height;

 	/* Color depth. */
 	u16 bits_per_pixel;

 	/* VBVA_SCREEN_F_* */
 	u16 flags;
 } __packed;

 /* vbva_enable.flags */
 #define VBVA_F_NONE				0x00000000
 #define VBVA_F_ENABLE				0x00000001
 #define VBVA_F_DISABLE				0x00000002
 /* extended VBVA to be used with WDDM */
 #define VBVA_F_EXTENDED				0x00000004
 /* vbva offset is absolute VRAM offset */
 #define VBVA_F_ABSOFFSET			0x00000008

 struct vbva_enable {
 	u32 flags;
 	u32 offset;
 	s32 result;
 } __packed;

 struct vbva_enable_ex {
 	struct vbva_enable base;
 	u32 screen_id;
 } __packed;

 struct vbva_mouse_pointer_shape {
 	/* The host result. */
 	s32 result;

 	/* VBOX_MOUSE_POINTER_* bit flags. */
 	u32 flags;

 	/* X coordinate of the hot spot. */
 	u32 hot_X;

 	/* Y coordinate of the hot spot. */
 	u32 hot_y;

 	/* Width of the pointer in pixels. */
 	u32 width;

 	/* Height of the pointer in scanlines. */
 	u32 height;

 	/* Pointer data.
 	 *
 	 * The data consists of 1 bpp AND mask followed by 32 bpp XOR (color)
 	 * mask.
 	 *
 	 * For pointers without alpha channel the XOR mask pixels are 32 bit
 	 * values: (lsb)BGR0(msb). For pointers with alpha channel the XOR mask
 	 * consists of (lsb)BGRA(msb) 32 bit values.
 	 *
 	 * Guest driver must create the AND mask for pointers with alpha chan.,
 	 * so if host does not support alpha, the pointer could be displayed as
 	 * a normal color pointer. The AND mask can be constructed from alpha
 	 * values. For example alpha value >= 0xf0 means bit 0 in the AND mask.
 	 *
 	 * The AND mask is 1 bpp bitmap with byte aligned scanlines. Size of AND
 	 * mask, therefore, is and_len = (width + 7) / 8 * height. The padding
 	 * bits at the end of any scanline are undefined.
 	 *
 	 * The XOR mask follows the AND mask on the next 4 bytes aligned offset:
 	 * u8 *xor = and + (and_len + 3) & ~3
 	 * Bytes in the gap between the AND and the XOR mask are undefined.
 	 * XOR mask scanlines have no gap between them and size of XOR mask is:
 	 * xor_len = width * 4 * height.
 	 *
 	 * Preallocate 4 bytes for accessing actual data as p->data.
 	 */
 	u8 data[4];
 } __packed;

 /* pointer is visible */
 #define VBOX_MOUSE_POINTER_VISIBLE		0x0001
 /* pointer has alpha channel */
 #define VBOX_MOUSE_POINTER_ALPHA		0x0002
 /* pointerData contains new pointer shape */
 #define VBOX_MOUSE_POINTER_SHAPE		0x0004

 /*
  * The guest driver can handle asynch guest cmd completion by reading the
  * command offset from io port.
  */
 #define VBVACAPS_COMPLETEGCMD_BY_IOREAD		0x00000001
 /* the guest driver can handle video adapter IRQs */
 #define VBVACAPS_IRQ				0x00000002
 /* The guest can read video mode hints sent via VBVA. */
 #define VBVACAPS_VIDEO_MODE_HINTS		0x00000004
 /* The guest can switch to a software cursor on demand. */
 #define VBVACAPS_DISABLE_CURSOR_INTEGRATION	0x00000008
 /* The guest does not depend on host handling the VBE registers. */
 #define VBVACAPS_USE_VBVA_ONLY			0x00000010

 struct vbva_caps {
 	s32 rc;
 	u32 caps;
 } __packed;

 /* Query the most recent mode hints received from the host. */
 struct vbva_query_mode_hints {
 	/* The maximum number of screens to return hints for. */
 	u16 hints_queried_count;
 	/* The size of the mode hint structures directly following this one. */
 	u16 hint_structure_guest_size;
 	/* Return code for the operation. Initialise to VERR_NOT_SUPPORTED. */
 	s32 rc;
 } __packed;

 /*
  * Structure in which a mode hint is returned. The guest allocates an array
  * of these immediately after the vbva_query_mode_hints structure.
  * To accommodate future extensions, the vbva_query_mode_hints structure
  * specifies the size of the vbva_modehint structures allocated by the guest,
  * and the host only fills out structure elements which fit into that size. The
  * host should fill any unused members (e.g. dx, dy) or structure space on the
  * end with ~0. The whole structure can legally be set to ~0 to skip a screen.
  */
 struct vbva_modehint {
 	u32 magic;
 	u32 cx;
 	u32 cy;
 	u32 bpp;		/* Which has never been used... */
 	u32 display;
 	u32 dx;			/* X offset into the virtual frame-buffer. */
 	u32 dy;			/* Y offset into the virtual frame-buffer. */
 	u32 enabled;		/* Not flags. Add new members for new flags. */
 } __packed;

 #define VBVAMODEHINT_MAGIC 0x0801add9u

 /*
  * Report the rectangle relative to which absolute pointer events should be
  * expressed. This information remains valid until the next VBVA resize event
  * for any screen, at which time it is reset to the bounding rectangle of all
  * virtual screens and must be re-set.
  */
 struct vbva_report_input_mapping {
 	s32 x;	/* Upper left X co-ordinate relative to the first screen. */
 	s32 y;	/* Upper left Y co-ordinate relative to the first screen. */
 	u32 cx;	/* Rectangle width. */
 	u32 cy;	/* Rectangle height. */
 } __packed;

 /*
  * Report the guest cursor position and query the host one. The host may wish
  * to use the guest information to re-position its own cursor (though this is
  * currently unlikely).
  */
 struct vbva_cursor_position {
 	u32 report_position;	/* Are we reporting a position? */
 	u32 x;			/* Guest cursor X position */
 	u32 y;			/* Guest cursor Y position */
 } __packed;

 #endif
	/* SPDX-License-Identifier: MIT */
	/* Copyright (C) 2006-2016 Oracle Corporation */

	#ifndef __VBOXVIDEO_H__
	#define __VBOXVIDEO_H__

	#define VBOX_VIDEO_MAX_SCREENS 64

	/*
	* The last 4096 bytes of the guest VRAM contains the generic info for all
	* DualView chunks: sizes and offsets of chunks. This is filled by miniport.
	*
	* Last 4096 bytes of each chunk contain chunk specific data: framebuffer info,
	* etc. This is used exclusively by the corresponding instance of a display
	* driver.
	*
	* The VRAM layout:
	* Last 4096 bytes - Adapter information area.
	* 4096 bytes aligned miniport heap (value specified in the config rouded up).
	* Slack - what left after dividing the VRAM.
	* 4096 bytes aligned framebuffers:
	* last 4096 bytes of each framebuffer is the display information area.
	*
	* The Virtual Graphics Adapter information in the guest VRAM is stored by the
	* guest video driver using structures prepended by VBOXVIDEOINFOHDR.
	*
	* When the guest driver writes dword 0 to the VBE_DISPI_INDEX_VBOX_VIDEO
	* the host starts to process the info. The first element at the start of
	* the 4096 bytes region should be normally be a LINK that points to
	* actual information chain. That way the guest driver can have some
	* fixed layout of the information memory block and just rewrite
	* the link to point to relevant memory chain.
	*
	* The processing stops at the END element.
	*
	* The host can access the memory only when the port IO is processed.
	* All data that will be needed later must be copied from these 4096 bytes.
	* But other VRAM can be used by host until the mode is disabled.
	*
	* The guest driver writes dword 0xffffffff to the VBE_DISPI_INDEX_VBOX_VIDEO
	* to disable the mode.
	*
	* VBE_DISPI_INDEX_VBOX_VIDEO is used to read the configuration information
	* from the host and issue commands to the host.
	*
	* The guest writes the VBE_DISPI_INDEX_VBOX_VIDEO index register, the the
	* following operations with the VBE data register can be performed:
	*
	* Operation Result
	* write 16 bit value NOP
	* read 16 bit value count of monitors
	* write 32 bit value set the vbox cmd value and the cmd processed by the host
	* read 32 bit value result of the last vbox command is returned
	*/

	struct vbva_cmd_hdr {
	s16 x;
	s16 y;
	u16 w;
	u16 h;
	} __packed;

	/*
	* The VBVA ring buffer is suitable for transferring large (< 2GB) amount of
	* data. For example big bitmaps which do not fit to the buffer.
	*
	* Guest starts writing to the buffer by initializing a record entry in the
	* records queue. VBVA_F_RECORD_PARTIAL indicates that the record is being
	* written. As data is written to the ring buffer, the guest increases
	* free_offset.
	*
	* The host reads the records on flushes and processes all completed records.
	* When host encounters situation when only a partial record presents and
	* len_and_flags & ~VBVA_F_RECORD_PARTIAL >= VBVA_RING_BUFFER_SIZE -
	* VBVA_RING_BUFFER_THRESHOLD, the host fetched all record data and updates
	* data_offset. After that on each flush the host continues fetching the data
	* until the record is completed.
	*/

	#define VBVA_RING_BUFFER_SIZE (4194304 - 1024)
	#define VBVA_RING_BUFFER_THRESHOLD (4096)

	#define VBVA_MAX_RECORDS (64)

	#define VBVA_F_MODE_ENABLED 0x00000001u
	#define VBVA_F_MODE_VRDP 0x00000002u
	#define VBVA_F_MODE_VRDP_RESET 0x00000004u
	#define VBVA_F_MODE_VRDP_ORDER_MASK 0x00000008u

	#define VBVA_F_STATE_PROCESSING 0x00010000u

	#define VBVA_F_RECORD_PARTIAL 0x80000000u

	struct vbva_record {
	u32 len_and_flags;
	} __packed;

	/*
	* The minimum HGSMI heap size is PAGE_SIZE (4096 bytes) and is a restriction of
	* the runtime heapsimple API. Use minimum 2 pages here, because the info area
	* also may contain other data (for example hgsmi_host_flags structure).
	*/
	#define VBVA_ADAPTER_INFORMATION_SIZE 65536
	#define VBVA_MIN_BUFFER_SIZE 65536

	/* The value for port IO to let the adapter to interpret the adapter memory. */
	#define VBOX_VIDEO_DISABLE_ADAPTER_MEMORY 0xFFFFFFFF

	/* The value for port IO to let the adapter to interpret the adapter memory. */
	#define VBOX_VIDEO_INTERPRET_ADAPTER_MEMORY 0x00000000

	/*
	* The value for port IO to let the adapter to interpret the display memory.
	* The display number is encoded in low 16 bits.
	*/
	#define VBOX_VIDEO_INTERPRET_DISPLAY_MEMORY_BASE 0x00010000

	struct vbva_host_flags {
	u32 host_events;
	u32 supported_orders;
	} __packed;

	struct vbva_buffer {
	struct vbva_host_flags host_flags;

	/* The offset where the data start in the buffer. */
	u32 data_offset;
	/* The offset where next data must be placed in the buffer. */
	u32 free_offset;

	/* The queue of record descriptions. */
	struct vbva_record records[VBVA_MAX_RECORDS];
	u32 record_first_index;
	u32 record_free_index;

	/* Space to leave free when large partial records are transferred. */
	u32 partial_write_tresh;

	u32 data_len;
	/* variable size for the rest of the vbva_buffer area in VRAM. */
	u8 data[0];
	} __packed;

	#define VBVA_MAX_RECORD_SIZE (128 * 1024 * 1024)

	/* guest->host commands */
	#define VBVA_QUERY_CONF32 1
	#define VBVA_SET_CONF32 2
	#define VBVA_INFO_VIEW 3
	#define VBVA_INFO_HEAP 4
	#define VBVA_FLUSH 5
	#define VBVA_INFO_SCREEN 6
	#define VBVA_ENABLE 7
	#define VBVA_MOUSE_POINTER_SHAPE 8
	/* informs host about HGSMI caps. see vbva_caps below */
	#define VBVA_INFO_CAPS 12
	/* configures scanline, see VBVASCANLINECFG below */
	#define VBVA_SCANLINE_CFG 13
	/* requests scanline info, see VBVASCANLINEINFO below */
	#define VBVA_SCANLINE_INFO 14
	/* inform host about VBVA Command submission */
	#define VBVA_CMDVBVA_SUBMIT 16
	/* inform host about VBVA Command submission */
	#define VBVA_CMDVBVA_FLUSH 17
	/* G->H DMA command */
	#define VBVA_CMDVBVA_CTL 18
	/* Query most recent mode hints sent */
	#define VBVA_QUERY_MODE_HINTS 19
	/*
	* Report the guest virtual desktop position and size for mapping host and
	* guest pointer positions.
	*/
	#define VBVA_REPORT_INPUT_MAPPING 20
	/* Report the guest cursor position and query the host position. */
	#define VBVA_CURSOR_POSITION 21

	/* host->guest commands */
	#define VBVAHG_EVENT 1
	#define VBVAHG_DISPLAY_CUSTOM 2

	/* vbva_conf32::index */
	#define VBOX_VBVA_CONF32_MONITOR_COUNT 0
	#define VBOX_VBVA_CONF32_HOST_HEAP_SIZE 1
	/*
	* Returns VINF_SUCCESS if the host can report mode hints via VBVA.
	* Set value to VERR_NOT_SUPPORTED before calling.
	*/
	#define VBOX_VBVA_CONF32_MODE_HINT_REPORTING 2
	/*
	* Returns VINF_SUCCESS if the host can report guest cursor enabled status via
	* VBVA. Set value to VERR_NOT_SUPPORTED before calling.
	*/
	#define VBOX_VBVA_CONF32_GUEST_CURSOR_REPORTING 3
	/*
	* Returns the currently available host cursor capabilities. Available if
	* VBOX_VBVA_CONF32_GUEST_CURSOR_REPORTING returns success.
	*/
	#define VBOX_VBVA_CONF32_CURSOR_CAPABILITIES 4
	/* Returns the supported flags in vbva_infoscreen.flags. */
	#define VBOX_VBVA_CONF32_SCREEN_FLAGS 5
	/* Returns the max size of VBVA record. */
	#define VBOX_VBVA_CONF32_MAX_RECORD_SIZE 6

	struct vbva_conf32 {
	u32 index;
	u32 value;
	} __packed;

	/* Reserved for historical reasons. */
	#define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED0 BIT(0)
	/*
	* Guest cursor capability: can the host show a hardware cursor at the host
	* pointer location?
	*/
	#define VBOX_VBVA_CURSOR_CAPABILITY_HARDWARE BIT(1)
	/* Reserved for historical reasons. */
	#define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED2 BIT(2)
	/* Reserved for historical reasons. Must always be unset. */
	#define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED3 BIT(3)
	/* Reserved for historical reasons. */
	#define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED4 BIT(4)
	/* Reserved for historical reasons. */
	#define VBOX_VBVA_CURSOR_CAPABILITY_RESERVED5 BIT(5)

	struct vbva_infoview {
	/* Index of the screen, assigned by the guest. */
	u32 view_index;

	/* The screen offset in VRAM, the framebuffer starts here. */
	u32 view_offset;

	/* The size of the VRAM memory that can be used for the view. */
	u32 view_size;

	/* The recommended maximum size of the VRAM memory for the screen. */
	u32 max_screen_size;
	} __packed;

	struct vbva_flush {
	u32 reserved;
	} __packed;

	/* vbva_infoscreen.flags */
	#define VBVA_SCREEN_F_NONE 0x0000
	#define VBVA_SCREEN_F_ACTIVE 0x0001
	/*
	* The virtual monitor has been disabled by the guest and should be removed
	* by the host and ignored for purposes of pointer position calculation.
	*/
	#define VBVA_SCREEN_F_DISABLED 0x0002
	/*
	* The virtual monitor has been blanked by the guest and should be blacked
	* out by the host using width, height, etc values from the vbva_infoscreen
	* request.
	*/
	#define VBVA_SCREEN_F_BLANK 0x0004
	/*
	* The virtual monitor has been blanked by the guest and should be blacked
	* out by the host using the previous mode values for width. height, etc.
	*/
	#define VBVA_SCREEN_F_BLANK2 0x0008

	struct vbva_infoscreen {
	/* Which view contains the screen. */
	u32 view_index;

	/* Physical X origin relative to the primary screen. */
	s32 origin_x;

	/* Physical Y origin relative to the primary screen. */
	s32 origin_y;

	/* Offset of visible framebuffer relative to the framebuffer start. */
	u32 start_offset;

	/* The scan line size in bytes. */
	u32 line_size;

	/* Width of the screen. */
	u32 width;

	/* Height of the screen. */
	u32 height;

	/* Color depth. */
	u16 bits_per_pixel;

	/* VBVA_SCREEN_F_* */
	u16 flags;
	} __packed;

	/* vbva_enable.flags */
	#define VBVA_F_NONE 0x00000000
	#define VBVA_F_ENABLE 0x00000001
	#define VBVA_F_DISABLE 0x00000002
	/* extended VBVA to be used with WDDM */
	#define VBVA_F_EXTENDED 0x00000004
	/* vbva offset is absolute VRAM offset */
	#define VBVA_F_ABSOFFSET 0x00000008

	struct vbva_enable {
	u32 flags;
	u32 offset;
	s32 result;
	} __packed;

	struct vbva_enable_ex {
	struct vbva_enable base;
	u32 screen_id;
	} __packed;

	struct vbva_mouse_pointer_shape {
	/* The host result. */
	s32 result;

	/* VBOX_MOUSE_POINTER_* bit flags. */
	u32 flags;

	/* X coordinate of the hot spot. */
	u32 hot_X;

	/* Y coordinate of the hot spot. */
	u32 hot_y;

	/* Width of the pointer in pixels. */
	u32 width;

	/* Height of the pointer in scanlines. */
	u32 height;

	/* Pointer data.
	*
	* The data consists of 1 bpp AND mask followed by 32 bpp XOR (color)
	* mask.
	*
	* For pointers without alpha channel the XOR mask pixels are 32 bit
	* values: (lsb)BGR0(msb). For pointers with alpha channel the XOR mask
	* consists of (lsb)BGRA(msb) 32 bit values.
	*
	* Guest driver must create the AND mask for pointers with alpha chan.,
	* so if host does not support alpha, the pointer could be displayed as
	* a normal color pointer. The AND mask can be constructed from alpha
	* values. For example alpha value >= 0xf0 means bit 0 in the AND mask.
	*
	* The AND mask is 1 bpp bitmap with byte aligned scanlines. Size of AND
	* mask, therefore, is and_len = (width + 7) / 8 * height. The padding
	* bits at the end of any scanline are undefined.
	*
	* The XOR mask follows the AND mask on the next 4 bytes aligned offset:
	* u8 *xor = and + (and_len + 3) & ~3
	* Bytes in the gap between the AND and the XOR mask are undefined.
	* XOR mask scanlines have no gap between them and size of XOR mask is:
	* xor_len = width * 4 * height.
	*
	* Preallocate 4 bytes for accessing actual data as p->data.
	*/
	u8 data[4];
	} __packed;

	/* pointer is visible */
	#define VBOX_MOUSE_POINTER_VISIBLE 0x0001
	/* pointer has alpha channel */
	#define VBOX_MOUSE_POINTER_ALPHA 0x0002
	/* pointerData contains new pointer shape */
	#define VBOX_MOUSE_POINTER_SHAPE 0x0004

	/*
	* The guest driver can handle asynch guest cmd completion by reading the
	* command offset from io port.
	*/
	#define VBVACAPS_COMPLETEGCMD_BY_IOREAD 0x00000001
	/* the guest driver can handle video adapter IRQs */
	#define VBVACAPS_IRQ 0x00000002
	/* The guest can read video mode hints sent via VBVA. */
	#define VBVACAPS_VIDEO_MODE_HINTS 0x00000004
	/* The guest can switch to a software cursor on demand. */
	#define VBVACAPS_DISABLE_CURSOR_INTEGRATION 0x00000008
	/* The guest does not depend on host handling the VBE registers. */
	#define VBVACAPS_USE_VBVA_ONLY 0x00000010

	struct vbva_caps {
	s32 rc;
	u32 caps;
	} __packed;

	/* Query the most recent mode hints received from the host. */
	struct vbva_query_mode_hints {
	/* The maximum number of screens to return hints for. */
	u16 hints_queried_count;
	/* The size of the mode hint structures directly following this one. */
	u16 hint_structure_guest_size;
	/* Return code for the operation. Initialise to VERR_NOT_SUPPORTED. */
	s32 rc;
	} __packed;

	/*
	* Structure in which a mode hint is returned. The guest allocates an array
	* of these immediately after the vbva_query_mode_hints structure.
	* To accommodate future extensions, the vbva_query_mode_hints structure
	* specifies the size of the vbva_modehint structures allocated by the guest,
	* and the host only fills out structure elements which fit into that size. The
	* host should fill any unused members (e.g. dx, dy) or structure space on the
	* end with ~0. The whole structure can legally be set to ~0 to skip a screen.
	*/
	struct vbva_modehint {
	u32 magic;
	u32 cx;
	u32 cy;
	u32 bpp; /* Which has never been used... */
	u32 display;
	u32 dx; /* X offset into the virtual frame-buffer. */
	u32 dy; /* Y offset into the virtual frame-buffer. */
	u32 enabled; /* Not flags. Add new members for new flags. */
	} __packed;

	#define VBVAMODEHINT_MAGIC 0x0801add9u

	/*
	* Report the rectangle relative to which absolute pointer events should be
	* expressed. This information remains valid until the next VBVA resize event
	* for any screen, at which time it is reset to the bounding rectangle of all
	* virtual screens and must be re-set.
	*/
	struct vbva_report_input_mapping {
	s32 x; /* Upper left X co-ordinate relative to the first screen. */
	s32 y; /* Upper left Y co-ordinate relative to the first screen. */
	u32 cx; /* Rectangle width. */
	u32 cy; /* Rectangle height. */
	} __packed;

	/*
	* Report the guest cursor position and query the host one. The host may wish
	* to use the guest information to re-position its own cursor (though this is
	* currently unlikely).
	*/
	struct vbva_cursor_position {
	u32 report_position; /* Are we reporting a position? */
	u32 x; /* Guest cursor X position */
	u32 y; /* Guest cursor Y position */
	} __packed;

	#endif