drivers/staging/android/uapi/vsoc_shm.h - linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0 */
 /*
  * Copyright (C) 2017 Google, Inc.
  *
  */

 #ifndef _UAPI_LINUX_VSOC_SHM_H
 #define _UAPI_LINUX_VSOC_SHM_H

 #include <linux/types.h>

 /**
  * A permission is a token that permits a receiver to read and/or write an area
  * of memory within a Vsoc region.
  *
  * An fd_scoped permission grants both read and write access, and can be
  * attached to a file description (see open(2)).
  * Ownership of the area can then be shared by passing a file descriptor
  * among processes.
  *
  * begin_offset and end_offset define the area of memory that is controlled by
  * the permission. owner_offset points to a word, also in shared memory, that
  * controls ownership of the area.
  *
  * ownership of the region expires when the associated file description is
  * released.
  *
  * At most one permission can be attached to each file description.
  *
  * This is useful when implementing HALs like gralloc that scope and pass
  * ownership of shared resources via file descriptors.
  *
  * The caller is responsibe for doing any fencing.
  *
  * The calling process will normally identify a currently free area of
  * memory. It will construct a proposed fd_scoped_permission_arg structure:
  *
  *   begin_offset and end_offset describe the area being claimed
  *
  *   owner_offset points to the location in shared memory that indicates the
  *   owner of the area.
  *
  *   owned_value is the value that will be stored in owner_offset iff the
  *   permission can be granted. It must be different than VSOC_REGION_FREE.
  *
  * Two fd_scoped_permission structures are compatible if they vary only by
  * their owned_value fields.
  *
  * The driver ensures that, for any group of simultaneous callers proposing
  * compatible fd_scoped_permissions, it will accept exactly one of the
  * propopsals. The other callers will get a failure with errno of EAGAIN.
  *
  * A process receiving a file descriptor can identify the region being
  * granted using the VSOC_GET_FD_SCOPED_PERMISSION ioctl.
  */
 struct fd_scoped_permission {
 	__u32 begin_offset;
 	__u32 end_offset;
 	__u32 owner_offset;
 	__u32 owned_value;
 };

 /*
  * This value represents a free area of memory. The driver expects to see this
  * value at owner_offset when creating a permission otherwise it will not do it,
  * and will write this value back once the permission is no longer needed.
  */
 #define VSOC_REGION_FREE ((__u32)0)

 /**
  * ioctl argument for VSOC_CREATE_FD_SCOPE_PERMISSION
  */
 struct fd_scoped_permission_arg {
 	struct fd_scoped_permission perm;
 	__s32 managed_region_fd;
 };

 #define VSOC_NODE_FREE ((__u32)0)

 /*
  * Describes a signal table in shared memory. Each non-zero entry in the
  * table indicates that the receiver should signal the futex at the given
  * offset. Offsets are relative to the region, not the shared memory window.
  *
  * interrupt_signalled_offset is used to reliably signal interrupts across the
  * vmm boundary. There are two roles: transmitter and receiver. For example,
  * in the host_to_guest_signal_table the host is the transmitter and the
  * guest is the receiver. The protocol is as follows:
  *
  * 1. The transmitter should convert the offset of the futex to an offset
  *    in the signal table [0, (1 << num_nodes_lg2))
  *    The transmitter can choose any appropriate hashing algorithm, including
  *    hash = futex_offset & ((1 << num_nodes_lg2) - 1)
  *
  * 3. The transmitter should atomically compare and swap futex_offset with 0
  *    at hash. There are 3 possible outcomes
  *      a. The swap fails because the futex_offset is already in the table.
  *         The transmitter should stop.
  *      b. Some other offset is in the table. This is a hash collision. The
  *         transmitter should move to another table slot and try again. One
  *         possible algorithm:
  *         hash = (hash + 1) & ((1 << num_nodes_lg2) - 1)
  *      c. The swap worked. Continue below.
  *
  * 3. The transmitter atomically swaps 1 with the value at the
  *    interrupt_signalled_offset. There are two outcomes:
  *      a. The prior value was 1. In this case an interrupt has already been
  *         posted. The transmitter is done.
  *      b. The prior value was 0, indicating that the receiver may be sleeping.
  *         The transmitter will issue an interrupt.
  *
  * 4. On waking the receiver immediately exchanges a 0 with the
  *    interrupt_signalled_offset. If it receives a 0 then this a spurious
  *    interrupt. That may occasionally happen in the current protocol, but
  *    should be rare.
  *
  * 5. The receiver scans the signal table by atomicaly exchanging 0 at each
  *    location. If a non-zero offset is returned from the exchange the
  *    receiver wakes all sleepers at the given offset:
  *      futex((int*)(region_base + old_value), FUTEX_WAKE, MAX_INT);
  *
  * 6. The receiver thread then does a conditional wait, waking immediately
  *    if the value at interrupt_signalled_offset is non-zero. This catches cases
  *    here additional  signals were posted while the table was being scanned.
  *    On the guest the wait is handled via the VSOC_WAIT_FOR_INCOMING_INTERRUPT
  *    ioctl.
  */
 struct vsoc_signal_table_layout {
 	/* log_2(Number of signal table entries) */
 	__u32 num_nodes_lg2;
 	/*
 	 * Offset to the first signal table entry relative to the start of the
 	 * region
 	 */
 	__u32 futex_uaddr_table_offset;
 	/*
 	 * Offset to an atomic_t / atomic uint32_t. A non-zero value indicates
 	 * that one or more offsets are currently posted in the table.
 	 * semi-unique access to an entry in the table
 	 */
 	__u32 interrupt_signalled_offset;
 };

 #define VSOC_REGION_WHOLE ((__s32)0)
 #define VSOC_DEVICE_NAME_SZ 16

 /**
  * Each HAL would (usually) talk to a single device region
  * Mulitple entities care about these regions:
  * - The ivshmem_server will populate the regions in shared memory
  * - The guest kernel will read the region, create minor device nodes, and
  *   allow interested parties to register for FUTEX_WAKE events in the region
  * - HALs will access via the minor device nodes published by the guest kernel
  * - Host side processes will access the region via the ivshmem_server:
  *   1. Pass name to ivshmem_server at a UNIX socket
  *   2. ivshmemserver will reply with 2 fds:
  *     - host->guest doorbell fd
  *     - guest->host doorbell fd
  *     - fd for the shared memory region
  *     - region offset
  *   3. Start a futex receiver thread on the doorbell fd pointed at the
  *      signal_nodes
  */
 struct vsoc_device_region {
 	__u16 current_version;
 	__u16 min_compatible_version;
 	__u32 region_begin_offset;
 	__u32 region_end_offset;
 	__u32 offset_of_region_data;
 	struct vsoc_signal_table_layout guest_to_host_signal_table;
 	struct vsoc_signal_table_layout host_to_guest_signal_table;
 	/* Name of the device. Must always be terminated with a '\0', so
 	 * the longest supported device name is 15 characters.
 	 */
 	char device_name[VSOC_DEVICE_NAME_SZ];
 	/* There are two ways that permissions to access regions are handled:
 	 *   - When subdivided_by is VSOC_REGION_WHOLE, any process that can
 	 *     open the device node for the region gains complete access to it.
 	 *   - When subdivided is set processes that open the region cannot
 	 *     access it. Access to a sub-region must be established by invoking
 	 *     the VSOC_CREATE_FD_SCOPE_PERMISSION ioctl on the region
 	 *     referenced in subdivided_by, providing a fileinstance
 	 *     (represented by a fd) opened on this region.
 	 */
 	__u32 managed_by;
 };

 /*
  * The vsoc layout descriptor.
  * The first 4K should be reserved for the shm header and region descriptors.
  * The regions should be page aligned.
  */

 struct vsoc_shm_layout_descriptor {
 	__u16 major_version;
 	__u16 minor_version;

 	/* size of the shm. This may be redundant but nice to have */
 	__u32 size;

 	/* number of shared memory regions */
 	__u32 region_count;

 	/* The offset to the start of region descriptors */
 	__u32 vsoc_region_desc_offset;
 };

 /*
  * This specifies the current version that should be stored in
  * vsoc_shm_layout_descriptor.major_version and
  * vsoc_shm_layout_descriptor.minor_version.
  * It should be updated only if the vsoc_device_region and
  * vsoc_shm_layout_descriptor structures have changed.
  * Versioning within each region is transferred
  * via the min_compatible_version and current_version fields in
  * vsoc_device_region. The driver does not consult these fields: they are left
  * for the HALs and host processes and will change independently of the layout
  * version.
  */
 #define CURRENT_VSOC_LAYOUT_MAJOR_VERSION 2
 #define CURRENT_VSOC_LAYOUT_MINOR_VERSION 0

 #define VSOC_CREATE_FD_SCOPED_PERMISSION \
 	_IOW(0xF5, 0, struct fd_scoped_permission)
 #define VSOC_GET_FD_SCOPED_PERMISSION _IOR(0xF5, 1, struct fd_scoped_permission)

 /*
  * This is used to signal the host to scan the guest_to_host_signal_table
  * for new futexes to wake. This sends an interrupt if one is not already
  * in flight.
  */
 #define VSOC_MAYBE_SEND_INTERRUPT_TO_HOST _IO(0xF5, 2)

 /*
  * When this returns the guest will scan host_to_guest_signal_table to
  * check for new futexes to wake.
  */
 /* TODO(ghartman): Consider moving this to the bottom half */
 #define VSOC_WAIT_FOR_INCOMING_INTERRUPT _IO(0xF5, 3)

 /*
  * Guest HALs will use this to retrieve the region description after
  * opening their device node.
  */
 #define VSOC_DESCRIBE_REGION _IOR(0xF5, 4, struct vsoc_device_region)

 /*
  * Wake any threads that may be waiting for a host interrupt on this region.
  * This is mostly used during shutdown.
  */
 #define VSOC_SELF_INTERRUPT _IO(0xF5, 5)

 /*
  * This is used to signal the host to scan the guest_to_host_signal_table
  * for new futexes to wake. This sends an interrupt unconditionally.
  */
 #define VSOC_SEND_INTERRUPT_TO_HOST _IO(0xF5, 6)

 enum wait_types {
 	VSOC_WAIT_UNDEFINED = 0,
 	VSOC_WAIT_IF_EQUAL = 1,
 	VSOC_WAIT_IF_EQUAL_TIMEOUT = 2
 };

 /*
  * Wait for a condition to be true
  *
  * Note, this is sized and aligned so the 32 bit and 64 bit layouts are
  * identical.
  */
 struct vsoc_cond_wait {
 	/* Input: Offset of the 32 bit word to check */
 	__u32 offset;
 	/* Input: Value that will be compared with the offset */
 	__u32 value;
 	/* Monotonic time to wake at in seconds */
 	__u64 wake_time_sec;
 	/* Input: Monotonic time to wait in nanoseconds */
 	__u32 wake_time_nsec;
 	/* Input: Type of wait */
 	__u32 wait_type;
 	/* Output: Number of times the thread woke before returning. */
 	__u32 wakes;
 	/* Ensure that we're 8-byte aligned and 8 byte length for 32/64 bit
 	 * compatibility.
 	 */
 	__u32 reserved_1;
 };

 #define VSOC_COND_WAIT _IOWR(0xF5, 7, struct vsoc_cond_wait)

 /* Wake any local threads waiting at the offset given in arg */
 #define VSOC_COND_WAKE _IO(0xF5, 8)

 #endif /* _UAPI_LINUX_VSOC_SHM_H */
	/* SPDX-License-Identifier: GPL-2.0 */
	/*
	* Copyright (C) 2017 Google, Inc.
	*
	*/

	#ifndef _UAPI_LINUX_VSOC_SHM_H
	#define _UAPI_LINUX_VSOC_SHM_H

	#include <linux/types.h>

	/**
	* A permission is a token that permits a receiver to read and/or write an area
	* of memory within a Vsoc region.
	*
	* An fd_scoped permission grants both read and write access, and can be
	* attached to a file description (see open(2)).
	* Ownership of the area can then be shared by passing a file descriptor
	* among processes.
	*
	* begin_offset and end_offset define the area of memory that is controlled by
	* the permission. owner_offset points to a word, also in shared memory, that
	* controls ownership of the area.
	*
	* ownership of the region expires when the associated file description is
	* released.
	*
	* At most one permission can be attached to each file description.
	*
	* This is useful when implementing HALs like gralloc that scope and pass
	* ownership of shared resources via file descriptors.
	*
	* The caller is responsibe for doing any fencing.
	*
	* The calling process will normally identify a currently free area of
	* memory. It will construct a proposed fd_scoped_permission_arg structure:
	*
	* begin_offset and end_offset describe the area being claimed
	*
	* owner_offset points to the location in shared memory that indicates the
	* owner of the area.
	*
	* owned_value is the value that will be stored in owner_offset iff the
	* permission can be granted. It must be different than VSOC_REGION_FREE.
	*
	* Two fd_scoped_permission structures are compatible if they vary only by
	* their owned_value fields.
	*
	* The driver ensures that, for any group of simultaneous callers proposing
	* compatible fd_scoped_permissions, it will accept exactly one of the
	* propopsals. The other callers will get a failure with errno of EAGAIN.
	*
	* A process receiving a file descriptor can identify the region being
	* granted using the VSOC_GET_FD_SCOPED_PERMISSION ioctl.
	*/
	struct fd_scoped_permission {
	__u32 begin_offset;
	__u32 end_offset;
	__u32 owner_offset;
	__u32 owned_value;
	};

	/*
	* This value represents a free area of memory. The driver expects to see this
	* value at owner_offset when creating a permission otherwise it will not do it,
	* and will write this value back once the permission is no longer needed.
	*/
	#define VSOC_REGION_FREE ((__u32)0)

	/**
	* ioctl argument for VSOC_CREATE_FD_SCOPE_PERMISSION
	*/
	struct fd_scoped_permission_arg {
	struct fd_scoped_permission perm;
	__s32 managed_region_fd;
	};

	#define VSOC_NODE_FREE ((__u32)0)

	/*
	* Describes a signal table in shared memory. Each non-zero entry in the
	* table indicates that the receiver should signal the futex at the given
	* offset. Offsets are relative to the region, not the shared memory window.
	*
	* interrupt_signalled_offset is used to reliably signal interrupts across the
	* vmm boundary. There are two roles: transmitter and receiver. For example,
	* in the host_to_guest_signal_table the host is the transmitter and the
	* guest is the receiver. The protocol is as follows:
	*
	* 1. The transmitter should convert the offset of the futex to an offset
	* in the signal table [0, (1 << num_nodes_lg2))
	* The transmitter can choose any appropriate hashing algorithm, including
	* hash = futex_offset & ((1 << num_nodes_lg2) - 1)
	*
	* 3. The transmitter should atomically compare and swap futex_offset with 0
	* at hash. There are 3 possible outcomes
	* a. The swap fails because the futex_offset is already in the table.
	* The transmitter should stop.
	* b. Some other offset is in the table. This is a hash collision. The
	* transmitter should move to another table slot and try again. One
	* possible algorithm:
	* hash = (hash + 1) & ((1 << num_nodes_lg2) - 1)
	* c. The swap worked. Continue below.
	*
	* 3. The transmitter atomically swaps 1 with the value at the
	* interrupt_signalled_offset. There are two outcomes:
	* a. The prior value was 1. In this case an interrupt has already been
	* posted. The transmitter is done.
	* b. The prior value was 0, indicating that the receiver may be sleeping.
	* The transmitter will issue an interrupt.
	*
	* 4. On waking the receiver immediately exchanges a 0 with the
	* interrupt_signalled_offset. If it receives a 0 then this a spurious
	* interrupt. That may occasionally happen in the current protocol, but
	* should be rare.
	*
	* 5. The receiver scans the signal table by atomicaly exchanging 0 at each
	* location. If a non-zero offset is returned from the exchange the
	* receiver wakes all sleepers at the given offset:
	* futex((int*)(region_base + old_value), FUTEX_WAKE, MAX_INT);
	*
	* 6. The receiver thread then does a conditional wait, waking immediately
	* if the value at interrupt_signalled_offset is non-zero. This catches cases
	* here additional signals were posted while the table was being scanned.
	* On the guest the wait is handled via the VSOC_WAIT_FOR_INCOMING_INTERRUPT
	* ioctl.
	*/
	struct vsoc_signal_table_layout {
	/* log_2(Number of signal table entries) */
	__u32 num_nodes_lg2;
	/*
	* Offset to the first signal table entry relative to the start of the
	* region
	*/
	__u32 futex_uaddr_table_offset;
	/*
	* Offset to an atomic_t / atomic uint32_t. A non-zero value indicates
	* that one or more offsets are currently posted in the table.
	* semi-unique access to an entry in the table
	*/
	__u32 interrupt_signalled_offset;
	};

	#define VSOC_REGION_WHOLE ((__s32)0)
	#define VSOC_DEVICE_NAME_SZ 16

	/**
	* Each HAL would (usually) talk to a single device region
	* Mulitple entities care about these regions:
	* - The ivshmem_server will populate the regions in shared memory
	* - The guest kernel will read the region, create minor device nodes, and
	* allow interested parties to register for FUTEX_WAKE events in the region
	* - HALs will access via the minor device nodes published by the guest kernel
	* - Host side processes will access the region via the ivshmem_server:
	* 1. Pass name to ivshmem_server at a UNIX socket
	* 2. ivshmemserver will reply with 2 fds:
	* - host->guest doorbell fd
	* - guest->host doorbell fd
	* - fd for the shared memory region
	* - region offset
	* 3. Start a futex receiver thread on the doorbell fd pointed at the
	* signal_nodes
	*/
	struct vsoc_device_region {
	__u16 current_version;
	__u16 min_compatible_version;
	__u32 region_begin_offset;
	__u32 region_end_offset;
	__u32 offset_of_region_data;
	struct vsoc_signal_table_layout guest_to_host_signal_table;
	struct vsoc_signal_table_layout host_to_guest_signal_table;
	/* Name of the device. Must always be terminated with a '\0', so
	* the longest supported device name is 15 characters.
	*/
	char device_name[VSOC_DEVICE_NAME_SZ];
	/* There are two ways that permissions to access regions are handled:
	* - When subdivided_by is VSOC_REGION_WHOLE, any process that can
	* open the device node for the region gains complete access to it.
	* - When subdivided is set processes that open the region cannot
	* access it. Access to a sub-region must be established by invoking
	* the VSOC_CREATE_FD_SCOPE_PERMISSION ioctl on the region
	* referenced in subdivided_by, providing a fileinstance
	* (represented by a fd) opened on this region.
	*/
	__u32 managed_by;
	};

	/*
	* The vsoc layout descriptor.
	* The first 4K should be reserved for the shm header and region descriptors.
	* The regions should be page aligned.
	*/

	struct vsoc_shm_layout_descriptor {
	__u16 major_version;
	__u16 minor_version;

	/* size of the shm. This may be redundant but nice to have */
	__u32 size;

	/* number of shared memory regions */
	__u32 region_count;

	/* The offset to the start of region descriptors */
	__u32 vsoc_region_desc_offset;
	};

	/*
	* This specifies the current version that should be stored in
	* vsoc_shm_layout_descriptor.major_version and
	* vsoc_shm_layout_descriptor.minor_version.
	* It should be updated only if the vsoc_device_region and
	* vsoc_shm_layout_descriptor structures have changed.
	* Versioning within each region is transferred
	* via the min_compatible_version and current_version fields in
	* vsoc_device_region. The driver does not consult these fields: they are left
	* for the HALs and host processes and will change independently of the layout
	* version.
	*/
	#define CURRENT_VSOC_LAYOUT_MAJOR_VERSION 2
	#define CURRENT_VSOC_LAYOUT_MINOR_VERSION 0

	#define VSOC_CREATE_FD_SCOPED_PERMISSION \
	_IOW(0xF5, 0, struct fd_scoped_permission)
	#define VSOC_GET_FD_SCOPED_PERMISSION _IOR(0xF5, 1, struct fd_scoped_permission)

	/*
	* This is used to signal the host to scan the guest_to_host_signal_table
	* for new futexes to wake. This sends an interrupt if one is not already
	* in flight.
	*/
	#define VSOC_MAYBE_SEND_INTERRUPT_TO_HOST _IO(0xF5, 2)

	/*
	* When this returns the guest will scan host_to_guest_signal_table to
	* check for new futexes to wake.
	*/
	/* TODO(ghartman): Consider moving this to the bottom half */
	#define VSOC_WAIT_FOR_INCOMING_INTERRUPT _IO(0xF5, 3)

	/*
	* Guest HALs will use this to retrieve the region description after
	* opening their device node.
	*/
	#define VSOC_DESCRIBE_REGION _IOR(0xF5, 4, struct vsoc_device_region)

	/*
	* Wake any threads that may be waiting for a host interrupt on this region.
	* This is mostly used during shutdown.
	*/
	#define VSOC_SELF_INTERRUPT _IO(0xF5, 5)

	/*
	* This is used to signal the host to scan the guest_to_host_signal_table
	* for new futexes to wake. This sends an interrupt unconditionally.
	*/
	#define VSOC_SEND_INTERRUPT_TO_HOST _IO(0xF5, 6)

	enum wait_types {
	VSOC_WAIT_UNDEFINED = 0,
	VSOC_WAIT_IF_EQUAL = 1,
	VSOC_WAIT_IF_EQUAL_TIMEOUT = 2
	};

	/*
	* Wait for a condition to be true
	*
	* Note, this is sized and aligned so the 32 bit and 64 bit layouts are
	* identical.
	*/
	struct vsoc_cond_wait {
	/* Input: Offset of the 32 bit word to check */
	__u32 offset;
	/* Input: Value that will be compared with the offset */
	__u32 value;
	/* Monotonic time to wake at in seconds */
	__u64 wake_time_sec;
	/* Input: Monotonic time to wait in nanoseconds */
	__u32 wake_time_nsec;
	/* Input: Type of wait */
	__u32 wait_type;
	/* Output: Number of times the thread woke before returning. */
	__u32 wakes;
	/* Ensure that we're 8-byte aligned and 8 byte length for 32/64 bit
	* compatibility.
	*/
	__u32 reserved_1;
	};

	#define VSOC_COND_WAIT _IOWR(0xF5, 7, struct vsoc_cond_wait)

	/* Wake any local threads waiting at the offset given in arg */
	#define VSOC_COND_WAKE _IO(0xF5, 8)

	#endif /* _UAPI_LINUX_VSOC_SHM_H */