block/keyslot-manager.c - kernel/common - Git at Google

 // SPDX-License-Identifier: GPL-2.0
 /*
  * Copyright 2019 Google LLC
  */

 /**
  * DOC: The Keyslot Manager
  *
  * Many devices with inline encryption support have a limited number of "slots"
  * into which encryption contexts may be programmed, and requests can be tagged
  * with a slot number to specify the key to use for en/decryption.
  *
  * As the number of slots are limited, and programming keys is expensive on
  * many inline encryption hardware, we don't want to program the same key into
  * multiple slots - if multiple requests are using the same key, we want to
  * program just one slot with that key and use that slot for all requests.
  *
  * The keyslot manager manages these keyslots appropriately, and also acts as
  * an abstraction between the inline encryption hardware and the upper layers.
  *
  * Lower layer devices will set up a keyslot manager in their request queue
  * and tell it how to perform device specific operations like programming/
  * evicting keys from keyslots.
  *
  * Upper layers will call keyslot_manager_get_slot_for_key() to program a
  * key into some slot in the inline encryption hardware.
  */
 #include <crypto/algapi.h>
 #include <linux/keyslot-manager.h>
 #include <linux/atomic.h>
 #include <linux/mutex.h>
 #include <linux/pm_runtime.h>
 #include <linux/wait.h>
 #include <linux/blkdev.h>

 struct keyslot {
 	atomic_t slot_refs;
 	struct list_head idle_slot_node;
 	struct hlist_node hash_node;
 	struct blk_crypto_key key;
 };

 struct keyslot_manager {
 	unsigned int num_slots;
 	struct keyslot_mgmt_ll_ops ksm_ll_ops;
 	unsigned int features;
 	unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX];
 	unsigned int max_dun_bytes_supported;
 	void *ll_priv_data;

 #ifdef CONFIG_PM
 	/* Device for runtime power management (NULL if none) */
 	struct device *dev;
 #endif

 	/* Protects programming and evicting keys from the device */
 	struct rw_semaphore lock;

 	/* List of idle slots, with least recently used slot at front */
 	wait_queue_head_t idle_slots_wait_queue;
 	struct list_head idle_slots;
 	spinlock_t idle_slots_lock;

 	/*
 	 * Hash table which maps key hashes to keyslots, so that we can find a
 	 * key's keyslot in O(1) time rather than O(num_slots).  Protected by
 	 * 'lock'.  A cryptographic hash function is used so that timing attacks
 	 * can't leak information about the raw keys.
 	 */
 	struct hlist_head *slot_hashtable;
 	unsigned int slot_hashtable_size;

 	/* Per-keyslot data */
 	struct keyslot slots[];
 };

 static inline bool keyslot_manager_is_passthrough(struct keyslot_manager *ksm)
 {
 	return ksm->num_slots == 0;
 }

 #ifdef CONFIG_PM
 static inline void keyslot_manager_set_dev(struct keyslot_manager *ksm,
 					   struct device *dev)
 {
 	ksm->dev = dev;
 }

 /* If there's an underlying device and it's suspended, resume it. */
 static inline void keyslot_manager_pm_get(struct keyslot_manager *ksm)
 {
 	if (ksm->dev)
 		pm_runtime_get_sync(ksm->dev);
 }

 static inline void keyslot_manager_pm_put(struct keyslot_manager *ksm)
 {
 	if (ksm->dev)
 		pm_runtime_put_sync(ksm->dev);
 }
 #else /* CONFIG_PM */
 static inline void keyslot_manager_set_dev(struct keyslot_manager *ksm,
 					   struct device *dev)
 {
 }

 static inline void keyslot_manager_pm_get(struct keyslot_manager *ksm)
 {
 }

 static inline void keyslot_manager_pm_put(struct keyslot_manager *ksm)
 {
 }
 #endif /* !CONFIG_PM */

 static inline void keyslot_manager_hw_enter(struct keyslot_manager *ksm)
 {
 	/*
 	 * Calling into the driver requires ksm->lock held and the device
 	 * resumed.  But we must resume the device first, since that can acquire
 	 * and release ksm->lock via keyslot_manager_reprogram_all_keys().
 	 */
 	keyslot_manager_pm_get(ksm);
 	down_write(&ksm->lock);
 }

 static inline void keyslot_manager_hw_exit(struct keyslot_manager *ksm)
 {
 	up_write(&ksm->lock);
 	keyslot_manager_pm_put(ksm);
 }

 /**
  * keyslot_manager_create() - Create a keyslot manager
  * @dev: Device for runtime power management (NULL if none)
  * @num_slots: The number of key slots to manage.
  * @ksm_ll_ops: The struct keyslot_mgmt_ll_ops for the device that this keyslot
  *		manager will use to perform operations like programming and
  *		evicting keys.
  * @features: The supported features as a bitmask of BLK_CRYPTO_FEATURE_* flags.
  *	      Most drivers should set BLK_CRYPTO_FEATURE_STANDARD_KEYS here.
  * @crypto_mode_supported:	Array of size BLK_ENCRYPTION_MODE_MAX of
  *				bitmasks that represents whether a crypto mode
  *				and data unit size are supported. The i'th bit
  *				of crypto_mode_supported[crypto_mode] is set iff
  *				a data unit size of (1 << i) is supported. We
  *				only support data unit sizes that are powers of
  *				2.
  * @ll_priv_data: Private data passed as is to the functions in ksm_ll_ops.
  *
  * Allocate memory for and initialize a keyslot manager. Called by e.g.
  * storage drivers to set up a keyslot manager in their request_queue.
  *
  * Context: May sleep
  * Return: Pointer to constructed keyslot manager or NULL on error.
  */
 struct keyslot_manager *keyslot_manager_create(
 	struct device *dev,
 	unsigned int num_slots,
 	const struct keyslot_mgmt_ll_ops *ksm_ll_ops,
 	unsigned int features,
 	const unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX],
 	void *ll_priv_data)
 {
 	struct keyslot_manager *ksm;
 	unsigned int slot;
 	unsigned int i;

 	if (num_slots == 0)
 		return NULL;

 	/* Check that all ops are specified */
 	if (ksm_ll_ops->keyslot_program == NULL ||
 	    ksm_ll_ops->keyslot_evict == NULL)
 		return NULL;

 	ksm = kvzalloc(struct_size(ksm, slots, num_slots), GFP_KERNEL);
 	if (!ksm)
 		return NULL;

 	ksm->num_slots = num_slots;
 	ksm->ksm_ll_ops = *ksm_ll_ops;
 	ksm->features = features;
 	memcpy(ksm->crypto_mode_supported, crypto_mode_supported,
 	       sizeof(ksm->crypto_mode_supported));
 	ksm->max_dun_bytes_supported = BLK_CRYPTO_MAX_IV_SIZE;
 	ksm->ll_priv_data = ll_priv_data;
 	keyslot_manager_set_dev(ksm, dev);

 	init_rwsem(&ksm->lock);

 	init_waitqueue_head(&ksm->idle_slots_wait_queue);
 	INIT_LIST_HEAD(&ksm->idle_slots);

 	for (slot = 0; slot < num_slots; slot++) {
 		list_add_tail(&ksm->slots[slot].idle_slot_node,
 			      &ksm->idle_slots);
 	}

 	spin_lock_init(&ksm->idle_slots_lock);

 	ksm->slot_hashtable_size = roundup_pow_of_two(num_slots);
 	ksm->slot_hashtable = kvmalloc_array(ksm->slot_hashtable_size,
 					     sizeof(ksm->slot_hashtable[0]),
 					     GFP_KERNEL);
 	if (!ksm->slot_hashtable)
 		goto err_free_ksm;
 	for (i = 0; i < ksm->slot_hashtable_size; i++)
 		INIT_HLIST_HEAD(&ksm->slot_hashtable[i]);

 	return ksm;

 err_free_ksm:
 	keyslot_manager_destroy(ksm);
 	return NULL;
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_create);

 void keyslot_manager_set_max_dun_bytes(struct keyslot_manager *ksm,
 				       unsigned int max_dun_bytes)
 {
 	ksm->max_dun_bytes_supported = max_dun_bytes;
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_set_max_dun_bytes);

 static inline struct hlist_head *
 hash_bucket_for_key(struct keyslot_manager *ksm,
 		    const struct blk_crypto_key *key)
 {
 	return &ksm->slot_hashtable[blk_crypto_key_hash(key) &
 				    (ksm->slot_hashtable_size - 1)];
 }

 static void remove_slot_from_lru_list(struct keyslot_manager *ksm, int slot)
 {
 	unsigned long flags;

 	spin_lock_irqsave(&ksm->idle_slots_lock, flags);
 	list_del(&ksm->slots[slot].idle_slot_node);
 	spin_unlock_irqrestore(&ksm->idle_slots_lock, flags);
 }

 static int find_keyslot(struct keyslot_manager *ksm,
 			const struct blk_crypto_key *key)
 {
 	const struct hlist_head *head = hash_bucket_for_key(ksm, key);
 	const struct keyslot *slotp;

 	hlist_for_each_entry(slotp, head, hash_node) {
 		if (slotp->key.hash == key->hash &&
 		    slotp->key.crypto_mode == key->crypto_mode &&
 		    slotp->key.size == key->size &&
 		    slotp->key.data_unit_size == key->data_unit_size &&
 		    !crypto_memneq(slotp->key.raw, key->raw, key->size))
 			return slotp - ksm->slots;
 	}
 	return -ENOKEY;
 }

 static int find_and_grab_keyslot(struct keyslot_manager *ksm,
 				 const struct blk_crypto_key *key)
 {
 	int slot;

 	slot = find_keyslot(ksm, key);
 	if (slot < 0)
 		return slot;
 	if (atomic_inc_return(&ksm->slots[slot].slot_refs) == 1) {
 		/* Took first reference to this slot; remove it from LRU list */
 		remove_slot_from_lru_list(ksm, slot);
 	}
 	return slot;
 }

 /**
  * keyslot_manager_get_slot_for_key() - Program a key into a keyslot.
  * @ksm: The keyslot manager to program the key into.
  * @key: Pointer to the key object to program, including the raw key, crypto
  *	 mode, and data unit size.
  *
  * Get a keyslot that's been programmed with the specified key.  If one already
  * exists, return it with incremented refcount.  Otherwise, wait for a keyslot
  * to become idle and program it.
  *
  * Context: Process context. Takes and releases ksm->lock.
  * Return: The keyslot on success, else a -errno value.
  */
 int keyslot_manager_get_slot_for_key(struct keyslot_manager *ksm,
 				     const struct blk_crypto_key *key)
 {
 	int slot;
 	int err;
 	struct keyslot *idle_slot;

 	if (keyslot_manager_is_passthrough(ksm))
 		return 0;

 	down_read(&ksm->lock);
 	slot = find_and_grab_keyslot(ksm, key);
 	up_read(&ksm->lock);
 	if (slot != -ENOKEY)
 		return slot;

 	for (;;) {
 		keyslot_manager_hw_enter(ksm);
 		slot = find_and_grab_keyslot(ksm, key);
 		if (slot != -ENOKEY) {
 			keyslot_manager_hw_exit(ksm);
 			return slot;
 		}

 		/*
 		 * If we're here, that means there wasn't a slot that was
 		 * already programmed with the key. So try to program it.
 		 */
 		if (!list_empty(&ksm->idle_slots))
 			break;

 		keyslot_manager_hw_exit(ksm);
 		wait_event(ksm->idle_slots_wait_queue,
 			   !list_empty(&ksm->idle_slots));
 	}

 	idle_slot = list_first_entry(&ksm->idle_slots, struct keyslot,
 					     idle_slot_node);
 	slot = idle_slot - ksm->slots;

 	err = ksm->ksm_ll_ops.keyslot_program(ksm, key, slot);
 	if (err) {
 		wake_up(&ksm->idle_slots_wait_queue);
 		keyslot_manager_hw_exit(ksm);
 		return err;
 	}

 	/* Move this slot to the hash list for the new key. */
 	if (idle_slot->key.crypto_mode != BLK_ENCRYPTION_MODE_INVALID)
 		hlist_del(&idle_slot->hash_node);
 	hlist_add_head(&idle_slot->hash_node, hash_bucket_for_key(ksm, key));

 	atomic_set(&idle_slot->slot_refs, 1);
 	idle_slot->key = *key;

 	remove_slot_from_lru_list(ksm, slot);

 	keyslot_manager_hw_exit(ksm);
 	return slot;
 }

 /**
  * keyslot_manager_get_slot() - Increment the refcount on the specified slot.
  * @ksm: The keyslot manager that we want to modify.
  * @slot: The slot to increment the refcount of.
  *
  * This function assumes that there is already an active reference to that slot
  * and simply increments the refcount. This is useful when cloning a bio that
  * already has a reference to a keyslot, and we want the cloned bio to also have
  * its own reference.
  *
  * Context: Any context.
  */
 void keyslot_manager_get_slot(struct keyslot_manager *ksm, unsigned int slot)
 {
 	if (keyslot_manager_is_passthrough(ksm))
 		return;

 	if (WARN_ON(slot >= ksm->num_slots))
 		return;

 	WARN_ON(atomic_inc_return(&ksm->slots[slot].slot_refs) < 2);
 }

 /**
  * keyslot_manager_put_slot() - Release a reference to a slot
  * @ksm: The keyslot manager to release the reference from.
  * @slot: The slot to release the reference from.
  *
  * Context: Any context.
  */
 void keyslot_manager_put_slot(struct keyslot_manager *ksm, unsigned int slot)
 {
 	unsigned long flags;

 	if (keyslot_manager_is_passthrough(ksm))
 		return;

 	if (WARN_ON(slot >= ksm->num_slots))
 		return;

 	if (atomic_dec_and_lock_irqsave(&ksm->slots[slot].slot_refs,
 					&ksm->idle_slots_lock, flags)) {
 		list_add_tail(&ksm->slots[slot].idle_slot_node,
 			      &ksm->idle_slots);
 		spin_unlock_irqrestore(&ksm->idle_slots_lock, flags);
 		wake_up(&ksm->idle_slots_wait_queue);
 	}
 }

 /**
  * keyslot_manager_crypto_mode_supported() - Find out if a crypto_mode /
  *					     data unit size / is_hw_wrapped_key
  *					     combination is supported by a ksm.
  * @ksm: The keyslot manager to check
  * @crypto_mode: The crypto mode to check for.
  * @dun_bytes: The number of bytes that will be used to specify the DUN
  * @data_unit_size: The data_unit_size for the mode.
  * @is_hw_wrapped_key: Whether a hardware-wrapped key will be used.
  *
  * Calls and returns the result of the crypto_mode_supported function specified
  * by the ksm.
  *
  * Context: Process context.
  * Return: Whether or not this ksm supports the specified crypto settings.
  */
 bool keyslot_manager_crypto_mode_supported(struct keyslot_manager *ksm,
 					   enum blk_crypto_mode_num crypto_mode,
 					   unsigned int dun_bytes,
 					   unsigned int data_unit_size,
 					   bool is_hw_wrapped_key)
 {
 	if (!ksm)
 		return false;
 	if (WARN_ON(crypto_mode >= BLK_ENCRYPTION_MODE_MAX))
 		return false;
 	if (WARN_ON(!is_power_of_2(data_unit_size)))
 		return false;
 	if (is_hw_wrapped_key) {
 		if (!(ksm->features & BLK_CRYPTO_FEATURE_WRAPPED_KEYS))
 			return false;
 	} else {
 		if (!(ksm->features & BLK_CRYPTO_FEATURE_STANDARD_KEYS))
 			return false;
 	}
 	if (!(ksm->crypto_mode_supported[crypto_mode] & data_unit_size))
 		return false;

 	return ksm->max_dun_bytes_supported >= dun_bytes;
 }

 /**
  * keyslot_manager_evict_key() - Evict a key from the lower layer device.
  * @ksm: The keyslot manager to evict from
  * @key: The key to evict
  *
  * Find the keyslot that the specified key was programmed into, and evict that
  * slot from the lower layer device if that slot is not currently in use.
  *
  * Context: Process context. Takes and releases ksm->lock.
  * Return: 0 on success, -EBUSY if the key is still in use, or another
  *	   -errno value on other error.
  */
 int keyslot_manager_evict_key(struct keyslot_manager *ksm,
 			      const struct blk_crypto_key *key)
 {
 	int slot;
 	int err;
 	struct keyslot *slotp;

 	if (keyslot_manager_is_passthrough(ksm)) {
 		if (ksm->ksm_ll_ops.keyslot_evict) {
 			keyslot_manager_hw_enter(ksm);
 			err = ksm->ksm_ll_ops.keyslot_evict(ksm, key, -1);
 			keyslot_manager_hw_exit(ksm);
 			return err;
 		}
 		return 0;
 	}

 	keyslot_manager_hw_enter(ksm);

 	slot = find_keyslot(ksm, key);
 	if (slot < 0) {
 		err = slot;
 		goto out_unlock;
 	}
 	slotp = &ksm->slots[slot];

 	if (atomic_read(&slotp->slot_refs) != 0) {
 		err = -EBUSY;
 		goto out_unlock;
 	}
 	err = ksm->ksm_ll_ops.keyslot_evict(ksm, key, slot);
 	if (err)
 		goto out_unlock;

 	hlist_del(&slotp->hash_node);
 	memzero_explicit(&slotp->key, sizeof(slotp->key));
 	err = 0;
 out_unlock:
 	keyslot_manager_hw_exit(ksm);
 	return err;
 }

 /**
  * keyslot_manager_reprogram_all_keys() - Re-program all keyslots.
  * @ksm: The keyslot manager
  *
  * Re-program all keyslots that are supposed to have a key programmed.  This is
  * intended only for use by drivers for hardware that loses its keys on reset.
  *
  * Context: Process context. Takes and releases ksm->lock.
  */
 void keyslot_manager_reprogram_all_keys(struct keyslot_manager *ksm)
 {
 	unsigned int slot;

 	if (WARN_ON(keyslot_manager_is_passthrough(ksm)))
 		return;

 	/* This is for device initialization, so don't resume the device */
 	down_write(&ksm->lock);
 	for (slot = 0; slot < ksm->num_slots; slot++) {
 		const struct keyslot *slotp = &ksm->slots[slot];
 		int err;

 		if (slotp->key.crypto_mode == BLK_ENCRYPTION_MODE_INVALID)
 			continue;

 		err = ksm->ksm_ll_ops.keyslot_program(ksm, &slotp->key, slot);
 		WARN_ON(err);
 	}
 	up_write(&ksm->lock);
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_reprogram_all_keys);

 /**
  * keyslot_manager_private() - return the private data stored with ksm
  * @ksm: The keyslot manager
  *
  * Returns the private data passed to the ksm when it was created.
  */
 void *keyslot_manager_private(struct keyslot_manager *ksm)
 {
 	return ksm->ll_priv_data;
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_private);

 void keyslot_manager_destroy(struct keyslot_manager *ksm)
 {
 	if (ksm) {
 		kvfree(ksm->slot_hashtable);
 		memzero_explicit(ksm, struct_size(ksm, slots, ksm->num_slots));
 		kvfree(ksm);
 	}
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_destroy);

 /**
  * keyslot_manager_create_passthrough() - Create a passthrough keyslot manager
  * @dev: Device for runtime power management (NULL if none)
  * @ksm_ll_ops: The struct keyslot_mgmt_ll_ops
  * @features: Bitmask of BLK_CRYPTO_FEATURE_* flags
  * @crypto_mode_supported: Bitmasks for supported encryption modes
  * @ll_priv_data: Private data passed as is to the functions in ksm_ll_ops.
  *
  * Allocate memory for and initialize a passthrough keyslot manager.
  * Called by e.g. storage drivers to set up a keyslot manager in their
  * request_queue, when the storage driver wants to manage its keys by itself.
  * This is useful for inline encryption hardware that don't have a small fixed
  * number of keyslots, and for layered devices.
  *
  * See keyslot_manager_create() for more details about the parameters.
  *
  * Context: This function may sleep
  * Return: Pointer to constructed keyslot manager or NULL on error.
  */
 struct keyslot_manager *keyslot_manager_create_passthrough(
 	struct device *dev,
 	const struct keyslot_mgmt_ll_ops *ksm_ll_ops,
 	unsigned int features,
 	const unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX],
 	void *ll_priv_data)
 {
 	struct keyslot_manager *ksm;

 	ksm = kzalloc(sizeof(*ksm), GFP_KERNEL);
 	if (!ksm)
 		return NULL;

 	ksm->ksm_ll_ops = *ksm_ll_ops;
 	ksm->features = features;
 	memcpy(ksm->crypto_mode_supported, crypto_mode_supported,
 	       sizeof(ksm->crypto_mode_supported));
 	ksm->max_dun_bytes_supported = BLK_CRYPTO_MAX_IV_SIZE;
 	ksm->ll_priv_data = ll_priv_data;
 	keyslot_manager_set_dev(ksm, dev);

 	init_rwsem(&ksm->lock);

 	return ksm;
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_create_passthrough);

 /**
  * keyslot_manager_intersect_modes() - restrict supported modes by child device
  * @parent: The keyslot manager for parent device
  * @child: The keyslot manager for child device, or NULL
  *
  * Clear any crypto mode support bits in @parent that aren't set in @child.
  * If @child is NULL, then all parent bits are cleared.
  *
  * Only use this when setting up the keyslot manager for a layered device,
  * before it's been exposed yet.
  */
 void keyslot_manager_intersect_modes(struct keyslot_manager *parent,
 				     const struct keyslot_manager *child)
 {
 	if (child) {
 		unsigned int i;

 		parent->features &= child->features;
 		parent->max_dun_bytes_supported =
 			min(parent->max_dun_bytes_supported,
 			    child->max_dun_bytes_supported);
 		for (i = 0; i < ARRAY_SIZE(child->crypto_mode_supported); i++) {
 			parent->crypto_mode_supported[i] &=
 				child->crypto_mode_supported[i];
 		}
 	} else {
 		parent->features = 0;
 		parent->max_dun_bytes_supported = 0;
 		memset(parent->crypto_mode_supported, 0,
 		       sizeof(parent->crypto_mode_supported));
 	}
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_intersect_modes);

 /**
  * keyslot_manager_derive_raw_secret() - Derive software secret from wrapped key
  * @ksm: The keyslot manager
  * @wrapped_key: The wrapped key
  * @wrapped_key_size: Size of the wrapped key in bytes
  * @secret: (output) the software secret
  * @secret_size: (output) the number of secret bytes to derive
  *
  * Given a hardware-wrapped key, ask the hardware to derive a secret which
  * software can use for cryptographic tasks other than inline encryption.  The
  * derived secret is guaranteed to be cryptographically isolated from the key
  * with which any inline encryption with this wrapped key would actually be
  * done.  I.e., both will be derived from the unwrapped key.
  *
  * Return: 0 on success, -EOPNOTSUPP if hardware-wrapped keys are unsupported,
  *	   or another -errno code.
  */
 int keyslot_manager_derive_raw_secret(struct keyslot_manager *ksm,
 				      const u8 *wrapped_key,
 				      unsigned int wrapped_key_size,
 				      u8 *secret, unsigned int secret_size)
 {
 	int err;

 	if (ksm->ksm_ll_ops.derive_raw_secret) {
 		keyslot_manager_hw_enter(ksm);
 		err = ksm->ksm_ll_ops.derive_raw_secret(ksm, wrapped_key,
 							wrapped_key_size,
 							secret, secret_size);
 		keyslot_manager_hw_exit(ksm);
 	} else {
 		err = -EOPNOTSUPP;
 	}

 	return err;
 }
 EXPORT_SYMBOL_GPL(keyslot_manager_derive_raw_secret);
	// SPDX-License-Identifier: GPL-2.0
	/*
	* Copyright 2019 Google LLC
	*/

	/**
	* DOC: The Keyslot Manager
	*
	* Many devices with inline encryption support have a limited number of "slots"
	* into which encryption contexts may be programmed, and requests can be tagged
	* with a slot number to specify the key to use for en/decryption.
	*
	* As the number of slots are limited, and programming keys is expensive on
	* many inline encryption hardware, we don't want to program the same key into
	* multiple slots - if multiple requests are using the same key, we want to
	* program just one slot with that key and use that slot for all requests.
	*
	* The keyslot manager manages these keyslots appropriately, and also acts as
	* an abstraction between the inline encryption hardware and the upper layers.
	*
	* Lower layer devices will set up a keyslot manager in their request queue
	* and tell it how to perform device specific operations like programming/
	* evicting keys from keyslots.
	*
	* Upper layers will call keyslot_manager_get_slot_for_key() to program a
	* key into some slot in the inline encryption hardware.
	*/
	#include <crypto/algapi.h>
	#include <linux/keyslot-manager.h>
	#include <linux/atomic.h>
	#include <linux/mutex.h>
	#include <linux/pm_runtime.h>
	#include <linux/wait.h>
	#include <linux/blkdev.h>

	struct keyslot {
	atomic_t slot_refs;
	struct list_head idle_slot_node;
	struct hlist_node hash_node;
	struct blk_crypto_key key;
	};

	struct keyslot_manager {
	unsigned int num_slots;
	struct keyslot_mgmt_ll_ops ksm_ll_ops;
	unsigned int features;
	unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX];
	unsigned int max_dun_bytes_supported;
	void *ll_priv_data;

	#ifdef CONFIG_PM
	/* Device for runtime power management (NULL if none) */
	struct device *dev;
	#endif

	/* Protects programming and evicting keys from the device */
	struct rw_semaphore lock;

	/* List of idle slots, with least recently used slot at front */
	wait_queue_head_t idle_slots_wait_queue;
	struct list_head idle_slots;
	spinlock_t idle_slots_lock;

	/*
	* Hash table which maps key hashes to keyslots, so that we can find a
	* key's keyslot in O(1) time rather than O(num_slots). Protected by
	* 'lock'. A cryptographic hash function is used so that timing attacks
	* can't leak information about the raw keys.
	*/
	struct hlist_head *slot_hashtable;
	unsigned int slot_hashtable_size;

	/* Per-keyslot data */
	struct keyslot slots[];
	};

	static inline bool keyslot_manager_is_passthrough(struct keyslot_manager *ksm)
	{
	return ksm->num_slots == 0;
	}

	#ifdef CONFIG_PM
	static inline void keyslot_manager_set_dev(struct keyslot_manager *ksm,
	struct device *dev)
	{
	ksm->dev = dev;
	}

	/* If there's an underlying device and it's suspended, resume it. */
	static inline void keyslot_manager_pm_get(struct keyslot_manager *ksm)
	{
	if (ksm->dev)
	pm_runtime_get_sync(ksm->dev);
	}

	static inline void keyslot_manager_pm_put(struct keyslot_manager *ksm)
	{
	if (ksm->dev)
	pm_runtime_put_sync(ksm->dev);
	}
	#else /* CONFIG_PM */
	static inline void keyslot_manager_set_dev(struct keyslot_manager *ksm,
	struct device *dev)
	{
	}

	static inline void keyslot_manager_pm_get(struct keyslot_manager *ksm)
	{
	}

	static inline void keyslot_manager_pm_put(struct keyslot_manager *ksm)
	{
	}
	#endif /* !CONFIG_PM */

	static inline void keyslot_manager_hw_enter(struct keyslot_manager *ksm)
	{
	/*
	* Calling into the driver requires ksm->lock held and the device
	* resumed. But we must resume the device first, since that can acquire
	* and release ksm->lock via keyslot_manager_reprogram_all_keys().
	*/
	keyslot_manager_pm_get(ksm);
	down_write(&ksm->lock);
	}

	static inline void keyslot_manager_hw_exit(struct keyslot_manager *ksm)
	{
	up_write(&ksm->lock);
	keyslot_manager_pm_put(ksm);
	}

	/**
	* keyslot_manager_create() - Create a keyslot manager
	* @dev: Device for runtime power management (NULL if none)
	* @num_slots: The number of key slots to manage.
	* @ksm_ll_ops: The struct keyslot_mgmt_ll_ops for the device that this keyslot
	* manager will use to perform operations like programming and
	* evicting keys.
	* @features: The supported features as a bitmask of BLK_CRYPTO_FEATURE_* flags.
	* Most drivers should set BLK_CRYPTO_FEATURE_STANDARD_KEYS here.
	* @crypto_mode_supported: Array of size BLK_ENCRYPTION_MODE_MAX of
	* bitmasks that represents whether a crypto mode
	* and data unit size are supported. The i'th bit
	* of crypto_mode_supported[crypto_mode] is set iff
	* a data unit size of (1 << i) is supported. We
	* only support data unit sizes that are powers of
	* 2.
	* @ll_priv_data: Private data passed as is to the functions in ksm_ll_ops.
	*
	* Allocate memory for and initialize a keyslot manager. Called by e.g.
	* storage drivers to set up a keyslot manager in their request_queue.
	*
	* Context: May sleep
	* Return: Pointer to constructed keyslot manager or NULL on error.
	*/
	struct keyslot_manager *keyslot_manager_create(
	struct device *dev,
	unsigned int num_slots,
	const struct keyslot_mgmt_ll_ops *ksm_ll_ops,
	unsigned int features,
	const unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX],
	void *ll_priv_data)
	{
	struct keyslot_manager *ksm;
	unsigned int slot;
	unsigned int i;

	if (num_slots == 0)
	return NULL;

	/* Check that all ops are specified */
	if (ksm_ll_ops->keyslot_program == NULL \|\|
	ksm_ll_ops->keyslot_evict == NULL)
	return NULL;

	ksm = kvzalloc(struct_size(ksm, slots, num_slots), GFP_KERNEL);
	if (!ksm)
	return NULL;

	ksm->num_slots = num_slots;
	ksm->ksm_ll_ops = *ksm_ll_ops;
	ksm->features = features;
	memcpy(ksm->crypto_mode_supported, crypto_mode_supported,
	sizeof(ksm->crypto_mode_supported));
	ksm->max_dun_bytes_supported = BLK_CRYPTO_MAX_IV_SIZE;
	ksm->ll_priv_data = ll_priv_data;
	keyslot_manager_set_dev(ksm, dev);

	init_rwsem(&ksm->lock);

	init_waitqueue_head(&ksm->idle_slots_wait_queue);
	INIT_LIST_HEAD(&ksm->idle_slots);

	for (slot = 0; slot < num_slots; slot++) {
	list_add_tail(&ksm->slots[slot].idle_slot_node,
	&ksm->idle_slots);
	}

	spin_lock_init(&ksm->idle_slots_lock);

	ksm->slot_hashtable_size = roundup_pow_of_two(num_slots);
	ksm->slot_hashtable = kvmalloc_array(ksm->slot_hashtable_size,
	sizeof(ksm->slot_hashtable[0]),
	GFP_KERNEL);
	if (!ksm->slot_hashtable)
	goto err_free_ksm;
	for (i = 0; i < ksm->slot_hashtable_size; i++)
	INIT_HLIST_HEAD(&ksm->slot_hashtable[i]);

	return ksm;

	err_free_ksm:
	keyslot_manager_destroy(ksm);
	return NULL;
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_create);

	void keyslot_manager_set_max_dun_bytes(struct keyslot_manager *ksm,
	unsigned int max_dun_bytes)
	{
	ksm->max_dun_bytes_supported = max_dun_bytes;
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_set_max_dun_bytes);

	static inline struct hlist_head *
	hash_bucket_for_key(struct keyslot_manager *ksm,
	const struct blk_crypto_key *key)
	{
	return &ksm->slot_hashtable[blk_crypto_key_hash(key) &
	(ksm->slot_hashtable_size - 1)];
	}

	static void remove_slot_from_lru_list(struct keyslot_manager *ksm, int slot)
	{
	unsigned long flags;

	spin_lock_irqsave(&ksm->idle_slots_lock, flags);
	list_del(&ksm->slots[slot].idle_slot_node);
	spin_unlock_irqrestore(&ksm->idle_slots_lock, flags);
	}

	static int find_keyslot(struct keyslot_manager *ksm,
	const struct blk_crypto_key *key)
	{
	const struct hlist_head *head = hash_bucket_for_key(ksm, key);
	const struct keyslot *slotp;

	hlist_for_each_entry(slotp, head, hash_node) {
	if (slotp->key.hash == key->hash &&
	slotp->key.crypto_mode == key->crypto_mode &&
	slotp->key.size == key->size &&
	slotp->key.data_unit_size == key->data_unit_size &&
	!crypto_memneq(slotp->key.raw, key->raw, key->size))
	return slotp - ksm->slots;
	}
	return -ENOKEY;
	}

	static int find_and_grab_keyslot(struct keyslot_manager *ksm,
	const struct blk_crypto_key *key)
	{
	int slot;

	slot = find_keyslot(ksm, key);
	if (slot < 0)
	return slot;
	if (atomic_inc_return(&ksm->slots[slot].slot_refs) == 1) {
	/* Took first reference to this slot; remove it from LRU list */
	remove_slot_from_lru_list(ksm, slot);
	}
	return slot;
	}

	/**
	* keyslot_manager_get_slot_for_key() - Program a key into a keyslot.
	* @ksm: The keyslot manager to program the key into.
	* @key: Pointer to the key object to program, including the raw key, crypto
	* mode, and data unit size.
	*
	* Get a keyslot that's been programmed with the specified key. If one already
	* exists, return it with incremented refcount. Otherwise, wait for a keyslot
	* to become idle and program it.
	*
	* Context: Process context. Takes and releases ksm->lock.
	* Return: The keyslot on success, else a -errno value.
	*/
	int keyslot_manager_get_slot_for_key(struct keyslot_manager *ksm,
	const struct blk_crypto_key *key)
	{
	int slot;
	int err;
	struct keyslot *idle_slot;

	if (keyslot_manager_is_passthrough(ksm))
	return 0;

	down_read(&ksm->lock);
	slot = find_and_grab_keyslot(ksm, key);
	up_read(&ksm->lock);
	if (slot != -ENOKEY)
	return slot;

	for (;;) {
	keyslot_manager_hw_enter(ksm);
	slot = find_and_grab_keyslot(ksm, key);
	if (slot != -ENOKEY) {
	keyslot_manager_hw_exit(ksm);
	return slot;
	}

	/*
	* If we're here, that means there wasn't a slot that was
	* already programmed with the key. So try to program it.
	*/
	if (!list_empty(&ksm->idle_slots))
	break;

	keyslot_manager_hw_exit(ksm);
	wait_event(ksm->idle_slots_wait_queue,
	!list_empty(&ksm->idle_slots));
	}

	idle_slot = list_first_entry(&ksm->idle_slots, struct keyslot,
	idle_slot_node);
	slot = idle_slot - ksm->slots;

	err = ksm->ksm_ll_ops.keyslot_program(ksm, key, slot);
	if (err) {
	wake_up(&ksm->idle_slots_wait_queue);
	keyslot_manager_hw_exit(ksm);
	return err;
	}

	/* Move this slot to the hash list for the new key. */
	if (idle_slot->key.crypto_mode != BLK_ENCRYPTION_MODE_INVALID)
	hlist_del(&idle_slot->hash_node);
	hlist_add_head(&idle_slot->hash_node, hash_bucket_for_key(ksm, key));

	atomic_set(&idle_slot->slot_refs, 1);
	idle_slot->key = *key;

	remove_slot_from_lru_list(ksm, slot);

	keyslot_manager_hw_exit(ksm);
	return slot;
	}

	/**
	* keyslot_manager_get_slot() - Increment the refcount on the specified slot.
	* @ksm: The keyslot manager that we want to modify.
	* @slot: The slot to increment the refcount of.
	*
	* This function assumes that there is already an active reference to that slot
	* and simply increments the refcount. This is useful when cloning a bio that
	* already has a reference to a keyslot, and we want the cloned bio to also have
	* its own reference.
	*
	* Context: Any context.
	*/
	void keyslot_manager_get_slot(struct keyslot_manager *ksm, unsigned int slot)
	{
	if (keyslot_manager_is_passthrough(ksm))
	return;

	if (WARN_ON(slot >= ksm->num_slots))
	return;

	WARN_ON(atomic_inc_return(&ksm->slots[slot].slot_refs) < 2);
	}

	/**
	* keyslot_manager_put_slot() - Release a reference to a slot
	* @ksm: The keyslot manager to release the reference from.
	* @slot: The slot to release the reference from.
	*
	* Context: Any context.
	*/
	void keyslot_manager_put_slot(struct keyslot_manager *ksm, unsigned int slot)
	{
	unsigned long flags;

	if (keyslot_manager_is_passthrough(ksm))
	return;

	if (WARN_ON(slot >= ksm->num_slots))
	return;

	if (atomic_dec_and_lock_irqsave(&ksm->slots[slot].slot_refs,
	&ksm->idle_slots_lock, flags)) {
	list_add_tail(&ksm->slots[slot].idle_slot_node,
	&ksm->idle_slots);
	spin_unlock_irqrestore(&ksm->idle_slots_lock, flags);
	wake_up(&ksm->idle_slots_wait_queue);
	}
	}

	/**
	* keyslot_manager_crypto_mode_supported() - Find out if a crypto_mode /
	* data unit size / is_hw_wrapped_key
	* combination is supported by a ksm.
	* @ksm: The keyslot manager to check
	* @crypto_mode: The crypto mode to check for.
	* @dun_bytes: The number of bytes that will be used to specify the DUN
	* @data_unit_size: The data_unit_size for the mode.
	* @is_hw_wrapped_key: Whether a hardware-wrapped key will be used.
	*
	* Calls and returns the result of the crypto_mode_supported function specified
	* by the ksm.
	*
	* Context: Process context.
	* Return: Whether or not this ksm supports the specified crypto settings.
	*/
	bool keyslot_manager_crypto_mode_supported(struct keyslot_manager *ksm,
	enum blk_crypto_mode_num crypto_mode,
	unsigned int dun_bytes,
	unsigned int data_unit_size,
	bool is_hw_wrapped_key)
	{
	if (!ksm)
	return false;
	if (WARN_ON(crypto_mode >= BLK_ENCRYPTION_MODE_MAX))
	return false;
	if (WARN_ON(!is_power_of_2(data_unit_size)))
	return false;
	if (is_hw_wrapped_key) {
	if (!(ksm->features & BLK_CRYPTO_FEATURE_WRAPPED_KEYS))
	return false;
	} else {
	if (!(ksm->features & BLK_CRYPTO_FEATURE_STANDARD_KEYS))
	return false;
	}
	if (!(ksm->crypto_mode_supported[crypto_mode] & data_unit_size))
	return false;

	return ksm->max_dun_bytes_supported >= dun_bytes;
	}

	/**
	* keyslot_manager_evict_key() - Evict a key from the lower layer device.
	* @ksm: The keyslot manager to evict from
	* @key: The key to evict
	*
	* Find the keyslot that the specified key was programmed into, and evict that
	* slot from the lower layer device if that slot is not currently in use.
	*
	* Context: Process context. Takes and releases ksm->lock.
	* Return: 0 on success, -EBUSY if the key is still in use, or another
	* -errno value on other error.
	*/
	int keyslot_manager_evict_key(struct keyslot_manager *ksm,
	const struct blk_crypto_key *key)
	{
	int slot;
	int err;
	struct keyslot *slotp;

	if (keyslot_manager_is_passthrough(ksm)) {
	if (ksm->ksm_ll_ops.keyslot_evict) {
	keyslot_manager_hw_enter(ksm);
	err = ksm->ksm_ll_ops.keyslot_evict(ksm, key, -1);
	keyslot_manager_hw_exit(ksm);
	return err;
	}
	return 0;
	}

	keyslot_manager_hw_enter(ksm);

	slot = find_keyslot(ksm, key);
	if (slot < 0) {
	err = slot;
	goto out_unlock;
	}
	slotp = &ksm->slots[slot];

	if (atomic_read(&slotp->slot_refs) != 0) {
	err = -EBUSY;
	goto out_unlock;
	}
	err = ksm->ksm_ll_ops.keyslot_evict(ksm, key, slot);
	if (err)
	goto out_unlock;

	hlist_del(&slotp->hash_node);
	memzero_explicit(&slotp->key, sizeof(slotp->key));
	err = 0;
	out_unlock:
	keyslot_manager_hw_exit(ksm);
	return err;
	}

	/**
	* keyslot_manager_reprogram_all_keys() - Re-program all keyslots.
	* @ksm: The keyslot manager
	*
	* Re-program all keyslots that are supposed to have a key programmed. This is
	* intended only for use by drivers for hardware that loses its keys on reset.
	*
	* Context: Process context. Takes and releases ksm->lock.
	*/
	void keyslot_manager_reprogram_all_keys(struct keyslot_manager *ksm)
	{
	unsigned int slot;

	if (WARN_ON(keyslot_manager_is_passthrough(ksm)))
	return;

	/* This is for device initialization, so don't resume the device */
	down_write(&ksm->lock);
	for (slot = 0; slot < ksm->num_slots; slot++) {
	const struct keyslot *slotp = &ksm->slots[slot];
	int err;

	if (slotp->key.crypto_mode == BLK_ENCRYPTION_MODE_INVALID)
	continue;

	err = ksm->ksm_ll_ops.keyslot_program(ksm, &slotp->key, slot);
	WARN_ON(err);
	}
	up_write(&ksm->lock);
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_reprogram_all_keys);

	/**
	* keyslot_manager_private() - return the private data stored with ksm
	* @ksm: The keyslot manager
	*
	* Returns the private data passed to the ksm when it was created.
	*/
	void keyslot_manager_private(struct keyslot_manager ksm)
	{
	return ksm->ll_priv_data;
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_private);

	void keyslot_manager_destroy(struct keyslot_manager *ksm)
	{
	if (ksm) {
	kvfree(ksm->slot_hashtable);
	memzero_explicit(ksm, struct_size(ksm, slots, ksm->num_slots));
	kvfree(ksm);
	}
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_destroy);

	/**
	* keyslot_manager_create_passthrough() - Create a passthrough keyslot manager
	* @dev: Device for runtime power management (NULL if none)
	* @ksm_ll_ops: The struct keyslot_mgmt_ll_ops
	* @features: Bitmask of BLK_CRYPTO_FEATURE_* flags
	* @crypto_mode_supported: Bitmasks for supported encryption modes
	* @ll_priv_data: Private data passed as is to the functions in ksm_ll_ops.
	*
	* Allocate memory for and initialize a passthrough keyslot manager.
	* Called by e.g. storage drivers to set up a keyslot manager in their
	* request_queue, when the storage driver wants to manage its keys by itself.
	* This is useful for inline encryption hardware that don't have a small fixed
	* number of keyslots, and for layered devices.
	*
	* See keyslot_manager_create() for more details about the parameters.
	*
	* Context: This function may sleep
	* Return: Pointer to constructed keyslot manager or NULL on error.
	*/
	struct keyslot_manager *keyslot_manager_create_passthrough(
	struct device *dev,
	const struct keyslot_mgmt_ll_ops *ksm_ll_ops,
	unsigned int features,
	const unsigned int crypto_mode_supported[BLK_ENCRYPTION_MODE_MAX],
	void *ll_priv_data)
	{
	struct keyslot_manager *ksm;

	ksm = kzalloc(sizeof(*ksm), GFP_KERNEL);
	if (!ksm)
	return NULL;

	ksm->ksm_ll_ops = *ksm_ll_ops;
	ksm->features = features;
	memcpy(ksm->crypto_mode_supported, crypto_mode_supported,
	sizeof(ksm->crypto_mode_supported));
	ksm->max_dun_bytes_supported = BLK_CRYPTO_MAX_IV_SIZE;
	ksm->ll_priv_data = ll_priv_data;
	keyslot_manager_set_dev(ksm, dev);

	init_rwsem(&ksm->lock);

	return ksm;
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_create_passthrough);

	/**
	* keyslot_manager_intersect_modes() - restrict supported modes by child device
	* @parent: The keyslot manager for parent device
	* @child: The keyslot manager for child device, or NULL
	*
	* Clear any crypto mode support bits in @parent that aren't set in @child.
	* If @child is NULL, then all parent bits are cleared.
	*
	* Only use this when setting up the keyslot manager for a layered device,
	* before it's been exposed yet.
	*/
	void keyslot_manager_intersect_modes(struct keyslot_manager *parent,
	const struct keyslot_manager *child)
	{
	if (child) {
	unsigned int i;

	parent->features &= child->features;
	parent->max_dun_bytes_supported =
	min(parent->max_dun_bytes_supported,
	child->max_dun_bytes_supported);
	for (i = 0; i < ARRAY_SIZE(child->crypto_mode_supported); i++) {
	parent->crypto_mode_supported[i] &=
	child->crypto_mode_supported[i];
	}
	} else {
	parent->features = 0;
	parent->max_dun_bytes_supported = 0;
	memset(parent->crypto_mode_supported, 0,
	sizeof(parent->crypto_mode_supported));
	}
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_intersect_modes);

	/**
	* keyslot_manager_derive_raw_secret() - Derive software secret from wrapped key
	* @ksm: The keyslot manager
	* @wrapped_key: The wrapped key
	* @wrapped_key_size: Size of the wrapped key in bytes
	* @secret: (output) the software secret
	* @secret_size: (output) the number of secret bytes to derive
	*
	* Given a hardware-wrapped key, ask the hardware to derive a secret which
	* software can use for cryptographic tasks other than inline encryption. The
	* derived secret is guaranteed to be cryptographically isolated from the key
	* with which any inline encryption with this wrapped key would actually be
	* done. I.e., both will be derived from the unwrapped key.
	*
	* Return: 0 on success, -EOPNOTSUPP if hardware-wrapped keys are unsupported,
	* or another -errno code.
	*/
	int keyslot_manager_derive_raw_secret(struct keyslot_manager *ksm,
	const u8 *wrapped_key,
	unsigned int wrapped_key_size,
	u8 *secret, unsigned int secret_size)
	{
	int err;

	if (ksm->ksm_ll_ops.derive_raw_secret) {
	keyslot_manager_hw_enter(ksm);
	err = ksm->ksm_ll_ops.derive_raw_secret(ksm, wrapped_key,
	wrapped_key_size,
	secret, secret_size);
	keyslot_manager_hw_exit(ksm);
	} else {
	err = -EOPNOTSUPP;
	}

	return err;
	}
	EXPORT_SYMBOL_GPL(keyslot_manager_derive_raw_secret);