We introduce blk-crypto, which manages programming keyslots for struct bios. With blk-crypto, filesystems only need to call bio_crypt_set_ctx with the encryption key, algorithm and data_unit_num; they don't have to worry about getting a keyslot for each encryption context, as blk-crypto handles that. Blk-crypto also makes it possible for layered devices like device mapper to make use of inline encryption hardware. Blk-crypto delegates crypto operations to inline encryption hardware when available, and also contains a software fallback to the kernel crypto API. For more details, refer to Documentation/block/blk-crypto.txt. Signed-off-by: Satya Tangirala <satyat@xxxxxxxxxx> --- Documentation/block/inline-encryption.txt | 186 ++++++ block/Kconfig | 2 + block/Makefile | 3 +- block/bio-crypt-ctx.c | 7 +- block/bio.c | 5 + block/blk-core.c | 11 +- block/blk-crypto.c | 737 ++++++++++++++++++++++ include/linux/bio-crypt-ctx.h | 7 + include/linux/blk-crypto.h | 47 ++ 9 files changed, 1002 insertions(+), 3 deletions(-) create mode 100644 Documentation/block/inline-encryption.txt create mode 100644 block/blk-crypto.c create mode 100644 include/linux/blk-crypto.h diff --git a/Documentation/block/inline-encryption.txt b/Documentation/block/inline-encryption.txt new file mode 100644 index 000000000000..925611a5ea65 --- /dev/null +++ b/Documentation/block/inline-encryption.txt @@ -0,0 +1,186 @@ +BLK-CRYPTO and KEYSLOT MANAGER +=========================== + +CONTENTS +1. Objective +2. Constraints and notes +3. Design +4. Blk-crypto + 4-1 What does blk-crypto do on bio submission +5. Layered Devices +6. Future optimizations for layered devices + +1. Objective +============ + +We want to support inline encryption (IE) in the kernel. +To allow for testing, we also want a crypto API fallback when actual +IE hardware is absent. We also want IE to work with layered devices +like dm and loopback (i.e. we want to be able to use the IE hardware +of the underlying devices if present, or else fall back to crypto API +en/decryption). + + +2. Constraints and notes +======================== + +1) IE hardware have a limited number of “keyslots” that can be programmed +with an encryption context (key, algorithm, data unit size, etc.) at any time. +One can specify a keyslot in a data request made to the device, and the +device will en/decrypt the data using the encryption context programmed into +that specified keyslot. When possible, we want to make multiple requests with +the same encryption context share the same keyslot. + +2) We need a way for filesystems to specify an encryption context to use for +en/decrypting a struct bio, and a device driver (like UFS) needs to be able +to use that encryption context when it processes the bio. + +3) We need a way for device drivers to expose their capabilities in a unified +way to the upper layers. + + +3. Design +========= + +We add a struct bio_crypt_ctx to struct bio that can represent an +encryption context, because we need to be able to pass this encryption +context from the FS layer to the device driver to act upon. + +While IE hardware works on the notion of keyslots, the FS layer has no +knowledge of keyslots - it simply wants to specify an encryption context to +use while en/decrypting a bio. + +We introduce a keyslot manager (KSM) that handles the translation from +encryption contexts specified by the FS to keyslots on the IE hardware. +This KSM also serves as the way IE hardware can expose their capabilities to +upper layers. The generic mode of operation is: each device driver that wants +to support IE will construct a KSM and set it up in its struct request_queue. +Upper layers that want to use IE on this device can then use this KSM in +the device’s struct request_queue to translate an encryption context into +a keyslot. The presence of the KSM in the request queue shall be used to mean +that the device supports IE. + +On the device driver end of the interface, the device driver needs to tell the +KSM how to actually manipulate the IE hardware in the device to do things like +programming the crypto key into the IE hardware into a particular keyslot. All +this is achieved through the struct keyslot_mgmt_ll_ops that the device driver +passes to the KSM when creating it. + +It uses refcounts to track which keyslots are idle (either they have no +encryption context programmed, or there are no in-flight struct bios +referencing that keyslot). When a new encryption context needs a keyslot, it +tries to find a keyslot that has already been programmed with the same +encryption context, and if there is no such keyslot, it evicts the least +recently used idle keyslot and programs the new encryption context into that +one. If no idle keyslots are available, then the caller will sleep until there +is at least one. + + +4. Blk-crypto +============= + +The above is sufficient for simple cases, but does not work if there is a +need for a crypto API fallback, or if we are want to use IE with layered +devices. To these ends, we introduce blk-crypto. Blk-crypto allows us to +present a unified view of encryption to the FS (so FS only needs to specify +an encryption context and not worry about keyslots at all), and blk-crypto +can decide whether to delegate the en/decryption to IE hardware or to the +crypto API. Blk-crypto maintains an internal KSM that serves as the crypto +API fallback. + +Blk-crypto needs to ensure that the encryption context is programmed into the +"correct" keyslot manager for IE. If a bio is submitted to a layered device +that eventually passes the bio down to a device that really does support IE, we +want the encryption context to be programmed into a keyslot for the KSM of the +device with IE support. However, blk-crypto does not know a priori whether a +particular device is the final device in the layering structure for a bio or +not. So in the case that a particular device does not support IE, since it is +possibly the final destination device for the bio, if the bio requires +encryption (i.e. the bio is doing a write operation), blk-crypto must fallback +to the crypto API *before* sending the bio to the device. + +Blk-crypto ensures that +1) The bio’s encryption context is programmed into a keyslot in the KSM of the +request queue that the bio is being submitted to (or the crypto API fallback KSM +if the request queue doesn’t have a KSM), and that the processing_ksm in the +bi_crypt_context is set to this KSM + +2) That the bio has its own individual reference to the keyslot in this KSM. +Once the bio passes through blk-crypto, its encryption context is programmed +in some KSM. The “its own individual reference to the keyslot” ensures that +keyslots can be released by each bio independently of other bios while ensuring +that the bio has a valid reference to the keyslot when, for e.g., the crypto API +fallback KSM in blk-crypto performs crypto on the device’s behalf. The individual +references are ensured by increasing the refcount for the keyslot in the +processing_ksm when a bio with a programmed encryption context is cloned. + + +4-1. What blk-crypto does on bio submission +------------------------------------------- + +Case 1: blk-crypto is given a bio with only an encryption context that hasn’t +been programmed into any keyslot in any KSM (for e.g. a bio from the FS). In +this case, blk-crypto will program the encryption context into the KSM of the +request queue the bio is being submitted to (and if this KSM does not exist, +then it will program it into blk-crypto’s internal KSM for crypto API fallback). +The KSM that this encryption context was programmed into is stored as the +processing_ksm in the bio’s bi_crypt_context. + +Case 2: blk-crypto is given a bio whose encryption context has already been +programmed into a keyslot in the *crypto API fallback KSM*. In this case, +blk-crypto does nothing; it treats the bio as not having specified an +encryption context. Note that we cannot do here what we will do in Case 3 +because we would have already encrypted the bio via the crypto API by this +point. + +Case 3: blk-crypto is given a bio whose encryption context has already been +programmed into a keyslot in some KSM (that is *not* the crypto API fallback +KSM). In this case, blk-crypto first releases that keyslot from that KSM and +then treats the bio as in Case 1. + +This way, when a device driver is processing a bio, it can be sure that +the bio’s encryption context has been programmed into some KSM (either the +device driver’s request queue’s KSM, or blk-crypto’s crypto API fallback KSM). +It then simply needs to check if the bio’s processing_ksm is the device’s +request queue’s KSM. If so, then it should proceed with IE. If not, it should +simply do nothing with respect to crypto, because some other KSM (perhaps the +blk-crypto crypto API fallback KSM) is handling the en/decryption. + +Blk-crypto will release the keyslot that is being held by the bio (and also +decrypt it if the bio is using the crypto API fallback KSM) once +bio_remaining_done returns true for the bio. + + +5. Layered Devices +================== + +Layered devices that wish to support IE need to create their own keyslot +manager for their request queue, and expose whatever functionality they choose. +When a layered device wants to pass a bio to another layer (either by +resubmitting the same bio, or by submitting a clone), it doesn’t need to do +anything special because the bio (or the clone) will once again pass through +blk-crypto, which will work as described in Case 3. If a layered device wants +for some reason to do the IO by itself instead of passing it on to a child +device, but it also chose to expose IE capabilities by setting up a KSM in its +request queue, it is then responsible for en/decrypting the data itself. In +such cases, the device can choose to call the blk-crypto function +blk_crypto_fallback_to_kernel_crypto_api (TODO: Not yet implemented), which will +cause the en/decryption to be done via the crypto API fallback. + + +6. Future Optimizations for layered devices +=========================================== + +Creating a keyslot manager for the layered device uses up memory for each +keyslot, and in general, a layered device (like dm-linear) merely passes the +request on to a “child” device, so the keyslots in the layered device itself +might be completely unused. We can instead define a new type of KSM; the +“passthrough KSM”, that layered devices can use to let blk-crypto know that +this layered device *will* pass the bio to some child device (and hence +through blk-crypto again, at which point blk-crypto can program the encryption +context, instead of programming it into the layered device’s KSM). Again, if +the device “lies” and decides to do the IO itself instead of passing it on to +a child device, it is responsible for doing the en/decryption (and can choose +to call blk_crypto_fallback_to_kernel_crypto_api). Another use case for the +"passthrough KSM" is for IE devices that want to manage their own keyslots/do +not have a limited number of keyslots. diff --git a/block/Kconfig b/block/Kconfig index 1469efdd385b..4f7e593d0a6d 100644 --- a/block/Kconfig +++ b/block/Kconfig @@ -166,6 +166,8 @@ config BLK_SED_OPAL config BLK_INLINE_ENCRYPTION bool "Enable inline encryption support in block layer" + select CRYPTO + select CRYPTO_BLKCIPHER help Build the blk-crypto subsystem. Enabling this lets the block layer handle encryption, diff --git a/block/Makefile b/block/Makefile index 4147ffa63631..1ba7de84dbaf 100644 --- a/block/Makefile +++ b/block/Makefile @@ -35,4 +35,5 @@ obj-$(CONFIG_BLK_DEBUG_FS) += blk-mq-debugfs.o obj-$(CONFIG_BLK_DEBUG_FS_ZONED)+= blk-mq-debugfs-zoned.o obj-$(CONFIG_BLK_SED_OPAL) += sed-opal.o obj-$(CONFIG_BLK_PM) += blk-pm.o -obj-$(CONFIG_BLK_INLINE_ENCRYPTION) += keyslot-manager.o bio-crypt-ctx.o +obj-$(CONFIG_BLK_INLINE_ENCRYPTION) += keyslot-manager.o bio-crypt-ctx.o \ + blk-crypto.o diff --git a/block/bio-crypt-ctx.c b/block/bio-crypt-ctx.c index aa3571f72ee7..6a2b061865c6 100644 --- a/block/bio-crypt-ctx.c +++ b/block/bio-crypt-ctx.c @@ -43,7 +43,12 @@ EXPORT_SYMBOL(bio_crypt_free_ctx); int bio_crypt_clone(struct bio *dst, struct bio *src, gfp_t gfp_mask) { - if (!bio_has_crypt_ctx(src)) + /* + * If a bio is swhandled, then it will be decrypted when bio_endio + * is called. As we only want the data to be decrypted once, copies + * of the bio must not have have a crypt context. + */ + if (!bio_has_crypt_ctx(src) || bio_crypt_swhandled(src)) return 0; dst->bi_crypt_context = bio_crypt_alloc_ctx(gfp_mask); diff --git a/block/bio.c b/block/bio.c index ada9850c90dc..e2537e5588ac 100644 --- a/block/bio.c +++ b/block/bio.c @@ -17,6 +17,7 @@ #include <linux/cgroup.h> #include <linux/blk-cgroup.h> #include <linux/highmem.h> +#include <linux/blk-crypto.h> #include <trace/events/block.h> #include "blk.h" @@ -1800,6 +1801,10 @@ void bio_endio(struct bio *bio) again: if (!bio_remaining_done(bio)) return; + + if (!blk_crypto_endio(bio)) + return; + if (!bio_integrity_endio(bio)) return; diff --git a/block/blk-core.c b/block/blk-core.c index 35027e80e27d..f699ecd9ca2e 100644 --- a/block/blk-core.c +++ b/block/blk-core.c @@ -36,6 +36,7 @@ #include <linux/blk-cgroup.h> #include <linux/debugfs.h> #include <linux/bpf.h> +#include <linux/blk-crypto.h> #define CREATE_TRACE_POINTS #include <trace/events/block.h> @@ -1049,7 +1050,9 @@ blk_qc_t generic_make_request(struct bio *bio) /* Create a fresh bio_list for all subordinate requests */ bio_list_on_stack[1] = bio_list_on_stack[0]; bio_list_init(&bio_list_on_stack[0]); - ret = q->make_request_fn(q, bio); + + if (!blk_crypto_submit_bio(&bio)) + ret = q->make_request_fn(q, bio); blk_queue_exit(q); @@ -1102,6 +1105,9 @@ blk_qc_t direct_make_request(struct bio *bio) if (!generic_make_request_checks(bio)) return BLK_QC_T_NONE; + if (blk_crypto_submit_bio(&bio)) + return BLK_QC_T_NONE; + if (unlikely(blk_queue_enter(q, nowait ? BLK_MQ_REQ_NOWAIT : 0))) { if (nowait && !blk_queue_dying(q)) bio->bi_status = BLK_STS_AGAIN; @@ -1772,5 +1778,8 @@ int __init blk_dev_init(void) if (bio_crypt_ctx_init() < 0) panic("Failed to allocate mem for bio crypt ctxs\n"); + if (blk_crypto_init() < 0) + panic("Failed to init blk-crypto\n"); + return 0; } diff --git a/block/blk-crypto.c b/block/blk-crypto.c new file mode 100644 index 000000000000..c8f06264a0f5 --- /dev/null +++ b/block/blk-crypto.c @@ -0,0 +1,737 @@ +// SPDX-License-Identifier: GPL-2.0 +/* + * Copyright 2019 Google LLC + */ + +/* + * Refer to Documentation/block/inline-encryption.txt for detailed explanation. + */ + +#ifdef pr_fmt +#undef pr_fmt +#endif + +#define pr_fmt(fmt) "blk-crypto: " fmt + +#include <linux/blk-crypto.h> +#include <linux/keyslot-manager.h> +#include <linux/mempool.h> +#include <linux/blk-cgroup.h> +#include <linux/crypto.h> +#include <crypto/skcipher.h> +#include <crypto/algapi.h> +#include <linux/module.h> +#include <linux/sched/mm.h> + +/* Represents a crypto mode supported by blk-crypto */ +struct blk_crypto_mode { + const char *cipher_str; /* crypto API name (for fallback case) */ + size_t keysize; /* key size in bytes */ +}; + +static const struct blk_crypto_mode blk_crypto_modes[] = { + [BLK_ENCRYPTION_MODE_AES_256_XTS] = { + .cipher_str = "xts(aes)", + .keysize = 64, + }, +}; + +static unsigned int num_prealloc_bounce_pg = 32; +module_param(num_prealloc_bounce_pg, uint, 0); +MODULE_PARM_DESC(num_prealloc_bounce_pg, + "Number of preallocated bounce pages for blk-crypto to use during crypto API fallback encryption"); + +#define BLK_CRYPTO_MAX_KEY_SIZE 64 +static int blk_crypto_num_keyslots = 100; +module_param_named(num_keyslots, blk_crypto_num_keyslots, int, 0); +MODULE_PARM_DESC(num_keyslots, + "Number of keyslots for crypto API fallback in blk-crypto."); + +static struct blk_crypto_keyslot { + struct crypto_skcipher *tfm; + enum blk_crypto_mode_num crypto_mode; + u8 key[BLK_CRYPTO_MAX_KEY_SIZE]; + struct crypto_skcipher *tfms[ARRAY_SIZE(blk_crypto_modes)]; +} *blk_crypto_keyslots; + +static struct mutex tfms_lock[ARRAY_SIZE(blk_crypto_modes)]; +static bool tfms_inited[ARRAY_SIZE(blk_crypto_modes)]; + +struct work_mem { + struct work_struct crypto_work; + struct bio *bio; +}; + +/* The following few vars are only used during the crypto API fallback */ +static struct keyslot_manager *blk_crypto_ksm; +static struct workqueue_struct *blk_crypto_wq; +static mempool_t *blk_crypto_page_pool; +static struct kmem_cache *blk_crypto_work_mem_cache; + +bool bio_crypt_swhandled(struct bio *bio) +{ + return bio_has_crypt_ctx(bio) && + bio->bi_crypt_context->processing_ksm == blk_crypto_ksm; +} + +static const u8 zeroes[BLK_CRYPTO_MAX_KEY_SIZE]; +static void evict_keyslot(unsigned int slot) +{ + struct blk_crypto_keyslot *slotp = &blk_crypto_keyslots[slot]; + enum blk_crypto_mode_num crypto_mode = slotp->crypto_mode; + + /* Clear the key in the skcipher */ + crypto_skcipher_setkey(slotp->tfms[crypto_mode], zeroes, + blk_crypto_modes[crypto_mode].keysize); + memzero_explicit(slotp->key, BLK_CRYPTO_MAX_KEY_SIZE); +} + +static int blk_crypto_keyslot_program(void *priv, const u8 *key, + enum blk_crypto_mode_num crypto_mode, + unsigned int data_unit_size, + unsigned int slot) +{ + struct blk_crypto_keyslot *slotp = &blk_crypto_keyslots[slot]; + const struct blk_crypto_mode *mode = &blk_crypto_modes[crypto_mode]; + size_t keysize = mode->keysize; + int err; + + if (crypto_mode != slotp->crypto_mode) { + evict_keyslot(slot); + slotp->crypto_mode = crypto_mode; + } + + if (!slotp->tfms[crypto_mode]) + return -ENOMEM; + err = crypto_skcipher_setkey(slotp->tfms[crypto_mode], key, keysize); + + if (err) { + evict_keyslot(slot); + return err; + } + + memcpy(slotp->key, key, keysize); + + return 0; +} + +static int blk_crypto_keyslot_evict(void *priv, const u8 *key, + enum blk_crypto_mode_num crypto_mode, + unsigned int data_unit_size, + unsigned int slot) +{ + evict_keyslot(slot); + return 0; +} + +static int blk_crypto_keyslot_find(void *priv, + const u8 *key, + enum blk_crypto_mode_num crypto_mode, + unsigned int data_unit_size_bytes) +{ + int slot; + const size_t keysize = blk_crypto_modes[crypto_mode].keysize; + + for (slot = 0; slot < blk_crypto_num_keyslots; slot++) { + if (blk_crypto_keyslots[slot].crypto_mode == crypto_mode && + !crypto_memneq(blk_crypto_keyslots[slot].key, key, keysize)) + return slot; + } + + return -ENOKEY; +} + +static bool blk_crypto_mode_supported(void *priv, + enum blk_crypto_mode_num crypt_mode, + unsigned int data_unit_size) +{ + /* All blk_crypto_modes are required to have a crypto API fallback. */ + return true; +} + +/* + * The crypto API fallback KSM ops - only used for a bio when it specifies a + * blk_crypto_mode for which we failed to get a keyslot in the device's inline + * encryption hardware (which probably means the device doesn't have inline + * encryption hardware that supports that crypto mode). + */ +static const struct keyslot_mgmt_ll_ops blk_crypto_ksm_ll_ops = { + .keyslot_program = blk_crypto_keyslot_program, + .keyslot_evict = blk_crypto_keyslot_evict, + .keyslot_find = blk_crypto_keyslot_find, + .crypto_mode_supported = blk_crypto_mode_supported, +}; + +static void blk_crypto_encrypt_endio(struct bio *enc_bio) +{ + struct bio *src_bio = enc_bio->bi_private; + int i; + + for (i = 0; i < enc_bio->bi_vcnt; i++) + mempool_free(enc_bio->bi_io_vec[i].bv_page, + blk_crypto_page_pool); + + src_bio->bi_status = enc_bio->bi_status; + + bio_put(enc_bio); + bio_endio(src_bio); +} + +static struct bio *blk_crypto_clone_bio(struct bio *bio_src) +{ + struct bvec_iter iter; + struct bio_vec bv; + struct bio *bio; + + bio = bio_alloc_bioset(GFP_NOIO, bio_segments(bio_src), NULL); + if (!bio) + return NULL; + bio->bi_disk = bio_src->bi_disk; + bio->bi_opf = bio_src->bi_opf; + bio->bi_ioprio = bio_src->bi_ioprio; + bio->bi_write_hint = bio_src->bi_write_hint; + bio->bi_iter.bi_sector = bio_src->bi_iter.bi_sector; + bio->bi_iter.bi_size = bio_src->bi_iter.bi_size; + + bio_for_each_segment(bv, bio_src, iter) + bio->bi_io_vec[bio->bi_vcnt++] = bv; + + if (bio_integrity(bio_src) && + bio_integrity_clone(bio, bio_src, GFP_NOIO) < 0) { + bio_put(bio); + return NULL; + } + + bio_clone_blkg_association(bio, bio_src); + blkcg_bio_issue_init(bio); + + return bio; +} + +/* Check that all I/O segments are data unit aligned */ +static int bio_crypt_check_alignment(struct bio *bio) +{ + int data_unit_size = 1 << bio->bi_crypt_context->data_unit_size_bits; + struct bvec_iter iter; + struct bio_vec bv; + + bio_for_each_segment(bv, bio, iter) { + if (!IS_ALIGNED(bv.bv_len | bv.bv_offset, data_unit_size)) + return -EIO; + } + return 0; +} + +static int blk_crypto_alloc_cipher_req(struct bio *src_bio, + struct skcipher_request **ciph_req_ptr, + struct crypto_wait *wait) +{ + int slot; + struct skcipher_request *ciph_req; + struct blk_crypto_keyslot *slotp; + + slot = bio_crypt_get_keyslot(src_bio); + slotp = &blk_crypto_keyslots[slot]; + ciph_req = skcipher_request_alloc(slotp->tfms[slotp->crypto_mode], + GFP_NOIO); + if (!ciph_req) { + src_bio->bi_status = BLK_STS_RESOURCE; + return -ENOMEM; + } + + skcipher_request_set_callback(ciph_req, + CRYPTO_TFM_REQ_MAY_BACKLOG | + CRYPTO_TFM_REQ_MAY_SLEEP, + crypto_req_done, wait); + *ciph_req_ptr = ciph_req; + return 0; +} + +static int blk_crypto_split_bio_if_needed(struct bio **bio_ptr) +{ + struct bio *bio = *bio_ptr; + unsigned int i = 0; + unsigned int num_sectors = 0; + struct bio_vec bv; + struct bvec_iter iter; + + bio_for_each_segment(bv, bio, iter) { + num_sectors += bv.bv_len >> SECTOR_SHIFT; + if (++i == BIO_MAX_PAGES) + break; + } + if (num_sectors < bio_sectors(bio)) { + struct bio *split_bio; + + split_bio = bio_split(bio, num_sectors, GFP_NOIO, NULL); + if (!split_bio) { + bio->bi_status = BLK_STS_RESOURCE; + return -ENOMEM; + } + bio_chain(split_bio, bio); + generic_make_request(bio); + *bio_ptr = split_bio; + } + return 0; +} + +/* + * The crypto API fallback's encryption routine. + * Allocate a bounce bio for encryption, encrypt the input bio using + * crypto API, and replace *bio_ptr with the bounce bio. May split input + * bio if it's too large. + */ +static int blk_crypto_encrypt_bio(struct bio **bio_ptr) +{ + struct bio *src_bio; + struct skcipher_request *ciph_req = NULL; + DECLARE_CRYPTO_WAIT(wait); + int err = 0; + u64 curr_dun; + union { + __le64 dun; + u8 bytes[16]; + } iv; + struct scatterlist src, dst; + struct bio *enc_bio; + struct bio_vec *enc_bvec; + int i, j; + int data_unit_size; + + /* Split the bio if it's too big for single page bvec */ + err = blk_crypto_split_bio_if_needed(bio_ptr); + if (err) + return err; + + src_bio = *bio_ptr; + data_unit_size = 1 << src_bio->bi_crypt_context->data_unit_size_bits; + + /* Allocate bounce bio for encryption */ + enc_bio = blk_crypto_clone_bio(src_bio); + if (!enc_bio) { + src_bio->bi_status = BLK_STS_RESOURCE; + return -ENOMEM; + } + + /* + * Use the crypto API fallback keyslot manager to get a crypto_skcipher + * for the algorithm and key specified for this bio. + */ + err = bio_crypt_ctx_acquire_keyslot(src_bio, blk_crypto_ksm); + if (err) { + src_bio->bi_status = BLK_STS_IOERR; + goto out_put_enc_bio; + } + + /* and then allocate an skcipher_request for it */ + err = blk_crypto_alloc_cipher_req(src_bio, &ciph_req, &wait); + if (err) + goto out_release_keyslot; + + curr_dun = bio_crypt_data_unit_num(src_bio); + sg_init_table(&src, 1); + sg_init_table(&dst, 1); + + skcipher_request_set_crypt(ciph_req, &src, &dst, + data_unit_size, iv.bytes); + + /* Encrypt each page in the bounce bio */ + for (i = 0, enc_bvec = enc_bio->bi_io_vec; i < enc_bio->bi_vcnt; + enc_bvec++, i++) { + struct page *plaintext_page = enc_bvec->bv_page; + struct page *ciphertext_page = + mempool_alloc(blk_crypto_page_pool, GFP_NOIO); + + enc_bvec->bv_page = ciphertext_page; + + if (!ciphertext_page) { + src_bio->bi_status = BLK_STS_RESOURCE; + err = -ENOMEM; + goto out_free_bounce_pages; + } + + sg_set_page(&src, plaintext_page, data_unit_size, + enc_bvec->bv_offset); + sg_set_page(&dst, ciphertext_page, data_unit_size, + enc_bvec->bv_offset); + + /* Encrypt each data unit in this page */ + for (j = 0; j < enc_bvec->bv_len; j += data_unit_size) { + memset(&iv, 0, sizeof(iv)); + iv.dun = cpu_to_le64(curr_dun); + + err = crypto_wait_req(crypto_skcipher_encrypt(ciph_req), + &wait); + if (err) { + i++; + src_bio->bi_status = BLK_STS_RESOURCE; + goto out_free_bounce_pages; + } + curr_dun++; + src.offset += data_unit_size; + dst.offset += data_unit_size; + } + } + + enc_bio->bi_private = src_bio; + enc_bio->bi_end_io = blk_crypto_encrypt_endio; + *bio_ptr = enc_bio; + + enc_bio = NULL; + err = 0; + goto out_free_ciph_req; + +out_free_bounce_pages: + while (i > 0) + mempool_free(enc_bio->bi_io_vec[--i].bv_page, + blk_crypto_page_pool); +out_free_ciph_req: + skcipher_request_free(ciph_req); +out_release_keyslot: + bio_crypt_ctx_release_keyslot(src_bio); +out_put_enc_bio: + if (enc_bio) + bio_put(enc_bio); + + return err; +} + +/* + * The crypto API fallback's main decryption routine. + * Decrypts input bio in place. + */ +static void blk_crypto_decrypt_bio(struct work_struct *w) +{ + struct work_mem *work_mem = + container_of(w, struct work_mem, crypto_work); + struct bio *bio = work_mem->bio; + struct skcipher_request *ciph_req = NULL; + DECLARE_CRYPTO_WAIT(wait); + struct bio_vec bv; + struct bvec_iter iter; + u64 curr_dun; + union { + __le64 dun; + u8 bytes[16]; + } iv; + struct scatterlist sg; + int data_unit_size = 1 << bio->bi_crypt_context->data_unit_size_bits; + int i; + int err; + + /* + * Use the crypto API fallback keyslot manager to get a crypto_skcipher + * for the algorithm and key specified for this bio. + */ + if (bio_crypt_ctx_acquire_keyslot(bio, blk_crypto_ksm)) { + bio->bi_status = BLK_STS_RESOURCE; + goto out_no_keyslot; + } + + /* and then allocate an skcipher_request for it */ + err = blk_crypto_alloc_cipher_req(bio, &ciph_req, &wait); + if (err) + goto out; + + curr_dun = bio_crypt_sw_data_unit_num(bio); + sg_init_table(&sg, 1); + skcipher_request_set_crypt(ciph_req, &sg, &sg, data_unit_size, + iv.bytes); + + /* Decrypt each segment in the bio */ + __bio_for_each_segment(bv, bio, iter, + bio->bi_crypt_context->crypt_iter) { + struct page *page = bv.bv_page; + + sg_set_page(&sg, page, data_unit_size, bv.bv_offset); + + /* Decrypt each data unit in the segment */ + for (i = 0; i < bv.bv_len; i += data_unit_size) { + memset(&iv, 0, sizeof(iv)); + iv.dun = cpu_to_le64(curr_dun); + if (crypto_wait_req(crypto_skcipher_decrypt(ciph_req), + &wait)) { + bio->bi_status = BLK_STS_IOERR; + goto out; + } + curr_dun++; + sg.offset += data_unit_size; + } + } + +out: + skcipher_request_free(ciph_req); + bio_crypt_ctx_release_keyslot(bio); +out_no_keyslot: + kmem_cache_free(blk_crypto_work_mem_cache, work_mem); + bio_endio(bio); +} + +/* Queue bio for decryption */ +static void blk_crypto_queue_decrypt_bio(struct bio *bio) +{ + struct work_mem *work_mem = + kmem_cache_zalloc(blk_crypto_work_mem_cache, GFP_ATOMIC); + + if (!work_mem) { + bio->bi_status = BLK_STS_RESOURCE; + bio_endio(bio); + return; + } + + INIT_WORK(&work_mem->crypto_work, blk_crypto_decrypt_bio); + work_mem->bio = bio; + queue_work(blk_crypto_wq, &work_mem->crypto_work); +} + +/** + * blk_crypto_submit_bio - handle submitting bio for inline encryption + * + * @bio_ptr: pointer to original bio pointer + * + * If the bio doesn't have inline encryption enabled or the submitter already + * specified a keyslot for the target device, do nothing. Else, a raw key must + * have been provided, so acquire a device keyslot for it if supported. Else, + * use the crypto API fallback. + * + * When the crypto API fallback is used for encryption, blk-crypto may choose to + * split the bio into 2 - the first one that will continue to be processed and + * the second one that will be resubmitted via generic_make_request. + * A bounce bio will be allocated to encrypt the contents of the aforementioned + * "first one", and *bio_ptr will be updated to this bounce bio. + * + * Return: 0 if bio submission should continue; nonzero if bio_endio() was + * already called so bio submission should abort. + */ +int blk_crypto_submit_bio(struct bio **bio_ptr) +{ + struct bio *bio = *bio_ptr; + struct request_queue *q; + int err; + struct bio_crypt_ctx *crypt_ctx; + + if (!bio_has_crypt_ctx(bio) || !bio_has_data(bio)) + return 0; + + /* + * When a read bio is marked for sw decryption, its bi_iter is saved + * so that when we decrypt the bio later, we know what part of it was + * marked for sw decryption (when the bio is passed down after + * blk_crypto_submit bio, it may be split or advanced so we cannot rely + * on the bi_iter while decrypting in blk_crypto_endio) + */ + if (bio_crypt_swhandled(bio)) + return 0; + + err = bio_crypt_check_alignment(bio); + if (err) + goto out; + + crypt_ctx = bio->bi_crypt_context; + q = bio->bi_disk->queue; + + if (bio_crypt_has_keyslot(bio)) { + /* Key already programmed into device? */ + if (q->ksm == crypt_ctx->processing_ksm) + return 0; + + /* Nope, release the existing keyslot. */ + bio_crypt_ctx_release_keyslot(bio); + } + + /* Get device keyslot if supported */ + if (q->ksm) { + err = bio_crypt_ctx_acquire_keyslot(bio, q->ksm); + if (!err) + return 0; + + pr_warn_once("Failed to acquire keyslot for %s (err=%d). Falling back to crypto API.\n", + bio->bi_disk->disk_name, err); + } + + /* Fallback to crypto API */ + if (!READ_ONCE(tfms_inited[bio->bi_crypt_context->crypto_mode])) { + err = -EIO; + bio->bi_status = BLK_STS_IOERR; + goto out; + } + + if (bio_data_dir(bio) == WRITE) { + /* Encrypt the data now */ + err = blk_crypto_encrypt_bio(bio_ptr); + if (err) + goto out; + } else { + /* Mark bio as swhandled */ + bio->bi_crypt_context->processing_ksm = blk_crypto_ksm; + bio->bi_crypt_context->crypt_iter = bio->bi_iter; + bio->bi_crypt_context->sw_data_unit_num = + bio->bi_crypt_context->data_unit_num; + } + return 0; +out: + bio_endio(*bio_ptr); + return err; +} + +/** + * blk_crypto_endio - clean up bio w.r.t inline encryption during bio_endio + * + * @bio - the bio to clean up + * + * If blk_crypto_submit_bio decided to fallback to crypto API for this + * bio, we queue the bio for decryption into a workqueue and return false, + * and call bio_endio(bio) at a later time (after the bio has been decrypted). + * + * If the bio is not to be decrypted by the crypto API, this function releases + * the reference to the keyslot that blk_crypto_submit_bio got. + * + * Return: true if bio_endio should continue; false otherwise (bio_endio will + * be called again when bio has been decrypted). + */ +bool blk_crypto_endio(struct bio *bio) +{ + if (!bio_has_crypt_ctx(bio)) + return true; + + if (bio_crypt_swhandled(bio)) { + /* + * The only bios that are swhandled when they reach here + * are those with bio_data_dir(bio) == READ, since WRITE + * bios that are encrypted by the crypto API fallback are + * handled by blk_crypto_encrypt_endio. + */ + + /* If there was an IO error, don't decrypt. */ + if (bio->bi_status) + return true; + + blk_crypto_queue_decrypt_bio(bio); + return false; + } + + if (bio_has_crypt_ctx(bio) && bio_crypt_has_keyslot(bio)) + bio_crypt_ctx_release_keyslot(bio); + + return true; +} + +/* + * blk_crypto_mode_alloc_ciphers() - Allocate skciphers for a + * mode_num for all keyslots + * @mode_num - the blk_crypto_mode we want to allocate ciphers for. + * + * Upper layers (filesystems) should call this function to ensure that a + * the crypto API fallback has transforms for this algorithm, if they become + * necessary. + * + */ +int blk_crypto_mode_alloc_ciphers(enum blk_crypto_mode_num mode_num) +{ + struct blk_crypto_keyslot *slotp; + int err = 0; + int i; + + /* Fast path */ + if (likely(READ_ONCE(tfms_inited[mode_num]))) { + /* + * Ensure that updates to blk_crypto_keyslots[i].tfms[mode_num] + * for each i are visible before we try to access them. + */ + smp_rmb(); + return 0; + } + + mutex_lock(&tfms_lock[mode_num]); + if (likely(tfms_inited[mode_num])) + goto out; + + for (i = 0; i < blk_crypto_num_keyslots; i++) { + slotp = &blk_crypto_keyslots[i]; + slotp->tfms[mode_num] = crypto_alloc_skcipher( + blk_crypto_modes[mode_num].cipher_str, + 0, 0); + if (IS_ERR(slotp->tfms[mode_num])) { + err = PTR_ERR(slotp->tfms[mode_num]); + slotp->tfms[mode_num] = NULL; + goto out_free_tfms; + } + + crypto_skcipher_set_flags(slotp->tfms[mode_num], + CRYPTO_TFM_REQ_FORBID_WEAK_KEYS); + } + + /* + * Ensure that updates to blk_crypto_keyslots[i].tfms[mode_num] + * for each i are visible before we set tfms_inited[mode_num]. + */ + smp_wmb(); + WRITE_ONCE(tfms_inited[mode_num], true); + goto out; + +out_free_tfms: + for (i = 0; i < blk_crypto_num_keyslots; i++) { + slotp = &blk_crypto_keyslots[i]; + crypto_free_skcipher(slotp->tfms[mode_num]); + slotp->tfms[mode_num] = NULL; + } +out: + mutex_unlock(&tfms_lock[mode_num]); + return err; +} +EXPORT_SYMBOL(blk_crypto_mode_alloc_ciphers); + +int __init blk_crypto_init(void) +{ + int i; + int err = -ENOMEM; + + blk_crypto_ksm = keyslot_manager_create(blk_crypto_num_keyslots, + &blk_crypto_ksm_ll_ops, + NULL); + if (!blk_crypto_ksm) + goto out; + + blk_crypto_wq = alloc_workqueue("blk_crypto_wq", + WQ_UNBOUND | WQ_HIGHPRI | + WQ_MEM_RECLAIM, + num_online_cpus()); + if (!blk_crypto_wq) + goto out_free_ksm; + + blk_crypto_keyslots = kcalloc(blk_crypto_num_keyslots, + sizeof(*blk_crypto_keyslots), + GFP_KERNEL); + if (!blk_crypto_keyslots) + goto out_free_workqueue; + + for (i = 0; i < ARRAY_SIZE(blk_crypto_modes); i++) + mutex_init(&tfms_lock[i]); + + blk_crypto_page_pool = + mempool_create_page_pool(num_prealloc_bounce_pg, 0); + if (!blk_crypto_page_pool) + goto out_free_keyslots; + + blk_crypto_work_mem_cache = KMEM_CACHE(work_mem, SLAB_RECLAIM_ACCOUNT); + if (!blk_crypto_work_mem_cache) + goto out_free_page_pool; + + return 0; + +out_free_page_pool: + mempool_destroy(blk_crypto_page_pool); + blk_crypto_page_pool = NULL; +out_free_keyslots: + kzfree(blk_crypto_keyslots); + blk_crypto_keyslots = NULL; +out_free_workqueue: + destroy_workqueue(blk_crypto_wq); + blk_crypto_wq = NULL; +out_free_ksm: + keyslot_manager_destroy(blk_crypto_ksm); + blk_crypto_ksm = NULL; +out: + pr_warn("No memory for blk-crypto crypto API fallback."); + return err; +} diff --git a/include/linux/bio-crypt-ctx.h b/include/linux/bio-crypt-ctx.h index ebe456289338..b9e0515143a4 100644 --- a/include/linux/bio-crypt-ctx.h +++ b/include/linux/bio-crypt-ctx.h @@ -60,6 +60,8 @@ static inline void bio_crypt_advance(struct bio *bio, unsigned int bytes) } } +extern bool bio_crypt_swhandled(struct bio *bio); + static inline bool bio_crypt_has_keyslot(struct bio *bio) { return bio->bi_crypt_context->keyslot >= 0; @@ -177,6 +179,11 @@ static inline void bio_crypt_set_ctx(struct bio *bio, unsigned int dun_bits, gfp_t gfp_mask) { } +static inline bool bio_crypt_swhandled(struct bio *bio) +{ + return false; +} + static inline void bio_set_data_unit_num(struct bio *bio, u64 dun) { } static inline bool bio_crypt_has_keyslot(struct bio *bio) diff --git a/include/linux/blk-crypto.h b/include/linux/blk-crypto.h new file mode 100644 index 000000000000..42dbba33598f --- /dev/null +++ b/include/linux/blk-crypto.h @@ -0,0 +1,47 @@ +/* SPDX-License-Identifier: GPL-2.0 */ +/* + * Copyright 2019 Google LLC + */ + +#ifndef __LINUX_BLK_CRYPTO_H +#define __LINUX_BLK_CRYPTO_H + +#include <linux/types.h> +#include <linux/bio.h> + +#ifdef CONFIG_BLK_INLINE_ENCRYPTION + +int blk_crypto_init(void); + +int blk_crypto_submit_bio(struct bio **bio_ptr); + +bool blk_crypto_endio(struct bio *bio); + +int blk_crypto_mode_alloc_ciphers(enum blk_crypto_mode_num mode_num); + +#else /* CONFIG_BLK_INLINE_ENCRYPTION */ + +static inline int blk_crypto_init(void) +{ + return 0; +} + +static inline int blk_crypto_submit_bio(struct bio **bio_ptr) +{ + return 0; +} + +static inline bool blk_crypto_endio(struct bio *bio) +{ + return true; +} + +static inline int +blk_crypto_mode_alloc_ciphers(enum blk_crypto_mode_num mode_num) +{ + return -EOPNOTSUPP; +} + +#endif /* CONFIG_BLK_INLINE_ENCRYPTION */ + +#endif /* __LINUX_BLK_CRYPTO_H */ -- 2.23.0.rc1.153.gdeed80330f-goog