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https://github.com/AuxXxilium/linux_dsm_epyc7002.git
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12d28f7955
fscrypt currently only supports AES encryption. However, many low-end mobile devices have older CPUs that don't have AES instructions, e.g. the ARMv8 Cryptography Extensions. Currently, user data on such devices is not encrypted at rest because AES is too slow, even when the NEON bit-sliced implementation of AES is used. Unfortunately, it is infeasible to encrypt these devices at all when AES is the only option. Therefore, this patch updates fscrypt to support the Speck block cipher, which was recently added to the crypto API. The C implementation of Speck is not especially fast, but Speck can be implemented very efficiently with general-purpose vector instructions, e.g. ARM NEON. For example, on an ARMv7 processor, we measured the NEON-accelerated Speck128/256-XTS at 69 MB/s for both encryption and decryption, while AES-256-XTS with the NEON bit-sliced implementation was only 22 MB/s encryption and 19 MB/s decryption. There are multiple variants of Speck. This patch only adds support for Speck128/256, which is the variant with a 128-bit block size and 256-bit key size -- the same as AES-256. This is believed to be the most secure variant of Speck, and it's only about 6% slower than Speck128/128. Speck64/128 would be at least 20% faster because it has 20% rounds, and it can be even faster on CPUs that can't efficiently do the 64-bit operations needed for Speck128. However, Speck64's 64-bit block size is not preferred security-wise. ARM NEON also supports the needed 64-bit operations even on 32-bit CPUs, resulting in Speck128 being fast enough for our targeted use cases so far. The chosen modes of operation are XTS for contents and CTS-CBC for filenames. These are the same modes of operation that fscrypt defaults to for AES. Note that as with the other fscrypt modes, Speck will not be used unless userspace chooses to use it. Nor are any of the existing modes (which are all AES-based) being removed, of course. We intentionally don't make CONFIG_FS_ENCRYPTION select CONFIG_CRYPTO_SPECK, so people will have to enable Speck support themselves if they need it. This is because we shouldn't bloat the FS_ENCRYPTION dependencies with every new cipher, especially ones that aren't recommended for most users. Moreover, CRYPTO_SPECK is just the generic implementation, which won't be fast enough for many users; in practice, they'll need to enable CRYPTO_SPECK_NEON to get acceptable performance. More details about our choice of Speck can be found in our patches that added Speck to the crypto API, and the follow-on discussion threads. We're planning a publication that explains the choice in more detail. But briefly, we can't use ChaCha20 as we previously proposed, since it would be insecure to use a stream cipher in this context, with potential IV reuse during writes on f2fs and/or on wear-leveling flash storage. We also evaluated many other lightweight and/or ARX-based block ciphers such as Chaskey-LTS, RC5, LEA, CHAM, Threefish, RC6, NOEKEON, SPARX, and XTEA. However, all had disadvantages vs. Speck, such as insufficient performance with NEON, much less published cryptanalysis, or an insufficient security level. Various design choices in Speck make it perform better with NEON than competing ciphers while still having a security margin similar to AES, and in the case of Speck128 also the same available security levels. Unfortunately, Speck does have some political baggage attached -- it's an NSA designed cipher, and was rejected from an ISO standard (though for context, as far as I know none of the above-mentioned alternatives are ISO standards either). Nevertheless, we believe it is a good solution to the problem from a technical perspective. Certain algorithms constructed from ChaCha or the ChaCha permutation, such as MEM (Masked Even-Mansour) or HPolyC, may also meet our performance requirements. However, these are new constructions that need more time to receive the cryptographic review and acceptance needed to be confident in their security. HPolyC hasn't been published yet, and we are concerned that MEM makes stronger assumptions about the underlying permutation than the ChaCha stream cipher does. In contrast, the XTS mode of operation is relatively well accepted, and Speck has over 70 cryptanalysis papers. Of course, these ChaCha-based algorithms can still be added later if they become ready. The best known attack on Speck128/256 is a differential cryptanalysis attack on 25 of 34 rounds with 2^253 time complexity and 2^125 chosen plaintexts, i.e. only marginally faster than brute force. There is no known attack on the full 34 rounds. Signed-off-by: Eric Biggers <ebiggers@google.com> Signed-off-by: Theodore Ts'o <tytso@mit.edu>
126 lines
3.3 KiB
C
126 lines
3.3 KiB
C
/* SPDX-License-Identifier: GPL-2.0 */
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/*
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* fscrypt_private.h
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*
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* Copyright (C) 2015, Google, Inc.
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*
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* This contains encryption key functions.
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*
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* Written by Michael Halcrow, Ildar Muslukhov, and Uday Savagaonkar, 2015.
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*/
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#ifndef _FSCRYPT_PRIVATE_H
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#define _FSCRYPT_PRIVATE_H
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#define __FS_HAS_ENCRYPTION 1
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#include <linux/fscrypt.h>
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#include <crypto/hash.h>
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/* Encryption parameters */
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#define FS_IV_SIZE 16
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#define FS_KEY_DERIVATION_NONCE_SIZE 16
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/**
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* Encryption context for inode
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*
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* Protector format:
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* 1 byte: Protector format (1 = this version)
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* 1 byte: File contents encryption mode
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* 1 byte: File names encryption mode
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* 1 byte: Flags
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* 8 bytes: Master Key descriptor
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* 16 bytes: Encryption Key derivation nonce
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*/
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struct fscrypt_context {
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u8 format;
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u8 contents_encryption_mode;
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u8 filenames_encryption_mode;
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u8 flags;
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u8 master_key_descriptor[FS_KEY_DESCRIPTOR_SIZE];
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u8 nonce[FS_KEY_DERIVATION_NONCE_SIZE];
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} __packed;
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#define FS_ENCRYPTION_CONTEXT_FORMAT_V1 1
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/**
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* For encrypted symlinks, the ciphertext length is stored at the beginning
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* of the string in little-endian format.
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*/
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struct fscrypt_symlink_data {
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__le16 len;
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char encrypted_path[1];
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} __packed;
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/*
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* A pointer to this structure is stored in the file system's in-core
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* representation of an inode.
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*/
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struct fscrypt_info {
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u8 ci_data_mode;
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u8 ci_filename_mode;
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u8 ci_flags;
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struct crypto_skcipher *ci_ctfm;
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struct crypto_cipher *ci_essiv_tfm;
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u8 ci_master_key[FS_KEY_DESCRIPTOR_SIZE];
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};
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typedef enum {
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FS_DECRYPT = 0,
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FS_ENCRYPT,
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} fscrypt_direction_t;
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#define FS_CTX_REQUIRES_FREE_ENCRYPT_FL 0x00000001
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#define FS_CTX_HAS_BOUNCE_BUFFER_FL 0x00000002
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static inline bool fscrypt_valid_enc_modes(u32 contents_mode,
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u32 filenames_mode)
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{
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if (contents_mode == FS_ENCRYPTION_MODE_AES_128_CBC &&
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filenames_mode == FS_ENCRYPTION_MODE_AES_128_CTS)
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return true;
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if (contents_mode == FS_ENCRYPTION_MODE_AES_256_XTS &&
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filenames_mode == FS_ENCRYPTION_MODE_AES_256_CTS)
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return true;
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if (contents_mode == FS_ENCRYPTION_MODE_SPECK128_256_XTS &&
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filenames_mode == FS_ENCRYPTION_MODE_SPECK128_256_CTS)
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return true;
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return false;
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}
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/* crypto.c */
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extern struct kmem_cache *fscrypt_info_cachep;
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extern int fscrypt_initialize(unsigned int cop_flags);
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extern struct workqueue_struct *fscrypt_read_workqueue;
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extern int fscrypt_do_page_crypto(const struct inode *inode,
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fscrypt_direction_t rw, u64 lblk_num,
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struct page *src_page,
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struct page *dest_page,
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unsigned int len, unsigned int offs,
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gfp_t gfp_flags);
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extern struct page *fscrypt_alloc_bounce_page(struct fscrypt_ctx *ctx,
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gfp_t gfp_flags);
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extern const struct dentry_operations fscrypt_d_ops;
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extern void __printf(3, 4) __cold
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fscrypt_msg(struct super_block *sb, const char *level, const char *fmt, ...);
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#define fscrypt_warn(sb, fmt, ...) \
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fscrypt_msg(sb, KERN_WARNING, fmt, ##__VA_ARGS__)
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#define fscrypt_err(sb, fmt, ...) \
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fscrypt_msg(sb, KERN_ERR, fmt, ##__VA_ARGS__)
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/* fname.c */
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extern int fname_encrypt(struct inode *inode, const struct qstr *iname,
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u8 *out, unsigned int olen);
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extern bool fscrypt_fname_encrypted_size(const struct inode *inode,
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u32 orig_len, u32 max_len,
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u32 *encrypted_len_ret);
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/* keyinfo.c */
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extern void __exit fscrypt_essiv_cleanup(void);
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#endif /* _FSCRYPT_PRIVATE_H */
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