| Author | Tokens | Token Proportion | Commits | Commit Proportion |
|---|---|---|---|---|
| Harald Freudenberger | 4155 | 100.00% | 2 | 100.00% |
| Total | 4155 | 2 |
// SPDX-License-Identifier: GPL-2.0+ /* * Copyright IBM Corp. 2025 * * s390 specific HMAC support for protected keys. */ #define KMSG_COMPONENT "phmac_s390" #define pr_fmt(fmt) KMSG_COMPONENT ": " fmt #include <asm/cpacf.h> #include <asm/pkey.h> #include <crypto/engine.h> #include <crypto/hash.h> #include <crypto/internal/hash.h> #include <crypto/sha2.h> #include <linux/atomic.h> #include <linux/cpufeature.h> #include <linux/delay.h> #include <linux/miscdevice.h> #include <linux/module.h> #include <linux/spinlock.h> static struct crypto_engine *phmac_crypto_engine; #define MAX_QLEN 10 /* * A simple hash walk helper */ struct hash_walk_helper { struct crypto_hash_walk walk; const u8 *walkaddr; int walkbytes; }; /* * Prepare hash walk helper. * Set up the base hash walk, fill walkaddr and walkbytes. * Returns 0 on success or negative value on error. */ static inline int hwh_prepare(struct ahash_request *req, struct hash_walk_helper *hwh) { hwh->walkbytes = crypto_hash_walk_first(req, &hwh->walk); if (hwh->walkbytes < 0) return hwh->walkbytes; hwh->walkaddr = hwh->walk.data; return 0; } /* * Advance hash walk helper by n bytes. * Progress the walkbytes and walkaddr fields by n bytes. * If walkbytes is then 0, pull next hunk from hash walk * and update walkbytes and walkaddr. * If n is negative, unmap hash walk and return error. * Returns 0 on success or negative value on error. */ static inline int hwh_advance(struct hash_walk_helper *hwh, int n) { if (n < 0) return crypto_hash_walk_done(&hwh->walk, n); hwh->walkbytes -= n; hwh->walkaddr += n; if (hwh->walkbytes > 0) return 0; hwh->walkbytes = crypto_hash_walk_done(&hwh->walk, 0); if (hwh->walkbytes < 0) return hwh->walkbytes; hwh->walkaddr = hwh->walk.data; return 0; } /* * KMAC param block layout for sha2 function codes: * The layout of the param block for the KMAC instruction depends on the * blocksize of the used hashing sha2-algorithm function codes. The param block * contains the hash chaining value (cv), the input message bit-length (imbl) * and the hmac-secret (key). To prevent code duplication, the sizes of all * these are calculated based on the blocksize. * * param-block: * +-------+ * | cv | * +-------+ * | imbl | * +-------+ * | key | * +-------+ * * sizes: * part | sh2-alg | calculation | size | type * -----+---------+-------------+------+-------- * cv | 224/256 | blocksize/2 | 32 | u64[8] * | 384/512 | | 64 | u128[8] * imbl | 224/256 | blocksize/8 | 8 | u64 * | 384/512 | | 16 | u128 * key | 224/256 | blocksize | 96 | u8[96] * | 384/512 | | 160 | u8[160] */ #define MAX_DIGEST_SIZE SHA512_DIGEST_SIZE #define MAX_IMBL_SIZE sizeof(u128) #define MAX_BLOCK_SIZE SHA512_BLOCK_SIZE #define SHA2_CV_SIZE(bs) ((bs) >> 1) #define SHA2_IMBL_SIZE(bs) ((bs) >> 3) #define SHA2_IMBL_OFFSET(bs) (SHA2_CV_SIZE(bs)) #define SHA2_KEY_OFFSET(bs) (SHA2_CV_SIZE(bs) + SHA2_IMBL_SIZE(bs)) #define PHMAC_MAX_KEYSIZE 256 #define PHMAC_SHA256_PK_SIZE (SHA256_BLOCK_SIZE + 32) #define PHMAC_SHA512_PK_SIZE (SHA512_BLOCK_SIZE + 32) #define PHMAC_MAX_PK_SIZE PHMAC_SHA512_PK_SIZE /* phmac protected key struct */ struct phmac_protkey { u32 type; u32 len; u8 protkey[PHMAC_MAX_PK_SIZE]; }; #define PK_STATE_NO_KEY 0 #define PK_STATE_CONVERT_IN_PROGRESS 1 #define PK_STATE_VALID 2 /* phmac tfm context */ struct phmac_tfm_ctx { /* source key material used to derive a protected key from */ u8 keybuf[PHMAC_MAX_KEYSIZE]; unsigned int keylen; /* cpacf function code to use with this protected key type */ long fc; /* nr of requests enqueued via crypto engine which use this tfm ctx */ atomic_t via_engine_ctr; /* spinlock to atomic read/update all the following fields */ spinlock_t pk_lock; /* see PK_STATE* defines above, < 0 holds convert failure rc */ int pk_state; /* if state is valid, pk holds the protected key */ struct phmac_protkey pk; }; union kmac_gr0 { unsigned long reg; struct { unsigned long : 48; unsigned long ikp : 1; unsigned long iimp : 1; unsigned long ccup : 1; unsigned long : 6; unsigned long fc : 7; }; }; struct kmac_sha2_ctx { u8 param[MAX_DIGEST_SIZE + MAX_IMBL_SIZE + PHMAC_MAX_PK_SIZE]; union kmac_gr0 gr0; u8 buf[MAX_BLOCK_SIZE]; u64 buflen[2]; }; /* phmac request context */ struct phmac_req_ctx { struct hash_walk_helper hwh; struct kmac_sha2_ctx kmac_ctx; bool final; }; /* * Pkey 'token' struct used to derive a protected key value from a clear key. */ struct hmac_clrkey_token { u8 type; u8 res0[3]; u8 version; u8 res1[3]; u32 keytype; u32 len; u8 key[]; } __packed; static int hash_key(const u8 *in, unsigned int inlen, u8 *digest, unsigned int digestsize) { unsigned long func; union { struct sha256_paramblock { u32 h[8]; u64 mbl; } sha256; struct sha512_paramblock { u64 h[8]; u128 mbl; } sha512; } __packed param; #define PARAM_INIT(x, y, z) \ param.sha##x.h[0] = SHA##y ## _H0; \ param.sha##x.h[1] = SHA##y ## _H1; \ param.sha##x.h[2] = SHA##y ## _H2; \ param.sha##x.h[3] = SHA##y ## _H3; \ param.sha##x.h[4] = SHA##y ## _H4; \ param.sha##x.h[5] = SHA##y ## _H5; \ param.sha##x.h[6] = SHA##y ## _H6; \ param.sha##x.h[7] = SHA##y ## _H7; \ param.sha##x.mbl = (z) switch (digestsize) { case SHA224_DIGEST_SIZE: func = CPACF_KLMD_SHA_256; PARAM_INIT(256, 224, inlen * 8); break; case SHA256_DIGEST_SIZE: func = CPACF_KLMD_SHA_256; PARAM_INIT(256, 256, inlen * 8); break; case SHA384_DIGEST_SIZE: func = CPACF_KLMD_SHA_512; PARAM_INIT(512, 384, inlen * 8); break; case SHA512_DIGEST_SIZE: func = CPACF_KLMD_SHA_512; PARAM_INIT(512, 512, inlen * 8); break; default: return -EINVAL; } #undef PARAM_INIT cpacf_klmd(func, ¶m, in, inlen); memcpy(digest, ¶m, digestsize); return 0; } /* * make_clrkey_token() - wrap the clear key into a pkey clearkey token. */ static inline int make_clrkey_token(const u8 *clrkey, size_t clrkeylen, unsigned int digestsize, u8 *dest) { struct hmac_clrkey_token *token = (struct hmac_clrkey_token *)dest; unsigned int blocksize; int rc; token->type = 0x00; token->version = 0x02; switch (digestsize) { case SHA224_DIGEST_SIZE: case SHA256_DIGEST_SIZE: token->keytype = PKEY_KEYTYPE_HMAC_512; blocksize = 64; break; case SHA384_DIGEST_SIZE: case SHA512_DIGEST_SIZE: token->keytype = PKEY_KEYTYPE_HMAC_1024; blocksize = 128; break; default: return -EINVAL; } token->len = blocksize; if (clrkeylen > blocksize) { rc = hash_key(clrkey, clrkeylen, token->key, digestsize); if (rc) return rc; } else { memcpy(token->key, clrkey, clrkeylen); } return 0; } /* * phmac_tfm_ctx_setkey() - Set key value into tfm context, maybe construct * a clear key token digestible by pkey from a clear key value. */ static inline int phmac_tfm_ctx_setkey(struct phmac_tfm_ctx *tfm_ctx, const u8 *key, unsigned int keylen) { if (keylen > sizeof(tfm_ctx->keybuf)) return -EINVAL; memcpy(tfm_ctx->keybuf, key, keylen); tfm_ctx->keylen = keylen; return 0; } /* * Convert the raw key material into a protected key via PKEY api. * This function may sleep - don't call in non-sleeping context. */ static inline int convert_key(const u8 *key, unsigned int keylen, struct phmac_protkey *pk) { int rc, i; pk->len = sizeof(pk->protkey); /* * In case of a busy card retry with increasing delay * of 200, 400, 800 and 1600 ms - in total 3 s. */ for (rc = -EIO, i = 0; rc && i < 5; i++) { if (rc == -EBUSY && msleep_interruptible((1 << i) * 100)) { rc = -EINTR; goto out; } rc = pkey_key2protkey(key, keylen, pk->protkey, &pk->len, &pk->type, PKEY_XFLAG_NOMEMALLOC); } out: pr_debug("rc=%d\n", rc); return rc; } /* * (Re-)Convert the raw key material from the tfm ctx into a protected * key via convert_key() function. Update the pk_state, pk_type, pk_len * and the protected key in the tfm context. * Please note this function may be invoked concurrently with the very * same tfm context. The pk_lock spinlock in the context ensures an * atomic update of the pk and the pk state but does not guarantee any * order of update. So a fresh converted valid protected key may get * updated with an 'old' expired key value. As the cpacf instructions * detect this, refuse to operate with an invalid key and the calling * code triggers a (re-)conversion this does no harm. This may lead to * unnecessary additional conversion but never to invalid data on the * hash operation. */ static int phmac_convert_key(struct phmac_tfm_ctx *tfm_ctx) { struct phmac_protkey pk; int rc; spin_lock_bh(&tfm_ctx->pk_lock); tfm_ctx->pk_state = PK_STATE_CONVERT_IN_PROGRESS; spin_unlock_bh(&tfm_ctx->pk_lock); rc = convert_key(tfm_ctx->keybuf, tfm_ctx->keylen, &pk); /* update context */ spin_lock_bh(&tfm_ctx->pk_lock); if (rc) { tfm_ctx->pk_state = rc; } else { tfm_ctx->pk_state = PK_STATE_VALID; tfm_ctx->pk = pk; } spin_unlock_bh(&tfm_ctx->pk_lock); memzero_explicit(&pk, sizeof(pk)); pr_debug("rc=%d\n", rc); return rc; } /* * kmac_sha2_set_imbl - sets the input message bit-length based on the blocksize */ static inline void kmac_sha2_set_imbl(u8 *param, u64 buflen_lo, u64 buflen_hi, unsigned int blocksize) { u8 *imbl = param + SHA2_IMBL_OFFSET(blocksize); switch (blocksize) { case SHA256_BLOCK_SIZE: *(u64 *)imbl = buflen_lo * BITS_PER_BYTE; break; case SHA512_BLOCK_SIZE: *(u128 *)imbl = (((u128)buflen_hi << 64) + buflen_lo) << 3; break; default: break; } } static int phmac_kmac_update(struct ahash_request *req, bool maysleep) { struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *ctx = &req_ctx->kmac_ctx; struct hash_walk_helper *hwh = &req_ctx->hwh; unsigned int bs = crypto_ahash_blocksize(tfm); unsigned int offset, k, n; int rc = 0; /* * The walk is always mapped when this function is called. * Note that in case of partial processing or failure the walk * is NOT unmapped here. So a follow up task may reuse the walk * or in case of unrecoverable failure needs to unmap it. */ while (hwh->walkbytes > 0) { /* check sha2 context buffer */ offset = ctx->buflen[0] % bs; if (offset + hwh->walkbytes < bs) goto store; if (offset) { /* fill ctx buffer up to blocksize and process this block */ n = bs - offset; memcpy(ctx->buf + offset, hwh->walkaddr, n); ctx->gr0.iimp = 1; for (;;) { k = _cpacf_kmac(&ctx->gr0.reg, ctx->param, ctx->buf, bs); if (likely(k == bs)) break; if (unlikely(k > 0)) { /* * Can't deal with hunks smaller than blocksize. * And kmac should always return the nr of * processed bytes as 0 or a multiple of the * blocksize. */ rc = -EIO; goto out; } /* protected key is invalid and needs re-conversion */ if (!maysleep) { rc = -EKEYEXPIRED; goto out; } rc = phmac_convert_key(tfm_ctx); if (rc) goto out; spin_lock_bh(&tfm_ctx->pk_lock); memcpy(ctx->param + SHA2_KEY_OFFSET(bs), tfm_ctx->pk.protkey, tfm_ctx->pk.len); spin_unlock_bh(&tfm_ctx->pk_lock); } ctx->buflen[0] += n; if (ctx->buflen[0] < n) ctx->buflen[1]++; rc = hwh_advance(hwh, n); if (unlikely(rc)) goto out; offset = 0; } /* process as many blocks as possible from the walk */ while (hwh->walkbytes >= bs) { n = (hwh->walkbytes / bs) * bs; ctx->gr0.iimp = 1; k = _cpacf_kmac(&ctx->gr0.reg, ctx->param, hwh->walkaddr, n); if (likely(k > 0)) { ctx->buflen[0] += k; if (ctx->buflen[0] < k) ctx->buflen[1]++; rc = hwh_advance(hwh, k); if (unlikely(rc)) goto out; } if (unlikely(k < n)) { /* protected key is invalid and needs re-conversion */ if (!maysleep) { rc = -EKEYEXPIRED; goto out; } rc = phmac_convert_key(tfm_ctx); if (rc) goto out; spin_lock_bh(&tfm_ctx->pk_lock); memcpy(ctx->param + SHA2_KEY_OFFSET(bs), tfm_ctx->pk.protkey, tfm_ctx->pk.len); spin_unlock_bh(&tfm_ctx->pk_lock); } } store: /* store incomplete block in context buffer */ if (hwh->walkbytes) { memcpy(ctx->buf + offset, hwh->walkaddr, hwh->walkbytes); ctx->buflen[0] += hwh->walkbytes; if (ctx->buflen[0] < hwh->walkbytes) ctx->buflen[1]++; rc = hwh_advance(hwh, hwh->walkbytes); if (unlikely(rc)) goto out; } } /* end of while (hwh->walkbytes > 0) */ out: pr_debug("rc=%d\n", rc); return rc; } static int phmac_kmac_final(struct ahash_request *req, bool maysleep) { struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *ctx = &req_ctx->kmac_ctx; unsigned int ds = crypto_ahash_digestsize(tfm); unsigned int bs = crypto_ahash_blocksize(tfm); unsigned int k, n; int rc = 0; n = ctx->buflen[0] % bs; ctx->gr0.iimp = 0; kmac_sha2_set_imbl(ctx->param, ctx->buflen[0], ctx->buflen[1], bs); for (;;) { k = _cpacf_kmac(&ctx->gr0.reg, ctx->param, ctx->buf, n); if (likely(k == n)) break; if (unlikely(k > 0)) { /* Can't deal with hunks smaller than blocksize. */ rc = -EIO; goto out; } /* protected key is invalid and needs re-conversion */ if (!maysleep) { rc = -EKEYEXPIRED; goto out; } rc = phmac_convert_key(tfm_ctx); if (rc) goto out; spin_lock_bh(&tfm_ctx->pk_lock); memcpy(ctx->param + SHA2_KEY_OFFSET(bs), tfm_ctx->pk.protkey, tfm_ctx->pk.len); spin_unlock_bh(&tfm_ctx->pk_lock); } memcpy(req->result, ctx->param, ds); out: pr_debug("rc=%d\n", rc); return rc; } static int phmac_init(struct ahash_request *req) { struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *kmac_ctx = &req_ctx->kmac_ctx; unsigned int bs = crypto_ahash_blocksize(tfm); int rc = 0; /* zero request context (includes the kmac sha2 context) */ memset(req_ctx, 0, sizeof(*req_ctx)); /* * setkey() should have set a valid fc into the tfm context. * Copy this function code into the gr0 field of the kmac context. */ if (!tfm_ctx->fc) { rc = -ENOKEY; goto out; } kmac_ctx->gr0.fc = tfm_ctx->fc; /* * Copy the pk from tfm ctx into kmac ctx. The protected key * may be outdated but update() and final() will handle this. */ spin_lock_bh(&tfm_ctx->pk_lock); memcpy(kmac_ctx->param + SHA2_KEY_OFFSET(bs), tfm_ctx->pk.protkey, tfm_ctx->pk.len); spin_unlock_bh(&tfm_ctx->pk_lock); out: pr_debug("rc=%d\n", rc); return rc; } static int phmac_update(struct ahash_request *req) { struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct kmac_sha2_ctx *kmac_ctx = &req_ctx->kmac_ctx; struct hash_walk_helper *hwh = &req_ctx->hwh; int rc; /* prep the walk in the request context */ rc = hwh_prepare(req, hwh); if (rc) goto out; /* Try synchronous operation if no active engine usage */ if (!atomic_read(&tfm_ctx->via_engine_ctr)) { rc = phmac_kmac_update(req, false); if (rc == 0) goto out; } /* * If sync operation failed or key expired or there are already * requests enqueued via engine, fallback to async. Mark tfm as * using engine to serialize requests. */ if (rc == 0 || rc == -EKEYEXPIRED) { atomic_inc(&tfm_ctx->via_engine_ctr); rc = crypto_transfer_hash_request_to_engine(phmac_crypto_engine, req); if (rc != -EINPROGRESS) atomic_dec(&tfm_ctx->via_engine_ctr); } if (rc != -EINPROGRESS) { hwh_advance(hwh, rc); memzero_explicit(kmac_ctx, sizeof(*kmac_ctx)); } out: pr_debug("rc=%d\n", rc); return rc; } static int phmac_final(struct ahash_request *req) { struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct kmac_sha2_ctx *kmac_ctx = &req_ctx->kmac_ctx; int rc = 0; /* Try synchronous operation if no active engine usage */ if (!atomic_read(&tfm_ctx->via_engine_ctr)) { rc = phmac_kmac_final(req, false); if (rc == 0) goto out; } /* * If sync operation failed or key expired or there are already * requests enqueued via engine, fallback to async. Mark tfm as * using engine to serialize requests. */ if (rc == 0 || rc == -EKEYEXPIRED) { req->nbytes = 0; req_ctx->final = true; atomic_inc(&tfm_ctx->via_engine_ctr); rc = crypto_transfer_hash_request_to_engine(phmac_crypto_engine, req); if (rc != -EINPROGRESS) atomic_dec(&tfm_ctx->via_engine_ctr); } out: if (rc != -EINPROGRESS) memzero_explicit(kmac_ctx, sizeof(*kmac_ctx)); pr_debug("rc=%d\n", rc); return rc; } static int phmac_finup(struct ahash_request *req) { struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct kmac_sha2_ctx *kmac_ctx = &req_ctx->kmac_ctx; struct hash_walk_helper *hwh = &req_ctx->hwh; int rc; /* prep the walk in the request context */ rc = hwh_prepare(req, hwh); if (rc) goto out; /* Try synchronous operations if no active engine usage */ if (!atomic_read(&tfm_ctx->via_engine_ctr)) { rc = phmac_kmac_update(req, false); if (rc == 0) req->nbytes = 0; } if (!rc && !req->nbytes && !atomic_read(&tfm_ctx->via_engine_ctr)) { rc = phmac_kmac_final(req, false); if (rc == 0) goto out; } /* * If sync operation failed or key expired or there are already * requests enqueued via engine, fallback to async. Mark tfm as * using engine to serialize requests. */ if (rc == 0 || rc == -EKEYEXPIRED) { req_ctx->final = true; atomic_inc(&tfm_ctx->via_engine_ctr); rc = crypto_transfer_hash_request_to_engine(phmac_crypto_engine, req); if (rc != -EINPROGRESS) atomic_dec(&tfm_ctx->via_engine_ctr); } if (rc != -EINPROGRESS) hwh_advance(hwh, rc); out: if (rc != -EINPROGRESS) memzero_explicit(kmac_ctx, sizeof(*kmac_ctx)); pr_debug("rc=%d\n", rc); return rc; } static int phmac_digest(struct ahash_request *req) { int rc; rc = phmac_init(req); if (rc) goto out; rc = phmac_finup(req); out: pr_debug("rc=%d\n", rc); return rc; } static int phmac_setkey(struct crypto_ahash *tfm, const u8 *key, unsigned int keylen) { struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); unsigned int ds = crypto_ahash_digestsize(tfm); unsigned int bs = crypto_ahash_blocksize(tfm); unsigned int tmpkeylen; u8 *tmpkey = NULL; int rc = 0; if (!crypto_ahash_tested(tfm)) { /* * selftest running: key is a raw hmac clear key and needs * to get embedded into a 'clear key token' in order to have * it correctly processed by the pkey module. */ tmpkeylen = sizeof(struct hmac_clrkey_token) + bs; tmpkey = kzalloc(tmpkeylen, GFP_KERNEL); if (!tmpkey) { rc = -ENOMEM; goto out; } rc = make_clrkey_token(key, keylen, ds, tmpkey); if (rc) goto out; keylen = tmpkeylen; key = tmpkey; } /* copy raw key into tfm context */ rc = phmac_tfm_ctx_setkey(tfm_ctx, key, keylen); if (rc) goto out; /* convert raw key into protected key */ rc = phmac_convert_key(tfm_ctx); if (rc) goto out; /* set function code in tfm context, check for valid pk type */ switch (ds) { case SHA224_DIGEST_SIZE: if (tfm_ctx->pk.type != PKEY_KEYTYPE_HMAC_512) rc = -EINVAL; else tfm_ctx->fc = CPACF_KMAC_PHMAC_SHA_224; break; case SHA256_DIGEST_SIZE: if (tfm_ctx->pk.type != PKEY_KEYTYPE_HMAC_512) rc = -EINVAL; else tfm_ctx->fc = CPACF_KMAC_PHMAC_SHA_256; break; case SHA384_DIGEST_SIZE: if (tfm_ctx->pk.type != PKEY_KEYTYPE_HMAC_1024) rc = -EINVAL; else tfm_ctx->fc = CPACF_KMAC_PHMAC_SHA_384; break; case SHA512_DIGEST_SIZE: if (tfm_ctx->pk.type != PKEY_KEYTYPE_HMAC_1024) rc = -EINVAL; else tfm_ctx->fc = CPACF_KMAC_PHMAC_SHA_512; break; default: tfm_ctx->fc = 0; rc = -EINVAL; } out: kfree(tmpkey); pr_debug("rc=%d\n", rc); return rc; } static int phmac_export(struct ahash_request *req, void *out) { struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *ctx = &req_ctx->kmac_ctx; memcpy(out, ctx, sizeof(*ctx)); return 0; } static int phmac_import(struct ahash_request *req, const void *in) { struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *ctx = &req_ctx->kmac_ctx; memset(req_ctx, 0, sizeof(*req_ctx)); memcpy(ctx, in, sizeof(*ctx)); return 0; } static int phmac_init_tfm(struct crypto_ahash *tfm) { struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); memset(tfm_ctx, 0, sizeof(*tfm_ctx)); spin_lock_init(&tfm_ctx->pk_lock); crypto_ahash_set_reqsize(tfm, sizeof(struct phmac_req_ctx)); return 0; } static void phmac_exit_tfm(struct crypto_ahash *tfm) { struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); memzero_explicit(tfm_ctx->keybuf, sizeof(tfm_ctx->keybuf)); memzero_explicit(&tfm_ctx->pk, sizeof(tfm_ctx->pk)); } static int phmac_do_one_request(struct crypto_engine *engine, void *areq) { struct ahash_request *req = ahash_request_cast(areq); struct crypto_ahash *tfm = crypto_ahash_reqtfm(req); struct phmac_tfm_ctx *tfm_ctx = crypto_ahash_ctx(tfm); struct phmac_req_ctx *req_ctx = ahash_request_ctx(req); struct kmac_sha2_ctx *kmac_ctx = &req_ctx->kmac_ctx; struct hash_walk_helper *hwh = &req_ctx->hwh; int rc = -EINVAL; /* * Three kinds of requests come in here: * update when req->nbytes > 0 and req_ctx->final is false * final when req->nbytes = 0 and req_ctx->final is true * finup when req->nbytes > 0 and req_ctx->final is true * For update and finup the hwh walk needs to be prepared and * up to date but the actual nr of bytes in req->nbytes may be * any non zero number. For final there is no hwh walk needed. */ if (req->nbytes) { rc = phmac_kmac_update(req, true); if (rc == -EKEYEXPIRED) { /* * Protected key expired, conversion is in process. * Trigger a re-schedule of this request by returning * -ENOSPC ("hardware queue full") to the crypto engine. * To avoid immediately re-invocation of this callback, * tell scheduler to voluntarily give up the CPU here. */ pr_debug("rescheduling request\n"); cond_resched(); return -ENOSPC; } else if (rc) { hwh_advance(hwh, rc); goto out; } req->nbytes = 0; } if (req_ctx->final) { rc = phmac_kmac_final(req, true); if (rc == -EKEYEXPIRED) { /* * Protected key expired, conversion is in process. * Trigger a re-schedule of this request by returning * -ENOSPC ("hardware queue full") to the crypto engine. * To avoid immediately re-invocation of this callback, * tell scheduler to voluntarily give up the CPU here. */ pr_debug("rescheduling request\n"); cond_resched(); return -ENOSPC; } } out: if (rc || req_ctx->final) memzero_explicit(kmac_ctx, sizeof(*kmac_ctx)); pr_debug("request complete with rc=%d\n", rc); local_bh_disable(); atomic_dec(&tfm_ctx->via_engine_ctr); crypto_finalize_hash_request(engine, req, rc); local_bh_enable(); return rc; } #define S390_ASYNC_PHMAC_ALG(x) \ { \ .base = { \ .init = phmac_init, \ .update = phmac_update, \ .final = phmac_final, \ .finup = phmac_finup, \ .digest = phmac_digest, \ .setkey = phmac_setkey, \ .import = phmac_import, \ .export = phmac_export, \ .init_tfm = phmac_init_tfm, \ .exit_tfm = phmac_exit_tfm, \ .halg = { \ .digestsize = SHA##x##_DIGEST_SIZE, \ .statesize = sizeof(struct kmac_sha2_ctx), \ .base = { \ .cra_name = "phmac(sha" #x ")", \ .cra_driver_name = "phmac_s390_sha" #x, \ .cra_blocksize = SHA##x##_BLOCK_SIZE, \ .cra_priority = 400, \ .cra_flags = CRYPTO_ALG_ASYNC | \ CRYPTO_ALG_NO_FALLBACK, \ .cra_ctxsize = sizeof(struct phmac_tfm_ctx), \ .cra_module = THIS_MODULE, \ }, \ }, \ }, \ .op = { \ .do_one_request = phmac_do_one_request, \ }, \ } static struct phmac_alg { unsigned int fc; struct ahash_engine_alg alg; bool registered; } phmac_algs[] = { { .fc = CPACF_KMAC_PHMAC_SHA_224, .alg = S390_ASYNC_PHMAC_ALG(224), }, { .fc = CPACF_KMAC_PHMAC_SHA_256, .alg = S390_ASYNC_PHMAC_ALG(256), }, { .fc = CPACF_KMAC_PHMAC_SHA_384, .alg = S390_ASYNC_PHMAC_ALG(384), }, { .fc = CPACF_KMAC_PHMAC_SHA_512, .alg = S390_ASYNC_PHMAC_ALG(512), } }; static struct miscdevice phmac_dev = { .name = "phmac", .minor = MISC_DYNAMIC_MINOR, }; static void s390_phmac_exit(void) { struct phmac_alg *phmac; int i; if (phmac_crypto_engine) { crypto_engine_stop(phmac_crypto_engine); crypto_engine_exit(phmac_crypto_engine); } for (i = ARRAY_SIZE(phmac_algs) - 1; i >= 0; i--) { phmac = &phmac_algs[i]; if (phmac->registered) crypto_engine_unregister_ahash(&phmac->alg); } misc_deregister(&phmac_dev); } static int __init s390_phmac_init(void) { struct phmac_alg *phmac; int i, rc; /* for selftest cpacf klmd subfunction is needed */ if (!cpacf_query_func(CPACF_KLMD, CPACF_KLMD_SHA_256)) return -ENODEV; if (!cpacf_query_func(CPACF_KLMD, CPACF_KLMD_SHA_512)) return -ENODEV; /* register a simple phmac pseudo misc device */ rc = misc_register(&phmac_dev); if (rc) return rc; /* with this pseudo device alloc and start a crypto engine */ phmac_crypto_engine = crypto_engine_alloc_init_and_set(phmac_dev.this_device, true, false, MAX_QLEN); if (!phmac_crypto_engine) { rc = -ENOMEM; goto out_err; } rc = crypto_engine_start(phmac_crypto_engine); if (rc) { crypto_engine_exit(phmac_crypto_engine); phmac_crypto_engine = NULL; goto out_err; } for (i = 0; i < ARRAY_SIZE(phmac_algs); i++) { phmac = &phmac_algs[i]; if (!cpacf_query_func(CPACF_KMAC, phmac->fc)) continue; rc = crypto_engine_register_ahash(&phmac->alg); if (rc) goto out_err; phmac->registered = true; pr_debug("%s registered\n", phmac->alg.base.halg.base.cra_name); } return 0; out_err: s390_phmac_exit(); return rc; } module_init(s390_phmac_init); module_exit(s390_phmac_exit); MODULE_ALIAS_CRYPTO("phmac(sha224)"); MODULE_ALIAS_CRYPTO("phmac(sha256)"); MODULE_ALIAS_CRYPTO("phmac(sha384)"); MODULE_ALIAS_CRYPTO("phmac(sha512)"); MODULE_DESCRIPTION("S390 HMAC driver for protected keys"); MODULE_LICENSE("GPL");
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