cryptodev.c revision 1.34.6.4
1 1.34.6.3 mjf /* $NetBSD: cryptodev.c,v 1.34.6.4 2009/01/17 13:29:34 mjf Exp $ */ 2 1.4 jonathan /* $FreeBSD: src/sys/opencrypto/cryptodev.c,v 1.4.2.4 2003/06/03 00:09:02 sam Exp $ */ 3 1.1 jonathan /* $OpenBSD: cryptodev.c,v 1.53 2002/07/10 22:21:30 mickey Exp $ */ 4 1.1 jonathan 5 1.34.6.3 mjf /*- 6 1.34.6.3 mjf * Copyright (c) 2008 The NetBSD Foundation, Inc. 7 1.34.6.3 mjf * All rights reserved. 8 1.34.6.3 mjf * 9 1.34.6.3 mjf * This code is derived from software contributed to The NetBSD Foundation 10 1.34.6.3 mjf * by Coyote Point Systems, Inc. 11 1.34.6.3 mjf * 12 1.34.6.3 mjf * Redistribution and use in source and binary forms, with or without 13 1.34.6.3 mjf * modification, are permitted provided that the following conditions 14 1.34.6.3 mjf * are met: 15 1.34.6.3 mjf * 1. Redistributions of source code must retain the above copyright 16 1.34.6.3 mjf * notice, this list of conditions and the following disclaimer. 17 1.34.6.3 mjf * 2. Redistributions in binary form must reproduce the above copyright 18 1.34.6.3 mjf * notice, this list of conditions and the following disclaimer in the 19 1.34.6.3 mjf * documentation and/or other materials provided with the distribution. 20 1.34.6.3 mjf * 21 1.34.6.3 mjf * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 22 1.34.6.3 mjf * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 23 1.34.6.3 mjf * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 24 1.34.6.3 mjf * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 25 1.34.6.3 mjf * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 26 1.34.6.3 mjf * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 27 1.34.6.3 mjf * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 28 1.34.6.3 mjf * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 29 1.34.6.3 mjf * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 30 1.34.6.3 mjf * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 31 1.34.6.3 mjf * POSSIBILITY OF SUCH DAMAGE. 32 1.34.6.3 mjf */ 33 1.34.6.3 mjf 34 1.1 jonathan /* 35 1.1 jonathan * Copyright (c) 2001 Theo de Raadt 36 1.1 jonathan * 37 1.1 jonathan * Redistribution and use in source and binary forms, with or without 38 1.1 jonathan * modification, are permitted provided that the following conditions 39 1.1 jonathan * are met: 40 1.1 jonathan * 41 1.1 jonathan * 1. Redistributions of source code must retain the above copyright 42 1.1 jonathan * notice, this list of conditions and the following disclaimer. 43 1.1 jonathan * 2. Redistributions in binary form must reproduce the above copyright 44 1.1 jonathan * notice, this list of conditions and the following disclaimer in the 45 1.1 jonathan * documentation and/or other materials provided with the distribution. 46 1.1 jonathan * 3. The name of the author may not be used to endorse or promote products 47 1.1 jonathan * derived from this software without specific prior written permission. 48 1.1 jonathan * 49 1.1 jonathan * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 50 1.1 jonathan * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 51 1.1 jonathan * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 52 1.1 jonathan * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 53 1.1 jonathan * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 54 1.1 jonathan * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 55 1.1 jonathan * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 56 1.1 jonathan * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 57 1.1 jonathan * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 58 1.1 jonathan * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 59 1.1 jonathan * 60 1.1 jonathan * Effort sponsored in part by the Defense Advanced Research Projects 61 1.1 jonathan * Agency (DARPA) and Air Force Research Laboratory, Air Force 62 1.1 jonathan * Materiel Command, USAF, under agreement number F30602-01-2-0537. 63 1.1 jonathan * 64 1.1 jonathan */ 65 1.1 jonathan 66 1.1 jonathan #include <sys/cdefs.h> 67 1.34.6.3 mjf __KERNEL_RCSID(0, "$NetBSD: cryptodev.c,v 1.34.6.4 2009/01/17 13:29:34 mjf Exp $"); 68 1.1 jonathan 69 1.1 jonathan #include <sys/param.h> 70 1.1 jonathan #include <sys/systm.h> 71 1.34.6.3 mjf #include <sys/kmem.h> 72 1.1 jonathan #include <sys/malloc.h> 73 1.1 jonathan #include <sys/mbuf.h> 74 1.29 tls #include <sys/pool.h> 75 1.1 jonathan #include <sys/sysctl.h> 76 1.1 jonathan #include <sys/file.h> 77 1.1 jonathan #include <sys/filedesc.h> 78 1.1 jonathan #include <sys/errno.h> 79 1.2 jonathan #include <sys/md5.h> 80 1.1 jonathan #include <sys/sha1.h> 81 1.1 jonathan #include <sys/conf.h> 82 1.1 jonathan #include <sys/device.h> 83 1.21 elad #include <sys/kauth.h> 84 1.34.6.3 mjf #include <sys/select.h> 85 1.34.6.3 mjf #include <sys/poll.h> 86 1.34.6.3 mjf #include <sys/atomic.h> 87 1.1 jonathan 88 1.33 tls #include "opt_ocf.h" 89 1.1 jonathan #include <opencrypto/cryptodev.h> 90 1.1 jonathan #include <opencrypto/xform.h> 91 1.1 jonathan 92 1.1 jonathan struct csession { 93 1.1 jonathan TAILQ_ENTRY(csession) next; 94 1.1 jonathan u_int64_t sid; 95 1.1 jonathan u_int32_t ses; 96 1.1 jonathan 97 1.1 jonathan u_int32_t cipher; 98 1.1 jonathan struct enc_xform *txform; 99 1.1 jonathan u_int32_t mac; 100 1.1 jonathan struct auth_hash *thash; 101 1.1 jonathan 102 1.26 christos void * key; 103 1.1 jonathan int keylen; 104 1.1 jonathan u_char tmp_iv[EALG_MAX_BLOCK_LEN]; 105 1.1 jonathan 106 1.26 christos void * mackey; 107 1.1 jonathan int mackeylen; 108 1.1 jonathan u_char tmp_mac[CRYPTO_MAX_MAC_LEN]; 109 1.1 jonathan 110 1.29 tls struct iovec iovec[1]; /* user requests never have more */ 111 1.1 jonathan struct uio uio; 112 1.1 jonathan int error; 113 1.1 jonathan }; 114 1.1 jonathan 115 1.1 jonathan struct fcrypt { 116 1.1 jonathan TAILQ_HEAD(csessionlist, csession) csessions; 117 1.34.6.3 mjf TAILQ_HEAD(crprethead, cryptop) crp_ret_mq; 118 1.34.6.3 mjf TAILQ_HEAD(krprethead, cryptkop) crp_ret_mkq; 119 1.1 jonathan int sesn; 120 1.34.6.3 mjf struct selinfo sinfo; 121 1.34.6.3 mjf u_int32_t requestid; 122 1.1 jonathan }; 123 1.1 jonathan 124 1.29 tls /* For our fixed-size allocations */ 125 1.34.6.3 mjf static struct pool fcrpl; 126 1.34.6.3 mjf static struct pool csepl; 127 1.1 jonathan 128 1.1 jonathan /* Declaration of master device (fd-cloning/ctxt-allocating) entrypoints */ 129 1.16 christos static int cryptoopen(dev_t dev, int flag, int mode, struct lwp *l); 130 1.1 jonathan static int cryptoread(dev_t dev, struct uio *uio, int ioflag); 131 1.1 jonathan static int cryptowrite(dev_t dev, struct uio *uio, int ioflag); 132 1.16 christos static int cryptoselect(dev_t dev, int rw, struct lwp *l); 133 1.1 jonathan 134 1.1 jonathan /* Declaration of cloned-device (per-ctxt) entrypoints */ 135 1.34.6.3 mjf static int cryptof_read(struct file *, off_t *, struct uio *, 136 1.34.6.3 mjf kauth_cred_t, int); 137 1.34.6.3 mjf static int cryptof_write(struct file *, off_t *, struct uio *, 138 1.34.6.3 mjf kauth_cred_t, int); 139 1.34.6.3 mjf static int cryptof_ioctl(struct file *, u_long, void *); 140 1.34.6.3 mjf static int cryptof_close(struct file *); 141 1.34.6.3 mjf static int cryptof_poll(struct file *, int); 142 1.1 jonathan 143 1.12 christos static const struct fileops cryptofops = { 144 1.34.6.3 mjf cryptof_read, 145 1.34.6.3 mjf cryptof_write, 146 1.34.6.3 mjf cryptof_ioctl, 147 1.34.6.3 mjf fnullop_fcntl, 148 1.34.6.3 mjf cryptof_poll, 149 1.34.6.3 mjf fbadop_stat, 150 1.34.6.3 mjf cryptof_close, 151 1.34.6.3 mjf fnullop_kqfilter 152 1.1 jonathan }; 153 1.1 jonathan 154 1.1 jonathan static struct csession *csefind(struct fcrypt *, u_int); 155 1.1 jonathan static int csedelete(struct fcrypt *, struct csession *); 156 1.1 jonathan static struct csession *cseadd(struct fcrypt *, struct csession *); 157 1.34.6.3 mjf static struct csession *csecreate(struct fcrypt *, u_int64_t, void *, 158 1.34.6.3 mjf u_int64_t, void *, u_int64_t, u_int32_t, u_int32_t, struct enc_xform *, 159 1.1 jonathan struct auth_hash *); 160 1.1 jonathan static int csefree(struct csession *); 161 1.1 jonathan 162 1.34.6.3 mjf static int cryptodev_op(struct csession *, struct crypt_op *, 163 1.34.6.3 mjf struct lwp *); 164 1.34.6.3 mjf static int cryptodev_mop(struct fcrypt *, struct crypt_n_op *, int, 165 1.34.6.3 mjf struct lwp *); 166 1.1 jonathan static int cryptodev_key(struct crypt_kop *); 167 1.34.6.3 mjf static int cryptodev_mkey(struct fcrypt *, struct crypt_n_kop *, int); 168 1.34.6.3 mjf static int cryptodev_session(struct fcrypt *, struct session_op *); 169 1.34.6.3 mjf static int cryptodev_msession(struct fcrypt *, struct session_n_op *, int); 170 1.34.6.3 mjf static int cryptodev_msessionfin(struct fcrypt *, int, u_int32_t *); 171 1.1 jonathan 172 1.1 jonathan static int cryptodev_cb(void *); 173 1.1 jonathan static int cryptodevkey_cb(void *); 174 1.1 jonathan 175 1.34.6.3 mjf static int cryptodev_mcb(void *); 176 1.34.6.3 mjf static int cryptodevkey_mcb(void *); 177 1.34.6.3 mjf 178 1.34.6.3 mjf static int cryptodev_getmstatus(struct fcrypt *, struct crypt_result *, 179 1.34.6.3 mjf int); 180 1.34.6.3 mjf static int cryptodev_getstatus(struct fcrypt *, struct crypt_result *); 181 1.34.6.3 mjf 182 1.9 jonathan /* 183 1.9 jonathan * sysctl-able control variables for /dev/crypto now defined in crypto.c: 184 1.9 jonathan * crypto_usercrypto, crypto_userasmcrypto, crypto_devallowsoft. 185 1.9 jonathan */ 186 1.1 jonathan 187 1.1 jonathan /* ARGSUSED */ 188 1.1 jonathan int 189 1.34.6.1 mjf cryptof_read(file_t *fp, off_t *poff, 190 1.25 christos struct uio *uio, kauth_cred_t cred, int flags) 191 1.1 jonathan { 192 1.34.6.3 mjf return EIO; 193 1.1 jonathan } 194 1.1 jonathan 195 1.1 jonathan /* ARGSUSED */ 196 1.1 jonathan int 197 1.34.6.1 mjf cryptof_write(file_t *fp, off_t *poff, 198 1.25 christos struct uio *uio, kauth_cred_t cred, int flags) 199 1.1 jonathan { 200 1.34.6.3 mjf return EIO; 201 1.1 jonathan } 202 1.1 jonathan 203 1.1 jonathan /* ARGSUSED */ 204 1.1 jonathan int 205 1.34.6.3 mjf cryptof_ioctl(struct file *fp, u_long cmd, void *data) 206 1.1 jonathan { 207 1.34.6.1 mjf struct fcrypt *fcr = fp->f_data; 208 1.1 jonathan struct csession *cse; 209 1.1 jonathan struct session_op *sop; 210 1.34.6.3 mjf struct session_n_op *snop; 211 1.1 jonathan struct crypt_op *cop; 212 1.34.6.3 mjf struct crypt_mop *mop; 213 1.34.6.3 mjf struct crypt_mkop *mkop; 214 1.34.6.3 mjf struct crypt_n_op *cnop; 215 1.34.6.3 mjf struct crypt_n_kop *knop; 216 1.34.6.3 mjf struct crypt_sgop *sgop; 217 1.34.6.3 mjf struct crypt_sfop *sfop; 218 1.34.6.3 mjf struct cryptret *crypt_ret; 219 1.34.6.3 mjf struct crypt_result *crypt_res; 220 1.1 jonathan u_int32_t ses; 221 1.34.6.3 mjf u_int32_t *sesid; 222 1.1 jonathan int error = 0; 223 1.34.6.3 mjf size_t count; 224 1.1 jonathan 225 1.29 tls /* backwards compatibility */ 226 1.34.6.1 mjf file_t *criofp; 227 1.29 tls struct fcrypt *criofcr; 228 1.29 tls int criofd; 229 1.29 tls 230 1.34.6.3 mjf switch (cmd) { 231 1.29 tls case CRIOGET: /* XXX deprecated, remove after 5.0 */ 232 1.34.6.3 mjf if ((error = fd_allocfile(&criofp, &criofd)) != 0) 233 1.34.6.3 mjf return error; 234 1.34.6.3 mjf criofcr = pool_get(&fcrpl, PR_WAITOK); 235 1.33 tls mutex_spin_enter(&crypto_mtx); 236 1.34.6.3 mjf TAILQ_INIT(&criofcr->csessions); 237 1.34.6.3 mjf TAILQ_INIT(&criofcr->crp_ret_mq); 238 1.34.6.3 mjf TAILQ_INIT(&criofcr->crp_ret_mkq); 239 1.34.6.3 mjf selinit(&criofcr->sinfo); 240 1.34.6.3 mjf 241 1.29 tls /* 242 1.29 tls * Don't ever return session 0, to allow detection of 243 1.29 tls * failed creation attempts with multi-create ioctl. 244 1.29 tls */ 245 1.34.6.3 mjf criofcr->sesn = 1; 246 1.34.6.3 mjf criofcr->requestid = 1; 247 1.33 tls mutex_spin_exit(&crypto_mtx); 248 1.34.6.3 mjf (void)fd_clone(criofp, criofd, (FREAD|FWRITE), 249 1.29 tls &cryptofops, criofcr); 250 1.34.6.3 mjf *(u_int32_t *)data = criofd; 251 1.29 tls return error; 252 1.34.6.3 mjf break; 253 1.1 jonathan case CIOCGSESSION: 254 1.1 jonathan sop = (struct session_op *)data; 255 1.34.6.3 mjf error = cryptodev_session(fcr, sop); 256 1.34.6.3 mjf break; 257 1.34.6.3 mjf case CIOCNGSESSION: 258 1.34.6.3 mjf sgop = (struct crypt_sgop *)data; 259 1.34.6.3 mjf snop = kmem_alloc((sgop->count * 260 1.34.6.3 mjf sizeof(struct session_n_op)), KM_SLEEP); 261 1.34.6.3 mjf error = copyin(sgop->sessions, snop, sgop->count * 262 1.34.6.3 mjf sizeof(struct session_n_op)); 263 1.34.6.3 mjf if (error) { 264 1.34.6.3 mjf goto mbail; 265 1.1 jonathan } 266 1.1 jonathan 267 1.34.6.3 mjf error = cryptodev_msession(fcr, snop, sgop->count); 268 1.1 jonathan if (error) { 269 1.34.6.3 mjf goto mbail; 270 1.1 jonathan } 271 1.34.6.3 mjf 272 1.34.6.3 mjf error = copyout(snop, sgop->sessions, sgop->count * 273 1.34.6.3 mjf sizeof(struct session_n_op)); 274 1.34.6.3 mjf mbail: 275 1.34.6.3 mjf kmem_free(snop, sgop->count * sizeof(struct session_n_op)); 276 1.1 jonathan break; 277 1.1 jonathan case CIOCFSESSION: 278 1.33 tls mutex_spin_enter(&crypto_mtx); 279 1.1 jonathan ses = *(u_int32_t *)data; 280 1.1 jonathan cse = csefind(fcr, ses); 281 1.1 jonathan if (cse == NULL) 282 1.34.6.3 mjf return EINVAL; 283 1.1 jonathan csedelete(fcr, cse); 284 1.1 jonathan error = csefree(cse); 285 1.33 tls mutex_spin_exit(&crypto_mtx); 286 1.1 jonathan break; 287 1.34.6.3 mjf case CIOCNFSESSION: 288 1.34.6.3 mjf sfop = (struct crypt_sfop *)data; 289 1.34.6.3 mjf sesid = kmem_alloc((sfop->count * sizeof(u_int32_t)), 290 1.34.6.3 mjf KM_SLEEP); 291 1.34.6.3 mjf error = copyin(sfop->sesid, sesid, 292 1.34.6.3 mjf (sfop->count * sizeof(u_int32_t))); 293 1.34.6.3 mjf if (!error) { 294 1.34.6.3 mjf error = cryptodev_msessionfin(fcr, sfop->count, sesid); 295 1.34.6.3 mjf } 296 1.34.6.3 mjf kmem_free(sesid, (sfop->count * sizeof(u_int32_t))); 297 1.34.6.3 mjf break; 298 1.1 jonathan case CIOCCRYPT: 299 1.33 tls mutex_spin_enter(&crypto_mtx); 300 1.1 jonathan cop = (struct crypt_op *)data; 301 1.1 jonathan cse = csefind(fcr, cop->ses); 302 1.33 tls mutex_spin_exit(&crypto_mtx); 303 1.18 christos if (cse == NULL) { 304 1.18 christos DPRINTF(("csefind failed\n")); 305 1.34.6.3 mjf return EINVAL; 306 1.18 christos } 307 1.34.6.1 mjf error = cryptodev_op(cse, cop, curlwp); 308 1.34 tls DPRINTF(("cryptodev_op error = %d\n", error)); 309 1.1 jonathan break; 310 1.34.6.3 mjf case CIOCNCRYPTM: 311 1.34.6.3 mjf mop = (struct crypt_mop *)data; 312 1.34.6.3 mjf cnop = kmem_alloc((mop->count * sizeof(struct crypt_n_op)), 313 1.34.6.3 mjf KM_SLEEP); 314 1.34.6.3 mjf error = copyin(mop->reqs, cnop, 315 1.34.6.3 mjf (mop->count * sizeof(struct crypt_n_op))); 316 1.34.6.3 mjf if(!error) { 317 1.34.6.3 mjf error = cryptodev_mop(fcr, cnop, mop->count, curlwp); 318 1.34.6.3 mjf if (!error) { 319 1.34.6.3 mjf error = copyout(cnop, mop->reqs, 320 1.34.6.3 mjf (mop->count * sizeof(struct crypt_n_op))); 321 1.34.6.3 mjf } 322 1.34.6.3 mjf } 323 1.34.6.3 mjf kmem_free(cnop, (mop->count * sizeof(struct crypt_n_op))); 324 1.34.6.3 mjf break; 325 1.1 jonathan case CIOCKEY: 326 1.1 jonathan error = cryptodev_key((struct crypt_kop *)data); 327 1.34 tls DPRINTF(("cryptodev_key error = %d\n", error)); 328 1.1 jonathan break; 329 1.34.6.3 mjf case CIOCNFKEYM: 330 1.34.6.3 mjf mkop = (struct crypt_mkop *)data; 331 1.34.6.3 mjf knop = kmem_alloc((mkop->count * sizeof(struct crypt_n_kop)), 332 1.34.6.3 mjf KM_SLEEP); 333 1.34.6.3 mjf error = copyin(mkop->reqs, knop, 334 1.34.6.3 mjf (mkop->count * sizeof(struct crypt_n_kop))); 335 1.34.6.3 mjf if (!error) { 336 1.34.6.3 mjf error = cryptodev_mkey(fcr, knop, mkop->count); 337 1.34.6.3 mjf if (!error) 338 1.34.6.3 mjf error = copyout(knop, mkop->reqs, 339 1.34.6.3 mjf (mkop->count * sizeof(struct crypt_n_kop))); 340 1.34.6.3 mjf } 341 1.34.6.3 mjf kmem_free(knop, (mkop->count * sizeof(struct crypt_n_kop))); 342 1.34.6.3 mjf break; 343 1.1 jonathan case CIOCASYMFEAT: 344 1.1 jonathan error = crypto_getfeat((int *)data); 345 1.1 jonathan break; 346 1.34.6.3 mjf case CIOCNCRYPTRETM: 347 1.34.6.3 mjf crypt_ret = (struct cryptret *)data; 348 1.34.6.3 mjf count = crypt_ret->count; 349 1.34.6.3 mjf crypt_res = kmem_alloc((count * sizeof(struct crypt_result)), 350 1.34.6.3 mjf KM_SLEEP); 351 1.34.6.3 mjf error = copyin(crypt_ret->results, crypt_res, 352 1.34.6.3 mjf (count * sizeof(struct crypt_result))); 353 1.34.6.3 mjf if (error) 354 1.34.6.3 mjf goto reterr; 355 1.34.6.3 mjf crypt_ret->count = cryptodev_getmstatus(fcr, crypt_res, 356 1.34.6.3 mjf crypt_ret->count); 357 1.34.6.3 mjf /* sanity check count */ 358 1.34.6.3 mjf if (crypt_ret->count > count) { 359 1.34.6.3 mjf printf("%s.%d: error returned count %zd > original " 360 1.34.6.3 mjf " count %zd\n", 361 1.34.6.3 mjf __FILE__, __LINE__, crypt_ret->count, count); 362 1.34.6.3 mjf crypt_ret->count = count; 363 1.34.6.3 mjf 364 1.34.6.3 mjf } 365 1.34.6.3 mjf error = copyout(crypt_res, crypt_ret->results, 366 1.34.6.3 mjf (crypt_ret->count * sizeof(struct crypt_result))); 367 1.34.6.3 mjf reterr: 368 1.34.6.3 mjf kmem_free(crypt_res, (count * sizeof(struct crypt_result))); 369 1.34.6.3 mjf break; 370 1.34.6.3 mjf case CIOCNCRYPTRET: 371 1.34.6.3 mjf error = cryptodev_getstatus(fcr, (struct crypt_result *)data); 372 1.34.6.3 mjf break; 373 1.1 jonathan default: 374 1.18 christos DPRINTF(("invalid ioctl cmd %ld\n", cmd)); 375 1.1 jonathan error = EINVAL; 376 1.1 jonathan } 377 1.34.6.3 mjf return error; 378 1.1 jonathan } 379 1.1 jonathan 380 1.1 jonathan static int 381 1.25 christos cryptodev_op(struct csession *cse, struct crypt_op *cop, struct lwp *l) 382 1.1 jonathan { 383 1.1 jonathan struct cryptop *crp = NULL; 384 1.1 jonathan struct cryptodesc *crde = NULL, *crda = NULL; 385 1.33 tls int error; 386 1.1 jonathan 387 1.1 jonathan if (cop->len > 256*1024-4) 388 1.34.6.3 mjf return E2BIG; 389 1.1 jonathan 390 1.13 jonathan if (cse->txform) { 391 1.13 jonathan if (cop->len == 0 || (cop->len % cse->txform->blocksize) != 0) 392 1.34.6.3 mjf return EINVAL; 393 1.13 jonathan } 394 1.1 jonathan 395 1.34.6.3 mjf (void)memset(&cse->uio, 0, sizeof(cse->uio)); 396 1.1 jonathan cse->uio.uio_iovcnt = 1; 397 1.1 jonathan cse->uio.uio_resid = 0; 398 1.1 jonathan cse->uio.uio_rw = UIO_WRITE; 399 1.1 jonathan cse->uio.uio_iov = cse->iovec; 400 1.17 yamt UIO_SETUP_SYSSPACE(&cse->uio); 401 1.29 tls memset(&cse->iovec, 0, sizeof(cse->iovec)); 402 1.1 jonathan cse->uio.uio_iov[0].iov_len = cop->len; 403 1.34.6.3 mjf cse->uio.uio_iov[0].iov_base = kmem_alloc(cop->len, KM_SLEEP); 404 1.29 tls cse->uio.uio_resid = cse->uio.uio_iov[0].iov_len; 405 1.1 jonathan 406 1.1 jonathan crp = crypto_getreq((cse->txform != NULL) + (cse->thash != NULL)); 407 1.1 jonathan if (crp == NULL) { 408 1.1 jonathan error = ENOMEM; 409 1.1 jonathan goto bail; 410 1.1 jonathan } 411 1.1 jonathan 412 1.1 jonathan if (cse->thash) { 413 1.1 jonathan crda = crp->crp_desc; 414 1.34.6.3 mjf if (cse->txform && crda) 415 1.1 jonathan crde = crda->crd_next; 416 1.1 jonathan } else { 417 1.1 jonathan if (cse->txform) 418 1.1 jonathan crde = crp->crp_desc; 419 1.1 jonathan else { 420 1.1 jonathan error = EINVAL; 421 1.1 jonathan goto bail; 422 1.1 jonathan } 423 1.1 jonathan } 424 1.1 jonathan 425 1.1 jonathan if ((error = copyin(cop->src, cse->uio.uio_iov[0].iov_base, cop->len))) 426 1.34.6.3 mjf { 427 1.34.6.3 mjf printf("copyin failed %s %d \n", (char *)cop->src, error); 428 1.1 jonathan goto bail; 429 1.34.6.3 mjf } 430 1.1 jonathan 431 1.1 jonathan if (crda) { 432 1.1 jonathan crda->crd_skip = 0; 433 1.1 jonathan crda->crd_len = cop->len; 434 1.1 jonathan crda->crd_inject = 0; /* ??? */ 435 1.1 jonathan 436 1.1 jonathan crda->crd_alg = cse->mac; 437 1.1 jonathan crda->crd_key = cse->mackey; 438 1.1 jonathan crda->crd_klen = cse->mackeylen * 8; 439 1.1 jonathan } 440 1.1 jonathan 441 1.1 jonathan if (crde) { 442 1.1 jonathan if (cop->op == COP_ENCRYPT) 443 1.1 jonathan crde->crd_flags |= CRD_F_ENCRYPT; 444 1.1 jonathan else 445 1.1 jonathan crde->crd_flags &= ~CRD_F_ENCRYPT; 446 1.1 jonathan crde->crd_len = cop->len; 447 1.1 jonathan crde->crd_inject = 0; 448 1.1 jonathan 449 1.1 jonathan crde->crd_alg = cse->cipher; 450 1.1 jonathan crde->crd_key = cse->key; 451 1.1 jonathan crde->crd_klen = cse->keylen * 8; 452 1.1 jonathan } 453 1.1 jonathan 454 1.1 jonathan crp->crp_ilen = cop->len; 455 1.34.6.4 mjf /* The reqest is flagged as CRYPTO_F_USER as long as it is running 456 1.34.6.4 mjf * in the user IOCTL thread. This flag lets us skip using the retq for 457 1.34.6.4 mjf * the request if it completes immediately. If the request ends up being 458 1.34.6.4 mjf * delayed or is not completed immediately the flag is removed. 459 1.34.6.4 mjf */ 460 1.34.6.4 mjf crp->crp_flags = CRYPTO_F_IOV | (cop->flags & COP_F_BATCH) | CRYPTO_F_USER; 461 1.26 christos crp->crp_buf = (void *)&cse->uio; 462 1.1 jonathan crp->crp_callback = (int (*) (struct cryptop *)) cryptodev_cb; 463 1.1 jonathan crp->crp_sid = cse->sid; 464 1.1 jonathan crp->crp_opaque = (void *)cse; 465 1.1 jonathan 466 1.1 jonathan if (cop->iv) { 467 1.1 jonathan if (crde == NULL) { 468 1.1 jonathan error = EINVAL; 469 1.1 jonathan goto bail; 470 1.1 jonathan } 471 1.1 jonathan if (cse->cipher == CRYPTO_ARC4) { /* XXX use flag? */ 472 1.1 jonathan error = EINVAL; 473 1.1 jonathan goto bail; 474 1.1 jonathan } 475 1.34.6.3 mjf if ((error = copyin(cop->iv, cse->tmp_iv, 476 1.34.6.3 mjf cse->txform->blocksize))) 477 1.1 jonathan goto bail; 478 1.34.6.3 mjf (void)memcpy(crde->crd_iv, cse->tmp_iv, cse->txform->blocksize); 479 1.1 jonathan crde->crd_flags |= CRD_F_IV_EXPLICIT | CRD_F_IV_PRESENT; 480 1.1 jonathan crde->crd_skip = 0; 481 1.1 jonathan } else if (crde) { 482 1.20 christos if (cse->cipher == CRYPTO_ARC4) { /* XXX use flag? */ 483 1.20 christos crde->crd_skip = 0; 484 1.20 christos } else { 485 1.20 christos crde->crd_flags |= CRD_F_IV_PRESENT; 486 1.20 christos crde->crd_skip = cse->txform->blocksize; 487 1.20 christos crde->crd_len -= cse->txform->blocksize; 488 1.20 christos } 489 1.1 jonathan } 490 1.1 jonathan 491 1.1 jonathan if (cop->mac) { 492 1.1 jonathan if (crda == NULL) { 493 1.1 jonathan error = EINVAL; 494 1.1 jonathan goto bail; 495 1.1 jonathan } 496 1.1 jonathan crp->crp_mac=cse->tmp_mac; 497 1.1 jonathan } 498 1.1 jonathan 499 1.33 tls /* 500 1.33 tls * XXX there was a comment here which said that we went to 501 1.33 tls * XXX splcrypto() but needed to only if CRYPTO_F_CBIMM, 502 1.33 tls * XXX disabled on NetBSD since 1.6O due to a race condition. 503 1.33 tls * XXX But crypto_dispatch went to splcrypto() itself! (And 504 1.33 tls * XXX now takes the crypto_mtx mutex itself). We do, however, 505 1.33 tls * XXX need to hold the mutex across the call to cv_wait(). 506 1.33 tls * XXX (should we arrange for crypto_dispatch to return to 507 1.33 tls * XXX us with it held? it seems quite ugly to do so.) 508 1.33 tls */ 509 1.34.6.3 mjf #ifdef notyet 510 1.34.6.3 mjf eagain: 511 1.34.6.3 mjf #endif 512 1.1 jonathan error = crypto_dispatch(crp); 513 1.33 tls mutex_spin_enter(&crypto_mtx); 514 1.34.6.3 mjf 515 1.34.6.4 mjf /* 516 1.34.6.4 mjf * If the request was going to be completed by the 517 1.34.6.4 mjf * ioctl thread then it would have been done by now. 518 1.34.6.4 mjf * Remove the F_USER flag it so crypto_done() is not confused 519 1.34.6.4 mjf * if the crypto device calls it after this point. 520 1.34.6.4 mjf */ 521 1.34.6.4 mjf crp->crp_flags &= ~(CRYPTO_F_USER); 522 1.34.6.4 mjf 523 1.34.6.3 mjf switch (error) { 524 1.34.6.3 mjf #ifdef notyet /* don't loop forever -- but EAGAIN not possible here yet */ 525 1.34.6.3 mjf case EAGAIN: 526 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 527 1.34.6.3 mjf goto eagain; 528 1.34.6.3 mjf break; 529 1.34.6.3 mjf #endif 530 1.34.6.3 mjf case 0: 531 1.34.6.3 mjf break; 532 1.34.6.3 mjf default: 533 1.33 tls DPRINTF(("cryptodev_op: not waiting, error.\n")); 534 1.33 tls mutex_spin_exit(&crypto_mtx); 535 1.1 jonathan goto bail; 536 1.1 jonathan } 537 1.34.6.4 mjf 538 1.33 tls while (!(crp->crp_flags & CRYPTO_F_DONE)) { 539 1.33 tls DPRINTF(("cryptodev_op: sleeping on cv %08x for crp %08x\n", \ 540 1.34.6.3 mjf (uint32_t)&crp->crp_cv, (uint32_t)crp)); 541 1.33 tls cv_wait(&crp->crp_cv, &crypto_mtx); /* XXX cv_wait_sig? */ 542 1.33 tls } 543 1.33 tls if (crp->crp_flags & CRYPTO_F_ONRETQ) { 544 1.34.6.4 mjf /* XXX this should never happen now with the CRYPTO_F_USER flag 545 1.34.6.4 mjf * changes. 546 1.34.6.4 mjf */ 547 1.33 tls DPRINTF(("cryptodev_op: DONE, not woken by cryptoret.\n")); 548 1.33 tls (void)crypto_ret_q_remove(crp); 549 1.33 tls } 550 1.33 tls mutex_spin_exit(&crypto_mtx); 551 1.1 jonathan 552 1.1 jonathan if (crp->crp_etype != 0) { 553 1.34 tls DPRINTF(("cryptodev_op: crp_etype %d\n", crp->crp_etype)); 554 1.1 jonathan error = crp->crp_etype; 555 1.1 jonathan goto bail; 556 1.1 jonathan } 557 1.1 jonathan 558 1.1 jonathan if (cse->error) { 559 1.34 tls DPRINTF(("cryptodev_op: cse->error %d\n", cse->error)); 560 1.1 jonathan error = cse->error; 561 1.1 jonathan goto bail; 562 1.1 jonathan } 563 1.1 jonathan 564 1.1 jonathan if (cop->dst && 565 1.34.6.3 mjf (error = copyout(cse->uio.uio_iov[0].iov_base, cop->dst, cop->len))) 566 1.34.6.3 mjf { 567 1.34 tls DPRINTF(("cryptodev_op: copyout error %d\n", error)); 568 1.1 jonathan goto bail; 569 1.34 tls } 570 1.1 jonathan 571 1.1 jonathan if (cop->mac && 572 1.34 tls (error = copyout(crp->crp_mac, cop->mac, cse->thash->authsize))) { 573 1.34 tls DPRINTF(("cryptodev_op: mac copyout error %d\n", error)); 574 1.1 jonathan goto bail; 575 1.34 tls } 576 1.1 jonathan 577 1.1 jonathan bail: 578 1.34.6.4 mjf if (crp) { 579 1.1 jonathan crypto_freereq(crp); 580 1.34.6.4 mjf } 581 1.1 jonathan if (cse->uio.uio_iov[0].iov_base) 582 1.34.6.3 mjf kmem_free(cse->uio.uio_iov[0].iov_base, 583 1.34.6.3 mjf cse->uio.uio_iov[0].iov_len); 584 1.1 jonathan 585 1.34.6.3 mjf return error; 586 1.1 jonathan } 587 1.1 jonathan 588 1.1 jonathan static int 589 1.1 jonathan cryptodev_cb(void *op) 590 1.1 jonathan { 591 1.1 jonathan struct cryptop *crp = (struct cryptop *) op; 592 1.1 jonathan struct csession *cse = (struct csession *)crp->crp_opaque; 593 1.33 tls int error = 0; 594 1.1 jonathan 595 1.33 tls mutex_spin_enter(&crypto_mtx); 596 1.1 jonathan cse->error = crp->crp_etype; 597 1.33 tls if (crp->crp_etype == EAGAIN) { 598 1.33 tls /* always drop mutex to call dispatch routine */ 599 1.33 tls mutex_spin_exit(&crypto_mtx); 600 1.33 tls error = crypto_dispatch(crp); 601 1.33 tls mutex_spin_enter(&crypto_mtx); 602 1.33 tls } 603 1.33 tls if (error != 0 || (crp->crp_flags & CRYPTO_F_DONE)) { 604 1.33 tls cv_signal(&crp->crp_cv); 605 1.33 tls } 606 1.33 tls mutex_spin_exit(&crypto_mtx); 607 1.34.6.3 mjf return 0; 608 1.34.6.3 mjf } 609 1.34.6.3 mjf 610 1.34.6.3 mjf static int 611 1.34.6.3 mjf cryptodev_mcb(void *op) 612 1.34.6.3 mjf { 613 1.34.6.3 mjf struct cryptop *crp = (struct cryptop *) op; 614 1.34.6.3 mjf struct csession *cse = (struct csession *)crp->crp_opaque; 615 1.34.6.3 mjf int error=0; 616 1.34.6.3 mjf 617 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 618 1.34.6.3 mjf cse->error = crp->crp_etype; 619 1.34.6.3 mjf if (crp->crp_etype == EAGAIN) { 620 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 621 1.34.6.3 mjf error = crypto_dispatch(crp); 622 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 623 1.34.6.3 mjf } 624 1.34.6.3 mjf if (error != 0 || (crp->crp_flags & CRYPTO_F_DONE)) { 625 1.34.6.3 mjf cv_signal(&crp->crp_cv); 626 1.34.6.3 mjf } 627 1.34.6.3 mjf 628 1.34.6.3 mjf TAILQ_INSERT_TAIL(&crp->fcrp->crp_ret_mq, crp, crp_next); 629 1.34.6.3 mjf selnotify(&crp->fcrp->sinfo, 0, 0); 630 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 631 1.34.6.3 mjf return 0; 632 1.1 jonathan } 633 1.1 jonathan 634 1.1 jonathan static int 635 1.1 jonathan cryptodevkey_cb(void *op) 636 1.1 jonathan { 637 1.34.6.3 mjf struct cryptkop *krp = op; 638 1.34.6.3 mjf 639 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 640 1.34.6.3 mjf cv_signal(&krp->krp_cv); 641 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 642 1.34.6.3 mjf return 0; 643 1.34.6.3 mjf } 644 1.34.6.3 mjf 645 1.34.6.3 mjf static int 646 1.34.6.3 mjf cryptodevkey_mcb(void *op) 647 1.34.6.3 mjf { 648 1.34.6.3 mjf struct cryptkop *krp = op; 649 1.1 jonathan 650 1.33 tls mutex_spin_enter(&crypto_mtx); 651 1.33 tls cv_signal(&krp->krp_cv); 652 1.34.6.3 mjf TAILQ_INSERT_TAIL(&krp->fcrp->crp_ret_mkq, krp, krp_next); 653 1.34.6.3 mjf selnotify(&krp->fcrp->sinfo, 0, 0); 654 1.33 tls mutex_spin_exit(&crypto_mtx); 655 1.34.6.3 mjf return 0; 656 1.1 jonathan } 657 1.1 jonathan 658 1.1 jonathan static int 659 1.1 jonathan cryptodev_key(struct crypt_kop *kop) 660 1.1 jonathan { 661 1.1 jonathan struct cryptkop *krp = NULL; 662 1.1 jonathan int error = EINVAL; 663 1.1 jonathan int in, out, size, i; 664 1.1 jonathan 665 1.34.6.3 mjf if (kop->crk_iparams + kop->crk_oparams > CRK_MAXPARAM) 666 1.34.6.3 mjf return EFBIG; 667 1.1 jonathan 668 1.1 jonathan in = kop->crk_iparams; 669 1.1 jonathan out = kop->crk_oparams; 670 1.1 jonathan switch (kop->crk_op) { 671 1.1 jonathan case CRK_MOD_EXP: 672 1.1 jonathan if (in == 3 && out == 1) 673 1.1 jonathan break; 674 1.34.6.3 mjf return EINVAL; 675 1.1 jonathan case CRK_MOD_EXP_CRT: 676 1.1 jonathan if (in == 6 && out == 1) 677 1.1 jonathan break; 678 1.34.6.3 mjf return EINVAL; 679 1.1 jonathan case CRK_DSA_SIGN: 680 1.1 jonathan if (in == 5 && out == 2) 681 1.1 jonathan break; 682 1.34.6.3 mjf return EINVAL; 683 1.1 jonathan case CRK_DSA_VERIFY: 684 1.1 jonathan if (in == 7 && out == 0) 685 1.1 jonathan break; 686 1.34.6.3 mjf return EINVAL; 687 1.1 jonathan case CRK_DH_COMPUTE_KEY: 688 1.1 jonathan if (in == 3 && out == 1) 689 1.1 jonathan break; 690 1.34.6.3 mjf return EINVAL; 691 1.27 tls case CRK_MOD_ADD: 692 1.27 tls if (in == 3 && out == 1) 693 1.27 tls break; 694 1.34.6.3 mjf return EINVAL; 695 1.27 tls case CRK_MOD_ADDINV: 696 1.27 tls if (in == 2 && out == 1) 697 1.27 tls break; 698 1.34.6.3 mjf return EINVAL; 699 1.27 tls case CRK_MOD_SUB: 700 1.27 tls if (in == 3 && out == 1) 701 1.27 tls break; 702 1.34.6.3 mjf return EINVAL; 703 1.27 tls case CRK_MOD_MULT: 704 1.27 tls if (in == 3 && out == 1) 705 1.27 tls break; 706 1.34.6.3 mjf return EINVAL; 707 1.27 tls case CRK_MOD_MULTINV: 708 1.27 tls if (in == 2 && out == 1) 709 1.27 tls break; 710 1.34.6.3 mjf return EINVAL; 711 1.27 tls case CRK_MOD: 712 1.27 tls if (in == 2 && out == 1) 713 1.27 tls break; 714 1.34.6.3 mjf return EINVAL; 715 1.1 jonathan default: 716 1.34.6.3 mjf return EINVAL; 717 1.1 jonathan } 718 1.1 jonathan 719 1.33 tls krp = pool_get(&cryptkop_pool, PR_WAITOK); 720 1.34.6.3 mjf (void)memset(krp, 0, sizeof *krp); 721 1.33 tls cv_init(&krp->krp_cv, "crykdev"); 722 1.1 jonathan krp->krp_op = kop->crk_op; 723 1.1 jonathan krp->krp_status = kop->crk_status; 724 1.1 jonathan krp->krp_iparams = kop->crk_iparams; 725 1.1 jonathan krp->krp_oparams = kop->crk_oparams; 726 1.1 jonathan krp->krp_status = 0; 727 1.1 jonathan krp->krp_callback = (int (*) (struct cryptkop *)) cryptodevkey_cb; 728 1.1 jonathan 729 1.1 jonathan for (i = 0; i < CRK_MAXPARAM; i++) 730 1.1 jonathan krp->krp_param[i].crp_nbits = kop->crk_param[i].crp_nbits; 731 1.1 jonathan for (i = 0; i < krp->krp_iparams + krp->krp_oparams; i++) { 732 1.1 jonathan size = (krp->krp_param[i].crp_nbits + 7) / 8; 733 1.1 jonathan if (size == 0) 734 1.1 jonathan continue; 735 1.34.6.3 mjf krp->krp_param[i].crp_p = kmem_alloc(size, KM_SLEEP); 736 1.1 jonathan if (i >= krp->krp_iparams) 737 1.1 jonathan continue; 738 1.34.6.3 mjf error = copyin(kop->crk_param[i].crp_p, 739 1.34.6.3 mjf krp->krp_param[i].crp_p, size); 740 1.1 jonathan if (error) 741 1.1 jonathan goto fail; 742 1.1 jonathan } 743 1.1 jonathan 744 1.1 jonathan error = crypto_kdispatch(krp); 745 1.33 tls if (error != 0) { 746 1.1 jonathan goto fail; 747 1.33 tls } 748 1.33 tls 749 1.33 tls mutex_spin_enter(&crypto_mtx); 750 1.33 tls while (!(krp->krp_flags & CRYPTO_F_DONE)) { 751 1.33 tls cv_wait(&krp->krp_cv, &crypto_mtx); /* XXX cv_wait_sig? */ 752 1.33 tls } 753 1.33 tls if (krp->krp_flags & CRYPTO_F_ONRETQ) { 754 1.33 tls DPRINTF(("cryptodev_key: DONE early, not via cryptoret.\n")); 755 1.33 tls (void)crypto_ret_kq_remove(krp); 756 1.33 tls } 757 1.33 tls mutex_spin_exit(&crypto_mtx); 758 1.1 jonathan 759 1.1 jonathan if (krp->krp_status != 0) { 760 1.34.6.3 mjf DPRINTF(("cryptodev_key: krp->krp_status 0x%08x\n", 761 1.34.6.3 mjf krp->krp_status)); 762 1.1 jonathan error = krp->krp_status; 763 1.1 jonathan goto fail; 764 1.1 jonathan } 765 1.1 jonathan 766 1.34.6.3 mjf for (i = krp->krp_iparams; i < krp->krp_iparams + krp->krp_oparams; 767 1.34.6.3 mjf i++) { 768 1.1 jonathan size = (krp->krp_param[i].crp_nbits + 7) / 8; 769 1.1 jonathan if (size == 0) 770 1.1 jonathan continue; 771 1.34.6.3 mjf error = copyout(krp->krp_param[i].crp_p, 772 1.34.6.3 mjf kop->crk_param[i].crp_p, size); 773 1.34 tls if (error) { 774 1.34.6.3 mjf DPRINTF(("cryptodev_key: copyout oparam %d failed, " 775 1.34.6.3 mjf "error=%d\n", i-krp->krp_iparams, error)); 776 1.1 jonathan goto fail; 777 1.34 tls } 778 1.1 jonathan } 779 1.1 jonathan 780 1.1 jonathan fail: 781 1.34.6.3 mjf kop->crk_status = krp->krp_status; 782 1.34.6.3 mjf for (i = 0; i < CRK_MAXPARAM; i++) { 783 1.34.6.3 mjf struct crparam *kp = &(krp->krp_param[i]); 784 1.34.6.3 mjf if (krp->krp_param[i].crp_p) { 785 1.34.6.3 mjf size = (kp->crp_nbits + 7) / 8; 786 1.34.6.3 mjf KASSERT(size > 0); 787 1.34.6.3 mjf (void)memset(kp->crp_p, 0, size); 788 1.34.6.3 mjf kmem_free(kp->crp_p, size); 789 1.1 jonathan } 790 1.1 jonathan } 791 1.34.6.4 mjf cv_destroy(&krp->krp_cv); 792 1.34.6.3 mjf pool_put(&cryptkop_pool, krp); 793 1.34 tls DPRINTF(("cryptodev_key: error=0x%08x\n", error)); 794 1.34.6.3 mjf return error; 795 1.1 jonathan } 796 1.1 jonathan 797 1.1 jonathan /* ARGSUSED */ 798 1.1 jonathan static int 799 1.34.6.3 mjf cryptof_close(struct file *fp) 800 1.1 jonathan { 801 1.34.6.1 mjf struct fcrypt *fcr = fp->f_data; 802 1.1 jonathan struct csession *cse; 803 1.1 jonathan 804 1.33 tls mutex_spin_enter(&crypto_mtx); 805 1.1 jonathan while ((cse = TAILQ_FIRST(&fcr->csessions))) { 806 1.1 jonathan TAILQ_REMOVE(&fcr->csessions, cse, next); 807 1.1 jonathan (void)csefree(cse); 808 1.1 jonathan } 809 1.34.6.3 mjf seldestroy(&fcr->sinfo); 810 1.1 jonathan fp->f_data = NULL; 811 1.33 tls mutex_spin_exit(&crypto_mtx); 812 1.1 jonathan 813 1.34.6.3 mjf pool_put(&fcrpl, fcr); 814 1.1 jonathan return 0; 815 1.1 jonathan } 816 1.1 jonathan 817 1.33 tls /* csefind: call with crypto_mtx held. */ 818 1.1 jonathan static struct csession * 819 1.1 jonathan csefind(struct fcrypt *fcr, u_int ses) 820 1.1 jonathan { 821 1.34.6.4 mjf struct csession *cse, *cnext, *ret = NULL; 822 1.1 jonathan 823 1.33 tls KASSERT(mutex_owned(&crypto_mtx)); 824 1.34.6.4 mjf TAILQ_FOREACH_SAFE(cse, &fcr->csessions, next, cnext) 825 1.1 jonathan if (cse->ses == ses) 826 1.33 tls ret = cse; 827 1.34.6.3 mjf 828 1.34.6.3 mjf return ret; 829 1.1 jonathan } 830 1.1 jonathan 831 1.33 tls /* csedelete: call with crypto_mtx held. */ 832 1.1 jonathan static int 833 1.1 jonathan csedelete(struct fcrypt *fcr, struct csession *cse_del) 834 1.1 jonathan { 835 1.34.6.4 mjf struct csession *cse, *cnext; 836 1.33 tls int ret = 0; 837 1.1 jonathan 838 1.33 tls KASSERT(mutex_owned(&crypto_mtx)); 839 1.34.6.4 mjf TAILQ_FOREACH_SAFE(cse, &fcr->csessions, next, cnext) { 840 1.1 jonathan if (cse == cse_del) { 841 1.1 jonathan TAILQ_REMOVE(&fcr->csessions, cse, next); 842 1.33 tls ret = 1; 843 1.1 jonathan } 844 1.1 jonathan } 845 1.34.6.3 mjf return ret; 846 1.1 jonathan } 847 1.1 jonathan 848 1.33 tls /* cseadd: call with crypto_mtx held. */ 849 1.1 jonathan static struct csession * 850 1.1 jonathan cseadd(struct fcrypt *fcr, struct csession *cse) 851 1.1 jonathan { 852 1.33 tls KASSERT(mutex_owned(&crypto_mtx)); 853 1.33 tls /* don't let session ID wrap! */ 854 1.33 tls if (fcr->sesn + 1 == 0) return NULL; 855 1.1 jonathan TAILQ_INSERT_TAIL(&fcr->csessions, cse, next); 856 1.1 jonathan cse->ses = fcr->sesn++; 857 1.34.6.3 mjf return cse; 858 1.1 jonathan } 859 1.1 jonathan 860 1.33 tls /* csecreate: call with crypto_mtx held. */ 861 1.1 jonathan static struct csession * 862 1.26 christos csecreate(struct fcrypt *fcr, u_int64_t sid, void *key, u_int64_t keylen, 863 1.26 christos void *mackey, u_int64_t mackeylen, u_int32_t cipher, u_int32_t mac, 864 1.1 jonathan struct enc_xform *txform, struct auth_hash *thash) 865 1.1 jonathan { 866 1.1 jonathan struct csession *cse; 867 1.1 jonathan 868 1.33 tls KASSERT(mutex_owned(&crypto_mtx)); 869 1.29 tls cse = pool_get(&csepl, PR_NOWAIT); 870 1.1 jonathan if (cse == NULL) 871 1.1 jonathan return NULL; 872 1.1 jonathan cse->key = key; 873 1.1 jonathan cse->keylen = keylen/8; 874 1.1 jonathan cse->mackey = mackey; 875 1.1 jonathan cse->mackeylen = mackeylen/8; 876 1.1 jonathan cse->sid = sid; 877 1.1 jonathan cse->cipher = cipher; 878 1.1 jonathan cse->mac = mac; 879 1.1 jonathan cse->txform = txform; 880 1.1 jonathan cse->thash = thash; 881 1.34 tls cse->error = 0; 882 1.28 tls if (cseadd(fcr, cse)) 883 1.34.6.3 mjf return cse; 884 1.28 tls else { 885 1.33 tls pool_put(&csepl, cse); 886 1.28 tls return NULL; 887 1.28 tls } 888 1.1 jonathan } 889 1.1 jonathan 890 1.33 tls /* csefree: call with crypto_mtx held. */ 891 1.1 jonathan static int 892 1.1 jonathan csefree(struct csession *cse) 893 1.1 jonathan { 894 1.1 jonathan int error; 895 1.1 jonathan 896 1.33 tls KASSERT(mutex_owned(&crypto_mtx)); 897 1.1 jonathan error = crypto_freesession(cse->sid); 898 1.1 jonathan if (cse->key) 899 1.34.6.3 mjf free(cse->key, M_XDATA); 900 1.1 jonathan if (cse->mackey) 901 1.34.6.3 mjf free(cse->mackey, M_XDATA); 902 1.29 tls pool_put(&csepl, cse); 903 1.34.6.3 mjf return error; 904 1.1 jonathan } 905 1.1 jonathan 906 1.1 jonathan static int 907 1.25 christos cryptoopen(dev_t dev, int flag, int mode, 908 1.25 christos struct lwp *l) 909 1.1 jonathan { 910 1.34.6.1 mjf file_t *fp; 911 1.29 tls struct fcrypt *fcr; 912 1.29 tls int fd, error; 913 1.29 tls 914 1.1 jonathan if (crypto_usercrypto == 0) 915 1.34.6.3 mjf return ENXIO; 916 1.29 tls 917 1.34.6.1 mjf if ((error = fd_allocfile(&fp, &fd)) != 0) 918 1.29 tls return error; 919 1.29 tls 920 1.29 tls fcr = pool_get(&fcrpl, PR_WAITOK); 921 1.33 tls mutex_spin_enter(&crypto_mtx); 922 1.29 tls TAILQ_INIT(&fcr->csessions); 923 1.34.6.3 mjf TAILQ_INIT(&fcr->crp_ret_mq); 924 1.34.6.3 mjf TAILQ_INIT(&fcr->crp_ret_mkq); 925 1.34.6.3 mjf selinit(&fcr->sinfo); 926 1.29 tls /* 927 1.29 tls * Don't ever return session 0, to allow detection of 928 1.29 tls * failed creation attempts with multi-create ioctl. 929 1.29 tls */ 930 1.29 tls fcr->sesn = 1; 931 1.34.6.3 mjf fcr->requestid = 1; 932 1.33 tls mutex_spin_exit(&crypto_mtx); 933 1.34.6.1 mjf return fd_clone(fp, fd, flag, &cryptofops, fcr); 934 1.1 jonathan } 935 1.1 jonathan 936 1.1 jonathan static int 937 1.25 christos cryptoread(dev_t dev, struct uio *uio, int ioflag) 938 1.1 jonathan { 939 1.34.6.3 mjf return EIO; 940 1.1 jonathan } 941 1.1 jonathan 942 1.1 jonathan static int 943 1.25 christos cryptowrite(dev_t dev, struct uio *uio, int ioflag) 944 1.1 jonathan { 945 1.34.6.3 mjf return EIO; 946 1.1 jonathan } 947 1.1 jonathan 948 1.1 jonathan int 949 1.25 christos cryptoselect(dev_t dev, int rw, struct lwp *l) 950 1.1 jonathan { 951 1.34.6.3 mjf return 0; 952 1.1 jonathan } 953 1.1 jonathan 954 1.1 jonathan /*static*/ 955 1.1 jonathan struct cdevsw crypto_cdevsw = { 956 1.1 jonathan /* open */ cryptoopen, 957 1.29 tls /* close */ noclose, 958 1.1 jonathan /* read */ cryptoread, 959 1.1 jonathan /* write */ cryptowrite, 960 1.29 tls /* ioctl */ noioctl, 961 1.1 jonathan /* ttstop?*/ nostop, 962 1.1 jonathan /* ??*/ notty, 963 1.1 jonathan /* poll */ cryptoselect /*nopoll*/, 964 1.1 jonathan /* mmap */ nommap, 965 1.1 jonathan /* kqfilter */ nokqfilter, 966 1.23 christos /* type */ D_OTHER, 967 1.1 jonathan }; 968 1.1 jonathan 969 1.34.6.3 mjf static int 970 1.34.6.3 mjf cryptodev_mop(struct fcrypt *fcr, 971 1.34.6.3 mjf struct crypt_n_op * cnop, 972 1.34.6.3 mjf int count, struct lwp *l) 973 1.34.6.3 mjf { 974 1.34.6.3 mjf struct cryptop *crp = NULL; 975 1.34.6.3 mjf struct cryptodesc *crde = NULL, *crda = NULL; 976 1.34.6.3 mjf int req, error=0; 977 1.34.6.3 mjf struct csession *cse; 978 1.34.6.3 mjf 979 1.34.6.3 mjf for (req = 0; req < count; req++) { 980 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 981 1.34.6.3 mjf cse = csefind(fcr, cnop[req].ses); 982 1.34.6.3 mjf if (cse == NULL) { 983 1.34.6.3 mjf DPRINTF(("csefind failed\n")); 984 1.34.6.3 mjf cnop[req].status = EINVAL; 985 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 986 1.34.6.3 mjf continue; 987 1.34.6.3 mjf } 988 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 989 1.34.6.3 mjf 990 1.34.6.3 mjf if (cnop[req].len > 256*1024-4) { 991 1.34.6.3 mjf DPRINTF(("length failed\n")); 992 1.34.6.3 mjf cnop[req].status = EINVAL; 993 1.34.6.3 mjf continue; 994 1.34.6.3 mjf } 995 1.34.6.3 mjf if (cse->txform) { 996 1.34.6.3 mjf if (cnop[req].len == 0 || 997 1.34.6.3 mjf (cnop[req].len % cse->txform->blocksize) != 0) { 998 1.34.6.3 mjf cnop[req].status = EINVAL; 999 1.34.6.3 mjf continue; 1000 1.34.6.3 mjf } 1001 1.34.6.3 mjf } 1002 1.34.6.3 mjf 1003 1.34.6.3 mjf crp = crypto_getreq((cse->txform != NULL) + 1004 1.34.6.3 mjf (cse->thash != NULL)); 1005 1.34.6.3 mjf if (crp == NULL) { 1006 1.34.6.3 mjf cnop[req].status = ENOMEM; 1007 1.34.6.3 mjf goto bail; 1008 1.34.6.3 mjf } 1009 1.34.6.3 mjf 1010 1.34.6.3 mjf (void)memset(&crp->uio, 0, sizeof(crp->uio)); 1011 1.34.6.3 mjf crp->uio.uio_iovcnt = 1; 1012 1.34.6.3 mjf crp->uio.uio_resid = 0; 1013 1.34.6.3 mjf crp->uio.uio_rw = UIO_WRITE; 1014 1.34.6.3 mjf crp->uio.uio_iov = crp->iovec; 1015 1.34.6.3 mjf UIO_SETUP_SYSSPACE(&crp->uio); 1016 1.34.6.3 mjf memset(&crp->iovec, 0, sizeof(crp->iovec)); 1017 1.34.6.3 mjf crp->uio.uio_iov[0].iov_len = cnop[req].len; 1018 1.34.6.3 mjf crp->uio.uio_iov[0].iov_base = kmem_alloc(cnop[req].len, 1019 1.34.6.3 mjf KM_SLEEP); 1020 1.34.6.3 mjf crp->uio.uio_resid = crp->uio.uio_iov[0].iov_len; 1021 1.34.6.3 mjf 1022 1.34.6.3 mjf if (cse->thash) { 1023 1.34.6.3 mjf crda = crp->crp_desc; 1024 1.34.6.3 mjf if (cse->txform && crda) 1025 1.34.6.3 mjf crde = crda->crd_next; 1026 1.34.6.3 mjf } else { 1027 1.34.6.3 mjf if (cse->txform) 1028 1.34.6.3 mjf crde = crp->crp_desc; 1029 1.34.6.3 mjf else { 1030 1.34.6.3 mjf cnop[req].status = EINVAL; 1031 1.34.6.3 mjf goto bail; 1032 1.34.6.3 mjf } 1033 1.34.6.3 mjf } 1034 1.34.6.3 mjf 1035 1.34.6.3 mjf if ((copyin(cnop[req].src, 1036 1.34.6.3 mjf crp->uio.uio_iov[0].iov_base, cnop[req].len))) { 1037 1.34.6.3 mjf cnop[req].status = EINVAL; 1038 1.34.6.3 mjf goto bail; 1039 1.34.6.3 mjf } 1040 1.34.6.3 mjf 1041 1.34.6.3 mjf if (crda) { 1042 1.34.6.3 mjf crda->crd_skip = 0; 1043 1.34.6.3 mjf crda->crd_len = cnop[req].len; 1044 1.34.6.3 mjf crda->crd_inject = 0; /* ??? */ 1045 1.34.6.3 mjf 1046 1.34.6.3 mjf crda->crd_alg = cse->mac; 1047 1.34.6.3 mjf crda->crd_key = cse->mackey; 1048 1.34.6.3 mjf crda->crd_klen = cse->mackeylen * 8; 1049 1.34.6.3 mjf } 1050 1.34.6.3 mjf 1051 1.34.6.3 mjf if (crde) { 1052 1.34.6.3 mjf if (cnop[req].op == COP_ENCRYPT) 1053 1.34.6.3 mjf crde->crd_flags |= CRD_F_ENCRYPT; 1054 1.34.6.3 mjf else 1055 1.34.6.3 mjf crde->crd_flags &= ~CRD_F_ENCRYPT; 1056 1.34.6.3 mjf crde->crd_len = cnop[req].len; 1057 1.34.6.3 mjf crde->crd_inject = 0; 1058 1.34.6.3 mjf 1059 1.34.6.3 mjf crde->crd_alg = cse->cipher; 1060 1.34.6.3 mjf #ifdef notyet /* XXX must notify h/w driver new key, drain */ 1061 1.34.6.3 mjf if(cnop[req].key && cnop[req].keylen) { 1062 1.34.6.3 mjf crde->crd_key = malloc(cnop[req].keylen, 1063 1.34.6.3 mjf M_XDATA, M_WAITOK); 1064 1.34.6.3 mjf if((error = copyin(cnop[req].key, 1065 1.34.6.3 mjf crde->crd_key, cnop[req].keylen))) { 1066 1.34.6.3 mjf cnop[req].status = EINVAL; 1067 1.34.6.3 mjf goto bail; 1068 1.34.6.3 mjf } 1069 1.34.6.3 mjf crde->crd_klen = cnop[req].keylen * 8; 1070 1.34.6.3 mjf } else { ... } 1071 1.34.6.3 mjf #endif 1072 1.34.6.3 mjf crde->crd_key = cse->key; 1073 1.34.6.3 mjf crde->crd_klen = cse->keylen * 8; 1074 1.34.6.3 mjf } 1075 1.34.6.3 mjf 1076 1.34.6.3 mjf crp->crp_ilen = cnop[req].len; 1077 1.34.6.3 mjf crp->crp_flags = CRYPTO_F_IOV | CRYPTO_F_CBIMM | 1078 1.34.6.3 mjf (cnop[req].flags & COP_F_BATCH); 1079 1.34.6.3 mjf crp->crp_buf = (void *)&crp->uio; 1080 1.34.6.3 mjf crp->crp_callback = (int (*) (struct cryptop *)) cryptodev_mcb; 1081 1.34.6.3 mjf crp->crp_sid = cse->sid; 1082 1.34.6.3 mjf crp->crp_opaque = (void *)cse; 1083 1.34.6.3 mjf crp->fcrp = fcr; 1084 1.34.6.3 mjf crp->dst = cnop[req].dst; 1085 1.34.6.3 mjf /* we can use the crp_ilen in cryptop(crp) for this */ 1086 1.34.6.3 mjf crp->len = cnop[req].len; 1087 1.34.6.3 mjf crp->mac = cnop[req].mac; 1088 1.34.6.3 mjf 1089 1.34.6.3 mjf if (cnop[req].iv) { 1090 1.34.6.3 mjf if (crde == NULL) { 1091 1.34.6.3 mjf cnop[req].status = EINVAL; 1092 1.34.6.3 mjf goto bail; 1093 1.34.6.3 mjf } 1094 1.34.6.3 mjf if (cse->cipher == CRYPTO_ARC4) { /* XXX use flag? */ 1095 1.34.6.3 mjf cnop[req].status = EINVAL; 1096 1.34.6.3 mjf goto bail; 1097 1.34.6.3 mjf } 1098 1.34.6.3 mjf if ((error = copyin(cnop[req].iv, crp->tmp_iv, 1099 1.34.6.3 mjf cse->txform->blocksize))) { 1100 1.34.6.3 mjf cnop[req].status = EINVAL; 1101 1.34.6.3 mjf goto bail; 1102 1.34.6.3 mjf } 1103 1.34.6.3 mjf (void)memcpy(crde->crd_iv, crp->tmp_iv, 1104 1.34.6.3 mjf cse->txform->blocksize); 1105 1.34.6.3 mjf crde->crd_flags |= CRD_F_IV_EXPLICIT | CRD_F_IV_PRESENT; 1106 1.34.6.3 mjf crde->crd_skip = 0; 1107 1.34.6.3 mjf } else if (crde) { 1108 1.34.6.3 mjf if (cse->cipher == CRYPTO_ARC4) { /* XXX use flag? */ 1109 1.34.6.3 mjf crde->crd_skip = 0; 1110 1.34.6.3 mjf } else { 1111 1.34.6.3 mjf crde->crd_flags |= CRD_F_IV_PRESENT; 1112 1.34.6.3 mjf crde->crd_skip = cse->txform->blocksize; 1113 1.34.6.3 mjf crde->crd_len -= cse->txform->blocksize; 1114 1.34.6.3 mjf } 1115 1.34.6.3 mjf } 1116 1.34.6.3 mjf 1117 1.34.6.3 mjf if (cnop[req].mac) { 1118 1.34.6.3 mjf if (crda == NULL) { 1119 1.34.6.3 mjf cnop[req].status = EINVAL; 1120 1.34.6.3 mjf goto bail; 1121 1.34.6.3 mjf } 1122 1.34.6.3 mjf crp->crp_mac=cse->tmp_mac; 1123 1.34.6.3 mjf } 1124 1.34.6.3 mjf cnop[req].reqid = atomic_inc_32_nv(&(fcr->requestid)); 1125 1.34.6.3 mjf crp->crp_reqid = cnop[req].reqid; 1126 1.34.6.3 mjf crp->crp_usropaque = cnop[req].opaque; 1127 1.34.6.3 mjf #ifdef notyet 1128 1.34.6.3 mjf eagain: 1129 1.34.6.3 mjf #endif 1130 1.34.6.3 mjf cnop[req].status = crypto_dispatch(crp); 1131 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); /* XXX why mutex? */ 1132 1.34.6.3 mjf 1133 1.34.6.3 mjf switch (cnop[req].status) { 1134 1.34.6.3 mjf #ifdef notyet /* don't loop forever -- but EAGAIN not possible here yet */ 1135 1.34.6.3 mjf case EAGAIN: 1136 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1137 1.34.6.3 mjf goto eagain; 1138 1.34.6.3 mjf break; 1139 1.34.6.3 mjf #endif 1140 1.34.6.3 mjf case 0: 1141 1.34.6.3 mjf break; 1142 1.34.6.3 mjf default: 1143 1.34.6.3 mjf DPRINTF(("cryptodev_op: not waiting, error.\n")); 1144 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1145 1.34.6.3 mjf goto bail; 1146 1.34.6.3 mjf } 1147 1.34.6.3 mjf 1148 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1149 1.34.6.3 mjf bail: 1150 1.34.6.3 mjf if (cnop[req].status) { 1151 1.34.6.3 mjf if (crp) { 1152 1.34.6.3 mjf crypto_freereq(crp); 1153 1.34.6.3 mjf if(cse->uio.uio_iov[0].iov_base) { 1154 1.34.6.3 mjf kmem_free(cse->uio.uio_iov[0].iov_base, 1155 1.34.6.3 mjf cse->uio.uio_iov[0].iov_len); 1156 1.34.6.3 mjf } 1157 1.34.6.3 mjf } 1158 1.34.6.3 mjf error = 0; 1159 1.34.6.3 mjf } 1160 1.34.6.3 mjf } 1161 1.34.6.3 mjf return error; 1162 1.34.6.3 mjf } 1163 1.34.6.3 mjf 1164 1.34.6.3 mjf static int 1165 1.34.6.3 mjf cryptodev_mkey(struct fcrypt *fcr, struct crypt_n_kop *kop, int count) 1166 1.34.6.3 mjf { 1167 1.34.6.3 mjf struct cryptkop *krp = NULL; 1168 1.34.6.3 mjf int error = EINVAL; 1169 1.34.6.3 mjf int in, out, size, i, req; 1170 1.34.6.3 mjf 1171 1.34.6.3 mjf for (req = 0; req < count; req++) { 1172 1.34.6.3 mjf if (kop[req].crk_iparams + kop[req].crk_oparams > CRK_MAXPARAM) 1173 1.34.6.3 mjf return EFBIG; 1174 1.34.6.3 mjf 1175 1.34.6.3 mjf in = kop[req].crk_iparams; 1176 1.34.6.3 mjf out = kop[req].crk_oparams; 1177 1.34.6.3 mjf switch (kop[req].crk_op) { 1178 1.34.6.3 mjf case CRK_MOD_EXP: 1179 1.34.6.3 mjf if (in == 3 && out == 1) 1180 1.34.6.3 mjf break; 1181 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1182 1.34.6.3 mjf continue; 1183 1.34.6.3 mjf case CRK_MOD_EXP_CRT: 1184 1.34.6.3 mjf if (in == 6 && out == 1) 1185 1.34.6.3 mjf break; 1186 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1187 1.34.6.3 mjf continue; 1188 1.34.6.3 mjf case CRK_DSA_SIGN: 1189 1.34.6.3 mjf if (in == 5 && out == 2) 1190 1.34.6.3 mjf break; 1191 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1192 1.34.6.3 mjf continue; 1193 1.34.6.3 mjf case CRK_DSA_VERIFY: 1194 1.34.6.3 mjf if (in == 7 && out == 0) 1195 1.34.6.3 mjf break; 1196 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1197 1.34.6.3 mjf continue; 1198 1.34.6.3 mjf case CRK_DH_COMPUTE_KEY: 1199 1.34.6.3 mjf if (in == 3 && out == 1) 1200 1.34.6.3 mjf break; 1201 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1202 1.34.6.3 mjf continue; 1203 1.34.6.3 mjf case CRK_MOD_ADD: 1204 1.34.6.3 mjf if (in == 3 && out == 1) 1205 1.34.6.3 mjf break; 1206 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1207 1.34.6.3 mjf continue; 1208 1.34.6.3 mjf case CRK_MOD_ADDINV: 1209 1.34.6.3 mjf if (in == 2 && out == 1) 1210 1.34.6.3 mjf break; 1211 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1212 1.34.6.3 mjf continue; 1213 1.34.6.3 mjf case CRK_MOD_SUB: 1214 1.34.6.3 mjf if (in == 3 && out == 1) 1215 1.34.6.3 mjf break; 1216 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1217 1.34.6.3 mjf continue; 1218 1.34.6.3 mjf case CRK_MOD_MULT: 1219 1.34.6.3 mjf if (in == 3 && out == 1) 1220 1.34.6.3 mjf break; 1221 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1222 1.34.6.3 mjf continue; 1223 1.34.6.3 mjf case CRK_MOD_MULTINV: 1224 1.34.6.3 mjf if (in == 2 && out == 1) 1225 1.34.6.3 mjf break; 1226 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1227 1.34.6.3 mjf continue; 1228 1.34.6.3 mjf case CRK_MOD: 1229 1.34.6.3 mjf if (in == 2 && out == 1) 1230 1.34.6.3 mjf break; 1231 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1232 1.34.6.3 mjf continue; 1233 1.34.6.3 mjf default: 1234 1.34.6.3 mjf kop[req].crk_status = EINVAL; 1235 1.34.6.3 mjf continue; 1236 1.34.6.3 mjf } 1237 1.34.6.3 mjf 1238 1.34.6.3 mjf krp = pool_get(&cryptkop_pool, PR_WAITOK); 1239 1.34.6.3 mjf (void)memset(krp, 0, sizeof *krp); 1240 1.34.6.3 mjf cv_init(&krp->krp_cv, "crykdev"); 1241 1.34.6.3 mjf krp->krp_op = kop[req].crk_op; 1242 1.34.6.3 mjf krp->krp_status = kop[req].crk_status; 1243 1.34.6.3 mjf krp->krp_iparams = kop[req].crk_iparams; 1244 1.34.6.3 mjf krp->krp_oparams = kop[req].crk_oparams; 1245 1.34.6.3 mjf krp->krp_status = 0; 1246 1.34.6.3 mjf krp->krp_callback = 1247 1.34.6.3 mjf (int (*) (struct cryptkop *)) cryptodevkey_mcb; 1248 1.34.6.3 mjf (void)memcpy(krp->crk_param, kop[req].crk_param, 1249 1.34.6.3 mjf sizeof(kop[req].crk_param)); 1250 1.34.6.3 mjf 1251 1.34.6.3 mjf krp->krp_flags = CRYPTO_F_CBIMM; 1252 1.34.6.3 mjf 1253 1.34.6.3 mjf for (i = 0; i < CRK_MAXPARAM; i++) 1254 1.34.6.3 mjf krp->krp_param[i].crp_nbits = 1255 1.34.6.3 mjf kop[req].crk_param[i].crp_nbits; 1256 1.34.6.3 mjf for (i = 0; i < krp->krp_iparams + krp->krp_oparams; i++) { 1257 1.34.6.3 mjf size = (krp->krp_param[i].crp_nbits + 7) / 8; 1258 1.34.6.3 mjf if (size == 0) 1259 1.34.6.3 mjf continue; 1260 1.34.6.3 mjf krp->krp_param[i].crp_p = 1261 1.34.6.3 mjf kmem_alloc(size, KM_SLEEP); 1262 1.34.6.3 mjf if (i >= krp->krp_iparams) 1263 1.34.6.3 mjf continue; 1264 1.34.6.3 mjf kop[req].crk_status = 1265 1.34.6.3 mjf copyin(kop[req].crk_param[i].crp_p, 1266 1.34.6.3 mjf krp->krp_param[i].crp_p, size); 1267 1.34.6.3 mjf if (kop[req].crk_status) 1268 1.34.6.3 mjf goto fail; 1269 1.34.6.3 mjf } 1270 1.34.6.3 mjf krp->fcrp = fcr; 1271 1.34.6.3 mjf 1272 1.34.6.3 mjf kop[req].crk_reqid = atomic_inc_32_nv(&(fcr->requestid)); 1273 1.34.6.3 mjf krp->krp_reqid = kop[req].crk_reqid; 1274 1.34.6.3 mjf krp->krp_usropaque = kop[req].crk_opaque; 1275 1.34.6.3 mjf 1276 1.34.6.3 mjf kop[req].crk_status = crypto_kdispatch(krp); 1277 1.34.6.3 mjf if (kop[req].crk_status != 0) { 1278 1.34.6.3 mjf goto fail; 1279 1.34.6.3 mjf } 1280 1.34.6.3 mjf 1281 1.34.6.3 mjf fail: 1282 1.34.6.3 mjf if(kop[req].crk_status) { 1283 1.34.6.3 mjf if (krp) { 1284 1.34.6.3 mjf kop[req].crk_status = krp->krp_status; 1285 1.34.6.3 mjf for (i = 0; i < CRK_MAXPARAM; i++) { 1286 1.34.6.3 mjf struct crparam *kp = 1287 1.34.6.3 mjf &(krp->krp_param[i]); 1288 1.34.6.3 mjf if (kp->crp_p) { 1289 1.34.6.3 mjf size = (kp->crp_nbits + 7) / 8; 1290 1.34.6.3 mjf KASSERT(size > 0); 1291 1.34.6.3 mjf memset(kp->crp_p, 0, size); 1292 1.34.6.3 mjf kmem_free(kp->crp_p, size); 1293 1.34.6.3 mjf } 1294 1.34.6.3 mjf } 1295 1.34.6.4 mjf cv_destroy(&krp->krp_cv); 1296 1.34.6.3 mjf pool_put(&cryptkop_pool, krp); 1297 1.34.6.3 mjf } 1298 1.34.6.3 mjf } 1299 1.34.6.3 mjf error = 0; 1300 1.34.6.3 mjf } 1301 1.34.6.3 mjf DPRINTF(("cryptodev_key: error=0x%08x\n", error)); 1302 1.34.6.3 mjf return error; 1303 1.34.6.3 mjf } 1304 1.34.6.3 mjf 1305 1.34.6.3 mjf static int 1306 1.34.6.4 mjf cryptodev_session(struct fcrypt *fcr, struct session_op *sop) 1307 1.34.6.4 mjf { 1308 1.34.6.3 mjf struct cryptoini cria, crie; 1309 1.34.6.3 mjf struct enc_xform *txform = NULL; 1310 1.34.6.3 mjf struct auth_hash *thash = NULL; 1311 1.34.6.3 mjf struct csession *cse; 1312 1.34.6.3 mjf u_int64_t sid; 1313 1.34.6.3 mjf int error = 0; 1314 1.34.6.3 mjf 1315 1.34.6.3 mjf /* XXX there must be a way to not embed the list of xforms here */ 1316 1.34.6.3 mjf switch (sop->cipher) { 1317 1.34.6.3 mjf case 0: 1318 1.34.6.3 mjf break; 1319 1.34.6.3 mjf case CRYPTO_DES_CBC: 1320 1.34.6.3 mjf txform = &enc_xform_des; 1321 1.34.6.3 mjf break; 1322 1.34.6.3 mjf case CRYPTO_3DES_CBC: 1323 1.34.6.3 mjf txform = &enc_xform_3des; 1324 1.34.6.3 mjf break; 1325 1.34.6.3 mjf case CRYPTO_BLF_CBC: 1326 1.34.6.3 mjf txform = &enc_xform_blf; 1327 1.34.6.3 mjf break; 1328 1.34.6.3 mjf case CRYPTO_CAST_CBC: 1329 1.34.6.3 mjf txform = &enc_xform_cast5; 1330 1.34.6.3 mjf case CRYPTO_SKIPJACK_CBC: 1331 1.34.6.3 mjf txform = &enc_xform_skipjack; 1332 1.34.6.3 mjf break; 1333 1.34.6.3 mjf case CRYPTO_AES_CBC: 1334 1.34.6.3 mjf txform = &enc_xform_rijndael128; 1335 1.34.6.3 mjf break; 1336 1.34.6.3 mjf case CRYPTO_NULL_CBC: 1337 1.34.6.3 mjf txform = &enc_xform_null; 1338 1.34.6.3 mjf break; 1339 1.34.6.3 mjf case CRYPTO_ARC4: 1340 1.34.6.3 mjf txform = &enc_xform_arc4; 1341 1.34.6.3 mjf break; 1342 1.34.6.3 mjf default: 1343 1.34.6.3 mjf DPRINTF(("Invalid cipher %d\n", sop->cipher)); 1344 1.34.6.3 mjf return EINVAL; 1345 1.34.6.3 mjf } 1346 1.34.6.3 mjf 1347 1.34.6.3 mjf switch (sop->mac) { 1348 1.34.6.3 mjf case 0: 1349 1.34.6.3 mjf break; 1350 1.34.6.3 mjf case CRYPTO_MD5_HMAC: 1351 1.34.6.3 mjf thash = &auth_hash_hmac_md5; 1352 1.34.6.3 mjf break; 1353 1.34.6.3 mjf case CRYPTO_SHA1_HMAC: 1354 1.34.6.3 mjf thash = &auth_hash_hmac_sha1; 1355 1.34.6.3 mjf break; 1356 1.34.6.3 mjf case CRYPTO_MD5_HMAC_96: 1357 1.34.6.3 mjf thash = &auth_hash_hmac_md5_96; 1358 1.34.6.3 mjf break; 1359 1.34.6.3 mjf case CRYPTO_SHA1_HMAC_96: 1360 1.34.6.3 mjf thash = &auth_hash_hmac_sha1_96; 1361 1.34.6.3 mjf break; 1362 1.34.6.3 mjf case CRYPTO_SHA2_HMAC: 1363 1.34.6.3 mjf /* XXX switching on key length seems questionable */ 1364 1.34.6.3 mjf if (sop->mackeylen == auth_hash_hmac_sha2_256.keysize) { 1365 1.34.6.3 mjf thash = &auth_hash_hmac_sha2_256; 1366 1.34.6.3 mjf } else if (sop->mackeylen == auth_hash_hmac_sha2_384.keysize) { 1367 1.34.6.3 mjf thash = &auth_hash_hmac_sha2_384; 1368 1.34.6.3 mjf } else if (sop->mackeylen == auth_hash_hmac_sha2_512.keysize) { 1369 1.34.6.3 mjf thash = &auth_hash_hmac_sha2_512; 1370 1.34.6.3 mjf } else { 1371 1.34.6.3 mjf DPRINTF(("Invalid mackeylen %d\n", sop->mackeylen)); 1372 1.34.6.3 mjf return EINVAL; 1373 1.34.6.3 mjf } 1374 1.34.6.3 mjf break; 1375 1.34.6.3 mjf case CRYPTO_RIPEMD160_HMAC: 1376 1.34.6.3 mjf thash = &auth_hash_hmac_ripemd_160; 1377 1.34.6.3 mjf break; 1378 1.34.6.3 mjf case CRYPTO_RIPEMD160_HMAC_96: 1379 1.34.6.3 mjf thash = &auth_hash_hmac_ripemd_160_96; 1380 1.34.6.3 mjf break; 1381 1.34.6.3 mjf case CRYPTO_MD5: 1382 1.34.6.3 mjf thash = &auth_hash_md5; 1383 1.34.6.3 mjf break; 1384 1.34.6.3 mjf case CRYPTO_SHA1: 1385 1.34.6.3 mjf thash = &auth_hash_sha1; 1386 1.34.6.3 mjf break; 1387 1.34.6.3 mjf case CRYPTO_NULL_HMAC: 1388 1.34.6.3 mjf thash = &auth_hash_null; 1389 1.34.6.3 mjf break; 1390 1.34.6.3 mjf default: 1391 1.34.6.3 mjf DPRINTF(("Invalid mac %d\n", sop->mac)); 1392 1.34.6.3 mjf return EINVAL; 1393 1.34.6.3 mjf } 1394 1.34.6.3 mjf 1395 1.34.6.3 mjf memset(&crie, 0, sizeof(crie)); 1396 1.34.6.3 mjf memset(&cria, 0, sizeof(cria)); 1397 1.34.6.3 mjf 1398 1.34.6.3 mjf if (txform) { 1399 1.34.6.3 mjf crie.cri_alg = txform->type; 1400 1.34.6.3 mjf crie.cri_klen = sop->keylen * 8; 1401 1.34.6.3 mjf if (sop->keylen > txform->maxkey || 1402 1.34.6.3 mjf sop->keylen < txform->minkey) { 1403 1.34.6.3 mjf DPRINTF(("keylen %d not in [%d,%d]\n", 1404 1.34.6.3 mjf sop->keylen, txform->minkey, txform->maxkey)); 1405 1.34.6.3 mjf error = EINVAL; 1406 1.34.6.3 mjf goto bail; 1407 1.34.6.3 mjf } 1408 1.34.6.3 mjf 1409 1.34.6.3 mjf crie.cri_key = malloc(crie.cri_klen / 8, M_XDATA, M_WAITOK); 1410 1.34.6.3 mjf if ((error = copyin(sop->key, crie.cri_key, crie.cri_klen / 8))) 1411 1.34.6.3 mjf goto bail; 1412 1.34.6.3 mjf if (thash) 1413 1.34.6.3 mjf crie.cri_next = &cria; /* XXX forces enc then hash? */ 1414 1.34.6.3 mjf } 1415 1.34.6.3 mjf 1416 1.34.6.3 mjf if (thash) { 1417 1.34.6.3 mjf cria.cri_alg = thash->type; 1418 1.34.6.3 mjf cria.cri_klen = sop->mackeylen * 8; 1419 1.34.6.3 mjf if (sop->mackeylen != thash->keysize) { 1420 1.34.6.3 mjf DPRINTF(("mackeylen %d != keysize %d\n", 1421 1.34.6.3 mjf sop->mackeylen, thash->keysize)); 1422 1.34.6.3 mjf error = EINVAL; 1423 1.34.6.3 mjf goto bail; 1424 1.34.6.3 mjf } 1425 1.34.6.3 mjf if (cria.cri_klen) { 1426 1.34.6.3 mjf cria.cri_key = malloc(cria.cri_klen / 8, M_XDATA, 1427 1.34.6.3 mjf M_WAITOK); 1428 1.34.6.3 mjf if ((error = copyin(sop->mackey, cria.cri_key, 1429 1.34.6.3 mjf cria.cri_klen / 8))) { 1430 1.34.6.3 mjf goto bail; 1431 1.34.6.3 mjf } 1432 1.34.6.3 mjf } 1433 1.34.6.3 mjf } 1434 1.34.6.3 mjf /* crypto_newsession requires that we hold the mutex. */ 1435 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 1436 1.34.6.3 mjf error = crypto_newsession(&sid, (txform ? &crie : &cria), 1437 1.34.6.3 mjf crypto_devallowsoft); 1438 1.34.6.3 mjf if (!error) { 1439 1.34.6.3 mjf cse = csecreate(fcr, sid, crie.cri_key, crie.cri_klen, 1440 1.34.6.3 mjf cria.cri_key, cria.cri_klen, sop->cipher, sop->mac, 1441 1.34.6.3 mjf txform, thash); 1442 1.34.6.3 mjf if (cse != NULL) { 1443 1.34.6.3 mjf sop->ses = cse->ses; 1444 1.34.6.3 mjf } else { 1445 1.34.6.3 mjf DPRINTF(("csecreate failed\n")); 1446 1.34.6.3 mjf crypto_freesession(sid); 1447 1.34.6.3 mjf error = EINVAL; 1448 1.34.6.3 mjf } 1449 1.34.6.3 mjf } else { 1450 1.34.6.3 mjf DPRINTF(("SIOCSESSION violates kernel parameters %d\n", 1451 1.34.6.3 mjf error)); 1452 1.34.6.3 mjf } 1453 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1454 1.34.6.3 mjf bail: 1455 1.34.6.3 mjf if (error) { 1456 1.34.6.3 mjf if (crie.cri_key) { 1457 1.34.6.3 mjf memset(crie.cri_key, 0, crie.cri_klen / 8); 1458 1.34.6.3 mjf free(crie.cri_key, M_XDATA); 1459 1.34.6.3 mjf } 1460 1.34.6.3 mjf if (cria.cri_key) { 1461 1.34.6.3 mjf memset(cria.cri_key, 0, cria.cri_klen / 8); 1462 1.34.6.3 mjf free(cria.cri_key, M_XDATA); 1463 1.34.6.3 mjf } 1464 1.34.6.3 mjf } 1465 1.34.6.3 mjf return error; 1466 1.34.6.3 mjf } 1467 1.34.6.3 mjf 1468 1.34.6.3 mjf static int 1469 1.34.6.3 mjf cryptodev_msession(struct fcrypt *fcr, struct session_n_op *sn_ops, 1470 1.34.6.3 mjf int count) 1471 1.34.6.3 mjf { 1472 1.34.6.3 mjf int i; 1473 1.34.6.3 mjf 1474 1.34.6.3 mjf for (i = 0; i < count; i++, sn_ops++) { 1475 1.34.6.3 mjf struct session_op s_op; 1476 1.34.6.3 mjf s_op.cipher = sn_ops->cipher; 1477 1.34.6.3 mjf s_op.mac = sn_ops->mac; 1478 1.34.6.3 mjf s_op.keylen = sn_ops->keylen; 1479 1.34.6.3 mjf s_op.key = sn_ops->key; 1480 1.34.6.3 mjf s_op.mackeylen = sn_ops->mackeylen; 1481 1.34.6.3 mjf s_op.mackey = sn_ops->mackey; 1482 1.34.6.3 mjf 1483 1.34.6.3 mjf sn_ops->status = cryptodev_session(fcr, &s_op); 1484 1.34.6.3 mjf sn_ops->ses = s_op.ses; 1485 1.34.6.3 mjf } 1486 1.34.6.3 mjf 1487 1.34.6.3 mjf return 0; 1488 1.34.6.3 mjf } 1489 1.34.6.3 mjf 1490 1.34.6.3 mjf static int 1491 1.34.6.3 mjf cryptodev_msessionfin(struct fcrypt *fcr, int count, u_int32_t *sesid) 1492 1.34.6.3 mjf { 1493 1.34.6.3 mjf struct csession *cse; 1494 1.34.6.3 mjf int req, error = 0; 1495 1.34.6.3 mjf 1496 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 1497 1.34.6.3 mjf for(req = 0; req < count; req++) { 1498 1.34.6.3 mjf cse = csefind(fcr, sesid[req]); 1499 1.34.6.3 mjf if (cse == NULL) 1500 1.34.6.3 mjf continue; 1501 1.34.6.3 mjf csedelete(fcr, cse); 1502 1.34.6.3 mjf error = csefree(cse); 1503 1.34.6.3 mjf } 1504 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1505 1.34.6.3 mjf return 0; 1506 1.34.6.3 mjf } 1507 1.34.6.3 mjf 1508 1.34.6.3 mjf /* 1509 1.34.6.3 mjf * collect as many completed requests as are availble, or count completed 1510 1.34.6.3 mjf * requests whichever is less. 1511 1.34.6.3 mjf * return the number of requests. 1512 1.34.6.3 mjf */ 1513 1.34.6.3 mjf static int 1514 1.34.6.3 mjf cryptodev_getmstatus(struct fcrypt *fcr, struct crypt_result *crypt_res, 1515 1.34.6.3 mjf int count) 1516 1.34.6.3 mjf { 1517 1.34.6.3 mjf struct cryptop *crp = NULL; 1518 1.34.6.3 mjf struct cryptkop *krp = NULL; 1519 1.34.6.3 mjf struct csession *cse; 1520 1.34.6.3 mjf int i, size, req = 0; 1521 1.34.6.3 mjf int completed=0; 1522 1.34.6.3 mjf 1523 1.34.6.3 mjf /* On stack so nobody else can grab them -- no locking */ 1524 1.34.6.3 mjf SLIST_HEAD(, cryptop) crp_delfree_l = 1525 1.34.6.3 mjf SLIST_HEAD_INITIALIZER(crp_delfree_l); 1526 1.34.6.3 mjf SLIST_HEAD(, cryptkop) krp_delfree_l = 1527 1.34.6.3 mjf SLIST_HEAD_INITIALIZER(krp_delfree_l); 1528 1.34.6.3 mjf 1529 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 1530 1.34.6.3 mjf 1531 1.34.6.3 mjf /* at this point we do not know which response user is requesting for 1532 1.34.6.3 mjf * (symmetric or asymmetric) so we copyout one from each i.e if the 1533 1.34.6.3 mjf * count is 2 then 1 from symmetric and 1 from asymmetric queue and 1534 1.34.6.3 mjf * if 3 then 2 symmetric and 1 asymmetric and so on */ 1535 1.34.6.3 mjf for(; req < count ;) { 1536 1.34.6.3 mjf crp = TAILQ_FIRST(&fcr->crp_ret_mq); 1537 1.34.6.3 mjf if(crp) { 1538 1.34.6.3 mjf cse = (struct csession *)crp->crp_opaque; 1539 1.34.6.3 mjf crypt_res[req].reqid = crp->crp_reqid; 1540 1.34.6.3 mjf crypt_res[req].opaque = crp->crp_usropaque; 1541 1.34.6.3 mjf completed++; 1542 1.34.6.3 mjf cse = csefind(fcr, cse->ses); 1543 1.34.6.3 mjf if (cse == NULL) { 1544 1.34.6.3 mjf DPRINTF(("csefind failed\n")); 1545 1.34.6.3 mjf crypt_res[req].status = EINVAL; 1546 1.34.6.3 mjf goto bail; 1547 1.34.6.3 mjf } 1548 1.34.6.3 mjf 1549 1.34.6.3 mjf if (crp->crp_etype != 0) { 1550 1.34.6.3 mjf crypt_res[req].status = crp->crp_etype; 1551 1.34.6.3 mjf goto bail; 1552 1.34.6.3 mjf } 1553 1.34.6.3 mjf 1554 1.34.6.3 mjf if (cse->error) { 1555 1.34.6.3 mjf crypt_res[req].status = cse->error; 1556 1.34.6.3 mjf goto bail; 1557 1.34.6.3 mjf } 1558 1.34.6.3 mjf 1559 1.34.6.3 mjf if (crp->dst && (crypt_res[req].status = 1560 1.34.6.3 mjf copyout(crp->uio.uio_iov[0].iov_base, crp->dst, 1561 1.34.6.3 mjf crp->len))) 1562 1.34.6.3 mjf goto bail; 1563 1.34.6.3 mjf 1564 1.34.6.3 mjf if (crp->mac && (crypt_res[req].status = 1565 1.34.6.3 mjf copyout(crp->crp_mac, crp->mac, 1566 1.34.6.3 mjf cse->thash->authsize))) 1567 1.34.6.3 mjf goto bail; 1568 1.34.6.3 mjf bail: 1569 1.34.6.3 mjf TAILQ_REMOVE(&fcr->crp_ret_mq, crp, crp_next); 1570 1.34.6.3 mjf SLIST_INSERT_HEAD(&crp_delfree_l, crp, 1571 1.34.6.3 mjf crp_qun.crp_lnext); 1572 1.34.6.3 mjf req++; 1573 1.34.6.3 mjf } 1574 1.34.6.3 mjf 1575 1.34.6.3 mjf if(req < count) { 1576 1.34.6.3 mjf krp = TAILQ_FIRST(&fcr->crp_ret_mkq); 1577 1.34.6.3 mjf if (krp) { 1578 1.34.6.3 mjf crypt_res[req].reqid = krp->krp_reqid; 1579 1.34.6.3 mjf crypt_res[req].opaque = krp->krp_usropaque; 1580 1.34.6.3 mjf completed++; 1581 1.34.6.3 mjf if (krp->krp_status != 0) { 1582 1.34.6.3 mjf DPRINTF(("cryptodev_key: " 1583 1.34.6.3 mjf "krp->krp_status 0x%08x\n", 1584 1.34.6.3 mjf krp->krp_status)); 1585 1.34.6.3 mjf crypt_res[req].status = krp->krp_status; 1586 1.34.6.3 mjf goto fail; 1587 1.34.6.3 mjf } 1588 1.34.6.3 mjf 1589 1.34.6.3 mjf for (i = krp->krp_iparams; i < krp->krp_iparams 1590 1.34.6.3 mjf + krp->krp_oparams; i++) { 1591 1.34.6.3 mjf size = (krp->krp_param[i].crp_nbits 1592 1.34.6.3 mjf + 7) / 8; 1593 1.34.6.3 mjf if (size == 0) 1594 1.34.6.3 mjf continue; 1595 1.34.6.3 mjf crypt_res[req].status = copyout 1596 1.34.6.3 mjf (krp->krp_param[i].crp_p, 1597 1.34.6.3 mjf krp->crk_param[i].crp_p, size); 1598 1.34.6.3 mjf if (crypt_res[req].status) { 1599 1.34.6.3 mjf DPRINTF(("cryptodev_key: " 1600 1.34.6.3 mjf "copyout oparam %d failed, " 1601 1.34.6.3 mjf "error=%d\n", 1602 1.34.6.3 mjf i - krp->krp_iparams, 1603 1.34.6.3 mjf crypt_res[req].status)); 1604 1.34.6.3 mjf goto fail; 1605 1.34.6.3 mjf } 1606 1.34.6.3 mjf } 1607 1.34.6.3 mjf fail: 1608 1.34.6.3 mjf TAILQ_REMOVE(&fcr->crp_ret_mkq, krp, krp_next); 1609 1.34.6.3 mjf /* not sure what to do for this */ 1610 1.34.6.3 mjf /* kop[req].crk_status = krp->krp_status; */ 1611 1.34.6.3 mjf SLIST_INSERT_HEAD(&krp_delfree_l, krp, 1612 1.34.6.3 mjf krp_qun.krp_lnext); 1613 1.34.6.3 mjf } 1614 1.34.6.3 mjf req++; 1615 1.34.6.3 mjf } 1616 1.34.6.3 mjf } 1617 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1618 1.34.6.3 mjf 1619 1.34.6.3 mjf while(!SLIST_EMPTY(&crp_delfree_l)) { 1620 1.34.6.3 mjf crp = SLIST_FIRST(&crp_delfree_l); 1621 1.34.6.3 mjf SLIST_REMOVE_HEAD(&crp_delfree_l, crp_qun.crp_lnext); 1622 1.34.6.3 mjf kmem_free(crp->uio.uio_iov[0].iov_base, 1623 1.34.6.3 mjf crp->uio.uio_iov[0].iov_len); 1624 1.34.6.3 mjf crypto_freereq(crp); 1625 1.34.6.3 mjf } 1626 1.34.6.3 mjf 1627 1.34.6.3 mjf while(!SLIST_EMPTY(&krp_delfree_l)) { 1628 1.34.6.3 mjf krp = SLIST_FIRST(&krp_delfree_l); 1629 1.34.6.3 mjf for (i = 0; i < CRK_MAXPARAM; i++) { 1630 1.34.6.3 mjf struct crparam *kp = &(krp->krp_param[i]); 1631 1.34.6.3 mjf if (kp->crp_p) { 1632 1.34.6.3 mjf size = (kp->crp_nbits + 7) / 8; 1633 1.34.6.3 mjf KASSERT(size > 0); 1634 1.34.6.3 mjf (void)memset(kp->crp_p, 0, size); 1635 1.34.6.3 mjf kmem_free(kp->crp_p, size); 1636 1.34.6.3 mjf } 1637 1.34.6.3 mjf } 1638 1.34.6.3 mjf SLIST_REMOVE_HEAD(&krp_delfree_l, krp_qun.krp_lnext); 1639 1.34.6.4 mjf cv_destroy(&krp->krp_cv); 1640 1.34.6.3 mjf pool_put(&cryptkop_pool, krp); 1641 1.34.6.3 mjf } 1642 1.34.6.3 mjf return completed; 1643 1.34.6.3 mjf } 1644 1.34.6.3 mjf 1645 1.34.6.3 mjf static int 1646 1.34.6.3 mjf cryptodev_getstatus (struct fcrypt *fcr, struct crypt_result *crypt_res) 1647 1.34.6.3 mjf { 1648 1.34.6.4 mjf struct cryptop *crp = NULL, *cnext; 1649 1.34.6.4 mjf struct cryptkop *krp = NULL, *knext; 1650 1.34.6.3 mjf struct csession *cse; 1651 1.34.6.3 mjf int i, size, req = 0; 1652 1.34.6.3 mjf 1653 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 1654 1.34.6.3 mjf /* Here we dont know for which request the user is requesting the 1655 1.34.6.3 mjf * response so checking in both the queues */ 1656 1.34.6.4 mjf TAILQ_FOREACH_SAFE(crp, &fcr->crp_ret_mq, crp_next, cnext) { 1657 1.34.6.3 mjf if(crp && (crp->crp_reqid == crypt_res->reqid)) { 1658 1.34.6.3 mjf cse = (struct csession *)crp->crp_opaque; 1659 1.34.6.3 mjf crypt_res->opaque = crp->crp_usropaque; 1660 1.34.6.3 mjf cse = csefind(fcr, cse->ses); 1661 1.34.6.3 mjf if (cse == NULL) { 1662 1.34.6.3 mjf DPRINTF(("csefind failed\n")); 1663 1.34.6.3 mjf crypt_res->status = EINVAL; 1664 1.34.6.3 mjf goto bail; 1665 1.34.6.3 mjf } 1666 1.34.6.3 mjf 1667 1.34.6.3 mjf if (crp->crp_etype != 0) { 1668 1.34.6.3 mjf crypt_res->status = crp->crp_etype; 1669 1.34.6.3 mjf goto bail; 1670 1.34.6.3 mjf } 1671 1.34.6.3 mjf 1672 1.34.6.3 mjf if (cse->error) { 1673 1.34.6.3 mjf crypt_res->status = cse->error; 1674 1.34.6.3 mjf goto bail; 1675 1.34.6.3 mjf } 1676 1.34.6.3 mjf 1677 1.34.6.3 mjf if (crp->dst && (crypt_res->status = 1678 1.34.6.3 mjf copyout(crp->uio.uio_iov[0].iov_base, 1679 1.34.6.3 mjf crp->dst, crp->len))) 1680 1.34.6.3 mjf goto bail; 1681 1.34.6.3 mjf 1682 1.34.6.3 mjf if (crp->mac && (crypt_res->status = 1683 1.34.6.3 mjf copyout(crp->crp_mac, crp->mac, 1684 1.34.6.3 mjf cse->thash->authsize))) 1685 1.34.6.3 mjf goto bail; 1686 1.34.6.3 mjf bail: 1687 1.34.6.3 mjf TAILQ_REMOVE(&fcr->crp_ret_mq, crp, crp_next); 1688 1.34.6.3 mjf 1689 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1690 1.34.6.3 mjf crypto_freereq(crp); 1691 1.34.6.3 mjf return 0; 1692 1.34.6.3 mjf } 1693 1.34.6.3 mjf } 1694 1.34.6.3 mjf 1695 1.34.6.4 mjf TAILQ_FOREACH_SAFE(krp, &fcr->crp_ret_mkq, krp_next, knext) { 1696 1.34.6.3 mjf if(krp && (krp->krp_reqid == crypt_res->reqid)) { 1697 1.34.6.3 mjf crypt_res[req].opaque = krp->krp_usropaque; 1698 1.34.6.3 mjf if (krp->krp_status != 0) { 1699 1.34.6.3 mjf DPRINTF(("cryptodev_key: " 1700 1.34.6.3 mjf "krp->krp_status 0x%08x\n", 1701 1.34.6.3 mjf krp->krp_status)); 1702 1.34.6.3 mjf crypt_res[req].status = krp->krp_status; 1703 1.34.6.3 mjf goto fail; 1704 1.34.6.3 mjf } 1705 1.34.6.3 mjf 1706 1.34.6.3 mjf for (i = krp->krp_iparams; i < krp->krp_iparams + 1707 1.34.6.3 mjf krp->krp_oparams; i++) { 1708 1.34.6.3 mjf size = (krp->krp_param[i].crp_nbits + 7) / 8; 1709 1.34.6.3 mjf if (size == 0) 1710 1.34.6.3 mjf continue; 1711 1.34.6.3 mjf crypt_res[req].status = copyout( 1712 1.34.6.3 mjf krp->krp_param[i].crp_p, 1713 1.34.6.3 mjf krp->crk_param[i].crp_p, size); 1714 1.34.6.3 mjf if (crypt_res[req].status) { 1715 1.34.6.3 mjf DPRINTF(("cryptodev_key: copyout oparam" 1716 1.34.6.3 mjf "%d failed, error=%d\n", 1717 1.34.6.3 mjf i - krp->krp_iparams, 1718 1.34.6.3 mjf crypt_res[req].status)); 1719 1.34.6.3 mjf goto fail; 1720 1.34.6.3 mjf } 1721 1.34.6.3 mjf } 1722 1.34.6.3 mjf fail: 1723 1.34.6.3 mjf TAILQ_REMOVE(&fcr->crp_ret_mkq, krp, krp_next); 1724 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1725 1.34.6.3 mjf /* not sure what to do for this */ 1726 1.34.6.3 mjf /* kop[req].crk_status = krp->krp_status; */ 1727 1.34.6.3 mjf for (i = 0; i < CRK_MAXPARAM; i++) { 1728 1.34.6.3 mjf struct crparam *kp = &(krp->krp_param[i]); 1729 1.34.6.3 mjf if (kp->crp_p) { 1730 1.34.6.3 mjf size = (kp->crp_nbits + 7) / 8; 1731 1.34.6.3 mjf KASSERT(size > 0); 1732 1.34.6.3 mjf memset(kp->crp_p, 0, size); 1733 1.34.6.3 mjf kmem_free(kp->crp_p, size); 1734 1.34.6.3 mjf } 1735 1.34.6.3 mjf } 1736 1.34.6.4 mjf cv_destroy(&krp->krp_cv); 1737 1.34.6.3 mjf pool_put(&cryptkop_pool, krp); 1738 1.34.6.3 mjf return 0; 1739 1.34.6.3 mjf } 1740 1.34.6.3 mjf } 1741 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1742 1.34.6.3 mjf return EINPROGRESS; 1743 1.34.6.3 mjf } 1744 1.34.6.3 mjf 1745 1.34.6.3 mjf static int 1746 1.34.6.3 mjf cryptof_poll(struct file *fp, int events) 1747 1.34.6.3 mjf { 1748 1.34.6.3 mjf struct fcrypt *fcr = (struct fcrypt *)fp->f_data; 1749 1.34.6.3 mjf int revents = 0; 1750 1.34.6.3 mjf 1751 1.34.6.3 mjf if (!(events & (POLLIN | POLLRDNORM))) { 1752 1.34.6.3 mjf /* only support read and POLLIN */ 1753 1.34.6.3 mjf return 0; 1754 1.34.6.3 mjf } 1755 1.34.6.3 mjf 1756 1.34.6.3 mjf mutex_spin_enter(&crypto_mtx); 1757 1.34.6.3 mjf if (TAILQ_EMPTY(&fcr->crp_ret_mq) && TAILQ_EMPTY(&fcr->crp_ret_mkq)) { 1758 1.34.6.3 mjf /* no completed requests pending, save the poll for later */ 1759 1.34.6.3 mjf selrecord(curlwp, &fcr->sinfo); 1760 1.34.6.3 mjf } else { 1761 1.34.6.3 mjf /* let the app(s) know that there are completed requests */ 1762 1.34.6.3 mjf revents = events & (POLLIN | POLLRDNORM); 1763 1.34.6.3 mjf } 1764 1.34.6.3 mjf mutex_spin_exit(&crypto_mtx); 1765 1.34.6.3 mjf 1766 1.34.6.3 mjf return revents; 1767 1.34.6.3 mjf } 1768 1.34.6.3 mjf 1769 1.15 thorpej /* 1770 1.15 thorpej * Pseudo-device initialization routine for /dev/crypto 1771 1.15 thorpej */ 1772 1.15 thorpej void cryptoattach(int); 1773 1.15 thorpej 1774 1.15 thorpej void 1775 1.25 christos cryptoattach(int num) 1776 1.15 thorpej { 1777 1.34.6.2 mjf int maj = cdevsw_lookup_major(&crypto_cdevsw); 1778 1.34.6.2 mjf 1779 1.29 tls pool_init(&fcrpl, sizeof(struct fcrypt), 0, 0, 0, "fcrpl", 1780 1.34.6.3 mjf NULL, IPL_NET); /* XXX IPL_NET ("splcrypto") */ 1781 1.29 tls pool_init(&csepl, sizeof(struct csession), 0, 0, 0, "csepl", 1782 1.34.6.3 mjf NULL, IPL_NET); /* XXX IPL_NET ("splcrypto") */ 1783 1.29 tls 1784 1.29 tls /* 1785 1.29 tls * Preallocate space for 64 users, with 5 sessions each. 1786 1.29 tls * (consider that a TLS protocol session requires at least 1787 1.29 tls * 3DES, MD5, and SHA1 (both hashes are used in the PRF) for 1788 1.29 tls * the negotiation, plus HMAC_SHA1 for the actual SSL records, 1789 1.29 tls * consuming one session here for each algorithm. 1790 1.29 tls */ 1791 1.29 tls pool_prime(&fcrpl, 64); 1792 1.29 tls pool_prime(&csepl, 64 * 5); 1793 1.34.6.2 mjf 1794 1.34.6.2 mjf device_register_name(makedev(maj, 0), NULL, true, DEV_OTHER, "crypto"); 1795 1.15 thorpej } 1796
Indexes created Thu Oct 02 14:10:14 GMT 2025