freebsd-skq/sys/opencrypto/crypto.c
John Baldwin 9c0e3d3a53 Add support for optional separate output buffers to in-kernel crypto.
Some crypto consumers such as GELI and KTLS for file-backed sendfile
need to store their output in a separate buffer from the input.
Currently these consumers copy the contents of the input buffer into
the output buffer and queue an in-place crypto operation on the output
buffer.  Using a separate output buffer avoids this copy.

- Create a new 'struct crypto_buffer' describing a crypto buffer
  containing a type and type-specific fields.  crp_ilen is gone,
  instead buffers that use a flat kernel buffer have a cb_buf_len
  field for their length.  The length of other buffer types is
  inferred from the backing store (e.g. uio_resid for a uio).
  Requests now have two such structures: crp_buf for the input buffer,
  and crp_obuf for the output buffer.

- Consumers now use helper functions (crypto_use_*,
  e.g. crypto_use_mbuf()) to configure the input buffer.  If an output
  buffer is not configured, the request still modifies the input
  buffer in-place.  A consumer uses a second set of helper functions
  (crypto_use_output_*) to configure an output buffer.

- Consumers must request support for separate output buffers when
  creating a crypto session via the CSP_F_SEPARATE_OUTPUT flag and are
  only permitted to queue a request with a separate output buffer on
  sessions with this flag set.  Existing drivers already reject
  sessions with unknown flags, so this permits drivers to be modified
  to support this extension without requiring all drivers to change.

- Several data-related functions now have matching versions that
  operate on an explicit buffer (e.g. crypto_apply_buf,
  crypto_contiguous_subsegment_buf, bus_dma_load_crp_buf).

- Most of the existing data-related functions operate on the input
  buffer.  However crypto_copyback always writes to the output buffer
  if a request uses a separate output buffer.

- For the regions in input/output buffers, the following conventions
  are followed:
  - AAD and IV are always present in input only and their
    fields are offsets into the input buffer.
  - payload is always present in both buffers.  If a request uses a
    separate output buffer, it must set a new crp_payload_start_output
    field to the offset of the payload in the output buffer.
  - digest is in the input buffer for verify operations, and in the
    output buffer for compute operations.  crp_digest_start is relative
    to the appropriate buffer.

- Add a crypto buffer cursor abstraction.  This is a more general form
  of some bits in the cryptosoft driver that tried to always use uio's.
  However, compared to the original code, this avoids rewalking the uio
  iovec array for requests with multiple vectors.  It also avoids
  allocate an iovec array for mbufs and populating it by instead walking
  the mbuf chain directly.

- Update the cryptosoft(4) driver to support separate output buffers
  making use of the cursor abstraction.

Sponsored by:	Netflix
Differential Revision:	https://reviews.freebsd.org/D24545
2020-05-25 22:12:04 +00:00

2298 lines
58 KiB
C

/*-
* Copyright (c) 2002-2006 Sam Leffler. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/*
* Cryptographic Subsystem.
*
* This code is derived from the Openbsd Cryptographic Framework (OCF)
* that has the copyright shown below. Very little of the original
* code remains.
*/
/*-
* The author of this code is Angelos D. Keromytis (angelos@cis.upenn.edu)
*
* This code was written by Angelos D. Keromytis in Athens, Greece, in
* February 2000. Network Security Technologies Inc. (NSTI) kindly
* supported the development of this code.
*
* Copyright (c) 2000, 2001 Angelos D. Keromytis
*
* Permission to use, copy, and modify this software with or without fee
* is hereby granted, provided that this entire notice is included in
* all source code copies of any software which is or includes a copy or
* modification of this software.
*
* THIS SOFTWARE IS BEING PROVIDED "AS IS", WITHOUT ANY EXPRESS OR
* IMPLIED WARRANTY. IN PARTICULAR, NONE OF THE AUTHORS MAKES ANY
* REPRESENTATION OR WARRANTY OF ANY KIND CONCERNING THE
* MERCHANTABILITY OF THIS SOFTWARE OR ITS FITNESS FOR ANY PARTICULAR
* PURPOSE.
*/
#define CRYPTO_TIMING /* enable timing support */
#include "opt_compat.h"
#include "opt_ddb.h"
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/eventhandler.h>
#include <sys/kernel.h>
#include <sys/kthread.h>
#include <sys/linker.h>
#include <sys/lock.h>
#include <sys/module.h>
#include <sys/mutex.h>
#include <sys/malloc.h>
#include <sys/mbuf.h>
#include <sys/proc.h>
#include <sys/refcount.h>
#include <sys/sdt.h>
#include <sys/smp.h>
#include <sys/sysctl.h>
#include <sys/taskqueue.h>
#include <sys/uio.h>
#include <ddb/ddb.h>
#include <vm/uma.h>
#include <crypto/intake.h>
#include <opencrypto/cryptodev.h>
#include <opencrypto/xform_auth.h>
#include <opencrypto/xform_enc.h>
#include <sys/kobj.h>
#include <sys/bus.h>
#include "cryptodev_if.h"
#if defined(__i386__) || defined(__amd64__) || defined(__aarch64__)
#include <machine/pcb.h>
#endif
SDT_PROVIDER_DEFINE(opencrypto);
/*
* Crypto drivers register themselves by allocating a slot in the
* crypto_drivers table with crypto_get_driverid() and then registering
* each asym algorithm they support with crypto_kregister().
*/
static struct mtx crypto_drivers_mtx; /* lock on driver table */
#define CRYPTO_DRIVER_LOCK() mtx_lock(&crypto_drivers_mtx)
#define CRYPTO_DRIVER_UNLOCK() mtx_unlock(&crypto_drivers_mtx)
#define CRYPTO_DRIVER_ASSERT() mtx_assert(&crypto_drivers_mtx, MA_OWNED)
/*
* Crypto device/driver capabilities structure.
*
* Synchronization:
* (d) - protected by CRYPTO_DRIVER_LOCK()
* (q) - protected by CRYPTO_Q_LOCK()
* Not tagged fields are read-only.
*/
struct cryptocap {
device_t cc_dev;
uint32_t cc_hid;
u_int32_t cc_sessions; /* (d) # of sessions */
u_int32_t cc_koperations; /* (d) # os asym operations */
u_int8_t cc_kalg[CRK_ALGORITHM_MAX + 1];
int cc_flags; /* (d) flags */
#define CRYPTOCAP_F_CLEANUP 0x80000000 /* needs resource cleanup */
int cc_qblocked; /* (q) symmetric q blocked */
int cc_kqblocked; /* (q) asymmetric q blocked */
size_t cc_session_size;
volatile int cc_refs;
};
static struct cryptocap **crypto_drivers = NULL;
static int crypto_drivers_size = 0;
struct crypto_session {
struct cryptocap *cap;
void *softc;
struct crypto_session_params csp;
};
/*
* There are two queues for crypto requests; one for symmetric (e.g.
* cipher) operations and one for asymmetric (e.g. MOD)operations.
* A single mutex is used to lock access to both queues. We could
* have one per-queue but having one simplifies handling of block/unblock
* operations.
*/
static int crp_sleep = 0;
static TAILQ_HEAD(cryptop_q ,cryptop) crp_q; /* request queues */
static TAILQ_HEAD(,cryptkop) crp_kq;
static struct mtx crypto_q_mtx;
#define CRYPTO_Q_LOCK() mtx_lock(&crypto_q_mtx)
#define CRYPTO_Q_UNLOCK() mtx_unlock(&crypto_q_mtx)
static SYSCTL_NODE(_kern, OID_AUTO, crypto, CTLFLAG_RW, 0,
"In-kernel cryptography");
/*
* Taskqueue used to dispatch the crypto requests
* that have the CRYPTO_F_ASYNC flag
*/
static struct taskqueue *crypto_tq;
/*
* Crypto seq numbers are operated on with modular arithmetic
*/
#define CRYPTO_SEQ_GT(a,b) ((int)((a)-(b)) > 0)
struct crypto_ret_worker {
struct mtx crypto_ret_mtx;
TAILQ_HEAD(,cryptop) crp_ordered_ret_q; /* ordered callback queue for symetric jobs */
TAILQ_HEAD(,cryptop) crp_ret_q; /* callback queue for symetric jobs */
TAILQ_HEAD(,cryptkop) crp_ret_kq; /* callback queue for asym jobs */
u_int32_t reorder_ops; /* total ordered sym jobs received */
u_int32_t reorder_cur_seq; /* current sym job dispatched */
struct proc *cryptoretproc;
};
static struct crypto_ret_worker *crypto_ret_workers = NULL;
#define CRYPTO_RETW(i) (&crypto_ret_workers[i])
#define CRYPTO_RETW_ID(w) ((w) - crypto_ret_workers)
#define FOREACH_CRYPTO_RETW(w) \
for (w = crypto_ret_workers; w < crypto_ret_workers + crypto_workers_num; ++w)
#define CRYPTO_RETW_LOCK(w) mtx_lock(&w->crypto_ret_mtx)
#define CRYPTO_RETW_UNLOCK(w) mtx_unlock(&w->crypto_ret_mtx)
#define CRYPTO_RETW_EMPTY(w) \
(TAILQ_EMPTY(&w->crp_ret_q) && TAILQ_EMPTY(&w->crp_ret_kq) && TAILQ_EMPTY(&w->crp_ordered_ret_q))
static int crypto_workers_num = 0;
SYSCTL_INT(_kern_crypto, OID_AUTO, num_workers, CTLFLAG_RDTUN,
&crypto_workers_num, 0,
"Number of crypto workers used to dispatch crypto jobs");
#ifdef COMPAT_FREEBSD12
SYSCTL_INT(_kern, OID_AUTO, crypto_workers_num, CTLFLAG_RDTUN,
&crypto_workers_num, 0,
"Number of crypto workers used to dispatch crypto jobs");
#endif
static uma_zone_t cryptop_zone;
static uma_zone_t cryptoses_zone;
int crypto_userasymcrypto = 1;
SYSCTL_INT(_kern_crypto, OID_AUTO, asym_enable, CTLFLAG_RW,
&crypto_userasymcrypto, 0,
"Enable user-mode access to asymmetric crypto support");
#ifdef COMPAT_FREEBSD12
SYSCTL_INT(_kern, OID_AUTO, userasymcrypto, CTLFLAG_RW,
&crypto_userasymcrypto, 0,
"Enable/disable user-mode access to asymmetric crypto support");
#endif
int crypto_devallowsoft = 0;
SYSCTL_INT(_kern_crypto, OID_AUTO, allow_soft, CTLFLAG_RW,
&crypto_devallowsoft, 0,
"Enable use of software crypto by /dev/crypto");
#ifdef COMPAT_FREEBSD12
SYSCTL_INT(_kern, OID_AUTO, cryptodevallowsoft, CTLFLAG_RW,
&crypto_devallowsoft, 0,
"Enable/disable use of software crypto by /dev/crypto");
#endif
MALLOC_DEFINE(M_CRYPTO_DATA, "crypto", "crypto session records");
static void crypto_proc(void);
static struct proc *cryptoproc;
static void crypto_ret_proc(struct crypto_ret_worker *ret_worker);
static void crypto_destroy(void);
static int crypto_invoke(struct cryptocap *cap, struct cryptop *crp, int hint);
static int crypto_kinvoke(struct cryptkop *krp);
static void crypto_task_invoke(void *ctx, int pending);
static void crypto_batch_enqueue(struct cryptop *crp);
static struct cryptostats cryptostats;
SYSCTL_STRUCT(_kern_crypto, OID_AUTO, stats, CTLFLAG_RW, &cryptostats,
cryptostats, "Crypto system statistics");
#ifdef CRYPTO_TIMING
static int crypto_timing = 0;
SYSCTL_INT(_debug, OID_AUTO, crypto_timing, CTLFLAG_RW,
&crypto_timing, 0, "Enable/disable crypto timing support");
#endif
/* Try to avoid directly exposing the key buffer as a symbol */
static struct keybuf *keybuf;
static struct keybuf empty_keybuf = {
.kb_nents = 0
};
/* Obtain the key buffer from boot metadata */
static void
keybuf_init(void)
{
caddr_t kmdp;
kmdp = preload_search_by_type("elf kernel");
if (kmdp == NULL)
kmdp = preload_search_by_type("elf64 kernel");
keybuf = (struct keybuf *)preload_search_info(kmdp,
MODINFO_METADATA | MODINFOMD_KEYBUF);
if (keybuf == NULL)
keybuf = &empty_keybuf;
}
/* It'd be nice if we could store these in some kind of secure memory... */
struct keybuf * get_keybuf(void) {
return (keybuf);
}
static struct cryptocap *
cap_ref(struct cryptocap *cap)
{
refcount_acquire(&cap->cc_refs);
return (cap);
}
static void
cap_rele(struct cryptocap *cap)
{
if (refcount_release(&cap->cc_refs) == 0)
return;
KASSERT(cap->cc_sessions == 0,
("freeing crypto driver with active sessions"));
KASSERT(cap->cc_koperations == 0,
("freeing crypto driver with active key operations"));
free(cap, M_CRYPTO_DATA);
}
static int
crypto_init(void)
{
struct crypto_ret_worker *ret_worker;
int error;
mtx_init(&crypto_drivers_mtx, "crypto", "crypto driver table",
MTX_DEF|MTX_QUIET);
TAILQ_INIT(&crp_q);
TAILQ_INIT(&crp_kq);
mtx_init(&crypto_q_mtx, "crypto", "crypto op queues", MTX_DEF);
cryptop_zone = uma_zcreate("cryptop", sizeof (struct cryptop),
0, 0, 0, 0,
UMA_ALIGN_PTR, UMA_ZONE_ZINIT);
cryptoses_zone = uma_zcreate("crypto_session",
sizeof(struct crypto_session), NULL, NULL, NULL, NULL,
UMA_ALIGN_PTR, UMA_ZONE_ZINIT);
if (cryptop_zone == NULL || cryptoses_zone == NULL) {
printf("crypto_init: cannot setup crypto zones\n");
error = ENOMEM;
goto bad;
}
crypto_drivers_size = CRYPTO_DRIVERS_INITIAL;
crypto_drivers = malloc(crypto_drivers_size *
sizeof(struct cryptocap), M_CRYPTO_DATA, M_NOWAIT | M_ZERO);
if (crypto_drivers == NULL) {
printf("crypto_init: cannot setup crypto drivers\n");
error = ENOMEM;
goto bad;
}
if (crypto_workers_num < 1 || crypto_workers_num > mp_ncpus)
crypto_workers_num = mp_ncpus;
crypto_tq = taskqueue_create("crypto", M_WAITOK|M_ZERO,
taskqueue_thread_enqueue, &crypto_tq);
if (crypto_tq == NULL) {
printf("crypto init: cannot setup crypto taskqueue\n");
error = ENOMEM;
goto bad;
}
taskqueue_start_threads(&crypto_tq, crypto_workers_num, PRI_MIN_KERN,
"crypto");
error = kproc_create((void (*)(void *)) crypto_proc, NULL,
&cryptoproc, 0, 0, "crypto");
if (error) {
printf("crypto_init: cannot start crypto thread; error %d",
error);
goto bad;
}
crypto_ret_workers = malloc(crypto_workers_num * sizeof(struct crypto_ret_worker),
M_CRYPTO_DATA, M_NOWAIT|M_ZERO);
if (crypto_ret_workers == NULL) {
error = ENOMEM;
printf("crypto_init: cannot allocate ret workers\n");
goto bad;
}
FOREACH_CRYPTO_RETW(ret_worker) {
TAILQ_INIT(&ret_worker->crp_ordered_ret_q);
TAILQ_INIT(&ret_worker->crp_ret_q);
TAILQ_INIT(&ret_worker->crp_ret_kq);
ret_worker->reorder_ops = 0;
ret_worker->reorder_cur_seq = 0;
mtx_init(&ret_worker->crypto_ret_mtx, "crypto", "crypto return queues", MTX_DEF);
error = kproc_create((void (*)(void *)) crypto_ret_proc, ret_worker,
&ret_worker->cryptoretproc, 0, 0, "crypto returns %td", CRYPTO_RETW_ID(ret_worker));
if (error) {
printf("crypto_init: cannot start cryptoret thread; error %d",
error);
goto bad;
}
}
keybuf_init();
return 0;
bad:
crypto_destroy();
return error;
}
/*
* Signal a crypto thread to terminate. We use the driver
* table lock to synchronize the sleep/wakeups so that we
* are sure the threads have terminated before we release
* the data structures they use. See crypto_finis below
* for the other half of this song-and-dance.
*/
static void
crypto_terminate(struct proc **pp, void *q)
{
struct proc *p;
mtx_assert(&crypto_drivers_mtx, MA_OWNED);
p = *pp;
*pp = NULL;
if (p) {
wakeup_one(q);
PROC_LOCK(p); /* NB: insure we don't miss wakeup */
CRYPTO_DRIVER_UNLOCK(); /* let crypto_finis progress */
msleep(p, &p->p_mtx, PWAIT, "crypto_destroy", 0);
PROC_UNLOCK(p);
CRYPTO_DRIVER_LOCK();
}
}
static void
hmac_init_pad(struct auth_hash *axf, const char *key, int klen, void *auth_ctx,
uint8_t padval)
{
uint8_t hmac_key[HMAC_MAX_BLOCK_LEN];
u_int i;
KASSERT(axf->blocksize <= sizeof(hmac_key),
("Invalid HMAC block size %d", axf->blocksize));
/*
* If the key is larger than the block size, use the digest of
* the key as the key instead.
*/
memset(hmac_key, 0, sizeof(hmac_key));
if (klen > axf->blocksize) {
axf->Init(auth_ctx);
axf->Update(auth_ctx, key, klen);
axf->Final(hmac_key, auth_ctx);
klen = axf->hashsize;
} else
memcpy(hmac_key, key, klen);
for (i = 0; i < axf->blocksize; i++)
hmac_key[i] ^= padval;
axf->Init(auth_ctx);
axf->Update(auth_ctx, hmac_key, axf->blocksize);
}
void
hmac_init_ipad(struct auth_hash *axf, const char *key, int klen,
void *auth_ctx)
{
hmac_init_pad(axf, key, klen, auth_ctx, HMAC_IPAD_VAL);
}
void
hmac_init_opad(struct auth_hash *axf, const char *key, int klen,
void *auth_ctx)
{
hmac_init_pad(axf, key, klen, auth_ctx, HMAC_OPAD_VAL);
}
static void
crypto_destroy(void)
{
struct crypto_ret_worker *ret_worker;
int i;
/*
* Terminate any crypto threads.
*/
if (crypto_tq != NULL)
taskqueue_drain_all(crypto_tq);
CRYPTO_DRIVER_LOCK();
crypto_terminate(&cryptoproc, &crp_q);
FOREACH_CRYPTO_RETW(ret_worker)
crypto_terminate(&ret_worker->cryptoretproc, &ret_worker->crp_ret_q);
CRYPTO_DRIVER_UNLOCK();
/* XXX flush queues??? */
/*
* Reclaim dynamically allocated resources.
*/
for (i = 0; i < crypto_drivers_size; i++) {
if (crypto_drivers[i] != NULL)
cap_rele(crypto_drivers[i]);
}
free(crypto_drivers, M_CRYPTO_DATA);
if (cryptoses_zone != NULL)
uma_zdestroy(cryptoses_zone);
if (cryptop_zone != NULL)
uma_zdestroy(cryptop_zone);
mtx_destroy(&crypto_q_mtx);
FOREACH_CRYPTO_RETW(ret_worker)
mtx_destroy(&ret_worker->crypto_ret_mtx);
free(crypto_ret_workers, M_CRYPTO_DATA);
if (crypto_tq != NULL)
taskqueue_free(crypto_tq);
mtx_destroy(&crypto_drivers_mtx);
}
uint32_t
crypto_ses2hid(crypto_session_t crypto_session)
{
return (crypto_session->cap->cc_hid);
}
uint32_t
crypto_ses2caps(crypto_session_t crypto_session)
{
return (crypto_session->cap->cc_flags & 0xff000000);
}
void *
crypto_get_driver_session(crypto_session_t crypto_session)
{
return (crypto_session->softc);
}
const struct crypto_session_params *
crypto_get_params(crypto_session_t crypto_session)
{
return (&crypto_session->csp);
}
struct auth_hash *
crypto_auth_hash(const struct crypto_session_params *csp)
{
switch (csp->csp_auth_alg) {
case CRYPTO_SHA1_HMAC:
return (&auth_hash_hmac_sha1);
case CRYPTO_SHA2_224_HMAC:
return (&auth_hash_hmac_sha2_224);
case CRYPTO_SHA2_256_HMAC:
return (&auth_hash_hmac_sha2_256);
case CRYPTO_SHA2_384_HMAC:
return (&auth_hash_hmac_sha2_384);
case CRYPTO_SHA2_512_HMAC:
return (&auth_hash_hmac_sha2_512);
case CRYPTO_NULL_HMAC:
return (&auth_hash_null);
case CRYPTO_RIPEMD160_HMAC:
return (&auth_hash_hmac_ripemd_160);
case CRYPTO_SHA1:
return (&auth_hash_sha1);
case CRYPTO_SHA2_224:
return (&auth_hash_sha2_224);
case CRYPTO_SHA2_256:
return (&auth_hash_sha2_256);
case CRYPTO_SHA2_384:
return (&auth_hash_sha2_384);
case CRYPTO_SHA2_512:
return (&auth_hash_sha2_512);
case CRYPTO_AES_NIST_GMAC:
switch (csp->csp_auth_klen) {
case 128 / 8:
return (&auth_hash_nist_gmac_aes_128);
case 192 / 8:
return (&auth_hash_nist_gmac_aes_192);
case 256 / 8:
return (&auth_hash_nist_gmac_aes_256);
default:
return (NULL);
}
case CRYPTO_BLAKE2B:
return (&auth_hash_blake2b);
case CRYPTO_BLAKE2S:
return (&auth_hash_blake2s);
case CRYPTO_POLY1305:
return (&auth_hash_poly1305);
case CRYPTO_AES_CCM_CBC_MAC:
switch (csp->csp_auth_klen) {
case 128 / 8:
return (&auth_hash_ccm_cbc_mac_128);
case 192 / 8:
return (&auth_hash_ccm_cbc_mac_192);
case 256 / 8:
return (&auth_hash_ccm_cbc_mac_256);
default:
return (NULL);
}
default:
return (NULL);
}
}
struct enc_xform *
crypto_cipher(const struct crypto_session_params *csp)
{
switch (csp->csp_cipher_alg) {
case CRYPTO_RIJNDAEL128_CBC:
return (&enc_xform_rijndael128);
case CRYPTO_AES_XTS:
return (&enc_xform_aes_xts);
case CRYPTO_AES_ICM:
return (&enc_xform_aes_icm);
case CRYPTO_AES_NIST_GCM_16:
return (&enc_xform_aes_nist_gcm);
case CRYPTO_CAMELLIA_CBC:
return (&enc_xform_camellia);
case CRYPTO_NULL_CBC:
return (&enc_xform_null);
case CRYPTO_CHACHA20:
return (&enc_xform_chacha20);
case CRYPTO_AES_CCM_16:
return (&enc_xform_ccm);
default:
return (NULL);
}
}
static struct cryptocap *
crypto_checkdriver(u_int32_t hid)
{
return (hid >= crypto_drivers_size ? NULL : crypto_drivers[hid]);
}
/*
* Select a driver for a new session that supports the specified
* algorithms and, optionally, is constrained according to the flags.
*/
static struct cryptocap *
crypto_select_driver(const struct crypto_session_params *csp, int flags)
{
struct cryptocap *cap, *best;
int best_match, error, hid;
CRYPTO_DRIVER_ASSERT();
best = NULL;
for (hid = 0; hid < crypto_drivers_size; hid++) {
/*
* If there is no driver for this slot, or the driver
* is not appropriate (hardware or software based on
* match), then skip.
*/
cap = crypto_drivers[hid];
if (cap == NULL ||
(cap->cc_flags & flags) == 0)
continue;
error = CRYPTODEV_PROBESESSION(cap->cc_dev, csp);
if (error >= 0)
continue;
/*
* Use the driver with the highest probe value.
* Hardware drivers use a higher probe value than
* software. In case of a tie, prefer the driver with
* the fewest active sessions.
*/
if (best == NULL || error > best_match ||
(error == best_match &&
cap->cc_sessions < best->cc_sessions)) {
best = cap;
best_match = error;
}
}
return best;
}
static enum alg_type {
ALG_NONE = 0,
ALG_CIPHER,
ALG_DIGEST,
ALG_KEYED_DIGEST,
ALG_COMPRESSION,
ALG_AEAD
} alg_types[] = {
[CRYPTO_SHA1_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_RIPEMD160_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_AES_CBC] = ALG_CIPHER,
[CRYPTO_SHA1] = ALG_DIGEST,
[CRYPTO_NULL_HMAC] = ALG_DIGEST,
[CRYPTO_NULL_CBC] = ALG_CIPHER,
[CRYPTO_DEFLATE_COMP] = ALG_COMPRESSION,
[CRYPTO_SHA2_256_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_SHA2_384_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_SHA2_512_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_CAMELLIA_CBC] = ALG_CIPHER,
[CRYPTO_AES_XTS] = ALG_CIPHER,
[CRYPTO_AES_ICM] = ALG_CIPHER,
[CRYPTO_AES_NIST_GMAC] = ALG_KEYED_DIGEST,
[CRYPTO_AES_NIST_GCM_16] = ALG_AEAD,
[CRYPTO_BLAKE2B] = ALG_KEYED_DIGEST,
[CRYPTO_BLAKE2S] = ALG_KEYED_DIGEST,
[CRYPTO_CHACHA20] = ALG_CIPHER,
[CRYPTO_SHA2_224_HMAC] = ALG_KEYED_DIGEST,
[CRYPTO_RIPEMD160] = ALG_DIGEST,
[CRYPTO_SHA2_224] = ALG_DIGEST,
[CRYPTO_SHA2_256] = ALG_DIGEST,
[CRYPTO_SHA2_384] = ALG_DIGEST,
[CRYPTO_SHA2_512] = ALG_DIGEST,
[CRYPTO_POLY1305] = ALG_KEYED_DIGEST,
[CRYPTO_AES_CCM_CBC_MAC] = ALG_KEYED_DIGEST,
[CRYPTO_AES_CCM_16] = ALG_AEAD,
};
static enum alg_type
alg_type(int alg)
{
if (alg < nitems(alg_types))
return (alg_types[alg]);
return (ALG_NONE);
}
static bool
alg_is_compression(int alg)
{
return (alg_type(alg) == ALG_COMPRESSION);
}
static bool
alg_is_cipher(int alg)
{
return (alg_type(alg) == ALG_CIPHER);
}
static bool
alg_is_digest(int alg)
{
return (alg_type(alg) == ALG_DIGEST ||
alg_type(alg) == ALG_KEYED_DIGEST);
}
static bool
alg_is_keyed_digest(int alg)
{
return (alg_type(alg) == ALG_KEYED_DIGEST);
}
static bool
alg_is_aead(int alg)
{
return (alg_type(alg) == ALG_AEAD);
}
/* Various sanity checks on crypto session parameters. */
static bool
check_csp(const struct crypto_session_params *csp)
{
struct auth_hash *axf;
/* Mode-independent checks. */
if ((csp->csp_flags & ~CSP_F_SEPARATE_OUTPUT) != 0)
return (false);
if (csp->csp_ivlen < 0 || csp->csp_cipher_klen < 0 ||
csp->csp_auth_klen < 0 || csp->csp_auth_mlen < 0)
return (false);
if (csp->csp_auth_key != NULL && csp->csp_auth_klen == 0)
return (false);
if (csp->csp_cipher_key != NULL && csp->csp_cipher_klen == 0)
return (false);
switch (csp->csp_mode) {
case CSP_MODE_COMPRESS:
if (!alg_is_compression(csp->csp_cipher_alg))
return (false);
if (csp->csp_flags & CSP_F_SEPARATE_OUTPUT)
return (false);
if (csp->csp_cipher_klen != 0 || csp->csp_ivlen != 0 ||
csp->csp_auth_alg != 0 || csp->csp_auth_klen != 0 ||
csp->csp_auth_mlen != 0)
return (false);
break;
case CSP_MODE_CIPHER:
if (!alg_is_cipher(csp->csp_cipher_alg))
return (false);
if (csp->csp_cipher_alg != CRYPTO_NULL_CBC) {
if (csp->csp_cipher_klen == 0)
return (false);
if (csp->csp_ivlen == 0)
return (false);
}
if (csp->csp_ivlen >= EALG_MAX_BLOCK_LEN)
return (false);
if (csp->csp_auth_alg != 0 || csp->csp_auth_klen != 0 ||
csp->csp_auth_mlen != 0)
return (false);
break;
case CSP_MODE_DIGEST:
if (csp->csp_cipher_alg != 0 || csp->csp_cipher_klen != 0)
return (false);
/* IV is optional for digests (e.g. GMAC). */
if (csp->csp_ivlen >= EALG_MAX_BLOCK_LEN)
return (false);
if (!alg_is_digest(csp->csp_auth_alg))
return (false);
/* Key is optional for BLAKE2 digests. */
if (csp->csp_auth_alg == CRYPTO_BLAKE2B ||
csp->csp_auth_alg == CRYPTO_BLAKE2S)
;
else if (alg_is_keyed_digest(csp->csp_auth_alg)) {
if (csp->csp_auth_klen == 0)
return (false);
} else {
if (csp->csp_auth_klen != 0)
return (false);
}
if (csp->csp_auth_mlen != 0) {
axf = crypto_auth_hash(csp);
if (axf == NULL || csp->csp_auth_mlen > axf->hashsize)
return (false);
}
break;
case CSP_MODE_AEAD:
if (!alg_is_aead(csp->csp_cipher_alg))
return (false);
if (csp->csp_cipher_klen == 0)
return (false);
if (csp->csp_ivlen == 0 ||
csp->csp_ivlen >= EALG_MAX_BLOCK_LEN)
return (false);
if (csp->csp_auth_alg != 0 || csp->csp_auth_klen != 0)
return (false);
/*
* XXX: Would be nice to have a better way to get this
* value.
*/
switch (csp->csp_cipher_alg) {
case CRYPTO_AES_NIST_GCM_16:
case CRYPTO_AES_CCM_16:
if (csp->csp_auth_mlen > 16)
return (false);
break;
}
break;
case CSP_MODE_ETA:
if (!alg_is_cipher(csp->csp_cipher_alg))
return (false);
if (csp->csp_cipher_alg != CRYPTO_NULL_CBC) {
if (csp->csp_cipher_klen == 0)
return (false);
if (csp->csp_ivlen == 0)
return (false);
}
if (csp->csp_ivlen >= EALG_MAX_BLOCK_LEN)
return (false);
if (!alg_is_digest(csp->csp_auth_alg))
return (false);
/* Key is optional for BLAKE2 digests. */
if (csp->csp_auth_alg == CRYPTO_BLAKE2B ||
csp->csp_auth_alg == CRYPTO_BLAKE2S)
;
else if (alg_is_keyed_digest(csp->csp_auth_alg)) {
if (csp->csp_auth_klen == 0)
return (false);
} else {
if (csp->csp_auth_klen != 0)
return (false);
}
if (csp->csp_auth_mlen != 0) {
axf = crypto_auth_hash(csp);
if (axf == NULL || csp->csp_auth_mlen > axf->hashsize)
return (false);
}
break;
default:
return (false);
}
return (true);
}
/*
* Delete a session after it has been detached from its driver.
*/
static void
crypto_deletesession(crypto_session_t cses)
{
struct cryptocap *cap;
cap = cses->cap;
explicit_bzero(cses->softc, cap->cc_session_size);
free(cses->softc, M_CRYPTO_DATA);
uma_zfree(cryptoses_zone, cses);
CRYPTO_DRIVER_LOCK();
cap->cc_sessions--;
if (cap->cc_sessions == 0 && cap->cc_flags & CRYPTOCAP_F_CLEANUP)
wakeup(cap);
CRYPTO_DRIVER_UNLOCK();
cap_rele(cap);
}
/*
* Create a new session. The crid argument specifies a crypto
* driver to use or constraints on a driver to select (hardware
* only, software only, either). Whatever driver is selected
* must be capable of the requested crypto algorithms.
*/
int
crypto_newsession(crypto_session_t *cses,
const struct crypto_session_params *csp, int crid)
{
crypto_session_t res;
struct cryptocap *cap;
int err;
if (!check_csp(csp))
return (EINVAL);
res = NULL;
CRYPTO_DRIVER_LOCK();
if ((crid & (CRYPTOCAP_F_HARDWARE | CRYPTOCAP_F_SOFTWARE)) == 0) {
/*
* Use specified driver; verify it is capable.
*/
cap = crypto_checkdriver(crid);
if (cap != NULL && CRYPTODEV_PROBESESSION(cap->cc_dev, csp) > 0)
cap = NULL;
} else {
/*
* No requested driver; select based on crid flags.
*/
cap = crypto_select_driver(csp, crid);
}
if (cap == NULL) {
CRYPTO_DRIVER_UNLOCK();
CRYPTDEB("no driver");
return (EOPNOTSUPP);
}
cap_ref(cap);
cap->cc_sessions++;
CRYPTO_DRIVER_UNLOCK();
res = uma_zalloc(cryptoses_zone, M_WAITOK | M_ZERO);
res->cap = cap;
res->softc = malloc(cap->cc_session_size, M_CRYPTO_DATA, M_WAITOK |
M_ZERO);
res->csp = *csp;
/* Call the driver initialization routine. */
err = CRYPTODEV_NEWSESSION(cap->cc_dev, res, csp);
if (err != 0) {
CRYPTDEB("dev newsession failed: %d", err);
crypto_deletesession(res);
return (err);
}
*cses = res;
return (0);
}
/*
* Delete an existing session (or a reserved session on an unregistered
* driver).
*/
void
crypto_freesession(crypto_session_t cses)
{
struct cryptocap *cap;
if (cses == NULL)
return;
cap = cses->cap;
/* Call the driver cleanup routine, if available. */
CRYPTODEV_FREESESSION(cap->cc_dev, cses);
crypto_deletesession(cses);
}
/*
* Return a new driver id. Registers a driver with the system so that
* it can be probed by subsequent sessions.
*/
int32_t
crypto_get_driverid(device_t dev, size_t sessionsize, int flags)
{
struct cryptocap *cap, **newdrv;
int i;
if ((flags & (CRYPTOCAP_F_HARDWARE | CRYPTOCAP_F_SOFTWARE)) == 0) {
device_printf(dev,
"no flags specified when registering driver\n");
return -1;
}
cap = malloc(sizeof(*cap), M_CRYPTO_DATA, M_WAITOK | M_ZERO);
cap->cc_dev = dev;
cap->cc_session_size = sessionsize;
cap->cc_flags = flags;
refcount_init(&cap->cc_refs, 1);
CRYPTO_DRIVER_LOCK();
for (;;) {
for (i = 0; i < crypto_drivers_size; i++) {
if (crypto_drivers[i] == NULL)
break;
}
if (i < crypto_drivers_size)
break;
/* Out of entries, allocate some more. */
if (2 * crypto_drivers_size <= crypto_drivers_size) {
CRYPTO_DRIVER_UNLOCK();
printf("crypto: driver count wraparound!\n");
cap_rele(cap);
return (-1);
}
CRYPTO_DRIVER_UNLOCK();
newdrv = malloc(2 * crypto_drivers_size *
sizeof(*crypto_drivers), M_CRYPTO_DATA, M_WAITOK | M_ZERO);
CRYPTO_DRIVER_LOCK();
memcpy(newdrv, crypto_drivers,
crypto_drivers_size * sizeof(*crypto_drivers));
crypto_drivers_size *= 2;
free(crypto_drivers, M_CRYPTO_DATA);
crypto_drivers = newdrv;
}
cap->cc_hid = i;
crypto_drivers[i] = cap;
CRYPTO_DRIVER_UNLOCK();
if (bootverbose)
printf("crypto: assign %s driver id %u, flags 0x%x\n",
device_get_nameunit(dev), i, flags);
return i;
}
/*
* Lookup a driver by name. We match against the full device
* name and unit, and against just the name. The latter gives
* us a simple widlcarding by device name. On success return the
* driver/hardware identifier; otherwise return -1.
*/
int
crypto_find_driver(const char *match)
{
struct cryptocap *cap;
int i, len = strlen(match);
CRYPTO_DRIVER_LOCK();
for (i = 0; i < crypto_drivers_size; i++) {
if (crypto_drivers[i] == NULL)
continue;
cap = crypto_drivers[i];
if (strncmp(match, device_get_nameunit(cap->cc_dev), len) == 0 ||
strncmp(match, device_get_name(cap->cc_dev), len) == 0) {
CRYPTO_DRIVER_UNLOCK();
return (i);
}
}
CRYPTO_DRIVER_UNLOCK();
return (-1);
}
/*
* Return the device_t for the specified driver or NULL
* if the driver identifier is invalid.
*/
device_t
crypto_find_device_byhid(int hid)
{
struct cryptocap *cap;
device_t dev;
dev = NULL;
CRYPTO_DRIVER_LOCK();
cap = crypto_checkdriver(hid);
if (cap != NULL)
dev = cap->cc_dev;
CRYPTO_DRIVER_UNLOCK();
return (dev);
}
/*
* Return the device/driver capabilities.
*/
int
crypto_getcaps(int hid)
{
struct cryptocap *cap;
int flags;
flags = 0;
CRYPTO_DRIVER_LOCK();
cap = crypto_checkdriver(hid);
if (cap != NULL)
flags = cap->cc_flags;
CRYPTO_DRIVER_UNLOCK();
return (flags);
}
/*
* Register support for a key-related algorithm. This routine
* is called once for each algorithm supported a driver.
*/
int
crypto_kregister(u_int32_t driverid, int kalg, u_int32_t flags)
{
struct cryptocap *cap;
int err;
CRYPTO_DRIVER_LOCK();
cap = crypto_checkdriver(driverid);
if (cap != NULL &&
(CRK_ALGORITM_MIN <= kalg && kalg <= CRK_ALGORITHM_MAX)) {
/*
* XXX Do some performance testing to determine placing.
* XXX We probably need an auxiliary data structure that
* XXX describes relative performances.
*/
cap->cc_kalg[kalg] = flags | CRYPTO_ALG_FLAG_SUPPORTED;
if (bootverbose)
printf("crypto: %s registers key alg %u flags %u\n"
, device_get_nameunit(cap->cc_dev)
, kalg
, flags
);
err = 0;
} else
err = EINVAL;
CRYPTO_DRIVER_UNLOCK();
return err;
}
/*
* Unregister all algorithms associated with a crypto driver.
* If there are pending sessions using it, leave enough information
* around so that subsequent calls using those sessions will
* correctly detect the driver has been unregistered and reroute
* requests.
*/
int
crypto_unregister_all(u_int32_t driverid)
{
struct cryptocap *cap;
CRYPTO_DRIVER_LOCK();
cap = crypto_checkdriver(driverid);
if (cap == NULL) {
CRYPTO_DRIVER_UNLOCK();
return (EINVAL);
}
cap->cc_flags |= CRYPTOCAP_F_CLEANUP;
crypto_drivers[driverid] = NULL;
/*
* XXX: This doesn't do anything to kick sessions that
* have no pending operations.
*/
while (cap->cc_sessions != 0 || cap->cc_koperations != 0)
mtx_sleep(cap, &crypto_drivers_mtx, 0, "cryunreg", 0);
CRYPTO_DRIVER_UNLOCK();
cap_rele(cap);
return (0);
}
/*
* Clear blockage on a driver. The what parameter indicates whether
* the driver is now ready for cryptop's and/or cryptokop's.
*/
int
crypto_unblock(u_int32_t driverid, int what)
{
struct cryptocap *cap;
int err;
CRYPTO_Q_LOCK();
cap = crypto_checkdriver(driverid);
if (cap != NULL) {
if (what & CRYPTO_SYMQ)
cap->cc_qblocked = 0;
if (what & CRYPTO_ASYMQ)
cap->cc_kqblocked = 0;
if (crp_sleep)
wakeup_one(&crp_q);
err = 0;
} else
err = EINVAL;
CRYPTO_Q_UNLOCK();
return err;
}
size_t
crypto_buffer_len(struct crypto_buffer *cb)
{
switch (cb->cb_type) {
case CRYPTO_BUF_CONTIG:
return (cb->cb_buf_len);
case CRYPTO_BUF_MBUF:
if (cb->cb_mbuf->m_flags & M_PKTHDR)
return (cb->cb_mbuf->m_pkthdr.len);
return (m_length(cb->cb_mbuf, NULL));
case CRYPTO_BUF_UIO:
return (cb->cb_uio->uio_resid);
default:
return (0);
}
}
#ifdef INVARIANTS
/* Various sanity checks on crypto requests. */
static void
cb_sanity(struct crypto_buffer *cb, const char *name)
{
KASSERT(cb->cb_type > CRYPTO_BUF_NONE && cb->cb_type <= CRYPTO_BUF_LAST,
("incoming crp with invalid %s buffer type", name));
if (cb->cb_type == CRYPTO_BUF_CONTIG)
KASSERT(cb->cb_buf_len >= 0,
("incoming crp with -ve %s buffer length", name));
}
static void
crp_sanity(struct cryptop *crp)
{
struct crypto_session_params *csp;
struct crypto_buffer *out;
size_t ilen, len, olen;
KASSERT(crp->crp_session != NULL, ("incoming crp without a session"));
KASSERT(crp->crp_obuf.cb_type >= CRYPTO_BUF_NONE &&
crp->crp_obuf.cb_type <= CRYPTO_BUF_LAST,
("incoming crp with invalid output buffer type"));
KASSERT(crp->crp_etype == 0, ("incoming crp with error"));
KASSERT(!(crp->crp_flags & CRYPTO_F_DONE),
("incoming crp already done"));
csp = &crp->crp_session->csp;
cb_sanity(&crp->crp_buf, "input");
ilen = crypto_buffer_len(&crp->crp_buf);
olen = ilen;
out = NULL;
if (csp->csp_flags & CSP_F_SEPARATE_OUTPUT) {
if (crp->crp_obuf.cb_type != CRYPTO_BUF_NONE) {
cb_sanity(&crp->crp_obuf, "output");
out = &crp->crp_obuf;
olen = crypto_buffer_len(out);
}
} else
KASSERT(crp->crp_obuf.cb_type == CRYPTO_BUF_NONE,
("incoming crp with separate output buffer "
"but no session support"));
switch (csp->csp_mode) {
case CSP_MODE_COMPRESS:
KASSERT(crp->crp_op == CRYPTO_OP_COMPRESS ||
crp->crp_op == CRYPTO_OP_DECOMPRESS,
("invalid compression op %x", crp->crp_op));
break;
case CSP_MODE_CIPHER:
KASSERT(crp->crp_op == CRYPTO_OP_ENCRYPT ||
crp->crp_op == CRYPTO_OP_DECRYPT,
("invalid cipher op %x", crp->crp_op));
break;
case CSP_MODE_DIGEST:
KASSERT(crp->crp_op == CRYPTO_OP_COMPUTE_DIGEST ||
crp->crp_op == CRYPTO_OP_VERIFY_DIGEST,
("invalid digest op %x", crp->crp_op));
break;
case CSP_MODE_AEAD:
KASSERT(crp->crp_op ==
(CRYPTO_OP_ENCRYPT | CRYPTO_OP_COMPUTE_DIGEST) ||
crp->crp_op ==
(CRYPTO_OP_DECRYPT | CRYPTO_OP_VERIFY_DIGEST),
("invalid AEAD op %x", crp->crp_op));
if (csp->csp_cipher_alg == CRYPTO_AES_NIST_GCM_16)
KASSERT(crp->crp_flags & CRYPTO_F_IV_SEPARATE,
("GCM without a separate IV"));
if (csp->csp_cipher_alg == CRYPTO_AES_CCM_16)
KASSERT(crp->crp_flags & CRYPTO_F_IV_SEPARATE,
("CCM without a separate IV"));
break;
case CSP_MODE_ETA:
KASSERT(crp->crp_op ==
(CRYPTO_OP_ENCRYPT | CRYPTO_OP_COMPUTE_DIGEST) ||
crp->crp_op ==
(CRYPTO_OP_DECRYPT | CRYPTO_OP_VERIFY_DIGEST),
("invalid ETA op %x", crp->crp_op));
break;
}
if (csp->csp_mode == CSP_MODE_AEAD || csp->csp_mode == CSP_MODE_ETA) {
KASSERT(crp->crp_aad_start == 0 ||
crp->crp_aad_start < ilen,
("invalid AAD start"));
KASSERT(crp->crp_aad_length != 0 || crp->crp_aad_start == 0,
("AAD with zero length and non-zero start"));
KASSERT(crp->crp_aad_length == 0 ||
crp->crp_aad_start + crp->crp_aad_length <= ilen,
("AAD outside input length"));
} else {
KASSERT(crp->crp_aad_start == 0 && crp->crp_aad_length == 0,
("AAD region in request not supporting AAD"));
}
if (csp->csp_ivlen == 0) {
KASSERT((crp->crp_flags & CRYPTO_F_IV_SEPARATE) == 0,
("IV_SEPARATE set when IV isn't used"));
KASSERT(crp->crp_iv_start == 0,
("crp_iv_start set when IV isn't used"));
} else if (crp->crp_flags & CRYPTO_F_IV_SEPARATE) {
KASSERT(crp->crp_iv_start == 0,
("IV_SEPARATE used with non-zero IV start"));
} else {
KASSERT(crp->crp_iv_start < ilen,
("invalid IV start"));
KASSERT(crp->crp_iv_start + csp->csp_ivlen <= ilen,
("IV outside buffer length"));
}
/* XXX: payload_start of 0 should always be < ilen? */
KASSERT(crp->crp_payload_start == 0 ||
crp->crp_payload_start < ilen,
("invalid payload start"));
KASSERT(crp->crp_payload_start + crp->crp_payload_length <=
ilen, ("payload outside input buffer"));
if (out == NULL) {
KASSERT(crp->crp_payload_output_start == 0,
("payload output start non-zero without output buffer"));
} else {
KASSERT(crp->crp_payload_output_start < olen,
("invalid payload output start"));
KASSERT(crp->crp_payload_output_start +
crp->crp_payload_length <= olen,
("payload outside output buffer"));
}
if (csp->csp_mode == CSP_MODE_DIGEST ||
csp->csp_mode == CSP_MODE_AEAD || csp->csp_mode == CSP_MODE_ETA) {
if (crp->crp_op & CRYPTO_OP_VERIFY_DIGEST)
len = ilen;
else
len = olen;
KASSERT(crp->crp_digest_start == 0 ||
crp->crp_digest_start < len,
("invalid digest start"));
/* XXX: For the mlen == 0 case this check isn't perfect. */
KASSERT(crp->crp_digest_start + csp->csp_auth_mlen <= len,
("digest outside buffer"));
} else {
KASSERT(crp->crp_digest_start == 0,
("non-zero digest start for request without a digest"));
}
if (csp->csp_cipher_klen != 0)
KASSERT(csp->csp_cipher_key != NULL ||
crp->crp_cipher_key != NULL,
("cipher request without a key"));
if (csp->csp_auth_klen != 0)
KASSERT(csp->csp_auth_key != NULL || crp->crp_auth_key != NULL,
("auth request without a key"));
KASSERT(crp->crp_callback != NULL, ("incoming crp without callback"));
}
#endif
/*
* Add a crypto request to a queue, to be processed by the kernel thread.
*/
int
crypto_dispatch(struct cryptop *crp)
{
struct cryptocap *cap;
int result;
#ifdef INVARIANTS
crp_sanity(crp);
#endif
cryptostats.cs_ops++;
#ifdef CRYPTO_TIMING
if (crypto_timing)
binuptime(&crp->crp_tstamp);
#endif
crp->crp_retw_id = ((uintptr_t)crp->crp_session) % crypto_workers_num;
if (CRYPTOP_ASYNC(crp)) {
if (crp->crp_flags & CRYPTO_F_ASYNC_KEEPORDER) {
struct crypto_ret_worker *ret_worker;
ret_worker = CRYPTO_RETW(crp->crp_retw_id);
CRYPTO_RETW_LOCK(ret_worker);
crp->crp_seq = ret_worker->reorder_ops++;
CRYPTO_RETW_UNLOCK(ret_worker);
}
TASK_INIT(&crp->crp_task, 0, crypto_task_invoke, crp);
taskqueue_enqueue(crypto_tq, &crp->crp_task);
return (0);
}
if ((crp->crp_flags & CRYPTO_F_BATCH) == 0) {
/*
* Caller marked the request to be processed
* immediately; dispatch it directly to the
* driver unless the driver is currently blocked.
*/
cap = crp->crp_session->cap;
if (!cap->cc_qblocked) {
result = crypto_invoke(cap, crp, 0);
if (result != ERESTART)
return (result);
/*
* The driver ran out of resources, put the request on
* the queue.
*/
}
}
crypto_batch_enqueue(crp);
return 0;
}
void
crypto_batch_enqueue(struct cryptop *crp)
{
CRYPTO_Q_LOCK();
TAILQ_INSERT_TAIL(&crp_q, crp, crp_next);
if (crp_sleep)
wakeup_one(&crp_q);
CRYPTO_Q_UNLOCK();
}
/*
* Add an asymetric crypto request to a queue,
* to be processed by the kernel thread.
*/
int
crypto_kdispatch(struct cryptkop *krp)
{
int error;
cryptostats.cs_kops++;
krp->krp_cap = NULL;
error = crypto_kinvoke(krp);
if (error == ERESTART) {
CRYPTO_Q_LOCK();
TAILQ_INSERT_TAIL(&crp_kq, krp, krp_next);
if (crp_sleep)
wakeup_one(&crp_q);
CRYPTO_Q_UNLOCK();
error = 0;
}
return error;
}
/*
* Verify a driver is suitable for the specified operation.
*/
static __inline int
kdriver_suitable(const struct cryptocap *cap, const struct cryptkop *krp)
{
return (cap->cc_kalg[krp->krp_op] & CRYPTO_ALG_FLAG_SUPPORTED) != 0;
}
/*
* Select a driver for an asym operation. The driver must
* support the necessary algorithm. The caller can constrain
* which device is selected with the flags parameter. The
* algorithm we use here is pretty stupid; just use the first
* driver that supports the algorithms we need. If there are
* multiple suitable drivers we choose the driver with the
* fewest active operations. We prefer hardware-backed
* drivers to software ones when either may be used.
*/
static struct cryptocap *
crypto_select_kdriver(const struct cryptkop *krp, int flags)
{
struct cryptocap *cap, *best;
int match, hid;
CRYPTO_DRIVER_ASSERT();
/*
* Look first for hardware crypto devices if permitted.
*/
if (flags & CRYPTOCAP_F_HARDWARE)
match = CRYPTOCAP_F_HARDWARE;
else
match = CRYPTOCAP_F_SOFTWARE;
best = NULL;
again:
for (hid = 0; hid < crypto_drivers_size; hid++) {
/*
* If there is no driver for this slot, or the driver
* is not appropriate (hardware or software based on
* match), then skip.
*/
cap = crypto_drivers[hid];
if (cap->cc_dev == NULL ||
(cap->cc_flags & match) == 0)
continue;
/* verify all the algorithms are supported. */
if (kdriver_suitable(cap, krp)) {
if (best == NULL ||
cap->cc_koperations < best->cc_koperations)
best = cap;
}
}
if (best != NULL)
return best;
if (match == CRYPTOCAP_F_HARDWARE && (flags & CRYPTOCAP_F_SOFTWARE)) {
/* sort of an Algol 68-style for loop */
match = CRYPTOCAP_F_SOFTWARE;
goto again;
}
return best;
}
/*
* Choose a driver for an asymmetric crypto request.
*/
static struct cryptocap *
crypto_lookup_kdriver(struct cryptkop *krp)
{
struct cryptocap *cap;
uint32_t crid;
/* If this request is requeued, it might already have a driver. */
cap = krp->krp_cap;
if (cap != NULL)
return (cap);
/* Use krp_crid to choose a driver. */
crid = krp->krp_crid;
if ((crid & (CRYPTOCAP_F_HARDWARE | CRYPTOCAP_F_SOFTWARE)) == 0) {
cap = crypto_checkdriver(crid);
if (cap != NULL) {
/*
* Driver present, it must support the
* necessary algorithm and, if s/w drivers are
* excluded, it must be registered as
* hardware-backed.
*/
if (!kdriver_suitable(cap, krp) ||
(!crypto_devallowsoft &&
(cap->cc_flags & CRYPTOCAP_F_HARDWARE) == 0))
cap = NULL;
}
} else {
/*
* No requested driver; select based on crid flags.
*/
if (!crypto_devallowsoft) /* NB: disallow s/w drivers */
crid &= ~CRYPTOCAP_F_SOFTWARE;
cap = crypto_select_kdriver(krp, crid);
}
if (cap != NULL) {
krp->krp_cap = cap_ref(cap);
krp->krp_hid = cap->cc_hid;
}
return (cap);
}
/*
* Dispatch an asymmetric crypto request.
*/
static int
crypto_kinvoke(struct cryptkop *krp)
{
struct cryptocap *cap = NULL;
int error;
KASSERT(krp != NULL, ("%s: krp == NULL", __func__));
KASSERT(krp->krp_callback != NULL,
("%s: krp->crp_callback == NULL", __func__));
CRYPTO_DRIVER_LOCK();
cap = crypto_lookup_kdriver(krp);
if (cap == NULL) {
CRYPTO_DRIVER_UNLOCK();
krp->krp_status = ENODEV;
crypto_kdone(krp);
return (0);
}
/*
* If the device is blocked, return ERESTART to requeue it.
*/
if (cap->cc_kqblocked) {
/*
* XXX: Previously this set krp_status to ERESTART and
* invoked crypto_kdone but the caller would still
* requeue it.
*/
CRYPTO_DRIVER_UNLOCK();
return (ERESTART);
}
cap->cc_koperations++;
CRYPTO_DRIVER_UNLOCK();
error = CRYPTODEV_KPROCESS(cap->cc_dev, krp, 0);
if (error == ERESTART) {
CRYPTO_DRIVER_LOCK();
cap->cc_koperations--;
CRYPTO_DRIVER_UNLOCK();
return (error);
}
KASSERT(error == 0, ("error %d returned from crypto_kprocess", error));
return (0);
}
#ifdef CRYPTO_TIMING
static void
crypto_tstat(struct cryptotstat *ts, struct bintime *bt)
{
struct bintime now, delta;
struct timespec t;
uint64_t u;
binuptime(&now);
u = now.frac;
delta.frac = now.frac - bt->frac;
delta.sec = now.sec - bt->sec;
if (u < delta.frac)
delta.sec--;
bintime2timespec(&delta, &t);
timespecadd(&ts->acc, &t, &ts->acc);
if (timespeccmp(&t, &ts->min, <))
ts->min = t;
if (timespeccmp(&t, &ts->max, >))
ts->max = t;
ts->count++;
*bt = now;
}
#endif
static void
crypto_task_invoke(void *ctx, int pending)
{
struct cryptocap *cap;
struct cryptop *crp;
int result;
crp = (struct cryptop *)ctx;
cap = crp->crp_session->cap;
result = crypto_invoke(cap, crp, 0);
if (result == ERESTART)
crypto_batch_enqueue(crp);
}
/*
* Dispatch a crypto request to the appropriate crypto devices.
*/
static int
crypto_invoke(struct cryptocap *cap, struct cryptop *crp, int hint)
{
KASSERT(crp != NULL, ("%s: crp == NULL", __func__));
KASSERT(crp->crp_callback != NULL,
("%s: crp->crp_callback == NULL", __func__));
KASSERT(crp->crp_session != NULL,
("%s: crp->crp_session == NULL", __func__));
#ifdef CRYPTO_TIMING
if (crypto_timing)
crypto_tstat(&cryptostats.cs_invoke, &crp->crp_tstamp);
#endif
if (cap->cc_flags & CRYPTOCAP_F_CLEANUP) {
struct crypto_session_params csp;
crypto_session_t nses;
/*
* Driver has unregistered; migrate the session and return
* an error to the caller so they'll resubmit the op.
*
* XXX: What if there are more already queued requests for this
* session?
*
* XXX: Real solution is to make sessions refcounted
* and force callers to hold a reference when
* assigning to crp_session. Could maybe change
* crypto_getreq to accept a session pointer to make
* that work. Alternatively, we could abandon the
* notion of rewriting crp_session in requests forcing
* the caller to deal with allocating a new session.
* Perhaps provide a method to allow a crp's session to
* be swapped that callers could use.
*/
csp = crp->crp_session->csp;
crypto_freesession(crp->crp_session);
/*
* XXX: Key pointers may no longer be valid. If we
* really want to support this we need to define the
* KPI such that 'csp' is required to be valid for the
* duration of a session by the caller perhaps.
*
* XXX: If the keys have been changed this will reuse
* the old keys. This probably suggests making
* rekeying more explicit and updating the key
* pointers in 'csp' when the keys change.
*/
if (crypto_newsession(&nses, &csp,
CRYPTOCAP_F_HARDWARE | CRYPTOCAP_F_SOFTWARE) == 0)
crp->crp_session = nses;
crp->crp_etype = EAGAIN;
crypto_done(crp);
return 0;
} else {
/*
* Invoke the driver to process the request.
*/
return CRYPTODEV_PROCESS(cap->cc_dev, crp, hint);
}
}
void
crypto_freereq(struct cryptop *crp)
{
if (crp == NULL)
return;
#ifdef DIAGNOSTIC
{
struct cryptop *crp2;
struct crypto_ret_worker *ret_worker;
CRYPTO_Q_LOCK();
TAILQ_FOREACH(crp2, &crp_q, crp_next) {
KASSERT(crp2 != crp,
("Freeing cryptop from the crypto queue (%p).",
crp));
}
CRYPTO_Q_UNLOCK();
FOREACH_CRYPTO_RETW(ret_worker) {
CRYPTO_RETW_LOCK(ret_worker);
TAILQ_FOREACH(crp2, &ret_worker->crp_ret_q, crp_next) {
KASSERT(crp2 != crp,
("Freeing cryptop from the return queue (%p).",
crp));
}
CRYPTO_RETW_UNLOCK(ret_worker);
}
}
#endif
uma_zfree(cryptop_zone, crp);
}
struct cryptop *
crypto_getreq(crypto_session_t cses, int how)
{
struct cryptop *crp;
MPASS(how == M_WAITOK || how == M_NOWAIT);
crp = uma_zalloc(cryptop_zone, how | M_ZERO);
crp->crp_session = cses;
return (crp);
}
/*
* Invoke the callback on behalf of the driver.
*/
void
crypto_done(struct cryptop *crp)
{
KASSERT((crp->crp_flags & CRYPTO_F_DONE) == 0,
("crypto_done: op already done, flags 0x%x", crp->crp_flags));
crp->crp_flags |= CRYPTO_F_DONE;
if (crp->crp_etype != 0)
cryptostats.cs_errs++;
#ifdef CRYPTO_TIMING
if (crypto_timing)
crypto_tstat(&cryptostats.cs_done, &crp->crp_tstamp);
#endif
/*
* CBIMM means unconditionally do the callback immediately;
* CBIFSYNC means do the callback immediately only if the
* operation was done synchronously. Both are used to avoid
* doing extraneous context switches; the latter is mostly
* used with the software crypto driver.
*/
if (!CRYPTOP_ASYNC_KEEPORDER(crp) &&
((crp->crp_flags & CRYPTO_F_CBIMM) ||
((crp->crp_flags & CRYPTO_F_CBIFSYNC) &&
(crypto_ses2caps(crp->crp_session) & CRYPTOCAP_F_SYNC)))) {
/*
* Do the callback directly. This is ok when the
* callback routine does very little (e.g. the
* /dev/crypto callback method just does a wakeup).
*/
#ifdef CRYPTO_TIMING
if (crypto_timing) {
/*
* NB: We must copy the timestamp before
* doing the callback as the cryptop is
* likely to be reclaimed.
*/
struct bintime t = crp->crp_tstamp;
crypto_tstat(&cryptostats.cs_cb, &t);
crp->crp_callback(crp);
crypto_tstat(&cryptostats.cs_finis, &t);
} else
#endif
crp->crp_callback(crp);
} else {
struct crypto_ret_worker *ret_worker;
bool wake;
ret_worker = CRYPTO_RETW(crp->crp_retw_id);
wake = false;
/*
* Normal case; queue the callback for the thread.
*/
CRYPTO_RETW_LOCK(ret_worker);
if (CRYPTOP_ASYNC_KEEPORDER(crp)) {
struct cryptop *tmp;
TAILQ_FOREACH_REVERSE(tmp, &ret_worker->crp_ordered_ret_q,
cryptop_q, crp_next) {
if (CRYPTO_SEQ_GT(crp->crp_seq, tmp->crp_seq)) {
TAILQ_INSERT_AFTER(&ret_worker->crp_ordered_ret_q,
tmp, crp, crp_next);
break;
}
}
if (tmp == NULL) {
TAILQ_INSERT_HEAD(&ret_worker->crp_ordered_ret_q,
crp, crp_next);
}
if (crp->crp_seq == ret_worker->reorder_cur_seq)
wake = true;
}
else {
if (CRYPTO_RETW_EMPTY(ret_worker))
wake = true;
TAILQ_INSERT_TAIL(&ret_worker->crp_ret_q, crp, crp_next);
}
if (wake)
wakeup_one(&ret_worker->crp_ret_q); /* shared wait channel */
CRYPTO_RETW_UNLOCK(ret_worker);
}
}
/*
* Invoke the callback on behalf of the driver.
*/
void
crypto_kdone(struct cryptkop *krp)
{
struct crypto_ret_worker *ret_worker;
struct cryptocap *cap;
if (krp->krp_status != 0)
cryptostats.cs_kerrs++;
CRYPTO_DRIVER_LOCK();
cap = krp->krp_cap;
KASSERT(cap->cc_koperations > 0, ("cc_koperations == 0"));
cap->cc_koperations--;
if (cap->cc_koperations == 0 && cap->cc_flags & CRYPTOCAP_F_CLEANUP)
wakeup(cap);
CRYPTO_DRIVER_UNLOCK();
krp->krp_cap = NULL;
cap_rele(cap);
ret_worker = CRYPTO_RETW(0);
CRYPTO_RETW_LOCK(ret_worker);
if (CRYPTO_RETW_EMPTY(ret_worker))
wakeup_one(&ret_worker->crp_ret_q); /* shared wait channel */
TAILQ_INSERT_TAIL(&ret_worker->crp_ret_kq, krp, krp_next);
CRYPTO_RETW_UNLOCK(ret_worker);
}
int
crypto_getfeat(int *featp)
{
int hid, kalg, feat = 0;
CRYPTO_DRIVER_LOCK();
for (hid = 0; hid < crypto_drivers_size; hid++) {
const struct cryptocap *cap = crypto_drivers[hid];
if (cap == NULL ||
((cap->cc_flags & CRYPTOCAP_F_SOFTWARE) &&
!crypto_devallowsoft)) {
continue;
}
for (kalg = 0; kalg < CRK_ALGORITHM_MAX; kalg++)
if (cap->cc_kalg[kalg] & CRYPTO_ALG_FLAG_SUPPORTED)
feat |= 1 << kalg;
}
CRYPTO_DRIVER_UNLOCK();
*featp = feat;
return (0);
}
/*
* Terminate a thread at module unload. The process that
* initiated this is waiting for us to signal that we're gone;
* wake it up and exit. We use the driver table lock to insure
* we don't do the wakeup before they're waiting. There is no
* race here because the waiter sleeps on the proc lock for the
* thread so it gets notified at the right time because of an
* extra wakeup that's done in exit1().
*/
static void
crypto_finis(void *chan)
{
CRYPTO_DRIVER_LOCK();
wakeup_one(chan);
CRYPTO_DRIVER_UNLOCK();
kproc_exit(0);
}
/*
* Crypto thread, dispatches crypto requests.
*/
static void
crypto_proc(void)
{
struct cryptop *crp, *submit;
struct cryptkop *krp;
struct cryptocap *cap;
int result, hint;
#if defined(__i386__) || defined(__amd64__) || defined(__aarch64__)
fpu_kern_thread(FPU_KERN_NORMAL);
#endif
CRYPTO_Q_LOCK();
for (;;) {
/*
* Find the first element in the queue that can be
* processed and look-ahead to see if multiple ops
* are ready for the same driver.
*/
submit = NULL;
hint = 0;
TAILQ_FOREACH(crp, &crp_q, crp_next) {
cap = crp->crp_session->cap;
/*
* Driver cannot disappeared when there is an active
* session.
*/
KASSERT(cap != NULL, ("%s:%u Driver disappeared.",
__func__, __LINE__));
if (cap->cc_flags & CRYPTOCAP_F_CLEANUP) {
/* Op needs to be migrated, process it. */
if (submit == NULL)
submit = crp;
break;
}
if (!cap->cc_qblocked) {
if (submit != NULL) {
/*
* We stop on finding another op,
* regardless whether its for the same
* driver or not. We could keep
* searching the queue but it might be
* better to just use a per-driver
* queue instead.
*/
if (submit->crp_session->cap == cap)
hint = CRYPTO_HINT_MORE;
break;
} else {
submit = crp;
if ((submit->crp_flags & CRYPTO_F_BATCH) == 0)
break;
/* keep scanning for more are q'd */
}
}
}
if (submit != NULL) {
TAILQ_REMOVE(&crp_q, submit, crp_next);
cap = submit->crp_session->cap;
KASSERT(cap != NULL, ("%s:%u Driver disappeared.",
__func__, __LINE__));
CRYPTO_Q_UNLOCK();
result = crypto_invoke(cap, submit, hint);
CRYPTO_Q_LOCK();
if (result == ERESTART) {
/*
* The driver ran out of resources, mark the
* driver ``blocked'' for cryptop's and put
* the request back in the queue. It would
* best to put the request back where we got
* it but that's hard so for now we put it
* at the front. This should be ok; putting
* it at the end does not work.
*/
cap->cc_qblocked = 1;
TAILQ_INSERT_HEAD(&crp_q, submit, crp_next);
cryptostats.cs_blocks++;
}
}
/* As above, but for key ops */
TAILQ_FOREACH(krp, &crp_kq, krp_next) {
cap = krp->krp_cap;
if (cap->cc_flags & CRYPTOCAP_F_CLEANUP) {
/*
* Operation needs to be migrated,
* clear krp_cap so a new driver is
* selected.
*/
krp->krp_cap = NULL;
cap_rele(cap);
break;
}
if (!cap->cc_kqblocked)
break;
}
if (krp != NULL) {
TAILQ_REMOVE(&crp_kq, krp, krp_next);
CRYPTO_Q_UNLOCK();
result = crypto_kinvoke(krp);
CRYPTO_Q_LOCK();
if (result == ERESTART) {
/*
* The driver ran out of resources, mark the
* driver ``blocked'' for cryptkop's and put
* the request back in the queue. It would
* best to put the request back where we got
* it but that's hard so for now we put it
* at the front. This should be ok; putting
* it at the end does not work.
*/
krp->krp_cap->cc_kqblocked = 1;
TAILQ_INSERT_HEAD(&crp_kq, krp, krp_next);
cryptostats.cs_kblocks++;
}
}
if (submit == NULL && krp == NULL) {
/*
* Nothing more to be processed. Sleep until we're
* woken because there are more ops to process.
* This happens either by submission or by a driver
* becoming unblocked and notifying us through
* crypto_unblock. Note that when we wakeup we
* start processing each queue again from the
* front. It's not clear that it's important to
* preserve this ordering since ops may finish
* out of order if dispatched to different devices
* and some become blocked while others do not.
*/
crp_sleep = 1;
msleep(&crp_q, &crypto_q_mtx, PWAIT, "crypto_wait", 0);
crp_sleep = 0;
if (cryptoproc == NULL)
break;
cryptostats.cs_intrs++;
}
}
CRYPTO_Q_UNLOCK();
crypto_finis(&crp_q);
}
/*
* Crypto returns thread, does callbacks for processed crypto requests.
* Callbacks are done here, rather than in the crypto drivers, because
* callbacks typically are expensive and would slow interrupt handling.
*/
static void
crypto_ret_proc(struct crypto_ret_worker *ret_worker)
{
struct cryptop *crpt;
struct cryptkop *krpt;
CRYPTO_RETW_LOCK(ret_worker);
for (;;) {
/* Harvest return q's for completed ops */
crpt = TAILQ_FIRST(&ret_worker->crp_ordered_ret_q);
if (crpt != NULL) {
if (crpt->crp_seq == ret_worker->reorder_cur_seq) {
TAILQ_REMOVE(&ret_worker->crp_ordered_ret_q, crpt, crp_next);
ret_worker->reorder_cur_seq++;
} else {
crpt = NULL;
}
}
if (crpt == NULL) {
crpt = TAILQ_FIRST(&ret_worker->crp_ret_q);
if (crpt != NULL)
TAILQ_REMOVE(&ret_worker->crp_ret_q, crpt, crp_next);
}
krpt = TAILQ_FIRST(&ret_worker->crp_ret_kq);
if (krpt != NULL)
TAILQ_REMOVE(&ret_worker->crp_ret_kq, krpt, krp_next);
if (crpt != NULL || krpt != NULL) {
CRYPTO_RETW_UNLOCK(ret_worker);
/*
* Run callbacks unlocked.
*/
if (crpt != NULL) {
#ifdef CRYPTO_TIMING
if (crypto_timing) {
/*
* NB: We must copy the timestamp before
* doing the callback as the cryptop is
* likely to be reclaimed.
*/
struct bintime t = crpt->crp_tstamp;
crypto_tstat(&cryptostats.cs_cb, &t);
crpt->crp_callback(crpt);
crypto_tstat(&cryptostats.cs_finis, &t);
} else
#endif
crpt->crp_callback(crpt);
}
if (krpt != NULL)
krpt->krp_callback(krpt);
CRYPTO_RETW_LOCK(ret_worker);
} else {
/*
* Nothing more to be processed. Sleep until we're
* woken because there are more returns to process.
*/
msleep(&ret_worker->crp_ret_q, &ret_worker->crypto_ret_mtx, PWAIT,
"crypto_ret_wait", 0);
if (ret_worker->cryptoretproc == NULL)
break;
cryptostats.cs_rets++;
}
}
CRYPTO_RETW_UNLOCK(ret_worker);
crypto_finis(&ret_worker->crp_ret_q);
}
#ifdef DDB
static void
db_show_drivers(void)
{
int hid;
db_printf("%12s %4s %4s %8s %2s %2s\n"
, "Device"
, "Ses"
, "Kops"
, "Flags"
, "QB"
, "KB"
);
for (hid = 0; hid < crypto_drivers_size; hid++) {
const struct cryptocap *cap = crypto_drivers[hid];
if (cap == NULL)
continue;
db_printf("%-12s %4u %4u %08x %2u %2u\n"
, device_get_nameunit(cap->cc_dev)
, cap->cc_sessions
, cap->cc_koperations
, cap->cc_flags
, cap->cc_qblocked
, cap->cc_kqblocked
);
}
}
DB_SHOW_COMMAND(crypto, db_show_crypto)
{
struct cryptop *crp;
struct crypto_ret_worker *ret_worker;
db_show_drivers();
db_printf("\n");
db_printf("%4s %8s %4s %4s %4s %4s %8s %8s\n",
"HID", "Caps", "Ilen", "Olen", "Etype", "Flags",
"Device", "Callback");
TAILQ_FOREACH(crp, &crp_q, crp_next) {
db_printf("%4u %08x %4u %4u %04x %8p %8p\n"
, crp->crp_session->cap->cc_hid
, (int) crypto_ses2caps(crp->crp_session)
, crp->crp_olen
, crp->crp_etype
, crp->crp_flags
, device_get_nameunit(crp->crp_session->cap->cc_dev)
, crp->crp_callback
);
}
FOREACH_CRYPTO_RETW(ret_worker) {
db_printf("\n%8s %4s %4s %4s %8s\n",
"ret_worker", "HID", "Etype", "Flags", "Callback");
if (!TAILQ_EMPTY(&ret_worker->crp_ret_q)) {
TAILQ_FOREACH(crp, &ret_worker->crp_ret_q, crp_next) {
db_printf("%8td %4u %4u %04x %8p\n"
, CRYPTO_RETW_ID(ret_worker)
, crp->crp_session->cap->cc_hid
, crp->crp_etype
, crp->crp_flags
, crp->crp_callback
);
}
}
}
}
DB_SHOW_COMMAND(kcrypto, db_show_kcrypto)
{
struct cryptkop *krp;
struct crypto_ret_worker *ret_worker;
db_show_drivers();
db_printf("\n");
db_printf("%4s %5s %4s %4s %8s %4s %8s\n",
"Op", "Status", "#IP", "#OP", "CRID", "HID", "Callback");
TAILQ_FOREACH(krp, &crp_kq, krp_next) {
db_printf("%4u %5u %4u %4u %08x %4u %8p\n"
, krp->krp_op
, krp->krp_status
, krp->krp_iparams, krp->krp_oparams
, krp->krp_crid, krp->krp_hid
, krp->krp_callback
);
}
ret_worker = CRYPTO_RETW(0);
if (!TAILQ_EMPTY(&ret_worker->crp_ret_q)) {
db_printf("%4s %5s %8s %4s %8s\n",
"Op", "Status", "CRID", "HID", "Callback");
TAILQ_FOREACH(krp, &ret_worker->crp_ret_kq, krp_next) {
db_printf("%4u %5u %08x %4u %8p\n"
, krp->krp_op
, krp->krp_status
, krp->krp_crid, krp->krp_hid
, krp->krp_callback
);
}
}
}
#endif
int crypto_modevent(module_t mod, int type, void *unused);
/*
* Initialization code, both for static and dynamic loading.
* Note this is not invoked with the usual MODULE_DECLARE
* mechanism but instead is listed as a dependency by the
* cryptosoft driver. This guarantees proper ordering of
* calls on module load/unload.
*/
int
crypto_modevent(module_t mod, int type, void *unused)
{
int error = EINVAL;
switch (type) {
case MOD_LOAD:
error = crypto_init();
if (error == 0 && bootverbose)
printf("crypto: <crypto core>\n");
break;
case MOD_UNLOAD:
/*XXX disallow if active sessions */
error = 0;
crypto_destroy();
return 0;
}
return error;
}
MODULE_VERSION(crypto, 1);
MODULE_DEPEND(crypto, zlib, 1, 1, 1);