crypto
- API for cryptographic services in the kernel
SYNOPSIS
#include <opencrypto/cryptodev.h> int32_t
crypto_get_driverid (u_int8_t); int
crypto_register (u_int32_t int u_int16_t u_int32_t int lp]*rp]lp]void *, u_int32_t *, struct cryptoini *rp] int lp]*rp]lp]void *, u_int64_trp] int lp]*rp]lp]void *, struct cryptop *rp] void *); int
crypto_kregister (u_int32_t int u_int32_t int lp]*rp]lp]void *, struct cryptkop *rp] void *); int
crypto_unregister (u_int32_t int); int
crypto_unregister_all (u_int32_t); void
crypto_done (struct cryptop *); void
crypto_kdone (struct cryptkop *); int
crypto_newsession (u_int64_t * struct cryptoini * int); int
crypto_freesession (u_int64_t); int
crypto_dispatch (struct cryptop *); int
crypto_kdispatch (struct cryptkop *); int
crypto_unblock (u_int32_t int); struct cryptop *
crypto_getreq (int); void
crypto_freereq (void);
#define CRYPTO_SYMQ 0x1
#define CRYPTO_ASYMQ 0x2
#define EALG_MAX_BLOCK_LEN 16
struct cryptoini {
int cri_alg;
int cri_klen;
int cri_mlen;
caddr_t cri_key;
u_int8_t cri_iv[EALG_MAX_BLOCK_LEN];
struct cryptoini *cri_next;
};
struct cryptodesc {
int crd_skip;
int crd_len;
int crd_inject;
int crd_flags;
struct cryptoini CRD_INI;
#define crd_iv CRD_INI.cri_iv
#define crd_key CRD_INI.cri_key
#define crd_alg CRD_INI.cri_alg
#define crd_klen CRD_INI.cri_klen
struct cryptodesc *crd_next;
};
struct cryptop {
TAILQ_ENTRY(cryptop) crp_next;
u_int64_t crp_sid;
int crp_ilen;
int crp_olen;
int crp_etype;
int crp_flags;
caddr_t crp_buf;
caddr_t crp_opaque;
struct cryptodesc *crp_desc;
int (*crp_callback) (struct cryptop *);
caddr_t crp_mac;
};
struct crparam {
caddr_t crp_p;
u_int crp_nbits;
};
#define CRK_MAXPARAM 8
struct cryptkop {
TAILQ_ENTRY(cryptkop) krp_next;
u_int krp_op; /* ie. CRK_MOD_EXP or other */
u_int krp_status; /* return status */
u_short krp_iparams; /* # of input parameters */
u_short krp_oparams; /* # of output parameters */
u_int32_t krp_hid;
struct crparam krp_param[CRK_MAXPARAM];
int (*krp_callback)(struct cryptkop *);
};
DESCRIPTION
is a framework for drivers of cryptographic hardware to register with
the kernel so
``consumers''
(other kernel subsystems, and
users through the
/dev/crypto
device) are able to make use of it.
Drivers register with the framework the algorithms they support,
and provide entry points (functions) the framework may call to
establish, use, and tear down sessions.
Sessions are used to cache cryptographic information in a particular driver
(or associated hardware), so initialization is not needed with every request.
Consumers of cryptographic services pass a set of
descriptors that instruct the framework (and the drivers registered
with it) of the operations that should be applied on the data (more
than one cryptographic operation can be requested).
Keying operations are supported as well.
Unlike the symmetric operators described above,
these sessionless commands perform mathematical operations using
input and output parameters.
Since the consumers may not be associated with a process, drivers may
not
sleep(9).
The same holds for the framework.
Thus, a callback mechanism is used
to notify a consumer that a request has been completed (the
callback is specified by the consumer on an per-request basis).
The callback is invoked by the framework whether the request was
successfully completed or not.
An error indication is provided in the latter case.
A specific error code,
Er EAGAIN ,
is used to indicate that a session number has changed and that the
request may be re-submitted immediately with the new session number.
Errors are only returned to the invoking function if not
enough information to call the callback is available (meaning, there
was a fatal error in verifying the arguments).
For session initialization and teardown there is no callback mechanism used.
The
crypto_newsession ();
routine is called by consumers of cryptographic services (such as the
ipsec(4)
stack) that wish to establish a new session with the framework.
On success, the first argument will contain the Session Identifier (SID).
The second argument contains all the necessary information for
the driver to establish the session.
The third argument indicates whether a
hardware driver (1) should be used or not (0).
The various fields in the
Vt cryptoini
structure are:
cri_alg
Contains an algorithm identifier.
Currently supported algorithms are:
CRYPTO_AES_CBC
CRYPTO_ARC4
CRYPTO_BLF_CBC
CRYPTO_CAMELLIA_CBC
CRYPTO_CAST_CBC
CRYPTO_DES_CBC
CRYPTO_3DES_CBC
CRYPTO_SKIPJACK_CBC
CRYPTO_MD5
CRYPTO_MD5_HMAC
CRYPTO_MD5_KPDK
CRYPTO_RIPEMD160_HMAC
CRYPTO_SHA1
CRYPTO_SHA1_HMAC
CRYPTO_SHA1_KPDK
CRYPTO_SHA2_256_HMAC
CRYPTO_SHA2_384_HMAC
CRYPTO_SHA2_512_HMAC
CRYPTO_NULL_HMAC
CRYPTO_NULL_CBC
cri_klen
Specifies the length of the key in bits, for variable-size key
algorithms.
cri_mlen
Specifies how many bytes from the calculated hash should be copied back.
0 means entire hash.
cri_key
Contains the key to be used with the algorithm.
cri_iv
Contains an explicit initialization vector (IV), if it does not prefix
the data.
This field is ignored during initialization.
If no IV is explicitly passed (see below on details), a random IV is used
by the device driver processing the request.
cri_next
Contains a pointer to another
Vt cryptoini
structure.
Multiple such structures may be linked to establish multi-algorithm sessions
(ipsec4
is an example consumer of such a feature).
The
Vt cryptoini
structure and its contents will not be modified by the framework (or
the drivers used).
Subsequent requests for processing that use the
SID returned will avoid the cost of re-initializing the hardware (in
essence, SID acts as an index in the session cache of the driver).
crypto_freesession ();
is called with the SID returned by
crypto_newsession ();
to disestablish the session.
crypto_dispatch ();
is called to process a request.
The various fields in the
Vt cryptop
structure are:
crp_sid
Contains the SID.
crp_ilen
Indicates the total length in bytes of the buffer to be processed.
crp_olen
On return, contains the total length of the result.
For symmetric crypto operations, this will be the same as the input length.
This will be used if the framework needs to allocate a new
buffer for the result (or for re-formatting the input).
crp_callback
This routine is invoked upon completion of the request, whether
successful or not.
It is invoked through the
crypto_done ();
routine.
If the request was not successful, an error code is set in the
crp_etype
field.
It is the responsibility of the callback routine to set the appropriate
spl(9)
level.
crp_etype
Contains the error type, if any errors were encountered, or zero if
the request was successfully processed.
If the
Er EAGAIN
error code is returned, the SID has changed (and has been recorded in the
crp_sid
field).
The consumer should record the new SID and use it in all subsequent requests.
In this case, the request may be re-submitted immediately.
This mechanism is used by the framework to perform
session migration (move a session from one driver to another, because
of availability, performance, or other considerations).
Note that this field only makes sense when examined by
the callback routine specified in
crp_callback
Errors are returned to the invoker of
crypto_process ();
only when enough information is not present to call the callback
routine (i.e., if the pointer passed is
NULL
or if no callback routine was specified).
crp_flags
Is a bitmask of flags associated with this request.
Currently defined flags are:
CRYPTO_F_IMBUF
The buffer pointed to by
crp_buf
is an mbuf chain.
CRYPTO_F_IOV
The buffer pointed to by
crp_buf
is an
Vt uio
structure.
CRYPTO_F_REL
Must return data in the same place.
CRYPTO_F_BATCH
Batch operation if possible.
CRYPTO_F_CBIMM
Do callback immediately instead of doing it from a dedicated kernel thread.
CRYPTO_F_DONE
Operation completed.
CRYPTO_F_CBIFSYNC
Do callback immediately if operation is synchronous.
crp_buf
Points to the input buffer.
On return (when the callback is invoked),
it contains the result of the request.
The input buffer may be an mbuf
chain or a contiguous buffer,
depending on
crp_flags
crp_opaque
This is passed through the crypto framework untouched and is
intended for the invoking application's use.
crp_desc
This is a linked list of descriptors.
Each descriptor provides
information about what type of cryptographic operation should be done
on the input buffer.
The various fields are:
crd_iv
The field where IV should be provided when the
CRD_F_IV_EXPLICIT
flag is given.
crd_key
When the
CRD_F_KEY_EXPLICIT
flag is given, the
crd_key
points to a buffer with encryption or authentication key.
crd_alg
An algorithm to use.
Must be the same as the one given at newsession time.
crd_klen
The
crd_key
key length.
crd_skip
The offset in the input buffer where processing should start.
crd_len
How many bytes, after
crd_skip
should be processed.
crd_inject
Offset from the beginning of the buffer to insert any results.
For encryption algorithms, this is where the initialization vector
(IV) will be inserted when encrypting or where it can be found when
decrypting (subject to
crd_flags )
For MAC algorithms, this is where the result of the keyed hash will be
inserted.
crd_flags
The following flags are defined:
CRD_F_ENCRYPT
For encryption algorithms, this bit is set when encryption is required
(when not set, decryption is performed).
CRD_F_IV_PRESENT
For encryption algorithms, this bit is set when the IV already
precedes the data, so the
crd_inject
value will be ignored and no IV will be written in the buffer.
Otherwise, the IV used to encrypt the packet will be written
at the location pointed to by
crd_inject
The IV length is assumed to be equal to the blocksize of the
encryption algorithm.
Some applications that do special
``IV cooking''
such as the half-IV mode in
ipsec(4),
can use this flag to indicate that the IV should not be written on the packet.
This flag is typically used in conjunction with the
CRD_F_IV_EXPLICIT
flag.
CRD_F_IV_EXPLICIT
For encryption algorithms, this bit is set when the IV is explicitly
provided by the consumer in the
crd_iv
field.
Otherwise, for encryption operations the IV is provided for by
the driver used to perform the operation, whereas for decryption
operations it is pointed to by the
crd_inject
field.
This flag is typically used when the IV is calculated
``on the fly''
by the consumer, and does not precede the data (some
ipsec(4)
configurations, and the encrypted swap are two such examples).
CRD_F_KEY_EXPLICIT
For encryption and authentication (MAC) algorithms, this bit is set when the key
is explicitly provided by the consumer in the
crd_key
field for the given operation.
Otherwise, the key is taken at newsession time from the
cri_key
field.
CRD_F_COMP
For compression algorithms, this bit is set when compression is required (when
not set, decompression is performed).
CRD_INI
This
Vt cryptoini
structure will not be modified by the framework or the device drivers.
Since this information accompanies every cryptographic
operation request, drivers may re-initialize state on-demand
(typically an expensive operation).
Furthermore, the cryptographic
framework may re-route requests as a result of full queues or hardware
failure, as described above.
crd_next
Point to the next descriptor.
Linked operations are useful in protocols such as
ipsec(4),
where multiple cryptographic transforms may be applied on the same
block of data.
crypto_getreq ();
allocates a
Vt cryptop
structure with a linked list of as many
Vt cryptodesc
structures as were specified in the argument passed to it.
crypto_freereq ();
deallocates a structure
Vt cryptop
and any
Vt cryptodesc
structures linked to it.
Note that it is the responsibility of the
callback routine to do the necessary cleanups associated with the
opaque field in the
Vt cryptop
structure.
crypto_kdispatch ();
is called to perform a keying operation.
The various fields in the
Vt cryptkop
structure are:
krp_op
Operation code, such as
CRK_MOD_EXP
krp_status
Return code.
This
errno -style
variable indicates whether lower level reasons
for operation failure.
krp_iparams
Number if input parameters to the specified operation.
Note that each operation has a (typically hardwired) number of such parameters.
krp_oparams
Number if output parameters from the specified operation.
Note that each operation has a (typically hardwired) number of such parameters.
krp_kvp
An array of kernel memory blocks containing the parameters.
krp_hid
Identifier specifying which low-level driver is being used.
krp_callback
Callback called on completion of a keying operation.
DRIVER-SIDE API
The
crypto_get_driverid (,);
crypto_register (,);
crypto_kregister (,);
crypto_unregister (,);
crypto_unblock (,);
and
crypto_done ();
routines are used by drivers that provide support for cryptographic
primitives to register and unregister with the kernel crypto services
framework.
Drivers must first use the
crypto_get_driverid ();
function to acquire a driver identifier, specifying the
Fa cc_flags
as an argument (normally 0, but software-only drivers should specify
CRYPTOCAP_F_SOFTWARE )
For each algorithm the driver supports, it must then call
crypto_register (.);
The first two arguments are the driver and algorithm identifiers.
The next two arguments specify the largest possible operator length (in bits,
important for public key operations) and flags for this algorithm.
The last four arguments must be provided in the first call to
crypto_register ();
and are ignored in all subsequent calls.
They are pointers to three
driver-provided functions that the framework may call to establish new
cryptographic context with the driver, free already established
context, and ask for a request to be processed (encrypt, decrypt,
etc.); and an opaque parameter to pass when calling each of these routines.
crypto_unregister ();
is called by drivers that wish to withdraw support for an algorithm.
The two arguments are the driver and algorithm identifiers, respectively.
Typically, drivers for
PCMCIA
crypto cards that are being ejected will invoke this routine for all
algorithms supported by the card.
crypto_unregister_all ();
will unregister all algorithms registered by a driver
and the driver will be disabled (no new sessions will be allocated on
that driver, and any existing sessions will be migrated to other
drivers).
The same will be done if all algorithms associated with a driver are
unregistered one by one.
The calling convention for the three driver-supplied routines is:
On invocation, the first argument to
all routines is an opaque data value supplied when the algorithm
is registered with
crypto_register (.);
The second argument to
newsession ();
contains the driver identifier obtained via
crypto_get_driverid (.);
On successful return, it should contain a driver-specific session
identifier.
The third argument is identical to that of
crypto_newsession (.);
The
freesession ();
routine takes as arguments the opaque data value and the SID
(which is the concatenation of the
driver identifier and the driver-specific session identifier).
It should clear any context associated with the session (clear hardware
registers, memory, etc.).
The
process ();
routine is invoked with a request to perform crypto processing.
This routine must not block, but should queue the request and return
immediately.
Upon processing the request, the callback routine should be invoked.
In case of an unrecoverable error, the error indication must be placed in the
crp_etype
field of the
Vt cryptop
structure.
When the request is completed, or an error is detected, the
process ();
routine should invoke
crypto_done (.);
Session migration may be performed, as mentioned previously.
In case of a temporary resource exhaustion, the
process ();
routine may return
Er ERESTART
in which case the crypto services will requeue the request, mark the driver
as
``blocked''
and stop submitting requests for processing.
The driver is then responsible for notifying the crypto services
when it is again able to process requests through the
crypto_unblock ();
routine.
This simple flow control mechanism should only be used for short-lived
resource exhaustion as it causes operations to be queued in the crypto
layer.
Doing so is preferable to returning an error in such cases as
it can cause network protocols to degrade performance by treating the
failure much like a lost packet.
The
kprocess ();
routine is invoked with a request to perform crypto key processing.
This routine must not block, but should queue the request and return
immediately.
Upon processing the request, the callback routine should be invoked.
In case of an unrecoverable error, the error indication must be placed in the
krp_status
field of the
Vt cryptkop
structure.
When the request is completed, or an error is detected, the
kprocess ();
routine should invoked
crypto_kdone (.);
RETURN VALUES
crypto_register (,);
crypto_kregister (,);
crypto_unregister (,);
crypto_newsession (,);
crypto_freesession (,);
and
crypto_unblock ();
return 0 on success, or an error code on failure.
crypto_get_driverid ();
returns a non-negative value on error, and -1 on failure.
crypto_getreq ();
returns a pointer to a
Vt cryptop
structure and
NULL
on failure.
crypto_dispatch ();
returns
Er EINVAL
if its argument or the callback function was
NULL
and 0 otherwise.
The callback is provided with an error code in case of failure, in the
crp_etype
field.
The cryptographic framework first appeared in
Ox 2.7
and was written by
An Angelos D. Keromytis Aq angelos@openbsd.org .
BUGS
The framework currently assumes that all the algorithms in a
crypto_newsession ();
operation must be available by the same driver.
If that is not the case, session initialization will fail.
The framework also needs a mechanism for determining which driver is
best for a specific set of algorithms associated with a session.
Some type of benchmarking is in order here.
Multiple instances of the same algorithm in the same session are not
supported.
Note that 3DES is considered one algorithm (and not three
instances of DES).
Thus, 3DES and DES could be mixed in the same request.