/*
* pkcs11.c
* --------
*
* This is a partial implementation of PKCS #11 on top of the Cryptech
* libhal library connecting to the Cryptech FPGA cores.
*
* Author: Rob Austein
* Copyright (c) 2015-2016, NORDUnet A/S
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* - Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* - 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.
*
* - Neither the name of the NORDUnet nor the names of its contributors may
* be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 COPYRIGHT
* HOLDER OR CONTRIBUTORS 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 <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <stdarg.h>
#include <assert.h>
#include <hal.h>
/*
* Magic PKCS #11 macros that must be defined before including
* pkcs11.h. For now these are only the Unix versions, add others
* later (which may require minor refactoring).
*/
#define CK_PTR *
#define CK_DEFINE_FUNCTION(returnType, name) returnType name
#define CK_DECLARE_FUNCTION(returnType, name) returnType name
#define CK_DECLARE_FUNCTION_POINTER(returnType, name) returnType (* name)
#define CK_CALLBACK_FUNCTION(returnType, name) returnType (* name)
#ifndef NULL_PTR
#define NULL_PTR NULL
#endif
#include "pkcs11.h"
#include "attributes.h"
/*
* This PKCS #11 implementation is hardwired with one slot, the token
* for which is always present (so we return the same answer
* regardless of the value of tokenPresent).
*/
#define P11_ONE_AND_ONLY_SLOT 0
/*
* How many sessions and object handles to allow. We could do this
* with dynamic memory, but static arrays are simpler and faster. We
* don't expect all that many sessions, and slots in the object table
* are cheap.
*/
#ifndef P11_MAX_SESSION_HANDLES
#define P11_MAX_SESSION_HANDLES (64)
#endif
#ifndef P11_MAX_OBJECT_HANDLES
#define P11_MAX_OBJECT_HANDLES (4096)
#endif
/*
* Version numbers. Placeholders for now.
*
* Software version number is just the version of this PKCS #11
* implementation. Probably.
*/
#warning Figure out hardware and software version numbers
#define P11_VERSION_SW_MAJOR 0
#define P11_VERSION_SW_MINOR 1
#define P11_VERSION_HW_MAJOR 0
#define P11_VERSION_HW_MINOR 1
/*
* Debugging control.
*/
#ifndef DEBUG_HAL
#define DEBUG_HAL 0
#endif
#ifndef DEBUG_PKCS11
#define DEBUG_PKCS11 0
#endif
/*
* Whether to include POSIX-specific features.
*/
#ifndef USE_POSIX
#define USE_POSIX 1
#endif
/*
* Whether to use POSIX threads.
*/
#ifndef USE_PTHREADS
#define USE_PTHREADS USE_POSIX
#endif
#if USE_PTHREADS && !USE_POSIX
#error Can not use POSIX threads without using POSIX
#endif
#if USE_POSIX
#include <unistd.h>
#include <errno.h>
#endif
#if USE_PTHREADS
#include <pthread.h>
#endif
/*
* PKCS #11 sessions. General idea is that we have separate
* descriptors/handles/state for each operation that we're allowed to
* do in parallel, so sign, verify, digest, encrypt, decrypt, wrapkey,
* and unwrapkey all need separate slots in the session structure.
* Add these as we go.
*/
typedef struct p11_session {
CK_SESSION_HANDLE handle; /* Session handle */
CK_STATE state; /* State (CKS_*) of this session */
CK_NOTIFY notify; /* Notification callback */
CK_VOID_PTR application; /* Application data */
hal_rpc_pkey_attribute_t *find_query; /* FindObject*() query state */
unsigned find_query_token : 1; /* Find query for token objects in progress */
unsigned find_query_session : 1; /* Find query for session objects in progress */
unsigned find_query_n : 30; /* Number of entries in find_query */
hal_uuid_t find_query_previous_uuid; /* Previous UUID for find queries */
hal_digest_algorithm_t
digest_algorithm, /* Hash algorithm for C_Digest*() */
sign_digest_algorithm, /* Hash algorithm for C_Sign*() */
verify_digest_algorithm; /* Hash algorithm for C_Verify*() */
CK_OBJECT_HANDLE
sign_key_handle, /* Private key for C_Sign*() */
verify_key_handle; /* Public key for C_Verify() */
hal_hash_handle_t
digest_handle, /* Hash state for C_Digest*() */
sign_digest_handle, /* Hash state for C_Sign*() */
verify_digest_handle; /* Hash state for C_Verify*() */
} p11_session_t;
/*
* PKCS #11 objects. These are pretty simple, as they're really just
* mappings from PKCS #11's naming scheme to libhal UUIDs, with a little
* extra fun for PKCS #11 "session" objects.
*/
typedef struct p11_object {
CK_OBJECT_HANDLE handle; /* Object handle */
CK_SESSION_HANDLE session; /* Associated session (if any) */
hal_uuid_t uuid; /* libhal key UUID */
} p11_object_t;
/*
* PKCS #11 handle management. PKCS #11 has two kinds of handles:
* session handles and object handles. We subdivide object handles
* into token object handles (handles for objects which live on the
* token, ie, in non-volatile storage) and session object handles
* (handles for objects which live only as long as the session does),
* and we steal two bits of the handle as as flags to distinguish
* between these three kinds handles. We sub-divide the rest of a
* handle into a nonce (well, a lame one -- for now this is just a
* counter, if this becomes an issue we could do better) and an array
* index into the relevant table.
*/
typedef enum {
handle_flavor_none = 0, /* Matches CK_INVALID_HANDLE */
handle_flavor_session = 1,
handle_flavor_token_object = 2,
handle_flavor_session_object = 3
} handle_flavor_t;
#define HANDLE_MASK_FLAVOR (0xc0000000)
#define HANDLE_MASK_NONCE (0x3fff0000)
#define HANDLE_MASK_INDEX (0x0000ffff)
/*
* Current logged-in user.
*/
static enum {
not_logged_in,
logged_in_as_user,
logged_in_as_so
} logged_in_as = not_logged_in;
/*
* PKCS #11 sessions and object handles for this application.
*/
static p11_session_t p11_sessions [P11_MAX_SESSION_HANDLES];
static p11_object_t p11_objects [P11_MAX_OBJECT_HANDLES];
static unsigned p11_object_uuids [P11_MAX_OBJECT_HANDLES];
static unsigned p11_sessions_in_use, p11_objects_in_use;
/*
* Mutex callbacks.
*/
static CK_CREATEMUTEX mutex_cb_create;
static CK_DESTROYMUTEX mutex_cb_destroy;
static CK_LOCKMUTEX mutex_cb_lock;
static CK_UNLOCKMUTEX mutex_cb_unlock;
/*
* Global mutex. We may want something finer grained later, but this
* will suffice to comply with the API requirements.
*/
static CK_VOID_PTR p11_global_mutex;
/*
* (POSIX-specific) process which last called C_Initialize().
*/
#if USE_POSIX
static pid_t initialized_pid;
#endif
/*
* Syntactic sugar for functions returning CK_RV complex enough to
* need cleanup actions on failure. Also does very basic logging for
* debug-by-printf().
*
* NB: This uses a variable ("rv") and a goto target ("fail") which
* must be defined in the calling environment. We could make these
* arguments to the macro, but doing so would make the code less
* readable without significantly reducing the voodoo factor.
*/
#if DEBUG_PKCS11
#define lose(_ck_rv_code_) \
do { \
rv = (_ck_rv_code_); \
fprintf(stderr, "\n%s:%u: %s\n", __FILE__, __LINE__, #_ck_rv_code_); \
goto fail; \
} while (0)
#else /* DEBUG_PKCS11 */
#define lose(_ck_rv_code_) \
do { \
rv = (_ck_rv_code_); \
goto fail; \
} while (0)
#endif /* DEBUG_PKCS11 */
/*
* More debug-by-printf() support. One would like to consider this a
* relic of the previous millenium, but, sadly, broken debugging
* environments are still all too common.
*/
#if DEBUG_PKCS11 > 1
#define ENTER_PUBLIC_FUNCTION(_name_) \
fprintf(stderr, "\nEntering function %s\n", #_name_)
#else /* DEBUG_PKCS11 > 1 */
#define ENTER_PUBLIC_FUNCTION(_name_)
#endif /* DEBUG_PKCS11 > 1 */
/*
* Error checking for libhal calls.
*/
#define hal_whine(_expr_) (_hal_whine((_expr_), #_expr_, __FILE__, __LINE__, HAL_OK))
#define hal_whine_allow(_expr_, ...) (_hal_whine((_expr_), #_expr_, __FILE__, __LINE__, __VA_ARGS__, HAL_OK))
#define hal_check(_expr_) (hal_whine(_expr_) == HAL_OK)
#if DEBUG_HAL
static inline hal_error_t _hal_whine(const hal_error_t err,
const char * const expr,
const char * const file,
const unsigned line, ...)
{
va_list ap;
int ok = 0;
hal_error_t code;
va_start(ap, line);
do {
code = va_arg(ap, hal_error_t);
ok |= (err == code);
} while (code != HAL_OK);
va_end(ap);
if (!ok)
fprintf(stderr, "\n%s:%u: %s returned %s\n", file, line, expr, hal_error_string(err));
return err;
}
#else /* DEBUG_HAL */
#define _hal_whine(_expr_, ...) (_expr_)
#endif /* DEBUG_HAL */
/*
* Error translation fun for the entire family!
*/
#if DEBUG_PKCS11 || DEBUG_HAL
#define hal_p11_error_case(_hal_err_, _p11_err_) \
case _hal_err_: fprintf(stderr, "\n%s:%u: Mapping %s to %s\n", file, line, #_hal_err_, #_p11_err_); return _p11_err_;
#else
#define hal_p11_error_case(_hal_err_, _p11_err_) \
case _hal_err_: return _p11_err_;
#endif
#define p11_error_from_hal(_hal_err_) \
(_p11_error_from_hal((_hal_err_), __FILE__, __LINE__))
#define p11_whine_from_hal(_expr_) \
(_p11_error_from_hal(_hal_whine((_expr_), #_expr_, __FILE__, __LINE__, HAL_OK), __FILE__, __LINE__))
static CK_RV _p11_error_from_hal(const hal_error_t err, const char * const file, const unsigned line)
{
switch (err) {
hal_p11_error_case(HAL_ERROR_PIN_INCORRECT, CKR_PIN_INCORRECT);
hal_p11_error_case(HAL_ERROR_INVALID_SIGNATURE, CKR_SIGNATURE_INVALID);
/*
* More here later, first see if this compiles.
*/
case HAL_OK:
return CKR_OK;
default:
#if DEBUG_PKCS11 || DEBUG_HAL
fprintf(stderr, "\n%s:%u: Mapping unhandled HAL error to CKR_FUNCTION_FAILED\n", file, line);
#endif
return CKR_FUNCTION_FAILED;
}
}
#undef hal_p11_error_case
/*
* All (?) public functions should test whether we've been initialized or not.
* Where practical, we bury this check in other boilerplate.
*/
#if USE_POSIX
#define p11_uninitialized() (!initialized_pid)
#else
#define p11_uninitialized() (0)
#endif
/*
* Handle unsupported functions.
*/
#define UNSUPPORTED_FUNCTION(_name_) \
do { \
ENTER_PUBLIC_FUNCTION(_name_); \
if (p11_uninitialized()) \
return CKR_CRYPTOKI_NOT_INITIALIZED; \
return CKR_FUNCTION_NOT_SUPPORTED; \
} while (0)
/*
* Thread mutex utilities. We need to handle three separate cases:
*
* 1) User doesn't care about mutexes;
* 2) User wants us to use "OS" mutexes;
* 3) User wants us to use user-specified mutexs.
*
* For "OS" mutexes, read POSIX Threads mutexes, at least for now.
*
* PKCS #11 sort of has a fourth case, but it's really just license
* for us to pick either the second or third case at whim.
*
* To simplify the rest of the API, we provide a POSIX-based
* implementation which uses the same API an user-provided mutex
* implementation would be required to use, use null function pointers
* to represent the case where the user doesn't need mutexes at all,
* and wrap the whole thing in trivial macros to insulate the rest of
* the code from the grotty details.
*/
/*
* Basic macros.
*/
#define mutex_create(_m_) (mutex_cb_create == NULL ? CKR_OK : mutex_cb_create(_m_))
#define mutex_destroy(_m_) (mutex_cb_destroy == NULL ? CKR_OK : mutex_cb_destroy(_m_))
#define mutex_lock(_m_) (mutex_cb_lock == NULL ? CKR_OK : mutex_cb_lock(_m_))
#define mutex_unlock(_m_) (mutex_cb_unlock == NULL ? CKR_OK : mutex_cb_unlock(_m_))
/*
* Slightly higher-level macros for common operations.
*
* Since the locking code depends on initialization,
* attempting to lock anything when not initialized
* is a failure, by definition.
*/
#define mutex_lock_or_return_failure(_m_) \
do { \
if (p11_uninitialized()) \
return CKR_CRYPTOKI_NOT_INITIALIZED; \
CK_RV _rv = mutex_lock(_m_); \
if (_rv != CKR_OK) \
return _rv; \
} while (0)
#define mutex_unlock_return_with_rv(_rv_, _m_) \
do { \
CK_RV _rv1 = _rv_; \
CK_RV _rv2 = mutex_unlock(_m_); \
return _rv1 == CKR_OK ? _rv2 : _rv1; \
} while (0)
/*
* Mutex implementation using POSIX mutexes.
*/
#if USE_PTHREADS
static CK_RV posix_mutex_create(CK_VOID_PTR_PTR ppMutex)
{
pthread_mutex_t *m = NULL;
CK_RV rv;
if (ppMutex == NULL)
lose(CKR_GENERAL_ERROR);
if ((m = malloc(sizeof(*m))) == NULL)
lose(CKR_HOST_MEMORY);
switch (pthread_mutex_init(m, NULL)) {
case 0:
*ppMutex = m;
return CKR_OK;
case ENOMEM:
lose(CKR_HOST_MEMORY);
default:
lose(CKR_GENERAL_ERROR);
}
fail:
if (m != NULL)
free(m);
return rv;
}
static CK_RV posix_mutex_destroy(CK_VOID_PTR pMutex)
{
CK_RV rv;
if (pMutex == NULL)
lose(CKR_MUTEX_BAD);
switch (pthread_mutex_destroy(pMutex)) {
case 0:
free(pMutex);
return CKR_OK;
case EINVAL:
lose(CKR_MUTEX_BAD);
case EBUSY:
/*
* PKCS #11 mutex semantics are a bad match for POSIX here,
* leaving us only the nuclear option. Feh. Fall through.
*/
default:
lose(CKR_GENERAL_ERROR);
}
fail:
return rv;
}
static CK_RV posix_mutex_lock(CK_VOID_PTR pMutex)
{
CK_RV rv;
if (pMutex == NULL)
lose(CKR_MUTEX_BAD);
switch (pthread_mutex_lock(pMutex)) {
case 0:
return CKR_OK;
case EINVAL:
lose(CKR_MUTEX_BAD);
default:
lose(CKR_GENERAL_ERROR);
}
fail:
return rv;
}
static CK_RV posix_mutex_unlock(CK_VOID_PTR pMutex)
{
CK_RV rv;
if (pMutex == NULL)
lose(CKR_MUTEX_BAD);
switch (pthread_mutex_unlock(pMutex)) {
case 0:
return CKR_OK;
case EINVAL:
lose(CKR_MUTEX_BAD);
case EPERM:
lose(CKR_MUTEX_NOT_LOCKED);
default:
lose(CKR_GENERAL_ERROR);
}
fail:
return rv;
}
#endif /* USE_PTHREADS */
/*
* Bit mask twiddling utilities.
*/
static inline CK_ULONG mask_ldb(const CK_ULONG mask, const CK_ULONG value)
{
return (value & mask) / (mask & ~(mask - 1));
}
static inline CK_ULONG mask_dpb(const CK_ULONG mask, const CK_ULONG value)
{
return (value * (mask & ~(mask - 1))) & mask;
}
/*
* Translate between libhal EC curve names and OIDs.
*/
#warning Perhaps this should be a utility routine in libhal instead of here
static int ec_curve_oid_to_name(const uint8_t * const oid, const size_t oid_len, hal_curve_name_t *curve)
{
static uint8_t ec_curve_oid_p256[] = { 0x06, 0x08, 0x2a, 0x86, 0x48, 0xce, 0x3d, 0x03, 0x01, 0x07 };
static uint8_t ec_curve_oid_p384[] = { 0x06, 0x05, 0x2b, 0x81, 0x04, 0x00, 0x22 };
static uint8_t ec_curve_oid_p521[] = { 0x06, 0x05, 0x2b, 0x81, 0x04, 0x00, 0x23 };
if (oid == NULL || curve == NULL)
return 0;
else if (oid_len == sizeof(ec_curve_oid_p256) && memcmp(oid, ec_curve_oid_p256, oid_len) == 0)
*curve = HAL_CURVE_P256;
else if (oid_len == sizeof(ec_curve_oid_p384) && memcmp(oid, ec_curve_oid_p384, oid_len) == 0)
*curve = HAL_CURVE_P384;
else if (oid_len == sizeof(ec_curve_oid_p521) && memcmp(oid, ec_curve_oid_p521, oid_len) == 0)
*curve = HAL_CURVE_P521;
else
return 0;
return 1;
}
/*
* Extract libhal-compatible client and session identifiers from a session.
*
* libhal's session identifiers are deliberately chosen to be in the same
* numeric range as PKCS #11's, so we can just use them directly.
*
* libhal's client identifiers are multiplexing extension handled elsewhere,
* for our purposes using constant client identifier of zero will do.
*/
static inline hal_client_handle_t p11_session_hal_client(const p11_session_t * const session)
{
hal_client_handle_t handle = {0};
return handle;
}
static inline hal_session_handle_t p11_session_hal_session(const p11_session_t * const session)
{
hal_session_handle_t handle = {session->handle};
return handle;
}
/*
* Handle utilities.
*/
static inline CK_ULONG handle_compose(const handle_flavor_t flavor,
const unsigned nonce,
const unsigned index)
{
return (mask_dpb(HANDLE_MASK_FLAVOR, flavor) |
mask_dpb(HANDLE_MASK_NONCE, nonce) |
mask_dpb(HANDLE_MASK_INDEX, index));
}
static inline handle_flavor_t handle_flavor(const CK_ULONG handle)
{
return (handle_flavor_t) mask_ldb(HANDLE_MASK_FLAVOR, handle);
}
static inline unsigned handle_index(const CK_ULONG handle)
{
return mask_ldb(HANDLE_MASK_INDEX, handle);
}
// Backwards compatability, probably phase this out
#define is_token_handle(_handle_) (handle_flavor(_handle_) == handle_flavor_token_object)
/*
* Descriptor methods. Descriptors are generated at compile time by
* an auxiliary Python script, see attributes.* for details.
*/
/*
* Return the descriptor associated with a particular object class and
* key type.
*/
static const p11_descriptor_t *p11_descriptor_from_key_type(const CK_OBJECT_CLASS object_class,
const CK_KEY_TYPE key_type)
{
int i;
for (i = 0; i < sizeof(p11_descriptor_keyclass_map)/sizeof(*p11_descriptor_keyclass_map); i++) {
const p11_descriptor_keyclass_map_t * const m = &p11_descriptor_keyclass_map[i];
if (m->object_class == object_class && m->key_type == key_type)
return m->descriptor;
}
return NULL;
}
/*
* Find the entry for a particular attribute in a descriptor.
*/
static const p11_attribute_descriptor_t *p11_find_attribute_in_descriptor(const p11_descriptor_t *descriptor,
const CK_ATTRIBUTE_TYPE type)
{
int i;
if (descriptor != NULL && descriptor->attributes != NULL)
for (i = 0; i < descriptor->n_attributes; i++)
if (descriptor->attributes[i].type == type)
return &descriptor->attributes[i];
return NULL;
}
/*
* Check whether an attribute is marked as sensitive. If we don't
* recognize the attribute, report it as sensitive (safer than the
* alternative).
*/
static int p11_attribute_is_sensitive(const p11_descriptor_t *descriptor,
const CK_ATTRIBUTE_TYPE type)
{
const p11_attribute_descriptor_t *a = p11_find_attribute_in_descriptor(descriptor, type);
return a == NULL || (a->flags & P11_DESCRIPTOR_SENSITIVE) != 0;
}
/*
* Attribute methods.
*/
/*
* Find an attribute in a CK_ATTRIBUTE_PTR template. Returns index
* into template, or -1 if not found.
*/
static int p11_attribute_find_in_template(const CK_ATTRIBUTE_TYPE type,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG length)
{
if (template != NULL)
for (int i = 0; i < length; i++)
if (template[i].type == type)
return i;
return -1;
}
/*
* Find an attribute in a CK_ATTRIBUTE_PTR template. Returns pointer
* to attribute value, or NULL if not found.
*/
static void *p11_attribute_find_value_in_template(const CK_ATTRIBUTE_TYPE type,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG length)
{
const int i = p11_attribute_find_in_template(type, template, length);
return i < 0 ? NULL : template[i].pValue;
}
/*
* Set attributes for a newly-created or newly-uploaded HSM key.
*/
static int p11_attributes_set(const hal_pkey_handle_t pkey,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_length,
const p11_descriptor_t * const descriptor,
const hal_rpc_pkey_attribute_t *extra,
const unsigned extra_length)
{
assert(template != NULL && descriptor != NULL && (extra_length == 0 || extra != NULL));
/*
* Populate attributes, starting with the application's template,
* which we assume has already been blessed by the API function that
* called this method.
*
* If the attribute is flagged as sensitive in the descriptor, we
* don't store it as an attribute. Generally, this only arises for
* private key components of objects created with C_CreateObject(),
* but in theory there are some corner cases in which a user could
* choose to mark a private key as extractable and not sensitive, so
* we might have to back-fill missing values in those cases if
* anyone ever thinks up a sane reason for supporting them. For
* now, assume that private keys are bloody well supposed to be
* private.
*/
hal_rpc_pkey_attribute_t attributes[template_length + descriptor->n_attributes + extra_length];
unsigned n = 0;
for (int i = 0; i < template_length; i++) {
const CK_ATTRIBUTE_TYPE type = template[i].type;
const void * val = template[i].pValue;
const int len = template[i].ulValueLen;
if (p11_attribute_is_sensitive(descriptor, type))
continue;
if (n >= sizeof(attributes) / sizeof(*attributes))
return 0;
attributes[n].type = type;
attributes[n].value = val;
attributes[n].length = len;
n++;
}
/*
* Next, add defaults from the descriptor.
*/
for (int i = 0; i < descriptor->n_attributes; i++) {
const CK_ATTRIBUTE_TYPE type = descriptor->attributes[i].type;
const void * val = descriptor->attributes[i].value;
const int len = descriptor->attributes[i].length;
const unsigned flags = descriptor->attributes[i].flags;
if (val == NULL && (flags & P11_DESCRIPTOR_DEFAULT_VALUE) != 0)
val = "";
if (val == NULL || p11_attribute_find_in_template(type, template, template_length) >= 0)
continue;
if (n >= sizeof(attributes) / sizeof(*attributes))
return 0;
attributes[n].type = type;
attributes[n].value = val;
attributes[n].length = len;
n++;
}
/*
* Finally, add any attributes provided by the calling function itself.
*/
for (int i = 0; i < extra_length; i++) {
if (n >= sizeof(attributes) / sizeof(*attributes))
return 0;
attributes[n].type = extra[i].type;
attributes[n].value = extra[i].value;
attributes[n].length = extra[i].length;
n++;
}
/*
* Set all those attributes.
*/
if (!hal_check(hal_rpc_pkey_set_attributes(pkey, attributes, n)))
return 0;
return 1;
}
/*
* Map a keyusage-related attribute to a keyusage bit flag.
*
* Assumes that calling code has already checked whether this
* attribute is legal for this object class, that attribute which
* should be CK_BBOOLs are of the correct length, etcetera.
*
* To handle all the possible permutations of specified and default
* values, it may be necessary to defer calling this method until
* after the default and mandatory values have been merged into the
* values supplied by the application-supplied template.
*
* Semantics of the flags follow RFC 5280 4.2.1.3. Numeric values
* don't matter particularly as we only use them internally so we
* can simplify things a bit by reusing libhal's flag values.
*/
static void p11_attribute_apply_keyusage(hal_key_flags_t *keyusage, const CK_ATTRIBUTE_TYPE type, const CK_BBOOL *value)
{
unsigned flag;
assert(keyusage != NULL && value != NULL);
switch (type) {
case CKA_SIGN: /* Generate signature */
case CKA_VERIFY: /* Verify signature */
flag = HAL_KEY_FLAG_USAGE_DIGITALSIGNATURE;
break;
case CKA_ENCRYPT: /* Encrypt bulk data (seldom used) */
case CKA_DECRYPT: /* Bulk decryption (seldom used) */
flag = HAL_KEY_FLAG_USAGE_DATAENCIPHERMENT;
break;
case CKA_WRAP: /* Wrap key (normal way of doing encryption) */
case CKA_UNWRAP: /* Unwrap key (normal way of doing decryption) */
flag = HAL_KEY_FLAG_USAGE_KEYENCIPHERMENT;
break;
default:
return; /* Attribute not related to key usage */
}
if (*value)
*keyusage |= flag;
else
*keyusage &= ~flag;
}
/*
* Object methods.
*/
/*
* Look up an object's UUID in the object index table, return
* indication of whether it's present or not and the position it
* should occupy within the index table in either case.
*
* NB: *where is a position in p11_object_uuids[], not p11_objects[].
*/
static int p11_object_uuid_bsearch(const hal_uuid_t * const uuid, int *where)
{
assert(uuid != NULL && where != NULL);
int lo = -1;
int hi = p11_objects_in_use;
for (;;) {
int m = (lo + hi) / 2;
if (hi == 0 || m == lo) {
*where = hi;
return 0;
}
const int cmp = hal_uuid_cmp(uuid, &p11_objects[p11_object_uuids[m]].uuid);
if (cmp < 0)
hi = m;
else if (cmp > 0)
lo = m;
else {
*where = m;
return 1;
}
}
}
/*
* Allocate a new object.
*/
static CK_OBJECT_HANDLE p11_object_allocate(const handle_flavor_t flavor,
const hal_uuid_t *uuid,
const p11_session_t *session)
{
if (uuid == NULL)
return CK_INVALID_HANDLE;
if (flavor != handle_flavor_token_object && flavor != handle_flavor_session_object)
return CK_INVALID_HANDLE;
int where;
if (p11_object_uuid_bsearch(uuid, &where)) {
assert(where >= 0 && where < p11_objects_in_use);
const CK_OBJECT_HANDLE handle = p11_objects[p11_object_uuids[where]].handle;
return handle_flavor(handle) == flavor ? handle : CK_INVALID_HANDLE;
}
if (p11_objects_in_use >= sizeof(p11_objects) / sizeof(*p11_objects))
return CK_INVALID_HANDLE;
static unsigned next_index, nonce;
const unsigned last_index = next_index;
p11_object_t *object = NULL;
do {
next_index = (next_index + 1) % (sizeof(p11_objects) / sizeof(*p11_objects));
if (next_index == last_index)
return CK_INVALID_HANDLE;
if (next_index == 0)
++nonce;
object = &p11_objects[next_index];
} while (object->handle != CK_INVALID_HANDLE);
object->handle = handle_compose(flavor, nonce, next_index);
object->uuid = *uuid;
object->session = flavor == handle_flavor_session_object ? session->handle : CK_INVALID_HANDLE;
if (where < p11_objects_in_use)
memmove(&p11_object_uuids[where + 1], &p11_object_uuids[where],
(p11_objects_in_use - where) * sizeof(*p11_object_uuids));
p11_object_uuids[where] = next_index;
p11_objects_in_use++;
return object->handle;
}
/*
* Free an object.
*/
static void p11_object_free(p11_object_t *object)
{
if (object == NULL)
return;
int where;
if (p11_objects_in_use > 0 &&
p11_object_uuid_bsearch(&object->uuid, &where) &&
--p11_objects_in_use > where)
memmove(&p11_object_uuids[where], &p11_object_uuids[where + 1],
(p11_objects_in_use - where) * sizeof(*p11_object_uuids));
memset(object, 0, sizeof(*object));
}
/*
* Find an object given its UUID.
*/
static p11_object_t *p11_object_by_uuid(const hal_uuid_t * const uuid)
{
int where;
if (uuid == NULL || !p11_object_uuid_bsearch(uuid, &where))
return NULL;
assert(where >= 0 && where < p11_objects_in_use);
p11_object_t *object = &p11_objects[p11_object_uuids[where]];
if (handle_flavor(object->handle) != handle_flavor_session_object &&
handle_flavor(object->handle) != handle_flavor_token_object)
return NULL;
return object;
}
/*
* Find an object given its handle.
*/
static p11_object_t *p11_object_by_handle(const CK_OBJECT_HANDLE object_handle)
{
if (handle_flavor(object_handle) != handle_flavor_session_object &&
handle_flavor(object_handle) != handle_flavor_token_object)
return NULL;
const unsigned index = handle_index(object_handle);
if (index >= sizeof(p11_objects) / sizeof(*p11_objects))
return NULL;
p11_object_t *object = &p11_objects[index];
if (object->handle != object_handle)
return NULL;
return object;
}
/*
* Translate CKA_TOKEN value to handle flavor.
*/
static inline handle_flavor_t p11_object_flavor_from_cka_token(const CK_BBOOL *bbool)
{
return (bbool != NULL && *bbool) ? handle_flavor_token_object : handle_flavor_session_object;
}
static inline hal_key_flags_t p11_object_hal_flags(const CK_OBJECT_HANDLE handle)
{
return handle_flavor(handle) == handle_flavor_token_object ? HAL_KEY_FLAG_TOKEN : 0;
}
/*
* Open the HSM pkey object (if any) corresponding to the PKCS #11 handle.
*/
static int p11_object_pkey_open(const p11_session_t *session,
const CK_OBJECT_HANDLE object_handle,
hal_pkey_handle_t *pkey)
{
const p11_object_t *object = p11_object_by_handle(object_handle);
return (session != NULL && pkey != NULL && object != NULL &&
hal_check(hal_rpc_pkey_open(p11_session_hal_client(session),
p11_session_hal_session(session),
pkey, &object->uuid,
p11_object_hal_flags(object_handle))));
}
/*
* Check access rights for an object.
*/
typedef enum { p11_object_access_read, p11_object_access_write } p11_object_access_t;
static CK_RV p11_object_check_rights(const p11_session_t *session,
const CK_OBJECT_HANDLE object_handle,
const p11_object_access_t rights,
const CK_BBOOL cka_private,
const CK_BBOOL cka_token)
{
CK_RV rv;
if (session == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
/*
* Read-only sessions are, um, read-only. Well, except, in PKCS #11,
* read-only only sort of means what you might expect.
*/
if (rights == p11_object_access_write) {
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
if (cka_private)
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
case CKS_RO_USER_FUNCTIONS:
if (cka_token)
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
}
}
/*
* Private objects don't exist for sessions in the wrong state.
*/
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
case CKS_RW_PUBLIC_SESSION:
case CKS_RW_SO_FUNCTIONS:
if (cka_private)
lose(CKR_OBJECT_HANDLE_INVALID);
}
#warning Want session-object visibility sanity check here?
/*
* At this point the old code checked for objects which are not
* supposed to be visible to this session. In theory, the keystore
* now handles that, but we might want a sanity check here too.
*/
rv = CKR_OK;
fail:
return rv;
}
/*
* Create pkeys to go with PKCS #11 key objects loaded by C_CreateObject().
*/
static int p11_object_create_rsa_public_key(const p11_session_t * const session,
const handle_flavor_t flavor,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_len,
const p11_descriptor_t * const descriptor,
CK_OBJECT_HANDLE_PTR phObject,
const hal_key_flags_t flags)
{
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)}
};
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
uint8_t keybuf[hal_rsa_key_t_size];
hal_rsa_key_t *key = NULL;
hal_uuid_t uuid;
const uint8_t *cka_modulus = NULL;
size_t cka_modulus_len = 0;
const uint8_t *cka_public_exponent = const_0x010001;
size_t cka_public_exponent_len = sizeof(const_0x010001);
for (int i = 0; i < template_len; i++) {
const void * const val = template[i].pValue;
const size_t len = template[i].ulValueLen;
switch (template[i].type) {
case CKA_MODULUS: cka_modulus = val; cka_modulus_len = len; break;
case CKA_PUBLIC_EXPONENT: cka_public_exponent = val; cka_public_exponent_len = len; break;
}
}
int ok = hal_check(hal_rsa_key_load_public(&key, keybuf, sizeof(keybuf),
cka_modulus, cka_modulus_len,
cka_public_exponent, cka_public_exponent_len));
if (ok) {
uint8_t der[hal_rsa_public_key_to_der_len(key)];
ok = (hal_check(hal_rsa_public_key_to_der(key, der, NULL, sizeof(der))) &&
hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&pkey, HAL_KEY_TYPE_RSA_PUBLIC, HAL_CURVE_NONE,
&uuid, der, sizeof(der), flags)));
}
if (ok)
ok = p11_attributes_set(pkey, template, template_len, descriptor,
extra, sizeof(extra)/sizeof(*extra));
if (ok) {
*phObject = p11_object_allocate(flavor, &uuid, session);
ok = *phObject != CK_INVALID_HANDLE;
}
if (!ok && pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_delete(pkey);
else
(void) hal_rpc_pkey_close(pkey);
return ok;
}
static int p11_object_create_ec_public_key(const p11_session_t * const session,
const handle_flavor_t flavor,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_len,
const p11_descriptor_t * const descriptor,
CK_OBJECT_HANDLE_PTR phObject,
const hal_key_flags_t flags)
{
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)}
};
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
uint8_t keybuf[hal_ecdsa_key_t_size];
hal_ecdsa_key_t *key = NULL;
hal_curve_name_t curve;
hal_uuid_t uuid;
const uint8_t *cka_ec_point = NULL; size_t cka_ec_point_len = 0;
const uint8_t *cka_ec_params = NULL; size_t cka_ec_params_len = 0;
for (int i = 0; i < template_len; i++) {
const void * const val = template[i].pValue;
const size_t len = template[i].ulValueLen;
switch (template[i].type) {
case CKA_EC_POINT: cka_ec_point = val; cka_ec_point_len = len; break;
case CKA_EC_PARAMS: cka_ec_params = val; cka_ec_params_len = len; break;
}
}
int ok
= (ec_curve_oid_to_name(cka_ec_params, cka_ec_params_len, &curve) &&
hal_check(hal_ecdsa_key_from_ecpoint(&key, keybuf, sizeof(keybuf),
cka_ec_point, cka_ec_point_len,
curve)));
if (ok) {
uint8_t der[hal_ecdsa_public_key_to_der_len(key)];
ok = (hal_check(hal_ecdsa_public_key_to_der(key, der, NULL, sizeof(der))) &&
hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&pkey, HAL_KEY_TYPE_EC_PUBLIC, curve,
&uuid, der, sizeof(der), flags)));
}
if (ok)
ok = p11_attributes_set(pkey, template, template_len, descriptor,
extra, sizeof(extra)/sizeof(*extra));
if (ok) {
*phObject = p11_object_allocate(flavor, &uuid, session);
ok = *phObject != CK_INVALID_HANDLE;
}
if (!ok && pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_delete(pkey);
else
(void) hal_rpc_pkey_close(pkey);
return ok;
}
static int p11_object_create_rsa_private_key(const p11_session_t * const session,
const handle_flavor_t flavor,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_len,
const p11_descriptor_t * const descriptor,
CK_OBJECT_HANDLE_PTR phObject,
const hal_key_flags_t flags)
{
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)},
{.type = CKA_ALWAYS_SENSITIVE, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)},
{.type = CKA_NEVER_EXTRACTABLE, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)}
};
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
uint8_t keybuf[hal_rsa_key_t_size];
hal_rsa_key_t *key = NULL;
hal_uuid_t uuid;
const uint8_t *cka_modulus = NULL; size_t cka_modulus_len = 0;
const uint8_t *cka_private_exponent = NULL; size_t cka_private_exponent_len = 0;
const uint8_t *cka_prime_1 = NULL; size_t cka_prime_1_len = 0;
const uint8_t *cka_prime_2 = NULL; size_t cka_prime_2_len = 0;
const uint8_t *cka_exponent_1 = NULL; size_t cka_exponent_1_len = 0;
const uint8_t *cka_exponent_2 = NULL; size_t cka_exponent_2_len = 0;
const uint8_t *cka_coefficient = NULL; size_t cka_coefficient_len = 0;
const uint8_t *cka_public_exponent = const_0x010001;
size_t cka_public_exponent_len = sizeof(const_0x010001);
for (int i = 0; i < template_len; i++) {
const void * const val = template[i].pValue;
const size_t len = template[i].ulValueLen;
switch (template[i].type) {
case CKA_MODULUS: cka_modulus = val; cka_modulus_len = len; break;
case CKA_PUBLIC_EXPONENT: cka_public_exponent = val; cka_public_exponent_len = len; break;
case CKA_PRIVATE_EXPONENT: cka_private_exponent = val; cka_private_exponent_len = len; break;
case CKA_PRIME_1: cka_prime_1 = val; cka_prime_1_len = len; break;
case CKA_PRIME_2: cka_prime_2 = val; cka_prime_2_len = len; break;
case CKA_EXPONENT_1: cka_exponent_1 = val; cka_exponent_1_len = len; break;
case CKA_EXPONENT_2: cka_exponent_2 = val; cka_exponent_2_len = len; break;
case CKA_COEFFICIENT: cka_coefficient = val; cka_coefficient_len = len; break;
}
}
int ok = hal_check(hal_rsa_key_load_private(&key, keybuf, sizeof(keybuf),
cka_modulus, cka_modulus_len,
cka_public_exponent, cka_public_exponent_len,
cka_private_exponent, cka_private_exponent_len,
cka_prime_1, cka_prime_1_len,
cka_prime_2, cka_prime_2_len,
cka_coefficient, cka_coefficient_len,
cka_exponent_1, cka_exponent_1_len,
cka_exponent_2, cka_exponent_2_len));
if (ok) {
uint8_t der[hal_rsa_private_key_to_der_len(key)];
ok = (hal_check(hal_rsa_private_key_to_der(key, der, NULL, sizeof(der))) &&
hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&pkey, HAL_KEY_TYPE_RSA_PRIVATE,
HAL_CURVE_NONE, &uuid,
der, sizeof(der), flags)));
memset(der, 0, sizeof(der));
}
memset(keybuf, 0, sizeof(keybuf));
if (ok)
ok = p11_attributes_set(pkey, template, template_len, descriptor,
extra, sizeof(extra)/sizeof(*extra));
if (ok) {
*phObject = p11_object_allocate(flavor, &uuid, session);
ok = *phObject != CK_INVALID_HANDLE;
}
if (!ok && pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_delete(pkey);
else
(void) hal_rpc_pkey_close(pkey);
return ok;
}
static int p11_object_create_ec_private_key(const p11_session_t * const session,
const handle_flavor_t flavor,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_len,
const p11_descriptor_t * const descriptor,
CK_OBJECT_HANDLE_PTR phObject,
const hal_key_flags_t flags)
{
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)},
{.type = CKA_ALWAYS_SENSITIVE, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)},
{.type = CKA_NEVER_EXTRACTABLE, .value = &const_CK_FALSE, .length = sizeof(const_CK_FALSE)}
};
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
uint8_t keybuf[hal_ecdsa_key_t_size];
hal_ecdsa_key_t *key = NULL;
hal_curve_name_t curve;
hal_uuid_t uuid;
const uint8_t *cka_value = NULL; size_t cka_value_len = 0;
const uint8_t *cka_ec_point = NULL; size_t cka_ec_point_len = 0;
const uint8_t *cka_ec_params = NULL; size_t cka_ec_params_len = 0;
for (int i = 0; i < template_len; i++) {
const void * const val = template[i].pValue;
const size_t len = template[i].ulValueLen;
switch (template[i].type) {
case CKA_VALUE: cka_value = val; cka_value_len = len; break;
case CKA_EC_POINT: cka_ec_point = val; cka_ec_point_len = len; break;
case CKA_EC_PARAMS: cka_ec_params = val; cka_ec_params_len = len; break;
}
}
int ok
= (ec_curve_oid_to_name(cka_ec_params, cka_ec_params_len, &curve) &&
hal_check(hal_ecdsa_key_load_private(&key, keybuf, sizeof(keybuf), curve,
cka_ec_point + 1 + 0 * cka_ec_point_len / 2,
cka_ec_point_len / 2,
cka_ec_point + 1 + 1 * cka_ec_point_len / 2,
cka_ec_point_len / 2,
cka_value,
cka_value_len)));
if (ok) {
uint8_t der[hal_ecdsa_private_key_to_der_len(key)];
ok = (hal_check(hal_ecdsa_private_key_to_der(key, der, NULL, sizeof(der))) &&
hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&pkey, HAL_KEY_TYPE_EC_PRIVATE, curve,
&uuid, der, sizeof(der), flags)));
memset(der, 0, sizeof(der));
}
memset(keybuf, 0, sizeof(keybuf));
if (ok)
ok = p11_attributes_set(pkey, template, template_len, descriptor,
extra, sizeof(extra)/sizeof(*extra));
if (ok) {
*phObject = p11_object_allocate(flavor, &uuid, session);
ok = *phObject != CK_INVALID_HANDLE;
}
if (!ok && pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_delete(pkey);
else
(void) hal_rpc_pkey_close(pkey);
return ok;
}
/*
* Session methods.
*/
/*
* Create a new session.
*/
static p11_session_t *p11_session_allocate(void)
{
static unsigned next_index, nonce;
const unsigned last_index = next_index;
p11_session_t *session = NULL;
if (p11_sessions_in_use >= sizeof(p11_sessions) / sizeof(*p11_sessions))
return NULL;
do {
next_index = (next_index + 1) % (sizeof(p11_sessions) / sizeof(*p11_sessions));
if (next_index == last_index)
return NULL;
if (next_index == 0)
++nonce;
session = &p11_sessions[next_index];
} while (session->handle != CK_INVALID_HANDLE);
memset(session, 0, sizeof(*session));
session->handle = handle_compose(handle_flavor_session, nonce, next_index);
p11_sessions_in_use++;
return session;
}
/*
* Free a session.
*/
static void p11_session_free(p11_session_t *session)
{
if (session == NULL)
return;
assert(p11_sessions_in_use > 0);
if (session->find_query)
free(session->find_query);
(void) hal_rpc_hash_finalize(session->digest_handle, NULL, 0);
(void) hal_rpc_hash_finalize(session->sign_digest_handle, NULL, 0);
(void) hal_rpc_hash_finalize(session->verify_digest_handle, NULL, 0);
memset(session, 0, sizeof(*session));
if (--p11_sessions_in_use == 0)
logged_in_as = not_logged_in;
}
/*
* Find a session.
*/
static p11_session_t *p11_session_find(const CK_SESSION_HANDLE session_handle)
{
if (handle_flavor(session_handle) != handle_flavor_session)
return NULL;
const unsigned index = handle_index(session_handle);
if (index >= sizeof(p11_sessions) / sizeof(*p11_sessions))
return NULL;
p11_session_t *session = &p11_sessions[index];
if (session->handle != session_handle)
return NULL;
return session;
}
/*
* Iterate over session handles. Start with CK_INVALID_HANDLE,
* returns CK_INVALID_HANDLE when done.
*
* This does not verify the provided session handle, because we want
* to be able to modify the sessions this finds, including deleting
* them (which invalidates the session handle). Don't trust the
* returned handle until it has been blessed by p11_session_find().
*/
static CK_SESSION_HANDLE p11_session_handle_iterate(const CK_SESSION_HANDLE session_handle)
{
unsigned index;
if (session_handle == CK_INVALID_HANDLE)
index = 0;
else if (handle_flavor(session_handle) == handle_flavor_session)
index = handle_index(session_handle) + 1;
else
return CK_INVALID_HANDLE;
for (; index < sizeof(p11_sessions) / sizeof(*p11_sessions); index++)
if (handle_flavor(p11_sessions[index].handle) == handle_flavor_session)
return p11_sessions[index].handle;
return CK_INVALID_HANDLE;
}
/*
* Same thing, but return session objects instead of session handles.
* This is just syntactic sugar around a common idiom.
*/
static p11_session_t *p11_session_iterate(p11_session_t *session)
{
const CK_SESSION_HANDLE handle = session == NULL ? CK_INVALID_HANDLE : session->handle;
return p11_session_find(p11_session_handle_iterate(handle));
}
/*
* Delete all sessions. Have to use p11_session_handle_iterate() here.
*/
static void p11_session_free_all(void)
{
for (CK_SESSION_HANDLE handle = p11_session_handle_iterate(CK_INVALID_HANDLE);
handle != CK_INVALID_HANDLE; handle = p11_session_handle_iterate(handle))
p11_session_free(p11_session_find(handle));
}
/*
* Check session database against login state for consistency.
*
* This is mostly useful in assertions.
*/
static int p11_session_consistent_login(void)
{
switch (logged_in_as) {
case not_logged_in:
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session))
if (session->state != CKS_RO_PUBLIC_SESSION && session->state != CKS_RW_PUBLIC_SESSION)
return 0;
return 1;
case logged_in_as_user:
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session))
if (session->state != CKS_RO_USER_FUNCTIONS && session->state != CKS_RW_USER_FUNCTIONS)
return 0;
return 1;
case logged_in_as_so:
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session))
if (session->state != CKS_RW_SO_FUNCTIONS)
return 0;
return 1;
default:
return 0;
}
}
/*
* PKCS #11 likes space-padded rather than null-terminated strings.
* This requires minor antics so that we can use a printf()-like API
* while neither overflowing the caller's buffer nor truncating the
* output if it happens to be exactly the target length.
*/
static int psnprintf(void *buffer_, size_t size, const char *format, ...)
{
char buffer[size + 1];
size_t i, n;
va_list ap;
va_start(ap, format);
i = n = vsnprintf(buffer, sizeof(buffer), format, ap);
va_end(ap);
while (i < size)
buffer[i++] = ' ';
memcpy(buffer_, buffer, size);
return n;
}
/*
* Template checking and key generation.
*/
/*
* First pass: called once per template entry during initial pass over
* template to handle generic checks that apply regardless of
* attribute type.
*/
static CK_RV p11_template_check_1(const CK_ATTRIBUTE_TYPE type,
const void * const val,
const size_t len,
const p11_descriptor_t * const descriptor,
unsigned long forbidden_flag)
{
const p11_attribute_descriptor_t * const atd = p11_find_attribute_in_descriptor(descriptor, type);
CK_RV rv;
/* Attribute not allowed or not allowed for key generation */
if (atd == NULL || (atd->flags & forbidden_flag) != 0)
lose(CKR_ATTRIBUTE_TYPE_INVALID);
/* NULL or wrong-sized attribute values */
if (val == NULL || (atd->size != 0 && len != atd->size))
lose(CKR_ATTRIBUTE_VALUE_INVALID);
/* Attributes which only the SO user is allowed to set to CK_TRUE */
if ((atd->flags & P11_DESCRIPTOR_ONLY_SO_USER_CAN_SET) != 0 && logged_in_as != logged_in_as_so && *(CK_BBOOL *) val)
lose(CKR_ATTRIBUTE_VALUE_INVALID);
/* Attributes which don't match mandatory values */
if (atd->value != NULL && (atd->flags & P11_DESCRIPTOR_DEFAULT_VALUE) == 0 && memcmp(val, atd->value, atd->length) != 0)
lose(CKR_TEMPLATE_INCONSISTENT);
#warning Add _LATCH checks here?
rv = CKR_OK;
fail:
#if DEBUG_PKCS11
if (rv != CKR_OK)
fprintf(stderr, "\np11_template_check_1() rejected attribute 0x%08lx\n", (unsigned long) type);
#endif
return rv;
}
/*
* Second pass: called once per template to check that each attribute
* required for that template has been specified exactly once.
*/
static CK_RV p11_template_check_2(const p11_session_t *session,
const p11_descriptor_t * const descriptor,
const CK_ATTRIBUTE_PTR template,
const CK_ULONG template_length,
unsigned long required_flag,
unsigned long forbidden_flag)
{
const CK_BBOOL *object_is_private;
CK_RV rv;
int i, j;
/*
* Some session states aren't allowed to play with private objects.
*/
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
case CKS_RW_PUBLIC_SESSION:
case CKS_RW_SO_FUNCTIONS:
if ((object_is_private = p11_attribute_find_value_in_template(CKA_PRIVATE, template, template_length)) == NULL) {
const p11_attribute_descriptor_t * const atd = p11_find_attribute_in_descriptor(descriptor, CKA_PRIVATE);
assert(atd != NULL && atd->value != NULL);
object_is_private = atd->value;
}
if (*object_is_private)
lose(CKR_TEMPLATE_INCONSISTENT);
}
for (i = 0; i < descriptor->n_attributes; i++) {
const p11_attribute_descriptor_t * const atd = &descriptor->attributes[i];
const int required_by_api = (atd->flags & required_flag) != 0;
const int forbidden_by_api = (atd->flags & forbidden_flag) != 0;
const int in_descriptor = (atd->flags & P11_DESCRIPTOR_DEFAULT_VALUE) != 0 || atd->value != NULL;
const int pos_in_template = p11_attribute_find_in_template(atd->type, template, template_length);
/* Multiple entries for same attribute */
if (pos_in_template >= 0)
for (j = pos_in_template + 1; j < template_length; j++)
if (template[j].type == atd->type)
lose(CKR_TEMPLATE_INCONSISTENT);
/* Required attribute missing from template */
if (!forbidden_by_api && (required_by_api || !in_descriptor) && pos_in_template < 0) {
#if DEBUG_PKCS11
fprintf(stderr, "\n[Missing attribute 0x%lx]\n", atd->type);
#endif
lose(CKR_TEMPLATE_INCOMPLETE);
}
}
rv = CKR_OK;
fail:
return rv;
}
/*
* Mechanism-independent checks for templates and descriptors when
* generating new keypairs.
*
* PKCS #11 gives the application far too much rope (including but not
* limited to the ability to supply completely unrelated templates for
* public and private keys in a keypair), so we need to do a fair
* amount of checking. We automate as much of the dumb stuff as
* possible through the object descriptor.
*
* Key usage handling here is based on RFC 5280 4.2.1.3.
*/
static CK_RV p11_check_keypair_attributes(const p11_session_t *session,
const CK_ATTRIBUTE_PTR pPublicKeyTemplate,
const CK_ULONG ulPublicKeyAttributeCount,
const p11_descriptor_t * const public_descriptor,
hal_key_flags_t *public_flags,
const CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
const CK_ULONG ulPrivateKeyAttributeCount,
const p11_descriptor_t * const private_descriptor,
hal_key_flags_t *private_flags)
{
CK_RV rv = CKR_OK;
int i;
assert(session != NULL &&
pPublicKeyTemplate != NULL && public_descriptor != NULL && public_flags != NULL &&
pPrivateKeyTemplate != NULL && private_descriptor != NULL && private_flags != NULL);
*public_flags = *private_flags = 0;
const CK_BBOOL * public_cka_private = NULL, * public_cka_token = NULL;
const CK_BBOOL *private_cka_private = NULL, *private_cka_token = NULL;
/*
* Check values provided in the public and private templates.
*/
for (i = 0; i < ulPublicKeyAttributeCount; i++) {
const CK_ATTRIBUTE_TYPE type = pPublicKeyTemplate[i].type;
const void * const val = pPublicKeyTemplate[i].pValue;
const size_t len = pPublicKeyTemplate[i].ulValueLen;
if ((rv = p11_template_check_1(type, val, len, public_descriptor,
P11_DESCRIPTOR_FORBIDDEN_BY_GENERATE)) != CKR_OK)
goto fail;
if (type == CKA_TOKEN)
public_cka_token = val;
if (type == CKA_PRIVATE)
public_cka_private = val;
p11_attribute_apply_keyusage(public_flags, type, val);
}
for (i = 0; i < ulPrivateKeyAttributeCount; i++) {
const CK_ATTRIBUTE_TYPE type = pPrivateKeyTemplate[i].type;
const void * const val = pPrivateKeyTemplate[i].pValue;
const size_t len = pPrivateKeyTemplate[i].ulValueLen;
if ((rv = p11_template_check_1(type, val, len, private_descriptor,
P11_DESCRIPTOR_FORBIDDEN_BY_GENERATE)) != CKR_OK)
goto fail;
if (type == CKA_TOKEN)
public_cka_token = val;
if (type == CKA_PRIVATE)
public_cka_private = val;
p11_attribute_apply_keyusage(private_flags, type, val);
}
/*
* We insist that keyusage be specified for both public and private
* key, and that they match. May not need to be this strict.
*/
if (*public_flags != *private_flags || *public_flags == 0)
lose(CKR_TEMPLATE_INCONSISTENT);
/*
* Check that all required attributes have been specified.
*/
if ((rv = p11_template_check_2(session,
public_descriptor,
pPublicKeyTemplate,
ulPublicKeyAttributeCount,
P11_DESCRIPTOR_REQUIRED_BY_GENERATE,
P11_DESCRIPTOR_FORBIDDEN_BY_GENERATE)) != CKR_OK ||
(rv = p11_template_check_2(session,
private_descriptor,
pPrivateKeyTemplate,
ulPrivateKeyAttributeCount,
P11_DESCRIPTOR_REQUIRED_BY_GENERATE,
P11_DESCRIPTOR_FORBIDDEN_BY_GENERATE)) != CKR_OK)
goto fail;
/*
* Read-only sessions can't create objects, doh.
* Well, except when they can, thanks, PKCS #11.
*/
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
if ((public_cka_private == NULL || *public_cka_private) ||
(private_cka_private == NULL || *private_cka_private))
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
case CKS_RO_USER_FUNCTIONS:
if ((public_cka_token != NULL && *public_cka_token) ||
(private_cka_token != NULL && *private_cka_token))
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
}
/*
* If we get this far, we're happy. Maybe.
*/
rv = CKR_OK;
fail:
return rv;
}
/*
* CKM_RSA_PKCS_KEY_PAIR_GEN key pair generation handler.
*/
static CK_RV generate_keypair_rsa_pkcs(p11_session_t *session,
const handle_flavor_t public_handle_flavor,
const CK_ATTRIBUTE_PTR pPublicKeyTemplate,
const CK_ULONG ulPublicKeyAttributeCount,
const p11_descriptor_t *public_descriptor,
CK_OBJECT_HANDLE_PTR phPublicKey,
const hal_key_flags_t public_flags,
const handle_flavor_t private_handle_flavor,
const CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
const CK_ULONG ulPrivateKeyAttributeCount,
const p11_descriptor_t *private_descriptor,
CK_OBJECT_HANDLE_PTR phPrivateKey,
const hal_key_flags_t private_flags,
const CK_MECHANISM_PTR pMechanism)
{
hal_pkey_handle_t public_pkey = {HAL_HANDLE_NONE}, private_pkey = {HAL_HANDLE_NONE};
const uint8_t *public_exponent = const_0x010001;
size_t public_exponent_len = sizeof(const_0x010001);
hal_uuid_t public_uuid, private_uuid;
CK_ULONG keysize = 0;
CK_RV rv;
assert(pPublicKeyTemplate != NULL && pPrivateKeyTemplate != NULL &&
public_descriptor != NULL && private_descriptor != NULL &&
phPublicKey != NULL && phPrivateKey != NULL &&
session != NULL && pMechanism != NULL);
for (int i = 0; i < ulPublicKeyAttributeCount; i++) {
const CK_ATTRIBUTE_TYPE type = pPublicKeyTemplate[i].type;
const void * const val = pPublicKeyTemplate[i].pValue;
const size_t len = pPublicKeyTemplate[i].ulValueLen;
switch (type) {
case CKA_MODULUS_BITS: /* Keysize in bits -- only allow multiples of 8 */
keysize = *(CK_ULONG *) val;
if ((keysize & 7) != 0)
return CKR_ATTRIBUTE_VALUE_INVALID;
continue;
case CKA_PUBLIC_EXPONENT:
public_exponent = val;
public_exponent_len = len;
continue;
}
}
if (keysize == 0)
return CKR_TEMPLATE_INCOMPLETE;
{
if (!hal_check(hal_rpc_pkey_generate_rsa(p11_session_hal_client(session),
p11_session_hal_session(session),
&private_pkey, &private_uuid, keysize,
public_exponent, public_exponent_len,
private_flags)))
lose(CKR_FUNCTION_FAILED);
uint8_t der[hal_rpc_pkey_get_public_key_len(private_pkey)], keybuf[hal_rsa_key_t_size];
size_t der_len, modulus_len;
hal_rsa_key_t *key = NULL;
if (!hal_check(hal_rpc_pkey_get_public_key(private_pkey, der, &der_len, sizeof(der))) ||
!hal_check(hal_rsa_public_key_from_der(&key, keybuf, sizeof(keybuf), der, der_len)) ||
!hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&public_pkey, HAL_KEY_TYPE_RSA_PUBLIC, HAL_CURVE_NONE,
&public_uuid, der, der_len, public_flags)) ||
!hal_check(hal_rsa_key_get_modulus(key, NULL, &modulus_len, 0)))
lose(CKR_FUNCTION_FAILED);
uint8_t modulus[modulus_len];
if (!hal_check(hal_rsa_key_get_modulus(key, modulus, NULL, sizeof(modulus))))
lose(CKR_FUNCTION_FAILED);
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL,
.value = &const_CK_TRUE, .length = sizeof(const_CK_TRUE)},
{.type = CKA_KEY_GEN_MECHANISM,
.value = &pMechanism->mechanism, .length = sizeof(pMechanism->mechanism)},
{.type = CKA_MODULUS,
.value = modulus, .length = modulus_len}
};
if (!p11_attributes_set(private_pkey, pPrivateKeyTemplate, ulPrivateKeyAttributeCount,
private_descriptor, extra, sizeof(extra)/sizeof(*extra)) ||
!p11_attributes_set(public_pkey, pPublicKeyTemplate, ulPublicKeyAttributeCount,
public_descriptor, extra, sizeof(extra)/sizeof(*extra)))
lose(CKR_FUNCTION_FAILED);
*phPrivateKey = p11_object_allocate(private_handle_flavor, &private_uuid, session);
*phPublicKey = p11_object_allocate(public_handle_flavor, &public_uuid, session);
if (*phPrivateKey == CK_INVALID_HANDLE || *phPublicKey == CK_INVALID_HANDLE)
lose(CKR_FUNCTION_FAILED);
}
rv = CKR_OK;
fail:
hal_rpc_pkey_close(private_pkey);
hal_rpc_pkey_close(public_pkey);
return rv;
}
/*
* CKM_EC_KEY_PAIR_GEN key pair generation handler.
*/
static CK_RV generate_keypair_ec(p11_session_t *session,
const handle_flavor_t public_handle_flavor,
const CK_ATTRIBUTE_PTR pPublicKeyTemplate,
const CK_ULONG ulPublicKeyAttributeCount,
const p11_descriptor_t *public_descriptor,
CK_OBJECT_HANDLE_PTR phPublicKey,
const hal_key_flags_t public_flags,
const handle_flavor_t private_handle_flavor,
const CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
const CK_ULONG ulPrivateKeyAttributeCount,
const p11_descriptor_t *private_descriptor,
CK_OBJECT_HANDLE_PTR phPrivateKey,
const hal_key_flags_t private_flags,
const CK_MECHANISM_PTR pMechanism)
{
hal_pkey_handle_t public_pkey = {HAL_HANDLE_NONE}, private_pkey = {HAL_HANDLE_NONE};
const CK_BYTE *params = NULL;
hal_curve_name_t curve;
size_t params_len;
hal_uuid_t public_uuid, private_uuid;
CK_RV rv;
assert(session != NULL && pPublicKeyTemplate != NULL && pPrivateKeyTemplate != NULL);
for (int i = 0; i < ulPublicKeyAttributeCount; i++) {
const CK_ATTRIBUTE_TYPE type = pPublicKeyTemplate[i].type;
const void * const val = pPublicKeyTemplate[i].pValue;
const size_t len = pPublicKeyTemplate[i].ulValueLen;
switch (type) {
case CKA_EC_PARAMS:
params = val;
params_len = len;
continue;
}
}
if (!ec_curve_oid_to_name(params, params_len, &curve))
return CKR_TEMPLATE_INCOMPLETE;
{
if (!hal_check(hal_rpc_pkey_generate_ec(p11_session_hal_client(session),
p11_session_hal_session(session),
&private_pkey, &private_uuid,
curve, private_flags)))
lose(CKR_FUNCTION_FAILED);
uint8_t der[hal_rpc_pkey_get_public_key_len(private_pkey)], keybuf[hal_ecdsa_key_t_size];
hal_ecdsa_key_t *key = NULL;
size_t der_len;
if (!hal_check(hal_rpc_pkey_get_public_key(private_pkey, der, &der_len, sizeof(der))) ||
!hal_check(hal_ecdsa_public_key_from_der(&key, keybuf, sizeof(keybuf), der, der_len)) ||
!hal_check(hal_rpc_pkey_load(p11_session_hal_client(session),
p11_session_hal_session(session),
&public_pkey, HAL_KEY_TYPE_EC_PUBLIC, curve,
&public_uuid, der, der_len, public_flags)))
lose(CKR_FUNCTION_FAILED);
uint8_t point[hal_ecdsa_key_to_ecpoint_len(key)];
if (!hal_check(hal_ecdsa_key_to_ecpoint(key, point, NULL, sizeof(point))))
lose(CKR_FUNCTION_FAILED);
const hal_rpc_pkey_attribute_t extra[] = {
{.type = CKA_LOCAL,
.value = &const_CK_TRUE, .length = sizeof(const_CK_TRUE)},
{.type = CKA_KEY_GEN_MECHANISM,
.value = &pMechanism->mechanism, .length = sizeof(pMechanism->mechanism)},
{.type = CKA_EC_PARAMS,
.value = params, .length = params_len},
{.type = CKA_EC_POINT,
.value = point, .length = sizeof(point)}
};
if (!p11_attributes_set(private_pkey, pPrivateKeyTemplate, ulPrivateKeyAttributeCount,
private_descriptor, extra, sizeof(extra)/sizeof(*extra) - 1) ||
!p11_attributes_set(public_pkey, pPublicKeyTemplate, ulPublicKeyAttributeCount,
public_descriptor, extra, sizeof(extra)/sizeof(*extra)))
lose(CKR_FUNCTION_FAILED);
*phPrivateKey = p11_object_allocate(private_handle_flavor, &private_uuid, session);
*phPublicKey = p11_object_allocate(public_handle_flavor, &public_uuid, session);
if (*phPrivateKey == CK_INVALID_HANDLE || *phPublicKey == CK_INVALID_HANDLE)
lose(CKR_FUNCTION_FAILED);
}
rv = CKR_OK;
fail:
hal_rpc_pkey_close(private_pkey);
hal_rpc_pkey_close(public_pkey);
return rv;
}
/*
* Key pair generation. This needs a mechanism-specific function to
* do the inner bits, but there's a lot of boilerplate.
*/
static CK_RV generate_keypair(p11_session_t *session,
const CK_MECHANISM_PTR pMechanism,
CK_RV (*mechanism_handler)(p11_session_t *session,
const handle_flavor_t public_handle_flavor,
const CK_ATTRIBUTE_PTR pPublicKeyTemplate,
const CK_ULONG ulPublicKeyAttributeCount,
const p11_descriptor_t *public_descriptor,
CK_OBJECT_HANDLE_PTR phPublicKey,
const hal_key_flags_t public_flags,
const handle_flavor_t private_handle_flavor,
const CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
const CK_ULONG ulPrivateKeyAttributeCount,
const p11_descriptor_t *private_descriptor,
CK_OBJECT_HANDLE_PTR phPrivateKey,
const hal_key_flags_t private_flags,
const CK_MECHANISM_PTR pMechanism),
const CK_ATTRIBUTE_PTR pPublicKeyTemplate,
const CK_ULONG ulPublicKeyAttributeCount,
const p11_descriptor_t * const public_descriptor,
CK_OBJECT_HANDLE_PTR phPublicKey,
const CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
const CK_ULONG ulPrivateKeyAttributeCount,
const p11_descriptor_t * const private_descriptor,
CK_OBJECT_HANDLE_PTR phPrivateKey)
{
handle_flavor_t public_handle_flavor = handle_flavor_session_object;
handle_flavor_t private_handle_flavor = handle_flavor_session_object;
hal_key_flags_t public_flags = 0;
hal_key_flags_t private_flags = 0;
CK_RV rv;
rv = p11_check_keypair_attributes(session,
pPublicKeyTemplate, ulPublicKeyAttributeCount,
public_descriptor, &public_flags,
pPrivateKeyTemplate, ulPrivateKeyAttributeCount,
private_descriptor, &private_flags);
if (rv != CKR_OK)
return rv;
assert(session != NULL && pMechanism != NULL &&
pPublicKeyTemplate != NULL && phPublicKey != NULL &&
pPrivateKeyTemplate != NULL && phPrivateKey != NULL);
for (int i = 0; i < ulPublicKeyAttributeCount; i++)
if (pPublicKeyTemplate[i].type == CKA_TOKEN)
public_handle_flavor = p11_object_flavor_from_cka_token(pPublicKeyTemplate[i].pValue);
for (int i = 0; i < ulPrivateKeyAttributeCount; i++)
if (pPrivateKeyTemplate[i].type == CKA_TOKEN)
private_handle_flavor = p11_object_flavor_from_cka_token(pPrivateKeyTemplate[i].pValue);
if (public_handle_flavor == handle_flavor_token_object)
public_flags |= HAL_KEY_FLAG_TOKEN;
if (private_handle_flavor == handle_flavor_token_object)
private_flags |= HAL_KEY_FLAG_TOKEN;
return mechanism_handler(session,
public_handle_flavor, pPublicKeyTemplate, ulPublicKeyAttributeCount,
public_descriptor, phPublicKey, public_flags,
private_handle_flavor, pPrivateKeyTemplate, ulPrivateKeyAttributeCount,
private_descriptor, phPrivateKey, private_flags,
pMechanism);
}
/*
* Mechanism-independent checks for templates and descriptors when
* import objects via C_CreateObject().
*
* Fun question exactly how calling code knows what descriptor to
* pass. p11_descriptor_from_key_type() will suffice for key objects.
* Drive off that bridge when we get to it.
*/
static CK_RV p11_check_create_attributes(const p11_session_t *session,
const CK_ATTRIBUTE_PTR pTemplate,
const CK_ULONG ulCount,
const p11_descriptor_t * const descriptor)
{
const CK_BBOOL *cka_private = NULL;
const CK_BBOOL *cka_token = NULL;
CK_RV rv = CKR_OK;
int i;
assert(session != NULL && pTemplate != NULL && descriptor != NULL);
/*
* Check values provided in the template.
*/
for (i = 0; i < ulCount; i++) {
const CK_ATTRIBUTE_TYPE type = pTemplate[i].type;
const void * const val = pTemplate[i].pValue;
const size_t len = pTemplate[i].ulValueLen;
if ((rv = p11_template_check_1(type, val, len, descriptor,
P11_DESCRIPTOR_FORBIDDEN_BY_CREATEOBJECT)) != CKR_OK)
goto fail;
if (type == CKA_TOKEN)
cka_token = val;
if (type == CKA_PRIVATE)
cka_private = val;
}
/*
* Check that all required attributes have been specified.
*/
if ((rv = p11_template_check_2(session, descriptor, pTemplate, ulCount,
P11_DESCRIPTOR_REQUIRED_BY_CREATEOBJECT,
P11_DESCRIPTOR_FORBIDDEN_BY_CREATEOBJECT)) != CKR_OK)
goto fail;
/*
* Read-only sessions can't create objects, doh.
* Well, except when they can, thanks, PKCS #11.
*/
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
if (cka_private == NULL || *cka_private)
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
case CKS_RO_USER_FUNCTIONS:
if (cka_token != NULL && *cka_token)
lose(CKR_SESSION_READ_ONLY);
/* Fall through */
}
/*
* If we get this far, we're happy. Maybe.
*/
rv = CKR_OK;
fail:
return rv;
}
/*
* Add data to a digest.
*/
static CK_RV digest_update(const p11_session_t * const session,
const hal_digest_algorithm_t algorithm,
hal_hash_handle_t *handle,
const uint8_t * const data, const size_t data_len)
{
assert(algorithm != HAL_DIGEST_ALGORITHM_NONE && handle != NULL && data != NULL);
if (handle->handle == HAL_HANDLE_NONE) {
switch (hal_rpc_hash_initialize(p11_session_hal_client(session),
p11_session_hal_session(session),
handle, algorithm, NULL, 0)) {
case HAL_OK:
break;
case HAL_ERROR_ALLOCATION_FAILURE:
return CKR_HOST_MEMORY;
default:
return CKR_FUNCTION_FAILED;
}
}
if (!hal_check(hal_rpc_hash_update(*handle, data, data_len)))
return CKR_FUNCTION_FAILED;
return CKR_OK;
}
/*
* Finish using a digest context, if we haven't already.
*/
static void digest_cleanup(hal_hash_handle_t *handle)
{
assert(handle != NULL);
if (handle->handle == HAL_HANDLE_NONE)
return;
(void) hal_rpc_hash_finalize(*handle, NULL, 0);
handle->handle = HAL_HANDLE_NONE;
}
/*
* Compute the length of a signature based on the key.
*/
static int get_signature_len(const hal_pkey_handle_t pkey,
size_t *signature_len)
{
assert(signature_len != NULL);
hal_rpc_pkey_attribute_t attribute;
uint8_t attribute_buffer[sizeof(CK_KEY_TYPE)];
hal_curve_name_t curve;
CK_BYTE oid[20];
attribute.type = CKA_KEY_TYPE;
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, &attribute, 1,
attribute_buffer, sizeof(attribute_buffer))))
return 0;
switch (*(CK_KEY_TYPE*)attribute.value) {
case CKK_RSA:
attribute.type = CKA_MODULUS;
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, &attribute, 1, NULL, 0)))
return 0;
*signature_len = attribute.length;
return 1;
case CKK_EC:
attribute.type = CKA_EC_PARAMS;
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, &attribute, 1, oid, sizeof(oid))) ||
!ec_curve_oid_to_name(attribute.value, attribute.length, &curve))
return 0;
switch (curve) {
case HAL_CURVE_P256: *signature_len = 64; return 1;
case HAL_CURVE_P384: *signature_len = 96; return 1;
case HAL_CURVE_P521: *signature_len = 132; return 1;
default: return 0;
}
}
return 0;
}
/*
* Generate a signature using the libhal RPC API.
*/
static CK_RV sign_hal_rpc(p11_session_t *session,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pSignature,
CK_ULONG_PTR pulSignatureLen)
{
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
size_t signature_len;
CK_RV rv;
assert(session != NULL && pulSignatureLen != NULL);
if (!p11_object_pkey_open(session, session->sign_key_handle, &pkey))
lose(CKR_FUNCTION_FAILED);
if (!get_signature_len(pkey, &signature_len))
lose(CKR_FUNCTION_FAILED);
rv = pSignature != NULL && signature_len > *pulSignatureLen ? CKR_BUFFER_TOO_SMALL : CKR_OK;
*pulSignatureLen = signature_len;
if (pSignature != NULL && rv == CKR_OK)
rv = p11_whine_from_hal(hal_rpc_pkey_sign(pkey, session->sign_digest_handle, pData, ulDataLen,
pSignature, &signature_len, signature_len));
/* Fall through */
fail:
hal_rpc_pkey_close(pkey);
return rv;
}
/*
* Verify a signature using the libhal RPC API.
*/
static CK_RV verify_hal_rpc(p11_session_t *session,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pSignature,
CK_ULONG ulSignatureLen)
{
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
CK_RV rv;
assert(session != NULL);
if (!p11_object_pkey_open(session, session->verify_key_handle, &pkey))
lose(CKR_FUNCTION_FAILED);
rv = p11_whine_from_hal(hal_rpc_pkey_verify(pkey, session->verify_digest_handle, pData, ulDataLen,
pSignature, ulSignatureLen));
/* Fall through */
fail:
hal_rpc_pkey_close(pkey);
return rv;
}
#warning May need to do something about truncating oversized hashes for ECDSA, see PKCS11 spec
/*
* PKCS #11 API functions.
*/
CK_RV C_Initialize(CK_VOID_PTR pInitArgs)
{
ENTER_PUBLIC_FUNCTION(C_Initialize);
CK_C_INITIALIZE_ARGS_PTR a = pInitArgs;
CK_RV rv;
/*
* We'd like to detect the error of calling this method more than
* once in a single process without an intervening call to
* C_Finalize(), but there's no completely portable way to do that
* when faced with things like the POSIX fork() system call. For
* the moment, we use a POSIX-specific check, but may need to
* generalize this for other platforms.
*/
#if USE_POSIX
if (initialized_pid == getpid())
lose(CKR_CRYPTOKI_ALREADY_INITIALIZED);
#endif
/*
* Sort out what the user wants to do about mutexes. Default is not
* to use mutexes at all.
*
* There's a chicken and egg problem here: setting up the global
* mutex and mutex function pointers creates a race condition, and
* there's no obvious action we can take which is robust in the face
* of pathological behavior by the caller such as simultaneous calls
* to this method with incompatible mutex primitives.
*
* Given that (a) it's an error to call this method more than once
* in the same process without an intervening F_Finalize() call, and
* given that (b) we haven't actually promised to do any kind of
* locking at all until this method returns CKR_OK, we punt
* responsibility for this pathological case back to the caller.
*/
mutex_cb_create = NULL;
mutex_cb_destroy = NULL;
mutex_cb_lock = NULL;
mutex_cb_unlock = NULL;
if (a != NULL) {
const int functions_provided = ((a->CreateMutex != NULL) +
(a->DestroyMutex != NULL) +
(a->LockMutex != NULL) +
(a->UnlockMutex != NULL));
/*
* Reserved is, um, reserved.
* Mutex parameters must either all be present or all be absent.
*/
if (a->pReserved != NULL || (functions_provided & 3) != 0)
lose(CKR_ARGUMENTS_BAD);
/*
* If the user provided mutex functions, use them. Otherwise, if
* the user wants locking, use POSIX mutexes or return an error
* depending on whether we have POSIX mutexes available.
* Otherwise, we don't need to use mutexes.
*/
if (functions_provided) {
mutex_cb_create = a->CreateMutex;
mutex_cb_destroy = a->DestroyMutex;
mutex_cb_lock = a->LockMutex;
mutex_cb_unlock = a->UnlockMutex;
}
else if ((a->flags & CKF_OS_LOCKING_OK) != 0) {
#if USE_PTHREADS
mutex_cb_create = posix_mutex_create;
mutex_cb_destroy = posix_mutex_destroy;
mutex_cb_lock = posix_mutex_lock;
mutex_cb_unlock = posix_mutex_unlock;
#else
lose(CKR_CANT_LOCK);
#endif
}
}
/*
* Now that we know which mutex implementation to use, set up a
* global mutex. We may want something finer grained later, but
* this is enough to preserve the basic API semantics.
*
* Open question whether we should lock at this point, given that
* until we return we haven't promised to do locking. Skip for now
* as it's simpler, fix later if it turns out to be a problem.
*/
if ((rv = mutex_create(&p11_global_mutex)) != CKR_OK)
goto fail;
/*
* Initialize libhal RPC channel.
*/
if (!hal_check(hal_rpc_client_init()))
lose(CKR_GENERAL_ERROR);
#if USE_POSIX
initialized_pid = getpid();
#endif
return CKR_OK;
fail:
return rv;
}
CK_RV C_Finalize(CK_VOID_PTR pReserved)
{
ENTER_PUBLIC_FUNCTION(C_Finalize);
CK_RV rv = CKR_OK;
if (pReserved != NULL)
return CKR_ARGUMENTS_BAD;
mutex_lock_or_return_failure(p11_global_mutex);
/*
* Destroy all current sessions.
*/
p11_session_free_all();
/*
* At this point we're pretty well committed to shutting down, so
* there's not much to be done if any of the rest of this fails.
*/
hal_rpc_client_close();
rv = mutex_unlock(p11_global_mutex);
(void) mutex_destroy(p11_global_mutex);
p11_global_mutex = NULL;
#if USE_POSIX
initialized_pid = 0;
#endif
return rv;
}
CK_RV C_GetFunctionList(CK_FUNCTION_LIST_PTR_PTR ppFunctionList)
{
ENTER_PUBLIC_FUNCTION(C_GetFunctionList);
/*
* Use pkcs11f.h to build dispatch vector for C_GetFunctionList().
* This should be const, but that's not what PKCS #11 says, oh well.
*
* This doesn't touch anything requiring locks, nor should it.
*/
static CK_FUNCTION_LIST ck_function_list = {
{ CRYPTOKI_VERSION_MAJOR, CRYPTOKI_VERSION_MINOR },
#define CK_PKCS11_FUNCTION_INFO(name) name,
#include "pkcs11f.h"
#undef CK_PKCS11_FUNCTION_INFO
};
if (ppFunctionList == NULL)
return CKR_ARGUMENTS_BAD;
*ppFunctionList = &ck_function_list;
return CKR_OK;
}
CK_RV C_GetSlotList(CK_BBOOL tokenPresent,
CK_SLOT_ID_PTR pSlotList,
CK_ULONG_PTR pulCount)
{
ENTER_PUBLIC_FUNCTION(C_GetSlotList);
/*
* We only have one slot, and it's hardwired.
* No locking required here as long as this holds.
*/
if (pulCount == NULL)
return CKR_ARGUMENTS_BAD;
if (pSlotList != NULL && *pulCount < 1)
return CKR_BUFFER_TOO_SMALL;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
*pulCount = 1;
if (pSlotList != NULL)
pSlotList[0] = P11_ONE_AND_ONLY_SLOT;
return CKR_OK;
}
CK_RV C_GetTokenInfo(CK_SLOT_ID slotID,
CK_TOKEN_INFO_PTR pInfo)
{
ENTER_PUBLIC_FUNCTION(C_GetTokenInfo);
/*
* No locking required here as long as we're just returning constants.
*/
if (pInfo == NULL)
return CKR_ARGUMENTS_BAD;
if (slotID != P11_ONE_AND_ONLY_SLOT)
return CKR_SLOT_ID_INVALID;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
memset(pInfo, 0, sizeof(*pInfo));
/*
* No real idea (yet) how we get many of the following parameters.
*
* pInfo->label is supposed to be set when the token is initialized.
* Not yet sure what that means in our context, but need something
* here or the libhsm test programs will bomb trying to find the
* right token, so hard-wire something for now.
*/
psnprintf(pInfo->label, sizeof(pInfo->label),
"Cryptech Token");
psnprintf(pInfo->manufacturerID, sizeof(pInfo->manufacturerID),
"Cryptech Project");
psnprintf(pInfo->model, sizeof(pInfo->model),
"%04x%04x%04x%04x",
P11_VERSION_HW_MAJOR, P11_VERSION_HW_MINOR,
P11_VERSION_SW_MAJOR, P11_VERSION_SW_MINOR);
psnprintf(pInfo->serialNumber, sizeof(pInfo->serialNumber),
"007");
pInfo->flags = CKF_RNG | CKF_LOGIN_REQUIRED | CKF_USER_PIN_INITIALIZED | CKF_TOKEN_INITIALIZED;
#warning Have not yet sorted out token flags
#if 0
CKF_RNG
CKF_WRITE_PROTECTED
CKF_LOGIN_REQUIRED
CKF_USER_PIN_INITIALIZED
CKF_RESTORE_KEY_NOT_NEEDED
CKF_CLOCK_ON_TOKEN
CKF_PROTECTED_AUTHENTICATION_PATH
CKF_DUAL_CRYPTO_OPERATIONS
CKF_TOKEN_INITIALIZED
CKF_SECONDARY_AUTHENTICATION
CKF_USER_PIN_COUNT_LOW
CKF_USER_PIN_FINAL_TRY
CKF_USER_PIN_LOCKED
CKF_USER_PIN_TO_BE_CHANGED
CKF_SO_PIN_COUNT_LOW
CKF_SO_PIN_FINAL_TRY
CKF_SO_PIN_LOCKED
CKF_SO_PIN_TO_BE_CHANGED
CKF_ERROR_STATE
#endif
#warning Much of the TOKEN_INFO we return is nonsense
pInfo->ulMaxSessionCount = CK_EFFECTIVELY_INFINITE;
pInfo->ulSessionCount = CK_UNAVAILABLE_INFORMATION;
pInfo->ulMaxRwSessionCount = CK_EFFECTIVELY_INFINITE;
pInfo->ulRwSessionCount = CK_UNAVAILABLE_INFORMATION;
pInfo->ulMaxPinLen = (CK_ULONG) hal_rpc_min_pin_length;
pInfo->ulMinPinLen = (CK_ULONG) hal_rpc_max_pin_length;
pInfo->ulTotalPublicMemory = CK_UNAVAILABLE_INFORMATION;
pInfo->ulFreePublicMemory = CK_UNAVAILABLE_INFORMATION;
pInfo->ulTotalPrivateMemory = CK_UNAVAILABLE_INFORMATION;
pInfo->ulFreePrivateMemory = CK_UNAVAILABLE_INFORMATION;
pInfo->hardwareVersion.major = P11_VERSION_HW_MAJOR;
pInfo->hardwareVersion.minor = P11_VERSION_HW_MINOR;
pInfo->firmwareVersion.major = P11_VERSION_SW_MAJOR;
pInfo->firmwareVersion.minor = P11_VERSION_SW_MINOR;
#warning Need to sort out hardware clock
#if 0
/*
* Eventually we expect cryptech devices to have their own hardware
* clocks. Not implemented yet.
*/
pInfo->utcTime;
#endif
return CKR_OK;
}
CK_RV C_OpenSession(CK_SLOT_ID slotID,
CK_FLAGS flags,
CK_VOID_PTR pApplication,
CK_NOTIFY Notify,
CK_SESSION_HANDLE_PTR phSession)
{
ENTER_PUBLIC_FUNCTION(C_OpenSession);
const int parallel_session = (flags & CKF_SERIAL_SESSION) == 0;
const int read_only_session = (flags & CKF_RW_SESSION) == 0;
p11_session_t *session = NULL;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if (slotID != P11_ONE_AND_ONLY_SLOT)
lose(CKR_SLOT_ID_INVALID);
if (phSession == NULL)
lose(CKR_ARGUMENTS_BAD);
if (parallel_session)
lose(CKR_SESSION_PARALLEL_NOT_SUPPORTED);
if ((session = p11_session_allocate()) == NULL)
lose(CKR_HOST_MEMORY);
switch (logged_in_as) {
case not_logged_in:
session->state = read_only_session ? CKS_RO_PUBLIC_SESSION : CKS_RW_PUBLIC_SESSION;
break;
case logged_in_as_user:
session->state = read_only_session ? CKS_RO_USER_FUNCTIONS : CKS_RW_USER_FUNCTIONS;
break;
case logged_in_as_so:
if (read_only_session)
lose(CKR_SESSION_READ_WRITE_SO_EXISTS);
session->state = CKS_RW_SO_FUNCTIONS;
break;
}
session->notify = Notify;
session->application = pApplication;
assert(p11_session_consistent_login());
if ((rv = mutex_unlock(p11_global_mutex)) != CKR_OK)
goto fail;
*phSession = session->handle;
return CKR_OK;
fail:
p11_session_free(session);
(void) mutex_unlock(p11_global_mutex);
return rv;
}
CK_RV C_CloseSession(CK_SESSION_HANDLE hSession)
{
ENTER_PUBLIC_FUNCTION(C_CloseSession);
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
p11_session_free(session);
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_CloseAllSessions(CK_SLOT_ID slotID)
{
ENTER_PUBLIC_FUNCTION(C_CloseAllSessions);
if (slotID != P11_ONE_AND_ONLY_SLOT)
return CKR_SLOT_ID_INVALID;
mutex_lock_or_return_failure(p11_global_mutex);
p11_session_free_all();
return mutex_unlock(p11_global_mutex);
}
CK_RV C_Login(CK_SESSION_HANDLE hSession,
CK_USER_TYPE userType,
CK_UTF8CHAR_PTR pPin,
CK_ULONG ulPinLen)
{
ENTER_PUBLIC_FUNCTION(C_Login);
const hal_client_handle_t client = {HAL_HANDLE_NONE};
hal_user_t user = HAL_USER_NONE;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if (pPin == NULL)
lose(CKR_ARGUMENTS_BAD);
/*
* Mind, I don't really know why this function takes a session
* handle, given that the semantics don't seem to call upon us to do
* anything special for "this" session.
*/
if (p11_session_find(hSession) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
/*
* Figure out which PIN we're checking.
* We don't (yet?) support CKU_CONTEXT_SPECIFIC.
*
* We don't currently support re-login without an intervening
* logout, so reject the login attempt if we're already logged in.
*
* Read-only SO is an illegal state, so reject the login attempt if
* we have any read-only sessions and we're trying to log in as SO.
*/
switch (userType) {
case CKU_USER:
switch (logged_in_as) {
case not_logged_in: break;
case logged_in_as_user: lose(CKR_USER_ALREADY_LOGGED_IN);
case logged_in_as_so: lose(CKR_USER_ANOTHER_ALREADY_LOGGED_IN);
}
user = HAL_USER_NORMAL;
break;
case CKU_SO:
switch (logged_in_as) {
case not_logged_in: break;
case logged_in_as_so: lose(CKR_USER_ALREADY_LOGGED_IN);
case logged_in_as_user: lose(CKR_USER_ANOTHER_ALREADY_LOGGED_IN);
}
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session))
if (session->state == CKS_RO_PUBLIC_SESSION)
lose(CKR_SESSION_READ_ONLY_EXISTS);
user = HAL_USER_SO;
break;
case CKU_CONTEXT_SPECIFIC:
lose(CKR_OPERATION_NOT_INITIALIZED);
default:
lose(CKR_USER_TYPE_INVALID);
}
/*
* Try to log in the HSM.
*/
if ((rv = p11_whine_from_hal(hal_rpc_login(client, user, (char *) pPin, ulPinLen))) != CKR_OK)
goto fail;
/*
* If we get here, the PIN was OK. Update global login state, then
* whack every session into the correct new state.
*/
assert(p11_session_consistent_login());
logged_in_as = userType == CKU_SO ? logged_in_as_so : logged_in_as_user;
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session)) {
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
assert(userType == CKU_USER);
session->state = CKS_RO_USER_FUNCTIONS;
continue;
case CKS_RW_PUBLIC_SESSION:
session->state = userType == CKU_SO ? CKS_RW_SO_FUNCTIONS : CKS_RW_USER_FUNCTIONS;
continue;
}
}
assert(p11_session_consistent_login());
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_Logout(CK_SESSION_HANDLE hSession)
{
ENTER_PUBLIC_FUNCTION(C_Logout);
const hal_client_handle_t client = {HAL_HANDLE_NONE};
p11_session_t *session = NULL;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
/*
* Mind, I don't really know why this function takes a session
* handle, given that the semantics don't seem to call upon us to do
* anything special for "this" session.
*/
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (logged_in_as == not_logged_in)
lose(CKR_USER_NOT_LOGGED_IN);
/*
* Delete any private session objects, clear handles for all private
* objects, and whack every existing session into the right state.
*/
{
assert(p11_session_consistent_login());
const hal_rpc_pkey_attribute_t attrs[] = {
{.type = CKA_PRIVATE, .value = &const_CK_TRUE, .length = sizeof(const_CK_TRUE)}
};
hal_uuid_t uuids[64];
unsigned n;
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session)) {
memset(uuids, 0, sizeof(uuids));
do {
rv = p11_whine_from_hal(hal_rpc_pkey_match(p11_session_hal_client(session),
p11_session_hal_session(session),
HAL_KEY_TYPE_NONE, HAL_CURVE_NONE,
0,
attrs, sizeof(attrs)/sizeof(*attrs),
uuids, &n, sizeof(uuids)/sizeof(*uuids),
&uuids[sizeof(uuids)/sizeof(*uuids) - 1]));
if (rv != CKR_OK)
goto fail;
for (int i = 0; i < n; i++) {
p11_object_free(p11_object_by_uuid(&uuids[i]));
hal_pkey_handle_t pkey;
rv = p11_whine_from_hal(hal_rpc_pkey_open(p11_session_hal_client(session),
p11_session_hal_session(session),
&pkey, &uuids[i], 0));
if (rv != CKR_OK)
goto fail;
if ((rv = p11_whine_from_hal(hal_rpc_pkey_delete(pkey))) != CKR_OK) {
(void) hal_rpc_pkey_close(pkey);
goto fail;
}
}
} while (n == sizeof(uuids)/sizeof(*uuids));
}
memset(uuids, 0, sizeof(uuids));
do {
rv = p11_whine_from_hal(hal_rpc_pkey_match(p11_session_hal_client(session),
p11_session_hal_session(session),
HAL_KEY_TYPE_NONE, HAL_CURVE_NONE,
HAL_KEY_FLAG_TOKEN,
attrs, sizeof(attrs)/sizeof(*attrs),
uuids, &n, sizeof(uuids)/sizeof(*uuids),
&uuids[sizeof(uuids)/sizeof(*uuids) - 1]));
if (rv != CKR_OK)
goto fail;
for (int i = 0; i < n; i++)
p11_object_free(p11_object_by_uuid(&uuids[i]));
} while (n == sizeof(uuids)/sizeof(*uuids));
for (p11_session_t *session = p11_session_iterate(NULL);
session != NULL; session = p11_session_iterate(session)) {
switch (session->state) {
case CKS_RO_USER_FUNCTIONS:
session->state = CKS_RO_PUBLIC_SESSION;
continue;
case CKS_RW_USER_FUNCTIONS:
case CKS_RW_SO_FUNCTIONS:
session->state = CKS_RW_PUBLIC_SESSION;
continue;
}
}
if ((rv = p11_whine_from_hal(hal_rpc_logout(client))) != CKR_OK)
goto fail;
logged_in_as = not_logged_in;
assert(p11_session_consistent_login());
}
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_CreateObject(CK_SESSION_HANDLE hSession,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount,
CK_OBJECT_HANDLE_PTR phObject)
{
ENTER_PUBLIC_FUNCTION(C_CreateObject);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pTemplate == NULL || phObject == NULL)
lose(CKR_ARGUMENTS_BAD);
const CK_OBJECT_CLASS * const cka_class = p11_attribute_find_value_in_template(CKA_CLASS, pTemplate, ulCount);
const CK_KEY_TYPE * const cka_key_type = p11_attribute_find_value_in_template(CKA_KEY_TYPE, pTemplate, ulCount);
const CK_BBOOL * const cka_token = p11_attribute_find_value_in_template(CKA_TOKEN, pTemplate, ulCount);
if (cka_class == NULL)
lose(CKR_TEMPLATE_INCOMPLETE);
switch (*cka_class) {
case CKO_PUBLIC_KEY:
case CKO_PRIVATE_KEY:
case CKO_SECRET_KEY:
break;
default:
lose(CKR_TEMPLATE_INCONSISTENT);
}
if (cka_key_type == NULL)
lose(CKR_TEMPLATE_INCOMPLETE);
const p11_descriptor_t * const
descriptor = p11_descriptor_from_key_type(*cka_class, *cka_key_type);
if (descriptor == NULL)
lose(CKR_TEMPLATE_INCONSISTENT);
if ((rv = p11_check_create_attributes(session, pTemplate, ulCount, descriptor)) != CKR_OK)
goto fail;
const handle_flavor_t flavor = p11_object_flavor_from_cka_token(cka_token);
switch (session->state) {
case CKS_RO_PUBLIC_SESSION:
case CKS_RO_USER_FUNCTIONS:
if (flavor == handle_flavor_token_object)
lose(CKR_SESSION_READ_ONLY);
}
hal_key_flags_t flags = flavor == handle_flavor_token_object ? HAL_KEY_FLAG_TOKEN : 0;
for (int i = 0; i < ulCount; i++)
p11_attribute_apply_keyusage(&flags, pTemplate[i].type, pTemplate[i].pValue);
int (*handler)(const p11_session_t *session,
const handle_flavor_t flavor,
const CK_ATTRIBUTE_PTR pTemplate,
const CK_ULONG ulCount,
const p11_descriptor_t * const descriptor,
CK_OBJECT_HANDLE_PTR phObject,
const hal_key_flags_t flags) = NULL;
if (*cka_class == CKO_PUBLIC_KEY && *cka_key_type == CKK_RSA)
handler = p11_object_create_rsa_public_key;
if (*cka_class == CKO_PUBLIC_KEY && *cka_key_type == CKK_EC)
handler = p11_object_create_ec_public_key;
if (*cka_class == CKO_PRIVATE_KEY && *cka_key_type == CKK_RSA)
handler = p11_object_create_rsa_private_key;
if (*cka_class == CKO_PRIVATE_KEY && *cka_key_type == CKK_EC)
handler = p11_object_create_ec_private_key;
if (handler == NULL)
lose(CKR_FUNCTION_FAILED);
if (!handler(session, flavor, pTemplate, ulCount, descriptor, phObject, flags))
lose(CKR_FUNCTION_FAILED);
return mutex_unlock(p11_global_mutex);
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_DestroyObject(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hObject)
{
ENTER_PUBLIC_FUNCTION(C_DestroyObject);
uint8_t attributes_buffer[2 * sizeof(CK_BBOOL)];
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
hal_rpc_pkey_attribute_t attributes[] = {
[0].type = CKA_PRIVATE,
[1].type = CKA_TOKEN
};
CK_BBOOL cka_private;
CK_BBOOL cka_token;
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
session = p11_session_find(hSession);
if (!p11_object_pkey_open(session, hObject, &pkey))
lose(CKR_FUNCTION_FAILED);
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, attributes, sizeof(attributes)/sizeof(*attributes),
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_KEY_HANDLE_INVALID);
cka_private = *(CK_BBOOL*) attributes[0].value;
cka_token = *(CK_BBOOL*) attributes[1].value;
rv = p11_object_check_rights(session, hObject, p11_object_access_write, cka_private, cka_token);
if (rv != CKR_OK)
goto fail;
if (!hal_check(hal_rpc_pkey_delete(pkey)))
lose(CKR_FUNCTION_FAILED);
p11_object_free(p11_object_by_handle(hObject));
fail:
if (pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_close(pkey);
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_GetAttributeValue(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hObject,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount)
{
ENTER_PUBLIC_FUNCTION(C_GetAttributeValue);
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
const p11_descriptor_t *descriptor = NULL;
CK_BBOOL cka_extractable, cka_sensitive;
CK_OBJECT_CLASS cka_class;
CK_BBOOL cka_private;
CK_BBOOL cka_token;
int sensitive_object = 0;
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if (pTemplate == NULL)
lose(CKR_ARGUMENTS_BAD);
session = p11_session_find(hSession);
if (!p11_object_pkey_open(session, hObject, &pkey))
lose(CKR_OBJECT_HANDLE_INVALID);
{
hal_rpc_pkey_attribute_t attributes[] = {
[0].type = CKA_CLASS,
[1].type = CKA_PRIVATE,
[2].type = CKA_TOKEN
};
uint8_t attributes_buffer[sizeof(CK_OBJECT_CLASS) + 2 * sizeof(CK_BBOOL)];
if (!hal_check(hal_rpc_pkey_get_attributes(pkey,
attributes, sizeof(attributes)/sizeof(*attributes),
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_OBJECT_HANDLE_INVALID);
cka_class = *(CK_OBJECT_CLASS*) attributes[0].value;
cka_private = *(CK_BBOOL*) attributes[1].value;
cka_token = *(CK_BBOOL*) attributes[2].value;
rv = p11_object_check_rights(session, hObject, p11_object_access_read, cka_private, cka_token);
if (rv != CKR_OK)
goto fail;
}
if (cka_class == CKO_PRIVATE_KEY || cka_class == CKO_SECRET_KEY) {
hal_rpc_pkey_attribute_t attributes[] = {
[0].type = CKA_EXTRACTABLE,
[1].type = CKA_SENSITIVE
};
uint8_t attributes_buffer[sizeof(CK_OBJECT_CLASS) + sizeof(CK_KEY_TYPE)];
if (!hal_check(hal_rpc_pkey_get_attributes(pkey,
attributes, sizeof(attributes)/sizeof(*attributes),
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_OBJECT_HANDLE_INVALID);
cka_extractable = *(CK_BBOOL*) attributes[0].value;
cka_sensitive = *(CK_BBOOL*) attributes[1].value;
sensitive_object = cka_sensitive || !cka_extractable;
}
{
hal_rpc_pkey_attribute_t attributes[ulCount];
memset(attributes, 0, sizeof(attributes));
for (int i = 0; i < ulCount; i++)
attributes[i].type = pTemplate[i].type;
if (!hal_check(hal_rpc_pkey_get_attributes(pkey,
attributes, sizeof(attributes)/sizeof(*attributes),
NULL, 0)))
lose(CKR_OBJECT_HANDLE_INVALID);
rv = CKR_OK;
size_t attributes_buffer_len = 0;
for (int i = 0; i < ulCount; i++) {
if (sensitive_object && p11_attribute_is_sensitive(descriptor, pTemplate[i].type)) {
pTemplate[i].ulValueLen = -1;
rv = CKR_ATTRIBUTE_SENSITIVE;
continue;
}
if (attributes[i].length == 0) {
pTemplate[i].ulValueLen = -1;
rv = CKR_ATTRIBUTE_TYPE_INVALID;
continue;
}
if (pTemplate[i].pValue == NULL) {
pTemplate[i].ulValueLen = attributes[i].length;
continue;
}
if (pTemplate[i].ulValueLen < attributes[i].length) {
pTemplate[i].ulValueLen = -1;
rv = CKR_BUFFER_TOO_SMALL;
continue;
}
attributes_buffer_len += attributes[i].length;
}
if (attributes_buffer_len == 0)
goto fail;
uint8_t attributes_buffer[attributes_buffer_len];
unsigned n = 0;
for (int i = 0; i < ulCount; i++)
if (pTemplate[i].pValue != NULL && pTemplate[i].ulValueLen != -1)
attributes[n++].type = pTemplate[i].type;
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, attributes, n,
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_OBJECT_HANDLE_INVALID);
for (int i = 0; i < n; i++) {
int j = p11_attribute_find_in_template(attributes[i].type, pTemplate, ulCount);
if (j < 0 || pTemplate[j].ulValueLen == -1 || pTemplate[j].ulValueLen < attributes[i].length)
lose(CKR_FUNCTION_FAILED);
memcpy(pTemplate[j].pValue, attributes[i].value, attributes[i].length);
pTemplate[j].ulValueLen = attributes[i].length;
}
}
fail:
if (pkey.handle != HAL_HANDLE_NONE) {
if (rv == CKR_OK)
rv = p11_whine_from_hal(hal_rpc_pkey_close(pkey));
else
(void) hal_rpc_pkey_close(pkey);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_FindObjectsInit(CK_SESSION_HANDLE hSession,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount)
{
ENTER_PUBLIC_FUNCTION(C_FindObjectsInit);
const size_t attributes_len = sizeof(hal_rpc_pkey_attribute_t) * (ulCount + 1);
size_t len = attributes_len;
CK_BBOOL *cka_private = NULL;
CK_BBOOL *cka_token = NULL;
p11_session_t *session;
CK_RV rv = CKR_OK;
uint8_t *mem;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (ulCount > 0 && pTemplate == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->find_query != NULL)
lose(CKR_OPERATION_ACTIVE);
assert(!session->find_query_token && !session->find_query_session);
for (int i = 0; i < ulCount; i++) {
if (pTemplate[i].pValue == NULL || pTemplate[i].ulValueLen == 0)
lose(CKR_ARGUMENTS_BAD);
len += pTemplate[i].ulValueLen;
}
if ((mem = malloc(len)) == NULL)
lose(CKR_HOST_MEMORY);
session->find_query = (hal_rpc_pkey_attribute_t *) mem;
mem += attributes_len;
for (int i = 0; i < ulCount; i++) {
len = pTemplate[i].ulValueLen;
session->find_query[i].type = pTemplate[i].type;
session->find_query[i].value = mem;
session->find_query[i].length = len;
memcpy(mem, pTemplate[i].pValue, len);
mem += len;
}
cka_private = p11_attribute_find_value_in_template(CKA_PRIVATE, pTemplate, ulCount);
cka_token = p11_attribute_find_value_in_template(CKA_TOKEN, pTemplate, ulCount);
session->find_query_n = ulCount;
session->find_query_token = cka_token == NULL || *cka_token;
session->find_query_session = cka_token == NULL || !*cka_token;
memset(&session->find_query_previous_uuid, 0, sizeof(session->find_query_previous_uuid));
/*
* Quietly enforce object privacy even if template tries to bypass,
* per PCKS #11 specification.
*/
if (logged_in_as != logged_in_as_user && cka_private == NULL) {
session->find_query[ulCount].type = CKA_PRIVATE;
session->find_query[ulCount].value = &const_CK_FALSE;
session->find_query[ulCount].length = sizeof(const_CK_FALSE);
session->find_query_n++;
}
if (logged_in_as != logged_in_as_user && cka_private != NULL && *cka_private) {
int i = p11_attribute_find_in_template(CKA_PRIVATE, pTemplate, ulCount);
assert(i >= 0 && i < ulCount);
session->find_query[i].value = &const_CK_FALSE;
session->find_query[i].length = sizeof(const_CK_FALSE);
}
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_FindObjects(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE_PTR phObject,
CK_ULONG ulMaxObjectCount,
CK_ULONG_PTR pulObjectCount)
{
ENTER_PUBLIC_FUNCTION(C_FindObjects);
hal_uuid_t previous_uuid = {{0}};
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (session->find_query == NULL)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (phObject == NULL || pulObjectCount == NULL)
lose(CKR_ARGUMENTS_BAD);
*pulObjectCount = 0;
while (*pulObjectCount < ulMaxObjectCount &&
(session->find_query_token || session->find_query_session)) {
hal_uuid_t uuids[ulMaxObjectCount - *pulObjectCount];
handle_flavor_t flavor;
hal_key_flags_t flags;
unsigned n;
if (session->find_query_token) {
flavor = handle_flavor_token_object;
flags = HAL_KEY_FLAG_TOKEN;
}
else {
flavor = handle_flavor_session_object;
flags = 0;
}
rv = p11_whine_from_hal(hal_rpc_pkey_match(p11_session_hal_client(session),
p11_session_hal_session(session),
HAL_KEY_TYPE_NONE, HAL_CURVE_NONE, flags,
session->find_query, session->find_query_n,
uuids, &n, sizeof(uuids)/sizeof(*uuids),
&previous_uuid));
if (rv != CKR_OK)
goto fail;
for (int i = 0; i < n; i++) {
phObject[*pulObjectCount] = p11_object_allocate(flavor, &uuids[i], session);
if (phObject[*pulObjectCount] == CK_INVALID_HANDLE)
lose(CKR_FUNCTION_FAILED);
++*pulObjectCount;
}
if (n == sizeof(uuids)/sizeof(*uuids)) {
memcpy(&session->find_query_previous_uuid, &uuids[n - 1],
sizeof(session->find_query_previous_uuid));
}
else {
memset(&session->find_query_previous_uuid, 0, sizeof(session->find_query_previous_uuid));
if (session->find_query_token)
session->find_query_token = 0;
else
session->find_query_session = 0;
}
}
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_FindObjectsFinal(CK_SESSION_HANDLE hSession)
{
ENTER_PUBLIC_FUNCTION(C_FindObjectsFinal);
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (session->find_query == NULL)
lose(CKR_OPERATION_NOT_INITIALIZED);
free(session->find_query);
session->find_query = NULL;
session->find_query_n = 0;
session->find_query_token = 0;
session->find_query_session = 0;
memset(&session->find_query_previous_uuid, 0, sizeof(session->find_query_previous_uuid));
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_DigestInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism)
{
ENTER_PUBLIC_FUNCTION(C_DigestInit);
hal_digest_algorithm_t algorithm;
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pMechanism == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->digest_algorithm != HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_OPERATION_ACTIVE);
switch (pMechanism->mechanism) {
case CKM_SHA_1: algorithm = HAL_DIGEST_ALGORITHM_SHA1; break;
case CKM_SHA224: algorithm = HAL_DIGEST_ALGORITHM_SHA224; break;
case CKM_SHA256: algorithm = HAL_DIGEST_ALGORITHM_SHA256; break;
case CKM_SHA384: algorithm = HAL_DIGEST_ALGORITHM_SHA384; break;
case CKM_SHA512: algorithm = HAL_DIGEST_ALGORITHM_SHA512; break;
default: lose(CKR_MECHANISM_INVALID);
}
session->digest_algorithm = algorithm;
return mutex_unlock(p11_global_mutex);
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_Digest(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pDigest,
CK_ULONG_PTR pulDigestLen)
{
ENTER_PUBLIC_FUNCTION(C_Digest);
p11_session_t *session;
size_t digest_len;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pData == NULL || pulDigestLen == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->digest_algorithm == HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (session->digest_handle.handle != HAL_HANDLE_NONE)
lose(CKR_OPERATION_ACTIVE);
if (!hal_check(hal_rpc_hash_get_digest_length(session->digest_algorithm, &digest_len)))
lose(CKR_FUNCTION_FAILED);
rv = pDigest != NULL && *pulDigestLen < digest_len ? CKR_BUFFER_TOO_SMALL : CKR_OK;
*pulDigestLen = digest_len;
if (pDigest == NULL || rv == CKR_BUFFER_TOO_SMALL)
mutex_unlock_return_with_rv(rv, p11_global_mutex);
if ((rv = digest_update(session, session->digest_algorithm,
&session->digest_handle, pData, ulDataLen)) != CKR_OK)
goto fail;
if (!hal_check(hal_rpc_hash_finalize(session->digest_handle, pDigest, *pulDigestLen)))
lose(CKR_FUNCTION_FAILED);
rv = CKR_OK; /* Fall through */
fail:
if (session != NULL) {
digest_cleanup(&session->digest_handle);
session->digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_DigestUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen)
{
ENTER_PUBLIC_FUNCTION(C_DigestUpdate);
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pPart == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->digest_algorithm == HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if ((rv = digest_update(session, session->digest_algorithm,
&session->digest_handle, pPart, ulPartLen)) != CKR_OK)
goto fail;
return mutex_unlock(p11_global_mutex);
fail:
if (session != NULL) {
digest_cleanup(&session->digest_handle);
session->digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_DigestFinal(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pDigest,
CK_ULONG_PTR pulDigestLen)
{
ENTER_PUBLIC_FUNCTION(C_DigestFinal);
p11_session_t *session;
size_t digest_len;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pulDigestLen == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->digest_algorithm == HAL_DIGEST_ALGORITHM_NONE || session->digest_handle.handle == HAL_HANDLE_NONE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (!hal_check(hal_rpc_hash_get_digest_length(session->digest_algorithm, &digest_len)))
lose(CKR_FUNCTION_FAILED);
rv = pDigest != NULL && *pulDigestLen < digest_len ? CKR_BUFFER_TOO_SMALL : CKR_OK;
*pulDigestLen = digest_len;
if (pDigest == NULL || rv == CKR_BUFFER_TOO_SMALL)
mutex_unlock_return_with_rv(rv, p11_global_mutex);
if (!hal_check(hal_rpc_hash_finalize(session->digest_handle, pDigest, *pulDigestLen)))
lose(CKR_FUNCTION_FAILED);
rv = CKR_OK; /* Fall through */
fail:
if (session != NULL) {
digest_cleanup(&session->digest_handle);
session->digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_SignInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey)
{
ENTER_PUBLIC_FUNCTION(C_SignInit);
uint8_t attributes_buffer[sizeof(CK_OBJECT_CLASS) + sizeof(CK_KEY_TYPE) + 3 * sizeof(CK_BBOOL)];
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
hal_rpc_pkey_attribute_t attributes[] = {
[0].type = CKA_KEY_TYPE,
[1].type = CKA_SIGN,
[2].type = CKA_PRIVATE,
[3].type = CKA_TOKEN
};
CK_KEY_TYPE cka_key_type;
CK_BBOOL cka_sign;
CK_BBOOL cka_private;
CK_BBOOL cka_token;
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pMechanism == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->sign_key_handle != CK_INVALID_HANDLE ||
session->sign_digest_algorithm != HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_OPERATION_ACTIVE);
if (!p11_object_pkey_open(session, hKey, &pkey))
lose(CKR_KEY_HANDLE_INVALID);
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, attributes, sizeof(attributes)/sizeof(*attributes),
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_KEY_HANDLE_INVALID);
cka_key_type = *(CK_KEY_TYPE*) attributes[0].value;
cka_sign = *(CK_BBOOL*) attributes[1].value;
cka_private = *(CK_BBOOL*) attributes[2].value;
cka_token = *(CK_BBOOL*) attributes[3].value;
rv = p11_object_check_rights(session, hKey, p11_object_access_read, cka_private, cka_token);
if (rv != CKR_OK)
goto fail;
if (!cka_sign)
lose(CKR_KEY_FUNCTION_NOT_PERMITTED);
switch (pMechanism->mechanism) {
case CKM_RSA_PKCS:
case CKM_SHA1_RSA_PKCS:
case CKM_SHA224_RSA_PKCS:
case CKM_SHA256_RSA_PKCS:
case CKM_SHA384_RSA_PKCS:
case CKM_SHA512_RSA_PKCS:
if (cka_key_type != CKK_RSA)
lose(CKR_KEY_TYPE_INCONSISTENT);
break;
case CKM_ECDSA:
case CKM_ECDSA_SHA224:
case CKM_ECDSA_SHA256:
case CKM_ECDSA_SHA384:
case CKM_ECDSA_SHA512:
if (cka_key_type != CKK_EC)
lose(CKR_KEY_TYPE_INCONSISTENT);
break;
default:
return CKR_MECHANISM_INVALID;
}
session->sign_key_handle = hKey;
switch (pMechanism->mechanism) {
case CKM_RSA_PKCS:
case CKM_ECDSA:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
break;
case CKM_SHA1_RSA_PKCS:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA1;
break;
case CKM_SHA224_RSA_PKCS:
case CKM_ECDSA_SHA224:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA224;
break;
case CKM_SHA256_RSA_PKCS:
case CKM_ECDSA_SHA256:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA256;
break;
case CKM_SHA384_RSA_PKCS:
case CKM_ECDSA_SHA384:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA384;
break;
case CKM_SHA512_RSA_PKCS:
case CKM_ECDSA_SHA512:
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA512;
break;
default:
return CKR_MECHANISM_INVALID;
}
rv = CKR_OK;
fail:
if (pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_close(pkey);
if (rv != CKR_OK && session != NULL) {
session->sign_key_handle = CK_INVALID_HANDLE;
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_Sign(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pSignature,
CK_ULONG_PTR pulSignatureLen)
{
ENTER_PUBLIC_FUNCTION(C_Sign);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pData == NULL || pulSignatureLen == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->sign_key_handle == CK_INVALID_HANDLE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (session->sign_digest_handle.handle != HAL_HANDLE_NONE)
lose(CKR_OPERATION_ACTIVE);
if (session->sign_digest_algorithm != HAL_DIGEST_ALGORITHM_NONE && pSignature != NULL) {
if ((rv = digest_update(session, session->sign_digest_algorithm,
&session->sign_digest_handle, pData, ulDataLen)) != CKR_OK)
goto fail;
pData = NULL;
ulDataLen = 0;
}
rv = sign_hal_rpc(session, pData, ulDataLen, pSignature, pulSignatureLen);
/* Fall through */
fail:
if (session != NULL && pSignature != NULL && rv != CKR_BUFFER_TOO_SMALL) {
session->sign_key_handle = CK_INVALID_HANDLE;
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->sign_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_SignUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen)
{
ENTER_PUBLIC_FUNCTION(C_SignUpdate);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pPart == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->sign_key_handle == CK_INVALID_HANDLE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (session->sign_digest_algorithm == HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_FUNCTION_FAILED);
if ((rv = digest_update(session, session->sign_digest_algorithm,
&session->sign_digest_handle, pPart, ulPartLen)) != CKR_OK)
goto fail;
return mutex_unlock(p11_global_mutex);
fail:
if (session != NULL) {
session->sign_key_handle = CK_INVALID_HANDLE;
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->sign_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_SignFinal(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pSignature,
CK_ULONG_PTR pulSignatureLen)
{
ENTER_PUBLIC_FUNCTION(C_SignFinal);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pulSignatureLen == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->sign_key_handle == CK_INVALID_HANDLE ||
session->sign_digest_handle.handle == HAL_HANDLE_NONE)
lose(CKR_OPERATION_NOT_INITIALIZED);
rv = sign_hal_rpc(session, NULL, 0, pSignature, pulSignatureLen);
/* Fall through */
fail:
if (session != NULL && pSignature != NULL && rv != CKR_BUFFER_TOO_SMALL) {
session->sign_key_handle = CK_INVALID_HANDLE;
session->sign_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->sign_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_VerifyInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey )
{
ENTER_PUBLIC_FUNCTION(C_VerifyInit);
uint8_t attributes_buffer[sizeof(CK_OBJECT_CLASS) + sizeof(CK_KEY_TYPE) + 3 * sizeof(CK_BBOOL)];
hal_pkey_handle_t pkey = {HAL_HANDLE_NONE};
hal_rpc_pkey_attribute_t attributes[] = {
[0].type = CKA_KEY_TYPE,
[1].type = CKA_VERIFY,
[2].type = CKA_PRIVATE,
[3].type = CKA_TOKEN
};
CK_KEY_TYPE cka_key_type;
CK_BBOOL cka_verify;
CK_BBOOL cka_private;
CK_BBOOL cka_token;
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pMechanism == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->verify_key_handle != CK_INVALID_HANDLE ||
session->verify_digest_algorithm != HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_OPERATION_ACTIVE);
if (!p11_object_pkey_open(session, hKey, &pkey))
lose(CKR_KEY_HANDLE_INVALID);
if (!hal_check(hal_rpc_pkey_get_attributes(pkey, attributes, sizeof(attributes)/sizeof(*attributes),
attributes_buffer, sizeof(attributes_buffer))))
lose(CKR_KEY_HANDLE_INVALID);
cka_key_type = *(CK_KEY_TYPE*) attributes[0].value;
cka_verify = *(CK_BBOOL*) attributes[1].value;
cka_private = *(CK_BBOOL*) attributes[2].value;
cka_token = *(CK_BBOOL*) attributes[3].value;
rv = p11_object_check_rights(session, hKey, p11_object_access_read, cka_private, cka_token);
if (rv != CKR_OK)
goto fail;
if (!cka_verify)
lose(CKR_KEY_FUNCTION_NOT_PERMITTED);
switch (pMechanism->mechanism) {
case CKM_RSA_PKCS:
case CKM_SHA1_RSA_PKCS:
case CKM_SHA224_RSA_PKCS:
case CKM_SHA256_RSA_PKCS:
case CKM_SHA384_RSA_PKCS:
case CKM_SHA512_RSA_PKCS:
if (cka_key_type != CKK_RSA)
lose(CKR_KEY_TYPE_INCONSISTENT);
break;
case CKM_ECDSA:
case CKM_ECDSA_SHA224:
case CKM_ECDSA_SHA256:
case CKM_ECDSA_SHA384:
case CKM_ECDSA_SHA512:
if (cka_key_type != CKK_EC)
lose(CKR_KEY_TYPE_INCONSISTENT);
break;
default:
return CKR_MECHANISM_INVALID;
}
session->verify_key_handle = hKey;
switch (pMechanism->mechanism) {
case CKM_RSA_PKCS:
case CKM_ECDSA:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
break;
case CKM_SHA1_RSA_PKCS:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA1;
break;
case CKM_SHA224_RSA_PKCS:
case CKM_ECDSA_SHA224:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA224;
break;
case CKM_SHA256_RSA_PKCS:
case CKM_ECDSA_SHA256:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA256;
break;
case CKM_SHA384_RSA_PKCS:
case CKM_ECDSA_SHA384:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA384;
break;
case CKM_SHA512_RSA_PKCS:
case CKM_ECDSA_SHA512:
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_SHA512;
break;
default:
return CKR_MECHANISM_INVALID;
}
rv = CKR_OK;
fail:
if (pkey.handle != HAL_HANDLE_NONE)
(void) hal_rpc_pkey_close(pkey);
if (rv != CKR_OK && session != NULL) {
session->verify_key_handle = CK_INVALID_HANDLE;
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_Verify(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pSignature,
CK_ULONG ulSignatureLen)
{
ENTER_PUBLIC_FUNCTION(C_Verify);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pData == NULL || pSignature == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->verify_key_handle == CK_INVALID_HANDLE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (session->verify_digest_algorithm != HAL_DIGEST_ALGORITHM_NONE) {
if ((rv = digest_update(session, session->verify_digest_algorithm,
&session->verify_digest_handle, pData, ulDataLen)) != CKR_OK)
goto fail;
pData = NULL;
ulDataLen = 0;
}
rv = verify_hal_rpc(session, pData, ulDataLen, pSignature, ulSignatureLen);
fail: /* Fall through */
if (session != NULL) {
session->verify_key_handle = CK_INVALID_HANDLE;
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->verify_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_VerifyUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen)
{
ENTER_PUBLIC_FUNCTION(C_VerifyUpdate);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pPart == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->verify_key_handle == CK_INVALID_HANDLE)
lose(CKR_OPERATION_NOT_INITIALIZED);
if (session->verify_digest_algorithm == HAL_DIGEST_ALGORITHM_NONE)
lose(CKR_FUNCTION_FAILED);
if ((rv = digest_update(session, session->verify_digest_algorithm,
&session->verify_digest_handle, pPart, ulPartLen)) != CKR_OK)
goto fail;
return mutex_unlock(p11_global_mutex);
fail:
if (session != NULL) {
session->verify_key_handle = CK_INVALID_HANDLE;
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->verify_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_VerifyFinal(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pSignature,
CK_ULONG ulSignatureLen)
{
ENTER_PUBLIC_FUNCTION(C_VerifyFinal);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pSignature == NULL)
lose(CKR_ARGUMENTS_BAD);
if (session->verify_key_handle == CK_INVALID_HANDLE ||
session->verify_digest_handle.handle == HAL_HANDLE_NONE)
lose(CKR_OPERATION_NOT_INITIALIZED);
rv = verify_hal_rpc(session, NULL, 0, pSignature, ulSignatureLen);
fail: /* Fall through */
if (session != NULL) {
session->verify_key_handle = CK_INVALID_HANDLE;
session->verify_digest_algorithm = HAL_DIGEST_ALGORITHM_NONE;
digest_cleanup(&session->verify_digest_handle);
}
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
/*
* If there's any method in this entire package which really needs a
* more complex mutex structure than the single global mutex, it's
* probably this one. Key generation can take a looooong time.
* Drive off that bridge when we get to it.
*/
CK_RV C_GenerateKeyPair(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_ATTRIBUTE_PTR pPublicKeyTemplate,
CK_ULONG ulPublicKeyAttributeCount,
CK_ATTRIBUTE_PTR pPrivateKeyTemplate,
CK_ULONG ulPrivateKeyAttributeCount,
CK_OBJECT_HANDLE_PTR phPublicKey,
CK_OBJECT_HANDLE_PTR phPrivateKey)
{
ENTER_PUBLIC_FUNCTION(C_GenerateKeyPair);
p11_session_t *session;
CK_RV rv;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (pMechanism == NULL ||
pPublicKeyTemplate == NULL || phPublicKey == NULL ||
pPrivateKeyTemplate == NULL || phPrivateKey == NULL)
lose(CKR_ARGUMENTS_BAD);
switch (pMechanism->mechanism) {
case CKM_RSA_PKCS_KEY_PAIR_GEN:
rv = generate_keypair(session, pMechanism, generate_keypair_rsa_pkcs,
pPublicKeyTemplate, ulPublicKeyAttributeCount, &p11_descriptor_rsa_public_key, phPublicKey,
pPrivateKeyTemplate, ulPrivateKeyAttributeCount, &p11_descriptor_rsa_private_key, phPrivateKey);
break;
case CKM_EC_KEY_PAIR_GEN:
rv = generate_keypair(session, pMechanism, generate_keypair_ec,
pPublicKeyTemplate, ulPublicKeyAttributeCount, &p11_descriptor_ec_public_key, phPublicKey,
pPrivateKeyTemplate, ulPrivateKeyAttributeCount, &p11_descriptor_ec_private_key, phPrivateKey);
break;
default:
lose(CKR_MECHANISM_INVALID);
}
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_GenerateRandom(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR RandomData,
CK_ULONG ulRandomLen)
{
ENTER_PUBLIC_FUNCTION(C_GenerateRandom);
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
if (RandomData == NULL)
lose(CKR_ARGUMENTS_BAD);
if (!hal_check(hal_rpc_get_random(RandomData, ulRandomLen)))
lose(CKR_FUNCTION_FAILED);
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
/*
* Supply information about a particular mechanism. We may want a
* more generic structure for this, for the moment, just answer the
* questions that applications we care about are asking.
*
* Not really sure whether I should be setting CKF_HW here or not, RSA
* is a mix of hardware and software at the moment, but I'm also a
* little unclear on what "the device" means in this context, so let's
* just say that if it's implemented by libhal or the Verilog hiding
* behind libhal, it's implemented in hardware.
*/
CK_RV C_GetMechanismInfo(CK_SLOT_ID slotID,
CK_MECHANISM_TYPE type,
CK_MECHANISM_INFO_PTR pInfo)
{
ENTER_PUBLIC_FUNCTION(C_GetMechanismInfo);
const CK_ULONG rsa_key_min = 1024;
const CK_ULONG rsa_key_max = 8192;
const CK_ULONG ec_key_min = 256;
const CK_ULONG ec_key_max = 521;
/*
* No locking here, no obvious need for it.
*/
if (pInfo == NULL)
return CKR_ARGUMENTS_BAD;
if (slotID != P11_ONE_AND_ONLY_SLOT)
return CKR_SLOT_ID_INVALID;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
#if 0
/*
* Perhaps revisit this after adding an RPC call to let us check
* which cores are available. For now, given that we now have
* software core support for these hash algorithms, this test isn't
* particularly useful.
*/
hal_digest_algorithm_t algorithm = HAL_DIGEST_ALGORITHM_NONE;
CK_RV rv = CKR_OK;
switch (type) {
case CKM_SHA_1:
case CKM_SHA1_RSA_PKCS:
case CKM_SHA_1_HMAC:
algorithm = HAL_DIGEST_ALGORITHM_SHA1;
break;
case CKM_SHA224:
case CKM_SHA224_RSA_PKCS:
case CKM_SHA224_HMAC:
case CKM_ECDSA_SHA224:
algorithm = HAL_DIGEST_ALGORITHM_SHA224;
break;
case CKM_SHA256:
case CKM_SHA256_RSA_PKCS:
case CKM_SHA256_HMAC:
case CKM_ECDSA_SHA256:
algorithm = HAL_DIGEST_ALGORITHM_SHA256;
break;
case CKM_SHA384:
case CKM_SHA384_RSA_PKCS:
case CKM_SHA384_HMAC:
case CKM_ECDSA_SHA384:
algorithm = HAL_DIGEST_ALGORITHM_SHA384;
break;
case CKM_SHA512:
case CKM_SHA512_RSA_PKCS:
case CKM_SHA512_HMAC:
case CKM_ECDSA_SHA512:
algorithm = HAL_DIGEST_ALGORITHM_SHA512;
break;
default:
break;
}
if (algorithm != HAL_DIGEST_ALGORITHM_NONE && (rv = digest_available(algorithm)) != CKR_OK)
return rv;
#endif
switch (type) {
case CKM_RSA_PKCS_KEY_PAIR_GEN:
pInfo->ulMinKeySize = rsa_key_min;
pInfo->ulMaxKeySize = rsa_key_max;
pInfo->flags = CKF_HW | CKF_GENERATE_KEY_PAIR;
break;
case CKM_EC_KEY_PAIR_GEN:
pInfo->ulMinKeySize = ec_key_min;
pInfo->ulMaxKeySize = ec_key_max;
pInfo->flags = CKF_HW | CKF_GENERATE_KEY_PAIR | CKF_EC_F_P | CKF_EC_NAMEDCURVE | CKF_EC_UNCOMPRESS;
break;
case CKM_RSA_PKCS:
case CKM_SHA1_RSA_PKCS:
case CKM_SHA224_RSA_PKCS:
case CKM_SHA256_RSA_PKCS:
case CKM_SHA384_RSA_PKCS:
case CKM_SHA512_RSA_PKCS:
pInfo->ulMinKeySize = rsa_key_min;
pInfo->ulMaxKeySize = rsa_key_max;
pInfo->flags = CKF_HW | CKF_SIGN | CKF_VERIFY;
break;
case CKM_ECDSA:
case CKM_ECDSA_SHA224:
case CKM_ECDSA_SHA256:
case CKM_ECDSA_SHA384:
case CKM_ECDSA_SHA512:
pInfo->ulMinKeySize = ec_key_min;
pInfo->ulMaxKeySize = ec_key_max;
pInfo->flags = CKF_HW | CKF_SIGN | CKF_VERIFY | CKF_EC_F_P | CKF_EC_NAMEDCURVE | CKF_EC_UNCOMPRESS;
break;
case CKM_SHA_1:
case CKM_SHA224:
case CKM_SHA256:
case CKM_SHA384:
case CKM_SHA512:
pInfo->ulMinKeySize = 0;
pInfo->ulMaxKeySize = 0;
pInfo->flags = CKF_HW | CKF_DIGEST;
break;
#if 0
/*
* We have Verilog and libhal for these, but no PKCS #11 support (yet).
*/
case CKM_SHA_1_HMAC:
case CKM_SHA224_HMAC:
case CKM_SHA256_HMAC:
case CKM_SHA384_HMAC:
case CKM_SHA512_HMAC:
#endif
default:
return CKR_MECHANISM_INVALID;
}
return CKR_OK;
}
CK_RV C_GetSessionInfo(CK_SESSION_HANDLE hSession,
CK_SESSION_INFO_PTR pInfo)
{
ENTER_PUBLIC_FUNCTION(C_GetSessionInfo);
p11_session_t *session;
CK_RV rv = CKR_OK;
mutex_lock_or_return_failure(p11_global_mutex);
if (pInfo == NULL)
lose(CKR_ARGUMENTS_BAD);
if ((session = p11_session_find(hSession)) == NULL)
lose(CKR_SESSION_HANDLE_INVALID);
pInfo->slotID = P11_ONE_AND_ONLY_SLOT;
pInfo->state = session->state;
pInfo->flags = CKF_SERIAL_SESSION;
pInfo->ulDeviceError = 0;
switch (session->state) {
case CKS_RW_PUBLIC_SESSION:
case CKS_RW_SO_FUNCTIONS:
case CKS_RW_USER_FUNCTIONS:
pInfo->flags |= CKF_RW_SESSION;
default:
break;
}
fail:
mutex_unlock_return_with_rv(rv, p11_global_mutex);
}
CK_RV C_GetInfo(CK_INFO_PTR pInfo)
{
ENTER_PUBLIC_FUNCTION(C_GetInfo);
if (pInfo == NULL)
return CKR_ARGUMENTS_BAD;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
memset(pInfo, 0, sizeof(*pInfo));
pInfo->cryptokiVersion.major = 2;
pInfo->cryptokiVersion.minor = 30;
psnprintf(pInfo->manufacturerID, sizeof(pInfo->manufacturerID), "cryptech.is project");
psnprintf(pInfo->libraryDescription, sizeof(pInfo->libraryDescription), "cryptech.is pkcs11");
pInfo->libraryVersion.major = P11_VERSION_SW_MAJOR;
pInfo->libraryVersion.minor = P11_VERSION_SW_MINOR;
return CKR_OK;
}
CK_RV C_GetSlotInfo(CK_SLOT_ID slotID,
CK_SLOT_INFO_PTR pInfo)
{
ENTER_PUBLIC_FUNCTION(C_GetSlotInfo);
if (pInfo == NULL)
return CKR_ARGUMENTS_BAD;
if (slotID != P11_ONE_AND_ONLY_SLOT)
return CKR_SLOT_ID_INVALID;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
memset(pInfo, 0, sizeof(*pInfo));
psnprintf(pInfo->slotDescription, sizeof(pInfo->slotDescription), "cryptech.is slot on alpha");
psnprintf(pInfo->manufacturerID, sizeof(pInfo->manufacturerID), "cryptech.is project");
pInfo->flags = CKF_TOKEN_PRESENT | CKF_HW_SLOT;
pInfo->hardwareVersion.major = 0;
pInfo->hardwareVersion.minor = 2;
pInfo->firmwareVersion.major = P11_VERSION_HW_MAJOR;
pInfo->firmwareVersion.minor = P11_VERSION_HW_MINOR;
return CKR_OK;
}
CK_RV C_GetMechanismList(CK_SLOT_ID slotID,
CK_MECHANISM_TYPE_PTR pMechanismList,
CK_ULONG_PTR pulCount)
{
static const CK_MECHANISM_TYPE mechanisms[] = {
CKM_ECDSA_SHA224, CKM_ECDSA_SHA256, CKM_ECDSA_SHA384, CKM_ECDSA_SHA512, CKM_ECDSA, CKM_EC_KEY_PAIR_GEN,
CKM_SHA1_RSA_PKCS, CKM_SHA224_RSA_PKCS, CKM_SHA256_RSA_PKCS, CKM_SHA384_RSA_PKCS, CKM_SHA512_RSA_PKCS, CKM_RSA_PKCS, CKM_RSA_PKCS_KEY_PAIR_GEN,
CKM_SHA_1, CKM_SHA224, CKM_SHA256, CKM_SHA384, CKM_SHA512,
#if 0
/* libhal support these but pkcs11 doesn't, yet */
CKM_SHA_1_HMAC, CKM_SHA224_HMAC, CKM_SHA256_HMAC, CKM_SHA384_HMAC, CKM_SHA512_HMAC,
#endif
};
const CK_ULONG mechanisms_len = sizeof(mechanisms)/sizeof(*mechanisms);
ENTER_PUBLIC_FUNCTION(C_GetMechanismList);
if (pulCount == NULL)
return CKR_ARGUMENTS_BAD;
if (slotID != P11_ONE_AND_ONLY_SLOT)
return CKR_SLOT_ID_INVALID;
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
CK_RV rv = CKR_OK;
if (pMechanismList != NULL && *pulCount < mechanisms_len)
rv = CKR_BUFFER_TOO_SMALL;
else if (pMechanismList != NULL)
memcpy(pMechanismList, mechanisms, sizeof(mechanisms));
*pulCount = mechanisms_len;
return rv;
}
CK_RV C_SeedRandom(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pSeed,
CK_ULONG ulSeedLen)
{
ENTER_PUBLIC_FUNCTION(C_SeedRandom);
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
return CKR_RANDOM_SEED_NOT_SUPPORTED;
}
/*
* Legacy functions. These are basically just unimplemented functions
* which return a different error code to keep test suites happy.
*/
CK_RV C_GetFunctionStatus(CK_SESSION_HANDLE hSession)
{
ENTER_PUBLIC_FUNCTION(C_GetFunctionStatus);
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
return CKR_FUNCTION_NOT_PARALLEL;
}
CK_RV C_CancelFunction(CK_SESSION_HANDLE hSession)
{
ENTER_PUBLIC_FUNCTION(C_CancelFunction);
if (p11_uninitialized())
return CKR_CRYPTOKI_NOT_INITIALIZED;
return CKR_FUNCTION_NOT_PARALLEL;
}
/*
* Stubs for unsupported functions below here. Per the PKCS #11
* specification, it's OK to skip implementing almost any function in
* the API, but if one does so, one must provide a stub which returns
* CKR_FUNCTION_NOT_SUPPORTED, because every slot in the dispatch
* vector must be populated. We could reuse a single stub for all the
* unimplemented slots, but the type signatures wouldn't match, which
* would require some nasty casts I'd rather avoid.
*
* Many of these functions would be straightforward to implement, but
* there are enough bald yaks in this saga already.
*/
CK_RV C_GenerateKey(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount,
CK_OBJECT_HANDLE_PTR phKey)
{
UNSUPPORTED_FUNCTION(C_GenerateKey);
}
CK_RV C_InitToken(CK_SLOT_ID slotID,
CK_UTF8CHAR_PTR pPin,
CK_ULONG ulPinLen,
CK_UTF8CHAR_PTR pLabel)
{
UNSUPPORTED_FUNCTION(C_InitToken);
}
CK_RV C_InitPIN(CK_SESSION_HANDLE hSession,
CK_UTF8CHAR_PTR pPin,
CK_ULONG ulPinLen)
{
UNSUPPORTED_FUNCTION(C_InitPIN);
}
CK_RV C_SetPIN(CK_SESSION_HANDLE hSession,
CK_UTF8CHAR_PTR pOldPin,
CK_ULONG ulOldLen,
CK_UTF8CHAR_PTR pNewPin,
CK_ULONG ulNewLen)
{
UNSUPPORTED_FUNCTION(C_SetPIN);
}
CK_RV C_GetOperationState(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pOperationState,
CK_ULONG_PTR pulOperationStateLen)
{
UNSUPPORTED_FUNCTION(C_GetOperationState);
}
CK_RV C_SetOperationState(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pOperationState,
CK_ULONG ulOperationStateLen,
CK_OBJECT_HANDLE hEncryptionKey,
CK_OBJECT_HANDLE hAuthenticationKey)
{
UNSUPPORTED_FUNCTION(C_SetOperationState);
}
CK_RV C_CopyObject(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hObject,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount,
CK_OBJECT_HANDLE_PTR phNewObject)
{
UNSUPPORTED_FUNCTION(C_CopyObject);
}
CK_RV C_GetObjectSize(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hObject,
CK_ULONG_PTR pulSize)
{
UNSUPPORTED_FUNCTION(C_GetObjectSize);
}
CK_RV C_SetAttributeValue(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hObject,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulCount)
{
UNSUPPORTED_FUNCTION(C_SetAttributeValue);
}
CK_RV C_EncryptInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey)
{
UNSUPPORTED_FUNCTION(C_EncryptInit);
}
CK_RV C_Encrypt(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pEncryptedData,
CK_ULONG_PTR pulEncryptedDataLen)
{
UNSUPPORTED_FUNCTION(C_Encrypt);
}
CK_RV C_EncryptUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG_PTR pulEncryptedPartLen)
{
UNSUPPORTED_FUNCTION(C_EncryptUpdate);
}
CK_RV C_EncryptFinal(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pLastEncryptedPart,
CK_ULONG_PTR pulLastEncryptedPartLen)
{
UNSUPPORTED_FUNCTION(C_EncryptFinal);
}
CK_RV C_DecryptInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey)
{
UNSUPPORTED_FUNCTION(C_DecryptInit);
}
CK_RV C_Decrypt(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pEncryptedData,
CK_ULONG ulEncryptedDataLen,
CK_BYTE_PTR pData,
CK_ULONG_PTR pulDataLen)
{
UNSUPPORTED_FUNCTION(C_Decrypt);
}
CK_RV C_DecryptUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG ulEncryptedPartLen,
CK_BYTE_PTR pPart,
CK_ULONG_PTR pulPartLen)
{
UNSUPPORTED_FUNCTION(C_DecryptUpdate);
}
CK_RV C_DecryptFinal(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pLastPart,
CK_ULONG_PTR pulLastPartLen)
{
UNSUPPORTED_FUNCTION(C_DecryptFinal);
}
CK_RV C_DigestKey(CK_SESSION_HANDLE hSession,
CK_OBJECT_HANDLE hKey)
{
UNSUPPORTED_FUNCTION(C_DigestKey);
}
CK_RV C_SignRecoverInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey)
{
UNSUPPORTED_FUNCTION(C_SignRecoverInit);
}
CK_RV C_SignRecover(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pData,
CK_ULONG ulDataLen,
CK_BYTE_PTR pSignature,
CK_ULONG_PTR pulSignatureLen)
{
UNSUPPORTED_FUNCTION(C_SignRecover);
}
CK_RV C_VerifyRecoverInit(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hKey)
{
UNSUPPORTED_FUNCTION(C_VerifyRecoverInit);
}
CK_RV C_VerifyRecover(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pSignature,
CK_ULONG ulSignatureLen,
CK_BYTE_PTR pData,
CK_ULONG_PTR pulDataLen)
{
UNSUPPORTED_FUNCTION(C_VerifyRecover);
}
CK_RV C_DigestEncryptUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG_PTR pulEncryptedPartLen)
{
UNSUPPORTED_FUNCTION(C_DigestEncryptUpdate);
}
CK_RV C_DecryptDigestUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG ulEncryptedPartLen,
CK_BYTE_PTR pPart,
CK_ULONG_PTR pulPartLen)
{
UNSUPPORTED_FUNCTION(C_DecryptDigestUpdate);
}
CK_RV C_SignEncryptUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pPart,
CK_ULONG ulPartLen,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG_PTR pulEncryptedPartLen)
{
UNSUPPORTED_FUNCTION(C_SignEncryptUpdate);
}
CK_RV C_DecryptVerifyUpdate(CK_SESSION_HANDLE hSession,
CK_BYTE_PTR pEncryptedPart,
CK_ULONG ulEncryptedPartLen,
CK_BYTE_PTR pPart,
CK_ULONG_PTR pulPartLen)
{
UNSUPPORTED_FUNCTION(C_DecryptVerifyUpdate);
}
CK_RV C_WrapKey(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hWrappingKey,
CK_OBJECT_HANDLE hKey,
CK_BYTE_PTR pWrappedKey,
CK_ULONG_PTR pulWrappedKeyLen)
{
UNSUPPORTED_FUNCTION(C_WrapKey);
}
CK_RV C_UnwrapKey(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hUnwrappingKey,
CK_BYTE_PTR pWrappedKey,
CK_ULONG ulWrappedKeyLen,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulAttributeCount,
CK_OBJECT_HANDLE_PTR phKey)
{
UNSUPPORTED_FUNCTION(C_UnwrapKey);
}
CK_RV C_DeriveKey(CK_SESSION_HANDLE hSession,
CK_MECHANISM_PTR pMechanism,
CK_OBJECT_HANDLE hBaseKey,
CK_ATTRIBUTE_PTR pTemplate,
CK_ULONG ulAttributeCount,
CK_OBJECT_HANDLE_PTR phKey)
{
UNSUPPORTED_FUNCTION(C_DeriveKey);
}
CK_RV C_WaitForSlotEvent(CK_FLAGS flags,
CK_SLOT_ID_PTR pSlot,
CK_VOID_PTR pRserved)
{
UNSUPPORTED_FUNCTION(C_WaitForSlotEvent);
}
/*
* "Any programmer who fails to comply with the standard naming, formatting,
* or commenting conventions should be shot. If it so happens that it is
* inconvenient to shoot him, then he is to be politely requested to recode
* his program in adherence to the above standard."
* -- Michael Spier, Digital Equipment Corporation
*
* Local variables:
* indent-tabs-mode: nil
* End:
*/