/*
* hal_internal.h
* --------------
* Internal API declarations for libhal.
*
* Authors: Rob Austein, Paul Selkirk
* Copyright (c) 2015, 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.
*/
#ifndef _HAL_INTERNAL_H_
#define _HAL_INTERNAL_H_
#include <string.h>
#include "hal.h"
#include "verilog_constants.h"
/*
* Everything in this file is part of the internal API, that is,
* subject to change without notice. Nothing outside of libhal itself
* should be looking at this file.
*/
/*
* htonl and htons are not available in arm-none-eabi headers or libc.
*/
#ifndef STM32F4XX
#include <arpa/inet.h>
#else
#ifdef __ARMEL__ /* little endian */
inline uint32_t htonl(uint32_t w)
{
return
((w & 0x000000ff) << 24) +
((w & 0x0000ff00) << 8) +
((w & 0x00ff0000) >> 8) +
((w & 0xff000000) >> 24);
}
inline uint16_t htons(uint16_t w)
{
return
((w & 0x00ff) << 8) +
((w & 0xff00) >> 8);
}
#else /* big endian */
#define htonl(x) (x)
#define htons(x) (x)
#endif
#define ntohl htonl
#define ntohs htons
#endif
/*
* Low-level I/O convenience functions, moved here from hal.h
* because they use symbols defined in verilog_constants.h.
*/
static inline hal_error_t hal_io_zero(const hal_core_t *core)
{
const uint8_t buf[4] = { 0, 0, 0, 0 };
return hal_io_write(core, ADDR_CTRL, buf, sizeof(buf));
}
static inline hal_error_t hal_io_init(const hal_core_t *core)
{
const uint8_t buf[4] = { 0, 0, 0, CTRL_INIT };
return hal_io_write(core, ADDR_CTRL, buf, sizeof(buf));
}
static inline hal_error_t hal_io_next(const hal_core_t *core)
{
const uint8_t buf[4] = { 0, 0, 0, CTRL_NEXT };
return hal_io_write(core, ADDR_CTRL, buf, sizeof(buf));
}
static inline hal_error_t hal_io_wait_ready(const hal_core_t *core)
{
int limit = -1;
return hal_io_wait(core, STATUS_READY, &limit);
}
static inline hal_error_t hal_io_wait_valid(const hal_core_t *core)
{
int limit = -1;
return hal_io_wait(core, STATUS_VALID, &limit);
}
static inline hal_error_t hal_io_wait_ready2(const hal_core_t *core1, const hal_core_t *core2)
{
int limit = -1;
return hal_io_wait2(core1, core2, STATUS_READY, &limit);
}
static inline hal_error_t hal_io_wait_valid2(const hal_core_t *core1, const hal_core_t *core2)
{
int limit = -1;
return hal_io_wait2(core1, core2, STATUS_VALID, &limit);
}
/*
* Static memory allocation on start-up. Don't use this except where
* really necessary. Intent is just to allow allocation of things like
* the large-ish ks_index arrays used by ks_flash.c from a memory source
* external to the executable image file (eg, from the secondary SDRAM
* chip on the Cryptech Alpha board).
*
* We shouldn't need this except on the HSM, so for now we don't bother
* with implementing a version of this based on malloc() or sbrk().
*/
extern void *hal_allocate_static_memory(const size_t size);
extern hal_error_t hal_free_static_memory(const void * const ptr);
/*
* Longest hash block and digest we support at the moment.
*/
#define HAL_MAX_HASH_BLOCK_LENGTH SHA512_BLOCK_LEN
#define HAL_MAX_HASH_DIGEST_LENGTH SHA512_DIGEST_LEN
/*
* Locks and critical sections.
*/
extern void hal_critical_section_start(void);
extern void hal_critical_section_end(void);
extern void hal_ks_lock(void);
extern void hal_ks_unlock(void);
extern void hal_task_yield(void);
/*
* Thread sleep. Currently used only for bad-PIN delays.
*/
extern void hal_sleep(const unsigned seconds);
/*
* Logging.
*/
typedef enum {
HAL_LOG_DEBUG, HAL_LOG_INFO, HAL_LOG_WARN, HAL_LOG_ERROR, HAL_LOG_SILENT
} hal_log_level_t;
extern void hal_log_set_level(const hal_log_level_t level);
extern void hal_log(const hal_log_level_t level, const char *format, ...);
/*
* Dispatch structures for RPC implementation.
*
* The breakdown of which functions go into which dispatch vectors is
* based entirely on pesky details like making sure that the right
* functions get linked in the right cases, and should not be
* construed as making any particular sense in any larger context.
*
* In theory eventually we might want a fully general mechanism to
* allow us to dispatch arbitrary groups of functions either locally
* or remotely on a per-user basis. In practice, we probably want to
* run everything on the HSM except for hashing and digesting, so just
* code for that case initially while leaving the design open for a
* more general mechanism later if warranted.
*
* So we have three cases:
*
* - We're the HSM, so we do everything locally (ie, we run the RPC
* server functions.
*
* - We're the host, so we do everything remotely (ie, we do
* everything using the client-side RPC calls.
*
* - We're the host but are doing hashing locally, so we do a mix.
* This is slightly more complicated than it might at first appear,
* because we must handle the case of one of the pkey functions
* taking a hash context instead of a literal hash value, in which
* case we have to extract the hash value from the context and
* supply it to the pkey RPC client code as a literal value.
*
* ...Except that for PKCS #11 we also have to handle the case of
* "session keys", ie, keys which are not stored on the HSM.
* Apparently people really do use these, mostly for public keys, in
* order to conserve expensive memory on the HSM. So this is another
* feature of mixed mode: keys with HAL_KEY_FLAG_PROXIMATE set live on
* the host, not in the HSM, and the mixed-mode pkey handlers deal
* with the routing. In the other two modes we ignore the flag and
* send everything where we were going to send it anyway. Restricting
* the fancy key handling to mixed mode lets us drop this complexity
* out entirely for applications which have no use for it.
*/
typedef struct {
hal_error_t (*set_pin)(const hal_client_handle_t client,
const hal_user_t user,
const char * const newpin, const size_t newpin_len);
hal_error_t (*login)(const hal_client_handle_t client,
const hal_user_t user,
const char * const newpin, const size_t newpin_len);
hal_error_t (*logout)(const hal_client_handle_t client);
hal_error_t (*logout_all)(void);
hal_error_t (*is_logged_in)(const hal_client_handle_t client,
const hal_user_t user);
hal_error_t (*get_random)(void *buffer, const size_t length);
hal_error_t (*get_version)(uint32_t *version);
} hal_rpc_misc_dispatch_t;
typedef struct {
hal_error_t (*get_digest_length)(const hal_digest_algorithm_t alg, size_t *length);
hal_error_t (*get_digest_algorithm_id)(const hal_digest_algorithm_t alg,
uint8_t *id, size_t *len, const size_t len_max);
hal_error_t (*get_algorithm)(const hal_hash_handle_t hash, hal_digest_algorithm_t *alg);
hal_error_t (*initialize)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_hash_handle_t *hash,
const hal_digest_algorithm_t alg,
const uint8_t * const key, const size_t key_length);
hal_error_t (*update)(const hal_hash_handle_t hash,
const uint8_t * data, const size_t length);
hal_error_t (*finalize)(const hal_hash_handle_t hash,
uint8_t *digest, const size_t length);
} hal_rpc_hash_dispatch_t;
typedef struct {
hal_error_t (*load)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
hal_uuid_t *name,
const uint8_t * const der, const size_t der_len,
const hal_key_flags_t flags);
hal_error_t (*open)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
const hal_uuid_t * const name);
hal_error_t (*generate_rsa)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
hal_uuid_t *name,
const unsigned key_length,
const uint8_t * const public_exponent, const size_t public_exponent_len,
const hal_key_flags_t flags);
hal_error_t (*generate_ec)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
hal_uuid_t *name,
const hal_curve_name_t curve,
const hal_key_flags_t flags);
hal_error_t (*generate_hashsig)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
hal_uuid_t *name,
const size_t hss_levels,
const lms_algorithm_t lms_type,
const lmots_algorithm_t lmots_type,
const hal_key_flags_t flags);
hal_error_t (*close)(const hal_pkey_handle_t pkey);
hal_error_t (*delete)(const hal_pkey_handle_t pkey);
hal_error_t (*get_key_type)(const hal_pkey_handle_t pkey,
hal_key_type_t *type);
hal_error_t (*get_key_curve)(const hal_pkey_handle_t pkey,
hal_curve_name_t *curve);
hal_error_t (*get_key_flags)(const hal_pkey_handle_t pkey,
hal_key_flags_t *flags);
size_t (*get_public_key_len)(const hal_pkey_handle_t pkey);
hal_error_t (*get_public_key)(const hal_pkey_handle_t pkey,
uint8_t *der, size_t *der_len, const size_t der_max);
hal_error_t (*sign)(const hal_pkey_handle_t pkey,
const hal_hash_handle_t hash,
const uint8_t * const input, const size_t input_len,
uint8_t * signature, size_t *signature_len, const size_t signature_max);
hal_error_t (*verify)(const hal_pkey_handle_t pkey,
const hal_hash_handle_t hash,
const uint8_t * const input, const size_t input_len,
const uint8_t * const signature, const size_t signature_len);
hal_error_t (*match)(const hal_client_handle_t client,
const hal_session_handle_t session,
const hal_key_type_t type,
const hal_curve_name_t curve,
const hal_key_flags_t mask,
const hal_key_flags_t flags,
const hal_pkey_attribute_t *attributes,
const unsigned attributes_len,
unsigned *state,
hal_uuid_t *result,
unsigned *result_len,
const unsigned result_max,
const hal_uuid_t * const previous_uuid);
hal_error_t (*set_attributes)(const hal_pkey_handle_t pkey,
const hal_pkey_attribute_t *attributes,
const unsigned attributes_len);
hal_error_t (*get_attributes)(const hal_pkey_handle_t pkey,
hal_pkey_attribute_t *attributes,
const unsigned attributes_len,
uint8_t *attributes_buffer,
const size_t attributes_buffer_len);
hal_error_t (*export)(const hal_pkey_handle_t pkey_handle,
const hal_pkey_handle_t kekek_handle,
uint8_t *pkcs8, size_t *pkcs8_len, const size_t pkcs8_max,
uint8_t *kek, size_t *kek_len, const size_t kek_max);
hal_error_t (*import)(const hal_client_handle_t client,
const hal_session_handle_t session,
hal_pkey_handle_t *pkey,
hal_uuid_t *name,
const hal_pkey_handle_t kekek_handle,
const uint8_t * const pkcs8, const size_t pkcs8_len,
const uint8_t * const kek, const size_t kek_len,
const hal_key_flags_t flags);
} hal_rpc_pkey_dispatch_t;
extern const hal_rpc_misc_dispatch_t hal_rpc_local_misc_dispatch, hal_rpc_remote_misc_dispatch, *hal_rpc_misc_dispatch;
extern const hal_rpc_hash_dispatch_t hal_rpc_local_hash_dispatch, hal_rpc_remote_hash_dispatch, *hal_rpc_hash_dispatch;
extern const hal_rpc_pkey_dispatch_t hal_rpc_local_pkey_dispatch, hal_rpc_remote_pkey_dispatch, hal_rpc_mixed_pkey_dispatch, *hal_rpc_pkey_dispatch;
/*
* See code in rpc_pkey.c for how this flag fits into the pkey handle.
*/
#define HAL_PKEY_HANDLE_TOKEN_FLAG (1 << 31)
/*
* Mostly used by the local_pkey code, but the mixed_pkey code needs
* it to pad hashes for RSA PKCS #1.5 signatures. This may indicate
* that we need a slightly more general internal API here, but not
* worth worrying about as long as we can treat RSA as a special case
* and just pass the plain hash for everything else.
*/
extern hal_error_t hal_rpc_pkcs1_construct_digestinfo(const hal_hash_handle_t handle,
uint8_t *digest_info, size_t *digest_info_len,
const size_t digest_info_max);
/*
* CRC-32 stuff (for flash keystore, etc). Dunno if we want a Verilog
* implementation of this, or if it would even be faster than doing it
* the main CPU taking I/O overhead and so forth into account.
*
* These prototypes were generated by pycrc.py, see notes in crc32.c.
*/
typedef uint32_t hal_crc32_t;
static inline hal_crc32_t hal_crc32_init(void)
{
return 0xffffffff;
}
extern hal_crc32_t hal_crc32_update(hal_crc32_t crc, const void *data, size_t data_len);
static inline hal_crc32_t hal_crc32_finalize(hal_crc32_t crc)
{
return crc ^ 0xffffffff;
}
/*
* Sizes for PKCS #8 encoded private keys. This may not be exact due
* to ASN.1 INTEGER encoding rules, but should be good enough for
* buffer sizing.
*
* 2048-bit RSA: 1219 bytes
* 4096-bit RSA: 2373 bytes
* 8192-bit RSA: 4679 bytes
* EC P-256: 138 bytes
* EC P-384: 185 bytes
* EC P-521: 240 bytes
*
* Plus we need a bit of AES-keywrap overhead, since we're storing the
* wrapped form (see hal_aes_keywrap_cyphertext_length()).
*
* A buffer big enough for a 8192-bit RSA key would overflow one
* sub-sector on the flash chip we're using on the Alpha. We could
* invent some more complex scheme where key blocks are allowed to
* span multiple sub-sectors, but since an 8192-bit RSA key would also
* be unusably slow with the current RSA implementation, for the
* moment we take the easy way out and cap this at 4096-bit RSA.
*/
#if 0
#define HAL_KS_WRAPPED_KEYSIZE ((2373 + 15) & ~7)
#else
//#warning Temporary test hack to HAL_KS_WRAPPED_KEYSIZE, clean this up
//
// See how much of the problem we're having with pkey support for the
// new modexpa7 components is just this buffer size being too small.
//
#define HAL_KS_WRAPPED_KEYSIZE ((2373 + 6 * 4096 / 8 + 6 * 4 + 15) & ~7)
#if HAL_KS_WRAPPED_KEYSIZE + 8 > 8192
#warning HAL_KS_WRAPPED_KEYSIZE is too big for a single 8192-octet block
#endif
#endif
/*
* PINs.
*
* The functions here might want renaming, eg, to hal_pin_*().
*/
#ifndef HAL_PIN_SALT_LENGTH
#define HAL_PIN_SALT_LENGTH 16
#endif
typedef struct {
uint32_t iterations;
uint8_t pin[HAL_MAX_HASH_DIGEST_LENGTH];
uint8_t salt[HAL_PIN_SALT_LENGTH];
} hal_ks_pin_t;
extern hal_error_t hal_set_pin_default_iterations(const hal_client_handle_t client,
const uint32_t iterations);
extern hal_error_t hal_get_pin(const hal_user_t user,
const hal_ks_pin_t **pin);
extern hal_error_t hal_set_pin(const hal_user_t user,
const hal_ks_pin_t * const pin);
/*
* Master key memory (MKM) and key-encryption-key (KEK).
*
* Providing a mechanism for storing the KEK in flash is a horrible
* kludge which defeats the entire purpose of having the MKM. We
* support it for now because the Alpha hardware does not yet have
* a working battery backup for the MKM, but it should go away RSN.
*/
#ifndef HAL_MKM_FLASH_BACKUP_KLUDGE
#define HAL_MKM_FLASH_BACKUP_KLUDGE 1
#endif
#ifndef KEK_LENGTH
#define KEK_LENGTH (bitsToBytes(256))
#endif
extern hal_error_t hal_mkm_get_kek(uint8_t *kek, size_t *kek_len, const size_t kek_max);
extern hal_error_t hal_mkm_volatile_read(uint8_t *buf, const size_t len);
extern hal_error_t hal_mkm_volatile_write(const uint8_t * const buf, const size_t len);
extern hal_error_t hal_mkm_volatile_erase(const size_t len);
#if HAL_MKM_FLASH_BACKUP_KLUDGE
/* #warning MKM flash backup kludge enabled. Do NOT use this in production! */
extern hal_error_t hal_mkm_flash_read(uint8_t *buf, const size_t len);
extern hal_error_t hal_mkm_flash_read_no_lock(uint8_t *buf, const size_t len);
extern hal_error_t hal_mkm_flash_write(const uint8_t * const buf, const size_t len);
extern hal_error_t hal_mkm_flash_erase(const size_t len);
#endif
/*
* Clean up pkey stuff that's tied to a particular client on logout.
*/
extern hal_error_t hal_pkey_logout(const hal_client_handle_t client);
/*
* Keystore API for use by the pkey implementation.
*
* In an attempt to emulate what current theory says will eventually
* be the behavior of the underlying Cryptech Verilog "hardware",
* these functions automatically apply the AES keywrap transformations.
*
* Unclear whether these should also call the ASN.1 encode/decode
* functions. For the moment, the answer is no, but we may need to
* revisit this as the underlying Verilog API evolves.
*
* hal_pkey_slot_t is defined here too, so that keystore drivers can
* piggyback on the pkey database for storage related to keys on which
* the user currently has an active pkey handle. Nothing outside the
* pkey and keystore code should touch this.
*/
typedef struct {
hal_client_handle_t client;
hal_session_handle_t session;
hal_pkey_handle_t pkey;
hal_key_type_t type;
hal_curve_name_t curve;
hal_key_flags_t flags;
hal_uuid_t name;
int hint;
/*
* This might be where we'd stash a (hal_core_t *) pointing to a
* core which has already been loaded with the key, if we were
* trying to be clever about using multiple signing cores. Moot
* point (ie, no way we could possibly test such a thing) as long as
* the FPGA is too small to hold more than one modexp core and ECDSA
* is entirely software, so skip it for now, but the implied
* semantics are interesting: a pkey handle starts to resemble an
* initialized signing core, and once all the cores are in use, one
* can't load another key without closing an existing pkey handle.
*/
} hal_pkey_slot_t;
/*
* Keystore is an opaque type, we just pass pointers.
*/
typedef struct hal_ks hal_ks_t;
extern hal_ks_t * const hal_ks_token;
extern hal_ks_t * const hal_ks_volatile;
extern hal_error_t hal_ks_init(hal_ks_t *ks,
const int alloc);
extern void hal_ks_init_read_only_pins_only(void);
extern hal_error_t hal_ks_store(hal_ks_t *ks,
hal_pkey_slot_t *slot,
const uint8_t * const der, const size_t der_len);
extern hal_error_t hal_ks_fetch(hal_ks_t *ks,
hal_pkey_slot_t *slot,
uint8_t *der, size_t *der_len, const size_t der_max);
extern hal_error_t hal_ks_delete(hal_ks_t *ks,
hal_pkey_slot_t *slot);
extern hal_error_t hal_ks_match(hal_ks_t *ks,
const hal_client_handle_t client,
const hal_session_handle_t session,
const hal_key_type_t type,
const hal_curve_name_t curve,
const hal_key_flags_t mask,
const hal_key_flags_t flags,
const hal_pkey_attribute_t *attributes,
const unsigned attributes_len,
hal_uuid_t *result,
unsigned *result_len,
const unsigned result_max,
const hal_uuid_t * const previous_uuid);
extern hal_error_t hal_ks_set_attributes(hal_ks_t *ks,
hal_pkey_slot_t *slot,
const hal_pkey_attribute_t *attributes,
const unsigned attributes_len);
extern hal_error_t hal_ks_get_attributes(hal_ks_t *ks,
hal_pkey_slot_t *slot,
hal_pkey_attribute_t *attributes,
const unsigned attributes_len,
uint8_t *attributes_buffer,
const size_t attributes_buffer_len);
extern hal_error_t hal_ks_logout(hal_ks_t *ks,
const hal_client_handle_t client);
extern hal_error_t hal_ks_rewrite_der(hal_ks_t *ks,
hal_pkey_slot_t *slot,
const uint8_t * const der, const size_t der_len);
/*
* RPC lowest-level send and receive routines. These are blocking, and
* transport-specific (sockets, USB).
*/
extern hal_error_t hal_rpc_send(const uint8_t * const buf, const size_t len);
extern hal_error_t hal_rpc_recv(uint8_t * const buf, size_t * const len);
extern hal_error_t hal_rpc_sendto(const uint8_t * const buf, const size_t len, void *opaque);
extern hal_error_t hal_rpc_recvfrom(uint8_t * const buf, size_t * const len, void **opaque);
extern hal_error_t hal_rpc_client_transport_init(void);
extern hal_error_t hal_rpc_client_transport_close(void);
extern hal_error_t hal_rpc_server_transport_init(void);
extern hal_error_t hal_rpc_server_transport_close(void);
/*
* RPC function numbers
*/
typedef enum {
RPC_FUNC_GET_VERSION,
RPC_FUNC_GET_RANDOM,
RPC_FUNC_SET_PIN,
RPC_FUNC_LOGIN,
RPC_FUNC_LOGOUT,
RPC_FUNC_LOGOUT_ALL,
RPC_FUNC_IS_LOGGED_IN,
RPC_FUNC_HASH_GET_DIGEST_LEN,
RPC_FUNC_HASH_GET_DIGEST_ALGORITHM_ID,
RPC_FUNC_HASH_GET_ALGORITHM,
RPC_FUNC_HASH_INITIALIZE,
RPC_FUNC_HASH_UPDATE,
RPC_FUNC_HASH_FINALIZE,
RPC_FUNC_PKEY_LOAD,
RPC_FUNC_PKEY_OPEN,
RPC_FUNC_PKEY_GENERATE_RSA,
RPC_FUNC_PKEY_GENERATE_EC,
RPC_FUNC_PKEY_CLOSE,
RPC_FUNC_PKEY_DELETE,
RPC_FUNC_PKEY_GET_KEY_TYPE,
RPC_FUNC_PKEY_GET_KEY_FLAGS,
RPC_FUNC_PKEY_GET_PUBLIC_KEY_LEN,
RPC_FUNC_PKEY_GET_PUBLIC_KEY,
RPC_FUNC_PKEY_SIGN,
RPC_FUNC_PKEY_VERIFY,
RPC_FUNC_PKEY_MATCH,
RPC_FUNC_PKEY_GET_KEY_CURVE,
RPC_FUNC_PKEY_SET_ATTRIBUTES,
RPC_FUNC_PKEY_GET_ATTRIBUTES,
RPC_FUNC_PKEY_EXPORT,
RPC_FUNC_PKEY_IMPORT,
RPC_FUNC_PKEY_GENERATE_HASHSIG,
} rpc_func_num_t;
#define RPC_VERSION 0x01010100 /* 1.1.1.0 */
/*
* RPC client locality. These have to be defines rather than an enum,
* because they're handled by the preprocessor.
*/
#define RPC_CLIENT_LOCAL 0
#define RPC_CLIENT_REMOTE 1
#define RPC_CLIENT_MIXED 2
#define RPC_CLIENT_NONE 3
/*
* Maximum size of a HAL RPC packet.
*/
#ifndef HAL_RPC_MAX_PKT_SIZE
#define HAL_RPC_MAX_PKT_SIZE 16384
#endif
/*
* Location of AF_UNIX socket for RPC client mux daemon.
*/
#ifndef HAL_CLIENT_DAEMON_DEFAULT_SOCKET_NAME
#define HAL_CLIENT_DAEMON_DEFAULT_SOCKET_NAME "/tmp/.cryptech_muxd.rpc"
#endif
/*
* Default device name and line speed for HAL RPC serial connection to HSM.
*/
#ifndef HAL_CLIENT_SERIAL_DEFAULT_DEVICE
#define HAL_CLIENT_SERIAL_DEFAULT_DEVICE "/dev/ttyUSB0"
#endif
#ifndef HAL_CLIENT_SERIAL_DEFAULT_SPEED
#define HAL_CLIENT_SERIAL_DEFAULT_SPEED 921600
#endif
/*
* Names of environment variables for setting the above in RPC clients.
*/
#define HAL_CLIENT_SERIAL_DEVICE_ENVVAR "CRYPTECH_RPC_CLIENT_SERIAL_DEVICE"
#define HAL_CLIENT_SERIAL_SPEED_ENVVAR "CRYPTECH_RPC_CLIENT_SERIAL_SPEED"
#endif /* _HAL_INTERNAL_H_ */
/*
* Local variables:
* indent-tabs-mode: nil
* End:
*/