#ifndef SIGNAL_PROTOCOL_H #define SIGNAL_PROTOCOL_H #include #include #include #include "ratchet.h" #include "curve.h" #include "session_record.h" #include "session_pre_key.h" #include "sender_key_record.h" #include "signal_protocol_types.h" #ifdef __cplusplus extern "C" { #endif #define SG_SUCCESS 0 /* Standard error codes with values that match errno.h equivalents */ #define SG_ERR_NOMEM -12 /* Not enough space */ #define SG_ERR_INVAL -22 /* Invalid argument */ /* Custom error codes for error conditions specific to the library */ #define SG_ERR_UNKNOWN -1000 #define SG_ERR_DUPLICATE_MESSAGE -1001 #define SG_ERR_INVALID_KEY -1002 #define SG_ERR_INVALID_KEY_ID -1003 #define SG_ERR_INVALID_MAC -1004 #define SG_ERR_INVALID_MESSAGE -1005 #define SG_ERR_INVALID_VERSION -1006 #define SG_ERR_LEGACY_MESSAGE -1007 #define SG_ERR_NO_SESSION -1008 #define SG_ERR_STALE_KEY_EXCHANGE -1009 #define SG_ERR_UNTRUSTED_IDENTITY -1010 #define SG_ERR_VRF_SIG_VERIF_FAILED -1011 #define SG_ERR_INVALID_PROTO_BUF -1100 #define SG_ERR_FP_VERSION_MISMATCH -1200 #define SG_ERR_FP_IDENT_MISMATCH -1201 /* * Minimum negative error code value that this library may use. * When implementing library callback functions, using values * less than this constant will ensure that application-specific * errors can be distinguished from library errors. */ #define SG_ERR_MINIMUM -9999 /* Log levels */ #define SG_LOG_ERROR 0 #define SG_LOG_WARNING 1 #define SG_LOG_NOTICE 2 #define SG_LOG_INFO 3 #define SG_LOG_DEBUG 4 /* Mode settings for the crypto callbacks */ #define SG_CIPHER_AES_CTR_NOPADDING 1 #define SG_CIPHER_AES_CBC_PKCS5 2 void signal_type_ref(signal_type_base *instance); void signal_type_unref(signal_type_base *instance); #ifdef DEBUG_REFCOUNT int signal_type_ref_count(signal_type_base *instance); #define SIGNAL_REF(instance) do { \ signal_type_ref((signal_type_base *)instance); \ fprintf(stderr, "REF: " #instance " = %d\n", signal_type_ref_count((signal_type_base *)instance)); \ } while (0) #define SIGNAL_UNREF(instance) do { \ fprintf(stderr, "UNREF: " #instance " = %d\n", signal_type_ref_count((signal_type_base *)instance)); \ signal_type_unref((signal_type_base *)instance); \ instance = 0; \ } while(0) #else #define SIGNAL_REF(instance) signal_type_ref((signal_type_base *)instance) #define SIGNAL_UNREF(instance) do { signal_type_unref((signal_type_base *)instance); instance = 0; } while(0) #endif /** * Allocate a new buffer to store data of the provided length. * * @param len length of the buffer to allocate * @return pointer to the allocated buffer, or 0 on failure */ signal_buffer *signal_buffer_alloc(size_t len); /** * Create a new buffer and copy the provided data into it. * * @param data pointer to the start of the data * @param len length of the data * @return pointer to the allocated buffer, or 0 on failure */ signal_buffer *signal_buffer_create(const uint8_t *data, size_t len); /** * Create a copy of an existing buffer. * * @param buffer the existing buffer to copy * @return pointer to the updated buffer, or 0 on failure */ signal_buffer *signal_buffer_copy(const signal_buffer *buffer); /** * Create a copy of an existing buffer. * * @param buffer the existing buffer to copy * @param n the maximum number of bytes to copy * @return pointer to the updated buffer, or 0 on failure */ signal_buffer *signal_buffer_n_copy(const signal_buffer *buffer, size_t n); /** * Append the provided data to an existing buffer. * Note: The underlying buffer is only expanded by an amount sufficient * to hold the data being appended. There is no additional reserved space * to reduce the need for memory allocations. * * @param buffer the existing buffer to append to * @param data pointer to the start of the data * @param len length of the data * @return pointer to the updated buffer, or 0 on failure */ signal_buffer *signal_buffer_append(signal_buffer *buffer, const uint8_t *data, size_t len); /** * Gets the data pointer for the buffer. * This can be used to read and write data stored in the buffer. * * @param buffer pointer to the buffer instance * @return data pointer */ uint8_t *signal_buffer_data(signal_buffer *buffer); /** * Gets the data pointer for the buffer. * This can be used to read and write data stored in the buffer. * * @param buffer pointer to the buffer instance * @return data pointer */ const uint8_t *signal_buffer_const_data(const signal_buffer *buffer); /** * Gets the length of the data stored within the buffer. * * @param buffer pointer to the buffer instance * @return data length */ size_t signal_buffer_len(const signal_buffer *buffer); /** * Compare two buffers. * * @param buffer1 first buffer to compare * @param buffer2 second buffer to compare * @return 0 if the two buffers are equal, negative or positive otherwise */ int signal_buffer_compare(signal_buffer *buffer1, signal_buffer *buffer2); /** * Free the data buffer. * * @param buffer pointer to the buffer instance to free */ void signal_buffer_free(signal_buffer *buffer); /** * Zero and free the data buffer. * This function should be used when the buffer contains sensitive * data, to make sure the memory is cleared before being freed. * * @param buffer pointer to the buffer instance to free */ void signal_buffer_bzero_free(signal_buffer *buffer); /** * Allocate a new buffer list. * * @return pointer to the allocated buffer, or 0 on failure */ signal_buffer_list *signal_buffer_list_alloc(void); /** * Create a copy of an existing buffer list. * * @param list the existing buffer list to copy * @return pointer to the updated buffer, or 0 on failure */ signal_buffer_list *signal_buffer_list_copy(const signal_buffer_list *list); /** * Push the provided buffer onto the end of the list. * The list will take ownership of the buffer, and free it when the list is * freed. * * @param list the buffer list * @param buffer the buffer to push * @return 0 on success, or negative on failure */ int signal_buffer_list_push_back(signal_buffer_list *list, signal_buffer *buffer); /** * Gets the size of the buffer list. * * @param list the buffer list * @return the size of the list */ unsigned int signal_buffer_list_size(signal_buffer_list *list); /** * Gets the value of the element at a particular index in the list * * @param list the list * @param index the index within the list * @return the value */ signal_buffer *signal_buffer_list_at(signal_buffer_list *list, unsigned int index); /** * Free the buffer list, including all the buffers added to it. * * @param list the buffer list */ void signal_buffer_list_free(signal_buffer_list *list); /** * Free the buffer list, including all the buffers added to it. * This function should be used when the buffer list contains sensitive * data, to make sure the memory is cleared before being freed. * * @param list the buffer list */ void signal_buffer_list_bzero_free(signal_buffer_list *list); /** * Allocate a new int list * * @return pointer to the allocated buffer, or 0 on failure */ signal_int_list *signal_int_list_alloc(void); /** * Push a new value onto the end of the list * * @param list the list * @param value the value to push * @return 0 on success, or negative on failure */ int signal_int_list_push_back(signal_int_list *list, int value); /** * Gets the size of the list. * * @param list the list * @return the size of the list */ unsigned int signal_int_list_size(signal_int_list *list); /** * Gets the value of the element at a particular index in the list * * @param list the list * @param index the index within the list * @return the value */ int signal_int_list_at(signal_int_list *list, unsigned int index); /** * Free the int list * @param list the list to free */ void signal_int_list_free(signal_int_list *list); typedef struct signal_crypto_provider { /** * Callback for a secure random number generator. * This function shall fill the provided buffer with random bytes. * * @param data pointer to the output buffer * @param len size of the output buffer * @return 0 on success, negative on failure */ int (*random_func)(uint8_t *data, size_t len, void *user_data); /** * Callback for an HMAC-SHA256 implementation. * This function shall initialize an HMAC context with the provided key. * * @param hmac_context private HMAC context pointer * @param key pointer to the key * @param key_len length of the key * @return 0 on success, negative on failure */ int (*hmac_sha256_init_func)(void **hmac_context, const uint8_t *key, size_t key_len, void *user_data); /** * Callback for an HMAC-SHA256 implementation. * This function shall update the HMAC context with the provided data * * @param hmac_context private HMAC context pointer * @param data pointer to the data * @param data_len length of the data * @return 0 on success, negative on failure */ int (*hmac_sha256_update_func)(void *hmac_context, const uint8_t *data, size_t data_len, void *user_data); /** * Callback for an HMAC-SHA256 implementation. * This function shall finalize an HMAC calculation and populate the output * buffer with the result. * * @param hmac_context private HMAC context pointer * @param output buffer to be allocated and populated with the result * @return 0 on success, negative on failure */ int (*hmac_sha256_final_func)(void *hmac_context, signal_buffer **output, void *user_data); /** * Callback for an HMAC-SHA256 implementation. * This function shall free the private context allocated in * hmac_sha256_init_func. * * @param hmac_context private HMAC context pointer */ void (*hmac_sha256_cleanup_func)(void *hmac_context, void *user_data); /** * Callback for a SHA512 message digest implementation. * This function shall initialize a digest context. * * @param digest_context private digest context pointer * @return 0 on success, negative on failure */ int (*sha512_digest_init_func)(void **digest_context, void *user_data); /** * Callback for a SHA512 message digest implementation. * This function shall update the digest context with the provided data. * * @param digest_context private digest context pointer * @param data pointer to the data * @param data_len length of the data * @return 0 on success, negative on failure */ int (*sha512_digest_update_func)(void *digest_context, const uint8_t *data, size_t data_len, void *user_data); /** * Callback for a SHA512 message digest implementation. * This function shall finalize the digest calculation, populate the * output buffer with the result, and prepare the context for reuse. * * @param digest_context private digest context pointer * @param output buffer to be allocated and populated with the result * @return 0 on success, negative on failure */ int (*sha512_digest_final_func)(void *digest_context, signal_buffer **output, void *user_data); /** * Callback for a SHA512 message digest implementation. * This function shall free the private context allocated in * sha512_digest_init_func. * * @param digest_context private digest context pointer */ void (*sha512_digest_cleanup_func)(void *digest_context, void *user_data); /** * Callback for an AES encryption implementation. * * @param output buffer to be allocated and populated with the ciphertext * @param cipher specific cipher variant to use, either SG_CIPHER_AES_CTR_NOPADDING or SG_CIPHER_AES_CBC_PKCS5 * @param key the encryption key * @param key_len length of the encryption key * @param iv the initialization vector * @param iv_len length of the initialization vector * @param plaintext the plaintext to encrypt * @param plaintext_len length of the plaintext * @return 0 on success, negative on failure */ int (*encrypt_func)(signal_buffer **output, int cipher, const uint8_t *key, size_t key_len, const uint8_t *iv, size_t iv_len, const uint8_t *plaintext, size_t plaintext_len, void *user_data); /** * Callback for an AES decryption implementation. * * @param output buffer to be allocated and populated with the plaintext * @param cipher specific cipher variant to use, either SG_CIPHER_AES_CTR_NOPADDING or SG_CIPHER_AES_CBC_PKCS5 * @param key the encryption key * @param key_len length of the encryption key * @param iv the initialization vector * @param iv_len length of the initialization vector * @param ciphertext the ciphertext to decrypt * @param ciphertext_len length of the ciphertext * @return 0 on success, negative on failure */ int (*decrypt_func)(signal_buffer **output, int cipher, const uint8_t *key, size_t key_len, const uint8_t *iv, size_t iv_len, const uint8_t *ciphertext, size_t ciphertext_len, void *user_data); /** User data pointer */ void *user_data; } signal_crypto_provider; typedef struct signal_protocol_session_store { /** * Returns a copy of the serialized session record corresponding to the * provided recipient ID + device ID tuple. * * @param record pointer to a freshly allocated buffer containing the * serialized session record. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @param user_record pointer to a freshly allocated buffer containing * application specific data stored alongside the serialized session * record. If no such data exists, then this pointer may be left unset. * The Signal Protocol library is responsible for freeing this buffer. * @param address the address of the remote client * @return 1 if the session was loaded, 0 if the session was not found, negative on failure */ int (*load_session_func)(signal_buffer **record, signal_buffer **user_record, const signal_protocol_address *address, void *user_data); /** * Returns all known devices with active sessions for a recipient * * @param pointer to an array that will be allocated and populated with the result * @param name the name of the remote client * @param name_len the length of the name * @return size of the sessions array, or negative on failure */ int (*get_sub_device_sessions_func)(signal_int_list **sessions, const char *name, size_t name_len, void *user_data); /** * Commit to storage the session record for a given * recipient ID + device ID tuple. * * @param address the address of the remote client * @param record pointer to a buffer containing the serialized session * record for the remote client * @param record_len length of the serialized session record * @param user_record pointer to a buffer containing application specific * data to be stored alongside the serialized session record for the * remote client. If no such data exists, then this pointer will be null. * @param user_record_len length of the application specific data * @return 0 on success, negative on failure */ int (*store_session_func)(const signal_protocol_address *address, uint8_t *record, size_t record_len, uint8_t *user_record, size_t user_record_len, void *user_data); /** * Determine whether there is a committed session record for a * recipient ID + device ID tuple. * * @param address the address of the remote client * @return 1 if a session record exists, 0 otherwise. */ int (*contains_session_func)(const signal_protocol_address *address, void *user_data); /** * Remove a session record for a recipient ID + device ID tuple. * * @param address the address of the remote client * @return 1 if a session was deleted, 0 if a session was not deleted, negative on error */ int (*delete_session_func)(const signal_protocol_address *address, void *user_data); /** * Remove the session records corresponding to all devices of a recipient ID. * * @param name the name of the remote client * @param name_len the length of the name * @return the number of deleted sessions on success, negative on failure */ int (*delete_all_sessions_func)(const char *name, size_t name_len, void *user_data); /** * Function called to perform cleanup when the data store context is being * destroyed. */ void (*destroy_func)(void *user_data); /** User data pointer */ void *user_data; } signal_protocol_session_store; typedef struct signal_protocol_pre_key_store { /** * Load a local serialized PreKey record. * * @param record pointer to a newly allocated buffer containing the record, * if found. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @param pre_key_id the ID of the local serialized PreKey record * @retval SG_SUCCESS if the key was found * @retval SG_ERR_INVALID_KEY_ID if the key could not be found */ int (*load_pre_key)(signal_buffer **record, uint32_t pre_key_id, void *user_data); /** * Store a local serialized PreKey record. * * @param pre_key_id the ID of the PreKey record to store. * @param record pointer to a buffer containing the serialized record * @param record_len length of the serialized record * @return 0 on success, negative on failure */ int (*store_pre_key)(uint32_t pre_key_id, uint8_t *record, size_t record_len, void *user_data); /** * Determine whether there is a committed PreKey record matching the * provided ID. * * @param pre_key_id A PreKey record ID. * @return 1 if the store has a record for the PreKey ID, 0 otherwise */ int (*contains_pre_key)(uint32_t pre_key_id, void *user_data); /** * Delete a PreKey record from local storage. * * @param pre_key_id The ID of the PreKey record to remove. * @return 0 on success, negative on failure */ int (*remove_pre_key)(uint32_t pre_key_id, void *user_data); /** * Function called to perform cleanup when the data store context is being * destroyed. */ void (*destroy_func)(void *user_data); /** User data pointer */ void *user_data; } signal_protocol_pre_key_store; typedef struct signal_protocol_signed_pre_key_store { /** * Load a local serialized signed PreKey record. * * @param record pointer to a newly allocated buffer containing the record, * if found. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @param signed_pre_key_id the ID of the local signed PreKey record * @retval SG_SUCCESS if the key was found * @retval SG_ERR_INVALID_KEY_ID if the key could not be found */ int (*load_signed_pre_key)(signal_buffer **record, uint32_t signed_pre_key_id, void *user_data); /** * Store a local serialized signed PreKey record. * * @param signed_pre_key_id the ID of the signed PreKey record to store * @param record pointer to a buffer containing the serialized record * @param record_len length of the serialized record * @return 0 on success, negative on failure */ int (*store_signed_pre_key)(uint32_t signed_pre_key_id, uint8_t *record, size_t record_len, void *user_data); /** * Determine whether there is a committed signed PreKey record matching * the provided ID. * * @param signed_pre_key_id A signed PreKey record ID. * @return 1 if the store has a record for the signed PreKey ID, 0 otherwise */ int (*contains_signed_pre_key)(uint32_t signed_pre_key_id, void *user_data); /** * Delete a SignedPreKeyRecord from local storage. * * @param signed_pre_key_id The ID of the signed PreKey record to remove. * @return 0 on success, negative on failure */ int (*remove_signed_pre_key)(uint32_t signed_pre_key_id, void *user_data); /** * Function called to perform cleanup when the data store context is being * destroyed. */ void (*destroy_func)(void *user_data); /** User data pointer */ void *user_data; } signal_protocol_signed_pre_key_store; typedef struct signal_protocol_identity_key_store { /** * Get the local client's identity key pair. * * @param public_data pointer to a newly allocated buffer containing the * public key, if found. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @param private_data pointer to a newly allocated buffer containing the * private key, if found. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @return 0 on success, negative on failure */ int (*get_identity_key_pair)(signal_buffer **public_data, signal_buffer **private_data, void *user_data); /** * Return the local client's registration ID. * * Clients should maintain a registration ID, a random number * between 1 and 16380 that's generated once at install time. * * @param registration_id pointer to be set to the local client's * registration ID, if it was successfully retrieved. * @return 0 on success, negative on failure */ int (*get_local_registration_id)(void *user_data, uint32_t *registration_id); /** * Save a remote client's identity key *

* Store a remote client's identity key as trusted. * The value of key_data may be null. In this case remove the key data * from the identity store, but retain any metadata that may be kept * alongside it. * * @param address the address of the remote client * @param key_data Pointer to the remote client's identity key, may be null * @param key_len Length of the remote client's identity key * @return 0 on success, negative on failure */ int (*save_identity)(const signal_protocol_address *address, uint8_t *key_data, size_t key_len, void *user_data); /** * Verify a remote client's identity key. * * Determine whether a remote client's identity is trusted. Convention is * that the TextSecure protocol is 'trust on first use.' This means that * an identity key is considered 'trusted' if there is no entry for the recipient * in the local store, or if it matches the saved key for a recipient in the local * store. Only if it mismatches an entry in the local store is it considered * 'untrusted.' * * @param address the address of the remote client * @param identityKey The identity key to verify. * @param key_data Pointer to the identity key to verify * @param key_len Length of the identity key to verify * @return 1 if trusted, 0 if untrusted, negative on failure */ int (*is_trusted_identity)(const signal_protocol_address *address, uint8_t *key_data, size_t key_len, void *user_data); /** * Function called to perform cleanup when the data store context is being * destroyed. */ void (*destroy_func)(void *user_data); /** User data pointer */ void *user_data; } signal_protocol_identity_key_store; typedef struct signal_protocol_sender_key_store { /** * Store a serialized sender key record for a given * (groupId + senderId + deviceId) tuple. * * @param sender_key_name the (groupId + senderId + deviceId) tuple * @param record pointer to a buffer containing the serialized record * @param record_len length of the serialized record * @param user_record pointer to a buffer containing application specific * data to be stored alongside the serialized record. If no such * data exists, then this pointer will be null. * @param user_record_len length of the application specific data * @return 0 on success, negative on failure */ int (*store_sender_key)(const signal_protocol_sender_key_name *sender_key_name, uint8_t *record, size_t record_len, uint8_t *user_record, size_t user_record_len, void *user_data); /** * Returns a copy of the sender key record corresponding to the * (groupId + senderId + deviceId) tuple. * * @param record pointer to a newly allocated buffer containing the record, * if found. Unset if no record was found. * The Signal Protocol library is responsible for freeing this buffer. * @param user_record pointer to a newly allocated buffer containing * application-specific data stored alongside the record. If no such * data exists, then this pointer may be left unset. * The Signal Protocol library is responsible for freeing this buffer. * @param sender_key_name the (groupId + senderId + deviceId) tuple * @return 1 if the record was loaded, 0 if the record was not found, negative on failure */ int (*load_sender_key)(signal_buffer **record, signal_buffer **user_record, const signal_protocol_sender_key_name *sender_key_name, void *user_data); /** * Function called to perform cleanup when the data store context is being * destroyed. */ void (*destroy_func)(void *user_data); /** User data pointer */ void *user_data; } signal_protocol_sender_key_store; /** * Create a new instance of the global library context. */ int signal_context_create(signal_context **context, void *user_data); /** * Set the crypto provider to be used by the Signal Protocol library. * * @param crypto_provider Populated structure of crypto provider function * pointers. The contents of this structure are copied, so the caller * does not need to maintain its instance. * @return 0 on success, negative on failure */ int signal_context_set_crypto_provider(signal_context *context, const signal_crypto_provider *crypto_provider); /** * Set the locking functions to be used by the Signal Protocol library for * synchronization. * * Note: These functions must allow recursive locking (e.g. PTHREAD_MUTEX_RECURSIVE) * * @param lock function to lock a mutex * @param unlock function to unlock a mutex * @return 0 on success, negative on failure */ int signal_context_set_locking_functions(signal_context *context, void (*lock)(void *user_data), void (*unlock)(void *user_data)); /** * Set the log function to be used by the Signal Protocol library for logging. * * @return 0 on success, negative on failure */ int signal_context_set_log_function(signal_context *context, void (*log)(int level, const char *message, size_t len, void *user_data)); void signal_context_destroy(signal_context *context); /** * Create a new instance of the Signal Protocol data store interface. */ int signal_protocol_store_context_create(signal_protocol_store_context **context, signal_context *global_context); int signal_protocol_store_context_set_session_store(signal_protocol_store_context *context, const signal_protocol_session_store *store); int signal_protocol_store_context_set_pre_key_store(signal_protocol_store_context *context, const signal_protocol_pre_key_store *store); int signal_protocol_store_context_set_signed_pre_key_store(signal_protocol_store_context *context, const signal_protocol_signed_pre_key_store *store); int signal_protocol_store_context_set_identity_key_store(signal_protocol_store_context *context, const signal_protocol_identity_key_store *store); int signal_protocol_store_context_set_sender_key_store(signal_protocol_store_context *context, const signal_protocol_sender_key_store *store); void signal_protocol_store_context_destroy(signal_protocol_store_context *context); /* * Interface to the session store. * These functions will use the callbacks in the provided * signal_protocol_store_context instance and operate in terms of higher level * library data structures. */ int signal_protocol_session_load_session(signal_protocol_store_context *context, session_record **record, const signal_protocol_address *address); int signal_protocol_session_get_sub_device_sessions(signal_protocol_store_context *context, signal_int_list **sessions, const char *name, size_t name_len); int signal_protocol_session_store_session(signal_protocol_store_context *context, const signal_protocol_address *address, session_record *record); int signal_protocol_session_contains_session(signal_protocol_store_context *context, const signal_protocol_address *address); int signal_protocol_session_delete_session(signal_protocol_store_context *context, const signal_protocol_address *address); int signal_protocol_session_delete_all_sessions(signal_protocol_store_context *context, const char *name, size_t name_len); /* * Interface to the pre-key store. * These functions will use the callbacks in the provided * signal_protocol_store_context instance and operate in terms of higher level * library data structures. */ int signal_protocol_pre_key_load_key(signal_protocol_store_context *context, session_pre_key **pre_key, uint32_t pre_key_id); int signal_protocol_pre_key_store_key(signal_protocol_store_context *context, session_pre_key *pre_key); int signal_protocol_pre_key_contains_key(signal_protocol_store_context *context, uint32_t pre_key_id); int signal_protocol_pre_key_remove_key(signal_protocol_store_context *context, uint32_t pre_key_id); /* * Interface to the signed pre-key store. * These functions will use the callbacks in the provided * signal_protocol_store_context instance and operate in terms of higher level * library data structures. */ int signal_protocol_signed_pre_key_load_key(signal_protocol_store_context *context, session_signed_pre_key **pre_key, uint32_t signed_pre_key_id); int signal_protocol_signed_pre_key_store_key(signal_protocol_store_context *context, session_signed_pre_key *pre_key); int signal_protocol_signed_pre_key_contains_key(signal_protocol_store_context *context, uint32_t signed_pre_key_id); int signal_protocol_signed_pre_key_remove_key(signal_protocol_store_context *context, uint32_t signed_pre_key_id); /* * Interface to the identity key store. * These functions will use the callbacks in the provided * signal_protocol_store_context instance and operate in terms of higher level * library data structures. */ int signal_protocol_identity_get_key_pair(signal_protocol_store_context *context, ratchet_identity_key_pair **key_pair); int signal_protocol_identity_get_local_registration_id(signal_protocol_store_context *context, uint32_t *registration_id); int signal_protocol_identity_save_identity(signal_protocol_store_context *context, const signal_protocol_address *address, ec_public_key *identity_key); int signal_protocol_identity_is_trusted_identity(signal_protocol_store_context *context, const signal_protocol_address *address, ec_public_key *identity_key); /* * Interface to the sender key store. * These functions will use the callbacks in the provided * signal_protocol_store_context instance and operate in terms of higher level * library data structures. */ int signal_protocol_sender_key_store_key(signal_protocol_store_context *context, const signal_protocol_sender_key_name *sender_key_name, sender_key_record *record); int signal_protocol_sender_key_load_key(signal_protocol_store_context *context, sender_key_record **record, const signal_protocol_sender_key_name *sender_key_name); #ifdef __cplusplus } #endif #endif /* SIGNAL_PROTOCOL_H */