/* Jabber Protocol Plugin for Miranda NG Copyright (c) 2017-18 Miranda NG team This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ //TODO: further improovement requirements folllows in priority sequence /* * 1. per-contact encryption settings (enable/disable for one contact) * 2. fingerprints/keys management ui */ #include "stdafx.h" #include "jabber_omemo.h" #include #include #include #include #include #include #include #include #include #include //c++ #include #include #include namespace utils { // code from http://stackoverflow.com/questions/3368883/how-does-this-size-of-array-template-function-work template struct type_of_size { typedef char type[N]; }; template typename type_of_size::type& sizeof_array_helper(T(&)[Size]); #define _countof_portable(pArray) sizeof(sizeof_array_helper(pArray)) } using namespace utils; namespace omemo { int random_func(uint8_t *data, size_t len, void * /*user_data*/) { Utils_GetRandom(data, len); return 0; } int hmac_sha256_init_func(void **hmac_context, const uint8_t *key, size_t key_len, void * /*user_data*/) { HMAC_CTX *ctx = (HMAC_CTX*)mir_alloc(sizeof(HMAC_CTX)); HMAC_CTX_init(ctx); HMAC_Init_ex(ctx, key, (int)key_len, EVP_sha256(), NULL); *hmac_context = ctx; //TODO: handle errors return 0; } int hmac_sha256_update_func(void *hmac_context, const uint8_t *data, size_t data_len, void * /*user_data*/) { HMAC_CTX *ctx = (HMAC_CTX*)hmac_context; HMAC_Update(ctx, data, data_len); //TODO: handle errors return 0; } int hmac_sha256_final_func(void *hmac_context, signal_buffer **output, void * /*user_data*/) { HMAC_CTX *ctx = (HMAC_CTX*)hmac_context; unsigned char buf[128]; unsigned int len = 0; HMAC_Final(ctx, buf, &len); signal_buffer *output_buffer = signal_buffer_create(buf, len); *output = output_buffer; //TODO: handle errors return 0; } void hmac_sha256_cleanup_func(void * hmac_context, void * /*user_data*/) { HMAC_CTX *ctx = (HMAC_CTX*)hmac_context; HMAC_CTX_cleanup(ctx); mir_free(ctx); } int sha512_digest_init_func(void **digest_context, void * /*user_data*/) { int result = 0; EVP_MD_CTX *ctx; ctx = EVP_MD_CTX_create(); if (!ctx) { result = SG_ERR_NOMEM; goto complete; } result = EVP_DigestInit_ex(ctx, EVP_sha512(), nullptr); if (result == 1) { result = SG_SUCCESS; } else { result = SG_ERR_UNKNOWN; } complete: if (result < 0) { if (ctx) { EVP_MD_CTX_destroy(ctx); } } else { *digest_context = ctx; } return result; } int sha512_digest_update_func(void *digest_context, const uint8_t *data, size_t data_len, void * /*user_data*/) { EVP_MD_CTX *ctx = (EVP_MD_CTX*)digest_context; int result = EVP_DigestUpdate(ctx, data, data_len); return (result == 1) ? SG_SUCCESS : SG_ERR_UNKNOWN; } int sha512_digest_final_func(void *digest_context, signal_buffer **output, void * /*user_data*/) { int result = 0; unsigned char md[EVP_MAX_MD_SIZE]; unsigned int len = 0; EVP_MD_CTX *ctx = (EVP_MD_CTX*)digest_context; result = EVP_DigestFinal_ex(ctx, md, &len); if (result == 1) { result = SG_SUCCESS; } else { result = SG_ERR_UNKNOWN; goto complete; } result = EVP_DigestInit_ex(ctx, EVP_sha512(), nullptr); if (result == 1) { result = SG_SUCCESS; } else { result = SG_ERR_UNKNOWN; goto complete; } signal_buffer *output_buffer = signal_buffer_create(md, len); if (!output_buffer) { result = SG_ERR_NOMEM; goto complete; } *output = output_buffer; complete: return result; } void sha512_digest_cleanup_func(void *digest_context, void * /*user_data*/) { EVP_MD_CTX *ctx = (EVP_MD_CTX *)digest_context; EVP_MD_CTX_destroy(ctx); } const EVP_CIPHER *aes_cipher(int cipher, size_t key_len) { if (cipher == SG_CIPHER_AES_CBC_PKCS5) { if (key_len == 16) { return EVP_aes_128_cbc(); } else if (key_len == 24) { return EVP_aes_192_cbc(); } else if (key_len == 32) { return EVP_aes_256_cbc(); } } else if (cipher == SG_CIPHER_AES_CTR_NOPADDING) { if (key_len == 16) { return EVP_aes_128_ctr(); } else if (key_len == 24) { return EVP_aes_192_ctr(); } else if (key_len == 32) { return EVP_aes_256_ctr(); } } return nullptr; } 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*/) { //TODO: use netlib for log int result = 0; uint8_t *out_buf = nullptr; const EVP_CIPHER *evp_cipher = aes_cipher(cipher, key_len); if (!evp_cipher) { //fprintf(stderr, "invalid AES mode or key size: %zu\n", key_len); return SG_ERR_UNKNOWN; } if (iv_len != 16) { //fprintf(stderr, "invalid AES IV size: %zu\n", iv_len); return SG_ERR_UNKNOWN; } if (plaintext_len > INT_MAX - EVP_CIPHER_block_size(evp_cipher)) { //fprintf(stderr, "invalid plaintext length: %zu\n", plaintext_len); return SG_ERR_UNKNOWN; } EVP_CIPHER_CTX ctx; EVP_CIPHER_CTX_init(&ctx); result = EVP_EncryptInit_ex(&ctx, evp_cipher, nullptr, key, iv); if (!result) { //fprintf(stderr, "cannot initialize cipher\n"); result = SG_ERR_UNKNOWN; goto complete; } if (cipher == SG_CIPHER_AES_CTR_NOPADDING) { result = EVP_CIPHER_CTX_set_padding(&ctx, 0); if (!result) { //fprintf(stderr, "cannot set padding\n"); result = SG_ERR_UNKNOWN; goto complete; } } out_buf = (uint8_t*)mir_alloc(sizeof(uint8_t) * (plaintext_len + EVP_CIPHER_block_size(evp_cipher))); if (!out_buf) { //fprintf(stderr, "cannot allocate output buffer\n"); result = SG_ERR_NOMEM; goto complete; } int out_len = 0; result = EVP_EncryptUpdate(&ctx, out_buf, &out_len, plaintext, (int)plaintext_len); if (!result) { //fprintf(stderr, "cannot encrypt plaintext\n"); result = SG_ERR_UNKNOWN; goto complete; } int final_len = 0; result = EVP_EncryptFinal_ex(&ctx, out_buf + out_len, &final_len); if (!result) { //fprintf(stderr, "cannot finish encrypting plaintext\n"); result = SG_ERR_UNKNOWN; goto complete; } *output = signal_buffer_create(out_buf, out_len + final_len); complete: EVP_CIPHER_CTX_cleanup(&ctx); if (out_buf) { mir_free(out_buf); } return result; } 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*/) { //TODO: use netlib for log int result = 0; uint8_t *out_buf = nullptr; const EVP_CIPHER *evp_cipher = aes_cipher(cipher, key_len); if (!evp_cipher) { //fprintf(stderr, "invalid AES mode or key size: %zu\n", key_len); return SG_ERR_INVAL; } if (iv_len != 16) { //fprintf(stderr, "invalid AES IV size: %zu\n", iv_len); return SG_ERR_INVAL; } if (ciphertext_len > INT_MAX - EVP_CIPHER_block_size(evp_cipher)) { //fprintf(stderr, "invalid ciphertext length: %zu\n", ciphertext_len); return SG_ERR_UNKNOWN; } EVP_CIPHER_CTX ctx; EVP_CIPHER_CTX_init(&ctx); result = EVP_DecryptInit_ex(&ctx, evp_cipher, nullptr, key, iv); if (!result) { ///fprintf(stderr, "cannot initialize cipher\n"); result = SG_ERR_UNKNOWN; goto complete; } if (cipher == SG_CIPHER_AES_CTR_NOPADDING) { result = EVP_CIPHER_CTX_set_padding(&ctx, 0); if (!result) { //fprintf(stderr, "cannot set padding\n"); result = SG_ERR_UNKNOWN; goto complete; } } out_buf = (uint8_t*)mir_alloc(sizeof(uint8_t) * (ciphertext_len + EVP_CIPHER_block_size(evp_cipher))); if (!out_buf) { //fprintf(stderr, "cannot allocate output buffer\n"); result = SG_ERR_UNKNOWN; goto complete; } int out_len = 0; result = EVP_DecryptUpdate(&ctx, out_buf, &out_len, ciphertext, (int)ciphertext_len); if (!result) { //fprintf(stderr, "cannot decrypt ciphertext\n"); result = SG_ERR_UNKNOWN; goto complete; } int final_len = 0; result = EVP_DecryptFinal_ex(&ctx, out_buf + out_len, &final_len); if (!result) { //fprintf(stderr, "cannot finish decrypting ciphertext\n"); result = SG_ERR_UNKNOWN; goto complete; } *output = signal_buffer_create(out_buf, out_len + final_len); complete: EVP_CIPHER_CTX_cleanup(&ctx); if (out_buf) { mir_free(out_buf); } return result; } void lock(void *user_data) { omemo_impl *omi = (omemo_impl*)user_data; omi->signal_mutex->lock(); } void unlock(void *user_data) { omemo_impl *omi = (omemo_impl*)user_data; omi->signal_mutex->unlock(); } signal_context *global_context = nullptr; struct incomming_message { incomming_message(HXML x, wchar_t *j, time_t t) { node = x; jid = j; msgTime = t; } HXML node; wchar_t *jid; time_t msgTime; }; struct outgoing_message { outgoing_message(MCONTACT h, int u, char* p) { hContact = h; unused_unknown = u; pszSrc = p; } MCONTACT hContact; int unused_unknown; char* pszSrc; }; struct message_queue { std::list incomming_messages; std::list outgoing_messages; }; struct omemo_session_jabber_internal_ptrs { session_builder *builder; session_cipher *cipher; signal_protocol_store_context *store_context; }; omemo_impl::omemo_impl(CJabberProto *p) : proto(p), signal_mutex(nullptr), provider(nullptr) { if (proto->m_bUseOMEMO) init(); } void omemo_impl::init() { if (provider && signal_mutex) return; if (!global_context) signal_context_create(&global_context, this); signal_mutex = new mir_cslockfull(_signal_cs); signal_mutex->unlock(); //fuck... provider = new signal_crypto_provider; provider->random_func = &random_func; provider->hmac_sha256_init_func = &hmac_sha256_init_func; provider->hmac_sha256_update_func = &hmac_sha256_update_func; provider->hmac_sha256_final_func = &hmac_sha256_final_func; provider->hmac_sha256_cleanup_func = &hmac_sha256_cleanup_func; provider->sha512_digest_init_func = &sha512_digest_init_func; provider->sha512_digest_update_func = &sha512_digest_update_func; provider->sha512_digest_final_func = &sha512_digest_final_func; provider->sha512_digest_cleanup_func = &sha512_digest_cleanup_func; provider->encrypt_func = &encrypt_func; provider->decrypt_func = &decrypt_func; if (signal_context_set_crypto_provider(global_context, provider)) { proto->debugLogA("Jabber OMEMO: signal_context_set_crypto_provider failed"); //TODO: handle error } if (signal_context_set_locking_functions(global_context, &lock, &unlock)) { proto->debugLogA("Jabber OMEMO: signal_context_set_crypto_provider failed"); //TODO: handle error } sessions_internal = new std::map >; message_queue_internal = new message_queue; session_checked = new std::map; } omemo_impl::~omemo_impl() { if (proto->m_bUseOMEMO) { deinit(); } } void omemo_impl::deinit() { if (provider && signal_mutex) { for (std::map >::iterator i = ((std::map >*)sessions_internal)->begin(), end = ((std::map >*)sessions_internal)->end(); i != end; ++i) { for (std::map::iterator i2 = i->second.begin(), end2 = i->second.end(); i2 != end2; ++i2) { if (i2->second.cipher) session_cipher_free(i2->second.cipher); if (i2->second.builder) session_builder_free(i2->second.builder); if (i2->second.store_context) signal_protocol_store_context_destroy(i2->second.store_context); } } ((std::map >*)sessions_internal)->clear(); delete (std::map >*)sessions_internal; delete signal_mutex; delete provider; delete message_queue_internal; delete session_checked; provider = nullptr; signal_mutex = nullptr; } } struct omemo_device { uint32_t id; ratchet_identity_key_pair *device_key; }; omemo_device* omemo_impl::create_device() { omemo_device *dev = (omemo_device*)mir_alloc(sizeof(omemo_device)); for (dev->id = 0; dev->id == 0;) { Utils_GetRandom((void*)&(dev->id), 4); } dev->id &= ~0x80000000; if (signal_protocol_key_helper_generate_identity_key_pair(&(dev->device_key), global_context)) { proto->debugLogA("Jabber OMEMO: signal_protocol_key_helper_generate_identity_key_pair failed"); //TODO: handle error } return dev; } bool omemo_impl::IsFirstRun() { //TODO: more sanity checks //TODO: check and if necessary refresh prekeys unsigned int id = proto->getDword("OmemoDeviceId", 0); if (id == 0) return true; ptrA buf(proto->getStringA("OmemoDevicePublicKey")); if (!buf || !buf[0]) return true; ptrA buf2(proto->getStringA("OmemoDevicePrivateKey")); //ptrA reinitialization always return "" or random trash if (!buf2 || !buf2[0]) return true; return false; } unsigned long omemo_impl::GetOwnDeviceId() { unsigned long own_id = proto->getDword("OmemoDeviceId", 0); if (own_id == 0) { proto->OmemoInitDevice(); own_id = proto->getDword("OmemoDeviceId", 0); } return own_id; } void omemo_impl::RefreshDevice() { //generate and save device id omemo_device *new_dev = create_device(); proto->setDword("OmemoDeviceId", new_dev->id); //generate and save device key ec_public_key *public_key = ratchet_identity_key_pair_get_public(new_dev->device_key); signal_buffer *key_buf; ec_public_key_serialize(&key_buf, public_key); // SIGNAL_UNREF(public_key); char *key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); char *fingerprint = (char*)mir_alloc((signal_buffer_len(key_buf) * 2) + 1); bin2hex(signal_buffer_data(key_buf), signal_buffer_len(key_buf), fingerprint); proto->setString("OmemoFingerprintOwn", fingerprint); mir_free(fingerprint); proto->setString("OmemoDevicePublicKey", key); mir_free(key); signal_buffer_free(key_buf); ec_private_key *private_key = ratchet_identity_key_pair_get_private(new_dev->device_key); ec_private_key_serialize(&key_buf, private_key); // SIGNAL_UNREF(private_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); proto->setString("OmemoDevicePrivateKey", key); mir_free(key); signal_buffer_free(key_buf); //generate and save signed pre key session_signed_pre_key* signed_pre_key; { const unsigned int signed_pre_key_id = 1; signal_protocol_key_helper_generate_signed_pre_key(&signed_pre_key, new_dev->device_key, signed_pre_key_id, time(0), global_context); SIGNAL_UNREF(new_dev->device_key); signal_buffer *serialized_signed_pre_key; session_signed_pre_key_serialize(&serialized_signed_pre_key, signed_pre_key); char *setting_name = (char*)mir_alloc(strlen("OmemoSignalSignedPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalSignedPreKey_") + 31, "%s%u%d", "OmemoSignalSignedPreKey_", proto->m_omemo.GetOwnDeviceId(), signed_pre_key_id); db_set_blob(0, proto->m_szModuleName, setting_name, signal_buffer_data(serialized_signed_pre_key), (unsigned int)signal_buffer_len(serialized_signed_pre_key)); // SIGNAL_UNREF(serialized_signed_pre_key); mir_free(setting_name); } //TODO: store signed_pre_key for libsignal data backend too //TODO: dynamic signed pre_key id and setting name ? ec_key_pair *signed_pre_key_pair = session_signed_pre_key_get_key_pair(signed_pre_key); public_key = ec_key_pair_get_public(signed_pre_key_pair); ec_public_key_serialize(&key_buf, public_key); // SIGNAL_UNREF(public_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); proto->setString("OmemoSignedPreKeyPublic", key); mir_free(key); signal_buffer_free(key_buf); char *signature = mir_base64_encode(session_signed_pre_key_get_signature(signed_pre_key), session_signed_pre_key_get_signature_len(signed_pre_key)); proto->setString("OmemoSignedPreKeySignature", signature); mir_free(signature); //generate and save pre keys set signal_protocol_key_helper_pre_key_list_node *keys_root, *it; signal_protocol_key_helper_generate_pre_keys(&keys_root, 0, 100, global_context); it = keys_root; char setting_name[64], setting_name2[64]; for (; it; it = signal_protocol_key_helper_key_list_next(it)) { session_pre_key *pre_key = signal_protocol_key_helper_key_list_element(it); uint32_t pre_key_id = session_pre_key_get_id(pre_key); { signal_buffer *serialized_pre_key; session_pre_key_serialize(&serialized_pre_key, pre_key); mir_snprintf(setting_name2, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", GetOwnDeviceId(), pre_key_id); db_set_blob(0, proto->m_szModuleName, setting_name2, signal_buffer_data(serialized_pre_key), (unsigned int)signal_buffer_len(serialized_pre_key)); SIGNAL_UNREF(serialized_pre_key); } ec_key_pair *pre_key_pair = session_pre_key_get_key_pair(pre_key); public_key = ec_key_pair_get_public(pre_key_pair); ec_public_key_serialize(&key_buf, public_key); SIGNAL_UNREF(public_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); mir_snprintf(setting_name, "OmemoPreKey%uPublic", pre_key_id); proto->setString(setting_name, key); mir_free(key); signal_buffer_free(key_buf); } signal_protocol_key_helper_key_list_free(keys_root); } //signal_protocol_session_store callbacks follow struct signal_store_backend_user_data { MCONTACT hContact; unsigned int device_id; CJabberProto *proto; }; int load_session_func(signal_buffer **record, signal_buffer ** /*user_data_storage*/, const signal_protocol_address *address, void *user_data) { /** * 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 address the address of the remote client * @return 1 if the session was loaded, 0 if the session was not found, negative on failure */ //some sanity checks signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; if ((unsigned long)address->device_id == 0) { data->proto->debugLogA("Jabber OMEMO: libsignal data backend impl: failed to load session (invalid device id)"); return -1; } if (address->name_len > JABBER_MAX_JID_LEN) { data->proto->debugLogA("Jabber OMEMO: libsignal data backend impl: failed to load session (invalid address length)"); return -1; } char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalSession_", id_str); mir_free(id_str); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(data->hContact, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); data->proto->debugLogA("Jabber OMEMO: libsignal data backend impl: failed to load session (session does not exist)"); return 0; } *record = signal_buffer_create(dbv.pbVal, dbv.cpbVal); db_free(&dbv); return 1; //session exist and succesfully loaded } struct db_enum_settings_sub_cb_data { signal_store_backend_user_data* user_data; unsigned int &arr_size; signal_int_list *sessions; const char *name; size_t name_len; db_enum_settings_sub_cb_data(unsigned int &arr_size_) : arr_size(arr_size_) {} private: db_enum_settings_sub_cb_data(); //we always need array size }; int db_enum_settings_sub_cb(const char *szSetting, void *lParam) { db_enum_settings_sub_cb_data* data = (db_enum_settings_sub_cb_data*)lParam; if (strstr(szSetting, "OmemoSignalSession_")) { char *ptr = (char*)szSetting; ptr += mir_strlen("OmemoSignalSession_"); char *current_name = mir_base64_encode(data->name, data->name_len); if (strstr(ptr, current_name)) { char *dev_encoded = ptr; dev_encoded += strlen(current_name); size_t len; void *dev_tmp = mir_base64_decode(dev_encoded, &len); signal_int_list_push_back(data->sessions, *((int *)dev_tmp)); data->arr_size++; mir_free(dev_tmp); } mir_free(current_name); } return 0; //? } int get_sub_device_sessions_func(signal_int_list **sessions, const char *name, size_t name_len, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; signal_int_list *l = signal_int_list_alloc(); unsigned int array_size = 0; db_enum_settings_sub_cb_data *ud = new db_enum_settings_sub_cb_data(array_size); ud->user_data = data; ud->sessions = l; ud->name = name; ud->name_len = name_len; db_enum_settings(data->hContact, &db_enum_settings_sub_cb, data->proto->m_szModuleName, ud); *sessions = l; delete ud; return array_size; } 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) { /** * 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 * @return 0 on success, negative on failure */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalSession_", id_str); mir_free(id_str); db_set_blob(data->hContact, data->proto->m_szModuleName, setting_name, record, (unsigned int)record_len); //TODO: check return value mir_free(setting_name); return 0; } int contains_session_func(const signal_protocol_address *address, 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. */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalSession_", id_str); mir_free(id_str); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(data->hContact, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); return 0; } db_free(&dbv); return 1; } int delete_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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalSession_", id_str); mir_free(id_str); db_unset(data->hContact, data->proto->m_szModuleName, setting_name); mir_free(setting_name); return 1; } struct db_enum_settings_del_all_cb_data { signal_store_backend_user_data* user_data; std::list settings; const char *name; size_t name_len; }; int db_enum_settings_del_all_cb(const char *szSetting, void *lParam) { db_enum_settings_del_all_cb_data* data = (db_enum_settings_del_all_cb_data*)lParam; if (strstr(szSetting, "OmemoSignalSession_")) { char *ptr = (char*)szSetting; ptr += mir_strlen("OmemoSignalSession_"); char *current_name = mir_base64_encode(data->name, data->name_len); if (strstr(ptr, current_name)) data->settings.push_back(mir_strdup(szSetting)); mir_free(current_name); } return 0;//? } int delete_all_sessions_func(const char *name, size_t name_len, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; db_enum_settings_del_all_cb_data *ud = new db_enum_settings_del_all_cb_data; ud->user_data = data; ud->name = name; ud->name_len = name_len; db_enum_settings(data->hContact, &db_enum_settings_del_all_cb, data->proto->m_szModuleName, (void*)ud); int count = 0; for (std::list::iterator i = ud->settings.begin(), end = ud->settings.end(); i != end; i++) { db_unset(data->hContact, data->proto->m_szModuleName, *i); mir_free(*i); count++; } delete ud; return count; } void destroy_func(void *user_data) { if (user_data) { signal_store_backend_user_data* d = (signal_store_backend_user_data*)user_data; mir_free(d); user_data = nullptr; } } //signal_protocol_pre_key_store callback follow int load_pre_key(signal_buffer **record, uint32_t pre_key_id, void *user_data) { /** * 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", data->proto->m_omemo.GetOwnDeviceId(), pre_key_id); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(0, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); data->proto->debugLogA("Jabber OMEMO: libsignal data backend impl: failed to load prekey SG_ERR_INVALID_KEY_ID"); return SG_ERR_INVALID_KEY_ID; } *record = signal_buffer_create(dbv.pbVal, dbv.cpbVal); db_free(&dbv); return SG_SUCCESS; //key exist and succesfully loaded } int store_pre_key(uint32_t pre_key_id, uint8_t *record, size_t record_len, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", data->proto->m_omemo.GetOwnDeviceId(), pre_key_id); db_set_blob(0, data->proto->m_szModuleName, setting_name, record, (unsigned int)record_len); //TODO: check return value { //store base64 encoded keys for bundle (private key does not required ?) session_pre_key *prekey = nullptr; session_pre_key_deserialize(&prekey, record, record_len, global_context); //TODO: handle error if (prekey) { ec_public_key *public_key = nullptr; //ec_private_key *private_key = nullptr; ec_key_pair *pre_key_pair = session_pre_key_get_key_pair(prekey); signal_buffer *key_buf = nullptr; char *key = nullptr; public_key = ec_key_pair_get_public(pre_key_pair); ec_public_key_serialize(&key_buf, public_key); SIGNAL_UNREF(public_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "OmemoPreKey%uPublic", pre_key_id); data->proto->setString(setting_name, key); mir_free(key); signal_buffer_free(key_buf); /* private_key = ec_key_pair_get_private(pre_key_pair); ec_private_key_serialize(&key_buf, private_key); SIGNAL_UNREF(private_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "OmemoPreKey%uPrivate", pre_key_id); data->proto->setString(setting_name, key); mir_free(key); signal_buffer_free(key_buf); */ } } mir_free(setting_name); //TODO: resend bundle ? return 0; } int contains_pre_key(uint32_t pre_key_id, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", data->proto->m_omemo.GetOwnDeviceId(), pre_key_id); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(0, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); return 0; } db_free(&dbv); return 1; } int remove_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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", data->proto->m_omemo.GetOwnDeviceId(), pre_key_id); db_unset(0, data->proto->m_szModuleName, setting_name); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "OmemoPreKey%uPublic", pre_key_id); db_unset(0, data->proto->m_szModuleName, setting_name); mir_snprintf(setting_name, strlen("OmemoSignalPreKey_") + 31, "OmemoPreKey%uPrivate", pre_key_id); db_unset(0, data->proto->m_szModuleName, setting_name); mir_free(setting_name); //TODO: resend bundle ? return 0; } //void(*destroy_func)(void *user_data); //use first one as we have nothing special to destroy //signal_protocol_signed_pre_key_store callbacks follow int load_signed_pre_key(signal_buffer **record, uint32_t signed_pre_key_id, void *user_data) { /** * 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalSignedPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalSignedPreKey_") + 31, "%s%u%d", "OmemoSignalSignedPreKey_", data->proto->m_omemo.GetOwnDeviceId(), signed_pre_key_id); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(0, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); data->proto->debugLogA("Jabber OMEMO: libsignal data backend impl: failed to load signed prekey SG_ERR_INVALID_KEY_ID"); return SG_ERR_INVALID_KEY_ID; } *record = signal_buffer_create(dbv.pbVal, dbv.cpbVal); db_free(&dbv); return SG_SUCCESS; //key exist and succesfully loaded } int store_signed_pre_key(uint32_t signed_pre_key_id, uint8_t *record, size_t record_len, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalSignedPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalSignedPreKey_") + 31, "%s%u%d", "OmemoSignalSignedPreKey_", data->proto->m_omemo.GetOwnDeviceId(), signed_pre_key_id); db_set_blob(0, data->proto->m_szModuleName, setting_name, record, (unsigned int)record_len); //TODO: check return value mir_free(setting_name); //TODO: additionally store base64encoded public key for bundle return 0; } int contains_signed_pre_key(uint32_t signed_pre_key_id, 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalSignedPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalSignedPreKey_") + 31, "%s%u%d", "OmemoSignalSignedPreKey_", data->proto->m_omemo.GetOwnDeviceId(), signed_pre_key_id); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(0, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (!dbv.cpbVal) { db_free(&dbv); return 0; } db_free(&dbv); return 1; } int remove_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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *setting_name = (char*)mir_alloc(strlen("OmemoSignalSignedPreKey_") + 32); mir_snprintf(setting_name, strlen("OmemoSignalSignedPreKey_") + 31, "%s%u%d", "OmemoSignalSignedPreKey_", data->proto->m_omemo.GetOwnDeviceId(), signed_pre_key_id); db_unset(0, data->proto->m_szModuleName, setting_name); mir_free(setting_name); //TODO: additionally remove base64encoded public key for bundle return 0; } //void(*destroy_func)(void *user_data); //use first one as we have nothing special to destroy //signal_protocol_identity_key_store callbacks follow int get_identity_key_pair(signal_buffer **public_data, signal_buffer **private_data, void *user_data) { /** * 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *pub_key = data->proto->getStringA("OmemoDevicePublicKey"); char *priv_key = data->proto->getStringA("OmemoDevicePrivateKey"); size_t pub_key_len = 0, priv_key_len = 0; char *pub_key_buf = (char*)mir_base64_decode(pub_key, &pub_key_len); mir_free(pub_key); char *priv_key_buf = (char*)mir_base64_decode(priv_key, &priv_key_len); mir_free(priv_key); *public_data = signal_buffer_create((uint8_t*)pub_key_buf, pub_key_len); *private_data = signal_buffer_create((uint8_t*)priv_key_buf, priv_key_len); mir_free(priv_key_buf); mir_free(pub_key_buf); return 0; } int get_local_registration_id(void *user_data, uint32_t *registration_id) { /** * 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 */ // uint32_t *id = (uint32_t*)mir_alloc(sizeof(uint32_t)); signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; /* *id = data->proto->m_omemo.GetOwnDeviceId(); registration_id = id; */ *registration_id = data->proto->m_omemo.GetOwnDeviceId(); return 0; } int save_identity(const signal_protocol_address *address, uint8_t *key_data, size_t key_len, void *user_data) { /** * 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 */ signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalIdentity_", id_str); mir_free(id_str); if (key_data != nullptr) db_set_blob(data->hContact, data->proto->m_szModuleName, setting_name, key_data, (unsigned int)key_len); //TODO: check return value else db_unset(data->hContact, data->proto->m_szModuleName, setting_name); mir_free(setting_name); return 0; } int is_trusted_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 */ return 1; /* signal_store_backend_user_data* data = (signal_store_backend_user_data*)user_data; char *id_buf = (char*)mir_alloc(address->name_len + sizeof(int32_t)); memcpy(id_buf, address->name, address->name_len); char *id_buf_ptr = id_buf; id_buf_ptr += address->name_len; memcpy(id_buf_ptr, &address->device_id, sizeof(int32_t)); char *id_str = mir_base64_encode(id_buf, address->name_len + sizeof(int32_t)); mir_free(id_buf); char *setting_name = (char*)mir_alloc(strlen(id_str) + 65); mir_snprintf(setting_name, strlen(id_str) + 64, "%s%s", "OmemoSignalIdentity_", id_str); mir_free(id_str); DBVARIANT dbv = { 0 }; dbv.type = DBVT_BLOB; db_get(data->hContact, data->proto->m_szModuleName, setting_name, &dbv); mir_free(setting_name); if (key_len > 0 && !dbv.cpbVal) { db_free(&dbv); return 1; } if (dbv.cpbVal != key_len) { db_free(&dbv); return 0; } if (memcmp(key_data, dbv.pbVal, key_len)) { db_free(&dbv); return 0; } db_free(&dbv); return 1; */ } //void(*destroy_func)(void *user_data); //use first one as we have nothing special to destroy bool omemo_impl::create_session_store(MCONTACT hContact, const wchar_t *device_id) { signal_store_backend_user_data *data[4]; char *device_id_a = mir_u2a(device_id); DWORD device_id_int = strtoul(device_id_a, nullptr, 10); mir_free(device_id_a); for (int i = 0; i < 4; i++) { data[i] = (signal_store_backend_user_data*)mir_alloc(sizeof(signal_store_backend_user_data)); data[i]->hContact = hContact; data[i]->proto = proto; data[i]->device_id = device_id_int; } /* Create the data store context, and add all the callbacks to it */ //TODO: validation of functions return codes signal_protocol_store_context *store_context; signal_protocol_store_context_create(&store_context, global_context); signal_protocol_session_store ss; ss.contains_session_func = &contains_session_func; ss.delete_all_sessions_func = &delete_all_sessions_func; ss.delete_session_func = &delete_session_func; ss.destroy_func = &destroy_func; ss.get_sub_device_sessions_func = &get_sub_device_sessions_func; ss.load_session_func = &load_session_func; ss.store_session_func = &store_session_func; ss.user_data = (void*)data[0]; signal_protocol_store_context_set_session_store(store_context, &ss); signal_protocol_pre_key_store sp; sp.contains_pre_key = &contains_pre_key; sp.destroy_func = &destroy_func; sp.load_pre_key = &load_pre_key; sp.remove_pre_key = &remove_pre_key; sp.store_pre_key = &store_pre_key; sp.user_data = (void*)data[1]; signal_protocol_store_context_set_pre_key_store(store_context, &sp); signal_protocol_signed_pre_key_store ssp; ssp.contains_signed_pre_key = &contains_signed_pre_key; ssp.destroy_func = &destroy_func; ssp.load_signed_pre_key = &load_signed_pre_key; ssp.remove_signed_pre_key = &remove_signed_pre_key; ssp.store_signed_pre_key = &store_signed_pre_key; ssp.user_data = (void*)data[2]; signal_protocol_store_context_set_signed_pre_key_store(store_context, &ssp); signal_protocol_identity_key_store sip; sip.destroy_func = &destroy_func; sip.get_identity_key_pair = &get_identity_key_pair; sip.get_local_registration_id = &get_local_registration_id; sip.is_trusted_identity = &is_trusted_identity; sip.save_identity = &save_identity; sip.user_data = (void*)data[3]; signal_protocol_store_context_set_identity_key_store(store_context, &sip); (*(std::map >*)sessions_internal)[hContact][device_id_int].store_context = store_context; //oh shit .... return true; //success } bool omemo_impl::build_session(MCONTACT hContact, const wchar_t *jid, const wchar_t *dev_id, const wchar_t *key_id, const wchar_t *pre_key_public, const wchar_t *signed_pre_key_id, const wchar_t *signed_pre_key_public, const wchar_t *signed_pre_key_signature, const wchar_t *identity_key) { /* Instantiate a session_builder for a recipient address. */ char *jid_str = mir_u2a(jid); char *dev_id_a = mir_u2a(dev_id); DWORD dev_id_int = strtoul(dev_id_a, nullptr, 10); mir_free(dev_id_a); signal_protocol_address *address = (signal_protocol_address*)mir_alloc(sizeof(signal_protocol_address)); //libsignal does not copy structure, so we must allocate one manually, does it free it on exit ? //rotten compillers support address->name = jid_str; //will libsignal free arrav for us on exit ? address->name_len = mir_strlen(jid_str); address->device_id = dev_id_int; session_builder *builder; if (session_builder_create(&builder, (*(std::map >*)sessions_internal)[hContact][dev_id_int].store_context, address, global_context) < 0) { proto->debugLogA("Jabber OMEMO: error: session_builder_create failed"); return false; //failure } (*(std::map >*)sessions_internal)[hContact][dev_id_int].builder = builder; unsigned int key_id_int = _wtoi(key_id); char *pre_key_a = mir_u2a(pre_key_public); size_t key_buf_len; uint8_t *key_buf = (uint8_t*)mir_base64_decode(pre_key_a, &key_buf_len); ec_public_key *prekey; if (curve_decode_point(&prekey, key_buf, key_buf_len, global_context)) { proto->debugLogA("Jabber OMEMO: error: curve_decode_point failed to parse prekey"); return false; //TODO: cleanup } mir_free(pre_key_a); mir_free(key_buf); unsigned int signed_pre_key_id_int = _wtoi(signed_pre_key_id); pre_key_a = mir_u2a(signed_pre_key_public); key_buf = (uint8_t*)mir_base64_decode(pre_key_a, &key_buf_len); ec_public_key *signed_prekey; if(curve_decode_point(&signed_prekey, key_buf, key_buf_len, global_context)) { proto->debugLogA("Jabber OMEMO: error: curve_decode_point failed to parse signed prekey"); return false; //TODO: cleanup } mir_free(pre_key_a); mir_free(key_buf); //TODO: check this //load identity key ec_public_key *identity_key_p; pre_key_a = mir_u2a(identity_key); key_buf = (uint8_t*)mir_base64_decode(pre_key_a, &key_buf_len); if(curve_decode_point(&identity_key_p, key_buf, key_buf_len, global_context)) { proto->debugLogA("Jabber OMEMO: error: curve_decode_point failed to parse identity key"); return false; //TODO: cleanup } mir_free(pre_key_a); mir_free(key_buf); //TODO: check this bool fp_trusted = false; { //check fingerprint signal_buffer *key_buf2; ec_public_key_serialize(&key_buf2, identity_key_p); char *fingerprint = (char*)mir_alloc((signal_buffer_len(key_buf2) * 2) + 1); bin2hex(signal_buffer_data(key_buf2), signal_buffer_len(key_buf2), fingerprint); const size_t setting_name_len = strlen("OmemoFingerprintTrusted_") + strlen(fingerprint) + 1; char *fp_setting_name = (char*)mir_alloc(setting_name_len); mir_snprintf(fp_setting_name, setting_name_len, "%s%s", "OmemoFingerprintTrusted_", fingerprint); char val = proto->getByte(hContact, fp_setting_name, -1); if (val == 1) fp_trusted = true; if (val == -1) { const size_t msg_len = strlen(Translate("Do you want to create OMEMO session with new device:")) + strlen("\n\n\t") + strlen(fingerprint) + 1; char *msg = (char*)mir_alloc(msg_len); mir_snprintf(msg, msg_len, "%s%s%s", Translate("Do you want to create OMEMO session with new device:"), "\n\n\t", fingerprint); int ret = MessageBoxA(nullptr, msg, Translate("OMEMO: New session"), MB_YESNO); if (ret == IDYES) { proto->setByte(hContact, fp_setting_name, 1); fp_trusted = true; } else if(ret == IDNO) proto->setByte(hContact, fp_setting_name, 0); mir_free(msg); } mir_free(fp_setting_name); } if (!fp_trusted) { proto->debugLogA("Jabber OMEMO: untrusted key, session build failure"); return false; //TODO: cleanup here } pre_key_a = mir_u2a(signed_pre_key_signature); key_buf = (uint8_t*)mir_base64_decode(pre_key_a, &key_buf_len); mir_free(pre_key_a); session_pre_key_bundle *retrieved_pre_key; uint32_t *registration_id = (uint32_t*)mir_alloc(sizeof(uint32_t)); //let's create some momory leak... *registration_id = 0; signal_protocol_identity_get_local_registration_id((*(std::map >*)sessions_internal)[hContact][dev_id_int].store_context, registration_id); session_pre_key_bundle_create(&retrieved_pre_key, *registration_id, dev_id_int, key_id_int, prekey, signed_pre_key_id_int, signed_prekey, key_buf, key_buf_len, identity_key_p); mir_free(key_buf); /* Build a session with a pre key retrieved from the server. */ int ret = session_builder_process_pre_key_bundle(builder, retrieved_pre_key); switch (ret) { case SG_SUCCESS: break; case SG_ERR_UNTRUSTED_IDENTITY: //TODO: do necessary actions for untrusted identity break; case SG_ERR_INVALID_KEY: proto->debugLogA("Jabber OMEMO: session_builder_process_pre_key_bundle failure SG_ERR_INVALID_KEY"); return false; //failure break; default: proto->debugLogA("Jabber OMEMO: session_builder_process_pre_key_bundle failed with unknown error"); return false; //failure break; } /* Create the session cipher and encrypt the message */ session_cipher *cipher; if (session_cipher_create(&cipher, (*(std::map >*)sessions_internal)[hContact][dev_id_int].store_context, address, global_context) < 0) { proto->debugLogA("Jabber OMEMO: session_cipher_create failure"); return false; //failure } (*(std::map >*)sessions_internal)[hContact][dev_id_int].cipher = cipher; return true; //success } void OmemoRefreshUsedPreKey(CJabberProto *proto, pre_key_signal_message *psm) { uint32_t id = pre_key_signal_message_get_pre_key_id(psm); //generate and save pre keys set ec_public_key *public_key = nullptr; signal_buffer *key_buf = nullptr; char *key = nullptr; signal_protocol_key_helper_pre_key_list_node *keys_root, *it; signal_protocol_key_helper_generate_pre_keys(&keys_root, id, 1, global_context); it = keys_root; char setting_name[64], setting_name2[64]; for (; it; it = signal_protocol_key_helper_key_list_next(it)) { session_pre_key *pre_key = signal_protocol_key_helper_key_list_element(it); uint32_t pre_key_id = session_pre_key_get_id(pre_key); { signal_buffer *serialized_pre_key; session_pre_key_serialize(&serialized_pre_key, pre_key); mir_snprintf(setting_name2, strlen("OmemoSignalPreKey_") + 31, "%s%u%d", "OmemoSignalPreKey_", proto->m_omemo.GetOwnDeviceId(), pre_key_id); db_set_blob(0, proto->m_szModuleName, setting_name2, signal_buffer_data(serialized_pre_key), (unsigned int)signal_buffer_len(serialized_pre_key)); SIGNAL_UNREF(serialized_pre_key); } ec_key_pair *pre_key_pair = session_pre_key_get_key_pair(pre_key); public_key = ec_key_pair_get_public(pre_key_pair); ec_public_key_serialize(&key_buf, public_key); SIGNAL_UNREF(public_key); key = mir_base64_encode(signal_buffer_data(key_buf), signal_buffer_len(key_buf)); mir_snprintf(setting_name, "OmemoPreKey%uPublic", pre_key_id); proto->setString(setting_name, key); mir_free(key); signal_buffer_free(key_buf); } signal_protocol_key_helper_key_list_free(keys_root); // proto->OmemoAnnounceDevice(); proto->OmemoSendBundle(); } }; void CJabberProto::OmemoInitDevice() { if (m_omemo.IsFirstRun()) m_omemo.RefreshDevice(); } void CJabberProto::OmemoPutMessageToOutgoingQueue(MCONTACT hContact, int unused_unknown, const char* pszSrc) { char *msg = mir_strdup(pszSrc); ((omemo::message_queue*)m_omemo.message_queue_internal)->outgoing_messages.push_back(omemo::outgoing_message(hContact, unused_unknown, msg)); } void CJabberProto::OmemoPutMessageToIncommingQueue(HXML node, const wchar_t *jid, time_t msgTime) { wchar_t *jid_ = mir_wstrdup(jid); HXML node_ = xmlCopyNode(node); ((omemo::message_queue*)m_omemo.message_queue_internal)->incomming_messages.push_back(omemo::incomming_message(node_, jid_, msgTime)); } void CJabberProto::OmemoHandleMessageQueue() { for (auto i : ((omemo::message_queue*)m_omemo.message_queue_internal)->outgoing_messages) { SendMsg(i.hContact, i.unused_unknown, i.pszSrc); mir_free(i.pszSrc); } ((omemo::message_queue*)m_omemo.message_queue_internal)->outgoing_messages.clear(); std::list tmp = ((omemo::message_queue*)m_omemo.message_queue_internal)->incomming_messages; ((omemo::message_queue*)m_omemo.message_queue_internal)->incomming_messages.clear(); for (auto i : tmp) { if (!OmemoHandleMessage(i.node, i.jid, i.msgTime)) OmemoPutMessageToIncommingQueue(i.node, i.jid, i.msgTime); xmlFree(i.node); mir_free(i.jid); } } DWORD JabberGetLastContactMessageTime(MCONTACT hContact); bool CJabberProto::OmemoHandleMessage(HXML node, wchar_t *jid, time_t msgTime) { MCONTACT hContact = HContactFromJID(jid); if (!OmemoCheckSession(hContact)) { debugLogA("Jabber OMEMO: sessions not yet created, session creation launched"); return false; } HXML header_node = XmlGetChild(node, L"header"); if (!header_node) { debugLogA("Jabber OMEMO: error: omemo message does not contain header"); return true; //this should never happen } HXML payload_node = XmlGetChild(node, L"payload"); if (!payload_node) { debugLogA("Jabber OMEMO: omemo message does not contain payload, it's may be \"KeyTransportElement\" which is currently unused by our implementation"); return true; //this is "KeyTransportElement" which is currently unused } const wchar_t *payload_base64w = XmlGetText(payload_node); if (!payload_base64w) { debugLogA("Jabber OMEMO: error: failed to get payload data"); return true; //this should never happen } const wchar_t *iv_base64 = XmlGetText(XmlGetChild(header_node, L"iv")); if (!iv_base64) { Netlib_Log(nullptr, "Jabber OMEMO: error: failed to get iv data"); return true; } const wchar_t *sender_dev_id = XmlGetAttrValue(header_node, L"sid"); if (!sender_dev_id) { debugLogA("Jabber OMEMO: error: failed to get sender device id"); return true; } char *sender_device_id_a = mir_u2a(sender_dev_id); DWORD sender_dev_id_int = strtoul(sender_device_id_a, nullptr, 10); mir_free(sender_device_id_a); if (!(*(std::map >*)m_omemo.sessions_internal)[hContact][sender_dev_id_int].cipher || !(*(std::map >*)m_omemo.sessions_internal)[hContact][sender_dev_id_int].builder || !(*(std::map >*)m_omemo.sessions_internal)[hContact][sender_dev_id_int].store_context) { OmemoCheckSession(hContact); //this should not normally happened debugLogA("Jabber OMEMO: bug: omemo session does not exist or broken"); return false; } HXML key_node; DWORD own_id = m_omemo.GetOwnDeviceId(); const wchar_t *encrypted_key_base64 = nullptr; for (int p = 1; (key_node = XmlGetNthChild(header_node, L"key", p)) != nullptr; p++) { const wchar_t *dev_id = xmlGetAttrValue(key_node, L"rid"); char *dev_id_a = mir_u2a(dev_id); DWORD dev_id_int = strtoul(dev_id_a, nullptr, 10); mir_free(dev_id_a); if (dev_id_int == own_id) { encrypted_key_base64 = XmlGetText(key_node); break; } } if (!encrypted_key_base64) { debugLogA("Jabber OMEMO: message does not have decryption key for our device"); return true; //node does not contain key for our device } size_t encrypted_key_len; unsigned char *encrypted_key; { char *key_buf = mir_u2a(encrypted_key_base64); encrypted_key = (unsigned char*)mir_base64_decode(key_buf, &encrypted_key_len); mir_free(key_buf); } size_t iv_len; unsigned char *iv; { char *iv_buf = mir_u2a(iv_base64); iv = (unsigned char *)mir_base64_decode(iv_buf, &iv_len); mir_free(iv_buf); } signal_buffer *decrypted_key = nullptr; bool decrypted = false; { //try to decrypt as pre_key_signal_message pre_key_signal_message *pm = nullptr; bool deserialized = false; //TODO: cleanup before return on error { int ret = pre_key_signal_message_deserialize(&pm, encrypted_key, encrypted_key_len, omemo::global_context); switch (ret) { case SG_SUCCESS: deserialized = true; break; case SG_ERR_INVALID_PROTO_BUF: debugLogA("Jabber OMEMO: error: pre_key_signal_message_deserialize failed SG_ERR_INVALID_PROTO_BUF\nTODO: use prekey tag in incomming message key element to avoid this"); // return; break; default: debugLogA("Jabber OMEMO: error: pre_key_signal_message_deserialize failed with unknown error"); // return; break; } } if (deserialized && pm) { int ret = session_cipher_decrypt_pre_key_signal_message((*(std::map >*)m_omemo.sessions_internal)[hContact][sender_dev_id_int].cipher, pm, nullptr, &decrypted_key); switch (ret) { case SG_SUCCESS: decrypted = true; omemo::OmemoRefreshUsedPreKey(this, pm); break; case SG_ERR_INVALID_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_INVALID_MESSAGE\nTODO: use prekey tag in incomming message key element to avoid this"); // return; break; case SG_ERR_DUPLICATE_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_DUPLICATE_MESSAGE"); // return; break; case SG_ERR_LEGACY_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_LEGACY_MESSAGE"); // return; break; case SG_ERR_INVALID_KEY_ID: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_INVALID_KEY_ID"); // return; break; case SG_ERR_INVALID_KEY: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_INVALID_KEY"); // return; break; case SG_ERR_UNTRUSTED_IDENTITY: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed SG_ERR_UNTRUSTED_IDENTITY"); // return; break; default: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_pre_key_signal_message failed with unknown error"); // return; break; } } } if (!decrypted) { //try to decrypt as signal message signal_message *sm = nullptr; bool deserialized = false; int ret = signal_message_deserialize(&sm, encrypted_key, encrypted_key_len, omemo::global_context); switch (ret) { case SG_SUCCESS: deserialized = true; break; default: debugLogA("Jabber OMEMO: error: signal_message_deserialize failed with unknown error"); break; } if (deserialized && sm) { ret = session_cipher_decrypt_signal_message((*(std::map >*)m_omemo.sessions_internal)[hContact][sender_dev_id_int].cipher, sm, nullptr, &decrypted_key); switch (ret) { case SG_SUCCESS: decrypted = true; break; case SG_ERR_INVALID_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_signal_message failed SG_ERR_INVALID_MESSAGE"); break; case SG_ERR_DUPLICATE_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_signal_message failed SG_ERR_DUPLICATE_MESSAGE"); break; case SG_ERR_LEGACY_MESSAGE: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_signal_message failed SG_ERR_LEGACY_MESSAGE"); break; case SG_ERR_NO_SESSION: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_signal_message failed SG_ERR_NO_SESSION"); break; default: debugLogA("Jabber OMEMO: error: session_cipher_decrypt_signal_message failed with unknown error"); break; } } } if(!decrypted) { debugLogA("Jabber OMEMO: error: failed to decrypt incomming message"); return true; //TODO: cleanup } char *out = nullptr; { int dec_success = 0; size_t payload_len = 0; int outl = 0, round_len = 0, tag_len = 0; char *payload_base64 = mir_u2a(payload_base64w); unsigned char *payload = (unsigned char*)mir_base64_decode(payload_base64, &payload_len); out = (char*)mir_alloc(payload_len + 32); //TODO: check this mir_free(payload_base64); unsigned char key[16], *tag; { size_t buf_len = signal_buffer_len(decrypted_key); unsigned char *tmp = (unsigned char*)mir_alloc(buf_len); memcpy(tmp, signal_buffer_data(decrypted_key), buf_len); memcpy(key, tmp, 16); unsigned char *ptr = tmp + 16; tag_len = (int)buf_len - 16; tag = (unsigned char*)mir_alloc(tag_len); memcpy(tag, ptr, tag_len); mir_free(tmp); signal_buffer_free(decrypted_key); } EVP_CIPHER_CTX *ctx = EVP_CIPHER_CTX_new(); EVP_DecryptInit_ex(ctx, EVP_aes_128_gcm(), NULL, NULL, NULL); if (!EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_SET_IVLEN, (int)iv_len, NULL)) { debugLogA("Jabber OMEMO: error: EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_SET_IVLEN, (int)iv_len, NULL) failed"); mir_free(tag); return true; } if (!EVP_DecryptInit_ex(ctx, NULL, NULL, key, iv)) { debugLogA("Jabber OMEMO: error: EVP_DecryptInit_ex(ctx, NULL, NULL, key, iv) failed"); mir_free(tag); return true; } if (!EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_SET_TAG, tag_len, tag)) { debugLogA("Jabber OMEMO: error: EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_SET_TAG, tag_len, tag) failed"); mir_free(tag); return true; } if (!EVP_DecryptUpdate(ctx, (unsigned char*)out, &outl, payload, int(payload_len))) { debugLogA("Jabber OMEMO: error: EVP_DecryptUpdate(ctx, (unsigned char*)out, &outl, payload, int(payload_len)) failed"); mir_free(tag); return true; } /* for (;;) { if (!EVP_DecryptUpdate(ctx, (unsigned char*)out + outl, &round_len, payload + outl, int((payload_len >= 128) ? 128 : payload_len))) { debugLogA("Jabber OMEMO: error: EVP_DecryptUpdate(ctx, (unsigned char*)out + outl, &round_len, payload + outl, int((payload_len >= 128) ? 128 : payload_len)) failed"); mir_free(tag); return true; } outl += round_len; if (outl >= (int)payload_len - 128) break; } EVP_DecryptUpdate(ctx, (unsigned char*)out + outl, &round_len, payload + outl, int(payload_len - outl)); outl += round_len; */ dec_success = EVP_DecryptFinal_ex(ctx, (unsigned char*)out + outl, &round_len); outl += round_len; out[outl] = 0; mir_free(payload); EVP_CIPHER_CTX_free(ctx); mir_free(tag); if (dec_success <= 0) { debugLogA("Jabber OMEMO: error: aes_128_gcm verification failed"); return true; } } time_t now = time(0); if (!msgTime) msgTime = now; if (m_bFixIncorrectTimestamps && (msgTime > now || (msgTime < (time_t)JabberGetLastContactMessageTime(hContact)))) msgTime = now; PROTORECVEVENT recv = {}; recv.timestamp = (DWORD)msgTime; recv.szMessage = mir_strdup(out); ProtoChainRecvMsg(hContact, &recv); mir_free(out); return true; } void CJabberProto::OmemoHandleDeviceList(HXML node) { if (!node) return; HXML message = xmlGetParent(node); message = xmlGetParent(message); const wchar_t *jid = XmlGetAttrValue(message, L"from"); MCONTACT hContact = HContactFromJID(jid); node = XmlGetChild(node, "item"); //get node if (!node) { debugLogA("Jabber OMEMO: error: omemo devicelist does not have node"); return; } node = XmlGetChildByTag(node, L"list", L"xmlns", JABBER_FEAT_OMEMO); // if (!node) { debugLogA("Jabber OMEMO: error: omemo devicelist does not have node"); return; } bool own_jid = false; if (wcsstr(m_ThreadInfo->fullJID, jid)) own_jid = true; uint32_t current_id; const wchar_t *current_id_str; if (own_jid) { //check if our device exist bool own_device_listed = false; uint32_t own_id = m_omemo.GetOwnDeviceId(); char setting_name[64]; HXML list_item; int i = 0; for (int p = 1; (list_item = XmlGetNthChild(node, L"device", p)) != nullptr; p++, i++) { current_id_str = xmlGetAttrValue(list_item, L"id"); char *current_id_str_a = mir_u2a(current_id_str); current_id = strtoul(current_id_str_a, nullptr, 10); mir_free(current_id_str_a); if (current_id == own_id) own_device_listed = true; mir_snprintf(setting_name, "OmemoDeviceId%d", i); setDword(setting_name, current_id); } DWORD val = 0; mir_snprintf(setting_name, "OmemoDeviceId%d", i); val = getDword(setting_name, 0); while (val) { delSetting(setting_name); i++; mir_snprintf(setting_name, "OmemoDeviceId%d", i); val = getDword(setting_name, 0); } if (!own_device_listed) OmemoAnnounceDevice(); } else { //store device id's char setting_name[64]; HXML list_item; int i = 0; for (int p = 1; (list_item = XmlGetNthChild(node, L"device", p)) != nullptr; p++, i++) { current_id_str = xmlGetAttrValue(list_item, L"id"); char *current_id_str_a = mir_u2a(current_id_str); current_id = strtoul(current_id_str_a, nullptr, 10); mir_free(current_id_str_a); mir_snprintf(setting_name, "OmemoDeviceId%d", i); setDword(hContact, setting_name, current_id); } DWORD val = 0; mir_snprintf(setting_name, "OmemoDeviceId%d", i); val = getDword(hContact, setting_name, 0); while (val) { delSetting(hContact, setting_name); i++; mir_snprintf(setting_name, "OmemoDeviceId%d", i); val = getDword(hContact, setting_name, 0); } } } void CJabberProto::OmemoAnnounceDevice() { // check "OmemoDeviceId%d" for own id and send updated list if not exist unsigned int own_id = m_omemo.GetOwnDeviceId(); char setting_name[64]; for (int i = 0;; ++i) { mir_snprintf(setting_name, "OmemoDeviceId%d", i); DWORD val = getDword(setting_name); if (val == 0) break; if (val == own_id) return; // nothing to do, list is fresh enough } // add own device id // construct node wchar_t szBareJid[JABBER_MAX_JID_LEN]; XmlNodeIq iq(L"set", SerialNext()); iq << XATTR(L"from", JabberStripJid(m_ThreadInfo->fullJID, szBareJid, _countof_portable(szBareJid))); HXML publish_node = iq << XCHILDNS(L"pubsub", L"http://jabber.org/protocol/pubsub") << XCHILD(L"publish") << XATTR(L"node", JABBER_FEAT_OMEMO L".devicelist"); HXML list_node = publish_node << XCHILDNS(L"item") << XCHILDNS(L"list", JABBER_FEAT_OMEMO); for (int i = 0; ; ++i) { mir_snprintf(setting_name, "OmemoDeviceId%d", i); DWORD val = getDword(setting_name); if (val == 0) break; list_node << XCHILD(L"device") << XATTRI64(L"id", val); } list_node << XCHILD(L"device") << XATTRI64(L"id", own_id); // send device list back //TODOL handle response m_ThreadInfo->send(iq); } struct db_enum_settings_prekeys_cb_data { std::list settings; //TODO: check this }; int db_enum_settings_prekeys_cb(const char *szSetting, void *lParam) { db_enum_settings_prekeys_cb_data* data = (db_enum_settings_prekeys_cb_data*)lParam; if (strstr(szSetting, "OmemoPreKey") && strstr(szSetting, "Public")) //TODO: suboptimal code, use different names for simple searching data->settings.push_back(mir_strdup(szSetting)); return 0;//? } void CJabberProto::OmemoSendBundle() { // get own device id DWORD own_id = m_omemo.GetOwnDeviceId(); // construct bundle node wchar_t szBareJid[JABBER_MAX_JID_LEN]; XmlNodeIq iq(L"set", SerialNext()); iq << XATTR(L"from", JabberStripJid(m_ThreadInfo->fullJID, szBareJid, _countof_portable(szBareJid))); HXML publish_node = iq << XCHILDNS(L"pubsub", L"http://jabber.org/protocol/pubsub") << XCHILD(L"publish"); { wchar_t attr_val[128]; mir_snwprintf(attr_val, L"%s.bundles:%u", JABBER_FEAT_OMEMO, own_id); publish_node << XATTR(L"node", attr_val); } HXML bundle_node = publish_node << XCHILD(L"item") << XCHILDNS(L"bundle", JABBER_FEAT_OMEMO); // add signed pre key public bundle_node << XCHILD(L"signedPreKeyPublic", ptrW(getWStringA("OmemoSignedPreKeyPublic"))) << XATTR(L"signedPreKeyId", L"1"); //add pre key signature bundle_node << XCHILD(L"signedPreKeySignature", ptrW(getWStringA("OmemoSignedPreKeySignature"))); //add identity key //it is must be a public key right ?, standart is a bit confusing... bundle_node << XCHILD(L"identityKey", ptrW(getWStringA("OmemoDevicePublicKey"))); //add prekeys HXML prekeys_node = XmlAddChild(bundle_node, L"prekeys"); db_enum_settings_prekeys_cb_data *ud = new db_enum_settings_prekeys_cb_data; db_enum_settings(0, &db_enum_settings_prekeys_cb, m_szModuleName, ud); for (std::list::iterator i = ud->settings.begin(), end = ud->settings.end(); i != end; i++) { ptrW val(getWStringA(*i)); if (val) { unsigned int key_id = 0; char *p = *i, buf[5] = {0}; p += strlen("OmemoPreKey"); int i2 = 0; for (char c = 0; c != 'P'; i2++, c = p[i2]) ; memcpy(buf, p, i2); buf[i2 + 1] = 0; key_id = atoi(buf); prekeys_node << XCHILD(L"preKeyPublic", val) << XATTRI(L"preKeyId", key_id); } mir_free(*i); } ud->settings.clear(); delete ud; char setting_name[64]; for (int i = 0;; i++) { mir_snprintf(setting_name, "OmemoPreKey%dPublic", i); ptrW val(getWStringA(setting_name)); if (val == nullptr) break; prekeys_node << XCHILD(L"preKeyPublic", val) << XATTRI(L"preKeyId", i + 1); } // send bundle //TODOL handle response m_ThreadInfo->send(iq); } void CJabberProto::OmemoPublishNodes() { OmemoAnnounceDevice(); OmemoSendBundle(); } bool CJabberProto::OmemoCheckSession(MCONTACT hContact) { if ((*(std::map*)m_omemo.session_checked)[hContact]) return true; bool pending_check = false; char setting_name[64], setting_name2[64]; unsigned int id = 0; bool checked = false; int i = 0; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); db_set_resident(m_szModuleName, setting_name2); id = getDword(hContact, setting_name, 0); checked = getBool(hContact, setting_name2); while (id) { if (!checked) { pending_check = true; wchar_t szBareJid[JABBER_MAX_JID_LEN]; unsigned int *dev_id = (unsigned int*)mir_alloc(sizeof(unsigned int)); *dev_id = id; XmlNodeIq iq(AddIQ(&CJabberProto::OmemoOnIqResultGetBundle, JABBER_IQ_TYPE_GET, nullptr, 0UL, -1, dev_id)); iq << XATTR(L"from", JabberStripJid(m_ThreadInfo->fullJID, szBareJid, _countof_portable(szBareJid))); wchar_t *jid = ContactToJID(hContact); iq << XATTR(L"to", jid); HXML items = iq << XCHILDNS(L"pubsub", L"http://jabber.org/protocol/pubsub") << XCHILD(L"items"); wchar_t bundle[64]; mir_snwprintf(bundle, 63, L"%s%s%u", JABBER_FEAT_OMEMO, L".bundles:", id); XmlAddAttr(items, L"node", bundle); m_ThreadInfo->send(iq); mir_free(jid); break; } i++; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); id = getDword(hContact, setting_name, 0); checked = getBool(hContact, setting_name2); } if (!pending_check) { (*(std::map*)m_omemo.session_checked)[hContact] = true; OmemoHandleMessageQueue(); return true; } else debugLogA("Jabber OMEMO: info: OmemoCheckSession: pending session creation"); return false; } void CJabberProto::OmemoOnIqResultGetBundle(HXML iqNode, CJabberIqInfo *pInfo) { if (iqNode == nullptr) return; const wchar_t *jid = XmlGetAttrValue(iqNode, L"from"); MCONTACT hContact = HContactFromJID(jid); const wchar_t *type = XmlGetAttrValue(iqNode, L"type"); if (mir_wstrcmp(type, L"result")) { //failed to get bundle, do not try to build session unsigned int *dev_id = (unsigned int*)pInfo->GetUserData(); char setting_name[64], setting_name2[64]; DWORD id = 0; int i = 0; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); db_set_resident(m_szModuleName, setting_name2); id = getDword(hContact, setting_name, 0); while (id) { if (id == *dev_id) { setByte(hContact, setting_name2, 1); break; } i++; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); db_set_resident(m_szModuleName, setting_name2); id = getDword(hContact, setting_name, 0); } debugLogA("Jabber OMEMO: error: failed to get bundle for device, this may be due to absent data on server or due to our bug (incorrect device id in request)"); return; } HXML pubsub = XmlGetChildByTag(iqNode, L"pubsub", L"xmlns", L"http://jabber.org/protocol/pubsub"); if (!pubsub) { debugLogA("Jabber OMEMO: error: device bundle does not contain pubsub node"); return; } HXML items = XmlGetChild(pubsub, L"items"); const wchar_t *items_node_val = XmlGetAttrValue(items, L"node"); const wchar_t *device_id = items_node_val; device_id += mir_wstrlen(JABBER_FEAT_OMEMO L".bundles:"); HXML bundle = XmlGetChild(XmlGetChild(items, L"item"), L"bundle"); if (!bundle) { debugLogA("Jabber OMEMO: error: device bundle does not contain bundle node"); return; } const wchar_t *signedPreKeyPublic = XmlGetText(XmlGetChild(bundle, L"signedPreKeyPublic")); if (!signedPreKeyPublic) { debugLogA("Jabber OMEMO: error: device bundle does not contain signedPreKeyPublic node"); return; } const wchar_t *signedPreKeyId = XmlGetAttrValue(XmlGetChild(bundle, L"signedPreKeyPublic"), L"signedPreKeyId"); if (!signedPreKeyId) { debugLogA("Jabber OMEMO: error: device bundle does not contain signedPreKeyId attr"); return; } const wchar_t *signedPreKeySignature = XmlGetText(XmlGetChild(bundle, L"signedPreKeySignature")); if (!signedPreKeySignature) { debugLogA("Jabber OMEMO: error: device bundle does not contain signedPreKeySignature node"); return; } const wchar_t *identityKey = XmlGetText(XmlGetChild(bundle, L"identityKey")); if (!identityKey) { debugLogA("Jabber OMEMO: error: device bundle does not contain identityKey node"); return; } HXML prekeys = XmlGetChild(bundle, L"prekeys"); if (!prekeys) { debugLogA("Jabber OMEMO: error: device bundle does not contain prekeys node"); return; } unsigned char key_num = 0; while(key_num == 0) Utils_GetRandom(&key_num, 1); key_num = (key_num % (XmlGetChildCount(prekeys))) + 1; wchar_t key_num_str[4]; mir_snwprintf(key_num_str, 3, L"%d", key_num); HXML prekey_node; for (int p = 1; (prekey_node = XmlGetNthChild(prekeys, L"preKeyPublic", p)) != nullptr && p <= key_num; p++) ; if (!prekey_node) { debugLogA("Jabber OMEMO: error: device bundle does not contain preKeyPublic node"); return; } const wchar_t *preKeyPublic = XmlGetText(prekey_node); if (!preKeyPublic) { debugLogA("Jabber OMEMO: error: failed to get preKeyPublic data"); return; } const wchar_t *preKeyId = XmlGetAttrValue(prekey_node, L"preKeyId"); if (!preKeyId) { debugLogA("Jabber OMEMO: error: failed to get preKeyId data"); return; } if (!m_omemo.create_session_store(hContact, device_id)) { debugLogA("Jabber OMEMO: error: omemo::create_session_store failed"); return; //failed to create session store } if (!m_omemo.build_session(hContact, jid, device_id, preKeyId, preKeyPublic, signedPreKeyId, signedPreKeyPublic, signedPreKeySignature, identityKey)) { debugLogA("Jabber OMEMO: error: omemo::build_session failed"); return; //failed to build signal(omemo) session } { unsigned int *dev_id = (unsigned int*)pInfo->GetUserData(); char setting_name[64], setting_name2[64]; DWORD id = 0; int i = 0; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); db_set_resident(m_szModuleName, setting_name2); id = getDword(hContact, setting_name, 0); while (id) { if (id == *dev_id) { setByte(hContact, setting_name2, 1); break; } i++; mir_snprintf(setting_name, "OmemoDeviceId%d", i); mir_snprintf(setting_name2, "%sChecked", setting_name); db_set_resident(m_szModuleName, setting_name2); id = getDword(hContact, setting_name, 0); } } OmemoCheckSession(hContact); } unsigned int CJabberProto::OmemoEncryptMessage(XmlNode &msg, const wchar_t *msg_text, MCONTACT hContact) { const EVP_CIPHER *cipher = EVP_aes_128_gcm(); unsigned char key[16], iv[12], tag[16] /*, aad[48]*/; Utils_GetRandom(key, _countof_portable(key)); Utils_GetRandom(iv, _countof_portable(iv)); Utils_GetRandom(tag, _countof_portable(tag)); //Utils_GetRandom(aad, _countof_portable(aad)); EVP_CIPHER_CTX *ctx = EVP_CIPHER_CTX_new(); EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_SET_IVLEN, _countof_portable(iv), nullptr); EVP_EncryptInit(ctx, cipher, key, iv); char *in = mir_utf8encodeW(msg_text), *out; const size_t inl = strlen(in); int tmp_len = 0, outl; //EVP_EncryptUpdate(ctx, nullptr, &outl, aad, _countof_portable(aad)); out = (char*)mir_alloc(inl + _countof_portable(key) - 1); for (;;) { EVP_EncryptUpdate(ctx, (unsigned char*)(out + tmp_len), &outl, (unsigned char*)(in + tmp_len), (int)(inl - tmp_len)); tmp_len += outl; if (tmp_len >= (int)inl - 16 + 1) //cast to int is required here break; } EVP_EncryptFinal(ctx, (unsigned char*)(in + tmp_len), &outl); tmp_len += outl; EVP_CIPHER_CTX_ctrl(ctx, EVP_CTRL_GCM_GET_TAG, _countof_portable(tag), tag); EVP_CIPHER_CTX_free(ctx); mir_free(in); HXML encrypted = msg << XCHILDNS(L"encrypted", JABBER_FEAT_OMEMO); HXML payload = encrypted << XCHILD(L"payload"); char *payload_base64 = mir_base64_encode(out, tmp_len); wchar_t *payload_base64w = mir_a2u(payload_base64); mir_free(payload_base64); xmlSetText(payload, payload_base64w); mir_free(payload_base64w); HXML header = encrypted << XCHILD(L"header"); header << XATTRI64(L"sid", m_omemo.GetOwnDeviceId()); unsigned int session_count = 0; char key_plus_tag[32] = {0}; memcpy(key_plus_tag, key, 16); { char *ptr = key_plus_tag + 16; memcpy(ptr, tag, 16); } for (std::map::iterator i = (*(std::map >*)m_omemo.sessions_internal)[hContact].begin(), end = (*(std::map >*)m_omemo.sessions_internal)[hContact].end(); i != end; i++) { if (!i->second.cipher) { debugLogA("Jabber OMEMO: bug: omemo session does not have valid cipher"); continue; } unsigned int intdev_id = i->first; ciphertext_message *encrypted_key; if (session_cipher_encrypt(i->second.cipher, (uint8_t*)key_plus_tag, 32, &encrypted_key) != SG_SUCCESS) { //TODO: handle encryption error debugLogA("Jabber OMEMO: bug: session_cipher_encrypt failed"); continue; } else { HXML key_node = header << XCHILD(L"key"); key_node << XATTRI64(L"rid", intdev_id); int msg_type = ciphertext_message_get_type(encrypted_key); if(msg_type == CIPHERTEXT_PREKEY_TYPE) { key_node << XATTR(L"prekey", L"true"); } signal_buffer *serialized_encrypted_key = ciphertext_message_get_serialized(encrypted_key); char *key_base64 = mir_base64_encode(signal_buffer_data(serialized_encrypted_key), signal_buffer_len(serialized_encrypted_key)); wchar_t *key_base64w = mir_a2u(key_base64); mir_free(key_base64); xmlSetText(key_node, key_base64w); mir_free(key_base64w); SIGNAL_UNREF(encrypted_key); session_count++; } } HXML iv_node = header << XCHILD(L"iv"); char *iv_base64 = mir_base64_encode(iv, _countof_portable(iv)); wchar_t *iv_base64w = mir_a2u(iv_base64); mir_free(iv_base64); xmlSetText(iv_node, iv_base64w); mir_free(iv_base64w); msg << XCHILDNS(L"store", L"urn:xmpp:hints"); if (!session_count) { debugLogA("Jabber OMEMO: error: message does not encrypted for any sessions"); } return session_count; } bool CJabberProto::OmemoIsEnabled(MCONTACT /*hContact*/) { //TODO: return true; }