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Overview

This is a fork of libsignal-protocol-c, an implementation of Signal's ratcheting forward secrecy protocol that works in synchronous and asynchronous messaging. The fork adds support for OMEMO as defined in XEP-0384 versions 0.3.0 and later.

  • OMEMO version 0.3.0 uses the original libsignal-protocol-c implementation with its protocol versions 2 and 3.
  • OMEMO version 0.4.0+ is implemented using a new protocol version 4 internally. In comparison with protocol version 3, it changes:
    • HKDF info strings
    • Protocol buffer encoding
    • Signature scheme (uses XEd25519 instead of custom "Curve25519 signatures")
    • Specification-compliant double ratchet
    • Support for Ed25519 public keys
    • Various serializations
    • Removes unused functionality

Building libomemo-c

Development host setup

Build dependencies

Most of these dependencies are required just for the unit test suite and development of the library itself. When integrating into actual applications, you should not need anything beyond CMake. Alternatively, you may integrate the code using a build system of your choice. Items marked with *1 are required for tests, with *2 are additionally required for code coverage.

Setting up a fresh source tree

$ cd /path/to/libomemo-c
$ mkdir build
$ cd build
$ cmake -DCMAKE_BUILD_TYPE=Debug ..
$ make

Running the unit tests

$ cd /path/to/libomemo-c/build
$ cmake -DCMAKE_BUILD_TYPE=Debug -DBUILD_TESTING=1 ..
$ cd tests
$ make
$ cd ..
$ ctest

Creating the code coverage report

$ cd /path/to/libomemo-c/build
$ cmake -DCMAKE_BUILD_TYPE=Debug -DBUILD_TESTING=1 -DCOVERAGE=1 ..
$ make coverage

The generated code coverage report can be found in: /path/to/libomemo-c/build/coverage

Eclipse project setup

CMake provides a tutorial on Eclipse project setup here: https://cmake.org/Wiki/CMake:Eclipse_UNIX_Tutorial

It is recommended to follow the more manual "Option 2," since the Eclipse project generator built into CMake tends to be outdated and leads you toward a very awkward and occasionally broken project configuration.

Protocol Buffers compiler

This project uses serialization code based on Protocol Buffers. Since the official library does not support C, the protobuf-c generator is used instead. For the sake of convenience, the generated code and its dependencies are included in the source tree. The generated code can be regenerated at any time by installing the two mentioned packages and running "make" in the "protobuf/" subdirectory.

Target platforms

CMake toolchain files have been included from the following sources:

Using libomemo-c

Library initialization

Before using the library, a libomemo-c client needs to initialize a global context. This global context is used to provide callbacks for implementations of functions used across the library that need client-specific implementations. Refer to "signal_protocol.h" for detailed documentation on these functions, and the unit tests for example implementations.

signal_context *global_context;
signal_context_create(&global_context, user_data);
signal_context_set_crypto_provider(global_context, &provider);
signal_context_set_locking_functions(global_context, lock_function, unlock_function);

Client install time

At install time, a libomemo-c client needs to generate its identity keys, registration id, and prekeys.

ratchet_identity_key_pair *identity_key_pair;
uint32_t registration_id;
signal_protocol_key_helper_pre_key_list_node *pre_keys_head;
session_signed_pre_key *signed_pre_key;

signal_protocol_key_helper_generate_identity_key_pair(&identity_key_pair, global_context);
signal_protocol_key_helper_generate_registration_id(&registration_id, 0, global_context);
signal_protocol_key_helper_generate_pre_keys(&pre_keys_head, start_id, 100, global_context);
signal_protocol_key_helper_generate_signed_pre_key(&signed_pre_key, identity_key_pair, 5, timestamp, global_context);

/* Store identity_key_pair somewhere durable and safe. */
/* Store registration_id somewhere durable and safe. */

/* Store pre keys in the pre key store. */
/* Store signed pre key in the signed pre key store. */

The above example is simplified for the sake of clarity. All of these functions return errors on failure, and those errors should be checked for in real usage.

There are also iteration and serialization methods for the above types that should be used as appropriate.

Building a session

A libomemo-c client needs to implement four data store callback interfaces: signal_protocol_identity_key_store, signal_protocol_pre_key_store, signal_protocol_signed_pre_key_store, and signal_protocol_session_store. These will manage loading and storing of identity, prekeys, signed prekeys, and session state.

These callback interfaces are designed such that implementations should treat all data flowing through them as opaque binary blobs. Anything necessary for referencing that data will be provided as separate function arguments to those callbacks. If it is ever necessary for clients to directly access stored data in terms of library data structures, they should use the accessor functions declared in "signal_protocol.h" for these data stores.

Once the callbacks for these data stores are implemented, building a session is fairly straightforward:

/* Create the data store context, and add all the callbacks to it */
signal_protocol_store_context *store_context;
signal_protocol_store_context_create(&store_context, global_context);
signal_protocol_store_context_set_session_store(store_context, &session_store);
signal_protocol_store_context_set_pre_key_store(store_context, &pre_key_store);
signal_protocol_store_context_set_signed_pre_key_store(store_context, &signed_pre_key_store);
signal_protocol_store_context_set_identity_key_store(store_context, &identity_key_store);

/* Instantiate a session_builder for a recipient address. */
signal_protocol_address address = {
    "+14159998888", 12, 1
};
session_builder *builder;
session_builder_create(&builder, store_context, &address, global_context);
session_builder_set_version(builder, 4);

/* Build a session with a pre key retrieved from the server. */
session_builder_process_pre_key_bundle(builder, retrieved_pre_key);

/* Create the session cipher and encrypt the message */
session_cipher *cipher;
session_cipher_create(&cipher, store_context, &address, global_context);
session_cipher_set_version(cipher, 4);

ciphertext_message *encrypted_message;
session_cipher_encrypt(cipher, message, message_len, &encrypted_message);

/* Get the serialized content and deliver it */
signal_buffer *serialized = ciphertext_message_get_serialized(encrypted_message);

deliver(signal_buffer_data(serialized), signal_buffer_len(serialized));

/* Cleanup */
SIGNAL_UNREF(encrypted_message);
session_cipher_free(cipher);
session_builder_free(builder);
signal_protocol_store_context_destroy(store_context);

The above example is simplified for the sake of clarity. All of these functions return errors on failure, and those errors should be checked for in real usage. Note that the calls to session_builder_set_version and session_cipher_set_version are only required when a the session should be set up for OMEMO version 0.4.0 or later.

Memory management notes

For every custom data type that the libomemo-c library can allocate and return, a corresponding way of deallocating an instance of that data type is provided.

The more basic and higher level data types provide a type-specific free or destroy function. These types include signal_context, signal_protocol_store_context, signal_buffer, signal_buffer_list, signal_int_list, signal_protocol_key_helper_pre_key_list_node, session_builder, session_cipher, group_session_builder, group_cipher, and fingerprint_generator.

Most of the other data types, including everything internal, use a reference counting mechanism. If you are going to hold onto a reference to one of these types, use the SIGNAL_REF(x) macro to increment its count. If you are done with a reference, use SIGNAL_UNREF(x) to decrement its count. When the count reaches 0, the type's destructor function is called.

Legal things

Cryptography Notice

This distribution includes cryptographic software. The country in which you currently reside may have restrictions on the import, possession, use, and/or re-export to another country, of encryption software. BEFORE using any encryption software, please check your country's laws, regulations and policies concerning the import, possession, or use, and re-export of encryption software, to see if this is permitted. See http://www.wassenaar.org/ for more information.

The U.S. Government Department of Commerce, Bureau of Industry and Security (BIS), has classified this software as Export Commodity Control Number (ECCN) 5D002.C.1, which includes information security software using or performing cryptographic functions with asymmetric algorithms. The form and manner of this distribution makes it eligible for export under the License Exception ENC Technology Software Unrestricted (TSU) exception (see the BIS Export Administration Regulations, Section 740.13) for both object code and source code.

License

Copyright 2015-2016 Open Whisper Systems
Copyright 2020-2022 Dino Team

Licensed under the GPLv3: http://www.gnu.org/licenses/gpl-3.0.html

Additional Permissions For Submission to Apple App Store: Provided that you are otherwise in compliance with the GPLv3 for each covered work you convey (including without limitation making the Corresponding Source available in compliance with Section 6 of the GPLv3), Open Whisper Systems also grants you the additional permission to convey through the Apple App Store non-source executable versions of the Program as incorporated into each applicable covered work as Executable Versions only under the Mozilla Public License version 2.0 (https://www.mozilla.org/en-US/MPL/2.0/).