One or more embodiments of this specification provide message transmission methods and apparatuses. A method includes: registering each of a plurality of blockchain nodes in a blockchain relay communication network to a blockchain node set indicated in a registration request submitted by a corresponding blockchain node of the plurality of blockchain nodes; generating a routing policy corresponding to each of the plurality of blockchain nodes, the routing policy comprising a blockchain node set that the corresponding blockchain node belongs and a relay node that connects to the corresponding blockchain node; receiving a blockchain message for a target blockchain node in a target blockchain node set; determining a target relay node connected to the target blockchain node according to a tree-structured routing table obtained by organizing routing policies in a tree structure; and transmitting the blockchain message to the target blockchain node.

A set of computers can be grouped into a first group and second group of computers to receive a file object. The first group of computers are commanded to perform a peer-to-peer download of the file object from a source. The second group of computers are commanded to perform a peer-to-peer download of the file object from a computer in the first group of computers.

An approach is disclosed for providing free storage to a client on a blockchain platform. A number of free storage markers targeted for the client is generated by a governing entity. After validating the client by the governing entity, the number of free storage markers are transferred to the client where the free storage markers include a timestamp, a number of tokens, a client identification, an expiration, and a governing entity signature. An allocation from the number of free storage markers received from the client is processed by the governing entity for storage access.

Systems, devices, and methods discussed herein are directed to intelligently adjusting the set of worker nodes within a computing cluster. By way of example, a computing device (or service) may monitor performance metrics of a set of worker nodes of a computing cluster. When a performance metric is detected that is below a performance threshold, the computing device may perform a first adjustment (e.g., an increase or decrease) to the number of nodes in the cluster. Training data may be obtained based at least in part on the first adjustment and utilized with supervised learning techniques to train a machine-learning model to predict future performance changes in the cluster. Subsequent performance metrics and/or cluster metadata may be provided to the machine-learning model to obtain output indicating a predicted performance change. An additional adjustment to the number of worker nodes may be performed based at least in part on the output.

The systems and methods of a blockchain platform for distributed applications includes flexibility to implement a variety of client systems with a token usage and distributed computing based on separation of roles for a miner and a blobber. The message flow model between different parties including a client, a blobber and a miner allows for fast transactions on a lightweight blockchain by lightening the load on a mining network, i.e. a network of one or more miners. Offloading the work to a different group of machines allows for greater specialization in the design and specifications of the machines, allowing for the blockchain platform miners to be optimized for fast transaction handling and blockchain platform blobbers to be efficient at handling data for given transaction types.

A method and apparatus form and/or define a network topology in a Layer 3 network with a plurality of nodes, where each node has at least one interface. To that end, the method defines a plurality of neighborhoods, and assigns at least one interface of each node to at least one of the neighborhoods. The method also assigns a communication role to each interface so that each communication role is effective relative to one of the plurality of neighborhoods. The method then enables communication between the interfaces of the plurality of nodes as a function of the neighborhoods and the communication roles.

An approach is disclosed to replace or by-pass a first blobber utilizing a blockchain infrastructure. The first blobber is identified. For replacement, a second blobber is identified and a replacement transaction is written. Write markers with respect to content for the second blobber are generated. The content is transferred to the second blobber. After detecting a successful completion of all the writes to the second blobber, a transaction to drop the first blobber is written. When the first blobber is by-passed content written to the first blobber capable of being reconstructed from other blocks is written to other blobbers. Read markers are sent for the other blocks to the other blobbers. The blockchain monitors for successful completion of all reads of the other blocks. After detecting the successful completion of all the reads of the other blocks from the other blobbers, the content is reconstructed from the other blocks.

An example operation may include one or more of retrieving decentralized identifiers (DIDs) of a plurality of blockchain peers included within a blockchain network, generating a blockchain declarative descriptor (BDD) which uniquely identifies the blockchain network, where the BDD comprises a machine-readable data file with a first field includes the retrieved DIDs of the blockchain network, a second field including signature data of the plurality of blockchain peers, and a third field including metadata, and transmitting the generated BDD to a blockchain network registry.

Aspects discussed herein relate to systems, apparatuses, and methods for providing content distribution via a breadth-first approach for peer-to-peer file sharing in a temporary ad hoc mesh network. For example, a peer-to-peer orchestrator may receive requests for the same asset from multiple mobile devices, determine which of the mobile devices are likely to travel along the same route at the same time, group them together and cause transmission of different asset parts of the requested asset to different mobile devices in the group. If the mobile devices in the group lose connection with the peer-to-peer orchestrator, they may form an ad hock mesh network and retrieve asset parts from one another. If the group reconnects with a peer-to-peer orchestrator, additional asset parts of the asset may be transmitted to the group and the process may repeat so that each mobile device may obtain each of the asset parts.

Methods, media, and systems are disclosed for adding new users to a channel in a group-based communication system. The system receives a request to add new users to a channel. The system adds a new user by classifying the new user's email address domain as internal or external. If the domain is internal, the first user is added to the channel as a member, and if the domain is external, the user is prompted for a type of access for the new user. If the new user's access type is guest, the new user is added to the channel as a guest. If the type of access is shared, the channel is shared with an organization associated with the domain, and the new user is added as a member of the channel that has been shared.