WO2023153868A1

WO2023153868A1 - Non-mining blockchain network system for esg and method for operating server nodes participating in same system

Info

Publication number: WO2023153868A1
Application number: PCT/KR2023/002007
Authority: WO
Inventors: 김경민
Original assignee: 주식회사 스카이플레이
Priority date: 2022-02-10
Filing date: 2023-02-10
Publication date: 2023-08-17
Also published as: KR102439351B1

Abstract

Disclosed in the present invention are a blockchain network system and a method for operating server nodes participating in the system. According to one embodiment, a blockchain network system of the present invention comprises: a first server node participating in a blockchain network; and one or more second server nodes connected to the first server node and performing an agreement procedure defined in the blockchain network, wherein each of the first server node and the second server node may access the blockchain network through authorization that is executed at a system level of an operating system (OS) operating a corresponding server node, allocate a dedicated resource of the same size for the blockchain network, and perform the agreement procedure for the blockchain network by using the dedicated resource.

Description

Non-mining blockchain network system for ESG and operation method of server nodes participating in the system

The present invention relates to a non-mining blockchain network system for ESG and a method of operating a server node participating in the system. More specifically, the present invention relates to a blockchain network system for ESG that can be continuously and stably maintained compared to the prior art and a method of operating a server node participating in the system.

A blockchain system is a system in which numerous nodes are connected through a P2P (Peer-to-Peer) network to process user transactions, a kind of distributed ledger that sequentially stores records of transactions. ) system.

In such a blockchain system, since all nodes participating in the network copy and store the same data in block form, there is no distinction between the original and the copy, and there is a (authoritative) central system that can make unified decisions. I never do that. For this reason, in the blockchain system, a consensus algorithm that enables all nodes to continuously and stably retain the processing record of the same transaction is a very essential core element technology.

As an example of such a consensus algorithm, the Bitcoin system developed by Satoshi Nakamoto applies a Proof of Work (PoW) method consensus algorithm. The consensus algorithm is based on providing compensation through mining to the participating nodes so that the network system participating in the corresponding consensus algorithm transaction can be maintained by the participating nodes.

However, the above-mentioned mining operation requires enormous physical computing resources (eg GPU (Graphics Processing Units) resources, etc.) and power resources for each participating node, and a blockchain system based on this consensus algorithm is There is a problem of causing inefficient energy-consumption due to the increase, and there is a problem of going against the trend of pursuing a low-carbon industry required by the recent internationalization trend.

[Prior art literature]

[Patent Literature]

(Patent Document 0001) US Patent Publication No. 2017/0075941 (2017. 03. 16)

The purpose of the present invention is to solve the above-mentioned conventional problems, minimizing unnecessary energy consumption and considering the situation/conditions supporting node devices (devices, apparatuses), a blockchain network that can be maintained continuously and stably compared to the prior art It is to provide a method of operating a system and server nodes participating in the system.

According to an embodiment for solving the object of the present invention, a method of operating a server node participating in a blockchain network system includes an operating system (operating system) in which the server node operates the server node for access to the blockchain network. Performing authorization at the system level of an operation system (OS); After the authentication, obtaining assimilation information from another server node by accessing the blockchain network; and allocating dedicated resources for the blockchain network based on the moving picture information and performing a consensus procedure for the blockchain network using the dedicated resources.

In the present invention, the dedicated resource may include at least one or more of the following:

- Dedicated CPU (Central Processing Unit) for the blockchain network

- Dedicated processor for the blockchain network

- A dedicated integrated circuit (IC) for the blockchain network

In the present invention, allocating dedicated resources for the blockchain network may include allocating the dedicated resources through virtualization of hardware resources of the server node.

According to another embodiment for solving the object of the present invention, a blockchain network system includes a first server node participating in a blockchain network; and one or more second server nodes that are connected to the first server node and perform a consensus procedure defined in the blockchain network. At this time, each of the first server node and the second server node is connected to the blockchain network through authorization performed at the system level of an operating system (OS) operating a corresponding server node, A dedicated resource of the same size may be allocated for the blockchain network and an agreement procedure for the blockchain network may be performed using the dedicated resource.

In the present invention, the first server node corresponds to a host node or leader node for the blockchain network, and the one or more second server nodes are defined in the blockchain network according to the operation of the first server node. It can correspond to participating nodes or follower nodes that perform consensus procedures.

According to the present invention, a more efficient consensus procedure can be performed by performing conventionally time-consuming tasks and node authentication procedures prior to building a blockchain system corresponding to joining/participation in a blockchain network.

In addition, according to the present invention, since the difference in performance between nodes participating in the blockchain system is not large, improvement in communication performance (eg, optimized data processing, predictable delay time, etc.) in a distributed system can be expected.

1 is a diagram simply showing a basic model of a server node applicable to the present invention.

2 is a diagram briefly illustrating an assimilation procedure according to an example of the present invention.

3 is a flowchart illustrating a method of operating a server node applicable to the present invention.

Hereinafter, embodiments of a blockchain network system and a method of operating a server node participating in the system according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to clarify the gist of the present invention.

The present invention relates to a non-mining blockchain network system for ESG (Environment, Social and Governance) and a method of operating a server node participating in the system. More specifically, the present invention relates to a blockchain network system for ESG that can be continuously and stably maintained compared to the prior art and a method of operating a server node participating in the system.

Prior to the detailed description of the present invention, the blockchain and consensus algorithm applied to the present invention will be described in detail.

[블록체인 (block chain)][block chain]

Blockchain is a form of distributed database managed through a P2P (Peer to Peer) network. It is a technology that stores and stores ledgers containing transaction information on multiple computers connected to a blockchain network, rather than storing them in one central server.

In other words, the blockchain system is a kind of distributed ledger that records transaction information, and each node has its own ledger, and the contents of each ledger are kept the same by a consensus algorithm. One entry recorded in the ledger can be expressed as a transaction, and when a user who wants to record in the ledger creates a transaction and delivers it to the P2P network, blockchain processing nodes collect them to create a block.

At this time, the blocks are connected to each other in the form of a chain, and the blockchain system enables the ordered recording of transactions. At this time, individual nodes can generate blocks according to the defined consensus algorithm (or consensus protocol), and through this, all nodes can retain the same information.

This blockchain technology is characterized by high security and transparency by simultaneously applying distributed processing and encryption technology. In addition, such block chain technology may include smart contract technology that allows transactions to be made without a trusted third party in transaction contracts as well as transaction ledger data.

[합의 알고리즘 (Consensus Algorithm)][Consensus Algorithm]

For a blockchain system, a consensus algorithm can correspond to a mechanism to achieve consensus in a blockchain network. In general, a decentralized blockchain system consists of a decentralized system and does not depend on a central authority. Therefore, for such a blockchain system, an agreement on the validity of a transaction between distributed nodes included in the blockchain system is required. These consensus algorithms ensure that protocol rules are being followed within the blockchain system and ensure that all transactions proceed in a reliable manner.

Hereinafter, based on the above technical details, the blockchain network system proposed in the present invention and the operating method of the server node participating in the system will be described in detail.

For convenience of description below, objects implementing Distributed Ledger Technology (DLT) by accessing a P2P network, which is a blockchain system, are referred to as server nodes or nodes.

In the present invention, it is assumed that a node operates based on a basic model described later.

1 is a diagram simply showing a basic model of a server node applicable to the present invention. Hereinafter, for convenience of explanation, the basic model shown in FIG. 1 will be referred to as HSM (Holistic State Machine). However, the above name is only an example, and the basic model may be named differently according to embodiments.

As shown in FIG. 1, the HSM according to the present invention can be basically defined as a model that operates based on an operating system (OS, 1). In the present invention, the OS 1 may include system software that not only manages the system hardware of a corresponding node but also provides a hardware virtualization platform and common system services to execute application software. Alternatively, the OS 1 is an object / application / entity that can perform a function of allocating computing resources (eg, CPU (Central Processing Unit), etc.) of the node to a specific program etc. can be responded to.

In the present invention, the OS 1 may include at least one of apparatus 10, compatible firmware 20, and peer to peer application 30. As a more specific example, the OS 1 controls the Apparatus 10, the compatible firmware 20, the P2P application, etc. to perform participation and agreement procedures in the blockchain network system according to the present invention. can

In the present invention, Apparatus 10 may include hardware required to participate in a blockchain network. For example, the apparatus 10 may include hardware devices such as CPU, RAM (Random Access Memory), and IC (Integrated Circuits) included in the server node.

In the present invention, the compatible firmware 20 can control the operation of the dedicated CPU 22, the dedicated processor(s) 24, and the dedicated IC. For example, the compatible firmware 20 may include a Basic Input Output System (BIOS) capable of performing a function of initializing and inspecting hardware components in a node, and reading an operating system stored in a bootloader or mass storage device into RAM. can

In the present invention, the P2P application 30 may include software required to control the aforementioned Apparatus 10. For example, the P2P application 30 may include code information or application information related to the consensus model 35 for the corresponding blockchain system. In this case, the consensus model 35 may include various consensus algorithms according to embodiments. For example, the consensus model 35 is a PoW algorithm, a PoS algorithm, a RAFT algorithm (e.g., RPC (Remote Procedure Call) is applied), an improved RAFT algorithm (e.g., DPC (Distributed Procedure Call) is applied), etc.

A key principle of HSM may include resolving any computational conflict by assembling concrete methods to advance towards a common goal that is logical and orderly by all nodes. According to this method, it may not always be fast to reach an initial state before taking any action, but there is a great advantage in that unnecessary validation performed in a general distributed system can be removed.

In addition, according to HSM, it can be assumed that all nodes participating in a corresponding blockchain network share a common basis in hardware specifications. Through this, it is possible to harmonize the time each node spends reading and writing data with the predictable network traversal time.

The generalization of Figure 1 is not limited to algorithms beyond experimental ideas and thinking. This can be implemented through any hardware device, i.e. OS, on which a physical object or virtual device can run. An OS (1) (e.g. Windows OS, etc.) can allocate CPU cores to specific programs. Accordingly, according to the present invention, the OS 1 may allocate a dedicated CPU 22 and/or dedicated processor(s) 24 and/or a dedicated IC for P2P communication. Through this, according to the present invention, the following can be prevented:

- Irregularity in server response time

- Infinite wait-lock in program execution

In addition, the OS according to the present invention may serve as an external authority for managing admission to the corresponding blockchain network. According to this, since authentication to the corresponding blockchain network is performed in advance, it can have a great advantage over the conventional PoS model. This is because conventional PoS models and the like require node validity to be authenticated at transaction time, which separates service logic and system functions.

Through the above-described HSM, all nodes participating in the blockchain network according to the present invention can be operated by the same virtual machine. In other words, each node includes a virtual machine that operates on resources allocated by the OS (eg, CPU/processor/IC, etc.), and can participate in and operate a corresponding blockchain network through the virtual machine. At this time, each node receives the specification information of the HSM from the blockchain network and can always maintain the same specification of the virtual machine.

Based on the HSM described above, each node participates in the blockchain network through the assimilation procedure described later and performs the consensus procedure according to the corresponding consensus algorithm (e.g., the consensus algorithm defined on the blockchain network, etc.) can do.

The assimilation process (or assimilated authentication) according to the present invention applies recognizable and unified conditions to unknown devices/nodes to mirror their respective state into a rapidly usable data-exchange format. process may be included. This device-to-application mirroring (or reflection) can be the driving force behind an HSM in accordance with the present invention.

This assimilation process can serve two roles:

- Virtual hardware optimization

- Preliminary node authentication

Virtual hardware optimization can be controlled through the replicated state of the host node (or leader node).

In general, most operating systems have a system registry that tracks installed devices, and the HSM according to the present invention can generate a separate identifier by obtaining a registrar from the system registry. For example, the HSM may generate the identifier (eg, a video identifier) by applying a hash function to the obtained registrar information.

Each node participates in the blockchain network and first broadcasts the generated identifier to the resource management node in the nearby pool, and then, if the resource acquisition is successful, the generated identifier can be immediately delivered to the entire network. At this time, resource allocation is performed per request for a node intending to join the blockchain network, and may be performed in an execution-first order. More specifically, the assimilation process according to the present invention can be performed as follows.

As shown in FIG. 2 , in an initial stage, each node may have different hardware specifications. In the next staging step, each node performs system-level authorization and/or auxiliary validation at the OS level (or on the OS layer) in the process of accessing/participating in the blockchain network according to the present invention ( Ancillary Validation) can be performed. At this time, the fact that each node performs system-level authentication at the OS level means that the system-level authentication of the OS in the process of each node attempting to access / participate in the blockchain network system according to the present invention based on the OS and the like. If authentication is successful, each node can utilize the replicated state information of the host node (or leader node) to allocate the same hardware specifications exclusively for the P2P network and perform the consensus procedure defined in the corresponding blockchain system.

Additionally, a specific program executed on the system level of the OS of each node according to the present invention may be further included. In other words, a specific program running on the system level may exist in the OS of each node. For convenience of description, the specific system is named a watcher, but the name is only an example, and the basic model may be named differently depending on the embodiment.

A watcher is a daemon process/application running in the background (e.g., a process/application that is not displayed on the screen or is not primarily executed, but which remains running, a process/application that operates by itself without input from the user) etc.) can work. At this time, the monitor may play a role in finding at least one or more of the following abnormalities:

- Any changes in the assimilated state

- Post-validation of promotion and demotion of a node

- Preemptive attempt to disqualify a newly joined node

The above-described assimilation process may be performed internally in the process of data replication (or log replication) within the consensus algorithm.

Based on the foregoing assimilation process, nodes according to the present invention can operate based on consensus algorithms according to various consensus models.

For example, nodes according to the present invention may perform a consensus procedure according to a consensus model in which DPC is applied to the RAFT consensus algorithm. Here, the RAFT consensus algorithm is characterized in that consensus is performed through a leader elected among nodes. To this end, a leader election step and a log replication step may be performed.

[리더 선출 (leader election) 단계][Leader election stage]

Leader election can be performed when an existing leader fails or the consensus algorithm starts anew. To this end, each node can have one of three states: a leader state, a follower state, or a candidate state.

When the leader election is performed, a new term begins. If the leader election is successful, the Term can continue with the normal command coordinated by the elected leader node. On the other hand, if the leader election fails, a new term may start with the new leader election.

Each node in the follower state (hereinafter referred to as follower node) may become a candidate state if no contact is received from the leader node within the election timeout. At this time, the election timeout value for each node may be randomly determined.

Nodes that have entered the candidate state (hereinafter referred to as candidate nodes) can start electing a new leader. To this end, the candidate node may vote itself as a new leader while increasing a term count, and may transmit a message requesting voting to other nodes. Correspondingly, the follower node may transmit a response corresponding to the request to the candidate node if there is no case of voting within the corresponding term. At the same time, the follower node may initialize its election timeout value.

Through this process, if a candidate node receives a majority vote, the candidate node can become a leader node within the corresponding term. On the other hand, if the leader node within the term is not determined, a new term begins and a new leader election may begin.

[로그 복제 (log replication) 단계][log replication step]

Log replication can be controlled through a leader node. More specifically, the log replication process may be performed as follows.

(1) The node with the change (e.g. client) sends a request for it to the leader node.

(2) The leader node saves/connects the change to a new entry (eg, Log entry) of the leader node.

(3) The leader node sends a request for the change to the follower nodes as an entry extension message.

(4) In response to this, the follower nodes save/connect the change as a new entry (e.g. Log entry) and transmit a response to it to the leader node.

(5) When receiving a response from more than half of the follower nodes, the leader node commits its entry and transmits a response to the client.

(6) Also, the leader node notifies the follower nodes that the change has been committed, and in response, the follower nodes commit the changed entry.

In particular, according to an example applicable to the present invention, the nodes according to the present invention combine such a RAFT consensus algorithm with DPC, a signaling scheme suitable for a P2P network having characteristics different from the conventional 1:1 server-client system. A consensus process can be performed according to the consensus model.

As another example, the nodes according to the present invention may not operate with different states (eg, leader nodes or follower nodes) as in the above-described RAFT algorithm, but all may operate with the same state. In other words, all of the nodes may perform the consensus procedure in the same state. As a preferred example, the nodes may perform a consensus procedure according to a consensus model based on the same state (or the same priority, etc.) as in the PoW consensus algorithm.

Additionally, a separate reward may be provided to a node that generates a block according to the consensus algorithm according to the present invention. In this case, coins/tokens related to the blockchain system may be paid as compensation. However, this is an example applicable to the present invention, and the compensation may not be provided according to system settings or administrator settings.

According to the technical ideas described above, the blockchain network system and server nodes participating in the system according to the present invention may operate as follows.

First, the blockchain network system according to the present invention may be implemented in a form in which a plurality of server nodes are connected to a P2P network through a network.

As an example applicable to the present invention, a blockchain network system includes a plurality of server nodes (e.g., a first server node and one or more second server nodes connected to the first server node to perform a consensus procedure defined in the blockchain network). server node) may participate and be configured.

In particular, according to the present invention, each of the plurality of server nodes described above is connected to the blockchain network through authorization performed at the system level of an operating system (OS) operating a corresponding server node, and A dedicated resource of the same size may be allocated for the blockchain network and an agreement procedure for the blockchain network may be performed using the dedicated resource.

As another example applicable to the present invention, the plurality of server nodes described above may have the same state and perform a consensus procedure defined on a corresponding blockchain network. Alternatively, as another example, the plurality of server nodes described above include a first server node having a first state (eg, host node, leader node, etc.) and one or more second server nodes having a second state (eg, participating node, follower node, etc.) It can be configured as a server node. In this case, the first server node corresponds to a host node or leader node for the blockchain network, and the one or more second server nodes correspond to a consensus procedure defined in the blockchain network according to the operation of the first server node. may correspond to participating nodes or follower nodes that perform

More specifically, the above-described server nodes operate as follows and may participate in the blockchain network according to the present invention.

As shown in FIG. 3, the server node requires authorization at the system level of an operation system (OS) in which the server node operates the server node for access to the blockchain network according to the present invention. Perform (S310). Here, the fact that the server node performs authentication at the system level of the OS means that the server node is authenticated at the system level of the OS in the process of trying to access / participate in the blockchain network system according to the present invention based on the OS. This may include performing procedures.

After the above authentication, the server node accesses the blockchain network according to the present invention and obtains assimilation information from other server nodes (S320). At this time, the server node may obtain the moving image information based on the OS or obtain the moving image information through a medium unrelated to the OS. The animation information may be broadcast to each server node participating in the blockchain network. At this time, the animation information may include dedicated resource information (eg, hardware specification information, etc.) required to participate in the blockchain network. Such animation information can be generated in various data formats. The animation information is not limited thereto, but may be obtained through a data exchange format such as, for example, JSON (JavaScript Object Notation).

The server node allocates a dedicated resource for the blockchain network according to the present invention based on the acquired animation information and performs a consensus procedure for the blockchain network using the dedicated resource (S330). In this case, the dedicated resource allocation of the server node and the execution of an agreement procedure based thereon may be performed based on the OS of the server node. In other words, the server node may perform the above-described dedicated resource allocation and an agreement procedure based thereon using the OS.

Here, the dedicated resource for the blockchain network may include at least one or more of the consonants:

- Dedicated CPU (Central Processing Unit) for blockchain network

- Dedicated processor for blockchain network

- Dedicated integrated circuit (IC) for blockchain network

Allocating dedicated resources for a blockchain network by a server node according to the present invention may include allocating the dedicated resources through virtualization of hardware resources of the server node. Therefore, the server node can allocate dedicated resources for the blockchain network through virtualization using the obtained video information, and the dedicated resources can be restricted so that they are not used for other purposes. Through this, all server nodes participating in the blockchain network according to the present invention can always participate in the blockchain network with certain hardware specifications.

As described above, the preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art can make various modifications to the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. may be modified or changed.

[Description of code]

1: OS

10: apparatus

20: compatible firmware

22: Dedicated CPU

24: dedicated processor(s)

30: P2P application

35: Consensus Model

Claims

In the operating method of a server node participating in a blockchain network system,

For access to the blockchain network, the server node performing authorization at the system level of an operating system (OS) operating the server node;

After the authentication, obtaining assimilation information from another server node by accessing the blockchain network; and

Based on the assimilation information, allocating dedicated resources for the blockchain network and performing an agreement procedure for the blockchain network using the dedicated resources. A method of operating a server node.
According to claim 1,

The dedicated resource,

A dedicated CPU (Central Processing Unit) for the blockchain network,

a dedicated processor for the blockchain network; or

Characterized in that it comprises at least one or more of the dedicated integrated circuit (IC) for the blockchain network, the operating method of the server node.
According to claim 1,

Allocating dedicated resources for the blockchain network,

Characterized in that it comprises allocating the dedicated resource through virtualization of the hardware resources of the server node, the operating method of the server node.
In the blockchain network system,

A first server node participating in the blockchain network; and

Including one or more second server nodes connected to the first server node and performing an agreement procedure defined in the blockchain network;

Each of the first server node and the second server node,

Access to the blockchain network through authorization performed at the system level of an operating system (OS) operating a corresponding server node,

A blockchain network system, characterized in that allocating a dedicated resource of the same size for the blockchain network and performing an agreement procedure for the blockchain network using the dedicated resource.
According to claim 4,

The first server node corresponds to a host node or leader node for the blockchain network,

Characterized in that the at least one second server node corresponds to a participating node or a follower node that performs a consensus procedure defined in the blockchain network according to the operation of the first server node.