JP2020197822A - Server device, commission setting method, and program - Google Patents

Abstract

To provide a server device, a commission setting method, and a program which can implement mining loops allowing both preventing computational power concentration on a specific mining loop and satisfying users.SOLUTION: In a network structure, a server device 1 transmits a search request to request a search for a correct nonce to a plurality of mining devices and, when acquiring a correct nonce from the mining devices, transmits a block including the correct nonce and data to a network for a block chain. The service device 1 comprises: a setting unit 57 which sets commissions in accordance with ratios of hash rates of one or more client devices being transmission destinations of the search request and a hash rate of the entire network; an acquisition unit 56 which acquires a commission from mining rewards; and a distribution unit 58 which distributes mining rewards resulting from subtracting the commission to the mining devices.SELECTED DRAWING: Figure 4

Description

The present invention relates to a fee setting method for distributed computing, and more particularly to a fee setting method for cryptocurrency mining.

A cryptocurrency that records transaction information (transactions) on the blockchain is used. A blockchain is a database that records transaction information in a distributed network by generating blocks containing transaction information and concatenating the generated blocks.
Since the block contains the transaction information and the correct nonce, as well as a hash value indicating the contents of the block generated immediately before, the blockchain connects the generated blocks in chronological order. , Has a data structure that is difficult to tamper with. The correct nonce is, for example, a nonce that gives a header hash value smaller than a fixed threshold when a hash function is applied to the hash value of the previous block and the input value including the correct nonce and transaction information. is there.
The correct nonce is sought by mining. In proof of work, mining is the work of searching for the correct nonce by applying a hash function to the data contained in the block while changing the nonce contained in the block.
In recent years, a mining pool has been known as a service for stabilizing mining rewards for cryptocurrencies (Patent Document 1).
Since proof of work requires enormous computing power, the mining rewards obtained tend to be biased toward large-scale businesses.
On the other hand, in the mining pool, it is possible to secure the computing power that can compete with large-scale businesses and stabilize the mining reward by sharing the mining by the computing power of the participating individuals.

JP-A-2017-91148

However, in the conventional mining pool, there is a problem that users, that is, computing power, gather too much in the popular mining pool. The phenomenon of excessive computing power is, in other words, impaired decentralization, and there is a risk that the reliability of the cryptocurrency system will be impaired.
As a typical example, if one pool holds more than 50% of the computing power provided to the entire network, an attack called a 51% attack is possible by the pool operator.
In order to prevent this, pool operators and users have traditionally called on each other so that the computing power is not concentrated on a specific mining pool.
However, which mining pool to participate in is ultimately left to the discretion of each user, and the results are uncertain. On the other hand, if the number of participants in the mining pool is regulated by force, it is difficult to obtain the consent of the users who want to participate.
As one aspect of the present invention, the present invention realizes a mining pool that can prevent the concentration of calculation power in a specific mining pool and satisfy the user.

The present invention has been made to solve the above problems, and as one form, by applying a hash function to an input value including the nonce while changing the nonce, a hash of a value smaller than the search threshold is hashed. The value included in the input value and the search request requesting the search for the correct nonce are transmitted to the mining device that searches for the correct nonce from which the value is obtained, and when the correct nonce is obtained, the correct nonce and data are used. A transmitter that transmits a block containing the above to the network of the blockchain, a receiver that receives the correct nonce searched in response to the search request from the mining device, and one or more of the above destinations of the search request. A setting unit that sets a fee according to the ratio of the first processing capacity of the mining device to the second processing capacity of the network, and an acquisition unit that acquires the fee from the first reward obtained by mining. It is characterized by a server device including a distribution unit that distributes a second reward obtained by subtracting the fee from the first reward to one or more of the mining devices.

According to the present invention, as one aspect, a mining pool that can prevent the concentration of calculation power in a specific mining pool and satisfy the user is realized.

It is a figure which shows an example of the network structure of the blockchain of this embodiment. It is a functional block diagram which shows one Example of the mining apparatus of this embodiment. It is a functional block diagram which shows one Example of the mining apparatus of this embodiment. It is a functional block diagram which shows one Example of the server apparatus of this embodiment. It is a figure explaining the fee setting method performed by the server apparatus of this embodiment. It is a figure which shows the fee setting table. It is a figure explaining the presentation of information performed by the server apparatus of this embodiment. It is a flowchart explaining the process performed by the server apparatus of this embodiment. It is a block diagram which shows one Example of a computer apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing an example of the network structure of the blockchain of the present embodiment.
The blockchain network structure 100 will be described with reference to FIG.
The blockchain network structure 100 includes a server device 1, a client device 2, a mining device 3, a trading device 4, a network 150, and a network 160.
The server device 1, the mining device 3, and the trading device 4 are connected to each other so as to be able to communicate with each other via the network 150.
A plurality of mining devices 3 and trading devices 4 may be connected to the network 150, respectively.
The server device 1, the client device 2, the mining device 3, and the trading device 4 are, for example, computer devices described later.

In the example of FIG. 1, mining devices 3a, 3b, and 3c are connected as a plurality of mining devices 3. Further, as the plurality of trading devices 4, the trading devices 4a and 4b are connected.
The network 150 is a decentralized network such as a P2P (Peer to Peer) network, and records transaction information on a blockchain.
A blockchain is a database that records transaction information in a distributed network by generating blocks containing transaction information and concatenating the generated blocks.
Since the block contains the transaction information and the correct nonce, as well as a hash value indicating the contents of the block generated immediately before, the blockchain connects the generated blocks in chronological order. , Has a data structure that is difficult to tamper with.

The correct nonce is, for example, a nonce that gives a header hash value smaller than a fixed threshold when a hash function is applied to the hash value of the previous block and the input value including the correct nonce and transaction information. is there. As for the correct nonce condition, other conditions may be set as appropriate so that the difficulty level can be easily adjusted.
The correct nonce is sought by mining. In proof of work, mining is the work of searching for the correct nonce by performing a hash calculation that applies a hash function to the data contained in the block while changing the nonce contained in the block.
In proof of work, the number of times the mining device or the mining pool described later executes the above hash calculation per second is called a hash rate.
The server device 1 is a so-called pool server that instructs the connected client device 2 to search the nonce and efficiently utilizes the computing power of the plurality of client devices 2. The pool server is also referred to as a mining pool below.
The term mining pool may refer to the entire distributed processing system composed of the server device 1 and the client device 2.
Further, the mining pool described in the present specification shall refer to a specific mining pool provided by the specific server device 1.
A plurality of client devices 2 may be connected to the server device 1 via the network 160. Client devices 2a, 2b, 2c, and 2d are connected as a plurality of client devices 2.
The network 160, unlike the network 150, may be a normal client / server type network that is not a P2P network.

[Mining device]
FIG. 2 is a functional block diagram showing an embodiment of the mining device of the present embodiment.
The function of the mining device 3 will be described with reference to FIG.
The mining device 3 includes a control unit 10 and a storage unit 20, and is connected to the display device 8.
The storage unit 40 stores the blockchain 21 and the unapproved information 22.
The blockchain 21 is a database that records transaction information in a decentralized network.
The unapproved information 22 is a so-called transaction pool that stores unapproved transaction information.

The control unit 10 includes a reception unit 11, a verification unit 12, a search unit 13, a generation unit 14, a determination unit 15, and a transmission unit 16.
The receiving unit 11 receives the transaction information broadcast from the transaction device 4 via the network 150.
After verifying the transaction information, the verification unit 12 stores the transaction information as the unapproved information 22 in the storage unit 20.
The search unit 13 extracts the unapproved transaction information included in the block from the unapproved information 22 and searches for the correct nonce.
The generation unit 14 generates a block containing unapproved transaction information, a correct nonce, and a hash value of the previous block.
The determination unit 15 determines whether or not the mining is successful.
The transmission unit 16 broadcasts the block generated by the generation unit 14 to each device connected via the network 150.
In addition, the verification unit 12 may further verify the transaction information included in the block at least one before the search process by the search unit 13 and before the generation process by the generation unit 14. Further, the verification unit 12 stores the transaction information before verification as unapproved information 22 in the storage unit 20, and includes the transaction information in the block at least before the search process by the search unit 13 and before the generation process by the generation unit 14. You may perform verification of transaction information to be made.

[Client device 2]
FIG. 3 is a functional block diagram showing an embodiment of the client device 2 of the present embodiment.
The function of the client device 2 will be described with reference to FIG.
The client device 2 is a device capable of executing mining like the mining device 3, but mining is performed by participating in the mining pool instead of performing mining alone. Actually, the client device 2 is assigned a range of nonces to be searched from the mining pool, and searches for the correct nonce within that range.
The mining device 3 described with reference to FIG. 2 can also participate in the mining pool by connecting to the server device 1 and providing the processing unit described with reference to FIG.
FIG. 3 particularly describes a configuration for connecting to the mining pool included in the client device 2.
The client device 2 includes a control unit 30 and a storage unit 40, and is connected to the display device 8.
The storage unit 40 stores the blockchain 21 and the unapproved information 22.
As described above, the blockchain 21 is a database that records transaction information in a decentralized network. As described above, the unapproved information 22 is also a so-called transaction pool for storing unapproved transaction information.

The control unit 30 includes the reception unit 31, the search unit 32, the transmission unit 33, the connection unit 34, and the acquisition unit 35, and the reception unit 31 transmits the search request transmitted by the server device 1 via the connection unit 34. Is received and stored in the storage unit 40.
As will be described later, the search request is information indicating the transaction information, the hash value of the previous block, and the search range of the nonce distributed by the server device 1.
As a mining process, the search unit 32 searches the mining pool to see if there is a correct nonce in the range of the nonce to be searched.
The search unit 32 searches for a correct nonce that can obtain a hash value having a value smaller than the search threshold value by applying a hash function to the input value including the nonce while changing the nonce within the designated range.
The transmission unit 33 transmits the correct nonce searched by the search unit 32 to the server device 1 via the connection unit 34.
The connection unit 34 connects to the server device 1 via the network 160.
The acquisition unit 35 functions as a so-called Web browser, acquires graph information related to the mining fee disclosed by the server device 1 as a Web page via the network 160, and displays it on the display device 8.

[Server device]
FIG. 4 is a functional block diagram showing an embodiment of the server device of this embodiment.
The function of the server device 1 will be described with reference to FIG.
The server device 1 includes a control unit 50 and a storage unit 60.
The storage unit 60 stores the blockchain 21, the unapproved information 22, and the calculation power information 23.
As described above, the blockchain 21 is a database that records transaction information in a decentralized network. As described above, the unapproved information 22 is also a so-called transaction pool for storing unapproved transaction information.

Further, the calculation power information 23 is a database in which the server device 1 records log information regarding the calculation power of the network or the mining pool based on the information collected from the network or the client device 2.
Specifically, what is stored in the calculation power information 23 is
(1) Hash rate of the mining pool, which is the computing power of the mining pool (2) Hash rate of the entire network, which is the computing power of the entire network (3) Calculation of the mining pool calculated based on (1) and (2) Actual value of power provision rate (4) Difference (deviation) between the target value and actual value of the calculation power provision rate described later
It is the log information of.
The control unit 50 includes a connection unit 51, a distribution unit 52, a reception unit 53, a transmission unit 54, a determination unit 55, an acquisition unit 56, a setting unit 57, a distribution unit 58, and a presentation unit 59. ,including.
The connection unit 51 is communicably connected to the client device 2 via the network 160.
As described above, the client device 2 performs mining to search for a correct nonce that can obtain a hash value having a value smaller than the search threshold value by applying a hash function to the input value including the nonce while changing the nonce.
The distribution unit 52 distributes the range of nonces to be searched to a plurality of client devices 2 connected to the server device 1.

The receiving unit 53 receives the transaction information from the network 150 as an input value and stores it in the storage unit 60 as unapproved information.
Further, the receiving unit 53 receives the correct nonce from the client device 2 that has searched for the correct nonce in response to the search request via the connecting unit 51.
The transmission unit 54 sends the transaction information included in the input value, the hash value of the previous block, and the information indicating the search range of the nonce distributed by the distribution unit 52 to the client device 2 as the search request via the connection unit 51. Output.
Further, when the correct nonce is obtained by the mining device 2 connected to the server device 1, the transmission unit 54 transmits a block containing the correct nonce and data to the blockchain network 150.
The determination unit 55 determines whether or not the mining pool has acquired the authority to connect the blocks.
The acquisition unit 56 acquires a predetermined mining fee from the mining reward obtained by mining.

The setting unit 57 includes a target value setting unit 61, a fee setting unit 62, and a provision rate calculation unit 63, as will be described later.
The setting unit 57 sets a fee according to the calculation power provision rate, which is a ratio of the calculation power of one or more client devices participating in the mining pool to which the search request is transmitted and the calculation power of the network 150. To do.
The distribution unit 58 distributes the reward after deducting the mining fee from the mining reward to the client device 2 participating in the mining pool.
The presentation unit 59 externally provides information on the fee set by the setting unit 57, the hash rate of the mining pool and the hash rate of the entire network on which the fee is set, and the calculation power provision rate of the mining pool. Present to. These pieces of information are information stored in the computing power information 23 of the storage unit 60.
As will be described later, the presentation of such information is performed in the form described on the Web page, and the presentation unit 59 functions as a so-called Web server.

FIG. 5 is a diagram illustrating a fee setting method performed by the server device of the present embodiment.
The server device 1 of the present embodiment dynamically charges the mining fee collected from the user according to the computing power provision rate of the mining pool in the entire network, that is, the ratio of the hash rate of the mining pool to the hash rate of the entire network. change.
By appropriately changing the mining fee, the user is encouraged to set the calculation power provision rate of a specific mining pool to an appropriate target value.
By changing the mining fee, the user decides to participate in the mining pool at his / her own discretion, so that it is possible to avoid an excessive calculation power provision rate of the mining pool in a way that the user is satisfied with.

This will be described in more detail.
As described above, the setting unit 57 included in the server device 1 includes a target value setting unit 61, a fee setting unit 62, and a provision rate calculation unit 63.
The target value setting unit 61 accepts the setting of the target value using a keyboard or the like by a pool operator or the like that manages the server device 1.
The provision rate calculation unit 63 detects the hash rate of the mining pool based on the computing power provided by the user for the mining pool provided by the server device 1, and also detects the hash rate of the network.
In the following, the hash rate indicating the computing power of the mining pool is referred to as the pool hash rate, and the hash rate indicating the computing power of the entire network is referred to as the network hash rate.
The provision rate calculation unit 63 calculates the calculation power provision rate of the mining pool based on the pool hash rate and the network hash rate.
The provision rate calculation unit 63 can calculate the calculation power provision rate by dividing [pool hash rate] / [network hash rate].

As a first method of calculating the pool hash rate, the provision rate calculation unit 63 calculates the pool hash rate from the data corresponding to the processing capacity of the client device 2 submitted from the client device 2 participating in the mining pool. Can be done.
The data corresponding to the processing capacity of the client device 2 is the hash rate of the client device 2.
The pool hash rate can be derived by adding up the hash rates of all the client devices 2 connected to the mining pool.
As a second method of calculating the pool hash rate, the provision rate calculation unit 63 can calculate the pool hash rate from the number of blocks that the mining pool has found the correct nonce and recorded in the blockchain.
In this case, the provision rate calculation unit 63 obtains the hash rate of the mining pool from the ratio of the blocks transmitted from the transmission unit 54 and recorded on the blockchain to all the blocks recorded on the blockchain at predetermined intervals. Can be done.

In the first method, since the pool hash rate is calculated from the data submitted by the users participating in the mining pool, accurate values can be obtained, but third-party verification is difficult, and the server device 1 holds the pool hash rate. There is a problem that the data to be required becomes large.
In the second method, since the pool hash rate is calculated from the number of blocks actually discovered by the mining pool, there is a problem that the value becomes inaccurate especially in a pool with a low hash rate. On the other hand, according to the second method, third-party verification is easy because the data actually recorded on the blockchain is referred to.
About the hash rate of the network, the approximate value can be known by referring to the data recorded on the blockchain.

The target value setting unit 61 sets an arbitrary control target as a target value with respect to the computing power provision rate of the mining pool provided by the server device 1 in the entire network calculated by the provision rate calculation unit 63.
The fee setting unit 62 sets a mining fee to be collected from users participating in the mining pool in order to control the calculation power provision rate of the mining pool.
The deviation and difference between the target value set by the target value setting unit 61 and the actual value of the calculation power provision rate observed by the provision rate calculation unit 63 are input to the fee setting unit 62.
The fee setting unit 62 determines the mining fee to be collected from the users participating in the mining pool by the method described below based on the input deviation information. The determined fee is immediately reflected by the acquisition unit 56.

The mining fee determined by the fee setting unit 62 affects the number of users participating in the mining pool, that is, the computing power of the mining pool.
Here, the number of participants in the mining pool is synonymous with the number of client devices 2 connected to the mining pool or the server device 1.
If the mining fee is high, the number of users participating in the mining pool will decrease and the computing power will decrease. Conversely, if the fee is low, the number of users participating in the mining pool will increase and the computing power will increase. Be done.
The provision rate calculation unit 63 further calculates the calculation power provision rate in the entire network of the calculation power of the mining pool that fluctuates due to the change of the fee, and sets the deviation between the calculated actual value and the target value as the fee setting unit 62. Performs feedback control to be input to.
This feedback control is repeated until the calculation power providing rate of the mining pool reaches the target value set by the target value setting unit 61. The feedback control may be continuously performed so that the calculation power provision rate can maintain the target value even after the calculation power provision rate reaches the target value.
The target value set by the target value setting unit 61, the processing internal use by the fee setting unit 62, and the processing content by the provision rate calculation unit 63 are all publicly disclosed.

In addition to fluctuations in mining fees, disturbances such as market conditions can be considered as factors that affect the computing power of mining pools.
Disturbances are, for example, fluctuations in the value of cryptocurrencies with respect to legal tender, social and political trends, and rumors.
Some disturbances affect the entire network, such as changes in the number of people participating in mining due to fluctuations in the value of cryptocurrencies, while others affect specific mining pools due to rumors such as scandals of operating companies.
In this way, the hash rate as the computing power of the pool is affected by various external factors. In the present embodiment, the server device 1 controls the calculation power provision rate by increasing or decreasing the mining fee while incorporating such disturbance.
The server device 1 of the present embodiment controls the computing power provision rate in the entire network, not the absolute value of the pool hash rate, and disturbances that affect the entire network can be virtually ignored. ..
In addition, by changing the mining fee, it is possible to realize a hash rate that suppresses the influence of disturbance on each mining pool.

An example of the processing of this embodiment will be described.
The target value of the calculation power provision rate can be set to an arbitrary real number value by the target value setting unit 61, and it is assumed that the target value is set to 25%, for example.
The fee setting unit 62 sets the fee according to the input deviation based on the fee setting table shown in FIG.
When the computing power provision rate of the target mining pool in the entire network is 45% or more with respect to the target value of 25%, the deviation from the target value is 20% or more.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to 5%.
By setting the fee to 5%, the number of participating users will decrease and the computing power will be greatly reduced.
When the calculation power provision rate is 35% to 45% with respect to the target value of 25%, the deviation from the target value is 10% to 20%.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to 2%.
When the computing power provision rate of the target mining pool in the entire network is 25% to 35% with respect to the target value of 25%, the deviation from the target value is 0% to 10%.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to 1%.
When the calculation power provision rate is 15% to 25% with respect to the target value of 25%, the deviation from the target value is -10% to 0%.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to 0.5%.

When the calculation power provision rate is 5% to 15% with respect to the target value of 25%, the deviation from the target value is -20% to -10%.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to 0%. In other words, the fee is not collected from the mining reward.
By setting the fee to 0%, the number of participating users increases and the computing power increases.
Further, when the calculation power provision rate is 5% or less with respect to the target value of 25%, the deviation from the target value is 20% or less.
In that case, as shown in FIG. 6, the fee setting unit 62 sets the fee to −0.1%. That is, a reward of 0.1% is added to the mining reward.
Instead of being charged a fee, it is added to the mining reward, so the number of participating users is greatly increased and the computing power is greatly increased.
If the number of users participating in the mining pool is extremely reduced in order to reduce the calculation power provision rate, the continuity of the mining pool business itself will become severe.
Therefore, the fee setting unit 62 can set the fee low or negative to increase the number of users.

As described above, according to the table of FIG. 6, the setting unit 57 sets the mining fee higher as the ratio of the calculation power of the target mining pool to the calculation power of the entire network, that is, the calculation power provision rate becomes larger.
By setting the mining fee high, the server device 1 can reduce the number of users participating in the mining pool, reduce the computing power of the mining pool, and maintain the computing power provision rate appropriately.
Moreover, since the user decides to participate in the mining pool at his / her own discretion by changing the mining fee, it is possible to avoid the calculation power provision rate of the mining pool from becoming excessive in a way that the user is satisfied with.

The calculation power information 23 of the storage unit 60 may hold a history of the past calculation power provision rate, and the fee setting unit 62 may determine the fee based on the history.
The calculation power information 23 holds, for example, a history of the calculation power provision rate for the past one day.
Then, the fee setting unit 62 determines the mining fee based on the table of FIG. 6 with respect to the average value (moving average) of the deviations between the holding calculation power provision rate for the past day and the target value.
By doing so, it is possible to suppress and moderate sudden fluctuations in fees due to sudden factors, and prevent users from being confused.
Further, the fee setting unit 62 obtains an average value (weighted moving average) of a predetermined period in which the weight is strengthened as it approaches the current time with respect to the deviation between the actual value and the target value of the calculation power provision rate, and is based on the average value. The mining fee may be determined.
By doing so, the server device 1 can set the fee according to the current time situation such as the number of participating users while suppressing the sudden fluctuation of the fee.
The server device 1 calculates the ratio of the computing power provided to the mining pool to the entire network, and automatically calculates and sets the mining fee by feeding back the calculation result. The formula for automatic calculation shall be disclosed to the user.

FIG. 7 is a diagram illustrating the presentation of information performed by the server device of the present embodiment.
The presentation unit 59 of the server device 1 that functions as a Web server dynamically generates and presents a graph 200 (see FIG. 7) in response to a request from an external device such as a client device 2, a mining device 3, or a trading device 4. To do. Graph 200 shows the relationship between the mining fee, each hash rate of the mining pool and the network on which the fee is set, and the calculation power provision rate.
The graph 200 is a graph that can confirm the transition of the mining fee in time series and the data on which the mining fee is based. In the client device 2, the graph 200 can be displayed on the display device 8 by the Web browser.
The data on which the fee is based is at least one of a network hash rate, a pool hash rate, and a computing power provision rate.
When the user performs an operation of moving the mouse cursor 201 on the graph 200, for example, the Web browser queries the presentation unit 59 for the data of the portion corresponding to the mouse cursor 201.
When the presenting unit 59 returns the inquired data to the browser, the corresponding data can be popped up and displayed on the graph 200.
In Graph 200, the relationship between the calculation power provision rate and the mining fee is the same as the relationship shown in the table of FIG. It is assumed that the target value of the calculation power provision rate is also set at 25% as in FIG.
At 5 o'clock on a certain date in the graph 200, the network hash rate is 14.6 TH / s, the hash rate of the mining pool is 5.59 TH / s, and as a result, the computing power provision rate is 38.3%. ..
Further, in the graph 200, at 5 o'clock on a certain date, the difference between the calculation power provision rate at that time and the target value of the calculation power provision rate is 13.3%. Therefore, the mining fee is charged according to the table of FIG. Is clearly set to 2%.
By clarifying the grounds for determining the mining fee in this way, the user of the client device 2 can participate in the mining pool with peace of mind without feeling distrust of the fluctuation of the mining fee.

FIG. 8 is a flowchart illustrating a process performed by the server device of the present embodiment.
The process executed in the server device 1 of the embodiment will be described with reference to FIG. In the following description, for the sake of simplicity, the process executed by the control unit 50 of the server device 1 will be described as the process executed by the server device 1.
In step S100, the server device 1 distributes the range of nonces to be searched to the plurality of connected client devices 2 by the distribution unit 52.
In step S101, the server device 1 transmits a search request including a search range to the client device 2 by the transmission unit 54.
In step S102, the server device 1 determines whether the correct nonce has been received from the network by the receiving unit 53.
If it is determined that the correct nonce has been received (Yes in step S102), the server device 1 ends the process as it is.
If it is determined that the correct nonce has not been received (No in step S102), in step S103, the server device 1 determines whether or not the correct nonce has been received from the client device by the receiving unit 53.
If it is determined that the correct nonce has been received from the client device, in step S104, the server device 1 transmits a block containing the correct nonce and data to the network by the transmission unit 54.
Then, in step 105, the server device 1 sets the mining fee for the current mining by the setting unit 57.
This mining fee setting process is the process itself performed by the mining fee setting unit 62 based on the calculation power provision rate and the target value described in FIG.
Next, in step S106, the server device 1 acquires the mining fee from the mining fee obtained in the current mining by the acquisition unit 56, and in step S107, the distribution unit 58 subtracts the mining fee from the mining fee. , Distribute to each client device.
Since the server device 1 of the present embodiment is configured as described above, the server device 1 of the present embodiment can control the calculation power provision rate occupied by the mining pool in the entire network so as to always approach the target value, and maintain the calculation power provision rate appropriately. You can.
Moreover, since the user decides to participate in the mining pool at his / her own discretion by changing the mining fee, it is possible to avoid the calculation power provision rate of the mining pool from becoming excessive in a way that the user is satisfied with.

FIG. 9 is a block diagram showing an embodiment of a computer device.
The configurations of the server device 1, the client device 2, and the mining device 3 will be described with reference to FIG. The server device 1, the client device 2, the mining device 3, and the trading device 4 can be configured by appropriately selecting some or all of the components described in the computer device 300.
In FIG. 23, the computer device 300 includes a control circuit 301, a storage device 302, a reading device 303, a recording medium 304, a communication interface 305 (communication I / F), and an input / output interface 306 (input / output I / F). ), An input device 307, a display device 308, and a network 309.
Each of the above components is connected by a bus 310.
The control circuit 301 controls the entire computer device 300. The control circuit 301 is, for example, a processor such as a CPU, a multi-core CPU, an FPGA (Field Programmable Gate Array), and a PLD (Programmable Logic Device).
The control circuit 301 functions as the control unit 10 in FIG.
Further, the control circuit 301 functions as a control unit 30 in FIG.
Further, the control circuit 301 functions as a control unit 50 in FIG.

The storage device 302 stores various data. The storage device 302 is composed of, for example, a memory such as a ROM (Read Only Memory) and a RAM (Random Access Memory), an HD (Hard Disk), or the like. The storage device 302 may store a program that causes the control circuit 301 to function as a control unit.
The storage device 302 functions as a storage unit 20 in FIG.
Further, the storage device 302 functions as a storage unit 40 in FIG.
Further, the storage device 302 functions as a storage unit 60 in FIG.
Further, in the storage device 302, the ROM stores a program such as a boot program. The RAM is used as a work area for the control circuit 301. The HD stores programs such as an OS, an application program, and firmware, and various data.

The reading device 303 is controlled by the control circuit 301 to read / write data on the detachable recording medium 304. The reading device 303 includes, for example, FDD (Floppy Disk Drive), CDD (Compact Disc Drive), DVDD (Digital Versatile Disk Drive), BDD (Blu-ray (registered trademark) Disk Drive), and USB (Universal Serial Bus). And so on.

The recording medium 304 stores various data. Then, the recording medium 304 is connected to the bus 310 via the reading device 303, and the control circuit 301 controls the reading device 303 to read / write data.
The recording medium 304 may record a program that causes the control circuit 301 to function as the control units 10, 30, and 50.
The recording medium 304 is, for example, a non-temporary recording medium such as an FD (Floppy Disk), a CD (Compact Disc), a DVD (Digital Versatile Disk), a BD (Blu-ray (registered trademark) Disk), and a flash memory. Is.

The communication interface 305 connects the computer device 300 and other devices in a communicable manner via the network 309.
The communication interface 305 functions as a receiving unit 11 and a transmitting unit 16 in FIG.
Further, the communication interface 305 functions as a receiving unit 31, a transmitting unit 33, a connecting unit 34, and an acquiring unit 35 in FIG.
Further, the communication interface 305 functions as a connection unit 51, a reception unit 53, a transmission unit 54, an acquisition unit 56, and a presentation unit 59 in FIG.

The input / output interface 306 is connected to an input device 307 such as a keyboard, a mouse, a touch panel, and a scanner, and when a signal indicating various information is input from the connected device, the signal input via the bus 310. Is output to the control circuit 301. Further, when signals indicating various information output from the control circuit 301 are input via the bus 310, the input / output interface 306 outputs the signals input to the various connected devices.

The display device 308 displays various information based on the signal input from the control unit 30. Further, the display device 308 is, for example, a CRT (Cathode Ray Tube), an LCD (Liquid Crystal Display), a PDP (Plasma Display Panel), an OELD (Organic Electroluminescence Display), or the like.
Then, the display device 308 functions as the display device 8 in FIG.
The network 309 is, for example, a LAN, wireless communication, the Internet, or the like, and communicates and connects the computer device 300 with another device.
The present embodiment is not limited to the embodiments described above, and various configurations or embodiments can be taken within a range that does not deviate from the gist of the present embodiment.

1 Server device, 2 Client device, 3 Mining device, 4 Trading device, 8 Display device, 10 Control unit, 11 Reception unit, 12 Verification unit, 13 Search unit, 14 Generation unit, 15 Judgment unit, 16 Transmission unit, 20 Memory Unit, 21 blockchain, 22 unapproved information, 23 computing power information, 30 control unit, 31 receiver unit, 32 search unit, 33 transmitter unit, 34 connection unit, 35 acquisition unit, 40 storage unit, 50 control unit, 51 connection unit. Unit, 52 distribution unit, 53 receiver, 54 transmitter, 55 judgment unit, 56 acquisition unit, 57 setting unit, 58 distribution unit, 59 presentation unit, 60 storage unit, 61 target value setting unit, 62 fee setting unit, 63 Providing rate calculation unit, 100 network structure, 150 network, 160 network, 200 graph, 201 mouse cursor, 300 computer device, 301 control circuit, 302 storage device, 302 control circuit, 303 reading device, 304 recording medium, 305 communication interface , 306 I / O interface, 307 input device, 308 display device, 309 network, 310 bus

Claims (9)

By applying a hash function to the input value including the nonce while changing the nonce, a hash value having a value smaller than the search threshold can be obtained. The mining device for searching for the correct nonce is correct with the value included in the input value. A transmitter that transmits a search request requesting a search for a nonce, and when the correct nonce is obtained, transmits a block containing the correct nonce and data to the blockchain network.
A receiver that receives the correct nonce searched in response to the search request from the mining device, and
A setting unit that sets a fee according to the ratio of the first processing capacity of one or more mining devices to which the search request is transmitted and the second processing capacity of the network.
The acquisition department that acquires the above fee from the first reward obtained by mining,
A distribution unit that distributes the second reward, which is obtained by subtracting the fee from the first reward, to one or more of the mining devices.
A server device characterized by comprising. The setting unit
The server device according to claim 1, wherein the fee is set higher as the ratio of the first processing capacity to the second processing capacity increases. The setting unit
A claim characterized in that the average value of a predetermined period is obtained for the difference between the target value and the actual value of the ratio of the first processing capacity to the second processing capacity, and the fee is set according to the average value. Item 2. The server device according to item 1 or 2. The setting unit
Regarding the difference between the target value and the actual value of the ratio of the first processing capacity to the second processing capacity, the average value of a predetermined period in which the weight is strengthened as the time approaches the current time is obtained, and the fee is calculated according to the average value. The server device according to claim 1 or 2, wherein the server device is set. The setting unit
Claims 1 to 4 characterized in that the first processing capacity is obtained by using the data corresponding to the processing capacity of the mining device submitted from one or more of the mining devices to which the search request is transmitted. The server device according to any one of. The receiver further
Receive a block containing the correct nonce from the network and
The transmitter
When the receiving unit receives the block containing the correct nonce from one or more mining devices to which the search request is transmitted before receiving the block containing the correct nonce from the network, the correct nonce and the block are received. A block containing the data is transmitted to the network,
The setting unit
The first processing capacity is obtained from the ratio of the block transmitted from the transmission unit and recorded on the blockchain to all the blocks recorded on the blockchain at predetermined intervals. The server device according to any one of claims 1 to 5. In response to a request from an external device, the information related to the fee set by the setting unit is obtained from the first processing capacity, the second processing capacity, and the ratio when the setting unit sets the fee. Further includes a presentation unit to be presented to the external device together with at least one piece of information.
The server device according to any one of claims 1 to 6, characterized in that. It is a fee setting method executed by the server device.
By applying a hash function to the input value including the nonce while changing the nonce, a hash value having a value smaller than the search threshold can be obtained. The mining device for searching for the correct nonce is correct with the value included in the input value. Send a search request requesting a nonce search and
The correct nonce searched in response to the search request is received from the mining device, and the search is received.
Send a block containing the correct nonce and data to the blockchain network and
A fee is set according to the ratio of the first processing capacity of one or more mining devices to which the search request is transmitted and the second processing capacity of the network.
Obtain the above fee from the first reward obtained by mining,
A fee setting method characterized in that a second reward obtained by subtracting the fee from the first reward is distributed to one or more of the mining devices. By applying a hash function to the input value including the nonce while changing the nonce, a hash value having a value smaller than the search threshold can be obtained. The mining device for searching for the correct nonce is correct with the value included in the input value. Send a search request requesting a nonce search and
The correct nonce searched in response to the search request is received from the mining device, and the search is received.
Send a block containing the correct nonce and data to the blockchain network and
A fee is set according to the ratio of the first processing capacity of one or more mining devices to which the search request is transmitted and the second processing capacity of the network.
Obtain the above fee from the first reward obtained by mining,
A program characterized in that a processor executes a process of distributing a second reward obtained by subtracting the fee from the first reward to one or more of the mining devices.

Images