CN114500358A

CN114500358A - Gateway message distribution method, device, equipment and storage medium

Info

Publication number: CN114500358A
Application number: CN202210134876.XA
Authority: CN
Inventors: 覃德
Original assignee: Weikun Shanghai Technology Service Co Ltd
Current assignee: Tibet Chuanghuang Information Technology Co ltd
Priority date: 2022-02-14
Filing date: 2022-02-14
Publication date: 2022-05-13
Anticipated expiration: 2042-02-14
Also published as: CN114500358B

Abstract

The application relates to the technical field of artificial intelligence, and discloses a gateway message distribution method, a device, equipment and a storage medium, wherein the method comprises the following steps: acquiring a corresponding target system and a corresponding service type according to the service request instruction; generating message information carrying a first identifier and an analysis model according to a preset message rule; acquiring each communication path between the gateway and a target gateway; calculating transmission state parameters of the message channel until the transmission state parameters of at least one communication path meet a first threshold range; taking a communication path with the transmission state parameter meeting a first threshold range as a target path; and placing the message information and the analysis model in a sending queue of a message channel so that the target gateway analyzes the message information according to the received analysis model and sends the analyzed message information to a corresponding functional module of a target system according to the first identifier, thereby improving the distribution efficiency of the gateway message.

Description

Gateway message distribution method, device, equipment and storage medium

Technical Field

The present application relates to the field of artificial intelligence technologies, and in particular, to a method, an apparatus, a device, and a storage medium for distributing a gateway packet.

Background

With the development of online payment technology, many companies adopt independent internal system architectures of their own companies when docking banks and the like to enter a platform, so that different companies can generate a respective set of gateway message distribution methods based on their own internal system architectures. However, the multiplexing degree is not high, some service systems are directly connected with the channel Gateway system in an abutting mode, so that the service systems are required to be adapted to different channel request parameters, a unified common standard for abutting connection Gateway messages does not exist, and finally the access cost is gradually increased; but also cannot provide code technology output externally.

Disclosure of Invention

The present application mainly aims to provide a method, an apparatus, a device and a storage medium for distributing a gateway packet, and aims to solve the problem of low efficiency in distributing the gateway packet in the prior art.

In order to achieve the above object, the present application provides a method for distributing a gateway packet, where the method includes:

receiving a service request instruction sent by a service system through a first receiving interface, and acquiring a corresponding target system and a corresponding service type according to the service request instruction;

generating a corresponding first identifier according to the service type, generating message information carrying the first identifier according to a preset message rule, and generating an analysis model of the message information;

broadcasting a communication request to a target gateway of the target system, and acquiring each communication path between the target system and the target gateway after receiving a connection signal returned by the target gateway;

acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence according to the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range;

taking the communication path of which the transmission state parameter satisfies the first threshold range as a target path;

establishing a message channel according to the target path, and placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sends the analyzed message information to a corresponding functional module of the target system according to the first identifier.

Further, the method for calculating the current load value includes:

in a first time period, acquiring first load values of a plurality of communication paths according to a preset time interval;

performing normal distribution calculation on the first load value, filtering abnormal load values in the first load value, and taking the filtered first load value as a second load value;

and carrying out weighted correction on the second load value to obtain the current load value.

Further, the calculating the transmission state parameter of the packet channel according to the bandwidth and the current load value includes:

setting a first weighting coefficient corresponding to the bandwidth and a second weighting coefficient corresponding to the current load value;

and carrying out weighting calculation on the bandwidth according to the first weighting coefficient and the second weighting coefficient to obtain the transmission state parameter.

Further, after broadcasting the communication request to the target gateway of the target system, the method further includes:

timing a first waiting time;

if the first waiting time exceeds the preset overtime, the connection signal is not received, a communication re-request is broadcasted to a target gateway of the target system, and a second waiting time technology is carried out;

and if the second waiting time exceeds the overtime, the connection signal is not received, and a target error signal is returned to the service system, so that the service system resends the service request instruction until the connection signal is received.

Further, the broadcasting a communication request to a target gateway of the target system includes:

performing signal analysis on the connection signal to obtain the identity information of the target system carried in the connection signal;

and checking whether the identity information is consistent with the request object information carried in the communication request, if so, acquiring each communication path between the identity information and the target gateway, and if not, rebroadcasting the communication request.

Further, before establishing the message channel according to the target path, the method includes:

encrypting the message information and the analysis model according to an encryption key to obtain a first ciphertext;

the step of placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model comprises the following steps:

sending a decryption key corresponding to the encryption key to the target gateway so that the target gateway returns a signal of successful reception;

and after receiving the successful receiving signal, placing the first ciphertext into a sending queue of the message channel, so that the target gateway decrypts the first ciphertext according to the received decryption key to obtain the message information and the analysis model.

Further, before the communication path whose transmission state parameter satisfies the first threshold range is taken as a target path, the method further includes:

when the transmission state parameter of the communication path does not meet the first threshold range, a path busy signal is sent to a user;

and receiving a path selection signal returned by the user according to the path busy signal, and taking a communication path corresponding to the path selection signal as the target path.

The application further provides a gateway message distribution device, including:

the service acquisition module is used for receiving a service request instruction sent by a service system through a first receiving interface and acquiring a corresponding target system and a corresponding service type according to the service request instruction;

the analysis model generation module is used for generating a corresponding first identifier according to the service type, generating message information carrying the first identifier according to a preset message rule, and generating an analysis model of the message information;

the communication path acquisition module is used for broadcasting a communication request to a target gateway of the target system and acquiring each communication path between the communication path acquisition module and the target gateway after receiving a connection signal returned by the target gateway;

the path state calculation module is used for acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence and the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range;

a target path selection module, configured to use the communication path for which the transmission state parameter satisfies the first threshold range as a target path;

and the message information sending module is used for establishing a message channel according to the target path, placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sending the analyzed message information to a corresponding function module of the target system according to the first identifier.

The present application further proposes a computer device comprising a memory and a processor, the memory storing a computer program, the processor implementing the steps of any of the above methods when executing the computer program.

The present application also proposes a computer-readable storage medium having stored thereon a computer program which, when being executed by a processor, carries out the steps of the method of any of the above.

According to the gateway message distribution method, the device, the equipment and the storage medium, the service request instructions of different service systems are uniformly received through the first receiving interface, and the corresponding target systems and service types are identified through the service request instructions, so that the problem that the service systems need to be adapted to channel gateways of each target system is solved, the complexity of the service systems is simplified, the uniformity and the distribution efficiency of message distribution are improved, and system modularization and system transplantation are facilitated; the message information is generated through a set of preset general message rules, so that the embodiment can output the messages to the outside independently without setting different message rules for each channel; after a target system corresponding to the service request instruction is obtained, a communication request can be initiated to a target gateway of the target system, so that the target gateway returns a connection signal after receiving the broadcasted communication request, wherein the connection signal comprises the address or domain name information of the target gateway, all possible communication paths directly connected with the target gateway are obtained, and the flexibility of message transmission is improved; the current congestion state of each communication path is obtained by obtaining the path length, the bandwidth and the current load value of each communication path and calculating the transmission state parameters, so that a better communication path is selected for message distribution; according to the sequence of the path lengths from short to long, the transmission state parameters of the message channel are calculated according to the bandwidth and the current load value in sequence, once a communication path is calculated to meet a first threshold range, the path can be judged to be the path with the shortest length in all smooth paths, so that the calculation amount of the transmission state parameters is reduced, the calculation resources and the calculation time are saved, and the distribution efficiency is improved.

Drawings

Fig. 1 is a schematic flowchart of a gateway message distribution method according to an embodiment of the present application;

fig. 2 is a schematic block diagram of a gateway message distribution apparatus according to an embodiment of the present application;

fig. 3 is a block diagram illustrating a structure of a computer device according to an embodiment of the present application.

The implementation, functional features and advantages of the objectives of the present application will be further explained with reference to the accompanying drawings.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

Referring to fig. 1, in order to achieve the above object of the present invention, the present application provides a gateway packet distribution method, where the method includes:

s1: receiving a service request instruction sent by a service system through a first receiving interface, and acquiring a corresponding target system and a corresponding service type according to the service request instruction;

s2: generating a corresponding first identifier according to the service type, generating message information carrying the first identifier according to a preset message rule, and generating an analysis model of the message information;

s3: broadcasting a communication request to a target gateway of the target system, and acquiring each communication path between the target system and the target gateway after receiving a connection signal returned by the target gateway;

s4: acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence and the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range;

s5: taking the communication path of which the transmission state parameter satisfies the first threshold range as a target path;

s6: establishing a message channel according to the target path, and placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sends the analyzed message information to a corresponding functional module of the target system according to the first identifier.

In the embodiment, the first receiving interface is used for receiving service request instructions of different service systems in a unified manner, and the corresponding target systems and service types are identified through the service request instructions, so that the problem that the service systems need to be adapted to the channel gateway of each target system is solved, the complexity of the service systems is simplified, the uniformity and the distribution efficiency of message distribution are improved, and system modularization and system transplantation are facilitated; the message information is generated through a set of preset general message rules, so that the embodiment can output the messages to the outside independently without setting different message rules for each channel; after a target system corresponding to the service request instruction is obtained, a communication request can be initiated to a target gateway of the target system, so that the target gateway returns a connection signal after receiving the broadcasted communication request, wherein the connection signal comprises the address or domain name information of the target gateway, all possible communication paths directly connected with the target gateway are obtained, and the flexibility of message transmission is improved; the current congestion state of each communication path is obtained by obtaining the path length, the bandwidth and the current load value of each communication path and calculating the transmission state parameters, so that a better communication path is selected for message distribution; according to the sequence of the path lengths from short to long, the transmission state parameters of the message channel are calculated according to the bandwidth and the current load value in sequence, once a communication path is calculated to meet a first threshold range, the path can be judged to be the path with the shortest length in all smooth paths, so that the calculation amount of the transmission state parameters is reduced, the calculation resources and the calculation time are saved, and the distribution efficiency is improved.

For step S1, in the gateway message distribution of this embodiment, especially in the gateway message distribution process of the payment channel, the service request instruction reception, the target path selection, and the message distribution may be performed based on the artificial intelligence technology. Among them, Artificial Intelligence (AI) is a theory, method, technique and application system that simulates, extends and expands human Intelligence using a digital computer or a machine controlled by a digital computer, senses the environment, acquires knowledge and uses the knowledge to obtain the best result. Since the gateway message distribution in the prior art is usually performed by the service system, which results in that the service system needs to adapt to different channel parameter requests, the gateway message distribution method provided in this embodiment uniformly receives service request instructions, such as payment instructions, cash withdrawal instructions, and the like, of the service system through the first receiving interface, that is, the service system directly outputs the service request instructions, and does not need to modify the service system to adapt to different channel gateways. Specifically, the service request instruction carries an identifier of a service channel and a service type, so that the target system and the service type corresponding to the service request instruction are identified by the identifier in this embodiment, the target system may be a payment platform such as a business bank, an agricultural bank, a chinese bank, a secure payment, and the like, and the service type may be a recharge, a cash withdrawal, a transfer, and the like. The method and the device receive the service request commands of different service systems in a unified mode through the first receiving interface, and identify the corresponding target systems and service types through the service request commands, so that the problem that the service systems need to be adapted to channel gateways of each target system is solved, the complexity of the service systems is simplified, and the uniformity and the distribution efficiency of message distribution are improved.

For step S2, the message information is generated by a set of preset general message rules, so that the present embodiment can separately output a message to the outside, and it is not necessary to set different message rules for each channel. Illustratively, the target gateway message general Json format specification may be adopted: defining the first identifier as a businessType field, wherein the businessType field is used for marking the service types needing to be called, such as transfer, withdrawal and the like, and which service interface of the target system is butted can be known through the businessType field; the target system is defined as a paymentChannel field, which bank or payment company channel is connected can be known through the paymentChannel field, and therefore message information is accurately distributed to the corresponding target gateway; the channel request parameter Gson character string of the target system is defined as a dataStr field, the dataStr field is an abstract channel request parameter, the concrete meaning is analyzed in the target gateway of each target system through an analysis model, decoupling of service data and different channel request parameters is achieved, and universality and application range of the method are improved.

For step S3, after the target system corresponding to the service request instruction is obtained, a communication request may be initiated to the target gateway of the target system, so that the target gateway returns a connection signal after receiving the broadcasted communication request, where the connection signal includes address or domain name information of the target gateway, thereby obtaining all possible communication paths directly with the target gateway, and improving flexibility of message transmission.

For step S4, since some transmission paths may pass through network nodes such as a workstation and a server during data transmission, in order to facilitate comparison of the current quality of each communication path, the present application obtains the path length, bandwidth and current load value of each feasible communication path, and sorts the path lengths in order from short to long; generally speaking, the shorter the path length is under the same other conditions, the shorter the time for transmitting to the target gateway is, however, in the actual communication process, the shorter communication path may enter a congestion state because the current transmission load is too large, and therefore, it is necessary to calculate a transmission state parameter of the communication path in combination with the bandwidth and the current load value of the communication path, and if the parameter does not meet the preset threshold range, the communication path is congested, and the data transmission is currently not suitable; if the parameter meets the preset threshold range, the communication path is smooth, and the current communication path is suitable for data transmission. According to the method and the device, the path length, the bandwidth and the current load value of each communication path are obtained, and the transmission state parameters are calculated, so that the current congestion state of each communication path is obtained, and a better communication path is selected for message distribution.

For step S5, if each message distribution requires transmission state parameter calculation for each communication path, transmission efficiency is also reduced, and therefore, according to the order of path length from short to long, the transmission state parameters of the message channel are calculated in sequence according to the bandwidth and the current load value, and once a communication path is calculated to satisfy the first threshold range, it can be determined that the path is the shortest among all unobstructed paths. Illustratively, if paths L1, L2, and L3 exist, the corresponding path lengths are L1, L2, and L3, and L1 < L2 < L3, in the calculation process, the transmission state parameter of the path L1 is preferentially calculated, if the first threshold range is not satisfied, the transmission state parameter of the path L2 is calculated, and if the first threshold range is satisfied, the transmission state parameter of the path L3 is no longer calculated with L2 as the target path, so that the calculation amount of the transmission state parameter is reduced, the calculation resources and the calculation time are saved, and the distribution efficiency is improved.

For step S6, after the optimal communication path is obtained by calculation, the communication path is used as the target path, so that the target path is used as a message channel, thereby avoiding the problem of reduction in transmission efficiency due to path congestion; after a message channel is established, message information and a corresponding analysis model are placed in a sending queue, after a target gateway of a target system receives the analysis model, a request parameter Gson character string in the message information is analyzed according to the analysis model to obtain an analysis result, and the message information is sent to a corresponding functional module according to a first identifier; illustratively, if the first identifier corresponds to the transfer service, sending an analysis result obtained after analysis to a transfer service module of the target system so as to facilitate the target system to respond to the transfer function. The message information and the analysis model are sent to the target gateway together, so that technical output can be provided separately and externally; the external companies can be quickly docked according to the general message specification.

In one embodiment, the method for calculating the current load value includes:

s41: in a first time period, acquiring first load values of a plurality of communication paths according to a preset time interval;

s42: performing normal distribution calculation on the first load value, filtering abnormal load values in the first load value, and taking the filtered first load value as a second load value;

s43: and carrying out weighted correction on the second load value to obtain the current load value.

In this embodiment, the load value is corrected, so that a problem that a deviation of the load value acquired at a certain time is large due to network fluctuation and the like in the process of acquiring the load value of the communication path is avoided.

As for step S42, in the acquisition of the load values of the communication path, there is inevitably a problem that the deviation of the load values acquired at a certain time is large due to network fluctuations and the like, and to solve the above problem, in the present embodiment, in the first period T1, the first load values are sequentially acquired n times at preset intervals T1, so that the large deviation value of the first load values is excluded by using the normal distribution calculation method, specifically, according to the definition of the normal distribution, the probability that the load values fall within plus or minus 1 time of the standard deviation from the mean is 68.2%, the probability that the load values fall within plus or minus 2 times of the standard deviation from the mean is 95.4%, and the probability that the load values fall within plus or minus 3 times of the standard deviation from the mean is 99.6%, and therefore, the values that fall within plus or minus 2 times of the standard deviation from the mean and within 3 times of the standard deviation from the mean in the first load values can be regarded as abnormal load values, and filtering the abnormal load values, and taking the rest first load values as a plurality of second load values again.

For step S43, after filtering the abnormal load values, it is understood that if the average of the second load values is directly calculated and the average is taken as the current load value, it means that the contribution of the second load value to the current load value at each time is consistent, however, in the actual communication path, the influence ratio of the second load value closer to the current time in the acquisition time to the current load value is larger, and therefore, the weight of each second load value may be set incrementally according to the acquisition time, and for example, when three second load values are included, the weight may be corrected to a ratio of 5%, 20%, and 75%.

In one embodiment, the calculating the transmission state parameter of the packet channel according to the bandwidth and the current load value includes:

s44: setting a first weighting coefficient corresponding to the bandwidth and a second weighting coefficient corresponding to the current load value;

s45: and carrying out weighting calculation on the bandwidth according to the first weighting coefficient and the second weighting coefficient to obtain the transmission state parameter.

In this embodiment, the transmission state parameter is obtained by setting a weighting coefficient and performing weighting calculation on the bandwidth according to the first weighting coefficient and the second weighting coefficient, so as to realize quantization of the communication path state.

For step S45, when other variables are unchanged during the communication process, the larger the bandwidth is, the higher the transmission efficiency of the data is; the smaller the current load value of a certain communication path is, the greater the transmission efficiency of data is, however, in actual communication, if the current load value of a communication path with a large bandwidth is larger, the transmission efficiency may be lower than that of a communication path with a small bandwidth; therefore, in order to quantize the transmission status parameter, the present embodiment sets weighting coefficients for the bandwidth and the current load value, respectively, so as to more comprehensively reflect the influence of the bandwidth and the current load value on the transmission status parameter. Since the bandwidth size is positively correlated with the transmission efficiency and the current load value is negatively correlated with the transmission efficiency, the first weighting factor and the second weighting factor may be set to have opposite signs, for example, the first weighting factor may be 70% and the second weighting factor may be-30%.

In one embodiment, after broadcasting the communication request to the target gateway of the target system, the method further includes:

s31: timing a first waiting time;

s32: if the first waiting time exceeds the preset overtime, the connection signal is not received, a communication re-request is broadcasted to a target gateway of the target system, and a second waiting time technology is carried out;

s33: and if the second waiting time exceeds the overtime, the connection signal is not received, and a target error signal is returned to the service system, so that the service system resends the service request instruction until the connection signal is received.

By timing the waiting time, the embodiment determines whether the reason why the corresponding target system cannot be queried is a network problem or an instruction abnormity problem, so that a correct service request is initiated, and the service request efficiency and stability are improved.

For step S32, since the corresponding target system is obtained according to the service request instruction in this embodiment, if the service request instruction sent by the service system is incorrect, the corresponding target system cannot be queried. In actual communication, in order to eliminate the influence of the communication network, after one broadcast, a certain time is waited for, and if connection information is not received within the time, a request is initiated again.

In step S33, if the connection signal is still not received within the timeout period, it is determined that the service request command is abnormal, and at this time, a target error signal is sent to the service system, so that the service system automatically or a manager of the service system manually regenerates and sends the corresponding service request command.

In one embodiment, the broadcasting a communication request to a target gateway of the target system includes:

s34: performing signal analysis on the connection signal to obtain the identity information of the target system carried in the connection signal;

s35: and checking whether the identity information is consistent with the request object information carried in the communication request, if so, acquiring each communication path between the identity information and the target gateway, and if not, rebroadcasting the communication request.

In this embodiment, the connection signal is subjected to signal analysis to obtain the identity information of the target system carried in the connection signal, and the identity information is verified, so that the problem of establishing communication connection with a wrong target gateway is avoided.

For step S34, in order to avoid the problem of establishing a communication connection with the wrong target gateway, this embodiment adopts an authentication form, and analyzes the connection signal returned by the target system to obtain the identity information thereof.

For step S35, if the identity information is consistent with the request object, the target system returning the connection signal may be considered to be correct, and at this time, each feasible communication path of the target gateway of the target system may be acquired, so as to find a suitable communication path, handshake, and establish a communication connection. If the identity information does not match the request object, the communication request is rebroadcast to facilitate connection to the correct target system.

In an embodiment, before the establishing a packet channel according to the target path, the method further includes:

s601: encrypting the message information and the analysis model according to an encryption key to obtain a first ciphertext;

s61: sending a decryption key corresponding to the encryption key to the target gateway so that the target gateway returns a signal of successful reception;

s62: and after receiving the successful receiving signal, placing the first ciphertext into a sending queue of the message channel, so that the target gateway decrypts the first ciphertext according to the received decryption key to obtain the message information and the analysis model.

According to the embodiment, the data to be sent is encrypted through the encryption key, so that the safety of the communication process is improved, and the economic loss of a client and a payment platform caused by malicious interception or tampering of message information by people is avoided.

For step S61, in this embodiment, before sending the message information, the message information and the parsing model are encrypted, and the decryption key and the first ciphertext are sent separately, so that even if one of the messages is intercepted maliciously, the message content cannot be tampered with. And after the target gateway receives the decryption key, sending the encrypted first ciphertext to the target gateway so that the target gateway analyzes to obtain the original message information and an analysis model. In addition, the message information and the parsing model are encrypted together to obtain a first ciphertext of a whole packet, so that the problem that one data packet may be lost due to network fluctuation when the message information and the parsing model are sent separately can be avoided, namely, the problem that no parsing model can be used for data parsing after the message information is received by the target gateway is avoided, the problem that no message can be parsed after the parsing model is received by the target gateway is avoided, and the stability of data transmission is improved.

In one embodiment, before the communication path whose transmission state parameter satisfies the first threshold range is taken as a target path, the method further includes:

s501: when the transmission state parameter of the communication path does not meet the first threshold range, a path busy signal is sent to a user;

s502: and receiving a path selection signal returned by the user according to the path busy signal, and taking a communication path corresponding to the path selection signal as the target path.

According to the embodiment, the target path is selected by sending the path busy signal to the user and according to the path busy signal, so that the problem that the selection efficiency of the target path is low due to the fact that the path is busy is avoided.

For step S501, in a specific implementation, if the time period is busy, a situation that each communication path does not satisfy the transmission state parameter may occur, and if the calculation is performed in a loop until the transmission state parameter of at least one communication path satisfies the first threshold range, the problem that the transmission efficiency of the packet is reduced may be caused. Therefore, when the transmission state parameters of each communication path are identified to not meet the first threshold range, a path busy signal can be sent to the user, so that the user can actively select a message sending path.

For step S502, after receiving the path busy signal, the user may manually return a path selection signal, and at this time, the communication path selected by the user may be used as a target path for sending the packet according to the path selection signal.

Referring to fig. 2, the present application further provides a gateway packet distribution apparatus, including:

a service obtaining module 100, configured to receive a service request instruction sent by a service system through a first receiving interface, and obtain a corresponding target system and a corresponding service type according to the service request instruction;

the analysis model generation module 200 is configured to generate a corresponding first identifier according to the service type, generate, according to a preset packet rule, packet information carrying the first identifier, and generate an analysis model of the packet information;

a communication path obtaining module 300, configured to broadcast a communication request to a target gateway of the target system, and obtain each communication path between the target system and the target gateway after receiving a connection signal returned by the target gateway;

a path state calculation module 400, configured to obtain a path length, a bandwidth, and a current load value of each communication path, and calculate transmission state parameters of the packet channel according to the bandwidth and the current load value in sequence from short to long according to the path length until the transmission state parameters of at least one communication path meet a first threshold range;

a target path selecting module 500, configured to use the communication path whose transmission state parameter meets the first threshold range as a target path;

a message information sending module 600, configured to establish a message channel according to the target path, place the message information and the parsing model in a sending queue of the message channel, so that the target gateway parses the message information according to the received parsing model, and sends the parsed message information to a corresponding functional module of the target system according to the first identifier.

In one embodiment, the path state calculation module 400 is further configured to:

In one embodiment, the communication path obtaining module 300 is further configured to:

timing a first waiting time;

In an embodiment, the message information sending module 600 is further configured to:

In one embodiment, a manual selection module 700 is also included for:

Referring to fig. 3, a computer device, which may be a server and whose internal structure may be as shown in fig. 3, is also provided in the embodiment of the present application. The computer device includes a processor, a memory, a network interface, and a database connected by a system bus. Wherein the computer designed processor is used to provide computational and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The memory provides an environment for the operation of the operating system and the computer program in the non-volatile storage medium. The database of the computer device is used for storing data such as a gateway message distribution method and the like. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a gateway message distribution method. The gateway message distribution method comprises the following steps: receiving a service request instruction sent by a service system through a first receiving interface, and acquiring a corresponding target system and a corresponding service type according to the service request instruction; generating a corresponding first identifier according to the service type, generating message information carrying the first identifier according to a preset message rule, and generating an analysis model of the message information; broadcasting a communication request to a target gateway of the target system, and acquiring each communication path between the target system and the target gateway after receiving a connection signal returned by the target gateway; acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence and the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range; taking the communication path of which the transmission state parameter satisfies the first threshold range as a target path; establishing a message channel according to the target path, and placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sends the analyzed message information to a corresponding functional module of the target system according to the first identifier.

An embodiment of the present application further provides a computer-readable storage medium, on which a computer program is stored, where the computer program, when executed by a processor, implements a gateway message distribution method, including the steps of: receiving a service request instruction sent by a service system through a first receiving interface, and acquiring a corresponding target system and a corresponding service type according to the service request instruction; generating a corresponding first identifier according to the service type, generating message information carrying the first identifier according to a preset message rule, and generating an analysis model of the message information; broadcasting a communication request to a target gateway of the target system, and acquiring each communication path between the target system and the target gateway after receiving a connection signal returned by the target gateway; acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence and the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range; taking the communication path of which the transmission state parameter satisfies the first threshold range as a target path; establishing a message channel according to the target path, and placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sends the analyzed message information to a corresponding functional module of the target system according to the first identifier.

In the gateway message distribution method, the service request instructions of different service systems are uniformly received through the first receiving interface, and the corresponding target systems and service types are identified through the service request instructions, so that the problem that the service systems need to be adapted to the channel gateway of each target system is solved, the complexity of the service systems is simplified, the uniformity and the distribution efficiency of message distribution are improved, and system modularization and system transplantation are facilitated; the message information is generated through a set of preset general message rules, so that the embodiment can output the messages to the outside independently without setting different message rules for each channel; after a target system corresponding to the service request instruction is obtained, a communication request can be initiated to a target gateway of the target system, so that the target gateway returns a connection signal after receiving the broadcasted communication request, wherein the connection signal comprises the address or domain name information of the target gateway, all possible communication paths directly connected with the target gateway are obtained, and the flexibility of message transmission is improved; the current congestion state of each communication path is obtained by obtaining the path length, the bandwidth and the current load value of each communication path and calculating the transmission state parameters, so that a better communication path is selected for message distribution; according to the sequence of the path lengths from short to long, the transmission state parameters of the message channel are calculated according to the bandwidth and the current load value in sequence, once a communication path is calculated to meet a first threshold range, the path can be judged to be the path with the shortest length in all smooth paths, so that the calculation amount of the transmission state parameters is reduced, the calculation resources and the calculation time are saved, and the distribution efficiency is improved.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium provided herein and used in the examples may include non-volatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), double-rate SDRAM (SSRSDRAM), Enhanced SDRAM (ESDRAM), synchronous link (Synchlink) DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and bus dynamic RAM (RDRAM).

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, apparatus, article, or method that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, apparatus, article, or method. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, apparatus, article, or method that includes the element.

The above description is only a preferred embodiment of the present application, and not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application, or which are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims

1. A method for distributing gateway messages, the method comprising:

acquiring the path length, the bandwidth and the current load value of each communication path, and calculating the transmission state parameters of the message channel according to the path length from short to long in sequence and the bandwidth and the current load value until the transmission state parameters of at least one communication path meet a first threshold range;

establishing a message channel according to the target path, placing the message information and the analysis model in a sending queue of the message channel so that the target gateway analyzes the message information according to the received analysis model, and sending the analyzed message information to a corresponding functional module of the target system according to the first identification.

2. The gateway message distribution method according to claim 1, wherein the method for calculating the current load value comprises:

3. The method of claim 1, wherein the calculating the transmission state parameters of the packet channel according to the bandwidth and the current load value comprises:

4. The method for gateway message distribution according to claim 1, wherein after broadcasting the communication request to the target gateway of the target system, the method further comprises:

timing a first waiting time;

5. The gateway message distribution method of claim 1, wherein the broadcasting a communication request to a target gateway of the target system comprises:

6. The gateway message distribution method of claim 5, wherein before establishing the message channel according to the target path, the method further comprises:

7. The gateway packet distribution method according to claim 1, wherein before the communication path whose transmission state parameter satisfies the first threshold range is taken as a target path, the method further includes:

8. A gateway message distribution apparatus, comprising:

9. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor, when executing the computer program, implements the steps of the method of any of claims 1 to 7.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 7.