CN113765710A - Request processing system and method based on multi-active hybrid cloud deployment - Google Patents
Request processing system and method based on multi-active hybrid cloud deployment Download PDFInfo
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/06—Management of faults, events, alarms or notifications
- H04L41/0654—Management of faults, events, alarms or notifications using network fault recovery
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/01—Protocols
- H04L67/10—Protocols in which an application is distributed across nodes in the network
- H04L67/1001—Protocols in which an application is distributed across nodes in the network for accessing one among a plurality of replicated servers
- H04L67/1004—Server selection for load balancing
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/01—Protocols
- H04L67/10—Protocols in which an application is distributed across nodes in the network
- H04L67/1097—Protocols in which an application is distributed across nodes in the network for distributed storage of data in networks, e.g. transport arrangements for network file system [NFS], storage area networks [SAN] or network attached storage [NAS]
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L67/00—Network arrangements or protocols for supporting network services or applications
- H04L67/50—Network services
- H04L67/60—Scheduling or organising the servicing of application requests, e.g. requests for application data transmissions using the analysis and optimisation of the required network resources
Abstract
The invention relates to a request processing system and method based on multi-living hybrid cloud deployment, which comprises a client, a cloud analysis server, a private cloud component and a hosting gateway component, wherein the private cloud component comprises a private cloud gateway cluster and a private cloud computing module, the private cloud gateway cluster comprises a plurality of private cloud gateways, the hosting gateway component comprises a plurality of hosting gateway clusters, each hosting gateway cluster comprises a plurality of hosting gateways, and the method is based on the system. Compared with the prior art, the method has the advantages of high reliability, reduction of the fault influence of a single node, reduction of enterprise cost and the like.
Description
Technical Field
The invention relates to the field of cloud computing, in particular to a request processing system and method based on multi-active hybrid cloud deployment.
Background
With the rapid development of internet services, from the original hundreds of megabytes to gigabit networks, gigabit networks to tens of millions of gigabit networks still cannot meet the service requirements, and meanwhile, the service continuity requirement is higher and higher, and a single network inlet cannot meet the service requirements. There are two main technical schemes: one is to build a same-city double-activity data center, meet the requirements of business through the data center construction, conspire the layout for realizing the strategic objective of enterprises, but this needs to invest more equipment resources, internet bandwidth resources and the like to build the relevant centers, and needs to provide larger bandwidth for meeting the continuity requirements of business 7 × 24, which undoubtedly will further increase the private cloud construction and maintenance cost; the other method is to directly deploy the production environment to the public cloud, but the resources of the private cloud part are difficult to play, waste exists, and the data is deployed to the public cloud, so that the safety problem also exists.
Disclosure of Invention
The present invention is directed to overcome the above-mentioned drawbacks of the prior art, and to provide a request processing system and method based on multi-active hybrid cloud deployment.
The purpose of the invention can be realized by the following technical scheme:
a request processing system based on multi-living hybrid cloud deployment comprises a client, a cloud resolution server, a private cloud component and a managed gateway component, wherein the private cloud component comprises a private cloud gateway cluster and a private cloud computing module, the private cloud gateway cluster comprises a plurality of private cloud gateways, the managed gateway component comprises a plurality of managed gateway clusters, each managed gateway cluster comprises a plurality of managed gateways,
the cloud analysis server is used for acquiring and analyzing a user request of the client, and distributing a gateway cluster of the user request according to the state of the gateway;
the client is used for sending an analysis request to the cloud analysis server, acquiring an internet entrance of a corresponding gateway and sending a user request to the private cloud computing module through the corresponding gateway for processing;
the private cloud gateway and the hosting gateway component are used for acquiring a user request from a client and sending the user request to corresponding computing resources in the private cloud computing module;
the private cloud computing module is used for processing the user request.
Preferably, the hosted gateway component includes two hosted gateway clusters.
Preferably, the hosting gateway cluster is connected with the private cloud computing module through a dedicated cloud line.
Preferably, the private cloud line is formed by two private cloud lines of operators to share BGP load, and when one private cloud line of an operator fails, the private cloud line of the operator is automatically switched to the private cloud line of another operator.
A request processing method based on multi-active hybrid cloud deployment is based on the request processing system based on multi-active hybrid cloud deployment, and comprises the following steps:
s1: the client sends a user request to the cloud analysis server;
s2: the cloud analysis server acquires states of the private cloud gateway cluster and the gateway cluster in the hosting gateway component, and allocates a gateway cluster corresponding to the user request according to the states of the gateways;
s3: sending the user request to a private cloud computing module through a corresponding gateway cluster;
s4: and the private cloud computing module processes the user request.
Preferably, step S2 specifically includes:
s21: acquiring a gateway cluster fault type, if the gateway cluster has no fault, entering a step S22, if the fault type is a partial gateway fault, entering a step S23, if the fault is the gateway cluster fault, entering a step S24, and if the fault is a cloud private line fault, entering a step S25;
s22: distributing a corresponding gateway cluster for a user request according to a first preset proportion;
s23: confirming the gateway cluster with the fault, reducing the distribution proportion of the gateway cluster with the fault, improving the distribution proportion of the gateway cluster without the fault, and distributing the corresponding gateway cluster for the user request according to the adjusted proportion;
s24: confirming the gateway cluster with the fault, and distributing the user request to the gateway cluster without the fault;
s25: and confirming the failed hosting gateway cluster, and connecting the failed hosting gateway cluster with the private cloud computing module through the cloud special line of the non-failed hosting gateway cluster.
Preferably, the gateway cluster failures include gateway cluster entry failures and gateway cluster all-gateway failures.
Preferably, in step S24, the user request is equally distributed to the non-failed gateway cluster.
Preferably, the first preset proportion is a proportion for equally distributing the user request to each gateway cluster.
Preferably, the step S3 specifically includes acquiring a user request type, and forwarding the user request to the corresponding computing resource in the private cloud computing module according to the user request type.
Compared with the prior art, the invention has the following advantages:
(1) the request processing system disclosed by the invention has the advantages that the additional hosting gateway cluster is arranged to access the user request, and the hosting gateway and the private cloud gateway cluster are effectively combined, so that the original environment resources of the private cloud can be fully utilized, various scenes such as service increase, elastic bandwidth expansion, reduction of single node fault influence and the like can be dynamically met, and the enterprise cost is effectively reduced;
(2) the request processing method can distribute the gateways according to the working state of the gateway cluster in real time, automatically isolate fault points and automatically recover the use, reduce manual intervention, ensure the integral continuity of user requests and provide uninterrupted user request processing service;
(3) the invention can effectively process different possible fault conditions, improve the adaptability and reliability of the system and ensure the processing effect on the user request;
(4) the hosting gateway cluster is connected with the private cloud computing module through the cloud private line, so that the data transmission effect is improved, load sharing of the cloud private line BGP of the double operators is adopted, the condition that a user request cannot be transmitted due to single private line fault is avoided, and the reliability is high.
Drawings
FIG. 1 is a schematic diagram of a request processing system according to the present invention;
FIG. 2 is a flow chart of a request processing method of the present invention.
The cloud analysis system comprises a client 1, a cloud analysis server 2, a private cloud component 3, a hosting gateway component 4, a hosting gateway component 5, a private cloud gateway cluster 6, a private cloud computing module 7, a hosting gateway cluster 8, an office area computing resource module 9, a production area computing resource module 10 and a cloud private line.
Detailed Description
The invention is described in detail below with reference to the figures and specific embodiments. Note that the following description of the embodiments is merely a substantial example, and the present invention is not intended to be limited to the application or the use thereof, and is not limited to the following embodiments.
Examples
A request processing system based on multi-active hybrid cloud deployment, as shown in fig. 1, includes a client 1, a cloud resolution server 2, a private cloud component 3, and a hosted gateway component 4, where the private cloud component 3 includes a private cloud gateway cluster 5 and a private cloud computing module 6, the private cloud gateway cluster 5 includes a plurality of private cloud gateways, the hosted gateway component 4 includes a plurality of hosted gateway clusters 7, and each hosted gateway cluster 7 includes a plurality of hosted gateways.
Specifically, the functions of each part are as follows:
the cloud analysis server 2 is used for acquiring and analyzing the user request of the client 1, and distributing a gateway cluster of the user request according to the gateway state; the client 1 is used for sending an analysis request to the cloud analysis server 2, acquiring an internet entrance of a corresponding gateway, and sending a user request to the private cloud computing module 6 through the corresponding gateway for processing; the private cloud gateway and escrow gateway component 4 is used for acquiring a user request from the client 1 and sending the user request to a corresponding computing resource in the private cloud computing module 6; the private cloud computing module 6 is used for processing the user request. In this embodiment, the private cloud computing module 6 includes an office area computing resource module 8 and a production area computing resource module 9.
Based on the above parts, gateway allocation can be performed on the request sent by the client 1, and the user request is sent to the private cloud computing module 6 by using the allocated corresponding gateway for computing processing, so that the user request of the client 1 is completed.
The managed gateway cluster 7 is connected with the private cloud computing module 6 through the special cloud line 10, and the managed gateway component 4 and the private cloud computing module 6 are communicated through the special cloud line 10. In addition, in this embodiment, the dedicated cloud line 10 forms BGP load sharing for the dual-operator cloud line, and when one operator cloud line fails, the BGP load is automatically switched to another operator cloud line. In an extreme case, if two operator cloud private lines of the cloud private line 10 of one hosting gateway cluster 7 both fail, the cloud private line 10 of another hosting gateway cluster 7 in another place is switched to, and data transmission is performed through the cloud private lines 10 of the other hosting gateway clusters 7.
In this embodiment, the hosted gateway component 4 includes two hosted gateway clusters 7, and specifically, the hosted gateway component 4 adopts a financial cloud gateway form, which is a financial cloud AZ1 hosted gateway cluster 7 and a financial cloud AZ2 hosted gateway cluster 7.
A request processing method based on multi-active hybrid cloud deployment, based on the request processing system based on multi-active hybrid cloud deployment, as shown in fig. 2, includes the following steps:
s1: the client 1 sends a user request to the cloud resolution server 2.
S2: the cloud analysis server 2 acquires the states of the private cloud gateway cluster 5 and the gateway cluster in the hosting gateway component 4, and allocates a gateway cluster corresponding to the user request according to the states of the gateways.
Step S2 specifically includes:
s21: acquiring a gateway cluster fault type, if the gateway cluster has no fault, entering step S22, if the fault type is a partial gateway fault, entering step S23, if the fault is a gateway cluster fault, entering step S24, and if the fault is a cloud dedicated line 10 fault, entering step S25. Specifically, the gateway cluster failure includes a gateway cluster entry failure and a gateway cluster all-gateway failure.
S22: and distributing the corresponding gateway cluster for the user request according to a first preset proportion. In this embodiment, the first preset proportion is a proportion that the user request is evenly distributed to each gateway cluster.
Specifically, in this embodiment, if the gateway cluster does not have a fault, the cloud analysis server 2 returns the internet entries of the financial cloud AZ1 hosting gateway cluster 7, the financial cloud AZ2 hosting gateway cluster 7, and the private cloud gateway cluster 5, and the internet entries are calculated according to the following formula 1: 1: 1 proportion is automatically allocated, and the financial cloud AZ1 hosts the total traffic of the gateway cluster 7, the financial cloud AZ2 hosts the gateway cluster 7, and the private cloud gateway cluster 5 each bear 1/3.
S23: and confirming the gateway cluster with the fault, reducing the distribution proportion of the gateway cluster with the fault, improving the distribution proportion of the gateway cluster without the fault, and distributing the corresponding gateway cluster for the user request according to the adjusted proportion.
And the partial gateway faults are faults of partial gateways in a certain gateway cluster, and according to the proportion of the faulted gateways, the distribution proportion of the faulted gateway cluster is reduced, and the distribution proportion of the faulted gateway cluster is improved.
For example: half of gateways of the financial cloud AZ1 hosting gateway cluster 7 have faults, the distribution proportion is adjusted, the AZ2 gateway equipment is automatically brought into the financial cloud AZ1 hosting gateway cluster 7 to share the flow rapidly, the gateway equipment in the operation of AZ1 is prevented from being over-stressed, and the method comprises the following steps of: 2: 3, allocating the financial cloud AZ1 hosting gateway cluster 7, the financial cloud AZ2 hosting gateway cluster 7 and the private cloud gateway cluster 5, wherein at this time, AZ1 carries total traffic of 2/9, AZ2 carries total traffic of 4/9, and the private cloud gateway cluster 5 keeps 1/3 total traffic unchanged.
S24: and confirming the gateway cluster with the fault, and distributing the user request to the gateway cluster without the fault. In this embodiment, the user requests are evenly distributed to the gateway clusters which do not have faults;
the type of gateway cluster failure includes a gateway cluster ingress failure or a failure of all gateways of the gateway cluster.
For example, when an entry of the financial cloud AZ1 hosting gateway cluster 7 fails, cloud analysis automatically isolates the entry of the financial cloud AZ1 hosting gateway cluster 7, and the total traffic of each bearer 1/2 is evenly distributed to the financial cloud AZ2 hosting gateway cluster 7 and the private cloud gateway cluster 5, and the financial cloud AZ2 hosting gateway cluster 7 and the private cloud gateway cluster 5.
S25: and confirming the failed hosted gateway cluster 7, and connecting the failed hosted gateway cluster 7 with the private cloud computing module 6 through the private cloud line 10 of the un-failed hosted gateway cluster 7.
The failure of the dedicated cloud line 10 is disconnection of the dedicated cloud line 10 of the hosted gateway cluster 7, that is, in this embodiment, both the two operator dedicated cloud lines of the dedicated cloud line 10 of one hosted gateway cluster 7 fail.
S3: and acquiring the type of the user request, and forwarding the user request to the corresponding computing resource in the private cloud computing module 6 according to the type of the user request.
In this embodiment, the cloud analysis server 2 returns an internet entry address corresponding to the gateway cluster to the client 1 after completing gateway cluster allocation, the client 1 accesses the gateway cluster through the internet entry address, and the gateway cluster forwards the user request to the private cloud computing module 6.
If the internet entrance address of the private cloud gateway cluster 5 is returned, the client 1 accesses the private cloud gateway cluster 5 through the internet entrance of the private cloud gateway cluster 5, and the private cloud gateway forwards the internet address to the private cloud computing module 6 according to the type of the user request, wherein the private cloud gateway comprises an office area computing resource module 8 and a production area computing resource module 9.
If the address of the financial cloud AZ1 hosting gateway cluster 7 is returned, the user accesses the financial cloud AZ1 hosting gateway equipment through a financial cloud AZ1 internet entrance, and the financial cloud AZ1 hosting gateway forwards the information to office computing resources or production computing resources through a cloud special line 10 of AZ1 according to the type of the user request;
if the financial cloud AZ2 address is returned, the user accesses the financial cloud AZ2 hosting gateway equipment through the financial cloud AZ2 internet entrance, and the financial cloud AZ2 hosting gateway forwards the information to office computing resources or production computing resources through the cloud special line 10 of AZ2 according to the type of the user request.
S4: the private cloud computing module 6 processes the user request.
The above embodiments are merely examples and do not limit the scope of the present invention. These embodiments may be implemented in other various manners, and various omissions, substitutions, and changes may be made without departing from the technical spirit of the present invention.
Claims (10)
1. A request processing system based on multi-living hybrid cloud deployment is characterized by comprising a client, a cloud resolution server, a private cloud component and a managed gateway component, wherein the private cloud component comprises a private cloud gateway cluster and a private cloud computing module, the private cloud gateway cluster comprises a plurality of private cloud gateways, the managed gateway component comprises a plurality of managed gateway clusters, each managed gateway cluster comprises a plurality of managed gateways,
the cloud analysis server is used for acquiring and analyzing a user request of the client, and distributing a gateway cluster of the user request according to the state of the gateway;
the client is used for sending an analysis request to the cloud analysis server, acquiring an internet entrance of a corresponding gateway and sending a user request to the private cloud computing module through the corresponding gateway for processing;
the private cloud gateway and the hosting gateway component are used for acquiring a user request from a client and sending the user request to corresponding computing resources in the private cloud computing module;
the private cloud computing module is used for processing the user request.
2. The multi-live hybrid cloud deployment-based request processing system of claim 1, wherein the hosted gateway component comprises two hosted gateway clusters.
3. The system of claim 1, wherein the hosted gateway cluster is connected to the private cloud computing module via a dedicated cloud line.
4. The system of claim 3, wherein the dedicated cloud line is a BGP load share formed by dual operator cloud lines, and when one operator cloud line fails, the system automatically switches to another operator cloud line.
5. A request processing method based on multi-active hybrid cloud deployment is characterized in that the request processing system based on multi-active hybrid cloud deployment, which is disclosed by claims 1-4, comprises the following steps:
s1: the client sends a user request to the cloud analysis server;
s2: the cloud analysis server acquires states of the private cloud gateway cluster and the gateway cluster in the hosting gateway component, and allocates a gateway cluster corresponding to the user request according to the states of the gateways;
s3: sending the user request to a private cloud computing module through a corresponding gateway cluster;
s4: and the private cloud computing module processes the user request.
6. The method for processing the request based on the multi-active hybrid cloud deployment according to claim 5, wherein the step S2 specifically includes:
s21: acquiring a gateway cluster fault type, if the gateway cluster has no fault, entering a step S22, if the fault type is a partial gateway fault, entering a step S23, if the fault is the gateway cluster fault, entering a step S24, and if the fault is a cloud private line fault, entering a step S25;
s22: distributing a corresponding gateway cluster for a user request according to a first preset proportion;
s23: confirming the gateway cluster with the fault, reducing the distribution proportion of the gateway cluster with the fault, improving the distribution proportion of the gateway cluster without the fault, and distributing the corresponding gateway cluster for the user request according to the adjusted proportion;
s24: confirming the gateway cluster with the fault, and distributing the user request to the gateway cluster without the fault;
s25: and confirming the failed hosting gateway cluster, and connecting the failed hosting gateway cluster with the private cloud computing module through the cloud special line of the non-failed hosting gateway cluster.
7. The method according to claim 6, wherein the gateway cluster failure comprises a gateway cluster entry failure and a gateway cluster all gateway failure.
8. The method for processing the request based on the multi-active hybrid cloud deployment according to claim 6, wherein in the step S24, the user requests are evenly distributed to the non-failed gateway clusters.
9. The method as claimed in claim 6, wherein the first predetermined ratio is a ratio of evenly distributing the user requests to the gateway clusters.
10. The method for processing the request based on the multi-active hybrid cloud deployment according to claim 5, wherein the step S3 specifically includes acquiring a user request type, and forwarding the user request to the corresponding computing resource in the private cloud computing module according to the user request type.
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