CN111404930A - Composite instruction processing method and system - Google Patents

Abstract

The invention relates to a composite instruction processing method and a composite instruction processing system, on one hand, a plurality of sub-instructions corresponding to composite instruction codes of each service to be processed are sequentially executed according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction codes of each service to be processed, and the plurality of sub-instructions corresponding to each service to be processed are ensured to be sequentially executed, on the other hand, when the sub-instructions are asynchronous return-to-be-returned instructions, the plurality of services to be processed can be asynchronously executed by setting breakpoints on the sub-instructions, and therefore the processing efficiency of the services to be processed is improved.

Description

Composite instruction processing method and system

Technical Field

The invention relates to the technical field of telecommunication service support, in particular to a composite instruction processing method and a composite instruction processing system.

Background

At present, when a telecommunication service is handled, for example, all service handling of communication is in a CBSS and a BSS, and a new user and an old user of a mobile network (i.e., a mobile phone) of the CBSS and the BSS need to open a VO L TE function (VO L TE is collectively called Voice Over L ong-Term Evolution: long Term Evolution Voice bearer, which means that a high-speed wireless communication standard facing the mobile phone and a data terminal is provided, that is, after a user of the mobile network opens a VO L TE function, the user can obtain better network and call service, an actual use experience is that after a VO L TE function is opened, the user has an incoming call when playing a hand trip, and after the phone is connected, the network continues to be processed, so that the number of services to be processed is huge in real-time request, that the VO L TE function is opened in a complicated instruction, dozens of sub-instructions are requested once, that the instruction for opening the VO L TE function is a composite instruction, and the instruction for opening the VO L TE function includes a plurality of sub-instructions, a plurality of sub-instructions need to be returned to the VO L, and the problem that the VO and the user can only wait for opening a plurality of sub-TE instructions and a plurality of VO and a plurality of sub-order for opening a plurality of VO 3526 exists.

Disclosure of Invention

The invention provides a compound instruction processing method and a compound instruction processing system aiming at the defects of the prior art.

The technical scheme of the composite instruction processing method is as follows:

obtaining a corresponding composite instruction code according to each service to be managed;

acquiring a plurality of sub-instructions corresponding to each composite instruction code, setting breakpoints on the sub-instructions when the sub-instructions are asynchronous instructions to be returned, and waiting for returning when any breakpoint is executed;

sequentially executing a plurality of sub-instructions corresponding to the composite instruction code of each service to be managed according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed;

and when the executed breakpoint is detected to return, continuing to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

The beneficial effects of the compound instruction processing method of the invention are as follows:

on one hand, the sub-instructions corresponding to the composite instruction codes of each service to be processed are sequentially executed according to the execution sequence of the sub-instructions corresponding to the composite instruction codes of each service to be processed, so that the sub-instructions corresponding to each service to be processed are guaranteed to be sequentially executed, on the other hand, when the sub-instructions are asynchronous return-to-be-returned instructions, the break points are arranged on the sub-instructions, so that the services to be processed can be asynchronously executed, and the processing efficiency of the services to be processed is improved.

On the basis of the above scheme, the compound instruction processing method of the present invention may be further modified as follows.

Further, still include: creating a configuration table, wherein the configuration table stores the compound instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each compound instruction code;

the obtaining of the multiple sub-instructions corresponding to each compound instruction code includes:

acquiring a plurality of sub-instructions corresponding to each compound instruction code from the configuration table;

before the executing the multiple sub-instructions corresponding to the composite instruction code of each service to be handled according to the execution sequence of the multiple sub-instructions corresponding to the composite instruction code of each service to be handled in sequence, the method further includes:

and acquiring the execution sequence of a plurality of sub-instructions corresponding to the compound instruction code of each service to be managed from the configuration table.

The beneficial effect of adopting the further scheme is that: by creating the configuration table, the composite instruction codes of each service to be managed and the execution sequence of the plurality of sub instructions corresponding to each composite instruction code can be flexibly called from the configuration table, and the configuration table can be expanded and/or updated.

Further, still include: creating an instruction processing table, wherein the instruction processing table stores a plurality of services to be transacted and a composite instruction code corresponding to each service to be transacted;

the obtaining of the corresponding composite instruction code according to each service to be managed includes:

and obtaining a corresponding composite instruction code from the instruction processing table according to each service to be managed.

The beneficial effect of adopting the further scheme is that: the management of the business to be handled is facilitated by creating the instruction processing table.

Further, still include: and creating a sub-instruction processing list, wherein the instruction processing list records the execution state of each sub-instruction corresponding to each service to be processed.

The beneficial effect of adopting the further scheme is that: by creating the instruction processing table, the execution condition of each sub-instruction corresponding to each service to be managed is convenient to check.

The technical scheme of the compound instruction processing system is as follows:

comprises an acquisition module, an acquisition setting module, an execution module and a detection module,

the acquisition module is used for acquiring a corresponding composite instruction code according to each service to be managed;

the acquisition setting module is used for acquiring a plurality of sub-instructions corresponding to each composite instruction code, setting breakpoints on the sub-instructions when the sub-instructions are asynchronous instructions to be returned, and waiting for returning when any breakpoint is executed;

the execution module is used for sequentially executing a plurality of sub-instructions corresponding to the composite instruction code of each service to be managed according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed;

when the detection module detects that the executed breakpoint returns, the execution module continues to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

The beneficial effects of the compound instruction processing system of the invention are as follows:

on one hand, the sub-instructions corresponding to the composite instruction codes of each service to be processed are sequentially executed according to the execution sequence of the sub-instructions corresponding to the composite instruction codes of each service to be processed, so that the sub-instructions corresponding to each service to be processed are guaranteed to be sequentially executed, on the other hand, when the sub-instructions are asynchronous return-to-be-returned instructions, the break points are arranged on the sub-instructions, so that the services to be processed can be asynchronously executed, and the processing efficiency of the services to be processed is improved.

On the basis of the above scheme, the compound instruction processing system of the present invention can be further improved as follows.

Further comprises a creating module and an obtaining execution sequence module,

the creating module is used for creating a configuration table, and the configuration table stores the composite instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each composite instruction code;

the obtaining setting module is specifically configured to obtain, from the configuration table, a plurality of sub-instructions corresponding to each composite instruction code;

the execution sequence acquiring module is used for acquiring the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed from the configuration table.

The beneficial effect of adopting the further scheme is that: by creating the configuration table, the composite instruction codes of each service to be managed and the execution sequence of the plurality of sub instructions corresponding to each composite instruction code can be flexibly called from the configuration table, and the configuration table can be expanded and/or updated.

The creating module is further configured to create an instruction processing table, where the instruction processing table stores a plurality of services to be handled and a composite instruction code corresponding to each service to be handled;

the obtaining module is specifically configured to obtain a corresponding composite instruction code from the instruction processing table according to each service to be managed.

The beneficial effect of adopting the further scheme is that: the management of the business to be handled is facilitated by creating the instruction processing table.

Further, the creating module is further configured to create a sub-instruction processing list, where the instruction processing list records an execution state of each sub-instruction corresponding to each service to be handled.

The beneficial effect of adopting the further scheme is that: by creating the instruction processing table, the execution condition of each sub-instruction corresponding to each service to be managed is convenient to check.

Drawings

FIG. 1 is a flowchart illustrating a compound instruction processing method according to an embodiment of the present invention;

FIG. 2 is a second flowchart illustrating a compound instruction processing method according to an embodiment of the present invention;

FIG. 3 is a block diagram of a compound instruction processing system according to an embodiment of the present invention;

Detailed Description

As shown in fig. 1, a compound instruction processing method according to an embodiment of the present invention includes the following steps:

s1, obtaining corresponding composite command codes according to each service to be managed;

s2, acquiring a plurality of sub-instructions corresponding to each compound instruction code, setting breakpoints on the sub-instructions when the sub-instructions are asynchronous to-be-returned instructions, and waiting for return when any breakpoint is executed;

s3, sequentially executing a plurality of sub-instructions corresponding to the compound instruction code of each service to be handled according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code of each service to be handled;

and S4, when the executed breakpoint is detected to return, continuing to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

On one hand, the sub-instructions corresponding to the composite instruction codes of each service to be processed are sequentially executed according to the execution sequence of the sub-instructions corresponding to the composite instruction codes of each service to be processed, so that the sub-instructions corresponding to each service to be processed are guaranteed to be sequentially executed, on the other hand, when the sub-instructions are asynchronous return-to-be-returned instructions, the break points are arranged on the sub-instructions, so that the services to be processed can be asynchronously executed, and the processing efficiency of the services to be processed is improved.

The method comprises the following steps of dividing a plurality of sub-instructions into real-time instructions, asynchronous instructions to be returned and/or asynchronous instructions not to be returned according to different types of the sub-instructions, and specifically comprises the following steps:

1) real-time instructions: after the sub-instruction is sent, the other side needs to return in real time, only after the return is successfully received, the subsequent processing can be carried out, namely, the next sub-instruction is executed according to the execution sequence, and because the return time of the real-time instruction is extremely short, the breakpoint does not need to be set.

2) Asynchronous does not require a to-be-returned instruction: as long as the sub-instruction is correctly issued, there is no need to wait or look back.

3) Asynchronous instruction to return: after the sub-instruction is sent, the opposite side does not return whether the sub-instruction is successful in real time, but returns whether the sub-instruction is successful at a later time. As a sender, it needs to wait and check whether the other side has returned, and the subsequent processing cannot be performed until the return processing of the other side is successful, which is also the purpose of setting a breakpoint.

That is to say, the processing mode of the current service to be handled is serial, that is, after the previous service to be handled is handled, the next service to be handled is handled, and when the asynchronous return-to-return instruction is executed, the time of the user is consumed.

In the present application, the multiple sub-instructions corresponding to the composite instruction code of each service to be handled are sequentially executed according to the execution sequence of the multiple sub-instructions corresponding to the composite instruction code of each service to be handled, specifically:

executing a plurality of sub-instructions corresponding to the composite instruction code of the previous service to be handled according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of the previous service to be handled, and waiting for returning when any breakpoint is executed;

continuing to execute the plurality of sub-instructions corresponding to the composite instruction code of the next service to be handled according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of the next service to be handled, and waiting for returning when any breakpoint is executed;

continuing to execute the sub-instructions corresponding to the compound instruction code of the next service to be processed according to the execution sequence of the sub-instructions corresponding to the compound instruction code of the next service to be processed, and waiting for returning when any breakpoint is executed;

and by analogy, when the executed breakpoint is detected to return, continuing to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

Therefore, a plurality of services to be managed can be asynchronously executed, and the processing efficiency of the services to be managed is improved.

The composite command can be understood as that when a certain user manages to open the VO L TE function, the service to be managed is to open the VO L TE function, the command to open the VO L TE function includes tens of sub-commands, that is, the command to open the VO L TE function is the composite command, and in addition, the relative commands of opening a new mobile phone number, cancelling the mobile phone number and the like can be managed in the CBSS and the BSS, and the composite command is also used.

For example, when the to-be-handled service is the VO L TE function, the composite command code is 99110, when the to-be-handled service is the new phone number, the composite command code is 99120, when the to-be-handled service is the logout phone number, the composite command code is 99130, and the like, and various to-be-handled services and corresponding composite command codes thereof are stored in a table or a server, so that a service handling person or a front end can conveniently obtain the composite command code of the to-be-handled service.

If the to-be-handled service of a certain user is to open the VO L TE function, and the person handling the service or the front end obtains 99110 the composite command code for opening the VO L TE function, the back end executes a plurality of corresponding sub-commands by sending 99110 the composite command code and basic information thereof, such as a mobile phone number, a user name, and the like, to the back end.

For example, 100 users need to activate the VO L TE function, 100 users need to activate a new mobile phone number, and 100 users cancel the mobile phone number, and then the three different services to be handled are placed in different tables, or at this time, any table is not confused with respect to a certain service to be handled.

Preferably, in the above technical solution, the method further comprises:

s10, creating a configuration table, wherein the configuration table stores the compound instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each compound instruction code;

acquiring a plurality of sub-instructions corresponding to each compound instruction code, wherein the method comprises the following steps: acquiring a plurality of sub-instructions corresponding to each compound instruction code from a configuration table;

before the executing the multiple sub-instructions corresponding to the composite instruction code of each service to be handled according to the execution sequence of the multiple sub-instructions corresponding to the composite instruction code of each service to be handled in sequence, the method further includes:

the configuration table is created, so that the composite instruction code of each service to be handled and the execution sequence of the plurality of sub-instructions corresponding to each composite instruction code are flexibly called from the configuration table, the configuration table can be expanded and/or updated, for example, the composite instruction code for opening the VO L TE function and the execution sequence of the plurality of sub-instructions of the service to be handled are already included in the configuration table, the composite instruction code for opening a new mobile phone number and the execution sequence of the plurality of sub-instructions of the composite instruction code for opening the VO L TE function can be conveniently filled into the configuration table, and the composite instruction code for opening the VO L TE function and the execution sequence of the plurality of sub-instructions of the composite instruction code for opening the VO L TE function and the execution sequence of the plurality of sub-instructions of the composite instruction code for opening the VO L TE function can be more conveniently deleted from the configuration table.

Among these, it is understood that: different sub-instruction codes can be set for different sub-instructions in the configuration table, the execution sequence of a plurality of sub-instructions can be conveniently configured through the sub-instruction codes, wherein each sub-instruction code can be set to be 1, 2, 3 and the like, the execution sequence is that the sub-instruction code is executed for the first time and is corresponding to the sub-instruction code 1, and the like, sub-instruction information strings of different sub-instructions are set in the configuration table, the substance of the different sub-instructions is the sub-instruction information string for executing the different sub-instructions, or the different sub-instruction codes and the corresponding sub-instruction information strings are configured in a single database, and the corresponding sub-instruction information strings are obtained from the database according to the sub-instruction codes to be executed.

Preferably, in the above technical solution, the method further comprises:

s20, creating an instruction processing table, wherein the instruction processing table stores a plurality of services to be transacted and composite instruction codes corresponding to each service to be transacted;

obtaining a corresponding composite instruction code according to each service to be managed, comprising: and obtaining a corresponding composite instruction code from the instruction processing table according to each service to be handled.

The management of the business to be transacted is facilitated by creating the instruction processing table, and the created instruction processing table comprises the basic information of the user, the order identification, the composite instruction number, the instruction information string of each sub-instruction and the like.

Preferably, in the above technical solution, the method further comprises:

s30, creating a sub-instruction processing list, wherein the instruction processing list records the execution state of each sub-instruction corresponding to each service to be managed.

By creating the instruction processing table, the execution condition of each sub-instruction corresponding to each service to be managed is convenient to check.

The present application is explained in more detail below by means of another embodiment, as shown in fig. 2, in particular:

s40, creating a configuration table, specifically:

1) for a service to be transacted for opening a VO L TE function, a compound instruction code of the service to be transacted is 99110 and is recorded as a first compound instruction code, the first compound instruction code correspondingly includes 15 sub instructions, the execution sequence of the 15 sub instructions is identified by 1, 2, and 3, and the sub instruction code corresponding to each sub instruction is identified by h201, h211, and the like, as shown in table 1 below:

table 1:

the execution sequence of each sub-instruction from h201 to t217 is 1 to 15, it should be noted that the sub-instruction encoding is END sub-instruction, which means that the END sub-instruction is executed after all 15 sub-instructions corresponding to the first compound instruction encoding are executed, the sub-instruction type is 1 for asynchronous non-return-required instruction, 2 for asynchronous return-to-be-returned instruction, 3 for real-time instruction, and the third sub-instruction in table 1 that is to be executed and is encoded as h206 is asynchronous return-to-be-returned instruction, so that a breakpoint is set on the sub-instruction encoded as h 206.

In table 1, the sub-command network element is default to null, which means that each sub-command is sent to VO L TE, but not all services are so, and if some services require that each sub-command is sent to a different sub-command network element, the configuration table needs to be configured as in table 1.

2) Aiming at the service to be managed for opening the new mobile phone number, the composite instruction number is 99120 and is recorded as a second composite instruction code, and the second composite instruction code correspondingly comprises 20 sub-instructions;

3) aiming at the service to be managed for logging out the mobile phone number, the composite instruction number is 991230 and is recorded as a third composite instruction code, and the third composite instruction code correspondingly comprises 30 sub-instructions;

for the second compound instruction code and its respective sub-instructions, the third compound instruction code and its respective sub-instructions, refer to table 1, which is not described herein again.

S41, creating an instruction processing table, specifically, if the first client needs to transact the VO L TE opening function and the second client also needs to transact the VO L TE opening function, then:

1) the created instruction processing table includes basic information of the first user, such as a user identifier and a mobile phone number, a first compound instruction code 99110, instruction information strings of 15 sub-instructions corresponding to the first compound instruction code, and an execution state, as shown in table 2 below:

table 2:

the mobile phone number of a first user is filled in the mobile phone number, instruction information of each instruction comprises 15 sub-instructions corresponding to a first composite instruction code, execution states can be divided into 5 types, 0 is used for representing to-be-guarded execution, 1 is used for representing in-guarded execution, 2 is used for representing execution success, 3 is used for representing execution error, and 5 is used for representing execution break point, wherein the to-be-guarded execution represents to-be-executed, the daemon execution represents in-execution, the execution success represents that opening of a VO L TE function is successful, the execution error represents that the VO L TE function is not opened, and the execution break point represents that the break point is being executed.

2) The created instruction processing table further includes the basic information of the second user, the first compound instruction number 99110, the instruction information string of the 15 sub instructions of the first compound instruction, the execution STATE (TASK _ STATE), and the like, and the order identifier, the serial number for sending the first compound instruction code, the user identifier, and the mobile phone number of the order processing table are different from those in table 2, which is not described herein again.

The processing process comprises the following steps:

s42, when opening the VO L TE function for the first user, sending a first compound command code 99110, and executing each sub-command according to an execution sequence of the first compound command, specifically:

acquiring instruction information strings of 15 sub instructions from an instruction processing table according to each sub instruction corresponding to a first compound instruction in a configuration table and an execution sequence of the sub instructions to execute the 15 sub instructions of the first compound instruction, wherein the 3 rd sub instruction is an asynchronous to-be-returned instruction, and when the 3 rd sub instruction is executed, the instruction enters a waiting return mode, namely the waiting return mode is realized;

s43, asynchronously conducting a VO L TE opening function for the first user, specifically:

at this time, the first compound command code 99110 sent by the service to be transacted, which opens the VO L TE function, of the second user can also be used, the execution process is similar to the above S42, and then when the 3 rd sub command is also executed, the system waits, that is, the system waits for returning;

and S43, detecting whether the third sub-instruction of the first user and the third sub-instruction of the second user return in real time, if so, continuing to execute the remaining sub-instructions of the first user or the second user, namely, continuing to execute the sub-instruction coded as the sub-instruction of t 201. The frequency of detection can be 100 times within 1 second, 50 times within 1 second, etc.

S44, an instruction processing list may be created for the first user and the second user respectively, and used to record the execution status of each sub instruction, such as success or failure of execution.

The instruction processing list of the first user is shown in table 3 below:

table 3:

the execution state of the sub-instruction is divided into 4 types, wherein 0 is used for indicating that the sub-instruction is not executed, 2 is used for indicating that the sub-instruction is successfully executed, 3 is used for indicating that the sub-instruction is failed to be executed, 1 is used for indicating that the sub-instruction is being executed, a network element waiting for the sub-instruction returns, and when an instruction processing list of a first user is created, the execution state can be defaulted to 0; and whether the sub-instruction is sent successfully or not means whether the sub-instruction is sent to the corresponding network element or not, the sub-instruction is empty by default, and if the sub-instruction is sent successfully, the sub-instruction returns to 1.

Different processes can be added to send or receive the sub-instructions, the compound instruction codes, the sub-instruction codes, the waiting return and the like, and after all the sub-instructions are modified, the information such as the execution states in the tables 1, 2 and 3 is modified.

As shown in fig. 3, a compound instruction processing system 200 according to an embodiment of the present invention includes an obtaining module 210, an obtaining setting module 220, an executing module 230, and a detecting module 240;

the obtaining module 210 is configured to obtain a corresponding composite instruction code according to each service to be managed;

the obtaining and setting module 220 is configured to obtain a plurality of sub-instructions corresponding to each composite instruction code, set a breakpoint on the sub-instruction when the sub-instruction is an asynchronous instruction to be returned, and wait for returning when any breakpoint is executed;

the execution module 230 is configured to sequentially execute the multiple sub-instructions corresponding to the composite instruction code of each service to be handled according to the execution sequence of the multiple sub-instructions corresponding to the composite instruction code of each service to be handled;

when the detection module 240 detects that the executed breakpoint returns, the execution module continues to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

On one hand, the sub-instructions corresponding to the composite instruction codes of each service to be processed are sequentially executed according to the execution sequence of the sub-instructions corresponding to the composite instruction codes of each service to be processed, so that the sub-instructions corresponding to each service to be processed are guaranteed to be sequentially executed, on the other hand, when the sub-instructions are asynchronous return-to-be-returned instructions, the break points are arranged on the sub-instructions, so that the services to be processed can be asynchronously executed, and the processing efficiency of the services to be processed is improved.

Preferably, in the above technical solution, the method further comprises a creating module and an obtaining execution sequence module,

the creating module is used for creating a configuration table, and the configuration table stores the composite instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each composite instruction code;

the obtaining setting module 220 is specifically configured to obtain a plurality of sub instructions corresponding to each compound instruction code from the configuration table;

the execution sequence acquiring module is used for acquiring the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed from the configuration table.

By creating the configuration table, the composite instruction codes of each service to be managed and the execution sequence of the plurality of sub instructions corresponding to each composite instruction code can be flexibly called from the configuration table, and the configuration table can be expanded and/or updated.

Preferably, in the above technical solution, the creating module is further configured to create an instruction processing table, where the instruction processing table stores a plurality of services to be handled and a composite instruction code corresponding to each service to be handled;

the obtaining module 210 is specifically configured to obtain a corresponding composite instruction code from the instruction processing table according to each service to be handled, and facilitate management of the service to be handled by creating the instruction processing table.

Preferably, in the above technical solution, the creating module is further configured to create a sub-instruction processing list, and the instruction processing list records an execution state of each sub-instruction corresponding to each service to be managed.

By creating the instruction processing table, the execution condition of each sub-instruction corresponding to each service to be managed is convenient to check.

The above steps for implementing the corresponding functions of each parameter and each unit module in the compound instruction processing system 200 according to the present invention can refer to each parameter and step in the above embodiment of a compound instruction processing method, which are not described herein again.

In the present invention, the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (8)

1. A compound instruction processing method, comprising:

obtaining a corresponding composite instruction code according to each service to be managed;

acquiring a plurality of sub-instructions corresponding to each composite instruction code, setting breakpoints on the sub-instructions when the sub-instructions are asynchronous instructions to be returned, and waiting for returning when any breakpoint is executed;

sequentially executing a plurality of sub-instructions corresponding to the composite instruction code of each service to be managed according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed;

and when the executed breakpoint is detected to return, continuing to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

2. The compound instruction processing method according to claim 1, further comprising: creating a configuration table, wherein the configuration table stores the compound instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each compound instruction code;

the obtaining of the multiple sub-instructions corresponding to each compound instruction code includes:

acquiring a plurality of sub-instructions corresponding to each compound instruction code from the configuration table;

before the executing the multiple sub-instructions corresponding to the composite instruction code of each service to be handled according to the execution sequence of the multiple sub-instructions corresponding to the composite instruction code of each service to be handled in sequence, the method further includes:

and acquiring the execution sequence of a plurality of sub-instructions corresponding to the compound instruction code of each service to be managed from the configuration table.

3. A compound instruction processing method according to claim 1 or 2, further comprising:

creating an instruction processing table, wherein the instruction processing table stores a plurality of services to be transacted and a composite instruction code corresponding to each service to be transacted;

the obtaining of the corresponding composite instruction code according to each service to be managed includes:

and obtaining a corresponding composite instruction code from the instruction processing table according to each service to be managed.

4. A compound instruction processing method according to claim 1 or 2, further comprising:

and creating a sub-instruction processing list, wherein the instruction processing list records the execution state of each sub-instruction corresponding to each service to be processed.

5. A composite instruction processing system is characterized by comprising an acquisition module, an acquisition setting module, an execution module and a detection module;

the acquisition module is used for acquiring a corresponding composite instruction code according to each service to be managed;

the acquisition setting module is used for acquiring a plurality of sub-instructions corresponding to each composite instruction code, setting breakpoints on the sub-instructions when the sub-instructions are asynchronous instructions to be returned, and waiting for returning when any breakpoint is executed;

the execution module is used for sequentially executing a plurality of sub-instructions corresponding to the composite instruction code of each service to be managed according to the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed;

when the detection module detects that the executed breakpoint returns, the execution module continues to execute the sub-instructions after the returned breakpoint according to the execution sequence of the plurality of sub-instructions corresponding to the compound instruction code corresponding to the returned breakpoint.

6. The compound instruction processing system of claim 5, further comprising a creation module and a fetch execution order module,

the creating module is used for creating a configuration table, and the configuration table stores the composite instruction codes of each service to be managed and the execution sequence of a plurality of sub instructions corresponding to each composite instruction code;

the obtaining setting module is specifically configured to obtain, from the configuration table, a plurality of sub-instructions corresponding to each composite instruction code;

the execution sequence acquiring module is used for acquiring the execution sequence of the plurality of sub-instructions corresponding to the composite instruction code of each service to be managed from the configuration table.

7. The compound instruction processing system according to claim 6, wherein the creating module is further configured to create an instruction processing table, and the instruction processing table stores a plurality of services to be handled and a compound instruction code corresponding to each service to be handled;

the obtaining module is specifically configured to obtain a corresponding composite instruction code from the instruction processing table according to each service to be managed.

8. The system according to claim 6 or 7, wherein the creating module is further configured to create a sub-instruction processing list, and the instruction processing list records an execution state of each sub-instruction corresponding to each service to be processed.

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