CN117151614A - Workflow midflow Cheng Cuiban method - Google Patents

Abstract

The application relates to the technical field of flow promotion, in particular to a workflow in-flow Cheng Cuiban method. Comprising the following steps: acquiring a flow to be sponsored according to workflow parameters; acquiring an ordering node according to the parameters of the flow to be ordered, and setting an ordering instruction according to the ordering node and the flow to be ordered; and setting a monitoring time node according to the prompting instruction, acquiring a feedback instruction according to the monitoring time node, and correcting the prompting instruction according to the feedback instruction. Through obtaining the circulation time of the flow to be handled, set up different flows that need to be handled, in time early warning to the workflow that will overdue to the flow to be handled that has overdue carries out the handling, improves the flow treatment effeciency in the workflow, through predetermineeing the instruction class matrix of handling, establishes the system of handling of having a plurality of, realizes real-time supervision and the timely early warning to the flow in the workflow, sets up the solution of handling in time according to the urgency developments of flow simultaneously, reduces the fortune dimension cost, improves the efficiency of handling.

Description

Workflow midflow Cheng Cuiban method

Technical Field

The application relates to the technical field of flow promotion, in particular to a workflow in-flow Cheng Cuiban method.

Background

Along with the improvement of office automation level, people put forward higher requirements on convenient office, enterprises want to establish a unified office system among departments in the enterprises in order to simplify the process of working handover among the units, share a set of data resource base, thereby saving butt joint on work, optimizing the office process, simplifying office operation and improving office efficiency.

However, in the business flow system, when the business flow is longer or the related roles are more, the work of one user is prolonged, so that the work of other users is prolonged. Resulting in reduced office efficiency.

Disclosure of Invention

The purpose of the application is that: in order to solve the technical problems, the application provides a flow prompting method in a workflow, which aims to realize real-time monitoring and timely early warning of the workflow and improve the working efficiency.

In some embodiments of the present application, by obtaining the circulation time of the to-be-handled flows, setting different to-be-handled flows, timely early warning the workflow about to be overdue, and prompting the to-be-handled flows that are overdue, the flow processing efficiency in the workflow is improved.

In some embodiments of the application, a multi-element sponsorship system is established by presetting a sponsorship instruction grade matrix, so that real-time monitoring and timely early warning of the flow in the workflow are realized, meanwhile, the sponsorship scheme is dynamically set according to the urgency of the flow, the operation and maintenance cost is reduced, and the sponsorship efficiency is improved.

In some embodiments of the present application, a method for flow promotion in a workflow is provided, including:

acquiring a flow to be sponsored according to workflow parameters;

acquiring an sponsoring node according to the parameters of the sponsoring flow to be sponsored, and setting sponsoring instructions according to the sponsoring node and the sponsoring flow to be sponsored;

and setting a monitoring time node according to the prompting instruction, acquiring a feedback instruction according to the monitoring time node, and correcting the prompting instruction according to the feedback instruction.

In some embodiments of the present application, when the process to be sponsored is obtained according to the workflow parameter, the method includes:

acquiring all to-be-handled flows according to workflow parameters;

obtaining nodes to be circulated and a preset circulation time axis of a to-be-handled flow

Acquiring a current circulation node and real-time circulation time a1 of a to-be-handled flow;

generating preset circulation time a2 according to the current circulation node of the to-be-handled flow and the preset circulation time axis;

setting a to-be-handled flow type according to the real-time circulation time a1 and the preset circulation time a2;

presetting a primary flow needing to be sponsored, a secondary flow needing to be sponsored and a tertiary flow needing to be sponsored;

if a1 is less than a2, generating a circulation time difference value delta a according to a1 and a2, and setting a to-be-handled flow type according to the circulation time difference value delta a;

if a1 is more than or equal to a2, setting the to-be-handled flow as a three-level flow needing to be handled.

In some embodiments of the present application, when setting the to-Do flow type according to the flow time difference Δa, the method includes:

presetting a first flow time difference value A1 and a second flow time difference value A2, wherein A1 is smaller than A2;

if A1> delta a, setting the to-be-handled flow as a secondary flow to be handled;

if A1 is less than delta a is less than A2, setting the to-be-handled flow as a first-level to-be-handled flow;

if A2< deltaa, the promotion level of the to-be-handled flow is not set.

In some embodiments of the present application, when the to-be-sponsored node is obtained according to the to-be-sponsored flow parameter, the method includes:

acquiring a task flow branch of a flow to be sponsored, and acquiring sponsored nodes according to the task flow branch;

generating an sponsoring instruction according to the flow level to be sponsored, and setting the number of sponsoring instructions according to the number m of sponsoring nodes.

In some embodiments of the present application, when generating the to-be-sponsored instruction according to the to-be-sponsored flow level, the method includes:

presetting an instruction level matrix B, and setting B (B1, B2 and B3), wherein B1 is a preset primary instruction, B2 is a preset secondary instruction, and B3 is a preset tertiary instruction;

if the first-level to-be-sponsored process is the first-level to-be-sponsored process, generating a first-level sponsored instruction B1;

if the flow to be sponsored is a secondary flow to be sponsored, generating a secondary sponsored instruction B2;

if the flow to be sponsored is three-level flow to be sponsored, generating a three-level sponsored instruction B3.

In some embodiments of the present application, when the monitoring time node is set according to the sponsored instruction, the method includes:

presetting a monitoring time interval matrix T, and setting T (T1, T2 and T3), wherein T1 is a preset first monitoring time interval, T2 is a preset second monitoring time interval, T3 is a preset third monitoring time interval, and T1< T2< T3;

acquiring an prompting instruction b of a flow to be prompting, setting a real-time monitoring time interval t according to the prompting instruction b, and setting a monitoring time node according to the real-time monitoring time interval t;

if the prompting instruction B is the first-level prompting instruction B1, setting a real-time monitoring time interval T as a preset third monitoring time interval T3, namely t=t3;

if the prompting instruction B is a secondary prompting instruction B2, setting a real-time monitoring time interval T as a preset second monitoring time interval T2, namely t=t2;

if the prompting instruction B is the three-level prompting instruction B3, the real-time monitoring time interval T is set to be a preset first monitoring time interval T1, i.e. t=t1.

In some embodiments of the present application, when the monitoring time node is set according to the prompting instruction, the method further includes:

acquiring the number m of the sponsoring nodes in the flow needing sponsoring, setting a time interval correction coefficient n according to the number m of the sponsoring nodes, and correcting a real-time monitoring time interval t;

presetting a matrix M of the number of the sponsoring nodes, and setting M (M1, M2 and M3), wherein M1 is the preset number of the first sponsoring nodes, M2 is the preset number of the second sponsoring nodes, M3 is the preset number of the third sponsoring nodes, and M1 is less than M2 is less than M3;

presetting a time interval correction coefficient matrix N, setting N (N1, N2, N3), wherein N1 is a preset first time interval correction coefficient, N2 is a preset second time interval correction coefficient, N3 is a preset third time interval correction coefficient, and N1< N2< N3<1;

if the number of the sponsored nodes is m=m1, setting a time interval correction coefficient n=n1, and monitoring a time interval t=n1×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes is m=m2, setting a time interval correction coefficient n=n2, and monitoring a time interval t=n2×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes m=m3, setting a time interval correction coefficient n=n3, and monitoring the time interval t=n3×ti after correction in real time, (i=1, 2, 3).

In some embodiments of the present application, when obtaining a feedback instruction according to the monitoring time node, the method includes:

acquiring task processing states of all the sponsoring nodes according to the monitoring time nodes;

generating a feedback instruction according to the number m of the to-be-sponsored nodes and the task processing state in the to-be-sponsored process;

if m=1;

when the task processing state is finished, generating a primary feedback instruction;

when the task processing state is incomplete, generating a secondary feedback instruction;

if m is not equal to 1, setting an unfinished node threshold;

acquiring the number m1 of the incomplete hastening nodes in the task processing state;

if m1 is smaller than the unfinished node threshold, generating a second-level feedback instruction;

and if m2 is larger than the unfinished node threshold, generating a three-level feedback instruction.

In some embodiments of the present application, when correcting the sponsorship instruction according to the feedback instruction, the method includes:

acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the second-level feedback instruction, acquiring a previous prompting instruction of a procedure to be prompted, and setting a current prompting instruction according to the previous prompting instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a second-level instruction;

when the previous instruction is a second-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1.

In some embodiments of the present application, when the sponsoring instruction is modified according to the feedback instruction, the method further includes:

acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the three-level feedback instruction, acquiring a previous instruction of the flow to be sponsored, and setting a current sponsored instruction according to the previous instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a second-level prompting instruction, setting the current prompting instruction as a third-level prompting instruction, acquiring a last monitoring time interval t1, and setting a real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m2×t1, wherein m2 is a compensation coefficient, and m2< m1<1.

Compared with the prior art, the flow prompting method in the workflow has the beneficial effects that:

by acquiring the circulation time of the to-be-handled flows, different flows to be handled are set, early warning is timely carried out on the work flow to be overdue, the to-be-handled flows which are overdue are handled in an accelerating mode, and flow processing efficiency in the work flow is improved.

Through presetting the instruction class matrix of hastening, establish the system of hastening of many units, realize real-time supervision and timely early warning to the flow in the workflow, set up the scheme of hastening according to the urgency developments of flow simultaneously, reduce the fortune dimension cost, improve the efficiency of hastening.

Drawings

FIG. 1 is a flow chart of a method for flow promotion in a workflow according to a preferred embodiment of the application.

Detailed Description

The following describes in further detail the embodiments of the present application with reference to the drawings and examples. The following examples are illustrative of the application and are not intended to limit the scope of the application.

In the description of the present application, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present application and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

The terms "first," "second," and the like, 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 defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1, a method for prompting a procedure in a workflow according to a preferred embodiment of the present application includes:

s101: acquiring a flow to be sponsored according to workflow parameters;

s102: acquiring an ordering node according to the parameters of the flow to be ordered, and setting an ordering instruction according to the ordering node and the flow to be ordered;

s103: and setting a monitoring time node according to the prompting instruction, acquiring a feedback instruction according to the monitoring time node, and correcting the prompting instruction according to the feedback instruction.

Specifically, when the flow to be sponsored is obtained according to the workflow parameters, the method comprises the following steps:

acquiring all to-be-handled flows according to workflow parameters;

obtaining nodes to be circulated and a preset circulation time axis of a to-be-handled flow

Acquiring a current circulation node and real-time circulation time a1 of a to-be-handled flow;

generating preset circulation time a2 according to the current circulation node and the preset circulation time axis of the flow to be handled;

setting a to-be-handled flow type according to the real-time circulation time a1 and the preset circulation time a2;

presetting a primary flow needing to be sponsored, a secondary flow needing to be sponsored and a tertiary flow needing to be sponsored;

if a1 is less than a2, generating a circulation time difference value delta a according to a1 and a2, and setting a to-be-handled flow type according to the circulation time difference value delta a;

if a1 is more than or equal to a2, setting the to-be-handled flow as a three-level to-be-handled flow.

Specifically, when the to-be-handled flow type is set according to the circulation time difference Δa, the method includes:

presetting a first flow time difference value A1 and a second flow time difference value A2, wherein A1 is smaller than A2;

if A1> deltaa, setting the flow to be handled as a secondary flow to be handled;

if A1 is less than delta a is less than A2, setting the flow to be handled as a first-level flow to be handled;

if A2< deltaa, the promotion level of the flow to be sponsored is not set.

Specifically, according to the importance degree, the three-level flow needing to be sponsored is better than the two-level flow needing to be sponsored than the first-level flow needing to be sponsored;

specifically, the three-level flow requiring to be sponsored is a overdue flow, and the first-level flow requiring to be sponsored and the second-level flow requiring to be sponsored are non-overdue flows.

It can be appreciated that in the above embodiment, by obtaining the circulation time of the to-be-handled flows, setting different to-be-handled flows, early warning is timely performed on the workflow about to be overdue, and the to-be-handled flows that are overdue are accelerated, so that the flow processing efficiency in the workflow is improved.

In a preferred embodiment of the present application, when obtaining an to-be-sponsored node according to a to-be-sponsored flow parameter, the method includes:

acquiring a task flow branch of a flow to be sponsored, and acquiring sponsored nodes according to the task flow branch;

generating an order according to the order of the flow to be ordered, and setting the number of the order according to the number m of the order nodes.

Specifically, when generating the demand-induced instruction according to the demand-induced flow level, the method includes:

presetting an instruction level matrix B, and setting B (B1, B2 and B3), wherein B1 is a preset primary instruction, B2 is a preset secondary instruction, and B3 is a preset tertiary instruction;

if the first-level to-be-sponsored process is the first-level to-be-sponsored process, generating a first-level sponsored instruction B1;

if the flow to be sponsored is a secondary flow to be sponsored, generating a secondary sponsored instruction B2;

if the flow to be sponsored is three-level flow to be sponsored, generating a three-level sponsored instruction B3.

Specifically, the first-level prompting instruction refers to that the current task to be prompted is in a processing period, the processing time is sufficient, the prompting can be performed through a system short message, the second-level prompting instruction refers to that the current task to be prompted is in the processing period, the remaining processing time is short, the processing is required to be performed immediately, the prompting is performed through a system short message and an email, the third-level prompting instruction refers to that the current task to be prompted is overdue, the work of a next flow node is affected, the processing is required to be performed immediately, and the prompting is performed through the system short message, the email and the email.

Specifically, the system short message, the email and the short message are sent to the mobile terminal of the processor.

It can be understood that in the above embodiment, through presetting the instruction level matrix for accelerating, a multi-element accelerating system is established, so as to realize real-time monitoring and timely early warning of the flow in the workflow, and meanwhile, the accelerating scheme is dynamically set according to the urgency of the flow, so that the operation and maintenance cost is reduced, and the accelerating efficiency is improved.

In a preferred embodiment of the present application, when the monitoring time node is set according to the prompting instruction, the method includes:

presetting a monitoring time interval matrix T, and setting T (T1, T2 and T3), wherein T1 is a preset first monitoring time interval, T2 is a preset second monitoring time interval, T3 is a preset third monitoring time interval, and T1< T2< T3;

acquiring an prompting instruction b of a flow to be prompting, setting a real-time monitoring time interval t according to the prompting instruction b, and setting a monitoring time node according to the real-time monitoring time interval t;

if the prompting instruction B is the first-level prompting instruction B1, setting a real-time monitoring time interval T as a preset third monitoring time interval T3, namely t=t3;

if the prompting instruction B is a secondary prompting instruction B2, setting a real-time monitoring time interval T as a preset second monitoring time interval T2, namely t=t2;

if the prompting instruction B is the three-level prompting instruction B3, the real-time monitoring time interval T is set to be a preset first monitoring time interval T1, i.e. t=t1.

Specifically, when the monitoring time node is set according to the prompting instruction, the method further comprises:

acquiring the number m of the to-be-sponsored nodes in the to-be-sponsored process, and setting a time interval correction coefficient n to correct the real-time monitoring time interval t according to the number m of the to-be-sponsored nodes;

presetting a matrix M of the number of the sponsoring nodes, and setting M (M1, M2 and M3), wherein M1 is the preset number of the first sponsoring nodes, M2 is the preset number of the second sponsoring nodes, M3 is the preset number of the third sponsoring nodes, and M1 is less than M2 is less than M3;

presetting a time interval correction coefficient matrix N, setting N (N1, N2, N3), wherein N1 is a preset first time interval correction coefficient, N2 is a preset second time interval correction coefficient, N3 is a preset third time interval correction coefficient, and N1< N2< N3<1;

if the number of the sponsored nodes is m=m1, setting a time interval correction coefficient n=n1, and monitoring a time interval t=n1×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes is m=m2, setting a time interval correction coefficient n=n2, and monitoring a time interval t=n2×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes m=m3, setting a time interval correction coefficient n=n3, and monitoring the time interval t=n3×ti after correction in real time, (i=1, 2, 3).

It may be appreciated that in the above embodiment, by setting the monitoring time interval matrix and the time interval correction coefficient matrix, different feedback periods are established according to different promotion instructions, and the circulation monitoring promotion is performed on the flow to be promoted until the flow is completed, so that the reduction of the overall working efficiency caused by delay of a single node in the flow is avoided.

In a preferred embodiment of the present application, when acquiring a feedback instruction according to a monitoring time node, the method includes:

acquiring task processing states of all the sponsored nodes according to the monitoring time nodes;

generating a feedback instruction according to the number m of the to-be-sponsored nodes and the task processing state in the to-be-sponsored process;

if m=1;

when the task processing state is finished, generating a first-level feedback instruction;

when the task processing state is incomplete, generating a secondary feedback instruction;

if m is not equal to 1, setting an unfinished node threshold;

acquiring the number m1 of the incomplete hastening nodes in the task processing state;

if m1 is smaller than the unfinished node threshold, generating a secondary feedback instruction;

and if m2 is larger than the unfinished node threshold, generating a three-level feedback instruction.

Specifically, when one of the sponsoring tasks needs to be processed by a plurality of nodes, if one or more of the nodes are processed, the rest untreated nodes automatically enter the overdue state and are sponsored, so that the processing efficiency of the flow is improved, and the reduction of the overall working efficiency of the flow caused by the fact that a single node is untreated is avoided.

Specifically, the first-level feedback instruction is an end instruction, which means that the task in the flow to be sponsored is completed at the current sponsored node and can enter the next node.

Specifically, when correcting the sponsor command based on the feedback command, the method includes:

acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the second-level feedback instruction, acquiring a previous prompting instruction of a procedure to be prompted, and setting a current prompting instruction according to the previous prompting instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a second-level instruction;

when the previous instruction is a second-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1.

Acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the three-level feedback instruction, acquiring a previous instruction of the flow to be sponsored, and setting a current sponsored instruction according to the previous instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a second-level prompting instruction, setting the current prompting instruction as a third-level prompting instruction, acquiring a last monitoring time interval t1, and setting a real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m2×t1, wherein m2 is a compensation coefficient, and m2< m1<1.

It can be understood that in the above embodiment, the feedback instruction is obtained according to the monitoring time node to dynamically adjust the sponsorship instruction, and the sponsorship period is adjusted by the compensation coefficient, so that the sponsorship efficiency is improved, and the overall working efficiency in the workflow is ensured.

According to the first conception of the application, by obtaining the circulation time of the to-be-handled flows, setting different to-be-handled flows, timely early warning the work flow about to be overdue, and prompting the to-be-handled flows which are overdue, improving the flow processing efficiency in the work flow,

according to the second conception of the application, a multi-element sponsorship system is established through presetting a sponsorship instruction grade matrix, so that real-time monitoring and timely early warning of the flow in the workflow are realized, meanwhile, the sponsorship scheme is dynamically set according to the urgency of the flow, the operation and maintenance cost is reduced, and the sponsorship efficiency is improved.

The foregoing is merely a preferred embodiment of the present application, and it should be noted that modifications and substitutions can be made by those skilled in the art without departing from the technical principles of the present application, and these modifications and substitutions should also be considered as being within the scope of the present application.

Claims (10)

1. A workflow in-stream Cheng Cuiban method comprising:

acquiring a flow to be sponsored according to workflow parameters;

acquiring an sponsoring node according to the parameters of the sponsoring flow to be sponsored, and setting sponsoring instructions according to the sponsoring node and the sponsoring flow to be sponsored;

and setting a monitoring time node according to the prompting instruction, acquiring a feedback instruction according to the monitoring time node, and correcting the prompting instruction according to the feedback instruction.

2. The method of workflow Cheng Cuiban as claimed in claim 1, wherein said obtaining a desired sponsored flow based on workflow parameters comprises:

acquiring all to-be-handled flows according to workflow parameters;

obtaining nodes to be circulated and a preset circulation time axis of a to-be-handled flow

Acquiring a current circulation node and real-time circulation time a1 of a to-be-handled flow;

generating preset circulation time a2 according to the current circulation node of the to-be-handled flow and the preset circulation time axis;

setting a to-be-handled flow type according to the real-time circulation time a1 and the preset circulation time a2;

presetting a primary flow needing to be sponsored, a secondary flow needing to be sponsored and a tertiary flow needing to be sponsored;

if a1 is less than a2, generating a circulation time difference value delta a according to a1 and a2, and setting a to-be-handled flow type according to the circulation time difference value delta a;

if a1 is more than or equal to a2, setting the to-be-handled flow as a three-level flow needing to be handled.

3. The method of workflow Cheng Cuiban in workflow of claim 2, wherein setting a to-do flow type based on the flow time difference Δa comprises:

presetting a first flow time difference value A1 and a second flow time difference value A2, wherein A1 is smaller than A2;

if A1> delta a, setting the to-be-handled flow as a secondary flow to be handled;

if A1 is less than delta a is less than A2, setting the to-be-handled flow as a first-level to-be-handled flow;

if A2< deltaa, the promotion level of the to-be-handled flow is not set.

4. The method of workflow Cheng Cuiban as set forth in claim 3, wherein said obtaining an sponsored node based on a sponsored on demand flow parameter comprises:

acquiring a task flow branch of a flow to be sponsored, and acquiring sponsored nodes according to the task flow branch;

generating an sponsoring instruction according to the flow level to be sponsored, and setting the number of sponsoring instructions according to the number m of sponsoring nodes.

5. The method of workflow Cheng Cuiban as recited in claim 4 wherein generating an sponsorship instruction based on the desired sponsorship process level comprises:

presetting an instruction level matrix B, and setting B (B1, B2 and B3), wherein B1 is a preset primary instruction, B2 is a preset secondary instruction, and B3 is a preset tertiary instruction;

if the first-level to-be-sponsored process is the first-level to-be-sponsored process, generating a first-level sponsored instruction B1;

if the flow to be sponsored is a secondary flow to be sponsored, generating a secondary sponsored instruction B2;

if the flow to be sponsored is three-level flow to be sponsored, generating a three-level sponsored instruction B3.

6. The workflow in-process Cheng Cuiban method of claim 5, wherein said setting a monitoring time node in accordance with said sponsored instruction comprises:

presetting a monitoring time interval matrix T, and setting T (T1, T2 and T3), wherein T1 is a preset first monitoring time interval, T2 is a preset second monitoring time interval, T3 is a preset third monitoring time interval, and T1< T2< T3;

acquiring an prompting instruction b of a flow to be prompting, setting a real-time monitoring time interval t according to the prompting instruction b, and setting a monitoring time node according to the real-time monitoring time interval t;

if the prompting instruction B is the first-level prompting instruction B1, setting a real-time monitoring time interval T as a preset third monitoring time interval T3, namely t=t3;

if the prompting instruction B is a secondary prompting instruction B2, setting a real-time monitoring time interval T as a preset second monitoring time interval T2, namely t=t2;

if the prompting instruction B is the three-level prompting instruction B3, the real-time monitoring time interval T is set to be a preset first monitoring time interval T1, i.e. t=t1.

7. The workflow in-process Cheng Cuiban method of claim 6, wherein said setting a monitoring time node in accordance with said sponsored instruction further comprises:

acquiring the number m of the sponsoring nodes in the flow needing sponsoring, setting a time interval correction coefficient n according to the number m of the sponsoring nodes, and correcting a real-time monitoring time interval t;

presetting a matrix M of the number of the sponsoring nodes, and setting M (M1, M2 and M3), wherein M1 is the preset number of the first sponsoring nodes, M2 is the preset number of the second sponsoring nodes, M3 is the preset number of the third sponsoring nodes, and M1 is less than M2 is less than M3;

presetting a time interval correction coefficient matrix N, setting N (N1, N2, N3), wherein N1 is a preset first time interval correction coefficient, N2 is a preset second time interval correction coefficient, N3 is a preset third time interval correction coefficient, and N1< N2< N3<1;

if the number of the sponsored nodes is m=m1, setting a time interval correction coefficient n=n1, and monitoring a time interval t=n1×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes is m=m2, setting a time interval correction coefficient n=n2, and monitoring a time interval t=n2×ti after correction in real time, (i=1, 2, 3);

if the number of the sponsored nodes m=m3, setting a time interval correction coefficient n=n3, and monitoring the time interval t=n3×ti after correction in real time, (i=1, 2, 3).

8. The workflow in-stream Cheng Cuiban method of claim 7, wherein upon obtaining feedback instructions from said monitoring time node, comprising:

acquiring task processing states of all the sponsoring nodes according to the monitoring time nodes;

generating a feedback instruction according to the number m of the to-be-sponsored nodes and the task processing state in the to-be-sponsored process;

if m=1;

when the task processing state is finished, generating a primary feedback instruction;

when the task processing state is incomplete, generating a secondary feedback instruction;

if m is not equal to 1, setting an unfinished node threshold;

acquiring the number m1 of the incomplete hastening nodes in the task processing state;

if m1 is smaller than the unfinished node threshold, generating a second-level feedback instruction;

and if m2 is larger than the unfinished node threshold, generating a three-level feedback instruction.

9. The workflow in-stream Cheng Cuiban method of claim 8, wherein modifying said sponsored instruction based on said feedback instruction comprises:

acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the second-level feedback instruction, acquiring a previous prompting instruction of a procedure to be prompted, and setting a current prompting instruction according to the previous prompting instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a second-level instruction;

when the previous instruction is a second-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1.

10. The workflow in-stream Cheng Cuiban method of claim 9, wherein modifying the sponsored instruction based on the feedback instruction further comprises:

acquiring a feedback instruction of a current monitoring node of a flow needing to be sponsored;

if the instruction is the three-level feedback instruction, acquiring a previous instruction of the flow to be sponsored, and setting a current sponsored instruction according to the previous instruction;

when the previous instruction is a first-level instruction, setting the current instruction as a third-level instruction;

when the last prompting instruction is a second-level prompting instruction, setting the current prompting instruction as a third-level prompting instruction, acquiring a last monitoring time interval t1, and setting a real-time monitoring time interval t=m1×t1, wherein m1 is a compensation coefficient, and m1 is less than 1;

when the last prompting instruction is a three-level prompting instruction, setting the current prompting instruction as the three-level prompting instruction, acquiring the last monitoring time interval t1, and setting the real-time monitoring time interval t=m2×t1, wherein m2 is a compensation coefficient, and m2< m1<1.