RU2024055C1 - Device simulating servicing of different-priority requests - Google Patents

Abstract

FIELD: computer engineering. SUBSTANCE: device has three AND gates, two flip-flops, delay element, second and third OR gates; each model of servicing device is provided with time interval determining unit; each servicing device orienting unit is fitted with three flip-flops, two AND gates, OR gate, and delay element. EFFECT: improved simulating accuracy. 1 dwg

Description

 The invention relates to computer technology, is intended to simulate the process of servicing two application flows with different priorities by one serving device, and can be used to model the process of servicing applications in priority queuing systems with orientation.

 A device for modeling the process of servicing applications with different priorities, containing two pulse generators with random intervals, three And elements, two triggers, a ban element and a limiting diode [1]. This device is designed to simulate the process of servicing applications of two flows by one serving device, each of which has its own priority.

 However, this device does not simulate the orientation mode of the servicing device of the queuing system during the transition from servicing claims of one flow to servicing claims of another flow when switching from servicing one claim to another of the same flow and, conversely, which reduces the accuracy of modeling the service process.

 The closest in technical essence to the proposed one is a device for modeling the process of servicing applications with different priorities, containing an AND element, an OR element, a trigger, a counting pulse generator, the first and second orientation units of the service device, each of which includes a trigger, an And element, and a determination unit time intervals, the first and second model of the servicing device, each of which contains a pulse generator with a random interval, an element And a trigger [2].

 In many real-life priority queuing systems with orientation, it is required immediately after servicing applications before the arrival of the next application to carry out the orientation of the serving device.

 However, the known device does not allow to simulate the orientation mode of the servicing device of the mass service system of applications of various flows immediately upon completion of service of applications, i.e. it does not allow for the early orientation of the device to servicing applications of various priorities in the time intervals between the time when the next application ends and the moment the next application passes to one of the device’s two inputs. This limits the functionality and throughput of the device when modeling the process of servicing applications with different priorities and leads to the emergence of a significant number of unserved and lost applications.

 The purpose of the invention is improving the accuracy of modeling.

 The drawing shows a structural diagram of a device for modeling the process of servicing applications with different priorities.

 The device contains the input of 1 applications with a low priority, the input of 2 applications with a high priority, the first trigger 3, the first element 4, the first 5, the second 6 and the third 7 elements OR and the generator 8 counting pulses, the first 9, the second 10, the third 11, the fourth 12, fifth 13, sixth 14, seventh 15, eighth 16 counters, first 17 and second 18 orientation unit servicing devices, each of which contains the third 19, fourth 20, first 21 and second 22 triggers, third 23, fourth 24, first 25 and the second 26 AND elements, OR element 27, time interval determination unit 28, element 29 beyond erzhki, a first 30 and a second pattern 31 serving device, each of which comprises an input 32, AND gate 33, flip-flop 34, the unit 35 determining the time intervals, the pulse generator 36 with a random repetition interval. The device also includes a second element And 37, a third element And 38, a third trigger 39, a second trigger 40, a delay element 41, the first 42 and second 43 outputs of the device.

 The flows of service requests at inputs 1 and 2 are random pulses of a sequence, the intervals between which are distributed according to certain different or the same laws.

 Models 30 and 31 simulate one serving device, the law of distribution of random pulses at the outputs of generators 35 is the same. The time interval from the moment models are launched to the appearance of pulses at their output is random and distributed according to the accepted law of servicing applications.

 Blocks 17 and 18 simulate the process of orienting a service device toward servicing applications with different priorities. Claims with a low priority of service are received at input 1, and claims with a high priority of service are sent to input 2. At output 42, an outgoing stream of serviced low priority requests is formed, and at output 43, an outgoing flow of serviced high priority requests is formed.

 Counters 9 and 10, respectively, are designed to count pulses arriving at inputs 1 and 2 of the device and simulating the flows of incoming applications of low and high priority. Counters 11 and 12, respectively, are intended for counting pulses, the number of which characterizes the number of unserved low and high priority requests. Counters 13 and 14, respectively, are designed to count pulses from nodes 28 in blocks 17 and 18. Counters 15 and 16, respectively, are designed to count pulses, the number of which characterizes the number of served low- and high-priority applications. The nodes 28 for determining the time intervals in blocks 17 and 18 are binary counters, the capacity of which can be changed depending on the size of the time interval required for the orientation of the device to serve this flow of requests, and can be made in the form of a delay element with a variable amount of delay.

Blocks 35 for determining time intervals in the first and second models of the serving device are binary counters, the capacity of which can be changed depending on the value of the time interval t _n , which is the threshold value, after which it is not practical to interrupt the application service, i.e. if t ₁ is the application service start time, t ₂ is the application service end time, then t _n (t ₁ <t _n <t ₂ ) is the time after which the interruption of the application service is impractical.

 The verbal model of the device is as follows. Two random streams of service requests, each of which has its own priority in service, is received by one service device. Low priority service requests are accepted for service if there are no high priority service requests.

If the application with a higher priority was received during the service period of the application with a low priority and the time t _{o of} its service was t ₁ <t _o <t _n , then the service of the application with a low priority is terminated and the device starts orienting towards servicing a high priority application, after its completion serving a high priority application, while the low priority application is lost.

If the application with a higher priority was received during the service period of the application with a low priority and the time to its service was t _o > t _n , then the service of the application with a low priority does not stop and the device starts orienting towards servicing a high priority application, after its completion and completion of service of a low priority the application is being serviced by a high priority application.

 After completing the service of an application of various priority, the device, regardless of the arrival of the next application, switches to the mode of early orientation to the application of the priority that has been served before. Only one cycle of advance orientation to the application of the priority that would have been served before passes through the device. If not a single application of this priority arrives at the input of the device until the end of the early orientation cycle, then at the end of the early orientation cycle the device enters the standby mode for servicing the application of the priority that was served by the device before. With the arrival of this application to the input of the device, it immediately goes into the service mode of such an application. If this application arrived before the end of the early orientation cycle, then the moment of its transition to the service mode occurs earlier on the time interval equal to the difference between the moment this application arrives at the input of the device and the moment of the start of the next early orientation cycle.

 Since the device provides only one cycle of advance orientation, this increases the life of the device. The early orientation cycle can take place simultaneously in blocks 17 and 18. In this case, with the appearance of the application at input 1, the early orientation cycle in block 18 is not interrupted, with the arrival of the application for input 2 of the device, the early orientation cycle in block 17 is interrupted.

 If an application with a higher priority was received during the orientation of the device to servicing a low priority application, then this orientation is interrupted and the orientation of the servicing device to servicing a high priority application begins, and the low priority application is lost.

 The device operates as follows.

Models 30 and 31 of the service device operate as follows. In the initial state, the trigger 34 is installed in a position in which the element And 33 is open. The application arriving at the input of the model passes through the And 33 element, overturning the trigger 34, and starts the block 35 determining the time intervals, which corresponds to the beginning of the service. After time t _{n, the} pulse from the output of block 35 starts the generator 36. After a random interval of time, the generator 36 generates a pulse that transfers the trigger 34 to its original state, thereby opening the model input. Signals of disruption of the operation of block 35 may be received at the input 32 of the shutdown of block 35 of model 30.

 The device can operate in the modes of servicing a low priority application, servicing a high priority application with interruption of servicing a low priority application, servicing a high priority application after additional servicing of a low priority application without interrupting servicing of a low priority application, and orienting the device to servicing a low (high) priority application upon termination of service applications of low (high) priority, acceptance of applications of low (high) priority and its servicing without prior orientation ation device to service requests low (high) priority, if its arrival completed the second cycle of advance orientation of the device to the service running from the previous application a low (high) priority.

 After the device is turned on in the initial position, trigger 3 is set to a position where the resolving voltage is present at the second input of I4, trigger 39 to a position where I 37 is open, trigger 40 to a position where I 38 is closed.

 In blocks 17 and 18, the orientation of the servicing device for servicing applications of low and high priority after switching on the device, the triggers 19, 20, 21 and 22 are set to the initial state, as a result of which the enabling voltages from the inverted outputs of the triggers 19 and 20 are applied to the And 23 and 24, which become open at direct exits. At the output of the triggers 21 of the blocks 17 and 18 connected to the first inputs of the I25 elements of the blocks 17 and 18, there are no resolving voltages, the second inputs of the I25 elements receive counting pulses from the generator 8. The voltage at the inputs of the nodes 28 in the blocks 18 and 17 connected to the outputs there are no I25 elements, the triggers 22 in blocks 17 and 18 are in a state in which the I26 elements in these blocks are closed at the direct output and open at the inverse. There is no voltage at the triggering inputs of generator 36 in models 30 and 31. Subsequently, in all operating modes, the operability of the device is maintained automatically.

 Service applications of low priority is as follows.

 The pulse from input 1 goes to the input of the counter 9 and to the first input of the open element And 4. From the output of the element And4, the pulse goes to the second input of the element And23 block 17.

 Consider the operation of block 17 orientation of applications of low priority. Since the first voltage input of the I23 element receives the enabling voltage from the inverse output of the trigger 19, the pulse from the output of the I4 element appears at the direct output of the I23 element, which is fed to the single input of the trigger 22 and puts it into a state in which the And 26 element opens in a straight line the output, as well as through the OR element 27, is supplied to the single input of the trigger 21, translating it into the state in which the I25 element is opened, and through its counting pulses from the generator 8 begin to flow to the node 28. The counter capacity of the node 28 is set in advance, depending on the size of the time interval required for the orientation of the device to service low priority requests, and when this counter is filled, an impulse appears at the output of node 28, which simulates the end of the orientation of the device to service low priority applications. This pulse is supplied to the first input of the I26 element, open by direct output. At the same time, this pulse passes through the delay element 29 to the zero input of the trigger 22, translating it into a state in which the I26 element closes at the direct output and opens at the inverse. The same pulse from the output of the node 28 simultaneously enters the input of the counter 13 and through the OR5 element to the zero input of the trigger 21 in the block 17, setting it to its original state, in which the I25 element is closed and the counting pulses from the generator 8 do not arrive at the node 28. The pulse from the output of the node 28 appears at the direct output of the I26 element and, having passed the OR element 6, it enters the second input of the I33 element of model 30, to which the enabling voltage is supplied from the trigger 34 in the model 30, and at the same time it enters the installation input to the “0” trigger 19 block 17, confirming its condition of. After passing through the element I33, this pulse is fed to the input of the start of block 35 of model 30.

 The launch of model 30 simulates the start of serving a low priority application. After a random interval of time, a pulse appears at the output of model 30, simulating the end of the service of a received request passing to the output 42 of the device, the input of the counter 15 and to the zero input of the trigger 20 in block 17, confirming its initial state, as well as through the element OR27 to the single input of the trigger 21 of block 17, setting it in a state in which the I25 element opens, and through it the counting pulses from the generator 8 begin to flow to the node 28. Thereby, the beginning of the cycle of the block 17's early orientation toward servicing low priority wok immediately after the next service applications, ie in intervals between receipt of applications.

 The application, which came from input 1 during the cycle of the servicing device early orientation under the influence of a pulse from the output of model 30, passes through the open element I 23 of block 17 to the single input of trigger 22, putting it into a state in which the element I26 opens on direct output, and upon completion of the cycle of early orientation of the pulse from the output of node 28, it enters the input of model 30, thereby simulating the end of orientation in block 17 and the beginning of servicing this application by model 30.

 The application, which came to the service of the next application during orientation of the device, enters block 17, confirms the state of the triggers 21 and 22, and is lost, since when it appears during the orientation interval, no changes in the circuit occur.

 The application, which arrived during the servicing of the previous application and model 30, enters through the open element I4 to the second input of the element And 23 in block 17 and appears on its open direct output. Further, this pulse arrives at the single input of the trigger 22, transferring it to a state in which the And 26 element opens at the direct output. In addition, this pulse from the output of the And 23 element passes through the OR element 27 to the single input of the trigger 21, transferring it to the state in which the And 25 element opens, and counting pulses from the generator 8 to the input of the node 28 begin to flow through it. corresponding to the orientation time from the output of the node 28, the pulse through the open direct output of the AND 26 element and through the OR 6 element is fed to the triggering input of the model 30, as well as to the input of the counter 13, through the OR 5 element to the zero input of the trigger 21, prohibiting the passage of counting pulsest generator 8 to node 28 through delay element 29 at zero trigger input 22, converting it into a state in which the AND gate 26 is opened by the inverse output of the direct and closed. If the service of the previous application has not yet ended, then the received application from block 17 to the service is not accepted and is lost. If the service of the previous application has ended, then the received application is serviced after orienting the device to service.

 If until the end of the service of the next application, i.e. until a pulse appears at the output of model 30, a low priority order is not received at input 1, then a pulse simulating the end of service of a received order is sent to the zero input of trigger 20, confirming its initial state, as well as through unit OR 27 in block 17 to a single trigger input 21, and according to the above algorithm, in block 17, a cycle of early orientation of the serviced device to servicing the next low priority application begins. If even before the appearance of the pulse at the output of the node 28, no application arrives at input 1, then the pulse from the output of the node 28 passes through the delay element 29 and confirms the state of the trigger 22, and this pulse also enters the input of the counter 13, through the OR element 5 to the zero input of the trigger 21, thereby closing the element And 25. In addition, this pulse is fed to the first input of the element And 26 and appears on its inverse output, coming from it to the single input of the trigger 19, setting it in a state in which the element And 23 closes at the direct exit and opens on the inverse. Thus, in block 17, the process of early orientation to servicing the next application is completed, and the device is ready for this application of low priority in order to start the service mode with its arrival, bypassing the orientation process. This happens as follows.

 The next application of low priority, which appeared at input 1, passes through the open element And 4, goes to the second input of the element And 23 in block 17 and appears on its inverse output, while arriving at the first input of the element And 24, open at the direct output. From the direct output of the And 24 element, the pulse is supplied to the single input of the trigger 20, transferring it to a state in which the And 24 element closes in a straight line and opens by an inverse output. In addition, the pulse from the output of the AND 24 element simultaneously enters through the OR element 6 to the start input of the model 30, as well as from the output of the OR 6 element, this pulse goes to the zero input of the trigger 19, transferring it to the state in which the And 23 element opens in a straight line exit. In a short period of time, which lasts from the moment a pulse arrives at the single input of trigger 20 until it appears at the zero input of trigger 19, the pulses passing from input 1 sequentially pass through the inverse outputs of elements 23 and 24, respectively, and are lost when they arrive at the counter input eleven.

 If in the process of servicing an application received for servicing to model 30 without delay in block 17, the next application arrives at input 1, then it appears on the direct output of the And 23 element, and block 17 goes into the orientation mode to service the accepted application according to the algorithm described above .

 If the service process of such an application is completed before the next application arrives at input 1, then the pulse from the output of model 30 starts the cycle of early orientation of block 17 again. Next, the application is serviced by the above-described algorithm.

 Serving high priority applications.

 The pulse from input 2 enters the single input of trigger 3 and sets it to the state in which the And 4 element is closed, the enable voltage is removed from its second input and low priority applications do not pass from input 1 to block 17. At the same time, this pulse from input 2 arrives to the counter 10 and to the second input of the element And 23 of block 18. The algorithm of operation of block 18 is similar to the algorithm of operation of block 17. The algorithm of operation of models 30 and 31 is also identical.

 After a random interval of time, an impulse appears at the output of model 31, simulating the end of the service of a received application passing to output 43, to the input of counter 16, to the zero input of trigger 20 in block 18, and also to the zero input of trigger 3, setting it to its original state. The device is ready to receive applications of both high and low priorities.

Serving a high priority application received during the low priority application serving period when its service time t ₁ <t _o <t _n .

 An application of high priority from input 2 goes to the single input of trigger 3, translating it into a state that removes the resolving voltage from element And 4, thereby closing input 1 for incoming applications of low priority. At the same time, this application passes to the installation inputs of node 28 in block 17, disrupting the orientation of the device toward servicing a low priority application, if it was conducted, and to the 32 input of stopping block 35 of model 30, disrupting the maintenance of a low priority application, if it was conducted, as well as through an element OR 5 to the zero input of flip-flop 21 in block 17. If at this moment the device is oriented toward servicing a low priority order or servicing a request of this flow, they are interrupted and lost, and a high priority order is sent through direct my output of AND element 23 of block 18 and through OR element 27 of block 18 to a single input of trigger 21 of this block, translating it into a state when resolution voltage is applied from its output to element And 25 of block 18, and counting pulses from nodes 8 28 of block 18, putting the device into orientation mode to service a high-priority application, after which it will enter service mode. Further, the operation algorithm of block 18 and model 31 is identical to the algorithm of operation of block 17 and model 30.

Serving a high priority application received during the servicing period of a low priority application when its service time t _o > t _n .

At the moment t _o = t _n, when servicing a low priority application, an impulse appears from the output of block 35, which starts the generator 36 and simultaneously flips the trigger 39 to the state in which the And 37 element is closed. The high-priority application, which then arrives at the device, breaks down, as described above, the device’s orientation to servicing the low-priority application and the operation of block 35 of model 30, at the same time putting the device into orientation mode to serving the high-priority application. If before the appearance of a pulse from the output of the OR element 7, the low-priority order service ends, the pulse from the output of the generator 36 of the model 30 sets the trigger 39 to the initial state and the And 37 element is open for the passage of the pulse from the output of the OR element 7. If the pulse comes from the output of the OR element 7 , simulating the receipt of a high-priority application before the low-priority application is completed, it does not pass through the And 37 element, but throws the trigger 40 to the position at which the And 38 element is open. At the end of servicing a low-priority request from the output of the generator 36, the pulse resets the trigger 39 and passes through the open element And 38 to the element 41 of the delay. The delay value is selected so that the pulse from the output of the delay element passed through the OR element 7 to the moment when the trigger 39 is thrown and the And element 37 will be open. After passing through the And 37 element, the pulse from the output of the delay element 41 imitates the receipt of a high priority application to the service device after the low priority application is re-serviced.

 Indicators of service efficiency are determined by measuring the characteristics of input flows of applications, output flows of service and the number of responses of individual units of the device. So, for example, by the indicators of the counters 9 ... 16, it is possible to determine the probabilities of servicing (service interruption) of applications of low and high priority, applications of only low or high priority, probabilities of interruption of the service device in orientation or maintenance mode and other indicators characterizing the process of servicing applications different priorities.

Claims (1)

 DEVICE FOR MODELING THE APPLICATION SERVICE PROCESS WITH VARIOUS PRIORITIES, containing the first AND element, the first OR element, the first trigger, the counter of pulse counters, the first and second models of the service device, each of which includes a pulse generator with a random interval, the And element, and the first trigger and the second orientation unit servicing device, each of which includes a first trigger, the first element And and the node determining the time intervals, and in each orientation unit servicing when ora, the output of the first trigger is connected to the first input of the first element And, the output of which is connected to the start input of the node for determining time intervals, the second input of the first element And is connected to the output of the generator of counting pulses, the output of the node for determining time intervals of the first orientation unit of the servicing device is connected to the first input of the first element OR device, the output of which is connected to the zero input of the first trigger of the first orientation unit of the serving device, the output of the node determining the time intervals in The second unit of orientation of the serving device is connected to the zero input of the first trigger of the second orientation unit of the serving device, the first input of the first element AND of the device is the input of low priority applications, in each model of the serving device the output of the trigger is connected to the first input of the element And, the output of which is connected to the input of the installation in “1” of the trigger, the output of the pulse generator with a random interval is connected to the input of the installation in “0” of the trigger of each model of the servicing device and is the corresponding output of the device, the installation input in “1” of the first trigger of the device, the second input of the first OR element, the stop input of the time interval determination unit of the first orientation unit of the serving device are combined and are the input of the receipt of high priority requests, the output of the pulse generator with a random interval of the second serving model the device is connected to the installation input in "1" of the first trigger of the device, the output of which is connected to the second input of the first element AND of the device, which differs that, in order to improve the modeling accuracy, the second and third AND elements, the second and third triggers, the delay element, the second and third OR elements are introduced into it, a unit for determining time intervals is introduced into each model of the service device, and each orientation unit of the service device is entered the second, third and fourth triggers, the second and fourth AND elements, the OR element and the delay element, and in each orientation unit of the serving device, the output of the time interval determination unit is connected to the first input of the second element And and the input of the delay element, the output of which is connected to the input of the second trigger, the output of which is connected to the second input of the second element And, the direct output of the second element And the first orientation unit of the servicing device is connected to the first input of the second element OR, the output of which connected to the second input of the And element of the first model of the serving device and to the installation input at "0" of the third trigger of the first orientation unit of the serving device, the direct output of the second element And the second orientation unit of the serving about the device is connected to the first input of the third OR element, the output of which is connected to the first input of the second AND element, the installation input to "1" of the second device trigger and the installation input to "0" of the third trigger of the second orientation unit of the serving device, in each orientation unit of the serving device the inverse output of the third trigger is connected to the first input of the third element And, the inverse output of which is connected to the first input of the fourth element And, the direct output of which is connected to the installation input in "1" of the fourth trigger, directly the fourth element AND output in the first orientation unit of the serving device is connected to the second input of the second OR element of the device, the direct output of the fourth AND element in the second orientation unit of the serving device is connected to the second input of the third OR device element, in each orientation unit of the serving device the direct output of the third element And the inverse output of the second element is connected to the input of the installation "1" of the second trigger and the first input of the OR element, the output of which is connected to the input of the installation to "1" of the first trigger And connected to the input of the installation in “1” of the third trigger, the inverse output of the fourth trigger is connected to the second input of the fourth element And in each orientation unit of the serving device, the outputs of the pulse generators with a random interval of the first and second models of the serving device are connected to the input of the installation in “0 "of the fourth trigger and to the second input of the OR element, respectively, of the first and second orientation units of the service device, the output of the first element AND of the device is connected to the second input of the third element And the first unit of orientation of the servicing device, the input of applications of high priority of the device is connected to the second input of the third element And the second unit of orientation of the servicing device, the output of the second trigger of the device is connected to the first input of the third element And, the output of which is connected through the delay element to the third input of the third OR element, the output of the third trigger is connected to the second input of the second element And, the output of which is connected to the second input of the element And of the second model of the serving device, in each model of the output device, the output of the AND element is connected to the input of the time interval determination unit, the output of which is connected to the start input of the pulse generator with a random interval, the output of the pulse generator with a random interval of the first model of the serving device is connected to the second input of the third element AND of the device and the installation input to 0 "of the third trigger, the input of the installation in" 1 "of which is connected to the output of the unit for determining the time intervals of the first model of the serving device, the output of the pulse generator with a random interval following the second model, the service unit is connected to the set input "0" of the second trigger device, the input setting to "0" slot determination unit serving the first model unit coupled to the input of the high priority device applications.

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