CN1783805A - Method and device for controlling excited data flow, and excited message producer - Google Patents

Abstract

This invention discloses a flow control method for drive data including: designing a desired bandwidth of the drive data to obtain the actual bandwidth of the current time, comparing the actual and the above mentioned expected widths to generate the delay of the drive data, obtaining said delay to adjust the generation time of the data based on the data. This invention also discloses a flow control device for drive data and a drive message generator.

Description

A kind of flow control methods of excited data and device, excited message producer

Technical field

The present invention relates to the emulation technology of Digital Logical Circuits, particularly relate to excited data flow control methods and device, have the excited message producer of this control device.

Background technology

In the design process of Digital Logical Circuits, adopt computer simulation technique to verify the correctness of its design usually: in the environment of computer simulation, to check the working condition of Digital Logical Circuits.Digital Logical Circuits uses hardware design language to describe usually, and a Digital Logical Circuits normally is made up of a plurality of hardware language code files.Some EDA business softwares, such as the Modelsim of Mentor company, Digital Logical Circuits that can the simulation hardware language description, thus verify its design correctness.

When the simulated digital circuit logic, need apply data at the Digital Logical Circuits input port, i.e. excited data.For example, when carrying out the emulation of communication class Digital Logic, be applied to the data flow (excited message) of Digital Logical Circuits input port, the IP message is more typically arranged.That is to say that excited message is the communication packet under simulated environment, input to by the Digital Logical Circuits of emulation with excited message usually, whether correct by emulation check dight logical circuit to the processing of communication packet.Therefore, should make excited message near actual communication packet as far as possible.

When carrying out the emulation of communication class large scale digital logical circuit, excited message production method used in the prior art generally is directly to programme with C language or script.

The excited message producer of prior art comprises stimulating module and message constructing module.When generating excited message, at first by the value of stimulating module Initial message field; Call the message constructing module then, these field groups are synthesized the head of Ethernet message, and append to the afterbody of message buffer by Ethernet message constructed fuction.

When constructing the message of multi-layer protocol encapsulation, as the message d among Fig. 1, call the heading constructed fuction of Ethernet (Ethernet) earlier, call the constructed fuction of IPv4, TCP, Payload then successively.After message produces, just pass to emulation logic (promptly being in the Digital Logical Circuits under the simulation status) immediately.

Excited message producer of the prior art and the method part that comes with some shortcomings: at first, because message is directly passed to emulation logic after producing, the message flow of generation does not have traffic characteristic, can't the target flow size, the time interval that also can't provide adjacent message is to meet the flow of appointment.Secondly, actual message flow is a kind of unordered, but the data flow of certain traffic characteristic is arranged, it generally is the unordered mixing of a plurality of message flows, therefore, when carrying out the checking of communication class large scale digital logical circuit functional simulation,, be difficult to realize the generation of reusing, support various excitation communication packets of stimulating module because prior art does not possess flow control function.

Summary of the invention

The technical problem that the present invention solves is to provide a kind of flow control methods of excited data and device, excited message producer, can support the flow definition of excited message, realizes the flow control of excited data.

For this reason, the technical scheme of technical solution problem of the present invention is: a kind of flow control methods of excited data is provided, comprises:

1) desired bandwidth of excited data is set;

2) obtain the actual bandwidth of current time;

3) more described actual bandwidth and aforesaid desired bandwidth generate the time-delay of excited data;

4) obtain the time-delay of described excited data, and regulate the generation time of excited data according to the time-delay of this excited data.

Preferably, described step 2) in, obtain actual bandwidth and specifically comprise:

Upgrade the capacity of excited data; Obtain current time and the time difference that last time produced the time of excited data; Obtain actual bandwidth according to described capacity and time difference.

Preferably, in the described step 3), generate time-delay and specifically comprise:

Obtain the difference of desired bandwidth and actual bandwidth, obtain time-delay according to the capacity of excited data and this difference.

Preferably, this method also comprises: in described step 1), the number of the maximum excitation data cell of statistics bandwidth is set; In described step 2) the capacity of renewal excited data the time, judge whether the number of excited data unit surpasses the number of this maximum excitation data cell; If then remove initial excited data unit and enough upgrade; If not, then directly upgrade.

Preferably, described excited data unit forms the excited data unit and describes formation, and each member of this formation is an excited data unit description entry, and excited data unit description entry comprises the generation time of excited data and the byte number of this excited data.

Preferably, the adjustment process of described step 4) specifically comprises: whether the time-delay of judging this excited data is greater than predetermined value; If not, then generate excited data; If wait for that then the time-delay back generates excited data; After generating excited data, described step 4) also comprises the actual bandwidth that obtains the current time again.

The present invention also provides a kind of volume control device of excited data, comprising:

Desired bandwidth is provided with interface, is used to be provided with the desired bandwidth of excited data;

The actual bandwidth acquiring unit is used to obtain the actual bandwidth of current time;

The time-delay generation unit is used for more described actual bandwidth and described desired bandwidth, generates the time-delay of excited data.

Preferably, described actual bandwidth acquiring unit comprises:

The bandwidth refresh unit is used to calculate the actual bandwidth of current time;

Actual bandwidth obtains interface, is used to feed back this actual bandwidth.

Preferably, comprise that also the maximum excitation data cell number of adding up bandwidth is provided with interface, is used to the actual bandwidth acquiring unit that maximum excitation data cell number is provided.

The present invention also provides a kind of excited message producer, comprise the excited message generation unit, the volume control device that also comprises foregoing excited data, this volume control device and described excited message generation unit carry out data interaction, are used for transmitting to described excited message generation unit actual bandwidth and the time delay of current time; Described excited message generation unit generates the time of excited data according to this time delay decision.

With respect to prior art, the present invention the invention has the beneficial effects as follows: owing to can obtain the actual bandwidth of current time in real time, and the desired bandwidth of this actual bandwidth and setting is compared, obtain producing the time-delay that the excited message data should be carried out, thereby can provide flow control function for the module that produces excited message.

In addition, in the preferred embodiments of the invention, can also dynamically set the sample number of statistics bandwidth, thus the average effect that control bandwidth is calculated.

The present invention generally is applied in the logical simulation device, can after producing excited data, calculate the generation speed of excited message in real time, thereby obtain by the disposal ability of emulation logic, be convenient to further understand its service behaviour, for the design and the checking of Digital Logical Circuits provides reliable reference.

In addition, the type of the present invention and excited data is irrelevant, but widespread usage has stronger reusability in the various excited message generation devices that need flow control.

Description of drawings

Fig. 1 is a kind of schematic diagram of message of multi-protocols encapsulation;

Fig. 2 is the schematic diagram of excited message producer of the present invention;

Fig. 3 is the block diagram of volume control device shown in Figure 2;

Fig. 4 is the block diagram of another execution mode of volume control device shown in Figure 2;

Fig. 5 is the schematic diagram of excited message description entry formation among the present invention;

Fig. 6 is the flow chart of the flow control methods of excited data of the present invention;

Fig. 7 is the flow chart that obtains actual bandwidth among the present invention;

Fig. 8 is the block diagram of the application example of excited message producer of the present invention.

Embodiment

See also Fig. 2, excited message producer 100 of the present invention comprises volume control device 110, the excited message generation unit 120 of excited data.Described volume control device 110 carries out data interaction with described excited message generation unit 120, is used for transmitting actual bandwidth and the time delay of current time to described excited message generation unit 120; Described excited message generation unit 120 is used to generate excited data, generates the time of excited message according to this time delay decision.

Need to prove, among the present invention, the described current time is determined by simulation time, Digital Logical Circuits all carries clock module usually when emulation, this clock module is started working from 0 when emulation constantly, produce clock pulse, simulation time is exactly in simulation process, the chronometric data of this clock module.Simulation time does not generally have related with the time of computer system.Described bandwidth is meant the speed of excited data feed-in emulation logic, and unit is a BPS.In the embodiment among the present invention, be the flow control of example explanation to excited data with the excited message.But, be appreciated that the present invention is not limited to the flow control to excited message.

Consult Fig. 3 in the lump, this volume control device 110 comprises that desired bandwidth is provided with interface 111, actual bandwidth acquiring unit 112, time-delay generation unit 113.The generation unit 113 of wherein delaying time is provided with the desired bandwidth of interface 111 settings and the actual bandwidth that actual bandwidth acquiring unit 112 obtains according to desired bandwidth, generates the time-delay of excited data.

Desired bandwidth is provided with the desired bandwidth that interface 111 is used to be provided with excited data, produces the speed of excited message as user expectation.

Actual bandwidth acquiring unit 112 is used to calculate the bandwidth of current time, and excited message generation unit 120 need send two input parameter SimTime and SendByteNum to it when starting actual bandwidth acquiring unit 112.Input parameter SimTime must be current simulation time, and this time is always more than or equal to the time of last time calling input; Input parameter SendByteNum is the excited message byte number that produces the current time.

Described input parameter can be 0, and the expression current time does not produce excited message, usually occurs in excited message generation unit 120 before judging whether to produce message, when refreshing bandwidth.In addition, excited message generation unit 120 generally all will start actual bandwidth acquiring unit 112, to refresh bandwidth after producing message.

Time-delay generation unit 113 is used for the gap of actual bandwidth and the desired bandwidth of comparison current time, if actual bandwidth, then returns one greater than desired bandwidth greater than 0 delay data A, expression time-delay A produces excited data again after the time; If actual bandwidth is less than desired bandwidth, time-delay generation unit 113 returns one less than 0 data, and expression can produce excited data now.

Actual bandwidth acquiring unit 112 is when computation bandwidth, and what usually adopt is statistic algorithm, be in a period of time to the quantitative statistics of excited message data, the time span of statistics is big more, sample number is many more, average effect is strong more.But, need limit to some extent sample number for the consideration of efficient and resource.

Consult Fig. 4 in the lump, actual bandwidth acquiring unit 112 comprises that bandwidth refresh unit 1121 and actual bandwidth obtain interface 1122.Wherein, bandwidth refresh unit 1121 is calculated the bandwidth of current time, and obtains interface 1122 by actual bandwidth and send to excited message generation unit 120.

In the volume control device 110 of the present invention, comprise that also the maximum excitation data cell number of adding up bandwidth is provided with interface 114, be used to actual bandwidth acquiring unit 112 that maximum excitation data cell number is provided, as the maximum excitation message sample number of computation bandwidth is set.

During work, excited message producer at first carries out initialization, the maximum excitation data cell number that excited message generation unit 120 startup desired bandwidths are provided with interface 111 and statistics bandwidth is provided with interface 114, and speed and maximum excitation message sample number that expectation produces excited message are set.

Before generating excited message, excited message generation unit 120 starts bandwidth refresh unit 1121, calculates the actual bandwidth of current time; Start actual bandwidth subsequently and obtain interface 1122, obtain the bandwidth calculation result; Restart time delay generation unit 113, currently whether can generate excited message to judge.

After producing message, generally can start bandwidth refresh unit 1121, to refresh bandwidth, obtain up-to-date bandwidth calculation result.

See also Fig. 5, in the flow control methods of excited data of the present invention, safeguard the formation of an excited message description entry, each member of this formation is an excited message description entry, and the excited message description entry comprises the generation time of excited message and the byte number of this excited message.Adopt counter to come the byte number summation of all excited messages in the recorded message formation simultaneously.Based on the control that the management of this excited message description entry formation and inquiry is realized to flow.

Usually, the formation of excited message description entry has a length restriction, and inside defaults to 255, and the maximum excitation data cell number of statistics bandwidth is provided with interface 114 and is used to be provided with this restriction.

See also Fig. 6, introduce the flow process of the flow control methods of excited data of the present invention below.

Step S1 is provided with the desired bandwidth of excited data.

When the excited message producer initialization, excited message generation unit 120 starts desired bandwidth interface 111 is set, and the speed that expectation produces excited message is set.

Step S2 obtains the actual bandwidth of current time.

Excited message generation unit 120 starts bandwidth refresh unit 1121, calculates the actual bandwidth of current time; Start actual bandwidth subsequently and obtain interface 1122, obtain the bandwidth calculation result.Excited message generation unit 120 need send two input parameter SimTime and SendByteNum to bandwidth refresh unit 1121.Input parameter SimTime must be current simulation time, and this time is always more than or equal to the time of last time calling input; Input parameter SendByteNum is the excited message byte number that produces the current time, and this parameter S endByteNum can be 0 before generating excited message.

Step S3, more described actual bandwidth and aforesaid desired bandwidth generate time-delay.

Excited message generation unit 120 starts time-delay generation units 113, and the relatively actual bandwidth of current time and the gap of desired bandwidth are if actual bandwidth, then returns one greater than desired bandwidth greater than 0 delay data A; If actual bandwidth is less than desired bandwidth, time-delay generation unit 113 will return one less than 0 data.

Step S4 obtains described delay data, according to the generation time of described delay data control excited data.

If excited message generation unit 120 receives the delay data A greater than 0, then expression time-delay A produces excited data again after the time; Otherwise expression can produce excited data now.

What need further specify is, except delay data and 0 can being compared, be the flexibility of increase to the control of the generation time of excited data, can also further be provided with one according to the needs of various actual conditions is not 0 predetermined value, thereby more described delay data and this predetermined value after obtaining described time-delay judge that whether this time-delay is greater than predetermined value; If not, then generate excited data; If wait for that then the time-delay back generates excited data.

In addition, after producing message, excited message generation unit 120 generally can start bandwidth refresh unit 1121, to refresh bandwidth, obtains up-to-date bandwidth calculation result.

Seeing also Fig. 7, is in the flow control methods of excited data of the present invention, calculates the flow chart of an example of actual bandwidth.Consult Fig. 5 in the lump, safeguard the formation of an excited message description entry in this example.

After bandwidth refresh unit 1121 started, execution in step S11 judged whether input parameter SendByteNum is 0; If then enter step S18; If not, then enter step S12.

Step S12, when input parameter SendByteNum was not 0, bandwidth refresh unit 1121 was added the excited message description entry in formation.

Subsequently, execution in step S13, bandwidth refresh unit 1121 is revised counter, with the value adding byte number summation of input parameter.

Step S14, the length value of renewal excited message description entry formation.

Step S15 judges whether the length of excited message description entry formation surpasses restriction; If not, then enter step S18; If then enter step S16.

Step S16, bandwidth refresh unit 1121 is revised counter, deducts the excited message byte number of deleted excited message description entry appointment in the byte number summation.

Step S17, bandwidth refresh unit 1121 is removed the excited message description entry that adds the earliest.

Step S18 recomputates the actual bandwidth of current generation excited message.The computational process of actual bandwidth is as described below.

At first, calculate the time of excited message description entry rear of queue excited message description entry appointment and the gap TimeGap of current simulation time (input parameter SimTime):

The time of TimeGap=input parameter SimTime-tail excited message description entry appointment.

Subsequently, calculate actual bandwidth:

Actual bandwidth=total bytes * 8/TimeGap.

Then, actual bandwidth obtains interface 1122 the aforementioned calculation result is returned.

After obtaining actual bandwidth, time-delay generation unit 113 calculates the time-delay that excited message generates:

Time-delay=total bytes/desired bandwidth-total bytes/actual bandwidth.

In the above-mentioned execution mode, need calculate total bytes according to the maximum accounting message sample number that is provided with.Be appreciated that and also can adopt fairly simple bandwidth acquisition methods, promptly only the byte number of the excited message that produces is added up, when calculating actual bandwidth, from simulation time 0 constantly begin to the current time be lead time:

The current simulation time of TimeGap=

Then, actual bandwidth=total bytes * 8/TimeGap, wherein, total bytes represents from simulation time 0 constantly, up to the present, the byte number summation of all excited messages of generation.

Seeing also Fig. 8, is an application example of the volume control device of excited data of the present invention.

In this application example, excited message producer 100 is used for providing the excited message data for emulation logic (HDL DUV) 900 and reference unit 810 simultaneously, the result of 900 pairs of described excited messages of emulation logic (HDL DUV) sends to comparing unit 820 as a result, comparing unit 820 compares the result of this result and reference unit 810 as a result, finishes the design verification of Digital Logical Circuits.Wherein, the volume control device 110 and the excited message generation unit 120 of excited data carry out data interaction, to determine to generate the opportunity of excited message data.

Emulation logic (HDL DUV) 900 normally is made up of a plurality of hardware language code files, carries out communication, swap data by first bus interface module 910 with excited message generation unit 120; Carry out communication by second bus interface module 920 and comparing unit 820 as a result.Wherein, first bus interface module 910 and second bus interface module 920 are interface modules of being write as by hardware language.

The function of emulation logic (HDL DUV) 900 is supported that by simulation engine 800 simulation engine 800 is a business logic emulation software, such as the Modelsim of Mentor company.

When emulation begins, first bus interface module 910 is to excited message generation unit 120 application messages, excited message generation unit 120 query flows control device 110 to determine being to produce excited message to give first bus interface module 910, still return time-delay and give first bus interface module 910.If first bus interface module 910 obtains delay data, will carry out time-delay, the after date of delaying time is once more to excited message generation unit 120 application messages; If first bus interface module 910 obtains the excited message data, then the excited message data are sent to emulation logic (HDL DUV) 900.After data send and finish, once more to excited message generation unit 120 application messages.

Excited message generation unit 120 passes to the excited message of first bus interface module 910, and the portion that also is copied passes to reference unit 810.Reference unit 810 generally is the user with the module with emulation logic (HDL DUV) 900 same processing capacities finished of c/c++ language compilation.The output of the output of reference unit 810 and second bus interface module 920 is comparing in the comparing unit 820 as a result, handles the correctness of excited message to judge emulation logic.

The above only is a preferred implementation of the present invention; should be pointed out that for those skilled in the art, under the prerequisite that does not break away from the principle of the invention; can also make some improvements and modifications, these improvements and modifications also should be considered as protection scope of the present invention.

Claims (10)

1. the flow control methods of an excited data is characterized in that, comprising:

1) desired bandwidth of excited data is set;

2) obtain the actual bandwidth of current time;

3) more described actual bandwidth and aforesaid desired bandwidth generate the time-delay of excited data;

4) obtain the time-delay of described excited data, and regulate the generation time of excited data according to the time-delay of this excited data.

2. the control method of excited data flow according to claim 1 is characterized in that, described step 2) in, obtain actual bandwidth and specifically comprise:

Upgrade the capacity of excited data; Obtain current time and the time difference that last time produced the time of excited data; Obtain actual bandwidth according to described capacity and time difference.

3. the control method of excited data flow according to claim 2 is characterized in that, in the described step 3), generates time-delay and specifically comprises:

Obtain the difference of desired bandwidth and actual bandwidth, obtain time-delay according to the capacity of excited data and this difference.

4. according to the control method of claim 2 or 3 described excited data flows, it is characterized in that, in described step 1), also comprise the number of the maximum excitation data cell that the statistics bandwidth is set; In described step 2) the capacity of renewal excited data the time, judge whether the number of excited data unit surpasses the number of this maximum excitation data cell; If then remove initial excited data unit and enough upgrade; If not, then directly upgrade.

5. the control method of excited data flow according to claim 4, it is characterized in that, described excited data unit forms the excited data unit and describes formation, each member of this formation is an excited data unit description entry, and excited data unit description entry comprises the generation time of excited data and the byte number of this excited data.

6. according to the control method of each described excited data flow of claim 1 to 3, it is characterized in that the adjustment process of described step 4) specifically comprises: whether the time-delay of judging this excited data is greater than predetermined value; If not, then generate excited data; If wait for that then the time-delay back generates excited data; After generating excited data, described step 4) also comprises the actual bandwidth that obtains the current time again.

7. the volume control device of an excited data is characterized in that, comprising:

Desired bandwidth is provided with interface, is used to be provided with the desired bandwidth of excited data;

The actual bandwidth acquiring unit is used to obtain the actual bandwidth of current time;

The time-delay generation unit is used for more described actual bandwidth and described desired bandwidth, generates the time-delay of excited data.

8. volume control device according to claim 7 is characterized in that: described actual bandwidth acquiring unit comprises:

The bandwidth refresh unit is used to calculate the actual bandwidth of current time;

Actual bandwidth obtains interface, is used to feed back this actual bandwidth.

9. volume control device according to claim 7 is characterized in that: comprise that also the maximum excitation data cell number of adding up bandwidth is provided with interface, is used to the actual bandwidth acquiring unit that maximum excitation data cell number is provided.

10. excited message producer, comprise the excited message generation unit, it is characterized in that: also comprise volume control device as each described excited data of claim 7 to 9, this volume control device and described excited message generation unit carry out data interaction, are used for transmitting to described excited message generation unit actual bandwidth and the time delay of current time; Described excited message generation unit generates the time of excited data according to this time delay decision.

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