KR100907805B1 - Apparatus and method of transfer data between AXI Matrix system and AHB Master system use Wrapper - Google Patents

Abstract

The present invention relates to data processing between an AXI matrix system and an AHB master system bus. More specifically, the present invention relates to AXI transmission in the INCR mode continuous transmission scheme from an AHB master bus. The present invention relates to a wrapper device and a control method for data transmission between an AXI matrix system and an AHB master system that converts from a matrix system bus to a burst transmission method to improve the operation speed of the entire system. The apparatus of the present invention is provided with a bridge connected to the AHB master system and interfacing between the AHB master system and the AXI matrix system to transmit data, wherein the AHB master system is provided by the AHB master system from the HBURST signal transmitted from the AHB master system. AHB wrapper to determine whether the mode, and determine the number of continuous transmission data from the HWIDTH signal transmitted from the AHB master system to generate a converted HBURST signal to the bridge to improve the data transmission rate.

AHB wrapper, judgment output, burst mode generator.

Description

Apparatus and method of transfer data between AXI Matrix system and AHB Master system use Wrapper}

1 is a diagram schematically illustrating a connection configuration between a conventional AHB master system and an AXI matrix system.

2 is a view showing a data transmission waveform using the INCR mode in a conventional AHB master system.

3 shows data transmission waveforms in a conventional AXI matrix system.

4 is a diagram schematically illustrating a connection configuration between an AHB master system and an AXI matrix system of the present invention.

FIG. 5 is a detailed block diagram of the AHB wrapper of FIG. 4. FIG.

6 is a diagram illustrating a data transmission waveform during conversion transmission in an AXI matrix system according to the present invention.

7 is a flow chart for transmitting data in an AXI matrix system using the AHB wrapper of the present invention.

<Description of Major Symbols in Drawing>

100: AHB master system 110: AHB wrapper

112: judgment output section 114: burst mode generator

116: WIDTH storage 120: bridge

130: AXI Matrix System

The present invention relates to data processing between an Advanced Extensible Interface (AXI) matrix system and an Advanced High-performance Bus (AHB) master system bus. More specifically, the burst transmission in INCR mode from the AHB master is performed. The present invention relates to a wrapper device and a control method for data transmission between an AXI matrix system and an AHB master system that converts from an AXI matrix system bus to a burst transmission method to improve the operation speed of the entire system.

In general, to develop a system using an Advanced Extensible Interface (AXI) matrix as a system bus, a hardware designed for a conventional Advanced High-performance Bus (AHB) bus is connected to an AXI matrix. A device is needed.

There is an INCR mode in which AHB master system transmits data in bursts without setting the number of data transmissions in burst mode. However, for continuous transmission of AXI Matrix, the number of data to be transmitted must be determined. The INCR (Increment) mode of AHB does not transmit data continuously in AXI Matrix. It works.

1 is a diagram schematically illustrating a connection configuration between a conventional AHB master system and an AXI matrix system.

As shown in FIG. 1, a device for connecting the conventional AHB master system 20 and the AXI matrix system 40 may use an AHB master interface method using an AHB master interface 30. The transfer of data is handled by converting to Matrix interface.

In the AHB master system 20, only one HBURST has a continuous transmission control signal. In the AHB master system 20, HBURST 3 bits are used to indicate transmission schemes such as SINGLE, INCR, WRAP, etc., and the total number of continuous transmission data such as 1, 4, 8, 16, etc. is displayed.

Meanwhile, in the AXI matrix system 40, there are ARBURST and AWBURST signals that determine transmission modes such as FIXED, INCR, and WRAP (Wrapper) as continuous transmission control signals. It has ARLEN, AWLEN signal which decides the number of consecutive transmission data such as ....., 16.

Therefore, the burst transmission scheme of the AHB master system 20 is converted in the bridge 30 by the burst transmission scheme of the AXI matrix system 40 as shown in Table 1.

In particular, in the case of the INCR mode that does not determine the number of continuous transmission data of the AHB master system 20, it can be seen that the AXI matrix system 40 transmits the number of continuous transmission data by one.

AHB Master System AXI Matrix System HBURST [2: 0] ARBURST [1: 0] ARLEN [3: 0] AWBURST [1: 0] AWLEN [3: 0] SINGLE INCR One INCR INCR One WRAP4 WRAP 4 INCR4 INCR 4 WRAP8 WRAP 8 INCR8 INCR 8 WRAP16 WRAP 16 INCR16 INCR 16

As shown in Table 1, the most problematic point in the conversion of the continuous transmission scheme between the conventional AHB master system 20 and the AXI matrix (Advanced Extensible Interface) system 40 is that When the INCR (Increment) mode is converted from the AHB to AXI Bridge (30) among Burst transmission modes, the AXI matrix system 40 is set to Burst transmission so that there is no data limit, but the number of continuous transmission data is actually limited. Since it is changed to 1 and data is transmitted one by one, there is a problem that the entire system is slowed down.

In the AXI matrix system 40, the number of continuous transmission data is 1 is the same as SINGLE in the AHB master system 20. This is not a burst transmission but one transmission at a time.

In case of accessing the synchronous dynamic RAM (SDRAM), the system slows down the entire system because about 20 clocks are required to prepare one data transfer due to the characteristics of the SDRAM.

2 is a diagram illustrating a data transmission waveform using an INCR mode in a conventional AHB master system.

Referring to FIG. 2, the number of clocks required when 28 data are transferred to INCR, which is a burst transmission mode of the AHB master system 20, is 20 (SDRAM data ready to be clocked) x 1 (transmission occurrences) + 28 (Data Transfer Clock) = 48 clocks.

Referring to FIG. 2, data is transmitted one by one every time an address is increased by HADDER [31: 0].

 SDRAM Data Transfer Ready Clock 20 clocks and 28 data transfer clocks take up to 48 clocks.

 3 shows a data transmission waveform in a conventional AXI matrix system.

Referring to FIG. 3, in the AXI matrix system 40 through the AHB to AXI Bridge 30, the continuous transmission mode INCR does not determine the number of continuous transmission data in the AHB master system 20. Referring to AxLEN [3: 0] of FIG. 3, the number of data is converted to 1 and data transmission is performed. Therefore, it is the same as that transmitted in single mode instead of INCR. . Therefore, there is an urgent need for countermeasures.

In the AXI matrix system 40 of FIG. 3, 28 data were transmitted in the AHB master system in the INCR mode. However, in the AXI matrix system via the bridge, the number of continuous transmission data is only 1, so the required clock is 20 (SDRAM data transmission). Ready clock) x 28 (transmission occurrences) + 8 (data transfer clock) = 568 clocks. Therefore, since the speed of the entire system is slowed down, there is an urgent need for countermeasures.

The present invention solves the above-described problems, the present invention is a situation where the chip development using the Advanced Extensible Interface (AXI) matrix system of the fast system bus is increasing significantly, and the system to which the AXI matrix system is applied AXI matrix system and AHB master system that prevents the slowdown when using the AHB master system by connecting the AHB master system to the AXI matrix system by using hardware blocks developed with the conventional AHB master system can not only shorten the development time but also reduce the bugs. An object of the present invention is to provide a wrapper device and a control method for data transmission between the devices.

In addition, the present invention provides an AXI matrix system and AHB (Advanced High-AHB) device that greatly improves the speed reduction in data transmission in an AXI matrix system by mounting an AHB wrapper device between the AHB master system and the bridge. performance Bus) It is an object to provide a wrapper device and a control method for data transfer between master systems.

In addition, the present invention provides the INCR of the AHB master system so that the burst can be transmitted as much as possible without setting the number of continuous data in the AXI matrix system to 1 when transmitting data in the INCR (Increment) mode of the AHB master system. The purpose is to provide a wrapper device and control method for data transfer between the AXI matrix system and the AHB master system, which improves the speed of the overall system by converting the mode to SINGLE, INCR4, INCR8, INCR16 as necessary. It is done.

The apparatus of the present invention for achieving the above object is provided with a bridge that is connected to the AHB master system and interface between the AHB master system and the AXI matrix system to transmit data, the HBURST signal transmitted from the AHB master system Determine whether the AHB master system is in INCR mode, determine the number of continuous transmission data in the HWIDTH signal transmitted from the AHB master system, and the AHB master system is in the INCR mode and convert HBURST according to the number of continuous transmission data. And an AHB wrapper for generating a signal and providing the signal to the bridge to improve a data transmission speed.

In addition, the AHB wrapper of the present invention receives the HBURST signal from the AHB master system and outputs the HBURST signal as it is when the AHB master system is not currently in INCR mode, and outputs the converted HBURST signal generated by the burst mode generator in the INCR mode. A burst mode generator for determining the number of continuous transmission data from the HWIDTH signal transmitted from the AHB master system, generating the converted HBURST signal according to the number of the continuous transmission data, and providing the converted output to the determination output unit; The number of consecutive transmission data outputted from is determined by storing the number of consecutive transmission data remaining and provided to the burst mode generator to generate the converted HBURST signal, characterized in that consisting of a WIDTH storage device.

The burst mode generator may further include generating and providing the converted HBURST signal until the number of consecutive transmission data received at the AHB master system and remaining in the WIDTH storage device becomes zero, and the burst mode generator generates the continuous HBURST signal. When the number of transmission data is 16 or more, generates a converted HBURST signal to have an INCR16 mode value, the burst mode generator generates a converted HBURST signal to have an INCR8 mode value when the number of consecutive transmission data is 8-15, burst mode The generator includes generating the converted HBURST signal to have an INCR4 mode value when the number of consecutive transmission data is 4-7.

The burst mode generator may also include generating a converted HBURST signal to have a single mode value when the number of consecutive transmission data is 1-3.

The method of the present invention for achieving the above object is a process of receiving the HBURST signal and the HWIDTH signal transmitted from the AHB master system in the AHB wrapper, the AHB master system in the HBURST signal and HWIDTH signal in the AHB wrapper is INCR mode Determining whether the AHB wrapper corresponds to the INCR mode and generating and outputting a converted signal according to the number of the continuous transmission data in the AHB wrapper. It features.

In addition, determining whether the AHB master system is in INCR mode and determining the number of continuous transmission data includes determining whether an INCR mode value exists in the HBURST signal transmitted from the AHB master system, and the INCR mode value in the HBURST signal. And outputting the HBURST signal as it is, and determining the number of continuous transmission data in the HWIDTH signal transmitted from the AHB master system when the INCR mode value is present.

Further, in the AHB wrapper of the present invention, generating and outputting a conversion signal according to the number of continuous transmission data means generating and outputting the conversion signal to have an INCR16 mode value when the number of continuous transmission data is 16 or more. It is characterized by including.

The AHB wrapper according to the present invention generates and outputs a converted signal according to the number of continuous transmission data in INCR 8 mode when the number of continuous transmission data is 8-15, and the number of continuous transmission data is 4-7. In case of the INCR 4 mode, the conversion signal is generated to have a SINGLE mode value when the number of continuous transmission data is 1-3, and the conversion is performed until all of the continuous transmission data transmitted from the AHB master system are transmitted. And generating and outputting a signal.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted.

According to the present invention, the INCR mode of the AHB master system enables the maximum continuous transmission without the number of consecutive transmission data being 1 in the AXI (Advanced Extensible Interface) matrix system when transmitting data in the INCR mode of the AHB master system. In some cases, it converts into SINGLE, INCR4, INCR8, INCR16 according to the amount of total data, and transmits the data quickly, improving the speed of the entire system.

4 schematically illustrates a connection configuration between an AHB master system and an AXI matrix system of the present invention.

In the present invention, when the AHB wrapper 110 is mounted between the AHB master system 100 and the bridge 120 to transmit data in the AHB master system 110 when the AHB wrapper 110 is in the INCR mode. The system is configured to convert to SINGLE, INCR4, INCR8, INCR16 and interface it with the AHB-to-AXI Bridge 120.

The AHB wrapper 110 receives the HWIDTH signal from the AHB master system 100. Receives the HBURST signal to determine whether the current AHB master system is in INCR mode, which is continuous transmission mode, and determines the number of continuous transmission data.In INCR mode, converts to SINGLE, INCR4, INCR8 and INCR16 according to the number of transmission data. The data transfer processing time is shortened when transferring data between the master system 100 and the AXI matrix system 130.

In the conventional case, when transmitting the burst transmission mode INCR in an AXI matrix system through an AHB to AXI bridge in an advanced high-performance bus (AHB) master system, one data can be continuously transmitted at a time. Therefore, the present invention shows that the speed of the entire system is reduced by being transmitted in a single (SINGLE) mode instead of INCR. Thus, the AHB wrapper 110 is mounted between the AHB master system 100 and the bridge 120 to reduce the number of continuous transmission data. By converting SINGLE, INCR4, INCR8, INCR16, etc., it is possible to transmit 16 data at a time in AXI (Advanced Extensible Interface) matrix system, resulting in very short processing time.

FIG. 5 shows a detailed block diagram of the AHB wrapper of FIG. 4.

The AHB wrapper 110 of the present invention includes a decision output unit 112, a burst mode generator 114, and a WIDTH storage unit 116.

The determination output unit 112 receives the iHBURST signal from the AHB master system 100 and determines whether the AHB master system 100 is in an INCR mode which is a current burst transmission mode.

The determination output unit 112 outputs the mode signal as oHBURST as it is from the iHBURST signal when the AHB master system 100 is not in the INCR mode, and receives the tHBURST signal generated by the burst mode generator 114 in the INCR mode to oHBURST. To the output.

The INCH mode of the AHB master system is converted from the AHB wrapper 110 to SINGLE, INCR4, INCR8, INCR16, which is determined by the number of consecutive transmission data.

Referring to the figure, the burst mode generator 114 detects the number of consecutive transmission data from the HWIDTH signal transmitted from the AHB master system, generates a tHBURST signal, and provides it to the determination output unit 112. The determination output unit 112 When the AHB master system 100 is in the INCR mode, the tHBURST signal is output to oHBURST.

As described above, the burst mode generator 114 determines the SINGLE, INCR4, INCR8, and INCR16 by using the HWIDTH signal transmitted from the AHB master system 100 and informs the number of continuous transmission data to generate and determine a tHBURST signal corresponding thereto. It is provided to the output unit 100.

The WIDTH storage unit 116 stores the number of consecutive transmission data remaining after the transmission is made, and the burst mode generator 114 generates a tHBURST signal from the WIDTH storage unit 116. Generate by referring to the number of data to be transmitted.

Burst Mode Generator Input Output iHBURST WIDTH tHBURST INCR 3 ~ 1 SINGLE 7-4 INCR4 15-8 INCR8 16 or more INCR16

Table 2 shows an example of a table for converting the INCR mode of the AHB master system 100 according to data in the burst mode generator 114 of the AHB wrapper 110 of the present invention.

Referring to Table 2, the burst mode generator 114 determines the number of continuous transmission data included in the HWIDTH signal and converts it to INCR16 if it is greater than or equal to 16, and WIDTH information (number of continuous transmission data) is between 15 and 8. Is converted to INCR8, 7 to 4 is converted to INCR4, and WIDTH information (number of consecutive transmission data) is converted to SINGLE from 3 to 1 to generate and provide tHBURST signal.

After the first data transmission is made, the WIDTH storage unit 116 stores the received data by subtracting the number of transmitted data from the total number of consecutive transmission data received.

The WIDTH storage unit 116 is for storing the number of consecutive transmission data remaining after the transmission is made.

In the second or more transmissions, the number of remaining data stored in the WIDTH storage unit 116 is determined to generate an appropriate tHBURST signal. This operation is repeated until the HWIDTH value is zero.

FIG. 6 illustrates a waveform for transmitting data in an AXI matrix system by converting the 28 data in the INCR mode from the AHB wrapper according to the present invention.

Referring to FIG. 6, the AHB wrapper converts the number of burst transmission data into 16, 8, and 4 according to received continuous transmission data to process continuous transmission.

The number of clocks required for data transmission using 28 data of the present invention takes 88 clocks.

20 (SDRAM ready clock) x 3 (number of transfers) + 28 (data transfer) = 88 clocks

Transferring 28 data takes three SDRAM ready clocks and 28 clock data transfer clocks.

On the other hand, the connection between the conventional AHB master system and the Advanced Extensible Interface (AXI) matrix system required far more than 568 clocks than 88 clocks.

6, when the 28 data are transmitted, first, 20 clocks of SDRAM ready clocks are transmitted, followed by 16 data, and 8 data are transmitted after 20 clocks of SDRAM ready clocks. Finally, after 20 clocks of SDRAM preparation clock, the remaining 4 clocks are transferred.

In the AHB wrapper, since there are 28 received data, set the tHBURST signal to INCR16 to transmit 16 data first according to Table 2, and after 16 transfers to handle the transmission of the remaining 12 data. tHBURST signal is set to INCR8. When set to INCR 8, 8 data are transmitted, and 4 untransmitted data. Finally, the AHB wrapper processes the tHBURST signal by setting INCR4 to transmit the remaining four data.

Meanwhile, the AHB wrapper generates a tHBURST signal to fit the number of received data and does not set the total number of received data to exceed.

7 is a flowchart for transferring data between an AHB master system and an AXI matrix system of the present invention using the AHB wrapper of the present invention.

When the operation starts after initialization in steps 200 to 204, the AHB wrapper judgment output unit 112 outputs the mode signal as it is from the iHBURST signal when the AHB master system 100 is not in the INCR mode, and in the INCR mode, AHB. Wait for the HWIDTH signal from the master system 100 to be received.

In step 206, when the AHB master system 100 generates HWIDTH together with other AHB signals and transmits the HWIDTH to the AHB wrapper 110, the burst mode generator 114 first transmits the WIDTH value from the HWIDTH signal (continuous). Number of transmission data).

In step 208, when the burst mode generator 114 has a WIDTH value (the number of consecutive transmission data) determined from the received HWIDTH signal having a value of 16 or more, the burst mode generator 114 performs INCR16 on the tHBURST signal. A value corresponding to the output is output to the judgment output unit 100, and the judgment output unit 100 outputs INCR16 as an oHBURST signal so that 16 data can be continuously (Burst) matched to the INCR16 mode in the AXI matrix system 130. To be transmitted.

In step 210, the WIDTH storage unit 116 has a WIDTH value (number of consecutive transmission data) of 16 or more, and if data is transmitted in an INCR16 mode, the remaining data value is subtracted from the number of 16 transmitted data. Save it.

Whether the mode data included in the HWIDTH signal transmitted from the AHB master system 100 is transmitted in step 212, the WIDTH value (the number of consecutive transmission data) of the WIDTH storage unit 116 in the AHB wrapper 110. ) Is determined.

If it is determined in step 220 that the WIDTH value (number of consecutive transmission data) obtained from the WIDTH storage unit 116 in the burst mode generator 114 has a value between 8 and 15 as shown in FIG. 7. In step 222, a signal indicating INCR8 is output to the decision output unit 100 in the output tHBURST signal of the burst mode generator 114, and the decision output unit 100 outputs INCR 8 as an oHBURST signal to output the AXI matrix system. In operation 130, data conforming to the INCR8 mode may be continuously transmitted.

In step 224, when the WIDTH storage unit 116 transmits data in the INCR8 mode in which the WIDTH value (number of consecutive transmission data) is between 8 and 15, the number of data to be transmitted is subtracted from the number of data to be transmitted. Save the value.

Whether the mode data included in the HWIDTH signal transmitted from the AHB master system 100 is transmitted in step 226, the WIDTH value (the number of consecutive transmission data) of the WIDTH storage unit 116 in the AHB wrapper 110. ) Is determined. It is determined whether the value of WIDTH (number of continuous transmission data) is zero.

If it is determined in step 230 that the WIDTH value obtained from the WIDTH storage unit 116 in the burst mode generator 114 has 4-7, the output of the burst mode generator 114 in step 232. A signal indicating INCR 4 is output to the tHBURST signal to the judgment output unit 100, and the judgment output unit 100 outputs INCR 4 as an oHBURST signal so that the data corresponding to the INCR 4 mode is continuously generated in the AXI matrix system 130 ( Burst) to be transmitted.

In step 234, the WIDTH storage unit 116 indicates a WIDTH value (number of consecutive transmission data) of 4-7, and when data is transmitted in an INCR 4 mode, the number of transmitted data needs to be subtracted from the number of 4 transmitted. Store the value of the data.

In step 236, the AHB wrapper 110 determines whether the WIDTH value (the number of consecutive transmission data) of the WIDTH storage unit 116 is zero.

If it is determined in step 240 that the WIDTH value (number of consecutive transmission data) obtained from the WIDTH storage unit 116 in the BURST mode generator 114 has 1 to 3, the burst in step 242 is performed. The output tHBURST signal of the mode generator 114 outputs a signal indicating a single signal to the judgment output unit 100, and the decision output unit 100 outputs a single signal as an oHBURST signal to output the AXI matrix system 130. In this example, data for the single mode is transmitted continuously.

In step 242, the WIDTH storage unit 116 indicates a WIDTH value (number of consecutive transmission data) of 1 to 3, and when data is transferred in a single mode, the number of transmitted data is subtracted from 1 and the remaining transmission is performed. Store the value of the data to be done.

Finally, in step 244, the AHB wrapper 110 determines whether the WIDTH value (the number of consecutive transmission data) of the WIDTH storage unit 116 is zero.

By using the WIDTH value stored in the WIDTH storage unit 116 in the above-described manner, the WIDTH value is compared again for the next transmission to determine the transmission modes SINGLE, INCR 4, INCR 8, and INCR 16. This transfer is repeated to process data transfer until WIDTH becomes zero.

In this way, after the transmission is completed for the first number of consecutive transmission data, the AHB wrapper device goes to the initialization state and waits for the next data transmission.

As described above, in the present invention, when 28 data are transmitted to INCR in an advanced high-performance bus (AHB) master system, the AHB wrapper 110 first transmits 16, then 8, and then last 4 By generating and interfacing the tHBURST signal for transmission, data transfer rates in AXI matrix systems are greatly improved.

So far, the configuration and operation of the embodiment of the present invention have been described. The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims but also by the equivalents of the claims.

The present invention has the effect of improving the data transfer speed of the entire chip when implemented by connecting a hardware block developed as an AHB master system in an AXI (Advanced Extensible Interface) matrix system implemented on a chip to transmit data.

In recent years, more and more chips have been developed using the AXI matrix system, which has a fast system bus. In the case of AXI matrix system, the hardware block developed by the conventional AHB master system should be utilized to shorten the time and reduce the bug. Therefore, the present invention has the effect of preventing the speed degradation when the AXI matrix system is connected to the AHB master system. There is.

Claims (14)

In order to transmit data, a bridge is connected to an AHB master system and interfaces between the AHB master system and an AXI matrix system. The AHB master system determines whether the AHB master system is in INCR mode from the HBURST signal transmitted from the AHB master system, the number of continuous transmission data in the HWIDTH signal transmitted from the AHB master system is determined, and the AHB master system is the INCR mode. A wrapper device for data transmission between an AXB matrix system and an HB master system, comprising an AHB wrapper for generating a converted HBURST signal according to the number of continuous transmission data and providing the converted HBURST signal to the bridge to improve data transmission speed. . A determination output unit which receives the HBURST signal from the AHB master system and outputs the HBURST signal as it is when the AHB master system is not in the INCR mode, and outputs the converted HBURST signal generated by the burst mode generator in the INCR mode; A burst mode generator which grasps the total number of continuous transmission data from the HWIDTH signal transmitted from the AHB master system, generates the converted HBURST signal according to the number of continuous transmission data, and provides the converted HBURST signal to the determination output unit; The AHB wrapper includes a Weedth storage device configured to generate the converted HBURST signal by grasping and storing the number of consecutive transmission data remaining after subtracting the number of continuous transmission data output from the determination output unit and providing the burst mode generator to the burst mode generator. A wrapper device for data transmission between an AXE matrix system and an HB master system. The method of claim 2, And the burst mode generator generates and provides the converted HBURST signal until the number of continuous transmission data received at the AHB master system and remaining in the WIDTH storage device becomes zero. Wrapper device for data transfer between matrix system and HB master system. The method according to claim 2 or 3, The burst mode generator is a wrapper for data transmission between the AXI matrix system and the HB master system, wherein the burst HBURST signal is generated to have an INCR16 mode value when the number of consecutive transmission data is 16 or more. Device. The method according to claim 2 or 3, The burst mode generator is configured to generate the converted HBURST signal to have an INCR8 mode value when the number of consecutive transmission data is 8-15. Wrapper device. The method according to claim 2 or 3, The burst mode generator may generate the converted HBURST signal to have an INCR4 mode value when the number of consecutive transmission data is 4-7, to transfer data between the AXI matrix system and the HB master system. Wrapper device. The method according to claim 2 or 3, The burst mode generator may generate the converted HBURST signal to have a single mode value when the number of consecutive transmission data is 1-3, between the AXE matrix system and the HB master system. Wrapper device for data transfer. Receiving a HBURST signal and an HWIDTH signal transmitted from the AHB master system by the AHB wrapper; Determining, by the AHB wrapper, whether the AHB master system is an INCR mode in the HBURST signal and the HWIDTH signal, and determining the number of continuous transmission data; If the AHB master system is in the INCR mode, the AHB wrapper includes three steps of generating and outputting a converted signal according to the number of continuous transmission data. How to control the wrapper for data transfer. The method of claim 8, Identifying whether the AHB master system is in INCR mode and determining the number of consecutive transmission data Determining whether there is an INCR mode value in the HBURST signal transmitted from the AHB master system; Outputting the HBURST signal as it is if there is no INCR mode value in the HBURST signal, and determining the number of continuous transmission data in the HWIDTH signal transmitted from the AHB master system if the INCR mode value is present. Wrapper control method for data transfer between AXE Matrix system and HB Master system. The method of claim 8, In the AHB wrapper, generating and outputting a converted signal according to the number of consecutive transmission data, And generating and outputting the converted signal to have an INCR16 mode value when the number of the continuous transmission data is 16 or more. 16. The wrapper control method for data transmission between an AXI matrix system and an HB master system. The method of claim 8, In the AHB wrapper, generating and outputting a converted signal according to the number of consecutive transmission data, A wrapper for data transmission between an AXI matrix system and an HB master system, comprising generating and outputting the converted signal to have an INCR 8 mode value when the number of consecutive transmission data is 8-15. Control method. The method of claim 8, In the AHB wrapper, generating and outputting a converted signal according to the number of consecutive transmission data, And generating and outputting the converted signal to have an INCR 4 mode value when the number of consecutive transmission data is 4-7. A wrapper control for data transmission between an AXI matrix system and an HB master system. Way. The method of claim 8, In the AHB wrapper, generating and outputting a converted signal according to the number of consecutive transmission data, And generating and converting the converted signal to have a SINGLE mode value when the number of consecutive transmission data is 1-3. A wrapper control method for data transmission between an AXI matrix system and an HB master system. . The method of claim 8, In the AHB wrapper, generating and outputting a converted signal according to the number of consecutive transmission data, And generating and outputting the converted signal until all of the continuous transmission data transmitted from the AHB master system is transmitted.

Images