KR20000059602A - apparatus and method for receiving asynchronous packet data in bus system - Google Patents

Abstract

PURPOSE: A method for receiving asynchronous packet data in a bus system, is provided to add a compressed module to an architecture using the restricted size of a buffer so as to receive larger asynchronous packet data. CONSTITUTION: Whether a compressed mode is set up in received asynchronous packet data is retrieved. If so, a signal compression selecting signal is outputted by comparing the sizes of an asynchronous packet data header with reference data. If not, the asynchronous packet data are stored with uncompressed, and corresponding compression information is turned off. The asynchronous packet data are compressed by the predetermined unit according to the compared result, and stored in a memory. A compression rate is retrieved when exceeding the predetermined number of times. According to the retrieved result, present asynchronous packet data are compressed to the last and stored, or re-transmission is requested and the size of asynchronous packet data capable of receiving bus information are re-set up.

Description

Apparatus and method for receiving asynchronous packet data in bus system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to bus systems, and more particularly, to an apparatus and method for receiving aacceptance packet data in a bus system.

With the demand for high speed interfaces between digital electronic devices, the use of the IEEE 1394 serial bus has been applied in various fields.

In the IEEE 1394 serial bus protocol, an isochronous transmission is first performed according to a cycle sync of 8 ms, and then an acknowledgment packet data is transmitted after a predetermined gap.

Isochronous transmission, which is assigned to a certain channel and periodically sent, is used for the transmission of data where timing is important such as video signal and audio signal, and ascronus transmission that receives Ack is used for transmission and reception of data that should be guaranteed that data is received safely. Will be used.

The IEEE 1934 serial bus protocol is described by a stacked layer consisting of a transaction layer, a link layer, a physical layer, and a serial bus manager. The transaction layer may be a request of a control and status register (CSR) architecture supporting read, write, and lock, and a response protocol. The link layer is defined as addressing, data checking, and packet composition to provide an acknowledged datagram (one-way transmission) service. Will be in charge of the back.

The physical layer converts a logical symbol used in the link layer into an electronic signal, guarantees that only one node is transmitted at a time through arbitration, and defines a physical interface to a serial bus.

The serial bus manager manages nodes and manages resources on the bus.

Hereinafter, an acknowledgment packet data receiving apparatus in a bus system according to the prior art will be described with reference to the accompanying drawings.

1 is a diagram illustrating a structure of a link layer according to the prior art, which performs CRC check, packetizing, and depacketizing of CRC generation and received data, and performs acronym packet data and isochronization. A link core 1 for outputting data, a configuration register 2 for storing configuration information performed by the link core 1, and a buffer for storing the acknowledgment packet data output from the link core 1 ( 3), an isodata mover 4 for controlling the movement of isochronous data output from the link core 1, and the acknowledgment packet data stored in the buffer 3 to be read and transmitted to the host or from the host. The host interface unit 5 transmits the acknowledgment packet data with reference to the stored configuration information according to the control.

The buffer 3 includes a reception buffer 3a for storing CRC check and depacketized data in the link core 1 and a transmission buffer 3b for storing data output from the host interface unit 5. It is composed of

2 is a diagram illustrating a format of an acknowledgment packet data packet according to the prior art.

Referring to the accompanying drawings, an acknowledgment packet data receiving apparatus in a bus system according to the related art as described above will be described in detail as follows.

First, the link core 1 in the link layer performs CRC generation and CRC check, packetizing, and depacketizing of received data.

That is, the link core 1 checks the CRC of the asynchronous packet data transmitted from the physical layer (not shown) and performs depacketizing if there is no error, and then buffers the acknowledgment packet data. (3) is stored in the reception buffer 3a.

In addition, the link core 1 stores the depacketized configuration information in the configuration register 2.

In addition, the link core 1 generates a CRC of the acknowledgment packet data transmitted from the upper layer, packetizes the acknowledgment packet data, and outputs the packet to the physical layer.

As shown in FIG. 2, the acknowledgment packet data includes a packet header and a data block, and may include only a header without data. The data size is 1 quadlet. The data in block units of several quadlets are not limited in size.

The host interface unit 5 then withdraws the data stored in the reception buffer 3a in the buffer 3 and transmits it to the host.

Meanwhile, an isochronous packet transmitted through the link core 1 is transmitted to the host through the isodata mobile device 4 and isodata transmitted from the host is transmitted to the link core 1. do.

The host interface unit 5 also stores the acknowledgment packet data transmitted from the host in the transmission buffer 3b in the buffer 3 with reference to the configuration information stored in the configuration register 2.

Then, the acknowledgment packet data stored in the transmission buffer 3b is transmitted to the physical layer through the link layer 1.

In such a prior art acronym packet data receiving apparatus in a bus system, an expected data size and host processing according to the type of data to be transmitted in an asynchronous packet, in which the size of the reception buffer is required in accordance with the characteristics of the system. This is determined in consideration of the characteristics and the transmission speed of the serial bus. If the receiving buffer is small, a large number of Asynchronous packets are received in small units, causing a burden on the host.

In addition, in the acronym packet data receiving apparatus in the bus system according to the prior art, since the acknowledgment transmission cannot take one packet for a predetermined time or more, the transmission speed of the bus determines the maximum size that can be transmitted as packet data. There are also problems that affect it.

Accordingly, the present invention has been made to solve the above problems, and by adding a compression module to the conventional structure using a limited size buffer to reduce the size of the hardware block to receive larger acronym packet data. It is an object of the present invention to provide an acknowledgment packet data receiving apparatus in a bus system.

In addition, an object of the present invention is to provide a method of receiving an acknowledgment packet data in a bus system corresponding to the above apparatus.

1 is a view showing the configuration of a link layer according to the prior art

2 is a diagram illustrating a format of an acknowledgment packet data packet according to the prior art;

3 is a diagram illustrating the configuration of an acknowledgment packet data receiving apparatus in a bus system according to the present invention.

4 is a diagram illustrating a format of received data transmitted to a host through the host interface of FIG. 3.

5 is a flowchart illustrating a method of receiving an acknowledgment packet data in a bus system according to the present invention.

Explanation of symbols for main parts of the drawings

101: link core 102: configuration register

103: signal compression module 103a: signal compression selection unit

103a-1: reference size register 103a-2: comparison unit

103b: signal compression unit 103c: compression rate search unit

104: first signal selector 105: memory

105a: receive buffer 105b: transmit buffer

106: signal extension section 107: second signal selection section

108: host interface unit 109: iso data moving unit

A feature of an acknowledgment packet data receiving apparatus in a bus system according to the present invention for achieving the above object is an acknowledgment packet data receiving apparatus in a bus system having a link core and a host interface unit. A signal compression module for compressing the acknowledgment packet data output from the signal; and outputting the acknowledgment packet data output from the link core according to the signal of the signal compression module or selecting and outputting the compressed data from the signal compression module. A first signal selector, a memory for storing and outputting the compressed data or the uncompressed acknowledgment packet data in the first signal selector, or storing a signal of the host, and stored in the memory according to a signal of the host interface unit Expand and output compressed data Includes a signal decompression unit and a second signal selector which selects and outputs uncompressed acknowledgment packet data stored in the memory or data decompressed by the signal decompression unit according to a signal of the signal compression module.

The signal compression module includes a signal compression selection unit for selecting whether to compress by comparing the size of the acknowledgment packet data output from the link core with a reference size, and the acknowledgment output from the link core according to the signal of the signal compression selection unit. The signal compression unit compresses the packet data by a predetermined unit, and a compression ratio search unit that searches for the compression efficiency of the signal compressed by the signal compression unit according to the signal of the signal compression selection unit.

The signal compression selection unit compares the size of the reference size register for storing the reference size for determining whether to compress the size of the acknowledgment packet data output from the link core with the size of the reference size of the reference size register, and receives the resultant signal. It is configured to include a comparator for outputting.

According to an aspect of the present invention, a method for receiving an acknowledgment packet data in a bus system according to the present invention may include: searching whether a compression mode is set in the received acknowledgment packet data, and according to the search result, Outputting a signal compression selection signal by comparing the data size of the acknowledgment packet data header with a reference size if the compression mode is set, and storing the data without being compressed and turning off the corresponding compression information if the compression mode is not set; Compressing the acknowledgment packet data in a predetermined unit according to the comparison result, storing the acknowledgment packet data in a memory unit, and retrieving a compression ratio after a predetermined number of times; and compressing and storing the current acknowledgment packet data to the end according to the search result. Or receive bus information after requesting a retransmission Resetting the possible acknowledgment packet data size.

The signal compression selection signal compares the acknowledgment packet data output from the link core with the stored reference size, and outputs a compressed acknowledgment packet data selection signal if it is large, and if it is small, outputs an uncompressed acknowledgment packet data selection signal. There are other features to the output.

Hereinafter, a preferred embodiment of an acknowledgment packet data receiving apparatus and method in a bus system according to the present invention will be described with reference to the accompanying drawings.

FIG. 3 is a diagram illustrating a configuration of an acknowledgment packet data receiving apparatus in a bus system according to the present invention. FIG. 3 illustrates CRC generation, CRC checking, packetizing, and depacketizing of received data. A link core 101 for performing the output of the acknowledgment packet data and isochronous data, a configuration register 102 for storing configuration information performed in the link core 101 and setting and storing a reference compression ratio reference size; Outputs a signal compression module 103 for compressing the acknowledgment packet data output from the link core 101 and an acknowledgment packet data output from the link core 101 according to the signal of the signal compression module 103. Or a first signal selector 104 for selecting and outputting data compressed by the signal compression module 103 and the first signal selector 104. Memory 105 for storing and outputting the compressed data or the uncompressed acknowledgment packet data or storing the signal of the host, and expanding the compressed data stored in the memory 105 according to the signal of the host. In accordance with the signal extending section 106 and the signal of the signal compression module 103 to output the uncompressed acknowledgment packet data stored in the memory 105 or the data extended in the signal extending section 106 A host for transmitting the second signal selector 107 and the data output from the second signal selector 107 to the host or transmitting the acknowledgment packet data with reference to the stored configuration information according to control from the host. An iso data moving unit for controlling the movement of the isochronous data output from the interface unit 108 and the link core 101 ( 109).

The signal compression module 103 compares the size of the acknowledgment packet data output from the link core 101 with a reference size to select whether to compress the signal, and the signal compression selector 103a. A signal compression unit 103b for compressing the acknowledgment packet data output from the link core 101 in a predetermined unit in accordance with a signal of the signal), and the signal compression unit 103b according to the signal of the signal compression selection unit 103a. ) Is composed of a compression rate searching unit 103c for searching the compression efficiency of the compressed signal.

The signal compression selector 103a includes a reference size register 103a-1 for storing a reference size for determining whether to compress, a size of the acknowledgment packet data output from the link core 101, and the reference size register. And a comparison unit 103a-2 for comparing the magnitude of the reference size of 103a-1 and outputting the resultant signal.

The memory 105 includes a reception buffer 105a for storing the compressed data or the uncompressed acknowledgment packet data output from the first signal selector 104, and the data output from the host interface 108. It consists of a transmission buffer 105b for storing the.

FIG. 4 is a diagram illustrating a format of received data transmitted to a host through the host interface of FIG. 3, and includes a destination ID area, a tlabel area, an rt area, a tcode area, and a priority. FIG. Area, dource ID area, destination offset high area, destination offset low area, data length area, extended tcode area, block data area, , spd area, and acksent area.

5 is a flowchart illustrating a method of receiving an acknowledgment packet data in a bus system according to the present invention.

Operation of the apparatus and method for acknowledging packet data in the bus system according to the present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, the link core 101 performs CRC check and depacketizing of the acknowledgment packet data received from the physical layer (not shown) to output the acknowledgment packet data and the isochronous data (S1). .

The configuration register 102 then stores configuration information output from the link core 101.

In addition, the signal compression module 103 searches whether a compression mode set of the acknowledgment packet data output from the link core 101 is set, and compresses or outputs the acknowledgment packet data according to the result. Outputs as is.

That is, the signal compression selecting unit 103a in the signal compression module 103 searches whether the compression mode is set in the acknowledgment packet data output from the link core 101, and if the compression mode is set, the acknowledgment packet Read the data size from the header of the data, compare it with the reference size, and output the corresponding signal compression selection signal. If the compression mode is not set, output it without compression and then turn off the corresponding compression information. off) (S2 to S5).

The comparator 103a-2 in the signal compression selector 103a determines whether to store the acknowledgment packet data output from the link core 101 and the compression stored in the internal reference size register 103a-1. When the size is large, a signal for selecting compressed accompaniment packet data is output if large, and a signal for selecting uncompressed acknowledgment packet data is output if small, and the corresponding compression information is turned off.

Subsequently, the signal compression unit 103b compresses and outputs the acknowledgment packet data output from the link core 101 according to a signal of the signal compression selection unit 103a until a predetermined number of times progresses in a predetermined unit (S6, S7).

At this time, the compression rate searching unit 103c searches for the compression efficiency of the signal compressed by the signal compression unit 103b according to the signal of the signal compression selecting unit 103a, and if it is not compressed below a predetermined ratio, the current acknowledgment packet data. After retransmission is requested, the size of the available information acknowledgment packet data of the bus information is reset (S8, S9, S10).

Accordingly, the first signal selector 104 outputs the acknowledgment packet data output from the link core 101 or selects the data compressed by the signal compression module 103 according to the signal of the signal compression module 103. To print.

Then, the memory 105 stores the compressed data or uncompressed acknowledgment packet data in the first signal selector 104 (S8 and S11).

That is, the reception buffer 105a in the memory 105 stores the compressed data or the uncompressed acknowledgment packet data output from the first signal selector 104.

Thereafter, when a control signal for decompressing the compressed data is output from the host interface unit 108 according to a user's request, the signal extension unit 106 extracts the compressed data from the reception buffer 105a in the memory 105. The compressed data is then decompressed and output.

Then, the second signal selector 107 selects the uncompressed acknowledgment packet data stored in the memory 105 or the data extended by the signal decompression unit 106 according to the signal of the signal compression module 103. Output

Accordingly, the host interface unit 108 converts the uncompressed acknowledgment packet data output from the second signal selector 107 or the data extended from the signal extension 106 into a format as shown in FIG. 4. Interface to the host.

In addition, the host interface 108 interfaces and outputs the data transmitted from the host.

The configuration register 102 then stores the configuration information of the data interfaced by the host interface unit 108 and outputs it.

In addition, the transmission buffer 105b in the memory 105 stores the data output from the host interface unit 108.

Accordingly, the link core 101 extracts the data stored in the transmission buffer 105b in the memory 105 according to the signal output from the configuration register 102, generates the CRC, packetizes it, and outputs the data. .

In addition, the isodata moving unit 109 controls the movement of the isochronous data output from the link core 101.

As described above, the apparatus and method for receiving a clinking packet data in a bus system according to the present invention adds a compression module to a conventional structure using a limited size buffer, thereby reducing the size of a hardware block and increasing the size of a larger clinking packet. By enabling the reception of data, the burden on the host can be reduced.

Claims (5)

An apparatus for receiving an acknowledgment packet data in a bus system having a link core and a host interface, A signal compression module for compressing the acknowledgment packet data output from the link core; A first signal selector configured to output the acknowledgment packet data output from the link core or to select and output data compressed by the signal compression module according to the signal of the signal compression module; A memory for storing and outputting compressed data or uncompressed acknowledgment packet data in the first signal selector, or storing a signal of a host; A signal decompression unit configured to decompress and output compressed data stored in the memory according to the signal of the host interface unit; And a second signal selector configured to select and output uncompressed acknowledgment packet data stored in the memory or data extended by the signal extension according to the signal of the signal compression module. Synchronous packet data receiver. The method of claim 1, The signal compression module A signal compression selection unit for selecting whether to compress by comparing the size of the acknowledgment packet data output from the link core with a reference size; A signal compressor for compressing the acknowledgment packet data output from the link core in a predetermined unit according to the signal of the signal compression selector; And a compression rate searching unit for searching the compression efficiency of the signal compressed by the signal compression unit according to the signal of the signal compression selection unit. The method of claim 2, The signal compression selector A reference size register for storing a reference size for determining whether to compress; And a comparison unit for comparing the size of the acknowledgment packet data output from the link core with the size of the reference size of the reference size register and outputting a resultant signal. . Searching whether the compression mode is set in the received acknowledgment packet data; According to the search result, if the compression mode is set, the data compression selection signal is output by comparing the data size of the acknowledgment packet data header with the reference size, and if the compression mode is not set, it is stored without compression and the corresponding compression is performed. Turning off the information; Retrieving the acknowledgment packet data in a predetermined unit and storing the compression data in a memory according to the comparison result, and then retrieving a compression ratio after a predetermined number of times passes; Reconstructing the current acknowledgment packet data to the end according to the search result or resetting the receivable acknowledgment packet data size of the bus information after requesting resend to the end; Packet data reception method. The method of claim 4, wherein The signal compression selection signal is And compares the acknowledgment packet data output from the link core with the stored reference size, and outputs a compressed acknowledgment packet data selection signal if large, and outputs an uncompressed acknowledgment packet data selection signal if small. A method of receiving acknowledgment packet data in a bus system.