Abstract:
The present invention relates to a USB-based host-to-host networking method capable of transferring information between two hosts. Devices for the method comprise: a register, a pair of FIFO control command transmitters and at least one FIFO bulk transmitter. 
     The register is to temporarily store control commands for information transaction and acts as a buffer. The control command transmitters is to connect two serial interface engines interfacing respectively with the USB interface of each host, by which the information transfer control commands can be delivered from either host. The bulk information transmitter connects to the two serial interface engines for bulk transfer so that any host is capable of issuing the information transfer control commands for executing data transaction between hosts. 
     The present invention provides a new design for networking controller connection by reducing the number of control command transmitters needed, and also capable of transferring bulk information between hosts.

Description:
FIELD OF THE INVENTION 
   The present invention relates to an USB-based host-to-host networking method capable of transmitting streams of data between PCs or notebooks via USBs, and more particularly, between two or more hosts capable of issuing control commands to control the transmission. 
   BACKGROUND OF THE INVENTION 
   USB specification was published in 1996 to provide an easy and economical method for connecting all kinds of peripheries with PCs., and has become a main interface for printers, scanners and CD burners thereafter. In year 2000, in addition to the full-speed mode (FS) of 12 Mbps and the low-speed mode (LS) of 1.5 Mbps for the USB 2.0 interface, a high-speed mode (HS) of 480 Mbps was provided for increasing the USB transmission speed by forty times of the original speed that enables the USB interface to become more suitable for high-performance peripheries, such as high-volume storage device, digital video camcorder, etc. Nowadays, the USB specification has stepped into an advance level to offer more services for mobile devices. In December of 2001, a supplement to the USB 2.0 specification had been issued to define the theories of mechanism, electrics, and communication protocol, etc. for enabling the USB interface to be applied onto the mobile devices. 
   The USB transfers signal and power over a four-wire cable. The signaling occurs over two wires on each point-to-point segment. For an high-speed external device that requires great bandwidth, the USB interface will adopt the full-speed mode of 12 Mbps for the transmission, on the other hand, for a low-speed external device, the USB interface will adopt the low-speed mode of 1.5 Mbps for the transmission. The USB interface can automatically detect and switch between the HS mode and the LS mode dynamically according to the external device connected therewith. USB interface is a serial bus for primitives which is similar to the serial bus for the token-ring or the primitives of the fiber distributed data interface (FDDI). The controller of the USB interface broadcasts commands for checking whether the address of commands of the equipment connected to the serial bus matches with that of the USB interface or not through receiving/transmitting data of the host. Additionally, the USB interface manages power of the serial bus by way of append/restore operation. The USB physically interconnected is a tiered star topology, consisting of three basic parts: host, hub and device. 
   There is only one host in any USB system. The USB interface to the host computer system is referred to as the host controller. The host comprises a host controller and a root-hub where the host Controller may be implemented in a combination of hardware, firmware, or software, which is capable of controlling the data transmission over the USB system, and the root hub is integrated within the host by connecting to the host controller to provide one or more attachment points. 
   A hub is a USB device that provides additional connections to the USB and is capable of providing power management and malfunction detection/restoration to the USB devices connected to the same. Each USB segment provides a limited amount of power over the cable. The host supplies power for use by USB devices that are directly connected. In addition, any USB device may have its own power supply. USB devices that rely totally on power from the cable are called bus-powered devices. In contrast, those that have an alternate source of power are called self-powered devices. A hub also supplies power for its connected USB devices. The specification of USB protocol defines that a USB frame is produced per millisecond, and a USB device can transmit and receive one transaction in each frame. A transaction is consisted of a plurality of packets, and a transmission is completed with at least one transaction for transferring a series of meaningful data. Herein a transmission is the same as a report. The USB supports functional data and control exchange between the USB host and a USB device as a set of either uni-directional or bi-directional pipes. USB data transfers take place between host software and a particular endpoint on a USB device. Such associations between the host software and a USB device endpoint are called pipes. In general, data movement though one pipe is independent from the data flow in any other pipe. A given USB device may have many pipes. As an example, a given USB device could have an endpoint that supports a pipe for transporting data to the USB device and another endpoint that supports a pipe for transporting data from the USB device. The USB architecture comprises two basic types of data transfers, i.e. control transfer and interrupt transfer. The Control transfer is used to configure a device at attach time and can be used for other device-specific purposes, including control of other pipes on the based on demand and the most general, which is used mainly for transferring message-type data. The interrupt transfer is used for characters or coordinates with human-perceptible echo or feedback response characteristics, wherein a small, limited-latency transfer to or from a device is referred to as interrupt data and such data may be presented for transfer by a device at any time and is delivered by the USB at a rate no slower than is specified by the device, which is adaptable for transferring stream-type data. Interrupt data typically consists of event notification, characters, or coordinates that are organized as one or more bytes. An example of interrupt data is the coordinates from a pointing device. Although an explicit timing rate is not required, interactive data may have response time bounds that the USB must support. 
   Data transaction between USBs is represented as report of data transfer, and the report descriptor is used for illustrating the usage of the report. There are three kinds of report: the input report, the output report and the feature report. The interrupt in pipe can only be used for transmitting the input report, the interrupt out pipe can only be used for transmitting the output report, and the control pipe can be used for transmitting all the input report, the output report and the feature report. The end point descriptor may announce what types of pipes are used for the end point. Descriptor is used for illustrating the usage of the transferred data which is meaningless by itself, and thus the kind of control specified by the descriptor can be performed. For example, buttons, indicating lights and displacements of x-axis and y-axis are generally referred as control, and the statuses of the buttons and the indicating lights or amount of displacement of x-axis and y-axis are referred as data. The report descriptors with respect to the corresponding controls are mapped one-on-one with the data by which data can be controlled accordingly. 
   There is only one host for each USB. The major layers of a host consist of the following:
     (1) USB bus interface: The USB bus interface handles interactions for the electrical and protocol layers. From the interconnect point of view, a similar USB bus interface is provided by both the USB device and the host, as exemplified by the Serial Interface Engine (SIE). On the host, however, the USB bus interface has additional responsibilities due to the unique role of the host on the USB and is implemented as the host controller. The host controller has an integrated root hub providing attachment points to the USB wire.   (2) USB System: The USB System uses the host controller to manage data transfers between the host and USB devices. The interface between the USB System and the host controller is dependent on the hardware definition of the host controller. The USB System is also responsible for managing USB resources, such as bandwidth and bus power, so that client access to the USB is possible.   (3) Client: The client layer describes all the software entities that are responsible for directly interacting with USB devices. When each device is attached to the system, these clients might interact directly with the peripheral hardware. The shared characteristics of the USB place USB System Software between the client and its device; that is, a client cannot directly access the device&#39;s hardware.
 
In addition, the USB System has three basic components as following:
   (1) Host Controller Driver: The Host Controller Driver (HCD) exists to more easily map the various Host Controller implementations into the USB System, such that a client can interact with its device without knowing to which Host Controller the device is connected. The USB Driver (USBD) provides the basic host interface (USBDI) for clients to USB devices. The interface between the HCD and the USBD is known as the Host Controller Driver Interface (HCDI). This interface is never available directly to clients and thus is not defined by the USB Specification. A particular HCDI is, however, defined by each operating system that supports various Host Controller implementations.   (2) USB Driver: The USBD provides data transfer mechanisms in the form of I/O Request Packets (IRPs), which consist of a request to transport data across a specific pipe. In addition to providing data transfer mechanisms, the USBD is responsible for presenting to its clients an abstraction of a USB device that can be manipulated for configuration and state management. As part of this abstraction, the USBD owns the default through which all USB devices are accessed for the purposes of standard USB control. This default pipe represents a logical communication between the USBD and the abstraction of a USB device.   (3) Host Software: In some operating systems, additional non-USB System Software is available that provides configuration and loading mechanisms to device drivers. In such operating systems, the device driver shall use the provided interfaces instead of directly accessing the USBDI mechanisms.   

   The USB is a polled bus. The Host Controller initiates all data transfers. All bus transactions involve the transmission of up to three packets. Each transaction begins when the Host Controller, on a scheduled basis, sends a USB packet describing the type and direction of transaction, the USB device address, and endpoint number. This packet is referred to as the “token packet.” The USB device that is addressed selects itself by decoding the appropriate address fields. In a given transaction, data is transferred either from the host to a device or from a device to the host. The direction of data transfer is specified in the token packet. The source of the transaction then sends a data packet or indicates it has no data to transfer. The destination, in general, responds with a handshake packet indicating whether the transfer was successful. Field formats for the token, data, and handshake packets in the USB specification are defined using a 4-bit Packet Identifier (PID). An endpoint is a uniquely identifiable portion of a USB device that is the terminus of a communication flow between the host and device. Each USB logical device is composed of a collection of independent endpoints. 
   In the present product design, FIFO is the most general form used to construct endpoints due to that the essence of FIFO being able to contain a packet. Therefore, Each logical device has a unique address assigned by the system at device attachment time. Each endpoint on a device is given at design time a unique device-determined identifier called the endpoint number. Each endpoint has a device-determined direction of data flow. The combination of the device address, endpoint number, and direction allows each endpoint to be uniquely referenced. Each endpoint is a simplex connection that supports data flow in one direction: either input (from device to host) or output (from host to device). 
   All USB devices are required to implement a default control method that uses both the input and output endpoints with endpoint number zero, i.e. Endpoint-0. The USB System Software uses this default control method to initialize and generically manipulate the logical device (e.g., to configure the logical device) as the Default Control Pipe. The Default Control Pipe provides access to the device&#39;s configuration information and allows generic USB status and control access. The endpoints with endpoint number zero are always accessible once a device is attached, powered, and has received a bus reset. Functions can have additional endpoints as required for their implementation. Low-speed (LS) functions are limited to two optional endpoints beyond the two required to implement the Default Control Pipe. Full-speed (FS) devices can have additional endpoints only limited by the protocol definition (i.e., a maximum of 15 additional input endpoints and 15 additional output endpoints). A hub device can detect a supported transfer rate. It is known that USB interface implements differential data output depending on two signal wires which are D+ and D−. Thus the device recognizes a supported transfer rate via a pull-up state of the two signal wires. While the D+ signal being pulled up, it represents the FS mode; otherwise, D− signal being pulled up represents the LS mode. In this regard, when the device is being attached to a connecting port of a USB hub, the hub may detect the transfer rate of the device. Moreover, the transfer category and the rate thereof are provided in the max payload size field, that is, the size of the FIFO. 
   The USB supports functional data and control exchange between the USB host and a USB device as a set of either uni-directional or bi-directional pipes. USB data transfers take place between host software and a particular endpoint on a USB device. Such associations between the host software and a USB device endpoint are called pipes. In general, data movement though one pipe is independent from the data flow in any other pipe. A given USB device may have many pipes. As an example, a given USB device could have an endpoint that supports a pipe for transporting data to the USB device and another endpoint that supports a pipe for transporting data from the USB device. The USB architecture comprehends four basic types of data transfers:
     (1) Control Transfers: Control data is used by the USB System Software to configure devices when they are first attached. Other driver software can choose to use control transfers in implementation-specific ways. Data delivery is lossless.   (2) Bulk Data Transfers: Bulk data typically consists of larger amounts of data, such as that used for printers or scanners. Bulk data is sequential. Reliable exchange of data is ensured at the hardware level by using error detection in hardware and invoking a limited number of retries in hardware. Also, the bandwidth taken up by bulk data can vary, depending on other bus activities.   (3) Interrupt Data Transfers: Interrupt data typically consists of event notification, characters, or coordinates that are organized as one or more bytes. An example of interrupt data is the coordinates from a pointing device. Although an explicit timing rate is not required, interactive data may have response time bounds that the USB must support.   (4) Isochronous Data Transfers: Isochronous data is continuous and real-time in creation, delivery, and consumption. Timing-related information is implied by the steady rate at which isochronous data is received and transferred. Isochronous data must be delivered at the rate received to maintain its timing. In addition to delivery rate, isochronous data may also be sensitive to delivery delays. For isochronous pipes, the bandwidth required is typically based upon the sampling characteristics of the associated function. The latency required is related to the buffering available at each endpoint.   

   USB bandwidth is allocated among pipes. The USB allocates bandwidth for some pipes when a pipe is established. USB devices are required to provide some buffering of data. It is assumed that USB devices requiring more bandwidth are capable of providing larger buffers. The USB&#39;s bandwidth capacity can be allocated among many different data streams. This allows a wide range of devices to be attached to the USB. Further, different device bit rates, with a wide dynamic range, can be concurrently supported. 
   SUMMARY OF THE INVENTION 
   Nowadays, it is more than common for a family or company to have more than one computer as it is being used for all kind of works. Thus, a kind of network, such as Local Area Network (LAN) is required to handle the data exchange among computers that are becoming more and more complicated. To construct a LAN using conventional network interface cards (NIC) and networking wires will require excellent networking layout experience and knowledge along with plenty of peripheral hardware and adaptors. However, most of the company or individual do not possess enough know-how for doing so and require an engineer to do the job for them that incurs additional cost. Hence, a simple way to construct a network is in much demand. After Pentium Chip is provided in the market, most mother boards are integrated with USB interfaces which can be used for networking. The data linkage between two PCs can be accomplished simply by connecting the USB interfaces thereof without requiring additional hardware and know-how. 
   Many users have more than one computer or notebook thesedays. It is really a hassle while requiring to transfer a great amount of data between two computers, especially when one of which has no NIC installed therein. Moreover, there are many obstacles for a user to install a NIC on a computer, such as open the casing and install driver of the NIC, and one might meet interrupt conflicts during the installment. The conventional way of using serial and parallel cable connections as the “direct cable connection” of Windows 98 is simple but the transfer rate is unsatisfactory due to the band width of only 1.5 Mbps that it is inapplicable to high-volume transaction 
   Another solution is to employ the USB feature of plug-and-play to engage in data transfer among computers. The bandwidth as defined in the USB 1.1 specification is 12 Mbps, which is much faster than the previous parallel cable connection. Further, the USB supports hot plug. The USB-TO-LINK cable currently available on the market comprises an USB-HOST-LINK cable and a driver including installation software. Two computers both have USB interfaces may be connected by the USB-HOST-LINK cable for transferring data jut by inserting the two plugs of the cable respectively into the USB socket of the computer. However, The current products on the market still have shortcomings, such as incomplete software and high cost, etc. 
   To improve the above issues, the present invention provides an USB-based host-to-host networking method by refining the single-control-chip of USB 2.0. The present invention uses a first, a second and a third pipe all defined by USB specification to perform data transaction among computers according to different definitions of physical pipe and logical pipe. Referring to  FIG. 1 , which is a functional block diagram of the present invention. As seen, the first host C 1  is being connected with the second host C 2  through the USB networking device  1 , wherein the USB networking device  1  comprises: an embedded endpoint FIFOs  31 , a host-to-host networking controller  32 , a configuration register  39 , an embedded micro-controller unit  33  (MCU) and two connecting interfaces  35  arranged at the sides respectively corresponding to the first host C 1  and the second host C 2 , and the connecting interface  35  further comprises: an USB transceiver  36 , an USB interface controller  37  and a clock synthesizer  38 . When the first host C 1  is going to send streams of data to the second host C 2 , it is required for the first host C 1  to send a transfer signal to the embedded endpoint FIFOs  31  prior the data transmission for informing the embedded MCU  32  that the first host C 1  is in a ready-to-transmit state, in addition, the transfer signal comprises a command instruction and a state instruction. At the same time, the embedded endpoint FIFOs  31  sends an interrupt signal to the second host C 2  for directing the second host C 2  to interrupt its normal procedures and enter a ready-to-receive state. When the embedded MCU  33  detects that the first host C 1  is sending a transfer signal to the embedded endpoint FIFOs  31 , the embedded MCU  33  is aware that the first host C 1  is going to transmit streams of data, and the transfer signal received by the embedded endpoint FIFOs  31  contains a destination information. Thus, the embedded MCU  33  stores the destination information to the configuration register  39  and performs a handshaking operation for enabling the second host C 2  to enter a start-to-receive state, and then outputting the destination information from the embedded endpoint FIFOs  31  to the second host C 2 . 
   Vice versa, When the second host C 2  is going to send streams of data to the first host C 1 , it is required for the second host C 2  to send a transfer signal to the embedded endpoint FIFOs  31  prior the data transmission for informing the embedded MCU  32  that the second host C 2  is in a ready-to-transmit state, in addition, the transfer signal comprises a command instruction and a state instruction. At the same time, the embedded endpoint FIFOs  31  sends an interrupt signal to the first host C 1  for directing the first host C 1  to interrupt its normal procedures and enter a ready-to-receive state. When the embedded MCU  33  detects that the second host C 2  is sending a transfer signal to the embedded endpoint FIFOs  31 , the embedded MCU  33  is aware that the second host C 2  is going to transmit streams of data, and the transfer signal received by the embedded endpoint FIFOs  31  contains a destination information. Thus, the embedded MCU  33  stores the destination information to the configuration register  39  and performs a handshaking operation for enabling the first host C 1  to enter a start-to-receive state, and then outputting the destination information from the embedded endpoint FIFOs  31  to the first host C 1 . 
   The USB-based networking solution for two or more USB hosts of PC/notebook of the present invention features: USB specification revision 2.0 compliant, and glueless single-chip integration with two on-chip USB 2.0 transceiver, controllers and Ping-Pong FIFOs. Furthermore, the built-in high-performance micro-processor accompanying the present invention enables users to interface with external devices for data sharing with ease. 
   The advantages of the present invention are as following: (1) the optimal transfer rate of a single-chip USB host-to-host being up to 8˜15 Mbps; (2) supporting WINDOWS 98/2000/ME/XP and Mac OSR2/98/2000; (3) document transferring being established by drag and drop similar to mode of resource management window; (4) supporting network printing; (5) supporting USB 1.1 specification with good compatibility; (6) ease to install; (7) having small volume and light weight for carrying. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a functional block diagram of the present invention; 
       FIG. 2  is a diagram showing a first preferred embodiment of the present invention; 
       FIG. 3  is a flowchart depicting the first preferred embodiment of the present invention; 
       FIG. 4  is a diagram showing a second preferred embodiment of the present invention; 
       FIG. 5  is a flowchart depicting the second preferred embodiment of the present invention; 
       FIG. 6  is a diagram showing a third preferred embodiment of the present invention; 
       FIG. 7  is a flowchart depicting the third preferred embodiment of the present invention; 
       FIG. 8  is a diagram showing a fourth preferred embodiment of the present invention; 
       FIG. 9  is a flowchart depicting the fourth preferred embodiment of the present invention; 
       FIG. 10  is a diagram showing a fifth preferred embodiment of the present invention; 
       FIG. 11  is a flowchart depicting the fifth preferred embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Please refer to  FIG. 2 , which is a diagram depicting a first preferred embodiment of the present invention. The objective of the present invention is to provide a single-chip USB-based host-to-host networking method capable of using at least a first pipe, a second pipe and a third pipe defined by the USB specification for transferring streams of data between a first host C 1  and a second host C 2 . Wherein the first pipe P 0  is used for transferring command and status information, and the third pipe P 2  is to used for receiving the command and the status from the first pipe P 0 , and the second pipe P 1  is used for two-way transmission between the first host C 1  and the second host C 2 . Each pipe has a corresponding specific identifier. The command and status information corresponding to the first pipe P 0  and the second pipe P 1  are separately defined by a first identifier ID 0  and a third identifier ID 2 , and the destination information is defined by a second identifier ID 1 . For clarity, hereinafter the identifiers for the first host C 1  are ID 0   1 , ID 1   1 , ID 2   1 , and the identifiers for the second host C 2  are ID 0   2 , ID 1   2 , ID 2   2 , in addition, the three pipes for the first host C 1  are P 0   1 , P 1   1 , P 2   1 ; other three pipes for the second host C 2  are P 0   2 , P 1   2 , P 2   2 . 
   The method of the present invention for transferring the command and status information and the destination information is that: using the first identifier ID 0  to transfer the command and status information via the first pipe P 0 , and using the third identifier ID 2  to receive the command and status information via the third pipe P 2 , and using the second identifier ID 1  to transfer the destination information via the second pipe P 1 . Referring to  FIG. 3 , which is a flowchart depicting the first preferred embodiment of the present invention. The flowchart comprises step of:
         Step S 11 : enabling the first host C 1  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   1  to a first pipe P 0   1  of a logic/control unit  5  which is disposed near the first host C 1 ;   Step S 12 : receiving the command and status information by a left endpoint FIFO P 0   L  of first pipe P 0   1  via the first pipe P 0 , and generating a third identifier ID 2   2  by the logic/control unit  5  in response to the first identifier ID 0   1  to be sent to the second host C 2  via a right endpoint FIFO P 2   R  of third pipe P 2  through the third pipe P 2   2  for enabling the second host C 2  to enter into a ready-to-receive state for receiving a destination information with respect to the third identifier ID 2   2 ;   Step S 13 : generating and outputting a command and status information including a first identifier ID 0   2  by the second host C 2  to be received by a right endpoint FIFO P 0   R  of first pipe P 0 , and generating a third identifier ID 2   1  by the logic/control unit  5  in response to the first identifier ID 0   2  to be sent to the first host C 1  via a left endpoint FIFO P 0   L  of first pipe P 0  through the third pipe P 2   1  for enabling the first host C 1  to be aware that the second host is at a ready-to-receive state for receiving a destination information with respect to the third identifier ID 2   1 ;   Step S 14 : generating and outputting a message comprising a second identifier ID 1   1  and a destination information from the first host C 1  to a rightward FIFO P R  of the logic/control unit  5  via the second pipe P 1   1      Step S 15 : generating and outputting a message including the second identifier ID 1   2  by the logic/control unit  5  to the second host C 2  via the rightward FIFO P R  and the second pipe P 1   2  for enabling the second host C 2  to receive the destination information with respect to the second identifier ID 1   2  while the logic/control unit  5  registering the destination information with respect to the second identifier ID 1   2 .       

   The above steps describe that the mode of the information being transferred from the first host C 1  to the second host C 2 , and the steps for the vice versa are as following:
         Step S 11 ′: enabling the second host C 2  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   2  to a first pipe P 0   2  of a logic/control unit  5  which is disposed near the second host C 2 ;   Step S 12 ′: receiving the command and status information by a right endpoint FIFO P 0   R  of first pipe P 0   2  via the first pipe P 0 , and generating a third identifier ID 2   1  by the logic/control unit  5  in response to the first identifier ID 0   2  to be sent to the first host C 1  via a left endpoint FIFO P 2   L  of third pipe P 2  through the third pipe P 2   1  for enabling the first host C 1  to enter into a ready-to-receive state for receiving a destination information with respect to the third identifier ID 2   1 ;   Step S 13 ′: generating and outputting a command and status information including a first identifier ID 0   1  by the first host C 1  to be received by a left endpoint FIFO P 0   L  of first pipe P 0 , and generating a third identifier ID 2   2  by the logic/control unit  5  in response to the first identifier ID 0   1  to be sent to the second host C 2  via a right endpoint FIFO P 0   R  of third pipe P 2  through the third pipe P 2   1  for enabling the second host C 2  to be aware that the first host is at a ready-to-receive state for receiving a destination information with respect to the third identifier ID 2   2 ;   Step S 14 ′: generating and outputting a message comprising a second identifier ID 1   2  and a destination information from the second host C 2  to a leftward FIFO P L  of the logic/control unit  5  via the second pipe P 1   2      Step S 15 ′: generating and outputting a message including the second identifier ID 1   1  by the logic/control unit  5  to the first host C 1  via the leftward FIFO P L  and the second pipe P 1   1  for enabling the first host C 1  to receive the destination information with respect to the second identifier ID 1   1  while the logic/control unit  5  registering the destination information with respect to the second identifier ID 1   1 .       

   Please refer to  FIG. 4 , which is a diagram depicting a second preferred embodiment of the present invention. The objective of the present invention is to provide a single-chip USB-based host-to-host networking method capable of using at least a first pipe, a second pipe and a third pipe defined by the USB specification for transferring streams of data between a first host C 1  and a second host C 2 . Wherein the first pipe P 0  is used for transferring command and status information, comprising a first pipe P 0   1  disposed near the first host C 1  and a first pipe P 0   2  disposed near the second host C 2 , and the second pipe P 1  and the third pipe P 2  are respectively used for outputting and inputting a destination information with respect to the command and status information of the first pipe P 0 . For clarity, hereinafter the identifiers for the first host C 1  are ID 0   1 , ID 1   1 , ID 2   1 , and the identifiers for the second host C 2  are ID 0   2 , ID 1   2 , ID 2   2 , in addition, the three pipes for the first host C 1  are P 0   1 , P 1   1 , P 2   1 ; other three pipes for the second host C 2  are P 0   2 , P 1   2 , P 2   2 , and a two-way FIFO P D  comprises a rightward FIFO P R  and a leftward FIFO P L . 
   The method of the present invention for transferring the command and status information and the destination information is that: using the first identifier ID 0  to transfer the command and status information via the first pipe P 0 , and using the second identifier ID 1  and the third identifier ID 2  to transfer the destination information. Referring to  FIG. 5 , which is a flowchart depicting the second preferred embodiment of the present invention. The flowchart comprises step of:
         Step S 21 : enabling the first host C 1  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   1  to a first pipe P 0   1  of a logic/control unit  5  which is disposed near the first host C 1 ;   Step S 22 : receiving the command and status information by a left endpoint FIFO P 0   L  of first pipe P 0  via the first pipe P 0   1 , and sending the first identifier ID 0   2  by the logic/control unit  5  to the second host C 2  via a right endpoint FIFO P 2   R  of third pipe P 2  via the first pipe P 0   2  for enabling the second host C 2  to enter into a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   1 ;   Step S 23 : generating and outputting a command and status information including a first identifier ID 0   2  by the second host C 2  to be received by a left endpoint FIFO P 0   L  of first pipe P 0 , and sending the first identifier ID 0   1  by the logic/control unit  5  to the first host C 1  via the first pipe P 0   2  for enabling the first host C 1  to be aware that the second host is at a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   2 ;   Step S 24 : generating and outputting a message comprising a third identifier ID 2   1  and a destination information from the first host C 1  to the logic/control unit  5  via a rightward FIFO P R  of a two-way FIFO P D  and the third pipe P 2   1 ;   Step S 25 : generating and outputting a message including the second identifier ID 1   2  by the logic/control unit  5  to the second host C 2  via the rightward FIFO P R  and the second pipe P 1   2  for enabling the second host C 2  to receive the destination information with respect to the second identifier ID 1   2  while the logic/control unit  5  registering the destination information with respect to the third identifier ID 2   1 .       

   The above steps describe that the mode of the information being transferred from the first host C 1  to the second host C 2 , and the steps for the vice versa are as following:
         Step S 21 ′: enabling the second host C 2  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   2  to a first pipe P 0   2  of a logic/control unit  5  which is disposed near the second host C 2 ;   Step S 22 ′: receiving the command and status information by a left endpoint FIFO P 0   L  of first pipe P 0  via the first pipe P 0   2 , and sending the first identifier ID 0   2  by the logic/control unit  5  to the first host C 1  via the first pipe P 0   1  for enabling the first host C 1  to enter into a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   2 ;   Step S 23 ′: generating and outputting a command and status information including a first identifier ID 0   1  by the first host C 1  to be received by a right endpoint FIFO P 0   R  of first pipe P 0  via the first pipe P 0   1 , and sending the first identifier ID 0   1  by the logic/control unit  5  to the second host C 2  via the first pipe P 0   2  for enabling the second host C 2  to be aware that the first host is at a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   1 ;   Step S 24 ′: generating and outputting a message comprising a third identifier ID 2   2  and a destination information from the second host C 2  to the logic/control unit  5  via a leftward FIFO P L  of a two-way FIFO P D  and the third pipe P 2   2 ;   Step S 25 ′: generating and outputting a message including the second identifier ID 1   1  by the logic/control unit  5  to the first host C 1  via the leftward FIFO P L  and the second pipe P 1   1  for enabling the first host C 1  to receive the destination information with respect to the second identifier ID 1   1  while the logic/control unit  5  registering the destination information with respect to the third identifier ID 2   2 .       

   Please refer to  FIG. 6 , which is a diagram showing a third preferred embodiment of the present invention, and the embodiment is an extended application of the second preferred embodiment. As seen, although the present embodiment substantially has at least a first pipe, a second pipe and a third pipe defined by the USB specification, but two of the one-way pipes can be logically combined into a a two-way pipe. Each pipe has a corresponding specific identifier. A first identifier ID 0  is used for corresponding with the first pipe P 0 , and a second identifier ID 1  is used for corresponding with the two-way pipe P 1 . Wherein the first pipe P 0  is used for transferring command and status information, and the second pipe P 1  is used for outputting/inputting destination information with respect to the command and status information of the first pipe P 0 . For clarity, hereinafter the identifiers for the first host C 1  are ID 0   1 , ID 1   1 , and the identifiers for the second host C 2  are ID 0   2 , ID 1   2 , in addition, the three pipes for the first host C 1  are P 0   1 , P 1   1 , other two pipes for the second host C 2  are P 0   2 , P 1   2 . 
   The method of the present invention for transferring the command and status information and the destination information is that: using the first identifier ID 0  to transfer the command and status information via the first pipe P 0 , and using the second identifier ID 1  to transfer the destination information. Referring to  FIG. 7 , which is a flowchart depicting the third preferred embodiment of the present invention. The flowchart comprises step of:
         Step S 31 : enabling the first host C 1  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   1  to a first pipe P 0   1  of a logic/control unit  5  which is disposed near the first host C 1 ;   Step S 32 : receiving the command and status information by a left endpoint FIFO P 0   L  of first pipe P 0  via the first pipe P 0   1 , and sending the first identifier ID 0   2  by the logic/control unit  5  to the second host C 2  via a right endpoint FIFO P 2   R  of third pipe P 2  via the first pipe P 0   2  for enabling the second host C 2  to enter into a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   1 ;   Step S 33 : generating and outputting a command and status information including a first identifier ID 0   2  by the second host C 2  to be received by a left endpoint FIFO P 0   L  of first pipe P 0 , and sending the first identifier ID 0   1  by the logic/control unit  5  to the first host C 1  via the first pipe P 0   2  for enabling the first host C 1  to be aware that the second host is at a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   2 ;   Step S 34 : generating and outputting a message comprising a second identifier ID 1   1  and a destination information from the first host C 1  to the logic/control unit  5  via a rightward FIFO P R  of a two-way FIFO P D  and the second pipe P 1   2 ;   Step S 35 : generating and outputting a message including the second identifier ID 1   2  by the logic/control unit  5  to the second host C 2  via the rightward FIFO P R  and the second pipe P 1   2  for enabling the second host C 2  to receive the destination information with respect to the second identifier ID 1   2  while the logic/control unit  5  registering the destination information with respect to the second identifier ID 1   2 .       

   The above steps describe that the mode of the information being transferred from the first host C 1  to the second host C 2 , and the steps for the vice versa are as following:
         Step S 31 ′: enabling the second host C 2  to enter a state for transferring a command and status information, and send a message including a first identifier ID 0   2  to a first pipe P 0   2  of a logic/control unit  5  which is disposed near the second host C 2 ;   Step S 32 ′: receiving the command and status information by a left endpoint FIFO P 0   L  of first pipe P 0  via the first pipe P 0   2 , and sending the first identifier ID 0   2  by the logic/control unit  5  to the first host C 1  via the first pipe P 0   1  for enabling the first host C 1  to enter into a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   2 ;   Step S 33 ′: generating and outputting a command and status information including a first identifier ID 0   1  by the first host C 1  to be received by a right endpoint FIFO P 0   R  of first pipe P 0  via the first pipe P 0   1 , and sending the first identifier ID 0   1  by the logic/control unit  5  to the second host C 2  via the first pipe P 0   2  for enabling the second host C 2  to be aware that the first host is at a ready-to-receive state for receiving a destination information with respect to the first identifier ID 0   1 ;   Step S 34 ′: generating and outputting a message comprising a second identifier ID 1   2  and a destination information from the second host C 2  to the logic/control unit  5  via a leftward FIFO P L  of a two-way FIFO P D  and the third pipe P 2   2 ;   Step S 35 ′: generating and outputting a message including the second identifier ID 1   1  by the logic/control unit  5  to the first host C 1  via the leftward FIFO P L  and the second pipe P 1   1  for enabling the first host C 1  to receive the destination information with respect to the second identifier ID 1   1  while the logic/control unit  5  registering the destination information with respect to the second identifier ID 1   1 .       

   Please refer to  FIG. 8 , which is a diagram depicting a fourth preferred embodiment of the present invention. The fourth embodiment is different from the previous three embodiments by that it adopts different protocol by way of self-definition to complete a new mode of data transfer, because of only one USB bus for entity. Previously, Each pipe has a corresponding specific identifier or at least a first identifier ID 0  is being defined for transferring command and status information since there is substantially only one bus existed. Sometimes even two identifiers are being used for handshaking to establish the operation of the command and status information. In practice, the establishment of the operation of the command and status information is only being performed once before transferring the destination information. Therefore, each identifier can be equipped with command/status/destination information simultaneously through the execution of the driver layer. 
   In the present embodiment, each side of an entity has two pipes comprising the protocol of the command/status/destination information, that the protocol is supported by the driver layer. As for the logic/control unit only being used as a two-way communication channel between the two hosts. For clarity, hereinafter the identifiers for the first host C 1  are ID 1   1 , ID 2   1 , and the identifiers for the second host C 2  are ID 1   2 , ID 2   2 , in addition, the three pipes for the first host C 1  are P 1   1 , P 2   1 , other two pipes for the second host C 2  are P 1   2 , P 2   2 . 
   The method of the present invention for transferring the command and status information and the destination information is that: using the second identifier ID 2  to transfer the command/status/destination information via the first pipe P 1 , and using the first identifier ID 1  to receive the command/status/destination information. Referring to  FIG. 9 , which is a flowchart depicting the fourth preferred embodiment of the present invention. The flowchart comprises step of:
         Step S 41 : enabling the first host C 1  to enter a state for transferring a command/status/destination information, and send a message including a second identifier ID 2   1  to a second pipe P 2   1  of a logic/control unit  5  which is disposed near the first host C 1 , wherein the second identifier ID 2   1  includes the command/status/destination information;   Step S 42 : receiving the command/status/destination information by a rightward FIFO P R  via the second pipe P 2   1  while the logic/control unit  5  registering the second identifier ID 2   1 ;   Step S 43 : converting the second identifier ID 2 , into a first identifier ID 1   2  via the rightward FIFO P R , and sending the first identifier ID 1   2  to the second host C 2  via the first pipe P 1   2  for enabling the second host to receive command/status/destination information including the first identifier ID 1   2  with respect to the first identifier ID 1   2 .       

   The above steps describe that the mode of the information being transferred from the first host C 1  to the second host C 2 , and the steps for the vice versa are as following:
         Step S 41 ′: enabling the second host C 2  to enter a state for transferring a command/status/destination information, and send a message including a second identifier ID 2   2  to a second pipe P 2   2  of a logic/control unit  5  which is disposed near the second host C 2 , wherein the second identifier ID 2   2  includes the command/status/destination information;   Step S 42 ′: receiving the command/status/destination information by a leftward FIFO P L  via the second pipe P 2   2  while the logic/control unit  5  registering the second identifier ID 2   2 ;   Step S 43 ′: converting the second identifier ID 2   2  into a first identifier ID 1   1  via the leftward FIFO P L , and sending the first identifier ID 1   1  to the first host Ca via the first pipe P 1   1  for enabling the first host to receive command/status/destination information including the first identifier ID 1   1  with respect to the first identifier ID 1   1 .       

   Please refer to  FIG. 10 , which is diagram depicting a fifth preferred embodiment of the present invention by declaring the two pipes of the fourth embodiment with correspondence to a same identifier, such that the USB networking device only needs one identifier to complete the information transmission. Similarly, Therefore, each identifier can be equipped with command/status/destination information simultaneously through the execution of the driver layer. 
   The method of the present invention for transferring the command and status information and the destination information is that: using the second identifier ID 2  to transfer the command/status/destination information via the first pipe P 1 , and using the first identifier ID 1  to receive the command/status/destination information. Referring to  FIG. 11 , which is a flowchart depicting the fifth preferred embodiment of the present invention. The flowchart comprises step of:
         Step S 51 : enabling the first host C 1  to enter a state for transferring a command/status/destination information, and send an identifier ID 1   1  including the command/status/destination information to a pipe P 1   1  of a logic/control unit  5 ;   Step S 52 : receiving the command/status/destination information by a rightward FIFO P R  via the pipe P 1   1  while the logic/control unit  5  registering the second identifier ID 1   1 ;   Step S 53 : converting the identifier ID 1   1  into an identifier ID 1   2  via the rightward FIFO P R , and sending the identifier ID 1   2  to the second host C 2  via the pipe P 1   2  for enabling the second host to receive command/status/destination information with respect to the identifier ID 1   2 .       

   The above steps describe that the mode of the information being transferred from the first host C 1  to the second host C 2 , and the steps for the vice versa are as following:
         Step S 51 ′: enabling the second host C 2  to enter a state for transferring a command/status/destination information, and send an identifier ID 1   2  including the command/status/destination information to a pipe P 1   2  of a logic/control unit  5 ;   Step S 52 ′: receiving the command/status/destination information by a leftward FIFO P L  via the pipe P 1   2  while the logic/control unit  5  registering the second identifier ID 1   2 ;   Step S 53 ′: converting the identifier ID 1   2  into an identifier ID 1   1  via the leftward FIFO P L , and sending the identifier ID 1   2  to the first host C 1  via the pipe P 1  for enabling the first host to receive command/status/destination information with respect to the identifier ID 1   1 .       

   While the invention has been described by way of example and in terms of a preferred embodiment, it is to be understood that the invention is not limited thereto. To the contrary, it is intended to cover various modifications and similar arrangements and procedures, and the scope of the appended claims therefore should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.