Abstract:
To facilitate efficient communications in a multi bus master system that communicates with a plurality of peripheral devices, a two channel bus is used that shares write and read addresses with data on a transmit channel to reduce wiring density and provide efficient, reliable, and high speed data transfers. The two channel bus includes the transmit channel, a receive channel, and a single control channel that provides control information for both the transmit channel and the receive channel further reducing the signaling requirements of the two channel bus. The control information includes a control flag that specifies control information for data transfers on the two channel bus. The control flag and control information may be supplied in two bus cycles or in a single bus cycle depending on the control requirements for two data transfers occurring in parallel on the two channel bus.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates generally to processing systems employing a bus interconnect structure and, more specifically, to techniques for reducing transfer qualifier signaling on a two channel bus. 
       BACKGROUND OF THE INVENTION 
       [0002]    Many portable products, such as cell phones, laptop computers, personal digital assistants (PDAs) or the like, incorporate a processor executing a program supporting communication and multimedia applications. The processing system for such products conventionally includes a number of components that communicate using a bus. 
         [0003]    A conventional processing system includes one or more processors, associated memory, and a number of peripheral devices determined by product requirements. Such a processing system may use multiple buses with an individual bus utilized between components according to the data transfer rates expected between the components. For example, one of the individual buses may be a shared bus or a point-to-point bus. A shared bus is connected to multiple components and provides a means for the multiple components to communicate over a common shared channel. A point-to-point bus-uses a switching connection between multiple components and provides a switched direct connection path between any two selected components. Multiple direct connection paths may be selected to allow several components to communicate in parallel. 
         [0004]    The conventional shared bus and point-to-point bus include separate read data, read address, read control, write data, write address, and write control channels. For example, a processor may write data to a memory or a peripheral by placing a write address value on the write address channel, write data on the write data channel, and controlling write qualifier signaling on the write control channel. The processor may also read data from a memory or peripheral device by placing a read address value on the read address channel, receiving read data on the read data channel, and controlling read qualifier signaling on the read control channel. 
         [0005]    Although such bus structures provide a standardized way to communicate between components of the processing system, such bus structures require a large number of interface signals. These interface signals require support circuits, such as drivers, receivers, buffers, and control circuits, all of which consume power. In integrated circuit applications, the wiring and support circuits for these interface signals occupy valuable chip area. 
       SUMMARY OF THE DISCLOSURE 
       [0006]    Among its several aspects, the present invention recognizes a need for a simplified bus structure and the advantage in reducing the number of interface signals to reduce power requirements and to maintain a high rate of communication between components in a processing system. To such ends, an embodiment of the invention applies a method of providing control information on a multi-channel bus. Two address values are issued on a transmit channel of the multi-channel bus for two data transactions occurring in parallel on the multi-channel bus. Control information is indicated for both of the two data transactions on a single control channel that supports time multiplexing of the control information. 
         [0007]    Another embodiment of the invention addresses a multi-channel bus. A single transmit channel provides two or more address values for two or more data transactions occurring in parallel on a read channel and the transmit channel. A single control channel supports time multiplexing of control information for each of the two or more data transactions. 
         [0008]    Another embodiment of the invention addresses a two channel bus master. A channel data circuit is configured to multiplex addresses and transmit data for transactions on a transmit channel and to receive data for transactions on a receive channel. A transmit control circuit is configured to supply the addresses to the channel data circuit and control information on a single control channel having a control flag to identify the control information with the transactions on the transmit channel and with the transactions on the receive channel. 
         [0009]    A more complete understanding of the present invention, as well as further features and advantages of the invention, will be apparent from the following Detailed Description and the accompanying drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0010]      FIG. 1  is a block diagram of an exemplary wireless communication system in which an embodiment of the invention may be advantageously employed; 
           [0011]      FIG. 2  is a functional block diagram of a processing system having a plurality of bus masters, a switching fabric, and a plurality of slave devices in accordance with the present invention; 
           [0012]      FIG. 3  is a transfer qualifier signaling list for a two channel bus in accordance with the present invention; 
           [0013]      FIG. 4A  is a timing diagram showing read and write operations between a bus master and a slave device over a two channel bus in accordance with the present invention; 
           [0014]      FIG. 4B  is a timing diagram showing write and read operations interleaved with a single write operation between a bus master and a slave device over a two channel bus in accordance with the present invention; 
           [0015]      FIG. 4C  is a timing diagram showing write and read operations between a bus master and a slave device over a two channel bus when each transfer has the same control information in accordance with the present invention; 
           [0016]      FIG. 5  illustrates an exemplary slave controller circuit for a transmit channel, one control signals, and control flag operations in accordance with the present invention; and 
           [0017]      FIG. 6  illustrates an exemplary master controller circuit for a transmit channel, one control signals, and control flag operations in accordance with the present invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0018]    The present invention will now be described more fully with reference to the accompanying drawings, in which several embodiments of the invention are shown. This invention may, however, be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. 
         [0019]    Computer program code or “program code” for being operated upon or for carrying out operations according to the teachings of the invention may be initially written in a high level programming language such as C, C++, JAVA®, Smalltalk, JavaScript®, Visual Basic®, TSQL, Perl, or in various other programming languages. A program written in one of these languages is compiled to a target processor architecture by converting the high level program code into a native assembler program. Programs for the target processor architecture may also be written directly in the native assembler language. A native assembler program uses instruction mnemonic representations of machine level binary instructions. Program code or computer readable medium as used herein refers to machine language code such as object code whose format is understandable by a processor. 
         [0020]      FIG. 1  illustrates an exemplary wireless communication system  100  in which an embodiment of the invention may be advantageously employed. For purposes of illustration,  FIG. 1  shows three remote units  120 ,  130 , and  150  and two base stations  140 . It will be recognized that common wireless communication systems may have many more remote units and base stations. Remote units  120 ,  130 ,  150 , and base stations  140  which include hardware components, software components, or both as represented by components  125 A,  125 C,  125 B, and  125 D, respectively, have been adapted to embody the invention as discussed further below.  FIG. 1  shows forward link signals  180  from the base stations  140  to the remote units  120 ,  130 , and  150  and reverse link signals  190  from the remote units  120 ,  130 , and  150  to the base stations  140 . 
         [0021]    In  FIG. 1 , remote unit  120  is shown as a mobile telephone, remote unit  130  is shown as a portable computer, and remote unit  150  is shown as a fixed location remote unit in a wireless local loop system. By way of example, the remote units may alternatively be cell phones, pagers, walkie talkies, handheld personal communication system (PCS) units, portable data units such as personal digital assistants, or fixed location data units such as meter reading equipment. Although  FIG. 1  illustrates remote units according to the teachings of the disclosure, the disclosure is not limited to these exemplary illustrated units. Embodiments of the invention may be suitably employed in any processor system having a bus for communicating between a processor, memory, and peripheral components. 
         [0022]      FIG. 2  is a functional block diagram of a processing system  200  having a plurality of bus masters  204   1 ,  204   2 , . . . ,  204   J , a switching fabric  206 , and a plurality of slave devices  208   1 ,  208   2 , . . . ,  208   K  in accordance with the present invention. The bus masters  204   1 ,  204   2 , . . . ,  204   J  each have bus interface circuits  205   1 ,  205   2 , . . . ,  205   J , respectively, and the slave devices  208   1 ,  208   2 , . . . ,  208   K  each have bus interface circuits  209   1 ,  209   2 , . . . ,  209   K , respectively. The switching fabric  206  includes master ports  224   1 ,  224   2 , . . . ,  224   J  that are connected to slave ports  225   1 ,  225   2 , . . . ,  225   K  according to an interconnection strategy, such as a completely connected network. 
         [0023]    A two channel bus according to the present invention includes a transmit channel, a read channel, and a single set of control signals, the one control signals. The transmit channel provides the functionality of one or more address buses and a write data bus of a traditional bus architecture. A sending device, such as a bus master, drives addresses on the transmit channel for both a write data operation and a read data operation. Data is received from a source over the read channel. The one control signals provide the functionality of two or more sets of control signals of a traditional bus architecture and may include transfer qualifiers and channel information. A transfer qualifier is a signal that describes an attribute of a read operation, a write operation, or other bus related operation. For example, a signal that indicates the size of a block of data or payload that is sequentially addressed in memory for a read or a write operation is considered a transfer qualifier. The one control signals identify operations on both the transmit channel and the read channel by time multiplexing the transfer qualifiers and thus provides a significant wiring reduction in a system implementation. 
         [0024]    With regard to  FIG. 2 , the bus masters  204   1 ,  204   2 , . . . ,  204   J  are configured to communicate over two channel buses with the switch fabric  206  using transmit channels  217   1 ,  217   2 , . . . ,  217   J , one control signals  218   1 ,  218   2 , . . . ,  218   J , and read channels  219   1 ,  219   2 , . . . ,  219   J , respectively. The slave devices  208   1 ,  208   2 , . . . ,  208   K  are configured to communicate over two channel buses with the switch fabric  206  using transmit channels  220   1 ,  220   2 , . . . ,  220   K , one control signals  221   1 ,  221   2 , . . . ,  221   K , and read channels  222   1 ,  222   2 , . . . ,  222   K , respectively. For example, transmit channels  217   1 ,  217   2 , . . . ,  217   J  and  220   1 ,  220   2 , . . . ,  220   K  and read channels  219   1 ,  219   2 , . . . ,  219   J  and  222   1 ,  222   2 , . . . ,  222   K  are 64-bit wide buses. A memory system may be designed to support the processing system  200  operations that require 32-bit addresses. Thus, two 32-bit addresses may be presented on any of the 64-bit wide transmit channels during a single clock cycle. 
         [0025]    A bus master, such as one of the bus masters  204   1 ,  204   2 , . . . ,  204   J , may be a processor, such as a general purpose processor, a digital signal processor (DSP), or a multi-core processor having a plurality of processors, a direct memory access (DMA) controller, an application specific circuit, a programmable logic circuit, or the like. For example, a processor acting as a bus master  204   2  employs the associated bus interface  205   2  to drive the transmit channel  217   2  and appropriate control signals  218   2 . The bus interface  205   2  also receives data communicated on the read channel  219   2 . 
         [0026]    A slave device, such as one of the slave devices  208   1 ,  208   2 , . . . ,  208   K , may be any device capable of retrieving and storing information. For example, a storage device acting as slave device  208   2  employs the associated bus interface  209   2  to drive the transmit channel  220   2  and appropriate control signals  221   2 . The bus interface  209   2  also receives data communicated on the read channel  222   2 . The storage device may be an integrated memory device, an external memory device, or a combination of both that stores data and software used in processing system  200  operations. 
         [0027]    In a typical implementation, a control bus for a read channel or for a write channel requires approximately twenty wires, or approximately forty wires for implementations having a separate read control channel and a separate write control channel. Using the present invention, the one control signals may use approximately twenty wires and the control flag an additional four wires or a total of twenty four wires. Thus, there is a sixteen wire savings per bus interface in accordance with the present invention. With reference to  FIG. 2 , with J master ports  224   1 ,  224   2 , . . . ,  224   J  that are connected to K slave ports  225   1 ,  225   2 , . . . ,  225   K , there are J*K two channel buses providing a savings of J*K*16 wires without considering the considerable wiring reduction in the switching fabric  206 . For example, in what might be considered a relatively small system with J=K=10, there is a possible savings of 1,600 wires without considering the switching fabric. A significant savings even in a relatively small system. 
         [0028]      FIG. 3  is a transfer qualifier signaling list  300  for a two channel bus in accordance with the present invention. Instead of having a first set of control signals for a transmit channel and a second set of control signals for a read channel, an embodiment of the present invention uses a single set of control signals, the one control signals, having a control flag to identify operations on both the transmit and read channels. The transfer qualifier signaling list  300  includes control flag values and associated operation specifications  302 - 310 . In one aspect, a control flag value  302  identifies a write data phase or a no operation (NOP) phase when no address information is presented on the transmit channel and no control information is presented on the one control signals. In another aspect, a control flag value  303  identifies control information in a clock period (cycle) “n−1” for a new address A 1  that is presented in a double transaction cycle “n” on the two channel bus. In another aspect, a control flag value  304  identifies control information in a clock cycle “n−1” for a new address A 2  that is presented in a double transaction cycle “n” on the two channel bus. In another aspect, a control flag value  305  identifies control information in a clock cycle “n−1” for two new addresses A 1  and A 2  that are presented in a double transaction cycle “n” on the two channel bus when each transfer has the same control information. In a another aspect, a control flag value  306  identifies control information in cycle “n” for a new address A 1  that is presented in the same cycle “n” for a single transfer on the two channel bus. In a another aspect, a control flag value  307  identifies control information in cycle “n” for a new address A 2  that is presented in the same cycle “n” for a single transfer on the two channel bus. In another aspect, a control flag value  308  identifies control information in cycle “n” for two new addresses A 1  and A 2  that are presented in the same cycle “n” on the two channel bus for two transfers when each transfer has the same control information. In another aspect, a control flag value  309  identifies control information in the same cycle “n” for a new address A 1  that is presented in cycle “n” for two transfers on the two channel bus. In a further aspect, a control flag value  310  identifies control information in the same cycle “n” for a new address A 2  that is presented in cycle “n” for two transfers on the two channel bus. While the transfer qualifier signaling list  300  is shown with binary coded decimal (BCD) encoding, those skilled in the art will realize that a different encoding could be chosen without changing the intent of this invention. 
         [0029]      FIG. 4A  is a timing diagram  400  showing read and write operations between a bus master, such as bus master  204   2  of  FIG. 2 , and a slave device, such as slave device  208   K  of  FIG. 2 , over a two channel bus  402  in accordance with the present invention. A clock  404 , is shown to indicate timing relationships between the signals on the two channel bus  402 . The clock  404  is divided into cycles  405 - 410 . The two channel bus  402  comprises a transmit channel  414 , a read channel  415 , and one control signals  416  including a control flag  417  shown separate from the one control signals  416 . The control flag  417  issues the appropriate control flag as illustrated in  FIG. 3 . The transmit channel  414  and the read channel  415  may both be 64-bit buses, for example. An exemplary packet size transfer qualifier of four 64-bit data packets is applied for both of the read and write operations as one of the signal qualifiers applied on the one control signals  416 . Also, it is assumed in the following example, that internal transmit and receive buffers or as appropriate first in first out (FIFO) buffers are not at full capacity to allow data streaming of the four 64-bit packets on the illustrated two channel bus. 
         [0030]    The “n−1” cycle  405  is either a write data phase for a previous operation or a no operation (NOP) phase as indicated by the slashed lines on the transmit channel  414  in the “n−1” cycle  405 . For such a cycle, a control flag value of “0000” is generally used. However, a control flag value of “0010” may be used that indicates control information is active on the one control signals  416 . For example, control information “0010” for the write address W A2  is presented in the “n−1” cycle  405 , while the write address W A2  is presented in the “n” cycle  406 . Also, control information “1101” for the read address R A1  and the read address R A1  is presented in the “n” cycle  406 . Thus, control information for both of the read and write operations, where both operations require different control information, may be issued on the one control signals  416 . 
         [0031]    The read and write operations on the two channel bus of  FIG. 4A  begin with a bus master, such as the bus master  204   2 , issuing control information C A2  on the one control signals  416  and a value of “0010” on the control flag  417  in the “n−1” cycle  405 . The control flag value “0010” indicates that the control signals are presented in the “n−1” cycle  405  are for the address A 2  presented in the “n” cycle  406 . The address A 2  is associated with the write operation, such as a 32-bit write address, and is illustrated as a write address A 2  (W A2 ) on the transmit channel  414  in the “n” cycle  406 . 
         [0032]    In the “n” cycle  406 , the bus master  204   2  issues control information C A1  on the one control signals  416  and a value of “1101” on the control flag  417 . The control flag value “1101” indicates that the control signals presented in the “n” cycle  406  are for the address A 1  also presented in the “n” cycle  406 . The address A 1  is associated with the read operation, such as a 32-bit read address, and is illustrated as a read address A 1  (R A1 ) on the transmit channel  414  in the “n” cycle  406 . Thus, in the “n” cycle  406  both a 32-bit read address R A1  and a 32-bit write address W A2  are presented on the transmit channel  414 . 
         [0033]    Beginning in “n+1” cycle  407  and continuing through “n+4” cycle  410  the four 64-bit read data packets and the four 64-bit write data packets are streamed across the two channel bus. During these transfers, the control flag  417  is set to a value “0000” indicating no control information is active on the one control signals  416 . Since the initial control information C A2  was overlapped with a previous bus operation in the “n−1” cycle  405 , no delay affected the performance of the two channel bus even though both of the read and write operations required different control information be supplied on the one control signals  416 . Although two cycles are required to transmit the required control information for two transfers with differing control attributes, one of the two cycles is hidden by overlapping it with a previous cycle having a no operation (NOP) or write data phase. It can be appreciated that the control information is not multiplexed onto the transmit channel since to do so would require additional transmit channel cycles and impact system performance of the many transmit and receive bus operations for each bus master and slave device. 
         [0034]      FIG. 4B  is a timing diagram  430  showing write and read operations interleaved with a single write packet operation between a bus master and a slave device over a two channel bus  432  in accordance with the present invention. The clock  434  is divided into cycles  435 - 442 . The two channel bus  432  comprises a transmit channel  444 , a read channel  445 , and a one control signals  446  including a control flag  447  shown separate from the one control signals  446 . For example, the transmit channel  444  and the read channel  445  may both be 64-bit buses. Also, an exemplary packet size transfer qualifier of four 64-bit data packets is applied for both of the read and write operations as one of the signal qualifiers applied on the one control signals  446 . Also, it is assumed that transmit and receive buffers are not at full capacity to allow data streaming of the four 64-bit packets and the single interleaved write packet on the illustrated two channel bus. 
         [0035]    Prior to the four packet write operation completing, a high priority write is interleaved on the transmit channel, after which the transmit channel completes the initial four packet write operation. While a read address may be delegated to the upper portion of the transmit channel as indicated in the read and write operations shown in timing diagram  400  of  FIG. 4A , it is not a requirement of this invention. The timing diagram  430  of  FIG. 4B  illustrates a case where the read address is on the lower portion of the transmit channel. 
         [0036]    The “n−1” cycle  435  is either a write data phase for a previous operation or a no operation (NOP) phase as indicated by the slashed lines on the transmit channel  444  in the “n−1” cycle  435 . For such a cycle, a control flag value of “0000” is generally used. However, a control flag value of “0010” indicates control information is active on the one control signals. Thus, control information for both of the read and write operations, where both operations require different control information, may be issued on the one control signals  446  in the “n−1” cycle  435 . 
         [0037]    The read and write operations on the two channel bus of  FIG. 4B  begin with a bus master, such as the bus master  204   2 , issuing control information C A2  on the one control signals  446  and a value of “0010” on the control flag  447  in the “n−1” cycle  435 . The control flag value “0010” indicates that the control signals presented in the “n−1” cycle  435  are for the address A 2  presented in the “n” cycle  436 . The address A 2  is associated with the read operation, such as a 32-bit read address, and is illustrated as a read address A 2  (R A2 ) on the transmit channel  444  in the “n” cycle  436 . 
         [0038]    In the “n” cycle  436 , the bus master  204   2  issues control information C A1  on the one control signals  446  and a value of “1101” on the control flag  447 . The control flag value “1101” indicates that the control signals presented in the “n” cycle  436  are for the address A 1  also presented in the “n” cycle  436  for two accesses. The address A 1  is associated with the write operation, such as a 32-bit write address, and is illustrated as a write address A 1  (W A1 ) on the transmit channel  444  in the “n” cycle  436 . Thus, in the “n” cycle  436  both a 32-bit read address R A2  and a 32-bit write address W A1  are presented on the transmit channel  444 . 
         [0039]    At “n+1” cycle  437 , a first 64-bit write data packet WD 0   A1  is transferred across the transmit channel  444 . A pending single write operation and a pending read burst operation cause the bus master  204   2  to issue control information C A4  on the one control signals  446  and a value of “0010” on the control flag  447 . The control flag value “0010” indicates that the control signals presented in the “n+1” cycle  437  are for the address A 4  presented in the “n+2” cycle  438 . The address A 4  is associated with the read operation, such as a 32-bit read address, and is illustrated as a read address A 4  (R A4 ) on the transmit channel  444  in the “n+2” cycle  438 . Also, beginning in “n+1” cycle  437  and continuing through “n+4” cycle  440  the four 64-bit read data packets are streamed across the read channel  445 . 
         [0040]    In the “n+2” cycle  438 , the bus master  204   2  issues control information C A3  on the one control signals  446  and a value of “1101” on the control flag  447 . The control flag value “1101” indicates that the control signals presented in the “n+2” cycle  438  are for the write address A 3  also presented in the “n+2” cycle  438 . The address A 4  is associated with the read operation, such as a 32-bit read address, and is illustrated as a read address A 4  (R A4 ) on the transmit channel  444  in the “n+2” cycle  438 . Thus, in the “n+2” cycle  438  both a 32-bit read address R A4  and a 32-bit write address W A3  are presented on the transmit channel  444 . 
         [0041]    At “n+3” cycle  439 , the interleaved single 64-bit write data packet WD 0   A3  is transferred across the transmit channel  444 . The read channel  445  continues with the four 64-bit read data packet transfer, without interference from the interleaved write operation. During the “n+3” cycle  439  to the “n+6” cycle  442 , the control flag  447  is set to a value “0000” indicating no control information is active on the one control signals  446 . 
         [0042]    At “n+4” cycle  440 , a second 64-bit write data packet WD 1   A1  is transferred across the transmit channel  444 . The read channel  445  completes the four 64-bit read data packet transfer, without interference from the interleaved write operation. 
         [0043]    At “n+5” cycle  441 , a third 64-bit write data packet WD 2   A1  is transferred across the transmit channel  444 . The first 64-bit read data packet RD 0   A4  associated with the read address A 4  is transferred across the read channel  445 . 
         [0044]    At “n+6” cycle  442 , a fourth and final 64-bit write data packet WD 3   A1  is transferred across the transmit channel  444 . 
         [0045]    Since the initial control information C A2  was overlapped with a previous bus operation in the “n−1” cycle  435 , no delay affected the performance of the two channel bus even though both of the read and write operations required different control information be supplied on the single one control signals  446 . Although two cycles are required to transmit the required control information for two transfers with differing control attributes, one of the two cycles is hidden by overlapping it with a previous cycle having a no operation (NOP) or write data phase. 
         [0046]      FIG. 4C  is a timing diagram  460  showing write and read operations between a bus master and a slave device over a two channel bus  462  when each transfer has the same control information in accordance with the present invention. The clock  464  is divided into cycles  465 - 469 . The two channel bus  462  comprises a transmit channel  474 , a read channel  475 , and a one control signals  476  including a control flag  477  shown separate from the one control signals  476 . For example, the transmit channel  474  and the read channel  475  may both be 64-bit buses. Also, an exemplary packet size transfer qualifier of four 64-bit data packets is applied for both of the read and write operations as one of the signal qualifiers applied on the one control signals  476 . Also, it is assumed that transmit and receive buffers are not at full capacity to allow data streaming of the four 64-bit packets and the single interleaved write packet on the illustrated two channel bus. 
         [0047]    The read and write operations on the two channel bus of  FIG. 4C  begin with a bus master, such as the bus master  204   2 , issuing control information C A1  and C A2  (C A1,A2 ), when each transfer has the same control information, on the one control signals  476  and a value of “1011” on the control flag  477  in the “n” cycle  465 . The control flag value “1011” indicates that the control signals are presented in the “n” cycle  465  are for both transactions having the addresses A 1  and A 2  also presented in the “n” cycle  465 . The address A 1 , such as a 32-bit address, is associated with the write operation and is illustrated as a write address A 1  (W A1 ) on the transmit channel  474  in the “n” cycle  465 . The address A 2 , such as a 32-bit address, is associated with the read operation and is illustrated as read address R A2  on the transmit channel  474  in the “n” cycle  465 . Thus, control information for both of the read and write operations, where both operations require the same control information, control information C A1  is equal to control information C A2 , may be issued on the one control signals in the same cycle. 
         [0048]    The cycles “n+1”  466  through “n+4”  469  complete the four packet transfers for both the read channel and the transmit channel. The shared control bus, one control signals  476 , in accordance with the present invention exploits spatial and temporal locality of reference for single cycle double pended transactions where the probability of control information for each of the pending transactions being the same is high. 
         [0049]      FIG. 5  illustrates an exemplary slave controller circuit  500  for a transmit channel, one control signals, and control flag operations in accordance with the present invention. The exemplary slave controller circuit  500  is part of the bus interface of a slave device, such as bus interface  209   K  of slave device  208   K  of  FIG. 2  and includes a decoder  504 , a storage circuit  506 , a first in first out (FIFO) write logic circuit  508 , a multiplexer (MUX)  510 , concatenate circuits  512  and  514 , and a transaction address control FIFO  516 . Operation of the slave controller circuit  500  is described with reference to the read and write transactions on the two channel bus  402  of  FIG. 4A  between the bus master  204   2 , and the slave device  208   K  of  FIG. 2 . 
         [0050]    Beginning at “n−1” cycle  405 , the bus interface  205   2  as directed by the bus master  204   2  issues control information C A2  on the one control signals  416  and a value of “0010” on the control flag  417 . The control flag value “0010” indicates that the control signals presented in the “n−1” cycle  405  are for the address A 2  presented in the “n” cycle  406 . The write address A 2  (W A2 ) is a 32-bit write address that is issued, for example, on bits [31:0] of the 64-bit transmit channel  414  in the “n” cycle  406 . At “n−1” cycle  405 , the control flag  417  is decoded in decoder  504  which generates an enable signal  520  to store the values on the one control signals  416  in the storage circuit  506 . The control flag  417  is also stored in the FIFO write logic circuit  508 . 
         [0051]    At “n” cycle  406 , the bus master  204   2  issues control information C A1  on the one control signals  416  and a value of “1101” on the control flag  417 . The control flag value “1101” indicates that the control signals presented in the “n” cycle  406  are associated with the address A 1  also presented in the “n” cycle  406 . The read address A 1  (R A1 ) is a 32-bit read address that is issued, for example, on bits [63:32] of the 64-bit transmit channel  414  in the “n” cycle  406 . At “n” cycle  406 , the control flag  417  is decoded in decoder  504 , but in this case does not generate an enable signal  520  for the storage circuit  506 . The control flag  417  is also stored in the FIFO write logic circuit  508 . 
         [0052]    Also, at the “n” cycle  406 , the FIFO write logic circuit  508  generates a MUX low address enable signal  522  which causes the MUX  510  to select the one control signals values stored from the “n−1” cycle  405  and pass these stored values  524  to the concatenate circuit  514 . The concatenate circuit  514  combines the write address A 2  issued on bits [31:0] of the 64-bit transmit channel  414  with the stored control information C A2  on stored values  524  on the 32+n bit concatenate low bus  526 . The concatenate circuit  512  combines the read address A 1  issued on bits [63:32] of the 64-bit transmit channel  414  with the current control information C A1  on the one control signals  416  on the 32+n bit concatenate high bus  528 . 
         [0053]    Further, during the “n” cycle  406 , the FIFO write logic circuit  508  generates a write high signal  530  and a write low signal  532  to the transaction address control FIFO circuit  516  for storing and controlling the data transactions received on the transmit channel  414 . Transactions of two channel bus to slave device  208   K  may be throttled by space control signal  534  generated by the transaction address control FIFO  516 . The space control signal  534  indicates whether memory space is available in the transaction address control FIFO  516  to store additional data transactions. If memory space is not available, data transactions may be paused pending the availability of memory space. With the control flag  417  having a “0000” value in cycles “n+1” through “n+4” while data is transmitted on the transmit channel  414 , the slave controller circuit  500  enters and stays in an idle state for responding to the one control signals  416  until the control flag  417  indicates control information is present on the one control signals  416 . 
         [0054]      FIG. 6  illustrates an exemplary master controller circuit  600  for a transmit channel, one control signals, and control flag operations in accordance with the present invention. The exemplary master controller circuit  600  is part of the bus interface of a bus master, such as bus interface  205   2  of bus master  204   2  of  FIG. 2 . The master controller circuit  600  includes a channel data bus circuit having a transaction write data FIFO  602 , multiplexers (MUXs)  614  and  615 , storage circuits  608  and  609 , and a receive channel circuit  607 . The master controller circuit  600  also includes a control circuit having a transaction address control FIFO  604 , a FIFO transmit and control circuit  606 , storage circuit  610 , multiplexer  616 , logic NOR circuits  618  and  619 , and logic AND circuits  623  and  624 . Operation of the master controller circuit  600  is described with reference to the read and write transactions on the two channel bus  402  of  FIG. 4A  between the bus master  204   2 , and the slave device  208   K  of  FIG. 2 . 
         [0055]    Prior to the “n−1” cycle  405 , the bus master  204   2  loads write data for a four data packet transmission in the transaction write data FIFO  602 . The bus master  204   2  also loads address and control information in the transaction address control FIFO  604  for both the four data packet transmission and for a four data packet receive operation. The setup operations cause a data available signal  642  and an address available signal  643  to be generated to the FIFO transmit and control circuit  606  to indicate a transaction operation is pending. 
         [0056]    At the “n−1” cycle  405 , the FIFO transmit and control circuit  606 , after receiving indication of a pending transaction operation, asserts a low select signal  640  to fetch the write address W A2  and control information C A2  from the transaction address control FIFO  604 . For this scenario, the FIFO transmit and control circuit  606  may also assert a high select signal  639  to fetch the read address R A1  and control information C A1  from the transaction address control FIFO  604 . An AND control signal  641  is asserted to enable the AND gates  623  and  624 . The Mux  616  receives the asserted low select signal  640  which enables the Mux  616  to select the control information C A2  to be issued on the one control signals  416 . Also, a value of “0010” is issued on the control flag  417  as selected from the storage circuit  610 . The control flag value “0010” indicates that the control signals presented in the “n−1” cycle  405  are for the address W A2  to be presented in the “n” cycle  406 . The write address A 2  (W A2 ) is a 32-bit write address that is issued, for example, on bits [31:0] of the 64-bit transmit channel  414  in the “n” cycle  406 . Since the transmit channel  414  is potentially active and completing a previous operation in the “n−1” cycle  405 , the addresses W A2  and R A1  are stored for use in the next cycle. For example, with a transmit write FIFO signal  638  in a non asserted state, the multiplexers Mux  614  and  615  are enabled to select address information from the transaction address control FIFO  604 . The addresses R A1  and W A2  are stored in the 32-bit storage circuits  608  and  609 , respectively, by the end of the “n−1” cycle  405  or at the start of the “n” cycle  406  using a clock edge, for example. 
         [0057]    At “n” cycle  406 , the control information C A1  is issued on the one control signals  416 . The AND control signal  641  is asserted to enable AND gates  623  and  624 . The low select signal  640  is deasserted causing the MUX  616  to select the control information C A1  and a value of “1101” is issued on the control flag  417  from the storage circuit  610 . The control flag value “1101” indicates that the control signals presented in the “n” cycle  406  are associated with the address R A1  also presented in the “n” cycle  406 . The read address R A1  is a 32-bit read address that is issued, for example, on bits [63:32] of the 64-bit transmit channel  414  in the “n” cycle  406 . The write address W A2  is a 32-bit write address that is issued, for example, on bits [31:0] of the 64-bit transmit channel  414  in the “n” cycle  406 . The transmit write FIFO signal  638  is asserted causing 64 bits of data to be read from the transaction write data FIFO  602  and selected by Mux&#39;s  614  and  615 . The Mux&#39;s  614  and  615  output data is stored in 32-bit storage circuits  608  and  609 , respectively, by the end of the “n” cycle  406  or at the start of the “n+1” cycle  407  using a clock edge, for example. 
         [0058]    At cycle “n+1”  407 , the AND control signal  641  is deasserted at AND gates  623  and  624  causing all zero&#39;s to be issued on the one control signals  416  so that no transition causes unnecessary power use and “0000” is issued on the control flag  417 . The first 64-bit write data packet WD 0   A2  is issued on the transmit channel  414 . The first 64-bit read data packet RD 0   A1  is received in receive channel circuit  607  from the read channel  415 . With the control flag  417  having a “0000” value in cycles “n+1” through “n+4” while data is transmitted on the transmit channel  414 , the master controller circuit  600  for controlling the one control signals  416  enters and stays in an idle state until the bus master  204   2  initiates new control information for another bus operation. 
         [0059]    The methods described in connection with the embodiments disclosed herein may be embodied in a combination of hardware and in a software module storing non-transitory signals executed by a processor. The software module may reside in random access memory (RAM), flash memory, read only memory (ROM), electrically programmable read only memory (EPROM), hard disk, a removable disk, tape, compact disk read only memory (CD-ROM), or any other form of storage medium known in the art. A storage medium may be coupled to the processor such that the processor can read information from, and in some cases write information to, the storage medium. The storage medium coupling to the processor may be a direct coupling integral to a circuit implementation or may utilize one or more interfaces, supporting direct accesses or data streaming using down loading techniques. 
         [0060]    While the invention is disclosed in the context of illustrative embodiments for use in processor systems it will be recognized that a wide variety of implementations may be employed by persons of ordinary skill in the art consistent with the above discussion and the claims which follow below. The present technique is scalable. For example, with a transmit channel of 128 bits supporting 128 bit write data and 32-bit addresses, up to four transaction addresses may be issued on the transmit channel in a single cycle. In this case, the control flags may be issued in cycles “n−3”, “n−2”, and “n−1”, which is three cycles prior to the “n” address phase, where the fourth control flag would be issued. In each of the transmit channel cycles proceeding the “n” address phase, the transmit channel is either a NOP or completing a previous write data transmission and the one control signals may be used to issue control information for each of the four transactions.