Data storage system having crossbar switch with multi-staged routing

Information

  • Patent Grant
  • 6636933
  • Patent Number
    6,636,933
  • Date Filed
    Thursday, December 21, 2000
    23 years ago
  • Date Issued
    Tuesday, October 21, 2003
    21 years ago
Abstract
A memory system having a backplane with a plurality of receiving slots. Each one of the slots has electrical contacts for providing an indication of Such one of the slots. Each one of the slots has a different slot indication. A plurality of memory boards is provided. Each one of the memory boards is plugged into a corresponding one of the slots. Each one of such boards is coupled to the electrical contacts in the corresponding one of the slots to provide a slot signal indicative of the slot indication provided by the electrical contacts. Each one of such boards has: a memory array region; and a switching network for transferring information between a port of the switching network and a memory on such memory boards The transfer is initiated by a director coupled to such port. The director designates a selected one of the plurality of memory boards. The director provides to the switching network a “tag” indicating such designated one of one of the plurality of memory boards having the memory involved in the requested transfer. The switch network includes a memory board checker, for comparing the slot signal with the “tag” for indicating whether the memory board receiving the “tag” is the director designated one of the plurality of memory boards.
Description




TECHNICAL FIELD




This invention relates generally to data storage systems, and more particularly to data storage systems having redundancy arrangements to protect against total system failure in the event of a failure in a component or subassembly of the storage system.




BACKGROUND




As is known in the art, large host computers and servers (collectively referred to herein as “host computer/servers”) require large capacity data storage systems. These large computer/servers generally includes data processors, which perform many operations on data introduced to the host computer/server through peripherals including the data storage system. The results of these operations are output to peripherals, including the storage system.




One type of data storage system is a magnetic disk storage system. Here a bank of disk drives and the host computer/server are coupled together through an interface. The interface includes “front end” or host computer/server controllers (or directors) and “back-end” or disk controllers (or directors). The interface operates the controllers (or directors) in such a way that they are transparent to the host computer/server. That is, data is stored in, and retrieved from, the bank of disk drives in such a way that the host computer/server merely thinks it is operating with its own local disk drive. One such system is described in U.S. Pat. No. 5,206,939, entitled “System and Method for Disk Mapping and Data Retrieval”, inventors Moshe Yanai, Natan Vishlitzky, Bruno Alterescu and Daniel Castel, issued Apr. 27, 1993, and assigned to the same assignee as the present invention.




As described in such U.S. Patent, the interface may also include, in addition to the host computer/server controllers (or directors) and disk controllers (or directors), addressable cache memories. The cache memory is a semiconductor memory and is provided to rapidly store data from the host computer/server before storage in the disk drives, and, on the other hand, store data from the disk drives prior to being sent to the host computer/server. The cache memory being a semiconductor memory, as distinguished from a magnetic memory as in the case of the disk drives, is much faster than the disk drives in reading and writing data.




The host computer/server controllers, disk controllers and cache memory are interconnected through a backplane printed circuit board. More particularly, disk controllers are mounted on disk controller printed circuit boards. The host computer/server controllers are mounted on host computer/server controller printed circuit boards. And, cache memories are mounted on cache memory printed circuit boards. The disk directors, host computer/server directors, and cache memory printed circuit boards plug into the backplane printed circuit board. In order to provide data integrity in case of a failure in a director, the backplane printed circuit board has a pair of buses. One set the disk directors is connected to one bus and another set of the disk directors is connected to the other bus. Likewise, one set the host computer/server directors is connected to one bus and another set of the host computer/server directors is directors connected to the other bus. The cache memories are connected to both buses. Each one of the buses provides data, address and control information.




The arrangement is shown schematically in FIG.


1


. Thus, the use of two buses B


1


, B


2


provides a degree of redundancy to protect against a total system failure in the event that the controllers or disk drives connected to one bus, fail. Further, the use of two buses increases the data transfer bandwidth of the system compared to a system having a single bus. Thus, in operation, when the host computer/server


12


wishes to store data, the host computer


12


issues a write request to one of the front-end directors


14


(i.e., host computer/server directors) to perform a write command. One of the front-end directors


14


replies to the request and asks the host computer


12


for the data. After the request has passed to the requesting one of the front-end directors


14


, the director


14


determines the size of the data and reserves space in the cache memory


18


to store the request. The front-end director


14


then produces control signals on one of the address memory busses B


1


, B


2


connected to such front-end director


14


to enable the transfer to the cache memory


18


. The host computer/server


12


then transfers the data to the front-end director


14


. The front-end director


14


then advises the host computer/server


12


that the transfer is complete. The front-end director


14


looks up in a Table, not shown, stored in the cache memory


18


to determine which one of the back-end directors


20


(i.e., disk directors) is to handle this request. The Table maps the host computer/server


12


addresses into an address in the bank


14


of disk drives. The front-end director


14


then puts a notification in a “mail box” (not shown and stored in the cache memory


18


) for the back-end director


20


, which is to handle the request, the amount of the data and the disk address for the data. Other back-end directors


20


poll the cache memory


18


when they are idle to check their “mail boxes”. If the polled “mail box” indicates a transfer is to be made, the back-end director


20


processes the request, addresses the disk drive in the bank


22


, reads the data from the cache memory


18


and writes it into the addresses of a disk drive in the bank


22


.




When data is to be read from a disk drive in bank


22


to the host computer/server


12


the system operates in a reciprocal manner. More particularly, during a read operation, a read request is instituted by the host computer/server


12


for data at specified memory locations (i.e., a requested data block). One of the front-end directors


14


receives the read request and examines the cache memory


18


to determine whether the requested data block is stored in the cache memory


18


. If the requested data block is in the cache memory


18


, the requested data block is read from the cache memory


18


and is sent to the host computer/server


12


. If the front-end director


14


determines that the requested data block is not in the cache memory


18


(i.e., a so-called “cache miss”) and the director


14


writes a note in the cache memory


18


(i.e., the “mail box”) that it needs to receive the requested data block. The back-end directors


20


poll the cache memory


18


to determine whether there is an action to be taken (i.e., a read operation of the requested block of data). The one of the back-end directors


20


which poll the cache memory


18


mail box and detects a read operation reads the requested data block and initiates storage of such requested data block stored in the cache memory


18


. When the storage is completely written into the cache memory


18


, a read complete indication is placed in the “mail box” in the cache memory


18


. It is to be noted that the front-end directors


14


are polling the cache memory


18


for read complete indications. When one of the polling front-end directors


14


detects a read complete indication, such front-end director


14


completes the transfer of the requested data which is now stored in the cache memory


18


to the host computer/server


12


.




The use of mailboxes and polling requires time to transfer data between the host computer/server


12


and the bank


22


of disk drives thus reducing the operating bandwidth of the interface.




SUMMARY




In accordance with the present invention, a memory system is provided having a backplane with a plurality of receiving slots. Each one of the slots has electrical contacts for providing an indication of such one of the slots. Each one of the slots has a different slot indication. A plurality of memory boards is provided. Each one of the memory boards is plugged into a corresponding one of the slots. Each one of such boards is coupled to the electrical contacts in the corresponding one of the slots to provide a slot signal indicative of the slot indication provided by the electrical contacts. Each one of such boards has: a memory array region; and a switching network for transferring information between a port of the switching network and a memory on such memory board. The transfer is initiated by a director coupled to such port. The director designates a selected one of the plurality of memory boards. The director provides to the switching network a “tag” indicating such designated one of one of the plurality of memory boards having the memory involved in the requested transfer. The switch network includes a memory board checker, for comparing the slot signal with the “tag” for indicating whether the memory board receiving the “tag,” is the director designated one of the plurality of memory boards.




In one embodiment, the memory board checker sends an indication to the requesting director slot signal as to whether the memory board receiving the “tag” is the designated one of the memory boards.




In one embodiment, the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.




In one embodiment, the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.











The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.




DESCRIPTION OF DRAWINGS




These and other features of the invention will become more readily apparent from the following detailed description when read together with the accompanying drawings, in which:





FIG. 1

is a block diagram of a data storage system according to the PRIOR ART;





FIG. 2

is a block diagram of a data storage system according to the invention;





FIG. 2A

shows the fields of a descriptor used in the system interface of the data storage system of

FIG. 2

;





FIG. 2B

shows the filed used in a MAC packet used in the system interface of the data storage system of

FIG. 2

;





FIG. 3

is a sketch of an electrical cabinet storing a system interface used in the data storage system of

FIG. 2

;





FIG. 4

is a diagramatical, isometric sketch showing printed circuit boards providing the system interface of the data storage system of

FIG. 2

;





FIG. 5

is a block diagram of the system interface used in the data storage system of

FIG. 2

;





FIG. 6

shows the relationship between

FIGS. 6A and 6B

which when taken together is a block diagram showing the connections between front-end and back-end directors to one of a pair of message network boards used in the system interface of the data storage system of

FIG. 2

;





FIG. 7

is a block diagram of an exemplary one of the director boards used in the system interface of he data storage system of

FIG. 2

;





FIG. 8

is a block diagram of the system interface used in the data storage system of

FIG. 2

;





FIG. 8A

is a diagram of an exemplary global cache memory board used in the system interface of

FIG. 8

;





FIG. 8B

is a diagram showing a pair of director boards coupled between a pair of host processors and global cache memory boards used in the system interface of

FIG. 8

;





FIGS. 9A

,


9


B and


9


C are a more detailed block diagram of the exemplary cache memory board of

FIG. 8A

;





FIG. 10

is a block diagram of a crossbar switch used in the memory board of

FIGS. 9A

,


9


B and


9


C;





FIGS. 11A

,


11


B,


11


C and


11


D are a block diagram of an upper port interface section used in the crossbar switch of

FIG. 10

;





FIGS. 12A

,


12


B,


12


C and


12


D are a block diagram of a lower port interface section used in the crossbar switch of

FIG. 10

;





FIGS. 13A

,


13


B,


13


C,


13


D and


13


E are a block diagram of a pair of logic sections used in the memory board of

FIGS. 9A

,


9


B and


9


C;





FIGS. 14A

,


14


B,


14


C and


14


D are a block diagram of a pair of port controllers used in the pair of logic sections of

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E;





FIGS. 15A

,


15


B,


15


C,


15


D and


15


E are a block diagram of a pair of arbitration logics used in the pair of logic sections of

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E and of a watchdog section used for such pair of logic sections;





FIG. 16

is a diagram showing words that make up exemplary information cycle used in the memory board of

FIGS. 9A

,


9


B and


9


C;





FIG. 17

is a Truth Table for a majority gate used in the memory board of

FIGS. 9A

,


9


B and


9


C;





FIG. 18

is a block diagram shown interconnections between one of the arbitration units used in one of the pair of port controllers of

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E and a filter used in the arbitration unit of the other one of such pair of controllers of

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E;





FIG. 19

is a timing diagram of signals in arbitration units of

FIG. 18

used of one of the pair of port controllers of

FIGS. 14A

,


14


B,


14


C and


14


D and a filter used in the arbitration unit used in the other one of such pair of controllers of

FIGS. 14A

,


14


B,


14


C and


14


D; and





FIGS. 20A

,


20


B and


20


C are a more detailed block diagram of arbitrations used in the arbitration logics of

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E.











DETAILED DESCRIPTION




Referring now to

FIG. 2

, a data storage system


100


is shown for transferring data between a host computer/server


120


and a bank of disk drives


140


through a system interface


160


. The system interface


160


includes: a plurality of, here 32 front-end directors


180




1


-


180




32


coupled to the host computer/server


120


via ports-


123




32


; a plurality of back-end directors


200




1


-


200




32


coupled to the bank of disk drives


140


via ports


123




33


-


123




64


; a data transfer section


240


, having a global cache memory


220


, coupled to the plurality of front-end directors


180




1


-


180




16


and the back-end directors


200




1


-


200




16


; and a messaging network


260


, operative independently of the data transfer section


240


, coupled to the plurality of front-end directors


180




1


-


180




32


and the plurality of back-end directors


200




1


-


200




32


, as shown. The front-end and back-end directors


180




1


-


180




32


,


200




1


-


200




32


are functionally similar and include a microprocessor (μP)


299


(i.e., a central processing unit (CPU) and RAM), a message engine/CPU controller


314


and a data pipe


316


to be described in detail in connection with

FIGS. 5

,


6


and


7


. Suffice it to say here, however, that the front-end and back-end directors


180




1


-


180




32


,


200




1


-


200




32


control data transfer between the host computer/server


120


and the bank of disk drives


140


in response to messages passing between the directors


180




1


-


180




32


,


200




1


-


200




32


through the messaging network


260


. The messages facilitate the data transfer between host computer/server


120


and the bank of disk drives


140


with such data passing through the global cache memory


220


via the data transfer section


240


. More particularly, in the case of the front-end directors


180




1


-


180




32


, the data passes between the host computer to the global cache memory


220


through the data pipe


316


in the front-end directors


180




1


-


180




32


and the messages pass through the message engine/CPU controller


314


in such front-end directors


180




1


-


180




32


. In the case of the back-end directors


200




1


-


200




32


the data passes between the back-end directors


200




1


-


200




32


and the bank of disk drives


140


and the global cache memory


220


through the data pipe


316


in the back-end directors


200




1


-


200




32


and again the messages pass through the message engine/CPU controller


314


in such back-end director


200




1


-


200




32


.




With such an arrangement, the cache memory


220


in the data transfer section


240


is not burdened with the task of transferring the director messaging. Rather the messaging network


260


operates independent of the data transfer section


240


thereby increasing the operating bandwidth of the system interface


160


.




In operation, and considering first a read request by the host computer/server


120


(i.e., the host computer/server


120


requests data from the bank of disk drives


140


), the request is passed from one of a plurality of, here


32


, host computer processors


121




1


-


121




32


in the host computer


120


to one or more of the pair of the front-end directors


180




1


-


180




32


connected to such host computer processor


121




1


-


121




32


. (It is noted that in the host computer


120


, each one of the host computer processors


121




1


-


121




32


is coupled to here a pair (but not limited to a pair) of the front-end directors


180




1


-


180




32


, to provide redundancy in the event of a failure in one of the front end-directors


181




1


-


181




32


coupled thereto. Likewise, the bank of disk drives


140


has a plurality of, here


32


, disk drives


141




1


-


141




32


, each disk drive


141




1


-


141




32


being coupled to here a pair (but not limited to a pair) of the back-end directors


200




1


-


200




32


, to provide redundancy in the event of a failure in one of the back-end directors


200




1


-


200




32


coupled thereto). Each front-end director


180




1


-


180




32


includes a microprocessor (μP)


299


(i.e., a central processing unit (CPU) and RAM) and will be described in detail in connection with

FIGS. 5 and 7

. Suffice it to say here, however, that the microprocessor


299


makes a request for the data from the global cache memory


220


. The global cache memory


220


has a resident cache management table, not shown. Every director


180




1


-


180




32


,


200




1


-


200




32


has access to the resident cache management table and every time a front-end director


180




1


-


180




32


requests a data transfer, the front-end director


180




1


-


180




32


must query the global cache memory


220


to determine whether the requested data is in the global cache memory


220


. If the requested data is in the global cache memory


220


(i.e., a read “hit”), the front-end director


180




1


-


180




32


, more particularly the microprocessor


299


therein, mediates a DMA (Direct Memory Access) operation for the global cache memory


220


and the requested data is transferred to the requesting host computer processor


121




1


-


121




32


.




If, on the other hand, the front-end director


180




1


-


180




32


receiving the data request determines that the requested data is not in the global cache memory


220


(i.e., a “miss”) as a result of a query of the cache management table in the global cache memory


220


, such front-end director


180




1


-


180




32


concludes that the requested data is in the bank of disk drives


140


. Thus the front-end director


180




1


-


180




32


that received the request for the data must make a request for the data from one of the back-end directors


200




1


-


200




32


in order for such back-end director


200




1


-


200




32


to request the data from the bank of disk drives


140


. The mapping of which back-end directors


200




1


-


200




32


control which disk drives


141




1


-


141




32


in the bank of disk drives


140


is determined during a power-up initialization phase. The map is stored in the global cache memory


220


. Thus, when the front-end director


180




1


-


180




32


makes a request for data from the global cache memory


220


and determines that the requested data is not in the global cache memory


220


(i.e., a “miss”), the front-end director


180




1


-


180




32


is also advised by the map in the global cache memory


220


of the back-end director


200




1


-


200




32


responsible for the requested data in the bank of disk drives


140


. The requesting front-end director


180




1


-


180




32


then must make a request for the data in the bank of disk drives


140


from the map designated back-end director


200




1


-


200




32


. This request between the front-end director


180




1


-


180




32


and the appropriate one of the back-end directors


200




1


-


200




32


(as determined by the map stored in the global cache memory


200


) is by a message which passes from the front-end director


180




1


-


180




32


through the message network


260


to the appropriate back-end director


200




1


-


200




32


. It is noted then that the message does not pass through the global cache memory


220


(i.e., does not pass through the data transfer section


240


) but rather passes through the separate, independent message network


260


. Thus, communication between the directors


180




1


-


180




32


,


200




1


-


200




32


is through the message network


260


and not through the global cache memory


220


. Consequently, valuable bandwidth for the global cache memory


220


is not used for messaging among the directors


180




1


-


180




32


,


200




1


-


200




32


.




Thus, on a global cache memory


220


“read miss”, the front-end director


180




1


-


180




32


sends a message to the appropriate one of the back-end directors


200




1


-


200




32


through the message network


260


to instruct such back-end director


200




1


-


200




32


to transfer the requested data from the bank of disk drives


140


to the global cache memory


220


. When accomplished, the back-end director


200




1


-


200




32


advises the requesting front-end director


180




1


-


180




32


that the transfer is accomplished by a message, which passes from the back-end director


200




1


-


200




32


to the front-end director


180




1


-


180




32


through the message network


260


. In response to the acknowledgement signal, the front-end director


180




1


-


180




32


is thereby advised that such front-end director


180




1


-


180




32


can transfer the data from the global cache memory


220


to the requesting host computer processor


121




1


-


121




32


as described above when there is a cache “read hit”.




It should be noted that there might be one or more back-end directors


200




1


-


200




32


responsible for the requested data. Thus, if only one back-end director


200




1


-


200




32


is responsible for the requested data, the requesting front-end director


180




1


-


180




32


sends a uni-cast message via the message network


260


to only that specific one of the back-end directors


200




1


-


200




32


. On the other hand, if more than one of the back-end directors


200




1


-


200




32


is responsible for the requested data, a multi-cast message (here implemented as a series of uni-cast messages) is sent by the requesting one of the front-end directors


180




1


-


180




32


to all of the back-end directors


200




1


-


200




32


having responsibility for the requested data. In any event, with both a uni-cast or multi-cast message, such message is passed through the message network


260


and not through the data transfer section


240


(i.e., not through the global cache memory


220


).




Likewise, it should be noted that while one of the host computer processors


121




1


-


121




32


might request data, the acknowledgement signal may be sent to the requesting host computer processor


121




1


or one or more other host computer processors


121




1


-


121




32


via a multi-cast (i.e., sequence of uni-cast) messages through the message network


260


to complete the data read operation.




Considering a write operation, the host computer


120


wishes to write data into storage (i.e., into the bank of disk drives


140


). One of the front-end directors


180




1


-


180




32


receives the data from the host computer


120


and writes it into the global cache memory


220


. The front-end director


180




1


-


180




32


then requests the transfer of such data after some period of time when the back-end director


200




1


-


200




32


determines that the data can be removed from such cache memory


220


and stored in the bank of disk drives


140


. Before the transfer to the bank of disk drives


140


, the data in the cache memory


220


is tagged with a bit as “fresh data” (i.e., data which has not been transferred to the bank of disk drives


140


, that is data which is “write pending”). Thus, if there are multiple write requests for the same memory location in the global cache memory


220


(e.g., a particular bank account) before being transferred to the bank of disk drives


140


, the data is overwritten in the cache memory


220


with the most recent data. Each time data is transferred to the global cache memory


220


, the front-end director


180




1


-


180




32


controlling the transfer also informs the host computer


120


that the transfer is complete to thereby free-up the host computer


120


for other data transfers.




When it is time to transfer the data in the global cache memory


220


to the bank of disk drives


140


, as determined by the back-end director


200




1


-


200




32


, the back-end director


200




1


-


200




32


transfers the data from the global cache memory


220


to the bank of disk drives


140


and resets the tag associated with data in the global cache memory


220


(i.e., un-tags the data) to indicate that the data in the global cache memory


220


has been transferred to the bank of disk drives


140


. It is noted that the un-tagged data in the global cache memory


220


remains there until overwritten with new data.




Referring now to

FIGS. 3 and 4

, the system interface


160


is shown to include an electrical cabinet


300


having stored therein: a plurality of, here eight front-end director boards


190




1


-


190




8


, each one having here four of the front-end directors


180




1


-


180




32


; a plurality of, here eight back-end director boards


210




1


-


210




8


, each one having here four of the back-end directors


200




1


-


200




32


; and a plurality of, here eight, memory boards


220


′ which together make up the global cache memory


220


. These boards plug into the front side of a backplane


302


. (It is noted that the backplane


302


is a mid-plane printed circuit board). Plugged into the backside of the backplane


302


are message network boards


304




1


,


304




2


. The backside of the backplane


302


has plugged into it adapter boards, not shown in

FIGS. 2-4

, which couple the boards plugged into the back-side of the backplane


302


with the computer


120


and the bank of disk drives


140


as shown in FIG.


2


. That is, referring again briefly to

FIG. 2

, an I/O adapter, not shown, is coupled between each one of the front-end directors


180




1


-


180




32


and the host computer


120


and an I/O adapter, not shown, is coupled between each one of the back-end directors


200




1


-


200




32


and the bank of disk drives


140


.




Referring now to

FIG. 5

, the system interface


160


is shown to include the director boards


190




1


-


190




8


,


210




1


-


210




8


and the global cache memory


220


, plugged into the backplane


302


and the disk drives


141




1


-


141




32


in the bank of disk drives along with the host computer


120


also plugged into the backplane


302


via I/O adapter boards, not shown. The message network


260


(

FIG. 2

) includes the message network boards


304




1


and


304




2


. Each one of the message network boards


304




1


and


304




2


is identical in construction. A pair of message network boards


304




1


and


304




2


is used for redundancy and for message load balancing. Thus, each message network board


304




1


,


304




2


, includes a controller


306


, (i.e., an initialization and diagnostic processor comprising a CPU, system controller interface and memory, as shown in

FIG. 6

for one of the message network boards


304




1


,


304




2


, here board


304




1


) and a crossbar switch section


308


(e.g., a switching fabric made up of here four switches


308




1


-


308




4


).




Referring again to

FIG. 5

, each one of the director boards


190




1


-


210




8


includes, as noted above four of the directors


180




1


-


180




32


,


200




1


-


200




32


(FIG.


2


). It is noted that the director boards


190




1


-


190




8


having four front-end directors per board,


180




1


-


180




32


are referred to as front-end directors, and the director boards


210




1


-


210




8


having four back-end directors per board,


200




1


-


200




32


are referred to as back-end directors. Each one of the directors


180




1


-


180




32


,


200




1


-


200




32


includes a CPU


310


, a RAM


312


(which make up the microprocessor


299


referred to above), the message engine/CPU controller


314


, and the data pipe


316


.




Each one of the director boards


190




1


-


210




8


includes a crossbar switch


318


. The crossbar switch


318


has four input/output ports


319


, each one being coupled to the data pipe


316


of a corresponding one of the four directors


180




1


-


180




32


,


200




1


-


200




32


on the director board.


190




1


-


210




8


. The crossbar switch


318


has eight output/input ports collectively identified in

FIG. 5

by numerical designation


321


(which plug into the backplane


302


. The crossbar switch


318


on the front-end director boards


191




1


-


191




8


is used for coupling the data pipe


316


of a selected one of the four front-end directors


180




1


-


180




32


on the front-end director board


190




1


-


190




8


to the global cache memory


220


via the backplane


302


and I/O adapter, not shown. The crossbar switch


318


on the back-end director boards


210




1


-


210




8


is used for coupling the data pipe


316


of a selected one of the four back-end directors


200




1


-


200




32


on the back-end director board


210




1


-


210




8


to the global cache memory


220


via the backplane


302


and I/O adapter, not shown. Thus, referring to

FIG. 2

, the data pipe


316


in the front-end directors


180




1


-


180




32


couples data between the host computer


120


and the global cache memory


220


while the data pipe


316


in the back-end directors


200




1


-


200




32


couples data between the bank of disk drives


140


and the global cache memory


220


. It is noted that there are separate point-to-point data paths P


1


-P


64


(

FIG. 2

) between each one of the directors


180




1


-


180




32


,


200




1


-


200




32


and the global cache memory


220


. It is also noted that the backplane


302


is a passive backplane because it is made up of only etched conductors on one or more layers to a printed circuit board. That is, the backplane


302


does not have any active components.




Referring again to

FIG. 5

, each one of the director boards


190




1


-


210




8


includes a crossbar switch


320


. Each crossbar switch


320


has four input/output ports


323


, each one of the four input/output ports


323


being coupled to the message engine/CPU controller


314


of a corresponding one of the four directors


180




1


-


180




32


,


200




1


-


200




32


on the director board


190




1


-


210




8


. Each crossbar switch


320


has a pair of output/input ports


325




1


,


325




2


, which plug into the backplane


302


. Each port


325




1


-


325




2


is coupled to a corresponding one of the message network boards


304




1


,


304




2


, respectively, through the backplane


302


. The crossbar switch


320


on the front-end director boards


190




1


-


190




8


is used to couple the messages between the message engine/CPU controller


314


of a selected one of the four front-end directors


180




1


-


180




32


on the front-end director boards


190




1


-


190




8


and the message network


260


, FIG.


2


. Likewise, the back-end director boards


210




1


-


210




8


are used to couple the messages produced by a selected one of the four back-end directors


200




1


-


200




32


on the back-end director board


210




1


-


210




8


between the message engine/CPU controller


314


of a selected one of such four back-end directors and the message network


260


(FIG.


2


). Thus, referring also to

FIG. 2

, instead of having a separate dedicated message path between each one of the directors


180




1


-


180




32


,


200




1


-


200




32


and the message network


260


(which would require M individual connections to the backplane


302


for each of the directors, where M is an integer), here only M/4 individual connections are required). Thus, the total number of connections between the directors


180




1


-


180




32


,


200




1


-


200




32


and the backplane


302


is reduced to ¼th. Thus, it Should be noted from

FIGS. 2 and 5

that the message network


260


(

FIG. 2

) includes the crossbar switch


320


and the message network boards


304




1


,


304




2


.




Each message is a 64-byte descriptor, shown in

FIG. 2A

, which is created by the CPU


310


(

FIG. 5

) under software control and is stored in a send queue in RAM


312


. When the message is to be read from the send queue in RAM


312


and transmitted through the message network


260


(

FIG. 2

) to one or more other directors via a DMA operation to be described, it is packetized in the packetizer portion of packetizer/de-packetizer


428


(

FIG. 7

) into a MAC type packet, shown in

FIG. 2B

, here using the NGIO protocol specification. There are three types of packets: a message packet section; an acknowledgement packet; and a message network fabric management packet, the latter being used to establish the message network routing during initialization (i.e., during power-up). Each one of the MAC packets has: an 8-byte header which includes source (i.e., transmitting director) and destination (i.e., receiving director) address; a payload; and terminates with a 4-byte Cyclic Redundancy Check (CRC), as shown in FIG.


2


B. The acknowledgement packet (i.e., signal) has a 4-byte acknowledgment payload section. The message packet has a 32-byte payload section. The Fabric Management Packet (FMP) has a 256-byte payload section. The MAC packet is sent to the crossbar switch


320


. The destination portion of the packet is used to indicate the destination for the message and is decoded by the switch


320


to determine which port the message is to be routed. The decoding process uses a decoder table


327


in the switch


318


, such table being initialized by controller during power-up by the initialization and diagnostic processor (controller)


306


(FIG.


5


). The table


327


(

FIG. 7

) provides the relationship between the destination address portion of the MAC packet, which identifies the routing for the message and the one of the four directors


180




1


-


180




32


,


200




1


-


200




32


on the director board


190




1


-


190




8


,


210




1


-


210




8


or to one of the message network boards


304




1


,


304




2


to which the message is to be directed.




More particularly, and referring to

FIG. 5

, a pair of output/input ports


325




1


,


325




2


is provided for each one of the crossbar switches


320


, each one being coupled to a corresponding one of the pair of message network boards


304




1


,


304




2


. Thus, each one of the message network boards


304




1


,


304




2


has sixteen input/output ports


322




1


-


322




16


, each one being coupled to a corresponding one of the output/input ports


325




1


,


325




2


, respectively, of a corresponding one of the director boards


190




1


-


190




8


,


210




1


-


210




8


through the backplane


302


, as shown. Thus, considering exemplary message network board


304




1


,

FIG. 6

, each switch


308




1


-


308




4


also includes three coupling ports


324




1


-


324




3


. The coupling ports


324




1


-


324




3


are used to interconnect the switches


322




1


-


322




4


, as shown in FIG.


6


. Thus, considering message network board


304




1


, input/output ports


322




1


-


322




8


are coupled to output/input ports


325




1


of front-end director boards


190




1


-


190




8


and input/output ports


322




9


-


322




16


are coupled to output/input ports


325




1


of back-end director boards


210




1


-


210




8


, as shown. Likewise, considering message network board


304




2


, input/output ports


322




1


-


322




8


thereof are coupled, via the backplane


302


, to output/input ports


325




2


of front-end director boards


190




1


-


190




8


and input/output ports


322




9


-


322




16


are coupled, via the backplane


302


, to output/input ports


325




2


of back-end director boards


210




1


-


210




8


.




As noted above, each one of the message network boards


304




1


,


304




2


includes a processor


306


(

FIG. 5

) and a crossbar switch section


308


having four switches


308




1


-


308




4


, as shown in

FIGS. 5 and 6

. The switches


308




1


-


308




4


are interconnected as shown so that messages can pass between any pair of the input/output ports


322




1


-


322




16


. Thus, it follow that a message from any one of the front-end directors


180




1


-


180




32


can be coupled to another one of the front-end directors


180




1


-


180




32


and/or to any one of the back-end directors


200




1


-


200




32


. Likewise, a message from any one of the back-end directors


180




1


-


180




32


can be coupled to another one of the back-end directors


180




1


-


180




32


and/or.to any one of the front-end directors


200




1


-


200




32


.




As noted above, each MAC packet (

FIG. 2B

) includes in an address destination portion and a data payload portion. The MAC header is used to indicate the destination for the MAC packet and such MAC header is decoded by the switch to determine which port the MAC packet is to be routed. The decoding process uses a table in the switch


308




1


-


308




4


, such table being initialized by processor


306


during power-up. The table provides the relationship between the MAC header, which identifies the destination for the MAC packet and the route to be taken through the message network. Thus, after initialization, the switches


320


and the switches


308




1


-


308




4


in switch section


308


provides packet routing which enables each one of the directors


180




1


-


180




32


,


200




1


-


200




32


to transmit a message between itself and any other one of the directors, regardless of whether such other director is on the same director board


190




1


-


190




8


,


210




1


-


210




8


or on a different director board. Further, the MAC packet has an additional bit B in the header thereof, as shown in

FIG. 2B

, which enables the message to pass through message network board


304




1


or through message network board


304




2


. During normal operation, this additional bit B is toggled between a logic 1 and a logic 0 so that one message passes through one of the redundant message network boards


304




1


,


304




2


and the next message to pass through the other one of the message network boards


304




1


,


304




2


to balance the load requirement on the system. However, in the event of a failure in one of the message network boards


304




1


,


304




2


, the non-failed one of the boards


304




1


,


304




2


is used exclusively until the failed message network board is replaced.




Referring now to

FIG. 7

, an exemplary one of the director boards


190




1


-


190




8


,


210




1


-


210




8


, here director board


190




1


is shown to include directors


180




1


,


180




3


,


180




5


and


180




7


. An exemplary one of the directors


180




1


-


180




4


, here director


180




1


is shown in detail to include the data pipe


316


, the message engine/CPU controller


314


, the RAM


312


, and the CPU


310


all coupled to the CPU interface bus


317


, as shown. The exemplary director


180




1


also includes: a local cache memory


319


(which is coupled to the CPU


310


); the crossbar switch


318


; and, the crossbar switch


320


, described briefly above in connection with

FIGS. 5 and 6

. The data pipe


316


includes a protocol translator


400


, a quad port RAM


402


and a quad port RAM controller


404


arranged as shown. Briefly, the protocol translator


400


converts between the protocol of the host computer


120


, in the case of a front-end director


180




1


-


180




32


, (and between the protocol used by the disk drives in bank


140


in the case of a back-end director


200




1


-


200




32


) and the protocol between the directors


180




1


-


180




3


,


200




1


-


200




32


and the global memory


220


(FIG.


2


). More particularly, the protocol used the host computer


120


may, for example, be fiber channel, SCSI, ESCON or FICON, for example, as determined by the manufacture of the host computer


120


while the protocol used internal to the system interface


160


(

FIG. 2

) may be selected by the manufacturer of the interface


160


. The quad port RAM


402


is a FIFO controlled by controller


404


because the rate data coming into the RAM


402


may be different from the rate data leaving the RAM


402


. The RAM


402


has four ports, each adapted to handle an 18 bit digital word. Here, the protocol translator


400


produces 36 bit digital words for the system interface


160


(

FIG. 2

) protocol, one 18 bit portion of the word is coupled to one of a pair of the ports of the quad port RAM


402


and the other 18 bit portion of the word is coupled to the other one of the pair of the ports of the quad port RAM


402


. The quad port RAM has a pair of ports


402


A,


402


B, each one of to ports


402


A,


402


B being adapted to handle an 18 bit digital word. Each one of the ports


402


A,


402


B is independently controllable and has independent, but arbitrated, access to the memory array within the RAM


402


. Data is transferred between the ports


402


A,


402


B and the cache memory


220


(

FIG. 2

) through the crossbar switch


318


, as shown.




The crossbar switch


318


includes a pair of switches


406


A,


406


B. Each one of the switches


406


A,


406


B includes four input/output director-side ports D


1


-D


4


(collectively referred to above in connection with

FIG. 5

as port


319


) and four input/output memory-side ports M


1


-M


4


, M


5


-M


8


, respectively, as indicated. The input/output memory-side ports M


1


-M


4


, M


5


-M


8


were collectively referred to above in connection with

FIG. 5

as port


317


). The director-side ports D


1


-D


4


of switch


406


A are connected to the


402


A ports of the quad port RAMs


402


in each one the directors


180




1


,


180




3


,


180




5


and


180




7


, as indicated. Likewise, director-side ports of switch


406


B are connected to the


402


B ports of the quad port RAMs


402


in each one the directors


180




1


,


180




3


,


180




5


, and


180




7


, as indicated. The ports D


1


-D


4


are selectively coupled to the ports M


1


-M


4


in accordance with control words provided to the switch


406


A by the controllers in directors


180




1


,


180




3


,


180




5


,


180




7


on busses R


A1


-R


A4


, respectively, and the ports D


1


-D


4


are coupled to ports M


5


-M


8


in accordance with the control words provided to switch


406


B by the controllers in directors


180




1


,


180




3


,


180




5


,


180




7


on busses R


B1


-R


B4


, as indicated. The signals on buses R


A1


-R


A4


are request signals. Thus, port


402


A of any one of the directors


180




1


,


180




3


,


180




5


,


180




7


may be coupled to any one of the ports M


1


-M


4


of switch


406


A, selectively in accordance with the request signals on buses R


A1


-R


A4


. Likewise, port


402


B of any one of the directors


180




1


-


180




4


may be coupled to any one of the ports M


5


-M


8


of switch


406


B, selectively in accordance with the request signals on buses R


B1


-R


B4


. The coupling between the director boards


190




1


-


190




8


,


210




1


-


210




8


and the global cache memory


220


is shown in FIG.


8


.




More particularly, and referring also to

FIG. 2

, as noted above, each one of the host computer processors


121




1


-


121




32


in the host computer


120


is coupled to a pair of the front-end directors


180




1


-


180




32


, to provide redundancy in the event of a failure in one of the front end-directors


181




1


-


181




32


coupled thereto. Likewise, the bank of disk drives


140


has a plurality of, here


32


, disk drives


141




1


-


141




32


, each disk drive


141




1


-


141




32


being coupled to a pair of the back-end directors


200




1


-


200




32


, to provide redundancy in the event of a failure in one of the back-end directors


200




1


-


200




32


coupled thereto). Thus, considering exemplary host computer processor


121




1


, such processor


121




1


is coupled to a pair of front-end directors


180




1


,


180




2


. Thus, if director


180




1


fails, the host computer processor


121




1


can still access the system interface


160


, albeit by the other front-end director


180




2


. Thus, directors


180




1


and


180




2


are considered redundancy pairs of directors. Likewise, other redundancy pairs of front-end directors are: front-end directors


180




3


,


180




4


;


180




5


,


180




6


;


180




7


,


180




8


;


180




9


,


180




10


;


180




11


,


180




12


;


180




13


,


180




14


;


180




15


,


180




16


;


180




17


,


180




18


;


180




19


,


180




20


;


180




21


,


180




22


,


180




23


,


180




24


;


180




25


,


180




26


;


180




27


,


180




28


;


180




29


,


180




30


; and


180




31


,


180




32


(only directors


180




31


and


180




32


being shown in FIG.


2


).




Likewise, disk drive


141




1


is coupled to a pair of back-end directors


200




1


,


200




2


. Thus, if director


200




1


fails, the disk drive


141




1


can still access the system interface


160


, albeit by the other back-end director


180




2


. Thus, directors


200




1


and


200




2


are considered redundancy pairs of directors. Likewise, other redundancy pairs of back-end directors are: back-end directors


200




3


,


200




4


;


200




5


,


200




6


;


200




7


,


200




8


;


200




9


,


200




10


;


200




11


,


200




12


;


200




13


,


200




14


;


200




15


,


200




16


,


200




17


,


200




18


;


200




19


,


200




20


;


200




21


,


200




22


;


200




23


,


200




24


;


200




25


,


200




26


;


200




27


,


200




28


;


200




29


,


200




30


; and


200




31


,


200




32


(only directors


200




31


and


200




32


being shown in FIG.


2


). Further, referring also to

FIG. 8

, the global cache memory


220


includes a plurality of, here eight, cache memory boards


220




1


-


220




8


, as shown. Still further, referring to

FIG. 8A

, an exemplary one of the cache memory boards, here board


220




1


is shown in detail and will be described in detail in connection with

FIGS. 23-29

. Here, each cache memory board includes four memory array regions, an exemplary one thereof being shown and described in connection with FIG. 6 of U.S. Pat. No. 5,943,287 entitled “Fault Tolerant Memory System”, John K. Walton, inventor, issued Aug. 24, 1999 and assigned to the same assignee as the present invention, the entire subject matter therein being incorporated herein by reference. Further detail of the exemplary one of the cache memory boards.




As shown in

FIG. 8A

, the board


220




1


includes a plurality of, here four RAM memory arrays, each one of the arrays has a pair of redundant ports, i.e., an A port and a B port. The board itself has sixteen ports; a set of eight A ports M


A1


-M


A8


and a set of eight B ports M


B1


-M


B8


. Four of the eight A port, here A ports M


A1


-M


A4


are coupled to the M


1


port of each of the front-end director boards


190




1


,


190




3


,


190




5


, and


190




7


, respectively, as indicated in FIG.


8


. Four of the eight B port, here B ports M


B1


-M


B4


are coupled to the M


1


port of each of the front-end director boards


190




2


,


190




4


,


190




6


, and


190




8


, respectively, as indicated in FIG.


8


. The other four of the eight A port, here A ports M


A5


-M


A8


are coupled to the M


1


port of each of the back-end director boards


210




1


,


210




3


,


210




5


, and


210




7


, respectively, as indicated in FIG.


8


. The other four of the eight B port, here B ports M


B5


-M


B8


are coupled to the M


1


port of each of the back-end director boards


210




2


,


210




4


,


210




6


, and


210




8


, respectively, as indicated in

FIG. 8






Considering the exemplary four A ports M


A1


-M


A4


, each one of the four A ports M


A1


-M


A4


can be coupled to the A port of any one of the memory arrays through the logic network


221




1A


, to be described in more detail in connection with

FIGS. 25

,


126


and


27


. Thus, considering port M


A1


, such port can be coupled to the A port of the four memory arrays. Likewise, considering the four A ports M


A5


-M


A8


, each one of the four A ports M


A5


-M


A8


can be coupled to the A port of any one of the memory arrays through the logic network


221




1B


. Likewise, considering the four B ports M


B1


-M


B4


, each one of the four B ports M


B1


-M


B4


can be coupled to the B port of any one of the memory arrays through logic network


221




1B


. Likewise, considering the four B ports M


B5


-M


B8


, each one of the four B ports M


B5


-M


B8


can be coupled to the B port of any one of the memory arrays through the logic network


221




2B


. Thus, considering port M


B1


, such port can be coupled to the B port of the four memory arrays. Thus, there are two paths data and control from either a front-end director


180




1


-


180




32


or a back-end director


200




1


-


200




32


can reach each one of the four memory arrays on the memory board. Thus, there are eight sets of redundant ports on a memory board, i.e., ports M


A1


, M


B1


; M


A2


, M


B2


; M


A3


, M


B3


; M


A4


, MB


4


; MA


5


, M


B5


; M


A6


, M


B6


; M


A7


, M


B7


; and M


A8


, M


B8


. Further, as noted above each one of the directors has a pair of redundant ports, i.e. a


402


A port and a


402


B port (FIG.


7


). Thus, for each pair of redundant directors, the A port (i.e., port


402


A) of one of the directors in the pair is connected to one of the pair of redundant memory ports and the B port (i.e.,


402


B) of the other one of the directors in such pair is connected to the other one of the pair of redundant memory ports.




More particularly, referring to

FIG. 8B

, an exemplary pair of redundant directors is shown, here, for example, front-end director


180




1


and front end-director


180




2


. It is first noted that the directors


180




1


,


180




2


in each redundant pair of directors must be on different director boards, here boards


190




1


,


190




2


, respectively. Thus, here front-end director boards


190




1


-


190




8


have thereon: front-end directors


180




1


,


180




3


,


180




5


and


180




7


; front-end directors


180




2


,


180




4


,


180




6


and


180




8


; front end directors


180




9


,


180




11


,


180




13


and


180




15


; front end directors


180




10


,


180




12


,


180




14


and


180




16


; front-end directors


180




17


,


180




19


,


180




21


and


180




23


, front-end directors


180




18


,


180




20


,


180




22


and


180




24


; front-end directors


180




25


,


180




27


,


180




29


and


180




31


; front-end directors


180




18


,


180




20


,


180




22


and


180




24


. Thus, here back-end director boards


210




1


-


210




8


have thereon: back-end directors


200




1


,


200




3


,


200




5


and


200




7


; back-end directors


200




2


,


200




4


,


200




6


and


200




8


; back-end directors


200




9


,


200




11


,


200




13


and


200




15


; back-end directors


200




10


,


200




12


,


200




14


and


200




16


; back-end directors


200




17


,


200




19


,


200




21


and


200




23


; back-end directors


200




18


,


200




20


,


200




22


and


200




24


; back-end directors


200




25


,


200




27


,


200




29


and


200




31


; back-end directors


200




18


,


200




20


,


200




22


and


200




24


.




Thus, here front-end director


180




1


, shown in

FIG. 8A

, is on front-end director board


190




1


and its redundant front-end director


180




2


, shown in

FIG. 8B

, is on anther front-end director board, here for example, front-end director board


190




2


. As described above, the port


402


A of the quad port RAM


402


(i.e., the A port referred to above) is connected to switch


406


A of crossbar switch


318


and the port


402


B of the quad port RAM


402


(i.e., the B port referred to above) is connected to switch


406


B of crossbar switch


318


. Likewise, for redundant director


180




2


. However, the ports M


1


-M


4


of switch


406


A of director


180




1


are connected to the M


A1


ports of global cache memory boards


220




1


-


200




4


, as shown, while for its redundancy director


180




2


, the ports M


1


-M


4


of switch


406


A are connected to the redundant M


B1


ports of global cache memory boards


220




1


-


200




4


, as shown.




Further details are provided in co-pending patent application Ser. No. 09/561,531 filed Apr. 28, 2000 and Ser. No. 09/561,161 assigned to the same assignee as the present patent application, the entire subject matter thereof being incorporated herein by reference.




CACHE MEMORY BOARDS




Referring again to

FIG. 8

, the system includes a plurality of, here eight, memory boards. As described above in connection with

FIG. 8A

, each one of the memory boards includes four memory array regions R


1


-R


4


. Referring now to

FIGS. 9A

,


9


B and


90


C, an exemplary one of the cache memory boards in the cache memory


220


(FIG.


8


), here cache memory board


220




1


, is shown in more detail to include, here, the four logic networks


221




1B


,


221




2B


,


221




1A


, and


221




2A


and, here eight interface, or memory region control, sections, here logic sections


5010




1


-


5010




8


, arranged as shown.




Each one of the four logic networks


221




1B


,


221




2B


,


221




1A


, and


221




2A


includes four sets of serial-to-parallel converters (S/P), each one of the sets having four of the S/P converters. The sets of S/P converters are coupled between ports M


B1


-M


B4


, M


B5


-M


B8


, M


A1


-M


A4


, and M


A5


—M


A5


, respectively, and a corresponding one of four crossbar switches


5004




1


-


5004




4


. The S/Ps convert between a serial stream of information (i.e., data, address, and control. Cyclic Redundancy Checks (CRCs), signaling semaphores, etc.) at ports M


B1


-M


B8


, M


A1


-M


A8


, and a parallel stream of the information which passes through the crossbar switches


5004




1


-


5004




4


. Thus, here the crossbar switches


5004




1


-


5004




4


process parallel information. Information is transferred between directors and the crossbar switches as transfers, or information cycles. An exemplary information transfer for information passing for storage in the memory array region is shown in FIG.


16


. Each information cycle is shown to include a plurality of sixteen bit words, each word being associated with a clock pulse. Thus, first word 0 is shown to include protocol signaling (e.g., semaphore) and a terminating “start-frame” indication. The next word 1 includes memory control information. The next three words, 2-4, include memory address (ADDR) information. The next word, 5, is a “tag” which indicated the memory board, memory array region, and other information to be described. The next two words, 6 and 7, provide Cyclic Redundancy Checks (CRC) information regarding the address (ADDR_CRC). The DATA to be written into the memory then follows. The number of words of DATA is variable and here is between 4 words and 256 words. The information cycle terminates with two words, X and Y which include DATA CRC information.




As will be described in more detail below, the cache memory board


220




1


is a multi-ported design which allows equal access to one of several, here four, regions of memory (i.e., here memory array regions R


1


-R


4


) from any of here sixteen ports M


B1


-M


B8


, M


A1


-M


A8


. The sixteen ports M


B1


-M


B8


, M


A1


-M


A8


are grouped into four sets S


1


-S


4


. Each one of the sets S


1


-S


4


is associated with, i.e., coupled to, a corresponding one of the four crossbar switches


5004




1


-


5004




4


, respectively, as indicated. Each one of the crossbar switches


5004




1


-


5004




4


interconnects its upper foul ports


5006




1


-


5006




4


to a corresponding one of the four memory regions R


1


-R


4


in a point-to-point fashion. Thus, between the four crossbar switches


5004




1


-


5004




4


and the four memory regions R


1


-R


4


there are sixteen potential unique interconnects.




The communication between any port M


B1


-M


B8


, M


A1


-M


A8


and its corresponding crossbar switch


5004




1


-


5004




4


is protected by Cyclic Redundancy Check (CRC) defined by CCITT-V.41. The communication between a crossbar switch


5004




1


-


5004




4


and the memory array region R


1


-R


4


is protected by byte parity (p). There is a pipelined architecture from the port M


B1


-M


B8


, M


A1


-M


A8


. Such architecture includes a pipeline having the crossbar switches


5004




1


-


5004




4


, the logic sections


5010




1


-


5010




8


and, the memory array regions R


1


-R


4


.




Each one of the memory regions R


1


-R


4


is here comprised of SDRAM memory chips, as noted above. Each one of these regions R


1


-R


4


is coupled to the four crossbar switches


5004




1


-


5004




4


through a pair of memory region controller, herein referred to as logic sections, here logic sections


5010




1


,


5010




2


; . . .


5010




7


,


5010




8


, respectively. Each logic section


5010




1


-


5010




8


is dual ported, (i.e., Port_A, (A) and Port_B, (B)) with each port being coupled to one of the crossbar switches. The two logic sections


5010




1


,


5010




2


; . . .


5010




7


,


5010




8


(i.e., region controllers) associated with one of the memory regions R


1


-R


4


, respectively, share control of the SDRAM in such memory region. More particularly, and as will be described in more detail below, each pair of logic section, such as for example pair


5010




1


and


5010




2


, share a common DATA port of memory array region R


1


. However, each one of the logic sections


5010




1


and


5010




2


is coupled to a different control port P


A


and P


B


, respectively, of memory array region R


1


, as indicated.




More particularly, each one of the crossbar switches


5004




1


-


5004




4


has, here, four lower ports


5008




1


-


5008




4


and four upper ports


5006




1


-


5006




4


. Each one of the four upper ports


5006




1


-


5006




4


, is, as noted above, coupled to a corresponding one of the four sets S


1


-S


4


, respectively, of four of the S/P converters. As noted above, the cache memory board


220




1


also includes eight logic sections coupled


5010




1


-


5010




8


(to be described in detail in connection with

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) as well as the four memory array regions R


1


-R


4


. An exemplary one of the memory array regions R


1


-R


4


is described in connection with FIG. 6 of U.S. Pat. No. 5,943,287. As described in such U. S. Patent, each one of the memory array regions includes a pair of redundant control ports P


A


, P


B


and a data/chip select port (here designated as DATA). As described in such U. S. Patent, data may be written into, or read from, one of the memory array regions by control signals fed to either port P


A


or to port P


B


. In either case, the data fed to, or read from, the memory array region is on the common DATA port.




An exemplary one of the logic sections


5010




1


-


5010




8


will be discussed below in detail in connection with

FIGS. 13A-15E

and an exemplary one of the crossbar switches


5004




1


-


5004




4


in the logic networks


221




1B


-


221




2A


will be discussed below in detail in connection with

FIGS. 10-12D

. Suffice it to say here, however, each one of the memory array regions R


1


-R


4


is coupled to a pair of the logic sections


5010




1


,


5010




2


;


5010




3


,


5010




4


;


5010




5


,


5010




6


;


5010




7


,


5010




8


, respectively, as shown. More particularly, each one of the logic sections


5010




1


,


5010




2


;


5010




3


,


5010




4




5010




5


,


5010




6


;


5010




7


,


5010




8


includes: a pair of upper ports, Port_A (A), Port_B (B); a control port, C; and a data port, D, as indicated. The control port C of one each one of the logic sections


5010




1


,


5010




3


,


5010




5


,


5010




7


, is coupled to port P


A


of a corresponding one of the four memory array regions R


1


-R


4


. In like manner, the control port C of one of each one of the logic sections


5010




2


,


5010




4


,


5010




6


,


5010




8


is coupled to port P


B


of a corresponding one of the four memory array regions R


1


-R


4


, respectively as shown. Thus, each one of the memory array regions R


1


-R


4


is coupled to a redundant pair of the logic sections


5010




1


,


5010




2


;


5010




3


,


5010




4


;


5010




5


,


5010




6


;


5010




7


,


5010




8


, respectively. The data ports D of logic section pairs


5010




1


,


5010




2


;


5010




3


,


5010




4


;


5010




5


,


5010




6


;


5010




7


,


5010




8


, respectively, are coupled together and to the DATA port of a corresponding one of the memory regions, R


1


-R


4


, respectively, as indicated.




It should be noted that each one of the crossbar switches


5004




1


-


5004




4


is adapted to couple the upper ports


5006




1


-


5006




4


thereof to the lower ports


5008




1


-


5008




4


thereof selectively in accordance with a portion (i.e., a “tag” portion) of the information fed to the crossbar switch. In response to such “tag” portion, a transfer of information between a selected one of the memory array regions R


1


-R


4


and a selected the of the directors coupled to the crossbar switch is enabled. The memory control portion (e.g., read, write, row address select, column address select, etc.) of the information passes between either port A or port B of a logic sections


5010




1


,


5010




3


,


5010




5


,


5010




7


, and port P


A


of the memory array region R


1


-R


4


coupled to such logic section and the data (DATA) portion of the information passes to the DATA port of such coupled memory array region R


1


-R


4


, respectively. Likewise, the control portion of the information passes between port A or port B of a logic sections


5010




2


,


5010




4


,


5010




6


,


5010




8


, and port P


B


of the memory array region R


1


-R


4


coupled to such logic section and the data portion of the information passes to the DATA port of such coupled memory array region R


1


-R


4


, respectively.




Thus, each one of the logic sections


5010




1


-


5010




8


includes a pair of redundant upper ports, A and B. The lower ports


5008




1


-


5008




4


of crossbar switch


5004




1


, are coupled to the A port of logic sections


5010




1


,


5010




3


,


5010




5


, and


5010




7


, respectively, while the lower ports


5008




1


-


5008




4


of crossbar switch


5004




2


are coupled to the B port of logic sections


5010




1


,


5010




3


,


5010




5


, and


5010




7


, respectively. The lower ports


5008




1


-


5008




4


of crossbar switch


5004




3


are coupled to the A port of logic sections


5010




1


,


5010




3


,


5010




5


, and


5010




7


, respectively, while the lower ports


5008




1


-


5008




4


of crossbar switch


5004




4


are coupled to the B port of logic sections


5010




2


,


5010




4


,


5010




6


, and


5010




8


, respectively.




As noted above in connection with

FIG. 2

, each one of the host computer processors


121




1


-


121




32


is coupled to here a pair (but not limited to a pair) of the front-end directors


180




1


-


180




32


, to provide redundancy in the event of a failure in one of the front end-directors


181




1


-


181




32


coupled thereto. Likewise, the bank of disk drives


140


has a plurality of, here


32


, disk drives


141




1


-


141




32


, each disk drive


141




1


-


141




32


is coupled to here a pair (but not limited to a pair) of the back-end directors


200




1


-


200




32


, to provide redundancy in the event of a failure in one of the back-end directors


200




1


-


200




32


coupled thereto. Thus, the system has redundant front-end processor pairs


121




1


,


121




2


through


121




31


,


121




32


and redundant back-end processor pairs


141




1


,


141




2


through


141




31


,


141




32


. Considering the exemplary logic network


220




1


shown in

FIGS. 9A

,


9


B and


9


C, as noted above in connection with

FIG. 8B

, redundant front-end processor pairs


121




1


and


121




2


, are able to be coupled to ports M


A1


and M


B1


of a cache memory board. Thus, the ports M


A1


and M


B1


may be considered as redundant memory board ports. In like manner, the following may be considered as redundant memory ports because the are able to be coupled to a pair of redundant processors: M


A2


and M


B2


; M


A3


and M


B3


; M


A4


and M


B4


; M


A5


and M


B5


; M


A6


and M


B6


; M


A7


and M


B7


; and, M


A8


and M


B8


. It is noted that ports M


A1


and M


B1


; M


A2


and M


B2


; M


A3


and M


B3


; M


A4


and M


B4


are coupled to the front-end processors through front-end directors and ports M


A5


and M


B5


; M


A6


and M


B6


; M


A7


and M


B7


; M


A8


and M


B8


are coupled to the disk drives through back-end directors.




Referring again to

FIGS. 9A

,


9


B and


9


C, from the above it should be noted then that logic networks


221




1B


and


221




1A


may be considered as a pair of redundant logic networks (i.e., pair


1


) because they are able to be coupled to redundant pairs of processors, here front-end processors. Likewise, logic networks


221




2B


and


221




2A


may be considered as a pair of redundant logic networks (i.e., pair


2


) because they are able to be coupled to redundant pairs of disk drives. Further, logic network


221




1B


of pair


1


is coupled to upper port A of logic sections


5010




1


,


5010




3


,


5010




5


, and


5010




7


while logic network


221




1A


of pair


1


is coupled to port A of the logic sections


5010




2


,


5010




4


,


5010




6


, and


5010




8


. Logic network


221




2B


of pair


2


is coupled to port B of logic sections


5010




1


,


5010




3


,


5010




5


, and


5010




7


while logic network


221




2A


of pair


2


is coupled to port B of the logic sections


5010




2


,


5010




4


,


5010




6


, and


5010




8


.




Thus, from the above it is noted that ports M


B1


-M


B4


, which are coupled to one of a pair of redundant processors, are adapted to be coupled to one of the ports in a pair of redundant control ports, here port P


A


of the four memory array regions R


1


-R


4


while ports M


A1


-M


A4


, of the other one of the pair of redundant processors are adapted to be coupled to the other one of the ports of the redundant control ports, here port P


B


of the four memory array regions R


1


-R


4


. Likewise, ports M


B5


-M


B8


, which are coupled to one of a pair of redundant processors, are adapted to be coupled to one of the ports in a pair of redundant control ports, here port P


A


of the four memory array regions R


1


-R


4


while ports M


A5


-M


A8


, of the other one of the pair of redundant processors are adapted to be coupled to the other one of the ports of the redundant control ports, here port P


B


of the four memory array regions R


1


-R


4


.




Thus, the memory board


220




1


(

FIGS. 9A

,


9


B and


9


C) is arranged with a pair of independent fault domains: One fault domain, Fault Domain A, is associated with logic networks


221




1B


and


221




2B


, logic sections


5010




1


,


5010




3




5010




5


,


5010




7


, and ports P


A


of the memory array regions R


1


-R


4


and, the other fault domain, Fault Domain B, is associated with logic networks


221




1A


and


221




2A


, logic sections


5010




2


,


5010




4


,


5010




6


,


5010




8


and port P


B


of the memory array regions R


1


-R


4


. The logic in each one of the fault domains is operated by a corresponding one of a pair of independent clocks, Clock


1


and Clock


2


(

FIGS. 9A

,


9


B and


9


C). More generally, a fault domain is defined as a collection of devices which share one or more common points of failure. Here, Fault Domain A includes: logic networks


221




1B


,


221




2B


(i.e., the S/Ps and crossbar switches


5004




1


-


5004




2


therein) and logic sections


5010




1


,


5010




3


,


5010




5


,


5010




7


, such devices being indicated by lines which slope from lower left to upper right (i.e., ///). The other fault domain, Fault Domain B, includes: logic networks


221




1A


,


221




AB


(i.e., the S/Ps and crossbar switches


5004




3


-


5004




4


therein) and logic sections


5010




2


,


5010




4


,


5010




6


,


5010




8


, such devices being indicated by lines which slope from upper left to lower right (i.e., \\\\). It is noted from

FIGS. 9A

,


9


B and


9


C that port P


A


of each one of the memory array regions R


1


-R


4


is coupled to Fault Domain A while port P


B


is coupled to fault domain B. Thus, each one of the fault domains includes the devices used to couple one of a pair of redundant processors to one of a pair of redundant control ports P


A


, P


B


of the memory array regions R


1


-R


4


and the other fault domain includes the devices used to couple the other one of the pair of redundant processors to the other one of a pair of redundant control ports P


A


, P


B


of the memory array regions R


1


-R


4


. As noted above each fault domain operates with a clock (i.e., clock


1


, clock


2


) separate from and independent of the clock used to operate the other fault domain.




Referring now to

FIG. 10

, an exemplary one of the crossbar switches


5004




1


-


5004




4


, here crossbar switch


5004




1


is shown in detail to include four upper port interface sections A-D and lower port interface sections W-Z. The details of an exemplary one of the upper port interface sections A-D, here upper port interface section A, will be described in more detail in connection with

FIGS. 11A

,


11


B,


11


C and


11


D and the details of an exemplary one of the lower port interface sections W-Z, here lower port interface section W, will be described in more detail in connection with

FIGS. 12A

,


12


B,


12


C and


12


D. The function of the exemplary crossbar switch


5004




1


is to mediate the information cycle at the request of an initiating one of the directors coupled to one of the upper


5006




1


-


5006




4


and one logic section


5010




1


-


5010




8


indicated by the “tag” portion of the information (FIG.


16


).




More particularly, the crossbar switches request, negotiate, and then effect a transfer between the upper thereof


5006




1


-


5006




4


and the lower ports


5008




1


-


5008




4


thereof in a manner to be described below. Suffice it to say here, however, that the upper interface section A-D handle the protocol between the director requesting a information cycle and the memory board


220




1


(FIG.


8


). It also provides a control and data interface to the serial-to-parallel (S-P) converters (e.g., serializer-deserializer). These interface sections A-D are also responsible for generating parity across the address, control, DATA, and CRC received from the director. There are here two parity bits, one per cycle as described in co-pending patent application entitled “Fault Tolerant Parity Generation” filed May 20, 1999, Ser. No. 99/315,437, and assigned to the same assignee as the present invention, the entire subject matter being incorporated herein by reference. As described in such patent application, the parity is generated such that one byte has odd parity and the other byte has even parity. The sense of these parity bits alternate on successive clocks.




The lower port interface sections W-Z provides address, control, DATA and routing to one of the four of the logic sections


5010




1


-


5010




8


(

FIGS. 9A

,


9


B and


9


C) in a manner to be described. Each one of the lower interface sections W-Z is adapted to couple a corresponding one of the four memory array regions R


1


-R


4


(

FIGS. 9A

,


9


B and


9


C), respectively, via logic sections


5010




1


-


5010




8


. Each one of the four lower interface sections W-Z independently acts as an arbiter between the four upper interface sections A-D and the logic section


5010




1


-


5010




8


coupled thereto. This allows for simultaneous transfers (i.e., information cycles) to multiple memory array regions R


1


-R


4


from multiple upper interface sections A-D. The upper interface section A-D are single threaded, i.e., one information cycle must be complete before another information cycle is allowed to the same memory array regions R


1


-R


4


.




The lower interfaces W-Z deliver control, address and the “tag” field (to be described in more detail below) to the logic section


5010




1


-


5010




8


. The parity across these fields are generated in the upper interface sections A-D and then pass unmodified such that the memory array region can check for alternating parity sense. For write transfers, the lower interface sections W-Z also deliver the write data to the memory array region, checking for correct CRC across the data. If any error is detected, and if the control field indicates a “Wait-and-Validate” process to be described, the parity of the last double byte of data is corrupted (e.g., a fault is induced in the parity (p) thereof) such that the logic section


5010




1


-


5010




8


coupled thereto detects the corrupted parity and inhibits execution of the information cycle. Otherwise, the alternating parity of the data is unmodified. For read transfers, the lower interface sections W-Z accept the data from the memory array regions R


1


-R


4


via the logic sections


5010




1


-


5010




8


, check the alternating parity, and generates CRC to be returned to the director.




More particularly, assume for example that information at upper port


5006




4


(

FIGS. 9A

,


9


B and


9


C) of crossbar switch


5004




4


is to be transferred to memory array region R


1


. Referring to

FIG. 10

a negotiation, i.e., arbitration, must be made by lower port interface W as a result of a request made by the upper port interface section D of crossbar switch


5004




4


to section interface W thereof. When interface section W is available to satisfy such request, (i.e., not satisfying request from other one of the upper port interface sections A-C) interface W issues a grant to upper interface section D.




Thus, each one of the upper port sections A-D sends requests signals (REQs) to the lower port sections W-Z when such upper port sections A-D wants access to (i.e. wants to be coupled to) such lower port sections. Conversely, each one of the upper port sections A-D receives grant signals (GR) from the lower port sections W-Z when such lower port sections W-Z grants access to (i.e., wants to be coupled to) such upper port sections A-D. The request (REQ) and grant (GR) signals, produced by and received from tile upper port sections A-D and lower port sections W-Z are as follows:

























UP






R




R




G




G




G




G






PER PORT




EQ




EQ




EQ




EQ




R




R




R




R






SECTION






R




RZA




G




G




GYA




G






A




WA




XA




YA





WA




XA





ZA






UP






R




R




G




G




G




G






PER PORT




EQ




EQ




EQ




EQ




R




R




R




R






SECTION






R




RZB




G




G




GYB




G






B




WB




XB




YB





WB




XB





ZB






UP






R




R




G




G




G




G






PER PORT




EQ




EQ




EQ




EQ




R




R




R




R






SECTION






R




RZC




G




G




GYC




G






C




WC




XC




YC





WC




XC





ZC






UP






R




R




G




G




G




G






PER PORT




EQ




EQ




EQ




EQ




R




R




R




R






SECTION






R




RZD




G




G




GYD




G






D




WD




XD




YD





WD




XD





ZD






LO






R




R




G




G




G




G






WER




EQ




EQ




EQ




EQ




R




R




R




R






PORT






R




RWD




G




G




GWC




G






SECTION




WA




WB




WC





WA




WB





WD






W






LO






R




R




G




G




G




G






WER




EQ




EQ




EQ




EQ




R




R




R




R






PORT






R




RXD




G




G




GXC




G






SECTION




XA




XB




XC





XA




XB





XD






X






LO






R




R




G




G




G




G






WER




EQ




EQ




EQ




EQ




R




R




R




R






PORT






R




RYD




G




G




GYC




G






SECTION




YA




YB




YC





YA




YB





YD






Y






LO






R




R




G




G




G




G






WER




EQ




EQ




EQ




EQ




R




R




R




R






PORT






R




RZD




G




G




GZC




G






SECTION




ZA




ZB




XC





ZA




ZB





ZD






Z














where:




For upper port section A:




RWA is a request signal sent by upper port section A to lower port section W;




RXA is a request signal sent by upper port section A to lower port section X;




RYA is a request signal sent by upper port section A to lower port section Y:




RZA is a request signal sent by upper port section A to lower port section Z;




GWA is a grant signal from lower port section W to upper port section A;




GXA is a grant signal from lower port section X to upper port section A;




GYA is a grant signal from lower port section Y to upper port section A;




GZA is a grant signal from lower port section Z to upper port section A;




For upper port B:




RWB is a request signal sent by upper port section B to lower port section W;




RXB is a request signal sent by upper port section B to lower port section X;




RYB is a request signal sent by upper port section B to upper port section Y:




RZB is a request signal sent by upper port section B to lower port section Z;




GWB is a grant signal from lower port section W to upper port section B;




GXB is a grant signal from lower port section X to upper port section B;




GYB is a grant signal from lower port section Y to upper port section B;




GZB is a grant signal from lower port section Z to upper port section B;




and so forth for the remaining upper and lower port sections C-D and W-Z.




Each one of the upper port sections A-D has four ports A


1


-A


4


, through D


1


-D


4


, respectively, as shown. Each one of the lower port sections W-Z has four ports W


1


-W


4


, through Z


1


-Z


4


, respectively, as shown. Ports A


1


-A


4


are connected to ports W


1


-Z


1


, respectively, as shown. In like manner, Ports B


1


-B


4


are connected to ports W


2


-Z


2


, respectively, as shown, ports C


1


-C


4


are connected to ports W


3


-Z


3


, as shown, and Ports D


1


-D


4


are connected to ports W


4


-Z


4


, as shown. Lower ports


5008




1


-


5008




4


are connected to lower port sections W-Z, respectively, as shown.




As noted above, an exemplary one of the upper port interface sections A-D and an exemplary one of the lower port interface sections W-Z will be described in more detail in connection with

FIGS. 11A-11D

and


12


A-


12


D, respectively. Suffice it to say here, however, that information fed to port


5006




1


is coupled to ports


5008




1


-


5008




4


selectively in accordance with a “tag” portion such information. In a reciprocal manner, information fed to port


5008




1


is coupled to ports


5006




1


-


5006




4


selectively in accordance with the “tag” portion in such information. Further, ports


5006




2


-


5006




4


operate in like manner to port


5006




1


, so that information at such ports


5006




2


-


5006




4


may be coupled to ports


5008




1


-


5008




4


. Still further, ports


5008




2


-


5008




4


operate in like manner to port


5008




1


, so that information at such ports


5008




2


-


5008




4


may be coupled to ports


5006




1


-


5006




4


. It should also be noted that information may appear simultaneously at ports


5008




1


-


5008




4


with the information at one of such ports being coupled simultaneously to one of the ports


5006




1


-


5006




4


while information at another one of the ports


5008




1


-


5008




4


is coupled to a different one of the ports


5006




1


-


5006




4


. It is also noted that, in a reciprocal manner, information may appear simultaneously at ports


5006




1


-


5006




4


with the information at one of such ports being coupled simultaneously to one of the ports


5008




1


-


5008




4


and with information at another one of the ports


5006




1


-


5006




4


being coupled to a different one of the ports


5008




1


-


5008




4


.




Referring now to

FIGS. 11A

,


11


B,


11


C and


11


D, an exemplary one of the upper port interface sections A-D, here upper port interface section A is shown in more detail. It is first noted that the information at port


5006




1


includes: the “tag” portion referred to above; an address CRC ADDR_CRC portion, an address ADDR portion, a memory control portion (i.e., read/write, transfer length, “Wait and Validate”, etc.); a data portion, (DATA); and a DATA Cyclic Redundancy Check (CRC) portion (DATA_CRC).




The “tag” portion includes: a two bit word indicating the one of the four memory array regions R


1


-R


4


where the data is to be stored/read; a three bit word indicating the one of the eight memory boards having the desired array region R


1


-R


4


; a four bit word indicating the one of the 16 director boards


190




1


-


190




8


,


210




1


-


210




8


(

FIG. 8

) having the director which initiated the transfer; a two bit word indicating which one of.the four directors on such one of the director boards is making the requested data transfer; and a five bit random number designating, (i.e., uniquely identifying) the particular information cycle.




The information described above passing from the director to the crossbar switch (i.e., the “tag”, the ADDR_CRC, the ADDR, the memory control, the DATA, and the DATA_CRC) for the entire information cycle (

FIG. 17

) are successively stored in a register


5100


, in response to clock pulses Clock I, in the order described above in connection with FIG.


17


. Tile information stored in the register


5100


is passed to a parity generator (PG)


5102


for appending to such information a byte parity (p). After passing through the parity generator (PG)


5102


, the different portions of the information are stored in registers


5104




1


-


5104




6


, as follows: Register


5104




1


stores the DATA_CRC portion (with the generated parity); register


5104




2


, here a FIFO, stores the data portion, DATA, (with the generated parity); register


5104




3


stores the memory control portion (with the generated parity); register


5104




4


stores the address ADDR portion (with the generated parity), register


5104




5


stores the address ADDR_CRC portion (with the generated parity); and register


5104




6


stores the “tag” portion (with the generated parity) in the order shown in FIG.


17


. Each clock pulse (Clock


1


or Clock


2


) results in one of the words described above in connection with FIG.


17


. Here, each word has two bytes and is stored in register


5100


. The word stored in register


5100


is then shifted out of register


5100


with the next clock pulse, as new information becomes stored in such register


5100


.




The portions stored in the registers


5104




1


-


5104




4


and


5104




6


(not register


5104




5


which stores ADDR_CRC) are fed to selectors


5106




1


-


5106




4


, and


5106




6


, respectively, as indicated. An exemplary one of the selectors


5106




1


-


5106




4


, and


5106




6


, here selector


5106




6


is shown to include four registers


5108




1


-


5108




4


. The four registers


5108




1


-


5108




4


are connected to the same input port I of the selector


5106




6


to thereby store four copies of the information portion, here the “tag” portion, fed to such input port I in this example. The output of each of the four registers


5108




1


-


5108




4


is fed to a corresponding one of four gated buffers


5110




1


-


5110




4


, respectively, as indicated. With such an arrangement, one of the stored four copies is coupled to a selected one of the output ports A


1


-A


4


selectively (and hence to ports W


1


-Z


1


, respectively) in accordance with enable memory control signals on lines EAW-EAZ as a result of decoding the two-bit portion of “tag” indicating the selected one of the four memory, array regions R


1


-R


4


. More particularly, each one of the lines EAW-EAZ is coupled to a corresponding one of the enable inputs of the four gated buffers


5110




1


-


5110




4


, respectively, as indicated.




More particularly, as noted above, the “tag” includes 2 bits which indicates the one of the four memory array regions R


1


-R


4


which is to receive the information at port


5006




1


(i.e., the “tag”, the ADDR_CRC, the ADDR, the memory control, the DATA, and the DATA_CRC). The “tag” is fed to a memory control logic/ADDR_CRC checker


5112


. In response to this two bit portion of the “tag”, the memory control logic/ADDR CRC checker


5112


activates one of the four lines EAW-EAZ to thereby enable a selected one of the four copies stored in the four registers


5108




1


-


5108




4


to pass to one of the ports A


1


-A


4


. It is noted that the lines EAW-EAZ are also fed to selectors


5106




1


-


5106




5


in a similar manner with the result that the information at port


5006




1


(i.e., the “tag”, the ADDR_CRC, the ADDR, the memory control, the DATA, and the DATA_CRC) portions Data CRC, Data, memory control, ADDR, and ADDR_CRC is fed to the same selected one of the ports A


1


-A


4


and thus to the one of the four memory array regions R


1


-R


4


described by the two-bit portion of the “tag”.




It is noted that the upper port section A also includes a memory board checker


5114


. Each of the here eight memory board


220




1


-


220




8


(

FIG. 8

) plugs into the backplane


302


as discussed above in connection with FIG.


3


. As noted above, here the backplane


302


is adapted to a plurality of, here up to eight memory boards. Thus, here the backplane


302


has eight memory board slots. Pins P


1


-P


3


(

FIGS. 9A

,


9


B and


9


C) are provided for each backplane


320


memory board slot and produce logic voltage levels indicating the slot position in the backplane. Thus, here the slot position may be indicated with the logic signals on the three pins P


1


-P


3


to produce a three bit logic signal representative of the backplane slot position. Referring again to

FIGS. 9A

,


9


B and


9


C, the exemplary memory board


220




1


is shown plugged into a slot in the backplane


302


. As noted above, the slot has pins P


1


-P


3


which provides the slot position three bit logic signal indicative of the slot or “memory board” number in the backplane. The logic signals produced by the pins P


1


-P


3


are fed to the memory board checker


5114


(

FIGS. 11A

,


11


B,


11


C and


11


D). Also fed to the memory board checker


5114


are the 3-bits of the “tag” which indicates the one of the memory array boards which is to receive the data (i.e., a 3-bit “memory board code”). If the three bit memory board indication provided by “tag” is the same as the backplane slot or “memory board number” indication provided by the pins P


1


-P


3


, the director routed the information cycle to the proper one of the eight memory boards and such “accept” indication is provided to the decode logic/ADDR CRC checker


5112


via line A/R. On the other hand, if the three bit memory board indication provided by “tag” is different from the backplane slot indication provided by the pins P


1


-P


3


, the information cycle was not received by the correct one of the memory boards and such “reject” indication is provided to the decode logic/ADDR CRC checker


5112


via line A/R. When a reject indication is provided to the decode logic/ADDR CRC checker


5112


, the intended transfer in prevented and the indication is provided by the decode logic/ADDR CRC checker


5112


to the initiating director via the A/R line. Thus, if the “memory board number” provided by pins P


1


-P


3


does not match the “memory board code” contained in the “tag” the transfer request from the director is rejected and such error indication is sent back to the director. In this manner, a routing error in the director is detected immediately and is not propagated along.




On the other hand, if the “memory board number” and the “memory board code” do match, the crossbar switch will forward the requested transfer to one of the four memory regions (i.e., the “memory region number”, R


1


-R


4


) designated by the “tag”.




The decode logic and ADDR_CRC checker


5112


also produces load signals L


1


-L


6


to the registers


5104




1


-


5104




6


, respectively, in response to the “start-frame” signal in word 0 described above in connection with FIG.


16


.




Also fed to the decode logic/ADDR_CRC checker


5112


is the ADDR_CRC portion stored in registers


5104




3




5104




6


(i.e., control, ADDR, ADDR_CRC, and “tag”). The decode logic/ADDR_CRC


5112


performs a check of the CRC of the control, ADDR, ADDR_CRC, and “tag” and if such checker


5112


detects an error such error is reported back to the transfer initiating director via line ADDR_CRC_CHECK, as indicated. Detection of such an ADDR_CRC_CHECK error also results in termination of the transfer.




When data is read from a selected one of the memory array region R


1


-R


4


as indicated by the “tag” stored in register


5104




6


, the decode logic/ADDR_CRC checker


5112


activates the proper one of the lines EAW-WAZ to coupled the proper one of the ports A


1


-A


4


coupled to such selected one of the memory array regions R


1


-R


4


to a register


5120


. Thus, read data passes via selector


5118


to the register


5120


and is then sent to the transfer-requesting director via pot


5006




1


.




It is noted that the decode logic and ADDR CRC checker


5112


in upper port interface logic A also produces request signals RWA, RXA, RYA, and RZA and sends such request signal to lower port sections W-Z, respectively. Such requests are fed to an arbitration logic


5114


(

FIGS. 12A

,


12


B,


12


C and


12


D) included within each of the lower port sections W, X, Y and Z, respectively. Thus, because the other upper port sections B-D operate in like manner to upper port section A, the arbitration


5114


in lower port interface section W may receive requests RWB, RWC, and RWD from such other upper port sections B-D, respectively. In accordance with a predetermined arbitration rule, such as, for example, first-come, first-served, the arbitration logic


5114


of lower port interface section W grants for access to lower port


5008




1


of lower port section W to one of the requesting upper port sections A-D via a grant signal on one of the lines GWA, GWB, GWC and GWD, respectively.




Thus, referring again to

FIGS. 11A

,


11


B,


11


C and


11


D, the decode logic/CRC ADR checker


5112


issues a request on line RWA when port


5008




1


(

FIG. 10

) desires, based on the two bit information in the “tag”, memory array region R


1


(

FIGS. 9A

,


9


B and


9


C). In like manner, if memory array regions R


2


-R


4


are indicted by the “tag”, requests are made by the upper port section on lines RXA, RYA, RZA, respectively. The other upper port sections B-D operate in like manner. The grants (GR) produced by the lower port sections W, X, Y and Z are fed to the upper port sections A-D as indicated above. Thus, considering exemplary upper port section A (

FIGS. 11A

,


11


B,


11


C and


11


D), the grant signals from lower port sections W-Z are fed to the decode logic/CRC checker


5112


therein on lines GWA, GXA, GYA and GZA, respectively. When a grant on one of these four lines GWA, GXA, GYA and GZA is received by the decode logic/CRC checker


5112


, such checker


5112


enables the gating signal to be produced on the one of the enable lines EAW, EAX, EAY, EAZ indicated by the “tag” portion. For example, if the “tag” indicates that memory array region R


3


(which is adapted for coupling to port


5008




3


of lower port section Y) the checker


5112


issues a request on line RYA. When after the arbitration logic


5114


in section Y determines that lower port logic A is to be granted access to port


5008




3


, such lower port section Y issues a grant signal on line GYA. In response to such grant, the checker


5112


issues an enable signal on line EAY to thereby enable information to pass to port A


3


(

FIGS. 11A

,


11


B,


11


C and


11


D).




In a reciprocal manner, when data is to be transferred from a memory array region to the requesting director, the information sent by the requesting director is processed as described above. Now, however, the checker


5112


sends a control signal to one of the lines EAW-EAZ to selector section


5118


to enable data on one of the ports A


1


-A


4


coupled to the addressed memory array regions R


1


-R


4


to pass to register


5120


and then to upper port


5006




1


.




Referring now to

FIGS. 12A

,


12


B,


12


C and


12


D, exemplary lower port section W is shown to include arbitration logic


5114


described above, and the selector


5120


fed by signals on ports W


1


-W


4


. (Referring again to

FIG. 10

, ports W


1


-W


4


are coupled to ports A


1


, B


1


, C


1


and D


1


, respectively, of upper port interface sections A-D, respectively.) Thus, when the arbitration logic


5114


grants access to one of the upper port sections A-D, the decoder


5122


decodes the grant information produced by the arbitration logic and produces a two bit control signal for the selector


5120


. In response to the two bit control signal produced by the decoder


5122


, the selector couples one of the ports W


1


-W


4


(and hence one of the upper port sections A-D, respectively), to the output of the selector


5120


and hence to lower port


5008




1


in a manner to be described.




As noted above, the communication between any port M


B1


-M


B8


, M


A1


-M


A8


and its corresponding crossbar switches


5004




1


-


5004




4


is protected by Cyclic Redundancy Check (CRC) defined by CCITT-V.41. The communication between a crossbar switch


5004




1


-


5004




4


and its corresponding memory array region R


1


-R


4


is protected by byte parity (p). There is a pipelined architecture from the port M


B1


-M


B8


, M


A1


-M


A8


, and through the crossbar switch, and through the logic sections


5010




1


-


5010




8


.




The nature of CRC calculation is such that an error in the data is not detected until the entire transfer is completed and the checksum of the CRC is known. In the case of a write of data into the memory, by the time the CRC is checked, most of the data is already through the pipeline and written into memory.




Here, the memory control field has a specific bit “Wait and Validate” in the control word


1


in

FIG. 16

which is at the director's control. If the bit is set, the logic sections


5010




1


-


5010




8


buffers the entire information cycle, pending the CRC calculation, performed at the lower port interface sections W-Z. If the CRC check indicates no CRC error, then the data is written into the memory array region. If the CRC check does indicate an error, then the memory array region is informed of the error, here by the lower interface section W-Z corrupting the data into a fault. Such fault is detected in the logic section


5010




1


-


5010




8


and such information is prevented from being stored in the memory region R


1


-R


4


, in a manner to be described. Suffice it to say here, however, that this “Wait and Validate” technique enables the director to flag certain data transfers as critical, and if an error occurs, prevents corruption of the data stored in the memory array. That is, the data having a CRC error is detected and prevented from being stored in the memory array region. For those transfers not indicated as critical by the director, the “Wait and Validate” bit is not set thereby maximum performance of the memory is obtained.




More particularly, the DATA, memory control, ADDR, and “tag” portions (with their byte parity (p) generated by parity generator


5102


(

FIGS. 11A

,


11


B,


11


C and


11


D)) of the information coupled to the output of selector


5120


is stored in the register


5124


. As noted above in connection with

FIG. 16

, the DATA_CRC portion (i.e., the words X and Y) occurs after the last DATA word.




Thus, as the words in the DATA clock through register


5124


they pass into the DATA_CRC checker


5132


where the CRC of the DATA is determined (i.e., the DATA_CRC checker


5132


determine X and Y words of the DATA fed to such checker


5132


). The actual X and Y words (i.e., DATA_CRC stored in register


5128


, both content (n) and parity (p)) are stored successively in register


5128


and are then passed to checker


5132


where they are checked against the X and Y words determined by the checker


5132


. As noted above, the DATA has appended to it its parity (p). Thus, the “information” whether in register


5124


or register


5128


has a content portion indicated by “n” and its parity indicated by “p”. Thus, the DATA_CRC register


5128


includes the DATA_CRC previously stored in register


5104




1


(

FIGS. 11A

,


11


B,


11


C and


11


D) (i.e., the content portion designated by “n”) and its parity (designated by “p”). The DATA, memory control, ADDR, and “tag” portions, (with their parity (p) (i.e., content “n” plus its appended parity “p”) stored in register


5124


may be coupled through a selector


5149


through one of two paths: One path is a direct path when the “Wait and Validate” command is not issued by the director; and, a second path which includes a delay network


5130


, here a three clock pulse delay network


5130


.




More particularly, it is noted that the DATA, control, ADDR, “tag”, both content (n) and parity (p) are also fed to a DATA_CRC checker


5132


. Also fed to the DATA_CRC checker


5132


is the output of DATA_CRC register


5128


. The CRC checker


5132


checks whether the DATA_CRC (content “n” plus its parity “p”) is the same as the CRC of the DATA, such DATA having been previously stored in register


5104




2


(

FIGS. 11A

,


11


B,


11


C and


11


D), i.e., the content “n” plus its parity “p” of the DATA previously stored in register


5104




2


(

FIGS. 11A

,


11


B,


11


C and


11


D). If they are the same, (i.e., no DATA_CRC_ERROR), a logic 0 is produced by the CRC checker


5132


. If, on the other hand, they are not the same, (i.e., a DATA_CRC_ERROR), the CRC checker


5132


produces a logic 1. The output of the Data_CRC checker


5132


thereby indicates whether there is an error in the CRC of the DATA. Note that a DATA_CRC_ERROR is not known until three clock cycles after the last sixteen-bit portion of the DATA (i.e., the word of the DATA,

FIG. 16

) is calculated due to the nature of the CRC algorithm. Such indication is fed to a selector


5152


via an OR gate


5141


. If there is a DATA_CRC_ERROR, the “information” at the output of the delay network


5130


(i.e., the last word of the DATA (FIG.


16


)) with its parity (p)) is corrupted. Here, the content (n) of such “information” (i.e., the “information” at the output of the delay network


5130


(i.e., the last word of the DATA (FIG.


16


))) is fed to a second input I


2


of the selector


5140


. The parity (p) of such “information” (i.e., the last word of the DATA (FIG.


16


)) is fed non-inverted to one input of selector


5152


and inverted, via inverter


5150


, to a second input of the selector


5152


. If there is a DATA_CRC_ERROR detected by data CRC checker


5132


, the inverted parity is passed through the selector


5152


and appended to the content portion (n) of the “information” (i.e., the last word of the DATA (FIG.


16


)) provided at the output of the delay network


5130


and both “n” and appended “p” are fed to the second input I


2


of selector


5140


thereby corrupting such “information”. It should be noted that the remaining portions of the information cycle (i.e., the memory control, address (ADDR), “tag”, and all but the last word of the DATA (FIG.


16


)) pass through the delay network


5130


without having their parity (p) corrupted.




If there is a no “Wait and Validate” transfer, logic decoder


5122


selects the first input I


1


as the output of the selector


5140


. If there is a “Wait and Validate” transfer, the logic decoder


5122


selects the second input I


2


as the output of the selector


5140


. It is noted, however, that that because the last word of DATA (

FIG. 16

) is delayed three clock pulses (from Clock


1


) by registers


5142


,


5144


, and


5146


(such registers


5142


,


5144


and


5146


being fed by such Clock


1


), the DATA_CRC check is performed before the last word of the DATA appears at the output of register


5146


. Thus, the last word of the DATA is corrupted in byte parity before being passed to the logic section


5010




1


-


5010




8


. That is, because of the delay network


5130


, the DATA_CRC is evaluated before the last word of the DATA has passed to port


5008




1


. This corruption in parity (p), as a result of a detected DATA_CRC error, is detected by a parity checker


6106


(

FIGS. 14A

,


14


B,


14


C and


14


D) in the following logic section


5010




1


-


5010




8


in a manner to be described. Suffice it to say here, however, that detection of the parity error (produced by the detected CRC error) prevents such corrupted information from storage in the SDRAMs.




On the other hand, if there is no DATA_CRC_ERROR (and no error in the parity of the DATA_CRC detected by the parity checker


6106


(

FIGS. 14A

,


14


B,


14


C and


14


D) in a manner to be described) the non-inverted parity (p) is appended to the “information” (i.e., DATA, memory control, ADDR, and “tag”) provided at the output of the delay network


5130


and such information is fed to the proper memory address region R


1


-R


4


as indicated by “tag”.




More particularly, it is noted that the selector


5140


is also fed the “information” (i.e., DATA, memory control, ADDR, and “tag”) without such “information” passing through the delay


5130


. The director issuing the transfer may not require that the transfer have the DATA_CRC check result preclude the writing to information into the memory (i.e., no “Wait and Validate”), in which case the “information” is passed directly through the selector


5140


. On the other hand, if such DATA_CRC check is to be effected, the delay network


5130


output, with a possible corruption as described above, is passed through the selector


5140


. The director provides the indication as part of the control field in the described “Wait and Validate” bit. Such bit is decoded by the logic decoder


5122


. In response to such director indication, a “Wait and Validate” control signal is sent by the logic decoder


5122


to the selector


5140


.




As noted above, the communication between any port and its corresponding crossbar switch is protected by Cyclic Redundancy Check (CRC) defined by CCITT-V.41. The communication between a crossbar switch and a memory array region R


1


-R


4


is protected by byte parity (p). This implies that the crossbar switch must translate between CRC protection and parity protection.




As a further check of the validity of the DATA CRC, the generated parity p of the CRC of Such DATA is checked. However, because the CRC is generated by the director, and the CRC parity is also generated by upper interface section A-D, a CRC generation fault would yield an undetectable CRC parity fault.




It has been discovered that the parity (p) of the DATA_CRC must be the same as the parity of the DATA parity (p). Thus, one merely has to check whether the parity of the DATA_CRC is the same as the parity of the DATA parity (p). Therefore, such detection DATA_CRC parity checking method is accomplished without using the DATA_CRC itself.




More particularly, since the DATA over which the DATA_CRC is being calculated is already parity protected, one can use the DATA parity (p) to calculate the DATA_CRC parity: i.e., the DATA_CRC parity is equal to the parity of all the DATA parity bits. Still more particularly, if there are N bytes of DATA:




[D(


0


), D(


1


), . . . D(N−1)]




and each byte is protected by a parity bit p, then the DATA_CRC parity is the parity of




[p(


0


), p(


1


), . . . p(N−1)].




Thus, if there is a fault in the generation of the DATA_CRC, it is immediately detected and isolated from the director.




Thus, the exemplary lower port interface section W (

FIGS. 12A

,


12


B,


12


C and


12


D) includes a parity generator made up of an exclusive OR gate


5134


and register


5136


arranged as shown fed by the parity (p) of the DATA portion stored in register


5124


. The generated parity p is fed to a comparator


5138


along with the parity (p) of the DATA_CRC (i.e., DATA_CRC_PARITY), as indicated. If the two are the same at the end of the DATA portion of the information cycle (FIG.


16


), a logic 0 is produced by the comparator


5138


and such logic 0 passes to the selector


5152


to enable the non-inverted parity to pass through such selector


5152


. If there is an error in the parity bit of the CRC, a logic 1 is produced by the comparator


5138


and the inverted parity is passed through the selector


5152


. The logic 1 output of comparator


5138


passes through OR gate


5141


to couple the inverted parity (p) through selector


5152


to append to the content port (n) of DATA control, ADDR, and “tag” at port I


2


of selector


5140


. Thus, if there is either a DATA_CRC_ERROR or if DATA_CRC_PARITY is different from parity of the DATA_PARITY at the end of the DATA portion of the information cycle as indicated by a signal produced on line COMP_ENABLE by the logic decoder


5122


, a logic 1 is produced at the output of OR gate


5141


thereby coupling the inverted parity through selector


5152


. Otherwise, the non-inverted parity passes through selector


5152


. That is, the COMP_EN is produced at the end of the DATA in the information cycle (FIG.


16


).




It is noted that information read from the memory region passes to a register


5170


and a CRC generator


5172


. The generated CRC is appended to the information clocked out of the register


5170


. Four copies of the information with appended CRC are stored in registers


5174




1


-


5174




4


, respectively. In response to the “tag” portion fed to logic decoder


5122


, a selected one of the registers


5174




1


-


5174




4


is coupled to one of the port W


1


-W


4


by selector


5180


and gates


5182




1


-


5182




4


in a manner similar to that described in connection with

FIGS. 11A

,


11


B,


11


C and


11


D.




Referring now to

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E, a pair of the logic sections


5010




1


-


5010




8


(memory array region controllers), here logic sections


5010




1


and


5010




2


are shown. As noted above in connection with

FIGS. 9A

,


9


B and


9


C, both logic sections


5010




1


and


5010




2


are coupled to the same memory array region, here memory array region R


1


. As was also noted above in connection with

FIGS. 9A

,


9


B and


9


C, the logic section


5010




1


is in one fault domain, here fault domain A, and logic section


5010




2


is in a different fault domain, here fault domain B. Thus, logic section


5010




1


operates in response to clock pulses from Clock


1


and logic section


5010




2


operates in response to clock pulses from Clock


2


.




As noted above, each logic section


5010




1


-


5010




8


(

FIGS. 9A

,


9


B and


9


C) includes a pair of upper ports, A and B, a control port C and a data port D. Referring to

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E, an exemplary logic section


5010




1


is shown in detail to include a upper port A controller


6002


A coupled to upper port A, a upper port B controller


6002


B coupled to upper port B, and a memory refresh section


6002


R.




Both port A and port B controllers


5010




1


,


5010




2


have access to the data stored in the same memory array region R


1


. Further, while each can provide different, independent control and address information, (i.e., memory control, ADDR, and “tag” (hereinafter sometimes referred to as ADDR/CONTROL)), both share the same DATA port. As noted above, the details of the memory array region I are described in detail in connection with FIG. 6 of U.S. Pat. No. 5,943,287. Thus, arbitration is required for access to the common memory array region R


1


when both the port A and port B controllers


5010




1


and


5010




2


desire access to the memory array region R


1


. Further, the SDRAMs in the memory array region R


1


require periodic refresh signals from the memory refresh section


6002


R. Thus, access or request for, the memory array region R


1


may come from: the upper port A controller


6002


A (i.e., REQUEST A); the upper port B controller


6002


B (i.e., REQUEST B); and from the memory refresh section


6002


R (i.e., REFRESH REQUEST). These request arc fed to an arbitration logic


6004


included within the logic section


5010




1


-


5010




8


. The arbitration sections


6004




1


,


6004




2


in the redundant paired logic sections, here logic sections


5010




1


,


5010




2


, respectively, arbitrate in accordance with an arbitration algorithm to be described and thereby to issue a grant for access to the memory array region R


1


to either: the upper port A controller


6002


A (i.e., GRANT A); the upper port B controller


6002


B (i.e., GRANT B); or the memory refresh section


6002


R (i.e., REFRESH GRANT).




Here, the arbitration algorithm is an asymmetric round robin sharing of the common memory array region R


1


. The arbitration logic


6004




1


,


6004




2


and the algorithm executed therein will be described in more detail in connection with

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E. Suffice it to say here however that the arbitration grants access to the common memory array region based on the following conditions:




Condition I—If both the logic sections


5010




1


and


5010




2


are operating properly (i.e., produce Memory Output Enable (MOE) and Memory Refresh Enable (MRE) signals, to be described, properly), the port A controller


6002


A memory refresh controller


6002


R is used exclusively for memory refresh during the round-robin arbitration). Thus, there is asymmetric round robin arbitration because the memory refresh section


6002


R of logic section


5010




2


is not used when operating in this normal Condition I. The states of the arbitration sequences are as follows:




State 1—The upper port A controller


6002


A of logic section


5010




1


is granted access to the memory array region R


1


;




State 2—The memory refresh section


6002


R of logic section


5010




1


is granted access to the memory array region R


1


;




State 3—The upper port B controller


6002


B of logic section


5010




1


is granted access to the memory array region R


1


;




State 4—The memory refresh section


6002


R of logic section


5010




1


is granted access to the memory array region R


1


;




State 4—A check is made as to whether the of logic section


5010




2


requests access to the memory array region R


1


. If such a request exist:




(a) The upper port A controller


6002


A of logic section


5010




2


is granted access to the memory array region R


1


if such access is requested;




(b) The upper port B controller


6002


B of logic section


5010




2


is granted access to the memory array region R


1


if such access is requested;




State 5—The process returns to State 1.




(It should be noted that the process uses the memory refresh section


6002


R of logic section


5010




1


but does not use the memory refresh section


6002


R of logic section


5010




2


. Thus the round robin is asymmetric.)




Condition II—If the logic section


5010




2


is disabled (i.e., does not produce MOE and MRE signals properly), the logic section


5010




2


is not part of the round-robin arbitration and memory refresh is provided, as in Condition I, exclusively by the logic section


5010




1


memory refresh controller


6002


R. The logic section


5010




1


no longer receives request signals FROM the logic section


5010




2


. Also the logic section


5010




1


is granted access to the memory array region R


1


all the time. Thus, the states of the arbitration sequence are in Condition II as follows:




State 1—The upper port A controller


6002


A of logic section


5010




1


is granted access to the memory array region R


1


;




State 2—The memory refresh section


6002


R of logic section


5010




1


is granted access to the memory array region R


1


;




State 3—The upper port B controller


6002


B of logic section


5010




1


is granted access to the memory array region R


1


;




State 4—The memory refresh section


6002


R of logic section


5010




1


is granted access to the memory array region R


1


;




State 5—The process returns to State 1.




Condition III—The logic section


5010




1


is disabled (i.e., does not produce MOE and MRE signals properly) and thus the logic section


5010




1


is not part of the round-robin arbitration. Memory refresh is provided exclusively by the memory refresh section


6002


R (not shown) in the logic section


5010




2


. The logic section


5010




2


is granted access to the memory array region R


1


all the time. Thus the states of the arbitration sequence in Condition III are as follows:




State 1—The upper port A controller


6002


A of logic section


5010




2


is granted access to the memory array region R


1


;




State 2—The memory refresh section


6002


R of logic section


5010




2


is granted access to the memory array region R


1


;




State 3—The upper port B controller


6002


B of logic section


5010




2


is granted access to the memory array region R


1


;




State 4—The memory refresh section


6002


R of logic section


5010




2


is granted access to the memory array region R


1


;




State 5—The process returns to State 1.




Condition IV-Reset (the arbitration is reset into Condition I from either Condition II or from condition III).




Referring again to

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E, the arbitration logic


6004




1


,


6004




2


in each one of the logic sections


5010




1


,


5010




2


produces: a memory output enable (MOE) signal; a memory refresh enable (MRE) signal (to be described in more detail in connection with

FIGS. 15A-15E

and


19


); and, a memory grant (MG) signal, (to be described in more detail in connection with

FIGS. 15A-15E

and


19


). Thus, logic section


5010




1


produces a memory output enable signal MOEA (to be described in more detail in connection with

FIGS. 15A-15E

and


19


), a memory refresh enable signal MREA (to be described in more detail in connection with

FIGS. 15A-15E

and


19


) and a memory grant signal MGA (to be described in more detail in connection with

FIGS. 15A-15E

and


19


). Likewise, logic section


5010




2


produces a memory output enable signal MOEB (to be described in more detail in connection with

FIGS. 15A-15E

and


19


), a memory refresh enable signal MREB (to be described in more detail in connection with

FIGS. 15A-15E

and


19


) and a memory grant signal MGB (to be described in more detail in connection with

FIGS. 15A-15E

and


19


). Suffice it to say here, however, that the MOEA signal is a triplicate signal MOE


1-1


, MOE


1-2


, MOE


1-3


and the MGA signal is also a triplicate signal MGE


IA


, MGE


ILA


, and MGE


Il1A


.




The MOEA and MREA signals from the logic section


5010




1


and the MOEB and MREB signals from the logic section


5010




2


are fed to a watch dog (WD) section


6006


, to be described in more detail in connection with

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E. Suffice it to say here, however, that, as noted above, the arbitration algorithm is a function of the operating/non-operating condition of the logic sections


5010




1


,


5010




2


. This operating/non-operating condition is determined by the watchdog section


6006


and more particularly by examining the MOEA, MREA, MOEB, MREB signals produced by the logic sections


5010




1


and


5010




2


,


6002


B, respectively. The MOEA, MREA, MOEB, MREB signals are asserted when there is a grant. Such signals MOEA, MREA, MOEB, MREB are fed to the watchdog section


6006


. As will be described, the watchdog section


6006


examines the time history of these signals to determine if the logic section


5010




1


or


5010




2


asserting them is operating properly. Based on the results of such examination, the watchdog selects the Condition I, Condition II, or Condition III, described above.




More particularly, consider, for example, a case where the MOEA signal is asserted for too long a predetermined time interval. It should be recalled that the logic section


5010




1


producing such MOEA signal is granted access to the memory in State


1


of the normal arbitration condition (i.e., Condition I, above). The watchdog section


6006


thus detects a fault in logic section


5010




1


. When such a fault is detected, the watchdog section


6006


issues a Condition III signal on in triplicate on lines MSAB to the arbitration sections


6004




1


,


6004




2


in both the logic sections


5010




1


,


5010




2


, respectively, indicating that the arbitration algorithm will operate in accordance with the States set forth above for Condition III. Further, the watchdog


6006


issues a data output enable signal in triplicate on lines DOEA (i.e., DOEA


0


, DOEA


1


, and DOEA


2


). This triplicate signal DOEA (i.e., DOEA


0


, DOEA


1


, and DOEA


2


) is fed to a majority gate (MG)


6007


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E), in accordance with the majority of the triplicate data fed to it, provides an enable/disable signal for gate


6009


. If the majority indicates a fault, the gate


6009


inhibits DATA from passing between the logic section


5010




1


and the data port D thereof.




Consider the case where the arbitration is in Condition I. Consider also that in such condition I, the MREA signal is not produced after a predetermined time interval which ensures proper refreshing on the SDRAMs in the memory array region R


1


. The watchdog section


6006


will again detect a fault in the logic section


5010




1


port A controller


6002


A. When such a fault is detected, the watchdog section


6006


issues a Condition III signal on in triplicate on lines MSAB (i.e., MSAB


0


, MSAB


1


, MSAB


2


) to the arbitration sections


6004




1


,


6004




2


in both the logic sections


5010




1


,


5010




2


, respectively. Further, the watchdog


6006


issues a data output enable signal in triplicate on lines DOEA (i.e., DOEA


0


, DOEA


1


, and DOEA


2


) (

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) to inhibit DATA from passing between the logic section


5010




1


and the data port D thereof.




Consider, for example, a case where the arbitration is in Condition I and the MOEB signal from the logic section


5010




2


is asserted for too long a predetermined time interval. The watchdog section


6006


thus detects a fault in the logic section


5010




2


. When such a fault is detected, the watchdog section


6006


issues a Condition II signal on line MSAB to the arbitration sections


6004




1


,


6004




2


in both the logic sections


5010




1


,


5010




2


. Further, the watchdog


6006


issues a data output enable signal in triplicate on lines DOEB to inhibit DATA from passing between the logic section


5010




2


and the data port D thereof.




It should be noted that the algorithm allows a transition between Condition II and Condition IV (i.e., reset) or from Condition III and Condition IV.




Thus, the arbitration logics


6004




1


and


6004




2


are adapted to issue the following signals:




GRANT A (GA)-grant port A controller


6002


B access to the memory array region R


1


;




GRANT B (GB)-grant port B controller


6002


B access to the memory array region R


1






REFRESH GRANT (GR)-grant the memory refresh section


6002


R of logic section


5010




1


access to the memory array region R


1


in Condition I and II or grant the memory refresh section


6002


R of logic section


5010




2


access to the memory array region R


1


in Condition III.




It should be noted that the details of GA and the other signal GB and GR are shown in more detail in connection with FIG.


19


.




Thus, referring to

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E, the memory array region R


1


may be coupled to either Port_A (A) or Port_B (B) of the logic sections


5010




1


,


5010




2


or to the memory refresh section


6002


R therein selectively in accordance with a Port_A_SELECT, Port_B_SELECT, Port_R_SELECT signal fed to a pair of selectors


6010




C


,


6010




D


, shown in more detail for exemplary logic section


5010




1


. Access by the upper port A controller


6002


A (i.e., Port_A), by the upper port B controller


6002


B, or the memory refresh section


6002


R to the memory array region R


1


is in accordance with the algorithm described above.




An exemplary one of the upper port A and port B logic controllers


6002


A and


6002


B, here controller


6002


A, will be described in more detail in connection with

FIGS. 14A

,


14


B,


14


C and


14


D. Suffice it to say here, however, that it is noted that the output of selector


6010




C


is coupled to the control port C of the exemplary logic section


5101




1


and the output of selector


6010




D


is coupled to the data port D of the exemplary logic section


5101




1


through the gate


6009


. Each one of the selectors


6010




C


and


6010




D


has three inputs A, B, and R, as shown. The A, B and R inputs of selector


6010




C


are coupled to: the ADR/CONTROL produced at the output of upper port A controller


6002


A; the ADR/CONTROL produced at the output of upper port B controller


6002


B; and, the portion REFRESH_C of the refresh signal produced by the memory refresh section


6002


R, respectively as indicated. The A, B and R inputs of selector


6010


D are coupled to: the WRITE DATA produced at the output of upper port A controller


6002


A; the WRITE DATA produced at the output of upper port B controller


6002


B; and, the portion REFRESH_D of the refresh signal produced by the memory refresh section


6002


R, respectively as indicated. The Port_A_SELECT, Port_B_SELECT are produced by the upper port A controller


6002


A, upper port B controller


6002


B in a manner to be described. The Port_R_SELECT signal is produced by the memory refresh section


6002


R in a manner to be described to enable proper operation of the above described arbitration algorithm and to proper a refresh signal to the SDRAMs in the memory array region R


1


at the proper time. Suffice it to say here, however, that when port A controller


6002


A produces the Port_A_SELECT signal, the ADR/CONTROL at the output of port A controller


6002


A passes to the output of the selector


6010


C and the DATA_WRITE at the output of the port A controller


6002


A passes to the output of the selector


6010


D. Likewise, when port B controller


6002


B produces the Port_B_SELECT signal, the ADR/CONTROL at the output of port B controller


6002


B passes to the output of the selector


6010


C and the DATA_WRITE at the output of the port B controller


6002


B passes to the output of the selector


6010


D. In like manner, when refresh memory section


6002


R produces the Port_R_SELECT_C signal, the REFRESH_C at the output of refresh memory section


8002


R passes to the output of the selector


6010


C and in response to the Port_R_SELECT signal, the REFRESH_D at the output of the refresh memory section


8002


R passes to the output of the selector


6010


D.




It is noted that data read from the memory array R


1


(i.e., READ_DATA) is fed from the data port D to both the upper Port A controller


6002


A and the upper Port B controller


6002


B.




Referring now to

FIGS. 14A

,


14


B,


14


C and


14


D, the exemplary port A controller


6002


A is shown in more detail to include a Port A primary control section


6100


P and a Port A secondary control section


6100


S. The two sections


6100


P and


6100


S are both coupled to port A and both implement the identical control logic. Thus, each one of the two sections


6100


P and


6100


S should produce the same results unless there is an error, here a hardware fault, in one of the two sections


6100


P and


6100


S. Such a fault is detected by a fault detector


6102


in a manner to be described.




Thus, referring to the details of one of the two sections


6100


P and


6100


S, here section


6100


P, it is first noted that the information at Port_A is fed to a parity checker


6101


. It is noted that is there is an error in parity induced by the CRC check described in

FIGS. 12A

,


12


B,


12


C and


12


D in connection with selector


5152


, such detected parity error is reported to a control and DATA path logic


6112


. In response to a detected parity error, control and DATA path logic


6112


prevents memory control signals (e.g., suppress the Column Address Select signal to the SDRAMs) from being produced on the CONTROL_P line. Thus, absent control signal, DATA will not be stored in the memory region.




The information at Port_A is also fed to a control register


6104


for storing the memory control portion of the information at port A, an ADDR register


6106


for storing the address portion (ADDR) of the information at port A, a write data register


6108


(here a FIFO) for storing the DATA portion of the information at port A, such being the data which is to be written into the memory array region R


1


. The control portion stored in register


6104


is fed also to the control and data path logic


6112


. Such logic


6112


produces: a memory array region request Request_Port_A_Primary (RAP) signal when the control portion in register


6104


indicates that there is data to be stored in the memory array region R


1


; a Port A Primary Select (Port_A_P_SELECT) signal when the grant has been issued thereto via a Grant_A_P signal (GAP) produced by the arbitration logic


6004




1


; and passes the control portion (CONTROL_P) stored in register


6104


to the output of the upper port A controller


6002


A, as indicated. It should be noted that the port A secondary control section


6100


S being fed the same information as the primary controller


6100


P should produce the Same signals: here indicated as a memory array region request Request_Port A_SECONDARY (RAS) signal when the control portion in register


6104


indicates that there is data to be stored in the memory array region R


1


; a Port A Secondary Select (Port_A_S_SELECT) signal when the grant has been issued thereto via a Grant_A_S signal (GAS) produced by the arbitration logic


6004




1


.




The address portion stored in the ADDR register


6106


(ADDR_P) is combined with the address portion ADDR_P stored in register


6106


. Both CONTOL_P and ADDR_P are fed to a parity generator


6109


to produce ADDR/CONTROL_P (which has both a content portion (n) and parity (p). The content portion (n) of ADDR/CONTROL_P is led to a parity generator


6120


to generate byte parity (p′) from the content portion (n) of ADDR/CONTROL_P. The generated parity (p′) is inverted by inverter


6122


and the inverted parity is fed to a first input I


1


of the selector


6124


. The content portion (n) of ADDR/CONRTOL_P is combined with a parity (p) produced at the output of selector


6124


in a manner to be described. The parity (p) of ADDR/CONTROL_P is fed to a second input I


2


of the selector


6124


and such parity (p) is also fed to an exclusive OR gate


6130


. Also fed to the exclusive OR gate


6130


is the parity (p) of the equivalent ADDR/CONTROL_S signal produced by the Port A secondary control section


6100


S. As noted above, since both sections


600


P and


600


S are fed the same information and implement the same logic functions, ADDR/CONTROL_P should be the same as ADDR/CONTROL_S unless there is a hardware fault in one of the sections


6100


P,


6100


S. If there is a fault (i.e., if ADDR/CONTROL_S and ADDR/CONTROL_P are different), the exclusive OR gate


6130


will produce a logic 1 and in the absence of a fault, (i.e., ADDR/CONTROL_S is the same as ADDR/CONTROL_P), the exclusive OR gate


6130


will produce a logic 0.




In like manner, the content (n) of ADDR/CONTROL_P is fed to an exclusive OR gate


6128


. Also fed to the exclusive OR gate


6128


is the content (n) of the equivalent ADDR/CONTROL_S signal produced by the Port A secondary control section


6100


S. As noted above, since both sections


600


P and


600


S are fed the same information and implement the same logic functions, ADDR/CONTROL_P should be the same as ADDR/CONTROL_S unless there is a hardware fault in one of the sections


6100


P,


6100


S. If there is a fault (i.e., if ADDR/CONTROL_S and ADDR/CONTROL_P are different), the exclusive OR gate


6128


will produce a logic 1 and in the absence of a fault, (i.e., ADDR/CONTROL_S is the same as ADDR/CONTROL_P), the exclusive OR gate


6128


will produce a logic 0.




The outputs of exclusive OR gates


6128


and


6130


are fed to an OR gate


6126


. Thus, if there is an error in either the content (n) or the parity (p), the OR gate produces a logic 1; otherwise it produces a logic 0. The output of OR gate


6126


is fed to a fault detector


6102


which detects such a fault and reports such detected fault to the director. The Output of OR gate


6126


is also fed as a control signal to selector


6124


. If the OR gate produces a logic 1 (i.e., there is a fault), the selector couples the inverted parity of input I


1


to the output of selector


6124


. This inverted parity is appended to the content (n) of ADDR/CONTROL_P to thereby corrupt such information. This corrupted information is detected by the memory array region and converted into a “no-operation” command as described in the above-referenced U.S. Pat. No. 5,943,287. On the other hand, if the OR gate


6126


produces a logic 0 (i.e., no fault), the non-inverted parity at input I


2


of selector


6124


passes through selector


6124


and is appended to the content portion (n) of ADDR/CONTROL/P.




A similar check is made with the DATA to be written into the memory array region. Thus, the DATA in register


6108


of primary controller


6100


P (WRITE_DATA_P) is fed to an exclusive OR gate


6116


along with the write DATA in the secondary controller


6100


S (WRITE_DATA_S). (It is noted the data in the write register


6108


of the primary controller


6100


P (DATA_WRITE_P) is fed to output DATA_WRITE bus while the write data in the secondary controller


6100


S (DATA_WRITE_S) is fed only to the exclusive OR gate


6118


.) Thus, the exclusive OR gate


6116


produces a logic 0 if WRITE_DATA_P and WRITE_DATA_S are the same and produces a logic 1 if they are different. The fault detector


6102


detects such logic 1 and reports the detected fault to the transfer requesting director.




In like manner, a check is made of the DATA read (READ_DATA) from the memory array region R


1


which becomes stored in Read data register


6119


, here a FIFO. The READ_DATA is fed to a read data register (here a FIFO) for transmission to the director via Port_A. Such READ_DATA in register


6119


indicated as READ_DATA_P is fed to an exclusive OR gate


6118


. In like manner, secondary controller


6100


S should produce the same signals on output READ_DATA_S. READ_DATA_P and READ_DATA_S are fed to an exclusive OR gate


6118


. Thus, the exclusive OR gate


6118


produces a logic 0 if READ_DATA_P and READ_DATA_S are the same and produces a logic 1 if the are different. The fault detector


6102


detects such logic 1 and reports the detected fault to the transfer requesting director.




It is noted that the RAP and PAS signals are both sent to the arbitration logic


6004




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) as composite signal REQUEST A. The arbitration section


6004




1


considers a valid request only if both signals RAP and RAS are the same. In like manner, the arbitration logic


6004




1


issues separate grant signals GAP and GAS which are shown in

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E as a composite signal GRANT_A. Likewise, PORT_A_P_SELECT and PORT_A_S_SELECT signals are both sent to the arbitration logic


6004




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) as composite signal PORT_A_SELECT. The arbitration section


6004




1


considers a valid request only if both signals PORT_A_P_SELECT and PORTA_S_SELECT are the same.




As noted above, the upper port B controller


6002


B provides signals: RBP, GBP, PORT_B_P_SELECT, ADDR/CONTROL, DATA_WRITE RBS, GBS, PORT B_SELECT, and READ_DATA, which are equivalent to RAP, GAP, PORT A_SELECT, ADR/CONTROL, DATA_WRITE, RAS, GAS, PORT A_SELECT, and READ_DATA, respectively, which are provided by the upper port A controller


6002


A.




Referring now to

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E, the arbitration logics


6004




1


,


6004




2


of the logic sections


5010




1


,


5010




2


, respectively, are shown along with the watchdog section


6006


. It is first noted that the arbitration logic


6004




1


,


6004




2


are identical in construction.




Arbitration logic


6004




1


is fed by:




REQUEST A (i.e., RAP, RAS) from upper port A controller


6002


A of logic section


5010




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E);




REQUEST B (RBP, RBS) from upper port B controller


6002


B of logic section


5010




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E);




REQUEST R from upper memory refresh section


6002


R of logic section


5010




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) (It is to be noted that the REQUEST R is made up of two signals, each being produced by identical primary and secondary identical memory refresh units, not shown, in memory refresh section


6002


R both of which have to produce the same refresh signal in order for the arbitration logic


6004




1


to respond to the refresh request). Arbitration logic


6004




2


is fed by:




REQUEST A from upper port A controller


6002


A of logic section


5010




2


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E);




REQUEST B from upper port B controller


6002


B of logic section


5010




2


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E);




REQUEST R from upper memory refresh section


6002


R of logic section


5010




2


.




As shown in

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E, each one of the three request signals REQUEST A, REQUEST B, and REQUEST R, produced in logic section


5010




1


is fed, in triplicate, to three identical arbitration units, (i.e., arbitration unit I, arbitration unit II, and arbitration unit III) in the arbitration logic


6004




1


of such logic section


5010




1


, as indicated. (See also FIG.


19


). Likewise, each one of the three request signals REQUEST A, REQUEST B, and REQUEST R, produced in logic section


5010




2


is fed, in triplicate, to three identical arbitration units, (i.e., arbitration unit I, arbitration unit II, and arbitration unit III, in the arbitration logic


6004




2


of such logic section


5010




2


as indicated.




In response to such request signals, REQUEST A, REQUEST B, and REQUEST R, each arbitration unit I, II, and III determines from the three requests; i.e., REQUEST A, REQUEST B, and REQUEST R, fed to it and in accordance with the algorithm described above, whether upper port A controller


6002


A, upper port B controller


6002


B, or the memory refresh


6002


R is to be given access to the memory array region R


1


. As noted above, the operating Condition (i.e., Condition I, Condition II, or Condition III) is a function of whether the logic section


5010




1


is operating properly and whether the logic section


5010




2


is operating properly. The watchdog section


2006


determines whether such logic sections


5010




1


,


5010




2


are operating properly. More particularly, when the arbitration units I, II, and III make their decision, they also produce a memory output enable (MOE) signals MOEI, MOEII and MOEIII, respectively, (when either logic section


5010




1


or


5010




2


is to be granted access to the memory array region R


1


) and a memory refresh signal MREs (i.e., MREI, MREII and MREIII, respectively, when memory refresh section


6002


R is to be granted access to the memory array region R


1


). Thus, MOE signals MOEI


1


, MOEII


1


, and MOEIII


1


are produced by arbitration units I, II, and III, respectively, in arbitration logic


6004




1


. Also, MRE signals MREI


1


, MREII


1


, and MREIII


1


are produced by arbitration units I, II, and III, respectively, in arbitration logic


6004




1


. In like manner, MOE signals MOEI


2


, MOEII


2


, and MOEIII


2


are produced by arbitration units I, II, and III, respectively, in arbitration logic


6004




2


. Also, MRE signals MREI


2


, MREII


2


, and MREIII


2


are produced by arbitration units I, II, and III, respectively, in arbitration logic


6004




2


. (See also FIG.


19


).




These signals are fed to each of three identical watchdogs, WD


I


, WD


II


, WD


III


as follows:




The MOE and MRE signals produced by the arbitration unit I in arbitration logics


6004




1


and


6004




2


(i.e., MOEI


1


, MOEI


2


, MREI


1


and MREI


2


) are fed to watchdog WD


I


;




The MOE and MRE signals produced by the arbitration unit II in arbitration logics


6004




1


and


6004




2


(i.e., MOEII


1


, MOEII


2


, MREII


1


and MREII


2


) are fed to watchdog WD


II


; and




The MOE and MRE signals produced by the arbitration unit III in arbitration logics


6004




1


and


6004




2


(i.e., MOEIII


1


, MOEIII


2


, MREIII


1


and MREIII


2


) are fed to watchdog WD


III


.




Each one of the watchdogs I, II, III is implemented and arranged identical to perform the same logic functions; however, they preferably implemented with components manufactured independently of each other. Further, each one of the watchdogs I, II, and III operates ill response to its own independent clock, i.e., Clock I, Clock II, and Clock III, respectively. Thus, each watchdog makes an independent determination as to whether these signals are in proper time and rate and thus, determine, in accordance with the “Condition algorithm” described above, the proper one of the Conditions (i.e., Condition I, Condition II, or Condition III) for the system. An indication of the Condition is provided by each of the watchdogs WD


I


, WD


II


, and WD


III


as a two-bit word MSAB


I


, MSAB


II


, and MSAB


III


, respectively. The two-bit word is produces as follows:




00=Condition I




01=Condition II




10=condition III




11=Reset (i.e., Condition IV)




These three words MSAB


I


, MSAB


II


, and MSAB


III


are fed to both arbitration logics


6004




1


and


6004




2


, as indicated. It should be remembered that each one of the arbitration logics


6004




1


and


6004




2


(and hence the arbitration logics


6004




1


and


6004




2


therein), operate with a separate independent clock, Clock


1


, and Clock


2


, respectively. In order to synchronize the three words MSAB


I


, MSAB


II


, and MSAB


III


are fed to logic section


5010




1


and fed to logic section


5010




2


. Each one of the arbitration logics


6004




1


,


6004




2


has a synchronization filter


6200




1


,


6200




2


to be described. Suffice it to say here, however, that the filter


6200




1


produces corresponding signals MSAB


I













1


, MSAB


II













1


, and MSAB


III













1


, respectively, and filter


6200




2


produce corresponding signals MSAB


I













2


, MSAB


II













2


, and MSAB


III













2


, respectively, as indicated.




The signals MSAB


I













1


, MSAB


II













1


, and MSAB


III













1


, are fed to the arbitration units I, II, and III, respectively, in arbitration logic


6004




1


. In like manner, the signals MSAB


I













2


, MSAB


II













2


, and MSAB


III













2


, are fed to the arbitration units I, II, and III, respectively, in arbitration logic


6004




2


. In response to such signals, each one of the arbitration units I, II, and III, makes an independent determination of whether logic section


5010




1


(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E) or logic section


5010




2


will be granted access to the memory array region R


1


. A grant by logic section


5010




1


to logic section


5010




2


is indicated by a Memory Grant (MG) signal. Thus, arbitration units I, II, and III of logic section


5010




1


produce Memory Grant signals MGI


1


, MGII


1


, and MGIII


1


, respectively. Such signals are fed to a synchronization filter


6202




2


in arbitration logic


6004




2


. The synchronization filter


6202




2


operates as is constructed in the same manner as synchronization filters


6200




1


and


6200




2


. In like manner arbitration units I, II, and III of logic section


5010




2


produce Memory Grant signals MGI


2


, MGII


2


, and MGIII


2


, respectively. Such signals are fed to a synchronization filter


6202




1


in arbitration logic


6004




1


. The synchronization filter


6202




1


operates as is constructed in the same manner as synchronization filter


6202




2


.




Thus, considering exemplary synchronization filter


6202




2


, such filter is fed by the three Memory Grant (MG) signals MGI


2


, MGII


2


, and MGIII


2


, as indicated. The three signals are stored in registers


6204


I,


6204


II and


6204


III, respectively, in response to a clock pulse produced by the Clock


2


. Each of the three registers


6204


I,


6204


II and


6204


III, send the information stored therein to each of three majority gates MGI, MGII, and MGIII, respectively, as indicated. The majority gates produce an output which is the majority of the three inputs fed thereto. The outputs of the three majority gates MGI, MGII and MGIII are the arbitration units I, II and III, respectively, in the arbitration logic


6004




2


, as indicated.




More particularly, referring to

FIG. 16

, portions of arbitration logics


6004




1


and


6004




2


are shown. The data to be fed to the output of arbitration logic


6004




1


is clocked into register


7000




1


of arbitration I, register


7000




2


of arbitration II, and register


7000




3


of arbitration III simultaneously in response to the same clock pulse produced by Clock


1


. Thus, each of the registers


7000




1


,


7000




2


,


7000




3


should store the same data at the clock pulse produced by Clock


1


, as indicated in FIG.


18


. The data is then fed to registers


7002




1


,


7002




2


,


7002




3


of filter


6202




2


of arbitration logic


6004




2


. The data at the registers


7002




1


,


7002




2


,


7002




3


are stored therein in response to the same clock produced by Clock


2


. Because of the data in registers


7000




1


,


7000




2


,


7000




3


arrive at registers


7002




1


,


7002




2


,


7002




3


with different delays as indicated in

FIG. 18

, while the data in


7000




1


,


7000




2




7000




3


is the same, here the data stored in registers


7002




1


,


7002




2


,


7002




3


may be different as shown in FIG.


18


. The data stored in register


7002




1


is fed to majority gates (MGs)


7004




1


,


7004




2


and


7004




3


. The data stored in register


7002




2


is also fed to majority gates (MGs)


7004




1


,


7004




2


and


7004




3


. Likewise, the data stored in register


7002




3


is fed to majority gates (MGs)


7004




1


,


7004




2


and


7004




3


. Each one of the majority gates MGs produces an output representative of the majority of the logic signals fed thereto as indicated in FIG.


17


.




Referring now to

FIGS. 20A

,


20


B and


20


C, the three arbitrations I, II, and III of exemplary arbitration logic


6004




1


are the signals fed thereto and produced thereby are shown in more detail. It is first noted that the primary signal REQUEST_A_P, (RAP), and the secondary request signal REQUEST_A_S (RAS) are each fed in triplicate; one copy to each of the arbitrations I, II, and III, as indicated. The one of the triplicate RAP and RAS fed to arbitration I are fed to an AND gate


8000




1


, a second one of the triplicate RAP and RAS fed to arbitration II are fed to an AND gate


8000




2


, and the third one of the triplicate RAP and RAS fed to arbitration III are fed to an AND gate


8000




3


, as indicated. Likewise, the signals REQUEST_B_P, (RBP), and REQUEST_B_S (RBS) are each fed in triplicate; one copy to each of the arbitrations I, II, and III, as indicated. The one of the triplicate RBP and RBS fed to arbitration I are fed to an AND gate


8002




1


, a second one of the triplicate RBP and RBS fed to arbitration II are fed to an AND gate


8002




2


, and the third one of the triplicate RBP and RBS fed to arbitration III are fed to an AND gate


8002




3


, as indicated. As mentioned briefly above, there are two memory refresh units in the memory refresh section


6002


R(

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E). One, a primary unit (not shown), issues a request RRP and the other, a secondary unit (not shown), issues a request RRS. Above, in connection with

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E, these two requests were considered as a composite request (REFRESH_REQUEST) to simplify the discussion presented above. Here, in connection with

FIG. 19

, the individual signals RRP, RRS are shown in more detail. Thus, the signals RRP, RRS are each fed in triplicate; one copy to each of the arbitrations I, II, and III, as indicated. The one of the triplicate RRP and RRS is fed to arbitration I are fed to an AND gate


8004




1


, a second one of the triplicate RRP and RRS fed to arbitration II are fed to an AND gate


8004




2


, and the third one of the triplicate RRP and RS fed to arbitration III are fed to an AND gate


8004




3


, as indicated.




Thus, in the case of each pair, in order for the request to be issued to the arbitration I, II, or III, the AND gate associated therewith must see the same request from both the primary signal and the secondary signal fed to it.




Each arbitration I, II and II issues pairs of grants, i.e., a primary grant to the primary unit and a secondary grant to the secondary unit. Thus, each of the arbitrations I, II and III issues: the primary and secondary grants (GAP and GAS, respectively) to the Port A primary control section


6100


P (

FIGS. 14A

,


14


B,


14


C and


14


D) and Port A secondary control section


6100


S of Port A controller


6002


A; the primary and secondary grants (GBP and GBS, respectively) to the Port B primary control section and Port A secondary control section of Port B controller


6002


B; and the primary and secondary grants (GRP and GRS, respectively) to the memory refresh primary unit memory refresh secondary unit of the memory refresh section


6002


R (

FIGS. 13A

,


13


B,


13


C,


13


D and


13


E).




The arbitrations I, II, and III produce Memory Output Enable signals MOE


I-1


, MOE


II-1


, and MOE


III-1


respectively, as indicated, for the watchdogs WD


I


, WD


II


, and WD


II


, respectively, as shown in

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E. The arbitrations I, II, and III produce Memory Refresh Enable signals MRE


I-1


, MRE


II-1


, and MRE


III-1


, respectively, as indicated, for the watchdogs WD


I


, WD


II


and WD


III


, respectively, as shown in

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E. The arbitrations I, II, and III produce Memory Grant signals MG


I


, MG


I


, and MG


III


, respectively, as indicated, for the registers


6204




I


,


6204




II


, and


6204




III


, respectively, of filter


6202




2


of logic section


5010




2


, as shown in

FIGS. 15A

,


15


B,


15


C,


15


D and


15


E.




Thus, it should be noted that while each one of the registers


7002




1


,


7002




2


,


7002




3


, of filters


6002




1


,


6002




2


(FIGS.


19


), are fed the same data from registers


7000




1


,


7000




2


, and


7000




3


, respectively, because of the time skew shown in

FIG. 18

, such registers


7002




1


,


7002




2


,


7002




3


, may not store the data which is in registers


7000




1


,


7000




2


, and


7000




3


, respectively. However, the majority gates MG


7004




1


-


7004




3


will produce the same data according to FIG.


17


. Therefore, the three arbitrations I, II, and III of arbitration logic


6004




2


will receive the same data (i.e., the data produced by the majority gates MG


7004




1


-


7004




3


) thereby providing coherency (i.e., synchronization) to tile arbitrations I, II, and III even though the arbitrations are operating independently of each other.




Other embodiments are within the spirit and scope of the appended claims.



Claims
  • 1. A memory system, comprising:a backplane having a plurality of receiving slots, each one of the slots having electrical contacts for providing an indication of such one of the slots, each one of the slots having a different slot indication; a plurality of memory boards, each one being plugged into a corresponding one of the slots, each one of such boards being coupled to the electrical contacts in the corresponding one of the slots to provide a slot signal indicative of the slot indication provided by the electrical contacts; each one of such boards having: a memory array region; and a switching network for transferring information between a port of the switching network and a memory on such memory board, such transfer being initiated by a director coupled to such port, such director designating a selected one of the plurality of memory boards, such director providing to the switching network a “tag” indicating such designated one of one of the plurality of memory boards having the memory involved in the requested transfer, such switch network having: a memory board checker, for comparing the slot signal with the “tag” for indicating whether the memory board receiving the “tag” is the director designated one of the plurality of memory boards.
  • 2. The memory system recited in claim 1 wherein the memory board checker sends an indication to the requesting director slot signal as to whether the memory board receiving the “tag” is the designated one of the memory boards.
  • 3. The memory system recited in claim 1 wherein the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.
  • 4. The memory system recited in claim 2 wherein the switching network includes a decoder responsive to the indication provided by, the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.
  • 5. A memory system, comprising:a backplane having a plurality of receiving slots, each one of the slots having electrical contacts for providing an indication of such one of the slots, each one of the slots having a different slot indication; a plurality of memory boards, each one being plugged into a corresponding one of the slots, each one of such boards being coupled to the electrical contacts in the corresponding one of the slots to provide a slot signal indicative of the slot indication provided by the electrical contacts; each one of such boards having: (A) a plurality of memory array regions, each one of such regions having a common DATA port and a pair of independent memory array control ports; (B) a plurality of logic sections, each one of the logic sections having: a first logic section upper ports, a second logic section upper ports, a logic section control port, and a logic section DATA port; (C) a plurality of crossbar switches, each one thereof having a plurality of crossbar switch upper ports and a plurality of crossbar switch lower ports, such crossbar switch upper ports and crossbar switch lower ports being coupled in accordance with information fed to the crossbar switch upper ports, such lower ports being coupled to the first and second upper ports of the plurality of logic sections, for transferring information between a selected one of the upper ports of the crossbar switches and the control logic sections to one of the memory array regions coupled thereto, such transfer being initiated by a director coupled to such selected one of the upper ports, such director designating a selected one of the plurality of memory boards, such director providing to the switching network a “tag” indicating such designated one of one of the plurality of memory boards having the memory involved in the requested transfer, such crossbar switches having: a memory board checker, for comparing the slot signal with the “tag” for indicating(whether the memory board receiving the “tag” is the director designated one of the plurality of memory boards.
  • 6. The memory system received in claim 5 wherein the memory board checker sends an indication to the requesting director slot signal as to whether the memory board receiving the “tag” is the designated one of the memory boards.
  • 7. The memory'system recited in claim 5 wherein the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.
  • 8. The memory system recited in claim 6 wherein the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving, the “tag” is different from the designated one of the memory boards.
  • 9. The memory system recited in claim 5 wherein:the plurality of logic sections are arranged in pairs, each pair being coupled to a corresponding one of the plurality of array regions; the logic section in each pair thereof having: the DATA port of such pair of logic sections connected to the memory DATA port of the corresponding one of the memory array region; the control port thereof connected to a corresponding one of the pair of memory array control ports the corresponding one of the memory array regions; and wherein each one of the plurality of crossbar switches comprises a plurality of crossbar switch upper ports and a plurality of crossbar switch lower ports, such crossbar switch upper ports and crossbar switch lower ports being coupled in accordance with information fed to the crossbar switch upper ports, wherein a first one of the crossbar switches has each one of the crossbar switch lower ports thereof connected to the first logic section upper port of a first one of the logic sections in a corresponding one of the pairs of such logic sections wherein a second one of the crossbar switches has each one of the crossbar switch lower ports thereof connected to the second logic section upper port of the first one of the logic sections in a corresponding one of the pairs of such logic sections; wherein a third one of the crossbar switches has each one of the crossbar switch lower ports thereof connected to the first logic section upper port in a second one of the logic sections in a corresponding one of the pairs of such logic sections; and wherein a fourth one of the crossbar switches has each one of the crossbar switch lower ports thereof connected to the second one of the pair of logic section upper ports of a corresponding one of the second logic sections in a corresponding one of the pairs of such logic sections.
  • 10. The memory system received in claim 9 wherein the memory board checker sends an indication to the requesting director slot signal as to whether the memory board receiving the “tag” is the designated one of the memory boards.
  • 11. The memory system recited in claim 9 wherein the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.
  • 12. The memory system recited in claim 10 wherein the switching network includes a decoder responsive to the indication provided by the memory board checker for inhibiting transfer of the information at the port to the memory if the memory board receiving the “tag” is different from the designated one of the memory boards.
US Referenced Citations (2)
Number Name Date Kind
6389494 Walton et al. May 2002 B1
20020059501 McKinney et al. May 2002 A1