Abstract:
A cache memory system includes a plurality of first storage hierarchical units provided individually to a plurality of processors. A second storage hierarchical unit is provided commonly to the plurality of processors. A control unit controls data transfer between the plurality of first storage hierarchical units and the second storage hierarchical unit. Each of the plurality of processors is capable of executing a no-data transfer store command as a store command that does not require data transfer from the second storage hierarchical unit to the corresponding first storage hierarchical unit, and each of the plurality of first storage hierarchical units outputs a transfer-control signal in response to occurrence of a cache miss hit when executing the no-data transfer store command by the corresponding processor.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2008-66067 filed on Mar. 14, 2008, the entire contents of which are incorporated herein by reference. 
     BACKGROUND 
     1. Field 
     The present invention relates to a cache memory system, a data processing apparatus, and a storage apparatus, and method thereof. 
     2. Description of the Related Art 
     In a data processing apparatus, since an access latency from a processor to a main storage apparatus includes many stall cycles, a cache memory which can be accessed speedily by the processor is often provided in order to reduce the penalty associated with access from the processor to the main storage apparatus. However, when a command associated with access to a storage area where no copy of data of the main storage apparatus exists in the cache memory is executed by the processor, a cache miss hit occurs. At that time, when a load command is executed or a store command is executed in the cache memory having a write-allocating system, since an operation (move-in operation) for preparing a copy of data of the main storage apparatus in the cache memory is required, a penalty for executing a command of the processor will be caused to a certain degree. 
     Although occurrence frequency of the cache miss hit can be reduced by increasing capacity of the cache memory, it is not easy to increase capacity of a memory which can be accessed speedily by the processor due to trade-off between operating frequency and cost. Therefore, a method is often used for reducing the penalty associated with occurrence of the cache miss hit by providing a primary cache memory which can be accessed in the same operating speed as that of the processor and a high-capacity secondary cache memory which cannot be accessed in the same operating speed as that of the processor but can be accessed more speedily than the main storage apparatus (that is, by providing a hierarchical structure in the cache memory). In the case where a hierarchical cache memory is used in a data processing apparatus having a multi-processor structure, a storage hierarchy which is closer to the main storage apparatus is often shared among a plurality of processors. In this case, a cache control apparatus for assuring coherency of data among the plurality of processors may be provided. 
     Further, when data of the corresponding entry of the cache memory is rewritten by a store command (writing store data), data transferred to the cache memory by the move-in operation is never referred to by the processor. Therefore, the move-in operation has been performed uselessly and it may cause problems in processing performance and power consumption of the data processing apparatus. 
     In addition, techniques related to the cache memory are disclosed in, for example, Japanese Patent No. 2552704, Japanese Patent No. 3055908, and Japanese Patent No. 2637320. 
     SUMMARY 
     According to an aspect of an embodiment of the invention, a method, apparatus, and computer readable recording media thereof is provided in which a computer processor implements a no-move-in store command as a store command that does not require a move-in and the no-move-in store command, when executed by the processor, controls not to request a move-in even if the cache miss hit occurs. 
     According to an aspect of an embodiment, there is provided a cache memory system including: a plurality of first storage hierarchical units provided individually to a plurality of processors; a second storage hierarchical unit provided commonly to the plurality of processors; and a control unit for controlling data transfer between the plurality of first storage hierarchical units and the second storage hierarchical unit, wherein each of the plurality of processors is capable of executing a no-data transfer store command as a store command that does not require data transfer from the second storage hierarchical unit to the corresponding first storage hierarchical unit, each of the plurality of first storage hierarchical units outputs a transfer-control signal in response to occurrence of a cache miss hit when executing the no-data transfer store command by the corresponding processor, and the control unit updates state information of a first storage hierarchical unit corresponding to a first processor included in the plurality of processors without performing data transfer at least from the second storage hierarchical unit to the first storage hierarchical unit corresponding to the first processor with respect to a storage area designated by the first storage hierarchical unit corresponding to the first processor in the case where the transfer-control signal is output by the first storage hierarchical unit corresponding to the first processor. 
     Other aspects and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the claims. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, as claimed. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a diagram representing an embodiment of the present invention; 
         FIGS. 2A and 2B  are diagrams representing an operation of a conventional data processing apparatus; 
         FIGS. 3A and 3B  are diagrams representing an operation of the data processing apparatus represented in  FIG. 1 ; 
         FIGS. 4A and 4B  are diagrams representing another operation of the conventional data processing apparatus; and 
         FIGS. 5A and 5B  are diagrams representing another operation of the data processing apparatus represented in  FIG. 1 . 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Hereinbelow, a preferred embodiment will be described in accordance with the accompanying drawings wherein like numerals refer to like parts throughout.  FIG. 1  represents an embodiment. A data processing apparatus  10  according to the embodiment has Central Processing Units (CPU)  20   a ,  20   b  and  20   c  (having a CPU core  21  and a primary cache  22 ), and a secondary cache  30  (having a cache control apparatus  31 ) shared by the CPUs  20   a ,  20   b  and  20   c . The secondary cache  30  is connected to a main storage apparatus, though it is not represented in the drawing. 
     The CPU core  21  has a command decoder  211  and can execute a no-move-in store command as a store command which does not require move-in (transferring data from the secondary cache  30  to the primary cache  22 ) in addition to various known commands. When the CPU core  21  executes the no-move-in store command, the CPU core  21  outputs a move-in prohibition signal S 1  (signal representing that move-in is not required) to the primary cache  22 . 
     The primary cache  22  has cache Random Access Memories (RAM)  221   a  and  221   b , selectors  222 ,  223  and  224 , tag RAMs  225   a  and  225   b , an address comparator  226 , a cache state information storing circuit  227 , and a control circuit  228 . For example, in the primary cache  22 , a write-allocating system is used. In addition, in the primary cache  22 , the MOSI cache coherency protocol/system is used for assuring a cache coherency. 
     The cache RAMs  221   a  and  221   b  write output data of the selector  222  into an entry depending on an output address of the CPU core  21  according to writing instructions of the control circuit  228 . Further, the cache RAMs  221   a  and  221   b  read data from the entry depending on the output address of the CPU core  21  according to reading instructions of the control circuit  228  and output the read data to the selector  223 . The selector  222  selects output data of the CPU core  21  or output data of the secondary cache  30  according to selecting instructions of the control circuit  228  and outputs the selected output data to the cache RAMs  221   a  and  221   b . The selector  223  selects output data of the cache RAM  221   a  or output data of the cache RAM  221   b  according to selecting instructions of the control circuit  228  and outputs the selected output data to the selector  224  and the secondary cache  30 . The selector  224  selects output data of the selector  223  or output data of the secondary cache  30  according to selecting instructions of the control circuit  228  and outputs the selected output data to the CPU core  21 . 
     The tag RAMs  225   a  and  225   b  write a part of an address into the entry depending on the output address of the CPU core  21  according to writing instructions of the control circuit  228 . The tag RAMs  225   a  and  225   b  read the address from the entry depending on the output address of the CPU core  21  according to reading instructions of the control circuit  228  and output the read address to the address comparator  226 . The address comparator  226  compares a part of the output address of the CPU core  21  with the output address of the tag RAMs  225   a  and  225   b  and outputs an address comparing result signal S 2  (signal representing whether the addresses match or not) to the control circuit  228 . The cache state information storing circuit  227  stores state information of each entry which is embodied by a register or the like and is used for controlling cache coherency. The state information is set to any one of a modified (M) state, an owned (O) state, a shared (S) state and an invalid (I) state by the control circuit  228 . 
     The control circuit  228  performs various operations for controlling the entire primary cache  22 . The control circuit  228  determines a cache hit/cache miss hit based on the address comparing result signal S 2 . When the control circuit  228  recognizes occurrence of the cache miss hit, upon output of the move-in prohibition signal S 1  by the CPU core  21 , a no-move-in store request signal S 3  (signal representing that a cache miss hit occurs when executing a no-move-in store command) is output to the secondary cache  30  (cache control apparatus  31 ). The cache control apparatus  31  performs an operation for controlling data transfer between the primary cache  22  (control circuit  228 ) of the CPUs  20   a ,  20   b  and  20   c  and the secondary cache  30 , an operation for assuring the cache coherency or the like. 
     Various control signals such as a move-in request signal (signal for requesting data transfer from the secondary cache  30  to the primary cache  22 ) are output from the primary cache  22  (control circuit  228 ) of the CPUs  20   a ,  20   b  and  20   c  to the secondary cache  30  (cache control apparatus  31 ) when necessary, though it is not represented in the drawing. Further, various control signals such as a flush request signal (signal for requesting to write back dirty data) or an invalidate request signal (signal for requesting to set the state information to the invalid state) are output from the secondary cache  30  (cache control apparatus  31 ) to the primary cache  22  (control circuit  228 ) of the CPUs  20   a ,  20   b  and  20   c  when necessary. 
       FIGS. 2A and 2B  represent an operation of a conventional data processing apparatus. The conventional data processing apparatus  10 ′ has CPUs  20   a ′,  20   b ′ and  20   c ′ and a secondary cache  30 ′. The CPUs  20   a ′,  20   b ′ and  20   c ′ are the same as the CPUs  20   a ,  20   b  and  20   c  represented in  FIG. 1  except that the CPUs  20   a ′,  20   b ′ and  20   c ′ do not have a mechanism related to the no-move-in store command. The secondary cache  30 ′ is the same as the secondary cache  30  represented in  FIG. 1  except that the secondary cache  30 ′ does not have a mechanism related to the no-move-in store request signal. 
     The operations represented in  FIGS. 2A and 2B  are performed when a cache miss hit occurs upon executing a store command for designating an address A as a store destination address at the CPU  20   a ′ (primary cache) in the case where line data corresponding to the address A does not exist in the modified cache state in the CPUs  20   b ′ or  20   c ′ (primary cache). In addition, it is previously known that the line data corresponding to the address A is never referred to at the CPU  20   a′.    
     When the cache miss hit occurs, upon executing the store command for designating the address A as a store destination address at the CPU  20   a ′, as represented in  FIG. 2A , a move-in request signal is output from the CPU  20   a ′ to the secondary cache  30 ′ (cache control apparatus  31 ′) (O 1 ). With this operation, as represented in  FIG. 2B , data of the corresponding line (line corresponding to the address A designated by the CPU  20   a ′) is transferred from the secondary cache  30 ′ to the CPU  20   a ′ by the move-in operation (O 2 ). At the CPU  20   a ′ (primary cache), after the data transferred from the secondary cache  30 ′ is written in the corresponding entry, the execution of the store command is completed by writing the store data into the corresponding entry. Thereafter, the state information of the corresponding entry of the cache state information storing circuit  227 ′ is updated from “I” to “M” (O 3 ). Since there is the circumstance when data transferred from the secondary cache  30 ′ to the CPU  20   a ′ by the move-in operation is never referred to at the CPU  20   a ′, data transfer (move-in) from the secondary cache  30 ′ to the CPU  20   a ′ is uselessly performed. 
       FIGS. 3A and 3B  represent operations of the data processing apparatus represented in  FIG. 1 . The operations represented in  FIGS. 3A and 3B  are performed when a cache miss hit occurs and executing a no-move-in store command for designating an address A as a store destination address at the CPU  20   a  (primary cache) in the case where line data corresponding to the address A does not exist in the modified cache state in the CPUs  20   b  or  20   c  (primary cache). In addition, it is previously known that the line data corresponding to the address A is never referred to at the CPU  20   a.    
     When the cache miss hit occurs, upon executing the no-move-in store command for designating the address A as a store destination address at the CPU  20   a , as represented in  FIG. 3A , not a move-in request signal but a no-move-in store request signal is output from the CPU  20   a  to the secondary cache  30  (cache control apparatus  31 ) (O 1 ). With this operation, as represented in  FIG. 3B , the move-in operation is not performed (O 2 ), but only an operation related to assuring cache coherency is performed in the cache control apparatus  31  of the secondary cache  30 . At the CPU  20   a , upon outputting the no-move-in store request signal, the CPU  20   a  completes execution of the store command by writing (i.e., directly writing) the store data into the corresponding primary cache  22  entry. Thereafter, the state information of the corresponding entry of the cache state information storing circuit  227  is updated from “I” to “M” (O 3 ). As described above, the data processing apparatus  10  represented in  FIG. 1  differs from the conventional data processing apparatus  10 ′ (represented in  FIGS. 2A and 2B ), so that useless data transfer from the secondary cache  30  to the CPU  20   a  associated with the move-in operation is avoided and data coherency among the CPUs  20   a ,  20   b  and  20   c  is assured. 
       FIGS. 4A and 4B  represent another operation of the conventional data processing apparatus. The operations represented in  FIGS. 4A and 4B  are performed when a cache miss hit occurs and executing a store command for designating an address A as a store destination address at the CPU  20   a ′ (primary cache) in the case where line data corresponding to the address A exists in the modified cache state in the CPU  20   c ′ (primary cache). In addition, it is previously known that the line data corresponding to the address A is never referred to at the CPU  20   a′.    
     When the cache miss hit occurs, upon executing the store command for designating the address A as a store destination address at the CPU  20   a ′, as represented in  FIG. 4A , a move-in request signal is output from the CPU  20   a ′ to the secondary cache  30 ′ (cache control apparatus  31 ′) (O 1 ). With this operation, as represented in  FIG. 4B , a flush request signal is output from the secondary cache  30 ′ (cache control apparatus  31 ′) to the CPU  20   c ′ (O 2 ). Therefore, dirty data of the corresponding line is transferred from the CPU  20   c ′ to the secondary cache  30 ′ by the flush operation (O 3 ), and at the CPU  20   c ′, the state information of the corresponding entry of the cache state information storing circuit  227 ′ is updated from “M” to “I” (O 4 ). Thereafter, data transferred from the CPU  20   c ′ to the secondary cache  30 ′ is transferred from the secondary cache  30 ′ to the CPU  20   a ′ by a move-in operation (O 5 ). At the CPU  20   a ′ (primary cache), after data transferred from the secondary cache  30 ′ is written into the corresponding entry, the execution of the store command is completed by writing store data into the corresponding entry and the state information of the corresponding entry of the cache state information storing circuit  227 ′ is updated from “I” to “M” (O 6 ). Since data transferred from the secondary cache  30 ′ to the CPU  20   a ′ by the move-in operation is never referred to at the CPU  20   a ′, data transfer (flush) from the CPU  20   c ′ to the secondary cache  30 ′ and data transfer (move-in) from the secondary cache  30 ′ to the CPU  20   a ′ are uselessly performed. 
       FIGS. 5A and 5B  represent another operation of the data processing apparatus represented in  FIG. 1 . The operations represented in  FIGS. 5A and 5B  are performed when a cache miss hit occurs and executing a no-move-in store command for designating an address A as a store destination address at the CPU  20   a  (primary cache) in the case where line data corresponding to the address A exists in the modified cache state in the CPU  20   c  (primary cache). In addition, it is previously known that the line data corresponding to the address A is never referred to at the CPU  20   a.    
     When the cache miss hit occurs, upon executing the no-move-in store command for designating the address A as a store destination address at the CPU  20   a , as represented in  FIG. 5A , not a move-in request signal but a no-move-in store request signal is output from the CPU  20   a  to the secondary cache  30  (cache control apparatus  31 ) (O 1 ). With this operation, as represented in  FIG. 5B , not a flush request signal but an invalidate request signal is output from the secondary cache  30  (cache control apparatus  31 ) to the CPU  20   c  (O 2 ). Therefore, the flush operation is not performed (O 3 ), and at the CPU  20   c , the state information of the corresponding entry of the cache state storing circuit  227  is updated from “M” to “I” (O 4 ). Further, a move-in operation is not performed (O 5 ), and at the CPU  20   a , upon outputting the no-move-in store request signal, the CPU  20   a  completes execution of the store command by writing (i.e., directly writing) the store data into the corresponding primary cache  22  entry. Thereafter, the state information of the corresponding entry of the cache state information storing circuit  227  is updated from “I” to “M” (O 6 ). As described above, the data processing apparatus  10  represented in  FIG. 1  differs from the conventional data processing apparatus  10 ′ (represented in  FIGS. 4A and 4B ), so that useless data transfer from the CPU  20   c  to the secondary cache  30  associated with the flush operation and useless data transfer from the secondary cache  30  to the CPU  20   a  associated with the move-in operation are avoided and data coherency among the CPUs  20   a ,  20   b  and  20   c  is assured. 
     As described above, the data processing apparatus  10  according to the embodiment can reduce useless data transfer (memory access) between the primary cache  22  of the CPUs  20   a ,  20   b  and  20   c  and the secondary cache  30  with/while assuring cache coherency. This will substantially contribute to improvement of the processing performance and reduction of the power consumption in the data processing apparatus  10 . 
     According to an aspect of the embodiments of the invention, any combinations of the described features, functions, operations, and/or benefits can be provided. The embodiments can be implemented as an apparatus (machine) that includes computing hardware (i.e., computing apparatus), such as (in a non-limiting example) any computer that can store, retrieve, process and/or output data and/or communicate (network) with other computers. According to an aspect of an embodiment, the described features, functions, operations, and/or benefits can be implemented by and/or use computing hardware and/or software. The apparatus (e.g., the data processing apparatus  10 ) comprises a controller (CPU) (e.g., a hardware logic circuitry based computer processor that processes or executes instructions, namely software/program), computer readable recording media (e.g., primary/secondary caches  30 ,  22 , main storage apparatus, etc.), transmission communication media interface (network interface), and/or a display device, all in communication through a data communication bus. The results produced can be displayed on a display of the computing apparatus. A program/software implementing the embodiments may be recorded on computer readable media comprising computer-readable recording media, such as in non-limiting examples, a semiconductor memory (for example, RAM, ROM, etc.). 
     While the present invention has been described in detail, it is to be understood that the foregoing embodiment is only an exemplary embodiment. The present invention is not limited to the above embodiment and various changes/modifications and equivalents can be made within the spirit and scope of the present invention.