| Patent application number | Description | Published |
|---|
| 20080201533 | REDUCING NUMBER OF REJECTED SNOOP REQUESTS BY EXTENDING TIME TO RESPOND TO SNOOP REQUEST - A cache, system and method for reducing the number of rejected snoop requests. An incoming snoop request is entered in the first available latch in a pipeline of latches in a stall/reorder unit if the stall/reorder unit is not full. The entered snoop request is dispatched to a selector upon entering a bottom latch in the pipeline. The stall/reorder unit is not informed as to whether the dispatched snoop request is accepted by an arbitration mechanism for several clock cycles after the dispatch occurred. A copy of the dispatched snoop request is stored in a top latch in an overrun pipeline of latches in the first unit upon dispatching the snoop request. By maintaining information about the snoop request, the snoop request may be dispatched again to the selector in case the dispatched snoop request was rejected thereby increasing the chance that the snoop request will ultimately be accepted. | 08-21-2008 |
| 20080201534 | REDUCING NUMBER OF REJECTED SNOOP REQUESTS BY EXTENDING TIME TO RESPOND TO SNOOP REQUEST - A cache, system and method for reducing the number of rejected snoop requests. A “stall/reorder unit” in a cache receives a snoop request from an interconnect. The snoop request is entered in the first available latch of the stall/reorder unit unless the stall/reorder unit is full in which case the new snoop request is transmitted to a second unit configured to transmit a request to retry resending the new snoop request. Snoop requests have a higher priority than requests from processors and snoop requests are selected by the arbitration mechanism over processor requests unless the arbitration mechanism requests otherwise (“stall request”) to the stall/reorder unit. By snoop requests having a higher priority than processor requests, the number of snoop requests rejected is reduced. By having the arbitration mechanism issue a stall request, the processor will not be starved. | 08-21-2008 |
| 20080209135 | DATA PROCESSING SYSTEM, METHOD AND INTERCONNECT FABRIC SUPPORTING DESTINATION DATA TAGGING - A data processing system includes a plurality of communication links and a plurality of processing units including a local master processing unit. The local master processing unit includes interconnect logic that couples the processing unit to one or more of the plurality of communication links and an originating master coupled to the interconnect logic. The originating master originates an operation by issuing a write-type request on at least one of the one or more communication links, receives from a snooper in the data processing system a destination tag identifying a route to the snooper, and, responsive to receipt of the combined response and the destination tag, initiates a data transfer including a data payload and a data tag identifying the route provided within the destination tag. | 08-28-2008 |
| 20080215824 | CACHE MEMORY, PROCESSING UNIT, DATA PROCESSING SYSTEM AND METHOD FOR FILTERING SNOOPED OPERATIONS - A cache coherent data processing system includes at least a first cache memory supporting a first processing unit and a second cache memory supporting a second processing unit. The first cache memory includes a cache array and a cache directory of contents of the cache array. In response to the first cache memory detecting on an interconnect a broadcast operation that specifies a request address, the first cache memory determines from the operation a type of the operation and a coherency state associated with the request address. In response to determining the type and the coherency state, the first cache memory filters out the broadcast operation without accessing the cache directory. | 09-04-2008 |
| 20080225863 | DATA PROCESSING SYSTEM, METHOD AND INTERCONNECT FABRIC SUPPORTING MULTIPLE PLANES OF PROCESSING NODES - A data processing system includes a first plane including a first plurality of processing nodes, each including multiple processing units, and a second plane including a second plurality of processing nodes, each including multiple processing units. The data processing system also includes a plurality of point-to-point first tier links. Each of the first plurality and second plurality of processing nodes includes one or more first tier links among the plurality of first tier links, where the first tier link(s) within each processing node connect a pair of processing units in the same processing node for communication. The data processing system further includes a plurality of point-to-point second tier links. At least a first of the plurality of second tier links connects processing units in different ones of the first plurality of processing nodes, at least a second of the plurality of second tier links connects processing units in different ones of the second plurality of processing nodes, and at least a third of the plurality of second tier links connects a processing unit in the first plane to a processing unit in the second plane. | 09-18-2008 |
| 20080229022 | EFFICIENT SYSTEM BOOTSTRAP LOADING - An efficient system for bootstrap loading scans cache lines into a cache store queue during a scan phase, and then transmits the cache lines from the cache store queue to a cache memory array during a functional phase. Scan circuitry stores a given cache line in a set of latches associated with one of a plurality of cache entries in the cache store queue, and passes the cache line from the latch set to the associated cache entry. The cache lines may be scanned from test software that is external to the computer system. Read/claim dispatch logic dispatches store instructions for the cache entries to read/claim machines which write the cache lines to the cache memory array without obtaining write permission, after the read/claim machines evaluate a mode bit which indicates that cache entries in the cache store queue are scanned cache lines. In the illustrative embodiment the cache memory is an L2 cache. | 09-18-2008 |
| 20080301377 | DATA PROCESSING SYSTEM, CACHE SYSTEM AND METHOD FOR UPDATING AN INVALID COHERENCY STATE IN RESPONSE TO SNOOPING AN OPERATION - A cache coherent data processing system includes at least first and second coherency domains. In a first cache memory within the first coherency domain of the data processing system, a coherency state field associated with a storage location and an address tag is set to a first data-invalid coherency state that indicates that the address tag is valid and that the storage location does not contain valid data. In response to snooping an exclusive access operation, the exclusive access request specifying a target address matching the address tag and indicating a relative domain location of a requestor that initiated the exclusive access operation, the first cache memory updates the coherency state field from the first data-invalid coherency state to a second data-invalid coherency state that indicates that the address tag is valid, that the storage location does not contain valid data, and whether a target memory block associated with the address tag is cached within the first coherency domain upon successful completion of the exclusive access operation based upon the relative location of the requestor. | 12-04-2008 |
| 20080301531 | FAULT TOLERANT ENCODING OF DIRECTORY STATES FOR STUCK BITS - A method of handling a stuck bit in a directory of a cache memory, by defining multiple binary encodings to indicate a defective cache state, detecting an error in a tag stored in a member of the directory (wherein the tag at least includes an address field, a state field and an error-correction field), determining that the error is associated with a stuck bit of the directory member, and writing new state information to the directory member which is selected from one of the binary encodings based on a field location of the stuck bit within the directory member. The multiple binary encodings may include a first binary encoding when the stuck bit is in the address field, a second binary encoding when the stuck bit is in the state field, and a third binary encoding when the stuck bit is in the error-correction field. The new state information may also further be selected based on the value of the stuck bit, e.g., a state bit corresponding to the stuck bit is assigned a bit value from the new state information which matches the value of the stuck bit. | 12-04-2008 |
| 20080307137 | DATA PROCESSING SYSTEM, METHOD AND INTERCONNECT FABRIC FOR SYNCHRONIZED COMMUNICATION IN A DATA PROCESSING SYSTEM - A data processing system includes a plurality of processing units, including at least a local master and a local hub, which are coupled for communication via a communication link. The local master includes a master capable of initiating an operation, a snooper capable of receiving an operation, and interconnect logic coupled to a communication link coupling the local master to the local hub. The interconnect logic includes request logic that synchronizes internal transmission of a request of the master to the snooper with transmission, via the communication link, of the request to the local hub. | 12-11-2008 |
| 20090006766 | DATA PROCESSING SYSTEM AND METHOD FOR PREDICTIVELY SELECTING A SCOPE OF BROADCAST OF AN OPERATION UTILIZING A HISTORY-BASED PREDICTION - According to a method of data processing, a predictor is maintained that indicates a historical scope of broadcast for one or more previous operations transmitted on an interconnect of a data processing system. A scope of broadcast of a subsequent operation is predictively selected by reference to the predictor. | 01-01-2009 |
| 20090198695 | Method and Apparatus for Supporting Distributed Computing Within a Multiprocessor System - A locking mechanism for supporting distributed computing within a multiprocessor system is disclosed. A lock control section and a stage control section are assigned to a data block within a system memory. In response to a request for accessing the data block by a processing unit, a determination is made by a memory controller whether or not the lock control section of the data block has been set. If the lock control section of the data block has been set, the access request is denied. Otherwise, if the lock control section of the data block has not been set, another determination is made whether or not a current processing stage of the requesting processing unit matches a processing stage indicated by the stage control section. If the current processing stage of the requesting processing unit does not match the processing stage indicated by the stage control section, the access request is denied; otherwise, the access request is allowed. | 08-06-2009 |
| 20090198849 | Memory Lock Mechanism for a Multiprocessor System - A memory lock mechanism within a multi-processor system is disclosed. A lock control section is initially assigned to a data block within a system memory of the multiprocessor system. In response to a request for accessing the data block by a processing unit within the multiprocessor system, a determination is made by a memory controller whether or not the lock control section of the data block has been set. If the lock control section of the data block has been set, the request for accessing the data block is denied. Otherwise, if the lock control section of the data block has not been set, the lock control section of the data block is set, and the request for accessing the data block is allowed. | 08-06-2009 |
| 20090198865 | DATA PROCESSING SYSTEM, PROCESSOR AND METHOD THAT PERFORM A PARTIAL CACHE LINE STORAGE-MODIFYING OPERATION BASED UPON A HINT - In at least one embodiment, a method of data processing in a data processing system having a memory hierarchy includes a processor core executing a storage-modifying memory access instruction to determine a memory address. The processor core transmits to a cache memory within the memory hierarchy a storage-modifying memory access request including the memory address, an indication of a memory access type, and, if present, a partial cache line hint signaling access to less than all granules of a target cache line of data associated with the memory address. In response to the storage-modifying memory access request, the cache memory performs a storage-modifying access to all granules of the target cache line of data if the partial cache line hint is not present and performs a storage-modifying access to less than all granules of the target cache line of data if the partial cache line hint is present. | 08-06-2009 |
| 20090198916 | Method and Apparatus for Supporting Low-Overhead Memory Locks Within a Multiprocessor System - A method for supporting low-overhead memory locks within a multi-processor system is disclosed. A lock control section is initially assigned to a data block within a system memory of the multiprocessor system. In response to a request for accessing the data block by a processing unit within the multiprocessor system, a determination is made by a memory controller whether or not the lock control section of the data block has been set. If the lock control section of the data block has been set, the request for accessing the data block is ignored. Otherwise, if the lock control section of the data block has not been set, the lock control section of the data block is set, and the request for accessing the data block is allowed. | 08-06-2009 |
| 20090198920 | Processing Units Within a Multiprocessor System Adapted to Support Memory Locks - A processing unit within a multiprocessor system adapted to support memory locks is disclosed. In response to a request for accessing a data block being denied when a lock control section of the data block has been set by a memory controller, a timer countdown is started within a processing unit within a multiprocessor system. The requesting processing unit can relinquish the access request once the timer countdown has reached a timeout period. | 08-06-2009 |
| 20090198933 | Method and Apparatus for Handling Multiple Memory Requests Within a Multiprocessor System - A method for handling multiple memory requests within a multi-processor system is disclosed. A lock control section is initially assigned to a data block within a system memory. In response to a request for accessing the data block by a processing unit, a determination is made whether or not the lock control section of the data block has been set. If the lock control section has been set, another determination is made whether or not the requesting processing unit is located beyond a predetermined distance from a memory controller. If the requesting processing unit is located beyond a predetermined distance from the memory controller, the requesting processing unit is invited to perform other functions; otherwise, the number of the requesting processing unit is placed in a queue table. However, if the lock control section has not been set, the lock control section of the data block is set, and the access request is allowed. | 08-06-2009 |
| 20090198971 | Heterogeneous Processing Elements - A heterogeneous processing element model is provided where I/O devices look and act like processors. In order to be treated like a processor, an I/O processing element, or other special purpose processing element, must follow some rules and have some characteristics of a processor, such as address translation, security, interrupt handling, and exception processing, for example. The heterogeneous processing element model puts special purpose processing elements on the same playing field as processors, from a programming perspective, operating system perspective, power perspective, as the processors. The operating system can get work to a security engine, for example, in the same way it does to a processor. | 08-06-2009 |
| 20100023695 | Victim Cache Replacement - A data processing system includes a processor core having an associated upper level cache and a lower level victim cache. In response to a memory access request of the processor core, the lower level cache victim determines whether the memory access request hits or misses in the directory of the lower level victim cache, and the upper level cache determines whether a castout from the upper level cache is to be performed and selects a victim coherency granule for eviction from the upper level cache. In response to determining that a castout from the upper level cache is to be performed, the upper level cache evicts the selected victim coherency granule. In the eviction, the upper level cache reads out the victim coherency granule from the data array of the upper level cache only in response to an indication that the memory access request misses in the directory of the lower level victim cache. | 01-28-2010 |
| 20100100682 | Victim Cache Replacement - A data processing system includes a processor core having an associated upper level cache and a lower level victim cache. In response to a memory access request of the processor core that specifies a non-modifying access to a target coherency granule, a determination is made whether the memory access request hits or misses in a directory of the lower level victim cache. In response to determining that the memory access request hits in the lower level victim cache in a data-valid coherence state, the lower level victim cache provides the target coherency granule of the memory access request to the upper level cache. The lower level victim cache preserves the target coherency granule in the lower level victim cache in a shared coherence state if the memory access request is of a first type and invalidates the target coherency granule if the memory access request is of a second type. | 04-22-2010 |
| 20100100683 | Victim Cache Prefetching - A processing unit for a multiprocessor data processing system includes a processor core and a cache hierarchy coupled to the processor core to provide low latency data access. The cache hierarchy includes an upper level cache coupled to the processor core and a lower level victim cache coupled to the upper level cache. In response to a prefetch request of the processor core that misses in the upper level cache, the lower level victim cache determines whether the prefetch request misses in the directory of the lower level victim cache and, if so, allocates a state machine in the lower level victim cache that services the prefetch request by issuing the prefetch request to at least one other processing unit of the multiprocessor data processing system. | 04-22-2010 |
| 20100153647 | Cache-To-Cache Cast-In - A data processing system includes a first processing unit and a second processing unit coupled by an interconnect fabric. The first processing unit has a first processor core and associated first upper and first lower level caches, and the second processing unit has a second processor core and associated second upper and lower level caches. In response to a data request, a victim cache line is selected for castout from the first lower level cache. The first processing unit issues on the interconnect fabric a lateral castout (LCO) command that identifies the victim cache line to be castout from the first lower level cache and indicates that a lower level cache is an intended destination. In response to a coherence response indicating success of the LCO command, the victim cache line is removed from the first lower level cache and held in the second lower level cache. | 06-17-2010 |
| 20100153650 | Victim Cache Line Selection - A cache memory includes a cache array including a plurality of congruence classes each containing a plurality of cache lines, where each cache line belongs to one of multiple classes which include at least a first class and a second class. The cache memory also includes a cache directory of the cache array that indicates class membership. The cache memory further includes a cache controller that selects a victim cache line for eviction from a congruence class. If the congruence class contains a cache line belonging to the second class, the cache controller preferentially selects as the victim cache line a cache line of the congruence class belonging to the second class based upon access order. If the congruence class contains no cache line belonging to the second class, the cache controller selects as the victim cache line a cache line belonging to the first class based upon access order. | 06-17-2010 |
| 20100235576 | Handling Castout Cache Lines In A Victim Cache - A victim cache memory includes a cache array, a cache directory of contents of the cache array, and a cache controller that controls operation of the victim cache memory. The cache controller, responsive to receiving a castout command identifying a victim cache line castout from another cache memory, causes the victim cache line to be held in the cache array. If the other cache memory is a higher level cache in the cache hierarchy of the processor core, the cache controller marks the victim cache line in the cache directory so that it is less likely to be evicted by a replacement policy of the victim cache, and otherwise, marks the victim cache line in the cache directory so that it is more likely to be evicted by the replacement policy of the victim cache. | 09-16-2010 |
| 20100235577 | VICTIM CACHE LATERAL CASTOUT TARGETING - A data processing system includes a plurality of processing units coupled by an interconnect fabric. In response to a data request, a victim cache line is selected for castout from a first lower level cache of a first processing unit, and a target lower level cache of one of the plurality of processing units is selected based upon architectural proximity of the target lower level cache to a home system memory to which the address of the victim cache line is assigned. The first processing unit issues on the interconnect fabric a lateral castout (LCO) command that identifies the victim cache line to be castout from the first lower level cache and indicates that the target lower level cache is an intended destination. In response to a coherence response indicating success of the LCO command, the victim cache line is removed from the first lower level cache and held in the second lower level cache. | 09-16-2010 |
| 20100235584 | Lateral Castout (LCO) Of Victim Cache Line In Data-Invalid State - A victim cache line having a data-invalid coherence state is selected for castout from a first lower level cache of a first processing unit. The first processing unit issues on an interconnect fabric a lateral castout (LCO) command identifying the victim cache line to be castout from the first lower level cache, indicating the data-invalid coherence state, and indicating that a lower level cache is an intended destination of the victim cache line. In response to a coherence response to the LCO command indicating success of the LCO command, the victim cache line is removed from the first lower level cache and held in a second lower level cache of a second processing unit in the data-invalid coherence state. | 09-16-2010 |
| 20100262778 | Empirically Based Dynamic Control of Transmission of Victim Cache Lateral Castouts - In response to a data request, a victim cache line is selected for castout from a lower level cache, and a target lower level cache of one of the plurality of processing units is selected. A determination is made whether the selected target lower level cache has provided more than a threshold number of retry responses to lateral castout (LCO) commands of the first lower level cache, and if so, a different target lower level cache is selected. The first processing unit thereafter issues a LCO command on the interconnect fabric. The LCO command identifies the victim cache line to be castout and indicates that the target lower level cache is an intended destination of the victim cache line. In response to a successful coherence response to the LCO command, the victim cache line is removed from the first lower level cache and held in the second lower level cache. | 10-14-2010 |
| 20100262782 | Lateral Castout Target Selection - In response to a data request of a first processing unit among a plurality of processing units, the first processing unit selects a victim cache line to be castout from the lower level cache of the first processing unit and selects the lower level cache of a second of the plurality of processing units as an intended destination of a lateral castout (LCO) command by randomized round-robin selection. The first processing unit issues on the interconnect fabric an LCO command identifying the victim cache line and the intended destination. In response to a coherence response to the LCO command indicating success of the LCO command, the first processing unit removes the victim cache line from its lower level cache, and the victim cache line is held in the lower level cache of one of the plurality of processing units other than the first processing unit. | 10-14-2010 |
| 20100262783 | Mode-Based Castout Destination Selection - In response to a data request of a first of a plurality of processing units, the first processing unit selects a victim cache line to be castout from the lower level cache of the first processing unit and determines whether a mode is set. If not, the first processing unit issues on the interconnect fabric an LCO command identifying the victim cache line and indicating that a lower level cache is the intended destination. If the mode is set, the first processing unit issues a castout command with an alternative intended destination. In response to a coherence response to the LCO command indicating success of the LCO command, the first processing unit removes the victim cache line from its lower level cache, and the victim cache line is held elsewhere in the data processing system. The mode can be set to inhibit castouts to system memory, for example, for testing. | 10-14-2010 |
| 20100262784 | Empirically Based Dynamic Control of Acceptance of Victim Cache Lateral Castouts - A second lower level cache receives an LCO command issued by a first lower level cache on an interconnect fabric. The LCO command indicates an address of a victim cache line to be castout from the first lower level cache and indicates that the second lower level cache is an intended destination of the victim cache line. The second lower level cache determines whether to accept the victim cache line from the first lower level cache based at least in part on the address of the victim cache line indicated by the LCO command. In response to determining not to accept the victim cache line, the second lower level cache provides a coherence response to the LCO command refusing the identified victim cache line. In response to determining to accept the victim cache line, the second lower level cache updates an entry corresponding to the identified victim cache line. | 10-14-2010 |
| 20100262786 | Barriers Processing in a Multiprocessor System Having a Weakly Ordered Storage Architecture Without Broadcast of a Synchronizing Operation - A data processing system employing a weakly ordered storage architecture includes first and second sets of processing units coupled to each other and data storage by an interconnect fabric. Each processing unit has a processor core having an associated cache hierarchy including at least a level one, level two and level three cache memories. In response to a request to perform an update to a portion of a first image of memory contained in the level three cache memory of a first processing unit while at last one kill-type command is pending at the first processing unit, the cache hierarchy of the first processing unit permitting the update to be exposed to any first processor core only after the at least one kill-type command is complete. | 10-14-2010 |
| 20100268884 | Updating Partial Cache Lines in a Data Processing System - A processing unit for a data processing system includes a processor core having one or more execution units for processing instructions and a register file for storing data accessed in processing of the instructions. The processing unit also includes a multi-level cache hierarchy coupled to and supporting the processor core. The multi-level cache hierarchy includes at least one upper level of cache memory having a lower access latency and at least one lower level of cache memory having a higher access latency. The lower level of cache memory, responsive to receipt of a memory access request that hits only a partial cache line in the lower level cache memory, sources the partial cache line to the at least one upper level cache memory to service the memory access request. The at least one upper level cache memory services the memory access request without caching the partial cache line. | 10-21-2010 |
| 20100268885 | SPECIFYING AN ACCESS HINT FOR PREFETCHING LIMITED USE DATA IN A CACHE HIERARCHY - A system and method for specifying an access hint for prefetching limited use data. A processing unit receives a data cache block touch (DCBT) instruction having an access hint indicating to the processing unit that a program executing on the data processing system may soon access a cache block addressed within the DCBT instruction. The access hint is contained in a code point stored in a subfield of the DCBT instruction. In response to detecting that the code point is set to a specific value, the data addressed in the DCBT instruction is prefetched into an entry in the lower level cache. The entry may then be updated as a least recently used entry of a plurality of entries in the lower level cache. In response to a new cache block being fetched to the cache, the prefetched cache block is cast out of the cache. | 10-21-2010 |
| 20100268984 | Delete Of Cache Line With Correctable Error - A processing unit includes a processor core and a cache memory coupled to the processor core. The cache memory includes a data array, a directory of the data array, error detection logic that sequentially detects a first, second and third correctable errors in the data array of the cache memory and provides indications of detection of the first, second and third correctable errors, and control circuitry that, responsive to the indication of the third correctable error and an indication that the first and second correctable errors occurred at too high a frequency, marks an entry of the data array containing a cache line having the third correctable error as deleted in the directory of the cache memory regardless of which entry of the data array contains a cache line having the second correctable error. | 10-21-2010 |
| 20110047352 | MEMORY COHERENCE DIRECTORY SUPPORTING REMOTELY SOURCED REQUESTS OF NODAL SCOPE - A data processing system includes at least a first through third processing nodes coupled by an interconnect fabric. The first processing node includes a master, a plurality of snoopers capable of participating in interconnect operations, and a node interface that receives a request of the master and transmits the request of the master to the second processing unit with a nodal scope of transmission limited to the second processing node. The second processing node includes a node interface having a directory. The node interface of the second processing node permits the request to proceed with the nodal scope of transmission if the directory does not indicate that a target memory block of the request is cached other than in the second processing node and prevents the request from succeeding if the directory indicates that the target memory block of the request is cached other than in the second processing node. | 02-24-2011 |
| 20110153943 | Aggregate Data Processing System Having Multiple Overlapping Synthetic Computers - A first SMP computer has first and second processing units and a first system memory pool, a second SMP computer has third and fourth processing units and a second system memory pool, and a third SMP computer has at least fifth and sixth processing units and third, fourth and fifth system memory pools. The fourth system memory pool is inaccessible to the third, fourth and sixth processing units and accessible to at least the second and fifth processing units, and the fifth system memory pool is inaccessible to the first, second and sixth processing units and accessible to at least the fourth and fifth processing units. A first interconnect couples the second processing unit for load-store coherent, ordered access to the fourth system memory pool, and a second interconnect couples the fourth processing unit for load-store coherent, ordered access to the fifth system memory pool. | 06-23-2011 |
| 20110161587 | PROACTIVE PREFETCH THROTTLING - According to a method of data processing, a memory controller receives a plurality of data prefetch requests from multiple processor cores in the data processing system, where the plurality of prefetch load requests include a data prefetch request issued by a particular processor core among the multiple processor cores. In response to receipt of the data prefetch request, the memory controller provides a coherency response indicating an excess number of data prefetch requests. In response to the coherency response, the particular processor core reduces a rate of issuance of data prefetch requests. | 06-30-2011 |
| 20110161588 | FORMATION OF AN EXCLUSIVE OWNERSHIP COHERENCE STATE IN A LOWER LEVEL CACHE - In response to a memory access request of a processor core that targets a target cache line, the lower level cache of a vertical cache hierarchy associated with the processor core supplies a copy of the target cache line to an upper level cache in the vertical cache hierarchy and retains a copy in a shared coherence state. The upper level cache holds the copy of the target cache line in a private shared ownership coherence state indicating that each cached copy of the target memory block is cached within the vertical cache hierarchy associated with the processor core. In response to the upper level cache signaling replacement of the copy of the target cache line in the private shared ownership coherence state, the lower level cache updates its copy of the target cache line to the exclusive ownership coherence state without coherency messaging with other vertical cache hierarchies. | 06-30-2011 |
| 20110161589 | SELECTIVE CACHE-TO-CACHE LATERAL CASTOUTS - A data processing system includes first and second processing units and a system memory. The first processing unit has first upper and first lower level caches, and the second processing unit has second upper and lower level caches. In response to a data request, a victim cache line to be castout from the first lower level cache is selected, and the first lower level cache selects between performing a lateral castout (LCO) of the victim cache line to the second lower level cache and a castout of the victim cache line to the system memory based upon a confidence indicator associated with the victim cache line. In response to selecting an LCO, the first processing unit issues an LCO command on the interconnect fabric and removes the victim cache line from the first lower level cache, and the second lower level cache holds the victim cache line. | 06-30-2011 |
