MSI protocol

In computing, the MSI protocol - a basic cache-coherence protocol - operates in multiprocessor systems. As with other cache coherency protocols, the letters of the protocol name identify the possible states in which a cache line can be.

Overview

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In MSI, each block contained inside a cache can have one of three possible states:

  • Modified: The block has been modified in the cache. The data in the cache is then inconsistent with the backing store (e.g. memory). A cache with a block in the "M" state has the responsibility to write the block to the backing store when it is evicted.
  • Shared: This block is unmodified and exists in read-only state in at least one cache. The cache can evict the data without writing it to the backing store.
  • Invalid: This block is either not present in the current cache or has been invalidated by a bus request, and must be fetched from memory or another cache if the block is to be stored in this cache.[1]

These coherency states are maintained through communication between the caches and the backing store. The caches have different responsibilities when blocks are read or written, or when they learn of other caches issuing reads or writes for a block.

When a read request arrives at a cache for a block in the "M" or "S" states, the cache supplies the data. If the block is not in the cache (in the "I" state), it must verify that the block is not in the "M" state in any other cache. Different caching architectures handle this differently. For example, bus architectures often perform snooping, where the read request is broadcast to all of the caches. Other architectures include cache directories which have agents (directories) that know which caches last had copies of a particular cache block. If another cache has the block in the "M" state, it must write back the data to the backing store and go to the "S" or "I" states. Once any "M" line is written back, the cache obtains the block from either the backing store, or another cache with the data in the "S" state. The cache can then supply the data to the requester. After supplying the data, the cache block is in the "S" state.

When a write request arrives at a cache for a block in the "M" state, the cache modifies the data locally. If the block is in the "S" state, the cache must notify any other caches that might contain the block in the "S" state that they must evict the block. This notification may be via bus snooping or a directory, as described above. Then the data may be locally modified. If the block is in the "I" state, the cache must notify any other caches that might contain the block in the "S" or "M" states that they must evict the block. If the block is in another cache in the "M" state, that cache must either write the data to the backing store or supply it to the requesting cache. If at this point the cache does not yet have the block locally, the block is read from the backing store before being modified in the cache. After the data is modified, the cache block is in the "M" state.

For any given pair of caches, the permitted states of a given cache line are as follows:

 M   S   I 
 M  Red XN Red XN Green tickY
 S  Red XN Green tickY Green tickY
 I  Green tickY Green tickY Green tickY

State Machine

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State diagram of processor requests for the MSI protocol

Processor requests to the cache include:

  • PrRd: Processor request to read a cache block.
  • PrWr: Processor request to write a cache block.
State diagram of bus transactions for the MSI protocol

In addition, there are bus side requests. These include:

  • BusRd: When a read miss occurs in a processor's cache, it sends a BusRd request on the bus and expects to receive the cache block in return.
  • BusRdX: When a write miss occurs in a processor's cache, it sends a BusRdX request on the bus which returns the cache block and invalidates the block in the caches of other processors.
  • BusUpgr: When there's a write hit in a processor's cache, it sends a BusUpgr request on the bus to invalidate the block in the caches of other processors.
  • Flush: Request that indicates that a whole cache block is being written back to the memory.[2]

State Transitions:

  • Invalid:
    • On a PrRd, BusRd is issued and state changes to Shared.
    • On a PrWr, BusRdX is issued and state changes to Modified.
    • On a BusRd, BusRdX or a BusUpgr an invalid block remains Invalid.
  • Shared:
    • On a PrRd, the block remains in the Shared state.
    • On a PrWr, BusUpgr is issued and state changes to Modified.
    • On a BusRd, the block remains in the Shared state.
    • On a BusRdX or BusUpgr, the block transitions to Invalid.
  • Modified:
    • On a PrRd or PrWr, the block remains in the Modified state.
    • On a BusRd, the cache block is flushed onto the bus and state changes to Shared.
    • On a BusRdX, the cache block is flushed onto the bus and state changes to Invalid.[2]
    • A BusUpgr is not possible. Note that by being in the Modified state in one particular processor, a cache block has to be in the Invalid state in all other processor(s), as the Modified state is allowed in either none or only one processor. This effectively negates the possibility of a BusUpgr on the bus, which would require this block to be in the Shared state in one of the processor(s) that, as seen above, issues a PrWr.

Usage

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This protocol is similar to the one used in the SGI 4D machine.[3]

Variants

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Modern systems use variants of the MSI protocol to reduce the amount of traffic in the coherency interconnect. The MESI protocol adds an "Exclusive" state to reduce the traffic caused by writes of blocks that only exist in one cache. The MOSI protocol adds an "Owned" state to reduce the traffic caused by write-backs of blocks that are read by other caches. The MOESI protocol does both of these things.

See also

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References

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  1. ^ Fuchsen, R. (2010-10-01). "How to address certification for multi-core based IMA platforms: Current status and potential solutions". 29th Digital Avionics Systems Conference. pp. 5.E.3–1-5.E.3-11. doi:10.1109/DASC.2010.5655461. ISBN 978-1-4244-6616-0. S2CID 16461614.
  2. ^ a b Solihin, Yan (2016). Fundamentals of Parallel Multicore Architecture. Chapman & Hall/CRC Computational Science Series.
  3. ^ Suh, Taeweon (December 2006). "INTEGRATION AND EVALUATION OF CACHE COHERENCE PROTOCOLS FOR MULTIPROCESSOR SOCS" (PDF).