CSC/ECE 506 Spring 2011/ch8 mc: Difference between revisions

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programming model in which all processors access the same physical address space. The most common multiprocessors today use [http://en.wikipedia.org/wiki/Symmetric_multiprocessing SMP] architecture which use a common bus as the interconnect.  In the case of multicore processors ("chip multiprocessors," or CMP) the [http://en.wikipedia.org/wiki/Symmetric_multiprocessing SMP] architecture applies to the cores treating them as separate processors. The key problem of shared-memory multiprocessors is providing a consistent view of memory with various cache hierarchies.  This is called '''''cache coherence problem'''''. It is  critical to  achieve correctness and performance-sensitive design point for supporting the shared-memory model. The cache coherence mechanisms not only govern communication in a shared-memory multiprocessor, but also typically determine how the memory system transfers data between processors, caches, and memory.
programming model in which all processors access the same physical address space. The most common multiprocessors today use [http://en.wikipedia.org/wiki/Symmetric_multiprocessing SMP] architecture which use a common bus as the interconnect.  In the case of multicore processors ("chip multiprocessors," or CMP) the [http://en.wikipedia.org/wiki/Symmetric_multiprocessing SMP] architecture applies to the cores treating them as separate processors. The key problem of shared-memory multiprocessors is providing a consistent view of memory with various cache hierarchies.  This is called '''''cache coherence problem'''''. It is  critical to  achieve correctness and performance-sensitive design point for supporting the shared-memory model. The cache coherence mechanisms not only govern communication in a shared-memory multiprocessor, but also typically determine how the memory system transfers data between processors, caches, and memory.


[[Image:Busbased SMP.jpg|frame|center|<b>Figure 1:</b> Typical Cache Model]]
[[Image:Busbased SMP.jpg|frame|center|<b>Figure 1:</b> Typical Bus-Based Processor Model]]
 
 


At any point in logical time, the permissions for a cache block can allow either a single writer or multiple readers. The '''''coherence protocol''''' ensures the invariants of the states are maintained. The different coherent states used by most of the cache coherent protocols are as shown in ''Table 1'':
At any point in logical time, the permissions for a cache block can allow either a single writer or multiple readers. The '''''coherence protocol''''' ensures the invariants of the states are maintained. The different coherent states used by most of the cache coherent protocols are as shown in ''Table 1'':
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<center><b>Table 1:</b> States Used by the Cache Coherent Protocols]]</center>


The first widely adopted approach to cache coherence is snooping on a bus. We will now discuss how some real time machines by '''Intel''' , '''AMD''' and other processors maintain cache coherence using '''''snooping based coherence protocols'''''.  For more information on snooping based protocols refer to Solihin text book Chapter 8.
The first widely adopted approach to cache coherence is snooping on a bus. We will now discuss how some real time machines by '''Intel''', '''AMD''' and other processors maintain cache coherence using '''''snooping based coherence protocols'''''.  For more information on snooping based protocols refer to Solihin text book Chapter 8.
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Revision as of 04:02, 19 March 2011

Introduction to bus-based cache coherence in real machines

Most parallel software in the commercial market relies on the shared-memory programming model in which all processors access the same physical address space. The most common multiprocessors today use SMP architecture which use a common bus as the interconnect. In the case of multicore processors ("chip multiprocessors," or CMP) the SMP architecture applies to the cores treating them as separate processors. The key problem of shared-memory multiprocessors is providing a consistent view of memory with various cache hierarchies. This is called cache coherence problem. It is critical to achieve correctness and performance-sensitive design point for supporting the shared-memory model. The cache coherence mechanisms not only govern communication in a shared-memory multiprocessor, but also typically determine how the memory system transfers data between processors, caches, and memory.

Figure 1: Typical Bus-Based Processor Model

At any point in logical time, the permissions for a cache block can allow either a single writer or multiple readers. The coherence protocol ensures the invariants of the states are maintained. The different coherent states used by most of the cache coherent protocols are as shown in Table 1:

States Access Type Invariant
Modified read, write all other caches in I state
Exclusive read all other caches in I state
Owned read all other caches in I or S state
Shared read no other cache in M or E state
Invalid - -
Table 1: States Used by the Cache Coherent Protocols]]

The first widely adopted approach to cache coherence is snooping on a bus. We will now discuss how some real time machines by Intel, AMD and other processors maintain cache coherence using snooping based coherence protocols. For more information on snooping based protocols refer to Solihin text book Chapter 8.

Cache Coherence in real machines

SGI - Silicon Graphics, Inc

MSI & SGI IRIS 4D Processors

MSI is a three-state write-back invalidation protocol which is one of the earliest snooping-based cache coherence-protocols. It marks the cache line in Modified(M) ,Shared(S) and Invalid(I) state. Invalid means the cache line is either not present or is invalid state. If the cache line is clean and is shared by more than one processor , it is marked shared. If cache line is dirty and the processor has exclusive ownership of the cache line, it is present in Modified state. BusRdx causes others to invalidate (demote) to I state. If it is present in M state in another cache, it will flush. BusRdx even if hit in S state, it is promoted to M (upgrade) state.

The following state transition diagram for MSI protocol explains the working of the protocol:

MSI protocol was first used in SGI IRIS 4D series. SGI produced a broad range of MIPS-based(Microprocessor without Interlocked Pipeline Stages) workstations and servers during the 1990s, running SGI's version of UNIX System V, now called IRIX. The 4D-MP graphics superworkstation brought 40 mips(million instructions per second) of computing performance to a graphics superworkstation. The unprecedented level of computing and graphics processing in an office-environment workstation was made possible by the fastest available Risc microprocessors in a single shared memory multiprocessor design driving a tightly coupled, highly parallel graphics system. Aggregate sustained data rates of over one gigabyte per second were achieved by a hierarchy of buses in a balanced system designed to avoid bottlenecks.

The Multiprocessor bus used in 4D-MP graphics superworkstation is a pipelined, block transfer bus that supports the cache coherence protocol as well as providing 64 megabytes of sustained data bandwidth between the processors, the memory and I/O system, and the graphics subsystem. Because the sync bus provides for efficient synchronization between processors, the cache coherence protocol was designed to support efficient data sharing between processors. If a cache coherence protocol has to support synchronization as well as sharing, a compromise in the efficiency of the data sharing protocol may be necessary to improve the efficiency of the synchronization operations. Hence it uses the simple cache coherence protocol which is the MSI protocol.

With the simple rules of MSI enforced by the hardware protocols of the sync bus and the Multiprocessor bus, efficient synchronization and efficient data sharing are achieved in a simple shared memory model of parallel processing in the 4D-MP graphics superworkstation.

SYNAPSE Multiprocessor

Synapse protocol and Synapse multiprocessor

From the state transition diagram of MSI, we observe that for MSI there is transition to state S from state M when a BusRd is observed for that block. The contents of the block is flushed to the bus before going to S state. It would look more appropriate to move to I state thus giving up the block entirely in certain cases. This choice of moving to S or I reflects the designer's assertion that the original processor is more likely to continue reading the block than the new processor to write to the block. In synapse protocol, used in the early Synapse multiprocessor, made this alternate choice of going directly from M state to I state on a BusRd, assuming the migratory pattern would be more frequent. More details about this protocol can be found in these papers published in late 1980's Coherence protocols: evaluation using a multiprocessor simulation model and Synapse tightly coupled multiprocessors: a new approach to solve old problems

In Synapse protocol M state is called D (Dirty) state. The following is the state transition diagram for Synapse protocol which clearly shows its working.

Intel

MESI & Intel Processors

MSIhas a major drawback in that each read-write sequence incurs 2 bus transactions irrespective of whether the cache line is stored in only one cache or not. This is a huge setback for highly parallel programs that have little data sharing. MESI protocol solves this problem by introducing the Exclusive state to distinguish between a cache line stored in multiple caches and a line stored in a single cache. Let us briefly see how the MESI protocol works. For a more detailed version refer Solihin textbook pg. 215.

MESI coherence protocol marks each cache line in of the Modified, Exclusive, Shared, or Invalid state.

  • Invalid : The cache line is either not present or is invalid
  • Exclusive : The cache line is clean and is owned by this core/processor only
  • Modified : This implies that the cache line is dirty and the core/processor has exclusive ownership of the cache line,exclusive of the memory also.
  • Shared : The cache line is clean and is shared by more than one core/processor

In a nutshell, the MESI protocol works as follows: A line that is fetched, receives E, or S state depending on whether it exists in other processors in the system. A cache line gets the M state when a processor writes to it; if the line is not in E or M-state prior to writing it, the cache sends a Bus Upgrade(BusUpgr) signal or as the Intel manuals term it, “Read-For-Ownership (RFO) request” that ensures that the line exists in the cache and is in the I state in all other processors on the bus (if any). A table is shown below to summarize MESI protocol.


Cache Line State: Modified Exclusive Shared Invalid
This cache line is valid? Yes Yes Yes No
The memory copy is… out of date valid valid -
No No Maybe Maybe
does not go to bus does not go to bus goes to bus and updates cache goes directly to bus


The transition diagram from the lecture slides is given below for reference.


The Pentium Pro microprocessor, introduced in 1992 was the first Intel architecture microprocessor to support symmetric multiprocessing(SMP) in various multiprocessor configurations. SMP and MESI protocol was the architecture used consistently until the introduction of the 45-nm Hi-k Core micro-architecture in Intel's (Nehalem-EP) quad-core x86-64. The 45-nm Hi-k Intel Core microarchitecture utilizes a new system of framework called the QuickPath Interconnect which uses point-to-point interconnection technology based on distributed shared memory architecture. It uses a modified version of MESI protocol called MESIF, by introducing an additional state, F, the forward state.

The Intel architecture uses the MESI protocol as the basis to ensure cache coherence, which is true whether you're on one of the older processors that use a common bus to communicate or using the new Intel QuickPath point-to-point interconnection technology.

Let us now walk through a briefing on the MESIF protocl:

The MESIF protocol, used in the latest Intel multi-core processors was introduced to accommodate the point-to-point links used in the QuickPath Interconnect. Using the MESI protocol in this architecture would send many redundant messages between different processors, often with unnecessarily high latency. For example, when a processor requests a cache line that is stored in multiple locations, every location might respond with the data. As the the requesting processor only needs a single copy of the data, the system would be wasting the bandwidth. As a solution to this problem, an additional state, Forward state, was added by slightly changing the role of the Shared state. Whenever there is a read request, only the cache line in the F state will respond to the request, while all the S state caches remain dormant. Hence, by designating a single cache line to respond to requests, coherency traffic is substantially reduced when multiple copies of the data exist. Also, on a read request, the F state transitions from F to S state. That is, when a cache line in the F state is copied, the F state migrates to the newer copy, while the older one drops back to S. Moving the new copy to the F state exploits both temporal and spatial locality. Because the newest copy of the cache line is always in the F state, it is very unlikely that the line in the F state will be evicted from the caches. This takes advantage of the temporal locality of the request. The second advantage is that if a particular cache line is in high demand due to spatial locality, the bandwidth used to transmit that data will be spread across several nodes. All M to S state transition and E to S state transitions will now be from M to F and E to F. The F state is different from the Owned state of the MOESI protocol as it is not a unique copy because a valid copy is stored in memory. Thus, unlike the Owned state of the MOESI protocol, in which the data in the O state is the only valid copy of the data, the data in the F state can be evicted or converted to the S state, if desired.

More information on the QuickPath Interconnect and MESIF protocol can be found at Introduction to QuickPath Interconnect

CMP Implementation in Intel Architecture

Let us now see how Intel architecture using the MESI protocol progressed from a uniprocessor architecture to a Chip MultiProcessor(CMP) using the bus as the interconnect.


Uniprocessor Architecture

The diagram below shows the structure of the memory cluster in Intel Pentium M processor.



In this structure we have,

  • A unified on-chip L1 cache with the processor/core,
  • A Memory/L2 access control unit, through which all the accesses to the L2 cache, main memory and IO space are made,
  • The second level L2 cache along with the prefetch unit and
  • Front side bus (FSB), a single shared bi-directional bus through which all the traffic is sent across.These wide buses bring in multiple data bytes at a time.

As Intel explains it, using this structure, the processor requests were first sought in the L2 cache and only on a miss, were they forwarded to the main memory via the front side bus (FSB). The Memory/L2 access control unit served as a central point for maintaining coherence within the core and with the external world. It contains a snoop control unit that receives snoop requests from the bus and performs the required operations on each cache (and internal buffers) in parallel. It also handles RFO requests (BusUpgr) and ensures the operation continues only after it guarantees that no other version on the cache line exists in any other cache in the system.


CMP Architecture

For CMP implementation, Intel chose the bus-based architecture using snoopy protocols vs the directory protocol because though directory protocol reduces the active power due to reduced snoop activity, it increased the design complexity and the static power due to larger tag arrays. Since Intel has a large market for the processors in the mobility family, directory-based solution was less favorable since battery life mainly depends on static power consumption and less on dynamic power. Let us examine how CMP was implemented in Intel Core Duo, which was one of the first dual-core processor for the budget/entry-level market. The general CMP implementation structure of the Intel Core Duo is shown below


This structure has the following changes when compared to the uniprocessor memory cluster structure.

  • L1 cache and the processor/core structure is duplicated to give 2 cores.
  • The Memory/L2 access control unit is split into 2 logical units: L2 controller and bus controller. The L2 controller handles all requests to the L2 cache from the core and the snoop requests from the FSB. The bus controller handles data and I/O requests to and from the FSB.
  • The prefetching unit is extended to handle the hardware prefetches for each core separately.
  • A new logical unit (represented by the hexagon) was added to maintain fairness between the requests coming from the different cores and hence balance the requests to L2 and memory.

This new partitioned structure for the memory/L2 access control unit enhanced the performance while reducing power consumption. For more information on uniprocessor and multiprocessor implementation under the Intel architecture, refer to CMP Implementation in Intel Core Duo Processors

The Intel bus architecture has been evolving in order to accommodate the demands of scalability while using the same MESI protocol; From using a single shared bus to dual independent buses (DIB) doubling the available bandwidth and to the logical conclusion of DIB with the introduction of dedicated high-speed interconnects (DHSI). The DHSI-based platforms use four FSBs, one for each processor in the platform. In both DIB and DHSI, the snoop filter was used in the chipset to cache snoop information, thereby significantly reducing the broadcasting needed for the snoop traffic on the buses. With the production of processors based on next generation 45-nm Hi-k Intel Core microarchitecture, the Intel Xeon processor fabric will transition from a DHSI, with the memory controller in the chipset, to a distributed shared memory architecture using Intel QuickPath Interconnects using MESIF protocol.

AMD - Advanced Micro Devices Processors

MOESI & AMD Processors


AMD Opteron was the AMD’s first-generation dual core which had 2 distinct K8 cores together on a single die. Cache coherence produces bigger problems on such multiprocessors. It was necessary to use an appropriate coherence protocol to address this problem. The Intel Xeon, which was the competitive counterpart from Intel to AMD dual core Opteron , used the MESI protocol to handle cache coherence. MESI came with the drawback of using much time and bandwidth in certain situations.

MOESI was the AMD’s answer to this problem . MOESI added a fifth state to MESI protocol called “Owned” . MOESI addresses the bandwidth problem faced in MESI protocol when processor having invalid data in its cache wants to modify the data. The processor seeking the data access will have to wait for the processor which modified this data to write back to the main memory, which takes time and bandwidth. This drawback is removed in MOESI by allowing dirty sharing. When the data is held by a processor in the new state “Owned”, it can provide other processors the modified data without or even before writing it to the main memory. This is called dirty sharing. The processor with the data in "Owned" stays responsible to update the main memory later when the cache line is evicted.

MOESI' has become one of the most popular snoop-based protocols supported in the AMD64 architecture. The AMD dual-core Opteron can maintain cache coherence in systems up to 8 processors using this protocol.

The five different states of MOESI protocol are:

  • Modified (M) : The most recent copy of the data is present in the cache line. But it is not present in any other processor cache.
  • Owned (O)  : The cache line has the most recent correct copy of the data . This can be shared by other processors. The processor in this state for this cache line is responsible to update the correct value in the main memory before it gets evicted.
  • Exclusive (E) : A cache line holds the most recent, correct copy of the data, which is exclusively present on this processor and a copy is present in the main memory.
  • Shared (S) : A cache line in the shared state holds the most recent, correct copy of the data, which may be shared by other processors.
  • Invalid (I) : A cache line does not hold a valid copy of the data.

A detailed explanation of this protocol implementation on AMD processor can be found in the manual Architecture of the AMD 64-bit core

The following table summarizes the MOESI protocol:


Cache Line State: Modified Owner Exclusive Shared Invalid
This cache line is valid? Yes Yes Yes Yes No
The memory copy is… out of date out of date valid valid -
Copies exist in caches of other processors? No No Yes(out of date values) Maybe Maybe
A write to this line does not go to bus does not go to bus does not go to bus goes to bus and updates cache goes directly to bus


State transition for MOESIis as shown below :


MOESIState transition Diagram



AMD Opteron memory Architecture



The AMD processor’s high-performance cache architecture includes an integrated, 64-bit, dual-ported 128-Kbyte split-L1 cache with separate snoop port, multi-level translation lookaside buffers (TLBs), a scalable L2 cache controller with a 72-bit (64-bit data + 8-bit ECC) interface to as much as 8-Mbyte of industry-standard SDR or DDR SRAMs, and an integrated tag for the most cost-effective 512-Kbyte L2 configurations. The AMD Athlon processor’s integrated L1 cache comprises two separate 64-Kbyte, two-way set-associative data and instruction caches.

More information about this can be found in AMD 64 bit Architecture Programmers's Manual

Special Coherence Considerations in AMD64 architectures


Instruction prefetching is a technique used to speedup the execution of the program. But in multiprocessors, prefetching comes at the cost of performance. Due to prefetching, the data can be modified in such a way that the memory coherence protocol will not be able to handle the effects. In such situations software must use serializing instructions or cache-invalidation instructions to guarantee subsequent data accesses are coherent.
An example of this type of a situation is a page-table update followed by accesses to the physical pages referenced by the updated page tables. The physical-memory references for the page tables are different than the physical-memory references for the data. Because of prefetching there maybe problem with correctness. The following sequence of events shows such a situation when software changes the translation of virtual-page A from physical-page M to physical-page N:

  1. The tables that translate virtual-page A to physical-page M are now held only in main memory. The copies in the cache ae invalidated.
  2. Page-table entry is changed by the software for virtual-page A in main memory to point to physical page N rather than physical-page M.
  3. Data in virtual-page A is accessed.

Software expects the processor to access the data from physical-page N after the update. However, it is possible for the processor to prefetch the data from physical-page M before the page table for virtual page A is updated. Because the physical-memory references are different, the processor does not recognize them as requiring coherence checking and believes it is safe to prefetch the data from virtual-page A, which is translated into a read from physical page M. Similar behavior can occur when instructions are prefetched from beyond the page table update instruction.

In order to prevent errors from occuring, there are special instructions provided by software like INVLPG or MOV CR3 instruction which is executed immediately after the page-table update to ensure that subsequent instruction fetches and data accesses use the correct virtual-page-to-physical-page translation. It is not necessary to perform a TLB invalidation operation preceding the table update.

More information can be found about this in AMD64 Architecture Programmer's manual

Optimization techniques on MOESI when implemented on AMD Phenom processors


In real machines, using some optimization techniques on the standard cache coherence protocol used , improves the performance of the machine. For example AMD Phenom family of microprocessors (Family 0×10) which is AMD’s first generation to incorporate 4 distinct cores on a single die, and the first to have a cache that all the cores share, uses the MOESI protocol with some optimization techniques incorporated.

It focuses on a small subset of compute problems which behave like Producer and Consumer programs. In such a computing problem, a thread of a program running on a single core produces data, which is consumed by a thread that is running on a separate core. With such programs, it is desirable to get the two distinct cores to communicate through the shared cache, to avoid round trips to/from main memory. The MOESI protocol that the AMD Phenom cache uses for cache coherence can also limit bandwidth. Hence by keeping the cache line in the ‘M’ state for such computing problems, we can achieve better performance.

When the producer thread , writes a new entry, it allocates cache-lines in the modified (M) state. Eventually, these M-marked cache lines will start to fill the L3 cache. When the consumer reads the cache line, the MOESI protocol changes the state of the cache line to owned (O) in the L3 cache and pulls down a shared (S) copy for its own use. Now, the producer thread circles the ring buffer to arrive back to the same cache line it had previously written. However, when the producer attempts to write new data to the owned (marked ‘O’) cache line, it finds that it cannot, since a cache line marked ‘O’ by the previous consumer read does not have sufficient permission for a write request (in the MOESI). To maintain coherence, the memory controller must initiate probes in the other caches (to handle any other S copies that may exist). This will slow down the process.

Thus, it is preferable to keep the cache line in the ‘M’ state in the L3 cache. In such a situation, when the producer comes back around the ring buffer, it finds the previously written cache line still marked ‘M’, to which it is safe to write without coherence concerns. Thus better performance can be achieved by such optimization techniques to standard protocols when implemented in real machines.

You can find more information on how this is implemented and various other ways of optimizations in this manual Software Optimization guide for AMD 10h Processors


Xerox Corporation

Dragon Protocol & Xerox Dragon Processors

The Dragon Protocol is an update based coherence protocol which does not invalidate other cached copies like what we have seen in the coherence protocols so far. Write propagation is achieved by updating the cached copies instead of invalidating them. But the Dragon Protocol does not update memory on a cache to cache transfer and delays the memory and cache consistency until the data is evicted and written back, which saves time and lowers the memory access requirements. Moreover only the written byte or the word is communicated to the other caches instead of the whole block which further reduces the bandwidth usage. It has the ability to detect dynamically, the sharing status of a block and use a write through policy for shared blocks and write back for currently non-shared blocks. The Dragon Protocol employs the following four states for the cache blocks: Shared Clean, Shared Modified, Exclusive and Modified.

  • Modified(M) and Exclusive(E) - these states have the same meaning as explained in the protocols above.
  • Shared Modified (Sm) - Only one cache line in the system can be in the Shared Modified state. Potentially two or more caches have this block and memory may or may not be up to date and this processor's cache had modified the block.
  • Shared Clean (Sc) - Potentially two or more caches have this block and memory may or may not be up to date(if no other cache has it in Sm state, memory will be up to date else it is not).

When a Shared Modified line is evicted from the cache on a cache miss only then is the block written back to the main memory in order to keep memory consistent. For more information on Dragon protocol, refer to Solihin textbook, page number 229. The state transition diagram has been given below for reference.

]]


The Dragon Protocol , was developed by Xerox Palo Alto Research Center(Xerox PARC), a subsidiary of Xerox Corporation. This protocol was used in the Xerox PARC Dragon multiprocessor workstation, a VLSI research computer that could support multiple processors on a central high bandwidth memory bus. The Dragon design implemented snoopy caches that provided the appearance of a uniform memory space to multiple processors. Here, each cache listens to 2 buses: the processor bus and the memory bus. The caches are also responsible for address translation, so the processor bus carries virtual addresses and the memory bus carries physical addresses. The Dragon system was designed to support 4 to 8 Dragon processors. The memory bus used in the Xeron Dragon evolved to become the XDBus , a low-cost, synchronous, packet-switched VLSI bus designed for use in high-performance multiprocessors. This was used as the interconnect in many multiprocessor server systems like Cray Superserver 6400, Sun Microsystems' SPARCcenter 2000 and SPARCserver 1000 and Sun4d systems.

References

  1. Cache coherence
  2. Introduction to QuickPath Interconnect
  3. CMP Implementation in Intel Core Duo Processors
  4. Common System Interface in Intel Processors
  5. Cache consistency with MESI on Intel processor
  6. AMD dual core Architecture
  7. AMD64 Architecture Programmer's manual
  8. Software Optimization guide for AMD 10h Processors
  9. Architecture of AMD 64 bit core
  10. Silicon Graphics Computer Systems
  11. Parallel computer architecture: a hardware/software approach By David E. Culler, Jaswinder Pal Singh, Anoop Gupta
  12. Three state invalidation protocols
  13. Synapse tightly coupled multiprocessors: a new approach to solve old problems
  14. Coherence protocols: evaluation using a multiprocessor simulation model
  15. Dragon Protocol
  16. Xerox Dragon
  17. Coherence Protocols
  18. XDBus