Difference between revisions of "Memory System"
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− | M5's new memory system was | + | M5's new memory system (introduced in the first 2.0 beta release) was designed with the following goals: |
− | # | + | # Unify timing and functional accesses in timing mode. With the old memory system the timing accesses did not have data and just accounted for the time it would take to do an operation. Then a separate functional access actually made the operation visible to the system. This method was confusing, it allowed simulated components to accidentally cheat, and prevented the memory system from returning timing-dependent values, which isn't reasonable for an execute-in-execute CPU model. |
# Simplify the memory system code -- remove the huge amount of templating and duplicate code. | # Simplify the memory system code -- remove the huge amount of templating and duplicate code. | ||
− | # Make changes easier | + | # Make changes easier, specifically to allow other memory interconnects besides a shared bus. |
− | ===MemObjects=== | + | For details on the new coherence protocol, introduced (along with a substantial cache model rewrite) in 2.0b4, see [[Coherence Protocol]]. |
− | All objects that connect to the memory system inherit from <code>MemObject</code>. This class adds the pure virtual | + | |
+ | === MemObjects === | ||
+ | |||
+ | All objects that connect to the memory system inherit from <code>MemObject</code>. This class adds the pure virtual functions <code>getMasterPort(const std::string &name, PortID idx)</code> and <code>getSlavePort(const std::string &name, PortID idx)</code> which returns a port corresponding to the given name and index. This interface is used to structurally connect the MemObjects together. | ||
+ | |||
+ | ===Ports=== | ||
+ | The next large part of the memory system is the idea of ports. Ports are used to interface memory objects to each other. They will always come in pairs, with a MasterPort and a SlavePort, and we refer to the other port object as the peer. These are used to make the design more modular. With ports a specific interface between every type of object doesn't have to be created. Every memory object has to have at least one port to be useful. A master module, such as a CPU, has one or more MasterPort instances. A slave module, such as a memory controller, has one or more SlavePorts. An interconnect component, such as a cache, bridge or bus, has both MasterPort and SlavePort instances. | ||
+ | |||
+ | There are two groups of functions in the port object. The <code>send*</code> functions are called on the port by the object that owns that port. For example to send a packet in the memory system a CPU would call <code>myPort->sendTimingReq(pkt)</code> to send a packet. Each send function has a corresponding recv function that is called on the ports peer. So the implementation of the <code>sendTimingReq()</code> call above would simply be <code> peer->recvTimingReq(pkt)</code> on the slave port. Using this method we only have one virtual function call penalty but keep generic ports that can connect together any memory system objects. | ||
+ | |||
+ | Master ports can send requests and receive responses, whereas slave ports receive requests and send responses. Due to the coherence protocol, a slave port can also send snoop requests and receive snoop responses, with the master port having the mirrored interface. | ||
+ | |||
+ | ===Connections=== | ||
+ | |||
+ | In Python, Ports are first-class attributes of simulation objects, much like Params. Two objects can specify that their ports should be connected using the assignment operator. Unlike a normal variable or parameter assignment, port connections are symmetric: <code>A.port1 = B.port2</code> has the same meaning as <code>B.port2 = A.port1</code>. The notion of master and slave ports exists in the Python objects as well, and a check is done when the ports are connected together. | ||
+ | |||
+ | Objects such as busses that have a potentially unlimited number of ports use "vector ports". An assignment to a vector port appends the peer to a list of connections rather than overwriting a previous connection. | ||
+ | |||
+ | In C++, memory ports are connected together by the python code after all objects are instantiated. | ||
=== Request === | === Request === | ||
− | A request | + | A request object encapsulates the original request issued by a CPU or I/O device. The parameters of this request are persistent throughout the transaction, so a request object's fields are intended to be written at most once for a given request. There are a handful of constructors and update methods that allow subsets of the object's fields to be written at different times (or not at all). Read access to all request fields is provided via accessor methods which verify that the data in the field being read is valid. |
+ | |||
+ | The fields in the request object are typically not available to devices in a real system, so they should normally be used only for statistics or debugging and not as architectural values. | ||
− | + | Request object fields include: | |
− | * | + | * Virtual address. This field may be invalid if the request was issued directly on a physical address (e.g., by a DMA I/O device). |
− | * | + | * Physical address. |
− | * | + | * Data size. |
− | * | + | * Time the request was created. |
− | * The | + | * The ID of the CPU/thread that caused this request. May be invalid if the request was not issued by a CPU (e.g., a device access or a cache writeback). |
− | * The | + | * The PC that caused this request. Also may be invalid if the request was not issued by a CPU. |
=== Packet === | === Packet === | ||
A Packet is used to encapsulate a transfer between two objects in the memory system (e.g., the L1 and L2 cache). This is in contrast to a Request where a single Request travels all the way from the requester to the ultimate destination and back, possibly being conveyed by several different Packets along the way. | A Packet is used to encapsulate a transfer between two objects in the memory system (e.g., the L1 and L2 cache). This is in contrast to a Request where a single Request travels all the way from the requester to the ultimate destination and back, possibly being conveyed by several different Packets along the way. | ||
+ | |||
+ | Read access to many packet fields is provided via accessor methods which verify that the data in the field being read is valid. | ||
A packet contains the following all of which are accessed by accessors to be certain the data is valid: | A packet contains the following all of which are accessed by accessors to be certain the data is valid: | ||
− | * | + | * The address. This is the address that will be used to route the packet to its target (if the destination is not explicitly set) and to process the packet at the target. It is typically derived from the request object's physical address, but may be derived from the virtual address in some situations (e.g., for accessing a fully virtual cache before address translation has been performed). It may not be identical to the original request address: for example, on a cache miss, the packet address may be the address of the block to fetch and not the request address. |
− | * | + | * The size. Again, this size may not be the same as that of the original request, as in the cache miss scenario. |
* A pointer to the data being manipulated. | * A pointer to the data being manipulated. | ||
** Set by <code>dataStatic()</code>, <code>dataDynamic()</code>, and <code>dataDynamicArray()</code> which control if the data associated with the packet is freed when the packet is, not, with <code>delete</code>, and with <code>delete []</code> respectively. | ** Set by <code>dataStatic()</code>, <code>dataDynamic()</code>, and <code>dataDynamicArray()</code> which control if the data associated with the packet is freed when the packet is, not, with <code>delete</code>, and with <code>delete []</code> respectively. | ||
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* A status indicating Success, BadAddress, Not Acknowleged, and Unknown. | * A status indicating Success, BadAddress, Not Acknowleged, and Unknown. | ||
* A list of command attributes associated with the packet | * A list of command attributes associated with the packet | ||
+ | **Note: There is some overlap in the data in the status field and the command attributes. This is largely so that a packet an be easily reinitialized when nacked or easily reused with atomic or functional accesses. | ||
* A <code>SenderState</code> pointer which is a virtual base opaque structure used to hold state associated with the packet but specific to the sending device (e.g., an MSHR). A pointer to this state is returned in the packet's response so that the sender can quickly look up the state needed to process it. A specific subclass would be derived from this to carry state specific to a particular sending device. | * A <code>SenderState</code> pointer which is a virtual base opaque structure used to hold state associated with the packet but specific to the sending device (e.g., an MSHR). A pointer to this state is returned in the packet's response so that the sender can quickly look up the state needed to process it. A specific subclass would be derived from this to carry state specific to a particular sending device. | ||
* A <code>CoherenceState</code> pointer which is a virtual base opaque structure used to hold coherence-related state. A specific subclass would be derived from this to carry state specific to a particular coherence protocol. | * A <code>CoherenceState</code> pointer which is a virtual base opaque structure used to hold coherence-related state. A specific subclass would be derived from this to carry state specific to a particular coherence protocol. | ||
* A pointer to the request. | * A pointer to the request. | ||
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=== Access Types=== | === Access Types=== | ||
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# '''Timing''' - Timing accesses are the most detailed access. They reflect our best effort for realistic timing and include the modeling of queuing delay and resource contention. Once a timing request is successfully sent at some point in the future the device that sent the request will either get the response or a NACK if the request could not be completed (more below). Timing and Atomic accesses can not coexist in the memory system. | # '''Timing''' - Timing accesses are the most detailed access. They reflect our best effort for realistic timing and include the modeling of queuing delay and resource contention. Once a timing request is successfully sent at some point in the future the device that sent the request will either get the response or a NACK if the request could not be completed (more below). Timing and Atomic accesses can not coexist in the memory system. | ||
# '''Atomic''' - Atomic accesses are a faster than detailed access. They are used for fast forwarding and warming up caches and return an approximate time to complete the request without any resource contention or queuing delay. When a atomic access is sent the response is provided when the function returns. Atomic and timing accesses can not coexist in the memory system. | # '''Atomic''' - Atomic accesses are a faster than detailed access. They are used for fast forwarding and warming up caches and return an approximate time to complete the request without any resource contention or queuing delay. When a atomic access is sent the response is provided when the function returns. Atomic and timing accesses can not coexist in the memory system. | ||
− | # '''Functional''' - Like atomic accesses functional accesses happen instantaneously, but unlike atomic accesses they can coexist in the memory system with atomic | + | # '''Functional''' - Like atomic accesses functional accesses happen instantaneously, but unlike atomic accesses they can coexist in the memory system with atomic or timing accesses. Functional accesses are used for things such as loading binaries, examining/changing variables in the simulated system, and allowing a remote debugger to be attached to the simulator. The important note is when a functional access is received by a device, if it contains a queue of packets all the packets must be searched for requests or responses that the functional access is effecting and they must be updated as appropriate. The <code>Packet::intersect()</code> and <code>fixPacket()</code> methods can help with this. |
+ | |||
+ | === Packet allocation protocol === | ||
+ | |||
+ | The protocol for allocation and deallocation of Packet objects varies depending on the access type. (We're talking about low-level C++ <code>new</code>/<code>delete</code> issues here, not anything related to the coherence protocol.) | ||
+ | |||
+ | ; ''Atomic'' and ''Functional'' : The Packet object is owned by the requester. The responder must overwrite the request packet with the response (typically using the <code>Packet::makeResponse()</code> method). There is no provision for having multiple responders to a single request. Since the response is always generated before <code>sendAtomic()</code> or <code>sendFunctional()</code> returns, the requester can allocate the Packet object statically or on the stack. | ||
+ | |||
+ | ; ''Timing'' : Timing transactions are composed of two one-way messages, a request and a response. In both cases, the Packet object must be dynamically allocated by the sender. Deallocation is the responsibility of the receiver (or, for broadcast coherence packets, the target device, typically memory). In the case where the receiver of a request is generating a response, it ''may'' choose to reuse the request packet for its response to save the overhead of calling <code>delete</code> and then <code>new</code> (and gain the convenience of using <code>makeResponse()</code>). However, this optimization is optional, and the requester must not rely on receiving the same Packet object back in response to a request. Note that when the responder is not the target device (as in a cache-to-cache transfer), then the target device will still delete the request packet, and thus the responding cache must allocate a new Packet object for its response. Also, because the target device may delete the request packet immediately on delivery, any other memory device wishing to reference a broadcast packet past point where the packet is delivered must make a copy of that packet, as the pointer to the packet that is delivered cannot be relied upon to stay valid. | ||
=== Timing Flow control === | === Timing Flow control === | ||
− | Timing requests simulate a real memory system so unlike functional and atomic accesses their response is not instantaneous. | + | Timing requests simulate a real memory system, so unlike functional and atomic accesses their response is not instantaneous. Because the timing requests are not instantaneous, flow control is needed. When a timing packet is sent via <code>sendTiming()</code> the packet may or may not be accepted, which is signaled by returning true or false. If false is returned the object should not attempt to sent anymore packets until it receives a <code>recvRetry()</code> call. At this time it should again try to call <code>sendTiming()</code>; however the packet may again be rejected. Note: The original packet does not need to be resent, a higher priority packet can be sent instead. Once <code>sendTiming()</code> returns true, the packet may still not be able to make it to its destination. For packets that require a response (i.e. <code> pkt->needsResponse()</code> is true), any memory object can refuse to acknowledge the packet by changing its result to <code>Nacked</code> and sending it back to its source. However, if it is a response packet, this can not be done. The true/false return is intended to be used for local flow control, while nacking is for global flow control. In both cases a response can not be nacked. |
=== Response and Snoop ranges === | === Response and Snoop ranges === | ||
− | Ranges in the memory system | + | Ranges in the memory system are handled by having devices that are sensitive to an address range provide an implementation for <code>getAddrRanges</code> in their slave port objects. This method returns an <code>AddrRangeList</code> of addresses it responds to. When these ranges change (e.g. from PCI configuration taking place) the device should call <code>sendRangeChange()</code> on its slave port so that the new ranges are propagated to the entire hierarchy. This is precisely what happens during <code>init()</code>; all memory objects call <code>sendRangeChange()</code>, and a flurry of range updates occur until everyones ranges have been propagated to all busses in the system. |
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__NOTOC__ | __NOTOC__ |
Latest revision as of 14:45, 30 November 2012
M5's new memory system (introduced in the first 2.0 beta release) was designed with the following goals:
- Unify timing and functional accesses in timing mode. With the old memory system the timing accesses did not have data and just accounted for the time it would take to do an operation. Then a separate functional access actually made the operation visible to the system. This method was confusing, it allowed simulated components to accidentally cheat, and prevented the memory system from returning timing-dependent values, which isn't reasonable for an execute-in-execute CPU model.
- Simplify the memory system code -- remove the huge amount of templating and duplicate code.
- Make changes easier, specifically to allow other memory interconnects besides a shared bus.
For details on the new coherence protocol, introduced (along with a substantial cache model rewrite) in 2.0b4, see Coherence Protocol.
MemObjects
All objects that connect to the memory system inherit from MemObject
. This class adds the pure virtual functions getMasterPort(const std::string &name, PortID idx)
and getSlavePort(const std::string &name, PortID idx)
which returns a port corresponding to the given name and index. This interface is used to structurally connect the MemObjects together.
Ports
The next large part of the memory system is the idea of ports. Ports are used to interface memory objects to each other. They will always come in pairs, with a MasterPort and a SlavePort, and we refer to the other port object as the peer. These are used to make the design more modular. With ports a specific interface between every type of object doesn't have to be created. Every memory object has to have at least one port to be useful. A master module, such as a CPU, has one or more MasterPort instances. A slave module, such as a memory controller, has one or more SlavePorts. An interconnect component, such as a cache, bridge or bus, has both MasterPort and SlavePort instances.
There are two groups of functions in the port object. The send*
functions are called on the port by the object that owns that port. For example to send a packet in the memory system a CPU would call myPort->sendTimingReq(pkt)
to send a packet. Each send function has a corresponding recv function that is called on the ports peer. So the implementation of the sendTimingReq()
call above would simply be peer->recvTimingReq(pkt)
on the slave port. Using this method we only have one virtual function call penalty but keep generic ports that can connect together any memory system objects.
Master ports can send requests and receive responses, whereas slave ports receive requests and send responses. Due to the coherence protocol, a slave port can also send snoop requests and receive snoop responses, with the master port having the mirrored interface.
Connections
In Python, Ports are first-class attributes of simulation objects, much like Params. Two objects can specify that their ports should be connected using the assignment operator. Unlike a normal variable or parameter assignment, port connections are symmetric: A.port1 = B.port2
has the same meaning as B.port2 = A.port1
. The notion of master and slave ports exists in the Python objects as well, and a check is done when the ports are connected together.
Objects such as busses that have a potentially unlimited number of ports use "vector ports". An assignment to a vector port appends the peer to a list of connections rather than overwriting a previous connection.
In C++, memory ports are connected together by the python code after all objects are instantiated.
Request
A request object encapsulates the original request issued by a CPU or I/O device. The parameters of this request are persistent throughout the transaction, so a request object's fields are intended to be written at most once for a given request. There are a handful of constructors and update methods that allow subsets of the object's fields to be written at different times (or not at all). Read access to all request fields is provided via accessor methods which verify that the data in the field being read is valid.
The fields in the request object are typically not available to devices in a real system, so they should normally be used only for statistics or debugging and not as architectural values.
Request object fields include:
- Virtual address. This field may be invalid if the request was issued directly on a physical address (e.g., by a DMA I/O device).
- Physical address.
- Data size.
- Time the request was created.
- The ID of the CPU/thread that caused this request. May be invalid if the request was not issued by a CPU (e.g., a device access or a cache writeback).
- The PC that caused this request. Also may be invalid if the request was not issued by a CPU.
Packet
A Packet is used to encapsulate a transfer between two objects in the memory system (e.g., the L1 and L2 cache). This is in contrast to a Request where a single Request travels all the way from the requester to the ultimate destination and back, possibly being conveyed by several different Packets along the way.
Read access to many packet fields is provided via accessor methods which verify that the data in the field being read is valid.
A packet contains the following all of which are accessed by accessors to be certain the data is valid:
- The address. This is the address that will be used to route the packet to its target (if the destination is not explicitly set) and to process the packet at the target. It is typically derived from the request object's physical address, but may be derived from the virtual address in some situations (e.g., for accessing a fully virtual cache before address translation has been performed). It may not be identical to the original request address: for example, on a cache miss, the packet address may be the address of the block to fetch and not the request address.
- The size. Again, this size may not be the same as that of the original request, as in the cache miss scenario.
- A pointer to the data being manipulated.
- Set by
dataStatic()
,dataDynamic()
, anddataDynamicArray()
which control if the data associated with the packet is freed when the packet is, not, withdelete
, and withdelete []
respectively. - Allocated if not set by one of the above methods
allocate()
and the data is freed when the packet is destroyed. (Always safe to call). - A pointer can be retrived by calling
getPtr()
-
get()
andset()
can be used to manipulate the data in the packet. The get() method does a guest-to-host endian conversion and the set method does a host-to-guest endian conversion.
- Set by
- A status indicating Success, BadAddress, Not Acknowleged, and Unknown.
- A list of command attributes associated with the packet
- Note: There is some overlap in the data in the status field and the command attributes. This is largely so that a packet an be easily reinitialized when nacked or easily reused with atomic or functional accesses.
- A
SenderState
pointer which is a virtual base opaque structure used to hold state associated with the packet but specific to the sending device (e.g., an MSHR). A pointer to this state is returned in the packet's response so that the sender can quickly look up the state needed to process it. A specific subclass would be derived from this to carry state specific to a particular sending device. - A
CoherenceState
pointer which is a virtual base opaque structure used to hold coherence-related state. A specific subclass would be derived from this to carry state specific to a particular coherence protocol. - A pointer to the request.
Access Types
There are three types of accesses supported by the ports.
- Timing - Timing accesses are the most detailed access. They reflect our best effort for realistic timing and include the modeling of queuing delay and resource contention. Once a timing request is successfully sent at some point in the future the device that sent the request will either get the response or a NACK if the request could not be completed (more below). Timing and Atomic accesses can not coexist in the memory system.
- Atomic - Atomic accesses are a faster than detailed access. They are used for fast forwarding and warming up caches and return an approximate time to complete the request without any resource contention or queuing delay. When a atomic access is sent the response is provided when the function returns. Atomic and timing accesses can not coexist in the memory system.
- Functional - Like atomic accesses functional accesses happen instantaneously, but unlike atomic accesses they can coexist in the memory system with atomic or timing accesses. Functional accesses are used for things such as loading binaries, examining/changing variables in the simulated system, and allowing a remote debugger to be attached to the simulator. The important note is when a functional access is received by a device, if it contains a queue of packets all the packets must be searched for requests or responses that the functional access is effecting and they must be updated as appropriate. The
Packet::intersect()
andfixPacket()
methods can help with this.
Packet allocation protocol
The protocol for allocation and deallocation of Packet objects varies depending on the access type. (We're talking about low-level C++ new
/delete
issues here, not anything related to the coherence protocol.)
- Atomic and Functional
- The Packet object is owned by the requester. The responder must overwrite the request packet with the response (typically using the
Packet::makeResponse()
method). There is no provision for having multiple responders to a single request. Since the response is always generated beforesendAtomic()
orsendFunctional()
returns, the requester can allocate the Packet object statically or on the stack.
- Timing
- Timing transactions are composed of two one-way messages, a request and a response. In both cases, the Packet object must be dynamically allocated by the sender. Deallocation is the responsibility of the receiver (or, for broadcast coherence packets, the target device, typically memory). In the case where the receiver of a request is generating a response, it may choose to reuse the request packet for its response to save the overhead of calling
delete
and thennew
(and gain the convenience of usingmakeResponse()
). However, this optimization is optional, and the requester must not rely on receiving the same Packet object back in response to a request. Note that when the responder is not the target device (as in a cache-to-cache transfer), then the target device will still delete the request packet, and thus the responding cache must allocate a new Packet object for its response. Also, because the target device may delete the request packet immediately on delivery, any other memory device wishing to reference a broadcast packet past point where the packet is delivered must make a copy of that packet, as the pointer to the packet that is delivered cannot be relied upon to stay valid.
Timing Flow control
Timing requests simulate a real memory system, so unlike functional and atomic accesses their response is not instantaneous. Because the timing requests are not instantaneous, flow control is needed. When a timing packet is sent via sendTiming()
the packet may or may not be accepted, which is signaled by returning true or false. If false is returned the object should not attempt to sent anymore packets until it receives a recvRetry()
call. At this time it should again try to call sendTiming()
; however the packet may again be rejected. Note: The original packet does not need to be resent, a higher priority packet can be sent instead. Once sendTiming()
returns true, the packet may still not be able to make it to its destination. For packets that require a response (i.e. pkt->needsResponse()
is true), any memory object can refuse to acknowledge the packet by changing its result to Nacked
and sending it back to its source. However, if it is a response packet, this can not be done. The true/false return is intended to be used for local flow control, while nacking is for global flow control. In both cases a response can not be nacked.
Response and Snoop ranges
Ranges in the memory system are handled by having devices that are sensitive to an address range provide an implementation for getAddrRanges
in their slave port objects. This method returns an AddrRangeList
of addresses it responds to. When these ranges change (e.g. from PCI configuration taking place) the device should call sendRangeChange()
on its slave port so that the new ranges are propagated to the entire hierarchy. This is precisely what happens during init()
; all memory objects call sendRangeChange()
, and a flurry of range updates occur until everyones ranges have been propagated to all busses in the system.