I was reading the MDS attack paper RIDL: Rogue In-Flight Data Load. They discuss how the Line Fill Buffer can cause leakage of data. There is the About the RIDL vulnerabilities and the "replaying" of loads question that discusses the micro-architectural details of the exploit.

One thing that isn't clear to me after reading that question is why we need a Line Fill Buffer if we already have a store buffer.

John McCalpin discusses how the store buffer and Line Fill Buffer are connected in How does WC-buffer relate to LFB? on the Intel forums, but that doesn't really make things clearer to me.

For stores to WB space, the store data stays in the store buffer until after the retirement of the stores. Once retired, data can written to the L1 Data Cache (if the line is present and has write permission), otherwise an LFB is allocated for the store miss. The LFB will eventually receive the "current" copy of the cache line so that it can be installed in the L1 Data Cache and the store data can be written to the cache. Details of merging, buffering, ordering, and "short cuts" are unclear.... One interpretation that is reasonably consistent with the above would be that the LFBs serve as the cacheline-sized buffers in which store data is merged before being sent to the L1 Data Cache. At least I think that makes sense, but I am probably forgetting something....

I've just recently started reading up on out-of-order execution so please excuse my ignorance. Here is my idea of how a store would pass through the store buffer and Line Fill Buffer.

  1. A store instruction get scheduled in the front-end.
  2. It executes in the store unit.
  3. The store request is put in the store buffer (an address and the data)
  4. An invalidate read request is sent from the store buffer to the cache system
  5. If it misses the L1d cache, then the request is put in the Line Fill Buffer
  6. The Line Fill Buffer forwards the invalidate read request to L2
  7. Some cache receives the invalidate read and sends its cache line
  8. The store buffer applies its value to the incoming cache line
  9. Uh? The Line Fill Buffer marks the entry as invalid

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  1. Why do we need the Line Fill Buffer if the store buffer already exists to track outsanding store requests?
  2. Is the ordering of events correct in my description?
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    An LFB can be tracking an incoming cache line, not just a store. An LFB buffers between the L1d and the L2 or off-core. The store buffer buffers between execution and L1d (or off-core for NT stores). Some of the description of having data in an LFB waiting to merge with an RFO result doesn't fully make sense; we're not sure CPUs actually do anything like that. i.e. Dr. Bandwidth's mental model (at the time he wrote that specific post) might not match reality there. @ BeeOnRope, @ HadiBrais, and I have debated what does/doesn't make sense for that in previous SO Q&As, IIRC – Peter Cordes Apr 9 at 21:09
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    @PeterCordes Since each store is preceded by an RFO and since data from upper levels is stored in the LFBs, isn't it possible that the SB "writes" into the relative LFB? I.e. not using it as a temporary buffer while doing the RFO but writing into it after the RFO has bring data into it. Now, if the line the store would go to is already in EX state then I'm not sure an LFB is allocated. That seems a waste w.r.t. writing in the data lines directly but maybe the cache CAM doesn't allow for partial writes. Anyway, do we already have a canonical answer of SB <-> LFB interaction here? – Margaret Bloom Apr 10 at 7:19
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    @MargaretBloom: IIRC, the main difficulties with this idea of committing from the SB into an LFB before it's architecturally allowed (memory ordering) to commit to L1d is that multiple stores to the same line lose memory-ordering info relative to each other (and anything else). We must maintain in-order stores even for code that alternates stores to two different lines. In Exclusive or Modified state there's no reason to expect an LFB to be involved in committing from SB to L1d, and before we reach that state it needs to stay in the SB for ordering. IDK if we have a canonical Q&A. – Peter Cordes Apr 10 at 12:44
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    @PeterCordes Why would we want to commit stores to LFB before it's architecturally allowed? I was reasoning about the possibility of the SB to write to the LFB after the RFO brought the line into the LFB and before saving it in the cache's CAM. So this all happens after the core is sure the store is architecturally allowed. – Margaret Bloom Apr 10 at 12:50
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    @MargaretBloom: Oh, now I see what you were saying. That sounds plausible and would be legal because the RFO is finished; we just have to make sure the store data shows up when responding to other cores. We already want to make sure we get a chance to commit at least one store before giving up the line again. So yes maybe we save on cache write ports by committing pending store(s) from the head of the SB into the LFB as the data arrives, maybe while the cache is indexing the right set/way to store the LFB. We do know that NT stores can write straight into an LFB, not cache, they're connected – Peter Cordes Apr 10 at 13:00

Why do we need the Line Fill Buffer if the store buffer already exists to track outsanding store requests?

The store buffer is used to track stores, in order, both before they retire and after they retire but before they commit to the L1 cache2. The store buffer conceptually is a totally local thing which doesn't really care about cache misses. The store buffer deals in "units" of individual stores of various sizes. Chips like Intel Skylake have store buffers of 50+ entries.

The line fill buffers primary deal with both loads and stores that miss in the L1 cache. Essentially, it is the path from the L1 cache to the rest of the memory subsystem and deals in cache line sized units. We don't expect the LFB to get involved if the load or store hits in the L1 cache1. Intel chips like Skylake have many fewer LFB entries, probably 10 to 12.

Is the ordering of events correct in my description?

Pretty close. Here's how I'd change your list:

  1. A store instructions gets decoded and split into store-data and store-address uops, which are renamed, scheduled and have a store buffer entry allocated for them.
  2. The store uops execute in any order or simultaneously (the two sub-items can execute in either order depending mostly on which has its dependencies satisfied first).
    1. The store data uop writes the store data into the store buffer.
    2. The store address uop does the V-P translation and writes the address(es) into the store buffer.
  3. At some point when all older instructions have retired, the store instruction retires. This means that the instruction is no longer speculative and the results can be made visible. At this point, the store remains in the store buffer and is called a senior store.
  4. The store now waits until it is at the head of the store buffer (it is the oldest not committed store), at which point it will commit (become globally observable) into the L1, if the associated cache line is present in the L1 in MESIF Modified or Exclusive state. (i.e. this core owns the line)
  5. If the line is not present in the required state (either missing entirely, i.e,. a cache miss, or present but in a non-exclusive state), permission to modify the line and the line data (sometimes) must be obtained from the memory subsystem: this allocates an LFB for the entire line, if one is not already allocated. This is a so-called request for ownership (RFO), which means that the memory hierarchy should return the line in an exclusive state suitable for modification, as opposed to a shared state suitable only for reading (this invalidates copies of the line present in any other private caches).

An RFO to convert Shared to Exclusive still has to wait for a response to make sure all other caches have invalidated their copies. The response to such an invalidate doesn't need to include a copy of the data because this cache already has one. It can still be called an RFO; the important part is gaining ownership before modifying a line. 6. In the miss scenario the LFB eventually comes back with the full contents of the line, which is committed to the L1 and the pending store can now commit3.

This is a rough approximation of the process. Some details may differ on some or all chips, including details which are not well understood.

As one example, in the above order, the store miss lines are not fetched until the store reaches the head of the store queue. In reality, the store subsystem may implement a type of RFO prefetch where the store queue is examined for upcoming stores and if the lines aren't present in L1, a request is started early (the actual visible commit to L1 still has to happen in order, on x86, or at least "as if" in order).

So the request and LFB use may occur as early as when step 3 completes (if RFO prefetch applies only after a store retires), or perhaps even as early as when 2.2 completes, if junior stores are subject to prefetch.

As another example, step 6 describes the line coming back from the memory hierarchy and being committed to the L1, then the store commits. It is possible that the pending store is actually merged instead with the returning data and then that is written to L1. It is also possible that the store can leave the store buffer even in the miss case and simply wait in the LFB, freeing up some store buffer entries.

1 In the case of stores that hit in the L1 cache, there is a suggestion that the LFBs are actually involved: that each store actually enters a combining buffer (which may just be an LFB) prior to being committed to the cache, such that a series of stores targeting the same cache line get combined in the cache and only need to access the L1 once. This isn't proven but in any case it is not really part of the main use of LFBs (more obvious from the fact we can't even really tell if it is happening or not).

2 The buffers that hold stores before and retirement might be two entirely different structures, with different sizes and behaviors, but here we'll refer to them as one structure.

3 The described scenarios involves the store that misses waiting at the head of the store buffer until the associated line returns. An alternate scenario is that the store data is written into the LFB used for the request, and the store buffer entry can be freed. This potentially allows some subsequent stores to be processed while the miss is in progress, subject to the strict x86 ordering requirements. This could increase store MLP.

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  • You said that step 4 (send an invalidate request) happens later, when the store is ready to commit. The concepts of retire/commit are new to me. Is this the right sequence of events: 1. The store uop executes in the store execution unit 2. It gets placed in the store buffer 3. The store uop is in the retirement units Reorder Buffer (ROB) until it is known to be not-speculative 4. The store buffer sends the invalidate read request (this may take some time, but since the store buffer keeps track of the req, the store don't have to wait around) ...to be continued.. – Daniel Näslund Apr 10 at 16:54
  • Steps 5-7 in my question happens. Then the store buffer applies its value and thus it commits. – Daniel Näslund Apr 10 at 16:55
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    @DanielNäslund - I've created my own list, take a look and see if makes sense. WRT to your question, I believe the store buffer entry is actually allocated at rename, which happens even before execution (the uops enter the scheduler at rename). The buffer entry is basically empty at this point and then separate "address" and "data" uops fill those into the buffer entry when they execute. After retirement, one could think of the store buffer operating in order: stores are committed to L1 one at a time in the order they appear in the source (this is a requirement of the strong memory ... – BeeOnRope Apr 11 at 22:50
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    ordering on x86, where stores to WB memory are forbidden from reordering). However, there may be optimization to that simple one-at-a-time model in that the store system may "look ahead" to pending stores and start getting those lines early. So the miss is not necessarily handled at an exactly specified moment, but rather a range of times which may also depend on the specific CPU, heuristics/predictors checking whether RFO prefetch has been helping out in practice, etc. – BeeOnRope Apr 11 at 22:52
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    I added a bit to entry 5 about RFOs for lines that were present but shared (not owned exclusively) – Peter Cordes Apr 11 at 23:11

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