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Assume a 5 stage pipeline architecture (IF = Instruction Fetch, ID = Instruction Decode, EX = Execute, MEM = Memory access, WB = Register write back).There are 4 instructions that has to be executed.

(These sample instruction are not accurate, but I believe the point would be understood)

In the fifth clock cycle, these instruction will be in pipeline as shown below.

Add a, b, c [IF ID EX MEM WB]

Add a, b, d [IF ID EX MEM]

Add a, b, e [IF ID EX]

Add a, b, f [IF ID]

Now if an hardware interrupts occur what happens to these instructions. Will the interrupt be handled only after all the instructions in the pipeline is executed? Will the software interrupts and exceptions be handled in a different way??

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The pipelines get flushed in much the same way as they would for e.g. a mispredicted branch - exact details depend on what CPU you are talking about. –  Paul R Jan 17 '12 at 21:50
    
I think it is a pity that the question has been voted -1. It's actually a fairly fundamental question in computer (micro)architecture, one that is often misunderstood - as is shown by the first answer being confused. –  Krazy Glew May 12 '12 at 0:11

2 Answers 2

up vote 6 down vote accepted

First, terminology:

Usually, at Intel at least, an interrupt is something that comes from the outside world. Usually it is not synchronized with instructions executing on the processor, i.e. it is an asynchronous external interrupt.

In Intel terminology an exception is something caused by instructions executing on the processor. E.g. a page fault, or an undefined instruction trap.

---+ Interrupts flush all instructions in flight

On every machine that I am familiar with - e.g. all Intel processors since the P5 (I worked on the P6), AMD x86s, ARM, MIPS - when the interrupt signal is received the instructions in the pipeline are nearly always flushed, thrown away.

The only reason I say "nearly always" is that on some of these machines you are not always at a place where you are allowed to receive an interrupt. So, you proceed to the next place where an interruopt is allowed - any instruction boundary, typically - and THEN throw away all of the instructions in the pipeline.

For that matter, interrupts may be blocked. So you proceed until interrupts are unblocked, and THEN you throw them away.

Now, these machines aren't exactly simple 5 stage pipelines. Nevertheless, this observation - that most machines throw away all instructions in the pipeline, in pipestages before the pipestage where the interrupt logic lives - remains almost universally true.

In simple machines the interrupt logic typically lives in the last stage of the pipelinwe, WB, corresponding roughly to the commit pipestage of advanced machines. Sometimes it is moved up to a pipestage just before, e.g. MEM in your example. So, on such machines, all instructions in IF ID EX, and usually MEM, are thrown away.

---++ Why I care

This topic is near and dear to my heart because I have proposed NOT doing this. E.g. in customer visits while we were planning to build the P6, I asked customers which they preferred - lower latency interrupts, flushing instructions that are in flight, or (slightly) higher throughput, allowing at least some of the instructions in flight to complete, at the cost of slightly longer latency.

However, although some customers preferred the latter, we chose to do the traditional thing, flushing immediately. Apart from the lower latency, the main reason is complexity:

E.g. if you take an interrupt, but if one of the instructions already in flight also takes an exception, after you haved resteered IF but before any instructuion in the interrupt has committed, which takes priority? A: it depends. And that sort of thing is a pain to deal with.

---+ Exceptions mark the instructions affected

Conversely, exceptions, things like page faults, mark the instruction affected.

When that instruction is about to commit, at that point all later instructions after the exception are flushed, and instruction fetch is redirected.

Conceivably, instruction fetch could be resteered earlier, the way branch mispredictions are already handled on most processors, at the point at which we know that the exception is going to occur. I don't know anyone who does this. On current workloads, exceptions are not that important.

---+ "Software Interrupts"

"Software interrupts" are a misnamed instruction usually associated with system calls.

Conceivably, such an instruction could be handled without interrupting the pipeline, predicted like a branch.

However, all of the machines I am familiar with serialize in some way. In my parlance, they do not rename the privilege level.

---+ "Precise Interrupts", EMON, PEBS

Another poster mentioned precise interrupts.

This is a historical term. On most modern machines interrupts are defined to be precise. Older machines with imprecise interrupts have not been very successful in the market place.

However, there is an alternate meaning, I was involved in introducing: when I got Intel to add the capability to produce an interrupt on performance counter overflow, first using external hardware, and then inside the CPU, it was, in the first few generations, completely imprecise.

E.g. you might set the counter to count the number of instructions retired. The retirement logic (RL)would see the instructions retire, and signal the performance event monitoring circuitry (EMON). It might take two or three clock cycles to send this signal from RL to EMON. EMON would increment the counter, and then see that there was an overflow. The overflow would trigger an interrupt request to the APIC (Advanced Programmable Interrupt Controller). The APIC might take a few cycles to figure out what was happening, and then signal the retirement logic.

I.e. the EMON interrupt would be signalled imprecisely. Not at the time of the event, but some time thereafter.

Why this imprecision? Well, in 1992-6, performance measurement hardware was not a high priority. We were leveraging existing interrupt hardware. Beggars can't be choosers.

But furthermore, some performance are intrinsically imprecise. E.g. when do you signal an interrupt for a cache miss on a speculative instruction that never retires? (I have a scheme I called Deferred EMON events, but this is still considered too expensive.) For that matter, what about cache misses on store instructions, where the store is placed into a store buffer, and the instruction has already retired?

I.e. sometimes performance events occur after the instruction they are associated with has committed (retired). Sometimes before. And often not exactly at the instruction they are associated with.

But in all of the implementations so far, as far as I know, these performance events are treated like interrupts: existing instructions in the pipe are flushed.

Now, you can make a performance event precise by treating it like a trap. E.g. if it is an event like instructions retired, you can have the retirement logic trap immediately, instead of taking that circuitous loop I described above. If it occurs earlier in the pipeline, you can have the fact that it occurred marked in the instruction fault status in the ROB (Re-Order Buffer). Something like this is what Intel has done with PEBS (Precise Event Based Sampling). http://software.intel.com/sites/products/collateral/hpc/vtune/performance_analysis_guide.pdf.

However, note that not all events can be sampled using PEBS. For example, PEBS in the exanple above can count loads that took a cache hit or miss, but not stores (since stores occur later.)

So this is like exceptions: the event is delivered only when the instruction retires. Because in a sense the event has not completely occurred - it is a load instruction, that takes a cache miss, and then retires. And instructions after the marked PEBS instruction are flushed from the pipeline.

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How hard would it have been to have asynchronous interrupts specify that instructions should stop entering the pipeline, but those in the pipeline should run to completion? One might need to have two IRQ lines (one of which would request a pipeline flush) but conceptually it seems like it should be straightforward. –  supercat Mar 6 '13 at 22:37
    
Nothing is hard to build. Verifying, to make sure that you haven't broken something, some implicit assumption, is what takes time. Because the cost of verification is high, and the cost of getting something wrong can be very high (recalls, possibly lawsuits), companies (not just hardware companies, but all companies), tend to be pretty conservative. Don't innovate, unless the need is very clearly demonstrated. IMHO too conservative, but I understand the risk aversion. // Did I mention that rarely occurring bugs in something like interrupts are very much disliked? –  Krazy Glew Jun 19 '13 at 23:04
    
That makes a lot of sense. I guess the only processors whose pipelining behavior I've examined in any detail are the ones which are simple enough that I can understand them, and could imagine how they could be verified. On many more sophisticated processors, all the pipeline interactions seem sufficiently complex I'm amazed they work at all, and I can see that adding another variable to the mix might complicate things. Still, I've done programming on one chip which had both delayed and non-delayed branch instructions, and I liked the delayed branches. Maybe they added some... –  supercat Jun 20 '13 at 14:26
    
...complexity, but in a tight loop cutting two cycles from the cost of a branch can be a pretty major performance boost. I'd guess that delayed branches/calls and delayed interrupts would probably share a lot of implementation details. –  supercat Jun 20 '13 at 14:28
    
Well, yes and no. Delayed branches (usually, on all of the public machines that I am aware of having implemented them) have a deterministic delay. Basically, you create the moral equivalent of a shift register of PCs, and insert the delayed branch at the end of the shift register, with the intervening ones sequential. (Actually, delayed branch architects get quite picky about exactly what they do - some might take exception to what I said about a shift register - but from 10,000 feet, that's what they are doing.) –  Krazy Glew Jun 21 '13 at 2:55

For precise interrupts, instructions in flight before the IF stage jumps to the ISR retire normally. When the ISR returns, execution resumes starting with the next instruction after the last retired instruction of the original process. In other words, precise interrupts always happen in between instructions.

Processing for synchronous interrupts is a bit different. Taking x86 as an example, synchronous exceptions come in three flavors, traps, faults and aborts.

A trap, like INT3, causes the core to push the instruction after the trap on the stack, such that when the ISR returns, the core does not pointlessly reexecute the same trapping instruction.

A fault, like a page fault, causes the core the push the faulting instruction on the stack, such that when the ISR returns, the core will reexecute the faulting instruction, presumably now in circumstances that avoid the same fault again.

An abort, like a double fault, is a fatal unrecoverable problem in which the processor cannot resume execution where it left off.

The content of interrupt stack frame pushed by core the before entering the ISR differs depending on which case you're talking about.

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