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Can anyone give me the approximate time (in nanoseconds) to access L1, L2 and L3 caches, as well as main memory on Intel i7 processors?

While this isn't specifically a programming question, knowing these kinds of speed details is neccessary for some low-latency programming challenges.

EDIT: The second link from Dave has the following numbers:
Core i7 Xeon 5500 Series Data Source Latency (approximate)
L1 CACHE hit, ~4 cycles
L2 CACHE hit, ~10 cycles
L3 CACHE hit, line unshared ~40 cycles
L3 CACHE hit, shared line in another core ~65 cycles
L3 CACHE hit, modified in another core ~75 cycles remote
remote L3 CACHE ~100-300 cycles
Local Dram ~60 ns
Remote Dram ~100 ns

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How do I convert ns to cycles? If I simply divide 100 ns by 2.3 GHz, I get 230 cycles. Is this correct? – Nathan Dec 17 '14 at 19:26

3 Answers 3

up vote 23 down vote accepted

Here is a Performance Analysis Guide for the i7 and Xeon range of processors. I should stress, this has what you need and more (for example, check page 22 for some timings & cycles for example).

Additionally, this page has some details on clock cycles etc

EDIT: I should highlight that, as well as timing/cycle information, the above intel document addresses much more (extremely) useful details of the i7 and Xeon range of processors (from a performance point of view).

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Numbers everyone should know

  • L1 cache reference 0.5 ns
  • Branch mispredict 5 ns
  • L2 cache reference 7 ns
  • Mutex lock/unlock 100 ns
  • Main memory reference 100 ns
  • Compress 1K bytes with Zippy 10,000 ns
  • Send 2K bytes over 1 Gbps network 20,000 ns
  • Read 1 MB sequentially from memory 250,000 ns
  • Round trip within same datacenter 500,000 ns
  • Disk seek 10,000,000 ns
  • Read 1 MB sequentially from network 10,000,000 ns
  • Read 1 MB sequentially from disk 30,000,000 ns
  • Send packet CA->Netherlands->CA 150,000,000 ns


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Surely these care very HUGE amounts, based on processor design, ram latency/frequency, hard disk caching(both type and size)/rpm etc etc? To Quote INTEL (for values they released for one specific CPU):"NOTE:These values are rough approximations. They depend on Core and Uncore Frequencies, Memory speeds, BIOS settings, Number of DIMMS, etc etc. YOUR MILEAGE MAY VARY..." – Dave Nov 3 '10 at 13:22
@Dave that's true, but this numbers show the order of magnitude – Andrey Nov 3 '10 at 13:24
@Dave, even though type/speed/architecture of the cpu is different, I believe the relative timing should roughly remain same, so it's just a rough guideline to know when you code. More meaningful analysis should be done via profiler of course... – xosp7tom Jan 3 '12 at 23:32
To have an idea of how much time it is, Wikipedia mentions "One nanosecond is to one second as one second is to 31.7 years." – Only You Nov 23 '13 at 23:07
@kernel if there is cache miss it means that it will require access of lower level cache or even main memory. In this case it will take time according to that level access time. You can look for data for newer CPUs here – Andrey Apr 23 '14 at 11:10

Cost to access various memories in a pretty page

--> Decrease of memory access latency, year after year, from 1990 to 2020


  1. Values that do not really change since 2005:

            1 ns        L1 cache
            3 ns        Branch mispredict
            4 ns        L2 cache
           17 ns        Mutex lock/unlock
          100 ns        Main memory (RAM)
        2 000 ns (2µs)  1KB Zippy-compress
  2. Still some improvements, prediction for 2020:

       16 000 ns (16µs) SSD random read
      500 000 ns (½ms)  Round trip in datacenter 
    2 000 000 ns (2ms)  HDD random read (seek)

See also other sources

See also a training

For further understanding, I recommend the excellent presentation of modern cache architectures (June 2014) from Gerhard Wellein, Hannes Hofmann and Dietmar Fey at University Erlangen-Nürnberg.

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