For more details about cycle-counting and out-of-order execution, see Agner Fog's microarch pdf, and other links in the x86 tag wiki.
Intel Haswell's L1 load-use latency is 4 cycles, which is typical of modern x86 CPUs. i.e. how fast
mov eax, [eax] can run in a loop, with a pointer that points to itself. (Or to a small closed-loop linked list).
Load-use latency is 1 cycle higher for SSE/AVX vectors in Intel CPUs.
Store-reload latency is 5 cycles, and is unrelated to cache hit or miss (it's store-forwarding, not L1 cache).
As harold commented, register access is 0 cycles. So, for example:
inc eax has 1 cycle latency (just the ALU operation)
inc dword [mem] has 6 cycle latency until a load from
dword [mem] will be ready. (ALU + store-forwarding). e.g. keeping a loop counter in memory limits a loop to one iteration per 6 cycles.
mov rax, [rsi] has 4 cycle latency from
rsi being ready to
rax being ready on an L1 hit (L1 load-use latency.)
http://www.7-cpu.com/cpu/Haswell.html has a table of latency per cache (which I'll copy here), and some other experimental numbers, including L2-TLB hit latency (on an L1DTLB miss).
Intel i7-4770 (Haswell), 3.4 GHz (Turbo Boost off), 22 nm. RAM: 32 GB (PC3-12800 cl11 cr2).
- L1 Data cache = 32 KB, 64 B/line, 8-WAY.
- L1 Instruction cache = 32 KB, 64 B/line, 8-WAY.
- L2 cache = 256 KB, 64 B/line, 8-WAY
L3 cache = 8 MB, 64 B/line
L1 Data Cache Latency = 4 cycles for simple access via pointer (
mov rax, [rax])
- L1 Data Cache Latency = 5 cycles for access with complex address calculation (
mov rax, [rsi + rax*8]).
- L2 Cache Latency = 12 cycles
- L3 Cache Latency = 36 cycles
- RAM Latency = 36 cycles + 57 ns
The top-level benchmark page is http://www.7-cpu.com/utils.html, but still doesn't really explain what the different test-sizes mean, but the code is available. The test results include Skylake, which is nearly the same as Haswell in this test.
@paulsm4's answer has a table for a multi-socket Nehalem Xeon, including some remote (other-socket) memory / L3 numbers.