WAR hazards for registers are pretty much not an issue, thanks to register renaming. (except for
tzcnt, which have a false dependency on the old value of their write-only destination on Intel CPUs.) I'm not sure how much it matters for memory.
Very cool assignment. So much better than the ones I've seen where students were asked to optimize some code for
gcc -O0, learning a bunch of tricks that don't matter in real code. In this case, you're being asked to learn about the CPU pipeline and use that to guide your de-optimization efforts, not just blind guessing.
Replace local vars with members of structs, so you can control the memory layout.
volatile if you're compiling with
-O3, to force the compiler to actually store/reload all over the place. Or go even further and use C++11
std::atomic<double> for the most pessimal code.
-m32 will also help (to make slower code), because x87 code will probably be worse than SSE2 code.
-march=i386 may also help, since FP comparisons with old-style
fcom instead of 686
fcomi requires extra steps to test the FP status register, instead of setting EFLAGS directly. gcc
-O0 wouldn't use
atomic<double> might require
cmpxchg8B (586), or without it gcc might fall back to using a lock. ([Evil laugh]). (Thanks @Jesper for the suggestion).
Store things in memory so they all go into the same "way" in the L1 cache.
Even better, put things exactly 4096B apart, so loads have a false dependency on stores. If you can introduce an extra level of indirection, so load/store addresses aren't known early, that can hurt.
Traverse arrays in non-sequential order (Thanks @JesperJuhl for the idea). Your code doesn't actually store any results in arrays. If you separate the random number generation from the random number use, you could justify storing an array of random numbers, and then consuming them. For maximum pessimization, loop over your array with a stride of 4096 bytes (i.e. 512 doubles). e.g.
for (int i=0 ; i<512; i++) for (int j=i ; j<UPPER_BOUND ; j+=512) monte_carlo_step(rng_array[j]);
So the access pattern is 0, 4096, 8192, ...,
8, 4104, 8200, ...
16, 4112, 8208, ...
Adjust the loop bounds if necessary to use many different pages instead of reusing the same few pages, if the array isn't that big. Hardware prefetching doesn't work (as well/at all) across pages. The prefetcher can track one forward and one backward stream within each page (which is what happens here), but will only act on it if the memory bandwidth isn't already saturated with non-prefetch.
This will also generate lots of TLB misses, unless the pages get merged into a hugepage (Linux does this opportunistically for anonymous (not file-backed) allocations like
new that use
Use a union to store an
int into memory using multiple narrower stores, causing a store-forwarding stall when loading it again right away.
Force conversion from integer to
float and back again. And/or
float conversions. The instructions have greater-than-one latency, and scalar int->float (
cvtsi2ss) is badly designed to not zero the rest of the xmm register. (gcc inserts an extra
pxor to break dependencies, for this reason.)
If you can use intrinsics (
clflush to evict your data from cache.
If targeting pre-IvB, or esp. Nehalem, try to get gcc to cause partial-register stalls with 8bit operations.
LCP stalls from 16bit instructions with immediates too large to fit in 8 bits is unlikely to be useful because the uop cache on SnB and later means you only pay the penalty once. On Nehalem, it might work for a loop that don't fit in the 28 uop loop buffer. Even with
-mtune=intel, gcc will generate such instructions.