Summary: I am not aware of any recent x86 architecture that incurs additional delays when using the the "wrong" load instruction (i.e., a load instruction followed by an ALU instruction from the opposite domain).
Here's what Agner has to say about bypass delays which are the delays you might incur when moving between the various execution domains with in the CPU (sometimes these are unavoidable, but sometimes they may be caused by using the "wrong" version of an instruction which is at issue here):
Data bypass delays on Nehalem On the Nehalem, the execution units are
divided into five "domains":
The integer domain handles all operations in general purpose
registers. The integer vector (SIMD) domain handles integer operations
in vector registers. The FP domain handles floating point operations
in XMM and x87 registers. The load domain handles all memory reads.
The store domain handles all memory stores. There is an extra latency
of 1 or 2 clock cycles when the output of an operation in one domain
is used as input in another domain. These so-called bypass delays are
listed in table 8.2.
There is still no extra bypass delay for using load and store
instructions on the wrong type of data. For example, it can be
convenient to use MOVHPS on integer data for reading or writing the
upper half of an XMM register.
The emphasis in the last paragraph is mine and is the key part: the bypass delays didn't apply to Nehalem load and store instructions. Intuitively, this makes sense: the load and store units are dedicated for the entire core and will have to make their result available in a way suitable for any execution unit (or store it in the PRF) - unlike the ALU case the same concerns with forwarding aren't present.
Now don't really care about Nehalem any more, but in the sections for Sandy Bridge/Ivy Bridge, Haswell and Skylake you'll find a note that the domains are as discussed for Nehalem, and that there are fewer delays overall. So one could assume that the behavior where loads and stores don't suffer a delay based on the instruction type remains.
We can also test it. I wrote a benchmark like this:
sub rsp, 120
xor eax, eax
pxor xmm1, xmm1
movdqa xmm0, [rsp + rax] ; 7 cycles
pand xmm0, xmm1 ; 1 cycle
movq rax, xmm0 ; 1 cycle
add rsp, 120
This loads a value using
movdqa, does an integer domain operation (
pand) on it, and then moves it to general purpose register
rax so it can be used as part of the address for
movdqa in the next loop. I also created 3 other benchmarks identical to the above, except with
movdqa replaced with
The results on Skylake-client (i7-6700HQ with recent microcode):
** Running benchmark group Vector unit bypass latency **
movdqa [mem] -> pxor latency 9.00
movdqu [mem] -> pxor latency 9.00
movups [mem] -> pxor latency 9.00
movupd [mem] -> pxor latency 9.00
In every case the rountrip latency was the same: 9 cycles, as expected: 6 + 1 + 2 cycles for the load,
All of these tests are added in uarch-bench in case you would like to run them on any other architecture (I would be interested in the results). I used the command line:
./uarch-bench.sh --test-name=vector/* --timer=libpfc