I suspect that masked NT vector stores no longer work well for multi-core CPUs, so probably even the 128-bit version just sucks on modern x86 for masked writes, if there are any unmodified bytes in a full 64-byte line.
(Regular masked vector stores are back with a vengeance in AVX512BW byte-masked vectors; masked commit to L1d cache seems to be efficiently supported for that, and dword / qword masking with AVX1
vmaskmovps/pd and integer equivalent, and AVX512F)
The SDRAM (including DDR4) bus protocol does support byte-masked writes (with 1 mask line per byte as part of a cache-line burst transfer). This Intel doc (about FPGAs or something) includes discussion of the
DM (data mask) signals, confirming that DDR4 still has them, with the same function as the DQM lines described on Wikipedia for SDRAM https://en.wikipedia.org/wiki/Synchronous_dynamic_random-access_memory#SDR_SDRAM. (DDR1 changed it to write-mask only, not read-mask.)
So the hardware functionality is there, and presumably modern x86 CPUs use it for single-byte writes to uncacheable memory, for example.
No-RFO stores are great if we write a full line: we just invalidate other copies of the line and store to memory.
John "Dr. Bandwidth" McCalpin says that normal NT stores that flush after filling a full 64-byte line will invalidate even lines that are dirty, without causing a writeback of the dirty data.
So masked NT stores need to use a different mechanism, because any masked-out bytes need to take their value from the dirty line in another core, not from whatever was in DRAM.
If the mechanism for partial-line NT stores isn't efficient, adding new instructions that create it is unwise. I don't know if it's more or less efficient than doing normal stores to part of a line, or if that depends on the situation and uarch.
It doesn't have to be a RFO exactly, but it would mean that when such a store reaches the memory controller, it would have to get the snoop filter to make sure the line is in sync, or maybe merge with the old contents from cache before flushing to DRAM.
Or the CPU core could do an RFO and merge, before sending the full-line write down
the memory hierarchy.
CPUs do already need some kind of mechanism for flushing partial-line NT stores when reclaiming an LFB that hasn't had all 64 bytes written yet, and we know that's not as efficient. (But I forget the details.) But maybe this is how
maskmovdqu executes on modern CPUs, either always or if you leave any bytes unmodified.
An experiment could probably find out.
maskmovqdu may have only been implemented efficiently in single-core CPUs. It originated in Katmai Pentium III with MMX
maskmovq mm0, mm1; SMP systems existed, but maybe weren't the primary consideration for this instruction when it was being designed. SMP systems didn't have shared last-level cache, but they did still have private write-back L1d cache on each socket.