I have a few additional aspects here:
Consider the operation "a=b/c" x86 would implement this as
div dword ptr c
As an additional bonus of the div instruction edx will contain the remainder.
A RISC processor would require first loading the addresses of b and c, loading b and c from memory to registers, doing the division and loading the address of a and then storing the result. Dst,src syntax:
mov r5,addr b
mov r6,addr c
mov r5,addr a
Here there typically won't be a remainder.
If any variables are to be loaded through pointers both sequences may become longer though this is less of a possibility for the RISC because it may have one or more pointers already loaded in another register. x86 has fewer register so the likelihood of the pointer being in one of them is smaller.
Pros and cons:
The RISC instructionss may be mixed with surrounding code to improve instruction scheduling, this is less of a possibility with x86 which instead does this work (more or less well depending on the sequence) inside the CPU itself. The RISC sequence above will typically be 28 bytes long (7 instructions of 32-bit/4 byte width each) on a 32-bit architecture. This will cause the off-chip memory to work more when fetching the instructions (seven fetches). The denser x86 sequence contains fewer instructions and though their widths vary you're probably looking at an average of 4 bytes/instruction there too. Even if you have instruction caches to speed this up seven fetches means that you will have a deficit of three elsewhere to make up for compared to the x86.
The x86 architecture with fewer registers to save/restore means that it will probably do thread switches and handle interrupts faster than RISC. More registers to save and restore requires more temporary RAM stack space to do interrupts and more permanent stack space to store thread states. These aspects should make x86 a better candidate for running pure RTOS.
On a more personal note I find it more difficult to write RISC assembly than x86. I solve this by writing the RISC routine in C, compiling and modifying the generated code. This is more efficient from a code production standpoint and probably less efficient from an execution standpoint. All those 32 registers to keep track of. With x86 it is the other way around: 6-8 registers with "real" names makes the problem more manageable and instills more confidence that the code produced will work as expected.
Ugly? That's in the eye of the beholder. I prefer "different."