MIPS specifically is less important than understanding asm in general so you have some idea of what happens when you compile high-level source. Understanding a bit of asm can help you make sense of the symptoms of bugs in high-level code. (e.g. overwriting the wrong data through a bogus pointer, or modifying other locals on the stack when you write outside an array).
Obviously understanding how to make C or C++ run fast is much easier when you know that what actually runs is the compiler-generate asm. It's impossible to design good microbenchmarks to test anything if you don't already mostly know what's going on.
Once you've learned MIPS assembly, it will be pretty easy to learn any other. All other mainstream CPUs are also register machines that work basically the same way:
- There are registers and memory
- Everything including pointers are just bits and bytes in memory or registers, i.e. integers.
- Each instruction is independent, and updates the architectural state (register values) according to its simple rules. It only cares about its inputs (usually registers, sometimes also memory). There is no magic.
- Execution continues from one instruction to the next in increasing address in program memory, except for jump / branch instructions.
- Writing programs / functions is a matter of constructing a series of steps for the machine to take that will result in data being moved around and processed the way you want. It's like designing the steps in an algorithm
- ASM is where a debugger really shines: it can show you the full architectural state of the machine (because there are a finite number of registers), and show you which register values changed when you single-step by one instruction.
Every architecture has its own extra wrinkles, but these basics don't change and are what you really learn when you learn your first assembly language. One of MIPS's major wrinkle is the branch-delay slot (which the MARS and SPIM simulators hide / disable by default)
RISC-V is a lot like MIPS, but without quirks like a branch-delay slot. And there is a RARS simulator with a toy system-call environment a lot like MARS provides for MIPS. As a bonus, RISC-V is a lot more commercially-relevant these days, so knowing it specifically has more real-world benefit if it catches your interest. But you can still imagine a classic-RISC pipeline that implements RISC-V, and learn all the same computer-architecture basics.
MIPS is a pretty nice assembly language to learn. It's simple and orthogonal, and leads nicely to discussions of pipelined CPUs because that's what it was designed for. (No microcoded instructions, and very regular machine-code format that's easy to decode.)
Also, there are nice MIPS simulators, MARS and SPIM, which have an editor / assembler / simulator + debugger all in one. And some "system calls" which do high-level things like read an integer from the user's keyboard into a register. Normal OSes have system calls that just let you read/write characters, and you have to call library functions or write your own integer->string functions. This is a blessing and a curse: if you don't realize that MARS system calls are basically library functions with a special calling convention, you might not realize that you can write your own code that does some of those things, or that it's not "normal" for system calls to work this way.
You could learn all this on x86, though, especially if you want to do performance experiments on your desktop / laptop.