I would say you need to work on a disassembler first. The simulator is the next step beyond a disassembler. For example an x86 (or other variable word length instruction sets) disassembler would for need to follow the execution of the code. First it has to know based on the opcodes how many bytes are used by that instruction, second is this a branch and if so what kind, conditional or unconditional and react accordingly. The simulator does all this plus it simulates the registers. The disassembler would be for educational purposes, not a polished publish on sourceforge thing. Just enough to get the feel for how to parse the instructions at the bit level, compute jump offsets.
I have one (instruction set simulator) called thumbulator at github if interested, not perfect, but simple and possibly educational. There are many, many, others out there. I would start with a simple instruction set like the 12 bit pic or 6502 or something like that (msp430 is another possible candidate). If you go with an existing instruction set for learning how to write the simulator, you can capitalize on the existing toolchains (assemblers and maybe compilers) for that isa. Divide the task in half. For a new instruction set you will need a toolchain at some point or at least a good disassembler if you want to hand code the machine code (the disassembler double checks you have the machine code you thought you wanted). Or you could have an option in the simulator to output disassembled code in execution order, good for debugging anyway.
Dont worry about interrupts at first, but be aware that you are going to need to have a mechanism for stopping the flow of the simulation, save state and re-use the simulator for so many clock cycles. You will see a lot of simulators essentially single step each instruction. Evaluating the number of clock ticks on each instruction for hardware reasons either for periodic interrupts, or other simulated hardware that needs to be in sync with the simulated processor. So it would be a good ideal to start by modelling yours that way and then coming up with performance improvements later as needed.
If you have not programmed using state machines I highly recommend learning a little about them and writing some practice programs.
I am working on a project I hope to publish that if I ever finish may help with topics like this. My instruction set simulators these days are actually written in a hardware design language (verilog for example, not the hdl I use but it converts to verilog) then use something like verilator with a C/C++ wrapper. So the work related to extracting opcodes and bits is handled by a language designed to manage just that. And the parts that want to simulate peripherals or provide guis or other ways of displaying what is going on are handled by a language designed for that. If you happen to be working on a project where this new instruction set is realized in vhdl or verilog I highly recommend a hybrid hdl simulator plus software solution either through VPI if it is a commercial hdl simulator or through other simpler methods if you go with verilator or icarus verilog or ghdl or others. (icarus may need the commercial like vpi interface). The beauty here is that you are closer to the real hardware, bugs/warts, etc in the hardware can be found and dealt with before going to silicon, changes or improvements in the hardware are instantly realized in the simulation instead of having to make matching changes or improvements in the simulator, etc. The hdl simulators have scripty languages, or system C, etc, which are fine for getting the hardware functionally tested but you cant run it on silicon. If you discourage the use of these tools and have real binaries run on the simulated logic, and provide an abstraction layer to real tools to load or debug or monitor (for example write a back end to openocd to pass through the host to hdl sim layer and talk to the simulated jtag debugger on the chip, depending on the complexity of this design(quite doable as I have done it myself)). These real programs can be run both in simulation and on silicon, saving time in writing tests, and getting test software written well before silicon arrives instead of starting after it arrives.
Sorry for the HDL tangent. If this is a new or otherwise without toolchain instruction set you are going to have to spend time on that toolchain, at least an assembler and linker and I would do some sort of disassembler and then turn that disassembler or portions of it into the first cut at the simulator. As far as standard things I have seen in instruction set simulators, basically think in terms of single stepping so that you can handle clocks and interrupts and other simulated hardware. the core function of the simulation either simulates one clock cycle which may not be a complete instruction (a state machine approach) or the core function simulates a single instruction and returns modifying registers, flags and memory as demanded by the instruction (and counting simulated clocks). Depending on how feature rich you want this simulator from the very beginning make your reads and writes of ram/rom and registers functions so that you can in one place trap memory and register changes for displaying to the user. Only access or at least modify registers and ram through these abstract functions. Beyond that it is just a ton of typing, the more complicated the instruction set, the more instructions the more lines of code to type.