A clock cycle is simply a single cycle of the oscillator that drives a processor's logic, what a processor might be capable of achieving in that cycle depends on the processor architecture and other factors such as memory speed.
The code in your example is in a high level language and almost certainly translates to multiple machine-level instructions if translated directly. In pseudo-machine code for example:
That would be at least two machine cycles per loop. There is little or no deterministic relationship between high level code and the generated machine instructions; although in this simple case, it may seems so.
The issue is further complicated by how an instruction set is implemented by a processor. A typical RISC processor executes an instruction in a single cycle, while on a CISC processor, different individual instructions each take a different number of cycles depending on their complexity.
Another consideration is memory bus latency. Often a processor is capable of executing instructions faster than it is able to access memory, this is often especially true of flash memory. An instruction accessing slower memory may introduce wait-states, where the processor is stalled until the data arrives.
Some processors have the ability to execute instructions in parallel, allowing multiple instructions in a single cycle. Others employ SIMD (single instruction-multiple data) instructions that can perform the same operation on different data at the same time.
Another technique that affects instruction throughput is pipe-lining, where an instruction may take multiple cycles, but a new instruction can be started on each cycle, so say if 5 four cycle instructions are each started one after the other, a result is yielded once per cycle.
Some processors employ a Harvard architecture that uses separate buses to allow the simultaneous fetching of data and instructions.
Other techniques are employed to maintain instruction throughput such as branch prediction. A high-level language compiler will often generate code that will maximise the potential of all the techniques mentioned above.
Often a performance measure that is given for a particular architecture is MIPS/MHz - an indication of the number of instructions typically executed per clock cycle (amortized over many clock cycles). An ARM Cortex-M3 for example manages 1.25 MIPS/MHz, while a Renesas SH-4 achieves 1.8 MIPS/MHz.