@David Schwartz and @RKT are right, it doesn't take any CPU cycles to check the interrupt line.
Basically, the processor has a set of interrupt wires which are connected to a bunch of devices. When one of the devices has something to say, it turns its interrupt wire on, which triggers the processor (without the help of any software) to pause the execution of current instructions and start running a handler function.
Here's how it works. When the operating system boots, it registers a set of callbacks (a table of function pointers, actually) with the processor using a special instruction which takes the address of the first entry of the table. When interrupt
N is triggered, the processor pulls the
Nth entry from the table and runs the code at the location in memory it refers to. The code inside the function is written by the OS authors in assembly, but typically all it does is save the state of the stack and registers so that the current task can be resumed after the interrupt handler has been called and then call a higher-level common interrupt handler which is written in C and that handles the logic of "If this a page fault, do X", "If this is a keyboard interrupt, do Y", "If this is a system call, do Z", etc. Of course there are variations on this with different architectures and languages, but the gist of it is the same.
The idea with software interrupts ("signals", in Unix parlance) is the same, except that the OS does the work of setting up the stack for the signal handler to run. The basic procedure is that the userland process registers signal handlers one at a time to the OS via a system call which takes the address of the handler function as an argument, then some time in the future the OS recognizes that it should send that process a signal. The next time that process is run, the OS will set its instruction pointer to the beginning of the handler function and save all its registers to somewhere the process can restore them from before resuming the execution of that process. Usually, the handler will have some sort of routing logic to alert the relevant bit of code that it received a signal. When the process finishes executing the signal handler, it restores the register state that existed previous to the signal handler running, and resumes execution where it left off. Hence, software interrupts are also more efficient than polling for learning about events coming from the kernel to this process (however this is not really a general-use mechanism since most of the signals have specific uses).