Yes and no.
On an x86 CPU (for one example) there's an
int instruction that generates an interrupt. Once the interrupt is generated, the CPU won't necessarily1 distinguish between an interrupt generated by hardware and one generated by software. For one example, in the original PC BIOS, IBM chose an interrupt that would cause the print-screen command to execute. The interrupt they chose (interrupt 5) was one that wasn't then in use, but which Intel had said was reserved for future use. Intel eventually did put that interrupt to use -- in the 286 they added a
bound instruction that checks that a value is within bounds, and generates an interrupt if it's not. The
bound instruction is essentially never used though, because it generates interrupt 5 if a value is out of bounds. This means (if you're running something like MS-DOS that allows it) executing the
bound instruction with a value that's out of bounds will print the screen.
On a modern OS, however, this won't generally be allowed. All generation and handling of interrupts happens in the kernel. The hardware had 4 levels of protection ("rings") and support for specifying the ring at which the
int instruction can be executed. If you try to execute it from code running at ring 3, it won't execute directly -- instead, execution will switch to the OS kernel, which can treat it as it chooses.
This allows (for example) Windows to emulate MS-DOS, so MS-DOS programs (which do use the
int instruction) can execute in a virtual machine, with virtualized input and output, so even though they "think" they're working directly with the keyboard and screen hardware, they're actually using emulations of them provided by software.
For "native" programs, however, using most
int instructions (i.e. any but a tiny number of interrupts intended for communication with the kernel) will simply result in the program being shut down.
So, bottom line: yes, the hardware supports it -- but the hardware also supports prohibiting it, and nearly every modern OS does exactly that, at least for most code outside the OS kernel itself.
- Though, with typical hardware, the interrupt handler can read data from the programmable interrupt controller (PIC) chip that will tell it whether the interrupt came through the PIC (i.e., hardware interrupt) or not (software interrupt). Most hardware also supports at least a few interrupts that can be generated only by hardware, such as NMI on the x86. These are usually reserved for fairly narrow uses though (e.g., NMI on a PC is normally used for things like memory parity errors).