If I understand what you're really talking about.. you're asking a question way outside the scope of SO, and not worded correctly. I think you're asking how system calls work and why some of them are platform specific.
It's true that there's code that is closely tied to one specific OS, or one specific chipset, that's more at the embedded level. Consider this rainbow image I borrowed from Google (Not quite right, but I don't want to go draw my own):
I want to know that what is that thing that makes the calls platform specific?
You're right, software, at its lowest level is tied to hardware. If I develop a BSP at the firmware level it's tied to the hardware. It's not portable at all. Why? Because each hardware platform can use different chips, and can be configured with generic inputs/outputs (GPIOs for example) differently, each IC can have a different set of registers and functions, and can map those with different endianness.
How does OS implement this at kernel level?
At a layer up from the BSPs there are drivers, typically found in the kernel of the OS. These access the hardware specific functions and are more abstracted for the upper layers. I might have a logitc XXX mouse, for example, and I have firmware that knows how to talk to that, but a layer up I might have a "mouse" driver in the kernel that knows how to talk to a lot of different types of mice.
The upper layers of the OS can then provide some handles to the standard libraries to call to "get mouse click" for example. A very generic type function that has very hardware specific requirements to work.
How the portability issues are solved?
Each layer things get more and more abstracted. When you get to the layer of the "C standard libraries", it doesn't know or care about what hardware you're on, it will work anywhere C will work. You can by pass the C standard libraries, and make System calls.. basically you're just hopping down the chain making calls that are less abstracted from hardware and thus less portable.