The C language expresses the things it is specified to express: fundamental arithmetic operations, assignment of values to variables, and branches and function calls. Objects may be allocated using
static, automatic (local), or dynamic (malloc) storage duration. If you want something outside this conceptual scope, you need something other than pure C.
The C language can be extended arbitrarily, and many platforms define syntax for things like defining a function or variable at a particular address.
But the hardware of the CPU cares about a lot of details, such as the values of flag registers. The part of the scheduler which switches threads needs to be able to save all the registers to memory before doing anything, because overwriting any register would lose essential data in the interrupted thread.
The only way to be able to write such a thing in C, would be for the compiler to provide a C function which generates the finely-tuned assembly. And then you're essentially back at square 1, because the important details are still at the level of the assembly code.
Vendors with multiple product lines of microcontrollers sometimes go out of their way to allow C source compatibility even at the lowest levels, to allow their customers to port code (or conversely, to prevent them from going to another vendor when they need to switch platforms). But the distinction between C and assembly blurs at a certain point, when you're calling pseudo-functions that generate specific instructions (known as intrinsics).