I've found the answer. Tnx to Jester & the links. :D
Here's an image that shows the relationship of the IDTR (Interrupt Descriptor Table Register) and IDT (Interrupt Descriptor Table). (Reference: Intel's manual):
Here's also a pricture that shows how the entries in the IDT look like (Reference: Intel's manual):
The base address(the address where the IDT starts) of the IDT (Interrupt Description Table) is given by the bits 16 to 47, 16 and 47 inclusive. To get the address of the vector #3 the size of the first 2 entries has to be added to the base address. To find the addresses where the bits for the offset and for the segment selector reside one needs to find the address of the vector and then add bytes according to the second picture, so to say one moves inside an entry of the IDT.
"The base addresses of the IDT should be aligned on an 8-byte boundary to maximize performance of cache line
fills. The limit value is expressed in bytes and is added to the base address to get the address of the last valid byte.
A limit value of 0 results in exactly 1 valid byte. Because IDT entries are always eight bytes long, the limit should
always be one less than an integral multiple of eight (that is, 8N – 1).
The IDT may reside anywhere in the linear address space.As shown in Figure 6-1, the processor locates the IDT
using the IDTR register. This register holds both a 32-bit base address and 16-bit limit for the IDT." - (Reference: Intel's manual)
So one should align the table as it is said in the manual for better performance.
For educational purposes I'll explain how to find the physical addresses of the offset bytes and the segment bytes when the IDTR contains 3A000h.
First I'll write 3A000h in binary format so it is easier to understand the number using the picture.
So 3A000h becomes: 0000 0000 0000 0000 0000 0000 0000 0011 1010 0000 0000 0000
Note: It is a 48 digit number because the IDTR is 48 bits long.
The base address is the number that starts at bit 16 and ends at bit 47. So:
The base address = 0000 0000 0000 0000 0000 0000 0000 0011
and that's 3h.
So the first entry is at physical address 3.
To get the third entry one adds the size of the 2 entries before it so the address of the third entry is:
The 2 entries are multiplied by 8 because one entry is 8 bytes long.
Now to get the physical address of the offset bytes, we just need to look at the figure 6.2 and see that entries look like this:
So reading from the picture
The physical addresses of the segment selector are:
19+2 and 19+2+1
13h+2h and 13h+2h+1h
The physical addresses of the offset bytes are (assuming it's an interrupt or a trap gate):
19, 19+1, 19+6, 19+7
13h, 13h+1, 13h+6h, 13h+7h
The General Procedure For Solving This Kind Of Problem:
BaseAddress=IDTR/(2^16) -> Integer division
Physical addresses of the segments selector bytes are: VectorPhysicalAddress+2 and VectorPhysicalAddress+3
Physical addresses of the offset bytes are: VectorPhysicalAddress, VectorPhyscialAddress+1, VectorPhysicalAddress+6, VectorPhysicalAddress+7