what is meant by normalization in huge pointers

I have a lot of confusion on understanding the difference between a "far" pointer and "huge" pointer, searched for it all over in google for a solution, couldnot find one. Can any one explain me the difference between the two. Also, what is the exact normalization concept related to huge pointers.

Please donot give me the following or any similar answers:

"The only difference between a far pointer and a huge pointer is that a huge pointer is normalized by the compiler. A normalized pointer is one that has as much of the address as possible in the segment, meaning that the offset is never larger than 15. A huge pointer is normalized only when pointer arithmetic is performed on it. It is not normalized when an assignment is made. You can cause it to be normalized without changing the value by incrementing and then decrementing it. The offset must be less than 16 because the segment can represent any value greater than or equal to 16 (e.g. Absolute address `0x17` in a normalized form would be `0001:0001`. While a far pointer could address the absolute address `0x17` with `0000:0017`, this is not a valid huge (normalized) pointer because the offset is greater than `0000F`.). Huge pointers can also be incremented and decremented using arithmetic operators, but since they are normalized they will not wrap like far pointers."

Here the normalization concept is not very well explained, or may be I'm unable to understand it very well.

Can anyone try explaining this concept from a beginners point of view.

Thanks, Rahamath

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What platform is this? Some sort of embedded target with a 16-bit address space? It sounds like far/huge pointers actually have a segment and offset, as opposed to being simple linear addresses. –  tomlogic May 20 '10 at 20:14
1985 called, wants its lame technology back. –  ergosys May 20 '10 at 20:26
ergosys, you would be surprized to learn that there are still embedded controller based on 80186 architecture in use today, and while they are no longer advertised by intel and AMD you can still purchase them. –  tristopia May 20 '10 at 21:03
No, I'm not surprised, but it's still a lame idea. –  ergosys May 20 '10 at 21:04
Reading this question and answers reminds me of why I am glad that I have not had to work with segmented memory models for 10+ years. –  Jay May 20 '10 at 21:22

``````Example:
Segment  0x1234   Offset 0x5678 will give the real address
0x 1234
+0x  5678
---------
=0x 179B8
``````

As you will have noticed, this operation is not bijective, meaning you can generate the real address with other combinations of segment and offset.

``````   0x 1264               0x 1111
+0x  5378             +0x  68A8
---------             ---------     etc.
=0x 179B8             =0x 179B8
``````

There are in fact 4096 different combinations possible, because of the 3 overlapping nibbles (`3*4 = 12` bits, `2^12 = 4096`) . The normalized combination is the only one in 4096 possible values that will have the 3 high nibbles of the offset to zero. In our example it will be:

``````   0x 179B
+0x  0008
---------
=0x 179B8
``````

The difference between a `far` and a `huge` pointer is not in the normalisation, you can have non normalised `huge` pointer, it's absolutly allowed. The difference is in the code generated when performing pointer arithmetic. With far pointers when incrementing or adding values to the pointer there will be no overflow handling and you will be only able to handle 64K of memory.

``````char far *p = (char far *)0x1000FFFF;
p++;
printf("p=%p\n");
``````

will print `1000:0000` For huge pointers the compiler will generate the code necessary to handle the carry over.

``````char huge *p = (char huge *)0x1000FFFF;
p++;
printf("p=%p\n");
``````

will print `2000:0000`

This means you have to be careful when using far or huge pointers as the cost of the arithmetic with them is different.

One should also not forget that most 16 bit compilers had libraries that didn't handle these cases correctly giving sometimes buggy software. Microsofts real mode compiler didn't handle huge pointers on all its string functions. Borland was even worse as even the mem functions (`memcpy`, `memset`, etc.) didn't handle offset overflows. That was the reason why it was a good idea to use normalised pointers with these library functions, the likelyhood of offset overflows was lower with them.

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Thanks for this wonderful explaination!! –  wrapperm May 22 '10 at 14:15

First thing to understand is how a segmented pointer is converted into a linear address. For the example you have, the conversion is:

``````linear = segment * 16 + offset;
``````

Because of that, it turns out there there the same linear address can be expressed using different segment/offset combinations. For example, the following segment/offset combinations all refer to the same linear address:

``````0004:0000
0003:0010
0002:0020
0001:0030
0000:0040
``````

The problem with this is that if you have ptr1 with a segmented address of `0100:0000` and ptr2 with a segmented address of `0010:0020`, a simple comparison will determine that `ptr1 != ptr2` even though they actually point to the same address.

Normalization is the process by which you convert an address to a form such that if two non-normalized pointers refer to the same linear address, they will both be converted to the same normalized form.

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+1 for mentioning pointer comparison, I forgot that in my answer. –  tristopia May 20 '10 at 20:50
Numbers are wrong, 0100:0000 == 00FF:0010 == 00FE:0020, etc. –  Hans Passant May 20 '10 at 20:59
@HansPassant - dang, for some reason I used binary for the segment and hex on the index. Will fix that.. –  R Samuel Klatchko May 20 '10 at 21:01
Thanks for the explaining the concept wonderfull!!! Pat on the Back!!! –  wrapperm May 22 '10 at 14:16

As I recall, it's something like this:

• Near pointers point to memory in the same segment (as the pointer).
• Far pointers point to memory in another segment.
• Huge pointers let you point to memory that's larger than a segment (so you can have a block >64k and do arithmetic on your pointer, and what Samuel said).

If you're a beginner, it's probably best to forget that you heard about Near/Far/Huge. They only have meaning in the old 16-bit segmented memory model commonly seen on early Intel 80x86's. In 32- and 64-bit land (i.e., everything since 1994), memory is just a big contiguous block, so a pointer is just a pointer (as far as a single application is concerned).

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