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I've read that in the days of the Intel 8086 CPU the biggest registers were 16-bits and everyone were looking for a way to access more than 65536 bytes of linear memory but instead of expanding the CPU registers they invented the segment:offset addressing scheme and the way I understand it you're able to "group" two 16-bit registers together into a 32-bit memory address. But the same place I have also read that the CPU could only access 1MB of memory. How does that work? 2^32 equals 4,294,967,296 so I don't understand, please enlighten me :)

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2 Answers 2

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The segment register value is shifted left by 4 (multiplied by 16) and added to the operand address.

16 * 65536 = 1 megabyte.

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Could you please show me the largest segment:offset address that can be expressed in the old x86 manner? –  Benjamin Jan 1 '12 at 19:59
The largest effective address is 0xffffff. There are multiple segment register and offset value combinations that accomplish that. Arbitrarily seg = 0xf000, offset = 0xffff. Is this homework? –  Hans Passant Jan 1 '12 at 20:22
No it isn't homework. But to be precise, the 16-bit segment:offset addressing scheme can access 1114095 bytes right? (65535 * 16 + 65535) –  Benjamin Jan 1 '12 at 21:07
Only on a processor with an address bus wider than 20 bits (286 and up) with the A20 gate disabled. The extra 0xfff0 of memory (0xffff0 + 0xffff - 1MB) was called the "DOS High Memory Area" iirc. On the original 8086 the effective address would wrap back around. –  Hans Passant Jan 1 '12 at 21:37
What do you mean by "wrap back around"? –  Benjamin Jan 2 '12 at 12:41

8086 has 20bit address line. so the maximum it can address is 2^20 = 1MB. http://en.wikipedia.org/wiki/Intel_8086

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