Intel 8086-2 Computer Hardware User Manual


 
8086
FUNCTIONAL DESCRIPTION
General Operation
The internal functions of the 8086 processor are
partitioned logically into two processing units The
first is the Bus Interface Unit (BIU) and the second is
the Execution Unit (EU) as shown in the block dia-
gram of Figure 1
These units can interact directly but for the most
part perform as separate asynchronous operational
processors The bus interface unit provides the func-
tions related to instruction fetching and queuing op-
erand fetch and store and address relocation This
unit also provides the basic bus control The overlap
of instruction pre-fetching provided by this unit
serves to increase processor performance through
improved bus bandwidth utilization Up to 6 bytes of
the instruction stream can be queued while waiting
for decoding and execution
The instruction stream queuing mechanism allows
the BIU to keep the memory utilized very efficiently
Whenever there is space for at least 2 bytes in the
queue the BIU will attempt a word fetch memory
cycle This greatly reduces ‘‘dead time’’ on the
memory bus The queue acts as a First-In-First-Out
(FIFO) buffer from which the EU extracts instruction
bytes as required If the queue is empty (following a
branch instruction for example) the first byte into
the queue immediately becomes available to the EU
The execution unit receives pre-fetched instructions
from the BIU queue and provides un-relocated oper-
and addresses to the BIU Memory operands are
passed through the BIU for processing by the EU
which passes results to the BIU for storage See the
Instruction Set description for further register set
and architectural descriptions
MEMORY ORGANIZATION
The processor provides a 20-bit address to memory
which locates the byte being referenced The memo-
ry is organized as a linear array of up to 1 million
bytes addressed as 00000(H) to FFFFF(H) The
memory is logically divided into code data extra
data and stack segments of up to 64K bytes each
with each segment falling on 16-byte boundaries
(See Figure 3a)
All memory references are made relative to base ad-
dresses contained in high speed segment registers
The segment types were chosen based on the ad-
dressing needs of programs The segment register
to be selected is automatically chosen according to
the rules of the following table All information in one
segment type share the same logical attributes (eg
code or data) By structuring memory into relocat-
able areas of similar characteristics and by automati-
cally selecting segment registers programs are
shorter faster and more structured
Word (16-bit) operands can be located on even or
odd address boundaries and are thus not con-
strained to even boundaries as is the case in many
16-bit computers For address and data operands
the least significant byte of the word is stored in the
lower valued address location and the most signifi-
cant byte in the next higher address location The
BIU automatically performs the proper number of
memory accesses one if the word operand is on an
even byte boundary and two if it is on an odd byte
boundary Except for the performance penalty this
double access is transparent to the software This
performance penalty does not occur for instruction
fetches only word operands
Physically the memory is organized as a high bank
(D
15
–D
8
) and a low bank (D
7
–D
0
) of 512K 8-bit
bytes addressed in parallel by the processor’s ad-
dress lines A
19
–A
1
Byte data with even addresses
is transferred on the D
7
–D
0
bus lines while odd ad-
dressed byte data (A
0
HIGH) is transferred on the
D
15
–D
8
bus lines The processor provides two en-
able signals BHE
and A
0
to selectively allow read-
ing from or writing into either an odd byte location
even byte location or both The instruction stream is
fetched from memory as words and is addressed
internally by the processor to the byte level as nec-
essary
Memory Segment Register Segment
Reference Need Used Selection Rule
Instructions CODE(CS) Automatic with all instruction prefetch
Stack STACK (SS) All stack pushes and pops Memory references relative to BP
base register except data references
Local Data DATA(DS) Datareferences when relative to stack destination of string
operation or explicitly overridden
External (Global) Data EXTRA (ES) Destination of string operations explicitly selected using a
segment override
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