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The 8088 and 8086
Microprocessors


The 8086, announced in 1978, was the first 16bit microprocessor introduced by Intel
Corporation
8086 and 8088 are internally 16-bit MPU.

Externally the 8086 has a 16-bit data bus and
the 8088 has an 8-bit data bus
The 8088 and 8086
Microprocessors (cont.)



8086 and 8088 both have the ability to address
up to 1 Mbyte of memory and 64K of
input/output port
The 8088 and 8086 are both manufactured
using high-performance metal-oxide
semiconductor (HMOS) technology
The 8088 and 8086 are housed in a 40-pin dual
inline package and many pins have multiple
functions
The 8088 and 8086
Microprocessors (cont.)


CMOS, Complementary Metal-OxideSemiconductor, is a major class of integrated
circuits used in chips such as microprocessors,
microcontrollers, static RAM, digital logic
circuits, and analog circuits such as image
sensors
Two important characteristics of CMOS devices
are high noise immunity and low static power
supply drain.

Significant power is only drawn when its
transistors are switching between on and off
states
The 8088 and 8086
Microprocessors (cont.)


CMOS devices do not produce as much heat as
other forms of logic such as TTL.
CMOS also allows a high density of logic
functions on a chip
The 8088 and 8086
Microprocessors (cont.)
Pin layout of the 8086 and 8088 microprocessor
8086 Features
• 16-bit Arithmetic Logic Unit
• 16-bit data bus (8088 has 8-bit data bus)
• 20-bit address bus - 220 = 1,048,576 = 1 meg
The address refers to a byte in memory. In the 8088, these bytes come in on
the 8-bit data bus. In the 8086, bytes at even addresses come in on the low
half of the data bus (bits 0-7) and bytes at odd addresses come in on the upper
half of the data bus (bits 8-15).
The 8086 can read a 16-bit word at an even address in one operation and at an
odd address in two operations. The 8088 needs two operations in either case.
The least significant byte of a word on an 8086 family microprocessor is at the
lower address.
Simplified CPU Design
Data Bus
Data Registers
Control
Unit
Address Registers
Address Bus
Arithmetic
Logic Unit
Status
Flags
Memory
Intel 16-bit Registers
General Purpose
AH
AL
AX
Index
BP
SP
BH
BL
BX
SI
CH
CL
DH
DL
CX
DI
Segment
DX
CS
Status and Control
SS
Flags
DS
IP
ES
8086 Architecture
• The 8086 has two parts, the Bus Interface Unit (BIU) and the
Execution Unit (EU).
• The BIU fetches instructions, reads and writes data, and computes the
20-bit address.
• The EU decodes and executes the instructions using the 16-bit ALU.
• The BIU contains the following registers:
IP - the Instruction Pointer
CS - the Code Segment Register
DS - the Data Segment Register
SS - the Stack Segment Register
ES - the Extra Segment Register
The BIU fetches instructions using the CS and IP, written CS:IP, to contract
the 20-bit address. Data is fetched using a segment register (usually the DS)
and an effective address (EA) computed by the EU depending on the
addressing mode.
The EU contains the following 16-bit registers:
AX - the Accumulator
BX - the Base Register
CX - the Count Register
DX - the Data Register
SP - the Stack Pointer \ defaults to stack segment
BP - the Base Pointer /
SI - the Source Index Register
DI - the Destination Register
These are referred to as general-purpose registers, although, as seen by
their names, they often have a special-purpose use for some instructions.
The AX, BX, CX, and DX registers can be considers as two 8-bit registers, a
High byte and a Low byte. This allows byte operations and compatibility with
the previous generation of 8-bit processors, the 8080 and 8085. 8085 source
code could be translated in 8086 code and assembled. The 8-bit registers are:
AX --> AH,AL
BX --> BH,BL
CX --> CH,CL
DX --> DH,DL
8086 Programmer’s Model
ES
CS
SS
DS
IP
BIU registers
(20 bit adder)
EU registers
AX
BX
CX
DX
AH
BH
CH
DH
Extra Segment
Code Segment
Stack Segment
Data Segment
Instruction Pointer
AL
BL
CL
DL
SP
BP
SI
DI
FLAGS
Accumulator
Base Register
Count Register
Data Register
Stack Pointer
Base Pointer
Source Index Register
Destination Index Register
8086/88 internal registers 16 bits (2 bytes each)
AX, BX, CX and DX are two
bytes wide and each byte can
be accessed separately
These registers are used as
memory pointers.
Flags will be discussed later
Segment registers are used
as base address for a segment
in the 1 M byte of memory
The 8086/8088 Microprocessors: Registers
• Registers
– Registers are in the CPU and are referred to by
specific names
– Data registers
• Hold data for an operation to be performed
• There are 4 data registers (AX, BX, CX, DX)
– Address registers
•
•
•
•
Hold the address of an instruction or data element
Segment registers (CS, DS, ES, SS)
Pointer registers (SP, BP, IP)
Index registers (SI, DI)
– Status register
• Keeps the current status of the processor
• On an IBM PC the status register is called the FLAGS
register
– In total there are fourteen 16-bit registers in an
Data Registers: AX, BX, CX, DX
• Instructions execute faster if the data is in a register
• AX, BX, CX, DX are the data registers
• Low and High bytes of the data registers can be accessed
separately
– AH, BH, CH, DH are the high bytes
– AL, BL, CL, and DL are the low bytes
• Data Registers are general purpose registers but they also perform
special functions
• AX
– Accumulator Register
– Preferred register to use in arithmetic, logic and data
transfer instructions because it generates the shortest
Machine Language Code
– Must be used in multiplication and division operations
– Must also be used in I/O operations
• BX
–
–
–
–
Base Register
Also serves as an address register
Used in array operations
Used in Table Lookup operations (XLAT)
• CX
– Count register
– Used as a loop counter
– Used in shift and rotate operations
• DX
– Data register
– Used in multiplication and division
– Also used in I/O operations
Pointer and Index Registers
• Contain the offset addresses of memory locations
• Can also be used in arithmetic and other operations
• SP: Stack pointer
– Used with SS to access the stack segment
• BP: Base Pointer
– Primarily used to access data on the stack
– Can be used to access data in other segments
• SI: Source Index register
– is required for some string operations
– When string operations are performed, the SI
register points to memory locations in the data
segment which is addressed by the DS register.
Thus, SI is associated with the DS in string
operations.
• DI: Destination Index register
– is also required for some string operations.
– When string operations are performed, the DI
register points to memory locations in the data
segment which is addressed by the ES register.
Thus, DI is associated with the ES in string
operations.
• The SI and the DI registers may also be used to access data
stored in arrays
Segment Registers - CS, DS, SS and ES
• Are Address registers
• Store the memory addresses of instructions and data
• Memory Organization
– Each byte in memory has a 20 bit address starting with
0 to 220-1 or 1 meg of addressable memory
– Addresses are expressed as 5 hex digits from 00000 FFFFF
– Problem: But 20 bit addresses are TOO BIG to fit in 16
bit registers!
– Solution: Memory Segment
•
•
•
•
Block of 64K (65,536) consecutive memory bytes
A segment number is a 16 bit number
Segment numbers range from 0000 to FFFF
Within a segment, a particular memory location is specified
with an offset
• An offset also ranges from 0000 to FFFF
Segmented Memory
Segmented memory addressing: absolute (linear) address
is a combination of a 16-bit segment value added to a 16bit offset
F0000
E0000
8000:FFFF
D0000
C0000
B0000
A0000
one segment
90000
80000
70000
60000
8000:0250
50000
0250
40000
30000
8000:0000
20000
10000
00000
seg
ofs
Intel
Memory Address
Generation
• The BIU has a dedicated adder for
determining physical memory
addresses
Offset Value (16 bits)
Segment Register (16 bits)
0000
Adder
Physical Address (20 Bits)
Intel
Example Address
Calculation
• If the data segment starts at
location 1000h and a data
reference contains the address 29h
9
2 data?
where is the actual
Offset:
0000000000101001
Segment:
0001000000000000 0000
Address:
0001000000000010 1001
Segment:Offset Address
• Logical Address is specified as segment:offset
• Physical address is obtained by shifting the segment address 4
bits to the left and adding the offset address
• Thus the physical address of the logical address A4FB:4872 is
A4FB0
+ 4872
A9822
Your turn . . .
What linear address corresponds to the segment/offset
address 028F:0030?
028F0 + 0030 = 02920
Always use hexadecimal notation for addresses.
Your turn . . .
What segment addresses correspond to the linear address
28F30h?
Many different segment-offset addresses can produce the
linear address 28F30h. For example:
28F0:0030, 28F3:0000, 28B0:0430, . . .
The Code Segment
0H
CS:
4000H
0400H
IP
4056H
0056H
CS:IP = 400:56
Logical Address
Memory
0400 0
Segment Register
+
Offset
Physical or
Absolute Address
0056
04056H
0FFFFFH
The offset is the distance in bytes from the start of the segment.
The offset is given by the IP for the Code Segment.
Instructions are always fetched with using the CS register.
The physical address is also called the absolute address.
The Data Segment
0H
DS:
05C00H
05C0
05C50H
EA
0050
DS:EA
Memory
05C0
Segment Register
+
Offset
Physical Address
0
0050
05C50H
0FFFFFH
Data is usually fetched with respect to the DS register.
The effective address (EA) is the offset.
The EA depends on the addressing mode.
The Stack Segment
0H
SS:
0A000H
0A00
0A100H
SP
0100
SS:SP
Memory
0A00 0
Segment Register
Offset
Physical Address
+
0100
0A100H
0FFFFFH
The offset is given by the SP register.
The stack is always referenced with respect to the stack segment register.
The stack grows toward decreasing memory locations.
The SP points to the last or top item on the stack.
PUSH - pre-decrement the SP
POP - post-increment the SP
Flags
Carry flag
Overflow
Parity flag
Direction
Interrupt enable
Auxiliary flag
Trap
6 are status flags
3 are control flag
Zero
Sign
Flag Register
• Conditional flags:
– They are set according to some results of arithmetic
operation. You do not need to alter the value yourself.
• Control flags:
– Used to control some operations of the MPU. These flags
are to be set by you in order to achieve some specific
purposes.
Flag
Bit no.
15
14
13
12
O
D
I
T
S
Z
11
1
0
9
8
7
6
A
5
4
P
3
2
• CF (carry) Contains carry from leftmost bit following
arithmetic, also contains last bit from a shift or rotate
operation.
C
1
0
Flag Register
• OF (overflow) Indicates overflow of
the leftmost bit during arithmetic.
• DF (direction) Indicates left or
right for moving or comparing
string data.
• IF (interrupt) Indicates whether
external interrupts are being
processed or ignored.
• TF (trap) Permits operation of the
processor in single step mode.
• SF (sign) Contains the resulting
sign of an arithmetic operation
(1=negative)
• ZF (zero) Indicates when the result
of arithmetic or a comparison is
zero. (1=yes)
• AF (auxiliary carry) Contains carry
out of bit 3 into bit 4 for
specialized arithmetic.
• PF (parity) Indicates the number of
1 bits that result from an
operation.
Minimum-Mode and MaximumMode System

Minimum-Mode and MaximumMode System (cont.)
Signals common to both minimum and maximum mode
Minimum-Mode and MaximumMode System (cont.)
Unique minimum-mode signals
Minimum-Mode and MaximumMode System (cont.)
Unique maximum-mode signals
Minimum-Mode and MaximumMode System (cont.)

Minimum-Mode Interface
Block diagram of the minimum-mode 8088 MPU
Minimum-Mode Interface (cont.)
Block diagram of the minimum-mode 8086 MPU
Minimum-Mode Interface (cont.)

The minimum-mode signals can be divided into
the following basic groups:





Address/Data bus
Status signals
Control signals
Interrupt signals
DMA interface signals
Minimum-Mode Interface (cont.)

Address/Data bus


The address bus is used to carry address
information to the memory and I/O ports
The address bus is 20-bit long and consists of
signal lines A0 through A19


Only address line A0 through A15 are used when
addressing I/O.



A 20-bit address gives the 8088 a 1 Mbyte
memory address space
This give an I/O address space of 64 Kbytes
The 8088 has 8 multiplexed address/data bus
lines (A0~A7)
8086 has 16 multiplexed address/data bus lines
(A0~A15)
Minimum-Mode Interface (cont.)

Status signals

The four most significant address, A19 through
A16 are multiplexed with status signal S6
through S3



Bits S4 and S3 together form a 2-bit binary code
that identifies which of the internal segment
registers was used to generate the physical
address.
S5 is the logic level of the internal interrupt flag.
S6 is always at the 0 logic level
Minimum-Mode Interface (cont.)

Minimum-Mode Interface (cont.)

Minimum-Mode Interface (cont.)

Maximum-Mode Interface

The maximum-mode configuration is mainly
used for implementing a
multiprocessor/coprocessor system
environment



Global resources and local resources



Multiple processors exist in the system
Each executes its own program
The former are common to all processors
The latter are assigned to specific processors
In the maximum-mode, facilities are provided
for implementing allocation of global resources
and passing bus control to other
microprocessors sharing the system bus
Maximum-Mode Interface (cont.)
8088 maximum-mode block diagram
Maximum-Mode Interface (cont.)
8086 maximum-mode block diagram
Maximum-Mode Interface (cont.)

8288 bus controller
Block diagram and pin layout of 8288
Maximum-Mode Interface (cont.)

8288 bus controller



In the maximum-mode, 8088/8086 outputs a
status code on three signal line, S0, S1, S2, prior
to the initialization of each bus cycle
The 3-bit bus status code identifies which type of
bus cycle is to follow and are input to the
external bus controller device, 8288
The 8288 produces one or two command signals
for each bus cycle
Maximum-Mode Interface (cont.)

8288 bus controller
Bus status code
Maximum-Mode Interface (cont.)

Maximum-Mode Interface (cont.)

Maximum-Mode Interface (cont.)

Queue status signals

The 2-bit queue status code QS0 and QS1 tells
the external circuitry what type of information
was removed form the queue during the previous
clock cycle
Queue status code
Electrical Characteristics



Power is applied between pin 40 (Vcc) and pins
1 (GND) and 20 (GND)
The nominal value of Vcc is specified as +5V dc
with a tolerance of ±10%.
Both 8088 and 8086 draw a maximum of
340mA from the supply
I/O voltage levels
System Clock

The time base for synchronization of the
internal and external operations of the
microprocessor in a microcomputer system is
provided by the clock (CLK) input signal



The standard 8088 operates at 5 MHz and the
8088-2 operates at 8 MHz
The 8086 is manufactured in three speeds: 5MHz 8086, 8-MHz 8086-2, and the 10-MHz
8086-1
The CLK is externally generated by the 8284
clock generator and driver IC
System Clock (cont.)

Block diagram of the 8284 clock generator
System Clock (cont.)

Block diagram of the 8284 clock generator
System Clock (cont.)

Connecting the 8284 to the 8088
15- or 24MHz
crystal
Typical value of CL when used with
15MHz crystal is 12pF
The fundamental crystal frequency is divided
by 3 within the 8284 to give either a 5- or 8MHz clock signal
System Clock (cont.)

CLK waveform


The signal is specified at Metal Oxide
Semiconductor (MOS)-compatible voltage level
The period of the 5-MHz 8088 can range from
200 ns to 500 ns, and the maximum rise and fall
times of its edges equal 10 ns
System Clock (cont.)

PCLK and OSC signals


The peripheral clock (PCLK) and oscillator clock
(OSC) signals are provided to drive peripheral
ICs
The clock output at PCLK is half the frequency of
CLK. The OSC output is at the crystal frequency
which is three times of CLK
System Clock (cont.)

The 8284 can also be driven from an external
clock source


Applied to the EFI (External Frequency Input)
Input F/C is used for selection



0: crystal between X1 and X2 is used
1: selects EFI
The CSYNC input is used for external
synchronization in systems with multiple
clocks
System Clock (cont.)

EXAMPLE


If the CLK input of an 8086 MPU is to be driven
by a 9-MHz signal, what speed version of the
8086 must be used and what frequency crystal
must be attached to the 8284
Solution:

The 8086-1 is the version of the 8086 that can
be run at 9-MHz. To create the 9-MHz clock, a
27-MHz crystal must be used on the 8284.
Bus Cycle and Time States





A bus cycle defines the basic operation that a
microprocessor performs to communicate with
external devices.
Examples of bus cycles are the memory read,
memory write, input/output read, and
input/output write.
The bus cycle of the 8088 and 8086
microprocessors consists of at least four clock
periods.
If no bus cycles are required, the
microprocessor performs what are known as
idle states.
When READY is held at the 0 level, wait states
are inserted between states T3 and T4 of the
bus cycle.
Bus Cycle and Time States (cont.)
Bus cycle clock periods, idle state, and wait state
Bus Cycle and Time States (cont.)

EXAMPLE


What is the duration of the bus cycle in the 8088based microcomputer if the clock is 8 MHz and
the two wait states are inserted.
Solution:


The duration of the bus cycle in an 8 MHz system
is given by
 tcyc = 500 ns + N x 125 ns
In this expression the N stands for the number of
waits states. For a bus cycle with two wait states,
we get
 tcyc = 500 ns + 2 x 125 ns = 500 ns + 250 ns
= 750 ns
Hardware Organization of the
Memory Address Space
1Mx8 memory bank of the 8088
Hardware Organization of the
Memory Address Space (cont.)
High and low memory banks of the 8086
Hardware Organization of the
Memory Address Space (cont.)
Byte transfer by the 8088
Hardware Organization of the
Memory Address Space (cont.)
Word transfer by the 8088
Hardware Organization of the
Memory Address Space (cont.)
Even address byte transfer by the 8086
Hardware Organization of the
Memory Address Space (cont.)
Odd address byte transfer by the 8086
Hardware Organization of the
Memory Address Space (cont.)
Even address word transfer by the 8086
Hardware Organization of the
Memory Address Space (cont.)
Odd-address word transfer by the 8086
Hardware Organization of the
Memory Address Space (cont.)

EXAMPLE


Is the word at memory address 0123116 of an
8086-based microcomputer aligned or misaligned?
How many cycle are required to read it from
memory?
Solution:

The first byte of the word is the second byte at
the aligned-word address 0123016. Therefore, the
word is misaligned and required two bus cycles to
be read from memory.
Address Bus Status Codes

Whenever a memory bus cycle is in progress,
an address bus status code S4S3 is output by
the processor.


S4S3 identifies which one of the four segment
register is used to generate the physical address
in the current bus cycle:
 S4S3=00 identifies the extra segment
register (ES)
 S4S3=01 identifies the stack segment
register (SS)
 S4S3=10 identifies the code segment register
(CS)
 S4S3=11 identifies the data segment register
(DS)
The memory address reach of the
microprocessor can thus be expanded to 4
Mbytes.
Memory Control Signals

Minimum-mode memory control signals
Memory Control Signals (cont.)

Minimum-mode memory control signals (8088)







ALE – Address Latch Enable – used to latch the
address in external memory.
IO/M – Input-Output/Memory – signal
external circuitry whether a memory of I/O bus
cycle is in progress.
DT/R – Data Transmit/Receive – signal
external circuitry whether the 8088 is
transmitting or receiving data over the bus.
RD – Read – identifies that a read bus cycle is in
progress.
WR – Write – identifies that a write bus cycle is
in progress.
DEN – Data Enable – used to enable the data
bus.
SSO – Status Line – identifies whether a code or
data access is in progress.
Memory Control Signals (cont.)

The control signals for the 8086’s minimummode memory interface differs in three ways:



IO/M signal is replaced by M/IO signal.
The signal SSO is removed from the interface.
BHE (bank high enable) is added to the interface
and is used to select input for the high bank of
memory in the 8086’s memory subsystem.
Memory Control Signals (cont.)

Maximum-mode memory control signals
Memory Control Signals (cont.)

Maximum-mode memory control signals



MRDC – Memory Read Command
MWTC – Memory Write Command
AMWC – Advanced Memory Write Command
Read and Write Bus Cycle

Read cycle
Minimum-mode memory read bus cycle of the 8088
Read and Write Bus Cycle (cont.)

Read cycle
Minimum-mode memory read bus cycle of the 8086
Read and Write Bus Cycle (cont.)

Read cycle
Maximum-mode memory read bus cycle of the 8086
Read and Write Bus Cycle (cont.)

Write cycle
Minimum-mode memory write bus cycle of the 8088
Read and Write Bus Cycle (cont.)

Write cycle
Maximum-mode memory write bus cycle of the 8086
Memory Interface Circuit




Address bus latches and buffers
Bank write and bank read control logic
Data bus transceivers/buffers
Address decoders
Memory Interface Circuit (cont.)
Memory interface block diagram
Memory Interface Circuit (cont.)

Address bus latches and buffers
Block diagram of a D-type latch
Memory Interface Circuit (cont.)

Address bus latches and buffers
Circuit diagram of the 74F373
Memory Interface Circuit (cont.)

A review of flip-flop/latch logic
Positive edge-triggered D flip-flop
Memory Interface Circuit (cont.)

A review of flip-flop/latch logic
Positive edge-triggered JK flip-flop
Memory Interface Circuit (cont.)

A review of flip-flop/latch logic
D-type latch
Memory Interface Circuit (cont.)

Address bus latches and buffers
Address latch circuit
Memory Interface Circuit (cont.)

Bank write and bank read control logic
Bank write control logic
Bank read control logic
Memory Interface Circuit (cont.)

Data bus transceivers
Block diagram and circuit
diagram of the 74F245 octal bus
transceiver
Memory Interface Circuit (cont.)

Data bus transceivers
Data bus transceiver circuit
Memory Interface Circuit (cont.)

Address decoder
Address bus configuration with address decoding
Memory Interface Circuit (cont.)

Address decoder
Block diagram and operation of the 74F139 decoder
Memory Interface Circuit (cont.)

Address decoder
Circuit diagram of the 74F139 decoder
Memory Interface Circuit (cont.)

Address decoder
Address decoder circuit using 74F139
Memory Interface Circuit (cont.)

Address decoder
Block diagram and operation of the 74F138 decoder
Memory Interface Circuit (cont.)

Address decoder
Circuit diagram of the 74F138 decoder
Memory Interface Circuit (cont.)

Address decoder
Address decoder circuit using 74F138
Types of Input/Output

The I/O system allows peripherals to provide
data or receive results of processing the data


Using I/O ports
The 8088/8086 MPU can employ two types
of I/O


Isolated I/O
Memory-mapped I/O

They differ in how I/O ports are mapped into the
address space
Types of Input/Output (cont.)

Isolated input/output

When using isolated I/O in a microcomputer
system, the I/O device are treated separate from
memory




The memory address space contains 1 M consecutive
byte address in the range 0000016 through FFFFF16
The I/O address space contains 64K consecutive byte
addresses in the range 000016 through FFFF16
The bytes in two consecutive I/O addresses can
be accessed as word-wide data
Page 0: 000016  00FF16

Certain I/O instructions can only perform in this range
Types of Input/Output (cont.)

Isolated input/output
8088/8086 memory and I/O address spaces
Types of Input/Output (cont.)

Isolated input/output
Isolated I/O ports
Types of Input/Output (cont.)

Isolated input/output

Advantages:




The complete 1Mbyte memory address space is
available for use with memory
Special instructions have been provided to perform
I/O operations with maximized performance
The bytes in two consecutive I/O addresses can
be accessed as word-wide data
Disadvantages:

All input and output data transfers must take place
between the AL or AX register and I/O port
Types of Input/Output (cont.)

Memory-mapped input/output

MPU looks at the I/O port as though it is a
storage location in memory


Instructions that affect data in memory are used
instead of the special I/O instructions




Some of the memory address space is dedicated to
I/O ports
More instructions and addressing modes are available
to perform I/O operations
I/O transfers can take place between I/O port and
other internal registers
The memory instructions tend to execute slower
than those specifically designed for isolated I/O
Part of the memory address space is lost
Types of Input/Output(cont.)

Memory-mapped input/output
Memory mapped I/O ports
Isolated Input/Output Interface

I/O devices:





Keyboard
Printer
Mouse
82C55A, etc
Functions of interface circuit:





Select the I/O port
Latch output data
Sample input data
Synchronize data transfer
Translate between TTL voltage levels and those
required to operate the I/O devices
Isolated Input/Output Interface
(cont.)

Minimum-mode interface
Minimum-mode 8088 system I/O interface
Isolated Input/Output Interface
(cont.)

Minimum-mode interface
Minimum-mode 8086 system I/O interface
Isolated Input/Output Interface
(cont.)

Maximum-mode interface
Maximum-mode 8088 system I/O interface
Isolated Input/Output Interface
(cont.)

Maximum-mode interface
Maximum-mode 8086 system I/O interface
Isolated Input/Output Interface
(cont.)

Maximum-mode interface
I/O bus cycle status codes
Input/Output Data Transfer



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
Input/output data transfers in the 8088 and
8086 microcomputers can be either byte-wide
or word-wide
I/O addresses are 16 bits in length and are
output by the 8088 to the I/O interface over
bus lines AD0 through AD7 and A8 through A15
In 8088, the word transfers is performed as
two consecutive byte-wide data transfer and
takes two bus cycle
In 8086, the word transfers can takes either
one or two bus cycle
Word-wide I/O ports should be aligned at
even-address boundaries
Input/Output Data Instructions
Input/Output Data Instructions
(cont.)
EXAMPLE:

Write a sequence of instructions that will output
the data FF16 to a byte-wide output port at
address AB16 of the I/O address space.
Solution:


First, the AL register is loaded with FF16 as an
immediate operand in the instruction
MOV AL, 0FFH
Now the data in AL can be output to the bytewide output port with the instruction
OUT 0ABH, AL
Input/Output Data Instructions
(cont.)
EXAMPLE:

Write a series of instructions that will output FF16
to an output port located at address B00016 of
the I/O address space
Solution:



The DX register must first be loaded with the
address of the output port. This is done with the
instruction
MOV DX, 0B000H
Next, the data that are to be output must be
loaded into AL with the instruction
MOV AL, 0FFH
Finally, the data are output with the instruction
OUT DX, AL
Input/Output Data Instructions
(cont.)
EXAMPLE:

Data are to be read in from two byte-wide input
ports at addresses AA16 and A916 and then output
as a word-wide output port at address B00016.
Write a sequence of instructions to perform this
input/output operation.
Input/Output Data Instructions
(cont.)
Solution:



First read in the byte at address AA16 into AL and
move it into AH.
IN AL, 0AAH
MOV AH, AL
Now the other byte can be read into AL by the
instruction
IN AL, 09AH
And to write out the word of data
MOV DX, 0B000H
OUT DX, AX
Input/Output Bus Cycles

Input bus cycle of the 8088
Input/Output Bus Cycles (cont.)

Output bus cycle of the 8088
Input/Output Bus Cycles (cont.)

Input bus cycle of the 8086
Input/Output Bus Cycles (cont.)

Output bus cycle of the 8086