Chapter 2 Number conversion (BCD) 8086 microprocessor Internal registers Making of Memory address.

67
Chapter 2 Number conversion (BCD) 8086 microprocessor Internal registers Making of Memory address

Transcript of Chapter 2 Number conversion (BCD) 8086 microprocessor Internal registers Making of Memory address.

Chapter 2

Number conversion (BCD) 8086 microprocessor Internal registers Making of Memory address

Instruction Execution (MOV A, X)

8088 RAM

Address Bus

Cod

e

MOV A, X

Data Bus

Dat

a

3

Fetch InstructionIssue Address of

MOV A, X

Control Bus

Decode InstructionDecoding MOV A, X

Execute InstructionIssue Address of X

8088 Processor

Address Lines Data Lines Control Lines Power/GND Lines Clock (33% Duty cycle) Reset

Pin held high for min. of 4 clk cycles

Executes instruction at FFFF0 H

Disables interrupts

Address & Data Bus

Address Bus Size Size of Memory accessible by Processor 20 bit = 1 MByte 8088 A0 - A19 Address Lines

Data Bus Size Chunk of Data accessible 8088 D0 – D7 Data Lines

8086 D0 – D15 Data Lines

8088 Address and Data Bus Multiplexed

Multipurpose/General Purpose Registers AX Accumulator 16-bit register

AH and AL 8-bit Registers AX Used for Arithmetic & logical operations Used specifically for multiplication, division

and adjustment instructions Holds offset address of a location in memory

BX Base Index 16-bit register BH and BL 8-bit Registers Used for Arithmetic and Data operations Holds offset address of a location in memory

Multipurpose/General Purpose Registers CX Count 16-bit register

CH and CL 8-bit Registers Used for Arithmetic and data operations Holds count value for various instructions Counts the number of characters in string

operations

Multipurpose/General Purpose Registers DX Data 16-bit register

DH and DL 8-bit Registers Used for Arithmetic and Data Operations Holds the high 16-bits of the product in

multiplication operations Holds remainder for 16-bit division Holds I/O addresses

Base Registers

Base Pointer BP 16-bit Register Points to a memory location Holds an offset or displacement from Stack

Segment (SS) Register Used by subroutines to locate variables

passed on stack by calling program BX Base Index 16-bit register

BH and BL 8-bit Registers Used for Arithmetic and Data operations Holds offset address of a location in memory

Index Registers

Destination Index DI 16-bit Register Addresses string destination for string

instructions Holds an offset or displacement from ES

register Source Index SI 16-bit Register

Addresses string source for string instructions Holds an offset or displacement from DS

register

Stack Pointer Registers

Stack Pointer SP 16-bit Register Addresses Stack memory Holds an offset or displacement from SS

Register Contents are combined with contents of SS

Register to give address of top of stack

Special Registers

Instruction Pointer IP 16-bit Register Points to the next instruction in the Code Segment Contents are combined with contents of Code

Segment (CS) Register to give address of next instruction to be fetched

Flag 16-bit Register Contents of this register are neither data nor address Individual bits in this register indicate different status

information Individual bits are set (1) or cleared (0) as a result of

an operation by the microprocessor

Special Registers

Bit 0: Carry Flag Set to indicate occurrence of Carry

Bit 2: Parity Flag Set to indicate even Parity

Bit 4: Auxiliary Flag Set to indicate occurrence of Aux. carry

Bit 6: Zero Flag Set to indicate Zero result

Special Registers

Bit 7: Sign Flag Set to indicate a negative number

Bit 8: Trap Flag Set to enable Debug mode

Bit 9: Interrupt Flag Set to indicate interrupt enabled

Bit 10: Direction Flag Set to 1 automatically decrements DI & SI Set to 0 automatically increments DI & SI

Special Registers

Bit 11: Overflow Flag Set to indicate an overflow

Lecture 02 16

DC Characteristics

Input Characteristics Input current and voltage requirements Logic 0 0.8 Vmax ±10 Amax

Logic 1 2 Vmin ±10 Amax

Inputs gate connections of MOSFETs Leakage currents

Lecture 02 17

DC Characteristics

Output Characteristics Output current and voltage requirements Logic 0 0.45 Vmax 2.0 mAmax

Logic 1 2.4 Vmin -400 Amax

Reduced noise immunity 350 mV Avoid long connections Avoid too many loads

Max. 10 loads without Buffering

How to make address.

CHAPTER 8

Lecture 02 20

Bus Buffering & Latching

Bus should be buffered for large systems Multiplexed Address & Data Buses should be

De-multiplexed Why De-multiplexed Buses?

Address on the Address Bus has to remain constant throughout a read and write cycle

Read and Write Cycle? 8088/8086 read/write operation is completed

in a minimum period of 4 clocks

Lecture 02 21

Bus De-Multiplexing

During T1 clock of Read/write cycle 8088 issues address AD0 to AD7 & A8 to A19

8088 activates ALE signal (Address Latch Enable)

Lecture 02 22

373 Latch

Lecture 03 23

Bus Buffering

Address Lines A0 – A19 have to be buffered A0 – A7 & A16 – A19 have been buffered by 373 Logic 0 sinks 32 mA Logic 1 sources 5.2 mA

A8 – A15 have to be buffered

74LS244 Octal Buffer used for Buffering

De-multiplexed Bus

8088

AD0 – AD7

373 Latch

373

A0 – A7

A8 – A15

A16 – A19

ALELE

LE

GND

GND

OE*

OE*

D0 – D7

Lecture 03 25

Clock Circuitry

Clock Generator 8284 Clock Signals Reset Synchronization READY Synchronization TTL-level peripheral clock

Lecture 04 26

Clock Generator 8284

Lecture 04 27

Processor RESET

RESET pin needs to remain high for min. of 4 clocks and must not go low for at least 50 s

8284

+ 5 V

10K

10F

RES*

RESET

Lecture 04 28

Bus Timing

Memory & I/O is slow Rate of data transfer depends on access time

of Memory & I/O Processor Read/Write cycles have to be

extended to allow transfer from slow devices Basic Bus Operation

Address, Data and Control Buses are involved in reading and writing of data

Address, Data and Control Bus operations are carried out in a sequence

Lecture 04 29

Bus Timing

8086/8088 use the Memory/IO in periods called Bus Cycles

Each Bus Cycle equals 4 system clocking periods (T states) Pentium has 2 T state Bus cycle

At 5 MHz, one Bus cycle is completed at 0.8 sec or 800 nsec

Processor can read/write at a max. rate of 1.25 million times a sec.

Lecture 04 30

Bus Timing

With internal queue processor can execute 2.5 million instructions per sec. [MIPS] in bursts Pentium operates at much higher rates due to

higher clock rates, shorter Bus cycle and internal queuing

Lecture 04 31

Bus Timing T1 Clock

Address of the Memory/IO is issued via the Address/Data Multiplexed Bus

Following Signals are also issued ALE Address Latch Enable signal DT/R* Data Transmit/Receive signal IO/M* IO/Memory signal

Lecture 04 32

Bus Timing T2 & T3 Clocks

RD* or WR* Read or Write Signal is issued Incase of Write the Data to be written also

appears on the Data Bus DEN* Data Bus Enable signal is issued READY signal is sampled at the end of T2

If READY is low T3 becomes a Wait State TW

READY is again sampled in the middle of Wait State

If the Bus Cycle is Read Cycle, Data Bus is sampled at the end of T3

Lecture 04 33

Bus Timings T4 Clock

All Bus signals are deactivated in preparation for the next Bus Cycle

During a Read Cycle the processor continues to sample the Data Bus during T4 cycle

During a Write Cycle the trailing edge of the Write signal transfers the data to Memory or IO

Minimum Vs. Maximum Mode

8088/8086 has two Modes of operation Minimum Mode Maximum Mode

Minimum Mode Operation similar to 8085 (8 bit processor) MN/MX* pin connected to +5 V 8-bit peripherals can be used with 8088/8086

Minimum Vs. Maximum Mode

Maximum Mode Enhanced Operation used whenever a

coprocessor is used with 8088/8086 MN/MX* pin connected to GND 8288 Bus Controller required to generate extra

signals

Summary

Memory Interface

Memory Pin Connections

Address Pins Data Pins Control Pins Selection Pins

Address Lines Data Lines

Write*

Read*

WE

OESelect*

CS

Memory Interface

Address Pins Number of locations

in memory determine the number of Address Pins

4 K = 12 lines 1 M = 20 lines

Address Lines Data Lines

Write*

Read*

WE

OESelect*

CS

Memory Interface

Data Pins Width of memory

determines the number of Data Pins

8 bit width = 8 lines 1 bit width = 1 line

Address Lines Data Lines

Write*

Read*

WE

OESelect*

CS

Memory Interface

ROM Control Pins OE* or G* allows

data to flow out RAM Control Pins

WE* allows data to be written

OE*allows data to be read

Can have a single R/W* pin

Address Lines Data Lines

Write*

Read*

WE

OESelect*

CS

Memory Interface

Selection Pins CE* or CS* allows

the RAM/ROM chip to be selected

Sometimes there are more than one CS* signal

Address Lines Data Lines

Write*

Read*

WE

OESelect*

CS

ROM

Read Only ROM Permanently stores program/data Does not allow write (read Only)

2764 (8 KB) EPROM

Address Decoding

Processors have very large address space Pentium 4 has a 64 GB memory space

Entire memory space is not used Processor memory space is used for specific

purpose Operating System Program Code Data Interrupt Vector Table

Address Decoding

RAM, ROM and I/O devices are mapped in the processor memory space

More memory can be added in the vacant memory space

Memory Mapping

Least significant lines of the processor address bus always connected to the address lines of the Memory chip (A0 – A18)

Most significant line(s) of the processor address bus always used for mapping memory chip in the address space and connected to the chip select (A19)

First 512 KB Ram chip selected when A19 = 0 Second 512 KB Ram chip selected when A19

= 1

Memory Mapping

512 KB

512 KB

A0 – A18

A0 – A18

D0 – D7

D0 – D7

RD*WR*

CS*

CS*

A19

A19*

Memory Mapping

256 KB RAM chip (A0 – A17)

Four 256 KB RAM chips should be connected to completely map the 1 MB processor memory space

Address Lines A18 & A19 used for chip selection

Gate Decoder

1st 256 KB RAM chip selected when A19 = 0 & A18 = 0 A two input OR gate

2nd 256 KB RAM chip selected when A19 = 0 & A18 = 1 A two input OR gate with A18 input inverted

3rd 256 KB RAM chip selected when A19 = 1 & A18 = 0 A two input OR gate with A19 input inverted

4th 256 KB RAM chip selected when A19 = 1 & A18 = 1 A two input NAND gate

Lecture 08 50

Designing Address Decoders

Flexible Design can be easily modified

Allow for future expansion Should introduce minimum gate delay Low chip count

Lecture 08 51

Address Decoding

Full Address Decoding Entire address space is fully decoded More decoding circuitry is required

Partial Address Decoding Address space is not fully decoded Less decoding circuitry is required Address clashes occur

Block Address Decoding Memory space divided into blocks of equal

sizes

Lecture 08 52

Address Decoding example

OS 8K ROM1

Vector Table 4K RAM1

Data Memory 32K RAM3

Program Memory 64K RAM2

Ports 256 B

Buffer 2K RAM4

Stack 64K RAM5

00000 H

02000 H

10000 H

20000 H

A0000 H

B0000 H

F0000 H

Lecture 08 53

Address Decoding example

A19

A16

A15

A14

A13

ROM1 CS*

A15

A14

A12

A13

RAM1 CS*

Lecture 08 54

Address Decoding example

A19

A18RAM2 CS*

A15

RAM3 CS*

A17

A16

A19

A18

A17

A16

Lecture 08 55

Address Decoding example

A19

A18PORTS CS*

A11

RAM4 CS*

A17

A16

A19

A18

A17

A16

A15

A12

A11

A08

A19

A16

RAM5 CS*

Lecture 08 56

Types of Address Decoders

Logic Gate Decoders Simple Irregular structure No future expansion allowed

M x N Decoders Regular structure Future expansion allowed Divides address space into equal sized blocks

Lecture 08 57

Types of Address Decoders

ROM based Decoders Very flexible New decoding scheme implemented by

reprogramming the ROM PLDs based Decoders

Very flexible have replaced PROM based Decoders

Lecture 09 58

Block-Address Decoding example

PORTS CS*

RAM4 CS*

RAM5 CS*

4 X 16 Decoder

A16

A17

A13

ROM1 CS*

RAM1 CS*

RAM2 CS*

RAM3 CS*A15

A18

A19 012

101115

Lecture 09 59

Address Decoding Example

Map the memory chips in contiguous memory locations starting from address 0000 H with minimal empty slots

2K ROM1, 4K RAM1, 1K RAM2, 2K RAM3 How should it be done?

Start by sketching an Address Decoding Table

Lecture 09 60

Address Decoding Example

A15 – A12 A11 – A8 A7 – A4 A3 – A0

ROM1 2K 0000 0XXX XXXX XXXX

RAM1 4K 0001 XXXX XXXX XXXX

RAM2 1K 0010 00XX XXXX XXXX

RAM3 2K 0010 1XXX XXXX XXXX

Lecture 10 61

Types of Address Decoders

Logic Gate Decoders Simple Irregular structure No future expansion allowed High chip count High decoding speed

Lecture 10 62

Types of Address Decoders

M x N Decoders Regular structure Future expansion allowed Divides address space into equal sized blocks Low chip count

Lecture 10 63

Types of Address Decoders

ROM based Decoders Very flexible New decoding scheme implemented by

reprogramming the ROM PLDs based Decoders

Very flexible have replaced PROM based Decoders

8088 Processor

Address Lines Data Lines Control Lines Power/GND Lines Clock (33% Duty cycle) Reset

Pin held high for min. of 4 clk cycles

Executes instruction at FFFF0 H

Disables interrupts

8288 bus controller

8288 bus controller

8155 chip