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8085 Microprocessor
Prof. K. Adisesha
1
Microprocessor
Microprocessor is defined as a silicon chip embedded with a Central Processing Unit or CPU. It is also
referred to as a computer's logic chip, micro chip, and processor. Advantages of Microprocessors is that these are general purpose electronic processing devices which can be programmed to execute a number of tasks. These are used in personal computers as well as a number of other
embedded products. There are no disadvantages as such but when compared tofixed logic devices or certain ASICs (application
specific intergrated circuits), there is a need to program Microprocessors and write software/firmware when used in embedded applications.
Function
The function of a Microprocessor is to conduct arithmetic and logic operations.
Speed
One advantage of a Microprocessor is its speed, which is measured in hertz. For instance, a Microprocessor with 3 gigahertz, shortly GHz, is capable of performing 3 billion tasks per second.
Data Movement
Another advantage of a Microprocessor is that it can quickly move data between the various memory locations.
Complex Mathematics
Microprocessors are used to perform complicated mathematical operations, like operating on the floating point numbers.
Disadvantages
Some of the disadvantages with the Microprocessor are that it might get over-heated, and the limitation it
imposes on the size of data.
Applications of Microprocessors
Microprocessors are a mass storage device. They are the advanced form of computers. They arealso called as microcomputers. The impact of microprocessor in different lures of fields is significant. The availability of
low cost, low power and small weight, computing capability makes it useful in different applications. Now a days, a microprocessor based systems are used in instructions, automatic testing product, speed control of
motors, traffic light control , light control of furnaces etc. Some of the important areas are mentioned below:
Instrumentation:
it is very useful in the field of instrumentation. Frequency counters, function generators, frequency synthesizers, spectrum analyses and many other instruments are available, when microprocessors are used as
controller. It is also used in medical instrumentation.
Control:
Microprocessor based controllers are available in home appliances, such as microwave oven, washing
machine etc., microprocessors are being used in controlling various parameters like speed, pressure, temperature etc. These are used with the help of suitable transduction.
Communication:
Microprocessors are being used in a wide range of communication equipments. In telephone industry, these are used in digital telephone sets. Telephone exchanges and modem etc. The use of microprocessor in
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television, satellite communication have made teleconferencing possible. Railway reservation and air reservation system also uses this technology. LAN and WAN for communication of vertical information
through computer network.
Office Automation and Publication:
Microprocessor based micro computer with software packages has changed the office environment.
Microprocessors based systems are being used for word processing, spread sheet operations, storage etc. The microprocessor has revolutionize the publication technology.
Consumer:
The use of microprocessor in toys, entertainment equipment and home applications is making them more
entertaining and full of features. The use of microprocessors is more widespread and popular.Now the Microprocessors are used in :
1. Calculators 2. Accounting system 3. Games machine 4. Complex Industrial Controllers
5. Traffic light Control 6. Data acquisition systems
7. Multi user, multi- function environments 8. Military applications 9. Communication systems
Evolution of Microprocessor:
Microprocessors were categorized into five generations: first, second, third, fourth, and fifth generations. Their characteristics are described below:
First-generation: The microprocessors that were introduced in 1971 to 1972 were referred to as the first generation systems. First-generation microprocessors processed their instructions serially—they fetched the
instruction, decoded it, then executed it. When an instruction was completed, the microprocessor updated the instruction pointer and fetched the next instruction, performing this sequential drill for each instruction in
turn.
Second generation: By the late 1970s, enough transistors were available on the IC to usher in the second generation of microprocessor sophistication: 16-bit arithmetic and pipelined instruction processing. Motorola’s MC68000 microprocessor, introduced in 1979, is an example. Another example is Intel’s 8080.
This generation is defined by overlapped fetch, decode, and execute steps (Computer 1996). As the first instruction is processed in the execution unit, the second instruction is decoded and the third instruction is
fetched. The distinction between the first and second generation devices was primarily the use of newer semiconductor technology to fabricate the chips. This new technology resulted in a five-fold increase in
instruction, execution, speed, and higher chip densities.
Third generation: The third generation, introduced in 1978, was represented by Intel’s 8086 and the Zilog Z8000, which were 16-bit processors with minicomputer-like performance. The third generation came about
as IC transistor counts approached 250,000.
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Motorola’s MC68020, for example, incorporated an on-chip cache for the first time and the depth of the pipeline increased to five or more stages. This generation of microprocessors was different from the previous
ones in that all major workstation manufacturers began developing their own RISC-based microprocessor architectures (Computer, 1996).
Fourth generation: As the workstation companies converted from commercial microprocessors to in-house
designs, microprocessors entered their fourth generation with designs surpassing a million transistors. Leading-edge microprocessors such as Intel’s 80960CA and Motorola’s 88100 could issue and retire more than one instruction per clock cycle.
Fifth generation: Microprocessors in their fifth generation, employed decoupled super scalar processing,
and their design soon surpassed 10 million transistors. In this generation, PCs are a low-margin, high-volume-business dominated by a single microprocessor.
Classification of Microprocessor:
The microprocessor is identified with the word size of data. For E.g. The ALU can perform a 4- bit data
operation at a time these microprocessor is called as 4-bit microprocessor.
4-Bit Processors
INTEL 404 4040
8-Bit Processors
8008 8080 8085 MOTOROLA 6800 (M6800)
16-Bit Processors
8086 8088 Zilog Z800 80186 80286
32-Bit Processors
Intel 80386 80387 80486 PENTIUM PENTIUM PRO
Architechture of 8085
This is the functional block diagram of the 8085 Microprocessor.
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Acumulator
It is a 8-bit register which is used to perform airthmetical and logical operation. It stores the output of any
operation. It also works as registers for i/o accesses. Temporary Register
It is a 8-bit register which is used to hold the data on which the acumulator is computing operation. It is also
called as operand register because it provides operands to ALU. Registers
These are general purposes registers. Microprocessor consists 6 general purpose registers of 8-bit each named as B,C,D,E,H and L. Generally theses registers are not used for storing the data permanently. It carries the 8-bits data. These are used only during the execution of the instructions.
These registers can also be used to carry the 16 bits data by making the pair of 2 registers. The valid register pairs available are BC,DE HL. We can not use other pairs except BC,DEand HL. These registers are
programmed by user. ALU
ALU performs the airthmetic operations and logical operation.
Flag Registers
It consists of 5 flip flop which changes its status according to the result stored in an accumulator. It is also
known as status registers. It is connected to the ALU. There are five flip-flops in the flag register are as follows:
1. Sign(S) 2. zero(z)
3. Auxiliary carry(AC) 4. Parity(P) 5. Carry(C)
The bit position of the flip flop in flag register is:
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D7 D6 D5 D4 D3 D2 D1 D0
S Z
AC
P
CY
All of the three flip flop set and reset according to the stored result in the accumulator. 1.Sign-
If D7 of the result is 1 then sign flag is set otherwise reset. As we know that a number on the D7 always
desides the sign of the number. if D7 is 1: the number is negative. if D7 is 0: the number is positive. 2.Zeros(Z)-
If the result stored in an accumulator is zero then this flip flop is set otherwise it is reset. 3.Auxiliary carry(AC)-
If any carry goes from D3 to D4 in the output then it is set otherwise it is reset.
4.Parity(P)-
If the no of 1's is even in the output stored in the accumulator then it is set otherwise it is reset for the odd.
5.Carry(C)-
If the result stored in an accumulator generates a carry in its final output then it is set otherwise it is reset. Instruction registers(IR)
It is a 8-bit register. When an instruction is fetched from memory then it is stored in this register. Instruction Decoder(ID)
Instruction decoder identifies the instructions. It takes the informations from instruction register and decodes the instruction to be performed. Program Counter(PC)
It is a 16 bit register used as memory pointer. It stores the memory address of the next instruction to be executed. So we can say that this register is used to sequencing the program. Generally the memory have 16
bit addresses so that it has 16 bit memory. The program counter is set to 0000H. Stack Pointer(SP)
It is also a 16 bit register used as memory pointer. It points to the memory location called stack. Generally
stack is a reserved portion of memory where information can be stores or taken back together. Timing and Control Unit
It provides timing and control signal to the microprocessor to perform the various operation.It has three control signal. It controls all external and internal circuits. It operates with reference to clock signal.It synchronizes all the data transfers.
There are three control signal:
1. ALE-Airthmetic Latch Enable, It provides control signal to synchronize the components of microprocessor.
2. RD- This is active low used for reading operation.
3. WR-This is active low used for writing operation. There are three status signal used in microprocessor S0, S1 and IO/M. It changes its status according the
provided input to these pins. Serial Input Output Control-
There are two pins in this unit. This unit is used for serial data communication.
Interrupt Unit
There are 6 interrupt pins in this unit. Generally an external hardware is connected to these pins. These pins
provide interrupt signal sent by external hardware to microprocessor and microprocessor sends acknowledgement for receiving the interrupt signal. Generally INTA is used for acknowledgement. Register Section
Many registers has been used in microprocessor. PIPO shift register It consists of PIPO(Parallel Input
Parallel Output) register.
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Pin Diagram and Pin description of 8085
8085 is a 40 pin IC, The signals from the pins can be grouped as follows
1. Power supply and clock signals 2. Address bus
3. Data bus 4. Control and status signals
5. Interrupts and externally initiated signals 6. Serial I/O ports
1. Power supply and Clock frequency signals:
Vcc: + 5 volt power supply Vss: Ground X1, X2 : Crystal or R/C network or LC network connections to set the frequency of internal clock generator.
The frequency is internally divided by two. Since the basic operating timing frequency is 3 MHz, a 6 MHz crystal is connected externally. CLK (output)-Clock Output is used as the system clock for peripheral and
devices interfaced with the microprocessor. 2. Address Bus:
A8 - A15: (output; 3-state)
It carries the most significant 8 bits of the memory address or the 8 bits of the I/O address. 3. Data bus:
AD0 - AD7 (input/output; 3-state)
These multiplexed set of lines used to carry the lower order 8 bit address as well as data bus. During the opcode fetch operation, in the first clock cycle, the lines deliver the lower order address
A0 - A7.
In the subsequent IO / memory, read / write clock cycle the lines are used as data bus. The CPU may read or write out data through these lines.
4. Control and Status signals:
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ALE (output) - Address Latch Enable. It is an output signal used to give information of AD0-AD7 contents.
It is a positive going pulse generated when a new operation is started by uP. When pulse goes high it indicates that AD0-AD7 are address. When it is low it indicates that the contents are data.
RD (output 3-state, active low) Read memory or IO device.
This indicates that the selected memory location or I/O device is to be read and that the data bus is ready for accepting data from the memory or I/O device
WR (output 3-state, active low)
device. IO/M (output) - Select memory or an IO device.
This status signal indicates that the read / write operation relates to whether the memory or I/O
device. It goes high to indicate an I/O operation.
It goes low for memory operations. 5. Status Signals:
S1: S2:
It is used to know the type of current operation of the microprocessor.
IO/M S1 S0 OPERATION
0 1 1 Opcode fetch
0 1 0 Memory read
0 0 1 Memory write
1 1 0 I/O read
1 0 1 I/O write
1 1 0 Interrupt acknowledge
Z 0 1 Halt
Z x x Hold
Z x x Reset
6. Interrupts and Externally initiated operations:
They are the signals initiated by an external device to request the microprocessor to do a particular task or work.
There are five hardware interrupts called, TRAP, RST 7.5, RST 6.5, RST 5.5, INTA On receipt of an interrupt, the microprocessor acknowledges the interrupt by the active low INTA
(Interrupt Acknowledge) signal. Reset In (input, active low)
This signal is used to reset the microprocessor.
The program counter inside the microprocessor is set to zero. The buses are tri-stated. Reset Out (Output)
It indicates CPU is being reset. Used to reset all the connected devices when the microprocessor is reset.
7. Direct Memory Access (DMA): Tri state devices:
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When 2 or more devices are connected to a common bus, to prevent the devices from interfering with
each other, the tristate gates are used to disconnect all devices except the one that is communicating at a given instant.
The CPU controls the data transfer operation between memory and I/O device. Direct Memory
Access operation is used for large volume data transfer between memory and an I/O device directly. The CPU is disabled by tri-stating its buses and the transfer is effected directly by external control
circuits. HOLD signal is generated by the DMA controller circuit. On receipt of this signal, the
microprocessor acknowledges the request by sending out HLDA signal and leaves out the control of
the buses. After the HLDA signal the DMA controller starts the direct transfer of data. READY (input)
Memory and I/O devices will have slower response compared to microprocessors. Before completing the present job such a slow peripheral may not be able to handle further data or
control signal from CPU.
The processor sets the READY signal after completing the present job to access the data. The microprocessor enters into WAIT state while the READY pin is disabled.
8. Single Bit Serial I/O ports:
SID (input) Serial input data line
SOD (output) Serial output data line
These signals are used for serial communication.
Addressing Modes in 8085
1. Immediate Addressing Mode
2. Register Addressing Mode 3. Direct Addressing Mode 4. Indirect Addressing Mode
5. Implied/implicit Addressing Mode
Immediate Addressing Mode:
An immediate is transferred directly to the register.
Eg: - MVI A, 30H (30H is copied into the register A)
MVI B,40H(40H is copied into the register B). Register Addressing Mode
Data is copied from one register to another register.
Eg: - MOV B, A (the content of A is copied into the register B) MOV A, C (the content of C is copied into the register A).
Direct Addressing Mode
Data is directly copied from the given address to the register.
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Eg: - LDA 3000H (The content at the location 3000H is copied to the register A).
Indirect Addressing Mode
The data is transferred from the address pointed by the data in a register to other register. Eg: - MOV A, M (data is transferred from the memory location pointed by the regiser to the accumulator).
Implied Addressing Mode
This mode doesn't require any operand. The data is specified by opcode itself. Eg: -
RAL CMP
Bus Structure in 8085 There are three buses in Microprocessor:
1. Address Bus 2. Data Bus
3. Control Bus
Address Bus
Genearlly, Microprocessor has 16 bit address bus. The bus over which the CPU sends out the address of the memory location is known as Address bus. The address bus carries the address of memory location to be written or to be read from.
The address bus is unidirectional. It means bits flowing occurs only in one direction, only from microprocessor to peripheral devices. We can find that how much memory location it can using the formula
2^N. where N is the number of bits used for address lines.
Data Bus
8085 Microprocessor has 8 bit data bus. So it can be used to carry the 8 bit data starting from 00000000H(00H) to 11111111H(FFH). Here 'H' tells the Hexadecimal Number. It is bidirectional. These
lines are used for data flowing in both direction means data can be transferred or can be received through these lines. The data bus also connects the I/O ports and CPU. The largest number that can appear on the data bus is 11111111.
It has 8 parallel lines of data bus. So it can access upto 2^8 = 256 data bus lines.
Control Bus
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The control bus is used for sending control signals to the memory and I/O devices. The CPU sends control signal on the control bus to enable the outputs of addressed memory devices or I/O port devices.
Some of the control bus signals are as follows: 1. Memory read 2. Memory write
3. I/O read 4. I/O write
Interrupts In 8085
what is Interrupt?
Interrupt is a mechanism by which an I/O or an instruction can suspend the normal execution of processor
and get itself serviced. Generally, a particular task is assigned to that interrupt signal. In the microprocessor based system the interrupts are used for data transfer between the peripheral devices and the microprocessor.
Interrupt Service Routine(ISR)
A small program or a routine that when executed services the corresponding interrupting source is called as
an ISR.
Maskable/Non-Maskable Interrupt
An interrupt that can be disabled by writing some instruction is known as Maskable Interrupt otherwise it is called Non-Maskable Interrupt.
There are 6 pins available in 8085 for interrupt:
1. TRAP
2. RST 7.5 3. RST6.5
4. RST5.5 5. INTR 6. INTA
Execution of Interrupts
When there is an interrupt requests to the Microprocessor then after accepting the interrupts Microprocessor send the INTA (active low) signal to the peripheral. The vectored address of particular interrupt is stored in program counter. The processor executes an interrupt service routine (ISR) addressed in program counter.
There are two types of interrupts used in 8085 Microprocessor:
1. Hardware Interrupts 2. Software Interrupts
Software Interrupts
A software interrupts is a particular instructions that can be inserted into the desired location in the rpogram.
There are eight Software interrupts in 8085 Microprocessor. From RST0 to RST7. 1. RST0 2. RST1
3. RST2 4. RST3
5. RST4 6. RST5 7. RST6
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8. RST7
They allow the microprocessor to transfer program control from the main program to the subroutine program. After completing the subroutine program, the program control returns back to the main program. We can calculate the vector address of these interrupts using the formula given below:
Vector Address = Interrupt Number * 8
For Example: RST2: vector address=2*8 = 16 RST1: vector address=1*8 = 08
RST3: vector address=3*8 = 24 Vector address table for the software interrupts:
Interrupt Vector Address
RST0 RST1
0000H 0008H
RST2 RST3
0010H 0018H
RST4 RST5
0020H 0028H
RST6
RST7
0030H
0038H
Hardware Interrupt
As i have already discussed that there are 6 interrupt pins in the microprocessor used as Hardware Interrrupts given below:
1. TRAP
2. RST7.5 3. RST6.5
4. RST5.5 5. INTR
Note:
INTA is not an interrupt. INTA is used by the Microprocessor for sending the acknowledgement. TRAP has
highest priority and RST7.5 has second highest priority and so on. The Vector address of these interrupts are given below:
Interrupt Vector Address
RST7.5 003CH
RST6.5 0034H
RST5.5 002CH
TRAP 0024H
TRAP
It is non maskable edge and level triggered interrupt. TRAP has the highest priority and vectores interrupt. Edge and level triggered means that the TRAP must go high and remain high until it is acknowledged. In
case of sudden power failure, it executes a ISR and send the data from main memory to backup memory.
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As we know that TRAP can not be masked but it can be delayed using HOLD signal. This interrupt transfers the microprocessor's control to location 0024H.
TRAP interrupts can only be masked by reseting the microprocessor. There is no other way to mask it.
RST7.5
It has the second highest priority. It is maskable and edge level triggered interrupt. The vector address of this
interrupt is 003CH. Edge sensitive means input goes high and no need to maintain high state until it is recognized. It can also be reset or masked by reseting microprocessor. It can also be resetted by DI instruction.
RST6.5 and RST5.5
These are level triggered and maskable interrupts. When RST6.5 pin is at logic 1, INTE flip-flop is set. RST 6.5 has third highest priority and RST 5.5 has fourth highest priority.
It can be masked by giving DI and SIM instructions or by reseting microprocessor.
INTR
It is level triggered and maskable interrupt. The following sequence of events occurs when INTR signal goes high:
1. The 8085 checks the status of INTR signal during execution of each instruction. 2. If INTR signal is high, then 8085 complete its current instruction and sends active low interrupt
acknowledge signal, if the interrupt is enabled.
3. On receiving the instruction, the 8085 save the address of next instruction on stack and execute received instruction.
It has the lowest priority. It can be disabled by reseting the microprocessor or by DI and SIM instruction.
Instruction Set 8085
1. Control 2. Logical
3. Branching 4. Arithmetic
5. Data Transfer
Control Instructions
Opcode Operand Explanation of
Instruction Description
NOP none No operation No operation is performed. The instruction is fetched and decoded. However no operation is executed. Example: NOP
HLT none Halt and enter wait state
The CPU finishes executing the current instruction and halts any further execution. An interrupt or reset is necessary to exit from the halt state. Example: HLT
DI none Disable interrupts
The interrupt enable flip-flop is reset and all the interrupts except the TRAP are disabled. No flags are affected. Example: DI
EI none Enable interrupts
The interrupt enable flip-flop is set and all interrupts are enabled. No flags are affected. After a system reset or the acknowledgement of an interrupt, the interrupt enable flipflop is reset, thus disabling the interrupts. This instruction is necessary to reenable the interrupts (except TRAP). Example: EI
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RIM none Read interrupt mas
This is a multipurpose instruction used to read the status of interrupts 7.5, 6.5, 5.5 and read serial data input bit. The instruction loads eight bits in the accumulator with the following interpretations. Example: RIM
SIM none Set interrupt mask
This is a multipurpose instruction and used to implement the 8085 interrupts 7.5, 6.5, 5.5, and serial data output. The instruction interprets the accumulator contents as follows. Example: SIM
LOGICAL INSTRUCTIONS
Opcode Operand Explanation of
Instruction Description
CMP R
M
Compare register or memory with accumulator
The contents of the operand (register or memory) are M compared with the contents of the accumulator. Both contents are preserved . The result of the comparison is shown by setting the flags of the PSW as follows:
if (A) < (reg/mem): carry flag is set if (A) = (reg/mem): zero flag is set if (A) > (reg/mem): carry and zero flags are reset
Example: CMP B or CMP M
CPI 8-bit data Compare immediate with accumulator
The second byte (8-bit data) is compared with the contents of the accumulator. The values being compared remain unchanged. The result of the comparison is shown by setting the flags of the PSW as follows:
if (A) < data: carry flag is set if (A) = data: zero flag is set if (A) > data: carry and zero flags are reset Example: CPI 89H
ANA R
M
Logical AND register or memory with accumulator
The contents of the accumulator are logically ANDed with M the contents of the operand (register or memory), and the result is placed in the accumulator. If the operand is a memory location, its address is specified by the contents of HL registers. S, Z, P are modified to reflect the result of the operation. CY is reset. AC is set. Example: ANA B or ANA M
ANI 8-bit
data
Logical AND immediate with accumulator
The contents of the accumulator are logically ANDed with the 8-bit data (operand) and the result is placed in the accumulator. S, Z, P are modified to reflect the result of the operation. CY is reset. AC is set. Example: ANI 86H
XRA
R
M
Exclusive OR register or memory with accumulator
The contents of the accumulator are Exclusive ORed with M the contents of the operand (register or memory), and the result is placed in the accumulator. If the operand is a memory location, its address is specified by the contents of HL registers. S, Z, P are modified to reflect the result of the operation. CY and AC are reset. Example: XRA B or XRA M
XRI 8-bit
data
Exclusive OR immediate with accumulator
The contents of the accumulator are Exclusive ORed with the 8-bit data (operand) and the result is placed in the accumulator. S, Z, P are modified to reflect the result of the operation. CY and AC are reset. Example: XRI 86H
ORA
R
M
Logical OR register or memory with accumulator
The contents of the accumulator are logically ORed with M the contents of the operand (register or memory), and the result is placed in the accumulator. If the operand is a memory location, its address is specified
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by the contents of HL registers. S, Z, P are modified to reflect the result of the operation. CY and AC are reset. Example: ORA B or ORA M
ORI 8-bit
data
Logical OR immediate with accumulator
The contents of the accumulator are logically ORed with the 8-bit data (operand) and the result is placed in the accumulator. S, Z, P are modified to reflect the result of the operation. CY and AC are reset. Example: ORI 86H
RLC none Rotate accumulator left
Each binary bit of the accumulator is rotated left by one position. Bit D7 is placed in the position of D0 as well as in the Carry flag. CY is modified according to bit D7. S, Z, P, AC are not affected. Example: RLC
RRC none Rotate accumulator right
Each binary bit of the accumulator is rotated right by one position. Bit D0 is placed in the position of D7 as well as in the Carry flag. CY is modified according to bit D0. S, Z, P, AC are not affected. Example: RRC
RAL none Rotate accumulator left through carry
Each binary bit of the accumulator is rotated left by one position through the Carry flag. Bit D7 is placed in the Carry flag, and the Carry flag is placed in the least significant position D0. CY is modified according to bit D7. S, Z, P, AC are not affected. Example: RAL
RAR none Rotate accumulator right through carry
Each binary bit of the accumulator is rotated right by one position through the Carry flag. Bit D0 is placed in the Carry flag, and the Carry flag is placed in the most significant position D7. CY is modified according to bit D0. S, Z, P, AC are not affected. Example: RAR
CMA none Complement accumulator
The contents of the accumulator are complemented. No flags are affected. Example: CMA
CMC none Complement carry The Carry flag is complemented. No other flags are affected. Example: CMC
STC none Set Carry Set Carry Example: STC
BRANCHING INSTRUCTIONS
Opcode Operand Explanation of
Instruction Description
JMP 16-bit
address
Jump unconditionally
The program sequence is transferred to the memory location specified by the 16-bit address given in the operand. Example: JMP 2034H or JMP XYZ
Opcode Description Flag Status
JC Jump on Carry CY = 1
JNC Jump on no Carry CY = 0
JP Jump on positive S = 0
JM Jump on minus S = 1
JZ Jump on zero Z = 1
JNZ Jump on no zero Z = 0
JPE Jump on parity
even P = 1
JPO Jump on parity P = 0
16-bit
address
Jump conditionally
The program sequence is transferred to the memory location specified by the 16-bit address given in the operand based on the specified flag of the PSW as described below.
Example: JZ 2034H or JZ XYZ
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odd
Opcode Description Flag Status
CC Call on Carry CY = 1
CNC Call on no Carry CY = 0
CP Call on positive S = 0
CM Call on minus S = 1
CZ Call on zero Z = 1
CNZ Call on no zero Z = 0
CPE Call on parity
even P = 1
CPO Call on parity odd P = 0
16-bit
address
Unconditional subroutine call
The program sequence is transferred to the memory location specified by the 16-bit address given in the operand. Before the transfer, the address of the next instruction after CALL (the contents of the program counter) is pushed onto the stack.
Example: CALL 2034H or CALL XYZ
RET none
Return from subroutine unconditionally
The program sequence is transferred from the subroutine to the calling program. The two bytes from the top of the stack are copied into the program counter,and program execution begins at the new address. Example: RET
Opcode Description Flag Status
RC Return on Carry CY = 1
RNC Return on no Carry
CY = 0
RP Return on positive S = 0
RM Return on minus S = 1
RZ Return on zero Z = 1
RNZ Return on no zero Z = 0
RPE Return on parity
even P = 1
RPO Return on parity
odd P = 0
none
Return from subroutine conditionally
The program sequence is transferred from the subroutine to the calling program based on the specified flag of the PSW as described below. The two bytes from the top of the stack are copied into the program counter, and program execution begins at the new address. Example: RZ
PCHL none
Load program counter with HL contents
The contents of registers H and L are copied into the program counter. The contents of H are placed as the high-order byte and the contents of L as the low-order byte. Example: PCHL
RST
0-7 Restart
The RST instruction is equivalent to a 1-byte call instruction to one of eight memory locations depending upon the number. The instructions are generally used in conjunction with interrupts and inserted using external hardware. However these can be used as software instructions in a program to transfer program execution to one of the eight locations. The addresses are:
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Instruction Restart
Address
RST 0 0000H
RST1 0008H
RST 2 0010H
RST 3 0018H
RST 4 0020H
RST 5 0028H
RST 6 0030H
RST 7 0038H
The 8085 has four additional interrupts and these interrupts generate RST instructions internally and thus do not require any external hardware. These instructions and their Restart addresses are:
Interrupt Restart
Address
TRAP 0024H
RST 5.5 002CH
RST 6.5 0034H
RST 7.5 003CH
Arithmetic Instructions
Opcode Operand Explanation of
Instruction Description
ADD
R
M
Add register or memory, to accumulator
The contents of the operand (register or memory) are added to the contents of the accumulator and the result is stored in the accumulator. If the operand is a memory location, its location is specified by the contents of the HL registers. All flags are modified to reflect the result of the addition. Example: ADD B or ADD M
ADC
R
M
Add register to accumulator with carry
The contents of the operand (register or memory) and M the Carry flag are added to the contents of the accumulator and the result is stored in the accumulator. If the operand is a memory location, its location is specified by the contents of the HL registers. All flags are modified to reflect the result of the addition. Example: ADC B or ADC M
ADI 8-bit data Add immediate to accumulator
The 8-bit data (operand) is added to the contents of the accumulator and the result is stored in the accumulator. All flags are modified to reflect the result of the addition. Example: ADI 45H
ACI 8-bit data Add immediate to accumulator with carry
The 8-bit data (operand) and the Carry flag are added to the contents of the accumulator and the result is stored in the accumulator. All flags are modified to reflect the result of the addition.
Example: ACI 45H
LXI Reg. pair,
16-bit data
Load register pair immediate
The instruction loads 16-bit data in the register pair designated in the operand. Example: LXI H, 2034H or LXI H, XYZ
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DAD Reg. pair Add register pair to H and L registers
The 16-bit contents of the specified register pair are added to the contents of the HL register and the sum is stored in the HL register. The contents of the source register pair are not altered. If the result is larger than 16 bits, the CY flag is set. No other flags are affected. Example: DAD H
SUB
R
M
Subtract register or memory from accumulator
The contents of the operand (register or memory ) are subtracted from the contents of the accumulator, and the result is stored in the accumulator. If the operand is a memory location, its location is specified by the contents of the HL registers. All flags are modified to reflect the result of the subtraction. Example: SUB B or SUB M
SBB
R
M
Subtract source and borrow from accumulator
The contents of the operand (register or memory ) and M the Borrow flag are subtracted from the contents of the accumulator and the result is placed in the accumulator. If the operand is a memory location, its location is specified by the contents of the HL registers. All flags are modified to reflect the result of the subtraction. Example: SBB B or SBB M
SUI 8-bit data Subtract immediate from accumulator
The 8-bit data (operand) is subtracted from the contents of the accumulator and the result is stored in the accumulator. All flags are modified to reflect the result of the subtraction. Example: SUI 45H
SBI 8-bit data Subtract immediate from accumulator with borrow
The contents of register H are exchanged with the contents of register D, and the contents of register L are exchanged with the contents of register E. Example: XCHG
INR R
M
Increment register or memory by 1
The contents of the designated register or memory) are incremented by 1 and the result is stored in the same place. If the operand is a memory location, its location is specified by the contents of the HL registers. Example: INR B or INR M
INX R Increment register pair by 1
The contents of the designated register pair are incremented by 1 and the result is stored in the same place. Example: INX H
DCR R
M
Decrement register or memory by 1
The contents of the designated register or memory are M decremented by 1 and the result is stored in the same place. If the operand is a memory location, its location is specified by the contents of the HL registers. Example: DCR B or DCR M
DCX R Decrement register pair by 1
The contents of the designated register pair are decremented by 1 and the result is stored in the same place. Example: DCX H
DAA none Decimal adjust accumulator
The contents of the accumulator are changed from a binary value to two 4-bit binary coded decimal (BCD) digits. This is the only instruction that uses the auxiliary flag to perform the binary to BCD conversion, and the conversion procedure is described below. S, Z, AC, P, CY flags are altered to reflect the results of the operation.
If the value of the low-order 4-bits in the accumulator is greater than 9 or if AC flag is set, the instruction adds 6 to the low-order four bits.
If the value of the high-order 4-bits in the accumulator is greater than 9 or if the Carry flag is set, the instruction adds 6 to the high-order four bits. Example: DAA
Data Transfer Instructions
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Opcode Operand Explanation of
Instruction Description
MOV
Rd, Rs
M, Rs
Rd, M
Copy from source(Rs) to destination(Rd)
This instruction copies the contents of the source register into the destination register; the contents of the source register are not altered. If one of the operands is a memory location, its location is specified by the contents of the HL registers. Example: MOV B, C or MOV B, M
MVI
Rd, data
M, data
Move immediate 8-bit The 8-bit data is stored in the destination register or memory. If the operand is a memory location, its location is specified by the contents of the HL registers. Example: MVI B, 57H or MVI M, 57H
LDA 16-bit
address Load accumulator
The contents of a memory location, specified by a 16-bit address in the operand, are copied to the accumulator. The contents of the source are not altered. Example: LDA 2034H
LDAX B/D Reg.
pair
Load accumulator indirect
The contents of the designated register pair point to a memory location. This instruction copies the contents of that memory location into the accumulator. The contents of either the register pair or the memory location are not altered. Example: LDAX B
LXI Reg. pair,
16-bit data
Load register pair immediate
The instruction loads 16-bit data in the register pair designated in the operand. Example: LXI H, 2034H or LXI H, XYZ
LHLD 16-bit
address
Load H and L registers direct
The instruction copies the contents of the memory location pointed out by the 16-bit address into register L and copies the contents of the next memory location into register H. The contents of source memory locations are not altered. Example: LHLD 2040H
STA 16-bit
address 16-bit address
The contents of the accumulator are copied into the memory location specified by the operand. This is a 3-byte instruction, the second byte specifies the low-order address and the third byte specifies the high-order address. Example: STA 4350H
STAX Reg. pair Store accumulator indirect
The contents of the accumulator are copied into the memory location specified by the contents of the operand (register pair). The contents of the accumulator are not altered. Example: STAX B
SHLD 16-bit
address
Store H and L registers direct
The contents of register L are stored into the memory location specified by the 16-bit address in the operand and the contents of H register are stored into the next memory location by incrementing the operand. The contents of registers HL are not altered. This is a 3-byte instruction, the second byte specifies the low-order address and the third byte specifies the high-order address. Example: SHLD 2470H
XCHG none Exchange H and L with D and E
The contents of register H are exchanged with the contents of register D, and the contents of register L are exchanged with the contents of register E. Example: XCHG
SPHL none Copy H and L registers to the stack pointer
The instruction loads the contents of the H and L registers into the stack pointer register, the contents of the H register provide the high-order address and the contents of the L register provide the low-order address. The contents of the H and L registers are not altered. Example: SPHL
XTHL none Exchange H and L with top of stack
The contents of the L register are exchanged with the stack location pointed out by the contents of the stack pointer register. The contents of the H register are exchanged with the next stack location (SP+1); however, the contents of the stack pointer register are not altered. Example: XTHL
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PUSH Reg. pair Push register pair onto stack
The contents of the register pair designated in the operand are copied onto the stack in the following sequence. The stack pointer register is decremented and the contents of the highorder register (B, D, H, A) are copied into that location. The stack pointer register is decremented again and the contents of the low-order register (C, E, L, flags) are copied to that location. Example: PUSH B or PUSH A
POP Reg. pair Pop off stack to register pair
The contents of the memory location pointed out by the stack pointer register are copied to the low-order register (C, E, L, status flags) of the operand. The stack pointer is incremented by 1 and the contents of that memory location are copied to the high-order register (B, D, H, A) of the operand. The stack pointer register is again incremented by 1. Example: POP H or POP A
OUT 8-bit port
address
Output data from accumulator to a port with 8-bit address
The contents of the accumulator are copied into the I/O port specified by the operand. Example: OUT F8H
IN 8-bit port
address
Input data to accumulator from a port with 8-bit address
The contents of the input port designated in the operand are read and loaded into the accumulator. Example: IN 8CH
Introduction of 8237
Direct Memory Access (DMA) is a method of allowing data to be moved from one location to
another in a computer without intervention from the central processor (CPU). It is also a fast way of transferring data within (and sometimes between) computer. The DMA I/O technique provides direct access to the memory while the microprocessor is
temporarily disabled. The DMA controller temporarily borrows the address bus, data bus and control bus from the
microprocessor and transfers the data directly from the external devices to a series of memory
locations (and vice versa).
Basic DMA Operation:
Two control signals are used to request and acknowledge a direct memory access (DMA) transfer in the microprocessor-based system.
1. The HOLD signal as an input(to the processor) is used to request a DMA action. 2. The HLDA signal as an output that acknowledges the DMA action.
When the processor recognizes the hold, it stops its execution and enters hold cycles. HOLD input has higher priority than INTR or NMI. The only microprocessor pin that has a higher priority than a HOLD is the RESET pin.
HLDA becomes active to indicate that the processor has placed its buses at high-impedance state.
Basic DMA Definitions
Direct memory accesses normally occur between an I/O device and memory without the use of the
microprocessor. 1. A DMA read transfers data from the memory
to the I/O device.
2. A DMA write transfers data from an I/O device to memory.
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The system contains separate memory and I/O control signals. Hence the Memory & the I/O are controlled simultaneously
The DMA controller provides memory with its address, and the controller signal selects the I/O device during the transfer.
Data transfer speed is determined by speed of the memory device or a DMA controller.
In many cases, the DMA controller slows the speed of the system when transfers occur. The serial PCI (Peripheral Component Interface) Express bus transfers data at rates exceeding DMA
transfers. This in modern systems has made DMA is less important.
CPU having the control over the bus When DMA operates
The 8237 DMA Controller
The 8237 supplies memory & I/O with control signals and memory address information during the DMA transfer.
It is actually a special-purpose microprocessor whose job is high-speed data transfer between memory and I/O
8237 is not a discrete component in modern microprocessor-based systems. It appears within many system controller chip sets 8237 is a four-channel device compatible with 8086/8088, adequate for small systems.
Expandable to any number of DMA channel inputs 8237 is capable of DMA transfers at rates up to 1.6MB per second.
Each channel is capable of addressing a full 64K-byte section of memory.
Block Diagram of 8237
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8237 Internal Registers
CAR
The current address register holds a 16-bit memory address used for the DMA transfer. each channel has its own current address
register for this purpose. When a byte of data is transferred during a DMA operation, CAR is either incremented
or decremented. depending on how it is programmed CWCR
The current word count register programs a channel for the number of bytes to transferred during a DMA action.
CR
The command register programs the operation of the 8237 DMA controller.
The register uses bit position 0 to select the memory-to-memory DMA transfer mode. 1. Memory-to-memory DMA transfers use DMA channel
2. DMA channel 0 to hold the source address 3. DMA channel 1 holds the destination address
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BA and BWC
The base address (BA) and base word count (BWC) registers are used when auto-initialization is selected for a channel.
In auto-initialization mode, these registers are used to reload the CAR and CWCR after the DMA action is completed.
MR
The mode register programs the mode of operation for a channel.
Each channel has its own mode register as selected by bit positions 1 and 0. 1. Remaining bits of the mode register select operation, auto-initialization, increment/decrement,
and mode for the channel
BR
The bus request register is used to request a DMA transfer via software. 1. very useful in memory-to-memory transfers, where an external signal is not available to begin
the DMA transfer
MRSR
The mask register set/reset sets or clears the channel mask. 1. if the mask is set, the channel is disabled
2. the RESET signal sets all channel masks to disable them
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MSR
The mask register clears or sets all of the masks with one command instead of individual channels, as with the MRSR.
SR
The status register shows status of each DMA channel. The TC bits indicate if the channel has reached its terminal count (transferred all its bytes).
When the terminal count is reached, the DMA transfer is terminated for most modes of operation.
The request bits indicate whether the DREQ input for a given channel is active.
8237 Software Commands
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Master clear
Acts exactly the same as the RESET signal to the 8237. As with the RESET signal, this command
disables all channels Clear mask register
Enables all four DMA channels.
Clear the first/last flip-flop
Clears the first/last (F/L) flip-flop within 8237. The F/L flip-flop selects which byte (low or high order) is read/written in the current address and current count registers. if F/L = 0, the low-order byte
is selected if F/L = 1, the high-order byte is selected Any read or write to the address or count register automatically toggles the F/L flip-flop.
Pin Diagram and Pin description of 8237
VCC
POWER: a5V supply.
VSS
GROUND: Ground.
CLK Input
CLOCK INPUT:Clock Input controls the internal operations of the 8237A and its rate of data transfers. The
input may be driven at up to 5 MHz for the 8237A-5.
CS Input
CHIP SELECT:Chip Select is an active low input used to select the 8237A as an I/O device during the Idle
cycle. This allows CPU communication on the data bus.
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RESET Input
RESET: Reset is an active high input which clears the Command, Status, Request and Temporary registers. It also clears the first/ last flip/flop and sets the Mask register. Following a Reset the device is in the Idle cycle.
READY Input
READY: Ready is an input used to extend the memory read and write pulses from the 8237A to accommodate slow memories or I/O peripheral devices. Ready must not make transitions during its specified
setup/hold time.
HLDA Input
HOLD ACKNOWLEDGE: The active high Hold Acknowledge from the CPU indicates that it has relinquished control of the system busses.
DREQ0 ±DREQ3 Input
DMA REQUEST: The DMA Request lines are individual asynchronous channel request inputs used by peripheral circuits to obtain DMA service. In fixed Priority, DREQ0 has the highest priority and DREQ3 has
the lowest priority. A request is generated by activating the DREQ line of a channel. DACK will acknowledge the recognition of DREQ signal. Polarity of DREQ is programmable. Reset initializes these
lines to active high. DREQ must be maintained until the corresponding DACK goes active.
DB0 ±DB7
DATA BUS: The Data Bus lines are bidirectional three-state signals connected to the system data bus. The outputs are enabled in the Program condition during the I/O Read to output the contents of an Address
register, a Status register, the Temporary register or a Word Count register to the CPU. The outputs are disabled and the inputs are read during an I/O Write cycle when the CPU is programming the 8237A control
registers. During DMA cycles the most significant 8 bits of the address are output onto the data bus to be strobed into an external latch by ADSTB. In memory-to-memory operations, data from the memory comes into the 8237A on the data bus during the read-from-memory transfer. In the write-to-memory transfer, the
data bus outputs place the data into the new memory location.
IOR Input/Output
I/O READ: I/O Read is a bidirectional active low three-state line. In the Idle cycle, it is an input control
signal used by the CPU to read the control registers. In the Active cycle, it is an output control signal used by the 8237A to access data from a peripheral during a DMA Write transfer.
IOW Input/Output
I/O WRITE: I/O Write is a bidirectional active low three-state line. In the Idle cycle, it is an input control
signal used by the CPU to load information into the 8237A. In the Active cycle, it is an output control signal used by the 8237A to load data to the peripheral during a DMA Read transfer.
EOP Input/Output
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END OF PROCESS: End of Process is an active low bidirectional signal. Information concerning the completion of DMA services is available at the bidirectional EOP pin. The 8237A allows an external signal
to terminate an active DMA service. This is accomplished by pulling the EOP input low with an external EOP signal. The 8237A also generates a pulse when the terminal count (TC) for any channel is reached. This generates an EOP signal which is output through the EOP line. The reception of EOP, either internal or
external, will cause the 8237A to terminate the service, reset the request, and, if Autoinitialize is enabled, to write the base registers to the current registers of that channel. The mask bit and TC bit in the status word
will be set for the currently active channel by EOP unless the channel is programmed for Autoinitialize. In that case, the mask bit remains unchanged. During memory-to-memory transfers, EOP will be output when the TC for channel 1 occurs. EOP should be tied high with a pull-up resistor if it is not used to prevent
erroneous end of process inputs.
A0 ±A3 Input/Output
ADDRESS: The four least significant address lines are bidirectional three-state signals. In the Idle cycle they
are inputs and are used by the CPU to address the register to be loaded or read. In the Active cycle they are outputs and provide the lower 4 bits of the output address.
A4 ±A7 Output
ADDRESS: The four most significant address lines are three-state outputs and provide 4 bits of address. These lines are enabled only during the DMA service.
HRQ Output
HOLD REQUEST: This is the Hold Request to the CPU and is used to request control of the system bus. If
the corresponding mask bit is clear, the presence of any valid DREQ causes 8237A to issue the HRQ.
DACK0 ±DACK3 Output
DMA ACKNOWLEDGE: DMA Acknowledge is used to notify the individual peripherals when one has
been granted a DMA cycle. The sense of these lines is programmable. Reset initializes them to active low.
AEN Output
ADDRESS ENABLE:Address Enable enables the 8-bit latch containing the upper 8 address bits onto the
system address bus. AEN can also be used to disable other system bus drivers during DMA transfers. AEN is active HIGH.
ADSTB Output
ADDRESS STROBE: The active high, Address Strobe is used to strobe the upper address byte into an
external latch.
MEMR Output
MEMORY READ: The Memory Read signal is an active low three-state output used to access data from the
selected memory location during a DMA Read or a memory-to-memory transfer.
MEMW Output
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MEMORY WRITE: The Memory Write is an active low three-state output used to write data to the selected memory location during a DMA Write or a memory-to-memory transfer.
PIN5 Input
PIN5: This pin should always be at a logic HIGH level. An internal pull-up resistor will establish a logic high
when the pin is left floating. It is recommended however, that PIN5 be connected to VCC
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8085 Microprocessor AL Programs
Store 8-bit data in memory
1. Program 1: 2. MVI A, 52H : "Store 32H in the accumulator"
3. STA 4000H : "Copy accumulator contents at address 4000H" 4. HLT : "Terminate program execution"
1. Program 2:
2. LXI H : "Load HL with 4000H" 3. MVI M : "Store 32H in memory location pointed by HL register pair (4000H)"
4. HLT : "Terminate program execution"
Note: The result of both programs will be the same. In program 1 direct addressing instruction is used, whereas in program 2 indirect addressing instruction is used.
Exchange the contents of memory locations
Statement: Exchange the contents of memory locations 2000H and 4000H.
1. Program 1: 2. LDA 2000H : "Get the contents of memory location 2000H into accumulator" 3. MOV B, A : "Save the contents into B register" 4. LDA 4000H : "Get the contents of memory location 4000Hinto accumulator"
5. STA 2000H : "Store the contents of accumulator at address 2000H" 6. MOV A, B : "Get the saved contents back into A register"
7. STA 4000H : "Store the contents of accumulator at address 4000H"
1. Program 2: 2. LXI H 2000H : "Initialize HL register pair as a pointer to memory location 2000H." 3. LXI D 4000H : "Initialize DE register pair as a pointer to memory location 4000H."
4. MOV B, M : "Get the contents of memory location 2000H into B register." 5. LDAX D : "Get the contents of memory location 4000H into A register."
6. MOV M, A : "Store the contents of A register into memory location 2000H." 7. MOV A, B : "Copy the contents of B register into accumulator." 8. STAX D : "Store the contents of A register into memory location 4000H."
9. HLT : "Terminate program execution."
Note: In Program 1, direct addressing instructions are used, whereas in Program 2, indirect addressing instructions are used.
Add two 8-bit numbers
Statement: Add the contents of memory locations 4000H and 4001H and place the result in memory location
4002H.
1. Sample problem 2. (4000H) = 14H
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3. (4001H) = 89H 4. Result = 14H + 89H = 9DH
5. Source program 6. LXI H 4000H : "HL points 4000H" 7. MOV A, M : "Get first operand"
8. INX H : "HL points 4001H" 9. ADD M : "Add second operand"
10. INX H : "HL points 4002H" 11. MOV M, A : "Store result at 4002H" 12. HLT : "Terminate program execution"
Subtract two 8-bit numbers
Statement: Subtract the contents of memory location 4001H from the memory location 2000H and place the result in memory location 4002H.
1. Program –: Subtract two 8-bit numbers 2. Sample problem:
3. (4000H) = 51H 4. (4001H) = 19H
5. Result = 51H – 19H = 38H
Source program:
LXI H, 4000H : "HL points 4000H" MOV A, M : "Get first operand"
INX H : "HL points 4001H" SUB M : "Subtract second operand" INX H : "HL points 4002H"
MOV M, A : "Store result at 4002H" HLT : "Terminate program execution"
Add two 16-bit numbers
Statement: Add the 16-bit number in memory locations 4000H and 4001H to the 16-bit number in memory
locations 4002H and 4003H. The most significant eight bits of the two numbers to be added are in memory locations 4001H and 4003H. Store the result in memory locations 4004H and 4005H with the most significant byte in memory location 4005H.
Sample problem: (4000H) = 15H
(4001H) = 1CH (4002H) = B7H (4003H) = 5AH
Result = 1C15 + 5AB7H = 76CCH (4004H) = CCH
(4005H) = 76H Source Program 1:
LHLD 4000H : "Get first I6-bit number in HL" XCHG : "Save first I6-bit number in DE"
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LHLD 4002H : "Get second I6-bit number in HL" MOV A, E : "Get lower byte of the first number"
ADD L : "Add lower byte of the second number" MOV L, A : "Store result in L register" MOV A, D : "Get higher byte of the first number"
ADC H : "Add higher byte of the second number with CARRY" MOV H, A : "Store result in H register"
SHLD 4004H : "Store I6-bit result in memory locations 4004H and 4005H" HLT : "Terminate program execution"
Source program 2: LHLD 4000H : Get first I6-bit number
XCHG : Save first I6-bit number in DE LHLD 4002H : Get second I6-bit number in HL DAD D : Add DE and HL
SHLD 4004H : Store I6-bit result in memory locations 4004H and 4005H. HLT : Terminate program execution
NOTE: In program 1, eight bit addition instructions are used (ADD and ADC) and addition is performed in two steps. First lower byte addition using ADD instruction and then higher byte addition using ADC
instruction.In program 2, 16-bit addition instruction (DAD) is used.
Add contents of two memory locations
Statement: Add the contents of memory locations 40001H and 4001H and place the result in the memory locations 4002Hand 4003H.
Sample problem: (4000H) = 7FH
(400lH) = 89H Result = 7FH + 89H = lO8H (4002H) = 08H
(4003H) = 0lH
Source program: LXI H, 4000H : "HL Points 4000H" MOV A, M : "Get first operand"
INX H : "HL Points 4001H" ADD M : "Add second operand"
INX H : "HL Points 4002H" MOV M, A : "Store the lower byte of result at 4002H" MVIA, 00 : "Initialize higher byte result with 00H"
ADC A : "Add carry in the high byte result" INX H : "HL Points 4003H"
MOV M, A : "Store the higher byte of result at 4003H" HLT : "Terminate program execution"
Subtract two 16-bit numbers
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Statement: Subtract the 16-bit number in memory locations 4002H and 4003H from the 16-bit number in memory locations 4000H and 4001H. The most significant eight bits of the two numbers are in memory
locations 4001H and 4003H. Store the result in memory locations 4004H and 4005H with the most significant byte in memory location 4005H.
Sample problem:
(4000H) = 19H (400IH) = 6AH
(4004H) = I5H (4003H) = 5CH Result = 6A19H – 5C15H = OE04H (4004H) = 04H
(4005H) = OEH Source program:
LHLD 4000H : "Get first 16-bit number in HL" XCHG : "Save first 16-bit number in DE" LHLD 4002H : "Get second 16-bit number in HL"
MOV A, E : "Get lower byte of the first number" SUB L : "Subtract lower byte of the second number"
MOV L, A : "Store the result in L register" MOV A, D : "Get higher byte of the first number" SBB H : "Subtract higher byte of second number with borrow"
MOV H, A : "Store l6-bit result in memory locations 4004H and 4005H" SHLD 4004H : "Store l6-bit result in memory locations 4004H and 4005H"
HLT : "Terminate program execution" Finding one’s complement of a number
Statement: Find the l’s complement of the number stored at memory location 4400H and store the complemented number at memory location 4300H.
Sample problem:
(4400H) = 55H Result = (4300B) = AAB
Source program: LDA 4400B : "Get the number"
CMA : "Complement number" STA 4300H : "Store the result" HLT : "Terminate program execution"
Finding Two’s complement of a number
Statement: Find the 2′s complement of the number stored at memory location 4200H and store the complemented number at memory location 4300H
Sample problem:
(4200H) = 55H Result = (4300H) = AAH + 1 = ABH
Source program: LDA 4200H : "Get the number" CMA : "Complement the number"
ADI, 01 H : "Add one in the number" STA 4300H : "Store the result"
HLT : "Terminate program execution"
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Pack the unpacked BCD numbers
Statement: Pack the two unpacked BCD numbers stored in memory locations 4200H and 4201H and store result in memory location 4300H. Assume the least significant digit is stored at 4200H.
Sample problem: (4200H) = 04
(4201H) = 09 Result = (4300H) = 94 Source program:
LDA 4201H : "Get the Most significant BCD digit" RLC
RLC RLC RLC : "Adjust the position of the second digit (09 is changed to 90)"
ANI FOH : "Make least significant BCD digit zero" MOV C, A : "store the partial result"
LDA 4200H : "Get the lower BCD digit" ADD C : "Add lower BCD digit" STA 4300H : "Store the result"
HLT : "Terminate program execution"
Unpack a BCD number
Statement: Two digit BCD number is stored in memory location 4200H. Unpack the BCD number and store the two digits in memory locations 4300H and 4301H such that memory location 4300H will have lower
BCD digit. Sample problem: (4200H) = 58
Result = (4300H) = 08 and (4301H) = 05
Source program: LDA 4200H : "Get the packed BCD number" ANI FOH : "Mask lower nibble"
RRC RRC
RRC RRC : "Adjust higher BCD digit as a lower digit" STA 4301H : "Store the partial result"
LDA 4200H : "Get the original BCD number" ANI OFH : "Mask higher nibble"
STA 4201H : "Store the result" HLT : "Terminate program execution"
Execution format of instructions
Statement: Read the program given below and state the contents of all registers after the execution of each
instruction in sequence. Main program: 4000H LXI SP, 27FFH
4003H LXI H, 2000H
8085 Microprocessor
Prof. K. Adisesha
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4006H LXI B, 1020H 4009H CALL SUB
400CH HLT Subroutine program: 4100H SUB: PUSH B
4101H PUSH H 4102H LXI B, 4080H
4105H LXI H, 4090H 4108H SHLD 2200H 4109H DAD B
410CH POP H
1. 410DH POP B 2. 410EH RET
Right shift, bit of data( 8 bit and 16 bit)
Statement: Write a program to shift an eight bit data four bits right. Assume data is in register C.
Sample problem: (4200H) = 58
Result = (4300H) = 08 and (4301H) = 05
Source program 1: MOV A, C
RAR RAR RAR
RAR MOV C, A
HLT Statement: Write a program to shift a 16 bit data, 1 bit right. Assume that data is in BC register pair.
Source program 2
MOV A, B RAR
MOV B, A MOV A, C RAR
MOV C, A HLT
Left Shifting of a 16-bit data
Statement: Program to shift a 16-bit data 1 bit left. Assume data is in the HL register
HL = 1025 = 0001 0000 0010 0101
HL = 0001 0000 0010 0101 + HL = 0001 0000 0010 0101 ----------------------------
Result = 0010 0000 0100 1010
8085 Microprocessor
Prof. K. Adisesha
34
Alter the contents of flag register in 8085
Statement: Write a set of instructions to alter the contents of flag register in 8085. PUSH PSW : "Save flags on stack"
POP H : "Retrieve flags in ‘L’" MOV A, L : "Flags in accumulator"
CMA : "Complement accumulator" MOV L, A : "Accumulator in ‘L’" PUSH H : "Save on stack"
POP PSW : "Back to flag register" HLT : "Terminate program execution"
Count number of one’s in a number
Statement: Write a program to count number of l’s in the contents of D register and store the count in the B
register. Sample problem (2200H) = 04
(2201H) = 34H (2202H) = A9H
(2203H) = 78H (2204H) = 56H Result = (2202H) = A9H
MVI B, 00H MVI C, 08H
MOV A, D BACK: RAR JNC SKIP
INR B SKIP: DCR C
JNZ BACK HLT
Arrange in ascending order
Statement: Write a program to sort given 10 numbers from memory location 2200H in the ascending order.
MVI B, 09 :"Initialize counter" START :"LXI H, 2200H: Initialize memory pointer" MVI C, 09H :"Initialize counter 2"
BACK: MOV A, M :"Get the number" INX H :"Increment memory pointer"
CMP M :"Compare number with next number" JC SKIP :"If less, don’t interchange" JZ SKIP :"If equal, don’t interchange"
MOV D, M MOV M, A
DCX H MOV M, D INX H :"Interchange two numbers"
SKIP:DCR C :"Decrement counter 2"
8085 Microprocessor
Prof. K. Adisesha
35
JNZ BACK :"If not zero, repeat" DCR B :"Decrement counter 1"
JNZ START HLT :"Terminate program execution"
Calculate the sum of series of even numbers
Statement: Calculate the sum of series of even numbers from the list of numbers. The length of the list is in
memory location 2200H and the series itself begins from memory location 2201H. Assume the sum to be 8 bit number so you can ignore carries and store the sum at memory location 2210H. Sample problem
2200H= 4H 2201H= 20H
2202H= l5H 2203H= l3H 2204H= 22H
Result 22l0H= 20 + 22 = 42H = 42H
LDA 2200H MOV C, A :"Initialize counter" MVI B, 00H :"sum = 0"
LXI H, 2201H :"Initialize pointer" BACK: MOV A, M :"Get the number"
ANI 0lH :"Mask Bit l to Bit7" JNZ SKIP :"Don’t add if number is ODD" MOV A, B :"Get the sum"
ADD M :"SUM = SUM + data" MOV B, A :"Store result in B register"
SKIP: INX H :"increment pointer" DCR C :"Decrement counter" JNZ BACK :"if counter 0 repeat"
STA 2210H :"store sum" HLT :"Terminate program execution"
Calculate the sum of series of odd numbers
Statement: Calculate the sum of series of odd numbers from the list of numbers. The length of the list is in
memory location 2200H and the series itself begins from memory location 2201H. Assume the sum to be 16-bit. Store the sum at memory locations 2300H and 2301H. Sample problem
2200H = 4H 2201H= 9AH
2202H= 52H 2203H= 89H 2204H= 3FH
Result = 89H + 3FH = C8H 2300H= H Lower byte
2301H = H Higher byte Source program : LDA 2200H
8085 Microprocessor
Prof. K. Adisesha
36
MOV C, A :"Initialize counter" LXI H, 2201H :"Initialize pointer"
MVI E, 00 :"Sum low = 0" MOV D, E :"Sum high = 0" BACK: MOV A, M :"Get the number"
ANI 0lH :"Mask Bit 1 to Bit7" JZ SKIP :"Don’t add if number is even"
MOV A, E :"Get the lower byte of sum" ADD M :"Sum = sum + data" MOV E, A :"Store result in E register"
JNC SKIP INR D :"Add carry to MSB of SUM"
SKIP: INX H :"Increment pointer"
Find the square of given number
Statement: Find the square of the given numbers from memory location 6100H and store the result from memory location 7000H.
Sample problem 2200H = 4H 2201H= 9AH
2202H= 52H 2203H= 89H
2204H= 3FH Result = 89H + 3FH = C8H 2300H= H Lower byte
2301H = H Higher byte LXI H, 6200H :"Initialize lookup table pointer"
LXI D, 6100H :"Initialize source memory pointer" LXI B, 7000H :"Initialize destination memory pointer" BACK: LDAX D :"Get the number"
MOV L, A :"A point to the square" MOV A, M :"Get the square"
STAX B :"Store the result at destination memory location" INX D :"Increment source memory pointer" INX B :"Increment destination memory pointer"
MOV A, C CPI 05H :"Check for last number"
JNZ BACK :"If not repeat" HLT :"Terminate program execution"
Search a byte in a given number
Statement: Search the given byte in the list of 50 numbers stored in the consecutive memory locations and store the address of memory location in the memory locations 2200H and 2201H. Assume byte is in the C
register and starting address of the list is 2000H. If byte is not found store 00 at 2200H and 2201H. LX I H, 2000H :"Initialize memory pointer 52H"
MVI B, 52H :"Initialize counter" BACK: MOV A, M :"Get the number" CMP C :"Compare with the given byte"
8085 Microprocessor
Prof. K. Adisesha
37
JZ LAST :"Go last if match occurs" INX H :"Increment memory pointer"
DCR B :"Decrement counter" JNZ B :"If not zero, repeat" LXI H, 0000H
SHLD 2200H JMP END :"Store 00 at 2200H and 2201H"
LAST: SHLD 2200H :"Store memory address" END: HLT :"Stop"
Add two decimal numbers of 6 digit each
Statement: Two decimal numbers six digits each, are stored in BCD package form. Each number occupies a
sequence of byte in the memory. The starting address of first number is 6000H Write an assembly language program that adds these two numbers and stores the sum in the same format starting from memory location 6200H.
LXI H, 6000H :"Initialize pointer l to first number" LXI D, 6l00H :"Initialize pointer2 to second number"
LXI B, 6200H :"Initialize pointer3 to result" STC CMC :"Carry = 0"
BACK: LDAX D :"Get the digit" ADD M :"Add two digits"
DAA :"Adjust for decimal" STAX.B :"Store the result" INX H :"Increment pointer 1"
INX D :"Increment pointer2" INX B :"Increment result pointer"
MOV A, L CPI 06H :"Check for last digit" JNZ BACK :"If not last digit repeat"
HLT :"Terminate program execution"
Separate even numbers from given numbers
Statement: Write an assembly language program to separate even numbers from the given list of 50 numbers
and store them in the another list starting from 2300H. Assume starting address of 50 number list is 2200H. LXI H, 2200H :"Initialize memory pointer l" LXI D, 2300H :"Initialize memory pointer2"
MVI C, 32H :"Initialize counter" BACK:MOV A, M :"Get the number"
ANI 0lH :"Check for even number" JNZ SKIP :"If ODD, don’t store" MOV A, M :"Get the number"
STAX D :"Store the number in result list" INX D :"Increment pointer 2"
SKIP: INX H :"Increment pointer l" DCR C :"Decrement counter" JNZ BACK :"If not zero, repeat"
8085 Microprocessor
Prof. K. Adisesha
38
HLT :"Stop
Transfer contents to overlapping memory blocks
Statement: Write assembly language program with proper comments for the following: A block of data consisting of 256 bytes is stored in memory starting at 3000H. This block is to be shifted
(relocated) in memory from 3050H onwards. Do not shift the block or part of the block anywhere else in the memory.
Two blocks (3000 – 30FF and 3050 – 314F) are overlapping. Therefore it is necessary to transfer last byte first and first byte last.
MVI C, FFH :"Initialize counter"
LX I H, 30FFH :"Initialize source memory pointer 3l4FH" LXI D, 314FH :"Initialize destination memory pointer"
BACK: MOV A, M :"Get byte from source memory block" STAX D :"Store byte in the destination memory block" DCX H :"Decrement source memory pointer"
DCX :"Decrement destination memory pointer" DCR C :"Decrement counter"
JNZ BACK :"If counter 0 repeat" HLT :"Stop execution"