CEN 226 : Computer Organization & Assembly Language : CSC 225 (Lec#4)

1. CEN 226: Computer Organization & Assembly Language :CSC 225(Lec#4) By Dr. Syed Noman

2. Assembly language • An assembly language is a low-level language for programming computers. • It implements a symbolic representation of the numeric machine codes and other constants needed to program a particular CPU architecture. This representation is usually defined by the hardware manufacturer, and is based on abbreviations (called mnemonics) that help the programmer remember individual instructions, registers, etc. • An assembly language is thus specific to certain physical or virtual computer architecture (as opposed to most high-level languages, which are usually portable).

3. How to learn programming • C –Concept • L– Logic thinking • P– Practice • Concept – we must learn the basic syntax, such as how a program statement is written • Logic thinking – programming is problem solving so we must think logically in order to derive a solution • Practice – write programs

4. Instruction Set • A collection of assembly/machine language instructions that the processor can execute. • Types of instructions: • Transfer (MOV, PUSH, POP etc) • Arithmetic (ADD, SUB, MUL etc) • Logical (AND, OR, NOT etc • Control Transfer (CALL, JMP etc) • Miscelleneous (NOP, INT, LEA)

5. Format of Assembly language Statement • General format for an assembly language statement • Label Instruction Comment • Start: Mov AX, BX ; copy BX into AX Start is a user defined name. put in a label in your statement when necessary!!!! The symbol : is used to indicate that it is a label In instruction, ‘mov’ is operation code (opcode) and ‘AX’ and ‘BX’ are operands.

6. #-operands instruction • 2-operands instruction • Mov ax, bx • 1-operand instruction • Inc dl • 0-operand instruction • Nop

7. Assignment Statement • Assignment • In Java, assignment takes the form: • x = 42 ; • y = 24; • z = x + y; • In assembly language we carry out the same operation but we use an instruction to denote the assignment operator (“=” in Java). • mov x, 42 • mov y, 24 • add z, x • add z, y

8. Assignment Statement • The mov instruction carries out assignment in 8086 assembly language. • It allows us to place a number in a register or in a memory location (a variable) i.e. it assigns a value to a register or variable. • Example: Store the ASCII code for the letter A in register bx. • A has ASCII code 65D (01000001B, 41H) • The following mov instruction carries out the task: • movbx, 65d

9. Assignment Statement We could also write it as: movbx, 41h or movbx, 01000001b or movbx, ‘A’ All of the above are equivalent. They each carry out exactly the same task, namely the binary number representing the ASCII code of A is copied into the bx register.

10. Assembly program development Program .asm Object file .obj Executable file .exe link Assemble

11. Input and Output in 8086 Assembly • Each microprocessor provides instructions for I/O with the devices that are attached to it, e.g. the keyboard and screen. • The 8086 provides the instructions “in” for input and “out” for output. These instructions are quite complicated to use, so we usually use the operating system to do I/O instead. • The operating system provides a range of I/O subprograms, in much the same way as there is an extensive library of subprograms available to the C programmer. In C, to perform an I/O operation, a subprogram is called using its name, e.g. putchar() , printf() , getchar() . In addition, for example the character to be displayed by putchar() is passed as a parameter to the subprogram e.g. putchar(c).

12. Software Interrupts • In assembly language we must have a mechanism to call the operating system to carry out I/O. In addition we must be able o tell the operating system what kind of I/O operation we wish to carry out, e.g. to read a character from the keyboard, to display a character or string on the screen or to do disk I/O. • Finally, we must have a means of passing parameters to the operating subprogram.

13. “int” instruction • In 8086 assembly language, operating system subprograms are not called by name, instead, by using a software interrupt mechanism An interrupt signals the processor to suspend its current activity (i.e. running your program) and to pass control to an interrupt service program (i.e. part of the operating system). • A software interrupt is one generated by a program (as opposed to one generated by hardware). The 8086 int instruction generates a software interrupt. • It uses a single operand which is a number indicating which MSDOS subprogram is to be invoked. • When the I/O operation is finished, the interrupt service program terminates and our program will be resumed at the instruction following int.

14. int21h and its services • For I/O and some other operations, the number used is 21h . Thus, the instruction int21h transfers control to the operating system, to a subprogram that handles I/O operations. This subprogram handles a variety of I/O operations by calling appropriate subprograms. • This means that particular I/O operation (e.g. read a character, display a character) must be specified. This is done by placing a specific number in a register. The ‘ah’ register is used to pass this information. For example, the subprogram to display a string is subprogram number 9h.

15. String Output • Service 9h to display strings which are terminated by the ‘$’ character. • In order to use it, we must: • Ensure the string is terminated with the ‘$’ character. • Specify the starting address of the string in the dx register. • Specify the string output subprogram by storing 9h in ah. • Use int 21h to call MS-DOS to execute subprogram 9h.

16. Defining String Variables • The following 3 definitions are equivalent ways of defining a string “abc“: style1 db “abc” ; string constant style2 db ‘a’, ‘b’, ‘c’ ; character constants style3 db 97, 98, 99 ; ASCII codes

17. A program template .model small .stack 100h .code start: ; < the code/statements are here > mov ax, 4c00h ; return to OS int 21h end start

18. EP#1: A Simple Assembly Program .model small .stack 100h .data mesg db “Welcome to Assembly Language $” .code start: mov ax, @data movds, ax ;initialize data segment mov ah, 9h ; service of interrupt 21 to print a message lea dx, mesg ; load effective address int21h mov ax, 4c00h ; terminating program service int 21h end start end

19. Program elements

20. Character Output • The task here is to display a single character on the screen. There are three elements involved in carrying out this operation using the int instruction: • We specify the character to be displayed. This is done by storing the character’s ASCII code in a specific 8086 register. In this case we use the dl register, i.e. we use dl to pass a parameter to the output subprogram. • We specify which of MS-DOS’s I/O subprograms we wish to use. The subprogram to display a character is subprogram number 2h . This number is stored in the ah register. • We request MS-DOS to carry out the I/O operation using the int instruction. This means that we interrupt our program and transfer control to the MS-DOS subprogram that we have specified using the ah register.

21. Character Output • Example : Write a code fragment to display the character ’a’ on the screen: • C version: putchar( ‘a’ ) ; • 8086 version: mov dl, ‘a’ ;dl = ‘a‘ mov ah, 2h ; character output subprogram int 21h ; call ms-dos output character • As you can see, this simple task is quite complicated in assembly language.

22. EP#2: Displaying a character from a register .model small .stack 100h .data msg1 db "Displaying a character from register:$” .code mov ax, @data mov ds, ax mov ah,9 ; display message mov dx, offset msg1 ; lea dx, msg1 int 21h mov ah,2 ; display character mov dl, 65 int 21h mov ax, 4c00h int 21h end

23. EP#3: Displaying a character from a register on newline .model small .stack 100h .data msg1 db "Displaying a character from register:”,13,10, ‘$’ .code mov ax, @data mov ds, ax mov ah,9 ; display message mov dx, offset msg1 ; lea dx, msg1 int 21h mov ah,2 ; display character mov dl, 65 int 21h mov ax, 4c00h int 21h end

24. Assignment AP#1, AP#2 • Write a program to display ‘Salam’ using (a) character output and (b) using string output. • Write a program to display the message ‘Ding! Ding! Ding!’ and output ASCII code 7 three times. (ASCII code 7 is the Belcharacter. It causes your machine to beep! ).

25. Character Input with echo • Example : Write a code fragment to input a character from the keyboard: • C version: getche( ) ; • 8086 version: mov ah, 1 ; character input subprogram int 21h ; call ms-dos output character • The ASCII code of the character will be moved in ‘al’ register.

26. EP#4: Program to read a character and display it .model small .stack 100h .code start: movah, 1h ; keyboard input subprogram int21h ; read character into al movdl, al movah, 2h ; display subprogram int21h ; display character in dl movax, 4c00h ; return to ms-dos int21h end start

27. Assignment: AP#3 • Write a program to beep, display ‘?’ as a prompt, read a character and display it on a new line.

28. EP#5: Input character and display with messages Title ask user for 1 character and display it again on screen with appropriate messages . .model small .stack 100h .data msg1 db "Input a character: $" msg2 db 13,10,"You entered: $" .code mov ax, @data mov ds, ax mov ah,9 ; display message lea dx, msg1 int 21h mov ah, 1 int 21h ; my character in al register movbh, al mov ah,9 lea dx, msg2 int 21h mov ah,2 ; display character mov dl, bh int 21h mov ax, 4c00h int 21h end

29. Character Input without echo • Example : Write a code fragment to input a character from the keyboard without displaying it: • C version: getch( ) ; • 8086 version: mov ah, 8 ; character input subprogram int 21h ; call ms-dos output character • The ASCII code of the character will be moved in ‘al’ register.

30. Assignment: AP#4 • Write a program to display a message “Input a secret character:” and then input the character and display the character after displaying the message on newline “hmm.. You actually input:”.