What is Assembly Language
Each personal computer has a microprocessor that manages the computer's arithmetical, logical and control activities.
Each family of processors has its own set of instructions for handling various operations like getting input from keyboard, displaying information on screen and performing various other jobs. These set of instructions are called 'machine language instruction'.
Processor understands only machine language instructions which are strings of 1s and 0s. However machine language is too obscure and complex for using in software development. So the low level assembly language is designed for a specific family of processors that represents various instructions in symbolic code and a more understandable form.
Advantages of Assembly Language
An understanding of assembly language provides knowledge of:
- Interface of programs with OS, processor and BIOS;
- Representation of data in memory and other external devices;
- How processor accesses and executes instruction;
- How instructions accesses and process data;
- How a program access external devices.
Other advantages of using assembly language are:
- It requires less memory and execution time;
- It allows hardware-specific complex jobs in an easier way;
- It is suitable for time-critical jobs;
- It is most suitable for writing interrupt service routines and other memory resident programs.
Basic Features of PC Hardware
The main internal hardware of a PC consists of the processor, memory and the registers. The registers are processor components that hold data and address. To execute a program the system copies it from the external device into the internal memory. The processor executes the program instructions.
The fundamental unit of computer storage is a bit; it could be on (1) or off (0). A group of nine related bits makes a byte. Eight bits are used for data and the last one is used for parity. According to the rule of parity, number of bits that are on (1) in each byte should always be odd.
So the parity bit is used to make the number of bits in a byte odd. If the parity is even, the system assumes that there had been a parity error (though rare) which might have caused due to hardware fault or electrical disturbance.
The processor supports the following data sizes:
- Word: a 2-byte data item
- Doubleword: a 4-byte (32 bit) data item
- Quadword: an 8-byte (64 bit) data item
- Paragraph: a 16-byte (128 bit) area
- Kilobyte: 1024 bytes
- Megabyte: 1,048,576 bytes
The Binary Number System
Every number system uses positional notation i.e., each position in which a digit is written has a different positional value. Each position is power of the base, which is 2 for binary number system, and these powers begin at 0 and increase by 1.
The following table shows the positional values for an 8-bit binary number, where all bits are set on.
| Bit value | 1 | 1 | 1 | 1 | 1 | 1 | 1 | 1 |
|---|---|---|---|---|---|---|---|---|
| Position value as a power of base 2 | 128 | 64 | 32 | 16 | 8 | 4 | 2 | 1 |
| Bit number | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
The value of a binary number is based on the presence of 1 bits and their positional value. So the value of the given binary number is: 1 + 2 + 4 + 8 +16 + 32 + 64 + 128 = 255, which is same as 28 - 1.
The Hexadecimal Number System
Hexadecimal number system uses base 16. The digits range from 0 to 15. By convention, the letters A through F is used to represent the hexadecimal digits corresponding to decimal values 10 through 15.
Main use of hexadecimal numbers in computing is for abbreviating lengthy binary representations. Basically hexadecimal number system represents a binary data by dividing each byte in half and expressing the value of each half-byte. The following table provides the decimal, binary and hexadecimal equivalents:
Example:
| Decimal number | Binary representation | Hexadecimal representation |
|---|---|---|
| 0 | 0 | 0 |
| 1 | 1 | 1 |
| 2 | 10 | 2 |
| 3 | 11 | 3 |
| 4 | 100 | 4 |
| Decimal | Binary |
|---|---|
| 60 | 00111100 |
| +42 | 00101010 |
| 102 | 01100110 |
A negative binary value is expressed in two's complement notation. According to this rule, to convert a binary number to its negative value is to reverse its bit values and add 1.
Example:
| Number 53 | 00110101 |
| Reverse the bits | 11001010 |
| Add 1 | 1 |
| Number -53 | 11001011 |
To subtract one value from another, convert the number being subtracted to two's complement format and add the numbers.
Example: Subtract 42 from 53
| Number 53 | 00110101 |
| Number 42 | 00101010 |
| Reverse the bits of 42 | 11010101 |
| Add 1 | 1 |
| Number -42 | 11010110 |
| 53 - 42 = 11 | 00001011 |
Overflow of the last 1 bit is lost.
Addressing Data in Memory
The process through which the processor controls the execution of instructions is referred as the fetch-decode-execute cycle, or the execution cycle. It consists of three continuous steps:
- Fetching the instruction from memory
- Decoding or identifying the instruction
- Executing the instruction
The processor may access one or more bytes of memory at a time. Let us consider a hexadecimal number 0725H. This number will require two bytes of memory. The high-order byte or most significant byte is 07 and the low order byte is 25.
The processor stores data in reverse-byte sequence i.e., the low-order byte is stored in low memory address and high-order byte in high memory address. So if processor brings the value 0725H from register to memory, it will transfer 25 first to the lower memory address and 07 to the next memory address.
x: memory address
When the processor gets the numeric data from memory to register, it again reverses the bytes. There are two kinds of memory addresses:
- An absolute address - a direct reference of specific location.
- The segment address (or offset) - starting address of a memory segment with the offset value
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